diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/galoisgroups.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/galoisgroups.py new file mode 100644 index 0000000000000000000000000000000000000000..a0e424bf7554c0cedd926902e7322b9640735a8b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/galoisgroups.py @@ -0,0 +1,623 @@ +""" +Compute Galois groups of polynomials. + +We use algorithms from [1], with some modifications to use lookup tables for +resolvents. + +References +========== + +.. [1] Cohen, H. *A Course in Computational Algebraic Number Theory*. + +""" + +from collections import defaultdict +import random + +from sympy.core.symbol import Dummy, symbols +from sympy.ntheory.primetest import is_square +from sympy.polys.domains import ZZ +from sympy.polys.densebasic import dup_random +from sympy.polys.densetools import dup_eval +from sympy.polys.euclidtools import dup_discriminant +from sympy.polys.factortools import dup_factor_list, dup_irreducible_p +from sympy.polys.numberfields.galois_resolvents import ( + GaloisGroupException, get_resolvent_by_lookup, define_resolvents, + Resolvent, +) +from sympy.polys.numberfields.utilities import coeff_search +from sympy.polys.polytools import (Poly, poly_from_expr, + PolificationFailed, ComputationFailed) +from sympy.polys.sqfreetools import dup_sqf_p +from sympy.utilities import public + + +class MaxTriesException(GaloisGroupException): + ... + + +def tschirnhausen_transformation(T, max_coeff=10, max_tries=30, history=None, + fixed_order=True): + r""" + Given a univariate, monic, irreducible polynomial over the integers, find + another such polynomial defining the same number field. + + Explanation + =========== + + See Alg 6.3.4 of [1]. + + Parameters + ========== + + T : Poly + The given polynomial + max_coeff : int + When choosing a transformation as part of the process, + keep the coeffs between plus and minus this. + max_tries : int + Consider at most this many transformations. + history : set, None, optional (default=None) + Pass a set of ``Poly.rep``'s in order to prevent any of these + polynomials from being returned as the polynomial ``U`` i.e. the + transformation of the given polynomial *T*. The given poly *T* will + automatically be added to this set, before we try to find a new one. + fixed_order : bool, default True + If ``True``, work through candidate transformations A(x) in a fixed + order, from small coeffs to large, resulting in deterministic behavior. + If ``False``, the A(x) are chosen randomly, while still working our way + up from small coefficients to larger ones. + + Returns + ======= + + Pair ``(A, U)`` + + ``A`` and ``U`` are ``Poly``, ``A`` is the + transformation, and ``U`` is the transformed polynomial that defines + the same number field as *T*. The polynomial ``A`` maps the roots of + *T* to the roots of ``U``. + + Raises + ====== + + MaxTriesException + if could not find a polynomial before exceeding *max_tries*. + + """ + X = Dummy('X') + n = T.degree() + if history is None: + history = set() + history.add(T.rep) + + if fixed_order: + coeff_generators = {} + deg_coeff_sum = 3 + current_degree = 2 + + def get_coeff_generator(degree): + gen = coeff_generators.get(degree, coeff_search(degree, 1)) + coeff_generators[degree] = gen + return gen + + for i in range(max_tries): + + # We never use linear A(x), since applying a fixed linear transformation + # to all roots will only multiply the discriminant of T by a square + # integer. This will change nothing important. In particular, if disc(T) + # was zero before, it will still be zero now, and typically we apply + # the transformation in hopes of replacing T by a squarefree poly. + + if fixed_order: + # If d is degree and c max coeff, we move through the dc-space + # along lines of constant sum. First d + c = 3 with (d, c) = (2, 1). + # Then d + c = 4 with (d, c) = (3, 1), (2, 2). Then d + c = 5 with + # (d, c) = (4, 1), (3, 2), (2, 3), and so forth. For a given (d, c) + # we go though all sets of coeffs where max = c, before moving on. + gen = get_coeff_generator(current_degree) + coeffs = next(gen) + m = max(abs(c) for c in coeffs) + if current_degree + m > deg_coeff_sum: + if current_degree == 2: + deg_coeff_sum += 1 + current_degree = deg_coeff_sum - 1 + else: + current_degree -= 1 + gen = get_coeff_generator(current_degree) + coeffs = next(gen) + a = [ZZ(1)] + [ZZ(c) for c in coeffs] + + else: + # We use a progressive coeff bound, up to the max specified, since it + # is preferable to succeed with smaller coeffs. + # Give each coeff bound five tries, before incrementing. + C = min(i//5 + 1, max_coeff) + d = random.randint(2, n - 1) + a = dup_random(d, -C, C, ZZ) + + A = Poly(a, T.gen) + U = Poly(T.resultant(X - A), X) + if U.rep not in history and dup_sqf_p(U.rep.to_list(), ZZ): + return A, U + raise MaxTriesException + + +def has_square_disc(T): + """Convenience to check if a Poly or dup has square discriminant. """ + d = T.discriminant() if isinstance(T, Poly) else dup_discriminant(T, ZZ) + return is_square(d) + + +def _galois_group_degree_3(T, max_tries=30, randomize=False): + r""" + Compute the Galois group of a polynomial of degree 3. + + Explanation + =========== + + Uses Prop 6.3.5 of [1]. + + """ + from sympy.combinatorics.galois import S3TransitiveSubgroups + return ((S3TransitiveSubgroups.A3, True) if has_square_disc(T) + else (S3TransitiveSubgroups.S3, False)) + + +def _galois_group_degree_4_root_approx(T, max_tries=30, randomize=False): + r""" + Compute the Galois group of a polynomial of degree 4. + + Explanation + =========== + + Follows Alg 6.3.7 of [1], using a pure root approximation approach. + + """ + from sympy.combinatorics.permutations import Permutation + from sympy.combinatorics.galois import S4TransitiveSubgroups + + X = symbols('X0 X1 X2 X3') + # We start by considering the resolvent for the form + # F = X0*X2 + X1*X3 + # and the group G = S4. In this case, the stabilizer H is D4 = < (0123), (02) >, + # and a set of representatives of G/H is {I, (01), (03)} + F1 = X[0]*X[2] + X[1]*X[3] + s1 = [ + Permutation(3), + Permutation(3)(0, 1), + Permutation(3)(0, 3) + ] + R1 = Resolvent(F1, X, s1) + + # In the second half of the algorithm (if we reach it), we use another + # form and set of coset representatives. However, we may need to permute + # them first, so cannot form their resolvent now. + F2_pre = X[0]*X[1]**2 + X[1]*X[2]**2 + X[2]*X[3]**2 + X[3]*X[0]**2 + s2_pre = [ + Permutation(3), + Permutation(3)(0, 2) + ] + + history = set() + for i in range(max_tries): + if i > 0: + # If we're retrying, need a new polynomial T. + _, T = tschirnhausen_transformation(T, max_tries=max_tries, + history=history, + fixed_order=not randomize) + + R_dup, _, i0 = R1.eval_for_poly(T, find_integer_root=True) + # If R is not squarefree, must retry. + if not dup_sqf_p(R_dup, ZZ): + continue + + # By Prop 6.3.1 of [1], Gal(T) is contained in A4 iff disc(T) is square. + sq_disc = has_square_disc(T) + + if i0 is None: + # By Thm 6.3.3 of [1], Gal(T) is not conjugate to any subgroup of the + # stabilizer H = D4 that we chose. This means Gal(T) is either A4 or S4. + return ((S4TransitiveSubgroups.A4, True) if sq_disc + else (S4TransitiveSubgroups.S4, False)) + + # Gal(T) is conjugate to a subgroup of H = D4, so it is either V, C4 + # or D4 itself. + + if sq_disc: + # Neither C4 nor D4 is contained in A4, so Gal(T) must be V. + return (S4TransitiveSubgroups.V, True) + + # Gal(T) can only be D4 or C4. + # We will now use our second resolvent, with G being that conjugate of D4 that + # Gal(T) is contained in. To determine the right conjugate, we will need + # the permutation corresponding to the integer root we found. + sigma = s1[i0] + # Applying sigma means permuting the args of F, and + # conjugating the set of coset representatives. + F2 = F2_pre.subs(zip(X, sigma(X)), simultaneous=True) + s2 = [sigma*tau*sigma for tau in s2_pre] + R2 = Resolvent(F2, X, s2) + R_dup, _, _ = R2.eval_for_poly(T) + d = dup_discriminant(R_dup, ZZ) + # If d is zero (R has a repeated root), must retry. + if d == 0: + continue + if is_square(d): + return (S4TransitiveSubgroups.C4, False) + else: + return (S4TransitiveSubgroups.D4, False) + + raise MaxTriesException + + +def _galois_group_degree_4_lookup(T, max_tries=30, randomize=False): + r""" + Compute the Galois group of a polynomial of degree 4. + + Explanation + =========== + + Based on Alg 6.3.6 of [1], but uses resolvent coeff lookup. + + """ + from sympy.combinatorics.galois import S4TransitiveSubgroups + + history = set() + for i in range(max_tries): + R_dup = get_resolvent_by_lookup(T, 0) + if dup_sqf_p(R_dup, ZZ): + break + _, T = tschirnhausen_transformation(T, max_tries=max_tries, + history=history, + fixed_order=not randomize) + else: + raise MaxTriesException + + # Compute list L of degrees of irreducible factors of R, in increasing order: + fl = dup_factor_list(R_dup, ZZ) + L = sorted(sum([ + [len(r) - 1] * e for r, e in fl[1] + ], [])) + + if L == [6]: + return ((S4TransitiveSubgroups.A4, True) if has_square_disc(T) + else (S4TransitiveSubgroups.S4, False)) + + if L == [1, 1, 4]: + return (S4TransitiveSubgroups.C4, False) + + if L == [2, 2, 2]: + return (S4TransitiveSubgroups.V, True) + + assert L == [2, 4] + return (S4TransitiveSubgroups.D4, False) + + +def _galois_group_degree_5_hybrid(T, max_tries=30, randomize=False): + r""" + Compute the Galois group of a polynomial of degree 5. + + Explanation + =========== + + Based on Alg 6.3.9 of [1], but uses a hybrid approach, combining resolvent + coeff lookup, with root approximation. + + """ + from sympy.combinatorics.galois import S5TransitiveSubgroups + from sympy.combinatorics.permutations import Permutation + + X5 = symbols("X0,X1,X2,X3,X4") + res = define_resolvents() + F51, _, s51 = res[(5, 1)] + F51 = F51.as_expr(*X5) + R51 = Resolvent(F51, X5, s51) + + history = set() + reached_second_stage = False + for i in range(max_tries): + if i > 0: + _, T = tschirnhausen_transformation(T, max_tries=max_tries, + history=history, + fixed_order=not randomize) + R51_dup = get_resolvent_by_lookup(T, 1) + if not dup_sqf_p(R51_dup, ZZ): + continue + + # First stage + # If we have not yet reached the second stage, then the group still + # might be S5, A5, or M20, so must test for that. + if not reached_second_stage: + sq_disc = has_square_disc(T) + + if dup_irreducible_p(R51_dup, ZZ): + return ((S5TransitiveSubgroups.A5, True) if sq_disc + else (S5TransitiveSubgroups.S5, False)) + + if not sq_disc: + return (S5TransitiveSubgroups.M20, False) + + # Second stage + reached_second_stage = True + # R51 must have an integer root for T. + # To choose our second resolvent, we need to know which conjugate of + # F51 is a root. + rounded_roots = R51.round_roots_to_integers_for_poly(T) + # These are integers, and candidates to be roots of R51. + # We find the first one that actually is a root. + for permutation_index, candidate_root in rounded_roots.items(): + if not dup_eval(R51_dup, candidate_root, ZZ): + break + + X = X5 + F2_pre = X[0]*X[1]**2 + X[1]*X[2]**2 + X[2]*X[3]**2 + X[3]*X[4]**2 + X[4]*X[0]**2 + s2_pre = [ + Permutation(4), + Permutation(4)(0, 1)(2, 4) + ] + + i0 = permutation_index + sigma = s51[i0] + F2 = F2_pre.subs(zip(X, sigma(X)), simultaneous=True) + s2 = [sigma*tau*sigma for tau in s2_pre] + R2 = Resolvent(F2, X, s2) + R_dup, _, _ = R2.eval_for_poly(T) + d = dup_discriminant(R_dup, ZZ) + + if d == 0: + continue + if is_square(d): + return (S5TransitiveSubgroups.C5, True) + else: + return (S5TransitiveSubgroups.D5, True) + + raise MaxTriesException + + +def _galois_group_degree_5_lookup_ext_factor(T, max_tries=30, randomize=False): + r""" + Compute the Galois group of a polynomial of degree 5. + + Explanation + =========== + + Based on Alg 6.3.9 of [1], but uses resolvent coeff lookup, plus + factorization over an algebraic extension. + + """ + from sympy.combinatorics.galois import S5TransitiveSubgroups + + _T = T + + history = set() + for i in range(max_tries): + R_dup = get_resolvent_by_lookup(T, 1) + if dup_sqf_p(R_dup, ZZ): + break + _, T = tschirnhausen_transformation(T, max_tries=max_tries, + history=history, + fixed_order=not randomize) + else: + raise MaxTriesException + + sq_disc = has_square_disc(T) + + if dup_irreducible_p(R_dup, ZZ): + return ((S5TransitiveSubgroups.A5, True) if sq_disc + else (S5TransitiveSubgroups.S5, False)) + + if not sq_disc: + return (S5TransitiveSubgroups.M20, False) + + # If we get this far, Gal(T) can only be D5 or C5. + # But for Gal(T) to have order 5, T must already split completely in + # the extension field obtained by adjoining a single one of its roots. + fl = Poly(_T, domain=ZZ.alg_field_from_poly(_T)).factor_list()[1] + if len(fl) == 5: + return (S5TransitiveSubgroups.C5, True) + else: + return (S5TransitiveSubgroups.D5, True) + + +def _galois_group_degree_6_lookup(T, max_tries=30, randomize=False): + r""" + Compute the Galois group of a polynomial of degree 6. + + Explanation + =========== + + Based on Alg 6.3.10 of [1], but uses resolvent coeff lookup. + + """ + from sympy.combinatorics.galois import S6TransitiveSubgroups + + # First resolvent: + + history = set() + for i in range(max_tries): + R_dup = get_resolvent_by_lookup(T, 1) + if dup_sqf_p(R_dup, ZZ): + break + _, T = tschirnhausen_transformation(T, max_tries=max_tries, + history=history, + fixed_order=not randomize) + else: + raise MaxTriesException + + fl = dup_factor_list(R_dup, ZZ) + + # Group the factors by degree. + factors_by_deg = defaultdict(list) + for r, _ in fl[1]: + factors_by_deg[len(r) - 1].append(r) + + L = sorted(sum([ + [d] * len(ff) for d, ff in factors_by_deg.items() + ], [])) + + T_has_sq_disc = has_square_disc(T) + + if L == [1, 2, 3]: + f1 = factors_by_deg[3][0] + return ((S6TransitiveSubgroups.C6, False) if has_square_disc(f1) + else (S6TransitiveSubgroups.D6, False)) + + elif L == [3, 3]: + f1, f2 = factors_by_deg[3] + any_square = has_square_disc(f1) or has_square_disc(f2) + return ((S6TransitiveSubgroups.G18, False) if any_square + else (S6TransitiveSubgroups.G36m, False)) + + elif L == [2, 4]: + if T_has_sq_disc: + return (S6TransitiveSubgroups.S4p, True) + else: + f1 = factors_by_deg[4][0] + return ((S6TransitiveSubgroups.A4xC2, False) if has_square_disc(f1) + else (S6TransitiveSubgroups.S4xC2, False)) + + elif L == [1, 1, 4]: + return ((S6TransitiveSubgroups.A4, True) if T_has_sq_disc + else (S6TransitiveSubgroups.S4m, False)) + + elif L == [1, 5]: + return ((S6TransitiveSubgroups.PSL2F5, True) if T_has_sq_disc + else (S6TransitiveSubgroups.PGL2F5, False)) + + elif L == [1, 1, 1, 3]: + return (S6TransitiveSubgroups.S3, False) + + assert L == [6] + + # Second resolvent: + + history = set() + for i in range(max_tries): + R_dup = get_resolvent_by_lookup(T, 2) + if dup_sqf_p(R_dup, ZZ): + break + _, T = tschirnhausen_transformation(T, max_tries=max_tries, + history=history, + fixed_order=not randomize) + else: + raise MaxTriesException + + T_has_sq_disc = has_square_disc(T) + + if dup_irreducible_p(R_dup, ZZ): + return ((S6TransitiveSubgroups.A6, True) if T_has_sq_disc + else (S6TransitiveSubgroups.S6, False)) + else: + return ((S6TransitiveSubgroups.G36p, True) if T_has_sq_disc + else (S6TransitiveSubgroups.G72, False)) + + +@public +def galois_group(f, *gens, by_name=False, max_tries=30, randomize=False, **args): + r""" + Compute the Galois group for polynomials *f* up to degree 6. + + Examples + ======== + + >>> from sympy import galois_group + >>> from sympy.abc import x + >>> f = x**4 + 1 + >>> G, alt = galois_group(f) + >>> print(G) + PermutationGroup([ + (0 1)(2 3), + (0 2)(1 3)]) + + The group is returned along with a boolean, indicating whether it is + contained in the alternating group $A_n$, where $n$ is the degree of *T*. + Along with other group properties, this can help determine which group it + is: + + >>> alt + True + >>> G.order() + 4 + + Alternatively, the group can be returned by name: + + >>> G_name, _ = galois_group(f, by_name=True) + >>> print(G_name) + S4TransitiveSubgroups.V + + The group itself can then be obtained by calling the name's + ``get_perm_group()`` method: + + >>> G_name.get_perm_group() + PermutationGroup([ + (0 1)(2 3), + (0 2)(1 3)]) + + Group names are values of the enum classes + :py:class:`sympy.combinatorics.galois.S1TransitiveSubgroups`, + :py:class:`sympy.combinatorics.galois.S2TransitiveSubgroups`, + etc. + + Parameters + ========== + + f : Expr + Irreducible polynomial over :ref:`ZZ` or :ref:`QQ`, whose Galois group + is to be determined. + gens : optional list of symbols + For converting *f* to Poly, and will be passed on to the + :py:func:`~.poly_from_expr` function. + by_name : bool, default False + If ``True``, the Galois group will be returned by name. + Otherwise it will be returned as a :py:class:`~.PermutationGroup`. + max_tries : int, default 30 + Make at most this many attempts in those steps that involve + generating Tschirnhausen transformations. + randomize : bool, default False + If ``True``, then use random coefficients when generating Tschirnhausen + transformations. Otherwise try transformations in a fixed order. Both + approaches start with small coefficients and degrees and work upward. + args : optional + For converting *f* to Poly, and will be passed on to the + :py:func:`~.poly_from_expr` function. + + Returns + ======= + + Pair ``(G, alt)`` + The first element ``G`` indicates the Galois group. It is an instance + of one of the :py:class:`sympy.combinatorics.galois.S1TransitiveSubgroups` + :py:class:`sympy.combinatorics.galois.S2TransitiveSubgroups`, etc. enum + classes if *by_name* was ``True``, and a :py:class:`~.PermutationGroup` + if ``False``. + + The second element is a boolean, saying whether the group is contained + in the alternating group $A_n$ ($n$ the degree of *T*). + + Raises + ====== + + ValueError + if *f* is of an unsupported degree. + + MaxTriesException + if could not complete before exceeding *max_tries* in those steps + that involve generating Tschirnhausen transformations. + + See Also + ======== + + .Poly.galois_group + + """ + gens = gens or [] + args = args or {} + + try: + F, opt = poly_from_expr(f, *gens, **args) + except PolificationFailed as exc: + raise ComputationFailed('galois_group', 1, exc) + + return F.galois_group(by_name=by_name, max_tries=max_tries, + randomize=randomize) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/minpoly.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/minpoly.py new file mode 100644 index 0000000000000000000000000000000000000000..e5f556e6f82a9790aa7c421fc14ac0fb637b7b49 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/minpoly.py @@ -0,0 +1,882 @@ +"""Minimal polynomials for algebraic numbers.""" + +from functools import reduce + +from sympy.core.add import Add +from sympy.core.exprtools import Factors +from sympy.core.function import expand_mul, expand_multinomial, _mexpand +from sympy.core.mul import Mul +from sympy.core.numbers import (I, Rational, pi, _illegal) +from sympy.core.singleton import S +from sympy.core.symbol import Dummy +from sympy.core.sympify import sympify +from sympy.core.traversal import preorder_traversal +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt, cbrt +from sympy.functions.elementary.trigonometric import cos, sin, tan +from sympy.ntheory.factor_ import divisors +from sympy.utilities.iterables import subsets + +from sympy.polys.domains import ZZ, QQ, FractionField +from sympy.polys.orthopolys import dup_chebyshevt +from sympy.polys.polyerrors import ( + NotAlgebraic, + GeneratorsError, +) +from sympy.polys.polytools import ( + Poly, PurePoly, invert, factor_list, groebner, resultant, + degree, poly_from_expr, parallel_poly_from_expr, lcm +) +from sympy.polys.polyutils import dict_from_expr, expr_from_dict +from sympy.polys.ring_series import rs_compose_add +from sympy.polys.rings import ring +from sympy.polys.rootoftools import CRootOf +from sympy.polys.specialpolys import cyclotomic_poly +from sympy.utilities import ( + numbered_symbols, public, sift +) + + +def _choose_factor(factors, x, v, dom=QQ, prec=200, bound=5): + """ + Return a factor having root ``v`` + It is assumed that one of the factors has root ``v``. + """ + + if isinstance(factors[0], tuple): + factors = [f[0] for f in factors] + if len(factors) == 1: + return factors[0] + + prec1 = 10 + points = {} + symbols = dom.symbols if hasattr(dom, 'symbols') else [] + while prec1 <= prec: + # when dealing with non-Rational numbers we usually evaluate + # with `subs` argument but we only need a ballpark evaluation + fe = [f.as_expr().xreplace({x:v}) for f in factors] + if v.is_number: + fe = [f.n(prec) for f in fe] + + # assign integers [0, n) to symbols (if any) + for n in subsets(range(bound), k=len(symbols), repetition=True): + for s, i in zip(symbols, n): + points[s] = i + + # evaluate the expression at these points + candidates = [(abs(f.subs(points).n(prec1)), i) + for i,f in enumerate(fe)] + + # if we get invalid numbers (e.g. from division by zero) + # we try again + if any(i in _illegal for i, _ in candidates): + continue + + # find the smallest two -- if they differ significantly + # then we assume we have found the factor that becomes + # 0 when v is substituted into it + can = sorted(candidates) + (a, ix), (b, _) = can[:2] + if b > a * 10**6: # XXX what to use? + return factors[ix] + + prec1 *= 2 + + raise NotImplementedError("multiple candidates for the minimal polynomial of %s" % v) + + +def _is_sum_surds(p): + return all(f.is_Rational or f.is_Pow and + f.base.is_Rational and (2*f.exp).is_Integer and f.is_extended_real + for t in Add.make_args(p) for f in Mul.make_args(t)) + + +def _separate_sq(p): + """ + helper function for ``_minimal_polynomial_sq`` + + It selects a rational ``g`` such that the polynomial ``p`` + consists of a sum of terms whose surds squared have gcd equal to ``g`` + and a sum of terms with surds squared prime with ``g``; + then it takes the field norm to eliminate ``sqrt(g)`` + + See simplify.simplify.split_surds and polytools.sqf_norm. + + Examples + ======== + + >>> from sympy import sqrt + >>> from sympy.abc import x + >>> from sympy.polys.numberfields.minpoly import _separate_sq + >>> p= -x + sqrt(2) + sqrt(3) + sqrt(7) + >>> p = _separate_sq(p); p + -x**2 + 2*sqrt(3)*x + 2*sqrt(7)*x - 2*sqrt(21) - 8 + >>> p = _separate_sq(p); p + -x**4 + 4*sqrt(7)*x**3 - 32*x**2 + 8*sqrt(7)*x + 20 + >>> p = _separate_sq(p); p + -x**8 + 48*x**6 - 536*x**4 + 1728*x**2 - 400 + + """ + def is_sqrt(expr): + return expr.is_Pow and expr.exp is S.Half + # p = c1*sqrt(q1) + ... + cn*sqrt(qn) -> a = [(c1, q1), .., (cn, qn)] + a = [] + for y in p.args: + if not y.is_Mul: + if is_sqrt(y): + a.append((S.One, y**2)) + elif y.is_Atom: + a.append((y, S.One)) + elif y.is_Pow and y.exp.is_integer: + a.append((y, S.One)) + else: + raise NotImplementedError + else: + T, F = sift(y.args, is_sqrt, binary=True) + a.append((Mul(*F), Mul(*T)**2)) + a.sort(key=lambda z: z[1]) + if a[-1][1] is S.One: + # there are no surds + return p + surds = [z for y, z in a] + for i in range(len(surds)): + if surds[i] != 1: + break + from sympy.simplify.radsimp import _split_gcd + g, b1, b2 = _split_gcd(*surds[i:]) + a1 = [] + a2 = [] + for y, z in a: + if z in b1: + a1.append(y*z**S.Half) + else: + a2.append(y*z**S.Half) + p1 = Add(*a1) + p2 = Add(*a2) + p = _mexpand(p1**2) - _mexpand(p2**2) + return p + +def _minimal_polynomial_sq(p, n, x): + """ + Returns the minimal polynomial for the ``nth-root`` of a sum of surds + or ``None`` if it fails. + + Parameters + ========== + + p : sum of surds + n : positive integer + x : variable of the returned polynomial + + Examples + ======== + + >>> from sympy.polys.numberfields.minpoly import _minimal_polynomial_sq + >>> from sympy import sqrt + >>> from sympy.abc import x + >>> q = 1 + sqrt(2) + sqrt(3) + >>> _minimal_polynomial_sq(q, 3, x) + x**12 - 4*x**9 - 4*x**6 + 16*x**3 - 8 + + """ + p = sympify(p) + n = sympify(n) + if not n.is_Integer or not n > 0 or not _is_sum_surds(p): + return None + pn = p**Rational(1, n) + # eliminate the square roots + p -= x + while 1: + p1 = _separate_sq(p) + if p1 is p: + p = p1.subs({x:x**n}) + break + else: + p = p1 + + # _separate_sq eliminates field extensions in a minimal way, so that + # if n = 1 then `p = constant*(minimal_polynomial(p))` + # if n > 1 it contains the minimal polynomial as a factor. + if n == 1: + p1 = Poly(p) + if p.coeff(x**p1.degree(x)) < 0: + p = -p + p = p.primitive()[1] + return p + # by construction `p` has root `pn` + # the minimal polynomial is the factor vanishing in x = pn + factors = factor_list(p)[1] + + result = _choose_factor(factors, x, pn) + return result + +def _minpoly_op_algebraic_element(op, ex1, ex2, x, dom, mp1=None, mp2=None): + """ + return the minimal polynomial for ``op(ex1, ex2)`` + + Parameters + ========== + + op : operation ``Add`` or ``Mul`` + ex1, ex2 : expressions for the algebraic elements + x : indeterminate of the polynomials + dom: ground domain + mp1, mp2 : minimal polynomials for ``ex1`` and ``ex2`` or None + + Examples + ======== + + >>> from sympy import sqrt, Add, Mul, QQ + >>> from sympy.polys.numberfields.minpoly import _minpoly_op_algebraic_element + >>> from sympy.abc import x, y + >>> p1 = sqrt(sqrt(2) + 1) + >>> p2 = sqrt(sqrt(2) - 1) + >>> _minpoly_op_algebraic_element(Mul, p1, p2, x, QQ) + x - 1 + >>> q1 = sqrt(y) + >>> q2 = 1 / y + >>> _minpoly_op_algebraic_element(Add, q1, q2, x, QQ.frac_field(y)) + x**2*y**2 - 2*x*y - y**3 + 1 + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Resultant + .. [2] I.M. Isaacs, Proc. Amer. Math. Soc. 25 (1970), 638 + "Degrees of sums in a separable field extension". + + """ + y = Dummy(str(x)) + if mp1 is None: + mp1 = _minpoly_compose(ex1, x, dom) + if mp2 is None: + mp2 = _minpoly_compose(ex2, y, dom) + else: + mp2 = mp2.subs({x: y}) + + if op is Add: + # mp1a = mp1.subs({x: x - y}) + if dom == QQ: + R, X = ring('X', QQ) + p1 = R(dict_from_expr(mp1)[0]) + p2 = R(dict_from_expr(mp2)[0]) + else: + (p1, p2), _ = parallel_poly_from_expr((mp1, x - y), x, y) + r = p1.compose(p2) + mp1a = r.as_expr() + + elif op is Mul: + mp1a = _muly(mp1, x, y) + else: + raise NotImplementedError('option not available') + + if op is Mul or dom != QQ: + r = resultant(mp1a, mp2, gens=[y, x]) + else: + r = rs_compose_add(p1, p2) + r = expr_from_dict(r.as_expr_dict(), x) + + deg1 = degree(mp1, x) + deg2 = degree(mp2, y) + if op is Mul and deg1 == 1 or deg2 == 1: + # if deg1 = 1, then mp1 = x - a; mp1a = x - y - a; + # r = mp2(x - a), so that `r` is irreducible + return r + + r = Poly(r, x, domain=dom) + _, factors = r.factor_list() + res = _choose_factor(factors, x, op(ex1, ex2), dom) + return res.as_expr() + + +def _invertx(p, x): + """ + Returns ``expand_mul(x**degree(p, x)*p.subs(x, 1/x))`` + """ + p1 = poly_from_expr(p, x)[0] + + n = degree(p1) + a = [c * x**(n - i) for (i,), c in p1.terms()] + return Add(*a) + + +def _muly(p, x, y): + """ + Returns ``_mexpand(y**deg*p.subs({x:x / y}))`` + """ + p1 = poly_from_expr(p, x)[0] + + n = degree(p1) + a = [c * x**i * y**(n - i) for (i,), c in p1.terms()] + return Add(*a) + + +def _minpoly_pow(ex, pw, x, dom, mp=None): + """ + Returns ``minpoly(ex**pw, x)`` + + Parameters + ========== + + ex : algebraic element + pw : rational number + x : indeterminate of the polynomial + dom: ground domain + mp : minimal polynomial of ``p`` + + Examples + ======== + + >>> from sympy import sqrt, QQ, Rational + >>> from sympy.polys.numberfields.minpoly import _minpoly_pow, minpoly + >>> from sympy.abc import x, y + >>> p = sqrt(1 + sqrt(2)) + >>> _minpoly_pow(p, 2, x, QQ) + x**2 - 2*x - 1 + >>> minpoly(p**2, x) + x**2 - 2*x - 1 + >>> _minpoly_pow(y, Rational(1, 3), x, QQ.frac_field(y)) + x**3 - y + >>> minpoly(y**Rational(1, 3), x) + x**3 - y + + """ + pw = sympify(pw) + if not mp: + mp = _minpoly_compose(ex, x, dom) + if not pw.is_rational: + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + if pw < 0: + if mp == x: + raise ZeroDivisionError('%s is zero' % ex) + mp = _invertx(mp, x) + if pw == -1: + return mp + pw = -pw + ex = 1/ex + + y = Dummy(str(x)) + mp = mp.subs({x: y}) + n, d = pw.as_numer_denom() + res = Poly(resultant(mp, x**d - y**n, gens=[y]), x, domain=dom) + _, factors = res.factor_list() + res = _choose_factor(factors, x, ex**pw, dom) + return res.as_expr() + + +def _minpoly_add(x, dom, *a): + """ + returns ``minpoly(Add(*a), dom, x)`` + """ + mp = _minpoly_op_algebraic_element(Add, a[0], a[1], x, dom) + p = a[0] + a[1] + for px in a[2:]: + mp = _minpoly_op_algebraic_element(Add, p, px, x, dom, mp1=mp) + p = p + px + return mp + + +def _minpoly_mul(x, dom, *a): + """ + returns ``minpoly(Mul(*a), dom, x)`` + """ + mp = _minpoly_op_algebraic_element(Mul, a[0], a[1], x, dom) + p = a[0] * a[1] + for px in a[2:]: + mp = _minpoly_op_algebraic_element(Mul, p, px, x, dom, mp1=mp) + p = p * px + return mp + + +def _minpoly_sin(ex, x): + """ + Returns the minimal polynomial of ``sin(ex)`` + see https://mathworld.wolfram.com/TrigonometryAngles.html + """ + c, a = ex.args[0].as_coeff_Mul() + if a is pi: + if c.is_rational: + n = c.q + q = sympify(n) + if q.is_prime: + # for a = pi*p/q with q odd prime, using chebyshevt + # write sin(q*a) = mp(sin(a))*sin(a); + # the roots of mp(x) are sin(pi*p/q) for p = 1,..., q - 1 + a = dup_chebyshevt(n, ZZ) + return Add(*[x**(n - i - 1)*a[i] for i in range(n)]) + if c.p == 1: + if q == 9: + return 64*x**6 - 96*x**4 + 36*x**2 - 3 + + if n % 2 == 1: + # for a = pi*p/q with q odd, use + # sin(q*a) = 0 to see that the minimal polynomial must be + # a factor of dup_chebyshevt(n, ZZ) + a = dup_chebyshevt(n, ZZ) + a = [x**(n - i)*a[i] for i in range(n + 1)] + r = Add(*a) + _, factors = factor_list(r) + res = _choose_factor(factors, x, ex) + return res + + expr = ((1 - cos(2*c*pi))/2)**S.Half + res = _minpoly_compose(expr, x, QQ) + return res + + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + + +def _minpoly_cos(ex, x): + """ + Returns the minimal polynomial of ``cos(ex)`` + see https://mathworld.wolfram.com/TrigonometryAngles.html + """ + c, a = ex.args[0].as_coeff_Mul() + if a is pi: + if c.is_rational: + if c.p == 1: + if c.q == 7: + return 8*x**3 - 4*x**2 - 4*x + 1 + if c.q == 9: + return 8*x**3 - 6*x - 1 + elif c.p == 2: + q = sympify(c.q) + if q.is_prime: + s = _minpoly_sin(ex, x) + return _mexpand(s.subs({x:sqrt((1 - x)/2)})) + + # for a = pi*p/q, cos(q*a) =T_q(cos(a)) = (-1)**p + n = int(c.q) + a = dup_chebyshevt(n, ZZ) + a = [x**(n - i)*a[i] for i in range(n + 1)] + r = Add(*a) - (-1)**c.p + _, factors = factor_list(r) + res = _choose_factor(factors, x, ex) + return res + + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + + +def _minpoly_tan(ex, x): + """ + Returns the minimal polynomial of ``tan(ex)`` + see https://github.com/sympy/sympy/issues/21430 + """ + c, a = ex.args[0].as_coeff_Mul() + if a is pi: + if c.is_rational: + c = c * 2 + n = int(c.q) + a = n if c.p % 2 == 0 else 1 + terms = [] + for k in range((c.p+1)%2, n+1, 2): + terms.append(a*x**k) + a = -(a*(n-k-1)*(n-k)) // ((k+1)*(k+2)) + + r = Add(*terms) + _, factors = factor_list(r) + res = _choose_factor(factors, x, ex) + return res + + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + + +def _minpoly_exp(ex, x): + """ + Returns the minimal polynomial of ``exp(ex)`` + """ + c, a = ex.args[0].as_coeff_Mul() + if a == I*pi: + if c.is_rational: + q = sympify(c.q) + if c.p == 1 or c.p == -1: + if q == 3: + return x**2 - x + 1 + if q == 4: + return x**4 + 1 + if q == 6: + return x**4 - x**2 + 1 + if q == 8: + return x**8 + 1 + if q == 9: + return x**6 - x**3 + 1 + if q == 10: + return x**8 - x**6 + x**4 - x**2 + 1 + if q.is_prime: + s = 0 + for i in range(q): + s += (-x)**i + return s + + # x**(2*q) = product(factors) + factors = [cyclotomic_poly(i, x) for i in divisors(2*q)] + mp = _choose_factor(factors, x, ex) + return mp + else: + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + + +def _minpoly_rootof(ex, x): + """ + Returns the minimal polynomial of a ``CRootOf`` object. + """ + p = ex.expr + p = p.subs({ex.poly.gens[0]:x}) + _, factors = factor_list(p, x) + result = _choose_factor(factors, x, ex) + return result + + +def _minpoly_compose(ex, x, dom): + """ + Computes the minimal polynomial of an algebraic element + using operations on minimal polynomials + + Examples + ======== + + >>> from sympy import minimal_polynomial, sqrt, Rational + >>> from sympy.abc import x, y + >>> minimal_polynomial(sqrt(2) + 3*Rational(1, 3), x, compose=True) + x**2 - 2*x - 1 + >>> minimal_polynomial(sqrt(y) + 1/y, x, compose=True) + x**2*y**2 - 2*x*y - y**3 + 1 + + """ + if ex.is_Rational: + return ex.q*x - ex.p + if ex is I: + _, factors = factor_list(x**2 + 1, x, domain=dom) + return x**2 + 1 if len(factors) == 1 else x - I + + if ex is S.GoldenRatio: + _, factors = factor_list(x**2 - x - 1, x, domain=dom) + if len(factors) == 1: + return x**2 - x - 1 + else: + return _choose_factor(factors, x, (1 + sqrt(5))/2, dom=dom) + + if ex is S.TribonacciConstant: + _, factors = factor_list(x**3 - x**2 - x - 1, x, domain=dom) + if len(factors) == 1: + return x**3 - x**2 - x - 1 + else: + fac = (1 + cbrt(19 - 3*sqrt(33)) + cbrt(19 + 3*sqrt(33))) / 3 + return _choose_factor(factors, x, fac, dom=dom) + + if hasattr(dom, 'symbols') and ex in dom.symbols: + return x - ex + + if dom.is_QQ and _is_sum_surds(ex): + # eliminate the square roots + v = ex + ex -= x + while 1: + ex1 = _separate_sq(ex) + if ex1 is ex: + return _choose_factor(factor_list(ex)[1], x, v) + else: + ex = ex1 + + if ex.is_Add: + res = _minpoly_add(x, dom, *ex.args) + elif ex.is_Mul: + f = Factors(ex).factors + r = sift(f.items(), lambda itx: itx[0].is_Rational and itx[1].is_Rational) + if r[True] and dom == QQ: + ex1 = Mul(*[bx**ex for bx, ex in r[False] + r[None]]) + r1 = dict(r[True]) + dens = [y.q for y in r1.values()] + lcmdens = reduce(lcm, dens, 1) + neg1 = S.NegativeOne + expn1 = r1.pop(neg1, S.Zero) + nums = [base**(y.p*lcmdens // y.q) for base, y in r1.items()] + ex2 = Mul(*nums) + mp1 = minimal_polynomial(ex1, x) + # use the fact that in SymPy canonicalization products of integers + # raised to rational powers are organized in relatively prime + # bases, and that in ``base**(n/d)`` a perfect power is + # simplified with the root + # Powers of -1 have to be treated separately to preserve sign. + mp2 = ex2.q*x**lcmdens - ex2.p*neg1**(expn1*lcmdens) + ex2 = neg1**expn1 * ex2**Rational(1, lcmdens) + res = _minpoly_op_algebraic_element(Mul, ex1, ex2, x, dom, mp1=mp1, mp2=mp2) + else: + res = _minpoly_mul(x, dom, *ex.args) + elif ex.is_Pow: + res = _minpoly_pow(ex.base, ex.exp, x, dom) + elif ex.__class__ is sin: + res = _minpoly_sin(ex, x) + elif ex.__class__ is cos: + res = _minpoly_cos(ex, x) + elif ex.__class__ is tan: + res = _minpoly_tan(ex, x) + elif ex.__class__ is exp: + res = _minpoly_exp(ex, x) + elif ex.__class__ is CRootOf: + res = _minpoly_rootof(ex, x) + else: + raise NotAlgebraic("%s does not seem to be an algebraic element" % ex) + return res + + +@public +def minimal_polynomial(ex, x=None, compose=True, polys=False, domain=None): + """ + Computes the minimal polynomial of an algebraic element. + + Parameters + ========== + + ex : Expr + Element or expression whose minimal polynomial is to be calculated. + + x : Symbol, optional + Independent variable of the minimal polynomial + + compose : boolean, optional (default=True) + Method to use for computing minimal polynomial. If ``compose=True`` + (default) then ``_minpoly_compose`` is used, if ``compose=False`` then + groebner bases are used. + + polys : boolean, optional (default=False) + If ``True`` returns a ``Poly`` object else an ``Expr`` object. + + domain : Domain, optional + Ground domain + + Notes + ===== + + By default ``compose=True``, the minimal polynomial of the subexpressions of ``ex`` + are computed, then the arithmetic operations on them are performed using the resultant + and factorization. + If ``compose=False``, a bottom-up algorithm is used with ``groebner``. + The default algorithm stalls less frequently. + + If no ground domain is given, it will be generated automatically from the expression. + + Examples + ======== + + >>> from sympy import minimal_polynomial, sqrt, solve, QQ + >>> from sympy.abc import x, y + + >>> minimal_polynomial(sqrt(2), x) + x**2 - 2 + >>> minimal_polynomial(sqrt(2), x, domain=QQ.algebraic_field(sqrt(2))) + x - sqrt(2) + >>> minimal_polynomial(sqrt(2) + sqrt(3), x) + x**4 - 10*x**2 + 1 + >>> minimal_polynomial(solve(x**3 + x + 3)[0], x) + x**3 + x + 3 + >>> minimal_polynomial(sqrt(y), x) + x**2 - y + + """ + + ex = sympify(ex) + if ex.is_number: + # not sure if it's always needed but try it for numbers (issue 8354) + ex = _mexpand(ex, recursive=True) + for expr in preorder_traversal(ex): + if expr.is_AlgebraicNumber: + compose = False + break + + if x is not None: + x, cls = sympify(x), Poly + else: + x, cls = Dummy('x'), PurePoly + + if not domain: + if ex.free_symbols: + domain = FractionField(QQ, list(ex.free_symbols)) + else: + domain = QQ + if hasattr(domain, 'symbols') and x in domain.symbols: + raise GeneratorsError("the variable %s is an element of the ground " + "domain %s" % (x, domain)) + + if compose: + result = _minpoly_compose(ex, x, domain) + result = result.primitive()[1] + c = result.coeff(x**degree(result, x)) + if c.is_negative: + result = expand_mul(-result) + return cls(result, x, field=True) if polys else result.collect(x) + + if not domain.is_QQ: + raise NotImplementedError("groebner method only works for QQ") + + result = _minpoly_groebner(ex, x, cls) + return cls(result, x, field=True) if polys else result.collect(x) + + +def _minpoly_groebner(ex, x, cls): + """ + Computes the minimal polynomial of an algebraic number + using Groebner bases + + Examples + ======== + + >>> from sympy import minimal_polynomial, sqrt, Rational + >>> from sympy.abc import x + >>> minimal_polynomial(sqrt(2) + 3*Rational(1, 3), x, compose=False) + x**2 - 2*x - 1 + + """ + + generator = numbered_symbols('a', cls=Dummy) + mapping, symbols = {}, {} + + def update_mapping(ex, exp, base=None): + a = next(generator) + symbols[ex] = a + + if base is not None: + mapping[ex] = a**exp + base + else: + mapping[ex] = exp.as_expr(a) + + return a + + def bottom_up_scan(ex): + """ + Transform a given algebraic expression *ex* into a multivariate + polynomial, by introducing fresh variables with defining equations. + + Explanation + =========== + + The critical elements of the algebraic expression *ex* are root + extractions, instances of :py:class:`~.AlgebraicNumber`, and negative + powers. + + When we encounter a root extraction or an :py:class:`~.AlgebraicNumber` + we replace this expression with a fresh variable ``a_i``, and record + the defining polynomial for ``a_i``. For example, if ``a_0**(1/3)`` + occurs, we will replace it with ``a_1``, and record the new defining + polynomial ``a_1**3 - a_0``. + + When we encounter a negative power we transform it into a positive + power by algebraically inverting the base. This means computing the + minimal polynomial in ``x`` for the base, inverting ``x`` modulo this + poly (which generates a new polynomial) and then substituting the + original base expression for ``x`` in this last polynomial. + + We return the transformed expression, and we record the defining + equations for new symbols using the ``update_mapping()`` function. + + """ + if ex.is_Atom: + if ex is S.ImaginaryUnit: + if ex not in mapping: + return update_mapping(ex, 2, 1) + else: + return symbols[ex] + elif ex.is_Rational: + return ex + elif ex.is_Add: + return Add(*[ bottom_up_scan(g) for g in ex.args ]) + elif ex.is_Mul: + return Mul(*[ bottom_up_scan(g) for g in ex.args ]) + elif ex.is_Pow: + if ex.exp.is_Rational: + if ex.exp < 0: + minpoly_base = _minpoly_groebner(ex.base, x, cls) + inverse = invert(x, minpoly_base).as_expr() + base_inv = inverse.subs(x, ex.base).expand() + + if ex.exp == -1: + return bottom_up_scan(base_inv) + else: + ex = base_inv**(-ex.exp) + if not ex.exp.is_Integer: + base, exp = ( + ex.base**ex.exp.p).expand(), Rational(1, ex.exp.q) + else: + base, exp = ex.base, ex.exp + base = bottom_up_scan(base) + expr = base**exp + + if expr not in mapping: + if exp.is_Integer: + return expr.expand() + else: + return update_mapping(expr, 1 / exp, -base) + else: + return symbols[expr] + elif ex.is_AlgebraicNumber: + if ex not in mapping: + return update_mapping(ex, ex.minpoly_of_element()) + else: + return symbols[ex] + + raise NotAlgebraic("%s does not seem to be an algebraic number" % ex) + + def simpler_inverse(ex): + """ + Returns True if it is more likely that the minimal polynomial + algorithm works better with the inverse + """ + if ex.is_Pow: + if (1/ex.exp).is_integer and ex.exp < 0: + if ex.base.is_Add: + return True + if ex.is_Mul: + hit = True + for p in ex.args: + if p.is_Add: + return False + if p.is_Pow: + if p.base.is_Add and p.exp > 0: + return False + + if hit: + return True + return False + + inverted = False + ex = expand_multinomial(ex) + if ex.is_AlgebraicNumber: + return ex.minpoly_of_element().as_expr(x) + elif ex.is_Rational: + result = ex.q*x - ex.p + else: + inverted = simpler_inverse(ex) + if inverted: + ex = ex**-1 + res = None + if ex.is_Pow and (1/ex.exp).is_Integer: + n = 1/ex.exp + res = _minimal_polynomial_sq(ex.base, n, x) + + elif _is_sum_surds(ex): + res = _minimal_polynomial_sq(ex, S.One, x) + + if res is not None: + result = res + + if res is None: + bus = bottom_up_scan(ex) + F = [x - bus] + list(mapping.values()) + G = groebner(F, list(symbols.values()) + [x], order='lex') + + _, factors = factor_list(G[-1]) + # by construction G[-1] has root `ex` + result = _choose_factor(factors, x, ex) + if inverted: + result = _invertx(result, x) + if result.coeff(x**degree(result, x)) < 0: + result = expand_mul(-result) + + return result + + +@public +def minpoly(ex, x=None, compose=True, polys=False, domain=None): + """This is a synonym for :py:func:`~.minimal_polynomial`.""" + return minimal_polynomial(ex, x=x, compose=compose, polys=polys, domain=domain) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/modules.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/modules.py new file mode 100644 index 0000000000000000000000000000000000000000..af2e29bcc9cf73d97def0701712f90db58601b86 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/modules.py @@ -0,0 +1,2114 @@ +r"""Modules in number fields. + +The classes defined here allow us to work with finitely generated, free +modules, whose generators are algebraic numbers. + +There is an abstract base class called :py:class:`~.Module`, which has two +concrete subclasses, :py:class:`~.PowerBasis` and :py:class:`~.Submodule`. + +Every module is defined by its basis, or set of generators: + +* For a :py:class:`~.PowerBasis`, the generators are the first $n$ powers + (starting with the zeroth) of an algebraic integer $\theta$ of degree $n$. + The :py:class:`~.PowerBasis` is constructed by passing either the minimal + polynomial of $\theta$, or an :py:class:`~.AlgebraicField` having $\theta$ + as its primitive element. + +* For a :py:class:`~.Submodule`, the generators are a set of + $\mathbb{Q}$-linear combinations of the generators of another module. That + other module is then the "parent" of the :py:class:`~.Submodule`. The + coefficients of the $\mathbb{Q}$-linear combinations may be given by an + integer matrix, and a positive integer denominator. Each column of the matrix + defines a generator. + +>>> from sympy.polys import Poly, cyclotomic_poly, ZZ +>>> from sympy.abc import x +>>> from sympy.polys.matrices import DomainMatrix, DM +>>> from sympy.polys.numberfields.modules import PowerBasis +>>> T = Poly(cyclotomic_poly(5, x)) +>>> A = PowerBasis(T) +>>> print(A) +PowerBasis(x**4 + x**3 + x**2 + x + 1) +>>> B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ), denom=3) +>>> print(B) +Submodule[[2, 0, 0, 0], [0, 2, 0, 0], [0, 0, 2, 0], [0, 0, 0, 2]]/3 +>>> print(B.parent) +PowerBasis(x**4 + x**3 + x**2 + x + 1) + +Thus, every module is either a :py:class:`~.PowerBasis`, +or a :py:class:`~.Submodule`, some ancestor of which is a +:py:class:`~.PowerBasis`. (If ``S`` is a :py:class:`~.Submodule`, then its +ancestors are ``S.parent``, ``S.parent.parent``, and so on). + +The :py:class:`~.ModuleElement` class represents a linear combination of the +generators of any module. Critically, the coefficients of this linear +combination are not restricted to be integers, but may be any rational +numbers. This is necessary so that any and all algebraic integers be +representable, starting from the power basis in a primitive element $\theta$ +for the number field in question. For example, in a quadratic field +$\mathbb{Q}(\sqrt{d})$ where $d \equiv 1 \mod{4}$, a denominator of $2$ is +needed. + +A :py:class:`~.ModuleElement` can be constructed from an integer column vector +and a denominator: + +>>> U = Poly(x**2 - 5) +>>> M = PowerBasis(U) +>>> e = M(DM([[1], [1]], ZZ), denom=2) +>>> print(e) +[1, 1]/2 +>>> print(e.module) +PowerBasis(x**2 - 5) + +The :py:class:`~.PowerBasisElement` class is a subclass of +:py:class:`~.ModuleElement` that represents elements of a +:py:class:`~.PowerBasis`, and adds functionality pertinent to elements +represented directly over powers of the primitive element $\theta$. + + +Arithmetic with module elements +=============================== + +While a :py:class:`~.ModuleElement` represents a linear combination over the +generators of a particular module, recall that every module is either a +:py:class:`~.PowerBasis` or a descendant (along a chain of +:py:class:`~.Submodule` objects) thereof, so that in fact every +:py:class:`~.ModuleElement` represents an algebraic number in some field +$\mathbb{Q}(\theta)$, where $\theta$ is the defining element of some +:py:class:`~.PowerBasis`. It thus makes sense to talk about the number field +to which a given :py:class:`~.ModuleElement` belongs. + +This means that any two :py:class:`~.ModuleElement` instances can be added, +subtracted, multiplied, or divided, provided they belong to the same number +field. Similarly, since $\mathbb{Q}$ is a subfield of every number field, +any :py:class:`~.ModuleElement` may be added, multiplied, etc. by any +rational number. + +>>> from sympy import QQ +>>> from sympy.polys.numberfields.modules import to_col +>>> T = Poly(cyclotomic_poly(5)) +>>> A = PowerBasis(T) +>>> C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) +>>> e = A(to_col([0, 2, 0, 0]), denom=3) +>>> f = A(to_col([0, 0, 0, 7]), denom=5) +>>> g = C(to_col([1, 1, 1, 1])) +>>> e + f +[0, 10, 0, 21]/15 +>>> e - f +[0, 10, 0, -21]/15 +>>> e - g +[-9, -7, -9, -9]/3 +>>> e + QQ(7, 10) +[21, 20, 0, 0]/30 +>>> e * f +[-14, -14, -14, -14]/15 +>>> e ** 2 +[0, 0, 4, 0]/9 +>>> f // g +[7, 7, 7, 7]/15 +>>> f * QQ(2, 3) +[0, 0, 0, 14]/15 + +However, care must be taken with arithmetic operations on +:py:class:`~.ModuleElement`, because the module $C$ to which the result will +belong will be the nearest common ancestor (NCA) of the modules $A$, $B$ to +which the two operands belong, and $C$ may be different from either or both +of $A$ and $B$. + +>>> A = PowerBasis(T) +>>> B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) +>>> C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) +>>> print((B(0) * C(0)).module == A) +True + +Before the arithmetic operation is performed, copies of the two operands are +automatically converted into elements of the NCA (the operands themselves are +not modified). This upward conversion along an ancestor chain is easy: it just +requires the successive multiplication by the defining matrix of each +:py:class:`~.Submodule`. + +Conversely, downward conversion, i.e. representing a given +:py:class:`~.ModuleElement` in a submodule, is also supported -- namely by +the :py:meth:`~sympy.polys.numberfields.modules.Submodule.represent` method +-- but is not guaranteed to succeed in general, since the given element may +not belong to the submodule. The main circumstance in which this issue tends +to arise is with multiplication, since modules, while closed under addition, +need not be closed under multiplication. + + +Multiplication +-------------- + +Generally speaking, a module need not be closed under multiplication, i.e. need +not form a ring. However, many of the modules we work with in the context of +number fields are in fact rings, and our classes do support multiplication. + +Specifically, any :py:class:`~.Module` can attempt to compute its own +multiplication table, but this does not happen unless an attempt is made to +multiply two :py:class:`~.ModuleElement` instances belonging to it. + +>>> A = PowerBasis(T) +>>> print(A._mult_tab is None) +True +>>> a = A(0)*A(1) +>>> print(A._mult_tab is None) +False + +Every :py:class:`~.PowerBasis` is, by its nature, closed under multiplication, +so instances of :py:class:`~.PowerBasis` can always successfully compute their +multiplication table. + +When a :py:class:`~.Submodule` attempts to compute its multiplication table, +it converts each of its own generators into elements of its parent module, +multiplies them there, in every possible pairing, and then tries to +represent the results in itself, i.e. as $\mathbb{Z}$-linear combinations +over its own generators. This will succeed if and only if the submodule is +in fact closed under multiplication. + + +Module Homomorphisms +==================== + +Many important number theoretic algorithms require the calculation of the +kernel of one or more module homomorphisms. Accordingly we have several +lightweight classes, :py:class:`~.ModuleHomomorphism`, +:py:class:`~.ModuleEndomorphism`, :py:class:`~.InnerEndomorphism`, and +:py:class:`~.EndomorphismRing`, which provide the minimal necessary machinery +to support this. + +""" + +from sympy.core.intfunc import igcd, ilcm +from sympy.core.symbol import Dummy +from sympy.polys.polyclasses import ANP +from sympy.polys.polytools import Poly +from sympy.polys.densetools import dup_clear_denoms +from sympy.polys.domains.algebraicfield import AlgebraicField +from sympy.polys.domains.finitefield import FF +from sympy.polys.domains.rationalfield import QQ +from sympy.polys.domains.integerring import ZZ +from sympy.polys.matrices.domainmatrix import DomainMatrix +from sympy.polys.matrices.exceptions import DMBadInputError +from sympy.polys.matrices.normalforms import hermite_normal_form +from sympy.polys.polyerrors import CoercionFailed, UnificationFailed +from sympy.polys.polyutils import IntegerPowerable +from .exceptions import ClosureFailure, MissingUnityError, StructureError +from .utilities import AlgIntPowers, is_rat, get_num_denom + + +def to_col(coeffs): + r"""Transform a list of integer coefficients into a column vector.""" + return DomainMatrix([[ZZ(c) for c in coeffs]], (1, len(coeffs)), ZZ).transpose() + + +class Module: + """ + Generic finitely-generated module. + + This is an abstract base class, and should not be instantiated directly. + The two concrete subclasses are :py:class:`~.PowerBasis` and + :py:class:`~.Submodule`. + + Every :py:class:`~.Submodule` is derived from another module, referenced + by its ``parent`` attribute. If ``S`` is a submodule, then we refer to + ``S.parent``, ``S.parent.parent``, and so on, as the "ancestors" of + ``S``. Thus, every :py:class:`~.Module` is either a + :py:class:`~.PowerBasis` or a :py:class:`~.Submodule`, some ancestor of + which is a :py:class:`~.PowerBasis`. + """ + + @property + def n(self): + """The number of generators of this module.""" + raise NotImplementedError + + def mult_tab(self): + """ + Get the multiplication table for this module (if closed under mult). + + Explanation + =========== + + Computes a dictionary ``M`` of dictionaries of lists, representing the + upper triangular half of the multiplication table. + + In other words, if ``0 <= i <= j < self.n``, then ``M[i][j]`` is the + list ``c`` of coefficients such that + ``g[i] * g[j] == sum(c[k]*g[k], k in range(self.n))``, + where ``g`` is the list of generators of this module. + + If ``j < i`` then ``M[i][j]`` is undefined. + + Examples + ======== + + >>> from sympy.polys import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.modules import PowerBasis + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> print(A.mult_tab()) # doctest: +SKIP + {0: {0: [1, 0, 0, 0], 1: [0, 1, 0, 0], 2: [0, 0, 1, 0], 3: [0, 0, 0, 1]}, + 1: {1: [0, 0, 1, 0], 2: [0, 0, 0, 1], 3: [-1, -1, -1, -1]}, + 2: {2: [-1, -1, -1, -1], 3: [1, 0, 0, 0]}, + 3: {3: [0, 1, 0, 0]}} + + Returns + ======= + + dict of dict of lists + + Raises + ====== + + ClosureFailure + If the module is not closed under multiplication. + + """ + raise NotImplementedError + + @property + def parent(self): + """ + The parent module, if any, for this module. + + Explanation + =========== + + For a :py:class:`~.Submodule` this is its ``parent`` attribute; for a + :py:class:`~.PowerBasis` this is ``None``. + + Returns + ======= + + :py:class:`~.Module`, ``None`` + + See Also + ======== + + Module + + """ + return None + + def represent(self, elt): + r""" + Represent a module element as an integer-linear combination over the + generators of this module. + + Explanation + =========== + + In our system, to "represent" always means to write a + :py:class:`~.ModuleElement` as a :ref:`ZZ`-linear combination over the + generators of the present :py:class:`~.Module`. Furthermore, the + incoming :py:class:`~.ModuleElement` must belong to an ancestor of + the present :py:class:`~.Module` (or to the present + :py:class:`~.Module` itself). + + The most common application is to represent a + :py:class:`~.ModuleElement` in a :py:class:`~.Submodule`. For example, + this is involved in computing multiplication tables. + + On the other hand, representing in a :py:class:`~.PowerBasis` is an + odd case, and one which tends not to arise in practice, except for + example when using a :py:class:`~.ModuleEndomorphism` on a + :py:class:`~.PowerBasis`. + + In such a case, (1) the incoming :py:class:`~.ModuleElement` must + belong to the :py:class:`~.PowerBasis` itself (since the latter has no + proper ancestors) and (2) it is "representable" iff it belongs to + $\mathbb{Z}[\theta]$ (although generally a + :py:class:`~.PowerBasisElement` may represent any element of + $\mathbb{Q}(\theta)$, i.e. any algebraic number). + + Examples + ======== + + >>> from sympy import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.modules import PowerBasis, to_col + >>> from sympy.abc import zeta + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> a = A(to_col([2, 4, 6, 8])) + + The :py:class:`~.ModuleElement` ``a`` has all even coefficients. + If we represent ``a`` in the submodule ``B = 2*A``, the coefficients in + the column vector will be halved: + + >>> B = A.submodule_from_gens([2*A(i) for i in range(4)]) + >>> b = B.represent(a) + >>> print(b.transpose()) # doctest: +SKIP + DomainMatrix([[1, 2, 3, 4]], (1, 4), ZZ) + + However, the element of ``B`` so defined still represents the same + algebraic number: + + >>> print(a.poly(zeta).as_expr()) + 8*zeta**3 + 6*zeta**2 + 4*zeta + 2 + >>> print(B(b).over_power_basis().poly(zeta).as_expr()) + 8*zeta**3 + 6*zeta**2 + 4*zeta + 2 + + Parameters + ========== + + elt : :py:class:`~.ModuleElement` + The module element to be represented. Must belong to some ancestor + module of this module (including this module itself). + + Returns + ======= + + :py:class:`~.DomainMatrix` over :ref:`ZZ` + This will be a column vector, representing the coefficients of a + linear combination of this module's generators, which equals the + given element. + + Raises + ====== + + ClosureFailure + If the given element cannot be represented as a :ref:`ZZ`-linear + combination over this module. + + See Also + ======== + + .Submodule.represent + .PowerBasis.represent + + """ + raise NotImplementedError + + def ancestors(self, include_self=False): + """ + Return the list of ancestor modules of this module, from the + foundational :py:class:`~.PowerBasis` downward, optionally including + ``self``. + + See Also + ======== + + Module + + """ + c = self.parent + a = [] if c is None else c.ancestors(include_self=True) + if include_self: + a.append(self) + return a + + def power_basis_ancestor(self): + """ + Return the :py:class:`~.PowerBasis` that is an ancestor of this module. + + See Also + ======== + + Module + + """ + if isinstance(self, PowerBasis): + return self + c = self.parent + if c is not None: + return c.power_basis_ancestor() + return None + + def nearest_common_ancestor(self, other): + """ + Locate the nearest common ancestor of this module and another. + + Returns + ======= + + :py:class:`~.Module`, ``None`` + + See Also + ======== + + Module + + """ + sA = self.ancestors(include_self=True) + oA = other.ancestors(include_self=True) + nca = None + for sa, oa in zip(sA, oA): + if sa == oa: + nca = sa + else: + break + return nca + + @property + def number_field(self): + r""" + Return the associated :py:class:`~.AlgebraicField`, if any. + + Explanation + =========== + + A :py:class:`~.PowerBasis` can be constructed on a :py:class:`~.Poly` + $f$ or on an :py:class:`~.AlgebraicField` $K$. In the latter case, the + :py:class:`~.PowerBasis` and all its descendant modules will return $K$ + as their ``.number_field`` property, while in the former case they will + all return ``None``. + + Returns + ======= + + :py:class:`~.AlgebraicField`, ``None`` + + """ + return self.power_basis_ancestor().number_field + + def is_compat_col(self, col): + """Say whether *col* is a suitable column vector for this module.""" + return isinstance(col, DomainMatrix) and col.shape == (self.n, 1) and col.domain.is_ZZ + + def __call__(self, spec, denom=1): + r""" + Generate a :py:class:`~.ModuleElement` belonging to this module. + + Examples + ======== + + >>> from sympy.polys import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.modules import PowerBasis, to_col + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> e = A(to_col([1, 2, 3, 4]), denom=3) + >>> print(e) # doctest: +SKIP + [1, 2, 3, 4]/3 + >>> f = A(2) + >>> print(f) # doctest: +SKIP + [0, 0, 1, 0] + + Parameters + ========== + + spec : :py:class:`~.DomainMatrix`, int + Specifies the numerators of the coefficients of the + :py:class:`~.ModuleElement`. Can be either a column vector over + :ref:`ZZ`, whose length must equal the number $n$ of generators of + this module, or else an integer ``j``, $0 \leq j < n$, which is a + shorthand for column $j$ of $I_n$, the $n \times n$ identity + matrix. + denom : int, optional (default=1) + Denominator for the coefficients of the + :py:class:`~.ModuleElement`. + + Returns + ======= + + :py:class:`~.ModuleElement` + The coefficients are the entries of the *spec* vector, divided by + *denom*. + + """ + if isinstance(spec, int) and 0 <= spec < self.n: + spec = DomainMatrix.eye(self.n, ZZ)[:, spec].to_dense() + if not self.is_compat_col(spec): + raise ValueError('Compatible column vector required.') + return make_mod_elt(self, spec, denom=denom) + + def starts_with_unity(self): + """Say whether the module's first generator equals unity.""" + raise NotImplementedError + + def basis_elements(self): + """ + Get list of :py:class:`~.ModuleElement` being the generators of this + module. + """ + return [self(j) for j in range(self.n)] + + def zero(self): + """Return a :py:class:`~.ModuleElement` representing zero.""" + return self(0) * 0 + + def one(self): + """ + Return a :py:class:`~.ModuleElement` representing unity, + and belonging to the first ancestor of this module (including + itself) that starts with unity. + """ + return self.element_from_rational(1) + + def element_from_rational(self, a): + """ + Return a :py:class:`~.ModuleElement` representing a rational number. + + Explanation + =========== + + The returned :py:class:`~.ModuleElement` will belong to the first + module on this module's ancestor chain (including this module + itself) that starts with unity. + + Examples + ======== + + >>> from sympy.polys import Poly, cyclotomic_poly, QQ + >>> from sympy.polys.numberfields.modules import PowerBasis + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> a = A.element_from_rational(QQ(2, 3)) + >>> print(a) # doctest: +SKIP + [2, 0, 0, 0]/3 + + Parameters + ========== + + a : int, :ref:`ZZ`, :ref:`QQ` + + Returns + ======= + + :py:class:`~.ModuleElement` + + """ + raise NotImplementedError + + def submodule_from_gens(self, gens, hnf=True, hnf_modulus=None): + """ + Form the submodule generated by a list of :py:class:`~.ModuleElement` + belonging to this module. + + Examples + ======== + + >>> from sympy.polys import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.modules import PowerBasis + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> gens = [A(0), 2*A(1), 3*A(2), 4*A(3)//5] + >>> B = A.submodule_from_gens(gens) + >>> print(B) # doctest: +SKIP + Submodule[[5, 0, 0, 0], [0, 10, 0, 0], [0, 0, 15, 0], [0, 0, 0, 4]]/5 + + Parameters + ========== + + gens : list of :py:class:`~.ModuleElement` belonging to this module. + hnf : boolean, optional (default=True) + If True, we will reduce the matrix into Hermite Normal Form before + forming the :py:class:`~.Submodule`. + hnf_modulus : int, None, optional (default=None) + Modulus for use in the HNF reduction algorithm. See + :py:func:`~sympy.polys.matrices.normalforms.hermite_normal_form`. + + Returns + ======= + + :py:class:`~.Submodule` + + See Also + ======== + + submodule_from_matrix + + """ + if not all(g.module == self for g in gens): + raise ValueError('Generators must belong to this module.') + n = len(gens) + if n == 0: + raise ValueError('Need at least one generator.') + m = gens[0].n + d = gens[0].denom if n == 1 else ilcm(*[g.denom for g in gens]) + B = DomainMatrix.zeros((m, 0), ZZ).hstack(*[(d // g.denom) * g.col for g in gens]) + if hnf: + B = hermite_normal_form(B, D=hnf_modulus) + return self.submodule_from_matrix(B, denom=d) + + def submodule_from_matrix(self, B, denom=1): + """ + Form the submodule generated by the elements of this module indicated + by the columns of a matrix, with an optional denominator. + + Examples + ======== + + >>> from sympy.polys import Poly, cyclotomic_poly, ZZ + >>> from sympy.polys.matrices import DM + >>> from sympy.polys.numberfields.modules import PowerBasis + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> B = A.submodule_from_matrix(DM([ + ... [0, 10, 0, 0], + ... [0, 0, 7, 0], + ... ], ZZ).transpose(), denom=15) + >>> print(B) # doctest: +SKIP + Submodule[[0, 10, 0, 0], [0, 0, 7, 0]]/15 + + Parameters + ========== + + B : :py:class:`~.DomainMatrix` over :ref:`ZZ` + Each column gives the numerators of the coefficients of one + generator of the submodule. Thus, the number of rows of *B* must + equal the number of generators of the present module. + denom : int, optional (default=1) + Common denominator for all generators of the submodule. + + Returns + ======= + + :py:class:`~.Submodule` + + Raises + ====== + + ValueError + If the given matrix *B* is not over :ref:`ZZ` or its number of rows + does not equal the number of generators of the present module. + + See Also + ======== + + submodule_from_gens + + """ + m, n = B.shape + if not B.domain.is_ZZ: + raise ValueError('Matrix must be over ZZ.') + if not m == self.n: + raise ValueError('Matrix row count must match base module.') + return Submodule(self, B, denom=denom) + + def whole_submodule(self): + """ + Return a submodule equal to this entire module. + + Explanation + =========== + + This is useful when you have a :py:class:`~.PowerBasis` and want to + turn it into a :py:class:`~.Submodule` (in order to use methods + belonging to the latter). + + """ + B = DomainMatrix.eye(self.n, ZZ) + return self.submodule_from_matrix(B) + + def endomorphism_ring(self): + """Form the :py:class:`~.EndomorphismRing` for this module.""" + return EndomorphismRing(self) + + +class PowerBasis(Module): + """The module generated by the powers of an algebraic integer.""" + + def __init__(self, T): + """ + Parameters + ========== + + T : :py:class:`~.Poly`, :py:class:`~.AlgebraicField` + Either (1) the monic, irreducible, univariate polynomial over + :ref:`ZZ`, a root of which is the generator of the power basis, + or (2) an :py:class:`~.AlgebraicField` whose primitive element + is the generator of the power basis. + + """ + K = None + if isinstance(T, AlgebraicField): + K, T = T, T.ext.minpoly_of_element() + # Sometimes incoming Polys are formally over QQ, although all their + # coeffs are integral. We want them to be formally over ZZ. + T = T.set_domain(ZZ) + self.K = K + self.T = T + self._n = T.degree() + self._mult_tab = None + + @property + def number_field(self): + return self.K + + def __repr__(self): + return f'PowerBasis({self.T.as_expr()})' + + def __eq__(self, other): + if isinstance(other, PowerBasis): + return self.T == other.T + return NotImplemented + + @property + def n(self): + return self._n + + def mult_tab(self): + if self._mult_tab is None: + self.compute_mult_tab() + return self._mult_tab + + def compute_mult_tab(self): + theta_pow = AlgIntPowers(self.T) + M = {} + n = self.n + for u in range(n): + M[u] = {} + for v in range(u, n): + M[u][v] = theta_pow[u + v] + self._mult_tab = M + + def represent(self, elt): + r""" + Represent a module element as an integer-linear combination over the + generators of this module. + + See Also + ======== + + .Module.represent + .Submodule.represent + + """ + if elt.module == self and elt.denom == 1: + return elt.column() + else: + raise ClosureFailure('Element not representable in ZZ[theta].') + + def starts_with_unity(self): + return True + + def element_from_rational(self, a): + return self(0) * a + + def element_from_poly(self, f): + """ + Produce an element of this module, representing *f* after reduction mod + our defining minimal polynomial. + + Parameters + ========== + + f : :py:class:`~.Poly` over :ref:`ZZ` in same var as our defining poly. + + Returns + ======= + + :py:class:`~.PowerBasisElement` + + """ + n, k = self.n, f.degree() + if k >= n: + f = f % self.T + if f == 0: + return self.zero() + d, c = dup_clear_denoms(f.rep.to_list(), QQ, convert=True) + c = list(reversed(c)) + ell = len(c) + z = [ZZ(0)] * (n - ell) + col = to_col(c + z) + return self(col, denom=d) + + def _element_from_rep_and_mod(self, rep, mod): + """ + Produce a PowerBasisElement representing a given algebraic number. + + Parameters + ========== + + rep : list of coeffs + Represents the number as polynomial in the primitive element of the + field. + + mod : list of coeffs + Represents the minimal polynomial of the primitive element of the + field. + + Returns + ======= + + :py:class:`~.PowerBasisElement` + + """ + if mod != self.T.rep.to_list(): + raise UnificationFailed('Element does not appear to be in the same field.') + return self.element_from_poly(Poly(rep, self.T.gen)) + + def element_from_ANP(self, a): + """Convert an ANP into a PowerBasisElement. """ + return self._element_from_rep_and_mod(a.to_list(), a.mod_to_list()) + + def element_from_alg_num(self, a): + """Convert an AlgebraicNumber into a PowerBasisElement. """ + return self._element_from_rep_and_mod(a.rep.to_list(), a.minpoly.rep.to_list()) + + +class Submodule(Module, IntegerPowerable): + """A submodule of another module.""" + + def __init__(self, parent, matrix, denom=1, mult_tab=None): + """ + Parameters + ========== + + parent : :py:class:`~.Module` + The module from which this one is derived. + matrix : :py:class:`~.DomainMatrix` over :ref:`ZZ` + The matrix whose columns define this submodule's generators as + linear combinations over the parent's generators. + denom : int, optional (default=1) + Denominator for the coefficients given by the matrix. + mult_tab : dict, ``None``, optional + If already known, the multiplication table for this module may be + supplied. + + """ + self._parent = parent + self._matrix = matrix + self._denom = denom + self._mult_tab = mult_tab + self._n = matrix.shape[1] + self._QQ_matrix = None + self._starts_with_unity = None + self._is_sq_maxrank_HNF = None + + def __repr__(self): + r = 'Submodule' + repr(self.matrix.transpose().to_Matrix().tolist()) + if self.denom > 1: + r += f'/{self.denom}' + return r + + def reduced(self): + """ + Produce a reduced version of this submodule. + + Explanation + =========== + + In the reduced version, it is guaranteed that 1 is the only positive + integer dividing both the submodule's denominator, and every entry in + the submodule's matrix. + + Returns + ======= + + :py:class:`~.Submodule` + + """ + if self.denom == 1: + return self + g = igcd(self.denom, *self.coeffs) + if g == 1: + return self + return type(self)(self.parent, (self.matrix / g).convert_to(ZZ), denom=self.denom // g, mult_tab=self._mult_tab) + + def discard_before(self, r): + """ + Produce a new module by discarding all generators before a given + index *r*. + """ + W = self.matrix[:, r:] + s = self.n - r + M = None + mt = self._mult_tab + if mt is not None: + M = {} + for u in range(s): + M[u] = {} + for v in range(u, s): + M[u][v] = mt[r + u][r + v][r:] + return Submodule(self.parent, W, denom=self.denom, mult_tab=M) + + @property + def n(self): + return self._n + + def mult_tab(self): + if self._mult_tab is None: + self.compute_mult_tab() + return self._mult_tab + + def compute_mult_tab(self): + gens = self.basis_element_pullbacks() + M = {} + n = self.n + for u in range(n): + M[u] = {} + for v in range(u, n): + M[u][v] = self.represent(gens[u] * gens[v]).flat() + self._mult_tab = M + + @property + def parent(self): + return self._parent + + @property + def matrix(self): + return self._matrix + + @property + def coeffs(self): + return self.matrix.flat() + + @property + def denom(self): + return self._denom + + @property + def QQ_matrix(self): + """ + :py:class:`~.DomainMatrix` over :ref:`QQ`, equal to + ``self.matrix / self.denom``, and guaranteed to be dense. + + Explanation + =========== + + Depending on how it is formed, a :py:class:`~.DomainMatrix` may have + an internal representation that is sparse or dense. We guarantee a + dense representation here, so that tests for equivalence of submodules + always come out as expected. + + Examples + ======== + + >>> from sympy.polys import Poly, cyclotomic_poly, ZZ + >>> from sympy.abc import x + >>> from sympy.polys.matrices import DomainMatrix + >>> from sympy.polys.numberfields.modules import PowerBasis + >>> T = Poly(cyclotomic_poly(5, x)) + >>> A = PowerBasis(T) + >>> B = A.submodule_from_matrix(3*DomainMatrix.eye(4, ZZ), denom=6) + >>> C = A.submodule_from_matrix(DomainMatrix.eye(4, ZZ), denom=2) + >>> print(B.QQ_matrix == C.QQ_matrix) + True + + Returns + ======= + + :py:class:`~.DomainMatrix` over :ref:`QQ` + + """ + if self._QQ_matrix is None: + self._QQ_matrix = (self.matrix / self.denom).to_dense() + return self._QQ_matrix + + def starts_with_unity(self): + if self._starts_with_unity is None: + self._starts_with_unity = self(0).equiv(1) + return self._starts_with_unity + + def is_sq_maxrank_HNF(self): + if self._is_sq_maxrank_HNF is None: + self._is_sq_maxrank_HNF = is_sq_maxrank_HNF(self._matrix) + return self._is_sq_maxrank_HNF + + def is_power_basis_submodule(self): + return isinstance(self.parent, PowerBasis) + + def element_from_rational(self, a): + if self.starts_with_unity(): + return self(0) * a + else: + return self.parent.element_from_rational(a) + + def basis_element_pullbacks(self): + """ + Return list of this submodule's basis elements as elements of the + submodule's parent module. + """ + return [e.to_parent() for e in self.basis_elements()] + + def represent(self, elt): + """ + Represent a module element as an integer-linear combination over the + generators of this module. + + See Also + ======== + + .Module.represent + .PowerBasis.represent + + """ + if elt.module == self: + return elt.column() + elif elt.module == self.parent: + try: + # The given element should be a ZZ-linear combination over our + # basis vectors; however, due to the presence of denominators, + # we need to solve over QQ. + A = self.QQ_matrix + b = elt.QQ_col + x = A._solve(b)[0].transpose() + x = x.convert_to(ZZ) + except DMBadInputError: + raise ClosureFailure('Element outside QQ-span of this basis.') + except CoercionFailed: + raise ClosureFailure('Element in QQ-span but not ZZ-span of this basis.') + return x + elif isinstance(self.parent, Submodule): + coeffs_in_parent = self.parent.represent(elt) + parent_element = self.parent(coeffs_in_parent) + return self.represent(parent_element) + else: + raise ClosureFailure('Element outside ancestor chain of this module.') + + def is_compat_submodule(self, other): + return isinstance(other, Submodule) and other.parent == self.parent + + def __eq__(self, other): + if self.is_compat_submodule(other): + return other.QQ_matrix == self.QQ_matrix + return NotImplemented + + def add(self, other, hnf=True, hnf_modulus=None): + """ + Add this :py:class:`~.Submodule` to another. + + Explanation + =========== + + This represents the module generated by the union of the two modules' + sets of generators. + + Parameters + ========== + + other : :py:class:`~.Submodule` + hnf : boolean, optional (default=True) + If ``True``, reduce the matrix of the combined module to its + Hermite Normal Form. + hnf_modulus : :ref:`ZZ`, None, optional + If a positive integer is provided, use this as modulus in the + HNF reduction. See + :py:func:`~sympy.polys.matrices.normalforms.hermite_normal_form`. + + Returns + ======= + + :py:class:`~.Submodule` + + """ + d, e = self.denom, other.denom + m = ilcm(d, e) + a, b = m // d, m // e + B = (a * self.matrix).hstack(b * other.matrix) + if hnf: + B = hermite_normal_form(B, D=hnf_modulus) + return self.parent.submodule_from_matrix(B, denom=m) + + def __add__(self, other): + if self.is_compat_submodule(other): + return self.add(other) + return NotImplemented + + __radd__ = __add__ + + def mul(self, other, hnf=True, hnf_modulus=None): + """ + Multiply this :py:class:`~.Submodule` by a rational number, a + :py:class:`~.ModuleElement`, or another :py:class:`~.Submodule`. + + Explanation + =========== + + To multiply by a rational number or :py:class:`~.ModuleElement` means + to form the submodule whose generators are the products of this + quantity with all the generators of the present submodule. + + To multiply by another :py:class:`~.Submodule` means to form the + submodule whose generators are all the products of one generator from + the one submodule, and one generator from the other. + + Parameters + ========== + + other : int, :ref:`ZZ`, :ref:`QQ`, :py:class:`~.ModuleElement`, :py:class:`~.Submodule` + hnf : boolean, optional (default=True) + If ``True``, reduce the matrix of the product module to its + Hermite Normal Form. + hnf_modulus : :ref:`ZZ`, None, optional + If a positive integer is provided, use this as modulus in the + HNF reduction. See + :py:func:`~sympy.polys.matrices.normalforms.hermite_normal_form`. + + Returns + ======= + + :py:class:`~.Submodule` + + """ + if is_rat(other): + a, b = get_num_denom(other) + if a == b == 1: + return self + else: + return Submodule(self.parent, + self.matrix * a, denom=self.denom * b, + mult_tab=None).reduced() + elif isinstance(other, ModuleElement) and other.module == self.parent: + # The submodule is multiplied by an element of the parent module. + # We presume this means we want a new submodule of the parent module. + gens = [other * e for e in self.basis_element_pullbacks()] + return self.parent.submodule_from_gens(gens, hnf=hnf, hnf_modulus=hnf_modulus) + elif self.is_compat_submodule(other): + # This case usually means you're multiplying ideals, and want another + # ideal, i.e. another submodule of the same parent module. + alphas, betas = self.basis_element_pullbacks(), other.basis_element_pullbacks() + gens = [a * b for a in alphas for b in betas] + return self.parent.submodule_from_gens(gens, hnf=hnf, hnf_modulus=hnf_modulus) + return NotImplemented + + def __mul__(self, other): + return self.mul(other) + + __rmul__ = __mul__ + + def _first_power(self): + return self + + def reduce_element(self, elt): + r""" + If this submodule $B$ has defining matrix $W$ in square, maximal-rank + Hermite normal form, then, given an element $x$ of the parent module + $A$, we produce an element $y \in A$ such that $x - y \in B$, and the + $i$th coordinate of $y$ satisfies $0 \leq y_i < w_{i,i}$. This + representative $y$ is unique, in the sense that every element of + the coset $x + B$ reduces to it under this procedure. + + Explanation + =========== + + In the special case where $A$ is a power basis for a number field $K$, + and $B$ is a submodule representing an ideal $I$, this operation + represents one of a few important ways of reducing an element of $K$ + modulo $I$ to obtain a "small" representative. See [Cohen00]_ Section + 1.4.3. + + Examples + ======== + + >>> from sympy import QQ, Poly, symbols + >>> t = symbols('t') + >>> k = QQ.alg_field_from_poly(Poly(t**3 + t**2 - 2*t + 8)) + >>> Zk = k.maximal_order() + >>> A = Zk.parent + >>> B = (A(2) - 3*A(0))*Zk + >>> B.reduce_element(A(2)) + [3, 0, 0] + + Parameters + ========== + + elt : :py:class:`~.ModuleElement` + An element of this submodule's parent module. + + Returns + ======= + + elt : :py:class:`~.ModuleElement` + An element of this submodule's parent module. + + Raises + ====== + + NotImplementedError + If the given :py:class:`~.ModuleElement` does not belong to this + submodule's parent module. + StructureError + If this submodule's defining matrix is not in square, maximal-rank + Hermite normal form. + + References + ========== + + .. [Cohen00] Cohen, H. *Advanced Topics in Computational Number + Theory.* + + """ + if not elt.module == self.parent: + raise NotImplementedError + if not self.is_sq_maxrank_HNF(): + msg = "Reduction not implemented unless matrix square max-rank HNF" + raise StructureError(msg) + B = self.basis_element_pullbacks() + a = elt + for i in range(self.n - 1, -1, -1): + b = B[i] + q = a.coeffs[i]*b.denom // (b.coeffs[i]*a.denom) + a -= q*b + return a + + +def is_sq_maxrank_HNF(dm): + r""" + Say whether a :py:class:`~.DomainMatrix` is in that special case of Hermite + Normal Form, in which the matrix is also square and of maximal rank. + + Explanation + =========== + + We commonly work with :py:class:`~.Submodule` instances whose matrix is in + this form, and it can be useful to be able to check that this condition is + satisfied. + + For example this is the case with the :py:class:`~.Submodule` ``ZK`` + returned by :py:func:`~sympy.polys.numberfields.basis.round_two`, which + represents the maximal order in a number field, and with ideals formed + therefrom, such as ``2 * ZK``. + + """ + if dm.domain.is_ZZ and dm.is_square and dm.is_upper: + n = dm.shape[0] + for i in range(n): + d = dm[i, i].element + if d <= 0: + return False + for j in range(i + 1, n): + if not (0 <= dm[i, j].element < d): + return False + return True + return False + + +def make_mod_elt(module, col, denom=1): + r""" + Factory function which builds a :py:class:`~.ModuleElement`, but ensures + that it is a :py:class:`~.PowerBasisElement` if the module is a + :py:class:`~.PowerBasis`. + """ + if isinstance(module, PowerBasis): + return PowerBasisElement(module, col, denom=denom) + else: + return ModuleElement(module, col, denom=denom) + + +class ModuleElement(IntegerPowerable): + r""" + Represents an element of a :py:class:`~.Module`. + + NOTE: Should not be constructed directly. Use the + :py:meth:`~.Module.__call__` method or the :py:func:`make_mod_elt()` + factory function instead. + """ + + def __init__(self, module, col, denom=1): + """ + Parameters + ========== + + module : :py:class:`~.Module` + The module to which this element belongs. + col : :py:class:`~.DomainMatrix` over :ref:`ZZ` + Column vector giving the numerators of the coefficients of this + element. + denom : int, optional (default=1) + Denominator for the coefficients of this element. + + """ + self.module = module + self.col = col + self.denom = denom + self._QQ_col = None + + def __repr__(self): + r = str([int(c) for c in self.col.flat()]) + if self.denom > 1: + r += f'/{self.denom}' + return r + + def reduced(self): + """ + Produce a reduced version of this ModuleElement, i.e. one in which the + gcd of the denominator together with all numerator coefficients is 1. + """ + if self.denom == 1: + return self + g = igcd(self.denom, *self.coeffs) + if g == 1: + return self + return type(self)(self.module, + (self.col / g).convert_to(ZZ), + denom=self.denom // g) + + def reduced_mod_p(self, p): + """ + Produce a version of this :py:class:`~.ModuleElement` in which all + numerator coefficients have been reduced mod *p*. + """ + return make_mod_elt(self.module, + self.col.convert_to(FF(p)).convert_to(ZZ), + denom=self.denom) + + @classmethod + def from_int_list(cls, module, coeffs, denom=1): + """ + Make a :py:class:`~.ModuleElement` from a list of ints (instead of a + column vector). + """ + col = to_col(coeffs) + return cls(module, col, denom=denom) + + @property + def n(self): + """The length of this element's column.""" + return self.module.n + + def __len__(self): + return self.n + + def column(self, domain=None): + """ + Get a copy of this element's column, optionally converting to a domain. + """ + if domain is None: + return self.col.copy() + else: + return self.col.convert_to(domain) + + @property + def coeffs(self): + return self.col.flat() + + @property + def QQ_col(self): + """ + :py:class:`~.DomainMatrix` over :ref:`QQ`, equal to + ``self.col / self.denom``, and guaranteed to be dense. + + See Also + ======== + + .Submodule.QQ_matrix + + """ + if self._QQ_col is None: + self._QQ_col = (self.col / self.denom).to_dense() + return self._QQ_col + + def to_parent(self): + """ + Transform into a :py:class:`~.ModuleElement` belonging to the parent of + this element's module. + """ + if not isinstance(self.module, Submodule): + raise ValueError('Not an element of a Submodule.') + return make_mod_elt( + self.module.parent, self.module.matrix * self.col, + denom=self.module.denom * self.denom) + + def to_ancestor(self, anc): + """ + Transform into a :py:class:`~.ModuleElement` belonging to a given + ancestor of this element's module. + + Parameters + ========== + + anc : :py:class:`~.Module` + + """ + if anc == self.module: + return self + else: + return self.to_parent().to_ancestor(anc) + + def over_power_basis(self): + """ + Transform into a :py:class:`~.PowerBasisElement` over our + :py:class:`~.PowerBasis` ancestor. + """ + e = self + while not isinstance(e.module, PowerBasis): + e = e.to_parent() + return e + + def is_compat(self, other): + """ + Test whether other is another :py:class:`~.ModuleElement` with same + module. + """ + return isinstance(other, ModuleElement) and other.module == self.module + + def unify(self, other): + """ + Try to make a compatible pair of :py:class:`~.ModuleElement`, one + equivalent to this one, and one equivalent to the other. + + Explanation + =========== + + We search for the nearest common ancestor module for the pair of + elements, and represent each one there. + + Returns + ======= + + Pair ``(e1, e2)`` + Each ``ei`` is a :py:class:`~.ModuleElement`, they belong to the + same :py:class:`~.Module`, ``e1`` is equivalent to ``self``, and + ``e2`` is equivalent to ``other``. + + Raises + ====== + + UnificationFailed + If ``self`` and ``other`` have no common ancestor module. + + """ + if self.module == other.module: + return self, other + nca = self.module.nearest_common_ancestor(other.module) + if nca is not None: + return self.to_ancestor(nca), other.to_ancestor(nca) + raise UnificationFailed(f"Cannot unify {self} with {other}") + + def __eq__(self, other): + if self.is_compat(other): + return self.QQ_col == other.QQ_col + return NotImplemented + + def equiv(self, other): + """ + A :py:class:`~.ModuleElement` may test as equivalent to a rational + number or another :py:class:`~.ModuleElement`, if they represent the + same algebraic number. + + Explanation + =========== + + This method is intended to check equivalence only in those cases in + which it is easy to test; namely, when *other* is either a + :py:class:`~.ModuleElement` that can be unified with this one (i.e. one + which shares a common :py:class:`~.PowerBasis` ancestor), or else a + rational number (which is easy because every :py:class:`~.PowerBasis` + represents every rational number). + + Parameters + ========== + + other : int, :ref:`ZZ`, :ref:`QQ`, :py:class:`~.ModuleElement` + + Returns + ======= + + bool + + Raises + ====== + + UnificationFailed + If ``self`` and ``other`` do not share a common + :py:class:`~.PowerBasis` ancestor. + + """ + if self == other: + return True + elif isinstance(other, ModuleElement): + a, b = self.unify(other) + return a == b + elif is_rat(other): + if isinstance(self, PowerBasisElement): + return self == self.module(0) * other + else: + return self.over_power_basis().equiv(other) + return False + + def __add__(self, other): + """ + A :py:class:`~.ModuleElement` can be added to a rational number, or to + another :py:class:`~.ModuleElement`. + + Explanation + =========== + + When the other summand is a rational number, it will be converted into + a :py:class:`~.ModuleElement` (belonging to the first ancestor of this + module that starts with unity). + + In all cases, the sum belongs to the nearest common ancestor (NCA) of + the modules of the two summands. If the NCA does not exist, we return + ``NotImplemented``. + """ + if self.is_compat(other): + d, e = self.denom, other.denom + m = ilcm(d, e) + u, v = m // d, m // e + col = to_col([u * a + v * b for a, b in zip(self.coeffs, other.coeffs)]) + return type(self)(self.module, col, denom=m).reduced() + elif isinstance(other, ModuleElement): + try: + a, b = self.unify(other) + except UnificationFailed: + return NotImplemented + return a + b + elif is_rat(other): + return self + self.module.element_from_rational(other) + return NotImplemented + + __radd__ = __add__ + + def __neg__(self): + return self * -1 + + def __sub__(self, other): + return self + (-other) + + def __rsub__(self, other): + return -self + other + + def __mul__(self, other): + """ + A :py:class:`~.ModuleElement` can be multiplied by a rational number, + or by another :py:class:`~.ModuleElement`. + + Explanation + =========== + + When the multiplier is a rational number, the product is computed by + operating directly on the coefficients of this + :py:class:`~.ModuleElement`. + + When the multiplier is another :py:class:`~.ModuleElement`, the product + will belong to the nearest common ancestor (NCA) of the modules of the + two operands, and that NCA must have a multiplication table. If the NCA + does not exist, we return ``NotImplemented``. If the NCA does not have + a mult. table, ``ClosureFailure`` will be raised. + """ + if self.is_compat(other): + M = self.module.mult_tab() + A, B = self.col.flat(), other.col.flat() + n = self.n + C = [0] * n + for u in range(n): + for v in range(u, n): + c = A[u] * B[v] + if v > u: + c += A[v] * B[u] + if c != 0: + R = M[u][v] + for k in range(n): + C[k] += c * R[k] + d = self.denom * other.denom + return self.from_int_list(self.module, C, denom=d) + elif isinstance(other, ModuleElement): + try: + a, b = self.unify(other) + except UnificationFailed: + return NotImplemented + return a * b + elif is_rat(other): + a, b = get_num_denom(other) + if a == b == 1: + return self + else: + return make_mod_elt(self.module, + self.col * a, denom=self.denom * b).reduced() + return NotImplemented + + __rmul__ = __mul__ + + def _zeroth_power(self): + return self.module.one() + + def _first_power(self): + return self + + def __floordiv__(self, a): + if is_rat(a): + a = QQ(a) + return self * (1/a) + elif isinstance(a, ModuleElement): + return self * (1//a) + return NotImplemented + + def __rfloordiv__(self, a): + return a // self.over_power_basis() + + def __mod__(self, m): + r""" + Reduce this :py:class:`~.ModuleElement` mod a :py:class:`~.Submodule`. + + Parameters + ========== + + m : int, :ref:`ZZ`, :ref:`QQ`, :py:class:`~.Submodule` + If a :py:class:`~.Submodule`, reduce ``self`` relative to this. + If an integer or rational, reduce relative to the + :py:class:`~.Submodule` that is our own module times this constant. + + See Also + ======== + + .Submodule.reduce_element + + """ + if is_rat(m): + m = m * self.module.whole_submodule() + if isinstance(m, Submodule) and m.parent == self.module: + return m.reduce_element(self) + return NotImplemented + + +class PowerBasisElement(ModuleElement): + r""" + Subclass for :py:class:`~.ModuleElement` instances whose module is a + :py:class:`~.PowerBasis`. + """ + + @property + def T(self): + """Access the defining polynomial of the :py:class:`~.PowerBasis`.""" + return self.module.T + + def numerator(self, x=None): + """Obtain the numerator as a polynomial over :ref:`ZZ`.""" + x = x or self.T.gen + return Poly(reversed(self.coeffs), x, domain=ZZ) + + def poly(self, x=None): + """Obtain the number as a polynomial over :ref:`QQ`.""" + return self.numerator(x=x) // self.denom + + @property + def is_rational(self): + """Say whether this element represents a rational number.""" + return self.col[1:, :].is_zero_matrix + + @property + def generator(self): + """ + Return a :py:class:`~.Symbol` to be used when expressing this element + as a polynomial. + + If we have an associated :py:class:`~.AlgebraicField` whose primitive + element has an alias symbol, we use that. Otherwise we use the variable + of the minimal polynomial defining the power basis to which we belong. + """ + K = self.module.number_field + return K.ext.alias if K and K.ext.is_aliased else self.T.gen + + def as_expr(self, x=None): + """Create a Basic expression from ``self``. """ + return self.poly(x or self.generator).as_expr() + + def norm(self, T=None): + """Compute the norm of this number.""" + T = T or self.T + x = T.gen + A = self.numerator(x=x) + return T.resultant(A) // self.denom ** self.n + + def inverse(self): + f = self.poly() + f_inv = f.invert(self.T) + return self.module.element_from_poly(f_inv) + + def __rfloordiv__(self, a): + return self.inverse() * a + + def _negative_power(self, e, modulo=None): + return self.inverse() ** abs(e) + + def to_ANP(self): + """Convert to an equivalent :py:class:`~.ANP`. """ + return ANP(list(reversed(self.QQ_col.flat())), QQ.map(self.T.rep.to_list()), QQ) + + def to_alg_num(self): + """ + Try to convert to an equivalent :py:class:`~.AlgebraicNumber`. + + Explanation + =========== + + In general, the conversion from an :py:class:`~.AlgebraicNumber` to a + :py:class:`~.PowerBasisElement` throws away information, because an + :py:class:`~.AlgebraicNumber` specifies a complex embedding, while a + :py:class:`~.PowerBasisElement` does not. However, in some cases it is + possible to convert a :py:class:`~.PowerBasisElement` back into an + :py:class:`~.AlgebraicNumber`, namely when the associated + :py:class:`~.PowerBasis` has a reference to an + :py:class:`~.AlgebraicField`. + + Returns + ======= + + :py:class:`~.AlgebraicNumber` + + Raises + ====== + + StructureError + If the :py:class:`~.PowerBasis` to which this element belongs does + not have an associated :py:class:`~.AlgebraicField`. + + """ + K = self.module.number_field + if K: + return K.to_alg_num(self.to_ANP()) + raise StructureError("No associated AlgebraicField") + + +class ModuleHomomorphism: + r"""A homomorphism from one module to another.""" + + def __init__(self, domain, codomain, mapping): + r""" + Parameters + ========== + + domain : :py:class:`~.Module` + The domain of the mapping. + + codomain : :py:class:`~.Module` + The codomain of the mapping. + + mapping : callable + An arbitrary callable is accepted, but should be chosen so as + to represent an actual module homomorphism. In particular, should + accept elements of *domain* and return elements of *codomain*. + + Examples + ======== + + >>> from sympy import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.modules import PowerBasis, ModuleHomomorphism + >>> T = Poly(cyclotomic_poly(5)) + >>> A = PowerBasis(T) + >>> B = A.submodule_from_gens([2*A(j) for j in range(4)]) + >>> phi = ModuleHomomorphism(A, B, lambda x: 6*x) + >>> print(phi.matrix()) # doctest: +SKIP + DomainMatrix([[3, 0, 0, 0], [0, 3, 0, 0], [0, 0, 3, 0], [0, 0, 0, 3]], (4, 4), ZZ) + + """ + self.domain = domain + self.codomain = codomain + self.mapping = mapping + + def matrix(self, modulus=None): + r""" + Compute the matrix of this homomorphism. + + Parameters + ========== + + modulus : int, optional + A positive prime number $p$ if the matrix should be reduced mod + $p$. + + Returns + ======= + + :py:class:`~.DomainMatrix` + The matrix is over :ref:`ZZ`, or else over :ref:`GF(p)` if a + modulus was given. + + """ + basis = self.domain.basis_elements() + cols = [self.codomain.represent(self.mapping(elt)) for elt in basis] + if not cols: + return DomainMatrix.zeros((self.codomain.n, 0), ZZ).to_dense() + M = cols[0].hstack(*cols[1:]) + if modulus: + M = M.convert_to(FF(modulus)) + return M + + def kernel(self, modulus=None): + r""" + Compute a Submodule representing the kernel of this homomorphism. + + Parameters + ========== + + modulus : int, optional + A positive prime number $p$ if the kernel should be computed mod + $p$. + + Returns + ======= + + :py:class:`~.Submodule` + This submodule's generators span the kernel of this + homomorphism over :ref:`ZZ`, or else over :ref:`GF(p)` if a + modulus was given. + + """ + M = self.matrix(modulus=modulus) + if modulus is None: + M = M.convert_to(QQ) + # Note: Even when working over a finite field, what we want here is + # the pullback into the integers, so in this case the conversion to ZZ + # below is appropriate. When working over ZZ, the kernel should be a + # ZZ-submodule, so, while the conversion to QQ above was required in + # order for the nullspace calculation to work, conversion back to ZZ + # afterward should always work. + # TODO: + # Watch , which calls + # for fraction-free algorithms. If this is implemented, we can skip + # the conversion to `QQ` above. + K = M.nullspace().convert_to(ZZ).transpose() + return self.domain.submodule_from_matrix(K) + + +class ModuleEndomorphism(ModuleHomomorphism): + r"""A homomorphism from one module to itself.""" + + def __init__(self, domain, mapping): + r""" + Parameters + ========== + + domain : :py:class:`~.Module` + The common domain and codomain of the mapping. + + mapping : callable + An arbitrary callable is accepted, but should be chosen so as + to represent an actual module endomorphism. In particular, should + accept and return elements of *domain*. + + """ + super().__init__(domain, domain, mapping) + + +class InnerEndomorphism(ModuleEndomorphism): + r""" + An inner endomorphism on a module, i.e. the endomorphism corresponding to + multiplication by a fixed element. + """ + + def __init__(self, domain, multiplier): + r""" + Parameters + ========== + + domain : :py:class:`~.Module` + The domain and codomain of the endomorphism. + + multiplier : :py:class:`~.ModuleElement` + The element $a$ defining the mapping as $x \mapsto a x$. + + """ + super().__init__(domain, lambda x: multiplier * x) + self.multiplier = multiplier + + +class EndomorphismRing: + r"""The ring of endomorphisms on a module.""" + + def __init__(self, domain): + """ + Parameters + ========== + + domain : :py:class:`~.Module` + The domain and codomain of the endomorphisms. + + """ + self.domain = domain + + def inner_endomorphism(self, multiplier): + r""" + Form an inner endomorphism belonging to this endomorphism ring. + + Parameters + ========== + + multiplier : :py:class:`~.ModuleElement` + Element $a$ defining the inner endomorphism $x \mapsto a x$. + + Returns + ======= + + :py:class:`~.InnerEndomorphism` + + """ + return InnerEndomorphism(self.domain, multiplier) + + def represent(self, element): + r""" + Represent an element of this endomorphism ring, as a single column + vector. + + Explanation + =========== + + Let $M$ be a module, and $E$ its ring of endomorphisms. Let $N$ be + another module, and consider a homomorphism $\varphi: N \rightarrow E$. + In the event that $\varphi$ is to be represented by a matrix $A$, each + column of $A$ must represent an element of $E$. This is possible when + the elements of $E$ are themselves representable as matrices, by + stacking the columns of such a matrix into a single column. + + This method supports calculating such matrices $A$, by representing + an element of this endomorphism ring first as a matrix, and then + stacking that matrix's columns into a single column. + + Examples + ======== + + Note that in these examples we print matrix transposes, to make their + columns easier to inspect. + + >>> from sympy import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.modules import PowerBasis + >>> from sympy.polys.numberfields.modules import ModuleHomomorphism + >>> T = Poly(cyclotomic_poly(5)) + >>> M = PowerBasis(T) + >>> E = M.endomorphism_ring() + + Let $\zeta$ be a primitive 5th root of unity, a generator of our field, + and consider the inner endomorphism $\tau$ on the ring of integers, + induced by $\zeta$: + + >>> zeta = M(1) + >>> tau = E.inner_endomorphism(zeta) + >>> tau.matrix().transpose() # doctest: +SKIP + DomainMatrix( + [[0, 1, 0, 0], [0, 0, 1, 0], [0, 0, 0, 1], [-1, -1, -1, -1]], + (4, 4), ZZ) + + The matrix representation of $\tau$ is as expected. The first column + shows that multiplying by $\zeta$ carries $1$ to $\zeta$, the second + column that it carries $\zeta$ to $\zeta^2$, and so forth. + + The ``represent`` method of the endomorphism ring ``E`` stacks these + into a single column: + + >>> E.represent(tau).transpose() # doctest: +SKIP + DomainMatrix( + [[0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, -1, -1, -1, -1]], + (1, 16), ZZ) + + This is useful when we want to consider a homomorphism $\varphi$ having + ``E`` as codomain: + + >>> phi = ModuleHomomorphism(M, E, lambda x: E.inner_endomorphism(x)) + + and we want to compute the matrix of such a homomorphism: + + >>> phi.matrix().transpose() # doctest: +SKIP + DomainMatrix( + [[1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1], + [0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, -1, -1, -1, -1], + [0, 0, 1, 0, 0, 0, 0, 1, -1, -1, -1, -1, 1, 0, 0, 0], + [0, 0, 0, 1, -1, -1, -1, -1, 1, 0, 0, 0, 0, 1, 0, 0]], + (4, 16), ZZ) + + Note that the stacked matrix of $\tau$ occurs as the second column in + this example. This is because $\zeta$ is the second basis element of + ``M``, and $\varphi(\zeta) = \tau$. + + Parameters + ========== + + element : :py:class:`~.ModuleEndomorphism` belonging to this ring. + + Returns + ======= + + :py:class:`~.DomainMatrix` + Column vector equalling the vertical stacking of all the columns + of the matrix that represents the given *element* as a mapping. + + """ + if isinstance(element, ModuleEndomorphism) and element.domain == self.domain: + M = element.matrix() + # Transform the matrix into a single column, which should reproduce + # the original columns, one after another. + m, n = M.shape + if n == 0: + return M + return M[:, 0].vstack(*[M[:, j] for j in range(1, n)]) + raise NotImplementedError + + +def find_min_poly(alpha, domain, x=None, powers=None): + r""" + Find a polynomial of least degree (not necessarily irreducible) satisfied + by an element of a finitely-generated ring with unity. + + Examples + ======== + + For the $n$th cyclotomic field, $n$ an odd prime, consider the quadratic + equation whose roots are the two periods of length $(n-1)/2$. Article 356 + of Gauss tells us that we should get $x^2 + x - (n-1)/4$ or + $x^2 + x + (n+1)/4$ according to whether $n$ is 1 or 3 mod 4, respectively. + + >>> from sympy import Poly, cyclotomic_poly, primitive_root, QQ + >>> from sympy.abc import x + >>> from sympy.polys.numberfields.modules import PowerBasis, find_min_poly + >>> n = 13 + >>> g = primitive_root(n) + >>> C = PowerBasis(Poly(cyclotomic_poly(n, x))) + >>> ee = [g**(2*k+1) % n for k in range((n-1)//2)] + >>> eta = sum(C(e) for e in ee) + >>> print(find_min_poly(eta, QQ, x=x).as_expr()) + x**2 + x - 3 + >>> n = 19 + >>> g = primitive_root(n) + >>> C = PowerBasis(Poly(cyclotomic_poly(n, x))) + >>> ee = [g**(2*k+2) % n for k in range((n-1)//2)] + >>> eta = sum(C(e) for e in ee) + >>> print(find_min_poly(eta, QQ, x=x).as_expr()) + x**2 + x + 5 + + Parameters + ========== + + alpha : :py:class:`~.ModuleElement` + The element whose min poly is to be found, and whose module has + multiplication and starts with unity. + + domain : :py:class:`~.Domain` + The desired domain of the polynomial. + + x : :py:class:`~.Symbol`, optional + The desired variable for the polynomial. + + powers : list, optional + If desired, pass an empty list. The powers of *alpha* (as + :py:class:`~.ModuleElement` instances) from the zeroth up to the degree + of the min poly will be recorded here, as we compute them. + + Returns + ======= + + :py:class:`~.Poly`, ``None`` + The minimal polynomial for alpha, or ``None`` if no polynomial could be + found over the desired domain. + + Raises + ====== + + MissingUnityError + If the module to which alpha belongs does not start with unity. + ClosureFailure + If the module to which alpha belongs is not closed under + multiplication. + + """ + R = alpha.module + if not R.starts_with_unity(): + raise MissingUnityError("alpha must belong to finitely generated ring with unity.") + if powers is None: + powers = [] + one = R(0) + powers.append(one) + powers_matrix = one.column(domain=domain) + ak = alpha + m = None + for k in range(1, R.n + 1): + powers.append(ak) + ak_col = ak.column(domain=domain) + try: + X = powers_matrix._solve(ak_col)[0] + except DMBadInputError: + # This means alpha^k still isn't in the domain-span of the lower powers. + powers_matrix = powers_matrix.hstack(ak_col) + ak *= alpha + else: + # alpha^k is in the domain-span of the lower powers, so we have found a + # minimal-degree poly for alpha. + coeffs = [1] + [-c for c in reversed(X.to_list_flat())] + x = x or Dummy('x') + if domain.is_FF: + m = Poly(coeffs, x, modulus=domain.mod) + else: + m = Poly(coeffs, x, domain=domain) + break + return m diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/primes.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/primes.py new file mode 100644 index 0000000000000000000000000000000000000000..8f28f13d94f33ed59cded8eabd05e9cf7d0f103f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/primes.py @@ -0,0 +1,784 @@ +"""Prime ideals in number fields. """ + +from sympy.polys.polytools import Poly +from sympy.polys.domains.finitefield import FF +from sympy.polys.domains.rationalfield import QQ +from sympy.polys.domains.integerring import ZZ +from sympy.polys.matrices.domainmatrix import DomainMatrix +from sympy.polys.polyerrors import CoercionFailed +from sympy.polys.polyutils import IntegerPowerable +from sympy.utilities.decorator import public +from .basis import round_two, nilradical_mod_p +from .exceptions import StructureError +from .modules import ModuleEndomorphism, find_min_poly +from .utilities import coeff_search, supplement_a_subspace + + +def _check_formal_conditions_for_maximal_order(submodule): + r""" + Several functions in this module accept an argument which is to be a + :py:class:`~.Submodule` representing the maximal order in a number field, + such as returned by the :py:func:`~sympy.polys.numberfields.basis.round_two` + algorithm. + + We do not attempt to check that the given ``Submodule`` actually represents + a maximal order, but we do check a basic set of formal conditions that the + ``Submodule`` must satisfy, at a minimum. The purpose is to catch an + obviously ill-formed argument. + """ + prefix = 'The submodule representing the maximal order should ' + cond = None + if not submodule.is_power_basis_submodule(): + cond = 'be a direct submodule of a power basis.' + elif not submodule.starts_with_unity(): + cond = 'have 1 as its first generator.' + elif not submodule.is_sq_maxrank_HNF(): + cond = 'have square matrix, of maximal rank, in Hermite Normal Form.' + if cond is not None: + raise StructureError(prefix + cond) + + +class PrimeIdeal(IntegerPowerable): + r""" + A prime ideal in a ring of algebraic integers. + """ + + def __init__(self, ZK, p, alpha, f, e=None): + """ + Parameters + ========== + + ZK : :py:class:`~.Submodule` + The maximal order where this ideal lives. + p : int + The rational prime this ideal divides. + alpha : :py:class:`~.PowerBasisElement` + Such that the ideal is equal to ``p*ZK + alpha*ZK``. + f : int + The inertia degree. + e : int, ``None``, optional + The ramification index, if already known. If ``None``, we will + compute it here. + + """ + _check_formal_conditions_for_maximal_order(ZK) + self.ZK = ZK + self.p = p + self.alpha = alpha + self.f = f + self._test_factor = None + self.e = e if e is not None else self.valuation(p * ZK) + + def __str__(self): + if self.is_inert: + return f'({self.p})' + return f'({self.p}, {self.alpha.as_expr()})' + + @property + def is_inert(self): + """ + Say whether the rational prime we divide is inert, i.e. stays prime in + our ring of integers. + """ + return self.f == self.ZK.n + + def repr(self, field_gen=None, just_gens=False): + """ + Print a representation of this prime ideal. + + Examples + ======== + + >>> from sympy import cyclotomic_poly, QQ + >>> from sympy.abc import x, zeta + >>> T = cyclotomic_poly(7, x) + >>> K = QQ.algebraic_field((T, zeta)) + >>> P = K.primes_above(11) + >>> print(P[0].repr()) + [ (11, x**3 + 5*x**2 + 4*x - 1) e=1, f=3 ] + >>> print(P[0].repr(field_gen=zeta)) + [ (11, zeta**3 + 5*zeta**2 + 4*zeta - 1) e=1, f=3 ] + >>> print(P[0].repr(field_gen=zeta, just_gens=True)) + (11, zeta**3 + 5*zeta**2 + 4*zeta - 1) + + Parameters + ========== + + field_gen : :py:class:`~.Symbol`, ``None``, optional (default=None) + The symbol to use for the generator of the field. This will appear + in our representation of ``self.alpha``. If ``None``, we use the + variable of the defining polynomial of ``self.ZK``. + just_gens : bool, optional (default=False) + If ``True``, just print the "(p, alpha)" part, showing "just the + generators" of the prime ideal. Otherwise, print a string of the + form "[ (p, alpha) e=..., f=... ]", giving the ramification index + and inertia degree, along with the generators. + + """ + field_gen = field_gen or self.ZK.parent.T.gen + p, alpha, e, f = self.p, self.alpha, self.e, self.f + alpha_rep = str(alpha.numerator(x=field_gen).as_expr()) + if alpha.denom > 1: + alpha_rep = f'({alpha_rep})/{alpha.denom}' + gens = f'({p}, {alpha_rep})' + if just_gens: + return gens + return f'[ {gens} e={e}, f={f} ]' + + def __repr__(self): + return self.repr() + + def as_submodule(self): + r""" + Represent this prime ideal as a :py:class:`~.Submodule`. + + Explanation + =========== + + The :py:class:`~.PrimeIdeal` class serves to bundle information about + a prime ideal, such as its inertia degree, ramification index, and + two-generator representation, as well as to offer helpful methods like + :py:meth:`~.PrimeIdeal.valuation` and + :py:meth:`~.PrimeIdeal.test_factor`. + + However, in order to be added and multiplied by other ideals or + rational numbers, it must first be converted into a + :py:class:`~.Submodule`, which is a class that supports these + operations. + + In many cases, the user need not perform this conversion deliberately, + since it is automatically performed by the arithmetic operator methods + :py:meth:`~.PrimeIdeal.__add__` and :py:meth:`~.PrimeIdeal.__mul__`. + + Raising a :py:class:`~.PrimeIdeal` to a non-negative integer power is + also supported. + + Examples + ======== + + >>> from sympy import Poly, cyclotomic_poly, prime_decomp + >>> T = Poly(cyclotomic_poly(7)) + >>> P0 = prime_decomp(7, T)[0] + >>> print(P0**6 == 7*P0.ZK) + True + + Note that, on both sides of the equation above, we had a + :py:class:`~.Submodule`. In the next equation we recall that adding + ideals yields their GCD. This time, we need a deliberate conversion + to :py:class:`~.Submodule` on the right: + + >>> print(P0 + 7*P0.ZK == P0.as_submodule()) + True + + Returns + ======= + + :py:class:`~.Submodule` + Will be equal to ``self.p * self.ZK + self.alpha * self.ZK``. + + See Also + ======== + + __add__ + __mul__ + + """ + M = self.p * self.ZK + self.alpha * self.ZK + # Pre-set expensive boolean properties whose value we already know: + M._starts_with_unity = False + M._is_sq_maxrank_HNF = True + return M + + def __eq__(self, other): + if isinstance(other, PrimeIdeal): + return self.as_submodule() == other.as_submodule() + return NotImplemented + + def __add__(self, other): + """ + Convert to a :py:class:`~.Submodule` and add to another + :py:class:`~.Submodule`. + + See Also + ======== + + as_submodule + + """ + return self.as_submodule() + other + + __radd__ = __add__ + + def __mul__(self, other): + """ + Convert to a :py:class:`~.Submodule` and multiply by another + :py:class:`~.Submodule` or a rational number. + + See Also + ======== + + as_submodule + + """ + return self.as_submodule() * other + + __rmul__ = __mul__ + + def _zeroth_power(self): + return self.ZK + + def _first_power(self): + return self + + def test_factor(self): + r""" + Compute a test factor for this prime ideal. + + Explanation + =========== + + Write $\mathfrak{p}$ for this prime ideal, $p$ for the rational prime + it divides. Then, for computing $\mathfrak{p}$-adic valuations it is + useful to have a number $\beta \in \mathbb{Z}_K$ such that + $p/\mathfrak{p} = p \mathbb{Z}_K + \beta \mathbb{Z}_K$. + + Essentially, this is the same as the number $\Psi$ (or the "reagent") + from Kummer's 1847 paper (*Ueber die Zerlegung...*, Crelle vol. 35) in + which ideal divisors were invented. + """ + if self._test_factor is None: + self._test_factor = _compute_test_factor(self.p, [self.alpha], self.ZK) + return self._test_factor + + def valuation(self, I): + r""" + Compute the $\mathfrak{p}$-adic valuation of integral ideal I at this + prime ideal. + + Parameters + ========== + + I : :py:class:`~.Submodule` + + See Also + ======== + + prime_valuation + + """ + return prime_valuation(I, self) + + def reduce_element(self, elt): + """ + Reduce a :py:class:`~.PowerBasisElement` to a "small representative" + modulo this prime ideal. + + Parameters + ========== + + elt : :py:class:`~.PowerBasisElement` + The element to be reduced. + + Returns + ======= + + :py:class:`~.PowerBasisElement` + The reduced element. + + See Also + ======== + + reduce_ANP + reduce_alg_num + .Submodule.reduce_element + + """ + return self.as_submodule().reduce_element(elt) + + def reduce_ANP(self, a): + """ + Reduce an :py:class:`~.ANP` to a "small representative" modulo this + prime ideal. + + Parameters + ========== + + elt : :py:class:`~.ANP` + The element to be reduced. + + Returns + ======= + + :py:class:`~.ANP` + The reduced element. + + See Also + ======== + + reduce_element + reduce_alg_num + .Submodule.reduce_element + + """ + elt = self.ZK.parent.element_from_ANP(a) + red = self.reduce_element(elt) + return red.to_ANP() + + def reduce_alg_num(self, a): + """ + Reduce an :py:class:`~.AlgebraicNumber` to a "small representative" + modulo this prime ideal. + + Parameters + ========== + + elt : :py:class:`~.AlgebraicNumber` + The element to be reduced. + + Returns + ======= + + :py:class:`~.AlgebraicNumber` + The reduced element. + + See Also + ======== + + reduce_element + reduce_ANP + .Submodule.reduce_element + + """ + elt = self.ZK.parent.element_from_alg_num(a) + red = self.reduce_element(elt) + return a.field_element(list(reversed(red.QQ_col.flat()))) + + +def _compute_test_factor(p, gens, ZK): + r""" + Compute the test factor for a :py:class:`~.PrimeIdeal` $\mathfrak{p}$. + + Parameters + ========== + + p : int + The rational prime $\mathfrak{p}$ divides + + gens : list of :py:class:`PowerBasisElement` + A complete set of generators for $\mathfrak{p}$ over *ZK*, EXCEPT that + an element equivalent to rational *p* can and should be omitted (since + it has no effect except to waste time). + + ZK : :py:class:`~.Submodule` + The maximal order where the prime ideal $\mathfrak{p}$ lives. + + Returns + ======= + + :py:class:`~.PowerBasisElement` + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory.* + (See Proposition 4.8.15.) + + """ + _check_formal_conditions_for_maximal_order(ZK) + E = ZK.endomorphism_ring() + matrices = [E.inner_endomorphism(g).matrix(modulus=p) for g in gens] + B = DomainMatrix.zeros((0, ZK.n), FF(p)).vstack(*matrices) + # A nonzero element of the nullspace of B will represent a + # lin comb over the omegas which (i) is not a multiple of p + # (since it is nonzero over FF(p)), while (ii) is such that + # its product with each g in gens _is_ a multiple of p (since + # B represents multiplication by these generators). Theory + # predicts that such an element must exist, so nullspace should + # be non-trivial. + x = B.nullspace()[0, :].transpose() + beta = ZK.parent(ZK.matrix * x.convert_to(ZZ), denom=ZK.denom) + return beta + + +@public +def prime_valuation(I, P): + r""" + Compute the *P*-adic valuation for an integral ideal *I*. + + Examples + ======== + + >>> from sympy import QQ + >>> from sympy.polys.numberfields import prime_valuation + >>> K = QQ.cyclotomic_field(5) + >>> P = K.primes_above(5) + >>> ZK = K.maximal_order() + >>> print(prime_valuation(25*ZK, P[0])) + 8 + + Parameters + ========== + + I : :py:class:`~.Submodule` + An integral ideal whose valuation is desired. + + P : :py:class:`~.PrimeIdeal` + The prime at which to compute the valuation. + + Returns + ======= + + int + + See Also + ======== + + .PrimeIdeal.valuation + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory.* + (See Algorithm 4.8.17.) + + """ + p, ZK = P.p, P.ZK + n, W, d = ZK.n, ZK.matrix, ZK.denom + + A = W.convert_to(QQ).inv() * I.matrix * d / I.denom + # Although A must have integer entries, given that I is an integral ideal, + # as a DomainMatrix it will still be over QQ, so we convert back: + A = A.convert_to(ZZ) + D = A.det() + if D % p != 0: + return 0 + + beta = P.test_factor() + + f = d ** n // W.det() + need_complete_test = (f % p == 0) + v = 0 + while True: + # Entering the loop, the cols of A represent lin combs of omegas. + # Turn them into lin combs of thetas: + A = W * A + # And then one column at a time... + for j in range(n): + c = ZK.parent(A[:, j], denom=d) + c *= beta + # ...turn back into lin combs of omegas, after multiplying by beta: + c = ZK.represent(c).flat() + for i in range(n): + A[i, j] = c[i] + if A[n - 1, n - 1].element % p != 0: + break + A = A / p + # As noted above, domain converts to QQ even when division goes evenly. + # So must convert back, even when we don't "need_complete_test". + if need_complete_test: + # In this case, having a non-integer entry is actually just our + # halting condition. + try: + A = A.convert_to(ZZ) + except CoercionFailed: + break + else: + # In this case theory says we should not have any non-integer entries. + A = A.convert_to(ZZ) + v += 1 + return v + + +def _two_elt_rep(gens, ZK, p, f=None, Np=None): + r""" + Given a set of *ZK*-generators of a prime ideal, compute a set of just two + *ZK*-generators for the same ideal, one of which is *p* itself. + + Parameters + ========== + + gens : list of :py:class:`PowerBasisElement` + Generators for the prime ideal over *ZK*, the ring of integers of the + field $K$. + + ZK : :py:class:`~.Submodule` + The maximal order in $K$. + + p : int + The rational prime divided by the prime ideal. + + f : int, optional + The inertia degree of the prime ideal, if known. + + Np : int, optional + The norm $p^f$ of the prime ideal, if known. + NOTE: There is no reason to supply both *f* and *Np*. Either one will + save us from having to compute the norm *Np* ourselves. If both are known, + *Np* is preferred since it saves one exponentiation. + + Returns + ======= + + :py:class:`~.PowerBasisElement` representing a single algebraic integer + alpha such that the prime ideal is equal to ``p*ZK + alpha*ZK``. + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory.* + (See Algorithm 4.7.10.) + + """ + _check_formal_conditions_for_maximal_order(ZK) + pb = ZK.parent + T = pb.T + # Detect the special cases in which either (a) all generators are multiples + # of p, or (b) there are no generators (so `all` is vacuously true): + if all((g % p).equiv(0) for g in gens): + return pb.zero() + + if Np is None: + if f is not None: + Np = p**f + else: + Np = abs(pb.submodule_from_gens(gens).matrix.det()) + + omega = ZK.basis_element_pullbacks() + beta = [p*om for om in omega[1:]] # note: we omit omega[0] == 1 + beta += gens + search = coeff_search(len(beta), 1) + for c in search: + alpha = sum(ci*betai for ci, betai in zip(c, beta)) + # Note: It may be tempting to reduce alpha mod p here, to try to work + # with smaller numbers, but must not do that, as it can result in an + # infinite loop! E.g. try factoring 2 in Q(sqrt(-7)). + n = alpha.norm(T) // Np + if n % p != 0: + # Now can reduce alpha mod p. + return alpha % p + + +def _prime_decomp_easy_case(p, ZK): + r""" + Compute the decomposition of rational prime *p* in the ring of integers + *ZK* (given as a :py:class:`~.Submodule`), in the "easy case", i.e. the + case where *p* does not divide the index of $\theta$ in *ZK*, where + $\theta$ is the generator of the ``PowerBasis`` of which *ZK* is a + ``Submodule``. + """ + T = ZK.parent.T + T_bar = Poly(T, modulus=p) + lc, fl = T_bar.factor_list() + if len(fl) == 1 and fl[0][1] == 1: + return [PrimeIdeal(ZK, p, ZK.parent.zero(), ZK.n, 1)] + return [PrimeIdeal(ZK, p, + ZK.parent.element_from_poly(Poly(t, domain=ZZ)), + t.degree(), e) + for t, e in fl] + + +def _prime_decomp_compute_kernel(I, p, ZK): + r""" + Parameters + ========== + + I : :py:class:`~.Module` + An ideal of ``ZK/pZK``. + p : int + The rational prime being factored. + ZK : :py:class:`~.Submodule` + The maximal order. + + Returns + ======= + + Pair ``(N, G)``, where: + + ``N`` is a :py:class:`~.Module` representing the kernel of the map + ``a |--> a**p - a`` on ``(O/pO)/I``, guaranteed to be a module with + unity. + + ``G`` is a :py:class:`~.Module` representing a basis for the separable + algebra ``A = O/I`` (see Cohen). + + """ + W = I.matrix + n, r = W.shape + # Want to take the Fp-basis given by the columns of I, adjoin (1, 0, ..., 0) + # (which we know is not already in there since I is a basis for a prime ideal) + # and then supplement this with additional columns to make an invertible n x n + # matrix. This will then represent a full basis for ZK, whose first r columns + # are pullbacks of the basis for I. + if r == 0: + B = W.eye(n, ZZ) + else: + B = W.hstack(W.eye(n, ZZ)[:, 0]) + if B.shape[1] < n: + B = supplement_a_subspace(B.convert_to(FF(p))).convert_to(ZZ) + + G = ZK.submodule_from_matrix(B) + # Must compute G's multiplication table _before_ discarding the first r + # columns. (See Step 9 in Alg 6.2.9 in Cohen, where the betas are actually + # needed in order to represent each product of gammas. However, once we've + # found the representations, then we can ignore the betas.) + G.compute_mult_tab() + G = G.discard_before(r) + + phi = ModuleEndomorphism(G, lambda x: x**p - x) + N = phi.kernel(modulus=p) + assert N.starts_with_unity() + return N, G + + +def _prime_decomp_maximal_ideal(I, p, ZK): + r""" + We have reached the case where we have a maximal (hence prime) ideal *I*, + which we know because the quotient ``O/I`` is a field. + + Parameters + ========== + + I : :py:class:`~.Module` + An ideal of ``O/pO``. + p : int + The rational prime being factored. + ZK : :py:class:`~.Submodule` + The maximal order. + + Returns + ======= + + :py:class:`~.PrimeIdeal` instance representing this prime + + """ + m, n = I.matrix.shape + f = m - n + G = ZK.matrix * I.matrix + gens = [ZK.parent(G[:, j], denom=ZK.denom) for j in range(G.shape[1])] + alpha = _two_elt_rep(gens, ZK, p, f=f) + return PrimeIdeal(ZK, p, alpha, f) + + +def _prime_decomp_split_ideal(I, p, N, G, ZK): + r""" + Perform the step in the prime decomposition algorithm where we have determined + the quotient ``ZK/I`` is _not_ a field, and we want to perform a non-trivial + factorization of *I* by locating an idempotent element of ``ZK/I``. + """ + assert I.parent == ZK and G.parent is ZK and N.parent is G + # Since ZK/I is not a field, the kernel computed in the previous step contains + # more than just the prime field Fp, and our basis N for the nullspace therefore + # contains at least a second column (which represents an element outside Fp). + # Let alpha be such an element: + alpha = N(1).to_parent() + assert alpha.module is G + + alpha_powers = [] + m = find_min_poly(alpha, FF(p), powers=alpha_powers) + # TODO (future work): + # We don't actually need full factorization, so might use a faster method + # to just break off a single non-constant factor m1? + lc, fl = m.factor_list() + m1 = fl[0][0] + m2 = m.quo(m1) + U, V, g = m1.gcdex(m2) + # Sanity check: theory says m is squarefree, so m1, m2 should be coprime: + assert g == 1 + E = list(reversed(Poly(U * m1, domain=ZZ).rep.to_list())) + eps1 = sum(E[i]*alpha_powers[i] for i in range(len(E))) + eps2 = 1 - eps1 + idemps = [eps1, eps2] + factors = [] + for eps in idemps: + e = eps.to_parent() + assert e.module is ZK + D = I.matrix.convert_to(FF(p)).hstack(*[ + (e * om).column(domain=FF(p)) for om in ZK.basis_elements() + ]) + W = D.columnspace().convert_to(ZZ) + H = ZK.submodule_from_matrix(W) + factors.append(H) + return factors + + +@public +def prime_decomp(p, T=None, ZK=None, dK=None, radical=None): + r""" + Compute the decomposition of rational prime *p* in a number field. + + Explanation + =========== + + Ordinarily this should be accessed through the + :py:meth:`~.AlgebraicField.primes_above` method of an + :py:class:`~.AlgebraicField`. + + Examples + ======== + + >>> from sympy import Poly, QQ + >>> from sympy.abc import x, theta + >>> T = Poly(x ** 3 + x ** 2 - 2 * x + 8) + >>> K = QQ.algebraic_field((T, theta)) + >>> print(K.primes_above(2)) + [[ (2, x**2 + 1) e=1, f=1 ], [ (2, (x**2 + 3*x + 2)/2) e=1, f=1 ], + [ (2, (3*x**2 + 3*x)/2) e=1, f=1 ]] + + Parameters + ========== + + p : int + The rational prime whose decomposition is desired. + + T : :py:class:`~.Poly`, optional + Monic irreducible polynomial defining the number field $K$ in which to + factor. NOTE: at least one of *T* or *ZK* must be provided. + + ZK : :py:class:`~.Submodule`, optional + The maximal order for $K$, if already known. + NOTE: at least one of *T* or *ZK* must be provided. + + dK : int, optional + The discriminant of the field $K$, if already known. + + radical : :py:class:`~.Submodule`, optional + The nilradical mod *p* in the integers of $K$, if already known. + + Returns + ======= + + List of :py:class:`~.PrimeIdeal` instances. + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory.* + (See Algorithm 6.2.9.) + + """ + if T is None and ZK is None: + raise ValueError('At least one of T or ZK must be provided.') + if ZK is not None: + _check_formal_conditions_for_maximal_order(ZK) + if T is None: + T = ZK.parent.T + radicals = {} + if dK is None or ZK is None: + ZK, dK = round_two(T, radicals=radicals) + dT = T.discriminant() + f_squared = dT // dK + if f_squared % p != 0: + return _prime_decomp_easy_case(p, ZK) + radical = radical or radicals.get(p) or nilradical_mod_p(ZK, p) + stack = [radical] + primes = [] + while stack: + I = stack.pop() + N, G = _prime_decomp_compute_kernel(I, p, ZK) + if N.n == 1: + P = _prime_decomp_maximal_ideal(I, p, ZK) + primes.append(P) + else: + I1, I2 = _prime_decomp_split_ideal(I, p, N, G, ZK) + stack.extend([I1, I2]) + return primes diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/resolvent_lookup.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/resolvent_lookup.py new file mode 100644 index 0000000000000000000000000000000000000000..71812c0d7aec6501039eefe4f3602b1916628071 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/resolvent_lookup.py @@ -0,0 +1,456 @@ +"""Lookup table for Galois resolvents for polys of degree 4 through 6. """ +# This table was generated by a call to +# `sympy.polys.numberfields.galois_resolvents.generate_lambda_lookup()`. +# The entire job took 543.23s. +# Of this, Case (6, 1) took 539.03s. +# The final polynomial of Case (6, 1) alone took 455.09s. +resolvent_coeff_lambdas = { + (4, 0): [ + lambda s1, s2, s3, s4: (-2*s1*s2 + 6*s3), + lambda s1, s2, s3, s4: (2*s1**3*s3 + s1**2*s2**2 + s1**2*s4 - 17*s1*s2*s3 + 2*s2**3 - 8*s2*s4 + 24*s3**2), + lambda s1, s2, s3, s4: (-2*s1**5*s4 - 2*s1**4*s2*s3 + 10*s1**3*s2*s4 + 8*s1**3*s3**2 + 10*s1**2*s2**2*s3 - +12*s1**2*s3*s4 - 2*s1*s2**4 - 54*s1*s2*s3**2 + 32*s1*s4**2 + 8*s2**3*s3 - 32*s2*s3*s4 ++ 56*s3**3), + lambda s1, s2, s3, s4: (2*s1**6*s2*s4 + s1**6*s3**2 - 5*s1**5*s3*s4 - 11*s1**4*s2**2*s4 - 13*s1**4*s2*s3**2 ++ 7*s1**4*s4**2 + 3*s1**3*s2**3*s3 + 30*s1**3*s2*s3*s4 + 22*s1**3*s3**3 + 10*s1**2*s2**3*s4 ++ 33*s1**2*s2**2*s3**2 - 72*s1**2*s2*s4**2 - 36*s1**2*s3**2*s4 - 13*s1*s2**4*s3 + +48*s1*s2**2*s3*s4 - 116*s1*s2*s3**3 + 144*s1*s3*s4**2 + s2**6 - 12*s2**4*s4 + 22*s2**3*s3**2 ++ 48*s2**2*s4**2 - 120*s2*s3**2*s4 + 96*s3**4 - 64*s4**3), + lambda s1, s2, s3, s4: (-2*s1**8*s3*s4 - s1**7*s4**2 + 22*s1**6*s2*s3*s4 + 2*s1**6*s3**3 - 2*s1**5*s2**3*s4 +- s1**5*s2**2*s3**2 - 29*s1**5*s3**2*s4 - 60*s1**4*s2**2*s3*s4 - 19*s1**4*s2*s3**3 ++ 38*s1**4*s3*s4**2 + 9*s1**3*s2**4*s4 + 10*s1**3*s2**3*s3**2 + 24*s1**3*s2**2*s4**2 ++ 134*s1**3*s2*s3**2*s4 + 28*s1**3*s3**4 + 16*s1**3*s4**3 - s1**2*s2**5*s3 - 4*s1**2*s2**3*s3*s4 ++ 34*s1**2*s2**2*s3**3 - 288*s1**2*s2*s3*s4**2 - 104*s1**2*s3**3*s4 - 19*s1*s2**4*s3**2 ++ 120*s1*s2**2*s3**2*s4 - 128*s1*s2*s3**4 + 336*s1*s3**2*s4**2 + 2*s2**6*s3 - 24*s2**4*s3*s4 ++ 28*s2**3*s3**3 + 96*s2**2*s3*s4**2 - 176*s2*s3**3*s4 + 96*s3**5 - 128*s3*s4**3), + lambda s1, s2, s3, s4: (s1**10*s4**2 - 11*s1**8*s2*s4**2 - 2*s1**8*s3**2*s4 + s1**7*s2**2*s3*s4 + 15*s1**7*s3*s4**2 ++ 45*s1**6*s2**2*s4**2 + 17*s1**6*s2*s3**2*s4 + s1**6*s3**4 - 5*s1**6*s4**3 - 12*s1**5*s2**3*s3*s4 +- 133*s1**5*s2*s3*s4**2 - 22*s1**5*s3**3*s4 + s1**4*s2**5*s4 - 76*s1**4*s2**3*s4**2 +- 6*s1**4*s2**2*s3**2*s4 - 12*s1**4*s2*s3**4 + 32*s1**4*s2*s4**3 + 128*s1**4*s3**2*s4**2 ++ 29*s1**3*s2**4*s3*s4 + 2*s1**3*s2**3*s3**3 + 344*s1**3*s2**2*s3*s4**2 + 48*s1**3*s2*s3**3*s4 ++ 16*s1**3*s3**5 - 48*s1**3*s3*s4**3 - 4*s1**2*s2**6*s4 + 32*s1**2*s2**4*s4**2 - 134*s1**2*s2**3*s3**2*s4 ++ 36*s1**2*s2**2*s3**4 - 64*s1**2*s2**2*s4**3 - 648*s1**2*s2*s3**2*s4**2 - 48*s1**2*s3**4*s4 ++ 16*s1*s2**5*s3*s4 - 12*s1*s2**4*s3**3 - 128*s1*s2**3*s3*s4**2 + 296*s1*s2**2*s3**3*s4 +- 96*s1*s2*s3**5 + 256*s1*s2*s3*s4**3 + 416*s1*s3**3*s4**2 + s2**6*s3**2 - 28*s2**4*s3**2*s4 ++ 16*s2**3*s3**4 + 176*s2**2*s3**2*s4**2 - 224*s2*s3**4*s4 + 64*s3**6 - 320*s3**2*s4**3) + ], + (4, 1): [ + lambda s1, s2, s3, s4: (-s2), + lambda s1, s2, s3, s4: (s1*s3 - 4*s4), + lambda s1, s2, s3, s4: (-s1**2*s4 + 4*s2*s4 - s3**2) + ], + (5, 1): [ + lambda s1, s2, s3, s4, s5: (-2*s1*s3 + 8*s4), + lambda s1, s2, s3, s4, s5: (-8*s1**3*s5 + 2*s1**2*s2*s4 + s1**2*s3**2 + 30*s1*s2*s5 - 14*s1*s3*s4 - 6*s2**2*s4 ++ 2*s2*s3**2 - 50*s3*s5 + 40*s4**2), + lambda s1, s2, s3, s4, s5: (16*s1**4*s3*s5 - 2*s1**4*s4**2 - 2*s1**3*s2**2*s5 - 2*s1**3*s2*s3*s4 - 44*s1**3*s4*s5 +- 66*s1**2*s2*s3*s5 + 21*s1**2*s2*s4**2 + 6*s1**2*s3**2*s4 - 50*s1**2*s5**2 + 9*s1*s2**3*s5 ++ 5*s1*s2**2*s3*s4 - 2*s1*s2*s3**3 + 190*s1*s2*s4*s5 + 120*s1*s3**2*s5 - 80*s1*s3*s4**2 +- 15*s2**2*s3*s5 - 40*s2**2*s4**2 + 21*s2*s3**2*s4 + 125*s2*s5**2 - 2*s3**4 - 400*s3*s4*s5 ++ 160*s4**3), + lambda s1, s2, s3, s4, s5: (16*s1**6*s5**2 - 8*s1**5*s2*s4*s5 - 8*s1**5*s3**2*s5 + 2*s1**5*s3*s4**2 + 2*s1**4*s2**2*s3*s5 ++ s1**4*s2**2*s4**2 - 120*s1**4*s2*s5**2 + 68*s1**4*s3*s4*s5 - 8*s1**4*s4**3 + 46*s1**3*s2**2*s4*s5 ++ 28*s1**3*s2*s3**2*s5 - 19*s1**3*s2*s3*s4**2 + 250*s1**3*s3*s5**2 - 144*s1**3*s4**2*s5 +- 9*s1**2*s2**3*s3*s5 - 6*s1**2*s2**3*s4**2 + 3*s1**2*s2**2*s3**2*s4 + 225*s1**2*s2**2*s5**2 +- 354*s1**2*s2*s3*s4*s5 + 76*s1**2*s2*s4**3 - 70*s1**2*s3**3*s5 + 41*s1**2*s3**2*s4**2 +- 200*s1**2*s4*s5**2 - 54*s1*s2**3*s4*s5 + 45*s1*s2**2*s3**2*s5 + 30*s1*s2**2*s3*s4**2 +- 19*s1*s2*s3**3*s4 - 875*s1*s2*s3*s5**2 + 640*s1*s2*s4**2*s5 + 2*s1*s3**5 + 630*s1*s3**2*s4*s5 +- 264*s1*s3*s4**3 + 9*s2**4*s4**2 - 6*s2**3*s3**2*s4 + s2**2*s3**4 + 90*s2**2*s3*s4*s5 +- 136*s2**2*s4**3 - 50*s2*s3**3*s5 + 76*s2*s3**2*s4**2 + 500*s2*s4*s5**2 - 8*s3**4*s4 ++ 625*s3**2*s5**2 - 1400*s3*s4**2*s5 + 400*s4**4), + lambda s1, s2, s3, s4, s5: (-32*s1**7*s3*s5**2 + 8*s1**7*s4**2*s5 + 8*s1**6*s2**2*s5**2 + 8*s1**6*s2*s3*s4*s5 +- 2*s1**6*s2*s4**3 + 48*s1**6*s4*s5**2 - 2*s1**5*s2**3*s4*s5 + 264*s1**5*s2*s3*s5**2 +- 94*s1**5*s2*s4**2*s5 - 24*s1**5*s3**2*s4*s5 + 6*s1**5*s3*s4**3 - 56*s1**5*s5**3 +- 66*s1**4*s2**3*s5**2 - 50*s1**4*s2**2*s3*s4*s5 + 19*s1**4*s2**2*s4**3 + 8*s1**4*s2*s3**3*s5 +- 2*s1**4*s2*s3**2*s4**2 - 318*s1**4*s2*s4*s5**2 - 352*s1**4*s3**2*s5**2 + 166*s1**4*s3*s4**2*s5 ++ 3*s1**4*s4**4 + 15*s1**3*s2**4*s4*s5 - 2*s1**3*s2**3*s3**2*s5 - s1**3*s2**3*s3*s4**2 +- 574*s1**3*s2**2*s3*s5**2 + 347*s1**3*s2**2*s4**2*s5 + 194*s1**3*s2*s3**2*s4*s5 - +89*s1**3*s2*s3*s4**3 + 350*s1**3*s2*s5**3 - 8*s1**3*s3**4*s5 + 4*s1**3*s3**3*s4**2 ++ 1090*s1**3*s3*s4*s5**2 - 364*s1**3*s4**3*s5 + 162*s1**2*s2**4*s5**2 + 33*s1**2*s2**3*s3*s4*s5 +- 51*s1**2*s2**3*s4**3 - 32*s1**2*s2**2*s3**3*s5 + 28*s1**2*s2**2*s3**2*s4**2 + 305*s1**2*s2**2*s4*s5**2 +- 2*s1**2*s2*s3**4*s4 + 1340*s1**2*s2*s3**2*s5**2 - 901*s1**2*s2*s3*s4**2*s5 + 76*s1**2*s2*s4**4 +- 234*s1**2*s3**3*s4*s5 + 102*s1**2*s3**2*s4**3 - 750*s1**2*s3*s5**3 - 550*s1**2*s4**2*s5**2 +- 27*s1*s2**5*s4*s5 + 9*s1*s2**4*s3**2*s5 + 3*s1*s2**4*s3*s4**2 - s1*s2**3*s3**3*s4 ++ 180*s1*s2**3*s3*s5**2 - 366*s1*s2**3*s4**2*s5 - 231*s1*s2**2*s3**2*s4*s5 + 212*s1*s2**2*s3*s4**3 +- 375*s1*s2**2*s5**3 + 112*s1*s2*s3**4*s5 - 89*s1*s2*s3**3*s4**2 - 3075*s1*s2*s3*s4*s5**2 ++ 1640*s1*s2*s4**3*s5 + 6*s1*s3**5*s4 - 850*s1*s3**3*s5**2 + 1220*s1*s3**2*s4**2*s5 +- 384*s1*s3*s4**4 + 2500*s1*s4*s5**3 - 108*s2**5*s5**2 + 117*s2**4*s3*s4*s5 + 32*s2**4*s4**3 +- 31*s2**3*s3**3*s5 - 51*s2**3*s3**2*s4**2 + 525*s2**3*s4*s5**2 + 19*s2**2*s3**4*s4 +- 325*s2**2*s3**2*s5**2 + 260*s2**2*s3*s4**2*s5 - 256*s2**2*s4**4 - 2*s2*s3**6 + 105*s2*s3**3*s4*s5 ++ 76*s2*s3**2*s4**3 + 625*s2*s3*s5**3 - 500*s2*s4**2*s5**2 - 58*s3**5*s5 + 3*s3**4*s4**2 ++ 2750*s3**2*s4*s5**2 - 2400*s3*s4**3*s5 + 512*s4**5 - 3125*s5**4), + lambda s1, s2, s3, s4, s5: (16*s1**8*s3**2*s5**2 - 8*s1**8*s3*s4**2*s5 + s1**8*s4**4 - 8*s1**7*s2**2*s3*s5**2 ++ 2*s1**7*s2**2*s4**2*s5 - 48*s1**7*s3*s4*s5**2 + 12*s1**7*s4**3*s5 + s1**6*s2**4*s5**2 ++ 12*s1**6*s2**2*s4*s5**2 - 144*s1**6*s2*s3**2*s5**2 + 88*s1**6*s2*s3*s4**2*s5 - 13*s1**6*s2*s4**4 ++ 56*s1**6*s3*s5**3 + 86*s1**6*s4**2*s5**2 + 72*s1**5*s2**3*s3*s5**2 - 22*s1**5*s2**3*s4**2*s5 +- 4*s1**5*s2**2*s3**2*s4*s5 + s1**5*s2**2*s3*s4**3 - 14*s1**5*s2**2*s5**3 + 304*s1**5*s2*s3*s4*s5**2 +- 148*s1**5*s2*s4**3*s5 + 152*s1**5*s3**3*s5**2 - 54*s1**5*s3**2*s4**2*s5 + 5*s1**5*s3*s4**4 +- 468*s1**5*s4*s5**3 - 9*s1**4*s2**5*s5**2 + s1**4*s2**4*s3*s4*s5 - 76*s1**4*s2**3*s4*s5**2 ++ 370*s1**4*s2**2*s3**2*s5**2 - 287*s1**4*s2**2*s3*s4**2*s5 + 65*s1**4*s2**2*s4**4 +- 28*s1**4*s2*s3**3*s4*s5 + 5*s1**4*s2*s3**2*s4**3 - 200*s1**4*s2*s3*s5**3 - 294*s1**4*s2*s4**2*s5**2 ++ 8*s1**4*s3**5*s5 - 2*s1**4*s3**4*s4**2 - 676*s1**4*s3**2*s4*s5**2 + 180*s1**4*s3*s4**3*s5 ++ 17*s1**4*s4**5 + 625*s1**4*s5**4 - 210*s1**3*s2**4*s3*s5**2 + 76*s1**3*s2**4*s4**2*s5 ++ 43*s1**3*s2**3*s3**2*s4*s5 - 15*s1**3*s2**3*s3*s4**3 + 50*s1**3*s2**3*s5**3 - 6*s1**3*s2**2*s3**4*s5 ++ 2*s1**3*s2**2*s3**3*s4**2 - 397*s1**3*s2**2*s3*s4*s5**2 + 514*s1**3*s2**2*s4**3*s5 +- 700*s1**3*s2*s3**3*s5**2 + 447*s1**3*s2*s3**2*s4**2*s5 - 118*s1**3*s2*s3*s4**4 + +2300*s1**3*s2*s4*s5**3 - 12*s1**3*s3**4*s4*s5 + 6*s1**3*s3**3*s4**3 + 250*s1**3*s3**2*s5**3 ++ 1470*s1**3*s3*s4**2*s5**2 - 276*s1**3*s4**4*s5 + 27*s1**2*s2**6*s5**2 - 9*s1**2*s2**5*s3*s4*s5 ++ s1**2*s2**5*s4**3 + s1**2*s2**4*s3**3*s5 + 141*s1**2*s2**4*s4*s5**2 - 185*s1**2*s2**3*s3**2*s5**2 ++ 168*s1**2*s2**3*s3*s4**2*s5 - 128*s1**2*s2**3*s4**4 + 93*s1**2*s2**2*s3**3*s4*s5 ++ 19*s1**2*s2**2*s3**2*s4**3 - 125*s1**2*s2**2*s3*s5**3 - 610*s1**2*s2**2*s4**2*s5**2 +- 36*s1**2*s2*s3**5*s5 + 5*s1**2*s2*s3**4*s4**2 + 1995*s1**2*s2*s3**2*s4*s5**2 - 1174*s1**2*s2*s3*s4**3*s5 +- 16*s1**2*s2*s4**5 - 3125*s1**2*s2*s5**4 + 375*s1**2*s3**4*s5**2 - 172*s1**2*s3**3*s4**2*s5 ++ 82*s1**2*s3**2*s4**4 - 3500*s1**2*s3*s4*s5**3 - 1450*s1**2*s4**3*s5**2 + 198*s1*s2**5*s3*s5**2 +- 78*s1*s2**5*s4**2*s5 - 95*s1*s2**4*s3**2*s4*s5 + 44*s1*s2**4*s3*s4**3 + 25*s1*s2**3*s3**4*s5 +- 15*s1*s2**3*s3**3*s4**2 + 15*s1*s2**3*s3*s4*s5**2 - 384*s1*s2**3*s4**3*s5 + s1*s2**2*s3**5*s4 ++ 525*s1*s2**2*s3**3*s5**2 - 528*s1*s2**2*s3**2*s4**2*s5 + 384*s1*s2**2*s3*s4**4 - +1750*s1*s2**2*s4*s5**3 - 29*s1*s2*s3**4*s4*s5 - 118*s1*s2*s3**3*s4**3 + 625*s1*s2*s3**2*s5**3 +- 850*s1*s2*s3*s4**2*s5**2 + 1760*s1*s2*s4**4*s5 + 38*s1*s3**6*s5 + 5*s1*s3**5*s4**2 +- 2050*s1*s3**3*s4*s5**2 + 780*s1*s3**2*s4**3*s5 - 192*s1*s3*s4**5 + 3125*s1*s3*s5**4 ++ 7500*s1*s4**2*s5**3 - 27*s2**7*s5**2 + 18*s2**6*s3*s4*s5 - 4*s2**6*s4**3 - 4*s2**5*s3**3*s5 ++ s2**5*s3**2*s4**2 - 99*s2**5*s4*s5**2 - 150*s2**4*s3**2*s5**2 + 196*s2**4*s3*s4**2*s5 ++ 48*s2**4*s4**4 + 12*s2**3*s3**3*s4*s5 - 128*s2**3*s3**2*s4**3 + 1200*s2**3*s4**2*s5**2 +- 12*s2**2*s3**5*s5 + 65*s2**2*s3**4*s4**2 - 725*s2**2*s3**2*s4*s5**2 - 160*s2**2*s3*s4**3*s5 +- 192*s2**2*s4**5 + 3125*s2**2*s5**4 - 13*s2*s3**6*s4 - 125*s2*s3**4*s5**2 + 590*s2*s3**3*s4**2*s5 +- 16*s2*s3**2*s4**4 - 1250*s2*s3*s4*s5**3 - 2000*s2*s4**3*s5**2 + s3**8 - 124*s3**5*s4*s5 ++ 17*s3**4*s4**3 + 3250*s3**2*s4**2*s5**2 - 1600*s3*s4**4*s5 + 256*s4**6 - 9375*s4*s5**4) + ], + (6, 1): [ + lambda s1, s2, s3, s4, s5, s6: (8*s1*s5 - 2*s2*s4 - 18*s6), + lambda s1, s2, s3, s4, s5, s6: (-50*s1**2*s4*s6 + 40*s1**2*s5**2 + 30*s1*s2*s3*s6 - 14*s1*s2*s4*s5 - 6*s1*s3**2*s5 ++ 2*s1*s3*s4**2 - 30*s1*s5*s6 - 8*s2**3*s6 + 2*s2**2*s3*s5 + s2**2*s4**2 + 114*s2*s4*s6 +- 50*s2*s5**2 - 54*s3**2*s6 + 30*s3*s4*s5 - 8*s4**3 - 135*s6**2), + lambda s1, s2, s3, s4, s5, s6: (125*s1**3*s3*s6**2 - 400*s1**3*s4*s5*s6 + 160*s1**3*s5**3 - 50*s1**2*s2**2*s6**2 + +190*s1**2*s2*s3*s5*s6 + 120*s1**2*s2*s4**2*s6 - 80*s1**2*s2*s4*s5**2 - 15*s1**2*s3**2*s4*s6 +- 40*s1**2*s3**2*s5**2 + 21*s1**2*s3*s4**2*s5 - 2*s1**2*s4**4 + 900*s1**2*s4*s6**2 +- 80*s1**2*s5**2*s6 - 44*s1*s2**3*s5*s6 - 66*s1*s2**2*s3*s4*s6 + 21*s1*s2**2*s3*s5**2 ++ 6*s1*s2**2*s4**2*s5 + 9*s1*s2*s3**3*s6 + 5*s1*s2*s3**2*s4*s5 - 2*s1*s2*s3*s4**3 +- 990*s1*s2*s3*s6**2 + 920*s1*s2*s4*s5*s6 - 400*s1*s2*s5**3 - 135*s1*s3**2*s5*s6 - +126*s1*s3*s4**2*s6 + 190*s1*s3*s4*s5**2 - 44*s1*s4**3*s5 - 2070*s1*s5*s6**2 + 16*s2**4*s4*s6 +- 2*s2**4*s5**2 - 2*s2**3*s3**2*s6 - 2*s2**3*s3*s4*s5 + 304*s2**3*s6**2 - 126*s2**2*s3*s5*s6 +- 232*s2**2*s4**2*s6 + 120*s2**2*s4*s5**2 + 198*s2*s3**2*s4*s6 - 15*s2*s3**2*s5**2 +- 66*s2*s3*s4**2*s5 + 16*s2*s4**4 - 1440*s2*s4*s6**2 + 900*s2*s5**2*s6 - 27*s3**4*s6 ++ 9*s3**3*s4*s5 - 2*s3**2*s4**3 + 1350*s3**2*s6**2 - 990*s3*s4*s5*s6 + 125*s3*s5**3 ++ 304*s4**3*s6 - 50*s4**2*s5**2 + 3240*s6**3), + lambda s1, s2, s3, s4, s5, s6: (500*s1**4*s3*s5*s6**2 + 625*s1**4*s4**2*s6**2 - 1400*s1**4*s4*s5**2*s6 + 400*s1**4*s5**4 +- 200*s1**3*s2**2*s5*s6**2 - 875*s1**3*s2*s3*s4*s6**2 + 640*s1**3*s2*s3*s5**2*s6 + +630*s1**3*s2*s4**2*s5*s6 - 264*s1**3*s2*s4*s5**3 + 90*s1**3*s3**2*s4*s5*s6 - 136*s1**3*s3**2*s5**3 +- 50*s1**3*s3*s4**3*s6 + 76*s1**3*s3*s4**2*s5**2 - 1125*s1**3*s3*s6**3 - 8*s1**3*s4**4*s5 ++ 2550*s1**3*s4*s5*s6**2 - 200*s1**3*s5**3*s6 + 250*s1**2*s2**3*s4*s6**2 - 144*s1**2*s2**3*s5**2*s6 ++ 225*s1**2*s2**2*s3**2*s6**2 - 354*s1**2*s2**2*s3*s4*s5*s6 + 76*s1**2*s2**2*s3*s5**3 +- 70*s1**2*s2**2*s4**3*s6 + 41*s1**2*s2**2*s4**2*s5**2 + 450*s1**2*s2**2*s6**3 - 54*s1**2*s2*s3**3*s5*s6 ++ 45*s1**2*s2*s3**2*s4**2*s6 + 30*s1**2*s2*s3**2*s4*s5**2 - 19*s1**2*s2*s3*s4**3*s5 +- 2880*s1**2*s2*s3*s5*s6**2 + 2*s1**2*s2*s4**5 - 3480*s1**2*s2*s4**2*s6**2 + 4692*s1**2*s2*s4*s5**2*s6 +- 1400*s1**2*s2*s5**4 + 9*s1**2*s3**4*s5**2 - 6*s1**2*s3**3*s4**2*s5 + s1**2*s3**2*s4**4 ++ 1485*s1**2*s3**2*s4*s6**2 - 522*s1**2*s3**2*s5**2*s6 - 1257*s1**2*s3*s4**2*s5*s6 ++ 640*s1**2*s3*s4*s5**3 + 218*s1**2*s4**4*s6 - 144*s1**2*s4**3*s5**2 + 1350*s1**2*s4*s6**3 +- 5175*s1**2*s5**2*s6**2 - 120*s1*s2**4*s3*s6**2 + 68*s1*s2**4*s4*s5*s6 - 8*s1*s2**4*s5**3 ++ 46*s1*s2**3*s3**2*s5*s6 + 28*s1*s2**3*s3*s4**2*s6 - 19*s1*s2**3*s3*s4*s5**2 + 868*s1*s2**3*s5*s6**2 +- 9*s1*s2**2*s3**3*s4*s6 - 6*s1*s2**2*s3**3*s5**2 + 3*s1*s2**2*s3**2*s4**2*s5 + 2484*s1*s2**2*s3*s4*s6**2 +- 1257*s1*s2**2*s3*s5**2*s6 - 1356*s1*s2**2*s4**2*s5*s6 + 630*s1*s2**2*s4*s5**3 - +891*s1*s2*s3**3*s6**2 + 882*s1*s2*s3**2*s4*s5*s6 + 90*s1*s2*s3**2*s5**3 + 84*s1*s2*s3*s4**3*s6 +- 354*s1*s2*s3*s4**2*s5**2 + 3240*s1*s2*s3*s6**3 + 68*s1*s2*s4**4*s5 - 4392*s1*s2*s4*s5*s6**2 ++ 2550*s1*s2*s5**3*s6 + 54*s1*s3**4*s5*s6 - 54*s1*s3**3*s4**2*s6 - 54*s1*s3**3*s4*s5**2 ++ 46*s1*s3**2*s4**3*s5 + 2727*s1*s3**2*s5*s6**2 - 8*s1*s3*s4**5 + 756*s1*s3*s4**2*s6**2 +- 2880*s1*s3*s4*s5**2*s6 + 500*s1*s3*s5**4 + 868*s1*s4**3*s5*s6 - 200*s1*s4**2*s5**3 ++ 8100*s1*s5*s6**3 + 16*s2**6*s6**2 - 8*s2**5*s3*s5*s6 - 8*s2**5*s4**2*s6 + 2*s2**5*s4*s5**2 ++ 2*s2**4*s3**2*s4*s6 + s2**4*s3**2*s5**2 - 688*s2**4*s4*s6**2 + 218*s2**4*s5**2*s6 ++ 234*s2**3*s3**2*s6**2 + 84*s2**3*s3*s4*s5*s6 - 50*s2**3*s3*s5**3 + 168*s2**3*s4**3*s6 +- 70*s2**3*s4**2*s5**2 - 1224*s2**3*s6**3 - 54*s2**2*s3**3*s5*s6 - 144*s2**2*s3**2*s4**2*s6 ++ 45*s2**2*s3**2*s4*s5**2 + 28*s2**2*s3*s4**3*s5 + 756*s2**2*s3*s5*s6**2 - 8*s2**2*s4**5 ++ 4320*s2**2*s4**2*s6**2 - 3480*s2**2*s4*s5**2*s6 + 625*s2**2*s5**4 + 27*s2*s3**4*s4*s6 +- 9*s2*s3**3*s4**2*s5 + 2*s2*s3**2*s4**4 - 4752*s2*s3**2*s4*s6**2 + 1485*s2*s3**2*s5**2*s6 ++ 2484*s2*s3*s4**2*s5*s6 - 875*s2*s3*s4*s5**3 - 688*s2*s4**4*s6 + 250*s2*s4**3*s5**2 +- 4536*s2*s4*s6**3 + 1350*s2*s5**2*s6**2 + 972*s3**4*s6**2 - 891*s3**3*s4*s5*s6 + +234*s3**2*s4**3*s6 + 225*s3**2*s4**2*s5**2 - 1944*s3**2*s6**3 - 120*s3*s4**4*s5 + +3240*s3*s4*s5*s6**2 - 1125*s3*s5**3*s6 + 16*s4**6 - 1224*s4**3*s6**2 + 450*s4**2*s5**2*s6), + lambda s1, s2, s3, s4, s5, s6: (-3125*s1**6*s6**4 + 2500*s1**5*s2*s5*s6**3 + 625*s1**5*s3*s4*s6**3 - 500*s1**5*s3*s5**2*s6**2 ++ 2750*s1**5*s4**2*s5*s6**2 - 2400*s1**5*s4*s5**3*s6 + 512*s1**5*s5**5 - 750*s1**4*s2**2*s4*s6**3 +- 550*s1**4*s2**2*s5**2*s6**2 - 375*s1**4*s2*s3**2*s6**3 - 3075*s1**4*s2*s3*s4*s5*s6**2 ++ 1640*s1**4*s2*s3*s5**3*s6 - 850*s1**4*s2*s4**3*s6**2 + 1220*s1**4*s2*s4**2*s5**2*s6 +- 384*s1**4*s2*s4*s5**4 + 22500*s1**4*s2*s6**4 + 525*s1**4*s3**3*s5*s6**2 - 325*s1**4*s3**2*s4**2*s6**2 ++ 260*s1**4*s3**2*s4*s5**2*s6 - 256*s1**4*s3**2*s5**4 + 105*s1**4*s3*s4**3*s5*s6 + +76*s1**4*s3*s4**2*s5**3 + 375*s1**4*s3*s5*s6**3 - 58*s1**4*s4**5*s6 + 3*s1**4*s4**4*s5**2 +- 12750*s1**4*s4**2*s6**3 + 3700*s1**4*s4*s5**2*s6**2 + 640*s1**4*s5**4*s6 + 350*s1**3*s2**3*s3*s6**3 ++ 1090*s1**3*s2**3*s4*s5*s6**2 - 364*s1**3*s2**3*s5**3*s6 + 305*s1**3*s2**2*s3**2*s5*s6**2 ++ 1340*s1**3*s2**2*s3*s4**2*s6**2 - 901*s1**3*s2**2*s3*s4*s5**2*s6 + 76*s1**3*s2**2*s3*s5**4 +- 234*s1**3*s2**2*s4**3*s5*s6 + 102*s1**3*s2**2*s4**2*s5**3 - 16650*s1**3*s2**2*s5*s6**3 ++ 180*s1**3*s2*s3**3*s4*s6**2 - 366*s1**3*s2*s3**3*s5**2*s6 - 231*s1**3*s2*s3**2*s4**2*s5*s6 ++ 212*s1**3*s2*s3**2*s4*s5**3 + 112*s1**3*s2*s3*s4**4*s6 - 89*s1**3*s2*s3*s4**3*s5**2 ++ 10950*s1**3*s2*s3*s4*s6**3 + 1555*s1**3*s2*s3*s5**2*s6**2 + 6*s1**3*s2*s4**5*s5 +- 9540*s1**3*s2*s4**2*s5*s6**2 + 9016*s1**3*s2*s4*s5**3*s6 - 2400*s1**3*s2*s5**5 - +108*s1**3*s3**5*s6**2 + 117*s1**3*s3**4*s4*s5*s6 + 32*s1**3*s3**4*s5**3 - 31*s1**3*s3**3*s4**3*s6 +- 51*s1**3*s3**3*s4**2*s5**2 - 2025*s1**3*s3**3*s6**3 + 19*s1**3*s3**2*s4**4*s5 + +2955*s1**3*s3**2*s4*s5*s6**2 - 1436*s1**3*s3**2*s5**3*s6 - 2*s1**3*s3*s4**6 + 2770*s1**3*s3*s4**3*s6**2 +- 5123*s1**3*s3*s4**2*s5**2*s6 + 1640*s1**3*s3*s4*s5**4 - 40500*s1**3*s3*s6**4 + 914*s1**3*s4**4*s5*s6 +- 364*s1**3*s4**3*s5**3 + 53550*s1**3*s4*s5*s6**3 - 17930*s1**3*s5**3*s6**2 - 56*s1**2*s2**5*s6**3 +- 318*s1**2*s2**4*s3*s5*s6**2 - 352*s1**2*s2**4*s4**2*s6**2 + 166*s1**2*s2**4*s4*s5**2*s6 ++ 3*s1**2*s2**4*s5**4 - 574*s1**2*s2**3*s3**2*s4*s6**2 + 347*s1**2*s2**3*s3**2*s5**2*s6 ++ 194*s1**2*s2**3*s3*s4**2*s5*s6 - 89*s1**2*s2**3*s3*s4*s5**3 - 8*s1**2*s2**3*s4**4*s6 ++ 4*s1**2*s2**3*s4**3*s5**2 + 560*s1**2*s2**3*s4*s6**3 + 3662*s1**2*s2**3*s5**2*s6**2 ++ 162*s1**2*s2**2*s3**4*s6**2 + 33*s1**2*s2**2*s3**3*s4*s5*s6 - 51*s1**2*s2**2*s3**3*s5**3 +- 32*s1**2*s2**2*s3**2*s4**3*s6 + 28*s1**2*s2**2*s3**2*s4**2*s5**2 + 270*s1**2*s2**2*s3**2*s6**3 +- 2*s1**2*s2**2*s3*s4**4*s5 + 4872*s1**2*s2**2*s3*s4*s5*s6**2 - 5123*s1**2*s2**2*s3*s5**3*s6 ++ 2144*s1**2*s2**2*s4**3*s6**2 - 2812*s1**2*s2**2*s4**2*s5**2*s6 + 1220*s1**2*s2**2*s4*s5**4 +- 37800*s1**2*s2**2*s6**4 - 27*s1**2*s2*s3**5*s5*s6 + 9*s1**2*s2*s3**4*s4**2*s6 + +3*s1**2*s2*s3**4*s4*s5**2 - s1**2*s2*s3**3*s4**3*s5 - 3078*s1**2*s2*s3**3*s5*s6**2 +- 4014*s1**2*s2*s3**2*s4**2*s6**2 + 5412*s1**2*s2*s3**2*s4*s5**2*s6 + 260*s1**2*s2*s3**2*s5**4 +- 310*s1**2*s2*s3*s4**3*s5*s6 - 901*s1**2*s2*s3*s4**2*s5**3 - 3780*s1**2*s2*s3*s5*s6**3 ++ 166*s1**2*s2*s4**4*s5**2 + 40320*s1**2*s2*s4**2*s6**3 - 25344*s1**2*s2*s4*s5**2*s6**2 ++ 3700*s1**2*s2*s5**4*s6 + 918*s1**2*s3**4*s4*s6**2 + 27*s1**2*s3**4*s5**2*s6 - 342*s1**2*s3**3*s4**2*s5*s6 +- 366*s1**2*s3**3*s4*s5**3 + 32*s1**2*s3**2*s4**4*s6 + 347*s1**2*s3**2*s4**3*s5**2 +- 4590*s1**2*s3**2*s4*s6**3 + 594*s1**2*s3**2*s5**2*s6**2 - 94*s1**2*s3*s4**5*s5 + +3618*s1**2*s3*s4**2*s5*s6**2 + 1555*s1**2*s3*s4*s5**3*s6 - 500*s1**2*s3*s5**5 + 8*s1**2*s4**7 +- 7192*s1**2*s4**4*s6**2 + 3662*s1**2*s4**3*s5**2*s6 - 550*s1**2*s4**2*s5**4 - 48600*s1**2*s4*s6**4 ++ 1080*s1**2*s5**2*s6**3 + 48*s1*s2**6*s5*s6**2 + 264*s1*s2**5*s3*s4*s6**2 - 94*s1*s2**5*s3*s5**2*s6 +- 24*s1*s2**5*s4**2*s5*s6 + 6*s1*s2**5*s4*s5**3 - 66*s1*s2**4*s3**3*s6**2 - 50*s1*s2**4*s3**2*s4*s5*s6 ++ 19*s1*s2**4*s3**2*s5**3 + 8*s1*s2**4*s3*s4**3*s6 - 2*s1*s2**4*s3*s4**2*s5**2 - 552*s1*s2**4*s3*s6**3 +- 2560*s1*s2**4*s4*s5*s6**2 + 914*s1*s2**4*s5**3*s6 + 15*s1*s2**3*s3**4*s5*s6 - 2*s1*s2**3*s3**3*s4**2*s6 +- s1*s2**3*s3**3*s4*s5**2 + 1602*s1*s2**3*s3**2*s5*s6**2 - 608*s1*s2**3*s3*s4**2*s6**2 +- 310*s1*s2**3*s3*s4*s5**2*s6 + 105*s1*s2**3*s3*s5**4 + 600*s1*s2**3*s4**3*s5*s6 - +234*s1*s2**3*s4**2*s5**3 + 31368*s1*s2**3*s5*s6**3 + 756*s1*s2**2*s3**3*s4*s6**2 - +342*s1*s2**2*s3**3*s5**2*s6 + 216*s1*s2**2*s3**2*s4**2*s5*s6 - 231*s1*s2**2*s3**2*s4*s5**3 +- 192*s1*s2**2*s3*s4**4*s6 + 194*s1*s2**2*s3*s4**3*s5**2 - 39096*s1*s2**2*s3*s4*s6**3 ++ 3618*s1*s2**2*s3*s5**2*s6**2 - 24*s1*s2**2*s4**5*s5 + 9408*s1*s2**2*s4**2*s5*s6**2 +- 9540*s1*s2**2*s4*s5**3*s6 + 2750*s1*s2**2*s5**5 - 162*s1*s2*s3**5*s6**2 - 378*s1*s2*s3**4*s4*s5*s6 ++ 117*s1*s2*s3**4*s5**3 + 150*s1*s2*s3**3*s4**3*s6 + 33*s1*s2*s3**3*s4**2*s5**2 + +10044*s1*s2*s3**3*s6**3 - 50*s1*s2*s3**2*s4**4*s5 - 8640*s1*s2*s3**2*s4*s5*s6**2 + +2955*s1*s2*s3**2*s5**3*s6 + 8*s1*s2*s3*s4**6 + 6144*s1*s2*s3*s4**3*s6**2 + 4872*s1*s2*s3*s4**2*s5**2*s6 +- 3075*s1*s2*s3*s4*s5**4 + 174960*s1*s2*s3*s6**4 - 2560*s1*s2*s4**4*s5*s6 + 1090*s1*s2*s4**3*s5**3 +- 148824*s1*s2*s4*s5*s6**3 + 53550*s1*s2*s5**3*s6**2 + 81*s1*s3**6*s5*s6 - 27*s1*s3**5*s4**2*s6 +- 27*s1*s3**5*s4*s5**2 + 15*s1*s3**4*s4**3*s5 + 2430*s1*s3**4*s5*s6**2 - 2*s1*s3**3*s4**5 +- 2052*s1*s3**3*s4**2*s6**2 - 3078*s1*s3**3*s4*s5**2*s6 + 525*s1*s3**3*s5**4 + 1602*s1*s3**2*s4**3*s5*s6 ++ 305*s1*s3**2*s4**2*s5**3 + 18144*s1*s3**2*s5*s6**3 - 104*s1*s3*s4**5*s6 - 318*s1*s3*s4**4*s5**2 +- 33696*s1*s3*s4**2*s6**3 - 3780*s1*s3*s4*s5**2*s6**2 + 375*s1*s3*s5**4*s6 + 48*s1*s4**6*s5 ++ 31368*s1*s4**3*s5*s6**2 - 16650*s1*s4**2*s5**3*s6 + 2500*s1*s4*s5**5 + 77760*s1*s5*s6**4 +- 32*s2**7*s4*s6**2 + 8*s2**7*s5**2*s6 + 8*s2**6*s3**2*s6**2 + 8*s2**6*s3*s4*s5*s6 +- 2*s2**6*s3*s5**3 + 96*s2**6*s6**3 - 2*s2**5*s3**3*s5*s6 - 104*s2**5*s3*s5*s6**2 ++ 416*s2**5*s4**2*s6**2 - 58*s2**5*s5**4 - 312*s2**4*s3**2*s4*s6**2 + 32*s2**4*s3**2*s5**2*s6 +- 192*s2**4*s3*s4**2*s5*s6 + 112*s2**4*s3*s4*s5**3 - 8*s2**4*s4**3*s5**2 + 4224*s2**4*s4*s6**3 +- 7192*s2**4*s5**2*s6**2 + 54*s2**3*s3**4*s6**2 + 150*s2**3*s3**3*s4*s5*s6 - 31*s2**3*s3**3*s5**3 +- 32*s2**3*s3**2*s4**2*s5**2 - 864*s2**3*s3**2*s6**3 + 8*s2**3*s3*s4**4*s5 + 6144*s2**3*s3*s4*s5*s6**2 ++ 2770*s2**3*s3*s5**3*s6 - 4032*s2**3*s4**3*s6**2 + 2144*s2**3*s4**2*s5**2*s6 - 850*s2**3*s4*s5**4 +- 16416*s2**3*s6**4 - 27*s2**2*s3**5*s5*s6 + 9*s2**2*s3**4*s4*s5**2 - 2*s2**2*s3**3*s4**3*s5 +- 2052*s2**2*s3**3*s5*s6**2 + 2376*s2**2*s3**2*s4**2*s6**2 - 4014*s2**2*s3**2*s4*s5**2*s6 +- 325*s2**2*s3**2*s5**4 - 608*s2**2*s3*s4**3*s5*s6 + 1340*s2**2*s3*s4**2*s5**3 - 33696*s2**2*s3*s5*s6**3 ++ 416*s2**2*s4**5*s6 - 352*s2**2*s4**4*s5**2 - 6048*s2**2*s4**2*s6**3 + 40320*s2**2*s4*s5**2*s6**2 +- 12750*s2**2*s5**4*s6 - 324*s2*s3**4*s4*s6**2 + 918*s2*s3**4*s5**2*s6 + 756*s2*s3**3*s4**2*s5*s6 ++ 180*s2*s3**3*s4*s5**3 - 312*s2*s3**2*s4**4*s6 - 574*s2*s3**2*s4**3*s5**2 + 43416*s2*s3**2*s4*s6**3 +- 4590*s2*s3**2*s5**2*s6**2 + 264*s2*s3*s4**5*s5 - 39096*s2*s3*s4**2*s5*s6**2 + 10950*s2*s3*s4*s5**3*s6 ++ 625*s2*s3*s5**5 - 32*s2*s4**7 + 4224*s2*s4**4*s6**2 + 560*s2*s4**3*s5**2*s6 - 750*s2*s4**2*s5**4 ++ 85536*s2*s4*s6**4 - 48600*s2*s5**2*s6**3 - 162*s3**5*s4*s5*s6 - 108*s3**5*s5**3 ++ 54*s3**4*s4**3*s6 + 162*s3**4*s4**2*s5**2 - 11664*s3**4*s6**3 - 66*s3**3*s4**4*s5 ++ 10044*s3**3*s4*s5*s6**2 - 2025*s3**3*s5**3*s6 + 8*s3**2*s4**6 - 864*s3**2*s4**3*s6**2 ++ 270*s3**2*s4**2*s5**2*s6 - 375*s3**2*s4*s5**4 - 163296*s3**2*s6**4 - 552*s3*s4**4*s5*s6 ++ 350*s3*s4**3*s5**3 + 174960*s3*s4*s5*s6**3 - 40500*s3*s5**3*s6**2 + 96*s4**6*s6 +- 56*s4**5*s5**2 - 16416*s4**3*s6**3 - 37800*s4**2*s5**2*s6**2 + 22500*s4*s5**4*s6 +- 3125*s5**6 - 93312*s6**5), + lambda s1, s2, s3, s4, s5, s6: (-9375*s1**7*s5*s6**4 + 3125*s1**6*s2*s4*s6**4 + 7500*s1**6*s2*s5**2*s6**3 + 3125*s1**6*s3**2*s6**4 +- 1250*s1**6*s3*s4*s5*s6**3 - 2000*s1**6*s3*s5**3*s6**2 + 3250*s1**6*s4**2*s5**2*s6**2 +- 1600*s1**6*s4*s5**4*s6 + 256*s1**6*s5**6 + 40625*s1**6*s6**5 - 3125*s1**5*s2**2*s3*s6**4 +- 3500*s1**5*s2**2*s4*s5*s6**3 - 1450*s1**5*s2**2*s5**3*s6**2 - 1750*s1**5*s2*s3**2*s5*s6**3 ++ 625*s1**5*s2*s3*s4**2*s6**3 - 850*s1**5*s2*s3*s4*s5**2*s6**2 + 1760*s1**5*s2*s3*s5**4*s6 +- 2050*s1**5*s2*s4**3*s5*s6**2 + 780*s1**5*s2*s4**2*s5**3*s6 - 192*s1**5*s2*s4*s5**5 ++ 35000*s1**5*s2*s5*s6**4 + 1200*s1**5*s3**3*s5**2*s6**2 - 725*s1**5*s3**2*s4**2*s5*s6**2 +- 160*s1**5*s3**2*s4*s5**3*s6 - 192*s1**5*s3**2*s5**5 - 125*s1**5*s3*s4**4*s6**2 + +590*s1**5*s3*s4**3*s5**2*s6 - 16*s1**5*s3*s4**2*s5**4 - 20625*s1**5*s3*s4*s6**4 + +17250*s1**5*s3*s5**2*s6**3 - 124*s1**5*s4**5*s5*s6 + 17*s1**5*s4**4*s5**3 - 20250*s1**5*s4**2*s5*s6**3 ++ 1900*s1**5*s4*s5**3*s6**2 + 1344*s1**5*s5**5*s6 + 625*s1**4*s2**4*s6**4 + 2300*s1**4*s2**3*s3*s5*s6**3 ++ 250*s1**4*s2**3*s4**2*s6**3 + 1470*s1**4*s2**3*s4*s5**2*s6**2 - 276*s1**4*s2**3*s5**4*s6 +- 125*s1**4*s2**2*s3**2*s4*s6**3 - 610*s1**4*s2**2*s3**2*s5**2*s6**2 + 1995*s1**4*s2**2*s3*s4**2*s5*s6**2 +- 1174*s1**4*s2**2*s3*s4*s5**3*s6 - 16*s1**4*s2**2*s3*s5**5 + 375*s1**4*s2**2*s4**4*s6**2 +- 172*s1**4*s2**2*s4**3*s5**2*s6 + 82*s1**4*s2**2*s4**2*s5**4 - 7750*s1**4*s2**2*s4*s6**4 +- 46650*s1**4*s2**2*s5**2*s6**3 + 15*s1**4*s2*s3**3*s4*s5*s6**2 - 384*s1**4*s2*s3**3*s5**3*s6 ++ 525*s1**4*s2*s3**2*s4**3*s6**2 - 528*s1**4*s2*s3**2*s4**2*s5**2*s6 + 384*s1**4*s2*s3**2*s4*s5**4 +- 10125*s1**4*s2*s3**2*s6**4 - 29*s1**4*s2*s3*s4**4*s5*s6 - 118*s1**4*s2*s3*s4**3*s5**3 ++ 36700*s1**4*s2*s3*s4*s5*s6**3 + 2410*s1**4*s2*s3*s5**3*s6**2 + 38*s1**4*s2*s4**6*s6 ++ 5*s1**4*s2*s4**5*s5**2 + 5550*s1**4*s2*s4**3*s6**3 - 10040*s1**4*s2*s4**2*s5**2*s6**2 ++ 5800*s1**4*s2*s4*s5**4*s6 - 1600*s1**4*s2*s5**6 - 292500*s1**4*s2*s6**5 - 99*s1**4*s3**5*s5*s6**2 +- 150*s1**4*s3**4*s4**2*s6**2 + 196*s1**4*s3**4*s4*s5**2*s6 + 48*s1**4*s3**4*s5**4 ++ 12*s1**4*s3**3*s4**3*s5*s6 - 128*s1**4*s3**3*s4**2*s5**3 - 6525*s1**4*s3**3*s5*s6**3 +- 12*s1**4*s3**2*s4**5*s6 + 65*s1**4*s3**2*s4**4*s5**2 + 225*s1**4*s3**2*s4**2*s6**3 ++ 80*s1**4*s3**2*s4*s5**2*s6**2 - 13*s1**4*s3*s4**6*s5 + 5145*s1**4*s3*s4**3*s5*s6**2 +- 6746*s1**4*s3*s4**2*s5**3*s6 + 1760*s1**4*s3*s4*s5**5 - 103500*s1**4*s3*s5*s6**4 ++ s1**4*s4**8 + 954*s1**4*s4**5*s6**2 + 449*s1**4*s4**4*s5**2*s6 - 276*s1**4*s4**3*s5**4 ++ 70125*s1**4*s4**2*s6**4 + 58900*s1**4*s4*s5**2*s6**3 - 23310*s1**4*s5**4*s6**2 - +468*s1**3*s2**5*s5*s6**3 - 200*s1**3*s2**4*s3*s4*s6**3 - 294*s1**3*s2**4*s3*s5**2*s6**2 +- 676*s1**3*s2**4*s4**2*s5*s6**2 + 180*s1**3*s2**4*s4*s5**3*s6 + 17*s1**3*s2**4*s5**5 ++ 50*s1**3*s2**3*s3**3*s6**3 - 397*s1**3*s2**3*s3**2*s4*s5*s6**2 + 514*s1**3*s2**3*s3**2*s5**3*s6 +- 700*s1**3*s2**3*s3*s4**3*s6**2 + 447*s1**3*s2**3*s3*s4**2*s5**2*s6 - 118*s1**3*s2**3*s3*s4*s5**4 ++ 11700*s1**3*s2**3*s3*s6**4 - 12*s1**3*s2**3*s4**4*s5*s6 + 6*s1**3*s2**3*s4**3*s5**3 ++ 10360*s1**3*s2**3*s4*s5*s6**3 + 11404*s1**3*s2**3*s5**3*s6**2 + 141*s1**3*s2**2*s3**4*s5*s6**2 +- 185*s1**3*s2**2*s3**3*s4**2*s6**2 + 168*s1**3*s2**2*s3**3*s4*s5**2*s6 - 128*s1**3*s2**2*s3**3*s5**4 ++ 93*s1**3*s2**2*s3**2*s4**3*s5*s6 + 19*s1**3*s2**2*s3**2*s4**2*s5**3 + 5895*s1**3*s2**2*s3**2*s5*s6**3 +- 36*s1**3*s2**2*s3*s4**5*s6 + 5*s1**3*s2**2*s3*s4**4*s5**2 - 12020*s1**3*s2**2*s3*s4**2*s6**3 +- 5698*s1**3*s2**2*s3*s4*s5**2*s6**2 - 6746*s1**3*s2**2*s3*s5**4*s6 + 5064*s1**3*s2**2*s4**3*s5*s6**2 +- 762*s1**3*s2**2*s4**2*s5**3*s6 + 780*s1**3*s2**2*s4*s5**5 + 93900*s1**3*s2**2*s5*s6**4 ++ 198*s1**3*s2*s3**5*s4*s6**2 - 78*s1**3*s2*s3**5*s5**2*s6 - 95*s1**3*s2*s3**4*s4**2*s5*s6 ++ 44*s1**3*s2*s3**4*s4*s5**3 + 25*s1**3*s2*s3**3*s4**4*s6 - 15*s1**3*s2*s3**3*s4**3*s5**2 ++ 1935*s1**3*s2*s3**3*s4*s6**3 - 2808*s1**3*s2*s3**3*s5**2*s6**2 + s1**3*s2*s3**2*s4**5*s5 +- 4844*s1**3*s2*s3**2*s4**2*s5*s6**2 + 8996*s1**3*s2*s3**2*s4*s5**3*s6 - 160*s1**3*s2*s3**2*s5**5 +- 3616*s1**3*s2*s3*s4**4*s6**2 + 500*s1**3*s2*s3*s4**3*s5**2*s6 - 1174*s1**3*s2*s3*s4**2*s5**4 ++ 72900*s1**3*s2*s3*s4*s6**4 - 55665*s1**3*s2*s3*s5**2*s6**3 + 128*s1**3*s2*s4**5*s5*s6 ++ 180*s1**3*s2*s4**4*s5**3 + 16240*s1**3*s2*s4**2*s5*s6**3 - 9330*s1**3*s2*s4*s5**3*s6**2 ++ 1900*s1**3*s2*s5**5*s6 - 27*s1**3*s3**7*s6**2 + 18*s1**3*s3**6*s4*s5*s6 - 4*s1**3*s3**6*s5**3 +- 4*s1**3*s3**5*s4**3*s6 + s1**3*s3**5*s4**2*s5**2 + 54*s1**3*s3**5*s6**3 + 1143*s1**3*s3**4*s4*s5*s6**2 +- 820*s1**3*s3**4*s5**3*s6 + 923*s1**3*s3**3*s4**3*s6**2 + 57*s1**3*s3**3*s4**2*s5**2*s6 +- 384*s1**3*s3**3*s4*s5**4 + 29700*s1**3*s3**3*s6**4 - 547*s1**3*s3**2*s4**4*s5*s6 ++ 514*s1**3*s3**2*s4**3*s5**3 - 10305*s1**3*s3**2*s4*s5*s6**3 - 7405*s1**3*s3**2*s5**3*s6**2 ++ 108*s1**3*s3*s4**6*s6 - 148*s1**3*s3*s4**5*s5**2 - 11360*s1**3*s3*s4**3*s6**3 + +22209*s1**3*s3*s4**2*s5**2*s6**2 + 2410*s1**3*s3*s4*s5**4*s6 - 2000*s1**3*s3*s5**6 ++ 432000*s1**3*s3*s6**5 + 12*s1**3*s4**7*s5 - 22624*s1**3*s4**4*s5*s6**2 + 11404*s1**3*s4**3*s5**3*s6 +- 1450*s1**3*s4**2*s5**5 - 242100*s1**3*s4*s5*s6**4 + 58430*s1**3*s5**3*s6**3 + 56*s1**2*s2**6*s4*s6**3 ++ 86*s1**2*s2**6*s5**2*s6**2 - 14*s1**2*s2**5*s3**2*s6**3 + 304*s1**2*s2**5*s3*s4*s5*s6**2 +- 148*s1**2*s2**5*s3*s5**3*s6 + 152*s1**2*s2**5*s4**3*s6**2 - 54*s1**2*s2**5*s4**2*s5**2*s6 ++ 5*s1**2*s2**5*s4*s5**4 - 2472*s1**2*s2**5*s6**4 - 76*s1**2*s2**4*s3**3*s5*s6**2 ++ 370*s1**2*s2**4*s3**2*s4**2*s6**2 - 287*s1**2*s2**4*s3**2*s4*s5**2*s6 + 65*s1**2*s2**4*s3**2*s5**4 +- 28*s1**2*s2**4*s3*s4**3*s5*s6 + 5*s1**2*s2**4*s3*s4**2*s5**3 - 8092*s1**2*s2**4*s3*s5*s6**3 ++ 8*s1**2*s2**4*s4**5*s6 - 2*s1**2*s2**4*s4**4*s5**2 + 1096*s1**2*s2**4*s4**2*s6**3 +- 5144*s1**2*s2**4*s4*s5**2*s6**2 + 449*s1**2*s2**4*s5**4*s6 - 210*s1**2*s2**3*s3**4*s4*s6**2 ++ 76*s1**2*s2**3*s3**4*s5**2*s6 + 43*s1**2*s2**3*s3**3*s4**2*s5*s6 - 15*s1**2*s2**3*s3**3*s4*s5**3 +- 6*s1**2*s2**3*s3**2*s4**4*s6 + 2*s1**2*s2**3*s3**2*s4**3*s5**2 + 1962*s1**2*s2**3*s3**2*s4*s6**3 ++ 3181*s1**2*s2**3*s3**2*s5**2*s6**2 + 1684*s1**2*s2**3*s3*s4**2*s5*s6**2 + 500*s1**2*s2**3*s3*s4*s5**3*s6 ++ 590*s1**2*s2**3*s3*s5**5 - 168*s1**2*s2**3*s4**4*s6**2 - 494*s1**2*s2**3*s4**3*s5**2*s6 +- 172*s1**2*s2**3*s4**2*s5**4 - 22080*s1**2*s2**3*s4*s6**4 + 58894*s1**2*s2**3*s5**2*s6**3 ++ 27*s1**2*s2**2*s3**6*s6**2 - 9*s1**2*s2**2*s3**5*s4*s5*s6 + s1**2*s2**2*s3**5*s5**3 ++ s1**2*s2**2*s3**4*s4**3*s6 - 486*s1**2*s2**2*s3**4*s6**3 + 1071*s1**2*s2**2*s3**3*s4*s5*s6**2 ++ 57*s1**2*s2**2*s3**3*s5**3*s6 + 2262*s1**2*s2**2*s3**2*s4**3*s6**2 - 2742*s1**2*s2**2*s3**2*s4**2*s5**2*s6 +- 528*s1**2*s2**2*s3**2*s4*s5**4 - 29160*s1**2*s2**2*s3**2*s6**4 + 772*s1**2*s2**2*s3*s4**4*s5*s6 ++ 447*s1**2*s2**2*s3*s4**3*s5**3 - 96732*s1**2*s2**2*s3*s4*s5*s6**3 + 22209*s1**2*s2**2*s3*s5**3*s6**2 +- 160*s1**2*s2**2*s4**6*s6 - 54*s1**2*s2**2*s4**5*s5**2 - 7992*s1**2*s2**2*s4**3*s6**3 ++ 8634*s1**2*s2**2*s4**2*s5**2*s6**2 - 10040*s1**2*s2**2*s4*s5**4*s6 + 3250*s1**2*s2**2*s5**6 ++ 529200*s1**2*s2**2*s6**5 - 351*s1**2*s2*s3**5*s5*s6**2 - 1215*s1**2*s2*s3**4*s4**2*s6**2 +- 360*s1**2*s2*s3**4*s4*s5**2*s6 + 196*s1**2*s2*s3**4*s5**4 + 741*s1**2*s2*s3**3*s4**3*s5*s6 ++ 168*s1**2*s2*s3**3*s4**2*s5**3 + 11718*s1**2*s2*s3**3*s5*s6**3 - 106*s1**2*s2*s3**2*s4**5*s6 +- 287*s1**2*s2*s3**2*s4**4*s5**2 + 22572*s1**2*s2*s3**2*s4**2*s6**3 - 8892*s1**2*s2*s3**2*s4*s5**2*s6**2 ++ 80*s1**2*s2*s3**2*s5**4*s6 + 88*s1**2*s2*s3*s4**6*s5 + 22144*s1**2*s2*s3*s4**3*s5*s6**2 +- 5698*s1**2*s2*s3*s4**2*s5**3*s6 - 850*s1**2*s2*s3*s4*s5**5 + 169560*s1**2*s2*s3*s5*s6**4 +- 8*s1**2*s2*s4**8 + 3032*s1**2*s2*s4**5*s6**2 - 5144*s1**2*s2*s4**4*s5**2*s6 + 1470*s1**2*s2*s4**3*s5**4 +- 249480*s1**2*s2*s4**2*s6**4 - 105390*s1**2*s2*s4*s5**2*s6**3 + 58900*s1**2*s2*s5**4*s6**2 ++ 162*s1**2*s3**6*s4*s6**2 + 216*s1**2*s3**6*s5**2*s6 - 216*s1**2*s3**5*s4**2*s5*s6 +- 78*s1**2*s3**5*s4*s5**3 + 36*s1**2*s3**4*s4**4*s6 + 76*s1**2*s3**4*s4**3*s5**2 - +3564*s1**2*s3**4*s4*s6**3 + 8802*s1**2*s3**4*s5**2*s6**2 - 22*s1**2*s3**3*s4**5*s5 +- 11475*s1**2*s3**3*s4**2*s5*s6**2 - 2808*s1**2*s3**3*s4*s5**3*s6 + 1200*s1**2*s3**3*s5**5 ++ 2*s1**2*s3**2*s4**7 + 222*s1**2*s3**2*s4**4*s6**2 + 3181*s1**2*s3**2*s4**3*s5**2*s6 +- 610*s1**2*s3**2*s4**2*s5**4 - 165240*s1**2*s3**2*s4*s6**4 + 118260*s1**2*s3**2*s5**2*s6**3 ++ 572*s1**2*s3*s4**5*s5*s6 - 294*s1**2*s3*s4**4*s5**3 - 32616*s1**2*s3*s4**2*s5*s6**3 +- 55665*s1**2*s3*s4*s5**3*s6**2 + 17250*s1**2*s3*s5**5*s6 - 232*s1**2*s4**7*s6 + 86*s1**2*s4**6*s5**2 ++ 48408*s1**2*s4**4*s6**3 + 58894*s1**2*s4**3*s5**2*s6**2 - 46650*s1**2*s4**2*s5**4*s6 ++ 7500*s1**2*s4*s5**6 - 129600*s1**2*s4*s6**5 + 41040*s1**2*s5**2*s6**4 - 48*s1*s2**7*s4*s5*s6**2 ++ 12*s1*s2**7*s5**3*s6 + 12*s1*s2**6*s3**2*s5*s6**2 - 144*s1*s2**6*s3*s4**2*s6**2 ++ 88*s1*s2**6*s3*s4*s5**2*s6 - 13*s1*s2**6*s3*s5**4 + 1680*s1*s2**6*s5*s6**3 + 72*s1*s2**5*s3**3*s4*s6**2 +- 22*s1*s2**5*s3**3*s5**2*s6 - 4*s1*s2**5*s3**2*s4**2*s5*s6 + s1*s2**5*s3**2*s4*s5**3 +- 144*s1*s2**5*s3*s4*s6**3 + 572*s1*s2**5*s3*s5**2*s6**2 + 736*s1*s2**5*s4**2*s5*s6**2 ++ 128*s1*s2**5*s4*s5**3*s6 - 124*s1*s2**5*s5**5 - 9*s1*s2**4*s3**5*s6**2 + s1*s2**4*s3**4*s4*s5*s6 ++ 36*s1*s2**4*s3**3*s6**3 - 2028*s1*s2**4*s3**2*s4*s5*s6**2 - 547*s1*s2**4*s3**2*s5**3*s6 +- 480*s1*s2**4*s3*s4**3*s6**2 + 772*s1*s2**4*s3*s4**2*s5**2*s6 - 29*s1*s2**4*s3*s4*s5**4 ++ 6336*s1*s2**4*s3*s6**4 - 12*s1*s2**4*s4**3*s5**3 + 4368*s1*s2**4*s4*s5*s6**3 - 22624*s1*s2**4*s5**3*s6**2 ++ 441*s1*s2**3*s3**4*s5*s6**2 + 336*s1*s2**3*s3**3*s4**2*s6**2 + 741*s1*s2**3*s3**3*s4*s5**2*s6 ++ 12*s1*s2**3*s3**3*s5**4 - 868*s1*s2**3*s3**2*s4**3*s5*s6 + 93*s1*s2**3*s3**2*s4**2*s5**3 ++ 11016*s1*s2**3*s3**2*s5*s6**3 + 176*s1*s2**3*s3*s4**5*s6 - 28*s1*s2**3*s3*s4**4*s5**2 ++ 14784*s1*s2**3*s3*s4**2*s6**3 + 22144*s1*s2**3*s3*s4*s5**2*s6**2 + 5145*s1*s2**3*s3*s5**4*s6 +- 11344*s1*s2**3*s4**3*s5*s6**2 + 5064*s1*s2**3*s4**2*s5**3*s6 - 2050*s1*s2**3*s4*s5**5 +- 346896*s1*s2**3*s5*s6**4 - 54*s1*s2**2*s3**5*s4*s6**2 - 216*s1*s2**2*s3**5*s5**2*s6 ++ 324*s1*s2**2*s3**4*s4**2*s5*s6 - 95*s1*s2**2*s3**4*s4*s5**3 - 80*s1*s2**2*s3**3*s4**4*s6 ++ 43*s1*s2**2*s3**3*s4**3*s5**2 - 12204*s1*s2**2*s3**3*s4*s6**3 - 11475*s1*s2**2*s3**3*s5**2*s6**2 +- 4*s1*s2**2*s3**2*s4**5*s5 - 3888*s1*s2**2*s3**2*s4**2*s5*s6**2 - 4844*s1*s2**2*s3**2*s4*s5**3*s6 +- 725*s1*s2**2*s3**2*s5**5 - 1312*s1*s2**2*s3*s4**4*s6**2 + 1684*s1*s2**2*s3*s4**3*s5**2*s6 ++ 1995*s1*s2**2*s3*s4**2*s5**4 + 139104*s1*s2**2*s3*s4*s6**4 - 32616*s1*s2**2*s3*s5**2*s6**3 ++ 736*s1*s2**2*s4**5*s5*s6 - 676*s1*s2**2*s4**4*s5**3 + 131040*s1*s2**2*s4**2*s5*s6**3 ++ 16240*s1*s2**2*s4*s5**3*s6**2 - 20250*s1*s2**2*s5**5*s6 - 27*s1*s2*s3**6*s4*s5*s6 ++ 18*s1*s2*s3**6*s5**3 + 9*s1*s2*s3**5*s4**3*s6 - 9*s1*s2*s3**5*s4**2*s5**2 + 1944*s1*s2*s3**5*s6**3 ++ s1*s2*s3**4*s4**4*s5 + 6156*s1*s2*s3**4*s4*s5*s6**2 + 1143*s1*s2*s3**4*s5**3*s6 ++ 324*s1*s2*s3**3*s4**3*s6**2 + 1071*s1*s2*s3**3*s4**2*s5**2*s6 + 15*s1*s2*s3**3*s4*s5**4 +- 7776*s1*s2*s3**3*s6**4 - 2028*s1*s2*s3**2*s4**4*s5*s6 - 397*s1*s2*s3**2*s4**3*s5**3 ++ 112860*s1*s2*s3**2*s4*s5*s6**3 - 10305*s1*s2*s3**2*s5**3*s6**2 + 336*s1*s2*s3*s4**6*s6 ++ 304*s1*s2*s3*s4**5*s5**2 - 68976*s1*s2*s3*s4**3*s6**3 - 96732*s1*s2*s3*s4**2*s5**2*s6**2 ++ 36700*s1*s2*s3*s4*s5**4*s6 - 1250*s1*s2*s3*s5**6 - 1477440*s1*s2*s3*s6**5 - 48*s1*s2*s4**7*s5 ++ 4368*s1*s2*s4**4*s5*s6**2 + 10360*s1*s2*s4**3*s5**3*s6 - 3500*s1*s2*s4**2*s5**5 ++ 935280*s1*s2*s4*s5*s6**4 - 242100*s1*s2*s5**3*s6**3 - 972*s1*s3**6*s5*s6**2 - 351*s1*s3**5*s4*s5**2*s6 +- 99*s1*s3**5*s5**4 + 441*s1*s3**4*s4**3*s5*s6 + 141*s1*s3**4*s4**2*s5**3 - 36936*s1*s3**4*s5*s6**3 +- 84*s1*s3**3*s4**5*s6 - 76*s1*s3**3*s4**4*s5**2 + 17496*s1*s3**3*s4**2*s6**3 + 11718*s1*s3**3*s4*s5**2*s6**2 +- 6525*s1*s3**3*s5**4*s6 + 12*s1*s3**2*s4**6*s5 + 11016*s1*s3**2*s4**3*s5*s6**2 + +5895*s1*s3**2*s4**2*s5**3*s6 - 1750*s1*s3**2*s4*s5**5 - 252720*s1*s3**2*s5*s6**4 - +2544*s1*s3*s4**5*s6**2 - 8092*s1*s3*s4**4*s5**2*s6 + 2300*s1*s3*s4**3*s5**4 + 536544*s1*s3*s4**2*s6**4 ++ 169560*s1*s3*s4*s5**2*s6**3 - 103500*s1*s3*s5**4*s6**2 + 1680*s1*s4**6*s5*s6 - 468*s1*s4**5*s5**3 +- 346896*s1*s4**3*s5*s6**3 + 93900*s1*s4**2*s5**3*s6**2 + 35000*s1*s4*s5**5*s6 - 9375*s1*s5**7 ++ 108864*s1*s5*s6**5 + 16*s2**8*s4**2*s6**2 - 8*s2**8*s4*s5**2*s6 + s2**8*s5**4 - +8*s2**7*s3**2*s4*s6**2 + 2*s2**7*s3**2*s5**2*s6 - 96*s2**7*s4*s6**3 - 232*s2**7*s5**2*s6**2 ++ s2**6*s3**4*s6**2 + 24*s2**6*s3**2*s6**3 + 336*s2**6*s3*s4*s5*s6**2 + 108*s2**6*s3*s5**3*s6 +- 32*s2**6*s4**3*s6**2 - 160*s2**6*s4**2*s5**2*s6 + 38*s2**6*s4*s5**4 + 144*s2**6*s6**4 +- 84*s2**5*s3**3*s5*s6**2 + 8*s2**5*s3**2*s4**2*s6**2 - 106*s2**5*s3**2*s4*s5**2*s6 +- 12*s2**5*s3**2*s5**4 + 176*s2**5*s3*s4**3*s5*s6 - 36*s2**5*s3*s4**2*s5**3 - 2544*s2**5*s3*s5*s6**3 +- 32*s2**5*s4**5*s6 + 8*s2**5*s4**4*s5**2 - 3072*s2**5*s4**2*s6**3 + 3032*s2**5*s4*s5**2*s6**2 ++ 954*s2**5*s5**4*s6 + 36*s2**4*s3**4*s5**2*s6 - 80*s2**4*s3**3*s4**2*s5*s6 + 25*s2**4*s3**3*s4*s5**3 ++ 16*s2**4*s3**2*s4**4*s6 - 6*s2**4*s3**2*s4**3*s5**2 + 2520*s2**4*s3**2*s4*s6**3 ++ 222*s2**4*s3**2*s5**2*s6**2 - 1312*s2**4*s3*s4**2*s5*s6**2 - 3616*s2**4*s3*s4*s5**3*s6 +- 125*s2**4*s3*s5**5 + 1296*s2**4*s4**4*s6**2 - 168*s2**4*s4**3*s5**2*s6 + 375*s2**4*s4**2*s5**4 ++ 19296*s2**4*s4*s6**4 + 48408*s2**4*s5**2*s6**3 + 9*s2**3*s3**5*s4*s5*s6 - 4*s2**3*s3**5*s5**3 +- 2*s2**3*s3**4*s4**3*s6 + s2**3*s3**4*s4**2*s5**2 - 432*s2**3*s3**4*s6**3 + 324*s2**3*s3**3*s4*s5*s6**2 ++ 923*s2**3*s3**3*s5**3*s6 - 752*s2**3*s3**2*s4**3*s6**2 + 2262*s2**3*s3**2*s4**2*s5**2*s6 ++ 525*s2**3*s3**2*s4*s5**4 - 9936*s2**3*s3**2*s6**4 - 480*s2**3*s3*s4**4*s5*s6 - 700*s2**3*s3*s4**3*s5**3 +- 68976*s2**3*s3*s4*s5*s6**3 - 11360*s2**3*s3*s5**3*s6**2 - 32*s2**3*s4**6*s6 + 152*s2**3*s4**5*s5**2 ++ 6912*s2**3*s4**3*s6**3 - 7992*s2**3*s4**2*s5**2*s6**2 + 5550*s2**3*s4*s5**4*s6 - +29376*s2**3*s6**5 + 108*s2**2*s3**4*s4**2*s6**2 - 1215*s2**2*s3**4*s4*s5**2*s6 - 150*s2**2*s3**4*s5**4 ++ 336*s2**2*s3**3*s4**3*s5*s6 - 185*s2**2*s3**3*s4**2*s5**3 + 17496*s2**2*s3**3*s5*s6**3 ++ 8*s2**2*s3**2*s4**5*s6 + 370*s2**2*s3**2*s4**4*s5**2 - 864*s2**2*s3**2*s4**2*s6**3 ++ 22572*s2**2*s3**2*s4*s5**2*s6**2 + 225*s2**2*s3**2*s5**4*s6 - 144*s2**2*s3*s4**6*s5 ++ 14784*s2**2*s3*s4**3*s5*s6**2 - 12020*s2**2*s3*s4**2*s5**3*s6 + 625*s2**2*s3*s4*s5**5 ++ 536544*s2**2*s3*s5*s6**4 + 16*s2**2*s4**8 - 3072*s2**2*s4**5*s6**2 + 1096*s2**2*s4**4*s5**2*s6 ++ 250*s2**2*s4**3*s5**4 - 93744*s2**2*s4**2*s6**4 - 249480*s2**2*s4*s5**2*s6**3 + +70125*s2**2*s5**4*s6**2 + 162*s2*s3**6*s5**2*s6 - 54*s2*s3**5*s4**2*s5*s6 + 198*s2*s3**5*s4*s5**3 +- 210*s2*s3**4*s4**3*s5**2 - 3564*s2*s3**4*s5**2*s6**2 + 72*s2*s3**3*s4**5*s5 - 12204*s2*s3**3*s4**2*s5*s6**2 ++ 1935*s2*s3**3*s4*s5**3*s6 - 8*s2*s3**2*s4**7 + 2520*s2*s3**2*s4**4*s6**2 + 1962*s2*s3**2*s4**3*s5**2*s6 +- 125*s2*s3**2*s4**2*s5**4 - 178848*s2*s3**2*s4*s6**4 - 165240*s2*s3**2*s5**2*s6**3 +- 144*s2*s3*s4**5*s5*s6 - 200*s2*s3*s4**4*s5**3 + 139104*s2*s3*s4**2*s5*s6**3 + 72900*s2*s3*s4*s5**3*s6**2 +- 20625*s2*s3*s5**5*s6 - 96*s2*s4**7*s6 + 56*s2*s4**6*s5**2 + 19296*s2*s4**4*s6**3 +- 22080*s2*s4**3*s5**2*s6**2 - 7750*s2*s4**2*s5**4*s6 + 3125*s2*s4*s5**6 + 248832*s2*s4*s6**5 +- 129600*s2*s5**2*s6**4 - 27*s3**7*s5**3 + 27*s3**6*s4**2*s5**2 - 9*s3**5*s4**4*s5 ++ 1944*s3**5*s4*s5*s6**2 + 54*s3**5*s5**3*s6 + s3**4*s4**6 - 432*s3**4*s4**3*s6**2 +- 486*s3**4*s4**2*s5**2*s6 + 46656*s3**4*s6**4 + 36*s3**3*s4**4*s5*s6 + 50*s3**3*s4**3*s5**3 +- 7776*s3**3*s4*s5*s6**3 + 29700*s3**3*s5**3*s6**2 + 24*s3**2*s4**6*s6 - 14*s3**2*s4**5*s5**2 +- 9936*s3**2*s4**3*s6**3 - 29160*s3**2*s4**2*s5**2*s6**2 - 10125*s3**2*s4*s5**4*s6 ++ 3125*s3**2*s5**6 + 1026432*s3**2*s6**5 + 6336*s3*s4**4*s5*s6**2 + 11700*s3*s4**3*s5**3*s6 +- 3125*s3*s4**2*s5**5 - 1477440*s3*s4*s5*s6**4 + 432000*s3*s5**3*s6**3 + 144*s4**6*s6**2 +- 2472*s4**5*s5**2*s6 + 625*s4**4*s5**4 - 29376*s4**3*s6**4 + 529200*s4**2*s5**2*s6**3 +- 292500*s4*s5**4*s6**2 + 40625*s5**6*s6 - 186624*s6**6) + ], + (6, 2): [ + lambda s1, s2, s3, s4, s5, s6: (-s3), + lambda s1, s2, s3, s4, s5, s6: (-s1*s5 + s2*s4 - 9*s6), + lambda s1, s2, s3, s4, s5, s6: (s1*s2*s6 + 2*s1*s3*s5 - s1*s4**2 - s2**2*s5 + 6*s3*s6 + s4*s5), + lambda s1, s2, s3, s4, s5, s6: (s1**2*s4*s6 - s1**2*s5**2 - 3*s1*s2*s3*s6 + s1*s2*s4*s5 + 9*s1*s5*s6 + s2**3*s6 - +9*s2*s4*s6 + s2*s5**2 + 3*s3**2*s6 - 3*s3*s4*s5 + s4**3 + 27*s6**2), + lambda s1, s2, s3, s4, s5, s6: (-2*s1**3*s6**2 + 2*s1**2*s2*s5*s6 + 2*s1**2*s3*s4*s6 - s1**2*s3*s5**2 - s1*s2**2*s4*s6 +- 3*s1*s2*s6**2 - 16*s1*s3*s5*s6 + 4*s1*s4**2*s6 + 2*s1*s4*s5**2 + 4*s2**2*s5*s6 + +s2*s3*s4*s6 + 2*s2*s3*s5**2 - s2*s4**2*s5 - 9*s3*s6**2 - 3*s4*s5*s6 - 2*s5**3), + lambda s1, s2, s3, s4, s5, s6: (s1**3*s3*s6**2 - 3*s1**3*s4*s5*s6 + s1**3*s5**3 - s1**2*s2**2*s6**2 + s1**2*s2*s3*s5*s6 +- 2*s1**2*s4*s6**2 + 6*s1**2*s5**2*s6 + 16*s1*s2*s3*s6**2 - 3*s1*s2*s5**3 - s1*s3**2*s5*s6 +- 2*s1*s3*s4**2*s6 + s1*s3*s4*s5**2 - 30*s1*s5*s6**2 - 4*s2**3*s6**2 - 2*s2**2*s3*s5*s6 ++ s2**2*s4**2*s6 + 18*s2*s4*s6**2 - 2*s2*s5**2*s6 - 15*s3**2*s6**2 + 16*s3*s4*s5*s6 ++ s3*s5**3 - 4*s4**3*s6 - s4**2*s5**2 - 27*s6**3), + lambda s1, s2, s3, s4, s5, s6: (s1**4*s5*s6**2 + 2*s1**3*s2*s4*s6**2 - s1**3*s2*s5**2*s6 - s1**3*s3**2*s6**2 + 9*s1**3*s6**3 +- 14*s1**2*s2*s5*s6**2 - 11*s1**2*s3*s4*s6**2 + 6*s1**2*s3*s5**2*s6 + 3*s1**2*s4**2*s5*s6 +- s1**2*s4*s5**3 + 3*s1*s2**2*s5**2*s6 + 3*s1*s2*s3**2*s6**2 - s1*s2*s3*s4*s5*s6 + +39*s1*s3*s5*s6**2 - 14*s1*s4*s5**2*s6 + s1*s5**4 - 11*s2*s3*s5**2*s6 + 2*s2*s4*s5**3 +- 3*s3**3*s6**2 + 3*s3**2*s4*s5*s6 - s3**2*s5**3 + 9*s5**3*s6), + lambda s1, s2, s3, s4, s5, s6: (-s1**4*s2*s6**3 + s1**4*s3*s5*s6**2 - 4*s1**3*s3*s6**3 + 10*s1**3*s4*s5*s6**2 - 4*s1**3*s5**3*s6 ++ 8*s1**2*s2**2*s6**3 - 8*s1**2*s2*s3*s5*s6**2 - 2*s1**2*s2*s4**2*s6**2 + s1**2*s2*s4*s5**2*s6 ++ s1**2*s3**2*s4*s6**2 - 6*s1**2*s4*s6**3 - 7*s1**2*s5**2*s6**2 - 24*s1*s2*s3*s6**3 +- 4*s1*s2*s4*s5*s6**2 + 10*s1*s2*s5**3*s6 + 8*s1*s3**2*s5*s6**2 + 8*s1*s3*s4**2*s6**2 +- 8*s1*s3*s4*s5**2*s6 + s1*s3*s5**4 + 36*s1*s5*s6**3 + 8*s2**2*s3*s5*s6**2 - 2*s2**2*s4*s5**2*s6 +- 2*s2*s3**2*s4*s6**2 + s2*s3**2*s5**2*s6 - 6*s2*s5**2*s6**2 + 18*s3**2*s6**3 - 24*s3*s4*s5*s6**2 +- 4*s3*s5**3*s6 + 8*s4**2*s5**2*s6 - s4*s5**4), + lambda s1, s2, s3, s4, s5, s6: (-s1**5*s4*s6**3 - 2*s1**4*s5*s6**3 + 3*s1**3*s2*s5**2*s6**2 + 3*s1**3*s3**2*s6**3 +- s1**3*s3*s4*s5*s6**2 - 8*s1**3*s6**4 + 16*s1**2*s2*s5*s6**3 + 8*s1**2*s3*s4*s6**3 +- 6*s1**2*s3*s5**2*s6**2 - 8*s1**2*s4**2*s5*s6**2 + 3*s1**2*s4*s5**3*s6 - 8*s1*s2**2*s5**2*s6**2 +- 8*s1*s2*s3**2*s6**3 + 8*s1*s2*s3*s4*s5*s6**2 - s1*s2*s3*s5**3*s6 - s1*s3**3*s5*s6**2 +- 24*s1*s3*s5*s6**3 + 16*s1*s4*s5**2*s6**2 - 2*s1*s5**4*s6 + 8*s2*s3*s5**2*s6**2 - +s2*s5**5 + 8*s3**3*s6**3 - 8*s3**2*s4*s5*s6**2 + 3*s3**2*s5**3*s6 - 8*s5**3*s6**2), + lambda s1, s2, s3, s4, s5, s6: (s1**6*s6**4 - 4*s1**4*s2*s6**4 - 2*s1**4*s3*s5*s6**3 + s1**4*s4**2*s6**3 + 8*s1**3*s3*s6**4 +- 4*s1**3*s4*s5*s6**3 + 2*s1**3*s5**3*s6**2 + 8*s1**2*s2*s3*s5*s6**3 - 2*s1**2*s2*s4*s5**2*s6**2 +- 2*s1**2*s3**2*s4*s6**3 + s1**2*s3**2*s5**2*s6**2 - 4*s1*s2*s5**3*s6**2 - 12*s1*s3**2*s5*s6**3 ++ 8*s1*s3*s4*s5**2*s6**2 - 2*s1*s3*s5**4*s6 + s2**2*s5**4*s6 - 2*s2*s3**2*s5**2*s6**2 ++ s3**4*s6**3 + 8*s3*s5**3*s6**2 - 4*s4*s5**4*s6 + s5**6) + ], +} diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/subfield.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/subfield.py new file mode 100644 index 0000000000000000000000000000000000000000..c56d0662e4a38b4c0fcaa385c2e0166490354790 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/subfield.py @@ -0,0 +1,516 @@ +r""" +Functions in ``polys.numberfields.subfield`` solve the "Subfield Problem" and +allied problems, for algebraic number fields. + +Following Cohen (see [Cohen93]_ Section 4.5), we can define the main problem as +follows: + +* **Subfield Problem:** + + Given two number fields $\mathbb{Q}(\alpha)$, $\mathbb{Q}(\beta)$ + via the minimal polynomials for their generators $\alpha$ and $\beta$, decide + whether one field is isomorphic to a subfield of the other. + +From a solution to this problem flow solutions to the following problems as +well: + +* **Primitive Element Problem:** + + Given several algebraic numbers + $\alpha_1, \ldots, \alpha_m$, compute a single algebraic number $\theta$ + such that $\mathbb{Q}(\alpha_1, \ldots, \alpha_m) = \mathbb{Q}(\theta)$. + +* **Field Isomorphism Problem:** + + Decide whether two number fields + $\mathbb{Q}(\alpha)$, $\mathbb{Q}(\beta)$ are isomorphic. + +* **Field Membership Problem:** + + Given two algebraic numbers $\alpha$, + $\beta$, decide whether $\alpha \in \mathbb{Q}(\beta)$, and if so write + $\alpha = f(\beta)$ for some $f(x) \in \mathbb{Q}[x]$. +""" + +from sympy.core.add import Add +from sympy.core.numbers import AlgebraicNumber +from sympy.core.singleton import S +from sympy.core.symbol import Dummy +from sympy.core.sympify import sympify, _sympify +from sympy.ntheory import sieve +from sympy.polys.densetools import dup_eval +from sympy.polys.domains import QQ +from sympy.polys.numberfields.minpoly import _choose_factor, minimal_polynomial +from sympy.polys.polyerrors import IsomorphismFailed +from sympy.polys.polytools import Poly, PurePoly, factor_list +from sympy.utilities import public + +from mpmath import MPContext + + +def is_isomorphism_possible(a, b): + """Necessary but not sufficient test for isomorphism. """ + n = a.minpoly.degree() + m = b.minpoly.degree() + + if m % n != 0: + return False + + if n == m: + return True + + da = a.minpoly.discriminant() + db = b.minpoly.discriminant() + + i, k, half = 1, m//n, db//2 + + while True: + p = sieve[i] + P = p**k + + if P > half: + break + + if ((da % p) % 2) and not (db % P): + return False + + i += 1 + + return True + + +def field_isomorphism_pslq(a, b): + """Construct field isomorphism using PSLQ algorithm. """ + if not a.root.is_real or not b.root.is_real: + raise NotImplementedError("PSLQ doesn't support complex coefficients") + + f = a.minpoly + g = b.minpoly.replace(f.gen) + + n, m, prev = 100, b.minpoly.degree(), None + ctx = MPContext() + + for i in range(1, 5): + A = a.root.evalf(n) + B = b.root.evalf(n) + + basis = [1, B] + [ B**i for i in range(2, m) ] + [-A] + + ctx.dps = n + coeffs = ctx.pslq(basis, maxcoeff=10**10, maxsteps=1000) + + if coeffs is None: + # PSLQ can't find an integer linear combination. Give up. + break + + if coeffs != prev: + prev = coeffs + else: + # Increasing precision didn't produce anything new. Give up. + break + + # We have + # c0 + c1*B + c2*B^2 + ... + cm-1*B^(m-1) - cm*A ~ 0. + # So bring cm*A to the other side, and divide through by cm, + # for an approximate representation of A as a polynomial in B. + # (We know cm != 0 since `b.minpoly` is irreducible.) + coeffs = [S(c)/coeffs[-1] for c in coeffs[:-1]] + + # Throw away leading zeros. + while not coeffs[-1]: + coeffs.pop() + + coeffs = list(reversed(coeffs)) + h = Poly(coeffs, f.gen, domain='QQ') + + # We only have A ~ h(B). We must check whether the relation is exact. + if f.compose(h).rem(g).is_zero: + # Now we know that h(b) is in fact equal to _some conjugate of_ a. + # But from the very precise approximation A ~ h(B) we can assume + # the conjugate is a itself. + return coeffs + else: + n *= 2 + + return None + + +def field_isomorphism_factor(a, b): + """Construct field isomorphism via factorization. """ + _, factors = factor_list(a.minpoly, extension=b) + for f, _ in factors: + if f.degree() == 1: + # Any linear factor f(x) represents some conjugate of a in QQ(b). + # We want to know whether this linear factor represents a itself. + # Let f = x - c + c = -f.rep.TC() + # Write c as polynomial in b + coeffs = c.to_sympy_list() + d, terms = len(coeffs) - 1, [] + for i, coeff in enumerate(coeffs): + terms.append(coeff*b.root**(d - i)) + r = Add(*terms) + # Check whether we got the number a + if a.minpoly.same_root(r, a): + return coeffs + + # If none of the linear factors represented a in QQ(b), then in fact a is + # not an element of QQ(b). + return None + + +@public +def field_isomorphism(a, b, *, fast=True): + r""" + Find an embedding of one number field into another. + + Explanation + =========== + + This function looks for an isomorphism from $\mathbb{Q}(a)$ onto some + subfield of $\mathbb{Q}(b)$. Thus, it solves the Subfield Problem. + + Examples + ======== + + >>> from sympy import sqrt, field_isomorphism, I + >>> print(field_isomorphism(3, sqrt(2))) # doctest: +SKIP + [3] + >>> print(field_isomorphism( I*sqrt(3), I*sqrt(3)/2)) # doctest: +SKIP + [2, 0] + + Parameters + ========== + + a : :py:class:`~.Expr` + Any expression representing an algebraic number. + b : :py:class:`~.Expr` + Any expression representing an algebraic number. + fast : boolean, optional (default=True) + If ``True``, we first attempt a potentially faster way of computing the + isomorphism, falling back on a slower method if this fails. If + ``False``, we go directly to the slower method, which is guaranteed to + return a result. + + Returns + ======= + + List of rational numbers, or None + If $\mathbb{Q}(a)$ is not isomorphic to some subfield of + $\mathbb{Q}(b)$, then return ``None``. Otherwise, return a list of + rational numbers representing an element of $\mathbb{Q}(b)$ to which + $a$ may be mapped, in order to define a monomorphism, i.e. an + isomorphism from $\mathbb{Q}(a)$ to some subfield of $\mathbb{Q}(b)$. + The elements of the list are the coefficients of falling powers of $b$. + + """ + a, b = sympify(a), sympify(b) + + if not a.is_AlgebraicNumber: + a = AlgebraicNumber(a) + + if not b.is_AlgebraicNumber: + b = AlgebraicNumber(b) + + a = a.to_primitive_element() + b = b.to_primitive_element() + + if a == b: + return a.coeffs() + + n = a.minpoly.degree() + m = b.minpoly.degree() + + if n == 1: + return [a.root] + + if m % n != 0: + return None + + if fast: + try: + result = field_isomorphism_pslq(a, b) + + if result is not None: + return result + except NotImplementedError: + pass + + return field_isomorphism_factor(a, b) + + +def _switch_domain(g, K): + # An algebraic relation f(a, b) = 0 over Q can also be written + # g(b) = 0 where g is in Q(a)[x] and h(a) = 0 where h is in Q(b)[x]. + # This function transforms g into h where Q(b) = K. + frep = g.rep.inject() + hrep = frep.eject(K, front=True) + + return g.new(hrep, g.gens[0]) + + +def _linsolve(p): + # Compute root of linear polynomial. + c, d = p.rep.to_list() + return -d/c + + +@public +def primitive_element(extension, x=None, *, ex=False, polys=False): + r""" + Find a single generator for a number field given by several generators. + + Explanation + =========== + + The basic problem is this: Given several algebraic numbers + $\alpha_1, \alpha_2, \ldots, \alpha_n$, find a single algebraic number + $\theta$ such that + $\mathbb{Q}(\alpha_1, \alpha_2, \ldots, \alpha_n) = \mathbb{Q}(\theta)$. + + This function actually guarantees that $\theta$ will be a linear + combination of the $\alpha_i$, with non-negative integer coefficients. + + Furthermore, if desired, this function will tell you how to express each + $\alpha_i$ as a $\mathbb{Q}$-linear combination of the powers of $\theta$. + + Examples + ======== + + >>> from sympy import primitive_element, sqrt, S, minpoly, simplify + >>> from sympy.abc import x + >>> f, lincomb, reps = primitive_element([sqrt(2), sqrt(3)], x, ex=True) + + Then ``lincomb`` tells us the primitive element as a linear combination of + the given generators ``sqrt(2)`` and ``sqrt(3)``. + + >>> print(lincomb) + [1, 1] + + This means the primtiive element is $\sqrt{2} + \sqrt{3}$. + Meanwhile ``f`` is the minimal polynomial for this primitive element. + + >>> print(f) + x**4 - 10*x**2 + 1 + >>> print(minpoly(sqrt(2) + sqrt(3), x)) + x**4 - 10*x**2 + 1 + + Finally, ``reps`` (which was returned only because we set keyword arg + ``ex=True``) tells us how to recover each of the generators $\sqrt{2}$ and + $\sqrt{3}$ as $\mathbb{Q}$-linear combinations of the powers of the + primitive element $\sqrt{2} + \sqrt{3}$. + + >>> print([S(r) for r in reps[0]]) + [1/2, 0, -9/2, 0] + >>> theta = sqrt(2) + sqrt(3) + >>> print(simplify(theta**3/2 - 9*theta/2)) + sqrt(2) + >>> print([S(r) for r in reps[1]]) + [-1/2, 0, 11/2, 0] + >>> print(simplify(-theta**3/2 + 11*theta/2)) + sqrt(3) + + Parameters + ========== + + extension : list of :py:class:`~.Expr` + Each expression must represent an algebraic number $\alpha_i$. + x : :py:class:`~.Symbol`, optional (default=None) + The desired symbol to appear in the computed minimal polynomial for the + primitive element $\theta$. If ``None``, we use a dummy symbol. + ex : boolean, optional (default=False) + If and only if ``True``, compute the representation of each $\alpha_i$ + as a $\mathbb{Q}$-linear combination over the powers of $\theta$. + polys : boolean, optional (default=False) + If ``True``, return the minimal polynomial as a :py:class:`~.Poly`. + Otherwise return it as an :py:class:`~.Expr`. + + Returns + ======= + + Pair (f, coeffs) or triple (f, coeffs, reps), where: + ``f`` is the minimal polynomial for the primitive element. + ``coeffs`` gives the primitive element as a linear combination of the + given generators. + ``reps`` is present if and only if argument ``ex=True`` was passed, + and is a list of lists of rational numbers. Each list gives the + coefficients of falling powers of the primitive element, to recover + one of the original, given generators. + + """ + if not extension: + raise ValueError("Cannot compute primitive element for empty extension") + extension = [_sympify(ext) for ext in extension] + + if x is not None: + x, cls = sympify(x), Poly + else: + x, cls = Dummy('x'), PurePoly + + def _canonicalize(f): + _, f = f.primitive() + if f.LC() < 0: + f = -f + return f + + if not ex: + gen, coeffs = extension[0], [1] + g = minimal_polynomial(gen, x, polys=True) + for ext in extension[1:]: + if ext.is_Rational: + coeffs.append(0) + continue + _, factors = factor_list(g, extension=ext) + g = _choose_factor(factors, x, gen) + [s], _, g = g.sqf_norm() + gen += s*ext + coeffs.append(s) + + g = _canonicalize(g) + if not polys: + return g.as_expr(), coeffs + else: + return cls(g), coeffs + + gen, coeffs = extension[0], [1] + f = minimal_polynomial(gen, x, polys=True) + K = QQ.algebraic_field((f, gen)) # incrementally constructed field + reps = [K.unit] # representations of extension elements in K + for ext in extension[1:]: + if ext.is_Rational: + coeffs.append(0) # rational ext is not included in the expression of a primitive element + reps.append(K.convert(ext)) # but it is included in reps + continue + p = minimal_polynomial(ext, x, polys=True) + L = QQ.algebraic_field((p, ext)) + _, factors = factor_list(f, domain=L) + f = _choose_factor(factors, x, gen) + [s], g, f = f.sqf_norm() + gen += s*ext + coeffs.append(s) + K = QQ.algebraic_field((f, gen)) + h = _switch_domain(g, K) + erep = _linsolve(h.gcd(p)) # ext as element of K + ogen = K.unit - s*erep # old gen as element of K + reps = [dup_eval(_.to_list(), ogen, K) for _ in reps] + [erep] + + if K.ext.root.is_Rational: # all extensions are rational + H = [K.convert(_).rep for _ in extension] + coeffs = [0]*len(extension) + f = cls(x, domain=QQ) + else: + H = [_.to_list() for _ in reps] + + f = _canonicalize(f) + if not polys: + return f.as_expr(), coeffs, H + else: + return f, coeffs, H + + +@public +def to_number_field(extension, theta=None, *, gen=None, alias=None): + r""" + Express one algebraic number in the field generated by another. + + Explanation + =========== + + Given two algebraic numbers $\eta, \theta$, this function either expresses + $\eta$ as an element of $\mathbb{Q}(\theta)$, or else raises an exception + if $\eta \not\in \mathbb{Q}(\theta)$. + + This function is essentially just a convenience, utilizing + :py:func:`~.field_isomorphism` (our solution of the Subfield Problem) to + solve this, the Field Membership Problem. + + As an additional convenience, this function allows you to pass a list of + algebraic numbers $\alpha_1, \alpha_2, \ldots, \alpha_n$ instead of $\eta$. + It then computes $\eta$ for you, as a solution of the Primitive Element + Problem, using :py:func:`~.primitive_element` on the list of $\alpha_i$. + + Examples + ======== + + >>> from sympy import sqrt, to_number_field + >>> eta = sqrt(2) + >>> theta = sqrt(2) + sqrt(3) + >>> a = to_number_field(eta, theta) + >>> print(type(a)) + + >>> a.root + sqrt(2) + sqrt(3) + >>> print(a) + sqrt(2) + >>> a.coeffs() + [1/2, 0, -9/2, 0] + + We get an :py:class:`~.AlgebraicNumber`, whose ``.root`` is $\theta$, whose + value is $\eta$, and whose ``.coeffs()`` show how to write $\eta$ as a + $\mathbb{Q}$-linear combination in falling powers of $\theta$. + + Parameters + ========== + + extension : :py:class:`~.Expr` or list of :py:class:`~.Expr` + Either the algebraic number that is to be expressed in the other field, + or else a list of algebraic numbers, a primitive element for which is + to be expressed in the other field. + theta : :py:class:`~.Expr`, None, optional (default=None) + If an :py:class:`~.Expr` representing an algebraic number, behavior is + as described under **Explanation**. If ``None``, then this function + reduces to a shorthand for calling :py:func:`~.primitive_element` on + ``extension`` and turning the computed primitive element into an + :py:class:`~.AlgebraicNumber`. + gen : :py:class:`~.Symbol`, None, optional (default=None) + If provided, this will be used as the generator symbol for the minimal + polynomial in the returned :py:class:`~.AlgebraicNumber`. + alias : str, :py:class:`~.Symbol`, None, optional (default=None) + If provided, this will be used as the alias symbol for the returned + :py:class:`~.AlgebraicNumber`. + + Returns + ======= + + AlgebraicNumber + Belonging to $\mathbb{Q}(\theta)$ and equaling $\eta$. + + Raises + ====== + + IsomorphismFailed + If $\eta \not\in \mathbb{Q}(\theta)$. + + See Also + ======== + + field_isomorphism + primitive_element + + """ + if hasattr(extension, '__iter__'): + extension = list(extension) + else: + extension = [extension] + + if len(extension) == 1 and isinstance(extension[0], tuple): + return AlgebraicNumber(extension[0], alias=alias) + + minpoly, coeffs = primitive_element(extension, gen, polys=True) + root = sum(coeff*ext for coeff, ext in zip(coeffs, extension)) + + if theta is None: + return AlgebraicNumber((minpoly, root), alias=alias) + else: + theta = sympify(theta) + + if not theta.is_AlgebraicNumber: + theta = AlgebraicNumber(theta, gen=gen, alias=alias) + + coeffs = field_isomorphism(root, theta) + + if coeffs is not None: + return AlgebraicNumber(theta, coeffs, alias=alias) + else: + raise IsomorphismFailed( + "%s is not in a subfield of %s" % (root, theta.root)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_basis.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_basis.py new file mode 100644 index 0000000000000000000000000000000000000000..c0ed017936cc5c24da63ac02ceca0480f1945feb --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_basis.py @@ -0,0 +1,85 @@ +from sympy.abc import x +from sympy.core import S +from sympy.core.numbers import AlgebraicNumber +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.polys import Poly, cyclotomic_poly +from sympy.polys.domains import QQ +from sympy.polys.matrices import DomainMatrix, DM +from sympy.polys.numberfields.basis import round_two +from sympy.testing.pytest import raises + + +def test_round_two(): + # Poly must be irreducible, and over ZZ or QQ: + raises(ValueError, lambda: round_two(Poly(x ** 2 - 1))) + raises(ValueError, lambda: round_two(Poly(x ** 2 + sqrt(2)))) + + # Test on many fields: + cases = ( + # A couple of cyclotomic fields: + (cyclotomic_poly(5), DomainMatrix.eye(4, QQ), 125), + (cyclotomic_poly(7), DomainMatrix.eye(6, QQ), -16807), + # A couple of quadratic fields (one 1 mod 4, one 3 mod 4): + (x ** 2 - 5, DM([[1, (1, 2)], [0, (1, 2)]], QQ), 5), + (x ** 2 - 7, DM([[1, 0], [0, 1]], QQ), 28), + # Dedekind's example of a field with 2 as essential disc divisor: + (x ** 3 + x ** 2 - 2 * x + 8, DM([[1, 0, 0], [0, 1, 0], [0, (1, 2), (1, 2)]], QQ).transpose(), -503), + # A bunch of cubics with various forms for F -- all of these require + # second or third enlargements. (Five of them require a third, while the rest require just a second.) + # F = 2^2 + (x**3 + 3 * x**2 - 4 * x + 4, DM([((1, 2), (1, 4), (1, 4)), (0, (1, 2), (1, 2)), (0, 0, 1)], QQ).transpose(), -83), + # F = 2^2 * 3 + (x**3 + 3 * x**2 + 3 * x - 3, DM([((1, 2), 0, (1, 2)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), -108), + # F = 2^3 + (x**3 + 5 * x**2 - x + 3, DM([((1, 4), 0, (3, 4)), (0, (1, 2), (1, 2)), (0, 0, 1)], QQ).transpose(), -31), + # F = 2^2 * 5 + (x**3 + 5 * x**2 - 5 * x - 5, DM([((1, 2), 0, (1, 2)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), 1300), + # F = 3^2 + (x**3 + 3 * x**2 + 5, DM([((1, 3), (1, 3), (1, 3)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), -135), + # F = 3^3 + (x**3 + 6 * x**2 + 3 * x - 1, DM([((1, 3), (1, 3), (1, 3)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), 81), + # F = 2^2 * 3^2 + (x**3 + 6 * x**2 + 4, DM([((1, 3), (2, 3), (1, 3)), (0, 1, 0), (0, 0, (1, 2))], QQ).transpose(), -108), + # F = 2^3 * 7 + (x**3 + 7 * x**2 + 7 * x - 7, DM([((1, 4), 0, (3, 4)), (0, (1, 2), (1, 2)), (0, 0, 1)], QQ).transpose(), 49), + # F = 2^2 * 13 + (x**3 + 7 * x**2 - x + 5, DM([((1, 2), 0, (1, 2)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), -2028), + # F = 2^4 + (x**3 + 7 * x**2 - 5 * x + 5, DM([((1, 4), 0, (3, 4)), (0, (1, 2), (1, 2)), (0, 0, 1)], QQ).transpose(), -140), + # F = 5^2 + (x**3 + 4 * x**2 - 3 * x + 7, DM([((1, 5), (4, 5), (4, 5)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), -175), + # F = 7^2 + (x**3 + 8 * x**2 + 5 * x - 1, DM([((1, 7), (6, 7), (2, 7)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), 49), + # F = 2 * 5 * 7 + (x**3 + 8 * x**2 - 2 * x + 6, DM([(1, 0, 0), (0, 1, 0), (0, 0, 1)], QQ).transpose(), -14700), + # F = 2^2 * 3 * 5 + (x**3 + 6 * x**2 - 3 * x + 8, DM([(1, 0, 0), (0, (1, 4), (1, 4)), (0, 0, 1)], QQ).transpose(), -675), + # F = 2 * 3^2 * 7 + (x**3 + 9 * x**2 + 6 * x - 8, DM([(1, 0, 0), (0, (1, 2), (1, 2)), (0, 0, 1)], QQ).transpose(), 3969), + # F = 2^2 * 3^2 * 7 + (x**3 + 15 * x**2 - 9 * x + 13, DM([((1, 6), (1, 3), (1, 6)), (0, 1, 0), (0, 0, 1)], QQ).transpose(), -5292), + # Polynomial need not be monic + (5*x**3 + 5*x**2 - 10 * x + 40, DM([[1, 0, 0], [0, 1, 0], [0, (1, 2), (1, 2)]], QQ).transpose(), -503), + # Polynomial can have non-integer rational coeffs + (QQ(5, 3)*x**3 + QQ(5, 3)*x**2 - QQ(10, 3)*x + QQ(40, 3), DM([[1, 0, 0], [0, 1, 0], [0, (1, 2), (1, 2)]], QQ).transpose(), -503), + ) + for f, B_exp, d_exp in cases: + K = QQ.alg_field_from_poly(f) + B = K.maximal_order().QQ_matrix + d = K.discriminant() + assert d == d_exp + # The computed basis need not equal the expected one, but their quotient + # must be unimodular: + assert (B.inv()*B_exp).det()**2 == 1 + + +def test_AlgebraicField_integral_basis(): + alpha = AlgebraicNumber(sqrt(5), alias='alpha') + k = QQ.algebraic_field(alpha) + B0 = k.integral_basis() + B1 = k.integral_basis(fmt='sympy') + B2 = k.integral_basis(fmt='alg') + assert B0 == [k([1]), k([S.Half, S.Half])] + assert B1 == [1, S.Half + alpha/2] + assert B2 == [k.ext.field_element([1]), + k.ext.field_element([S.Half, S.Half])] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_galoisgroups.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_galoisgroups.py new file mode 100644 index 0000000000000000000000000000000000000000..e4cb3d51bcdfad7764b3f6f62dbd2049e466e9e1 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_galoisgroups.py @@ -0,0 +1,143 @@ +"""Tests for computing Galois groups. """ + +from sympy.abc import x +from sympy.combinatorics.galois import ( + S1TransitiveSubgroups, S2TransitiveSubgroups, S3TransitiveSubgroups, + S4TransitiveSubgroups, S5TransitiveSubgroups, S6TransitiveSubgroups, +) +from sympy.polys.domains.rationalfield import QQ +from sympy.polys.numberfields.galoisgroups import ( + tschirnhausen_transformation, + galois_group, + _galois_group_degree_4_root_approx, + _galois_group_degree_5_hybrid, +) +from sympy.polys.numberfields.subfield import field_isomorphism +from sympy.polys.polytools import Poly +from sympy.testing.pytest import raises + + +def test_tschirnhausen_transformation(): + for T in [ + Poly(x**2 - 2), + Poly(x**2 + x + 1), + Poly(x**4 + 1), + Poly(x**4 - x**3 + x**2 - x + 1), + ]: + _, U = tschirnhausen_transformation(T) + assert U.degree() == T.degree() + assert U.is_monic + assert U.is_irreducible + K = QQ.alg_field_from_poly(T) + L = QQ.alg_field_from_poly(U) + assert field_isomorphism(K.ext, L.ext) is not None + + +# Test polys are from: +# Cohen, H. *A Course in Computational Algebraic Number Theory*. +test_polys_by_deg = { + # Degree 1 + 1: [ + (x, S1TransitiveSubgroups.S1, True) + ], + # Degree 2 + 2: [ + (x**2 + x + 1, S2TransitiveSubgroups.S2, False) + ], + # Degree 3 + 3: [ + (x**3 + x**2 - 2*x - 1, S3TransitiveSubgroups.A3, True), + (x**3 + 2, S3TransitiveSubgroups.S3, False), + ], + # Degree 4 + 4: [ + (x**4 + x**3 + x**2 + x + 1, S4TransitiveSubgroups.C4, False), + (x**4 + 1, S4TransitiveSubgroups.V, True), + (x**4 - 2, S4TransitiveSubgroups.D4, False), + (x**4 + 8*x + 12, S4TransitiveSubgroups.A4, True), + (x**4 + x + 1, S4TransitiveSubgroups.S4, False), + ], + # Degree 5 + 5: [ + (x**5 + x**4 - 4*x**3 - 3*x**2 + 3*x + 1, S5TransitiveSubgroups.C5, True), + (x**5 - 5*x + 12, S5TransitiveSubgroups.D5, True), + (x**5 + 2, S5TransitiveSubgroups.M20, False), + (x**5 + 20*x + 16, S5TransitiveSubgroups.A5, True), + (x**5 - x + 1, S5TransitiveSubgroups.S5, False), + ], + # Degree 6 + 6: [ + (x**6 + x**5 + x**4 + x**3 + x**2 + x + 1, S6TransitiveSubgroups.C6, False), + (x**6 + 108, S6TransitiveSubgroups.S3, False), + (x**6 + 2, S6TransitiveSubgroups.D6, False), + (x**6 - 3*x**2 - 1, S6TransitiveSubgroups.A4, True), + (x**6 + 3*x**3 + 3, S6TransitiveSubgroups.G18, False), + (x**6 - 3*x**2 + 1, S6TransitiveSubgroups.A4xC2, False), + (x**6 - 4*x**2 - 1, S6TransitiveSubgroups.S4p, True), + (x**6 - 3*x**5 + 6*x**4 - 7*x**3 + 2*x**2 + x - 4, S6TransitiveSubgroups.S4m, False), + (x**6 + 2*x**3 - 2, S6TransitiveSubgroups.G36m, False), + (x**6 + 2*x**2 + 2, S6TransitiveSubgroups.S4xC2, False), + (x**6 + 10*x**5 + 55*x**4 + 140*x**3 + 175*x**2 + 170*x + 25, S6TransitiveSubgroups.PSL2F5, True), + (x**6 + 10*x**5 + 55*x**4 + 140*x**3 + 175*x**2 - 3019*x + 25, S6TransitiveSubgroups.PGL2F5, False), + (x**6 + 6*x**4 + 2*x**3 + 9*x**2 + 6*x - 4, S6TransitiveSubgroups.G36p, True), + (x**6 + 2*x**4 + 2*x**3 + x**2 + 2*x + 2, S6TransitiveSubgroups.G72, False), + (x**6 + 24*x - 20, S6TransitiveSubgroups.A6, True), + (x**6 + x + 1, S6TransitiveSubgroups.S6, False), + ], +} + + +def test_galois_group(): + """ + Try all the test polys. + """ + for deg in range(1, 7): + polys = test_polys_by_deg[deg] + for T, G, alt in polys: + assert galois_group(T, by_name=True) == (G, alt) + + +def test_galois_group_degree_out_of_bounds(): + raises(ValueError, lambda: galois_group(Poly(0, x))) + raises(ValueError, lambda: galois_group(Poly(1, x))) + raises(ValueError, lambda: galois_group(Poly(x ** 7 + 1))) + + +def test_galois_group_not_by_name(): + """ + Check at least one polynomial of each supported degree, to see that + conversion from name to group works. + """ + for deg in range(1, 7): + T, G_name, _ = test_polys_by_deg[deg][0] + G, _ = galois_group(T) + assert G == G_name.get_perm_group() + + +def test_galois_group_not_monic_over_ZZ(): + """ + Check that we can work with polys that are not monic over ZZ. + """ + for deg in range(1, 7): + T, G, alt = test_polys_by_deg[deg][0] + assert galois_group(T/2, by_name=True) == (G, alt) + + +def test__galois_group_degree_4_root_approx(): + for T, G, alt in test_polys_by_deg[4]: + assert _galois_group_degree_4_root_approx(Poly(T)) == (G, alt) + + +def test__galois_group_degree_5_hybrid(): + for T, G, alt in test_polys_by_deg[5]: + assert _galois_group_degree_5_hybrid(Poly(T)) == (G, alt) + + +def test_AlgebraicField_galois_group(): + k = QQ.alg_field_from_poly(Poly(x**4 + 1)) + G, _ = k.galois_group(by_name=True) + assert G == S4TransitiveSubgroups.V + + k = QQ.alg_field_from_poly(Poly(x**4 - 2)) + G, _ = k.galois_group(by_name=True) + assert G == S4TransitiveSubgroups.D4 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_minpoly.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_minpoly.py new file mode 100644 index 0000000000000000000000000000000000000000..792e5ad6e136bb00abda0b0739b2fff4fd41937b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_minpoly.py @@ -0,0 +1,490 @@ +"""Tests for minimal polynomials. """ + +from sympy.core.function import expand +from sympy.core import (GoldenRatio, TribonacciConstant) +from sympy.core.numbers import (AlgebraicNumber, I, Rational, oo, pi) +from sympy.core.power import Pow +from sympy.core.singleton import S +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import (cbrt, sqrt) +from sympy.functions.elementary.trigonometric import (cos, sin, tan) +from sympy.ntheory.generate import nextprime +from sympy.polys.polytools import Poly +from sympy.polys.rootoftools import CRootOf +from sympy.solvers.solveset import nonlinsolve +from sympy.geometry import Circle, intersection +from sympy.testing.pytest import raises, slow +from sympy.sets.sets import FiniteSet +from sympy.geometry.point import Point2D +from sympy.polys.numberfields.minpoly import ( + minimal_polynomial, + _choose_factor, + _minpoly_op_algebraic_element, + _separate_sq, + _minpoly_groebner, +) +from sympy.polys.partfrac import apart +from sympy.polys.polyerrors import ( + NotAlgebraic, + GeneratorsError, +) + +from sympy.polys.domains import QQ +from sympy.polys.rootoftools import rootof +from sympy.polys.polytools import degree + +from sympy.abc import x, y, z + +Q = Rational + + +def test_minimal_polynomial(): + assert minimal_polynomial(-7, x) == x + 7 + assert minimal_polynomial(-1, x) == x + 1 + assert minimal_polynomial( 0, x) == x + assert minimal_polynomial( 1, x) == x - 1 + assert minimal_polynomial( 7, x) == x - 7 + + assert minimal_polynomial(sqrt(2), x) == x**2 - 2 + assert minimal_polynomial(sqrt(5), x) == x**2 - 5 + assert minimal_polynomial(sqrt(6), x) == x**2 - 6 + + assert minimal_polynomial(2*sqrt(2), x) == x**2 - 8 + assert minimal_polynomial(3*sqrt(5), x) == x**2 - 45 + assert minimal_polynomial(4*sqrt(6), x) == x**2 - 96 + + assert minimal_polynomial(2*sqrt(2) + 3, x) == x**2 - 6*x + 1 + assert minimal_polynomial(3*sqrt(5) + 6, x) == x**2 - 12*x - 9 + assert minimal_polynomial(4*sqrt(6) + 7, x) == x**2 - 14*x - 47 + + assert minimal_polynomial(2*sqrt(2) - 3, x) == x**2 + 6*x + 1 + assert minimal_polynomial(3*sqrt(5) - 6, x) == x**2 + 12*x - 9 + assert minimal_polynomial(4*sqrt(6) - 7, x) == x**2 + 14*x - 47 + + assert minimal_polynomial(sqrt(1 + sqrt(6)), x) == x**4 - 2*x**2 - 5 + assert minimal_polynomial(sqrt(I + sqrt(6)), x) == x**8 - 10*x**4 + 49 + + assert minimal_polynomial(2*I + sqrt(2 + I), x) == x**4 + 4*x**2 + 8*x + 37 + + assert minimal_polynomial(sqrt(2) + sqrt(3), x) == x**4 - 10*x**2 + 1 + assert minimal_polynomial( + sqrt(2) + sqrt(3) + sqrt(6), x) == x**4 - 22*x**2 - 48*x - 23 + + a = 1 - 9*sqrt(2) + 7*sqrt(3) + + assert minimal_polynomial( + 1/a, x) == 392*x**4 - 1232*x**3 + 612*x**2 + 4*x - 1 + assert minimal_polynomial( + 1/sqrt(a), x) == 392*x**8 - 1232*x**6 + 612*x**4 + 4*x**2 - 1 + + raises(NotAlgebraic, lambda: minimal_polynomial(oo, x)) + raises(NotAlgebraic, lambda: minimal_polynomial(2**y, x)) + raises(NotAlgebraic, lambda: minimal_polynomial(sin(1), x)) + + assert minimal_polynomial(sqrt(2)).dummy_eq(x**2 - 2) + assert minimal_polynomial(sqrt(2), x) == x**2 - 2 + + assert minimal_polynomial(sqrt(2), polys=True) == Poly(x**2 - 2) + assert minimal_polynomial(sqrt(2), x, polys=True) == Poly(x**2 - 2, domain='QQ') + assert minimal_polynomial(sqrt(2), x, polys=True, compose=False) == Poly(x**2 - 2, domain='QQ') + + a = AlgebraicNumber(sqrt(2)) + b = AlgebraicNumber(sqrt(3)) + + assert minimal_polynomial(a, x) == x**2 - 2 + assert minimal_polynomial(b, x) == x**2 - 3 + + assert minimal_polynomial(a, x, polys=True) == Poly(x**2 - 2, domain='QQ') + assert minimal_polynomial(b, x, polys=True) == Poly(x**2 - 3, domain='QQ') + + assert minimal_polynomial(sqrt(a/2 + 17), x) == 2*x**4 - 68*x**2 + 577 + assert minimal_polynomial(sqrt(b/2 + 17), x) == 4*x**4 - 136*x**2 + 1153 + + a, b = sqrt(2)/3 + 7, AlgebraicNumber(sqrt(2)/3 + 7) + + f = 81*x**8 - 2268*x**6 - 4536*x**5 + 22644*x**4 + 63216*x**3 - \ + 31608*x**2 - 189648*x + 141358 + + assert minimal_polynomial(sqrt(a) + sqrt(sqrt(a)), x) == f + assert minimal_polynomial(sqrt(b) + sqrt(sqrt(b)), x) == f + + assert minimal_polynomial( + a**Q(3, 2), x) == 729*x**4 - 506898*x**2 + 84604519 + + # issue 5994 + eq = S(''' + -1/(800*sqrt(-1/240 + 1/(18000*(-1/17280000 + + sqrt(15)*I/28800000)**(1/3)) + 2*(-1/17280000 + + sqrt(15)*I/28800000)**(1/3)))''') + assert minimal_polynomial(eq, x) == 8000*x**2 - 1 + + ex = (sqrt(5)*sqrt(I)/(5*sqrt(1 + 125*I)) + + 25*sqrt(5)/(I**Q(5,2)*(1 + 125*I)**Q(3,2)) + + 3125*sqrt(5)/(I**Q(11,2)*(1 + 125*I)**Q(3,2)) + + 5*I*sqrt(1 - I/125)) + mp = minimal_polynomial(ex, x) + assert mp == 25*x**4 + 5000*x**2 + 250016 + + ex = 1 + sqrt(2) + sqrt(3) + mp = minimal_polynomial(ex, x) + assert mp == x**4 - 4*x**3 - 4*x**2 + 16*x - 8 + + ex = 1/(1 + sqrt(2) + sqrt(3)) + mp = minimal_polynomial(ex, x) + assert mp == 8*x**4 - 16*x**3 + 4*x**2 + 4*x - 1 + + p = (expand((1 + sqrt(2) - 2*sqrt(3) + sqrt(7))**3))**Rational(1, 3) + mp = minimal_polynomial(p, x) + assert mp == x**8 - 8*x**7 - 56*x**6 + 448*x**5 + 480*x**4 - 5056*x**3 + 1984*x**2 + 7424*x - 3008 + p = expand((1 + sqrt(2) - 2*sqrt(3) + sqrt(7))**3) + mp = minimal_polynomial(p, x) + assert mp == x**8 - 512*x**7 - 118208*x**6 + 31131136*x**5 + 647362560*x**4 - 56026611712*x**3 + 116994310144*x**2 + 404854931456*x - 27216576512 + + assert minimal_polynomial(S("-sqrt(5)/2 - 1/2 + (-sqrt(5)/2 - 1/2)**2"), x) == x - 1 + a = 1 + sqrt(2) + assert minimal_polynomial((a*sqrt(2) + a)**3, x) == x**2 - 198*x + 1 + + p = 1/(1 + sqrt(2) + sqrt(3)) + assert minimal_polynomial(p, x, compose=False) == 8*x**4 - 16*x**3 + 4*x**2 + 4*x - 1 + + p = 2/(1 + sqrt(2) + sqrt(3)) + assert minimal_polynomial(p, x, compose=False) == x**4 - 4*x**3 + 2*x**2 + 4*x - 2 + + assert minimal_polynomial(1 + sqrt(2)*I, x, compose=False) == x**2 - 2*x + 3 + assert minimal_polynomial(1/(1 + sqrt(2)) + 1, x, compose=False) == x**2 - 2 + assert minimal_polynomial(sqrt(2)*I + I*(1 + sqrt(2)), x, + compose=False) == x**4 + 18*x**2 + 49 + + # minimal polynomial of I + assert minimal_polynomial(I, x, domain=QQ.algebraic_field(I)) == x - I + K = QQ.algebraic_field(I*(sqrt(2) + 1)) + assert minimal_polynomial(I, x, domain=K) == x - I + assert minimal_polynomial(I, x, domain=QQ) == x**2 + 1 + assert minimal_polynomial(I, x, domain='QQ(y)') == x**2 + 1 + + #issue 11553 + assert minimal_polynomial(GoldenRatio, x) == x**2 - x - 1 + assert minimal_polynomial(TribonacciConstant + 3, x) == x**3 - 10*x**2 + 32*x - 34 + assert minimal_polynomial(GoldenRatio, x, domain=QQ.algebraic_field(sqrt(5))) == \ + 2*x - sqrt(5) - 1 + assert minimal_polynomial(TribonacciConstant, x, domain=QQ.algebraic_field(cbrt(19 - 3*sqrt(33)))) == \ + 48*x - 19*(19 - 3*sqrt(33))**Rational(2, 3) - 3*sqrt(33)*(19 - 3*sqrt(33))**Rational(2, 3) \ + - 16*(19 - 3*sqrt(33))**Rational(1, 3) - 16 + + # AlgebraicNumber with an alias. + # Wester H24 + phi = AlgebraicNumber(S.GoldenRatio.expand(func=True), alias='phi') + assert minimal_polynomial(phi, x) == x**2 - x - 1 + + +def test_issue_26903(): + p1 = nextprime(10**16) # greater than 10**15 + p2 = nextprime(p1) + assert sqrt(p1**2*p2).is_Pow # square not extracted + zero = sqrt(p1**2*p2) - p1*sqrt(p2) + assert minimal_polynomial(zero, x) == x + assert minimal_polynomial(sqrt(2) - zero, x) == x**2 - 2 + + +def test_issue_8353(): + assert minimal_polynomial(exp(3*I*pi, evaluate=False), x) == x + 1 + assert minimal_polynomial(Pow(8, S(1)/3, evaluate=False), x + ) == x - 2 + + +def test_minimal_polynomial_issue_19732(): + # https://github.com/sympy/sympy/issues/19732 + expr = (-280898097948878450887044002323982963174671632174995451265117559518123750720061943079105185551006003416773064305074191140286225850817291393988597615/(-488144716373031204149459129212782509078221364279079444636386844223983756114492222145074506571622290776245390771587888364089507840000000*sqrt(238368341569)*sqrt(S(11918417078450)/63568729 + - 24411360*sqrt(238368341569)/63568729) + + 238326799225996604451373809274348704114327860564921529846705817404208077866956345381951726531296652901169111729944612727047670549086208000000*sqrt(S(11918417078450)/63568729 + - 24411360*sqrt(238368341569)/63568729)) - + 180561807339168676696180573852937120123827201075968945871075967679148461189459480842956689723484024031016208588658753107/(-59358007109636562851035004992802812513575019937126272896569856090962677491318275291141463850327474176000000*sqrt(238368341569)*sqrt(S(11918417078450)/63568729 + - 24411360*sqrt(238368341569)/63568729) + + 28980348180319251787320809875930301310576055074938369007463004788921613896002936637780993064387310446267596800000*sqrt(S(11918417078450)/63568729 + - 24411360*sqrt(238368341569)/63568729))) + poly = (2151288870990266634727173620565483054187142169311153766675688628985237817262915166497766867289157986631135400926544697981091151416655364879773546003475813114962656742744975460025956167152918469472166170500512008351638710934022160294849059721218824490226159355197136265032810944357335461128949781377875451881300105989490353140886315677977149440000000000000000000000*x**4 + - 5773274155644072033773937864114266313663195672820501581692669271302387257492905909558846459600429795784309388968498783843631580008547382703258503404023153694528041873101120067477617592651525155101107144042679962433039557235772239171616433004024998230222455940044709064078962397144550855715640331680262171410099614469231080995436488414164502751395405398078353242072696360734131090111239998110773292915337556205692674790561090109440000000000000*x**2 + + 211295968822207088328287206509522887719741955693091053353263782924470627623790749534705683380138972642560898936171035770539616881000369889020398551821767092685775598633794696371561234818461806577723412581353857653829324364446419444210520602157621008010129702779407422072249192199762604318993590841636967747488049176548615614290254356975376588506729604345612047361483789518445332415765213187893207704958013682516462853001964919444736320672860140355089) + assert minimal_polynomial(expr, x) == poly + + +def test_minimal_polynomial_hi_prec(): + p = 1/sqrt(1 - 9*sqrt(2) + 7*sqrt(3) + Rational(1, 10)**30) + mp = minimal_polynomial(p, x) + # checked with Wolfram Alpha + assert mp.coeff(x**6) == -1232000000000000000000000000001223999999999999999999999999999987999999999999999999999999999996000000000000000000000000000000 + + +def test_minimal_polynomial_sq(): + from sympy.core.add import Add + from sympy.core.function import expand_multinomial + p = expand_multinomial((1 + 5*sqrt(2) + 2*sqrt(3))**3) + mp = minimal_polynomial(p**Rational(1, 3), x) + assert mp == x**4 - 4*x**3 - 118*x**2 + 244*x + 1321 + p = expand_multinomial((1 + sqrt(2) - 2*sqrt(3) + sqrt(7))**3) + mp = minimal_polynomial(p**Rational(1, 3), x) + assert mp == x**8 - 8*x**7 - 56*x**6 + 448*x**5 + 480*x**4 - 5056*x**3 + 1984*x**2 + 7424*x - 3008 + p = Add(*[sqrt(i) for i in range(1, 12)]) + mp = minimal_polynomial(p, x) + assert mp.subs({x: 0}) == -71965773323122507776 + + +def test_minpoly_compose(): + # issue 6868 + eq = S(''' + -1/(800*sqrt(-1/240 + 1/(18000*(-1/17280000 + + sqrt(15)*I/28800000)**(1/3)) + 2*(-1/17280000 + + sqrt(15)*I/28800000)**(1/3)))''') + mp = minimal_polynomial(eq + 3, x) + assert mp == 8000*x**2 - 48000*x + 71999 + + # issue 5888 + assert minimal_polynomial(exp(I*pi/8), x) == x**8 + 1 + + mp = minimal_polynomial(sin(pi/7) + sqrt(2), x) + assert mp == 4096*x**12 - 63488*x**10 + 351488*x**8 - 826496*x**6 + \ + 770912*x**4 - 268432*x**2 + 28561 + mp = minimal_polynomial(cos(pi/7) + sqrt(2), x) + assert mp == 64*x**6 - 64*x**5 - 432*x**4 + 304*x**3 + 712*x**2 - \ + 232*x - 239 + mp = minimal_polynomial(exp(I*pi/7) + sqrt(2), x) + assert mp == x**12 - 2*x**11 - 9*x**10 + 16*x**9 + 43*x**8 - 70*x**7 - 97*x**6 + 126*x**5 + 211*x**4 - 212*x**3 - 37*x**2 + 142*x + 127 + + mp = minimal_polynomial(sin(pi/7) + sqrt(2), x) + assert mp == 4096*x**12 - 63488*x**10 + 351488*x**8 - 826496*x**6 + \ + 770912*x**4 - 268432*x**2 + 28561 + mp = minimal_polynomial(cos(pi/7) + sqrt(2), x) + assert mp == 64*x**6 - 64*x**5 - 432*x**4 + 304*x**3 + 712*x**2 - \ + 232*x - 239 + mp = minimal_polynomial(exp(I*pi/7) + sqrt(2), x) + assert mp == x**12 - 2*x**11 - 9*x**10 + 16*x**9 + 43*x**8 - 70*x**7 - 97*x**6 + 126*x**5 + 211*x**4 - 212*x**3 - 37*x**2 + 142*x + 127 + + mp = minimal_polynomial(exp(I*pi*Rational(2, 7)), x) + assert mp == x**6 + x**5 + x**4 + x**3 + x**2 + x + 1 + mp = minimal_polynomial(exp(I*pi*Rational(2, 15)), x) + assert mp == x**8 - x**7 + x**5 - x**4 + x**3 - x + 1 + mp = minimal_polynomial(cos(pi*Rational(2, 7)), x) + assert mp == 8*x**3 + 4*x**2 - 4*x - 1 + mp = minimal_polynomial(sin(pi*Rational(2, 7)), x) + ex = (5*cos(pi*Rational(2, 7)) - 7)/(9*cos(pi/7) - 5*cos(pi*Rational(3, 7))) + mp = minimal_polynomial(ex, x) + assert mp == x**3 + 2*x**2 - x - 1 + assert minimal_polynomial(-1/(2*cos(pi/7)), x) == x**3 + 2*x**2 - x - 1 + assert minimal_polynomial(sin(pi*Rational(2, 15)), x) == \ + 256*x**8 - 448*x**6 + 224*x**4 - 32*x**2 + 1 + assert minimal_polynomial(sin(pi*Rational(5, 14)), x) == 8*x**3 - 4*x**2 - 4*x + 1 + assert minimal_polynomial(cos(pi/15), x) == 16*x**4 + 8*x**3 - 16*x**2 - 8*x + 1 + + ex = rootof(x**3 +x*4 + 1, 0) + mp = minimal_polynomial(ex, x) + assert mp == x**3 + 4*x + 1 + mp = minimal_polynomial(ex + 1, x) + assert mp == x**3 - 3*x**2 + 7*x - 4 + assert minimal_polynomial(exp(I*pi/3), x) == x**2 - x + 1 + assert minimal_polynomial(exp(I*pi/4), x) == x**4 + 1 + assert minimal_polynomial(exp(I*pi/6), x) == x**4 - x**2 + 1 + assert minimal_polynomial(exp(I*pi/9), x) == x**6 - x**3 + 1 + assert minimal_polynomial(exp(I*pi/10), x) == x**8 - x**6 + x**4 - x**2 + 1 + assert minimal_polynomial(sin(pi/9), x) == 64*x**6 - 96*x**4 + 36*x**2 - 3 + assert minimal_polynomial(sin(pi/11), x) == 1024*x**10 - 2816*x**8 + \ + 2816*x**6 - 1232*x**4 + 220*x**2 - 11 + assert minimal_polynomial(sin(pi/21), x) == 4096*x**12 - 11264*x**10 + \ + 11264*x**8 - 4992*x**6 + 960*x**4 - 64*x**2 + 1 + assert minimal_polynomial(cos(pi/9), x) == 8*x**3 - 6*x - 1 + + ex = 2**Rational(1, 3)*exp(2*I*pi/3) + assert minimal_polynomial(ex, x) == x**3 - 2 + + raises(NotAlgebraic, lambda: minimal_polynomial(cos(pi*sqrt(2)), x)) + raises(NotAlgebraic, lambda: minimal_polynomial(sin(pi*sqrt(2)), x)) + raises(NotAlgebraic, lambda: minimal_polynomial(exp(1.618*I*pi), x)) + raises(NotAlgebraic, lambda: minimal_polynomial(exp(I*pi*sqrt(2)), x)) + + # issue 5934 + ex = 1/(-36000 - 7200*sqrt(5) + (12*sqrt(10)*sqrt(sqrt(5) + 5) + + 24*sqrt(10)*sqrt(-sqrt(5) + 5))**2) + 1 + raises(ZeroDivisionError, lambda: minimal_polynomial(ex, x)) + + ex = sqrt(1 + 2**Rational(1,3)) + sqrt(1 + 2**Rational(1,4)) + sqrt(2) + mp = minimal_polynomial(ex, x) + assert degree(mp) == 48 and mp.subs({x:0}) == -16630256576 + + ex = tan(pi/5, evaluate=False) + mp = minimal_polynomial(ex, x) + assert mp == x**4 - 10*x**2 + 5 + assert mp.subs(x, tan(pi/5)).is_zero + + ex = tan(pi/6, evaluate=False) + mp = minimal_polynomial(ex, x) + assert mp == 3*x**2 - 1 + assert mp.subs(x, tan(pi/6)).is_zero + + ex = tan(pi/10, evaluate=False) + mp = minimal_polynomial(ex, x) + assert mp == 5*x**4 - 10*x**2 + 1 + assert mp.subs(x, tan(pi/10)).is_zero + + raises(NotAlgebraic, lambda: minimal_polynomial(tan(pi*sqrt(2)), x)) + + +def test_minpoly_issue_7113(): + # see discussion in https://github.com/sympy/sympy/pull/2234 + from sympy.simplify.simplify import nsimplify + r = nsimplify(pi, tolerance=0.000000001) + mp = minimal_polynomial(r, x) + assert mp == 1768292677839237920489538677417507171630859375*x**109 - \ + 2734577732179183863586489182929671773182898498218854181690460140337930774573792597743853652058046464 + + +def test_minpoly_issue_23677(): + r1 = CRootOf(4000000*x**3 - 239960000*x**2 + 4782399900*x - 31663998001, 0) + r2 = CRootOf(4000000*x**3 - 239960000*x**2 + 4782399900*x - 31663998001, 1) + num = (7680000000000000000*r1**4*r2**4 - 614323200000000000000*r1**4*r2**3 + + 18458112576000000000000*r1**4*r2**2 - 246896663036160000000000*r1**4*r2 + + 1240473830323209600000000*r1**4 - 614323200000000000000*r1**3*r2**4 + - 1476464424954240000000000*r1**3*r2**2 - 99225501687553535904000000*r1**3 + + 18458112576000000000000*r1**2*r2**4 - 1476464424954240000000000*r1**2*r2**3 + - 593391458458356671712000000*r1**2*r2 + 2981354896834339226880720000*r1**2 + - 246896663036160000000000*r1*r2**4 - 593391458458356671712000000*r1*r2**2 + - 39878756418031796275267195200*r1 + 1240473830323209600000000*r2**4 + - 99225501687553535904000000*r2**3 + 2981354896834339226880720000*r2**2 - + 39878756418031796275267195200*r2 + 200361370275616536577343808012) + mp = (x**3 + 59426520028417434406408556687919*x**2 + + 1161475464966574421163316896737773190861975156439163671112508400*x + + 7467465541178623874454517208254940823818304424383315270991298807299003671748074773558707779600) + assert minimal_polynomial(num, x) == mp + + +def test_minpoly_issue_7574(): + ex = -(-1)**Rational(1, 3) + (-1)**Rational(2,3) + assert minimal_polynomial(ex, x) == x + 1 + + +def test_choose_factor(): + # Test that this does not enter an infinite loop: + bad_factors = [Poly(x-2, x), Poly(x+2, x)] + raises(NotImplementedError, lambda: _choose_factor(bad_factors, x, sqrt(3))) + + +def test_minpoly_fraction_field(): + assert minimal_polynomial(1/x, y) == -x*y + 1 + assert minimal_polynomial(1 / (x + 1), y) == (x + 1)*y - 1 + + assert minimal_polynomial(sqrt(x), y) == y**2 - x + assert minimal_polynomial(sqrt(x + 1), y) == y**2 - x - 1 + assert minimal_polynomial(sqrt(x) / x, y) == x*y**2 - 1 + assert minimal_polynomial(sqrt(2) * sqrt(x), y) == y**2 - 2 * x + assert minimal_polynomial(sqrt(2) + sqrt(x), y) == \ + y**4 + (-2*x - 4)*y**2 + x**2 - 4*x + 4 + + assert minimal_polynomial(x**Rational(1,3), y) == y**3 - x + assert minimal_polynomial(x**Rational(1,3) + sqrt(x), y) == \ + y**6 - 3*x*y**4 - 2*x*y**3 + 3*x**2*y**2 - 6*x**2*y - x**3 + x**2 + + assert minimal_polynomial(sqrt(x) / z, y) == z**2*y**2 - x + assert minimal_polynomial(sqrt(x) / (z + 1), y) == (z**2 + 2*z + 1)*y**2 - x + + assert minimal_polynomial(1/x, y, polys=True) == Poly(-x*y + 1, y, domain='ZZ(x)') + assert minimal_polynomial(1 / (x + 1), y, polys=True) == \ + Poly((x + 1)*y - 1, y, domain='ZZ(x)') + assert minimal_polynomial(sqrt(x), y, polys=True) == Poly(y**2 - x, y, domain='ZZ(x)') + assert minimal_polynomial(sqrt(x) / z, y, polys=True) == \ + Poly(z**2*y**2 - x, y, domain='ZZ(x, z)') + + # this is (sqrt(1 + x**3)/x).integrate(x).diff(x) - sqrt(1 + x**3)/x + a = sqrt(x)/sqrt(1 + x**(-3)) - sqrt(x**3 + 1)/x + 1/(x**Rational(5, 2)* \ + (1 + x**(-3))**Rational(3, 2)) + 1/(x**Rational(11, 2)*(1 + x**(-3))**Rational(3, 2)) + + assert minimal_polynomial(a, y) == y + + raises(NotAlgebraic, lambda: minimal_polynomial(exp(x), y)) + raises(GeneratorsError, lambda: minimal_polynomial(sqrt(x), x)) + raises(GeneratorsError, lambda: minimal_polynomial(sqrt(x) - y, x)) + raises(NotImplementedError, lambda: minimal_polynomial(sqrt(x), y, compose=False)) + +@slow +def test_minpoly_fraction_field_slow(): + assert minimal_polynomial(minimal_polynomial(sqrt(x**Rational(1,5) - 1), + y).subs(y, sqrt(x**Rational(1,5) - 1)), z) == z + +def test_minpoly_domain(): + assert minimal_polynomial(sqrt(2), x, domain=QQ.algebraic_field(sqrt(2))) == \ + x - sqrt(2) + assert minimal_polynomial(sqrt(8), x, domain=QQ.algebraic_field(sqrt(2))) == \ + x - 2*sqrt(2) + assert minimal_polynomial(sqrt(Rational(3,2)), x, + domain=QQ.algebraic_field(sqrt(2))) == 2*x**2 - 3 + + raises(NotAlgebraic, lambda: minimal_polynomial(y, x, domain=QQ)) + + +def test_issue_14831(): + a = -2*sqrt(2)*sqrt(12*sqrt(2) + 17) + assert minimal_polynomial(a, x) == x**2 + 16*x - 8 + e = (-3*sqrt(12*sqrt(2) + 17) + 12*sqrt(2) + + 17 - 2*sqrt(2)*sqrt(12*sqrt(2) + 17)) + assert minimal_polynomial(e, x) == x + + +def test_issue_18248(): + assert nonlinsolve([x*y**3-sqrt(2)/3, x*y**6-4/(9*(sqrt(3)))],x,y) == \ + FiniteSet((sqrt(3)/2, sqrt(6)/3), (sqrt(3)/2, -sqrt(6)/6 - sqrt(2)*I/2), + (sqrt(3)/2, -sqrt(6)/6 + sqrt(2)*I/2)) + + +def test_issue_13230(): + c1 = Circle(Point2D(3, sqrt(5)), 5) + c2 = Circle(Point2D(4, sqrt(7)), 6) + assert intersection(c1, c2) == [Point2D(-1 + (-sqrt(7) + sqrt(5))*(-2*sqrt(7)/29 + + 9*sqrt(5)/29 + sqrt(196*sqrt(35) + 1941)/29), -2*sqrt(7)/29 + 9*sqrt(5)/29 + + sqrt(196*sqrt(35) + 1941)/29), Point2D(-1 + (-sqrt(7) + sqrt(5))*(-sqrt(196*sqrt(35) + + 1941)/29 - 2*sqrt(7)/29 + 9*sqrt(5)/29), -sqrt(196*sqrt(35) + 1941)/29 - 2*sqrt(7)/29 + 9*sqrt(5)/29)] + +def test_issue_19760(): + e = 1/(sqrt(1 + sqrt(2)) - sqrt(2)*sqrt(1 + sqrt(2))) + 1 + mp_expected = x**4 - 4*x**3 + 4*x**2 - 2 + + for comp in (True, False): + mp = Poly(minimal_polynomial(e, compose=comp)) + assert mp(x) == mp_expected, "minimal_polynomial(e, compose=%s) = %s; %s expected" % (comp, mp(x), mp_expected) + + +def test_issue_20163(): + assert apart(1/(x**6+1), extension=[sqrt(3), I]) == \ + (sqrt(3) + I)/(2*x + sqrt(3) + I)/6 + \ + (sqrt(3) - I)/(2*x + sqrt(3) - I)/6 - \ + (sqrt(3) - I)/(2*x - sqrt(3) + I)/6 - \ + (sqrt(3) + I)/(2*x - sqrt(3) - I)/6 + \ + I/(x + I)/6 - I/(x - I)/6 + + +def test_issue_22559(): + alpha = AlgebraicNumber(sqrt(2)) + assert minimal_polynomial(alpha**3, x) == x**2 - 8 + + +def test_issue_22561(): + a = AlgebraicNumber(sqrt(2) + sqrt(3), [S(1) / 2, 0, S(-9) / 2, 0], gen=x) + assert a.as_expr() == sqrt(2) + assert minimal_polynomial(a, x) == x**2 - 2 + assert minimal_polynomial(a**3, x) == x**2 - 8 + + +def test_separate_sq_not_impl(): + raises(NotImplementedError, lambda: _separate_sq(x**(S(1)/3) + x)) + + +def test_minpoly_op_algebraic_element_not_impl(): + raises(NotImplementedError, + lambda: _minpoly_op_algebraic_element(Pow, sqrt(2), sqrt(3), x, QQ)) + + +def test_minpoly_groebner(): + assert _minpoly_groebner(S(2)/3, x, Poly) == 3*x - 2 + assert _minpoly_groebner( + (sqrt(2) + 3)*(sqrt(2) + 1), x, Poly) == x**2 - 10*x - 7 + assert _minpoly_groebner((sqrt(2) + 3)**(S(1)/3)*(sqrt(2) + 1)**(S(1)/3), + x, Poly) == x**6 - 10*x**3 - 7 + assert _minpoly_groebner((sqrt(2) + 3)**(-S(1)/3)*(sqrt(2) + 1)**(S(1)/3), + x, Poly) == 7*x**6 - 2*x**3 - 1 + raises(NotAlgebraic, lambda: _minpoly_groebner(pi**2, x, Poly)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_modules.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_modules.py new file mode 100644 index 0000000000000000000000000000000000000000..f3c61c98e33d3c78e79eeed45efcfa1f74478645 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_modules.py @@ -0,0 +1,752 @@ +from sympy.abc import x, zeta +from sympy.polys import Poly, cyclotomic_poly +from sympy.polys.domains import FF, QQ, ZZ +from sympy.polys.matrices import DomainMatrix, DM +from sympy.polys.numberfields.exceptions import ( + ClosureFailure, MissingUnityError, StructureError +) +from sympy.polys.numberfields.modules import ( + Module, ModuleElement, ModuleEndomorphism, PowerBasis, PowerBasisElement, + find_min_poly, is_sq_maxrank_HNF, make_mod_elt, to_col, +) +from sympy.polys.numberfields.utilities import is_int +from sympy.polys.polyerrors import UnificationFailed +from sympy.testing.pytest import raises + + +def test_to_col(): + c = [1, 2, 3, 4] + m = to_col(c) + assert m.domain.is_ZZ + assert m.shape == (4, 1) + assert m.flat() == c + + +def test_Module_NotImplemented(): + M = Module() + raises(NotImplementedError, lambda: M.n) + raises(NotImplementedError, lambda: M.mult_tab()) + raises(NotImplementedError, lambda: M.represent(None)) + raises(NotImplementedError, lambda: M.starts_with_unity()) + raises(NotImplementedError, lambda: M.element_from_rational(QQ(2, 3))) + + +def test_Module_ancestors(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = B.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + D = B.submodule_from_matrix(5 * DomainMatrix.eye(4, ZZ)) + assert C.ancestors(include_self=True) == [A, B, C] + assert D.ancestors(include_self=True) == [A, B, D] + assert C.power_basis_ancestor() == A + assert C.nearest_common_ancestor(D) == B + M = Module() + assert M.power_basis_ancestor() is None + + +def test_Module_compat_col(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + col = to_col([1, 2, 3, 4]) + row = col.transpose() + assert A.is_compat_col(col) is True + assert A.is_compat_col(row) is False + assert A.is_compat_col(1) is False + assert A.is_compat_col(DomainMatrix.eye(3, ZZ)[:, 0]) is False + assert A.is_compat_col(DomainMatrix.eye(4, QQ)[:, 0]) is False + assert A.is_compat_col(DomainMatrix.eye(4, ZZ)[:, 0]) is True + + +def test_Module_call(): + T = Poly(cyclotomic_poly(5, x)) + B = PowerBasis(T) + assert B(0).col.flat() == [1, 0, 0, 0] + assert B(1).col.flat() == [0, 1, 0, 0] + col = DomainMatrix.eye(4, ZZ)[:, 2] + assert B(col).col == col + raises(ValueError, lambda: B(-1)) + + +def test_Module_starts_with_unity(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + assert A.starts_with_unity() is True + assert B.starts_with_unity() is False + + +def test_Module_basis_elements(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + basis = B.basis_elements() + bp = B.basis_element_pullbacks() + for i, (e, p) in enumerate(zip(basis, bp)): + c = [0] * 4 + assert e.module == B + assert p.module == A + c[i] = 1 + assert e == B(to_col(c)) + c[i] = 2 + assert p == A(to_col(c)) + + +def test_Module_zero(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + assert A.zero().col.flat() == [0, 0, 0, 0] + assert A.zero().module == A + assert B.zero().col.flat() == [0, 0, 0, 0] + assert B.zero().module == B + + +def test_Module_one(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + assert A.one().col.flat() == [1, 0, 0, 0] + assert A.one().module == A + assert B.one().col.flat() == [1, 0, 0, 0] + assert B.one().module == A + + +def test_Module_element_from_rational(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + rA = A.element_from_rational(QQ(22, 7)) + rB = B.element_from_rational(QQ(22, 7)) + assert rA.coeffs == [22, 0, 0, 0] + assert rA.denom == 7 + assert rA.module == A + assert rB.coeffs == [22, 0, 0, 0] + assert rB.denom == 7 + assert rB.module == A + + +def test_Module_submodule_from_gens(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + gens = [2*A(0), 2*A(1), 6*A(0), 6*A(1)] + B = A.submodule_from_gens(gens) + # Because the 3rd and 4th generators do not add anything new, we expect + # the cols of the matrix of B to just reproduce the first two gens: + M = gens[0].column().hstack(gens[1].column()) + assert B.matrix == M + # At least one generator must be provided: + raises(ValueError, lambda: A.submodule_from_gens([])) + # All generators must belong to A: + raises(ValueError, lambda: A.submodule_from_gens([3*A(0), B(0)])) + + +def test_Module_submodule_from_matrix(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + e = B(to_col([1, 2, 3, 4])) + f = e.to_parent() + assert f.col.flat() == [2, 4, 6, 8] + # Matrix must be over ZZ: + raises(ValueError, lambda: A.submodule_from_matrix(DomainMatrix.eye(4, QQ))) + # Number of rows of matrix must equal number of generators of module A: + raises(ValueError, lambda: A.submodule_from_matrix(2 * DomainMatrix.eye(5, ZZ))) + + +def test_Module_whole_submodule(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.whole_submodule() + e = B(to_col([1, 2, 3, 4])) + f = e.to_parent() + assert f.col.flat() == [1, 2, 3, 4] + e0, e1, e2, e3 = B(0), B(1), B(2), B(3) + assert e2 * e3 == e0 + assert e3 ** 2 == e1 + + +def test_PowerBasis_repr(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + assert repr(A) == 'PowerBasis(x**4 + x**3 + x**2 + x + 1)' + + +def test_PowerBasis_eq(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = PowerBasis(T) + assert A == B + + +def test_PowerBasis_mult_tab(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + M = A.mult_tab() + exp = {0: {0: [1, 0, 0, 0], 1: [0, 1, 0, 0], 2: [0, 0, 1, 0], 3: [0, 0, 0, 1]}, + 1: {1: [0, 0, 1, 0], 2: [0, 0, 0, 1], 3: [-1, -1, -1, -1]}, + 2: {2: [-1, -1, -1, -1], 3: [1, 0, 0, 0]}, + 3: {3: [0, 1, 0, 0]}} + # We get the table we expect: + assert M == exp + # And all entries are of expected type: + assert all(is_int(c) for u in M for v in M[u] for c in M[u][v]) + + +def test_PowerBasis_represent(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + col = to_col([1, 2, 3, 4]) + a = A(col) + assert A.represent(a) == col + b = A(col, denom=2) + raises(ClosureFailure, lambda: A.represent(b)) + + +def test_PowerBasis_element_from_poly(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + f = Poly(1 + 2*x) + g = Poly(x**4) + h = Poly(0, x) + assert A.element_from_poly(f).coeffs == [1, 2, 0, 0] + assert A.element_from_poly(g).coeffs == [-1, -1, -1, -1] + assert A.element_from_poly(h).coeffs == [0, 0, 0, 0] + + +def test_PowerBasis_element__conversions(): + k = QQ.cyclotomic_field(5) + L = QQ.cyclotomic_field(7) + B = PowerBasis(k) + + # ANP --> PowerBasisElement + a = k([QQ(1, 2), QQ(1, 3), 5, 7]) + e = B.element_from_ANP(a) + assert e.coeffs == [42, 30, 2, 3] + assert e.denom == 6 + + # PowerBasisElement --> ANP + assert e.to_ANP() == a + + # Cannot convert ANP from different field + d = L([QQ(1, 2), QQ(1, 3), 5, 7]) + raises(UnificationFailed, lambda: B.element_from_ANP(d)) + + # AlgebraicNumber --> PowerBasisElement + alpha = k.to_alg_num(a) + eps = B.element_from_alg_num(alpha) + assert eps.coeffs == [42, 30, 2, 3] + assert eps.denom == 6 + + # PowerBasisElement --> AlgebraicNumber + assert eps.to_alg_num() == alpha + + # Cannot convert AlgebraicNumber from different field + delta = L.to_alg_num(d) + raises(UnificationFailed, lambda: B.element_from_alg_num(delta)) + + # When we don't know the field: + C = PowerBasis(k.ext.minpoly) + # Can convert from AlgebraicNumber: + eps = C.element_from_alg_num(alpha) + assert eps.coeffs == [42, 30, 2, 3] + assert eps.denom == 6 + # But can't convert back: + raises(StructureError, lambda: eps.to_alg_num()) + + +def test_Submodule_repr(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ), denom=3) + assert repr(B) == 'Submodule[[2, 0, 0, 0], [0, 2, 0, 0], [0, 0, 2, 0], [0, 0, 0, 2]]/3' + + +def test_Submodule_reduced(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = A.submodule_from_matrix(6 * DomainMatrix.eye(4, ZZ), denom=3) + D = C.reduced() + assert D.denom == 1 and D == C == B + + +def test_Submodule_discard_before(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + B.compute_mult_tab() + C = B.discard_before(2) + assert C.parent == B.parent + assert B.is_sq_maxrank_HNF() and not C.is_sq_maxrank_HNF() + assert C.matrix == B.matrix[:, 2:] + assert C.mult_tab() == {0: {0: [-2, -2], 1: [0, 0]}, 1: {1: [0, 0]}} + + +def test_Submodule_QQ_matrix(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = A.submodule_from_matrix(6 * DomainMatrix.eye(4, ZZ), denom=3) + assert C.QQ_matrix == B.QQ_matrix + + +def test_Submodule_represent(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = B.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + a0 = A(to_col([6, 12, 18, 24])) + a1 = A(to_col([2, 4, 6, 8])) + a2 = A(to_col([1, 3, 5, 7])) + + b1 = B.represent(a1) + assert b1.flat() == [1, 2, 3, 4] + + c0 = C.represent(a0) + assert c0.flat() == [1, 2, 3, 4] + + Y = A.submodule_from_matrix(DomainMatrix([ + [1, 0, 0, 0], + [0, 1, 0, 0], + [0, 0, 1, 0], + ], (3, 4), ZZ).transpose()) + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + z0 = Z(to_col([1, 2, 3, 4, 5, 6])) + + raises(ClosureFailure, lambda: Y.represent(A(3))) + raises(ClosureFailure, lambda: B.represent(a2)) + raises(ClosureFailure, lambda: B.represent(z0)) + + +def test_Submodule_is_compat_submodule(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + D = C.submodule_from_matrix(5 * DomainMatrix.eye(4, ZZ)) + assert B.is_compat_submodule(C) is True + assert B.is_compat_submodule(A) is False + assert B.is_compat_submodule(D) is False + + +def test_Submodule_eq(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = A.submodule_from_matrix(6 * DomainMatrix.eye(4, ZZ), denom=3) + assert C == B + + +def test_Submodule_add(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(DomainMatrix([ + [4, 0, 0, 0], + [0, 4, 0, 0], + ], (2, 4), ZZ).transpose(), denom=6) + C = A.submodule_from_matrix(DomainMatrix([ + [0, 10, 0, 0], + [0, 0, 7, 0], + ], (2, 4), ZZ).transpose(), denom=15) + D = A.submodule_from_matrix(DomainMatrix([ + [20, 0, 0, 0], + [ 0, 20, 0, 0], + [ 0, 0, 14, 0], + ], (3, 4), ZZ).transpose(), denom=30) + assert B + C == D + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + Y = Z.submodule_from_gens([Z(0), Z(1)]) + raises(TypeError, lambda: B + Y) + + +def test_Submodule_mul(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + C = A.submodule_from_matrix(DomainMatrix([ + [0, 10, 0, 0], + [0, 0, 7, 0], + ], (2, 4), ZZ).transpose(), denom=15) + C1 = A.submodule_from_matrix(DomainMatrix([ + [0, 20, 0, 0], + [0, 0, 14, 0], + ], (2, 4), ZZ).transpose(), denom=3) + C2 = A.submodule_from_matrix(DomainMatrix([ + [0, 0, 10, 0], + [0, 0, 0, 7], + ], (2, 4), ZZ).transpose(), denom=15) + C3_unred = A.submodule_from_matrix(DomainMatrix([ + [0, 0, 100, 0], + [0, 0, 0, 70], + [0, 0, 0, 70], + [-49, -49, -49, -49] + ], (4, 4), ZZ).transpose(), denom=225) + C3 = A.submodule_from_matrix(DomainMatrix([ + [4900, 4900, 0, 0], + [4410, 4410, 10, 0], + [2107, 2107, 7, 7] + ], (3, 4), ZZ).transpose(), denom=225) + assert C * 1 == C + assert C ** 1 == C + assert C * 10 == C1 + assert C * A(1) == C2 + assert C.mul(C, hnf=False) == C3_unred + assert C * C == C3 + assert C ** 2 == C3 + + +def test_Submodule_reduce_element(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.whole_submodule() + b = B(to_col([90, 84, 80, 75]), denom=120) + + C = B.submodule_from_matrix(DomainMatrix.eye(4, ZZ), denom=2) + b_bar_expected = B(to_col([30, 24, 20, 15]), denom=120) + b_bar = C.reduce_element(b) + assert b_bar == b_bar_expected + + C = B.submodule_from_matrix(DomainMatrix.eye(4, ZZ), denom=4) + b_bar_expected = B(to_col([0, 24, 20, 15]), denom=120) + b_bar = C.reduce_element(b) + assert b_bar == b_bar_expected + + C = B.submodule_from_matrix(DomainMatrix.eye(4, ZZ), denom=8) + b_bar_expected = B(to_col([0, 9, 5, 0]), denom=120) + b_bar = C.reduce_element(b) + assert b_bar == b_bar_expected + + a = A(to_col([1, 2, 3, 4])) + raises(NotImplementedError, lambda: C.reduce_element(a)) + + C = B.submodule_from_matrix(DomainMatrix([ + [5, 4, 3, 2], + [0, 8, 7, 6], + [0, 0,11,12], + [0, 0, 0, 1] + ], (4, 4), ZZ).transpose()) + raises(StructureError, lambda: C.reduce_element(b)) + + +def test_is_HNF(): + M = DM([ + [3, 2, 1], + [0, 2, 1], + [0, 0, 1] + ], ZZ) + M1 = DM([ + [3, 2, 1], + [0, -2, 1], + [0, 0, 1] + ], ZZ) + M2 = DM([ + [3, 2, 3], + [0, 2, 1], + [0, 0, 1] + ], ZZ) + assert is_sq_maxrank_HNF(M) is True + assert is_sq_maxrank_HNF(M1) is False + assert is_sq_maxrank_HNF(M2) is False + + +def test_make_mod_elt(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + col = to_col([1, 2, 3, 4]) + eA = make_mod_elt(A, col) + eB = make_mod_elt(B, col) + assert isinstance(eA, PowerBasisElement) + assert not isinstance(eB, PowerBasisElement) + + +def test_ModuleElement_repr(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 2, 3, 4]), denom=2) + assert repr(e) == '[1, 2, 3, 4]/2' + + +def test_ModuleElement_reduced(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([2, 4, 6, 8]), denom=2) + f = e.reduced() + assert f.denom == 1 and f == e + + +def test_ModuleElement_reduced_mod_p(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([20, 40, 60, 80])) + f = e.reduced_mod_p(7) + assert f.coeffs == [-1, -2, -3, 3] + + +def test_ModuleElement_from_int_list(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + c = [1, 2, 3, 4] + assert ModuleElement.from_int_list(A, c).coeffs == c + + +def test_ModuleElement_len(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(0) + assert len(e) == 4 + + +def test_ModuleElement_column(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(0) + col1 = e.column() + assert col1 == e.col and col1 is not e.col + col2 = e.column(domain=FF(5)) + assert col2.domain.is_FF + + +def test_ModuleElement_QQ_col(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 2, 3, 4]), denom=1) + f = A(to_col([3, 6, 9, 12]), denom=3) + assert e.QQ_col == f.QQ_col + + +def test_ModuleElement_to_ancestors(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = B.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + D = C.submodule_from_matrix(5 * DomainMatrix.eye(4, ZZ)) + eD = D(0) + eC = eD.to_parent() + eB = eD.to_ancestor(B) + eA = eD.over_power_basis() + assert eC.module is C and eC.coeffs == [5, 0, 0, 0] + assert eB.module is B and eB.coeffs == [15, 0, 0, 0] + assert eA.module is A and eA.coeffs == [30, 0, 0, 0] + + a = A(0) + raises(ValueError, lambda: a.to_parent()) + + +def test_ModuleElement_compatibility(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = B.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + D = B.submodule_from_matrix(5 * DomainMatrix.eye(4, ZZ)) + assert C(0).is_compat(C(1)) is True + assert C(0).is_compat(D(0)) is False + u, v = C(0).unify(D(0)) + assert u.module is B and v.module is B + assert C(C.represent(u)) == C(0) and D(D.represent(v)) == D(0) + + u, v = C(0).unify(C(1)) + assert u == C(0) and v == C(1) + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + raises(UnificationFailed, lambda: C(0).unify(Z(1))) + + +def test_ModuleElement_eq(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 2, 3, 4]), denom=1) + f = A(to_col([3, 6, 9, 12]), denom=3) + assert e == f + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + assert e != Z(0) + assert e != 3.14 + + +def test_ModuleElement_equiv(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 2, 3, 4]), denom=1) + f = A(to_col([3, 6, 9, 12]), denom=3) + assert e.equiv(f) + + C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + g = C(to_col([1, 2, 3, 4]), denom=1) + h = A(to_col([3, 6, 9, 12]), denom=1) + assert g.equiv(h) + assert C(to_col([5, 0, 0, 0]), denom=7).equiv(QQ(15, 7)) + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + raises(UnificationFailed, lambda: e.equiv(Z(0))) + + assert e.equiv(3.14) is False + + +def test_ModuleElement_add(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + e = A(to_col([1, 2, 3, 4]), denom=6) + f = A(to_col([5, 6, 7, 8]), denom=10) + g = C(to_col([1, 1, 1, 1]), denom=2) + assert e + f == A(to_col([10, 14, 18, 22]), denom=15) + assert e - f == A(to_col([-5, -4, -3, -2]), denom=15) + assert e + g == A(to_col([10, 11, 12, 13]), denom=6) + assert e + QQ(7, 10) == A(to_col([26, 10, 15, 20]), denom=30) + assert g + QQ(7, 10) == A(to_col([22, 15, 15, 15]), denom=10) + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + raises(TypeError, lambda: e + Z(0)) + raises(TypeError, lambda: e + 3.14) + + +def test_ModuleElement_mul(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + e = A(to_col([0, 2, 0, 0]), denom=3) + f = A(to_col([0, 0, 0, 7]), denom=5) + g = C(to_col([0, 0, 0, 1]), denom=2) + h = A(to_col([0, 0, 3, 1]), denom=7) + assert e * f == A(to_col([-14, -14, -14, -14]), denom=15) + assert e * g == A(to_col([-1, -1, -1, -1])) + assert e * h == A(to_col([-2, -2, -2, 4]), denom=21) + assert e * QQ(6, 5) == A(to_col([0, 4, 0, 0]), denom=5) + assert (g * QQ(10, 21)).equiv(A(to_col([0, 0, 0, 5]), denom=7)) + assert e // QQ(6, 5) == A(to_col([0, 5, 0, 0]), denom=9) + + U = Poly(cyclotomic_poly(7, x)) + Z = PowerBasis(U) + raises(TypeError, lambda: e * Z(0)) + raises(TypeError, lambda: e * 3.14) + raises(TypeError, lambda: e // 3.14) + raises(ZeroDivisionError, lambda: e // 0) + + +def test_ModuleElement_div(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + e = A(to_col([0, 2, 0, 0]), denom=3) + f = A(to_col([0, 0, 0, 7]), denom=5) + g = C(to_col([1, 1, 1, 1])) + assert e // f == 10*A(3)//21 + assert e // g == -2*A(2)//9 + assert 3 // g == -A(1) + + +def test_ModuleElement_pow(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + C = A.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + e = A(to_col([0, 2, 0, 0]), denom=3) + g = C(to_col([0, 0, 0, 1]), denom=2) + assert e ** 3 == A(to_col([0, 0, 0, 8]), denom=27) + assert g ** 2 == C(to_col([0, 3, 0, 0]), denom=4) + assert e ** 0 == A(to_col([1, 0, 0, 0])) + assert g ** 0 == A(to_col([1, 0, 0, 0])) + assert e ** 1 == e + assert g ** 1 == g + + +def test_ModuleElement_mod(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 15, 8, 0]), denom=2) + assert e % 7 == A(to_col([1, 1, 8, 0]), denom=2) + assert e % QQ(1, 2) == A.zero() + assert e % QQ(1, 3) == A(to_col([1, 1, 0, 0]), denom=6) + + B = A.submodule_from_gens([A(0), 5*A(1), 3*A(2), A(3)]) + assert e % B == A(to_col([1, 5, 2, 0]), denom=2) + + C = B.whole_submodule() + raises(TypeError, lambda: e % C) + + +def test_PowerBasisElement_polys(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 15, 8, 0]), denom=2) + assert e.numerator(x=zeta) == Poly(8 * zeta ** 2 + 15 * zeta + 1, domain=ZZ) + assert e.poly(x=zeta) == Poly(4 * zeta ** 2 + QQ(15, 2) * zeta + QQ(1, 2), domain=QQ) + + +def test_PowerBasisElement_norm(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + lam = A(to_col([1, -1, 0, 0])) + assert lam.norm() == 5 + + +def test_PowerBasisElement_inverse(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + e = A(to_col([1, 1, 1, 1])) + assert 2 // e == -2*A(1) + assert e ** -3 == -A(3) + + +def test_ModuleHomomorphism_matrix(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + phi = ModuleEndomorphism(A, lambda a: a ** 2) + M = phi.matrix() + assert M == DomainMatrix([ + [1, 0, -1, 0], + [0, 0, -1, 1], + [0, 1, -1, 0], + [0, 0, -1, 0] + ], (4, 4), ZZ) + + +def test_ModuleHomomorphism_kernel(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + phi = ModuleEndomorphism(A, lambda a: a ** 5) + N = phi.kernel() + assert N.n == 3 + + +def test_EndomorphismRing_represent(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + R = A.endomorphism_ring() + phi = R.inner_endomorphism(A(1)) + col = R.represent(phi) + assert col.transpose() == DomainMatrix([ + [0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, -1, -1, -1, -1] + ], (1, 16), ZZ) + + B = A.submodule_from_matrix(DomainMatrix.zeros((4, 0), ZZ)) + S = B.endomorphism_ring() + psi = S.inner_endomorphism(A(1)) + col = S.represent(psi) + assert col == DomainMatrix([], (0, 0), ZZ) + + raises(NotImplementedError, lambda: R.represent(3.14)) + + +def test_find_min_poly(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + powers = [] + m = find_min_poly(A(1), QQ, x=x, powers=powers) + assert m == Poly(T, domain=QQ) + assert len(powers) == 5 + + # powers list need not be passed + m = find_min_poly(A(1), QQ, x=x) + assert m == Poly(T, domain=QQ) + + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + raises(MissingUnityError, lambda: find_min_poly(B(1), QQ)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_numbers.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_numbers.py new file mode 100644 index 0000000000000000000000000000000000000000..f8f350719cc740901a29d03e45ae9f3978446f31 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_numbers.py @@ -0,0 +1,202 @@ +"""Tests on algebraic numbers. """ + +from sympy.core.containers import Tuple +from sympy.core.numbers import (AlgebraicNumber, I, Rational) +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.polys.polytools import Poly +from sympy.polys.numberfields.subfield import to_number_field +from sympy.polys.polyclasses import DMP +from sympy.polys.domains import QQ +from sympy.polys.rootoftools import CRootOf +from sympy.abc import x, y + + +def test_AlgebraicNumber(): + minpoly, root = x**2 - 2, sqrt(2) + + a = AlgebraicNumber(root, gen=x) + + assert a.rep == DMP([QQ(1), QQ(0)], QQ) + assert a.root == root + assert a.alias is None + assert a.minpoly == minpoly + assert a.is_number + + assert a.is_aliased is False + + assert a.coeffs() == [S.One, S.Zero] + assert a.native_coeffs() == [QQ(1), QQ(0)] + + a = AlgebraicNumber(root, gen=x, alias='y') + + assert a.rep == DMP([QQ(1), QQ(0)], QQ) + assert a.root == root + assert a.alias == Symbol('y') + assert a.minpoly == minpoly + assert a.is_number + + assert a.is_aliased is True + + a = AlgebraicNumber(root, gen=x, alias=Symbol('y')) + + assert a.rep == DMP([QQ(1), QQ(0)], QQ) + assert a.root == root + assert a.alias == Symbol('y') + assert a.minpoly == minpoly + assert a.is_number + + assert a.is_aliased is True + + assert AlgebraicNumber(sqrt(2), []).rep == DMP([], QQ) + assert AlgebraicNumber(sqrt(2), ()).rep == DMP([], QQ) + assert AlgebraicNumber(sqrt(2), (0, 0)).rep == DMP([], QQ) + + assert AlgebraicNumber(sqrt(2), [8]).rep == DMP([QQ(8)], QQ) + assert AlgebraicNumber(sqrt(2), [Rational(8, 3)]).rep == DMP([QQ(8, 3)], QQ) + + assert AlgebraicNumber(sqrt(2), [7, 3]).rep == DMP([QQ(7), QQ(3)], QQ) + assert AlgebraicNumber( + sqrt(2), [Rational(7, 9), Rational(3, 2)]).rep == DMP([QQ(7, 9), QQ(3, 2)], QQ) + + assert AlgebraicNumber(sqrt(2), [1, 2, 3]).rep == DMP([QQ(2), QQ(5)], QQ) + + a = AlgebraicNumber(AlgebraicNumber(root, gen=x), [1, 2]) + + assert a.rep == DMP([QQ(1), QQ(2)], QQ) + assert a.root == root + assert a.alias is None + assert a.minpoly == minpoly + assert a.is_number + + assert a.is_aliased is False + + assert a.coeffs() == [S.One, S(2)] + assert a.native_coeffs() == [QQ(1), QQ(2)] + + a = AlgebraicNumber((minpoly, root), [1, 2]) + + assert a.rep == DMP([QQ(1), QQ(2)], QQ) + assert a.root == root + assert a.alias is None + assert a.minpoly == minpoly + assert a.is_number + + assert a.is_aliased is False + + a = AlgebraicNumber((Poly(minpoly), root), [1, 2]) + + assert a.rep == DMP([QQ(1), QQ(2)], QQ) + assert a.root == root + assert a.alias is None + assert a.minpoly == minpoly + assert a.is_number + + assert a.is_aliased is False + + assert AlgebraicNumber( sqrt(3)).rep == DMP([ QQ(1), QQ(0)], QQ) + assert AlgebraicNumber(-sqrt(3)).rep == DMP([ QQ(1), QQ(0)], QQ) + + a = AlgebraicNumber(sqrt(2)) + b = AlgebraicNumber(sqrt(2)) + + assert a == b + + c = AlgebraicNumber(sqrt(2), gen=x) + + assert a == b + assert a == c + + a = AlgebraicNumber(sqrt(2), [1, 2]) + b = AlgebraicNumber(sqrt(2), [1, 3]) + + assert a != b and a != sqrt(2) + 3 + + assert (a == x) is False and (a != x) is True + + a = AlgebraicNumber(sqrt(2), [1, 0]) + b = AlgebraicNumber(sqrt(2), [1, 0], alias=y) + + assert a.as_poly(x) == Poly(x, domain='QQ') + assert b.as_poly() == Poly(y, domain='QQ') + + assert a.as_expr() == sqrt(2) + assert a.as_expr(x) == x + assert b.as_expr() == sqrt(2) + assert b.as_expr(x) == x + + a = AlgebraicNumber(sqrt(2), [2, 3]) + b = AlgebraicNumber(sqrt(2), [2, 3], alias=y) + + p = a.as_poly() + + assert p == Poly(2*p.gen + 3) + + assert a.as_poly(x) == Poly(2*x + 3, domain='QQ') + assert b.as_poly() == Poly(2*y + 3, domain='QQ') + + assert a.as_expr() == 2*sqrt(2) + 3 + assert a.as_expr(x) == 2*x + 3 + assert b.as_expr() == 2*sqrt(2) + 3 + assert b.as_expr(x) == 2*x + 3 + + a = AlgebraicNumber(sqrt(2)) + b = to_number_field(sqrt(2)) + assert a.args == b.args == (sqrt(2), Tuple(1, 0)) + b = AlgebraicNumber(sqrt(2), alias='alpha') + assert b.args == (sqrt(2), Tuple(1, 0), Symbol('alpha')) + + a = AlgebraicNumber(sqrt(2), [1, 2, 3]) + assert a.args == (sqrt(2), Tuple(1, 2, 3)) + + a = AlgebraicNumber(sqrt(2), [1, 2], "alpha") + b = AlgebraicNumber(a) + c = AlgebraicNumber(a, alias="gamma") + assert a == b + assert c.alias.name == "gamma" + + a = AlgebraicNumber(sqrt(2) + sqrt(3), [S(1)/2, 0, S(-9)/2, 0]) + b = AlgebraicNumber(a, [1, 0, 0]) + assert b.root == a.root + assert a.to_root() == sqrt(2) + assert b.to_root() == 2 + + a = AlgebraicNumber(2) + assert a.is_primitive_element is True + + +def test_to_algebraic_integer(): + a = AlgebraicNumber(sqrt(3), gen=x).to_algebraic_integer() + + assert a.minpoly == x**2 - 3 + assert a.root == sqrt(3) + assert a.rep == DMP([QQ(1), QQ(0)], QQ) + + a = AlgebraicNumber(2*sqrt(3), gen=x).to_algebraic_integer() + assert a.minpoly == x**2 - 12 + assert a.root == 2*sqrt(3) + assert a.rep == DMP([QQ(1), QQ(0)], QQ) + + a = AlgebraicNumber(sqrt(3)/2, gen=x).to_algebraic_integer() + + assert a.minpoly == x**2 - 12 + assert a.root == 2*sqrt(3) + assert a.rep == DMP([QQ(1), QQ(0)], QQ) + + a = AlgebraicNumber(sqrt(3)/2, [Rational(7, 19), 3], gen=x).to_algebraic_integer() + + assert a.minpoly == x**2 - 12 + assert a.root == 2*sqrt(3) + assert a.rep == DMP([QQ(7, 19), QQ(3)], QQ) + + +def test_AlgebraicNumber_to_root(): + assert AlgebraicNumber(sqrt(2)).to_root() == sqrt(2) + + zeta5_squared = AlgebraicNumber(CRootOf(x**5 - 1, 4), coeffs=[1, 0, 0]) + assert zeta5_squared.to_root() == CRootOf(x**4 + x**3 + x**2 + x + 1, 1) + + zeta3_squared = AlgebraicNumber(CRootOf(x**3 - 1, 2), coeffs=[1, 0, 0]) + assert zeta3_squared.to_root() == -S(1)/2 - sqrt(3)*I/2 + assert zeta3_squared.to_root(radicals=False) == CRootOf(x**2 + x + 1, 0) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_primes.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_primes.py new file mode 100644 index 0000000000000000000000000000000000000000..f121d60d272fe65345de773748828a8a67eb0028 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_primes.py @@ -0,0 +1,296 @@ +from math import prod + +from sympy import QQ, ZZ +from sympy.abc import x, theta +from sympy.ntheory import factorint +from sympy.ntheory.residue_ntheory import n_order +from sympy.polys import Poly, cyclotomic_poly +from sympy.polys.matrices import DomainMatrix +from sympy.polys.numberfields.basis import round_two +from sympy.polys.numberfields.exceptions import StructureError +from sympy.polys.numberfields.modules import PowerBasis, to_col +from sympy.polys.numberfields.primes import ( + prime_decomp, _two_elt_rep, + _check_formal_conditions_for_maximal_order, +) +from sympy.testing.pytest import raises + + +def test_check_formal_conditions_for_maximal_order(): + T = Poly(cyclotomic_poly(5, x)) + A = PowerBasis(T) + B = A.submodule_from_matrix(2 * DomainMatrix.eye(4, ZZ)) + C = B.submodule_from_matrix(3 * DomainMatrix.eye(4, ZZ)) + D = A.submodule_from_matrix(DomainMatrix.eye(4, ZZ)[:, :-1]) + # Is a direct submodule of a power basis, but lacks 1 as first generator: + raises(StructureError, lambda: _check_formal_conditions_for_maximal_order(B)) + # Is not a direct submodule of a power basis: + raises(StructureError, lambda: _check_formal_conditions_for_maximal_order(C)) + # Is direct submod of pow basis, and starts with 1, but not sq/max rank/HNF: + raises(StructureError, lambda: _check_formal_conditions_for_maximal_order(D)) + + +def test_two_elt_rep(): + ell = 7 + T = Poly(cyclotomic_poly(ell)) + ZK, dK = round_two(T) + for p in [29, 13, 11, 5]: + P = prime_decomp(p, T) + for Pi in P: + # We have Pi in two-element representation, and, because we are + # looking at a cyclotomic field, this was computed by the "easy" + # method that just factors T mod p. We will now convert this to + # a set of Z-generators, then convert that back into a two-element + # rep. The latter need not be identical to the two-elt rep we + # already have, but it must have the same HNF. + H = p*ZK + Pi.alpha*ZK + gens = H.basis_element_pullbacks() + # Note: we could supply f = Pi.f, but prefer to test behavior without it. + b = _two_elt_rep(gens, ZK, p) + if b != Pi.alpha: + H2 = p*ZK + b*ZK + assert H2 == H + + +def test_valuation_at_prime_ideal(): + p = 7 + T = Poly(cyclotomic_poly(p)) + ZK, dK = round_two(T) + P = prime_decomp(p, T, dK=dK, ZK=ZK) + assert len(P) == 1 + P0 = P[0] + v = P0.valuation(p*ZK) + assert v == P0.e + # Test easy 0 case: + assert P0.valuation(5*ZK) == 0 + + +def test_decomp_1(): + # All prime decompositions in cyclotomic fields are in the "easy case," + # since the index is unity. + # Here we check the ramified prime. + T = Poly(cyclotomic_poly(7)) + raises(ValueError, lambda: prime_decomp(7)) + P = prime_decomp(7, T) + assert len(P) == 1 + P0 = P[0] + assert P0.e == 6 + assert P0.f == 1 + # Test powers: + assert P0**0 == P0.ZK + assert P0**1 == P0 + assert P0**6 == 7 * P0.ZK + + +def test_decomp_2(): + # More easy cyclotomic cases, but here we check unramified primes. + ell = 7 + T = Poly(cyclotomic_poly(ell)) + for p in [29, 13, 11, 5]: + f_exp = n_order(p, ell) + g_exp = (ell - 1) // f_exp + P = prime_decomp(p, T) + assert len(P) == g_exp + for Pi in P: + assert Pi.e == 1 + assert Pi.f == f_exp + + +def test_decomp_3(): + T = Poly(x ** 2 - 35) + rad = {} + ZK, dK = round_two(T, radicals=rad) + # 35 is 3 mod 4, so field disc is 4*5*7, and theory says each of the + # rational primes 2, 5, 7 should be the square of a prime ideal. + for p in [2, 5, 7]: + P = prime_decomp(p, T, dK=dK, ZK=ZK, radical=rad.get(p)) + assert len(P) == 1 + assert P[0].e == 2 + assert P[0]**2 == p*ZK + + +def test_decomp_4(): + T = Poly(x ** 2 - 21) + rad = {} + ZK, dK = round_two(T, radicals=rad) + # 21 is 1 mod 4, so field disc is 3*7, and theory says the + # rational primes 3, 7 should be the square of a prime ideal. + for p in [3, 7]: + P = prime_decomp(p, T, dK=dK, ZK=ZK, radical=rad.get(p)) + assert len(P) == 1 + assert P[0].e == 2 + assert P[0]**2 == p*ZK + + +def test_decomp_5(): + # Here is our first test of the "hard case" of prime decomposition. + # We work in a quadratic extension Q(sqrt(d)) where d is 1 mod 4, and + # we consider the factorization of the rational prime 2, which divides + # the index. + # Theory says the form of p's factorization depends on the residue of + # d mod 8, so we consider both cases, d = 1 mod 8 and d = 5 mod 8. + for d in [-7, -3]: + T = Poly(x ** 2 - d) + rad = {} + ZK, dK = round_two(T, radicals=rad) + p = 2 + P = prime_decomp(p, T, dK=dK, ZK=ZK, radical=rad.get(p)) + if d % 8 == 1: + assert len(P) == 2 + assert all(P[i].e == 1 and P[i].f == 1 for i in range(2)) + assert prod(Pi**Pi.e for Pi in P) == p * ZK + else: + assert d % 8 == 5 + assert len(P) == 1 + assert P[0].e == 1 + assert P[0].f == 2 + assert P[0].as_submodule() == p * ZK + + +def test_decomp_6(): + # Another case where 2 divides the index. This is Dedekind's example of + # an essential discriminant divisor. (See Cohen, Exercise 6.10.) + T = Poly(x ** 3 + x ** 2 - 2 * x + 8) + rad = {} + ZK, dK = round_two(T, radicals=rad) + p = 2 + P = prime_decomp(p, T, dK=dK, ZK=ZK, radical=rad.get(p)) + assert len(P) == 3 + assert all(Pi.e == Pi.f == 1 for Pi in P) + assert prod(Pi**Pi.e for Pi in P) == p*ZK + + +def test_decomp_7(): + # Try working through an AlgebraicField + T = Poly(x ** 3 + x ** 2 - 2 * x + 8) + K = QQ.alg_field_from_poly(T) + p = 2 + P = K.primes_above(p) + ZK = K.maximal_order() + assert len(P) == 3 + assert all(Pi.e == Pi.f == 1 for Pi in P) + assert prod(Pi**Pi.e for Pi in P) == p*ZK + + +def test_decomp_8(): + # This time we consider various cubics, and try factoring all primes + # dividing the index. + cases = ( + x ** 3 + 3 * x ** 2 - 4 * x + 4, + x ** 3 + 3 * x ** 2 + 3 * x - 3, + x ** 3 + 5 * x ** 2 - x + 3, + x ** 3 + 5 * x ** 2 - 5 * x - 5, + x ** 3 + 3 * x ** 2 + 5, + x ** 3 + 6 * x ** 2 + 3 * x - 1, + x ** 3 + 6 * x ** 2 + 4, + x ** 3 + 7 * x ** 2 + 7 * x - 7, + x ** 3 + 7 * x ** 2 - x + 5, + x ** 3 + 7 * x ** 2 - 5 * x + 5, + x ** 3 + 4 * x ** 2 - 3 * x + 7, + x ** 3 + 8 * x ** 2 + 5 * x - 1, + x ** 3 + 8 * x ** 2 - 2 * x + 6, + x ** 3 + 6 * x ** 2 - 3 * x + 8, + x ** 3 + 9 * x ** 2 + 6 * x - 8, + x ** 3 + 15 * x ** 2 - 9 * x + 13, + ) + def display(T, p, radical, P, I, J): + """Useful for inspection, when running test manually.""" + print('=' * 20) + print(T, p, radical) + for Pi in P: + print(f' ({Pi!r})') + print("I: ", I) + print("J: ", J) + print(f'Equal: {I == J}') + inspect = False + for g in cases: + T = Poly(g) + rad = {} + ZK, dK = round_two(T, radicals=rad) + dT = T.discriminant() + f_squared = dT // dK + F = factorint(f_squared) + for p in F: + radical = rad.get(p) + P = prime_decomp(p, T, dK=dK, ZK=ZK, radical=radical) + I = prod(Pi**Pi.e for Pi in P) + J = p * ZK + if inspect: + display(T, p, radical, P, I, J) + assert I == J + + +def test_PrimeIdeal_eq(): + # `==` should fail on objects of different types, so even a completely + # inert PrimeIdeal should test unequal to the rational prime it divides. + T = Poly(cyclotomic_poly(7)) + P0 = prime_decomp(5, T)[0] + assert P0.f == 6 + assert P0.as_submodule() == 5 * P0.ZK + assert P0 != 5 + + +def test_PrimeIdeal_add(): + T = Poly(cyclotomic_poly(7)) + P0 = prime_decomp(7, T)[0] + # Adding ideals computes their GCD, so adding the ramified prime dividing + # 7 to 7 itself should reproduce this prime (as a submodule). + assert P0 + 7 * P0.ZK == P0.as_submodule() + + +def test_str(): + # Without alias: + k = QQ.alg_field_from_poly(Poly(x**2 + 7)) + frp = k.primes_above(2)[0] + assert str(frp) == '(2, 3*_x/2 + 1/2)' + + frp = k.primes_above(3)[0] + assert str(frp) == '(3)' + + # With alias: + k = QQ.alg_field_from_poly(Poly(x ** 2 + 7), alias='alpha') + frp = k.primes_above(2)[0] + assert str(frp) == '(2, 3*alpha/2 + 1/2)' + + frp = k.primes_above(3)[0] + assert str(frp) == '(3)' + + +def test_repr(): + T = Poly(x**2 + 7) + ZK, dK = round_two(T) + P = prime_decomp(2, T, dK=dK, ZK=ZK) + assert repr(P[0]) == '[ (2, (3*x + 1)/2) e=1, f=1 ]' + assert P[0].repr(field_gen=theta) == '[ (2, (3*theta + 1)/2) e=1, f=1 ]' + assert P[0].repr(field_gen=theta, just_gens=True) == '(2, (3*theta + 1)/2)' + + +def test_PrimeIdeal_reduce(): + k = QQ.alg_field_from_poly(Poly(x ** 3 + x ** 2 - 2 * x + 8)) + Zk = k.maximal_order() + P = k.primes_above(2) + frp = P[2] + + # reduce_element + a = Zk.parent(to_col([23, 20, 11]), denom=6) + a_bar_expected = Zk.parent(to_col([11, 5, 2]), denom=6) + a_bar = frp.reduce_element(a) + assert a_bar == a_bar_expected + + # reduce_ANP + a = k([QQ(11, 6), QQ(20, 6), QQ(23, 6)]) + a_bar_expected = k([QQ(2, 6), QQ(5, 6), QQ(11, 6)]) + a_bar = frp.reduce_ANP(a) + assert a_bar == a_bar_expected + + # reduce_alg_num + a = k.to_alg_num(a) + a_bar_expected = k.to_alg_num(a_bar_expected) + a_bar = frp.reduce_alg_num(a) + assert a_bar == a_bar_expected + + +def test_issue_23402(): + k = QQ.alg_field_from_poly(Poly(x ** 3 + x ** 2 - 2 * x + 8)) + P = k.primes_above(3) + assert P[0].alpha.equiv(0) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_subfield.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_subfield.py new file mode 100644 index 0000000000000000000000000000000000000000..b152dd684aa20034f9233eedb1866aac2639b5f9 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_subfield.py @@ -0,0 +1,317 @@ +"""Tests for the subfield problem and allied problems. """ + +from sympy.core.numbers import (AlgebraicNumber, I, pi, Rational) +from sympy.core.singleton import S +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.external.gmpy import MPQ +from sympy.polys.numberfields.subfield import ( + is_isomorphism_possible, + field_isomorphism_pslq, + field_isomorphism, + primitive_element, + to_number_field, +) +from sympy.polys.domains import QQ +from sympy.polys.polyerrors import IsomorphismFailed +from sympy.polys.polytools import Poly +from sympy.polys.rootoftools import CRootOf +from sympy.testing.pytest import raises + +from sympy.abc import x + +Q = Rational + + +def test_field_isomorphism_pslq(): + a = AlgebraicNumber(I) + b = AlgebraicNumber(I*sqrt(3)) + + raises(NotImplementedError, lambda: field_isomorphism_pslq(a, b)) + + a = AlgebraicNumber(sqrt(2)) + b = AlgebraicNumber(sqrt(3)) + c = AlgebraicNumber(sqrt(7)) + d = AlgebraicNumber(sqrt(2) + sqrt(3)) + e = AlgebraicNumber(sqrt(2) + sqrt(3) + sqrt(7)) + + assert field_isomorphism_pslq(a, a) == [1, 0] + assert field_isomorphism_pslq(a, b) is None + assert field_isomorphism_pslq(a, c) is None + assert field_isomorphism_pslq(a, d) == [Q(1, 2), 0, -Q(9, 2), 0] + assert field_isomorphism_pslq( + a, e) == [Q(1, 80), 0, -Q(1, 2), 0, Q(59, 20), 0] + + assert field_isomorphism_pslq(b, a) is None + assert field_isomorphism_pslq(b, b) == [1, 0] + assert field_isomorphism_pslq(b, c) is None + assert field_isomorphism_pslq(b, d) == [-Q(1, 2), 0, Q(11, 2), 0] + assert field_isomorphism_pslq(b, e) == [-Q( + 3, 640), 0, Q(67, 320), 0, -Q(297, 160), 0, Q(313, 80), 0] + + assert field_isomorphism_pslq(c, a) is None + assert field_isomorphism_pslq(c, b) is None + assert field_isomorphism_pslq(c, c) == [1, 0] + assert field_isomorphism_pslq(c, d) is None + assert field_isomorphism_pslq(c, e) == [Q( + 3, 640), 0, -Q(71, 320), 0, Q(377, 160), 0, -Q(469, 80), 0] + + assert field_isomorphism_pslq(d, a) is None + assert field_isomorphism_pslq(d, b) is None + assert field_isomorphism_pslq(d, c) is None + assert field_isomorphism_pslq(d, d) == [1, 0] + assert field_isomorphism_pslq(d, e) == [-Q( + 3, 640), 0, Q(71, 320), 0, -Q(377, 160), 0, Q(549, 80), 0] + + assert field_isomorphism_pslq(e, a) is None + assert field_isomorphism_pslq(e, b) is None + assert field_isomorphism_pslq(e, c) is None + assert field_isomorphism_pslq(e, d) is None + assert field_isomorphism_pslq(e, e) == [1, 0] + + f = AlgebraicNumber(3*sqrt(2) + 8*sqrt(7) - 5) + + assert field_isomorphism_pslq( + f, e) == [Q(3, 80), 0, -Q(139, 80), 0, Q(347, 20), 0, -Q(761, 20), -5] + + +def test_field_isomorphism(): + assert field_isomorphism(3, sqrt(2)) == [3] + + assert field_isomorphism( I*sqrt(3), I*sqrt(3)/2) == [ 2, 0] + assert field_isomorphism(-I*sqrt(3), I*sqrt(3)/2) == [-2, 0] + + assert field_isomorphism( I*sqrt(3), -I*sqrt(3)/2) == [-2, 0] + assert field_isomorphism(-I*sqrt(3), -I*sqrt(3)/2) == [ 2, 0] + + assert field_isomorphism( 2*I*sqrt(3)/7, 5*I*sqrt(3)/3) == [ Rational(6, 35), 0] + assert field_isomorphism(-2*I*sqrt(3)/7, 5*I*sqrt(3)/3) == [Rational(-6, 35), 0] + + assert field_isomorphism( 2*I*sqrt(3)/7, -5*I*sqrt(3)/3) == [Rational(-6, 35), 0] + assert field_isomorphism(-2*I*sqrt(3)/7, -5*I*sqrt(3)/3) == [ Rational(6, 35), 0] + + assert field_isomorphism( + 2*I*sqrt(3)/7 + 27, 5*I*sqrt(3)/3) == [ Rational(6, 35), 27] + assert field_isomorphism( + -2*I*sqrt(3)/7 + 27, 5*I*sqrt(3)/3) == [Rational(-6, 35), 27] + + assert field_isomorphism( + 2*I*sqrt(3)/7 + 27, -5*I*sqrt(3)/3) == [Rational(-6, 35), 27] + assert field_isomorphism( + -2*I*sqrt(3)/7 + 27, -5*I*sqrt(3)/3) == [ Rational(6, 35), 27] + + p = AlgebraicNumber( sqrt(2) + sqrt(3)) + q = AlgebraicNumber(-sqrt(2) + sqrt(3)) + r = AlgebraicNumber( sqrt(2) - sqrt(3)) + s = AlgebraicNumber(-sqrt(2) - sqrt(3)) + + pos_coeffs = [ S.Half, S.Zero, Rational(-9, 2), S.Zero] + neg_coeffs = [Rational(-1, 2), S.Zero, Rational(9, 2), S.Zero] + + a = AlgebraicNumber(sqrt(2)) + + assert is_isomorphism_possible(a, p) is True + assert is_isomorphism_possible(a, q) is True + assert is_isomorphism_possible(a, r) is True + assert is_isomorphism_possible(a, s) is True + + assert field_isomorphism(a, p, fast=True) == pos_coeffs + assert field_isomorphism(a, q, fast=True) == neg_coeffs + assert field_isomorphism(a, r, fast=True) == pos_coeffs + assert field_isomorphism(a, s, fast=True) == neg_coeffs + + assert field_isomorphism(a, p, fast=False) == pos_coeffs + assert field_isomorphism(a, q, fast=False) == neg_coeffs + assert field_isomorphism(a, r, fast=False) == pos_coeffs + assert field_isomorphism(a, s, fast=False) == neg_coeffs + + a = AlgebraicNumber(-sqrt(2)) + + assert is_isomorphism_possible(a, p) is True + assert is_isomorphism_possible(a, q) is True + assert is_isomorphism_possible(a, r) is True + assert is_isomorphism_possible(a, s) is True + + assert field_isomorphism(a, p, fast=True) == neg_coeffs + assert field_isomorphism(a, q, fast=True) == pos_coeffs + assert field_isomorphism(a, r, fast=True) == neg_coeffs + assert field_isomorphism(a, s, fast=True) == pos_coeffs + + assert field_isomorphism(a, p, fast=False) == neg_coeffs + assert field_isomorphism(a, q, fast=False) == pos_coeffs + assert field_isomorphism(a, r, fast=False) == neg_coeffs + assert field_isomorphism(a, s, fast=False) == pos_coeffs + + pos_coeffs = [ S.Half, S.Zero, Rational(-11, 2), S.Zero] + neg_coeffs = [Rational(-1, 2), S.Zero, Rational(11, 2), S.Zero] + + a = AlgebraicNumber(sqrt(3)) + + assert is_isomorphism_possible(a, p) is True + assert is_isomorphism_possible(a, q) is True + assert is_isomorphism_possible(a, r) is True + assert is_isomorphism_possible(a, s) is True + + assert field_isomorphism(a, p, fast=True) == neg_coeffs + assert field_isomorphism(a, q, fast=True) == neg_coeffs + assert field_isomorphism(a, r, fast=True) == pos_coeffs + assert field_isomorphism(a, s, fast=True) == pos_coeffs + + assert field_isomorphism(a, p, fast=False) == neg_coeffs + assert field_isomorphism(a, q, fast=False) == neg_coeffs + assert field_isomorphism(a, r, fast=False) == pos_coeffs + assert field_isomorphism(a, s, fast=False) == pos_coeffs + + a = AlgebraicNumber(-sqrt(3)) + + assert is_isomorphism_possible(a, p) is True + assert is_isomorphism_possible(a, q) is True + assert is_isomorphism_possible(a, r) is True + assert is_isomorphism_possible(a, s) is True + + assert field_isomorphism(a, p, fast=True) == pos_coeffs + assert field_isomorphism(a, q, fast=True) == pos_coeffs + assert field_isomorphism(a, r, fast=True) == neg_coeffs + assert field_isomorphism(a, s, fast=True) == neg_coeffs + + assert field_isomorphism(a, p, fast=False) == pos_coeffs + assert field_isomorphism(a, q, fast=False) == pos_coeffs + assert field_isomorphism(a, r, fast=False) == neg_coeffs + assert field_isomorphism(a, s, fast=False) == neg_coeffs + + pos_coeffs = [ Rational(3, 2), S.Zero, Rational(-33, 2), -S(8)] + neg_coeffs = [Rational(-3, 2), S.Zero, Rational(33, 2), -S(8)] + + a = AlgebraicNumber(3*sqrt(3) - 8) + + assert is_isomorphism_possible(a, p) is True + assert is_isomorphism_possible(a, q) is True + assert is_isomorphism_possible(a, r) is True + assert is_isomorphism_possible(a, s) is True + + assert field_isomorphism(a, p, fast=True) == neg_coeffs + assert field_isomorphism(a, q, fast=True) == neg_coeffs + assert field_isomorphism(a, r, fast=True) == pos_coeffs + assert field_isomorphism(a, s, fast=True) == pos_coeffs + + assert field_isomorphism(a, p, fast=False) == neg_coeffs + assert field_isomorphism(a, q, fast=False) == neg_coeffs + assert field_isomorphism(a, r, fast=False) == pos_coeffs + assert field_isomorphism(a, s, fast=False) == pos_coeffs + + a = AlgebraicNumber(3*sqrt(2) + 2*sqrt(3) + 1) + + pos_1_coeffs = [ S.Half, S.Zero, Rational(-5, 2), S.One] + neg_5_coeffs = [Rational(-5, 2), S.Zero, Rational(49, 2), S.One] + pos_5_coeffs = [ Rational(5, 2), S.Zero, Rational(-49, 2), S.One] + neg_1_coeffs = [Rational(-1, 2), S.Zero, Rational(5, 2), S.One] + + assert is_isomorphism_possible(a, p) is True + assert is_isomorphism_possible(a, q) is True + assert is_isomorphism_possible(a, r) is True + assert is_isomorphism_possible(a, s) is True + + assert field_isomorphism(a, p, fast=True) == pos_1_coeffs + assert field_isomorphism(a, q, fast=True) == neg_5_coeffs + assert field_isomorphism(a, r, fast=True) == pos_5_coeffs + assert field_isomorphism(a, s, fast=True) == neg_1_coeffs + + assert field_isomorphism(a, p, fast=False) == pos_1_coeffs + assert field_isomorphism(a, q, fast=False) == neg_5_coeffs + assert field_isomorphism(a, r, fast=False) == pos_5_coeffs + assert field_isomorphism(a, s, fast=False) == neg_1_coeffs + + a = AlgebraicNumber(sqrt(2)) + b = AlgebraicNumber(sqrt(3)) + c = AlgebraicNumber(sqrt(7)) + + assert is_isomorphism_possible(a, b) is True + assert is_isomorphism_possible(b, a) is True + + assert is_isomorphism_possible(c, p) is False + + assert field_isomorphism(sqrt(2), sqrt(3), fast=True) is None + assert field_isomorphism(sqrt(3), sqrt(2), fast=True) is None + + assert field_isomorphism(sqrt(2), sqrt(3), fast=False) is None + assert field_isomorphism(sqrt(3), sqrt(2), fast=False) is None + + a = AlgebraicNumber(sqrt(2)) + b = AlgebraicNumber(2 ** (S(1) / 3)) + + assert is_isomorphism_possible(a, b) is False + assert field_isomorphism(a, b) is None + + +def test_primitive_element(): + assert primitive_element([sqrt(2)], x) == (x**2 - 2, [1]) + assert primitive_element( + [sqrt(2), sqrt(3)], x) == (x**4 - 10*x**2 + 1, [1, 1]) + + assert primitive_element([sqrt(2)], x, polys=True) == (Poly(x**2 - 2, domain='QQ'), [1]) + assert primitive_element([sqrt( + 2), sqrt(3)], x, polys=True) == (Poly(x**4 - 10*x**2 + 1, domain='QQ'), [1, 1]) + + assert primitive_element( + [sqrt(2)], x, ex=True) == (x**2 - 2, [1], [[1, 0]]) + assert primitive_element([sqrt(2), sqrt(3)], x, ex=True) == \ + (x**4 - 10*x**2 + 1, [1, 1], [[Q(1, 2), 0, -Q(9, 2), 0], [- + Q(1, 2), 0, Q(11, 2), 0]]) + + assert primitive_element( + [sqrt(2)], x, ex=True, polys=True) == (Poly(x**2 - 2, domain='QQ'), [1], [[1, 0]]) + assert primitive_element([sqrt(2), sqrt(3)], x, ex=True, polys=True) == \ + (Poly(x**4 - 10*x**2 + 1, domain='QQ'), [1, 1], [[Q(1, 2), 0, -Q(9, 2), + 0], [-Q(1, 2), 0, Q(11, 2), 0]]) + + assert primitive_element([sqrt(2)], polys=True) == (Poly(x**2 - 2), [1]) + + raises(ValueError, lambda: primitive_element([], x, ex=False)) + raises(ValueError, lambda: primitive_element([], x, ex=True)) + + # Issue 14117 + a, b = I*sqrt(2*sqrt(2) + 3), I*sqrt(-2*sqrt(2) + 3) + assert primitive_element([a, b, I], x) == (x**4 + 6*x**2 + 1, [1, 0, 0]) + + assert primitive_element([sqrt(2), 0], x) == (x**2 - 2, [1, 0]) + assert primitive_element([0, sqrt(2)], x) == (x**2 - 2, [1, 1]) + assert primitive_element([sqrt(2), 0], x, ex=True) == (x**2 - 2, [1, 0], [[MPQ(1,1), MPQ(0,1)], []]) + assert primitive_element([0, sqrt(2)], x, ex=True) == (x**2 - 2, [1, 1], [[], [MPQ(1,1), MPQ(0,1)]]) + + +def test_to_number_field(): + assert to_number_field(sqrt(2)) == AlgebraicNumber(sqrt(2)) + assert to_number_field( + [sqrt(2), sqrt(3)]) == AlgebraicNumber(sqrt(2) + sqrt(3)) + + a = AlgebraicNumber(sqrt(2) + sqrt(3), [S.Half, S.Zero, Rational(-9, 2), S.Zero]) + + assert to_number_field(sqrt(2), sqrt(2) + sqrt(3)) == a + assert to_number_field(sqrt(2), AlgebraicNumber(sqrt(2) + sqrt(3))) == a + + raises(IsomorphismFailed, lambda: to_number_field(sqrt(2), sqrt(3))) + + +def test_issue_22561(): + a = to_number_field(sqrt(2), sqrt(2) + sqrt(3)) + b = to_number_field(sqrt(2), sqrt(2) + sqrt(5)) + assert field_isomorphism(a, b) == [1, 0] + + +def test_issue_22736(): + a = CRootOf(x**4 + x**3 + x**2 + x + 1, -1) + a._reset() + b = exp(2*I*pi/5) + assert field_isomorphism(a, b) == [1, 0] + + +def test_issue_27798(): + # https://github.com/sympy/sympy/issues/27798 + a, b = CRootOf(49*x**3 - 49*x**2 + 14*x - 1, 2), CRootOf(49*x**3 - 49*x**2 + 14*x - 1, 0) + assert primitive_element([a, b], polys=True)[0].primitive()[0] == 1 + assert primitive_element([a, b], polys=True, ex=True)[0].primitive()[0] == 1 + + f1, f2 = QQ.algebraic_field(a), QQ.algebraic_field(b) + f3 = f1.unify(f2) + assert f3.mod.primitive()[0] == 1 + assert Poly(x, x, domain=f1) + Poly(x, x, domain=f2) == Poly(2*x, x, domain=f3) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_utilities.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_utilities.py new file mode 100644 index 0000000000000000000000000000000000000000..134853ef0c88045ef9cc7e215bb98db37041e63a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/tests/test_utilities.py @@ -0,0 +1,113 @@ +from sympy.abc import x +from sympy.core.numbers import (I, Rational) +from sympy.core.singleton import S +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.polys import Poly, cyclotomic_poly +from sympy.polys.domains import FF, QQ +from sympy.polys.matrices import DomainMatrix, DM +from sympy.polys.matrices.exceptions import DMRankError +from sympy.polys.numberfields.utilities import ( + AlgIntPowers, coeff_search, extract_fundamental_discriminant, + isolate, supplement_a_subspace, +) +from sympy.printing.lambdarepr import IntervalPrinter +from sympy.testing.pytest import raises + + +def test_AlgIntPowers_01(): + T = Poly(cyclotomic_poly(5)) + zeta_pow = AlgIntPowers(T) + raises(ValueError, lambda: zeta_pow[-1]) + for e in range(10): + a = e % 5 + if a < 4: + c = zeta_pow[e] + assert c[a] == 1 and all(c[i] == 0 for i in range(4) if i != a) + else: + assert zeta_pow[e] == [-1] * 4 + + +def test_AlgIntPowers_02(): + T = Poly(x**3 + 2*x**2 + 3*x + 4) + m = 7 + theta_pow = AlgIntPowers(T, m) + for e in range(10): + computed = theta_pow[e] + coeffs = (Poly(x)**e % T + Poly(x**3)).rep.to_list()[1:] + expected = [c % m for c in reversed(coeffs)] + assert computed == expected + + +def test_coeff_search(): + C = [] + search = coeff_search(2, 1) + for i, c in enumerate(search): + C.append(c) + if i == 12: + break + assert C == [[1, 1], [1, 0], [1, -1], [0, 1], [2, 2], [2, 1], [2, 0], [2, -1], [2, -2], [1, 2], [1, -2], [0, 2], [3, 3]] + + +def test_extract_fundamental_discriminant(): + # To extract, integer must be 0 or 1 mod 4. + raises(ValueError, lambda: extract_fundamental_discriminant(2)) + raises(ValueError, lambda: extract_fundamental_discriminant(3)) + # Try many cases, of different forms: + cases = ( + (0, {}, {0: 1}), + (1, {}, {}), + (8, {2: 3}, {}), + (-8, {2: 3, -1: 1}, {}), + (12, {2: 2, 3: 1}, {}), + (36, {}, {2: 1, 3: 1}), + (45, {5: 1}, {3: 1}), + (48, {2: 2, 3: 1}, {2: 1}), + (1125, {5: 1}, {3: 1, 5: 1}), + ) + for a, D_expected, F_expected in cases: + D, F = extract_fundamental_discriminant(a) + assert D == D_expected + assert F == F_expected + + +def test_supplement_a_subspace_1(): + M = DM([[1, 7, 0], [2, 3, 4]], QQ).transpose() + + # First supplement over QQ: + B = supplement_a_subspace(M) + assert B[:, :2] == M + assert B[:, 2] == DomainMatrix.eye(3, QQ).to_dense()[:, 0] + + # Now supplement over FF(7): + M = M.convert_to(FF(7)) + B = supplement_a_subspace(M) + assert B[:, :2] == M + # When we work mod 7, first col of M goes to [1, 0, 0], + # so the supplementary vector cannot equal this, as it did + # when we worked over QQ. Instead, we get the second std basis vector: + assert B[:, 2] == DomainMatrix.eye(3, FF(7)).to_dense()[:, 1] + + +def test_supplement_a_subspace_2(): + M = DM([[1, 0, 0], [2, 0, 0]], QQ).transpose() + with raises(DMRankError): + supplement_a_subspace(M) + + +def test_IntervalPrinter(): + ip = IntervalPrinter() + assert ip.doprint(x**Rational(1, 3)) == "x**(mpi('1/3'))" + assert ip.doprint(sqrt(x)) == "x**(mpi('1/2'))" + + +def test_isolate(): + assert isolate(1) == (1, 1) + assert isolate(S.Half) == (S.Half, S.Half) + + assert isolate(sqrt(2)) == (1, 2) + assert isolate(-sqrt(2)) == (-2, -1) + + assert isolate(sqrt(2), eps=Rational(1, 100)) == (Rational(24, 17), Rational(17, 12)) + assert isolate(-sqrt(2), eps=Rational(1, 100)) == (Rational(-17, 12), Rational(-24, 17)) + + raises(NotImplementedError, lambda: isolate(I)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/utilities.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/utilities.py new file mode 100644 index 0000000000000000000000000000000000000000..fe583efb440f02f1b16c38fb7d03621c1f97e83d --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/numberfields/utilities.py @@ -0,0 +1,474 @@ +"""Utilities for algebraic number theory. """ + +from sympy.core.sympify import sympify +from sympy.ntheory.factor_ import factorint +from sympy.polys.domains.rationalfield import QQ +from sympy.polys.domains.integerring import ZZ +from sympy.polys.matrices.exceptions import DMRankError +from sympy.polys.numberfields.minpoly import minpoly +from sympy.printing.lambdarepr import IntervalPrinter +from sympy.utilities.decorator import public +from sympy.utilities.lambdify import lambdify + +from mpmath import mp + + +def is_rat(c): + r""" + Test whether an argument is of an acceptable type to be used as a rational + number. + + Explanation + =========== + + Returns ``True`` on any argument of type ``int``, :ref:`ZZ`, or :ref:`QQ`. + + See Also + ======== + + is_int + + """ + # ``c in QQ`` is too accepting (e.g. ``3.14 in QQ`` is ``True``), + # ``QQ.of_type(c)`` is too demanding (e.g. ``QQ.of_type(3)`` is ``False``). + # + # Meanwhile, if gmpy2 is installed then ``ZZ.of_type()`` accepts only + # ``mpz``, not ``int``, so we need another clause to ensure ``int`` is + # accepted. + return isinstance(c, int) or ZZ.of_type(c) or QQ.of_type(c) + + +def is_int(c): + r""" + Test whether an argument is of an acceptable type to be used as an integer. + + Explanation + =========== + + Returns ``True`` on any argument of type ``int`` or :ref:`ZZ`. + + See Also + ======== + + is_rat + + """ + # If gmpy2 is installed then ``ZZ.of_type()`` accepts only + # ``mpz``, not ``int``, so we need another clause to ensure ``int`` is + # accepted. + return isinstance(c, int) or ZZ.of_type(c) + + +def get_num_denom(c): + r""" + Given any argument on which :py:func:`~.is_rat` is ``True``, return the + numerator and denominator of this number. + + See Also + ======== + + is_rat + + """ + r = QQ(c) + return r.numerator, r.denominator + + +@public +def extract_fundamental_discriminant(a): + r""" + Extract a fundamental discriminant from an integer *a*. + + Explanation + =========== + + Given any rational integer *a* that is 0 or 1 mod 4, write $a = d f^2$, + where $d$ is either 1 or a fundamental discriminant, and return a pair + of dictionaries ``(D, F)`` giving the prime factorizations of $d$ and $f$ + respectively, in the same format returned by :py:func:`~.factorint`. + + A fundamental discriminant $d$ is different from unity, and is either + 1 mod 4 and squarefree, or is 0 mod 4 and such that $d/4$ is squarefree + and 2 or 3 mod 4. This is the same as being the discriminant of some + quadratic field. + + Examples + ======== + + >>> from sympy.polys.numberfields.utilities import extract_fundamental_discriminant + >>> print(extract_fundamental_discriminant(-432)) + ({3: 1, -1: 1}, {2: 2, 3: 1}) + + For comparison: + + >>> from sympy import factorint + >>> print(factorint(-432)) + {2: 4, 3: 3, -1: 1} + + Parameters + ========== + + a: int, must be 0 or 1 mod 4 + + Returns + ======= + + Pair ``(D, F)`` of dictionaries. + + Raises + ====== + + ValueError + If *a* is not 0 or 1 mod 4. + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory.* + (See Prop. 5.1.3) + + """ + if a % 4 not in [0, 1]: + raise ValueError('To extract fundamental discriminant, number must be 0 or 1 mod 4.') + if a == 0: + return {}, {0: 1} + if a == 1: + return {}, {} + a_factors = factorint(a) + D = {} + F = {} + # First pass: just make d squarefree, and a/d a perfect square. + # We'll count primes (and units! i.e. -1) that are 3 mod 4 and present in d. + num_3_mod_4 = 0 + for p, e in a_factors.items(): + if e % 2 == 1: + D[p] = 1 + if p % 4 == 3: + num_3_mod_4 += 1 + if e >= 3: + F[p] = (e - 1) // 2 + else: + F[p] = e // 2 + # Second pass: if d is cong. to 2 or 3 mod 4, then we must steal away + # another factor of 4 from f**2 and give it to d. + even = 2 in D + if even or num_3_mod_4 % 2 == 1: + e2 = F[2] + assert e2 > 0 + if e2 == 1: + del F[2] + else: + F[2] = e2 - 1 + D[2] = 3 if even else 2 + return D, F + + +@public +class AlgIntPowers: + r""" + Compute the powers of an algebraic integer. + + Explanation + =========== + + Given an algebraic integer $\theta$ by its monic irreducible polynomial + ``T`` over :ref:`ZZ`, this class computes representations of arbitrarily + high powers of $\theta$, as :ref:`ZZ`-linear combinations over + $\{1, \theta, \ldots, \theta^{n-1}\}$, where $n = \deg(T)$. + + The representations are computed using the linear recurrence relations for + powers of $\theta$, derived from the polynomial ``T``. See [1], Sec. 4.2.2. + + Optionally, the representations may be reduced with respect to a modulus. + + Examples + ======== + + >>> from sympy import Poly, cyclotomic_poly + >>> from sympy.polys.numberfields.utilities import AlgIntPowers + >>> T = Poly(cyclotomic_poly(5)) + >>> zeta_pow = AlgIntPowers(T) + >>> print(zeta_pow[0]) + [1, 0, 0, 0] + >>> print(zeta_pow[1]) + [0, 1, 0, 0] + >>> print(zeta_pow[4]) # doctest: +SKIP + [-1, -1, -1, -1] + >>> print(zeta_pow[24]) # doctest: +SKIP + [-1, -1, -1, -1] + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory.* + + """ + + def __init__(self, T, modulus=None): + """ + Parameters + ========== + + T : :py:class:`~.Poly` + The monic irreducible polynomial over :ref:`ZZ` defining the + algebraic integer. + + modulus : int, None, optional + If not ``None``, all representations will be reduced w.r.t. this. + + """ + self.T = T + self.modulus = modulus + self.n = T.degree() + self.powers_n_and_up = [[-c % self for c in reversed(T.rep.to_list())][:-1]] + self.max_so_far = self.n + + def red(self, exp): + return exp if self.modulus is None else exp % self.modulus + + def __rmod__(self, other): + return self.red(other) + + def compute_up_through(self, e): + m = self.max_so_far + if e <= m: return + n = self.n + r = self.powers_n_and_up + c = r[0] + for k in range(m+1, e+1): + b = r[k-1-n][n-1] + r.append( + [c[0]*b % self] + [ + (r[k-1-n][i-1] + c[i]*b) % self for i in range(1, n) + ] + ) + self.max_so_far = e + + def get(self, e): + n = self.n + if e < 0: + raise ValueError('Exponent must be non-negative.') + elif e < n: + return [1 if i == e else 0 for i in range(n)] + else: + self.compute_up_through(e) + return self.powers_n_and_up[e - n] + + def __getitem__(self, item): + return self.get(item) + + +@public +def coeff_search(m, R): + r""" + Generate coefficients for searching through polynomials. + + Explanation + =========== + + Lead coeff is always non-negative. Explore all combinations with coeffs + bounded in absolute value before increasing the bound. Skip the all-zero + list, and skip any repeats. See examples. + + Examples + ======== + + >>> from sympy.polys.numberfields.utilities import coeff_search + >>> cs = coeff_search(2, 1) + >>> C = [next(cs) for i in range(13)] + >>> print(C) + [[1, 1], [1, 0], [1, -1], [0, 1], [2, 2], [2, 1], [2, 0], [2, -1], [2, -2], + [1, 2], [1, -2], [0, 2], [3, 3]] + + Parameters + ========== + + m : int + Length of coeff list. + R : int + Initial max abs val for coeffs (will increase as search proceeds). + + Returns + ======= + + generator + Infinite generator of lists of coefficients. + + """ + R0 = R + c = [R] * m + while True: + if R == R0 or R in c or -R in c: + yield c[:] + j = m - 1 + while c[j] == -R: + j -= 1 + c[j] -= 1 + for i in range(j + 1, m): + c[i] = R + for j in range(m): + if c[j] != 0: + break + else: + R += 1 + c = [R] * m + + +def supplement_a_subspace(M): + r""" + Extend a basis for a subspace to a basis for the whole space. + + Explanation + =========== + + Given an $n \times r$ matrix *M* of rank $r$ (so $r \leq n$), this function + computes an invertible $n \times n$ matrix $B$ such that the first $r$ + columns of $B$ equal *M*. + + This operation can be interpreted as a way of extending a basis for a + subspace, to give a basis for the whole space. + + To be precise, suppose you have an $n$-dimensional vector space $V$, with + basis $\{v_1, v_2, \ldots, v_n\}$, and an $r$-dimensional subspace $W$ of + $V$, spanned by a basis $\{w_1, w_2, \ldots, w_r\}$, where the $w_j$ are + given as linear combinations of the $v_i$. If the columns of *M* represent + the $w_j$ as such linear combinations, then the columns of the matrix $B$ + computed by this function give a new basis $\{u_1, u_2, \ldots, u_n\}$ for + $V$, again relative to the $\{v_i\}$ basis, and such that $u_j = w_j$ + for $1 \leq j \leq r$. + + Examples + ======== + + Note: The function works in terms of columns, so in these examples we + print matrix transposes in order to make the columns easier to inspect. + + >>> from sympy.polys.matrices import DM + >>> from sympy import QQ, FF + >>> from sympy.polys.numberfields.utilities import supplement_a_subspace + >>> M = DM([[1, 7, 0], [2, 3, 4]], QQ).transpose() + >>> print(supplement_a_subspace(M).to_Matrix().transpose()) + Matrix([[1, 7, 0], [2, 3, 4], [1, 0, 0]]) + + >>> M2 = M.convert_to(FF(7)) + >>> print(M2.to_Matrix().transpose()) + Matrix([[1, 0, 0], [2, 3, -3]]) + >>> print(supplement_a_subspace(M2).to_Matrix().transpose()) + Matrix([[1, 0, 0], [2, 3, -3], [0, 1, 0]]) + + Parameters + ========== + + M : :py:class:`~.DomainMatrix` + The columns give the basis for the subspace. + + Returns + ======= + + :py:class:`~.DomainMatrix` + This matrix is invertible and its first $r$ columns equal *M*. + + Raises + ====== + + DMRankError + If *M* was not of maximal rank. + + References + ========== + + .. [1] Cohen, H. *A Course in Computational Algebraic Number Theory* + (See Sec. 2.3.2.) + + """ + n, r = M.shape + # Let In be the n x n identity matrix. + # Form the augmented matrix [M | In] and compute RREF. + Maug = M.hstack(M.eye(n, M.domain)) + R, pivots = Maug.rref() + if pivots[:r] != tuple(range(r)): + raise DMRankError('M was not of maximal rank') + # Let J be the n x r matrix equal to the first r columns of In. + # Since M is of rank r, RREF reduces [M | In] to [J | A], where A is the product of + # elementary matrices Ei corresp. to the row ops performed by RREF. Since the Ei are + # invertible, so is A. Let B = A^(-1). + A = R[:, r:] + B = A.inv() + # Then B is the desired matrix. It is invertible, since B^(-1) == A. + # And A * [M | In] == [J | A] + # => A * M == J + # => M == B * J == the first r columns of B. + return B + + +@public +def isolate(alg, eps=None, fast=False): + """ + Find a rational isolating interval for a real algebraic number. + + Examples + ======== + + >>> from sympy import isolate, sqrt, Rational + >>> print(isolate(sqrt(2))) # doctest: +SKIP + (1, 2) + >>> print(isolate(sqrt(2), eps=Rational(1, 100))) + (24/17, 17/12) + + Parameters + ========== + + alg : str, int, :py:class:`~.Expr` + The algebraic number to be isolated. Must be a real number, to use this + particular function. However, see also :py:meth:`.Poly.intervals`, + which isolates complex roots when you pass ``all=True``. + eps : positive element of :ref:`QQ`, None, optional (default=None) + Precision to be passed to :py:meth:`.Poly.refine_root` + fast : boolean, optional (default=False) + Say whether fast refinement procedure should be used. + (Will be passed to :py:meth:`.Poly.refine_root`.) + + Returns + ======= + + Pair of rational numbers defining an isolating interval for the given + algebraic number. + + See Also + ======== + + .Poly.intervals + + """ + alg = sympify(alg) + + if alg.is_Rational: + return (alg, alg) + elif not alg.is_real: + raise NotImplementedError( + "complex algebraic numbers are not supported") + + func = lambdify((), alg, modules="mpmath", printer=IntervalPrinter()) + + poly = minpoly(alg, polys=True) + intervals = poly.intervals(sqf=True) + + dps, done = mp.dps, False + + try: + while not done: + alg = func() + + for a, b in intervals: + if a <= alg.a and alg.b <= b: + done = True + break + else: + mp.dps *= 2 + finally: + mp.dps = dps + + if eps is not None: + a, b = poly.refine_root(a, b, eps=eps, fast=fast) + + return (a, b) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_appellseqs.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_appellseqs.py new file mode 100644 index 0000000000000000000000000000000000000000..f4718a2da272ac6f36a968572dc246ebc699e5c4 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_appellseqs.py @@ -0,0 +1,91 @@ +"""Tests for efficient functions for generating Appell sequences.""" +from sympy.core.numbers import Rational as Q +from sympy.polys.polytools import Poly +from sympy.testing.pytest import raises +from sympy.polys.appellseqs import (bernoulli_poly, bernoulli_c_poly, + euler_poly, genocchi_poly, andre_poly) +from sympy.abc import x + +def test_bernoulli_poly(): + raises(ValueError, lambda: bernoulli_poly(-1, x)) + assert bernoulli_poly(1, x, polys=True) == Poly(x - Q(1,2)) + + assert bernoulli_poly(0, x) == 1 + assert bernoulli_poly(1, x) == x - Q(1,2) + assert bernoulli_poly(2, x) == x**2 - x + Q(1,6) + assert bernoulli_poly(3, x) == x**3 - Q(3,2)*x**2 + Q(1,2)*x + assert bernoulli_poly(4, x) == x**4 - 2*x**3 + x**2 - Q(1,30) + assert bernoulli_poly(5, x) == x**5 - Q(5,2)*x**4 + Q(5,3)*x**3 - Q(1,6)*x + assert bernoulli_poly(6, x) == x**6 - 3*x**5 + Q(5,2)*x**4 - Q(1,2)*x**2 + Q(1,42) + + assert bernoulli_poly(1).dummy_eq(x - Q(1,2)) + assert bernoulli_poly(1, polys=True) == Poly(x - Q(1,2)) + +def test_bernoulli_c_poly(): + raises(ValueError, lambda: bernoulli_c_poly(-1, x)) + assert bernoulli_c_poly(1, x, polys=True) == Poly(x, domain='QQ') + + assert bernoulli_c_poly(0, x) == 1 + assert bernoulli_c_poly(1, x) == x + assert bernoulli_c_poly(2, x) == x**2 - Q(1,3) + assert bernoulli_c_poly(3, x) == x**3 - x + assert bernoulli_c_poly(4, x) == x**4 - 2*x**2 + Q(7,15) + assert bernoulli_c_poly(5, x) == x**5 - Q(10,3)*x**3 + Q(7,3)*x + assert bernoulli_c_poly(6, x) == x**6 - 5*x**4 + 7*x**2 - Q(31,21) + + assert bernoulli_c_poly(1).dummy_eq(x) + assert bernoulli_c_poly(1, polys=True) == Poly(x, domain='QQ') + + assert 2**8 * bernoulli_poly(8, (x+1)/2).expand() == bernoulli_c_poly(8, x) + assert 2**9 * bernoulli_poly(9, (x+1)/2).expand() == bernoulli_c_poly(9, x) + +def test_genocchi_poly(): + raises(ValueError, lambda: genocchi_poly(-1, x)) + assert genocchi_poly(2, x, polys=True) == Poly(-2*x + 1) + + assert genocchi_poly(0, x) == 0 + assert genocchi_poly(1, x) == -1 + assert genocchi_poly(2, x) == 1 - 2*x + assert genocchi_poly(3, x) == 3*x - 3*x**2 + assert genocchi_poly(4, x) == -1 + 6*x**2 - 4*x**3 + assert genocchi_poly(5, x) == -5*x + 10*x**3 - 5*x**4 + assert genocchi_poly(6, x) == 3 - 15*x**2 + 15*x**4 - 6*x**5 + + assert genocchi_poly(2).dummy_eq(-2*x + 1) + assert genocchi_poly(2, polys=True) == Poly(-2*x + 1) + + assert 2 * (bernoulli_poly(8, x) - bernoulli_c_poly(8, x)) == genocchi_poly(8, x) + assert 2 * (bernoulli_poly(9, x) - bernoulli_c_poly(9, x)) == genocchi_poly(9, x) + +def test_euler_poly(): + raises(ValueError, lambda: euler_poly(-1, x)) + assert euler_poly(1, x, polys=True) == Poly(x - Q(1,2)) + + assert euler_poly(0, x) == 1 + assert euler_poly(1, x) == x - Q(1,2) + assert euler_poly(2, x) == x**2 - x + assert euler_poly(3, x) == x**3 - Q(3,2)*x**2 + Q(1,4) + assert euler_poly(4, x) == x**4 - 2*x**3 + x + assert euler_poly(5, x) == x**5 - Q(5,2)*x**4 + Q(5,2)*x**2 - Q(1,2) + assert euler_poly(6, x) == x**6 - 3*x**5 + 5*x**3 - 3*x + + assert euler_poly(1).dummy_eq(x - Q(1,2)) + assert euler_poly(1, polys=True) == Poly(x - Q(1,2)) + + assert genocchi_poly(9, x) == euler_poly(8, x) * -9 + assert genocchi_poly(10, x) == euler_poly(9, x) * -10 + +def test_andre_poly(): + raises(ValueError, lambda: andre_poly(-1, x)) + assert andre_poly(1, x, polys=True) == Poly(x) + + assert andre_poly(0, x) == 1 + assert andre_poly(1, x) == x + assert andre_poly(2, x) == x**2 - 1 + assert andre_poly(3, x) == x**3 - 3*x + assert andre_poly(4, x) == x**4 - 6*x**2 + 5 + assert andre_poly(5, x) == x**5 - 10*x**3 + 25*x + assert andre_poly(6, x) == x**6 - 15*x**4 + 75*x**2 - 61 + + assert andre_poly(1).dummy_eq(x) + assert andre_poly(1, polys=True) == Poly(x) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_constructor.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_constructor.py new file mode 100644 index 0000000000000000000000000000000000000000..b02d8a4b360dd09b993bbed80cdec307d09908fc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_constructor.py @@ -0,0 +1,236 @@ +"""Tests for tools for constructing domains for expressions. """ + +from sympy.testing.pytest import tooslow + +from sympy.polys.constructor import construct_domain +from sympy.polys.domains import ZZ, QQ, ZZ_I, QQ_I, RR, CC, EX +from sympy.polys.domains.realfield import RealField +from sympy.polys.domains.complexfield import ComplexField + +from sympy.core import (Catalan, GoldenRatio) +from sympy.core.numbers import (E, Float, I, Rational, pi) +from sympy.core.singleton import S +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import sin +from sympy import rootof + +from sympy.abc import x, y + + +def test_construct_domain(): + + assert construct_domain([1, 2, 3]) == (ZZ, [ZZ(1), ZZ(2), ZZ(3)]) + assert construct_domain([1, 2, 3], field=True) == (QQ, [QQ(1), QQ(2), QQ(3)]) + + assert construct_domain([S.One, S(2), S(3)]) == (ZZ, [ZZ(1), ZZ(2), ZZ(3)]) + assert construct_domain([S.One, S(2), S(3)], field=True) == (QQ, [QQ(1), QQ(2), QQ(3)]) + + assert construct_domain([S.Half, S(2)]) == (QQ, [QQ(1, 2), QQ(2)]) + result = construct_domain([3.14, 1, S.Half]) + assert isinstance(result[0], RealField) + assert result[1] == [RR(3.14), RR(1.0), RR(0.5)] + + result = construct_domain([3.14, I, S.Half]) + assert isinstance(result[0], ComplexField) + assert result[1] == [CC(3.14), CC(1.0j), CC(0.5)] + + assert construct_domain([1.0+I]) == (CC, [CC(1.0, 1.0)]) + assert construct_domain([2.0+3.0*I]) == (CC, [CC(2.0, 3.0)]) + + assert construct_domain([1, I]) == (ZZ_I, [ZZ_I(1, 0), ZZ_I(0, 1)]) + assert construct_domain([1, I/2]) == (QQ_I, [QQ_I(1, 0), QQ_I(0, S.Half)]) + + assert construct_domain([3.14, sqrt(2)], extension=None) == (EX, [EX(3.14), EX(sqrt(2))]) + assert construct_domain([3.14, sqrt(2)], extension=True) == (EX, [EX(3.14), EX(sqrt(2))]) + + assert construct_domain([1, sqrt(2)], extension=None) == (EX, [EX(1), EX(sqrt(2))]) + + assert construct_domain([x, sqrt(x)]) == (EX, [EX(x), EX(sqrt(x))]) + assert construct_domain([x, sqrt(x), sqrt(y)]) == (EX, [EX(x), EX(sqrt(x)), EX(sqrt(y))]) + + alg = QQ.algebraic_field(sqrt(2)) + + assert construct_domain([7, S.Half, sqrt(2)], extension=True) == \ + (alg, [alg.convert(7), alg.convert(S.Half), alg.convert(sqrt(2))]) + + alg = QQ.algebraic_field(sqrt(2) + sqrt(3)) + + assert construct_domain([7, sqrt(2), sqrt(3)], extension=True) == \ + (alg, [alg.convert(7), alg.convert(sqrt(2)), alg.convert(sqrt(3))]) + + dom = ZZ[x] + + assert construct_domain([2*x, 3]) == \ + (dom, [dom.convert(2*x), dom.convert(3)]) + + dom = ZZ[x, y] + + assert construct_domain([2*x, 3*y]) == \ + (dom, [dom.convert(2*x), dom.convert(3*y)]) + + dom = QQ[x] + + assert construct_domain([x/2, 3]) == \ + (dom, [dom.convert(x/2), dom.convert(3)]) + + dom = QQ[x, y] + + assert construct_domain([x/2, 3*y]) == \ + (dom, [dom.convert(x/2), dom.convert(3*y)]) + + dom = ZZ_I[x] + + assert construct_domain([2*x, I]) == \ + (dom, [dom.convert(2*x), dom.convert(I)]) + + dom = ZZ_I[x, y] + + assert construct_domain([2*x, I*y]) == \ + (dom, [dom.convert(2*x), dom.convert(I*y)]) + + dom = QQ_I[x] + + assert construct_domain([x/2, I]) == \ + (dom, [dom.convert(x/2), dom.convert(I)]) + + dom = QQ_I[x, y] + + assert construct_domain([x/2, I*y]) == \ + (dom, [dom.convert(x/2), dom.convert(I*y)]) + + dom = RR[x] + + assert construct_domain([x/2, 3.5]) == \ + (dom, [dom.convert(x/2), dom.convert(3.5)]) + + dom = RR[x, y] + + assert construct_domain([x/2, 3.5*y]) == \ + (dom, [dom.convert(x/2), dom.convert(3.5*y)]) + + dom = CC[x] + + assert construct_domain([I*x/2, 3.5]) == \ + (dom, [dom.convert(I*x/2), dom.convert(3.5)]) + + dom = CC[x, y] + + assert construct_domain([I*x/2, 3.5*y]) == \ + (dom, [dom.convert(I*x/2), dom.convert(3.5*y)]) + + dom = CC[x] + + assert construct_domain([x/2, I*3.5]) == \ + (dom, [dom.convert(x/2), dom.convert(I*3.5)]) + + dom = CC[x, y] + + assert construct_domain([x/2, I*3.5*y]) == \ + (dom, [dom.convert(x/2), dom.convert(I*3.5*y)]) + + dom = ZZ.frac_field(x) + + assert construct_domain([2/x, 3]) == \ + (dom, [dom.convert(2/x), dom.convert(3)]) + + dom = ZZ.frac_field(x, y) + + assert construct_domain([2/x, 3*y]) == \ + (dom, [dom.convert(2/x), dom.convert(3*y)]) + + dom = RR.frac_field(x) + + assert construct_domain([2/x, 3.5]) == \ + (dom, [dom.convert(2/x), dom.convert(3.5)]) + + dom = RR.frac_field(x, y) + + assert construct_domain([2/x, 3.5*y]) == \ + (dom, [dom.convert(2/x), dom.convert(3.5*y)]) + + dom = RealField(prec=336)[x] + + assert construct_domain([pi.evalf(100)*x]) == \ + (dom, [dom.convert(pi.evalf(100)*x)]) + + assert construct_domain(2) == (ZZ, ZZ(2)) + assert construct_domain(S(2)/3) == (QQ, QQ(2, 3)) + assert construct_domain(Rational(2, 3)) == (QQ, QQ(2, 3)) + + assert construct_domain({}) == (ZZ, {}) + + +def test_complex_exponential(): + w = exp(-I*2*pi/3, evaluate=False) + alg = QQ.algebraic_field(w) + assert construct_domain([w**2, w, 1], extension=True) == ( + alg, + [alg.convert(w**2), + alg.convert(w), + alg.convert(1)] + ) + + +def test_rootof(): + r1 = rootof(x**3 + x + 1, 0) + r2 = rootof(x**3 + x + 1, 1) + K1 = QQ.algebraic_field(r1) + K2 = QQ.algebraic_field(r2) + assert construct_domain([r1]) == (EX, [EX(r1)]) + assert construct_domain([r2]) == (EX, [EX(r2)]) + assert construct_domain([r1, r2]) == (EX, [EX(r1), EX(r2)]) + + assert construct_domain([r1], extension=True) == ( + K1, [K1.from_sympy(r1)]) + assert construct_domain([r2], extension=True) == ( + K2, [K2.from_sympy(r2)]) + + +@tooslow +def test_rootof_primitive_element(): + r1 = rootof(x**3 + x + 1, 0) + r2 = rootof(x**3 + x + 1, 1) + K12 = QQ.algebraic_field(r1 + r2) + assert construct_domain([r1, r2], extension=True) == ( + K12, [K12.from_sympy(r1), K12.from_sympy(r2)]) + + +def test_composite_option(): + assert construct_domain({(1,): sin(y)}, composite=False) == \ + (EX, {(1,): EX(sin(y))}) + + assert construct_domain({(1,): y}, composite=False) == \ + (EX, {(1,): EX(y)}) + + assert construct_domain({(1, 1): 1}, composite=False) == \ + (ZZ, {(1, 1): 1}) + + assert construct_domain({(1, 0): y}, composite=False) == \ + (EX, {(1, 0): EX(y)}) + + +def test_precision(): + f1 = Float("1.01") + f2 = Float("1.0000000000000000000001") + for u in [1, 1e-2, 1e-6, 1e-13, 1e-14, 1e-16, 1e-20, 1e-100, 1e-300, + f1, f2]: + result = construct_domain([u]) + v = float(result[1][0]) + assert abs(u - v) / u < 1e-14 # Test relative accuracy + + result = construct_domain([f1]) + y = result[1][0] + assert y-1 > 1e-50 + + result = construct_domain([f2]) + y = result[1][0] + assert y-1 > 1e-50 + + +def test_issue_11538(): + for n in [E, pi, Catalan]: + assert construct_domain(n)[0] == ZZ[n] + assert construct_domain(x + n)[0] == ZZ[x, n] + assert construct_domain(GoldenRatio)[0] == EX + assert construct_domain(x + GoldenRatio)[0] == EX diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densearith.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densearith.py new file mode 100644 index 0000000000000000000000000000000000000000..ebb29d50867ad578274ed11c766e0515d8e4da35 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densearith.py @@ -0,0 +1,1007 @@ +"""Tests for dense recursive polynomials' arithmetics. """ + +from sympy.external.gmpy import GROUND_TYPES + +from sympy.polys.densebasic import ( + dup_normal, dmp_normal, +) + +from sympy.polys.densearith import ( + dup_add_term, dmp_add_term, + dup_sub_term, dmp_sub_term, + dup_mul_term, dmp_mul_term, + dup_add_ground, dmp_add_ground, + dup_sub_ground, dmp_sub_ground, + dup_mul_ground, dmp_mul_ground, + dup_quo_ground, dmp_quo_ground, + dup_exquo_ground, dmp_exquo_ground, + dup_lshift, dup_rshift, + dup_abs, dmp_abs, + dup_neg, dmp_neg, + dup_add, dmp_add, + dup_sub, dmp_sub, + dup_mul, dmp_mul, + dup_sqr, dmp_sqr, + dup_pow, dmp_pow, + dup_add_mul, dmp_add_mul, + dup_sub_mul, dmp_sub_mul, + dup_pdiv, dup_prem, dup_pquo, dup_pexquo, + dmp_pdiv, dmp_prem, dmp_pquo, dmp_pexquo, + dup_rr_div, dmp_rr_div, + dup_ff_div, dmp_ff_div, + dup_div, dup_rem, dup_quo, dup_exquo, + dmp_div, dmp_rem, dmp_quo, dmp_exquo, + dup_max_norm, dmp_max_norm, + dup_l1_norm, dmp_l1_norm, + dup_l2_norm_squared, dmp_l2_norm_squared, + dup_expand, dmp_expand, +) + +from sympy.polys.polyerrors import ( + ExactQuotientFailed, +) + +from sympy.polys.specialpolys import f_polys, Symbol, Poly +from sympy.polys.domains import FF, ZZ, QQ, CC + +from sympy.testing.pytest import raises + +x = Symbol('x') + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = [ f.to_dense() for f in f_polys() ] +F_0 = dmp_mul_ground(dmp_normal(f_0, 2, QQ), QQ(1, 7), 2, QQ) + +def test_dup_add_term(): + f = dup_normal([], ZZ) + + assert dup_add_term(f, ZZ(0), 0, ZZ) == dup_normal([], ZZ) + + assert dup_add_term(f, ZZ(1), 0, ZZ) == dup_normal([1], ZZ) + assert dup_add_term(f, ZZ(1), 1, ZZ) == dup_normal([1, 0], ZZ) + assert dup_add_term(f, ZZ(1), 2, ZZ) == dup_normal([1, 0, 0], ZZ) + + f = dup_normal([1, 1, 1], ZZ) + + assert dup_add_term(f, ZZ(1), 0, ZZ) == dup_normal([1, 1, 2], ZZ) + assert dup_add_term(f, ZZ(1), 1, ZZ) == dup_normal([1, 2, 1], ZZ) + assert dup_add_term(f, ZZ(1), 2, ZZ) == dup_normal([2, 1, 1], ZZ) + + assert dup_add_term(f, ZZ(1), 3, ZZ) == dup_normal([1, 1, 1, 1], ZZ) + assert dup_add_term(f, ZZ(1), 4, ZZ) == dup_normal([1, 0, 1, 1, 1], ZZ) + assert dup_add_term(f, ZZ(1), 5, ZZ) == dup_normal([1, 0, 0, 1, 1, 1], ZZ) + assert dup_add_term( + f, ZZ(1), 6, ZZ) == dup_normal([1, 0, 0, 0, 1, 1, 1], ZZ) + + assert dup_add_term(f, ZZ(-1), 2, ZZ) == dup_normal([1, 1], ZZ) + + +def test_dmp_add_term(): + assert dmp_add_term([ZZ(1), ZZ(1), ZZ(1)], ZZ(1), 2, 0, ZZ) == \ + dup_add_term([ZZ(1), ZZ(1), ZZ(1)], ZZ(1), 2, ZZ) + assert dmp_add_term(f_0, [[]], 3, 2, ZZ) == f_0 + assert dmp_add_term(F_0, [[]], 3, 2, QQ) == F_0 + + +def test_dup_sub_term(): + f = dup_normal([], ZZ) + + assert dup_sub_term(f, ZZ(0), 0, ZZ) == dup_normal([], ZZ) + + assert dup_sub_term(f, ZZ(1), 0, ZZ) == dup_normal([-1], ZZ) + assert dup_sub_term(f, ZZ(1), 1, ZZ) == dup_normal([-1, 0], ZZ) + assert dup_sub_term(f, ZZ(1), 2, ZZ) == dup_normal([-1, 0, 0], ZZ) + + f = dup_normal([1, 1, 1], ZZ) + + assert dup_sub_term(f, ZZ(2), 0, ZZ) == dup_normal([ 1, 1, -1], ZZ) + assert dup_sub_term(f, ZZ(2), 1, ZZ) == dup_normal([ 1, -1, 1], ZZ) + assert dup_sub_term(f, ZZ(2), 2, ZZ) == dup_normal([-1, 1, 1], ZZ) + + assert dup_sub_term(f, ZZ(1), 3, ZZ) == dup_normal([-1, 1, 1, 1], ZZ) + assert dup_sub_term(f, ZZ(1), 4, ZZ) == dup_normal([-1, 0, 1, 1, 1], ZZ) + assert dup_sub_term(f, ZZ(1), 5, ZZ) == dup_normal([-1, 0, 0, 1, 1, 1], ZZ) + assert dup_sub_term( + f, ZZ(1), 6, ZZ) == dup_normal([-1, 0, 0, 0, 1, 1, 1], ZZ) + + assert dup_sub_term(f, ZZ(1), 2, ZZ) == dup_normal([1, 1], ZZ) + + +def test_dmp_sub_term(): + assert dmp_sub_term([ZZ(1), ZZ(1), ZZ(1)], ZZ(1), 2, 0, ZZ) == \ + dup_sub_term([ZZ(1), ZZ(1), ZZ(1)], ZZ(1), 2, ZZ) + assert dmp_sub_term(f_0, [[]], 3, 2, ZZ) == f_0 + assert dmp_sub_term(F_0, [[]], 3, 2, QQ) == F_0 + + +def test_dup_mul_term(): + f = dup_normal([], ZZ) + + assert dup_mul_term(f, ZZ(2), 3, ZZ) == dup_normal([], ZZ) + + f = dup_normal([1, 1], ZZ) + + assert dup_mul_term(f, ZZ(0), 3, ZZ) == dup_normal([], ZZ) + + f = dup_normal([1, 2, 3], ZZ) + + assert dup_mul_term(f, ZZ(2), 0, ZZ) == dup_normal([2, 4, 6], ZZ) + assert dup_mul_term(f, ZZ(2), 1, ZZ) == dup_normal([2, 4, 6, 0], ZZ) + assert dup_mul_term(f, ZZ(2), 2, ZZ) == dup_normal([2, 4, 6, 0, 0], ZZ) + assert dup_mul_term(f, ZZ(2), 3, ZZ) == dup_normal([2, 4, 6, 0, 0, 0], ZZ) + + +def test_dmp_mul_term(): + assert dmp_mul_term([ZZ(1), ZZ(2), ZZ(3)], ZZ(2), 1, 0, ZZ) == \ + dup_mul_term([ZZ(1), ZZ(2), ZZ(3)], ZZ(2), 1, ZZ) + + assert dmp_mul_term([[]], [ZZ(2)], 3, 1, ZZ) == [[]] + assert dmp_mul_term([[ZZ(1)]], [], 3, 1, ZZ) == [[]] + + assert dmp_mul_term([[ZZ(1), ZZ(2)], [ZZ(3)]], [ZZ(2)], 2, 1, ZZ) == \ + [[ZZ(2), ZZ(4)], [ZZ(6)], [], []] + + assert dmp_mul_term([[]], [QQ(2, 3)], 3, 1, QQ) == [[]] + assert dmp_mul_term([[QQ(1, 2)]], [], 3, 1, QQ) == [[]] + + assert dmp_mul_term([[QQ(1, 5), QQ(2, 5)], [QQ(3, 5)]], [QQ(2, 3)], 2, 1, QQ) == \ + [[QQ(2, 15), QQ(4, 15)], [QQ(6, 15)], [], []] + + +def test_dup_add_ground(): + f = ZZ.map([1, 2, 3, 4]) + g = ZZ.map([1, 2, 3, 8]) + + assert dup_add_ground(f, ZZ(4), ZZ) == g + + +def test_dmp_add_ground(): + f = ZZ.map([[1], [2], [3], [4]]) + g = ZZ.map([[1], [2], [3], [8]]) + + assert dmp_add_ground(f, ZZ(4), 1, ZZ) == g + + +def test_dup_sub_ground(): + f = ZZ.map([1, 2, 3, 4]) + g = ZZ.map([1, 2, 3, 0]) + + assert dup_sub_ground(f, ZZ(4), ZZ) == g + + +def test_dmp_sub_ground(): + f = ZZ.map([[1], [2], [3], [4]]) + g = ZZ.map([[1], [2], [3], []]) + + assert dmp_sub_ground(f, ZZ(4), 1, ZZ) == g + + +def test_dup_mul_ground(): + f = dup_normal([], ZZ) + + assert dup_mul_ground(f, ZZ(2), ZZ) == dup_normal([], ZZ) + + f = dup_normal([1, 2, 3], ZZ) + + assert dup_mul_ground(f, ZZ(0), ZZ) == dup_normal([], ZZ) + assert dup_mul_ground(f, ZZ(2), ZZ) == dup_normal([2, 4, 6], ZZ) + + +def test_dmp_mul_ground(): + assert dmp_mul_ground(f_0, ZZ(2), 2, ZZ) == [ + [[ZZ(2), ZZ(4), ZZ(6)], [ZZ(4)]], + [[ZZ(6)]], + [[ZZ(8), ZZ(10), ZZ(12)], [ZZ(2), ZZ(4), ZZ(2)], [ZZ(2)]] + ] + + assert dmp_mul_ground(F_0, QQ(1, 2), 2, QQ) == [ + [[QQ(1, 14), QQ(2, 14), QQ(3, 14)], [QQ(2, 14)]], + [[QQ(3, 14)]], + [[QQ(4, 14), QQ(5, 14), QQ(6, 14)], [QQ(1, 14), QQ(2, 14), + QQ(1, 14)], [QQ(1, 14)]] + ] + + +def test_dup_quo_ground(): + raises(ZeroDivisionError, lambda: dup_quo_ground(dup_normal([1, 2, + 3], ZZ), ZZ(0), ZZ)) + + f = dup_normal([], ZZ) + + assert dup_quo_ground(f, ZZ(3), ZZ) == dup_normal([], ZZ) + + f = dup_normal([6, 2, 8], ZZ) + + assert dup_quo_ground(f, ZZ(1), ZZ) == f + assert dup_quo_ground(f, ZZ(2), ZZ) == dup_normal([3, 1, 4], ZZ) + + assert dup_quo_ground(f, ZZ(3), ZZ) == dup_normal([2, 0, 2], ZZ) + + f = dup_normal([6, 2, 8], QQ) + + assert dup_quo_ground(f, QQ(1), QQ) == f + assert dup_quo_ground(f, QQ(2), QQ) == [QQ(3), QQ(1), QQ(4)] + assert dup_quo_ground(f, QQ(7), QQ) == [QQ(6, 7), QQ(2, 7), QQ(8, 7)] + + +def test_dup_exquo_ground(): + raises(ZeroDivisionError, lambda: dup_exquo_ground(dup_normal([1, + 2, 3], ZZ), ZZ(0), ZZ)) + raises(ExactQuotientFailed, lambda: dup_exquo_ground(dup_normal([1, + 2, 3], ZZ), ZZ(3), ZZ)) + + f = dup_normal([], ZZ) + + assert dup_exquo_ground(f, ZZ(3), ZZ) == dup_normal([], ZZ) + + f = dup_normal([6, 2, 8], ZZ) + + assert dup_exquo_ground(f, ZZ(1), ZZ) == f + assert dup_exquo_ground(f, ZZ(2), ZZ) == dup_normal([3, 1, 4], ZZ) + + f = dup_normal([6, 2, 8], QQ) + + assert dup_exquo_ground(f, QQ(1), QQ) == f + assert dup_exquo_ground(f, QQ(2), QQ) == [QQ(3), QQ(1), QQ(4)] + assert dup_exquo_ground(f, QQ(7), QQ) == [QQ(6, 7), QQ(2, 7), QQ(8, 7)] + + +def test_dmp_quo_ground(): + f = dmp_normal([[6], [2], [8]], 1, ZZ) + + assert dmp_quo_ground(f, ZZ(1), 1, ZZ) == f + assert dmp_quo_ground( + f, ZZ(2), 1, ZZ) == dmp_normal([[3], [1], [4]], 1, ZZ) + + assert dmp_normal(dmp_quo_ground( + f, ZZ(3), 1, ZZ), 1, ZZ) == dmp_normal([[2], [], [2]], 1, ZZ) + + +def test_dmp_exquo_ground(): + f = dmp_normal([[6], [2], [8]], 1, ZZ) + + assert dmp_exquo_ground(f, ZZ(1), 1, ZZ) == f + assert dmp_exquo_ground( + f, ZZ(2), 1, ZZ) == dmp_normal([[3], [1], [4]], 1, ZZ) + + +def test_dup_lshift(): + assert dup_lshift([], 3, ZZ) == [] + assert dup_lshift([1], 3, ZZ) == [1, 0, 0, 0] + + +def test_dup_rshift(): + assert dup_rshift([], 3, ZZ) == [] + assert dup_rshift([1, 0, 0, 0], 3, ZZ) == [1] + + +def test_dup_abs(): + assert dup_abs([], ZZ) == [] + assert dup_abs([ZZ( 1)], ZZ) == [ZZ(1)] + assert dup_abs([ZZ(-7)], ZZ) == [ZZ(7)] + assert dup_abs([ZZ(-1), ZZ(2), ZZ(3)], ZZ) == [ZZ(1), ZZ(2), ZZ(3)] + + assert dup_abs([], QQ) == [] + assert dup_abs([QQ( 1, 2)], QQ) == [QQ(1, 2)] + assert dup_abs([QQ(-7, 3)], QQ) == [QQ(7, 3)] + assert dup_abs( + [QQ(-1, 7), QQ(2, 7), QQ(3, 7)], QQ) == [QQ(1, 7), QQ(2, 7), QQ(3, 7)] + + +def test_dmp_abs(): + assert dmp_abs([ZZ(-1)], 0, ZZ) == [ZZ(1)] + assert dmp_abs([QQ(-1, 2)], 0, QQ) == [QQ(1, 2)] + + assert dmp_abs([[[]]], 2, ZZ) == [[[]]] + assert dmp_abs([[[ZZ(1)]]], 2, ZZ) == [[[ZZ(1)]]] + assert dmp_abs([[[ZZ(-7)]]], 2, ZZ) == [[[ZZ(7)]]] + + assert dmp_abs([[[]]], 2, QQ) == [[[]]] + assert dmp_abs([[[QQ(1, 2)]]], 2, QQ) == [[[QQ(1, 2)]]] + assert dmp_abs([[[QQ(-7, 9)]]], 2, QQ) == [[[QQ(7, 9)]]] + + +def test_dup_neg(): + assert dup_neg([], ZZ) == [] + assert dup_neg([ZZ(1)], ZZ) == [ZZ(-1)] + assert dup_neg([ZZ(-7)], ZZ) == [ZZ(7)] + assert dup_neg([ZZ(-1), ZZ(2), ZZ(3)], ZZ) == [ZZ(1), ZZ(-2), ZZ(-3)] + + assert dup_neg([], QQ) == [] + assert dup_neg([QQ(1, 2)], QQ) == [QQ(-1, 2)] + assert dup_neg([QQ(-7, 9)], QQ) == [QQ(7, 9)] + assert dup_neg([QQ( + -1, 7), QQ(2, 7), QQ(3, 7)], QQ) == [QQ(1, 7), QQ(-2, 7), QQ(-3, 7)] + + +def test_dmp_neg(): + assert dmp_neg([ZZ(-1)], 0, ZZ) == [ZZ(1)] + assert dmp_neg([QQ(-1, 2)], 0, QQ) == [QQ(1, 2)] + + assert dmp_neg([[[]]], 2, ZZ) == [[[]]] + assert dmp_neg([[[ZZ(1)]]], 2, ZZ) == [[[ZZ(-1)]]] + assert dmp_neg([[[ZZ(-7)]]], 2, ZZ) == [[[ZZ(7)]]] + + assert dmp_neg([[[]]], 2, QQ) == [[[]]] + assert dmp_neg([[[QQ(1, 9)]]], 2, QQ) == [[[QQ(-1, 9)]]] + assert dmp_neg([[[QQ(-7, 9)]]], 2, QQ) == [[[QQ(7, 9)]]] + + +def test_dup_add(): + assert dup_add([], [], ZZ) == [] + assert dup_add([ZZ(1)], [], ZZ) == [ZZ(1)] + assert dup_add([], [ZZ(1)], ZZ) == [ZZ(1)] + assert dup_add([ZZ(1)], [ZZ(1)], ZZ) == [ZZ(2)] + assert dup_add([ZZ(1)], [ZZ(2)], ZZ) == [ZZ(3)] + + assert dup_add([ZZ(1), ZZ(2)], [ZZ(1)], ZZ) == [ZZ(1), ZZ(3)] + assert dup_add([ZZ(1)], [ZZ(1), ZZ(2)], ZZ) == [ZZ(1), ZZ(3)] + + assert dup_add([ZZ(1), ZZ( + 2), ZZ(3)], [ZZ(8), ZZ(9), ZZ(10)], ZZ) == [ZZ(9), ZZ(11), ZZ(13)] + + assert dup_add([], [], QQ) == [] + assert dup_add([QQ(1, 2)], [], QQ) == [QQ(1, 2)] + assert dup_add([], [QQ(1, 2)], QQ) == [QQ(1, 2)] + assert dup_add([QQ(1, 4)], [QQ(1, 4)], QQ) == [QQ(1, 2)] + assert dup_add([QQ(1, 4)], [QQ(1, 2)], QQ) == [QQ(3, 4)] + + assert dup_add([QQ(1, 2), QQ(2, 3)], [QQ(1)], QQ) == [QQ(1, 2), QQ(5, 3)] + assert dup_add([QQ(1)], [QQ(1, 2), QQ(2, 3)], QQ) == [QQ(1, 2), QQ(5, 3)] + + assert dup_add([QQ(1, 7), QQ(2, 7), QQ(3, 7)], [QQ( + 8, 7), QQ(9, 7), QQ(10, 7)], QQ) == [QQ(9, 7), QQ(11, 7), QQ(13, 7)] + + +def test_dmp_add(): + assert dmp_add([ZZ(1), ZZ(2)], [ZZ(1)], 0, ZZ) == \ + dup_add([ZZ(1), ZZ(2)], [ZZ(1)], ZZ) + assert dmp_add([QQ(1, 2), QQ(2, 3)], [QQ(1)], 0, QQ) == \ + dup_add([QQ(1, 2), QQ(2, 3)], [QQ(1)], QQ) + + assert dmp_add([[[]]], [[[]]], 2, ZZ) == [[[]]] + assert dmp_add([[[ZZ(1)]]], [[[]]], 2, ZZ) == [[[ZZ(1)]]] + assert dmp_add([[[]]], [[[ZZ(1)]]], 2, ZZ) == [[[ZZ(1)]]] + assert dmp_add([[[ZZ(2)]]], [[[ZZ(1)]]], 2, ZZ) == [[[ZZ(3)]]] + assert dmp_add([[[ZZ(1)]]], [[[ZZ(2)]]], 2, ZZ) == [[[ZZ(3)]]] + + assert dmp_add([[[]]], [[[]]], 2, QQ) == [[[]]] + assert dmp_add([[[QQ(1, 2)]]], [[[]]], 2, QQ) == [[[QQ(1, 2)]]] + assert dmp_add([[[]]], [[[QQ(1, 2)]]], 2, QQ) == [[[QQ(1, 2)]]] + assert dmp_add([[[QQ(2, 7)]]], [[[QQ(1, 7)]]], 2, QQ) == [[[QQ(3, 7)]]] + assert dmp_add([[[QQ(1, 7)]]], [[[QQ(2, 7)]]], 2, QQ) == [[[QQ(3, 7)]]] + + +def test_dup_sub(): + assert dup_sub([], [], ZZ) == [] + assert dup_sub([ZZ(1)], [], ZZ) == [ZZ(1)] + assert dup_sub([], [ZZ(1)], ZZ) == [ZZ(-1)] + assert dup_sub([ZZ(1)], [ZZ(1)], ZZ) == [] + assert dup_sub([ZZ(1)], [ZZ(2)], ZZ) == [ZZ(-1)] + + assert dup_sub([ZZ(1), ZZ(2)], [ZZ(1)], ZZ) == [ZZ(1), ZZ(1)] + assert dup_sub([ZZ(1)], [ZZ(1), ZZ(2)], ZZ) == [ZZ(-1), ZZ(-1)] + + assert dup_sub([ZZ(3), ZZ( + 2), ZZ(1)], [ZZ(8), ZZ(9), ZZ(10)], ZZ) == [ZZ(-5), ZZ(-7), ZZ(-9)] + + assert dup_sub([], [], QQ) == [] + assert dup_sub([QQ(1, 2)], [], QQ) == [QQ(1, 2)] + assert dup_sub([], [QQ(1, 2)], QQ) == [QQ(-1, 2)] + assert dup_sub([QQ(1, 3)], [QQ(1, 3)], QQ) == [] + assert dup_sub([QQ(1, 3)], [QQ(2, 3)], QQ) == [QQ(-1, 3)] + + assert dup_sub([QQ(1, 7), QQ(2, 7)], [QQ(1)], QQ) == [QQ(1, 7), QQ(-5, 7)] + assert dup_sub([QQ(1)], [QQ(1, 7), QQ(2, 7)], QQ) == [QQ(-1, 7), QQ(5, 7)] + + assert dup_sub([QQ(3, 7), QQ(2, 7), QQ(1, 7)], [QQ( + 8, 7), QQ(9, 7), QQ(10, 7)], QQ) == [QQ(-5, 7), QQ(-7, 7), QQ(-9, 7)] + + +def test_dmp_sub(): + assert dmp_sub([ZZ(1), ZZ(2)], [ZZ(1)], 0, ZZ) == \ + dup_sub([ZZ(1), ZZ(2)], [ZZ(1)], ZZ) + assert dmp_sub([QQ(1, 2), QQ(2, 3)], [QQ(1)], 0, QQ) == \ + dup_sub([QQ(1, 2), QQ(2, 3)], [QQ(1)], QQ) + + assert dmp_sub([[[]]], [[[]]], 2, ZZ) == [[[]]] + assert dmp_sub([[[ZZ(1)]]], [[[]]], 2, ZZ) == [[[ZZ(1)]]] + assert dmp_sub([[[]]], [[[ZZ(1)]]], 2, ZZ) == [[[ZZ(-1)]]] + assert dmp_sub([[[ZZ(2)]]], [[[ZZ(1)]]], 2, ZZ) == [[[ZZ(1)]]] + assert dmp_sub([[[ZZ(1)]]], [[[ZZ(2)]]], 2, ZZ) == [[[ZZ(-1)]]] + + assert dmp_sub([[[]]], [[[]]], 2, QQ) == [[[]]] + assert dmp_sub([[[QQ(1, 2)]]], [[[]]], 2, QQ) == [[[QQ(1, 2)]]] + assert dmp_sub([[[]]], [[[QQ(1, 2)]]], 2, QQ) == [[[QQ(-1, 2)]]] + assert dmp_sub([[[QQ(2, 7)]]], [[[QQ(1, 7)]]], 2, QQ) == [[[QQ(1, 7)]]] + assert dmp_sub([[[QQ(1, 7)]]], [[[QQ(2, 7)]]], 2, QQ) == [[[QQ(-1, 7)]]] + + +def test_dup_add_mul(): + assert dup_add_mul([ZZ(1), ZZ(2), ZZ(3)], [ZZ(3), ZZ(2), ZZ(1)], + [ZZ(1), ZZ(2)], ZZ) == [ZZ(3), ZZ(9), ZZ(7), ZZ(5)] + assert dmp_add_mul([[ZZ(1), ZZ(2)], [ZZ(3)]], [[ZZ(3)], [ZZ(2), ZZ(1)]], + [[ZZ(1)], [ZZ(2)]], 1, ZZ) == [[ZZ(3)], [ZZ(3), ZZ(9)], [ZZ(4), ZZ(5)]] + + +def test_dup_sub_mul(): + assert dup_sub_mul([ZZ(1), ZZ(2), ZZ(3)], [ZZ(3), ZZ(2), ZZ(1)], + [ZZ(1), ZZ(2)], ZZ) == [ZZ(-3), ZZ(-7), ZZ(-3), ZZ(1)] + assert dmp_sub_mul([[ZZ(1), ZZ(2)], [ZZ(3)]], [[ZZ(3)], [ZZ(2), ZZ(1)]], + [[ZZ(1)], [ZZ(2)]], 1, ZZ) == [[ZZ(-3)], [ZZ(-1), ZZ(-5)], [ZZ(-4), ZZ(1)]] + + +def test_dup_mul(): + assert dup_mul([], [], ZZ) == [] + assert dup_mul([], [ZZ(1)], ZZ) == [] + assert dup_mul([ZZ(1)], [], ZZ) == [] + assert dup_mul([ZZ(1)], [ZZ(1)], ZZ) == [ZZ(1)] + assert dup_mul([ZZ(5)], [ZZ(7)], ZZ) == [ZZ(35)] + + assert dup_mul([], [], QQ) == [] + assert dup_mul([], [QQ(1, 2)], QQ) == [] + assert dup_mul([QQ(1, 2)], [], QQ) == [] + assert dup_mul([QQ(1, 2)], [QQ(4, 7)], QQ) == [QQ(2, 7)] + assert dup_mul([QQ(5, 7)], [QQ(3, 7)], QQ) == [QQ(15, 49)] + + f = dup_normal([3, 0, 0, 6, 1, 2], ZZ) + g = dup_normal([4, 0, 1, 0], ZZ) + h = dup_normal([12, 0, 3, 24, 4, 14, 1, 2, 0], ZZ) + + assert dup_mul(f, g, ZZ) == h + assert dup_mul(g, f, ZZ) == h + + f = dup_normal([2, 0, 0, 1, 7], ZZ) + h = dup_normal([4, 0, 0, 4, 28, 0, 1, 14, 49], ZZ) + + assert dup_mul(f, f, ZZ) == h + + K = FF(6) + + assert dup_mul([K(2), K(1)], [K(3), K(4)], K) == [K(5), K(4)] + + p1 = dup_normal([79, -1, 78, -94, -10, 11, 32, -19, 78, 2, -89, 30, 73, 42, + 85, 77, 83, -30, -34, -2, 95, -81, 37, -49, -46, -58, -16, 37, 35, -11, + -57, -15, -31, 67, -20, 27, 76, 2, 70, 67, -65, 65, -26, -93, -44, -12, + -92, 57, -90, -57, -11, -67, -98, -69, 97, -41, 89, 33, 89, -50, 81, + -31, 60, -27, 43, 29, -77, 44, 21, -91, 32, -57, 33, 3, 53, -51, -38, + -99, -84, 23, -50, 66, -100, 1, -75, -25, 27, -60, 98, -51, -87, 6, 8, + 78, -28, -95, -88, 12, -35, 26, -9, 16, -92, 55, -7, -86, 68, -39, -46, + 84, 94, 45, 60, 92, 68, -75, -74, -19, 8, 75, 78, 91, 57, 34, 14, -3, + -49, 65, 78, -18, 6, -29, -80, -98, 17, 13, 58, 21, 20, 9, 37, 7, -30, + -53, -20, 34, 67, -42, 89, -22, 73, 43, -6, 5, 51, -8, -15, -52, -22, + -58, -72, -3, 43, -92, 82, 83, -2, -13, -23, -60, 16, -94, -8, -28, + -95, -72, 63, -90, 76, 6, -43, -100, -59, 76, 3, 3, 46, -85, 75, 62, + -71, -76, 88, 97, -72, -1, 30, -64, 72, -48, 14, -78, 58, 63, -91, 24, + -87, -27, -80, -100, -44, 98, 70, 100, -29, -38, 11, 77, 100, 52, 86, + 65, -5, -42, -81, -38, -42, 43, -2, -70, -63, -52], ZZ) + p2 = dup_normal([65, -19, -47, 1, 90, 81, -15, -34, 25, -75, 9, -83, 50, -5, + -44, 31, 1, 70, -7, 78, 74, 80, 85, 65, 21, 41, 66, 19, -40, 63, -21, + -27, 32, 69, 83, 34, -35, 14, 81, 57, -75, 32, -67, -89, -100, -61, 46, + 84, -78, -29, -50, -94, -24, -32, -68, -16, 100, -7, -72, -89, 35, 82, + 58, 81, -92, 62, 5, -47, -39, -58, -72, -13, 84, 44, 55, -25, 48, -54, + -31, -56, -11, -50, -84, 10, 67, 17, 13, -14, 61, 76, -64, -44, -40, + -96, 11, -11, -94, 2, 6, 27, -6, 68, -54, 66, -74, -14, -1, -24, -73, + 96, 89, -11, -89, 56, -53, 72, -43, 96, 25, 63, -31, 29, 68, 83, 91, + -93, -19, -38, -40, 40, -12, -19, -79, 44, 100, -66, -29, -77, 62, 39, + -8, 11, -97, 14, 87, 64, 21, -18, 13, 15, -59, -75, -99, -88, 57, 54, + 56, -67, 6, -63, -59, -14, 28, 87, -20, -39, 84, -91, -2, 49, -75, 11, + -24, -95, 36, 66, 5, 25, -72, -40, 86, 90, 37, -33, 57, -35, 29, -18, + 4, -79, 64, -17, -27, 21, 29, -5, -44, -87, -24, 52, 78, 11, -23, -53, + 36, 42, 21, -68, 94, -91, -51, -21, 51, -76, 72, 31, 24, -48, -80, -9, + 37, -47, -6, -8, -63, -91, 79, -79, -100, 38, -20, 38, 100, 83, -90, + 87, 63, -36, 82, -19, 18, -98, -38, 26, 98, -70, 79, 92, 12, 12, 70, + 74, 36, 48, -13, 31, 31, -47, -71, -12, -64, 36, -42, 32, -86, 60, 83, + 70, 55, 0, 1, 29, -35, 8, -82, 8, -73, -46, -50, 43, 48, -5, -86, -72, + 44, -90, 19, 19, 5, -20, 97, -13, -66, -5, 5, -69, 64, -30, 41, 51, 36, + 13, -99, -61, 94, -12, 74, 98, 68, 24, 46, -97, -87, -6, -27, 82, 62, + -11, -77, 86, 66, -47, -49, -50, 13, 18, 89, -89, 46, -80, 13, 98, -35, + -36, -25, 12, 20, 26, -52, 79, 27, 79, 100, 8, 62, -58, -28, 37], ZZ) + res = dup_normal([5135, -1566, 1376, -7466, 4579, 11710, 8001, -7183, + -3737, -7439, 345, -10084, 24522, -1201, 1070, -10245, 9582, 9264, + 1903, 23312, 18953, 10037, -15268, -5450, 6442, -6243, -3777, 5110, + 10936, -16649, -6022, 16255, 31300, 24818, 31922, 32760, 7854, 27080, + 15766, 29596, 7139, 31945, -19810, 465, -38026, -3971, 9641, 465, + -19375, 5524, -30112, -11960, -12813, 13535, 30670, 5925, -43725, + -14089, 11503, -22782, 6371, 43881, 37465, -33529, -33590, -39798, + -37854, -18466, -7908, -35825, -26020, -36923, -11332, -5699, 25166, + -3147, 19885, 12962, -20659, -1642, 27723, -56331, -24580, -11010, + -20206, 20087, -23772, -16038, 38580, 20901, -50731, 32037, -4299, + 26508, 18038, -28357, 31846, -7405, -20172, -15894, 2096, 25110, + -45786, 45918, -55333, -31928, -49428, -29824, -58796, -24609, -15408, + 69, -35415, -18439, 10123, -20360, -65949, 33356, -20333, 26476, + -32073, 33621, 930, 28803, -42791, 44716, 38164, 12302, -1739, 11421, + 73385, -7613, 14297, 38155, -414, 77587, 24338, -21415, 29367, 42639, + 13901, -288, 51027, -11827, 91260, 43407, 88521, -15186, 70572, -12049, + 5090, -12208, -56374, 15520, -623, -7742, 50825, 11199, -14894, 40892, + 59591, -31356, -28696, -57842, -87751, -33744, -28436, -28945, -40287, + 37957, -35638, 33401, -61534, 14870, 40292, 70366, -10803, 102290, + -71719, -85251, 7902, -22409, 75009, 99927, 35298, -1175, -762, -34744, + -10587, -47574, -62629, -19581, -43659, -54369, -32250, -39545, 15225, + -24454, 11241, -67308, -30148, 39929, 37639, 14383, -73475, -77636, + -81048, -35992, 41601, -90143, 76937, -8112, 56588, 9124, -40094, + -32340, 13253, 10898, -51639, 36390, 12086, -1885, 100714, -28561, + -23784, -18735, 18916, 16286, 10742, -87360, -13697, 10689, -19477, + -29770, 5060, 20189, -8297, 112407, 47071, 47743, 45519, -4109, 17468, + -68831, 78325, -6481, -21641, -19459, 30919, 96115, 8607, 53341, 32105, + -16211, 23538, 57259, -76272, -40583, 62093, 38511, -34255, -40665, + -40604, -37606, -15274, 33156, -13885, 103636, 118678, -14101, -92682, + -100791, 2634, 63791, 98266, 19286, -34590, -21067, -71130, 25380, + -40839, -27614, -26060, 52358, -15537, 27138, -6749, 36269, -33306, + 13207, -91084, -5540, -57116, 69548, 44169, -57742, -41234, -103327, + -62904, -8566, 41149, -12866, 71188, 23980, 1838, 58230, 73950, 5594, + 43113, -8159, -15925, 6911, 85598, -75016, -16214, -62726, -39016, + 8618, -63882, -4299, 23182, 49959, 49342, -3238, -24913, -37138, 78361, + 32451, 6337, -11438, -36241, -37737, 8169, -3077, -24829, 57953, 53016, + -31511, -91168, 12599, -41849, 41576, 55275, -62539, 47814, -62319, + 12300, -32076, -55137, -84881, -27546, 4312, -3433, -54382, 113288, + -30157, 74469, 18219, 79880, -2124, 98911, 17655, -33499, -32861, + 47242, -37393, 99765, 14831, -44483, 10800, -31617, -52710, 37406, + 22105, 29704, -20050, 13778, 43683, 36628, 8494, 60964, -22644, 31550, + -17693, 33805, -124879, -12302, 19343, 20400, -30937, -21574, -34037, + -33380, 56539, -24993, -75513, -1527, 53563, 65407, -101, 53577, 37991, + 18717, -23795, -8090, -47987, -94717, 41967, 5170, -14815, -94311, + 17896, -17734, -57718, -774, -38410, 24830, 29682, 76480, 58802, + -46416, -20348, -61353, -68225, -68306, 23822, -31598, 42972, 36327, + 28968, -65638, -21638, 24354, -8356, 26777, 52982, -11783, -44051, + -26467, -44721, -28435, -53265, -25574, -2669, 44155, 22946, -18454, + -30718, -11252, 58420, 8711, 67447, 4425, 41749, 67543, 43162, 11793, + -41907, 20477, -13080, 6559, -6104, -13244, 42853, 42935, 29793, 36730, + -28087, 28657, 17946, 7503, 7204, 21491, -27450, -24241, -98156, + -18082, -42613, -24928, 10775, -14842, -44127, 55910, 14777, 31151, -2194, + 39206, -2100, -4211, 11827, -8918, -19471, 72567, 36447, -65590, -34861, + -17147, -45303, 9025, -7333, -35473, 11101, 11638, 3441, 6626, -41800, + 9416, 13679, 33508, 40502, -60542, 16358, 8392, -43242, -35864, -34127, + -48721, 35878, 30598, 28630, 20279, -19983, -14638, -24455, -1851, -11344, + 45150, 42051, 26034, -28889, -32382, -3527, -14532, 22564, -22346, 477, + 11706, 28338, -25972, -9185, -22867, -12522, 32120, -4424, 11339, -33913, + -7184, 5101, -23552, -17115, -31401, -6104, 21906, 25708, 8406, 6317, + -7525, 5014, 20750, 20179, 22724, 11692, 13297, 2493, -253, -16841, -17339, + -6753, -4808, 2976, -10881, -10228, -13816, -12686, 1385, 2316, 2190, -875, + -1924], ZZ) + + assert dup_mul(p1, p2, ZZ) == res + + p1 = dup_normal([83, -61, -86, -24, 12, 43, -88, -9, 42, 55, -66, 74, 95, + -25, -12, 68, -99, 4, 45, 6, -15, -19, 78, 65, -55, 47, -13, 17, 86, + 81, -58, -27, 50, -40, -24, 39, -41, -92, 75, 90, -1, 40, -15, -27, + -35, 68, 70, -64, -40, 78, -88, -58, -39, 69, 46, 12, 28, -94, -37, + -50, -80, -96, -61, 25, 1, 71, 4, 12, 48, 4, 34, -47, -75, 5, 48, 82, + 88, 23, 98, 35, 17, -10, 48, -61, -95, 47, 65, -19, -66, -57, -6, -51, + -42, -89, 66, -13, 18, 37, 90, -23, 72, 96, -53, 0, 40, -73, -52, -68, + 32, -25, -53, 79, -52, 18, 44, 73, -81, 31, -90, 70, 3, 36, 48, 76, + -24, -44, 23, 98, -4, 73, 69, 88, -70, 14, -68, 94, -78, -15, -64, -97, + -70, -35, 65, 88, 49, -53, -7, 12, -45, -7, 59, -94, 99, -2, 67, -60, + -71, 29, -62, -77, 1, 51, 17, 80, -20, -47, -19, 24, -9, 39, -23, 21, + -84, 10, 84, 56, -17, -21, -66, 85, 70, 46, -51, -22, -95, 78, -60, + -96, -97, -45, 72, 35, 30, -61, -92, -93, -60, -61, 4, -4, -81, -73, + 46, 53, -11, 26, 94, 45, 14, -78, 55, 84, -68, 98, 60, 23, 100, -63, + 68, 96, -16, 3, 56, 21, -58, 62, -67, 66, 85, 41, -79, -22, 97, -67, + 82, 82, -96, -20, -7, 48, -67, 48, -9, -39, 78], ZZ) + p2 = dup_normal([52, 88, 76, 66, 9, -64, 46, -20, -28, 69, 60, 96, -36, + -92, -30, -11, -35, 35, 55, 63, -92, -7, 25, -58, 74, 55, -6, 4, 47, + -92, -65, 67, -45, 74, -76, 59, -6, 69, 39, 24, -71, -7, 39, -45, 60, + -68, 98, 97, -79, 17, 4, 94, -64, 68, -100, -96, -2, 3, 22, 96, 54, + -77, -86, 67, 6, 57, 37, 40, 89, -78, 64, -94, -45, -92, 57, 87, -26, + 36, 19, 97, 25, 77, -87, 24, 43, -5, 35, 57, 83, 71, 35, 63, 61, 96, + -22, 8, -1, 96, 43, 45, 94, -93, 36, 71, -41, -99, 85, -48, 59, 52, + -17, 5, 87, -16, -68, -54, 76, -18, 100, 91, -42, -70, -66, -88, -12, + 1, 95, -82, 52, 43, -29, 3, 12, 72, -99, -43, -32, -93, -51, 16, -20, + -12, -11, 5, 33, -38, 93, -5, -74, 25, 74, -58, 93, 59, -63, -86, 63, + -20, -4, -74, -73, -95, 29, -28, 93, -91, -2, -38, -62, 77, -58, -85, + -28, 95, 38, 19, -69, 86, 94, 25, -2, -4, 47, 34, -59, 35, -48, 29, + -63, -53, 34, 29, 66, 73, 6, 92, -84, 89, 15, 81, 93, 97, 51, -72, -78, + 25, 60, 90, -45, 39, 67, -84, -62, 57, 26, -32, -56, -14, -83, 76, 5, + -2, 99, -100, 28, 46, 94, -7, 53, -25, 16, -23, -36, 89, -78, -63, 31, + 1, 84, -99, -52, 76, 48, 90, -76, 44, -19, 54, -36, -9, -73, -100, -69, + 31, 42, 25, -39, 76, -26, -8, -14, 51, 3, 37, 45, 2, -54, 13, -34, -92, + 17, -25, -65, 53, -63, 30, 4, -70, -67, 90, 52, 51, 18, -3, 31, -45, + -9, 59, 63, -87, 22, -32, 29, -38, 21, 36, -82, 27, -11], ZZ) + res = dup_normal([4316, 4132, -3532, -7974, -11303, -10069, 5484, -3330, + -5874, 7734, 4673, 11327, -9884, -8031, 17343, 21035, -10570, -9285, + 15893, 3780, -14083, 8819, 17592, 10159, 7174, -11587, 8598, -16479, + 3602, 25596, 9781, 12163, 150, 18749, -21782, -12307, 27578, -2757, + -12573, 12565, 6345, -18956, 19503, -15617, 1443, -16778, 36851, 23588, + -28474, 5749, 40695, -7521, -53669, -2497, -18530, 6770, 57038, 3926, + -6927, -15399, 1848, -64649, -27728, 3644, 49608, 15187, -8902, -9480, + -7398, -40425, 4824, 23767, -7594, -6905, 33089, 18786, 12192, 24670, + 31114, 35334, -4501, -14676, 7107, -59018, -21352, 20777, 19661, 20653, + 33754, -885, -43758, 6269, 51897, -28719, -97488, -9527, 13746, 11644, + 17644, -21720, 23782, -10481, 47867, 20752, 33810, -1875, 39918, -7710, + -40840, 19808, -47075, 23066, 46616, 25201, 9287, 35436, -1602, 9645, + -11978, 13273, 15544, 33465, 20063, 44539, 11687, 27314, -6538, -37467, + 14031, 32970, -27086, 41323, 29551, 65910, -39027, -37800, -22232, + 8212, 46316, -28981, -55282, 50417, -44929, -44062, 73879, 37573, + -2596, -10877, -21893, -133218, -33707, -25753, -9531, 17530, 61126, + 2748, -56235, 43874, -10872, -90459, -30387, 115267, -7264, -44452, + 122626, 14839, -599, 10337, 57166, -67467, -54957, 63669, 1202, 18488, + 52594, 7205, -97822, 612, 78069, -5403, -63562, 47236, 36873, -154827, + -26188, 82427, -39521, 5628, 7416, 5276, -53095, 47050, 26121, -42207, + 79021, -13035, 2499, -66943, 29040, -72355, -23480, 23416, -12885, + -44225, -42688, -4224, 19858, 55299, 15735, 11465, 101876, -39169, + 51786, 14723, 43280, -68697, 16410, 92295, 56767, 7183, 111850, 4550, + 115451, -38443, -19642, -35058, 10230, 93829, 8925, 63047, 3146, 29250, + 8530, 5255, -98117, -115517, -76817, -8724, 41044, 1312, -35974, 79333, + -28567, 7547, -10580, -24559, -16238, 10794, -3867, 24848, 57770, + -51536, -35040, 71033, 29853, 62029, -7125, -125585, -32169, -47907, + 156811, -65176, -58006, -15757, -57861, 11963, 30225, -41901, -41681, + 31310, 27982, 18613, 61760, 60746, -59096, 33499, 30097, -17997, 24032, + 56442, -83042, 23747, -20931, -21978, -158752, -9883, -73598, -7987, + -7333, -125403, -116329, 30585, 53281, 51018, -29193, 88575, 8264, + -40147, -16289, 113088, 12810, -6508, 101552, -13037, 34440, -41840, + 101643, 24263, 80532, 61748, 65574, 6423, -20672, 6591, -10834, -71716, + 86919, -92626, 39161, 28490, 81319, 46676, 106720, 43530, 26998, 57456, + -8862, 60989, 13982, 3119, -2224, 14743, 55415, -49093, -29303, 28999, + 1789, 55953, -84043, -7780, -65013, 57129, -47251, 61484, 61994, + -78361, -82778, 22487, -26894, 9756, -74637, -15519, -4360, 30115, + 42433, 35475, 15286, 69768, 21509, -20214, 78675, -21163, 13596, 11443, + -10698, -53621, -53867, -24155, 64500, -42784, -33077, -16500, 873, + -52788, 14546, -38011, 36974, -39849, -34029, -94311, 83068, -50437, + -26169, -46746, 59185, 42259, -101379, -12943, 30089, -59086, 36271, + 22723, -30253, -52472, -70826, -23289, 3331, -31687, 14183, -857, + -28627, 35246, -51284, 5636, -6933, 66539, 36654, 50927, 24783, 3457, + 33276, 45281, 45650, -4938, -9968, -22590, 47995, 69229, 5214, -58365, + -17907, -14651, 18668, 18009, 12649, -11851, -13387, 20339, 52472, + -1087, -21458, -68647, 52295, 15849, 40608, 15323, 25164, -29368, + 10352, -7055, 7159, 21695, -5373, -54849, 101103, -24963, -10511, + 33227, 7659, 41042, -69588, 26718, -20515, 6441, 38135, -63, 24088, + -35364, -12785, -18709, 47843, 48533, -48575, 17251, -19394, 32878, + -9010, -9050, 504, -12407, 28076, -3429, 25324, -4210, -26119, 752, + -29203, 28251, -11324, -32140, -3366, -25135, 18702, -31588, -7047, + -24267, 49987, -14975, -33169, 37744, -7720, -9035, 16964, -2807, -421, + 14114, -17097, -13662, 40628, -12139, -9427, 5369, 17551, -13232, -16211, + 9804, -7422, 2677, 28635, -8280, -4906, 2908, -22558, 5604, 12459, 8756, + -3980, -4745, -18525, 7913, 5970, -16457, 20230, -6247, -13812, 2505, + 11899, 1409, -15094, 22540, -18863, 137, 11123, -4516, 2290, -8594, 12150, + -10380, 3005, 5235, -7350, 2535, -858], ZZ) + + assert dup_mul(p1, p2, ZZ) == res + + +def test_dmp_mul(): + assert dmp_mul([ZZ(5)], [ZZ(7)], 0, ZZ) == \ + dup_mul([ZZ(5)], [ZZ(7)], ZZ) + assert dmp_mul([QQ(5, 7)], [QQ(3, 7)], 0, QQ) == \ + dup_mul([QQ(5, 7)], [QQ(3, 7)], QQ) + + assert dmp_mul([[[]]], [[[]]], 2, ZZ) == [[[]]] + assert dmp_mul([[[ZZ(1)]]], [[[]]], 2, ZZ) == [[[]]] + assert dmp_mul([[[]]], [[[ZZ(1)]]], 2, ZZ) == [[[]]] + assert dmp_mul([[[ZZ(2)]]], [[[ZZ(1)]]], 2, ZZ) == [[[ZZ(2)]]] + assert dmp_mul([[[ZZ(1)]]], [[[ZZ(2)]]], 2, ZZ) == [[[ZZ(2)]]] + + assert dmp_mul([[[]]], [[[]]], 2, QQ) == [[[]]] + assert dmp_mul([[[QQ(1, 2)]]], [[[]]], 2, QQ) == [[[]]] + assert dmp_mul([[[]]], [[[QQ(1, 2)]]], 2, QQ) == [[[]]] + assert dmp_mul([[[QQ(2, 7)]]], [[[QQ(1, 3)]]], 2, QQ) == [[[QQ(2, 21)]]] + assert dmp_mul([[[QQ(1, 7)]]], [[[QQ(2, 3)]]], 2, QQ) == [[[QQ(2, 21)]]] + + K = FF(6) + + assert dmp_mul( + [[K(2)], [K(1)]], [[K(3)], [K(4)]], 1, K) == [[K(5)], [K(4)]] + + +def test_dup_sqr(): + assert dup_sqr([], ZZ) == [] + assert dup_sqr([ZZ(2)], ZZ) == [ZZ(4)] + assert dup_sqr([ZZ(1), ZZ(2)], ZZ) == [ZZ(1), ZZ(4), ZZ(4)] + + assert dup_sqr([], QQ) == [] + assert dup_sqr([QQ(2, 3)], QQ) == [QQ(4, 9)] + assert dup_sqr([QQ(1, 3), QQ(2, 3)], QQ) == [QQ(1, 9), QQ(4, 9), QQ(4, 9)] + + f = dup_normal([2, 0, 0, 1, 7], ZZ) + + assert dup_sqr(f, ZZ) == dup_normal([4, 0, 0, 4, 28, 0, 1, 14, 49], ZZ) + + K = FF(9) + + assert dup_sqr([K(3), K(4)], K) == [K(6), K(7)] + + +def test_dmp_sqr(): + assert dmp_sqr([ZZ(1), ZZ(2)], 0, ZZ) == \ + dup_sqr([ZZ(1), ZZ(2)], ZZ) + + assert dmp_sqr([[[]]], 2, ZZ) == [[[]]] + assert dmp_sqr([[[ZZ(2)]]], 2, ZZ) == [[[ZZ(4)]]] + + assert dmp_sqr([[[]]], 2, QQ) == [[[]]] + assert dmp_sqr([[[QQ(2, 3)]]], 2, QQ) == [[[QQ(4, 9)]]] + + K = FF(9) + + assert dmp_sqr([[K(3)], [K(4)]], 1, K) == [[K(6)], [K(7)]] + + +def test_dup_pow(): + assert dup_pow([], 0, ZZ) == [ZZ(1)] + assert dup_pow([], 0, QQ) == [QQ(1)] + + assert dup_pow([], 1, ZZ) == [] + assert dup_pow([], 7, ZZ) == [] + + assert dup_pow([ZZ(1)], 0, ZZ) == [ZZ(1)] + assert dup_pow([ZZ(1)], 1, ZZ) == [ZZ(1)] + assert dup_pow([ZZ(1)], 7, ZZ) == [ZZ(1)] + + assert dup_pow([ZZ(3)], 0, ZZ) == [ZZ(1)] + assert dup_pow([ZZ(3)], 1, ZZ) == [ZZ(3)] + assert dup_pow([ZZ(3)], 7, ZZ) == [ZZ(2187)] + + assert dup_pow([QQ(1, 1)], 0, QQ) == [QQ(1, 1)] + assert dup_pow([QQ(1, 1)], 1, QQ) == [QQ(1, 1)] + assert dup_pow([QQ(1, 1)], 7, QQ) == [QQ(1, 1)] + + assert dup_pow([QQ(3, 7)], 0, QQ) == [QQ(1, 1)] + assert dup_pow([QQ(3, 7)], 1, QQ) == [QQ(3, 7)] + assert dup_pow([QQ(3, 7)], 7, QQ) == [QQ(2187, 823543)] + + f = dup_normal([2, 0, 0, 1, 7], ZZ) + + assert dup_pow(f, 0, ZZ) == dup_normal([1], ZZ) + assert dup_pow(f, 1, ZZ) == dup_normal([2, 0, 0, 1, 7], ZZ) + assert dup_pow(f, 2, ZZ) == dup_normal([4, 0, 0, 4, 28, 0, 1, 14, 49], ZZ) + assert dup_pow(f, 3, ZZ) == dup_normal( + [8, 0, 0, 12, 84, 0, 6, 84, 294, 1, 21, 147, 343], ZZ) + + +def test_dmp_pow(): + assert dmp_pow([[]], 0, 1, ZZ) == [[ZZ(1)]] + assert dmp_pow([[]], 0, 1, QQ) == [[QQ(1)]] + + assert dmp_pow([[]], 1, 1, ZZ) == [[]] + assert dmp_pow([[]], 7, 1, ZZ) == [[]] + + assert dmp_pow([[ZZ(1)]], 0, 1, ZZ) == [[ZZ(1)]] + assert dmp_pow([[ZZ(1)]], 1, 1, ZZ) == [[ZZ(1)]] + assert dmp_pow([[ZZ(1)]], 7, 1, ZZ) == [[ZZ(1)]] + + assert dmp_pow([[QQ(3, 7)]], 0, 1, QQ) == [[QQ(1, 1)]] + assert dmp_pow([[QQ(3, 7)]], 1, 1, QQ) == [[QQ(3, 7)]] + assert dmp_pow([[QQ(3, 7)]], 7, 1, QQ) == [[QQ(2187, 823543)]] + + f = dup_normal([2, 0, 0, 1, 7], ZZ) + + assert dmp_pow(f, 2, 0, ZZ) == dup_pow(f, 2, ZZ) + + +def test_dup_pdiv(): + f = dup_normal([3, 1, 1, 5], ZZ) + g = dup_normal([5, -3, 1], ZZ) + + q = dup_normal([15, 14], ZZ) + r = dup_normal([52, 111], ZZ) + + assert dup_pdiv(f, g, ZZ) == (q, r) + assert dup_pquo(f, g, ZZ) == q + assert dup_prem(f, g, ZZ) == r + + raises(ExactQuotientFailed, lambda: dup_pexquo(f, g, ZZ)) + + f = dup_normal([3, 1, 1, 5], QQ) + g = dup_normal([5, -3, 1], QQ) + + q = dup_normal([15, 14], QQ) + r = dup_normal([52, 111], QQ) + + assert dup_pdiv(f, g, QQ) == (q, r) + assert dup_pquo(f, g, QQ) == q + assert dup_prem(f, g, QQ) == r + + raises(ExactQuotientFailed, lambda: dup_pexquo(f, g, QQ)) + + +def test_dmp_pdiv(): + f = dmp_normal([[1], [], [1, 0, 0]], 1, ZZ) + g = dmp_normal([[1], [-1, 0]], 1, ZZ) + + q = dmp_normal([[1], [1, 0]], 1, ZZ) + r = dmp_normal([[2, 0, 0]], 1, ZZ) + + assert dmp_pdiv(f, g, 1, ZZ) == (q, r) + assert dmp_pquo(f, g, 1, ZZ) == q + assert dmp_prem(f, g, 1, ZZ) == r + + raises(ExactQuotientFailed, lambda: dmp_pexquo(f, g, 1, ZZ)) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, ZZ) + g = dmp_normal([[2], [-2, 0]], 1, ZZ) + + q = dmp_normal([[2], [2, 0]], 1, ZZ) + r = dmp_normal([[8, 0, 0]], 1, ZZ) + + assert dmp_pdiv(f, g, 1, ZZ) == (q, r) + assert dmp_pquo(f, g, 1, ZZ) == q + assert dmp_prem(f, g, 1, ZZ) == r + + raises(ExactQuotientFailed, lambda: dmp_pexquo(f, g, 1, ZZ)) + + +def test_dup_rr_div(): + raises(ZeroDivisionError, lambda: dup_rr_div([1, 2, 3], [], ZZ)) + + f = dup_normal([3, 1, 1, 5], ZZ) + g = dup_normal([5, -3, 1], ZZ) + + q, r = [], f + + assert dup_rr_div(f, g, ZZ) == (q, r) + + +def test_dmp_rr_div(): + raises(ZeroDivisionError, lambda: dmp_rr_div([[1, 2], [3]], [[]], 1, ZZ)) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, ZZ) + g = dmp_normal([[1], [-1, 0]], 1, ZZ) + + q = dmp_normal([[1], [1, 0]], 1, ZZ) + r = dmp_normal([[2, 0, 0]], 1, ZZ) + + assert dmp_rr_div(f, g, 1, ZZ) == (q, r) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, ZZ) + g = dmp_normal([[-1], [1, 0]], 1, ZZ) + + q = dmp_normal([[-1], [-1, 0]], 1, ZZ) + r = dmp_normal([[2, 0, 0]], 1, ZZ) + + assert dmp_rr_div(f, g, 1, ZZ) == (q, r) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, ZZ) + g = dmp_normal([[2], [-2, 0]], 1, ZZ) + + q, r = [[]], f + + assert dmp_rr_div(f, g, 1, ZZ) == (q, r) + + +def test_dup_ff_div(): + raises(ZeroDivisionError, lambda: dup_ff_div([1, 2, 3], [], QQ)) + + f = dup_normal([3, 1, 1, 5], QQ) + g = dup_normal([5, -3, 1], QQ) + + q = [QQ(3, 5), QQ(14, 25)] + r = [QQ(52, 25), QQ(111, 25)] + + assert dup_ff_div(f, g, QQ) == (q, r) + +def test_dup_ff_div_gmpy2(): + if GROUND_TYPES != 'gmpy2': + return + + from gmpy2 import mpq + from sympy.polys.domains import GMPYRationalField + K = GMPYRationalField() + + f = [mpq(1,3), mpq(3,2)] + g = [mpq(2,1)] + assert dmp_ff_div(f, g, 0, K) == ([mpq(1,6), mpq(3,4)], []) + + f = [mpq(1,2), mpq(1,3), mpq(1,4), mpq(1,5)] + g = [mpq(-1,1), mpq(1,1), mpq(-1,1)] + assert dmp_ff_div(f, g, 0, K) == ([mpq(-1,2), mpq(-5,6)], [mpq(7,12), mpq(-19,30)]) + +def test_dmp_ff_div(): + raises(ZeroDivisionError, lambda: dmp_ff_div([[1, 2], [3]], [[]], 1, QQ)) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, QQ) + g = dmp_normal([[1], [-1, 0]], 1, QQ) + + q = [[QQ(1, 1)], [QQ(1, 1), QQ(0, 1)]] + r = [[QQ(2, 1), QQ(0, 1), QQ(0, 1)]] + + assert dmp_ff_div(f, g, 1, QQ) == (q, r) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, QQ) + g = dmp_normal([[-1], [1, 0]], 1, QQ) + + q = [[QQ(-1, 1)], [QQ(-1, 1), QQ(0, 1)]] + r = [[QQ(2, 1), QQ(0, 1), QQ(0, 1)]] + + assert dmp_ff_div(f, g, 1, QQ) == (q, r) + + f = dmp_normal([[1], [], [1, 0, 0]], 1, QQ) + g = dmp_normal([[2], [-2, 0]], 1, QQ) + + q = [[QQ(1, 2)], [QQ(1, 2), QQ(0, 1)]] + r = [[QQ(2, 1), QQ(0, 1), QQ(0, 1)]] + + assert dmp_ff_div(f, g, 1, QQ) == (q, r) + + +def test_dup_div(): + f, g, q, r = [5, 4, 3, 2, 1], [1, 2, 3], [5, -6, 0], [20, 1] + + assert dup_div(f, g, ZZ) == (q, r) + assert dup_quo(f, g, ZZ) == q + assert dup_rem(f, g, ZZ) == r + + raises(ExactQuotientFailed, lambda: dup_exquo(f, g, ZZ)) + + f, g, q, r = [5, 4, 3, 2, 1, 0], [1, 2, 0, 0, 9], [5, -6], [15, 2, -44, 54] + + assert dup_div(f, g, ZZ) == (q, r) + assert dup_quo(f, g, ZZ) == q + assert dup_rem(f, g, ZZ) == r + + raises(ExactQuotientFailed, lambda: dup_exquo(f, g, ZZ)) + + +def test_dmp_div(): + f, g, q, r = [5, 4, 3, 2, 1], [1, 2, 3], [5, -6, 0], [20, 1] + + assert dmp_div(f, g, 0, ZZ) == (q, r) + assert dmp_quo(f, g, 0, ZZ) == q + assert dmp_rem(f, g, 0, ZZ) == r + + raises(ExactQuotientFailed, lambda: dmp_exquo(f, g, 0, ZZ)) + + f, g, q, r = [[[1]]], [[[2]], [1]], [[[]]], [[[1]]] + + assert dmp_div(f, g, 2, ZZ) == (q, r) + assert dmp_quo(f, g, 2, ZZ) == q + assert dmp_rem(f, g, 2, ZZ) == r + + raises(ExactQuotientFailed, lambda: dmp_exquo(f, g, 2, ZZ)) + + +def test_dup_max_norm(): + assert dup_max_norm([], ZZ) == 0 + assert dup_max_norm([1], ZZ) == 1 + + assert dup_max_norm([1, 4, 2, 3], ZZ) == 4 + + +def test_dmp_max_norm(): + assert dmp_max_norm([[[]]], 2, ZZ) == 0 + assert dmp_max_norm([[[1]]], 2, ZZ) == 1 + + assert dmp_max_norm(f_0, 2, ZZ) == 6 + + +def test_dup_l1_norm(): + assert dup_l1_norm([], ZZ) == 0 + assert dup_l1_norm([1], ZZ) == 1 + assert dup_l1_norm([1, 4, 2, 3], ZZ) == 10 + + +def test_dmp_l1_norm(): + assert dmp_l1_norm([[[]]], 2, ZZ) == 0 + assert dmp_l1_norm([[[1]]], 2, ZZ) == 1 + + assert dmp_l1_norm(f_0, 2, ZZ) == 31 + + +def test_dup_l2_norm_squared(): + assert dup_l2_norm_squared([], ZZ) == 0 + assert dup_l2_norm_squared([1], ZZ) == 1 + assert dup_l2_norm_squared([1, 4, 2, 3], ZZ) == 30 + + +def test_dmp_l2_norm_squared(): + assert dmp_l2_norm_squared([[[]]], 2, ZZ) == 0 + assert dmp_l2_norm_squared([[[1]]], 2, ZZ) == 1 + assert dmp_l2_norm_squared(f_0, 2, ZZ) == 111 + + +def test_dup_expand(): + assert dup_expand((), ZZ) == [1] + assert dup_expand(([1, 2, 3], [1, 2], [7, 5, 4, 3]), ZZ) == \ + dup_mul([1, 2, 3], dup_mul([1, 2], [7, 5, 4, 3], ZZ), ZZ) + + +def test_dmp_expand(): + assert dmp_expand((), 1, ZZ) == [[1]] + assert dmp_expand(([[1], [2], [3]], [[1], [2]], [[7], [5], [4], [3]]), 1, ZZ) == \ + dmp_mul([[1], [2], [3]], dmp_mul([[1], [2]], [[7], [5], [ + 4], [3]], 1, ZZ), 1, ZZ) + +def test_dup_mul_poly(): + p = Poly(18786186952704.0*x**165 + 9.31746684052255e+31*x**82, x, domain='RR') + px = Poly(18786186952704.0*x**166 + 9.31746684052255e+31*x**83, x, domain='RR') + + assert p * x == px + assert p.set_domain(QQ) * x == px.set_domain(QQ) + assert p.set_domain(CC) * x == px.set_domain(CC) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densebasic.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densebasic.py new file mode 100644 index 0000000000000000000000000000000000000000..43386d86d0e6ec7b20d3962d8063aa6402165f9a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densebasic.py @@ -0,0 +1,730 @@ +"""Tests for dense recursive polynomials' basic tools. """ + +from sympy.polys.densebasic import ( + ninf, + dup_LC, dmp_LC, + dup_TC, dmp_TC, + dmp_ground_LC, dmp_ground_TC, + dmp_true_LT, + dup_degree, dmp_degree, + dmp_degree_in, dmp_degree_list, + dup_strip, dmp_strip, + dmp_validate, + dup_reverse, + dup_copy, dmp_copy, + dup_normal, dmp_normal, + dup_convert, dmp_convert, + dup_from_sympy, dmp_from_sympy, + dup_nth, dmp_nth, dmp_ground_nth, + dmp_zero_p, dmp_zero, + dmp_one_p, dmp_one, + dmp_ground_p, dmp_ground, + dmp_negative_p, dmp_positive_p, + dmp_zeros, dmp_grounds, + dup_from_dict, dup_from_raw_dict, + dup_to_dict, dup_to_raw_dict, + dmp_from_dict, dmp_to_dict, + dmp_swap, dmp_permute, + dmp_nest, dmp_raise, + dup_deflate, dmp_deflate, + dup_multi_deflate, dmp_multi_deflate, + dup_inflate, dmp_inflate, + dmp_exclude, dmp_include, + dmp_inject, dmp_eject, + dup_terms_gcd, dmp_terms_gcd, + dmp_list_terms, dmp_apply_pairs, + dup_slice, + dup_random, +) + +from sympy.polys.specialpolys import f_polys +from sympy.polys.domains import ZZ, QQ +from sympy.polys.rings import ring + +from sympy.core.singleton import S +from sympy.testing.pytest import raises + +from sympy.core.numbers import oo + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = [ f.to_dense() for f in f_polys() ] + +def test_dup_LC(): + assert dup_LC([], ZZ) == 0 + assert dup_LC([2, 3, 4, 5], ZZ) == 2 + + +def test_dup_TC(): + assert dup_TC([], ZZ) == 0 + assert dup_TC([2, 3, 4, 5], ZZ) == 5 + + +def test_dmp_LC(): + assert dmp_LC([[]], ZZ) == [] + assert dmp_LC([[2, 3, 4], [5]], ZZ) == [2, 3, 4] + assert dmp_LC([[[]]], ZZ) == [[]] + assert dmp_LC([[[2], [3, 4]], [[5]]], ZZ) == [[2], [3, 4]] + + +def test_dmp_TC(): + assert dmp_TC([[]], ZZ) == [] + assert dmp_TC([[2, 3, 4], [5]], ZZ) == [5] + assert dmp_TC([[[]]], ZZ) == [[]] + assert dmp_TC([[[2], [3, 4]], [[5]]], ZZ) == [[5]] + + +def test_dmp_ground_LC(): + assert dmp_ground_LC([[]], 1, ZZ) == 0 + assert dmp_ground_LC([[2, 3, 4], [5]], 1, ZZ) == 2 + assert dmp_ground_LC([[[]]], 2, ZZ) == 0 + assert dmp_ground_LC([[[2], [3, 4]], [[5]]], 2, ZZ) == 2 + + +def test_dmp_ground_TC(): + assert dmp_ground_TC([[]], 1, ZZ) == 0 + assert dmp_ground_TC([[2, 3, 4], [5]], 1, ZZ) == 5 + assert dmp_ground_TC([[[]]], 2, ZZ) == 0 + assert dmp_ground_TC([[[2], [3, 4]], [[5]]], 2, ZZ) == 5 + + +def test_dmp_true_LT(): + assert dmp_true_LT([[]], 1, ZZ) == ((0, 0), 0) + assert dmp_true_LT([[7]], 1, ZZ) == ((0, 0), 7) + + assert dmp_true_LT([[1, 0]], 1, ZZ) == ((0, 1), 1) + assert dmp_true_LT([[1], []], 1, ZZ) == ((1, 0), 1) + assert dmp_true_LT([[1, 0], []], 1, ZZ) == ((1, 1), 1) + + +def test_dup_degree(): + assert ninf == float('-inf') + assert dup_degree([]) is ninf + assert dup_degree([1]) == 0 + assert dup_degree([1, 0]) == 1 + assert dup_degree([1, 0, 0, 0, 1]) == 4 + + +def test_dmp_degree(): + assert dmp_degree([[]], 1) is ninf + assert dmp_degree([[[]]], 2) is ninf + + assert dmp_degree([[1]], 1) == 0 + assert dmp_degree([[2], [1]], 1) == 1 + + +def test_dmp_degree_in(): + assert dmp_degree_in([[[]]], 0, 2) is ninf + assert dmp_degree_in([[[]]], 1, 2) is ninf + assert dmp_degree_in([[[]]], 2, 2) is ninf + + assert dmp_degree_in([[[1]]], 0, 2) == 0 + assert dmp_degree_in([[[1]]], 1, 2) == 0 + assert dmp_degree_in([[[1]]], 2, 2) == 0 + + assert dmp_degree_in(f_4, 0, 2) == 9 + assert dmp_degree_in(f_4, 1, 2) == 12 + assert dmp_degree_in(f_4, 2, 2) == 8 + + assert dmp_degree_in(f_6, 0, 2) == 4 + assert dmp_degree_in(f_6, 1, 2) == 4 + assert dmp_degree_in(f_6, 2, 2) == 6 + assert dmp_degree_in(f_6, 3, 3) == 3 + + raises(IndexError, lambda: dmp_degree_in([[1]], -5, 1)) + + +def test_dmp_degree_list(): + assert dmp_degree_list([[[[ ]]]], 3) == (-oo, -oo, -oo, -oo) + assert dmp_degree_list([[[[1]]]], 3) == ( 0, 0, 0, 0) + + assert dmp_degree_list(f_0, 2) == (2, 2, 2) + assert dmp_degree_list(f_1, 2) == (3, 3, 3) + assert dmp_degree_list(f_2, 2) == (5, 3, 3) + assert dmp_degree_list(f_3, 2) == (5, 4, 7) + assert dmp_degree_list(f_4, 2) == (9, 12, 8) + assert dmp_degree_list(f_5, 2) == (3, 3, 3) + assert dmp_degree_list(f_6, 3) == (4, 4, 6, 3) + + +def test_dup_strip(): + assert dup_strip([]) == [] + assert dup_strip([0]) == [] + assert dup_strip([0, 0, 0]) == [] + + assert dup_strip([1]) == [1] + assert dup_strip([0, 1]) == [1] + assert dup_strip([0, 0, 0, 1]) == [1] + + assert dup_strip([1, 2, 0]) == [1, 2, 0] + assert dup_strip([0, 1, 2, 0]) == [1, 2, 0] + assert dup_strip([0, 0, 0, 1, 2, 0]) == [1, 2, 0] + + +def test_dmp_strip(): + assert dmp_strip([0, 1, 0], 0) == [1, 0] + + assert dmp_strip([[]], 1) == [[]] + assert dmp_strip([[], []], 1) == [[]] + assert dmp_strip([[], [], []], 1) == [[]] + + assert dmp_strip([[[]]], 2) == [[[]]] + assert dmp_strip([[[]], [[]]], 2) == [[[]]] + assert dmp_strip([[[]], [[]], [[]]], 2) == [[[]]] + + assert dmp_strip([[[1]]], 2) == [[[1]]] + assert dmp_strip([[[]], [[1]]], 2) == [[[1]]] + assert dmp_strip([[[]], [[1]], [[]]], 2) == [[[1]], [[]]] + + +def test_dmp_validate(): + assert dmp_validate([]) == ([], 0) + assert dmp_validate([0, 0, 0, 1, 0]) == ([1, 0], 0) + + assert dmp_validate([[[]]]) == ([[[]]], 2) + assert dmp_validate([[0], [], [0], [1], [0]]) == ([[1], []], 1) + + raises(ValueError, lambda: dmp_validate([[0], 0, [0], [1], [0]])) + + +def test_dup_reverse(): + assert dup_reverse([1, 2, 0, 3]) == [3, 0, 2, 1] + assert dup_reverse([1, 2, 3, 0]) == [3, 2, 1] + + +def test_dup_copy(): + f = [ZZ(1), ZZ(0), ZZ(2)] + g = dup_copy(f) + + g[0], g[2] = ZZ(7), ZZ(0) + + assert f != g + + +def test_dmp_copy(): + f = [[ZZ(1)], [ZZ(2), ZZ(0)]] + g = dmp_copy(f, 1) + + g[0][0], g[1][1] = ZZ(7), ZZ(1) + + assert f != g + + +def test_dup_normal(): + assert dup_normal([0, 0, 2, 1, 0, 11, 0], ZZ) == \ + [ZZ(2), ZZ(1), ZZ(0), ZZ(11), ZZ(0)] + + +def test_dmp_normal(): + assert dmp_normal([[0], [], [0, 2, 1], [0], [11], []], 1, ZZ) == \ + [[ZZ(2), ZZ(1)], [], [ZZ(11)], []] + + +def test_dup_convert(): + K0, K1 = ZZ['x'], ZZ + + f = [K0(1), K0(2), K0(0), K0(3)] + + assert dup_convert(f, K0, K1) == \ + [ZZ(1), ZZ(2), ZZ(0), ZZ(3)] + + +def test_dmp_convert(): + K0, K1 = ZZ['x'], ZZ + + f = [[K0(1)], [K0(2)], [], [K0(3)]] + + assert dmp_convert(f, 1, K0, K1) == \ + [[ZZ(1)], [ZZ(2)], [], [ZZ(3)]] + + +def test_dup_from_sympy(): + assert dup_from_sympy([S.One, S(2)], ZZ) == \ + [ZZ(1), ZZ(2)] + assert dup_from_sympy([S.Half, S(3)], QQ) == \ + [QQ(1, 2), QQ(3, 1)] + + +def test_dmp_from_sympy(): + assert dmp_from_sympy([[S.One, S(2)], [S.Zero]], 1, ZZ) == \ + [[ZZ(1), ZZ(2)], []] + assert dmp_from_sympy([[S.Half, S(2)]], 1, QQ) == \ + [[QQ(1, 2), QQ(2, 1)]] + + +def test_dup_nth(): + assert dup_nth([1, 2, 3], 0, ZZ) == 3 + assert dup_nth([1, 2, 3], 1, ZZ) == 2 + assert dup_nth([1, 2, 3], 2, ZZ) == 1 + + assert dup_nth([1, 2, 3], 9, ZZ) == 0 + + raises(IndexError, lambda: dup_nth([3, 4, 5], -1, ZZ)) + + +def test_dmp_nth(): + assert dmp_nth([[1], [2], [3]], 0, 1, ZZ) == [3] + assert dmp_nth([[1], [2], [3]], 1, 1, ZZ) == [2] + assert dmp_nth([[1], [2], [3]], 2, 1, ZZ) == [1] + + assert dmp_nth([[1], [2], [3]], 9, 1, ZZ) == [] + + raises(IndexError, lambda: dmp_nth([[3], [4], [5]], -1, 1, ZZ)) + + +def test_dmp_ground_nth(): + assert dmp_ground_nth([[]], (0, 0), 1, ZZ) == 0 + assert dmp_ground_nth([[1], [2], [3]], (0, 0), 1, ZZ) == 3 + assert dmp_ground_nth([[1], [2], [3]], (1, 0), 1, ZZ) == 2 + assert dmp_ground_nth([[1], [2], [3]], (2, 0), 1, ZZ) == 1 + + assert dmp_ground_nth([[1], [2], [3]], (2, 1), 1, ZZ) == 0 + assert dmp_ground_nth([[1], [2], [3]], (3, 0), 1, ZZ) == 0 + + raises(IndexError, lambda: dmp_ground_nth([[3], [4], [5]], (2, -1), 1, ZZ)) + + +def test_dmp_zero_p(): + assert dmp_zero_p([], 0) is True + assert dmp_zero_p([[]], 1) is True + + assert dmp_zero_p([[[]]], 2) is True + assert dmp_zero_p([[[1]]], 2) is False + + +def test_dmp_zero(): + assert dmp_zero(0) == [] + assert dmp_zero(2) == [[[]]] + + +def test_dmp_one_p(): + assert dmp_one_p([1], 0, ZZ) is True + assert dmp_one_p([[1]], 1, ZZ) is True + assert dmp_one_p([[[1]]], 2, ZZ) is True + assert dmp_one_p([[[12]]], 2, ZZ) is False + + +def test_dmp_one(): + assert dmp_one(0, ZZ) == [ZZ(1)] + assert dmp_one(2, ZZ) == [[[ZZ(1)]]] + + +def test_dmp_ground_p(): + assert dmp_ground_p([], 0, 0) is True + assert dmp_ground_p([[]], 0, 1) is True + assert dmp_ground_p([[]], 1, 1) is False + + assert dmp_ground_p([[ZZ(1)]], 1, 1) is True + assert dmp_ground_p([[[ZZ(2)]]], 2, 2) is True + + assert dmp_ground_p([[[ZZ(2)]]], 3, 2) is False + assert dmp_ground_p([[[ZZ(3)], []]], 3, 2) is False + + assert dmp_ground_p([], None, 0) is True + assert dmp_ground_p([[]], None, 1) is True + + assert dmp_ground_p([ZZ(1)], None, 0) is True + assert dmp_ground_p([[[ZZ(1)]]], None, 2) is True + + assert dmp_ground_p([[[ZZ(3)], []]], None, 2) is False + + +def test_dmp_ground(): + assert dmp_ground(ZZ(0), 2) == [[[]]] + + assert dmp_ground(ZZ(7), -1) == ZZ(7) + assert dmp_ground(ZZ(7), 0) == [ZZ(7)] + assert dmp_ground(ZZ(7), 2) == [[[ZZ(7)]]] + + +def test_dmp_zeros(): + assert dmp_zeros(4, 0, ZZ) == [[], [], [], []] + + assert dmp_zeros(0, 2, ZZ) == [] + assert dmp_zeros(1, 2, ZZ) == [[[[]]]] + assert dmp_zeros(2, 2, ZZ) == [[[[]]], [[[]]]] + assert dmp_zeros(3, 2, ZZ) == [[[[]]], [[[]]], [[[]]]] + + assert dmp_zeros(3, -1, ZZ) == [0, 0, 0] + + +def test_dmp_grounds(): + assert dmp_grounds(ZZ(7), 0, 2) == [] + + assert dmp_grounds(ZZ(7), 1, 2) == [[[[7]]]] + assert dmp_grounds(ZZ(7), 2, 2) == [[[[7]]], [[[7]]]] + assert dmp_grounds(ZZ(7), 3, 2) == [[[[7]]], [[[7]]], [[[7]]]] + + assert dmp_grounds(ZZ(7), 3, -1) == [7, 7, 7] + + +def test_dmp_negative_p(): + assert dmp_negative_p([[[]]], 2, ZZ) is False + assert dmp_negative_p([[[1], [2]]], 2, ZZ) is False + assert dmp_negative_p([[[-1], [2]]], 2, ZZ) is True + + +def test_dmp_positive_p(): + assert dmp_positive_p([[[]]], 2, ZZ) is False + assert dmp_positive_p([[[1], [2]]], 2, ZZ) is True + assert dmp_positive_p([[[-1], [2]]], 2, ZZ) is False + + +def test_dup_from_to_dict(): + assert dup_from_raw_dict({}, ZZ) == [] + assert dup_from_dict({}, ZZ) == [] + + assert dup_to_raw_dict([]) == {} + assert dup_to_dict([]) == {} + + assert dup_to_raw_dict([], ZZ, zero=True) == {0: ZZ(0)} + assert dup_to_dict([], ZZ, zero=True) == {(0,): ZZ(0)} + + f = [3, 0, 0, 2, 0, 0, 0, 0, 8] + g = {8: 3, 5: 2, 0: 8} + h = {(8,): 3, (5,): 2, (0,): 8} + + assert dup_from_raw_dict(g, ZZ) == f + assert dup_from_dict(h, ZZ) == f + + assert dup_to_raw_dict(f) == g + assert dup_to_dict(f) == h + + R, x,y = ring("x,y", ZZ) + K = R.to_domain() + + f = [R(3), R(0), R(2), R(0), R(0), R(8)] + g = {5: R(3), 3: R(2), 0: R(8)} + h = {(5,): R(3), (3,): R(2), (0,): R(8)} + + assert dup_from_raw_dict(g, K) == f + assert dup_from_dict(h, K) == f + + assert dup_to_raw_dict(f) == g + assert dup_to_dict(f) == h + + +def test_dmp_from_to_dict(): + assert dmp_from_dict({}, 1, ZZ) == [[]] + assert dmp_to_dict([[]], 1) == {} + + assert dmp_to_dict([], 0, ZZ, zero=True) == {(0,): ZZ(0)} + assert dmp_to_dict([[]], 1, ZZ, zero=True) == {(0, 0): ZZ(0)} + + f = [[3], [], [], [2], [], [], [], [], [8]] + g = {(8, 0): 3, (5, 0): 2, (0, 0): 8} + + assert dmp_from_dict(g, 1, ZZ) == f + assert dmp_to_dict(f, 1) == g + + +def test_dmp_swap(): + f = dmp_normal([[1, 0, 0], [], [1, 0], [], [1]], 1, ZZ) + g = dmp_normal([[1, 0, 0, 0, 0], [1, 0, 0], [1]], 1, ZZ) + + assert dmp_swap(f, 1, 1, 1, ZZ) == f + + assert dmp_swap(f, 0, 1, 1, ZZ) == g + assert dmp_swap(g, 0, 1, 1, ZZ) == f + + raises(IndexError, lambda: dmp_swap(f, -1, -7, 1, ZZ)) + + +def test_dmp_permute(): + f = dmp_normal([[1, 0, 0], [], [1, 0], [], [1]], 1, ZZ) + g = dmp_normal([[1, 0, 0, 0, 0], [1, 0, 0], [1]], 1, ZZ) + + assert dmp_permute(f, [0, 1], 1, ZZ) == f + assert dmp_permute(g, [0, 1], 1, ZZ) == g + + assert dmp_permute(f, [1, 0], 1, ZZ) == g + assert dmp_permute(g, [1, 0], 1, ZZ) == f + + +def test_dmp_nest(): + assert dmp_nest(ZZ(1), 2, ZZ) == [[[1]]] + + assert dmp_nest([[1]], 0, ZZ) == [[1]] + assert dmp_nest([[1]], 1, ZZ) == [[[1]]] + assert dmp_nest([[1]], 2, ZZ) == [[[[1]]]] + + +def test_dmp_raise(): + assert dmp_raise([], 2, 0, ZZ) == [[[]]] + assert dmp_raise([[1]], 0, 1, ZZ) == [[1]] + + assert dmp_raise([[1, 2, 3], [], [2, 3]], 2, 1, ZZ) == \ + [[[[1]], [[2]], [[3]]], [[[]]], [[[2]], [[3]]]] + + +def test_dup_deflate(): + assert dup_deflate([], ZZ) == (1, []) + assert dup_deflate([2], ZZ) == (1, [2]) + assert dup_deflate([1, 2, 3], ZZ) == (1, [1, 2, 3]) + assert dup_deflate([1, 0, 2, 0, 3], ZZ) == (2, [1, 2, 3]) + + assert dup_deflate(dup_from_raw_dict({7: 1, 1: 1}, ZZ), ZZ) == \ + (1, [1, 0, 0, 0, 0, 0, 1, 0]) + assert dup_deflate(dup_from_raw_dict({7: 1, 0: 1}, ZZ), ZZ) == \ + (7, [1, 1]) + assert dup_deflate(dup_from_raw_dict({7: 1, 3: 1}, ZZ), ZZ) == \ + (1, [1, 0, 0, 0, 1, 0, 0, 0]) + + assert dup_deflate(dup_from_raw_dict({7: 1, 4: 1}, ZZ), ZZ) == \ + (1, [1, 0, 0, 1, 0, 0, 0, 0]) + assert dup_deflate(dup_from_raw_dict({8: 1, 4: 1}, ZZ), ZZ) == \ + (4, [1, 1, 0]) + + assert dup_deflate(dup_from_raw_dict({8: 1}, ZZ), ZZ) == \ + (8, [1, 0]) + assert dup_deflate(dup_from_raw_dict({7: 1}, ZZ), ZZ) == \ + (7, [1, 0]) + assert dup_deflate(dup_from_raw_dict({1: 1}, ZZ), ZZ) == \ + (1, [1, 0]) + + +def test_dmp_deflate(): + assert dmp_deflate([[]], 1, ZZ) == ((1, 1), [[]]) + assert dmp_deflate([[2]], 1, ZZ) == ((1, 1), [[2]]) + + f = [[1, 0, 0], [], [1, 0], [], [1]] + + assert dmp_deflate(f, 1, ZZ) == ((2, 1), [[1, 0, 0], [1, 0], [1]]) + + +def test_dup_multi_deflate(): + assert dup_multi_deflate(([2],), ZZ) == (1, ([2],)) + assert dup_multi_deflate(([], []), ZZ) == (1, ([], [])) + + assert dup_multi_deflate(([1, 2, 3],), ZZ) == (1, ([1, 2, 3],)) + assert dup_multi_deflate(([1, 0, 2, 0, 3],), ZZ) == (2, ([1, 2, 3],)) + + assert dup_multi_deflate(([1, 0, 2, 0, 3], [2, 0, 0]), ZZ) == \ + (2, ([1, 2, 3], [2, 0])) + assert dup_multi_deflate(([1, 0, 2, 0, 3], [2, 1, 0]), ZZ) == \ + (1, ([1, 0, 2, 0, 3], [2, 1, 0])) + + +def test_dmp_multi_deflate(): + assert dmp_multi_deflate(([[]],), 1, ZZ) == \ + ((1, 1), ([[]],)) + assert dmp_multi_deflate(([[]], [[]]), 1, ZZ) == \ + ((1, 1), ([[]], [[]])) + + assert dmp_multi_deflate(([[1]], [[]]), 1, ZZ) == \ + ((1, 1), ([[1]], [[]])) + assert dmp_multi_deflate(([[1]], [[2]]), 1, ZZ) == \ + ((1, 1), ([[1]], [[2]])) + assert dmp_multi_deflate(([[1]], [[2, 0]]), 1, ZZ) == \ + ((1, 1), ([[1]], [[2, 0]])) + + assert dmp_multi_deflate(([[2, 0]], [[2, 0]]), 1, ZZ) == \ + ((1, 1), ([[2, 0]], [[2, 0]])) + + assert dmp_multi_deflate( + ([[2]], [[2, 0, 0]]), 1, ZZ) == ((1, 2), ([[2]], [[2, 0]])) + assert dmp_multi_deflate( + ([[2, 0, 0]], [[2, 0, 0]]), 1, ZZ) == ((1, 2), ([[2, 0]], [[2, 0]])) + + assert dmp_multi_deflate(([2, 0, 0], [1, 0, 4, 0, 1]), 0, ZZ) == \ + ((2,), ([2, 0], [1, 4, 1])) + + f = [[1, 0, 0], [], [1, 0], [], [1]] + g = [[1, 0, 1, 0], [], [1]] + + assert dmp_multi_deflate((f,), 1, ZZ) == \ + ((2, 1), ([[1, 0, 0], [1, 0], [1]],)) + + assert dmp_multi_deflate((f, g), 1, ZZ) == \ + ((2, 1), ([[1, 0, 0], [1, 0], [1]], + [[1, 0, 1, 0], [1]])) + + +def test_dup_inflate(): + assert dup_inflate([], 17, ZZ) == [] + + assert dup_inflate([1, 2, 3], 1, ZZ) == [1, 2, 3] + assert dup_inflate([1, 2, 3], 2, ZZ) == [1, 0, 2, 0, 3] + assert dup_inflate([1, 2, 3], 3, ZZ) == [1, 0, 0, 2, 0, 0, 3] + assert dup_inflate([1, 2, 3], 4, ZZ) == [1, 0, 0, 0, 2, 0, 0, 0, 3] + + raises(IndexError, lambda: dup_inflate([1, 2, 3], 0, ZZ)) + + +def test_dmp_inflate(): + assert dmp_inflate([1], (3,), 0, ZZ) == [1] + + assert dmp_inflate([[]], (3, 7), 1, ZZ) == [[]] + assert dmp_inflate([[2]], (1, 2), 1, ZZ) == [[2]] + + assert dmp_inflate([[2, 0]], (1, 1), 1, ZZ) == [[2, 0]] + assert dmp_inflate([[2, 0]], (1, 2), 1, ZZ) == [[2, 0, 0]] + assert dmp_inflate([[2, 0]], (1, 3), 1, ZZ) == [[2, 0, 0, 0]] + + assert dmp_inflate([[1, 0, 0], [1], [1, 0]], (2, 1), 1, ZZ) == \ + [[1, 0, 0], [], [1], [], [1, 0]] + + raises(IndexError, lambda: dmp_inflate([[]], (-3, 7), 1, ZZ)) + + +def test_dmp_exclude(): + assert dmp_exclude([[[]]], 2, ZZ) == ([], [[[]]], 2) + assert dmp_exclude([[[7]]], 2, ZZ) == ([], [[[7]]], 2) + + assert dmp_exclude([1, 2, 3], 0, ZZ) == ([], [1, 2, 3], 0) + assert dmp_exclude([[1], [2, 3]], 1, ZZ) == ([], [[1], [2, 3]], 1) + + assert dmp_exclude([[1, 2, 3]], 1, ZZ) == ([0], [1, 2, 3], 0) + assert dmp_exclude([[1], [2], [3]], 1, ZZ) == ([1], [1, 2, 3], 0) + + assert dmp_exclude([[[1, 2, 3]]], 2, ZZ) == ([0, 1], [1, 2, 3], 0) + assert dmp_exclude([[[1]], [[2]], [[3]]], 2, ZZ) == ([1, 2], [1, 2, 3], 0) + + +def test_dmp_include(): + assert dmp_include([1, 2, 3], [], 0, ZZ) == [1, 2, 3] + + assert dmp_include([1, 2, 3], [0], 0, ZZ) == [[1, 2, 3]] + assert dmp_include([1, 2, 3], [1], 0, ZZ) == [[1], [2], [3]] + + assert dmp_include([1, 2, 3], [0, 1], 0, ZZ) == [[[1, 2, 3]]] + assert dmp_include([1, 2, 3], [1, 2], 0, ZZ) == [[[1]], [[2]], [[3]]] + + +def test_dmp_inject(): + R, x,y = ring("x,y", ZZ) + K = R.to_domain() + + assert dmp_inject([], 0, K) == ([[[]]], 2) + assert dmp_inject([[]], 1, K) == ([[[[]]]], 3) + + assert dmp_inject([R(1)], 0, K) == ([[[1]]], 2) + assert dmp_inject([[R(1)]], 1, K) == ([[[[1]]]], 3) + + assert dmp_inject([R(1), 2*x + 3*y + 4], 0, K) == ([[[1]], [[2], [3, 4]]], 2) + + f = [3*x**2 + 7*x*y + 5*y**2, 2*x, R(0), x*y**2 + 11] + g = [[[3], [7, 0], [5, 0, 0]], [[2], []], [[]], [[1, 0, 0], [11]]] + + assert dmp_inject(f, 0, K) == (g, 2) + + +def test_dmp_eject(): + R, x,y = ring("x,y", ZZ) + K = R.to_domain() + + assert dmp_eject([[[]]], 2, K) == [] + assert dmp_eject([[[[]]]], 3, K) == [[]] + + assert dmp_eject([[[1]]], 2, K) == [R(1)] + assert dmp_eject([[[[1]]]], 3, K) == [[R(1)]] + + assert dmp_eject([[[1]], [[2], [3, 4]]], 2, K) == [R(1), 2*x + 3*y + 4] + + f = [3*x**2 + 7*x*y + 5*y**2, 2*x, R(0), x*y**2 + 11] + g = [[[3], [7, 0], [5, 0, 0]], [[2], []], [[]], [[1, 0, 0], [11]]] + + assert dmp_eject(g, 2, K) == f + + +def test_dup_terms_gcd(): + assert dup_terms_gcd([], ZZ) == (0, []) + assert dup_terms_gcd([1, 0, 1], ZZ) == (0, [1, 0, 1]) + assert dup_terms_gcd([1, 0, 1, 0], ZZ) == (1, [1, 0, 1]) + + +def test_dmp_terms_gcd(): + assert dmp_terms_gcd([[]], 1, ZZ) == ((0, 0), [[]]) + + assert dmp_terms_gcd([1, 0, 1, 0], 0, ZZ) == ((1,), [1, 0, 1]) + assert dmp_terms_gcd([[1], [], [1], []], 1, ZZ) == ((1, 0), [[1], [], [1]]) + + assert dmp_terms_gcd( + [[1, 0], [], [1]], 1, ZZ) == ((0, 0), [[1, 0], [], [1]]) + assert dmp_terms_gcd( + [[1, 0], [1, 0, 0], [], []], 1, ZZ) == ((2, 1), [[1], [1, 0]]) + + +def test_dmp_list_terms(): + assert dmp_list_terms([[[]]], 2, ZZ) == [((0, 0, 0), 0)] + assert dmp_list_terms([[[1]]], 2, ZZ) == [((0, 0, 0), 1)] + + assert dmp_list_terms([1, 2, 4, 3, 5], 0, ZZ) == \ + [((4,), 1), ((3,), 2), ((2,), 4), ((1,), 3), ((0,), 5)] + + assert dmp_list_terms([[1], [2, 4], [3, 5, 0]], 1, ZZ) == \ + [((2, 0), 1), ((1, 1), 2), ((1, 0), 4), ((0, 2), 3), ((0, 1), 5)] + + f = [[2, 0, 0, 0], [1, 0, 0], []] + + assert dmp_list_terms(f, 1, ZZ, order='lex') == [((2, 3), 2), ((1, 2), 1)] + assert dmp_list_terms( + f, 1, ZZ, order='grlex') == [((2, 3), 2), ((1, 2), 1)] + + f = [[2, 0, 0, 0], [1, 0, 0, 0, 0, 0], []] + + assert dmp_list_terms(f, 1, ZZ, order='lex') == [((2, 3), 2), ((1, 5), 1)] + assert dmp_list_terms( + f, 1, ZZ, order='grlex') == [((1, 5), 1), ((2, 3), 2)] + + +def test_dmp_apply_pairs(): + h = lambda a, b: a*b + + assert dmp_apply_pairs([1, 2, 3], [4, 5, 6], h, [], 0, ZZ) == [4, 10, 18] + + assert dmp_apply_pairs([2, 3], [4, 5, 6], h, [], 0, ZZ) == [10, 18] + assert dmp_apply_pairs([1, 2, 3], [5, 6], h, [], 0, ZZ) == [10, 18] + + assert dmp_apply_pairs( + [[1, 2], [3]], [[4, 5], [6]], h, [], 1, ZZ) == [[4, 10], [18]] + + assert dmp_apply_pairs( + [[1, 2], [3]], [[4], [5, 6]], h, [], 1, ZZ) == [[8], [18]] + assert dmp_apply_pairs( + [[1], [2, 3]], [[4, 5], [6]], h, [], 1, ZZ) == [[5], [18]] + + +def test_dup_slice(): + f = [1, 2, 3, 4] + + assert dup_slice(f, 0, 0, ZZ) == [] + assert dup_slice(f, 0, 1, ZZ) == [4] + assert dup_slice(f, 0, 2, ZZ) == [3, 4] + assert dup_slice(f, 0, 3, ZZ) == [2, 3, 4] + assert dup_slice(f, 0, 4, ZZ) == [1, 2, 3, 4] + + assert dup_slice(f, 0, 4, ZZ) == f + assert dup_slice(f, 0, 9, ZZ) == f + + assert dup_slice(f, 1, 0, ZZ) == [] + assert dup_slice(f, 1, 1, ZZ) == [] + assert dup_slice(f, 1, 2, ZZ) == [3, 0] + assert dup_slice(f, 1, 3, ZZ) == [2, 3, 0] + assert dup_slice(f, 1, 4, ZZ) == [1, 2, 3, 0] + + assert dup_slice([1, 2], 0, 3, ZZ) == [1, 2] + + g = [1, 0, 0, 2] + + assert dup_slice(g, 0, 3, ZZ) == [2] + + +def test_dup_random(): + f = dup_random(0, -10, 10, ZZ) + + assert dup_degree(f) == 0 + assert all(-10 <= c <= 10 for c in f) + + f = dup_random(1, -20, 20, ZZ) + + assert dup_degree(f) == 1 + assert all(-20 <= c <= 20 for c in f) + + f = dup_random(2, -30, 30, ZZ) + + assert dup_degree(f) == 2 + assert all(-30 <= c <= 30 for c in f) + + f = dup_random(3, -40, 40, ZZ) + + assert dup_degree(f) == 3 + assert all(-40 <= c <= 40 for c in f) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densetools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densetools.py new file mode 100644 index 0000000000000000000000000000000000000000..b4bebd2a6f061a13a7d34b7689c696456310f62e --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_densetools.py @@ -0,0 +1,714 @@ +"""Tests for dense recursive polynomials' tools. """ + +from sympy.polys.densebasic import ( + dup_normal, dmp_normal, + dup_from_raw_dict, + dmp_convert, dmp_swap, +) + +from sympy.polys.densearith import dmp_mul_ground + +from sympy.polys.densetools import ( + dup_clear_denoms, dmp_clear_denoms, + dup_integrate, dmp_integrate, dmp_integrate_in, + dup_diff, dmp_diff, dmp_diff_in, + dup_eval, dmp_eval, dmp_eval_in, + dmp_eval_tail, dmp_diff_eval_in, + dup_trunc, dmp_trunc, dmp_ground_trunc, + dup_monic, dmp_ground_monic, + dup_content, dmp_ground_content, + dup_primitive, dmp_ground_primitive, + dup_extract, dmp_ground_extract, + dup_real_imag, + dup_mirror, dup_scale, dup_shift, dmp_shift, + dup_transform, + dup_compose, dmp_compose, + dup_decompose, + dmp_lift, + dup_sign_variations, + dup_revert, dmp_revert, +) +from sympy.polys.polyclasses import ANP + +from sympy.polys.polyerrors import ( + MultivariatePolynomialError, + ExactQuotientFailed, + NotReversible, + DomainError, +) + +from sympy.polys.specialpolys import f_polys + +from sympy.polys.domains import FF, ZZ, QQ, ZZ_I, QQ_I, EX, RR +from sympy.polys.rings import ring + +from sympy.core.numbers import I +from sympy.core.singleton import S +from sympy.functions.elementary.trigonometric import sin + +from sympy.abc import x +from sympy.testing.pytest import raises + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = [ f.to_dense() for f in f_polys() ] + +def test_dup_integrate(): + assert dup_integrate([], 1, QQ) == [] + assert dup_integrate([], 2, QQ) == [] + + assert dup_integrate([QQ(1)], 1, QQ) == [QQ(1), QQ(0)] + assert dup_integrate([QQ(1)], 2, QQ) == [QQ(1, 2), QQ(0), QQ(0)] + + assert dup_integrate([QQ(1), QQ(2), QQ(3)], 0, QQ) == \ + [QQ(1), QQ(2), QQ(3)] + assert dup_integrate([QQ(1), QQ(2), QQ(3)], 1, QQ) == \ + [QQ(1, 3), QQ(1), QQ(3), QQ(0)] + assert dup_integrate([QQ(1), QQ(2), QQ(3)], 2, QQ) == \ + [QQ(1, 12), QQ(1, 3), QQ(3, 2), QQ(0), QQ(0)] + assert dup_integrate([QQ(1), QQ(2), QQ(3)], 3, QQ) == \ + [QQ(1, 60), QQ(1, 12), QQ(1, 2), QQ(0), QQ(0), QQ(0)] + + assert dup_integrate(dup_from_raw_dict({29: QQ(17)}, QQ), 3, QQ) == \ + dup_from_raw_dict({32: QQ(17, 29760)}, QQ) + + assert dup_integrate(dup_from_raw_dict({29: QQ(17), 5: QQ(1, 2)}, QQ), 3, QQ) == \ + dup_from_raw_dict({32: QQ(17, 29760), 8: QQ(1, 672)}, QQ) + + +def test_dmp_integrate(): + assert dmp_integrate([QQ(1)], 2, 0, QQ) == [QQ(1, 2), QQ(0), QQ(0)] + + assert dmp_integrate([[[]]], 1, 2, QQ) == [[[]]] + assert dmp_integrate([[[]]], 2, 2, QQ) == [[[]]] + + assert dmp_integrate([[[QQ(1)]]], 1, 2, QQ) == [[[QQ(1)]], [[]]] + assert dmp_integrate([[[QQ(1)]]], 2, 2, QQ) == [[[QQ(1, 2)]], [[]], [[]]] + + assert dmp_integrate([[QQ(1)], [QQ(2)], [QQ(3)]], 0, 1, QQ) == \ + [[QQ(1)], [QQ(2)], [QQ(3)]] + assert dmp_integrate([[QQ(1)], [QQ(2)], [QQ(3)]], 1, 1, QQ) == \ + [[QQ(1, 3)], [QQ(1)], [QQ(3)], []] + assert dmp_integrate([[QQ(1)], [QQ(2)], [QQ(3)]], 2, 1, QQ) == \ + [[QQ(1, 12)], [QQ(1, 3)], [QQ(3, 2)], [], []] + assert dmp_integrate([[QQ(1)], [QQ(2)], [QQ(3)]], 3, 1, QQ) == \ + [[QQ(1, 60)], [QQ(1, 12)], [QQ(1, 2)], [], [], []] + + +def test_dmp_integrate_in(): + f = dmp_convert(f_6, 3, ZZ, QQ) + + assert dmp_integrate_in(f, 2, 1, 3, QQ) == \ + dmp_swap( + dmp_integrate(dmp_swap(f, 0, 1, 3, QQ), 2, 3, QQ), 0, 1, 3, QQ) + assert dmp_integrate_in(f, 3, 1, 3, QQ) == \ + dmp_swap( + dmp_integrate(dmp_swap(f, 0, 1, 3, QQ), 3, 3, QQ), 0, 1, 3, QQ) + assert dmp_integrate_in(f, 2, 2, 3, QQ) == \ + dmp_swap( + dmp_integrate(dmp_swap(f, 0, 2, 3, QQ), 2, 3, QQ), 0, 2, 3, QQ) + assert dmp_integrate_in(f, 3, 2, 3, QQ) == \ + dmp_swap( + dmp_integrate(dmp_swap(f, 0, 2, 3, QQ), 3, 3, QQ), 0, 2, 3, QQ) + + raises(IndexError, lambda: dmp_integrate_in(f, 1, -1, 3, QQ)) + raises(IndexError, lambda: dmp_integrate_in(f, 1, 4, 3, QQ)) + + +def test_dup_diff(): + assert dup_diff([], 1, ZZ) == [] + assert dup_diff([7], 1, ZZ) == [] + assert dup_diff([2, 7], 1, ZZ) == [2] + assert dup_diff([1, 2, 1], 1, ZZ) == [2, 2] + assert dup_diff([1, 2, 3, 4], 1, ZZ) == [3, 4, 3] + assert dup_diff([1, -1, 0, 0, 2], 1, ZZ) == [4, -3, 0, 0] + + f = dup_normal([17, 34, 56, -345, 23, 76, 0, 0, 12, 3, 7], ZZ) + + assert dup_diff(f, 0, ZZ) == f + assert dup_diff(f, 1, ZZ) == [170, 306, 448, -2415, 138, 380, 0, 0, 24, 3] + assert dup_diff(f, 2, ZZ) == dup_diff(dup_diff(f, 1, ZZ), 1, ZZ) + assert dup_diff( + f, 3, ZZ) == dup_diff(dup_diff(dup_diff(f, 1, ZZ), 1, ZZ), 1, ZZ) + + K = FF(3) + f = dup_normal([17, 34, 56, -345, 23, 76, 0, 0, 12, 3, 7], K) + + assert dup_diff(f, 1, K) == dup_normal([2, 0, 1, 0, 0, 2, 0, 0, 0, 0], K) + assert dup_diff(f, 2, K) == dup_normal([1, 0, 0, 2, 0, 0, 0], K) + assert dup_diff(f, 3, K) == dup_normal([], K) + + assert dup_diff(f, 0, K) == f + assert dup_diff(f, 2, K) == dup_diff(dup_diff(f, 1, K), 1, K) + assert dup_diff( + f, 3, K) == dup_diff(dup_diff(dup_diff(f, 1, K), 1, K), 1, K) + + +def test_dmp_diff(): + assert dmp_diff([], 1, 0, ZZ) == [] + assert dmp_diff([[]], 1, 1, ZZ) == [[]] + assert dmp_diff([[[]]], 1, 2, ZZ) == [[[]]] + + assert dmp_diff([[[1], [2]]], 1, 2, ZZ) == [[[]]] + + assert dmp_diff([[[1]], [[]]], 1, 2, ZZ) == [[[1]]] + assert dmp_diff([[[3]], [[1]], [[]]], 1, 2, ZZ) == [[[6]], [[1]]] + + assert dmp_diff([1, -1, 0, 0, 2], 1, 0, ZZ) == \ + dup_diff([1, -1, 0, 0, 2], 1, ZZ) + + assert dmp_diff(f_6, 0, 3, ZZ) == f_6 + assert dmp_diff(f_6, 1, 3, ZZ) == [[[[8460]], [[]]], + [[[135, 0, 0], [], [], [-135, 0, 0]]], + [[[]]], + [[[-423]], [[-47]], [[]], [[141], [], [94, 0], []], [[]]]] + assert dmp_diff( + f_6, 2, 3, ZZ) == dmp_diff(dmp_diff(f_6, 1, 3, ZZ), 1, 3, ZZ) + assert dmp_diff(f_6, 3, 3, ZZ) == dmp_diff( + dmp_diff(dmp_diff(f_6, 1, 3, ZZ), 1, 3, ZZ), 1, 3, ZZ) + + K = FF(23) + F_6 = dmp_normal(f_6, 3, K) + + assert dmp_diff(F_6, 0, 3, K) == F_6 + assert dmp_diff(F_6, 1, 3, K) == dmp_diff(F_6, 1, 3, K) + assert dmp_diff(F_6, 2, 3, K) == dmp_diff(dmp_diff(F_6, 1, 3, K), 1, 3, K) + assert dmp_diff(F_6, 3, 3, K) == dmp_diff( + dmp_diff(dmp_diff(F_6, 1, 3, K), 1, 3, K), 1, 3, K) + + +def test_dmp_diff_in(): + assert dmp_diff_in(f_6, 2, 1, 3, ZZ) == \ + dmp_swap(dmp_diff(dmp_swap(f_6, 0, 1, 3, ZZ), 2, 3, ZZ), 0, 1, 3, ZZ) + assert dmp_diff_in(f_6, 3, 1, 3, ZZ) == \ + dmp_swap(dmp_diff(dmp_swap(f_6, 0, 1, 3, ZZ), 3, 3, ZZ), 0, 1, 3, ZZ) + assert dmp_diff_in(f_6, 2, 2, 3, ZZ) == \ + dmp_swap(dmp_diff(dmp_swap(f_6, 0, 2, 3, ZZ), 2, 3, ZZ), 0, 2, 3, ZZ) + assert dmp_diff_in(f_6, 3, 2, 3, ZZ) == \ + dmp_swap(dmp_diff(dmp_swap(f_6, 0, 2, 3, ZZ), 3, 3, ZZ), 0, 2, 3, ZZ) + + raises(IndexError, lambda: dmp_diff_in(f_6, 1, -1, 3, ZZ)) + raises(IndexError, lambda: dmp_diff_in(f_6, 1, 4, 3, ZZ)) + +def test_dup_eval(): + assert dup_eval([], 7, ZZ) == 0 + assert dup_eval([1, 2], 0, ZZ) == 2 + assert dup_eval([1, 2, 3], 7, ZZ) == 66 + + +def test_dmp_eval(): + assert dmp_eval([], 3, 0, ZZ) == 0 + + assert dmp_eval([[]], 3, 1, ZZ) == [] + assert dmp_eval([[[]]], 3, 2, ZZ) == [[]] + + assert dmp_eval([[1, 2]], 0, 1, ZZ) == [1, 2] + + assert dmp_eval([[[1]]], 3, 2, ZZ) == [[1]] + assert dmp_eval([[[1, 2]]], 3, 2, ZZ) == [[1, 2]] + + assert dmp_eval([[3, 2], [1, 2]], 3, 1, ZZ) == [10, 8] + assert dmp_eval([[[3, 2]], [[1, 2]]], 3, 2, ZZ) == [[10, 8]] + + +def test_dmp_eval_in(): + assert dmp_eval_in( + f_6, -2, 1, 3, ZZ) == dmp_eval(dmp_swap(f_6, 0, 1, 3, ZZ), -2, 3, ZZ) + assert dmp_eval_in( + f_6, 7, 1, 3, ZZ) == dmp_eval(dmp_swap(f_6, 0, 1, 3, ZZ), 7, 3, ZZ) + assert dmp_eval_in(f_6, -2, 2, 3, ZZ) == dmp_swap( + dmp_eval(dmp_swap(f_6, 0, 2, 3, ZZ), -2, 3, ZZ), 0, 1, 2, ZZ) + assert dmp_eval_in(f_6, 7, 2, 3, ZZ) == dmp_swap( + dmp_eval(dmp_swap(f_6, 0, 2, 3, ZZ), 7, 3, ZZ), 0, 1, 2, ZZ) + + f = [[[int(45)]], [[]], [[]], [[int(-9)], [-1], [], [int(3), int(0), int(10), int(0)]]] + + assert dmp_eval_in(f, -2, 2, 2, ZZ) == \ + [[45], [], [], [-9, -1, 0, -44]] + + raises(IndexError, lambda: dmp_eval_in(f_6, ZZ(1), -1, 3, ZZ)) + raises(IndexError, lambda: dmp_eval_in(f_6, ZZ(1), 4, 3, ZZ)) + + +def test_dmp_eval_tail(): + assert dmp_eval_tail([[]], [1], 1, ZZ) == [] + assert dmp_eval_tail([[[]]], [1], 2, ZZ) == [[]] + assert dmp_eval_tail([[[]]], [1, 2], 2, ZZ) == [] + + assert dmp_eval_tail(f_0, [], 2, ZZ) == f_0 + + assert dmp_eval_tail(f_0, [1, -17, 8], 2, ZZ) == 84496 + assert dmp_eval_tail(f_0, [-17, 8], 2, ZZ) == [-1409, 3, 85902] + assert dmp_eval_tail(f_0, [8], 2, ZZ) == [[83, 2], [3], [302, 81, 1]] + + assert dmp_eval_tail(f_1, [-17, 8], 2, ZZ) == [-136, 15699, 9166, -27144] + + assert dmp_eval_tail( + f_2, [-12, 3], 2, ZZ) == [-1377, 0, -702, -1224, 0, -624] + assert dmp_eval_tail( + f_3, [-12, 3], 2, ZZ) == [144, 82, -5181, -28872, -14868, -540] + + assert dmp_eval_tail( + f_4, [25, -1], 2, ZZ) == [152587890625, 9765625, -59605407714843750, + -3839159765625, -1562475, 9536712644531250, 610349546750, -4, 24414375000, 1562520] + assert dmp_eval_tail(f_5, [25, -1], 2, ZZ) == [-1, -78, -2028, -17576] + + assert dmp_eval_tail(f_6, [0, 2, 4], 3, ZZ) == [5040, 0, 0, 4480] + + +def test_dmp_diff_eval_in(): + assert dmp_diff_eval_in(f_6, 2, 7, 1, 3, ZZ) == \ + dmp_eval(dmp_diff(dmp_swap(f_6, 0, 1, 3, ZZ), 2, 3, ZZ), 7, 3, ZZ) + + assert dmp_diff_eval_in(f_6, 2, 7, 0, 3, ZZ) == \ + dmp_eval(dmp_diff(f_6, 2, 3, ZZ), 7, 3, ZZ) + + raises(IndexError, lambda: dmp_diff_eval_in(f_6, 1, ZZ(1), 4, 3, ZZ)) + + +def test_dup_revert(): + f = [-QQ(1, 720), QQ(0), QQ(1, 24), QQ(0), -QQ(1, 2), QQ(0), QQ(1)] + g = [QQ(61, 720), QQ(0), QQ(5, 24), QQ(0), QQ(1, 2), QQ(0), QQ(1)] + + assert dup_revert(f, 8, QQ) == g + + raises(NotReversible, lambda: dup_revert([QQ(1), QQ(0)], 3, QQ)) + + +def test_dmp_revert(): + f = [-QQ(1, 720), QQ(0), QQ(1, 24), QQ(0), -QQ(1, 2), QQ(0), QQ(1)] + g = [QQ(61, 720), QQ(0), QQ(5, 24), QQ(0), QQ(1, 2), QQ(0), QQ(1)] + + assert dmp_revert(f, 8, 0, QQ) == g + + raises(MultivariatePolynomialError, lambda: dmp_revert([[1]], 2, 1, QQ)) + + +def test_dup_trunc(): + assert dup_trunc([1, 2, 3, 4, 5, 6], ZZ(3), ZZ) == [1, -1, 0, 1, -1, 0] + assert dup_trunc([6, 5, 4, 3, 2, 1], ZZ(3), ZZ) == [-1, 1, 0, -1, 1] + + R = ZZ_I + assert dup_trunc([R(3), R(4), R(5)], R(3), R) == [R(1), R(-1)] + + K = FF(5) + assert dup_trunc([K(3), K(4), K(5)], K(3), K) == [K(1), K(0)] + + +def test_dmp_trunc(): + assert dmp_trunc([[]], [1, 2], 2, ZZ) == [[]] + assert dmp_trunc([[1, 2], [1, 4, 1], [1]], [1, 2], 1, ZZ) == [[-3], [1]] + + +def test_dmp_ground_trunc(): + assert dmp_ground_trunc(f_0, ZZ(3), 2, ZZ) == \ + dmp_normal( + [[[1, -1, 0], [-1]], [[]], [[1, -1, 0], [1, -1, 1], [1]]], 2, ZZ) + + +def test_dup_monic(): + assert dup_monic([3, 6, 9], ZZ) == [1, 2, 3] + + raises(ExactQuotientFailed, lambda: dup_monic([3, 4, 5], ZZ)) + + assert dup_monic([], QQ) == [] + assert dup_monic([QQ(1)], QQ) == [QQ(1)] + assert dup_monic([QQ(7), QQ(1), QQ(21)], QQ) == [QQ(1), QQ(1, 7), QQ(3)] + + +def test_dmp_ground_monic(): + assert dmp_ground_monic([3, 6, 9], 0, ZZ) == [1, 2, 3] + + assert dmp_ground_monic([[3], [6], [9]], 1, ZZ) == [[1], [2], [3]] + + raises( + ExactQuotientFailed, lambda: dmp_ground_monic([[3], [4], [5]], 1, ZZ)) + + assert dmp_ground_monic([[]], 1, QQ) == [[]] + assert dmp_ground_monic([[QQ(1)]], 1, QQ) == [[QQ(1)]] + assert dmp_ground_monic( + [[QQ(7)], [QQ(1)], [QQ(21)]], 1, QQ) == [[QQ(1)], [QQ(1, 7)], [QQ(3)]] + + +def test_dup_content(): + assert dup_content([], ZZ) == ZZ(0) + assert dup_content([1], ZZ) == ZZ(1) + assert dup_content([-1], ZZ) == ZZ(1) + assert dup_content([1, 1], ZZ) == ZZ(1) + assert dup_content([2, 2], ZZ) == ZZ(2) + assert dup_content([1, 2, 1], ZZ) == ZZ(1) + assert dup_content([2, 4, 2], ZZ) == ZZ(2) + + assert dup_content([QQ(2, 3), QQ(4, 9)], QQ) == QQ(2, 9) + assert dup_content([QQ(2, 3), QQ(4, 5)], QQ) == QQ(2, 15) + + +def test_dmp_ground_content(): + assert dmp_ground_content([[]], 1, ZZ) == ZZ(0) + assert dmp_ground_content([[]], 1, QQ) == QQ(0) + assert dmp_ground_content([[1]], 1, ZZ) == ZZ(1) + assert dmp_ground_content([[-1]], 1, ZZ) == ZZ(1) + assert dmp_ground_content([[1], [1]], 1, ZZ) == ZZ(1) + assert dmp_ground_content([[2], [2]], 1, ZZ) == ZZ(2) + assert dmp_ground_content([[1], [2], [1]], 1, ZZ) == ZZ(1) + assert dmp_ground_content([[2], [4], [2]], 1, ZZ) == ZZ(2) + + assert dmp_ground_content([[QQ(2, 3)], [QQ(4, 9)]], 1, QQ) == QQ(2, 9) + assert dmp_ground_content([[QQ(2, 3)], [QQ(4, 5)]], 1, QQ) == QQ(2, 15) + + assert dmp_ground_content(f_0, 2, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_0, ZZ(2), 2, ZZ), 2, ZZ) == ZZ(2) + + assert dmp_ground_content(f_1, 2, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_1, ZZ(3), 2, ZZ), 2, ZZ) == ZZ(3) + + assert dmp_ground_content(f_2, 2, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_2, ZZ(4), 2, ZZ), 2, ZZ) == ZZ(4) + + assert dmp_ground_content(f_3, 2, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_3, ZZ(5), 2, ZZ), 2, ZZ) == ZZ(5) + + assert dmp_ground_content(f_4, 2, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_4, ZZ(6), 2, ZZ), 2, ZZ) == ZZ(6) + + assert dmp_ground_content(f_5, 2, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_5, ZZ(7), 2, ZZ), 2, ZZ) == ZZ(7) + + assert dmp_ground_content(f_6, 3, ZZ) == ZZ(1) + assert dmp_ground_content( + dmp_mul_ground(f_6, ZZ(8), 3, ZZ), 3, ZZ) == ZZ(8) + + +def test_dup_primitive(): + assert dup_primitive([], ZZ) == (ZZ(0), []) + assert dup_primitive([ZZ(1)], ZZ) == (ZZ(1), [ZZ(1)]) + assert dup_primitive([ZZ(1), ZZ(1)], ZZ) == (ZZ(1), [ZZ(1), ZZ(1)]) + assert dup_primitive([ZZ(2), ZZ(2)], ZZ) == (ZZ(2), [ZZ(1), ZZ(1)]) + assert dup_primitive( + [ZZ(1), ZZ(2), ZZ(1)], ZZ) == (ZZ(1), [ZZ(1), ZZ(2), ZZ(1)]) + assert dup_primitive( + [ZZ(2), ZZ(4), ZZ(2)], ZZ) == (ZZ(2), [ZZ(1), ZZ(2), ZZ(1)]) + + assert dup_primitive([], QQ) == (QQ(0), []) + assert dup_primitive([QQ(1)], QQ) == (QQ(1), [QQ(1)]) + assert dup_primitive([QQ(1), QQ(1)], QQ) == (QQ(1), [QQ(1), QQ(1)]) + assert dup_primitive([QQ(2), QQ(2)], QQ) == (QQ(2), [QQ(1), QQ(1)]) + assert dup_primitive( + [QQ(1), QQ(2), QQ(1)], QQ) == (QQ(1), [QQ(1), QQ(2), QQ(1)]) + assert dup_primitive( + [QQ(2), QQ(4), QQ(2)], QQ) == (QQ(2), [QQ(1), QQ(2), QQ(1)]) + + assert dup_primitive( + [QQ(2, 3), QQ(4, 9)], QQ) == (QQ(2, 9), [QQ(3), QQ(2)]) + assert dup_primitive( + [QQ(2, 3), QQ(4, 5)], QQ) == (QQ(2, 15), [QQ(5), QQ(6)]) + + +def test_dmp_ground_primitive(): + assert dmp_ground_primitive([ZZ(1)], 0, ZZ) == (ZZ(1), [ZZ(1)]) + + assert dmp_ground_primitive([[]], 1, ZZ) == (ZZ(0), [[]]) + + assert dmp_ground_primitive(f_0, 2, ZZ) == (ZZ(1), f_0) + assert dmp_ground_primitive( + dmp_mul_ground(f_0, ZZ(2), 2, ZZ), 2, ZZ) == (ZZ(2), f_0) + + assert dmp_ground_primitive(f_1, 2, ZZ) == (ZZ(1), f_1) + assert dmp_ground_primitive( + dmp_mul_ground(f_1, ZZ(3), 2, ZZ), 2, ZZ) == (ZZ(3), f_1) + + assert dmp_ground_primitive(f_2, 2, ZZ) == (ZZ(1), f_2) + assert dmp_ground_primitive( + dmp_mul_ground(f_2, ZZ(4), 2, ZZ), 2, ZZ) == (ZZ(4), f_2) + + assert dmp_ground_primitive(f_3, 2, ZZ) == (ZZ(1), f_3) + assert dmp_ground_primitive( + dmp_mul_ground(f_3, ZZ(5), 2, ZZ), 2, ZZ) == (ZZ(5), f_3) + + assert dmp_ground_primitive(f_4, 2, ZZ) == (ZZ(1), f_4) + assert dmp_ground_primitive( + dmp_mul_ground(f_4, ZZ(6), 2, ZZ), 2, ZZ) == (ZZ(6), f_4) + + assert dmp_ground_primitive(f_5, 2, ZZ) == (ZZ(1), f_5) + assert dmp_ground_primitive( + dmp_mul_ground(f_5, ZZ(7), 2, ZZ), 2, ZZ) == (ZZ(7), f_5) + + assert dmp_ground_primitive(f_6, 3, ZZ) == (ZZ(1), f_6) + assert dmp_ground_primitive( + dmp_mul_ground(f_6, ZZ(8), 3, ZZ), 3, ZZ) == (ZZ(8), f_6) + + assert dmp_ground_primitive([[ZZ(2)]], 1, ZZ) == (ZZ(2), [[ZZ(1)]]) + assert dmp_ground_primitive([[QQ(2)]], 1, QQ) == (QQ(2), [[QQ(1)]]) + + assert dmp_ground_primitive( + [[QQ(2, 3)], [QQ(4, 9)]], 1, QQ) == (QQ(2, 9), [[QQ(3)], [QQ(2)]]) + assert dmp_ground_primitive( + [[QQ(2, 3)], [QQ(4, 5)]], 1, QQ) == (QQ(2, 15), [[QQ(5)], [QQ(6)]]) + + +def test_dup_extract(): + f = dup_normal([2930944, 0, 2198208, 0, 549552, 0, 45796], ZZ) + g = dup_normal([17585664, 0, 8792832, 0, 1099104, 0], ZZ) + + F = dup_normal([64, 0, 48, 0, 12, 0, 1], ZZ) + G = dup_normal([384, 0, 192, 0, 24, 0], ZZ) + + assert dup_extract(f, g, ZZ) == (45796, F, G) + + +def test_dmp_ground_extract(): + f = dmp_normal( + [[2930944], [], [2198208], [], [549552], [], [45796]], 1, ZZ) + g = dmp_normal([[17585664], [], [8792832], [], [1099104], []], 1, ZZ) + + F = dmp_normal([[64], [], [48], [], [12], [], [1]], 1, ZZ) + G = dmp_normal([[384], [], [192], [], [24], []], 1, ZZ) + + assert dmp_ground_extract(f, g, 1, ZZ) == (45796, F, G) + + +def test_dup_real_imag(): + assert dup_real_imag([], ZZ) == ([[]], [[]]) + assert dup_real_imag([1], ZZ) == ([[1]], [[]]) + + assert dup_real_imag([1, 1], ZZ) == ([[1], [1]], [[1, 0]]) + assert dup_real_imag([1, 2], ZZ) == ([[1], [2]], [[1, 0]]) + + assert dup_real_imag( + [1, 2, 3], ZZ) == ([[1], [2], [-1, 0, 3]], [[2, 0], [2, 0]]) + + assert dup_real_imag([ZZ(1), ZZ(0), ZZ(1), ZZ(3)], ZZ) == ( + [[ZZ(1)], [], [ZZ(-3), ZZ(0), ZZ(1)], [ZZ(3)]], + [[ZZ(3), ZZ(0)], [], [ZZ(-1), ZZ(0), ZZ(1), ZZ(0)]] + ) + + raises(DomainError, lambda: dup_real_imag([EX(1), EX(2)], EX)) + + + +def test_dup_mirror(): + assert dup_mirror([], ZZ) == [] + assert dup_mirror([1], ZZ) == [1] + + assert dup_mirror([1, 2, 3, 4, 5], ZZ) == [1, -2, 3, -4, 5] + assert dup_mirror([1, 2, 3, 4, 5, 6], ZZ) == [-1, 2, -3, 4, -5, 6] + + +def test_dup_scale(): + assert dup_scale([], -1, ZZ) == [] + assert dup_scale([1], -1, ZZ) == [1] + + assert dup_scale([1, 2, 3, 4, 5], -1, ZZ) == [1, -2, 3, -4, 5] + assert dup_scale([1, 2, 3, 4, 5], -7, ZZ) == [2401, -686, 147, -28, 5] + + +def test_dup_shift(): + assert dup_shift([], 1, ZZ) == [] + assert dup_shift([1], 1, ZZ) == [1] + + assert dup_shift([1, 2, 3, 4, 5], 1, ZZ) == [1, 6, 15, 20, 15] + assert dup_shift([1, 2, 3, 4, 5], 7, ZZ) == [1, 30, 339, 1712, 3267] + + +def test_dmp_shift(): + assert dmp_shift([ZZ(1), ZZ(2)], [ZZ(1)], 0, ZZ) == [ZZ(1), ZZ(3)] + + assert dmp_shift([[]], [ZZ(1), ZZ(2)], 1, ZZ) == [[]] + + xy = [[ZZ(1), ZZ(0)], []] # x*y + x1y2 = [[ZZ(1), ZZ(2)], [ZZ(1), ZZ(2)]] # (x+1)*(y+2) + assert dmp_shift(xy, [ZZ(1), ZZ(2)], 1, ZZ) == x1y2 + + +def test_dup_transform(): + assert dup_transform([], [], [1, 1], ZZ) == [] + assert dup_transform([], [1], [1, 1], ZZ) == [] + assert dup_transform([], [1, 2], [1, 1], ZZ) == [] + + assert dup_transform([6, -5, 4, -3, 17], [1, -3, 4], [2, -3], ZZ) == \ + [6, -82, 541, -2205, 6277, -12723, 17191, -13603, 4773] + + +def test_dup_compose(): + assert dup_compose([], [], ZZ) == [] + assert dup_compose([], [1], ZZ) == [] + assert dup_compose([], [1, 2], ZZ) == [] + + assert dup_compose([1], [], ZZ) == [1] + + assert dup_compose([1, 2, 0], [], ZZ) == [] + assert dup_compose([1, 2, 1], [], ZZ) == [1] + + assert dup_compose([1, 2, 1], [1], ZZ) == [4] + assert dup_compose([1, 2, 1], [7], ZZ) == [64] + + assert dup_compose([1, 2, 1], [1, -1], ZZ) == [1, 0, 0] + assert dup_compose([1, 2, 1], [1, 1], ZZ) == [1, 4, 4] + assert dup_compose([1, 2, 1], [1, 2, 1], ZZ) == [1, 4, 8, 8, 4] + + +def test_dmp_compose(): + assert dmp_compose([1, 2, 1], [1, 2, 1], 0, ZZ) == [1, 4, 8, 8, 4] + + assert dmp_compose([[[]]], [[[]]], 2, ZZ) == [[[]]] + assert dmp_compose([[[]]], [[[1]]], 2, ZZ) == [[[]]] + assert dmp_compose([[[]]], [[[1]], [[2]]], 2, ZZ) == [[[]]] + + assert dmp_compose([[[1]]], [], 2, ZZ) == [[[1]]] + + assert dmp_compose([[1], [2], [ ]], [[]], 1, ZZ) == [[]] + assert dmp_compose([[1], [2], [1]], [[]], 1, ZZ) == [[1]] + + assert dmp_compose([[1], [2], [1]], [[1]], 1, ZZ) == [[4]] + assert dmp_compose([[1], [2], [1]], [[7]], 1, ZZ) == [[64]] + + assert dmp_compose([[1], [2], [1]], [[1], [-1]], 1, ZZ) == [[1], [ ], [ ]] + assert dmp_compose([[1], [2], [1]], [[1], [ 1]], 1, ZZ) == [[1], [4], [4]] + + assert dmp_compose( + [[1], [2], [1]], [[1], [2], [1]], 1, ZZ) == [[1], [4], [8], [8], [4]] + + +def test_dup_decompose(): + assert dup_decompose([1], ZZ) == [[1]] + + assert dup_decompose([1, 0], ZZ) == [[1, 0]] + assert dup_decompose([1, 0, 0, 0], ZZ) == [[1, 0, 0, 0]] + + assert dup_decompose([1, 0, 0, 0, 0], ZZ) == [[1, 0, 0], [1, 0, 0]] + assert dup_decompose( + [1, 0, 0, 0, 0, 0, 0], ZZ) == [[1, 0, 0, 0], [1, 0, 0]] + + assert dup_decompose([7, 0, 0, 0, 1], ZZ) == [[7, 0, 1], [1, 0, 0]] + assert dup_decompose([4, 0, 3, 0, 2], ZZ) == [[4, 3, 2], [1, 0, 0]] + + f = [1, 0, 20, 0, 150, 0, 500, 0, 625, -2, 0, -10, 9] + + assert dup_decompose(f, ZZ) == [[1, 0, 0, -2, 9], [1, 0, 5, 0]] + + f = [2, 0, 40, 0, 300, 0, 1000, 0, 1250, -4, 0, -20, 18] + + assert dup_decompose(f, ZZ) == [[2, 0, 0, -4, 18], [1, 0, 5, 0]] + + f = [1, 0, 20, -8, 150, -120, 524, -600, 865, -1034, 600, -170, 29] + + assert dup_decompose(f, ZZ) == [[1, -8, 24, -34, 29], [1, 0, 5, 0]] + + R, t = ring("t", ZZ) + f = [6*t**2 - 42, + 48*t**2 + 96, + 144*t**2 + 648*t + 288, + 624*t**2 + 864*t + 384, + 108*t**3 + 312*t**2 + 432*t + 192] + + assert dup_decompose(f, R.to_domain()) == [f] + + +def test_dmp_lift(): + q = [QQ(1, 1), QQ(0, 1), QQ(1, 1)] + + f_a = [ANP([QQ(1, 1)], q, QQ), ANP([], q, QQ), ANP([], q, QQ), + ANP([QQ(1, 1), QQ(0, 1)], q, QQ), ANP([QQ(17, 1), QQ(0, 1)], q, QQ)] + + f_lift = QQ.map([1, 0, 0, 0, 0, 0, 1, 34, 289]) + + assert dmp_lift(f_a, 0, QQ.algebraic_field(I)) == f_lift + + f_g = [QQ_I(1), QQ_I(0), QQ_I(0), QQ_I(0, 1), QQ_I(0, 17)] + + assert dmp_lift(f_g, 0, QQ_I) == f_lift + + raises(DomainError, lambda: dmp_lift([EX(1), EX(2)], 0, EX)) + + +def test_dup_sign_variations(): + assert dup_sign_variations([], ZZ) == 0 + assert dup_sign_variations([1, 0], ZZ) == 0 + assert dup_sign_variations([1, 0, 2], ZZ) == 0 + assert dup_sign_variations([1, 0, 3, 0], ZZ) == 0 + assert dup_sign_variations([1, 0, 4, 0, 5], ZZ) == 0 + + assert dup_sign_variations([-1, 0, 2], ZZ) == 1 + assert dup_sign_variations([-1, 0, 3, 0], ZZ) == 1 + assert dup_sign_variations([-1, 0, 4, 0, 5], ZZ) == 1 + + assert dup_sign_variations([-1, -4, -5], ZZ) == 0 + assert dup_sign_variations([ 1, -4, -5], ZZ) == 1 + assert dup_sign_variations([ 1, 4, -5], ZZ) == 1 + assert dup_sign_variations([ 1, -4, 5], ZZ) == 2 + assert dup_sign_variations([-1, 4, -5], ZZ) == 2 + assert dup_sign_variations([-1, 4, 5], ZZ) == 1 + assert dup_sign_variations([-1, -4, 5], ZZ) == 1 + assert dup_sign_variations([ 1, 4, 5], ZZ) == 0 + + assert dup_sign_variations([-1, 0, -4, 0, -5], ZZ) == 0 + assert dup_sign_variations([ 1, 0, -4, 0, -5], ZZ) == 1 + assert dup_sign_variations([ 1, 0, 4, 0, -5], ZZ) == 1 + assert dup_sign_variations([ 1, 0, -4, 0, 5], ZZ) == 2 + assert dup_sign_variations([-1, 0, 4, 0, -5], ZZ) == 2 + assert dup_sign_variations([-1, 0, 4, 0, 5], ZZ) == 1 + assert dup_sign_variations([-1, 0, -4, 0, 5], ZZ) == 1 + assert dup_sign_variations([ 1, 0, 4, 0, 5], ZZ) == 0 + + +def test_dup_clear_denoms(): + assert dup_clear_denoms([], QQ, ZZ) == (ZZ(1), []) + + assert dup_clear_denoms([QQ(1)], QQ, ZZ) == (ZZ(1), [QQ(1)]) + assert dup_clear_denoms([QQ(7)], QQ, ZZ) == (ZZ(1), [QQ(7)]) + + assert dup_clear_denoms([QQ(7, 3)], QQ) == (ZZ(3), [QQ(7)]) + assert dup_clear_denoms([QQ(7, 3)], QQ, ZZ) == (ZZ(3), [QQ(7)]) + + assert dup_clear_denoms( + [QQ(3), QQ(1), QQ(0)], QQ, ZZ) == (ZZ(1), [QQ(3), QQ(1), QQ(0)]) + assert dup_clear_denoms( + [QQ(1), QQ(1, 2), QQ(0)], QQ, ZZ) == (ZZ(2), [QQ(2), QQ(1), QQ(0)]) + + assert dup_clear_denoms([QQ(3), QQ( + 1), QQ(0)], QQ, ZZ, convert=True) == (ZZ(1), [ZZ(3), ZZ(1), ZZ(0)]) + assert dup_clear_denoms([QQ(1), QQ( + 1, 2), QQ(0)], QQ, ZZ, convert=True) == (ZZ(2), [ZZ(2), ZZ(1), ZZ(0)]) + + assert dup_clear_denoms( + [EX(S(3)/2), EX(S(9)/4)], EX) == (EX(4), [EX(6), EX(9)]) + + assert dup_clear_denoms([EX(7)], EX) == (EX(1), [EX(7)]) + assert dup_clear_denoms([EX(sin(x)/x), EX(0)], EX) == (EX(x), [EX(sin(x)), EX(0)]) + + F = RR.frac_field(x) + result = dup_clear_denoms([F(8.48717/(8.0089*x + 2.83)), F(0.0)], F) + assert str(result) == "(x + 0.353356890459364, [1.05971731448763, 0.0])" + +def test_dmp_clear_denoms(): + assert dmp_clear_denoms([[]], 1, QQ, ZZ) == (ZZ(1), [[]]) + + assert dmp_clear_denoms([[QQ(1)]], 1, QQ, ZZ) == (ZZ(1), [[QQ(1)]]) + assert dmp_clear_denoms([[QQ(7)]], 1, QQ, ZZ) == (ZZ(1), [[QQ(7)]]) + + assert dmp_clear_denoms([[QQ(7, 3)]], 1, QQ) == (ZZ(3), [[QQ(7)]]) + assert dmp_clear_denoms([[QQ(7, 3)]], 1, QQ, ZZ) == (ZZ(3), [[QQ(7)]]) + + assert dmp_clear_denoms( + [[QQ(3)], [QQ(1)], []], 1, QQ, ZZ) == (ZZ(1), [[QQ(3)], [QQ(1)], []]) + assert dmp_clear_denoms([[QQ( + 1)], [QQ(1, 2)], []], 1, QQ, ZZ) == (ZZ(2), [[QQ(2)], [QQ(1)], []]) + + assert dmp_clear_denoms([QQ(3), QQ( + 1), QQ(0)], 0, QQ, ZZ, convert=True) == (ZZ(1), [ZZ(3), ZZ(1), ZZ(0)]) + assert dmp_clear_denoms([QQ(1), QQ(1, 2), QQ( + 0)], 0, QQ, ZZ, convert=True) == (ZZ(2), [ZZ(2), ZZ(1), ZZ(0)]) + + assert dmp_clear_denoms([[QQ(3)], [QQ( + 1)], []], 1, QQ, ZZ, convert=True) == (ZZ(1), [[QQ(3)], [QQ(1)], []]) + assert dmp_clear_denoms([[QQ(1)], [QQ(1, 2)], []], 1, QQ, ZZ, + convert=True) == (ZZ(2), [[QQ(2)], [QQ(1)], []]) + + assert dmp_clear_denoms( + [[EX(S(3)/2)], [EX(S(9)/4)]], 1, EX) == (EX(4), [[EX(6)], [EX(9)]]) + assert dmp_clear_denoms([[EX(7)]], 1, EX) == (EX(1), [[EX(7)]]) + assert dmp_clear_denoms([[EX(sin(x)/x), EX(0)]], 1, EX) == (EX(x), [[EX(sin(x)), EX(0)]]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_dispersion.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_dispersion.py new file mode 100644 index 0000000000000000000000000000000000000000..ad56b7bebd73c38e037085d36625a41729c0369a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_dispersion.py @@ -0,0 +1,95 @@ +from sympy.core import Symbol, S, oo +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.polys import poly +from sympy.polys.dispersion import dispersion, dispersionset + + +def test_dispersion(): + x = Symbol("x") + a = Symbol("a") + + fp = poly(S.Zero, x) + assert sorted(dispersionset(fp)) == [0] + + fp = poly(S(2), x) + assert sorted(dispersionset(fp)) == [0] + + fp = poly(x + 1, x) + assert sorted(dispersionset(fp)) == [0] + assert dispersion(fp) == 0 + + fp = poly((x + 1)*(x + 2), x) + assert sorted(dispersionset(fp)) == [0, 1] + assert dispersion(fp) == 1 + + fp = poly(x*(x + 3), x) + assert sorted(dispersionset(fp)) == [0, 3] + assert dispersion(fp) == 3 + + fp = poly((x - 3)*(x + 3), x) + assert sorted(dispersionset(fp)) == [0, 6] + assert dispersion(fp) == 6 + + fp = poly(x**4 - 3*x**2 + 1, x) + gp = fp.shift(-3) + assert sorted(dispersionset(fp, gp)) == [2, 3, 4] + assert dispersion(fp, gp) == 4 + assert sorted(dispersionset(gp, fp)) == [] + assert dispersion(gp, fp) is -oo + + fp = poly(x*(3*x**2+a)*(x-2536)*(x**3+a), x) + gp = fp.as_expr().subs(x, x-345).as_poly(x) + assert sorted(dispersionset(fp, gp)) == [345, 2881] + assert sorted(dispersionset(gp, fp)) == [2191] + + gp = poly((x-2)**2*(x-3)**3*(x-5)**3, x) + assert sorted(dispersionset(gp)) == [0, 1, 2, 3] + assert sorted(dispersionset(gp, (gp+4)**2)) == [1, 2] + + fp = poly(x*(x+2)*(x-1), x) + assert sorted(dispersionset(fp)) == [0, 1, 2, 3] + + fp = poly(x**2 + sqrt(5)*x - 1, x, domain='QQ') + gp = poly(x**2 + (2 + sqrt(5))*x + sqrt(5), x, domain='QQ') + assert sorted(dispersionset(fp, gp)) == [2] + assert sorted(dispersionset(gp, fp)) == [1, 4] + + # There are some difficulties if we compute over Z[a] + # and alpha happens to lie in Z[a] instead of simply Z. + # Hence we can not decide if alpha is indeed integral + # in general. + + fp = poly(4*x**4 + (4*a + 8)*x**3 + (a**2 + 6*a + 4)*x**2 + (a**2 + 2*a)*x, x) + assert sorted(dispersionset(fp)) == [0, 1] + + # For any specific value of a, the dispersion is 3*a + # but the algorithm can not find this in general. + # This is the point where the resultant based Ansatz + # is superior to the current one. + fp = poly(a**2*x**3 + (a**3 + a**2 + a + 1)*x, x) + gp = fp.as_expr().subs(x, x - 3*a).as_poly(x) + assert sorted(dispersionset(fp, gp)) == [] + + fpa = fp.as_expr().subs(a, 2).as_poly(x) + gpa = gp.as_expr().subs(a, 2).as_poly(x) + assert sorted(dispersionset(fpa, gpa)) == [6] + + # Work with Expr instead of Poly + f = (x + 1)*(x + 2) + assert sorted(dispersionset(f)) == [0, 1] + assert dispersion(f) == 1 + + f = x**4 - 3*x**2 + 1 + g = x**4 - 12*x**3 + 51*x**2 - 90*x + 55 + assert sorted(dispersionset(f, g)) == [2, 3, 4] + assert dispersion(f, g) == 4 + + # Work with Expr and specify a generator + f = (x + 1)*(x + 2) + assert sorted(dispersionset(f, None, x)) == [0, 1] + assert dispersion(f, None, x) == 1 + + f = x**4 - 3*x**2 + 1 + g = x**4 - 12*x**3 + 51*x**2 - 90*x + 55 + assert sorted(dispersionset(f, g, x)) == [2, 3, 4] + assert dispersion(f, g, x) == 4 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_distributedmodules.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_distributedmodules.py new file mode 100644 index 0000000000000000000000000000000000000000..c95672f99f878f3def660aadec901afbde9adf8b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_distributedmodules.py @@ -0,0 +1,208 @@ +"""Tests for sparse distributed modules. """ + +from sympy.polys.distributedmodules import ( + sdm_monomial_mul, sdm_monomial_deg, sdm_monomial_divides, + sdm_add, sdm_LM, sdm_LT, sdm_mul_term, sdm_zero, sdm_deg, + sdm_LC, sdm_from_dict, + sdm_spoly, sdm_ecart, sdm_nf_mora, sdm_groebner, + sdm_from_vector, sdm_to_vector, sdm_monomial_lcm +) + +from sympy.polys.orderings import lex, grlex, InverseOrder +from sympy.polys.domains import QQ + +from sympy.abc import x, y, z + + +def test_sdm_monomial_mul(): + assert sdm_monomial_mul((1, 1, 0), (1, 3)) == (1, 2, 3) + + +def test_sdm_monomial_deg(): + assert sdm_monomial_deg((5, 2, 1)) == 3 + + +def test_sdm_monomial_lcm(): + assert sdm_monomial_lcm((1, 2, 3), (1, 5, 0)) == (1, 5, 3) + + +def test_sdm_monomial_divides(): + assert sdm_monomial_divides((1, 0, 0), (1, 0, 0)) is True + assert sdm_monomial_divides((1, 0, 0), (1, 2, 1)) is True + assert sdm_monomial_divides((5, 1, 1), (5, 2, 1)) is True + + assert sdm_monomial_divides((1, 0, 0), (2, 0, 0)) is False + assert sdm_monomial_divides((1, 1, 0), (1, 0, 0)) is False + assert sdm_monomial_divides((5, 1, 2), (5, 0, 1)) is False + + +def test_sdm_LC(): + assert sdm_LC([((1, 2, 3), QQ(5))], QQ) == QQ(5) + + +def test_sdm_from_dict(): + dic = {(1, 2, 1, 1): QQ(1), (1, 1, 2, 1): QQ(1), (1, 0, 2, 1): QQ(1), + (1, 0, 0, 3): QQ(1), (1, 1, 1, 0): QQ(1)} + assert sdm_from_dict(dic, grlex) == \ + [((1, 2, 1, 1), QQ(1)), ((1, 1, 2, 1), QQ(1)), + ((1, 0, 2, 1), QQ(1)), ((1, 0, 0, 3), QQ(1)), ((1, 1, 1, 0), QQ(1))] + +# TODO test to_dict? + + +def test_sdm_add(): + assert sdm_add([((1, 1, 1), QQ(1))], [((2, 0, 0), QQ(1))], lex, QQ) == \ + [((2, 0, 0), QQ(1)), ((1, 1, 1), QQ(1))] + assert sdm_add([((1, 1, 1), QQ(1))], [((1, 1, 1), QQ(-1))], lex, QQ) == [] + assert sdm_add([((1, 0, 0), QQ(1))], [((1, 0, 0), QQ(2))], lex, QQ) == \ + [((1, 0, 0), QQ(3))] + assert sdm_add([((1, 0, 1), QQ(1))], [((1, 1, 0), QQ(1))], lex, QQ) == \ + [((1, 1, 0), QQ(1)), ((1, 0, 1), QQ(1))] + + +def test_sdm_LM(): + dic = {(1, 2, 3): QQ(1), (4, 0, 0): QQ(1), (4, 0, 1): QQ(1)} + assert sdm_LM(sdm_from_dict(dic, lex)) == (4, 0, 1) + + +def test_sdm_LT(): + dic = {(1, 2, 3): QQ(1), (4, 0, 0): QQ(2), (4, 0, 1): QQ(3)} + assert sdm_LT(sdm_from_dict(dic, lex)) == ((4, 0, 1), QQ(3)) + + +def test_sdm_mul_term(): + assert sdm_mul_term([((1, 0, 0), QQ(1))], ((0, 0), QQ(0)), lex, QQ) == [] + assert sdm_mul_term([], ((1, 0), QQ(1)), lex, QQ) == [] + assert sdm_mul_term([((1, 0, 0), QQ(1))], ((1, 0), QQ(1)), lex, QQ) == \ + [((1, 1, 0), QQ(1))] + f = [((2, 0, 1), QQ(4)), ((1, 1, 0), QQ(3))] + assert sdm_mul_term(f, ((1, 1), QQ(2)), lex, QQ) == \ + [((2, 1, 2), QQ(8)), ((1, 2, 1), QQ(6))] + + +def test_sdm_zero(): + assert sdm_zero() == [] + + +def test_sdm_deg(): + assert sdm_deg([((1, 2, 3), 1), ((10, 0, 1), 1), ((2, 3, 4), 4)]) == 7 + + +def test_sdm_spoly(): + f = [((2, 1, 1), QQ(1)), ((1, 0, 1), QQ(1))] + g = [((2, 3, 0), QQ(1))] + h = [((1, 2, 3), QQ(1))] + assert sdm_spoly(f, h, lex, QQ) == [] + assert sdm_spoly(f, g, lex, QQ) == [((1, 2, 1), QQ(1))] + + +def test_sdm_ecart(): + assert sdm_ecart([((1, 2, 3), 1), ((1, 0, 1), 1)]) == 0 + assert sdm_ecart([((2, 2, 1), 1), ((1, 5, 1), 1)]) == 3 + + +def test_sdm_nf_mora(): + f = sdm_from_dict({(1, 2, 1, 1): QQ(1), (1, 1, 2, 1): QQ(1), + (1, 0, 2, 1): QQ(1), (1, 0, 0, 3): QQ(1), (1, 1, 1, 0): QQ(1)}, + grlex) + f1 = sdm_from_dict({(1, 1, 1, 0): QQ(1), (1, 0, 2, 0): QQ(1), + (1, 0, 0, 0): QQ(-1)}, grlex) + f2 = sdm_from_dict({(1, 1, 1, 0): QQ(1)}, grlex) + (id0, id1, id2) = [sdm_from_dict({(i, 0, 0, 0): QQ(1)}, grlex) + for i in range(3)] + + assert sdm_nf_mora(f, [f1, f2], grlex, QQ, phantom=(id0, [id1, id2])) == \ + ([((1, 0, 2, 1), QQ(1)), ((1, 0, 0, 3), QQ(1)), ((1, 1, 1, 0), QQ(1)), + ((1, 1, 0, 1), QQ(1))], + [((1, 1, 0, 1), QQ(-1)), ((0, 0, 0, 0), QQ(1))]) + assert sdm_nf_mora(f, [f2, f1], grlex, QQ, phantom=(id0, [id2, id1])) == \ + ([((1, 0, 2, 1), QQ(1)), ((1, 0, 0, 3), QQ(1)), ((1, 1, 1, 0), QQ(1))], + [((2, 1, 0, 1), QQ(-1)), ((2, 0, 1, 1), QQ(-1)), ((0, 0, 0, 0), QQ(1))]) + + f = sdm_from_vector([x*z, y**2 + y*z - z, y], lex, QQ, gens=[x, y, z]) + f1 = sdm_from_vector([x, y, 1], lex, QQ, gens=[x, y, z]) + f2 = sdm_from_vector([x*y, z, z**2], lex, QQ, gens=[x, y, z]) + assert sdm_nf_mora(f, [f1, f2], lex, QQ) == \ + sdm_nf_mora(f, [f2, f1], lex, QQ) == \ + [((1, 0, 1, 1), QQ(1)), ((1, 0, 0, 1), QQ(-1)), ((0, 1, 1, 0), QQ(-1)), + ((0, 1, 0, 1), QQ(1))] + + +def test_conversion(): + f = [x**2 + y**2, 2*z] + g = [((1, 0, 0, 1), QQ(2)), ((0, 2, 0, 0), QQ(1)), ((0, 0, 2, 0), QQ(1))] + assert sdm_to_vector(g, [x, y, z], QQ) == f + assert sdm_from_vector(f, lex, QQ) == g + assert sdm_from_vector( + [x, 1], lex, QQ) == [((1, 0), QQ(1)), ((0, 1), QQ(1))] + assert sdm_to_vector([((1, 1, 0, 0), 1)], [x, y, z], QQ, n=3) == [0, x, 0] + assert sdm_from_vector([0, 0], lex, QQ, gens=[x, y]) == sdm_zero() + + +def test_nontrivial(): + gens = [x, y, z] + + def contains(I, f): + S = [sdm_from_vector([g], lex, QQ, gens=gens) for g in I] + G = sdm_groebner(S, sdm_nf_mora, lex, QQ) + return sdm_nf_mora(sdm_from_vector([f], lex, QQ, gens=gens), + G, lex, QQ) == sdm_zero() + + assert contains([x, y], x) + assert contains([x, y], x + y) + assert not contains([x, y], 1) + assert not contains([x, y], z) + assert contains([x**2 + y, x**2 + x], x - y) + assert not contains([x + y + z, x*y + x*z + y*z, x*y*z], x**2) + assert contains([x + y + z, x*y + x*z + y*z, x*y*z], x**3) + assert contains([x + y + z, x*y + x*z + y*z, x*y*z], x**4) + assert not contains([x + y + z, x*y + x*z + y*z, x*y*z], x*y**2) + assert contains([x + y + z, x*y + x*z + y*z, x*y*z], x**4 + y**3 + 2*z*y*x) + assert contains([x + y + z, x*y + x*z + y*z, x*y*z], x*y*z) + assert contains([x, 1 + x + y, 5 - 7*y], 1) + assert contains( + [x**3 + y**3, y**3 + z**3, z**3 + x**3, x**2*y + x**2*z + y**2*z], + x**3) + assert not contains( + [x**3 + y**3, y**3 + z**3, z**3 + x**3, x**2*y + x**2*z + y**2*z], + x**2 + y**2) + + # compare local order + assert not contains([x*(1 + x + y), y*(1 + z)], x) + assert not contains([x*(1 + x + y), y*(1 + z)], x + y) + + +def test_local(): + igrlex = InverseOrder(grlex) + gens = [x, y, z] + + def contains(I, f): + S = [sdm_from_vector([g], igrlex, QQ, gens=gens) for g in I] + G = sdm_groebner(S, sdm_nf_mora, igrlex, QQ) + return sdm_nf_mora(sdm_from_vector([f], lex, QQ, gens=gens), + G, lex, QQ) == sdm_zero() + assert contains([x, y], x) + assert contains([x, y], x + y) + assert not contains([x, y], 1) + assert not contains([x, y], z) + assert contains([x**2 + y, x**2 + x], x - y) + assert not contains([x + y + z, x*y + x*z + y*z, x*y*z], x**2) + assert contains([x*(1 + x + y), y*(1 + z)], x) + assert contains([x*(1 + x + y), y*(1 + z)], x + y) + + +def test_uncovered_line(): + gens = [x, y] + f1 = sdm_zero() + f2 = sdm_from_vector([x, 0], lex, QQ, gens=gens) + f3 = sdm_from_vector([0, y], lex, QQ, gens=gens) + + assert sdm_spoly(f1, f2, lex, QQ) == sdm_zero() + assert sdm_spoly(f3, f2, lex, QQ) == sdm_zero() + + +def test_chain_criterion(): + gens = [x] + f1 = sdm_from_vector([1, x], grlex, QQ, gens=gens) + f2 = sdm_from_vector([0, x - 2], grlex, QQ, gens=gens) + assert len(sdm_groebner([f1, f2], sdm_nf_mora, grlex, QQ)) == 2 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_euclidtools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_euclidtools.py new file mode 100644 index 0000000000000000000000000000000000000000..3061be73f987163951a5836ff50125d29abc60c7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_euclidtools.py @@ -0,0 +1,712 @@ +"""Tests for Euclidean algorithms, GCDs, LCMs and polynomial remainder sequences. """ + +from sympy.polys.rings import ring +from sympy.polys.domains import ZZ, QQ, RR + +from sympy.polys.specialpolys import ( + f_polys, + dmp_fateman_poly_F_1, + dmp_fateman_poly_F_2, + dmp_fateman_poly_F_3) + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = f_polys() + +def test_dup_gcdex(): + R, x = ring("x", QQ) + + f = x**4 - 2*x**3 - 6*x**2 + 12*x + 15 + g = x**3 + x**2 - 4*x - 4 + + s = -QQ(1,5)*x + QQ(3,5) + t = QQ(1,5)*x**2 - QQ(6,5)*x + 2 + h = x + 1 + + assert R.dup_half_gcdex(f, g) == (s, h) + assert R.dup_gcdex(f, g) == (s, t, h) + + f = x**4 + 4*x**3 - x + 1 + g = x**3 - x + 1 + + s, t, h = R.dup_gcdex(f, g) + S, T, H = R.dup_gcdex(g, f) + + assert R.dup_add(R.dup_mul(s, f), + R.dup_mul(t, g)) == h + assert R.dup_add(R.dup_mul(S, g), + R.dup_mul(T, f)) == H + + f = 2*x + g = x**2 - 16 + + s = QQ(1,32)*x + t = -QQ(1,16) + h = 1 + + assert R.dup_half_gcdex(f, g) == (s, h) + assert R.dup_gcdex(f, g) == (s, t, h) + + +def test_dup_invert(): + R, x = ring("x", QQ) + assert R.dup_invert(2*x, x**2 - 16) == QQ(1,32)*x + + +def test_dup_euclidean_prs(): + R, x = ring("x", QQ) + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + assert R.dup_euclidean_prs(f, g) == [ + f, + g, + -QQ(5,9)*x**4 + QQ(1,9)*x**2 - QQ(1,3), + -QQ(117,25)*x**2 - 9*x + QQ(441,25), + QQ(233150,19773)*x - QQ(102500,6591), + -QQ(1288744821,543589225)] + + +def test_dup_primitive_prs(): + R, x = ring("x", ZZ) + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + assert R.dup_primitive_prs(f, g) == [ + f, + g, + -5*x**4 + x**2 - 3, + 13*x**2 + 25*x - 49, + 4663*x - 6150, + 1] + + +def test_dup_subresultants(): + R, x = ring("x", ZZ) + + assert R.dup_resultant(0, 0) == 0 + + assert R.dup_resultant(1, 0) == 0 + assert R.dup_resultant(0, 1) == 0 + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + a = 15*x**4 - 3*x**2 + 9 + b = 65*x**2 + 125*x - 245 + c = 9326*x - 12300 + d = 260708 + + assert R.dup_subresultants(f, g) == [f, g, a, b, c, d] + assert R.dup_resultant(f, g) == R.dup_LC(d) + + f = x**2 - 2*x + 1 + g = x**2 - 1 + + a = 2*x - 2 + + assert R.dup_subresultants(f, g) == [f, g, a] + assert R.dup_resultant(f, g) == 0 + + f = x**2 + 1 + g = x**2 - 1 + + a = -2 + + assert R.dup_subresultants(f, g) == [f, g, a] + assert R.dup_resultant(f, g) == 4 + + f = x**2 - 1 + g = x**3 - x**2 + 2 + + assert R.dup_resultant(f, g) == 0 + + f = 3*x**3 - x + g = 5*x**2 + 1 + + assert R.dup_resultant(f, g) == 64 + + f = x**2 - 2*x + 7 + g = x**3 - x + 5 + + assert R.dup_resultant(f, g) == 265 + + f = x**3 - 6*x**2 + 11*x - 6 + g = x**3 - 15*x**2 + 74*x - 120 + + assert R.dup_resultant(f, g) == -8640 + + f = x**3 - 6*x**2 + 11*x - 6 + g = x**3 - 10*x**2 + 29*x - 20 + + assert R.dup_resultant(f, g) == 0 + + f = x**3 - 1 + g = x**3 + 2*x**2 + 2*x - 1 + + assert R.dup_resultant(f, g) == 16 + + f = x**8 - 2 + g = x - 1 + + assert R.dup_resultant(f, g) == -1 + + +def test_dmp_subresultants(): + R, x, y = ring("x,y", ZZ) + + assert R.dmp_resultant(0, 0) == 0 + assert R.dmp_prs_resultant(0, 0)[0] == 0 + assert R.dmp_zz_collins_resultant(0, 0) == 0 + assert R.dmp_qq_collins_resultant(0, 0) == 0 + + assert R.dmp_resultant(1, 0) == 0 + assert R.dmp_resultant(1, 0) == 0 + assert R.dmp_resultant(1, 0) == 0 + + assert R.dmp_resultant(0, 1) == 0 + assert R.dmp_prs_resultant(0, 1)[0] == 0 + assert R.dmp_zz_collins_resultant(0, 1) == 0 + assert R.dmp_qq_collins_resultant(0, 1) == 0 + + f = 3*x**2*y - y**3 - 4 + g = x**2 + x*y**3 - 9 + + a = 3*x*y**4 + y**3 - 27*y + 4 + b = -3*y**10 - 12*y**7 + y**6 - 54*y**4 + 8*y**3 + 729*y**2 - 216*y + 16 + + r = R.dmp_LC(b) + + assert R.dmp_subresultants(f, g) == [f, g, a, b] + + assert R.dmp_resultant(f, g) == r + assert R.dmp_prs_resultant(f, g)[0] == r + assert R.dmp_zz_collins_resultant(f, g) == r + assert R.dmp_qq_collins_resultant(f, g) == r + + f = -x**3 + 5 + g = 3*x**2*y + x**2 + + a = 45*y**2 + 30*y + 5 + b = 675*y**3 + 675*y**2 + 225*y + 25 + + r = R.dmp_LC(b) + + assert R.dmp_subresultants(f, g) == [f, g, a] + assert R.dmp_resultant(f, g) == r + assert R.dmp_prs_resultant(f, g)[0] == r + assert R.dmp_zz_collins_resultant(f, g) == r + assert R.dmp_qq_collins_resultant(f, g) == r + + R, x, y, z, u, v = ring("x,y,z,u,v", ZZ) + + f = 6*x**2 - 3*x*y - 2*x*z + y*z + g = x**2 - x*u - x*v + u*v + + r = y**2*z**2 - 3*y**2*z*u - 3*y**2*z*v + 9*y**2*u*v - 2*y*z**2*u \ + - 2*y*z**2*v + 6*y*z*u**2 + 12*y*z*u*v + 6*y*z*v**2 - 18*y*u**2*v \ + - 18*y*u*v**2 + 4*z**2*u*v - 12*z*u**2*v - 12*z*u*v**2 + 36*u**2*v**2 + + assert R.dmp_zz_collins_resultant(f, g) == r.drop(x) + + R, x, y, z, u, v = ring("x,y,z,u,v", QQ) + + f = x**2 - QQ(1,2)*x*y - QQ(1,3)*x*z + QQ(1,6)*y*z + g = x**2 - x*u - x*v + u*v + + r = QQ(1,36)*y**2*z**2 - QQ(1,12)*y**2*z*u - QQ(1,12)*y**2*z*v + QQ(1,4)*y**2*u*v \ + - QQ(1,18)*y*z**2*u - QQ(1,18)*y*z**2*v + QQ(1,6)*y*z*u**2 + QQ(1,3)*y*z*u*v \ + + QQ(1,6)*y*z*v**2 - QQ(1,2)*y*u**2*v - QQ(1,2)*y*u*v**2 + QQ(1,9)*z**2*u*v \ + - QQ(1,3)*z*u**2*v - QQ(1,3)*z*u*v**2 + u**2*v**2 + + assert R.dmp_qq_collins_resultant(f, g) == r.drop(x) + + Rt, t = ring("t", ZZ) + Rx, x = ring("x", Rt) + + f = x**6 - 5*x**4 + 5*x**2 + 4 + g = -6*t*x**5 + x**4 + 20*t*x**3 - 3*x**2 - 10*t*x + 6 + + assert Rx.dup_resultant(f, g) == 2930944*t**6 + 2198208*t**4 + 549552*t**2 + 45796 + + +def test_dup_discriminant(): + R, x = ring("x", ZZ) + + assert R.dup_discriminant(0) == 0 + assert R.dup_discriminant(x) == 1 + + assert R.dup_discriminant(x**3 + 3*x**2 + 9*x - 13) == -11664 + assert R.dup_discriminant(5*x**5 + x**3 + 2) == 31252160 + assert R.dup_discriminant(x**4 + 2*x**3 + 6*x**2 - 22*x + 13) == 0 + assert R.dup_discriminant(12*x**7 + 15*x**4 + 30*x**3 + x**2 + 1) == -220289699947514112 + + +def test_dmp_discriminant(): + R, x = ring("x", ZZ) + + assert R.dmp_discriminant(0) == 0 + + R, x, y = ring("x,y", ZZ) + + assert R.dmp_discriminant(0) == 0 + assert R.dmp_discriminant(y) == 0 + + assert R.dmp_discriminant(x**3 + 3*x**2 + 9*x - 13) == -11664 + assert R.dmp_discriminant(5*x**5 + x**3 + 2) == 31252160 + assert R.dmp_discriminant(x**4 + 2*x**3 + 6*x**2 - 22*x + 13) == 0 + assert R.dmp_discriminant(12*x**7 + 15*x**4 + 30*x**3 + x**2 + 1) == -220289699947514112 + + assert R.dmp_discriminant(x**2*y + 2*y) == (-8*y**2).drop(x) + assert R.dmp_discriminant(x*y**2 + 2*x) == 1 + + R, x, y, z = ring("x,y,z", ZZ) + assert R.dmp_discriminant(x*y + z) == 1 + + R, x, y, z, u = ring("x,y,z,u", ZZ) + assert R.dmp_discriminant(x**2*y + x*z + u) == (-4*y*u + z**2).drop(x) + + R, x, y, z, u, v = ring("x,y,z,u,v", ZZ) + assert R.dmp_discriminant(x**3*y + x**2*z + x*u + v) == \ + (-27*y**2*v**2 + 18*y*z*u*v - 4*y*u**3 - 4*z**3*v + z**2*u**2).drop(x) + + +def test_dup_gcd(): + R, x = ring("x", ZZ) + + f, g = 0, 0 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (0, 0, 0) + + f, g = 2, 0 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, 1, 0) + + f, g = -2, 0 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, -1, 0) + + f, g = 0, -2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, 0, -1) + + f, g = 0, 2*x + 4 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2*x + 4, 0, 1) + + f, g = 2*x + 4, 0 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2*x + 4, 1, 0) + + f, g = 2, 2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, 1, 1) + + f, g = -2, 2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, -1, 1) + + f, g = 2, -2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, 1, -1) + + f, g = -2, -2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, -1, -1) + + f, g = x**2 + 2*x + 1, 1 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (1, x**2 + 2*x + 1, 1) + + f, g = x**2 + 2*x + 1, 2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (1, x**2 + 2*x + 1, 2) + + f, g = 2*x**2 + 4*x + 2, 2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, x**2 + 2*x + 1, 1) + + f, g = 2, 2*x**2 + 4*x + 2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (2, 1, x**2 + 2*x + 1) + + f, g = 2*x**2 + 4*x + 2, x + 1 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (x + 1, 2*x + 2, 1) + + f, g = x + 1, 2*x**2 + 4*x + 2 + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (x + 1, 1, 2*x + 2) + + f, g = x - 31, x + assert R.dup_zz_heu_gcd(f, g) == R.dup_rr_prs_gcd(f, g) == (1, f, g) + + f = x**4 + 8*x**3 + 21*x**2 + 22*x + 8 + g = x**3 + 6*x**2 + 11*x + 6 + + h = x**2 + 3*x + 2 + + cff = x**2 + 5*x + 4 + cfg = x + 3 + + assert R.dup_zz_heu_gcd(f, g) == (h, cff, cfg) + assert R.dup_rr_prs_gcd(f, g) == (h, cff, cfg) + + f = x**4 - 4 + g = x**4 + 4*x**2 + 4 + + h = x**2 + 2 + + cff = x**2 - 2 + cfg = x**2 + 2 + + assert R.dup_zz_heu_gcd(f, g) == (h, cff, cfg) + assert R.dup_rr_prs_gcd(f, g) == (h, cff, cfg) + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + h = 1 + + cff = f + cfg = g + + assert R.dup_zz_heu_gcd(f, g) == (h, cff, cfg) + assert R.dup_rr_prs_gcd(f, g) == (h, cff, cfg) + + R, x = ring("x", QQ) + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + h = 1 + + cff = f + cfg = g + + assert R.dup_qq_heu_gcd(f, g) == (h, cff, cfg) + assert R.dup_ff_prs_gcd(f, g) == (h, cff, cfg) + + R, x = ring("x", ZZ) + + f = - 352518131239247345597970242177235495263669787845475025293906825864749649589178600387510272*x**49 \ + + 46818041807522713962450042363465092040687472354933295397472942006618953623327997952*x**42 \ + + 378182690892293941192071663536490788434899030680411695933646320291525827756032*x**35 \ + + 112806468807371824947796775491032386836656074179286744191026149539708928*x**28 \ + - 12278371209708240950316872681744825481125965781519138077173235712*x**21 \ + + 289127344604779611146960547954288113529690984687482920704*x**14 \ + + 19007977035740498977629742919480623972236450681*x**7 \ + + 311973482284542371301330321821976049 + + g = 365431878023781158602430064717380211405897160759702125019136*x**21 \ + + 197599133478719444145775798221171663643171734081650688*x**14 \ + - 9504116979659010018253915765478924103928886144*x**7 \ + - 311973482284542371301330321821976049 + + assert R.dup_zz_heu_gcd(f, R.dup_diff(f, 1))[0] == g + assert R.dup_rr_prs_gcd(f, R.dup_diff(f, 1))[0] == g + + R, x = ring("x", QQ) + + f = QQ(1,2)*x**2 + x + QQ(1,2) + g = QQ(1,2)*x + QQ(1,2) + + h = x + 1 + + assert R.dup_qq_heu_gcd(f, g) == (h, g, QQ(1,2)) + assert R.dup_ff_prs_gcd(f, g) == (h, g, QQ(1,2)) + + R, x = ring("x", ZZ) + + f = 1317378933230047068160*x + 2945748836994210856960 + g = 120352542776360960*x + 269116466014453760 + + h = 120352542776360960*x + 269116466014453760 + cff = 10946 + cfg = 1 + + assert R.dup_zz_heu_gcd(f, g) == (h, cff, cfg) + + +def test_dmp_gcd(): + R, x, y = ring("x,y", ZZ) + + f, g = 0, 0 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (0, 0, 0) + + f, g = 2, 0 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, 1, 0) + + f, g = -2, 0 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, -1, 0) + + f, g = 0, -2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, 0, -1) + + f, g = 0, 2*x + 4 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2*x + 4, 0, 1) + + f, g = 2*x + 4, 0 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2*x + 4, 1, 0) + + f, g = 2, 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, 1, 1) + + f, g = -2, 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, -1, 1) + + f, g = 2, -2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, 1, -1) + + f, g = -2, -2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, -1, -1) + + f, g = x**2 + 2*x + 1, 1 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (1, x**2 + 2*x + 1, 1) + + f, g = x**2 + 2*x + 1, 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (1, x**2 + 2*x + 1, 2) + + f, g = 2*x**2 + 4*x + 2, 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, x**2 + 2*x + 1, 1) + + f, g = 2, 2*x**2 + 4*x + 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (2, 1, x**2 + 2*x + 1) + + f, g = 2*x**2 + 4*x + 2, x + 1 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (x + 1, 2*x + 2, 1) + + f, g = x + 1, 2*x**2 + 4*x + 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (x + 1, 1, 2*x + 2) + + R, x, y, z, u = ring("x,y,z,u", ZZ) + + f, g = u**2 + 2*u + 1, 2*u + 2 + assert R.dmp_zz_heu_gcd(f, g) == R.dmp_rr_prs_gcd(f, g) == (u + 1, u + 1, 2) + + f, g = z**2*u**2 + 2*z**2*u + z**2 + z*u + z, u**2 + 2*u + 1 + h, cff, cfg = u + 1, z**2*u + z**2 + z, u + 1 + + assert R.dmp_zz_heu_gcd(f, g) == (h, cff, cfg) + assert R.dmp_rr_prs_gcd(f, g) == (h, cff, cfg) + + assert R.dmp_zz_heu_gcd(g, f) == (h, cfg, cff) + assert R.dmp_rr_prs_gcd(g, f) == (h, cfg, cff) + + R, x, y, z = ring("x,y,z", ZZ) + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_1(2, ZZ)) + H, cff, cfg = R.dmp_zz_heu_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + H, cff, cfg = R.dmp_rr_prs_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + R, x, y, z, u, v = ring("x,y,z,u,v", ZZ) + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_1(4, ZZ)) + H, cff, cfg = R.dmp_zz_heu_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + R, x, y, z, u, v, a, b = ring("x,y,z,u,v,a,b", ZZ) + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_1(6, ZZ)) + H, cff, cfg = R.dmp_zz_heu_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + R, x, y, z, u, v, a, b, c, d = ring("x,y,z,u,v,a,b,c,d", ZZ) + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_1(8, ZZ)) + H, cff, cfg = R.dmp_zz_heu_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + R, x, y, z = ring("x,y,z", ZZ) + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_2(2, ZZ)) + H, cff, cfg = R.dmp_zz_heu_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + H, cff, cfg = R.dmp_rr_prs_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_3(2, ZZ)) + H, cff, cfg = R.dmp_zz_heu_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + H, cff, cfg = R.dmp_rr_prs_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + R, x, y, z, u, v = ring("x,y,z,u,v", ZZ) + + f, g, h = map(R.from_dense, dmp_fateman_poly_F_3(4, ZZ)) + H, cff, cfg = R.dmp_inner_gcd(f, g) + + assert H == h and R.dmp_mul(H, cff) == f \ + and R.dmp_mul(H, cfg) == g + + R, x, y = ring("x,y", QQ) + + f = QQ(1,2)*x**2 + x + QQ(1,2) + g = QQ(1,2)*x + QQ(1,2) + + h = x + 1 + + assert R.dmp_qq_heu_gcd(f, g) == (h, g, QQ(1,2)) + assert R.dmp_ff_prs_gcd(f, g) == (h, g, QQ(1,2)) + + R, x, y = ring("x,y", RR) + + f = 2.1*x*y**2 - 2.2*x*y + 2.1*x + g = 1.0*x**3 + + assert R.dmp_ff_prs_gcd(f, g) == \ + (1.0*x, 2.1*y**2 - 2.2*y + 2.1, 1.0*x**2) + + +def test_dup_lcm(): + R, x = ring("x", ZZ) + + assert R.dup_lcm(2, 6) == 6 + + assert R.dup_lcm(2*x**3, 6*x) == 6*x**3 + assert R.dup_lcm(2*x**3, 3*x) == 6*x**3 + + assert R.dup_lcm(x**2 + x, x) == x**2 + x + assert R.dup_lcm(x**2 + x, 2*x) == 2*x**2 + 2*x + assert R.dup_lcm(x**2 + 2*x, x) == x**2 + 2*x + assert R.dup_lcm(2*x**2 + x, x) == 2*x**2 + x + assert R.dup_lcm(2*x**2 + x, 2*x) == 4*x**2 + 2*x + + +def test_dmp_lcm(): + R, x, y = ring("x,y", ZZ) + + assert R.dmp_lcm(2, 6) == 6 + assert R.dmp_lcm(x, y) == x*y + + assert R.dmp_lcm(2*x**3, 6*x*y**2) == 6*x**3*y**2 + assert R.dmp_lcm(2*x**3, 3*x*y**2) == 6*x**3*y**2 + + assert R.dmp_lcm(x**2*y, x*y**2) == x**2*y**2 + + f = 2*x*y**5 - 3*x*y**4 - 2*x*y**3 + 3*x*y**2 + g = y**5 - 2*y**3 + y + h = 2*x*y**7 - 3*x*y**6 - 4*x*y**5 + 6*x*y**4 + 2*x*y**3 - 3*x*y**2 + + assert R.dmp_lcm(f, g) == h + + f = x**3 - 3*x**2*y - 9*x*y**2 - 5*y**3 + g = x**4 + 6*x**3*y + 12*x**2*y**2 + 10*x*y**3 + 3*y**4 + h = x**5 + x**4*y - 18*x**3*y**2 - 50*x**2*y**3 - 47*x*y**4 - 15*y**5 + + assert R.dmp_lcm(f, g) == h + + +def test_dmp_content(): + R, x,y = ring("x,y", ZZ) + + assert R.dmp_content(-2) == 2 + + f, g, F = 3*y**2 + 2*y + 1, 1, 0 + + for i in range(0, 5): + g *= f + F += x**i*g + + assert R.dmp_content(F) == f.drop(x) + + R, x,y,z = ring("x,y,z", ZZ) + + assert R.dmp_content(f_4) == 1 + assert R.dmp_content(f_5) == 1 + + R, x,y,z,t = ring("x,y,z,t", ZZ) + assert R.dmp_content(f_6) == 1 + + +def test_dmp_primitive(): + R, x,y = ring("x,y", ZZ) + + assert R.dmp_primitive(0) == (0, 0) + assert R.dmp_primitive(1) == (1, 1) + + f, g, F = 3*y**2 + 2*y + 1, 1, 0 + + for i in range(0, 5): + g *= f + F += x**i*g + + assert R.dmp_primitive(F) == (f.drop(x), F / f) + + R, x,y,z = ring("x,y,z", ZZ) + + cont, f = R.dmp_primitive(f_4) + assert cont == 1 and f == f_4 + cont, f = R.dmp_primitive(f_5) + assert cont == 1 and f == f_5 + + R, x,y,z,t = ring("x,y,z,t", ZZ) + + cont, f = R.dmp_primitive(f_6) + assert cont == 1 and f == f_6 + + +def test_dup_cancel(): + R, x = ring("x", ZZ) + + f = 2*x**2 - 2 + g = x**2 - 2*x + 1 + + p = 2*x + 2 + q = x - 1 + + assert R.dup_cancel(f, g) == (p, q) + assert R.dup_cancel(f, g, include=False) == (1, 1, p, q) + + f = -x - 2 + g = 3*x - 4 + + F = x + 2 + G = -3*x + 4 + + assert R.dup_cancel(f, g) == (f, g) + assert R.dup_cancel(F, G) == (f, g) + + assert R.dup_cancel(0, 0) == (0, 0) + assert R.dup_cancel(0, 0, include=False) == (1, 1, 0, 0) + + assert R.dup_cancel(x, 0) == (1, 0) + assert R.dup_cancel(x, 0, include=False) == (1, 1, 1, 0) + + assert R.dup_cancel(0, x) == (0, 1) + assert R.dup_cancel(0, x, include=False) == (1, 1, 0, 1) + + f = 0 + g = x + one = 1 + + assert R.dup_cancel(f, g, include=True) == (f, one) + + +def test_dmp_cancel(): + R, x, y = ring("x,y", ZZ) + + f = 2*x**2 - 2 + g = x**2 - 2*x + 1 + + p = 2*x + 2 + q = x - 1 + + assert R.dmp_cancel(f, g) == (p, q) + assert R.dmp_cancel(f, g, include=False) == (1, 1, p, q) + + assert R.dmp_cancel(0, 0) == (0, 0) + assert R.dmp_cancel(0, 0, include=False) == (1, 1, 0, 0) + + assert R.dmp_cancel(y, 0) == (1, 0) + assert R.dmp_cancel(y, 0, include=False) == (1, 1, 1, 0) + + assert R.dmp_cancel(0, y) == (0, 1) + assert R.dmp_cancel(0, y, include=False) == (1, 1, 0, 1) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_factortools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_factortools.py new file mode 100644 index 0000000000000000000000000000000000000000..7f99097c71e9cde761a800b01b149ec5c9896266 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_factortools.py @@ -0,0 +1,784 @@ +"""Tools for polynomial factorization routines in characteristic zero. """ + +from sympy.polys.rings import ring, xring +from sympy.polys.domains import FF, ZZ, QQ, ZZ_I, QQ_I, RR, EX + +from sympy.polys import polyconfig as config +from sympy.polys.polyerrors import DomainError +from sympy.polys.polyclasses import ANP +from sympy.polys.specialpolys import f_polys, w_polys + +from sympy.core.numbers import I +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import sin +from sympy.ntheory.generate import nextprime +from sympy.testing.pytest import raises, XFAIL + + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = f_polys() +w_1, w_2 = w_polys() + +def test_dup_trial_division(): + R, x = ring("x", ZZ) + assert R.dup_trial_division(x**5 + 8*x**4 + 25*x**3 + 38*x**2 + 28*x + 8, (x + 1, x + 2)) == [(x + 1, 2), (x + 2, 3)] + + +def test_dmp_trial_division(): + R, x, y = ring("x,y", ZZ) + assert R.dmp_trial_division(x**5 + 8*x**4 + 25*x**3 + 38*x**2 + 28*x + 8, (x + 1, x + 2)) == [(x + 1, 2), (x + 2, 3)] + + +def test_dup_zz_mignotte_bound(): + R, x = ring("x", ZZ) + assert R.dup_zz_mignotte_bound(2*x**2 + 3*x + 4) == 6 + assert R.dup_zz_mignotte_bound(x**3 + 14*x**2 + 56*x + 64) == 152 + + +def test_dmp_zz_mignotte_bound(): + R, x, y = ring("x,y", ZZ) + assert R.dmp_zz_mignotte_bound(2*x**2 + 3*x + 4) == 32 + + +def test_dup_zz_hensel_step(): + R, x = ring("x", ZZ) + + f = x**4 - 1 + g = x**3 + 2*x**2 - x - 2 + h = x - 2 + s = -2 + t = 2*x**2 - 2*x - 1 + + G, H, S, T = R.dup_zz_hensel_step(5, f, g, h, s, t) + + assert G == x**3 + 7*x**2 - x - 7 + assert H == x - 7 + assert S == 8 + assert T == -8*x**2 - 12*x - 1 + + +def test_dup_zz_hensel_lift(): + R, x = ring("x", ZZ) + + f = x**4 - 1 + F = [x - 1, x - 2, x + 2, x + 1] + + assert R.dup_zz_hensel_lift(ZZ(5), f, F, 4) == \ + [x - 1, x - 182, x + 182, x + 1] + + +def test_dup_zz_irreducible_p(): + R, x = ring("x", ZZ) + + assert R.dup_zz_irreducible_p(3*x**4 + 2*x**3 + 6*x**2 + 8*x + 7) is None + assert R.dup_zz_irreducible_p(3*x**4 + 2*x**3 + 6*x**2 + 8*x + 4) is None + + assert R.dup_zz_irreducible_p(3*x**4 + 2*x**3 + 6*x**2 + 8*x + 10) is True + assert R.dup_zz_irreducible_p(3*x**4 + 2*x**3 + 6*x**2 + 8*x + 14) is True + + +def test_dup_cyclotomic_p(): + R, x = ring("x", ZZ) + + assert R.dup_cyclotomic_p(x - 1) is True + assert R.dup_cyclotomic_p(x + 1) is True + assert R.dup_cyclotomic_p(x**2 + x + 1) is True + assert R.dup_cyclotomic_p(x**2 + 1) is True + assert R.dup_cyclotomic_p(x**4 + x**3 + x**2 + x + 1) is True + assert R.dup_cyclotomic_p(x**2 - x + 1) is True + assert R.dup_cyclotomic_p(x**6 + x**5 + x**4 + x**3 + x**2 + x + 1) is True + assert R.dup_cyclotomic_p(x**4 + 1) is True + assert R.dup_cyclotomic_p(x**6 + x**3 + 1) is True + + assert R.dup_cyclotomic_p(0) is False + assert R.dup_cyclotomic_p(1) is False + assert R.dup_cyclotomic_p(x) is False + assert R.dup_cyclotomic_p(x + 2) is False + assert R.dup_cyclotomic_p(3*x + 1) is False + assert R.dup_cyclotomic_p(x**2 - 1) is False + + f = x**16 + x**14 - x**10 + x**8 - x**6 + x**2 + 1 + assert R.dup_cyclotomic_p(f) is False + + g = x**16 + x**14 - x**10 - x**8 - x**6 + x**2 + 1 + assert R.dup_cyclotomic_p(g) is True + + R, x = ring("x", QQ) + assert R.dup_cyclotomic_p(x**2 + x + 1) is True + assert R.dup_cyclotomic_p(QQ(1,2)*x**2 + x + 1) is False + + R, x = ring("x", ZZ["y"]) + assert R.dup_cyclotomic_p(x**2 + x + 1) is False + + +def test_dup_zz_cyclotomic_poly(): + R, x = ring("x", ZZ) + + assert R.dup_zz_cyclotomic_poly(1) == x - 1 + assert R.dup_zz_cyclotomic_poly(2) == x + 1 + assert R.dup_zz_cyclotomic_poly(3) == x**2 + x + 1 + assert R.dup_zz_cyclotomic_poly(4) == x**2 + 1 + assert R.dup_zz_cyclotomic_poly(5) == x**4 + x**3 + x**2 + x + 1 + assert R.dup_zz_cyclotomic_poly(6) == x**2 - x + 1 + assert R.dup_zz_cyclotomic_poly(7) == x**6 + x**5 + x**4 + x**3 + x**2 + x + 1 + assert R.dup_zz_cyclotomic_poly(8) == x**4 + 1 + assert R.dup_zz_cyclotomic_poly(9) == x**6 + x**3 + 1 + + +def test_dup_zz_cyclotomic_factor(): + R, x = ring("x", ZZ) + + assert R.dup_zz_cyclotomic_factor(0) is None + assert R.dup_zz_cyclotomic_factor(1) is None + + assert R.dup_zz_cyclotomic_factor(2*x**10 - 1) is None + assert R.dup_zz_cyclotomic_factor(x**10 - 3) is None + assert R.dup_zz_cyclotomic_factor(x**10 + x**5 - 1) is None + + assert R.dup_zz_cyclotomic_factor(x + 1) == [x + 1] + assert R.dup_zz_cyclotomic_factor(x - 1) == [x - 1] + + assert R.dup_zz_cyclotomic_factor(x**2 + 1) == [x**2 + 1] + assert R.dup_zz_cyclotomic_factor(x**2 - 1) == [x - 1, x + 1] + + assert R.dup_zz_cyclotomic_factor(x**27 + 1) == \ + [x + 1, x**2 - x + 1, x**6 - x**3 + 1, x**18 - x**9 + 1] + assert R.dup_zz_cyclotomic_factor(x**27 - 1) == \ + [x - 1, x**2 + x + 1, x**6 + x**3 + 1, x**18 + x**9 + 1] + + +def test_dup_zz_factor(): + R, x = ring("x", ZZ) + + assert R.dup_zz_factor(0) == (0, []) + assert R.dup_zz_factor(7) == (7, []) + assert R.dup_zz_factor(-7) == (-7, []) + + assert R.dup_zz_factor_sqf(0) == (0, []) + assert R.dup_zz_factor_sqf(7) == (7, []) + assert R.dup_zz_factor_sqf(-7) == (-7, []) + + assert R.dup_zz_factor(2*x + 4) == (2, [(x + 2, 1)]) + assert R.dup_zz_factor_sqf(2*x + 4) == (2, [x + 2]) + + f = x**4 + x + 1 + + for i in range(0, 20): + assert R.dup_zz_factor(f) == (1, [(f, 1)]) + + assert R.dup_zz_factor(x**2 + 2*x + 2) == \ + (1, [(x**2 + 2*x + 2, 1)]) + + assert R.dup_zz_factor(18*x**2 + 12*x + 2) == \ + (2, [(3*x + 1, 2)]) + + assert R.dup_zz_factor(-9*x**2 + 1) == \ + (-1, [(3*x - 1, 1), + (3*x + 1, 1)]) + + assert R.dup_zz_factor_sqf(-9*x**2 + 1) == \ + (-1, [3*x - 1, + 3*x + 1]) + + # The order of the factors will be different when the ground types are + # flint. At the higher level dup_factor_list will sort the factors. + c, factors = R.dup_zz_factor(x**3 - 6*x**2 + 11*x - 6) + assert c == 1 + assert set(factors) == {(x - 3, 1), (x - 2, 1), (x - 1, 1)} + + assert R.dup_zz_factor_sqf(x**3 - 6*x**2 + 11*x - 6) == \ + (1, [x - 3, + x - 2, + x - 1]) + + assert R.dup_zz_factor(3*x**3 + 10*x**2 + 13*x + 10) == \ + (1, [(x + 2, 1), + (3*x**2 + 4*x + 5, 1)]) + + assert R.dup_zz_factor_sqf(3*x**3 + 10*x**2 + 13*x + 10) == \ + (1, [x + 2, + 3*x**2 + 4*x + 5]) + + c, factors = R.dup_zz_factor(-x**6 + x**2) + assert c == -1 + assert set(factors) == {(x, 2), (x - 1, 1), (x + 1, 1), (x**2 + 1, 1)} + + f = 1080*x**8 + 5184*x**7 + 2099*x**6 + 744*x**5 + 2736*x**4 - 648*x**3 + 129*x**2 - 324 + + assert R.dup_zz_factor(f) == \ + (1, [(5*x**4 + 24*x**3 + 9*x**2 + 12, 1), + (216*x**4 + 31*x**2 - 27, 1)]) + + f = -29802322387695312500000000000000000000*x**25 \ + + 2980232238769531250000000000000000*x**20 \ + + 1743435859680175781250000000000*x**15 \ + + 114142894744873046875000000*x**10 \ + - 210106372833251953125*x**5 \ + + 95367431640625 + + c, factors = R.dup_zz_factor(f) + assert c == -95367431640625 + assert set(factors) == { + (5*x - 1, 1), + (100*x**2 + 10*x - 1, 2), + (625*x**4 + 125*x**3 + 25*x**2 + 5*x + 1, 1), + (10000*x**4 - 3000*x**3 + 400*x**2 - 20*x + 1, 2), + (10000*x**4 + 2000*x**3 + 400*x**2 + 30*x + 1, 2), + } + + f = x**10 - 1 + + config.setup('USE_CYCLOTOMIC_FACTOR', True) + c0, F_0 = R.dup_zz_factor(f) + + config.setup('USE_CYCLOTOMIC_FACTOR', False) + c1, F_1 = R.dup_zz_factor(f) + + assert c0 == c1 == 1 + assert set(F_0) == set(F_1) == { + (x - 1, 1), + (x + 1, 1), + (x**4 - x**3 + x**2 - x + 1, 1), + (x**4 + x**3 + x**2 + x + 1, 1), + } + + config.setup('USE_CYCLOTOMIC_FACTOR') + + f = x**10 + 1 + + config.setup('USE_CYCLOTOMIC_FACTOR', True) + F_0 = R.dup_zz_factor(f) + + config.setup('USE_CYCLOTOMIC_FACTOR', False) + F_1 = R.dup_zz_factor(f) + + assert F_0 == F_1 == \ + (1, [(x**2 + 1, 1), + (x**8 - x**6 + x**4 - x**2 + 1, 1)]) + + config.setup('USE_CYCLOTOMIC_FACTOR') + +def test_dmp_zz_wang(): + R, x,y,z = ring("x,y,z", ZZ) + UV, _x = ring("x", ZZ) + + p = ZZ(nextprime(R.dmp_zz_mignotte_bound(w_1))) + assert p == 6291469 + + t_1, k_1, e_1 = y, 1, ZZ(-14) + t_2, k_2, e_2 = z, 2, ZZ(3) + t_3, k_3, e_3 = y + z, 2, ZZ(-11) + t_4, k_4, e_4 = y - z, 1, ZZ(-17) + + T = [t_1, t_2, t_3, t_4] + K = [k_1, k_2, k_3, k_4] + E = [e_1, e_2, e_3, e_4] + + T = zip([ t.drop(x) for t in T ], K) + + A = [ZZ(-14), ZZ(3)] + + S = R.dmp_eval_tail(w_1, A) + cs, s = UV.dup_primitive(S) + + assert cs == 1 and s == S == \ + 1036728*_x**6 + 915552*_x**5 + 55748*_x**4 + 105621*_x**3 - 17304*_x**2 - 26841*_x - 644 + + assert R.dmp_zz_wang_non_divisors(E, cs, ZZ(4)) == [7, 3, 11, 17] + assert UV.dup_sqf_p(s) and UV.dup_degree(s) == R.dmp_degree(w_1) + + _, H = UV.dup_zz_factor_sqf(s) + + h_1 = 44*_x**2 + 42*_x + 1 + h_2 = 126*_x**2 - 9*_x + 28 + h_3 = 187*_x**2 - 23 + + assert H == [h_1, h_2, h_3] + + LC = [ lc.drop(x) for lc in [-4*y - 4*z, -y*z**2, y**2 - z**2] ] + + assert R.dmp_zz_wang_lead_coeffs(w_1, T, cs, E, H, A) == (w_1, H, LC) + + factors = R.dmp_zz_wang_hensel_lifting(w_1, H, LC, A, p) + assert R.dmp_expand(factors) == w_1 + + +@XFAIL +def test_dmp_zz_wang_fail(): + R, x,y,z = ring("x,y,z", ZZ) + UV, _x = ring("x", ZZ) + + p = ZZ(nextprime(R.dmp_zz_mignotte_bound(w_1))) + assert p == 6291469 + + H_1 = [44*x**2 + 42*x + 1, 126*x**2 - 9*x + 28, 187*x**2 - 23] + H_2 = [-4*x**2*y - 12*x**2 - 3*x*y + 1, -9*x**2*y - 9*x - 2*y, x**2*y**2 - 9*x**2 + y - 9] + H_3 = [-4*x**2*y - 12*x**2 - 3*x*y + 1, -9*x**2*y - 9*x - 2*y, x**2*y**2 - 9*x**2 + y - 9] + + c_1 = -70686*x**5 - 5863*x**4 - 17826*x**3 + 2009*x**2 + 5031*x + 74 + c_2 = 9*x**5*y**4 + 12*x**5*y**3 - 45*x**5*y**2 - 108*x**5*y - 324*x**5 + 18*x**4*y**3 - 216*x**4*y**2 - 810*x**4*y + 2*x**3*y**4 + 9*x**3*y**3 - 252*x**3*y**2 - 288*x**3*y - 945*x**3 - 30*x**2*y**2 - 414*x**2*y + 2*x*y**3 - 54*x*y**2 - 3*x*y + 81*x + 12*y + c_3 = -36*x**4*y**2 - 108*x**4*y - 27*x**3*y**2 - 36*x**3*y - 108*x**3 - 8*x**2*y**2 - 42*x**2*y - 6*x*y**2 + 9*x + 2*y + + assert R.dmp_zz_diophantine(H_1, c_1, [], 5, p) == [-3*x, -2, 1] + assert R.dmp_zz_diophantine(H_2, c_2, [ZZ(-14)], 5, p) == [-x*y, -3*x, -6] + assert R.dmp_zz_diophantine(H_3, c_3, [ZZ(-14)], 5, p) == [0, 0, -1] + + +def test_issue_6355(): + # This tests a bug in the Wang algorithm that occurred only with a very + # specific set of random numbers. + random_sequence = [-1, -1, 0, 0, 0, 0, -1, -1, 0, -1, 3, -1, 3, 3, 3, 3, -1, 3] + + R, x, y, z = ring("x,y,z", ZZ) + f = 2*x**2 + y*z - y - z**2 + z + + assert R.dmp_zz_wang(f, seed=random_sequence) == [f] + + +def test_dmp_zz_factor(): + R, x = ring("x", ZZ) + assert R.dmp_zz_factor(0) == (0, []) + assert R.dmp_zz_factor(7) == (7, []) + assert R.dmp_zz_factor(-7) == (-7, []) + + assert R.dmp_zz_factor(x**2 - 9) == (1, [(x - 3, 1), (x + 3, 1)]) + + R, x, y = ring("x,y", ZZ) + assert R.dmp_zz_factor(0) == (0, []) + assert R.dmp_zz_factor(7) == (7, []) + assert R.dmp_zz_factor(-7) == (-7, []) + + assert R.dmp_zz_factor(x) == (1, [(x, 1)]) + assert R.dmp_zz_factor(4*x) == (4, [(x, 1)]) + assert R.dmp_zz_factor(4*x + 2) == (2, [(2*x + 1, 1)]) + assert R.dmp_zz_factor(x*y + 1) == (1, [(x*y + 1, 1)]) + assert R.dmp_zz_factor(y**2 + 1) == (1, [(y**2 + 1, 1)]) + assert R.dmp_zz_factor(y**2 - 1) == (1, [(y - 1, 1), (y + 1, 1)]) + + assert R.dmp_zz_factor(x**2*y**2 + 6*x**2*y + 9*x**2 - 1) == (1, [(x*y + 3*x - 1, 1), (x*y + 3*x + 1, 1)]) + assert R.dmp_zz_factor(x**2*y**2 - 9) == (1, [(x*y - 3, 1), (x*y + 3, 1)]) + + R, x, y, z = ring("x,y,z", ZZ) + assert R.dmp_zz_factor(x**2*y**2*z**2 - 9) == \ + (1, [(x*y*z - 3, 1), + (x*y*z + 3, 1)]) + + R, x, y, z, u = ring("x,y,z,u", ZZ) + assert R.dmp_zz_factor(x**2*y**2*z**2*u**2 - 9) == \ + (1, [(x*y*z*u - 3, 1), + (x*y*z*u + 3, 1)]) + + R, x, y, z = ring("x,y,z", ZZ) + assert R.dmp_zz_factor(f_1) == \ + (1, [(x + y*z + 20, 1), + (x*y + z + 10, 1), + (x*z + y + 30, 1)]) + + assert R.dmp_zz_factor(f_2) == \ + (1, [(x**2*y**2 + x**2*z**2 + y + 90, 1), + (x**3*y + x**3*z + z - 11, 1)]) + + assert R.dmp_zz_factor(f_3) == \ + (1, [(x**2*y**2 + x*z**4 + x + z, 1), + (x**3 + x*y*z + y**2 + y*z**3, 1)]) + + assert R.dmp_zz_factor(f_4) == \ + (-1, [(x*y**3 + z**2, 1), + (x**2*z + y**4*z**2 + 5, 1), + (x**3*y - z**2 - 3, 1), + (x**3*y**4 + z**2, 1)]) + + assert R.dmp_zz_factor(f_5) == \ + (-1, [(x + y - z, 3)]) + + R, x, y, z, t = ring("x,y,z,t", ZZ) + assert R.dmp_zz_factor(f_6) == \ + (1, [(47*x*y + z**3*t**2 - t**2, 1), + (45*x**3 - 9*y**3 - y**2 + 3*z**3 + 2*z*t, 1)]) + + R, x, y, z = ring("x,y,z", ZZ) + assert R.dmp_zz_factor(w_1) == \ + (1, [(x**2*y**2 - x**2*z**2 + y - z**2, 1), + (x**2*y*z**2 + 3*x*z + 2*y, 1), + (4*x**2*y + 4*x**2*z + x*y*z - 1, 1)]) + + R, x, y = ring("x,y", ZZ) + f = -12*x**16*y + 240*x**12*y**3 - 768*x**10*y**4 + 1080*x**8*y**5 - 768*x**6*y**6 + 240*x**4*y**7 - 12*y**9 + + assert R.dmp_zz_factor(f) == \ + (-12, [(y, 1), + (x**2 - y, 6), + (x**4 + 6*x**2*y + y**2, 1)]) + + +def test_dup_qq_i_factor(): + R, x = ring("x", QQ_I) + i = QQ_I(0, 1) + + assert R.dup_qq_i_factor(x**2 - 2) == (QQ_I(1, 0), [(x**2 - 2, 1)]) + + assert R.dup_qq_i_factor(x**2 - 1) == (QQ_I(1, 0), [(x - 1, 1), (x + 1, 1)]) + + assert R.dup_qq_i_factor(x**2 + 1) == (QQ_I(1, 0), [(x - i, 1), (x + i, 1)]) + + assert R.dup_qq_i_factor(x**2/4 + 1) == \ + (QQ_I(QQ(1, 4), 0), [(x - 2*i, 1), (x + 2*i, 1)]) + + assert R.dup_qq_i_factor(x**2 + 4) == \ + (QQ_I(1, 0), [(x - 2*i, 1), (x + 2*i, 1)]) + + assert R.dup_qq_i_factor(x**2 + 2*x + 1) == \ + (QQ_I(1, 0), [(x + 1, 2)]) + + assert R.dup_qq_i_factor(x**2 + 2*i*x - 1) == \ + (QQ_I(1, 0), [(x + i, 2)]) + + f = 8192*x**2 + x*(22656 + 175232*i) - 921416 + 242313*i + + assert R.dup_qq_i_factor(f) == \ + (QQ_I(8192, 0), [(x + QQ_I(QQ(177, 128), QQ(1369, 128)), 2)]) + + +def test_dmp_qq_i_factor(): + R, x, y = ring("x, y", QQ_I) + i = QQ_I(0, 1) + + assert R.dmp_qq_i_factor(x**2 + 2*y**2) == \ + (QQ_I(1, 0), [(x**2 + 2*y**2, 1)]) + + assert R.dmp_qq_i_factor(x**2 + y**2) == \ + (QQ_I(1, 0), [(x - i*y, 1), (x + i*y, 1)]) + + assert R.dmp_qq_i_factor(x**2 + y**2/4) == \ + (QQ_I(1, 0), [(x - i*y/2, 1), (x + i*y/2, 1)]) + + assert R.dmp_qq_i_factor(4*x**2 + y**2) == \ + (QQ_I(4, 0), [(x - i*y/2, 1), (x + i*y/2, 1)]) + + +def test_dup_zz_i_factor(): + R, x = ring("x", ZZ_I) + i = ZZ_I(0, 1) + + assert R.dup_zz_i_factor(x**2 - 2) == (ZZ_I(1, 0), [(x**2 - 2, 1)]) + + assert R.dup_zz_i_factor(x**2 - 1) == (ZZ_I(1, 0), [(x - 1, 1), (x + 1, 1)]) + + assert R.dup_zz_i_factor(x**2 + 1) == (ZZ_I(1, 0), [(x - i, 1), (x + i, 1)]) + + assert R.dup_zz_i_factor(x**2 + 4) == \ + (ZZ_I(1, 0), [(x - 2*i, 1), (x + 2*i, 1)]) + + assert R.dup_zz_i_factor(x**2 + 2*x + 1) == \ + (ZZ_I(1, 0), [(x + 1, 2)]) + + assert R.dup_zz_i_factor(x**2 + 2*i*x - 1) == \ + (ZZ_I(1, 0), [(x + i, 2)]) + + f = 8192*x**2 + x*(22656 + 175232*i) - 921416 + 242313*i + + assert R.dup_zz_i_factor(f) == \ + (ZZ_I(0, 1), [((64 - 64*i)*x + (773 + 596*i), 2)]) + + +def test_dmp_zz_i_factor(): + R, x, y = ring("x, y", ZZ_I) + i = ZZ_I(0, 1) + + assert R.dmp_zz_i_factor(x**2 + 2*y**2) == \ + (ZZ_I(1, 0), [(x**2 + 2*y**2, 1)]) + + assert R.dmp_zz_i_factor(x**2 + y**2) == \ + (ZZ_I(1, 0), [(x - i*y, 1), (x + i*y, 1)]) + + assert R.dmp_zz_i_factor(4*x**2 + y**2) == \ + (ZZ_I(1, 0), [(2*x - i*y, 1), (2*x + i*y, 1)]) + + +def test_dup_ext_factor(): + R, x = ring("x", QQ.algebraic_field(I)) + def anp(element): + return ANP(element, [QQ(1), QQ(0), QQ(1)], QQ) + + assert R.dup_ext_factor(0) == (anp([]), []) + + f = anp([QQ(1)])*x + anp([QQ(1)]) + + assert R.dup_ext_factor(f) == (anp([QQ(1)]), [(f, 1)]) + + g = anp([QQ(2)])*x + anp([QQ(2)]) + + assert R.dup_ext_factor(g) == (anp([QQ(2)]), [(f, 1)]) + + f = anp([QQ(7)])*x**4 + anp([QQ(1, 1)]) + g = anp([QQ(1)])*x**4 + anp([QQ(1, 7)]) + + assert R.dup_ext_factor(f) == (anp([QQ(7)]), [(g, 1)]) + + f = anp([QQ(1)])*x**4 + anp([QQ(1)]) + + assert R.dup_ext_factor(f) == \ + (anp([QQ(1, 1)]), [(anp([QQ(1)])*x**2 + anp([QQ(-1), QQ(0)]), 1), + (anp([QQ(1)])*x**2 + anp([QQ( 1), QQ(0)]), 1)]) + + f = anp([QQ(4, 1)])*x**2 + anp([QQ(9, 1)]) + + assert R.dup_ext_factor(f) == \ + (anp([QQ(4, 1)]), [(anp([QQ(1, 1)])*x + anp([-QQ(3, 2), QQ(0, 1)]), 1), + (anp([QQ(1, 1)])*x + anp([ QQ(3, 2), QQ(0, 1)]), 1)]) + + f = anp([QQ(4, 1)])*x**4 + anp([QQ(8, 1)])*x**3 + anp([QQ(77, 1)])*x**2 + anp([QQ(18, 1)])*x + anp([QQ(153, 1)]) + + assert R.dup_ext_factor(f) == \ + (anp([QQ(4, 1)]), [(anp([QQ(1, 1)])*x + anp([-QQ(4, 1), QQ(1, 1)]), 1), + (anp([QQ(1, 1)])*x + anp([-QQ(3, 2), QQ(0, 1)]), 1), + (anp([QQ(1, 1)])*x + anp([ QQ(3, 2), QQ(0, 1)]), 1), + (anp([QQ(1, 1)])*x + anp([ QQ(4, 1), QQ(1, 1)]), 1)]) + + R, x = ring("x", QQ.algebraic_field(sqrt(2))) + def anp(element): + return ANP(element, [QQ(1), QQ(0), QQ(-2)], QQ) + + f = anp([QQ(1)])*x**4 + anp([QQ(1, 1)]) + + assert R.dup_ext_factor(f) == \ + (anp([QQ(1)]), [(anp([QQ(1)])*x**2 + anp([QQ(-1), QQ(0)])*x + anp([QQ(1)]), 1), + (anp([QQ(1)])*x**2 + anp([QQ( 1), QQ(0)])*x + anp([QQ(1)]), 1)]) + + f = anp([QQ(1, 1)])*x**2 + anp([QQ(2), QQ(0)])*x + anp([QQ(2, 1)]) + + assert R.dup_ext_factor(f) == \ + (anp([QQ(1, 1)]), [(anp([1])*x + anp([1, 0]), 2)]) + + assert R.dup_ext_factor(f**3) == \ + (anp([QQ(1, 1)]), [(anp([1])*x + anp([1, 0]), 6)]) + + f *= anp([QQ(2, 1)]) + + assert R.dup_ext_factor(f) == \ + (anp([QQ(2, 1)]), [(anp([1])*x + anp([1, 0]), 2)]) + + assert R.dup_ext_factor(f**3) == \ + (anp([QQ(8, 1)]), [(anp([1])*x + anp([1, 0]), 6)]) + + +def test_dmp_ext_factor(): + K = QQ.algebraic_field(sqrt(2)) + R, x,y = ring("x,y", K) + sqrt2 = K.unit + + def anp(x): + return ANP(x, [QQ(1), QQ(0), QQ(-2)], QQ) + + assert R.dmp_ext_factor(0) == (anp([]), []) + + f = anp([QQ(1)])*x + anp([QQ(1)]) + + assert R.dmp_ext_factor(f) == (anp([QQ(1)]), [(f, 1)]) + + g = anp([QQ(2)])*x + anp([QQ(2)]) + + assert R.dmp_ext_factor(g) == (anp([QQ(2)]), [(f, 1)]) + + f = anp([QQ(1)])*x**2 + anp([QQ(-2)])*y**2 + + assert R.dmp_ext_factor(f) == \ + (anp([QQ(1)]), [(anp([QQ(1)])*x + anp([QQ(-1), QQ(0)])*y, 1), + (anp([QQ(1)])*x + anp([QQ( 1), QQ(0)])*y, 1)]) + + f = anp([QQ(2)])*x**2 + anp([QQ(-4)])*y**2 + + assert R.dmp_ext_factor(f) == \ + (anp([QQ(2)]), [(anp([QQ(1)])*x + anp([QQ(-1), QQ(0)])*y, 1), + (anp([QQ(1)])*x + anp([QQ( 1), QQ(0)])*y, 1)]) + + f1 = y + 1 + f2 = y + sqrt2 + f3 = x**2 + x + 2 + 3*sqrt2 + f = f1**2 * f2**2 * f3**2 + assert R.dmp_ext_factor(f) == (K.one, [(f1, 2), (f2, 2), (f3, 2)]) + + +def test_dup_factor_list(): + R, x = ring("x", ZZ) + assert R.dup_factor_list(0) == (0, []) + assert R.dup_factor_list(7) == (7, []) + + R, x = ring("x", QQ) + assert R.dup_factor_list(0) == (0, []) + assert R.dup_factor_list(QQ(1, 7)) == (QQ(1, 7), []) + + R, x = ring("x", ZZ['t']) + assert R.dup_factor_list(0) == (0, []) + assert R.dup_factor_list(7) == (7, []) + + R, x = ring("x", QQ['t']) + assert R.dup_factor_list(0) == (0, []) + assert R.dup_factor_list(QQ(1, 7)) == (QQ(1, 7), []) + + R, x = ring("x", ZZ) + assert R.dup_factor_list_include(0) == [(0, 1)] + assert R.dup_factor_list_include(7) == [(7, 1)] + + assert R.dup_factor_list(x**2 + 2*x + 1) == (1, [(x + 1, 2)]) + assert R.dup_factor_list_include(x**2 + 2*x + 1) == [(x + 1, 2)] + # issue 8037 + assert R.dup_factor_list(6*x**2 - 5*x - 6) == (1, [(2*x - 3, 1), (3*x + 2, 1)]) + + R, x = ring("x", QQ) + assert R.dup_factor_list(QQ(1,2)*x**2 + x + QQ(1,2)) == (QQ(1, 2), [(x + 1, 2)]) + + R, x = ring("x", FF(2)) + assert R.dup_factor_list(x**2 + 1) == (1, [(x + 1, 2)]) + + R, x = ring("x", RR) + assert R.dup_factor_list(1.0*x**2 + 2.0*x + 1.0) == (1.0, [(1.0*x + 1.0, 2)]) + assert R.dup_factor_list(2.0*x**2 + 4.0*x + 2.0) == (2.0, [(1.0*x + 1.0, 2)]) + + f = 6.7225336055071*x**2 - 10.6463972754741*x - 0.33469524022264 + coeff, factors = R.dup_factor_list(f) + assert coeff == RR(10.6463972754741) + assert len(factors) == 1 + assert factors[0][0].max_norm() == RR(1.0) + assert factors[0][1] == 1 + + Rt, t = ring("t", ZZ) + R, x = ring("x", Rt) + + f = 4*t*x**2 + 4*t**2*x + + assert R.dup_factor_list(f) == \ + (4*t, [(x, 1), + (x + t, 1)]) + + Rt, t = ring("t", QQ) + R, x = ring("x", Rt) + + f = QQ(1, 2)*t*x**2 + QQ(1, 2)*t**2*x + + assert R.dup_factor_list(f) == \ + (QQ(1, 2)*t, [(x, 1), + (x + t, 1)]) + + R, x = ring("x", QQ.algebraic_field(I)) + def anp(element): + return ANP(element, [QQ(1), QQ(0), QQ(1)], QQ) + + f = anp([QQ(1, 1)])*x**4 + anp([QQ(2, 1)])*x**2 + + assert R.dup_factor_list(f) == \ + (anp([QQ(1, 1)]), [(anp([QQ(1, 1)])*x, 2), + (anp([QQ(1, 1)])*x**2 + anp([])*x + anp([QQ(2, 1)]), 1)]) + + R, x = ring("x", EX) + raises(DomainError, lambda: R.dup_factor_list(EX(sin(1)))) + + +def test_dmp_factor_list(): + R, x, y = ring("x,y", ZZ) + assert R.dmp_factor_list(0) == (ZZ(0), []) + assert R.dmp_factor_list(7) == (7, []) + + R, x, y = ring("x,y", QQ) + assert R.dmp_factor_list(0) == (QQ(0), []) + assert R.dmp_factor_list(QQ(1, 7)) == (QQ(1, 7), []) + + Rt, t = ring("t", ZZ) + R, x, y = ring("x,y", Rt) + assert R.dmp_factor_list(0) == (0, []) + assert R.dmp_factor_list(7) == (ZZ(7), []) + + Rt, t = ring("t", QQ) + R, x, y = ring("x,y", Rt) + assert R.dmp_factor_list(0) == (0, []) + assert R.dmp_factor_list(QQ(1, 7)) == (QQ(1, 7), []) + + R, x, y = ring("x,y", ZZ) + assert R.dmp_factor_list_include(0) == [(0, 1)] + assert R.dmp_factor_list_include(7) == [(7, 1)] + + R, X = xring("x:200", ZZ) + + f, g = X[0]**2 + 2*X[0] + 1, X[0] + 1 + assert R.dmp_factor_list(f) == (1, [(g, 2)]) + + f, g = X[-1]**2 + 2*X[-1] + 1, X[-1] + 1 + assert R.dmp_factor_list(f) == (1, [(g, 2)]) + + R, x = ring("x", ZZ) + assert R.dmp_factor_list(x**2 + 2*x + 1) == (1, [(x + 1, 2)]) + R, x = ring("x", QQ) + assert R.dmp_factor_list(QQ(1,2)*x**2 + x + QQ(1,2)) == (QQ(1,2), [(x + 1, 2)]) + + R, x, y = ring("x,y", ZZ) + assert R.dmp_factor_list(x**2 + 2*x + 1) == (1, [(x + 1, 2)]) + R, x, y = ring("x,y", QQ) + assert R.dmp_factor_list(QQ(1,2)*x**2 + x + QQ(1,2)) == (QQ(1,2), [(x + 1, 2)]) + + R, x, y = ring("x,y", ZZ) + f = 4*x**2*y + 4*x*y**2 + + assert R.dmp_factor_list(f) == \ + (4, [(y, 1), + (x, 1), + (x + y, 1)]) + + assert R.dmp_factor_list_include(f) == \ + [(4*y, 1), + (x, 1), + (x + y, 1)] + + R, x, y = ring("x,y", QQ) + f = QQ(1,2)*x**2*y + QQ(1,2)*x*y**2 + + assert R.dmp_factor_list(f) == \ + (QQ(1,2), [(y, 1), + (x, 1), + (x + y, 1)]) + + R, x, y = ring("x,y", RR) + f = 2.0*x**2 - 8.0*y**2 + + assert R.dmp_factor_list(f) == \ + (RR(8.0), [(0.5*x - y, 1), + (0.5*x + y, 1)]) + + f = 6.7225336055071*x**2*y**2 - 10.6463972754741*x*y - 0.33469524022264 + coeff, factors = R.dmp_factor_list(f) + assert coeff == RR(10.6463972754741) + assert len(factors) == 1 + assert factors[0][0].max_norm() == RR(1.0) + assert factors[0][1] == 1 + + Rt, t = ring("t", ZZ) + R, x, y = ring("x,y", Rt) + f = 4*t*x**2 + 4*t**2*x + + assert R.dmp_factor_list(f) == \ + (4*t, [(x, 1), + (x + t, 1)]) + + Rt, t = ring("t", QQ) + R, x, y = ring("x,y", Rt) + f = QQ(1, 2)*t*x**2 + QQ(1, 2)*t**2*x + + assert R.dmp_factor_list(f) == \ + (QQ(1, 2)*t, [(x, 1), + (x + t, 1)]) + + R, x, y = ring("x,y", FF(2)) + raises(NotImplementedError, lambda: R.dmp_factor_list(x**2 + y**2)) + + R, x, y = ring("x,y", EX) + raises(DomainError, lambda: R.dmp_factor_list(EX(sin(1)))) + + +def test_dup_irreducible_p(): + R, x = ring("x", ZZ) + assert R.dup_irreducible_p(x**2 + x + 1) is True + assert R.dup_irreducible_p(x**2 + 2*x + 1) is False + + +def test_dmp_irreducible_p(): + R, x, y = ring("x,y", ZZ) + assert R.dmp_irreducible_p(x**2 + x + 1) is True + assert R.dmp_irreducible_p(x**2 + 2*x + 1) is False diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_fields.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_fields.py new file mode 100644 index 0000000000000000000000000000000000000000..4f85a00d75dc02ab794ff94c83ba18ddc2023313 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_fields.py @@ -0,0 +1,353 @@ +"""Test sparse rational functions. """ + +from sympy.polys.fields import field, sfield, FracField, FracElement +from sympy.polys.rings import ring +from sympy.polys.domains import ZZ, QQ +from sympy.polys.orderings import lex + +from sympy.testing.pytest import raises, XFAIL +from sympy.core import symbols, E +from sympy.core.numbers import Rational +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt + +def test_FracField___init__(): + F1 = FracField("x,y", ZZ, lex) + F2 = FracField("x,y", ZZ, lex) + F3 = FracField("x,y,z", ZZ, lex) + + assert F1.x == F1.gens[0] + assert F1.y == F1.gens[1] + assert F1.x == F2.x + assert F1.y == F2.y + assert F1.x != F3.x + assert F1.y != F3.y + +def test_FracField___hash__(): + F, x, y, z = field("x,y,z", QQ) + assert hash(F) + +def test_FracField___eq__(): + assert field("x,y,z", QQ)[0] == field("x,y,z", QQ)[0] + assert field("x,y,z", QQ)[0] != field("x,y,z", ZZ)[0] + assert field("x,y,z", ZZ)[0] != field("x,y,z", QQ)[0] + assert field("x,y,z", QQ)[0] != field("x,y", QQ)[0] + assert field("x,y", QQ)[0] != field("x,y,z", QQ)[0] + +def test_sfield(): + x = symbols("x") + + F = FracField((E, exp(exp(x)), exp(x)), ZZ, lex) + e, exex, ex = F.gens + assert sfield(exp(x)*exp(exp(x) + 1 + log(exp(x) + 3)/2)**2/(exp(x) + 3)) \ + == (F, e**2*exex**2*ex) + + F = FracField((x, exp(1/x), log(x), x**QQ(1, 3)), ZZ, lex) + _, ex, lg, x3 = F.gens + assert sfield(((x-3)*log(x)+4*x**2)*exp(1/x+log(x)/3)/x**2) == \ + (F, (4*F.x**2*ex + F.x*ex*lg - 3*ex*lg)/x3**5) + + F = FracField((x, log(x), sqrt(x + log(x))), ZZ, lex) + _, lg, srt = F.gens + assert sfield((x + 1) / (x * (x + log(x))**QQ(3, 2)) - 1/(x * log(x)**2)) \ + == (F, (F.x*lg**2 - F.x*srt + lg**2 - lg*srt)/ + (F.x**2*lg**2*srt + F.x*lg**3*srt)) + +def test_FracElement___hash__(): + F, x, y, z = field("x,y,z", QQ) + assert hash(x*y/z) + +def test_FracElement_copy(): + F, x, y, z = field("x,y,z", ZZ) + + f = x*y/3*z + g = f.copy() + + assert f == g + g.numer[(1, 1, 1)] = 7 + assert f != g + +def test_FracElement_as_expr(): + F, x, y, z = field("x,y,z", ZZ) + f = (3*x**2*y - x*y*z)/(7*z**3 + 1) + + X, Y, Z = F.symbols + g = (3*X**2*Y - X*Y*Z)/(7*Z**3 + 1) + + assert f != g + assert f.as_expr() == g + + X, Y, Z = symbols("x,y,z") + g = (3*X**2*Y - X*Y*Z)/(7*Z**3 + 1) + + assert f != g + assert f.as_expr(X, Y, Z) == g + + raises(ValueError, lambda: f.as_expr(X)) + +def test_FracElement_from_expr(): + x, y, z = symbols("x,y,z") + F, X, Y, Z = field((x, y, z), ZZ) + + f = F.from_expr(1) + assert f == 1 and F.is_element(f) + + f = F.from_expr(Rational(3, 7)) + assert f == F(3)/7 and F.is_element(f) + + f = F.from_expr(x) + assert f == X and F.is_element(f) + + f = F.from_expr(Rational(3,7)*x) + assert f == X*Rational(3, 7) and F.is_element(f) + + f = F.from_expr(1/x) + assert f == 1/X and F.is_element(f) + + f = F.from_expr(x*y*z) + assert f == X*Y*Z and F.is_element(f) + + f = F.from_expr(x*y/z) + assert f == X*Y/Z and F.is_element(f) + + f = F.from_expr(x*y*z + x*y + x) + assert f == X*Y*Z + X*Y + X and F.is_element(f) + + f = F.from_expr((x*y*z + x*y + x)/(x*y + 7)) + assert f == (X*Y*Z + X*Y + X)/(X*Y + 7) and F.is_element(f) + + f = F.from_expr(x**3*y*z + x**2*y**7 + 1) + assert f == X**3*Y*Z + X**2*Y**7 + 1 and F.is_element(f) + + raises(ValueError, lambda: F.from_expr(2**x)) + raises(ValueError, lambda: F.from_expr(7*x + sqrt(2))) + + assert isinstance(ZZ[2**x].get_field().convert(2**(-x)), + FracElement) + assert isinstance(ZZ[x**2].get_field().convert(x**(-6)), + FracElement) + assert isinstance(ZZ[exp(Rational(1, 3))].get_field().convert(E), + FracElement) + + +def test_FracField_nested(): + a, b, x = symbols('a b x') + F1 = ZZ.frac_field(a, b) + F2 = F1.frac_field(x) + frac = F2(a + b) + assert frac.numer == F1.poly_ring(x)(a + b) + assert frac.numer.coeffs() == [F1(a + b)] + assert frac.denom == F1.poly_ring(x)(1) + + F3 = ZZ.poly_ring(a, b) + F4 = F3.frac_field(x) + frac = F4(a + b) + assert frac.numer == F3.poly_ring(x)(a + b) + assert frac.numer.coeffs() == [F3(a + b)] + assert frac.denom == F3.poly_ring(x)(1) + + frac = F2(F3(a + b)) + assert frac.numer == F1.poly_ring(x)(a + b) + assert frac.numer.coeffs() == [F1(a + b)] + assert frac.denom == F1.poly_ring(x)(1) + + frac = F4(F1(a + b)) + assert frac.numer == F3.poly_ring(x)(a + b) + assert frac.numer.coeffs() == [F3(a + b)] + assert frac.denom == F3.poly_ring(x)(1) + + +def test_FracElement__lt_le_gt_ge__(): + F, x, y = field("x,y", ZZ) + + assert F(1) < 1/x < 1/x**2 < 1/x**3 + assert F(1) <= 1/x <= 1/x**2 <= 1/x**3 + + assert -7/x < 1/x < 3/x < y/x < 1/x**2 + assert -7/x <= 1/x <= 3/x <= y/x <= 1/x**2 + + assert 1/x**3 > 1/x**2 > 1/x > F(1) + assert 1/x**3 >= 1/x**2 >= 1/x >= F(1) + + assert 1/x**2 > y/x > 3/x > 1/x > -7/x + assert 1/x**2 >= y/x >= 3/x >= 1/x >= -7/x + +def test_FracElement___neg__(): + F, x,y = field("x,y", QQ) + + f = (7*x - 9)/y + g = (-7*x + 9)/y + + assert -f == g + assert -g == f + +def test_FracElement___add__(): + F, x,y = field("x,y", QQ) + + f, g = 1/x, 1/y + assert f + g == g + f == (x + y)/(x*y) + + assert x + F.ring.gens[0] == F.ring.gens[0] + x == 2*x + + F, x,y = field("x,y", ZZ) + assert x + 3 == 3 + x + assert x + QQ(3,7) == QQ(3,7) + x == (7*x + 3)/7 + + Fuv, u,v = field("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Fuv) + + f = (u*v + x)/(y + u*v) + assert dict(f.numer) == {(1, 0, 0, 0): 1, (0, 0, 0, 0): u*v} + assert dict(f.denom) == {(0, 1, 0, 0): 1, (0, 0, 0, 0): u*v} + + Ruv, u,v = ring("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Ruv) + + f = (u*v + x)/(y + u*v) + assert dict(f.numer) == {(1, 0, 0, 0): 1, (0, 0, 0, 0): u*v} + assert dict(f.denom) == {(0, 1, 0, 0): 1, (0, 0, 0, 0): u*v} + +def test_FracElement___sub__(): + F, x,y = field("x,y", QQ) + + f, g = 1/x, 1/y + assert f - g == (-x + y)/(x*y) + + assert x - F.ring.gens[0] == F.ring.gens[0] - x == 0 + + F, x,y = field("x,y", ZZ) + assert x - 3 == -(3 - x) + assert x - QQ(3,7) == -(QQ(3,7) - x) == (7*x - 3)/7 + + Fuv, u,v = field("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Fuv) + + f = (u*v - x)/(y - u*v) + assert dict(f.numer) == {(1, 0, 0, 0):-1, (0, 0, 0, 0): u*v} + assert dict(f.denom) == {(0, 1, 0, 0): 1, (0, 0, 0, 0):-u*v} + + Ruv, u,v = ring("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Ruv) + + f = (u*v - x)/(y - u*v) + assert dict(f.numer) == {(1, 0, 0, 0):-1, (0, 0, 0, 0): u*v} + assert dict(f.denom) == {(0, 1, 0, 0): 1, (0, 0, 0, 0):-u*v} + +def test_FracElement___mul__(): + F, x,y = field("x,y", QQ) + + f, g = 1/x, 1/y + assert f*g == g*f == 1/(x*y) + + assert x*F.ring.gens[0] == F.ring.gens[0]*x == x**2 + + F, x,y = field("x,y", ZZ) + assert x*3 == 3*x + assert x*QQ(3,7) == QQ(3,7)*x == x*Rational(3, 7) + + Fuv, u,v = field("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Fuv) + + f = ((u + 1)*x*y + 1)/((v - 1)*z - t*u*v - 1) + assert dict(f.numer) == {(1, 1, 0, 0): u + 1, (0, 0, 0, 0): 1} + assert dict(f.denom) == {(0, 0, 1, 0): v - 1, (0, 0, 0, 1): -u*v, (0, 0, 0, 0): -1} + + Ruv, u,v = ring("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Ruv) + + f = ((u + 1)*x*y + 1)/((v - 1)*z - t*u*v - 1) + assert dict(f.numer) == {(1, 1, 0, 0): u + 1, (0, 0, 0, 0): 1} + assert dict(f.denom) == {(0, 0, 1, 0): v - 1, (0, 0, 0, 1): -u*v, (0, 0, 0, 0): -1} + +def test_FracElement___truediv__(): + F, x,y = field("x,y", QQ) + + f, g = 1/x, 1/y + assert f/g == y/x + + assert x/F.ring.gens[0] == F.ring.gens[0]/x == 1 + + F, x,y = field("x,y", ZZ) + assert x*3 == 3*x + assert x/QQ(3,7) == (QQ(3,7)/x)**-1 == x*Rational(7, 3) + + raises(ZeroDivisionError, lambda: x/0) + raises(ZeroDivisionError, lambda: 1/(x - x)) + raises(ZeroDivisionError, lambda: x/(x - x)) + + Fuv, u,v = field("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Fuv) + + f = (u*v)/(x*y) + assert dict(f.numer) == {(0, 0, 0, 0): u*v} + assert dict(f.denom) == {(1, 1, 0, 0): 1} + + g = (x*y)/(u*v) + assert dict(g.numer) == {(1, 1, 0, 0): 1} + assert dict(g.denom) == {(0, 0, 0, 0): u*v} + + Ruv, u,v = ring("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Ruv) + + f = (u*v)/(x*y) + assert dict(f.numer) == {(0, 0, 0, 0): u*v} + assert dict(f.denom) == {(1, 1, 0, 0): 1} + + g = (x*y)/(u*v) + assert dict(g.numer) == {(1, 1, 0, 0): 1} + assert dict(g.denom) == {(0, 0, 0, 0): u*v} + +def test_FracElement___pow__(): + F, x,y = field("x,y", QQ) + + f, g = 1/x, 1/y + + assert f**3 == 1/x**3 + assert g**3 == 1/y**3 + + assert (f*g)**3 == 1/(x**3*y**3) + assert (f*g)**-3 == (x*y)**3 + + raises(ZeroDivisionError, lambda: (x - x)**-3) + +def test_FracElement_diff(): + F, x,y,z = field("x,y,z", ZZ) + + assert ((x**2 + y)/(z + 1)).diff(x) == 2*x/(z + 1) + +@XFAIL +def test_FracElement___call__(): + F, x,y,z = field("x,y,z", ZZ) + f = (x**2 + 3*y)/z + + r = f(1, 1, 1) + assert r == 4 and not isinstance(r, FracElement) + raises(ZeroDivisionError, lambda: f(1, 1, 0)) + +def test_FracElement_evaluate(): + F, x,y,z = field("x,y,z", ZZ) + Fyz = field("y,z", ZZ)[0] + f = (x**2 + 3*y)/z + + assert f.evaluate(x, 0) == 3*Fyz.y/Fyz.z + raises(ZeroDivisionError, lambda: f.evaluate(z, 0)) + +def test_FracElement_subs(): + F, x,y,z = field("x,y,z", ZZ) + f = (x**2 + 3*y)/z + + assert f.subs(x, 0) == 3*y/z + raises(ZeroDivisionError, lambda: f.subs(z, 0)) + +def test_FracElement_compose(): + pass + +def test_FracField_index(): + a = symbols("a") + F, x, y, z = field('x y z', QQ) + assert F.index(x) == 0 + assert F.index(y) == 1 + + raises(ValueError, lambda: F.index(1)) + raises(ValueError, lambda: F.index(a)) + pass diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_galoistools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_galoistools.py new file mode 100644 index 0000000000000000000000000000000000000000..e512bdd865c300bb138cb40b4ff78f393b323c22 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_galoistools.py @@ -0,0 +1,875 @@ +from sympy.polys.galoistools import ( + gf_crt, gf_crt1, gf_crt2, gf_int, + gf_degree, gf_strip, gf_trunc, gf_normal, + gf_from_dict, gf_to_dict, + gf_from_int_poly, gf_to_int_poly, + gf_neg, gf_add_ground, gf_sub_ground, gf_mul_ground, + gf_add, gf_sub, gf_add_mul, gf_sub_mul, gf_mul, gf_sqr, + gf_div, gf_rem, gf_quo, gf_exquo, + gf_lshift, gf_rshift, gf_expand, + gf_pow, gf_pow_mod, + gf_gcdex, gf_gcd, gf_lcm, gf_cofactors, + gf_LC, gf_TC, gf_monic, + gf_eval, gf_multi_eval, + gf_compose, gf_compose_mod, + gf_trace_map, + gf_diff, + gf_irreducible, gf_irreducible_p, + gf_irred_p_ben_or, gf_irred_p_rabin, + gf_sqf_list, gf_sqf_part, gf_sqf_p, + gf_Qmatrix, gf_Qbasis, + gf_ddf_zassenhaus, gf_ddf_shoup, + gf_edf_zassenhaus, gf_edf_shoup, + gf_berlekamp, + gf_factor_sqf, gf_factor, + gf_value, linear_congruence, _csolve_prime_las_vegas, + csolve_prime, gf_csolve, gf_frobenius_map, gf_frobenius_monomial_base +) + +from sympy.polys.polyerrors import ( + ExactQuotientFailed, +) + +from sympy.polys import polyconfig as config + +from sympy.polys.domains import ZZ +from sympy.core.numbers import pi +from sympy.ntheory.generate import nextprime +from sympy.testing.pytest import raises + + +def test_gf_crt(): + U = [49, 76, 65] + M = [99, 97, 95] + + p = 912285 + u = 639985 + + assert gf_crt(U, M, ZZ) == u + + E = [9215, 9405, 9603] + S = [62, 24, 12] + + assert gf_crt1(M, ZZ) == (p, E, S) + assert gf_crt2(U, M, p, E, S, ZZ) == u + + +def test_gf_int(): + assert gf_int(0, 5) == 0 + assert gf_int(1, 5) == 1 + assert gf_int(2, 5) == 2 + assert gf_int(3, 5) == -2 + assert gf_int(4, 5) == -1 + assert gf_int(5, 5) == 0 + + +def test_gf_degree(): + assert gf_degree([]) == -1 + assert gf_degree([1]) == 0 + assert gf_degree([1, 0]) == 1 + assert gf_degree([1, 0, 0, 0, 1]) == 4 + + +def test_gf_strip(): + assert gf_strip([]) == [] + assert gf_strip([0]) == [] + assert gf_strip([0, 0, 0]) == [] + + assert gf_strip([1]) == [1] + assert gf_strip([0, 1]) == [1] + assert gf_strip([0, 0, 0, 1]) == [1] + + assert gf_strip([1, 2, 0]) == [1, 2, 0] + assert gf_strip([0, 1, 2, 0]) == [1, 2, 0] + assert gf_strip([0, 0, 0, 1, 2, 0]) == [1, 2, 0] + + +def test_gf_trunc(): + assert gf_trunc([], 11) == [] + assert gf_trunc([1], 11) == [1] + assert gf_trunc([22], 11) == [] + assert gf_trunc([12], 11) == [1] + + assert gf_trunc([11, 22, 17, 1, 0], 11) == [6, 1, 0] + assert gf_trunc([12, 23, 17, 1, 0], 11) == [1, 1, 6, 1, 0] + + +def test_gf_normal(): + assert gf_normal([11, 22, 17, 1, 0], 11, ZZ) == [6, 1, 0] + + +def test_gf_from_to_dict(): + f = {11: 12, 6: 2, 0: 25} + F = {11: 1, 6: 2, 0: 3} + g = [1, 0, 0, 0, 0, 2, 0, 0, 0, 0, 0, 3] + + assert gf_from_dict(f, 11, ZZ) == g + assert gf_to_dict(g, 11) == F + + f = {11: -5, 4: 0, 3: 1, 0: 12} + F = {11: -5, 3: 1, 0: 1} + g = [6, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 1] + + assert gf_from_dict(f, 11, ZZ) == g + assert gf_to_dict(g, 11) == F + + assert gf_to_dict([10], 11, symmetric=True) == {0: -1} + assert gf_to_dict([10], 11, symmetric=False) == {0: 10} + + +def test_gf_from_to_int_poly(): + assert gf_from_int_poly([1, 0, 7, 2, 20], 5) == [1, 0, 2, 2, 0] + assert gf_to_int_poly([1, 0, 4, 2, 3], 5) == [1, 0, -1, 2, -2] + + assert gf_to_int_poly([10], 11, symmetric=True) == [-1] + assert gf_to_int_poly([10], 11, symmetric=False) == [10] + + +def test_gf_LC(): + assert gf_LC([], ZZ) == 0 + assert gf_LC([1], ZZ) == 1 + assert gf_LC([1, 2], ZZ) == 1 + + +def test_gf_TC(): + assert gf_TC([], ZZ) == 0 + assert gf_TC([1], ZZ) == 1 + assert gf_TC([1, 2], ZZ) == 2 + + +def test_gf_monic(): + assert gf_monic(ZZ.map([]), 11, ZZ) == (0, []) + + assert gf_monic(ZZ.map([1]), 11, ZZ) == (1, [1]) + assert gf_monic(ZZ.map([2]), 11, ZZ) == (2, [1]) + + assert gf_monic(ZZ.map([1, 2, 3, 4]), 11, ZZ) == (1, [1, 2, 3, 4]) + assert gf_monic(ZZ.map([2, 3, 4, 5]), 11, ZZ) == (2, [1, 7, 2, 8]) + + +def test_gf_arith(): + assert gf_neg([], 11, ZZ) == [] + assert gf_neg([1], 11, ZZ) == [10] + assert gf_neg([1, 2, 3], 11, ZZ) == [10, 9, 8] + + assert gf_add_ground([], 0, 11, ZZ) == [] + assert gf_sub_ground([], 0, 11, ZZ) == [] + + assert gf_add_ground([], 3, 11, ZZ) == [3] + assert gf_sub_ground([], 3, 11, ZZ) == [8] + + assert gf_add_ground([1], 3, 11, ZZ) == [4] + assert gf_sub_ground([1], 3, 11, ZZ) == [9] + + assert gf_add_ground([8], 3, 11, ZZ) == [] + assert gf_sub_ground([3], 3, 11, ZZ) == [] + + assert gf_add_ground([1, 2, 3], 3, 11, ZZ) == [1, 2, 6] + assert gf_sub_ground([1, 2, 3], 3, 11, ZZ) == [1, 2, 0] + + assert gf_mul_ground([], 0, 11, ZZ) == [] + assert gf_mul_ground([], 1, 11, ZZ) == [] + + assert gf_mul_ground([1], 0, 11, ZZ) == [] + assert gf_mul_ground([1], 1, 11, ZZ) == [1] + + assert gf_mul_ground([1, 2, 3], 0, 11, ZZ) == [] + assert gf_mul_ground([1, 2, 3], 1, 11, ZZ) == [1, 2, 3] + assert gf_mul_ground([1, 2, 3], 7, 11, ZZ) == [7, 3, 10] + + assert gf_add([], [], 11, ZZ) == [] + assert gf_add([1], [], 11, ZZ) == [1] + assert gf_add([], [1], 11, ZZ) == [1] + assert gf_add([1], [1], 11, ZZ) == [2] + assert gf_add([1], [2], 11, ZZ) == [3] + + assert gf_add([1, 2], [1], 11, ZZ) == [1, 3] + assert gf_add([1], [1, 2], 11, ZZ) == [1, 3] + + assert gf_add([1, 2, 3], [8, 9, 10], 11, ZZ) == [9, 0, 2] + + assert gf_sub([], [], 11, ZZ) == [] + assert gf_sub([1], [], 11, ZZ) == [1] + assert gf_sub([], [1], 11, ZZ) == [10] + assert gf_sub([1], [1], 11, ZZ) == [] + assert gf_sub([1], [2], 11, ZZ) == [10] + + assert gf_sub([1, 2], [1], 11, ZZ) == [1, 1] + assert gf_sub([1], [1, 2], 11, ZZ) == [10, 10] + + assert gf_sub([3, 2, 1], [8, 9, 10], 11, ZZ) == [6, 4, 2] + + assert gf_add_mul( + [1, 5, 6], [7, 3], [8, 0, 6, 1], 11, ZZ) == [1, 2, 10, 8, 9] + assert gf_sub_mul( + [1, 5, 6], [7, 3], [8, 0, 6, 1], 11, ZZ) == [10, 9, 3, 2, 3] + + assert gf_mul([], [], 11, ZZ) == [] + assert gf_mul([], [1], 11, ZZ) == [] + assert gf_mul([1], [], 11, ZZ) == [] + assert gf_mul([1], [1], 11, ZZ) == [1] + assert gf_mul([5], [7], 11, ZZ) == [2] + + assert gf_mul([3, 0, 0, 6, 1, 2], [4, 0, 1, 0], 11, ZZ) == [1, 0, + 3, 2, 4, 3, 1, 2, 0] + assert gf_mul([4, 0, 1, 0], [3, 0, 0, 6, 1, 2], 11, ZZ) == [1, 0, + 3, 2, 4, 3, 1, 2, 0] + + assert gf_mul([2, 0, 0, 1, 7], [2, 0, 0, 1, 7], 11, ZZ) == [4, 0, + 0, 4, 6, 0, 1, 3, 5] + + assert gf_sqr([], 11, ZZ) == [] + assert gf_sqr([2], 11, ZZ) == [4] + assert gf_sqr([1, 2], 11, ZZ) == [1, 4, 4] + + assert gf_sqr([2, 0, 0, 1, 7], 11, ZZ) == [4, 0, 0, 4, 6, 0, 1, 3, 5] + + +def test_gf_division(): + raises(ZeroDivisionError, lambda: gf_div([1, 2, 3], [], 11, ZZ)) + raises(ZeroDivisionError, lambda: gf_rem([1, 2, 3], [], 11, ZZ)) + raises(ZeroDivisionError, lambda: gf_quo([1, 2, 3], [], 11, ZZ)) + raises(ZeroDivisionError, lambda: gf_quo([1, 2, 3], [], 11, ZZ)) + + assert gf_div([1], [1, 2, 3], 7, ZZ) == ([], [1]) + assert gf_rem([1], [1, 2, 3], 7, ZZ) == [1] + assert gf_quo([1], [1, 2, 3], 7, ZZ) == [] + + f = ZZ.map([5, 4, 3, 2, 1, 0]) + g = ZZ.map([1, 2, 3]) + q = [5, 1, 0, 6] + r = [3, 3] + + assert gf_div(f, g, 7, ZZ) == (q, r) + assert gf_rem(f, g, 7, ZZ) == r + assert gf_quo(f, g, 7, ZZ) == q + + raises(ExactQuotientFailed, lambda: gf_exquo(f, g, 7, ZZ)) + + f = ZZ.map([5, 4, 3, 2, 1, 0]) + g = ZZ.map([1, 2, 3, 0]) + q = [5, 1, 0] + r = [6, 1, 0] + + assert gf_div(f, g, 7, ZZ) == (q, r) + assert gf_rem(f, g, 7, ZZ) == r + assert gf_quo(f, g, 7, ZZ) == q + + raises(ExactQuotientFailed, lambda: gf_exquo(f, g, 7, ZZ)) + + assert gf_quo(ZZ.map([1, 2, 1]), ZZ.map([1, 1]), 11, ZZ) == [1, 1] + + +def test_gf_shift(): + f = [1, 2, 3, 4, 5] + + assert gf_lshift([], 5, ZZ) == [] + assert gf_rshift([], 5, ZZ) == ([], []) + + assert gf_lshift(f, 1, ZZ) == [1, 2, 3, 4, 5, 0] + assert gf_lshift(f, 2, ZZ) == [1, 2, 3, 4, 5, 0, 0] + + assert gf_rshift(f, 0, ZZ) == (f, []) + assert gf_rshift(f, 1, ZZ) == ([1, 2, 3, 4], [5]) + assert gf_rshift(f, 3, ZZ) == ([1, 2], [3, 4, 5]) + assert gf_rshift(f, 5, ZZ) == ([], f) + + +def test_gf_expand(): + F = [([1, 1], 2), ([1, 2], 3)] + + assert gf_expand(F, 11, ZZ) == [1, 8, 3, 5, 6, 8] + assert gf_expand((4, F), 11, ZZ) == [4, 10, 1, 9, 2, 10] + + +def test_gf_powering(): + assert gf_pow([1, 0, 0, 1, 8], 0, 11, ZZ) == [1] + assert gf_pow([1, 0, 0, 1, 8], 1, 11, ZZ) == [1, 0, 0, 1, 8] + assert gf_pow([1, 0, 0, 1, 8], 2, 11, ZZ) == [1, 0, 0, 2, 5, 0, 1, 5, 9] + + assert gf_pow([1, 0, 0, 1, 8], 5, 11, ZZ) == \ + [1, 0, 0, 5, 7, 0, 10, 6, 2, 10, 9, 6, 10, 6, 6, 0, 5, 2, 5, 9, 10] + + assert gf_pow([1, 0, 0, 1, 8], 8, 11, ZZ) == \ + [1, 0, 0, 8, 9, 0, 6, 8, 10, 1, 2, 5, 10, 7, 7, 9, 1, 2, 0, 0, 6, 2, + 5, 2, 5, 7, 7, 9, 10, 10, 7, 5, 5] + + assert gf_pow([1, 0, 0, 1, 8], 45, 11, ZZ) == \ + [ 1, 0, 0, 1, 8, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 4, 0, 0, 4, 10, 0, 0, 0, 0, 0, 0, + 10, 0, 0, 10, 3, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 6, 0, 0, 6, 4, 0, 0, 0, 0, 0, 0, 8, 0, 0, 8, 9, 0, 0, 0, 0, 0, 0, + 10, 0, 0, 10, 3, 0, 0, 0, 0, 0, 0, 4, 0, 0, 4, 10, 0, 0, 0, 0, 0, 0, + 8, 0, 0, 8, 9, 0, 0, 0, 0, 0, 0, 9, 0, 0, 9, 6, 0, 0, 0, 0, 0, 0, + 3, 0, 0, 3, 2, 0, 0, 0, 0, 0, 0, 10, 0, 0, 10, 3, 0, 0, 0, 0, 0, 0, + 10, 0, 0, 10, 3, 0, 0, 0, 0, 0, 0, 2, 0, 0, 2, 5, 0, 0, 0, 0, 0, 0, + 4, 0, 0, 4, 10] + + assert gf_pow_mod(ZZ.map([1, 0, 0, 1, 8]), 0, ZZ.map([2, 0, 7]), 11, ZZ) == [1] + assert gf_pow_mod(ZZ.map([1, 0, 0, 1, 8]), 1, ZZ.map([2, 0, 7]), 11, ZZ) == [1, 1] + assert gf_pow_mod(ZZ.map([1, 0, 0, 1, 8]), 2, ZZ.map([2, 0, 7]), 11, ZZ) == [2, 3] + assert gf_pow_mod(ZZ.map([1, 0, 0, 1, 8]), 5, ZZ.map([2, 0, 7]), 11, ZZ) == [7, 8] + assert gf_pow_mod(ZZ.map([1, 0, 0, 1, 8]), 8, ZZ.map([2, 0, 7]), 11, ZZ) == [1, 5] + assert gf_pow_mod(ZZ.map([1, 0, 0, 1, 8]), 45, ZZ.map([2, 0, 7]), 11, ZZ) == [5, 4] + + +def test_gf_gcdex(): + assert gf_gcdex(ZZ.map([]), ZZ.map([]), 11, ZZ) == ([1], [], []) + assert gf_gcdex(ZZ.map([2]), ZZ.map([]), 11, ZZ) == ([6], [], [1]) + assert gf_gcdex(ZZ.map([]), ZZ.map([2]), 11, ZZ) == ([], [6], [1]) + assert gf_gcdex(ZZ.map([2]), ZZ.map([2]), 11, ZZ) == ([], [6], [1]) + + assert gf_gcdex(ZZ.map([]), ZZ.map([3, 0]), 11, ZZ) == ([], [4], [1, 0]) + assert gf_gcdex(ZZ.map([3, 0]), ZZ.map([]), 11, ZZ) == ([4], [], [1, 0]) + + assert gf_gcdex(ZZ.map([3, 0]), ZZ.map([3, 0]), 11, ZZ) == ([], [4], [1, 0]) + + assert gf_gcdex(ZZ.map([1, 8, 7]), ZZ.map([1, 7, 1, 7]), 11, ZZ) == ([5, 6], [6], [1, 7]) + + +def test_gf_gcd(): + assert gf_gcd(ZZ.map([]), ZZ.map([]), 11, ZZ) == [] + assert gf_gcd(ZZ.map([2]), ZZ.map([]), 11, ZZ) == [1] + assert gf_gcd(ZZ.map([]), ZZ.map([2]), 11, ZZ) == [1] + assert gf_gcd(ZZ.map([2]), ZZ.map([2]), 11, ZZ) == [1] + + assert gf_gcd(ZZ.map([]), ZZ.map([1, 0]), 11, ZZ) == [1, 0] + assert gf_gcd(ZZ.map([1, 0]), ZZ.map([]), 11, ZZ) == [1, 0] + + assert gf_gcd(ZZ.map([3, 0]), ZZ.map([3, 0]), 11, ZZ) == [1, 0] + assert gf_gcd(ZZ.map([1, 8, 7]), ZZ.map([1, 7, 1, 7]), 11, ZZ) == [1, 7] + + +def test_gf_lcm(): + assert gf_lcm(ZZ.map([]), ZZ.map([]), 11, ZZ) == [] + assert gf_lcm(ZZ.map([2]), ZZ.map([]), 11, ZZ) == [] + assert gf_lcm(ZZ.map([]), ZZ.map([2]), 11, ZZ) == [] + assert gf_lcm(ZZ.map([2]), ZZ.map([2]), 11, ZZ) == [1] + + assert gf_lcm(ZZ.map([]), ZZ.map([1, 0]), 11, ZZ) == [] + assert gf_lcm(ZZ.map([1, 0]), ZZ.map([]), 11, ZZ) == [] + + assert gf_lcm(ZZ.map([3, 0]), ZZ.map([3, 0]), 11, ZZ) == [1, 0] + assert gf_lcm(ZZ.map([1, 8, 7]), ZZ.map([1, 7, 1, 7]), 11, ZZ) == [1, 8, 8, 8, 7] + + +def test_gf_cofactors(): + assert gf_cofactors(ZZ.map([]), ZZ.map([]), 11, ZZ) == ([], [], []) + assert gf_cofactors(ZZ.map([2]), ZZ.map([]), 11, ZZ) == ([1], [2], []) + assert gf_cofactors(ZZ.map([]), ZZ.map([2]), 11, ZZ) == ([1], [], [2]) + assert gf_cofactors(ZZ.map([2]), ZZ.map([2]), 11, ZZ) == ([1], [2], [2]) + + assert gf_cofactors(ZZ.map([]), ZZ.map([1, 0]), 11, ZZ) == ([1, 0], [], [1]) + assert gf_cofactors(ZZ.map([1, 0]), ZZ.map([]), 11, ZZ) == ([1, 0], [1], []) + + assert gf_cofactors(ZZ.map([3, 0]), ZZ.map([3, 0]), 11, ZZ) == ( + [1, 0], [3], [3]) + assert gf_cofactors(ZZ.map([1, 8, 7]), ZZ.map([1, 7, 1, 7]), 11, ZZ) == ( + ([1, 7], [1, 1], [1, 0, 1])) + + +def test_gf_diff(): + assert gf_diff([], 11, ZZ) == [] + assert gf_diff([7], 11, ZZ) == [] + + assert gf_diff([7, 3], 11, ZZ) == [7] + assert gf_diff([7, 3, 1], 11, ZZ) == [3, 3] + + assert gf_diff([1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1], 11, ZZ) == [] + + +def test_gf_eval(): + assert gf_eval([], 4, 11, ZZ) == 0 + assert gf_eval([], 27, 11, ZZ) == 0 + assert gf_eval([7], 4, 11, ZZ) == 7 + assert gf_eval([7], 27, 11, ZZ) == 7 + + assert gf_eval([1, 0, 3, 2, 4, 3, 1, 2, 0], 0, 11, ZZ) == 0 + assert gf_eval([1, 0, 3, 2, 4, 3, 1, 2, 0], 4, 11, ZZ) == 9 + assert gf_eval([1, 0, 3, 2, 4, 3, 1, 2, 0], 27, 11, ZZ) == 5 + + assert gf_eval([4, 0, 0, 4, 6, 0, 1, 3, 5], 0, 11, ZZ) == 5 + assert gf_eval([4, 0, 0, 4, 6, 0, 1, 3, 5], 4, 11, ZZ) == 3 + assert gf_eval([4, 0, 0, 4, 6, 0, 1, 3, 5], 27, 11, ZZ) == 9 + + assert gf_multi_eval([3, 2, 1], [0, 1, 2, 3], 11, ZZ) == [1, 6, 6, 1] + + +def test_gf_compose(): + assert gf_compose([], [1, 0], 11, ZZ) == [] + assert gf_compose_mod([], [1, 0], [1, 0], 11, ZZ) == [] + + assert gf_compose([1], [], 11, ZZ) == [1] + assert gf_compose([1, 0], [], 11, ZZ) == [] + assert gf_compose([1, 0], [1, 0], 11, ZZ) == [1, 0] + + f = ZZ.map([1, 1, 4, 9, 1]) + g = ZZ.map([1, 1, 1]) + h = ZZ.map([1, 0, 0, 2]) + + assert gf_compose(g, h, 11, ZZ) == [1, 0, 0, 5, 0, 0, 7] + assert gf_compose_mod(g, h, f, 11, ZZ) == [3, 9, 6, 10] + + +def test_gf_trace_map(): + f = ZZ.map([1, 1, 4, 9, 1]) + a = [1, 1, 1] + c = ZZ.map([1, 0]) + b = gf_pow_mod(c, 11, f, 11, ZZ) + + assert gf_trace_map(a, b, c, 0, f, 11, ZZ) == \ + ([1, 1, 1], [1, 1, 1]) + assert gf_trace_map(a, b, c, 1, f, 11, ZZ) == \ + ([5, 2, 10, 3], [5, 3, 0, 4]) + assert gf_trace_map(a, b, c, 2, f, 11, ZZ) == \ + ([5, 9, 5, 3], [10, 1, 5, 7]) + assert gf_trace_map(a, b, c, 3, f, 11, ZZ) == \ + ([1, 10, 6, 0], [7]) + assert gf_trace_map(a, b, c, 4, f, 11, ZZ) == \ + ([1, 1, 1], [1, 1, 8]) + assert gf_trace_map(a, b, c, 5, f, 11, ZZ) == \ + ([5, 2, 10, 3], [5, 3, 0, 0]) + assert gf_trace_map(a, b, c, 11, f, 11, ZZ) == \ + ([1, 10, 6, 0], [10]) + + +def test_gf_irreducible(): + assert gf_irreducible_p(gf_irreducible(1, 11, ZZ), 11, ZZ) is True + assert gf_irreducible_p(gf_irreducible(2, 11, ZZ), 11, ZZ) is True + assert gf_irreducible_p(gf_irreducible(3, 11, ZZ), 11, ZZ) is True + assert gf_irreducible_p(gf_irreducible(4, 11, ZZ), 11, ZZ) is True + assert gf_irreducible_p(gf_irreducible(5, 11, ZZ), 11, ZZ) is True + assert gf_irreducible_p(gf_irreducible(6, 11, ZZ), 11, ZZ) is True + assert gf_irreducible_p(gf_irreducible(7, 11, ZZ), 11, ZZ) is True + + +def test_gf_irreducible_p(): + assert gf_irred_p_ben_or(ZZ.map([7]), 11, ZZ) is True + assert gf_irred_p_ben_or(ZZ.map([7, 3]), 11, ZZ) is True + assert gf_irred_p_ben_or(ZZ.map([7, 3, 1]), 11, ZZ) is False + + assert gf_irred_p_rabin(ZZ.map([7]), 11, ZZ) is True + assert gf_irred_p_rabin(ZZ.map([7, 3]), 11, ZZ) is True + assert gf_irred_p_rabin(ZZ.map([7, 3, 1]), 11, ZZ) is False + + config.setup('GF_IRRED_METHOD', 'ben-or') + + assert gf_irreducible_p(ZZ.map([7]), 11, ZZ) is True + assert gf_irreducible_p(ZZ.map([7, 3]), 11, ZZ) is True + assert gf_irreducible_p(ZZ.map([7, 3, 1]), 11, ZZ) is False + + config.setup('GF_IRRED_METHOD', 'rabin') + + assert gf_irreducible_p(ZZ.map([7]), 11, ZZ) is True + assert gf_irreducible_p(ZZ.map([7, 3]), 11, ZZ) is True + assert gf_irreducible_p(ZZ.map([7, 3, 1]), 11, ZZ) is False + + config.setup('GF_IRRED_METHOD', 'other') + raises(KeyError, lambda: gf_irreducible_p([7], 11, ZZ)) + config.setup('GF_IRRED_METHOD') + + f = ZZ.map([1, 9, 9, 13, 16, 15, 6, 7, 7, 7, 10]) + g = ZZ.map([1, 7, 16, 7, 15, 13, 13, 11, 16, 10, 9]) + + h = gf_mul(f, g, 17, ZZ) + + assert gf_irred_p_ben_or(f, 17, ZZ) is True + assert gf_irred_p_ben_or(g, 17, ZZ) is True + + assert gf_irred_p_ben_or(h, 17, ZZ) is False + + assert gf_irred_p_rabin(f, 17, ZZ) is True + assert gf_irred_p_rabin(g, 17, ZZ) is True + + assert gf_irred_p_rabin(h, 17, ZZ) is False + + +def test_gf_squarefree(): + assert gf_sqf_list([], 11, ZZ) == (0, []) + assert gf_sqf_list([1], 11, ZZ) == (1, []) + assert gf_sqf_list([1, 1], 11, ZZ) == (1, [([1, 1], 1)]) + + assert gf_sqf_p([], 11, ZZ) is True + assert gf_sqf_p([1], 11, ZZ) is True + assert gf_sqf_p([1, 1], 11, ZZ) is True + + f = gf_from_dict({11: 1, 0: 1}, 11, ZZ) + + assert gf_sqf_p(f, 11, ZZ) is False + + assert gf_sqf_list(f, 11, ZZ) == \ + (1, [([1, 1], 11)]) + + f = [1, 5, 8, 4] + + assert gf_sqf_p(f, 11, ZZ) is False + + assert gf_sqf_list(f, 11, ZZ) == \ + (1, [([1, 1], 1), + ([1, 2], 2)]) + + assert gf_sqf_part(f, 11, ZZ) == [1, 3, 2] + + f = [1, 0, 0, 2, 0, 0, 2, 0, 0, 1, 0] + + assert gf_sqf_list(f, 3, ZZ) == \ + (1, [([1, 0], 1), + ([1, 1], 3), + ([1, 2], 6)]) + +def test_gf_frobenius_map(): + f = ZZ.map([2, 0, 1, 0, 2, 2, 0, 2, 2, 2]) + g = ZZ.map([1,1,0,2,0,1,0,2,0,1]) + p = 3 + b = gf_frobenius_monomial_base(g, p, ZZ) + h = gf_frobenius_map(f, g, b, p, ZZ) + h1 = gf_pow_mod(f, p, g, p, ZZ) + assert h == h1 + + +def test_gf_berlekamp(): + f = gf_from_int_poly([1, -3, 1, -3, -1, -3, 1], 11) + + Q = [[1, 0, 0, 0, 0, 0], + [3, 5, 8, 8, 6, 5], + [3, 6, 6, 1, 10, 0], + [9, 4, 10, 3, 7, 9], + [7, 8, 10, 0, 0, 8], + [8, 10, 7, 8, 10, 8]] + + V = [[1, 0, 0, 0, 0, 0], + [0, 1, 1, 1, 1, 0], + [0, 0, 7, 9, 0, 1]] + + assert gf_Qmatrix(f, 11, ZZ) == Q + assert gf_Qbasis(Q, 11, ZZ) == V + + assert gf_berlekamp(f, 11, ZZ) == \ + [[1, 1], [1, 5, 3], [1, 2, 3, 4]] + + f = ZZ.map([1, 0, 1, 0, 10, 10, 8, 2, 8]) + + Q = ZZ.map([[1, 0, 0, 0, 0, 0, 0, 0], + [2, 1, 7, 11, 10, 12, 5, 11], + [3, 6, 4, 3, 0, 4, 7, 2], + [4, 3, 6, 5, 1, 6, 2, 3], + [2, 11, 8, 8, 3, 1, 3, 11], + [6, 11, 8, 6, 2, 7, 10, 9], + [5, 11, 7, 10, 0, 11, 7, 12], + [3, 3, 12, 5, 0, 11, 9, 12]]) + + V = [[1, 0, 0, 0, 0, 0, 0, 0], + [0, 5, 5, 0, 9, 5, 1, 0], + [0, 9, 11, 9, 10, 12, 0, 1]] + + assert gf_Qmatrix(f, 13, ZZ) == Q + assert gf_Qbasis(Q, 13, ZZ) == V + + assert gf_berlekamp(f, 13, ZZ) == \ + [[1, 3], [1, 8, 4, 12], [1, 2, 3, 4, 6]] + + +def test_gf_ddf(): + f = gf_from_dict({15: ZZ(1), 0: ZZ(-1)}, 11, ZZ) + g = [([1, 0, 0, 0, 0, 10], 1), + ([1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1], 2)] + + assert gf_ddf_zassenhaus(f, 11, ZZ) == g + assert gf_ddf_shoup(f, 11, ZZ) == g + + f = gf_from_dict({63: ZZ(1), 0: ZZ(1)}, 2, ZZ) + g = [([1, 1], 1), + ([1, 1, 1], 2), + ([1, 1, 1, 1, 1, 1, 1], 3), + ([1, 1, 0, 1, 1, 0, 1, 0, 1, 1, 0, 1, 1, 0, 0, 0, 0, 0, 0, + 0, 0, 1, 1, 0, 1, 1, 0, 1, 0, 1, 1, 0, 1, 1, 0, 0, 0, 0, + 0, 0, 0, 0, 1, 1, 0, 1, 1, 0, 1, 0, 1, 1, 0, 1, 1], 6)] + + assert gf_ddf_zassenhaus(f, 2, ZZ) == g + assert gf_ddf_shoup(f, 2, ZZ) == g + + f = gf_from_dict({6: ZZ(1), 5: ZZ(-1), 4: ZZ(1), 3: ZZ(1), 1: ZZ(-1)}, 3, ZZ) + g = [([1, 1, 0], 1), + ([1, 1, 0, 1, 2], 2)] + + assert gf_ddf_zassenhaus(f, 3, ZZ) == g + assert gf_ddf_shoup(f, 3, ZZ) == g + + f = ZZ.map([1, 2, 5, 26, 677, 436, 791, 325, 456, 24, 577]) + g = [([1, 701], 1), + ([1, 110, 559, 532, 694, 151, 110, 70, 735, 122], 9)] + + assert gf_ddf_zassenhaus(f, 809, ZZ) == g + assert gf_ddf_shoup(f, 809, ZZ) == g + + p = ZZ(nextprime(int((2**15 * pi).evalf()))) + f = gf_from_dict({15: 1, 1: 1, 0: 1}, p, ZZ) + g = [([1, 22730, 68144], 2), + ([1, 64876, 83977, 10787, 12561, 68608, 52650, 88001, 84356], 4), + ([1, 15347, 95022, 84569, 94508, 92335], 5)] + + assert gf_ddf_zassenhaus(f, p, ZZ) == g + assert gf_ddf_shoup(f, p, ZZ) == g + + +def test_gf_edf(): + f = ZZ.map([1, 1, 0, 1, 2]) + g = ZZ.map([[1, 0, 1], [1, 1, 2]]) + + assert gf_edf_zassenhaus(f, 2, 3, ZZ) == g + assert gf_edf_shoup(f, 2, 3, ZZ) == g + + +def test_issue_23174(): + f = ZZ.map([1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]) + g = ZZ.map([[1, 0, 0, 1, 1, 1, 0, 0, 1], [1, 1, 1, 0, 1, 0, 1, 1, 1]]) + + assert gf_edf_zassenhaus(f, 8, 2, ZZ) == g + + +def test_gf_factor(): + assert gf_factor([], 11, ZZ) == (0, []) + assert gf_factor([1], 11, ZZ) == (1, []) + assert gf_factor([1, 1], 11, ZZ) == (1, [([1, 1], 1)]) + + assert gf_factor_sqf([], 11, ZZ) == (0, []) + assert gf_factor_sqf([1], 11, ZZ) == (1, []) + assert gf_factor_sqf([1, 1], 11, ZZ) == (1, [[1, 1]]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + + assert gf_factor_sqf([], 11, ZZ) == (0, []) + assert gf_factor_sqf([1], 11, ZZ) == (1, []) + assert gf_factor_sqf([1, 1], 11, ZZ) == (1, [[1, 1]]) + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + + assert gf_factor_sqf([], 11, ZZ) == (0, []) + assert gf_factor_sqf([1], 11, ZZ) == (1, []) + assert gf_factor_sqf([1, 1], 11, ZZ) == (1, [[1, 1]]) + + config.setup('GF_FACTOR_METHOD', 'shoup') + + assert gf_factor_sqf(ZZ.map([]), 11, ZZ) == (0, []) + assert gf_factor_sqf(ZZ.map([1]), 11, ZZ) == (1, []) + assert gf_factor_sqf(ZZ.map([1, 1]), 11, ZZ) == (1, [[1, 1]]) + + f, p = ZZ.map([1, 0, 0, 1, 0]), 2 + + g = (1, [([1, 0], 1), + ([1, 1], 1), + ([1, 1, 1], 1)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + g = (1, [[1, 0], + [1, 1], + [1, 1, 1]]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor_sqf(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor_sqf(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor_sqf(f, p, ZZ) == g + + f, p = gf_from_int_poly([1, -3, 1, -3, -1, -3, 1], 11), 11 + + g = (1, [([1, 1], 1), + ([1, 5, 3], 1), + ([1, 2, 3, 4], 1)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + f, p = [1, 5, 8, 4], 11 + + g = (1, [([1, 1], 1), ([1, 2], 2)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + f, p = [1, 1, 10, 1, 0, 10, 10, 10, 0, 0], 11 + + g = (1, [([1, 0], 2), ([1, 9, 5], 1), ([1, 3, 0, 8, 5, 2], 1)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + f, p = gf_from_dict({32: 1, 0: 1}, 11, ZZ), 11 + + g = (1, [([1, 0, 0, 0, 0, 0, 0, 0, 3, 0, 0, 0, 0, 0, 0, 0, 10], 1), + ([1, 0, 0, 0, 0, 0, 0, 0, 8, 0, 0, 0, 0, 0, 0, 0, 10], 1)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + f, p = gf_from_dict({32: ZZ(8), 0: ZZ(5)}, 11, ZZ), 11 + + g = (8, [([1, 3], 1), + ([1, 8], 1), + ([1, 0, 9], 1), + ([1, 2, 2], 1), + ([1, 9, 2], 1), + ([1, 0, 5, 0, 7], 1), + ([1, 0, 6, 0, 7], 1), + ([1, 0, 0, 0, 1, 0, 0, 0, 6], 1), + ([1, 0, 0, 0, 10, 0, 0, 0, 6], 1)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + f, p = gf_from_dict({63: ZZ(8), 0: ZZ(5)}, 11, ZZ), 11 + + g = (8, [([1, 7], 1), + ([1, 4, 5], 1), + ([1, 6, 8, 2], 1), + ([1, 9, 9, 2], 1), + ([1, 0, 0, 9, 0, 0, 4], 1), + ([1, 2, 0, 8, 4, 6, 4], 1), + ([1, 2, 3, 8, 0, 6, 4], 1), + ([1, 2, 6, 0, 8, 4, 4], 1), + ([1, 3, 3, 1, 6, 8, 4], 1), + ([1, 5, 6, 0, 8, 6, 4], 1), + ([1, 6, 2, 7, 9, 8, 4], 1), + ([1, 10, 4, 7, 10, 7, 4], 1), + ([1, 10, 10, 1, 4, 9, 4], 1)]) + + config.setup('GF_FACTOR_METHOD', 'berlekamp') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + # Gathen polynomials: x**n + x + 1 (mod p > 2**n * pi) + + p = ZZ(nextprime(int((2**15 * pi).evalf()))) + f = gf_from_dict({15: 1, 1: 1, 0: 1}, p, ZZ) + + assert gf_sqf_p(f, p, ZZ) is True + + g = (1, [([1, 22730, 68144], 1), + ([1, 81553, 77449, 86810, 4724], 1), + ([1, 86276, 56779, 14859, 31575], 1), + ([1, 15347, 95022, 84569, 94508, 92335], 1)]) + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + g = (1, [[1, 22730, 68144], + [1, 81553, 77449, 86810, 4724], + [1, 86276, 56779, 14859, 31575], + [1, 15347, 95022, 84569, 94508, 92335]]) + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor_sqf(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor_sqf(f, p, ZZ) == g + + # Shoup polynomials: f = a_0 x**n + a_1 x**(n-1) + ... + a_n + # (mod p > 2**(n-2) * pi), where a_n = a_{n-1}**2 + 1, a_0 = 1 + + p = ZZ(nextprime(int((2**4 * pi).evalf()))) + f = ZZ.map([1, 2, 5, 26, 41, 39, 38]) + + assert gf_sqf_p(f, p, ZZ) is True + + g = (1, [([1, 44, 26], 1), + ([1, 11, 25, 18, 30], 1)]) + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor(f, p, ZZ) == g + + g = (1, [[1, 44, 26], + [1, 11, 25, 18, 30]]) + + config.setup('GF_FACTOR_METHOD', 'zassenhaus') + assert gf_factor_sqf(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'shoup') + assert gf_factor_sqf(f, p, ZZ) == g + + config.setup('GF_FACTOR_METHOD', 'other') + raises(KeyError, lambda: gf_factor([1, 1], 11, ZZ)) + config.setup('GF_FACTOR_METHOD') + + +def test_gf_csolve(): + assert gf_value([1, 7, 2, 4], 11) == 2204 + + assert linear_congruence(4, 3, 5) == [2] + assert linear_congruence(0, 3, 5) == [] + assert linear_congruence(6, 1, 4) == [] + assert linear_congruence(0, 5, 5) == [0, 1, 2, 3, 4] + assert linear_congruence(3, 12, 15) == [4, 9, 14] + assert linear_congruence(6, 0, 18) == [0, 3, 6, 9, 12, 15] + # _csolve_prime_las_vegas + assert _csolve_prime_las_vegas([2, 3, 1], 5) == [2, 4] + assert _csolve_prime_las_vegas([2, 0, 1], 5) == [] + from sympy.ntheory import primerange + for p in primerange(2, 100): + # f = x**(p-1) - 1 + f = gf_sub_ground(gf_pow([1, 0], p - 1, p, ZZ), 1, p, ZZ) + assert _csolve_prime_las_vegas(f, p) == list(range(1, p)) + # with power = 1 + assert csolve_prime([1, 3, 2, 17], 7) == [3] + assert csolve_prime([1, 3, 1, 5], 5) == [0, 1] + assert csolve_prime([3, 6, 9, 3], 3) == [0, 1, 2] + # with power > 1 + assert csolve_prime( + [1, 1, 223], 3, 4) == [4, 13, 22, 31, 40, 49, 58, 67, 76] + assert csolve_prime([3, 5, 2, 25], 5, 3) == [16, 50, 99] + assert csolve_prime([3, 2, 2, 49], 7, 3) == [147, 190, 234] + + assert gf_csolve([1, 1, 7], 189) == [13, 49, 76, 112, 139, 175] + assert gf_csolve([1, 3, 4, 1, 30], 60) == [10, 30] + assert gf_csolve([1, 1, 7], 15) == [] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_groebnertools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_groebnertools.py new file mode 100644 index 0000000000000000000000000000000000000000..b7d0fc112047ac26f67d096db02eb8a1c91cab89 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_groebnertools.py @@ -0,0 +1,533 @@ +"""Tests for Groebner bases. """ + +from sympy.polys.groebnertools import ( + groebner, sig, sig_key, + lbp, lbp_key, critical_pair, + cp_key, is_rewritable_or_comparable, + Sign, Polyn, Num, s_poly, f5_reduce, + groebner_lcm, groebner_gcd, is_groebner, + is_reduced +) + +from sympy.polys.fglmtools import _representing_matrices +from sympy.polys.orderings import lex, grlex + +from sympy.polys.rings import ring, xring +from sympy.polys.domains import ZZ, QQ + +from sympy.testing.pytest import slow +from sympy.polys import polyconfig as config + +def _do_test_groebner(): + R, x,y = ring("x,y", QQ, lex) + f = x**2 + 2*x*y**2 + g = x*y + 2*y**3 - 1 + + assert groebner([f, g], R) == [x, y**3 - QQ(1,2)] + + R, y,x = ring("y,x", QQ, lex) + f = 2*x**2*y + y**2 + g = 2*x**3 + x*y - 1 + + assert groebner([f, g], R) == [y, x**3 - QQ(1,2)] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = x - z**2 + g = y - z**3 + + assert groebner([f, g], R) == [f, g] + + R, x,y = ring("x,y", QQ, grlex) + f = x**3 - 2*x*y + g = x**2*y + x - 2*y**2 + + assert groebner([f, g], R) == [x**2, x*y, -QQ(1,2)*x + y**2] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = -x**2 + y + g = -x**3 + z + + assert groebner([f, g], R) == [x**2 - y, x*y - z, x*z - y**2, y**3 - z**2] + + R, x,y,z = ring("x,y,z", QQ, grlex) + f = -x**2 + y + g = -x**3 + z + + assert groebner([f, g], R) == [y**3 - z**2, x**2 - y, x*y - z, x*z - y**2] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = -x**2 + z + g = -x**3 + y + + assert groebner([f, g], R) == [x**2 - z, x*y - z**2, x*z - y, y**2 - z**3] + + R, x,y,z = ring("x,y,z", QQ, grlex) + f = -x**2 + z + g = -x**3 + y + + assert groebner([f, g], R) == [-y**2 + z**3, x**2 - z, x*y - z**2, x*z - y] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = x - y**2 + g = -y**3 + z + + assert groebner([f, g], R) == [x - y**2, y**3 - z] + + R, x,y,z = ring("x,y,z", QQ, grlex) + f = x - y**2 + g = -y**3 + z + + assert groebner([f, g], R) == [x**2 - y*z, x*y - z, -x + y**2] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = x - z**2 + g = y - z**3 + + assert groebner([f, g], R) == [x - z**2, y - z**3] + + R, x,y,z = ring("x,y,z", QQ, grlex) + f = x - z**2 + g = y - z**3 + + assert groebner([f, g], R) == [x**2 - y*z, x*z - y, -x + z**2] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = -y**2 + z + g = x - y**3 + + assert groebner([f, g], R) == [x - y*z, y**2 - z] + + R, x,y,z = ring("x,y,z", QQ, grlex) + f = -y**2 + z + g = x - y**3 + + assert groebner([f, g], R) == [-x**2 + z**3, x*y - z**2, y**2 - z, -x + y*z] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = y - z**2 + g = x - z**3 + + assert groebner([f, g], R) == [x - z**3, y - z**2] + + R, x,y,z = ring("x,y,z", QQ, grlex) + f = y - z**2 + g = x - z**3 + + assert groebner([f, g], R) == [-x**2 + y**3, x*z - y**2, -x + y*z, -y + z**2] + + R, x,y,z = ring("x,y,z", QQ, lex) + f = 4*x**2*y**2 + 4*x*y + 1 + g = x**2 + y**2 - 1 + + assert groebner([f, g], R) == [ + x - 4*y**7 + 8*y**5 - 7*y**3 + 3*y, + y**8 - 2*y**6 + QQ(3,2)*y**4 - QQ(1,2)*y**2 + QQ(1,16), + ] + +def test_groebner_buchberger(): + with config.using(groebner='buchberger'): + _do_test_groebner() + +def test_groebner_f5b(): + with config.using(groebner='f5b'): + _do_test_groebner() + +def _do_test_benchmark_minpoly(): + R, x,y,z = ring("x,y,z", QQ, lex) + + F = [x**3 + x + 1, y**2 + y + 1, (x + y) * z - (x**2 + y)] + G = [x + QQ(155,2067)*z**5 - QQ(355,689)*z**4 + QQ(6062,2067)*z**3 - QQ(3687,689)*z**2 + QQ(6878,2067)*z - QQ(25,53), + y + QQ(4,53)*z**5 - QQ(91,159)*z**4 + QQ(523,159)*z**3 - QQ(387,53)*z**2 + QQ(1043,159)*z - QQ(308,159), + z**6 - 7*z**5 + 41*z**4 - 82*z**3 + 89*z**2 - 46*z + 13] + + assert groebner(F, R) == G + +def test_benchmark_minpoly_buchberger(): + with config.using(groebner='buchberger'): + _do_test_benchmark_minpoly() + +def test_benchmark_minpoly_f5b(): + with config.using(groebner='f5b'): + _do_test_benchmark_minpoly() + + +def test_benchmark_coloring(): + V = range(1, 12 + 1) + E = [(1, 2), (2, 3), (1, 4), (1, 6), (1, 12), (2, 5), (2, 7), (3, 8), (3, 10), + (4, 11), (4, 9), (5, 6), (6, 7), (7, 8), (8, 9), (9, 10), (10, 11), + (11, 12), (5, 12), (5, 9), (6, 10), (7, 11), (8, 12), (3, 4)] + + R, V = xring([ "x%d" % v for v in V ], QQ, lex) + E = [(V[i - 1], V[j - 1]) for i, j in E] + + x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12 = V + + I3 = [x**3 - 1 for x in V] + Ig = [x**2 + x*y + y**2 for x, y in E] + + I = I3 + Ig + + assert groebner(I[:-1], R) == [ + x1 + x11 + x12, + x2 - x11, + x3 - x12, + x4 - x12, + x5 + x11 + x12, + x6 - x11, + x7 - x12, + x8 + x11 + x12, + x9 - x11, + x10 + x11 + x12, + x11**2 + x11*x12 + x12**2, + x12**3 - 1, + ] + + assert groebner(I, R) == [1] + + +def _do_test_benchmark_katsura_3(): + R, x0,x1,x2 = ring("x:3", ZZ, lex) + I = [x0 + 2*x1 + 2*x2 - 1, + x0**2 + 2*x1**2 + 2*x2**2 - x0, + 2*x0*x1 + 2*x1*x2 - x1] + + assert groebner(I, R) == [ + -7 + 7*x0 + 8*x2 + 158*x2**2 - 420*x2**3, + 7*x1 + 3*x2 - 79*x2**2 + 210*x2**3, + x2 + x2**2 - 40*x2**3 + 84*x2**4, + ] + + R, x0,x1,x2 = ring("x:3", ZZ, grlex) + I = [ i.set_ring(R) for i in I ] + + assert groebner(I, R) == [ + 7*x1 + 3*x2 - 79*x2**2 + 210*x2**3, + -x1 + x2 - 3*x2**2 + 5*x1**2, + -x1 - 4*x2 + 10*x1*x2 + 12*x2**2, + -1 + x0 + 2*x1 + 2*x2, + ] + +def test_benchmark_katsura3_buchberger(): + with config.using(groebner='buchberger'): + _do_test_benchmark_katsura_3() + +def test_benchmark_katsura3_f5b(): + with config.using(groebner='f5b'): + _do_test_benchmark_katsura_3() + +def _do_test_benchmark_katsura_4(): + R, x0,x1,x2,x3 = ring("x:4", ZZ, lex) + I = [x0 + 2*x1 + 2*x2 + 2*x3 - 1, + x0**2 + 2*x1**2 + 2*x2**2 + 2*x3**2 - x0, + 2*x0*x1 + 2*x1*x2 + 2*x2*x3 - x1, + x1**2 + 2*x0*x2 + 2*x1*x3 - x2] + + assert groebner(I, R) == [ + 5913075*x0 - 159690237696*x3**7 + 31246269696*x3**6 + 27439610544*x3**5 - 6475723368*x3**4 - 838935856*x3**3 + 275119624*x3**2 + 4884038*x3 - 5913075, + 1971025*x1 - 97197721632*x3**7 + 73975630752*x3**6 - 12121915032*x3**5 - 2760941496*x3**4 + 814792828*x3**3 - 1678512*x3**2 - 9158924*x3, + 5913075*x2 + 371438283744*x3**7 - 237550027104*x3**6 + 22645939824*x3**5 + 11520686172*x3**4 - 2024910556*x3**3 - 132524276*x3**2 + 30947828*x3, + 128304*x3**8 - 93312*x3**7 + 15552*x3**6 + 3144*x3**5 - + 1120*x3**4 + 36*x3**3 + 15*x3**2 - x3, + ] + + R, x0,x1,x2,x3 = ring("x:4", ZZ, grlex) + I = [ i.set_ring(R) for i in I ] + + assert groebner(I, R) == [ + 393*x1 - 4662*x2**2 + 4462*x2*x3 - 59*x2 + 224532*x3**4 - 91224*x3**3 - 678*x3**2 + 2046*x3, + -x1 + 196*x2**3 - 21*x2**2 + 60*x2*x3 - 18*x2 - 168*x3**3 + 83*x3**2 - 9*x3, + -6*x1 + 1134*x2**2*x3 - 189*x2**2 - 466*x2*x3 + 32*x2 - 630*x3**3 + 57*x3**2 + 51*x3, + 33*x1 + 63*x2**2 + 2268*x2*x3**2 - 188*x2*x3 + 34*x2 + 2520*x3**3 - 849*x3**2 + 3*x3, + 7*x1**2 - x1 - 7*x2**2 - 24*x2*x3 + 3*x2 - 15*x3**2 + 5*x3, + 14*x1*x2 - x1 + 14*x2**2 + 18*x2*x3 - 4*x2 + 6*x3**2 - 2*x3, + 14*x1*x3 - x1 + 7*x2**2 + 32*x2*x3 - 4*x2 + 27*x3**2 - 9*x3, + x0 + 2*x1 + 2*x2 + 2*x3 - 1, + ] + +def test_benchmark_kastura_4_buchberger(): + with config.using(groebner='buchberger'): + _do_test_benchmark_katsura_4() + +def test_benchmark_kastura_4_f5b(): + with config.using(groebner='f5b'): + _do_test_benchmark_katsura_4() + +def _do_test_benchmark_czichowski(): + R, x,t = ring("x,t", ZZ, lex) + I = [9*x**8 + 36*x**7 - 32*x**6 - 252*x**5 - 78*x**4 + 468*x**3 + 288*x**2 - 108*x + 9, + (-72 - 72*t)*x**7 + (-256 - 252*t)*x**6 + (192 + 192*t)*x**5 + (1280 + 1260*t)*x**4 + (312 + 312*t)*x**3 + (-404*t)*x**2 + (-576 - 576*t)*x + 96 + 108*t] + + assert groebner(I, R) == [ + 3725588592068034903797967297424801242396746870413359539263038139343329273586196480000*x - + 160420835591776763325581422211936558925462474417709511019228211783493866564923546661604487873*t**7 - + 1406108495478033395547109582678806497509499966197028487131115097902188374051595011248311352864*t**6 - + 5241326875850889518164640374668786338033653548841427557880599579174438246266263602956254030352*t**5 - + 10758917262823299139373269714910672770004760114329943852726887632013485035262879510837043892416*t**4 - + 13119383576444715672578819534846747735372132018341964647712009275306635391456880068261130581248*t**3 - + 9491412317016197146080450036267011389660653495578680036574753839055748080962214787557853941760*t**2 - + 3767520915562795326943800040277726397326609797172964377014046018280260848046603967211258368000*t - + 632314652371226552085897259159210286886724229880266931574701654721512325555116066073245696000, + 610733380717522355121*t**8 + + 6243748742141230639968*t**7 + + 27761407182086143225024*t**6 + + 70066148869420956398592*t**5 + + 109701225644313784229376*t**4 + + 109009005495588442152960*t**3 + + 67072101084384786432000*t**2 + + 23339979742629593088000*t + + 3513592776846090240000, + ] + + R, x,t = ring("x,t", ZZ, grlex) + I = [ i.set_ring(R) for i in I ] + + assert groebner(I, R) == [ + 16996618586000601590732959134095643086442*t**3*x - + 32936701459297092865176560282688198064839*t**3 + + 78592411049800639484139414821529525782364*t**2*x - + 120753953358671750165454009478961405619916*t**2 + + 120988399875140799712152158915653654637280*t*x - + 144576390266626470824138354942076045758736*t + + 60017634054270480831259316163620768960*x**2 + + 61976058033571109604821862786675242894400*x - + 56266268491293858791834120380427754600960, + 576689018321912327136790519059646508441672750656050290242749*t**4 + + 2326673103677477425562248201573604572527893938459296513327336*t**3 + + 110743790416688497407826310048520299245819959064297990236000*t**2*x + + 3308669114229100853338245486174247752683277925010505284338016*t**2 + + 323150205645687941261103426627818874426097912639158572428800*t*x + + 1914335199925152083917206349978534224695445819017286960055680*t + + 861662882561803377986838989464278045397192862768588480000*x**2 + + 235296483281783440197069672204341465480107019878814196672000*x + + 361850798943225141738895123621685122544503614946436727532800, + -117584925286448670474763406733005510014188341867*t**3 + + 68566565876066068463853874568722190223721653044*t**2*x - + 435970731348366266878180788833437896139920683940*t**2 + + 196297602447033751918195568051376792491869233408*t*x - + 525011527660010557871349062870980202067479780112*t + + 517905853447200553360289634770487684447317120*x**3 + + 569119014870778921949288951688799397569321920*x**2 + + 138877356748142786670127389526667463202210102080*x - + 205109210539096046121625447192779783475018619520, + -3725142681462373002731339445216700112264527*t**3 + + 583711207282060457652784180668273817487940*t**2*x - + 12381382393074485225164741437227437062814908*t**2 + + 151081054097783125250959636747516827435040*t*x**2 + + 1814103857455163948531448580501928933873280*t*x - + 13353115629395094645843682074271212731433648*t + + 236415091385250007660606958022544983766080*x**2 + + 1390443278862804663728298060085399578417600*x - + 4716885828494075789338754454248931750698880, + ] + +# NOTE: This is very slow (> 2 minutes on 3.4 GHz) without GMPY +@slow +def test_benchmark_czichowski_buchberger(): + with config.using(groebner='buchberger'): + _do_test_benchmark_czichowski() + +def test_benchmark_czichowski_f5b(): + with config.using(groebner='f5b'): + _do_test_benchmark_czichowski() + +def _do_test_benchmark_cyclic_4(): + R, a,b,c,d = ring("a,b,c,d", ZZ, lex) + + I = [a + b + c + d, + a*b + a*d + b*c + b*d, + a*b*c + a*b*d + a*c*d + b*c*d, + a*b*c*d - 1] + + assert groebner(I, R) == [ + 4*a + 3*d**9 - 4*d**5 - 3*d, + 4*b + 4*c - 3*d**9 + 4*d**5 + 7*d, + 4*c**2 + 3*d**10 - 4*d**6 - 3*d**2, + 4*c*d**4 + 4*c - d**9 + 4*d**5 + 5*d, d**12 - d**8 - d**4 + 1 + ] + + R, a,b,c,d = ring("a,b,c,d", ZZ, grlex) + I = [ i.set_ring(R) for i in I ] + + assert groebner(I, R) == [ + 3*b*c - c**2 + d**6 - 3*d**2, + -b + 3*c**2*d**3 - c - d**5 - 4*d, + -b + 3*c*d**4 + 2*c + 2*d**5 + 2*d, + c**4 + 2*c**2*d**2 - d**4 - 2, + c**3*d + c*d**3 + d**4 + 1, + b*c**2 - c**3 - c**2*d - 2*c*d**2 - d**3, + b**2 - c**2, b*d + c**2 + c*d + d**2, + a + b + c + d + ] + +def test_benchmark_cyclic_4_buchberger(): + with config.using(groebner='buchberger'): + _do_test_benchmark_cyclic_4() + +def test_benchmark_cyclic_4_f5b(): + with config.using(groebner='f5b'): + _do_test_benchmark_cyclic_4() + +def test_sig_key(): + s1 = sig((0,) * 3, 2) + s2 = sig((1,) * 3, 4) + s3 = sig((2,) * 3, 2) + + assert sig_key(s1, lex) > sig_key(s2, lex) + assert sig_key(s2, lex) < sig_key(s3, lex) + + +def test_lbp_key(): + R, x,y,z,t = ring("x,y,z,t", ZZ, lex) + + p1 = lbp(sig((0,) * 4, 3), R.zero, 12) + p2 = lbp(sig((0,) * 4, 4), R.zero, 13) + p3 = lbp(sig((0,) * 4, 4), R.zero, 12) + + assert lbp_key(p1) > lbp_key(p2) + assert lbp_key(p2) < lbp_key(p3) + + +def test_critical_pair(): + # from cyclic4 with grlex + R, x,y,z,t = ring("x,y,z,t", QQ, grlex) + + p1 = (((0, 0, 0, 0), 4), y*z*t**2 + z**2*t**2 - t**4 - 1, 4) + q1 = (((0, 0, 0, 0), 2), -y**2 - y*t - z*t - t**2, 2) + + p2 = (((0, 0, 0, 2), 3), z**3*t**2 + z**2*t**3 - z - t, 5) + q2 = (((0, 0, 2, 2), 2), y*z + z*t**5 + z*t + t**6, 13) + + assert critical_pair(p1, q1, R) == ( + ((0, 0, 1, 2), 2), ((0, 0, 1, 2), QQ(-1, 1)), (((0, 0, 0, 0), 2), -y**2 - y*t - z*t - t**2, 2), + ((0, 1, 0, 0), 4), ((0, 1, 0, 0), QQ(1, 1)), (((0, 0, 0, 0), 4), y*z*t**2 + z**2*t**2 - t**4 - 1, 4) + ) + assert critical_pair(p2, q2, R) == ( + ((0, 0, 4, 2), 2), ((0, 0, 2, 0), QQ(1, 1)), (((0, 0, 2, 2), 2), y*z + z*t**5 + z*t + t**6, 13), + ((0, 0, 0, 5), 3), ((0, 0, 0, 3), QQ(1, 1)), (((0, 0, 0, 2), 3), z**3*t**2 + z**2*t**3 - z - t, 5) + ) + +def test_cp_key(): + # from cyclic4 with grlex + R, x,y,z,t = ring("x,y,z,t", QQ, grlex) + + p1 = (((0, 0, 0, 0), 4), y*z*t**2 + z**2*t**2 - t**4 - 1, 4) + q1 = (((0, 0, 0, 0), 2), -y**2 - y*t - z*t - t**2, 2) + + p2 = (((0, 0, 0, 2), 3), z**3*t**2 + z**2*t**3 - z - t, 5) + q2 = (((0, 0, 2, 2), 2), y*z + z*t**5 + z*t + t**6, 13) + + cp1 = critical_pair(p1, q1, R) + cp2 = critical_pair(p2, q2, R) + + assert cp_key(cp1, R) < cp_key(cp2, R) + + cp1 = critical_pair(p1, p2, R) + cp2 = critical_pair(q1, q2, R) + + assert cp_key(cp1, R) < cp_key(cp2, R) + + +def test_is_rewritable_or_comparable(): + # from katsura4 with grlex + R, x,y,z,t = ring("x,y,z,t", QQ, grlex) + + p = lbp(sig((0, 0, 2, 1), 2), R.zero, 2) + B = [lbp(sig((0, 0, 0, 1), 2), QQ(2,45)*y**2 + QQ(1,5)*y*z + QQ(5,63)*y*t + z**2*t + QQ(4,45)*z**2 + QQ(76,35)*z*t**2 - QQ(32,105)*z*t + QQ(13,7)*t**3 - QQ(13,21)*t**2, 6)] + + # rewritable: + assert is_rewritable_or_comparable(Sign(p), Num(p), B) is True + + p = lbp(sig((0, 1, 1, 0), 2), R.zero, 7) + B = [lbp(sig((0, 0, 0, 0), 3), QQ(10,3)*y*z + QQ(4,3)*y*t - QQ(1,3)*y + 4*z**2 + QQ(22,3)*z*t - QQ(4,3)*z + 4*t**2 - QQ(4,3)*t, 3)] + + # comparable: + assert is_rewritable_or_comparable(Sign(p), Num(p), B) is True + + +def test_f5_reduce(): + # katsura3 with lex + R, x,y,z = ring("x,y,z", QQ, lex) + + F = [(((0, 0, 0), 1), x + 2*y + 2*z - 1, 1), + (((0, 0, 0), 2), 6*y**2 + 8*y*z - 2*y + 6*z**2 - 2*z, 2), + (((0, 0, 0), 3), QQ(10,3)*y*z - QQ(1,3)*y + 4*z**2 - QQ(4,3)*z, 3), + (((0, 0, 1), 2), y + 30*z**3 - QQ(79,7)*z**2 + QQ(3,7)*z, 4), + (((0, 0, 2), 2), z**4 - QQ(10,21)*z**3 + QQ(1,84)*z**2 + QQ(1,84)*z, 5)] + + cp = critical_pair(F[0], F[1], R) + s = s_poly(cp) + + assert f5_reduce(s, F) == (((0, 2, 0), 1), R.zero, 1) + + s = lbp(sig(Sign(s)[0], 100), Polyn(s), Num(s)) + assert f5_reduce(s, F) == s + + +def test_representing_matrices(): + R, x,y = ring("x,y", QQ, grlex) + + basis = [(0, 0), (0, 1), (1, 0), (1, 1)] + F = [x**2 - x - 3*y + 1, -2*x + y**2 + y - 1] + + assert _representing_matrices(basis, F, R) == [ + [[QQ(0, 1), QQ(0, 1),-QQ(1, 1), QQ(3, 1)], + [QQ(0, 1), QQ(0, 1), QQ(3, 1),-QQ(4, 1)], + [QQ(1, 1), QQ(0, 1), QQ(1, 1), QQ(6, 1)], + [QQ(0, 1), QQ(1, 1), QQ(0, 1), QQ(1, 1)]], + [[QQ(0, 1), QQ(1, 1), QQ(0, 1),-QQ(2, 1)], + [QQ(1, 1),-QQ(1, 1), QQ(0, 1), QQ(6, 1)], + [QQ(0, 1), QQ(2, 1), QQ(0, 1), QQ(3, 1)], + [QQ(0, 1), QQ(0, 1), QQ(1, 1),-QQ(1, 1)]]] + +def test_groebner_lcm(): + R, x,y,z = ring("x,y,z", ZZ) + + assert groebner_lcm(x**2 - y**2, x - y) == x**2 - y**2 + assert groebner_lcm(2*x**2 - 2*y**2, 2*x - 2*y) == 2*x**2 - 2*y**2 + + R, x,y,z = ring("x,y,z", QQ) + + assert groebner_lcm(x**2 - y**2, x - y) == x**2 - y**2 + assert groebner_lcm(2*x**2 - 2*y**2, 2*x - 2*y) == 2*x**2 - 2*y**2 + + R, x,y = ring("x,y", ZZ) + + assert groebner_lcm(x**2*y, x*y**2) == x**2*y**2 + + f = 2*x*y**5 - 3*x*y**4 - 2*x*y**3 + 3*x*y**2 + g = y**5 - 2*y**3 + y + h = 2*x*y**7 - 3*x*y**6 - 4*x*y**5 + 6*x*y**4 + 2*x*y**3 - 3*x*y**2 + + assert groebner_lcm(f, g) == h + + f = x**3 - 3*x**2*y - 9*x*y**2 - 5*y**3 + g = x**4 + 6*x**3*y + 12*x**2*y**2 + 10*x*y**3 + 3*y**4 + h = x**5 + x**4*y - 18*x**3*y**2 - 50*x**2*y**3 - 47*x*y**4 - 15*y**5 + + assert groebner_lcm(f, g) == h + +def test_groebner_gcd(): + R, x,y,z = ring("x,y,z", ZZ) + + assert groebner_gcd(x**2 - y**2, x - y) == x - y + assert groebner_gcd(2*x**2 - 2*y**2, 2*x - 2*y) == 2*x - 2*y + + R, x,y,z = ring("x,y,z", QQ) + + assert groebner_gcd(x**2 - y**2, x - y) == x - y + assert groebner_gcd(2*x**2 - 2*y**2, 2*x - 2*y) == x - y + +def test_is_groebner(): + R, x,y = ring("x,y", QQ, grlex) + valid_groebner = [x**2, x*y, -QQ(1,2)*x + y**2] + invalid_groebner = [x**3, x*y, -QQ(1,2)*x + y**2] + assert is_groebner(valid_groebner, R) is True + assert is_groebner(invalid_groebner, R) is False + +def test_is_reduced(): + R, x, y = ring("x,y", QQ, lex) + f = x**2 + 2*x*y**2 + g = x*y + 2*y**3 - 1 + assert is_reduced([f, g], R) == False + G = groebner([f, g], R) + assert is_reduced(G, R) == True diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_heuristicgcd.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_heuristicgcd.py new file mode 100644 index 0000000000000000000000000000000000000000..7ff6bd6ea4effbd49c5e942ea8925cfcca4ba162 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_heuristicgcd.py @@ -0,0 +1,152 @@ +from sympy.polys.rings import ring +from sympy.polys.domains import ZZ +from sympy.polys.heuristicgcd import heugcd + + +def test_heugcd_univariate_integers(): + R, x = ring("x", ZZ) + + f = x**4 + 8*x**3 + 21*x**2 + 22*x + 8 + g = x**3 + 6*x**2 + 11*x + 6 + + h = x**2 + 3*x + 2 + + cff = x**2 + 5*x + 4 + cfg = x + 3 + + assert heugcd(f, g) == (h, cff, cfg) + + f = x**4 - 4 + g = x**4 + 4*x**2 + 4 + + h = x**2 + 2 + + cff = x**2 - 2 + cfg = x**2 + 2 + + assert heugcd(f, g) == (h, cff, cfg) + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + h = 1 + + cff = f + cfg = g + + assert heugcd(f, g) == (h, cff, cfg) + + f = - 352518131239247345597970242177235495263669787845475025293906825864749649589178600387510272*x**49 \ + + 46818041807522713962450042363465092040687472354933295397472942006618953623327997952*x**42 \ + + 378182690892293941192071663536490788434899030680411695933646320291525827756032*x**35 \ + + 112806468807371824947796775491032386836656074179286744191026149539708928*x**28 \ + - 12278371209708240950316872681744825481125965781519138077173235712*x**21 \ + + 289127344604779611146960547954288113529690984687482920704*x**14 \ + + 19007977035740498977629742919480623972236450681*x**7 \ + + 311973482284542371301330321821976049 + + g = 365431878023781158602430064717380211405897160759702125019136*x**21 \ + + 197599133478719444145775798221171663643171734081650688*x**14 \ + - 9504116979659010018253915765478924103928886144*x**7 \ + - 311973482284542371301330321821976049 + + # TODO: assert heugcd(f, f.diff(x))[0] == g + + f = 1317378933230047068160*x + 2945748836994210856960 + g = 120352542776360960*x + 269116466014453760 + + h = 120352542776360960*x + 269116466014453760 + cff = 10946 + cfg = 1 + + assert heugcd(f, g) == (h, cff, cfg) + +def test_heugcd_multivariate_integers(): + R, x, y = ring("x,y", ZZ) + + f, g = 2*x**2 + 4*x + 2, x + 1 + assert heugcd(f, g) == (x + 1, 2*x + 2, 1) + + f, g = x + 1, 2*x**2 + 4*x + 2 + assert heugcd(f, g) == (x + 1, 1, 2*x + 2) + + R, x, y, z, u = ring("x,y,z,u", ZZ) + + f, g = u**2 + 2*u + 1, 2*u + 2 + assert heugcd(f, g) == (u + 1, u + 1, 2) + + f, g = z**2*u**2 + 2*z**2*u + z**2 + z*u + z, u**2 + 2*u + 1 + h, cff, cfg = u + 1, z**2*u + z**2 + z, u + 1 + + assert heugcd(f, g) == (h, cff, cfg) + assert heugcd(g, f) == (h, cfg, cff) + + R, x, y, z = ring("x,y,z", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, u, v = ring("x,y,z,u,v", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, u, v, a, b = ring("x,y,z,u,v,a,b", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, u, v, a, b, c, d = ring("x,y,z,u,v,a,b,c,d", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z = ring("x,y,z", ZZ) + + f, g, h = R.fateman_poly_F_2() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + f, g, h = R.fateman_poly_F_3() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, t = ring("x,y,z,t", ZZ) + + f, g, h = R.fateman_poly_F_3() + H, cff, cfg = heugcd(f, g) + + assert H == h and H*cff == f and H*cfg == g + + +def test_issue_10996(): + R, x, y, z = ring("x,y,z", ZZ) + + f = 12*x**6*y**7*z**3 - 3*x**4*y**9*z**3 + 12*x**3*y**5*z**4 + g = -48*x**7*y**8*z**3 + 12*x**5*y**10*z**3 - 48*x**5*y**7*z**2 + \ + 36*x**4*y**7*z - 48*x**4*y**6*z**4 + 12*x**3*y**9*z**2 - 48*x**3*y**4 \ + - 9*x**2*y**9*z - 48*x**2*y**5*z**3 + 12*x*y**6 + 36*x*y**5*z**2 - 48*y**2*z + + H, cff, cfg = heugcd(f, g) + + assert H == 12*x**3*y**4 - 3*x*y**6 + 12*y**2*z + assert H*cff == f and H*cfg == g + + +def test_issue_25793(): + R, x = ring("x", ZZ) + f = x - 4851 # failure starts for values more than 4850 + g = f*(2*x + 1) + H, cff, cfg = R.dup_zz_heu_gcd(f, g) + assert H == f + # needs a test for dmp, too, that fails in master before this change diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_hypothesis.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_hypothesis.py new file mode 100644 index 0000000000000000000000000000000000000000..78c2369179c3f0ea4d34b8a7868417506177e3c5 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_hypothesis.py @@ -0,0 +1,36 @@ +from hypothesis import given +from hypothesis import strategies as st +from sympy.abc import x +from sympy.polys.polytools import Poly + + +def polys(*, nonzero=False, domain="ZZ"): + # This is a simple strategy, but sufficient the tests below + elems = {"ZZ": st.integers(), "QQ": st.fractions()} + coeff_st = st.lists(elems[domain]) + if nonzero: + coeff_st = coeff_st.filter(any) + return st.builds(Poly, coeff_st, st.just(x), domain=st.just(domain)) + + +@given(f=polys(), g=polys(), r=polys()) +def test_gcd_hypothesis(f, g, r): + gcd_1 = f.gcd(g) + gcd_2 = g.gcd(f) + assert gcd_1 == gcd_2 + + # multiply by r + gcd_3 = g.gcd(f + r * g) + assert gcd_1 == gcd_3 + + +@given(f_z=polys(), g_z=polys(nonzero=True)) +def test_poly_hypothesis_integers(f_z, g_z): + remainder_z = f_z.rem(g_z) + assert g_z.degree() >= remainder_z.degree() or remainder_z.degree() == 0 + + +@given(f_q=polys(domain="QQ"), g_q=polys(nonzero=True, domain="QQ")) +def test_poly_hypothesis_rationals(f_q, g_q): + remainder_q = f_q.rem(g_q) + assert g_q.degree() >= remainder_q.degree() or remainder_q.degree() == 0 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_injections.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_injections.py new file mode 100644 index 0000000000000000000000000000000000000000..63a5537c94f00e52a3899c97f0d78bfadab78a67 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_injections.py @@ -0,0 +1,39 @@ +"""Tests for functions that inject symbols into the global namespace. """ + +from sympy.polys.rings import vring +from sympy.polys.fields import vfield +from sympy.polys.domains import QQ + +def test_vring(): + ns = {'vring':vring, 'QQ':QQ} + exec('R = vring("r", QQ)', ns) + exec('assert r == R.gens[0]', ns) + + exec('R = vring("rb rbb rcc rzz _rx", QQ)', ns) + exec('assert rb == R.gens[0]', ns) + exec('assert rbb == R.gens[1]', ns) + exec('assert rcc == R.gens[2]', ns) + exec('assert rzz == R.gens[3]', ns) + exec('assert _rx == R.gens[4]', ns) + + exec('R = vring(["rd", "re", "rfg"], QQ)', ns) + exec('assert rd == R.gens[0]', ns) + exec('assert re == R.gens[1]', ns) + exec('assert rfg == R.gens[2]', ns) + +def test_vfield(): + ns = {'vfield':vfield, 'QQ':QQ} + exec('F = vfield("f", QQ)', ns) + exec('assert f == F.gens[0]', ns) + + exec('F = vfield("fb fbb fcc fzz _fx", QQ)', ns) + exec('assert fb == F.gens[0]', ns) + exec('assert fbb == F.gens[1]', ns) + exec('assert fcc == F.gens[2]', ns) + exec('assert fzz == F.gens[3]', ns) + exec('assert _fx == F.gens[4]', ns) + + exec('F = vfield(["fd", "fe", "ffg"], QQ)', ns) + exec('assert fd == F.gens[0]', ns) + exec('assert fe == F.gens[1]', ns) + exec('assert ffg == F.gens[2]', ns) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_modulargcd.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_modulargcd.py new file mode 100644 index 0000000000000000000000000000000000000000..20510f59186524ed4008ade943fab526a9ae7194 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_modulargcd.py @@ -0,0 +1,325 @@ +from sympy.polys.rings import ring +from sympy.polys.domains import ZZ, QQ, AlgebraicField +from sympy.polys.modulargcd import ( + modgcd_univariate, + modgcd_bivariate, + _chinese_remainder_reconstruction_multivariate, + modgcd_multivariate, + _to_ZZ_poly, + _to_ANP_poly, + func_field_modgcd, + _func_field_modgcd_m) +from sympy.functions.elementary.miscellaneous import sqrt + + +def test_modgcd_univariate_integers(): + R, x = ring("x", ZZ) + + f, g = R.zero, R.zero + assert modgcd_univariate(f, g) == (0, 0, 0) + + f, g = R.zero, x + assert modgcd_univariate(f, g) == (x, 0, 1) + assert modgcd_univariate(g, f) == (x, 1, 0) + + f, g = R.zero, -x + assert modgcd_univariate(f, g) == (x, 0, -1) + assert modgcd_univariate(g, f) == (x, -1, 0) + + f, g = 2*x, R(2) + assert modgcd_univariate(f, g) == (2, x, 1) + + f, g = 2*x + 2, 6*x**2 - 6 + assert modgcd_univariate(f, g) == (2*x + 2, 1, 3*x - 3) + + f = x**4 + 8*x**3 + 21*x**2 + 22*x + 8 + g = x**3 + 6*x**2 + 11*x + 6 + + h = x**2 + 3*x + 2 + + cff = x**2 + 5*x + 4 + cfg = x + 3 + + assert modgcd_univariate(f, g) == (h, cff, cfg) + + f = x**4 - 4 + g = x**4 + 4*x**2 + 4 + + h = x**2 + 2 + + cff = x**2 - 2 + cfg = x**2 + 2 + + assert modgcd_univariate(f, g) == (h, cff, cfg) + + f = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + g = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + + h = 1 + + cff = f + cfg = g + + assert modgcd_univariate(f, g) == (h, cff, cfg) + + f = - 352518131239247345597970242177235495263669787845475025293906825864749649589178600387510272*x**49 \ + + 46818041807522713962450042363465092040687472354933295397472942006618953623327997952*x**42 \ + + 378182690892293941192071663536490788434899030680411695933646320291525827756032*x**35 \ + + 112806468807371824947796775491032386836656074179286744191026149539708928*x**28 \ + - 12278371209708240950316872681744825481125965781519138077173235712*x**21 \ + + 289127344604779611146960547954288113529690984687482920704*x**14 \ + + 19007977035740498977629742919480623972236450681*x**7 \ + + 311973482284542371301330321821976049 + + g = 365431878023781158602430064717380211405897160759702125019136*x**21 \ + + 197599133478719444145775798221171663643171734081650688*x**14 \ + - 9504116979659010018253915765478924103928886144*x**7 \ + - 311973482284542371301330321821976049 + + assert modgcd_univariate(f, f.diff(x))[0] == g + + f = 1317378933230047068160*x + 2945748836994210856960 + g = 120352542776360960*x + 269116466014453760 + + h = 120352542776360960*x + 269116466014453760 + cff = 10946 + cfg = 1 + + assert modgcd_univariate(f, g) == (h, cff, cfg) + + +def test_modgcd_bivariate_integers(): + R, x, y = ring("x,y", ZZ) + + f, g = R.zero, R.zero + assert modgcd_bivariate(f, g) == (0, 0, 0) + + f, g = 2*x, R(2) + assert modgcd_bivariate(f, g) == (2, x, 1) + + f, g = x + 2*y, x + y + assert modgcd_bivariate(f, g) == (1, f, g) + + f, g = x**2 + 2*x*y + y**2, x**3 + y**3 + assert modgcd_bivariate(f, g) == (x + y, x + y, x**2 - x*y + y**2) + + f, g = x*y**2 + 2*x*y + x, x*y**3 + x + assert modgcd_bivariate(f, g) == (x*y + x, y + 1, y**2 - y + 1) + + f, g = x**2*y**2 + x**2*y + 1, x*y**2 + x*y + 1 + assert modgcd_bivariate(f, g) == (1, f, g) + + f = 2*x*y**2 + 4*x*y + 2*x + y**2 + 2*y + 1 + g = 2*x*y**3 + 2*x + y**3 + 1 + assert modgcd_bivariate(f, g) == (2*x*y + 2*x + y + 1, y + 1, y**2 - y + 1) + + f, g = 2*x**2 + 4*x + 2, x + 1 + assert modgcd_bivariate(f, g) == (x + 1, 2*x + 2, 1) + + f, g = x + 1, 2*x**2 + 4*x + 2 + assert modgcd_bivariate(f, g) == (x + 1, 1, 2*x + 2) + + f = 2*x**2 + 4*x*y - 2*x - 4*y + g = x**2 + x - 2 + assert modgcd_bivariate(f, g) == (x - 1, 2*x + 4*y, x + 2) + + f = 2*x**2 + 2*x*y - 3*x - 3*y + g = 4*x*y - 2*x + 4*y**2 - 2*y + assert modgcd_bivariate(f, g) == (x + y, 2*x - 3, 4*y - 2) + + +def test_chinese_remainder(): + R, x, y = ring("x, y", ZZ) + p, q = 3, 5 + + hp = x**3*y - x**2 - 1 + hq = -x**3*y - 2*x*y**2 + 2 + + hpq = _chinese_remainder_reconstruction_multivariate(hp, hq, p, q) + + assert hpq.trunc_ground(p) == hp + assert hpq.trunc_ground(q) == hq + + T, z = ring("z", R) + p, q = 3, 7 + + hp = (x*y + 1)*z**2 + x + hq = (x**2 - 3*y)*z + 2 + + hpq = _chinese_remainder_reconstruction_multivariate(hp, hq, p, q) + + assert hpq.trunc_ground(p) == hp + assert hpq.trunc_ground(q) == hq + + +def test_modgcd_multivariate_integers(): + R, x, y = ring("x,y", ZZ) + + f, g = R.zero, R.zero + assert modgcd_multivariate(f, g) == (0, 0, 0) + + f, g = 2*x**2 + 4*x + 2, x + 1 + assert modgcd_multivariate(f, g) == (x + 1, 2*x + 2, 1) + + f, g = x + 1, 2*x**2 + 4*x + 2 + assert modgcd_multivariate(f, g) == (x + 1, 1, 2*x + 2) + + f = 2*x**2 + 2*x*y - 3*x - 3*y + g = 4*x*y - 2*x + 4*y**2 - 2*y + assert modgcd_multivariate(f, g) == (x + y, 2*x - 3, 4*y - 2) + + f, g = x*y**2 + 2*x*y + x, x*y**3 + x + assert modgcd_multivariate(f, g) == (x*y + x, y + 1, y**2 - y + 1) + + f, g = x**2*y**2 + x**2*y + 1, x*y**2 + x*y + 1 + assert modgcd_multivariate(f, g) == (1, f, g) + + f = x**4 + 8*x**3 + 21*x**2 + 22*x + 8 + g = x**3 + 6*x**2 + 11*x + 6 + + h = x**2 + 3*x + 2 + + cff = x**2 + 5*x + 4 + cfg = x + 3 + + assert modgcd_multivariate(f, g) == (h, cff, cfg) + + R, x, y, z, u = ring("x,y,z,u", ZZ) + + f, g = x + y + z, -x - y - z - u + assert modgcd_multivariate(f, g) == (1, f, g) + + f, g = u**2 + 2*u + 1, 2*u + 2 + assert modgcd_multivariate(f, g) == (u + 1, u + 1, 2) + + f, g = z**2*u**2 + 2*z**2*u + z**2 + z*u + z, u**2 + 2*u + 1 + h, cff, cfg = u + 1, z**2*u + z**2 + z, u + 1 + + assert modgcd_multivariate(f, g) == (h, cff, cfg) + assert modgcd_multivariate(g, f) == (h, cfg, cff) + + R, x, y, z = ring("x,y,z", ZZ) + + f, g = x - y*z, x - y*z + assert modgcd_multivariate(f, g) == (x - y*z, 1, 1) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, u, v = ring("x,y,z,u,v", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, u, v, a, b = ring("x,y,z,u,v,a,b", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, u, v, a, b, c, d = ring("x,y,z,u,v,a,b,c,d", ZZ) + + f, g, h = R.fateman_poly_F_1() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z = ring("x,y,z", ZZ) + + f, g, h = R.fateman_poly_F_2() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + f, g, h = R.fateman_poly_F_3() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + R, x, y, z, t = ring("x,y,z,t", ZZ) + + f, g, h = R.fateman_poly_F_3() + H, cff, cfg = modgcd_multivariate(f, g) + + assert H == h and H*cff == f and H*cfg == g + + +def test_to_ZZ_ANP_poly(): + A = AlgebraicField(QQ, sqrt(2)) + R, x = ring("x", A) + f = x*(sqrt(2) + 1) + + T, x_, z_ = ring("x_, z_", ZZ) + f_ = x_*z_ + x_ + + assert _to_ZZ_poly(f, T) == f_ + assert _to_ANP_poly(f_, R) == f + + R, x, t, s = ring("x, t, s", A) + f = x*t**2 + x*s + sqrt(2) + + D, t_, s_ = ring("t_, s_", ZZ) + T, x_, z_ = ring("x_, z_", D) + f_ = (t_**2 + s_)*x_ + z_ + + assert _to_ZZ_poly(f, T) == f_ + assert _to_ANP_poly(f_, R) == f + + +def test_modgcd_algebraic_field(): + A = AlgebraicField(QQ, sqrt(2)) + R, x = ring("x", A) + one = A.one + + f, g = 2*x, R(2) + assert func_field_modgcd(f, g) == (one, f, g) + + f, g = 2*x, R(sqrt(2)) + assert func_field_modgcd(f, g) == (one, f, g) + + f, g = 2*x + 2, 6*x**2 - 6 + assert func_field_modgcd(f, g) == (x + 1, R(2), 6*x - 6) + + R, x, y = ring("x, y", A) + + f, g = x + sqrt(2)*y, x + y + assert func_field_modgcd(f, g) == (one, f, g) + + f, g = x*y + sqrt(2)*y**2, R(sqrt(2))*y + assert func_field_modgcd(f, g) == (y, x + sqrt(2)*y, R(sqrt(2))) + + f, g = x**2 + 2*sqrt(2)*x*y + 2*y**2, x + sqrt(2)*y + assert func_field_modgcd(f, g) == (g, g, one) + + A = AlgebraicField(QQ, sqrt(2), sqrt(3)) + R, x, y, z = ring("x, y, z", A) + + h = x**2*y**7 + sqrt(6)/21*z + f, g = h*(27*y**3 + 1), h*(y + x) + assert func_field_modgcd(f, g) == (h, 27*y**3+1, y+x) + + h = x**13*y**3 + 1/2*x**10 + 1/sqrt(2) + f, g = h*(x + 1), h*sqrt(2)/sqrt(3) + assert func_field_modgcd(f, g) == (h, x + 1, R(sqrt(2)/sqrt(3))) + + A = AlgebraicField(QQ, sqrt(2)**(-1)*sqrt(3)) + R, x = ring("x", A) + + f, g = x + 1, x - 1 + assert func_field_modgcd(f, g) == (A.one, f, g) + + +# when func_field_modgcd supports function fields, this test can be changed +def test_modgcd_func_field(): + D, t = ring("t", ZZ) + R, x, z = ring("x, z", D) + + minpoly = (z**2*t**2 + z**2*t - 1).drop(0) + f, g = x + 1, x - 1 + + assert _func_field_modgcd_m(f, g, minpoly) == R.one diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_monomials.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_monomials.py new file mode 100644 index 0000000000000000000000000000000000000000..c5ed28ba0e8e3f8e9f85c543a4fffcaef855fff8 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_monomials.py @@ -0,0 +1,269 @@ +"""Tests for tools and arithmetics for monomials of distributed polynomials. """ + +from sympy.polys.monomials import ( + itermonomials, monomial_count, + monomial_mul, monomial_div, + monomial_gcd, monomial_lcm, + monomial_max, monomial_min, + monomial_divides, monomial_pow, + Monomial, +) + +from sympy.polys.polyerrors import ExactQuotientFailed + +from sympy.abc import a, b, c, x, y, z +from sympy.core import S, symbols +from sympy.testing.pytest import raises + +def test_monomials(): + + # total_degree tests + assert set(itermonomials([], 0)) == {S.One} + assert set(itermonomials([], 1)) == {S.One} + assert set(itermonomials([], 2)) == {S.One} + + assert set(itermonomials([], 0, 0)) == {S.One} + assert set(itermonomials([], 1, 0)) == {S.One} + assert set(itermonomials([], 2, 0)) == {S.One} + + raises(StopIteration, lambda: next(itermonomials([], 0, 1))) + raises(StopIteration, lambda: next(itermonomials([], 0, 2))) + raises(StopIteration, lambda: next(itermonomials([], 0, 3))) + + assert set(itermonomials([], 0, 1)) == set() + assert set(itermonomials([], 0, 2)) == set() + assert set(itermonomials([], 0, 3)) == set() + + raises(ValueError, lambda: set(itermonomials([], -1))) + raises(ValueError, lambda: set(itermonomials([x], -1))) + raises(ValueError, lambda: set(itermonomials([x, y], -1))) + + assert set(itermonomials([x], 0)) == {S.One} + assert set(itermonomials([x], 1)) == {S.One, x} + assert set(itermonomials([x], 2)) == {S.One, x, x**2} + assert set(itermonomials([x], 3)) == {S.One, x, x**2, x**3} + + assert set(itermonomials([x, y], 0)) == {S.One} + assert set(itermonomials([x, y], 1)) == {S.One, x, y} + assert set(itermonomials([x, y], 2)) == {S.One, x, y, x**2, y**2, x*y} + assert set(itermonomials([x, y], 3)) == \ + {S.One, x, y, x**2, x**3, y**2, y**3, x*y, x*y**2, y*x**2} + + i, j, k = symbols('i j k', commutative=False) + assert set(itermonomials([i, j, k], 0)) == {S.One} + assert set(itermonomials([i, j, k], 1)) == {S.One, i, j, k} + assert set(itermonomials([i, j, k], 2)) == \ + {S.One, i, j, k, i**2, j**2, k**2, i*j, i*k, j*i, j*k, k*i, k*j} + + assert set(itermonomials([i, j, k], 3)) == \ + {S.One, i, j, k, i**2, j**2, k**2, i*j, i*k, j*i, j*k, k*i, k*j, + i**3, j**3, k**3, + i**2 * j, i**2 * k, j * i**2, k * i**2, + j**2 * i, j**2 * k, i * j**2, k * j**2, + k**2 * i, k**2 * j, i * k**2, j * k**2, + i*j*i, i*k*i, j*i*j, j*k*j, k*i*k, k*j*k, + i*j*k, i*k*j, j*i*k, j*k*i, k*i*j, k*j*i, + } + + assert set(itermonomials([x, i, j], 0)) == {S.One} + assert set(itermonomials([x, i, j], 1)) == {S.One, x, i, j} + assert set(itermonomials([x, i, j], 2)) == {S.One, x, i, j, x*i, x*j, i*j, j*i, x**2, i**2, j**2} + assert set(itermonomials([x, i, j], 3)) == \ + {S.One, x, i, j, x*i, x*j, i*j, j*i, x**2, i**2, j**2, + x**3, i**3, j**3, + x**2 * i, x**2 * j, + x * i**2, j * i**2, i**2 * j, i*j*i, + x * j**2, i * j**2, j**2 * i, j*i*j, + x * i * j, x * j * i + } + + # degree_list tests + assert set(itermonomials([], [])) == {S.One} + + raises(ValueError, lambda: set(itermonomials([], [0]))) + raises(ValueError, lambda: set(itermonomials([], [1]))) + raises(ValueError, lambda: set(itermonomials([], [2]))) + + raises(ValueError, lambda: set(itermonomials([x], [1], []))) + raises(ValueError, lambda: set(itermonomials([x], [1, 2], []))) + raises(ValueError, lambda: set(itermonomials([x], [1, 2, 3], []))) + + raises(ValueError, lambda: set(itermonomials([x], [], [1]))) + raises(ValueError, lambda: set(itermonomials([x], [], [1, 2]))) + raises(ValueError, lambda: set(itermonomials([x], [], [1, 2, 3]))) + + raises(ValueError, lambda: set(itermonomials([x, y], [1, 2], [1, 2, 3]))) + raises(ValueError, lambda: set(itermonomials([x, y, z], [1, 2, 3], [0, 1]))) + + raises(ValueError, lambda: set(itermonomials([x], [1], [-1]))) + raises(ValueError, lambda: set(itermonomials([x, y], [1, 2], [1, -1]))) + + raises(ValueError, lambda: set(itermonomials([], [], 1))) + raises(ValueError, lambda: set(itermonomials([], [], 2))) + raises(ValueError, lambda: set(itermonomials([], [], 3))) + + raises(ValueError, lambda: set(itermonomials([x, y], [0, 1], [1, 2]))) + raises(ValueError, lambda: set(itermonomials([x, y, z], [0, 0, 3], [0, 1, 2]))) + + assert set(itermonomials([x], [0])) == {S.One} + assert set(itermonomials([x], [1])) == {S.One, x} + assert set(itermonomials([x], [2])) == {S.One, x, x**2} + assert set(itermonomials([x], [3])) == {S.One, x, x**2, x**3} + + assert set(itermonomials([x], [3], [1])) == {x, x**3, x**2} + assert set(itermonomials([x], [3], [2])) == {x**3, x**2} + + assert set(itermonomials([x, y], 3, 3)) == {x**3, x**2*y, x*y**2, y**3} + assert set(itermonomials([x, y], 3, 2)) == {x**2, x*y, y**2, x**3, x**2*y, x*y**2, y**3} + + assert set(itermonomials([x, y], [0, 0])) == {S.One} + assert set(itermonomials([x, y], [0, 1])) == {S.One, y} + assert set(itermonomials([x, y], [0, 2])) == {S.One, y, y**2} + assert set(itermonomials([x, y], [0, 2], [0, 1])) == {y, y**2} + assert set(itermonomials([x, y], [0, 2], [0, 2])) == {y**2} + + assert set(itermonomials([x, y], [1, 0])) == {S.One, x} + assert set(itermonomials([x, y], [1, 1])) == {S.One, x, y, x*y} + assert set(itermonomials([x, y], [1, 2])) == {S.One, x, y, x*y, y**2, x*y**2} + assert set(itermonomials([x, y], [1, 2], [1, 1])) == {x*y, x*y**2} + assert set(itermonomials([x, y], [1, 2], [1, 2])) == {x*y**2} + + assert set(itermonomials([x, y], [2, 0])) == {S.One, x, x**2} + assert set(itermonomials([x, y], [2, 1])) == {S.One, x, y, x*y, x**2, x**2*y} + assert set(itermonomials([x, y], [2, 2])) == \ + {S.One, y**2, x*y**2, x, x*y, x**2, x**2*y**2, y, x**2*y} + + i, j, k = symbols('i j k', commutative=False) + assert set(itermonomials([i, j, k], 2, 2)) == \ + {k*i, i**2, i*j, j*k, j*i, k**2, j**2, k*j, i*k} + assert set(itermonomials([i, j, k], 3, 2)) == \ + {j*k**2, i*k**2, k*i*j, k*i**2, k**2, j*k*j, k*j**2, i*k*i, i*j, + j**2*k, i**2*j, j*i*k, j**3, i**3, k*j*i, j*k*i, j*i, + k**2*j, j*i**2, k*j, k*j*k, i*j*i, j*i*j, i*j**2, j**2, + k*i*k, i**2, j*k, i*k, i*k*j, k**3, i**2*k, j**2*i, k**2*i, + i*j*k, k*i + } + assert set(itermonomials([i, j, k], [0, 0, 0])) == {S.One} + assert set(itermonomials([i, j, k], [0, 0, 1])) == {1, k} + assert set(itermonomials([i, j, k], [0, 1, 0])) == {1, j} + assert set(itermonomials([i, j, k], [1, 0, 0])) == {i, 1} + assert set(itermonomials([i, j, k], [0, 0, 2])) == {k**2, 1, k} + assert set(itermonomials([i, j, k], [0, 2, 0])) == {1, j, j**2} + assert set(itermonomials([i, j, k], [2, 0, 0])) == {i, 1, i**2} + assert set(itermonomials([i, j, k], [1, 1, 1])) == {1, k, j, j*k, i*k, i, i*j, i*j*k} + assert set(itermonomials([i, j, k], [2, 2, 2])) == \ + {1, k, i**2*k**2, j*k, j**2, i, i*k, j*k**2, i*j**2*k**2, + i**2*j, i**2*j**2, k**2, j**2*k, i*j**2*k, + j**2*k**2, i*j, i**2*k, i**2*j**2*k, j, i**2*j*k, + i*j**2, i*k**2, i*j*k, i**2*j**2*k**2, i*j*k**2, i**2, i**2*j*k**2 + } + + assert set(itermonomials([x, j, k], [0, 0, 0])) == {S.One} + assert set(itermonomials([x, j, k], [0, 0, 1])) == {1, k} + assert set(itermonomials([x, j, k], [0, 1, 0])) == {1, j} + assert set(itermonomials([x, j, k], [1, 0, 0])) == {x, 1} + assert set(itermonomials([x, j, k], [0, 0, 2])) == {k**2, 1, k} + assert set(itermonomials([x, j, k], [0, 2, 0])) == {1, j, j**2} + assert set(itermonomials([x, j, k], [2, 0, 0])) == {x, 1, x**2} + assert set(itermonomials([x, j, k], [1, 1, 1])) == {1, k, j, j*k, x*k, x, x*j, x*j*k} + assert set(itermonomials([x, j, k], [2, 2, 2])) == \ + {1, k, x**2*k**2, j*k, j**2, x, x*k, j*k**2, x*j**2*k**2, + x**2*j, x**2*j**2, k**2, j**2*k, x*j**2*k, + j**2*k**2, x*j, x**2*k, x**2*j**2*k, j, x**2*j*k, + x*j**2, x*k**2, x*j*k, x**2*j**2*k**2, x*j*k**2, x**2, x**2*j*k**2 + } + +def test_monomial_count(): + assert monomial_count(2, 2) == 6 + assert monomial_count(2, 3) == 10 + +def test_monomial_mul(): + assert monomial_mul((3, 4, 1), (1, 2, 0)) == (4, 6, 1) + +def test_monomial_div(): + assert monomial_div((3, 4, 1), (1, 2, 0)) == (2, 2, 1) + +def test_monomial_gcd(): + assert monomial_gcd((3, 4, 1), (1, 2, 0)) == (1, 2, 0) + +def test_monomial_lcm(): + assert monomial_lcm((3, 4, 1), (1, 2, 0)) == (3, 4, 1) + +def test_monomial_max(): + assert monomial_max((3, 4, 5), (0, 5, 1), (6, 3, 9)) == (6, 5, 9) + +def test_monomial_pow(): + assert monomial_pow((1, 2, 3), 3) == (3, 6, 9) + +def test_monomial_min(): + assert monomial_min((3, 4, 5), (0, 5, 1), (6, 3, 9)) == (0, 3, 1) + +def test_monomial_divides(): + assert monomial_divides((1, 2, 3), (4, 5, 6)) is True + assert monomial_divides((1, 2, 3), (0, 5, 6)) is False + +def test_Monomial(): + m = Monomial((3, 4, 1), (x, y, z)) + n = Monomial((1, 2, 0), (x, y, z)) + + assert m.as_expr() == x**3*y**4*z + assert n.as_expr() == x**1*y**2 + + assert m.as_expr(a, b, c) == a**3*b**4*c + assert n.as_expr(a, b, c) == a**1*b**2 + + assert m.exponents == (3, 4, 1) + assert m.gens == (x, y, z) + + assert n.exponents == (1, 2, 0) + assert n.gens == (x, y, z) + + assert m == (3, 4, 1) + assert n != (3, 4, 1) + assert m != (1, 2, 0) + assert n == (1, 2, 0) + assert (m == 1) is False + + assert m[0] == m[-3] == 3 + assert m[1] == m[-2] == 4 + assert m[2] == m[-1] == 1 + + assert n[0] == n[-3] == 1 + assert n[1] == n[-2] == 2 + assert n[2] == n[-1] == 0 + + assert m[:2] == (3, 4) + assert n[:2] == (1, 2) + + assert m*n == Monomial((4, 6, 1)) + assert m/n == Monomial((2, 2, 1)) + + assert m*(1, 2, 0) == Monomial((4, 6, 1)) + assert m/(1, 2, 0) == Monomial((2, 2, 1)) + + assert m.gcd(n) == Monomial((1, 2, 0)) + assert m.lcm(n) == Monomial((3, 4, 1)) + + assert m.gcd((1, 2, 0)) == Monomial((1, 2, 0)) + assert m.lcm((1, 2, 0)) == Monomial((3, 4, 1)) + + assert m**0 == Monomial((0, 0, 0)) + assert m**1 == m + assert m**2 == Monomial((6, 8, 2)) + assert m**3 == Monomial((9, 12, 3)) + _a = Monomial((0, 0, 0)) + for n in range(10): + assert _a == m**n + _a *= m + + raises(ExactQuotientFailed, lambda: m/Monomial((5, 2, 0))) + + mm = Monomial((1, 2, 3)) + raises(ValueError, lambda: mm.as_expr()) + assert str(mm) == 'Monomial((1, 2, 3))' + assert str(m) == 'x**3*y**4*z**1' + raises(NotImplementedError, lambda: m*1) + raises(NotImplementedError, lambda: m/1) + raises(ValueError, lambda: m**-1) + raises(TypeError, lambda: m.gcd(3)) + raises(TypeError, lambda: m.lcm(3)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_multivariate_resultants.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_multivariate_resultants.py new file mode 100644 index 0000000000000000000000000000000000000000..0799feb41fc875cf038723916a3efd62ff31b1b4 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_multivariate_resultants.py @@ -0,0 +1,294 @@ +"""Tests for Dixon's and Macaulay's classes. """ + +from sympy.matrices.dense import Matrix +from sympy.polys.polytools import factor +from sympy.core import symbols +from sympy.tensor.indexed import IndexedBase + +from sympy.polys.multivariate_resultants import (DixonResultant, + MacaulayResultant) + +c, d = symbols("a, b") +x, y = symbols("x, y") + +p = c * x + y +q = x + d * y + +dixon = DixonResultant(polynomials=[p, q], variables=[x, y]) +macaulay = MacaulayResultant(polynomials=[p, q], variables=[x, y]) + +def test_dixon_resultant_init(): + """Test init method of DixonResultant.""" + a = IndexedBase("alpha") + + assert dixon.polynomials == [p, q] + assert dixon.variables == [x, y] + assert dixon.n == 2 + assert dixon.m == 2 + assert dixon.dummy_variables == [a[0], a[1]] + +def test_get_dixon_polynomial_numerical(): + """Test Dixon's polynomial for a numerical example.""" + a = IndexedBase("alpha") + + p = x + y + q = x ** 2 + y **3 + h = x ** 2 + y + + dixon = DixonResultant([p, q, h], [x, y]) + polynomial = -x * y ** 2 * a[0] - x * y ** 2 * a[1] - x * y * a[0] \ + * a[1] - x * y * a[1] ** 2 - x * a[0] * a[1] ** 2 + x * a[0] - \ + y ** 2 * a[0] * a[1] + y ** 2 * a[1] - y * a[0] * a[1] ** 2 + y * \ + a[1] ** 2 + + assert dixon.get_dixon_polynomial().as_expr().expand() == polynomial + +def test_get_max_degrees(): + """Tests max degrees function.""" + + p = x + y + q = x ** 2 + y **3 + h = x ** 2 + y + + dixon = DixonResultant(polynomials=[p, q, h], variables=[x, y]) + dixon_polynomial = dixon.get_dixon_polynomial() + + assert dixon.get_max_degrees(dixon_polynomial) == [1, 2] + +def test_get_dixon_matrix(): + """Test Dixon's resultant for a numerical example.""" + + x, y = symbols('x, y') + + p = x + y + q = x ** 2 + y ** 3 + h = x ** 2 + y + + dixon = DixonResultant([p, q, h], [x, y]) + polynomial = dixon.get_dixon_polynomial() + + assert dixon.get_dixon_matrix(polynomial).det() == 0 + +def test_get_dixon_matrix_example_two(): + """Test Dixon's matrix for example from [Palancz08]_.""" + x, y, z = symbols('x, y, z') + + f = x ** 2 + y ** 2 - 1 + z * 0 + g = x ** 2 + z ** 2 - 1 + y * 0 + h = y ** 2 + z ** 2 - 1 + + example_two = DixonResultant([f, g, h], [y, z]) + poly = example_two.get_dixon_polynomial() + matrix = example_two.get_dixon_matrix(poly) + + expr = 1 - 8 * x ** 2 + 24 * x ** 4 - 32 * x ** 6 + 16 * x ** 8 + assert (matrix.det() - expr).expand() == 0 + +def test_KSY_precondition(): + """Tests precondition for KSY Resultant.""" + A, B, C = symbols('A, B, C') + + m1 = Matrix([[1, 2, 3], + [4, 5, 12], + [6, 7, 18]]) + + m2 = Matrix([[0, C**2], + [-2 * C, -C ** 2]]) + + m3 = Matrix([[1, 0], + [0, 1]]) + + m4 = Matrix([[A**2, 0, 1], + [A, 1, 1 / A]]) + + m5 = Matrix([[5, 1], + [2, B], + [0, 1], + [0, 0]]) + + assert dixon.KSY_precondition(m1) == False + assert dixon.KSY_precondition(m2) == True + assert dixon.KSY_precondition(m3) == True + assert dixon.KSY_precondition(m4) == False + assert dixon.KSY_precondition(m5) == True + +def test_delete_zero_rows_and_columns(): + """Tests method for deleting rows and columns containing only zeros.""" + A, B, C = symbols('A, B, C') + + m1 = Matrix([[0, 0], + [0, 0], + [1, 2]]) + + m2 = Matrix([[0, 1, 2], + [0, 3, 4], + [0, 5, 6]]) + + m3 = Matrix([[0, 0, 0, 0], + [0, 1, 2, 0], + [0, 3, 4, 0], + [0, 0, 0, 0]]) + + m4 = Matrix([[1, 0, 2], + [0, 0, 0], + [3, 0, 4]]) + + m5 = Matrix([[0, 0, 0, 1], + [0, 0, 0, 2], + [0, 0, 0, 3], + [0, 0, 0, 4]]) + + m6 = Matrix([[0, 0, A], + [B, 0, 0], + [0, 0, C]]) + + assert dixon.delete_zero_rows_and_columns(m1) == Matrix([[1, 2]]) + + assert dixon.delete_zero_rows_and_columns(m2) == Matrix([[1, 2], + [3, 4], + [5, 6]]) + + assert dixon.delete_zero_rows_and_columns(m3) == Matrix([[1, 2], + [3, 4]]) + + assert dixon.delete_zero_rows_and_columns(m4) == Matrix([[1, 2], + [3, 4]]) + + assert dixon.delete_zero_rows_and_columns(m5) == Matrix([[1], + [2], + [3], + [4]]) + + assert dixon.delete_zero_rows_and_columns(m6) == Matrix([[0, A], + [B, 0], + [0, C]]) + +def test_product_leading_entries(): + """Tests product of leading entries method.""" + A, B = symbols('A, B') + + m1 = Matrix([[1, 2, 3], + [0, 4, 5], + [0, 0, 6]]) + + m2 = Matrix([[0, 0, 1], + [2, 0, 3]]) + + m3 = Matrix([[0, 0, 0], + [1, 2, 3], + [0, 0, 0]]) + + m4 = Matrix([[0, 0, A], + [1, 2, 3], + [B, 0, 0]]) + + assert dixon.product_leading_entries(m1) == 24 + assert dixon.product_leading_entries(m2) == 2 + assert dixon.product_leading_entries(m3) == 1 + assert dixon.product_leading_entries(m4) == A * B + +def test_get_KSY_Dixon_resultant_example_one(): + """Tests the KSY Dixon resultant for example one""" + x, y, z = symbols('x, y, z') + + p = x * y * z + q = x**2 - z**2 + h = x + y + z + dixon = DixonResultant([p, q, h], [x, y]) + dixon_poly = dixon.get_dixon_polynomial() + dixon_matrix = dixon.get_dixon_matrix(dixon_poly) + D = dixon.get_KSY_Dixon_resultant(dixon_matrix) + + assert D == -z**3 + +def test_get_KSY_Dixon_resultant_example_two(): + """Tests the KSY Dixon resultant for example two""" + x, y, A = symbols('x, y, A') + + p = x * y + x * A + x - A**2 - A + y**2 + y + q = x**2 + x * A - x + x * y + y * A - y + h = x**2 + x * y + 2 * x - x * A - y * A - 2 * A + + dixon = DixonResultant([p, q, h], [x, y]) + dixon_poly = dixon.get_dixon_polynomial() + dixon_matrix = dixon.get_dixon_matrix(dixon_poly) + D = factor(dixon.get_KSY_Dixon_resultant(dixon_matrix)) + + assert D == -8*A*(A - 1)*(A + 2)*(2*A - 1)**2 + +def test_macaulay_resultant_init(): + """Test init method of MacaulayResultant.""" + + assert macaulay.polynomials == [p, q] + assert macaulay.variables == [x, y] + assert macaulay.n == 2 + assert macaulay.degrees == [1, 1] + assert macaulay.degree_m == 1 + assert macaulay.monomials_size == 2 + +def test_get_degree_m(): + assert macaulay._get_degree_m() == 1 + +def test_get_size(): + assert macaulay.get_size() == 2 + +def test_macaulay_example_one(): + """Tests the Macaulay for example from [Bruce97]_""" + + x, y, z = symbols('x, y, z') + a_1_1, a_1_2, a_1_3 = symbols('a_1_1, a_1_2, a_1_3') + a_2_2, a_2_3, a_3_3 = symbols('a_2_2, a_2_3, a_3_3') + b_1_1, b_1_2, b_1_3 = symbols('b_1_1, b_1_2, b_1_3') + b_2_2, b_2_3, b_3_3 = symbols('b_2_2, b_2_3, b_3_3') + c_1, c_2, c_3 = symbols('c_1, c_2, c_3') + + f_1 = a_1_1 * x ** 2 + a_1_2 * x * y + a_1_3 * x * z + \ + a_2_2 * y ** 2 + a_2_3 * y * z + a_3_3 * z ** 2 + f_2 = b_1_1 * x ** 2 + b_1_2 * x * y + b_1_3 * x * z + \ + b_2_2 * y ** 2 + b_2_3 * y * z + b_3_3 * z ** 2 + f_3 = c_1 * x + c_2 * y + c_3 * z + + mac = MacaulayResultant([f_1, f_2, f_3], [x, y, z]) + + assert mac.degrees == [2, 2, 1] + assert mac.degree_m == 3 + + assert mac.monomial_set == [x ** 3, x ** 2 * y, x ** 2 * z, + x * y ** 2, + x * y * z, x * z ** 2, y ** 3, + y ** 2 *z, y * z ** 2, z ** 3] + assert mac.monomials_size == 10 + assert mac.get_row_coefficients() == [[x, y, z], [x, y, z], + [x * y, x * z, y * z, z ** 2]] + + matrix = mac.get_matrix() + assert matrix.shape == (mac.monomials_size, mac.monomials_size) + assert mac.get_submatrix(matrix) == Matrix([[a_1_1, a_2_2], + [b_1_1, b_2_2]]) + +def test_macaulay_example_two(): + """Tests the Macaulay formulation for example from [Stiller96]_.""" + + x, y, z = symbols('x, y, z') + a_0, a_1, a_2 = symbols('a_0, a_1, a_2') + b_0, b_1, b_2 = symbols('b_0, b_1, b_2') + c_0, c_1, c_2, c_3, c_4 = symbols('c_0, c_1, c_2, c_3, c_4') + + f = a_0 * y - a_1 * x + a_2 * z + g = b_1 * x ** 2 + b_0 * y ** 2 - b_2 * z ** 2 + h = c_0 * y - c_1 * x ** 3 + c_2 * x ** 2 * z - c_3 * x * z ** 2 + \ + c_4 * z ** 3 + + mac = MacaulayResultant([f, g, h], [x, y, z]) + + assert mac.degrees == [1, 2, 3] + assert mac.degree_m == 4 + assert mac.monomials_size == 15 + assert len(mac.get_row_coefficients()) == mac.n + + matrix = mac.get_matrix() + assert matrix.shape == (mac.monomials_size, mac.monomials_size) + assert mac.get_submatrix(matrix) == Matrix([[-a_1, a_0, a_2, 0], + [0, -a_1, 0, 0], + [0, 0, -a_1, 0], + [0, 0, 0, -a_1]]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_orderings.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_orderings.py new file mode 100644 index 0000000000000000000000000000000000000000..d61d4887754c9d9f49905c2e131d253a45cf2ffd --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_orderings.py @@ -0,0 +1,124 @@ +"""Tests of monomial orderings. """ + +from sympy.polys.orderings import ( + monomial_key, lex, grlex, grevlex, ilex, igrlex, + LexOrder, InverseOrder, ProductOrder, build_product_order, +) + +from sympy.abc import x, y, z, t +from sympy.core import S +from sympy.testing.pytest import raises + +def test_lex_order(): + assert lex((1, 2, 3)) == (1, 2, 3) + assert str(lex) == 'lex' + + assert lex((1, 2, 3)) == lex((1, 2, 3)) + + assert lex((2, 2, 3)) > lex((1, 2, 3)) + assert lex((1, 3, 3)) > lex((1, 2, 3)) + assert lex((1, 2, 4)) > lex((1, 2, 3)) + + assert lex((0, 2, 3)) < lex((1, 2, 3)) + assert lex((1, 1, 3)) < lex((1, 2, 3)) + assert lex((1, 2, 2)) < lex((1, 2, 3)) + + assert lex.is_global is True + assert lex == LexOrder() + assert lex != grlex + +def test_grlex_order(): + assert grlex((1, 2, 3)) == (6, (1, 2, 3)) + assert str(grlex) == 'grlex' + + assert grlex((1, 2, 3)) == grlex((1, 2, 3)) + + assert grlex((2, 2, 3)) > grlex((1, 2, 3)) + assert grlex((1, 3, 3)) > grlex((1, 2, 3)) + assert grlex((1, 2, 4)) > grlex((1, 2, 3)) + + assert grlex((0, 2, 3)) < grlex((1, 2, 3)) + assert grlex((1, 1, 3)) < grlex((1, 2, 3)) + assert grlex((1, 2, 2)) < grlex((1, 2, 3)) + + assert grlex((2, 2, 3)) > grlex((1, 2, 4)) + assert grlex((1, 3, 3)) > grlex((1, 2, 4)) + + assert grlex((0, 2, 3)) < grlex((1, 2, 2)) + assert grlex((1, 1, 3)) < grlex((1, 2, 2)) + + assert grlex((0, 1, 1)) > grlex((0, 0, 2)) + assert grlex((0, 3, 1)) < grlex((2, 2, 1)) + + assert grlex.is_global is True + +def test_grevlex_order(): + assert grevlex((1, 2, 3)) == (6, (-3, -2, -1)) + assert str(grevlex) == 'grevlex' + + assert grevlex((1, 2, 3)) == grevlex((1, 2, 3)) + + assert grevlex((2, 2, 3)) > grevlex((1, 2, 3)) + assert grevlex((1, 3, 3)) > grevlex((1, 2, 3)) + assert grevlex((1, 2, 4)) > grevlex((1, 2, 3)) + + assert grevlex((0, 2, 3)) < grevlex((1, 2, 3)) + assert grevlex((1, 1, 3)) < grevlex((1, 2, 3)) + assert grevlex((1, 2, 2)) < grevlex((1, 2, 3)) + + assert grevlex((2, 2, 3)) > grevlex((1, 2, 4)) + assert grevlex((1, 3, 3)) > grevlex((1, 2, 4)) + + assert grevlex((0, 2, 3)) < grevlex((1, 2, 2)) + assert grevlex((1, 1, 3)) < grevlex((1, 2, 2)) + + assert grevlex((0, 1, 1)) > grevlex((0, 0, 2)) + assert grevlex((0, 3, 1)) < grevlex((2, 2, 1)) + + assert grevlex.is_global is True + +def test_InverseOrder(): + ilex = InverseOrder(lex) + igrlex = InverseOrder(grlex) + + assert ilex((1, 2, 3)) > ilex((2, 0, 3)) + assert igrlex((1, 2, 3)) < igrlex((0, 2, 3)) + assert str(ilex) == "ilex" + assert str(igrlex) == "igrlex" + assert ilex.is_global is False + assert igrlex.is_global is False + assert ilex != igrlex + assert ilex == InverseOrder(LexOrder()) + +def test_ProductOrder(): + P = ProductOrder((grlex, lambda m: m[:2]), (grlex, lambda m: m[2:])) + assert P((1, 3, 3, 4, 5)) > P((2, 1, 5, 5, 5)) + assert str(P) == "ProductOrder(grlex, grlex)" + assert P.is_global is True + assert ProductOrder((grlex, None), (ilex, None)).is_global is None + assert ProductOrder((igrlex, None), (ilex, None)).is_global is False + +def test_monomial_key(): + assert monomial_key() == lex + + assert monomial_key('lex') == lex + assert monomial_key('grlex') == grlex + assert monomial_key('grevlex') == grevlex + + raises(ValueError, lambda: monomial_key('foo')) + raises(ValueError, lambda: monomial_key(1)) + + M = [x, x**2*z**2, x*y, x**2, S.One, y**2, x**3, y, z, x*y**2*z, x**2*y**2] + assert sorted(M, key=monomial_key('lex', [z, y, x])) == \ + [S.One, x, x**2, x**3, y, x*y, y**2, x**2*y**2, z, x*y**2*z, x**2*z**2] + assert sorted(M, key=monomial_key('grlex', [z, y, x])) == \ + [S.One, x, y, z, x**2, x*y, y**2, x**3, x**2*y**2, x*y**2*z, x**2*z**2] + assert sorted(M, key=monomial_key('grevlex', [z, y, x])) == \ + [S.One, x, y, z, x**2, x*y, y**2, x**3, x**2*y**2, x**2*z**2, x*y**2*z] + +def test_build_product_order(): + assert build_product_order((("grlex", x, y), ("grlex", z, t)), [x, y, z, t])((4, 5, 6, 7)) == \ + ((9, (4, 5)), (13, (6, 7))) + + assert build_product_order((("grlex", x, y), ("grlex", z, t)), [x, y, z, t]) == \ + build_product_order((("grlex", x, y), ("grlex", z, t)), [x, y, z, t]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_orthopolys.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_orthopolys.py new file mode 100644 index 0000000000000000000000000000000000000000..e81fbe75aa6285d229ba817026f44b23b76abd6a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_orthopolys.py @@ -0,0 +1,175 @@ +"""Tests for efficient functions for generating orthogonal polynomials. """ + +from sympy.core.numbers import Rational as Q +from sympy.core.singleton import S +from sympy.core.symbol import symbols +from sympy.polys.polytools import Poly +from sympy.testing.pytest import raises + +from sympy.polys.orthopolys import ( + jacobi_poly, + gegenbauer_poly, + chebyshevt_poly, + chebyshevu_poly, + hermite_poly, + hermite_prob_poly, + legendre_poly, + laguerre_poly, + spherical_bessel_fn, +) + +from sympy.abc import x, a, b + + +def test_jacobi_poly(): + raises(ValueError, lambda: jacobi_poly(-1, a, b, x)) + + assert jacobi_poly(1, a, b, x, polys=True) == Poly( + (a/2 + b/2 + 1)*x + a/2 - b/2, x, domain='ZZ(a,b)') + + assert jacobi_poly(0, a, b, x) == 1 + assert jacobi_poly(1, a, b, x) == a/2 - b/2 + x*(a/2 + b/2 + 1) + assert jacobi_poly(2, a, b, x) == (a**2/8 - a*b/4 - a/8 + b**2/8 - b/8 + + x**2*(a**2/8 + a*b/4 + a*Q(7, 8) + b**2/8 + + b*Q(7, 8) + Q(3, 2)) + x*(a**2/4 + + a*Q(3, 4) - b**2/4 - b*Q(3, 4)) - S.Half) + + assert jacobi_poly(1, a, b, polys=True) == Poly( + (a/2 + b/2 + 1)*x + a/2 - b/2, x, domain='ZZ(a,b)') + + +def test_gegenbauer_poly(): + raises(ValueError, lambda: gegenbauer_poly(-1, a, x)) + + assert gegenbauer_poly( + 1, a, x, polys=True) == Poly(2*a*x, x, domain='ZZ(a)') + + assert gegenbauer_poly(0, a, x) == 1 + assert gegenbauer_poly(1, a, x) == 2*a*x + assert gegenbauer_poly(2, a, x) == -a + x**2*(2*a**2 + 2*a) + assert gegenbauer_poly( + 3, a, x) == x**3*(4*a**3/3 + 4*a**2 + a*Q(8, 3)) + x*(-2*a**2 - 2*a) + + assert gegenbauer_poly(1, S.Half).dummy_eq(x) + assert gegenbauer_poly(1, a, polys=True) == Poly(2*a*x, x, domain='ZZ(a)') + + +def test_chebyshevt_poly(): + raises(ValueError, lambda: chebyshevt_poly(-1, x)) + + assert chebyshevt_poly(1, x, polys=True) == Poly(x) + + assert chebyshevt_poly(0, x) == 1 + assert chebyshevt_poly(1, x) == x + assert chebyshevt_poly(2, x) == 2*x**2 - 1 + assert chebyshevt_poly(3, x) == 4*x**3 - 3*x + assert chebyshevt_poly(4, x) == 8*x**4 - 8*x**2 + 1 + assert chebyshevt_poly(5, x) == 16*x**5 - 20*x**3 + 5*x + assert chebyshevt_poly(6, x) == 32*x**6 - 48*x**4 + 18*x**2 - 1 + assert chebyshevt_poly(75, x) == (2*chebyshevt_poly(37, x)*chebyshevt_poly(38, x) - x).expand() + assert chebyshevt_poly(100, x) == (2*chebyshevt_poly(50, x)**2 - 1).expand() + + assert chebyshevt_poly(1).dummy_eq(x) + assert chebyshevt_poly(1, polys=True) == Poly(x) + + +def test_chebyshevu_poly(): + raises(ValueError, lambda: chebyshevu_poly(-1, x)) + + assert chebyshevu_poly(1, x, polys=True) == Poly(2*x) + + assert chebyshevu_poly(0, x) == 1 + assert chebyshevu_poly(1, x) == 2*x + assert chebyshevu_poly(2, x) == 4*x**2 - 1 + assert chebyshevu_poly(3, x) == 8*x**3 - 4*x + assert chebyshevu_poly(4, x) == 16*x**4 - 12*x**2 + 1 + assert chebyshevu_poly(5, x) == 32*x**5 - 32*x**3 + 6*x + assert chebyshevu_poly(6, x) == 64*x**6 - 80*x**4 + 24*x**2 - 1 + + assert chebyshevu_poly(1).dummy_eq(2*x) + assert chebyshevu_poly(1, polys=True) == Poly(2*x) + + +def test_hermite_poly(): + raises(ValueError, lambda: hermite_poly(-1, x)) + + assert hermite_poly(1, x, polys=True) == Poly(2*x) + + assert hermite_poly(0, x) == 1 + assert hermite_poly(1, x) == 2*x + assert hermite_poly(2, x) == 4*x**2 - 2 + assert hermite_poly(3, x) == 8*x**3 - 12*x + assert hermite_poly(4, x) == 16*x**4 - 48*x**2 + 12 + assert hermite_poly(5, x) == 32*x**5 - 160*x**3 + 120*x + assert hermite_poly(6, x) == 64*x**6 - 480*x**4 + 720*x**2 - 120 + + assert hermite_poly(1).dummy_eq(2*x) + assert hermite_poly(1, polys=True) == Poly(2*x) + + +def test_hermite_prob_poly(): + raises(ValueError, lambda: hermite_prob_poly(-1, x)) + + assert hermite_prob_poly(1, x, polys=True) == Poly(x) + + assert hermite_prob_poly(0, x) == 1 + assert hermite_prob_poly(1, x) == x + assert hermite_prob_poly(2, x) == x**2 - 1 + assert hermite_prob_poly(3, x) == x**3 - 3*x + assert hermite_prob_poly(4, x) == x**4 - 6*x**2 + 3 + assert hermite_prob_poly(5, x) == x**5 - 10*x**3 + 15*x + assert hermite_prob_poly(6, x) == x**6 - 15*x**4 + 45*x**2 - 15 + + assert hermite_prob_poly(1).dummy_eq(x) + assert hermite_prob_poly(1, polys=True) == Poly(x) + + +def test_legendre_poly(): + raises(ValueError, lambda: legendre_poly(-1, x)) + + assert legendre_poly(1, x, polys=True) == Poly(x, domain='QQ') + + assert legendre_poly(0, x) == 1 + assert legendre_poly(1, x) == x + assert legendre_poly(2, x) == Q(3, 2)*x**2 - Q(1, 2) + assert legendre_poly(3, x) == Q(5, 2)*x**3 - Q(3, 2)*x + assert legendre_poly(4, x) == Q(35, 8)*x**4 - Q(30, 8)*x**2 + Q(3, 8) + assert legendre_poly(5, x) == Q(63, 8)*x**5 - Q(70, 8)*x**3 + Q(15, 8)*x + assert legendre_poly(6, x) == Q( + 231, 16)*x**6 - Q(315, 16)*x**4 + Q(105, 16)*x**2 - Q(5, 16) + + assert legendre_poly(1).dummy_eq(x) + assert legendre_poly(1, polys=True) == Poly(x) + + +def test_laguerre_poly(): + raises(ValueError, lambda: laguerre_poly(-1, x)) + + assert laguerre_poly(1, x, polys=True) == Poly(-x + 1, domain='QQ') + + assert laguerre_poly(0, x) == 1 + assert laguerre_poly(1, x) == -x + 1 + assert laguerre_poly(2, x) == Q(1, 2)*x**2 - Q(4, 2)*x + 1 + assert laguerre_poly(3, x) == -Q(1, 6)*x**3 + Q(9, 6)*x**2 - Q(18, 6)*x + 1 + assert laguerre_poly(4, x) == Q( + 1, 24)*x**4 - Q(16, 24)*x**3 + Q(72, 24)*x**2 - Q(96, 24)*x + 1 + assert laguerre_poly(5, x) == -Q(1, 120)*x**5 + Q(25, 120)*x**4 - Q( + 200, 120)*x**3 + Q(600, 120)*x**2 - Q(600, 120)*x + 1 + assert laguerre_poly(6, x) == Q(1, 720)*x**6 - Q(36, 720)*x**5 + Q(450, 720)*x**4 - Q(2400, 720)*x**3 + Q(5400, 720)*x**2 - Q(4320, 720)*x + 1 + + assert laguerre_poly(0, x, a) == 1 + assert laguerre_poly(1, x, a) == -x + a + 1 + assert laguerre_poly(2, x, a) == x**2/2 + (-a - 2)*x + a**2/2 + a*Q(3, 2) + 1 + assert laguerre_poly(3, x, a) == -x**3/6 + (a/2 + Q( + 3)/2)*x**2 + (-a**2/2 - a*Q(5, 2) - 3)*x + a**3/6 + a**2 + a*Q(11, 6) + 1 + + assert laguerre_poly(1).dummy_eq(-x + 1) + assert laguerre_poly(1, polys=True) == Poly(-x + 1) + + +def test_spherical_bessel_fn(): + x, z = symbols("x z") + assert spherical_bessel_fn(1, z) == 1/z**2 + assert spherical_bessel_fn(2, z) == -1/z + 3/z**3 + assert spherical_bessel_fn(3, z) == -6/z**2 + 15/z**4 + assert spherical_bessel_fn(4, z) == 1/z - 45/z**3 + 105/z**5 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_partfrac.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_partfrac.py new file mode 100644 index 0000000000000000000000000000000000000000..83c5d48383d20e67dbb53c081093ad35e654c9a0 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_partfrac.py @@ -0,0 +1,249 @@ +"""Tests for algorithms for partial fraction decomposition of rational +functions. """ + +from sympy.polys.partfrac import ( + apart_undetermined_coeffs, + apart, + apart_list, assemble_partfrac_list +) + +from sympy.core.expr import Expr +from sympy.core.function import Lambda +from sympy.core.numbers import (E, I, Rational, pi, all_close) +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, Symbol) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.matrices.dense import Matrix +from sympy.polys.polytools import (Poly, factor) +from sympy.polys.rationaltools import together +from sympy.polys.rootoftools import RootSum +from sympy.testing.pytest import raises, XFAIL +from sympy.abc import x, y, a, b, c + + +def test_apart(): + assert apart(1) == 1 + assert apart(1, x) == 1 + + f, g = (x**2 + 1)/(x + 1), 2/(x + 1) + x - 1 + + assert apart(f, full=False) == g + assert apart(f, full=True) == g + + f, g = 1/(x + 2)/(x + 1), 1/(1 + x) - 1/(2 + x) + + assert apart(f, full=False) == g + assert apart(f, full=True) == g + + f, g = 1/(x + 1)/(x + 5), -1/(5 + x)/4 + 1/(1 + x)/4 + + assert apart(f, full=False) == g + assert apart(f, full=True) == g + + assert apart((E*x + 2)/(x - pi)*(x - 1), x) == \ + 2 - E + E*pi + E*x + (E*pi + 2)*(pi - 1)/(x - pi) + + assert apart(Eq((x**2 + 1)/(x + 1), x), x) == Eq(x - 1 + 2/(x + 1), x) + + assert apart(x/2, y) == x/2 + + f, g = (x+y)/(2*x - y), Rational(3, 2)*y/(2*x - y) + S.Half + + assert apart(f, x, full=False) == g + assert apart(f, x, full=True) == g + + f, g = (x+y)/(2*x - y), 3*x/(2*x - y) - 1 + + assert apart(f, y, full=False) == g + assert apart(f, y, full=True) == g + + raises(NotImplementedError, lambda: apart(1/(x + 1)/(y + 2))) + + +def test_apart_matrix(): + M = Matrix(2, 2, lambda i, j: 1/(x + i + 1)/(x + j)) + + assert apart(M) == Matrix([ + [1/x - 1/(x + 1), (x + 1)**(-2)], + [1/(2*x) - (S.Half)/(x + 2), 1/(x + 1) - 1/(x + 2)], + ]) + + +def test_apart_symbolic(): + f = a*x**4 + (2*b + 2*a*c)*x**3 + (4*b*c - a**2 + a*c**2)*x**2 + \ + (-2*a*b + 2*b*c**2)*x - b**2 + g = a**2*x**4 + (2*a*b + 2*c*a**2)*x**3 + (4*a*b*c + b**2 + + a**2*c**2)*x**2 + (2*c*b**2 + 2*a*b*c**2)*x + b**2*c**2 + + assert apart(f/g, x) == 1/a - 1/(x + c)**2 - b**2/(a*(a*x + b)**2) + + assert apart(1/((x + a)*(x + b)*(x + c)), x) == \ + 1/((a - c)*(b - c)*(c + x)) - 1/((a - b)*(b - c)*(b + x)) + \ + 1/((a - b)*(a - c)*(a + x)) + + +def _make_extension_example(): + # https://github.com/sympy/sympy/issues/18531 + from sympy.core import Mul + def mul2(expr): + # 2-arg mul hack... + return Mul(2, expr, evaluate=False) + + f = ((x**2 + 1)**3/((x - 1)**2*(x + 1)**2*(-x**2 + 2*x + 1)*(x**2 + 2*x - 1))) + g = (1/mul2(x - sqrt(2) + 1) + - 1/mul2(x - sqrt(2) - 1) + + 1/mul2(x + 1 + sqrt(2)) + - 1/mul2(x - 1 + sqrt(2)) + + 1/mul2((x + 1)**2) + + 1/mul2((x - 1)**2)) + return f, g + + +def test_apart_extension(): + f = 2/(x**2 + 1) + g = I/(x + I) - I/(x - I) + + assert apart(f, extension=I) == g + assert apart(f, gaussian=True) == g + + f = x/((x - 2)*(x + I)) + + assert factor(together(apart(f)).expand()) == f + + f, g = _make_extension_example() + + # XXX: Only works with dotprodsimp. See test_apart_extension_xfail below + from sympy.matrices import dotprodsimp + with dotprodsimp(True): + assert apart(f, x, extension={sqrt(2)}) == g + + +def test_apart_extension_xfail(): + f, g = _make_extension_example() + assert apart(f, x, extension={sqrt(2)}) == g + + +def test_apart_full(): + f = 1/(x**2 + 1) + + assert apart(f, full=False) == f + assert apart(f, full=True).dummy_eq( + -RootSum(x**2 + 1, Lambda(a, a/(x - a)), auto=False)/2) + + f = 1/(x**3 + x + 1) + + assert apart(f, full=False) == f + assert apart(f, full=True).dummy_eq( + RootSum(x**3 + x + 1, + Lambda(a, (a**2*Rational(6, 31) - a*Rational(9, 31) + Rational(4, 31))/(x - a)), auto=False)) + + f = 1/(x**5 + 1) + + assert apart(f, full=False) == \ + (Rational(-1, 5))*((x**3 - 2*x**2 + 3*x - 4)/(x**4 - x**3 + x**2 - + x + 1)) + (Rational(1, 5))/(x + 1) + assert apart(f, full=True).dummy_eq( + -RootSum(x**4 - x**3 + x**2 - x + 1, + Lambda(a, a/(x - a)), auto=False)/5 + (Rational(1, 5))/(x + 1)) + + +def test_apart_full_floats(): + # https://github.com/sympy/sympy/issues/26648 + f = ( + 6.43369157032015e-9*x**3 + 1.35203404799555e-5*x**2 + + 0.00357538393743079*x + 0.085 + )/( + 4.74334912634438e-11*x**4 + 4.09576274286244e-6*x**3 + + 0.00334241812250921*x**2 + 0.15406018058983*x + 1.0 + ) + + expected = ( + 133.599202650992/(x + 85524.0054884464) + + 1.07757928431867/(x + 774.88576677949) + + 0.395006955518971/(x + 40.7977016133126) + + 0.564264854137341/(x + 7.79746609204661) + ) + + f_apart = apart(f, full=True).evalf() + + # There is a significant floating point error in this operation. + assert all_close(f_apart, expected, rtol=1e-3, atol=1e-5) + + +def test_apart_undetermined_coeffs(): + p = Poly(2*x - 3) + q = Poly(x**9 - x**8 - x**6 + x**5 - 2*x**2 + 3*x - 1) + r = (-x**7 - x**6 - x**5 + 4)/(x**8 - x**5 - 2*x + 1) + 1/(x - 1) + + assert apart_undetermined_coeffs(p, q) == r + + p = Poly(1, x, domain='ZZ[a,b]') + q = Poly((x + a)*(x + b), x, domain='ZZ[a,b]') + r = 1/((a - b)*(b + x)) - 1/((a - b)*(a + x)) + + assert apart_undetermined_coeffs(p, q) == r + + +def test_apart_list(): + from sympy.utilities.iterables import numbered_symbols + def dummy_eq(i, j): + if type(i) in (list, tuple): + return all(dummy_eq(i, j) for i, j in zip(i, j)) + return i == j or i.dummy_eq(j) + + w0, w1, w2 = Symbol("w0"), Symbol("w1"), Symbol("w2") + _a = Dummy("a") + + f = (-2*x - 2*x**2) / (3*x**2 - 6*x) + got = apart_list(f, x, dummies=numbered_symbols("w")) + ans = (-1, Poly(Rational(2, 3), x, domain='QQ'), + [(Poly(w0 - 2, w0, domain='ZZ'), Lambda(_a, 2), Lambda(_a, -_a + x), 1)]) + assert dummy_eq(got, ans) + + got = apart_list(2/(x**2-2), x, dummies=numbered_symbols("w")) + ans = (1, Poly(0, x, domain='ZZ'), [(Poly(w0**2 - 2, w0, domain='ZZ'), + Lambda(_a, _a/2), + Lambda(_a, -_a + x), 1)]) + assert dummy_eq(got, ans) + + f = 36 / (x**5 - 2*x**4 - 2*x**3 + 4*x**2 + x - 2) + got = apart_list(f, x, dummies=numbered_symbols("w")) + ans = (1, Poly(0, x, domain='ZZ'), + [(Poly(w0 - 2, w0, domain='ZZ'), Lambda(_a, 4), Lambda(_a, -_a + x), 1), + (Poly(w1**2 - 1, w1, domain='ZZ'), Lambda(_a, -3*_a - 6), Lambda(_a, -_a + x), 2), + (Poly(w2 + 1, w2, domain='ZZ'), Lambda(_a, -4), Lambda(_a, -_a + x), 1)]) + assert dummy_eq(got, ans) + + +def test_assemble_partfrac_list(): + f = 36 / (x**5 - 2*x**4 - 2*x**3 + 4*x**2 + x - 2) + pfd = apart_list(f) + assert assemble_partfrac_list(pfd) == -4/(x + 1) - 3/(x + 1)**2 - 9/(x - 1)**2 + 4/(x - 2) + + a = Dummy("a") + pfd = (1, Poly(0, x, domain='ZZ'), [([sqrt(2),-sqrt(2)], Lambda(a, a/2), Lambda(a, -a + x), 1)]) + assert assemble_partfrac_list(pfd) == -1/(sqrt(2)*(x + sqrt(2))) + 1/(sqrt(2)*(x - sqrt(2))) + + +@XFAIL +def test_noncommutative_pseudomultivariate(): + # apart doesn't go inside noncommutative expressions + class foo(Expr): + is_commutative=False + e = x/(x + x*y) + c = 1/(1 + y) + assert apart(e + foo(e)) == c + foo(c) + assert apart(e*foo(e)) == c*foo(c) + +def test_noncommutative(): + class foo(Expr): + is_commutative=False + e = x/(x + x*y) + c = 1/(1 + y) + assert apart(e + foo()) == c + foo() + +def test_issue_5798(): + assert apart( + 2*x/(x**2 + 1) - (x - 1)/(2*(x**2 + 1)) + 1/(2*(x + 1)) - 2/x) == \ + (3*x + 1)/(x**2 + 1)/2 + 1/(x + 1)/2 - 2/x diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyclasses.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyclasses.py new file mode 100644 index 0000000000000000000000000000000000000000..5e2c8f2c3ca94c42fc524c3ec1c0300d881cf3a5 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyclasses.py @@ -0,0 +1,601 @@ +"""Tests for OO layer of several polynomial representations. """ + +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.polys.domains import ZZ, QQ +from sympy.polys.polyclasses import DMP, DMF, ANP +from sympy.polys.polyerrors import (CoercionFailed, ExactQuotientFailed, + NotInvertible) +from sympy.polys.specialpolys import f_polys +from sympy.testing.pytest import raises, warns_deprecated_sympy + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = [ f.to_dense() for f in f_polys() ] + +def test_DMP___init__(): + f = DMP([[ZZ(0)], [], [ZZ(0), ZZ(1), ZZ(2)], [ZZ(3)]], ZZ) + + assert f._rep == [[1, 2], [3]] + assert f.dom == ZZ + assert f.lev == 1 + + f = DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ, 1) + + assert f._rep == [[1, 2], [3]] + assert f.dom == ZZ + assert f.lev == 1 + + f = DMP.from_dict({(1, 1): ZZ(1), (0, 0): ZZ(2)}, 1, ZZ) + + assert f._rep == [[1, 0], [2]] + assert f.dom == ZZ + assert f.lev == 1 + + +def test_DMP_rep_deprecation(): + f = DMP([1, 2, 3], ZZ) + + with warns_deprecated_sympy(): + assert f.rep == [1, 2, 3] + + +def test_DMP___eq__(): + assert DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ) == \ + DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ) + + assert DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ) == \ + DMP([[QQ(1), QQ(2)], [QQ(3)]], QQ) + assert DMP([[QQ(1), QQ(2)], [QQ(3)]], QQ) == \ + DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ) + + assert DMP([[[ZZ(1)]]], ZZ) != DMP([[ZZ(1)]], ZZ) + assert DMP([[ZZ(1)]], ZZ) != DMP([[[ZZ(1)]]], ZZ) + + +def test_DMP___bool__(): + assert bool(DMP([[]], ZZ)) is False + assert bool(DMP([[ZZ(1)]], ZZ)) is True + + +def test_DMP_to_dict(): + f = DMP([[ZZ(3)], [], [ZZ(2)], [], [ZZ(8)]], ZZ) + + assert f.to_dict() == \ + {(4, 0): 3, (2, 0): 2, (0, 0): 8} + assert f.to_sympy_dict() == \ + {(4, 0): ZZ.to_sympy(3), (2, 0): ZZ.to_sympy(2), (0, 0): + ZZ.to_sympy(8)} + + +def test_DMP_properties(): + assert DMP([[]], ZZ).is_zero is True + assert DMP([[ZZ(1)]], ZZ).is_zero is False + + assert DMP([[ZZ(1)]], ZZ).is_one is True + assert DMP([[ZZ(2)]], ZZ).is_one is False + + assert DMP([[ZZ(1)]], ZZ).is_ground is True + assert DMP([[ZZ(1)], [ZZ(2)], [ZZ(1)]], ZZ).is_ground is False + + assert DMP([[ZZ(1)], [ZZ(2), ZZ(0)], [ZZ(1), ZZ(0)]], ZZ).is_sqf is True + assert DMP([[ZZ(1)], [ZZ(2), ZZ(0)], [ZZ(1), ZZ(0), ZZ(0)]], ZZ).is_sqf is False + + assert DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ).is_monic is True + assert DMP([[ZZ(2), ZZ(2)], [ZZ(3)]], ZZ).is_monic is False + + assert DMP([[ZZ(1), ZZ(2)], [ZZ(3)]], ZZ).is_primitive is True + assert DMP([[ZZ(2), ZZ(4)], [ZZ(6)]], ZZ).is_primitive is False + + +def test_DMP_arithmetics(): + f = DMP([[ZZ(2)], [ZZ(2), ZZ(0)]], ZZ) + + assert f.mul_ground(2) == DMP([[ZZ(4)], [ZZ(4), ZZ(0)]], ZZ) + assert f.quo_ground(2) == DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + + raises(ExactQuotientFailed, lambda: f.exquo_ground(3)) + + f = DMP([[ZZ(-5)]], ZZ) + g = DMP([[ZZ(5)]], ZZ) + + assert f.abs() == g + assert abs(f) == g + + assert g.neg() == f + assert -g == f + + h = DMP([[]], ZZ) + + assert f.add(g) == h + assert f + g == h + assert g + f == h + assert f + 5 == h + assert 5 + f == h + + h = DMP([[ZZ(-10)]], ZZ) + + assert f.sub(g) == h + assert f - g == h + assert g - f == -h + assert f - 5 == h + assert 5 - f == -h + + h = DMP([[ZZ(-25)]], ZZ) + + assert f.mul(g) == h + assert f * g == h + assert g * f == h + assert f * 5 == h + assert 5 * f == h + + h = DMP([[ZZ(25)]], ZZ) + + assert f.sqr() == h + assert f.pow(2) == h + assert f**2 == h + + raises(TypeError, lambda: f.pow('x')) + + f = DMP([[ZZ(1)], [], [ZZ(1), ZZ(0), ZZ(0)]], ZZ) + g = DMP([[ZZ(2)], [ZZ(-2), ZZ(0)]], ZZ) + + q = DMP([[ZZ(2)], [ZZ(2), ZZ(0)]], ZZ) + r = DMP([[ZZ(8), ZZ(0), ZZ(0)]], ZZ) + + assert f.pdiv(g) == (q, r) + assert f.pquo(g) == q + assert f.prem(g) == r + + raises(ExactQuotientFailed, lambda: f.pexquo(g)) + + f = DMP([[ZZ(1)], [], [ZZ(1), ZZ(0), ZZ(0)]], ZZ) + g = DMP([[ZZ(1)], [ZZ(-1), ZZ(0)]], ZZ) + + q = DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + r = DMP([[ZZ(2), ZZ(0), ZZ(0)]], ZZ) + + assert f.div(g) == (q, r) + assert f.quo(g) == q + assert f.rem(g) == r + + assert divmod(f, g) == (q, r) + assert f // g == q + assert f % g == r + + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f = DMP([ZZ(1), ZZ(0), ZZ(-1)], ZZ) + g = DMP([ZZ(2), ZZ(-2)], ZZ) + + q = DMP([], ZZ) + r = f + + pq = DMP([ZZ(2), ZZ(2)], ZZ) + pr = DMP([], ZZ) + + assert f.div(g) == (q, r) + assert f.quo(g) == q + assert f.rem(g) == r + + assert divmod(f, g) == (q, r) + assert f // g == q + assert f % g == r + + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + assert f.pdiv(g) == (pq, pr) + assert f.pquo(g) == pq + assert f.prem(g) == pr + assert f.pexquo(g) == pq + + +def test_DMP_functionality(): + f = DMP([[ZZ(1)], [ZZ(2), ZZ(0)], [ZZ(1), ZZ(0), ZZ(0)]], ZZ) + g = DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + h = DMP([[ZZ(1)]], ZZ) + + assert f.degree() == 2 + assert f.degree_list() == (2, 2) + assert f.total_degree() == 2 + + assert f.LC() == ZZ(1) + assert f.TC() == ZZ(0) + assert f.nth(1, 1) == ZZ(2) + + raises(TypeError, lambda: f.nth(0, 'x')) + + assert f.max_norm() == 2 + assert f.l1_norm() == 4 + + u = DMP([[ZZ(2)], [ZZ(2), ZZ(0)]], ZZ) + + assert f.diff(m=1, j=0) == u + assert f.diff(m=1, j=1) == u + + raises(TypeError, lambda: f.diff(m='x', j=0)) + + u = DMP([ZZ(1), ZZ(2), ZZ(1)], ZZ) + v = DMP([ZZ(1), ZZ(2), ZZ(1)], ZZ) + + assert f.eval(a=1, j=0) == u + assert f.eval(a=1, j=1) == v + + assert f.eval(1).eval(1) == ZZ(4) + + assert f.cofactors(g) == (g, g, h) + assert f.gcd(g) == g + assert f.lcm(g) == f + + u = DMP([[QQ(45), QQ(30), QQ(5)]], QQ) + v = DMP([[QQ(1), QQ(2, 3), QQ(1, 9)]], QQ) + + assert u.monic() == v + + assert (4*f).content() == ZZ(4) + assert (4*f).primitive() == (ZZ(4), f) + + f = DMP([QQ(1,3), QQ(1)], QQ) + g = DMP([QQ(1,7), QQ(1)], QQ) + + assert f.cancel(g) == f.cancel(g, include=True) == ( + DMP([QQ(7), QQ(21)], QQ), + DMP([QQ(3), QQ(21)], QQ) + ) + assert f.cancel(g, include=False) == ( + QQ(7), + QQ(3), + DMP([QQ(1), QQ(3)], QQ), + DMP([QQ(1), QQ(7)], QQ) + ) + + f = DMP([[ZZ(1)], [ZZ(2)], [ZZ(3)], [ZZ(4)], [ZZ(5)], [ZZ(6)]], ZZ) + + assert f.trunc(3) == DMP([[ZZ(1)], [ZZ(-1)], [], [ZZ(1)], [ZZ(-1)], []], ZZ) + + f = DMP(f_4, ZZ) + + assert f.sqf_part() == -f + assert f.sqf_list() == (ZZ(-1), [(-f, 1)]) + + f = DMP([[ZZ(-1)], [], [], [ZZ(5)]], ZZ) + g = DMP([[ZZ(3), ZZ(1)], [], []], ZZ) + h = DMP([[ZZ(45), ZZ(30), ZZ(5)]], ZZ) + + r = DMP([ZZ(675), ZZ(675), ZZ(225), ZZ(25)], ZZ) + + assert f.subresultants(g) == [f, g, h] + assert f.resultant(g) == r + + f = DMP([ZZ(1), ZZ(3), ZZ(9), ZZ(-13)], ZZ) + + assert f.discriminant() == -11664 + + f = DMP([QQ(2), QQ(0)], QQ) + g = DMP([QQ(1), QQ(0), QQ(-16)], QQ) + + s = DMP([QQ(1, 32), QQ(0)], QQ) + t = DMP([QQ(-1, 16)], QQ) + h = DMP([QQ(1)], QQ) + + assert f.half_gcdex(g) == (s, h) + assert f.gcdex(g) == (s, t, h) + + assert f.invert(g) == s + + f = DMP([[QQ(1)], [QQ(2)], [QQ(3)]], QQ) + + raises(ValueError, lambda: f.half_gcdex(f)) + raises(ValueError, lambda: f.gcdex(f)) + + raises(ValueError, lambda: f.invert(f)) + + f = DMP(ZZ.map([1, 0, 20, 0, 150, 0, 500, 0, 625, -2, 0, -10, 9]), ZZ) + g = DMP([ZZ(1), ZZ(0), ZZ(0), ZZ(-2), ZZ(9)], ZZ) + h = DMP([ZZ(1), ZZ(0), ZZ(5), ZZ(0)], ZZ) + + assert g.compose(h) == f + assert f.decompose() == [g, h] + + f = DMP([[QQ(1)], [QQ(2)], [QQ(3)]], QQ) + + raises(ValueError, lambda: f.decompose()) + raises(ValueError, lambda: f.sturm()) + + +def test_DMP_exclude(): + f = [[[[[[[[[[[[[[[[[[[[[[[[[[ZZ(1)]], [[]]]]]]]]]]]]]]]]]]]]]]]]]] + J = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, + 18, 19, 20, 21, 22, 24, 25] + + assert DMP(f, ZZ).exclude() == (J, DMP([ZZ(1), ZZ(0)], ZZ)) + assert DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ).exclude() ==\ + ([], DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ)) + + +def test_DMF__init__(): + f = DMF(([[0], [], [0, 1, 2], [3]], [[1, 2, 3]]), ZZ) + + assert f.num == [[1, 2], [3]] + assert f.den == [[1, 2, 3]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[1, 2], [3]], [[1, 2, 3]]), ZZ, 1) + + assert f.num == [[1, 2], [3]] + assert f.den == [[1, 2, 3]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[-1], [-2]], [[3], [-4]]), ZZ) + + assert f.num == [[-1], [-2]] + assert f.den == [[3], [-4]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[1], [2]], [[-3], [4]]), ZZ) + + assert f.num == [[-1], [-2]] + assert f.den == [[3], [-4]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[1], [2]], [[-3], [4]]), ZZ) + + assert f.num == [[-1], [-2]] + assert f.den == [[3], [-4]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[]], [[-3], [4]]), ZZ) + + assert f.num == [[]] + assert f.den == [[1]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(17, ZZ, 1) + + assert f.num == [[17]] + assert f.den == [[1]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[1], [2]]), ZZ) + + assert f.num == [[1], [2]] + assert f.den == [[1]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF([[0], [], [0, 1, 2], [3]], ZZ) + + assert f.num == [[1, 2], [3]] + assert f.den == [[1]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF({(1, 1): 1, (0, 0): 2}, ZZ, 1) + + assert f.num == [[1, 0], [2]] + assert f.den == [[1]] + assert f.lev == 1 + assert f.dom == ZZ + + f = DMF(([[QQ(1)], [QQ(2)]], [[-QQ(3)], [QQ(4)]]), QQ) + + assert f.num == [[-QQ(1)], [-QQ(2)]] + assert f.den == [[QQ(3)], [-QQ(4)]] + assert f.lev == 1 + assert f.dom == QQ + + f = DMF(([[QQ(1, 5)], [QQ(2, 5)]], [[-QQ(3, 7)], [QQ(4, 7)]]), QQ) + + assert f.num == [[-QQ(7)], [-QQ(14)]] + assert f.den == [[QQ(15)], [-QQ(20)]] + assert f.lev == 1 + assert f.dom == QQ + + raises(ValueError, lambda: DMF(([1], [[1]]), ZZ)) + raises(ZeroDivisionError, lambda: DMF(([1], []), ZZ)) + + +def test_DMF__bool__(): + assert bool(DMF([[]], ZZ)) is False + assert bool(DMF([[1]], ZZ)) is True + + +def test_DMF_properties(): + assert DMF([[]], ZZ).is_zero is True + assert DMF([[]], ZZ).is_one is False + + assert DMF([[1]], ZZ).is_zero is False + assert DMF([[1]], ZZ).is_one is True + + assert DMF(([[1]], [[2]]), ZZ).is_one is False + + +def test_DMF_arithmetics(): + f = DMF([[7], [-9]], ZZ) + g = DMF([[-7], [9]], ZZ) + + assert f.neg() == -f == g + + f = DMF(([[1]], [[1], []]), ZZ) + g = DMF(([[1]], [[1, 0]]), ZZ) + + h = DMF(([[1], [1, 0]], [[1, 0], []]), ZZ) + + assert f.add(g) == f + g == h + assert g.add(f) == g + f == h + + h = DMF(([[-1], [1, 0]], [[1, 0], []]), ZZ) + + assert f.sub(g) == f - g == h + + h = DMF(([[1]], [[1, 0], []]), ZZ) + + assert f.mul(g) == f*g == h + assert g.mul(f) == g*f == h + + h = DMF(([[1, 0]], [[1], []]), ZZ) + + assert f.quo(g) == f/g == h + + h = DMF(([[1]], [[1], [], [], []]), ZZ) + + assert f.pow(3) == f**3 == h + + h = DMF(([[1]], [[1, 0, 0, 0]]), ZZ) + + assert g.pow(3) == g**3 == h + + h = DMF(([[1, 0]], [[1]]), ZZ) + + assert g.pow(-1) == g**-1 == h + + +def test_ANP___init__(): + rep = [QQ(1), QQ(1)] + mod = [QQ(1), QQ(0), QQ(1)] + + f = ANP(rep, mod, QQ) + + assert f.to_list() == [QQ(1), QQ(1)] + assert f.mod_to_list() == [QQ(1), QQ(0), QQ(1)] + assert f.dom == QQ + + rep = {1: QQ(1), 0: QQ(1)} + mod = {2: QQ(1), 0: QQ(1)} + + f = ANP(rep, mod, QQ) + + assert f.to_list() == [QQ(1), QQ(1)] + assert f.mod_to_list() == [QQ(1), QQ(0), QQ(1)] + assert f.dom == QQ + + f = ANP(1, mod, QQ) + + assert f.to_list() == [QQ(1)] + assert f.mod_to_list() == [QQ(1), QQ(0), QQ(1)] + assert f.dom == QQ + + f = ANP([1, 0.5], mod, QQ) + + assert all(QQ.of_type(a) for a in f.to_list()) + + raises(CoercionFailed, lambda: ANP([sqrt(2)], mod, QQ)) + + +def test_ANP___eq__(): + a = ANP([QQ(1), QQ(1)], [QQ(1), QQ(0), QQ(1)], QQ) + b = ANP([QQ(1), QQ(1)], [QQ(1), QQ(0), QQ(2)], QQ) + + assert (a == a) is True + assert (a != a) is False + + assert (a == b) is False + assert (a != b) is True + + b = ANP([QQ(1), QQ(2)], [QQ(1), QQ(0), QQ(1)], QQ) + + assert (a == b) is False + assert (a != b) is True + + +def test_ANP___bool__(): + assert bool(ANP([], [QQ(1), QQ(0), QQ(1)], QQ)) is False + assert bool(ANP([QQ(1)], [QQ(1), QQ(0), QQ(1)], QQ)) is True + + +def test_ANP_properties(): + mod = [QQ(1), QQ(0), QQ(1)] + + assert ANP([QQ(0)], mod, QQ).is_zero is True + assert ANP([QQ(1)], mod, QQ).is_zero is False + + assert ANP([QQ(1)], mod, QQ).is_one is True + assert ANP([QQ(2)], mod, QQ).is_one is False + + +def test_ANP_arithmetics(): + mod = [QQ(1), QQ(0), QQ(0), QQ(-2)] + + a = ANP([QQ(2), QQ(-1), QQ(1)], mod, QQ) + b = ANP([QQ(1), QQ(2)], mod, QQ) + + c = ANP([QQ(-2), QQ(1), QQ(-1)], mod, QQ) + + assert a.neg() == -a == c + + c = ANP([QQ(2), QQ(0), QQ(3)], mod, QQ) + + assert a.add(b) == a + b == c + assert b.add(a) == b + a == c + + c = ANP([QQ(2), QQ(-2), QQ(-1)], mod, QQ) + + assert a.sub(b) == a - b == c + + c = ANP([QQ(-2), QQ(2), QQ(1)], mod, QQ) + + assert b.sub(a) == b - a == c + + c = ANP([QQ(3), QQ(-1), QQ(6)], mod, QQ) + + assert a.mul(b) == a*b == c + assert b.mul(a) == b*a == c + + c = ANP([QQ(-1, 43), QQ(9, 43), QQ(5, 43)], mod, QQ) + + assert a.pow(0) == a**(0) == ANP(1, mod, QQ) + assert a.pow(1) == a**(1) == a + + assert a.pow(-1) == a**(-1) == c + + assert a.quo(a) == a.mul(a.pow(-1)) == a*a**(-1) == ANP(1, mod, QQ) + + c = ANP([], [1, 0, 0, -2], QQ) + r1 = a.rem(b) + + (q, r2) = a.div(b) + + assert r1 == r2 == c == a % b + + raises(NotInvertible, lambda: a.div(c)) + raises(NotInvertible, lambda: a.rem(c)) + + # Comparison with "hard-coded" value fails despite looking identical + # from sympy import Rational + # c = ANP([Rational(11, 10), Rational(-1, 5), Rational(-3, 5)], [1, 0, 0, -2], QQ) + + assert q == a/b # == c + +def test_ANP_unify(): + mod_z = [ZZ(1), ZZ(0), ZZ(-2)] + mod_q = [QQ(1), QQ(0), QQ(-2)] + + a = ANP([QQ(1)], mod_q, QQ) + b = ANP([ZZ(1)], mod_z, ZZ) + + assert a.unify(b)[0] == QQ + assert b.unify(a)[0] == QQ + assert a.unify(a)[0] == QQ + assert b.unify(b)[0] == ZZ + + assert a.unify_ANP(b)[-1] == QQ + assert b.unify_ANP(a)[-1] == QQ + assert a.unify_ANP(a)[-1] == QQ + assert b.unify_ANP(b)[-1] == ZZ + + +def test_zero_poly(): + from sympy import Symbol + x = Symbol('x') + + R_old = ZZ.old_poly_ring(x) + zero_poly_old = R_old(0) + cont_old, prim_old = zero_poly_old.primitive() + + assert cont_old == 0 + assert prim_old == zero_poly_old + assert prim_old.is_primitive is False diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyfuncs.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyfuncs.py new file mode 100644 index 0000000000000000000000000000000000000000..496f63bf14e4dd9f68cf653004eb35a3ed7615ca --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyfuncs.py @@ -0,0 +1,126 @@ +"""Tests for high-level polynomials manipulation functions. """ + +from sympy.polys.polyfuncs import ( + symmetrize, horner, interpolate, rational_interpolate, viete, +) + +from sympy.polys.polyerrors import ( + MultivariatePolynomialError, +) + +from sympy.core.singleton import S +from sympy.core.symbol import symbols +from sympy.testing.pytest import raises + +from sympy.abc import a, b, c, d, e, x, y, z + + +def test_symmetrize(): + assert symmetrize(0, x, y, z) == (0, 0) + assert symmetrize(1, x, y, z) == (1, 0) + + s1 = x + y + z + s2 = x*y + x*z + y*z + + assert symmetrize(1) == (1, 0) + assert symmetrize(1, formal=True) == (1, 0, []) + + assert symmetrize(x) == (x, 0) + assert symmetrize(x + 1) == (x + 1, 0) + + assert symmetrize(x, x, y) == (x + y, -y) + assert symmetrize(x + 1, x, y) == (x + y + 1, -y) + + assert symmetrize(x, x, y, z) == (s1, -y - z) + assert symmetrize(x + 1, x, y, z) == (s1 + 1, -y - z) + + assert symmetrize(x**2, x, y, z) == (s1**2 - 2*s2, -y**2 - z**2) + + assert symmetrize(x**2 + y**2) == (-2*x*y + (x + y)**2, 0) + assert symmetrize(x**2 - y**2) == (-2*x*y + (x + y)**2, -2*y**2) + + assert symmetrize(x**3 + y**2 + a*x**2 + b*y**3, x, y) == \ + (-3*x*y*(x + y) - 2*a*x*y + a*(x + y)**2 + (x + y)**3, + y**2*(1 - a) + y**3*(b - 1)) + + U = [u0, u1, u2] = symbols('u:3') + + assert symmetrize(x + 1, x, y, z, formal=True, symbols=U) == \ + (u0 + 1, -y - z, [(u0, x + y + z), (u1, x*y + x*z + y*z), (u2, x*y*z)]) + + assert symmetrize([1, 2, 3]) == [(1, 0), (2, 0), (3, 0)] + assert symmetrize([1, 2, 3], formal=True) == ([(1, 0), (2, 0), (3, 0)], []) + + assert symmetrize([x + y, x - y]) == [(x + y, 0), (x + y, -2*y)] + + +def test_horner(): + assert horner(0) == 0 + assert horner(1) == 1 + assert horner(x) == x + + assert horner(x + 1) == x + 1 + assert horner(x**2 + 1) == x**2 + 1 + assert horner(x**2 + x) == (x + 1)*x + assert horner(x**2 + x + 1) == (x + 1)*x + 1 + + assert horner( + 9*x**4 + 8*x**3 + 7*x**2 + 6*x + 5) == (((9*x + 8)*x + 7)*x + 6)*x + 5 + assert horner( + a*x**4 + b*x**3 + c*x**2 + d*x + e) == (((a*x + b)*x + c)*x + d)*x + e + + assert horner(4*x**2*y**2 + 2*x**2*y + 2*x*y**2 + x*y, wrt=x) == (( + 4*y + 2)*x*y + (2*y + 1)*y)*x + assert horner(4*x**2*y**2 + 2*x**2*y + 2*x*y**2 + x*y, wrt=y) == (( + 4*x + 2)*y*x + (2*x + 1)*x)*y + + +def test_interpolate(): + assert interpolate([1, 4, 9, 16], x) == x**2 + assert interpolate([1, 4, 9, 25], x) == S(3)*x**3/2 - S(8)*x**2 + S(33)*x/2 - 9 + assert interpolate([(1, 1), (2, 4), (3, 9)], x) == x**2 + assert interpolate([(1, 2), (2, 5), (3, 10)], x) == 1 + x**2 + assert interpolate({1: 2, 2: 5, 3: 10}, x) == 1 + x**2 + assert interpolate({5: 2, 7: 5, 8: 10, 9: 13}, x) == \ + -S(13)*x**3/24 + S(12)*x**2 - S(2003)*x/24 + 187 + assert interpolate([(1, 3), (0, 6), (2, 5), (5, 7), (-2, 4)], x) == \ + S(-61)*x**4/280 + S(247)*x**3/210 + S(139)*x**2/280 - S(1871)*x/420 + 6 + assert interpolate((9, 4, 9), 3) == 9 + assert interpolate((1, 9, 16), 1) is S.One + assert interpolate(((x, 1), (2, 3)), x) is S.One + assert interpolate({x: 1, 2: 3}, x) is S.One + assert interpolate(((2, x), (1, 3)), x) == x**2 - 4*x + 6 + + +def test_rational_interpolate(): + x, y = symbols('x,y') + xdata = [1, 2, 3, 4, 5, 6] + ydata1 = [120, 150, 200, 255, 312, 370] + ydata2 = [-210, -35, 105, 231, 350, 465] + assert rational_interpolate(list(zip(xdata, ydata1)), 2) == ( + (60*x**2 + 60)/x ) + assert rational_interpolate(list(zip(xdata, ydata1)), 3) == ( + (60*x**2 + 60)/x ) + assert rational_interpolate(list(zip(xdata, ydata2)), 2, X=y) == ( + (105*y**2 - 525)/(y + 1) ) + xdata = list(range(1,11)) + ydata = [-1923885361858460, -5212158811973685, -9838050145867125, + -15662936261217245, -22469424125057910, -30073793365223685, + -38332297297028735, -47132954289530109, -56387719094026320, + -66026548943876885] + assert rational_interpolate(list(zip(xdata, ydata)), 5) == ( + (-12986226192544605*x**4 + + 8657484128363070*x**3 - 30301194449270745*x**2 + 4328742064181535*x + - 4328742064181535)/(x**3 + 9*x**2 - 3*x + 11)) + + +def test_viete(): + r1, r2 = symbols('r1, r2') + + assert viete( + a*x**2 + b*x + c, [r1, r2], x) == [(r1 + r2, -b/a), (r1*r2, c/a)] + + raises(ValueError, lambda: viete(1, [], x)) + raises(ValueError, lambda: viete(x**2 + 1, [r1])) + + raises(MultivariatePolynomialError, lambda: viete(x + y, [r1])) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polymatrix.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polymatrix.py new file mode 100644 index 0000000000000000000000000000000000000000..287f23d537392510acda094e764a8c3dbbd1ef73 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polymatrix.py @@ -0,0 +1,185 @@ +from sympy.testing.pytest import raises + +from sympy.polys.polymatrix import PolyMatrix +from sympy.polys import Poly + +from sympy.core.singleton import S +from sympy.matrices.dense import Matrix +from sympy.polys.domains.integerring import ZZ +from sympy.polys.domains.rationalfield import QQ + +from sympy.abc import x, y + + +def _test_polymatrix(): + pm1 = PolyMatrix([[Poly(x**2, x), Poly(-x, x)], [Poly(x**3, x), Poly(-1 + x, x)]]) + v1 = PolyMatrix([[1, 0], [-1, 0]], ring='ZZ[x]') + m1 = PolyMatrix([[1, 0], [-1, 0]], ring='ZZ[x]') + A = PolyMatrix([[Poly(x**2 + x, x), Poly(0, x)], \ + [Poly(x**3 - x + 1, x), Poly(0, x)]]) + B = PolyMatrix([[Poly(x**2, x), Poly(-x, x)], [Poly(-x**2, x), Poly(x, x)]]) + assert A.ring == ZZ[x] + assert isinstance(pm1*v1, PolyMatrix) + assert pm1*v1 == A + assert pm1*m1 == A + assert v1*pm1 == B + + pm2 = PolyMatrix([[Poly(x**2, x, domain='QQ'), Poly(0, x, domain='QQ'), Poly(-x**2, x, domain='QQ'), \ + Poly(x**3, x, domain='QQ'), Poly(0, x, domain='QQ'), Poly(-x**3, x, domain='QQ')]]) + assert pm2.ring == QQ[x] + v2 = PolyMatrix([1, 0, 0, 0, 0, 0], ring='ZZ[x]') + m2 = PolyMatrix([1, 0, 0, 0, 0, 0], ring='ZZ[x]') + C = PolyMatrix([[Poly(x**2, x, domain='QQ')]]) + assert pm2*v2 == C + assert pm2*m2 == C + + pm3 = PolyMatrix([[Poly(x**2, x), S.One]], ring='ZZ[x]') + v3 = S.Half*pm3 + assert v3 == PolyMatrix([[Poly(S.Half*x**2, x, domain='QQ'), S.Half]], ring='QQ[x]') + assert pm3*S.Half == v3 + assert v3.ring == QQ[x] + + pm4 = PolyMatrix([[Poly(x**2, x, domain='ZZ'), Poly(-x**2, x, domain='ZZ')]]) + v4 = PolyMatrix([1, -1], ring='ZZ[x]') + assert pm4*v4 == PolyMatrix([[Poly(2*x**2, x, domain='ZZ')]]) + + assert len(PolyMatrix(ring=ZZ[x])) == 0 + assert PolyMatrix([1, 0, 0, 1], x)/(-1) == PolyMatrix([-1, 0, 0, -1], x) + + +def test_polymatrix_constructor(): + M1 = PolyMatrix([[x, y]], ring=QQ[x,y]) + assert M1.ring == QQ[x,y] + assert M1.domain == QQ + assert M1.gens == (x, y) + assert M1.shape == (1, 2) + assert M1.rows == 1 + assert M1.cols == 2 + assert len(M1) == 2 + assert list(M1) == [Poly(x, (x, y), domain=QQ), Poly(y, (x, y), domain=QQ)] + + M2 = PolyMatrix([[x, y]], ring=QQ[x][y]) + assert M2.ring == QQ[x][y] + assert M2.domain == QQ[x] + assert M2.gens == (y,) + assert M2.shape == (1, 2) + assert M2.rows == 1 + assert M2.cols == 2 + assert len(M2) == 2 + assert list(M2) == [Poly(x, (y,), domain=QQ[x]), Poly(y, (y,), domain=QQ[x])] + + assert PolyMatrix([[x, y]], y) == PolyMatrix([[x, y]], ring=ZZ.frac_field(x)[y]) + assert PolyMatrix([[x, y]], ring='ZZ[x,y]') == PolyMatrix([[x, y]], ring=ZZ[x,y]) + + assert PolyMatrix([[x, y]], (x, y)) == PolyMatrix([[x, y]], ring=QQ[x,y]) + assert PolyMatrix([[x, y]], x, y) == PolyMatrix([[x, y]], ring=QQ[x,y]) + assert PolyMatrix([x, y]) == PolyMatrix([[x], [y]], ring=QQ[x,y]) + assert PolyMatrix(1, 2, [x, y]) == PolyMatrix([[x, y]], ring=QQ[x,y]) + assert PolyMatrix(1, 2, lambda i,j: [x,y][j]) == PolyMatrix([[x, y]], ring=QQ[x,y]) + assert PolyMatrix(0, 2, [], x, y).shape == (0, 2) + assert PolyMatrix(2, 0, [], x, y).shape == (2, 0) + assert PolyMatrix([[], []], x, y).shape == (2, 0) + assert PolyMatrix(ring=QQ[x,y]) == PolyMatrix(0, 0, [], ring=QQ[x,y]) == PolyMatrix([], ring=QQ[x,y]) + raises(TypeError, lambda: PolyMatrix()) + raises(TypeError, lambda: PolyMatrix(1)) + + assert PolyMatrix([Poly(x), Poly(y)]) == PolyMatrix([[x], [y]], ring=ZZ[x,y]) + + # XXX: Maybe a bug in parallel_poly_from_expr (x lost from gens and domain): + assert PolyMatrix([Poly(y, x), 1]) == PolyMatrix([[y], [1]], ring=QQ[y]) + + +def test_polymatrix_eq(): + assert (PolyMatrix([x]) == PolyMatrix([x])) is True + assert (PolyMatrix([y]) == PolyMatrix([x])) is False + assert (PolyMatrix([x]) != PolyMatrix([x])) is False + assert (PolyMatrix([y]) != PolyMatrix([x])) is True + + assert PolyMatrix([[x, y]]) != PolyMatrix([x, y]) == PolyMatrix([[x], [y]]) + + assert PolyMatrix([x], ring=QQ[x]) != PolyMatrix([x], ring=ZZ[x]) + + assert PolyMatrix([x]) != Matrix([x]) + assert PolyMatrix([x]).to_Matrix() == Matrix([x]) + + assert PolyMatrix([1], x) == PolyMatrix([1], x) + assert PolyMatrix([1], x) != PolyMatrix([1], y) + + +def test_polymatrix_from_Matrix(): + assert PolyMatrix.from_Matrix(Matrix([1, 2]), x) == PolyMatrix([1, 2], x, ring=QQ[x]) + assert PolyMatrix.from_Matrix(Matrix([1]), ring=QQ[x]) == PolyMatrix([1], x) + pmx = PolyMatrix([1, 2], x) + pmy = PolyMatrix([1, 2], y) + assert pmx != pmy + assert pmx.set_gens(y) == pmy + + +def test_polymatrix_repr(): + assert repr(PolyMatrix([[1, 2]], x)) == 'PolyMatrix([[1, 2]], ring=QQ[x])' + assert repr(PolyMatrix(0, 2, [], x)) == 'PolyMatrix(0, 2, [], ring=QQ[x])' + + +def test_polymatrix_getitem(): + M = PolyMatrix([[1, 2], [3, 4]], x) + assert M[:, :] == M + assert M[0, :] == PolyMatrix([[1, 2]], x) + assert M[:, 0] == PolyMatrix([1, 3], x) + assert M[0, 0] == Poly(1, x, domain=QQ) + assert M[0] == Poly(1, x, domain=QQ) + assert M[:2] == [Poly(1, x, domain=QQ), Poly(2, x, domain=QQ)] + + +def test_polymatrix_arithmetic(): + M = PolyMatrix([[1, 2], [3, 4]], x) + assert M + M == PolyMatrix([[2, 4], [6, 8]], x) + assert M - M == PolyMatrix([[0, 0], [0, 0]], x) + assert -M == PolyMatrix([[-1, -2], [-3, -4]], x) + raises(TypeError, lambda: M + 1) + raises(TypeError, lambda: M - 1) + raises(TypeError, lambda: 1 + M) + raises(TypeError, lambda: 1 - M) + + assert M * M == PolyMatrix([[7, 10], [15, 22]], x) + assert 2 * M == PolyMatrix([[2, 4], [6, 8]], x) + assert M * 2 == PolyMatrix([[2, 4], [6, 8]], x) + assert S(2) * M == PolyMatrix([[2, 4], [6, 8]], x) + assert M * S(2) == PolyMatrix([[2, 4], [6, 8]], x) + raises(TypeError, lambda: [] * M) + raises(TypeError, lambda: M * []) + M2 = PolyMatrix([[1, 2]], ring=ZZ[x]) + assert S.Half * M2 == PolyMatrix([[S.Half, 1]], ring=QQ[x]) + assert M2 * S.Half == PolyMatrix([[S.Half, 1]], ring=QQ[x]) + + assert M / 2 == PolyMatrix([[S(1)/2, 1], [S(3)/2, 2]], x) + assert M / Poly(2, x) == PolyMatrix([[S(1)/2, 1], [S(3)/2, 2]], x) + raises(TypeError, lambda: M / []) + + +def test_polymatrix_manipulations(): + M1 = PolyMatrix([[1, 2], [3, 4]], x) + assert M1.transpose() == PolyMatrix([[1, 3], [2, 4]], x) + M2 = PolyMatrix([[5, 6], [7, 8]], x) + assert M1.row_join(M2) == PolyMatrix([[1, 2, 5, 6], [3, 4, 7, 8]], x) + assert M1.col_join(M2) == PolyMatrix([[1, 2], [3, 4], [5, 6], [7, 8]], x) + assert M1.applyfunc(lambda e: 2*e) == PolyMatrix([[2, 4], [6, 8]], x) + + +def test_polymatrix_ones_zeros(): + assert PolyMatrix.zeros(1, 2, x) == PolyMatrix([[0, 0]], x) + assert PolyMatrix.eye(2, x) == PolyMatrix([[1, 0], [0, 1]], x) + + +def test_polymatrix_rref(): + M = PolyMatrix([[1, 2], [3, 4]], x) + assert M.rref() == (PolyMatrix.eye(2, x), (0, 1)) + raises(ValueError, lambda: PolyMatrix([1, 2], ring=ZZ[x]).rref()) + raises(ValueError, lambda: PolyMatrix([1, x], ring=QQ[x]).rref()) + + +def test_polymatrix_nullspace(): + M = PolyMatrix([[1, 2], [3, 6]], x) + assert M.nullspace() == [PolyMatrix([-2, 1], x)] + raises(ValueError, lambda: PolyMatrix([1, 2], ring=ZZ[x]).nullspace()) + raises(ValueError, lambda: PolyMatrix([1, x], ring=QQ[x]).nullspace()) + assert M.rank() == 1 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyoptions.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyoptions.py new file mode 100644 index 0000000000000000000000000000000000000000..fa2e6054bad43aef5470949180ea5c2ffdc11f30 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyoptions.py @@ -0,0 +1,485 @@ +"""Tests for options manager for :class:`Poly` and public API functions. """ + +from sympy.polys.polyoptions import ( + Options, Expand, Gens, Wrt, Sort, Order, Field, Greedy, Domain, + Split, Gaussian, Extension, Modulus, Symmetric, Strict, Auto, + Frac, Formal, Polys, Include, All, Gen, Symbols, Method) + +from sympy.polys.orderings import lex +from sympy.polys.domains import FF, GF, ZZ, QQ, QQ_I, RR, CC, EX + +from sympy.polys.polyerrors import OptionError, GeneratorsError + +from sympy.core.numbers import (I, Integer) +from sympy.core.symbol import Symbol +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.testing.pytest import raises +from sympy.abc import x, y, z + + +def test_Options_clone(): + opt = Options((x, y, z), {'domain': 'ZZ'}) + + assert opt.gens == (x, y, z) + assert opt.domain == ZZ + assert ('order' in opt) is False + + new_opt = opt.clone({'gens': (x, y), 'order': 'lex'}) + + assert opt.gens == (x, y, z) + assert opt.domain == ZZ + assert ('order' in opt) is False + + assert new_opt.gens == (x, y) + assert new_opt.domain == ZZ + assert ('order' in new_opt) is True + + +def test_Expand_preprocess(): + assert Expand.preprocess(False) is False + assert Expand.preprocess(True) is True + + assert Expand.preprocess(0) is False + assert Expand.preprocess(1) is True + + raises(OptionError, lambda: Expand.preprocess(x)) + + +def test_Expand_postprocess(): + opt = {'expand': True} + Expand.postprocess(opt) + + assert opt == {'expand': True} + + +def test_Gens_preprocess(): + assert Gens.preprocess((None,)) == () + assert Gens.preprocess((x, y, z)) == (x, y, z) + assert Gens.preprocess(((x, y, z),)) == (x, y, z) + + a = Symbol('a', commutative=False) + + raises(GeneratorsError, lambda: Gens.preprocess((x, x, y))) + raises(GeneratorsError, lambda: Gens.preprocess((x, y, a))) + + +def test_Gens_postprocess(): + opt = {'gens': (x, y)} + Gens.postprocess(opt) + + assert opt == {'gens': (x, y)} + + +def test_Wrt_preprocess(): + assert Wrt.preprocess(x) == ['x'] + assert Wrt.preprocess('') == [] + assert Wrt.preprocess(' ') == [] + assert Wrt.preprocess('x,y') == ['x', 'y'] + assert Wrt.preprocess('x y') == ['x', 'y'] + assert Wrt.preprocess('x, y') == ['x', 'y'] + assert Wrt.preprocess('x , y') == ['x', 'y'] + assert Wrt.preprocess(' x, y') == ['x', 'y'] + assert Wrt.preprocess(' x, y') == ['x', 'y'] + assert Wrt.preprocess([x, y]) == ['x', 'y'] + + raises(OptionError, lambda: Wrt.preprocess(',')) + raises(OptionError, lambda: Wrt.preprocess(0)) + + +def test_Wrt_postprocess(): + opt = {'wrt': ['x']} + Wrt.postprocess(opt) + + assert opt == {'wrt': ['x']} + + +def test_Sort_preprocess(): + assert Sort.preprocess([x, y, z]) == ['x', 'y', 'z'] + assert Sort.preprocess((x, y, z)) == ['x', 'y', 'z'] + + assert Sort.preprocess('x > y > z') == ['x', 'y', 'z'] + assert Sort.preprocess('x>y>z') == ['x', 'y', 'z'] + + raises(OptionError, lambda: Sort.preprocess(0)) + raises(OptionError, lambda: Sort.preprocess({x, y, z})) + + +def test_Sort_postprocess(): + opt = {'sort': 'x > y'} + Sort.postprocess(opt) + + assert opt == {'sort': 'x > y'} + + +def test_Order_preprocess(): + assert Order.preprocess('lex') == lex + + +def test_Order_postprocess(): + opt = {'order': True} + Order.postprocess(opt) + + assert opt == {'order': True} + + +def test_Field_preprocess(): + assert Field.preprocess(False) is False + assert Field.preprocess(True) is True + + assert Field.preprocess(0) is False + assert Field.preprocess(1) is True + + raises(OptionError, lambda: Field.preprocess(x)) + + +def test_Field_postprocess(): + opt = {'field': True} + Field.postprocess(opt) + + assert opt == {'field': True} + + +def test_Greedy_preprocess(): + assert Greedy.preprocess(False) is False + assert Greedy.preprocess(True) is True + + assert Greedy.preprocess(0) is False + assert Greedy.preprocess(1) is True + + raises(OptionError, lambda: Greedy.preprocess(x)) + + +def test_Greedy_postprocess(): + opt = {'greedy': True} + Greedy.postprocess(opt) + + assert opt == {'greedy': True} + + +def test_Domain_preprocess(): + assert Domain.preprocess(ZZ) == ZZ + assert Domain.preprocess(QQ) == QQ + assert Domain.preprocess(EX) == EX + assert Domain.preprocess(FF(2)) == FF(2) + assert Domain.preprocess(ZZ[x, y]) == ZZ[x, y] + + assert Domain.preprocess('Z') == ZZ + assert Domain.preprocess('Q') == QQ + + assert Domain.preprocess('ZZ') == ZZ + assert Domain.preprocess('QQ') == QQ + + assert Domain.preprocess('EX') == EX + + assert Domain.preprocess('FF(23)') == FF(23) + assert Domain.preprocess('GF(23)') == GF(23) + + raises(OptionError, lambda: Domain.preprocess('Z[]')) + + assert Domain.preprocess('Z[x]') == ZZ[x] + assert Domain.preprocess('Q[x]') == QQ[x] + assert Domain.preprocess('R[x]') == RR[x] + assert Domain.preprocess('C[x]') == CC[x] + + assert Domain.preprocess('ZZ[x]') == ZZ[x] + assert Domain.preprocess('QQ[x]') == QQ[x] + assert Domain.preprocess('RR[x]') == RR[x] + assert Domain.preprocess('CC[x]') == CC[x] + + assert Domain.preprocess('Z[x,y]') == ZZ[x, y] + assert Domain.preprocess('Q[x,y]') == QQ[x, y] + assert Domain.preprocess('R[x,y]') == RR[x, y] + assert Domain.preprocess('C[x,y]') == CC[x, y] + + assert Domain.preprocess('ZZ[x,y]') == ZZ[x, y] + assert Domain.preprocess('QQ[x,y]') == QQ[x, y] + assert Domain.preprocess('RR[x,y]') == RR[x, y] + assert Domain.preprocess('CC[x,y]') == CC[x, y] + + raises(OptionError, lambda: Domain.preprocess('Z()')) + + assert Domain.preprocess('Z(x)') == ZZ.frac_field(x) + assert Domain.preprocess('Q(x)') == QQ.frac_field(x) + + assert Domain.preprocess('ZZ(x)') == ZZ.frac_field(x) + assert Domain.preprocess('QQ(x)') == QQ.frac_field(x) + + assert Domain.preprocess('Z(x,y)') == ZZ.frac_field(x, y) + assert Domain.preprocess('Q(x,y)') == QQ.frac_field(x, y) + + assert Domain.preprocess('ZZ(x,y)') == ZZ.frac_field(x, y) + assert Domain.preprocess('QQ(x,y)') == QQ.frac_field(x, y) + + assert Domain.preprocess('Q') == QQ.algebraic_field(I) + assert Domain.preprocess('QQ') == QQ.algebraic_field(I) + + assert Domain.preprocess('Q') == QQ.algebraic_field(sqrt(2), I) + assert Domain.preprocess( + 'QQ') == QQ.algebraic_field(sqrt(2), I) + + raises(OptionError, lambda: Domain.preprocess('abc')) + + +def test_Domain_postprocess(): + raises(GeneratorsError, lambda: Domain.postprocess({'gens': (x, y), + 'domain': ZZ[y, z]})) + + raises(GeneratorsError, lambda: Domain.postprocess({'gens': (), + 'domain': EX})) + raises(GeneratorsError, lambda: Domain.postprocess({'domain': EX})) + + +def test_Split_preprocess(): + assert Split.preprocess(False) is False + assert Split.preprocess(True) is True + + assert Split.preprocess(0) is False + assert Split.preprocess(1) is True + + raises(OptionError, lambda: Split.preprocess(x)) + + +def test_Split_postprocess(): + raises(NotImplementedError, lambda: Split.postprocess({'split': True})) + + +def test_Gaussian_preprocess(): + assert Gaussian.preprocess(False) is False + assert Gaussian.preprocess(True) is True + + assert Gaussian.preprocess(0) is False + assert Gaussian.preprocess(1) is True + + raises(OptionError, lambda: Gaussian.preprocess(x)) + + +def test_Gaussian_postprocess(): + opt = {'gaussian': True} + Gaussian.postprocess(opt) + + assert opt == { + 'gaussian': True, + 'domain': QQ_I, + } + + +def test_Extension_preprocess(): + assert Extension.preprocess(True) is True + assert Extension.preprocess(1) is True + + assert Extension.preprocess([]) is None + + assert Extension.preprocess(sqrt(2)) == {sqrt(2)} + assert Extension.preprocess([sqrt(2)]) == {sqrt(2)} + + assert Extension.preprocess([sqrt(2), I]) == {sqrt(2), I} + + raises(OptionError, lambda: Extension.preprocess(False)) + raises(OptionError, lambda: Extension.preprocess(0)) + + +def test_Extension_postprocess(): + opt = {'extension': {sqrt(2)}} + Extension.postprocess(opt) + + assert opt == { + 'extension': {sqrt(2)}, + 'domain': QQ.algebraic_field(sqrt(2)), + } + + opt = {'extension': True} + Extension.postprocess(opt) + + assert opt == {'extension': True} + + +def test_Modulus_preprocess(): + assert Modulus.preprocess(23) == 23 + assert Modulus.preprocess(Integer(23)) == 23 + + raises(OptionError, lambda: Modulus.preprocess(0)) + raises(OptionError, lambda: Modulus.preprocess(x)) + + +def test_Modulus_postprocess(): + opt = {'modulus': 5} + Modulus.postprocess(opt) + + assert opt == { + 'modulus': 5, + 'domain': FF(5), + } + + opt = {'modulus': 5, 'symmetric': False} + Modulus.postprocess(opt) + + assert opt == { + 'modulus': 5, + 'domain': FF(5, False), + 'symmetric': False, + } + + +def test_Symmetric_preprocess(): + assert Symmetric.preprocess(False) is False + assert Symmetric.preprocess(True) is True + + assert Symmetric.preprocess(0) is False + assert Symmetric.preprocess(1) is True + + raises(OptionError, lambda: Symmetric.preprocess(x)) + + +def test_Symmetric_postprocess(): + opt = {'symmetric': True} + Symmetric.postprocess(opt) + + assert opt == {'symmetric': True} + + +def test_Strict_preprocess(): + assert Strict.preprocess(False) is False + assert Strict.preprocess(True) is True + + assert Strict.preprocess(0) is False + assert Strict.preprocess(1) is True + + raises(OptionError, lambda: Strict.preprocess(x)) + + +def test_Strict_postprocess(): + opt = {'strict': True} + Strict.postprocess(opt) + + assert opt == {'strict': True} + + +def test_Auto_preprocess(): + assert Auto.preprocess(False) is False + assert Auto.preprocess(True) is True + + assert Auto.preprocess(0) is False + assert Auto.preprocess(1) is True + + raises(OptionError, lambda: Auto.preprocess(x)) + + +def test_Auto_postprocess(): + opt = {'auto': True} + Auto.postprocess(opt) + + assert opt == {'auto': True} + + +def test_Frac_preprocess(): + assert Frac.preprocess(False) is False + assert Frac.preprocess(True) is True + + assert Frac.preprocess(0) is False + assert Frac.preprocess(1) is True + + raises(OptionError, lambda: Frac.preprocess(x)) + + +def test_Frac_postprocess(): + opt = {'frac': True} + Frac.postprocess(opt) + + assert opt == {'frac': True} + + +def test_Formal_preprocess(): + assert Formal.preprocess(False) is False + assert Formal.preprocess(True) is True + + assert Formal.preprocess(0) is False + assert Formal.preprocess(1) is True + + raises(OptionError, lambda: Formal.preprocess(x)) + + +def test_Formal_postprocess(): + opt = {'formal': True} + Formal.postprocess(opt) + + assert opt == {'formal': True} + + +def test_Polys_preprocess(): + assert Polys.preprocess(False) is False + assert Polys.preprocess(True) is True + + assert Polys.preprocess(0) is False + assert Polys.preprocess(1) is True + + raises(OptionError, lambda: Polys.preprocess(x)) + + +def test_Polys_postprocess(): + opt = {'polys': True} + Polys.postprocess(opt) + + assert opt == {'polys': True} + + +def test_Include_preprocess(): + assert Include.preprocess(False) is False + assert Include.preprocess(True) is True + + assert Include.preprocess(0) is False + assert Include.preprocess(1) is True + + raises(OptionError, lambda: Include.preprocess(x)) + + +def test_Include_postprocess(): + opt = {'include': True} + Include.postprocess(opt) + + assert opt == {'include': True} + + +def test_All_preprocess(): + assert All.preprocess(False) is False + assert All.preprocess(True) is True + + assert All.preprocess(0) is False + assert All.preprocess(1) is True + + raises(OptionError, lambda: All.preprocess(x)) + + +def test_All_postprocess(): + opt = {'all': True} + All.postprocess(opt) + + assert opt == {'all': True} + + +def test_Gen_postprocess(): + opt = {'gen': x} + Gen.postprocess(opt) + + assert opt == {'gen': x} + + +def test_Symbols_preprocess(): + raises(OptionError, lambda: Symbols.preprocess(x)) + + +def test_Symbols_postprocess(): + opt = {'symbols': [x, y, z]} + Symbols.postprocess(opt) + + assert opt == {'symbols': [x, y, z]} + + +def test_Method_preprocess(): + raises(OptionError, lambda: Method.preprocess(10)) + + +def test_Method_postprocess(): + opt = {'method': 'f5b'} + Method.postprocess(opt) + + assert opt == {'method': 'f5b'} diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyroots.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyroots.py new file mode 100644 index 0000000000000000000000000000000000000000..7f96b1930f6789ce3150ae2c920ba7d9faa68791 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyroots.py @@ -0,0 +1,758 @@ +"""Tests for algorithms for computing symbolic roots of polynomials. """ + +from sympy.core.numbers import (I, Rational, pi) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, Wild, symbols) +from sympy.functions.elementary.complexes import (conjugate, im, re) +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import (root, sqrt) +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (acos, cos, sin) +from sympy.polys.domains.integerring import ZZ +from sympy.sets.sets import Interval +from sympy.simplify.powsimp import powsimp + +from sympy.polys import Poly, cyclotomic_poly, intervals, nroots, rootof + +from sympy.polys.polyroots import (root_factors, roots_linear, + roots_quadratic, roots_cubic, roots_quartic, roots_quintic, + roots_cyclotomic, roots_binomial, preprocess_roots, roots) + +from sympy.polys.orthopolys import legendre_poly +from sympy.polys.polyerrors import PolynomialError, \ + UnsolvableFactorError +from sympy.polys.polyutils import _nsort + +from sympy.testing.pytest import raises, slow +from sympy.core.random import verify_numerically +import mpmath +from itertools import product + + + +a, b, c, d, e, q, t, x, y, z = symbols('a,b,c,d,e,q,t,x,y,z') + + +def _check(roots): + # this is the desired invariant for roots returned + # by all_roots. It is trivially true for linear + # polynomials. + nreal = sum(1 if i.is_real else 0 for i in roots) + assert sorted(roots[:nreal]) == list(roots[:nreal]) + for ix in range(nreal, len(roots), 2): + if not ( + roots[ix + 1] == roots[ix] or + roots[ix + 1] == conjugate(roots[ix])): + return False + return True + + +def test_roots_linear(): + assert roots_linear(Poly(2*x + 1, x)) == [Rational(-1, 2)] + + +def test_roots_quadratic(): + assert roots_quadratic(Poly(2*x**2, x)) == [0, 0] + assert roots_quadratic(Poly(2*x**2 + 3*x, x)) == [Rational(-3, 2), 0] + assert roots_quadratic(Poly(2*x**2 + 3, x)) == [-I*sqrt(6)/2, I*sqrt(6)/2] + assert roots_quadratic(Poly(2*x**2 + 4*x + 3, x)) == [-1 - I*sqrt(2)/2, -1 + I*sqrt(2)/2] + _check(Poly(2*x**2 + 4*x + 3, x).all_roots()) + + f = x**2 + (2*a*e + 2*c*e)/(a - c)*x + (d - b + a*e**2 - c*e**2)/(a - c) + assert roots_quadratic(Poly(f, x)) == \ + [-e*(a + c)/(a - c) - sqrt(a*b + c*d - a*d - b*c + 4*a*c*e**2)/(a - c), + -e*(a + c)/(a - c) + sqrt(a*b + c*d - a*d - b*c + 4*a*c*e**2)/(a - c)] + + # check for simplification + f = Poly(y*x**2 - 2*x - 2*y, x) + assert roots_quadratic(f) == \ + [-sqrt(2*y**2 + 1)/y + 1/y, sqrt(2*y**2 + 1)/y + 1/y] + f = Poly(x**2 + (-y**2 - 2)*x + y**2 + 1, x) + assert roots_quadratic(f) == \ + [1,y**2 + 1] + + f = Poly(sqrt(2)*x**2 - 1, x) + r = roots_quadratic(f) + assert r == _nsort(r) + + # issue 8255 + f = Poly(-24*x**2 - 180*x + 264) + assert [w.n(2) for w in f.all_roots(radicals=True)] == \ + [w.n(2) for w in f.all_roots(radicals=False)] + for _a, _b, _c in product((-2, 2), (-2, 2), (0, -1)): + f = Poly(_a*x**2 + _b*x + _c) + roots = roots_quadratic(f) + assert roots == _nsort(roots) + + +def test_issue_7724(): + eq = Poly(x**4*I + x**2 + I, x) + assert roots(eq) == { + sqrt(I/2 + sqrt(5)*I/2): 1, + sqrt(-sqrt(5)*I/2 + I/2): 1, + -sqrt(I/2 + sqrt(5)*I/2): 1, + -sqrt(-sqrt(5)*I/2 + I/2): 1} + + +def test_issue_8438(): + p = Poly([1, y, -2, -3], x).as_expr() + roots = roots_cubic(Poly(p, x), x) + z = Rational(-3, 2) - I*7/2 # this will fail in code given in commit msg + post = [r.subs(y, z) for r in roots] + assert set(post) == \ + set(roots_cubic(Poly(p.subs(y, z), x))) + # /!\ if p is not made an expression, this is *very* slow + assert all(p.subs({y: z, x: i}).n(2, chop=True) == 0 for i in post) + + +def test_issue_8285(): + roots = (Poly(4*x**8 - 1, x)*Poly(x**2 + 1)).all_roots() + assert _check(roots) + f = Poly(x**4 + 5*x**2 + 6, x) + ro = [rootof(f, i) for i in range(4)] + roots = Poly(x**4 + 5*x**2 + 6, x).all_roots() + assert roots == ro + assert _check(roots) + # more than 2 complex roots from which to identify the + # imaginary ones + roots = Poly(2*x**8 - 1).all_roots() + assert _check(roots) + assert len(Poly(2*x**10 - 1).all_roots()) == 10 # doesn't fail + + +def test_issue_8289(): + roots = (Poly(x**2 + 2)*Poly(x**4 + 2)).all_roots() + assert _check(roots) + roots = Poly(x**6 + 3*x**3 + 2, x).all_roots() + assert _check(roots) + roots = Poly(x**6 - x + 1).all_roots() + assert _check(roots) + # all imaginary roots with multiplicity of 2 + roots = Poly(x**4 + 4*x**2 + 4, x).all_roots() + assert _check(roots) + + +def test_issue_14291(): + assert Poly(((x - 1)**2 + 1)*((x - 1)**2 + 2)*(x - 1) + ).all_roots() == [1, 1 - I, 1 + I, 1 - sqrt(2)*I, 1 + sqrt(2)*I] + p = x**4 + 10*x**2 + 1 + ans = [rootof(p, i) for i in range(4)] + assert Poly(p).all_roots() == ans + _check(ans) + + +def test_issue_13340(): + eq = Poly(y**3 + exp(x)*y + x, y, domain='EX') + roots_d = roots(eq) + assert len(roots_d) == 3 + + +def test_issue_14522(): + eq = Poly(x**4 + x**3*(16 + 32*I) + x**2*(-285 + 386*I) + x*(-2824 - 448*I) - 2058 - 6053*I, x) + roots_eq = roots(eq) + assert all(eq(r) == 0 for r in roots_eq) + + +def test_issue_15076(): + sol = roots_quartic(Poly(t**4 - 6*t**2 + t/x - 3, t)) + assert sol[0].has(x) + + +def test_issue_16589(): + eq = Poly(x**4 - 8*sqrt(2)*x**3 + 4*x**3 - 64*sqrt(2)*x**2 + 1024*x, x) + roots_eq = roots(eq) + assert 0 in roots_eq + + +def test_roots_cubic(): + assert roots_cubic(Poly(2*x**3, x)) == [0, 0, 0] + assert roots_cubic(Poly(x**3 - 3*x**2 + 3*x - 1, x)) == [1, 1, 1] + + # valid for arbitrary y (issue 21263) + r = root(y, 3) + assert roots_cubic(Poly(x**3 - y, x)) == [r, + r*(-S.Half + sqrt(3)*I/2), + r*(-S.Half - sqrt(3)*I/2)] + # simpler form when y is negative + assert roots_cubic(Poly(x**3 - -1, x)) == \ + [-1, S.Half - I*sqrt(3)/2, S.Half + I*sqrt(3)/2] + assert roots_cubic(Poly(2*x**3 - 3*x**2 - 3*x - 1, x))[0] == \ + S.Half + 3**Rational(1, 3)/2 + 3**Rational(2, 3)/2 + eq = -x**3 + 2*x**2 + 3*x - 2 + assert roots(eq, trig=True, multiple=True) == \ + roots_cubic(Poly(eq, x), trig=True) == [ + Rational(2, 3) + 2*sqrt(13)*cos(acos(8*sqrt(13)/169)/3)/3, + -2*sqrt(13)*sin(-acos(8*sqrt(13)/169)/3 + pi/6)/3 + Rational(2, 3), + -2*sqrt(13)*cos(-acos(8*sqrt(13)/169)/3 + pi/3)/3 + Rational(2, 3), + ] + + +def test_roots_quartic(): + assert roots_quartic(Poly(x**4, x)) == [0, 0, 0, 0] + assert roots_quartic(Poly(x**4 + x**3, x)) in [ + [-1, 0, 0, 0], + [0, -1, 0, 0], + [0, 0, -1, 0], + [0, 0, 0, -1] + ] + assert roots_quartic(Poly(x**4 - x**3, x)) in [ + [1, 0, 0, 0], + [0, 1, 0, 0], + [0, 0, 1, 0], + [0, 0, 0, 1] + ] + + lhs = roots_quartic(Poly(x**4 + x, x)) + rhs = [S.Half + I*sqrt(3)/2, S.Half - I*sqrt(3)/2, S.Zero, -S.One] + + assert sorted(lhs, key=hash) == sorted(rhs, key=hash) + + # test of all branches of roots quartic + for i, (a, b, c, d) in enumerate([(1, 2, 3, 0), + (3, -7, -9, 9), + (1, 2, 3, 4), + (1, 2, 3, 4), + (-7, -3, 3, -6), + (-3, 5, -6, -4), + (6, -5, -10, -3)]): + if i == 2: + c = -a*(a**2/S(8) - b/S(2)) + elif i == 3: + d = a*(a*(a**2*Rational(3, 256) - b/S(16)) + c/S(4)) + eq = x**4 + a*x**3 + b*x**2 + c*x + d + ans = roots_quartic(Poly(eq, x)) + assert all(eq.subs(x, ai).n(chop=True) == 0 for ai in ans) + + # not all symbolic quartics are unresolvable + eq = Poly(q*x + q/4 + x**4 + x**3 + 2*x**2 - Rational(1, 3), x) + sol = roots_quartic(eq) + assert all(verify_numerically(eq.subs(x, i), 0) for i in sol) + z = symbols('z', negative=True) + eq = x**4 + 2*x**3 + 3*x**2 + x*(z + 11) + 5 + zans = roots_quartic(Poly(eq, x)) + assert all(verify_numerically(eq.subs(((x, i), (z, -1))), 0) for i in zans) + # but some are (see also issue 4989) + # it's ok if the solution is not Piecewise, but the tests below should pass + eq = Poly(y*x**4 + x**3 - x + z, x) + ans = roots_quartic(eq) + assert all(type(i) == Piecewise for i in ans) + reps = ( + {"y": Rational(-1, 3), "z": Rational(-1, 4)}, # 4 real + {"y": Rational(-1, 3), "z": Rational(-1, 2)}, # 2 real + {"y": Rational(-1, 3), "z": -2}) # 0 real + for rep in reps: + sol = roots_quartic(Poly(eq.subs(rep), x)) + assert all(verify_numerically(w.subs(rep) - s, 0) for w, s in zip(ans, sol)) + + +def test_issue_21287(): + assert not any(isinstance(i, Piecewise) for i in roots_quartic( + Poly(x**4 - x**2*(3 + 5*I) + 2*x*(-1 + I) - 1 + 3*I, x))) + + +def test_roots_quintic(): + eqs = (x**5 - 2, + (x/2 + 1)**5 - 5*(x/2 + 1) + 12, + x**5 - 110*x**3 - 55*x**2 + 2310*x + 979) + for eq in eqs: + roots = roots_quintic(Poly(eq)) + assert len(roots) == 5 + assert all(eq.subs(x, r.n(10)).n(chop = 1e-5) == 0 for r in roots) + + +def test_roots_cyclotomic(): + assert roots_cyclotomic(cyclotomic_poly(1, x, polys=True)) == [1] + assert roots_cyclotomic(cyclotomic_poly(2, x, polys=True)) == [-1] + assert roots_cyclotomic(cyclotomic_poly( + 3, x, polys=True)) == [Rational(-1, 2) - I*sqrt(3)/2, Rational(-1, 2) + I*sqrt(3)/2] + assert roots_cyclotomic(cyclotomic_poly(4, x, polys=True)) == [-I, I] + assert roots_cyclotomic(cyclotomic_poly( + 6, x, polys=True)) == [S.Half - I*sqrt(3)/2, S.Half + I*sqrt(3)/2] + + assert roots_cyclotomic(cyclotomic_poly(7, x, polys=True)) == [ + -cos(pi/7) - I*sin(pi/7), + -cos(pi/7) + I*sin(pi/7), + -cos(pi*Rational(3, 7)) - I*sin(pi*Rational(3, 7)), + -cos(pi*Rational(3, 7)) + I*sin(pi*Rational(3, 7)), + cos(pi*Rational(2, 7)) - I*sin(pi*Rational(2, 7)), + cos(pi*Rational(2, 7)) + I*sin(pi*Rational(2, 7)), + ] + + assert roots_cyclotomic(cyclotomic_poly(8, x, polys=True)) == [ + -sqrt(2)/2 - I*sqrt(2)/2, + -sqrt(2)/2 + I*sqrt(2)/2, + sqrt(2)/2 - I*sqrt(2)/2, + sqrt(2)/2 + I*sqrt(2)/2, + ] + + assert roots_cyclotomic(cyclotomic_poly(12, x, polys=True)) == [ + -sqrt(3)/2 - I/2, + -sqrt(3)/2 + I/2, + sqrt(3)/2 - I/2, + sqrt(3)/2 + I/2, + ] + + assert roots_cyclotomic( + cyclotomic_poly(1, x, polys=True), factor=True) == [1] + assert roots_cyclotomic( + cyclotomic_poly(2, x, polys=True), factor=True) == [-1] + + assert roots_cyclotomic(cyclotomic_poly(3, x, polys=True), factor=True) == \ + [-root(-1, 3), -1 + root(-1, 3)] + assert roots_cyclotomic(cyclotomic_poly(4, x, polys=True), factor=True) == \ + [-I, I] + assert roots_cyclotomic(cyclotomic_poly(5, x, polys=True), factor=True) == \ + [-root(-1, 5), -root(-1, 5)**3, root(-1, 5)**2, -1 - root(-1, 5)**2 + root(-1, 5) + root(-1, 5)**3] + + assert roots_cyclotomic(cyclotomic_poly(6, x, polys=True), factor=True) == \ + [1 - root(-1, 3), root(-1, 3)] + + +def test_roots_binomial(): + assert roots_binomial(Poly(5*x, x)) == [0] + assert roots_binomial(Poly(5*x**4, x)) == [0, 0, 0, 0] + assert roots_binomial(Poly(5*x + 2, x)) == [Rational(-2, 5)] + + A = 10**Rational(3, 4)/10 + + assert roots_binomial(Poly(5*x**4 + 2, x)) == \ + [-A - A*I, -A + A*I, A - A*I, A + A*I] + _check(roots_binomial(Poly(x**8 - 2))) + + a1 = Symbol('a1', nonnegative=True) + b1 = Symbol('b1', nonnegative=True) + + r0 = roots_quadratic(Poly(a1*x**2 + b1, x)) + r1 = roots_binomial(Poly(a1*x**2 + b1, x)) + + assert powsimp(r0[0]) == powsimp(r1[0]) + assert powsimp(r0[1]) == powsimp(r1[1]) + for a, b, s, n in product((1, 2), (1, 2), (-1, 1), (2, 3, 4, 5)): + if a == b and a != 1: # a == b == 1 is sufficient + continue + p = Poly(a*x**n + s*b) + ans = roots_binomial(p) + assert ans == _nsort(ans) + + # issue 8813 + assert roots(Poly(2*x**3 - 16*y**3, x)) == { + 2*y*(Rational(-1, 2) - sqrt(3)*I/2): 1, + 2*y: 1, + 2*y*(Rational(-1, 2) + sqrt(3)*I/2): 1} + + +def test_roots_preprocessing(): + f = a*y*x**2 + y - b + + coeff, poly = preprocess_roots(Poly(f, x)) + + assert coeff == 1 + assert poly == Poly(a*y*x**2 + y - b, x) + + f = c**3*x**3 + c**2*x**2 + c*x + a + + coeff, poly = preprocess_roots(Poly(f, x)) + + assert coeff == 1/c + assert poly == Poly(x**3 + x**2 + x + a, x) + + f = c**3*x**3 + c**2*x**2 + a + + coeff, poly = preprocess_roots(Poly(f, x)) + + assert coeff == 1/c + assert poly == Poly(x**3 + x**2 + a, x) + + f = c**3*x**3 + c*x + a + + coeff, poly = preprocess_roots(Poly(f, x)) + + assert coeff == 1/c + assert poly == Poly(x**3 + x + a, x) + + f = c**3*x**3 + a + + coeff, poly = preprocess_roots(Poly(f, x)) + + assert coeff == 1/c + assert poly == Poly(x**3 + a, x) + + E, F, J, L = symbols("E,F,J,L") + + f = -21601054687500000000*E**8*J**8/L**16 + \ + 508232812500000000*F*x*E**7*J**7/L**14 - \ + 4269543750000000*E**6*F**2*J**6*x**2/L**12 + \ + 16194716250000*E**5*F**3*J**5*x**3/L**10 - \ + 27633173750*E**4*F**4*J**4*x**4/L**8 + \ + 14840215*E**3*F**5*J**3*x**5/L**6 + \ + 54794*E**2*F**6*J**2*x**6/(5*L**4) - \ + 1153*E*J*F**7*x**7/(80*L**2) + \ + 633*F**8*x**8/160000 + + coeff, poly = preprocess_roots(Poly(f, x)) + + assert coeff == 20*E*J/(F*L**2) + assert poly == 633*x**8 - 115300*x**7 + 4383520*x**6 + 296804300*x**5 - 27633173750*x**4 + \ + 809735812500*x**3 - 10673859375000*x**2 + 63529101562500*x - 135006591796875 + + f = Poly(-y**2 + x**2*exp(x), y, domain=ZZ[x, exp(x)]) + g = Poly(-y**2 + exp(x), y, domain=ZZ[exp(x)]) + + assert preprocess_roots(f) == (x, g) + + +def test_roots0(): + assert roots(1, x) == {} + assert roots(x, x) == {S.Zero: 1} + assert roots(x**9, x) == {S.Zero: 9} + assert roots(((x - 2)*(x + 3)*(x - 4)).expand(), x) == {-S(3): 1, S(2): 1, S(4): 1} + + assert roots(2*x + 1, x) == {Rational(-1, 2): 1} + assert roots((2*x + 1)**2, x) == {Rational(-1, 2): 2} + assert roots((2*x + 1)**5, x) == {Rational(-1, 2): 5} + assert roots((2*x + 1)**10, x) == {Rational(-1, 2): 10} + + assert roots(x**4 - 1, x) == {I: 1, S.One: 1, -S.One: 1, -I: 1} + assert roots((x**4 - 1)**2, x) == {I: 2, S.One: 2, -S.One: 2, -I: 2} + + assert roots(((2*x - 3)**2).expand(), x) == {Rational( 3, 2): 2} + assert roots(((2*x + 3)**2).expand(), x) == {Rational(-3, 2): 2} + + assert roots(((2*x - 3)**3).expand(), x) == {Rational( 3, 2): 3} + assert roots(((2*x + 3)**3).expand(), x) == {Rational(-3, 2): 3} + + assert roots(((2*x - 3)**5).expand(), x) == {Rational( 3, 2): 5} + assert roots(((2*x + 3)**5).expand(), x) == {Rational(-3, 2): 5} + + assert roots(((a*x - b)**5).expand(), x) == { b/a: 5} + assert roots(((a*x + b)**5).expand(), x) == {-b/a: 5} + + assert roots(x**2 + (-a - 1)*x + a, x) == {a: 1, S.One: 1} + + assert roots(x**4 - 2*x**2 + 1, x) == {S.One: 2, S.NegativeOne: 2} + + assert roots(x**6 - 4*x**4 + 4*x**3 - x**2, x) == \ + {S.One: 2, -1 - sqrt(2): 1, S.Zero: 2, -1 + sqrt(2): 1} + + assert roots(x**8 - 1, x) == { + sqrt(2)/2 + I*sqrt(2)/2: 1, + sqrt(2)/2 - I*sqrt(2)/2: 1, + -sqrt(2)/2 + I*sqrt(2)/2: 1, + -sqrt(2)/2 - I*sqrt(2)/2: 1, + S.One: 1, -S.One: 1, I: 1, -I: 1 + } + + f = -2016*x**2 - 5616*x**3 - 2056*x**4 + 3324*x**5 + 2176*x**6 - \ + 224*x**7 - 384*x**8 - 64*x**9 + + assert roots(f) == {S.Zero: 2, -S(2): 2, S(2): 1, Rational(-7, 2): 1, + Rational(-3, 2): 1, Rational(-1, 2): 1, Rational(3, 2): 1} + + assert roots((a + b + c)*x - (a + b + c + d), x) == {(a + b + c + d)/(a + b + c): 1} + + assert roots(x**3 + x**2 - x + 1, x, cubics=False) == {} + assert roots(((x - 2)*( + x + 3)*(x - 4)).expand(), x, cubics=False) == {-S(3): 1, S(2): 1, S(4): 1} + assert roots(((x - 2)*(x + 3)*(x - 4)*(x - 5)).expand(), x, cubics=False) == \ + {-S(3): 1, S(2): 1, S(4): 1, S(5): 1} + assert roots(x**3 + 2*x**2 + 4*x + 8, x) == {-S(2): 1, -2*I: 1, 2*I: 1} + assert roots(x**3 + 2*x**2 + 4*x + 8, x, cubics=True) == \ + {-2*I: 1, 2*I: 1, -S(2): 1} + assert roots((x**2 - x)*(x**3 + 2*x**2 + 4*x + 8), x ) == \ + {S.One: 1, S.Zero: 1, -S(2): 1, -2*I: 1, 2*I: 1} + + r1_2, r1_3 = S.Half, Rational(1, 3) + + x0 = (3*sqrt(33) + 19)**r1_3 + x1 = 4/x0/3 + x2 = x0/3 + x3 = sqrt(3)*I/2 + x4 = x3 - r1_2 + x5 = -x3 - r1_2 + assert roots(x**3 + x**2 - x + 1, x, cubics=True) == { + -x1 - x2 - r1_3: 1, + -x1/x4 - x2*x4 - r1_3: 1, + -x1/x5 - x2*x5 - r1_3: 1, + } + + f = (x**2 + 2*x + 3).subs(x, 2*x**2 + 3*x).subs(x, 5*x - 4) + + r13_20, r1_20 = [ Rational(*r) + for r in ((13, 20), (1, 20)) ] + + s2 = sqrt(2) + assert roots(f, x) == { + r13_20 + r1_20*sqrt(1 - 8*I*s2): 1, + r13_20 - r1_20*sqrt(1 - 8*I*s2): 1, + r13_20 + r1_20*sqrt(1 + 8*I*s2): 1, + r13_20 - r1_20*sqrt(1 + 8*I*s2): 1, + } + + f = x**4 + x**3 + x**2 + x + 1 + + r1_4, r1_8, r5_8 = [ Rational(*r) for r in ((1, 4), (1, 8), (5, 8)) ] + + assert roots(f, x) == { + -r1_4 + r1_4*5**r1_2 + I*(r5_8 + r1_8*5**r1_2)**r1_2: 1, + -r1_4 + r1_4*5**r1_2 - I*(r5_8 + r1_8*5**r1_2)**r1_2: 1, + -r1_4 - r1_4*5**r1_2 + I*(r5_8 - r1_8*5**r1_2)**r1_2: 1, + -r1_4 - r1_4*5**r1_2 - I*(r5_8 - r1_8*5**r1_2)**r1_2: 1, + } + + f = z**3 + (-2 - y)*z**2 + (1 + 2*y - 2*x**2)*z - y + 2*x**2 + + assert roots(f, z) == { + S.One: 1, + S.Half + S.Half*y + S.Half*sqrt(1 - 2*y + y**2 + 8*x**2): 1, + S.Half + S.Half*y - S.Half*sqrt(1 - 2*y + y**2 + 8*x**2): 1, + } + + assert roots(a*b*c*x**3 + 2*x**2 + 4*x + 8, x, cubics=False) == {} + assert roots(a*b*c*x**3 + 2*x**2 + 4*x + 8, x, cubics=True) != {} + + assert roots(x**4 - 1, x, filter='Z') == {S.One: 1, -S.One: 1} + assert roots(x**4 - 1, x, filter='I') == {I: 1, -I: 1} + + assert roots((x - 1)*(x + 1), x) == {S.One: 1, -S.One: 1} + assert roots( + (x - 1)*(x + 1), x, predicate=lambda r: r.is_positive) == {S.One: 1} + + assert roots(x**4 - 1, x, filter='Z', multiple=True) == [-S.One, S.One] + assert roots(x**4 - 1, x, filter='I', multiple=True) == [I, -I] + + ar, br = symbols('a, b', real=True) + p = x**2*(ar-br)**2 + 2*x*(br-ar) + 1 + assert roots(p, x, filter='R') == {1/(ar - br): 2} + + assert roots(x**3, x, multiple=True) == [S.Zero, S.Zero, S.Zero] + assert roots(1234, x, multiple=True) == [] + + f = x**6 - x**5 + x**4 - x**3 + x**2 - x + 1 + + assert roots(f) == { + -I*sin(pi/7) + cos(pi/7): 1, + -I*sin(pi*Rational(2, 7)) - cos(pi*Rational(2, 7)): 1, + -I*sin(pi*Rational(3, 7)) + cos(pi*Rational(3, 7)): 1, + I*sin(pi/7) + cos(pi/7): 1, + I*sin(pi*Rational(2, 7)) - cos(pi*Rational(2, 7)): 1, + I*sin(pi*Rational(3, 7)) + cos(pi*Rational(3, 7)): 1, + } + + g = ((x**2 + 1)*f**2).expand() + + assert roots(g) == { + -I*sin(pi/7) + cos(pi/7): 2, + -I*sin(pi*Rational(2, 7)) - cos(pi*Rational(2, 7)): 2, + -I*sin(pi*Rational(3, 7)) + cos(pi*Rational(3, 7)): 2, + I*sin(pi/7) + cos(pi/7): 2, + I*sin(pi*Rational(2, 7)) - cos(pi*Rational(2, 7)): 2, + I*sin(pi*Rational(3, 7)) + cos(pi*Rational(3, 7)): 2, + -I: 1, I: 1, + } + + r = roots(x**3 + 40*x + 64) + real_root = [rx for rx in r if rx.is_real][0] + cr = 108 + 6*sqrt(1074) + assert real_root == -2*root(cr, 3)/3 + 20/root(cr, 3) + + eq = Poly((7 + 5*sqrt(2))*x**3 + (-6 - 4*sqrt(2))*x**2 + (-sqrt(2) - 1)*x + 2, x, domain='EX') + assert roots(eq) == {-1 + sqrt(2): 1, -2 + 2*sqrt(2): 1, -sqrt(2) + 1: 1} + + eq = Poly(41*x**5 + 29*sqrt(2)*x**5 - 153*x**4 - 108*sqrt(2)*x**4 + + 175*x**3 + 125*sqrt(2)*x**3 - 45*x**2 - 30*sqrt(2)*x**2 - 26*sqrt(2)*x - + 26*x + 24, x, domain='EX') + assert roots(eq) == {-sqrt(2) + 1: 1, -2 + 2*sqrt(2): 1, -1 + sqrt(2): 1, + -4 + 4*sqrt(2): 1, -3 + 3*sqrt(2): 1} + + eq = Poly(x**3 - 2*x**2 + 6*sqrt(2)*x**2 - 8*sqrt(2)*x + 23*x - 14 + + 14*sqrt(2), x, domain='EX') + assert roots(eq) == {-2*sqrt(2) + 2: 1, -2*sqrt(2) + 1: 1, -2*sqrt(2) - 1: 1} + + assert roots(Poly((x + sqrt(2))**3 - 7, x, domain='EX')) == \ + {-sqrt(2) + root(7, 3)*(-S.Half - sqrt(3)*I/2): 1, + -sqrt(2) + root(7, 3)*(-S.Half + sqrt(3)*I/2): 1, + -sqrt(2) + root(7, 3): 1} + +def test_roots_slow(): + """Just test that calculating these roots does not hang. """ + a, b, c, d, x = symbols("a,b,c,d,x") + + f1 = x**2*c + (a/b) + x*c*d - a + f2 = x**2*(a + b*(c - d)*a) + x*a*b*c/(b*d - d) + (a*d - c/d) + + assert list(roots(f1, x).values()) == [1, 1] + assert list(roots(f2, x).values()) == [1, 1] + + (zz, yy, xx, zy, zx, yx, k) = symbols("zz,yy,xx,zy,zx,yx,k") + + e1 = (zz - k)*(yy - k)*(xx - k) + zy*yx*zx + zx - zy - yx + e2 = (zz - k)*yx*yx + zx*(yy - k)*zx + zy*zy*(xx - k) + + assert list(roots(e1 - e2, k).values()) == [1, 1, 1] + + f = x**3 + 2*x**2 + 8 + R = list(roots(f).keys()) + + assert not any(i for i in [f.subs(x, ri).n(chop=True) for ri in R]) + + +def test_roots_inexact(): + R1 = roots(x**2 + x + 1, x, multiple=True) + R2 = roots(x**2 + x + 1.0, x, multiple=True) + + for r1, r2 in zip(R1, R2): + assert abs(r1 - r2) < 1e-12 + + f = x**4 + 3.0*sqrt(2.0)*x**3 - (78.0 + 24.0*sqrt(3.0))*x**2 \ + + 144.0*(2*sqrt(3.0) + 9.0) + + R1 = roots(f, multiple=True) + R2 = (-12.7530479110482, -3.85012393732929, + 4.89897948556636, 7.46155167569183) + + for r1, r2 in zip(R1, R2): + assert abs(r1 - r2) < 1e-10 + + +def test_roots_preprocessed(): + E, F, J, L = symbols("E,F,J,L") + + f = -21601054687500000000*E**8*J**8/L**16 + \ + 508232812500000000*F*x*E**7*J**7/L**14 - \ + 4269543750000000*E**6*F**2*J**6*x**2/L**12 + \ + 16194716250000*E**5*F**3*J**5*x**3/L**10 - \ + 27633173750*E**4*F**4*J**4*x**4/L**8 + \ + 14840215*E**3*F**5*J**3*x**5/L**6 + \ + 54794*E**2*F**6*J**2*x**6/(5*L**4) - \ + 1153*E*J*F**7*x**7/(80*L**2) + \ + 633*F**8*x**8/160000 + + assert roots(f, x) == {} + + R1 = roots(f.evalf(), x, multiple=True) + R2 = [-1304.88375606366, 97.1168816800648, 186.946430171876, 245.526792947065, + 503.441004174773, 791.549343830097, 1273.16678129348, 1850.10650616851] + + w = Wild('w') + p = w*E*J/(F*L**2) + + assert len(R1) == len(R2) + + for r1, r2 in zip(R1, R2): + match = r1.match(p) + assert match is not None and abs(match[w] - r2) < 1e-10 + + +def test_roots_strict(): + assert roots(x**2 - 2*x + 1, strict=False) == {1: 2} + assert roots(x**2 - 2*x + 1, strict=True) == {1: 2} + + assert roots(x**6 - 2*x**5 - x**2 + 3*x - 2, strict=False) == {2: 1} + raises(UnsolvableFactorError, lambda: roots(x**6 - 2*x**5 - x**2 + 3*x - 2, strict=True)) + + +def test_roots_mixed(): + f = -1936 - 5056*x - 7592*x**2 + 2704*x**3 - 49*x**4 + + _re, _im = intervals(f, all=True) + _nroots = nroots(f) + _sroots = roots(f, multiple=True) + + _re = [ Interval(a, b) for (a, b), _ in _re ] + _im = [ Interval(re(a), re(b))*Interval(im(a), im(b)) for (a, b), + _ in _im ] + + _intervals = _re + _im + _sroots = [ r.evalf() for r in _sroots ] + + _nroots = sorted(_nroots, key=lambda x: x.sort_key()) + _sroots = sorted(_sroots, key=lambda x: x.sort_key()) + + for _roots in (_nroots, _sroots): + for i, r in zip(_intervals, _roots): + if r.is_real: + assert r in i + else: + assert (re(r), im(r)) in i + + +def test_root_factors(): + assert root_factors(Poly(1, x)) == [Poly(1, x)] + assert root_factors(Poly(x, x)) == [Poly(x, x)] + + assert root_factors(x**2 - 1, x) == [x + 1, x - 1] + assert root_factors(x**2 - y, x) == [x - sqrt(y), x + sqrt(y)] + + assert root_factors((x**4 - 1)**2) == \ + [x + 1, x + 1, x - 1, x - 1, x - I, x - I, x + I, x + I] + + assert root_factors(Poly(x**4 - 1, x), filter='Z') == \ + [Poly(x + 1, x), Poly(x - 1, x), Poly(x**2 + 1, x)] + assert root_factors(8*x**2 + 12*x**4 + 6*x**6 + x**8, x, filter='Q') == \ + [x, x, x**6 + 6*x**4 + 12*x**2 + 8] + + +@slow +def test_nroots1(): + n = 64 + p = legendre_poly(n, x, polys=True) + + raises(mpmath.mp.NoConvergence, lambda: p.nroots(n=3, maxsteps=5)) + + roots = p.nroots(n=3) + # The order of roots matters. They are ordered from smallest to the + # largest. + assert [str(r) for r in roots] == \ + ['-0.999', '-0.996', '-0.991', '-0.983', '-0.973', '-0.961', + '-0.946', '-0.930', '-0.911', '-0.889', '-0.866', '-0.841', + '-0.813', '-0.784', '-0.753', '-0.720', '-0.685', '-0.649', + '-0.611', '-0.572', '-0.531', '-0.489', '-0.446', '-0.402', + '-0.357', '-0.311', '-0.265', '-0.217', '-0.170', '-0.121', + '-0.0730', '-0.0243', '0.0243', '0.0730', '0.121', '0.170', + '0.217', '0.265', '0.311', '0.357', '0.402', '0.446', '0.489', + '0.531', '0.572', '0.611', '0.649', '0.685', '0.720', '0.753', + '0.784', '0.813', '0.841', '0.866', '0.889', '0.911', '0.930', + '0.946', '0.961', '0.973', '0.983', '0.991', '0.996', '0.999'] + +def test_nroots2(): + p = Poly(x**5 + 3*x + 1, x) + + roots = p.nroots(n=3) + # The order of roots matters. The roots are ordered by their real + # components (if they agree, then by their imaginary components), + # with real roots appearing first. + assert [str(r) for r in roots] == \ + ['-0.332', '-0.839 - 0.944*I', '-0.839 + 0.944*I', + '1.01 - 0.937*I', '1.01 + 0.937*I'] + + roots = p.nroots(n=5) + assert [str(r) for r in roots] == \ + ['-0.33199', '-0.83907 - 0.94385*I', '-0.83907 + 0.94385*I', + '1.0051 - 0.93726*I', '1.0051 + 0.93726*I'] + + +def test_roots_composite(): + assert len(roots(Poly(y**3 + y**2*sqrt(x) + y + x, y, composite=True))) == 3 + + +def test_issue_19113(): + eq = cos(x)**3 - cos(x) + 1 + raises(PolynomialError, lambda: roots(eq)) + + +def test_issue_17454(): + assert roots([1, -3*(-4 - 4*I)**2/8 + 12*I, 0], multiple=True) == [0, 0] + + +def test_issue_20913(): + assert Poly(x + 9671406556917067856609794, x).real_roots() == [-9671406556917067856609794] + assert Poly(x**3 + 4, x).real_roots() == [-2**(S(2)/3)] + + +def test_issue_22768(): + e = Rational(1, 3) + r = (-1/a)**e*(a + 1)**(5*e) + assert roots(Poly(a*x**3 + (a + 1)**5, x)) == { + r: 1, + -r*(1 + sqrt(3)*I)/2: 1, + r*(-1 + sqrt(3)*I)/2: 1} diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polytools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polytools.py new file mode 100644 index 0000000000000000000000000000000000000000..a4096447cecea9db6e7559c305af6312b2a72725 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polytools.py @@ -0,0 +1,3976 @@ +"""Tests for user-friendly public interface to polynomial functions. """ + +import pickle + +from sympy.polys.polytools import ( + Poly, PurePoly, poly, + parallel_poly_from_expr, + degree, degree_list, + total_degree, + LC, LM, LT, + pdiv, prem, pquo, pexquo, + div, rem, quo, exquo, + half_gcdex, gcdex, invert, + subresultants, + resultant, discriminant, + terms_gcd, cofactors, + gcd, gcd_list, + lcm, lcm_list, + trunc, + monic, content, primitive, + compose, decompose, + sturm, + gff_list, gff, + sqf_norm, sqf_part, sqf_list, sqf, + factor_list, factor, + intervals, refine_root, count_roots, + all_roots, real_roots, nroots, ground_roots, + nth_power_roots_poly, + cancel, reduced, groebner, + GroebnerBasis, is_zero_dimensional, + _torational_factor_list, + to_rational_coeffs) + +from sympy.polys.polyerrors import ( + MultivariatePolynomialError, + ExactQuotientFailed, + PolificationFailed, + ComputationFailed, + UnificationFailed, + RefinementFailed, + GeneratorsNeeded, + GeneratorsError, + PolynomialError, + CoercionFailed, + DomainError, + OptionError, + FlagError) + +from sympy.polys.polyclasses import DMP + +from sympy.polys.fields import field +from sympy.polys.domains import FF, ZZ, QQ, ZZ_I, QQ_I, RR, EX +from sympy.polys.domains.realfield import RealField +from sympy.polys.domains.complexfield import ComplexField +from sympy.polys.orderings import lex, grlex, grevlex + +from sympy.combinatorics.galois import S4TransitiveSubgroups +from sympy.core.add import Add +from sympy.core.basic import _aresame +from sympy.core.containers import Tuple +from sympy.core.expr import Expr +from sympy.core.function import (Derivative, diff, expand) +from sympy.core.mul import _keep_coeff, Mul +from sympy.core.numbers import (Float, I, Integer, Rational, oo, pi) +from sympy.core.power import Pow +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.functions.elementary.complexes import (im, re) +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.hyperbolic import tanh +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import sin +from sympy.matrices.dense import Matrix +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.polys.rootoftools import rootof +from sympy.simplify.simplify import signsimp +from sympy.utilities.iterables import iterable +from sympy.utilities.exceptions import SymPyDeprecationWarning + +from sympy.testing.pytest import ( + raises, warns_deprecated_sympy, warns, tooslow, XFAIL +) + +from sympy.abc import a, b, c, d, p, q, t, w, x, y, z + + +def _epsilon_eq(a, b): + for u, v in zip(a, b): + if abs(u - v) > 1e-10: + return False + return True + + +def _strict_eq(a, b): + if type(a) == type(b): + if iterable(a): + if len(a) == len(b): + return all(_strict_eq(c, d) for c, d in zip(a, b)) + else: + return False + else: + return isinstance(a, Poly) and a.eq(b, strict=True) + else: + return False + + +def test_Poly_mixed_operations(): + p = Poly(x, x) + with warns_deprecated_sympy(): + p * exp(x) + with warns_deprecated_sympy(): + p + exp(x) + with warns_deprecated_sympy(): + p - exp(x) + + +def test_Poly_from_dict(): + K = FF(3) + + assert Poly.from_dict( + {0: 1, 1: 2}, gens=x, domain=K).rep == DMP([K(2), K(1)], K) + assert Poly.from_dict( + {0: 1, 1: 5}, gens=x, domain=K).rep == DMP([K(2), K(1)], K) + + assert Poly.from_dict( + {(0,): 1, (1,): 2}, gens=x, domain=K).rep == DMP([K(2), K(1)], K) + assert Poly.from_dict( + {(0,): 1, (1,): 5}, gens=x, domain=K).rep == DMP([K(2), K(1)], K) + + assert Poly.from_dict({(0, 0): 1, (1, 1): 2}, gens=( + x, y), domain=K).rep == DMP([[K(2), K(0)], [K(1)]], K) + + assert Poly.from_dict({0: 1, 1: 2}, gens=x).rep == DMP([ZZ(2), ZZ(1)], ZZ) + assert Poly.from_dict( + {0: 1, 1: 2}, gens=x, field=True).rep == DMP([QQ(2), QQ(1)], QQ) + + assert Poly.from_dict( + {0: 1, 1: 2}, gens=x, domain=ZZ).rep == DMP([ZZ(2), ZZ(1)], ZZ) + assert Poly.from_dict( + {0: 1, 1: 2}, gens=x, domain=QQ).rep == DMP([QQ(2), QQ(1)], QQ) + + assert Poly.from_dict( + {(0,): 1, (1,): 2}, gens=x).rep == DMP([ZZ(2), ZZ(1)], ZZ) + assert Poly.from_dict( + {(0,): 1, (1,): 2}, gens=x, field=True).rep == DMP([QQ(2), QQ(1)], QQ) + + assert Poly.from_dict( + {(0,): 1, (1,): 2}, gens=x, domain=ZZ).rep == DMP([ZZ(2), ZZ(1)], ZZ) + assert Poly.from_dict( + {(0,): 1, (1,): 2}, gens=x, domain=QQ).rep == DMP([QQ(2), QQ(1)], QQ) + + assert Poly.from_dict({(1,): sin(y)}, gens=x, composite=False) == \ + Poly(sin(y)*x, x, domain='EX') + assert Poly.from_dict({(1,): y}, gens=x, composite=False) == \ + Poly(y*x, x, domain='EX') + assert Poly.from_dict({(1, 1): 1}, gens=(x, y), composite=False) == \ + Poly(x*y, x, y, domain='ZZ') + assert Poly.from_dict({(1, 0): y}, gens=(x, z), composite=False) == \ + Poly(y*x, x, z, domain='EX') + + +def test_Poly_from_list(): + K = FF(3) + + assert Poly.from_list([2, 1], gens=x, domain=K).rep == DMP([K(2), K(1)], K) + assert Poly.from_list([5, 1], gens=x, domain=K).rep == DMP([K(2), K(1)], K) + + assert Poly.from_list([2, 1], gens=x).rep == DMP([ZZ(2), ZZ(1)], ZZ) + assert Poly.from_list([2, 1], gens=x, field=True).rep == DMP([QQ(2), QQ(1)], QQ) + + assert Poly.from_list([2, 1], gens=x, domain=ZZ).rep == DMP([ZZ(2), ZZ(1)], ZZ) + assert Poly.from_list([2, 1], gens=x, domain=QQ).rep == DMP([QQ(2), QQ(1)], QQ) + + assert Poly.from_list([0, 1.0], gens=x).rep == DMP([RR(1.0)], RR) + assert Poly.from_list([1.0, 0], gens=x).rep == DMP([RR(1.0), RR(0.0)], RR) + + raises(MultivariatePolynomialError, lambda: Poly.from_list([[]], gens=(x, y))) + + +def test_Poly_from_poly(): + f = Poly(x + 7, x, domain=ZZ) + g = Poly(x + 2, x, modulus=3) + h = Poly(x + y, x, y, domain=ZZ) + + K = FF(3) + + assert Poly.from_poly(f) == f + assert Poly.from_poly(f, domain=K).rep == DMP([K(1), K(1)], K) + assert Poly.from_poly(f, domain=ZZ).rep == DMP([ZZ(1), ZZ(7)], ZZ) + assert Poly.from_poly(f, domain=QQ).rep == DMP([QQ(1), QQ(7)], QQ) + + assert Poly.from_poly(f, gens=x) == f + assert Poly.from_poly(f, gens=x, domain=K).rep == DMP([K(1), K(1)], K) + assert Poly.from_poly(f, gens=x, domain=ZZ).rep == DMP([ZZ(1), ZZ(7)], ZZ) + assert Poly.from_poly(f, gens=x, domain=QQ).rep == DMP([QQ(1), QQ(7)], QQ) + + assert Poly.from_poly(f, gens=y) == Poly(x + 7, y, domain='ZZ[x]') + raises(CoercionFailed, lambda: Poly.from_poly(f, gens=y, domain=K)) + raises(CoercionFailed, lambda: Poly.from_poly(f, gens=y, domain=ZZ)) + raises(CoercionFailed, lambda: Poly.from_poly(f, gens=y, domain=QQ)) + + assert Poly.from_poly(f, gens=(x, y)) == Poly(x + 7, x, y, domain='ZZ') + assert Poly.from_poly( + f, gens=(x, y), domain=ZZ) == Poly(x + 7, x, y, domain='ZZ') + assert Poly.from_poly( + f, gens=(x, y), domain=QQ) == Poly(x + 7, x, y, domain='QQ') + assert Poly.from_poly( + f, gens=(x, y), modulus=3) == Poly(x + 7, x, y, domain='FF(3)') + + K = FF(2) + + assert Poly.from_poly(g) == g + assert Poly.from_poly(g, domain=ZZ).rep == DMP([ZZ(1), ZZ(-1)], ZZ) + raises(CoercionFailed, lambda: Poly.from_poly(g, domain=QQ)) + assert Poly.from_poly(g, domain=K).rep == DMP([K(1), K(0)], K) + + assert Poly.from_poly(g, gens=x) == g + assert Poly.from_poly(g, gens=x, domain=ZZ).rep == DMP([ZZ(1), ZZ(-1)], ZZ) + raises(CoercionFailed, lambda: Poly.from_poly(g, gens=x, domain=QQ)) + assert Poly.from_poly(g, gens=x, domain=K).rep == DMP([K(1), K(0)], K) + + K = FF(3) + + assert Poly.from_poly(h) == h + assert Poly.from_poly( + h, domain=ZZ).rep == DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + assert Poly.from_poly( + h, domain=QQ).rep == DMP([[QQ(1)], [QQ(1), QQ(0)]], QQ) + assert Poly.from_poly(h, domain=K).rep == DMP([[K(1)], [K(1), K(0)]], K) + + assert Poly.from_poly(h, gens=x) == Poly(x + y, x, domain=ZZ[y]) + raises(CoercionFailed, lambda: Poly.from_poly(h, gens=x, domain=ZZ)) + assert Poly.from_poly( + h, gens=x, domain=ZZ[y]) == Poly(x + y, x, domain=ZZ[y]) + raises(CoercionFailed, lambda: Poly.from_poly(h, gens=x, domain=QQ)) + assert Poly.from_poly( + h, gens=x, domain=QQ[y]) == Poly(x + y, x, domain=QQ[y]) + raises(CoercionFailed, lambda: Poly.from_poly(h, gens=x, modulus=3)) + + assert Poly.from_poly(h, gens=y) == Poly(x + y, y, domain=ZZ[x]) + raises(CoercionFailed, lambda: Poly.from_poly(h, gens=y, domain=ZZ)) + assert Poly.from_poly( + h, gens=y, domain=ZZ[x]) == Poly(x + y, y, domain=ZZ[x]) + raises(CoercionFailed, lambda: Poly.from_poly(h, gens=y, domain=QQ)) + assert Poly.from_poly( + h, gens=y, domain=QQ[x]) == Poly(x + y, y, domain=QQ[x]) + raises(CoercionFailed, lambda: Poly.from_poly(h, gens=y, modulus=3)) + + assert Poly.from_poly(h, gens=(x, y)) == h + assert Poly.from_poly( + h, gens=(x, y), domain=ZZ).rep == DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + assert Poly.from_poly( + h, gens=(x, y), domain=QQ).rep == DMP([[QQ(1)], [QQ(1), QQ(0)]], QQ) + assert Poly.from_poly( + h, gens=(x, y), domain=K).rep == DMP([[K(1)], [K(1), K(0)]], K) + + assert Poly.from_poly( + h, gens=(y, x)).rep == DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + assert Poly.from_poly( + h, gens=(y, x), domain=ZZ).rep == DMP([[ZZ(1)], [ZZ(1), ZZ(0)]], ZZ) + assert Poly.from_poly( + h, gens=(y, x), domain=QQ).rep == DMP([[QQ(1)], [QQ(1), QQ(0)]], QQ) + assert Poly.from_poly( + h, gens=(y, x), domain=K).rep == DMP([[K(1)], [K(1), K(0)]], K) + + assert Poly.from_poly( + h, gens=(x, y), field=True).rep == DMP([[QQ(1)], [QQ(1), QQ(0)]], QQ) + assert Poly.from_poly( + h, gens=(x, y), field=True).rep == DMP([[QQ(1)], [QQ(1), QQ(0)]], QQ) + + +def test_Poly_from_expr(): + raises(GeneratorsNeeded, lambda: Poly.from_expr(S.Zero)) + raises(GeneratorsNeeded, lambda: Poly.from_expr(S(7))) + + F3 = FF(3) + + assert Poly.from_expr(x + 5, domain=F3).rep == DMP([F3(1), F3(2)], F3) + assert Poly.from_expr(y + 5, domain=F3).rep == DMP([F3(1), F3(2)], F3) + + assert Poly.from_expr(x + 5, x, domain=F3).rep == DMP([F3(1), F3(2)], F3) + assert Poly.from_expr(y + 5, y, domain=F3).rep == DMP([F3(1), F3(2)], F3) + + assert Poly.from_expr(x + y, domain=F3).rep == DMP([[F3(1)], [F3(1), F3(0)]], F3) + assert Poly.from_expr(x + y, x, y, domain=F3).rep == DMP([[F3(1)], [F3(1), F3(0)]], F3) + + assert Poly.from_expr(x + 5).rep == DMP([ZZ(1), ZZ(5)], ZZ) + assert Poly.from_expr(y + 5).rep == DMP([ZZ(1), ZZ(5)], ZZ) + + assert Poly.from_expr(x + 5, x).rep == DMP([ZZ(1), ZZ(5)], ZZ) + assert Poly.from_expr(y + 5, y).rep == DMP([ZZ(1), ZZ(5)], ZZ) + + assert Poly.from_expr(x + 5, domain=ZZ).rep == DMP([ZZ(1), ZZ(5)], ZZ) + assert Poly.from_expr(y + 5, domain=ZZ).rep == DMP([ZZ(1), ZZ(5)], ZZ) + + assert Poly.from_expr(x + 5, x, domain=ZZ).rep == DMP([ZZ(1), ZZ(5)], ZZ) + assert Poly.from_expr(y + 5, y, domain=ZZ).rep == DMP([ZZ(1), ZZ(5)], ZZ) + + assert Poly.from_expr(x + 5, x, y, domain=ZZ).rep == DMP([[ZZ(1)], [ZZ(5)]], ZZ) + assert Poly.from_expr(y + 5, x, y, domain=ZZ).rep == DMP([[ZZ(1), ZZ(5)]], ZZ) + + +def test_Poly_rootof_extension(): + r1 = rootof(x**3 + x + 3, 0) + r2 = rootof(x**3 + x + 3, 1) + K1 = QQ.algebraic_field(r1) + K2 = QQ.algebraic_field(r2) + assert Poly(r1, y) == Poly(r1, y, domain=EX) + assert Poly(r2, y) == Poly(r2, y, domain=EX) + assert Poly(r1, y, extension=True) == Poly(r1, y, domain=K1) + assert Poly(r2, y, extension=True) == Poly(r2, y, domain=K2) + + +@tooslow +def test_Poly_rootof_extension_primitive_element(): + r1 = rootof(x**3 + x + 3, 0) + r2 = rootof(x**3 + x + 3, 1) + K12 = QQ.algebraic_field(r1 + r2) + assert Poly(r1*y + r2, y, extension=True) == Poly(r1*y + r2, y, domain=K12) + + +@XFAIL +def test_Poly_rootof_same_symbol_issue_26808(): + # XXX: This fails because r1 contains x. + r1 = rootof(x**3 + x + 3, 0) + K1 = QQ.algebraic_field(r1) + assert Poly(r1, x) == Poly(r1, x, domain=EX) + assert Poly(r1, x, extension=True) == Poly(r1, x, domain=K1) + + +def test_Poly_rootof_extension_to_sympy(): + # Verify that when primitive elements and RootOf are used, the expression + # is not exploded on the way back to sympy. + r1 = rootof(y**3 + y**2 - 1, 0) + r2 = rootof(z**5 + z**2 - 1, 0) + p = -x**5 + x**2 + x*r1 - r2 + 3*r1**2 + assert p.as_poly(x, extension=True).as_expr() == p + + +def test_poly_from_domain_element(): + dom = ZZ[x] + assert Poly(dom(x+1), y, domain=dom).rep == DMP([dom(x+1)], dom) + dom = dom.get_field() + assert Poly(dom(x+1), y, domain=dom).rep == DMP([dom(x+1)], dom) + + dom = QQ[x] + assert Poly(dom(x+1), y, domain=dom).rep == DMP([dom(x+1)], dom) + dom = dom.get_field() + assert Poly(dom(x+1), y, domain=dom).rep == DMP([dom(x+1)], dom) + + dom = ZZ.old_poly_ring(x) + assert Poly(dom([ZZ(1), ZZ(1)]), y, domain=dom).rep == DMP([dom([ZZ(1), ZZ(1)])], dom) + dom = dom.get_field() + assert Poly(dom([ZZ(1), ZZ(1)]), y, domain=dom).rep == DMP([dom([ZZ(1), ZZ(1)])], dom) + + dom = QQ.old_poly_ring(x) + assert Poly(dom([QQ(1), QQ(1)]), y, domain=dom).rep == DMP([dom([QQ(1), QQ(1)])], dom) + dom = dom.get_field() + assert Poly(dom([QQ(1), QQ(1)]), y, domain=dom).rep == DMP([dom([QQ(1), QQ(1)])], dom) + + dom = QQ.algebraic_field(I) + assert Poly(dom([1, 1]), x, domain=dom).rep == DMP([dom([1, 1])], dom) + + +def test_Poly__new__(): + raises(GeneratorsError, lambda: Poly(x + 1, x, x)) + + raises(GeneratorsError, lambda: Poly(x + y, x, y, domain=ZZ[x])) + raises(GeneratorsError, lambda: Poly(x + y, x, y, domain=ZZ[y])) + + raises(OptionError, lambda: Poly(x, x, symmetric=True)) + raises(OptionError, lambda: Poly(x + 2, x, modulus=3, domain=QQ)) + + raises(OptionError, lambda: Poly(x + 2, x, domain=ZZ, gaussian=True)) + raises(OptionError, lambda: Poly(x + 2, x, modulus=3, gaussian=True)) + + raises(OptionError, lambda: Poly(x + 2, x, domain=ZZ, extension=[sqrt(3)])) + raises(OptionError, lambda: Poly(x + 2, x, modulus=3, extension=[sqrt(3)])) + + raises(OptionError, lambda: Poly(x + 2, x, domain=ZZ, extension=True)) + raises(OptionError, lambda: Poly(x + 2, x, modulus=3, extension=True)) + + raises(OptionError, lambda: Poly(x + 2, x, domain=ZZ, greedy=True)) + raises(OptionError, lambda: Poly(x + 2, x, domain=QQ, field=True)) + + raises(OptionError, lambda: Poly(x + 2, x, domain=ZZ, greedy=False)) + raises(OptionError, lambda: Poly(x + 2, x, domain=QQ, field=False)) + + raises(NotImplementedError, lambda: Poly(x + 1, x, modulus=3, order='grlex')) + raises(NotImplementedError, lambda: Poly(x + 1, x, order='grlex')) + + raises(GeneratorsNeeded, lambda: Poly({1: 2, 0: 1})) + raises(GeneratorsNeeded, lambda: Poly([2, 1])) + raises(GeneratorsNeeded, lambda: Poly((2, 1))) + + raises(GeneratorsNeeded, lambda: Poly(1)) + + assert Poly('x-x') == Poly(0, x) + + f = a*x**2 + b*x + c + + assert Poly({2: a, 1: b, 0: c}, x) == f + assert Poly(iter([a, b, c]), x) == f + assert Poly([a, b, c], x) == f + assert Poly((a, b, c), x) == f + + f = Poly({}, x, y, z) + + assert f.gens == (x, y, z) and f.as_expr() == 0 + + assert Poly(Poly(a*x + b*y, x, y), x) == Poly(a*x + b*y, x) + + assert Poly(3*x**2 + 2*x + 1, domain='ZZ').all_coeffs() == [3, 2, 1] + assert Poly(3*x**2 + 2*x + 1, domain='QQ').all_coeffs() == [3, 2, 1] + assert Poly(3*x**2 + 2*x + 1, domain='RR').all_coeffs() == [3.0, 2.0, 1.0] + + raises(CoercionFailed, lambda: Poly(3*x**2/5 + x*Rational(2, 5) + 1, domain='ZZ')) + assert Poly( + 3*x**2/5 + x*Rational(2, 5) + 1, domain='QQ').all_coeffs() == [Rational(3, 5), Rational(2, 5), 1] + assert _epsilon_eq( + Poly(3*x**2/5 + x*Rational(2, 5) + 1, domain='RR').all_coeffs(), [0.6, 0.4, 1.0]) + + assert Poly(3.0*x**2 + 2.0*x + 1, domain='ZZ').all_coeffs() == [3, 2, 1] + assert Poly(3.0*x**2 + 2.0*x + 1, domain='QQ').all_coeffs() == [3, 2, 1] + assert Poly( + 3.0*x**2 + 2.0*x + 1, domain='RR').all_coeffs() == [3.0, 2.0, 1.0] + + raises(CoercionFailed, lambda: Poly(3.1*x**2 + 2.1*x + 1, domain='ZZ')) + assert Poly(3.1*x**2 + 2.1*x + 1, domain='QQ').all_coeffs() == [Rational(31, 10), Rational(21, 10), 1] + assert Poly(3.1*x**2 + 2.1*x + 1, domain='RR').all_coeffs() == [3.1, 2.1, 1.0] + + assert Poly({(2, 1): 1, (1, 2): 2, (1, 1): 3}, x, y) == \ + Poly(x**2*y + 2*x*y**2 + 3*x*y, x, y) + + assert Poly(x**2 + 1, extension=I).get_domain() == QQ.algebraic_field(I) + + f = 3*x**5 - x**4 + x**3 - x** 2 + 65538 + + assert Poly(f, x, modulus=65537, symmetric=True) == \ + Poly(3*x**5 - x**4 + x**3 - x** 2 + 1, x, modulus=65537, + symmetric=True) + assert Poly(f, x, modulus=65537, symmetric=False) == \ + Poly(3*x**5 + 65536*x**4 + x**3 + 65536*x** 2 + 1, x, + modulus=65537, symmetric=False) + + N = 10**100 + assert Poly(-1, x, modulus=N, symmetric=False).as_expr() == N - 1 + + assert isinstance(Poly(x**2 + x + 1.0).get_domain(), RealField) + assert isinstance(Poly(x**2 + x + I + 1.0).get_domain(), ComplexField) + + +def test_Poly__args(): + assert Poly(x**2 + 1).args == (x**2 + 1, x) + + +def test_Poly__gens(): + assert Poly((x - p)*(x - q), x).gens == (x,) + assert Poly((x - p)*(x - q), p).gens == (p,) + assert Poly((x - p)*(x - q), q).gens == (q,) + + assert Poly((x - p)*(x - q), x, p).gens == (x, p) + assert Poly((x - p)*(x - q), x, q).gens == (x, q) + + assert Poly((x - p)*(x - q), x, p, q).gens == (x, p, q) + assert Poly((x - p)*(x - q), p, x, q).gens == (p, x, q) + assert Poly((x - p)*(x - q), p, q, x).gens == (p, q, x) + + assert Poly((x - p)*(x - q)).gens == (x, p, q) + + assert Poly((x - p)*(x - q), sort='x > p > q').gens == (x, p, q) + assert Poly((x - p)*(x - q), sort='p > x > q').gens == (p, x, q) + assert Poly((x - p)*(x - q), sort='p > q > x').gens == (p, q, x) + + assert Poly((x - p)*(x - q), x, p, q, sort='p > q > x').gens == (x, p, q) + + assert Poly((x - p)*(x - q), wrt='x').gens == (x, p, q) + assert Poly((x - p)*(x - q), wrt='p').gens == (p, x, q) + assert Poly((x - p)*(x - q), wrt='q').gens == (q, x, p) + + assert Poly((x - p)*(x - q), wrt=x).gens == (x, p, q) + assert Poly((x - p)*(x - q), wrt=p).gens == (p, x, q) + assert Poly((x - p)*(x - q), wrt=q).gens == (q, x, p) + + assert Poly((x - p)*(x - q), x, p, q, wrt='p').gens == (x, p, q) + + assert Poly((x - p)*(x - q), wrt='p', sort='q > x').gens == (p, q, x) + assert Poly((x - p)*(x - q), wrt='q', sort='p > x').gens == (q, p, x) + + +def test_Poly_zero(): + assert Poly(x).zero == Poly(0, x, domain=ZZ) + assert Poly(x/2).zero == Poly(0, x, domain=QQ) + + +def test_Poly_one(): + assert Poly(x).one == Poly(1, x, domain=ZZ) + assert Poly(x/2).one == Poly(1, x, domain=QQ) + + +def test_Poly__unify(): + raises(UnificationFailed, lambda: Poly(x)._unify(y)) + + F3 = FF(3) + + assert Poly(x, x, modulus=3)._unify(Poly(y, y, modulus=3))[2:] == ( + DMP([[F3(1)], []], F3), DMP([[F3(1), F3(0)]], F3)) + raises(UnificationFailed, lambda: Poly(x, x, modulus=3)._unify(Poly(y, y, modulus=5))) + + raises(UnificationFailed, lambda: Poly(y, x, y)._unify(Poly(x, x, modulus=3))) + raises(UnificationFailed, lambda: Poly(x, x, modulus=3)._unify(Poly(y, x, y))) + + assert Poly(x + 1, x)._unify(Poly(x + 2, x))[2:] ==\ + (DMP([ZZ(1), ZZ(1)], ZZ), DMP([ZZ(1), ZZ(2)], ZZ)) + assert Poly(x + 1, x, domain='QQ')._unify(Poly(x + 2, x))[2:] ==\ + (DMP([QQ(1), QQ(1)], QQ), DMP([QQ(1), QQ(2)], QQ)) + assert Poly(x + 1, x)._unify(Poly(x + 2, x, domain='QQ'))[2:] ==\ + (DMP([QQ(1), QQ(1)], QQ), DMP([QQ(1), QQ(2)], QQ)) + + assert Poly(x + 1, x)._unify(Poly(x + 2, x, y))[2:] ==\ + (DMP([[ZZ(1)], [ZZ(1)]], ZZ), DMP([[ZZ(1)], [ZZ(2)]], ZZ)) + assert Poly(x + 1, x, domain='QQ')._unify(Poly(x + 2, x, y))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + assert Poly(x + 1, x)._unify(Poly(x + 2, x, y, domain='QQ'))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + + assert Poly(x + 1, x, y)._unify(Poly(x + 2, x))[2:] ==\ + (DMP([[ZZ(1)], [ZZ(1)]], ZZ), DMP([[ZZ(1)], [ZZ(2)]], ZZ)) + assert Poly(x + 1, x, y, domain='QQ')._unify(Poly(x + 2, x))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + assert Poly(x + 1, x, y)._unify(Poly(x + 2, x, domain='QQ'))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + + assert Poly(x + 1, x, y)._unify(Poly(x + 2, x, y))[2:] ==\ + (DMP([[ZZ(1)], [ZZ(1)]], ZZ), DMP([[ZZ(1)], [ZZ(2)]], ZZ)) + assert Poly(x + 1, x, y, domain='QQ')._unify(Poly(x + 2, x, y))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + assert Poly(x + 1, x, y)._unify(Poly(x + 2, x, y, domain='QQ'))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + + assert Poly(x + 1, x)._unify(Poly(x + 2, y, x))[2:] ==\ + (DMP([[ZZ(1), ZZ(1)]], ZZ), DMP([[ZZ(1), ZZ(2)]], ZZ)) + assert Poly(x + 1, x, domain='QQ')._unify(Poly(x + 2, y, x))[2:] ==\ + (DMP([[QQ(1), QQ(1)]], QQ), DMP([[QQ(1), QQ(2)]], QQ)) + assert Poly(x + 1, x)._unify(Poly(x + 2, y, x, domain='QQ'))[2:] ==\ + (DMP([[QQ(1), QQ(1)]], QQ), DMP([[QQ(1), QQ(2)]], QQ)) + + assert Poly(x + 1, y, x)._unify(Poly(x + 2, x))[2:] ==\ + (DMP([[ZZ(1), ZZ(1)]], ZZ), DMP([[ZZ(1), ZZ(2)]], ZZ)) + assert Poly(x + 1, y, x, domain='QQ')._unify(Poly(x + 2, x))[2:] ==\ + (DMP([[QQ(1), QQ(1)]], QQ), DMP([[QQ(1), QQ(2)]], QQ)) + assert Poly(x + 1, y, x)._unify(Poly(x + 2, x, domain='QQ'))[2:] ==\ + (DMP([[QQ(1), QQ(1)]], QQ), DMP([[QQ(1), QQ(2)]], QQ)) + + assert Poly(x + 1, x, y)._unify(Poly(x + 2, y, x))[2:] ==\ + (DMP([[ZZ(1)], [ZZ(1)]], ZZ), DMP([[ZZ(1)], [ZZ(2)]], ZZ)) + assert Poly(x + 1, x, y, domain='QQ')._unify(Poly(x + 2, y, x))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + assert Poly(x + 1, x, y)._unify(Poly(x + 2, y, x, domain='QQ'))[2:] ==\ + (DMP([[QQ(1)], [QQ(1)]], QQ), DMP([[QQ(1)], [QQ(2)]], QQ)) + + assert Poly(x + 1, y, x)._unify(Poly(x + 2, x, y))[2:] ==\ + (DMP([[ZZ(1), ZZ(1)]], ZZ), DMP([[ZZ(1), ZZ(2)]], ZZ)) + assert Poly(x + 1, y, x, domain='QQ')._unify(Poly(x + 2, x, y))[2:] ==\ + (DMP([[QQ(1), QQ(1)]], QQ), DMP([[QQ(1), QQ(2)]], QQ)) + assert Poly(x + 1, y, x)._unify(Poly(x + 2, x, y, domain='QQ'))[2:] ==\ + (DMP([[QQ(1), QQ(1)]], QQ), DMP([[QQ(1), QQ(2)]], QQ)) + + assert Poly(x**2 + I, x, domain=ZZ_I).unify(Poly(x**2 + sqrt(2), x, extension=True)) == \ + (Poly(x**2 + I, x, domain='QQ'), Poly(x**2 + sqrt(2), x, domain='QQ')) + + F, A, B = field("a,b", ZZ) + + assert Poly(a*x, x, domain='ZZ[a]')._unify(Poly(a*b*x, x, domain='ZZ(a,b)'))[2:] == \ + (DMP([A, F(0)], F.to_domain()), DMP([A*B, F(0)], F.to_domain())) + + assert Poly(a*x, x, domain='ZZ(a)')._unify(Poly(a*b*x, x, domain='ZZ(a,b)'))[2:] == \ + (DMP([A, F(0)], F.to_domain()), DMP([A*B, F(0)], F.to_domain())) + + raises(CoercionFailed, lambda: Poly(Poly(x**2 + x**2*z, y, field=True), domain='ZZ(x)')) + + f = Poly(t**2 + t/3 + x, t, domain='QQ(x)') + g = Poly(t**2 + t/3 + x, t, domain='QQ[x]') + + assert f._unify(g)[2:] == (f.rep, f.rep) + + +def test_Poly_free_symbols(): + assert Poly(x**2 + 1).free_symbols == {x} + assert Poly(x**2 + y*z).free_symbols == {x, y, z} + assert Poly(x**2 + y*z, x).free_symbols == {x, y, z} + assert Poly(x**2 + sin(y*z)).free_symbols == {x, y, z} + assert Poly(x**2 + sin(y*z), x).free_symbols == {x, y, z} + assert Poly(x**2 + sin(y*z), x, domain=EX).free_symbols == {x, y, z} + assert Poly(1 + x + x**2, x, y, z).free_symbols == {x} + assert Poly(x + sin(y), z).free_symbols == {x, y} + + +def test_PurePoly_free_symbols(): + assert PurePoly(x**2 + 1).free_symbols == set() + assert PurePoly(x**2 + y*z).free_symbols == set() + assert PurePoly(x**2 + y*z, x).free_symbols == {y, z} + assert PurePoly(x**2 + sin(y*z)).free_symbols == set() + assert PurePoly(x**2 + sin(y*z), x).free_symbols == {y, z} + assert PurePoly(x**2 + sin(y*z), x, domain=EX).free_symbols == {y, z} + + +def test_Poly__eq__(): + assert (Poly(x, x) == Poly(x, x)) is True + assert (Poly(x, x, domain=QQ) == Poly(x, x)) is False + assert (Poly(x, x) == Poly(x, x, domain=QQ)) is False + + assert (Poly(x, x, domain=ZZ[a]) == Poly(x, x)) is False + assert (Poly(x, x) == Poly(x, x, domain=ZZ[a])) is False + + assert (Poly(x*y, x, y) == Poly(x, x)) is False + + assert (Poly(x, x, y) == Poly(x, x)) is False + assert (Poly(x, x) == Poly(x, x, y)) is False + + assert (Poly(x**2 + 1, x) == Poly(y**2 + 1, y)) is False + assert (Poly(y**2 + 1, y) == Poly(x**2 + 1, x)) is False + + f = Poly(x, x, domain=ZZ) + g = Poly(x, x, domain=QQ) + + assert f.eq(g) is False + assert f.ne(g) is True + + assert f.eq(g, strict=True) is False + assert f.ne(g, strict=True) is True + + t0 = Symbol('t0') + + f = Poly((t0/2 + x**2)*t**2 - x**2*t, t, domain='QQ[x,t0]') + g = Poly((t0/2 + x**2)*t**2 - x**2*t, t, domain='ZZ(x,t0)') + + assert (f == g) is False + + +def test_PurePoly__eq__(): + assert (PurePoly(x, x) == PurePoly(x, x)) is True + assert (PurePoly(x, x, domain=QQ) == PurePoly(x, x)) is True + assert (PurePoly(x, x) == PurePoly(x, x, domain=QQ)) is True + + assert (PurePoly(x, x, domain=ZZ[a]) == PurePoly(x, x)) is True + assert (PurePoly(x, x) == PurePoly(x, x, domain=ZZ[a])) is True + + assert (PurePoly(x*y, x, y) == PurePoly(x, x)) is False + + assert (PurePoly(x, x, y) == PurePoly(x, x)) is False + assert (PurePoly(x, x) == PurePoly(x, x, y)) is False + + assert (PurePoly(x**2 + 1, x) == PurePoly(y**2 + 1, y)) is True + assert (PurePoly(y**2 + 1, y) == PurePoly(x**2 + 1, x)) is True + + f = PurePoly(x, x, domain=ZZ) + g = PurePoly(x, x, domain=QQ) + + assert f.eq(g) is True + assert f.ne(g) is False + + assert f.eq(g, strict=True) is False + assert f.ne(g, strict=True) is True + + f = PurePoly(x, x, domain=ZZ) + g = PurePoly(y, y, domain=QQ) + + assert f.eq(g) is True + assert f.ne(g) is False + + assert f.eq(g, strict=True) is False + assert f.ne(g, strict=True) is True + + +def test_PurePoly_Poly(): + assert isinstance(PurePoly(Poly(x**2 + 1)), PurePoly) is True + assert isinstance(Poly(PurePoly(x**2 + 1)), Poly) is True + + +def test_Poly_get_domain(): + assert Poly(2*x).get_domain() == ZZ + + assert Poly(2*x, domain='ZZ').get_domain() == ZZ + assert Poly(2*x, domain='QQ').get_domain() == QQ + + assert Poly(x/2).get_domain() == QQ + + raises(CoercionFailed, lambda: Poly(x/2, domain='ZZ')) + assert Poly(x/2, domain='QQ').get_domain() == QQ + + assert isinstance(Poly(0.2*x).get_domain(), RealField) + + +def test_Poly_set_domain(): + assert Poly(2*x + 1).set_domain(ZZ) == Poly(2*x + 1) + assert Poly(2*x + 1).set_domain('ZZ') == Poly(2*x + 1) + + assert Poly(2*x + 1).set_domain(QQ) == Poly(2*x + 1, domain='QQ') + assert Poly(2*x + 1).set_domain('QQ') == Poly(2*x + 1, domain='QQ') + + assert Poly(Rational(2, 10)*x + Rational(1, 10)).set_domain('RR') == Poly(0.2*x + 0.1) + assert Poly(0.2*x + 0.1).set_domain('QQ') == Poly(Rational(2, 10)*x + Rational(1, 10)) + + raises(CoercionFailed, lambda: Poly(x/2 + 1).set_domain(ZZ)) + raises(CoercionFailed, lambda: Poly(x + 1, modulus=2).set_domain(QQ)) + + raises(GeneratorsError, lambda: Poly(x*y, x, y).set_domain(ZZ[y])) + + +def test_Poly_get_modulus(): + assert Poly(x**2 + 1, modulus=2).get_modulus() == 2 + raises(PolynomialError, lambda: Poly(x**2 + 1).get_modulus()) + + +def test_Poly_set_modulus(): + assert Poly( + x**2 + 1, modulus=2).set_modulus(7) == Poly(x**2 + 1, modulus=7) + assert Poly( + x**2 + 5, modulus=7).set_modulus(2) == Poly(x**2 + 1, modulus=2) + + assert Poly(x**2 + 1).set_modulus(2) == Poly(x**2 + 1, modulus=2) + + raises(CoercionFailed, lambda: Poly(x/2 + 1).set_modulus(2)) + + +def test_Poly_add_ground(): + assert Poly(x + 1).add_ground(2) == Poly(x + 3) + + +def test_Poly_sub_ground(): + assert Poly(x + 1).sub_ground(2) == Poly(x - 1) + + +def test_Poly_mul_ground(): + assert Poly(x + 1).mul_ground(2) == Poly(2*x + 2) + + +def test_Poly_quo_ground(): + assert Poly(2*x + 4).quo_ground(2) == Poly(x + 2) + assert Poly(2*x + 3).quo_ground(2) == Poly(x + 1) + + +def test_Poly_exquo_ground(): + assert Poly(2*x + 4).exquo_ground(2) == Poly(x + 2) + raises(ExactQuotientFailed, lambda: Poly(2*x + 3).exquo_ground(2)) + + +def test_Poly_abs(): + assert Poly(-x + 1, x).abs() == abs(Poly(-x + 1, x)) == Poly(x + 1, x) + + +def test_Poly_neg(): + assert Poly(-x + 1, x).neg() == -Poly(-x + 1, x) == Poly(x - 1, x) + + +def test_Poly_add(): + assert Poly(0, x).add(Poly(0, x)) == Poly(0, x) + assert Poly(0, x) + Poly(0, x) == Poly(0, x) + + assert Poly(1, x).add(Poly(0, x)) == Poly(1, x) + assert Poly(1, x, y) + Poly(0, x) == Poly(1, x, y) + assert Poly(0, x).add(Poly(1, x, y)) == Poly(1, x, y) + assert Poly(0, x, y) + Poly(1, x, y) == Poly(1, x, y) + + assert Poly(1, x) + x == Poly(x + 1, x) + with warns_deprecated_sympy(): + Poly(1, x) + sin(x) + + assert Poly(x, x) + 1 == Poly(x + 1, x) + assert 1 + Poly(x, x) == Poly(x + 1, x) + + +def test_Poly_sub(): + assert Poly(0, x).sub(Poly(0, x)) == Poly(0, x) + assert Poly(0, x) - Poly(0, x) == Poly(0, x) + + assert Poly(1, x).sub(Poly(0, x)) == Poly(1, x) + assert Poly(1, x, y) - Poly(0, x) == Poly(1, x, y) + assert Poly(0, x).sub(Poly(1, x, y)) == Poly(-1, x, y) + assert Poly(0, x, y) - Poly(1, x, y) == Poly(-1, x, y) + + assert Poly(1, x) - x == Poly(1 - x, x) + with warns_deprecated_sympy(): + Poly(1, x) - sin(x) + + assert Poly(x, x) - 1 == Poly(x - 1, x) + assert 1 - Poly(x, x) == Poly(1 - x, x) + + +def test_Poly_mul(): + assert Poly(0, x).mul(Poly(0, x)) == Poly(0, x) + assert Poly(0, x) * Poly(0, x) == Poly(0, x) + + assert Poly(2, x).mul(Poly(4, x)) == Poly(8, x) + assert Poly(2, x, y) * Poly(4, x) == Poly(8, x, y) + assert Poly(4, x).mul(Poly(2, x, y)) == Poly(8, x, y) + assert Poly(4, x, y) * Poly(2, x, y) == Poly(8, x, y) + + assert Poly(1, x) * x == Poly(x, x) + with warns_deprecated_sympy(): + Poly(1, x) * sin(x) + + assert Poly(x, x) * 2 == Poly(2*x, x) + assert 2 * Poly(x, x) == Poly(2*x, x) + +def test_issue_13079(): + assert Poly(x)*x == Poly(x**2, x, domain='ZZ') + assert x*Poly(x) == Poly(x**2, x, domain='ZZ') + assert -2*Poly(x) == Poly(-2*x, x, domain='ZZ') + assert S(-2)*Poly(x) == Poly(-2*x, x, domain='ZZ') + assert Poly(x)*S(-2) == Poly(-2*x, x, domain='ZZ') + +def test_Poly_sqr(): + assert Poly(x*y, x, y).sqr() == Poly(x**2*y**2, x, y) + + +def test_Poly_pow(): + assert Poly(x, x).pow(10) == Poly(x**10, x) + assert Poly(x, x).pow(Integer(10)) == Poly(x**10, x) + + assert Poly(2*y, x, y).pow(4) == Poly(16*y**4, x, y) + assert Poly(2*y, x, y).pow(Integer(4)) == Poly(16*y**4, x, y) + + assert Poly(7*x*y, x, y)**3 == Poly(343*x**3*y**3, x, y) + + raises(TypeError, lambda: Poly(x*y + 1, x, y)**(-1)) + raises(TypeError, lambda: Poly(x*y + 1, x, y)**x) + + +def test_Poly_divmod(): + f, g = Poly(x**2), Poly(x) + q, r = g, Poly(0, x) + + assert divmod(f, g) == (q, r) + assert f // g == q + assert f % g == r + + assert divmod(f, x) == (q, r) + assert f // x == q + assert f % x == r + + q, r = Poly(0, x), Poly(2, x) + + assert divmod(2, g) == (q, r) + assert 2 // g == q + assert 2 % g == r + + assert Poly(x)/Poly(x) == 1 + assert Poly(x**2)/Poly(x) == x + assert Poly(x)/Poly(x**2) == 1/x + + +def test_Poly_eq_ne(): + assert (Poly(x + y, x, y) == Poly(x + y, x, y)) is True + assert (Poly(x + y, x) == Poly(x + y, x, y)) is False + assert (Poly(x + y, x, y) == Poly(x + y, x)) is False + assert (Poly(x + y, x) == Poly(x + y, x)) is True + assert (Poly(x + y, y) == Poly(x + y, y)) is True + + assert (Poly(x + y, x, y) == x + y) is True + assert (Poly(x + y, x) == x + y) is True + assert (Poly(x + y, x, y) == x + y) is True + assert (Poly(x + y, x) == x + y) is True + assert (Poly(x + y, y) == x + y) is True + + assert (Poly(x + y, x, y) != Poly(x + y, x, y)) is False + assert (Poly(x + y, x) != Poly(x + y, x, y)) is True + assert (Poly(x + y, x, y) != Poly(x + y, x)) is True + assert (Poly(x + y, x) != Poly(x + y, x)) is False + assert (Poly(x + y, y) != Poly(x + y, y)) is False + + assert (Poly(x + y, x, y) != x + y) is False + assert (Poly(x + y, x) != x + y) is False + assert (Poly(x + y, x, y) != x + y) is False + assert (Poly(x + y, x) != x + y) is False + assert (Poly(x + y, y) != x + y) is False + + assert (Poly(x, x) == sin(x)) is False + assert (Poly(x, x) != sin(x)) is True + + +def test_Poly_nonzero(): + assert not bool(Poly(0, x)) is True + assert not bool(Poly(1, x)) is False + + +def test_Poly_properties(): + assert Poly(0, x).is_zero is True + assert Poly(1, x).is_zero is False + + assert Poly(1, x).is_one is True + assert Poly(2, x).is_one is False + + assert Poly(x - 1, x).is_sqf is True + assert Poly((x - 1)**2, x).is_sqf is False + + assert Poly(x - 1, x).is_monic is True + assert Poly(2*x - 1, x).is_monic is False + + assert Poly(3*x + 2, x).is_primitive is True + assert Poly(4*x + 2, x).is_primitive is False + + assert Poly(1, x).is_ground is True + assert Poly(x, x).is_ground is False + + assert Poly(x + y + z + 1).is_linear is True + assert Poly(x*y*z + 1).is_linear is False + + assert Poly(x*y + z + 1).is_quadratic is True + assert Poly(x*y*z + 1).is_quadratic is False + + assert Poly(x*y).is_monomial is True + assert Poly(x*y + 1).is_monomial is False + + assert Poly(x**2 + x*y).is_homogeneous is True + assert Poly(x**3 + x*y).is_homogeneous is False + + assert Poly(x).is_univariate is True + assert Poly(x*y).is_univariate is False + + assert Poly(x*y).is_multivariate is True + assert Poly(x).is_multivariate is False + + assert Poly( + x**16 + x**14 - x**10 + x**8 - x**6 + x**2 + 1).is_cyclotomic is False + assert Poly( + x**16 + x**14 - x**10 - x**8 - x**6 + x**2 + 1).is_cyclotomic is True + + +def test_Poly_is_irreducible(): + assert Poly(x**2 + x + 1).is_irreducible is True + assert Poly(x**2 + 2*x + 1).is_irreducible is False + + assert Poly(7*x + 3, modulus=11).is_irreducible is True + assert Poly(7*x**2 + 3*x + 1, modulus=11).is_irreducible is False + + +def test_Poly_subs(): + assert Poly(x + 1).subs(x, 0) == 1 + + assert Poly(x + 1).subs(x, x) == Poly(x + 1) + assert Poly(x + 1).subs(x, y) == Poly(y + 1) + + assert Poly(x*y, x).subs(y, x) == x**2 + assert Poly(x*y, x).subs(x, y) == y**2 + + +def test_Poly_replace(): + assert Poly(x + 1).replace(x) == Poly(x + 1) + assert Poly(x + 1).replace(y) == Poly(y + 1) + + raises(PolynomialError, lambda: Poly(x + y).replace(z)) + + assert Poly(x + 1).replace(x, x) == Poly(x + 1) + assert Poly(x + 1).replace(x, y) == Poly(y + 1) + + assert Poly(x + y).replace(x, x) == Poly(x + y) + assert Poly(x + y).replace(x, z) == Poly(z + y, z, y) + + assert Poly(x + y).replace(y, y) == Poly(x + y) + assert Poly(x + y).replace(y, z) == Poly(x + z, x, z) + assert Poly(x + y).replace(z, t) == Poly(x + y) + + raises(PolynomialError, lambda: Poly(x + y).replace(x, y)) + + assert Poly(x + y, x).replace(x, z) == Poly(z + y, z) + assert Poly(x + y, y).replace(y, z) == Poly(x + z, z) + + raises(PolynomialError, lambda: Poly(x + y, x).replace(x, y)) + raises(PolynomialError, lambda: Poly(x + y, y).replace(y, x)) + + +def test_Poly_reorder(): + raises(PolynomialError, lambda: Poly(x + y).reorder(x, z)) + + assert Poly(x + y, x, y).reorder(x, y) == Poly(x + y, x, y) + assert Poly(x + y, x, y).reorder(y, x) == Poly(x + y, y, x) + + assert Poly(x + y, y, x).reorder(x, y) == Poly(x + y, x, y) + assert Poly(x + y, y, x).reorder(y, x) == Poly(x + y, y, x) + + assert Poly(x + y, x, y).reorder(wrt=x) == Poly(x + y, x, y) + assert Poly(x + y, x, y).reorder(wrt=y) == Poly(x + y, y, x) + + +def test_Poly_ltrim(): + f = Poly(y**2 + y*z**2, x, y, z).ltrim(y) + assert f.as_expr() == y**2 + y*z**2 and f.gens == (y, z) + assert Poly(x*y - x, z, x, y).ltrim(1) == Poly(x*y - x, x, y) + + raises(PolynomialError, lambda: Poly(x*y**2 + y**2, x, y).ltrim(y)) + raises(PolynomialError, lambda: Poly(x*y - x, x, y).ltrim(-1)) + +def test_Poly_has_only_gens(): + assert Poly(x*y + 1, x, y, z).has_only_gens(x, y) is True + assert Poly(x*y + z, x, y, z).has_only_gens(x, y) is False + + raises(GeneratorsError, lambda: Poly(x*y**2 + y**2, x, y).has_only_gens(t)) + + +def test_Poly_to_ring(): + assert Poly(2*x + 1, domain='ZZ').to_ring() == Poly(2*x + 1, domain='ZZ') + assert Poly(2*x + 1, domain='QQ').to_ring() == Poly(2*x + 1, domain='ZZ') + + raises(CoercionFailed, lambda: Poly(x/2 + 1).to_ring()) + raises(DomainError, lambda: Poly(2*x + 1, modulus=3).to_ring()) + + +def test_Poly_to_field(): + assert Poly(2*x + 1, domain='ZZ').to_field() == Poly(2*x + 1, domain='QQ') + assert Poly(2*x + 1, domain='QQ').to_field() == Poly(2*x + 1, domain='QQ') + + assert Poly(x/2 + 1, domain='QQ').to_field() == Poly(x/2 + 1, domain='QQ') + assert Poly(2*x + 1, modulus=3).to_field() == Poly(2*x + 1, modulus=3) + + assert Poly(2.0*x + 1.0).to_field() == Poly(2.0*x + 1.0) + + +def test_Poly_to_exact(): + assert Poly(2*x).to_exact() == Poly(2*x) + assert Poly(x/2).to_exact() == Poly(x/2) + + assert Poly(0.1*x).to_exact() == Poly(x/10) + + +def test_Poly_retract(): + f = Poly(x**2 + 1, x, domain=QQ[y]) + + assert f.retract() == Poly(x**2 + 1, x, domain='ZZ') + assert f.retract(field=True) == Poly(x**2 + 1, x, domain='QQ') + + assert Poly(0, x, y).retract() == Poly(0, x, y) + + +def test_Poly_slice(): + f = Poly(x**3 + 2*x**2 + 3*x + 4) + + assert f.slice(0, 0) == Poly(0, x) + assert f.slice(0, 1) == Poly(4, x) + assert f.slice(0, 2) == Poly(3*x + 4, x) + assert f.slice(0, 3) == Poly(2*x**2 + 3*x + 4, x) + assert f.slice(0, 4) == Poly(x**3 + 2*x**2 + 3*x + 4, x) + + assert f.slice(x, 0, 0) == Poly(0, x) + assert f.slice(x, 0, 1) == Poly(4, x) + assert f.slice(x, 0, 2) == Poly(3*x + 4, x) + assert f.slice(x, 0, 3) == Poly(2*x**2 + 3*x + 4, x) + assert f.slice(x, 0, 4) == Poly(x**3 + 2*x**2 + 3*x + 4, x) + + g = Poly(x**3 + 1) + + assert g.slice(0, 3) == Poly(1, x) + + +def test_Poly_coeffs(): + assert Poly(0, x).coeffs() == [0] + assert Poly(1, x).coeffs() == [1] + + assert Poly(2*x + 1, x).coeffs() == [2, 1] + + assert Poly(7*x**2 + 2*x + 1, x).coeffs() == [7, 2, 1] + assert Poly(7*x**4 + 2*x + 1, x).coeffs() == [7, 2, 1] + + assert Poly(x*y**7 + 2*x**2*y**3).coeffs('lex') == [2, 1] + assert Poly(x*y**7 + 2*x**2*y**3).coeffs('grlex') == [1, 2] + + +def test_Poly_monoms(): + assert Poly(0, x).monoms() == [(0,)] + assert Poly(1, x).monoms() == [(0,)] + + assert Poly(2*x + 1, x).monoms() == [(1,), (0,)] + + assert Poly(7*x**2 + 2*x + 1, x).monoms() == [(2,), (1,), (0,)] + assert Poly(7*x**4 + 2*x + 1, x).monoms() == [(4,), (1,), (0,)] + + assert Poly(x*y**7 + 2*x**2*y**3).monoms('lex') == [(2, 3), (1, 7)] + assert Poly(x*y**7 + 2*x**2*y**3).monoms('grlex') == [(1, 7), (2, 3)] + + +def test_Poly_terms(): + assert Poly(0, x).terms() == [((0,), 0)] + assert Poly(1, x).terms() == [((0,), 1)] + + assert Poly(2*x + 1, x).terms() == [((1,), 2), ((0,), 1)] + + assert Poly(7*x**2 + 2*x + 1, x).terms() == [((2,), 7), ((1,), 2), ((0,), 1)] + assert Poly(7*x**4 + 2*x + 1, x).terms() == [((4,), 7), ((1,), 2), ((0,), 1)] + + assert Poly( + x*y**7 + 2*x**2*y**3).terms('lex') == [((2, 3), 2), ((1, 7), 1)] + assert Poly( + x*y**7 + 2*x**2*y**3).terms('grlex') == [((1, 7), 1), ((2, 3), 2)] + + +def test_Poly_all_coeffs(): + assert Poly(0, x).all_coeffs() == [0] + assert Poly(1, x).all_coeffs() == [1] + + assert Poly(2*x + 1, x).all_coeffs() == [2, 1] + + assert Poly(7*x**2 + 2*x + 1, x).all_coeffs() == [7, 2, 1] + assert Poly(7*x**4 + 2*x + 1, x).all_coeffs() == [7, 0, 0, 2, 1] + + +def test_Poly_all_monoms(): + assert Poly(0, x).all_monoms() == [(0,)] + assert Poly(1, x).all_monoms() == [(0,)] + + assert Poly(2*x + 1, x).all_monoms() == [(1,), (0,)] + + assert Poly(7*x**2 + 2*x + 1, x).all_monoms() == [(2,), (1,), (0,)] + assert Poly(7*x**4 + 2*x + 1, x).all_monoms() == [(4,), (3,), (2,), (1,), (0,)] + + +def test_Poly_all_terms(): + assert Poly(0, x).all_terms() == [((0,), 0)] + assert Poly(1, x).all_terms() == [((0,), 1)] + + assert Poly(2*x + 1, x).all_terms() == [((1,), 2), ((0,), 1)] + + assert Poly(7*x**2 + 2*x + 1, x).all_terms() == \ + [((2,), 7), ((1,), 2), ((0,), 1)] + assert Poly(7*x**4 + 2*x + 1, x).all_terms() == \ + [((4,), 7), ((3,), 0), ((2,), 0), ((1,), 2), ((0,), 1)] + + +def test_Poly_termwise(): + f = Poly(x**2 + 20*x + 400) + g = Poly(x**2 + 2*x + 4) + + def func(monom, coeff): + (k,) = monom + return coeff//10**(2 - k) + + assert f.termwise(func) == g + + def func(monom, coeff): + (k,) = monom + return (k,), coeff//10**(2 - k) + + assert f.termwise(func) == g + + +def test_Poly_length(): + assert Poly(0, x).length() == 0 + assert Poly(1, x).length() == 1 + assert Poly(x, x).length() == 1 + + assert Poly(x + 1, x).length() == 2 + assert Poly(x**2 + 1, x).length() == 2 + assert Poly(x**2 + x + 1, x).length() == 3 + + +def test_Poly_as_dict(): + assert Poly(0, x).as_dict() == {} + assert Poly(0, x, y, z).as_dict() == {} + + assert Poly(1, x).as_dict() == {(0,): 1} + assert Poly(1, x, y, z).as_dict() == {(0, 0, 0): 1} + + assert Poly(x**2 + 3, x).as_dict() == {(2,): 1, (0,): 3} + assert Poly(x**2 + 3, x, y, z).as_dict() == {(2, 0, 0): 1, (0, 0, 0): 3} + + assert Poly(3*x**2*y*z**3 + 4*x*y + 5*x*z).as_dict() == {(2, 1, 3): 3, + (1, 1, 0): 4, (1, 0, 1): 5} + + +def test_Poly_as_expr(): + assert Poly(0, x).as_expr() == 0 + assert Poly(0, x, y, z).as_expr() == 0 + + assert Poly(1, x).as_expr() == 1 + assert Poly(1, x, y, z).as_expr() == 1 + + assert Poly(x**2 + 3, x).as_expr() == x**2 + 3 + assert Poly(x**2 + 3, x, y, z).as_expr() == x**2 + 3 + + assert Poly( + 3*x**2*y*z**3 + 4*x*y + 5*x*z).as_expr() == 3*x**2*y*z**3 + 4*x*y + 5*x*z + + f = Poly(x**2 + 2*x*y**2 - y, x, y) + + assert f.as_expr() == -y + x**2 + 2*x*y**2 + + assert f.as_expr({x: 5}) == 25 - y + 10*y**2 + assert f.as_expr({y: 6}) == -6 + 72*x + x**2 + + assert f.as_expr({x: 5, y: 6}) == 379 + assert f.as_expr(5, 6) == 379 + + raises(GeneratorsError, lambda: f.as_expr({z: 7})) + + +def test_Poly_lift(): + p = Poly(x**4 - I*x + 17*I, x, gaussian=True) + assert p.lift() == Poly(x**8 + x**2 - 34*x + 289, x, domain='QQ') + + +def test_Poly_lift_multiple(): + + r1 = rootof(y**3 + y**2 - 1, 0) + r2 = rootof(z**5 + z**2 - 1, 0) + p = Poly(r1*x + 3*r1**2 - r2 + x**2 - x**5, x, extension=True) + + assert p.lift() == Poly( + -x**75 + 15*x**72 - 5*x**71 + 15*x**70 - 105*x**69 + 70*x**68 - + 220*x**67 + 560*x**66 - 635*x**65 + 1495*x**64 - 2735*x**63 + + 4415*x**62 - 7410*x**61 + 12741*x**60 - 22090*x**59 + 32125*x**58 - + 56281*x**57 + 88157*x**56 - 126842*x**55 + 214223*x**54 - 311802*x**53 + + 462667*x**52 - 700883*x**51 + 1006278*x**50 - 1480950*x**49 + + 2078055*x**48 - 3004675*x**47 + 4140410*x**46 - 5664222*x**45 + + 8029445*x**44 - 10528785*x**43 + 14309614*x**42 - 19032988*x**41 + + 24570573*x**40 - 32530459*x**39 + 41239581*x**38 - 52968051*x**37 + + 65891606*x**36 - 81997276*x**35 + 102530732*x**34 - 122009994*x**33 + + 150227996*x**32 - 176452478*x**31 + 206393768*x**30 - 245291426*x**29 + + 276598718*x**28 - 320005297*x**27 + 353649032*x**26 + - 393246309*x**25 + 434566186*x**24 - 460608964*x**23 + 508052079*x**22 + - 513976618*x**21 + 539374498*x**20 - 557851717*x**19 + 540788016*x**18 + - 564949060*x**17 + 520866566*x**16 + - 507861375*x**15 + 474999819*x**14 - 423619160*x**13 + 414540540*x**12 + - 322522367*x**11 + 311586511*x**10 - 238812299*x**9 + 184482053*x**8 + - 189265274*x**7 + 93619528*x**6 - 106852385*x**5 + 57294385*x**4 - + 26486666*x**3 + 42614683*x**2 - 1511583*x + 15975845, x, domain='QQ' + ) + + +def test_Poly_deflate(): + assert Poly(0, x).deflate() == ((1,), Poly(0, x)) + assert Poly(1, x).deflate() == ((1,), Poly(1, x)) + assert Poly(x, x).deflate() == ((1,), Poly(x, x)) + + assert Poly(x**2, x).deflate() == ((2,), Poly(x, x)) + assert Poly(x**17, x).deflate() == ((17,), Poly(x, x)) + + assert Poly( + x**2*y*z**11 + x**4*z**11).deflate() == ((2, 1, 11), Poly(x*y*z + x**2*z)) + + +def test_Poly_inject(): + f = Poly(x**2*y + x*y**3 + x*y + 1, x) + + assert f.inject() == Poly(x**2*y + x*y**3 + x*y + 1, x, y) + assert f.inject(front=True) == Poly(y**3*x + y*x**2 + y*x + 1, y, x) + + +def test_Poly_eject(): + f = Poly(x**2*y + x*y**3 + x*y + 1, x, y) + + assert f.eject(x) == Poly(x*y**3 + (x**2 + x)*y + 1, y, domain='ZZ[x]') + assert f.eject(y) == Poly(y*x**2 + (y**3 + y)*x + 1, x, domain='ZZ[y]') + + ex = x + y + z + t + w + g = Poly(ex, x, y, z, t, w) + + assert g.eject(x) == Poly(ex, y, z, t, w, domain='ZZ[x]') + assert g.eject(x, y) == Poly(ex, z, t, w, domain='ZZ[x, y]') + assert g.eject(x, y, z) == Poly(ex, t, w, domain='ZZ[x, y, z]') + assert g.eject(w) == Poly(ex, x, y, z, t, domain='ZZ[w]') + assert g.eject(t, w) == Poly(ex, x, y, z, domain='ZZ[t, w]') + assert g.eject(z, t, w) == Poly(ex, x, y, domain='ZZ[z, t, w]') + + raises(DomainError, lambda: Poly(x*y, x, y, domain=ZZ[z]).eject(y)) + raises(NotImplementedError, lambda: Poly(x*y, x, y, z).eject(y)) + + +def test_Poly_exclude(): + assert Poly(x, x, y).exclude() == Poly(x, x) + assert Poly(x*y, x, y).exclude() == Poly(x*y, x, y) + assert Poly(1, x, y).exclude() == Poly(1, x, y) + + +def test_Poly__gen_to_level(): + assert Poly(1, x, y)._gen_to_level(-2) == 0 + assert Poly(1, x, y)._gen_to_level(-1) == 1 + assert Poly(1, x, y)._gen_to_level( 0) == 0 + assert Poly(1, x, y)._gen_to_level( 1) == 1 + + raises(PolynomialError, lambda: Poly(1, x, y)._gen_to_level(-3)) + raises(PolynomialError, lambda: Poly(1, x, y)._gen_to_level( 2)) + + assert Poly(1, x, y)._gen_to_level(x) == 0 + assert Poly(1, x, y)._gen_to_level(y) == 1 + + assert Poly(1, x, y)._gen_to_level('x') == 0 + assert Poly(1, x, y)._gen_to_level('y') == 1 + + raises(PolynomialError, lambda: Poly(1, x, y)._gen_to_level(z)) + raises(PolynomialError, lambda: Poly(1, x, y)._gen_to_level('z')) + + +def test_Poly_degree(): + assert Poly(0, x).degree() is -oo + assert Poly(1, x).degree() == 0 + assert Poly(x, x).degree() == 1 + + assert Poly(0, x).degree(gen=0) is -oo + assert Poly(1, x).degree(gen=0) == 0 + assert Poly(x, x).degree(gen=0) == 1 + + assert Poly(0, x).degree(gen=x) is -oo + assert Poly(1, x).degree(gen=x) == 0 + assert Poly(x, x).degree(gen=x) == 1 + + assert Poly(0, x).degree(gen='x') is -oo + assert Poly(1, x).degree(gen='x') == 0 + assert Poly(x, x).degree(gen='x') == 1 + + raises(PolynomialError, lambda: Poly(1, x).degree(gen=1)) + raises(PolynomialError, lambda: Poly(1, x).degree(gen=y)) + raises(PolynomialError, lambda: Poly(1, x).degree(gen='y')) + + assert Poly(1, x, y).degree() == 0 + assert Poly(2*y, x, y).degree() == 0 + assert Poly(x*y, x, y).degree() == 1 + + assert Poly(1, x, y).degree(gen=x) == 0 + assert Poly(2*y, x, y).degree(gen=x) == 0 + assert Poly(x*y, x, y).degree(gen=x) == 1 + + assert Poly(1, x, y).degree(gen=y) == 0 + assert Poly(2*y, x, y).degree(gen=y) == 1 + assert Poly(x*y, x, y).degree(gen=y) == 1 + + assert degree(0, x) is -oo + assert degree(1, x) == 0 + assert degree(x, x) == 1 + + assert degree(x*y**2, x) == 1 + assert degree(x*y**2, y) == 2 + assert degree(x*y**2, z) == 0 + + assert degree(pi) == 1 + + raises(TypeError, lambda: degree(y**2 + x**3)) + raises(TypeError, lambda: degree(y**2 + x**3, 1)) + raises(PolynomialError, lambda: degree(x, 1.1)) + raises(PolynomialError, lambda: degree(x**2/(x**3 + 1), x)) + + assert degree(Poly(0,x),z) is -oo + assert degree(Poly(1,x),z) == 0 + assert degree(Poly(x**2+y**3,y)) == 3 + assert degree(Poly(y**2 + x**3, y, x), 1) == 3 + assert degree(Poly(y**2 + x**3, x), z) == 0 + assert degree(Poly(y**2 + x**3 + z**4, x), z) == 4 + +def test_Poly_degree_list(): + assert Poly(0, x).degree_list() == (-oo,) + assert Poly(0, x, y).degree_list() == (-oo, -oo) + assert Poly(0, x, y, z).degree_list() == (-oo, -oo, -oo) + + assert Poly(1, x).degree_list() == (0,) + assert Poly(1, x, y).degree_list() == (0, 0) + assert Poly(1, x, y, z).degree_list() == (0, 0, 0) + + assert Poly(x**2*y + x**3*z**2 + 1).degree_list() == (3, 1, 2) + + assert degree_list(1, x) == (0,) + assert degree_list(x, x) == (1,) + + assert degree_list(x*y**2) == (1, 2) + + raises(ComputationFailed, lambda: degree_list(1)) + + +def test_Poly_total_degree(): + assert Poly(x**2*y + x**3*z**2 + 1).total_degree() == 5 + assert Poly(x**2 + z**3).total_degree() == 3 + assert Poly(x*y*z + z**4).total_degree() == 4 + assert Poly(x**3 + x + 1).total_degree() == 3 + + assert total_degree(x*y + z**3) == 3 + assert total_degree(x*y + z**3, x, y) == 2 + assert total_degree(1) == 0 + assert total_degree(Poly(y**2 + x**3 + z**4)) == 4 + assert total_degree(Poly(y**2 + x**3 + z**4, x)) == 3 + assert total_degree(Poly(y**2 + x**3 + z**4, x), z) == 4 + assert total_degree(Poly(x**9 + x*z*y + x**3*z**2 + z**7,x), z) == 7 + +def test_Poly_homogenize(): + assert Poly(x**2+y).homogenize(z) == Poly(x**2+y*z) + assert Poly(x+y).homogenize(z) == Poly(x+y, x, y, z) + assert Poly(x+y**2).homogenize(y) == Poly(x*y+y**2) + + +def test_Poly_homogeneous_order(): + assert Poly(0, x, y).homogeneous_order() is -oo + assert Poly(1, x, y).homogeneous_order() == 0 + assert Poly(x, x, y).homogeneous_order() == 1 + assert Poly(x*y, x, y).homogeneous_order() == 2 + + assert Poly(x + 1, x, y).homogeneous_order() is None + assert Poly(x*y + x, x, y).homogeneous_order() is None + + assert Poly(x**5 + 2*x**3*y**2 + 9*x*y**4).homogeneous_order() == 5 + assert Poly(x**5 + 2*x**3*y**3 + 9*x*y**4).homogeneous_order() is None + + +def test_Poly_LC(): + assert Poly(0, x).LC() == 0 + assert Poly(1, x).LC() == 1 + assert Poly(2*x**2 + x, x).LC() == 2 + + assert Poly(x*y**7 + 2*x**2*y**3).LC('lex') == 2 + assert Poly(x*y**7 + 2*x**2*y**3).LC('grlex') == 1 + + assert LC(x*y**7 + 2*x**2*y**3, order='lex') == 2 + assert LC(x*y**7 + 2*x**2*y**3, order='grlex') == 1 + + +def test_Poly_TC(): + assert Poly(0, x).TC() == 0 + assert Poly(1, x).TC() == 1 + assert Poly(2*x**2 + x, x).TC() == 0 + + +def test_Poly_EC(): + assert Poly(0, x).EC() == 0 + assert Poly(1, x).EC() == 1 + assert Poly(2*x**2 + x, x).EC() == 1 + + assert Poly(x*y**7 + 2*x**2*y**3).EC('lex') == 1 + assert Poly(x*y**7 + 2*x**2*y**3).EC('grlex') == 2 + + +def test_Poly_coeff(): + assert Poly(0, x).coeff_monomial(1) == 0 + assert Poly(0, x).coeff_monomial(x) == 0 + + assert Poly(1, x).coeff_monomial(1) == 1 + assert Poly(1, x).coeff_monomial(x) == 0 + + assert Poly(x**8, x).coeff_monomial(1) == 0 + assert Poly(x**8, x).coeff_monomial(x**7) == 0 + assert Poly(x**8, x).coeff_monomial(x**8) == 1 + assert Poly(x**8, x).coeff_monomial(x**9) == 0 + + assert Poly(3*x*y**2 + 1, x, y).coeff_monomial(1) == 1 + assert Poly(3*x*y**2 + 1, x, y).coeff_monomial(x*y**2) == 3 + + p = Poly(24*x*y*exp(8) + 23*x, x, y) + + assert p.coeff_monomial(x) == 23 + assert p.coeff_monomial(y) == 0 + assert p.coeff_monomial(x*y) == 24*exp(8) + + assert p.as_expr().coeff(x) == 24*y*exp(8) + 23 + raises(NotImplementedError, lambda: p.coeff(x)) + + raises(ValueError, lambda: Poly(x + 1).coeff_monomial(0)) + raises(ValueError, lambda: Poly(x + 1).coeff_monomial(3*x)) + raises(ValueError, lambda: Poly(x + 1).coeff_monomial(3*x*y)) + + +def test_Poly_nth(): + assert Poly(0, x).nth(0) == 0 + assert Poly(0, x).nth(1) == 0 + + assert Poly(1, x).nth(0) == 1 + assert Poly(1, x).nth(1) == 0 + + assert Poly(x**8, x).nth(0) == 0 + assert Poly(x**8, x).nth(7) == 0 + assert Poly(x**8, x).nth(8) == 1 + assert Poly(x**8, x).nth(9) == 0 + + assert Poly(3*x*y**2 + 1, x, y).nth(0, 0) == 1 + assert Poly(3*x*y**2 + 1, x, y).nth(1, 2) == 3 + + raises(ValueError, lambda: Poly(x*y + 1, x, y).nth(1)) + + +def test_Poly_LM(): + assert Poly(0, x).LM() == (0,) + assert Poly(1, x).LM() == (0,) + assert Poly(2*x**2 + x, x).LM() == (2,) + + assert Poly(x*y**7 + 2*x**2*y**3).LM('lex') == (2, 3) + assert Poly(x*y**7 + 2*x**2*y**3).LM('grlex') == (1, 7) + + assert LM(x*y**7 + 2*x**2*y**3, order='lex') == x**2*y**3 + assert LM(x*y**7 + 2*x**2*y**3, order='grlex') == x*y**7 + + +def test_Poly_LM_custom_order(): + f = Poly(x**2*y**3*z + x**2*y*z**3 + x*y*z + 1) + rev_lex = lambda monom: tuple(reversed(monom)) + + assert f.LM(order='lex') == (2, 3, 1) + assert f.LM(order=rev_lex) == (2, 1, 3) + + +def test_Poly_EM(): + assert Poly(0, x).EM() == (0,) + assert Poly(1, x).EM() == (0,) + assert Poly(2*x**2 + x, x).EM() == (1,) + + assert Poly(x*y**7 + 2*x**2*y**3).EM('lex') == (1, 7) + assert Poly(x*y**7 + 2*x**2*y**3).EM('grlex') == (2, 3) + + +def test_Poly_LT(): + assert Poly(0, x).LT() == ((0,), 0) + assert Poly(1, x).LT() == ((0,), 1) + assert Poly(2*x**2 + x, x).LT() == ((2,), 2) + + assert Poly(x*y**7 + 2*x**2*y**3).LT('lex') == ((2, 3), 2) + assert Poly(x*y**7 + 2*x**2*y**3).LT('grlex') == ((1, 7), 1) + + assert LT(x*y**7 + 2*x**2*y**3, order='lex') == 2*x**2*y**3 + assert LT(x*y**7 + 2*x**2*y**3, order='grlex') == x*y**7 + + +def test_Poly_ET(): + assert Poly(0, x).ET() == ((0,), 0) + assert Poly(1, x).ET() == ((0,), 1) + assert Poly(2*x**2 + x, x).ET() == ((1,), 1) + + assert Poly(x*y**7 + 2*x**2*y**3).ET('lex') == ((1, 7), 1) + assert Poly(x*y**7 + 2*x**2*y**3).ET('grlex') == ((2, 3), 2) + + +def test_Poly_max_norm(): + assert Poly(-1, x).max_norm() == 1 + assert Poly( 0, x).max_norm() == 0 + assert Poly( 1, x).max_norm() == 1 + + +def test_Poly_l1_norm(): + assert Poly(-1, x).l1_norm() == 1 + assert Poly( 0, x).l1_norm() == 0 + assert Poly( 1, x).l1_norm() == 1 + + +def test_Poly_clear_denoms(): + coeff, poly = Poly(x + 2, x).clear_denoms() + assert coeff == 1 and poly == Poly( + x + 2, x, domain='ZZ') and poly.get_domain() == ZZ + + coeff, poly = Poly(x/2 + 1, x).clear_denoms() + assert coeff == 2 and poly == Poly( + x + 2, x, domain='QQ') and poly.get_domain() == QQ + + coeff, poly = Poly(2*x**2 + 3, modulus=5).clear_denoms() + assert coeff == 1 and poly == Poly( + 2*x**2 + 3, x, modulus=5) and poly.get_domain() == FF(5) + + coeff, poly = Poly(x/2 + 1, x).clear_denoms(convert=True) + assert coeff == 2 and poly == Poly( + x + 2, x, domain='ZZ') and poly.get_domain() == ZZ + + coeff, poly = Poly(x/y + 1, x).clear_denoms(convert=True) + assert coeff == y and poly == Poly( + x + y, x, domain='ZZ[y]') and poly.get_domain() == ZZ[y] + + coeff, poly = Poly(x/3 + sqrt(2), x, domain='EX').clear_denoms() + assert coeff == 3 and poly == Poly( + x + 3*sqrt(2), x, domain='EX') and poly.get_domain() == EX + + coeff, poly = Poly( + x/3 + sqrt(2), x, domain='EX').clear_denoms(convert=True) + assert coeff == 3 and poly == Poly( + x + 3*sqrt(2), x, domain='EX') and poly.get_domain() == EX + + +def test_Poly_rat_clear_denoms(): + f = Poly(x**2/y + 1, x) + g = Poly(x**3 + y, x) + + assert f.rat_clear_denoms(g) == \ + (Poly(x**2 + y, x), Poly(y*x**3 + y**2, x)) + + f = f.set_domain(EX) + g = g.set_domain(EX) + + assert f.rat_clear_denoms(g) == (f, g) + + +def test_issue_20427(): + f = Poly(-117968192370600*18**(S(1)/3)/(217603955769048*(24201 + + 253*sqrt(9165))**(S(1)/3) + 2273005839412*sqrt(9165)*(24201 + + 253*sqrt(9165))**(S(1)/3)) - 15720318185*2**(S(2)/3)*3**(S(1)/3)*(24201 + + 253*sqrt(9165))**(S(2)/3)/(217603955769048*(24201 + 253*sqrt(9165))** + (S(1)/3) + 2273005839412*sqrt(9165)*(24201 + 253*sqrt(9165))**(S(1)/3)) + + 15720318185*12**(S(1)/3)*(24201 + 253*sqrt(9165))**(S(2)/3)/( + 217603955769048*(24201 + 253*sqrt(9165))**(S(1)/3) + 2273005839412* + sqrt(9165)*(24201 + 253*sqrt(9165))**(S(1)/3)) + 117968192370600*2**( + S(1)/3)*3**(S(2)/3)/(217603955769048*(24201 + 253*sqrt(9165))**(S(1)/3) + + 2273005839412*sqrt(9165)*(24201 + 253*sqrt(9165))**(S(1)/3)), x) + assert f == Poly(0, x, domain='EX') + + +def test_Poly_integrate(): + assert Poly(x + 1).integrate() == Poly(x**2/2 + x) + assert Poly(x + 1).integrate(x) == Poly(x**2/2 + x) + assert Poly(x + 1).integrate((x, 1)) == Poly(x**2/2 + x) + + assert Poly(x*y + 1).integrate(x) == Poly(x**2*y/2 + x) + assert Poly(x*y + 1).integrate(y) == Poly(x*y**2/2 + y) + + assert Poly(x*y + 1).integrate(x, x) == Poly(x**3*y/6 + x**2/2) + assert Poly(x*y + 1).integrate(y, y) == Poly(x*y**3/6 + y**2/2) + + assert Poly(x*y + 1).integrate((x, 2)) == Poly(x**3*y/6 + x**2/2) + assert Poly(x*y + 1).integrate((y, 2)) == Poly(x*y**3/6 + y**2/2) + + assert Poly(x*y + 1).integrate(x, y) == Poly(x**2*y**2/4 + x*y) + assert Poly(x*y + 1).integrate(y, x) == Poly(x**2*y**2/4 + x*y) + + +def test_Poly_diff(): + assert Poly(x**2 + x).diff() == Poly(2*x + 1) + assert Poly(x**2 + x).diff(x) == Poly(2*x + 1) + assert Poly(x**2 + x).diff((x, 1)) == Poly(2*x + 1) + + assert Poly(x**2*y**2 + x*y).diff(x) == Poly(2*x*y**2 + y) + assert Poly(x**2*y**2 + x*y).diff(y) == Poly(2*x**2*y + x) + + assert Poly(x**2*y**2 + x*y).diff(x, x) == Poly(2*y**2, x, y) + assert Poly(x**2*y**2 + x*y).diff(y, y) == Poly(2*x**2, x, y) + + assert Poly(x**2*y**2 + x*y).diff((x, 2)) == Poly(2*y**2, x, y) + assert Poly(x**2*y**2 + x*y).diff((y, 2)) == Poly(2*x**2, x, y) + + assert Poly(x**2*y**2 + x*y).diff(x, y) == Poly(4*x*y + 1) + assert Poly(x**2*y**2 + x*y).diff(y, x) == Poly(4*x*y + 1) + + +def test_issue_9585(): + assert diff(Poly(x**2 + x)) == Poly(2*x + 1) + assert diff(Poly(x**2 + x), x, evaluate=False) == \ + Derivative(Poly(x**2 + x), x) + assert Derivative(Poly(x**2 + x), x).doit() == Poly(2*x + 1) + + +def test_Poly_eval(): + assert Poly(0, x).eval(7) == 0 + assert Poly(1, x).eval(7) == 1 + assert Poly(x, x).eval(7) == 7 + + assert Poly(0, x).eval(0, 7) == 0 + assert Poly(1, x).eval(0, 7) == 1 + assert Poly(x, x).eval(0, 7) == 7 + + assert Poly(0, x).eval(x, 7) == 0 + assert Poly(1, x).eval(x, 7) == 1 + assert Poly(x, x).eval(x, 7) == 7 + + assert Poly(0, x).eval('x', 7) == 0 + assert Poly(1, x).eval('x', 7) == 1 + assert Poly(x, x).eval('x', 7) == 7 + + raises(PolynomialError, lambda: Poly(1, x).eval(1, 7)) + raises(PolynomialError, lambda: Poly(1, x).eval(y, 7)) + raises(PolynomialError, lambda: Poly(1, x).eval('y', 7)) + + assert Poly(123, x, y).eval(7) == Poly(123, y) + assert Poly(2*y, x, y).eval(7) == Poly(2*y, y) + assert Poly(x*y, x, y).eval(7) == Poly(7*y, y) + + assert Poly(123, x, y).eval(x, 7) == Poly(123, y) + assert Poly(2*y, x, y).eval(x, 7) == Poly(2*y, y) + assert Poly(x*y, x, y).eval(x, 7) == Poly(7*y, y) + + assert Poly(123, x, y).eval(y, 7) == Poly(123, x) + assert Poly(2*y, x, y).eval(y, 7) == Poly(14, x) + assert Poly(x*y, x, y).eval(y, 7) == Poly(7*x, x) + + assert Poly(x*y + y, x, y).eval({x: 7}) == Poly(8*y, y) + assert Poly(x*y + y, x, y).eval({y: 7}) == Poly(7*x + 7, x) + + assert Poly(x*y + y, x, y).eval({x: 6, y: 7}) == 49 + assert Poly(x*y + y, x, y).eval({x: 7, y: 6}) == 48 + + assert Poly(x*y + y, x, y).eval((6, 7)) == 49 + assert Poly(x*y + y, x, y).eval([6, 7]) == 49 + + assert Poly(x + 1, domain='ZZ').eval(S.Half) == Rational(3, 2) + assert Poly(x + 1, domain='ZZ').eval(sqrt(2)) == sqrt(2) + 1 + + raises(ValueError, lambda: Poly(x*y + y, x, y).eval((6, 7, 8))) + raises(DomainError, lambda: Poly(x + 1, domain='ZZ').eval(S.Half, auto=False)) + + # issue 6344 + alpha = Symbol('alpha') + result = (2*alpha*z - 2*alpha + z**2 + 3)/(z**2 - 2*z + 1) + + f = Poly(x**2 + (alpha - 1)*x - alpha + 1, x, domain='ZZ[alpha]') + assert f.eval((z + 1)/(z - 1)) == result + + g = Poly(x**2 + (alpha - 1)*x - alpha + 1, x, y, domain='ZZ[alpha]') + assert g.eval((z + 1)/(z - 1)) == Poly(result, y, domain='ZZ(alpha,z)') + +def test_Poly___call__(): + f = Poly(2*x*y + 3*x + y + 2*z) + + assert f(2) == Poly(5*y + 2*z + 6) + assert f(2, 5) == Poly(2*z + 31) + assert f(2, 5, 7) == 45 + + +def test_parallel_poly_from_expr(): + assert parallel_poly_from_expr( + [x - 1, x**2 - 1], x)[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [Poly(x - 1, x), x**2 - 1], x)[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [x - 1, Poly(x**2 - 1, x)], x)[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr([Poly( + x - 1, x), Poly(x**2 - 1, x)], x)[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + + assert parallel_poly_from_expr( + [x - 1, x**2 - 1], x, y)[0] == [Poly(x - 1, x, y), Poly(x**2 - 1, x, y)] + assert parallel_poly_from_expr([Poly( + x - 1, x), x**2 - 1], x, y)[0] == [Poly(x - 1, x, y), Poly(x**2 - 1, x, y)] + assert parallel_poly_from_expr([x - 1, Poly( + x**2 - 1, x)], x, y)[0] == [Poly(x - 1, x, y), Poly(x**2 - 1, x, y)] + assert parallel_poly_from_expr([Poly(x - 1, x), Poly( + x**2 - 1, x)], x, y)[0] == [Poly(x - 1, x, y), Poly(x**2 - 1, x, y)] + + assert parallel_poly_from_expr( + [x - 1, x**2 - 1])[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [Poly(x - 1, x), x**2 - 1])[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [x - 1, Poly(x**2 - 1, x)])[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [Poly(x - 1, x), Poly(x**2 - 1, x)])[0] == [Poly(x - 1, x), Poly(x**2 - 1, x)] + + assert parallel_poly_from_expr( + [1, x**2 - 1])[0] == [Poly(1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [1, x**2 - 1])[0] == [Poly(1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [1, Poly(x**2 - 1, x)])[0] == [Poly(1, x), Poly(x**2 - 1, x)] + assert parallel_poly_from_expr( + [1, Poly(x**2 - 1, x)])[0] == [Poly(1, x), Poly(x**2 - 1, x)] + + assert parallel_poly_from_expr( + [x**2 - 1, 1])[0] == [Poly(x**2 - 1, x), Poly(1, x)] + assert parallel_poly_from_expr( + [x**2 - 1, 1])[0] == [Poly(x**2 - 1, x), Poly(1, x)] + assert parallel_poly_from_expr( + [Poly(x**2 - 1, x), 1])[0] == [Poly(x**2 - 1, x), Poly(1, x)] + assert parallel_poly_from_expr( + [Poly(x**2 - 1, x), 1])[0] == [Poly(x**2 - 1, x), Poly(1, x)] + + assert parallel_poly_from_expr([Poly(x, x, y), Poly(y, x, y)], x, y, order='lex')[0] == \ + [Poly(x, x, y, domain='ZZ'), Poly(y, x, y, domain='ZZ')] + + raises(PolificationFailed, lambda: parallel_poly_from_expr([0, 1])) + + +def test_pdiv(): + f, g = x**2 - y**2, x - y + q, r = x + y, 0 + + F, G, Q, R = [ Poly(h, x, y) for h in (f, g, q, r) ] + + assert F.pdiv(G) == (Q, R) + assert F.prem(G) == R + assert F.pquo(G) == Q + assert F.pexquo(G) == Q + + assert pdiv(f, g) == (q, r) + assert prem(f, g) == r + assert pquo(f, g) == q + assert pexquo(f, g) == q + + assert pdiv(f, g, x, y) == (q, r) + assert prem(f, g, x, y) == r + assert pquo(f, g, x, y) == q + assert pexquo(f, g, x, y) == q + + assert pdiv(f, g, (x, y)) == (q, r) + assert prem(f, g, (x, y)) == r + assert pquo(f, g, (x, y)) == q + assert pexquo(f, g, (x, y)) == q + + assert pdiv(F, G) == (Q, R) + assert prem(F, G) == R + assert pquo(F, G) == Q + assert pexquo(F, G) == Q + + assert pdiv(f, g, polys=True) == (Q, R) + assert prem(f, g, polys=True) == R + assert pquo(f, g, polys=True) == Q + assert pexquo(f, g, polys=True) == Q + + assert pdiv(F, G, polys=False) == (q, r) + assert prem(F, G, polys=False) == r + assert pquo(F, G, polys=False) == q + assert pexquo(F, G, polys=False) == q + + raises(ComputationFailed, lambda: pdiv(4, 2)) + raises(ComputationFailed, lambda: prem(4, 2)) + raises(ComputationFailed, lambda: pquo(4, 2)) + raises(ComputationFailed, lambda: pexquo(4, 2)) + + +def test_div(): + f, g = x**2 - y**2, x - y + q, r = x + y, 0 + + F, G, Q, R = [ Poly(h, x, y) for h in (f, g, q, r) ] + + assert F.div(G) == (Q, R) + assert F.rem(G) == R + assert F.quo(G) == Q + assert F.exquo(G) == Q + + assert div(f, g) == (q, r) + assert rem(f, g) == r + assert quo(f, g) == q + assert exquo(f, g) == q + + assert div(f, g, x, y) == (q, r) + assert rem(f, g, x, y) == r + assert quo(f, g, x, y) == q + assert exquo(f, g, x, y) == q + + assert div(f, g, (x, y)) == (q, r) + assert rem(f, g, (x, y)) == r + assert quo(f, g, (x, y)) == q + assert exquo(f, g, (x, y)) == q + + assert div(F, G) == (Q, R) + assert rem(F, G) == R + assert quo(F, G) == Q + assert exquo(F, G) == Q + + assert div(f, g, polys=True) == (Q, R) + assert rem(f, g, polys=True) == R + assert quo(f, g, polys=True) == Q + assert exquo(f, g, polys=True) == Q + + assert div(F, G, polys=False) == (q, r) + assert rem(F, G, polys=False) == r + assert quo(F, G, polys=False) == q + assert exquo(F, G, polys=False) == q + + raises(ComputationFailed, lambda: div(4, 2)) + raises(ComputationFailed, lambda: rem(4, 2)) + raises(ComputationFailed, lambda: quo(4, 2)) + raises(ComputationFailed, lambda: exquo(4, 2)) + + f, g = x**2 + 1, 2*x - 4 + + qz, rz = 0, x**2 + 1 + qq, rq = x/2 + 1, 5 + + assert div(f, g) == (qq, rq) + assert div(f, g, auto=True) == (qq, rq) + assert div(f, g, auto=False) == (qz, rz) + assert div(f, g, domain=ZZ) == (qz, rz) + assert div(f, g, domain=QQ) == (qq, rq) + assert div(f, g, domain=ZZ, auto=True) == (qq, rq) + assert div(f, g, domain=ZZ, auto=False) == (qz, rz) + assert div(f, g, domain=QQ, auto=True) == (qq, rq) + assert div(f, g, domain=QQ, auto=False) == (qq, rq) + + assert rem(f, g) == rq + assert rem(f, g, auto=True) == rq + assert rem(f, g, auto=False) == rz + assert rem(f, g, domain=ZZ) == rz + assert rem(f, g, domain=QQ) == rq + assert rem(f, g, domain=ZZ, auto=True) == rq + assert rem(f, g, domain=ZZ, auto=False) == rz + assert rem(f, g, domain=QQ, auto=True) == rq + assert rem(f, g, domain=QQ, auto=False) == rq + + assert quo(f, g) == qq + assert quo(f, g, auto=True) == qq + assert quo(f, g, auto=False) == qz + assert quo(f, g, domain=ZZ) == qz + assert quo(f, g, domain=QQ) == qq + assert quo(f, g, domain=ZZ, auto=True) == qq + assert quo(f, g, domain=ZZ, auto=False) == qz + assert quo(f, g, domain=QQ, auto=True) == qq + assert quo(f, g, domain=QQ, auto=False) == qq + + f, g, q = x**2, 2*x, x/2 + + assert exquo(f, g) == q + assert exquo(f, g, auto=True) == q + raises(ExactQuotientFailed, lambda: exquo(f, g, auto=False)) + raises(ExactQuotientFailed, lambda: exquo(f, g, domain=ZZ)) + assert exquo(f, g, domain=QQ) == q + assert exquo(f, g, domain=ZZ, auto=True) == q + raises(ExactQuotientFailed, lambda: exquo(f, g, domain=ZZ, auto=False)) + assert exquo(f, g, domain=QQ, auto=True) == q + assert exquo(f, g, domain=QQ, auto=False) == q + + f, g = Poly(x**2), Poly(x) + + q, r = f.div(g) + assert q.get_domain().is_ZZ and r.get_domain().is_ZZ + r = f.rem(g) + assert r.get_domain().is_ZZ + q = f.quo(g) + assert q.get_domain().is_ZZ + q = f.exquo(g) + assert q.get_domain().is_ZZ + + f, g = Poly(x+y, x), Poly(2*x+y, x) + q, r = f.div(g) + assert q.get_domain().is_Frac and r.get_domain().is_Frac + + # https://github.com/sympy/sympy/issues/19579 + p = Poly(2+3*I, x, domain=ZZ_I) + q = Poly(1-I, x, domain=ZZ_I) + assert p.div(q, auto=False) == \ + (Poly(0, x, domain='ZZ_I'), Poly(2 + 3*I, x, domain='ZZ_I')) + assert p.div(q, auto=True) == \ + (Poly(-S(1)/2 + 5*I/2, x, domain='QQ_I'), Poly(0, x, domain='QQ_I')) + + f = 5*x**2 + 10*x + 3 + g = 2*x + 2 + assert div(f, g, domain=ZZ) == (0, f) + + +def test_issue_7864(): + q, r = div(a, .408248290463863*a) + assert abs(q - 2.44948974278318) < 1e-14 + assert r == 0 + + +def test_gcdex(): + f, g = 2*x, x**2 - 16 + s, t, h = x/32, Rational(-1, 16), 1 + + F, G, S, T, H = [ Poly(u, x, domain='QQ') for u in (f, g, s, t, h) ] + + assert F.half_gcdex(G) == (S, H) + assert F.gcdex(G) == (S, T, H) + assert F.invert(G) == S + + assert half_gcdex(f, g) == (s, h) + assert gcdex(f, g) == (s, t, h) + assert invert(f, g) == s + + assert half_gcdex(f, g, x) == (s, h) + assert gcdex(f, g, x) == (s, t, h) + assert invert(f, g, x) == s + + assert half_gcdex(f, g, (x,)) == (s, h) + assert gcdex(f, g, (x,)) == (s, t, h) + assert invert(f, g, (x,)) == s + + assert half_gcdex(F, G) == (S, H) + assert gcdex(F, G) == (S, T, H) + assert invert(F, G) == S + + assert half_gcdex(f, g, polys=True) == (S, H) + assert gcdex(f, g, polys=True) == (S, T, H) + assert invert(f, g, polys=True) == S + + assert half_gcdex(F, G, polys=False) == (s, h) + assert gcdex(F, G, polys=False) == (s, t, h) + assert invert(F, G, polys=False) == s + + assert half_gcdex(100, 2004) == (-20, 4) + assert gcdex(100, 2004) == (-20, 1, 4) + assert invert(3, 7) == 5 + + raises(DomainError, lambda: half_gcdex(x + 1, 2*x + 1, auto=False)) + raises(DomainError, lambda: gcdex(x + 1, 2*x + 1, auto=False)) + raises(DomainError, lambda: invert(x + 1, 2*x + 1, auto=False)) + + +def test_revert(): + f = Poly(1 - x**2/2 + x**4/24 - x**6/720) + g = Poly(61*x**6/720 + 5*x**4/24 + x**2/2 + 1) + + assert f.revert(8) == g + + +def test_subresultants(): + f, g, h = x**2 - 2*x + 1, x**2 - 1, 2*x - 2 + F, G, H = Poly(f), Poly(g), Poly(h) + + assert F.subresultants(G) == [F, G, H] + assert subresultants(f, g) == [f, g, h] + assert subresultants(f, g, x) == [f, g, h] + assert subresultants(f, g, (x,)) == [f, g, h] + assert subresultants(F, G) == [F, G, H] + assert subresultants(f, g, polys=True) == [F, G, H] + assert subresultants(F, G, polys=False) == [f, g, h] + + raises(ComputationFailed, lambda: subresultants(4, 2)) + + +def test_resultant(): + f, g, h = x**2 - 2*x + 1, x**2 - 1, 0 + F, G = Poly(f), Poly(g) + + assert F.resultant(G) == h + assert resultant(f, g) == h + assert resultant(f, g, x) == h + assert resultant(f, g, (x,)) == h + assert resultant(F, G) == h + assert resultant(f, g, polys=True) == h + assert resultant(F, G, polys=False) == h + assert resultant(f, g, includePRS=True) == (h, [f, g, 2*x - 2]) + + f, g, h = x - a, x - b, a - b + F, G, H = Poly(f), Poly(g), Poly(h) + + assert F.resultant(G) == H + assert resultant(f, g) == h + assert resultant(f, g, x) == h + assert resultant(f, g, (x,)) == h + assert resultant(F, G) == H + assert resultant(f, g, polys=True) == H + assert resultant(F, G, polys=False) == h + + raises(ComputationFailed, lambda: resultant(4, 2)) + + +def test_discriminant(): + f, g = x**3 + 3*x**2 + 9*x - 13, -11664 + F = Poly(f) + + assert F.discriminant() == g + assert discriminant(f) == g + assert discriminant(f, x) == g + assert discriminant(f, (x,)) == g + assert discriminant(F) == g + assert discriminant(f, polys=True) == g + assert discriminant(F, polys=False) == g + + f, g = a*x**2 + b*x + c, b**2 - 4*a*c + F, G = Poly(f), Poly(g) + + assert F.discriminant() == G + assert discriminant(f) == g + assert discriminant(f, x, a, b, c) == g + assert discriminant(f, (x, a, b, c)) == g + assert discriminant(F) == G + assert discriminant(f, polys=True) == G + assert discriminant(F, polys=False) == g + + raises(ComputationFailed, lambda: discriminant(4)) + + +def test_dispersion(): + # We test only the API here. For more mathematical + # tests see the dedicated test file. + fp = poly((x + 1)*(x + 2), x) + assert sorted(fp.dispersionset()) == [0, 1] + assert fp.dispersion() == 1 + + fp = poly(x**4 - 3*x**2 + 1, x) + gp = fp.shift(-3) + assert sorted(fp.dispersionset(gp)) == [2, 3, 4] + assert fp.dispersion(gp) == 4 + + +def test_gcd_list(): + F = [x**3 - 1, x**2 - 1, x**2 - 3*x + 2] + + assert gcd_list(F) == x - 1 + assert gcd_list(F, polys=True) == Poly(x - 1) + + assert gcd_list([]) == 0 + assert gcd_list([1, 2]) == 1 + assert gcd_list([4, 6, 8]) == 2 + + assert gcd_list([x*(y + 42) - x*y - x*42]) == 0 + + gcd = gcd_list([], x) + assert gcd.is_Number and gcd is S.Zero + + gcd = gcd_list([], x, polys=True) + assert gcd.is_Poly and gcd.is_zero + + a = sqrt(2) + assert gcd_list([a, -a]) == gcd_list([-a, a]) == a + + raises(ComputationFailed, lambda: gcd_list([], polys=True)) + + +def test_lcm_list(): + F = [x**3 - 1, x**2 - 1, x**2 - 3*x + 2] + + assert lcm_list(F) == x**5 - x**4 - 2*x**3 - x**2 + x + 2 + assert lcm_list(F, polys=True) == Poly(x**5 - x**4 - 2*x**3 - x**2 + x + 2) + + assert lcm_list([]) == 1 + assert lcm_list([1, 2]) == 2 + assert lcm_list([4, 6, 8]) == 24 + + assert lcm_list([x*(y + 42) - x*y - x*42]) == 0 + + lcm = lcm_list([], x) + assert lcm.is_Number and lcm is S.One + + lcm = lcm_list([], x, polys=True) + assert lcm.is_Poly and lcm.is_one + + raises(ComputationFailed, lambda: lcm_list([], polys=True)) + + +def test_gcd(): + f, g = x**3 - 1, x**2 - 1 + s, t = x**2 + x + 1, x + 1 + h, r = x - 1, x**4 + x**3 - x - 1 + + F, G, S, T, H, R = [ Poly(u) for u in (f, g, s, t, h, r) ] + + assert F.cofactors(G) == (H, S, T) + assert F.gcd(G) == H + assert F.lcm(G) == R + + assert cofactors(f, g) == (h, s, t) + assert gcd(f, g) == h + assert lcm(f, g) == r + + assert cofactors(f, g, x) == (h, s, t) + assert gcd(f, g, x) == h + assert lcm(f, g, x) == r + + assert cofactors(f, g, (x,)) == (h, s, t) + assert gcd(f, g, (x,)) == h + assert lcm(f, g, (x,)) == r + + assert cofactors(F, G) == (H, S, T) + assert gcd(F, G) == H + assert lcm(F, G) == R + + assert cofactors(f, g, polys=True) == (H, S, T) + assert gcd(f, g, polys=True) == H + assert lcm(f, g, polys=True) == R + + assert cofactors(F, G, polys=False) == (h, s, t) + assert gcd(F, G, polys=False) == h + assert lcm(F, G, polys=False) == r + + f, g = 1.0*x**2 - 1.0, 1.0*x - 1.0 + h, s, t = g, 1.0*x + 1.0, 1.0 + + assert cofactors(f, g) == (h, s, t) + assert gcd(f, g) == h + assert lcm(f, g) == f + + f, g = 1.0*x**2 - 1.0, 1.0*x - 1.0 + h, s, t = g, 1.0*x + 1.0, 1.0 + + assert cofactors(f, g) == (h, s, t) + assert gcd(f, g) == h + assert lcm(f, g) == f + + assert cofactors(8, 6) == (2, 4, 3) + assert gcd(8, 6) == 2 + assert lcm(8, 6) == 24 + + f, g = x**2 - 3*x - 4, x**3 - 4*x**2 + x - 4 + l = x**4 - 3*x**3 - 3*x**2 - 3*x - 4 + h, s, t = x - 4, x + 1, x**2 + 1 + + assert cofactors(f, g, modulus=11) == (h, s, t) + assert gcd(f, g, modulus=11) == h + assert lcm(f, g, modulus=11) == l + + f, g = x**2 + 8*x + 7, x**3 + 7*x**2 + x + 7 + l = x**4 + 8*x**3 + 8*x**2 + 8*x + 7 + h, s, t = x + 7, x + 1, x**2 + 1 + + assert cofactors(f, g, modulus=11, symmetric=False) == (h, s, t) + assert gcd(f, g, modulus=11, symmetric=False) == h + assert lcm(f, g, modulus=11, symmetric=False) == l + + a, b = sqrt(2), -sqrt(2) + assert gcd(a, b) == gcd(b, a) == sqrt(2) + + a, b = sqrt(-2), -sqrt(-2) + assert gcd(a, b) == gcd(b, a) == sqrt(2) + + assert gcd(Poly(x - 2, x), Poly(I*x, x)) == Poly(1, x, domain=ZZ_I) + + raises(TypeError, lambda: gcd(x)) + raises(TypeError, lambda: lcm(x)) + + f = Poly(-1, x) + g = Poly(1, x) + assert lcm(f, g) == Poly(1, x) + + f = Poly(0, x) + g = Poly([1, 1], x) + for i in (f, g): + assert lcm(i, 0) == 0 + assert lcm(0, i) == 0 + assert lcm(i, f) == 0 + assert lcm(f, i) == 0 + + f = 4*x**2 + x + 2 + pfz = Poly(f, domain=ZZ) + pfq = Poly(f, domain=QQ) + + assert pfz.gcd(pfz) == pfz + assert pfz.lcm(pfz) == pfz + assert pfq.gcd(pfq) == pfq.monic() + assert pfq.lcm(pfq) == pfq.monic() + assert gcd(f, f) == f + assert lcm(f, f) == f + assert gcd(f, f, domain=QQ) == monic(f) + assert lcm(f, f, domain=QQ) == monic(f) + + +def test_gcd_numbers_vs_polys(): + assert isinstance(gcd(3, 9), Integer) + assert isinstance(gcd(3*x, 9), Integer) + + assert gcd(3, 9) == 3 + assert gcd(3*x, 9) == 3 + + assert isinstance(gcd(Rational(3, 2), Rational(9, 4)), Rational) + assert isinstance(gcd(Rational(3, 2)*x, Rational(9, 4)), Rational) + + assert gcd(Rational(3, 2), Rational(9, 4)) == Rational(3, 4) + assert gcd(Rational(3, 2)*x, Rational(9, 4)) == 1 + + assert isinstance(gcd(3.0, 9.0), Float) + assert isinstance(gcd(3.0*x, 9.0), Float) + + assert gcd(3.0, 9.0) == 1.0 + assert gcd(3.0*x, 9.0) == 1.0 + + # partial fix of 20597 + assert gcd(Mul(2, 3, evaluate=False), 2) == 2 + + +def test_terms_gcd(): + assert terms_gcd(1) == 1 + assert terms_gcd(1, x) == 1 + + assert terms_gcd(x - 1) == x - 1 + assert terms_gcd(-x - 1) == -x - 1 + + assert terms_gcd(2*x + 3) == 2*x + 3 + assert terms_gcd(6*x + 4) == Mul(2, 3*x + 2, evaluate=False) + + assert terms_gcd(x**3*y + x*y**3) == x*y*(x**2 + y**2) + assert terms_gcd(2*x**3*y + 2*x*y**3) == 2*x*y*(x**2 + y**2) + assert terms_gcd(x**3*y/2 + x*y**3/2) == x*y/2*(x**2 + y**2) + + assert terms_gcd(x**3*y + 2*x*y**3) == x*y*(x**2 + 2*y**2) + assert terms_gcd(2*x**3*y + 4*x*y**3) == 2*x*y*(x**2 + 2*y**2) + assert terms_gcd(2*x**3*y/3 + 4*x*y**3/5) == x*y*Rational(2, 15)*(5*x**2 + 6*y**2) + + assert terms_gcd(2.0*x**3*y + 4.1*x*y**3) == x*y*(2.0*x**2 + 4.1*y**2) + assert _aresame(terms_gcd(2.0*x + 3), 2.0*x + 3) + + assert terms_gcd((3 + 3*x)*(x + x*y), expand=False) == \ + (3*x + 3)*(x*y + x) + assert terms_gcd((3 + 3*x)*(x + x*sin(3 + 3*y)), expand=False, deep=True) == \ + 3*x*(x + 1)*(sin(Mul(3, y + 1, evaluate=False)) + 1) + assert terms_gcd(sin(x + x*y), deep=True) == \ + sin(x*(y + 1)) + + eq = Eq(2*x, 2*y + 2*z*y) + assert terms_gcd(eq) == Eq(2*x, 2*y*(z + 1)) + assert terms_gcd(eq, deep=True) == Eq(2*x, 2*y*(z + 1)) + + raises(TypeError, lambda: terms_gcd(x < 2)) + + +def test_trunc(): + f, g = x**5 + 2*x**4 + 3*x**3 + 4*x**2 + 5*x + 6, x**5 - x**4 + x**2 - x + F, G = Poly(f), Poly(g) + + assert F.trunc(3) == G + assert trunc(f, 3) == g + assert trunc(f, 3, x) == g + assert trunc(f, 3, (x,)) == g + assert trunc(F, 3) == G + assert trunc(f, 3, polys=True) == G + assert trunc(F, 3, polys=False) == g + + f, g = 6*x**5 + 5*x**4 + 4*x**3 + 3*x**2 + 2*x + 1, -x**4 + x**3 - x + 1 + F, G = Poly(f), Poly(g) + + assert F.trunc(3) == G + assert trunc(f, 3) == g + assert trunc(f, 3, x) == g + assert trunc(f, 3, (x,)) == g + assert trunc(F, 3) == G + assert trunc(f, 3, polys=True) == G + assert trunc(F, 3, polys=False) == g + + f = Poly(x**2 + 2*x + 3, modulus=5) + + assert f.trunc(2) == Poly(x**2 + 1, modulus=5) + + +def test_monic(): + f, g = 2*x - 1, x - S.Half + F, G = Poly(f, domain='QQ'), Poly(g) + + assert F.monic() == G + assert monic(f) == g + assert monic(f, x) == g + assert monic(f, (x,)) == g + assert monic(F) == G + assert monic(f, polys=True) == G + assert monic(F, polys=False) == g + + raises(ComputationFailed, lambda: monic(4)) + + assert monic(2*x**2 + 6*x + 4, auto=False) == x**2 + 3*x + 2 + raises(ExactQuotientFailed, lambda: monic(2*x + 6*x + 1, auto=False)) + + assert monic(2.0*x**2 + 6.0*x + 4.0) == 1.0*x**2 + 3.0*x + 2.0 + assert monic(2*x**2 + 3*x + 4, modulus=5) == x**2 - x + 2 + + +def test_content(): + f, F = 4*x + 2, Poly(4*x + 2) + + assert F.content() == 2 + assert content(f) == 2 + + raises(ComputationFailed, lambda: content(4)) + + f = Poly(2*x, modulus=3) + + assert f.content() == 1 + + +def test_primitive(): + f, g = 4*x + 2, 2*x + 1 + F, G = Poly(f), Poly(g) + + assert F.primitive() == (2, G) + assert primitive(f) == (2, g) + assert primitive(f, x) == (2, g) + assert primitive(f, (x,)) == (2, g) + assert primitive(F) == (2, G) + assert primitive(f, polys=True) == (2, G) + assert primitive(F, polys=False) == (2, g) + + raises(ComputationFailed, lambda: primitive(4)) + + f = Poly(2*x, modulus=3) + g = Poly(2.0*x, domain=RR) + + assert f.primitive() == (1, f) + assert g.primitive() == (1.0, g) + + assert primitive(S('-3*x/4 + y + 11/8')) == \ + S('(1/8, -6*x + 8*y + 11)') + + +def test_compose(): + f = x**12 + 20*x**10 + 150*x**8 + 500*x**6 + 625*x**4 - 2*x**3 - 10*x + 9 + g = x**4 - 2*x + 9 + h = x**3 + 5*x + + F, G, H = map(Poly, (f, g, h)) + + assert G.compose(H) == F + assert compose(g, h) == f + assert compose(g, h, x) == f + assert compose(g, h, (x,)) == f + assert compose(G, H) == F + assert compose(g, h, polys=True) == F + assert compose(G, H, polys=False) == f + + assert F.decompose() == [G, H] + assert decompose(f) == [g, h] + assert decompose(f, x) == [g, h] + assert decompose(f, (x,)) == [g, h] + assert decompose(F) == [G, H] + assert decompose(f, polys=True) == [G, H] + assert decompose(F, polys=False) == [g, h] + + raises(ComputationFailed, lambda: compose(4, 2)) + raises(ComputationFailed, lambda: decompose(4)) + + assert compose(x**2 - y**2, x - y, x, y) == x**2 - 2*x*y + assert compose(x**2 - y**2, x - y, y, x) == -y**2 + 2*x*y + + +def test_shift(): + assert Poly(x**2 - 2*x + 1, x).shift(2) == Poly(x**2 + 2*x + 1, x) + + +def test_shift_list(): + assert Poly(x*y, [x,y]).shift_list([1,2]) == Poly((x+1)*(y+2), [x,y]) + + +def test_transform(): + # Also test that 3-way unification is done correctly + assert Poly(x**2 - 2*x + 1, x).transform(Poly(x + 1), Poly(x - 1)) == \ + Poly(4, x) == \ + cancel((x - 1)**2*(x**2 - 2*x + 1).subs(x, (x + 1)/(x - 1))) + + assert Poly(x**2 - x/2 + 1, x).transform(Poly(x + 1), Poly(x - 1)) == \ + Poly(3*x**2/2 + Rational(5, 2), x) == \ + cancel((x - 1)**2*(x**2 - x/2 + 1).subs(x, (x + 1)/(x - 1))) + + assert Poly(x**2 - 2*x + 1, x).transform(Poly(x + S.Half), Poly(x - 1)) == \ + Poly(Rational(9, 4), x) == \ + cancel((x - 1)**2*(x**2 - 2*x + 1).subs(x, (x + S.Half)/(x - 1))) + + assert Poly(x**2 - 2*x + 1, x).transform(Poly(x + 1), Poly(x - S.Half)) == \ + Poly(Rational(9, 4), x) == \ + cancel((x - S.Half)**2*(x**2 - 2*x + 1).subs(x, (x + 1)/(x - S.Half))) + + # Unify ZZ, QQ, and RR + assert Poly(x**2 - 2*x + 1, x).transform(Poly(x + 1.0), Poly(x - S.Half)) == \ + Poly(Rational(9, 4), x, domain='RR') == \ + cancel((x - S.Half)**2*(x**2 - 2*x + 1).subs(x, (x + 1.0)/(x - S.Half))) + + raises(ValueError, lambda: Poly(x*y).transform(Poly(x + 1), Poly(x - 1))) + raises(ValueError, lambda: Poly(x).transform(Poly(y + 1), Poly(x - 1))) + raises(ValueError, lambda: Poly(x).transform(Poly(x + 1), Poly(y - 1))) + raises(ValueError, lambda: Poly(x).transform(Poly(x*y + 1), Poly(x - 1))) + raises(ValueError, lambda: Poly(x).transform(Poly(x + 1), Poly(x*y - 1))) + + +def test_sturm(): + f, F = x, Poly(x, domain='QQ') + g, G = 1, Poly(1, x, domain='QQ') + + assert F.sturm() == [F, G] + assert sturm(f) == [f, g] + assert sturm(f, x) == [f, g] + assert sturm(f, (x,)) == [f, g] + assert sturm(F) == [F, G] + assert sturm(f, polys=True) == [F, G] + assert sturm(F, polys=False) == [f, g] + + raises(ComputationFailed, lambda: sturm(4)) + raises(DomainError, lambda: sturm(f, auto=False)) + + f = Poly(S(1024)/(15625*pi**8)*x**5 + - S(4096)/(625*pi**8)*x**4 + + S(32)/(15625*pi**4)*x**3 + - S(128)/(625*pi**4)*x**2 + + Rational(1, 62500)*x + - Rational(1, 625), x, domain='ZZ(pi)') + + assert sturm(f) == \ + [Poly(x**3 - 100*x**2 + pi**4/64*x - 25*pi**4/16, x, domain='ZZ(pi)'), + Poly(3*x**2 - 200*x + pi**4/64, x, domain='ZZ(pi)'), + Poly((Rational(20000, 9) - pi**4/96)*x + 25*pi**4/18, x, domain='ZZ(pi)'), + Poly((-3686400000000*pi**4 - 11520000*pi**8 - 9*pi**12)/(26214400000000 - 245760000*pi**4 + 576*pi**8), x, domain='ZZ(pi)')] + + +def test_gff(): + f = x**5 + 2*x**4 - x**3 - 2*x**2 + + assert Poly(f).gff_list() == [(Poly(x), 1), (Poly(x + 2), 4)] + assert gff_list(f) == [(x, 1), (x + 2, 4)] + + raises(NotImplementedError, lambda: gff(f)) + + f = x*(x - 1)**3*(x - 2)**2*(x - 4)**2*(x - 5) + + assert Poly(f).gff_list() == [( + Poly(x**2 - 5*x + 4), 1), (Poly(x**2 - 5*x + 4), 2), (Poly(x), 3)] + assert gff_list(f) == [(x**2 - 5*x + 4, 1), (x**2 - 5*x + 4, 2), (x, 3)] + + raises(NotImplementedError, lambda: gff(f)) + + +def test_norm(): + a, b = sqrt(2), sqrt(3) + f = Poly(a*x + b*y, x, y, extension=(a, b)) + assert f.norm() == Poly(4*x**4 - 12*x**2*y**2 + 9*y**4, x, y, domain='QQ') + + +def test_sqf_norm(): + assert sqf_norm(x**2 - 2, extension=sqrt(3)) == \ + ([1], x**2 - 2*sqrt(3)*x + 1, x**4 - 10*x**2 + 1) + assert sqf_norm(x**2 - 3, extension=sqrt(2)) == \ + ([1], x**2 - 2*sqrt(2)*x - 1, x**4 - 10*x**2 + 1) + + assert Poly(x**2 - 2, extension=sqrt(3)).sqf_norm() == \ + ([1], Poly(x**2 - 2*sqrt(3)*x + 1, x, extension=sqrt(3)), + Poly(x**4 - 10*x**2 + 1, x, domain='QQ')) + + assert Poly(x**2 - 3, extension=sqrt(2)).sqf_norm() == \ + ([1], Poly(x**2 - 2*sqrt(2)*x - 1, x, extension=sqrt(2)), + Poly(x**4 - 10*x**2 + 1, x, domain='QQ')) + + +def test_sqf(): + f = x**5 - x**3 - x**2 + 1 + g = x**3 + 2*x**2 + 2*x + 1 + h = x - 1 + + p = x**4 + x**3 - x - 1 + + F, G, H, P = map(Poly, (f, g, h, p)) + + assert F.sqf_part() == P + assert sqf_part(f) == p + assert sqf_part(f, x) == p + assert sqf_part(f, (x,)) == p + assert sqf_part(F) == P + assert sqf_part(f, polys=True) == P + assert sqf_part(F, polys=False) == p + + assert F.sqf_list() == (1, [(G, 1), (H, 2)]) + assert sqf_list(f) == (1, [(g, 1), (h, 2)]) + assert sqf_list(f, x) == (1, [(g, 1), (h, 2)]) + assert sqf_list(f, (x,)) == (1, [(g, 1), (h, 2)]) + assert sqf_list(F) == (1, [(G, 1), (H, 2)]) + assert sqf_list(f, polys=True) == (1, [(G, 1), (H, 2)]) + assert sqf_list(F, polys=False) == (1, [(g, 1), (h, 2)]) + + assert F.sqf_list_include() == [(G, 1), (H, 2)] + + raises(ComputationFailed, lambda: sqf_part(4)) + + assert sqf(1) == 1 + assert sqf_list(1) == (1, []) + + assert sqf((2*x**2 + 2)**7) == 128*(x**2 + 1)**7 + + assert sqf(f) == g*h**2 + assert sqf(f, x) == g*h**2 + assert sqf(f, (x,)) == g*h**2 + + d = x**2 + y**2 + + assert sqf(f/d) == (g*h**2)/d + assert sqf(f/d, x) == (g*h**2)/d + assert sqf(f/d, (x,)) == (g*h**2)/d + + assert sqf(x - 1) == x - 1 + assert sqf(-x - 1) == -x - 1 + + assert sqf(x - 1) == x - 1 + assert sqf(6*x - 10) == Mul(2, 3*x - 5, evaluate=False) + + assert sqf((6*x - 10)/(3*x - 6)) == Rational(2, 3)*((3*x - 5)/(x - 2)) + assert sqf(Poly(x**2 - 2*x + 1)) == (x - 1)**2 + + f = 3 + x - x*(1 + x) + x**2 + + assert sqf(f) == 3 + + f = (x**2 + 2*x + 1)**20000000000 + + assert sqf(f) == (x + 1)**40000000000 + assert sqf_list(f) == (1, [(x + 1, 40000000000)]) + + # https://github.com/sympy/sympy/issues/26497 + assert sqf(expand(((y - 2)**2 * (y + 2) * (x + 1)))) == \ + (y - 2)**2 * expand((y + 2) * (x + 1)) + assert sqf(expand(((y - 2)**2 * (y + 2) * (z + 1)))) == \ + (y - 2)**2 * expand((y + 2) * (z + 1)) + assert sqf(expand(((y - I)**2 * (y + I) * (x + 1)))) == \ + (y - I)**2 * expand((y + I) * (x + 1)) + assert sqf(expand(((y - I)**2 * (y + I) * (z + 1)))) == \ + (y - I)**2 * expand((y + I) * (z + 1)) + + # Check that factors are combined and sorted. + p = (x - 2)**2*(x - 1)*(x + y)**2*(y - 2)**2*(y - 1) + assert Poly(p).sqf_list() == (1, [ + (Poly(x*y - x - y + 1), 1), + (Poly(x**2*y - 2*x**2 + x*y**2 - 4*x*y + 4*x - 2*y**2 + 4*y), 2) + ]) + + +def test_factor(): + f = x**5 - x**3 - x**2 + 1 + + u = x + 1 + v = x - 1 + w = x**2 + x + 1 + + F, U, V, W = map(Poly, (f, u, v, w)) + + assert F.factor_list() == (1, [(U, 1), (V, 2), (W, 1)]) + assert factor_list(f) == (1, [(u, 1), (v, 2), (w, 1)]) + assert factor_list(f, x) == (1, [(u, 1), (v, 2), (w, 1)]) + assert factor_list(f, (x,)) == (1, [(u, 1), (v, 2), (w, 1)]) + assert factor_list(F) == (1, [(U, 1), (V, 2), (W, 1)]) + assert factor_list(f, polys=True) == (1, [(U, 1), (V, 2), (W, 1)]) + assert factor_list(F, polys=False) == (1, [(u, 1), (v, 2), (w, 1)]) + + assert F.factor_list_include() == [(U, 1), (V, 2), (W, 1)] + + assert factor_list(1) == (1, []) + assert factor_list(6) == (6, []) + assert factor_list(sqrt(3), x) == (sqrt(3), []) + assert factor_list((-1)**x, x) == (1, [(-1, x)]) + assert factor_list((2*x)**y, x) == (1, [(2, y), (x, y)]) + assert factor_list(sqrt(x*y), x) == (1, [(x*y, S.Half)]) + + assert factor(6) == 6 and factor(6).is_Integer + + assert factor_list(3*x) == (3, [(x, 1)]) + assert factor_list(3*x**2) == (3, [(x, 2)]) + + assert factor(3*x) == 3*x + assert factor(3*x**2) == 3*x**2 + + assert factor((2*x**2 + 2)**7) == 128*(x**2 + 1)**7 + + assert factor(f) == u*v**2*w + assert factor(f, x) == u*v**2*w + assert factor(f, (x,)) == u*v**2*w + + g, p, q, r = x**2 - y**2, x - y, x + y, x**2 + 1 + + assert factor(f/g) == (u*v**2*w)/(p*q) + assert factor(f/g, x) == (u*v**2*w)/(p*q) + assert factor(f/g, (x,)) == (u*v**2*w)/(p*q) + + p = Symbol('p', positive=True) + i = Symbol('i', integer=True) + r = Symbol('r', real=True) + + assert factor(sqrt(x*y)).is_Pow is True + + assert factor(sqrt(3*x**2 - 3)) == sqrt(3)*sqrt((x - 1)*(x + 1)) + assert factor(sqrt(3*x**2 + 3)) == sqrt(3)*sqrt(x**2 + 1) + + assert factor((y*x**2 - y)**i) == y**i*(x - 1)**i*(x + 1)**i + assert factor((y*x**2 + y)**i) == y**i*(x**2 + 1)**i + + assert factor((y*x**2 - y)**t) == (y*(x - 1)*(x + 1))**t + assert factor((y*x**2 + y)**t) == (y*(x**2 + 1))**t + + f = sqrt(expand((r**2 + 1)*(p + 1)*(p - 1)*(p - 2)**3)) + g = sqrt((p - 2)**3*(p - 1))*sqrt(p + 1)*sqrt(r**2 + 1) + + assert factor(f) == g + assert factor(g) == g + + g = (x - 1)**5*(r**2 + 1) + f = sqrt(expand(g)) + + assert factor(f) == sqrt(g) + + f = Poly(sin(1)*x + 1, x, domain=EX) + + assert f.factor_list() == (1, [(f, 1)]) + + f = x**4 + 1 + + assert factor(f) == f + assert factor(f, extension=I) == (x**2 - I)*(x**2 + I) + assert factor(f, gaussian=True) == (x**2 - I)*(x**2 + I) + assert factor( + f, extension=sqrt(2)) == (x**2 + sqrt(2)*x + 1)*(x**2 - sqrt(2)*x + 1) + + assert factor(x**2 + 4*I*x - 4) == (x + 2*I)**2 + + f = x**2 + 2*I*x - 4 + + assert factor(f) == f + + f = 8192*x**2 + x*(22656 + 175232*I) - 921416 + 242313*I + f_zzi = I*(x*(64 - 64*I) + 773 + 596*I)**2 + f_qqi = 8192*(x + S(177)/128 + 1369*I/128)**2 + + assert factor(f) == f_zzi + assert factor(f, domain=ZZ_I) == f_zzi + assert factor(f, domain=QQ_I) == f_qqi + + f = x**2 + 2*sqrt(2)*x + 2 + + assert factor(f, extension=sqrt(2)) == (x + sqrt(2))**2 + assert factor(f**3, extension=sqrt(2)) == (x + sqrt(2))**6 + + assert factor(x**2 - 2*y**2, extension=sqrt(2)) == \ + (x + sqrt(2)*y)*(x - sqrt(2)*y) + assert factor(2*x**2 - 4*y**2, extension=sqrt(2)) == \ + 2*((x + sqrt(2)*y)*(x - sqrt(2)*y)) + + assert factor(x - 1) == x - 1 + assert factor(-x - 1) == -x - 1 + + assert factor(x - 1) == x - 1 + + assert factor(6*x - 10) == Mul(2, 3*x - 5, evaluate=False) + + assert factor(x**11 + x + 1, modulus=65537, symmetric=True) == \ + (x**2 + x + 1)*(x**9 - x**8 + x**6 - x**5 + x**3 - x** 2 + 1) + assert factor(x**11 + x + 1, modulus=65537, symmetric=False) == \ + (x**2 + x + 1)*(x**9 + 65536*x**8 + x**6 + 65536*x**5 + + x**3 + 65536*x** 2 + 1) + + f = x/pi + x*sin(x)/pi + g = y/(pi**2 + 2*pi + 1) + y*sin(x)/(pi**2 + 2*pi + 1) + + assert factor(f) == x*(sin(x) + 1)/pi + assert factor(g) == y*(sin(x) + 1)/(pi + 1)**2 + + assert factor(Eq( + x**2 + 2*x + 1, x**3 + 1)) == Eq((x + 1)**2, (x + 1)*(x**2 - x + 1)) + + f = (x**2 - 1)/(x**2 + 4*x + 4) + + assert factor(f) == (x + 1)*(x - 1)/(x + 2)**2 + assert factor(f, x) == (x + 1)*(x - 1)/(x + 2)**2 + + f = 3 + x - x*(1 + x) + x**2 + + assert factor(f) == 3 + assert factor(f, x) == 3 + + assert factor(1/(x**2 + 2*x + 1/x) - 1) == -((1 - x + 2*x**2 + + x**3)/(1 + 2*x**2 + x**3)) + + assert factor(f, expand=False) == f + raises(PolynomialError, lambda: factor(f, x, expand=False)) + + raises(FlagError, lambda: factor(x**2 - 1, polys=True)) + + assert factor([x, Eq(x**2 - y**2, Tuple(x**2 - z**2, 1/x + 1/y))]) == \ + [x, Eq((x - y)*(x + y), Tuple((x - z)*(x + z), (x + y)/x/y))] + + assert not isinstance( + Poly(x**3 + x + 1).factor_list()[1][0][0], PurePoly) is True + assert isinstance( + PurePoly(x**3 + x + 1).factor_list()[1][0][0], PurePoly) is True + + assert factor(sqrt(-x)) == sqrt(-x) + + # issue 5917 + e = (-2*x*(-x + 1)*(x - 1)*(-x*(-x + 1)*(x - 1) - x*(x - 1)**2)*(x**2*(x - + 1) - x*(x - 1) - x) - (-2*x**2*(x - 1)**2 - x*(-x + 1)*(-x*(-x + 1) + + x*(x - 1)))*(x**2*(x - 1)**4 - x*(-x*(-x + 1)*(x - 1) - x*(x - 1)**2))) + assert factor(e) == 0 + + # deep option + assert factor(sin(x**2 + x) + x, deep=True) == sin(x*(x + 1)) + x + assert factor(sin(x**2 + x)*x, deep=True) == sin(x*(x + 1))*x + + assert factor(sqrt(x**2)) == sqrt(x**2) + + # issue 13149 + assert factor(expand((0.5*x+1)*(0.5*y+1))) == Mul(1.0, 0.5*x + 1.0, + 0.5*y + 1.0, evaluate = False) + assert factor(expand((0.5*x+0.5)**2)) == 0.25*(1.0*x + 1.0)**2 + + eq = x**2*y**2 + 11*x**2*y + 30*x**2 + 7*x*y**2 + 77*x*y + 210*x + 12*y**2 + 132*y + 360 + assert factor(eq, x) == (x + 3)*(x + 4)*(y**2 + 11*y + 30) + assert factor(eq, x, deep=True) == (x + 3)*(x + 4)*(y**2 + 11*y + 30) + assert factor(eq, y, deep=True) == (y + 5)*(y + 6)*(x**2 + 7*x + 12) + + # fraction option + f = 5*x + 3*exp(2 - 7*x) + assert factor(f, deep=True) == factor(f, deep=True, fraction=True) + assert factor(f, deep=True, fraction=False) == 5*x + 3*exp(2)*exp(-7*x) + + assert factor_list(x**3 - x*y**2, t, w, x) == ( + 1, [(x, 1), (x - y, 1), (x + y, 1)]) + assert factor_list((x+1)*(x**6-1)) == ( + 1, [(x - 1, 1), (x + 1, 2), (x**2 - x + 1, 1), (x**2 + x + 1, 1)]) + + # https://github.com/sympy/sympy/issues/24952 + s2, s2p, s2n = sqrt(2), 1 + sqrt(2), 1 - sqrt(2) + pip, pin = 1 + pi, 1 - pi + assert factor_list(s2p*s2n) == (-1, [(-s2n, 1), (s2p, 1)]) + assert factor_list(pip*pin) == (-1, [(-pin, 1), (pip, 1)]) + # Not sure about this one. Maybe coeff should be 1 or -1? + assert factor_list(s2*s2n) == (-s2, [(-s2n, 1)]) + assert factor_list(pi*pin) == (-1, [(-pin, 1), (pi, 1)]) + assert factor_list(s2p*s2n, x) == (s2p*s2n, []) + assert factor_list(pip*pin, x) == (pip*pin, []) + assert factor_list(s2*s2n, x) == (s2*s2n, []) + assert factor_list(pi*pin, x) == (pi*pin, []) + assert factor_list((x - sqrt(2)*pi)*(x + sqrt(2)*pi), x) == ( + 1, [(x - sqrt(2)*pi, 1), (x + sqrt(2)*pi, 1)]) + + # https://github.com/sympy/sympy/issues/26497 + p = ((y - I)**2 * (y + I) * (x + 1)) + assert factor(expand(p)) == p + + p = ((x - I)**2 * (x + I) * (y + 1)) + assert factor(expand(p)) == p + + p = (y + 1)**2*(y + sqrt(2))**2*(x**2 + x + 2 + 3*sqrt(2))**2 + assert factor(expand(p), extension=True) == p + + e = ( + -x**2*y**4/(y**2 + 1) + 2*I*x**2*y**3/(y**2 + 1) + 2*I*x**2*y/(y**2 + 1) + + x**2/(y**2 + 1) - 2*x*y**4/(y**2 + 1) + 4*I*x*y**3/(y**2 + 1) + + 4*I*x*y/(y**2 + 1) + 2*x/(y**2 + 1) - y**4 - y**4/(y**2 + 1) + 2*I*y**3 + + 2*I*y**3/(y**2 + 1) + 2*I*y + 2*I*y/(y**2 + 1) + 1 + 1/(y**2 + 1) + ) + assert factor(e) == -(y - I)**3*(y + I)*(x**2 + 2*x + y**2 + 2)/(y**2 + 1) + + # issue 27506 + e = (I*t*x*y - 3*I*t - I*x*y*z - 6*x*y + 3*I*z + 18) + assert factor(e) == -I*(x*y - 3)*(-t + z - 6*I) + + e = (8*x**2*z**2 - 32*x**2*z*t + 24*x**2*t**2 - 4*I*x*y*z**2 + 16*I*x*y*z*t - + 12*I*x*y*t**2 + z**4 - 8*z**3*t + 22*z**2*t**2 - 24*z*t**3 + 9*t**4) + assert factor(e) == (-3*t + z)*(-t + z)*(3*t**2 - 4*t*z + 8*x**2 - 4*I*x*y + z**2) + + +def test_factor_large(): + f = (x**2 + 4*x + 4)**10000000*(x**2 + 1)*(x**2 + 2*x + 1)**1234567 + g = ((x**2 + 2*x + 1)**3000*y**2 + (x**2 + 2*x + 1)**3000*2*y + ( + x**2 + 2*x + 1)**3000) + + assert factor(f) == (x + 2)**20000000*(x**2 + 1)*(x + 1)**2469134 + assert factor(g) == (x + 1)**6000*(y + 1)**2 + + assert factor_list( + f) == (1, [(x + 1, 2469134), (x + 2, 20000000), (x**2 + 1, 1)]) + assert factor_list(g) == (1, [(y + 1, 2), (x + 1, 6000)]) + + f = (x**2 - y**2)**200000*(x**7 + 1) + g = (x**2 + y**2)**200000*(x**7 + 1) + + assert factor(f) == \ + (x + 1)*(x - y)**200000*(x + y)**200000*(x**6 - x**5 + + x**4 - x**3 + x**2 - x + 1) + assert factor(g, gaussian=True) == \ + (x + 1)*(x - I*y)**200000*(x + I*y)**200000*(x**6 - x**5 + + x**4 - x**3 + x**2 - x + 1) + + assert factor_list(f) == \ + (1, [(x + 1, 1), (x - y, 200000), (x + y, 200000), (x**6 - + x**5 + x**4 - x**3 + x**2 - x + 1, 1)]) + assert factor_list(g, gaussian=True) == \ + (1, [(x + 1, 1), (x - I*y, 200000), (x + I*y, 200000), ( + x**6 - x**5 + x**4 - x**3 + x**2 - x + 1, 1)]) + + +def test_factor_noeval(): + assert factor(6*x - 10) == Mul(2, 3*x - 5, evaluate=False) + assert factor((6*x - 10)/(3*x - 6)) == Mul(Rational(2, 3), 3*x - 5, 1/(x - 2)) + + +def test_intervals(): + assert intervals(0) == [] + assert intervals(1) == [] + + assert intervals(x, sqf=True) == [(0, 0)] + assert intervals(x) == [((0, 0), 1)] + + assert intervals(x**128) == [((0, 0), 128)] + assert intervals([x**2, x**4]) == [((0, 0), {0: 2, 1: 4})] + + f = Poly((x*Rational(2, 5) - Rational(17, 3))*(4*x + Rational(1, 257))) + + assert f.intervals(sqf=True) == [(-1, 0), (14, 15)] + assert f.intervals() == [((-1, 0), 1), ((14, 15), 1)] + + assert f.intervals(fast=True, sqf=True) == [(-1, 0), (14, 15)] + assert f.intervals(fast=True) == [((-1, 0), 1), ((14, 15), 1)] + + assert f.intervals(eps=Rational(1, 10)) == f.intervals(eps=0.1) == \ + [((Rational(-1, 258), 0), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + assert f.intervals(eps=Rational(1, 100)) == f.intervals(eps=0.01) == \ + [((Rational(-1, 258), 0), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + assert f.intervals(eps=Rational(1, 1000)) == f.intervals(eps=0.001) == \ + [((Rational(-1, 1002), 0), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + assert f.intervals(eps=Rational(1, 10000)) == f.intervals(eps=0.0001) == \ + [((Rational(-1, 1028), Rational(-1, 1028)), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + + f = (x*Rational(2, 5) - Rational(17, 3))*(4*x + Rational(1, 257)) + + assert intervals(f, sqf=True) == [(-1, 0), (14, 15)] + assert intervals(f) == [((-1, 0), 1), ((14, 15), 1)] + + assert intervals(f, eps=Rational(1, 10)) == intervals(f, eps=0.1) == \ + [((Rational(-1, 258), 0), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + assert intervals(f, eps=Rational(1, 100)) == intervals(f, eps=0.01) == \ + [((Rational(-1, 258), 0), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + assert intervals(f, eps=Rational(1, 1000)) == intervals(f, eps=0.001) == \ + [((Rational(-1, 1002), 0), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + assert intervals(f, eps=Rational(1, 10000)) == intervals(f, eps=0.0001) == \ + [((Rational(-1, 1028), Rational(-1, 1028)), 1), ((Rational(85, 6), Rational(85, 6)), 1)] + + f = Poly((x**2 - 2)*(x**2 - 3)**7*(x + 1)*(7*x + 3)**3) + + assert f.intervals() == \ + [((-2, Rational(-3, 2)), 7), ((Rational(-3, 2), -1), 1), + ((-1, -1), 1), ((-1, 0), 3), + ((1, Rational(3, 2)), 1), ((Rational(3, 2), 2), 7)] + + assert intervals([x**5 - 200, x**5 - 201]) == \ + [((Rational(75, 26), Rational(101, 35)), {0: 1}), ((Rational(309, 107), Rational(26, 9)), {1: 1})] + + assert intervals([x**5 - 200, x**5 - 201], fast=True) == \ + [((Rational(75, 26), Rational(101, 35)), {0: 1}), ((Rational(309, 107), Rational(26, 9)), {1: 1})] + + assert intervals([x**2 - 200, x**2 - 201]) == \ + [((Rational(-71, 5), Rational(-85, 6)), {1: 1}), ((Rational(-85, 6), -14), {0: 1}), + ((14, Rational(85, 6)), {0: 1}), ((Rational(85, 6), Rational(71, 5)), {1: 1})] + + assert intervals([x + 1, x + 2, x - 1, x + 1, 1, x - 1, x - 1, (x - 2)**2]) == \ + [((-2, -2), {1: 1}), ((-1, -1), {0: 1, 3: 1}), ((1, 1), {2: + 1, 5: 1, 6: 1}), ((2, 2), {7: 2})] + + f, g, h = x**2 - 2, x**4 - 4*x**2 + 4, x - 1 + + assert intervals(f, inf=Rational(7, 4), sqf=True) == [] + assert intervals(f, inf=Rational(7, 5), sqf=True) == [(Rational(7, 5), Rational(3, 2))] + assert intervals(f, sup=Rational(7, 4), sqf=True) == [(-2, -1), (1, Rational(3, 2))] + assert intervals(f, sup=Rational(7, 5), sqf=True) == [(-2, -1)] + + assert intervals(g, inf=Rational(7, 4)) == [] + assert intervals(g, inf=Rational(7, 5)) == [((Rational(7, 5), Rational(3, 2)), 2)] + assert intervals(g, sup=Rational(7, 4)) == [((-2, -1), 2), ((1, Rational(3, 2)), 2)] + assert intervals(g, sup=Rational(7, 5)) == [((-2, -1), 2)] + + assert intervals([g, h], inf=Rational(7, 4)) == [] + assert intervals([g, h], inf=Rational(7, 5)) == [((Rational(7, 5), Rational(3, 2)), {0: 2})] + assert intervals([g, h], sup=S( + 7)/4) == [((-2, -1), {0: 2}), ((1, 1), {1: 1}), ((1, Rational(3, 2)), {0: 2})] + assert intervals( + [g, h], sup=Rational(7, 5)) == [((-2, -1), {0: 2}), ((1, 1), {1: 1})] + + assert intervals([x + 2, x**2 - 2]) == \ + [((-2, -2), {0: 1}), ((-2, -1), {1: 1}), ((1, 2), {1: 1})] + assert intervals([x + 2, x**2 - 2], strict=True) == \ + [((-2, -2), {0: 1}), ((Rational(-3, 2), -1), {1: 1}), ((1, 2), {1: 1})] + + f = 7*z**4 - 19*z**3 + 20*z**2 + 17*z + 20 + + assert intervals(f) == [] + + real_part, complex_part = intervals(f, all=True, sqf=True) + + assert real_part == [] + assert all(re(a) < re(r) < re(b) and im( + a) < im(r) < im(b) for (a, b), r in zip(complex_part, nroots(f))) + + assert complex_part == [(Rational(-40, 7) - I*40/7, 0), + (Rational(-40, 7), I*40/7), + (I*Rational(-40, 7), Rational(40, 7)), + (0, Rational(40, 7) + I*40/7)] + + real_part, complex_part = intervals(f, all=True, sqf=True, eps=Rational(1, 10)) + + assert real_part == [] + assert all(re(a) < re(r) < re(b) and im( + a) < im(r) < im(b) for (a, b), r in zip(complex_part, nroots(f))) + + raises(ValueError, lambda: intervals(x**2 - 2, eps=10**-100000)) + raises(ValueError, lambda: Poly(x**2 - 2).intervals(eps=10**-100000)) + raises( + ValueError, lambda: intervals([x**2 - 2, x**2 - 3], eps=10**-100000)) + + +def test_refine_root(): + f = Poly(x**2 - 2) + + assert f.refine_root(1, 2, steps=0) == (1, 2) + assert f.refine_root(-2, -1, steps=0) == (-2, -1) + + assert f.refine_root(1, 2, steps=None) == (1, Rational(3, 2)) + assert f.refine_root(-2, -1, steps=None) == (Rational(-3, 2), -1) + + assert f.refine_root(1, 2, steps=1) == (1, Rational(3, 2)) + assert f.refine_root(-2, -1, steps=1) == (Rational(-3, 2), -1) + + assert f.refine_root(1, 2, steps=1, fast=True) == (1, Rational(3, 2)) + assert f.refine_root(-2, -1, steps=1, fast=True) == (Rational(-3, 2), -1) + + assert f.refine_root(1, 2, eps=Rational(1, 100)) == (Rational(24, 17), Rational(17, 12)) + assert f.refine_root(1, 2, eps=1e-2) == (Rational(24, 17), Rational(17, 12)) + + raises(PolynomialError, lambda: (f**2).refine_root(1, 2, check_sqf=True)) + + raises(RefinementFailed, lambda: (f**2).refine_root(1, 2)) + raises(RefinementFailed, lambda: (f**2).refine_root(2, 3)) + + f = x**2 - 2 + + assert refine_root(f, 1, 2, steps=1) == (1, Rational(3, 2)) + assert refine_root(f, -2, -1, steps=1) == (Rational(-3, 2), -1) + + assert refine_root(f, 1, 2, steps=1, fast=True) == (1, Rational(3, 2)) + assert refine_root(f, -2, -1, steps=1, fast=True) == (Rational(-3, 2), -1) + + assert refine_root(f, 1, 2, eps=Rational(1, 100)) == (Rational(24, 17), Rational(17, 12)) + assert refine_root(f, 1, 2, eps=1e-2) == (Rational(24, 17), Rational(17, 12)) + + raises(PolynomialError, lambda: refine_root(1, 7, 8, eps=Rational(1, 100))) + + raises(ValueError, lambda: Poly(f).refine_root(1, 2, eps=10**-100000)) + raises(ValueError, lambda: refine_root(f, 1, 2, eps=10**-100000)) + + +def test_count_roots(): + assert count_roots(x**2 - 2) == 2 + + assert count_roots(x**2 - 2, inf=-oo) == 2 + assert count_roots(x**2 - 2, sup=+oo) == 2 + assert count_roots(x**2 - 2, inf=-oo, sup=+oo) == 2 + + assert count_roots(x**2 - 2, inf=-2) == 2 + assert count_roots(x**2 - 2, inf=-1) == 1 + + assert count_roots(x**2 - 2, sup=1) == 1 + assert count_roots(x**2 - 2, sup=2) == 2 + + assert count_roots(x**2 - 2, inf=-1, sup=1) == 0 + assert count_roots(x**2 - 2, inf=-2, sup=2) == 2 + + assert count_roots(x**2 - 2, inf=-1, sup=1) == 0 + assert count_roots(x**2 - 2, inf=-2, sup=2) == 2 + + assert count_roots(x**2 + 2) == 0 + assert count_roots(x**2 + 2, inf=-2*I) == 2 + assert count_roots(x**2 + 2, sup=+2*I) == 2 + assert count_roots(x**2 + 2, inf=-2*I, sup=+2*I) == 2 + + assert count_roots(x**2 + 2, inf=0) == 0 + assert count_roots(x**2 + 2, sup=0) == 0 + + assert count_roots(x**2 + 2, inf=-I) == 1 + assert count_roots(x**2 + 2, sup=+I) == 1 + + assert count_roots(x**2 + 2, inf=+I/2, sup=+I) == 0 + assert count_roots(x**2 + 2, inf=-I, sup=-I/2) == 0 + + raises(PolynomialError, lambda: count_roots(1)) + + +def test_count_roots_extension(): + + p1 = Poly(sqrt(2)*x**2 - 2, x, extension=True) + assert p1.count_roots() == 2 + assert p1.count_roots(inf=0) == 1 + assert p1.count_roots(sup=0) == 1 + + p2 = Poly(x**2 + sqrt(2), x, extension=True) + assert p2.count_roots() == 0 + + p3 = Poly(x**2 + 2*sqrt(2)*x + 1, x, extension=True) + assert p3.count_roots() == 2 + assert p3.count_roots(inf=-10, sup=10) == 2 + assert p3.count_roots(inf=-10, sup=0) == 2 + assert p3.count_roots(inf=-10, sup=-3) == 0 + assert p3.count_roots(inf=-3, sup=-2) == 1 + assert p3.count_roots(inf=-1, sup=0) == 1 + + +def test_Poly_root(): + f = Poly(2*x**3 - 7*x**2 + 4*x + 4) + + assert f.root(0) == Rational(-1, 2) + assert f.root(1) == 2 + assert f.root(2) == 2 + raises(IndexError, lambda: f.root(3)) + + assert Poly(x**5 + x + 1).root(0) == rootof(x**3 - x**2 + 1, 0) + + +def test_real_roots(): + + assert real_roots(x) == [0] + assert real_roots(x, multiple=False) == [(0, 1)] + + assert real_roots(x**3) == [0, 0, 0] + assert real_roots(x**3, multiple=False) == [(0, 3)] + + assert real_roots(x*(x**3 + x + 3)) == [rootof(x**3 + x + 3, 0), 0] + assert real_roots(x*(x**3 + x + 3), multiple=False) == [(rootof( + x**3 + x + 3, 0), 1), (0, 1)] + + assert real_roots( + x**3*(x**3 + x + 3)) == [rootof(x**3 + x + 3, 0), 0, 0, 0] + assert real_roots(x**3*(x**3 + x + 3), multiple=False) == [(rootof( + x**3 + x + 3, 0), 1), (0, 3)] + + assert real_roots(x**2 - 2, radicals=False) == [ + rootof(x**2 - 2, 0, radicals=False), + rootof(x**2 - 2, 1, radicals=False), + ] + + f = 2*x**3 - 7*x**2 + 4*x + 4 + g = x**3 + x + 1 + + assert Poly(f).real_roots() == [Rational(-1, 2), 2, 2] + assert Poly(g).real_roots() == [rootof(g, 0)] + + # testing extension + f = x**2 - sqrt(2) + roots = [-2**(S(1)/4), 2**(S(1)/4)] + raises(NotImplementedError, lambda: real_roots(f)) + raises(NotImplementedError, lambda: real_roots(Poly(f, x))) + assert real_roots(f, extension=True) == roots + assert real_roots(Poly(f, extension=True)) == roots + assert real_roots(Poly(f), extension=True) == roots + + +def test_all_roots(): + + f = 2*x**3 - 7*x**2 + 4*x + 4 + froots = [Rational(-1, 2), 2, 2] + assert all_roots(f) == Poly(f).all_roots() == froots + + g = x**3 + x + 1 + groots = [rootof(g, 0), rootof(g, 1), rootof(g, 2)] + assert all_roots(g) == Poly(g).all_roots() == groots + + assert all_roots(x**2 - 2) == [-sqrt(2), sqrt(2)] + assert all_roots(x**2 - 2, multiple=False) == [(-sqrt(2), 1), (sqrt(2), 1)] + assert all_roots(x**2 - 2, radicals=False) == [ + rootof(x**2 - 2, 0, radicals=False), + rootof(x**2 - 2, 1, radicals=False), + ] + + p = x**5 - x - 1 + assert all_roots(p) == [ + rootof(p, 0), rootof(p, 1), rootof(p, 2), rootof(p, 3), rootof(p, 4) + ] + + # testing extension + f = x**2 + sqrt(2) + roots = [-2**(S(1)/4)*I, 2**(S(1)/4)*I] + raises(NotImplementedError, lambda: all_roots(f)) + raises(NotImplementedError, lambda : all_roots(Poly(f, x))) + assert all_roots(f, extension=True) == roots + assert all_roots(Poly(f, extension=True)) == roots + assert all_roots(Poly(f), extension=True) == roots + + +def test_nroots(): + assert Poly(0, x).nroots() == [] + assert Poly(1, x).nroots() == [] + + assert Poly(x**2 - 1, x).nroots() == [-1.0, 1.0] + assert Poly(x**2 + 1, x).nroots() == [-1.0*I, 1.0*I] + + roots = Poly(x**2 - 1, x).nroots() + assert roots == [-1.0, 1.0] + + roots = Poly(x**2 + 1, x).nroots() + assert roots == [-1.0*I, 1.0*I] + + roots = Poly(x**2/3 - Rational(1, 3), x).nroots() + assert roots == [-1.0, 1.0] + + roots = Poly(x**2/3 + Rational(1, 3), x).nroots() + assert roots == [-1.0*I, 1.0*I] + + assert Poly(x**2 + 2*I, x).nroots() == [-1.0 + 1.0*I, 1.0 - 1.0*I] + assert Poly( + x**2 + 2*I, x, extension=I).nroots() == [-1.0 + 1.0*I, 1.0 - 1.0*I] + + assert Poly(0.2*x + 0.1).nroots() == [-0.5] + + roots = nroots(x**5 + x + 1, n=5) + eps = Float("1e-5") + + assert re(roots[0]).epsilon_eq(-0.75487, eps) is S.true + assert im(roots[0]) == 0 + assert re(roots[1]) == Float(-0.5, 5) + assert im(roots[1]).epsilon_eq(-0.86602, eps) is S.true + assert re(roots[2]) == Float(-0.5, 5) + assert im(roots[2]).epsilon_eq(+0.86602, eps) is S.true + assert re(roots[3]).epsilon_eq(+0.87743, eps) is S.true + assert im(roots[3]).epsilon_eq(-0.74486, eps) is S.true + assert re(roots[4]).epsilon_eq(+0.87743, eps) is S.true + assert im(roots[4]).epsilon_eq(+0.74486, eps) is S.true + + eps = Float("1e-6") + + assert re(roots[0]).epsilon_eq(-0.75487, eps) is S.false + assert im(roots[0]) == 0 + assert re(roots[1]) == Float(-0.5, 5) + assert im(roots[1]).epsilon_eq(-0.86602, eps) is S.false + assert re(roots[2]) == Float(-0.5, 5) + assert im(roots[2]).epsilon_eq(+0.86602, eps) is S.false + assert re(roots[3]).epsilon_eq(+0.87743, eps) is S.false + assert im(roots[3]).epsilon_eq(-0.74486, eps) is S.false + assert re(roots[4]).epsilon_eq(+0.87743, eps) is S.false + assert im(roots[4]).epsilon_eq(+0.74486, eps) is S.false + + raises(DomainError, lambda: Poly(x + y, x).nroots()) + raises(MultivariatePolynomialError, lambda: Poly(x + y).nroots()) + + assert nroots(x**2 - 1) == [-1.0, 1.0] + + roots = nroots(x**2 - 1) + assert roots == [-1.0, 1.0] + + assert nroots(x + I) == [-1.0*I] + assert nroots(x + 2*I) == [-2.0*I] + + raises(PolynomialError, lambda: nroots(0)) + + # issue 8296 + f = Poly(x**4 - 1) + assert f.nroots(2) == [w.n(2) for w in f.all_roots()] + + assert str(Poly(x**16 + 32*x**14 + 508*x**12 + 5440*x**10 + + 39510*x**8 + 204320*x**6 + 755548*x**4 + 1434496*x**2 + + 877969).nroots(2)) == ('[-1.7 - 1.9*I, -1.7 + 1.9*I, -1.7 ' + '- 2.5*I, -1.7 + 2.5*I, -1.0*I, 1.0*I, -1.7*I, 1.7*I, -2.8*I, ' + '2.8*I, -3.4*I, 3.4*I, 1.7 - 1.9*I, 1.7 + 1.9*I, 1.7 - 2.5*I, ' + '1.7 + 2.5*I]') + assert str(Poly(1e-15*x**2 -1).nroots()) == ('[-31622776.6016838, 31622776.6016838]') + + # https://github.com/sympy/sympy/issues/23861 + + i = Float('3.000000000000000000000000000000000000000000000000001') + [r] = nroots(x + I*i, n=300) + assert abs(r + I*i) < 1e-300 + + +def test_ground_roots(): + f = x**6 - 4*x**4 + 4*x**3 - x**2 + + assert Poly(f).ground_roots() == {S.One: 2, S.Zero: 2} + assert ground_roots(f) == {S.One: 2, S.Zero: 2} + + +def test_nth_power_roots_poly(): + f = x**4 - x**2 + 1 + + f_2 = (x**2 - x + 1)**2 + f_3 = (x**2 + 1)**2 + f_4 = (x**2 + x + 1)**2 + f_12 = (x - 1)**4 + + assert nth_power_roots_poly(f, 1) == f + + raises(ValueError, lambda: nth_power_roots_poly(f, 0)) + raises(ValueError, lambda: nth_power_roots_poly(f, x)) + + assert factor(nth_power_roots_poly(f, 2)) == f_2 + assert factor(nth_power_roots_poly(f, 3)) == f_3 + assert factor(nth_power_roots_poly(f, 4)) == f_4 + assert factor(nth_power_roots_poly(f, 12)) == f_12 + + raises(MultivariatePolynomialError, lambda: nth_power_roots_poly( + x + y, 2, x, y)) + +def test_which_real_roots(): + f = Poly(x**4 - 1) + + assert f.which_real_roots([1, -1]) == [1, -1] + assert f.which_real_roots([1, -1, 2, 4]) == [1, -1] + assert f.which_real_roots([1, -1, -1, 1, 2, 5]) == [1, -1] + assert f.which_real_roots([10, 8, 7, -1, 1]) == [-1, 1] + + # no real roots + # (technically its still a superset) + f = Poly(x**2 + 1) + assert f.which_real_roots([5, 10]) == [] + + # not square free + f = Poly((x-1)**2) + assert f.which_real_roots([1, 1, -1, 2]) == [1] + + # candidates not superset + f = Poly(x**2 - 1) + assert f.which_real_roots([0, 2]) == [0, 2] + +def test_which_all_roots(): + f = Poly(x**4 - 1) + + assert f.which_all_roots([1, -1, I, -I]) == [1, -1, I, -I] + assert f.which_all_roots([I, I, -I, 1, -1]) == [I, -I, 1, -1] + + f = Poly(x**2 + 1) + assert f.which_all_roots([I, -I, I/2]) == [I, -I] + + # not square free + f = Poly((x-I)**2) + assert f.which_all_roots([I, I, 1, -1, 0]) == [I] + + # candidates not superset + f = Poly(x**2 + 1) + assert f.which_all_roots([I/2, -I/2]) == [I/2, -I/2] + +def test_same_root(): + f = Poly(x**4 + x**3 + x**2 + x + 1) + eq = f.same_root + r0 = exp(2 * I * pi / 5) + assert [i for i, r in enumerate(f.all_roots()) if eq(r, r0)] == [3] + + raises(PolynomialError, + lambda: Poly(x + 1, domain=QQ).same_root(0, 0)) + raises(DomainError, + lambda: Poly(x**2 + 1, domain=FF(7)).same_root(0, 0)) + raises(DomainError, + lambda: Poly(x ** 2 + 1, domain=ZZ_I).same_root(0, 0)) + raises(DomainError, + lambda: Poly(y * x**2 + 1, domain=ZZ[y]).same_root(0, 0)) + raises(MultivariatePolynomialError, + lambda: Poly(x * y + 1, domain=ZZ).same_root(0, 0)) + + +def test_torational_factor_list(): + p = expand(((x**2-1)*(x-2)).subs({x:x*(1 + sqrt(2))})) + assert _torational_factor_list(p, x) == (-2, [ + (-x*(1 + sqrt(2))/2 + 1, 1), + (-x*(1 + sqrt(2)) - 1, 1), + (-x*(1 + sqrt(2)) + 1, 1)]) + + + p = expand(((x**2-1)*(x-2)).subs({x:x*(1 + 2**Rational(1, 4))})) + assert _torational_factor_list(p, x) is None + + +def test_cancel(): + assert cancel(0) == 0 + assert cancel(7) == 7 + assert cancel(x) == x + + assert cancel(oo) is oo + + raises(ValueError, lambda: cancel((1, 2, 3))) + + # test first tuple returnr + assert (t:=cancel((2, 3))) == (1, 2, 3) + assert isinstance(t, tuple) + + # tests 2nd tuple return + assert (t:=cancel((1, 0), x)) == (1, 1, 0) + assert isinstance(t, tuple) + assert cancel((0, 1), x) == (1, 0, 1) + + f, g, p, q = 4*x**2 - 4, 2*x - 2, 2*x + 2, 1 + F, G, P, Q = [ Poly(u, x) for u in (f, g, p, q) ] + + assert F.cancel(G) == (1, P, Q) + assert cancel((f, g)) == (1, p, q) + assert cancel((f, g), x) == (1, p, q) + assert cancel((f, g), (x,)) == (1, p, q) + # tests 3rd tuple return + assert (t:=cancel((F, G))) == (1, P, Q) + assert isinstance(t, tuple) + assert cancel((f, g), polys=True) == (1, P, Q) + assert cancel((F, G), polys=False) == (1, p, q) + + f = (x**2 - 2)/(x + sqrt(2)) + + assert cancel(f) == f + assert cancel(f, greedy=False) == x - sqrt(2) + + f = (x**2 - 2)/(x - sqrt(2)) + + assert cancel(f) == f + assert cancel(f, greedy=False) == x + sqrt(2) + + assert cancel((x**2/4 - 1, x/2 - 1)) == (1, x + 2, 2) + # assert cancel((x**2/4 - 1, x/2 - 1)) == (S.Half, x + 2, 1) + + assert cancel((x**2 - y)/(x - y)) == 1/(x - y)*(x**2 - y) + + assert cancel((x**2 - y**2)/(x - y), x) == x + y + assert cancel((x**2 - y**2)/(x - y), y) == x + y + assert cancel((x**2 - y**2)/(x - y)) == x + y + + assert cancel((x**3 - 1)/(x**2 - 1)) == (x**2 + x + 1)/(x + 1) + assert cancel((x**3/2 - S.Half)/(x**2 - 1)) == (x**2 + x + 1)/(2*x + 2) + + assert cancel((exp(2*x) + 2*exp(x) + 1)/(exp(x) + 1)) == exp(x) + 1 + + f = Poly(x**2 - a**2, x) + g = Poly(x - a, x) + + F = Poly(x + a, x, domain='ZZ[a]') + G = Poly(1, x, domain='ZZ[a]') + + assert cancel((f, g)) == (1, F, G) + + f = x**3 + (sqrt(2) - 2)*x**2 - (2*sqrt(2) + 3)*x - 3*sqrt(2) + g = x**2 - 2 + + assert cancel((f, g), extension=True) == (1, x**2 - 2*x - 3, x - sqrt(2)) + + f = Poly(-2*x + 3, x) + g = Poly(-x**9 + x**8 + x**6 - x**5 + 2*x**2 - 3*x + 1, x) + + assert cancel((f, g)) == (1, -f, -g) + + f = Poly(x/3 + 1, x) + g = Poly(x/7 + 1, x) + + assert f.cancel(g) == (S(7)/3, + Poly(x + 3, x, domain=QQ), + Poly(x + 7, x, domain=QQ)) + assert f.cancel(g, include=True) == ( + Poly(7*x + 21, x, domain=QQ), + Poly(3*x + 21, x, domain=QQ)) + + pairs = [ + (1 + x, 1 + x, 1, 1, 1), + (1 + x, 1 - x, -1, -1-x, -1+x), + (1 - x, 1 + x, -1, 1-x, 1+x), + (1 - x, 1 - x, 1, 1, 1), + ] + for f, g, coeff, p, q in pairs: + assert cancel((f, g)) == (1, p, q) + pf = Poly(f, x) + pg = Poly(g, x) + pp = Poly(p, x) + pq = Poly(q, x) + assert pf.cancel(pg) == (coeff, coeff*pp, pq) + assert pf.rep.cancel(pg.rep) == (pp.rep, pq.rep) + assert pf.rep.cancel(pg.rep, include=True) == (pp.rep, pq.rep) + + f = Poly(y, y, domain='ZZ(x)') + g = Poly(1, y, domain='ZZ[x]') + + assert f.cancel( + g) == (1, Poly(y, y, domain='ZZ(x)'), Poly(1, y, domain='ZZ(x)')) + assert f.cancel(g, include=True) == ( + Poly(y, y, domain='ZZ(x)'), Poly(1, y, domain='ZZ(x)')) + + f = Poly(5*x*y + x, y, domain='ZZ(x)') + g = Poly(2*x**2*y, y, domain='ZZ(x)') + + assert f.cancel(g, include=True) == ( + Poly(5*y + 1, y, domain='ZZ(x)'), Poly(2*x*y, y, domain='ZZ(x)')) + + f = -(-2*x - 4*y + 0.005*(z - y)**2)/((z - y)*(-z + y + 2)) + assert cancel(f).is_Mul == True + + P = tanh(x - 3.0) + Q = tanh(x + 3.0) + f = ((-2*P**2 + 2)*(-P**2 + 1)*Q**2/2 + (-2*P**2 + 2)*(-2*Q**2 + 2)*P*Q - (-2*P**2 + 2)*P**2*Q**2 + (-2*Q**2 + 2)*(-Q**2 + 1)*P**2/2 - (-2*Q**2 + 2)*P**2*Q**2)/(2*sqrt(P**2*Q**2 + 0.0001)) \ + + (-(-2*P**2 + 2)*P*Q**2/2 - (-2*Q**2 + 2)*P**2*Q/2)*((-2*P**2 + 2)*P*Q**2/2 + (-2*Q**2 + 2)*P**2*Q/2)/(2*(P**2*Q**2 + 0.0001)**Rational(3, 2)) + assert cancel(f).is_Mul == True + + # issue 7022 + A = Symbol('A', commutative=False) + p1 = Piecewise((A*(x**2 - 1)/(x + 1), x > 1), ((x + 2)/(x**2 + 2*x), True)) + p2 = Piecewise((A*(x - 1), x > 1), (1/x, True)) + assert cancel(p1) == p2 + assert cancel(2*p1) == 2*p2 + assert cancel(1 + p1) == 1 + p2 + assert cancel((x**2 - 1)/(x + 1)*p1) == (x - 1)*p2 + assert cancel((x**2 - 1)/(x + 1) + p1) == (x - 1) + p2 + p3 = Piecewise(((x**2 - 1)/(x + 1), x > 1), ((x + 2)/(x**2 + 2*x), True)) + p4 = Piecewise(((x - 1), x > 1), (1/x, True)) + assert cancel(p3) == p4 + assert cancel(2*p3) == 2*p4 + assert cancel(1 + p3) == 1 + p4 + assert cancel((x**2 - 1)/(x + 1)*p3) == (x - 1)*p4 + assert cancel((x**2 - 1)/(x + 1) + p3) == (x - 1) + p4 + + # issue 4077 + q = S('''(2*1*(x - 1/x)/(x*(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - + 1/x)) - 2/x)) - 2*1*((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - + 1/x)))*((-x + 1/x)*((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - + 1/x)))/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - 1/x)) - + 2/x) + 1)*((x - 1/x)/((x - 1/x)**2) - ((x - 1/x)/((x*(x - 1/x)**2)) - + 1/(x*(x - 1/x)))**2/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x + - 1/x)) - 2/x) - 1/(x - 1/x))*(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - + 1/(x**2*(x - 1/x)) - 2/x)/x - 1/x)*(((-x + 1/x)/((x*(x - 1/x)**2)) + + 1/(x*(x - 1/x)))*((-(x - 1/x)/(x*(x - 1/x)) - 1/x)*((x - 1/x)/((x*(x - + 1/x)**2)) - 1/(x*(x - 1/x)))/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - + 1/(x**2*(x - 1/x)) - 2/x) - 1 + (x - 1/x)/(x - 1/x))/((x*((x - + 1/x)/((x - 1/x)**2) - ((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - + 1/x)))**2/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - 1/x)) - + 2/x) - 1/(x - 1/x))*(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x + - 1/x)) - 2/x))) + ((x - 1/x)/((x*(x - 1/x))) + 1/x)/((x*(2*x - (-x + + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - 1/x)) - 2/x))) + 1/x)/(2*x + + 2*((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - 1/x)))*((-(x - 1/x)/(x*(x + - 1/x)) - 1/x)*((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - 1/x)))/(2*x - + (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - 1/x)) - 2/x) - 1 + (x - + 1/x)/(x - 1/x))/((x*((x - 1/x)/((x - 1/x)**2) - ((x - 1/x)/((x*(x - + 1/x)**2)) - 1/(x*(x - 1/x)))**2/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) + - 1/(x**2*(x - 1/x)) - 2/x) - 1/(x - 1/x))*(2*x - (-x + 1/x)/(x**2*(x + - 1/x)**2) - 1/(x**2*(x - 1/x)) - 2/x))) - 2*((x - 1/x)/((x*(x - + 1/x))) + 1/x)/(x*(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - + 1/x)) - 2/x)) - 2/x) - ((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - + 1/x)))*((-x + 1/x)*((x - 1/x)/((x*(x - 1/x)**2)) - 1/(x*(x - + 1/x)))/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - 1/x)) - + 2/x) + 1)/(x*((x - 1/x)/((x - 1/x)**2) - ((x - 1/x)/((x*(x - 1/x)**2)) + - 1/(x*(x - 1/x)))**2/(2*x - (-x + 1/x)/(x**2*(x - 1/x)**2) - + 1/(x**2*(x - 1/x)) - 2/x) - 1/(x - 1/x))*(2*x - (-x + 1/x)/(x**2*(x - + 1/x)**2) - 1/(x**2*(x - 1/x)) - 2/x)) + (x - 1/x)/((x*(2*x - (-x + + 1/x)/(x**2*(x - 1/x)**2) - 1/(x**2*(x - 1/x)) - 2/x))) - 1/x''', + evaluate=False) + assert cancel(q, _signsimp=False) is S.NaN + assert q.subs(x, 2) is S.NaN + assert signsimp(q) is S.NaN + + # issue 9363 + M = MatrixSymbol('M', 5, 5) + assert cancel(M[0,0] + 7) == M[0,0] + 7 + expr = sin(M[1, 4] + M[2, 1] * 5 * M[4, 0]) - 5 * M[1, 2] / z + assert cancel(expr) == (z*sin(M[1, 4] + M[2, 1] * 5 * M[4, 0]) - 5 * M[1, 2]) / z + + assert cancel((x**2 + 1)/(x - I)) == x + I + + +def test_cancel_modulus(): + assert cancel((x**2 - 1)/(x + 1), modulus=2) == x + 1 + assert Poly(x**2 - 1, modulus=2).cancel(Poly(x + 1, modulus=2)) ==\ + (1, Poly(x + 1, modulus=2), Poly(1, x, modulus=2)) + + +def test_make_monic_over_integers_by_scaling_roots(): + f = Poly(x**2 + 3*x + 4, x, domain='ZZ') + g, c = f.make_monic_over_integers_by_scaling_roots() + assert g == f + assert c == ZZ.one + + f = Poly(x**2 + 3*x + 4, x, domain='QQ') + g, c = f.make_monic_over_integers_by_scaling_roots() + assert g == f.to_ring() + assert c == ZZ.one + + f = Poly(x**2/2 + S(1)/4 * x + S(1)/8, x, domain='QQ') + g, c = f.make_monic_over_integers_by_scaling_roots() + assert g == Poly(x**2 + 2*x + 4, x, domain='ZZ') + assert c == 4 + + f = Poly(x**3/2 + S(1)/4 * x + S(1)/8, x, domain='QQ') + g, c = f.make_monic_over_integers_by_scaling_roots() + assert g == Poly(x**3 + 8*x + 16, x, domain='ZZ') + assert c == 4 + + f = Poly(x*y, x, y) + raises(ValueError, lambda: f.make_monic_over_integers_by_scaling_roots()) + + f = Poly(x, domain='RR') + raises(ValueError, lambda: f.make_monic_over_integers_by_scaling_roots()) + + +def test_galois_group(): + f = Poly(x ** 4 - 2) + G, alt = f.galois_group(by_name=True) + assert G == S4TransitiveSubgroups.D4 + assert alt is False + + +def test_reduced(): + f = 2*x**4 + y**2 - x**2 + y**3 + G = [x**3 - x, y**3 - y] + + Q = [2*x, 1] + r = x**2 + y**2 + y + + assert reduced(f, G) == (Q, r) + assert reduced(f, G, x, y) == (Q, r) + + H = groebner(G) + + assert H.reduce(f) == (Q, r) + + Q = [Poly(2*x, x, y), Poly(1, x, y)] + r = Poly(x**2 + y**2 + y, x, y) + + assert _strict_eq(reduced(f, G, polys=True), (Q, r)) + assert _strict_eq(reduced(f, G, x, y, polys=True), (Q, r)) + + H = groebner(G, polys=True) + + assert _strict_eq(H.reduce(f), (Q, r)) + + f = 2*x**3 + y**3 + 3*y + G = groebner([x**2 + y**2 - 1, x*y - 2]) + + Q = [x**2 - x*y**3/2 + x*y/2 + y**6/4 - y**4/2 + y**2/4, -y**5/4 + y**3/2 + y*Rational(3, 4)] + r = 0 + + assert reduced(f, G) == (Q, r) + assert G.reduce(f) == (Q, r) + + assert reduced(f, G, auto=False)[1] != 0 + assert G.reduce(f, auto=False)[1] != 0 + + assert G.contains(f) is True + assert G.contains(f + 1) is False + + assert reduced(1, [1], x) == ([1], 0) + raises(ComputationFailed, lambda: reduced(1, [1])) + + f_poly = Poly(2*x**3 + y**3 + 3*y) + G_poly = groebner([Poly(x**2 + y**2 - 1), Poly(x*y - 2)]) + + Q_poly = [Poly(x**2 - 1/2*x*y**3 + 1/2*x*y + 1/4*y**6 - 1/2*y**4 + 1/4*y**2, x, y, domain='QQ'), + Poly(-1/4*y**5 + 1/2*y**3 + 3/4*y, x, y, domain='QQ')] + r_poly = Poly(0, x, y, domain='QQ') + + assert G_poly.reduce(f_poly) == (Q_poly, r_poly) + + Q, r = G_poly.reduce(f) + assert all(isinstance(q, Poly) for q in Q) + assert isinstance(r, Poly) + + f_wrong_gens = Poly(2*x**3 + y**3 + 3*y, x, y, z) + raises(ValueError, lambda: G_poly.reduce(f_wrong_gens)) + + zero_poly = Poly(0, x, y) + Q, r = G_poly.reduce(zero_poly) + assert all(q.is_zero for q in Q) + assert r.is_zero + + const_poly = Poly(1, x, y) + Q, r = G_poly.reduce(const_poly) + assert isinstance(r, Poly) + assert r.as_expr() == 1 + assert all(q.is_zero for q in Q) + + +def test_groebner(): + assert groebner([], x, y, z) == [] + + assert groebner([x**2 + 1, y**4*x + x**3], x, y, order='lex') == [1 + x**2, -1 + y**4] + assert groebner([x**2 + 1, y**4*x + x**3, x*y*z**3], x, y, z, order='grevlex') == [-1 + y**4, z**3, 1 + x**2] + + assert groebner([x**2 + 1, y**4*x + x**3], x, y, order='lex', polys=True) == \ + [Poly(1 + x**2, x, y), Poly(-1 + y**4, x, y)] + assert groebner([x**2 + 1, y**4*x + x**3, x*y*z**3], x, y, z, order='grevlex', polys=True) == \ + [Poly(-1 + y**4, x, y, z), Poly(z**3, x, y, z), Poly(1 + x**2, x, y, z)] + + assert groebner([x**3 - 1, x**2 - 1]) == [x - 1] + assert groebner([Eq(x**3, 1), Eq(x**2, 1)]) == [x - 1] + + F = [3*x**2 + y*z - 5*x - 1, 2*x + 3*x*y + y**2, x - 3*y + x*z - 2*z**2] + f = z**9 - x**2*y**3 - 3*x*y**2*z + 11*y*z**2 + x**2*z**2 - 5 + + G = groebner(F, x, y, z, modulus=7, symmetric=False) + + assert G == [1 + x + y + 3*z + 2*z**2 + 2*z**3 + 6*z**4 + z**5, + 1 + 3*y + y**2 + 6*z**2 + 3*z**3 + 3*z**4 + 3*z**5 + 4*z**6, + 1 + 4*y + 4*z + y*z + 4*z**3 + z**4 + z**6, + 6 + 6*z + z**2 + 4*z**3 + 3*z**4 + 6*z**5 + 3*z**6 + z**7] + + Q, r = reduced(f, G, x, y, z, modulus=7, symmetric=False, polys=True) + + assert sum([ q*g for q, g in zip(Q, G.polys)], r) == Poly(f, modulus=7) + + F = [x*y - 2*y, 2*y**2 - x**2] + + assert groebner(F, x, y, order='grevlex') == \ + [y**3 - 2*y, x**2 - 2*y**2, x*y - 2*y] + assert groebner(F, y, x, order='grevlex') == \ + [x**3 - 2*x**2, -x**2 + 2*y**2, x*y - 2*y] + assert groebner(F, order='grevlex', field=True) == \ + [y**3 - 2*y, x**2 - 2*y**2, x*y - 2*y] + + assert groebner([1], x) == [1] + + assert groebner([x**2 + 2.0*y], x, y) == [1.0*x**2 + 2.0*y] + raises(ComputationFailed, lambda: groebner([1])) + + assert groebner([x**2 - 1, x**3 + 1], method='buchberger') == [x + 1] + assert groebner([x**2 - 1, x**3 + 1], method='f5b') == [x + 1] + + raises(ValueError, lambda: groebner([x, y], method='unknown')) + + +def test_fglm(): + F = [a + b + c + d, a*b + a*d + b*c + b*d, a*b*c + a*b*d + a*c*d + b*c*d, a*b*c*d - 1] + G = groebner(F, a, b, c, d, order=grlex) + + B = [ + 4*a + 3*d**9 - 4*d**5 - 3*d, + 4*b + 4*c - 3*d**9 + 4*d**5 + 7*d, + 4*c**2 + 3*d**10 - 4*d**6 - 3*d**2, + 4*c*d**4 + 4*c - d**9 + 4*d**5 + 5*d, + d**12 - d**8 - d**4 + 1, + ] + + assert groebner(F, a, b, c, d, order=lex) == B + assert G.fglm(lex) == B + + F = [9*x**8 + 36*x**7 - 32*x**6 - 252*x**5 - 78*x**4 + 468*x**3 + 288*x**2 - 108*x + 9, + -72*t*x**7 - 252*t*x**6 + 192*t*x**5 + 1260*t*x**4 + 312*t*x**3 - 404*t*x**2 - 576*t*x + \ + 108*t - 72*x**7 - 256*x**6 + 192*x**5 + 1280*x**4 + 312*x**3 - 576*x + 96] + G = groebner(F, t, x, order=grlex) + + B = [ + 203577793572507451707*t + 627982239411707112*x**7 - 666924143779443762*x**6 - \ + 10874593056632447619*x**5 + 5119998792707079562*x**4 + 72917161949456066376*x**3 + \ + 20362663855832380362*x**2 - 142079311455258371571*x + 183756699868981873194, + 9*x**8 + 36*x**7 - 32*x**6 - 252*x**5 - 78*x**4 + 468*x**3 + 288*x**2 - 108*x + 9, + ] + + assert groebner(F, t, x, order=lex) == B + assert G.fglm(lex) == B + + F = [x**2 - x - 3*y + 1, -2*x + y**2 + y - 1] + G = groebner(F, x, y, order=lex) + + B = [ + x**2 - x - 3*y + 1, + y**2 - 2*x + y - 1, + ] + + assert groebner(F, x, y, order=grlex) == B + assert G.fglm(grlex) == B + + +def test_is_zero_dimensional(): + assert is_zero_dimensional([x, y], x, y) is True + assert is_zero_dimensional([x**3 + y**2], x, y) is False + + assert is_zero_dimensional([x, y, z], x, y, z) is True + assert is_zero_dimensional([x, y, z], x, y, z, t) is False + + F = [x*y - z, y*z - x, x*y - y] + assert is_zero_dimensional(F, x, y, z) is True + + F = [x**2 - 2*x*z + 5, x*y**2 + y*z**3, 3*y**2 - 8*z**2] + assert is_zero_dimensional(F, x, y, z) is True + + +def test_GroebnerBasis(): + F = [x*y - 2*y, 2*y**2 - x**2] + + G = groebner(F, x, y, order='grevlex') + H = [y**3 - 2*y, x**2 - 2*y**2, x*y - 2*y] + P = [ Poly(h, x, y) for h in H ] + + assert groebner(F + [0], x, y, order='grevlex') == G + assert isinstance(G, GroebnerBasis) is True + + assert len(G) == 3 + + assert G[0] == H[0] and not G[0].is_Poly + assert G[1] == H[1] and not G[1].is_Poly + assert G[2] == H[2] and not G[2].is_Poly + + assert G[1:] == H[1:] and not any(g.is_Poly for g in G[1:]) + assert G[:2] == H[:2] and not any(g.is_Poly for g in G[1:]) + + assert G.exprs == H + assert G.polys == P + assert G.gens == (x, y) + assert G.domain == ZZ + assert G.order == grevlex + + assert G == H + assert G == tuple(H) + assert G == P + assert G == tuple(P) + + assert G != [] + + G = groebner(F, x, y, order='grevlex', polys=True) + + assert G[0] == P[0] and G[0].is_Poly + assert G[1] == P[1] and G[1].is_Poly + assert G[2] == P[2] and G[2].is_Poly + + assert G[1:] == P[1:] and all(g.is_Poly for g in G[1:]) + assert G[:2] == P[:2] and all(g.is_Poly for g in G[1:]) + + +def test_poly(): + assert poly(x) == Poly(x, x) + assert poly(y) == Poly(y, y) + + assert poly(x + y) == Poly(x + y, x, y) + assert poly(x + sin(x)) == Poly(x + sin(x), x, sin(x)) + + assert poly(x + y, wrt=y) == Poly(x + y, y, x) + assert poly(x + sin(x), wrt=sin(x)) == Poly(x + sin(x), sin(x), x) + + assert poly(x*y + 2*x*z**2 + 17) == Poly(x*y + 2*x*z**2 + 17, x, y, z) + + assert poly(2*(y + z)**2 - 1) == Poly(2*y**2 + 4*y*z + 2*z**2 - 1, y, z) + assert poly( + x*(y + z)**2 - 1) == Poly(x*y**2 + 2*x*y*z + x*z**2 - 1, x, y, z) + assert poly(2*x*( + y + z)**2 - 1) == Poly(2*x*y**2 + 4*x*y*z + 2*x*z**2 - 1, x, y, z) + + assert poly(2*( + y + z)**2 - x - 1) == Poly(2*y**2 + 4*y*z + 2*z**2 - x - 1, x, y, z) + assert poly(x*( + y + z)**2 - x - 1) == Poly(x*y**2 + 2*x*y*z + x*z**2 - x - 1, x, y, z) + assert poly(2*x*(y + z)**2 - x - 1) == Poly(2*x*y**2 + 4*x*y*z + 2* + x*z**2 - x - 1, x, y, z) + + assert poly(x*y + (x + y)**2 + (x + z)**2) == \ + Poly(2*x*z + 3*x*y + y**2 + z**2 + 2*x**2, x, y, z) + assert poly(x*y*(x + y)*(x + z)**2) == \ + Poly(x**3*y**2 + x*y**2*z**2 + y*x**2*z**2 + 2*z*x**2* + y**2 + 2*y*z*x**3 + y*x**4, x, y, z) + + assert poly(Poly(x + y + z, y, x, z)) == Poly(x + y + z, y, x, z) + + assert poly((x + y)**2, x) == Poly(x**2 + 2*x*y + y**2, x, domain=ZZ[y]) + assert poly((x + y)**2, y) == Poly(x**2 + 2*x*y + y**2, y, domain=ZZ[x]) + + assert poly(1, x) == Poly(1, x) + raises(GeneratorsNeeded, lambda: poly(1)) + + # issue 6184 + assert poly(x + y, x, y) == Poly(x + y, x, y) + assert poly(x + y, y, x) == Poly(x + y, y, x) + + # https://github.com/sympy/sympy/issues/19755 + expr1 = x + (2*x + 3)**2/5 + S(6)/5 + assert poly(expr1).as_expr() == expr1.expand() + expr2 = y*(y+1) + S(1)/3 + assert poly(expr2).as_expr() == expr2.expand() + + +def test_keep_coeff(): + u = Mul(2, x + 1, evaluate=False) + assert _keep_coeff(S.One, x) == x + assert _keep_coeff(S.NegativeOne, x) == -x + assert _keep_coeff(S(1.0), x) == 1.0*x + assert _keep_coeff(S(-1.0), x) == -1.0*x + assert _keep_coeff(S.One, 2*x) == 2*x + assert _keep_coeff(S(2), x/2) == x + assert _keep_coeff(S(2), sin(x)) == 2*sin(x) + assert _keep_coeff(S(2), x + 1) == u + assert _keep_coeff(x, 1/x) == 1 + assert _keep_coeff(x + 1, S(2)) == u + assert _keep_coeff(S.Half, S.One) == S.Half + p = Pow(2, 3, evaluate=False) + assert _keep_coeff(S(-1), p) == Mul(-1, p, evaluate=False) + a = Add(2, p, evaluate=False) + assert _keep_coeff(S.Half, a, clear=True + ) == Mul(S.Half, a, evaluate=False) + assert _keep_coeff(S.Half, a, clear=False + ) == Add(1, Mul(S.Half, p, evaluate=False), evaluate=False) + + +def test_poly_matching_consistency(): + # Test for this issue: + # https://github.com/sympy/sympy/issues/5514 + assert I * Poly(x, x) == Poly(I*x, x) + assert Poly(x, x) * I == Poly(I*x, x) + + +def test_issue_5786(): + assert expand(factor(expand( + (x - I*y)*(z - I*t)), extension=[I])) == -I*t*x - t*y + x*z - I*y*z + + +def test_noncommutative(): + class foo(Expr): + is_commutative=False + e = x/(x + x*y) + c = 1/( 1 + y) + assert cancel(foo(e)) == foo(c) + assert cancel(e + foo(e)) == c + foo(c) + assert cancel(e*foo(c)) == c*foo(c) + + +def test_to_rational_coeffs(): + assert to_rational_coeffs( + Poly(x**3 + y*x**2 + sqrt(y), x, domain='EX')) is None + # issue 21268 + assert to_rational_coeffs( + Poly(y**3 + sqrt(2)*y**2*sin(x) + 1, y)) is None + + assert to_rational_coeffs(Poly(x, y)) is None + assert to_rational_coeffs(Poly(sqrt(2)*y)) is None + + +def test_factor_terms(): + # issue 7067 + assert factor_list(x*(x + y)) == (1, [(x, 1), (x + y, 1)]) + assert sqf_list(x*(x + y)) == (1, [(x**2 + x*y, 1)]) + + +def test_as_list(): + # issue 14496 + assert Poly(x**3 + 2, x, domain='ZZ').as_list() == [1, 0, 0, 2] + assert Poly(x**2 + y + 1, x, y, domain='ZZ').as_list() == [[1], [], [1, 1]] + assert Poly(x**2 + y + 1, x, y, z, domain='ZZ').as_list() == \ + [[[1]], [[]], [[1], [1]]] + + +def test_issue_11198(): + assert factor_list(sqrt(2)*x) == (sqrt(2), [(x, 1)]) + assert factor_list(sqrt(2)*sin(x), sin(x)) == (sqrt(2), [(sin(x), 1)]) + + +def test_Poly_precision(): + # Make sure Poly doesn't lose precision + p = Poly(pi.evalf(100)*x) + assert p.as_expr() == pi.evalf(100)*x + + +def test_issue_12400(): + # Correction of check for negative exponents + assert poly(1/(1+sqrt(2)), x) == \ + Poly(1/(1+sqrt(2)), x, domain='EX') + +def test_issue_14364(): + assert gcd(S(6)*(1 + sqrt(3))/5, S(3)*(1 + sqrt(3))/10) == Rational(3, 10) * (1 + sqrt(3)) + assert gcd(sqrt(5)*Rational(4, 7), sqrt(5)*Rational(2, 3)) == sqrt(5)*Rational(2, 21) + + assert lcm(Rational(2, 3)*sqrt(3), Rational(5, 6)*sqrt(3)) == S(10)*sqrt(3)/3 + assert lcm(3*sqrt(3), 4/sqrt(3)) == 12*sqrt(3) + assert lcm(S(5)*(1 + 2**Rational(1, 3))/6, S(3)*(1 + 2**Rational(1, 3))/8) == Rational(15, 2) * (1 + 2**Rational(1, 3)) + + assert gcd(Rational(2, 3)*sqrt(3), Rational(5, 6)/sqrt(3)) == sqrt(3)/18 + assert gcd(S(4)*sqrt(13)/7, S(3)*sqrt(13)/14) == sqrt(13)/14 + + # gcd_list and lcm_list + assert gcd([S(2)*sqrt(47)/7, S(6)*sqrt(47)/5, S(8)*sqrt(47)/5]) == sqrt(47)*Rational(2, 35) + assert gcd([S(6)*(1 + sqrt(7))/5, S(2)*(1 + sqrt(7))/7, S(4)*(1 + sqrt(7))/13]) == (1 + sqrt(7))*Rational(2, 455) + assert lcm((Rational(7, 2)/sqrt(15), Rational(5, 6)/sqrt(15), Rational(5, 8)/sqrt(15))) == Rational(35, 2)/sqrt(15) + assert lcm([S(5)*(2 + 2**Rational(5, 7))/6, S(7)*(2 + 2**Rational(5, 7))/2, S(13)*(2 + 2**Rational(5, 7))/4]) == Rational(455, 2) * (2 + 2**Rational(5, 7)) + + +def test_issue_15669(): + x = Symbol("x", positive=True) + expr = (16*x**3/(-x**2 + sqrt(8*x**2 + (x**2 - 2)**2) + 2)**2 - + 2*2**Rational(4, 5)*x*(-x**2 + sqrt(8*x**2 + (x**2 - 2)**2) + 2)**Rational(3, 5) + 10*x) + assert factor(expr, deep=True) == x*(x**2 + 2) + + +def test_issue_17988(): + x = Symbol('x') + p = poly(x - 1) + with warns_deprecated_sympy(): + M = Matrix([[poly(x + 1), poly(x + 1)]]) + with warns(SymPyDeprecationWarning, test_stacklevel=False): + assert p * M == M * p == Matrix([[poly(x**2 - 1), poly(x**2 - 1)]]) + + +def test_issue_18205(): + assert cancel((2 + I)*(3 - I)) == 7 + I + assert cancel((2 + I)*(2 - I)) == 5 + + +def test_issue_8695(): + p = (x**2 + 1) * (x - 1)**2 * (x - 2)**3 * (x - 3)**3 + result = (1, [(x**2 + 1, 1), (x - 1, 2), (x**2 - 5*x + 6, 3)]) + assert sqf_list(p) == result + + +def test_issue_19113(): + eq = sin(x)**3 - sin(x) + 1 + raises(PolynomialError, lambda: refine_root(eq, 1, 2, 1e-2)) + raises(PolynomialError, lambda: count_roots(eq, -1, 1)) + raises(PolynomialError, lambda: real_roots(eq)) + raises(PolynomialError, lambda: nroots(eq)) + raises(PolynomialError, lambda: ground_roots(eq)) + raises(PolynomialError, lambda: nth_power_roots_poly(eq, 2)) + + +def test_issue_19360(): + f = 2*x**2 - 2*sqrt(2)*x*y + y**2 + assert factor(f, extension=sqrt(2)) == 2*(x - (sqrt(2)*y/2))**2 + + f = -I*t*x - t*y + x*z - I*y*z + assert factor(f, extension=I) == (x - I*y)*(-I*t + z) + + +def test_poly_copy_equals_original(): + poly = Poly(x + y, x, y, z) + copy = poly.copy() + assert poly == copy, ( + "Copied polynomial not equal to original.") + assert poly.gens == copy.gens, ( + "Copied polynomial has different generators than original.") + + +def test_deserialized_poly_equals_original(): + poly = Poly(x + y, x, y, z) + deserialized = pickle.loads(pickle.dumps(poly)) + assert poly == deserialized, ( + "Deserialized polynomial not equal to original.") + assert poly.gens == deserialized.gens, ( + "Deserialized polynomial has different generators than original.") + + +def test_issue_20389(): + result = degree(x * (x + 1) - x ** 2 - x, x) + assert result == -oo + + +def test_issue_20985(): + from sympy.core.symbol import symbols + w, R = symbols('w R') + poly = Poly(1.0 + I*w/R, w, 1/R) + assert poly.degree() == S(1) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyutils.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyutils.py new file mode 100644 index 0000000000000000000000000000000000000000..f39561a1c5035fed52add5e49476d0eea91bdae0 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_polyutils.py @@ -0,0 +1,300 @@ +"""Tests for useful utilities for higher level polynomial classes. """ + +from sympy.core.mul import Mul +from sympy.core.numbers import (Integer, pi) +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.integrals.integrals import Integral +from sympy.testing.pytest import raises + +from sympy.polys.polyutils import ( + _nsort, + _sort_gens, + _unify_gens, + _analyze_gens, + _sort_factors, + parallel_dict_from_expr, + dict_from_expr, +) + +from sympy.polys.polyerrors import PolynomialError + +from sympy.polys.domains import ZZ + +x, y, z, p, q, r, s, t, u, v, w = symbols('x,y,z,p,q,r,s,t,u,v,w') +A, B = symbols('A,B', commutative=False) + + +def test__nsort(): + # issue 6137 + r = S('''[3/2 + sqrt(-14/3 - 2*(-415/216 + 13*I/12)**(1/3) - 4/sqrt(-7/3 + + 61/(18*(-415/216 + 13*I/12)**(1/3)) + 2*(-415/216 + 13*I/12)**(1/3)) - + 61/(18*(-415/216 + 13*I/12)**(1/3)))/2 - sqrt(-7/3 + 61/(18*(-415/216 + + 13*I/12)**(1/3)) + 2*(-415/216 + 13*I/12)**(1/3))/2, 3/2 - sqrt(-7/3 + + 61/(18*(-415/216 + 13*I/12)**(1/3)) + 2*(-415/216 + + 13*I/12)**(1/3))/2 - sqrt(-14/3 - 2*(-415/216 + 13*I/12)**(1/3) - + 4/sqrt(-7/3 + 61/(18*(-415/216 + 13*I/12)**(1/3)) + 2*(-415/216 + + 13*I/12)**(1/3)) - 61/(18*(-415/216 + 13*I/12)**(1/3)))/2, 3/2 + + sqrt(-14/3 - 2*(-415/216 + 13*I/12)**(1/3) + 4/sqrt(-7/3 + + 61/(18*(-415/216 + 13*I/12)**(1/3)) + 2*(-415/216 + 13*I/12)**(1/3)) - + 61/(18*(-415/216 + 13*I/12)**(1/3)))/2 + sqrt(-7/3 + 61/(18*(-415/216 + + 13*I/12)**(1/3)) + 2*(-415/216 + 13*I/12)**(1/3))/2, 3/2 + sqrt(-7/3 + + 61/(18*(-415/216 + 13*I/12)**(1/3)) + 2*(-415/216 + + 13*I/12)**(1/3))/2 - sqrt(-14/3 - 2*(-415/216 + 13*I/12)**(1/3) + + 4/sqrt(-7/3 + 61/(18*(-415/216 + 13*I/12)**(1/3)) + 2*(-415/216 + + 13*I/12)**(1/3)) - 61/(18*(-415/216 + 13*I/12)**(1/3)))/2]''') + ans = [r[1], r[0], r[-1], r[-2]] + assert _nsort(r) == ans + assert len(_nsort(r, separated=True)[0]) == 0 + b, c, a = exp(-1000), exp(-999), exp(-1001) + assert _nsort((b, c, a)) == [a, b, c] + # issue 12560 + a = cos(1)**2 + sin(1)**2 - 1 + assert _nsort([a]) == [a] + + +def test__sort_gens(): + assert _sort_gens([]) == () + + assert _sort_gens([x]) == (x,) + assert _sort_gens([p]) == (p,) + assert _sort_gens([q]) == (q,) + + assert _sort_gens([x, p]) == (x, p) + assert _sort_gens([p, x]) == (x, p) + assert _sort_gens([q, p]) == (p, q) + + assert _sort_gens([q, p, x]) == (x, p, q) + + assert _sort_gens([x, p, q], wrt=x) == (x, p, q) + assert _sort_gens([x, p, q], wrt=p) == (p, x, q) + assert _sort_gens([x, p, q], wrt=q) == (q, x, p) + + assert _sort_gens([x, p, q], wrt='x') == (x, p, q) + assert _sort_gens([x, p, q], wrt='p') == (p, x, q) + assert _sort_gens([x, p, q], wrt='q') == (q, x, p) + + assert _sort_gens([x, p, q], wrt='x,q') == (x, q, p) + assert _sort_gens([x, p, q], wrt='q,x') == (q, x, p) + assert _sort_gens([x, p, q], wrt='p,q') == (p, q, x) + assert _sort_gens([x, p, q], wrt='q,p') == (q, p, x) + + assert _sort_gens([x, p, q], wrt='x, q') == (x, q, p) + assert _sort_gens([x, p, q], wrt='q, x') == (q, x, p) + assert _sort_gens([x, p, q], wrt='p, q') == (p, q, x) + assert _sort_gens([x, p, q], wrt='q, p') == (q, p, x) + + assert _sort_gens([x, p, q], wrt=[x, 'q']) == (x, q, p) + assert _sort_gens([x, p, q], wrt=[q, 'x']) == (q, x, p) + assert _sort_gens([x, p, q], wrt=[p, 'q']) == (p, q, x) + assert _sort_gens([x, p, q], wrt=[q, 'p']) == (q, p, x) + + assert _sort_gens([x, p, q], wrt=['x', 'q']) == (x, q, p) + assert _sort_gens([x, p, q], wrt=['q', 'x']) == (q, x, p) + assert _sort_gens([x, p, q], wrt=['p', 'q']) == (p, q, x) + assert _sort_gens([x, p, q], wrt=['q', 'p']) == (q, p, x) + + assert _sort_gens([x, p, q], sort='x > p > q') == (x, p, q) + assert _sort_gens([x, p, q], sort='p > x > q') == (p, x, q) + assert _sort_gens([x, p, q], sort='p > q > x') == (p, q, x) + + assert _sort_gens([x, p, q], wrt='x', sort='q > p') == (x, q, p) + assert _sort_gens([x, p, q], wrt='p', sort='q > x') == (p, q, x) + assert _sort_gens([x, p, q], wrt='q', sort='p > x') == (q, p, x) + + # https://github.com/sympy/sympy/issues/19353 + n1 = Symbol('\n1') + assert _sort_gens([n1]) == (n1,) + assert _sort_gens([x, n1]) == (x, n1) + + X = symbols('x0,x1,x2,x10,x11,x12,x20,x21,x22') + + assert _sort_gens(X) == X + + +def test__unify_gens(): + assert _unify_gens([], []) == () + + assert _unify_gens([x], [x]) == (x,) + assert _unify_gens([y], [y]) == (y,) + + assert _unify_gens([x, y], [x]) == (x, y) + assert _unify_gens([x], [x, y]) == (x, y) + + assert _unify_gens([x, y], [x, y]) == (x, y) + assert _unify_gens([y, x], [y, x]) == (y, x) + + assert _unify_gens([x], [y]) == (x, y) + assert _unify_gens([y], [x]) == (y, x) + + assert _unify_gens([x], [y, x]) == (y, x) + assert _unify_gens([y, x], [x]) == (y, x) + + assert _unify_gens([x, y, z], [x, y, z]) == (x, y, z) + assert _unify_gens([z, y, x], [x, y, z]) == (z, y, x) + assert _unify_gens([x, y, z], [z, y, x]) == (x, y, z) + assert _unify_gens([z, y, x], [z, y, x]) == (z, y, x) + + assert _unify_gens([x, y, z], [t, x, p, q, z]) == (t, x, y, p, q, z) + + +def test__analyze_gens(): + assert _analyze_gens((x, y, z)) == (x, y, z) + assert _analyze_gens([x, y, z]) == (x, y, z) + + assert _analyze_gens(([x, y, z],)) == (x, y, z) + assert _analyze_gens(((x, y, z),)) == (x, y, z) + + +def test__sort_factors(): + assert _sort_factors([], multiple=True) == [] + assert _sort_factors([], multiple=False) == [] + + F = [[1, 2, 3], [1, 2], [1]] + G = [[1], [1, 2], [1, 2, 3]] + + assert _sort_factors(F, multiple=False) == G + + F = [[1, 2], [1, 2, 3], [1, 2], [1]] + G = [[1], [1, 2], [1, 2], [1, 2, 3]] + + assert _sort_factors(F, multiple=False) == G + + F = [[2, 2], [1, 2, 3], [1, 2], [1]] + G = [[1], [1, 2], [2, 2], [1, 2, 3]] + + assert _sort_factors(F, multiple=False) == G + + F = [([1, 2, 3], 1), ([1, 2], 1), ([1], 1)] + G = [([1], 1), ([1, 2], 1), ([1, 2, 3], 1)] + + assert _sort_factors(F, multiple=True) == G + + F = [([1, 2], 1), ([1, 2, 3], 1), ([1, 2], 1), ([1], 1)] + G = [([1], 1), ([1, 2], 1), ([1, 2], 1), ([1, 2, 3], 1)] + + assert _sort_factors(F, multiple=True) == G + + F = [([2, 2], 1), ([1, 2, 3], 1), ([1, 2], 1), ([1], 1)] + G = [([1], 1), ([1, 2], 1), ([2, 2], 1), ([1, 2, 3], 1)] + + assert _sort_factors(F, multiple=True) == G + + F = [([2, 2], 1), ([1, 2, 3], 1), ([1, 2], 2), ([1], 1)] + G = [([1], 1), ([2, 2], 1), ([1, 2], 2), ([1, 2, 3], 1)] + + assert _sort_factors(F, multiple=True) == G + + +def test__dict_from_expr_if_gens(): + assert dict_from_expr( + Integer(17), gens=(x,)) == ({(0,): Integer(17)}, (x,)) + assert dict_from_expr( + Integer(17), gens=(x, y)) == ({(0, 0): Integer(17)}, (x, y)) + assert dict_from_expr( + Integer(17), gens=(x, y, z)) == ({(0, 0, 0): Integer(17)}, (x, y, z)) + + assert dict_from_expr( + Integer(-17), gens=(x,)) == ({(0,): Integer(-17)}, (x,)) + assert dict_from_expr( + Integer(-17), gens=(x, y)) == ({(0, 0): Integer(-17)}, (x, y)) + assert dict_from_expr(Integer( + -17), gens=(x, y, z)) == ({(0, 0, 0): Integer(-17)}, (x, y, z)) + + assert dict_from_expr( + Integer(17)*x, gens=(x,)) == ({(1,): Integer(17)}, (x,)) + assert dict_from_expr( + Integer(17)*x, gens=(x, y)) == ({(1, 0): Integer(17)}, (x, y)) + assert dict_from_expr(Integer( + 17)*x, gens=(x, y, z)) == ({(1, 0, 0): Integer(17)}, (x, y, z)) + + assert dict_from_expr( + Integer(17)*x**7, gens=(x,)) == ({(7,): Integer(17)}, (x,)) + assert dict_from_expr( + Integer(17)*x**7*y, gens=(x, y)) == ({(7, 1): Integer(17)}, (x, y)) + assert dict_from_expr(Integer(17)*x**7*y*z**12, gens=( + x, y, z)) == ({(7, 1, 12): Integer(17)}, (x, y, z)) + + assert dict_from_expr(x + 2*y + 3*z, gens=(x,)) == \ + ({(1,): Integer(1), (0,): 2*y + 3*z}, (x,)) + assert dict_from_expr(x + 2*y + 3*z, gens=(x, y)) == \ + ({(1, 0): Integer(1), (0, 1): Integer(2), (0, 0): 3*z}, (x, y)) + assert dict_from_expr(x + 2*y + 3*z, gens=(x, y, z)) == \ + ({(1, 0, 0): Integer( + 1), (0, 1, 0): Integer(2), (0, 0, 1): Integer(3)}, (x, y, z)) + + assert dict_from_expr(x*y + 2*x*z + 3*y*z, gens=(x,)) == \ + ({(1,): y + 2*z, (0,): 3*y*z}, (x,)) + assert dict_from_expr(x*y + 2*x*z + 3*y*z, gens=(x, y)) == \ + ({(1, 1): Integer(1), (1, 0): 2*z, (0, 1): 3*z}, (x, y)) + assert dict_from_expr(x*y + 2*x*z + 3*y*z, gens=(x, y, z)) == \ + ({(1, 1, 0): Integer( + 1), (1, 0, 1): Integer(2), (0, 1, 1): Integer(3)}, (x, y, z)) + + assert dict_from_expr(2**y*x, gens=(x,)) == ({(1,): 2**y}, (x,)) + assert dict_from_expr(Integral(x, (x, 1, 2)) + x) == ( + {(0, 1): 1, (1, 0): 1}, (x, Integral(x, (x, 1, 2)))) + raises(PolynomialError, lambda: dict_from_expr(2**y*x, gens=(x, y))) + + +def test__dict_from_expr_no_gens(): + assert dict_from_expr(Integer(17)) == ({(): Integer(17)}, ()) + + assert dict_from_expr(x) == ({(1,): Integer(1)}, (x,)) + assert dict_from_expr(y) == ({(1,): Integer(1)}, (y,)) + + assert dict_from_expr(x*y) == ({(1, 1): Integer(1)}, (x, y)) + assert dict_from_expr( + x + y) == ({(1, 0): Integer(1), (0, 1): Integer(1)}, (x, y)) + + assert dict_from_expr(sqrt(2)) == ({(1,): Integer(1)}, (sqrt(2),)) + assert dict_from_expr(sqrt(2), greedy=False) == ({(): sqrt(2)}, ()) + + assert dict_from_expr(x*y, domain=ZZ[x]) == ({(1,): x}, (y,)) + assert dict_from_expr(x*y, domain=ZZ[y]) == ({(1,): y}, (x,)) + + assert dict_from_expr(3*sqrt( + 2)*pi*x*y, extension=None) == ({(1, 1, 1, 1): 3}, (x, y, pi, sqrt(2))) + assert dict_from_expr(3*sqrt( + 2)*pi*x*y, extension=True) == ({(1, 1, 1): 3*sqrt(2)}, (x, y, pi)) + + assert dict_from_expr(3*sqrt( + 2)*pi*x*y, extension=True) == ({(1, 1, 1): 3*sqrt(2)}, (x, y, pi)) + + f = cos(x)*sin(x) + cos(x)*sin(y) + cos(y)*sin(x) + cos(y)*sin(y) + + assert dict_from_expr(f) == ({(0, 1, 0, 1): 1, (0, 1, 1, 0): 1, + (1, 0, 0, 1): 1, (1, 0, 1, 0): 1}, (cos(x), cos(y), sin(x), sin(y))) + + +def test__parallel_dict_from_expr_if_gens(): + assert parallel_dict_from_expr([x + 2*y + 3*z, Integer(7)], gens=(x,)) == \ + ([{(1,): Integer(1), (0,): 2*y + 3*z}, {(0,): Integer(7)}], (x,)) + + +def test__parallel_dict_from_expr_no_gens(): + assert parallel_dict_from_expr([x*y, Integer(3)]) == \ + ([{(1, 1): Integer(1)}, {(0, 0): Integer(3)}], (x, y)) + assert parallel_dict_from_expr([x*y, 2*z, Integer(3)]) == \ + ([{(1, 1, 0): Integer( + 1)}, {(0, 0, 1): Integer(2)}, {(0, 0, 0): Integer(3)}], (x, y, z)) + assert parallel_dict_from_expr((Mul(x, x**2, evaluate=False),)) == \ + ([{(3,): 1}], (x,)) + + +def test_parallel_dict_from_expr(): + assert parallel_dict_from_expr([Eq(x, 1), Eq( + x**2, 2)]) == ([{(0,): -Integer(1), (1,): Integer(1)}, + {(0,): -Integer(2), (2,): Integer(1)}], (x,)) + raises(PolynomialError, lambda: parallel_dict_from_expr([A*B - B*A])) + + +def test_dict_from_expr(): + assert dict_from_expr(Eq(x, 1)) == \ + ({(0,): -Integer(1), (1,): Integer(1)}, (x,)) + raises(PolynomialError, lambda: dict_from_expr(A*B - B*A)) + raises(PolynomialError, lambda: dict_from_expr(S.true)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_puiseux.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_puiseux.py new file mode 100644 index 0000000000000000000000000000000000000000..031881e9d12c53053d8ec7136374bd8b3a385df0 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_puiseux.py @@ -0,0 +1,204 @@ +# +# Tests for PuiseuxRing and PuiseuxPoly +# + +from sympy.testing.pytest import raises + +from sympy import ZZ, QQ, ring +from sympy.polys.puiseux import PuiseuxRing, PuiseuxPoly, puiseux_ring + +from sympy.abc import x, y + + +def test_puiseux_ring(): + R, px = puiseux_ring('x', QQ) + R2, px2 = puiseux_ring([x], QQ) + assert isinstance(R, PuiseuxRing) + assert isinstance(px, PuiseuxPoly) + assert R == R2 + assert px == px2 + assert R == PuiseuxRing('x', QQ) + assert R == PuiseuxRing([x], QQ) + assert R != PuiseuxRing('y', QQ) + assert R != PuiseuxRing('x', ZZ) + assert R != PuiseuxRing('x, y', QQ) + assert R != QQ + assert str(R) == 'PuiseuxRing((x,), QQ)' + + +def test_puiseux_ring_attributes(): + R1, px1, py1 = ring('x, y', QQ) + R2, px2, py2 = puiseux_ring('x, y', QQ) + assert R2.domain == QQ + assert R2.symbols == (x, y) + assert R2.gens == (px2, py2) + assert R2.ngens == 2 + assert R2.poly_ring == R1 + assert R2.zero == PuiseuxPoly(R1.zero, R2) + assert R2.one == PuiseuxPoly(R1.one, R2) + assert R2.zero_monom == R1.zero_monom == (0, 0) # type: ignore + assert R2.monomial_mul((1, 2), (3, 4)) == (4, 6) + + +def test_puiseux_ring_methods(): + R1, px1, py1 = ring('x, y', QQ) + R2, px2, py2 = puiseux_ring('x, y', QQ) + assert R2({(1, 2): 3}) == 3*px2*py2**2 + assert R2(px1) == px2 + assert R2(1) == R2.one + assert R2(QQ(1,2)) == QQ(1,2)*R2.one + assert R2.from_poly(px1) == px2 + assert R2.from_poly(px1) != py2 + assert R2.from_dict({(1, 2): QQ(3)}) == 3*px2*py2**2 + assert R2.from_dict({(QQ(1,2), 2): QQ(3)}) == 3*px2**QQ(1,2)*py2**2 + assert R2.from_int(3) == 3*R2.one + assert R2.domain_new(3) == QQ(3) + assert QQ.of_type(R2.domain_new(3)) + assert R2.ground_new(3) == 3*R2.one + assert isinstance(R2.ground_new(3), PuiseuxPoly) + assert R2.index(px2) == 0 + assert R2.index(py2) == 1 + + +def test_puiseux_poly(): + R1, px1 = ring('x', QQ) + R2, px2 = puiseux_ring('x', QQ) + assert PuiseuxPoly(px1, R2) == px2 + assert px2.ring == R2 + assert px2.as_expr() == px1.as_expr() == x + assert px1 != px2 + assert R2.one == px2**0 == 1 + assert px2 == px1 + assert px2 != 2.0 + assert px2**QQ(1,2) != px1 + + +def test_puiseux_poly_normalization(): + R, x = puiseux_ring('x', QQ) + assert (x**2 + 1) / x == x + 1/x == R({(1,): 1, (-1,): 1}) + assert (x**QQ(1,6))**2 == x**QQ(1,3) == R({(QQ(1,3),): 1}) + assert (x**QQ(1,6))**(-2) == x**(-QQ(1,3)) == R({(-QQ(1,3),): 1}) + assert (x**QQ(1,6))**QQ(1,2) == x**QQ(1,12) == R({(QQ(1,12),): 1}) + assert (x**QQ(1,6))**6 == x == R({(1,): 1}) + assert x**QQ(1,6) * x**QQ(1,3) == x**QQ(1,2) == R({(QQ(1,2),): 1}) + assert 1/x * x**2 == x == R({(1,): 1}) + assert 1/x**QQ(1,3) * x**QQ(1,3) == 1 == R({(0,): 1}) + + +def test_puiseux_poly_monoms(): + R, x = puiseux_ring('x', QQ) + assert x.monoms() == [(1,)] + assert list(x) == [(1,)] + assert (x**2 + 1).monoms() == [(2,), (0,)] + assert R({(1,): 1, (-1,): 1}).monoms() == [(1,), (-1,)] + assert R({(QQ(1,3),): 1}).monoms() == [(QQ(1,3),)] + assert R({(-QQ(1,3),): 1}).monoms() == [(-QQ(1,3),)] + p = x**QQ(1,6) + assert p[(QQ(1,6),)] == 1 + raises(KeyError, lambda: p[(1,)]) + assert p.to_dict() == {(QQ(1,6),): 1} + assert R(p.to_dict()) == p + assert PuiseuxPoly.from_dict({(QQ(1,6),): 1}, R) == p + + +def test_puiseux_poly_repr(): + R, x = puiseux_ring('x', QQ) + assert repr(x) == 'x' + assert repr(x**QQ(1,2)) == 'x**(1/2)' + assert repr(1/x) == 'x**(-1)' + assert repr(2*x**2 + 1) == '1 + 2*x**2' + assert repr(R.one) == '1' + assert repr(2*R.one) == '2' + + +def test_puiseux_poly_unify(): + R, x = puiseux_ring('x', QQ) + assert 1/x + x == x + 1/x == R({(1,): 1, (-1,): 1}) + assert repr(1/x + x) == 'x**(-1) + x' + assert 1/x + 1/x == 2/x == R({(-1,): 2}) + assert repr(1/x + 1/x) == '2*x**(-1)' + assert x**QQ(1,2) + x**QQ(1,2) == 2*x**QQ(1,2) == R({(QQ(1,2),): 2}) + assert repr(x**QQ(1,2) + x**QQ(1,2)) == '2*x**(1/2)' + assert x**QQ(1,2) + x**QQ(1,3) == R({(QQ(1,2),): 1, (QQ(1,3),): 1}) + assert repr(x**QQ(1,2) + x**QQ(1,3)) == 'x**(1/3) + x**(1/2)' + assert x + x**QQ(1,2) == R({(1,): 1, (QQ(1,2),): 1}) + assert repr(x + x**QQ(1,2)) == 'x**(1/2) + x' + assert 1/x**QQ(1,2) + 1/x**QQ(1,3) == R({(-QQ(1,2),): 1, (-QQ(1,3),): 1}) + assert repr(1/x**QQ(1,2) + 1/x**QQ(1,3)) == 'x**(-1/2) + x**(-1/3)' + assert 1/x + x**QQ(1,2) == x**QQ(1,2) + 1/x == R({(-1,): 1, (QQ(1,2),): 1}) + assert repr(1/x + x**QQ(1,2)) == 'x**(-1) + x**(1/2)' + + +def test_puiseux_poly_arit(): + R, x = puiseux_ring('x', QQ) + R2, y = puiseux_ring('y', QQ) + p = x**2 + 1 + assert +p == p + assert -p == -1 - x**2 + assert p + p == 2*p == 2*x**2 + 2 + assert p + 1 == 1 + p == x**2 + 2 + assert p + QQ(1,2) == QQ(1,2) + p == x**2 + QQ(3,2) + assert p - p == 0 + assert p - 1 == -1 + p == x**2 + assert p - QQ(1,2) == -QQ(1,2) + p == x**2 + QQ(1,2) + assert 1 - p == -p + 1 == -x**2 + assert QQ(1,2) - p == -p + QQ(1,2) == -x**2 - QQ(1,2) + assert p * p == x**4 + 2*x**2 + 1 + assert p * 1 == 1 * p == p + assert 2 * p == p * 2 == 2*x**2 + 2 + assert p * QQ(1,2) == QQ(1,2) * p == QQ(1,2)*x**2 + QQ(1,2) + assert x**QQ(1,2) * x**QQ(1,2) == x + raises(ValueError, lambda: x + y) + raises(ValueError, lambda: x - y) + raises(ValueError, lambda: x * y) + raises(TypeError, lambda: x + None) + raises(TypeError, lambda: x - None) + raises(TypeError, lambda: x * None) + raises(TypeError, lambda: None + x) + raises(TypeError, lambda: None - x) + raises(TypeError, lambda: None * x) + + +def test_puiseux_poly_div(): + R, x = puiseux_ring('x', QQ) + R2, y = puiseux_ring('y', QQ) + p = x**2 - 1 + assert p / 1 == p + assert p / QQ(1,2) == 2*p == 2*x**2 - 2 + assert p / x == x - 1/x == R({(1,): 1, (-1,): -1}) + assert 2 / x == 2*x**-1 == R({(-1,): 2}) + assert QQ(1,2) / x == QQ(1,2)*x**-1 == 1/(2*x) == 1/x/2 == R({(-1,): QQ(1,2)}) + raises(ZeroDivisionError, lambda: p / 0) + raises(ValueError, lambda: (x + 1) / (x + 2)) + raises(ValueError, lambda: (x + 1) / (x + 1)) + raises(ValueError, lambda: x / y) + raises(TypeError, lambda: x / None) + raises(TypeError, lambda: None / x) + + +def test_puiseux_poly_pow(): + R, x = puiseux_ring('x', QQ) + Rz, xz = puiseux_ring('x', ZZ) + assert x**0 == 1 == R({(0,): 1}) + assert x**1 == x == R({(1,): 1}) + assert x**2 == x*x == R({(2,): 1}) + assert x**QQ(1,2) == R({(QQ(1,2),): 1}) + assert x**-1 == 1/x == R({(-1,): 1}) + assert x**-QQ(1,2) == 1/x**QQ(1,2) == R({(-QQ(1,2),): 1}) + assert (2*x)**-1 == 1/(2*x) == QQ(1,2)/x == QQ(1,2)*x**-1 == R({(-1,): QQ(1,2)}) + assert 2/x**2 == 2*x**-2 == R({(-2,): 2}) + assert 2/xz**2 == 2*xz**-2 == Rz({(-2,): 2}) + raises(TypeError, lambda: x**None) + raises(ValueError, lambda: (x + 1)**-1) + raises(ValueError, lambda: (x + 1)**QQ(1,2)) + raises(ValueError, lambda: (2*x)**QQ(1,2)) + raises(ValueError, lambda: (2*xz)**-1) + + +def test_puiseux_poly_diff(): + R, x, y = puiseux_ring('x, y', QQ) + assert (x**2 + 1).diff(x) == 2*x + assert (x**2 + 1).diff(y) == 0 + assert (x**2 + y**2).diff(x) == 2*x + assert (x**QQ(1,2) + y**QQ(1,2)).diff(x) == QQ(1,2)*x**-QQ(1,2) + assert ((x*y)**QQ(1,2)).diff(x) == QQ(1,2)*y**QQ(1,2)*x**-QQ(1,2) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_pythonrational.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_pythonrational.py new file mode 100644 index 0000000000000000000000000000000000000000..547a5679626fd3a6165b151364bb506a574bb1db --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_pythonrational.py @@ -0,0 +1,139 @@ +"""Tests for PythonRational type. """ + +from sympy.polys.domains import PythonRational as QQ +from sympy.testing.pytest import raises + +def test_PythonRational__init__(): + assert QQ(0).numerator == 0 + assert QQ(0).denominator == 1 + assert QQ(0, 1).numerator == 0 + assert QQ(0, 1).denominator == 1 + assert QQ(0, -1).numerator == 0 + assert QQ(0, -1).denominator == 1 + + assert QQ(1).numerator == 1 + assert QQ(1).denominator == 1 + assert QQ(1, 1).numerator == 1 + assert QQ(1, 1).denominator == 1 + assert QQ(-1, -1).numerator == 1 + assert QQ(-1, -1).denominator == 1 + + assert QQ(-1).numerator == -1 + assert QQ(-1).denominator == 1 + assert QQ(-1, 1).numerator == -1 + assert QQ(-1, 1).denominator == 1 + assert QQ( 1, -1).numerator == -1 + assert QQ( 1, -1).denominator == 1 + + assert QQ(1, 2).numerator == 1 + assert QQ(1, 2).denominator == 2 + assert QQ(3, 4).numerator == 3 + assert QQ(3, 4).denominator == 4 + + assert QQ(2, 2).numerator == 1 + assert QQ(2, 2).denominator == 1 + assert QQ(2, 4).numerator == 1 + assert QQ(2, 4).denominator == 2 + +def test_PythonRational__hash__(): + assert hash(QQ(0)) == hash(0) + assert hash(QQ(1)) == hash(1) + assert hash(QQ(117)) == hash(117) + +def test_PythonRational__int__(): + assert int(QQ(-1, 4)) == 0 + assert int(QQ( 1, 4)) == 0 + assert int(QQ(-5, 4)) == -1 + assert int(QQ( 5, 4)) == 1 + +def test_PythonRational__float__(): + assert float(QQ(-1, 2)) == -0.5 + assert float(QQ( 1, 2)) == 0.5 + +def test_PythonRational__abs__(): + assert abs(QQ(-1, 2)) == QQ(1, 2) + assert abs(QQ( 1, 2)) == QQ(1, 2) + +def test_PythonRational__pos__(): + assert +QQ(-1, 2) == QQ(-1, 2) + assert +QQ( 1, 2) == QQ( 1, 2) + +def test_PythonRational__neg__(): + assert -QQ(-1, 2) == QQ( 1, 2) + assert -QQ( 1, 2) == QQ(-1, 2) + +def test_PythonRational__add__(): + assert QQ(-1, 2) + QQ( 1, 2) == QQ(0) + assert QQ( 1, 2) + QQ(-1, 2) == QQ(0) + + assert QQ(1, 2) + QQ(1, 2) == QQ(1) + assert QQ(1, 2) + QQ(3, 2) == QQ(2) + assert QQ(3, 2) + QQ(1, 2) == QQ(2) + assert QQ(3, 2) + QQ(3, 2) == QQ(3) + + assert 1 + QQ(1, 2) == QQ(3, 2) + assert QQ(1, 2) + 1 == QQ(3, 2) + +def test_PythonRational__sub__(): + assert QQ(-1, 2) - QQ( 1, 2) == QQ(-1) + assert QQ( 1, 2) - QQ(-1, 2) == QQ( 1) + + assert QQ(1, 2) - QQ(1, 2) == QQ( 0) + assert QQ(1, 2) - QQ(3, 2) == QQ(-1) + assert QQ(3, 2) - QQ(1, 2) == QQ( 1) + assert QQ(3, 2) - QQ(3, 2) == QQ( 0) + + assert 1 - QQ(1, 2) == QQ( 1, 2) + assert QQ(1, 2) - 1 == QQ(-1, 2) + +def test_PythonRational__mul__(): + assert QQ(-1, 2) * QQ( 1, 2) == QQ(-1, 4) + assert QQ( 1, 2) * QQ(-1, 2) == QQ(-1, 4) + + assert QQ(1, 2) * QQ(1, 2) == QQ(1, 4) + assert QQ(1, 2) * QQ(3, 2) == QQ(3, 4) + assert QQ(3, 2) * QQ(1, 2) == QQ(3, 4) + assert QQ(3, 2) * QQ(3, 2) == QQ(9, 4) + + assert 2 * QQ(1, 2) == QQ(1) + assert QQ(1, 2) * 2 == QQ(1) + +def test_PythonRational__truediv__(): + assert QQ(-1, 2) / QQ( 1, 2) == QQ(-1) + assert QQ( 1, 2) / QQ(-1, 2) == QQ(-1) + + assert QQ(1, 2) / QQ(1, 2) == QQ(1) + assert QQ(1, 2) / QQ(3, 2) == QQ(1, 3) + assert QQ(3, 2) / QQ(1, 2) == QQ(3) + assert QQ(3, 2) / QQ(3, 2) == QQ(1) + + assert 2 / QQ(1, 2) == QQ(4) + assert QQ(1, 2) / 2 == QQ(1, 4) + + raises(ZeroDivisionError, lambda: QQ(1, 2) / QQ(0)) + raises(ZeroDivisionError, lambda: QQ(1, 2) / 0) + +def test_PythonRational__pow__(): + assert QQ(1)**10 == QQ(1) + assert QQ(2)**10 == QQ(1024) + + assert QQ(1)**(-10) == QQ(1) + assert QQ(2)**(-10) == QQ(1, 1024) + +def test_PythonRational__eq__(): + assert (QQ(1, 2) == QQ(1, 2)) is True + assert (QQ(1, 2) != QQ(1, 2)) is False + + assert (QQ(1, 2) == QQ(1, 3)) is False + assert (QQ(1, 2) != QQ(1, 3)) is True + +def test_PythonRational__lt_le_gt_ge__(): + assert (QQ(1, 2) < QQ(1, 4)) is False + assert (QQ(1, 2) <= QQ(1, 4)) is False + assert (QQ(1, 2) > QQ(1, 4)) is True + assert (QQ(1, 2) >= QQ(1, 4)) is True + + assert (QQ(1, 4) < QQ(1, 2)) is True + assert (QQ(1, 4) <= QQ(1, 2)) is True + assert (QQ(1, 4) > QQ(1, 2)) is False + assert (QQ(1, 4) >= QQ(1, 2)) is False diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rationaltools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rationaltools.py new file mode 100644 index 0000000000000000000000000000000000000000..3ee0192a3fbc8997347df081663015afd91dd8ad --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rationaltools.py @@ -0,0 +1,63 @@ +"""Tests for tools for manipulation of rational expressions. """ + +from sympy.polys.rationaltools import together + +from sympy.core.mul import Mul +from sympy.core.numbers import Rational +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import symbols +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.trigonometric import sin +from sympy.integrals.integrals import Integral +from sympy.abc import x, y, z + +A, B = symbols('A,B', commutative=False) + + +def test_together(): + assert together(0) == 0 + assert together(1) == 1 + + assert together(x*y*z) == x*y*z + assert together(x + y) == x + y + + assert together(1/x) == 1/x + + assert together(1/x + 1) == (x + 1)/x + assert together(1/x + 3) == (3*x + 1)/x + assert together(1/x + x) == (x**2 + 1)/x + + assert together(1/x + S.Half) == (x + 2)/(2*x) + assert together(S.Half + x/2) == Mul(S.Half, x + 1, evaluate=False) + + assert together(1/x + 2/y) == (2*x + y)/(y*x) + assert together(1/(1 + 1/x)) == x/(1 + x) + assert together(x/(1 + 1/x)) == x**2/(1 + x) + + assert together(1/x + 1/y + 1/z) == (x*y + x*z + y*z)/(x*y*z) + assert together(1/(1 + x + 1/y + 1/z)) == y*z/(y + z + y*z + x*y*z) + + assert together(1/(x*y) + 1/(x*y)**2) == y**(-2)*x**(-2)*(1 + x*y) + assert together(1/(x*y) + 1/(x*y)**4) == y**(-4)*x**(-4)*(1 + x**3*y**3) + assert together(1/(x**7*y) + 1/(x*y)**4) == y**(-4)*x**(-7)*(x**3 + y**3) + + assert together(5/(2 + 6/(3 + 7/(4 + 8/(5 + 9/x))))) == \ + Rational(5, 2)*((171 + 119*x)/(279 + 203*x)) + + assert together(1 + 1/(x + 1)**2) == (1 + (x + 1)**2)/(x + 1)**2 + assert together(1 + 1/(x*(1 + x))) == (1 + x*(1 + x))/(x*(1 + x)) + assert together( + 1/(x*(x + 1)) + 1/(x*(x + 2))) == (3 + 2*x)/(x*(1 + x)*(2 + x)) + assert together(1 + 1/(2*x + 2)**2) == (4*(x + 1)**2 + 1)/(4*(x + 1)**2) + + assert together(sin(1/x + 1/y)) == sin(1/x + 1/y) + assert together(sin(1/x + 1/y), deep=True) == sin((x + y)/(x*y)) + + assert together(1/exp(x) + 1/(x*exp(x))) == (1 + x)/(x*exp(x)) + assert together(1/exp(2*x) + 1/(x*exp(3*x))) == (1 + exp(x)*x)/(x*exp(3*x)) + + assert together(Integral(1/x + 1/y, x)) == Integral((x + y)/(x*y), x) + assert together(Eq(1/x + 1/y, 1 + 1/z)) == Eq((x + y)/(x*y), (z + 1)/z) + + assert together((A*B)**-1 + (B*A)**-1) == (A*B)**-1 + (B*A)**-1 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_ring_series.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_ring_series.py new file mode 100644 index 0000000000000000000000000000000000000000..d983fc99f8ffcf9361d8d069f1d381928ac0aada --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_ring_series.py @@ -0,0 +1,831 @@ +from sympy.polys.domains import ZZ, QQ, EX, RR +from sympy.polys.rings import ring +from sympy.polys.puiseux import puiseux_ring +from sympy.polys.ring_series import (_invert_monoms, rs_integrate, + rs_trunc, rs_mul, rs_square, rs_pow, _has_constant_term, rs_hadamard_exp, + rs_series_from_list, rs_exp, rs_log, rs_newton, rs_series_inversion, + rs_compose_add, rs_asin, _atan, rs_atan, _atanh, rs_atanh, rs_asinh, rs_tan, + rs_cot, rs_sin, rs_cos, rs_cos_sin, rs_sinh, rs_cosh, rs_cosh_sinh, rs_tanh, + _tan1, rs_fun, rs_nth_root, rs_LambertW, rs_series_reversion, rs_is_puiseux, + rs_series) +from sympy.testing.pytest import raises, slow +from sympy.core.symbol import symbols +from sympy.functions import (sin, cos, exp, tan, cot, sinh, cosh, atan, atanh, + asinh, tanh, log, sqrt) +from sympy.core.numbers import Rational, pi +from sympy.core import expand, S + +def is_close(a, b): + tol = 10**(-10) + assert abs(a - b) < tol + + +def test_ring_series1(): + R, x = ring('x', QQ) + p = x**4 + 2*x**3 + 3*x + 4 + assert _invert_monoms(p) == 4*x**4 + 3*x**3 + 2*x + 1 + assert rs_hadamard_exp(p) == x**4/24 + x**3/3 + 3*x + 4 + R, x = ring('x', QQ) + p = x**4 + 2*x**3 + 3*x + 4 + assert rs_integrate(p, x) == x**5/5 + x**4/2 + 3*x**2/2 + 4*x + R, x, y = ring('x, y', QQ) + p = x**2*y**2 + x + 1 + assert rs_integrate(p, x) == x**3*y**2/3 + x**2/2 + x + assert rs_integrate(p, y) == x**2*y**3/3 + x*y + y + + +def test_trunc(): + R, x, y, t = ring('x, y, t', QQ) + p = (y + t*x)**4 + p1 = rs_trunc(p, x, 3) + assert p1 == y**4 + 4*y**3*t*x + 6*y**2*t**2*x**2 + + +def test_mul_trunc(): + R, x, y, t = ring('x, y, t', QQ) + p = 1 + t*x + t*y + for i in range(2): + p = rs_mul(p, p, t, 3) + + assert p == 6*x**2*t**2 + 12*x*y*t**2 + 6*y**2*t**2 + 4*x*t + 4*y*t + 1 + p = 1 + t*x + t*y + t**2*x*y + p1 = rs_mul(p, p, t, 2) + assert p1 == 1 + 2*t*x + 2*t*y + R1, z = ring('z', QQ) + raises(ValueError, lambda: rs_mul(p, z, x, 2)) + + p1 = 2 + 2*x + 3*x**2 + p2 = 3 + x**2 + assert rs_mul(p1, p2, x, 4) == 2*x**3 + 11*x**2 + 6*x + 6 + + +def test_square_trunc(): + R, x, y, t = ring('x, y, t', QQ) + p = (1 + t*x + t*y)*2 + p1 = rs_mul(p, p, x, 3) + p2 = rs_square(p, x, 3) + assert p1 == p2 + p = 1 + x + x**2 + x**3 + assert rs_square(p, x, 4) == 4*x**3 + 3*x**2 + 2*x + 1 + + +def test_pow_trunc(): + R, x, y, z = ring('x, y, z', QQ) + p0 = y + x*z + p = p0**16 + for xx in (x, y, z): + p1 = rs_trunc(p, xx, 8) + p2 = rs_pow(p0, 16, xx, 8) + assert p1 == p2 + + p = 1 + x + p1 = rs_pow(p, 3, x, 2) + assert p1 == 1 + 3*x + assert rs_pow(p, 0, x, 2) == 1 + assert rs_pow(p, -2, x, 2) == 1 - 2*x + p = x + y + assert rs_pow(p, 3, y, 3) == x**3 + 3*x**2*y + 3*x*y**2 + assert rs_pow(1 + x, Rational(2, 3), x, 4) == 4*x**3/81 - x**2/9 + x*Rational(2, 3) + 1 + + +def test_has_constant_term(): + R, x, y, z = ring('x, y, z', QQ) + p = y + x*z + assert _has_constant_term(p, x) + p = x + x**4 + assert not _has_constant_term(p, x) + p = 1 + x + x**4 + assert _has_constant_term(p, x) + p = x + y + x*z + + +def test_inversion(): + R, x = ring('x', QQ) + p = 2 + x + 2*x**2 + n = 5 + p1 = rs_series_inversion(p, x, n) + assert rs_trunc(p*p1, x, n) == 1 + R, x, y = ring('x, y', QQ) + p = 2 + x + 2*x**2 + y*x + x**2*y + p1 = rs_series_inversion(p, x, n) + assert rs_trunc(p*p1, x, n) == 1 + + R, x, y = ring('x, y', QQ) + p = 1 + x + y + raises(NotImplementedError, lambda: rs_series_inversion(p, x, 4)) + p = R.zero + raises(ZeroDivisionError, lambda: rs_series_inversion(p, x, 3)) + + R, x = ring('x', ZZ) + p = 2 + x + raises(ValueError, lambda: rs_series_inversion(p, x, 3)) + + +def test_series_reversion(): + R, x, y = ring('x, y', QQ) + + p = rs_tan(x, x, 10) + assert rs_series_reversion(p, x, 8, y) == rs_atan(y, y, 8) + + p = rs_sin(x, x, 10) + assert rs_series_reversion(p, x, 8, y) == 5*y**7/112 + 3*y**5/40 + \ + y**3/6 + y + + +def test_series_from_list(): + R, x = ring('x', QQ) + p = 1 + 2*x + x**2 + 3*x**3 + c = [1, 2, 0, 4, 4] + r = rs_series_from_list(p, c, x, 5) + pc = R.from_list(list(reversed(c))) + r1 = rs_trunc(pc.compose(x, p), x, 5) + assert r == r1 + R, x, y = ring('x, y', QQ) + c = [1, 3, 5, 7] + p1 = rs_series_from_list(x + y, c, x, 3, concur=0) + p2 = rs_trunc((1 + 3*(x+y) + 5*(x+y)**2 + 7*(x+y)**3), x, 3) + assert p1 == p2 + + R, x = ring('x', QQ) + h = 25 + p = rs_exp(x, x, h) - 1 + p1 = rs_series_from_list(p, c, x, h) + p2 = 0 + for i, cx in enumerate(c): + p2 += cx*rs_pow(p, i, x, h) + assert p1 == p2 + + +def test_log(): + R, x = ring('x', QQ) + p = 1 + x + assert rs_log(p, x, 4) == x - x**2/2 + x**3/3 + p = 1 + x +2*x**2/3 + p1 = rs_log(p, x, 9) + assert p1 == -17*x**8/648 + 13*x**7/189 - 11*x**6/162 - x**5/45 + \ + 7*x**4/36 - x**3/3 + x**2/6 + x + p2 = rs_series_inversion(p, x, 9) + p3 = rs_log(p2, x, 9) + assert p3 == -p1 + + R, x, y = ring('x, y', QQ) + p = 1 + x + 2*y*x**2 + p1 = rs_log(p, x, 6) + assert p1 == (4*x**5*y**2 - 2*x**5*y - 2*x**4*y**2 + x**5/5 + 2*x**4*y - + x**4/4 - 2*x**3*y + x**3/3 + 2*x**2*y - x**2/2 + x) + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', EX) + assert rs_log(x + a, x, 5) == -EX(1/(4*a**4))*x**4 + EX(1/(3*a**3))*x**3 \ + - EX(1/(2*a**2))*x**2 + EX(1/a)*x + EX(log(a)) + assert rs_log(x + x**2*y + a, x, 4) == -EX(a**(-2))*x**3*y + \ + EX(1/(3*a**3))*x**3 + EX(1/a)*x**2*y - EX(1/(2*a**2))*x**2 + \ + EX(1/a)*x + EX(log(a)) + + p = x + x**2 + 3 + assert rs_log(p, x, 10).compose(x, 5) == EX(log(3) + Rational(19281291595, 9920232)) + + +def test_exp(): + R, x = ring('x', QQ) + p = x + x**4 + for h in [10, 30]: + q = rs_series_inversion(1 + p, x, h) - 1 + p1 = rs_exp(q, x, h) + q1 = rs_log(p1, x, h) + assert q1 == q + p1 = rs_exp(p, x, 30) + assert p1.coeff(x**29) == QQ(74274246775059676726972369, 353670479749588078181744640000) + prec = 21 + p = rs_log(1 + x, x, prec) + p1 = rs_exp(p, x, prec) + assert p1 == x + 1 + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', QQ[exp(a), a]) + assert rs_exp(x + a, x, 5) == exp(a)*x**4/24 + exp(a)*x**3/6 + \ + exp(a)*x**2/2 + exp(a)*x + exp(a) + assert rs_exp(x + x**2*y + a, x, 5) == exp(a)*x**4*y**2/2 + \ + exp(a)*x**4*y/2 + exp(a)*x**4/24 + exp(a)*x**3*y + \ + exp(a)*x**3/6 + exp(a)*x**2*y + exp(a)*x**2/2 + exp(a)*x + exp(a) + + R, x, y = ring('x, y', EX) + assert rs_exp(x + a, x, 5) == EX(exp(a)/24)*x**4 + EX(exp(a)/6)*x**3 + \ + EX(exp(a)/2)*x**2 + EX(exp(a))*x + EX(exp(a)) + assert rs_exp(x + x**2*y + a, x, 5) == EX(exp(a)/2)*x**4*y**2 + \ + EX(exp(a)/2)*x**4*y + EX(exp(a)/24)*x**4 + EX(exp(a))*x**3*y + \ + EX(exp(a)/6)*x**3 + EX(exp(a))*x**2*y + EX(exp(a)/2)*x**2 + \ + EX(exp(a))*x + EX(exp(a)) + + +def test_newton(): + R, x = ring('x', QQ) + p = x**2 - 2 + r = rs_newton(p, x, 4) + assert r == 8*x**4 + 4*x**2 + 2 + + +def test_compose_add(): + R, x = ring('x', QQ) + p1 = x**3 - 1 + p2 = x**2 - 2 + assert rs_compose_add(p1, p2) == x**6 - 6*x**4 - 2*x**3 + 12*x**2 - 12*x - 7 + + +def test_fun(): + R, x, y = ring('x, y', QQ) + p = x*y + x**2*y**3 + x**5*y + assert rs_fun(p, rs_tan, x, 10) == rs_tan(p, x, 10) + assert rs_fun(p, _tan1, x, 10) == _tan1(p, x, 10) + + +def test_nth_root(): + R, x, y = puiseux_ring('x, y', QQ) + assert rs_nth_root(1 + x**2*y, 4, x, 10) == -77*x**8*y**4/2048 + \ + 7*x**6*y**3/128 - 3*x**4*y**2/32 + x**2*y/4 + 1 + assert rs_nth_root(1 + x*y + x**2*y**3, 3, x, 5) == -x**4*y**6/9 + \ + 5*x**4*y**5/27 - 10*x**4*y**4/243 - 2*x**3*y**4/9 + 5*x**3*y**3/81 + \ + x**2*y**3/3 - x**2*y**2/9 + x*y/3 + 1 + assert rs_nth_root(8*x, 3, x, 3) == 2*x**QQ(1, 3) + assert rs_nth_root(8*x + x**2 + x**3, 3, x, 3) == x**QQ(4,3)/12 + 2*x**QQ(1,3) + r = rs_nth_root(8*x + x**2*y + x**3, 3, x, 4) + assert r == -x**QQ(7,3)*y**2/288 + x**QQ(7,3)/12 + x**QQ(4,3)*y/12 + 2*x**QQ(1,3) + + # Constant term in series + a = symbols('a') + R, x, y = puiseux_ring('x, y', EX) + assert rs_nth_root(x + EX(a), 3, x, 4) == EX(5/(81*a**QQ(8, 3)))*x**3 - \ + EX(1/(9*a**QQ(5, 3)))*x**2 + EX(1/(3*a**QQ(2, 3)))*x + EX(a**QQ(1, 3)) + assert rs_nth_root(x**QQ(2, 3) + x**2*y + 5, 2, x, 3) == -EX(sqrt(5)/100)*\ + x**QQ(8, 3)*y - EX(sqrt(5)/16000)*x**QQ(8, 3) + EX(sqrt(5)/10)*x**2*y + \ + EX(sqrt(5)/2000)*x**2 - EX(sqrt(5)/200)*x**QQ(4, 3) + \ + EX(sqrt(5)/10)*x**QQ(2, 3) + EX(sqrt(5)) + + +def test_atan(): + R, x, y = ring('x, y', QQ) + assert rs_atan(x, x, 9) == -x**7/7 + x**5/5 - x**3/3 + x + assert rs_atan(x*y + x**2*y**3, x, 9) == 2*x**8*y**11 - x**8*y**9 + \ + 2*x**7*y**9 - x**7*y**7/7 - x**6*y**9/3 + x**6*y**7 - x**5*y**7 + \ + x**5*y**5/5 - x**4*y**5 - x**3*y**3/3 + x**2*y**3 + x*y + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', EX) + assert rs_atan(x + a, x, 5) == -EX((a**3 - a)/(a**8 + 4*a**6 + 6*a**4 + \ + 4*a**2 + 1))*x**4 + EX((3*a**2 - 1)/(3*a**6 + 9*a**4 + \ + 9*a**2 + 3))*x**3 - EX(a/(a**4 + 2*a**2 + 1))*x**2 + \ + EX(1/(a**2 + 1))*x + EX(atan(a)) + assert rs_atan(x + x**2*y + a, x, 4) == -EX(2*a/(a**4 + 2*a**2 + 1)) \ + *x**3*y + EX((3*a**2 - 1)/(3*a**6 + 9*a**4 + 9*a**2 + 3))*x**3 + \ + EX(1/(a**2 + 1))*x**2*y - EX(a/(a**4 + 2*a**2 + 1))*x**2 + EX(1/(a**2 \ + + 1))*x + EX(atan(a)) + + # Test for _atan faster for small and univariate series + R, x = ring('x', QQ) + p = x**2 + 2*x + assert _atan(p, x, 5) == rs_atan(p, x, 5) + + R, x = ring('x', EX) + p = x**2 + 2*x + assert _atan(p, x, 9) == rs_atan(p, x, 9) + + +def test_asin(): + R, x, y = ring('x, y', QQ) + assert rs_asin(x + x*y, x, 5) == x**3*y**3/6 + x**3*y**2/2 + x**3*y/2 + \ + x**3/6 + x*y + x + assert rs_asin(x*y + x**2*y**3, x, 6) == x**5*y**7/2 + 3*x**5*y**5/40 + \ + x**4*y**5/2 + x**3*y**3/6 + x**2*y**3 + x*y + + +def test_tan(): + R, x, y = ring('x, y', QQ) + assert rs_tan(x, x, 9) == x + x**3/3 + QQ(2,15)*x**5 + QQ(17,315)*x**7 + assert rs_tan(x*y + x**2*y**3, x, 9) == 4*x**8*y**11/3 + 17*x**8*y**9/45 + \ + 4*x**7*y**9/3 + 17*x**7*y**7/315 + x**6*y**9/3 + 2*x**6*y**7/3 + \ + x**5*y**7 + 2*x**5*y**5/15 + x**4*y**5 + x**3*y**3/3 + x**2*y**3 + x*y + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', QQ[tan(a), a]) + assert rs_tan(x + a, x, 5) == (tan(a)**5 + 5*tan(a)**3/3 + + 2*tan(a)/3)*x**4 + (tan(a)**4 + 4*tan(a)**2/3 + Rational(1, 3))*x**3 + \ + (tan(a)**3 + tan(a))*x**2 + (tan(a)**2 + 1)*x + tan(a) + assert rs_tan(x + x**2*y + a, x, 4) == (2*tan(a)**3 + 2*tan(a))*x**3*y + \ + (tan(a)**4 + Rational(4, 3)*tan(a)**2 + Rational(1, 3))*x**3 + (tan(a)**2 + 1)*x**2*y + \ + (tan(a)**3 + tan(a))*x**2 + (tan(a)**2 + 1)*x + tan(a) + + R, x, y = ring('x, y', EX) + assert rs_tan(x + a, x, 5) == EX(tan(a)**5 + 5*tan(a)**3/3 + + 2*tan(a)/3)*x**4 + EX(tan(a)**4 + 4*tan(a)**2/3 + EX(1)/3)*x**3 + \ + EX(tan(a)**3 + tan(a))*x**2 + EX(tan(a)**2 + 1)*x + EX(tan(a)) + assert rs_tan(x + x**2*y + a, x, 4) == EX(2*tan(a)**3 + + 2*tan(a))*x**3*y + EX(tan(a)**4 + 4*tan(a)**2/3 + EX(1)/3)*x**3 + \ + EX(tan(a)**2 + 1)*x**2*y + EX(tan(a)**3 + tan(a))*x**2 + \ + EX(tan(a)**2 + 1)*x + EX(tan(a)) + + p = x + x**2 + 5 + assert rs_atan(p, x, 10).compose(x, 10) == EX(atan(5) + S(67701870330562640) / \ + 668083460499) + + +def test_cot(): + R, x, y = puiseux_ring('x, y', QQ) + assert rs_cot(x**6 + x**7, x, 8) == x**(-6) - x**(-5) + x**(-4) - \ + x**(-3) + x**(-2) - x**(-1) + 1 - x + x**2 - x**3 + x**4 - x**5 + \ + 2*x**6/3 - 4*x**7/3 + assert rs_cot(x + x**2*y, x, 5) == -x**4*y**5 - x**4*y/15 + x**3*y**4 - \ + x**3/45 - x**2*y**3 - x**2*y/3 + x*y**2 - x/3 - y + x**(-1) + + +def test_sin(): + R, x, y = ring('x, y', QQ) + assert rs_sin(x, x, 9) == x - x**3/6 + x**5/120 - x**7/5040 + assert rs_sin(x*y + x**2*y**3, x, 9) == x**8*y**11/12 - \ + x**8*y**9/720 + x**7*y**9/12 - x**7*y**7/5040 - x**6*y**9/6 + \ + x**6*y**7/24 - x**5*y**7/2 + x**5*y**5/120 - x**4*y**5/2 - \ + x**3*y**3/6 + x**2*y**3 + x*y + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', QQ[sin(a), cos(a), a]) + assert rs_sin(x + a, x, 5) == sin(a)*x**4/24 - cos(a)*x**3/6 - \ + sin(a)*x**2/2 + cos(a)*x + sin(a) + assert rs_sin(x + x**2*y + a, x, 5) == -sin(a)*x**4*y**2/2 - \ + cos(a)*x**4*y/2 + sin(a)*x**4/24 - sin(a)*x**3*y - cos(a)*x**3/6 + \ + cos(a)*x**2*y - sin(a)*x**2/2 + cos(a)*x + sin(a) + + R, x, y = ring('x, y', EX) + assert rs_sin(x + a, x, 5) == EX(sin(a)/24)*x**4 - EX(cos(a)/6)*x**3 - \ + EX(sin(a)/2)*x**2 + EX(cos(a))*x + EX(sin(a)) + assert rs_sin(x + x**2*y + a, x, 5) == -EX(sin(a)/2)*x**4*y**2 - \ + EX(cos(a)/2)*x**4*y + EX(sin(a)/24)*x**4 - EX(sin(a))*x**3*y - \ + EX(cos(a)/6)*x**3 + EX(cos(a))*x**2*y - EX(sin(a)/2)*x**2 + \ + EX(cos(a))*x + EX(sin(a)) + + +def test_cos(): + R, x, y = ring('x, y', QQ) + assert rs_cos(x, x, 9) == 1 - x**2/2 + x**4/24 - x**6/720 + x**8/40320 + assert rs_cos(x*y + x**2*y**3, x, 9) == x**8*y**12/24 - \ + x**8*y**10/48 + x**8*y**8/40320 + x**7*y**10/6 - \ + x**7*y**8/120 + x**6*y**8/4 - x**6*y**6/720 + x**5*y**6/6 - \ + x**4*y**6/2 + x**4*y**4/24 - x**3*y**4 - x**2*y**2/2 + 1 + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', QQ[sin(a), cos(a), a]) + assert rs_cos(x + a, x, 5) == cos(a)*x**4/24 + sin(a)*x**3/6 - \ + cos(a)*x**2/2 - sin(a)*x + cos(a) + assert rs_cos(x + x**2*y + a, x, 5) == -cos(a)*x**4*y**2/2 + \ + sin(a)*x**4*y/2 + cos(a)*x**4/24 - cos(a)*x**3*y + sin(a)*x**3/6 - \ + sin(a)*x**2*y - cos(a)*x**2/2 - sin(a)*x + cos(a) + + R, x, y = ring('x, y', EX) + assert rs_cos(x + a, x, 5) == EX(cos(a)/24)*x**4 + EX(sin(a)/6)*x**3 - \ + EX(cos(a)/2)*x**2 - EX(sin(a))*x + EX(cos(a)) + assert rs_cos(x + x**2*y + a, x, 5) == -EX(cos(a)/2)*x**4*y**2 + \ + EX(sin(a)/2)*x**4*y + EX(cos(a)/24)*x**4 - EX(cos(a))*x**3*y + \ + EX(sin(a)/6)*x**3 - EX(sin(a))*x**2*y - EX(cos(a)/2)*x**2 - \ + EX(sin(a))*x + EX(cos(a)) + + +def test_cos_sin(): + R, x, y = ring('x, y', QQ) + c, s = rs_cos_sin(x, x, 9) + assert c == rs_cos(x, x, 9) + assert s == rs_sin(x, x, 9) + c, s = rs_cos_sin(x + x*y, x, 5) + assert c == rs_cos(x + x*y, x, 5) + assert s == rs_sin(x + x*y, x, 5) + + # constant term in series + c, s = rs_cos_sin(1 + x + x**2, x, 5) + assert c == rs_cos(1 + x + x**2, x, 5) + assert s == rs_sin(1 + x + x**2, x, 5) + + a = symbols('a') + R, x, y = ring('x, y', QQ[sin(a), cos(a), a]) + c, s = rs_cos_sin(x + a, x, 5) + assert c == rs_cos(x + a, x, 5) + assert s == rs_sin(x + a, x, 5) + + R, x, y = ring('x, y', EX) + c, s = rs_cos_sin(x + a, x, 5) + assert c == rs_cos(x + a, x, 5) + assert s == rs_sin(x + a, x, 5) + + +def test_atanh(): + R, x, y = ring('x, y', QQ) + assert rs_atanh(x, x, 9) == x + x**3/3 + x**5/5 + x**7/7 + assert rs_atanh(x*y + x**2*y**3, x, 9) == 2*x**8*y**11 + x**8*y**9 + \ + 2*x**7*y**9 + x**7*y**7/7 + x**6*y**9/3 + x**6*y**7 + x**5*y**7 + \ + x**5*y**5/5 + x**4*y**5 + x**3*y**3/3 + x**2*y**3 + x*y + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', EX) + assert rs_atanh(x + a, x, 5) == EX((a**3 + a)/(a**8 - 4*a**6 + 6*a**4 - \ + 4*a**2 + 1))*x**4 - EX((3*a**2 + 1)/(3*a**6 - 9*a**4 + \ + 9*a**2 - 3))*x**3 + EX(a/(a**4 - 2*a**2 + 1))*x**2 - EX(1/(a**2 - \ + 1))*x + EX(atanh(a)) + assert rs_atanh(x + x**2*y + a, x, 4) == EX(2*a/(a**4 - 2*a**2 + \ + 1))*x**3*y - EX((3*a**2 + 1)/(3*a**6 - 9*a**4 + 9*a**2 - 3))*x**3 - \ + EX(1/(a**2 - 1))*x**2*y + EX(a/(a**4 - 2*a**2 + 1))*x**2 - \ + EX(1/(a**2 - 1))*x + EX(atanh(a)) + + p = x + x**2 + 5 + assert rs_atanh(p, x, 10).compose(x, 10) == EX(Rational(-733442653682135, 5079158784) \ + + atanh(5)) + + # Test for _atanh faster for small and univariate series + R,x = ring('x', QQ) + p = x**2 + 2*x + assert _atanh(p, x, 5) == rs_atanh(p, x, 5) + + R,x = ring('x', EX) + p = x**2 + 2*x + assert _atanh(p, x, 9) == rs_atanh(p, x, 9) + + +def test_asinh(): + R, x, y = ring('x, y', QQ) + assert rs_asinh(x, x, 9) == -5/112*x**7 + 3/40*x**5 - 1/6*x**3 + x + assert rs_asinh(x*y + x**2*y**3, x, 9) == 3/4*x**8*y**11 - 5/16*x**8*y**9 + \ + 3/4*x**7*y**9 - 5/112*x**7*y**7 - 1/6*x**6*y**9 + 3/8*x**6*y**7 - 1/2*x \ + **5*y**7 + 3/40*x**5*y**5 - 1/2*x**4*y**5 - 1/6*x**3*y**3 + x**2*y**3 + x*y + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', EX) + assert rs_asinh(x + a, x, 3) == -EX(a/(2*a**2*sqrt(a**2 + 1) + 2*sqrt(a**2 + 1))) \ + *x**2 + EX(1/sqrt(a**2 + 1))*x + EX(asinh(a)) + assert rs_asinh(x + x**2*y + a, x, 3) == EX(1/sqrt(a**2 + 1))*x**2*y - EX(a/(2*a**2 \ + *sqrt(a**2 + 1) + 2*sqrt(a**2 + 1)))*x**2 + EX(1/sqrt(a**2 + 1))*x + EX(asinh(a)) + + p = x + x ** 2 + 5 + assert rs_asinh(p, x, 10).compose(x, 10) == EX(asinh(5) + 4643789843094995*sqrt(26)/\ + 205564141692) + + +def test_sinh(): + R, x, y = ring('x, y', QQ) + assert rs_sinh(x, x, 9) == x + x**3/6 + x**5/120 + x**7/5040 + assert rs_sinh(x*y + x**2*y**3, x, 9) == x**8*y**11/12 + \ + x**8*y**9/720 + x**7*y**9/12 + x**7*y**7/5040 + x**6*y**9/6 + \ + x**6*y**7/24 + x**5*y**7/2 + x**5*y**5/120 + x**4*y**5/2 + \ + x**3*y**3/6 + x**2*y**3 + x*y + + # constant term in series + a = symbols('a') + R, x, y = ring('x, y', QQ[sinh(a), cosh(a), a]) + assert rs_sinh(x + a, x, 5) == 1/24*x**4*(sinh(a)) + 1/6*x**3*(cosh(a)) + 1/\ + 2*x**2*(sinh(a)) + x*(cosh(a)) + (sinh(a)) + assert rs_sinh(x + x**2*y + a, x, 5) == 1/2*(sinh(a))*x**4*y**2 + 1/2*(cosh(a))\ + *x**4*y + 1/24*(sinh(a))*x**4 + (sinh(a))*x**3*y + 1/6*(cosh(a))*x**3 + \ + (cosh(a))*x**2*y + 1/2*(sinh(a))*x**2 + (cosh(a))*x + (sinh(a)) + + R, x, y = ring('x, y', EX) + assert rs_sinh(x + a, x, 5) == EX(sinh(a)/24)*x**4 + EX(cosh(a)/6)*x**3 + \ + EX(sinh(a)/2)*x**2 + EX(cosh(a))*x + EX(sinh(a)) + assert rs_sinh(x + x**2*y + a, x, 5) == EX(sinh(a)/2)*x**4*y**2 + EX(cosh(a)/\ + 2)*x**4*y + EX(sinh(a)/24)*x**4 + EX(sinh(a))*x**3*y + EX(cosh(a)/6)*x**3 \ + + EX(cosh(a))*x**2*y + EX(sinh(a)/2)*x**2 + EX(cosh(a))*x + EX(sinh(a)) + + +def test_cosh(): + R, x, y = ring('x, y', QQ) + assert rs_cosh(x, x, 9) == 1 + x**2/2 + x**4/24 + x**6/720 + x**8/40320 + assert rs_cosh(x*y + x**2*y**3, x, 9) == x**8*y**12/24 + \ + x**8*y**10/48 + x**8*y**8/40320 + x**7*y**10/6 + \ + x**7*y**8/120 + x**6*y**8/4 + x**6*y**6/720 + x**5*y**6/6 + \ + x**4*y**6/2 + x**4*y**4/24 + x**3*y**4 + x**2*y**2/2 + 1 + + # constant term in series + a = symbols('a') + R, x, y = ring('x, y', QQ[sinh(a), cosh(a), a]) + assert rs_cosh(x + a, x, 5) == 1/24*(cosh(a))*x**4 + 1/6*(sinh(a))*x**3 + \ + 1/2*(cosh(a))*x**2 + (sinh(a))*x + (cosh(a)) + assert rs_cosh(x + x**2*y + a, x, 5) == 1/2*(cosh(a))*x**4*y**2 + 1/2*(sinh(a))\ + *x**4*y + 1/24*(cosh(a))*x**4 + (cosh(a))*x**3*y + 1/6*(sinh(a))*x**3 + \ + (sinh(a))*x**2*y + 1/2*(cosh(a))*x**2 + (sinh(a))*x + (cosh(a)) + R, x, y = ring('x, y', EX) + assert rs_cosh(x + a, x, 5) == EX(cosh(a)/24)*x**4 + EX(sinh(a)/6)*x**3 + \ + EX(cosh(a)/2)*x**2 + EX(sinh(a))*x + EX(cosh(a)) + assert rs_cosh(x + x**2*y + a, x, 5) == EX(cosh(a)/2)*x**4*y**2 + EX(sinh(a)/\ + 2)*x**4*y + EX(cosh(a)/24)*x**4 + EX(cosh(a))*x**3*y + EX(sinh(a)/6)*x**3 \ + + EX(sinh(a))*x**2*y + EX(cosh(a)/2)*x**2 + EX(sinh(a))*x + EX(cosh(a)) + + +def test_cosh_sinh(): + R, x, y = ring('x, y', QQ) + ch, sh = rs_cosh_sinh(x, x, 9) + assert ch == rs_cosh(x, x, 9) + assert sh == rs_sinh(x, x, 9) + ch, sh = rs_cosh_sinh(x + x*y, x, 5) + assert ch == rs_cosh(x + x*y, x, 5) + assert sh == rs_sinh(x + x*y, x, 5) + + # constant term in series + c, s = rs_cosh_sinh(1 + x + x**2, x, 5) + assert c == rs_cosh(1 + x + x**2, x, 5) + assert s == rs_sinh(1 + x + x**2, x, 5) + + a = symbols('a') + R, x, y = ring('x, y', QQ[sinh(a), cosh(a), a]) + ch, sh = rs_cosh_sinh(x + a, x, 5) + assert ch == rs_cosh(x + a, x, 5) + assert sh == rs_sinh(x + a, x, 5) + R, x, y = ring('x, y', EX) + ch, sh = rs_cosh_sinh(x + a, x, 5) + assert ch == rs_cosh(x + a, x, 5) + assert sh == rs_sinh(x + a, x, 5) + + +def test_tanh(): + R, x, y = ring('x, y', QQ) + assert rs_tanh(x, x, 9) == x - QQ(1,3)*x**3 + QQ(2,15)*x**5 - QQ(17,315)*x**7 + assert rs_tanh(x*y + x**2*y**3, x, 9) == 4*x**8*y**11/3 - \ + 17*x**8*y**9/45 + 4*x**7*y**9/3 - 17*x**7*y**7/315 - x**6*y**9/3 + \ + 2*x**6*y**7/3 - x**5*y**7 + 2*x**5*y**5/15 - x**4*y**5 - \ + x**3*y**3/3 + x**2*y**3 + x*y + + # Constant term in series + a = symbols('a') + R, x, y = ring('x, y', EX) + assert rs_tanh(x + a, x, 5) == EX(tanh(a)**5 - 5*tanh(a)**3/3 + + 2*tanh(a)/3)*x**4 + EX(-tanh(a)**4 + 4*tanh(a)**2/3 - QQ(1, 3))*x**3 + \ + EX(tanh(a)**3 - tanh(a))*x**2 + EX(-tanh(a)**2 + 1)*x + EX(tanh(a)) + + p = rs_tanh(x + x**2*y + a, x, 4) + assert (p.compose(x, 10)).compose(y, 5) == EX(-1000*tanh(a)**4 + \ + 10100*tanh(a)**3 + 2470*tanh(a)**2/3 - 10099*tanh(a) + QQ(530, 3)) + + +def test_RR(): + rs_funcs = [rs_sin, rs_cos, rs_tan, rs_cot, rs_atan, rs_tanh] + sympy_funcs = [sin, cos, tan, cot, atan, tanh] + R, x, y = ring('x, y', RR) + a = symbols('a') + for rs_func, sympy_func in zip(rs_funcs, sympy_funcs): + p = rs_func(2 + x, x, 5).compose(x, 5) + q = sympy_func(2 + a).series(a, 0, 5).removeO() + is_close(p.as_expr(), q.subs(a, 5).n()) + + p = rs_nth_root(2 + x, 5, x, 5).compose(x, 5) + q = ((2 + a)**QQ(1, 5)).series(a, 0, 5).removeO() + is_close(p.as_expr(), q.subs(a, 5).n()) + + +def test_is_regular(): + R, x, y = puiseux_ring('x, y', QQ) + p = 1 + 2*x + x**2 + 3*x**3 + assert not rs_is_puiseux(p, x) + + p = x + x**QQ(1,5)*y + assert rs_is_puiseux(p, x) + assert not rs_is_puiseux(p, y) + + p = x + x**2*y**QQ(1,5)*y + assert not rs_is_puiseux(p, x) + + +def test_puiseux(): + R, x, y = puiseux_ring('x, y', QQ) + p = x**QQ(2,5) + x**QQ(2,3) + x + + r = rs_series_inversion(p, x, 1) + r1 = -x**QQ(14,15) + x**QQ(4,5) - 3*x**QQ(11,15) + x**QQ(2,3) + \ + 2*x**QQ(7,15) - x**QQ(2,5) - x**QQ(1,5) + x**QQ(2,15) - x**QQ(-2,15) \ + + x**QQ(-2,5) + assert r == r1 + + r = rs_nth_root(1 + p, 3, x, 1) + assert r == -x**QQ(4,5)/9 + x**QQ(2,3)/3 + x**QQ(2,5)/3 + 1 + + r = rs_log(1 + p, x, 1) + assert r == -x**QQ(4,5)/2 + x**QQ(2,3) + x**QQ(2,5) + + r = rs_LambertW(p, x, 1) + assert r == -x**QQ(4,5) + x**QQ(2,3) + x**QQ(2,5) + + p1 = x + x**QQ(1,5)*y + r = rs_exp(p1, x, 1) + assert r == x**QQ(4,5)*y**4/24 + x**QQ(3,5)*y**3/6 + x**QQ(2,5)*y**2/2 + \ + x**QQ(1,5)*y + 1 + + r = rs_atan(p, x, 2) + assert r == -x**QQ(9,5) - x**QQ(26,15) - x**QQ(22,15) - x**QQ(6,5)/3 + \ + x + x**QQ(2,3) + x**QQ(2,5) + + r = rs_atan(p1, x, 2) + assert r == x**QQ(9,5)*y**9/9 + x**QQ(9,5)*y**4 - x**QQ(7,5)*y**7/7 - \ + x**QQ(7,5)*y**2 + x*y**5/5 + x - x**QQ(3,5)*y**3/3 + x**QQ(1,5)*y + + r = rs_tan(p, x, 2) + assert r == x**QQ(2,5) + x**QQ(2,3) + x + QQ(1,3)*x**QQ(6,5) + x**QQ(22,15)\ + + x**QQ(26,15) + x**QQ(9,5) + + r = rs_sin(p, x, 2) + assert r == x**QQ(2,5) + x**QQ(2,3) + x - QQ(1,6)*x**QQ(6,5) - QQ(1,2)*x**\ + QQ(22,15) - QQ(1,2)*x**QQ(26,15) - QQ(1,2)*x**QQ(9,5) + + r = rs_cos(p, x, 2) + assert r == 1 - QQ(1,2)*x**QQ(4,5) - x**QQ(16,15) - QQ(1,2)*x**QQ(4,3) - \ + x**QQ(7,5) + QQ(1,24)*x**QQ(8,5) - x**QQ(5,3) + QQ(1,6)*x**QQ(28,15) + + r = rs_asin(p, x, 2) + assert r == x**QQ(9,5)/2 + x**QQ(26,15)/2 + x**QQ(22,15)/2 + \ + x**QQ(6,5)/6 + x + x**QQ(2,3) + x**QQ(2,5) + + r = rs_cot(p, x, 1) + assert r == -x**QQ(14,15) + x**QQ(4,5) - 3*x**QQ(11,15) + \ + 2*x**QQ(2,3)/3 + 2*x**QQ(7,15) - 4*x**QQ(2,5)/3 - x**QQ(1,5) + \ + x**QQ(2,15) - x**QQ(-2,15) + x**QQ(-2,5) + + r = rs_cos_sin(p, x, 2) + assert r[0] == x**QQ(28,15)/6 - x**QQ(5,3) + x**QQ(8,5)/24 - x**QQ(7,5) - \ + x**QQ(4,3)/2 - x**QQ(16,15) - x**QQ(4,5)/2 + 1 + assert r[1] == -x**QQ(9,5)/2 - x**QQ(26,15)/2 - x**QQ(22,15)/2 - \ + x**QQ(6,5)/6 + x + x**QQ(2,3) + x**QQ(2,5) + + r = rs_atanh(p, x, 2) + assert r == x**QQ(9,5) + x**QQ(26,15) + x**QQ(22,15) + x**QQ(6,5)/3 + x + \ + x**QQ(2,3) + x**QQ(2,5) + + r = rs_asinh(p, x, 2) + assert r == x**QQ(2,5) + x**QQ(2,3) + x - QQ(1,6)*x**QQ(6,5) - QQ(1,2)*x**\ + QQ(22,15) - QQ(1,2)*x**QQ(26,15) - QQ(1,2)*x**QQ(9,5) + + r = rs_cosh(p, x, 2) + assert r == x**QQ(28,15)/6 + x**QQ(5,3) + x**QQ(8,5)/24 + x**QQ(7,5) + \ + x**QQ(4,3)/2 + x**QQ(16,15) + x**QQ(4,5)/2 + 1 + + r = rs_sinh(p, x, 2) + assert r == x**QQ(9,5)/2 + x**QQ(26,15)/2 + x**QQ(22,15)/2 + \ + x**QQ(6,5)/6 + x + x**QQ(2,3) + x**QQ(2,5) + + r = rs_cosh_sinh(p, x, 2) + assert r[0] == x**QQ(28,15)/6 + x**QQ(5,3) + x**QQ(8,5)/24 + x**QQ(7,5) + \ + x**QQ(4,3)/2 + x**QQ(16,15) + x**QQ(4,5)/2 + 1 + assert r[1] == x**QQ(9,5)/2 + x**QQ(26,15)/2 + x**QQ(22,15)/2 + \ + x**QQ(6,5)/6 + x + x**QQ(2,3) + x**QQ(2,5) + + r = rs_tanh(p, x, 2) + assert r == -x**QQ(9,5) - x**QQ(26,15) - x**QQ(22,15) - x**QQ(6,5)/3 + \ + x + x**QQ(2,3) + x**QQ(2,5) + + +def test_puiseux_algebraic(): # https://github.com/sympy/sympy/issues/24395 + + K = QQ.algebraic_field(sqrt(2)) + sqrt2 = K.from_sympy(sqrt(2)) + x, y = symbols('x, y') + R, xr, yr = puiseux_ring([x, y], K) + p = (1+sqrt2)*xr**QQ(1,2) + (1-sqrt2)*yr**QQ(2,3) + + assert p.to_dict() == {(QQ(1,2),QQ(0)):1+sqrt2, (QQ(0),QQ(2,3)):1-sqrt2} + assert p.as_expr() == (1 + sqrt(2))*x**(S(1)/2) + (1 - sqrt(2))*y**(S(2)/3) + + +def test1(): + R, x = puiseux_ring('x', QQ) + r = rs_sin(x, x, 15)*x**(-5) + assert r == x**8/6227020800 - x**6/39916800 + x**4/362880 - x**2/5040 + \ + QQ(1,120) - x**-2/6 + x**-4 + + p = rs_sin(x, x, 10) + r = rs_nth_root(p, 2, x, 10) + assert r == -67*x**QQ(17,2)/29030400 - x**QQ(13,2)/24192 + \ + x**QQ(9,2)/1440 - x**QQ(5,2)/12 + x**QQ(1,2) + + p = rs_sin(x, x, 10) + r = rs_nth_root(p, 7, x, 10) + r = rs_pow(r, 5, x, 10) + assert r == -97*x**QQ(61,7)/124467840 - x**QQ(47,7)/16464 + \ + 11*x**QQ(33,7)/3528 - 5*x**QQ(19,7)/42 + x**QQ(5,7) + + r = rs_exp(x**QQ(1,2), x, 10) + assert r == x**QQ(19,2)/121645100408832000 + x**9/6402373705728000 + \ + x**QQ(17,2)/355687428096000 + x**8/20922789888000 + \ + x**QQ(15,2)/1307674368000 + x**7/87178291200 + \ + x**QQ(13,2)/6227020800 + x**6/479001600 + x**QQ(11,2)/39916800 + \ + x**5/3628800 + x**QQ(9,2)/362880 + x**4/40320 + x**QQ(7,2)/5040 + \ + x**3/720 + x**QQ(5,2)/120 + x**2/24 + x**QQ(3,2)/6 + x/2 + \ + x**QQ(1,2) + 1 + + +def test_puiseux2(): + R, y = ring('y', QQ) + S, x = puiseux_ring('x', R.to_domain()) + + p = x + x**QQ(1,5)*y + r = rs_atan(p, x, 3) + assert r == (y**13/13 + y**8 + 2*y**3)*x**QQ(13,5) - (y**11/11 + y**6 + + y)*x**QQ(11,5) + (y**9/9 + y**4)*x**QQ(9,5) - (y**7/7 + + y**2)*x**QQ(7,5) + (y**5/5 + 1)*x - y**3*x**QQ(3,5)/3 + y*x**QQ(1,5) + + +@slow +def test_rs_series(): + x, a, b, c = symbols('x, a, b, c') + + assert rs_series(a, a, 5).as_expr() == a + assert rs_series(sin(a), a, 5).as_expr() == (sin(a).series(a, 0, + 5)).removeO() + assert rs_series(sin(a) + cos(a), a, 5).as_expr() == ((sin(a) + + cos(a)).series(a, 0, 5)).removeO() + assert rs_series(sin(a)*cos(a), a, 5).as_expr() == ((sin(a)* + cos(a)).series(a, 0, 5)).removeO() + + p = (sin(a) - a)*(cos(a**2) + a**4/2) + assert expand(rs_series(p, a, 10).as_expr()) == expand(p.series(a, 0, + 10).removeO()) + + p = sin(a**2/2 + a/3) + cos(a/5)*sin(a/2)**3 + assert expand(rs_series(p, a, 5).as_expr()) == expand(p.series(a, 0, + 5).removeO()) + + p = sin(x**2 + a)*(cos(x**3 - 1) - a - a**2) + assert expand(rs_series(p, a, 5).as_expr()) == expand(p.series(a, 0, + 5).removeO()) + + p = sin(a**2 - a/3 + 2)**5*exp(a**3 - a/2) + assert expand(rs_series(p, a, 10).as_expr()) == expand(p.series(a, 0, + 10).removeO()) + + p = sin(a + b + c) + assert expand(rs_series(p, a, 5).as_expr()) == expand(p.series(a, 0, + 5).removeO()) + + p = tan(sin(a**2 + 4) + b + c) + assert expand(rs_series(p, a, 6).as_expr()) == expand(p.series(a, 0, + 6).removeO()) + + p = a**QQ(2,5) + a**QQ(2,3) + a + + r = rs_series(tan(p), a, 2) + assert r.as_expr() == a**QQ(9,5) + a**QQ(26,15) + a**QQ(22,15) + a**QQ(6,5)/3 + \ + a + a**QQ(2,3) + a**QQ(2,5) + + r = rs_series(exp(p), a, 1) + assert r.as_expr() == a**QQ(4,5)/2 + a**QQ(2,3) + a**QQ(2,5) + 1 + + r = rs_series(sin(p), a, 2) + assert r.as_expr() == -a**QQ(9,5)/2 - a**QQ(26,15)/2 - a**QQ(22,15)/2 - \ + a**QQ(6,5)/6 + a + a**QQ(2,3) + a**QQ(2,5) + + r = rs_series(cos(p), a, 2) + assert r.as_expr() == a**QQ(28,15)/6 - a**QQ(5,3) + a**QQ(8,5)/24 - a**QQ(7,5) - \ + a**QQ(4,3)/2 - a**QQ(16,15) - a**QQ(4,5)/2 + 1 + + assert rs_series(sin(a)/7, a, 5).as_expr() == (sin(a)/7).series(a, 0, + 5).removeO() + + +def test_rs_series_ConstantInExpr(): + x, a = symbols('x a') + assert rs_series(log(1 + x), x, 5).as_expr() == -x**4/4 + x**3/3 - \ + x**2/2 + x + assert rs_series(log(1 + 4*x), x, 5).as_expr() == -64*x**4 + 64*x**3/3 - \ + 8*x**2 + 4*x + assert rs_series(log(1 + x + x**2), x, 10).as_expr() == -2*x**9/9 + \ + x**8/8 + x**7/7 - x**6/3 + x**5/5 + x**4/4 - 2*x**3/3 + x**2/2 + x + assert rs_series(log(1 + x*a**2), x, 7).as_expr() == -x**6*a**12/6 + \ + x**5*a**10/5 - x**4*a**8/4 + x**3*a**6/3 - x**2*a**4/2 + x*a**2 + + assert rs_series(atan(1 + x), x, 9).as_expr() == -x**7/112 + x**6/48 - x**5/40 \ + + x**3/12 - x**2/4 + x/2 + pi/4 + assert rs_series(atan(1 + x + x**2),x, 9).as_expr() == -15*x**7/112 - x**6/48 + \ + 9*x**5/40 - 5*x**3/12 + x**2/4 + x/2 + pi/4 + assert rs_series(atan(1 + x * a), x, 9).as_expr() == -a**7*x**7/112 + a**6*x**6/48 \ + - a**5*x**5/40 + a**3*x**3/12 - a**2*x**2/4 + a*x/2 + pi/4 + + assert rs_series(tanh(1 + x), x, 5).as_expr() == -5*x**4*tanh(1)**3/3 + x**4* \ + tanh(1)**5 + 2*x**4*tanh(1)/3 - x**3*tanh(1)**4 - x**3/3 + 4*x**3*tanh(1) \ + **2/3 - x**2*tanh(1) + x**2*tanh(1)**3 - x*tanh(1)**2 + x + tanh(1) + assert rs_series(tanh(1 + x * a), x, 3).as_expr() == -a**2*x**2*tanh(1) + a**2*x** \ + 2*tanh(1)**3 - a*x*tanh(1)**2 + a*x + tanh(1) + + assert rs_series(sinh(1 + x), x, 5).as_expr() == x**4*sinh(1)/24 + x**3*cosh(1)/6 + \ + x**2*sinh(1)/2 + x*cosh(1) + sinh(1) + assert rs_series(sinh(1 + x * a), x, 5).as_expr() == a**4*x**4*sinh(1)/24 + \ + a**3*x**3*cosh(1)/6 + a**2*x**2*sinh(1)/2 + a*x*cosh(1) + sinh(1) + + assert rs_series(cosh(1 + x), x, 5).as_expr() == x**4*cosh(1)/24 + x**3*sinh(1)/6 + \ + x**2*cosh(1)/2 + x*sinh(1) + cosh(1) + assert rs_series(cosh(1 + x * a), x, 5).as_expr() == a**4*x**4*cosh(1)/24 + \ + a**3*x**3*sinh(1)/6 + a**2*x**2*cosh(1)/2 + a*x*sinh(1) + cosh(1) + + +def test_issue(): + # https://github.com/sympy/sympy/issues/10191 + # https://github.com/sympy/sympy/issues/19543 + + a, b = symbols('a b') + assert rs_series(sin(a**QQ(3,7))*exp(a + b**QQ(6,7)), a,2).as_expr() == \ + a**QQ(10,7)*exp(b**QQ(6,7)) - a**QQ(9,7)*exp(b**QQ(6,7))/6 + a**QQ(3,7)*exp(b**QQ(6,7)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rings.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rings.py new file mode 100644 index 0000000000000000000000000000000000000000..455cc319908d0173737531b339e22def8e4a26fc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rings.py @@ -0,0 +1,1591 @@ +"""Test sparse polynomials. """ + +from functools import reduce +from operator import add, mul + +from sympy.polys.rings import ring, xring, sring, PolyRing, PolyElement +from sympy.polys.fields import field, FracField +from sympy.polys.densebasic import ninf +from sympy.polys.domains import ZZ, QQ, RR, FF, EX +from sympy.polys.orderings import lex, grlex +from sympy.polys.polyerrors import GeneratorsError, \ + ExactQuotientFailed, MultivariatePolynomialError, CoercionFailed + +from sympy.testing.pytest import raises +from sympy.core import Symbol, symbols +from sympy.core.singleton import S +from sympy.core.numbers import pi +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt + +def test_PolyRing___init__(): + x, y, z, t = map(Symbol, "xyzt") + + assert len(PolyRing("x,y,z", ZZ, lex).gens) == 3 + assert len(PolyRing(x, ZZ, lex).gens) == 1 + assert len(PolyRing(("x", "y", "z"), ZZ, lex).gens) == 3 + assert len(PolyRing((x, y, z), ZZ, lex).gens) == 3 + assert len(PolyRing("", ZZ, lex).gens) == 0 + assert len(PolyRing([], ZZ, lex).gens) == 0 + + raises(GeneratorsError, lambda: PolyRing(0, ZZ, lex)) + + assert PolyRing("x", ZZ[t], lex).domain == ZZ[t] + assert PolyRing("x", 'ZZ[t]', lex).domain == ZZ[t] + assert PolyRing("x", PolyRing("t", ZZ, lex), lex).domain == ZZ[t] + + raises(GeneratorsError, lambda: PolyRing("x", PolyRing("x", ZZ, lex), lex)) + + _lex = Symbol("lex") + assert PolyRing("x", ZZ, lex).order == lex + assert PolyRing("x", ZZ, _lex).order == lex + assert PolyRing("x", ZZ, 'lex').order == lex + + R1 = PolyRing("x,y", ZZ, lex) + R2 = PolyRing("x,y", ZZ, lex) + R3 = PolyRing("x,y,z", ZZ, lex) + + assert R1.x == R1.gens[0] + assert R1.y == R1.gens[1] + assert R1.x == R2.x + assert R1.y == R2.y + assert R1.x != R3.x + assert R1.y != R3.y + +def test_PolyRing___hash__(): + R, x, y, z = ring("x,y,z", QQ) + assert hash(R) + +def test_PolyRing___eq__(): + assert ring("x,y,z", QQ)[0] == ring("x,y,z", QQ)[0] + assert ring("x,y,z", QQ)[0] != ring("x,y,z", ZZ)[0] + assert ring("x,y,z", ZZ)[0] != ring("x,y,z", QQ)[0] + assert ring("x,y,z", QQ)[0] != ring("x,y", QQ)[0] + assert ring("x,y", QQ)[0] != ring("x,y,z", QQ)[0] + +def test_PolyRing_ring_new(): + R, x, y, z = ring("x,y,z", QQ) + + assert R.ring_new(7) == R(7) + assert R.ring_new(7*x*y*z) == 7*x*y*z + + f = x**2 + 2*x*y + 3*x + 4*z**2 + 5*z + 6 + + assert R.ring_new([[[1]], [[2], [3]], [[4, 5, 6]]]) == f + assert R.ring_new({(2, 0, 0): 1, (1, 1, 0): 2, (1, 0, 0): 3, (0, 0, 2): 4, (0, 0, 1): 5, (0, 0, 0): 6}) == f + assert R.ring_new([((2, 0, 0), 1), ((1, 1, 0), 2), ((1, 0, 0), 3), ((0, 0, 2), 4), ((0, 0, 1), 5), ((0, 0, 0), 6)]) == f + + R, = ring("", QQ) + assert R.ring_new([((), 7)]) == R(7) + +def test_PolyRing_drop(): + R, x,y,z = ring("x,y,z", ZZ) + + assert R.drop(x) == PolyRing("y,z", ZZ, lex) + assert R.drop(y) == PolyRing("x,z", ZZ, lex) + assert R.drop(z) == PolyRing("x,y", ZZ, lex) + + assert R.drop(0) == PolyRing("y,z", ZZ, lex) + assert R.drop(0).drop(0) == PolyRing("z", ZZ, lex) + assert R.drop(0).drop(0).drop(0) == ZZ + + assert R.drop(1) == PolyRing("x,z", ZZ, lex) + + assert R.drop(2) == PolyRing("x,y", ZZ, lex) + assert R.drop(2).drop(1) == PolyRing("x", ZZ, lex) + assert R.drop(2).drop(1).drop(0) == ZZ + + raises(ValueError, lambda: R.drop(3)) + raises(ValueError, lambda: R.drop(x).drop(y)) + +def test_PolyRing___getitem__(): + R, x,y,z = ring("x,y,z", ZZ) + + assert R[0:] == PolyRing("x,y,z", ZZ, lex) + assert R[1:] == PolyRing("y,z", ZZ, lex) + assert R[2:] == PolyRing("z", ZZ, lex) + assert R[3:] == ZZ + +def test_PolyRing_is_(): + R = PolyRing("x", QQ, lex) + + assert R.is_univariate is True + assert R.is_multivariate is False + + R = PolyRing("x,y,z", QQ, lex) + + assert R.is_univariate is False + assert R.is_multivariate is True + + R = PolyRing("", QQ, lex) + + assert R.is_univariate is False + assert R.is_multivariate is False + +def test_PolyRing_add(): + R, x = ring("x", ZZ) + F = [ x**2 + 2*i + 3 for i in range(4) ] + + assert R.add(F) == reduce(add, F) == 4*x**2 + 24 + + R, = ring("", ZZ) + + assert R.add([2, 5, 7]) == 14 + +def test_PolyRing_mul(): + R, x = ring("x", ZZ) + F = [ x**2 + 2*i + 3 for i in range(4) ] + + assert R.mul(F) == reduce(mul, F) == x**8 + 24*x**6 + 206*x**4 + 744*x**2 + 945 + + R, = ring("", ZZ) + + assert R.mul([2, 3, 5]) == 30 + +def test_PolyRing_symmetric_poly(): + R, x, y, z, t = ring("x,y,z,t", ZZ) + + raises(ValueError, lambda: R.symmetric_poly(-1)) + raises(ValueError, lambda: R.symmetric_poly(5)) + + assert R.symmetric_poly(0) == R.one + assert R.symmetric_poly(1) == x + y + z + t + assert R.symmetric_poly(2) == x*y + x*z + x*t + y*z + y*t + z*t + assert R.symmetric_poly(3) == x*y*z + x*y*t + x*z*t + y*z*t + assert R.symmetric_poly(4) == x*y*z*t + +def test_sring(): + x, y, z, t = symbols("x,y,z,t") + + R = PolyRing("x,y,z", ZZ, lex) + assert sring(x + 2*y + 3*z) == (R, R.x + 2*R.y + 3*R.z) + + R = PolyRing("x,y,z", QQ, lex) + assert sring(x + 2*y + z/3) == (R, R.x + 2*R.y + R.z/3) + assert sring([x, 2*y, z/3]) == (R, [R.x, 2*R.y, R.z/3]) + + Rt = PolyRing("t", ZZ, lex) + R = PolyRing("x,y,z", Rt, lex) + assert sring(x + 2*t*y + 3*t**2*z, x, y, z) == (R, R.x + 2*Rt.t*R.y + 3*Rt.t**2*R.z) + + Rt = PolyRing("t", QQ, lex) + R = PolyRing("x,y,z", Rt, lex) + assert sring(x + t*y/2 + t**2*z/3, x, y, z) == (R, R.x + Rt.t*R.y/2 + Rt.t**2*R.z/3) + + Rt = FracField("t", ZZ, lex) + R = PolyRing("x,y,z", Rt, lex) + assert sring(x + 2*y/t + t**2*z/3, x, y, z) == (R, R.x + 2*R.y/Rt.t + Rt.t**2*R.z/3) + + r = sqrt(2) - sqrt(3) + R, a = sring(r, extension=True) + assert R.domain == QQ.algebraic_field(sqrt(2) + sqrt(3)) + assert R.gens == () + assert a == R.domain.from_sympy(r) + +def test_PolyElement___hash__(): + R, x, y, z = ring("x,y,z", QQ) + assert hash(x*y*z) + +def test_PolyElement___eq__(): + R, x, y = ring("x,y", ZZ, lex) + + assert ((x*y + 5*x*y) == 6) == False + assert ((x*y + 5*x*y) == 6*x*y) == True + assert (6 == (x*y + 5*x*y)) == False + assert (6*x*y == (x*y + 5*x*y)) == True + + assert ((x*y - x*y) == 0) == True + assert (0 == (x*y - x*y)) == True + + assert ((x*y - x*y) == 1) == False + assert (1 == (x*y - x*y)) == False + + assert ((x*y - x*y) == 1) == False + assert (1 == (x*y - x*y)) == False + + assert ((x*y + 5*x*y) != 6) == True + assert ((x*y + 5*x*y) != 6*x*y) == False + assert (6 != (x*y + 5*x*y)) == True + assert (6*x*y != (x*y + 5*x*y)) == False + + assert ((x*y - x*y) != 0) == False + assert (0 != (x*y - x*y)) == False + + assert ((x*y - x*y) != 1) == True + assert (1 != (x*y - x*y)) == True + + assert R.one == QQ(1, 1) == R.one + assert R.one == 1 == R.one + + Rt, t = ring("t", ZZ) + R, x, y = ring("x,y", Rt) + + assert (t**3*x/x == t**3) == True + assert (t**3*x/x == t**4) == False + +def test_PolyElement__lt_le_gt_ge__(): + R, x, y = ring("x,y", ZZ) + + assert R(1) < x < x**2 < x**3 + assert R(1) <= x <= x**2 <= x**3 + + assert x**3 > x**2 > x > R(1) + assert x**3 >= x**2 >= x >= R(1) + +def test_PolyElement__str__(): + x, y = symbols('x, y') + + for dom in [ZZ, QQ, ZZ[x], ZZ[x,y], ZZ[x][y]]: + R, t = ring('t', dom) + assert str(2*t**2 + 1) == '2*t**2 + 1' + + for dom in [EX, EX[x]]: + R, t = ring('t', dom) + assert str(2*t**2 + 1) == 'EX(2)*t**2 + EX(1)' + +def test_PolyElement_copy(): + R, x, y, z = ring("x,y,z", ZZ) + + f = x*y + 3*z + g = f.copy() + + assert f == g + g[(1, 1, 1)] = 7 + assert f != g + +def test_PolyElement_as_expr(): + R, x, y, z = ring("x,y,z", ZZ) + f = 3*x**2*y - x*y*z + 7*z**3 + 1 + + X, Y, Z = R.symbols + g = 3*X**2*Y - X*Y*Z + 7*Z**3 + 1 + + assert f != g + assert f.as_expr() == g + + U, V, W = symbols("u,v,w") + g = 3*U**2*V - U*V*W + 7*W**3 + 1 + + assert f != g + assert f.as_expr(U, V, W) == g + + raises(ValueError, lambda: f.as_expr(X)) + + R, = ring("", ZZ) + assert R(3).as_expr() == 3 + +def test_PolyElement_from_expr(): + x, y, z = symbols("x,y,z") + R, X, Y, Z = ring((x, y, z), ZZ) + + f = R.from_expr(1) + assert f == 1 and R.is_element(f) + + f = R.from_expr(x) + assert f == X and R.is_element(f) + + f = R.from_expr(x*y*z) + assert f == X*Y*Z and R.is_element(f) + + f = R.from_expr(x*y*z + x*y + x) + assert f == X*Y*Z + X*Y + X and R.is_element(f) + + f = R.from_expr(x**3*y*z + x**2*y**7 + 1) + assert f == X**3*Y*Z + X**2*Y**7 + 1 and R.is_element(f) + + r, F = sring([exp(2)]) + f = r.from_expr(exp(2)) + assert f == F[0] and r.is_element(f) + + raises(ValueError, lambda: R.from_expr(1/x)) + raises(ValueError, lambda: R.from_expr(2**x)) + raises(ValueError, lambda: R.from_expr(7*x + sqrt(2))) + + R, = ring("", ZZ) + f = R.from_expr(1) + assert f == 1 and R.is_element(f) + +def test_PolyElement_degree(): + R, x,y,z = ring("x,y,z", ZZ) + + assert ninf == float('-inf') + + assert R(0).degree() is ninf + assert R(1).degree() == 0 + assert (x + 1).degree() == 1 + assert (2*y**3 + z).degree() == 0 + assert (x*y**3 + z).degree() == 1 + assert (x**5*y**3 + z).degree() == 5 + + assert R(0).degree(x) is ninf + assert R(1).degree(x) == 0 + assert (x + 1).degree(x) == 1 + assert (2*y**3 + z).degree(x) == 0 + assert (x*y**3 + z).degree(x) == 1 + assert (7*x**5*y**3 + z).degree(x) == 5 + + assert R(0).degree(y) is ninf + assert R(1).degree(y) == 0 + assert (x + 1).degree(y) == 0 + assert (2*y**3 + z).degree(y) == 3 + assert (x*y**3 + z).degree(y) == 3 + assert (7*x**5*y**3 + z).degree(y) == 3 + + assert R(0).degree(z) is ninf + assert R(1).degree(z) == 0 + assert (x + 1).degree(z) == 0 + assert (2*y**3 + z).degree(z) == 1 + assert (x*y**3 + z).degree(z) == 1 + assert (7*x**5*y**3 + z).degree(z) == 1 + + R, = ring("", ZZ) + assert R(0).degree() is ninf + assert R(1).degree() == 0 + +def test_PolyElement_tail_degree(): + R, x,y,z = ring("x,y,z", ZZ) + + assert R(0).tail_degree() is ninf + assert R(1).tail_degree() == 0 + assert (x + 1).tail_degree() == 0 + assert (2*y**3 + x**3*z).tail_degree() == 0 + assert (x*y**3 + x**3*z).tail_degree() == 1 + assert (x**5*y**3 + x**3*z).tail_degree() == 3 + + assert R(0).tail_degree(x) is ninf + assert R(1).tail_degree(x) == 0 + assert (x + 1).tail_degree(x) == 0 + assert (2*y**3 + x**3*z).tail_degree(x) == 0 + assert (x*y**3 + x**3*z).tail_degree(x) == 1 + assert (7*x**5*y**3 + x**3*z).tail_degree(x) == 3 + + assert R(0).tail_degree(y) is ninf + assert R(1).tail_degree(y) == 0 + assert (x + 1).tail_degree(y) == 0 + assert (2*y**3 + x**3*z).tail_degree(y) == 0 + assert (x*y**3 + x**3*z).tail_degree(y) == 0 + assert (7*x**5*y**3 + x**3*z).tail_degree(y) == 0 + + assert R(0).tail_degree(z) is ninf + assert R(1).tail_degree(z) == 0 + assert (x + 1).tail_degree(z) == 0 + assert (2*y**3 + x**3*z).tail_degree(z) == 0 + assert (x*y**3 + x**3*z).tail_degree(z) == 0 + assert (7*x**5*y**3 + x**3*z).tail_degree(z) == 0 + + R, = ring("", ZZ) + assert R(0).tail_degree() is ninf + assert R(1).tail_degree() == 0 + +def test_PolyElement_degrees(): + R, x,y,z = ring("x,y,z", ZZ) + + assert R(0).degrees() == (ninf, ninf, ninf) + assert R(1).degrees() == (0, 0, 0) + assert (x**2*y + x**3*z**2).degrees() == (3, 1, 2) + +def test_PolyElement_tail_degrees(): + R, x,y,z = ring("x,y,z", ZZ) + + assert R(0).tail_degrees() == (ninf, ninf, ninf) + assert R(1).tail_degrees() == (0, 0, 0) + assert (x**2*y + x**3*z**2).tail_degrees() == (2, 0, 0) + +def test_PolyElement_coeff(): + R, x, y, z = ring("x,y,z", ZZ, lex) + f = 3*x**2*y - x*y*z + 7*z**3 + 23 + + assert f.coeff(1) == 23 + raises(ValueError, lambda: f.coeff(3)) + + assert f.coeff(x) == 0 + assert f.coeff(y) == 0 + assert f.coeff(z) == 0 + + assert f.coeff(x**2*y) == 3 + assert f.coeff(x*y*z) == -1 + assert f.coeff(z**3) == 7 + + raises(ValueError, lambda: f.coeff(3*x**2*y)) + raises(ValueError, lambda: f.coeff(-x*y*z)) + raises(ValueError, lambda: f.coeff(7*z**3)) + + R, = ring("", ZZ) + assert R(3).coeff(1) == 3 + +def test_PolyElement_LC(): + R, x, y = ring("x,y", QQ, lex) + assert R(0).LC == QQ(0) + assert (QQ(1,2)*x).LC == QQ(1, 2) + assert (QQ(1,4)*x*y + QQ(1,2)*x).LC == QQ(1, 4) + +def test_PolyElement_LM(): + R, x, y = ring("x,y", QQ, lex) + assert R(0).LM == (0, 0) + assert (QQ(1,2)*x).LM == (1, 0) + assert (QQ(1,4)*x*y + QQ(1,2)*x).LM == (1, 1) + +def test_PolyElement_LT(): + R, x, y = ring("x,y", QQ, lex) + assert R(0).LT == ((0, 0), QQ(0)) + assert (QQ(1,2)*x).LT == ((1, 0), QQ(1, 2)) + assert (QQ(1,4)*x*y + QQ(1,2)*x).LT == ((1, 1), QQ(1, 4)) + + R, = ring("", ZZ) + assert R(0).LT == ((), 0) + assert R(1).LT == ((), 1) + +def test_PolyElement_leading_monom(): + R, x, y = ring("x,y", QQ, lex) + assert R(0).leading_monom() == 0 + assert (QQ(1,2)*x).leading_monom() == x + assert (QQ(1,4)*x*y + QQ(1,2)*x).leading_monom() == x*y + +def test_PolyElement_leading_term(): + R, x, y = ring("x,y", QQ, lex) + assert R(0).leading_term() == 0 + assert (QQ(1,2)*x).leading_term() == QQ(1,2)*x + assert (QQ(1,4)*x*y + QQ(1,2)*x).leading_term() == QQ(1,4)*x*y + +def test_PolyElement_terms(): + R, x,y,z = ring("x,y,z", QQ) + terms = (x**2/3 + y**3/4 + z**4/5).terms() + assert terms == [((2,0,0), QQ(1,3)), ((0,3,0), QQ(1,4)), ((0,0,4), QQ(1,5))] + + R, x,y = ring("x,y", ZZ, lex) + f = x*y**7 + 2*x**2*y**3 + + assert f.terms() == f.terms(lex) == f.terms('lex') == [((2, 3), 2), ((1, 7), 1)] + assert f.terms(grlex) == f.terms('grlex') == [((1, 7), 1), ((2, 3), 2)] + + R, x,y = ring("x,y", ZZ, grlex) + f = x*y**7 + 2*x**2*y**3 + + assert f.terms() == f.terms(grlex) == f.terms('grlex') == [((1, 7), 1), ((2, 3), 2)] + assert f.terms(lex) == f.terms('lex') == [((2, 3), 2), ((1, 7), 1)] + + R, = ring("", ZZ) + assert R(3).terms() == [((), 3)] + +def test_PolyElement_monoms(): + R, x,y,z = ring("x,y,z", QQ) + monoms = (x**2/3 + y**3/4 + z**4/5).monoms() + assert monoms == [(2,0,0), (0,3,0), (0,0,4)] + + R, x,y = ring("x,y", ZZ, lex) + f = x*y**7 + 2*x**2*y**3 + + assert f.monoms() == f.monoms(lex) == f.monoms('lex') == [(2, 3), (1, 7)] + assert f.monoms(grlex) == f.monoms('grlex') == [(1, 7), (2, 3)] + + R, x,y = ring("x,y", ZZ, grlex) + f = x*y**7 + 2*x**2*y**3 + + assert f.monoms() == f.monoms(grlex) == f.monoms('grlex') == [(1, 7), (2, 3)] + assert f.monoms(lex) == f.monoms('lex') == [(2, 3), (1, 7)] + +def test_PolyElement_coeffs(): + R, x,y,z = ring("x,y,z", QQ) + coeffs = (x**2/3 + y**3/4 + z**4/5).coeffs() + assert coeffs == [QQ(1,3), QQ(1,4), QQ(1,5)] + + R, x,y = ring("x,y", ZZ, lex) + f = x*y**7 + 2*x**2*y**3 + + assert f.coeffs() == f.coeffs(lex) == f.coeffs('lex') == [2, 1] + assert f.coeffs(grlex) == f.coeffs('grlex') == [1, 2] + + R, x,y = ring("x,y", ZZ, grlex) + f = x*y**7 + 2*x**2*y**3 + + assert f.coeffs() == f.coeffs(grlex) == f.coeffs('grlex') == [1, 2] + assert f.coeffs(lex) == f.coeffs('lex') == [2, 1] + +def test_PolyElement___add__(): + Rt, t = ring("t", ZZ) + Ruv, u,v = ring("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Ruv) + + assert dict(x + 3*y) == {(1, 0, 0): 1, (0, 1, 0): 3} + + assert dict(u + x) == dict(x + u) == {(1, 0, 0): 1, (0, 0, 0): u} + assert dict(u + x*y) == dict(x*y + u) == {(1, 1, 0): 1, (0, 0, 0): u} + assert dict(u + x*y + z) == dict(x*y + z + u) == {(1, 1, 0): 1, (0, 0, 1): 1, (0, 0, 0): u} + + assert dict(u*x + x) == dict(x + u*x) == {(1, 0, 0): u + 1} + assert dict(u*x + x*y) == dict(x*y + u*x) == {(1, 1, 0): 1, (1, 0, 0): u} + assert dict(u*x + x*y + z) == dict(x*y + z + u*x) == {(1, 1, 0): 1, (0, 0, 1): 1, (1, 0, 0): u} + + raises(TypeError, lambda: t + x) + raises(TypeError, lambda: x + t) + raises(TypeError, lambda: t + u) + raises(TypeError, lambda: u + t) + + Fuv, u,v = field("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Fuv) + + assert dict(u + x) == dict(x + u) == {(1, 0, 0): 1, (0, 0, 0): u} + + Rxyz, x,y,z = ring("x,y,z", EX) + + assert dict(EX(pi) + x*y*z) == dict(x*y*z + EX(pi)) == {(1, 1, 1): EX(1), (0, 0, 0): EX(pi)} + +def test_PolyElement___sub__(): + Rt, t = ring("t", ZZ) + Ruv, u,v = ring("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Ruv) + + assert dict(x - 3*y) == {(1, 0, 0): 1, (0, 1, 0): -3} + + assert dict(-u + x) == dict(x - u) == {(1, 0, 0): 1, (0, 0, 0): -u} + assert dict(-u + x*y) == dict(x*y - u) == {(1, 1, 0): 1, (0, 0, 0): -u} + assert dict(-u + x*y + z) == dict(x*y + z - u) == {(1, 1, 0): 1, (0, 0, 1): 1, (0, 0, 0): -u} + + assert dict(-u*x + x) == dict(x - u*x) == {(1, 0, 0): -u + 1} + assert dict(-u*x + x*y) == dict(x*y - u*x) == {(1, 1, 0): 1, (1, 0, 0): -u} + assert dict(-u*x + x*y + z) == dict(x*y + z - u*x) == {(1, 1, 0): 1, (0, 0, 1): 1, (1, 0, 0): -u} + + raises(TypeError, lambda: t - x) + raises(TypeError, lambda: x - t) + raises(TypeError, lambda: t - u) + raises(TypeError, lambda: u - t) + + Fuv, u,v = field("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Fuv) + + assert dict(-u + x) == dict(x - u) == {(1, 0, 0): 1, (0, 0, 0): -u} + + Rxyz, x,y,z = ring("x,y,z", EX) + + assert dict(-EX(pi) + x*y*z) == dict(x*y*z - EX(pi)) == {(1, 1, 1): EX(1), (0, 0, 0): -EX(pi)} + +def test_PolyElement___mul__(): + Rt, t = ring("t", ZZ) + Ruv, u,v = ring("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Ruv) + + assert dict(u*x) == dict(x*u) == {(1, 0, 0): u} + + assert dict(2*u*x + z) == dict(x*2*u + z) == {(1, 0, 0): 2*u, (0, 0, 1): 1} + assert dict(u*2*x + z) == dict(2*x*u + z) == {(1, 0, 0): 2*u, (0, 0, 1): 1} + assert dict(2*u*x + z) == dict(x*2*u + z) == {(1, 0, 0): 2*u, (0, 0, 1): 1} + assert dict(u*x*2 + z) == dict(x*u*2 + z) == {(1, 0, 0): 2*u, (0, 0, 1): 1} + + assert dict(2*u*x*y + z) == dict(x*y*2*u + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + assert dict(u*2*x*y + z) == dict(2*x*y*u + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + assert dict(2*u*x*y + z) == dict(x*y*2*u + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + assert dict(u*x*y*2 + z) == dict(x*y*u*2 + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + + assert dict(2*u*y*x + z) == dict(y*x*2*u + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + assert dict(u*2*y*x + z) == dict(2*y*x*u + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + assert dict(2*u*y*x + z) == dict(y*x*2*u + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + assert dict(u*y*x*2 + z) == dict(y*x*u*2 + z) == {(1, 1, 0): 2*u, (0, 0, 1): 1} + + assert dict(3*u*(x + y) + z) == dict((x + y)*3*u + z) == {(1, 0, 0): 3*u, (0, 1, 0): 3*u, (0, 0, 1): 1} + + raises(TypeError, lambda: t*x + z) + raises(TypeError, lambda: x*t + z) + raises(TypeError, lambda: t*u + z) + raises(TypeError, lambda: u*t + z) + + Fuv, u,v = field("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Fuv) + + assert dict(u*x) == dict(x*u) == {(1, 0, 0): u} + + Rxyz, x,y,z = ring("x,y,z", EX) + + assert dict(EX(pi)*x*y*z) == dict(x*y*z*EX(pi)) == {(1, 1, 1): EX(pi)} + +def test_PolyElement___truediv__(): + R, x,y,z = ring("x,y,z", ZZ) + + assert (2*x**2 - 4)/2 == x**2 - 2 + assert (2*x**2 - 3)/2 == x**2 + + assert (x**2 - 1).quo(x) == x + assert (x**2 - x).quo(x) == x - 1 + + raises(ExactQuotientFailed, lambda: (x**2 - 1)/x) + assert (x**2 - x)/x == x - 1 + raises(ExactQuotientFailed, lambda: (x**2 - 1)/(2*x)) + + assert (x**2 - 1).quo(2*x) == 0 + assert (x**2 - x)/(x - 1) == (x**2 - x).quo(x - 1) == x + + + R, x,y,z = ring("x,y,z", ZZ) + assert len((x**2/3 + y**3/4 + z**4/5).terms()) == 0 + + R, x,y,z = ring("x,y,z", QQ) + assert len((x**2/3 + y**3/4 + z**4/5).terms()) == 3 + + Rt, t = ring("t", ZZ) + Ruv, u,v = ring("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Ruv) + + assert dict((u**2*x + u)/u) == {(1, 0, 0): u, (0, 0, 0): 1} + raises(ExactQuotientFailed, lambda: u/(u**2*x + u)) + + raises(TypeError, lambda: t/x) + raises(TypeError, lambda: x/t) + raises(TypeError, lambda: t/u) + raises(TypeError, lambda: u/t) + + R, x = ring("x", ZZ) + f, g = x**2 + 2*x + 3, R(0) + + raises(ZeroDivisionError, lambda: f.div(g)) + raises(ZeroDivisionError, lambda: divmod(f, g)) + raises(ZeroDivisionError, lambda: f.rem(g)) + raises(ZeroDivisionError, lambda: f % g) + raises(ZeroDivisionError, lambda: f.quo(g)) + raises(ZeroDivisionError, lambda: f / g) + raises(ZeroDivisionError, lambda: f.exquo(g)) + + R, x, y = ring("x,y", ZZ) + f, g = x*y + 2*x + 3, R(0) + + raises(ZeroDivisionError, lambda: f.div(g)) + raises(ZeroDivisionError, lambda: divmod(f, g)) + raises(ZeroDivisionError, lambda: f.rem(g)) + raises(ZeroDivisionError, lambda: f % g) + raises(ZeroDivisionError, lambda: f.quo(g)) + raises(ZeroDivisionError, lambda: f / g) + raises(ZeroDivisionError, lambda: f.exquo(g)) + + R, x = ring("x", ZZ) + + f, g = x**2 + 1, 2*x - 4 + q, r = R(0), x**2 + 1 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = 3*x**3 + x**2 + x + 5, 5*x**2 - 3*x + 1 + q, r = R(0), f + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = 5*x**4 + 4*x**3 + 3*x**2 + 2*x + 1, x**2 + 2*x + 3 + q, r = 5*x**2 - 6*x, 20*x + 1 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = 5*x**5 + 4*x**4 + 3*x**3 + 2*x**2 + x, x**4 + 2*x**3 + 9 + q, r = 5*x - 6, 15*x**3 + 2*x**2 - 44*x + 54 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + R, x = ring("x", QQ) + + f, g = x**2 + 1, 2*x - 4 + q, r = x/2 + 1, R(5) + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = 3*x**3 + x**2 + x + 5, 5*x**2 - 3*x + 1 + q, r = QQ(3, 5)*x + QQ(14, 25), QQ(52, 25)*x + QQ(111, 25) + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + R, x,y = ring("x,y", ZZ) + + f, g = x**2 - y**2, x - y + q, r = x + y, R(0) + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + assert f.exquo(g) == f / g == q + + f, g = x**2 + y**2, x - y + q, r = x + y, 2*y**2 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = x**2 + y**2, -x + y + q, r = -x - y, 2*y**2 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = x**2 + y**2, 2*x - 2*y + q, r = R(0), f + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + R, x,y = ring("x,y", QQ) + + f, g = x**2 - y**2, x - y + q, r = x + y, R(0) + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + assert f.exquo(g) == f / g == q + + f, g = x**2 + y**2, x - y + q, r = x + y, 2*y**2 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = x**2 + y**2, -x + y + q, r = -x - y, 2*y**2 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + + f, g = x**2 + y**2, 2*x - 2*y + q, r = x/2 + y/2, 2*y**2 + + assert f.div(g) == divmod(f, g) == (q, r) + assert f.rem(g) == f % g == r + assert f.quo(g) == q + raises(ExactQuotientFailed, lambda: f / g) + raises(ExactQuotientFailed, lambda: f.exquo(g)) + +def test_PolyElement___pow__(): + R, x = ring("x", ZZ, grlex) + f = 2*x + 3 + + assert f**0 == 1 + assert f**1 == f + raises(ValueError, lambda: f**(-1)) + + assert f**2 == f._pow_generic(2) == f._pow_multinomial(2) == 4*x**2 + 12*x + 9 + assert f**3 == f._pow_generic(3) == f._pow_multinomial(3) == 8*x**3 + 36*x**2 + 54*x + 27 + assert f**4 == f._pow_generic(4) == f._pow_multinomial(4) == 16*x**4 + 96*x**3 + 216*x**2 + 216*x + 81 + assert f**5 == f._pow_generic(5) == f._pow_multinomial(5) == 32*x**5 + 240*x**4 + 720*x**3 + 1080*x**2 + 810*x + 243 + + R, x,y,z = ring("x,y,z", ZZ, grlex) + f = x**3*y - 2*x*y**2 - 3*z + 1 + g = x**6*y**2 - 4*x**4*y**3 - 6*x**3*y*z + 2*x**3*y + 4*x**2*y**4 + 12*x*y**2*z - 4*x*y**2 + 9*z**2 - 6*z + 1 + + assert f**2 == f._pow_generic(2) == f._pow_multinomial(2) == g + + R, t = ring("t", ZZ) + f = -11200*t**4 - 2604*t**2 + 49 + g = 15735193600000000*t**16 + 14633730048000000*t**14 + 4828147466240000*t**12 \ + + 598976863027200*t**10 + 3130812416256*t**8 - 2620523775744*t**6 \ + + 92413760096*t**4 - 1225431984*t**2 + 5764801 + + assert f**4 == f._pow_generic(4) == f._pow_multinomial(4) == g + +def test_PolyElement_div(): + R, x = ring("x", ZZ, grlex) + + f = x**3 - 12*x**2 - 42 + g = x - 3 + + q = x**2 - 9*x - 27 + r = -123 + + assert f.div([g]) == ([q], r) + + R, x = ring("x", ZZ, grlex) + f = x**2 + 2*x + 2 + assert f.div([R(1)]) == ([f], 0) + + R, x = ring("x", QQ, grlex) + f = x**2 + 2*x + 2 + assert f.div([R(2)]) == ([QQ(1,2)*x**2 + x + 1], 0) + + R, x,y = ring("x,y", ZZ, grlex) + f = 4*x**2*y - 2*x*y + 4*x - 2*y + 8 + + assert f.div([R(2)]) == ([2*x**2*y - x*y + 2*x - y + 4], 0) + assert f.div([2*y]) == ([2*x**2 - x - 1], 4*x + 8) + + f = x - 1 + g = y - 1 + + assert f.div([g]) == ([0], f) + + f = x*y**2 + 1 + G = [x*y + 1, y + 1] + + Q = [y, -1] + r = 2 + + assert f.div(G) == (Q, r) + + f = x**2*y + x*y**2 + y**2 + G = [x*y - 1, y**2 - 1] + + Q = [x + y, 1] + r = x + y + 1 + + assert f.div(G) == (Q, r) + + G = [y**2 - 1, x*y - 1] + + Q = [x + 1, x] + r = 2*x + 1 + + assert f.div(G) == (Q, r) + + R, = ring("", ZZ) + assert R(3).div(R(2)) == (0, 3) + + R, = ring("", QQ) + assert R(3).div(R(2)) == (QQ(3, 2), 0) + +def test_PolyElement_rem(): + R, x = ring("x", ZZ, grlex) + + f = x**3 - 12*x**2 - 42 + g = x - 3 + r = -123 + + assert f.rem([g]) == f.div([g])[1] == r + + R, x,y = ring("x,y", ZZ, grlex) + + f = 4*x**2*y - 2*x*y + 4*x - 2*y + 8 + + assert f.rem([R(2)]) == f.div([R(2)])[1] == 0 + assert f.rem([2*y]) == f.div([2*y])[1] == 4*x + 8 + + f = x - 1 + g = y - 1 + + assert f.rem([g]) == f.div([g])[1] == f + + f = x*y**2 + 1 + G = [x*y + 1, y + 1] + r = 2 + + assert f.rem(G) == f.div(G)[1] == r + + f = x**2*y + x*y**2 + y**2 + G = [x*y - 1, y**2 - 1] + r = x + y + 1 + + assert f.rem(G) == f.div(G)[1] == r + + G = [y**2 - 1, x*y - 1] + r = 2*x + 1 + + assert f.rem(G) == f.div(G)[1] == r + +def test_PolyElement_deflate(): + R, x = ring("x", ZZ) + + assert (2*x**2).deflate(x**4 + 4*x**2 + 1) == ((2,), [2*x, x**2 + 4*x + 1]) + + R, x,y = ring("x,y", ZZ) + + assert R(0).deflate(R(0)) == ((1, 1), [0, 0]) + assert R(1).deflate(R(0)) == ((1, 1), [1, 0]) + assert R(1).deflate(R(2)) == ((1, 1), [1, 2]) + assert R(1).deflate(2*y) == ((1, 1), [1, 2*y]) + assert (2*y).deflate(2*y) == ((1, 1), [2*y, 2*y]) + assert R(2).deflate(2*y**2) == ((1, 2), [2, 2*y]) + assert (2*y**2).deflate(2*y**2) == ((1, 2), [2*y, 2*y]) + + f = x**4*y**2 + x**2*y + 1 + g = x**2*y**3 + x**2*y + 1 + + assert f.deflate(g) == ((2, 1), [x**2*y**2 + x*y + 1, x*y**3 + x*y + 1]) + +def test_PolyElement_clear_denoms(): + R, x,y = ring("x,y", QQ) + + assert R(1).clear_denoms() == (ZZ(1), 1) + assert R(7).clear_denoms() == (ZZ(1), 7) + + assert R(QQ(7,3)).clear_denoms() == (3, 7) + assert R(QQ(7,3)).clear_denoms() == (3, 7) + + assert (3*x**2 + x).clear_denoms() == (1, 3*x**2 + x) + assert (x**2 + QQ(1,2)*x).clear_denoms() == (2, 2*x**2 + x) + + rQQ, x,t = ring("x,t", QQ, lex) + rZZ, X,T = ring("x,t", ZZ, lex) + + F = [x - QQ(17824537287975195925064602467992950991718052713078834557692023531499318507213727406844943097,413954288007559433755329699713866804710749652268151059918115348815925474842910720000)*t**7 + - QQ(4882321164854282623427463828745855894130208215961904469205260756604820743234704900167747753,12936071500236232304854053116058337647210926633379720622441104650497671088840960000)*t**6 + - QQ(36398103304520066098365558157422127347455927422509913596393052633155821154626830576085097433,25872143000472464609708106232116675294421853266759441244882209300995342177681920000)*t**5 + - QQ(168108082231614049052707339295479262031324376786405372698857619250210703675982492356828810819,58212321751063045371843239022262519412449169850208742800984970927239519899784320000)*t**4 + - QQ(5694176899498574510667890423110567593477487855183144378347226247962949388653159751849449037,1617008937529529038106756639507292205901365829172465077805138081312208886105120000)*t**3 + - QQ(154482622347268833757819824809033388503591365487934245386958884099214649755244381307907779,60637835157357338929003373981523457721301218593967440417692678049207833228942000)*t**2 + - QQ(2452813096069528207645703151222478123259511586701148682951852876484544822947007791153163,2425513406294293557160134959260938308852048743758697616707707121968313329157680)*t + - QQ(34305265428126440542854669008203683099323146152358231964773310260498715579162112959703,202126117191191129763344579938411525737670728646558134725642260164026110763140), + t**8 + QQ(693749860237914515552,67859264524169150569)*t**7 + + QQ(27761407182086143225024,610733380717522355121)*t**6 + + QQ(7785127652157884044288,67859264524169150569)*t**5 + + QQ(36567075214771261409792,203577793572507451707)*t**4 + + QQ(36336335165196147384320,203577793572507451707)*t**3 + + QQ(7452455676042754048000,67859264524169150569)*t**2 + + QQ(2593331082514399232000,67859264524169150569)*t + + QQ(390399197427343360000,67859264524169150569)] + + G = [3725588592068034903797967297424801242396746870413359539263038139343329273586196480000*X - + 160420835591776763325581422211936558925462474417709511019228211783493866564923546661604487873*T**7 - + 1406108495478033395547109582678806497509499966197028487131115097902188374051595011248311352864*T**6 - + 5241326875850889518164640374668786338033653548841427557880599579174438246266263602956254030352*T**5 - + 10758917262823299139373269714910672770004760114329943852726887632013485035262879510837043892416*T**4 - + 13119383576444715672578819534846747735372132018341964647712009275306635391456880068261130581248*T**3 - + 9491412317016197146080450036267011389660653495578680036574753839055748080962214787557853941760*T**2 - + 3767520915562795326943800040277726397326609797172964377014046018280260848046603967211258368000*T - + 632314652371226552085897259159210286886724229880266931574701654721512325555116066073245696000, + 610733380717522355121*T**8 + + 6243748742141230639968*T**7 + + 27761407182086143225024*T**6 + + 70066148869420956398592*T**5 + + 109701225644313784229376*T**4 + + 109009005495588442152960*T**3 + + 67072101084384786432000*T**2 + + 23339979742629593088000*T + + 3513592776846090240000] + + assert [ f.clear_denoms()[1].set_ring(rZZ) for f in F ] == G + +def test_PolyElement_cofactors(): + R, x, y = ring("x,y", ZZ) + + f, g = R(0), R(0) + assert f.cofactors(g) == (0, 0, 0) + + f, g = R(2), R(0) + assert f.cofactors(g) == (2, 1, 0) + + f, g = R(-2), R(0) + assert f.cofactors(g) == (2, -1, 0) + + f, g = R(0), R(-2) + assert f.cofactors(g) == (2, 0, -1) + + f, g = R(0), 2*x + 4 + assert f.cofactors(g) == (2*x + 4, 0, 1) + + f, g = 2*x + 4, R(0) + assert f.cofactors(g) == (2*x + 4, 1, 0) + + f, g = R(2), R(2) + assert f.cofactors(g) == (2, 1, 1) + + f, g = R(-2), R(2) + assert f.cofactors(g) == (2, -1, 1) + + f, g = R(2), R(-2) + assert f.cofactors(g) == (2, 1, -1) + + f, g = R(-2), R(-2) + assert f.cofactors(g) == (2, -1, -1) + + f, g = x**2 + 2*x + 1, R(1) + assert f.cofactors(g) == (1, x**2 + 2*x + 1, 1) + + f, g = x**2 + 2*x + 1, R(2) + assert f.cofactors(g) == (1, x**2 + 2*x + 1, 2) + + f, g = 2*x**2 + 4*x + 2, R(2) + assert f.cofactors(g) == (2, x**2 + 2*x + 1, 1) + + f, g = R(2), 2*x**2 + 4*x + 2 + assert f.cofactors(g) == (2, 1, x**2 + 2*x + 1) + + f, g = 2*x**2 + 4*x + 2, x + 1 + assert f.cofactors(g) == (x + 1, 2*x + 2, 1) + + f, g = x + 1, 2*x**2 + 4*x + 2 + assert f.cofactors(g) == (x + 1, 1, 2*x + 2) + + R, x, y, z, t = ring("x,y,z,t", ZZ) + + f, g = t**2 + 2*t + 1, 2*t + 2 + assert f.cofactors(g) == (t + 1, t + 1, 2) + + f, g = z**2*t**2 + 2*z**2*t + z**2 + z*t + z, t**2 + 2*t + 1 + h, cff, cfg = t + 1, z**2*t + z**2 + z, t + 1 + + assert f.cofactors(g) == (h, cff, cfg) + assert g.cofactors(f) == (h, cfg, cff) + + R, x, y = ring("x,y", QQ) + + f = QQ(1,2)*x**2 + x + QQ(1,2) + g = QQ(1,2)*x + QQ(1,2) + + h = x + 1 + + assert f.cofactors(g) == (h, g, QQ(1,2)) + assert g.cofactors(f) == (h, QQ(1,2), g) + + R, x, y = ring("x,y", RR) + + f = 2.1*x*y**2 - 2.1*x*y + 2.1*x + g = 2.1*x**3 + h = 1.0*x + + assert f.cofactors(g) == (h, f/h, g/h) + assert g.cofactors(f) == (h, g/h, f/h) + +def test_PolyElement_gcd(): + R, x, y = ring("x,y", QQ) + + f = QQ(1,2)*x**2 + x + QQ(1,2) + g = QQ(1,2)*x + QQ(1,2) + + assert f.gcd(g) == x + 1 + +def test_PolyElement_cancel(): + R, x, y = ring("x,y", ZZ) + + f = 2*x**3 + 4*x**2 + 2*x + g = 3*x**2 + 3*x + F = 2*x + 2 + G = 3 + + assert f.cancel(g) == (F, G) + + assert (-f).cancel(g) == (-F, G) + assert f.cancel(-g) == (-F, G) + + R, x, y = ring("x,y", QQ) + + f = QQ(1,2)*x**3 + x**2 + QQ(1,2)*x + g = QQ(1,3)*x**2 + QQ(1,3)*x + F = 3*x + 3 + G = 2 + + assert f.cancel(g) == (F, G) + + assert (-f).cancel(g) == (-F, G) + assert f.cancel(-g) == (-F, G) + + Fx, x = field("x", ZZ) + Rt, t = ring("t", Fx) + + f = (-x**2 - 4)/4*t + g = t**2 + (x**2 + 2)/2 + + assert f.cancel(g) == ((-x**2 - 4)*t, 4*t**2 + 2*x**2 + 4) + +def test_PolyElement_max_norm(): + R, x, y = ring("x,y", ZZ) + + assert R(0).max_norm() == 0 + assert R(1).max_norm() == 1 + + assert (x**3 + 4*x**2 + 2*x + 3).max_norm() == 4 + +def test_PolyElement_l1_norm(): + R, x, y = ring("x,y", ZZ) + + assert R(0).l1_norm() == 0 + assert R(1).l1_norm() == 1 + + assert (x**3 + 4*x**2 + 2*x + 3).l1_norm() == 10 + +def test_PolyElement_diff(): + R, X = xring("x:11", QQ) + + f = QQ(288,5)*X[0]**8*X[1]**6*X[4]**3*X[10]**2 + 8*X[0]**2*X[2]**3*X[4]**3 +2*X[0]**2 - 2*X[1]**2 + + assert f.diff(X[0]) == QQ(2304,5)*X[0]**7*X[1]**6*X[4]**3*X[10]**2 + 16*X[0]*X[2]**3*X[4]**3 + 4*X[0] + assert f.diff(X[4]) == QQ(864,5)*X[0]**8*X[1]**6*X[4]**2*X[10]**2 + 24*X[0]**2*X[2]**3*X[4]**2 + assert f.diff(X[10]) == QQ(576,5)*X[0]**8*X[1]**6*X[4]**3*X[10] + +def test_PolyElement___call__(): + R, x = ring("x", ZZ) + f = 3*x + 1 + + assert f(0) == 1 + assert f(1) == 4 + + raises(ValueError, lambda: f()) + raises(ValueError, lambda: f(0, 1)) + + raises(CoercionFailed, lambda: f(QQ(1,7))) + + R, x,y = ring("x,y", ZZ) + f = 3*x + y**2 + 1 + + assert f(0, 0) == 1 + assert f(1, 7) == 53 + + Ry = R.drop(x) + + assert f(0) == Ry.y**2 + 1 + assert f(1) == Ry.y**2 + 4 + + raises(ValueError, lambda: f()) + raises(ValueError, lambda: f(0, 1, 2)) + + raises(CoercionFailed, lambda: f(1, QQ(1,7))) + raises(CoercionFailed, lambda: f(QQ(1,7), 1)) + raises(CoercionFailed, lambda: f(QQ(1,7), QQ(1,7))) + +def test_PolyElement_evaluate(): + R, x = ring("x", ZZ) + f = x**3 + 4*x**2 + 2*x + 3 + + r = f.evaluate(x, 0) + assert r == 3 and not isinstance(r, PolyElement) + + raises(CoercionFailed, lambda: f.evaluate(x, QQ(1,7))) + + R, x, y, z = ring("x,y,z", ZZ) + f = (x*y)**3 + 4*(x*y)**2 + 2*x*y + 3 + + r = f.evaluate(x, 0) + assert r == 3 and R.drop(x).is_element(r) + r = f.evaluate([(x, 0), (y, 0)]) + assert r == 3 and R.drop(x, y).is_element(r) + r = f.evaluate(y, 0) + assert r == 3 and R.drop(y).is_element(r) + r = f.evaluate([(y, 0), (x, 0)]) + assert r == 3 and R.drop(y, x).is_element(r) + + r = f.evaluate([(x, 0), (y, 0), (z, 0)]) + assert r == 3 and not isinstance(r, PolyElement) + + raises(CoercionFailed, lambda: f.evaluate([(x, 1), (y, QQ(1,7))])) + raises(CoercionFailed, lambda: f.evaluate([(x, QQ(1,7)), (y, 1)])) + raises(CoercionFailed, lambda: f.evaluate([(x, QQ(1,7)), (y, QQ(1,7))])) + +def test_PolyElement_subs(): + R, x = ring("x", ZZ) + f = x**3 + 4*x**2 + 2*x + 3 + + r = f.subs(x, 0) + assert r == 3 and R.is_element(r) + + raises(CoercionFailed, lambda: f.subs(x, QQ(1,7))) + + R, x, y, z = ring("x,y,z", ZZ) + f = x**3 + 4*x**2 + 2*x + 3 + + r = f.subs(x, 0) + assert r == 3 and R.is_element(r) + r = f.subs([(x, 0), (y, 0)]) + assert r == 3 and R.is_element(r) + + raises(CoercionFailed, lambda: f.subs([(x, 1), (y, QQ(1,7))])) + raises(CoercionFailed, lambda: f.subs([(x, QQ(1,7)), (y, 1)])) + raises(CoercionFailed, lambda: f.subs([(x, QQ(1,7)), (y, QQ(1,7))])) + +def test_PolyElement_symmetrize(): + R, x, y = ring("x,y", ZZ) + + # Homogeneous, symmetric + f = x**2 + y**2 + sym, rem, m = f.symmetrize() + assert rem == 0 + assert sym.compose(m) + rem == f + + # Homogeneous, asymmetric + f = x**2 - y**2 + sym, rem, m = f.symmetrize() + assert rem != 0 + assert sym.compose(m) + rem == f + + # Inhomogeneous, symmetric + f = x*y + 7 + sym, rem, m = f.symmetrize() + assert rem == 0 + assert sym.compose(m) + rem == f + + # Inhomogeneous, asymmetric + f = y + 7 + sym, rem, m = f.symmetrize() + assert rem != 0 + assert sym.compose(m) + rem == f + + # Constant + f = R.from_expr(3) + sym, rem, m = f.symmetrize() + assert rem == 0 + assert sym.compose(m) + rem == f + + # Constant constructed from sring + R, f = sring(3) + sym, rem, m = f.symmetrize() + assert rem == 0 + assert sym.compose(m) + rem == f + +def test_PolyElement_compose(): + R, x = ring("x", ZZ) + f = x**3 + 4*x**2 + 2*x + 3 + + r = f.compose(x, 0) + assert r == 3 and R.is_element(r) + + assert f.compose(x, x) == f + assert f.compose(x, x**2) == x**6 + 4*x**4 + 2*x**2 + 3 + + raises(CoercionFailed, lambda: f.compose(x, QQ(1,7))) + + R, x, y, z = ring("x,y,z", ZZ) + f = x**3 + 4*x**2 + 2*x + 3 + + r = f.compose(x, 0) + assert r == 3 and R.is_element(r) + r = f.compose([(x, 0), (y, 0)]) + assert r == 3 and R.is_element(r) + + r = (x**3 + 4*x**2 + 2*x*y*z + 3).compose(x, y*z**2 - 1) + q = (y*z**2 - 1)**3 + 4*(y*z**2 - 1)**2 + 2*(y*z**2 - 1)*y*z + 3 + assert r == q and R.is_element(r) + +def test_PolyElement_is_(): + R, x,y,z = ring("x,y,z", QQ) + + assert (x - x).is_generator == False + assert (x - x).is_ground == True + assert (x - x).is_monomial == True + assert (x - x).is_term == True + + assert (x - x + 1).is_generator == False + assert (x - x + 1).is_ground == True + assert (x - x + 1).is_monomial == True + assert (x - x + 1).is_term == True + + assert x.is_generator == True + assert x.is_ground == False + assert x.is_monomial == True + assert x.is_term == True + + assert (x*y).is_generator == False + assert (x*y).is_ground == False + assert (x*y).is_monomial == True + assert (x*y).is_term == True + + assert (3*x).is_generator == False + assert (3*x).is_ground == False + assert (3*x).is_monomial == False + assert (3*x).is_term == True + + assert (3*x + 1).is_generator == False + assert (3*x + 1).is_ground == False + assert (3*x + 1).is_monomial == False + assert (3*x + 1).is_term == False + + assert R(0).is_zero is True + assert R(1).is_zero is False + + assert R(0).is_one is False + assert R(1).is_one is True + + assert (x - 1).is_monic is True + assert (2*x - 1).is_monic is False + + assert (3*x + 2).is_primitive is True + assert (4*x + 2).is_primitive is False + + assert (x + y + z + 1).is_linear is True + assert (x*y*z + 1).is_linear is False + + assert (x*y + z + 1).is_quadratic is True + assert (x*y*z + 1).is_quadratic is False + + assert (x - 1).is_squarefree is True + assert ((x - 1)**2).is_squarefree is False + + assert (x**2 + x + 1).is_irreducible is True + assert (x**2 + 2*x + 1).is_irreducible is False + + _, t = ring("t", FF(11)) + + assert (7*t + 3).is_irreducible is True + assert (7*t**2 + 3*t + 1).is_irreducible is False + + _, u = ring("u", ZZ) + f = u**16 + u**14 - u**10 - u**8 - u**6 + u**2 + + assert f.is_cyclotomic is False + assert (f + 1).is_cyclotomic is True + + raises(MultivariatePolynomialError, lambda: x.is_cyclotomic) + + R, = ring("", ZZ) + assert R(4).is_squarefree is True + assert R(6).is_irreducible is True + +def test_PolyElement_drop(): + R, x,y,z = ring("x,y,z", ZZ) + + assert R(1).drop(0).ring == PolyRing("y,z", ZZ, lex) + assert R(1).drop(0).drop(0).ring == PolyRing("z", ZZ, lex) + assert R.is_element(R(1).drop(0).drop(0).drop(0)) is False + + raises(ValueError, lambda: z.drop(0).drop(0).drop(0)) + raises(ValueError, lambda: x.drop(0)) + +def test_PolyElement_coeff_wrt(): + R, x, y, z = ring("x, y, z", ZZ) + + p = 4*x**3 + 5*y**2 + 6*y**2*z + 7 + assert p.coeff_wrt(1, 2) == 6*z + 5 # using generator index + assert p.coeff_wrt(x, 3) == 4 # using generator + + p = 2*x**4 + 3*x*y**2*z + 10*y**2 + 10*x*z**2 + assert p.coeff_wrt(x, 1) == 3*y**2*z + 10*z**2 + assert p.coeff_wrt(y, 2) == 3*x*z + 10 + + p = 4*x**2 + 2*x*y + 5 + assert p.coeff_wrt(z, 1) == R(0) + assert p.coeff_wrt(y, 2) == R(0) + +def test_PolyElement_prem(): + R, x, y = ring("x, y", ZZ) + + f, g = x**2 + x*y, 2*x + 2 + assert f.prem(g) == -4*y + 4 # first generator is chosen by default if it is not given + + f, g = x**2 + 1, 2*x - 4 + assert f.prem(g) == f.prem(g, x) == 20 + assert f.prem(g, 1) == R(0) + + f, g = x*y + 2*x + 1, x + y + assert f.prem(g) == -y**2 - 2*y + 1 + assert f.prem(g, 1) == f.prem(g, y) == -x**2 + 2*x + 1 + + raises(ZeroDivisionError, lambda: f.prem(R(0))) + +def test_PolyElement_pdiv(): + R, x, y = ring("x,y", ZZ) + + f, g = x**4 + 5*x**3 + 7*x**2, 2*x**2 + 3 + assert f.pdiv(g) == f.pdiv(g, x) == (4*x**2 + 20*x + 22, -60*x - 66) + + f, g = x**2 - y**2, x - y + assert f.pdiv(g) == f.pdiv(g, 0) == (x + y, 0) + + f, g = x*y + 2*x + 1, x + y + assert f.pdiv(g) == (y + 2, -y**2 - 2*y + 1) + assert f.pdiv(g, y) == f.pdiv(g, 1) == (x + 1, -x**2 + 2*x + 1) + + assert R(0).pdiv(g) == (0, 0) + raises(ZeroDivisionError, lambda: f.prem(R(0))) + +def test_PolyElement_pquo(): + R, x, y = ring("x, y", ZZ) + + f, g = x**4 - 4*x**2*y + 4*y**2, x**2 - 2*y + assert f.pquo(g) == f.pquo(g, x) == x**2 - 2*y + assert f.pquo(g, y) == 4*x**2 - 8*y + 4 + + f, g = x**4 - y**4, x**2 - y**2 + assert f.pquo(g) == f.pquo(g, 0) == x**2 + y**2 + +def test_PolyElement_pexquo(): + R, x, y = ring("x, y", ZZ) + + f, g = x**2 - y**2, x - y + assert f.pexquo(g) == f.pexquo(g, x) == x + y + assert f.pexquo(g, y) == f.pexquo(g, 1) == x + y + 1 + + f, g = x**2 + 3*x + 6, x + 2 + raises(ExactQuotientFailed, lambda: f.pexquo(g)) + +def test_PolyElement_gcdex(): + _, x = ring("x", QQ) + + f, g = 2*x, x**2 - 16 + s, t, h = x/32, -QQ(1, 16), 1 + + assert f.half_gcdex(g) == (s, h) + assert f.gcdex(g) == (s, t, h) + +def test_PolyElement_subresultants(): + R, x, y = ring("x, y", ZZ) + + f, g = x**2*y + x*y, x + y # degree(f, x) > degree(g, x) + h = y**3 - y**2 + assert f.subresultants(g) == [f, g, h] # first generator is chosen default + + # generator index or generator is given + assert f.subresultants(g, 0) == f.subresultants(g, x) == [f, g, h] + + assert f.subresultants(g, y) == [x**2*y + x*y, x + y, x**3 + x**2] + + f, g = 2*x - y, x**2 + 2*y + x # degree(f, x) < degree(g, x) + assert f.subresultants(g) == [x**2 + x + 2*y, 2*x - y, y**2 + 10*y] + + f, g = R(0), y**3 - y**2 # f = 0 + assert f.subresultants(g) == [y**3 - y**2, 1] + + f, g = x**2*y + x*y, R(0) # g = 0 + assert f.subresultants(g) == [x**2*y + x*y, 1] + + f, g = R(0), R(0) # f = 0 and g = 0 + assert f.subresultants(g) == [0, 0] + + f, g = x**2 + x, x**2 + x # f and g are same polynomial + assert f.subresultants(g) == [x**2 + x, x**2 + x] + +def test_PolyElement_resultant(): + _, x = ring("x", ZZ) + f, g, h = x**2 - 2*x + 1, x**2 - 1, 0 + + assert f.resultant(g) == h + +def test_PolyElement_discriminant(): + _, x = ring("x", ZZ) + f, g = x**3 + 3*x**2 + 9*x - 13, -11664 + + assert f.discriminant() == g + + F, a, b, c = ring("a,b,c", ZZ) + _, x = ring("x", F) + + f, g = a*x**2 + b*x + c, b**2 - 4*a*c + + assert f.discriminant() == g + +def test_PolyElement_decompose(): + _, x = ring("x", ZZ) + + f = x**12 + 20*x**10 + 150*x**8 + 500*x**6 + 625*x**4 - 2*x**3 - 10*x + 9 + g = x**4 - 2*x + 9 + h = x**3 + 5*x + + assert g.compose(x, h) == f + assert f.decompose() == [g, h] + +def test_PolyElement_shift(): + _, x = ring("x", ZZ) + assert (x**2 - 2*x + 1).shift(2) == x**2 + 2*x + 1 + assert (x**2 - 2*x + 1).shift_list([2]) == x**2 + 2*x + 1 + + R, x, y = ring("x, y", ZZ) + assert (x*y).shift_list([1, 2]) == (x+1)*(y+2) + + raises(MultivariatePolynomialError, lambda: (x*y).shift(1)) + +def test_PolyElement_sturm(): + F, t = field("t", ZZ) + _, x = ring("x", F) + + f = 1024/(15625*t**8)*x**5 - 4096/(625*t**8)*x**4 + 32/(15625*t**4)*x**3 - 128/(625*t**4)*x**2 + F(1)/62500*x - F(1)/625 + + assert f.sturm() == [ + x**3 - 100*x**2 + t**4/64*x - 25*t**4/16, + 3*x**2 - 200*x + t**4/64, + (-t**4/96 + F(20000)/9)*x + 25*t**4/18, + (-9*t**12 - 11520000*t**8 - 3686400000000*t**4)/(576*t**8 - 245760000*t**4 + 26214400000000), + ] + +def test_PolyElement_gff_list(): + _, x = ring("x", ZZ) + + f = x**5 + 2*x**4 - x**3 - 2*x**2 + assert f.gff_list() == [(x, 1), (x + 2, 4)] + + f = x*(x - 1)**3*(x - 2)**2*(x - 4)**2*(x - 5) + assert f.gff_list() == [(x**2 - 5*x + 4, 1), (x**2 - 5*x + 4, 2), (x, 3)] + +def test_PolyElement_norm(): + k = QQ + K = QQ.algebraic_field(sqrt(2)) + sqrt2 = K.unit + _, X, Y = ring("x,y", k) + _, x, y = ring("x,y", K) + + assert (x*y + sqrt2).norm() == X**2*Y**2 - 2 + +def test_PolyElement_sqf_norm(): + R, x = ring("x", QQ.algebraic_field(sqrt(3))) + X = R.to_ground().x + + assert (x**2 - 2).sqf_norm() == ([1], x**2 - 2*sqrt(3)*x + 1, X**4 - 10*X**2 + 1) + + R, x = ring("x", QQ.algebraic_field(sqrt(2))) + X = R.to_ground().x + + assert (x**2 - 3).sqf_norm() == ([1], x**2 - 2*sqrt(2)*x - 1, X**4 - 10*X**2 + 1) + +def test_PolyElement_sqf_list(): + _, x = ring("x", ZZ) + + f = x**5 - x**3 - x**2 + 1 + g = x**3 + 2*x**2 + 2*x + 1 + h = x - 1 + p = x**4 + x**3 - x - 1 + + assert f.sqf_part() == p + assert f.sqf_list() == (1, [(g, 1), (h, 2)]) + +def test_issue_18894(): + items = [S(3)/16 + sqrt(3*sqrt(3) + 10)/8, S(1)/8 + 3*sqrt(3)/16, S(1)/8 + 3*sqrt(3)/16, -S(3)/16 + sqrt(3*sqrt(3) + 10)/8] + R, a = sring(items, extension=True) + assert R.domain == QQ.algebraic_field(sqrt(3)+sqrt(3*sqrt(3)+10)) + assert R.gens == () + result = [] + for item in items: + result.append(R.domain.from_sympy(item)) + assert a == result + +def test_PolyElement_factor_list(): + _, x = ring("x", ZZ) + + f = x**5 - x**3 - x**2 + 1 + + u = x + 1 + v = x - 1 + w = x**2 + x + 1 + + assert f.factor_list() == (1, [(u, 1), (v, 2), (w, 1)]) + + +def test_issue_21410(): + R, x = ring('x', FF(2)) + p = x**6 + x**5 + x**4 + x**3 + 1 + assert p._pow_multinomial(4) == x**24 + x**20 + x**16 + x**12 + 1 + + +def test_zero_polynomial_primitive(): + + x = symbols('x') + + R = ZZ[x] + zero_poly = R(0) + cont, prim = zero_poly.primitive() + assert cont == 0 + assert prim == zero_poly + assert prim.is_primitive is False diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rootisolation.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rootisolation.py new file mode 100644 index 0000000000000000000000000000000000000000..9661c1d6b63bfb941157c7e904ba4e048afbc538 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rootisolation.py @@ -0,0 +1,823 @@ +"""Tests for real and complex root isolation and refinement algorithms. """ + +from sympy.polys.rings import ring +from sympy.polys.domains import ZZ, QQ, ZZ_I, EX +from sympy.polys.polyerrors import DomainError, RefinementFailed, PolynomialError +from sympy.polys.rootisolation import ( + dup_cauchy_upper_bound, dup_cauchy_lower_bound, + dup_mignotte_sep_bound_squared, +) +from sympy.testing.pytest import raises + +def test_dup_sturm(): + R, x = ring("x", QQ) + + assert R.dup_sturm(5) == [1] + assert R.dup_sturm(x) == [x, 1] + + f = x**3 - 2*x**2 + 3*x - 5 + assert R.dup_sturm(f) == [f, 3*x**2 - 4*x + 3, -QQ(10,9)*x + QQ(13,3), -QQ(3303,100)] + + +def test_dup_cauchy_upper_bound(): + raises(PolynomialError, lambda: dup_cauchy_upper_bound([], QQ)) + raises(PolynomialError, lambda: dup_cauchy_upper_bound([QQ(1)], QQ)) + raises(DomainError, lambda: dup_cauchy_upper_bound([ZZ_I(1), ZZ_I(1)], ZZ_I)) + + assert dup_cauchy_upper_bound([QQ(1), QQ(0), QQ(0)], QQ) == QQ.zero + assert dup_cauchy_upper_bound([QQ(1), QQ(0), QQ(-2)], QQ) == QQ(3) + + +def test_dup_cauchy_lower_bound(): + raises(PolynomialError, lambda: dup_cauchy_lower_bound([], QQ)) + raises(PolynomialError, lambda: dup_cauchy_lower_bound([QQ(1)], QQ)) + raises(PolynomialError, lambda: dup_cauchy_lower_bound([QQ(1), QQ(0), QQ(0)], QQ)) + raises(DomainError, lambda: dup_cauchy_lower_bound([ZZ_I(1), ZZ_I(1)], ZZ_I)) + + assert dup_cauchy_lower_bound([QQ(1), QQ(0), QQ(-2)], QQ) == QQ(2, 3) + + +def test_dup_mignotte_sep_bound_squared(): + raises(PolynomialError, lambda: dup_mignotte_sep_bound_squared([], QQ)) + raises(PolynomialError, lambda: dup_mignotte_sep_bound_squared([QQ(1)], QQ)) + + assert dup_mignotte_sep_bound_squared([QQ(1), QQ(0), QQ(-2)], QQ) == QQ(3, 5) + + +def test_dup_refine_real_root(): + R, x = ring("x", ZZ) + f = x**2 - 2 + + assert R.dup_refine_real_root(f, QQ(1), QQ(1), steps=1) == (QQ(1), QQ(1)) + assert R.dup_refine_real_root(f, QQ(1), QQ(1), steps=9) == (QQ(1), QQ(1)) + + raises(ValueError, lambda: R.dup_refine_real_root(f, QQ(-2), QQ(2))) + + s, t = QQ(1, 1), QQ(2, 1) + + assert R.dup_refine_real_root(f, s, t, steps=0) == (QQ(1, 1), QQ(2, 1)) + assert R.dup_refine_real_root(f, s, t, steps=1) == (QQ(1, 1), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=2) == (QQ(4, 3), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=3) == (QQ(7, 5), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=4) == (QQ(7, 5), QQ(10, 7)) + + s, t = QQ(1, 1), QQ(3, 2) + + assert R.dup_refine_real_root(f, s, t, steps=0) == (QQ(1, 1), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=1) == (QQ(4, 3), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=2) == (QQ(7, 5), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=3) == (QQ(7, 5), QQ(10, 7)) + assert R.dup_refine_real_root(f, s, t, steps=4) == (QQ(7, 5), QQ(17, 12)) + + s, t = QQ(1, 1), QQ(5, 3) + + assert R.dup_refine_real_root(f, s, t, steps=0) == (QQ(1, 1), QQ(5, 3)) + assert R.dup_refine_real_root(f, s, t, steps=1) == (QQ(1, 1), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=2) == (QQ(7, 5), QQ(3, 2)) + assert R.dup_refine_real_root(f, s, t, steps=3) == (QQ(7, 5), QQ(13, 9)) + assert R.dup_refine_real_root(f, s, t, steps=4) == (QQ(7, 5), QQ(27, 19)) + + s, t = QQ(-1, 1), QQ(-2, 1) + + assert R.dup_refine_real_root(f, s, t, steps=0) == (-QQ(2, 1), -QQ(1, 1)) + assert R.dup_refine_real_root(f, s, t, steps=1) == (-QQ(3, 2), -QQ(1, 1)) + assert R.dup_refine_real_root(f, s, t, steps=2) == (-QQ(3, 2), -QQ(4, 3)) + assert R.dup_refine_real_root(f, s, t, steps=3) == (-QQ(3, 2), -QQ(7, 5)) + assert R.dup_refine_real_root(f, s, t, steps=4) == (-QQ(10, 7), -QQ(7, 5)) + + raises(RefinementFailed, lambda: R.dup_refine_real_root(f, QQ(0), QQ(1))) + + s, t, u, v, w = QQ(1), QQ(2), QQ(24, 17), QQ(17, 12), QQ(7, 5) + + assert R.dup_refine_real_root(f, s, t, eps=QQ(1, 100)) == (u, v) + assert R.dup_refine_real_root(f, s, t, steps=6) == (u, v) + + assert R.dup_refine_real_root(f, s, t, eps=QQ(1, 100), steps=5) == (w, v) + assert R.dup_refine_real_root(f, s, t, eps=QQ(1, 100), steps=6) == (u, v) + assert R.dup_refine_real_root(f, s, t, eps=QQ(1, 100), steps=7) == (u, v) + + s, t, u, v = QQ(-2), QQ(-1), QQ(-3, 2), QQ(-4, 3) + + assert R.dup_refine_real_root(f, s, t, disjoint=QQ(-5)) == (s, t) + assert R.dup_refine_real_root(f, s, t, disjoint=-v) == (s, t) + assert R.dup_refine_real_root(f, s, t, disjoint=v) == (u, v) + + s, t, u, v = QQ(1), QQ(2), QQ(4, 3), QQ(3, 2) + + assert R.dup_refine_real_root(f, s, t, disjoint=QQ(5)) == (s, t) + assert R.dup_refine_real_root(f, s, t, disjoint=-u) == (s, t) + assert R.dup_refine_real_root(f, s, t, disjoint=u) == (u, v) + + +def test_dup_isolate_real_roots_sqf(): + R, x = ring("x", ZZ) + + assert R.dup_isolate_real_roots_sqf(0) == [] + assert R.dup_isolate_real_roots_sqf(5) == [] + + assert R.dup_isolate_real_roots_sqf(x**2 + x) == [(-1, -1), (0, 0)] + assert R.dup_isolate_real_roots_sqf(x**2 - x) == [( 0, 0), (1, 1)] + + assert R.dup_isolate_real_roots_sqf(x**4 + x + 1) == [] + + I = [(-2, -1), (1, 2)] + + assert R.dup_isolate_real_roots_sqf(x**2 - 2) == I + assert R.dup_isolate_real_roots_sqf(-x**2 + 2) == I + + assert R.dup_isolate_real_roots_sqf(x - 1) == \ + [(1, 1)] + assert R.dup_isolate_real_roots_sqf(x**2 - 3*x + 2) == \ + [(1, 1), (2, 2)] + assert R.dup_isolate_real_roots_sqf(x**3 - 6*x**2 + 11*x - 6) == \ + [(1, 1), (2, 2), (3, 3)] + assert R.dup_isolate_real_roots_sqf(x**4 - 10*x**3 + 35*x**2 - 50*x + 24) == \ + [(1, 1), (2, 2), (3, 3), (4, 4)] + assert R.dup_isolate_real_roots_sqf(x**5 - 15*x**4 + 85*x**3 - 225*x**2 + 274*x - 120) == \ + [(1, 1), (2, 2), (3, 3), (4, 4), (5, 5)] + + assert R.dup_isolate_real_roots_sqf(x - 10) == \ + [(10, 10)] + assert R.dup_isolate_real_roots_sqf(x**2 - 30*x + 200) == \ + [(10, 10), (20, 20)] + assert R.dup_isolate_real_roots_sqf(x**3 - 60*x**2 + 1100*x - 6000) == \ + [(10, 10), (20, 20), (30, 30)] + assert R.dup_isolate_real_roots_sqf(x**4 - 100*x**3 + 3500*x**2 - 50000*x + 240000) == \ + [(10, 10), (20, 20), (30, 30), (40, 40)] + assert R.dup_isolate_real_roots_sqf(x**5 - 150*x**4 + 8500*x**3 - 225000*x**2 + 2740000*x - 12000000) == \ + [(10, 10), (20, 20), (30, 30), (40, 40), (50, 50)] + + assert R.dup_isolate_real_roots_sqf(x + 1) == \ + [(-1, -1)] + assert R.dup_isolate_real_roots_sqf(x**2 + 3*x + 2) == \ + [(-2, -2), (-1, -1)] + assert R.dup_isolate_real_roots_sqf(x**3 + 6*x**2 + 11*x + 6) == \ + [(-3, -3), (-2, -2), (-1, -1)] + assert R.dup_isolate_real_roots_sqf(x**4 + 10*x**3 + 35*x**2 + 50*x + 24) == \ + [(-4, -4), (-3, -3), (-2, -2), (-1, -1)] + assert R.dup_isolate_real_roots_sqf(x**5 + 15*x**4 + 85*x**3 + 225*x**2 + 274*x + 120) == \ + [(-5, -5), (-4, -4), (-3, -3), (-2, -2), (-1, -1)] + + assert R.dup_isolate_real_roots_sqf(x + 10) == \ + [(-10, -10)] + assert R.dup_isolate_real_roots_sqf(x**2 + 30*x + 200) == \ + [(-20, -20), (-10, -10)] + assert R.dup_isolate_real_roots_sqf(x**3 + 60*x**2 + 1100*x + 6000) == \ + [(-30, -30), (-20, -20), (-10, -10)] + assert R.dup_isolate_real_roots_sqf(x**4 + 100*x**3 + 3500*x**2 + 50000*x + 240000) == \ + [(-40, -40), (-30, -30), (-20, -20), (-10, -10)] + assert R.dup_isolate_real_roots_sqf(x**5 + 150*x**4 + 8500*x**3 + 225000*x**2 + 2740000*x + 12000000) == \ + [(-50, -50), (-40, -40), (-30, -30), (-20, -20), (-10, -10)] + + assert R.dup_isolate_real_roots_sqf(x**2 - 5) == [(-3, -2), (2, 3)] + assert R.dup_isolate_real_roots_sqf(x**3 - 5) == [(1, 2)] + assert R.dup_isolate_real_roots_sqf(x**4 - 5) == [(-2, -1), (1, 2)] + assert R.dup_isolate_real_roots_sqf(x**5 - 5) == [(1, 2)] + assert R.dup_isolate_real_roots_sqf(x**6 - 5) == [(-2, -1), (1, 2)] + assert R.dup_isolate_real_roots_sqf(x**7 - 5) == [(1, 2)] + assert R.dup_isolate_real_roots_sqf(x**8 - 5) == [(-2, -1), (1, 2)] + assert R.dup_isolate_real_roots_sqf(x**9 - 5) == [(1, 2)] + + assert R.dup_isolate_real_roots_sqf(x**2 - 1) == \ + [(-1, -1), (1, 1)] + assert R.dup_isolate_real_roots_sqf(x**3 + 2*x**2 - x - 2) == \ + [(-2, -2), (-1, -1), (1, 1)] + assert R.dup_isolate_real_roots_sqf(x**4 - 5*x**2 + 4) == \ + [(-2, -2), (-1, -1), (1, 1), (2, 2)] + assert R.dup_isolate_real_roots_sqf(x**5 + 3*x**4 - 5*x**3 - 15*x**2 + 4*x + 12) == \ + [(-3, -3), (-2, -2), (-1, -1), (1, 1), (2, 2)] + assert R.dup_isolate_real_roots_sqf(x**6 - 14*x**4 + 49*x**2 - 36) == \ + [(-3, -3), (-2, -2), (-1, -1), (1, 1), (2, 2), (3, 3)] + assert R.dup_isolate_real_roots_sqf(2*x**7 + x**6 - 28*x**5 - 14*x**4 + 98*x**3 + 49*x**2 - 72*x - 36) == \ + [(-3, -3), (-2, -2), (-1, -1), (-1, 0), (1, 1), (2, 2), (3, 3)] + assert R.dup_isolate_real_roots_sqf(4*x**8 - 57*x**6 + 210*x**4 - 193*x**2 + 36) == \ + [(-3, -3), (-2, -2), (-1, -1), (-1, 0), (0, 1), (1, 1), (2, 2), (3, 3)] + + f = 9*x**2 - 2 + + assert R.dup_isolate_real_roots_sqf(f) == \ + [(-1, 0), (0, 1)] + + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 10)) == \ + [(QQ(-1, 2), QQ(-3, 7)), (QQ(3, 7), QQ(1, 2))] + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 100)) == \ + [(QQ(-9, 19), QQ(-8, 17)), (QQ(8, 17), QQ(9, 19))] + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 1000)) == \ + [(QQ(-33, 70), QQ(-8, 17)), (QQ(8, 17), QQ(33, 70))] + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 10000)) == \ + [(QQ(-33, 70), QQ(-107, 227)), (QQ(107, 227), QQ(33, 70))] + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 100000)) == \ + [(QQ(-305, 647), QQ(-272, 577)), (QQ(272, 577), QQ(305, 647))] + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 1000000)) == \ + [(QQ(-1121, 2378), QQ(-272, 577)), (QQ(272, 577), QQ(1121, 2378))] + + f = 200100012*x**5 - 700390052*x**4 + 700490079*x**3 - 200240054*x**2 + 40017*x - 2 + + assert R.dup_isolate_real_roots_sqf(f) == \ + [(QQ(0), QQ(1, 10002)), (QQ(1, 10002), QQ(1, 10002)), + (QQ(1, 2), QQ(1, 2)), (QQ(1), QQ(1)), (QQ(2), QQ(2))] + + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 100000)) == \ + [(QQ(1, 10003), QQ(1, 10003)), (QQ(1, 10002), QQ(1, 10002)), + (QQ(1, 2), QQ(1, 2)), (QQ(1), QQ(1)), (QQ(2), QQ(2))] + + a, b, c, d = 10000090000001, 2000100003, 10000300007, 10000005000008 + + f = 20001600074001600021*x**4 \ + + 1700135866278935491773999857*x**3 \ + - 2000179008931031182161141026995283662899200197*x**2 \ + - 800027600594323913802305066986600025*x \ + + 100000950000540000725000008 + + assert R.dup_isolate_real_roots_sqf(f) == \ + [(-a, -a), (-1, 0), (0, 1), (d, d)] + + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 100000000000)) == \ + [(-QQ(a), -QQ(a)), (-QQ(1, b), -QQ(1, b)), (QQ(1, c), QQ(1, c)), (QQ(d), QQ(d))] + + (u, v), B, C, (s, t) = R.dup_isolate_real_roots_sqf(f, fast=True) + + assert u < -a < v and B == (-QQ(1), QQ(0)) and C == (QQ(0), QQ(1)) and s < d < t + + assert R.dup_isolate_real_roots_sqf(f, fast=True, eps=QQ(1, 100000000000000000000000000000)) == \ + [(-QQ(a), -QQ(a)), (-QQ(1, b), -QQ(1, b)), (QQ(1, c), QQ(1, c)), (QQ(d), QQ(d))] + + f = -10*x**4 + 8*x**3 + 80*x**2 - 32*x - 160 + + assert R.dup_isolate_real_roots_sqf(f) == \ + [(-2, -2), (-2, -1), (2, 2), (2, 3)] + + assert R.dup_isolate_real_roots_sqf(f, eps=QQ(1, 100)) == \ + [(-QQ(2), -QQ(2)), (-QQ(23, 14), -QQ(18, 11)), (QQ(2), QQ(2)), (QQ(39, 16), QQ(22, 9))] + + f = x - 1 + + assert R.dup_isolate_real_roots_sqf(f, inf=2) == [] + assert R.dup_isolate_real_roots_sqf(f, sup=0) == [] + + assert R.dup_isolate_real_roots_sqf(f) == [(1, 1)] + assert R.dup_isolate_real_roots_sqf(f, inf=1) == [(1, 1)] + assert R.dup_isolate_real_roots_sqf(f, sup=1) == [(1, 1)] + assert R.dup_isolate_real_roots_sqf(f, inf=1, sup=1) == [(1, 1)] + + f = x**2 - 2 + + assert R.dup_isolate_real_roots_sqf(f, inf=QQ(7, 4)) == [] + assert R.dup_isolate_real_roots_sqf(f, inf=QQ(7, 5)) == [(QQ(7, 5), QQ(3, 2))] + assert R.dup_isolate_real_roots_sqf(f, sup=QQ(7, 5)) == [(-2, -1)] + assert R.dup_isolate_real_roots_sqf(f, sup=QQ(7, 4)) == [(-2, -1), (1, QQ(3, 2))] + assert R.dup_isolate_real_roots_sqf(f, sup=-QQ(7, 4)) == [] + assert R.dup_isolate_real_roots_sqf(f, sup=-QQ(7, 5)) == [(-QQ(3, 2), -QQ(7, 5))] + assert R.dup_isolate_real_roots_sqf(f, inf=-QQ(7, 5)) == [(1, 2)] + assert R.dup_isolate_real_roots_sqf(f, inf=-QQ(7, 4)) == [(-QQ(3, 2), -1), (1, 2)] + + I = [(-2, -1), (1, 2)] + + assert R.dup_isolate_real_roots_sqf(f, inf=-2) == I + assert R.dup_isolate_real_roots_sqf(f, sup=+2) == I + + assert R.dup_isolate_real_roots_sqf(f, inf=-2, sup=2) == I + + R, x = ring("x", QQ) + f = QQ(8, 5)*x**2 - QQ(87374, 3855)*x - QQ(17, 771) + + assert R.dup_isolate_real_roots_sqf(f) == [(-1, 0), (14, 15)] + + R, x = ring("x", EX) + raises(DomainError, lambda: R.dup_isolate_real_roots_sqf(x + 3)) + +def test_dup_isolate_real_roots(): + R, x = ring("x", ZZ) + + assert R.dup_isolate_real_roots(0) == [] + assert R.dup_isolate_real_roots(3) == [] + + assert R.dup_isolate_real_roots(5*x) == [((0, 0), 1)] + assert R.dup_isolate_real_roots(7*x**4) == [((0, 0), 4)] + + assert R.dup_isolate_real_roots(x**2 + x) == [((-1, -1), 1), ((0, 0), 1)] + assert R.dup_isolate_real_roots(x**2 - x) == [((0, 0), 1), ((1, 1), 1)] + + assert R.dup_isolate_real_roots(x**4 + x + 1) == [] + + I = [((-2, -1), 1), ((1, 2), 1)] + + assert R.dup_isolate_real_roots(x**2 - 2) == I + assert R.dup_isolate_real_roots(-x**2 + 2) == I + + f = 16*x**14 - 96*x**13 + 24*x**12 + 936*x**11 - 1599*x**10 - 2880*x**9 + 9196*x**8 \ + + 552*x**7 - 21831*x**6 + 13968*x**5 + 21690*x**4 - 26784*x**3 - 2916*x**2 + 15552*x - 5832 + g = R.dup_sqf_part(f) + + assert R.dup_isolate_real_roots(f) == \ + [((-QQ(2), -QQ(3, 2)), 2), ((-QQ(3, 2), -QQ(1, 1)), 3), ((QQ(1), QQ(3, 2)), 3), + ((QQ(3, 2), QQ(3, 2)), 4), ((QQ(5, 3), QQ(2)), 2)] + + assert R.dup_isolate_real_roots_sqf(g) == \ + [(-QQ(2), -QQ(3, 2)), (-QQ(3, 2), -QQ(1, 1)), (QQ(1), QQ(3, 2)), + (QQ(3, 2), QQ(3, 2)), (QQ(3, 2), QQ(2))] + assert R.dup_isolate_real_roots(g) == \ + [((-QQ(2), -QQ(3, 2)), 1), ((-QQ(3, 2), -QQ(1, 1)), 1), ((QQ(1), QQ(3, 2)), 1), + ((QQ(3, 2), QQ(3, 2)), 1), ((QQ(3, 2), QQ(2)), 1)] + + f = x - 1 + + assert R.dup_isolate_real_roots(f, inf=2) == [] + assert R.dup_isolate_real_roots(f, sup=0) == [] + + assert R.dup_isolate_real_roots(f) == [((1, 1), 1)] + assert R.dup_isolate_real_roots(f, inf=1) == [((1, 1), 1)] + assert R.dup_isolate_real_roots(f, sup=1) == [((1, 1), 1)] + assert R.dup_isolate_real_roots(f, inf=1, sup=1) == [((1, 1), 1)] + + f = x**4 - 4*x**2 + 4 + + assert R.dup_isolate_real_roots(f, inf=QQ(7, 4)) == [] + assert R.dup_isolate_real_roots(f, inf=QQ(7, 5)) == [((QQ(7, 5), QQ(3, 2)), 2)] + assert R.dup_isolate_real_roots(f, sup=QQ(7, 5)) == [((-2, -1), 2)] + assert R.dup_isolate_real_roots(f, sup=QQ(7, 4)) == [((-2, -1), 2), ((1, QQ(3, 2)), 2)] + assert R.dup_isolate_real_roots(f, sup=-QQ(7, 4)) == [] + assert R.dup_isolate_real_roots(f, sup=-QQ(7, 5)) == [((-QQ(3, 2), -QQ(7, 5)), 2)] + assert R.dup_isolate_real_roots(f, inf=-QQ(7, 5)) == [((1, 2), 2)] + assert R.dup_isolate_real_roots(f, inf=-QQ(7, 4)) == [((-QQ(3, 2), -1), 2), ((1, 2), 2)] + + I = [((-2, -1), 2), ((1, 2), 2)] + + assert R.dup_isolate_real_roots(f, inf=-2) == I + assert R.dup_isolate_real_roots(f, sup=+2) == I + + assert R.dup_isolate_real_roots(f, inf=-2, sup=2) == I + + f = x**11 - 3*x**10 - x**9 + 11*x**8 - 8*x**7 - 8*x**6 + 12*x**5 - 4*x**4 + + assert R.dup_isolate_real_roots(f, basis=False) == \ + [((-2, -1), 2), ((0, 0), 4), ((1, 1), 3), ((1, 2), 2)] + assert R.dup_isolate_real_roots(f, basis=True) == \ + [((-2, -1), 2, [1, 0, -2]), ((0, 0), 4, [1, 0]), ((1, 1), 3, [1, -1]), ((1, 2), 2, [1, 0, -2])] + + f = (x**45 - 45*x**44 + 990*x**43 - 1) + g = (x**46 - 15180*x**43 + 9366819*x**40 - 53524680*x**39 + 260932815*x**38 - 1101716330*x**37 + 4076350421*x**36 - 13340783196*x**35 + 38910617655*x**34 - 101766230790*x**33 + 239877544005*x**32 - 511738760544*x**31 + 991493848554*x**30 - 1749695026860*x**29 + 2818953098830*x**28 - 4154246671960*x**27 + 5608233007146*x**26 - 6943526580276*x**25 + 7890371113950*x**24 - 8233430727600*x**23 + 7890371113950*x**22 - 6943526580276*x**21 + 5608233007146*x**20 - 4154246671960*x**19 + 2818953098830*x**18 - 1749695026860*x**17 + 991493848554*x**16 - 511738760544*x**15 + 239877544005*x**14 - 101766230790*x**13 + 38910617655*x**12 - 13340783196*x**11 + 4076350421*x**10 - 1101716330*x**9 + 260932815*x**8 - 53524680*x**7 + 9366819*x**6 - 1370754*x**5 + 163185*x**4 - 15180*x**3 + 1035*x**2 - 47*x + 1) + + assert R.dup_isolate_real_roots(f*g) == \ + [((0, QQ(1, 2)), 1), ((QQ(2, 3), QQ(3, 4)), 1), ((QQ(3, 4), 1), 1), ((6, 7), 1), ((24, 25), 1)] + + R, x = ring("x", EX) + raises(DomainError, lambda: R.dup_isolate_real_roots(x + 3)) + + +def test_dup_isolate_real_roots_list(): + R, x = ring("x", ZZ) + + assert R.dup_isolate_real_roots_list([x**2 + x, x]) == \ + [((-1, -1), {0: 1}), ((0, 0), {0: 1, 1: 1})] + assert R.dup_isolate_real_roots_list([x**2 - x, x]) == \ + [((0, 0), {0: 1, 1: 1}), ((1, 1), {0: 1})] + + assert R.dup_isolate_real_roots_list([x + 1, x + 2, x - 1, x + 1, x - 1, x - 1]) == \ + [((-QQ(2), -QQ(2)), {1: 1}), ((-QQ(1), -QQ(1)), {0: 1, 3: 1}), ((QQ(1), QQ(1)), {2: 1, 4: 1, 5: 1})] + + assert R.dup_isolate_real_roots_list([x + 1, x + 2, x - 1, x + 1, x - 1, x + 2]) == \ + [((-QQ(2), -QQ(2)), {1: 1, 5: 1}), ((-QQ(1), -QQ(1)), {0: 1, 3: 1}), ((QQ(1), QQ(1)), {2: 1, 4: 1})] + + f, g = x**4 - 4*x**2 + 4, x - 1 + + assert R.dup_isolate_real_roots_list([f, g], inf=QQ(7, 4)) == [] + assert R.dup_isolate_real_roots_list([f, g], inf=QQ(7, 5)) == \ + [((QQ(7, 5), QQ(3, 2)), {0: 2})] + assert R.dup_isolate_real_roots_list([f, g], sup=QQ(7, 5)) == \ + [((-2, -1), {0: 2}), ((1, 1), {1: 1})] + assert R.dup_isolate_real_roots_list([f, g], sup=QQ(7, 4)) == \ + [((-2, -1), {0: 2}), ((1, 1), {1: 1}), ((1, QQ(3, 2)), {0: 2})] + assert R.dup_isolate_real_roots_list([f, g], sup=-QQ(7, 4)) == [] + assert R.dup_isolate_real_roots_list([f, g], sup=-QQ(7, 5)) == \ + [((-QQ(3, 2), -QQ(7, 5)), {0: 2})] + assert R.dup_isolate_real_roots_list([f, g], inf=-QQ(7, 5)) == \ + [((1, 1), {1: 1}), ((1, 2), {0: 2})] + assert R.dup_isolate_real_roots_list([f, g], inf=-QQ(7, 4)) == \ + [((-QQ(3, 2), -1), {0: 2}), ((1, 1), {1: 1}), ((1, 2), {0: 2})] + + f, g = 2*x**2 - 1, x**2 - 2 + + assert R.dup_isolate_real_roots_list([f, g]) == \ + [((-QQ(2), -QQ(1)), {1: 1}), ((-QQ(1), QQ(0)), {0: 1}), + ((QQ(0), QQ(1)), {0: 1}), ((QQ(1), QQ(2)), {1: 1})] + assert R.dup_isolate_real_roots_list([f, g], strict=True) == \ + [((-QQ(3, 2), -QQ(4, 3)), {1: 1}), ((-QQ(1), -QQ(2, 3)), {0: 1}), + ((QQ(2, 3), QQ(1)), {0: 1}), ((QQ(4, 3), QQ(3, 2)), {1: 1})] + + f, g = x**2 - 2, x**3 - x**2 - 2*x + 2 + + assert R.dup_isolate_real_roots_list([f, g]) == \ + [((-QQ(2), -QQ(1)), {1: 1, 0: 1}), ((QQ(1), QQ(1)), {1: 1}), ((QQ(1), QQ(2)), {1: 1, 0: 1})] + + f, g = x**3 - 2*x, x**5 - x**4 - 2*x**3 + 2*x**2 + + assert R.dup_isolate_real_roots_list([f, g]) == \ + [((-QQ(2), -QQ(1)), {1: 1, 0: 1}), ((QQ(0), QQ(0)), {0: 1, 1: 2}), + ((QQ(1), QQ(1)), {1: 1}), ((QQ(1), QQ(2)), {1: 1, 0: 1})] + + f, g = x**9 - 3*x**8 - x**7 + 11*x**6 - 8*x**5 - 8*x**4 + 12*x**3 - 4*x**2, x**5 - 2*x**4 + 3*x**3 - 4*x**2 + 2*x + + assert R.dup_isolate_real_roots_list([f, g], basis=False) == \ + [((-2, -1), {0: 2}), ((0, 0), {0: 2, 1: 1}), ((1, 1), {0: 3, 1: 2}), ((1, 2), {0: 2})] + assert R.dup_isolate_real_roots_list([f, g], basis=True) == \ + [((-2, -1), {0: 2}, [1, 0, -2]), ((0, 0), {0: 2, 1: 1}, [1, 0]), + ((1, 1), {0: 3, 1: 2}, [1, -1]), ((1, 2), {0: 2}, [1, 0, -2])] + + R, x = ring("x", EX) + raises(DomainError, lambda: R.dup_isolate_real_roots_list([x + 3])) + + +def test_dup_isolate_real_roots_list_QQ(): + R, x = ring("x", ZZ) + + f = x**5 - 200 + g = x**5 - 201 + + assert R.dup_isolate_real_roots_list([f, g]) == \ + [((QQ(75, 26), QQ(101, 35)), {0: 1}), ((QQ(309, 107), QQ(26, 9)), {1: 1})] + + R, x = ring("x", QQ) + + f = -QQ(1, 200)*x**5 + 1 + g = -QQ(1, 201)*x**5 + 1 + + assert R.dup_isolate_real_roots_list([f, g]) == \ + [((QQ(75, 26), QQ(101, 35)), {0: 1}), ((QQ(309, 107), QQ(26, 9)), {1: 1})] + + +def test_dup_count_real_roots(): + R, x = ring("x", ZZ) + + assert R.dup_count_real_roots(0) == 0 + assert R.dup_count_real_roots(7) == 0 + + f = x - 1 + assert R.dup_count_real_roots(f) == 1 + assert R.dup_count_real_roots(f, inf=1) == 1 + assert R.dup_count_real_roots(f, sup=0) == 0 + assert R.dup_count_real_roots(f, sup=1) == 1 + assert R.dup_count_real_roots(f, inf=0, sup=1) == 1 + assert R.dup_count_real_roots(f, inf=0, sup=2) == 1 + assert R.dup_count_real_roots(f, inf=1, sup=2) == 1 + + f = x**2 - 2 + assert R.dup_count_real_roots(f) == 2 + assert R.dup_count_real_roots(f, sup=0) == 1 + assert R.dup_count_real_roots(f, inf=-1, sup=1) == 0 + + +# parameters for test_dup_count_complex_roots_n(): n = 1..8 +a, b = (-QQ(1), -QQ(1)), (QQ(1), QQ(1)) +c, d = ( QQ(0), QQ(0)), (QQ(1), QQ(1)) + +def test_dup_count_complex_roots_1(): + R, x = ring("x", ZZ) + + # z-1 + f = x - 1 + assert R.dup_count_complex_roots(f, a, b) == 1 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # z+1 + f = x + 1 + assert R.dup_count_complex_roots(f, a, b) == 1 + assert R.dup_count_complex_roots(f, c, d) == 0 + + +def test_dup_count_complex_roots_2(): + R, x = ring("x", ZZ) + + # (z-1)*(z) + f = x**2 - x + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-1)*(-z) + f = -x**2 + x + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z+1)*(z) + f = x**2 + x + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z+1)*(-z) + f = -x**2 - x + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 1 + + +def test_dup_count_complex_roots_3(): + R, x = ring("x", ZZ) + + # (z-1)*(z+1) + f = x**2 - 1 + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-1)*(z+1)*(z) + f = x**3 - x + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-1)*(z+1)*(-z) + f = -x**3 + x + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 2 + + +def test_dup_count_complex_roots_4(): + R, x = ring("x", ZZ) + + # (z-I)*(z+I) + f = x**2 + 1 + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I)*(z+I)*(z) + f = x**3 + x + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I)*(z+I)*(-z) + f = -x**3 - x + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I)*(z+I)*(z-1) + f = x**3 - x**2 + x - 1 + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I)*(z+I)*(z-1)*(z) + f = x**4 - x**3 + x**2 - x + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 3 + + # (z-I)*(z+I)*(z-1)*(-z) + f = -x**4 + x**3 - x**2 + x + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 3 + + # (z-I)*(z+I)*(z-1)*(z+1) + f = x**4 - 1 + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I)*(z+I)*(z-1)*(z+1)*(z) + f = x**5 - x + assert R.dup_count_complex_roots(f, a, b) == 5 + assert R.dup_count_complex_roots(f, c, d) == 3 + + # (z-I)*(z+I)*(z-1)*(z+1)*(-z) + f = -x**5 + x + assert R.dup_count_complex_roots(f, a, b) == 5 + assert R.dup_count_complex_roots(f, c, d) == 3 + + +def test_dup_count_complex_roots_5(): + R, x = ring("x", ZZ) + + # (z-I+1)*(z+I+1) + f = x**2 + 2*x + 2 + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 0 + + # (z-I+1)*(z+I+1)*(z-1) + f = x**3 + x**2 - 2 + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I+1)*(z+I+1)*(z-1)*z + f = x**4 + x**3 - 2*x + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I+1)*(z+I+1)*(z+1) + f = x**3 + 3*x**2 + 4*x + 2 + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 0 + + # (z-I+1)*(z+I+1)*(z+1)*z + f = x**4 + 3*x**3 + 4*x**2 + 2*x + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I+1)*(z+I+1)*(z-1)*(z+1) + f = x**4 + 2*x**3 + x**2 - 2*x - 2 + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I+1)*(z+I+1)*(z-1)*(z+1)*z + f = x**5 + 2*x**4 + x**3 - 2*x**2 - 2*x + assert R.dup_count_complex_roots(f, a, b) == 5 + assert R.dup_count_complex_roots(f, c, d) == 2 + + +def test_dup_count_complex_roots_6(): + R, x = ring("x", ZZ) + + # (z-I-1)*(z+I-1) + f = x**2 - 2*x + 2 + assert R.dup_count_complex_roots(f, a, b) == 2 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I-1)*(z+I-1)*(z-1) + f = x**3 - 3*x**2 + 4*x - 2 + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I-1)*(z+I-1)*(z-1)*z + f = x**4 - 3*x**3 + 4*x**2 - 2*x + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 3 + + # (z-I-1)*(z+I-1)*(z+1) + f = x**3 - x**2 + 2 + assert R.dup_count_complex_roots(f, a, b) == 3 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I-1)*(z+I-1)*(z+1)*z + f = x**4 - x**3 + 2*x + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I-1)*(z+I-1)*(z-1)*(z+1) + f = x**4 - 2*x**3 + x**2 + 2*x - 2 + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I-1)*(z+I-1)*(z-1)*(z+1)*z + f = x**5 - 2*x**4 + x**3 + 2*x**2 - 2*x + assert R.dup_count_complex_roots(f, a, b) == 5 + assert R.dup_count_complex_roots(f, c, d) == 3 + + +def test_dup_count_complex_roots_7(): + R, x = ring("x", ZZ) + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1) + f = x**4 + 4 + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-2) + f = x**5 - 2*x**4 + 4*x - 8 + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z**2-2) + f = x**6 - 2*x**4 + 4*x**2 - 8 + assert R.dup_count_complex_roots(f, a, b) == 4 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1) + f = x**5 - x**4 + 4*x - 4 + assert R.dup_count_complex_roots(f, a, b) == 5 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1)*z + f = x**6 - x**5 + 4*x**2 - 4*x + assert R.dup_count_complex_roots(f, a, b) == 6 + assert R.dup_count_complex_roots(f, c, d) == 3 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z+1) + f = x**5 + x**4 + 4*x + 4 + assert R.dup_count_complex_roots(f, a, b) == 5 + assert R.dup_count_complex_roots(f, c, d) == 1 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z+1)*z + f = x**6 + x**5 + 4*x**2 + 4*x + assert R.dup_count_complex_roots(f, a, b) == 6 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1)*(z+1) + f = x**6 - x**4 + 4*x**2 - 4 + assert R.dup_count_complex_roots(f, a, b) == 6 + assert R.dup_count_complex_roots(f, c, d) == 2 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1)*(z+1)*z + f = x**7 - x**5 + 4*x**3 - 4*x + assert R.dup_count_complex_roots(f, a, b) == 7 + assert R.dup_count_complex_roots(f, c, d) == 3 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1)*(z+1)*(z-I)*(z+I) + f = x**8 + 3*x**4 - 4 + assert R.dup_count_complex_roots(f, a, b) == 8 + assert R.dup_count_complex_roots(f, c, d) == 3 + + +def test_dup_count_complex_roots_8(): + R, x = ring("x", ZZ) + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1)*(z+1)*(z-I)*(z+I)*z + f = x**9 + 3*x**5 - 4*x + assert R.dup_count_complex_roots(f, a, b) == 9 + assert R.dup_count_complex_roots(f, c, d) == 4 + + # (z-I-1)*(z+I-1)*(z-I+1)*(z+I+1)*(z-1)*(z+1)*(z-I)*(z+I)*(z**2-2)*z + f = x**11 - 2*x**9 + 3*x**7 - 6*x**5 - 4*x**3 + 8*x + assert R.dup_count_complex_roots(f, a, b) == 9 + assert R.dup_count_complex_roots(f, c, d) == 4 + + +def test_dup_count_complex_roots_implicit(): + R, x = ring("x", ZZ) + + # z*(z-1)*(z+1)*(z-I)*(z+I) + f = x**5 - x + + assert R.dup_count_complex_roots(f) == 5 + + assert R.dup_count_complex_roots(f, sup=(0, 0)) == 3 + assert R.dup_count_complex_roots(f, inf=(0, 0)) == 3 + + +def test_dup_count_complex_roots_exclude(): + R, x = ring("x", ZZ) + + # z*(z-1)*(z+1)*(z-I)*(z+I) + f = x**5 - x + + a, b = (-QQ(1), QQ(0)), (QQ(1), QQ(1)) + + assert R.dup_count_complex_roots(f, a, b) == 4 + + assert R.dup_count_complex_roots(f, a, b, exclude=['S']) == 3 + assert R.dup_count_complex_roots(f, a, b, exclude=['N']) == 3 + + assert R.dup_count_complex_roots(f, a, b, exclude=['S', 'N']) == 2 + + assert R.dup_count_complex_roots(f, a, b, exclude=['E']) == 4 + assert R.dup_count_complex_roots(f, a, b, exclude=['W']) == 4 + + assert R.dup_count_complex_roots(f, a, b, exclude=['E', 'W']) == 4 + + assert R.dup_count_complex_roots(f, a, b, exclude=['N', 'S', 'E', 'W']) == 2 + + assert R.dup_count_complex_roots(f, a, b, exclude=['SW']) == 3 + assert R.dup_count_complex_roots(f, a, b, exclude=['SE']) == 3 + + assert R.dup_count_complex_roots(f, a, b, exclude=['SW', 'SE']) == 2 + assert R.dup_count_complex_roots(f, a, b, exclude=['SW', 'SE', 'S']) == 1 + assert R.dup_count_complex_roots(f, a, b, exclude=['SW', 'SE', 'S', 'N']) == 0 + + a, b = (QQ(0), QQ(0)), (QQ(1), QQ(1)) + + assert R.dup_count_complex_roots(f, a, b, exclude=True) == 1 + + +def test_dup_isolate_complex_roots_sqf(): + R, x = ring("x", ZZ) + f = x**2 - 2*x + 3 + + assert R.dup_isolate_complex_roots_sqf(f) == \ + [((0, -6), (6, 0)), ((0, 0), (6, 6))] + assert [ r.as_tuple() for r in R.dup_isolate_complex_roots_sqf(f, blackbox=True) ] == \ + [((0, -6), (6, 0)), ((0, 0), (6, 6))] + + assert R.dup_isolate_complex_roots_sqf(f, eps=QQ(1, 10)) == \ + [((QQ(15, 16), -QQ(3, 2)), (QQ(33, 32), -QQ(45, 32))), + ((QQ(15, 16), QQ(45, 32)), (QQ(33, 32), QQ(3, 2)))] + assert R.dup_isolate_complex_roots_sqf(f, eps=QQ(1, 100)) == \ + [((QQ(255, 256), -QQ(363, 256)), (QQ(513, 512), -QQ(723, 512))), + ((QQ(255, 256), QQ(723, 512)), (QQ(513, 512), QQ(363, 256)))] + + f = 7*x**4 - 19*x**3 + 20*x**2 + 17*x + 20 + + assert R.dup_isolate_complex_roots_sqf(f) == \ + [((-QQ(40, 7), -QQ(40, 7)), (0, 0)), ((-QQ(40, 7), 0), (0, QQ(40, 7))), + ((0, -QQ(40, 7)), (QQ(40, 7), 0)), ((0, 0), (QQ(40, 7), QQ(40, 7)))] + + +def test_dup_isolate_all_roots_sqf(): + R, x = ring("x", ZZ) + f = 4*x**4 - x**3 + 2*x**2 + 5*x + + assert R.dup_isolate_all_roots_sqf(f) == \ + ([(-1, 0), (0, 0)], + [((0, -QQ(5, 2)), (QQ(5, 2), 0)), ((0, 0), (QQ(5, 2), QQ(5, 2)))]) + + assert R.dup_isolate_all_roots_sqf(f, eps=QQ(1, 10)) == \ + ([(QQ(-7, 8), QQ(-6, 7)), (0, 0)], + [((QQ(35, 64), -QQ(35, 32)), (QQ(5, 8), -QQ(65, 64))), ((QQ(35, 64), QQ(65, 64)), (QQ(5, 8), QQ(35, 32)))]) + + +def test_dup_isolate_all_roots(): + R, x = ring("x", ZZ) + f = 4*x**4 - x**3 + 2*x**2 + 5*x + + assert R.dup_isolate_all_roots(f) == \ + ([((-1, 0), 1), ((0, 0), 1)], + [(((0, -QQ(5, 2)), (QQ(5, 2), 0)), 1), + (((0, 0), (QQ(5, 2), QQ(5, 2))), 1)]) + + assert R.dup_isolate_all_roots(f, eps=QQ(1, 10)) == \ + ([((QQ(-7, 8), QQ(-6, 7)), 1), ((0, 0), 1)], + [(((QQ(35, 64), -QQ(35, 32)), (QQ(5, 8), -QQ(65, 64))), 1), + (((QQ(35, 64), QQ(65, 64)), (QQ(5, 8), QQ(35, 32))), 1)]) + + f = x**5 + x**4 - 2*x**3 - 2*x**2 + x + 1 + raises(NotImplementedError, lambda: R.dup_isolate_all_roots(f)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rootoftools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rootoftools.py new file mode 100644 index 0000000000000000000000000000000000000000..de9dbcabd0a7e2bed0c5adb7127041b4be058379 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_rootoftools.py @@ -0,0 +1,697 @@ +"""Tests for the implementation of RootOf class and related tools. """ + +from sympy.polys.polytools import Poly +import sympy.polys.rootoftools as rootoftools +from sympy.polys.rootoftools import (rootof, RootOf, CRootOf, RootSum, + _pure_key_dict as D) + +from sympy.polys.polyerrors import ( + MultivariatePolynomialError, + GeneratorsNeeded, + PolynomialError, +) + +from sympy.core.function import (Function, Lambda) +from sympy.core.numbers import (Float, I, Rational) +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import tan +from sympy.integrals.integrals import Integral +from sympy.polys.orthopolys import legendre_poly +from sympy.solvers.solvers import solve + + +from sympy.testing.pytest import raises, slow +from sympy.core.expr import unchanged + +from sympy.abc import a, b, x, y, z, r + + +def test_CRootOf___new__(): + assert rootof(x, 0) == 0 + assert rootof(x, -1) == 0 + + assert rootof(x, S.Zero) == 0 + + assert rootof(x - 1, 0) == 1 + assert rootof(x - 1, -1) == 1 + + assert rootof(x + 1, 0) == -1 + assert rootof(x + 1, -1) == -1 + + assert rootof(x**2 + 2*x + 3, 0) == -1 - I*sqrt(2) + assert rootof(x**2 + 2*x + 3, 1) == -1 + I*sqrt(2) + assert rootof(x**2 + 2*x + 3, -1) == -1 + I*sqrt(2) + assert rootof(x**2 + 2*x + 3, -2) == -1 - I*sqrt(2) + + r = rootof(x**2 + 2*x + 3, 0, radicals=False) + assert isinstance(r, RootOf) is True + + r = rootof(x**2 + 2*x + 3, 1, radicals=False) + assert isinstance(r, RootOf) is True + + r = rootof(x**2 + 2*x + 3, -1, radicals=False) + assert isinstance(r, RootOf) is True + + r = rootof(x**2 + 2*x + 3, -2, radicals=False) + assert isinstance(r, RootOf) is True + + assert rootof((x - 1)*(x + 1), 0, radicals=False) == -1 + assert rootof((x - 1)*(x + 1), 1, radicals=False) == 1 + assert rootof((x - 1)*(x + 1), -1, radicals=False) == 1 + assert rootof((x - 1)*(x + 1), -2, radicals=False) == -1 + + assert rootof((x - 1)*(x + 1), 0, radicals=True) == -1 + assert rootof((x - 1)*(x + 1), 1, radicals=True) == 1 + assert rootof((x - 1)*(x + 1), -1, radicals=True) == 1 + assert rootof((x - 1)*(x + 1), -2, radicals=True) == -1 + + assert rootof((x - 1)*(x**3 + x + 3), 0) == rootof(x**3 + x + 3, 0) + assert rootof((x - 1)*(x**3 + x + 3), 1) == 1 + assert rootof((x - 1)*(x**3 + x + 3), 2) == rootof(x**3 + x + 3, 1) + assert rootof((x - 1)*(x**3 + x + 3), 3) == rootof(x**3 + x + 3, 2) + assert rootof((x - 1)*(x**3 + x + 3), -1) == rootof(x**3 + x + 3, 2) + assert rootof((x - 1)*(x**3 + x + 3), -2) == rootof(x**3 + x + 3, 1) + assert rootof((x - 1)*(x**3 + x + 3), -3) == 1 + assert rootof((x - 1)*(x**3 + x + 3), -4) == rootof(x**3 + x + 3, 0) + + assert rootof(x**4 + 3*x**3, 0) == -3 + assert rootof(x**4 + 3*x**3, 1) == 0 + assert rootof(x**4 + 3*x**3, 2) == 0 + assert rootof(x**4 + 3*x**3, 3) == 0 + + raises(GeneratorsNeeded, lambda: rootof(0, 0)) + raises(GeneratorsNeeded, lambda: rootof(1, 0)) + + raises(PolynomialError, lambda: rootof(Poly(0, x), 0)) + raises(PolynomialError, lambda: rootof(Poly(1, x), 0)) + raises(PolynomialError, lambda: rootof(x - y, 0)) + # issue 8617 + raises(PolynomialError, lambda: rootof(exp(x), 0)) + + raises(NotImplementedError, lambda: rootof(x**3 - x + sqrt(2), 0)) + raises(NotImplementedError, lambda: rootof(x**3 - x + I, 0)) + + raises(IndexError, lambda: rootof(x**2 - 1, -4)) + raises(IndexError, lambda: rootof(x**2 - 1, -3)) + raises(IndexError, lambda: rootof(x**2 - 1, 2)) + raises(IndexError, lambda: rootof(x**2 - 1, 3)) + raises(ValueError, lambda: rootof(x**2 - 1, x)) + + assert rootof(Poly(x - y, x), 0) == y + + assert rootof(Poly(x**2 - y, x), 0) == -sqrt(y) + assert rootof(Poly(x**2 - y, x), 1) == sqrt(y) + + assert rootof(Poly(x**3 - y, x), 0) == y**Rational(1, 3) + + assert rootof(y*x**3 + y*x + 2*y, x, 0) == -1 + raises(NotImplementedError, lambda: rootof(x**3 + x + 2*y, x, 0)) + + assert rootof(x**3 + x + 1, 0).is_commutative is True + + +def test_CRootOf_attributes(): + r = rootof(x**3 + x + 3, 0) + assert r.is_number + assert r.free_symbols == set() + # if the following assertion fails then multivariate polynomials + # are apparently supported and the RootOf.free_symbols routine + # should be changed to return whatever symbols would not be + # the PurePoly dummy symbol + raises(NotImplementedError, lambda: rootof(Poly(x**3 + y*x + 1, x), 0)) + + +def test_CRootOf___eq__(): + assert (rootof(x**3 + x + 3, 0) == rootof(x**3 + x + 3, 0)) is True + assert (rootof(x**3 + x + 3, 0) == rootof(x**3 + x + 3, 1)) is False + assert (rootof(x**3 + x + 3, 1) == rootof(x**3 + x + 3, 1)) is True + assert (rootof(x**3 + x + 3, 1) == rootof(x**3 + x + 3, 2)) is False + assert (rootof(x**3 + x + 3, 2) == rootof(x**3 + x + 3, 2)) is True + + assert (rootof(x**3 + x + 3, 0) == rootof(y**3 + y + 3, 0)) is True + assert (rootof(x**3 + x + 3, 0) == rootof(y**3 + y + 3, 1)) is False + assert (rootof(x**3 + x + 3, 1) == rootof(y**3 + y + 3, 1)) is True + assert (rootof(x**3 + x + 3, 1) == rootof(y**3 + y + 3, 2)) is False + assert (rootof(x**3 + x + 3, 2) == rootof(y**3 + y + 3, 2)) is True + + +def test_CRootOf___eval_Eq__(): + f = Function('f') + eq = x**3 + x + 3 + r = rootof(eq, 2) + r1 = rootof(eq, 1) + assert Eq(r, r1) is S.false + assert Eq(r, r) is S.true + assert unchanged(Eq, r, x) + assert Eq(r, 0) is S.false + assert Eq(r, S.Infinity) is S.false + assert Eq(r, I) is S.false + assert unchanged(Eq, r, f(0)) + sol = solve(eq) + for s in sol: + if s.is_real: + assert Eq(r, s) is S.false + r = rootof(eq, 0) + for s in sol: + if s.is_real: + assert Eq(r, s) is S.true + eq = x**3 + x + 1 + sol = solve(eq) + assert [Eq(rootof(eq, i), j) for i in range(3) for j in sol + ].count(True) == 3 + assert Eq(rootof(eq, 0), 1 + S.ImaginaryUnit) == False + + +def test_CRootOf_is_real(): + assert rootof(x**3 + x + 3, 0).is_real is True + assert rootof(x**3 + x + 3, 1).is_real is False + assert rootof(x**3 + x + 3, 2).is_real is False + + +def test_CRootOf_is_complex(): + assert rootof(x**3 + x + 3, 0).is_complex is True + + +def test_CRootOf_is_algebraic(): + assert rootof(x**3 + x + 3, 0).is_algebraic is True + assert rootof(x**3 + x + 3, 1).is_algebraic is True + assert rootof(x**3 + x + 3, 2).is_algebraic is True + + +def test_CRootOf_subs(): + assert rootof(x**3 + x + 1, 0).subs(x, y) == rootof(y**3 + y + 1, 0) + + +def test_CRootOf_diff(): + assert rootof(x**3 + x + 1, 0).diff(x) == 0 + assert rootof(x**3 + x + 1, 0).diff(y) == 0 + +@slow +def test_CRootOf_evalf(): + real = rootof(x**3 + x + 3, 0).evalf(n=20) + + assert real.epsilon_eq(Float("-1.2134116627622296341")) + + re, im = rootof(x**3 + x + 3, 1).evalf(n=20).as_real_imag() + + assert re.epsilon_eq( Float("0.60670583138111481707")) + assert im.epsilon_eq(-Float("1.45061224918844152650")) + + re, im = rootof(x**3 + x + 3, 2).evalf(n=20).as_real_imag() + + assert re.epsilon_eq(Float("0.60670583138111481707")) + assert im.epsilon_eq(Float("1.45061224918844152650")) + + p = legendre_poly(4, x, polys=True) + roots = [str(r.n(17)) for r in p.real_roots()] + # magnitudes are given by + # sqrt(3/S(7) - 2*sqrt(6/S(5))/7) + # and + # sqrt(3/S(7) + 2*sqrt(6/S(5))/7) + assert roots == [ + "-0.86113631159405258", + "-0.33998104358485626", + "0.33998104358485626", + "0.86113631159405258", + ] + + re = rootof(x**5 - 5*x + 12, 0).evalf(n=20) + assert re.epsilon_eq(Float("-1.84208596619025438271")) + + re, im = rootof(x**5 - 5*x + 12, 1).evalf(n=20).as_real_imag() + assert re.epsilon_eq(Float("-0.351854240827371999559")) + assert im.epsilon_eq(Float("-1.709561043370328882010")) + + re, im = rootof(x**5 - 5*x + 12, 2).evalf(n=20).as_real_imag() + assert re.epsilon_eq(Float("-0.351854240827371999559")) + assert im.epsilon_eq(Float("+1.709561043370328882010")) + + re, im = rootof(x**5 - 5*x + 12, 3).evalf(n=20).as_real_imag() + assert re.epsilon_eq(Float("+1.272897223922499190910")) + assert im.epsilon_eq(Float("-0.719798681483861386681")) + + re, im = rootof(x**5 - 5*x + 12, 4).evalf(n=20).as_real_imag() + assert re.epsilon_eq(Float("+1.272897223922499190910")) + assert im.epsilon_eq(Float("+0.719798681483861386681")) + + # issue 6393 + assert str(rootof(x**5 + 2*x**4 + x**3 - 68719476736, 0).n(3)) == '147.' + eq = (531441*x**11 + 3857868*x**10 + 13730229*x**9 + 32597882*x**8 + + 55077472*x**7 + 60452000*x**6 + 32172064*x**5 - 4383808*x**4 - + 11942912*x**3 - 1506304*x**2 + 1453312*x + 512) + a, b = rootof(eq, 1).n(2).as_real_imag() + c, d = rootof(eq, 2).n(2).as_real_imag() + assert a == c + assert b < d + assert b == -d + # issue 6451 + r = rootof(legendre_poly(64, x), 7) + assert r.n(2) == r.n(100).n(2) + # issue 9019 + r0 = rootof(x**2 + 1, 0, radicals=False) + r1 = rootof(x**2 + 1, 1, radicals=False) + assert r0.n(4) == Float(-1.0, 4) * I + assert r1.n(4) == Float(1.0, 4) * I + + # make sure verification is used in case a max/min traps the "root" + assert str(rootof(4*x**5 + 16*x**3 + 12*x**2 + 7, 0).n(3)) == '-0.976' + + # watch out for UnboundLocalError + c = CRootOf(90720*x**6 - 4032*x**4 + 84*x**2 - 1, 0) + assert c._eval_evalf(2) # doesn't fail + + # watch out for imaginary parts that don't want to evaluate + assert str(RootOf(x**16 + 32*x**14 + 508*x**12 + 5440*x**10 + + 39510*x**8 + 204320*x**6 + 755548*x**4 + 1434496*x**2 + + 877969, 10).n(2)) == '-3.4*I' + assert abs(RootOf(x**4 + 10*x**2 + 1, 0).n(2)) < 0.4 + + # check reset and args + r = [RootOf(x**3 + x + 3, i) for i in range(3)] + r[0]._reset() + for ri in r: + i = ri._get_interval() + ri.n(2) + assert i != ri._get_interval() + ri._reset() + assert i == ri._get_interval() + assert i == i.func(*i.args) + + +def test_issue_24978(): + # Irreducible poly with negative leading coeff is normalized + # (factor of -1 is extracted), before being stored as CRootOf.poly. + f = -x**2 + 2 + r = CRootOf(f, 0) + assert r.poly.as_expr() == x**2 - 2 + # An action that prompts calculation of an interval puts r.poly in + # the cache. + r.n() + assert r.poly in rootoftools._reals_cache + + +def test_CRootOf_evalf_caching_bug(): + r = rootof(x**5 - 5*x + 12, 1) + r.n() + a = r._get_interval() + r = rootof(x**5 - 5*x + 12, 1) + r.n() + b = r._get_interval() + assert a == b + + +def test_CRootOf_real_roots(): + assert Poly(x**5 + x + 1).real_roots() == [rootof(x**3 - x**2 + 1, 0)] + assert Poly(x**5 + x + 1).real_roots(radicals=False) == [rootof( + x**3 - x**2 + 1, 0)] + + # https://github.com/sympy/sympy/issues/20902 + p = Poly(-3*x**4 - 10*x**3 - 12*x**2 - 6*x - 1, x, domain='ZZ') + assert CRootOf.real_roots(p) == [S(-1), S(-1), S(-1), S(-1)/3] + + # with real algebraic coefficients + assert Poly(x**3 + sqrt(2)*x**2 - 1, x, extension=True).real_roots() == [ + rootof(x**6 - 2*x**4 - 2*x**3 + 1, 0) + ] + assert Poly(x**5 + sqrt(2) * x**3 - 1, x, extension=True).real_roots() == [ + rootof(x**10 - 2*x**6 - 2*x**5 + 1, 0) + ] + r = rootof(y**5 + y**3 - 1, 0) + assert Poly(x**5 + r*x - 1, x, extension=True).real_roots() ==\ + [ + rootof(x**25 - 5*x**20 + x**17 + 10*x**15 - 3*x**12 - + 10*x**10 + 3*x**7 + 6*x**5 - x**2 - 1, 0) + ] + # roots with multiplicity + assert Poly((x-1) * (x-sqrt(2))**2, x, extension=True).real_roots() ==\ + [ + S(1), sqrt(2), sqrt(2) + ] + + +def test_CRootOf_all_roots(): + assert Poly(x**5 + x + 1).all_roots() == [ + rootof(x**3 - x**2 + 1, 0), + Rational(-1, 2) - sqrt(3)*I/2, + Rational(-1, 2) + sqrt(3)*I/2, + rootof(x**3 - x**2 + 1, 1), + rootof(x**3 - x**2 + 1, 2), + ] + + assert Poly(x**5 + x + 1).all_roots(radicals=False) == [ + rootof(x**3 - x**2 + 1, 0), + rootof(x**2 + x + 1, 0, radicals=False), + rootof(x**2 + x + 1, 1, radicals=False), + rootof(x**3 - x**2 + 1, 1), + rootof(x**3 - x**2 + 1, 2), + ] + + # with real algebraic coefficients + assert Poly(x**3 + sqrt(2)*x**2 - 1, x, extension=True).all_roots() ==\ + [ + rootof(x**6 - 2*x**4 - 2*x**3 + 1, 0), + rootof(x**6 - 2*x**4 - 2*x**3 + 1, 2), + rootof(x**6 - 2*x**4 - 2*x**3 + 1, 3) + ] + # roots with multiplicity + assert Poly((x-1) * (x-sqrt(2))**2 * (x-I) * (x+I), x, extension=True).all_roots() ==\ + [ + S(1), sqrt(2), sqrt(2), -I, I + ] + + # imaginary algebraic coeffs (gaussian domain) + assert Poly(x**2 - I/2, x, extension=True).all_roots() ==\ + [ + S(1)/2 + I/2, + -S(1)/2 - I/2 + ] + + +def test_CRootOf_eval_rational(): + p = legendre_poly(4, x, polys=True) + roots = [r.eval_rational(n=18) for r in p.real_roots()] + for root in roots: + assert isinstance(root, Rational) + roots = [str(root.n(17)) for root in roots] + assert roots == [ + "-0.86113631159405258", + "-0.33998104358485626", + "0.33998104358485626", + "0.86113631159405258", + ] + + +def test_CRootOf_lazy(): + # irreducible poly with both real and complex roots: + f = Poly(x**3 + 2*x + 2) + + # real root: + CRootOf.clear_cache() + r = CRootOf(f, 0) + # Not yet in cache, after construction: + assert r.poly not in rootoftools._reals_cache + assert r.poly not in rootoftools._complexes_cache + r.evalf() + # In cache after evaluation: + assert r.poly in rootoftools._reals_cache + assert r.poly not in rootoftools._complexes_cache + + # complex root: + CRootOf.clear_cache() + r = CRootOf(f, 1) + # Not yet in cache, after construction: + assert r.poly not in rootoftools._reals_cache + assert r.poly not in rootoftools._complexes_cache + r.evalf() + # In cache after evaluation: + assert r.poly in rootoftools._reals_cache + assert r.poly in rootoftools._complexes_cache + + # composite poly with both real and complex roots: + f = Poly((x**2 - 2)*(x**2 + 1)) + + # real root: + CRootOf.clear_cache() + r = CRootOf(f, 0) + # In cache immediately after construction: + assert r.poly in rootoftools._reals_cache + assert r.poly not in rootoftools._complexes_cache + + # complex root: + CRootOf.clear_cache() + r = CRootOf(f, 2) + # In cache immediately after construction: + assert r.poly in rootoftools._reals_cache + assert r.poly in rootoftools._complexes_cache + + +def test_RootSum___new__(): + f = x**3 + x + 3 + + g = Lambda(r, log(r*x)) + s = RootSum(f, g) + + assert isinstance(s, RootSum) is True + + assert RootSum(f**2, g) == 2*RootSum(f, g) + assert RootSum((x - 7)*f**3, g) == log(7*x) + 3*RootSum(f, g) + + # issue 5571 + assert hash(RootSum((x - 7)*f**3, g)) == hash(log(7*x) + 3*RootSum(f, g)) + + raises(MultivariatePolynomialError, lambda: RootSum(x**3 + x + y)) + raises(ValueError, lambda: RootSum(x**2 + 3, lambda x: x)) + + assert RootSum(f, exp) == RootSum(f, Lambda(x, exp(x))) + assert RootSum(f, log) == RootSum(f, Lambda(x, log(x))) + + assert isinstance(RootSum(f, auto=False), RootSum) is True + + assert RootSum(f) == 0 + assert RootSum(f, Lambda(x, x)) == 0 + assert RootSum(f, Lambda(x, x**2)) == -2 + + assert RootSum(f, Lambda(x, 1)) == 3 + assert RootSum(f, Lambda(x, 2)) == 6 + + assert RootSum(f, auto=False).is_commutative is True + + assert RootSum(f, Lambda(x, 1/(x + x**2))) == Rational(11, 3) + assert RootSum(f, Lambda(x, y/(x + x**2))) == Rational(11, 3)*y + + assert RootSum(x**2 - 1, Lambda(x, 3*x**2), x) == 6 + assert RootSum(x**2 - y, Lambda(x, 3*x**2), x) == 6*y + + assert RootSum(x**2 - 1, Lambda(x, z*x**2), x) == 2*z + assert RootSum(x**2 - y, Lambda(x, z*x**2), x) == 2*z*y + + assert RootSum( + x**2 - 1, Lambda(x, exp(x)), quadratic=True) == exp(-1) + exp(1) + + assert RootSum(x**3 + a*x + a**3, tan, x) == \ + RootSum(x**3 + x + 1, Lambda(x, tan(a*x))) + assert RootSum(a**3*x**3 + a*x + 1, tan, x) == \ + RootSum(x**3 + x + 1, Lambda(x, tan(x/a))) + + +def test_RootSum_free_symbols(): + assert RootSum(x**3 + x + 3, Lambda(r, exp(r))).free_symbols == set() + assert RootSum(x**3 + x + 3, Lambda(r, exp(a*r))).free_symbols == {a} + assert RootSum( + x**3 + x + y, Lambda(r, exp(a*r)), x).free_symbols == {a, y} + + +def test_RootSum___eq__(): + f = Lambda(x, exp(x)) + + assert (RootSum(x**3 + x + 1, f) == RootSum(x**3 + x + 1, f)) is True + assert (RootSum(x**3 + x + 1, f) == RootSum(y**3 + y + 1, f)) is True + + assert (RootSum(x**3 + x + 1, f) == RootSum(x**3 + x + 2, f)) is False + assert (RootSum(x**3 + x + 1, f) == RootSum(y**3 + y + 2, f)) is False + + +def test_RootSum_doit(): + rs = RootSum(x**2 + 1, exp) + + assert isinstance(rs, RootSum) is True + assert rs.doit() == exp(-I) + exp(I) + + rs = RootSum(x**2 + a, exp, x) + + assert isinstance(rs, RootSum) is True + assert rs.doit() == exp(-sqrt(-a)) + exp(sqrt(-a)) + + +def test_RootSum_evalf(): + rs = RootSum(x**2 + 1, exp) + + assert rs.evalf(n=20, chop=True).epsilon_eq(Float("1.0806046117362794348")) + assert rs.evalf(n=15, chop=True).epsilon_eq(Float("1.08060461173628")) + + rs = RootSum(x**2 + a, exp, x) + + assert rs.evalf() == rs + + +def test_RootSum_diff(): + f = x**3 + x + 3 + + g = Lambda(r, exp(r*x)) + h = Lambda(r, r*exp(r*x)) + + assert RootSum(f, g).diff(x) == RootSum(f, h) + + +def test_RootSum_subs(): + f = x**3 + x + 3 + g = Lambda(r, exp(r*x)) + + F = y**3 + y + 3 + G = Lambda(r, exp(r*y)) + + assert RootSum(f, g).subs(y, 1) == RootSum(f, g) + assert RootSum(f, g).subs(x, y) == RootSum(F, G) + + +def test_RootSum_rational(): + assert RootSum( + z**5 - z + 1, Lambda(z, z/(x - z))) == (4*x - 5)/(x**5 - x + 1) + + f = 161*z**3 + 115*z**2 + 19*z + 1 + g = Lambda(z, z*log( + -3381*z**4/4 - 3381*z**3/4 - 625*z**2/2 - z*Rational(125, 2) - 5 + exp(x))) + + assert RootSum(f, g).diff(x) == -( + (5*exp(2*x) - 6*exp(x) + 4)*exp(x)/(exp(3*x) - exp(2*x) + 1))/7 + + +def test_RootSum_independent(): + f = (x**3 - a)**2*(x**4 - b)**3 + + g = Lambda(x, 5*tan(x) + 7) + h = Lambda(x, tan(x)) + + r0 = RootSum(x**3 - a, h, x) + r1 = RootSum(x**4 - b, h, x) + + assert RootSum(f, g, x).as_ordered_terms() == [10*r0, 15*r1, 126] + + +def test_issue_7876(): + l1 = Poly(x**6 - x + 1, x).all_roots() + l2 = [rootof(x**6 - x + 1, i) for i in range(6)] + assert frozenset(l1) == frozenset(l2) + + +def test_issue_8316(): + f = Poly(7*x**8 - 9) + assert len(f.all_roots()) == 8 + f = Poly(7*x**8 - 10) + assert len(f.all_roots()) == 8 + + +def test__imag_count(): + from sympy.polys.rootoftools import _imag_count_of_factor + def imag_count(p): + return sum(_imag_count_of_factor(f)*m for f, m in + p.factor_list()[1]) + assert imag_count(Poly(x**6 + 10*x**2 + 1)) == 2 + assert imag_count(Poly(x**2)) == 0 + assert imag_count(Poly([1]*3 + [-1], x)) == 0 + assert imag_count(Poly(x**3 + 1)) == 0 + assert imag_count(Poly(x**2 + 1)) == 2 + assert imag_count(Poly(x**2 - 1)) == 0 + assert imag_count(Poly(x**4 - 1)) == 2 + assert imag_count(Poly(x**4 + 1)) == 0 + assert imag_count(Poly([1, 2, 3], x)) == 0 + assert imag_count(Poly(x**3 + x + 1)) == 0 + assert imag_count(Poly(x**4 + x + 1)) == 0 + def q(r1, r2, p): + return Poly(((x - r1)*(x - r2)).subs(x, x**p), x) + assert imag_count(q(-1, -2, 2)) == 4 + assert imag_count(q(-1, 2, 2)) == 2 + assert imag_count(q(1, 2, 2)) == 0 + assert imag_count(q(1, 2, 4)) == 4 + assert imag_count(q(-1, 2, 4)) == 2 + assert imag_count(q(-1, -2, 4)) == 0 + + +def test_RootOf_is_imaginary(): + r = RootOf(x**4 + 4*x**2 + 1, 1) + i = r._get_interval() + assert r.is_imaginary and i.ax*i.bx <= 0 + + +def test_is_disjoint(): + eq = x**3 + 5*x + 1 + ir = rootof(eq, 0)._get_interval() + ii = rootof(eq, 1)._get_interval() + assert ir.is_disjoint(ii) + assert ii.is_disjoint(ir) + + +def test_pure_key_dict(): + p = D() + assert (x in p) is False + assert (1 in p) is False + p[x] = 1 + assert x in p + assert y in p + assert p[y] == 1 + raises(KeyError, lambda: p[1]) + def dont(k): + p[k] = 2 + raises(ValueError, lambda: dont(1)) + + +@slow +def test_eval_approx_relative(): + CRootOf.clear_cache() + t = [CRootOf(x**3 + 10*x + 1, i) for i in range(3)] + assert [i.eval_rational(1e-1) for i in t] == [ + Rational(-21, 220), Rational(15, 256) - I*805/256, + Rational(15, 256) + I*805/256] + t[0]._reset() + assert [i.eval_rational(1e-1, 1e-4) for i in t] == [ + Rational(-21, 220), Rational(3275, 65536) - I*414645/131072, + Rational(3275, 65536) + I*414645/131072] + assert S(t[0]._get_interval().dx) < 1e-1 + assert S(t[1]._get_interval().dx) < 1e-1 + assert S(t[1]._get_interval().dy) < 1e-4 + assert S(t[2]._get_interval().dx) < 1e-1 + assert S(t[2]._get_interval().dy) < 1e-4 + t[0]._reset() + assert [i.eval_rational(1e-4, 1e-4) for i in t] == [ + Rational(-2001, 20020), Rational(6545, 131072) - I*414645/131072, + Rational(6545, 131072) + I*414645/131072] + assert S(t[0]._get_interval().dx) < 1e-4 + assert S(t[1]._get_interval().dx) < 1e-4 + assert S(t[1]._get_interval().dy) < 1e-4 + assert S(t[2]._get_interval().dx) < 1e-4 + assert S(t[2]._get_interval().dy) < 1e-4 + # in the following, the actual relative precision is + # less than tested, but it should never be greater + t[0]._reset() + assert [i.eval_rational(n=2) for i in t] == [ + Rational(-202201, 2024022), Rational(104755, 2097152) - I*6634255/2097152, + Rational(104755, 2097152) + I*6634255/2097152] + assert abs(S(t[0]._get_interval().dx)/t[0]) < 1e-2 + assert abs(S(t[1]._get_interval().dx)/t[1]).n() < 1e-2 + assert abs(S(t[1]._get_interval().dy)/t[1]).n() < 1e-2 + assert abs(S(t[2]._get_interval().dx)/t[2]).n() < 1e-2 + assert abs(S(t[2]._get_interval().dy)/t[2]).n() < 1e-2 + t[0]._reset() + assert [i.eval_rational(n=3) for i in t] == [ + Rational(-202201, 2024022), Rational(1676045, 33554432) - I*106148135/33554432, + Rational(1676045, 33554432) + I*106148135/33554432] + assert abs(S(t[0]._get_interval().dx)/t[0]) < 1e-3 + assert abs(S(t[1]._get_interval().dx)/t[1]).n() < 1e-3 + assert abs(S(t[1]._get_interval().dy)/t[1]).n() < 1e-3 + assert abs(S(t[2]._get_interval().dx)/t[2]).n() < 1e-3 + assert abs(S(t[2]._get_interval().dy)/t[2]).n() < 1e-3 + + t[0]._reset() + a = [i.eval_approx(2) for i in t] + assert [str(i) for i in a] == [ + '-0.10', '0.05 - 3.2*I', '0.05 + 3.2*I'] + assert all(abs(((a[i] - t[i])/t[i]).n()) < 1e-2 for i in range(len(a))) + + +def test_issue_15920(): + r = rootof(x**5 - x + 1, 0) + p = Integral(x, (x, 1, y)) + assert unchanged(Eq, r, p) + + +def test_issue_19113(): + eq = y**3 - y + 1 + # generator is a canonical x in RootOf + assert str(Poly(eq).real_roots()) == '[CRootOf(x**3 - x + 1, 0)]' + assert str(Poly(eq.subs(y, tan(y))).real_roots() + ) == '[CRootOf(x**3 - x + 1, 0)]' + assert str(Poly(eq.subs(y, tan(x))).real_roots() + ) == '[CRootOf(x**3 - x + 1, 0)]' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_solvers.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_solvers.py new file mode 100644 index 0000000000000000000000000000000000000000..bf8708314466b6a8676ba1a4438eb84924d0030c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_solvers.py @@ -0,0 +1,112 @@ +"""Tests for low-level linear systems solver. """ + +from sympy.matrices import Matrix +from sympy.polys.domains import ZZ, QQ +from sympy.polys.fields import field +from sympy.polys.rings import ring +from sympy.polys.solvers import solve_lin_sys, eqs_to_matrix + + +def test_solve_lin_sys_2x2_one(): + domain, x1,x2 = ring("x1,x2", QQ) + eqs = [x1 + x2 - 5, + 2*x1 - x2] + sol = {x1: QQ(5, 3), x2: QQ(10, 3)} + _sol = solve_lin_sys(eqs, domain) + assert _sol == sol and all(s.ring == domain for s in _sol) + +def test_solve_lin_sys_2x4_none(): + domain, x1,x2 = ring("x1,x2", QQ) + eqs = [x1 - 1, + x1 - x2, + x1 - 2*x2, + x2 - 1] + assert solve_lin_sys(eqs, domain) is None + + +def test_solve_lin_sys_3x4_one(): + domain, x1,x2,x3 = ring("x1,x2,x3", QQ) + eqs = [x1 + 2*x2 + 3*x3, + 2*x1 - x2 + x3, + 3*x1 + x2 + x3, + 5*x2 + 2*x3] + sol = {x1: 0, x2: 0, x3: 0} + assert solve_lin_sys(eqs, domain) == sol + +def test_solve_lin_sys_3x3_inf(): + domain, x1,x2,x3 = ring("x1,x2,x3", QQ) + eqs = [x1 - x2 + 2*x3 - 1, + 2*x1 + x2 + x3 - 8, + x1 + x2 - 5] + sol = {x1: -x3 + 3, x2: x3 + 2} + assert solve_lin_sys(eqs, domain) == sol + +def test_solve_lin_sys_3x4_none(): + domain, x1,x2,x3,x4 = ring("x1,x2,x3,x4", QQ) + eqs = [2*x1 + x2 + 7*x3 - 7*x4 - 2, + -3*x1 + 4*x2 - 5*x3 - 6*x4 - 3, + x1 + x2 + 4*x3 - 5*x4 - 2] + assert solve_lin_sys(eqs, domain) is None + + +def test_solve_lin_sys_4x7_inf(): + domain, x1,x2,x3,x4,x5,x6,x7 = ring("x1,x2,x3,x4,x5,x6,x7", QQ) + eqs = [x1 + 4*x2 - x4 + 7*x6 - 9*x7 - 3, + 2*x1 + 8*x2 - x3 + 3*x4 + 9*x5 - 13*x6 + 7*x7 - 9, + 2*x3 - 3*x4 - 4*x5 + 12*x6 - 8*x7 - 1, + -x1 - 4*x2 + 2*x3 + 4*x4 + 8*x5 - 31*x6 + 37*x7 - 4] + sol = {x1: 4 - 4*x2 - 2*x5 - x6 + 3*x7, + x3: 2 - x5 + 3*x6 - 5*x7, + x4: 1 - 2*x5 + 6*x6 - 6*x7} + assert solve_lin_sys(eqs, domain) == sol + +def test_solve_lin_sys_5x5_inf(): + domain, x1,x2,x3,x4,x5 = ring("x1,x2,x3,x4,x5", QQ) + eqs = [x1 - x2 - 2*x3 + x4 + 11*x5 - 13, + x1 - x2 + x3 + x4 + 5*x5 - 16, + 2*x1 - 2*x2 + x4 + 10*x5 - 21, + 2*x1 - 2*x2 - x3 + 3*x4 + 20*x5 - 38, + 2*x1 - 2*x2 + x3 + x4 + 8*x5 - 22] + sol = {x1: 6 + x2 - 3*x5, + x3: 1 + 2*x5, + x4: 9 - 4*x5} + assert solve_lin_sys(eqs, domain) == sol + +def test_solve_lin_sys_6x6_1(): + ground, d,r,e,g,i,j,l,o,m,p,q = field("d,r,e,g,i,j,l,o,m,p,q", ZZ) + domain, c,f,h,k,n,b = ring("c,f,h,k,n,b", ground) + + eqs = [b + q/d - c/d, c*(1/d + 1/e + 1/g) - f/g - q/d, f*(1/g + 1/i + 1/j) - c/g - h/i, h*(1/i + 1/l + 1/m) - f/i - k/m, k*(1/m + 1/o + 1/p) - h/m - n/p, n/p - k/p] + sol = { + b: (e*i*l*q + e*i*m*q + e*i*o*q + e*j*l*q + e*j*m*q + e*j*o*q + e*l*m*q + e*l*o*q + g*i*l*q + g*i*m*q + g*i*o*q + g*j*l*q + g*j*m*q + g*j*o*q + g*l*m*q + g*l*o*q + i*j*l*q + i*j*m*q + i*j*o*q + j*l*m*q + j*l*o*q)/(-d*e*i*l - d*e*i*m - d*e*i*o - d*e*j*l - d*e*j*m - d*e*j*o - d*e*l*m - d*e*l*o - d*g*i*l - d*g*i*m - d*g*i*o - d*g*j*l - d*g*j*m - d*g*j*o - d*g*l*m - d*g*l*o - d*i*j*l - d*i*j*m - d*i*j*o - d*j*l*m - d*j*l*o - e*g*i*l - e*g*i*m - e*g*i*o - e*g*j*l - e*g*j*m - e*g*j*o - e*g*l*m - e*g*l*o - e*i*j*l - e*i*j*m - e*i*j*o - e*j*l*m - e*j*l*o), + c: (-e*g*i*l*q - e*g*i*m*q - e*g*i*o*q - e*g*j*l*q - e*g*j*m*q - e*g*j*o*q - e*g*l*m*q - e*g*l*o*q - e*i*j*l*q - e*i*j*m*q - e*i*j*o*q - e*j*l*m*q - e*j*l*o*q)/(-d*e*i*l - d*e*i*m - d*e*i*o - d*e*j*l - d*e*j*m - d*e*j*o - d*e*l*m - d*e*l*o - d*g*i*l - d*g*i*m - d*g*i*o - d*g*j*l - d*g*j*m - d*g*j*o - d*g*l*m - d*g*l*o - d*i*j*l - d*i*j*m - d*i*j*o - d*j*l*m - d*j*l*o - e*g*i*l - e*g*i*m - e*g*i*o - e*g*j*l - e*g*j*m - e*g*j*o - e*g*l*m - e*g*l*o - e*i*j*l - e*i*j*m - e*i*j*o - e*j*l*m - e*j*l*o), + f: (-e*i*j*l*q - e*i*j*m*q - e*i*j*o*q - e*j*l*m*q - e*j*l*o*q)/(-d*e*i*l - d*e*i*m - d*e*i*o - d*e*j*l - d*e*j*m - d*e*j*o - d*e*l*m - d*e*l*o - d*g*i*l - d*g*i*m - d*g*i*o - d*g*j*l - d*g*j*m - d*g*j*o - d*g*l*m - d*g*l*o - d*i*j*l - d*i*j*m - d*i*j*o - d*j*l*m - d*j*l*o - e*g*i*l - e*g*i*m - e*g*i*o - e*g*j*l - e*g*j*m - e*g*j*o - e*g*l*m - e*g*l*o - e*i*j*l - e*i*j*m - e*i*j*o - e*j*l*m - e*j*l*o), + h: (-e*j*l*m*q - e*j*l*o*q)/(-d*e*i*l - d*e*i*m - d*e*i*o - d*e*j*l - d*e*j*m - d*e*j*o - d*e*l*m - d*e*l*o - d*g*i*l - d*g*i*m - d*g*i*o - d*g*j*l - d*g*j*m - d*g*j*o - d*g*l*m - d*g*l*o - d*i*j*l - d*i*j*m - d*i*j*o - d*j*l*m - d*j*l*o - e*g*i*l - e*g*i*m - e*g*i*o - e*g*j*l - e*g*j*m - e*g*j*o - e*g*l*m - e*g*l*o - e*i*j*l - e*i*j*m - e*i*j*o - e*j*l*m - e*j*l*o), + k: e*j*l*o*q/(d*e*i*l + d*e*i*m + d*e*i*o + d*e*j*l + d*e*j*m + d*e*j*o + d*e*l*m + d*e*l*o + d*g*i*l + d*g*i*m + d*g*i*o + d*g*j*l + d*g*j*m + d*g*j*o + d*g*l*m + d*g*l*o + d*i*j*l + d*i*j*m + d*i*j*o + d*j*l*m + d*j*l*o + e*g*i*l + e*g*i*m + e*g*i*o + e*g*j*l + e*g*j*m + e*g*j*o + e*g*l*m + e*g*l*o + e*i*j*l + e*i*j*m + e*i*j*o + e*j*l*m + e*j*l*o), + n: e*j*l*o*q/(d*e*i*l + d*e*i*m + d*e*i*o + d*e*j*l + d*e*j*m + d*e*j*o + d*e*l*m + d*e*l*o + d*g*i*l + d*g*i*m + d*g*i*o + d*g*j*l + d*g*j*m + d*g*j*o + d*g*l*m + d*g*l*o + d*i*j*l + d*i*j*m + d*i*j*o + d*j*l*m + d*j*l*o + e*g*i*l + e*g*i*m + e*g*i*o + e*g*j*l + e*g*j*m + e*g*j*o + e*g*l*m + e*g*l*o + e*i*j*l + e*i*j*m + e*i*j*o + e*j*l*m + e*j*l*o), + } + + assert solve_lin_sys(eqs, domain) == sol + +def test_solve_lin_sys_6x6_2(): + ground, d,r,e,g,i,j,l,o,m,p,q = field("d,r,e,g,i,j,l,o,m,p,q", ZZ) + domain, c,f,h,k,n,b = ring("c,f,h,k,n,b", ground) + + eqs = [b + r/d - c/d, c*(1/d + 1/e + 1/g) - f/g - r/d, f*(1/g + 1/i + 1/j) - c/g - h/i, h*(1/i + 1/l + 1/m) - f/i - k/m, k*(1/m + 1/o + 1/p) - h/m - n/p, n*(1/p + 1/q) - k/p] + sol = { + b: -((l*q*e*o + l*q*g*o + i*m*q*e + i*l*q*e + i*l*p*e + i*j*o*q + j*e*o*q + g*j*o*q + i*e*o*q + g*i*o*q + e*l*o*p + e*l*m*p + e*l*m*o + e*i*o*p + e*i*m*p + e*i*m*o + e*i*l*o + j*e*o*p + j*e*m*q + j*e*m*p + j*e*m*o + j*l*m*q + j*l*m*p + j*l*m*o + i*j*m*p + i*j*m*o + i*j*l*q + i*j*l*o + i*j*m*q + j*l*o*p + j*e*l*o + g*j*o*p + g*j*m*q + g*j*m*p + i*j*l*p + i*j*o*p + j*e*l*q + j*e*l*p + j*l*o*q + g*j*m*o + g*j*l*q + g*j*l*p + g*j*l*o + g*l*o*p + g*l*m*p + g*l*m*o + g*i*m*o + g*i*o*p + g*i*m*q + g*i*m*p + g*i*l*q + g*i*l*p + g*i*l*o + l*m*q*e + l*m*q*g)*r)/(l*q*d*e*o + l*q*d*g*o + l*q*e*g*o + i*j*d*o*q + i*j*e*o*q + j*d*e*o*q + g*j*d*o*q + g*j*e*o*q + g*i*e*o*q + i*d*e*o*q + g*i*d*o*q + g*i*d*o*p + g*i*d*m*q + g*i*d*m*p + g*i*d*m*o + g*i*d*l*q + g*i*d*l*p + g*i*d*l*o + g*e*l*m*p + g*e*l*o*p + g*j*e*l*q + g*e*l*m*o + g*j*e*m*p + g*j*e*m*o + d*e*l*m*p + d*e*l*m*o + i*d*e*m*p + g*j*e*l*p + g*j*e*l*o + d*e*l*o*p + i*j*d*l*o + i*j*e*o*p + i*j*e*m*q + i*j*d*m*q + i*j*d*m*p + i*j*d*m*o + i*j*d*l*q + i*j*d*l*p + i*j*e*m*p + i*j*e*m*o + i*j*e*l*q + i*j*e*l*p + i*j*e*l*o + i*d*e*m*q + i*d*e*m*o + i*d*e*l*q + i*d*e*l*p + j*d*l*o*p + j*d*e*l*o + g*j*d*o*p + g*j*d*m*q + g*j*d*m*p + g*j*d*m*o + g*j*d*l*q + g*j*d*l*p + g*j*d*l*o + g*j*e*o*p + g*j*e*m*q + g*d*l*o*p + g*d*l*m*p + g*d*l*m*o + j*d*e*m*p + i*d*e*o*p + j*e*o*q*l + j*e*o*p*l + j*e*m*q*l + j*d*e*o*p + j*d*e*m*q + i*j*d*o*p + g*i*e*o*p + j*d*e*m*o + j*d*e*l*q + j*d*e*l*p + j*e*m*p*l + j*e*m*o*l + g*i*e*m*q + g*i*e*m*p + g*i*e*m*o + g*i*e*l*q + g*i*e*l*p + g*i*e*l*o + j*d*l*o*q + j*d*l*m*q + j*d*l*m*p + j*d*l*m*o + i*d*e*l*o + l*m*q*d*e + l*m*q*d*g + l*m*q*e*g), + c: (r*e*(l*q*g*o + i*j*o*q + g*j*o*q + g*i*o*q + j*l*m*q + j*l*m*p + j*l*m*o + i*j*m*p + i*j*m*o + i*j*l*q + i*j*l*o + i*j*m*q + j*l*o*p + g*j*o*p + g*j*m*q + g*j*m*p + i*j*l*p + i*j*o*p + j*l*o*q + g*j*m*o + g*j*l*q + g*j*l*p + g*j*l*o + g*l*o*p + g*l*m*p + g*l*m*o + g*i*m*o + g*i*o*p + g*i*m*q + g*i*m*p + g*i*l*q + g*i*l*p + g*i*l*o + l*m*q*g))/(l*q*d*e*o + l*q*d*g*o + l*q*e*g*o + i*j*d*o*q + i*j*e*o*q + j*d*e*o*q + g*j*d*o*q + g*j*e*o*q + g*i*e*o*q + i*d*e*o*q + g*i*d*o*q + g*i*d*o*p + g*i*d*m*q + g*i*d*m*p + g*i*d*m*o + g*i*d*l*q + g*i*d*l*p + g*i*d*l*o + g*e*l*m*p + g*e*l*o*p + g*j*e*l*q + g*e*l*m*o + g*j*e*m*p + g*j*e*m*o + d*e*l*m*p + d*e*l*m*o + i*d*e*m*p + g*j*e*l*p + g*j*e*l*o + d*e*l*o*p + i*j*d*l*o + i*j*e*o*p + i*j*e*m*q + i*j*d*m*q + i*j*d*m*p + i*j*d*m*o + i*j*d*l*q + i*j*d*l*p + i*j*e*m*p + i*j*e*m*o + i*j*e*l*q + i*j*e*l*p + i*j*e*l*o + i*d*e*m*q + i*d*e*m*o + i*d*e*l*q + i*d*e*l*p + j*d*l*o*p + j*d*e*l*o + g*j*d*o*p + g*j*d*m*q + g*j*d*m*p + g*j*d*m*o + g*j*d*l*q + g*j*d*l*p + g*j*d*l*o + g*j*e*o*p + g*j*e*m*q + g*d*l*o*p + g*d*l*m*p + g*d*l*m*o + j*d*e*m*p + i*d*e*o*p + j*e*o*q*l + j*e*o*p*l + j*e*m*q*l + j*d*e*o*p + j*d*e*m*q + i*j*d*o*p + g*i*e*o*p + j*d*e*m*o + j*d*e*l*q + j*d*e*l*p + j*e*m*p*l + j*e*m*o*l + g*i*e*m*q + g*i*e*m*p + g*i*e*m*o + g*i*e*l*q + g*i*e*l*p + g*i*e*l*o + j*d*l*o*q + j*d*l*m*q + j*d*l*m*p + j*d*l*m*o + i*d*e*l*o + l*m*q*d*e + l*m*q*d*g + l*m*q*e*g), + f: (r*e*j*(l*q*o + l*o*p + l*m*q + l*m*p + l*m*o + i*o*q + i*o*p + i*m*q + i*m*p + i*m*o + i*l*q + i*l*p + i*l*o))/(l*q*d*e*o + l*q*d*g*o + l*q*e*g*o + i*j*d*o*q + i*j*e*o*q + j*d*e*o*q + g*j*d*o*q + g*j*e*o*q + g*i*e*o*q + i*d*e*o*q + g*i*d*o*q + g*i*d*o*p + g*i*d*m*q + g*i*d*m*p + g*i*d*m*o + g*i*d*l*q + g*i*d*l*p + g*i*d*l*o + g*e*l*m*p + g*e*l*o*p + g*j*e*l*q + g*e*l*m*o + g*j*e*m*p + g*j*e*m*o + d*e*l*m*p + d*e*l*m*o + i*d*e*m*p + g*j*e*l*p + g*j*e*l*o + d*e*l*o*p + i*j*d*l*o + i*j*e*o*p + i*j*e*m*q + i*j*d*m*q + i*j*d*m*p + i*j*d*m*o + i*j*d*l*q + i*j*d*l*p + i*j*e*m*p + i*j*e*m*o + i*j*e*l*q + i*j*e*l*p + i*j*e*l*o + i*d*e*m*q + i*d*e*m*o + i*d*e*l*q + i*d*e*l*p + j*d*l*o*p + j*d*e*l*o + g*j*d*o*p + g*j*d*m*q + g*j*d*m*p + g*j*d*m*o + g*j*d*l*q + g*j*d*l*p + g*j*d*l*o + g*j*e*o*p + g*j*e*m*q + g*d*l*o*p + g*d*l*m*p + g*d*l*m*o + j*d*e*m*p + i*d*e*o*p + j*e*o*q*l + j*e*o*p*l + j*e*m*q*l + j*d*e*o*p + j*d*e*m*q + i*j*d*o*p + g*i*e*o*p + j*d*e*m*o + j*d*e*l*q + j*d*e*l*p + j*e*m*p*l + j*e*m*o*l + g*i*e*m*q + g*i*e*m*p + g*i*e*m*o + g*i*e*l*q + g*i*e*l*p + g*i*e*l*o + j*d*l*o*q + j*d*l*m*q + j*d*l*m*p + j*d*l*m*o + i*d*e*l*o + l*m*q*d*e + l*m*q*d*g + l*m*q*e*g), + h: (j*e*r*l*(o*q + o*p + m*q + m*p + m*o))/(l*q*d*e*o + l*q*d*g*o + l*q*e*g*o + i*j*d*o*q + i*j*e*o*q + j*d*e*o*q + g*j*d*o*q + g*j*e*o*q + g*i*e*o*q + i*d*e*o*q + g*i*d*o*q + g*i*d*o*p + g*i*d*m*q + g*i*d*m*p + g*i*d*m*o + g*i*d*l*q + g*i*d*l*p + g*i*d*l*o + g*e*l*m*p + g*e*l*o*p + g*j*e*l*q + g*e*l*m*o + g*j*e*m*p + g*j*e*m*o + d*e*l*m*p + d*e*l*m*o + i*d*e*m*p + g*j*e*l*p + g*j*e*l*o + d*e*l*o*p + i*j*d*l*o + i*j*e*o*p + i*j*e*m*q + i*j*d*m*q + i*j*d*m*p + i*j*d*m*o + i*j*d*l*q + i*j*d*l*p + i*j*e*m*p + i*j*e*m*o + i*j*e*l*q + i*j*e*l*p + i*j*e*l*o + i*d*e*m*q + i*d*e*m*o + i*d*e*l*q + i*d*e*l*p + j*d*l*o*p + j*d*e*l*o + g*j*d*o*p + g*j*d*m*q + g*j*d*m*p + g*j*d*m*o + g*j*d*l*q + g*j*d*l*p + g*j*d*l*o + g*j*e*o*p + g*j*e*m*q + g*d*l*o*p + g*d*l*m*p + g*d*l*m*o + j*d*e*m*p + i*d*e*o*p + j*e*o*q*l + j*e*o*p*l + j*e*m*q*l + j*d*e*o*p + j*d*e*m*q + i*j*d*o*p + g*i*e*o*p + j*d*e*m*o + j*d*e*l*q + j*d*e*l*p + j*e*m*p*l + j*e*m*o*l + g*i*e*m*q + g*i*e*m*p + g*i*e*m*o + g*i*e*l*q + g*i*e*l*p + g*i*e*l*o + j*d*l*o*q + j*d*l*m*q + j*d*l*m*p + j*d*l*m*o + i*d*e*l*o + l*m*q*d*e + l*m*q*d*g + l*m*q*e*g), + k: (j*e*r*o*l*(q + p))/(l*q*d*e*o + l*q*d*g*o + l*q*e*g*o + i*j*d*o*q + i*j*e*o*q + j*d*e*o*q + g*j*d*o*q + g*j*e*o*q + g*i*e*o*q + i*d*e*o*q + g*i*d*o*q + g*i*d*o*p + g*i*d*m*q + g*i*d*m*p + g*i*d*m*o + g*i*d*l*q + g*i*d*l*p + g*i*d*l*o + g*e*l*m*p + g*e*l*o*p + g*j*e*l*q + g*e*l*m*o + g*j*e*m*p + g*j*e*m*o + d*e*l*m*p + d*e*l*m*o + i*d*e*m*p + g*j*e*l*p + g*j*e*l*o + d*e*l*o*p + i*j*d*l*o + i*j*e*o*p + i*j*e*m*q + i*j*d*m*q + i*j*d*m*p + i*j*d*m*o + i*j*d*l*q + i*j*d*l*p + i*j*e*m*p + i*j*e*m*o + i*j*e*l*q + i*j*e*l*p + i*j*e*l*o + i*d*e*m*q + i*d*e*m*o + i*d*e*l*q + i*d*e*l*p + j*d*l*o*p + j*d*e*l*o + g*j*d*o*p + g*j*d*m*q + g*j*d*m*p + g*j*d*m*o + g*j*d*l*q + g*j*d*l*p + g*j*d*l*o + g*j*e*o*p + g*j*e*m*q + g*d*l*o*p + g*d*l*m*p + g*d*l*m*o + j*d*e*m*p + i*d*e*o*p + j*e*o*q*l + j*e*o*p*l + j*e*m*q*l + j*d*e*o*p + j*d*e*m*q + i*j*d*o*p + g*i*e*o*p + j*d*e*m*o + j*d*e*l*q + j*d*e*l*p + j*e*m*p*l + j*e*m*o*l + g*i*e*m*q + g*i*e*m*p + g*i*e*m*o + g*i*e*l*q + g*i*e*l*p + g*i*e*l*o + j*d*l*o*q + j*d*l*m*q + j*d*l*m*p + j*d*l*m*o + i*d*e*l*o + l*m*q*d*e + l*m*q*d*g + l*m*q*e*g), + n: (j*e*r*o*q*l)/(l*q*d*e*o + l*q*d*g*o + l*q*e*g*o + i*j*d*o*q + i*j*e*o*q + j*d*e*o*q + g*j*d*o*q + g*j*e*o*q + g*i*e*o*q + i*d*e*o*q + g*i*d*o*q + g*i*d*o*p + g*i*d*m*q + g*i*d*m*p + g*i*d*m*o + g*i*d*l*q + g*i*d*l*p + g*i*d*l*o + g*e*l*m*p + g*e*l*o*p + g*j*e*l*q + g*e*l*m*o + g*j*e*m*p + g*j*e*m*o + d*e*l*m*p + d*e*l*m*o + i*d*e*m*p + g*j*e*l*p + g*j*e*l*o + d*e*l*o*p + i*j*d*l*o + i*j*e*o*p + i*j*e*m*q + i*j*d*m*q + i*j*d*m*p + i*j*d*m*o + i*j*d*l*q + i*j*d*l*p + i*j*e*m*p + i*j*e*m*o + i*j*e*l*q + i*j*e*l*p + i*j*e*l*o + i*d*e*m*q + i*d*e*m*o + i*d*e*l*q + i*d*e*l*p + j*d*l*o*p + j*d*e*l*o + g*j*d*o*p + g*j*d*m*q + g*j*d*m*p + g*j*d*m*o + g*j*d*l*q + g*j*d*l*p + g*j*d*l*o + g*j*e*o*p + g*j*e*m*q + g*d*l*o*p + g*d*l*m*p + g*d*l*m*o + j*d*e*m*p + i*d*e*o*p + j*e*o*q*l + j*e*o*p*l + j*e*m*q*l + j*d*e*o*p + j*d*e*m*q + i*j*d*o*p + g*i*e*o*p + j*d*e*m*o + j*d*e*l*q + j*d*e*l*p + j*e*m*p*l + j*e*m*o*l + g*i*e*m*q + g*i*e*m*p + g*i*e*m*o + g*i*e*l*q + g*i*e*l*p + g*i*e*l*o + j*d*l*o*q + j*d*l*m*q + j*d*l*m*p + j*d*l*m*o + i*d*e*l*o + l*m*q*d*e + l*m*q*d*g + l*m*q*e*g), + } + + assert solve_lin_sys(eqs, domain) == sol + +def test_eqs_to_matrix(): + domain, x1,x2 = ring("x1,x2", QQ) + eqs_coeff = [{x1: QQ(1), x2: QQ(1)}, {x1: QQ(2), x2: QQ(-1)}] + eqs_rhs = [QQ(-5), QQ(0)] + M = eqs_to_matrix(eqs_coeff, eqs_rhs, [x1, x2], QQ) + assert M.to_Matrix() == Matrix([[1, 1, 5], [2, -1, 0]]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_specialpolys.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_specialpolys.py new file mode 100644 index 0000000000000000000000000000000000000000..39f551c9e70b5c2bae748ea681b9c8a8cb349fe1 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_specialpolys.py @@ -0,0 +1,152 @@ +"""Tests for functions for generating interesting polynomials. """ + +from sympy.core.add import Add +from sympy.core.symbol import symbols +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.ntheory.generate import prime +from sympy.polys.domains.integerring import ZZ +from sympy.polys.polytools import Poly +from sympy.utilities.iterables import permute_signs +from sympy.testing.pytest import raises + +from sympy.polys.specialpolys import ( + swinnerton_dyer_poly, + cyclotomic_poly, + symmetric_poly, + random_poly, + interpolating_poly, + fateman_poly_F_1, + dmp_fateman_poly_F_1, + fateman_poly_F_2, + dmp_fateman_poly_F_2, + fateman_poly_F_3, + dmp_fateman_poly_F_3, +) + +from sympy.abc import x, y, z + + +def test_swinnerton_dyer_poly(): + raises(ValueError, lambda: swinnerton_dyer_poly(0, x)) + + assert swinnerton_dyer_poly(1, x, polys=True) == Poly(x**2 - 2) + + assert swinnerton_dyer_poly(1, x) == x**2 - 2 + assert swinnerton_dyer_poly(2, x) == x**4 - 10*x**2 + 1 + assert swinnerton_dyer_poly( + 3, x) == x**8 - 40*x**6 + 352*x**4 - 960*x**2 + 576 + # we only need to check that the polys arg works but + # we may as well test that the roots are correct + p = [sqrt(prime(i)) for i in range(1, 5)] + assert str([i.n(3) for i in + swinnerton_dyer_poly(4, polys=True).all_roots()] + ) == str(sorted([Add(*i).n(3) for i in permute_signs(p)])) + + +def test_cyclotomic_poly(): + raises(ValueError, lambda: cyclotomic_poly(0, x)) + + assert cyclotomic_poly(1, x, polys=True) == Poly(x - 1) + + assert cyclotomic_poly(1, x) == x - 1 + assert cyclotomic_poly(2, x) == x + 1 + assert cyclotomic_poly(3, x) == x**2 + x + 1 + assert cyclotomic_poly(4, x) == x**2 + 1 + assert cyclotomic_poly(5, x) == x**4 + x**3 + x**2 + x + 1 + assert cyclotomic_poly(6, x) == x**2 - x + 1 + + +def test_symmetric_poly(): + raises(ValueError, lambda: symmetric_poly(-1, x, y, z)) + raises(ValueError, lambda: symmetric_poly(5, x, y, z)) + + assert symmetric_poly(1, x, y, z, polys=True) == Poly(x + y + z) + assert symmetric_poly(1, (x, y, z), polys=True) == Poly(x + y + z) + + assert symmetric_poly(0, x, y, z) == 1 + assert symmetric_poly(1, x, y, z) == x + y + z + assert symmetric_poly(2, x, y, z) == x*y + x*z + y*z + assert symmetric_poly(3, x, y, z) == x*y*z + + +def test_random_poly(): + poly = random_poly(x, 10, -100, 100, polys=False) + + assert Poly(poly).degree() == 10 + assert all(-100 <= coeff <= 100 for coeff in Poly(poly).coeffs()) is True + + poly = random_poly(x, 10, -100, 100, polys=True) + + assert poly.degree() == 10 + assert all(-100 <= coeff <= 100 for coeff in poly.coeffs()) is True + + +def test_interpolating_poly(): + x0, x1, x2, x3, y0, y1, y2, y3 = symbols('x:4, y:4') + + assert interpolating_poly(0, x) == 0 + assert interpolating_poly(1, x) == y0 + + assert interpolating_poly(2, x) == \ + y0*(x - x1)/(x0 - x1) + y1*(x - x0)/(x1 - x0) + + assert interpolating_poly(3, x) == \ + y0*(x - x1)*(x - x2)/((x0 - x1)*(x0 - x2)) + \ + y1*(x - x0)*(x - x2)/((x1 - x0)*(x1 - x2)) + \ + y2*(x - x0)*(x - x1)/((x2 - x0)*(x2 - x1)) + + assert interpolating_poly(4, x) == \ + y0*(x - x1)*(x - x2)*(x - x3)/((x0 - x1)*(x0 - x2)*(x0 - x3)) + \ + y1*(x - x0)*(x - x2)*(x - x3)/((x1 - x0)*(x1 - x2)*(x1 - x3)) + \ + y2*(x - x0)*(x - x1)*(x - x3)/((x2 - x0)*(x2 - x1)*(x2 - x3)) + \ + y3*(x - x0)*(x - x1)*(x - x2)/((x3 - x0)*(x3 - x1)*(x3 - x2)) + + raises(ValueError, lambda: + interpolating_poly(2, x, (x, 2), (1, 3))) + raises(ValueError, lambda: + interpolating_poly(2, x, (x + y, 2), (1, 3))) + raises(ValueError, lambda: + interpolating_poly(2, x + y, (x, 2), (1, 3))) + raises(ValueError, lambda: + interpolating_poly(2, 3, (4, 5), (6, 7))) + raises(ValueError, lambda: + interpolating_poly(2, 3, (4, 5), (6, 7, 8))) + assert interpolating_poly(0, x, (1, 2), (3, 4)) == 0 + assert interpolating_poly(1, x, (1, 2), (3, 4)) == 3 + assert interpolating_poly(2, x, (1, 2), (3, 4)) == x + 2 + + +def test_fateman_poly_F_1(): + f, g, h = fateman_poly_F_1(1) + F, G, H = dmp_fateman_poly_F_1(1, ZZ) + + assert [ t.rep.to_list() for t in [f, g, h] ] == [F, G, H] + + f, g, h = fateman_poly_F_1(3) + F, G, H = dmp_fateman_poly_F_1(3, ZZ) + + assert [ t.rep.to_list() for t in [f, g, h] ] == [F, G, H] + + +def test_fateman_poly_F_2(): + f, g, h = fateman_poly_F_2(1) + F, G, H = dmp_fateman_poly_F_2(1, ZZ) + + assert [ t.rep.to_list() for t in [f, g, h] ] == [F, G, H] + + f, g, h = fateman_poly_F_2(3) + F, G, H = dmp_fateman_poly_F_2(3, ZZ) + + assert [ t.rep.to_list() for t in [f, g, h] ] == [F, G, H] + + +def test_fateman_poly_F_3(): + f, g, h = fateman_poly_F_3(1) + F, G, H = dmp_fateman_poly_F_3(1, ZZ) + + assert [ t.rep.to_list() for t in [f, g, h] ] == [F, G, H] + + f, g, h = fateman_poly_F_3(3) + F, G, H = dmp_fateman_poly_F_3(3, ZZ) + + assert [ t.rep.to_list() for t in [f, g, h] ] == [F, G, H] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_sqfreetools.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_sqfreetools.py new file mode 100644 index 0000000000000000000000000000000000000000..b772a05a50e2eacd5a7c80352b1eadd52c69c3fa --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_sqfreetools.py @@ -0,0 +1,160 @@ +"""Tests for square-free decomposition algorithms and related tools. """ + +from sympy.polys.rings import ring +from sympy.polys.domains import FF, ZZ, QQ +from sympy.polys.specialpolys import f_polys + +from sympy.testing.pytest import raises +from sympy.external.gmpy import MPQ + +f_0, f_1, f_2, f_3, f_4, f_5, f_6 = f_polys() + +def test_dup_sqf(): + R, x = ring("x", ZZ) + + assert R.dup_sqf_part(0) == 0 + assert R.dup_sqf_p(0) is True + + assert R.dup_sqf_part(7) == 1 + assert R.dup_sqf_p(7) is True + + assert R.dup_sqf_part(2*x + 2) == x + 1 + assert R.dup_sqf_p(2*x + 2) is True + + assert R.dup_sqf_part(x**3 + x + 1) == x**3 + x + 1 + assert R.dup_sqf_p(x**3 + x + 1) is True + + assert R.dup_sqf_part(-x**3 + x + 1) == x**3 - x - 1 + assert R.dup_sqf_p(-x**3 + x + 1) is True + + assert R.dup_sqf_part(2*x**3 + 3*x**2) == 2*x**2 + 3*x + assert R.dup_sqf_p(2*x**3 + 3*x**2) is False + + assert R.dup_sqf_part(-2*x**3 + 3*x**2) == 2*x**2 - 3*x + assert R.dup_sqf_p(-2*x**3 + 3*x**2) is False + + assert R.dup_sqf_list(0) == (0, []) + assert R.dup_sqf_list(1) == (1, []) + + assert R.dup_sqf_list(x) == (1, [(x, 1)]) + assert R.dup_sqf_list(2*x**2) == (2, [(x, 2)]) + assert R.dup_sqf_list(3*x**3) == (3, [(x, 3)]) + + assert R.dup_sqf_list(-x**5 + x**4 + x - 1) == \ + (-1, [(x**3 + x**2 + x + 1, 1), (x - 1, 2)]) + assert R.dup_sqf_list(x**8 + 6*x**6 + 12*x**4 + 8*x**2) == \ + ( 1, [(x, 2), (x**2 + 2, 3)]) + + assert R.dup_sqf_list(2*x**2 + 4*x + 2) == (2, [(x + 1, 2)]) + + R, x = ring("x", QQ) + assert R.dup_sqf_list(2*x**2 + 4*x + 2) == (2, [(x + 1, 2)]) + + R, x = ring("x", FF(2)) + assert R.dup_sqf_list(x**2 + 1) == (1, [(x + 1, 2)]) + + R, x = ring("x", FF(3)) + assert R.dup_sqf_list(x**10 + 2*x**7 + 2*x**4 + x) == \ + (1, [(x, 1), + (x + 1, 3), + (x + 2, 6)]) + + R1, x = ring("x", ZZ) + R2, y = ring("y", FF(3)) + + f = x**3 + 1 + g = y**3 + 1 + + assert R1.dup_sqf_part(f) == f + assert R2.dup_sqf_part(g) == y + 1 + + assert R1.dup_sqf_p(f) is True + assert R2.dup_sqf_p(g) is False + + R, x, y = ring("x,y", ZZ) + + A = x**4 - 3*x**2 + 6 + D = x**6 - 5*x**4 + 5*x**2 + 4 + + f, g = D, R.dmp_sub(A, R.dmp_mul(R.dmp_diff(D, 1), y)) + res = R.dmp_resultant(f, g) + h = (4*y**2 + 1).drop(x) + + assert R.drop(x).dup_sqf_list(res) == (45796, [(h, 3)]) + + Rt, t = ring("t", ZZ) + R, x = ring("x", Rt) + assert R.dup_sqf_list_include(t**3*x**2) == [(t**3, 1), (x, 2)] + + +def test_dmp_sqf(): + R, x, y = ring("x,y", ZZ) + assert R.dmp_sqf_part(0) == 0 + assert R.dmp_sqf_p(0) is True + + assert R.dmp_sqf_part(7) == 1 + assert R.dmp_sqf_p(7) is True + + assert R.dmp_sqf_list(3) == (3, []) + assert R.dmp_sqf_list_include(3) == [(3, 1)] + + R, x, y, z = ring("x,y,z", ZZ) + assert R.dmp_sqf_p(f_0) is True + assert R.dmp_sqf_p(f_0**2) is False + assert R.dmp_sqf_p(f_1) is True + assert R.dmp_sqf_p(f_1**2) is False + assert R.dmp_sqf_p(f_2) is True + assert R.dmp_sqf_p(f_2**2) is False + assert R.dmp_sqf_p(f_3) is True + assert R.dmp_sqf_p(f_3**2) is False + assert R.dmp_sqf_p(f_5) is False + assert R.dmp_sqf_p(f_5**2) is False + + assert R.dmp_sqf_p(f_4) is True + assert R.dmp_sqf_part(f_4) == -f_4 + + assert R.dmp_sqf_part(f_5) == x + y - z + + R, x, y, z, t = ring("x,y,z,t", ZZ) + assert R.dmp_sqf_p(f_6) is True + assert R.dmp_sqf_part(f_6) == f_6 + + R, x = ring("x", ZZ) + f = -x**5 + x**4 + x - 1 + + assert R.dmp_sqf_list(f) == (-1, [(x**3 + x**2 + x + 1, 1), (x - 1, 2)]) + assert R.dmp_sqf_list_include(f) == [(-x**3 - x**2 - x - 1, 1), (x - 1, 2)] + + R, x, y = ring("x,y", ZZ) + f = -x**5 + x**4 + x - 1 + + assert R.dmp_sqf_list(f) == (-1, [(x**3 + x**2 + x + 1, 1), (x - 1, 2)]) + assert R.dmp_sqf_list_include(f) == [(-x**3 - x**2 - x - 1, 1), (x - 1, 2)] + + f = -x**2 + 2*x - 1 + assert R.dmp_sqf_list_include(f) == [(-1, 1), (x - 1, 2)] + + f = (y**2 + 1)**2*(x**2 + 2*x + 2) + assert R.dmp_sqf_p(f) is False + assert R.dmp_sqf_list(f) == (1, [(x**2 + 2*x + 2, 1), (y**2 + 1, 2)]) + + R, x, y = ring("x,y", FF(2)) + raises(NotImplementedError, lambda: R.dmp_sqf_list(y**2 + 1)) + + +def test_dup_gff_list(): + R, x = ring("x", ZZ) + + f = x**5 + 2*x**4 - x**3 - 2*x**2 + assert R.dup_gff_list(f) == [(x, 1), (x + 2, 4)] + + g = x**9 - 20*x**8 + 166*x**7 - 744*x**6 + 1965*x**5 - 3132*x**4 + 2948*x**3 - 1504*x**2 + 320*x + assert R.dup_gff_list(g) == [(x**2 - 5*x + 4, 1), (x**2 - 5*x + 4, 2), (x, 3)] + + raises(ValueError, lambda: R.dup_gff_list(0)) + +def test_issue_26178(): + R, x, y, z = ring(['x', 'y', 'z'], QQ) + assert (x**2 - 2*y**2 + 1).sqf_list() == (MPQ(1,1), [(x**2 - 2*y**2 + 1, 1)]) + assert (x**2 - 2*z**2 + 1).sqf_list() == (MPQ(1,1), [(x**2 - 2*z**2 + 1, 1)]) + assert (y**2 - 2*z**2 + 1).sqf_list() == (MPQ(1,1), [(y**2 - 2*z**2 + 1, 1)]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_subresultants_qq_zz.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_subresultants_qq_zz.py new file mode 100644 index 0000000000000000000000000000000000000000..7f7560dfeaf93b20f7cf68cdc597c024cb519cca --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/polys/tests/test_subresultants_qq_zz.py @@ -0,0 +1,347 @@ +from sympy.core.symbol import Symbol +from sympy.polys.polytools import (pquo, prem, sturm, subresultants) +from sympy.matrices import Matrix +from sympy.polys.subresultants_qq_zz import (sylvester, res, res_q, res_z, bezout, + subresultants_sylv, modified_subresultants_sylv, + subresultants_bezout, modified_subresultants_bezout, + backward_eye, + sturm_pg, sturm_q, sturm_amv, euclid_pg, euclid_q, + euclid_amv, modified_subresultants_pg, subresultants_pg, + subresultants_amv_q, quo_z, rem_z, subresultants_amv, + modified_subresultants_amv, subresultants_rem, + subresultants_vv, subresultants_vv_2) + + +def test_sylvester(): + x = Symbol('x') + + assert sylvester(x**3 -7, 0, x) == sylvester(x**3 -7, 0, x, 1) == Matrix([[0]]) + assert sylvester(0, x**3 -7, x) == sylvester(0, x**3 -7, x, 1) == Matrix([[0]]) + assert sylvester(x**3 -7, 0, x, 2) == Matrix([[0]]) + assert sylvester(0, x**3 -7, x, 2) == Matrix([[0]]) + + assert sylvester(x**3 -7, 7, x).det() == sylvester(x**3 -7, 7, x, 1).det() == 343 + assert sylvester(7, x**3 -7, x).det() == sylvester(7, x**3 -7, x, 1).det() == 343 + assert sylvester(x**3 -7, 7, x, 2).det() == -343 + assert sylvester(7, x**3 -7, x, 2).det() == 343 + + assert sylvester(3, 7, x).det() == sylvester(3, 7, x, 1).det() == sylvester(3, 7, x, 2).det() == 1 + + assert sylvester(3, 0, x).det() == sylvester(3, 0, x, 1).det() == sylvester(3, 0, x, 2).det() == 1 + + assert sylvester(x - 3, x - 8, x) == sylvester(x - 3, x - 8, x, 1) == sylvester(x - 3, x - 8, x, 2) == Matrix([[1, -3], [1, -8]]) + + assert sylvester(x**3 - 7*x + 7, 3*x**2 - 7, x) == sylvester(x**3 - 7*x + 7, 3*x**2 - 7, x, 1) == Matrix([[1, 0, -7, 7, 0], [0, 1, 0, -7, 7], [3, 0, -7, 0, 0], [0, 3, 0, -7, 0], [0, 0, 3, 0, -7]]) + + assert sylvester(x**3 - 7*x + 7, 3*x**2 - 7, x, 2) == Matrix([ +[1, 0, -7, 7, 0, 0], [0, 3, 0, -7, 0, 0], [0, 1, 0, -7, 7, 0], [0, 0, 3, 0, -7, 0], [0, 0, 1, 0, -7, 7], [0, 0, 0, 3, 0, -7]]) + +def test_subresultants_sylv(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_sylv(p, q, x) == subresultants(p, q, x) + assert subresultants_sylv(p, q, x)[-1] == res(p, q, x) + assert subresultants_sylv(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_sylv(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_sylv(p, q, x) == euclid_amv(p, q, x) + +def test_modified_subresultants_sylv(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + amv_factors = [1, 1, -1, 1, -1, 1] + assert modified_subresultants_sylv(p, q, x) == [i*j for i, j in zip(amv_factors, subresultants_amv(p, q, x))] + assert modified_subresultants_sylv(p, q, x)[-1] != res_q(p + x**8, q, x) + assert modified_subresultants_sylv(p, q, x) != sturm_amv(p, q, x) + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert modified_subresultants_sylv(p, q, x) == sturm_amv(p, q, x) + assert modified_subresultants_sylv(-p, q, x) != sturm_amv(-p, q, x) + +def test_res(): + x = Symbol('x') + + assert res(3, 5, x) == 1 + +def test_res_q(): + x = Symbol('x') + + assert res_q(3, 5, x) == 1 + +def test_res_z(): + x = Symbol('x') + + assert res_z(3, 5, x) == 1 + assert res(3, 5, x) == res_q(3, 5, x) == res_z(3, 5, x) + +def test_bezout(): + x = Symbol('x') + + p = -2*x**5+7*x**3+9*x**2-3*x+1 + q = -10*x**4+21*x**2+18*x-3 + assert bezout(p, q, x, 'bz').det() == sylvester(p, q, x, 2).det() + assert bezout(p, q, x, 'bz').det() != sylvester(p, q, x, 1).det() + assert bezout(p, q, x, 'prs') == backward_eye(5) * bezout(p, q, x, 'bz') * backward_eye(5) + +def test_subresultants_bezout(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_bezout(p, q, x) == subresultants(p, q, x) + assert subresultants_bezout(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_bezout(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_bezout(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_bezout(p, q, x) == euclid_amv(p, q, x) + +def test_modified_subresultants_bezout(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + amv_factors = [1, 1, -1, 1, -1, 1] + assert modified_subresultants_bezout(p, q, x) == [i*j for i, j in zip(amv_factors, subresultants_amv(p, q, x))] + assert modified_subresultants_bezout(p, q, x)[-1] != sylvester(p + x**8, q, x).det() + assert modified_subresultants_bezout(p, q, x) != sturm_amv(p, q, x) + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert modified_subresultants_bezout(p, q, x) == sturm_amv(p, q, x) + assert modified_subresultants_bezout(-p, q, x) != sturm_amv(-p, q, x) + +def test_sturm_pg(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert sturm_pg(p, q, x)[-1] != sylvester(p, q, x, 2).det() + sam_factors = [1, 1, -1, -1, 1, 1] + assert sturm_pg(p, q, x) == [i*j for i,j in zip(sam_factors, euclid_pg(p, q, x))] + + p = -9*x**5 - 5*x**3 - 9 + q = -45*x**4 - 15*x**2 + assert sturm_pg(p, q, x, 1)[-1] == sylvester(p, q, x, 1).det() + assert sturm_pg(p, q, x)[-1] != sylvester(p, q, x, 2).det() + assert sturm_pg(-p, q, x)[-1] == sylvester(-p, q, x, 2).det() + assert sturm_pg(-p, q, x) == modified_subresultants_pg(-p, q, x) + +def test_sturm_q(): + x = Symbol('x') + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert sturm_q(p, q, x) == sturm(p) + assert sturm_q(-p, -q, x) != sturm(-p) + + +def test_sturm_amv(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert sturm_amv(p, q, x)[-1] != sylvester(p, q, x, 2).det() + sam_factors = [1, 1, -1, -1, 1, 1] + assert sturm_amv(p, q, x) == [i*j for i,j in zip(sam_factors, euclid_amv(p, q, x))] + + p = -9*x**5 - 5*x**3 - 9 + q = -45*x**4 - 15*x**2 + assert sturm_amv(p, q, x, 1)[-1] == sylvester(p, q, x, 1).det() + assert sturm_amv(p, q, x)[-1] != sylvester(p, q, x, 2).det() + assert sturm_amv(-p, q, x)[-1] == sylvester(-p, q, x, 2).det() + assert sturm_pg(-p, q, x) == modified_subresultants_pg(-p, q, x) + + +def test_euclid_pg(): + x = Symbol('x') + + p = x**6+x**5-x**4-x**3+x**2-x+1 + q = 6*x**5+5*x**4-4*x**3-3*x**2+2*x-1 + assert euclid_pg(p, q, x)[-1] == sylvester(p, q, x).det() + assert euclid_pg(p, q, x) == subresultants_pg(p, q, x) + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert euclid_pg(p, q, x)[-1] != sylvester(p, q, x, 2).det() + sam_factors = [1, 1, -1, -1, 1, 1] + assert euclid_pg(p, q, x) == [i*j for i,j in zip(sam_factors, sturm_pg(p, q, x))] + + +def test_euclid_q(): + x = Symbol('x') + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert euclid_q(p, q, x)[-1] == -sturm(p)[-1] + + +def test_euclid_amv(): + x = Symbol('x') + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert euclid_amv(p, q, x)[-1] == sylvester(p, q, x).det() + assert euclid_amv(p, q, x) == subresultants_amv(p, q, x) + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert euclid_amv(p, q, x)[-1] != sylvester(p, q, x, 2).det() + sam_factors = [1, 1, -1, -1, 1, 1] + assert euclid_amv(p, q, x) == [i*j for i,j in zip(sam_factors, sturm_amv(p, q, x))] + + +def test_modified_subresultants_pg(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + amv_factors = [1, 1, -1, 1, -1, 1] + assert modified_subresultants_pg(p, q, x) == [i*j for i, j in zip(amv_factors, subresultants_pg(p, q, x))] + assert modified_subresultants_pg(p, q, x)[-1] != sylvester(p + x**8, q, x).det() + assert modified_subresultants_pg(p, q, x) != sturm_pg(p, q, x) + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert modified_subresultants_pg(p, q, x) == sturm_pg(p, q, x) + assert modified_subresultants_pg(-p, q, x) != sturm_pg(-p, q, x) + + +def test_subresultants_pg(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_pg(p, q, x) == subresultants(p, q, x) + assert subresultants_pg(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_pg(p, q, x) != euclid_pg(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_pg(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_pg(p, q, x) == euclid_pg(p, q, x) + + +def test_subresultants_amv_q(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_amv_q(p, q, x) == subresultants(p, q, x) + assert subresultants_amv_q(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_amv_q(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_amv_q(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_amv(p, q, x) == euclid_amv(p, q, x) + + +def test_rem_z(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert rem_z(p, -q, x) != prem(p, -q, x) + +def test_quo_z(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert quo_z(p, -q, x) != pquo(p, -q, x) + + y = Symbol('y') + q = 3*x**6 + 5*y**4 - 4*x**2 - 9*x + 21 + assert quo_z(p, -q, x) == pquo(p, -q, x) + +def test_subresultants_amv(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_amv(p, q, x) == subresultants(p, q, x) + assert subresultants_amv(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_amv(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_amv(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_amv(p, q, x) == euclid_amv(p, q, x) + + +def test_modified_subresultants_amv(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + amv_factors = [1, 1, -1, 1, -1, 1] + assert modified_subresultants_amv(p, q, x) == [i*j for i, j in zip(amv_factors, subresultants_amv(p, q, x))] + assert modified_subresultants_amv(p, q, x)[-1] != sylvester(p + x**8, q, x).det() + assert modified_subresultants_amv(p, q, x) != sturm_amv(p, q, x) + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert modified_subresultants_amv(p, q, x) == sturm_amv(p, q, x) + assert modified_subresultants_amv(-p, q, x) != sturm_amv(-p, q, x) + + +def test_subresultants_rem(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_rem(p, q, x) == subresultants(p, q, x) + assert subresultants_rem(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_rem(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_rem(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_rem(p, q, x) == euclid_amv(p, q, x) + + +def test_subresultants_vv(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_vv(p, q, x) == subresultants(p, q, x) + assert subresultants_vv(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_vv(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_vv(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_vv(p, q, x) == euclid_amv(p, q, x) + + +def test_subresultants_vv_2(): + x = Symbol('x') + + p = x**8 + x**6 - 3*x**4 - 3*x**3 + 8*x**2 + 2*x - 5 + q = 3*x**6 + 5*x**4 - 4*x**2 - 9*x + 21 + assert subresultants_vv_2(p, q, x) == subresultants(p, q, x) + assert subresultants_vv_2(p, q, x)[-1] == sylvester(p, q, x).det() + assert subresultants_vv_2(p, q, x) != euclid_amv(p, q, x) + amv_factors = [1, 1, -1, 1, -1, 1] + assert subresultants_vv_2(p, q, x) == [i*j for i, j in zip(amv_factors, modified_subresultants_amv(p, q, x))] + + p = x**3 - 7*x + 7 + q = 3*x**2 - 7 + assert subresultants_vv_2(p, q, x) == euclid_amv(p, q, x) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..15dfaf70eb3777195b7c9a0930894bb2187bbb50 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/__init__.py @@ -0,0 +1,111 @@ +"""Printing subsystem""" + +from .pretty import pager_print, pretty, pretty_print, pprint, pprint_use_unicode, pprint_try_use_unicode + +from .latex import latex, print_latex, multiline_latex + +from .mathml import mathml, print_mathml + +from .python import python, print_python + +from .pycode import pycode + +from .codeprinter import print_ccode, print_fcode + +from .codeprinter import ccode, fcode, cxxcode, rust_code # noqa:F811 + +from .smtlib import smtlib_code + +from .glsl import glsl_code, print_glsl + +from .rcode import rcode, print_rcode + +from .jscode import jscode, print_jscode + +from .julia import julia_code + +from .mathematica import mathematica_code + +from .octave import octave_code + +from .gtk import print_gtk + +from .preview import preview + +from .repr import srepr + +from .tree import print_tree + +from .str import StrPrinter, sstr, sstrrepr + +from .tableform import TableForm + +from .dot import dotprint + +from .maple import maple_code, print_maple_code + +__all__ = [ + # sympy.printing.pretty + 'pager_print', 'pretty', 'pretty_print', 'pprint', 'pprint_use_unicode', + 'pprint_try_use_unicode', + + # sympy.printing.latex + 'latex', 'print_latex', 'multiline_latex', + + # sympy.printing.mathml + 'mathml', 'print_mathml', + + # sympy.printing.python + 'python', 'print_python', + + # sympy.printing.pycode + 'pycode', + + # sympy.printing.codeprinter + 'ccode', 'print_ccode', 'cxxcode', 'fcode', 'print_fcode', 'rust_code', + + # sympy.printing.smtlib + 'smtlib_code', + + # sympy.printing.glsl + 'glsl_code', 'print_glsl', + + # sympy.printing.rcode + 'rcode', 'print_rcode', + + # sympy.printing.jscode + 'jscode', 'print_jscode', + + # sympy.printing.julia + 'julia_code', + + # sympy.printing.mathematica + 'mathematica_code', + + # sympy.printing.octave + 'octave_code', + + # sympy.printing.gtk + 'print_gtk', + + # sympy.printing.preview + 'preview', + + # sympy.printing.repr + 'srepr', + + # sympy.printing.tree + 'print_tree', + + # sympy.printing.str + 'StrPrinter', 'sstr', 'sstrrepr', + + # sympy.printing.tableform + 'TableForm', + + # sympy.printing.dot + 'dotprint', + + # sympy.printing.maple + 'maple_code', 'print_maple_code', +] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/aesaracode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/aesaracode.py new file mode 100644 index 0000000000000000000000000000000000000000..1e31c6940a86bd25ef8805420b84c22c5e08bca9 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/aesaracode.py @@ -0,0 +1,563 @@ +from __future__ import annotations +import math +from typing import Any + +from sympy.external import import_module +from sympy.printing.printer import Printer +from sympy.utilities.exceptions import sympy_deprecation_warning +from sympy.utilities.iterables import is_sequence +import sympy +from functools import partial + + +aesara = import_module('aesara') + +if aesara: + aes = aesara.scalar + aet = aesara.tensor + from aesara.tensor import nlinalg + from aesara.tensor.elemwise import Elemwise + from aesara.tensor.elemwise import DimShuffle + + # `true_divide` replaced `true_div` in Aesara 2.8.11 (released 2023) to + # match NumPy + # XXX: Remove this when not needed to support older versions. + true_divide = getattr(aet, 'true_divide', None) + if true_divide is None: + true_divide = aet.true_div + + mapping = { + sympy.Add: aet.add, + sympy.Mul: aet.mul, + sympy.Abs: aet.abs, + sympy.sign: aet.sgn, + sympy.ceiling: aet.ceil, + sympy.floor: aet.floor, + sympy.log: aet.log, + sympy.exp: aet.exp, + sympy.sqrt: aet.sqrt, + sympy.cos: aet.cos, + sympy.acos: aet.arccos, + sympy.sin: aet.sin, + sympy.asin: aet.arcsin, + sympy.tan: aet.tan, + sympy.atan: aet.arctan, + sympy.atan2: aet.arctan2, + sympy.cosh: aet.cosh, + sympy.acosh: aet.arccosh, + sympy.sinh: aet.sinh, + sympy.asinh: aet.arcsinh, + sympy.tanh: aet.tanh, + sympy.atanh: aet.arctanh, + sympy.re: aet.real, + sympy.im: aet.imag, + sympy.arg: aet.angle, + sympy.erf: aet.erf, + sympy.gamma: aet.gamma, + sympy.loggamma: aet.gammaln, + sympy.Pow: aet.pow, + sympy.Eq: aet.eq, + sympy.StrictGreaterThan: aet.gt, + sympy.StrictLessThan: aet.lt, + sympy.LessThan: aet.le, + sympy.GreaterThan: aet.ge, + sympy.And: aet.bitwise_and, # bitwise + sympy.Or: aet.bitwise_or, # bitwise + sympy.Not: aet.invert, # bitwise + sympy.Xor: aet.bitwise_xor, # bitwise + sympy.Max: aet.maximum, # Sympy accept >2 inputs, Aesara only 2 + sympy.Min: aet.minimum, # Sympy accept >2 inputs, Aesara only 2 + sympy.conjugate: aet.conj, + sympy.core.numbers.ImaginaryUnit: lambda:aet.complex(0,1), + # Matrices + sympy.MatAdd: Elemwise(aes.add), + sympy.HadamardProduct: Elemwise(aes.mul), + sympy.Trace: nlinalg.trace, + sympy.Determinant : nlinalg.det, + sympy.Inverse: nlinalg.matrix_inverse, + sympy.Transpose: DimShuffle((False, False), [1, 0]), + } + + +class AesaraPrinter(Printer): + """ + .. deprecated:: 1.14. + The ``Aesara Code printing`` is deprecated.See its documentation for + more information. See :ref:`deprecated-aesaraprinter` for details. + + Code printer which creates Aesara symbolic expression graphs. + + Parameters + ========== + + cache : dict + Cache dictionary to use. If None (default) will use + the global cache. To create a printer which does not depend on or alter + global state pass an empty dictionary. Note: the dictionary is not + copied on initialization of the printer and will be updated in-place, + so using the same dict object when creating multiple printers or making + multiple calls to :func:`.aesara_code` or :func:`.aesara_function` means + the cache is shared between all these applications. + + Attributes + ========== + + cache : dict + A cache of Aesara variables which have been created for SymPy + symbol-like objects (e.g. :class:`sympy.core.symbol.Symbol` or + :class:`sympy.matrices.expressions.MatrixSymbol`). This is used to + ensure that all references to a given symbol in an expression (or + multiple expressions) are printed as the same Aesara variable, which is + created only once. Symbols are differentiated only by name and type. The + format of the cache's contents should be considered opaque to the user. + """ + printmethod = "_aesara" + + def __init__(self, *args, **kwargs): + self.cache = kwargs.pop('cache', {}) + super().__init__(*args, **kwargs) + + def _get_key(self, s, name=None, dtype=None, broadcastable=None): + """ Get the cache key for a SymPy object. + + Parameters + ========== + + s : sympy.core.basic.Basic + SymPy object to get key for. + + name : str + Name of object, if it does not have a ``name`` attribute. + """ + + if name is None: + name = s.name + + return (name, type(s), s.args, dtype, broadcastable) + + def _get_or_create(self, s, name=None, dtype=None, broadcastable=None): + """ + Get the Aesara variable for a SymPy symbol from the cache, or create it + if it does not exist. + """ + + # Defaults + if name is None: + name = s.name + if dtype is None: + dtype = 'floatX' + if broadcastable is None: + broadcastable = () + + key = self._get_key(s, name, dtype=dtype, broadcastable=broadcastable) + + if key in self.cache: + return self.cache[key] + + value = aet.tensor(name=name, dtype=dtype, shape=broadcastable) + self.cache[key] = value + return value + + def _print_Symbol(self, s, **kwargs): + dtype = kwargs.get('dtypes', {}).get(s) + bc = kwargs.get('broadcastables', {}).get(s) + return self._get_or_create(s, dtype=dtype, broadcastable=bc) + + def _print_AppliedUndef(self, s, **kwargs): + name = str(type(s)) + '_' + str(s.args[0]) + dtype = kwargs.get('dtypes', {}).get(s) + bc = kwargs.get('broadcastables', {}).get(s) + return self._get_or_create(s, name=name, dtype=dtype, broadcastable=bc) + + def _print_Basic(self, expr, **kwargs): + op = mapping[type(expr)] + children = [self._print(arg, **kwargs) for arg in expr.args] + return op(*children) + + def _print_Number(self, n, **kwargs): + # Integers already taken care of below, interpret as float + return float(n.evalf()) + + def _print_MatrixSymbol(self, X, **kwargs): + dtype = kwargs.get('dtypes', {}).get(X) + return self._get_or_create(X, dtype=dtype, broadcastable=(None, None)) + + def _print_DenseMatrix(self, X, **kwargs): + if not hasattr(aet, 'stacklists'): + raise NotImplementedError( + "Matrix translation not yet supported in this version of Aesara") + + return aet.stacklists([ + [self._print(arg, **kwargs) for arg in L] + for L in X.tolist() + ]) + + _print_ImmutableMatrix = _print_ImmutableDenseMatrix = _print_DenseMatrix + + def _print_MatMul(self, expr, **kwargs): + children = [self._print(arg, **kwargs) for arg in expr.args] + result = children[0] + for child in children[1:]: + result = aet.dot(result, child) + return result + + def _print_MatPow(self, expr, **kwargs): + children = [self._print(arg, **kwargs) for arg in expr.args] + result = 1 + if isinstance(children[1], int) and children[1] > 0: + for i in range(children[1]): + result = aet.dot(result, children[0]) + else: + raise NotImplementedError('''Only non-negative integer + powers of matrices can be handled by Aesara at the moment''') + return result + + def _print_MatrixSlice(self, expr, **kwargs): + parent = self._print(expr.parent, **kwargs) + rowslice = self._print(slice(*expr.rowslice), **kwargs) + colslice = self._print(slice(*expr.colslice), **kwargs) + return parent[rowslice, colslice] + + def _print_BlockMatrix(self, expr, **kwargs): + nrows, ncols = expr.blocks.shape + blocks = [[self._print(expr.blocks[r, c], **kwargs) + for c in range(ncols)] + for r in range(nrows)] + return aet.join(0, *[aet.join(1, *row) for row in blocks]) + + + def _print_slice(self, expr, **kwargs): + return slice(*[self._print(i, **kwargs) + if isinstance(i, sympy.Basic) else i + for i in (expr.start, expr.stop, expr.step)]) + + def _print_Pi(self, expr, **kwargs): + return math.pi + + def _print_Piecewise(self, expr, **kwargs): + import numpy as np + e, cond = expr.args[0].args # First condition and corresponding value + + # Print conditional expression and value for first condition + p_cond = self._print(cond, **kwargs) + p_e = self._print(e, **kwargs) + + # One condition only + if len(expr.args) == 1: + # Return value if condition else NaN + return aet.switch(p_cond, p_e, np.nan) + + # Return value_1 if condition_1 else evaluate remaining conditions + p_remaining = self._print(sympy.Piecewise(*expr.args[1:]), **kwargs) + return aet.switch(p_cond, p_e, p_remaining) + + def _print_Rational(self, expr, **kwargs): + return true_divide(self._print(expr.p, **kwargs), + self._print(expr.q, **kwargs)) + + def _print_Integer(self, expr, **kwargs): + return expr.p + + def _print_factorial(self, expr, **kwargs): + return self._print(sympy.gamma(expr.args[0] + 1), **kwargs) + + def _print_Derivative(self, deriv, **kwargs): + from aesara.gradient import Rop + + rv = self._print(deriv.expr, **kwargs) + for var in deriv.variables: + var = self._print(var, **kwargs) + rv = Rop(rv, var, aet.ones_like(var)) + return rv + + def emptyPrinter(self, expr): + return expr + + def doprint(self, expr, dtypes=None, broadcastables=None): + """ Convert a SymPy expression to a Aesara graph variable. + + The ``dtypes`` and ``broadcastables`` arguments are used to specify the + data type, dimension, and broadcasting behavior of the Aesara variables + corresponding to the free symbols in ``expr``. Each is a mapping from + SymPy symbols to the value of the corresponding argument to + ``aesara.tensor.var.TensorVariable``. + + See the corresponding `documentation page`__ for more information on + broadcasting in Aesara. + + + .. __: https://aesara.readthedocs.io/en/latest/reference/tensor/shapes.html#broadcasting + + Parameters + ========== + + expr : sympy.core.expr.Expr + SymPy expression to print. + + dtypes : dict + Mapping from SymPy symbols to Aesara datatypes to use when creating + new Aesara variables for those symbols. Corresponds to the ``dtype`` + argument to ``aesara.tensor.var.TensorVariable``. Defaults to ``'floatX'`` + for symbols not included in the mapping. + + broadcastables : dict + Mapping from SymPy symbols to the value of the ``broadcastable`` + argument to ``aesara.tensor.var.TensorVariable`` to use when creating Aesara + variables for those symbols. Defaults to the empty tuple for symbols + not included in the mapping (resulting in a scalar). + + Returns + ======= + + aesara.graph.basic.Variable + A variable corresponding to the expression's value in a Aesara + symbolic expression graph. + + """ + if dtypes is None: + dtypes = {} + if broadcastables is None: + broadcastables = {} + + return self._print(expr, dtypes=dtypes, broadcastables=broadcastables) + + +global_cache: dict[Any, Any] = {} + + +def aesara_code(expr, cache=None, **kwargs): + """ + Convert a SymPy expression into a Aesara graph variable. + + Parameters + ========== + + expr : sympy.core.expr.Expr + SymPy expression object to convert. + + cache : dict + Cached Aesara variables (see :class:`AesaraPrinter.cache + `). Defaults to the module-level global cache. + + dtypes : dict + Passed to :meth:`.AesaraPrinter.doprint`. + + broadcastables : dict + Passed to :meth:`.AesaraPrinter.doprint`. + + Returns + ======= + + aesara.graph.basic.Variable + A variable corresponding to the expression's value in a Aesara symbolic + expression graph. + + """ + sympy_deprecation_warning( + """ + The aesara_code function is deprecated. + """, + deprecated_since_version="1.14", + active_deprecations_target='deprecated-aesaraprinter', + ) + + if not aesara: + raise ImportError("aesara is required for aesara_code") + + if cache is None: + cache = global_cache + + return AesaraPrinter(cache=cache, settings={}).doprint(expr, **kwargs) + + +def dim_handling(inputs, dim=None, dims=None, broadcastables=None): + r""" + Get value of ``broadcastables`` argument to :func:`.aesara_code` from + keyword arguments to :func:`.aesara_function`. + + Included for backwards compatibility. + + Parameters + ========== + + inputs + Sequence of input symbols. + + dim : int + Common number of dimensions for all inputs. Overrides other arguments + if given. + + dims : dict + Mapping from input symbols to number of dimensions. Overrides + ``broadcastables`` argument if given. + + broadcastables : dict + Explicit value of ``broadcastables`` argument to + :meth:`.AesaraPrinter.doprint`. If not None function will return this value unchanged. + + Returns + ======= + dict + Dictionary mapping elements of ``inputs`` to their "broadcastable" + values (tuple of ``bool``\ s). + """ + if dim is not None: + return dict.fromkeys(inputs, (False,) * dim) + + if dims is not None: + maxdim = max(dims.values()) + return { + s: (False,) * d + (True,) * (maxdim - d) + for s, d in dims.items() + } + + if broadcastables is not None: + return broadcastables + + return {} + + +def aesara_function(inputs, outputs, scalar=False, *, + dim=None, dims=None, broadcastables=None, **kwargs): + """ + Create a Aesara function from SymPy expressions. + + The inputs and outputs are converted to Aesara variables using + :func:`.aesara_code` and then passed to ``aesara.function``. + + Parameters + ========== + + inputs + Sequence of symbols which constitute the inputs of the function. + + outputs + Sequence of expressions which constitute the outputs(s) of the + function. The free symbols of each expression must be a subset of + ``inputs``. + + scalar : bool + Convert 0-dimensional arrays in output to scalars. This will return a + Python wrapper function around the Aesara function object. + + cache : dict + Cached Aesara variables (see :class:`AesaraPrinter.cache + `). Defaults to the module-level global cache. + + dtypes : dict + Passed to :meth:`.AesaraPrinter.doprint`. + + broadcastables : dict + Passed to :meth:`.AesaraPrinter.doprint`. + + dims : dict + Alternative to ``broadcastables`` argument. Mapping from elements of + ``inputs`` to integers indicating the dimension of their associated + arrays/tensors. Overrides ``broadcastables`` argument if given. + + dim : int + Another alternative to the ``broadcastables`` argument. Common number of + dimensions to use for all arrays/tensors. + ``aesara_function([x, y], [...], dim=2)`` is equivalent to using + ``broadcastables={x: (False, False), y: (False, False)}``. + + Returns + ======= + callable + A callable object which takes values of ``inputs`` as positional + arguments and returns an output array for each of the expressions + in ``outputs``. If ``outputs`` is a single expression the function will + return a Numpy array, if it is a list of multiple expressions the + function will return a list of arrays. See description of the ``squeeze`` + argument above for the behavior when a single output is passed in a list. + The returned object will either be an instance of + ``aesara.compile.function.types.Function`` or a Python wrapper + function around one. In both cases, the returned value will have a + ``aesara_function`` attribute which points to the return value of + ``aesara.function``. + + Examples + ======== + + >>> from sympy.abc import x, y, z + >>> from sympy.printing.aesaracode import aesara_function + + A simple function with one input and one output: + + >>> f1 = aesara_function([x], [x**2 - 1], scalar=True) + >>> f1(3) + 8.0 + + A function with multiple inputs and one output: + + >>> f2 = aesara_function([x, y, z], [(x**z + y**z)**(1/z)], scalar=True) + >>> f2(3, 4, 2) + 5.0 + + A function with multiple inputs and multiple outputs: + + >>> f3 = aesara_function([x, y], [x**2 + y**2, x**2 - y**2], scalar=True) + >>> f3(2, 3) + [13.0, -5.0] + + See also + ======== + + dim_handling + + """ + sympy_deprecation_warning( + """ + The aesara_function function is deprecated. + """, + deprecated_since_version="1.14", + active_deprecations_target='deprecated-aesaraprinter', + ) + + if not aesara: + raise ImportError("Aesara is required for aesara_function") + + # Pop off non-aesara keyword args + cache = kwargs.pop('cache', {}) + dtypes = kwargs.pop('dtypes', {}) + + broadcastables = dim_handling( + inputs, dim=dim, dims=dims, broadcastables=broadcastables, + ) + + # Print inputs/outputs + code = partial(aesara_code, cache=cache, dtypes=dtypes, + broadcastables=broadcastables) + tinputs = list(map(code, inputs)) + toutputs = list(map(code, outputs)) + + #fix constant expressions as variables + toutputs = [output if isinstance(output, aesara.graph.basic.Variable) else aet.as_tensor_variable(output) for output in toutputs] + + if len(toutputs) == 1: + toutputs = toutputs[0] + + # Compile aesara func + func = aesara.function(tinputs, toutputs, **kwargs) + + is_0d = [len(o.variable.broadcastable) == 0 for o in func.outputs] + + # No wrapper required + if not scalar or not any(is_0d): + func.aesara_function = func + return func + + # Create wrapper to convert 0-dimensional outputs to scalars + def wrapper(*args): + out = func(*args) + # out can be array(1.0) or [array(1.0), array(2.0)] + + if is_sequence(out): + return [o[()] if is_0d[i] else o for i, o in enumerate(out)] + else: + return out[()] + + wrapper.__wrapped__ = func + wrapper.__doc__ = func.__doc__ + wrapper.aesara_function = func + return wrapper diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/c.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/c.py new file mode 100644 index 0000000000000000000000000000000000000000..34c4b8f021073aeee7672248838557b5fa85fbae --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/c.py @@ -0,0 +1,747 @@ +""" +C code printer + +The C89CodePrinter & C99CodePrinter converts single SymPy expressions into +single C expressions, using the functions defined in math.h where possible. + +A complete code generator, which uses ccode extensively, can be found in +sympy.utilities.codegen. The codegen module can be used to generate complete +source code files that are compilable without further modifications. + + +""" + +from __future__ import annotations +from typing import Any + +from functools import wraps +from itertools import chain + +from sympy.core import S +from sympy.core.numbers import equal_valued, Float +from sympy.codegen.ast import ( + Assignment, Pointer, Variable, Declaration, Type, + real, complex_, integer, bool_, float32, float64, float80, + complex64, complex128, intc, value_const, pointer_const, + int8, int16, int32, int64, uint8, uint16, uint32, uint64, untyped, + none +) +from sympy.printing.codeprinter import CodePrinter, requires +from sympy.printing.precedence import precedence, PRECEDENCE +from sympy.sets.fancysets import Range + +# These are defined in the other file so we can avoid importing sympy.codegen +# from the top-level 'import sympy'. Export them here as well. +from sympy.printing.codeprinter import ccode, print_ccode # noqa:F401 + +# dictionary mapping SymPy function to (argument_conditions, C_function). +# Used in C89CodePrinter._print_Function(self) +known_functions_C89 = { + "Abs": [(lambda x: not x.is_integer, "fabs"), (lambda x: x.is_integer, "abs")], + "sin": "sin", + "cos": "cos", + "tan": "tan", + "asin": "asin", + "acos": "acos", + "atan": "atan", + "atan2": "atan2", + "exp": "exp", + "log": "log", + "log10": "log10", + "sinh": "sinh", + "cosh": "cosh", + "tanh": "tanh", + "floor": "floor", + "ceiling": "ceil", + "sqrt": "sqrt", # To enable automatic rewrites +} + +known_functions_C99 = dict(known_functions_C89, **{ + 'exp2': 'exp2', + 'expm1': 'expm1', + 'log2': 'log2', + 'log1p': 'log1p', + 'Cbrt': 'cbrt', + 'hypot': 'hypot', + 'fma': 'fma', + 'loggamma': 'lgamma', + 'erfc': 'erfc', + 'Max': 'fmax', + 'Min': 'fmin', + "asinh": "asinh", + "acosh": "acosh", + "atanh": "atanh", + "erf": "erf", + "gamma": "tgamma", +}) + +# These are the core reserved words in the C language. Taken from: +# https://en.cppreference.com/w/c/keyword + +reserved_words = [ + 'auto', 'break', 'case', 'char', 'const', 'continue', 'default', 'do', + 'double', 'else', 'enum', 'extern', 'float', 'for', 'goto', 'if', 'int', + 'long', 'register', 'return', 'short', 'signed', 'sizeof', 'static', + 'struct', 'entry', # never standardized, we'll leave it here anyway + 'switch', 'typedef', 'union', 'unsigned', 'void', 'volatile', 'while' +] + +reserved_words_c99 = ['inline', 'restrict'] + +def get_math_macros(): + """ Returns a dictionary with math-related macros from math.h/cmath + + Note that these macros are not strictly required by the C/C++-standard. + For MSVC they are enabled by defining "_USE_MATH_DEFINES" (preferably + via a compilation flag). + + Returns + ======= + + Dictionary mapping SymPy expressions to strings (macro names) + + """ + from sympy.codegen.cfunctions import log2, Sqrt + from sympy.functions.elementary.exponential import log + from sympy.functions.elementary.miscellaneous import sqrt + + return { + S.Exp1: 'M_E', + log2(S.Exp1): 'M_LOG2E', + 1/log(2): 'M_LOG2E', + log(2): 'M_LN2', + log(10): 'M_LN10', + S.Pi: 'M_PI', + S.Pi/2: 'M_PI_2', + S.Pi/4: 'M_PI_4', + 1/S.Pi: 'M_1_PI', + 2/S.Pi: 'M_2_PI', + 2/sqrt(S.Pi): 'M_2_SQRTPI', + 2/Sqrt(S.Pi): 'M_2_SQRTPI', + sqrt(2): 'M_SQRT2', + Sqrt(2): 'M_SQRT2', + 1/sqrt(2): 'M_SQRT1_2', + 1/Sqrt(2): 'M_SQRT1_2' + } + + +def _as_macro_if_defined(meth): + """ Decorator for printer methods + + When a Printer's method is decorated using this decorator the expressions printed + will first be looked for in the attribute ``math_macros``, and if present it will + print the macro name in ``math_macros`` followed by a type suffix for the type + ``real``. e.g. printing ``sympy.pi`` would print ``M_PIl`` if real is mapped to float80. + + """ + @wraps(meth) + def _meth_wrapper(self, expr, **kwargs): + if expr in self.math_macros: + return '%s%s' % (self.math_macros[expr], self._get_math_macro_suffix(real)) + else: + return meth(self, expr, **kwargs) + + return _meth_wrapper + + +class C89CodePrinter(CodePrinter): + """A printer to convert Python expressions to strings of C code""" + printmethod = "_ccode" + language = "C" + standard = "C89" + reserved_words = set(reserved_words) + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 17, + 'user_functions': {}, + 'contract': True, + 'dereference': set(), + 'error_on_reserved': False, + }) + + type_aliases = { + real: float64, + complex_: complex128, + integer: intc + } + + type_mappings: dict[Type, Any] = { + real: 'double', + intc: 'int', + float32: 'float', + float64: 'double', + integer: 'int', + bool_: 'bool', + int8: 'int8_t', + int16: 'int16_t', + int32: 'int32_t', + int64: 'int64_t', + uint8: 'int8_t', + uint16: 'int16_t', + uint32: 'int32_t', + uint64: 'int64_t', + } + + type_headers = { + bool_: {'stdbool.h'}, + int8: {'stdint.h'}, + int16: {'stdint.h'}, + int32: {'stdint.h'}, + int64: {'stdint.h'}, + uint8: {'stdint.h'}, + uint16: {'stdint.h'}, + uint32: {'stdint.h'}, + uint64: {'stdint.h'}, + } + + # Macros needed to be defined when using a Type + type_macros: dict[Type, tuple[str, ...]] = {} + + type_func_suffixes = { + float32: 'f', + float64: '', + float80: 'l' + } + + type_literal_suffixes = { + float32: 'F', + float64: '', + float80: 'L' + } + + type_math_macro_suffixes = { + float80: 'l' + } + + math_macros = None + + _ns = '' # namespace, C++ uses 'std::' + # known_functions-dict to copy + _kf: dict[str, Any] = known_functions_C89 + + def __init__(self, settings=None): + settings = settings or {} + if self.math_macros is None: + self.math_macros = settings.pop('math_macros', get_math_macros()) + self.type_aliases = dict(chain(self.type_aliases.items(), + settings.pop('type_aliases', {}).items())) + self.type_mappings = dict(chain(self.type_mappings.items(), + settings.pop('type_mappings', {}).items())) + self.type_headers = dict(chain(self.type_headers.items(), + settings.pop('type_headers', {}).items())) + self.type_macros = dict(chain(self.type_macros.items(), + settings.pop('type_macros', {}).items())) + self.type_func_suffixes = dict(chain(self.type_func_suffixes.items(), + settings.pop('type_func_suffixes', {}).items())) + self.type_literal_suffixes = dict(chain(self.type_literal_suffixes.items(), + settings.pop('type_literal_suffixes', {}).items())) + self.type_math_macro_suffixes = dict(chain(self.type_math_macro_suffixes.items(), + settings.pop('type_math_macro_suffixes', {}).items())) + super().__init__(settings) + self.known_functions = dict(self._kf, **settings.get('user_functions', {})) + self._dereference = set(settings.get('dereference', [])) + self.headers = set() + self.libraries = set() + self.macros = set() + + def _rate_index_position(self, p): + return p*5 + + def _get_statement(self, codestring): + """ Get code string as a statement - i.e. ending with a semicolon. """ + return codestring if codestring.endswith(';') else codestring + ';' + + def _get_comment(self, text): + return "/* {} */".format(text) + + def _declare_number_const(self, name, value): + type_ = self.type_aliases[real] + var = Variable(name, type=type_, value=value.evalf(type_.decimal_dig), attrs={value_const}) + decl = Declaration(var) + return self._get_statement(self._print(decl)) + + def _format_code(self, lines): + return self.indent_code(lines) + + def _traverse_matrix_indices(self, mat): + rows, cols = mat.shape + return ((i, j) for i in range(rows) for j in range(cols)) + + @_as_macro_if_defined + def _print_Mul(self, expr, **kwargs): + return super()._print_Mul(expr, **kwargs) + + @_as_macro_if_defined + def _print_Pow(self, expr): + if "Pow" in self.known_functions: + return self._print_Function(expr) + PREC = precedence(expr) + suffix = self._get_func_suffix(real) + if equal_valued(expr.exp, -1): + return '%s/%s' % (self._print_Float(Float(1.0)), self.parenthesize(expr.base, PREC)) + elif equal_valued(expr.exp, 0.5): + return '%ssqrt%s(%s)' % (self._ns, suffix, self._print(expr.base)) + elif expr.exp == S.One/3 and self.standard != 'C89': + return '%scbrt%s(%s)' % (self._ns, suffix, self._print(expr.base)) + else: + return '%spow%s(%s, %s)' % (self._ns, suffix, self._print(expr.base), + self._print(expr.exp)) + + def _print_Mod(self, expr): + num, den = expr.args + if num.is_integer and den.is_integer: + PREC = precedence(expr) + snum, sden = [self.parenthesize(arg, PREC) for arg in expr.args] + # % is remainder (same sign as numerator), not modulo (same sign as + # denominator), in C. Hence, % only works as modulo if both numbers + # have the same sign + if (num.is_nonnegative and den.is_nonnegative or + num.is_nonpositive and den.is_nonpositive): + return f"{snum} % {sden}" + return f"(({snum} % {sden}) + {sden}) % {sden}" + # Not guaranteed integer + return self._print_math_func(expr, known='fmod') + + def _print_Rational(self, expr): + p, q = int(expr.p), int(expr.q) + suffix = self._get_literal_suffix(real) + return '%d.0%s/%d.0%s' % (p, suffix, q, suffix) + + def _print_Indexed(self, expr): + # calculate index for 1d array + offset = getattr(expr.base, 'offset', S.Zero) + strides = getattr(expr.base, 'strides', None) + indices = expr.indices + + if strides is None or isinstance(strides, str): + dims = expr.shape + shift = S.One + temp = () + if strides == 'C' or strides is None: + traversal = reversed(range(expr.rank)) + indices = indices[::-1] + elif strides == 'F': + traversal = range(expr.rank) + + for i in traversal: + temp += (shift,) + shift *= dims[i] + strides = temp + flat_index = sum(x[0]*x[1] for x in zip(indices, strides)) + offset + return "%s[%s]" % (self._print(expr.base.label), + self._print(flat_index)) + + @_as_macro_if_defined + def _print_NumberSymbol(self, expr): + return super()._print_NumberSymbol(expr) + + def _print_Infinity(self, expr): + return 'HUGE_VAL' + + def _print_NegativeInfinity(self, expr): + return '-HUGE_VAL' + + def _print_Piecewise(self, expr): + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + if expr.has(Assignment): + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s) {" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines.append("else {") + else: + lines.append("else if (%s) {" % self._print(c)) + code0 = self._print(e) + lines.append(code0) + lines.append("}") + return "\n".join(lines) + else: + # The piecewise was used in an expression, need to do inline + # operators. This has the downside that inline operators will + # not work for statements that span multiple lines (Matrix or + # Indexed expressions). + ecpairs = ["((%s) ? (\n%s\n)\n" % (self._print(c), + self._print(e)) + for e, c in expr.args[:-1]] + last_line = ": (\n%s\n)" % self._print(expr.args[-1].expr) + return ": ".join(ecpairs) + last_line + " ".join([")"*len(ecpairs)]) + + def _print_ITE(self, expr): + from sympy.functions import Piecewise + return self._print(expr.rewrite(Piecewise, deep=False)) + + def _print_MatrixElement(self, expr): + return "{}[{}]".format(self.parenthesize(expr.parent, PRECEDENCE["Atom"], + strict=True), expr.j + expr.i*expr.parent.shape[1]) + + def _print_Symbol(self, expr): + name = super()._print_Symbol(expr) + if expr in self._settings['dereference']: + return '(*{})'.format(name) + else: + return name + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_For(self, expr): + target = self._print(expr.target) + if isinstance(expr.iterable, Range): + start, stop, step = expr.iterable.args + else: + raise NotImplementedError("Only iterable currently supported is Range") + body = self._print(expr.body) + return ('for ({target} = {start}; {target} < {stop}; {target} += ' + '{step}) {{\n{body}\n}}').format(target=target, start=start, + stop=stop, step=step, body=body) + + def _print_sign(self, func): + return '((({0}) > 0) - (({0}) < 0))'.format(self._print(func.args[0])) + + def _print_Max(self, expr): + if "Max" in self.known_functions: + return self._print_Function(expr) + def inner_print_max(args): # The more natural abstraction of creating + if len(args) == 1: # and printing smaller Max objects is slow + return self._print(args[0]) # when there are many arguments. + half = len(args) // 2 + return "((%(a)s > %(b)s) ? %(a)s : %(b)s)" % { + 'a': inner_print_max(args[:half]), + 'b': inner_print_max(args[half:]) + } + return inner_print_max(expr.args) + + def _print_Min(self, expr): + if "Min" in self.known_functions: + return self._print_Function(expr) + def inner_print_min(args): # The more natural abstraction of creating + if len(args) == 1: # and printing smaller Min objects is slow + return self._print(args[0]) # when there are many arguments. + half = len(args) // 2 + return "((%(a)s < %(b)s) ? %(a)s : %(b)s)" % { + 'a': inner_print_min(args[:half]), + 'b': inner_print_min(args[half:]) + } + return inner_print_min(expr.args) + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_token = ('{', '(', '{\n', '(\n') + dec_token = ('}', ')') + + code = [line.lstrip(' \t') for line in code] + + increase = [int(any(map(line.endswith, inc_token))) for line in code] + decrease = [int(any(map(line.startswith, dec_token))) for line in code] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty + + def _get_func_suffix(self, type_): + return self.type_func_suffixes[self.type_aliases.get(type_, type_)] + + def _get_literal_suffix(self, type_): + return self.type_literal_suffixes[self.type_aliases.get(type_, type_)] + + def _get_math_macro_suffix(self, type_): + alias = self.type_aliases.get(type_, type_) + dflt = self.type_math_macro_suffixes.get(alias, '') + return self.type_math_macro_suffixes.get(type_, dflt) + + def _print_Tuple(self, expr): + return '{'+', '.join(self._print(e) for e in expr)+'}' + + _print_List = _print_Tuple + + def _print_Type(self, type_): + self.headers.update(self.type_headers.get(type_, set())) + self.macros.update(self.type_macros.get(type_, set())) + return self._print(self.type_mappings.get(type_, type_.name)) + + def _print_Declaration(self, decl): + from sympy.codegen.cnodes import restrict + var = decl.variable + val = var.value + if var.type == untyped: + raise ValueError("C does not support untyped variables") + + if isinstance(var, Pointer): + result = '{vc}{t} *{pc} {r}{s}'.format( + vc='const ' if value_const in var.attrs else '', + t=self._print(var.type), + pc=' const' if pointer_const in var.attrs else '', + r='restrict ' if restrict in var.attrs else '', + s=self._print(var.symbol) + ) + elif isinstance(var, Variable): + result = '{vc}{t} {s}'.format( + vc='const ' if value_const in var.attrs else '', + t=self._print(var.type), + s=self._print(var.symbol) + ) + else: + raise NotImplementedError("Unknown type of var: %s" % type(var)) + if val != None: # Must be "!= None", cannot be "is not None" + result += ' = %s' % self._print(val) + return result + + def _print_Float(self, flt): + type_ = self.type_aliases.get(real, real) + self.macros.update(self.type_macros.get(type_, set())) + suffix = self._get_literal_suffix(type_) + num = str(flt.evalf(type_.decimal_dig)) + if 'e' not in num and '.' not in num: + num += '.0' + num_parts = num.split('e') + num_parts[0] = num_parts[0].rstrip('0') + if num_parts[0].endswith('.'): + num_parts[0] += '0' + return 'e'.join(num_parts) + suffix + + @requires(headers={'stdbool.h'}) + def _print_BooleanTrue(self, expr): + return 'true' + + @requires(headers={'stdbool.h'}) + def _print_BooleanFalse(self, expr): + return 'false' + + def _print_Element(self, elem): + if elem.strides == None: # Must be "== None", cannot be "is None" + if elem.offset != None: # Must be "!= None", cannot be "is not None" + raise ValueError("Expected strides when offset is given") + idxs = ']['.join((self._print(arg) for arg in elem.indices)) + else: + global_idx = sum(i*s for i, s in zip(elem.indices, elem.strides)) + if elem.offset != None: # Must be "!= None", cannot be "is not None" + global_idx += elem.offset + idxs = self._print(global_idx) + + return "{symb}[{idxs}]".format( + symb=self._print(elem.symbol), + idxs=idxs + ) + + def _print_CodeBlock(self, expr): + """ Elements of code blocks printed as statements. """ + return '\n'.join([self._get_statement(self._print(i)) for i in expr.args]) + + def _print_While(self, expr): + return 'while ({condition}) {{\n{body}\n}}'.format(**expr.kwargs( + apply=lambda arg: self._print(arg))) + + def _print_Scope(self, expr): + return '{\n%s\n}' % self._print_CodeBlock(expr.body) + + @requires(headers={'stdio.h'}) + def _print_Print(self, expr): + if expr.file == none: + template = 'printf({fmt}, {pargs})' + else: + template = 'fprintf(%(out)s, {fmt}, {pargs})' % { + 'out': self._print(expr.file) + } + return template.format( + fmt="%s\n" if expr.format_string == none else self._print(expr.format_string), + pargs=', '.join((self._print(arg) for arg in expr.print_args)) + ) + + def _print_Stream(self, strm): + return strm.name + + def _print_FunctionPrototype(self, expr): + pars = ', '.join((self._print(Declaration(arg)) for arg in expr.parameters)) + return "%s %s(%s)" % ( + tuple((self._print(arg) for arg in (expr.return_type, expr.name))) + (pars,) + ) + + def _print_FunctionDefinition(self, expr): + return "%s%s" % (self._print_FunctionPrototype(expr), + self._print_Scope(expr)) + + def _print_Return(self, expr): + arg, = expr.args + return 'return %s' % self._print(arg) + + def _print_CommaOperator(self, expr): + return '(%s)' % ', '.join((self._print(arg) for arg in expr.args)) + + def _print_Label(self, expr): + if expr.body == none: + return '%s:' % str(expr.name) + if len(expr.body.args) == 1: + return '%s:\n%s' % (str(expr.name), self._print_CodeBlock(expr.body)) + return '%s:\n{\n%s\n}' % (str(expr.name), self._print_CodeBlock(expr.body)) + + def _print_goto(self, expr): + return 'goto %s' % expr.label.name + + def _print_PreIncrement(self, expr): + arg, = expr.args + return '++(%s)' % self._print(arg) + + def _print_PostIncrement(self, expr): + arg, = expr.args + return '(%s)++' % self._print(arg) + + def _print_PreDecrement(self, expr): + arg, = expr.args + return '--(%s)' % self._print(arg) + + def _print_PostDecrement(self, expr): + arg, = expr.args + return '(%s)--' % self._print(arg) + + def _print_struct(self, expr): + return "%(keyword)s %(name)s {\n%(lines)s}" % { + "keyword": expr.__class__.__name__, "name": expr.name, "lines": ';\n'.join( + [self._print(decl) for decl in expr.declarations] + ['']) + } + + def _print_BreakToken(self, _): + return 'break' + + def _print_ContinueToken(self, _): + return 'continue' + + _print_union = _print_struct + +class C99CodePrinter(C89CodePrinter): + standard = 'C99' + reserved_words = set(reserved_words + reserved_words_c99) + type_mappings=dict(chain(C89CodePrinter.type_mappings.items(), { + complex64: 'float complex', + complex128: 'double complex', + }.items())) + type_headers = dict(chain(C89CodePrinter.type_headers.items(), { + complex64: {'complex.h'}, + complex128: {'complex.h'} + }.items())) + + # known_functions-dict to copy + _kf: dict[str, Any] = known_functions_C99 + + # functions with versions with 'f' and 'l' suffixes: + _prec_funcs = ('fabs fmod remainder remquo fma fmax fmin fdim nan exp exp2' + ' expm1 log log10 log2 log1p pow sqrt cbrt hypot sin cos tan' + ' asin acos atan atan2 sinh cosh tanh asinh acosh atanh erf' + ' erfc tgamma lgamma ceil floor trunc round nearbyint rint' + ' frexp ldexp modf scalbn ilogb logb nextafter copysign').split() + + def _print_Infinity(self, expr): + return 'INFINITY' + + def _print_NegativeInfinity(self, expr): + return '-INFINITY' + + def _print_NaN(self, expr): + return 'NAN' + + # tgamma was already covered by 'known_functions' dict + + @requires(headers={'math.h'}, libraries={'m'}) + @_as_macro_if_defined + def _print_math_func(self, expr, nest=False, known=None): + if known is None: + known = self.known_functions[expr.__class__.__name__] + if not isinstance(known, str): + for cb, name in known: + if cb(*expr.args): + known = name + break + else: + raise ValueError("No matching printer") + try: + return known(self, *expr.args) + except TypeError: + suffix = self._get_func_suffix(real) if self._ns + known in self._prec_funcs else '' + + if nest: + args = self._print(expr.args[0]) + if len(expr.args) > 1: + paren_pile = '' + for curr_arg in expr.args[1:-1]: + paren_pile += ')' + args += ', {ns}{name}{suffix}({next}'.format( + ns=self._ns, + name=known, + suffix=suffix, + next = self._print(curr_arg) + ) + args += ', %s%s' % ( + self._print(expr.func(expr.args[-1])), + paren_pile + ) + else: + args = ', '.join((self._print(arg) for arg in expr.args)) + return '{ns}{name}{suffix}({args})'.format( + ns=self._ns, + name=known, + suffix=suffix, + args=args + ) + + def _print_Max(self, expr): + return self._print_math_func(expr, nest=True) + + def _print_Min(self, expr): + return self._print_math_func(expr, nest=True) + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + loopstart = "for (int %(var)s=%(start)s; %(var)s<%(end)s; %(var)s++){" # C99 + for i in indices: + # C arrays start at 0 and end at dimension-1 + open_lines.append(loopstart % { + 'var': self._print(i.label), + 'start': self._print(i.lower), + 'end': self._print(i.upper + 1)}) + close_lines.append("}") + return open_lines, close_lines + + +for k in ('Abs Sqrt exp exp2 expm1 log log10 log2 log1p Cbrt hypot fma' + ' loggamma sin cos tan asin acos atan atan2 sinh cosh tanh asinh acosh ' + 'atanh erf erfc loggamma gamma ceiling floor').split(): + setattr(C99CodePrinter, '_print_%s' % k, C99CodePrinter._print_math_func) + + +class C11CodePrinter(C99CodePrinter): + + @requires(headers={'stdalign.h'}) + def _print_alignof(self, expr): + arg, = expr.args + return 'alignof(%s)' % self._print(arg) + + +c_code_printers = { + 'c89': C89CodePrinter, + 'c99': C99CodePrinter, + 'c11': C11CodePrinter +} diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/codeprinter.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/codeprinter.py new file mode 100644 index 0000000000000000000000000000000000000000..1faaa0f054cbd8ff438b90e914808f720d2da90a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/codeprinter.py @@ -0,0 +1,1039 @@ +from __future__ import annotations +from typing import Any + +from functools import wraps + +from sympy.core import Add, Mul, Pow, S, sympify, Float +from sympy.core.basic import Basic +from sympy.core.expr import Expr, UnevaluatedExpr +from sympy.core.function import Lambda +from sympy.core.mul import _keep_coeff +from sympy.core.sorting import default_sort_key +from sympy.core.symbol import Symbol +from sympy.functions.elementary.complexes import re +from sympy.printing.str import StrPrinter +from sympy.printing.precedence import precedence, PRECEDENCE + + +class requires: + """ Decorator for registering requirements on print methods. """ + def __init__(self, **kwargs): + self._req = kwargs + + def __call__(self, method): + def _method_wrapper(self_, *args, **kwargs): + for k, v in self._req.items(): + getattr(self_, k).update(v) + return method(self_, *args, **kwargs) + return wraps(method)(_method_wrapper) + + +class AssignmentError(Exception): + """ + Raised if an assignment variable for a loop is missing. + """ + pass + +class PrintMethodNotImplementedError(NotImplementedError): + """ + Raised if a _print_* method is missing in the Printer. + """ + pass + +def _convert_python_lists(arg): + if isinstance(arg, list): + from sympy.codegen.abstract_nodes import List + return List(*(_convert_python_lists(e) for e in arg)) + elif isinstance(arg, tuple): + return tuple(_convert_python_lists(e) for e in arg) + else: + return arg + + +class CodePrinter(StrPrinter): + """ + The base class for code-printing subclasses. + """ + + _operators = { + 'and': '&&', + 'or': '||', + 'not': '!', + } + + _default_settings: dict[str, Any] = { + 'order': None, + 'full_prec': 'auto', + 'error_on_reserved': False, + 'reserved_word_suffix': '_', + 'human': True, + 'inline': False, + 'allow_unknown_functions': False, + 'strict': None # True or False; None => True if human == True + } + + # Functions which are "simple" to rewrite to other functions that + # may be supported + # function_to_rewrite : (function_to_rewrite_to, iterable_with_other_functions_required) + _rewriteable_functions = { + 'cot': ('tan', []), + 'csc': ('sin', []), + 'sec': ('cos', []), + 'acot': ('atan', []), + 'acsc': ('asin', []), + 'asec': ('acos', []), + 'coth': ('exp', []), + 'csch': ('exp', []), + 'sech': ('exp', []), + 'acoth': ('log', []), + 'acsch': ('log', []), + 'asech': ('log', []), + 'catalan': ('gamma', []), + 'fibonacci': ('sqrt', []), + 'lucas': ('sqrt', []), + 'beta': ('gamma', []), + 'sinc': ('sin', ['Piecewise']), + 'Mod': ('floor', []), + 'factorial': ('gamma', []), + 'factorial2': ('gamma', ['Piecewise']), + 'subfactorial': ('uppergamma', []), + 'RisingFactorial': ('gamma', ['Piecewise']), + 'FallingFactorial': ('gamma', ['Piecewise']), + 'binomial': ('gamma', []), + 'frac': ('floor', []), + 'Max': ('Piecewise', []), + 'Min': ('Piecewise', []), + 'Heaviside': ('Piecewise', []), + 'erf2': ('erf', []), + 'erfc': ('erf', []), + 'Li': ('li', []), + 'Ei': ('li', []), + 'dirichlet_eta': ('zeta', []), + 'riemann_xi': ('zeta', ['gamma']), + 'SingularityFunction': ('Piecewise', []), + } + + def __init__(self, settings=None): + super().__init__(settings=settings) + if self._settings.get('strict', True) == None: + # for backwards compatibility, human=False need not to throw: + self._settings['strict'] = self._settings.get('human', True) == True + if not hasattr(self, 'reserved_words'): + self.reserved_words = set() + + def _handle_UnevaluatedExpr(self, expr): + return expr.replace(re, lambda arg: arg if isinstance( + arg, UnevaluatedExpr) and arg.args[0].is_real else re(arg)) + + def doprint(self, expr, assign_to=None): + """ + Print the expression as code. + + Parameters + ---------- + expr : Expression + The expression to be printed. + + assign_to : Symbol, string, MatrixSymbol, list of strings or Symbols (optional) + If provided, the printed code will set the expression to a variable or multiple variables + with the name or names given in ``assign_to``. + """ + from sympy.matrices.expressions.matexpr import MatrixSymbol + from sympy.codegen.ast import CodeBlock, Assignment + + def _handle_assign_to(expr, assign_to): + if assign_to is None: + return sympify(expr) + if isinstance(assign_to, (list, tuple)): + if len(expr) != len(assign_to): + raise ValueError('Failed to assign an expression of length {} to {} variables'.format(len(expr), len(assign_to))) + return CodeBlock(*[_handle_assign_to(lhs, rhs) for lhs, rhs in zip(expr, assign_to)]) + if isinstance(assign_to, str): + if expr.is_Matrix: + assign_to = MatrixSymbol(assign_to, *expr.shape) + else: + assign_to = Symbol(assign_to) + elif not isinstance(assign_to, Basic): + raise TypeError("{} cannot assign to object of type {}".format( + type(self).__name__, type(assign_to))) + return Assignment(assign_to, expr) + + expr = _convert_python_lists(expr) + expr = _handle_assign_to(expr, assign_to) + + # Remove re(...) nodes due to UnevaluatedExpr.is_real always is None: + expr = self._handle_UnevaluatedExpr(expr) + + # keep a set of expressions that are not strictly translatable to Code + # and number constants that must be declared and initialized + self._not_supported = set() + self._number_symbols = set() + + lines = self._print(expr).splitlines() + + # format the output + if self._settings["human"]: + frontlines = [] + if self._not_supported: + frontlines.append(self._get_comment( + "Not supported in {}:".format(self.language))) + for expr in sorted(self._not_supported, key=str): + frontlines.append(self._get_comment(type(expr).__name__)) + for name, value in sorted(self._number_symbols, key=str): + frontlines.append(self._declare_number_const(name, value)) + lines = frontlines + lines + lines = self._format_code(lines) + result = "\n".join(lines) + else: + lines = self._format_code(lines) + num_syms = {(k, self._print(v)) for k, v in self._number_symbols} + result = (num_syms, self._not_supported, "\n".join(lines)) + self._not_supported = set() + self._number_symbols = set() + return result + + def _doprint_loops(self, expr, assign_to=None): + # Here we print an expression that contains Indexed objects, they + # correspond to arrays in the generated code. The low-level implementation + # involves looping over array elements and possibly storing results in temporary + # variables or accumulate it in the assign_to object. + + if self._settings.get('contract', True): + from sympy.tensor import get_contraction_structure + # Setup loops over non-dummy indices -- all terms need these + indices = self._get_expression_indices(expr, assign_to) + # Setup loops over dummy indices -- each term needs separate treatment + dummies = get_contraction_structure(expr) + else: + indices = [] + dummies = {None: (expr,)} + openloop, closeloop = self._get_loop_opening_ending(indices) + + # terms with no summations first + if None in dummies: + text = StrPrinter.doprint(self, Add(*dummies[None])) + else: + # If all terms have summations we must initialize array to Zero + text = StrPrinter.doprint(self, 0) + + # skip redundant assignments (where lhs == rhs) + lhs_printed = self._print(assign_to) + lines = [] + if text != lhs_printed: + lines.extend(openloop) + if assign_to is not None: + text = self._get_statement("%s = %s" % (lhs_printed, text)) + lines.append(text) + lines.extend(closeloop) + + # then terms with summations + for d in dummies: + if isinstance(d, tuple): + indices = self._sort_optimized(d, expr) + openloop_d, closeloop_d = self._get_loop_opening_ending( + indices) + + for term in dummies[d]: + if term in dummies and not ([list(f.keys()) for f in dummies[term]] + == [[None] for f in dummies[term]]): + # If one factor in the term has it's own internal + # contractions, those must be computed first. + # (temporary variables?) + raise NotImplementedError( + "FIXME: no support for contractions in factor yet") + else: + + # We need the lhs expression as an accumulator for + # the loops, i.e + # + # for (int d=0; d < dim; d++){ + # lhs[] = lhs[] + term[][d] + # } ^.................. the accumulator + # + # We check if the expression already contains the + # lhs, and raise an exception if it does, as that + # syntax is currently undefined. FIXME: What would be + # a good interpretation? + if assign_to is None: + raise AssignmentError( + "need assignment variable for loops") + if term.has(assign_to): + raise ValueError("FIXME: lhs present in rhs,\ + this is undefined in CodePrinter") + + lines.extend(openloop) + lines.extend(openloop_d) + text = "%s = %s" % (lhs_printed, StrPrinter.doprint( + self, assign_to + term)) + lines.append(self._get_statement(text)) + lines.extend(closeloop_d) + lines.extend(closeloop) + + return "\n".join(lines) + + def _get_expression_indices(self, expr, assign_to): + from sympy.tensor import get_indices + rinds, junk = get_indices(expr) + linds, junk = get_indices(assign_to) + + # support broadcast of scalar + if linds and not rinds: + rinds = linds + if rinds != linds: + raise ValueError("lhs indices must match non-dummy" + " rhs indices in %s" % expr) + + return self._sort_optimized(rinds, assign_to) + + def _sort_optimized(self, indices, expr): + + from sympy.tensor.indexed import Indexed + + if not indices: + return [] + + # determine optimized loop order by giving a score to each index + # the index with the highest score are put in the innermost loop. + score_table = {} + for i in indices: + score_table[i] = 0 + + arrays = expr.atoms(Indexed) + for arr in arrays: + for p, ind in enumerate(arr.indices): + try: + score_table[ind] += self._rate_index_position(p) + except KeyError: + pass + + return sorted(indices, key=lambda x: score_table[x]) + + def _rate_index_position(self, p): + """function to calculate score based on position among indices + + This method is used to sort loops in an optimized order, see + CodePrinter._sort_optimized() + """ + raise NotImplementedError("This function must be implemented by " + "subclass of CodePrinter.") + + def _get_statement(self, codestring): + """Formats a codestring with the proper line ending.""" + raise NotImplementedError("This function must be implemented by " + "subclass of CodePrinter.") + + def _get_comment(self, text): + """Formats a text string as a comment.""" + raise NotImplementedError("This function must be implemented by " + "subclass of CodePrinter.") + + def _declare_number_const(self, name, value): + """Declare a numeric constant at the top of a function""" + raise NotImplementedError("This function must be implemented by " + "subclass of CodePrinter.") + + def _format_code(self, lines): + """Take in a list of lines of code, and format them accordingly. + + This may include indenting, wrapping long lines, etc...""" + raise NotImplementedError("This function must be implemented by " + "subclass of CodePrinter.") + + def _get_loop_opening_ending(self, indices): + """Returns a tuple (open_lines, close_lines) containing lists + of codelines""" + raise NotImplementedError("This function must be implemented by " + "subclass of CodePrinter.") + + def _print_Dummy(self, expr): + if expr.name.startswith('Dummy_'): + return '_' + expr.name + else: + return '%s_%d' % (expr.name, expr.dummy_index) + + def _print_Idx(self, expr): + return self._print(expr.label) + + def _print_CodeBlock(self, expr): + return '\n'.join([self._print(i) for i in expr.args]) + + def _print_String(self, string): + return str(string) + + def _print_QuotedString(self, arg): + return '"%s"' % arg.text + + def _print_Comment(self, string): + return self._get_comment(str(string)) + + def _print_Assignment(self, expr): + from sympy.codegen.ast import Assignment + from sympy.functions.elementary.piecewise import Piecewise + from sympy.matrices.expressions.matexpr import MatrixSymbol + from sympy.tensor.indexed import IndexedBase + lhs = expr.lhs + rhs = expr.rhs + # We special case assignments that take multiple lines + if isinstance(expr.rhs, Piecewise): + # Here we modify Piecewise so each expression is now + # an Assignment, and then continue on the print. + expressions = [] + conditions = [] + for (e, c) in rhs.args: + expressions.append(Assignment(lhs, e)) + conditions.append(c) + temp = Piecewise(*zip(expressions, conditions)) + return self._print(temp) + elif isinstance(lhs, MatrixSymbol): + # Here we form an Assignment for each element in the array, + # printing each one. + lines = [] + for (i, j) in self._traverse_matrix_indices(lhs): + temp = Assignment(lhs[i, j], rhs[i, j]) + code0 = self._print(temp) + lines.append(code0) + return "\n".join(lines) + elif self._settings.get("contract", False) and (lhs.has(IndexedBase) or + rhs.has(IndexedBase)): + # Here we check if there is looping to be done, and if so + # print the required loops. + return self._doprint_loops(rhs, lhs) + else: + lhs_code = self._print(lhs) + rhs_code = self._print(rhs) + return self._get_statement("%s = %s" % (lhs_code, rhs_code)) + + def _print_AugmentedAssignment(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + return self._get_statement("{} {} {}".format( + *(self._print(arg) for arg in [lhs_code, expr.op, rhs_code]))) + + def _print_FunctionCall(self, expr): + return '%s(%s)' % ( + expr.name, + ', '.join((self._print(arg) for arg in expr.function_args))) + + def _print_Variable(self, expr): + return self._print(expr.symbol) + + def _print_Symbol(self, expr): + name = super()._print_Symbol(expr) + + if name in self.reserved_words: + if self._settings['error_on_reserved']: + msg = ('This expression includes the symbol "{}" which is a ' + 'reserved keyword in this language.') + raise ValueError(msg.format(name)) + return name + self._settings['reserved_word_suffix'] + else: + return name + + def _can_print(self, name): + """ Check if function ``name`` is either a known function or has its own + printing method. Used to check if rewriting is possible.""" + return name in self.known_functions or getattr(self, '_print_{}'.format(name), False) + + def _print_Function(self, expr): + if expr.func.__name__ in self.known_functions: + cond_func = self.known_functions[expr.func.__name__] + if isinstance(cond_func, str): + return "%s(%s)" % (cond_func, self.stringify(expr.args, ", ")) + else: + for cond, func in cond_func: + if cond(*expr.args): + break + if func is not None: + try: + return func(*[self.parenthesize(item, 0) for item in expr.args]) + except TypeError: + return "%s(%s)" % (func, self.stringify(expr.args, ", ")) + elif hasattr(expr, '_imp_') and isinstance(expr._imp_, Lambda): + # inlined function + return self._print(expr._imp_(*expr.args)) + elif expr.func.__name__ in self._rewriteable_functions: + # Simple rewrite to supported function possible + target_f, required_fs = self._rewriteable_functions[expr.func.__name__] + if self._can_print(target_f) and all(self._can_print(f) for f in required_fs): + return '(' + self._print(expr.rewrite(target_f)) + ')' + + if expr.is_Function and self._settings.get('allow_unknown_functions', False): + return '%s(%s)' % (self._print(expr.func), ', '.join(map(self._print, expr.args))) + else: + return self._print_not_supported(expr) + + _print_Expr = _print_Function + + def _print_Derivative(self, expr): + obj, *wrt_order_pairs = expr.args + for func_arg in obj.args: + if not func_arg.is_Symbol: + raise ValueError("%s._print_Derivative(...) only supports functions with symbols as arguments." % + self.__class__.__name__) + meth_name = '_print_Derivative_%s' % obj.func.__name__ + pmeth = getattr(self, meth_name, None) + if pmeth is None: + if self._settings.get('strict', False): + raise PrintMethodNotImplementedError( + f"Unsupported by {type(self)}: {type(expr)}" + + f"\nPrinter has no method: {meth_name}" + + "\nSet the printer option 'strict' to False in order to generate partially printed code." + ) + return self._print_not_supported(expr) + orders = dict(wrt_order_pairs) + seq_orders = [orders[arg] for arg in obj.args] + return pmeth(obj.args, seq_orders) + + # Don't inherit the str-printer method for Heaviside to the code printers + _print_Heaviside = None + + def _print_NumberSymbol(self, expr): + if self._settings.get("inline", False): + return self._print(Float(expr.evalf(self._settings["precision"]))) + else: + # A Number symbol that is not implemented here or with _printmethod + # is registered and evaluated + self._number_symbols.add((expr, + Float(expr.evalf(self._settings["precision"])))) + return str(expr) + + def _print_Catalan(self, expr): + return self._print_NumberSymbol(expr) + def _print_EulerGamma(self, expr): + return self._print_NumberSymbol(expr) + def _print_GoldenRatio(self, expr): + return self._print_NumberSymbol(expr) + def _print_TribonacciConstant(self, expr): + return self._print_NumberSymbol(expr) + def _print_Exp1(self, expr): + return self._print_NumberSymbol(expr) + def _print_Pi(self, expr): + return self._print_NumberSymbol(expr) + + def _print_And(self, expr): + PREC = precedence(expr) + return (" %s " % self._operators['and']).join(self.parenthesize(a, PREC) + for a in sorted(expr.args, key=default_sort_key)) + + def _print_Or(self, expr): + PREC = precedence(expr) + return (" %s " % self._operators['or']).join(self.parenthesize(a, PREC) + for a in sorted(expr.args, key=default_sort_key)) + + def _print_Xor(self, expr): + if self._operators.get('xor') is None: + return self._print(expr.to_nnf()) + PREC = precedence(expr) + return (" %s " % self._operators['xor']).join(self.parenthesize(a, PREC) + for a in expr.args) + + def _print_Equivalent(self, expr): + if self._operators.get('equivalent') is None: + return self._print(expr.to_nnf()) + PREC = precedence(expr) + return (" %s " % self._operators['equivalent']).join(self.parenthesize(a, PREC) + for a in expr.args) + + def _print_Not(self, expr): + PREC = precedence(expr) + return self._operators['not'] + self.parenthesize(expr.args[0], PREC) + + def _print_BooleanFunction(self, expr): + return self._print(expr.to_nnf()) + + def _print_isnan(self, arg): + return 'isnan(%s)' % self._print(*arg.args) + + def _print_isinf(self, arg): + return 'isinf(%s)' % self._print(*arg.args) + + def _print_Mul(self, expr): + + prec = precedence(expr) + + c, e = expr.as_coeff_Mul() + if c < 0: + expr = _keep_coeff(-c, e) + sign = "-" + else: + sign = "" + + a = [] # items in the numerator + b = [] # items that are in the denominator (if any) + + pow_paren = [] # Will collect all pow with more than one base element and exp = -1 + + if self.order not in ('old', 'none'): + args = expr.as_ordered_factors() + else: + # use make_args in case expr was something like -x -> x + args = Mul.make_args(expr) + + # Gather args for numerator/denominator + for item in args: + if item.is_commutative and item.is_Pow and item.exp.is_Rational and item.exp.is_negative: + if item.exp != -1: + b.append(Pow(item.base, -item.exp, evaluate=False)) + else: + if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 + pow_paren.append(item) + b.append(Pow(item.base, -item.exp)) + else: + a.append(item) + + a = a or [S.One] + + if len(a) == 1 and sign == "-": + # Unary minus does not have a SymPy class, and hence there's no + # precedence weight associated with it, Python's unary minus has + # an operator precedence between multiplication and exponentiation, + # so we use this to compute a weight. + a_str = [self.parenthesize(a[0], 0.5*(PRECEDENCE["Pow"]+PRECEDENCE["Mul"]))] + else: + a_str = [self.parenthesize(x, prec) for x in a] + b_str = [self.parenthesize(x, prec) for x in b] + + # To parenthesize Pow with exp = -1 and having more than one Symbol + for item in pow_paren: + if item.base in b: + b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] + + if not b: + return sign + '*'.join(a_str) + elif len(b) == 1: + return sign + '*'.join(a_str) + "/" + b_str[0] + else: + return sign + '*'.join(a_str) + "/(%s)" % '*'.join(b_str) + + def _print_not_supported(self, expr): + if self._settings.get('strict', False): + raise PrintMethodNotImplementedError( + f"Unsupported by {type(self)}: {type(expr)}" + + "\nSet the printer option 'strict' to False in order to generate partially printed code." + ) + try: + self._not_supported.add(expr) + except TypeError: + # not hashable + pass + return self.emptyPrinter(expr) + + # The following can not be simply translated into C or Fortran + _print_Basic = _print_not_supported + _print_ComplexInfinity = _print_not_supported + _print_ExprCondPair = _print_not_supported + _print_GeometryEntity = _print_not_supported + _print_Infinity = _print_not_supported + _print_Integral = _print_not_supported + _print_Interval = _print_not_supported + _print_AccumulationBounds = _print_not_supported + _print_Limit = _print_not_supported + _print_MatrixBase = _print_not_supported + _print_DeferredVector = _print_not_supported + _print_NaN = _print_not_supported + _print_NegativeInfinity = _print_not_supported + _print_Order = _print_not_supported + _print_RootOf = _print_not_supported + _print_RootsOf = _print_not_supported + _print_RootSum = _print_not_supported + _print_Uniform = _print_not_supported + _print_Unit = _print_not_supported + _print_Wild = _print_not_supported + _print_WildFunction = _print_not_supported + _print_Relational = _print_not_supported + + +# Code printer functions. These are included in this file so that they can be +# imported in the top-level __init__.py without importing the sympy.codegen +# module. + +def ccode(expr, assign_to=None, standard='c99', **settings): + """Converts an expr to a string of c code + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This is helpful in case of + line-wrapping, or for expressions that generate multi-line statements. + standard : str, optional + String specifying the standard. If your compiler supports a more modern + standard you may set this to 'c99' to allow the printer to use more math + functions. [default='c89']. + precision : integer, optional + The precision for numbers such as pi [default=17]. + user_functions : dict, optional + A dictionary where the keys are string representations of either + ``FunctionClass`` or ``UndefinedFunction`` instances and the values + are their desired C string representations. Alternatively, the + dictionary value can be a list of tuples i.e. [(argument_test, + cfunction_string)] or [(argument_test, cfunction_formater)]. See below + for examples. + dereference : iterable, optional + An iterable of symbols that should be dereferenced in the printed code + expression. These would be values passed by address to the function. + For example, if ``dereference=[a]``, the resulting code would print + ``(*a)`` instead of ``a``. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + + Examples + ======== + + >>> from sympy import ccode, symbols, Rational, sin, ceiling, Abs, Function + >>> x, tau = symbols("x, tau") + >>> expr = (2*tau)**Rational(7, 2) + >>> ccode(expr) + '8*M_SQRT2*pow(tau, 7.0/2.0)' + >>> ccode(expr, math_macros={}) + '8*sqrt(2)*pow(tau, 7.0/2.0)' + >>> ccode(sin(x), assign_to="s") + 's = sin(x);' + >>> from sympy.codegen.ast import real, float80 + >>> ccode(expr, type_aliases={real: float80}) + '8*M_SQRT2l*powl(tau, 7.0L/2.0L)' + + Simple custom printing can be defined for certain types by passing a + dictionary of {"type" : "function"} to the ``user_functions`` kwarg. + Alternatively, the dictionary value can be a list of tuples i.e. + [(argument_test, cfunction_string)]. + + >>> custom_functions = { + ... "ceiling": "CEIL", + ... "Abs": [(lambda x: not x.is_integer, "fabs"), + ... (lambda x: x.is_integer, "ABS")], + ... "func": "f" + ... } + >>> func = Function('func') + >>> ccode(func(Abs(x) + ceiling(x)), standard='C89', user_functions=custom_functions) + 'f(fabs(x) + CEIL(x))' + + or if the C-function takes a subset of the original arguments: + + >>> ccode(2**x + 3**x, standard='C99', user_functions={'Pow': [ + ... (lambda b, e: b == 2, lambda b, e: 'exp2(%s)' % e), + ... (lambda b, e: b != 2, 'pow')]}) + 'exp2(x) + pow(3, x)' + + ``Piecewise`` expressions are converted into conditionals. If an + ``assign_to`` variable is provided an if statement is created, otherwise + the ternary operator is used. Note that if the ``Piecewise`` lacks a + default term, represented by ``(expr, True)`` then an error will be thrown. + This is to prevent generating an expression that may not evaluate to + anything. + + >>> from sympy import Piecewise + >>> expr = Piecewise((x + 1, x > 0), (x, True)) + >>> print(ccode(expr, tau, standard='C89')) + if (x > 0) { + tau = x + 1; + } + else { + tau = x; + } + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e=Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> ccode(e.rhs, assign_to=e.lhs, contract=False, standard='C89') + 'Dy[i] = (y[i + 1] - y[i])/(t[i + 1] - t[i]);' + + Matrices are also supported, but a ``MatrixSymbol`` of the same dimensions + must be provided to ``assign_to``. Note that any expression that can be + generated normally can also exist inside a Matrix: + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([x**2, Piecewise((x + 1, x > 0), (x, True)), sin(x)]) + >>> A = MatrixSymbol('A', 3, 1) + >>> print(ccode(mat, A, standard='C89')) + A[0] = pow(x, 2); + if (x > 0) { + A[1] = x + 1; + } + else { + A[1] = x; + } + A[2] = sin(x); + """ + from sympy.printing.c import c_code_printers + return c_code_printers[standard.lower()](settings).doprint(expr, assign_to) + +def print_ccode(expr, **settings): + """Prints C representation of the given expression.""" + print(ccode(expr, **settings)) + +def fcode(expr, assign_to=None, **settings): + """Converts an expr to a string of fortran code + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This is helpful in case of + line-wrapping, or for expressions that generate multi-line statements. + precision : integer, optional + DEPRECATED. Use type_mappings instead. The precision for numbers such + as pi [default=17]. + user_functions : dict, optional + A dictionary where keys are ``FunctionClass`` instances and values are + their string representations. Alternatively, the dictionary value can + be a list of tuples i.e. [(argument_test, cfunction_string)]. See below + for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + source_format : optional + The source format can be either 'fixed' or 'free'. [default='fixed'] + standard : integer, optional + The Fortran standard to be followed. This is specified as an integer. + Acceptable standards are 66, 77, 90, 95, 2003, and 2008. Default is 77. + Note that currently the only distinction internally is between + standards before 95, and those 95 and after. This may change later as + more features are added. + name_mangling : bool, optional + If True, then the variables that would become identical in + case-insensitive Fortran are mangled by appending different number + of ``_`` at the end. If False, SymPy Will not interfere with naming of + variables. [default=True] + + Examples + ======== + + >>> from sympy import fcode, symbols, Rational, sin, ceiling, floor + >>> x, tau = symbols("x, tau") + >>> fcode((2*tau)**Rational(7, 2)) + ' 8*sqrt(2.0d0)*tau**(7.0d0/2.0d0)' + >>> fcode(sin(x), assign_to="s") + ' s = sin(x)' + + Custom printing can be defined for certain types by passing a dictionary of + "type" : "function" to the ``user_functions`` kwarg. Alternatively, the + dictionary value can be a list of tuples i.e. [(argument_test, + cfunction_string)]. + + >>> custom_functions = { + ... "ceiling": "CEIL", + ... "floor": [(lambda x: not x.is_integer, "FLOOR1"), + ... (lambda x: x.is_integer, "FLOOR2")] + ... } + >>> fcode(floor(x) + ceiling(x), user_functions=custom_functions) + ' CEIL(x) + FLOOR1(x)' + + ``Piecewise`` expressions are converted into conditionals. If an + ``assign_to`` variable is provided an if statement is created, otherwise + the ternary operator is used. Note that if the ``Piecewise`` lacks a + default term, represented by ``(expr, True)`` then an error will be thrown. + This is to prevent generating an expression that may not evaluate to + anything. + + >>> from sympy import Piecewise + >>> expr = Piecewise((x + 1, x > 0), (x, True)) + >>> print(fcode(expr, tau)) + if (x > 0) then + tau = x + 1 + else + tau = x + end if + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e=Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> fcode(e.rhs, assign_to=e.lhs, contract=False) + ' Dy(i) = (y(i + 1) - y(i))/(t(i + 1) - t(i))' + + Matrices are also supported, but a ``MatrixSymbol`` of the same dimensions + must be provided to ``assign_to``. Note that any expression that can be + generated normally can also exist inside a Matrix: + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([x**2, Piecewise((x + 1, x > 0), (x, True)), sin(x)]) + >>> A = MatrixSymbol('A', 3, 1) + >>> print(fcode(mat, A)) + A(1, 1) = x**2 + if (x > 0) then + A(2, 1) = x + 1 + else + A(2, 1) = x + end if + A(3, 1) = sin(x) + """ + from sympy.printing.fortran import FCodePrinter + return FCodePrinter(settings).doprint(expr, assign_to) + + +def print_fcode(expr, **settings): + """Prints the Fortran representation of the given expression. + + See fcode for the meaning of the optional arguments. + """ + print(fcode(expr, **settings)) + +def cxxcode(expr, assign_to=None, standard='c++11', **settings): + """ C++ equivalent of :func:`~.ccode`. """ + from sympy.printing.cxx import cxx_code_printers + return cxx_code_printers[standard.lower()](settings).doprint(expr, assign_to) + + +def rust_code(expr, assign_to=None, **settings): + """Converts an expr to a string of Rust code + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This is helpful in case of + line-wrapping, or for expressions that generate multi-line statements. + precision : integer, optional + The precision for numbers such as pi [default=15]. + user_functions : dict, optional + A dictionary where the keys are string representations of either + ``FunctionClass`` or ``UndefinedFunction`` instances and the values + are their desired C string representations. Alternatively, the + dictionary value can be a list of tuples i.e. [(argument_test, + cfunction_string)]. See below for examples. + dereference : iterable, optional + An iterable of symbols that should be dereferenced in the printed code + expression. These would be values passed by address to the function. + For example, if ``dereference=[a]``, the resulting code would print + ``(*a)`` instead of ``a``. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + + Examples + ======== + + >>> from sympy import rust_code, symbols, Rational, sin, ceiling, Abs, Function + >>> x, tau = symbols("x, tau") + >>> rust_code((2*tau)**Rational(7, 2)) + '8.0*1.4142135623731*tau.powf(7_f64/2.0)' + >>> rust_code(sin(x), assign_to="s") + 's = x.sin();' + + Simple custom printing can be defined for certain types by passing a + dictionary of {"type" : "function"} to the ``user_functions`` kwarg. + Alternatively, the dictionary value can be a list of tuples i.e. + [(argument_test, cfunction_string)]. + + >>> custom_functions = { + ... "ceiling": "CEIL", + ... "Abs": [(lambda x: not x.is_integer, "fabs", 4), + ... (lambda x: x.is_integer, "ABS", 4)], + ... "func": "f" + ... } + >>> func = Function('func') + >>> rust_code(func(Abs(x) + ceiling(x)), user_functions=custom_functions) + '(fabs(x) + x.ceil()).f()' + + ``Piecewise`` expressions are converted into conditionals. If an + ``assign_to`` variable is provided an if statement is created, otherwise + the ternary operator is used. Note that if the ``Piecewise`` lacks a + default term, represented by ``(expr, True)`` then an error will be thrown. + This is to prevent generating an expression that may not evaluate to + anything. + + >>> from sympy import Piecewise + >>> expr = Piecewise((x + 1, x > 0), (x, True)) + >>> print(rust_code(expr, tau)) + tau = if (x > 0.0) { + x + 1 + } else { + x + }; + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e=Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> rust_code(e.rhs, assign_to=e.lhs, contract=False) + 'Dy[i] = (y[i + 1] - y[i])/(t[i + 1] - t[i]);' + + Matrices are also supported, but a ``MatrixSymbol`` of the same dimensions + must be provided to ``assign_to``. Note that any expression that can be + generated normally can also exist inside a Matrix: + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([x**2, Piecewise((x + 1, x > 0), (x, True)), sin(x)]) + >>> A = MatrixSymbol('A', 3, 1) + >>> print(rust_code(mat, A)) + A = [x.powi(2), if (x > 0.0) { + x + 1 + } else { + x + }, x.sin()]; + """ + from sympy.printing.rust import RustCodePrinter + printer = RustCodePrinter(settings) + expr = printer._rewrite_known_functions(expr) + if isinstance(expr, Expr): + for src_func, dst_func in printer.function_overrides.values(): + expr = expr.replace(src_func, dst_func) + return printer.doprint(expr, assign_to) + + +def print_rust_code(expr, **settings): + """Prints Rust representation of the given expression.""" + print(rust_code(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/conventions.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/conventions.py new file mode 100644 index 0000000000000000000000000000000000000000..4f5545ae38511e0bb0366da5c9fb4e59156095c8 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/conventions.py @@ -0,0 +1,88 @@ +""" +A few practical conventions common to all printers. +""" + +import re + +from collections.abc import Iterable +from sympy.core.function import Derivative + +_name_with_digits_p = re.compile(r'^([^\W\d_]+)(\d+)$', re.UNICODE) + + +def split_super_sub(text): + """Split a symbol name into a name, superscripts and subscripts + + The first part of the symbol name is considered to be its actual + 'name', followed by super- and subscripts. Each superscript is + preceded with a "^" character or by "__". Each subscript is preceded + by a "_" character. The three return values are the actual name, a + list with superscripts and a list with subscripts. + + Examples + ======== + + >>> from sympy.printing.conventions import split_super_sub + >>> split_super_sub('a_x^1') + ('a', ['1'], ['x']) + >>> split_super_sub('var_sub1__sup_sub2') + ('var', ['sup'], ['sub1', 'sub2']) + + """ + if not text: + return text, [], [] + + pos = 0 + name = None + supers = [] + subs = [] + while pos < len(text): + start = pos + 1 + if text[pos:pos + 2] == "__": + start += 1 + pos_hat = text.find("^", start) + if pos_hat < 0: + pos_hat = len(text) + pos_usc = text.find("_", start) + if pos_usc < 0: + pos_usc = len(text) + pos_next = min(pos_hat, pos_usc) + part = text[pos:pos_next] + pos = pos_next + if name is None: + name = part + elif part.startswith("^"): + supers.append(part[1:]) + elif part.startswith("__"): + supers.append(part[2:]) + elif part.startswith("_"): + subs.append(part[1:]) + else: + raise RuntimeError("This should never happen.") + + # Make a little exception when a name ends with digits, i.e. treat them + # as a subscript too. + m = _name_with_digits_p.match(name) + if m: + name, sub = m.groups() + subs.insert(0, sub) + + return name, supers, subs + + +def requires_partial(expr): + """Return whether a partial derivative symbol is required for printing + + This requires checking how many free variables there are, + filtering out the ones that are integers. Some expressions do not have + free variables. In that case, check its variable list explicitly to + get the context of the expression. + """ + + if isinstance(expr, Derivative): + return requires_partial(expr.expr) + + if not isinstance(expr.free_symbols, Iterable): + return len(set(expr.variables)) > 1 + + return sum(not s.is_integer for s in expr.free_symbols) > 1 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/cxx.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/cxx.py new file mode 100644 index 0000000000000000000000000000000000000000..0ed4f468b866e1b44aba6ae94a85c740dd324689 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/cxx.py @@ -0,0 +1,181 @@ +""" +C++ code printer +""" + +from itertools import chain +from sympy.codegen.ast import Type, none +from .codeprinter import requires +from .c import C89CodePrinter, C99CodePrinter + +# These are defined in the other file so we can avoid importing sympy.codegen +# from the top-level 'import sympy'. Export them here as well. +from sympy.printing.codeprinter import cxxcode # noqa:F401 + +# from https://en.cppreference.com/w/cpp/keyword +reserved = { + 'C++98': [ + 'and', 'and_eq', 'asm', 'auto', 'bitand', 'bitor', 'bool', 'break', + 'case', 'catch,', 'char', 'class', 'compl', 'const', 'const_cast', + 'continue', 'default', 'delete', 'do', 'double', 'dynamic_cast', + 'else', 'enum', 'explicit', 'export', 'extern', 'false', 'float', + 'for', 'friend', 'goto', 'if', 'inline', 'int', 'long', 'mutable', + 'namespace', 'new', 'not', 'not_eq', 'operator', 'or', 'or_eq', + 'private', 'protected', 'public', 'register', 'reinterpret_cast', + 'return', 'short', 'signed', 'sizeof', 'static', 'static_cast', + 'struct', 'switch', 'template', 'this', 'throw', 'true', 'try', + 'typedef', 'typeid', 'typename', 'union', 'unsigned', 'using', + 'virtual', 'void', 'volatile', 'wchar_t', 'while', 'xor', 'xor_eq' + ] +} + +reserved['C++11'] = reserved['C++98'][:] + [ + 'alignas', 'alignof', 'char16_t', 'char32_t', 'constexpr', 'decltype', + 'noexcept', 'nullptr', 'static_assert', 'thread_local' +] +reserved['C++17'] = reserved['C++11'][:] +reserved['C++17'].remove('register') +# TM TS: atomic_cancel, atomic_commit, atomic_noexcept, synchronized +# concepts TS: concept, requires +# module TS: import, module + + +_math_functions = { + 'C++98': { + 'Mod': 'fmod', + 'ceiling': 'ceil', + }, + 'C++11': { + 'gamma': 'tgamma', + }, + 'C++17': { + 'beta': 'beta', + 'Ei': 'expint', + 'zeta': 'riemann_zeta', + } +} + +# from https://en.cppreference.com/w/cpp/header/cmath +for k in ('Abs', 'exp', 'log', 'log10', 'sqrt', 'sin', 'cos', 'tan', # 'Pow' + 'asin', 'acos', 'atan', 'atan2', 'sinh', 'cosh', 'tanh', 'floor'): + _math_functions['C++98'][k] = k.lower() + + +for k in ('asinh', 'acosh', 'atanh', 'erf', 'erfc'): + _math_functions['C++11'][k] = k.lower() + + +def _attach_print_method(cls, sympy_name, func_name): + meth_name = '_print_%s' % sympy_name + if hasattr(cls, meth_name): + raise ValueError("Edit method (or subclass) instead of overwriting.") + def _print_method(self, expr): + return '{}{}({})'.format(self._ns, func_name, ', '.join(map(self._print, expr.args))) + _print_method.__doc__ = "Prints code for %s" % k + setattr(cls, meth_name, _print_method) + + +def _attach_print_methods(cls, cont): + for sympy_name, cxx_name in cont[cls.standard].items(): + _attach_print_method(cls, sympy_name, cxx_name) + + +class _CXXCodePrinterBase: + printmethod = "_cxxcode" + language = 'C++' + _ns = 'std::' # namespace + + def __init__(self, settings=None): + super().__init__(settings or {}) + + @requires(headers={'algorithm'}) + def _print_Max(self, expr): + from sympy.functions.elementary.miscellaneous import Max + if len(expr.args) == 1: + return self._print(expr.args[0]) + return "%smax(%s, %s)" % (self._ns, self._print(expr.args[0]), + self._print(Max(*expr.args[1:]))) + + @requires(headers={'algorithm'}) + def _print_Min(self, expr): + from sympy.functions.elementary.miscellaneous import Min + if len(expr.args) == 1: + return self._print(expr.args[0]) + return "%smin(%s, %s)" % (self._ns, self._print(expr.args[0]), + self._print(Min(*expr.args[1:]))) + + def _print_using(self, expr): + if expr.alias == none: + return 'using %s' % expr.type + else: + raise ValueError("C++98 does not support type aliases") + + def _print_Raise(self, rs): + arg, = rs.args + return 'throw %s' % self._print(arg) + + @requires(headers={'stdexcept'}) + def _print_RuntimeError_(self, re): + message, = re.args + return "%sruntime_error(%s)" % (self._ns, self._print(message)) + + +class CXX98CodePrinter(_CXXCodePrinterBase, C89CodePrinter): + standard = 'C++98' + reserved_words = set(reserved['C++98']) + + +# _attach_print_methods(CXX98CodePrinter, _math_functions) + + +class CXX11CodePrinter(_CXXCodePrinterBase, C99CodePrinter): + standard = 'C++11' + reserved_words = set(reserved['C++11']) + type_mappings = dict(chain( + CXX98CodePrinter.type_mappings.items(), + { + Type('int8'): ('int8_t', {'cstdint'}), + Type('int16'): ('int16_t', {'cstdint'}), + Type('int32'): ('int32_t', {'cstdint'}), + Type('int64'): ('int64_t', {'cstdint'}), + Type('uint8'): ('uint8_t', {'cstdint'}), + Type('uint16'): ('uint16_t', {'cstdint'}), + Type('uint32'): ('uint32_t', {'cstdint'}), + Type('uint64'): ('uint64_t', {'cstdint'}), + Type('complex64'): ('std::complex', {'complex'}), + Type('complex128'): ('std::complex', {'complex'}), + Type('bool'): ('bool', None), + }.items() + )) + + def _print_using(self, expr): + if expr.alias == none: + return super()._print_using(expr) + else: + return 'using %(alias)s = %(type)s' % expr.kwargs(apply=self._print) + +# _attach_print_methods(CXX11CodePrinter, _math_functions) + + +class CXX17CodePrinter(_CXXCodePrinterBase, C99CodePrinter): + standard = 'C++17' + reserved_words = set(reserved['C++17']) + + _kf = dict(C99CodePrinter._kf, **_math_functions['C++17']) + + def _print_beta(self, expr): + return self._print_math_func(expr) + + def _print_Ei(self, expr): + return self._print_math_func(expr) + + def _print_zeta(self, expr): + return self._print_math_func(expr) + + +# _attach_print_methods(CXX17CodePrinter, _math_functions) + +cxx_code_printers = { + 'c++98': CXX98CodePrinter, + 'c++11': CXX11CodePrinter, + 'c++17': CXX17CodePrinter +} diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/defaults.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/defaults.py new file mode 100644 index 0000000000000000000000000000000000000000..77a88d353fed4bd70496456ddd03cc429a4ba5e7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/defaults.py @@ -0,0 +1,5 @@ +from sympy.core._print_helpers import Printable + +# alias for compatibility +Printable.__module__ = __name__ +DefaultPrinting = Printable diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/dot.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/dot.py new file mode 100644 index 0000000000000000000000000000000000000000..c968fee389c16108b757b8fcad531ac6fa4ddb2f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/dot.py @@ -0,0 +1,294 @@ +from sympy.core.basic import Basic +from sympy.core.expr import Expr +from sympy.core.symbol import Symbol +from sympy.core.numbers import Integer, Rational, Float +from sympy.printing.repr import srepr + +__all__ = ['dotprint'] + +default_styles = ( + (Basic, {'color': 'blue', 'shape': 'ellipse'}), + (Expr, {'color': 'black'}) +) + +slotClasses = (Symbol, Integer, Rational, Float) +def purestr(x, with_args=False): + """A string that follows ```obj = type(obj)(*obj.args)``` exactly. + + Parameters + ========== + + with_args : boolean, optional + If ``True``, there will be a second argument for the return + value, which is a tuple containing ``purestr`` applied to each + of the subnodes. + + If ``False``, there will not be a second argument for the + return. + + Default is ``False`` + + Examples + ======== + + >>> from sympy import Float, Symbol, MatrixSymbol + >>> from sympy import Integer # noqa: F401 + >>> from sympy.core.symbol import Str # noqa: F401 + >>> from sympy.printing.dot import purestr + + Applying ``purestr`` for basic symbolic object: + >>> code = purestr(Symbol('x')) + >>> code + "Symbol('x')" + >>> eval(code) == Symbol('x') + True + + For basic numeric object: + >>> purestr(Float(2)) + "Float('2.0', precision=53)" + + For matrix symbol: + >>> code = purestr(MatrixSymbol('x', 2, 2)) + >>> code + "MatrixSymbol(Str('x'), Integer(2), Integer(2))" + >>> eval(code) == MatrixSymbol('x', 2, 2) + True + + With ``with_args=True``: + >>> purestr(Float(2), with_args=True) + ("Float('2.0', precision=53)", ()) + >>> purestr(MatrixSymbol('x', 2, 2), with_args=True) + ("MatrixSymbol(Str('x'), Integer(2), Integer(2))", + ("Str('x')", 'Integer(2)', 'Integer(2)')) + """ + sargs = () + if not isinstance(x, Basic): + rv = str(x) + elif not x.args: + rv = srepr(x) + else: + args = x.args + sargs = tuple(map(purestr, args)) + rv = "%s(%s)"%(type(x).__name__, ', '.join(sargs)) + if with_args: + rv = rv, sargs + return rv + + +def styleof(expr, styles=default_styles): + """ Merge style dictionaries in order + + Examples + ======== + + >>> from sympy import Symbol, Basic, Expr, S + >>> from sympy.printing.dot import styleof + >>> styles = [(Basic, {'color': 'blue', 'shape': 'ellipse'}), + ... (Expr, {'color': 'black'})] + + >>> styleof(Basic(S(1)), styles) + {'color': 'blue', 'shape': 'ellipse'} + + >>> x = Symbol('x') + >>> styleof(x + 1, styles) # this is an Expr + {'color': 'black', 'shape': 'ellipse'} + """ + style = {} + for typ, sty in styles: + if isinstance(expr, typ): + style.update(sty) + return style + + +def attrprint(d, delimiter=', '): + """ Print a dictionary of attributes + + Examples + ======== + + >>> from sympy.printing.dot import attrprint + >>> print(attrprint({'color': 'blue', 'shape': 'ellipse'})) + "color"="blue", "shape"="ellipse" + """ + return delimiter.join('"%s"="%s"'%item for item in sorted(d.items())) + + +def dotnode(expr, styles=default_styles, labelfunc=str, pos=(), repeat=True): + """ String defining a node + + Examples + ======== + + >>> from sympy.printing.dot import dotnode + >>> from sympy.abc import x + >>> print(dotnode(x)) + "Symbol('x')_()" ["color"="black", "label"="x", "shape"="ellipse"]; + """ + style = styleof(expr, styles) + + if isinstance(expr, Basic) and not expr.is_Atom: + label = str(expr.__class__.__name__) + else: + label = labelfunc(expr) + style['label'] = label + expr_str = purestr(expr) + if repeat: + expr_str += '_%s' % str(pos) + return '"%s" [%s];' % (expr_str, attrprint(style)) + + +def dotedges(expr, atom=lambda x: not isinstance(x, Basic), pos=(), repeat=True): + """ List of strings for all expr->expr.arg pairs + + See the docstring of dotprint for explanations of the options. + + Examples + ======== + + >>> from sympy.printing.dot import dotedges + >>> from sympy.abc import x + >>> for e in dotedges(x+2): + ... print(e) + "Add(Integer(2), Symbol('x'))_()" -> "Integer(2)_(0,)"; + "Add(Integer(2), Symbol('x'))_()" -> "Symbol('x')_(1,)"; + """ + if atom(expr): + return [] + else: + expr_str, arg_strs = purestr(expr, with_args=True) + if repeat: + expr_str += '_%s' % str(pos) + arg_strs = ['%s_%s' % (a, str(pos + (i,))) + for i, a in enumerate(arg_strs)] + return ['"%s" -> "%s";' % (expr_str, a) for a in arg_strs] + +template = \ +"""digraph{ + +# Graph style +%(graphstyle)s + +######### +# Nodes # +######### + +%(nodes)s + +######### +# Edges # +######### + +%(edges)s +}""" + +_graphstyle = {'rankdir': 'TD', 'ordering': 'out'} + +def dotprint(expr, + styles=default_styles, atom=lambda x: not isinstance(x, Basic), + maxdepth=None, repeat=True, labelfunc=str, **kwargs): + """DOT description of a SymPy expression tree + + Parameters + ========== + + styles : list of lists composed of (Class, mapping), optional + Styles for different classes. + + The default is + + .. code-block:: python + + ( + (Basic, {'color': 'blue', 'shape': 'ellipse'}), + (Expr, {'color': 'black'}) + ) + + atom : function, optional + Function used to determine if an arg is an atom. + + A good choice is ``lambda x: not x.args``. + + The default is ``lambda x: not isinstance(x, Basic)``. + + maxdepth : integer, optional + The maximum depth. + + The default is ``None``, meaning no limit. + + repeat : boolean, optional + Whether to use different nodes for common subexpressions. + + The default is ``True``. + + For example, for ``x + x*y`` with ``repeat=True``, it will have + two nodes for ``x``; with ``repeat=False``, it will have one + node. + + .. warning:: + Even if a node appears twice in the same object like ``x`` in + ``Pow(x, x)``, it will still only appear once. + Hence, with ``repeat=False``, the number of arrows out of an + object might not equal the number of args it has. + + labelfunc : function, optional + A function to create a label for a given leaf node. + + The default is ``str``. + + Another good option is ``srepr``. + + For example with ``str``, the leaf nodes of ``x + 1`` are labeled, + ``x`` and ``1``. With ``srepr``, they are labeled ``Symbol('x')`` + and ``Integer(1)``. + + **kwargs : optional + Additional keyword arguments are included as styles for the graph. + + Examples + ======== + + >>> from sympy import dotprint + >>> from sympy.abc import x + >>> print(dotprint(x+2)) # doctest: +NORMALIZE_WHITESPACE + digraph{ + + # Graph style + "ordering"="out" + "rankdir"="TD" + + ######### + # Nodes # + ######### + + "Add(Integer(2), Symbol('x'))_()" ["color"="black", "label"="Add", "shape"="ellipse"]; + "Integer(2)_(0,)" ["color"="black", "label"="2", "shape"="ellipse"]; + "Symbol('x')_(1,)" ["color"="black", "label"="x", "shape"="ellipse"]; + + ######### + # Edges # + ######### + + "Add(Integer(2), Symbol('x'))_()" -> "Integer(2)_(0,)"; + "Add(Integer(2), Symbol('x'))_()" -> "Symbol('x')_(1,)"; + } + + """ + # repeat works by adding a signature tuple to the end of each node for its + # position in the graph. For example, for expr = Add(x, Pow(x, 2)), the x in the + # Pow will have the tuple (1, 0), meaning it is expr.args[1].args[0]. + graphstyle = _graphstyle.copy() + graphstyle.update(kwargs) + + nodes = [] + edges = [] + def traverse(e, depth, pos=()): + nodes.append(dotnode(e, styles, labelfunc=labelfunc, pos=pos, repeat=repeat)) + if maxdepth and depth >= maxdepth: + return + edges.extend(dotedges(e, atom=atom, pos=pos, repeat=repeat)) + [traverse(arg, depth+1, pos + (i,)) for i, arg in enumerate(e.args) if not atom(arg)] + traverse(expr, 0) + + return template%{'graphstyle': attrprint(graphstyle, delimiter='\n'), + 'nodes': '\n'.join(nodes), + 'edges': '\n'.join(edges)} diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/fortran.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/fortran.py new file mode 100644 index 0000000000000000000000000000000000000000..7cea812d72ddcd3ccb56c7258f74e6fe3b8d5211 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/fortran.py @@ -0,0 +1,779 @@ +""" +Fortran code printer + +The FCodePrinter converts single SymPy expressions into single Fortran +expressions, using the functions defined in the Fortran 77 standard where +possible. Some useful pointers to Fortran can be found on wikipedia: + +https://en.wikipedia.org/wiki/Fortran + +Most of the code below is based on the "Professional Programmer\'s Guide to +Fortran77" by Clive G. Page: + +https://www.star.le.ac.uk/~cgp/prof77.html + +Fortran is a case-insensitive language. This might cause trouble because +SymPy is case sensitive. So, fcode adds underscores to variable names when +it is necessary to make them different for Fortran. +""" + +from __future__ import annotations +from typing import Any + +from collections import defaultdict +from itertools import chain +import string + +from sympy.codegen.ast import ( + Assignment, Declaration, Pointer, value_const, + float32, float64, float80, complex64, complex128, int8, int16, int32, + int64, intc, real, integer, bool_, complex_, none, stderr, stdout +) +from sympy.codegen.fnodes import ( + allocatable, isign, dsign, cmplx, merge, literal_dp, elemental, pure, + intent_in, intent_out, intent_inout +) +from sympy.core import S, Add, N, Float, Symbol +from sympy.core.function import Function +from sympy.core.numbers import equal_valued +from sympy.core.relational import Eq +from sympy.sets import Range +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence, PRECEDENCE +from sympy.printing.printer import printer_context + +# These are defined in the other file so we can avoid importing sympy.codegen +# from the top-level 'import sympy'. Export them here as well. +from sympy.printing.codeprinter import fcode, print_fcode # noqa:F401 + +known_functions = { + "sin": "sin", + "cos": "cos", + "tan": "tan", + "asin": "asin", + "acos": "acos", + "atan": "atan", + "atan2": "atan2", + "sinh": "sinh", + "cosh": "cosh", + "tanh": "tanh", + "log": "log", + "exp": "exp", + "erf": "erf", + "Abs": "abs", + "conjugate": "conjg", + "Max": "max", + "Min": "min", +} + + +class FCodePrinter(CodePrinter): + """A printer to convert SymPy expressions to strings of Fortran code""" + printmethod = "_fcode" + language = "Fortran" + + type_aliases = { + integer: int32, + real: float64, + complex_: complex128, + } + + type_mappings = { + intc: 'integer(c_int)', + float32: 'real*4', # real(kind(0.e0)) + float64: 'real*8', # real(kind(0.d0)) + float80: 'real*10', # real(kind(????)) + complex64: 'complex*8', + complex128: 'complex*16', + int8: 'integer*1', + int16: 'integer*2', + int32: 'integer*4', + int64: 'integer*8', + bool_: 'logical' + } + + type_modules = { + intc: {'iso_c_binding': 'c_int'} + } + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 17, + 'user_functions': {}, + 'source_format': 'fixed', + 'contract': True, + 'standard': 77, + 'name_mangling': True, + }) + + _operators = { + 'and': '.and.', + 'or': '.or.', + 'xor': '.neqv.', + 'equivalent': '.eqv.', + 'not': '.not. ', + } + + _relationals = { + '!=': '/=', + } + + def __init__(self, settings=None): + if not settings: + settings = {} + self.mangled_symbols = {} # Dict showing mapping of all words + self.used_name = [] + self.type_aliases = dict(chain(self.type_aliases.items(), + settings.pop('type_aliases', {}).items())) + self.type_mappings = dict(chain(self.type_mappings.items(), + settings.pop('type_mappings', {}).items())) + super().__init__(settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + # leading columns depend on fixed or free format + standards = {66, 77, 90, 95, 2003, 2008} + if self._settings['standard'] not in standards: + raise ValueError("Unknown Fortran standard: %s" % self._settings[ + 'standard']) + self.module_uses = defaultdict(set) # e.g.: use iso_c_binding, only: c_int + + @property + def _lead(self): + if self._settings['source_format'] == 'fixed': + return {'code': " ", 'cont': " @ ", 'comment': "C "} + elif self._settings['source_format'] == 'free': + return {'code': "", 'cont': " ", 'comment': "! "} + else: + raise ValueError("Unknown source format: %s" % self._settings['source_format']) + + def _print_Symbol(self, expr): + if self._settings['name_mangling'] == True: + if expr not in self.mangled_symbols: + name = expr.name + while name.lower() in self.used_name: + name += '_' + self.used_name.append(name.lower()) + if name == expr.name: + self.mangled_symbols[expr] = expr + else: + self.mangled_symbols[expr] = Symbol(name) + + expr = expr.xreplace(self.mangled_symbols) + + name = super()._print_Symbol(expr) + return name + + def _rate_index_position(self, p): + return -p*5 + + def _get_statement(self, codestring): + return codestring + + def _get_comment(self, text): + return "! {}".format(text) + + def _declare_number_const(self, name, value): + return "parameter ({} = {})".format(name, self._print(value)) + + def _print_NumberSymbol(self, expr): + # A Number symbol that is not implemented here or with _printmethod + # is registered and evaluated + self._number_symbols.add((expr, Float(expr.evalf(self._settings['precision'])))) + return str(expr) + + def _format_code(self, lines): + return self._wrap_fortran(self.indent_code(lines)) + + def _traverse_matrix_indices(self, mat): + rows, cols = mat.shape + return ((i, j) for j in range(cols) for i in range(rows)) + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + for i in indices: + # fortran arrays start at 1 and end at dimension + var, start, stop = map(self._print, + [i.label, i.lower + 1, i.upper + 1]) + open_lines.append("do %s = %s, %s" % (var, start, stop)) + close_lines.append("end do") + return open_lines, close_lines + + def _print_sign(self, expr): + from sympy.functions.elementary.complexes import Abs + arg, = expr.args + if arg.is_integer: + new_expr = merge(0, isign(1, arg), Eq(arg, 0)) + elif (arg.is_complex or arg.is_infinite): + new_expr = merge(cmplx(literal_dp(0), literal_dp(0)), arg/Abs(arg), Eq(Abs(arg), literal_dp(0))) + else: + new_expr = merge(literal_dp(0), dsign(literal_dp(1), arg), Eq(arg, literal_dp(0))) + return self._print(new_expr) + + + def _print_Piecewise(self, expr): + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + if expr.has(Assignment): + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s) then" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines.append("else") + else: + lines.append("else if (%s) then" % self._print(c)) + lines.append(self._print(e)) + lines.append("end if") + return "\n".join(lines) + elif self._settings["standard"] >= 95: + # Only supported in F95 and newer: + # The piecewise was used in an expression, need to do inline + # operators. This has the downside that inline operators will + # not work for statements that span multiple lines (Matrix or + # Indexed expressions). + pattern = "merge({T}, {F}, {COND})" + code = self._print(expr.args[-1].expr) + terms = list(expr.args[:-1]) + while terms: + e, c = terms.pop() + expr = self._print(e) + cond = self._print(c) + code = pattern.format(T=expr, F=code, COND=cond) + return code + else: + # `merge` is not supported prior to F95 + raise NotImplementedError("Using Piecewise as an expression using " + "inline operators is not supported in " + "standards earlier than Fortran95.") + + def _print_MatrixElement(self, expr): + return "{}({}, {})".format(self.parenthesize(expr.parent, + PRECEDENCE["Atom"], strict=True), expr.i + 1, expr.j + 1) + + def _print_Add(self, expr): + # purpose: print complex numbers nicely in Fortran. + # collect the purely real and purely imaginary parts: + pure_real = [] + pure_imaginary = [] + mixed = [] + for arg in expr.args: + if arg.is_number and arg.is_real: + pure_real.append(arg) + elif arg.is_number and arg.is_imaginary: + pure_imaginary.append(arg) + else: + mixed.append(arg) + if pure_imaginary: + if mixed: + PREC = precedence(expr) + term = Add(*mixed) + t = self._print(term) + if t.startswith('-'): + sign = "-" + t = t[1:] + else: + sign = "+" + if precedence(term) < PREC: + t = "(%s)" % t + + return "cmplx(%s,%s) %s %s" % ( + self._print(Add(*pure_real)), + self._print(-S.ImaginaryUnit*Add(*pure_imaginary)), + sign, t, + ) + else: + return "cmplx(%s,%s)" % ( + self._print(Add(*pure_real)), + self._print(-S.ImaginaryUnit*Add(*pure_imaginary)), + ) + else: + return CodePrinter._print_Add(self, expr) + + def _print_Function(self, expr): + # All constant function args are evaluated as floats + prec = self._settings['precision'] + args = [N(a, prec) for a in expr.args] + eval_expr = expr.func(*args) + if not isinstance(eval_expr, Function): + return self._print(eval_expr) + else: + return CodePrinter._print_Function(self, expr.func(*args)) + + def _print_Mod(self, expr): + # NOTE : Fortran has the functions mod() and modulo(). modulo() behaves + # the same wrt to the sign of the arguments as Python and SymPy's + # modulus computations (% and Mod()) but is not available in Fortran 66 + # or Fortran 77, thus we raise an error. + if self._settings['standard'] in [66, 77]: + msg = ("Python % operator and SymPy's Mod() function are not " + "supported by Fortran 66 or 77 standards.") + raise NotImplementedError(msg) + else: + x, y = expr.args + return " modulo({}, {})".format(self._print(x), self._print(y)) + + def _print_ImaginaryUnit(self, expr): + # purpose: print complex numbers nicely in Fortran. + return "cmplx(0,1)" + + def _print_int(self, expr): + return str(expr) + + def _print_Mul(self, expr): + # purpose: print complex numbers nicely in Fortran. + if expr.is_number and expr.is_imaginary: + return "cmplx(0,%s)" % ( + self._print(-S.ImaginaryUnit*expr) + ) + else: + return CodePrinter._print_Mul(self, expr) + + def _print_Pow(self, expr): + PREC = precedence(expr) + if equal_valued(expr.exp, -1): + return '%s/%s' % ( + self._print(literal_dp(1)), + self.parenthesize(expr.base, PREC) + ) + elif equal_valued(expr.exp, 0.5): + if expr.base.is_integer: + # Fortran intrinsic sqrt() does not accept integer argument + if expr.base.is_Number: + return 'sqrt(%s.0d0)' % self._print(expr.base) + else: + return 'sqrt(dble(%s))' % self._print(expr.base) + else: + return 'sqrt(%s)' % self._print(expr.base) + else: + return CodePrinter._print_Pow(self, expr) + + def _print_Rational(self, expr): + p, q = int(expr.p), int(expr.q) + return "%d.0d0/%d.0d0" % (p, q) + + def _print_Float(self, expr): + printed = CodePrinter._print_Float(self, expr) + e = printed.find('e') + if e > -1: + return "%sd%s" % (printed[:e], printed[e + 1:]) + return "%sd0" % printed + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + op = op if op not in self._relationals else self._relationals[op] + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_Indexed(self, expr): + inds = [ self._print(i) for i in expr.indices ] + return "%s(%s)" % (self._print(expr.base.label), ", ".join(inds)) + + def _print_AugmentedAssignment(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + return self._get_statement("{0} = {0} {1} {2}".format( + self._print(lhs_code), self._print(expr.binop), self._print(rhs_code))) + + def _print_sum_(self, sm): + params = self._print(sm.array) + if sm.dim != None: # Must use '!= None', cannot use 'is not None' + params += ', ' + self._print(sm.dim) + if sm.mask != None: # Must use '!= None', cannot use 'is not None' + params += ', mask=' + self._print(sm.mask) + return '%s(%s)' % (sm.__class__.__name__.rstrip('_'), params) + + def _print_product_(self, prod): + return self._print_sum_(prod) + + def _print_Do(self, do): + excl = ['concurrent'] + if do.step == 1: + excl.append('step') + step = '' + else: + step = ', {step}' + + return ( + 'do {concurrent}{counter} = {first}, {last}'+step+'\n' + '{body}\n' + 'end do\n' + ).format( + concurrent='concurrent ' if do.concurrent else '', + **do.kwargs(apply=lambda arg: self._print(arg), exclude=excl) + ) + + def _print_ImpliedDoLoop(self, idl): + step = '' if idl.step == 1 else ', {step}' + return ('({expr}, {counter} = {first}, {last}'+step+')').format( + **idl.kwargs(apply=lambda arg: self._print(arg)) + ) + + def _print_For(self, expr): + target = self._print(expr.target) + if isinstance(expr.iterable, Range): + start, stop, step = expr.iterable.args + else: + raise NotImplementedError("Only iterable currently supported is Range") + body = self._print(expr.body) + return ('do {target} = {start}, {stop}, {step}\n' + '{body}\n' + 'end do').format(target=target, start=start, stop=stop - 1, + step=step, body=body) + + def _print_Type(self, type_): + type_ = self.type_aliases.get(type_, type_) + type_str = self.type_mappings.get(type_, type_.name) + module_uses = self.type_modules.get(type_) + if module_uses: + for k, v in module_uses: + self.module_uses[k].add(v) + return type_str + + def _print_Element(self, elem): + return '{symbol}({idxs})'.format( + symbol=self._print(elem.symbol), + idxs=', '.join((self._print(arg) for arg in elem.indices)) + ) + + def _print_Extent(self, ext): + return str(ext) + + def _print_Declaration(self, expr): + var = expr.variable + val = var.value + dim = var.attr_params('dimension') + intents = [intent in var.attrs for intent in (intent_in, intent_out, intent_inout)] + if intents.count(True) == 0: + intent = '' + elif intents.count(True) == 1: + intent = ', intent(%s)' % ['in', 'out', 'inout'][intents.index(True)] + else: + raise ValueError("Multiple intents specified for %s" % self) + + if isinstance(var, Pointer): + raise NotImplementedError("Pointers are not available by default in Fortran.") + if self._settings["standard"] >= 90: + result = '{t}{vc}{dim}{intent}{alloc} :: {s}'.format( + t=self._print(var.type), + vc=', parameter' if value_const in var.attrs else '', + dim=', dimension(%s)' % ', '.join((self._print(arg) for arg in dim)) if dim else '', + intent=intent, + alloc=', allocatable' if allocatable in var.attrs else '', + s=self._print(var.symbol) + ) + if val != None: # Must be "!= None", cannot be "is not None" + result += ' = %s' % self._print(val) + else: + if value_const in var.attrs or val: + raise NotImplementedError("F77 init./parameter statem. req. multiple lines.") + result = ' '.join((self._print(arg) for arg in [var.type, var.symbol])) + + return result + + + def _print_Infinity(self, expr): + return '(huge(%s) + 1)' % self._print(literal_dp(0)) + + def _print_While(self, expr): + return 'do while ({condition})\n{body}\nend do'.format(**expr.kwargs( + apply=lambda arg: self._print(arg))) + + def _print_BooleanTrue(self, expr): + return '.true.' + + def _print_BooleanFalse(self, expr): + return '.false.' + + def _pad_leading_columns(self, lines): + result = [] + for line in lines: + if line.startswith('!'): + result.append(self._lead['comment'] + line[1:].lstrip()) + else: + result.append(self._lead['code'] + line) + return result + + def _wrap_fortran(self, lines): + """Wrap long Fortran lines + + Argument: + lines -- a list of lines (without \\n character) + + A comment line is split at white space. Code lines are split with a more + complex rule to give nice results. + """ + # routine to find split point in a code line + my_alnum = set("_+-." + string.digits + string.ascii_letters) + my_white = set(" \t()") + + def split_pos_code(line, endpos): + if len(line) <= endpos: + return len(line) + pos = endpos + split = lambda pos: \ + (line[pos] in my_alnum and line[pos - 1] not in my_alnum) or \ + (line[pos] not in my_alnum and line[pos - 1] in my_alnum) or \ + (line[pos] in my_white and line[pos - 1] not in my_white) or \ + (line[pos] not in my_white and line[pos - 1] in my_white) + while not split(pos): + pos -= 1 + if pos == 0: + return endpos + return pos + # split line by line and add the split lines to result + result = [] + if self._settings['source_format'] == 'free': + trailing = ' &' + else: + trailing = '' + for line in lines: + if line.startswith(self._lead['comment']): + # comment line + if len(line) > 72: + pos = line.rfind(" ", 6, 72) + if pos == -1: + pos = 72 + hunk = line[:pos] + line = line[pos:].lstrip() + result.append(hunk) + while line: + pos = line.rfind(" ", 0, 66) + if pos == -1 or len(line) < 66: + pos = 66 + hunk = line[:pos] + line = line[pos:].lstrip() + result.append("%s%s" % (self._lead['comment'], hunk)) + else: + result.append(line) + elif line.startswith(self._lead['code']): + # code line + pos = split_pos_code(line, 72) + hunk = line[:pos].rstrip() + line = line[pos:].lstrip() + if line: + hunk += trailing + result.append(hunk) + while line: + pos = split_pos_code(line, 65) + hunk = line[:pos].rstrip() + line = line[pos:].lstrip() + if line: + hunk += trailing + result.append("%s%s" % (self._lead['cont'], hunk)) + else: + result.append(line) + return result + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + free = self._settings['source_format'] == 'free' + code = [ line.lstrip(' \t') for line in code ] + + inc_keyword = ('do ', 'if(', 'if ', 'do\n', 'else', 'program', 'interface') + dec_keyword = ('end do', 'enddo', 'end if', 'endif', 'else', 'end program', 'end interface') + + increase = [ int(any(map(line.startswith, inc_keyword))) + for line in code ] + decrease = [ int(any(map(line.startswith, dec_keyword))) + for line in code ] + continuation = [ int(any(map(line.endswith, ['&', '&\n']))) + for line in code ] + + level = 0 + cont_padding = 0 + tabwidth = 3 + new_code = [] + for i, line in enumerate(code): + if line in ('', '\n'): + new_code.append(line) + continue + level -= decrease[i] + + if free: + padding = " "*(level*tabwidth + cont_padding) + else: + padding = " "*level*tabwidth + + line = "%s%s" % (padding, line) + if not free: + line = self._pad_leading_columns([line])[0] + + new_code.append(line) + + if continuation[i]: + cont_padding = 2*tabwidth + else: + cont_padding = 0 + level += increase[i] + + if not free: + return self._wrap_fortran(new_code) + return new_code + + def _print_GoTo(self, goto): + if goto.expr: # computed goto + return "go to ({labels}), {expr}".format( + labels=', '.join((self._print(arg) for arg in goto.labels)), + expr=self._print(goto.expr) + ) + else: + lbl, = goto.labels + return "go to %s" % self._print(lbl) + + def _print_Program(self, prog): + return ( + "program {name}\n" + "{body}\n" + "end program\n" + ).format(**prog.kwargs(apply=lambda arg: self._print(arg))) + + def _print_Module(self, mod): + return ( + "module {name}\n" + "{declarations}\n" + "\ncontains\n\n" + "{definitions}\n" + "end module\n" + ).format(**mod.kwargs(apply=lambda arg: self._print(arg))) + + def _print_Stream(self, strm): + if strm.name == 'stdout' and self._settings["standard"] >= 2003: + self.module_uses['iso_c_binding'].add('stdint=>input_unit') + return 'input_unit' + elif strm.name == 'stderr' and self._settings["standard"] >= 2003: + self.module_uses['iso_c_binding'].add('stdint=>error_unit') + return 'error_unit' + else: + if strm.name == 'stdout': + return '*' + else: + return strm.name + + def _print_Print(self, ps): + if ps.format_string == none: # Must be '!= None', cannot be 'is not None' + template = "print {fmt}, {iolist}" + fmt = '*' + else: + template = 'write(%(out)s, fmt="{fmt}", advance="no"), {iolist}' % { + 'out': {stderr: '0', stdout: '6'}.get(ps.file, '*') + } + fmt = self._print(ps.format_string) + return template.format(fmt=fmt, iolist=', '.join( + (self._print(arg) for arg in ps.print_args))) + + def _print_Return(self, rs): + arg, = rs.args + return "{result_name} = {arg}".format( + result_name=self._context.get('result_name', 'sympy_result'), + arg=self._print(arg) + ) + + def _print_FortranReturn(self, frs): + arg, = frs.args + if arg: + return 'return %s' % self._print(arg) + else: + return 'return' + + def _head(self, entity, fp, **kwargs): + bind_C_params = fp.attr_params('bind_C') + if bind_C_params is None: + bind = '' + else: + bind = ' bind(C, name="%s")' % bind_C_params[0] if bind_C_params else ' bind(C)' + result_name = self._settings.get('result_name', None) + return ( + "{entity}{name}({arg_names}){result}{bind}\n" + "{arg_declarations}" + ).format( + entity=entity, + name=self._print(fp.name), + arg_names=', '.join([self._print(arg.symbol) for arg in fp.parameters]), + result=(' result(%s)' % result_name) if result_name else '', + bind=bind, + arg_declarations='\n'.join((self._print(Declaration(arg)) for arg in fp.parameters)) + ) + + def _print_FunctionPrototype(self, fp): + entity = "{} function ".format(self._print(fp.return_type)) + return ( + "interface\n" + "{function_head}\n" + "end function\n" + "end interface" + ).format(function_head=self._head(entity, fp)) + + def _print_FunctionDefinition(self, fd): + if elemental in fd.attrs: + prefix = 'elemental ' + elif pure in fd.attrs: + prefix = 'pure ' + else: + prefix = '' + + entity = "{} function ".format(self._print(fd.return_type)) + with printer_context(self, result_name=fd.name): + return ( + "{prefix}{function_head}\n" + "{body}\n" + "end function\n" + ).format( + prefix=prefix, + function_head=self._head(entity, fd), + body=self._print(fd.body) + ) + + def _print_Subroutine(self, sub): + return ( + '{subroutine_head}\n' + '{body}\n' + 'end subroutine\n' + ).format( + subroutine_head=self._head('subroutine ', sub), + body=self._print(sub.body) + ) + + def _print_SubroutineCall(self, scall): + return 'call {name}({args})'.format( + name=self._print(scall.name), + args=', '.join((self._print(arg) for arg in scall.subroutine_args)) + ) + + def _print_use_rename(self, rnm): + return "%s => %s" % tuple((self._print(arg) for arg in rnm.args)) + + def _print_use(self, use): + result = 'use %s' % self._print(use.namespace) + if use.rename != None: # Must be '!= None', cannot be 'is not None' + result += ', ' + ', '.join([self._print(rnm) for rnm in use.rename]) + if use.only != None: # Must be '!= None', cannot be 'is not None' + result += ', only: ' + ', '.join([self._print(nly) for nly in use.only]) + return result + + def _print_BreakToken(self, _): + return 'exit' + + def _print_ContinueToken(self, _): + return 'cycle' + + def _print_ArrayConstructor(self, ac): + fmtstr = "[%s]" if self._settings["standard"] >= 2003 else '(/%s/)' + return fmtstr % ', '.join((self._print(arg) for arg in ac.elements)) + + def _print_ArrayElement(self, elem): + return '{symbol}({idxs})'.format( + symbol=self._print(elem.name), + idxs=', '.join((self._print(arg) for arg in elem.indices)) + ) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/glsl.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/glsl.py new file mode 100644 index 0000000000000000000000000000000000000000..f98df8d46abec5f891b6bc9836a13ca69934275c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/glsl.py @@ -0,0 +1,548 @@ +from __future__ import annotations + +from sympy.core import Basic, S +from sympy.core.function import Lambda +from sympy.core.numbers import equal_valued +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence +from functools import reduce + +known_functions = { + 'Abs': 'abs', + 'sin': 'sin', + 'cos': 'cos', + 'tan': 'tan', + 'acos': 'acos', + 'asin': 'asin', + 'atan': 'atan', + 'atan2': 'atan', + 'ceiling': 'ceil', + 'floor': 'floor', + 'sign': 'sign', + 'exp': 'exp', + 'log': 'log', + 'add': 'add', + 'sub': 'sub', + 'mul': 'mul', + 'pow': 'pow' +} + +class GLSLPrinter(CodePrinter): + """ + Rudimentary, generic GLSL printing tools. + + Additional settings: + 'use_operators': Boolean (should the printer use operators for +,-,*, or functions?) + """ + _not_supported: set[Basic] = set() + printmethod = "_glsl" + language = "GLSL" + + _default_settings = dict(CodePrinter._default_settings, **{ + 'use_operators': True, + 'zero': 0, + 'mat_nested': False, + 'mat_separator': ',\n', + 'mat_transpose': False, + 'array_type': 'float', + 'glsl_types': True, + + 'precision': 9, + 'user_functions': {}, + 'contract': True, + }) + + def __init__(self, settings={}): + CodePrinter.__init__(self, settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + + def _rate_index_position(self, p): + return p*5 + + def _get_statement(self, codestring): + return "%s;" % codestring + + def _get_comment(self, text): + return "// {}".format(text) + + def _declare_number_const(self, name, value): + return "float {} = {};".format(name, value) + + def _format_code(self, lines): + return self.indent_code(lines) + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_token = ('{', '(', '{\n', '(\n') + dec_token = ('}', ')') + + code = [line.lstrip(' \t') for line in code] + + increase = [int(any(map(line.endswith, inc_token))) for line in code] + decrease = [int(any(map(line.startswith, dec_token))) for line in code] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty + + def _print_MatrixBase(self, mat): + mat_separator = self._settings['mat_separator'] + mat_transpose = self._settings['mat_transpose'] + column_vector = (mat.rows == 1) if mat_transpose else (mat.cols == 1) + A = mat.transpose() if mat_transpose != column_vector else mat + + glsl_types = self._settings['glsl_types'] + array_type = self._settings['array_type'] + array_size = A.cols*A.rows + array_constructor = "{}[{}]".format(array_type, array_size) + + if A.cols == 1: + return self._print(A[0]) + if A.rows <= 4 and A.cols <= 4 and glsl_types: + if A.rows == 1: + return "vec{}{}".format( + A.cols, A.table(self,rowstart='(',rowend=')') + ) + elif A.rows == A.cols: + return "mat{}({})".format( + A.rows, A.table(self,rowsep=', ', + rowstart='',rowend='') + ) + else: + return "mat{}x{}({})".format( + A.cols, A.rows, + A.table(self,rowsep=', ', + rowstart='',rowend='') + ) + elif S.One in A.shape: + return "{}({})".format( + array_constructor, + A.table(self,rowsep=mat_separator,rowstart='',rowend='') + ) + elif not self._settings['mat_nested']: + return "{}(\n{}\n) /* a {}x{} matrix */".format( + array_constructor, + A.table(self,rowsep=mat_separator,rowstart='',rowend=''), + A.rows, A.cols + ) + elif self._settings['mat_nested']: + return "{}[{}][{}](\n{}\n)".format( + array_type, A.rows, A.cols, + A.table(self,rowsep=mat_separator,rowstart='float[](',rowend=')') + ) + + def _print_SparseRepMatrix(self, mat): + # do not allow sparse matrices to be made dense + return self._print_not_supported(mat) + + def _traverse_matrix_indices(self, mat): + mat_transpose = self._settings['mat_transpose'] + if mat_transpose: + rows,cols = mat.shape + else: + cols,rows = mat.shape + return ((i, j) for i in range(cols) for j in range(rows)) + + def _print_MatrixElement(self, expr): + # print('begin _print_MatrixElement') + nest = self._settings['mat_nested'] + glsl_types = self._settings['glsl_types'] + mat_transpose = self._settings['mat_transpose'] + if mat_transpose: + cols,rows = expr.parent.shape + i,j = expr.j,expr.i + else: + rows,cols = expr.parent.shape + i,j = expr.i,expr.j + pnt = self._print(expr.parent) + if glsl_types and ((rows <= 4 and cols <=4) or nest): + return "{}[{}][{}]".format(pnt, i, j) + else: + return "{}[{}]".format(pnt, i + j*rows) + + def _print_list(self, expr): + l = ', '.join(self._print(item) for item in expr) + glsl_types = self._settings['glsl_types'] + array_type = self._settings['array_type'] + array_size = len(expr) + array_constructor = '{}[{}]'.format(array_type, array_size) + + if array_size <= 4 and glsl_types: + return 'vec{}({})'.format(array_size, l) + else: + return '{}({})'.format(array_constructor, l) + + _print_tuple = _print_list + _print_Tuple = _print_list + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + loopstart = "for (int %(varble)s=%(start)s; %(varble)s<%(end)s; %(varble)s++){" + for i in indices: + # GLSL arrays start at 0 and end at dimension-1 + open_lines.append(loopstart % { + 'varble': self._print(i.label), + 'start': self._print(i.lower), + 'end': self._print(i.upper + 1)}) + close_lines.append("}") + return open_lines, close_lines + + def _print_Function_with_args(self, func, func_args): + if func in self.known_functions: + cond_func = self.known_functions[func] + func = None + if isinstance(cond_func, str): + func = cond_func + else: + for cond, func in cond_func: + if cond(func_args): + break + if func is not None: + try: + return func(*[self.parenthesize(item, 0) for item in func_args]) + except TypeError: + return '{}({})'.format(func, self.stringify(func_args, ", ")) + elif isinstance(func, Lambda): + # inlined function + return self._print(func(*func_args)) + else: + return self._print_not_supported(func) + + def _print_Piecewise(self, expr): + from sympy.codegen.ast import Assignment + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + if expr.has(Assignment): + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s) {" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines.append("else {") + else: + lines.append("else if (%s) {" % self._print(c)) + code0 = self._print(e) + lines.append(code0) + lines.append("}") + return "\n".join(lines) + else: + # The piecewise was used in an expression, need to do inline + # operators. This has the downside that inline operators will + # not work for statements that span multiple lines (Matrix or + # Indexed expressions). + ecpairs = ["((%s) ? (\n%s\n)\n" % (self._print(c), + self._print(e)) + for e, c in expr.args[:-1]] + last_line = ": (\n%s\n)" % self._print(expr.args[-1].expr) + return ": ".join(ecpairs) + last_line + " ".join([")"*len(ecpairs)]) + + def _print_Indexed(self, expr): + # calculate index for 1d array + dims = expr.shape + elem = S.Zero + offset = S.One + for i in reversed(range(expr.rank)): + elem += expr.indices[i]*offset + offset *= dims[i] + return "{}[{}]".format( + self._print(expr.base.label), + self._print(elem) + ) + + def _print_Pow(self, expr): + PREC = precedence(expr) + if equal_valued(expr.exp, -1): + return '1.0/%s' % (self.parenthesize(expr.base, PREC)) + elif equal_valued(expr.exp, 0.5): + return 'sqrt(%s)' % self._print(expr.base) + else: + try: + e = self._print(float(expr.exp)) + except TypeError: + e = self._print(expr.exp) + return self._print_Function_with_args('pow', ( + self._print(expr.base), + e + )) + + def _print_int(self, expr): + return str(float(expr)) + + def _print_Rational(self, expr): + return "{}.0/{}.0".format(expr.p, expr.q) + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_Add(self, expr, order=None): + if self._settings['use_operators']: + return CodePrinter._print_Add(self, expr, order=order) + + terms = expr.as_ordered_terms() + + def partition(p,l): + return reduce(lambda x, y: (x[0]+[y], x[1]) if p(y) else (x[0], x[1]+[y]), l, ([], [])) + def add(a,b): + return self._print_Function_with_args('add', (a, b)) + # return self.known_functions['add']+'(%s, %s)' % (a,b) + neg, pos = partition(lambda arg: arg.could_extract_minus_sign(), terms) + if pos: + s = pos = reduce(lambda a,b: add(a,b), (self._print(t) for t in pos)) + else: + s = pos = self._print(self._settings['zero']) + + if neg: + # sum the absolute values of the negative terms + neg = reduce(lambda a,b: add(a,b), (self._print(-n) for n in neg)) + # then subtract them from the positive terms + s = self._print_Function_with_args('sub', (pos,neg)) + # s = self.known_functions['sub']+'(%s, %s)' % (pos,neg) + return s + + def _print_Mul(self, expr, **kwargs): + if self._settings['use_operators']: + return CodePrinter._print_Mul(self, expr, **kwargs) + terms = expr.as_ordered_factors() + def mul(a,b): + # return self.known_functions['mul']+'(%s, %s)' % (a,b) + return self._print_Function_with_args('mul', (a,b)) + + s = reduce(lambda a,b: mul(a,b), (self._print(t) for t in terms)) + return s + +def glsl_code(expr,assign_to=None,**settings): + """Converts an expr to a string of GLSL code + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used for naming the variable or variables + to which the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol`` or ``Indexed`` type object. In cases where ``expr`` + would be printed as an array, a list of string or ``Symbol`` objects + can also be passed. + + This is helpful in case of line-wrapping, or for expressions that + generate multi-line statements. It can also be used to spread an array-like + expression into multiple assignments. + use_operators: bool, optional + If set to False, then *,/,+,- operators will be replaced with functions + mul, add, and sub, which must be implemented by the user, e.g. for + implementing non-standard rings or emulated quad/octal precision. + [default=True] + glsl_types: bool, optional + Set this argument to ``False`` in order to avoid using the ``vec`` and ``mat`` + types. The printer will instead use arrays (or nested arrays). + [default=True] + mat_nested: bool, optional + GLSL version 4.3 and above support nested arrays (arrays of arrays). Set this to ``True`` + to render matrices as nested arrays. + [default=False] + mat_separator: str, optional + By default, matrices are rendered with newlines using this separator, + making them easier to read, but less compact. By removing the newline + this option can be used to make them more vertically compact. + [default=',\n'] + mat_transpose: bool, optional + GLSL's matrix multiplication implementation assumes column-major indexing. + By default, this printer ignores that convention. Setting this option to + ``True`` transposes all matrix output. + [default=False] + array_type: str, optional + The GLSL array constructor type. + [default='float'] + precision : integer, optional + The precision for numbers such as pi [default=15]. + user_functions : dict, optional + A dictionary where keys are ``FunctionClass`` instances and values are + their string representations. Alternatively, the dictionary value can + be a list of tuples i.e. [(argument_test, js_function_string)]. See + below for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + + Examples + ======== + + >>> from sympy import glsl_code, symbols, Rational, sin, ceiling, Abs + >>> x, tau = symbols("x, tau") + >>> glsl_code((2*tau)**Rational(7, 2)) + '8*sqrt(2)*pow(tau, 3.5)' + >>> glsl_code(sin(x), assign_to="float y") + 'float y = sin(x);' + + Various GLSL types are supported: + >>> from sympy import Matrix, glsl_code + >>> glsl_code(Matrix([1,2,3])) + 'vec3(1, 2, 3)' + + >>> glsl_code(Matrix([[1, 2],[3, 4]])) + 'mat2(1, 2, 3, 4)' + + Pass ``mat_transpose = True`` to switch to column-major indexing: + >>> glsl_code(Matrix([[1, 2],[3, 4]]), mat_transpose = True) + 'mat2(1, 3, 2, 4)' + + By default, larger matrices get collapsed into float arrays: + >>> print(glsl_code( Matrix([[1,2,3,4,5],[6,7,8,9,10]]) )) + float[10]( + 1, 2, 3, 4, 5, + 6, 7, 8, 9, 10 + ) /* a 2x5 matrix */ + + The type of array constructor used to print GLSL arrays can be controlled + via the ``array_type`` parameter: + >>> glsl_code(Matrix([1,2,3,4,5]), array_type='int') + 'int[5](1, 2, 3, 4, 5)' + + Passing a list of strings or ``symbols`` to the ``assign_to`` parameter will yield + a multi-line assignment for each item in an array-like expression: + >>> x_struct_members = symbols('x.a x.b x.c x.d') + >>> print(glsl_code(Matrix([1,2,3,4]), assign_to=x_struct_members)) + x.a = 1; + x.b = 2; + x.c = 3; + x.d = 4; + + This could be useful in cases where it's desirable to modify members of a + GLSL ``Struct``. It could also be used to spread items from an array-like + expression into various miscellaneous assignments: + >>> misc_assignments = ('x[0]', 'x[1]', 'float y', 'float z') + >>> print(glsl_code(Matrix([1,2,3,4]), assign_to=misc_assignments)) + x[0] = 1; + x[1] = 2; + float y = 3; + float z = 4; + + Passing ``mat_nested = True`` instead prints out nested float arrays, which are + supported in GLSL 4.3 and above. + >>> mat = Matrix([ + ... [ 0, 1, 2], + ... [ 3, 4, 5], + ... [ 6, 7, 8], + ... [ 9, 10, 11], + ... [12, 13, 14]]) + >>> print(glsl_code( mat, mat_nested = True )) + float[5][3]( + float[]( 0, 1, 2), + float[]( 3, 4, 5), + float[]( 6, 7, 8), + float[]( 9, 10, 11), + float[](12, 13, 14) + ) + + + + Custom printing can be defined for certain types by passing a dictionary of + "type" : "function" to the ``user_functions`` kwarg. Alternatively, the + dictionary value can be a list of tuples i.e. [(argument_test, + js_function_string)]. + + >>> custom_functions = { + ... "ceiling": "CEIL", + ... "Abs": [(lambda x: not x.is_integer, "fabs"), + ... (lambda x: x.is_integer, "ABS")] + ... } + >>> glsl_code(Abs(x) + ceiling(x), user_functions=custom_functions) + 'fabs(x) + CEIL(x)' + + If further control is needed, addition, subtraction, multiplication and + division operators can be replaced with ``add``, ``sub``, and ``mul`` + functions. This is done by passing ``use_operators = False``: + + >>> x,y,z = symbols('x,y,z') + >>> glsl_code(x*(y+z), use_operators = False) + 'mul(x, add(y, z))' + >>> glsl_code(x*(y+z*(x-y)**z), use_operators = False) + 'mul(x, add(y, mul(z, pow(sub(x, y), z))))' + + ``Piecewise`` expressions are converted into conditionals. If an + ``assign_to`` variable is provided an if statement is created, otherwise + the ternary operator is used. Note that if the ``Piecewise`` lacks a + default term, represented by ``(expr, True)`` then an error will be thrown. + This is to prevent generating an expression that may not evaluate to + anything. + + >>> from sympy import Piecewise + >>> expr = Piecewise((x + 1, x > 0), (x, True)) + >>> print(glsl_code(expr, tau)) + if (x > 0) { + tau = x + 1; + } + else { + tau = x; + } + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e=Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> glsl_code(e.rhs, assign_to=e.lhs, contract=False) + 'Dy[i] = (y[i + 1] - y[i])/(t[i + 1] - t[i]);' + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([x**2, Piecewise((x + 1, x > 0), (x, True)), sin(x)]) + >>> A = MatrixSymbol('A', 3, 1) + >>> print(glsl_code(mat, A)) + A[0][0] = pow(x, 2.0); + if (x > 0) { + A[1][0] = x + 1; + } + else { + A[1][0] = x; + } + A[2][0] = sin(x); + """ + return GLSLPrinter(settings).doprint(expr,assign_to) + +def print_glsl(expr, **settings): + """Prints the GLSL representation of the given expression. + + See GLSLPrinter init function for settings. + """ + print(glsl_code(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/gtk.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/gtk.py new file mode 100644 index 0000000000000000000000000000000000000000..4123d7231c730bbde28e33f441470c28b21c78d0 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/gtk.py @@ -0,0 +1,16 @@ +from sympy.printing.mathml import mathml +from sympy.utilities.mathml import c2p +import tempfile +import subprocess + + +def print_gtk(x, start_viewer=True): + """Print to Gtkmathview, a gtk widget capable of rendering MathML. + + Needs libgtkmathview-bin""" + with tempfile.NamedTemporaryFile('w') as file: + file.write(c2p(mathml(x), simple=True)) + file.flush() + + if start_viewer: + subprocess.check_call(('mathmlviewer', file.name)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/jscode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/jscode.py new file mode 100644 index 0000000000000000000000000000000000000000..753eb3291dd719ff53b06584de8ebe76c4471a3f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/jscode.py @@ -0,0 +1,332 @@ +""" +Javascript code printer + +The JavascriptCodePrinter converts single SymPy expressions into single +Javascript expressions, using the functions defined in the Javascript +Math object where possible. + +""" + +from __future__ import annotations +from typing import Any + +from sympy.core import S +from sympy.core.numbers import equal_valued +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence, PRECEDENCE + + +# dictionary mapping SymPy function to (argument_conditions, Javascript_function). +# Used in JavascriptCodePrinter._print_Function(self) +known_functions = { + 'Abs': 'Math.abs', + 'acos': 'Math.acos', + 'acosh': 'Math.acosh', + 'asin': 'Math.asin', + 'asinh': 'Math.asinh', + 'atan': 'Math.atan', + 'atan2': 'Math.atan2', + 'atanh': 'Math.atanh', + 'ceiling': 'Math.ceil', + 'cos': 'Math.cos', + 'cosh': 'Math.cosh', + 'exp': 'Math.exp', + 'floor': 'Math.floor', + 'log': 'Math.log', + 'Max': 'Math.max', + 'Min': 'Math.min', + 'sign': 'Math.sign', + 'sin': 'Math.sin', + 'sinh': 'Math.sinh', + 'tan': 'Math.tan', + 'tanh': 'Math.tanh', +} + + +class JavascriptCodePrinter(CodePrinter): + """"A Printer to convert Python expressions to strings of JavaScript code + """ + printmethod = '_javascript' + language = 'JavaScript' + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 17, + 'user_functions': {}, + 'contract': True, + }) + + def __init__(self, settings={}): + CodePrinter.__init__(self, settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + + def _rate_index_position(self, p): + return p*5 + + def _get_statement(self, codestring): + return "%s;" % codestring + + def _get_comment(self, text): + return "// {}".format(text) + + def _declare_number_const(self, name, value): + return "var {} = {};".format(name, value.evalf(self._settings['precision'])) + + def _format_code(self, lines): + return self.indent_code(lines) + + def _traverse_matrix_indices(self, mat): + rows, cols = mat.shape + return ((i, j) for i in range(rows) for j in range(cols)) + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + loopstart = "for (var %(varble)s=%(start)s; %(varble)s<%(end)s; %(varble)s++){" + for i in indices: + # Javascript arrays start at 0 and end at dimension-1 + open_lines.append(loopstart % { + 'varble': self._print(i.label), + 'start': self._print(i.lower), + 'end': self._print(i.upper + 1)}) + close_lines.append("}") + return open_lines, close_lines + + def _print_Pow(self, expr): + PREC = precedence(expr) + if equal_valued(expr.exp, -1): + return '1/%s' % (self.parenthesize(expr.base, PREC)) + elif equal_valued(expr.exp, 0.5): + return 'Math.sqrt(%s)' % self._print(expr.base) + elif expr.exp == S.One/3: + return 'Math.cbrt(%s)' % self._print(expr.base) + else: + return 'Math.pow(%s, %s)' % (self._print(expr.base), + self._print(expr.exp)) + + def _print_Rational(self, expr): + p, q = int(expr.p), int(expr.q) + return '%d/%d' % (p, q) + + def _print_Mod(self, expr): + num, den = expr.args + PREC = precedence(expr) + snum, sden = [self.parenthesize(arg, PREC) for arg in expr.args] + # % is remainder (same sign as numerator), not modulo (same sign as + # denominator), in js. Hence, % only works as modulo if both numbers + # have the same sign + if (num.is_nonnegative and den.is_nonnegative or + num.is_nonpositive and den.is_nonpositive): + return f"{snum} % {sden}" + return f"(({snum} % {sden}) + {sden}) % {sden}" + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_Indexed(self, expr): + # calculate index for 1d array + dims = expr.shape + elem = S.Zero + offset = S.One + for i in reversed(range(expr.rank)): + elem += expr.indices[i]*offset + offset *= dims[i] + return "%s[%s]" % (self._print(expr.base.label), self._print(elem)) + + def _print_Exp1(self, expr): + return "Math.E" + + def _print_Pi(self, expr): + return 'Math.PI' + + def _print_Infinity(self, expr): + return 'Number.POSITIVE_INFINITY' + + def _print_NegativeInfinity(self, expr): + return 'Number.NEGATIVE_INFINITY' + + def _print_Piecewise(self, expr): + from sympy.codegen.ast import Assignment + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + if expr.has(Assignment): + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s) {" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines.append("else {") + else: + lines.append("else if (%s) {" % self._print(c)) + code0 = self._print(e) + lines.append(code0) + lines.append("}") + return "\n".join(lines) + else: + # The piecewise was used in an expression, need to do inline + # operators. This has the downside that inline operators will + # not work for statements that span multiple lines (Matrix or + # Indexed expressions). + ecpairs = ["((%s) ? (\n%s\n)\n" % (self._print(c), self._print(e)) + for e, c in expr.args[:-1]] + last_line = ": (\n%s\n)" % self._print(expr.args[-1].expr) + return ": ".join(ecpairs) + last_line + " ".join([")"*len(ecpairs)]) + + def _print_MatrixElement(self, expr): + return "{}[{}]".format(self.parenthesize(expr.parent, + PRECEDENCE["Atom"], strict=True), + expr.j + expr.i*expr.parent.shape[1]) + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_token = ('{', '(', '{\n', '(\n') + dec_token = ('}', ')') + + code = [ line.lstrip(' \t') for line in code ] + + increase = [ int(any(map(line.endswith, inc_token))) for line in code ] + decrease = [ int(any(map(line.startswith, dec_token))) + for line in code ] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty + + +def jscode(expr, assign_to=None, **settings): + """Converts an expr to a string of javascript code + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This is helpful in case of + line-wrapping, or for expressions that generate multi-line statements. + precision : integer, optional + The precision for numbers such as pi [default=15]. + user_functions : dict, optional + A dictionary where keys are ``FunctionClass`` instances and values are + their string representations. Alternatively, the dictionary value can + be a list of tuples i.e. [(argument_test, js_function_string)]. See + below for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + + Examples + ======== + + >>> from sympy import jscode, symbols, Rational, sin, ceiling, Abs + >>> x, tau = symbols("x, tau") + >>> jscode((2*tau)**Rational(7, 2)) + '8*Math.sqrt(2)*Math.pow(tau, 7/2)' + >>> jscode(sin(x), assign_to="s") + 's = Math.sin(x);' + + Custom printing can be defined for certain types by passing a dictionary of + "type" : "function" to the ``user_functions`` kwarg. Alternatively, the + dictionary value can be a list of tuples i.e. [(argument_test, + js_function_string)]. + + >>> custom_functions = { + ... "ceiling": "CEIL", + ... "Abs": [(lambda x: not x.is_integer, "fabs"), + ... (lambda x: x.is_integer, "ABS")] + ... } + >>> jscode(Abs(x) + ceiling(x), user_functions=custom_functions) + 'fabs(x) + CEIL(x)' + + ``Piecewise`` expressions are converted into conditionals. If an + ``assign_to`` variable is provided an if statement is created, otherwise + the ternary operator is used. Note that if the ``Piecewise`` lacks a + default term, represented by ``(expr, True)`` then an error will be thrown. + This is to prevent generating an expression that may not evaluate to + anything. + + >>> from sympy import Piecewise + >>> expr = Piecewise((x + 1, x > 0), (x, True)) + >>> print(jscode(expr, tau)) + if (x > 0) { + tau = x + 1; + } + else { + tau = x; + } + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e=Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> jscode(e.rhs, assign_to=e.lhs, contract=False) + 'Dy[i] = (y[i + 1] - y[i])/(t[i + 1] - t[i]);' + + Matrices are also supported, but a ``MatrixSymbol`` of the same dimensions + must be provided to ``assign_to``. Note that any expression that can be + generated normally can also exist inside a Matrix: + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([x**2, Piecewise((x + 1, x > 0), (x, True)), sin(x)]) + >>> A = MatrixSymbol('A', 3, 1) + >>> print(jscode(mat, A)) + A[0] = Math.pow(x, 2); + if (x > 0) { + A[1] = x + 1; + } + else { + A[1] = x; + } + A[2] = Math.sin(x); + """ + + return JavascriptCodePrinter(settings).doprint(expr, assign_to) + + +def print_jscode(expr, **settings): + """Prints the Javascript representation of the given expression. + + See jscode for the meaning of the optional arguments. + """ + print(jscode(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/julia.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/julia.py new file mode 100644 index 0000000000000000000000000000000000000000..3ab815add4d87fe953f646409e3a7bb383b1bbc6 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/julia.py @@ -0,0 +1,652 @@ +""" +Julia code printer + +The `JuliaCodePrinter` converts SymPy expressions into Julia expressions. + +A complete code generator, which uses `julia_code` extensively, can be found +in `sympy.utilities.codegen`. The `codegen` module can be used to generate +complete source code files. + +""" + +from __future__ import annotations +from typing import Any + +from sympy.core import Mul, Pow, S, Rational +from sympy.core.mul import _keep_coeff +from sympy.core.numbers import equal_valued +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence, PRECEDENCE +from re import search + +# List of known functions. First, those that have the same name in +# SymPy and Julia. This is almost certainly incomplete! +known_fcns_src1 = ["sin", "cos", "tan", "cot", "sec", "csc", + "asin", "acos", "atan", "acot", "asec", "acsc", + "sinh", "cosh", "tanh", "coth", "sech", "csch", + "asinh", "acosh", "atanh", "acoth", "asech", "acsch", + "atan2", "sign", "floor", "log", "exp", + "cbrt", "sqrt", "erf", "erfc", "erfi", + "factorial", "gamma", "digamma", "trigamma", + "polygamma", "beta", + "airyai", "airyaiprime", "airybi", "airybiprime", + "besselj", "bessely", "besseli", "besselk", + "erfinv", "erfcinv"] +# These functions have different names ("SymPy": "Julia"), more +# generally a mapping to (argument_conditions, julia_function). +known_fcns_src2 = { + "Abs": "abs", + "ceiling": "ceil", + "conjugate": "conj", + "hankel1": "hankelh1", + "hankel2": "hankelh2", + "im": "imag", + "re": "real" +} + + +class JuliaCodePrinter(CodePrinter): + """ + A printer to convert expressions to strings of Julia code. + """ + printmethod = "_julia" + language = "Julia" + + _operators = { + 'and': '&&', + 'or': '||', + 'not': '!', + } + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 17, + 'user_functions': {}, + 'contract': True, + 'inline': True, + }) + # Note: contract is for expressing tensors as loops (if True), or just + # assignment (if False). FIXME: this should be looked a more carefully + # for Julia. + + def __init__(self, settings={}): + super().__init__(settings) + self.known_functions = dict(zip(known_fcns_src1, known_fcns_src1)) + self.known_functions.update(dict(known_fcns_src2)) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + + + def _rate_index_position(self, p): + return p*5 + + + def _get_statement(self, codestring): + return "%s" % codestring + + + def _get_comment(self, text): + return "# {}".format(text) + + + def _declare_number_const(self, name, value): + return "const {} = {}".format(name, value) + + + def _format_code(self, lines): + return self.indent_code(lines) + + + def _traverse_matrix_indices(self, mat): + # Julia uses Fortran order (column-major) + rows, cols = mat.shape + return ((i, j) for j in range(cols) for i in range(rows)) + + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + for i in indices: + # Julia arrays start at 1 and end at dimension + var, start, stop = map(self._print, + [i.label, i.lower + 1, i.upper + 1]) + open_lines.append("for %s = %s:%s" % (var, start, stop)) + close_lines.append("end") + return open_lines, close_lines + + + def _print_Mul(self, expr): + # print complex numbers nicely in Julia + if (expr.is_number and expr.is_imaginary and + expr.as_coeff_Mul()[0].is_integer): + return "%sim" % self._print(-S.ImaginaryUnit*expr) + + # cribbed from str.py + prec = precedence(expr) + + c, e = expr.as_coeff_Mul() + if c < 0: + expr = _keep_coeff(-c, e) + sign = "-" + else: + sign = "" + + a = [] # items in the numerator + b = [] # items that are in the denominator (if any) + + pow_paren = [] # Will collect all pow with more than one base element and exp = -1 + + if self.order not in ('old', 'none'): + args = expr.as_ordered_factors() + else: + # use make_args in case expr was something like -x -> x + args = Mul.make_args(expr) + + # Gather args for numerator/denominator + for item in args: + if (item.is_commutative and item.is_Pow and item.exp.is_Rational + and item.exp.is_negative): + if item.exp != -1: + b.append(Pow(item.base, -item.exp, evaluate=False)) + else: + if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 + pow_paren.append(item) + b.append(Pow(item.base, -item.exp)) + elif item.is_Rational and item is not S.Infinity and item.p == 1: + # Save the Rational type in julia Unless the numerator is 1. + # For example: + # julia_code(Rational(3, 7)*x) --> (3 // 7) * x + # julia_code(x/3) --> x / 3 but not x * (1 // 3) + b.append(Rational(item.q)) + else: + a.append(item) + + a = a or [S.One] + + a_str = [self.parenthesize(x, prec) for x in a] + b_str = [self.parenthesize(x, prec) for x in b] + + # To parenthesize Pow with exp = -1 and having more than one Symbol + for item in pow_paren: + if item.base in b: + b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] + + # from here it differs from str.py to deal with "*" and ".*" + def multjoin(a, a_str): + # here we probably are assuming the constants will come first + r = a_str[0] + for i in range(1, len(a)): + mulsym = '*' if a[i-1].is_number else '.*' + r = "%s %s %s" % (r, mulsym, a_str[i]) + return r + + if not b: + return sign + multjoin(a, a_str) + elif len(b) == 1: + divsym = '/' if b[0].is_number else './' + return "%s %s %s" % (sign+multjoin(a, a_str), divsym, b_str[0]) + else: + divsym = '/' if all(bi.is_number for bi in b) else './' + return "%s %s (%s)" % (sign + multjoin(a, a_str), divsym, multjoin(b, b_str)) + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_Pow(self, expr): + powsymbol = '^' if all(x.is_number for x in expr.args) else '.^' + + PREC = precedence(expr) + + if equal_valued(expr.exp, 0.5): + return "sqrt(%s)" % self._print(expr.base) + + if expr.is_commutative: + if equal_valued(expr.exp, -0.5): + sym = '/' if expr.base.is_number else './' + return "1 %s sqrt(%s)" % (sym, self._print(expr.base)) + if equal_valued(expr.exp, -1): + sym = '/' if expr.base.is_number else './' + return "1 %s %s" % (sym, self.parenthesize(expr.base, PREC)) + + return '%s %s %s' % (self.parenthesize(expr.base, PREC), powsymbol, + self.parenthesize(expr.exp, PREC)) + + + def _print_MatPow(self, expr): + PREC = precedence(expr) + return '%s ^ %s' % (self.parenthesize(expr.base, PREC), + self.parenthesize(expr.exp, PREC)) + + + def _print_Pi(self, expr): + if self._settings["inline"]: + return "pi" + else: + return super()._print_NumberSymbol(expr) + + + def _print_ImaginaryUnit(self, expr): + return "im" + + + def _print_Exp1(self, expr): + if self._settings["inline"]: + return "e" + else: + return super()._print_NumberSymbol(expr) + + + def _print_EulerGamma(self, expr): + if self._settings["inline"]: + return "eulergamma" + else: + return super()._print_NumberSymbol(expr) + + + def _print_Catalan(self, expr): + if self._settings["inline"]: + return "catalan" + else: + return super()._print_NumberSymbol(expr) + + + def _print_GoldenRatio(self, expr): + if self._settings["inline"]: + return "golden" + else: + return super()._print_NumberSymbol(expr) + + + def _print_Assignment(self, expr): + from sympy.codegen.ast import Assignment + from sympy.functions.elementary.piecewise import Piecewise + from sympy.tensor.indexed import IndexedBase + # Copied from codeprinter, but remove special MatrixSymbol treatment + lhs = expr.lhs + rhs = expr.rhs + # We special case assignments that take multiple lines + if not self._settings["inline"] and isinstance(expr.rhs, Piecewise): + # Here we modify Piecewise so each expression is now + # an Assignment, and then continue on the print. + expressions = [] + conditions = [] + for (e, c) in rhs.args: + expressions.append(Assignment(lhs, e)) + conditions.append(c) + temp = Piecewise(*zip(expressions, conditions)) + return self._print(temp) + if self._settings["contract"] and (lhs.has(IndexedBase) or + rhs.has(IndexedBase)): + # Here we check if there is looping to be done, and if so + # print the required loops. + return self._doprint_loops(rhs, lhs) + else: + lhs_code = self._print(lhs) + rhs_code = self._print(rhs) + return self._get_statement("%s = %s" % (lhs_code, rhs_code)) + + + def _print_Infinity(self, expr): + return 'Inf' + + + def _print_NegativeInfinity(self, expr): + return '-Inf' + + + def _print_NaN(self, expr): + return 'NaN' + + + def _print_list(self, expr): + return 'Any[' + ', '.join(self._print(a) for a in expr) + ']' + + + def _print_tuple(self, expr): + if len(expr) == 1: + return "(%s,)" % self._print(expr[0]) + else: + return "(%s)" % self.stringify(expr, ", ") + _print_Tuple = _print_tuple + + + def _print_BooleanTrue(self, expr): + return "true" + + + def _print_BooleanFalse(self, expr): + return "false" + + + def _print_bool(self, expr): + return str(expr).lower() + + + # Could generate quadrature code for definite Integrals? + #_print_Integral = _print_not_supported + + + def _print_MatrixBase(self, A): + # Handle zero dimensions: + if S.Zero in A.shape: + return 'zeros(%s, %s)' % (A.rows, A.cols) + elif (A.rows, A.cols) == (1, 1): + return "[%s]" % A[0, 0] + elif A.rows == 1: + return "[%s]" % A.table(self, rowstart='', rowend='', colsep=' ') + elif A.cols == 1: + # note .table would unnecessarily equispace the rows + return "[%s]" % ", ".join([self._print(a) for a in A]) + return "[%s]" % A.table(self, rowstart='', rowend='', + rowsep=';\n', colsep=' ') + + + def _print_SparseRepMatrix(self, A): + from sympy.matrices import Matrix + L = A.col_list() + # make row vectors of the indices and entries + I = Matrix([k[0] + 1 for k in L]) + J = Matrix([k[1] + 1 for k in L]) + AIJ = Matrix([k[2] for k in L]) + return "sparse(%s, %s, %s, %s, %s)" % (self._print(I), self._print(J), + self._print(AIJ), A.rows, A.cols) + + + def _print_MatrixElement(self, expr): + return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) \ + + '[%s,%s]' % (expr.i + 1, expr.j + 1) + + + def _print_MatrixSlice(self, expr): + def strslice(x, lim): + l = x[0] + 1 + h = x[1] + step = x[2] + lstr = self._print(l) + hstr = 'end' if h == lim else self._print(h) + if step == 1: + if l == 1 and h == lim: + return ':' + if l == h: + return lstr + else: + return lstr + ':' + hstr + else: + return ':'.join((lstr, self._print(step), hstr)) + return (self._print(expr.parent) + '[' + + strslice(expr.rowslice, expr.parent.shape[0]) + ',' + + strslice(expr.colslice, expr.parent.shape[1]) + ']') + + + def _print_Indexed(self, expr): + inds = [ self._print(i) for i in expr.indices ] + return "%s[%s]" % (self._print(expr.base.label), ",".join(inds)) + + def _print_Identity(self, expr): + return "eye(%s)" % self._print(expr.shape[0]) + + def _print_HadamardProduct(self, expr): + return ' .* '.join([self.parenthesize(arg, precedence(expr)) + for arg in expr.args]) + + def _print_HadamardPower(self, expr): + PREC = precedence(expr) + return '.**'.join([ + self.parenthesize(expr.base, PREC), + self.parenthesize(expr.exp, PREC) + ]) + + def _print_Rational(self, expr): + if expr.q == 1: + return str(expr.p) + return "%s // %s" % (expr.p, expr.q) + + # Note: as of 2022, Julia doesn't have spherical Bessel functions + def _print_jn(self, expr): + from sympy.functions import sqrt, besselj + x = expr.argument + expr2 = sqrt(S.Pi/(2*x))*besselj(expr.order + S.Half, x) + return self._print(expr2) + + + def _print_yn(self, expr): + from sympy.functions import sqrt, bessely + x = expr.argument + expr2 = sqrt(S.Pi/(2*x))*bessely(expr.order + S.Half, x) + return self._print(expr2) + + def _print_sinc(self, expr): + # Julia has the normalized sinc function + return "sinc({})".format(self._print(expr.args[0] / S.Pi)) + + def _print_Piecewise(self, expr): + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + if self._settings["inline"]: + # Express each (cond, expr) pair in a nested Horner form: + # (condition) .* (expr) + (not cond) .* () + # Expressions that result in multiple statements won't work here. + ecpairs = ["({}) ? ({}) :".format + (self._print(c), self._print(e)) + for e, c in expr.args[:-1]] + elast = " (%s)" % self._print(expr.args[-1].expr) + pw = "\n".join(ecpairs) + elast + # Note: current need these outer brackets for 2*pw. Would be + # nicer to teach parenthesize() to do this for us when needed! + return "(" + pw + ")" + else: + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s)" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines.append("else") + else: + lines.append("elseif (%s)" % self._print(c)) + code0 = self._print(e) + lines.append(code0) + if i == len(expr.args) - 1: + lines.append("end") + return "\n".join(lines) + + def _print_MatMul(self, expr): + c, m = expr.as_coeff_mmul() + + sign = "" + if c.is_number: + re, im = c.as_real_imag() + if im.is_zero and re.is_negative: + expr = _keep_coeff(-c, m) + sign = "-" + elif re.is_zero and im.is_negative: + expr = _keep_coeff(-c, m) + sign = "-" + + return sign + ' * '.join( + (self.parenthesize(arg, precedence(expr)) for arg in expr.args) + ) + + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + # code mostly copied from ccode + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_regex = ('^function ', '^if ', '^elseif ', '^else$', '^for ') + dec_regex = ('^end$', '^elseif ', '^else$') + + # pre-strip left-space from the code + code = [ line.lstrip(' \t') for line in code ] + + increase = [ int(any(search(re, line) for re in inc_regex)) + for line in code ] + decrease = [ int(any(search(re, line) for re in dec_regex)) + for line in code ] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty + + +def julia_code(expr, assign_to=None, **settings): + r"""Converts `expr` to a string of Julia code. + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This can be helpful for + expressions that generate multi-line statements. + precision : integer, optional + The precision for numbers such as pi [default=16]. + user_functions : dict, optional + A dictionary where keys are ``FunctionClass`` instances and values are + their string representations. Alternatively, the dictionary value can + be a list of tuples i.e. [(argument_test, cfunction_string)]. See + below for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + inline: bool, optional + If True, we try to create single-statement code instead of multiple + statements. [default=True]. + + Examples + ======== + + >>> from sympy import julia_code, symbols, sin, pi + >>> x = symbols('x') + >>> julia_code(sin(x).series(x).removeO()) + 'x .^ 5 / 120 - x .^ 3 / 6 + x' + + >>> from sympy import Rational, ceiling + >>> x, y, tau = symbols("x, y, tau") + >>> julia_code((2*tau)**Rational(7, 2)) + '8 * sqrt(2) * tau .^ (7 // 2)' + + Note that element-wise (Hadamard) operations are used by default between + symbols. This is because its possible in Julia to write "vectorized" + code. It is harmless if the values are scalars. + + >>> julia_code(sin(pi*x*y), assign_to="s") + 's = sin(pi * x .* y)' + + If you need a matrix product "*" or matrix power "^", you can specify the + symbol as a ``MatrixSymbol``. + + >>> from sympy import Symbol, MatrixSymbol + >>> n = Symbol('n', integer=True, positive=True) + >>> A = MatrixSymbol('A', n, n) + >>> julia_code(3*pi*A**3) + '(3 * pi) * A ^ 3' + + This class uses several rules to decide which symbol to use a product. + Pure numbers use "*", Symbols use ".*" and MatrixSymbols use "*". + A HadamardProduct can be used to specify componentwise multiplication ".*" + of two MatrixSymbols. There is currently there is no easy way to specify + scalar symbols, so sometimes the code might have some minor cosmetic + issues. For example, suppose x and y are scalars and A is a Matrix, then + while a human programmer might write "(x^2*y)*A^3", we generate: + + >>> julia_code(x**2*y*A**3) + '(x .^ 2 .* y) * A ^ 3' + + Matrices are supported using Julia inline notation. When using + ``assign_to`` with matrices, the name can be specified either as a string + or as a ``MatrixSymbol``. The dimensions must align in the latter case. + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([[x**2, sin(x), ceiling(x)]]) + >>> julia_code(mat, assign_to='A') + 'A = [x .^ 2 sin(x) ceil(x)]' + + ``Piecewise`` expressions are implemented with logical masking by default. + Alternatively, you can pass "inline=False" to use if-else conditionals. + Note that if the ``Piecewise`` lacks a default term, represented by + ``(expr, True)`` then an error will be thrown. This is to prevent + generating an expression that may not evaluate to anything. + + >>> from sympy import Piecewise + >>> pw = Piecewise((x + 1, x > 0), (x, True)) + >>> julia_code(pw, assign_to=tau) + 'tau = ((x > 0) ? (x + 1) : (x))' + + Note that any expression that can be generated normally can also exist + inside a Matrix: + + >>> mat = Matrix([[x**2, pw, sin(x)]]) + >>> julia_code(mat, assign_to='A') + 'A = [x .^ 2 ((x > 0) ? (x + 1) : (x)) sin(x)]' + + Custom printing can be defined for certain types by passing a dictionary of + "type" : "function" to the ``user_functions`` kwarg. Alternatively, the + dictionary value can be a list of tuples i.e., [(argument_test, + cfunction_string)]. This can be used to call a custom Julia function. + + >>> from sympy import Function + >>> f = Function('f') + >>> g = Function('g') + >>> custom_functions = { + ... "f": "existing_julia_fcn", + ... "g": [(lambda x: x.is_Matrix, "my_mat_fcn"), + ... (lambda x: not x.is_Matrix, "my_fcn")] + ... } + >>> mat = Matrix([[1, x]]) + >>> julia_code(f(x) + g(x) + g(mat), user_functions=custom_functions) + 'existing_julia_fcn(x) + my_fcn(x) + my_mat_fcn([1 x])' + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e = Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> julia_code(e.rhs, assign_to=e.lhs, contract=False) + 'Dy[i] = (y[i + 1] - y[i]) ./ (t[i + 1] - t[i])' + """ + return JuliaCodePrinter(settings).doprint(expr, assign_to) + + +def print_julia_code(expr, **settings): + """Prints the Julia representation of the given expression. + + See `julia_code` for the meaning of the optional arguments. + """ + print(julia_code(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/lambdarepr.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/lambdarepr.py new file mode 100644 index 0000000000000000000000000000000000000000..87fa0988d138d54d68ab8aef1bbc0f27b243b472 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/lambdarepr.py @@ -0,0 +1,251 @@ +from .pycode import ( + PythonCodePrinter, + MpmathPrinter, +) +from .numpy import NumPyPrinter # NumPyPrinter is imported for backward compatibility +from sympy.core.sorting import default_sort_key + + +__all__ = [ + 'PythonCodePrinter', + 'MpmathPrinter', # MpmathPrinter is published for backward compatibility + 'NumPyPrinter', + 'LambdaPrinter', + 'NumPyPrinter', + 'IntervalPrinter', + 'lambdarepr', +] + + +class LambdaPrinter(PythonCodePrinter): + """ + This printer converts expressions into strings that can be used by + lambdify. + """ + printmethod = "_lambdacode" + + + def _print_And(self, expr): + result = ['('] + for arg in sorted(expr.args, key=default_sort_key): + result.extend(['(', self._print(arg), ')']) + result.append(' and ') + result = result[:-1] + result.append(')') + return ''.join(result) + + def _print_Or(self, expr): + result = ['('] + for arg in sorted(expr.args, key=default_sort_key): + result.extend(['(', self._print(arg), ')']) + result.append(' or ') + result = result[:-1] + result.append(')') + return ''.join(result) + + def _print_Not(self, expr): + result = ['(', 'not (', self._print(expr.args[0]), '))'] + return ''.join(result) + + def _print_BooleanTrue(self, expr): + return "True" + + def _print_BooleanFalse(self, expr): + return "False" + + def _print_ITE(self, expr): + result = [ + '((', self._print(expr.args[1]), + ') if (', self._print(expr.args[0]), + ') else (', self._print(expr.args[2]), '))' + ] + return ''.join(result) + + def _print_NumberSymbol(self, expr): + return str(expr) + + def _print_Pow(self, expr, **kwargs): + # XXX Temporary workaround. Should Python math printer be + # isolated from PythonCodePrinter? + return super(PythonCodePrinter, self)._print_Pow(expr, **kwargs) + + +# numexpr works by altering the string passed to numexpr.evaluate +# rather than by populating a namespace. Thus a special printer... +class NumExprPrinter(LambdaPrinter): + # key, value pairs correspond to SymPy name and numexpr name + # functions not appearing in this dict will raise a TypeError + printmethod = "_numexprcode" + + _numexpr_functions = { + 'sin' : 'sin', + 'cos' : 'cos', + 'tan' : 'tan', + 'asin': 'arcsin', + 'acos': 'arccos', + 'atan': 'arctan', + 'atan2' : 'arctan2', + 'sinh' : 'sinh', + 'cosh' : 'cosh', + 'tanh' : 'tanh', + 'asinh': 'arcsinh', + 'acosh': 'arccosh', + 'atanh': 'arctanh', + 'ln' : 'log', + 'log': 'log', + 'exp': 'exp', + 'sqrt' : 'sqrt', + 'Abs' : 'abs', + 'conjugate' : 'conj', + 'im' : 'imag', + 're' : 'real', + 'where' : 'where', + 'complex' : 'complex', + 'contains' : 'contains', + } + + module = 'numexpr' + + def _print_ImaginaryUnit(self, expr): + return '1j' + + def _print_seq(self, seq, delimiter=', '): + # simplified _print_seq taken from pretty.py + s = [self._print(item) for item in seq] + if s: + return delimiter.join(s) + else: + return "" + + def _print_Function(self, e): + func_name = e.func.__name__ + + nstr = self._numexpr_functions.get(func_name, None) + if nstr is None: + # check for implemented_function + if hasattr(e, '_imp_'): + return "(%s)" % self._print(e._imp_(*e.args)) + else: + raise TypeError("numexpr does not support function '%s'" % + func_name) + return "%s(%s)" % (nstr, self._print_seq(e.args)) + + def _print_Piecewise(self, expr): + "Piecewise function printer" + exprs = [self._print(arg.expr) for arg in expr.args] + conds = [self._print(arg.cond) for arg in expr.args] + # If [default_value, True] is a (expr, cond) sequence in a Piecewise object + # it will behave the same as passing the 'default' kwarg to select() + # *as long as* it is the last element in expr.args. + # If this is not the case, it may be triggered prematurely. + ans = [] + parenthesis_count = 0 + is_last_cond_True = False + for cond, expr in zip(conds, exprs): + if cond == 'True': + ans.append(expr) + is_last_cond_True = True + break + else: + ans.append('where(%s, %s, ' % (cond, expr)) + parenthesis_count += 1 + if not is_last_cond_True: + # See https://github.com/pydata/numexpr/issues/298 + # + # simplest way to put a nan but raises + # 'RuntimeWarning: invalid value encountered in log' + # + # There are other ways to do this such as + # + # >>> import numexpr as ne + # >>> nan = float('nan') + # >>> ne.evaluate('where(x < 0, -1, nan)', {'x': [-1, 2, 3], 'nan':nan}) + # array([-1., nan, nan]) + # + # That needs to be handled in the lambdified function though rather + # than here in the printer. + ans.append('log(-1)') + return ''.join(ans) + ')' * parenthesis_count + + def _print_ITE(self, expr): + from sympy.functions.elementary.piecewise import Piecewise + return self._print(expr.rewrite(Piecewise)) + + def blacklisted(self, expr): + raise TypeError("numexpr cannot be used with %s" % + expr.__class__.__name__) + + # blacklist all Matrix printing + _print_SparseRepMatrix = \ + _print_MutableSparseMatrix = \ + _print_ImmutableSparseMatrix = \ + _print_Matrix = \ + _print_DenseMatrix = \ + _print_MutableDenseMatrix = \ + _print_ImmutableMatrix = \ + _print_ImmutableDenseMatrix = \ + blacklisted + # blacklist some Python expressions + _print_list = \ + _print_tuple = \ + _print_Tuple = \ + _print_dict = \ + _print_Dict = \ + blacklisted + + def _print_NumExprEvaluate(self, expr): + evaluate = self._module_format(self.module +".evaluate") + return "%s('%s', truediv=True)" % (evaluate, self._print(expr.expr)) + + def doprint(self, expr): + from sympy.codegen.ast import CodegenAST + from sympy.codegen.pynodes import NumExprEvaluate + if not isinstance(expr, CodegenAST): + expr = NumExprEvaluate(expr) + return super().doprint(expr) + + def _print_Return(self, expr): + from sympy.codegen.pynodes import NumExprEvaluate + r, = expr.args + if not isinstance(r, NumExprEvaluate): + expr = expr.func(NumExprEvaluate(r)) + return super()._print_Return(expr) + + def _print_Assignment(self, expr): + from sympy.codegen.pynodes import NumExprEvaluate + lhs, rhs, *args = expr.args + if not isinstance(rhs, NumExprEvaluate): + expr = expr.func(lhs, NumExprEvaluate(rhs), *args) + return super()._print_Assignment(expr) + + def _print_CodeBlock(self, expr): + from sympy.codegen.ast import CodegenAST + from sympy.codegen.pynodes import NumExprEvaluate + args = [ arg if isinstance(arg, CodegenAST) else NumExprEvaluate(arg) for arg in expr.args ] + return super()._print_CodeBlock(self, expr.func(*args)) + + +class IntervalPrinter(MpmathPrinter, LambdaPrinter): + """Use ``lambda`` printer but print numbers as ``mpi`` intervals. """ + + def _print_Integer(self, expr): + return "mpi('%s')" % super(PythonCodePrinter, self)._print_Integer(expr) + + def _print_Rational(self, expr): + return "mpi('%s')" % super(PythonCodePrinter, self)._print_Rational(expr) + + def _print_Half(self, expr): + return "mpi('%s')" % super(PythonCodePrinter, self)._print_Rational(expr) + + def _print_Pow(self, expr): + return super(MpmathPrinter, self)._print_Pow(expr, rational=True) + + +for k in NumExprPrinter._numexpr_functions: + setattr(NumExprPrinter, '_print_%s' % k, NumExprPrinter._print_Function) + +def lambdarepr(expr, **settings): + """ + Returns a string usable for lambdifying. + """ + return LambdaPrinter(settings).doprint(expr) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/latex.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/latex.py new file mode 100644 index 0000000000000000000000000000000000000000..724df719d560e001deb175649a3769703bdf5ca5 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/latex.py @@ -0,0 +1,3318 @@ +""" +A Printer which converts an expression into its LaTeX equivalent. +""" +from __future__ import annotations +from typing import Any, Callable, TYPE_CHECKING + +import itertools + +from sympy.core import Add, Float, Mod, Mul, Number, S, Symbol, Expr +from sympy.core.alphabets import greeks +from sympy.core.containers import Tuple +from sympy.core.function import Function, AppliedUndef, Derivative +from sympy.core.operations import AssocOp +from sympy.core.power import Pow +from sympy.core.sorting import default_sort_key +from sympy.core.sympify import SympifyError +from sympy.logic.boolalg import true, BooleanTrue, BooleanFalse + + +# sympy.printing imports +from sympy.printing.precedence import precedence_traditional +from sympy.printing.printer import Printer, print_function +from sympy.printing.conventions import split_super_sub, requires_partial +from sympy.printing.precedence import precedence, PRECEDENCE + +from mpmath.libmp.libmpf import prec_to_dps, to_str as mlib_to_str + +from sympy.utilities.iterables import has_variety, sift + +import re + +if TYPE_CHECKING: + from sympy.tensor.array import NDimArray + from sympy.vector.basisdependent import BasisDependent + +# Hand-picked functions which can be used directly in both LaTeX and MathJax +# Complete list at +# https://docs.mathjax.org/en/latest/tex.html#supported-latex-commands +# This variable only contains those functions which SymPy uses. +accepted_latex_functions = ['arcsin', 'arccos', 'arctan', 'sin', 'cos', 'tan', + 'sinh', 'cosh', 'tanh', 'sqrt', 'ln', 'log', 'sec', + 'csc', 'cot', 'coth', 're', 'im', 'frac', 'root', + 'arg', + ] + +tex_greek_dictionary = { + 'Alpha': r'\mathrm{A}', + 'Beta': r'\mathrm{B}', + 'Gamma': r'\Gamma', + 'Delta': r'\Delta', + 'Epsilon': r'\mathrm{E}', + 'Zeta': r'\mathrm{Z}', + 'Eta': r'\mathrm{H}', + 'Theta': r'\Theta', + 'Iota': r'\mathrm{I}', + 'Kappa': r'\mathrm{K}', + 'Lambda': r'\Lambda', + 'Mu': r'\mathrm{M}', + 'Nu': r'\mathrm{N}', + 'Xi': r'\Xi', + 'omicron': 'o', + 'Omicron': r'\mathrm{O}', + 'Pi': r'\Pi', + 'Rho': r'\mathrm{P}', + 'Sigma': r'\Sigma', + 'Tau': r'\mathrm{T}', + 'Upsilon': r'\Upsilon', + 'Phi': r'\Phi', + 'Chi': r'\mathrm{X}', + 'Psi': r'\Psi', + 'Omega': r'\Omega', + 'lamda': r'\lambda', + 'Lamda': r'\Lambda', + 'khi': r'\chi', + 'Khi': r'\mathrm{X}', + 'varepsilon': r'\varepsilon', + 'varkappa': r'\varkappa', + 'varphi': r'\varphi', + 'varpi': r'\varpi', + 'varrho': r'\varrho', + 'varsigma': r'\varsigma', + 'vartheta': r'\vartheta', +} + +other_symbols = {'aleph', 'beth', 'daleth', 'gimel', 'ell', 'eth', 'hbar', + 'hslash', 'mho', 'wp'} + +# Variable name modifiers +modifier_dict: dict[str, Callable[[str], str]] = { + # Accents + 'mathring': lambda s: r'\mathring{'+s+r'}', + 'ddddot': lambda s: r'\ddddot{'+s+r'}', + 'dddot': lambda s: r'\dddot{'+s+r'}', + 'ddot': lambda s: r'\ddot{'+s+r'}', + 'dot': lambda s: r'\dot{'+s+r'}', + 'check': lambda s: r'\check{'+s+r'}', + 'breve': lambda s: r'\breve{'+s+r'}', + 'acute': lambda s: r'\acute{'+s+r'}', + 'grave': lambda s: r'\grave{'+s+r'}', + 'tilde': lambda s: r'\tilde{'+s+r'}', + 'hat': lambda s: r'\hat{'+s+r'}', + 'bar': lambda s: r'\bar{'+s+r'}', + 'vec': lambda s: r'\vec{'+s+r'}', + 'prime': lambda s: "{"+s+"}'", + 'prm': lambda s: "{"+s+"}'", + # Faces + 'bold': lambda s: r'\boldsymbol{'+s+r'}', + 'bm': lambda s: r'\boldsymbol{'+s+r'}', + 'cal': lambda s: r'\mathcal{'+s+r'}', + 'scr': lambda s: r'\mathscr{'+s+r'}', + 'frak': lambda s: r'\mathfrak{'+s+r'}', + # Brackets + 'norm': lambda s: r'\left\|{'+s+r'}\right\|', + 'avg': lambda s: r'\left\langle{'+s+r'}\right\rangle', + 'abs': lambda s: r'\left|{'+s+r'}\right|', + 'mag': lambda s: r'\left|{'+s+r'}\right|', +} + +greek_letters_set = frozenset(greeks) + +_between_two_numbers_p = ( + re.compile(r'[0-9][} ]*$'), # search + re.compile(r'(\d|\\frac{\d+}{\d+})'), # match +) + + +def latex_escape(s: str) -> str: + """ + Escape a string such that latex interprets it as plaintext. + + We cannot use verbatim easily with mathjax, so escaping is easier. + Rules from https://tex.stackexchange.com/a/34586/41112. + """ + s = s.replace('\\', r'\textbackslash') + for c in '&%$#_{}': + s = s.replace(c, '\\' + c) + s = s.replace('~', r'\textasciitilde') + s = s.replace('^', r'\textasciicircum') + return s + + +class LatexPrinter(Printer): + printmethod = "_latex" + + _default_settings: dict[str, Any] = { + "full_prec": False, + "fold_frac_powers": False, + "fold_func_brackets": False, + "fold_short_frac": None, + "inv_trig_style": "abbreviated", + "itex": False, + "ln_notation": False, + "long_frac_ratio": None, + "mat_delim": "[", + "mat_str": None, + "mode": "plain", + "mul_symbol": None, + "order": None, + "symbol_names": {}, + "root_notation": True, + "mat_symbol_style": "plain", + "imaginary_unit": "i", + "gothic_re_im": False, + "decimal_separator": "period", + "perm_cyclic": True, + "parenthesize_super": True, + "min": None, + "max": None, + "diff_operator": "d", + "adjoint_style": "dagger", + "disable_split_super_sub": False, + } + + def __init__(self, settings=None): + Printer.__init__(self, settings) + + if 'mode' in self._settings: + valid_modes = ['inline', 'plain', 'equation', + 'equation*'] + if self._settings['mode'] not in valid_modes: + raise ValueError("'mode' must be one of 'inline', 'plain', " + "'equation' or 'equation*'") + + if self._settings['fold_short_frac'] is None and \ + self._settings['mode'] == 'inline': + self._settings['fold_short_frac'] = True + + mul_symbol_table = { + None: r" ", + "ldot": r" \,.\, ", + "dot": r" \cdot ", + "times": r" \times " + } + try: + self._settings['mul_symbol_latex'] = \ + mul_symbol_table[self._settings['mul_symbol']] + except KeyError: + self._settings['mul_symbol_latex'] = \ + self._settings['mul_symbol'] + try: + self._settings['mul_symbol_latex_numbers'] = \ + mul_symbol_table[self._settings['mul_symbol'] or 'dot'] + except KeyError: + if (self._settings['mul_symbol'].strip() in + ['', ' ', '\\', '\\,', '\\:', '\\;', '\\quad']): + self._settings['mul_symbol_latex_numbers'] = \ + mul_symbol_table['dot'] + else: + self._settings['mul_symbol_latex_numbers'] = \ + self._settings['mul_symbol'] + + self._delim_dict = {'(': ')', '[': ']'} + + imaginary_unit_table = { + None: r"i", + "i": r"i", + "ri": r"\mathrm{i}", + "ti": r"\text{i}", + "j": r"j", + "rj": r"\mathrm{j}", + "tj": r"\text{j}", + } + imag_unit = self._settings['imaginary_unit'] + self._settings['imaginary_unit_latex'] = imaginary_unit_table.get(imag_unit, imag_unit) + + diff_operator_table = { + None: r"d", + "d": r"d", + "rd": r"\mathrm{d}", + "td": r"\text{d}", + } + diff_operator = self._settings['diff_operator'] + self._settings["diff_operator_latex"] = diff_operator_table.get(diff_operator, diff_operator) + + def _add_parens(self, s) -> str: + return r"\left({}\right)".format(s) + + # TODO: merge this with the above, which requires a lot of test changes + def _add_parens_lspace(self, s) -> str: + return r"\left( {}\right)".format(s) + + def parenthesize(self, item, level, is_neg=False, strict=False) -> str: + prec_val = precedence_traditional(item) + if is_neg and strict: + return self._add_parens(self._print(item)) + + if (prec_val < level) or ((not strict) and prec_val <= level): + return self._add_parens(self._print(item)) + else: + return self._print(item) + + def parenthesize_super(self, s): + """ + Protect superscripts in s + + If the parenthesize_super option is set, protect with parentheses, else + wrap in braces. + """ + if "^" in s: + if self._settings['parenthesize_super']: + return self._add_parens(s) + else: + return "{{{}}}".format(s) + return s + + def doprint(self, expr) -> str: + tex = Printer.doprint(self, expr) + + if self._settings['mode'] == 'plain': + return tex + elif self._settings['mode'] == 'inline': + return r"$%s$" % tex + elif self._settings['itex']: + return r"$$%s$$" % tex + else: + env_str = self._settings['mode'] + return r"\begin{%s}%s\end{%s}" % (env_str, tex, env_str) + + def _needs_brackets(self, expr) -> bool: + """ + Returns True if the expression needs to be wrapped in brackets when + printed, False otherwise. For example: a + b => True; a => False; + 10 => False; -10 => True. + """ + return not ((expr.is_Integer and expr.is_nonnegative) + or (expr.is_Atom and (expr is not S.NegativeOne + and expr.is_Rational is False))) + + def _needs_function_brackets(self, expr) -> bool: + """ + Returns True if the expression needs to be wrapped in brackets when + passed as an argument to a function, False otherwise. This is a more + liberal version of _needs_brackets, in that many expressions which need + to be wrapped in brackets when added/subtracted/raised to a power do + not need them when passed to a function. Such an example is a*b. + """ + if not self._needs_brackets(expr): + return False + else: + # Muls of the form a*b*c... can be folded + if expr.is_Mul and not self._mul_is_clean(expr): + return True + # Pows which don't need brackets can be folded + elif expr.is_Pow and not self._pow_is_clean(expr): + return True + # Add and Function always need brackets + elif expr.is_Add or expr.is_Function: + return True + else: + return False + + def _needs_mul_brackets(self, expr, first=False, last=False) -> bool: + """ + Returns True if the expression needs to be wrapped in brackets when + printed as part of a Mul, False otherwise. This is True for Add, + but also for some container objects that would not need brackets + when appearing last in a Mul, e.g. an Integral. ``last=True`` + specifies that this expr is the last to appear in a Mul. + ``first=True`` specifies that this expr is the first to appear in + a Mul. + """ + from sympy.concrete.products import Product + from sympy.concrete.summations import Sum + from sympy.integrals.integrals import Integral + + if expr.is_Mul: + if not first and expr.could_extract_minus_sign(): + return True + elif precedence_traditional(expr) < PRECEDENCE["Mul"]: + return True + elif expr.is_Relational: + return True + if expr.is_Piecewise: + return True + if any(expr.has(x) for x in (Mod,)): + return True + if (not last and + any(expr.has(x) for x in (Integral, Product, Sum))): + return True + + return False + + def _needs_add_brackets(self, expr) -> bool: + """ + Returns True if the expression needs to be wrapped in brackets when + printed as part of an Add, False otherwise. This is False for most + things. + """ + if expr.is_Relational: + return True + if any(expr.has(x) for x in (Mod,)): + return True + if expr.is_Add: + return True + return False + + def _mul_is_clean(self, expr) -> bool: + for arg in expr.args: + if arg.is_Function: + return False + return True + + def _pow_is_clean(self, expr) -> bool: + return not self._needs_brackets(expr.base) + + def _do_exponent(self, expr: str, exp): + if exp is not None: + return r"\left(%s\right)^{%s}" % (expr, exp) + else: + return expr + + def _print_Basic(self, expr): + name = self._deal_with_super_sub(expr.__class__.__name__) + if expr.args: + ls = [self._print(o) for o in expr.args] + s = r"\operatorname{{{}}}\left({}\right)" + return s.format(name, ", ".join(ls)) + else: + return r"\text{{{}}}".format(name) + + def _print_bool(self, e: bool | BooleanTrue | BooleanFalse): + return r"\text{%s}" % e + + _print_BooleanTrue = _print_bool + _print_BooleanFalse = _print_bool + + def _print_NoneType(self, e): + return r"\text{%s}" % e + + def _print_Add(self, expr, order=None): + terms = self._as_ordered_terms(expr, order=order) + + tex = "" + for i, term in enumerate(terms): + if i == 0: + pass + elif term.could_extract_minus_sign(): + tex += " - " + term = -term + else: + tex += " + " + term_tex = self._print(term) + if self._needs_add_brackets(term): + term_tex = r"\left(%s\right)" % term_tex + tex += term_tex + + return tex + + def _print_Cycle(self, expr): + from sympy.combinatorics.permutations import Permutation + if expr.size == 0: + return r"\left( \right)" + expr = Permutation(expr) + expr_perm = expr.cyclic_form + siz = expr.size + if expr.array_form[-1] == siz - 1: + expr_perm = expr_perm + [[siz - 1]] + term_tex = '' + for i in expr_perm: + term_tex += str(i).replace(',', r"\;") + term_tex = term_tex.replace('[', r"\left( ") + term_tex = term_tex.replace(']', r"\right)") + return term_tex + + def _print_Permutation(self, expr): + from sympy.combinatorics.permutations import Permutation + from sympy.utilities.exceptions import sympy_deprecation_warning + + perm_cyclic = Permutation.print_cyclic + if perm_cyclic is not None: + sympy_deprecation_warning( + f""" + Setting Permutation.print_cyclic is deprecated. Instead use + init_printing(perm_cyclic={perm_cyclic}). + """, + deprecated_since_version="1.6", + active_deprecations_target="deprecated-permutation-print_cyclic", + stacklevel=8, + ) + else: + perm_cyclic = self._settings.get("perm_cyclic", True) + + if perm_cyclic: + return self._print_Cycle(expr) + + if expr.size == 0: + return r"\left( \right)" + + lower = [self._print(arg) for arg in expr.array_form] + upper = [self._print(arg) for arg in range(len(lower))] + + row1 = " & ".join(upper) + row2 = " & ".join(lower) + mat = r" \\ ".join((row1, row2)) + return r"\begin{pmatrix} %s \end{pmatrix}" % mat + + + def _print_AppliedPermutation(self, expr): + perm, var = expr.args + return r"\sigma_{%s}(%s)" % (self._print(perm), self._print(var)) + + def _print_Float(self, expr): + # Based off of that in StrPrinter + dps = prec_to_dps(expr._prec) + strip = False if self._settings['full_prec'] else True + low = self._settings["min"] if "min" in self._settings else None + high = self._settings["max"] if "max" in self._settings else None + str_real = mlib_to_str(expr._mpf_, dps, strip_zeros=strip, min_fixed=low, max_fixed=high) + + # Must always have a mul symbol (as 2.5 10^{20} just looks odd) + # thus we use the number separator + separator = self._settings['mul_symbol_latex_numbers'] + + if 'e' in str_real: + (mant, exp) = str_real.split('e') + + if exp[0] == '+': + exp = exp[1:] + if self._settings['decimal_separator'] == 'comma': + mant = mant.replace('.','{,}') + + return r"%s%s10^{%s}" % (mant, separator, exp) + elif str_real == "+inf": + return r"\infty" + elif str_real == "-inf": + return r"- \infty" + else: + if self._settings['decimal_separator'] == 'comma': + str_real = str_real.replace('.','{,}') + return str_real + + def _print_Cross(self, expr): + vec1 = expr._expr1 + vec2 = expr._expr2 + return r"%s \times %s" % (self.parenthesize(vec1, PRECEDENCE['Mul']), + self.parenthesize(vec2, PRECEDENCE['Mul'])) + + def _print_Curl(self, expr): + vec = expr._expr + return r"\nabla\times %s" % self.parenthesize(vec, PRECEDENCE['Mul']) + + def _print_Divergence(self, expr): + vec = expr._expr + return r"\nabla\cdot %s" % self.parenthesize(vec, PRECEDENCE['Mul']) + + def _print_Dot(self, expr): + vec1 = expr._expr1 + vec2 = expr._expr2 + return r"%s \cdot %s" % (self.parenthesize(vec1, PRECEDENCE['Mul']), + self.parenthesize(vec2, PRECEDENCE['Mul'])) + + def _print_Gradient(self, expr): + func = expr._expr + return r"\nabla %s" % self.parenthesize(func, PRECEDENCE['Mul']) + + def _print_Laplacian(self, expr): + func = expr._expr + return r"\Delta %s" % self.parenthesize(func, PRECEDENCE['Mul']) + + def _print_Mul(self, expr: Expr): + from sympy.simplify import fraction + separator: str = self._settings['mul_symbol_latex'] + numbersep: str = self._settings['mul_symbol_latex_numbers'] + + def convert(expr) -> str: + if not expr.is_Mul: + return str(self._print(expr)) + else: + if self.order not in ('old', 'none'): + args = expr.as_ordered_factors() + else: + args = list(expr.args) + + # If there are quantities or prefixes, append them at the back. + units, nonunits = sift(args, lambda x: (hasattr(x, "_scale_factor") or hasattr(x, "is_physical_constant")) or + (isinstance(x, Pow) and + hasattr(x.base, "is_physical_constant")), binary=True) + prefixes, units = sift(units, lambda x: hasattr(x, "_scale_factor"), binary=True) + return convert_args(nonunits + prefixes + units) + + def convert_args(args) -> str: + _tex = last_term_tex = "" + + for i, term in enumerate(args): + term_tex = self._print(term) + if not (hasattr(term, "_scale_factor") or hasattr(term, "is_physical_constant")): + if self._needs_mul_brackets(term, first=(i == 0), + last=(i == len(args) - 1)): + term_tex = r"\left(%s\right)" % term_tex + + if _between_two_numbers_p[0].search(last_term_tex) and \ + _between_two_numbers_p[1].match(term_tex): + # between two numbers + _tex += numbersep + elif _tex: + _tex += separator + elif _tex: + _tex += separator + + _tex += term_tex + last_term_tex = term_tex + return _tex + + # Check for unevaluated Mul. In this case we need to make sure the + # identities are visible, multiple Rational factors are not combined + # etc so we display in a straight-forward form that fully preserves all + # args and their order. + # XXX: _print_Pow calls this routine with instances of Pow... + if isinstance(expr, Mul): + args = expr.args + if args[0] is S.One or any(isinstance(arg, Number) for arg in args[1:]): + return convert_args(args) + + include_parens = False + if expr.could_extract_minus_sign(): + expr = -expr + tex = "- " + if expr.is_Add: + tex += "(" + include_parens = True + else: + tex = "" + + numer, denom = fraction(expr, exact=True) + + if denom is S.One and Pow(1, -1, evaluate=False) not in expr.args: + # use the original expression here, since fraction() may have + # altered it when producing numer and denom + tex += convert(expr) + + else: + snumer = convert(numer) + sdenom = convert(denom) + ldenom = len(sdenom.split()) + ratio = self._settings['long_frac_ratio'] + if self._settings['fold_short_frac'] and ldenom <= 2 and \ + "^" not in sdenom: + # handle short fractions + if self._needs_mul_brackets(numer, last=False): + tex += r"\left(%s\right) / %s" % (snumer, sdenom) + else: + tex += r"%s / %s" % (snumer, sdenom) + elif ratio is not None and \ + len(snumer.split()) > ratio*ldenom: + # handle long fractions + if self._needs_mul_brackets(numer, last=True): + tex += r"\frac{1}{%s}%s\left(%s\right)" \ + % (sdenom, separator, snumer) + elif numer.is_Mul: + # split a long numerator + a = S.One + b = S.One + for x in numer.args: + if self._needs_mul_brackets(x, last=False) or \ + len(convert(a*x).split()) > ratio*ldenom or \ + (b.is_commutative is x.is_commutative is False): + b *= x + else: + a *= x + if self._needs_mul_brackets(b, last=True): + tex += r"\frac{%s}{%s}%s\left(%s\right)" \ + % (convert(a), sdenom, separator, convert(b)) + else: + tex += r"\frac{%s}{%s}%s%s" \ + % (convert(a), sdenom, separator, convert(b)) + else: + tex += r"\frac{1}{%s}%s%s" % (sdenom, separator, snumer) + else: + tex += r"\frac{%s}{%s}" % (snumer, sdenom) + + if include_parens: + tex += ")" + return tex + + def _print_AlgebraicNumber(self, expr): + if expr.is_aliased: + return self._print(expr.as_poly().as_expr()) + else: + return self._print(expr.as_expr()) + + def _print_PrimeIdeal(self, expr): + p = self._print(expr.p) + if expr.is_inert: + return rf'\left({p}\right)' + alpha = self._print(expr.alpha.as_expr()) + return rf'\left({p}, {alpha}\right)' + + def _print_Pow(self, expr: Pow): + # Treat x**Rational(1,n) as special case + if expr.exp.is_Rational: + p: int = expr.exp.p # type: ignore + q: int = expr.exp.q # type: ignore + if abs(p) == 1 and q != 1 and self._settings['root_notation']: + base = self._print(expr.base) + if q == 2: + tex = r"\sqrt{%s}" % base + elif self._settings['itex']: + tex = r"\root{%d}{%s}" % (q, base) + else: + tex = r"\sqrt[%d]{%s}" % (q, base) + if expr.exp.is_negative: + return r"\frac{1}{%s}" % tex + else: + return tex + elif self._settings['fold_frac_powers'] and q != 1: + base = self.parenthesize(expr.base, PRECEDENCE['Pow']) + # issue #12886: add parentheses for superscripts raised to powers + if expr.base.is_Symbol: + base = self.parenthesize_super(base) + if expr.base.is_Function: + return self._print(expr.base, exp="%s/%s" % (p, q)) + return r"%s^{%s/%s}" % (base, p, q) + elif expr.exp.is_negative and expr.base.is_commutative: + # special case for 1^(-x), issue 9216 + if expr.base == 1: + return r"%s^{%s}" % (expr.base, expr.exp) + # special case for (1/x)^(-y) and (-1/-x)^(-y), issue 20252 + if expr.base.is_Rational: + base_p: int = expr.base.p # type: ignore + base_q: int = expr.base.q # type: ignore + if base_p * base_q == abs(base_q): + if expr.exp == -1: + return r"\frac{1}{\frac{%s}{%s}}" % (base_p, base_q) + else: + return r"\frac{1}{(\frac{%s}{%s})^{%s}}" % (base_p, base_q, abs(expr.exp)) + # things like 1/x + return self._print_Mul(expr) + if expr.base.is_Function: + return self._print(expr.base, exp=self._print(expr.exp)) + tex = r"%s^{%s}" + return self._helper_print_standard_power(expr, tex) + + def _helper_print_standard_power(self, expr, template: str) -> str: + exp = self._print(expr.exp) + # issue #12886: add parentheses around superscripts raised + # to powers + base = self.parenthesize(expr.base, PRECEDENCE['Pow']) + if expr.base.is_Symbol: + base = self.parenthesize_super(base) + elif expr.base.is_Float: + base = r"{%s}" % base + elif (isinstance(expr.base, Derivative) + and base.startswith(r'\left(') + and re.match(r'\\left\(\\d?d?dot', base) + and base.endswith(r'\right)')): + # don't use parentheses around dotted derivative + base = base[6: -7] # remove outermost added parens + return template % (base, exp) + + def _print_UnevaluatedExpr(self, expr): + return self._print(expr.args[0]) + + def _print_Sum(self, expr): + if len(expr.limits) == 1: + tex = r"\sum_{%s=%s}^{%s} " % \ + tuple([self._print(i) for i in expr.limits[0]]) + else: + def _format_ineq(l): + return r"%s \leq %s \leq %s" % \ + tuple([self._print(s) for s in (l[1], l[0], l[2])]) + + tex = r"\sum_{\substack{%s}} " % \ + str.join('\\\\', [_format_ineq(l) for l in expr.limits]) + + if isinstance(expr.function, Add): + tex += r"\left(%s\right)" % self._print(expr.function) + else: + tex += self._print(expr.function) + + return tex + + def _print_Product(self, expr): + if len(expr.limits) == 1: + tex = r"\prod_{%s=%s}^{%s} " % \ + tuple([self._print(i) for i in expr.limits[0]]) + else: + def _format_ineq(l): + return r"%s \leq %s \leq %s" % \ + tuple([self._print(s) for s in (l[1], l[0], l[2])]) + + tex = r"\prod_{\substack{%s}} " % \ + str.join('\\\\', [_format_ineq(l) for l in expr.limits]) + + if isinstance(expr.function, Add): + tex += r"\left(%s\right)" % self._print(expr.function) + else: + tex += self._print(expr.function) + + return tex + + def _print_BasisDependent(self, expr: 'BasisDependent'): + from sympy.vector import Vector + + o1: list[str] = [] + if expr == expr.zero: + return expr.zero._latex_form + if isinstance(expr, Vector): + items = expr.separate().items() + else: + items = [(0, expr)] + + for system, vect in items: + inneritems = list(vect.components.items()) + inneritems.sort(key=lambda x: x[0].__str__()) + for k, v in inneritems: + if v == 1: + o1.append(' + ' + k._latex_form) + elif v == -1: + o1.append(' - ' + k._latex_form) + else: + arg_str = r'\left(' + self._print(v) + r'\right)' + o1.append(' + ' + arg_str + k._latex_form) + + outstr = (''.join(o1)) + if outstr[1] != '-': + outstr = outstr[3:] + else: + outstr = outstr[1:] + return outstr + + def _print_Indexed(self, expr): + tex_base = self._print(expr.base) + tex = '{'+tex_base+'}'+'_{%s}' % ','.join( + map(self._print, expr.indices)) + return tex + + def _print_IndexedBase(self, expr): + return self._print(expr.label) + + def _print_Idx(self, expr): + label = self._print(expr.label) + if expr.upper is not None: + upper = self._print(expr.upper) + if expr.lower is not None: + lower = self._print(expr.lower) + else: + lower = self._print(S.Zero) + interval = '{lower}\\mathrel{{..}}\\nobreak {upper}'.format( + lower = lower, upper = upper) + return '{{{label}}}_{{{interval}}}'.format( + label = label, interval = interval) + #if no bounds are defined this just prints the label + return label + + def _print_Derivative(self, expr): + if requires_partial(expr.expr): + diff_symbol = r'\partial' + else: + diff_symbol = self._settings["diff_operator_latex"] + + tex = "" + dim = 0 + for x, num in reversed(expr.variable_count): + dim += num + if num == 1: + tex += r"%s %s" % (diff_symbol, self._print(x)) + else: + tex += r"%s %s^{%s}" % (diff_symbol, + self.parenthesize_super(self._print(x)), + self._print(num)) + + if dim == 1: + tex = r"\frac{%s}{%s}" % (diff_symbol, tex) + else: + tex = r"\frac{%s^{%s}}{%s}" % (diff_symbol, self._print(dim), tex) + + if any(i.could_extract_minus_sign() for i in expr.args): + return r"%s %s" % (tex, self.parenthesize(expr.expr, + PRECEDENCE["Mul"], + is_neg=True, + strict=True)) + + return r"%s %s" % (tex, self.parenthesize(expr.expr, + PRECEDENCE["Mul"], + is_neg=False, + strict=True)) + + def _print_Subs(self, subs): + expr, old, new = subs.args + latex_expr = self._print(expr) + latex_old = (self._print(e) for e in old) + latex_new = (self._print(e) for e in new) + latex_subs = r'\\ '.join( + e[0] + '=' + e[1] for e in zip(latex_old, latex_new)) + return r'\left. %s \right|_{\substack{ %s }}' % (latex_expr, + latex_subs) + + def _print_Integral(self, expr): + tex, symbols = "", [] + diff_symbol = self._settings["diff_operator_latex"] + + # Only up to \iiiint exists + if len(expr.limits) <= 4 and all(len(lim) == 1 for lim in expr.limits): + # Use len(expr.limits)-1 so that syntax highlighters don't think + # \" is an escaped quote + tex = r"\i" + "i"*(len(expr.limits) - 1) + "nt" + symbols = [r"\, %s%s" % (diff_symbol, self._print(symbol[0])) + for symbol in expr.limits] + + else: + for lim in reversed(expr.limits): + symbol = lim[0] + tex += r"\int" + + if len(lim) > 1: + if self._settings['mode'] != 'inline' \ + and not self._settings['itex']: + tex += r"\limits" + + if len(lim) == 3: + tex += "_{%s}^{%s}" % (self._print(lim[1]), + self._print(lim[2])) + if len(lim) == 2: + tex += "^{%s}" % (self._print(lim[1])) + + symbols.insert(0, r"\, %s%s" % (diff_symbol, self._print(symbol))) + + return r"%s %s%s" % (tex, self.parenthesize(expr.function, + PRECEDENCE["Mul"], + is_neg=any(i.could_extract_minus_sign() for i in expr.args), + strict=True), + "".join(symbols)) + + def _print_Limit(self, expr): + e, z, z0, dir = expr.args + + tex = r"\lim_{%s \to " % self._print(z) + if str(dir) == '+-' or z0 in (S.Infinity, S.NegativeInfinity): + tex += r"%s}" % self._print(z0) + else: + tex += r"%s^%s}" % (self._print(z0), self._print(dir)) + + if isinstance(e, AssocOp): + return r"%s\left(%s\right)" % (tex, self._print(e)) + else: + return r"%s %s" % (tex, self._print(e)) + + def _hprint_Function(self, func: str) -> str: + r''' + Logic to decide how to render a function to latex + - if it is a recognized latex name, use the appropriate latex command + - if it is a single letter, excluding sub- and superscripts, just use that letter + - if it is a longer name, then put \operatorname{} around it and be + mindful of undercores in the name + ''' + func = self._deal_with_super_sub(func) + superscriptidx = func.find("^") + subscriptidx = func.find("_") + if func in accepted_latex_functions: + name = r"\%s" % func + elif len(func) == 1 or func.startswith('\\') or subscriptidx == 1 or superscriptidx == 1: + name = func + else: + if superscriptidx > 0 and subscriptidx > 0: + name = r"\operatorname{%s}%s" %( + func[:min(subscriptidx,superscriptidx)], + func[min(subscriptidx,superscriptidx):]) + elif superscriptidx > 0: + name = r"\operatorname{%s}%s" %( + func[:superscriptidx], + func[superscriptidx:]) + elif subscriptidx > 0: + name = r"\operatorname{%s}%s" %( + func[:subscriptidx], + func[subscriptidx:]) + else: + name = r"\operatorname{%s}" % func + return name + + def _print_Function(self, expr: Function, exp=None) -> str: + r''' + Render functions to LaTeX, handling functions that LaTeX knows about + e.g., sin, cos, ... by using the proper LaTeX command (\sin, \cos, ...). + For single-letter function names, render them as regular LaTeX math + symbols. For multi-letter function names that LaTeX does not know + about, (e.g., Li, sech) use \operatorname{} so that the function name + is rendered in Roman font and LaTeX handles spacing properly. + + expr is the expression involving the function + exp is an exponent + ''' + func = expr.func.__name__ + if hasattr(self, '_print_' + func) and \ + not isinstance(expr, AppliedUndef): + return getattr(self, '_print_' + func)(expr, exp) + else: + args = [str(self._print(arg)) for arg in expr.args] + # How inverse trig functions should be displayed, formats are: + # abbreviated: asin, full: arcsin, power: sin^-1 + inv_trig_style = self._settings['inv_trig_style'] + # If we are dealing with a power-style inverse trig function + inv_trig_power_case = False + # If it is applicable to fold the argument brackets + can_fold_brackets = self._settings['fold_func_brackets'] and \ + len(args) == 1 and \ + not self._needs_function_brackets(expr.args[0]) + + inv_trig_table = [ + "asin", "acos", "atan", + "acsc", "asec", "acot", + "asinh", "acosh", "atanh", + "acsch", "asech", "acoth", + ] + + # If the function is an inverse trig function, handle the style + if func in inv_trig_table: + if inv_trig_style == "abbreviated": + pass + elif inv_trig_style == "full": + func = ("ar" if func[-1] == "h" else "arc") + func[1:] + elif inv_trig_style == "power": + func = func[1:] + inv_trig_power_case = True + + # Can never fold brackets if we're raised to a power + if exp is not None: + can_fold_brackets = False + + if inv_trig_power_case: + if func in accepted_latex_functions: + name = r"\%s^{-1}" % func + else: + name = r"\operatorname{%s}^{-1}" % func + elif exp is not None: + func_tex = self._hprint_Function(func) + func_tex = self.parenthesize_super(func_tex) + name = r'%s^{%s}' % (func_tex, exp) + else: + name = self._hprint_Function(func) + + if can_fold_brackets: + if func in accepted_latex_functions: + # Wrap argument safely to avoid parse-time conflicts + # with the function name itself + name += r" {%s}" + else: + name += r"%s" + else: + name += r"{\left(%s \right)}" + + if inv_trig_power_case and exp is not None: + name += r"^{%s}" % exp + + return name % ",".join(args) + + def _print_UndefinedFunction(self, expr): + return self._hprint_Function(str(expr)) + + def _print_ElementwiseApplyFunction(self, expr): + return r"{%s}_{\circ}\left({%s}\right)" % ( + self._print(expr.function), + self._print(expr.expr), + ) + + @property + def _special_function_classes(self): + from sympy.functions.special.tensor_functions import KroneckerDelta + from sympy.functions.special.gamma_functions import gamma, lowergamma + from sympy.functions.special.beta_functions import beta + from sympy.functions.special.delta_functions import DiracDelta + from sympy.functions.special.error_functions import Chi + return {KroneckerDelta: r'\delta', + gamma: r'\Gamma', + lowergamma: r'\gamma', + beta: r'\operatorname{B}', + DiracDelta: r'\delta', + Chi: r'\operatorname{Chi}'} + + def _print_FunctionClass(self, expr): + for cls in self._special_function_classes: + if issubclass(expr, cls) and expr.__name__ == cls.__name__: + return self._special_function_classes[cls] + return self._hprint_Function(str(expr)) + + def _print_Lambda(self, expr): + symbols, expr = expr.args + + if len(symbols) == 1: + symbols = self._print(symbols[0]) + else: + symbols = self._print(tuple(symbols)) + + tex = r"\left( %s \mapsto %s \right)" % (symbols, self._print(expr)) + + return tex + + def _print_IdentityFunction(self, expr): + return r"\left( x \mapsto x \right)" + + def _hprint_variadic_function(self, expr, exp=None) -> str: + args = sorted(expr.args, key=default_sort_key) + texargs = [r"%s" % self._print(symbol) for symbol in args] + tex = r"\%s\left(%s\right)" % (str(expr.func).lower(), + ", ".join(texargs)) + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + _print_Min = _print_Max = _hprint_variadic_function + + def _print_floor(self, expr, exp=None): + tex = r"\left\lfloor{%s}\right\rfloor" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_ceiling(self, expr, exp=None): + tex = r"\left\lceil{%s}\right\rceil" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_log(self, expr, exp=None): + if not self._settings["ln_notation"]: + tex = r"\log{\left(%s \right)}" % self._print(expr.args[0]) + else: + tex = r"\ln{\left(%s \right)}" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_Abs(self, expr, exp=None): + tex = r"\left|{%s}\right|" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_re(self, expr, exp=None): + if self._settings['gothic_re_im']: + tex = r"\Re{%s}" % self.parenthesize(expr.args[0], PRECEDENCE['Atom']) + else: + tex = r"\operatorname{{re}}{{{}}}".format(self.parenthesize(expr.args[0], PRECEDENCE['Atom'])) + + return self._do_exponent(tex, exp) + + def _print_im(self, expr, exp=None): + if self._settings['gothic_re_im']: + tex = r"\Im{%s}" % self.parenthesize(expr.args[0], PRECEDENCE['Atom']) + else: + tex = r"\operatorname{{im}}{{{}}}".format(self.parenthesize(expr.args[0], PRECEDENCE['Atom'])) + + return self._do_exponent(tex, exp) + + def _print_Not(self, e): + from sympy.logic.boolalg import (Equivalent, Implies) + if isinstance(e.args[0], Equivalent): + return self._print_Equivalent(e.args[0], r"\not\Leftrightarrow") + if isinstance(e.args[0], Implies): + return self._print_Implies(e.args[0], r"\not\Rightarrow") + if (e.args[0].is_Boolean): + return r"\neg \left(%s\right)" % self._print(e.args[0]) + else: + return r"\neg %s" % self._print(e.args[0]) + + def _print_LogOp(self, args, char): + arg = args[0] + if arg.is_Boolean and not arg.is_Not: + tex = r"\left(%s\right)" % self._print(arg) + else: + tex = r"%s" % self._print(arg) + + for arg in args[1:]: + if arg.is_Boolean and not arg.is_Not: + tex += r" %s \left(%s\right)" % (char, self._print(arg)) + else: + tex += r" %s %s" % (char, self._print(arg)) + + return tex + + def _print_And(self, e): + args = sorted(e.args, key=default_sort_key) + return self._print_LogOp(args, r"\wedge") + + def _print_Or(self, e): + args = sorted(e.args, key=default_sort_key) + return self._print_LogOp(args, r"\vee") + + def _print_Xor(self, e): + args = sorted(e.args, key=default_sort_key) + return self._print_LogOp(args, r"\veebar") + + def _print_Implies(self, e, altchar=None): + return self._print_LogOp(e.args, altchar or r"\Rightarrow") + + def _print_Equivalent(self, e, altchar=None): + args = sorted(e.args, key=default_sort_key) + return self._print_LogOp(args, altchar or r"\Leftrightarrow") + + def _print_conjugate(self, expr, exp=None): + tex = r"\overline{%s}" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_polar_lift(self, expr, exp=None): + func = r"\operatorname{polar\_lift}" + arg = r"{\left(%s \right)}" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}%s" % (func, exp, arg) + else: + return r"%s%s" % (func, arg) + + def _print_ExpBase(self, expr, exp=None): + # TODO should exp_polar be printed differently? + # what about exp_polar(0), exp_polar(1)? + tex = r"e^{%s}" % self._print(expr.args[0]) + return self._do_exponent(tex, exp) + + def _print_Exp1(self, expr, exp=None): + return "e" + + def _print_elliptic_k(self, expr, exp=None): + tex = r"\left(%s\right)" % self._print(expr.args[0]) + if exp is not None: + return r"K^{%s}%s" % (exp, tex) + else: + return r"K%s" % tex + + def _print_elliptic_f(self, expr, exp=None): + tex = r"\left(%s\middle| %s\right)" % \ + (self._print(expr.args[0]), self._print(expr.args[1])) + if exp is not None: + return r"F^{%s}%s" % (exp, tex) + else: + return r"F%s" % tex + + def _print_elliptic_e(self, expr, exp=None): + if len(expr.args) == 2: + tex = r"\left(%s\middle| %s\right)" % \ + (self._print(expr.args[0]), self._print(expr.args[1])) + else: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + if exp is not None: + return r"E^{%s}%s" % (exp, tex) + else: + return r"E%s" % tex + + def _print_elliptic_pi(self, expr, exp=None): + if len(expr.args) == 3: + tex = r"\left(%s; %s\middle| %s\right)" % \ + (self._print(expr.args[0]), self._print(expr.args[1]), + self._print(expr.args[2])) + else: + tex = r"\left(%s\middle| %s\right)" % \ + (self._print(expr.args[0]), self._print(expr.args[1])) + if exp is not None: + return r"\Pi^{%s}%s" % (exp, tex) + else: + return r"\Pi%s" % tex + + def _print_beta(self, expr, exp=None): + x = expr.args[0] + # Deal with unevaluated single argument beta + y = expr.args[0] if len(expr.args) == 1 else expr.args[1] + tex = rf"\left({x}, {y}\right)" + + if exp is not None: + return r"\operatorname{B}^{%s}%s" % (exp, tex) + else: + return r"\operatorname{B}%s" % tex + + def _print_betainc(self, expr, exp=None, operator='B'): + largs = [self._print(arg) for arg in expr.args] + tex = r"\left(%s, %s\right)" % (largs[0], largs[1]) + + if exp is not None: + return r"\operatorname{%s}_{(%s, %s)}^{%s}%s" % (operator, largs[2], largs[3], exp, tex) + else: + return r"\operatorname{%s}_{(%s, %s)}%s" % (operator, largs[2], largs[3], tex) + + def _print_betainc_regularized(self, expr, exp=None): + return self._print_betainc(expr, exp, operator='I') + + def _print_uppergamma(self, expr, exp=None): + tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), + self._print(expr.args[1])) + + if exp is not None: + return r"\Gamma^{%s}%s" % (exp, tex) + else: + return r"\Gamma%s" % tex + + def _print_lowergamma(self, expr, exp=None): + tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), + self._print(expr.args[1])) + + if exp is not None: + return r"\gamma^{%s}%s" % (exp, tex) + else: + return r"\gamma%s" % tex + + def _hprint_one_arg_func(self, expr, exp=None) -> str: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}%s" % (self._print(expr.func), exp, tex) + else: + return r"%s%s" % (self._print(expr.func), tex) + + _print_gamma = _hprint_one_arg_func + + def _print_Chi(self, expr, exp=None): + tex = r"\left(%s\right)" % self._print(expr.args[0]) + + if exp is not None: + return r"\operatorname{Chi}^{%s}%s" % (exp, tex) + else: + return r"\operatorname{Chi}%s" % tex + + def _print_expint(self, expr, exp=None): + tex = r"\left(%s\right)" % self._print(expr.args[1]) + nu = self._print(expr.args[0]) + + if exp is not None: + return r"\operatorname{E}_{%s}^{%s}%s" % (nu, exp, tex) + else: + return r"\operatorname{E}_{%s}%s" % (nu, tex) + + def _print_fresnels(self, expr, exp=None): + tex = r"\left(%s\right)" % self._print(expr.args[0]) + + if exp is not None: + return r"S^{%s}%s" % (exp, tex) + else: + return r"S%s" % tex + + def _print_fresnelc(self, expr, exp=None): + tex = r"\left(%s\right)" % self._print(expr.args[0]) + + if exp is not None: + return r"C^{%s}%s" % (exp, tex) + else: + return r"C%s" % tex + + def _print_subfactorial(self, expr, exp=None): + tex = r"!%s" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) + + if exp is not None: + return r"\left(%s\right)^{%s}" % (tex, exp) + else: + return tex + + def _print_factorial(self, expr, exp=None): + tex = r"%s!" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_factorial2(self, expr, exp=None): + tex = r"%s!!" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_binomial(self, expr, exp=None): + tex = r"{\binom{%s}{%s}}" % (self._print(expr.args[0]), + self._print(expr.args[1])) + + if exp is not None: + return r"%s^{%s}" % (tex, exp) + else: + return tex + + def _print_RisingFactorial(self, expr, exp=None): + n, k = expr.args + base = r"%s" % self.parenthesize(n, PRECEDENCE['Func']) + + tex = r"{%s}^{\left(%s\right)}" % (base, self._print(k)) + + return self._do_exponent(tex, exp) + + def _print_FallingFactorial(self, expr, exp=None): + n, k = expr.args + sub = r"%s" % self.parenthesize(k, PRECEDENCE['Func']) + + tex = r"{\left(%s\right)}_{%s}" % (self._print(n), sub) + + return self._do_exponent(tex, exp) + + def _hprint_BesselBase(self, expr, exp, sym: str) -> str: + tex = r"%s" % (sym) + + need_exp = False + if exp is not None: + if tex.find('^') == -1: + tex = r"%s^{%s}" % (tex, exp) + else: + need_exp = True + + tex = r"%s_{%s}\left(%s\right)" % (tex, self._print(expr.order), + self._print(expr.argument)) + + if need_exp: + tex = self._do_exponent(tex, exp) + return tex + + def _hprint_vec(self, vec) -> str: + if not vec: + return "" + s = "" + for i in vec[:-1]: + s += "%s, " % self._print(i) + s += self._print(vec[-1]) + return s + + def _print_besselj(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'J') + + def _print_besseli(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'I') + + def _print_besselk(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'K') + + def _print_bessely(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'Y') + + def _print_yn(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'y') + + def _print_jn(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'j') + + def _print_hankel1(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'H^{(1)}') + + def _print_hankel2(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'H^{(2)}') + + def _print_hn1(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'h^{(1)}') + + def _print_hn2(self, expr, exp=None): + return self._hprint_BesselBase(expr, exp, 'h^{(2)}') + + def _hprint_airy(self, expr, exp=None, notation="") -> str: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + + if exp is not None: + return r"%s^{%s}%s" % (notation, exp, tex) + else: + return r"%s%s" % (notation, tex) + + def _hprint_airy_prime(self, expr, exp=None, notation="") -> str: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + + if exp is not None: + return r"{%s^\prime}^{%s}%s" % (notation, exp, tex) + else: + return r"%s^\prime%s" % (notation, tex) + + def _print_airyai(self, expr, exp=None): + return self._hprint_airy(expr, exp, 'Ai') + + def _print_airybi(self, expr, exp=None): + return self._hprint_airy(expr, exp, 'Bi') + + def _print_airyaiprime(self, expr, exp=None): + return self._hprint_airy_prime(expr, exp, 'Ai') + + def _print_airybiprime(self, expr, exp=None): + return self._hprint_airy_prime(expr, exp, 'Bi') + + def _print_hyper(self, expr, exp=None): + tex = r"{{}_{%s}F_{%s}\left(\begin{matrix} %s \\ %s \end{matrix}" \ + r"\middle| {%s} \right)}" % \ + (self._print(len(expr.ap)), self._print(len(expr.bq)), + self._hprint_vec(expr.ap), self._hprint_vec(expr.bq), + self._print(expr.argument)) + + if exp is not None: + tex = r"{%s}^{%s}" % (tex, exp) + return tex + + def _print_meijerg(self, expr, exp=None): + tex = r"{G_{%s, %s}^{%s, %s}\left(\begin{matrix} %s & %s \\" \ + r"%s & %s \end{matrix} \middle| {%s} \right)}" % \ + (self._print(len(expr.ap)), self._print(len(expr.bq)), + self._print(len(expr.bm)), self._print(len(expr.an)), + self._hprint_vec(expr.an), self._hprint_vec(expr.aother), + self._hprint_vec(expr.bm), self._hprint_vec(expr.bother), + self._print(expr.argument)) + + if exp is not None: + tex = r"{%s}^{%s}" % (tex, exp) + return tex + + def _print_dirichlet_eta(self, expr, exp=None): + tex = r"\left(%s\right)" % self._print(expr.args[0]) + if exp is not None: + return r"\eta^{%s}%s" % (exp, tex) + return r"\eta%s" % tex + + def _print_zeta(self, expr, exp=None): + if len(expr.args) == 2: + tex = r"\left(%s, %s\right)" % tuple(map(self._print, expr.args)) + else: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + if exp is not None: + return r"\zeta^{%s}%s" % (exp, tex) + return r"\zeta%s" % tex + + def _print_stieltjes(self, expr, exp=None): + if len(expr.args) == 2: + tex = r"_{%s}\left(%s\right)" % tuple(map(self._print, expr.args)) + else: + tex = r"_{%s}" % self._print(expr.args[0]) + if exp is not None: + return r"\gamma%s^{%s}" % (tex, exp) + return r"\gamma%s" % tex + + def _print_lerchphi(self, expr, exp=None): + tex = r"\left(%s, %s, %s\right)" % tuple(map(self._print, expr.args)) + if exp is None: + return r"\Phi%s" % tex + return r"\Phi^{%s}%s" % (exp, tex) + + def _print_polylog(self, expr, exp=None): + s, z = map(self._print, expr.args) + tex = r"\left(%s\right)" % z + if exp is None: + return r"\operatorname{Li}_{%s}%s" % (s, tex) + return r"\operatorname{Li}_{%s}^{%s}%s" % (s, exp, tex) + + def _print_jacobi(self, expr, exp=None): + n, a, b, x = map(self._print, expr.args) + tex = r"P_{%s}^{\left(%s,%s\right)}\left(%s\right)" % (n, a, b, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_gegenbauer(self, expr, exp=None): + n, a, x = map(self._print, expr.args) + tex = r"C_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_chebyshevt(self, expr, exp=None): + n, x = map(self._print, expr.args) + tex = r"T_{%s}\left(%s\right)" % (n, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_chebyshevu(self, expr, exp=None): + n, x = map(self._print, expr.args) + tex = r"U_{%s}\left(%s\right)" % (n, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_legendre(self, expr, exp=None): + n, x = map(self._print, expr.args) + tex = r"P_{%s}\left(%s\right)" % (n, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_assoc_legendre(self, expr, exp=None): + n, a, x = map(self._print, expr.args) + tex = r"P_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_hermite(self, expr, exp=None): + n, x = map(self._print, expr.args) + tex = r"H_{%s}\left(%s\right)" % (n, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_laguerre(self, expr, exp=None): + n, x = map(self._print, expr.args) + tex = r"L_{%s}\left(%s\right)" % (n, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_assoc_laguerre(self, expr, exp=None): + n, a, x = map(self._print, expr.args) + tex = r"L_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_Ynm(self, expr, exp=None): + n, m, theta, phi = map(self._print, expr.args) + tex = r"Y_{%s}^{%s}\left(%s,%s\right)" % (n, m, theta, phi) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def _print_Znm(self, expr, exp=None): + n, m, theta, phi = map(self._print, expr.args) + tex = r"Z_{%s}^{%s}\left(%s,%s\right)" % (n, m, theta, phi) + if exp is not None: + tex = r"\left(" + tex + r"\right)^{%s}" % (exp) + return tex + + def __print_mathieu_functions(self, character, args, prime=False, exp=None): + a, q, z = map(self._print, args) + sup = r"^{\prime}" if prime else "" + exp = "" if not exp else "^{%s}" % exp + return r"%s%s\left(%s, %s, %s\right)%s" % (character, sup, a, q, z, exp) + + def _print_mathieuc(self, expr, exp=None): + return self.__print_mathieu_functions("C", expr.args, exp=exp) + + def _print_mathieus(self, expr, exp=None): + return self.__print_mathieu_functions("S", expr.args, exp=exp) + + def _print_mathieucprime(self, expr, exp=None): + return self.__print_mathieu_functions("C", expr.args, prime=True, exp=exp) + + def _print_mathieusprime(self, expr, exp=None): + return self.__print_mathieu_functions("S", expr.args, prime=True, exp=exp) + + def _print_Rational(self, expr): + if expr.q != 1: + sign = "" + p = expr.p + if expr.p < 0: + sign = "- " + p = -p + if self._settings['fold_short_frac']: + return r"%s%d / %d" % (sign, p, expr.q) + return r"%s\frac{%d}{%d}" % (sign, p, expr.q) + else: + return self._print(expr.p) + + def _print_Order(self, expr): + s = self._print(expr.expr) + if expr.point and any(p != S.Zero for p in expr.point) or \ + len(expr.variables) > 1: + s += '; ' + if len(expr.variables) > 1: + s += self._print(expr.variables) + elif expr.variables: + s += self._print(expr.variables[0]) + s += r'\rightarrow ' + if len(expr.point) > 1: + s += self._print(expr.point) + else: + s += self._print(expr.point[0]) + return r"O\left(%s\right)" % s + + def _print_Symbol(self, expr: Symbol, style='plain'): + name: str = self._settings['symbol_names'].get(expr) + if name is not None: + return name + + return self._deal_with_super_sub(expr.name, style=style) + + _print_RandomSymbol = _print_Symbol + + def _split_super_sub(self, name: str) -> tuple[str, list[str], list[str]]: + if name is None or '{' in name: + return (name, [], []) + elif self._settings["disable_split_super_sub"]: + name, supers, subs = (name.replace('_', '\\_').replace('^', '\\^'), [], []) + else: + name, supers, subs = split_super_sub(name) + name = translate(name) + supers = [translate(sup) for sup in supers] + subs = [translate(sub) for sub in subs] + return (name, supers, subs) + + def _deal_with_super_sub(self, string: str, style='plain') -> str: + name, supers, subs = self._split_super_sub(string) + + # apply the style only to the name + if style == 'bold': + name = "\\mathbf{{{}}}".format(name) + + # glue all items together: + if supers: + name += "^{%s}" % " ".join(supers) + if subs: + name += "_{%s}" % " ".join(subs) + + return name + + def _print_Relational(self, expr): + if self._settings['itex']: + gt = r"\gt" + lt = r"\lt" + else: + gt = ">" + lt = "<" + + charmap = { + "==": "=", + ">": gt, + "<": lt, + ">=": r"\geq", + "<=": r"\leq", + "!=": r"\neq", + } + + return "%s %s %s" % (self._print(expr.lhs), + charmap[expr.rel_op], self._print(expr.rhs)) + + def _print_Piecewise(self, expr): + ecpairs = [r"%s & \text{for}\: %s" % (self._print(e), self._print(c)) + for e, c in expr.args[:-1]] + if expr.args[-1].cond == true: + ecpairs.append(r"%s & \text{otherwise}" % + self._print(expr.args[-1].expr)) + else: + ecpairs.append(r"%s & \text{for}\: %s" % + (self._print(expr.args[-1].expr), + self._print(expr.args[-1].cond))) + tex = r"\begin{cases} %s \end{cases}" + return tex % r" \\".join(ecpairs) + + def _print_matrix_contents(self, expr): + lines = [] + + for line in range(expr.rows): # horrible, should be 'rows' + lines.append(" & ".join([self._print(i) for i in expr[line, :]])) + + mat_str = self._settings['mat_str'] + if mat_str is None: + if self._settings['mode'] == 'inline': + mat_str = 'smallmatrix' + else: + if (expr.cols <= 10) is True: + mat_str = 'matrix' + else: + mat_str = 'array' + + out_str = r'\begin{%MATSTR%}%s\end{%MATSTR%}' + out_str = out_str.replace('%MATSTR%', mat_str) + if mat_str == 'array': + out_str = out_str.replace('%s', '{' + 'c'*expr.cols + '}%s') + return out_str % r"\\".join(lines) + + def _print_MatrixBase(self, expr): + out_str = self._print_matrix_contents(expr) + if self._settings['mat_delim']: + left_delim = self._settings['mat_delim'] + right_delim = self._delim_dict[left_delim] + out_str = r'\left' + left_delim + out_str + \ + r'\right' + right_delim + return out_str + + def _print_MatrixElement(self, expr): + matrix_part = self.parenthesize(expr.parent, PRECEDENCE['Atom'], strict=True) + index_part = f"{self._print(expr.i)},{self._print(expr.j)}" + return f"{{{matrix_part}}}_{{{index_part}}}" + + def _print_MatrixSlice(self, expr): + def latexslice(x, dim): + x = list(x) + if x[2] == 1: + del x[2] + if x[0] == 0: + x[0] = None + if x[1] == dim: + x[1] = None + return ':'.join(self._print(xi) if xi is not None else '' for xi in x) + return (self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) + r'\left[' + + latexslice(expr.rowslice, expr.parent.rows) + ', ' + + latexslice(expr.colslice, expr.parent.cols) + r'\right]') + + def _print_BlockMatrix(self, expr): + return self._print(expr.blocks) + + def _print_Transpose(self, expr): + mat = expr.arg + from sympy.matrices import MatrixSymbol, BlockMatrix + if (not isinstance(mat, MatrixSymbol) and + not isinstance(mat, BlockMatrix) and mat.is_MatrixExpr): + return r"\left(%s\right)^{T}" % self._print(mat) + else: + s = self.parenthesize(mat, precedence_traditional(expr), True) + if '^' in s: + return r"\left(%s\right)^{T}" % s + else: + return "%s^{T}" % s + + def _print_Trace(self, expr): + mat = expr.arg + return r"\operatorname{tr}\left(%s \right)" % self._print(mat) + + def _print_Adjoint(self, expr): + style_to_latex = { + "dagger" : r"\dagger", + "star" : r"\ast", + "hermitian": r"\mathsf{H}" + } + adjoint_style = style_to_latex.get(self._settings["adjoint_style"], r"\dagger") + mat = expr.arg + from sympy.matrices import MatrixSymbol, BlockMatrix + if (not isinstance(mat, MatrixSymbol) and + not isinstance(mat, BlockMatrix) and mat.is_MatrixExpr): + return r"\left(%s\right)^{%s}" % (self._print(mat), adjoint_style) + else: + s = self.parenthesize(mat, precedence_traditional(expr), True) + if '^' in s: + return r"\left(%s\right)^{%s}" % (s, adjoint_style) + else: + return r"%s^{%s}" % (s, adjoint_style) + + def _print_MatMul(self, expr): + from sympy import MatMul + + # Parenthesize nested MatMul but not other types of Mul objects: + parens = lambda x: self._print(x) if isinstance(x, Mul) and not isinstance(x, MatMul) else \ + self.parenthesize(x, precedence_traditional(expr), False) + + args = list(expr.args) + if expr.could_extract_minus_sign(): + if args[0] == -1: + args = args[1:] + else: + args[0] = -args[0] + return '- ' + ' '.join(map(parens, args)) + else: + return ' '.join(map(parens, args)) + + def _print_DotProduct(self, expr): + level = precedence_traditional(expr) + left, right = expr.args + return rf"{self.parenthesize(left, level)} \cdot {self.parenthesize(right, level)}" + + def _print_Determinant(self, expr): + mat = expr.arg + if mat.is_MatrixExpr: + from sympy.matrices.expressions.blockmatrix import BlockMatrix + if isinstance(mat, BlockMatrix): + return r"\left|{%s}\right|" % self._print_matrix_contents(mat.blocks) + return r"\left|{%s}\right|" % self._print(mat) + return r"\left|{%s}\right|" % self._print_matrix_contents(mat) + + + def _print_Mod(self, expr, exp=None): + if exp is not None: + return r'\left(%s \bmod %s\right)^{%s}' % \ + (self.parenthesize(expr.args[0], PRECEDENCE['Mul'], + strict=True), + self.parenthesize(expr.args[1], PRECEDENCE['Mul'], + strict=True), + exp) + return r'%s \bmod %s' % (self.parenthesize(expr.args[0], + PRECEDENCE['Mul'], + strict=True), + self.parenthesize(expr.args[1], + PRECEDENCE['Mul'], + strict=True)) + + def _print_HadamardProduct(self, expr): + args = expr.args + prec = PRECEDENCE['Pow'] + parens = self.parenthesize + + return r' \circ '.join( + (parens(arg, prec, strict=True) for arg in args)) + + def _print_HadamardPower(self, expr): + if precedence_traditional(expr.exp) < PRECEDENCE["Mul"]: + template = r"%s^{\circ \left({%s}\right)}" + else: + template = r"%s^{\circ {%s}}" + return self._helper_print_standard_power(expr, template) + + def _print_KroneckerProduct(self, expr): + args = expr.args + prec = PRECEDENCE['Pow'] + parens = self.parenthesize + + return r' \otimes '.join( + (parens(arg, prec, strict=True) for arg in args)) + + def _print_MatPow(self, expr): + base, exp = expr.base, expr.exp + from sympy.matrices import MatrixSymbol + if not isinstance(base, MatrixSymbol) and base.is_MatrixExpr: + return "\\left(%s\\right)^{%s}" % (self._print(base), + self._print(exp)) + else: + base_str = self._print(base) + if '^' in base_str: + return r"\left(%s\right)^{%s}" % (base_str, self._print(exp)) + else: + return "%s^{%s}" % (base_str, self._print(exp)) + + def _print_MatrixSymbol(self, expr): + return self._print_Symbol(expr, style=self._settings[ + 'mat_symbol_style']) + + def _print_ZeroMatrix(self, Z): + return "0" if self._settings[ + 'mat_symbol_style'] == 'plain' else r"\mathbf{0}" + + def _print_OneMatrix(self, O): + return "1" if self._settings[ + 'mat_symbol_style'] == 'plain' else r"\mathbf{1}" + + def _print_Identity(self, I): + return r"\mathbb{I}" if self._settings[ + 'mat_symbol_style'] == 'plain' else r"\mathbf{I}" + + def _print_PermutationMatrix(self, P): + perm_str = self._print(P.args[0]) + return "P_{%s}" % perm_str + + def _print_NDimArray(self, expr: NDimArray): + + if expr.rank() == 0: + return self._print(expr[()]) + + mat_str = self._settings['mat_str'] + if mat_str is None: + if self._settings['mode'] == 'inline': + mat_str = 'smallmatrix' + else: + if (expr.rank() == 0) or (expr.shape[-1] <= 10): + mat_str = 'matrix' + else: + mat_str = 'array' + block_str = r'\begin{%MATSTR%}%s\end{%MATSTR%}' + block_str = block_str.replace('%MATSTR%', mat_str) + if mat_str == 'array': + block_str = block_str.replace('%s', '{' + 'c'*expr.shape[0] + '}%s') + + if self._settings['mat_delim']: + left_delim: str = self._settings['mat_delim'] + right_delim = self._delim_dict[left_delim] + block_str = r'\left' + left_delim + block_str + \ + r'\right' + right_delim + + if expr.rank() == 0: + return block_str % "" + + level_str: list[list[str]] = [[] for i in range(expr.rank() + 1)] + shape_ranges = [list(range(i)) for i in expr.shape] + for outer_i in itertools.product(*shape_ranges): + level_str[-1].append(self._print(expr[outer_i])) + even = True + for back_outer_i in range(expr.rank()-1, -1, -1): + if len(level_str[back_outer_i+1]) < expr.shape[back_outer_i]: + break + if even: + level_str[back_outer_i].append( + r" & ".join(level_str[back_outer_i+1])) + else: + level_str[back_outer_i].append( + block_str % (r"\\".join(level_str[back_outer_i+1]))) + if len(level_str[back_outer_i+1]) == 1: + level_str[back_outer_i][-1] = r"\left[" + \ + level_str[back_outer_i][-1] + r"\right]" + even = not even + level_str[back_outer_i+1] = [] + + out_str = level_str[0][0] + + if expr.rank() % 2 == 1: + out_str = block_str % out_str + + return out_str + + def _printer_tensor_indices(self, name, indices, index_map: dict): + out_str = self._print(name) + last_valence = None + prev_map = None + for index in indices: + new_valence = index.is_up + if ((index in index_map) or prev_map) and \ + last_valence == new_valence: + out_str += "," + if last_valence != new_valence: + if last_valence is not None: + out_str += "}" + if index.is_up: + out_str += "{}^{" + else: + out_str += "{}_{" + out_str += self._print(index.args[0]) + if index in index_map: + out_str += "=" + out_str += self._print(index_map[index]) + prev_map = True + else: + prev_map = False + last_valence = new_valence + if last_valence is not None: + out_str += "}" + return out_str + + def _print_Tensor(self, expr): + name = expr.args[0].args[0] + indices = expr.get_indices() + return self._printer_tensor_indices(name, indices, {}) + + def _print_TensorElement(self, expr): + name = expr.expr.args[0].args[0] + indices = expr.expr.get_indices() + index_map = expr.index_map + return self._printer_tensor_indices(name, indices, index_map) + + def _print_TensMul(self, expr): + # prints expressions like "A(a)", "3*A(a)", "(1+x)*A(a)" + sign, args = expr._get_args_for_traditional_printer() + return sign + "".join( + [self.parenthesize(arg, precedence(expr)) for arg in args] + ) + + def _print_TensAdd(self, expr): + a = [] + args = expr.args + for x in args: + a.append(self.parenthesize(x, precedence(expr))) + a.sort() + s = ' + '.join(a) + s = s.replace('+ -', '- ') + return s + + def _print_TensorIndex(self, expr): + return "{}%s{%s}" % ( + "^" if expr.is_up else "_", + self._print(expr.args[0]) + ) + + def _print_PartialDerivative(self, expr): + if len(expr.variables) == 1: + return r"\frac{\partial}{\partial {%s}}{%s}" % ( + self._print(expr.variables[0]), + self.parenthesize(expr.expr, PRECEDENCE["Mul"], False) + ) + else: + return r"\frac{\partial^{%s}}{%s}{%s}" % ( + len(expr.variables), + " ".join([r"\partial {%s}" % self._print(i) for i in expr.variables]), + self.parenthesize(expr.expr, PRECEDENCE["Mul"], False) + ) + + def _print_ArraySymbol(self, expr): + return self._print(expr.name) + + def _print_ArrayElement(self, expr): + return "{{%s}_{%s}}" % ( + self.parenthesize(expr.name, PRECEDENCE["Func"], True), + ", ".join([f"{self._print(i)}" for i in expr.indices])) + + def _print_UniversalSet(self, expr): + return r"\mathbb{U}" + + def _print_frac(self, expr, exp=None): + if exp is None: + return r"\operatorname{frac}{\left(%s\right)}" % self._print(expr.args[0]) + else: + return r"\operatorname{frac}{\left(%s\right)}^{%s}" % ( + self._print(expr.args[0]), exp) + + def _print_tuple(self, expr): + if self._settings['decimal_separator'] == 'comma': + sep = ";" + elif self._settings['decimal_separator'] == 'period': + sep = "," + else: + raise ValueError('Unknown Decimal Separator') + + if len(expr) == 1: + # 1-tuple needs a trailing separator + return self._add_parens_lspace(self._print(expr[0]) + sep) + else: + return self._add_parens_lspace( + (sep + r" \ ").join([self._print(i) for i in expr])) + + def _print_TensorProduct(self, expr): + elements = [self._print(a) for a in expr.args] + return r' \otimes '.join(elements) + + def _print_WedgeProduct(self, expr): + elements = [self._print(a) for a in expr.args] + return r' \wedge '.join(elements) + + def _print_Tuple(self, expr): + return self._print_tuple(expr) + + def _print_list(self, expr): + if self._settings['decimal_separator'] == 'comma': + return r"\left[ %s\right]" % \ + r"; \ ".join([self._print(i) for i in expr]) + elif self._settings['decimal_separator'] == 'period': + return r"\left[ %s\right]" % \ + r", \ ".join([self._print(i) for i in expr]) + else: + raise ValueError('Unknown Decimal Separator') + + + def _print_dict(self, d): + keys = sorted(d.keys(), key=default_sort_key) + items = [] + + for key in keys: + val = d[key] + items.append("%s : %s" % (self._print(key), self._print(val))) + + return r"\left\{ %s\right\}" % r", \ ".join(items) + + def _print_Dict(self, expr): + return self._print_dict(expr) + + def _print_DiracDelta(self, expr, exp=None): + if len(expr.args) == 1 or expr.args[1] == 0: + tex = r"\delta\left(%s\right)" % self._print(expr.args[0]) + else: + tex = r"\delta^{\left( %s \right)}\left( %s \right)" % ( + self._print(expr.args[1]), self._print(expr.args[0])) + if exp: + tex = r"\left(%s\right)^{%s}" % (tex, exp) + return tex + + def _print_SingularityFunction(self, expr, exp=None): + shift = self._print(expr.args[0] - expr.args[1]) + power = self._print(expr.args[2]) + tex = r"{\left\langle %s \right\rangle}^{%s}" % (shift, power) + if exp is not None: + tex = r"{\left({\langle %s \rangle}^{%s}\right)}^{%s}" % (shift, power, exp) + return tex + + def _print_Heaviside(self, expr, exp=None): + pargs = ', '.join(self._print(arg) for arg in expr.pargs) + tex = r"\theta\left(%s\right)" % pargs + if exp: + tex = r"\left(%s\right)^{%s}" % (tex, exp) + return tex + + def _print_KroneckerDelta(self, expr, exp=None): + i = self._print(expr.args[0]) + j = self._print(expr.args[1]) + if expr.args[0].is_Atom and expr.args[1].is_Atom: + tex = r'\delta_{%s %s}' % (i, j) + else: + tex = r'\delta_{%s, %s}' % (i, j) + if exp is not None: + tex = r'\left(%s\right)^{%s}' % (tex, exp) + return tex + + def _print_LeviCivita(self, expr, exp=None): + indices = map(self._print, expr.args) + if all(x.is_Atom for x in expr.args): + tex = r'\varepsilon_{%s}' % " ".join(indices) + else: + tex = r'\varepsilon_{%s}' % ", ".join(indices) + if exp: + tex = r'\left(%s\right)^{%s}' % (tex, exp) + return tex + + def _print_RandomDomain(self, d): + if hasattr(d, 'as_boolean'): + return '\\text{Domain: }' + self._print(d.as_boolean()) + elif hasattr(d, 'set'): + return ('\\text{Domain: }' + self._print(d.symbols) + ' \\in ' + + self._print(d.set)) + elif hasattr(d, 'symbols'): + return '\\text{Domain on }' + self._print(d.symbols) + else: + return self._print(None) + + def _print_FiniteSet(self, s): + items = sorted(s.args, key=default_sort_key) + return self._print_set(items) + + def _print_set(self, s): + items = sorted(s, key=default_sort_key) + if self._settings['decimal_separator'] == 'comma': + items = "; ".join(map(self._print, items)) + elif self._settings['decimal_separator'] == 'period': + items = ", ".join(map(self._print, items)) + else: + raise ValueError('Unknown Decimal Separator') + return r"\left\{%s\right\}" % items + + + _print_frozenset = _print_set + + def _print_Range(self, s): + def _print_symbolic_range(): + # Symbolic Range that cannot be resolved + if s.args[0] == 0: + if s.args[2] == 1: + cont = self._print(s.args[1]) + else: + cont = ", ".join(self._print(arg) for arg in s.args) + else: + if s.args[2] == 1: + cont = ", ".join(self._print(arg) for arg in s.args[:2]) + else: + cont = ", ".join(self._print(arg) for arg in s.args) + + return(f"\\text{{Range}}\\left({cont}\\right)") + + dots = object() + + if s.start.is_infinite and s.stop.is_infinite: + if s.step.is_positive: + printset = dots, -1, 0, 1, dots + else: + printset = dots, 1, 0, -1, dots + elif s.start.is_infinite: + printset = dots, s[-1] - s.step, s[-1] + elif s.stop.is_infinite: + it = iter(s) + printset = next(it), next(it), dots + elif s.is_empty is not None: + if (s.size < 4) == True: + printset = tuple(s) + elif s.is_iterable: + it = iter(s) + printset = next(it), next(it), dots, s[-1] + else: + return _print_symbolic_range() + else: + return _print_symbolic_range() + return (r"\left\{" + + r", ".join(self._print(el) if el is not dots else r'\ldots' for el in printset) + + r"\right\}") + + def __print_number_polynomial(self, expr, letter, exp=None): + if len(expr.args) == 2: + if exp is not None: + return r"%s_{%s}^{%s}\left(%s\right)" % (letter, + self._print(expr.args[0]), exp, + self._print(expr.args[1])) + return r"%s_{%s}\left(%s\right)" % (letter, + self._print(expr.args[0]), self._print(expr.args[1])) + + tex = r"%s_{%s}" % (letter, self._print(expr.args[0])) + if exp is not None: + tex = r"%s^{%s}" % (tex, exp) + return tex + + def _print_bernoulli(self, expr, exp=None): + return self.__print_number_polynomial(expr, "B", exp) + + def _print_genocchi(self, expr, exp=None): + return self.__print_number_polynomial(expr, "G", exp) + + def _print_bell(self, expr, exp=None): + if len(expr.args) == 3: + tex1 = r"B_{%s, %s}" % (self._print(expr.args[0]), + self._print(expr.args[1])) + tex2 = r"\left(%s\right)" % r", ".join(self._print(el) for + el in expr.args[2]) + if exp is not None: + tex = r"%s^{%s}%s" % (tex1, exp, tex2) + else: + tex = tex1 + tex2 + return tex + return self.__print_number_polynomial(expr, "B", exp) + + def _print_fibonacci(self, expr, exp=None): + return self.__print_number_polynomial(expr, "F", exp) + + def _print_lucas(self, expr, exp=None): + tex = r"L_{%s}" % self._print(expr.args[0]) + if exp is not None: + tex = r"%s^{%s}" % (tex, exp) + return tex + + def _print_tribonacci(self, expr, exp=None): + return self.__print_number_polynomial(expr, "T", exp) + + def _print_mobius(self, expr, exp=None): + if exp is None: + return r'\mu\left(%s\right)' % self._print(expr.args[0]) + return r'\mu^{%s}\left(%s\right)' % (exp, self._print(expr.args[0])) + + def _print_SeqFormula(self, s): + dots = object() + if len(s.start.free_symbols) > 0 or len(s.stop.free_symbols) > 0: + return r"\left\{%s\right\}_{%s=%s}^{%s}" % ( + self._print(s.formula), + self._print(s.variables[0]), + self._print(s.start), + self._print(s.stop) + ) + if s.start is S.NegativeInfinity: + stop = s.stop + printset = (dots, s.coeff(stop - 3), s.coeff(stop - 2), + s.coeff(stop - 1), s.coeff(stop)) + elif s.stop is S.Infinity or s.length > 4: + printset = s[:4] + printset.append(dots) + else: + printset = tuple(s) + + return (r"\left[" + + r", ".join(self._print(el) if el is not dots else r'\ldots' for el in printset) + + r"\right]") + + _print_SeqPer = _print_SeqFormula + _print_SeqAdd = _print_SeqFormula + _print_SeqMul = _print_SeqFormula + + def _print_Interval(self, i): + if i.start == i.end: + return r"\left\{%s\right\}" % self._print(i.start) + + else: + if i.left_open: + left = '(' + else: + left = '[' + + if i.right_open: + right = ')' + else: + right = ']' + + return r"\left%s%s, %s\right%s" % \ + (left, self._print(i.start), self._print(i.end), right) + + def _print_AccumulationBounds(self, i): + return r"\left\langle %s, %s\right\rangle" % \ + (self._print(i.min), self._print(i.max)) + + def _print_Union(self, u): + prec = precedence_traditional(u) + args_str = [self.parenthesize(i, prec) for i in u.args] + return r" \cup ".join(args_str) + + def _print_Complement(self, u): + prec = precedence_traditional(u) + args_str = [self.parenthesize(i, prec) for i in u.args] + return r" \setminus ".join(args_str) + + def _print_Intersection(self, u): + prec = precedence_traditional(u) + args_str = [self.parenthesize(i, prec) for i in u.args] + return r" \cap ".join(args_str) + + def _print_SymmetricDifference(self, u): + prec = precedence_traditional(u) + args_str = [self.parenthesize(i, prec) for i in u.args] + return r" \triangle ".join(args_str) + + def _print_ProductSet(self, p): + prec = precedence_traditional(p) + if len(p.sets) >= 1 and not has_variety(p.sets): + return self.parenthesize(p.sets[0], prec) + "^{%d}" % len(p.sets) + return r" \times ".join( + self.parenthesize(set, prec) for set in p.sets) + + def _print_EmptySet(self, e): + return r"\emptyset" + + def _print_Naturals(self, n): + return r"\mathbb{N}" + + def _print_Naturals0(self, n): + return r"\mathbb{N}_0" + + def _print_Integers(self, i): + return r"\mathbb{Z}" + + def _print_Rationals(self, i): + return r"\mathbb{Q}" + + def _print_Reals(self, i): + return r"\mathbb{R}" + + def _print_Complexes(self, i): + return r"\mathbb{C}" + + def _print_ImageSet(self, s): + expr = s.lamda.expr + sig = s.lamda.signature + xys = ((self._print(x), self._print(y)) for x, y in zip(sig, s.base_sets)) + xinys = r", ".join(r"%s \in %s" % xy for xy in xys) + return r"\left\{%s\; \middle|\; %s\right\}" % (self._print(expr), xinys) + + def _print_ConditionSet(self, s): + vars_print = ', '.join([self._print(var) for var in Tuple(s.sym)]) + if s.base_set is S.UniversalSet: + return r"\left\{%s\; \middle|\; %s \right\}" % \ + (vars_print, self._print(s.condition)) + + return r"\left\{%s\; \middle|\; %s \in %s \wedge %s \right\}" % ( + vars_print, + vars_print, + self._print(s.base_set), + self._print(s.condition)) + + def _print_PowerSet(self, expr): + arg_print = self._print(expr.args[0]) + return r"\mathcal{{P}}\left({}\right)".format(arg_print) + + def _print_ComplexRegion(self, s): + vars_print = ', '.join([self._print(var) for var in s.variables]) + return r"\left\{%s\; \middle|\; %s \in %s \right\}" % ( + self._print(s.expr), + vars_print, + self._print(s.sets)) + + def _print_Contains(self, e): + return r"%s \in %s" % tuple(self._print(a) for a in e.args) + + def _print_FourierSeries(self, s): + if s.an.formula is S.Zero and s.bn.formula is S.Zero: + return self._print(s.a0) + return self._print_Add(s.truncate()) + r' + \ldots' + + def _print_FormalPowerSeries(self, s): + return self._print_Add(s.infinite) + + def _print_FiniteField(self, expr): + return r"\mathbb{F}_{%s}" % expr.mod + + def _print_IntegerRing(self, expr): + return r"\mathbb{Z}" + + def _print_RationalField(self, expr): + return r"\mathbb{Q}" + + def _print_RealField(self, expr): + return r"\mathbb{R}" + + def _print_ComplexField(self, expr): + return r"\mathbb{C}" + + def _print_PolynomialRing(self, expr): + domain = self._print(expr.domain) + symbols = ", ".join(map(self._print, expr.symbols)) + return r"%s\left[%s\right]" % (domain, symbols) + + def _print_FractionField(self, expr): + domain = self._print(expr.domain) + symbols = ", ".join(map(self._print, expr.symbols)) + return r"%s\left(%s\right)" % (domain, symbols) + + def _print_PolynomialRingBase(self, expr): + domain = self._print(expr.domain) + symbols = ", ".join(map(self._print, expr.symbols)) + inv = "" + if not expr.is_Poly: + inv = r"S_<^{-1}" + return r"%s%s\left[%s\right]" % (inv, domain, symbols) + + def _print_Poly(self, poly): + cls = poly.__class__.__name__ + terms = [] + for monom, coeff in poly.terms(): + s_monom = '' + for i, exp in enumerate(monom): + if exp > 0: + if exp == 1: + s_monom += self._print(poly.gens[i]) + else: + s_monom += self._print(pow(poly.gens[i], exp)) + + if coeff.is_Add: + if s_monom: + s_coeff = r"\left(%s\right)" % self._print(coeff) + else: + s_coeff = self._print(coeff) + else: + if s_monom: + if coeff is S.One: + terms.extend(['+', s_monom]) + continue + + if coeff is S.NegativeOne: + terms.extend(['-', s_monom]) + continue + + s_coeff = self._print(coeff) + + if not s_monom: + s_term = s_coeff + else: + s_term = s_coeff + " " + s_monom + + if s_term.startswith('-'): + terms.extend(['-', s_term[1:]]) + else: + terms.extend(['+', s_term]) + + if terms[0] in ('-', '+'): + modifier = terms.pop(0) + + if modifier == '-': + terms[0] = '-' + terms[0] + + expr = ' '.join(terms) + gens = list(map(self._print, poly.gens)) + domain = "domain=%s" % self._print(poly.get_domain()) + + args = ", ".join([expr] + gens + [domain]) + if cls in accepted_latex_functions: + tex = r"\%s {\left(%s \right)}" % (cls, args) + else: + tex = r"\operatorname{%s}{\left( %s \right)}" % (cls, args) + + return tex + + def _print_ComplexRootOf(self, root): + cls = root.__class__.__name__ + if cls == "ComplexRootOf": + cls = "CRootOf" + expr = self._print(root.expr) + index = root.index + if cls in accepted_latex_functions: + return r"\%s {\left(%s, %d\right)}" % (cls, expr, index) + else: + return r"\operatorname{%s} {\left(%s, %d\right)}" % (cls, expr, + index) + + def _print_RootSum(self, expr): + cls = expr.__class__.__name__ + args = [self._print(expr.expr)] + + if expr.fun is not S.IdentityFunction: + args.append(self._print(expr.fun)) + + if cls in accepted_latex_functions: + return r"\%s {\left(%s\right)}" % (cls, ", ".join(args)) + else: + return r"\operatorname{%s} {\left(%s\right)}" % (cls, + ", ".join(args)) + + def _print_OrdinalOmega(self, expr): + return r"\omega" + + def _print_OmegaPower(self, expr): + exp, mul = expr.args + if mul != 1: + if exp != 1: + return r"{} \omega^{{{}}}".format(mul, exp) + else: + return r"{} \omega".format(mul) + else: + if exp != 1: + return r"\omega^{{{}}}".format(exp) + else: + return r"\omega" + + def _print_Ordinal(self, expr): + return " + ".join([self._print(arg) for arg in expr.args]) + + def _print_PolyElement(self, poly): + mul_symbol = self._settings['mul_symbol_latex'] + return poly.str(self, PRECEDENCE, "{%s}^{%d}", mul_symbol) + + def _print_FracElement(self, frac): + if frac.denom == 1: + return self._print(frac.numer) + else: + numer = self._print(frac.numer) + denom = self._print(frac.denom) + return r"\frac{%s}{%s}" % (numer, denom) + + def _print_euler(self, expr, exp=None): + m, x = (expr.args[0], None) if len(expr.args) == 1 else expr.args + tex = r"E_{%s}" % self._print(m) + if exp is not None: + tex = r"%s^{%s}" % (tex, exp) + if x is not None: + tex = r"%s\left(%s\right)" % (tex, self._print(x)) + return tex + + def _print_catalan(self, expr, exp=None): + tex = r"C_{%s}" % self._print(expr.args[0]) + if exp is not None: + tex = r"%s^{%s}" % (tex, exp) + return tex + + def _print_UnifiedTransform(self, expr, s, inverse=False): + return r"\mathcal{{{}}}{}_{{{}}}\left[{}\right]\left({}\right)".format(s, '^{-1}' if inverse else '', self._print(expr.args[1]), self._print(expr.args[0]), self._print(expr.args[2])) + + def _print_MellinTransform(self, expr): + return self._print_UnifiedTransform(expr, 'M') + + def _print_InverseMellinTransform(self, expr): + return self._print_UnifiedTransform(expr, 'M', True) + + def _print_LaplaceTransform(self, expr): + return self._print_UnifiedTransform(expr, 'L') + + def _print_InverseLaplaceTransform(self, expr): + return self._print_UnifiedTransform(expr, 'L', True) + + def _print_FourierTransform(self, expr): + return self._print_UnifiedTransform(expr, 'F') + + def _print_InverseFourierTransform(self, expr): + return self._print_UnifiedTransform(expr, 'F', True) + + def _print_SineTransform(self, expr): + return self._print_UnifiedTransform(expr, 'SIN') + + def _print_InverseSineTransform(self, expr): + return self._print_UnifiedTransform(expr, 'SIN', True) + + def _print_CosineTransform(self, expr): + return self._print_UnifiedTransform(expr, 'COS') + + def _print_InverseCosineTransform(self, expr): + return self._print_UnifiedTransform(expr, 'COS', True) + + def _print_DMP(self, p): + try: + if p.ring is not None: + # TODO incorporate order + return self._print(p.ring.to_sympy(p)) + except SympifyError: + pass + return self._print(repr(p)) + + def _print_DMF(self, p): + return self._print_DMP(p) + + def _print_Object(self, object): + return self._print(Symbol(object.name)) + + def _print_LambertW(self, expr, exp=None): + arg0 = self._print(expr.args[0]) + exp = r"^{%s}" % (exp,) if exp is not None else "" + if len(expr.args) == 1: + result = r"W%s\left(%s\right)" % (exp, arg0) + else: + arg1 = self._print(expr.args[1]) + result = "W{0}_{{{1}}}\\left({2}\\right)".format(exp, arg1, arg0) + return result + + def _print_Expectation(self, expr): + return r"\operatorname{{E}}\left[{}\right]".format(self._print(expr.args[0])) + + def _print_Variance(self, expr): + return r"\operatorname{{Var}}\left({}\right)".format(self._print(expr.args[0])) + + def _print_Covariance(self, expr): + return r"\operatorname{{Cov}}\left({}\right)".format(", ".join(self._print(arg) for arg in expr.args)) + + def _print_Probability(self, expr): + return r"\operatorname{{P}}\left({}\right)".format(self._print(expr.args[0])) + + def _print_Morphism(self, morphism): + domain = self._print(morphism.domain) + codomain = self._print(morphism.codomain) + return "%s\\rightarrow %s" % (domain, codomain) + + def _print_TransferFunction(self, expr): + num, den = self._print(expr.num), self._print(expr.den) + return r"\frac{%s}{%s}" % (num, den) + + def _print_Series(self, expr): + args = list(expr.args) + parens = lambda x: self.parenthesize(x, precedence_traditional(expr), + False) + return ' '.join(map(parens, args)) + + def _print_MIMOSeries(self, expr): + from sympy.physics.control.lti import MIMOParallel + args = list(expr.args)[::-1] + parens = lambda x: self.parenthesize(x, precedence_traditional(expr), + False) if isinstance(x, MIMOParallel) else self._print(x) + return r"\cdot".join(map(parens, args)) + + def _print_Parallel(self, expr): + return ' + '.join(map(self._print, expr.args)) + + def _print_MIMOParallel(self, expr): + return ' + '.join(map(self._print, expr.args)) + + def _print_Feedback(self, expr): + from sympy.physics.control import TransferFunction, Series + + num, tf = expr.sys1, TransferFunction(1, 1, expr.var) + num_arg_list = list(num.args) if isinstance(num, Series) else [num] + den_arg_list = list(expr.sys2.args) if \ + isinstance(expr.sys2, Series) else [expr.sys2] + den_term_1 = tf + + if isinstance(num, Series) and isinstance(expr.sys2, Series): + den_term_2 = Series(*num_arg_list, *den_arg_list) + elif isinstance(num, Series) and isinstance(expr.sys2, TransferFunction): + if expr.sys2 == tf: + den_term_2 = Series(*num_arg_list) + else: + den_term_2 = tf, Series(*num_arg_list, expr.sys2) + elif isinstance(num, TransferFunction) and isinstance(expr.sys2, Series): + if num == tf: + den_term_2 = Series(*den_arg_list) + else: + den_term_2 = Series(num, *den_arg_list) + else: + if num == tf: + den_term_2 = Series(*den_arg_list) + elif expr.sys2 == tf: + den_term_2 = Series(*num_arg_list) + else: + den_term_2 = Series(*num_arg_list, *den_arg_list) + + numer = self._print(num) + denom_1 = self._print(den_term_1) + denom_2 = self._print(den_term_2) + _sign = "+" if expr.sign == -1 else "-" + + return r"\frac{%s}{%s %s %s}" % (numer, denom_1, _sign, denom_2) + + def _print_MIMOFeedback(self, expr): + from sympy.physics.control import MIMOSeries + inv_mat = self._print(MIMOSeries(expr.sys2, expr.sys1)) + sys1 = self._print(expr.sys1) + _sign = "+" if expr.sign == -1 else "-" + return r"\left(I_{\tau} %s %s\right)^{-1} \cdot %s" % (_sign, inv_mat, sys1) + + def _print_TransferFunctionMatrix(self, expr): + mat = self._print(expr._expr_mat) + return r"%s_\tau" % mat + + def _print_DFT(self, expr): + return r"\text{{{}}}_{{{}}}".format(expr.__class__.__name__, expr.n) + _print_IDFT = _print_DFT + + def _print_NamedMorphism(self, morphism): + pretty_name = self._print(Symbol(morphism.name)) + pretty_morphism = self._print_Morphism(morphism) + return "%s:%s" % (pretty_name, pretty_morphism) + + def _print_IdentityMorphism(self, morphism): + from sympy.categories import NamedMorphism + return self._print_NamedMorphism(NamedMorphism( + morphism.domain, morphism.codomain, "id")) + + def _print_CompositeMorphism(self, morphism): + # All components of the morphism have names and it is thus + # possible to build the name of the composite. + component_names_list = [self._print(Symbol(component.name)) for + component in morphism.components] + component_names_list.reverse() + component_names = "\\circ ".join(component_names_list) + ":" + + pretty_morphism = self._print_Morphism(morphism) + return component_names + pretty_morphism + + def _print_Category(self, morphism): + return r"\mathbf{{{}}}".format(self._print(Symbol(morphism.name))) + + def _print_Diagram(self, diagram): + if not diagram.premises: + # This is an empty diagram. + return self._print(S.EmptySet) + + latex_result = self._print(diagram.premises) + if diagram.conclusions: + latex_result += "\\Longrightarrow %s" % \ + self._print(diagram.conclusions) + + return latex_result + + def _print_DiagramGrid(self, grid): + latex_result = "\\begin{array}{%s}\n" % ("c" * grid.width) + + for i in range(grid.height): + for j in range(grid.width): + if grid[i, j]: + latex_result += latex(grid[i, j]) + latex_result += " " + if j != grid.width - 1: + latex_result += "& " + + if i != grid.height - 1: + latex_result += "\\\\" + latex_result += "\n" + + latex_result += "\\end{array}\n" + return latex_result + + def _print_FreeModule(self, M): + return '{{{}}}^{{{}}}'.format(self._print(M.ring), self._print(M.rank)) + + def _print_FreeModuleElement(self, m): + # Print as row vector for convenience, for now. + return r"\left[ {} \right]".format(",".join( + '{' + self._print(x) + '}' for x in m)) + + def _print_SubModule(self, m): + gens = [[self._print(m.ring.to_sympy(x)) for x in g] for g in m.gens] + curly = lambda o: r"{" + o + r"}" + square = lambda o: r"\left[ " + o + r" \right]" + gens_latex = ",".join(curly(square(",".join(curly(x) for x in g))) for g in gens) + return r"\left\langle {} \right\rangle".format(gens_latex) + + def _print_SubQuotientModule(self, m): + gens_latex = ",".join(["{" + self._print(g) + "}" for g in m.gens]) + return r"\left\langle {} \right\rangle".format(gens_latex) + + def _print_ModuleImplementedIdeal(self, m): + gens = [m.ring.to_sympy(x) for [x] in m._module.gens] + gens_latex = ",".join('{' + self._print(x) + '}' for x in gens) + return r"\left\langle {} \right\rangle".format(gens_latex) + + def _print_Quaternion(self, expr): + # TODO: This expression is potentially confusing, + # shall we print it as `Quaternion( ... )`? + s = [self.parenthesize(i, PRECEDENCE["Mul"], strict=True) + for i in expr.args] + a = [s[0]] + [i+" "+j for i, j in zip(s[1:], "ijk")] + return " + ".join(a) + + def _print_QuotientRing(self, R): + # TODO nicer fractions for few generators... + return r"\frac{{{}}}{{{}}}".format(self._print(R.ring), + self._print(R.base_ideal)) + + def _print_QuotientRingElement(self, x): + x_latex = self._print(x.ring.to_sympy(x)) + return r"{{{}}} + {{{}}}".format(x_latex, + self._print(x.ring.base_ideal)) + + def _print_QuotientModuleElement(self, m): + data = [m.module.ring.to_sympy(x) for x in m.data] + data_latex = r"\left[ {} \right]".format(",".join( + '{' + self._print(x) + '}' for x in data)) + return r"{{{}}} + {{{}}}".format(data_latex, + self._print(m.module.killed_module)) + + def _print_QuotientModule(self, M): + # TODO nicer fractions for few generators... + return r"\frac{{{}}}{{{}}}".format(self._print(M.base), + self._print(M.killed_module)) + + def _print_MatrixHomomorphism(self, h): + return r"{{{}}} : {{{}}} \to {{{}}}".format(self._print(h._sympy_matrix()), + self._print(h.domain), self._print(h.codomain)) + + def _print_Manifold(self, manifold): + name, supers, subs = self._split_super_sub(manifold.name.name) + + name = r'\text{%s}' % name + if supers: + name += "^{%s}" % " ".join(supers) + if subs: + name += "_{%s}" % " ".join(subs) + + return name + + def _print_Patch(self, patch): + return r'\text{%s}_{%s}' % (self._print(patch.name), self._print(patch.manifold)) + + def _print_CoordSystem(self, coordsys): + return r'\text{%s}^{\text{%s}}_{%s}' % ( + self._print(coordsys.name), self._print(coordsys.patch.name), self._print(coordsys.manifold) + ) + + def _print_CovarDerivativeOp(self, cvd): + return r'\mathbb{\nabla}_{%s}' % self._print(cvd._wrt) + + def _print_BaseScalarField(self, field): + string = field._coord_sys.symbols[field._index].name + return r'\mathbf{{{}}}'.format(self._print(Symbol(string))) + + def _print_BaseVectorField(self, field): + string = field._coord_sys.symbols[field._index].name + return r'\partial_{{{}}}'.format(self._print(Symbol(string))) + + def _print_Differential(self, diff): + field = diff._form_field + if hasattr(field, '_coord_sys'): + string = field._coord_sys.symbols[field._index].name + return r'\operatorname{{d}}{}'.format(self._print(Symbol(string))) + else: + string = self._print(field) + return r'\operatorname{{d}}\left({}\right)'.format(string) + + def _print_Tr(self, p): + # TODO: Handle indices + contents = self._print(p.args[0]) + return r'\operatorname{{tr}}\left({}\right)'.format(contents) + + def _print_totient(self, expr, exp=None): + if exp is not None: + return r'\left(\phi\left(%s\right)\right)^{%s}' % \ + (self._print(expr.args[0]), exp) + return r'\phi\left(%s\right)' % self._print(expr.args[0]) + + def _print_reduced_totient(self, expr, exp=None): + if exp is not None: + return r'\left(\lambda\left(%s\right)\right)^{%s}' % \ + (self._print(expr.args[0]), exp) + return r'\lambda\left(%s\right)' % self._print(expr.args[0]) + + def _print_divisor_sigma(self, expr, exp=None): + if len(expr.args) == 2: + tex = r"_%s\left(%s\right)" % tuple(map(self._print, + (expr.args[1], expr.args[0]))) + else: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + if exp is not None: + return r"\sigma^{%s}%s" % (exp, tex) + return r"\sigma%s" % tex + + def _print_udivisor_sigma(self, expr, exp=None): + if len(expr.args) == 2: + tex = r"_%s\left(%s\right)" % tuple(map(self._print, + (expr.args[1], expr.args[0]))) + else: + tex = r"\left(%s\right)" % self._print(expr.args[0]) + if exp is not None: + return r"\sigma^*^{%s}%s" % (exp, tex) + return r"\sigma^*%s" % tex + + def _print_primenu(self, expr, exp=None): + if exp is not None: + return r'\left(\nu\left(%s\right)\right)^{%s}' % \ + (self._print(expr.args[0]), exp) + return r'\nu\left(%s\right)' % self._print(expr.args[0]) + + def _print_primeomega(self, expr, exp=None): + if exp is not None: + return r'\left(\Omega\left(%s\right)\right)^{%s}' % \ + (self._print(expr.args[0]), exp) + return r'\Omega\left(%s\right)' % self._print(expr.args[0]) + + def _print_Str(self, s): + return str(s.name) + + def _print_float(self, expr): + return self._print(Float(expr)) + + def _print_int(self, expr): + return str(expr) + + def _print_mpz(self, expr): + return str(expr) + + def _print_mpq(self, expr): + return str(expr) + + def _print_fmpz(self, expr): + return str(expr) + + def _print_fmpq(self, expr): + return str(expr) + + def _print_Predicate(self, expr): + return r"\operatorname{{Q}}_{{\text{{{}}}}}".format(latex_escape(str(expr.name))) + + def _print_AppliedPredicate(self, expr): + pred = expr.function + args = expr.arguments + pred_latex = self._print(pred) + args_latex = ', '.join([self._print(a) for a in args]) + return '%s(%s)' % (pred_latex, args_latex) + + def emptyPrinter(self, expr): + # default to just printing as monospace, like would normally be shown + s = super().emptyPrinter(expr) + + return r"\mathtt{\text{%s}}" % latex_escape(s) + + +def translate(s: str) -> str: + r''' + Check for a modifier ending the string. If present, convert the + modifier to latex and translate the rest recursively. + + Given a description of a Greek letter or other special character, + return the appropriate latex. + + Let everything else pass as given. + + >>> from sympy.printing.latex import translate + >>> translate('alphahatdotprime') + "{\\dot{\\hat{\\alpha}}}'" + ''' + # Process the rest + tex = tex_greek_dictionary.get(s) + if tex: + return tex + elif s.lower() in greek_letters_set: + return "\\" + s.lower() + elif s in other_symbols: + return "\\" + s + else: + # Process modifiers, if any, and recurse + for key in sorted(modifier_dict.keys(), key=len, reverse=True): + if s.lower().endswith(key) and len(s) > len(key): + return modifier_dict[key](translate(s[:-len(key)])) + return s + + + +@print_function(LatexPrinter) +def latex(expr, **settings): + r"""Convert the given expression to LaTeX string representation. + + Parameters + ========== + full_prec: boolean, optional + If set to True, a floating point number is printed with full precision. + fold_frac_powers : boolean, optional + Emit ``^{p/q}`` instead of ``^{\frac{p}{q}}`` for fractional powers. + fold_func_brackets : boolean, optional + Fold function brackets where applicable. + fold_short_frac : boolean, optional + Emit ``p / q`` instead of ``\frac{p}{q}`` when the denominator is + simple enough (at most two terms and no powers). The default value is + ``True`` for inline mode, ``False`` otherwise. + inv_trig_style : string, optional + How inverse trig functions should be displayed. Can be one of + ``'abbreviated'``, ``'full'``, or ``'power'``. Defaults to + ``'abbreviated'``. + itex : boolean, optional + Specifies if itex-specific syntax is used, including emitting + ``$$...$$``. + ln_notation : boolean, optional + If set to ``True``, ``\ln`` is used instead of default ``\log``. + long_frac_ratio : float or None, optional + The allowed ratio of the width of the numerator to the width of the + denominator before the printer breaks off long fractions. If ``None`` + (the default value), long fractions are not broken up. + mat_delim : string, optional + The delimiter to wrap around matrices. Can be one of ``'['``, ``'('``, + or the empty string ``''``. Defaults to ``'['``. + mat_str : string, optional + Which matrix environment string to emit. ``'smallmatrix'``, + ``'matrix'``, ``'array'``, etc. Defaults to ``'smallmatrix'`` for + inline mode, ``'matrix'`` for matrices of no more than 10 columns, and + ``'array'`` otherwise. + mode: string, optional + Specifies how the generated code will be delimited. ``mode`` can be one + of ``'plain'``, ``'inline'``, ``'equation'`` or ``'equation*'``. If + ``mode`` is set to ``'plain'``, then the resulting code will not be + delimited at all (this is the default). If ``mode`` is set to + ``'inline'`` then inline LaTeX ``$...$`` will be used. If ``mode`` is + set to ``'equation'`` or ``'equation*'``, the resulting code will be + enclosed in the ``equation`` or ``equation*`` environment (remember to + import ``amsmath`` for ``equation*``), unless the ``itex`` option is + set. In the latter case, the ``$$...$$`` syntax is used. + mul_symbol : string or None, optional + The symbol to use for multiplication. Can be one of ``None``, + ``'ldot'``, ``'dot'``, or ``'times'``. + order: string, optional + Any of the supported monomial orderings (currently ``'lex'``, + ``'grlex'``, or ``'grevlex'``), ``'old'``, and ``'none'``. This + parameter does nothing for `~.Mul` objects. Setting order to ``'old'`` + uses the compatibility ordering for ``~.Add`` defined in Printer. For + very large expressions, set the ``order`` keyword to ``'none'`` if + speed is a concern. + symbol_names : dictionary of strings mapped to symbols, optional + Dictionary of symbols and the custom strings they should be emitted as. + root_notation : boolean, optional + If set to ``False``, exponents of the form 1/n are printed in fractonal + form. Default is ``True``, to print exponent in root form. + mat_symbol_style : string, optional + Can be either ``'plain'`` (default) or ``'bold'``. If set to + ``'bold'``, a `~.MatrixSymbol` A will be printed as ``\mathbf{A}``, + otherwise as ``A``. + imaginary_unit : string, optional + String to use for the imaginary unit. Defined options are ``'i'`` + (default) and ``'j'``. Adding ``r`` or ``t`` in front gives ``\mathrm`` + or ``\text``, so ``'ri'`` leads to ``\mathrm{i}`` which gives + `\mathrm{i}`. + gothic_re_im : boolean, optional + If set to ``True``, `\Re` and `\Im` is used for ``re`` and ``im``, respectively. + The default is ``False`` leading to `\operatorname{re}` and `\operatorname{im}`. + decimal_separator : string, optional + Specifies what separator to use to separate the whole and fractional parts of a + floating point number as in `2.5` for the default, ``period`` or `2{,}5` + when ``comma`` is specified. Lists, sets, and tuple are printed with semicolon + separating the elements when ``comma`` is chosen. For example, [1; 2; 3] when + ``comma`` is chosen and [1,2,3] for when ``period`` is chosen. + parenthesize_super : boolean, optional + If set to ``False``, superscripted expressions will not be parenthesized when + powered. Default is ``True``, which parenthesizes the expression when powered. + min: Integer or None, optional + Sets the lower bound for the exponent to print floating point numbers in + fixed-point format. + max: Integer or None, optional + Sets the upper bound for the exponent to print floating point numbers in + fixed-point format. + diff_operator: string, optional + String to use for differential operator. Default is ``'d'``, to print in italic + form. ``'rd'``, ``'td'`` are shortcuts for ``\mathrm{d}`` and ``\text{d}``. + adjoint_style: string, optional + String to use for the adjoint symbol. Defined options are ``'dagger'`` + (default),``'star'``, and ``'hermitian'``. + + Notes + ===== + + Not using a print statement for printing, results in double backslashes for + latex commands since that's the way Python escapes backslashes in strings. + + >>> from sympy import latex, Rational + >>> from sympy.abc import tau + >>> latex((2*tau)**Rational(7,2)) + '8 \\sqrt{2} \\tau^{\\frac{7}{2}}' + >>> print(latex((2*tau)**Rational(7,2))) + 8 \sqrt{2} \tau^{\frac{7}{2}} + + Examples + ======== + + >>> from sympy import latex, pi, sin, asin, Integral, Matrix, Rational, log + >>> from sympy.abc import x, y, mu, r, tau + + Basic usage: + + >>> print(latex((2*tau)**Rational(7,2))) + 8 \sqrt{2} \tau^{\frac{7}{2}} + + ``mode`` and ``itex`` options: + + >>> print(latex((2*mu)**Rational(7,2), mode='plain')) + 8 \sqrt{2} \mu^{\frac{7}{2}} + >>> print(latex((2*tau)**Rational(7,2), mode='inline')) + $8 \sqrt{2} \tau^{7 / 2}$ + >>> print(latex((2*mu)**Rational(7,2), mode='equation*')) + \begin{equation*}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation*} + >>> print(latex((2*mu)**Rational(7,2), mode='equation')) + \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} + >>> print(latex((2*mu)**Rational(7,2), mode='equation', itex=True)) + $$8 \sqrt{2} \mu^{\frac{7}{2}}$$ + >>> print(latex((2*mu)**Rational(7,2), mode='plain')) + 8 \sqrt{2} \mu^{\frac{7}{2}} + >>> print(latex((2*tau)**Rational(7,2), mode='inline')) + $8 \sqrt{2} \tau^{7 / 2}$ + >>> print(latex((2*mu)**Rational(7,2), mode='equation*')) + \begin{equation*}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation*} + >>> print(latex((2*mu)**Rational(7,2), mode='equation')) + \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} + >>> print(latex((2*mu)**Rational(7,2), mode='equation', itex=True)) + $$8 \sqrt{2} \mu^{\frac{7}{2}}$$ + + Fraction options: + + >>> print(latex((2*tau)**Rational(7,2), fold_frac_powers=True)) + 8 \sqrt{2} \tau^{7/2} + >>> print(latex((2*tau)**sin(Rational(7,2)))) + \left(2 \tau\right)^{\sin{\left(\frac{7}{2} \right)}} + >>> print(latex((2*tau)**sin(Rational(7,2)), fold_func_brackets=True)) + \left(2 \tau\right)^{\sin {\frac{7}{2}}} + >>> print(latex(3*x**2/y)) + \frac{3 x^{2}}{y} + >>> print(latex(3*x**2/y, fold_short_frac=True)) + 3 x^{2} / y + >>> print(latex(Integral(r, r)/2/pi, long_frac_ratio=2)) + \frac{\int r\, dr}{2 \pi} + >>> print(latex(Integral(r, r)/2/pi, long_frac_ratio=0)) + \frac{1}{2 \pi} \int r\, dr + + Multiplication options: + + >>> print(latex((2*tau)**sin(Rational(7,2)), mul_symbol="times")) + \left(2 \times \tau\right)^{\sin{\left(\frac{7}{2} \right)}} + + Trig options: + + >>> print(latex(asin(Rational(7,2)))) + \operatorname{asin}{\left(\frac{7}{2} \right)} + >>> print(latex(asin(Rational(7,2)), inv_trig_style="full")) + \arcsin{\left(\frac{7}{2} \right)} + >>> print(latex(asin(Rational(7,2)), inv_trig_style="power")) + \sin^{-1}{\left(\frac{7}{2} \right)} + + Matrix options: + + >>> print(latex(Matrix(2, 1, [x, y]))) + \left[\begin{matrix}x\\y\end{matrix}\right] + >>> print(latex(Matrix(2, 1, [x, y]), mat_str = "array")) + \left[\begin{array}{c}x\\y\end{array}\right] + >>> print(latex(Matrix(2, 1, [x, y]), mat_delim="(")) + \left(\begin{matrix}x\\y\end{matrix}\right) + + Custom printing of symbols: + + >>> print(latex(x**2, symbol_names={x: 'x_i'})) + x_i^{2} + + Logarithms: + + >>> print(latex(log(10))) + \log{\left(10 \right)} + >>> print(latex(log(10), ln_notation=True)) + \ln{\left(10 \right)} + + ``latex()`` also supports the builtin container types :class:`list`, + :class:`tuple`, and :class:`dict`: + + >>> print(latex([2/x, y], mode='inline')) + $\left[ 2 / x, \ y\right]$ + + Unsupported types are rendered as monospaced plaintext: + + >>> print(latex(int)) + \mathtt{\text{}} + >>> print(latex("plain % text")) + \mathtt{\text{plain \% text}} + + See :ref:`printer_method_example` for an example of how to override + this behavior for your own types by implementing ``_latex``. + + .. versionchanged:: 1.7.0 + Unsupported types no longer have their ``str`` representation treated as valid latex. + + """ + return LatexPrinter(settings).doprint(expr) + + +def print_latex(expr, **settings): + """Prints LaTeX representation of the given expression. Takes the same + settings as ``latex()``.""" + + print(latex(expr, **settings)) + + +def multiline_latex(lhs, rhs, terms_per_line=1, environment="align*", use_dots=False, **settings): + r""" + This function generates a LaTeX equation with a multiline right-hand side + in an ``align*``, ``eqnarray`` or ``IEEEeqnarray`` environment. + + Parameters + ========== + + lhs : Expr + Left-hand side of equation + + rhs : Expr + Right-hand side of equation + + terms_per_line : integer, optional + Number of terms per line to print. Default is 1. + + environment : "string", optional + Which LaTeX wnvironment to use for the output. Options are "align*" + (default), "eqnarray", and "IEEEeqnarray". + + use_dots : boolean, optional + If ``True``, ``\\dots`` is added to the end of each line. Default is ``False``. + + Examples + ======== + + >>> from sympy import multiline_latex, symbols, sin, cos, exp, log, I + >>> x, y, alpha = symbols('x y alpha') + >>> expr = sin(alpha*y) + exp(I*alpha) - cos(log(y)) + >>> print(multiline_latex(x, expr)) + \begin{align*} + x = & e^{i \alpha} \\ + & + \sin{\left(\alpha y \right)} \\ + & - \cos{\left(\log{\left(y \right)} \right)} + \end{align*} + + Using at most two terms per line: + >>> print(multiline_latex(x, expr, 2)) + \begin{align*} + x = & e^{i \alpha} + \sin{\left(\alpha y \right)} \\ + & - \cos{\left(\log{\left(y \right)} \right)} + \end{align*} + + Using ``eqnarray`` and dots: + >>> print(multiline_latex(x, expr, terms_per_line=2, environment="eqnarray", use_dots=True)) + \begin{eqnarray} + x & = & e^{i \alpha} + \sin{\left(\alpha y \right)} \dots\nonumber\\ + & & - \cos{\left(\log{\left(y \right)} \right)} + \end{eqnarray} + + Using ``IEEEeqnarray``: + >>> print(multiline_latex(x, expr, environment="IEEEeqnarray")) + \begin{IEEEeqnarray}{rCl} + x & = & e^{i \alpha} \nonumber\\ + & & + \sin{\left(\alpha y \right)} \nonumber\\ + & & - \cos{\left(\log{\left(y \right)} \right)} + \end{IEEEeqnarray} + + Notes + ===== + + All optional parameters from ``latex`` can also be used. + + """ + + # Based on code from https://github.com/sympy/sympy/issues/3001 + l = LatexPrinter(**settings) + if environment == "eqnarray": + result = r'\begin{eqnarray}' + '\n' + first_term = '& = &' + nonumber = r'\nonumber' + end_term = '\n\\end{eqnarray}' + doubleet = True + elif environment == "IEEEeqnarray": + result = r'\begin{IEEEeqnarray}{rCl}' + '\n' + first_term = '& = &' + nonumber = r'\nonumber' + end_term = '\n\\end{IEEEeqnarray}' + doubleet = True + elif environment == "align*": + result = r'\begin{align*}' + '\n' + first_term = '= &' + nonumber = '' + end_term = '\n\\end{align*}' + doubleet = False + else: + raise ValueError("Unknown environment: {}".format(environment)) + dots = '' + if use_dots: + dots=r'\dots' + terms = rhs.as_ordered_terms() + n_terms = len(terms) + term_count = 1 + for i in range(n_terms): + term = terms[i] + term_start = '' + term_end = '' + sign = '+' + if term_count > terms_per_line: + if doubleet: + term_start = '& & ' + else: + term_start = '& ' + term_count = 1 + if term_count == terms_per_line: + # End of line + if i < n_terms-1: + # There are terms remaining + term_end = dots + nonumber + r'\\' + '\n' + else: + term_end = '' + + if term.as_ordered_factors()[0] == -1: + term = -1*term + sign = r'-' + if i == 0: # beginning + if sign == '+': + sign = '' + result += r'{:s} {:s}{:s} {:s} {:s}'.format(l.doprint(lhs), + first_term, sign, l.doprint(term), term_end) + else: + result += r'{:s}{:s} {:s} {:s}'.format(term_start, sign, + l.doprint(term), term_end) + term_count += 1 + result += end_term + return result diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/llvmjitcode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/llvmjitcode.py new file mode 100644 index 0000000000000000000000000000000000000000..0e657f3b854be62fb4b6b4be96f82579b718f6ca --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/llvmjitcode.py @@ -0,0 +1,490 @@ +''' +Use llvmlite to create executable functions from SymPy expressions + +This module requires llvmlite (https://github.com/numba/llvmlite). +''' + +import ctypes + +from sympy.external import import_module +from sympy.printing.printer import Printer +from sympy.core.singleton import S +from sympy.tensor.indexed import IndexedBase +from sympy.utilities.decorator import doctest_depends_on + +llvmlite = import_module('llvmlite') +if llvmlite: + ll = import_module('llvmlite.ir').ir + llvm = import_module('llvmlite.binding').binding + llvm.initialize() + llvm.initialize_native_target() + llvm.initialize_native_asmprinter() + + +__doctest_requires__ = {('llvm_callable'): ['llvmlite']} + + +class LLVMJitPrinter(Printer): + '''Convert expressions to LLVM IR''' + def __init__(self, module, builder, fn, *args, **kwargs): + self.func_arg_map = kwargs.pop("func_arg_map", {}) + if not llvmlite: + raise ImportError("llvmlite is required for LLVMJITPrinter") + super().__init__(*args, **kwargs) + self.fp_type = ll.DoubleType() + self.module = module + self.builder = builder + self.fn = fn + self.ext_fn = {} # keep track of wrappers to external functions + self.tmp_var = {} + + def _add_tmp_var(self, name, value): + self.tmp_var[name] = value + + def _print_Number(self, n): + return ll.Constant(self.fp_type, float(n)) + + def _print_Integer(self, expr): + return ll.Constant(self.fp_type, float(expr.p)) + + def _print_Symbol(self, s): + val = self.tmp_var.get(s) + if not val: + # look up parameter with name s + val = self.func_arg_map.get(s) + if not val: + raise LookupError("Symbol not found: %s" % s) + return val + + def _print_Pow(self, expr): + base0 = self._print(expr.base) + if expr.exp == S.NegativeOne: + return self.builder.fdiv(ll.Constant(self.fp_type, 1.0), base0) + if expr.exp == S.Half: + fn = self.ext_fn.get("sqrt") + if not fn: + fn_type = ll.FunctionType(self.fp_type, [self.fp_type]) + fn = ll.Function(self.module, fn_type, "sqrt") + self.ext_fn["sqrt"] = fn + return self.builder.call(fn, [base0], "sqrt") + if expr.exp == 2: + return self.builder.fmul(base0, base0) + + exp0 = self._print(expr.exp) + fn = self.ext_fn.get("pow") + if not fn: + fn_type = ll.FunctionType(self.fp_type, [self.fp_type, self.fp_type]) + fn = ll.Function(self.module, fn_type, "pow") + self.ext_fn["pow"] = fn + return self.builder.call(fn, [base0, exp0], "pow") + + def _print_Mul(self, expr): + nodes = [self._print(a) for a in expr.args] + e = nodes[0] + for node in nodes[1:]: + e = self.builder.fmul(e, node) + return e + + def _print_Add(self, expr): + nodes = [self._print(a) for a in expr.args] + e = nodes[0] + for node in nodes[1:]: + e = self.builder.fadd(e, node) + return e + + # TODO - assumes all called functions take one double precision argument. + # Should have a list of math library functions to validate this. + def _print_Function(self, expr): + name = expr.func.__name__ + e0 = self._print(expr.args[0]) + fn = self.ext_fn.get(name) + if not fn: + fn_type = ll.FunctionType(self.fp_type, [self.fp_type]) + fn = ll.Function(self.module, fn_type, name) + self.ext_fn[name] = fn + return self.builder.call(fn, [e0], name) + + def emptyPrinter(self, expr): + raise TypeError("Unsupported type for LLVM JIT conversion: %s" + % type(expr)) + + +# Used when parameters are passed by array. Often used in callbacks to +# handle a variable number of parameters. +class LLVMJitCallbackPrinter(LLVMJitPrinter): + def __init__(self, *args, **kwargs): + super().__init__(*args, **kwargs) + + def _print_Indexed(self, expr): + array, idx = self.func_arg_map[expr.base] + offset = int(expr.indices[0].evalf()) + array_ptr = self.builder.gep(array, [ll.Constant(ll.IntType(32), offset)]) + fp_array_ptr = self.builder.bitcast(array_ptr, ll.PointerType(self.fp_type)) + value = self.builder.load(fp_array_ptr) + return value + + def _print_Symbol(self, s): + val = self.tmp_var.get(s) + if val: + return val + + array, idx = self.func_arg_map.get(s, [None, 0]) + if not array: + raise LookupError("Symbol not found: %s" % s) + array_ptr = self.builder.gep(array, [ll.Constant(ll.IntType(32), idx)]) + fp_array_ptr = self.builder.bitcast(array_ptr, + ll.PointerType(self.fp_type)) + value = self.builder.load(fp_array_ptr) + return value + + +# ensure lifetime of the execution engine persists (else call to compiled +# function will seg fault) +exe_engines = [] + +# ensure names for generated functions are unique +link_names = set() +current_link_suffix = 0 + + +class LLVMJitCode: + def __init__(self, signature): + self.signature = signature + self.fp_type = ll.DoubleType() + self.module = ll.Module('mod1') + self.fn = None + self.llvm_arg_types = [] + self.llvm_ret_type = self.fp_type + self.param_dict = {} # map symbol name to LLVM function argument + self.link_name = '' + + def _from_ctype(self, ctype): + if ctype == ctypes.c_int: + return ll.IntType(32) + if ctype == ctypes.c_double: + return self.fp_type + if ctype == ctypes.POINTER(ctypes.c_double): + return ll.PointerType(self.fp_type) + if ctype == ctypes.c_void_p: + return ll.PointerType(ll.IntType(32)) + if ctype == ctypes.py_object: + return ll.PointerType(ll.IntType(32)) + + print("Unhandled ctype = %s" % str(ctype)) + + def _create_args(self, func_args): + """Create types for function arguments""" + self.llvm_ret_type = self._from_ctype(self.signature.ret_type) + self.llvm_arg_types = \ + [self._from_ctype(a) for a in self.signature.arg_ctypes] + + def _create_function_base(self): + """Create function with name and type signature""" + global current_link_suffix + default_link_name = 'jit_func' + current_link_suffix += 1 + self.link_name = default_link_name + str(current_link_suffix) + link_names.add(self.link_name) + + fn_type = ll.FunctionType(self.llvm_ret_type, self.llvm_arg_types) + self.fn = ll.Function(self.module, fn_type, name=self.link_name) + + def _create_param_dict(self, func_args): + """Mapping of symbolic values to function arguments""" + for i, a in enumerate(func_args): + self.fn.args[i].name = str(a) + self.param_dict[a] = self.fn.args[i] + + def _create_function(self, expr): + """Create function body and return LLVM IR""" + bb_entry = self.fn.append_basic_block('entry') + builder = ll.IRBuilder(bb_entry) + + lj = LLVMJitPrinter(self.module, builder, self.fn, + func_arg_map=self.param_dict) + + ret = self._convert_expr(lj, expr) + lj.builder.ret(self._wrap_return(lj, ret)) + + strmod = str(self.module) + return strmod + + def _wrap_return(self, lj, vals): + # Return a single double if there is one return value, + # else return a tuple of doubles. + + # Don't wrap return value in this case + if self.signature.ret_type == ctypes.c_double: + return vals[0] + + # Use this instead of a real PyObject* + void_ptr = ll.PointerType(ll.IntType(32)) + + # Create a wrapped double: PyObject* PyFloat_FromDouble(double v) + wrap_type = ll.FunctionType(void_ptr, [self.fp_type]) + wrap_fn = ll.Function(lj.module, wrap_type, "PyFloat_FromDouble") + + wrapped_vals = [lj.builder.call(wrap_fn, [v]) for v in vals] + if len(vals) == 1: + final_val = wrapped_vals[0] + else: + # Create a tuple: PyObject* PyTuple_Pack(Py_ssize_t n, ...) + + # This should be Py_ssize_t + tuple_arg_types = [ll.IntType(32)] + + tuple_arg_types.extend([void_ptr]*len(vals)) + tuple_type = ll.FunctionType(void_ptr, tuple_arg_types) + tuple_fn = ll.Function(lj.module, tuple_type, "PyTuple_Pack") + + tuple_args = [ll.Constant(ll.IntType(32), len(wrapped_vals))] + tuple_args.extend(wrapped_vals) + + final_val = lj.builder.call(tuple_fn, tuple_args) + + return final_val + + def _convert_expr(self, lj, expr): + try: + # Match CSE return data structure. + if len(expr) == 2: + tmp_exprs = expr[0] + final_exprs = expr[1] + if len(final_exprs) != 1 and self.signature.ret_type == ctypes.c_double: + raise NotImplementedError("Return of multiple expressions not supported for this callback") + for name, e in tmp_exprs: + val = lj._print(e) + lj._add_tmp_var(name, val) + except TypeError: + final_exprs = [expr] + + vals = [lj._print(e) for e in final_exprs] + + return vals + + def _compile_function(self, strmod): + llmod = llvm.parse_assembly(strmod) + + pmb = llvm.create_pass_manager_builder() + pmb.opt_level = 2 + pass_manager = llvm.create_module_pass_manager() + pmb.populate(pass_manager) + + pass_manager.run(llmod) + + target_machine = \ + llvm.Target.from_default_triple().create_target_machine() + exe_eng = llvm.create_mcjit_compiler(llmod, target_machine) + exe_eng.finalize_object() + exe_engines.append(exe_eng) + + if False: + print("Assembly") + print(target_machine.emit_assembly(llmod)) + + fptr = exe_eng.get_function_address(self.link_name) + + return fptr + + +class LLVMJitCodeCallback(LLVMJitCode): + def __init__(self, signature): + super().__init__(signature) + + def _create_param_dict(self, func_args): + for i, a in enumerate(func_args): + if isinstance(a, IndexedBase): + self.param_dict[a] = (self.fn.args[i], i) + self.fn.args[i].name = str(a) + else: + self.param_dict[a] = (self.fn.args[self.signature.input_arg], + i) + + def _create_function(self, expr): + """Create function body and return LLVM IR""" + bb_entry = self.fn.append_basic_block('entry') + builder = ll.IRBuilder(bb_entry) + + lj = LLVMJitCallbackPrinter(self.module, builder, self.fn, + func_arg_map=self.param_dict) + + ret = self._convert_expr(lj, expr) + + if self.signature.ret_arg: + output_fp_ptr = builder.bitcast(self.fn.args[self.signature.ret_arg], + ll.PointerType(self.fp_type)) + for i, val in enumerate(ret): + index = ll.Constant(ll.IntType(32), i) + output_array_ptr = builder.gep(output_fp_ptr, [index]) + builder.store(val, output_array_ptr) + builder.ret(ll.Constant(ll.IntType(32), 0)) # return success + else: + lj.builder.ret(self._wrap_return(lj, ret)) + + strmod = str(self.module) + return strmod + + +class CodeSignature: + def __init__(self, ret_type): + self.ret_type = ret_type + self.arg_ctypes = [] + + # Input argument array element index + self.input_arg = 0 + + # For the case output value is referenced through a parameter rather + # than the return value + self.ret_arg = None + + +def _llvm_jit_code(args, expr, signature, callback_type): + """Create a native code function from a SymPy expression""" + if callback_type is None: + jit = LLVMJitCode(signature) + else: + jit = LLVMJitCodeCallback(signature) + + jit._create_args(args) + jit._create_function_base() + jit._create_param_dict(args) + strmod = jit._create_function(expr) + if False: + print("LLVM IR") + print(strmod) + fptr = jit._compile_function(strmod) + return fptr + + +@doctest_depends_on(modules=('llvmlite', 'scipy')) +def llvm_callable(args, expr, callback_type=None): + '''Compile function from a SymPy expression + + Expressions are evaluated using double precision arithmetic. + Some single argument math functions (exp, sin, cos, etc.) are supported + in expressions. + + Parameters + ========== + + args : List of Symbol + Arguments to the generated function. Usually the free symbols in + the expression. Currently each one is assumed to convert to + a double precision scalar. + expr : Expr, or (Replacements, Expr) as returned from 'cse' + Expression to compile. + callback_type : string + Create function with signature appropriate to use as a callback. + Currently supported: + 'scipy.integrate' + 'scipy.integrate.test' + 'cubature' + + Returns + ======= + + Compiled function that can evaluate the expression. + + Examples + ======== + + >>> import sympy.printing.llvmjitcode as jit + >>> from sympy.abc import a + >>> e = a*a + a + 1 + >>> e1 = jit.llvm_callable([a], e) + >>> e.subs(a, 1.1) # Evaluate via substitution + 3.31000000000000 + >>> e1(1.1) # Evaluate using JIT-compiled code + 3.3100000000000005 + + + Callbacks for integration functions can be JIT compiled. + + >>> import sympy.printing.llvmjitcode as jit + >>> from sympy.abc import a + >>> from sympy import integrate + >>> from scipy.integrate import quad + >>> e = a*a + >>> e1 = jit.llvm_callable([a], e, callback_type='scipy.integrate') + >>> integrate(e, (a, 0.0, 2.0)) + 2.66666666666667 + >>> quad(e1, 0.0, 2.0)[0] + 2.66666666666667 + + The 'cubature' callback is for the Python wrapper around the + cubature package ( https://github.com/saullocastro/cubature ) + and ( http://ab-initio.mit.edu/wiki/index.php/Cubature ) + + There are two signatures for the SciPy integration callbacks. + The first ('scipy.integrate') is the function to be passed to the + integration routine, and will pass the signature checks. + The second ('scipy.integrate.test') is only useful for directly calling + the function using ctypes variables. It will not pass the signature checks + for scipy.integrate. + + The return value from the cse module can also be compiled. This + can improve the performance of the compiled function. If multiple + expressions are given to cse, the compiled function returns a tuple. + The 'cubature' callback handles multiple expressions (set `fdim` + to match in the integration call.) + + >>> import sympy.printing.llvmjitcode as jit + >>> from sympy import cse + >>> from sympy.abc import x,y + >>> e1 = x*x + y*y + >>> e2 = 4*(x*x + y*y) + 8.0 + >>> after_cse = cse([e1,e2]) + >>> after_cse + ([(x0, x**2), (x1, y**2)], [x0 + x1, 4*x0 + 4*x1 + 8.0]) + >>> j1 = jit.llvm_callable([x,y], after_cse) + >>> j1(1.0, 2.0) + (5.0, 28.0) + ''' + + if not llvmlite: + raise ImportError("llvmlite is required for llvmjitcode") + + signature = CodeSignature(ctypes.py_object) + + arg_ctypes = [] + if callback_type is None: + for _ in args: + arg_ctype = ctypes.c_double + arg_ctypes.append(arg_ctype) + elif callback_type in ('scipy.integrate', 'scipy.integrate.test'): + signature.ret_type = ctypes.c_double + arg_ctypes = [ctypes.c_int, ctypes.POINTER(ctypes.c_double)] + arg_ctypes_formal = [ctypes.c_int, ctypes.c_double] + signature.input_arg = 1 + elif callback_type == 'cubature': + arg_ctypes = [ctypes.c_int, + ctypes.POINTER(ctypes.c_double), + ctypes.c_void_p, + ctypes.c_int, + ctypes.POINTER(ctypes.c_double) + ] + signature.ret_type = ctypes.c_int + signature.input_arg = 1 + signature.ret_arg = 4 + else: + raise ValueError("Unknown callback type: %s" % callback_type) + + signature.arg_ctypes = arg_ctypes + + fptr = _llvm_jit_code(args, expr, signature, callback_type) + + if callback_type and callback_type == 'scipy.integrate': + arg_ctypes = arg_ctypes_formal + + # PYFUNCTYPE holds the GIL which is needed to prevent a segfault when + # calling PyFloat_FromDouble on Python 3.10. Probably it is better to use + # ctypes.c_double when returning a float rather than using ctypes.py_object + # and returning a PyFloat from inside the jitted function (i.e. let ctypes + # handle the conversion from double to PyFloat). + if signature.ret_type == ctypes.py_object: + FUNCTYPE = ctypes.PYFUNCTYPE + else: + FUNCTYPE = ctypes.CFUNCTYPE + + cfunc = FUNCTYPE(signature.ret_type, *arg_ctypes)(fptr) + return cfunc diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/maple.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/maple.py new file mode 100644 index 0000000000000000000000000000000000000000..2c937cd262ab7f3ee5f32b3f4b5eb5633bc6bb3c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/maple.py @@ -0,0 +1,311 @@ +""" +Maple code printer + +The MapleCodePrinter converts single SymPy expressions into single +Maple expressions, using the functions defined in the Maple objects where possible. + + +FIXME: This module is still under actively developed. Some functions may be not completed. +""" + +from sympy.core import S +from sympy.core.numbers import Integer, IntegerConstant, equal_valued +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence, PRECEDENCE + +import sympy + +_known_func_same_name = ( + 'sin', 'cos', 'tan', 'sec', 'csc', 'cot', 'sinh', 'cosh', 'tanh', 'sech', + 'csch', 'coth', 'exp', 'floor', 'factorial', 'bernoulli', 'euler', + 'fibonacci', 'gcd', 'lcm', 'conjugate', 'Ci', 'Chi', 'Ei', 'Li', 'Si', 'Shi', + 'erf', 'erfc', 'harmonic', 'LambertW', + 'sqrt', # For automatic rewrites +) + +known_functions = { + # SymPy -> Maple + 'Abs': 'abs', + 'log': 'ln', + 'asin': 'arcsin', + 'acos': 'arccos', + 'atan': 'arctan', + 'asec': 'arcsec', + 'acsc': 'arccsc', + 'acot': 'arccot', + 'asinh': 'arcsinh', + 'acosh': 'arccosh', + 'atanh': 'arctanh', + 'asech': 'arcsech', + 'acsch': 'arccsch', + 'acoth': 'arccoth', + 'ceiling': 'ceil', + 'Max' : 'max', + 'Min' : 'min', + + 'factorial2': 'doublefactorial', + 'RisingFactorial': 'pochhammer', + 'besseli': 'BesselI', + 'besselj': 'BesselJ', + 'besselk': 'BesselK', + 'bessely': 'BesselY', + 'hankelh1': 'HankelH1', + 'hankelh2': 'HankelH2', + 'airyai': 'AiryAi', + 'airybi': 'AiryBi', + 'appellf1': 'AppellF1', + 'fresnelc': 'FresnelC', + 'fresnels': 'FresnelS', + 'lerchphi' : 'LerchPhi', +} + +for _func in _known_func_same_name: + known_functions[_func] = _func + +number_symbols = { + # SymPy -> Maple + S.Pi: 'Pi', + S.Exp1: 'exp(1)', + S.Catalan: 'Catalan', + S.EulerGamma: 'gamma', + S.GoldenRatio: '(1/2 + (1/2)*sqrt(5))' +} + +spec_relational_ops = { + # SymPy -> Maple + '==': '=', + '!=': '<>' +} + +not_supported_symbol = [ + S.ComplexInfinity +] + +class MapleCodePrinter(CodePrinter): + """ + Printer which converts a SymPy expression into a maple code. + """ + printmethod = "_maple" + language = "maple" + + _operators = { + 'and': 'and', + 'or': 'or', + 'not': 'not ', + } + + _default_settings = dict(CodePrinter._default_settings, **{ + 'inline': True, + 'allow_unknown_functions': True, + }) + + def __init__(self, settings=None): + if settings is None: + settings = {} + super().__init__(settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + + def _get_statement(self, codestring): + return "%s;" % codestring + + def _get_comment(self, text): + return "# {}".format(text) + + def _declare_number_const(self, name, value): + return "{} := {};".format(name, + value.evalf(self._settings['precision'])) + + def _format_code(self, lines): + return lines + + def _print_tuple(self, expr): + return self._print(list(expr)) + + def _print_Tuple(self, expr): + return self._print(list(expr)) + + def _print_Assignment(self, expr): + lhs = self._print(expr.lhs) + rhs = self._print(expr.rhs) + return "{lhs} := {rhs}".format(lhs=lhs, rhs=rhs) + + def _print_Pow(self, expr, **kwargs): + PREC = precedence(expr) + if equal_valued(expr.exp, -1): + return '1/%s' % (self.parenthesize(expr.base, PREC)) + elif equal_valued(expr.exp, 0.5): + return 'sqrt(%s)' % self._print(expr.base) + elif equal_valued(expr.exp, -0.5): + return '1/sqrt(%s)' % self._print(expr.base) + else: + return '{base}^{exp}'.format( + base=self.parenthesize(expr.base, PREC), + exp=self.parenthesize(expr.exp, PREC)) + + def _print_Piecewise(self, expr): + if (expr.args[-1].cond is not True) and (expr.args[-1].cond != S.BooleanTrue): + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + _coup_list = [ + ("{c}, {e}".format(c=self._print(c), + e=self._print(e)) if c is not True and c is not S.BooleanTrue else "{e}".format( + e=self._print(e))) + for e, c in expr.args] + _inbrace = ', '.join(_coup_list) + return 'piecewise({_inbrace})'.format(_inbrace=_inbrace) + + def _print_Rational(self, expr): + p, q = int(expr.p), int(expr.q) + return "{p}/{q}".format(p=str(p), q=str(q)) + + def _print_Relational(self, expr): + PREC=precedence(expr) + lhs_code = self.parenthesize(expr.lhs, PREC) + rhs_code = self.parenthesize(expr.rhs, PREC) + op = expr.rel_op + if op in spec_relational_ops: + op = spec_relational_ops[op] + return "{lhs} {rel_op} {rhs}".format(lhs=lhs_code, rel_op=op, rhs=rhs_code) + + def _print_NumberSymbol(self, expr): + return number_symbols[expr] + + def _print_NegativeInfinity(self, expr): + return '-infinity' + + def _print_Infinity(self, expr): + return 'infinity' + + def _print_BooleanTrue(self, expr): + return "true" + + def _print_BooleanFalse(self, expr): + return "false" + + def _print_bool(self, expr): + return 'true' if expr else 'false' + + def _print_NaN(self, expr): + return 'undefined' + + def _get_matrix(self, expr, sparse=False): + if S.Zero in expr.shape: + _strM = 'Matrix([], storage = {storage})'.format( + storage='sparse' if sparse else 'rectangular') + else: + _strM = 'Matrix({list}, storage = {storage})'.format( + list=self._print(expr.tolist()), + storage='sparse' if sparse else 'rectangular') + return _strM + + def _print_MatrixElement(self, expr): + return "{parent}[{i_maple}, {j_maple}]".format( + parent=self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True), + i_maple=self._print(expr.i + 1), + j_maple=self._print(expr.j + 1)) + + def _print_MatrixBase(self, expr): + return self._get_matrix(expr, sparse=False) + + def _print_SparseRepMatrix(self, expr): + return self._get_matrix(expr, sparse=True) + + def _print_Identity(self, expr): + if isinstance(expr.rows, (Integer, IntegerConstant)): + return self._print(sympy.SparseMatrix(expr)) + else: + return "Matrix({var_size}, shape = identity)".format(var_size=self._print(expr.rows)) + + def _print_MatMul(self, expr): + PREC=precedence(expr) + _fact_list = list(expr.args) + _const = None + if not isinstance(_fact_list[0], (sympy.MatrixBase, sympy.MatrixExpr, + sympy.MatrixSlice, sympy.MatrixSymbol)): + _const, _fact_list = _fact_list[0], _fact_list[1:] + + if _const is None or _const == 1: + return '.'.join(self.parenthesize(_m, PREC) for _m in _fact_list) + else: + return '{c}*{m}'.format(c=_const, m='.'.join(self.parenthesize(_m, PREC) for _m in _fact_list)) + + def _print_MatPow(self, expr): + # This function requires LinearAlgebra Function in Maple + return 'MatrixPower({A}, {n})'.format(A=self._print(expr.base), n=self._print(expr.exp)) + + def _print_HadamardProduct(self, expr): + PREC = precedence(expr) + _fact_list = list(expr.args) + return '*'.join(self.parenthesize(_m, PREC) for _m in _fact_list) + + def _print_Derivative(self, expr): + _f, (_var, _order) = expr.args + + if _order != 1: + _second_arg = '{var}${order}'.format(var=self._print(_var), + order=self._print(_order)) + else: + _second_arg = '{var}'.format(var=self._print(_var)) + return 'diff({func_expr}, {sec_arg})'.format(func_expr=self._print(_f), sec_arg=_second_arg) + + +def maple_code(expr, assign_to=None, **settings): + r"""Converts ``expr`` to a string of Maple code. + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This can be helpful for + expressions that generate multi-line statements. + precision : integer, optional + The precision for numbers such as pi [default=16]. + user_functions : dict, optional + A dictionary where keys are ``FunctionClass`` instances and values are + their string representations. Alternatively, the dictionary value can + be a list of tuples i.e. [(argument_test, cfunction_string)]. See + below for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + inline: bool, optional + If True, we try to create single-statement code instead of multiple + statements. [default=True]. + + """ + return MapleCodePrinter(settings).doprint(expr, assign_to) + + +def print_maple_code(expr, **settings): + """Prints the Maple representation of the given expression. + + See :func:`maple_code` for the meaning of the optional arguments. + + Examples + ======== + + >>> from sympy import print_maple_code, symbols + >>> x, y = symbols('x y') + >>> print_maple_code(x, assign_to=y) + y := x + """ + print(maple_code(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/mathematica.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/mathematica.py new file mode 100644 index 0000000000000000000000000000000000000000..064925ec1a9a477d7509110c57311239bac9fcaf --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/mathematica.py @@ -0,0 +1,353 @@ +""" +Mathematica code printer +""" + +from __future__ import annotations +from typing import Any + +from sympy.core import Basic, Expr, Float +from sympy.core.sorting import default_sort_key + +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence + +# Used in MCodePrinter._print_Function(self) +known_functions = { + "exp": [(lambda x: True, "Exp")], + "log": [(lambda x: True, "Log")], + "sin": [(lambda x: True, "Sin")], + "cos": [(lambda x: True, "Cos")], + "tan": [(lambda x: True, "Tan")], + "cot": [(lambda x: True, "Cot")], + "sec": [(lambda x: True, "Sec")], + "csc": [(lambda x: True, "Csc")], + "asin": [(lambda x: True, "ArcSin")], + "acos": [(lambda x: True, "ArcCos")], + "atan": [(lambda x: True, "ArcTan")], + "acot": [(lambda x: True, "ArcCot")], + "asec": [(lambda x: True, "ArcSec")], + "acsc": [(lambda x: True, "ArcCsc")], + "sinh": [(lambda x: True, "Sinh")], + "cosh": [(lambda x: True, "Cosh")], + "tanh": [(lambda x: True, "Tanh")], + "coth": [(lambda x: True, "Coth")], + "sech": [(lambda x: True, "Sech")], + "csch": [(lambda x: True, "Csch")], + "asinh": [(lambda x: True, "ArcSinh")], + "acosh": [(lambda x: True, "ArcCosh")], + "atanh": [(lambda x: True, "ArcTanh")], + "acoth": [(lambda x: True, "ArcCoth")], + "asech": [(lambda x: True, "ArcSech")], + "acsch": [(lambda x: True, "ArcCsch")], + "sinc": [(lambda x: True, "Sinc")], + "conjugate": [(lambda x: True, "Conjugate")], + "Max": [(lambda *x: True, "Max")], + "Min": [(lambda *x: True, "Min")], + "erf": [(lambda x: True, "Erf")], + "erf2": [(lambda *x: True, "Erf")], + "erfc": [(lambda x: True, "Erfc")], + "erfi": [(lambda x: True, "Erfi")], + "erfinv": [(lambda x: True, "InverseErf")], + "erfcinv": [(lambda x: True, "InverseErfc")], + "erf2inv": [(lambda *x: True, "InverseErf")], + "expint": [(lambda *x: True, "ExpIntegralE")], + "Ei": [(lambda x: True, "ExpIntegralEi")], + "fresnelc": [(lambda x: True, "FresnelC")], + "fresnels": [(lambda x: True, "FresnelS")], + "gamma": [(lambda x: True, "Gamma")], + "uppergamma": [(lambda *x: True, "Gamma")], + "polygamma": [(lambda *x: True, "PolyGamma")], + "loggamma": [(lambda x: True, "LogGamma")], + "beta": [(lambda *x: True, "Beta")], + "Ci": [(lambda x: True, "CosIntegral")], + "Si": [(lambda x: True, "SinIntegral")], + "Chi": [(lambda x: True, "CoshIntegral")], + "Shi": [(lambda x: True, "SinhIntegral")], + "li": [(lambda x: True, "LogIntegral")], + "factorial": [(lambda x: True, "Factorial")], + "factorial2": [(lambda x: True, "Factorial2")], + "subfactorial": [(lambda x: True, "Subfactorial")], + "catalan": [(lambda x: True, "CatalanNumber")], + "harmonic": [(lambda *x: True, "HarmonicNumber")], + "lucas": [(lambda x: True, "LucasL")], + "RisingFactorial": [(lambda *x: True, "Pochhammer")], + "FallingFactorial": [(lambda *x: True, "FactorialPower")], + "laguerre": [(lambda *x: True, "LaguerreL")], + "assoc_laguerre": [(lambda *x: True, "LaguerreL")], + "hermite": [(lambda *x: True, "HermiteH")], + "jacobi": [(lambda *x: True, "JacobiP")], + "gegenbauer": [(lambda *x: True, "GegenbauerC")], + "chebyshevt": [(lambda *x: True, "ChebyshevT")], + "chebyshevu": [(lambda *x: True, "ChebyshevU")], + "legendre": [(lambda *x: True, "LegendreP")], + "assoc_legendre": [(lambda *x: True, "LegendreP")], + "mathieuc": [(lambda *x: True, "MathieuC")], + "mathieus": [(lambda *x: True, "MathieuS")], + "mathieucprime": [(lambda *x: True, "MathieuCPrime")], + "mathieusprime": [(lambda *x: True, "MathieuSPrime")], + "stieltjes": [(lambda x: True, "StieltjesGamma")], + "elliptic_e": [(lambda *x: True, "EllipticE")], + "elliptic_f": [(lambda *x: True, "EllipticE")], + "elliptic_k": [(lambda x: True, "EllipticK")], + "elliptic_pi": [(lambda *x: True, "EllipticPi")], + "zeta": [(lambda *x: True, "Zeta")], + "dirichlet_eta": [(lambda x: True, "DirichletEta")], + "riemann_xi": [(lambda x: True, "RiemannXi")], + "besseli": [(lambda *x: True, "BesselI")], + "besselj": [(lambda *x: True, "BesselJ")], + "besselk": [(lambda *x: True, "BesselK")], + "bessely": [(lambda *x: True, "BesselY")], + "hankel1": [(lambda *x: True, "HankelH1")], + "hankel2": [(lambda *x: True, "HankelH2")], + "airyai": [(lambda x: True, "AiryAi")], + "airybi": [(lambda x: True, "AiryBi")], + "airyaiprime": [(lambda x: True, "AiryAiPrime")], + "airybiprime": [(lambda x: True, "AiryBiPrime")], + "polylog": [(lambda *x: True, "PolyLog")], + "lerchphi": [(lambda *x: True, "LerchPhi")], + "gcd": [(lambda *x: True, "GCD")], + "lcm": [(lambda *x: True, "LCM")], + "jn": [(lambda *x: True, "SphericalBesselJ")], + "yn": [(lambda *x: True, "SphericalBesselY")], + "hyper": [(lambda *x: True, "HypergeometricPFQ")], + "meijerg": [(lambda *x: True, "MeijerG")], + "appellf1": [(lambda *x: True, "AppellF1")], + "DiracDelta": [(lambda x: True, "DiracDelta")], + "Heaviside": [(lambda x: True, "HeavisideTheta")], + "KroneckerDelta": [(lambda *x: True, "KroneckerDelta")], + "sqrt": [(lambda x: True, "Sqrt")], # For automatic rewrites +} + + +class MCodePrinter(CodePrinter): + """A printer to convert Python expressions to + strings of the Wolfram's Mathematica code + """ + printmethod = "_mcode" + language = "Wolfram Language" + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 15, + 'user_functions': {}, + }) + + _number_symbols: set[tuple[Expr, Float]] = set() + _not_supported: set[Basic] = set() + + def __init__(self, settings={}): + """Register function mappings supplied by user""" + CodePrinter.__init__(self, settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}).copy() + for k, v in userfuncs.items(): + if not isinstance(v, list): + userfuncs[k] = [(lambda *x: True, v)] + self.known_functions.update(userfuncs) + + def _format_code(self, lines): + return lines + + def _print_Pow(self, expr): + PREC = precedence(expr) + return '%s^%s' % (self.parenthesize(expr.base, PREC), + self.parenthesize(expr.exp, PREC)) + + def _print_Mul(self, expr): + PREC = precedence(expr) + c, nc = expr.args_cnc() + res = super()._print_Mul(expr.func(*c)) + if nc: + res += '*' + res += '**'.join(self.parenthesize(a, PREC) for a in nc) + return res + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + # Primitive numbers + def _print_Zero(self, expr): + return '0' + + def _print_One(self, expr): + return '1' + + def _print_NegativeOne(self, expr): + return '-1' + + def _print_Half(self, expr): + return '1/2' + + def _print_ImaginaryUnit(self, expr): + return 'I' + + + # Infinity and invalid numbers + def _print_Infinity(self, expr): + return 'Infinity' + + def _print_NegativeInfinity(self, expr): + return '-Infinity' + + def _print_ComplexInfinity(self, expr): + return 'ComplexInfinity' + + def _print_NaN(self, expr): + return 'Indeterminate' + + + # Mathematical constants + def _print_Exp1(self, expr): + return 'E' + + def _print_Pi(self, expr): + return 'Pi' + + def _print_GoldenRatio(self, expr): + return 'GoldenRatio' + + def _print_TribonacciConstant(self, expr): + expanded = expr.expand(func=True) + PREC = precedence(expr) + return self.parenthesize(expanded, PREC) + + def _print_EulerGamma(self, expr): + return 'EulerGamma' + + def _print_Catalan(self, expr): + return 'Catalan' + + + def _print_list(self, expr): + return '{' + ', '.join(self.doprint(a) for a in expr) + '}' + _print_tuple = _print_list + _print_Tuple = _print_list + + def _print_ImmutableDenseMatrix(self, expr): + return self.doprint(expr.tolist()) + + def _print_ImmutableSparseMatrix(self, expr): + + def print_rule(pos, val): + return '{} -> {}'.format( + self.doprint((pos[0]+1, pos[1]+1)), self.doprint(val)) + + def print_data(): + items = sorted(expr.todok().items(), key=default_sort_key) + return '{' + \ + ', '.join(print_rule(k, v) for k, v in items) + \ + '}' + + def print_dims(): + return self.doprint(expr.shape) + + return 'SparseArray[{}, {}]'.format(print_data(), print_dims()) + + def _print_ImmutableDenseNDimArray(self, expr): + return self.doprint(expr.tolist()) + + def _print_ImmutableSparseNDimArray(self, expr): + def print_string_list(string_list): + return '{' + ', '.join(a for a in string_list) + '}' + + def to_mathematica_index(*args): + """Helper function to change Python style indexing to + Pathematica indexing. + + Python indexing (0, 1 ... n-1) + -> Mathematica indexing (1, 2 ... n) + """ + return tuple(i + 1 for i in args) + + def print_rule(pos, val): + """Helper function to print a rule of Mathematica""" + return '{} -> {}'.format(self.doprint(pos), self.doprint(val)) + + def print_data(): + """Helper function to print data part of Mathematica + sparse array. + + It uses the fourth notation ``SparseArray[data,{d1,d2,...}]`` + from + https://reference.wolfram.com/language/ref/SparseArray.html + + ``data`` must be formatted with rule. + """ + return print_string_list( + [print_rule( + to_mathematica_index(*(expr._get_tuple_index(key))), + value) + for key, value in sorted(expr._sparse_array.items())] + ) + + def print_dims(): + """Helper function to print dimensions part of Mathematica + sparse array. + + It uses the fourth notation ``SparseArray[data,{d1,d2,...}]`` + from + https://reference.wolfram.com/language/ref/SparseArray.html + """ + return self.doprint(expr.shape) + + return 'SparseArray[{}, {}]'.format(print_data(), print_dims()) + + def _print_Function(self, expr): + if expr.func.__name__ in self.known_functions: + cond_mfunc = self.known_functions[expr.func.__name__] + for cond, mfunc in cond_mfunc: + if cond(*expr.args): + return "%s[%s]" % (mfunc, self.stringify(expr.args, ", ")) + elif expr.func.__name__ in self._rewriteable_functions: + # Simple rewrite to supported function possible + target_f, required_fs = self._rewriteable_functions[expr.func.__name__] + if self._can_print(target_f) and all(self._can_print(f) for f in required_fs): + return self._print(expr.rewrite(target_f)) + return expr.func.__name__ + "[%s]" % self.stringify(expr.args, ", ") + + _print_MinMaxBase = _print_Function + + def _print_LambertW(self, expr): + if len(expr.args) == 1: + return "ProductLog[{}]".format(self._print(expr.args[0])) + return "ProductLog[{}, {}]".format( + self._print(expr.args[1]), self._print(expr.args[0])) + + def _print_atan2(self, expr): + return "ArcTan[{}, {}]".format( + self._print(expr.args[1]), self._print(expr.args[0])) + + def _print_Integral(self, expr): + if len(expr.variables) == 1 and not expr.limits[0][1:]: + args = [expr.args[0], expr.variables[0]] + else: + args = expr.args + return "Hold[Integrate[" + ', '.join(self.doprint(a) for a in args) + "]]" + + def _print_Sum(self, expr): + return "Hold[Sum[" + ', '.join(self.doprint(a) for a in expr.args) + "]]" + + def _print_Derivative(self, expr): + dexpr = expr.expr + dvars = [i[0] if i[1] == 1 else i for i in expr.variable_count] + return "Hold[D[" + ', '.join(self.doprint(a) for a in [dexpr] + dvars) + "]]" + + + def _get_comment(self, text): + return "(* {} *)".format(text) + + +def mathematica_code(expr, **settings): + r"""Converts an expr to a string of the Wolfram Mathematica code + + Examples + ======== + + >>> from sympy import mathematica_code as mcode, symbols, sin + >>> x = symbols('x') + >>> mcode(sin(x).series(x).removeO()) + '(1/120)*x^5 - 1/6*x^3 + x' + """ + return MCodePrinter(settings).doprint(expr) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/mathml.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/mathml.py new file mode 100644 index 0000000000000000000000000000000000000000..4dff74cd64b17036d3ff2a766253c9af850f088d --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/mathml.py @@ -0,0 +1,2157 @@ +""" +A MathML printer. +""" + +from __future__ import annotations +from typing import Any + +from sympy.core.mul import Mul +from sympy.core.singleton import S +from sympy.core.sorting import default_sort_key +from sympy.core.sympify import sympify +from sympy.printing.conventions import split_super_sub, requires_partial +from sympy.printing.precedence import \ + precedence_traditional, PRECEDENCE, PRECEDENCE_TRADITIONAL +from sympy.printing.pretty.pretty_symbology import greek_unicode +from sympy.printing.printer import Printer, print_function + +from mpmath.libmp import prec_to_dps, repr_dps, to_str as mlib_to_str + + +class MathMLPrinterBase(Printer): + """Contains common code required for MathMLContentPrinter and + MathMLPresentationPrinter. + """ + + _default_settings: dict[str, Any] = { + "order": None, + "encoding": "utf-8", + "fold_frac_powers": False, + "fold_func_brackets": False, + "fold_short_frac": None, + "inv_trig_style": "abbreviated", + "ln_notation": False, + "long_frac_ratio": None, + "mat_delim": "[", + "mat_symbol_style": "plain", + "mul_symbol": None, + "root_notation": True, + "symbol_names": {}, + "mul_symbol_mathml_numbers": '·', + "disable_split_super_sub": False, + } + + def __init__(self, settings=None): + Printer.__init__(self, settings) + from xml.dom.minidom import Document, Text + + self.dom = Document() + + # Workaround to allow strings to remain unescaped + # Based on + # https://stackoverflow.com/questions/38015864/python-xml-dom-minidom-\ + # please-dont-escape-my-strings/38041194 + class RawText(Text): + def writexml(self, writer, indent='', addindent='', newl=''): + if self.data: + writer.write('{}{}{}'.format(indent, self.data, newl)) + + def createRawTextNode(data): + r = RawText() + r.data = data + r.ownerDocument = self.dom + return r + + self.dom.createTextNode = createRawTextNode + + def doprint(self, expr): + """ + Prints the expression as MathML. + """ + mathML = Printer._print(self, expr) + unistr = mathML.toxml() + xmlbstr = unistr.encode('ascii', 'xmlcharrefreplace') + res = xmlbstr.decode() + return res + + def _split_super_sub(self, name): + if self._settings["disable_split_super_sub"]: + return (name, [], []) + else: + return split_super_sub(name) + + +class MathMLContentPrinter(MathMLPrinterBase): + """Prints an expression to the Content MathML markup language. + + References: https://www.w3.org/TR/MathML2/chapter4.html + """ + printmethod = "_mathml_content" + + def mathml_tag(self, e): + """Returns the MathML tag for an expression.""" + translate = { + 'Add': 'plus', + 'Mul': 'times', + 'Derivative': 'diff', + 'Number': 'cn', + 'int': 'cn', + 'Pow': 'power', + 'Max': 'max', + 'Min': 'min', + 'Abs': 'abs', + 'And': 'and', + 'Or': 'or', + 'Xor': 'xor', + 'Not': 'not', + 'Implies': 'implies', + 'Symbol': 'ci', + 'MatrixSymbol': 'ci', + 'RandomSymbol': 'ci', + 'Integral': 'int', + 'Sum': 'sum', + 'sin': 'sin', + 'cos': 'cos', + 'tan': 'tan', + 'cot': 'cot', + 'csc': 'csc', + 'sec': 'sec', + 'sinh': 'sinh', + 'cosh': 'cosh', + 'tanh': 'tanh', + 'coth': 'coth', + 'csch': 'csch', + 'sech': 'sech', + 'asin': 'arcsin', + 'asinh': 'arcsinh', + 'acos': 'arccos', + 'acosh': 'arccosh', + 'atan': 'arctan', + 'atanh': 'arctanh', + 'atan2': 'arctan', + 'acot': 'arccot', + 'acoth': 'arccoth', + 'asec': 'arcsec', + 'asech': 'arcsech', + 'acsc': 'arccsc', + 'acsch': 'arccsch', + 'log': 'ln', + 'Equality': 'eq', + 'Unequality': 'neq', + 'GreaterThan': 'geq', + 'LessThan': 'leq', + 'StrictGreaterThan': 'gt', + 'StrictLessThan': 'lt', + 'Union': 'union', + 'Intersection': 'intersect', + } + + for cls in e.__class__.__mro__: + n = cls.__name__ + if n in translate: + return translate[n] + # Not found in the MRO set + n = e.__class__.__name__ + return n.lower() + + def _print_Mul(self, expr): + + if expr.could_extract_minus_sign(): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('minus')) + x.appendChild(self._print_Mul(-expr)) + return x + + from sympy.simplify import fraction + numer, denom = fraction(expr) + + if denom is not S.One: + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('divide')) + x.appendChild(self._print(numer)) + x.appendChild(self._print(denom)) + return x + + coeff, terms = expr.as_coeff_mul() + if coeff is S.One and len(terms) == 1: + # XXX since the negative coefficient has been handled, I don't + # think a coeff of 1 can remain + return self._print(terms[0]) + + if self.order != 'old': + terms = Mul._from_args(terms).as_ordered_factors() + + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('times')) + if coeff != 1: + x.appendChild(self._print(coeff)) + for term in terms: + x.appendChild(self._print(term)) + return x + + def _print_Add(self, expr, order=None): + args = self._as_ordered_terms(expr, order=order) + lastProcessed = self._print(args[0]) + plusNodes = [] + for arg in args[1:]: + if arg.could_extract_minus_sign(): + # use minus + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('minus')) + x.appendChild(lastProcessed) + x.appendChild(self._print(-arg)) + # invert expression since this is now minused + lastProcessed = x + if arg == args[-1]: + plusNodes.append(lastProcessed) + else: + plusNodes.append(lastProcessed) + lastProcessed = self._print(arg) + if arg == args[-1]: + plusNodes.append(self._print(arg)) + if len(plusNodes) == 1: + return lastProcessed + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('plus')) + while plusNodes: + x.appendChild(plusNodes.pop(0)) + return x + + def _print_Piecewise(self, expr): + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + root = self.dom.createElement('piecewise') + for i, (e, c) in enumerate(expr.args): + if i == len(expr.args) - 1 and c == True: + piece = self.dom.createElement('otherwise') + piece.appendChild(self._print(e)) + else: + piece = self.dom.createElement('piece') + piece.appendChild(self._print(e)) + piece.appendChild(self._print(c)) + root.appendChild(piece) + return root + + def _print_MatrixBase(self, m): + x = self.dom.createElement('matrix') + for i in range(m.rows): + x_r = self.dom.createElement('matrixrow') + for j in range(m.cols): + x_r.appendChild(self._print(m[i, j])) + x.appendChild(x_r) + return x + + def _print_Rational(self, e): + if e.q == 1: + # don't divide + x = self.dom.createElement('cn') + x.appendChild(self.dom.createTextNode(str(e.p))) + return x + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('divide')) + # numerator + xnum = self.dom.createElement('cn') + xnum.appendChild(self.dom.createTextNode(str(e.p))) + # denominator + xdenom = self.dom.createElement('cn') + xdenom.appendChild(self.dom.createTextNode(str(e.q))) + x.appendChild(xnum) + x.appendChild(xdenom) + return x + + def _print_Limit(self, e): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement(self.mathml_tag(e))) + + x_1 = self.dom.createElement('bvar') + x_2 = self.dom.createElement('lowlimit') + x_1.appendChild(self._print(e.args[1])) + x_2.appendChild(self._print(e.args[2])) + + x.appendChild(x_1) + x.appendChild(x_2) + x.appendChild(self._print(e.args[0])) + return x + + def _print_ImaginaryUnit(self, e): + return self.dom.createElement('imaginaryi') + + def _print_EulerGamma(self, e): + return self.dom.createElement('eulergamma') + + def _print_GoldenRatio(self, e): + """We use unicode #x3c6 for Greek letter phi as defined here + https://www.w3.org/2003/entities/2007doc/isogrk1.html""" + x = self.dom.createElement('cn') + x.appendChild(self.dom.createTextNode("\N{GREEK SMALL LETTER PHI}")) + return x + + def _print_Exp1(self, e): + return self.dom.createElement('exponentiale') + + def _print_Pi(self, e): + return self.dom.createElement('pi') + + def _print_Infinity(self, e): + return self.dom.createElement('infinity') + + def _print_NaN(self, e): + return self.dom.createElement('notanumber') + + def _print_EmptySet(self, e): + return self.dom.createElement('emptyset') + + def _print_BooleanTrue(self, e): + return self.dom.createElement('true') + + def _print_BooleanFalse(self, e): + return self.dom.createElement('false') + + def _print_NegativeInfinity(self, e): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('minus')) + x.appendChild(self.dom.createElement('infinity')) + return x + + def _print_Integral(self, e): + def lime_recur(limits): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement(self.mathml_tag(e))) + bvar_elem = self.dom.createElement('bvar') + bvar_elem.appendChild(self._print(limits[0][0])) + x.appendChild(bvar_elem) + + if len(limits[0]) == 3: + low_elem = self.dom.createElement('lowlimit') + low_elem.appendChild(self._print(limits[0][1])) + x.appendChild(low_elem) + up_elem = self.dom.createElement('uplimit') + up_elem.appendChild(self._print(limits[0][2])) + x.appendChild(up_elem) + if len(limits[0]) == 2: + up_elem = self.dom.createElement('uplimit') + up_elem.appendChild(self._print(limits[0][1])) + x.appendChild(up_elem) + if len(limits) == 1: + x.appendChild(self._print(e.function)) + else: + x.appendChild(lime_recur(limits[1:])) + return x + + limits = list(e.limits) + limits.reverse() + return lime_recur(limits) + + def _print_Sum(self, e): + # Printer can be shared because Sum and Integral have the + # same internal representation. + return self._print_Integral(e) + + def _print_Symbol(self, sym): + ci = self.dom.createElement(self.mathml_tag(sym)) + + def join(items): + if len(items) > 1: + mrow = self.dom.createElement('mml:mrow') + for i, item in enumerate(items): + if i > 0: + mo = self.dom.createElement('mml:mo') + mo.appendChild(self.dom.createTextNode(" ")) + mrow.appendChild(mo) + mi = self.dom.createElement('mml:mi') + mi.appendChild(self.dom.createTextNode(item)) + mrow.appendChild(mi) + return mrow + else: + mi = self.dom.createElement('mml:mi') + mi.appendChild(self.dom.createTextNode(items[0])) + return mi + + # translate name, supers and subs to unicode characters + def translate(s): + if s in greek_unicode: + return greek_unicode.get(s) + else: + return s + + name, supers, subs = self._split_super_sub(sym.name) + name = translate(name) + supers = [translate(sup) for sup in supers] + subs = [translate(sub) for sub in subs] + + mname = self.dom.createElement('mml:mi') + mname.appendChild(self.dom.createTextNode(name)) + if not supers: + if not subs: + ci.appendChild(self.dom.createTextNode(name)) + else: + msub = self.dom.createElement('mml:msub') + msub.appendChild(mname) + msub.appendChild(join(subs)) + ci.appendChild(msub) + else: + if not subs: + msup = self.dom.createElement('mml:msup') + msup.appendChild(mname) + msup.appendChild(join(supers)) + ci.appendChild(msup) + else: + msubsup = self.dom.createElement('mml:msubsup') + msubsup.appendChild(mname) + msubsup.appendChild(join(subs)) + msubsup.appendChild(join(supers)) + ci.appendChild(msubsup) + return ci + + _print_MatrixSymbol = _print_Symbol + _print_RandomSymbol = _print_Symbol + + def _print_Pow(self, e): + # Here we use root instead of power if the exponent is the reciprocal + # of an integer + if (self._settings['root_notation'] and e.exp.is_Rational + and e.exp.p == 1): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('root')) + if e.exp.q != 2: + xmldeg = self.dom.createElement('degree') + xmlcn = self.dom.createElement('cn') + xmlcn.appendChild(self.dom.createTextNode(str(e.exp.q))) + xmldeg.appendChild(xmlcn) + x.appendChild(xmldeg) + x.appendChild(self._print(e.base)) + return x + + x = self.dom.createElement('apply') + x_1 = self.dom.createElement(self.mathml_tag(e)) + x.appendChild(x_1) + x.appendChild(self._print(e.base)) + x.appendChild(self._print(e.exp)) + return x + + def _print_Number(self, e): + x = self.dom.createElement(self.mathml_tag(e)) + x.appendChild(self.dom.createTextNode(str(e))) + return x + + def _print_Float(self, e): + x = self.dom.createElement(self.mathml_tag(e)) + repr_e = mlib_to_str(e._mpf_, repr_dps(e._prec)) + x.appendChild(self.dom.createTextNode(repr_e)) + return x + + def _print_Derivative(self, e): + x = self.dom.createElement('apply') + diff_symbol = self.mathml_tag(e) + if requires_partial(e.expr): + diff_symbol = 'partialdiff' + x.appendChild(self.dom.createElement(diff_symbol)) + x_1 = self.dom.createElement('bvar') + + for sym, times in reversed(e.variable_count): + x_1.appendChild(self._print(sym)) + if times > 1: + degree = self.dom.createElement('degree') + degree.appendChild(self._print(sympify(times))) + x_1.appendChild(degree) + + x.appendChild(x_1) + x.appendChild(self._print(e.expr)) + return x + + def _print_Function(self, e): + x = self.dom.createElement("apply") + x.appendChild(self.dom.createElement(self.mathml_tag(e))) + for arg in e.args: + x.appendChild(self._print(arg)) + return x + + def _print_Basic(self, e): + x = self.dom.createElement(self.mathml_tag(e)) + for arg in e.args: + x.appendChild(self._print(arg)) + return x + + def _print_AssocOp(self, e): + x = self.dom.createElement('apply') + x_1 = self.dom.createElement(self.mathml_tag(e)) + x.appendChild(x_1) + for arg in e.args: + x.appendChild(self._print(arg)) + return x + + def _print_Relational(self, e): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement(self.mathml_tag(e))) + x.appendChild(self._print(e.lhs)) + x.appendChild(self._print(e.rhs)) + return x + + def _print_list(self, seq): + """MathML reference for the element: + https://www.w3.org/TR/MathML2/chapter4.html#contm.list""" + dom_element = self.dom.createElement('list') + for item in seq: + dom_element.appendChild(self._print(item)) + return dom_element + + def _print_int(self, p): + dom_element = self.dom.createElement(self.mathml_tag(p)) + dom_element.appendChild(self.dom.createTextNode(str(p))) + return dom_element + + _print_Implies = _print_AssocOp + _print_Not = _print_AssocOp + _print_Xor = _print_AssocOp + + def _print_FiniteSet(self, e): + x = self.dom.createElement('set') + for arg in e.args: + x.appendChild(self._print(arg)) + return x + + def _print_Complement(self, e): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('setdiff')) + for arg in e.args: + x.appendChild(self._print(arg)) + return x + + def _print_ProductSet(self, e): + x = self.dom.createElement('apply') + x.appendChild(self.dom.createElement('cartesianproduct')) + for arg in e.args: + x.appendChild(self._print(arg)) + return x + + def _print_Lambda(self, e): + # MathML reference for the lambda element: + # https://www.w3.org/TR/MathML2/chapter4.html#id.4.2.1.7 + x = self.dom.createElement(self.mathml_tag(e)) + for arg in e.signature: + x_1 = self.dom.createElement('bvar') + x_1.appendChild(self._print(arg)) + x.appendChild(x_1) + x.appendChild(self._print(e.expr)) + return x + + # XXX Symmetric difference is not supported for MathML content printers. + + +class MathMLPresentationPrinter(MathMLPrinterBase): + """Prints an expression to the Presentation MathML markup language. + + References: https://www.w3.org/TR/MathML2/chapter3.html + """ + printmethod = "_mathml_presentation" + + def mathml_tag(self, e): + """Returns the MathML tag for an expression.""" + translate = { + 'Number': 'mn', + 'Limit': '→', + 'Derivative': 'ⅆ', + 'int': 'mn', + 'Symbol': 'mi', + 'Integral': '∫', + 'Sum': '∑', + 'sin': 'sin', + 'cos': 'cos', + 'tan': 'tan', + 'cot': 'cot', + 'asin': 'arcsin', + 'asinh': 'arcsinh', + 'acos': 'arccos', + 'acosh': 'arccosh', + 'atan': 'arctan', + 'atanh': 'arctanh', + 'acot': 'arccot', + 'atan2': 'arctan', + 'Equality': '=', + 'Unequality': '≠', + 'GreaterThan': '≥', + 'LessThan': '≤', + 'StrictGreaterThan': '>', + 'StrictLessThan': '<', + 'lerchphi': 'Φ', + 'zeta': 'ζ', + 'dirichlet_eta': 'η', + 'elliptic_k': 'Κ', + 'lowergamma': 'γ', + 'uppergamma': 'Γ', + 'gamma': 'Γ', + 'totient': 'ϕ', + 'reduced_totient': 'λ', + 'primenu': 'ν', + 'primeomega': 'Ω', + 'fresnels': 'S', + 'fresnelc': 'C', + 'LambertW': 'W', + 'Heaviside': 'Θ', + 'BooleanTrue': 'True', + 'BooleanFalse': 'False', + 'NoneType': 'None', + 'mathieus': 'S', + 'mathieuc': 'C', + 'mathieusprime': 'S′', + 'mathieucprime': 'C′', + 'Lambda': 'lambda', + } + + def mul_symbol_selection(): + if (self._settings["mul_symbol"] is None or + self._settings["mul_symbol"] == 'None'): + return '⁢' + elif self._settings["mul_symbol"] == 'times': + return '×' + elif self._settings["mul_symbol"] == 'dot': + return '·' + elif self._settings["mul_symbol"] == 'ldot': + return '․' + elif not isinstance(self._settings["mul_symbol"], str): + raise TypeError + else: + return self._settings["mul_symbol"] + for cls in e.__class__.__mro__: + n = cls.__name__ + if n in translate: + return translate[n] + # Not found in the MRO set + if e.__class__.__name__ == "Mul": + return mul_symbol_selection() + n = e.__class__.__name__ + return n.lower() + + def _l_paren(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('(')) + return mo + + def _r_paren(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(')')) + return mo + + def _l_brace(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('{')) + return mo + + def _r_brace(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('}')) + return mo + + def _comma(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(',')) + return mo + + def _bar(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('|')) + return mo + + def _semicolon(self): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(';')) + return mo + + def _paren_comma_separated(self, *args): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self._l_paren()) + for i, arg in enumerate(args): + if i: + mrow.appendChild(self._comma()) + mrow.appendChild(self._print(arg)) + mrow.appendChild(self._r_paren()) + return mrow + + def _paren_bar_separated(self, *args): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self._l_paren()) + for i, arg in enumerate(args): + if i: + mrow.appendChild(self._bar()) + mrow.appendChild(self._print(arg)) + mrow.appendChild(self._r_paren()) + return mrow + + def parenthesize(self, item, level, strict=False): + prec_val = precedence_traditional(item) + if (prec_val < level) or ((not strict) and prec_val <= level): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self._l_paren()) + mrow.appendChild(self._print(item)) + mrow.appendChild(self._r_paren()) + return mrow + return self._print(item) + + def _print_Mul(self, expr): + + def multiply(expr, mrow): + from sympy.simplify import fraction + numer, denom = fraction(expr) + if denom is not S.One: + frac = self.dom.createElement('mfrac') + if self._settings["fold_short_frac"] and len(str(expr)) < 7: + frac.setAttribute('bevelled', 'true') + xnum = self._print(numer) + xden = self._print(denom) + frac.appendChild(xnum) + frac.appendChild(xden) + mrow.appendChild(frac) + return mrow + + coeff, terms = expr.as_coeff_mul() + if coeff is S.One and len(terms) == 1: + mrow.appendChild(self._print(terms[0])) + return mrow + if self.order != 'old': + terms = Mul._from_args(terms).as_ordered_factors() + + if coeff != 1: + x = self._print(coeff) + y = self.dom.createElement('mo') + y.appendChild(self.dom.createTextNode(self.mathml_tag(expr))) + mrow.appendChild(x) + mrow.appendChild(y) + for term in terms: + mrow.appendChild(self.parenthesize(term, PRECEDENCE['Mul'])) + if not term == terms[-1]: + y = self.dom.createElement('mo') + y.appendChild(self.dom.createTextNode(self.mathml_tag(expr))) + mrow.appendChild(y) + return mrow + mrow = self.dom.createElement('mrow') + if expr.could_extract_minus_sign(): + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode('-')) + mrow.appendChild(x) + mrow = multiply(-expr, mrow) + else: + mrow = multiply(expr, mrow) + + return mrow + + def _print_Add(self, expr, order=None): + mrow = self.dom.createElement('mrow') + args = self._as_ordered_terms(expr, order=order) + mrow.appendChild(self._print(args[0])) + for arg in args[1:]: + if arg.could_extract_minus_sign(): + # use minus + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode('-')) + y = self._print(-arg) + # invert expression since this is now minused + else: + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode('+')) + y = self._print(arg) + mrow.appendChild(x) + mrow.appendChild(y) + + return mrow + + def _print_MatrixBase(self, m): + table = self.dom.createElement('mtable') + for i in range(m.rows): + x = self.dom.createElement('mtr') + for j in range(m.cols): + y = self.dom.createElement('mtd') + y.appendChild(self._print(m[i, j])) + x.appendChild(y) + table.appendChild(x) + mat_delim = self._settings["mat_delim"] + if mat_delim == '': + return table + left = self.dom.createElement('mo') + right = self.dom.createElement('mo') + if mat_delim == "[": + left.appendChild(self.dom.createTextNode("[")) + right.appendChild(self.dom.createTextNode("]")) + else: + left.appendChild(self.dom.createTextNode("(")) + right.appendChild(self.dom.createTextNode(")")) + mrow = self.dom.createElement('mrow') + mrow.appendChild(left) + mrow.appendChild(table) + mrow.appendChild(right) + return mrow + + def _get_printed_Rational(self, e, folded=None): + if e.p < 0: + p = -e.p + else: + p = e.p + x = self.dom.createElement('mfrac') + if folded or self._settings["fold_short_frac"]: + x.setAttribute('bevelled', 'true') + x.appendChild(self._print(p)) + x.appendChild(self._print(e.q)) + if e.p < 0: + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('-')) + mrow.appendChild(mo) + mrow.appendChild(x) + return mrow + else: + return x + + def _print_Rational(self, e): + if e.q == 1: + # don't divide + return self._print(e.p) + + return self._get_printed_Rational(e, self._settings["fold_short_frac"]) + + def _print_Limit(self, e): + mrow = self.dom.createElement('mrow') + munder = self.dom.createElement('munder') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode('lim')) + + x = self.dom.createElement('mrow') + x_1 = self._print(e.args[1]) + arrow = self.dom.createElement('mo') + arrow.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + x_2 = self._print(e.args[2]) + x.appendChild(x_1) + x.appendChild(arrow) + x.appendChild(x_2) + + munder.appendChild(mi) + munder.appendChild(x) + mrow.appendChild(munder) + mrow.appendChild(self._print(e.args[0])) + + return mrow + + def _print_ImaginaryUnit(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('ⅈ')) + return x + + def _print_GoldenRatio(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('Φ')) + return x + + def _print_Exp1(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('ⅇ')) + return x + + def _print_Pi(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('π')) + return x + + def _print_Infinity(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('∞')) + return x + + def _print_NegativeInfinity(self, e): + mrow = self.dom.createElement('mrow') + y = self.dom.createElement('mo') + y.appendChild(self.dom.createTextNode('-')) + x = self._print_Infinity(e) + mrow.appendChild(y) + mrow.appendChild(x) + return mrow + + def _print_HBar(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('ℏ')) + return x + + def _print_EulerGamma(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('γ')) + return x + + def _print_TribonacciConstant(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('TribonacciConstant')) + return x + + def _print_Dagger(self, e): + msup = self.dom.createElement('msup') + msup.appendChild(self._print(e.args[0])) + msup.appendChild(self.dom.createTextNode('†')) + return msup + + def _print_Contains(self, e): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self._print(e.args[0])) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∈')) + mrow.appendChild(mo) + mrow.appendChild(self._print(e.args[1])) + return mrow + + def _print_HilbertSpace(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('ℋ')) + return x + + def _print_ComplexSpace(self, e): + msup = self.dom.createElement('msup') + msup.appendChild(self.dom.createTextNode('𝒞')) + msup.appendChild(self._print(e.args[0])) + return msup + + def _print_FockSpace(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('ℱ')) + return x + + + def _print_Integral(self, expr): + intsymbols = {1: "∫", 2: "∬", 3: "∭"} + + mrow = self.dom.createElement('mrow') + if len(expr.limits) <= 3 and all(len(lim) == 1 for lim in expr.limits): + # Only up to three-integral signs exists + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(intsymbols[len(expr.limits)])) + mrow.appendChild(mo) + else: + # Either more than three or limits provided + for lim in reversed(expr.limits): + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(intsymbols[1])) + if len(lim) == 1: + mrow.appendChild(mo) + if len(lim) == 2: + msup = self.dom.createElement('msup') + msup.appendChild(mo) + msup.appendChild(self._print(lim[1])) + mrow.appendChild(msup) + if len(lim) == 3: + msubsup = self.dom.createElement('msubsup') + msubsup.appendChild(mo) + msubsup.appendChild(self._print(lim[1])) + msubsup.appendChild(self._print(lim[2])) + mrow.appendChild(msubsup) + # print function + mrow.appendChild(self.parenthesize(expr.function, PRECEDENCE["Mul"], + strict=True)) + # print integration variables + for lim in reversed(expr.limits): + d = self.dom.createElement('mo') + d.appendChild(self.dom.createTextNode('ⅆ')) + mrow.appendChild(d) + mrow.appendChild(self._print(lim[0])) + return mrow + + def _print_Sum(self, e): + limits = list(e.limits) + subsup = self.dom.createElement('munderover') + low_elem = self._print(limits[0][1]) + up_elem = self._print(limits[0][2]) + summand = self.dom.createElement('mo') + summand.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + + low = self.dom.createElement('mrow') + var = self._print(limits[0][0]) + equal = self.dom.createElement('mo') + equal.appendChild(self.dom.createTextNode('=')) + low.appendChild(var) + low.appendChild(equal) + low.appendChild(low_elem) + + subsup.appendChild(summand) + subsup.appendChild(low) + subsup.appendChild(up_elem) + + mrow = self.dom.createElement('mrow') + mrow.appendChild(subsup) + mrow.appendChild(self.parenthesize(e.function, precedence_traditional(e))) + return mrow + + def _print_Symbol(self, sym, style='plain'): + def join(items): + if len(items) > 1: + mrow = self.dom.createElement('mrow') + for i, item in enumerate(items): + if i > 0: + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(" ")) + mrow.appendChild(mo) + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(item)) + mrow.appendChild(mi) + return mrow + else: + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(items[0])) + return mi + + # translate name, supers and subs to unicode characters + def translate(s): + if s in greek_unicode: + return greek_unicode.get(s) + else: + return s + + name, supers, subs = self._split_super_sub(sym.name) + name = translate(name) + supers = [translate(sup) for sup in supers] + subs = [translate(sub) for sub in subs] + + mname = self.dom.createElement('mi') + mname.appendChild(self.dom.createTextNode(name)) + if len(supers) == 0: + if len(subs) == 0: + x = mname + else: + x = self.dom.createElement('msub') + x.appendChild(mname) + x.appendChild(join(subs)) + else: + if len(subs) == 0: + x = self.dom.createElement('msup') + x.appendChild(mname) + x.appendChild(join(supers)) + else: + x = self.dom.createElement('msubsup') + x.appendChild(mname) + x.appendChild(join(subs)) + x.appendChild(join(supers)) + # Set bold font? + if style == 'bold': + x.setAttribute('mathvariant', 'bold') + return x + + def _print_MatrixSymbol(self, sym): + return self._print_Symbol(sym, + style=self._settings['mat_symbol_style']) + + _print_RandomSymbol = _print_Symbol + + def _print_conjugate(self, expr): + enc = self.dom.createElement('menclose') + enc.setAttribute('notation', 'top') + enc.appendChild(self._print(expr.args[0])) + return enc + + def _print_operator_after(self, op, expr): + row = self.dom.createElement('mrow') + row.appendChild(self.parenthesize(expr, PRECEDENCE["Func"])) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(op)) + row.appendChild(mo) + return row + + def _print_factorial(self, expr): + return self._print_operator_after('!', expr.args[0]) + + def _print_factorial2(self, expr): + return self._print_operator_after('!!', expr.args[0]) + + def _print_binomial(self, expr): + frac = self.dom.createElement('mfrac') + frac.setAttribute('linethickness', '0') + frac.appendChild(self._print(expr.args[0])) + frac.appendChild(self._print(expr.args[1])) + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(frac) + brac.appendChild(self._r_paren()) + return brac + + def _print_Pow(self, e): + # Here we use root instead of power if the exponent is the + # reciprocal of an integer + if (e.exp.is_Rational and abs(e.exp.p) == 1 and e.exp.q != 1 and + self._settings['root_notation']): + if e.exp.q == 2: + x = self.dom.createElement('msqrt') + x.appendChild(self._print(e.base)) + if e.exp.q != 2: + x = self.dom.createElement('mroot') + x.appendChild(self._print(e.base)) + x.appendChild(self._print(e.exp.q)) + if e.exp.p == -1: + frac = self.dom.createElement('mfrac') + frac.appendChild(self._print(1)) + frac.appendChild(x) + return frac + else: + return x + + if e.exp.is_Rational and e.exp.q != 1: + if e.exp.is_negative: + top = self.dom.createElement('mfrac') + top.appendChild(self._print(1)) + x = self.dom.createElement('msup') + x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) + x.appendChild(self._get_printed_Rational(-e.exp, + self._settings['fold_frac_powers'])) + top.appendChild(x) + return top + else: + x = self.dom.createElement('msup') + x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) + x.appendChild(self._get_printed_Rational(e.exp, + self._settings['fold_frac_powers'])) + return x + + if e.exp.is_negative: + top = self.dom.createElement('mfrac') + top.appendChild(self._print(1)) + if e.exp == -1: + top.appendChild(self._print(e.base)) + else: + x = self.dom.createElement('msup') + x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) + x.appendChild(self._print(-e.exp)) + top.appendChild(x) + return top + + x = self.dom.createElement('msup') + x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) + x.appendChild(self._print(e.exp)) + return x + + def _print_Number(self, e): + x = self.dom.createElement(self.mathml_tag(e)) + x.appendChild(self.dom.createTextNode(str(e))) + return x + + def _print_AccumulationBounds(self, i): + left = self.dom.createElement('mo') + left.appendChild(self.dom.createTextNode('\u27e8')) + right = self.dom.createElement('mo') + right.appendChild(self.dom.createTextNode('\u27e9')) + brac = self.dom.createElement('mrow') + brac.appendChild(left) + brac.appendChild(self._print(i.min)) + brac.appendChild(self._comma()) + brac.appendChild(self._print(i.max)) + brac.appendChild(right) + return brac + + def _print_Derivative(self, e): + + if requires_partial(e.expr): + d = '∂' + else: + d = self.mathml_tag(e) + + # Determine denominator + m = self.dom.createElement('mrow') + dim = 0 # Total diff dimension, for numerator + for sym, num in reversed(e.variable_count): + dim += num + if num >= 2: + x = self.dom.createElement('msup') + xx = self.dom.createElement('mo') + xx.appendChild(self.dom.createTextNode(d)) + x.appendChild(xx) + x.appendChild(self._print(num)) + else: + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode(d)) + m.appendChild(x) + y = self._print(sym) + m.appendChild(y) + + mnum = self.dom.createElement('mrow') + if dim >= 2: + x = self.dom.createElement('msup') + xx = self.dom.createElement('mo') + xx.appendChild(self.dom.createTextNode(d)) + x.appendChild(xx) + x.appendChild(self._print(dim)) + else: + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode(d)) + + mnum.appendChild(x) + mrow = self.dom.createElement('mrow') + frac = self.dom.createElement('mfrac') + frac.appendChild(mnum) + frac.appendChild(m) + mrow.appendChild(frac) + + # Print function + mrow.appendChild(self._print(e.expr)) + + return mrow + + def _print_Function(self, e): + x = self.dom.createElement('mi') + if self.mathml_tag(e) == 'log' and self._settings["ln_notation"]: + x.appendChild(self.dom.createTextNode('ln')) + else: + x.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + mrow = self.dom.createElement('mrow') + mrow.appendChild(x) + mrow.appendChild(self._paren_comma_separated(*e.args)) + return mrow + + def _print_Float(self, expr): + # Based off of that in StrPrinter + dps = prec_to_dps(expr._prec) + str_real = mlib_to_str(expr._mpf_, dps, strip_zeros=True) + + # Must always have a mul symbol (as 2.5 10^{20} just looks odd) + # thus we use the number separator + separator = self._settings['mul_symbol_mathml_numbers'] + mrow = self.dom.createElement('mrow') + if 'e' in str_real: + (mant, exp) = str_real.split('e') + + if exp[0] == '+': + exp = exp[1:] + + mn = self.dom.createElement('mn') + mn.appendChild(self.dom.createTextNode(mant)) + mrow.appendChild(mn) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode(separator)) + mrow.appendChild(mo) + msup = self.dom.createElement('msup') + mn = self.dom.createElement('mn') + mn.appendChild(self.dom.createTextNode("10")) + msup.appendChild(mn) + mn = self.dom.createElement('mn') + mn.appendChild(self.dom.createTextNode(exp)) + msup.appendChild(mn) + mrow.appendChild(msup) + return mrow + elif str_real == "+inf": + return self._print_Infinity(None) + elif str_real == "-inf": + return self._print_NegativeInfinity(None) + else: + mn = self.dom.createElement('mn') + mn.appendChild(self.dom.createTextNode(str_real)) + return mn + + def _print_polylog(self, expr): + mrow = self.dom.createElement('mrow') + m = self.dom.createElement('msub') + + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode('Li')) + m.appendChild(mi) + m.appendChild(self._print(expr.args[0])) + mrow.appendChild(m) + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(expr.args[1])) + brac.appendChild(self._r_paren()) + mrow.appendChild(brac) + return mrow + + def _print_Basic(self, e): + mrow = self.dom.createElement('mrow') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + mrow.appendChild(mi) + mrow.appendChild(self._paren_comma_separated(*e.args)) + return mrow + + def _print_Tuple(self, e): + return self._paren_comma_separated(*e.args) + + def _print_Interval(self, i): + right = self.dom.createElement('mo') + if i.right_open: + right.appendChild(self.dom.createTextNode(')')) + else: + right.appendChild(self.dom.createTextNode(']')) + left = self.dom.createElement('mo') + if i.left_open: + left.appendChild(self.dom.createTextNode('(')) + else: + left.appendChild(self.dom.createTextNode('[')) + mrow = self.dom.createElement('mrow') + mrow.appendChild(left) + mrow.appendChild(self._print(i.start)) + mrow.appendChild(self._comma()) + mrow.appendChild(self._print(i.end)) + mrow.appendChild(right) + return mrow + + def _print_Abs(self, expr, exp=None): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self._bar()) + mrow.appendChild(self._print(expr.args[0])) + mrow.appendChild(self._bar()) + return mrow + + _print_Determinant = _print_Abs + + def _print_re_im(self, c, expr): + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(expr)) + brac.appendChild(self._r_paren()) + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(c)) + mrow = self.dom.createElement('mrow') + mrow.appendChild(mi) + mrow.appendChild(brac) + return mrow + + def _print_re(self, expr, exp=None): + return self._print_re_im('\u211C', expr.args[0]) + + def _print_im(self, expr, exp=None): + return self._print_re_im('\u2111', expr.args[0]) + + def _print_AssocOp(self, e): + mrow = self.dom.createElement('mrow') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + mrow.appendChild(mi) + for arg in e.args: + mrow.appendChild(self._print(arg)) + return mrow + + def _print_SetOp(self, expr, symbol, prec): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self.parenthesize(expr.args[0], prec)) + for arg in expr.args[1:]: + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode(symbol)) + y = self.parenthesize(arg, prec) + mrow.appendChild(x) + mrow.appendChild(y) + return mrow + + def _print_Union(self, expr): + prec = PRECEDENCE_TRADITIONAL['Union'] + return self._print_SetOp(expr, '∪', prec) + + def _print_Intersection(self, expr): + prec = PRECEDENCE_TRADITIONAL['Intersection'] + return self._print_SetOp(expr, '∩', prec) + + def _print_Complement(self, expr): + prec = PRECEDENCE_TRADITIONAL['Complement'] + return self._print_SetOp(expr, '∖', prec) + + def _print_SymmetricDifference(self, expr): + prec = PRECEDENCE_TRADITIONAL['SymmetricDifference'] + return self._print_SetOp(expr, '∆', prec) + + def _print_ProductSet(self, expr): + prec = PRECEDENCE_TRADITIONAL['ProductSet'] + return self._print_SetOp(expr, '×', prec) + + def _print_FiniteSet(self, s): + return self._print_set(s.args) + + def _print_set(self, s): + items = sorted(s, key=default_sort_key) + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_brace()) + for i, item in enumerate(items): + if i: + brac.appendChild(self._comma()) + brac.appendChild(self._print(item)) + brac.appendChild(self._r_brace()) + return brac + + _print_frozenset = _print_set + + def _print_LogOp(self, args, symbol): + mrow = self.dom.createElement('mrow') + if args[0].is_Boolean and not args[0].is_Not: + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(args[0])) + brac.appendChild(self._r_paren()) + mrow.appendChild(brac) + else: + mrow.appendChild(self._print(args[0])) + for arg in args[1:]: + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode(symbol)) + if arg.is_Boolean and not arg.is_Not: + y = self.dom.createElement('mrow') + y.appendChild(self._l_paren()) + y.appendChild(self._print(arg)) + y.appendChild(self._r_paren()) + else: + y = self._print(arg) + mrow.appendChild(x) + mrow.appendChild(y) + return mrow + + def _print_BasisDependent(self, expr): + from sympy.vector import Vector + + if expr == expr.zero: + # Not clear if this is ever called + return self._print(expr.zero) + if isinstance(expr, Vector): + items = expr.separate().items() + else: + items = [(0, expr)] + + mrow = self.dom.createElement('mrow') + for system, vect in items: + inneritems = list(vect.components.items()) + inneritems.sort(key = lambda x:x[0].__str__()) + for i, (k, v) in enumerate(inneritems): + if v == 1: + if i: # No + for first item + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('+')) + mrow.appendChild(mo) + mrow.appendChild(self._print(k)) + elif v == -1: + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('-')) + mrow.appendChild(mo) + mrow.appendChild(self._print(k)) + else: + if i: # No + for first item + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('+')) + mrow.appendChild(mo) + mbrac = self.dom.createElement('mrow') + mbrac.appendChild(self._l_paren()) + mbrac.appendChild(self._print(v)) + mbrac.appendChild(self._r_paren()) + mrow.appendChild(mbrac) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('⁢')) + mrow.appendChild(mo) + mrow.appendChild(self._print(k)) + return mrow + + + def _print_And(self, expr): + args = sorted(expr.args, key=default_sort_key) + return self._print_LogOp(args, '∧') + + def _print_Or(self, expr): + args = sorted(expr.args, key=default_sort_key) + return self._print_LogOp(args, '∨') + + def _print_Xor(self, expr): + args = sorted(expr.args, key=default_sort_key) + return self._print_LogOp(args, '⊻') + + def _print_Implies(self, expr): + return self._print_LogOp(expr.args, '⇒') + + def _print_Equivalent(self, expr): + args = sorted(expr.args, key=default_sort_key) + return self._print_LogOp(args, '⇔') + + def _print_Not(self, e): + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('¬')) + mrow.appendChild(mo) + if (e.args[0].is_Boolean): + x = self.dom.createElement('mrow') + x.appendChild(self._l_paren()) + x.appendChild(self._print(e.args[0])) + x.appendChild(self._r_paren()) + else: + x = self._print(e.args[0]) + mrow.appendChild(x) + return mrow + + def _print_bool(self, e): + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + return mi + + _print_BooleanTrue = _print_bool + _print_BooleanFalse = _print_bool + + def _print_NoneType(self, e): + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + return mi + + def _print_Range(self, s): + dots = "\u2026" + if s.start.is_infinite and s.stop.is_infinite: + if s.step.is_positive: + printset = dots, -1, 0, 1, dots + else: + printset = dots, 1, 0, -1, dots + elif s.start.is_infinite: + printset = dots, s[-1] - s.step, s[-1] + elif s.stop.is_infinite: + it = iter(s) + printset = next(it), next(it), dots + elif len(s) > 4: + it = iter(s) + printset = next(it), next(it), dots, s[-1] + else: + printset = tuple(s) + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_brace()) + for i, el in enumerate(printset): + if i: + brac.appendChild(self._comma()) + if el == dots: + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(dots)) + brac.appendChild(mi) + else: + brac.appendChild(self._print(el)) + brac.appendChild(self._r_brace()) + return brac + + def _hprint_variadic_function(self, expr): + args = sorted(expr.args, key=default_sort_key) + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode((str(expr.func)).lower())) + mrow.appendChild(mo) + mrow.appendChild(self._paren_comma_separated(*args)) + return mrow + + _print_Min = _print_Max = _hprint_variadic_function + + def _print_exp(self, expr): + msup = self.dom.createElement('msup') + msup.appendChild(self._print_Exp1(None)) + msup.appendChild(self._print(expr.args[0])) + return msup + + def _print_Relational(self, e): + mrow = self.dom.createElement('mrow') + mrow.appendChild(self._print(e.lhs)) + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode(self.mathml_tag(e))) + mrow.appendChild(x) + mrow.appendChild(self._print(e.rhs)) + return mrow + + def _print_int(self, p): + dom_element = self.dom.createElement(self.mathml_tag(p)) + dom_element.appendChild(self.dom.createTextNode(str(p))) + return dom_element + + def _print_BaseScalar(self, e): + msub = self.dom.createElement('msub') + index, system = e._id + mi = self.dom.createElement('mi') + mi.setAttribute('mathvariant', 'bold') + mi.appendChild(self.dom.createTextNode(system._variable_names[index])) + msub.appendChild(mi) + mi = self.dom.createElement('mi') + mi.setAttribute('mathvariant', 'bold') + mi.appendChild(self.dom.createTextNode(system._name)) + msub.appendChild(mi) + return msub + + def _print_BaseVector(self, e): + msub = self.dom.createElement('msub') + index, system = e._id + mover = self.dom.createElement('mover') + mi = self.dom.createElement('mi') + mi.setAttribute('mathvariant', 'bold') + mi.appendChild(self.dom.createTextNode(system._vector_names[index])) + mover.appendChild(mi) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('^')) + mover.appendChild(mo) + msub.appendChild(mover) + mi = self.dom.createElement('mi') + mi.setAttribute('mathvariant', 'bold') + mi.appendChild(self.dom.createTextNode(system._name)) + msub.appendChild(mi) + return msub + + def _print_VectorZero(self, e): + mover = self.dom.createElement('mover') + mi = self.dom.createElement('mi') + mi.setAttribute('mathvariant', 'bold') + mi.appendChild(self.dom.createTextNode("0")) + mover.appendChild(mi) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('^')) + mover.appendChild(mo) + return mover + + def _print_Cross(self, expr): + mrow = self.dom.createElement('mrow') + vec1 = expr._expr1 + vec2 = expr._expr2 + mrow.appendChild(self.parenthesize(vec1, PRECEDENCE['Mul'])) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('×')) + mrow.appendChild(mo) + mrow.appendChild(self.parenthesize(vec2, PRECEDENCE['Mul'])) + return mrow + + def _print_Curl(self, expr): + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∇')) + mrow.appendChild(mo) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('×')) + mrow.appendChild(mo) + mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) + return mrow + + def _print_Divergence(self, expr): + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∇')) + mrow.appendChild(mo) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('·')) + mrow.appendChild(mo) + mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) + return mrow + + def _print_Dot(self, expr): + mrow = self.dom.createElement('mrow') + vec1 = expr._expr1 + vec2 = expr._expr2 + mrow.appendChild(self.parenthesize(vec1, PRECEDENCE['Mul'])) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('·')) + mrow.appendChild(mo) + mrow.appendChild(self.parenthesize(vec2, PRECEDENCE['Mul'])) + return mrow + + def _print_Gradient(self, expr): + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∇')) + mrow.appendChild(mo) + mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) + return mrow + + def _print_Laplacian(self, expr): + mrow = self.dom.createElement('mrow') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∆')) + mrow.appendChild(mo) + mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) + return mrow + + def _print_Integers(self, e): + x = self.dom.createElement('mi') + x.setAttribute('mathvariant', 'normal') + x.appendChild(self.dom.createTextNode('ℤ')) + return x + + def _print_Complexes(self, e): + x = self.dom.createElement('mi') + x.setAttribute('mathvariant', 'normal') + x.appendChild(self.dom.createTextNode('ℂ')) + return x + + def _print_Reals(self, e): + x = self.dom.createElement('mi') + x.setAttribute('mathvariant', 'normal') + x.appendChild(self.dom.createTextNode('ℝ')) + return x + + def _print_Naturals(self, e): + x = self.dom.createElement('mi') + x.setAttribute('mathvariant', 'normal') + x.appendChild(self.dom.createTextNode('ℕ')) + return x + + def _print_Naturals0(self, e): + sub = self.dom.createElement('msub') + x = self.dom.createElement('mi') + x.setAttribute('mathvariant', 'normal') + x.appendChild(self.dom.createTextNode('ℕ')) + sub.appendChild(x) + sub.appendChild(self._print(S.Zero)) + return sub + + def _print_SingularityFunction(self, expr): + shift = expr.args[0] - expr.args[1] + power = expr.args[2] + left = self.dom.createElement('mo') + left.appendChild(self.dom.createTextNode('\u27e8')) + right = self.dom.createElement('mo') + right.appendChild(self.dom.createTextNode('\u27e9')) + brac = self.dom.createElement('mrow') + brac.appendChild(left) + brac.appendChild(self._print(shift)) + brac.appendChild(right) + sup = self.dom.createElement('msup') + sup.appendChild(brac) + sup.appendChild(self._print(power)) + return sup + + def _print_NaN(self, e): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('NaN')) + return x + + def _print_number_function(self, e, name): + # Print name_arg[0] for one argument or name_arg[0](arg[1]) + # for more than one argument + sub = self.dom.createElement('msub') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode(name)) + sub.appendChild(mi) + sub.appendChild(self._print(e.args[0])) + if len(e.args) == 1: + return sub + mrow = self.dom.createElement('mrow') + mrow.appendChild(sub) + mrow.appendChild(self._paren_comma_separated(*e.args[1:])) + return mrow + + def _print_bernoulli(self, e): + return self._print_number_function(e, 'B') + + _print_bell = _print_bernoulli + + def _print_catalan(self, e): + return self._print_number_function(e, 'C') + + def _print_euler(self, e): + return self._print_number_function(e, 'E') + + def _print_fibonacci(self, e): + return self._print_number_function(e, 'F') + + def _print_lucas(self, e): + return self._print_number_function(e, 'L') + + def _print_stieltjes(self, e): + return self._print_number_function(e, 'γ') + + def _print_tribonacci(self, e): + return self._print_number_function(e, 'T') + + def _print_ComplexInfinity(self, e): + x = self.dom.createElement('mover') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∞')) + x.appendChild(mo) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('~')) + x.appendChild(mo) + return x + + def _print_EmptySet(self, e): + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode('∅')) + return x + + def _print_UniversalSet(self, e): + x = self.dom.createElement('mo') + x.appendChild(self.dom.createTextNode('𝕌')) + return x + + def _print_Adjoint(self, expr): + from sympy.matrices import MatrixSymbol + mat = expr.arg + sup = self.dom.createElement('msup') + if not isinstance(mat, MatrixSymbol): + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(mat)) + brac.appendChild(self._r_paren()) + sup.appendChild(brac) + else: + sup.appendChild(self._print(mat)) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('†')) + sup.appendChild(mo) + return sup + + def _print_Transpose(self, expr): + from sympy.matrices import MatrixSymbol + mat = expr.arg + sup = self.dom.createElement('msup') + if not isinstance(mat, MatrixSymbol): + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(mat)) + brac.appendChild(self._r_paren()) + sup.appendChild(brac) + else: + sup.appendChild(self._print(mat)) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('T')) + sup.appendChild(mo) + return sup + + def _print_Inverse(self, expr): + from sympy.matrices import MatrixSymbol + mat = expr.arg + sup = self.dom.createElement('msup') + if not isinstance(mat, MatrixSymbol): + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(mat)) + brac.appendChild(self._r_paren()) + sup.appendChild(brac) + else: + sup.appendChild(self._print(mat)) + sup.appendChild(self._print(-1)) + return sup + + def _print_MatMul(self, expr): + from sympy.matrices.expressions.matmul import MatMul + + x = self.dom.createElement('mrow') + args = expr.args + if isinstance(args[0], Mul): + args = args[0].as_ordered_factors() + list(args[1:]) + else: + args = list(args) + + if isinstance(expr, MatMul) and expr.could_extract_minus_sign(): + if args[0] == -1: + args = args[1:] + else: + args[0] = -args[0] + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('-')) + x.appendChild(mo) + + for arg in args[:-1]: + x.appendChild(self.parenthesize(arg, precedence_traditional(expr), + False)) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('⁢')) + x.appendChild(mo) + x.appendChild(self.parenthesize(args[-1], precedence_traditional(expr), + False)) + return x + + def _print_MatPow(self, expr): + from sympy.matrices import MatrixSymbol + base, exp = expr.base, expr.exp + sup = self.dom.createElement('msup') + if not isinstance(base, MatrixSymbol): + brac = self.dom.createElement('mrow') + brac.appendChild(self._l_paren()) + brac.appendChild(self._print(base)) + brac.appendChild(self._r_paren()) + sup.appendChild(brac) + else: + sup.appendChild(self._print(base)) + sup.appendChild(self._print(exp)) + return sup + + def _print_HadamardProduct(self, expr): + x = self.dom.createElement('mrow') + args = expr.args + for arg in args[:-1]: + x.appendChild( + self.parenthesize(arg, precedence_traditional(expr), False)) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('∘')) + x.appendChild(mo) + x.appendChild( + self.parenthesize(args[-1], precedence_traditional(expr), False)) + return x + + def _print_ZeroMatrix(self, Z): + x = self.dom.createElement('mn') + x.appendChild(self.dom.createTextNode('𝟘')) + return x + + def _print_OneMatrix(self, Z): + x = self.dom.createElement('mn') + x.appendChild(self.dom.createTextNode('𝟙')) + return x + + def _print_Identity(self, I): + x = self.dom.createElement('mi') + x.appendChild(self.dom.createTextNode('𝕀')) + return x + + def _print_floor(self, e): + left = self.dom.createElement('mo') + left.appendChild(self.dom.createTextNode('\u230A')) + right = self.dom.createElement('mo') + right.appendChild(self.dom.createTextNode('\u230B')) + mrow = self.dom.createElement('mrow') + mrow.appendChild(left) + mrow.appendChild(self._print(e.args[0])) + mrow.appendChild(right) + return mrow + + def _print_ceiling(self, e): + left = self.dom.createElement('mo') + left.appendChild(self.dom.createTextNode('\u2308')) + right = self.dom.createElement('mo') + right.appendChild(self.dom.createTextNode('\u2309')) + mrow = self.dom.createElement('mrow') + mrow.appendChild(left) + mrow.appendChild(self._print(e.args[0])) + mrow.appendChild(right) + return mrow + + def _print_Lambda(self, e): + mrow = self.dom.createElement('mrow') + symbols = e.args[0] + if len(symbols) == 1: + symbols = self._print(symbols[0]) + else: + symbols = self._print(symbols) + mrow.appendChild(self._l_paren()) + mrow.appendChild(symbols) + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('↦')) + mrow.appendChild(mo) + mrow.appendChild(self._print(e.args[1])) + mrow.appendChild(self._r_paren()) + return mrow + + def _print_tuple(self, e): + return self._paren_comma_separated(*e) + + def _print_IndexedBase(self, e): + return self._print(e.label) + + def _print_Indexed(self, e): + x = self.dom.createElement('msub') + x.appendChild(self._print(e.base)) + if len(e.indices) == 1: + x.appendChild(self._print(e.indices[0])) + return x + x.appendChild(self._print(e.indices)) + return x + + def _print_MatrixElement(self, e): + x = self.dom.createElement('msub') + x.appendChild(self.parenthesize(e.parent, PRECEDENCE["Atom"], strict = True)) + brac = self.dom.createElement('mrow') + for i, arg in enumerate(e.indices): + if i: + brac.appendChild(self._comma()) + brac.appendChild(self._print(arg)) + x.appendChild(brac) + return x + + def _print_elliptic_f(self, e): + x = self.dom.createElement('mrow') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode('𝖥')) + x.appendChild(mi) + x.appendChild(self._paren_bar_separated(*e.args)) + return x + + def _print_elliptic_e(self, e): + x = self.dom.createElement('mrow') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode('𝖤')) + x.appendChild(mi) + x.appendChild(self._paren_bar_separated(*e.args)) + return x + + def _print_elliptic_pi(self, e): + x = self.dom.createElement('mrow') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode('𝛱')) + x.appendChild(mi) + y = self.dom.createElement('mrow') + y.appendChild(self._l_paren()) + if len(e.args) == 2: + n, m = e.args + y.appendChild(self._print(n)) + y.appendChild(self._bar()) + y.appendChild(self._print(m)) + else: + n, m, z = e.args + y.appendChild(self._print(n)) + y.appendChild(self._semicolon()) + y.appendChild(self._print(m)) + y.appendChild(self._bar()) + y.appendChild(self._print(z)) + y.appendChild(self._r_paren()) + x.appendChild(y) + return x + + def _print_Ei(self, e): + x = self.dom.createElement('mrow') + mi = self.dom.createElement('mi') + mi.appendChild(self.dom.createTextNode('Ei')) + x.appendChild(mi) + x.appendChild(self._print(e.args)) + return x + + def _print_expint(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msub') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('E')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + x.appendChild(y) + x.appendChild(self._print(e.args[1:])) + return x + + def _print_jacobi(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msubsup') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('P')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + y.appendChild(self._print(e.args[1:3])) + x.appendChild(y) + x.appendChild(self._print(e.args[3:])) + return x + + def _print_gegenbauer(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msubsup') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('C')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + y.appendChild(self._print(e.args[1:2])) + x.appendChild(y) + x.appendChild(self._print(e.args[2:])) + return x + + def _print_chebyshevt(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msub') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('T')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + x.appendChild(y) + x.appendChild(self._print(e.args[1:])) + return x + + def _print_chebyshevu(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msub') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('U')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + x.appendChild(y) + x.appendChild(self._print(e.args[1:])) + return x + + def _print_legendre(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msub') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('P')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + x.appendChild(y) + x.appendChild(self._print(e.args[1:])) + return x + + def _print_assoc_legendre(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msubsup') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('P')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + y.appendChild(self._print(e.args[1:2])) + x.appendChild(y) + x.appendChild(self._print(e.args[2:])) + return x + + def _print_laguerre(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msub') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('L')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + x.appendChild(y) + x.appendChild(self._print(e.args[1:])) + return x + + def _print_assoc_laguerre(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msubsup') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('L')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + y.appendChild(self._print(e.args[1:2])) + x.appendChild(y) + x.appendChild(self._print(e.args[2:])) + return x + + def _print_hermite(self, e): + x = self.dom.createElement('mrow') + y = self.dom.createElement('msub') + mo = self.dom.createElement('mo') + mo.appendChild(self.dom.createTextNode('H')) + y.appendChild(mo) + y.appendChild(self._print(e.args[0])) + x.appendChild(y) + x.appendChild(self._print(e.args[1:])) + return x + + +@print_function(MathMLPrinterBase) +def mathml(expr, printer='content', **settings): + """Returns the MathML representation of expr. If printer is presentation + then prints Presentation MathML else prints content MathML. + """ + if printer == 'presentation': + return MathMLPresentationPrinter(settings).doprint(expr) + else: + return MathMLContentPrinter(settings).doprint(expr) + + +def print_mathml(expr, printer='content', **settings): + """ + Prints a pretty representation of the MathML code for expr. If printer is + presentation then prints Presentation MathML else prints content MathML. + + Examples + ======== + + >>> ## + >>> from sympy import print_mathml + >>> from sympy.abc import x + >>> print_mathml(x+1) #doctest: +NORMALIZE_WHITESPACE + + + x + 1 + + >>> print_mathml(x+1, printer='presentation') + + x + + + 1 + + + """ + if printer == 'presentation': + s = MathMLPresentationPrinter(settings) + else: + s = MathMLContentPrinter(settings) + xml = s._print(sympify(expr)) + pretty_xml = xml.toprettyxml() + + print(pretty_xml) + + +# For backward compatibility +MathMLPrinter = MathMLContentPrinter diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/numpy.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/numpy.py new file mode 100644 index 0000000000000000000000000000000000000000..1ff68454bb287bc0a1d2dfc1fe68fb05b3c22a74 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/numpy.py @@ -0,0 +1,541 @@ +from sympy.core import S +from sympy.core.function import Lambda +from sympy.core.power import Pow +from .pycode import PythonCodePrinter, _known_functions_math, _print_known_const, _print_known_func, _unpack_integral_limits, ArrayPrinter +from .codeprinter import CodePrinter + + +_not_in_numpy = 'erf erfc factorial gamma loggamma'.split() +_in_numpy = [(k, v) for k, v in _known_functions_math.items() if k not in _not_in_numpy] +_known_functions_numpy = dict(_in_numpy, **{ + 'acos': 'arccos', + 'acosh': 'arccosh', + 'asin': 'arcsin', + 'asinh': 'arcsinh', + 'atan': 'arctan', + 'atan2': 'arctan2', + 'atanh': 'arctanh', + 'exp2': 'exp2', + 'sign': 'sign', + 'logaddexp': 'logaddexp', + 'logaddexp2': 'logaddexp2', + 'isinf': 'isinf', + 'isnan': 'isnan', + +}) +_known_constants_numpy = { + 'Exp1': 'e', + 'Pi': 'pi', + 'EulerGamma': 'euler_gamma', + 'NaN': 'nan', + 'Infinity': 'inf', +} + +_numpy_known_functions = {k: 'numpy.' + v for k, v in _known_functions_numpy.items()} +_numpy_known_constants = {k: 'numpy.' + v for k, v in _known_constants_numpy.items()} + +class NumPyPrinter(ArrayPrinter, PythonCodePrinter): + """ + Numpy printer which handles vectorized piecewise functions, + logical operators, etc. + """ + + _module = 'numpy' + _kf = _numpy_known_functions + _kc = _numpy_known_constants + + def __init__(self, settings=None): + """ + `settings` is passed to CodePrinter.__init__() + `module` specifies the array module to use, currently 'NumPy', 'CuPy' + or 'JAX'. + """ + self.language = "Python with {}".format(self._module) + self.printmethod = "_{}code".format(self._module) + + self._kf = {**PythonCodePrinter._kf, **self._kf} + + super().__init__(settings=settings) + + + def _print_seq(self, seq): + "General sequence printer: converts to tuple" + # Print tuples here instead of lists because numba supports + # tuples in nopython mode. + delimiter=', ' + return '({},)'.format(delimiter.join(self._print(item) for item in seq)) + + def _print_NegativeInfinity(self, expr): + return '-' + self._print(S.Infinity) + + def _print_MatMul(self, expr): + "Matrix multiplication printer" + if expr.as_coeff_matrices()[0] is not S.One: + expr_list = expr.as_coeff_matrices()[1]+[(expr.as_coeff_matrices()[0])] + return '({})'.format(').dot('.join(self._print(i) for i in expr_list)) + return '({})'.format(').dot('.join(self._print(i) for i in expr.args)) + + def _print_MatPow(self, expr): + "Matrix power printer" + return '{}({}, {})'.format(self._module_format(self._module + '.linalg.matrix_power'), + self._print(expr.args[0]), self._print(expr.args[1])) + + def _print_Inverse(self, expr): + "Matrix inverse printer" + return '{}({})'.format(self._module_format(self._module + '.linalg.inv'), + self._print(expr.args[0])) + + def _print_DotProduct(self, expr): + # DotProduct allows any shape order, but numpy.dot does matrix + # multiplication, so we have to make sure it gets 1 x n by n x 1. + arg1, arg2 = expr.args + if arg1.shape[0] != 1: + arg1 = arg1.T + if arg2.shape[1] != 1: + arg2 = arg2.T + + return "%s(%s, %s)" % (self._module_format(self._module + '.dot'), + self._print(arg1), + self._print(arg2)) + + def _print_MatrixSolve(self, expr): + return "%s(%s, %s)" % (self._module_format(self._module + '.linalg.solve'), + self._print(expr.matrix), + self._print(expr.vector)) + + def _print_ZeroMatrix(self, expr): + return '{}({})'.format(self._module_format(self._module + '.zeros'), + self._print(expr.shape)) + + def _print_OneMatrix(self, expr): + return '{}({})'.format(self._module_format(self._module + '.ones'), + self._print(expr.shape)) + + def _print_FunctionMatrix(self, expr): + from sympy.abc import i, j + lamda = expr.lamda + if not isinstance(lamda, Lambda): + lamda = Lambda((i, j), lamda(i, j)) + return '{}(lambda {}: {}, {})'.format(self._module_format(self._module + '.fromfunction'), + ', '.join(self._print(arg) for arg in lamda.args[0]), + self._print(lamda.args[1]), self._print(expr.shape)) + + def _print_HadamardProduct(self, expr): + func = self._module_format(self._module + '.multiply') + return ''.join('{}({}, '.format(func, self._print(arg)) \ + for arg in expr.args[:-1]) + "{}{}".format(self._print(expr.args[-1]), + ')' * (len(expr.args) - 1)) + + def _print_KroneckerProduct(self, expr): + func = self._module_format(self._module + '.kron') + return ''.join('{}({}, '.format(func, self._print(arg)) \ + for arg in expr.args[:-1]) + "{}{}".format(self._print(expr.args[-1]), + ')' * (len(expr.args) - 1)) + + def _print_Adjoint(self, expr): + return '{}({}({}))'.format( + self._module_format(self._module + '.conjugate'), + self._module_format(self._module + '.transpose'), + self._print(expr.args[0])) + + def _print_DiagonalOf(self, expr): + vect = '{}({})'.format( + self._module_format(self._module + '.diag'), + self._print(expr.arg)) + return '{}({}, (-1, 1))'.format( + self._module_format(self._module + '.reshape'), vect) + + def _print_DiagMatrix(self, expr): + return '{}({})'.format(self._module_format(self._module + '.diagflat'), + self._print(expr.args[0])) + + def _print_DiagonalMatrix(self, expr): + return '{}({}, {}({}, {}))'.format(self._module_format(self._module + '.multiply'), + self._print(expr.arg), self._module_format(self._module + '.eye'), + self._print(expr.shape[0]), self._print(expr.shape[1])) + + def _print_Piecewise(self, expr): + "Piecewise function printer" + from sympy.logic.boolalg import ITE, simplify_logic + def print_cond(cond): + """ Problem having an ITE in the cond. """ + if cond.has(ITE): + return self._print(simplify_logic(cond)) + else: + return self._print(cond) + exprs = '[{}]'.format(','.join(self._print(arg.expr) for arg in expr.args)) + conds = '[{}]'.format(','.join(print_cond(arg.cond) for arg in expr.args)) + # If [default_value, True] is a (expr, cond) sequence in a Piecewise object + # it will behave the same as passing the 'default' kwarg to select() + # *as long as* it is the last element in expr.args. + # If this is not the case, it may be triggered prematurely. + return '{}({}, {}, default={})'.format( + self._module_format(self._module + '.select'), conds, exprs, + self._print(S.NaN)) + + def _print_Relational(self, expr): + "Relational printer for Equality and Unequality" + op = { + '==' :'equal', + '!=' :'not_equal', + '<' :'less', + '<=' :'less_equal', + '>' :'greater', + '>=' :'greater_equal', + } + if expr.rel_op in op: + lhs = self._print(expr.lhs) + rhs = self._print(expr.rhs) + return '{op}({lhs}, {rhs})'.format(op=self._module_format(self._module + '.'+op[expr.rel_op]), + lhs=lhs, rhs=rhs) + return super()._print_Relational(expr) + + def _print_And(self, expr): + "Logical And printer" + # We have to override LambdaPrinter because it uses Python 'and' keyword. + # If LambdaPrinter didn't define it, we could use StrPrinter's + # version of the function and add 'logical_and' to NUMPY_TRANSLATIONS. + return '{}.reduce(({}))'.format(self._module_format(self._module + '.logical_and'), ','.join(self._print(i) for i in expr.args)) + + def _print_Or(self, expr): + "Logical Or printer" + # We have to override LambdaPrinter because it uses Python 'or' keyword. + # If LambdaPrinter didn't define it, we could use StrPrinter's + # version of the function and add 'logical_or' to NUMPY_TRANSLATIONS. + return '{}.reduce(({}))'.format(self._module_format(self._module + '.logical_or'), ','.join(self._print(i) for i in expr.args)) + + def _print_Not(self, expr): + "Logical Not printer" + # We have to override LambdaPrinter because it uses Python 'not' keyword. + # If LambdaPrinter didn't define it, we would still have to define our + # own because StrPrinter doesn't define it. + return '{}({})'.format(self._module_format(self._module + '.logical_not'), ','.join(self._print(i) for i in expr.args)) + + def _print_Pow(self, expr, rational=False): + # XXX Workaround for negative integer power error + if expr.exp.is_integer and expr.exp.is_negative: + expr = Pow(expr.base, expr.exp.evalf(), evaluate=False) + return self._hprint_Pow(expr, rational=rational, sqrt=self._module + '.sqrt') + + def _helper_minimum_maximum(self, op: str, *args): + if len(args) == 0: + raise NotImplementedError(f"Need at least one argument for {op}") + elif len(args) == 1: + return self._print(args[0]) + _reduce = self._module_format('functools.reduce') + s_args = [self._print(arg) for arg in args] + return f"{_reduce}({op}, [{', '.join(s_args)}])" + + def _print_Min(self, expr): + return self._print_minimum(expr) + + def _print_amin(self, expr): + return '{}({}, axis={})'.format(self._module_format(self._module + '.amin'), self._print(expr.array), self._print(expr.axis)) + + def _print_minimum(self, expr): + op = self._module_format(self._module + '.minimum') + return self._helper_minimum_maximum(op, *expr.args) + + def _print_Max(self, expr): + return self._print_maximum(expr) + + def _print_amax(self, expr): + return '{}({}, axis={})'.format(self._module_format(self._module + '.amax'), self._print(expr.array), self._print(expr.axis)) + + def _print_maximum(self, expr): + op = self._module_format(self._module + '.maximum') + return self._helper_minimum_maximum(op, *expr.args) + + def _print_arg(self, expr): + return "%s(%s)" % (self._module_format(self._module + '.angle'), self._print(expr.args[0])) + + def _print_im(self, expr): + return "%s(%s)" % (self._module_format(self._module + '.imag'), self._print(expr.args[0])) + + def _print_Mod(self, expr): + return "%s(%s)" % (self._module_format(self._module + '.mod'), ', '.join( + (self._print(arg) for arg in expr.args))) + + def _print_re(self, expr): + return "%s(%s)" % (self._module_format(self._module + '.real'), self._print(expr.args[0])) + + def _print_sinc(self, expr): + return "%s(%s)" % (self._module_format(self._module + '.sinc'), self._print(expr.args[0]/S.Pi)) + + def _print_MatrixBase(self, expr): + if 0 in expr.shape: + func = self._module_format(f'{self._module}.{self._zeros}') + return f"{func}({self._print(expr.shape)})" + func = self.known_functions.get(expr.__class__.__name__, None) + if func is None: + func = self._module_format(f'{self._module}.array') + return "%s(%s)" % (func, self._print(expr.tolist())) + + def _print_Identity(self, expr): + shape = expr.shape + if all(dim.is_Integer for dim in shape): + return "%s(%s)" % (self._module_format(self._module + '.eye'), self._print(expr.shape[0])) + else: + raise NotImplementedError("Symbolic matrix dimensions are not yet supported for identity matrices") + + def _print_BlockMatrix(self, expr): + return '{}({})'.format(self._module_format(self._module + '.block'), + self._print(expr.args[0].tolist())) + + def _print_NDimArray(self, expr): + if expr.rank() == 0: + func = self._module_format(f'{self._module}.array') + return f"{func}({self._print(expr[()])})" + if 0 in expr.shape: + func = self._module_format(f'{self._module}.{self._zeros}') + return f"{func}({self._print(expr.shape)})" + func = self._module_format(f'{self._module}.array') + return f"{func}({self._print(expr.tolist())})" + + _add = "add" + _einsum = "einsum" + _transpose = "transpose" + _ones = "ones" + _zeros = "zeros" + + _print_lowergamma = CodePrinter._print_not_supported + _print_uppergamma = CodePrinter._print_not_supported + _print_fresnelc = CodePrinter._print_not_supported + _print_fresnels = CodePrinter._print_not_supported + +for func in _numpy_known_functions: + setattr(NumPyPrinter, f'_print_{func}', _print_known_func) + +for const in _numpy_known_constants: + setattr(NumPyPrinter, f'_print_{const}', _print_known_const) + + +_known_functions_scipy_special = { + 'Ei': 'expi', + 'erf': 'erf', + 'erfc': 'erfc', + 'besselj': 'jv', + 'bessely': 'yv', + 'besseli': 'iv', + 'besselk': 'kv', + 'cosm1': 'cosm1', + 'powm1': 'powm1', + 'factorial': 'factorial', + 'gamma': 'gamma', + 'loggamma': 'gammaln', + 'digamma': 'psi', + 'polygamma': 'polygamma', + 'RisingFactorial': 'poch', + 'jacobi': 'eval_jacobi', + 'gegenbauer': 'eval_gegenbauer', + 'chebyshevt': 'eval_chebyt', + 'chebyshevu': 'eval_chebyu', + 'legendre': 'eval_legendre', + 'hermite': 'eval_hermite', + 'laguerre': 'eval_laguerre', + 'assoc_laguerre': 'eval_genlaguerre', + 'beta': 'beta', + 'LambertW' : 'lambertw', +} + +_known_constants_scipy_constants = { + 'GoldenRatio': 'golden_ratio', + 'Pi': 'pi', +} +_scipy_known_functions = {k : "scipy.special." + v for k, v in _known_functions_scipy_special.items()} +_scipy_known_constants = {k : "scipy.constants." + v for k, v in _known_constants_scipy_constants.items()} + +class SciPyPrinter(NumPyPrinter): + + _kf = {**NumPyPrinter._kf, **_scipy_known_functions} + _kc = {**NumPyPrinter._kc, **_scipy_known_constants} + + def __init__(self, settings=None): + super().__init__(settings=settings) + self.language = "Python with SciPy and NumPy" + + def _print_SparseRepMatrix(self, expr): + i, j, data = [], [], [] + for (r, c), v in expr.todok().items(): + i.append(r) + j.append(c) + data.append(v) + + return "{name}(({data}, ({i}, {j})), shape={shape})".format( + name=self._module_format('scipy.sparse.coo_matrix'), + data=data, i=i, j=j, shape=expr.shape + ) + + _print_ImmutableSparseMatrix = _print_SparseRepMatrix + + # SciPy's lpmv has a different order of arguments from assoc_legendre + def _print_assoc_legendre(self, expr): + return "{0}({2}, {1}, {3})".format( + self._module_format('scipy.special.lpmv'), + self._print(expr.args[0]), + self._print(expr.args[1]), + self._print(expr.args[2])) + + def _print_lowergamma(self, expr): + return "{0}({2})*{1}({2}, {3})".format( + self._module_format('scipy.special.gamma'), + self._module_format('scipy.special.gammainc'), + self._print(expr.args[0]), + self._print(expr.args[1])) + + def _print_uppergamma(self, expr): + return "{0}({2})*{1}({2}, {3})".format( + self._module_format('scipy.special.gamma'), + self._module_format('scipy.special.gammaincc'), + self._print(expr.args[0]), + self._print(expr.args[1])) + + def _print_betainc(self, expr): + betainc = self._module_format('scipy.special.betainc') + beta = self._module_format('scipy.special.beta') + args = [self._print(arg) for arg in expr.args] + return f"({betainc}({args[0]}, {args[1]}, {args[3]}) - {betainc}({args[0]}, {args[1]}, {args[2]})) \ + * {beta}({args[0]}, {args[1]})" + + def _print_betainc_regularized(self, expr): + return "{0}({1}, {2}, {4}) - {0}({1}, {2}, {3})".format( + self._module_format('scipy.special.betainc'), + self._print(expr.args[0]), + self._print(expr.args[1]), + self._print(expr.args[2]), + self._print(expr.args[3])) + + def _print_fresnels(self, expr): + return "{}({})[0]".format( + self._module_format("scipy.special.fresnel"), + self._print(expr.args[0])) + + def _print_fresnelc(self, expr): + return "{}({})[1]".format( + self._module_format("scipy.special.fresnel"), + self._print(expr.args[0])) + + def _print_airyai(self, expr): + return "{}({})[0]".format( + self._module_format("scipy.special.airy"), + self._print(expr.args[0])) + + def _print_airyaiprime(self, expr): + return "{}({})[1]".format( + self._module_format("scipy.special.airy"), + self._print(expr.args[0])) + + def _print_airybi(self, expr): + return "{}({})[2]".format( + self._module_format("scipy.special.airy"), + self._print(expr.args[0])) + + def _print_airybiprime(self, expr): + return "{}({})[3]".format( + self._module_format("scipy.special.airy"), + self._print(expr.args[0])) + + def _print_bernoulli(self, expr): + # scipy's bernoulli is inconsistent with SymPy's so rewrite + return self._print(expr._eval_rewrite_as_zeta(*expr.args)) + + def _print_harmonic(self, expr): + return self._print(expr._eval_rewrite_as_zeta(*expr.args)) + + def _print_Integral(self, e): + integration_vars, limits = _unpack_integral_limits(e) + + if len(limits) == 1: + # nicer (but not necessary) to prefer quad over nquad for 1D case + module_str = self._module_format("scipy.integrate.quad") + limit_str = "%s, %s" % tuple(map(self._print, limits[0])) + else: + module_str = self._module_format("scipy.integrate.nquad") + limit_str = "({})".format(", ".join( + "(%s, %s)" % tuple(map(self._print, l)) for l in limits)) + + return "{}(lambda {}: {}, {})[0]".format( + module_str, + ", ".join(map(self._print, integration_vars)), + self._print(e.args[0]), + limit_str) + + def _print_Si(self, expr): + return "{}({})[0]".format( + self._module_format("scipy.special.sici"), + self._print(expr.args[0])) + + def _print_Ci(self, expr): + return "{}({})[1]".format( + self._module_format("scipy.special.sici"), + self._print(expr.args[0])) + +for func in _scipy_known_functions: + setattr(SciPyPrinter, f'_print_{func}', _print_known_func) + +for const in _scipy_known_constants: + setattr(SciPyPrinter, f'_print_{const}', _print_known_const) + + +_cupy_known_functions = {k : "cupy." + v for k, v in _known_functions_numpy.items()} +_cupy_known_constants = {k : "cupy." + v for k, v in _known_constants_numpy.items()} + +class CuPyPrinter(NumPyPrinter): + """ + CuPy printer which handles vectorized piecewise functions, + logical operators, etc. + """ + + _module = 'cupy' + _kf = _cupy_known_functions + _kc = _cupy_known_constants + + def __init__(self, settings=None): + super().__init__(settings=settings) + +for func in _cupy_known_functions: + setattr(CuPyPrinter, f'_print_{func}', _print_known_func) + +for const in _cupy_known_constants: + setattr(CuPyPrinter, f'_print_{const}', _print_known_const) + + +_jax_known_functions = {k: 'jax.numpy.' + v for k, v in _known_functions_numpy.items()} +_jax_known_constants = {k: 'jax.numpy.' + v for k, v in _known_constants_numpy.items()} + +class JaxPrinter(NumPyPrinter): + """ + JAX printer which handles vectorized piecewise functions, + logical operators, etc. + """ + _module = "jax.numpy" + + _kf = _jax_known_functions + _kc = _jax_known_constants + + def __init__(self, settings=None): + super().__init__(settings=settings) + self.printmethod = '_jaxcode' + + # These need specific override to allow for the lack of "jax.numpy.reduce" + def _print_And(self, expr): + "Logical And printer" + return "{}({}.asarray([{}]), axis=0)".format( + self._module_format(self._module + ".all"), + self._module_format(self._module), + ",".join(self._print(i) for i in expr.args), + ) + + def _print_Or(self, expr): + "Logical Or printer" + return "{}({}.asarray([{}]), axis=0)".format( + self._module_format(self._module + ".any"), + self._module_format(self._module), + ",".join(self._print(i) for i in expr.args), + ) + +for func in _jax_known_functions: + setattr(JaxPrinter, f'_print_{func}', _print_known_func) + +for const in _jax_known_constants: + setattr(JaxPrinter, f'_print_{const}', _print_known_const) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/octave.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/octave.py new file mode 100644 index 0000000000000000000000000000000000000000..2cf2d6a5754668d7a95ef5dc7b27b4864756a9e5 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/octave.py @@ -0,0 +1,711 @@ +""" +Octave (and Matlab) code printer + +The `OctaveCodePrinter` converts SymPy expressions into Octave expressions. +It uses a subset of the Octave language for Matlab compatibility. + +A complete code generator, which uses `octave_code` extensively, can be found +in `sympy.utilities.codegen`. The `codegen` module can be used to generate +complete source code files. + +""" + +from __future__ import annotations +from typing import Any + +from sympy.core import Mul, Pow, S, Rational +from sympy.core.mul import _keep_coeff +from sympy.core.numbers import equal_valued +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence, PRECEDENCE +from re import search + +# List of known functions. First, those that have the same name in +# SymPy and Octave. This is almost certainly incomplete! +known_fcns_src1 = ["sin", "cos", "tan", "cot", "sec", "csc", + "asin", "acos", "acot", "atan", "atan2", "asec", "acsc", + "sinh", "cosh", "tanh", "coth", "csch", "sech", + "asinh", "acosh", "atanh", "acoth", "asech", "acsch", + "erfc", "erfi", "erf", "erfinv", "erfcinv", + "besseli", "besselj", "besselk", "bessely", + "bernoulli", "beta", "euler", "exp", "factorial", "floor", + "fresnelc", "fresnels", "gamma", "harmonic", "log", + "polylog", "sign", "zeta", "legendre"] + +# These functions have different names ("SymPy": "Octave"), more +# generally a mapping to (argument_conditions, octave_function). +known_fcns_src2 = { + "Abs": "abs", + "arg": "angle", # arg/angle ok in Octave but only angle in Matlab + "binomial": "bincoeff", + "ceiling": "ceil", + "chebyshevu": "chebyshevU", + "chebyshevt": "chebyshevT", + "Chi": "coshint", + "Ci": "cosint", + "conjugate": "conj", + "DiracDelta": "dirac", + "Heaviside": "heaviside", + "im": "imag", + "laguerre": "laguerreL", + "LambertW": "lambertw", + "li": "logint", + "loggamma": "gammaln", + "Max": "max", + "Min": "min", + "Mod": "mod", + "polygamma": "psi", + "re": "real", + "RisingFactorial": "pochhammer", + "Shi": "sinhint", + "Si": "sinint", +} + + +class OctaveCodePrinter(CodePrinter): + """ + A printer to convert expressions to strings of Octave/Matlab code. + """ + printmethod = "_octave" + language = "Octave" + + _operators = { + 'and': '&', + 'or': '|', + 'not': '~', + } + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 17, + 'user_functions': {}, + 'contract': True, + 'inline': True, + }) + # Note: contract is for expressing tensors as loops (if True), or just + # assignment (if False). FIXME: this should be looked a more carefully + # for Octave. + + + def __init__(self, settings={}): + super().__init__(settings) + self.known_functions = dict(zip(known_fcns_src1, known_fcns_src1)) + self.known_functions.update(dict(known_fcns_src2)) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + + + def _rate_index_position(self, p): + return p*5 + + + def _get_statement(self, codestring): + return "%s;" % codestring + + + def _get_comment(self, text): + return "% {}".format(text) + + + def _declare_number_const(self, name, value): + return "{} = {};".format(name, value) + + + def _format_code(self, lines): + return self.indent_code(lines) + + + def _traverse_matrix_indices(self, mat): + # Octave uses Fortran order (column-major) + rows, cols = mat.shape + return ((i, j) for j in range(cols) for i in range(rows)) + + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + for i in indices: + # Octave arrays start at 1 and end at dimension + var, start, stop = map(self._print, + [i.label, i.lower + 1, i.upper + 1]) + open_lines.append("for %s = %s:%s" % (var, start, stop)) + close_lines.append("end") + return open_lines, close_lines + + + def _print_Mul(self, expr): + # print complex numbers nicely in Octave + if (expr.is_number and expr.is_imaginary and + (S.ImaginaryUnit*expr).is_Integer): + return "%si" % self._print(-S.ImaginaryUnit*expr) + + # cribbed from str.py + prec = precedence(expr) + + c, e = expr.as_coeff_Mul() + if c < 0: + expr = _keep_coeff(-c, e) + sign = "-" + else: + sign = "" + + a = [] # items in the numerator + b = [] # items that are in the denominator (if any) + + pow_paren = [] # Will collect all pow with more than one base element and exp = -1 + + if self.order not in ('old', 'none'): + args = expr.as_ordered_factors() + else: + # use make_args in case expr was something like -x -> x + args = Mul.make_args(expr) + + # Gather args for numerator/denominator + for item in args: + if (item.is_commutative and item.is_Pow and item.exp.is_Rational + and item.exp.is_negative): + if item.exp != -1: + b.append(Pow(item.base, -item.exp, evaluate=False)) + else: + if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 + pow_paren.append(item) + b.append(Pow(item.base, -item.exp)) + elif item.is_Rational and item is not S.Infinity: + if item.p != 1: + a.append(Rational(item.p)) + if item.q != 1: + b.append(Rational(item.q)) + else: + a.append(item) + + a = a or [S.One] + + a_str = [self.parenthesize(x, prec) for x in a] + b_str = [self.parenthesize(x, prec) for x in b] + + # To parenthesize Pow with exp = -1 and having more than one Symbol + for item in pow_paren: + if item.base in b: + b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] + + # from here it differs from str.py to deal with "*" and ".*" + def multjoin(a, a_str): + # here we probably are assuming the constants will come first + r = a_str[0] + for i in range(1, len(a)): + mulsym = '*' if a[i-1].is_number else '.*' + r = r + mulsym + a_str[i] + return r + + if not b: + return sign + multjoin(a, a_str) + elif len(b) == 1: + divsym = '/' if b[0].is_number else './' + return sign + multjoin(a, a_str) + divsym + b_str[0] + else: + divsym = '/' if all(bi.is_number for bi in b) else './' + return (sign + multjoin(a, a_str) + + divsym + "(%s)" % multjoin(b, b_str)) + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_Pow(self, expr): + powsymbol = '^' if all(x.is_number for x in expr.args) else '.^' + + PREC = precedence(expr) + + if equal_valued(expr.exp, 0.5): + return "sqrt(%s)" % self._print(expr.base) + + if expr.is_commutative: + if equal_valued(expr.exp, -0.5): + sym = '/' if expr.base.is_number else './' + return "1" + sym + "sqrt(%s)" % self._print(expr.base) + if equal_valued(expr.exp, -1): + sym = '/' if expr.base.is_number else './' + return "1" + sym + "%s" % self.parenthesize(expr.base, PREC) + + return '%s%s%s' % (self.parenthesize(expr.base, PREC), powsymbol, + self.parenthesize(expr.exp, PREC)) + + + def _print_MatPow(self, expr): + PREC = precedence(expr) + return '%s^%s' % (self.parenthesize(expr.base, PREC), + self.parenthesize(expr.exp, PREC)) + + def _print_MatrixSolve(self, expr): + PREC = precedence(expr) + return "%s \\ %s" % (self.parenthesize(expr.matrix, PREC), + self.parenthesize(expr.vector, PREC)) + + def _print_Pi(self, expr): + return 'pi' + + + def _print_ImaginaryUnit(self, expr): + return "1i" + + + def _print_Exp1(self, expr): + return "exp(1)" + + + def _print_GoldenRatio(self, expr): + # FIXME: how to do better, e.g., for octave_code(2*GoldenRatio)? + #return self._print((1+sqrt(S(5)))/2) + return "(1+sqrt(5))/2" + + + def _print_Assignment(self, expr): + from sympy.codegen.ast import Assignment + from sympy.functions.elementary.piecewise import Piecewise + from sympy.tensor.indexed import IndexedBase + # Copied from codeprinter, but remove special MatrixSymbol treatment + lhs = expr.lhs + rhs = expr.rhs + # We special case assignments that take multiple lines + if not self._settings["inline"] and isinstance(expr.rhs, Piecewise): + # Here we modify Piecewise so each expression is now + # an Assignment, and then continue on the print. + expressions = [] + conditions = [] + for (e, c) in rhs.args: + expressions.append(Assignment(lhs, e)) + conditions.append(c) + temp = Piecewise(*zip(expressions, conditions)) + return self._print(temp) + if self._settings["contract"] and (lhs.has(IndexedBase) or + rhs.has(IndexedBase)): + # Here we check if there is looping to be done, and if so + # print the required loops. + return self._doprint_loops(rhs, lhs) + else: + lhs_code = self._print(lhs) + rhs_code = self._print(rhs) + return self._get_statement("%s = %s" % (lhs_code, rhs_code)) + + + def _print_Infinity(self, expr): + return 'inf' + + + def _print_NegativeInfinity(self, expr): + return '-inf' + + + def _print_NaN(self, expr): + return 'NaN' + + + def _print_list(self, expr): + return '{' + ', '.join(self._print(a) for a in expr) + '}' + _print_tuple = _print_list + _print_Tuple = _print_list + _print_List = _print_list + + + def _print_BooleanTrue(self, expr): + return "true" + + + def _print_BooleanFalse(self, expr): + return "false" + + + def _print_bool(self, expr): + return str(expr).lower() + + + # Could generate quadrature code for definite Integrals? + #_print_Integral = _print_not_supported + + + def _print_MatrixBase(self, A): + # Handle zero dimensions: + if (A.rows, A.cols) == (0, 0): + return '[]' + elif S.Zero in A.shape: + return 'zeros(%s, %s)' % (A.rows, A.cols) + elif (A.rows, A.cols) == (1, 1): + # Octave does not distinguish between scalars and 1x1 matrices + return self._print(A[0, 0]) + return "[%s]" % "; ".join(" ".join([self._print(a) for a in A[r, :]]) + for r in range(A.rows)) + + + def _print_SparseRepMatrix(self, A): + from sympy.matrices import Matrix + L = A.col_list() + # make row vectors of the indices and entries + I = Matrix([[k[0] + 1 for k in L]]) + J = Matrix([[k[1] + 1 for k in L]]) + AIJ = Matrix([[k[2] for k in L]]) + return "sparse(%s, %s, %s, %s, %s)" % (self._print(I), self._print(J), + self._print(AIJ), A.rows, A.cols) + + + def _print_MatrixElement(self, expr): + return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) \ + + '(%s, %s)' % (expr.i + 1, expr.j + 1) + + + def _print_MatrixSlice(self, expr): + def strslice(x, lim): + l = x[0] + 1 + h = x[1] + step = x[2] + lstr = self._print(l) + hstr = 'end' if h == lim else self._print(h) + if step == 1: + if l == 1 and h == lim: + return ':' + if l == h: + return lstr + else: + return lstr + ':' + hstr + else: + return ':'.join((lstr, self._print(step), hstr)) + return (self._print(expr.parent) + '(' + + strslice(expr.rowslice, expr.parent.shape[0]) + ', ' + + strslice(expr.colslice, expr.parent.shape[1]) + ')') + + + def _print_Indexed(self, expr): + inds = [ self._print(i) for i in expr.indices ] + return "%s(%s)" % (self._print(expr.base.label), ", ".join(inds)) + + + def _print_KroneckerDelta(self, expr): + prec = PRECEDENCE["Pow"] + return "double(%s == %s)" % tuple(self.parenthesize(x, prec) + for x in expr.args) + + def _print_HadamardProduct(self, expr): + return '.*'.join([self.parenthesize(arg, precedence(expr)) + for arg in expr.args]) + + def _print_HadamardPower(self, expr): + PREC = precedence(expr) + return '.**'.join([ + self.parenthesize(expr.base, PREC), + self.parenthesize(expr.exp, PREC) + ]) + + def _print_Identity(self, expr): + shape = expr.shape + if len(shape) == 2 and shape[0] == shape[1]: + shape = [shape[0]] + s = ", ".join(self._print(n) for n in shape) + return "eye(" + s + ")" + + def _print_lowergamma(self, expr): + # Octave implements regularized incomplete gamma function + return "(gammainc({1}, {0}).*gamma({0}))".format( + self._print(expr.args[0]), self._print(expr.args[1])) + + + def _print_uppergamma(self, expr): + return "(gammainc({1}, {0}, 'upper').*gamma({0}))".format( + self._print(expr.args[0]), self._print(expr.args[1])) + + + def _print_sinc(self, expr): + #Note: Divide by pi because Octave implements normalized sinc function. + return "sinc(%s)" % self._print(expr.args[0]/S.Pi) + + + def _print_hankel1(self, expr): + return "besselh(%s, 1, %s)" % (self._print(expr.order), + self._print(expr.argument)) + + + def _print_hankel2(self, expr): + return "besselh(%s, 2, %s)" % (self._print(expr.order), + self._print(expr.argument)) + + + # Note: as of 2015, Octave doesn't have spherical Bessel functions + def _print_jn(self, expr): + from sympy.functions import sqrt, besselj + x = expr.argument + expr2 = sqrt(S.Pi/(2*x))*besselj(expr.order + S.Half, x) + return self._print(expr2) + + + def _print_yn(self, expr): + from sympy.functions import sqrt, bessely + x = expr.argument + expr2 = sqrt(S.Pi/(2*x))*bessely(expr.order + S.Half, x) + return self._print(expr2) + + + def _print_airyai(self, expr): + return "airy(0, %s)" % self._print(expr.args[0]) + + + def _print_airyaiprime(self, expr): + return "airy(1, %s)" % self._print(expr.args[0]) + + + def _print_airybi(self, expr): + return "airy(2, %s)" % self._print(expr.args[0]) + + + def _print_airybiprime(self, expr): + return "airy(3, %s)" % self._print(expr.args[0]) + + + def _print_expint(self, expr): + mu, x = expr.args + if mu != 1: + return self._print_not_supported(expr) + return "expint(%s)" % self._print(x) + + + def _one_or_two_reversed_args(self, expr): + assert len(expr.args) <= 2 + return '{name}({args})'.format( + name=self.known_functions[expr.__class__.__name__], + args=", ".join([self._print(x) for x in reversed(expr.args)]) + ) + + + _print_DiracDelta = _print_LambertW = _one_or_two_reversed_args + + + def _nested_binary_math_func(self, expr): + return '{name}({arg1}, {arg2})'.format( + name=self.known_functions[expr.__class__.__name__], + arg1=self._print(expr.args[0]), + arg2=self._print(expr.func(*expr.args[1:])) + ) + + _print_Max = _print_Min = _nested_binary_math_func + + + def _print_Piecewise(self, expr): + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + if self._settings["inline"]: + # Express each (cond, expr) pair in a nested Horner form: + # (condition) .* (expr) + (not cond) .* () + # Expressions that result in multiple statements won't work here. + ecpairs = ["({0}).*({1}) + (~({0})).*(".format + (self._print(c), self._print(e)) + for e, c in expr.args[:-1]] + elast = "%s" % self._print(expr.args[-1].expr) + pw = " ...\n".join(ecpairs) + elast + ")"*len(ecpairs) + # Note: current need these outer brackets for 2*pw. Would be + # nicer to teach parenthesize() to do this for us when needed! + return "(" + pw + ")" + else: + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s)" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines.append("else") + else: + lines.append("elseif (%s)" % self._print(c)) + code0 = self._print(e) + lines.append(code0) + if i == len(expr.args) - 1: + lines.append("end") + return "\n".join(lines) + + + def _print_zeta(self, expr): + if len(expr.args) == 1: + return "zeta(%s)" % self._print(expr.args[0]) + else: + # Matlab two argument zeta is not equivalent to SymPy's + return self._print_not_supported(expr) + + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + # code mostly copied from ccode + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_regex = ('^function ', '^if ', '^elseif ', '^else$', '^for ') + dec_regex = ('^end$', '^elseif ', '^else$') + + # pre-strip left-space from the code + code = [ line.lstrip(' \t') for line in code ] + + increase = [ int(any(search(re, line) for re in inc_regex)) + for line in code ] + decrease = [ int(any(search(re, line) for re in dec_regex)) + for line in code ] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty + + +def octave_code(expr, assign_to=None, **settings): + r"""Converts `expr` to a string of Octave (or Matlab) code. + + The string uses a subset of the Octave language for Matlab compatibility. + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This can be helpful for + expressions that generate multi-line statements. + precision : integer, optional + The precision for numbers such as pi [default=16]. + user_functions : dict, optional + A dictionary where keys are ``FunctionClass`` instances and values are + their string representations. Alternatively, the dictionary value can + be a list of tuples i.e. [(argument_test, cfunction_string)]. See + below for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + inline: bool, optional + If True, we try to create single-statement code instead of multiple + statements. [default=True]. + + Examples + ======== + + >>> from sympy import octave_code, symbols, sin, pi + >>> x = symbols('x') + >>> octave_code(sin(x).series(x).removeO()) + 'x.^5/120 - x.^3/6 + x' + + >>> from sympy import Rational, ceiling + >>> x, y, tau = symbols("x, y, tau") + >>> octave_code((2*tau)**Rational(7, 2)) + '8*sqrt(2)*tau.^(7/2)' + + Note that element-wise (Hadamard) operations are used by default between + symbols. This is because its very common in Octave to write "vectorized" + code. It is harmless if the values are scalars. + + >>> octave_code(sin(pi*x*y), assign_to="s") + 's = sin(pi*x.*y);' + + If you need a matrix product "*" or matrix power "^", you can specify the + symbol as a ``MatrixSymbol``. + + >>> from sympy import Symbol, MatrixSymbol + >>> n = Symbol('n', integer=True, positive=True) + >>> A = MatrixSymbol('A', n, n) + >>> octave_code(3*pi*A**3) + '(3*pi)*A^3' + + This class uses several rules to decide which symbol to use a product. + Pure numbers use "*", Symbols use ".*" and MatrixSymbols use "*". + A HadamardProduct can be used to specify componentwise multiplication ".*" + of two MatrixSymbols. There is currently there is no easy way to specify + scalar symbols, so sometimes the code might have some minor cosmetic + issues. For example, suppose x and y are scalars and A is a Matrix, then + while a human programmer might write "(x^2*y)*A^3", we generate: + + >>> octave_code(x**2*y*A**3) + '(x.^2.*y)*A^3' + + Matrices are supported using Octave inline notation. When using + ``assign_to`` with matrices, the name can be specified either as a string + or as a ``MatrixSymbol``. The dimensions must align in the latter case. + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([[x**2, sin(x), ceiling(x)]]) + >>> octave_code(mat, assign_to='A') + 'A = [x.^2 sin(x) ceil(x)];' + + ``Piecewise`` expressions are implemented with logical masking by default. + Alternatively, you can pass "inline=False" to use if-else conditionals. + Note that if the ``Piecewise`` lacks a default term, represented by + ``(expr, True)`` then an error will be thrown. This is to prevent + generating an expression that may not evaluate to anything. + + >>> from sympy import Piecewise + >>> pw = Piecewise((x + 1, x > 0), (x, True)) + >>> octave_code(pw, assign_to=tau) + 'tau = ((x > 0).*(x + 1) + (~(x > 0)).*(x));' + + Note that any expression that can be generated normally can also exist + inside a Matrix: + + >>> mat = Matrix([[x**2, pw, sin(x)]]) + >>> octave_code(mat, assign_to='A') + 'A = [x.^2 ((x > 0).*(x + 1) + (~(x > 0)).*(x)) sin(x)];' + + Custom printing can be defined for certain types by passing a dictionary of + "type" : "function" to the ``user_functions`` kwarg. Alternatively, the + dictionary value can be a list of tuples i.e., [(argument_test, + cfunction_string)]. This can be used to call a custom Octave function. + + >>> from sympy import Function + >>> f = Function('f') + >>> g = Function('g') + >>> custom_functions = { + ... "f": "existing_octave_fcn", + ... "g": [(lambda x: x.is_Matrix, "my_mat_fcn"), + ... (lambda x: not x.is_Matrix, "my_fcn")] + ... } + >>> mat = Matrix([[1, x]]) + >>> octave_code(f(x) + g(x) + g(mat), user_functions=custom_functions) + 'existing_octave_fcn(x) + my_fcn(x) + my_mat_fcn([1 x])' + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e = Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> octave_code(e.rhs, assign_to=e.lhs, contract=False) + 'Dy(i) = (y(i + 1) - y(i))./(t(i + 1) - t(i));' + """ + return OctaveCodePrinter(settings).doprint(expr, assign_to) + + +def print_octave_code(expr, **settings): + """Prints the Octave (or Matlab) representation of the given expression. + + See `octave_code` for the meaning of the optional arguments. + """ + print(octave_code(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/precedence.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/precedence.py new file mode 100644 index 0000000000000000000000000000000000000000..d22d5746aeee51bddcf273d4575c30c3c27db71a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/precedence.py @@ -0,0 +1,180 @@ +"""A module providing information about the necessity of brackets""" + + +# Default precedence values for some basic types +PRECEDENCE = { + "Lambda": 1, + "Xor": 10, + "Or": 20, + "And": 30, + "Relational": 35, + "Add": 40, + "Mul": 50, + "Pow": 60, + "Func": 70, + "Not": 100, + "Atom": 1000, + "BitwiseOr": 36, + "BitwiseXor": 37, + "BitwiseAnd": 38 +} + +# A dictionary assigning precedence values to certain classes. These values are +# treated like they were inherited, so not every single class has to be named +# here. +# Do not use this with printers other than StrPrinter +PRECEDENCE_VALUES = { + "Equivalent": PRECEDENCE["Xor"], + "Xor": PRECEDENCE["Xor"], + "Implies": PRECEDENCE["Xor"], + "Or": PRECEDENCE["Or"], + "And": PRECEDENCE["And"], + "Add": PRECEDENCE["Add"], + "Pow": PRECEDENCE["Pow"], + "Relational": PRECEDENCE["Relational"], + "Sub": PRECEDENCE["Add"], + "Not": PRECEDENCE["Not"], + "Function" : PRECEDENCE["Func"], + "NegativeInfinity": PRECEDENCE["Add"], + "MatAdd": PRECEDENCE["Add"], + "MatPow": PRECEDENCE["Pow"], + "MatrixSolve": PRECEDENCE["Mul"], + "Mod": PRECEDENCE["Mul"], + "TensAdd": PRECEDENCE["Add"], + # As soon as `TensMul` is a subclass of `Mul`, remove this: + "TensMul": PRECEDENCE["Mul"], + "HadamardProduct": PRECEDENCE["Mul"], + "HadamardPower": PRECEDENCE["Pow"], + "KroneckerProduct": PRECEDENCE["Mul"], + "Equality": PRECEDENCE["Mul"], + "Unequality": PRECEDENCE["Mul"], +} + +# Sometimes it's not enough to assign a fixed precedence value to a +# class. Then a function can be inserted in this dictionary that takes +# an instance of this class as argument and returns the appropriate +# precedence value. + +# Precedence functions + + +def precedence_Mul(item): + from sympy.core.function import Function + if any(hasattr(arg, 'precedence') and isinstance(arg, Function) and + arg.precedence < PRECEDENCE["Mul"] for arg in item.args): + return PRECEDENCE["Mul"] + + if item.could_extract_minus_sign(): + return PRECEDENCE["Add"] + return PRECEDENCE["Mul"] + + +def precedence_Rational(item): + if item.p < 0: + return PRECEDENCE["Add"] + return PRECEDENCE["Mul"] + + +def precedence_Integer(item): + if item.p < 0: + return PRECEDENCE["Add"] + return PRECEDENCE["Atom"] + + +def precedence_Float(item): + if item < 0: + return PRECEDENCE["Add"] + return PRECEDENCE["Atom"] + + +def precedence_PolyElement(item): + if item.is_generator: + return PRECEDENCE["Atom"] + elif item.is_ground: + return precedence(item.coeff(1)) + elif item.is_term: + return PRECEDENCE["Mul"] + else: + return PRECEDENCE["Add"] + + +def precedence_FracElement(item): + if item.denom == 1: + return precedence_PolyElement(item.numer) + else: + return PRECEDENCE["Mul"] + + +def precedence_UnevaluatedExpr(item): + return precedence(item.args[0]) - 0.5 + + +PRECEDENCE_FUNCTIONS = { + "Integer": precedence_Integer, + "Mul": precedence_Mul, + "Rational": precedence_Rational, + "Float": precedence_Float, + "PolyElement": precedence_PolyElement, + "FracElement": precedence_FracElement, + "UnevaluatedExpr": precedence_UnevaluatedExpr, +} + + +def precedence(item): + """Returns the precedence of a given object. + + This is the precedence for StrPrinter. + """ + if hasattr(item, "precedence"): + return item.precedence + if not isinstance(item, type): + for i in type(item).mro(): + n = i.__name__ + if n in PRECEDENCE_FUNCTIONS: + return PRECEDENCE_FUNCTIONS[n](item) + elif n in PRECEDENCE_VALUES: + return PRECEDENCE_VALUES[n] + return PRECEDENCE["Atom"] + + +PRECEDENCE_TRADITIONAL = PRECEDENCE.copy() +PRECEDENCE_TRADITIONAL['Integral'] = PRECEDENCE["Mul"] +PRECEDENCE_TRADITIONAL['Sum'] = PRECEDENCE["Mul"] +PRECEDENCE_TRADITIONAL['Product'] = PRECEDENCE["Mul"] +PRECEDENCE_TRADITIONAL['Limit'] = PRECEDENCE["Mul"] +PRECEDENCE_TRADITIONAL['Derivative'] = PRECEDENCE["Mul"] +PRECEDENCE_TRADITIONAL['TensorProduct'] = PRECEDENCE["Mul"] +PRECEDENCE_TRADITIONAL['Transpose'] = PRECEDENCE["Pow"] +PRECEDENCE_TRADITIONAL['Adjoint'] = PRECEDENCE["Pow"] +PRECEDENCE_TRADITIONAL['Dot'] = PRECEDENCE["Mul"] - 1 +PRECEDENCE_TRADITIONAL['Cross'] = PRECEDENCE["Mul"] - 1 +PRECEDENCE_TRADITIONAL['Gradient'] = PRECEDENCE["Mul"] - 1 +PRECEDENCE_TRADITIONAL['Divergence'] = PRECEDENCE["Mul"] - 1 +PRECEDENCE_TRADITIONAL['Curl'] = PRECEDENCE["Mul"] - 1 +PRECEDENCE_TRADITIONAL['Laplacian'] = PRECEDENCE["Mul"] - 1 +PRECEDENCE_TRADITIONAL['Union'] = PRECEDENCE['Xor'] +PRECEDENCE_TRADITIONAL['Intersection'] = PRECEDENCE['Xor'] +PRECEDENCE_TRADITIONAL['Complement'] = PRECEDENCE['Xor'] +PRECEDENCE_TRADITIONAL['SymmetricDifference'] = PRECEDENCE['Xor'] +PRECEDENCE_TRADITIONAL['ProductSet'] = PRECEDENCE['Xor'] +PRECEDENCE_TRADITIONAL['DotProduct'] = PRECEDENCE_TRADITIONAL['Dot'] + + +def precedence_traditional(item): + """Returns the precedence of a given object according to the + traditional rules of mathematics. + + This is the precedence for the LaTeX and pretty printer. + """ + # Integral, Sum, Product, Limit have the precedence of Mul in LaTeX, + # the precedence of Atom for other printers: + from sympy.core.expr import UnevaluatedExpr + + if isinstance(item, UnevaluatedExpr): + return precedence_traditional(item.args[0]) + + n = item.__class__.__name__ + if n in PRECEDENCE_TRADITIONAL: + return PRECEDENCE_TRADITIONAL[n] + + return precedence(item) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..cbabc649152a3c353a37225d342064634fbb5805 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/__init__.py @@ -0,0 +1,12 @@ +"""ASCII-ART 2D pretty-printer""" + +from .pretty import (pretty, pretty_print, pprint, pprint_use_unicode, + pprint_try_use_unicode, pager_print) + +# if unicode output is available -- let's use it +pprint_try_use_unicode() + +__all__ = [ + 'pretty', 'pretty_print', 'pprint', 'pprint_use_unicode', + 'pprint_try_use_unicode', 'pager_print', +] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/pretty.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/pretty.py new file mode 100644 index 0000000000000000000000000000000000000000..b945f009119b24fc95e8452d91359957baba26a8 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/pretty.py @@ -0,0 +1,2937 @@ +import itertools + +from sympy.core import S +from sympy.core.add import Add +from sympy.core.containers import Tuple +from sympy.core.function import Function +from sympy.core.mul import Mul +from sympy.core.numbers import Number, Rational +from sympy.core.power import Pow +from sympy.core.sorting import default_sort_key +from sympy.core.symbol import Symbol +from sympy.core.sympify import SympifyError +from sympy.printing.conventions import requires_partial +from sympy.printing.precedence import PRECEDENCE, precedence, precedence_traditional +from sympy.printing.printer import Printer, print_function +from sympy.printing.str import sstr +from sympy.utilities.iterables import has_variety +from sympy.utilities.exceptions import sympy_deprecation_warning + +from sympy.printing.pretty.stringpict import prettyForm, stringPict +from sympy.printing.pretty.pretty_symbology import hobj, vobj, xobj, \ + xsym, pretty_symbol, pretty_atom, pretty_use_unicode, greek_unicode, U, \ + pretty_try_use_unicode, annotated, is_subscriptable_in_unicode, center_pad, root as nth_root + +# rename for usage from outside +pprint_use_unicode = pretty_use_unicode +pprint_try_use_unicode = pretty_try_use_unicode + + +class PrettyPrinter(Printer): + """Printer, which converts an expression into 2D ASCII-art figure.""" + printmethod = "_pretty" + + _default_settings = { + "order": None, + "full_prec": "auto", + "use_unicode": None, + "wrap_line": True, + "num_columns": None, + "use_unicode_sqrt_char": True, + "root_notation": True, + "mat_symbol_style": "plain", + "imaginary_unit": "i", + "perm_cyclic": True + } + + def __init__(self, settings=None): + Printer.__init__(self, settings) + + if not isinstance(self._settings['imaginary_unit'], str): + raise TypeError("'imaginary_unit' must a string, not {}".format(self._settings['imaginary_unit'])) + elif self._settings['imaginary_unit'] not in ("i", "j"): + raise ValueError("'imaginary_unit' must be either 'i' or 'j', not '{}'".format(self._settings['imaginary_unit'])) + + def emptyPrinter(self, expr): + return prettyForm(str(expr)) + + @property + def _use_unicode(self): + if self._settings['use_unicode']: + return True + else: + return pretty_use_unicode() + + def doprint(self, expr): + return self._print(expr).render(**self._settings) + + # empty op so _print(stringPict) returns the same + def _print_stringPict(self, e): + return e + + def _print_basestring(self, e): + return prettyForm(e) + + def _print_atan2(self, e): + pform = prettyForm(*self._print_seq(e.args).parens()) + pform = prettyForm(*pform.left('atan2')) + return pform + + def _print_Symbol(self, e, bold_name=False): + symb = pretty_symbol(e.name, bold_name) + return prettyForm(symb) + _print_RandomSymbol = _print_Symbol + def _print_MatrixSymbol(self, e): + return self._print_Symbol(e, self._settings['mat_symbol_style'] == "bold") + + def _print_Float(self, e): + # we will use StrPrinter's Float printer, but we need to handle the + # full_prec ourselves, according to the self._print_level + full_prec = self._settings["full_prec"] + if full_prec == "auto": + full_prec = self._print_level == 1 + return prettyForm(sstr(e, full_prec=full_prec)) + + def _print_Cross(self, e): + vec1 = e._expr1 + vec2 = e._expr2 + pform = self._print(vec2) + pform = prettyForm(*pform.left('(')) + pform = prettyForm(*pform.right(')')) + pform = prettyForm(*pform.left(self._print(U('MULTIPLICATION SIGN')))) + pform = prettyForm(*pform.left(')')) + pform = prettyForm(*pform.left(self._print(vec1))) + pform = prettyForm(*pform.left('(')) + return pform + + def _print_Curl(self, e): + vec = e._expr + pform = self._print(vec) + pform = prettyForm(*pform.left('(')) + pform = prettyForm(*pform.right(')')) + pform = prettyForm(*pform.left(self._print(U('MULTIPLICATION SIGN')))) + pform = prettyForm(*pform.left(self._print(U('NABLA')))) + return pform + + def _print_Divergence(self, e): + vec = e._expr + pform = self._print(vec) + pform = prettyForm(*pform.left('(')) + pform = prettyForm(*pform.right(')')) + pform = prettyForm(*pform.left(self._print(U('DOT OPERATOR')))) + pform = prettyForm(*pform.left(self._print(U('NABLA')))) + return pform + + def _print_Dot(self, e): + vec1 = e._expr1 + vec2 = e._expr2 + pform = self._print(vec2) + pform = prettyForm(*pform.left('(')) + pform = prettyForm(*pform.right(')')) + pform = prettyForm(*pform.left(self._print(U('DOT OPERATOR')))) + pform = prettyForm(*pform.left(')')) + pform = prettyForm(*pform.left(self._print(vec1))) + pform = prettyForm(*pform.left('(')) + return pform + + def _print_Gradient(self, e): + func = e._expr + pform = self._print(func) + pform = prettyForm(*pform.left('(')) + pform = prettyForm(*pform.right(')')) + pform = prettyForm(*pform.left(self._print(U('NABLA')))) + return pform + + def _print_Laplacian(self, e): + func = e._expr + pform = self._print(func) + pform = prettyForm(*pform.left('(')) + pform = prettyForm(*pform.right(')')) + pform = prettyForm(*pform.left(self._print(U('INCREMENT')))) + return pform + + def _print_Atom(self, e): + try: + # print atoms like Exp1 or Pi + return prettyForm(pretty_atom(e.__class__.__name__, printer=self)) + except KeyError: + return self.emptyPrinter(e) + + # Infinity inherits from Number, so we have to override _print_XXX order + _print_Infinity = _print_Atom + _print_NegativeInfinity = _print_Atom + _print_EmptySet = _print_Atom + _print_Naturals = _print_Atom + _print_Naturals0 = _print_Atom + _print_Integers = _print_Atom + _print_Rationals = _print_Atom + _print_Complexes = _print_Atom + + _print_EmptySequence = _print_Atom + + def _print_Reals(self, e): + if self._use_unicode: + return self._print_Atom(e) + else: + inf_list = ['-oo', 'oo'] + return self._print_seq(inf_list, '(', ')') + + def _print_subfactorial(self, e): + x = e.args[0] + pform = self._print(x) + # Add parentheses if needed + if not ((x.is_Integer and x.is_nonnegative) or x.is_Symbol): + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left('!')) + return pform + + def _print_factorial(self, e): + x = e.args[0] + pform = self._print(x) + # Add parentheses if needed + if not ((x.is_Integer and x.is_nonnegative) or x.is_Symbol): + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.right('!')) + return pform + + def _print_factorial2(self, e): + x = e.args[0] + pform = self._print(x) + # Add parentheses if needed + if not ((x.is_Integer and x.is_nonnegative) or x.is_Symbol): + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.right('!!')) + return pform + + def _print_binomial(self, e): + n, k = e.args + + n_pform = self._print(n) + k_pform = self._print(k) + + bar = ' '*max(n_pform.width(), k_pform.width()) + + pform = prettyForm(*k_pform.above(bar)) + pform = prettyForm(*pform.above(n_pform)) + pform = prettyForm(*pform.parens('(', ')')) + + pform.baseline = (pform.baseline + 1)//2 + + return pform + + def _print_Relational(self, e): + op = prettyForm(' ' + xsym(e.rel_op) + ' ') + + l = self._print(e.lhs) + r = self._print(e.rhs) + pform = prettyForm(*stringPict.next(l, op, r), binding=prettyForm.OPEN) + return pform + + def _print_Not(self, e): + from sympy.logic.boolalg import (Equivalent, Implies) + if self._use_unicode: + arg = e.args[0] + pform = self._print(arg) + if isinstance(arg, Equivalent): + return self._print_Equivalent(arg, altchar=pretty_atom('NotEquiv')) + if isinstance(arg, Implies): + return self._print_Implies(arg, altchar=pretty_atom('NotArrow')) + + if arg.is_Boolean and not arg.is_Not: + pform = prettyForm(*pform.parens()) + + return prettyForm(*pform.left(pretty_atom('Not'))) + else: + return self._print_Function(e) + + def __print_Boolean(self, e, char, sort=True): + args = e.args + if sort: + args = sorted(e.args, key=default_sort_key) + arg = args[0] + pform = self._print(arg) + + if arg.is_Boolean and not arg.is_Not: + pform = prettyForm(*pform.parens()) + + for arg in args[1:]: + pform_arg = self._print(arg) + + if arg.is_Boolean and not arg.is_Not: + pform_arg = prettyForm(*pform_arg.parens()) + + pform = prettyForm(*pform.right(' %s ' % char)) + pform = prettyForm(*pform.right(pform_arg)) + + return pform + + def _print_And(self, e): + if self._use_unicode: + return self.__print_Boolean(e, pretty_atom('And')) + else: + return self._print_Function(e, sort=True) + + def _print_Or(self, e): + if self._use_unicode: + return self.__print_Boolean(e, pretty_atom('Or')) + else: + return self._print_Function(e, sort=True) + + def _print_Xor(self, e): + if self._use_unicode: + return self.__print_Boolean(e, pretty_atom("Xor")) + else: + return self._print_Function(e, sort=True) + + def _print_Nand(self, e): + if self._use_unicode: + return self.__print_Boolean(e, pretty_atom('Nand')) + else: + return self._print_Function(e, sort=True) + + def _print_Nor(self, e): + if self._use_unicode: + return self.__print_Boolean(e, pretty_atom('Nor')) + else: + return self._print_Function(e, sort=True) + + def _print_Implies(self, e, altchar=None): + if self._use_unicode: + return self.__print_Boolean(e, altchar or pretty_atom('Arrow'), sort=False) + else: + return self._print_Function(e) + + def _print_Equivalent(self, e, altchar=None): + if self._use_unicode: + return self.__print_Boolean(e, altchar or pretty_atom('Equiv')) + else: + return self._print_Function(e, sort=True) + + def _print_conjugate(self, e): + pform = self._print(e.args[0]) + return prettyForm( *pform.above( hobj('_', pform.width())) ) + + def _print_Abs(self, e): + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens('|', '|')) + return pform + + def _print_floor(self, e): + if self._use_unicode: + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens('lfloor', 'rfloor')) + return pform + else: + return self._print_Function(e) + + def _print_ceiling(self, e): + if self._use_unicode: + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens('lceil', 'rceil')) + return pform + else: + return self._print_Function(e) + + def _print_Derivative(self, deriv): + if requires_partial(deriv.expr) and self._use_unicode: + deriv_symbol = U('PARTIAL DIFFERENTIAL') + else: + deriv_symbol = r'd' + x = None + count_total_deriv = 0 + + for sym, num in reversed(deriv.variable_count): + s = self._print(sym) + ds = prettyForm(*s.left(deriv_symbol)) + count_total_deriv += num + + if (not num.is_Integer) or (num > 1): + ds = ds**prettyForm(str(num)) + + if x is None: + x = ds + else: + x = prettyForm(*x.right(' ')) + x = prettyForm(*x.right(ds)) + + f = prettyForm( + binding=prettyForm.FUNC, *self._print(deriv.expr).parens()) + + pform = prettyForm(deriv_symbol) + + if (count_total_deriv > 1) != False: + pform = pform**prettyForm(str(count_total_deriv)) + + pform = prettyForm(*pform.below(stringPict.LINE, x)) + pform.baseline = pform.baseline + 1 + pform = prettyForm(*stringPict.next(pform, f)) + pform.binding = prettyForm.MUL + + return pform + + def _print_Cycle(self, dc): + from sympy.combinatorics.permutations import Permutation, Cycle + # for Empty Cycle + if dc == Cycle(): + cyc = stringPict('') + return prettyForm(*cyc.parens()) + + dc_list = Permutation(dc.list()).cyclic_form + # for Identity Cycle + if dc_list == []: + cyc = self._print(dc.size - 1) + return prettyForm(*cyc.parens()) + + cyc = stringPict('') + for i in dc_list: + l = self._print(str(tuple(i)).replace(',', '')) + cyc = prettyForm(*cyc.right(l)) + return cyc + + def _print_Permutation(self, expr): + from sympy.combinatorics.permutations import Permutation, Cycle + + perm_cyclic = Permutation.print_cyclic + if perm_cyclic is not None: + sympy_deprecation_warning( + f""" + Setting Permutation.print_cyclic is deprecated. Instead use + init_printing(perm_cyclic={perm_cyclic}). + """, + deprecated_since_version="1.6", + active_deprecations_target="deprecated-permutation-print_cyclic", + stacklevel=7, + ) + else: + perm_cyclic = self._settings.get("perm_cyclic", True) + + if perm_cyclic: + return self._print_Cycle(Cycle(expr)) + + lower = expr.array_form + upper = list(range(len(lower))) + + result = stringPict('') + first = True + for u, l in zip(upper, lower): + s1 = self._print(u) + s2 = self._print(l) + col = prettyForm(*s1.below(s2)) + if first: + first = False + else: + col = prettyForm(*col.left(" ")) + result = prettyForm(*result.right(col)) + return prettyForm(*result.parens()) + + + def _print_Integral(self, integral): + f = integral.function + + # Add parentheses if arg involves addition of terms and + # create a pretty form for the argument + prettyF = self._print(f) + # XXX generalize parens + if f.is_Add: + prettyF = prettyForm(*prettyF.parens()) + + # dx dy dz ... + arg = prettyF + for x in integral.limits: + prettyArg = self._print(x[0]) + # XXX qparens (parens if needs-parens) + if prettyArg.width() > 1: + prettyArg = prettyForm(*prettyArg.parens()) + + arg = prettyForm(*arg.right(' d', prettyArg)) + + # \int \int \int ... + firstterm = True + s = None + for lim in integral.limits: + # Create bar based on the height of the argument + h = arg.height() + H = h + 2 + + # XXX hack! + ascii_mode = not self._use_unicode + if ascii_mode: + H += 2 + + vint = vobj('int', H) + + # Construct the pretty form with the integral sign and the argument + pform = prettyForm(vint) + pform.baseline = arg.baseline + ( + H - h)//2 # covering the whole argument + + if len(lim) > 1: + # Create pretty forms for endpoints, if definite integral. + # Do not print empty endpoints. + if len(lim) == 2: + prettyA = prettyForm("") + prettyB = self._print(lim[1]) + if len(lim) == 3: + prettyA = self._print(lim[1]) + prettyB = self._print(lim[2]) + + if ascii_mode: # XXX hack + # Add spacing so that endpoint can more easily be + # identified with the correct integral sign + spc = max(1, 3 - prettyB.width()) + prettyB = prettyForm(*prettyB.left(' ' * spc)) + + spc = max(1, 4 - prettyA.width()) + prettyA = prettyForm(*prettyA.right(' ' * spc)) + + pform = prettyForm(*pform.above(prettyB)) + pform = prettyForm(*pform.below(prettyA)) + + if not ascii_mode: # XXX hack + pform = prettyForm(*pform.right(' ')) + + if firstterm: + s = pform # first term + firstterm = False + else: + s = prettyForm(*s.left(pform)) + + pform = prettyForm(*arg.left(s)) + pform.binding = prettyForm.MUL + return pform + + def _print_Product(self, expr): + func = expr.term + pretty_func = self._print(func) + + horizontal_chr = xobj('_', 1) + corner_chr = xobj('_', 1) + vertical_chr = xobj('|', 1) + + if self._use_unicode: + # use unicode corners + horizontal_chr = xobj('-', 1) + corner_chr = xobj('UpTack', 1) + + func_height = pretty_func.height() + + first = True + max_upper = 0 + sign_height = 0 + + for lim in expr.limits: + pretty_lower, pretty_upper = self.__print_SumProduct_Limits(lim) + + width = (func_height + 2) * 5 // 3 - 2 + sign_lines = [horizontal_chr + corner_chr + (horizontal_chr * (width-2)) + corner_chr + horizontal_chr] + for _ in range(func_height + 1): + sign_lines.append(' ' + vertical_chr + (' ' * (width-2)) + vertical_chr + ' ') + + pretty_sign = stringPict('') + pretty_sign = prettyForm(*pretty_sign.stack(*sign_lines)) + + + max_upper = max(max_upper, pretty_upper.height()) + + if first: + sign_height = pretty_sign.height() + + pretty_sign = prettyForm(*pretty_sign.above(pretty_upper)) + pretty_sign = prettyForm(*pretty_sign.below(pretty_lower)) + + if first: + pretty_func.baseline = 0 + first = False + + height = pretty_sign.height() + padding = stringPict('') + padding = prettyForm(*padding.stack(*[' ']*(height - 1))) + pretty_sign = prettyForm(*pretty_sign.right(padding)) + + pretty_func = prettyForm(*pretty_sign.right(pretty_func)) + + pretty_func.baseline = max_upper + sign_height//2 + pretty_func.binding = prettyForm.MUL + return pretty_func + + def __print_SumProduct_Limits(self, lim): + def print_start(lhs, rhs): + op = prettyForm(' ' + xsym("==") + ' ') + l = self._print(lhs) + r = self._print(rhs) + pform = prettyForm(*stringPict.next(l, op, r)) + return pform + + prettyUpper = self._print(lim[2]) + prettyLower = print_start(lim[0], lim[1]) + return prettyLower, prettyUpper + + def _print_Sum(self, expr): + ascii_mode = not self._use_unicode + + def asum(hrequired, lower, upper, use_ascii): + def adjust(s, wid=None, how='<^>'): + if not wid or len(s) > wid: + return s + need = wid - len(s) + if how in ('<^>', "<") or how not in list('<^>'): + return s + ' '*need + half = need//2 + lead = ' '*half + if how == ">": + return " "*need + s + return lead + s + ' '*(need - len(lead)) + + h = max(hrequired, 2) + d = h//2 + w = d + 1 + more = hrequired % 2 + + lines = [] + if use_ascii: + lines.append("_"*(w) + ' ') + lines.append(r"\%s`" % (' '*(w - 1))) + for i in range(1, d): + lines.append('%s\\%s' % (' '*i, ' '*(w - i))) + if more: + lines.append('%s)%s' % (' '*(d), ' '*(w - d))) + for i in reversed(range(1, d)): + lines.append('%s/%s' % (' '*i, ' '*(w - i))) + lines.append("/" + "_"*(w - 1) + ',') + return d, h + more, lines, more + else: + w = w + more + d = d + more + vsum = vobj('sum', 4) + lines.append("_"*(w)) + for i in range(0, d): + lines.append('%s%s%s' % (' '*i, vsum[2], ' '*(w - i - 1))) + for i in reversed(range(0, d)): + lines.append('%s%s%s' % (' '*i, vsum[4], ' '*(w - i - 1))) + lines.append(vsum[8]*(w)) + return d, h + 2*more, lines, more + + f = expr.function + + prettyF = self._print(f) + + if f.is_Add: # add parens + prettyF = prettyForm(*prettyF.parens()) + + H = prettyF.height() + 2 + + # \sum \sum \sum ... + first = True + max_upper = 0 + sign_height = 0 + + for lim in expr.limits: + prettyLower, prettyUpper = self.__print_SumProduct_Limits(lim) + + max_upper = max(max_upper, prettyUpper.height()) + + # Create sum sign based on the height of the argument + d, h, slines, adjustment = asum( + H, prettyLower.width(), prettyUpper.width(), ascii_mode) + prettySign = stringPict('') + prettySign = prettyForm(*prettySign.stack(*slines)) + + if first: + sign_height = prettySign.height() + + prettySign = prettyForm(*prettySign.above(prettyUpper)) + prettySign = prettyForm(*prettySign.below(prettyLower)) + + if first: + # change F baseline so it centers on the sign + prettyF.baseline -= d - (prettyF.height()//2 - + prettyF.baseline) + first = False + + # put padding to the right + pad = stringPict('') + pad = prettyForm(*pad.stack(*[' ']*h)) + prettySign = prettyForm(*prettySign.right(pad)) + # put the present prettyF to the right + prettyF = prettyForm(*prettySign.right(prettyF)) + + # adjust baseline of ascii mode sigma with an odd height so that it is + # exactly through the center + ascii_adjustment = ascii_mode if not adjustment else 0 + prettyF.baseline = max_upper + sign_height//2 + ascii_adjustment + + prettyF.binding = prettyForm.MUL + return prettyF + + def _print_Limit(self, l): + e, z, z0, dir = l.args + + E = self._print(e) + if precedence(e) <= PRECEDENCE["Mul"]: + E = prettyForm(*E.parens('(', ')')) + Lim = prettyForm('lim') + + LimArg = self._print(z) + if self._use_unicode: + LimArg = prettyForm(*LimArg.right(f"{xobj('-', 1)}{pretty_atom('Arrow')}")) + else: + LimArg = prettyForm(*LimArg.right('->')) + LimArg = prettyForm(*LimArg.right(self._print(z0))) + + if str(dir) == '+-' or z0 in (S.Infinity, S.NegativeInfinity): + dir = "" + else: + if self._use_unicode: + dir = pretty_atom('SuperscriptPlus') if str(dir) == "+" else pretty_atom('SuperscriptMinus') + + LimArg = prettyForm(*LimArg.right(self._print(dir))) + + Lim = prettyForm(*Lim.below(LimArg)) + Lim = prettyForm(*Lim.right(E), binding=prettyForm.MUL) + + return Lim + + def _print_matrix_contents(self, e): + """ + This method factors out what is essentially grid printing. + """ + M = e # matrix + Ms = {} # i,j -> pretty(M[i,j]) + for i in range(M.rows): + for j in range(M.cols): + Ms[i, j] = self._print(M[i, j]) + + # h- and v- spacers + hsep = 2 + vsep = 1 + + # max width for columns + maxw = [-1] * M.cols + + for j in range(M.cols): + maxw[j] = max([Ms[i, j].width() for i in range(M.rows)] or [0]) + + # drawing result + D = None + + for i in range(M.rows): + + D_row = None + for j in range(M.cols): + s = Ms[i, j] + + # reshape s to maxw + # XXX this should be generalized, and go to stringPict.reshape ? + assert s.width() <= maxw[j] + + # hcenter it, +0.5 to the right 2 + # ( it's better to align formula starts for say 0 and r ) + # XXX this is not good in all cases -- maybe introduce vbaseline? + left, right = center_pad(s.width(), maxw[j]) + + s = prettyForm(*s.right(right)) + s = prettyForm(*s.left(left)) + + # we don't need vcenter cells -- this is automatically done in + # a pretty way because when their baselines are taking into + # account in .right() + + if D_row is None: + D_row = s # first box in a row + continue + + D_row = prettyForm(*D_row.right(' '*hsep)) # h-spacer + D_row = prettyForm(*D_row.right(s)) + + if D is None: + D = D_row # first row in a picture + continue + + # v-spacer + for _ in range(vsep): + D = prettyForm(*D.below(' ')) + + D = prettyForm(*D.below(D_row)) + + if D is None: + D = prettyForm('') # Empty Matrix + + return D + + def _print_MatrixBase(self, e, lparens='[', rparens=']'): + D = self._print_matrix_contents(e) + D.baseline = D.height()//2 + D = prettyForm(*D.parens(lparens, rparens)) + return D + + def _print_Determinant(self, e): + mat = e.arg + if mat.is_MatrixExpr: + from sympy.matrices.expressions.blockmatrix import BlockMatrix + if isinstance(mat, BlockMatrix): + return self._print_MatrixBase(mat.blocks, lparens='|', rparens='|') + D = self._print(mat) + D.baseline = D.height()//2 + return prettyForm(*D.parens('|', '|')) + else: + return self._print_MatrixBase(mat, lparens='|', rparens='|') + + def _print_TensorProduct(self, expr): + # This should somehow share the code with _print_WedgeProduct: + if self._use_unicode: + circled_times = "\u2297" + else: + circled_times = ".*" + return self._print_seq(expr.args, None, None, circled_times, + parenthesize=lambda x: precedence_traditional(x) <= PRECEDENCE["Mul"]) + + def _print_WedgeProduct(self, expr): + # This should somehow share the code with _print_TensorProduct: + if self._use_unicode: + wedge_symbol = "\u2227" + else: + wedge_symbol = '/\\' + return self._print_seq(expr.args, None, None, wedge_symbol, + parenthesize=lambda x: precedence_traditional(x) <= PRECEDENCE["Mul"]) + + def _print_Trace(self, e): + D = self._print(e.arg) + D = prettyForm(*D.parens('(',')')) + D.baseline = D.height()//2 + D = prettyForm(*D.left('\n'*(0) + 'tr')) + return D + + + def _print_MatrixElement(self, expr): + from sympy.matrices import MatrixSymbol + if (isinstance(expr.parent, MatrixSymbol) + and expr.i.is_number and expr.j.is_number): + return self._print( + Symbol(expr.parent.name + '_%d%d' % (expr.i, expr.j))) + else: + prettyFunc = self._print(expr.parent) + prettyFunc = prettyForm(*prettyFunc.parens()) + prettyIndices = self._print_seq((expr.i, expr.j), delimiter=', ' + ).parens(left='[', right=']')[0] + pform = prettyForm(binding=prettyForm.FUNC, + *stringPict.next(prettyFunc, prettyIndices)) + + # store pform parts so it can be reassembled e.g. when powered + pform.prettyFunc = prettyFunc + pform.prettyArgs = prettyIndices + + return pform + + + def _print_MatrixSlice(self, m): + # XXX works only for applied functions + from sympy.matrices import MatrixSymbol + prettyFunc = self._print(m.parent) + if not isinstance(m.parent, MatrixSymbol): + prettyFunc = prettyForm(*prettyFunc.parens()) + def ppslice(x, dim): + x = list(x) + if x[2] == 1: + del x[2] + if x[0] == 0: + x[0] = '' + if x[1] == dim: + x[1] = '' + return prettyForm(*self._print_seq(x, delimiter=':')) + prettyArgs = self._print_seq((ppslice(m.rowslice, m.parent.rows), + ppslice(m.colslice, m.parent.cols)), delimiter=', ').parens(left='[', right=']')[0] + + pform = prettyForm( + binding=prettyForm.FUNC, *stringPict.next(prettyFunc, prettyArgs)) + + # store pform parts so it can be reassembled e.g. when powered + pform.prettyFunc = prettyFunc + pform.prettyArgs = prettyArgs + + return pform + + def _print_Transpose(self, expr): + mat = expr.arg + pform = self._print(mat) + from sympy.matrices import MatrixSymbol, BlockMatrix + if (not isinstance(mat, MatrixSymbol) and + not isinstance(mat, BlockMatrix) and mat.is_MatrixExpr): + pform = prettyForm(*pform.parens()) + pform = pform**(prettyForm('T')) + return pform + + def _print_Adjoint(self, expr): + mat = expr.arg + pform = self._print(mat) + if self._use_unicode: + dag = prettyForm(pretty_atom('Dagger')) + else: + dag = prettyForm('+') + from sympy.matrices import MatrixSymbol, BlockMatrix + if (not isinstance(mat, MatrixSymbol) and + not isinstance(mat, BlockMatrix) and mat.is_MatrixExpr): + pform = prettyForm(*pform.parens()) + pform = pform**dag + return pform + + def _print_BlockMatrix(self, B): + if B.blocks.shape == (1, 1): + return self._print(B.blocks[0, 0]) + return self._print(B.blocks) + + def _print_MatAdd(self, expr): + s = None + for item in expr.args: + pform = self._print(item) + if s is None: + s = pform # First element + else: + coeff = item.as_coeff_mmul()[0] + if S(coeff).could_extract_minus_sign(): + s = prettyForm(*stringPict.next(s, ' ')) + pform = self._print(item) + else: + s = prettyForm(*stringPict.next(s, ' + ')) + s = prettyForm(*stringPict.next(s, pform)) + + return s + + def _print_MatMul(self, expr): + args = list(expr.args) + from sympy.matrices.expressions.hadamard import HadamardProduct + from sympy.matrices.expressions.kronecker import KroneckerProduct + from sympy.matrices.expressions.matadd import MatAdd + for i, a in enumerate(args): + if (isinstance(a, (Add, MatAdd, HadamardProduct, KroneckerProduct)) + and len(expr.args) > 1): + args[i] = prettyForm(*self._print(a).parens()) + else: + args[i] = self._print(a) + + return prettyForm.__mul__(*args) + + def _print_Identity(self, expr): + if self._use_unicode: + return prettyForm(pretty_atom('IdentityMatrix')) + else: + return prettyForm('I') + + def _print_ZeroMatrix(self, expr): + if self._use_unicode: + return prettyForm(pretty_atom('ZeroMatrix')) + else: + return prettyForm('0') + + def _print_OneMatrix(self, expr): + if self._use_unicode: + return prettyForm(pretty_atom("OneMatrix")) + else: + return prettyForm('1') + + def _print_DotProduct(self, expr): + args = list(expr.args) + + for i, a in enumerate(args): + args[i] = self._print(a) + return prettyForm.__mul__(*args) + + def _print_MatPow(self, expr): + pform = self._print(expr.base) + from sympy.matrices import MatrixSymbol + if not isinstance(expr.base, MatrixSymbol) and expr.base.is_MatrixExpr: + pform = prettyForm(*pform.parens()) + pform = pform**(self._print(expr.exp)) + return pform + + def _print_HadamardProduct(self, expr): + from sympy.matrices.expressions.hadamard import HadamardProduct + from sympy.matrices.expressions.matadd import MatAdd + from sympy.matrices.expressions.matmul import MatMul + if self._use_unicode: + delim = pretty_atom('Ring') + else: + delim = '.*' + return self._print_seq(expr.args, None, None, delim, + parenthesize=lambda x: isinstance(x, (MatAdd, MatMul, HadamardProduct))) + + def _print_HadamardPower(self, expr): + # from sympy import MatAdd, MatMul + if self._use_unicode: + circ = pretty_atom('Ring') + else: + circ = self._print('.') + pretty_base = self._print(expr.base) + pretty_exp = self._print(expr.exp) + if precedence(expr.exp) < PRECEDENCE["Mul"]: + pretty_exp = prettyForm(*pretty_exp.parens()) + pretty_circ_exp = prettyForm( + binding=prettyForm.LINE, + *stringPict.next(circ, pretty_exp) + ) + return pretty_base**pretty_circ_exp + + def _print_KroneckerProduct(self, expr): + from sympy.matrices.expressions.matadd import MatAdd + from sympy.matrices.expressions.matmul import MatMul + if self._use_unicode: + delim = f" {pretty_atom('TensorProduct')} " + else: + delim = ' x ' + return self._print_seq(expr.args, None, None, delim, + parenthesize=lambda x: isinstance(x, (MatAdd, MatMul))) + + def _print_FunctionMatrix(self, X): + D = self._print(X.lamda.expr) + D = prettyForm(*D.parens('[', ']')) + return D + + def _print_TransferFunction(self, expr): + if not expr.num == 1: + num, den = expr.num, expr.den + res = Mul(num, Pow(den, -1, evaluate=False), evaluate=False) + return self._print_Mul(res) + else: + return self._print(1)/self._print(expr.den) + + def _print_Series(self, expr): + args = list(expr.args) + for i, a in enumerate(expr.args): + args[i] = prettyForm(*self._print(a).parens()) + return prettyForm.__mul__(*args) + + def _print_MIMOSeries(self, expr): + from sympy.physics.control.lti import MIMOParallel + args = list(expr.args) + pretty_args = [] + for a in reversed(args): + if (isinstance(a, MIMOParallel) and len(expr.args) > 1): + expression = self._print(a) + expression.baseline = expression.height()//2 + pretty_args.append(prettyForm(*expression.parens())) + else: + expression = self._print(a) + expression.baseline = expression.height()//2 + pretty_args.append(expression) + return prettyForm.__mul__(*pretty_args) + + def _print_Parallel(self, expr): + s = None + for item in expr.args: + pform = self._print(item) + if s is None: + s = pform # First element + else: + s = prettyForm(*stringPict.next(s)) + s.baseline = s.height()//2 + s = prettyForm(*stringPict.next(s, ' + ')) + s = prettyForm(*stringPict.next(s, pform)) + return s + + def _print_MIMOParallel(self, expr): + from sympy.physics.control.lti import TransferFunctionMatrix + s = None + for item in expr.args: + pform = self._print(item) + if s is None: + s = pform # First element + else: + s = prettyForm(*stringPict.next(s)) + s.baseline = s.height()//2 + s = prettyForm(*stringPict.next(s, ' + ')) + if isinstance(item, TransferFunctionMatrix): + s.baseline = s.height() - 1 + s = prettyForm(*stringPict.next(s, pform)) + # s.baseline = s.height()//2 + return s + + def _print_Feedback(self, expr): + from sympy.physics.control import TransferFunction, Series + + num, tf = expr.sys1, TransferFunction(1, 1, expr.var) + num_arg_list = list(num.args) if isinstance(num, Series) else [num] + den_arg_list = list(expr.sys2.args) if \ + isinstance(expr.sys2, Series) else [expr.sys2] + + if isinstance(num, Series) and isinstance(expr.sys2, Series): + den = Series(*num_arg_list, *den_arg_list) + elif isinstance(num, Series) and isinstance(expr.sys2, TransferFunction): + if expr.sys2 == tf: + den = Series(*num_arg_list) + else: + den = Series(*num_arg_list, expr.sys2) + elif isinstance(num, TransferFunction) and isinstance(expr.sys2, Series): + if num == tf: + den = Series(*den_arg_list) + else: + den = Series(num, *den_arg_list) + else: + if num == tf: + den = Series(*den_arg_list) + elif expr.sys2 == tf: + den = Series(*num_arg_list) + else: + den = Series(*num_arg_list, *den_arg_list) + + denom = prettyForm(*stringPict.next(self._print(tf))) + denom.baseline = denom.height()//2 + denom = prettyForm(*stringPict.next(denom, ' + ')) if expr.sign == -1 \ + else prettyForm(*stringPict.next(denom, ' - ')) + denom = prettyForm(*stringPict.next(denom, self._print(den))) + + return self._print(num)/denom + + def _print_MIMOFeedback(self, expr): + from sympy.physics.control import MIMOSeries, TransferFunctionMatrix + + inv_mat = self._print(MIMOSeries(expr.sys2, expr.sys1)) + plant = self._print(expr.sys1) + _feedback = prettyForm(*stringPict.next(inv_mat)) + _feedback = prettyForm(*stringPict.right("I + ", _feedback)) if expr.sign == -1 \ + else prettyForm(*stringPict.right("I - ", _feedback)) + _feedback = prettyForm(*stringPict.parens(_feedback)) + _feedback.baseline = 0 + _feedback = prettyForm(*stringPict.right(_feedback, '-1 ')) + _feedback.baseline = _feedback.height()//2 + _feedback = prettyForm.__mul__(_feedback, prettyForm(" ")) + if isinstance(expr.sys1, TransferFunctionMatrix): + _feedback.baseline = _feedback.height() - 1 + _feedback = prettyForm(*stringPict.next(_feedback, plant)) + return _feedback + + def _print_TransferFunctionMatrix(self, expr): + mat = self._print(expr._expr_mat) + mat.baseline = mat.height() - 1 + subscript = greek_unicode['tau'] if self._use_unicode else r'{t}' + mat = prettyForm(*mat.right(subscript)) + return mat + + def _print_StateSpace(self, expr): + from sympy.matrices.expressions.blockmatrix import BlockMatrix + A = expr._A + B = expr._B + C = expr._C + D = expr._D + mat = BlockMatrix([[A, B], [C, D]]) + return self._print(mat.blocks) + + def _print_BasisDependent(self, expr): + from sympy.vector import Vector + + if not self._use_unicode: + raise NotImplementedError("ASCII pretty printing of BasisDependent is not implemented") + + if expr == expr.zero: + return prettyForm(expr.zero._pretty_form) + o1 = [] + vectstrs = [] + if isinstance(expr, Vector): + items = expr.separate().items() + else: + items = [(0, expr)] + for system, vect in items: + inneritems = list(vect.components.items()) + inneritems.sort(key = lambda x: x[0].__str__()) + for k, v in inneritems: + #if the coef of the basis vector is 1 + #we skip the 1 + if v == 1: + o1.append("" + + k._pretty_form) + #Same for -1 + elif v == -1: + o1.append("(-1) " + + k._pretty_form) + #For a general expr + else: + #We always wrap the measure numbers in + #parentheses + arg_str = self._print( + v).parens()[0] + + o1.append(arg_str + ' ' + k._pretty_form) + vectstrs.append(k._pretty_form) + + #outstr = u("").join(o1) + if o1[0].startswith(" + "): + o1[0] = o1[0][3:] + elif o1[0].startswith(" "): + o1[0] = o1[0][1:] + #Fixing the newlines + lengths = [] + strs = [''] + flag = [] + for i, partstr in enumerate(o1): + flag.append(0) + # XXX: What is this hack? + if '\n' in partstr: + tempstr = partstr + tempstr = tempstr.replace(vectstrs[i], '') + if xobj(')_ext', 1) in tempstr: # If scalar is a fraction + for paren in range(len(tempstr)): + flag[i] = 1 + if tempstr[paren] == xobj(')_ext', 1) and tempstr[paren + 1] == '\n': + # We want to place the vector string after all the right parentheses, because + # otherwise, the vector will be in the middle of the string + tempstr = tempstr[:paren] + xobj(')_ext', 1)\ + + ' ' + vectstrs[i] + tempstr[paren + 1:] + break + elif xobj(')_lower_hook', 1) in tempstr: + # We want to place the vector string after all the right parentheses, because + # otherwise, the vector will be in the middle of the string. For this reason, + # we insert the vector string at the rightmost index. + index = tempstr.rfind(xobj(')_lower_hook', 1)) + if index != -1: # then this character was found in this string + flag[i] = 1 + tempstr = tempstr[:index] + xobj(')_lower_hook', 1)\ + + ' ' + vectstrs[i] + tempstr[index + 1:] + o1[i] = tempstr + + o1 = [x.split('\n') for x in o1] + n_newlines = max(len(x) for x in o1) # Width of part in its pretty form + + if 1 in flag: # If there was a fractional scalar + for i, parts in enumerate(o1): + if len(parts) == 1: # If part has no newline + parts.insert(0, ' ' * (len(parts[0]))) + flag[i] = 1 + + for i, parts in enumerate(o1): + lengths.append(len(parts[flag[i]])) + for j in range(n_newlines): + if j+1 <= len(parts): + if j >= len(strs): + strs.append(' ' * (sum(lengths[:-1]) + + 3*(len(lengths)-1))) + if j == flag[i]: + strs[flag[i]] += parts[flag[i]] + ' + ' + else: + strs[j] += parts[j] + ' '*(lengths[-1] - + len(parts[j])+ + 3) + else: + if j >= len(strs): + strs.append(' ' * (sum(lengths[:-1]) + + 3*(len(lengths)-1))) + strs[j] += ' '*(lengths[-1]+3) + + return prettyForm('\n'.join([s[:-3] for s in strs])) + + def _print_NDimArray(self, expr): + from sympy.matrices.immutable import ImmutableMatrix + + if expr.rank() == 0: + return self._print(expr[()]) + + level_str = [[]] + [[] for i in range(expr.rank())] + shape_ranges = [list(range(i)) for i in expr.shape] + # leave eventual matrix elements unflattened + mat = lambda x: ImmutableMatrix(x, evaluate=False) + for outer_i in itertools.product(*shape_ranges): + level_str[-1].append(expr[outer_i]) + even = True + for back_outer_i in range(expr.rank()-1, -1, -1): + if len(level_str[back_outer_i+1]) < expr.shape[back_outer_i]: + break + if even: + level_str[back_outer_i].append(level_str[back_outer_i+1]) + else: + level_str[back_outer_i].append(mat( + level_str[back_outer_i+1])) + if len(level_str[back_outer_i + 1]) == 1: + level_str[back_outer_i][-1] = mat( + [[level_str[back_outer_i][-1]]]) + even = not even + level_str[back_outer_i+1] = [] + + out_expr = level_str[0][0] + if expr.rank() % 2 == 1: + out_expr = mat([out_expr]) + + return self._print(out_expr) + + def _printer_tensor_indices(self, name, indices, index_map={}): + center = stringPict(name) + top = stringPict(" "*center.width()) + bot = stringPict(" "*center.width()) + + last_valence = None + prev_map = None + + for index in indices: + indpic = self._print(index.args[0]) + if ((index in index_map) or prev_map) and last_valence == index.is_up: + if index.is_up: + top = prettyForm(*stringPict.next(top, ",")) + else: + bot = prettyForm(*stringPict.next(bot, ",")) + if index in index_map: + indpic = prettyForm(*stringPict.next(indpic, "=")) + indpic = prettyForm(*stringPict.next(indpic, self._print(index_map[index]))) + prev_map = True + else: + prev_map = False + if index.is_up: + top = stringPict(*top.right(indpic)) + center = stringPict(*center.right(" "*indpic.width())) + bot = stringPict(*bot.right(" "*indpic.width())) + else: + bot = stringPict(*bot.right(indpic)) + center = stringPict(*center.right(" "*indpic.width())) + top = stringPict(*top.right(" "*indpic.width())) + last_valence = index.is_up + + pict = prettyForm(*center.above(top)) + pict = prettyForm(*pict.below(bot)) + return pict + + def _print_Tensor(self, expr): + name = expr.args[0].name + indices = expr.get_indices() + return self._printer_tensor_indices(name, indices) + + def _print_TensorElement(self, expr): + name = expr.expr.args[0].name + indices = expr.expr.get_indices() + index_map = expr.index_map + return self._printer_tensor_indices(name, indices, index_map) + + def _print_TensMul(self, expr): + sign, args = expr._get_args_for_traditional_printer() + args = [ + prettyForm(*self._print(i).parens()) if + precedence_traditional(i) < PRECEDENCE["Mul"] else self._print(i) + for i in args + ] + pform = prettyForm.__mul__(*args) + if sign: + return prettyForm(*pform.left(sign)) + else: + return pform + + def _print_TensAdd(self, expr): + args = [ + prettyForm(*self._print(i).parens()) if + precedence_traditional(i) < PRECEDENCE["Mul"] else self._print(i) + for i in expr.args + ] + return prettyForm.__add__(*args) + + def _print_TensorIndex(self, expr): + sym = expr.args[0] + if not expr.is_up: + sym = -sym + return self._print(sym) + + def _print_PartialDerivative(self, deriv): + if self._use_unicode: + deriv_symbol = U('PARTIAL DIFFERENTIAL') + else: + deriv_symbol = r'd' + x = None + + for variable in reversed(deriv.variables): + s = self._print(variable) + ds = prettyForm(*s.left(deriv_symbol)) + + if x is None: + x = ds + else: + x = prettyForm(*x.right(' ')) + x = prettyForm(*x.right(ds)) + + f = prettyForm( + binding=prettyForm.FUNC, *self._print(deriv.expr).parens()) + + pform = prettyForm(deriv_symbol) + + if len(deriv.variables) > 1: + pform = pform**self._print(len(deriv.variables)) + + pform = prettyForm(*pform.below(stringPict.LINE, x)) + pform.baseline = pform.baseline + 1 + pform = prettyForm(*stringPict.next(pform, f)) + pform.binding = prettyForm.MUL + + return pform + + def _print_Piecewise(self, pexpr): + + P = {} + for n, ec in enumerate(pexpr.args): + P[n, 0] = self._print(ec.expr) + if ec.cond == True: + P[n, 1] = prettyForm('otherwise') + else: + P[n, 1] = prettyForm( + *prettyForm('for ').right(self._print(ec.cond))) + hsep = 2 + vsep = 1 + len_args = len(pexpr.args) + + # max widths + maxw = [max(P[i, j].width() for i in range(len_args)) + for j in range(2)] + + # FIXME: Refactor this code and matrix into some tabular environment. + # drawing result + D = None + + for i in range(len_args): + D_row = None + for j in range(2): + p = P[i, j] + assert p.width() <= maxw[j] + + wdelta = maxw[j] - p.width() + wleft = wdelta // 2 + wright = wdelta - wleft + + p = prettyForm(*p.right(' '*wright)) + p = prettyForm(*p.left(' '*wleft)) + + if D_row is None: + D_row = p + continue + + D_row = prettyForm(*D_row.right(' '*hsep)) # h-spacer + D_row = prettyForm(*D_row.right(p)) + if D is None: + D = D_row # first row in a picture + continue + + # v-spacer + for _ in range(vsep): + D = prettyForm(*D.below(' ')) + + D = prettyForm(*D.below(D_row)) + + D = prettyForm(*D.parens('{', '')) + D.baseline = D.height()//2 + D.binding = prettyForm.OPEN + return D + + def _print_ITE(self, ite): + from sympy.functions.elementary.piecewise import Piecewise + return self._print(ite.rewrite(Piecewise)) + + def _hprint_vec(self, v): + D = None + + for a in v: + p = a + if D is None: + D = p + else: + D = prettyForm(*D.right(', ')) + D = prettyForm(*D.right(p)) + if D is None: + D = stringPict(' ') + + return D + + def _hprint_vseparator(self, p1, p2, left=None, right=None, delimiter='', ifascii_nougly=False): + if ifascii_nougly and not self._use_unicode: + return self._print_seq((p1, '|', p2), left=left, right=right, + delimiter=delimiter, ifascii_nougly=True) + tmp = self._print_seq((p1, p2,), left=left, right=right, delimiter=delimiter) + sep = stringPict(vobj('|', tmp.height()), baseline=tmp.baseline) + return self._print_seq((p1, sep, p2), left=left, right=right, + delimiter=delimiter) + + def _print_hyper(self, e): + # FIXME refactor Matrix, Piecewise, and this into a tabular environment + ap = [self._print(a) for a in e.ap] + bq = [self._print(b) for b in e.bq] + + P = self._print(e.argument) + P.baseline = P.height()//2 + + # Drawing result - first create the ap, bq vectors + D = None + for v in [ap, bq]: + D_row = self._hprint_vec(v) + if D is None: + D = D_row # first row in a picture + else: + D = prettyForm(*D.below(' ')) + D = prettyForm(*D.below(D_row)) + + # make sure that the argument `z' is centred vertically + D.baseline = D.height()//2 + + # insert horizontal separator + P = prettyForm(*P.left(' ')) + D = prettyForm(*D.right(' ')) + + # insert separating `|` + D = self._hprint_vseparator(D, P) + + # add parens + D = prettyForm(*D.parens('(', ')')) + + # create the F symbol + above = D.height()//2 - 1 + below = D.height() - above - 1 + + sz, t, b, add, img = annotated('F') + F = prettyForm('\n' * (above - t) + img + '\n' * (below - b), + baseline=above + sz) + add = (sz + 1)//2 + + F = prettyForm(*F.left(self._print(len(e.ap)))) + F = prettyForm(*F.right(self._print(len(e.bq)))) + F.baseline = above + add + + D = prettyForm(*F.right(' ', D)) + + return D + + def _print_meijerg(self, e): + # FIXME refactor Matrix, Piecewise, and this into a tabular environment + + v = {} + v[(0, 0)] = [self._print(a) for a in e.an] + v[(0, 1)] = [self._print(a) for a in e.aother] + v[(1, 0)] = [self._print(b) for b in e.bm] + v[(1, 1)] = [self._print(b) for b in e.bother] + + P = self._print(e.argument) + P.baseline = P.height()//2 + + vp = {} + for idx in v: + vp[idx] = self._hprint_vec(v[idx]) + + for i in range(2): + maxw = max(vp[(0, i)].width(), vp[(1, i)].width()) + for j in range(2): + s = vp[(j, i)] + left = (maxw - s.width()) // 2 + right = maxw - left - s.width() + s = prettyForm(*s.left(' ' * left)) + s = prettyForm(*s.right(' ' * right)) + vp[(j, i)] = s + + D1 = prettyForm(*vp[(0, 0)].right(' ', vp[(0, 1)])) + D1 = prettyForm(*D1.below(' ')) + D2 = prettyForm(*vp[(1, 0)].right(' ', vp[(1, 1)])) + D = prettyForm(*D1.below(D2)) + + # make sure that the argument `z' is centred vertically + D.baseline = D.height()//2 + + # insert horizontal separator + P = prettyForm(*P.left(' ')) + D = prettyForm(*D.right(' ')) + + # insert separating `|` + D = self._hprint_vseparator(D, P) + + # add parens + D = prettyForm(*D.parens('(', ')')) + + # create the G symbol + above = D.height()//2 - 1 + below = D.height() - above - 1 + + sz, t, b, add, img = annotated('G') + F = prettyForm('\n' * (above - t) + img + '\n' * (below - b), + baseline=above + sz) + + pp = self._print(len(e.ap)) + pq = self._print(len(e.bq)) + pm = self._print(len(e.bm)) + pn = self._print(len(e.an)) + + def adjust(p1, p2): + diff = p1.width() - p2.width() + if diff == 0: + return p1, p2 + elif diff > 0: + return p1, prettyForm(*p2.left(' '*diff)) + else: + return prettyForm(*p1.left(' '*-diff)), p2 + pp, pm = adjust(pp, pm) + pq, pn = adjust(pq, pn) + pu = prettyForm(*pm.right(', ', pn)) + pl = prettyForm(*pp.right(', ', pq)) + + ht = F.baseline - above - 2 + if ht > 0: + pu = prettyForm(*pu.below('\n'*ht)) + p = prettyForm(*pu.below(pl)) + + F.baseline = above + F = prettyForm(*F.right(p)) + + F.baseline = above + add + + D = prettyForm(*F.right(' ', D)) + + return D + + def _print_ExpBase(self, e): + # TODO should exp_polar be printed differently? + # what about exp_polar(0), exp_polar(1)? + base = prettyForm(pretty_atom('Exp1', 'e')) + return base ** self._print(e.args[0]) + + def _print_Exp1(self, e): + return prettyForm(pretty_atom('Exp1', 'e')) + + def _print_Function(self, e, sort=False, func_name=None, left='(', + right=')'): + # optional argument func_name for supplying custom names + # XXX works only for applied functions + return self._helper_print_function(e.func, e.args, sort=sort, func_name=func_name, left=left, right=right) + + def _print_mathieuc(self, e): + return self._print_Function(e, func_name='C') + + def _print_mathieus(self, e): + return self._print_Function(e, func_name='S') + + def _print_mathieucprime(self, e): + return self._print_Function(e, func_name="C'") + + def _print_mathieusprime(self, e): + return self._print_Function(e, func_name="S'") + + def _helper_print_function(self, func, args, sort=False, func_name=None, + delimiter=', ', elementwise=False, left='(', + right=')'): + if sort: + args = sorted(args, key=default_sort_key) + + if not func_name and hasattr(func, "__name__"): + func_name = func.__name__ + + if func_name: + prettyFunc = self._print(Symbol(func_name)) + else: + prettyFunc = prettyForm(*self._print(func).parens()) + + if elementwise: + if self._use_unicode: + circ = pretty_atom('Modifier Letter Low Ring') + else: + circ = '.' + circ = self._print(circ) + prettyFunc = prettyForm( + binding=prettyForm.LINE, + *stringPict.next(prettyFunc, circ) + ) + + prettyArgs = prettyForm(*self._print_seq(args, delimiter=delimiter).parens( + left=left, right=right)) + + pform = prettyForm( + binding=prettyForm.FUNC, *stringPict.next(prettyFunc, prettyArgs)) + + # store pform parts so it can be reassembled e.g. when powered + pform.prettyFunc = prettyFunc + pform.prettyArgs = prettyArgs + + return pform + + def _print_ElementwiseApplyFunction(self, e): + func = e.function + arg = e.expr + args = [arg] + return self._helper_print_function(func, args, delimiter="", elementwise=True) + + @property + def _special_function_classes(self): + from sympy.functions.special.tensor_functions import KroneckerDelta + from sympy.functions.special.gamma_functions import gamma, lowergamma + from sympy.functions.special.zeta_functions import lerchphi + from sympy.functions.special.beta_functions import beta + from sympy.functions.special.delta_functions import DiracDelta + from sympy.functions.special.error_functions import Chi + return {KroneckerDelta: [greek_unicode['delta'], 'delta'], + gamma: [greek_unicode['Gamma'], 'Gamma'], + lerchphi: [greek_unicode['Phi'], 'lerchphi'], + lowergamma: [greek_unicode['gamma'], 'gamma'], + beta: [greek_unicode['Beta'], 'B'], + DiracDelta: [greek_unicode['delta'], 'delta'], + Chi: ['Chi', 'Chi']} + + def _print_FunctionClass(self, expr): + for cls in self._special_function_classes: + if issubclass(expr, cls) and expr.__name__ == cls.__name__: + if self._use_unicode: + return prettyForm(self._special_function_classes[cls][0]) + else: + return prettyForm(self._special_function_classes[cls][1]) + func_name = expr.__name__ + return prettyForm(pretty_symbol(func_name)) + + def _print_GeometryEntity(self, expr): + # GeometryEntity is based on Tuple but should not print like a Tuple + return self.emptyPrinter(expr) + + def _print_polylog(self, e): + subscript = self._print(e.args[0]) + if self._use_unicode and is_subscriptable_in_unicode(subscript): + return self._print_Function(Function('Li_%s' % subscript)(e.args[1])) + return self._print_Function(e) + + def _print_lerchphi(self, e): + func_name = greek_unicode['Phi'] if self._use_unicode else 'lerchphi' + return self._print_Function(e, func_name=func_name) + + def _print_dirichlet_eta(self, e): + func_name = greek_unicode['eta'] if self._use_unicode else 'dirichlet_eta' + return self._print_Function(e, func_name=func_name) + + def _print_Heaviside(self, e): + func_name = greek_unicode['theta'] if self._use_unicode else 'Heaviside' + if e.args[1] is S.Half: + pform = prettyForm(*self._print(e.args[0]).parens()) + pform = prettyForm(*pform.left(func_name)) + return pform + else: + return self._print_Function(e, func_name=func_name) + + def _print_fresnels(self, e): + return self._print_Function(e, func_name="S") + + def _print_fresnelc(self, e): + return self._print_Function(e, func_name="C") + + def _print_airyai(self, e): + return self._print_Function(e, func_name="Ai") + + def _print_airybi(self, e): + return self._print_Function(e, func_name="Bi") + + def _print_airyaiprime(self, e): + return self._print_Function(e, func_name="Ai'") + + def _print_airybiprime(self, e): + return self._print_Function(e, func_name="Bi'") + + def _print_LambertW(self, e): + return self._print_Function(e, func_name="W") + + def _print_Covariance(self, e): + return self._print_Function(e, func_name="Cov") + + def _print_Variance(self, e): + return self._print_Function(e, func_name="Var") + + def _print_Probability(self, e): + return self._print_Function(e, func_name="P") + + def _print_Expectation(self, e): + return self._print_Function(e, func_name="E", left='[', right=']') + + def _print_Lambda(self, e): + expr = e.expr + sig = e.signature + if self._use_unicode: + arrow = f" {pretty_atom('ArrowFromBar')} " + else: + arrow = " -> " + if len(sig) == 1 and sig[0].is_symbol: + sig = sig[0] + var_form = self._print(sig) + + return prettyForm(*stringPict.next(var_form, arrow, self._print(expr)), binding=8) + + def _print_Order(self, expr): + pform = self._print(expr.expr) + if (expr.point and any(p != S.Zero for p in expr.point)) or \ + len(expr.variables) > 1: + pform = prettyForm(*pform.right("; ")) + if len(expr.variables) > 1: + pform = prettyForm(*pform.right(self._print(expr.variables))) + elif len(expr.variables): + pform = prettyForm(*pform.right(self._print(expr.variables[0]))) + if self._use_unicode: + pform = prettyForm(*pform.right(f" {pretty_atom('Arrow')} ")) + else: + pform = prettyForm(*pform.right(" -> ")) + if len(expr.point) > 1: + pform = prettyForm(*pform.right(self._print(expr.point))) + else: + pform = prettyForm(*pform.right(self._print(expr.point[0]))) + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left("O")) + return pform + + def _print_SingularityFunction(self, e): + if self._use_unicode: + shift = self._print(e.args[0]-e.args[1]) + n = self._print(e.args[2]) + base = prettyForm("<") + base = prettyForm(*base.right(shift)) + base = prettyForm(*base.right(">")) + pform = base**n + return pform + else: + n = self._print(e.args[2]) + shift = self._print(e.args[0]-e.args[1]) + base = self._print_seq(shift, "<", ">", ' ') + return base**n + + def _print_beta(self, e): + func_name = greek_unicode['Beta'] if self._use_unicode else 'B' + return self._print_Function(e, func_name=func_name) + + def _print_betainc(self, e): + func_name = "B'" + return self._print_Function(e, func_name=func_name) + + def _print_betainc_regularized(self, e): + func_name = 'I' + return self._print_Function(e, func_name=func_name) + + def _print_gamma(self, e): + func_name = greek_unicode['Gamma'] if self._use_unicode else 'Gamma' + return self._print_Function(e, func_name=func_name) + + def _print_uppergamma(self, e): + func_name = greek_unicode['Gamma'] if self._use_unicode else 'Gamma' + return self._print_Function(e, func_name=func_name) + + def _print_lowergamma(self, e): + func_name = greek_unicode['gamma'] if self._use_unicode else 'lowergamma' + return self._print_Function(e, func_name=func_name) + + def _print_DiracDelta(self, e): + if self._use_unicode: + if len(e.args) == 2: + a = prettyForm(greek_unicode['delta']) + b = self._print(e.args[1]) + b = prettyForm(*b.parens()) + c = self._print(e.args[0]) + c = prettyForm(*c.parens()) + pform = a**b + pform = prettyForm(*pform.right(' ')) + pform = prettyForm(*pform.right(c)) + return pform + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left(greek_unicode['delta'])) + return pform + else: + return self._print_Function(e) + + def _print_expint(self, e): + subscript = self._print(e.args[0]) + if self._use_unicode and is_subscriptable_in_unicode(subscript): + return self._print_Function(Function('E_%s' % subscript)(e.args[1])) + return self._print_Function(e) + + def _print_Chi(self, e): + # This needs a special case since otherwise it comes out as greek + # letter chi... + prettyFunc = prettyForm("Chi") + prettyArgs = prettyForm(*self._print_seq(e.args).parens()) + + pform = prettyForm( + binding=prettyForm.FUNC, *stringPict.next(prettyFunc, prettyArgs)) + + # store pform parts so it can be reassembled e.g. when powered + pform.prettyFunc = prettyFunc + pform.prettyArgs = prettyArgs + + return pform + + def _print_elliptic_e(self, e): + pforma0 = self._print(e.args[0]) + if len(e.args) == 1: + pform = pforma0 + else: + pforma1 = self._print(e.args[1]) + pform = self._hprint_vseparator(pforma0, pforma1) + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left('E')) + return pform + + def _print_elliptic_k(self, e): + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left('K')) + return pform + + def _print_elliptic_f(self, e): + pforma0 = self._print(e.args[0]) + pforma1 = self._print(e.args[1]) + pform = self._hprint_vseparator(pforma0, pforma1) + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left('F')) + return pform + + def _print_elliptic_pi(self, e): + name = greek_unicode['Pi'] if self._use_unicode else 'Pi' + pforma0 = self._print(e.args[0]) + pforma1 = self._print(e.args[1]) + if len(e.args) == 2: + pform = self._hprint_vseparator(pforma0, pforma1) + else: + pforma2 = self._print(e.args[2]) + pforma = self._hprint_vseparator(pforma1, pforma2, ifascii_nougly=False) + pforma = prettyForm(*pforma.left('; ')) + pform = prettyForm(*pforma.left(pforma0)) + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left(name)) + return pform + + def _print_GoldenRatio(self, expr): + if self._use_unicode: + return prettyForm(pretty_symbol('phi')) + return self._print(Symbol("GoldenRatio")) + + def _print_EulerGamma(self, expr): + if self._use_unicode: + return prettyForm(pretty_symbol('gamma')) + return self._print(Symbol("EulerGamma")) + + def _print_Catalan(self, expr): + return self._print(Symbol("G")) + + def _print_Mod(self, expr): + pform = self._print(expr.args[0]) + if pform.binding > prettyForm.MUL: + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.right(' mod ')) + pform = prettyForm(*pform.right(self._print(expr.args[1]))) + pform.binding = prettyForm.OPEN + return pform + + def _print_Add(self, expr, order=None): + terms = self._as_ordered_terms(expr, order=order) + pforms, indices = [], [] + + def pretty_negative(pform, index): + """Prepend a minus sign to a pretty form. """ + #TODO: Move this code to prettyForm + if index == 0: + if pform.height() > 1: + pform_neg = '- ' + else: + pform_neg = '-' + else: + pform_neg = ' - ' + + if (pform.binding > prettyForm.NEG + or pform.binding == prettyForm.ADD): + p = stringPict(*pform.parens()) + else: + p = pform + p = stringPict.next(pform_neg, p) + # Lower the binding to NEG, even if it was higher. Otherwise, it + # will print as a + ( - (b)), instead of a - (b). + return prettyForm(binding=prettyForm.NEG, *p) + + for i, term in enumerate(terms): + if term.is_Mul and term.could_extract_minus_sign(): + coeff, other = term.as_coeff_mul(rational=False) + if coeff == -1: + negterm = Mul(*other, evaluate=False) + else: + negterm = Mul(-coeff, *other, evaluate=False) + pform = self._print(negterm) + pforms.append(pretty_negative(pform, i)) + elif term.is_Rational and term.q > 1: + pforms.append(None) + indices.append(i) + elif term.is_Number and term < 0: + pform = self._print(-term) + pforms.append(pretty_negative(pform, i)) + elif term.is_Relational: + pforms.append(prettyForm(*self._print(term).parens())) + else: + pforms.append(self._print(term)) + + if indices: + large = True + + for pform in pforms: + if pform is not None and pform.height() > 1: + break + else: + large = False + + for i in indices: + term, negative = terms[i], False + + if term < 0: + term, negative = -term, True + + if large: + pform = prettyForm(str(term.p))/prettyForm(str(term.q)) + else: + pform = self._print(term) + + if negative: + pform = pretty_negative(pform, i) + + pforms[i] = pform + + return prettyForm.__add__(*pforms) + + def _print_Mul(self, product): + from sympy.physics.units import Quantity + + # Check for unevaluated Mul. In this case we need to make sure the + # identities are visible, multiple Rational factors are not combined + # etc so we display in a straight-forward form that fully preserves all + # args and their order. + args = product.args + if args[0] is S.One or any(isinstance(arg, Number) for arg in args[1:]): + strargs = list(map(self._print, args)) + # XXX: This is a hack to work around the fact that + # prettyForm.__mul__ absorbs a leading -1 in the args. Probably it + # would be better to fix this in prettyForm.__mul__ instead. + negone = strargs[0] == '-1' + if negone: + strargs[0] = prettyForm('1', 0, 0) + obj = prettyForm.__mul__(*strargs) + if negone: + obj = prettyForm('-' + obj.s, obj.baseline, obj.binding) + return obj + + a = [] # items in the numerator + b = [] # items that are in the denominator (if any) + + if self.order not in ('old', 'none'): + args = product.as_ordered_factors() + else: + args = list(product.args) + + # If quantities are present append them at the back + args = sorted(args, key=lambda x: isinstance(x, Quantity) or + (isinstance(x, Pow) and isinstance(x.base, Quantity))) + + # Gather terms for numerator/denominator + for item in args: + if item.is_commutative and item.is_Pow and item.exp.is_Rational and item.exp.is_negative: + if item.exp != -1: + b.append(Pow(item.base, -item.exp, evaluate=False)) + else: + b.append(Pow(item.base, -item.exp)) + elif item.is_Rational and item is not S.Infinity: + if item.p != 1: + a.append( Rational(item.p) ) + if item.q != 1: + b.append( Rational(item.q) ) + else: + a.append(item) + + # Convert to pretty forms. Parentheses are added by `__mul__`. + a = [self._print(ai) for ai in a] + b = [self._print(bi) for bi in b] + + # Construct a pretty form + if len(b) == 0: + return prettyForm.__mul__(*a) + else: + if len(a) == 0: + a.append( self._print(S.One) ) + return prettyForm.__mul__(*a)/prettyForm.__mul__(*b) + + # A helper function for _print_Pow to print x**(1/n) + def _print_nth_root(self, base, root): + bpretty = self._print(base) + + # In very simple cases, use a single-char root sign + if (self._settings['use_unicode_sqrt_char'] and self._use_unicode + and root == 2 and bpretty.height() == 1 + and (bpretty.width() == 1 + or (base.is_Integer and base.is_nonnegative))): + return prettyForm(*bpretty.left(nth_root[2])) + + # Construct root sign, start with the \/ shape + _zZ = xobj('/', 1) + rootsign = xobj('\\', 1) + _zZ + # Constructing the number to put on root + rpretty = self._print(root) + # roots look bad if they are not a single line + if rpretty.height() != 1: + return self._print(base)**self._print(1/root) + # If power is half, no number should appear on top of root sign + exp = '' if root == 2 else str(rpretty).ljust(2) + if len(exp) > 2: + rootsign = ' '*(len(exp) - 2) + rootsign + # Stack the exponent + rootsign = stringPict(exp + '\n' + rootsign) + rootsign.baseline = 0 + # Diagonal: length is one less than height of base + linelength = bpretty.height() - 1 + diagonal = stringPict('\n'.join( + ' '*(linelength - i - 1) + _zZ + ' '*i + for i in range(linelength) + )) + # Put baseline just below lowest line: next to exp + diagonal.baseline = linelength - 1 + # Make the root symbol + rootsign = prettyForm(*rootsign.right(diagonal)) + # Det the baseline to match contents to fix the height + # but if the height of bpretty is one, the rootsign must be one higher + rootsign.baseline = max(1, bpretty.baseline) + #build result + s = prettyForm(hobj('_', 2 + bpretty.width())) + s = prettyForm(*bpretty.above(s)) + s = prettyForm(*s.left(rootsign)) + return s + + def _print_Pow(self, power): + from sympy.simplify.simplify import fraction + b, e = power.as_base_exp() + if power.is_commutative: + if e is S.NegativeOne: + return prettyForm("1")/self._print(b) + n, d = fraction(e) + if n is S.One and d.is_Atom and not e.is_Integer and (e.is_Rational or d.is_Symbol) \ + and self._settings['root_notation']: + return self._print_nth_root(b, d) + if e.is_Rational and e < 0: + return prettyForm("1")/self._print(Pow(b, -e, evaluate=False)) + + if b.is_Relational: + return prettyForm(*self._print(b).parens()).__pow__(self._print(e)) + + return self._print(b)**self._print(e) + + def _print_UnevaluatedExpr(self, expr): + return self._print(expr.args[0]) + + def __print_numer_denom(self, p, q): + if q == 1: + if p < 0: + return prettyForm(str(p), binding=prettyForm.NEG) + else: + return prettyForm(str(p)) + elif abs(p) >= 10 and abs(q) >= 10: + # If more than one digit in numer and denom, print larger fraction + if p < 0: + return prettyForm(str(p), binding=prettyForm.NEG)/prettyForm(str(q)) + # Old printing method: + #pform = prettyForm(str(-p))/prettyForm(str(q)) + #return prettyForm(binding=prettyForm.NEG, *pform.left('- ')) + else: + return prettyForm(str(p))/prettyForm(str(q)) + else: + return None + + def _print_Rational(self, expr): + result = self.__print_numer_denom(expr.p, expr.q) + + if result is not None: + return result + else: + return self.emptyPrinter(expr) + + def _print_Fraction(self, expr): + result = self.__print_numer_denom(expr.numerator, expr.denominator) + + if result is not None: + return result + else: + return self.emptyPrinter(expr) + + def _print_ProductSet(self, p): + if len(p.sets) >= 1 and not has_variety(p.sets): + return self._print(p.sets[0]) ** self._print(len(p.sets)) + else: + prod_char = pretty_atom('Multiplication') if self._use_unicode else 'x' + return self._print_seq(p.sets, None, None, ' %s ' % prod_char, + parenthesize=lambda set: set.is_Union or + set.is_Intersection or set.is_ProductSet) + + def _print_FiniteSet(self, s): + items = sorted(s.args, key=default_sort_key) + return self._print_seq(items, '{', '}', ', ' ) + + def _print_Range(self, s): + + if self._use_unicode: + dots = pretty_atom('Dots') + else: + dots = '...' + + if s.start.is_infinite and s.stop.is_infinite: + if s.step.is_positive: + printset = dots, -1, 0, 1, dots + else: + printset = dots, 1, 0, -1, dots + elif s.start.is_infinite: + printset = dots, s[-1] - s.step, s[-1] + elif s.stop.is_infinite: + it = iter(s) + printset = next(it), next(it), dots + elif len(s) > 4: + it = iter(s) + printset = next(it), next(it), dots, s[-1] + else: + printset = tuple(s) + + return self._print_seq(printset, '{', '}', ', ' ) + + def _print_Interval(self, i): + if i.start == i.end: + return self._print_seq(i.args[:1], '{', '}') + + else: + if i.left_open: + left = '(' + else: + left = '[' + + if i.right_open: + right = ')' + else: + right = ']' + + return self._print_seq(i.args[:2], left, right) + + def _print_AccumulationBounds(self, i): + left = '<' + right = '>' + + return self._print_seq(i.args[:2], left, right) + + def _print_Intersection(self, u): + + delimiter = ' %s ' % pretty_atom('Intersection', 'n') + + return self._print_seq(u.args, None, None, delimiter, + parenthesize=lambda set: set.is_ProductSet or + set.is_Union or set.is_Complement) + + def _print_Union(self, u): + + union_delimiter = ' %s ' % pretty_atom('Union', 'U') + + return self._print_seq(u.args, None, None, union_delimiter, + parenthesize=lambda set: set.is_ProductSet or + set.is_Intersection or set.is_Complement) + + def _print_SymmetricDifference(self, u): + if not self._use_unicode: + raise NotImplementedError("ASCII pretty printing of SymmetricDifference is not implemented") + + sym_delimeter = ' %s ' % pretty_atom('SymmetricDifference') + + return self._print_seq(u.args, None, None, sym_delimeter) + + def _print_Complement(self, u): + + delimiter = r' \ ' + + return self._print_seq(u.args, None, None, delimiter, + parenthesize=lambda set: set.is_ProductSet or set.is_Intersection + or set.is_Union) + + def _print_ImageSet(self, ts): + if self._use_unicode: + inn = pretty_atom("SmallElementOf") + else: + inn = 'in' + fun = ts.lamda + sets = ts.base_sets + signature = fun.signature + expr = self._print(fun.expr) + + # TODO: the stuff to the left of the | and the stuff to the right of + # the | should have independent baselines, that way something like + # ImageSet(Lambda(x, 1/x**2), S.Naturals) prints the "x in N" part + # centered on the right instead of aligned with the fraction bar on + # the left. The same also applies to ConditionSet and ComplexRegion + if len(signature) == 1: + S = self._print_seq((signature[0], inn, sets[0]), + delimiter=' ') + return self._hprint_vseparator(expr, S, + left='{', right='}', + ifascii_nougly=True, delimiter=' ') + else: + pargs = tuple(j for var, setv in zip(signature, sets) for j in + (var, ' ', inn, ' ', setv, ", ")) + S = self._print_seq(pargs[:-1], delimiter='') + return self._hprint_vseparator(expr, S, + left='{', right='}', + ifascii_nougly=True, delimiter=' ') + + def _print_ConditionSet(self, ts): + if self._use_unicode: + inn = pretty_atom('SmallElementOf') + # using _and because and is a keyword and it is bad practice to + # overwrite them + _and = pretty_atom('And') + else: + inn = 'in' + _and = 'and' + + variables = self._print_seq(Tuple(ts.sym)) + as_expr = getattr(ts.condition, 'as_expr', None) + if as_expr is not None: + cond = self._print(ts.condition.as_expr()) + else: + cond = self._print(ts.condition) + if self._use_unicode: + cond = self._print(cond) + cond = prettyForm(*cond.parens()) + + if ts.base_set is S.UniversalSet: + return self._hprint_vseparator(variables, cond, left="{", + right="}", ifascii_nougly=True, + delimiter=' ') + + base = self._print(ts.base_set) + C = self._print_seq((variables, inn, base, _and, cond), + delimiter=' ') + return self._hprint_vseparator(variables, C, left="{", right="}", + ifascii_nougly=True, delimiter=' ') + + def _print_ComplexRegion(self, ts): + if self._use_unicode: + inn = pretty_atom('SmallElementOf') + else: + inn = 'in' + variables = self._print_seq(ts.variables) + expr = self._print(ts.expr) + prodsets = self._print(ts.sets) + + C = self._print_seq((variables, inn, prodsets), + delimiter=' ') + return self._hprint_vseparator(expr, C, left="{", right="}", + ifascii_nougly=True, delimiter=' ') + + def _print_Contains(self, e): + var, set = e.args + if self._use_unicode: + el = f" {pretty_atom('ElementOf')} " + return prettyForm(*stringPict.next(self._print(var), + el, self._print(set)), binding=8) + else: + return prettyForm(sstr(e)) + + def _print_FourierSeries(self, s): + if s.an.formula is S.Zero and s.bn.formula is S.Zero: + return self._print(s.a0) + if self._use_unicode: + dots = pretty_atom('Dots') + else: + dots = '...' + return self._print_Add(s.truncate()) + self._print(dots) + + def _print_FormalPowerSeries(self, s): + return self._print_Add(s.infinite) + + def _print_SetExpr(self, se): + pretty_set = prettyForm(*self._print(se.set).parens()) + pretty_name = self._print(Symbol("SetExpr")) + return prettyForm(*pretty_name.right(pretty_set)) + + def _print_SeqFormula(self, s): + if self._use_unicode: + dots = pretty_atom('Dots') + else: + dots = '...' + + if len(s.start.free_symbols) > 0 or len(s.stop.free_symbols) > 0: + raise NotImplementedError("Pretty printing of sequences with symbolic bound not implemented") + + if s.start is S.NegativeInfinity: + stop = s.stop + printset = (dots, s.coeff(stop - 3), s.coeff(stop - 2), + s.coeff(stop - 1), s.coeff(stop)) + elif s.stop is S.Infinity or s.length > 4: + printset = s[:4] + printset.append(dots) + printset = tuple(printset) + else: + printset = tuple(s) + return self._print_list(printset) + + _print_SeqPer = _print_SeqFormula + _print_SeqAdd = _print_SeqFormula + _print_SeqMul = _print_SeqFormula + + def _print_seq(self, seq, left=None, right=None, delimiter=', ', + parenthesize=lambda x: False, ifascii_nougly=True): + + pforms = [] + for item in seq: + pform = self._print(item) + if parenthesize(item): + pform = prettyForm(*pform.parens()) + if pforms: + pforms.append(delimiter) + pforms.append(pform) + + if not pforms: + s = stringPict('') + else: + s = prettyForm(*stringPict.next(*pforms)) + + s = prettyForm(*s.parens(left, right, ifascii_nougly=ifascii_nougly)) + return s + + def join(self, delimiter, args): + pform = None + + for arg in args: + if pform is None: + pform = arg + else: + pform = prettyForm(*pform.right(delimiter)) + pform = prettyForm(*pform.right(arg)) + + if pform is None: + return prettyForm("") + else: + return pform + + def _print_list(self, l): + return self._print_seq(l, '[', ']') + + def _print_tuple(self, t): + if len(t) == 1: + ptuple = prettyForm(*stringPict.next(self._print(t[0]), ',')) + return prettyForm(*ptuple.parens('(', ')', ifascii_nougly=True)) + else: + return self._print_seq(t, '(', ')') + + def _print_Tuple(self, expr): + return self._print_tuple(expr) + + def _print_dict(self, d): + keys = sorted(d.keys(), key=default_sort_key) + items = [] + + for k in keys: + K = self._print(k) + V = self._print(d[k]) + s = prettyForm(*stringPict.next(K, ': ', V)) + + items.append(s) + + return self._print_seq(items, '{', '}') + + def _print_Dict(self, d): + return self._print_dict(d) + + def _print_set(self, s): + if not s: + return prettyForm('set()') + items = sorted(s, key=default_sort_key) + pretty = self._print_seq(items) + pretty = prettyForm(*pretty.parens('{', '}', ifascii_nougly=True)) + return pretty + + def _print_frozenset(self, s): + if not s: + return prettyForm('frozenset()') + items = sorted(s, key=default_sort_key) + pretty = self._print_seq(items) + pretty = prettyForm(*pretty.parens('{', '}', ifascii_nougly=True)) + pretty = prettyForm(*pretty.parens('(', ')', ifascii_nougly=True)) + pretty = prettyForm(*stringPict.next(type(s).__name__, pretty)) + return pretty + + def _print_UniversalSet(self, s): + if self._use_unicode: + return prettyForm(pretty_atom('Universe')) + else: + return prettyForm('UniversalSet') + + def _print_PolyRing(self, ring): + return prettyForm(sstr(ring)) + + def _print_FracField(self, field): + return prettyForm(sstr(field)) + + def _print_FreeGroupElement(self, elm): + return prettyForm(str(elm)) + + def _print_PolyElement(self, poly): + return prettyForm(sstr(poly)) + + def _print_FracElement(self, frac): + return prettyForm(sstr(frac)) + + def _print_AlgebraicNumber(self, expr): + if expr.is_aliased: + return self._print(expr.as_poly().as_expr()) + else: + return self._print(expr.as_expr()) + + def _print_ComplexRootOf(self, expr): + args = [self._print_Add(expr.expr, order='lex'), expr.index] + pform = prettyForm(*self._print_seq(args).parens()) + pform = prettyForm(*pform.left('CRootOf')) + return pform + + def _print_RootSum(self, expr): + args = [self._print_Add(expr.expr, order='lex')] + + if expr.fun is not S.IdentityFunction: + args.append(self._print(expr.fun)) + + pform = prettyForm(*self._print_seq(args).parens()) + pform = prettyForm(*pform.left('RootSum')) + + return pform + + def _print_FiniteField(self, expr): + if self._use_unicode: + form = f"{pretty_atom('Integers')}_%d" + else: + form = 'GF(%d)' + + return prettyForm(pretty_symbol(form % expr.mod)) + + def _print_IntegerRing(self, expr): + if self._use_unicode: + return prettyForm(pretty_atom('Integers')) + else: + return prettyForm('ZZ') + + def _print_RationalField(self, expr): + if self._use_unicode: + return prettyForm(pretty_atom('Rationals')) + else: + return prettyForm('QQ') + + def _print_RealField(self, domain): + if self._use_unicode: + prefix = pretty_atom("Reals") + else: + prefix = 'RR' + + if domain.has_default_precision: + return prettyForm(prefix) + else: + return self._print(pretty_symbol(prefix + "_" + str(domain.precision))) + + def _print_ComplexField(self, domain): + if self._use_unicode: + prefix = pretty_atom('Complexes') + else: + prefix = 'CC' + + if domain.has_default_precision: + return prettyForm(prefix) + else: + return self._print(pretty_symbol(prefix + "_" + str(domain.precision))) + + def _print_PolynomialRing(self, expr): + args = list(expr.symbols) + + if not expr.order.is_default: + order = prettyForm(*prettyForm("order=").right(self._print(expr.order))) + args.append(order) + + pform = self._print_seq(args, '[', ']') + pform = prettyForm(*pform.left(self._print(expr.domain))) + + return pform + + def _print_FractionField(self, expr): + args = list(expr.symbols) + + if not expr.order.is_default: + order = prettyForm(*prettyForm("order=").right(self._print(expr.order))) + args.append(order) + + pform = self._print_seq(args, '(', ')') + pform = prettyForm(*pform.left(self._print(expr.domain))) + + return pform + + def _print_PolynomialRingBase(self, expr): + g = expr.symbols + if str(expr.order) != str(expr.default_order): + g = g + ("order=" + str(expr.order),) + pform = self._print_seq(g, '[', ']') + pform = prettyForm(*pform.left(self._print(expr.domain))) + + return pform + + def _print_GroebnerBasis(self, basis): + exprs = [ self._print_Add(arg, order=basis.order) + for arg in basis.exprs ] + exprs = prettyForm(*self.join(", ", exprs).parens(left="[", right="]")) + + gens = [ self._print(gen) for gen in basis.gens ] + + domain = prettyForm( + *prettyForm("domain=").right(self._print(basis.domain))) + order = prettyForm( + *prettyForm("order=").right(self._print(basis.order))) + + pform = self.join(", ", [exprs] + gens + [domain, order]) + + pform = prettyForm(*pform.parens()) + pform = prettyForm(*pform.left(basis.__class__.__name__)) + + return pform + + def _print_Subs(self, e): + pform = self._print(e.expr) + pform = prettyForm(*pform.parens()) + + h = pform.height() if pform.height() > 1 else 2 + rvert = stringPict(vobj('|', h), baseline=pform.baseline) + pform = prettyForm(*pform.right(rvert)) + + b = pform.baseline + pform.baseline = pform.height() - 1 + pform = prettyForm(*pform.right(self._print_seq([ + self._print_seq((self._print(v[0]), xsym('=='), self._print(v[1])), + delimiter='') for v in zip(e.variables, e.point) ]))) + + pform.baseline = b + return pform + + def _print_number_function(self, e, name): + # Print name_arg[0] for one argument or name_arg[0](arg[1]) + # for more than one argument + pform = prettyForm(name) + arg = self._print(e.args[0]) + pform_arg = prettyForm(" "*arg.width()) + pform_arg = prettyForm(*pform_arg.below(arg)) + pform = prettyForm(*pform.right(pform_arg)) + if len(e.args) == 1: + return pform + m, x = e.args + # TODO: copy-pasted from _print_Function: can we do better? + prettyFunc = pform + prettyArgs = prettyForm(*self._print_seq([x]).parens()) + pform = prettyForm( + binding=prettyForm.FUNC, *stringPict.next(prettyFunc, prettyArgs)) + pform.prettyFunc = prettyFunc + pform.prettyArgs = prettyArgs + return pform + + def _print_euler(self, e): + return self._print_number_function(e, "E") + + def _print_catalan(self, e): + return self._print_number_function(e, "C") + + def _print_bernoulli(self, e): + return self._print_number_function(e, "B") + + _print_bell = _print_bernoulli + + def _print_lucas(self, e): + return self._print_number_function(e, "L") + + def _print_fibonacci(self, e): + return self._print_number_function(e, "F") + + def _print_tribonacci(self, e): + return self._print_number_function(e, "T") + + def _print_stieltjes(self, e): + if self._use_unicode: + return self._print_number_function(e, greek_unicode['gamma']) + else: + return self._print_number_function(e, "stieltjes") + + def _print_KroneckerDelta(self, e): + pform = self._print(e.args[0]) + pform = prettyForm(*pform.right(prettyForm(','))) + pform = prettyForm(*pform.right(self._print(e.args[1]))) + if self._use_unicode: + a = stringPict(pretty_symbol('delta')) + else: + a = stringPict('d') + b = pform + top = stringPict(*b.left(' '*a.width())) + bot = stringPict(*a.right(' '*b.width())) + return prettyForm(binding=prettyForm.POW, *bot.below(top)) + + def _print_RandomDomain(self, d): + if hasattr(d, 'as_boolean'): + pform = self._print('Domain: ') + pform = prettyForm(*pform.right(self._print(d.as_boolean()))) + return pform + elif hasattr(d, 'set'): + pform = self._print('Domain: ') + pform = prettyForm(*pform.right(self._print(d.symbols))) + pform = prettyForm(*pform.right(self._print(' in '))) + pform = prettyForm(*pform.right(self._print(d.set))) + return pform + elif hasattr(d, 'symbols'): + pform = self._print('Domain on ') + pform = prettyForm(*pform.right(self._print(d.symbols))) + return pform + else: + return self._print(None) + + def _print_DMP(self, p): + try: + if p.ring is not None: + # TODO incorporate order + return self._print(p.ring.to_sympy(p)) + except SympifyError: + pass + return self._print(repr(p)) + + def _print_DMF(self, p): + return self._print_DMP(p) + + def _print_Object(self, object): + return self._print(pretty_symbol(object.name)) + + def _print_Morphism(self, morphism): + arrow = xsym("-->") + + domain = self._print(morphism.domain) + codomain = self._print(morphism.codomain) + tail = domain.right(arrow, codomain)[0] + + return prettyForm(tail) + + def _print_NamedMorphism(self, morphism): + pretty_name = self._print(pretty_symbol(morphism.name)) + pretty_morphism = self._print_Morphism(morphism) + return prettyForm(pretty_name.right(":", pretty_morphism)[0]) + + def _print_IdentityMorphism(self, morphism): + from sympy.categories import NamedMorphism + return self._print_NamedMorphism( + NamedMorphism(morphism.domain, morphism.codomain, "id")) + + def _print_CompositeMorphism(self, morphism): + + circle = xsym(".") + + # All components of the morphism have names and it is thus + # possible to build the name of the composite. + component_names_list = [pretty_symbol(component.name) for + component in morphism.components] + component_names_list.reverse() + component_names = circle.join(component_names_list) + ":" + + pretty_name = self._print(component_names) + pretty_morphism = self._print_Morphism(morphism) + return prettyForm(pretty_name.right(pretty_morphism)[0]) + + def _print_Category(self, category): + return self._print(pretty_symbol(category.name)) + + def _print_Diagram(self, diagram): + if not diagram.premises: + # This is an empty diagram. + return self._print(S.EmptySet) + + pretty_result = self._print(diagram.premises) + if diagram.conclusions: + results_arrow = " %s " % xsym("==>") + + pretty_conclusions = self._print(diagram.conclusions)[0] + pretty_result = pretty_result.right( + results_arrow, pretty_conclusions) + + return prettyForm(pretty_result[0]) + + def _print_DiagramGrid(self, grid): + from sympy.matrices import Matrix + matrix = Matrix([[grid[i, j] if grid[i, j] else Symbol(" ") + for j in range(grid.width)] + for i in range(grid.height)]) + return self._print_matrix_contents(matrix) + + def _print_FreeModuleElement(self, m): + # Print as row vector for convenience, for now. + return self._print_seq(m, '[', ']') + + def _print_SubModule(self, M): + gens = [[M.ring.to_sympy(g) for g in gen] for gen in M.gens] + return self._print_seq(gens, '<', '>') + + def _print_FreeModule(self, M): + return self._print(M.ring)**self._print(M.rank) + + def _print_ModuleImplementedIdeal(self, M): + sym = M.ring.to_sympy + return self._print_seq([sym(x) for [x] in M._module.gens], '<', '>') + + def _print_QuotientRing(self, R): + return self._print(R.ring) / self._print(R.base_ideal) + + def _print_QuotientRingElement(self, R): + return self._print(R.ring.to_sympy(R)) + self._print(R.ring.base_ideal) + + def _print_QuotientModuleElement(self, m): + return self._print(m.data) + self._print(m.module.killed_module) + + def _print_QuotientModule(self, M): + return self._print(M.base) / self._print(M.killed_module) + + def _print_MatrixHomomorphism(self, h): + matrix = self._print(h._sympy_matrix()) + matrix.baseline = matrix.height() // 2 + pform = prettyForm(*matrix.right(' : ', self._print(h.domain), + ' %s> ' % hobj('-', 2), self._print(h.codomain))) + return pform + + def _print_Manifold(self, manifold): + return self._print(manifold.name) + + def _print_Patch(self, patch): + return self._print(patch.name) + + def _print_CoordSystem(self, coords): + return self._print(coords.name) + + def _print_BaseScalarField(self, field): + string = field._coord_sys.symbols[field._index].name + return self._print(pretty_symbol(string)) + + def _print_BaseVectorField(self, field): + s = U('PARTIAL DIFFERENTIAL') + '_' + field._coord_sys.symbols[field._index].name + return self._print(pretty_symbol(s)) + + def _print_Differential(self, diff): + if self._use_unicode: + d = pretty_atom('Differential') + else: + d = 'd' + field = diff._form_field + if hasattr(field, '_coord_sys'): + string = field._coord_sys.symbols[field._index].name + return self._print(d + ' ' + pretty_symbol(string)) + else: + pform = self._print(field) + pform = prettyForm(*pform.parens()) + return prettyForm(*pform.left(d)) + + def _print_Tr(self, p): + #TODO: Handle indices + pform = self._print(p.args[0]) + pform = prettyForm(*pform.left('%s(' % (p.__class__.__name__))) + pform = prettyForm(*pform.right(')')) + return pform + + def _print_primenu(self, e): + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens()) + if self._use_unicode: + pform = prettyForm(*pform.left(greek_unicode['nu'])) + else: + pform = prettyForm(*pform.left('nu')) + return pform + + def _print_primeomega(self, e): + pform = self._print(e.args[0]) + pform = prettyForm(*pform.parens()) + if self._use_unicode: + pform = prettyForm(*pform.left(greek_unicode['Omega'])) + else: + pform = prettyForm(*pform.left('Omega')) + return pform + + def _print_Quantity(self, e): + if e.name.name == 'degree': + if self._use_unicode: + pform = self._print(pretty_atom('Degree')) + else: + pform = self._print(chr(176)) + return pform + else: + return self.emptyPrinter(e) + + def _print_AssignmentBase(self, e): + + op = prettyForm(' ' + xsym(e.op) + ' ') + + l = self._print(e.lhs) + r = self._print(e.rhs) + pform = prettyForm(*stringPict.next(l, op, r)) + return pform + + def _print_Str(self, s): + return self._print(s.name) + + +@print_function(PrettyPrinter) +def pretty(expr, **settings): + """Returns a string containing the prettified form of expr. + + For information on keyword arguments see pretty_print function. + + """ + pp = PrettyPrinter(settings) + + # XXX: this is an ugly hack, but at least it works + use_unicode = pp._settings['use_unicode'] + uflag = pretty_use_unicode(use_unicode) + + try: + return pp.doprint(expr) + finally: + pretty_use_unicode(uflag) + + +def pretty_print(expr, **kwargs): + """Prints expr in pretty form. + + pprint is just a shortcut for this function. + + Parameters + ========== + + expr : expression + The expression to print. + + wrap_line : bool, optional (default=True) + Line wrapping enabled/disabled. + + num_columns : int or None, optional (default=None) + Number of columns before line breaking (default to None which reads + the terminal width), useful when using SymPy without terminal. + + use_unicode : bool or None, optional (default=None) + Use unicode characters, such as the Greek letter pi instead of + the string pi. + + full_prec : bool or string, optional (default="auto") + Use full precision. + + order : bool or string, optional (default=None) + Set to 'none' for long expressions if slow; default is None. + + use_unicode_sqrt_char : bool, optional (default=True) + Use compact single-character square root symbol (when unambiguous). + + root_notation : bool, optional (default=True) + Set to 'False' for printing exponents of the form 1/n in fractional form. + By default exponent is printed in root form. + + mat_symbol_style : string, optional (default="plain") + Set to "bold" for printing MatrixSymbols using a bold mathematical symbol face. + By default the standard face is used. + + imaginary_unit : string, optional (default="i") + Letter to use for imaginary unit when use_unicode is True. + Can be "i" (default) or "j". + """ + print(pretty(expr, **kwargs)) + +pprint = pretty_print + + +def pager_print(expr, **settings): + """Prints expr using the pager, in pretty form. + + This invokes a pager command using pydoc. Lines are not wrapped + automatically. This routine is meant to be used with a pager that allows + sideways scrolling, like ``less -S``. + + Parameters are the same as for ``pretty_print``. If you wish to wrap lines, + pass ``num_columns=None`` to auto-detect the width of the terminal. + + """ + from pydoc import pager + from locale import getpreferredencoding + if 'num_columns' not in settings: + settings['num_columns'] = 500000 # disable line wrap + pager(pretty(expr, **settings).encode(getpreferredencoding())) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/pretty_symbology.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/pretty_symbology.py new file mode 100644 index 0000000000000000000000000000000000000000..bdb6ec556c6ed7b15dfcddcfc3da189102d5395b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/pretty_symbology.py @@ -0,0 +1,731 @@ +"""Symbolic primitives + unicode/ASCII abstraction for pretty.py""" + +import sys +import warnings +from string import ascii_lowercase, ascii_uppercase +import unicodedata + +unicode_warnings = '' + +def U(name): + """ + Get a unicode character by name or, None if not found. + + This exists because older versions of Python use older unicode databases. + """ + try: + return unicodedata.lookup(name) + except KeyError: + global unicode_warnings + unicode_warnings += 'No \'%s\' in unicodedata\n' % name + return None + +from sympy.printing.conventions import split_super_sub +from sympy.core.alphabets import greeks +from sympy.utilities.exceptions import sympy_deprecation_warning + +# prefix conventions when constructing tables +# L - LATIN i +# G - GREEK beta +# D - DIGIT 0 +# S - SYMBOL + + + +__all__ = ['greek_unicode', 'sub', 'sup', 'xsym', 'vobj', 'hobj', 'pretty_symbol', + 'annotated', 'center_pad', 'center'] + + +_use_unicode = False + + +def pretty_use_unicode(flag=None): + """Set whether pretty-printer should use unicode by default""" + global _use_unicode, unicode_warnings + if flag is None: + return _use_unicode + + if flag and unicode_warnings: + # print warnings (if any) on first unicode usage + warnings.warn(unicode_warnings) + unicode_warnings = '' + + use_unicode_prev = _use_unicode + _use_unicode = flag + return use_unicode_prev + + +def pretty_try_use_unicode(): + """See if unicode output is available and leverage it if possible""" + + encoding = getattr(sys.stdout, 'encoding', None) + + # this happens when e.g. stdout is redirected through a pipe, or is + # e.g. a cStringIO.StringO + if encoding is None: + return # sys.stdout has no encoding + + symbols = [] + + # see if we can represent greek alphabet + symbols += greek_unicode.values() + + # and atoms + symbols += atoms_table.values() + + for s in symbols: + if s is None: + return # common symbols not present! + + try: + s.encode(encoding) + except UnicodeEncodeError: + return + + # all the characters were present and encodable + pretty_use_unicode(True) + + +def xstr(*args): + sympy_deprecation_warning( + """ + The sympy.printing.pretty.pretty_symbology.xstr() function is + deprecated. Use str() instead. + """, + deprecated_since_version="1.7", + active_deprecations_target="deprecated-pretty-printing-functions" + ) + return str(*args) + +# GREEK +g = lambda l: U('GREEK SMALL LETTER %s' % l.upper()) +G = lambda l: U('GREEK CAPITAL LETTER %s' % l.upper()) + +greek_letters = list(greeks) # make a copy +# deal with Unicode's funny spelling of lambda +greek_letters[greek_letters.index('lambda')] = 'lamda' + +# {} greek letter -> (g,G) +greek_unicode = {L: g(L) for L in greek_letters} +greek_unicode.update((L[0].upper() + L[1:], G(L)) for L in greek_letters) + +# aliases +greek_unicode['lambda'] = greek_unicode['lamda'] +greek_unicode['Lambda'] = greek_unicode['Lamda'] +greek_unicode['varsigma'] = '\N{GREEK SMALL LETTER FINAL SIGMA}' + +# BOLD +b = lambda l: U('MATHEMATICAL BOLD SMALL %s' % l.upper()) +B = lambda l: U('MATHEMATICAL BOLD CAPITAL %s' % l.upper()) + +bold_unicode = {l: b(l) for l in ascii_lowercase} +bold_unicode.update((L, B(L)) for L in ascii_uppercase) + +# GREEK BOLD +gb = lambda l: U('MATHEMATICAL BOLD SMALL %s' % l.upper()) +GB = lambda l: U('MATHEMATICAL BOLD CAPITAL %s' % l.upper()) + +greek_bold_letters = list(greeks) # make a copy, not strictly required here +# deal with Unicode's funny spelling of lambda +greek_bold_letters[greek_bold_letters.index('lambda')] = 'lamda' + +# {} greek letter -> (g,G) +greek_bold_unicode = {L: g(L) for L in greek_bold_letters} +greek_bold_unicode.update((L[0].upper() + L[1:], G(L)) for L in greek_bold_letters) +greek_bold_unicode['lambda'] = greek_unicode['lamda'] +greek_bold_unicode['Lambda'] = greek_unicode['Lamda'] +greek_bold_unicode['varsigma'] = '\N{MATHEMATICAL BOLD SMALL FINAL SIGMA}' + +digit_2txt = { + '0': 'ZERO', + '1': 'ONE', + '2': 'TWO', + '3': 'THREE', + '4': 'FOUR', + '5': 'FIVE', + '6': 'SIX', + '7': 'SEVEN', + '8': 'EIGHT', + '9': 'NINE', +} + +symb_2txt = { + '+': 'PLUS SIGN', + '-': 'MINUS', + '=': 'EQUALS SIGN', + '(': 'LEFT PARENTHESIS', + ')': 'RIGHT PARENTHESIS', + '[': 'LEFT SQUARE BRACKET', + ']': 'RIGHT SQUARE BRACKET', + '{': 'LEFT CURLY BRACKET', + '}': 'RIGHT CURLY BRACKET', + + # non-std + '{}': 'CURLY BRACKET', + 'sum': 'SUMMATION', + 'int': 'INTEGRAL', +} + +# SUBSCRIPT & SUPERSCRIPT +LSUB = lambda letter: U('LATIN SUBSCRIPT SMALL LETTER %s' % letter.upper()) +GSUB = lambda letter: U('GREEK SUBSCRIPT SMALL LETTER %s' % letter.upper()) +DSUB = lambda digit: U('SUBSCRIPT %s' % digit_2txt[digit]) +SSUB = lambda symb: U('SUBSCRIPT %s' % symb_2txt[symb]) + +LSUP = lambda letter: U('SUPERSCRIPT LATIN SMALL LETTER %s' % letter.upper()) +DSUP = lambda digit: U('SUPERSCRIPT %s' % digit_2txt[digit]) +SSUP = lambda symb: U('SUPERSCRIPT %s' % symb_2txt[symb]) + +sub = {} # symb -> subscript symbol +sup = {} # symb -> superscript symbol + +# latin subscripts +for l in 'aeioruvxhklmnpst': + sub[l] = LSUB(l) + +for l in 'in': + sup[l] = LSUP(l) + +for gl in ['beta', 'gamma', 'rho', 'phi', 'chi']: + sub[gl] = GSUB(gl) + +for d in [str(i) for i in range(10)]: + sub[d] = DSUB(d) + sup[d] = DSUP(d) + +for s in '+-=()': + sub[s] = SSUB(s) + sup[s] = SSUP(s) + +# Variable modifiers +# TODO: Make brackets adjust to height of contents +modifier_dict = { + # Accents + 'mathring': lambda s: center_accent(s, '\N{COMBINING RING ABOVE}'), + 'ddddot': lambda s: center_accent(s, '\N{COMBINING FOUR DOTS ABOVE}'), + 'dddot': lambda s: center_accent(s, '\N{COMBINING THREE DOTS ABOVE}'), + 'ddot': lambda s: center_accent(s, '\N{COMBINING DIAERESIS}'), + 'dot': lambda s: center_accent(s, '\N{COMBINING DOT ABOVE}'), + 'check': lambda s: center_accent(s, '\N{COMBINING CARON}'), + 'breve': lambda s: center_accent(s, '\N{COMBINING BREVE}'), + 'acute': lambda s: center_accent(s, '\N{COMBINING ACUTE ACCENT}'), + 'grave': lambda s: center_accent(s, '\N{COMBINING GRAVE ACCENT}'), + 'tilde': lambda s: center_accent(s, '\N{COMBINING TILDE}'), + 'hat': lambda s: center_accent(s, '\N{COMBINING CIRCUMFLEX ACCENT}'), + 'bar': lambda s: center_accent(s, '\N{COMBINING OVERLINE}'), + 'vec': lambda s: center_accent(s, '\N{COMBINING RIGHT ARROW ABOVE}'), + 'prime': lambda s: s+'\N{PRIME}', + 'prm': lambda s: s+'\N{PRIME}', + # # Faces -- these are here for some compatibility with latex printing + # 'bold': lambda s: s, + # 'bm': lambda s: s, + # 'cal': lambda s: s, + # 'scr': lambda s: s, + # 'frak': lambda s: s, + # Brackets + 'norm': lambda s: '\N{DOUBLE VERTICAL LINE}'+s+'\N{DOUBLE VERTICAL LINE}', + 'avg': lambda s: '\N{MATHEMATICAL LEFT ANGLE BRACKET}'+s+'\N{MATHEMATICAL RIGHT ANGLE BRACKET}', + 'abs': lambda s: '\N{VERTICAL LINE}'+s+'\N{VERTICAL LINE}', + 'mag': lambda s: '\N{VERTICAL LINE}'+s+'\N{VERTICAL LINE}', +} + +# VERTICAL OBJECTS +HUP = lambda symb: U('%s UPPER HOOK' % symb_2txt[symb]) +CUP = lambda symb: U('%s UPPER CORNER' % symb_2txt[symb]) +MID = lambda symb: U('%s MIDDLE PIECE' % symb_2txt[symb]) +EXT = lambda symb: U('%s EXTENSION' % symb_2txt[symb]) +HLO = lambda symb: U('%s LOWER HOOK' % symb_2txt[symb]) +CLO = lambda symb: U('%s LOWER CORNER' % symb_2txt[symb]) +TOP = lambda symb: U('%s TOP' % symb_2txt[symb]) +BOT = lambda symb: U('%s BOTTOM' % symb_2txt[symb]) + +# {} '(' -> (extension, start, end, middle) 1-character +_xobj_unicode = { + + # vertical symbols + # (( ext, top, bot, mid ), c1) + '(': (( EXT('('), HUP('('), HLO('(') ), '('), + ')': (( EXT(')'), HUP(')'), HLO(')') ), ')'), + '[': (( EXT('['), CUP('['), CLO('[') ), '['), + ']': (( EXT(']'), CUP(']'), CLO(']') ), ']'), + '{': (( EXT('{}'), HUP('{'), HLO('{'), MID('{') ), '{'), + '}': (( EXT('{}'), HUP('}'), HLO('}'), MID('}') ), '}'), + '|': U('BOX DRAWINGS LIGHT VERTICAL'), + 'Tee': U('BOX DRAWINGS LIGHT UP AND HORIZONTAL'), + 'UpTack': U('BOX DRAWINGS LIGHT DOWN AND HORIZONTAL'), + 'corner_up_centre' + '(_ext': U('LEFT PARENTHESIS EXTENSION'), + ')_ext': U('RIGHT PARENTHESIS EXTENSION'), + '(_lower_hook': U('LEFT PARENTHESIS LOWER HOOK'), + ')_lower_hook': U('RIGHT PARENTHESIS LOWER HOOK'), + '(_upper_hook': U('LEFT PARENTHESIS UPPER HOOK'), + ')_upper_hook': U('RIGHT PARENTHESIS UPPER HOOK'), + '<': ((U('BOX DRAWINGS LIGHT VERTICAL'), + U('BOX DRAWINGS LIGHT DIAGONAL UPPER RIGHT TO LOWER LEFT'), + U('BOX DRAWINGS LIGHT DIAGONAL UPPER LEFT TO LOWER RIGHT')), '<'), + + '>': ((U('BOX DRAWINGS LIGHT VERTICAL'), + U('BOX DRAWINGS LIGHT DIAGONAL UPPER LEFT TO LOWER RIGHT'), + U('BOX DRAWINGS LIGHT DIAGONAL UPPER RIGHT TO LOWER LEFT')), '>'), + + 'lfloor': (( EXT('['), EXT('['), CLO('[') ), U('LEFT FLOOR')), + 'rfloor': (( EXT(']'), EXT(']'), CLO(']') ), U('RIGHT FLOOR')), + 'lceil': (( EXT('['), CUP('['), EXT('[') ), U('LEFT CEILING')), + 'rceil': (( EXT(']'), CUP(']'), EXT(']') ), U('RIGHT CEILING')), + + 'int': (( EXT('int'), U('TOP HALF INTEGRAL'), U('BOTTOM HALF INTEGRAL') ), U('INTEGRAL')), + 'sum': (( U('BOX DRAWINGS LIGHT DIAGONAL UPPER LEFT TO LOWER RIGHT'), '_', U('OVERLINE'), U('BOX DRAWINGS LIGHT DIAGONAL UPPER RIGHT TO LOWER LEFT')), U('N-ARY SUMMATION')), + + # horizontal objects + #'-': '-', + '-': U('BOX DRAWINGS LIGHT HORIZONTAL'), + '_': U('LOW LINE'), + # We used to use this, but LOW LINE looks better for roots, as it's a + # little lower (i.e., it lines up with the / perfectly. But perhaps this + # one would still be wanted for some cases? + # '_': U('HORIZONTAL SCAN LINE-9'), + + # diagonal objects '\' & '/' ? + '/': U('BOX DRAWINGS LIGHT DIAGONAL UPPER RIGHT TO LOWER LEFT'), + '\\': U('BOX DRAWINGS LIGHT DIAGONAL UPPER LEFT TO LOWER RIGHT'), +} + +_xobj_ascii = { + # vertical symbols + # (( ext, top, bot, mid ), c1) + '(': (( '|', '/', '\\' ), '('), + ')': (( '|', '\\', '/' ), ')'), + +# XXX this looks ugly +# '[': (( '|', '-', '-' ), '['), +# ']': (( '|', '-', '-' ), ']'), +# XXX not so ugly :( + '[': (( '[', '[', '[' ), '['), + ']': (( ']', ']', ']' ), ']'), + + '{': (( '|', '/', '\\', '<' ), '{'), + '}': (( '|', '\\', '/', '>' ), '}'), + '|': '|', + + '<': (( '|', '/', '\\' ), '<'), + '>': (( '|', '\\', '/' ), '>'), + + 'int': ( ' | ', ' /', '/ ' ), + + # horizontal objects + '-': '-', + '_': '_', + + # diagonal objects '\' & '/' ? + '/': '/', + '\\': '\\', +} + + +def xobj(symb, length): + """Construct spatial object of given length. + + return: [] of equal-length strings + """ + + if length <= 0: + raise ValueError("Length should be greater than 0") + + # TODO robustify when no unicodedat available + if _use_unicode: + _xobj = _xobj_unicode + else: + _xobj = _xobj_ascii + + vinfo = _xobj[symb] + + c1 = top = bot = mid = None + + if not isinstance(vinfo, tuple): # 1 entry + ext = vinfo + else: + if isinstance(vinfo[0], tuple): # (vlong), c1 + vlong = vinfo[0] + c1 = vinfo[1] + else: # (vlong), c1 + vlong = vinfo + + ext = vlong[0] + + try: + top = vlong[1] + bot = vlong[2] + mid = vlong[3] + except IndexError: + pass + + if c1 is None: + c1 = ext + if top is None: + top = ext + if bot is None: + bot = ext + if mid is not None: + if (length % 2) == 0: + # even height, but we have to print it somehow anyway... + # XXX is it ok? + length += 1 + + else: + mid = ext + + if length == 1: + return c1 + + res = [] + next = (length - 2)//2 + nmid = (length - 2) - next*2 + + res += [top] + res += [ext]*next + res += [mid]*nmid + res += [ext]*next + res += [bot] + + return res + + +def vobj(symb, height): + """Construct vertical object of a given height + + see: xobj + """ + return '\n'.join( xobj(symb, height) ) + + +def hobj(symb, width): + """Construct horizontal object of a given width + + see: xobj + """ + return ''.join( xobj(symb, width) ) + +# RADICAL +# n -> symbol +root = { + 2: U('SQUARE ROOT'), # U('RADICAL SYMBOL BOTTOM') + 3: U('CUBE ROOT'), + 4: U('FOURTH ROOT'), +} + + +# RATIONAL +VF = lambda txt: U('VULGAR FRACTION %s' % txt) + +# (p,q) -> symbol +frac = { + (1, 2): VF('ONE HALF'), + (1, 3): VF('ONE THIRD'), + (2, 3): VF('TWO THIRDS'), + (1, 4): VF('ONE QUARTER'), + (3, 4): VF('THREE QUARTERS'), + (1, 5): VF('ONE FIFTH'), + (2, 5): VF('TWO FIFTHS'), + (3, 5): VF('THREE FIFTHS'), + (4, 5): VF('FOUR FIFTHS'), + (1, 6): VF('ONE SIXTH'), + (5, 6): VF('FIVE SIXTHS'), + (1, 8): VF('ONE EIGHTH'), + (3, 8): VF('THREE EIGHTHS'), + (5, 8): VF('FIVE EIGHTHS'), + (7, 8): VF('SEVEN EIGHTHS'), +} + + +# atom symbols +_xsym = { + '==': ('=', '='), + '<': ('<', '<'), + '>': ('>', '>'), + '<=': ('<=', U('LESS-THAN OR EQUAL TO')), + '>=': ('>=', U('GREATER-THAN OR EQUAL TO')), + '!=': ('!=', U('NOT EQUAL TO')), + ':=': (':=', ':='), + '+=': ('+=', '+='), + '-=': ('-=', '-='), + '*=': ('*=', '*='), + '/=': ('/=', '/='), + '%=': ('%=', '%='), + '*': ('*', U('DOT OPERATOR')), + '-->': ('-->', U('EM DASH') + U('EM DASH') + + U('BLACK RIGHT-POINTING TRIANGLE') if U('EM DASH') + and U('BLACK RIGHT-POINTING TRIANGLE') else None), + '==>': ('==>', U('BOX DRAWINGS DOUBLE HORIZONTAL') + + U('BOX DRAWINGS DOUBLE HORIZONTAL') + + U('BLACK RIGHT-POINTING TRIANGLE') if + U('BOX DRAWINGS DOUBLE HORIZONTAL') and + U('BOX DRAWINGS DOUBLE HORIZONTAL') and + U('BLACK RIGHT-POINTING TRIANGLE') else None), + '.': ('*', U('RING OPERATOR')), +} + + +def xsym(sym): + """get symbology for a 'character'""" + op = _xsym[sym] + + if _use_unicode: + return op[1] + else: + return op[0] + + +# SYMBOLS + +atoms_table = { + # class how-to-display + 'Exp1': U('SCRIPT SMALL E'), + 'Pi': U('GREEK SMALL LETTER PI'), + 'Infinity': U('INFINITY'), + 'NegativeInfinity': U('INFINITY') and ('-' + U('INFINITY')), # XXX what to do here + #'ImaginaryUnit': U('GREEK SMALL LETTER IOTA'), + #'ImaginaryUnit': U('MATHEMATICAL ITALIC SMALL I'), + 'ImaginaryUnit': U('DOUBLE-STRUCK ITALIC SMALL I'), + 'EmptySet': U('EMPTY SET'), + 'Naturals': U('DOUBLE-STRUCK CAPITAL N'), + 'Naturals0': (U('DOUBLE-STRUCK CAPITAL N') and + (U('DOUBLE-STRUCK CAPITAL N') + + U('SUBSCRIPT ZERO'))), + 'Integers': U('DOUBLE-STRUCK CAPITAL Z'), + 'Rationals': U('DOUBLE-STRUCK CAPITAL Q'), + 'Reals': U('DOUBLE-STRUCK CAPITAL R'), + 'Complexes': U('DOUBLE-STRUCK CAPITAL C'), + 'Universe': U('MATHEMATICAL DOUBLE-STRUCK CAPITAL U'), + 'IdentityMatrix': U('MATHEMATICAL DOUBLE-STRUCK CAPITAL I'), + 'ZeroMatrix': U('MATHEMATICAL DOUBLE-STRUCK DIGIT ZERO'), + 'OneMatrix': U('MATHEMATICAL DOUBLE-STRUCK DIGIT ONE'), + 'Differential': U('DOUBLE-STRUCK ITALIC SMALL D'), + 'Union': U('UNION'), + 'ElementOf': U('ELEMENT OF'), + 'SmallElementOf': U('SMALL ELEMENT OF'), + 'SymmetricDifference': U('INCREMENT'), + 'Intersection': U('INTERSECTION'), + 'Ring': U('RING OPERATOR'), + 'Multiplication': U('MULTIPLICATION SIGN'), + 'TensorProduct': U('N-ARY CIRCLED TIMES OPERATOR'), + 'Dots': U('HORIZONTAL ELLIPSIS'), + 'Modifier Letter Low Ring':U('Modifier Letter Low Ring'), + 'EmptySequence': 'EmptySequence', + 'SuperscriptPlus': U('SUPERSCRIPT PLUS SIGN'), + 'SuperscriptMinus': U('SUPERSCRIPT MINUS'), + 'Dagger': U('DAGGER'), + 'Degree': U('DEGREE SIGN'), + #Logic Symbols + 'And': U('LOGICAL AND'), + 'Or': U('LOGICAL OR'), + 'Not': U('NOT SIGN'), + 'Nor': U('NOR'), + 'Nand': U('NAND'), + 'Xor': U('XOR'), + 'Equiv': U('LEFT RIGHT DOUBLE ARROW'), + 'NotEquiv': U('LEFT RIGHT DOUBLE ARROW WITH STROKE'), + 'Implies': U('LEFT RIGHT DOUBLE ARROW'), + 'NotImplies': U('LEFT RIGHT DOUBLE ARROW WITH STROKE'), + 'Arrow': U('RIGHTWARDS ARROW'), + 'ArrowFromBar': U('RIGHTWARDS ARROW FROM BAR'), + 'NotArrow': U('RIGHTWARDS ARROW WITH STROKE'), + 'Tautology': U('BOX DRAWINGS LIGHT UP AND HORIZONTAL'), + 'Contradiction': U('BOX DRAWINGS LIGHT DOWN AND HORIZONTAL') +} + + +def pretty_atom(atom_name, default=None, printer=None): + """return pretty representation of an atom""" + if _use_unicode: + if printer is not None and atom_name == 'ImaginaryUnit' and printer._settings['imaginary_unit'] == 'j': + return U('DOUBLE-STRUCK ITALIC SMALL J') + else: + return atoms_table[atom_name] + else: + if default is not None: + return default + + raise KeyError('only unicode') # send it default printer + + +def pretty_symbol(symb_name, bold_name=False): + """return pretty representation of a symbol""" + # let's split symb_name into symbol + index + # UC: beta1 + # UC: f_beta + + if not _use_unicode: + return symb_name + + name, sups, subs = split_super_sub(symb_name) + + def translate(s, bold_name) : + if bold_name: + gG = greek_bold_unicode.get(s) + else: + gG = greek_unicode.get(s) + if gG is not None: + return gG + for key in sorted(modifier_dict.keys(), key=lambda k:len(k), reverse=True) : + if s.lower().endswith(key) and len(s)>len(key): + return modifier_dict[key](translate(s[:-len(key)], bold_name)) + if bold_name: + return ''.join([bold_unicode[c] for c in s]) + return s + + name = translate(name, bold_name) + + # Let's prettify sups/subs. If it fails at one of them, pretty sups/subs are + # not used at all. + def pretty_list(l, mapping): + result = [] + for s in l: + pretty = mapping.get(s) + if pretty is None: + try: # match by separate characters + pretty = ''.join([mapping[c] for c in s]) + except (TypeError, KeyError): + return None + result.append(pretty) + return result + + pretty_sups = pretty_list(sups, sup) + if pretty_sups is not None: + pretty_subs = pretty_list(subs, sub) + else: + pretty_subs = None + + # glue the results into one string + if pretty_subs is None: # nice formatting of sups/subs did not work + if subs: + name += '_'+'_'.join([translate(s, bold_name) for s in subs]) + if sups: + name += '__'+'__'.join([translate(s, bold_name) for s in sups]) + return name + else: + sups_result = ' '.join(pretty_sups) + subs_result = ' '.join(pretty_subs) + + return ''.join([name, sups_result, subs_result]) + + +def annotated(letter): + """ + Return a stylised drawing of the letter ``letter``, together with + information on how to put annotations (super- and subscripts to the + left and to the right) on it. + + See pretty.py functions _print_meijerg, _print_hyper on how to use this + information. + """ + ucode_pics = { + 'F': (2, 0, 2, 0, '\N{BOX DRAWINGS LIGHT DOWN AND RIGHT}\N{BOX DRAWINGS LIGHT HORIZONTAL}\n' + '\N{BOX DRAWINGS LIGHT VERTICAL AND RIGHT}\N{BOX DRAWINGS LIGHT HORIZONTAL}\n' + '\N{BOX DRAWINGS LIGHT UP}'), + 'G': (3, 0, 3, 1, '\N{BOX DRAWINGS LIGHT ARC DOWN AND RIGHT}\N{BOX DRAWINGS LIGHT HORIZONTAL}\N{BOX DRAWINGS LIGHT ARC DOWN AND LEFT}\n' + '\N{BOX DRAWINGS LIGHT VERTICAL}\N{BOX DRAWINGS LIGHT RIGHT}\N{BOX DRAWINGS LIGHT DOWN AND LEFT}\n' + '\N{BOX DRAWINGS LIGHT ARC UP AND RIGHT}\N{BOX DRAWINGS LIGHT HORIZONTAL}\N{BOX DRAWINGS LIGHT ARC UP AND LEFT}') + } + ascii_pics = { + 'F': (3, 0, 3, 0, ' _\n|_\n|\n'), + 'G': (3, 0, 3, 1, ' __\n/__\n\\_|') + } + + if _use_unicode: + return ucode_pics[letter] + else: + return ascii_pics[letter] + +_remove_combining = dict.fromkeys(list(range(ord('\N{COMBINING GRAVE ACCENT}'), ord('\N{COMBINING LATIN SMALL LETTER X}'))) + + list(range(ord('\N{COMBINING LEFT HARPOON ABOVE}'), ord('\N{COMBINING ASTERISK ABOVE}')))) + +def is_combining(sym): + """Check whether symbol is a unicode modifier. """ + + return ord(sym) in _remove_combining + + +def center_accent(string, accent): + """ + Returns a string with accent inserted on the middle character. Useful to + put combining accents on symbol names, including multi-character names. + + Parameters + ========== + + string : string + The string to place the accent in. + accent : string + The combining accent to insert + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Combining_character + .. [2] https://en.wikipedia.org/wiki/Combining_Diacritical_Marks + + """ + + # Accent is placed on the previous character, although it may not always look + # like that depending on console + midpoint = len(string) // 2 + 1 + firstpart = string[:midpoint] + secondpart = string[midpoint:] + return firstpart + accent + secondpart + + +def line_width(line): + """Unicode combining symbols (modifiers) are not ever displayed as + separate symbols and thus should not be counted + """ + return len(line.translate(_remove_combining)) + + +def is_subscriptable_in_unicode(subscript): + """ + Checks whether a string is subscriptable in unicode or not. + + Parameters + ========== + + subscript: the string which needs to be checked + + Examples + ======== + + >>> from sympy.printing.pretty.pretty_symbology import is_subscriptable_in_unicode + >>> is_subscriptable_in_unicode('abc') + False + >>> is_subscriptable_in_unicode('123') + True + + """ + return all(character in sub for character in subscript) + + +def center_pad(wstring, wtarget, fillchar=' '): + """ + Return the padding strings necessary to center a string of + wstring characters wide in a wtarget wide space. + + The line_width wstring should always be less or equal to wtarget + or else a ValueError will be raised. + """ + if wstring > wtarget: + raise ValueError('not enough space for string') + wdelta = wtarget - wstring + + wleft = wdelta // 2 # favor left '1 ' + wright = wdelta - wleft + + left = fillchar * wleft + right = fillchar * wright + + return left, right + + +def center(string, width, fillchar=' '): + """Return a centered string of length determined by `line_width` + that uses `fillchar` for padding. + """ + left, right = center_pad(line_width(string), width, fillchar) + return ''.join([left, string, right]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/stringpict.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/stringpict.py new file mode 100644 index 0000000000000000000000000000000000000000..b6055f09c83b2abbe0c492991aaee4dff5b34f49 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/stringpict.py @@ -0,0 +1,537 @@ +"""Prettyprinter by Jurjen Bos. +(I hate spammers: mail me at pietjepuk314 at the reverse of ku.oc.oohay). +All objects have a method that create a "stringPict", +that can be used in the str method for pretty printing. + +Updates by Jason Gedge (email at cs mun ca) + - terminal_string() method + - minor fixes and changes (mostly to prettyForm) + +TODO: + - Allow left/center/right alignment options for above/below and + top/center/bottom alignment options for left/right +""" + +import shutil + +from .pretty_symbology import hobj, vobj, xsym, xobj, pretty_use_unicode, line_width, center +from sympy.utilities.exceptions import sympy_deprecation_warning + +_GLOBAL_WRAP_LINE = None + +class stringPict: + """An ASCII picture. + The pictures are represented as a list of equal length strings. + """ + #special value for stringPict.below + LINE = 'line' + + def __init__(self, s, baseline=0): + """Initialize from string. + Multiline strings are centered. + """ + self.s = s + #picture is a string that just can be printed + self.picture = stringPict.equalLengths(s.splitlines()) + #baseline is the line number of the "base line" + self.baseline = baseline + self.binding = None + + @staticmethod + def equalLengths(lines): + # empty lines + if not lines: + return [''] + + width = max(line_width(line) for line in lines) + return [center(line, width) for line in lines] + + def height(self): + """The height of the picture in characters.""" + return len(self.picture) + + def width(self): + """The width of the picture in characters.""" + return line_width(self.picture[0]) + + @staticmethod + def next(*args): + """Put a string of stringPicts next to each other. + Returns string, baseline arguments for stringPict. + """ + #convert everything to stringPicts + objects = [] + for arg in args: + if isinstance(arg, str): + arg = stringPict(arg) + objects.append(arg) + + #make a list of pictures, with equal height and baseline + newBaseline = max(obj.baseline for obj in objects) + newHeightBelowBaseline = max( + obj.height() - obj.baseline + for obj in objects) + newHeight = newBaseline + newHeightBelowBaseline + + pictures = [] + for obj in objects: + oneEmptyLine = [' '*obj.width()] + basePadding = newBaseline - obj.baseline + totalPadding = newHeight - obj.height() + pictures.append( + oneEmptyLine * basePadding + + obj.picture + + oneEmptyLine * (totalPadding - basePadding)) + + result = [''.join(lines) for lines in zip(*pictures)] + return '\n'.join(result), newBaseline + + def right(self, *args): + r"""Put pictures next to this one. + Returns string, baseline arguments for stringPict. + (Multiline) strings are allowed, and are given a baseline of 0. + + Examples + ======== + + >>> from sympy.printing.pretty.stringpict import stringPict + >>> print(stringPict("10").right(" + ",stringPict("1\r-\r2",1))[0]) + 1 + 10 + - + 2 + + """ + return stringPict.next(self, *args) + + def left(self, *args): + """Put pictures (left to right) at left. + Returns string, baseline arguments for stringPict. + """ + return stringPict.next(*(args + (self,))) + + @staticmethod + def stack(*args): + """Put pictures on top of each other, + from top to bottom. + Returns string, baseline arguments for stringPict. + The baseline is the baseline of the second picture. + Everything is centered. + Baseline is the baseline of the second picture. + Strings are allowed. + The special value stringPict.LINE is a row of '-' extended to the width. + """ + #convert everything to stringPicts; keep LINE + objects = [] + for arg in args: + if arg is not stringPict.LINE and isinstance(arg, str): + arg = stringPict(arg) + objects.append(arg) + + #compute new width + newWidth = max( + obj.width() + for obj in objects + if obj is not stringPict.LINE) + + lineObj = stringPict(hobj('-', newWidth)) + + #replace LINE with proper lines + for i, obj in enumerate(objects): + if obj is stringPict.LINE: + objects[i] = lineObj + + #stack the pictures, and center the result + newPicture = [center(line, newWidth) for obj in objects for line in obj.picture] + newBaseline = objects[0].height() + objects[1].baseline + return '\n'.join(newPicture), newBaseline + + def below(self, *args): + """Put pictures under this picture. + Returns string, baseline arguments for stringPict. + Baseline is baseline of top picture + + Examples + ======== + + >>> from sympy.printing.pretty.stringpict import stringPict + >>> print(stringPict("x+3").below( + ... stringPict.LINE, '3')[0]) #doctest: +NORMALIZE_WHITESPACE + x+3 + --- + 3 + + """ + s, baseline = stringPict.stack(self, *args) + return s, self.baseline + + def above(self, *args): + """Put pictures above this picture. + Returns string, baseline arguments for stringPict. + Baseline is baseline of bottom picture. + """ + string, baseline = stringPict.stack(*(args + (self,))) + baseline = len(string.splitlines()) - self.height() + self.baseline + return string, baseline + + def parens(self, left='(', right=')', ifascii_nougly=False): + """Put parentheses around self. + Returns string, baseline arguments for stringPict. + + left or right can be None or empty string which means 'no paren from + that side' + """ + h = self.height() + b = self.baseline + + # XXX this is a hack -- ascii parens are ugly! + if ifascii_nougly and not pretty_use_unicode(): + h = 1 + b = 0 + + res = self + + if left: + lparen = stringPict(vobj(left, h), baseline=b) + res = stringPict(*lparen.right(self)) + if right: + rparen = stringPict(vobj(right, h), baseline=b) + res = stringPict(*res.right(rparen)) + + return ('\n'.join(res.picture), res.baseline) + + def leftslash(self): + """Precede object by a slash of the proper size. + """ + # XXX not used anywhere ? + height = max( + self.baseline, + self.height() - 1 - self.baseline)*2 + 1 + slash = '\n'.join( + ' '*(height - i - 1) + xobj('/', 1) + ' '*i + for i in range(height) + ) + return self.left(stringPict(slash, height//2)) + + def root(self, n=None): + """Produce a nice root symbol. + Produces ugly results for big n inserts. + """ + # XXX not used anywhere + # XXX duplicate of root drawing in pretty.py + #put line over expression + result = self.above('_'*self.width()) + #construct right half of root symbol + height = self.height() + slash = '\n'.join( + ' ' * (height - i - 1) + '/' + ' ' * i + for i in range(height) + ) + slash = stringPict(slash, height - 1) + #left half of root symbol + if height > 2: + downline = stringPict('\\ \n \\', 1) + else: + downline = stringPict('\\') + #put n on top, as low as possible + if n is not None and n.width() > downline.width(): + downline = downline.left(' '*(n.width() - downline.width())) + downline = downline.above(n) + #build root symbol + root = downline.right(slash) + #glue it on at the proper height + #normally, the root symbel is as high as self + #which is one less than result + #this moves the root symbol one down + #if the root became higher, the baseline has to grow too + root.baseline = result.baseline - result.height() + root.height() + return result.left(root) + + def render(self, * args, **kwargs): + """Return the string form of self. + + Unless the argument line_break is set to False, it will + break the expression in a form that can be printed + on the terminal without being broken up. + """ + if _GLOBAL_WRAP_LINE is not None: + kwargs["wrap_line"] = _GLOBAL_WRAP_LINE + + if kwargs["wrap_line"] is False: + return "\n".join(self.picture) + + if kwargs["num_columns"] is not None: + # Read the argument num_columns if it is not None + ncols = kwargs["num_columns"] + else: + # Attempt to get a terminal width + ncols = self.terminal_width() + + if ncols <= 0: + ncols = 80 + + # If smaller than the terminal width, no need to correct + if self.width() <= ncols: + return type(self.picture[0])(self) + + """ + Break long-lines in a visually pleasing format. + without overflow indicators | with overflow indicators + | 2 2 3 | | 2 2 3 ↪| + |6*x *y + 4*x*y + | |6*x *y + 4*x*y + ↪| + | | | | + | 3 4 4 | |↪ 3 4 4 | + |4*y*x + x + y | |↪ 4*y*x + x + y | + |a*c*e + a*c*f + a*d | |a*c*e + a*c*f + a*d ↪| + |*e + a*d*f + b*c*e | | | + |+ b*c*f + b*d*e + b | |↪ *e + a*d*f + b*c* ↪| + |*d*f | | | + | | |↪ e + b*c*f + b*d*e ↪| + | | | | + | | |↪ + b*d*f | + """ + + overflow_first = "" + if kwargs["use_unicode"] or pretty_use_unicode(): + overflow_start = "\N{RIGHTWARDS ARROW WITH HOOK} " + overflow_end = " \N{RIGHTWARDS ARROW WITH HOOK}" + else: + overflow_start = "> " + overflow_end = " >" + + def chunks(line): + """Yields consecutive chunks of line_width ncols""" + prefix = overflow_first + width, start = line_width(prefix + overflow_end), 0 + for i, x in enumerate(line): + wx = line_width(x) + # Only flush the screen when the current character overflows. + # This way, combining marks can be appended even when width == ncols. + if width + wx > ncols: + yield prefix + line[start:i] + overflow_end + prefix = overflow_start + width, start = line_width(prefix + overflow_end), i + width += wx + yield prefix + line[start:] + + # Concurrently assemble chunks of all lines into individual screens + pictures = zip(*map(chunks, self.picture)) + + # Join lines of each screen into sub-pictures + pictures = ["\n".join(picture) for picture in pictures] + + # Add spacers between sub-pictures + return "\n\n".join(pictures) + + def terminal_width(self): + """Return the terminal width if possible, otherwise return 0. + """ + size = shutil.get_terminal_size(fallback=(0, 0)) + return size.columns + + def __eq__(self, o): + if isinstance(o, str): + return '\n'.join(self.picture) == o + elif isinstance(o, stringPict): + return o.picture == self.picture + return False + + def __hash__(self): + return super().__hash__() + + def __str__(self): + return '\n'.join(self.picture) + + def __repr__(self): + return "stringPict(%r,%d)" % ('\n'.join(self.picture), self.baseline) + + def __getitem__(self, index): + return self.picture[index] + + def __len__(self): + return len(self.s) + + +class prettyForm(stringPict): + """ + Extension of the stringPict class that knows about basic math applications, + optimizing double minus signs. + + "Binding" is interpreted as follows:: + + ATOM this is an atom: never needs to be parenthesized + FUNC this is a function application: parenthesize if added (?) + DIV this is a division: make wider division if divided + POW this is a power: only parenthesize if exponent + MUL this is a multiplication: parenthesize if powered + ADD this is an addition: parenthesize if multiplied or powered + NEG this is a negative number: optimize if added, parenthesize if + multiplied or powered + OPEN this is an open object: parenthesize if added, multiplied, or + powered (example: Piecewise) + """ + ATOM, FUNC, DIV, POW, MUL, ADD, NEG, OPEN = range(8) + + def __init__(self, s, baseline=0, binding=0, unicode=None): + """Initialize from stringPict and binding power.""" + stringPict.__init__(self, s, baseline) + self.binding = binding + if unicode is not None: + sympy_deprecation_warning( + """ + The unicode argument to prettyForm is deprecated. Only the s + argument (the first positional argument) should be passed. + """, + deprecated_since_version="1.7", + active_deprecations_target="deprecated-pretty-printing-functions") + self._unicode = unicode or s + + @property + def unicode(self): + sympy_deprecation_warning( + """ + The prettyForm.unicode attribute is deprecated. Use the + prettyForm.s attribute instead. + """, + deprecated_since_version="1.7", + active_deprecations_target="deprecated-pretty-printing-functions") + return self._unicode + + # Note: code to handle subtraction is in _print_Add + + def __add__(self, *others): + """Make a pretty addition. + Addition of negative numbers is simplified. + """ + arg = self + if arg.binding > prettyForm.NEG: + arg = stringPict(*arg.parens()) + result = [arg] + for arg in others: + #add parentheses for weak binders + if arg.binding > prettyForm.NEG: + arg = stringPict(*arg.parens()) + #use existing minus sign if available + if arg.binding != prettyForm.NEG: + result.append(' + ') + result.append(arg) + return prettyForm(binding=prettyForm.ADD, *stringPict.next(*result)) + + def __truediv__(self, den, slashed=False): + """Make a pretty division; stacked or slashed. + """ + if slashed: + raise NotImplementedError("Can't do slashed fraction yet") + num = self + if num.binding == prettyForm.DIV: + num = stringPict(*num.parens()) + if den.binding == prettyForm.DIV: + den = stringPict(*den.parens()) + + if num.binding==prettyForm.NEG: + num = num.right(" ")[0] + + return prettyForm(binding=prettyForm.DIV, *stringPict.stack( + num, + stringPict.LINE, + den)) + + def __mul__(self, *others): + """Make a pretty multiplication. + Parentheses are needed around +, - and neg. + """ + quantity = { + 'degree': "\N{DEGREE SIGN}" + } + + if len(others) == 0: + return self # We aren't actually multiplying... So nothing to do here. + + # add parens on args that need them + arg = self + if arg.binding > prettyForm.MUL and arg.binding != prettyForm.NEG: + arg = stringPict(*arg.parens()) + result = [arg] + for arg in others: + if arg.picture[0] not in quantity.values(): + result.append(xsym('*')) + #add parentheses for weak binders + if arg.binding > prettyForm.MUL and arg.binding != prettyForm.NEG: + arg = stringPict(*arg.parens()) + result.append(arg) + + len_res = len(result) + for i in range(len_res): + if i < len_res - 1 and result[i] == '-1' and result[i + 1] == xsym('*'): + # substitute -1 by -, like in -1*x -> -x + result.pop(i) + result.pop(i) + result.insert(i, '-') + if result[0][0] == '-': + # if there is a - sign in front of all + # This test was failing to catch a prettyForm.__mul__(prettyForm("-1", 0, 6)) being negative + bin = prettyForm.NEG + if result[0] == '-': + right = result[1] + if right.picture[right.baseline][0] == '-': + result[0] = '- ' + else: + bin = prettyForm.MUL + return prettyForm(binding=bin, *stringPict.next(*result)) + + def __repr__(self): + return "prettyForm(%r,%d,%d)" % ( + '\n'.join(self.picture), + self.baseline, + self.binding) + + def __pow__(self, b): + """Make a pretty power. + """ + a = self + use_inline_func_form = False + if b.binding == prettyForm.POW: + b = stringPict(*b.parens()) + if a.binding > prettyForm.FUNC: + a = stringPict(*a.parens()) + elif a.binding == prettyForm.FUNC: + # heuristic for when to use inline power + if b.height() > 1: + a = stringPict(*a.parens()) + else: + use_inline_func_form = True + + if use_inline_func_form: + # 2 + # sin + + (x) + b.baseline = a.prettyFunc.baseline + b.height() + func = stringPict(*a.prettyFunc.right(b)) + return prettyForm(*func.right(a.prettyArgs)) + else: + # 2 <-- top + # (x+y) <-- bot + top = stringPict(*b.left(' '*a.width())) + bot = stringPict(*a.right(' '*b.width())) + + return prettyForm(binding=prettyForm.POW, *bot.above(top)) + + simpleFunctions = ["sin", "cos", "tan"] + + @staticmethod + def apply(function, *args): + """Functions of one or more variables. + """ + if function in prettyForm.simpleFunctions: + #simple function: use only space if possible + assert len( + args) == 1, "Simple function %s must have 1 argument" % function + arg = args[0].__pretty__() + if arg.binding <= prettyForm.DIV: + #optimization: no parentheses necessary + return prettyForm(binding=prettyForm.FUNC, *arg.left(function + ' ')) + argumentList = [] + for arg in args: + argumentList.append(',') + argumentList.append(arg.__pretty__()) + argumentList = stringPict(*stringPict.next(*argumentList[1:])) + argumentList = stringPict(*argumentList.parens()) + return prettyForm(binding=prettyForm.ATOM, *argumentList.left(function)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/tests/test_pretty.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/tests/test_pretty.py new file mode 100644 index 0000000000000000000000000000000000000000..1cca79bd1dc5c3ba81483c8fe2e87c35926d1b94 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pretty/tests/test_pretty.py @@ -0,0 +1,7972 @@ +# -*- coding: utf-8 -*- +from sympy.concrete.products import Product +from sympy.concrete.summations import Sum +from sympy.core.add import Add +from sympy.core.basic import Basic +from sympy.core.containers import (Dict, Tuple) +from sympy.core.function import (Derivative, Function, Lambda, Subs) +from sympy.core.mul import Mul +from sympy.core import (EulerGamma, GoldenRatio, Catalan) +from sympy.core.numbers import (I, Rational, oo, pi) +from sympy.core.power import Pow +from sympy.core.relational import (Eq, Ge, Gt, Le, Lt, Ne) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.elementary.complexes import conjugate +from sympy.functions.elementary.exponential import LambertW +from sympy.functions.special.bessel import (airyai, airyaiprime, airybi, airybiprime) +from sympy.functions.special.delta_functions import Heaviside +from sympy.functions.special.error_functions import (fresnelc, fresnels) +from sympy.functions.special.singularity_functions import SingularityFunction +from sympy.functions.special.zeta_functions import dirichlet_eta +from sympy.geometry.line import (Ray, Segment) +from sympy.integrals.integrals import Integral +from sympy.logic.boolalg import (And, Equivalent, ITE, Implies, Nand, Nor, Not, Or, Xor) +from sympy.matrices.dense import (Matrix, diag) +from sympy.matrices.expressions.slice import MatrixSlice +from sympy.matrices.expressions.trace import Trace +from sympy.polys.domains.finitefield import FF +from sympy.polys.domains.integerring import ZZ +from sympy.polys.domains.rationalfield import QQ +from sympy.polys.domains.realfield import RR +from sympy.polys.orderings import (grlex, ilex) +from sympy.polys.polytools import groebner +from sympy.polys.rootoftools import (RootSum, rootof) +from sympy.series.formal import fps +from sympy.series.fourier import fourier_series +from sympy.series.limits import Limit +from sympy.series.order import O +from sympy.series.sequences import (SeqAdd, SeqFormula, SeqMul, SeqPer) +from sympy.sets.contains import Contains +from sympy.sets.fancysets import Range +from sympy.sets.sets import (Complement, FiniteSet, Intersection, Interval, Union) +from sympy.codegen.ast import (Assignment, AddAugmentedAssignment, + SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment) +from sympy.core.expr import UnevaluatedExpr +from sympy.physics.quantum.trace import Tr + +from sympy.functions import (Abs, Chi, Ci, Ei, KroneckerDelta, + Piecewise, Shi, Si, atan2, beta, binomial, catalan, ceiling, cos, + euler, exp, expint, factorial, factorial2, floor, gamma, hyper, log, + meijerg, sin, sqrt, subfactorial, tan, uppergamma, lerchphi, polylog, + elliptic_k, elliptic_f, elliptic_e, elliptic_pi, DiracDelta, bell, + bernoulli, fibonacci, tribonacci, lucas, stieltjes, mathieuc, mathieus, + mathieusprime, mathieucprime) + +from sympy.matrices import (Adjoint, Inverse, MatrixSymbol, Transpose, + KroneckerProduct, BlockMatrix, OneMatrix, ZeroMatrix) +from sympy.matrices.expressions import hadamard_power + +from sympy.physics import mechanics +from sympy.physics.control.lti import (TransferFunction, Feedback, TransferFunctionMatrix, + Series, Parallel, MIMOSeries, MIMOParallel, MIMOFeedback, StateSpace) +from sympy.physics.units import joule, degree +from sympy.printing.pretty import pprint, pretty as xpretty +from sympy.printing.pretty.pretty_symbology import center_accent, is_combining, center +from sympy.sets.conditionset import ConditionSet + +from sympy.sets import ImageSet, ProductSet +from sympy.sets.setexpr import SetExpr +from sympy.stats.crv_types import Normal +from sympy.stats.symbolic_probability import (Covariance, Expectation, + Probability, Variance) +from sympy.tensor.array import (ImmutableDenseNDimArray, ImmutableSparseNDimArray, + MutableDenseNDimArray, MutableSparseNDimArray, tensorproduct) +from sympy.tensor.functions import TensorProduct +from sympy.tensor.tensor import (TensorIndexType, tensor_indices, TensorHead, + TensorElement, tensor_heads) + +from sympy.testing.pytest import raises, _both_exp_pow, warns_deprecated_sympy + +from sympy.vector import CoordSys3D, Gradient, Curl, Divergence, Dot, Cross, Laplacian + + + +import sympy as sym +class lowergamma(sym.lowergamma): + pass # testing notation inheritance by a subclass with same name + +a, b, c, d, x, y, z, k, n, s, p = symbols('a,b,c,d,x,y,z,k,n,s,p') +f = Function("f") +th = Symbol('theta') +ph = Symbol('phi') + +""" +Expressions whose pretty-printing is tested here: +(A '#' to the right of an expression indicates that its various acceptable +orderings are accounted for by the tests.) + + +BASIC EXPRESSIONS: + +oo +(x**2) +1/x +y*x**-2 +x**Rational(-5,2) +(-2)**x +Pow(3, 1, evaluate=False) +(x**2 + x + 1) # +1-x # +1-2*x # +x/y +-x/y +(x+2)/y # +(1+x)*y #3 +-5*x/(x+10) # correct placement of negative sign +1 - Rational(3,2)*(x+1) +-(-x + 5)*(-x - 2*sqrt(2) + 5) - (-y + 5)*(-y + 5) # issue 5524 + + +ORDERING: + +x**2 + x + 1 +1 - x +1 - 2*x +2*x**4 + y**2 - x**2 + y**3 + + +RELATIONAL: + +Eq(x, y) +Lt(x, y) +Gt(x, y) +Le(x, y) +Ge(x, y) +Ne(x/(y+1), y**2) # + + +RATIONAL NUMBERS: + +y*x**-2 +y**Rational(3,2) * x**Rational(-5,2) +sin(x)**3/tan(x)**2 + + +FUNCTIONS (ABS, CONJ, EXP, FUNCTION BRACES, FACTORIAL, FLOOR, CEILING): + +(2*x + exp(x)) # +Abs(x) +Abs(x/(x**2+1)) # +Abs(1 / (y - Abs(x))) +factorial(n) +factorial(2*n) +subfactorial(n) +subfactorial(2*n) +factorial(factorial(factorial(n))) +factorial(n+1) # +conjugate(x) +conjugate(f(x+1)) # +f(x) +f(x, y) +f(x/(y+1), y) # +f(x**x**x**x**x**x) +sin(x)**2 +conjugate(a+b*I) +conjugate(exp(a+b*I)) +conjugate( f(1 + conjugate(f(x))) ) # +f(x/(y+1), y) # denom of first arg +floor(1 / (y - floor(x))) +ceiling(1 / (y - ceiling(x))) + + +SQRT: + +sqrt(2) +2**Rational(1,3) +2**Rational(1,1000) +sqrt(x**2 + 1) +(1 + sqrt(5))**Rational(1,3) +2**(1/x) +sqrt(2+pi) +(2+(1+x**2)/(2+x))**Rational(1,4)+(1+x**Rational(1,1000))/sqrt(3+x**2) + + +DERIVATIVES: + +Derivative(log(x), x, evaluate=False) +Derivative(log(x), x, evaluate=False) + x # +Derivative(log(x) + x**2, x, y, evaluate=False) +Derivative(2*x*y, y, x, evaluate=False) + x**2 # +beta(alpha).diff(alpha) + + +INTEGRALS: + +Integral(log(x), x) +Integral(x**2, x) +Integral((sin(x))**2 / (tan(x))**2) +Integral(x**(2**x), x) +Integral(x**2, (x,1,2)) +Integral(x**2, (x,Rational(1,2),10)) +Integral(x**2*y**2, x,y) +Integral(x**2, (x, None, 1)) +Integral(x**2, (x, 1, None)) +Integral(sin(th)/cos(ph), (th,0,pi), (ph, 0, 2*pi)) + + +MATRICES: + +Matrix([[x**2+1, 1], [y, x+y]]) # +Matrix([[x/y, y, th], [0, exp(I*k*ph), 1]]) + + +PIECEWISE: + +Piecewise((x,x<1),(x**2,True)) + +ITE: + +ITE(x, y, z) + +SEQUENCES (TUPLES, LISTS, DICTIONARIES): + +() +[] +{} +(1/x,) +[x**2, 1/x, x, y, sin(th)**2/cos(ph)**2] +(x**2, 1/x, x, y, sin(th)**2/cos(ph)**2) +{x: sin(x)} +{1/x: 1/y, x: sin(x)**2} # +[x**2] +(x**2,) +{x**2: 1} + + +LIMITS: + +Limit(x, x, oo) +Limit(x**2, x, 0) +Limit(1/x, x, 0) +Limit(sin(x)/x, x, 0) + + +UNITS: + +joule => kg*m**2/s + + +SUBS: + +Subs(f(x), x, ph**2) +Subs(f(x).diff(x), x, 0) +Subs(f(x).diff(x)/y, (x, y), (0, Rational(1, 2))) + + +ORDER: + +O(1) +O(1/x) +O(x**2 + y**2) + +""" + + +def pretty(expr, order=None): + """ASCII pretty-printing""" + return xpretty(expr, order=order, use_unicode=False, wrap_line=False) + + +def upretty(expr, order=None): + """Unicode pretty-printing""" + return xpretty(expr, order=order, use_unicode=True, wrap_line=False) + + +def test_pretty_ascii_str(): + assert pretty( 'xxx' ) == 'xxx' + assert pretty( "xxx" ) == 'xxx' + assert pretty( 'xxx\'xxx' ) == 'xxx\'xxx' + assert pretty( 'xxx"xxx' ) == 'xxx\"xxx' + assert pretty( 'xxx\"xxx' ) == 'xxx\"xxx' + assert pretty( "xxx'xxx" ) == 'xxx\'xxx' + assert pretty( "xxx\'xxx" ) == 'xxx\'xxx' + assert pretty( "xxx\"xxx" ) == 'xxx\"xxx' + assert pretty( "xxx\"xxx\'xxx" ) == 'xxx"xxx\'xxx' + assert pretty( "xxx\nxxx" ) == 'xxx\nxxx' + + +def test_pretty_unicode_str(): + assert pretty( 'xxx' ) == 'xxx' + assert pretty( 'xxx' ) == 'xxx' + assert pretty( 'xxx\'xxx' ) == 'xxx\'xxx' + assert pretty( 'xxx"xxx' ) == 'xxx\"xxx' + assert pretty( 'xxx\"xxx' ) == 'xxx\"xxx' + assert pretty( "xxx'xxx" ) == 'xxx\'xxx' + assert pretty( "xxx\'xxx" ) == 'xxx\'xxx' + assert pretty( "xxx\"xxx" ) == 'xxx\"xxx' + assert pretty( "xxx\"xxx\'xxx" ) == 'xxx"xxx\'xxx' + assert pretty( "xxx\nxxx" ) == 'xxx\nxxx' + + +def test_upretty_greek(): + assert upretty( oo ) == '∞' + assert upretty( Symbol('alpha^+_1') ) == 'α⁺₁' + assert upretty( Symbol('beta') ) == 'β' + assert upretty(Symbol('lambda')) == 'λ' + + +def test_upretty_multiindex(): + assert upretty( Symbol('beta12') ) == 'β₁₂' + assert upretty( Symbol('Y00') ) == 'Y₀₀' + assert upretty( Symbol('Y_00') ) == 'Y₀₀' + assert upretty( Symbol('F^+-') ) == 'F⁺⁻' + + +def test_upretty_sub_super(): + assert upretty( Symbol('beta_1_2') ) == 'β₁ ₂' + assert upretty( Symbol('beta^1^2') ) == 'β¹ ²' + assert upretty( Symbol('beta_1^2') ) == 'β²₁' + assert upretty( Symbol('beta_10_20') ) == 'β₁₀ ₂₀' + assert upretty( Symbol('beta_ax_gamma^i') ) == 'βⁱₐₓ ᵧ' + assert upretty( Symbol("F^1^2_3_4") ) == 'F¹ ²₃ ₄' + assert upretty( Symbol("F_1_2^3^4") ) == 'F³ ⁴₁ ₂' + assert upretty( Symbol("F_1_2_3_4") ) == 'F₁ ₂ ₃ ₄' + assert upretty( Symbol("F^1^2^3^4") ) == 'F¹ ² ³ ⁴' + + +def test_upretty_subs_missing_in_24(): + assert upretty( Symbol('F_beta') ) == 'Fᵦ' + assert upretty( Symbol('F_gamma') ) == 'Fᵧ' + assert upretty( Symbol('F_rho') ) == 'Fᵨ' + assert upretty( Symbol('F_phi') ) == 'Fᵩ' + assert upretty( Symbol('F_chi') ) == 'Fᵪ' + + assert upretty( Symbol('F_a') ) == 'Fₐ' + assert upretty( Symbol('F_e') ) == 'Fₑ' + assert upretty( Symbol('F_i') ) == 'Fᵢ' + assert upretty( Symbol('F_o') ) == 'Fₒ' + assert upretty( Symbol('F_u') ) == 'Fᵤ' + assert upretty( Symbol('F_r') ) == 'Fᵣ' + assert upretty( Symbol('F_v') ) == 'Fᵥ' + assert upretty( Symbol('F_x') ) == 'Fₓ' + + +def test_missing_in_2X_issue_9047(): + assert upretty( Symbol('F_h') ) == 'Fₕ' + assert upretty( Symbol('F_k') ) == 'Fₖ' + assert upretty( Symbol('F_l') ) == 'Fₗ' + assert upretty( Symbol('F_m') ) == 'Fₘ' + assert upretty( Symbol('F_n') ) == 'Fₙ' + assert upretty( Symbol('F_p') ) == 'Fₚ' + assert upretty( Symbol('F_s') ) == 'Fₛ' + assert upretty( Symbol('F_t') ) == 'Fₜ' + + +def test_upretty_modifiers(): + # Accents + assert upretty( Symbol('Fmathring') ) == 'F̊' + assert upretty( Symbol('Fddddot') ) == 'F⃜' + assert upretty( Symbol('Fdddot') ) == 'F⃛' + assert upretty( Symbol('Fddot') ) == 'F̈' + assert upretty( Symbol('Fdot') ) == 'Ḟ' + assert upretty( Symbol('Fcheck') ) == 'F̌' + assert upretty( Symbol('Fbreve') ) == 'F̆' + assert upretty( Symbol('Facute') ) == 'F́' + assert upretty( Symbol('Fgrave') ) == 'F̀' + assert upretty( Symbol('Ftilde') ) == 'F̃' + assert upretty( Symbol('Fhat') ) == 'F̂' + assert upretty( Symbol('Fbar') ) == 'F̅' + assert upretty( Symbol('Fvec') ) == 'F⃗' + assert upretty( Symbol('Fprime') ) == 'F′' + assert upretty( Symbol('Fprm') ) == 'F′' + # No faces are actually implemented, but test to make sure the modifiers are stripped + assert upretty( Symbol('Fbold') ) == 'Fbold' + assert upretty( Symbol('Fbm') ) == 'Fbm' + assert upretty( Symbol('Fcal') ) == 'Fcal' + assert upretty( Symbol('Fscr') ) == 'Fscr' + assert upretty( Symbol('Ffrak') ) == 'Ffrak' + # Brackets + assert upretty( Symbol('Fnorm') ) == '‖F‖' + assert upretty( Symbol('Favg') ) == '⟨F⟩' + assert upretty( Symbol('Fabs') ) == '|F|' + assert upretty( Symbol('Fmag') ) == '|F|' + # Combinations + assert upretty( Symbol('xvecdot') ) == 'x⃗̇' + assert upretty( Symbol('xDotVec') ) == 'ẋ⃗' + assert upretty( Symbol('xHATNorm') ) == '‖x̂‖' + assert upretty( Symbol('xMathring_yCheckPRM__zbreveAbs') ) == 'x̊_y̌′__|z̆|' + assert upretty( Symbol('alphadothat_nVECDOT__tTildePrime') ) == 'α̇̂_n⃗̇__t̃′' + assert upretty( Symbol('x_dot') ) == 'x_dot' + assert upretty( Symbol('x__dot') ) == 'x__dot' + + +def test_pretty_Cycle(): + from sympy.combinatorics.permutations import Cycle + assert pretty(Cycle(1, 2)) == '(1 2)' + assert pretty(Cycle(2)) == '(2)' + assert pretty(Cycle(1, 3)(4, 5)) == '(1 3)(4 5)' + assert pretty(Cycle()) == '()' + + +def test_pretty_Permutation(): + from sympy.combinatorics.permutations import Permutation + p1 = Permutation(1, 2)(3, 4) + assert xpretty(p1, perm_cyclic=True, use_unicode=True) == "(1 2)(3 4)" + assert xpretty(p1, perm_cyclic=True, use_unicode=False) == "(1 2)(3 4)" + assert xpretty(p1, perm_cyclic=False, use_unicode=True) == \ + '⎛0 1 2 3 4⎞\n'\ + '⎝0 2 1 4 3⎠' + assert xpretty(p1, perm_cyclic=False, use_unicode=False) == \ + "/0 1 2 3 4\\\n"\ + "\\0 2 1 4 3/" + + with warns_deprecated_sympy(): + old_print_cyclic = Permutation.print_cyclic + Permutation.print_cyclic = False + assert xpretty(p1, use_unicode=True) == \ + '⎛0 1 2 3 4⎞\n'\ + '⎝0 2 1 4 3⎠' + assert xpretty(p1, use_unicode=False) == \ + "/0 1 2 3 4\\\n"\ + "\\0 2 1 4 3/" + Permutation.print_cyclic = old_print_cyclic + + +def test_pretty_basic(): + assert pretty( -Rational(1)/2 ) == '-1/2' + assert pretty( -Rational(13)/22 ) == \ +"""\ +-13 \n\ +----\n\ + 22 \ +""" + expr = oo + ascii_str = \ +"""\ +oo\ +""" + ucode_str = \ +"""\ +∞\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (x**2) + ascii_str = \ +"""\ + 2\n\ +x \ +""" + ucode_str = \ +"""\ + 2\n\ +x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 1/x + ascii_str = \ +"""\ +1\n\ +-\n\ +x\ +""" + ucode_str = \ +"""\ +1\n\ +─\n\ +x\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + # not the same as 1/x + expr = x**-1.0 + ascii_str = \ +"""\ + -1.0\n\ +x \ +""" + ucode_str = \ +"""\ + -1.0\n\ +x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + # see issue #2860 + expr = Pow(S(2), -1.0, evaluate=False) + ascii_str = \ +"""\ + -1.0\n\ +2 \ +""" + ucode_str = \ +"""\ + -1.0\n\ +2 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = y*x**-2 + ascii_str = \ +"""\ +y \n\ +--\n\ + 2\n\ +x \ +""" + ucode_str = \ +"""\ +y \n\ +──\n\ + 2\n\ +x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + #see issue #14033 + expr = x**Rational(1, 3) + ascii_str = \ +"""\ + 1/3\n\ +x \ +""" + ucode_str = \ +"""\ + 1/3\n\ +x \ +""" + assert xpretty(expr, use_unicode=False, wrap_line=False,\ + root_notation = False) == ascii_str + assert xpretty(expr, use_unicode=True, wrap_line=False,\ + root_notation = False) == ucode_str + + expr = x**Rational(-5, 2) + ascii_str = \ +"""\ + 1 \n\ +----\n\ + 5/2\n\ +x \ +""" + ucode_str = \ +"""\ + 1 \n\ +────\n\ + 5/2\n\ +x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (-2)**x + ascii_str = \ +"""\ + x\n\ +(-2) \ +""" + ucode_str = \ +"""\ + x\n\ +(-2) \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + # See issue 4923 + expr = Pow(3, 1, evaluate=False) + ascii_str = \ +"""\ + 1\n\ +3 \ +""" + ucode_str = \ +"""\ + 1\n\ +3 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (x**2 + x + 1) + ascii_str_1 = \ +"""\ + 2\n\ +1 + x + x \ +""" + ascii_str_2 = \ +"""\ + 2 \n\ +x + x + 1\ +""" + ascii_str_3 = \ +"""\ + 2 \n\ +x + 1 + x\ +""" + ucode_str_1 = \ +"""\ + 2\n\ +1 + x + x \ +""" + ucode_str_2 = \ +"""\ + 2 \n\ +x + x + 1\ +""" + ucode_str_3 = \ +"""\ + 2 \n\ +x + 1 + x\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2, ascii_str_3] + assert upretty(expr) in [ucode_str_1, ucode_str_2, ucode_str_3] + + expr = 1 - x + ascii_str_1 = \ +"""\ +1 - x\ +""" + ascii_str_2 = \ +"""\ +-x + 1\ +""" + ucode_str_1 = \ +"""\ +1 - x\ +""" + ucode_str_2 = \ +"""\ +-x + 1\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = 1 - 2*x + ascii_str_1 = \ +"""\ +1 - 2*x\ +""" + ascii_str_2 = \ +"""\ +-2*x + 1\ +""" + ucode_str_1 = \ +"""\ +1 - 2⋅x\ +""" + ucode_str_2 = \ +"""\ +-2⋅x + 1\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = x/y + ascii_str = \ +"""\ +x\n\ +-\n\ +y\ +""" + ucode_str = \ +"""\ +x\n\ +─\n\ +y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = -x/y + ascii_str = \ +"""\ +-x \n\ +---\n\ + y \ +""" + ucode_str = \ +"""\ +-x \n\ +───\n\ + y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (x + 2)/y + ascii_str_1 = \ +"""\ +2 + x\n\ +-----\n\ + y \ +""" + ascii_str_2 = \ +"""\ +x + 2\n\ +-----\n\ + y \ +""" + ucode_str_1 = \ +"""\ +2 + x\n\ +─────\n\ + y \ +""" + ucode_str_2 = \ +"""\ +x + 2\n\ +─────\n\ + y \ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = (1 + x)*y + ascii_str_1 = \ +"""\ +y*(1 + x)\ +""" + ascii_str_2 = \ +"""\ +(1 + x)*y\ +""" + ascii_str_3 = \ +"""\ +y*(x + 1)\ +""" + ucode_str_1 = \ +"""\ +y⋅(1 + x)\ +""" + ucode_str_2 = \ +"""\ +(1 + x)⋅y\ +""" + ucode_str_3 = \ +"""\ +y⋅(x + 1)\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2, ascii_str_3] + assert upretty(expr) in [ucode_str_1, ucode_str_2, ucode_str_3] + + # Test for correct placement of the negative sign + expr = -5*x/(x + 10) + ascii_str_1 = \ +"""\ +-5*x \n\ +------\n\ +10 + x\ +""" + ascii_str_2 = \ +"""\ +-5*x \n\ +------\n\ +x + 10\ +""" + ucode_str_1 = \ +"""\ +-5⋅x \n\ +──────\n\ +10 + x\ +""" + ucode_str_2 = \ +"""\ +-5⋅x \n\ +──────\n\ +x + 10\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = -S.Half - 3*x + ascii_str = \ +"""\ +-3*x - 1/2\ +""" + ucode_str = \ +"""\ +-3⋅x - 1/2\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = S.Half - 3*x + ascii_str = \ +"""\ +1/2 - 3*x\ +""" + ucode_str = \ +"""\ +1/2 - 3⋅x\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = -S.Half - 3*x/2 + ascii_str = \ +"""\ + 3*x 1\n\ +- --- - -\n\ + 2 2\ +""" + ucode_str = \ +"""\ + 3⋅x 1\n\ +- ─── - ─\n\ + 2 2\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = S.Half - 3*x/2 + ascii_str = \ +"""\ +1 3*x\n\ +- - ---\n\ +2 2 \ +""" + ucode_str = \ +"""\ +1 3⋅x\n\ +─ - ───\n\ +2 2 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_negative_fractions(): + expr = -x/y + ascii_str =\ +"""\ +-x \n\ +---\n\ + y \ +""" + ucode_str =\ +"""\ +-x \n\ +───\n\ + y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = -x*z/y + ascii_str =\ +"""\ +-x*z \n\ +-----\n\ + y \ +""" + ucode_str =\ +"""\ +-x⋅z \n\ +─────\n\ + y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = x**2/y + ascii_str =\ +"""\ + 2\n\ +x \n\ +--\n\ +y \ +""" + ucode_str =\ +"""\ + 2\n\ +x \n\ +──\n\ +y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = -x**2/y + ascii_str =\ +"""\ + 2 \n\ +-x \n\ +----\n\ + y \ +""" + ucode_str =\ +"""\ + 2 \n\ +-x \n\ +────\n\ + y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = -x/(y*z) + ascii_str =\ +"""\ +-x \n\ +---\n\ +y*z\ +""" + ucode_str =\ +"""\ +-x \n\ +───\n\ +y⋅z\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = -a/y**2 + ascii_str =\ +"""\ +-a \n\ +---\n\ + 2 \n\ +y \ +""" + ucode_str =\ +"""\ +-a \n\ +───\n\ + 2 \n\ +y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = y**(-a/b) + ascii_str =\ +"""\ + -a \n\ + ---\n\ + b \n\ +y \ +""" + ucode_str =\ +"""\ + -a \n\ + ───\n\ + b \n\ +y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = -1/y**2 + ascii_str =\ +"""\ +-1 \n\ +---\n\ + 2 \n\ +y \ +""" + ucode_str =\ +"""\ +-1 \n\ +───\n\ + 2 \n\ +y \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = -10/b**2 + ascii_str =\ +"""\ +-10 \n\ +----\n\ + 2 \n\ + b \ +""" + ucode_str =\ +"""\ +-10 \n\ +────\n\ + 2 \n\ + b \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + expr = Rational(-200, 37) + ascii_str =\ +"""\ +-200 \n\ +-----\n\ + 37 \ +""" + ucode_str =\ +"""\ +-200 \n\ +─────\n\ + 37 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_Mul(): + expr = Mul(0, 1, evaluate=False) + assert pretty(expr) == "0*1" + assert upretty(expr) == "0⋅1" + expr = Mul(1, 0, evaluate=False) + assert pretty(expr) == "1*0" + assert upretty(expr) == "1⋅0" + expr = Mul(1, 1, evaluate=False) + assert pretty(expr) == "1*1" + assert upretty(expr) == "1⋅1" + expr = Mul(1, 1, 1, evaluate=False) + assert pretty(expr) == "1*1*1" + assert upretty(expr) == "1⋅1⋅1" + expr = Mul(1, 2, evaluate=False) + assert pretty(expr) == "1*2" + assert upretty(expr) == "1⋅2" + expr = Add(0, 1, evaluate=False) + assert pretty(expr) == "0 + 1" + assert upretty(expr) == "0 + 1" + expr = Mul(1, 1, 2, evaluate=False) + assert pretty(expr) == "1*1*2" + assert upretty(expr) == "1⋅1⋅2" + expr = Add(0, 0, 1, evaluate=False) + assert pretty(expr) == "0 + 0 + 1" + assert upretty(expr) == "0 + 0 + 1" + expr = Mul(1, -1, evaluate=False) + assert pretty(expr) == "1*-1" + assert upretty(expr) == "1⋅-1" + expr = Mul(1.0, x, evaluate=False) + assert pretty(expr) == "1.0*x" + assert upretty(expr) == "1.0⋅x" + expr = Mul(1, 1, 2, 3, x, evaluate=False) + assert pretty(expr) == "1*1*2*3*x" + assert upretty(expr) == "1⋅1⋅2⋅3⋅x" + expr = Mul(-1, 1, evaluate=False) + assert pretty(expr) == "-1*1" + assert upretty(expr) == "-1⋅1" + expr = Mul(4, 3, 2, 1, 0, y, x, evaluate=False) + assert pretty(expr) == "4*3*2*1*0*y*x" + assert upretty(expr) == "4⋅3⋅2⋅1⋅0⋅y⋅x" + expr = Mul(4, 3, 2, 1+z, 0, y, x, evaluate=False) + assert pretty(expr) == "4*3*2*(z + 1)*0*y*x" + assert upretty(expr) == "4⋅3⋅2⋅(z + 1)⋅0⋅y⋅x" + expr = Mul(Rational(2, 3), Rational(5, 7), evaluate=False) + assert pretty(expr) == "2/3*5/7" + assert upretty(expr) == "2/3⋅5/7" + expr = Mul(x + y, Rational(1, 2), evaluate=False) + assert pretty(expr) == "(x + y)*1/2" + assert upretty(expr) == "(x + y)⋅1/2" + expr = Mul(Rational(1, 2), x + y, evaluate=False) + assert pretty(expr) == "x + y\n-----\n 2 " + assert upretty(expr) == "x + y\n─────\n 2 " + expr = Mul(S.One, x + y, evaluate=False) + assert pretty(expr) == "1*(x + y)" + assert upretty(expr) == "1⋅(x + y)" + expr = Mul(x - y, S.One, evaluate=False) + assert pretty(expr) == "(x - y)*1" + assert upretty(expr) == "(x - y)⋅1" + expr = Mul(Rational(1, 2), x - y, S.One, x + y, evaluate=False) + assert pretty(expr) == "1/2*(x - y)*1*(x + y)" + assert upretty(expr) == "1/2⋅(x - y)⋅1⋅(x + y)" + expr = Mul(x + y, Rational(3, 4), S.One, y - z, evaluate=False) + assert pretty(expr) == "(x + y)*3/4*1*(y - z)" + assert upretty(expr) == "(x + y)⋅3/4⋅1⋅(y - z)" + expr = Mul(x + y, Rational(1, 1), Rational(3, 4), Rational(5, 6),evaluate=False) + assert pretty(expr) == "(x + y)*1*3/4*5/6" + assert upretty(expr) == "(x + y)⋅1⋅3/4⋅5/6" + expr = Mul(Rational(3, 4), x + y, S.One, y - z, evaluate=False) + assert pretty(expr) == "3/4*(x + y)*1*(y - z)" + assert upretty(expr) == "3/4⋅(x + y)⋅1⋅(y - z)" + + +def test_issue_5524(): + assert pretty(-(-x + 5)*(-x - 2*sqrt(2) + 5) - (-y + 5)*(-y + 5)) == \ +"""\ + 2 / ___ \\\n\ +- (5 - y) + (x - 5)*\\-x - 2*\\/ 2 + 5/\ +""" + + assert upretty(-(-x + 5)*(-x - 2*sqrt(2) + 5) - (-y + 5)*(-y + 5)) == \ +"""\ + 2 \n\ +- (5 - y) + (x - 5)⋅(-x - 2⋅√2 + 5)\ +""" + + +def test_pretty_ordering(): + assert pretty(x**2 + x + 1, order='lex') == \ +"""\ + 2 \n\ +x + x + 1\ +""" + assert pretty(x**2 + x + 1, order='rev-lex') == \ +"""\ + 2\n\ +1 + x + x \ +""" + assert pretty(1 - x, order='lex') == '-x + 1' + assert pretty(1 - x, order='rev-lex') == '1 - x' + + assert pretty(1 - 2*x, order='lex') == '-2*x + 1' + assert pretty(1 - 2*x, order='rev-lex') == '1 - 2*x' + + f = 2*x**4 + y**2 - x**2 + y**3 + assert pretty(f, order=None) == \ +"""\ + 4 2 3 2\n\ +2*x - x + y + y \ +""" + assert pretty(f, order='lex') == \ +"""\ + 4 2 3 2\n\ +2*x - x + y + y \ +""" + assert pretty(f, order='rev-lex') == \ +"""\ + 2 3 2 4\n\ +y + y - x + 2*x \ +""" + + expr = x - x**3/6 + x**5/120 + O(x**6) + ascii_str = \ +"""\ + 3 5 \n\ + x x / 6\\\n\ +x - -- + --- + O\\x /\n\ + 6 120 \ +""" + ucode_str = \ +"""\ + 3 5 \n\ + x x ⎛ 6⎞\n\ +x - ── + ─── + O⎝x ⎠\n\ + 6 120 \ +""" + assert pretty(expr, order=None) == ascii_str + assert upretty(expr, order=None) == ucode_str + + assert pretty(expr, order='lex') == ascii_str + assert upretty(expr, order='lex') == ucode_str + + assert pretty(expr, order='rev-lex') == ascii_str + assert upretty(expr, order='rev-lex') == ucode_str + + +def test_EulerGamma(): + assert pretty(EulerGamma) == str(EulerGamma) == "EulerGamma" + assert upretty(EulerGamma) == "γ" + + +def test_GoldenRatio(): + assert pretty(GoldenRatio) == str(GoldenRatio) == "GoldenRatio" + assert upretty(GoldenRatio) == "φ" + + +def test_Catalan(): + assert pretty(Catalan) == upretty(Catalan) == "G" + + +def test_pretty_relational(): + expr = Eq(x, y) + ascii_str = \ +"""\ +x = y\ +""" + ucode_str = \ +"""\ +x = y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Lt(x, y) + ascii_str = \ +"""\ +x < y\ +""" + ucode_str = \ +"""\ +x < y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Gt(x, y) + ascii_str = \ +"""\ +x > y\ +""" + ucode_str = \ +"""\ +x > y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Le(x, y) + ascii_str = \ +"""\ +x <= y\ +""" + ucode_str = \ +"""\ +x ≤ y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Ge(x, y) + ascii_str = \ +"""\ +x >= y\ +""" + ucode_str = \ +"""\ +x ≥ y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Ne(x/(y + 1), y**2) + ascii_str_1 = \ +"""\ + x 2\n\ +----- != y \n\ +1 + y \ +""" + ascii_str_2 = \ +"""\ + x 2\n\ +----- != y \n\ +y + 1 \ +""" + ucode_str_1 = \ +"""\ + x 2\n\ +───── ≠ y \n\ +1 + y \ +""" + ucode_str_2 = \ +"""\ + x 2\n\ +───── ≠ y \n\ +y + 1 \ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + +def test_Assignment(): + expr = Assignment(x, y) + ascii_str = \ +"""\ +x := y\ +""" + ucode_str = \ +"""\ +x := y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_AugmentedAssignment(): + expr = AddAugmentedAssignment(x, y) + ascii_str = \ +"""\ +x += y\ +""" + ucode_str = \ +"""\ +x += y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = SubAugmentedAssignment(x, y) + ascii_str = \ +"""\ +x -= y\ +""" + ucode_str = \ +"""\ +x -= y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = MulAugmentedAssignment(x, y) + ascii_str = \ +"""\ +x *= y\ +""" + ucode_str = \ +"""\ +x *= y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = DivAugmentedAssignment(x, y) + ascii_str = \ +"""\ +x /= y\ +""" + ucode_str = \ +"""\ +x /= y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = ModAugmentedAssignment(x, y) + ascii_str = \ +"""\ +x %= y\ +""" + ucode_str = \ +"""\ +x %= y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_rational(): + expr = y*x**-2 + ascii_str = \ +"""\ +y \n\ +--\n\ + 2\n\ +x \ +""" + ucode_str = \ +"""\ +y \n\ +──\n\ + 2\n\ +x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = y**Rational(3, 2) * x**Rational(-5, 2) + ascii_str = \ +"""\ + 3/2\n\ +y \n\ +----\n\ + 5/2\n\ +x \ +""" + ucode_str = \ +"""\ + 3/2\n\ +y \n\ +────\n\ + 5/2\n\ +x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = sin(x)**3/tan(x)**2 + ascii_str = \ +"""\ + 3 \n\ +sin (x)\n\ +-------\n\ + 2 \n\ +tan (x)\ +""" + ucode_str = \ +"""\ + 3 \n\ +sin (x)\n\ +───────\n\ + 2 \n\ +tan (x)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +@_both_exp_pow +def test_pretty_functions(): + """Tests for Abs, conjugate, exp, function braces, and factorial.""" + expr = (2*x + exp(x)) + ascii_str_1 = \ +"""\ + x\n\ +2*x + e \ +""" + ascii_str_2 = \ +"""\ + x \n\ +e + 2*x\ +""" + ucode_str_1 = \ +"""\ + x\n\ +2⋅x + ℯ \ +""" + ucode_str_2 = \ +"""\ + x \n\ +ℯ + 2⋅x\ +""" + ucode_str_3 = \ +"""\ + x \n\ +ℯ + 2⋅x\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2, ucode_str_3] + + expr = Abs(x) + ascii_str = \ +"""\ +|x|\ +""" + ucode_str = \ +"""\ +│x│\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Abs(x/(x**2 + 1)) + ascii_str_1 = \ +"""\ +| x |\n\ +|------|\n\ +| 2|\n\ +|1 + x |\ +""" + ascii_str_2 = \ +"""\ +| x |\n\ +|------|\n\ +| 2 |\n\ +|x + 1|\ +""" + ucode_str_1 = \ +"""\ +│ x │\n\ +│──────│\n\ +│ 2│\n\ +│1 + x │\ +""" + ucode_str_2 = \ +"""\ +│ x │\n\ +│──────│\n\ +│ 2 │\n\ +│x + 1│\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = Abs(1 / (y - Abs(x))) + ascii_str = \ +"""\ + 1 \n\ +---------\n\ +|y - |x||\ +""" + ucode_str = \ +"""\ + 1 \n\ +─────────\n\ +│y - │x││\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + n = Symbol('n', integer=True) + expr = factorial(n) + ascii_str = \ +"""\ +n!\ +""" + ucode_str = \ +"""\ +n!\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = factorial(2*n) + ascii_str = \ +"""\ +(2*n)!\ +""" + ucode_str = \ +"""\ +(2⋅n)!\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = factorial(factorial(factorial(n))) + ascii_str = \ +"""\ +((n!)!)!\ +""" + ucode_str = \ +"""\ +((n!)!)!\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = factorial(n + 1) + ascii_str_1 = \ +"""\ +(1 + n)!\ +""" + ascii_str_2 = \ +"""\ +(n + 1)!\ +""" + ucode_str_1 = \ +"""\ +(1 + n)!\ +""" + ucode_str_2 = \ +"""\ +(n + 1)!\ +""" + + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = subfactorial(n) + ascii_str = \ +"""\ +!n\ +""" + ucode_str = \ +"""\ +!n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = subfactorial(2*n) + ascii_str = \ +"""\ +!(2*n)\ +""" + ucode_str = \ +"""\ +!(2⋅n)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + n = Symbol('n', integer=True) + expr = factorial2(n) + ascii_str = \ +"""\ +n!!\ +""" + ucode_str = \ +"""\ +n!!\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = factorial2(2*n) + ascii_str = \ +"""\ +(2*n)!!\ +""" + ucode_str = \ +"""\ +(2⋅n)!!\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = factorial2(factorial2(factorial2(n))) + ascii_str = \ +"""\ +((n!!)!!)!!\ +""" + ucode_str = \ +"""\ +((n!!)!!)!!\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = factorial2(n + 1) + ascii_str_1 = \ +"""\ +(1 + n)!!\ +""" + ascii_str_2 = \ +"""\ +(n + 1)!!\ +""" + ucode_str_1 = \ +"""\ +(1 + n)!!\ +""" + ucode_str_2 = \ +"""\ +(n + 1)!!\ +""" + + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = 2*binomial(n, k) + ascii_str = \ +"""\ + /n\\\n\ +2*| |\n\ + \\k/\ +""" + ucode_str = \ +"""\ + ⎛n⎞\n\ +2⋅⎜ ⎟\n\ + ⎝k⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 2*binomial(2*n, k) + ascii_str = \ +"""\ + /2*n\\\n\ +2*| |\n\ + \\ k /\ +""" + ucode_str = \ +"""\ + ⎛2⋅n⎞\n\ +2⋅⎜ ⎟\n\ + ⎝ k ⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 2*binomial(n**2, k) + ascii_str = \ +"""\ + / 2\\\n\ + |n |\n\ +2*| |\n\ + \\k /\ +""" + ucode_str = \ +"""\ + ⎛ 2⎞\n\ + ⎜n ⎟\n\ +2⋅⎜ ⎟\n\ + ⎝k ⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = catalan(n) + ascii_str = \ +"""\ +C \n\ + n\ +""" + ucode_str = \ +"""\ +C \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = catalan(n) + ascii_str = \ +"""\ +C \n\ + n\ +""" + ucode_str = \ +"""\ +C \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = bell(n) + ascii_str = \ +"""\ +B \n\ + n\ +""" + ucode_str = \ +"""\ +B \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = bernoulli(n) + ascii_str = \ +"""\ +B \n\ + n\ +""" + ucode_str = \ +"""\ +B \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = bernoulli(n, x) + ascii_str = \ +"""\ +B (x)\n\ + n \ +""" + ucode_str = \ +"""\ +B (x)\n\ + n \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = fibonacci(n) + ascii_str = \ +"""\ +F \n\ + n\ +""" + ucode_str = \ +"""\ +F \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = lucas(n) + ascii_str = \ +"""\ +L \n\ + n\ +""" + ucode_str = \ +"""\ +L \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = tribonacci(n) + ascii_str = \ +"""\ +T \n\ + n\ +""" + ucode_str = \ +"""\ +T \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = stieltjes(n) + ascii_str = \ +"""\ +stieltjes \n\ + n\ +""" + ucode_str = \ +"""\ +γ \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = stieltjes(n, x) + ascii_str = \ +"""\ +stieltjes (x)\n\ + n \ +""" + ucode_str = \ +"""\ +γ (x)\n\ + n \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = mathieuc(x, y, z) + ascii_str = 'C(x, y, z)' + ucode_str = 'C(x, y, z)' + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = mathieus(x, y, z) + ascii_str = 'S(x, y, z)' + ucode_str = 'S(x, y, z)' + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = mathieucprime(x, y, z) + ascii_str = "C'(x, y, z)" + ucode_str = "C'(x, y, z)" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = mathieusprime(x, y, z) + ascii_str = "S'(x, y, z)" + ucode_str = "S'(x, y, z)" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = conjugate(x) + ascii_str = \ +"""\ +_\n\ +x\ +""" + ucode_str = \ +"""\ +_\n\ +x\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + f = Function('f') + expr = conjugate(f(x + 1)) + ascii_str_1 = \ +"""\ +________\n\ +f(1 + x)\ +""" + ascii_str_2 = \ +"""\ +________\n\ +f(x + 1)\ +""" + ucode_str_1 = \ +"""\ +________\n\ +f(1 + x)\ +""" + ucode_str_2 = \ +"""\ +________\n\ +f(x + 1)\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = f(x) + ascii_str = \ +"""\ +f(x)\ +""" + ucode_str = \ +"""\ +f(x)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = f(x, y) + ascii_str = \ +"""\ +f(x, y)\ +""" + ucode_str = \ +"""\ +f(x, y)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = f(x/(y + 1), y) + ascii_str_1 = \ +"""\ + / x \\\n\ +f|-----, y|\n\ + \\1 + y /\ +""" + ascii_str_2 = \ +"""\ + / x \\\n\ +f|-----, y|\n\ + \\y + 1 /\ +""" + ucode_str_1 = \ +"""\ + ⎛ x ⎞\n\ +f⎜─────, y⎟\n\ + ⎝1 + y ⎠\ +""" + ucode_str_2 = \ +"""\ + ⎛ x ⎞\n\ +f⎜─────, y⎟\n\ + ⎝y + 1 ⎠\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = f(x**x**x**x**x**x) + ascii_str = \ +"""\ + / / / / / x\\\\\\\\\\ + | | | | \\x /|||| + | | | \\x /||| + | | \\x /|| + | \\x /| +f\\x /\ +""" + ucode_str = \ +"""\ + ⎛ ⎛ ⎛ ⎛ ⎛ x⎞⎞⎞⎞⎞ + ⎜ ⎜ ⎜ ⎜ ⎝x ⎠⎟⎟⎟⎟ + ⎜ ⎜ ⎜ ⎝x ⎠⎟⎟⎟ + ⎜ ⎜ ⎝x ⎠⎟⎟ + ⎜ ⎝x ⎠⎟ +f⎝x ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = sin(x)**2 + ascii_str = \ +"""\ + 2 \n\ +sin (x)\ +""" + ucode_str = \ +"""\ + 2 \n\ +sin (x)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = conjugate(a + b*I) + ascii_str = \ +"""\ +_ _\n\ +a - I*b\ +""" + ucode_str = \ +"""\ +_ _\n\ +a - ⅈ⋅b\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = conjugate(exp(a + b*I)) + ascii_str = \ +"""\ + _ _\n\ + a - I*b\n\ +e \ +""" + ucode_str = \ +"""\ + _ _\n\ + a - ⅈ⋅b\n\ +ℯ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = conjugate( f(1 + conjugate(f(x))) ) + ascii_str_1 = \ +"""\ +___________\n\ + / ____\\\n\ +f\\1 + f(x)/\ +""" + ascii_str_2 = \ +"""\ +___________\n\ + /____ \\\n\ +f\\f(x) + 1/\ +""" + ucode_str_1 = \ +"""\ +___________\n\ + ⎛ ____⎞\n\ +f⎝1 + f(x)⎠\ +""" + ucode_str_2 = \ +"""\ +___________\n\ + ⎛____ ⎞\n\ +f⎝f(x) + 1⎠\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = f(x/(y + 1), y) + ascii_str_1 = \ +"""\ + / x \\\n\ +f|-----, y|\n\ + \\1 + y /\ +""" + ascii_str_2 = \ +"""\ + / x \\\n\ +f|-----, y|\n\ + \\y + 1 /\ +""" + ucode_str_1 = \ +"""\ + ⎛ x ⎞\n\ +f⎜─────, y⎟\n\ + ⎝1 + y ⎠\ +""" + ucode_str_2 = \ +"""\ + ⎛ x ⎞\n\ +f⎜─────, y⎟\n\ + ⎝y + 1 ⎠\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = floor(1 / (y - floor(x))) + ascii_str = \ +"""\ + / 1 \\\n\ +floor|------------|\n\ + \\y - floor(x)/\ +""" + ucode_str = \ +"""\ +⎢ 1 ⎥\n\ +⎢───────⎥\n\ +⎣y - ⌊x⌋⎦\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = ceiling(1 / (y - ceiling(x))) + ascii_str = \ +"""\ + / 1 \\\n\ +ceiling|--------------|\n\ + \\y - ceiling(x)/\ +""" + ucode_str = \ +"""\ +⎡ 1 ⎤\n\ +⎢───────⎥\n\ +⎢y - ⌈x⌉⎥\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = euler(n) + ascii_str = \ +"""\ +E \n\ + n\ +""" + ucode_str = \ +"""\ +E \n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = euler(1/(1 + 1/(1 + 1/n))) + ascii_str = \ +"""\ +E \n\ + 1 \n\ + ---------\n\ + 1 \n\ + 1 + -----\n\ + 1\n\ + 1 + -\n\ + n\ +""" + + ucode_str = \ +"""\ +E \n\ + 1 \n\ + ─────────\n\ + 1 \n\ + 1 + ─────\n\ + 1\n\ + 1 + ─\n\ + n\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = euler(n, x) + ascii_str = \ +"""\ +E (x)\n\ + n \ +""" + ucode_str = \ +"""\ +E (x)\n\ + n \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = euler(n, x/2) + ascii_str = \ +"""\ + /x\\\n\ +E |-|\n\ + n\\2/\ +""" + ucode_str = \ +"""\ + ⎛x⎞\n\ +E ⎜─⎟\n\ + n⎝2⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_sqrt(): + expr = sqrt(2) + ascii_str = \ +"""\ + ___\n\ +\\/ 2 \ +""" + ucode_str = \ +"√2" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 2**Rational(1, 3) + ascii_str = \ +"""\ +3 ___\n\ +\\/ 2 \ +""" + ucode_str = \ +"""\ +3 ___\n\ +╲╱ 2 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 2**Rational(1, 1000) + ascii_str = \ +"""\ +1000___\n\ + \\/ 2 \ +""" + ucode_str = \ +"""\ +1000___\n\ + ╲╱ 2 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = sqrt(x**2 + 1) + ascii_str = \ +"""\ + ________\n\ + / 2 \n\ +\\/ x + 1 \ +""" + ucode_str = \ +"""\ + ________\n\ + ╱ 2 \n\ +╲╱ x + 1 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (1 + sqrt(5))**Rational(1, 3) + ascii_str = \ +"""\ + ___________\n\ +3 / ___ \n\ +\\/ 1 + \\/ 5 \ +""" + ucode_str = \ +"""\ +3 ________\n\ +╲╱ 1 + √5 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 2**(1/x) + ascii_str = \ +"""\ +x ___\n\ +\\/ 2 \ +""" + ucode_str = \ +"""\ +x ___\n\ +╲╱ 2 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = sqrt(2 + pi) + ascii_str = \ +"""\ + ________\n\ +\\/ 2 + pi \ +""" + ucode_str = \ +"""\ + _______\n\ +╲╱ 2 + π \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (2 + ( + 1 + x**2)/(2 + x))**Rational(1, 4) + (1 + x**Rational(1, 1000))/sqrt(3 + x**2) + ascii_str = \ +"""\ + ____________ \n\ + / 2 1000___ \n\ + / x + 1 \\/ x + 1\n\ +4 / 2 + ------ + -----------\n\ +\\/ x + 2 ________\n\ + / 2 \n\ + \\/ x + 3 \ +""" + ucode_str = \ +"""\ + ____________ \n\ + ╱ 2 1000___ \n\ + ╱ x + 1 ╲╱ x + 1\n\ +4 ╱ 2 + ────── + ───────────\n\ +╲╱ x + 2 ________\n\ + ╱ 2 \n\ + ╲╱ x + 3 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_sqrt_char_knob(): + # See PR #9234. + expr = sqrt(2) + ucode_str1 = \ +"""\ + ___\n\ +╲╱ 2 \ +""" + ucode_str2 = \ +"√2" + assert xpretty(expr, use_unicode=True, + use_unicode_sqrt_char=False) == ucode_str1 + assert xpretty(expr, use_unicode=True, + use_unicode_sqrt_char=True) == ucode_str2 + + +def test_pretty_sqrt_longsymbol_no_sqrt_char(): + # Do not use unicode sqrt char for long symbols (see PR #9234). + expr = sqrt(Symbol('C1')) + ucode_str = \ +"""\ + ____\n\ +╲╱ C₁ \ +""" + assert upretty(expr) == ucode_str + + +def test_pretty_KroneckerDelta(): + x, y = symbols("x, y") + expr = KroneckerDelta(x, y) + ascii_str = \ +"""\ +d \n\ + x,y\ +""" + ucode_str = \ +"""\ +δ \n\ + x,y\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_product(): + n, m, k, l = symbols('n m k l') + f = symbols('f', cls=Function) + expr = Product(f((n/3)**2), (n, k**2, l)) + + unicode_str = \ +"""\ + l \n\ +─┬──────┬─ \n\ + │ │ ⎛ 2⎞\n\ + │ │ ⎜n ⎟\n\ + │ │ f⎜──⎟\n\ + │ │ ⎝9 ⎠\n\ + │ │ \n\ + 2 \n\ + n = k """ + ascii_str = \ +"""\ + l \n\ +__________ \n\ + | | / 2\\\n\ + | | |n |\n\ + | | f|--|\n\ + | | \\9 /\n\ + | | \n\ + 2 \n\ + n = k """ + + expr = Product(f((n/3)**2), (n, k**2, l), (l, 1, m)) + + unicode_str = \ +"""\ + m l \n\ +─┬──────┬─ ─┬──────┬─ \n\ + │ │ │ │ ⎛ 2⎞\n\ + │ │ │ │ ⎜n ⎟\n\ + │ │ │ │ f⎜──⎟\n\ + │ │ │ │ ⎝9 ⎠\n\ + │ │ │ │ \n\ + l = 1 2 \n\ + n = k """ + ascii_str = \ +"""\ + m l \n\ +__________ __________ \n\ + | | | | / 2\\\n\ + | | | | |n |\n\ + | | | | f|--|\n\ + | | | | \\9 /\n\ + | | | | \n\ + l = 1 2 \n\ + n = k """ + + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + + +def test_pretty_Lambda(): + # S.IdentityFunction is a special case + expr = Lambda(y, y) + assert pretty(expr) == "x -> x" + assert upretty(expr) == "x ↦ x" + + expr = Lambda(x, x+1) + assert pretty(expr) == "x -> x + 1" + assert upretty(expr) == "x ↦ x + 1" + + expr = Lambda(x, x**2) + ascii_str = \ +"""\ + 2\n\ +x -> x \ +""" + ucode_str = \ +"""\ + 2\n\ +x ↦ x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Lambda(x, x**2)**2 + ascii_str = \ +"""\ + 2 +/ 2\\ \n\ +\\x -> x / \ +""" + ucode_str = \ +"""\ + 2 +⎛ 2⎞ \n\ +⎝x ↦ x ⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Lambda((x, y), x) + ascii_str = "(x, y) -> x" + ucode_str = "(x, y) ↦ x" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Lambda((x, y), x**2) + ascii_str = \ +"""\ + 2\n\ +(x, y) -> x \ +""" + ucode_str = \ +"""\ + 2\n\ +(x, y) ↦ x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Lambda(((x, y),), x**2) + ascii_str = \ +"""\ + 2\n\ +((x, y),) -> x \ +""" + ucode_str = \ +"""\ + 2\n\ +((x, y),) ↦ x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_TransferFunction(): + tf1 = TransferFunction(s - 1, s + 1, s) + assert upretty(tf1) == "s - 1\n─────\ns + 1" + tf2 = TransferFunction(2*s + 1, 3 - p, s) + assert upretty(tf2) == "2⋅s + 1\n───────\n 3 - p " + tf3 = TransferFunction(p, p + 1, p) + assert upretty(tf3) == " p \n─────\np + 1" + + +def test_pretty_Series(): + tf1 = TransferFunction(x + y, x - 2*y, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(x**2 + y, y - x, y) + tf4 = TransferFunction(2, 3, y) + + tfm1 = TransferFunctionMatrix([[tf1, tf2], [tf3, tf4]]) + tfm2 = TransferFunctionMatrix([[tf3], [-tf4]]) + tfm3 = TransferFunctionMatrix([[tf1, -tf2, -tf3], [tf3, -tf4, tf2]]) + tfm4 = TransferFunctionMatrix([[tf1, tf2], [tf3, -tf4], [-tf2, -tf1]]) + tfm5 = TransferFunctionMatrix([[-tf2, -tf1], [tf4, -tf3], [tf1, tf2]]) + + expected1 = \ +"""\ + ⎛ 2 ⎞\n\ +⎛ x + y ⎞ ⎜x + y⎟\n\ +⎜───────⎟⋅⎜──────⎟\n\ +⎝x - 2⋅y⎠ ⎝-x + y⎠\ +""" + expected2 = \ +"""\ +⎛-x + y⎞ ⎛-x - y ⎞\n\ +⎜──────⎟⋅⎜───────⎟\n\ +⎝x + y ⎠ ⎝x - 2⋅y⎠\ +""" + expected3 = \ +"""\ +⎛ 2 ⎞ \n\ +⎜x + y⎟ ⎛ x + y ⎞ ⎛-x - y x - y⎞\n\ +⎜──────⎟⋅⎜───────⎟⋅⎜─────── + ─────⎟\n\ +⎝-x + y⎠ ⎝x - 2⋅y⎠ ⎝x - 2⋅y x + y⎠\ +""" + expected4 = \ +"""\ + ⎛ 2 ⎞\n\ +⎛ x + y x - y⎞ ⎜x - y x + y⎟\n\ +⎜─────── + ─────⎟⋅⎜───── + ──────⎟\n\ +⎝x - 2⋅y x + y⎠ ⎝x + y -x + y⎠\ +""" + expected5 = \ +"""\ +⎡ x + y x - y⎤ ⎡ 2 ⎤ \n\ +⎢─────── ─────⎥ ⎢x + y⎥ \n\ +⎢x - 2⋅y x + y⎥ ⎢──────⎥ \n\ +⎢ ⎥ ⎢-x + y⎥ \n\ +⎢ 2 ⎥ ⋅⎢ ⎥ \n\ +⎢x + y 2 ⎥ ⎢ -2 ⎥ \n\ +⎢────── ─ ⎥ ⎢ ─── ⎥ \n\ +⎣-x + y 3 ⎦τ ⎣ 3 ⎦τ\ +""" + expected6 = \ +"""\ + ⎛⎡ x + y x - y ⎤ ⎡ x - y x + y ⎤ ⎞\n\ + ⎜⎢─────── ───── ⎥ ⎢ ───── ───────⎥ ⎟\n\ +⎡ x + y x - y⎤ ⎡ 2 ⎤ ⎜⎢x - 2⋅y x + y ⎥ ⎢ x + y x - 2⋅y⎥ ⎟\n\ +⎢─────── ─────⎥ ⎢ x + y -x + y - x - y⎥ ⎜⎢ ⎥ ⎢ ⎥ ⎟\n\ +⎢x - 2⋅y x + y⎥ ⎢─────── ────── ────────⎥ ⎜⎢ 2 ⎥ ⎢ 2 ⎥ ⎟\n\ +⎢ ⎥ ⎢x - 2⋅y x + y -x + y ⎥ ⎜⎢x + y -2 ⎥ ⎢ -2 x + y ⎥ ⎟\n\ +⎢ 2 ⎥ ⋅⎢ ⎥ ⋅⎜⎢────── ─── ⎥ + ⎢ ─── ────── ⎥ ⎟\n\ +⎢x + y 2 ⎥ ⎢ 2 ⎥ ⎜⎢-x + y 3 ⎥ ⎢ 3 -x + y ⎥ ⎟\n\ +⎢────── ─ ⎥ ⎢x + y -2 x - y ⎥ ⎜⎢ ⎥ ⎢ ⎥ ⎟\n\ +⎣-x + y 3 ⎦τ ⎢────── ─── ───── ⎥ ⎜⎢-x + y -x - y ⎥ ⎢-x - y -x + y ⎥ ⎟\n\ + ⎣-x + y 3 x + y ⎦τ ⎜⎢────── ───────⎥ ⎢─────── ────── ⎥ ⎟\n\ + ⎝⎣x + y x - 2⋅y⎦τ ⎣x - 2⋅y x + y ⎦τ⎠\ +""" + + assert upretty(Series(tf1, tf3)) == expected1 + assert upretty(Series(-tf2, -tf1)) == expected2 + assert upretty(Series(tf3, tf1, Parallel(-tf1, tf2))) == expected3 + assert upretty(Series(Parallel(tf1, tf2), Parallel(tf2, tf3))) == expected4 + assert upretty(MIMOSeries(tfm2, tfm1)) == expected5 + assert upretty(MIMOSeries(MIMOParallel(tfm4, -tfm5), tfm3, tfm1)) == expected6 + + +def test_pretty_Parallel(): + tf1 = TransferFunction(x + y, x - 2*y, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(x**2 + y, y - x, y) + tf4 = TransferFunction(y**2 - x, x**3 + x, y) + + tfm1 = TransferFunctionMatrix([[tf1, tf2], [tf3, -tf4], [-tf2, -tf1]]) + tfm2 = TransferFunctionMatrix([[-tf2, -tf1], [tf4, -tf3], [tf1, tf2]]) + tfm3 = TransferFunctionMatrix([[-tf1, tf2], [-tf3, tf4], [tf2, tf1]]) + tfm4 = TransferFunctionMatrix([[-tf1, -tf2], [-tf3, -tf4]]) + + expected1 = \ +"""\ + x + y x - y\n\ +─────── + ─────\n\ +x - 2⋅y x + y\ +""" + expected2 = \ +"""\ +-x + y -x - y \n\ +────── + ─────── +x + y x - 2⋅y\ +""" + expected3 = \ +"""\ + 2 \n\ +x + y x + y ⎛-x - y ⎞ ⎛x - y⎞ +────── + ─────── + ⎜───────⎟⋅⎜─────⎟ +-x + y x - 2⋅y ⎝x - 2⋅y⎠ ⎝x + y⎠\ +""" + + expected4 = \ +"""\ + ⎛ 2 ⎞\n\ +⎛ x + y ⎞ ⎛x - y⎞ ⎛x - y⎞ ⎜x + y⎟\n\ +⎜───────⎟⋅⎜─────⎟ + ⎜─────⎟⋅⎜──────⎟\n\ +⎝x - 2⋅y⎠ ⎝x + y⎠ ⎝x + y⎠ ⎝-x + y⎠\ +""" + expected5 = \ +"""\ +⎡ x + y -x + y ⎤ ⎡ x - y x + y ⎤ ⎡ x + y x - y ⎤ \n\ +⎢─────── ────── ⎥ ⎢ ───── ───────⎥ ⎢─────── ───── ⎥ \n\ +⎢x - 2⋅y x + y ⎥ ⎢ x + y x - 2⋅y⎥ ⎢x - 2⋅y x + y ⎥ \n\ +⎢ ⎥ ⎢ ⎥ ⎢ ⎥ \n\ +⎢ 2 2 ⎥ ⎢ 2 2 ⎥ ⎢ 2 2 ⎥ \n\ +⎢x + y x - y ⎥ ⎢x - y x + y ⎥ ⎢x + y x - y ⎥ \n\ +⎢────── ────── ⎥ + ⎢────── ────── ⎥ + ⎢────── ────── ⎥ \n\ +⎢-x + y 3 ⎥ ⎢ 3 -x + y ⎥ ⎢-x + y 3 ⎥ \n\ +⎢ x + x ⎥ ⎢x + x ⎥ ⎢ x + x ⎥ \n\ +⎢ ⎥ ⎢ ⎥ ⎢ ⎥ \n\ +⎢-x + y -x - y ⎥ ⎢-x - y -x + y ⎥ ⎢-x + y -x - y ⎥ \n\ +⎢────── ───────⎥ ⎢─────── ────── ⎥ ⎢────── ───────⎥ \n\ +⎣x + y x - 2⋅y⎦τ ⎣x - 2⋅y x + y ⎦τ ⎣x + y x - 2⋅y⎦τ\ +""" + expected6 = \ +"""\ +⎡ x - y x + y ⎤ ⎡-x + y -x - y ⎤ \n\ +⎢ ───── ───────⎥ ⎢────── ─────── ⎥ \n\ +⎢ x + y x - 2⋅y⎥ ⎡-x - y -x + y⎤ ⎢x + y x - 2⋅y ⎥ \n\ +⎢ ⎥ ⎢─────── ──────⎥ ⎢ ⎥ \n\ +⎢ 2 2 ⎥ ⎢x - 2⋅y x + y ⎥ ⎢ 2 2 ⎥ \n\ +⎢x - y x + y ⎥ ⎢ ⎥ ⎢-x + y - x - y⎥ \n\ +⎢────── ────── ⎥ ⋅⎢ 2 2⎥ + ⎢─────── ────────⎥ \n\ +⎢ 3 -x + y ⎥ ⎢- x - y x - y ⎥ ⎢ 3 -x + y ⎥ \n\ +⎢x + x ⎥ ⎢──────── ──────⎥ ⎢x + x ⎥ \n\ +⎢ ⎥ ⎢ -x + y 3 ⎥ ⎢ ⎥ \n\ +⎢-x - y -x + y ⎥ ⎣ x + x⎦τ ⎢ x + y x - y ⎥ \n\ +⎢─────── ────── ⎥ ⎢─────── ───── ⎥ \n\ +⎣x - 2⋅y x + y ⎦τ ⎣x - 2⋅y x + y ⎦τ\ +""" + assert upretty(Parallel(tf1, tf2)) == expected1 + assert upretty(Parallel(-tf2, -tf1)) == expected2 + assert upretty(Parallel(tf3, tf1, Series(-tf1, tf2))) == expected3 + assert upretty(Parallel(Series(tf1, tf2), Series(tf2, tf3))) == expected4 + assert upretty(MIMOParallel(-tfm3, -tfm2, tfm1)) == expected5 + assert upretty(MIMOParallel(MIMOSeries(tfm4, -tfm2), tfm2)) == expected6 + + +def test_pretty_Feedback(): + tf = TransferFunction(1, 1, y) + tf1 = TransferFunction(x + y, x - 2*y, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(y**2 - 2*y + 1, y + 5, y) + tf4 = TransferFunction(x - 2*y**3, x + y, x) + tf5 = TransferFunction(1 - x, x - y, y) + tf6 = TransferFunction(2, 2, x) + expected1 = \ +"""\ + ⎛1⎞ \n\ + ⎜─⎟ \n\ + ⎝1⎠ \n\ +─────────────\n\ +1 ⎛ x + y ⎞\n\ +─ + ⎜───────⎟\n\ +1 ⎝x - 2⋅y⎠\ +""" + expected2 = \ +"""\ + ⎛1⎞ \n\ + ⎜─⎟ \n\ + ⎝1⎠ \n\ +────────────────────────────────────\n\ + ⎛ 2 ⎞\n\ +1 ⎛x - y⎞ ⎛ x + y ⎞ ⎜y - 2⋅y + 1⎟\n\ +─ + ⎜─────⎟⋅⎜───────⎟⋅⎜────────────⎟\n\ +1 ⎝x + y⎠ ⎝x - 2⋅y⎠ ⎝ y + 5 ⎠\ +""" + expected3 = \ +"""\ + ⎛ x + y ⎞ \n\ + ⎜───────⎟ \n\ + ⎝x - 2⋅y⎠ \n\ +────────────────────────────────────────────\n\ + ⎛ 2 ⎞ \n\ +1 ⎛ x + y ⎞ ⎛x - y⎞ ⎜y - 2⋅y + 1⎟ ⎛1 - x⎞\n\ +─ + ⎜───────⎟⋅⎜─────⎟⋅⎜────────────⎟⋅⎜─────⎟\n\ +1 ⎝x - 2⋅y⎠ ⎝x + y⎠ ⎝ y + 5 ⎠ ⎝x - y⎠\ +""" + expected4 = \ +"""\ + ⎛ x + y ⎞ ⎛x - y⎞ \n\ + ⎜───────⎟⋅⎜─────⎟ \n\ + ⎝x - 2⋅y⎠ ⎝x + y⎠ \n\ +─────────────────────\n\ +1 ⎛ x + y ⎞ ⎛x - y⎞\n\ +─ + ⎜───────⎟⋅⎜─────⎟\n\ +1 ⎝x - 2⋅y⎠ ⎝x + y⎠\ +""" + expected5 = \ +"""\ + ⎛ x + y ⎞ ⎛x - y⎞ \n\ + ⎜───────⎟⋅⎜─────⎟ \n\ + ⎝x - 2⋅y⎠ ⎝x + y⎠ \n\ +─────────────────────────────\n\ +1 ⎛ x + y ⎞ ⎛x - y⎞ ⎛1 - x⎞\n\ +─ + ⎜───────⎟⋅⎜─────⎟⋅⎜─────⎟\n\ +1 ⎝x - 2⋅y⎠ ⎝x + y⎠ ⎝x - y⎠\ +""" + expected6 = \ +"""\ + ⎛ 2 ⎞ \n\ + ⎜y - 2⋅y + 1⎟ ⎛1 - x⎞ \n\ + ⎜────────────⎟⋅⎜─────⎟ \n\ + ⎝ y + 5 ⎠ ⎝x - y⎠ \n\ +────────────────────────────────────────────\n\ + ⎛ 2 ⎞ \n\ +1 ⎜y - 2⋅y + 1⎟ ⎛1 - x⎞ ⎛x - y⎞ ⎛ x + y ⎞\n\ +─ + ⎜────────────⎟⋅⎜─────⎟⋅⎜─────⎟⋅⎜───────⎟\n\ +1 ⎝ y + 5 ⎠ ⎝x - y⎠ ⎝x + y⎠ ⎝x - 2⋅y⎠\ +""" + expected7 = \ +"""\ + ⎛ 3⎞ \n\ + ⎜x - 2⋅y ⎟ \n\ + ⎜────────⎟ \n\ + ⎝ x + y ⎠ \n\ +──────────────────\n\ + ⎛ 3⎞ \n\ +1 ⎜x - 2⋅y ⎟ ⎛2⎞\n\ +─ + ⎜────────⎟⋅⎜─⎟\n\ +1 ⎝ x + y ⎠ ⎝2⎠\ +""" + expected8 = \ +"""\ + ⎛1 - x⎞ \n\ + ⎜─────⎟ \n\ + ⎝x - y⎠ \n\ +───────────\n\ +1 ⎛1 - x⎞\n\ +─ + ⎜─────⎟\n\ +1 ⎝x - y⎠\ +""" + expected9 = \ +"""\ + ⎛ x + y ⎞ ⎛x - y⎞ \n\ + ⎜───────⎟⋅⎜─────⎟ \n\ + ⎝x - 2⋅y⎠ ⎝x + y⎠ \n\ +─────────────────────────────\n\ +1 ⎛ x + y ⎞ ⎛x - y⎞ ⎛1 - x⎞\n\ +─ - ⎜───────⎟⋅⎜─────⎟⋅⎜─────⎟\n\ +1 ⎝x - 2⋅y⎠ ⎝x + y⎠ ⎝x - y⎠\ +""" + expected10 = \ +"""\ + ⎛1 - x⎞ \n\ + ⎜─────⎟ \n\ + ⎝x - y⎠ \n\ +───────────\n\ +1 ⎛1 - x⎞\n\ +─ - ⎜─────⎟\n\ +1 ⎝x - y⎠\ +""" + assert upretty(Feedback(tf, tf1)) == expected1 + assert upretty(Feedback(tf, tf2*tf1*tf3)) == expected2 + assert upretty(Feedback(tf1, tf2*tf3*tf5)) == expected3 + assert upretty(Feedback(tf1*tf2, tf)) == expected4 + assert upretty(Feedback(tf1*tf2, tf5)) == expected5 + assert upretty(Feedback(tf3*tf5, tf2*tf1)) == expected6 + assert upretty(Feedback(tf4, tf6)) == expected7 + assert upretty(Feedback(tf5, tf)) == expected8 + + assert upretty(Feedback(tf1*tf2, tf5, 1)) == expected9 + assert upretty(Feedback(tf5, tf, 1)) == expected10 + + +def test_pretty_MIMOFeedback(): + tf1 = TransferFunction(x + y, x - 2*y, y) + tf2 = TransferFunction(x - y, x + y, y) + tfm_1 = TransferFunctionMatrix([[tf1, tf2], [tf2, tf1]]) + tfm_2 = TransferFunctionMatrix([[tf2, tf1], [tf1, tf2]]) + tfm_3 = TransferFunctionMatrix([[tf1, tf1], [tf2, tf2]]) + + expected1 = \ +"""\ +⎛ ⎡ x + y x - y ⎤ ⎡ x - y x + y ⎤ ⎞-1 ⎡ x + y x - y ⎤ \n\ +⎜ ⎢─────── ───── ⎥ ⎢ ───── ───────⎥ ⎟ ⎢─────── ───── ⎥ \n\ +⎜ ⎢x - 2⋅y x + y ⎥ ⎢ x + y x - 2⋅y⎥ ⎟ ⎢x - 2⋅y x + y ⎥ \n\ +⎜I - ⎢ ⎥ ⋅⎢ ⎥ ⎟ ⋅ ⎢ ⎥ \n\ +⎜ ⎢ x - y x + y ⎥ ⎢ x + y x - y ⎥ ⎟ ⎢ x - y x + y ⎥ \n\ +⎜ ⎢ ───── ───────⎥ ⎢─────── ───── ⎥ ⎟ ⎢ ───── ───────⎥ \n\ +⎝ ⎣ x + y x - 2⋅y⎦τ ⎣x - 2⋅y x + y ⎦τ⎠ ⎣ x + y x - 2⋅y⎦τ\ +""" + expected2 = \ +"""\ +⎛ ⎡ x + y x - y ⎤ ⎡ x - y x + y ⎤ ⎡ x + y x + y ⎤ ⎞-1 ⎡ x + y x - y ⎤ ⎡ x - y x + y ⎤ \n\ +⎜ ⎢─────── ───── ⎥ ⎢ ───── ───────⎥ ⎢─────── ───────⎥ ⎟ ⎢─────── ───── ⎥ ⎢ ───── ───────⎥ \n\ +⎜ ⎢x - 2⋅y x + y ⎥ ⎢ x + y x - 2⋅y⎥ ⎢x - 2⋅y x - 2⋅y⎥ ⎟ ⎢x - 2⋅y x + y ⎥ ⎢ x + y x - 2⋅y⎥ \n\ +⎜I + ⎢ ⎥ ⋅⎢ ⎥ ⋅⎢ ⎥ ⎟ ⋅ ⎢ ⎥ ⋅⎢ ⎥ \n\ +⎜ ⎢ x - y x + y ⎥ ⎢ x + y x - y ⎥ ⎢ x - y x - y ⎥ ⎟ ⎢ x - y x + y ⎥ ⎢ x + y x - y ⎥ \n\ +⎜ ⎢ ───── ───────⎥ ⎢─────── ───── ⎥ ⎢ ───── ───── ⎥ ⎟ ⎢ ───── ───────⎥ ⎢─────── ───── ⎥ \n\ +⎝ ⎣ x + y x - 2⋅y⎦τ ⎣x - 2⋅y x + y ⎦τ ⎣ x + y x + y ⎦τ⎠ ⎣ x + y x - 2⋅y⎦τ ⎣x - 2⋅y x + y ⎦τ\ +""" + + assert upretty(MIMOFeedback(tfm_1, tfm_2, 1)) == \ + expected1 # Positive MIMOFeedback + assert upretty(MIMOFeedback(tfm_1*tfm_2, tfm_3)) == \ + expected2 # Negative MIMOFeedback (Default) + + +def test_pretty_TransferFunctionMatrix(): + tf1 = TransferFunction(x + y, x - 2*y, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(y**2 - 2*y + 1, y + 5, y) + tf4 = TransferFunction(y, x**2 + x + 1, y) + tf5 = TransferFunction(1 - x, x - y, y) + tf6 = TransferFunction(2, 2, y) + expected1 = \ +"""\ +⎡ x + y ⎤ \n\ +⎢───────⎥ \n\ +⎢x - 2⋅y⎥ \n\ +⎢ ⎥ \n\ +⎢ x - y ⎥ \n\ +⎢ ───── ⎥ \n\ +⎣ x + y ⎦τ\ +""" + expected2 = \ +"""\ +⎡ x + y ⎤ \n\ +⎢ ─────── ⎥ \n\ +⎢ x - 2⋅y ⎥ \n\ +⎢ ⎥ \n\ +⎢ x - y ⎥ \n\ +⎢ ───── ⎥ \n\ +⎢ x + y ⎥ \n\ +⎢ ⎥ \n\ +⎢ 2 ⎥ \n\ +⎢- y + 2⋅y - 1⎥ \n\ +⎢──────────────⎥ \n\ +⎣ y + 5 ⎦τ\ +""" + expected3 = \ +"""\ +⎡ x + y x - y ⎤ \n\ +⎢ ─────── ───── ⎥ \n\ +⎢ x - 2⋅y x + y ⎥ \n\ +⎢ ⎥ \n\ +⎢ 2 ⎥ \n\ +⎢y - 2⋅y + 1 y ⎥ \n\ +⎢──────────── ──────────⎥ \n\ +⎢ y + 5 2 ⎥ \n\ +⎢ x + x + 1⎥ \n\ +⎢ ⎥ \n\ +⎢ 1 - x 2 ⎥ \n\ +⎢ ───── ─ ⎥ \n\ +⎣ x - y 2 ⎦τ\ +""" + expected4 = \ +"""\ +⎡ x - y x + y y ⎤ \n\ +⎢ ───── ─────── ──────────⎥ \n\ +⎢ x + y x - 2⋅y 2 ⎥ \n\ +⎢ x + x + 1⎥ \n\ +⎢ ⎥ \n\ +⎢ 2 ⎥ \n\ +⎢- y + 2⋅y - 1 x - 1 -2 ⎥ \n\ +⎢────────────── ───── ─── ⎥ \n\ +⎣ y + 5 x - y 2 ⎦τ\ +""" + expected5 = \ +"""\ +⎡ x + y x - y x + y y ⎤ \n\ +⎢───────⋅───── ─────── ──────────⎥ \n\ +⎢x - 2⋅y x + y x - 2⋅y 2 ⎥ \n\ +⎢ x + x + 1⎥ \n\ +⎢ ⎥ \n\ +⎢ 1 - x 2 x + y -2 ⎥ \n\ +⎢ ───── + ─ ─────── ─── ⎥ \n\ +⎣ x - y 2 x - 2⋅y 2 ⎦τ\ +""" + + assert upretty(TransferFunctionMatrix([[tf1], [tf2]])) == expected1 + assert upretty(TransferFunctionMatrix([[tf1], [tf2], [-tf3]])) == expected2 + assert upretty(TransferFunctionMatrix([[tf1, tf2], [tf3, tf4], [tf5, tf6]])) == expected3 + assert upretty(TransferFunctionMatrix([[tf2, tf1, tf4], [-tf3, -tf5, -tf6]])) == expected4 + assert upretty(TransferFunctionMatrix([[Series(tf2, tf1), tf1, tf4], [Parallel(tf6, tf5), tf1, -tf6]])) == \ + expected5 + + +def test_pretty_StateSpace(): + ss1 = StateSpace(Matrix([a]), Matrix([b]), Matrix([c]), Matrix([d])) + A = Matrix([[0, 1], [1, 0]]) + B = Matrix([1, 0]) + C = Matrix([[0, 1]]) + D = Matrix([0]) + ss2 = StateSpace(A, B, C, D) + ss3 = StateSpace(Matrix([[-1.5, -2], [1, 0]]), + Matrix([[0.5, 0], [0, 1]]), + Matrix([[0, 1], [0, 2]]), + Matrix([[2, 2], [1, 1]])) + + expected1 = \ +"""\ +⎡[a] [b]⎤\n\ +⎢ ⎥\n\ +⎣[c] [d]⎦\ +""" + expected2 = \ +"""\ +⎡⎡0 1⎤ ⎡1⎤⎤\n\ +⎢⎢ ⎥ ⎢ ⎥⎥\n\ +⎢⎣1 0⎦ ⎣0⎦⎥\n\ +⎢ ⎥\n\ +⎣[0 1] [0]⎦\ +""" + expected3 = \ +"""\ +⎡⎡-1.5 -2⎤ ⎡0.5 0⎤⎤\n\ +⎢⎢ ⎥ ⎢ ⎥⎥\n\ +⎢⎣ 1 0 ⎦ ⎣ 0 1⎦⎥\n\ +⎢ ⎥\n\ +⎢ ⎡0 1⎤ ⎡2 2⎤ ⎥\n\ +⎢ ⎢ ⎥ ⎢ ⎥ ⎥\n\ +⎣ ⎣0 2⎦ ⎣1 1⎦ ⎦\ +""" + + assert upretty(ss1) == expected1 + assert upretty(ss2) == expected2 + assert upretty(ss3) == expected3 + +def test_pretty_order(): + expr = O(1) + ascii_str = \ +"""\ +O(1)\ +""" + ucode_str = \ +"""\ +O(1)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = O(1/x) + ascii_str = \ +"""\ + /1\\\n\ +O|-|\n\ + \\x/\ +""" + ucode_str = \ +"""\ + ⎛1⎞\n\ +O⎜─⎟\n\ + ⎝x⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = O(x**2 + y**2) + ascii_str = \ +"""\ + / 2 2 \\\n\ +O\\x + y ; (x, y) -> (0, 0)/\ +""" + ucode_str = \ +"""\ + ⎛ 2 2 ⎞\n\ +O⎝x + y ; (x, y) → (0, 0)⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = O(1, (x, oo)) + ascii_str = \ +"""\ +O(1; x -> oo)\ +""" + ucode_str = \ +"""\ +O(1; x → ∞)\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = O(1/x, (x, oo)) + ascii_str = \ +"""\ + /1 \\\n\ +O|-; x -> oo|\n\ + \\x /\ +""" + ucode_str = \ +"""\ + ⎛1 ⎞\n\ +O⎜─; x → ∞⎟\n\ + ⎝x ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = O(x**2 + y**2, (x, oo), (y, oo)) + ascii_str = \ +"""\ + / 2 2 \\\n\ +O\\x + y ; (x, y) -> (oo, oo)/\ +""" + ucode_str = \ +"""\ + ⎛ 2 2 ⎞\n\ +O⎝x + y ; (x, y) → (∞, ∞)⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_derivatives(): + # Simple + expr = Derivative(log(x), x, evaluate=False) + ascii_str = \ +"""\ +d \n\ +--(log(x))\n\ +dx \ +""" + ucode_str = \ +"""\ +d \n\ +──(log(x))\n\ +dx \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Derivative(log(x), x, evaluate=False) + x + ascii_str_1 = \ +"""\ + d \n\ +x + --(log(x))\n\ + dx \ +""" + ascii_str_2 = \ +"""\ +d \n\ +--(log(x)) + x\n\ +dx \ +""" + ucode_str_1 = \ +"""\ + d \n\ +x + ──(log(x))\n\ + dx \ +""" + ucode_str_2 = \ +"""\ +d \n\ +──(log(x)) + x\n\ +dx \ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + # basic partial derivatives + expr = Derivative(log(x + y) + x, x) + ascii_str_1 = \ +"""\ +d \n\ +--(log(x + y) + x)\n\ +dx \ +""" + ascii_str_2 = \ +"""\ +d \n\ +--(x + log(x + y))\n\ +dx \ +""" + ucode_str_1 = \ +"""\ +∂ \n\ +──(log(x + y) + x)\n\ +∂x \ +""" + ucode_str_2 = \ +"""\ +∂ \n\ +──(x + log(x + y))\n\ +∂x \ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2], upretty(expr) + + # Multiple symbols + expr = Derivative(log(x) + x**2, x, y) + ascii_str_1 = \ +"""\ + 2 \n\ + d / 2\\\n\ +-----\\log(x) + x /\n\ +dy dx \ +""" + ascii_str_2 = \ +"""\ + 2 \n\ + d / 2 \\\n\ +-----\\x + log(x)/\n\ +dy dx \ +""" + ascii_str_3 = \ +"""\ + 2 \n\ + d / 2 \\\n\ +-----\\x + log(x)/\n\ +dy dx \ +""" + ucode_str_1 = \ +"""\ + 2 \n\ + d ⎛ 2⎞\n\ +─────⎝log(x) + x ⎠\n\ +dy dx \ +""" + ucode_str_2 = \ +"""\ + 2 \n\ + d ⎛ 2 ⎞\n\ +─────⎝x + log(x)⎠\n\ +dy dx \ +""" + ucode_str_3 = \ +"""\ + 2 \n\ + d ⎛ 2 ⎞\n\ +─────⎝x + log(x)⎠\n\ +dy dx \ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2, ascii_str_3] + assert upretty(expr) in [ucode_str_1, ucode_str_2, ucode_str_3] + + expr = Derivative(2*x*y, y, x) + x**2 + ascii_str_1 = \ +"""\ + 2 \n\ + d 2\n\ +-----(2*x*y) + x \n\ +dx dy \ +""" + ascii_str_2 = \ +"""\ + 2 \n\ + 2 d \n\ +x + -----(2*x*y)\n\ + dx dy \ +""" + ascii_str_3 = \ +"""\ + 2 \n\ + 2 d \n\ +x + -----(2*x*y)\n\ + dx dy \ +""" + ucode_str_1 = \ +"""\ + 2 \n\ + ∂ 2\n\ +─────(2⋅x⋅y) + x \n\ +∂x ∂y \ +""" + ucode_str_2 = \ +"""\ + 2 \n\ + 2 ∂ \n\ +x + ─────(2⋅x⋅y)\n\ + ∂x ∂y \ +""" + ucode_str_3 = \ +"""\ + 2 \n\ + 2 ∂ \n\ +x + ─────(2⋅x⋅y)\n\ + ∂x ∂y \ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2, ascii_str_3] + assert upretty(expr) in [ucode_str_1, ucode_str_2, ucode_str_3] + + expr = Derivative(2*x*y, x, x) + ascii_str = \ +"""\ + 2 \n\ +d \n\ +---(2*x*y)\n\ + 2 \n\ +dx \ +""" + ucode_str = \ +"""\ + 2 \n\ +∂ \n\ +───(2⋅x⋅y)\n\ + 2 \n\ +∂x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Derivative(2*x*y, x, 17) + ascii_str = \ +"""\ + 17 \n\ +d \n\ +----(2*x*y)\n\ + 17 \n\ +dx \ +""" + ucode_str = \ +"""\ + 17 \n\ +∂ \n\ +────(2⋅x⋅y)\n\ + 17 \n\ +∂x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Derivative(2*x*y, x, x, y) + ascii_str = \ +"""\ + 3 \n\ + d \n\ +------(2*x*y)\n\ + 2 \n\ +dy dx \ +""" + ucode_str = \ +"""\ + 3 \n\ + ∂ \n\ +──────(2⋅x⋅y)\n\ + 2 \n\ +∂y ∂x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + # Greek letters + alpha = Symbol('alpha') + beta = Function('beta') + expr = beta(alpha).diff(alpha) + ascii_str = \ +"""\ + d \n\ +------(beta(alpha))\n\ +dalpha \ +""" + ucode_str = \ +"""\ +d \n\ +──(β(α))\n\ +dα \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Derivative(f(x), (x, n)) + + ascii_str = \ +"""\ + n \n\ +d \n\ +---(f(x))\n\ + n \n\ +dx \ +""" + ucode_str = \ +"""\ + n \n\ +d \n\ +───(f(x))\n\ + n \n\ +dx \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_integrals(): + expr = Integral(log(x), x) + ascii_str = \ +"""\ + / \n\ + | \n\ + | log(x) dx\n\ + | \n\ +/ \ +""" + ucode_str = \ +"""\ +⌠ \n\ +⎮ log(x) dx\n\ +⌡ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(x**2, x) + ascii_str = \ +"""\ + / \n\ + | \n\ + | 2 \n\ + | x dx\n\ + | \n\ +/ \ +""" + ucode_str = \ +"""\ +⌠ \n\ +⎮ 2 \n\ +⎮ x dx\n\ +⌡ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral((sin(x))**2 / (tan(x))**2) + ascii_str = \ +"""\ + / \n\ + | \n\ + | 2 \n\ + | sin (x) \n\ + | ------- dx\n\ + | 2 \n\ + | tan (x) \n\ + | \n\ +/ \ +""" + ucode_str = \ +"""\ +⌠ \n\ +⎮ 2 \n\ +⎮ sin (x) \n\ +⎮ ─────── dx\n\ +⎮ 2 \n\ +⎮ tan (x) \n\ +⌡ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(x**(2**x), x) + ascii_str = \ +"""\ + / \n\ + | \n\ + | / x\\ \n\ + | \\2 / \n\ + | x dx\n\ + | \n\ +/ \ +""" + ucode_str = \ +"""\ +⌠ \n\ +⎮ ⎛ x⎞ \n\ +⎮ ⎝2 ⎠ \n\ +⎮ x dx\n\ +⌡ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(x**2, (x, 1, 2)) + ascii_str = \ +"""\ + 2 \n\ + / \n\ + | \n\ + | 2 \n\ + | x dx\n\ + | \n\ +/ \n\ +1 \ +""" + ucode_str = \ +"""\ +2 \n\ +⌠ \n\ +⎮ 2 \n\ +⎮ x dx\n\ +⌡ \n\ +1 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(x**2, (x, Rational(1, 2), 10)) + ascii_str = \ +"""\ + 10 \n\ + / \n\ + | \n\ + | 2 \n\ + | x dx\n\ + | \n\ +/ \n\ +1/2 \ +""" + ucode_str = \ +"""\ +10 \n\ +⌠ \n\ +⎮ 2 \n\ +⎮ x dx\n\ +⌡ \n\ +1/2 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(x**2*y**2, x, y) + ascii_str = \ +"""\ + / / \n\ + | | \n\ + | | 2 2 \n\ + | | x *y dx dy\n\ + | | \n\ +/ / \ +""" + ucode_str = \ +"""\ +⌠ ⌠ \n\ +⎮ ⎮ 2 2 \n\ +⎮ ⎮ x ⋅y dx dy\n\ +⌡ ⌡ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(sin(th)/cos(ph), (th, 0, pi), (ph, 0, 2*pi)) + ascii_str = \ +"""\ + 2*pi pi \n\ + / / \n\ + | | \n\ + | | sin(theta) \n\ + | | ---------- d(theta) d(phi)\n\ + | | cos(phi) \n\ + | | \n\ + / / \n\ +0 0 \ +""" + ucode_str = \ +"""\ +2⋅π π \n\ + ⌠ ⌠ \n\ + ⎮ ⎮ sin(θ) \n\ + ⎮ ⎮ ────── dθ dφ\n\ + ⎮ ⎮ cos(φ) \n\ + ⌡ ⌡ \n\ + 0 0 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_matrix(): + # Empty Matrix + expr = Matrix() + ascii_str = "[]" + unicode_str = "[]" + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + expr = Matrix(2, 0, lambda i, j: 0) + ascii_str = "[]" + unicode_str = "[]" + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + expr = Matrix(0, 2, lambda i, j: 0) + ascii_str = "[]" + unicode_str = "[]" + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + expr = Matrix([[x**2 + 1, 1], [y, x + y]]) + ascii_str_1 = \ +"""\ +[ 2 ] +[1 + x 1 ] +[ ] +[ y x + y]\ +""" + ascii_str_2 = \ +"""\ +[ 2 ] +[x + 1 1 ] +[ ] +[ y x + y]\ +""" + ucode_str_1 = \ +"""\ +⎡ 2 ⎤ +⎢1 + x 1 ⎥ +⎢ ⎥ +⎣ y x + y⎦\ +""" + ucode_str_2 = \ +"""\ +⎡ 2 ⎤ +⎢x + 1 1 ⎥ +⎢ ⎥ +⎣ y x + y⎦\ +""" + assert pretty(expr) in [ascii_str_1, ascii_str_2] + assert upretty(expr) in [ucode_str_1, ucode_str_2] + + expr = Matrix([[x/y, y, th], [0, exp(I*k*ph), 1]]) + ascii_str = \ +"""\ +[x ] +[- y theta] +[y ] +[ ] +[ I*k*phi ] +[0 e 1 ]\ +""" + ucode_str = \ +"""\ +⎡x ⎤ +⎢─ y θ⎥ +⎢y ⎥ +⎢ ⎥ +⎢ ⅈ⋅k⋅φ ⎥ +⎣0 ℯ 1⎦\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + unicode_str = \ +"""\ +⎡v̇_msc_00 0 0 ⎤ +⎢ ⎥ +⎢ 0 v̇_msc_01 0 ⎥ +⎢ ⎥ +⎣ 0 0 v̇_msc_02⎦\ +""" + + expr = diag(*MatrixSymbol('vdot_msc',1,3)) + assert upretty(expr) == unicode_str + + +def test_pretty_ndim_arrays(): + x, y, z, w = symbols("x y z w") + + for ArrayType in (ImmutableDenseNDimArray, ImmutableSparseNDimArray, MutableDenseNDimArray, MutableSparseNDimArray): + # Basic: scalar array + M = ArrayType(x) + + assert pretty(M) == "x" + assert upretty(M) == "x" + + M = ArrayType([[1/x, y], [z, w]]) + M1 = ArrayType([1/x, y, z]) + + M2 = tensorproduct(M1, M) + M3 = tensorproduct(M, M) + + ascii_str = \ +"""\ +[1 ]\n\ +[- y]\n\ +[x ]\n\ +[ ]\n\ +[z w]\ +""" + ucode_str = \ +"""\ +⎡1 ⎤\n\ +⎢─ y⎥\n\ +⎢x ⎥\n\ +⎢ ⎥\n\ +⎣z w⎦\ +""" + assert pretty(M) == ascii_str + assert upretty(M) == ucode_str + + ascii_str = \ +"""\ +[1 ]\n\ +[- y z]\n\ +[x ]\ +""" + ucode_str = \ +"""\ +⎡1 ⎤\n\ +⎢─ y z⎥\n\ +⎣x ⎦\ +""" + assert pretty(M1) == ascii_str + assert upretty(M1) == ucode_str + + ascii_str = \ +"""\ +[[1 y] ]\n\ +[[-- -] [z ]]\n\ +[[ 2 x] [ y 2 ] [- y*z]]\n\ +[[x ] [ - y ] [x ]]\n\ +[[ ] [ x ] [ ]]\n\ +[[z w] [ ] [ 2 ]]\n\ +[[- -] [y*z w*y] [z w*z]]\n\ +[[x x] ]\ +""" + ucode_str = \ +"""\ +⎡⎡1 y⎤ ⎤\n\ +⎢⎢── ─⎥ ⎡z ⎤⎥\n\ +⎢⎢ 2 x⎥ ⎡ y 2 ⎤ ⎢─ y⋅z⎥⎥\n\ +⎢⎢x ⎥ ⎢ ─ y ⎥ ⎢x ⎥⎥\n\ +⎢⎢ ⎥ ⎢ x ⎥ ⎢ ⎥⎥\n\ +⎢⎢z w⎥ ⎢ ⎥ ⎢ 2 ⎥⎥\n\ +⎢⎢─ ─⎥ ⎣y⋅z w⋅y⎦ ⎣z w⋅z⎦⎥\n\ +⎣⎣x x⎦ ⎦\ +""" + assert pretty(M2) == ascii_str + assert upretty(M2) == ucode_str + + ascii_str = \ +"""\ +[ [1 y] ]\n\ +[ [-- -] ]\n\ +[ [ 2 x] [ y 2 ]]\n\ +[ [x ] [ - y ]]\n\ +[ [ ] [ x ]]\n\ +[ [z w] [ ]]\n\ +[ [- -] [y*z w*y]]\n\ +[ [x x] ]\n\ +[ ]\n\ +[[z ] [ w ]]\n\ +[[- y*z] [ - w*y]]\n\ +[[x ] [ x ]]\n\ +[[ ] [ ]]\n\ +[[ 2 ] [ 2 ]]\n\ +[[z w*z] [w*z w ]]\ +""" + ucode_str = \ +"""\ +⎡ ⎡1 y⎤ ⎤\n\ +⎢ ⎢── ─⎥ ⎥\n\ +⎢ ⎢ 2 x⎥ ⎡ y 2 ⎤⎥\n\ +⎢ ⎢x ⎥ ⎢ ─ y ⎥⎥\n\ +⎢ ⎢ ⎥ ⎢ x ⎥⎥\n\ +⎢ ⎢z w⎥ ⎢ ⎥⎥\n\ +⎢ ⎢─ ─⎥ ⎣y⋅z w⋅y⎦⎥\n\ +⎢ ⎣x x⎦ ⎥\n\ +⎢ ⎥\n\ +⎢⎡z ⎤ ⎡ w ⎤⎥\n\ +⎢⎢─ y⋅z⎥ ⎢ ─ w⋅y⎥⎥\n\ +⎢⎢x ⎥ ⎢ x ⎥⎥\n\ +⎢⎢ ⎥ ⎢ ⎥⎥\n\ +⎢⎢ 2 ⎥ ⎢ 2 ⎥⎥\n\ +⎣⎣z w⋅z⎦ ⎣w⋅z w ⎦⎦\ +""" + assert pretty(M3) == ascii_str + assert upretty(M3) == ucode_str + + Mrow = ArrayType([[x, y, 1 / z]]) + Mcolumn = ArrayType([[x], [y], [1 / z]]) + Mcol2 = ArrayType([Mcolumn.tolist()]) + + ascii_str = \ +"""\ +[[ 1]]\n\ +[[x y -]]\n\ +[[ z]]\ +""" + ucode_str = \ +"""\ +⎡⎡ 1⎤⎤\n\ +⎢⎢x y ─⎥⎥\n\ +⎣⎣ z⎦⎦\ +""" + assert pretty(Mrow) == ascii_str + assert upretty(Mrow) == ucode_str + + ascii_str = \ +"""\ +[x]\n\ +[ ]\n\ +[y]\n\ +[ ]\n\ +[1]\n\ +[-]\n\ +[z]\ +""" + ucode_str = \ +"""\ +⎡x⎤\n\ +⎢ ⎥\n\ +⎢y⎥\n\ +⎢ ⎥\n\ +⎢1⎥\n\ +⎢─⎥\n\ +⎣z⎦\ +""" + assert pretty(Mcolumn) == ascii_str + assert upretty(Mcolumn) == ucode_str + + ascii_str = \ +"""\ +[[x]]\n\ +[[ ]]\n\ +[[y]]\n\ +[[ ]]\n\ +[[1]]\n\ +[[-]]\n\ +[[z]]\ +""" + ucode_str = \ +"""\ +⎡⎡x⎤⎤\n\ +⎢⎢ ⎥⎥\n\ +⎢⎢y⎥⎥\n\ +⎢⎢ ⎥⎥\n\ +⎢⎢1⎥⎥\n\ +⎢⎢─⎥⎥\n\ +⎣⎣z⎦⎦\ +""" + assert pretty(Mcol2) == ascii_str + assert upretty(Mcol2) == ucode_str + + +def test_tensor_TensorProduct(): + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + assert upretty(TensorProduct(A, B)) == "A\u2297B" + assert upretty(TensorProduct(A, B, A)) == "A\u2297B\u2297A" + + +def test_diffgeom_print_WedgeProduct(): + from sympy.diffgeom.rn import R2 + from sympy.diffgeom import WedgeProduct + wp = WedgeProduct(R2.dx, R2.dy) + assert upretty(wp) == "ⅆ x∧ⅆ y" + assert pretty(wp) == r"d x/\d y" + + +def test_Adjoint(): + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert pretty(Adjoint(X)) == " +\nX " + assert pretty(Adjoint(X + Y)) == " +\n(X + Y) " + assert pretty(Adjoint(X) + Adjoint(Y)) == " + +\nX + Y " + assert pretty(Adjoint(X*Y)) == " +\n(X*Y) " + assert pretty(Adjoint(Y)*Adjoint(X)) == " + +\nY *X " + assert pretty(Adjoint(X**2)) == " +\n/ 2\\ \n\\X / " + assert pretty(Adjoint(X)**2) == " 2\n/ +\\ \n\\X / " + assert pretty(Adjoint(Inverse(X))) == " +\n/ -1\\ \n\\X / " + assert pretty(Inverse(Adjoint(X))) == " -1\n/ +\\ \n\\X / " + assert pretty(Adjoint(Transpose(X))) == " +\n/ T\\ \n\\X / " + assert pretty(Transpose(Adjoint(X))) == " T\n/ +\\ \n\\X / " + assert upretty(Adjoint(X)) == " †\nX " + assert upretty(Adjoint(X + Y)) == " †\n(X + Y) " + assert upretty(Adjoint(X) + Adjoint(Y)) == " † †\nX + Y " + assert upretty(Adjoint(X*Y)) == " †\n(X⋅Y) " + assert upretty(Adjoint(Y)*Adjoint(X)) == " † †\nY ⋅X " + assert upretty(Adjoint(X**2)) == \ + " †\n⎛ 2⎞ \n⎝X ⎠ " + assert upretty(Adjoint(X)**2) == \ + " 2\n⎛ †⎞ \n⎝X ⎠ " + assert upretty(Adjoint(Inverse(X))) == \ + " †\n⎛ -1⎞ \n⎝X ⎠ " + assert upretty(Inverse(Adjoint(X))) == \ + " -1\n⎛ †⎞ \n⎝X ⎠ " + assert upretty(Adjoint(Transpose(X))) == \ + " †\n⎛ T⎞ \n⎝X ⎠ " + assert upretty(Transpose(Adjoint(X))) == \ + " T\n⎛ †⎞ \n⎝X ⎠ " + m = Matrix(((1, 2), (3, 4))) + assert upretty(Adjoint(m)) == \ + ' †\n'\ + '⎡1 2⎤ \n'\ + '⎢ ⎥ \n'\ + '⎣3 4⎦ ' + assert upretty(Adjoint(m+X)) == \ + ' †\n'\ + '⎛⎡1 2⎤ ⎞ \n'\ + '⎜⎢ ⎥ + X⎟ \n'\ + '⎝⎣3 4⎦ ⎠ ' + assert upretty(Adjoint(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + ' †\n'\ + '⎡ 𝟙 X⎤ \n'\ + '⎢ ⎥ \n'\ + '⎢⎡1 2⎤ ⎥ \n'\ + '⎢⎢ ⎥ 𝟘⎥ \n'\ + '⎣⎣3 4⎦ ⎦ ' + + +def test_Transpose(): + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert pretty(Transpose(X)) == " T\nX " + assert pretty(Transpose(X + Y)) == " T\n(X + Y) " + assert pretty(Transpose(X) + Transpose(Y)) == " T T\nX + Y " + assert pretty(Transpose(X*Y)) == " T\n(X*Y) " + assert pretty(Transpose(Y)*Transpose(X)) == " T T\nY *X " + assert pretty(Transpose(X**2)) == " T\n/ 2\\ \n\\X / " + assert pretty(Transpose(X)**2) == " 2\n/ T\\ \n\\X / " + assert pretty(Transpose(Inverse(X))) == " T\n/ -1\\ \n\\X / " + assert pretty(Inverse(Transpose(X))) == " -1\n/ T\\ \n\\X / " + assert upretty(Transpose(X)) == " T\nX " + assert upretty(Transpose(X + Y)) == " T\n(X + Y) " + assert upretty(Transpose(X) + Transpose(Y)) == " T T\nX + Y " + assert upretty(Transpose(X*Y)) == " T\n(X⋅Y) " + assert upretty(Transpose(Y)*Transpose(X)) == " T T\nY ⋅X " + assert upretty(Transpose(X**2)) == \ + " T\n⎛ 2⎞ \n⎝X ⎠ " + assert upretty(Transpose(X)**2) == \ + " 2\n⎛ T⎞ \n⎝X ⎠ " + assert upretty(Transpose(Inverse(X))) == \ + " T\n⎛ -1⎞ \n⎝X ⎠ " + assert upretty(Inverse(Transpose(X))) == \ + " -1\n⎛ T⎞ \n⎝X ⎠ " + m = Matrix(((1, 2), (3, 4))) + assert upretty(Transpose(m)) == \ + ' T\n'\ + '⎡1 2⎤ \n'\ + '⎢ ⎥ \n'\ + '⎣3 4⎦ ' + assert upretty(Transpose(m+X)) == \ + ' T\n'\ + '⎛⎡1 2⎤ ⎞ \n'\ + '⎜⎢ ⎥ + X⎟ \n'\ + '⎝⎣3 4⎦ ⎠ ' + assert upretty(Transpose(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + ' T\n'\ + '⎡ 𝟙 X⎤ \n'\ + '⎢ ⎥ \n'\ + '⎢⎡1 2⎤ ⎥ \n'\ + '⎢⎢ ⎥ 𝟘⎥ \n'\ + '⎣⎣3 4⎦ ⎦ ' + + +def test_pretty_Trace_issue_9044(): + X = Matrix([[1, 2], [3, 4]]) + Y = Matrix([[2, 4], [6, 8]]) + ascii_str_1 = \ +"""\ + /[1 2]\\ +tr|[ ]| + \\[3 4]/\ +""" + ucode_str_1 = \ +"""\ + ⎛⎡1 2⎤⎞ +tr⎜⎢ ⎥⎟ + ⎝⎣3 4⎦⎠\ +""" + ascii_str_2 = \ +"""\ + /[1 2]\\ /[2 4]\\ +tr|[ ]| + tr|[ ]| + \\[3 4]/ \\[6 8]/\ +""" + ucode_str_2 = \ +"""\ + ⎛⎡1 2⎤⎞ ⎛⎡2 4⎤⎞ +tr⎜⎢ ⎥⎟ + tr⎜⎢ ⎥⎟ + ⎝⎣3 4⎦⎠ ⎝⎣6 8⎦⎠\ +""" + assert pretty(Trace(X)) == ascii_str_1 + assert upretty(Trace(X)) == ucode_str_1 + + assert pretty(Trace(X) + Trace(Y)) == ascii_str_2 + assert upretty(Trace(X) + Trace(Y)) == ucode_str_2 + + +def test_MatrixSlice(): + n = Symbol('n', integer=True) + x, y, z, w, t, = symbols('x y z w t') + X = MatrixSymbol('X', n, n) + Y = MatrixSymbol('Y', 10, 10) + Z = MatrixSymbol('Z', 10, 10) + + expr = MatrixSlice(X, (None, None, None), (None, None, None)) + assert pretty(expr) == upretty(expr) == 'X[:, :]' + expr = X[x:x + 1, y:y + 1] + assert pretty(expr) == upretty(expr) == 'X[x:x + 1, y:y + 1]' + expr = X[x:x + 1:2, y:y + 1:2] + assert pretty(expr) == upretty(expr) == 'X[x:x + 1:2, y:y + 1:2]' + expr = X[:x, y:] + assert pretty(expr) == upretty(expr) == 'X[:x, y:]' + expr = X[:x, y:] + assert pretty(expr) == upretty(expr) == 'X[:x, y:]' + expr = X[x:, :y] + assert pretty(expr) == upretty(expr) == 'X[x:, :y]' + expr = X[x:y, z:w] + assert pretty(expr) == upretty(expr) == 'X[x:y, z:w]' + expr = X[x:y:t, w:t:x] + assert pretty(expr) == upretty(expr) == 'X[x:y:t, w:t:x]' + expr = X[x::y, t::w] + assert pretty(expr) == upretty(expr) == 'X[x::y, t::w]' + expr = X[:x:y, :t:w] + assert pretty(expr) == upretty(expr) == 'X[:x:y, :t:w]' + expr = X[::x, ::y] + assert pretty(expr) == upretty(expr) == 'X[::x, ::y]' + expr = MatrixSlice(X, (0, None, None), (0, None, None)) + assert pretty(expr) == upretty(expr) == 'X[:, :]' + expr = MatrixSlice(X, (None, n, None), (None, n, None)) + assert pretty(expr) == upretty(expr) == 'X[:, :]' + expr = MatrixSlice(X, (0, n, None), (0, n, None)) + assert pretty(expr) == upretty(expr) == 'X[:, :]' + expr = MatrixSlice(X, (0, n, 2), (0, n, 2)) + assert pretty(expr) == upretty(expr) == 'X[::2, ::2]' + expr = X[1:2:3, 4:5:6] + assert pretty(expr) == upretty(expr) == 'X[1:2:3, 4:5:6]' + expr = X[1:3:5, 4:6:8] + assert pretty(expr) == upretty(expr) == 'X[1:3:5, 4:6:8]' + expr = X[1:10:2] + assert pretty(expr) == upretty(expr) == 'X[1:10:2, :]' + expr = Y[:5, 1:9:2] + assert pretty(expr) == upretty(expr) == 'Y[:5, 1:9:2]' + expr = Y[:5, 1:10:2] + assert pretty(expr) == upretty(expr) == 'Y[:5, 1::2]' + expr = Y[5, :5:2] + assert pretty(expr) == upretty(expr) == 'Y[5:6, :5:2]' + expr = X[0:1, 0:1] + assert pretty(expr) == upretty(expr) == 'X[:1, :1]' + expr = X[0:1:2, 0:1:2] + assert pretty(expr) == upretty(expr) == 'X[:1:2, :1:2]' + expr = (Y + Z)[2:, 2:] + assert pretty(expr) == upretty(expr) == '(Y + Z)[2:, 2:]' + + +def test_MatrixExpressions(): + n = Symbol('n', integer=True) + X = MatrixSymbol('X', n, n) + + assert pretty(X) == upretty(X) == "X" + + # Apply function elementwise (`ElementwiseApplyFunc`): + + expr = (X.T*X).applyfunc(sin) + + ascii_str = """\ + / T \\\n\ +(d -> sin(d)).\\X *X/\ +""" + ucode_str = """\ + ⎛ T ⎞\n\ +(d ↦ sin(d))˳⎝X ⋅X⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + lamda = Lambda(x, 1/x) + expr = (n*X).applyfunc(lamda) + ascii_str = """\ +/ 1\\ \n\ +|x -> -|.(n*X)\n\ +\\ x/ \ +""" + ucode_str = """\ +⎛ 1⎞ \n\ +⎜x ↦ ─⎟˳(n⋅X)\n\ +⎝ x⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_dotproduct(): + from sympy.matrices.expressions.dotproduct import DotProduct + n = symbols("n", integer=True) + A = MatrixSymbol('A', n, 1) + B = MatrixSymbol('B', n, 1) + C = Matrix(1, 3, [1, 2, 3]) + D = Matrix(1, 3, [1, 3, 4]) + + assert pretty(DotProduct(A, B)) == "A*B" + assert pretty(DotProduct(C, D)) == "[1 2 3]*[1 3 4]" + assert upretty(DotProduct(A, B)) == "A⋅B" + assert upretty(DotProduct(C, D)) == "[1 2 3]⋅[1 3 4]" + + +def test_pretty_Determinant(): + from sympy.matrices import Determinant, Inverse, BlockMatrix, OneMatrix, ZeroMatrix + m = Matrix(((1, 2), (3, 4))) + assert upretty(Determinant(m)) == '│1 2│\n│ │\n│3 4│' + assert upretty(Determinant(Inverse(m))) == \ + '│ -1│\n'\ + '│⎡1 2⎤ │\n'\ + '│⎢ ⎥ │\n'\ + '│⎣3 4⎦ │' + X = MatrixSymbol('X', 2, 2) + assert upretty(Determinant(X)) == '│X│' + assert upretty(Determinant(X + m)) == \ + '│⎡1 2⎤ │\n'\ + '│⎢ ⎥ + X│\n'\ + '│⎣3 4⎦ │' + assert upretty(Determinant(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '│ 𝟙 X│\n'\ + '│ │\n'\ + '│⎡1 2⎤ │\n'\ + '│⎢ ⎥ 𝟘│\n'\ + '│⎣3 4⎦ │' + + +def test_pretty_piecewise(): + expr = Piecewise((x, x < 1), (x**2, True)) + ascii_str = \ +"""\ +/x for x < 1\n\ +| \n\ +< 2 \n\ +|x otherwise\n\ +\\ \ +""" + ucode_str = \ +"""\ +⎧x for x < 1\n\ +⎪ \n\ +⎨ 2 \n\ +⎪x otherwise\n\ +⎩ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = -Piecewise((x, x < 1), (x**2, True)) + ascii_str = \ +"""\ + //x for x < 1\\\n\ + || |\n\ +-|< 2 |\n\ + ||x otherwise|\n\ + \\\\ /\ +""" + ucode_str = \ +"""\ + ⎛⎧x for x < 1⎞\n\ + ⎜⎪ ⎟\n\ +-⎜⎨ 2 ⎟\n\ + ⎜⎪x otherwise⎟\n\ + ⎝⎩ ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = x + Piecewise((x, x > 0), (y, True)) + Piecewise((x/y, x < 2), + (y**2, x > 2), (1, True)) + 1 + ascii_str = \ +"""\ + //x \\ \n\ + ||- for x < 2| \n\ + ||y | \n\ + //x for x > 0\\ || | \n\ +x + |< | + |< 2 | + 1\n\ + \\\\y otherwise/ ||y for x > 2| \n\ + || | \n\ + ||1 otherwise| \n\ + \\\\ / \ +""" + ucode_str = \ +"""\ + ⎛⎧x ⎞ \n\ + ⎜⎪─ for x < 2⎟ \n\ + ⎜⎪y ⎟ \n\ + ⎛⎧x for x > 0⎞ ⎜⎪ ⎟ \n\ +x + ⎜⎨ ⎟ + ⎜⎨ 2 ⎟ + 1\n\ + ⎝⎩y otherwise⎠ ⎜⎪y for x > 2⎟ \n\ + ⎜⎪ ⎟ \n\ + ⎜⎪1 otherwise⎟ \n\ + ⎝⎩ ⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = x - Piecewise((x, x > 0), (y, True)) + Piecewise((x/y, x < 2), + (y**2, x > 2), (1, True)) + 1 + ascii_str = \ +"""\ + //x \\ \n\ + ||- for x < 2| \n\ + ||y | \n\ + //x for x > 0\\ || | \n\ +x - |< | + |< 2 | + 1\n\ + \\\\y otherwise/ ||y for x > 2| \n\ + || | \n\ + ||1 otherwise| \n\ + \\\\ / \ +""" + ucode_str = \ +"""\ + ⎛⎧x ⎞ \n\ + ⎜⎪─ for x < 2⎟ \n\ + ⎜⎪y ⎟ \n\ + ⎛⎧x for x > 0⎞ ⎜⎪ ⎟ \n\ +x - ⎜⎨ ⎟ + ⎜⎨ 2 ⎟ + 1\n\ + ⎝⎩y otherwise⎠ ⎜⎪y for x > 2⎟ \n\ + ⎜⎪ ⎟ \n\ + ⎜⎪1 otherwise⎟ \n\ + ⎝⎩ ⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = x*Piecewise((x, x > 0), (y, True)) + ascii_str = \ +"""\ + //x for x > 0\\\n\ +x*|< |\n\ + \\\\y otherwise/\ +""" + ucode_str = \ +"""\ + ⎛⎧x for x > 0⎞\n\ +x⋅⎜⎨ ⎟\n\ + ⎝⎩y otherwise⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Piecewise((x, x > 0), (y, True))*Piecewise((x/y, x < 2), (y**2, x > + 2), (1, True)) + ascii_str = \ +"""\ + //x \\\n\ + ||- for x < 2|\n\ + ||y |\n\ +//x for x > 0\\ || |\n\ +|< |*|< 2 |\n\ +\\\\y otherwise/ ||y for x > 2|\n\ + || |\n\ + ||1 otherwise|\n\ + \\\\ /\ +""" + ucode_str = \ +"""\ + ⎛⎧x ⎞\n\ + ⎜⎪─ for x < 2⎟\n\ + ⎜⎪y ⎟\n\ +⎛⎧x for x > 0⎞ ⎜⎪ ⎟\n\ +⎜⎨ ⎟⋅⎜⎨ 2 ⎟\n\ +⎝⎩y otherwise⎠ ⎜⎪y for x > 2⎟\n\ + ⎜⎪ ⎟\n\ + ⎜⎪1 otherwise⎟\n\ + ⎝⎩ ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = -Piecewise((x, x > 0), (y, True))*Piecewise((x/y, x < 2), (y**2, x + > 2), (1, True)) + ascii_str = \ +"""\ + //x \\\n\ + ||- for x < 2|\n\ + ||y |\n\ + //x for x > 0\\ || |\n\ +-|< |*|< 2 |\n\ + \\\\y otherwise/ ||y for x > 2|\n\ + || |\n\ + ||1 otherwise|\n\ + \\\\ /\ +""" + ucode_str = \ +"""\ + ⎛⎧x ⎞\n\ + ⎜⎪─ for x < 2⎟\n\ + ⎜⎪y ⎟\n\ + ⎛⎧x for x > 0⎞ ⎜⎪ ⎟\n\ +-⎜⎨ ⎟⋅⎜⎨ 2 ⎟\n\ + ⎝⎩y otherwise⎠ ⎜⎪y for x > 2⎟\n\ + ⎜⎪ ⎟\n\ + ⎜⎪1 otherwise⎟\n\ + ⎝⎩ ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Piecewise((0, Abs(1/y) < 1), (1, Abs(y) < 1), (y*meijerg(((2, 1), + ()), ((), (1, 0)), 1/y), True)) + ascii_str = \ +"""\ +/ 1 \n\ +| 0 for --- < 1\n\ +| |y| \n\ +| \n\ +< 1 for |y| < 1\n\ +| \n\ +| __0, 2 /1, 2 | 1\\ \n\ +|y*/__ | | -| otherwise \n\ +\\ \\_|2, 2 \\ 0, 1 | y/ \ +""" + ucode_str = \ +"""\ +⎧ 1 \n\ +⎪ 0 for ─── < 1\n\ +⎪ │y│ \n\ +⎪ \n\ +⎨ 1 for │y│ < 1\n\ +⎪ \n\ +⎪ ╭─╮0, 2 ⎛1, 2 │ 1⎞ \n\ +⎪y⋅│╶┐ ⎜ │ ─⎟ otherwise \n\ +⎩ ╰─╯2, 2 ⎝ 0, 1 │ y⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + # XXX: We have to use evaluate=False here because Piecewise._eval_power + # denests the power. + expr = Pow(Piecewise((x, x > 0), (y, True)), 2, evaluate=False) + ascii_str = \ +"""\ + 2\n\ +//x for x > 0\\ \n\ +|< | \n\ +\\\\y otherwise/ \ +""" + ucode_str = \ +"""\ + 2\n\ +⎛⎧x for x > 0⎞ \n\ +⎜⎨ ⎟ \n\ +⎝⎩y otherwise⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_ITE(): + expr = ITE(x, y, z) + assert pretty(expr) == ( + '/y for x \n' + '< \n' + '\\z otherwise' + ) + assert upretty(expr) == """\ +⎧y for x \n\ +⎨ \n\ +⎩z otherwise\ +""" + + +def test_pretty_seq(): + expr = () + ascii_str = \ +"""\ +()\ +""" + ucode_str = \ +"""\ +()\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = [] + ascii_str = \ +"""\ +[]\ +""" + ucode_str = \ +"""\ +[]\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = {} + expr_2 = {} + ascii_str = \ +"""\ +{}\ +""" + ucode_str = \ +"""\ +{}\ +""" + assert pretty(expr) == ascii_str + assert pretty(expr_2) == ascii_str + assert upretty(expr) == ucode_str + assert upretty(expr_2) == ucode_str + + expr = (1/x,) + ascii_str = \ +"""\ + 1 \n\ +(-,)\n\ + x \ +""" + ucode_str = \ +"""\ +⎛1 ⎞\n\ +⎜─,⎟\n\ +⎝x ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = [x**2, 1/x, x, y, sin(th)**2/cos(ph)**2] + ascii_str = \ +"""\ + 2 \n\ + 2 1 sin (theta) \n\ +[x , -, x, y, -----------]\n\ + x 2 \n\ + cos (phi) \ +""" + ucode_str = \ +"""\ +⎡ 2 ⎤\n\ +⎢ 2 1 sin (θ)⎥\n\ +⎢x , ─, x, y, ───────⎥\n\ +⎢ x 2 ⎥\n\ +⎣ cos (φ)⎦\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (x**2, 1/x, x, y, sin(th)**2/cos(ph)**2) + ascii_str = \ +"""\ + 2 \n\ + 2 1 sin (theta) \n\ +(x , -, x, y, -----------)\n\ + x 2 \n\ + cos (phi) \ +""" + ucode_str = \ +"""\ +⎛ 2 ⎞\n\ +⎜ 2 1 sin (θ)⎟\n\ +⎜x , ─, x, y, ───────⎟\n\ +⎜ x 2 ⎟\n\ +⎝ cos (φ)⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Tuple(x**2, 1/x, x, y, sin(th)**2/cos(ph)**2) + ascii_str = \ +"""\ + 2 \n\ + 2 1 sin (theta) \n\ +(x , -, x, y, -----------)\n\ + x 2 \n\ + cos (phi) \ +""" + ucode_str = \ +"""\ +⎛ 2 ⎞\n\ +⎜ 2 1 sin (θ)⎟\n\ +⎜x , ─, x, y, ───────⎟\n\ +⎜ x 2 ⎟\n\ +⎝ cos (φ)⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = {x: sin(x)} + expr_2 = Dict({x: sin(x)}) + ascii_str = \ +"""\ +{x: sin(x)}\ +""" + ucode_str = \ +"""\ +{x: sin(x)}\ +""" + assert pretty(expr) == ascii_str + assert pretty(expr_2) == ascii_str + assert upretty(expr) == ucode_str + assert upretty(expr_2) == ucode_str + + expr = {1/x: 1/y, x: sin(x)**2} + expr_2 = Dict({1/x: 1/y, x: sin(x)**2}) + ascii_str = \ +"""\ + 1 1 2 \n\ +{-: -, x: sin (x)}\n\ + x y \ +""" + ucode_str = \ +"""\ +⎧1 1 2 ⎫\n\ +⎨─: ─, x: sin (x)⎬\n\ +⎩x y ⎭\ +""" + assert pretty(expr) == ascii_str + assert pretty(expr_2) == ascii_str + assert upretty(expr) == ucode_str + assert upretty(expr_2) == ucode_str + + # There used to be a bug with pretty-printing sequences of even height. + expr = [x**2] + ascii_str = \ +"""\ + 2 \n\ +[x ]\ +""" + ucode_str = \ +"""\ +⎡ 2⎤\n\ +⎣x ⎦\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (x**2,) + ascii_str = \ +"""\ + 2 \n\ +(x ,)\ +""" + ucode_str = \ +"""\ +⎛ 2 ⎞\n\ +⎝x ,⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Tuple(x**2) + ascii_str = \ +"""\ + 2 \n\ +(x ,)\ +""" + ucode_str = \ +"""\ +⎛ 2 ⎞\n\ +⎝x ,⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = {x**2: 1} + expr_2 = Dict({x**2: 1}) + ascii_str = \ +"""\ + 2 \n\ +{x : 1}\ +""" + ucode_str = \ +"""\ +⎧ 2 ⎫\n\ +⎨x : 1⎬\n\ +⎩ ⎭\ +""" + assert pretty(expr) == ascii_str + assert pretty(expr_2) == ascii_str + assert upretty(expr) == ucode_str + assert upretty(expr_2) == ucode_str + + +def test_any_object_in_sequence(): + # Cf. issue 5306 + b1 = Basic() + b2 = Basic(Basic()) + + expr = [b2, b1] + assert pretty(expr) == "[Basic(Basic()), Basic()]" + assert upretty(expr) == "[Basic(Basic()), Basic()]" + + expr = {b2, b1} + assert pretty(expr) == "{Basic(), Basic(Basic())}" + assert upretty(expr) == "{Basic(), Basic(Basic())}" + + expr = {b2: b1, b1: b2} + expr2 = Dict({b2: b1, b1: b2}) + assert pretty(expr) == "{Basic(): Basic(Basic()), Basic(Basic()): Basic()}" + assert pretty( + expr2) == "{Basic(): Basic(Basic()), Basic(Basic()): Basic()}" + assert upretty( + expr) == "{Basic(): Basic(Basic()), Basic(Basic()): Basic()}" + assert upretty( + expr2) == "{Basic(): Basic(Basic()), Basic(Basic()): Basic()}" + + +def test_print_builtin_set(): + assert pretty(set()) == 'set()' + assert upretty(set()) == 'set()' + + assert pretty(frozenset()) == 'frozenset()' + assert upretty(frozenset()) == 'frozenset()' + + s1 = {1/x, x} + s2 = frozenset(s1) + + assert pretty(s1) == \ +"""\ + 1 \n\ +{-, x} + x \ +""" + assert upretty(s1) == \ +"""\ +⎧1 ⎫ +⎨─, x⎬ +⎩x ⎭\ +""" + + assert pretty(s2) == \ +"""\ + 1 \n\ +frozenset({-, x}) + x \ +""" + assert upretty(s2) == \ +"""\ + ⎛⎧1 ⎫⎞ +frozenset⎜⎨─, x⎬⎟ + ⎝⎩x ⎭⎠\ +""" + + +def test_pretty_sets(): + s = FiniteSet + assert pretty(s(*[x*y, x**2])) == \ +"""\ + 2 \n\ +{x , x*y}\ +""" + assert pretty(s(*range(1, 6))) == "{1, 2, 3, 4, 5}" + assert pretty(s(*range(1, 13))) == "{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12}" + + assert pretty({x*y, x**2}) == \ +"""\ + 2 \n\ +{x , x*y}\ +""" + assert pretty(set(range(1, 6))) == "{1, 2, 3, 4, 5}" + assert pretty(set(range(1, 13))) == \ + "{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12}" + + assert pretty(frozenset([x*y, x**2])) == \ +"""\ + 2 \n\ +frozenset({x , x*y})\ +""" + assert pretty(frozenset(range(1, 6))) == "frozenset({1, 2, 3, 4, 5})" + assert pretty(frozenset(range(1, 13))) == \ + "frozenset({1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12})" + + assert pretty(Range(0, 3, 1)) == '{0, 1, 2}' + + ascii_str = '{0, 1, ..., 29}' + ucode_str = '{0, 1, …, 29}' + assert pretty(Range(0, 30, 1)) == ascii_str + assert upretty(Range(0, 30, 1)) == ucode_str + + ascii_str = '{30, 29, ..., 2}' + ucode_str = '{30, 29, …, 2}' + assert pretty(Range(30, 1, -1)) == ascii_str + assert upretty(Range(30, 1, -1)) == ucode_str + + ascii_str = '{0, 2, ...}' + ucode_str = '{0, 2, …}' + assert pretty(Range(0, oo, 2)) == ascii_str + assert upretty(Range(0, oo, 2)) == ucode_str + + ascii_str = '{..., 2, 0}' + ucode_str = '{…, 2, 0}' + assert pretty(Range(oo, -2, -2)) == ascii_str + assert upretty(Range(oo, -2, -2)) == ucode_str + + ascii_str = '{-2, -3, ...}' + ucode_str = '{-2, -3, …}' + assert pretty(Range(-2, -oo, -1)) == ascii_str + assert upretty(Range(-2, -oo, -1)) == ucode_str + + +def test_pretty_SetExpr(): + iv = Interval(1, 3) + se = SetExpr(iv) + ascii_str = "SetExpr([1, 3])" + ucode_str = "SetExpr([1, 3])" + assert pretty(se) == ascii_str + assert upretty(se) == ucode_str + + +def test_pretty_ImageSet(): + imgset = ImageSet(Lambda((x, y), x + y), {1, 2, 3}, {3, 4}) + ascii_str = '{x + y | x in {1, 2, 3}, y in {3, 4}}' + ucode_str = '{x + y │ x ∊ {1, 2, 3}, y ∊ {3, 4}}' + assert pretty(imgset) == ascii_str + assert upretty(imgset) == ucode_str + + imgset = ImageSet(Lambda(((x, y),), x + y), ProductSet({1, 2, 3}, {3, 4})) + ascii_str = '{x + y | (x, y) in {1, 2, 3} x {3, 4}}' + ucode_str = '{x + y │ (x, y) ∊ {1, 2, 3} × {3, 4}}' + assert pretty(imgset) == ascii_str + assert upretty(imgset) == ucode_str + + imgset = ImageSet(Lambda(x, x**2), S.Naturals) + ascii_str = '''\ + 2 \n\ +{x | x in Naturals}''' + ucode_str = '''\ +⎧ 2 │ ⎫\n\ +⎨x │ x ∊ ℕ⎬\n\ +⎩ │ ⎭''' + assert pretty(imgset) == ascii_str + assert upretty(imgset) == ucode_str + + # TODO: The "x in N" parts below should be centered independently of the + # 1/x**2 fraction + imgset = ImageSet(Lambda(x, 1/x**2), S.Naturals) + ascii_str = '''\ + 1 \n\ +{-- | x in Naturals} + 2 \n\ + x ''' + ucode_str = '''\ +⎧1 │ ⎫\n\ +⎪── │ x ∊ ℕ⎪\n\ +⎨ 2 │ ⎬\n\ +⎪x │ ⎪\n\ +⎩ │ ⎭''' + assert pretty(imgset) == ascii_str + assert upretty(imgset) == ucode_str + + imgset = ImageSet(Lambda((x, y), 1/(x + y)**2), S.Naturals, S.Naturals) + ascii_str = '''\ + 1 \n\ +{-------- | x in Naturals, y in Naturals} + 2 \n\ + (x + y) ''' + ucode_str = '''\ +⎧ 1 │ ⎫ +⎪──────── │ x ∊ ℕ, y ∊ ℕ⎪ +⎨ 2 │ ⎬ +⎪(x + y) │ ⎪ +⎩ │ ⎭''' + assert pretty(imgset) == ascii_str + assert upretty(imgset) == ucode_str + + # issue 23449 centering issue + assert upretty([Symbol("ihat") / (Symbol("i") + 1)]) == '''\ +⎡ î ⎤ +⎢─────⎥ +⎣i + 1⎦\ +''' + assert upretty(Matrix([Symbol("ihat"), Symbol("i") + 1])) == '''\ +⎡ î ⎤ +⎢ ⎥ +⎣i + 1⎦\ +''' + + +def test_pretty_ConditionSet(): + ascii_str = '{x | x in (-oo, oo) and sin(x) = 0}' + ucode_str = '{x │ x ∊ ℝ ∧ (sin(x) = 0)}' + assert pretty(ConditionSet(x, Eq(sin(x), 0), S.Reals)) == ascii_str + assert upretty(ConditionSet(x, Eq(sin(x), 0), S.Reals)) == ucode_str + + assert pretty(ConditionSet(x, Contains(x, S.Reals, evaluate=False), FiniteSet(1))) == '{1}' + assert upretty(ConditionSet(x, Contains(x, S.Reals, evaluate=False), FiniteSet(1))) == '{1}' + + assert pretty(ConditionSet(x, And(x > 1, x < -1), FiniteSet(1, 2, 3))) == "EmptySet" + assert upretty(ConditionSet(x, And(x > 1, x < -1), FiniteSet(1, 2, 3))) == "∅" + + assert pretty(ConditionSet(x, Or(x > 1, x < -1), FiniteSet(1, 2))) == '{2}' + assert upretty(ConditionSet(x, Or(x > 1, x < -1), FiniteSet(1, 2))) == '{2}' + + condset = ConditionSet(x, 1/x**2 > 0) + ascii_str = '''\ + 1 \n\ +{x | -- > 0} + 2 \n\ + x ''' + ucode_str = '''\ +⎧ │ ⎛1 ⎞⎫ +⎪x │ ⎜── > 0⎟⎪ +⎨ │ ⎜ 2 ⎟⎬ +⎪ │ ⎝x ⎠⎪ +⎩ │ ⎭''' + assert pretty(condset) == ascii_str + assert upretty(condset) == ucode_str + + condset = ConditionSet(x, 1/x**2 > 0, S.Reals) + ascii_str = '''\ + 1 \n\ +{x | x in (-oo, oo) and -- > 0} + 2 \n\ + x ''' + ucode_str = '''\ +⎧ │ ⎛1 ⎞⎫ +⎪x │ x ∊ ℝ ∧ ⎜── > 0⎟⎪ +⎨ │ ⎜ 2 ⎟⎬ +⎪ │ ⎝x ⎠⎪ +⎩ │ ⎭''' + assert pretty(condset) == ascii_str + assert upretty(condset) == ucode_str + + +def test_pretty_ComplexRegion(): + from sympy.sets.fancysets import ComplexRegion + cregion = ComplexRegion(Interval(3, 5)*Interval(4, 6)) + ascii_str = '{x + y*I | x, y in [3, 5] x [4, 6]}' + ucode_str = '{x + y⋅ⅈ │ x, y ∊ [3, 5] × [4, 6]}' + assert pretty(cregion) == ascii_str + assert upretty(cregion) == ucode_str + + cregion = ComplexRegion(Interval(0, 1)*Interval(0, 2*pi), polar=True) + ascii_str = '{r*(I*sin(theta) + cos(theta)) | r, theta in [0, 1] x [0, 2*pi)}' + ucode_str = '{r⋅(ⅈ⋅sin(θ) + cos(θ)) │ r, θ ∊ [0, 1] × [0, 2⋅π)}' + assert pretty(cregion) == ascii_str + assert upretty(cregion) == ucode_str + + cregion = ComplexRegion(Interval(3, 1/a**2)*Interval(4, 6)) + ascii_str = '''\ + 1 \n\ +{x + y*I | x, y in [3, --] x [4, 6]} + 2 \n\ + a ''' + ucode_str = '''\ +⎧ │ ⎡ 1 ⎤ ⎫ +⎪x + y⋅ⅈ │ x, y ∊ ⎢3, ──⎥ × [4, 6]⎪ +⎨ │ ⎢ 2⎥ ⎬ +⎪ │ ⎣ a ⎦ ⎪ +⎩ │ ⎭''' + assert pretty(cregion) == ascii_str + assert upretty(cregion) == ucode_str + + cregion = ComplexRegion(Interval(0, 1/a**2)*Interval(0, 2*pi), polar=True) + ascii_str = '''\ + 1 \n\ +{r*(I*sin(theta) + cos(theta)) | r, theta in [0, --] x [0, 2*pi)} + 2 \n\ + a ''' + ucode_str = '''\ +⎧ │ ⎡ 1 ⎤ ⎫ +⎪r⋅(ⅈ⋅sin(θ) + cos(θ)) │ r, θ ∊ ⎢0, ──⎥ × [0, 2⋅π)⎪ +⎨ │ ⎢ 2⎥ ⎬ +⎪ │ ⎣ a ⎦ ⎪ +⎩ │ ⎭''' + assert pretty(cregion) == ascii_str + assert upretty(cregion) == ucode_str + + +def test_pretty_Union_issue_10414(): + a, b = Interval(2, 3), Interval(4, 7) + ucode_str = '[2, 3] ∪ [4, 7]' + ascii_str = '[2, 3] U [4, 7]' + assert upretty(Union(a, b)) == ucode_str + assert pretty(Union(a, b)) == ascii_str + + +def test_pretty_Intersection_issue_10414(): + x, y, z, w = symbols('x, y, z, w') + a, b = Interval(x, y), Interval(z, w) + ucode_str = '[x, y] ∩ [z, w]' + ascii_str = '[x, y] n [z, w]' + assert upretty(Intersection(a, b)) == ucode_str + assert pretty(Intersection(a, b)) == ascii_str + + +def test_ProductSet_exponent(): + ucode_str = ' 1\n[0, 1] ' + assert upretty(Interval(0, 1)**1) == ucode_str + ucode_str = ' 2\n[0, 1] ' + assert upretty(Interval(0, 1)**2) == ucode_str + + +def test_ProductSet_parenthesis(): + ucode_str = '([4, 7] × {1, 2}) ∪ ([2, 3] × [4, 7])' + + a, b = Interval(2, 3), Interval(4, 7) + assert upretty(Union(a*b, b*FiniteSet(1, 2))) == ucode_str + + +def test_ProductSet_prod_char_issue_10413(): + ascii_str = '[2, 3] x [4, 7]' + ucode_str = '[2, 3] × [4, 7]' + + a, b = Interval(2, 3), Interval(4, 7) + assert pretty(a*b) == ascii_str + assert upretty(a*b) == ucode_str + + +def test_pretty_sequences(): + s1 = SeqFormula(a**2, (0, oo)) + s2 = SeqPer((1, 2)) + + ascii_str = '[0, 1, 4, 9, ...]' + ucode_str = '[0, 1, 4, 9, …]' + + assert pretty(s1) == ascii_str + assert upretty(s1) == ucode_str + + ascii_str = '[1, 2, 1, 2, ...]' + ucode_str = '[1, 2, 1, 2, …]' + assert pretty(s2) == ascii_str + assert upretty(s2) == ucode_str + + s3 = SeqFormula(a**2, (0, 2)) + s4 = SeqPer((1, 2), (0, 2)) + + ascii_str = '[0, 1, 4]' + ucode_str = '[0, 1, 4]' + + assert pretty(s3) == ascii_str + assert upretty(s3) == ucode_str + + ascii_str = '[1, 2, 1]' + ucode_str = '[1, 2, 1]' + assert pretty(s4) == ascii_str + assert upretty(s4) == ucode_str + + s5 = SeqFormula(a**2, (-oo, 0)) + s6 = SeqPer((1, 2), (-oo, 0)) + + ascii_str = '[..., 9, 4, 1, 0]' + ucode_str = '[…, 9, 4, 1, 0]' + + assert pretty(s5) == ascii_str + assert upretty(s5) == ucode_str + + ascii_str = '[..., 2, 1, 2, 1]' + ucode_str = '[…, 2, 1, 2, 1]' + assert pretty(s6) == ascii_str + assert upretty(s6) == ucode_str + + ascii_str = '[1, 3, 5, 11, ...]' + ucode_str = '[1, 3, 5, 11, …]' + + assert pretty(SeqAdd(s1, s2)) == ascii_str + assert upretty(SeqAdd(s1, s2)) == ucode_str + + ascii_str = '[1, 3, 5]' + ucode_str = '[1, 3, 5]' + + assert pretty(SeqAdd(s3, s4)) == ascii_str + assert upretty(SeqAdd(s3, s4)) == ucode_str + + ascii_str = '[..., 11, 5, 3, 1]' + ucode_str = '[…, 11, 5, 3, 1]' + + assert pretty(SeqAdd(s5, s6)) == ascii_str + assert upretty(SeqAdd(s5, s6)) == ucode_str + + ascii_str = '[0, 2, 4, 18, ...]' + ucode_str = '[0, 2, 4, 18, …]' + + assert pretty(SeqMul(s1, s2)) == ascii_str + assert upretty(SeqMul(s1, s2)) == ucode_str + + ascii_str = '[0, 2, 4]' + ucode_str = '[0, 2, 4]' + + assert pretty(SeqMul(s3, s4)) == ascii_str + assert upretty(SeqMul(s3, s4)) == ucode_str + + ascii_str = '[..., 18, 4, 2, 0]' + ucode_str = '[…, 18, 4, 2, 0]' + + assert pretty(SeqMul(s5, s6)) == ascii_str + assert upretty(SeqMul(s5, s6)) == ucode_str + + # Sequences with symbolic limits, issue 12629 + s7 = SeqFormula(a**2, (a, 0, x)) + raises(NotImplementedError, lambda: pretty(s7)) + raises(NotImplementedError, lambda: upretty(s7)) + + b = Symbol('b') + s8 = SeqFormula(b*a**2, (a, 0, 2)) + ascii_str = '[0, b, 4*b]' + ucode_str = '[0, b, 4⋅b]' + assert pretty(s8) == ascii_str + assert upretty(s8) == ucode_str + + +def test_pretty_FourierSeries(): + f = fourier_series(x, (x, -pi, pi)) + + ascii_str = \ +"""\ + 2*sin(3*x) \n\ +2*sin(x) - sin(2*x) + ---------- + ...\n\ + 3 \ +""" + + ucode_str = \ +"""\ + 2⋅sin(3⋅x) \n\ +2⋅sin(x) - sin(2⋅x) + ────────── + …\n\ + 3 \ +""" + + assert pretty(f) == ascii_str + assert upretty(f) == ucode_str + + +def test_pretty_FormalPowerSeries(): + f = fps(log(1 + x)) + + + ascii_str = \ +"""\ + oo \n\ +____ \n\ +\\ ` \n\ + \\ -k k \n\ + \\ -(-1) *x \n\ + / -----------\n\ + / k \n\ +/___, \n\ +k = 1 \ +""" + + ucode_str = \ +"""\ + ∞ \n\ +____ \n\ +╲ \n\ + ╲ -k k \n\ + ╲ -(-1) ⋅x \n\ + ╱ ───────────\n\ + ╱ k \n\ +╱ \n\ +‾‾‾‾ \n\ +k = 1 \ +""" + + assert pretty(f) == ascii_str + assert upretty(f) == ucode_str + + +def test_pretty_limits(): + expr = Limit(x, x, oo) + ascii_str = \ +"""\ + lim x\n\ +x->oo \ +""" + ucode_str = \ +"""\ +lim x\n\ +x─→∞ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(x**2, x, 0) + ascii_str = \ +"""\ + 2\n\ + lim x \n\ +x->0+ \ +""" + ucode_str = \ +"""\ + 2\n\ + lim x \n\ +x─→0⁺ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(1/x, x, 0) + ascii_str = \ +"""\ + 1\n\ + lim -\n\ +x->0+x\ +""" + ucode_str = \ +"""\ + 1\n\ + lim ─\n\ +x─→0⁺x\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(sin(x)/x, x, 0) + ascii_str = \ +"""\ + /sin(x)\\\n\ + lim |------|\n\ +x->0+\\ x /\ +""" + ucode_str = \ +"""\ + ⎛sin(x)⎞\n\ + lim ⎜──────⎟\n\ +x─→0⁺⎝ x ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(sin(x)/x, x, 0, "-") + ascii_str = \ +"""\ + /sin(x)\\\n\ + lim |------|\n\ +x->0-\\ x /\ +""" + ucode_str = \ +"""\ + ⎛sin(x)⎞\n\ + lim ⎜──────⎟\n\ +x─→0⁻⎝ x ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(x + sin(x), x, 0) + ascii_str = \ +"""\ + lim (x + sin(x))\n\ +x->0+ \ +""" + ucode_str = \ +"""\ + lim (x + sin(x))\n\ +x─→0⁺ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(x, x, 0)**2 + ascii_str = \ +"""\ + 2\n\ +/ lim x\\ \n\ +\\x->0+ / \ +""" + ucode_str = \ +"""\ + 2\n\ +⎛ lim x⎞ \n\ +⎝x─→0⁺ ⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(x*Limit(y/2,y,0), x, 0) + ascii_str = \ +"""\ + / /y\\\\\n\ + lim |x* lim |-||\n\ +x->0+\\ y->0+\\2//\ +""" + ucode_str = \ +"""\ + ⎛ ⎛y⎞⎞\n\ + lim ⎜x⋅ lim ⎜─⎟⎟\n\ +x─→0⁺⎝ y─→0⁺⎝2⎠⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = 2*Limit(x*Limit(y/2,y,0), x, 0) + ascii_str = \ +"""\ + / /y\\\\\n\ +2* lim |x* lim |-||\n\ + x->0+\\ y->0+\\2//\ +""" + ucode_str = \ +"""\ + ⎛ ⎛y⎞⎞\n\ +2⋅ lim ⎜x⋅ lim ⎜─⎟⎟\n\ + x─→0⁺⎝ y─→0⁺⎝2⎠⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Limit(sin(x), x, 0, dir='+-') + ascii_str = \ +"""\ +lim sin(x)\n\ +x->0 \ +""" + ucode_str = \ +"""\ +lim sin(x)\n\ +x─→0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_ComplexRootOf(): + expr = rootof(x**5 + 11*x - 2, 0) + ascii_str = \ +"""\ + / 5 \\\n\ +CRootOf\\x + 11*x - 2, 0/\ +""" + ucode_str = \ +"""\ + ⎛ 5 ⎞\n\ +CRootOf⎝x + 11⋅x - 2, 0⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_RootSum(): + expr = RootSum(x**5 + 11*x - 2, auto=False) + ascii_str = \ +"""\ + / 5 \\\n\ +RootSum\\x + 11*x - 2/\ +""" + ucode_str = \ +"""\ + ⎛ 5 ⎞\n\ +RootSum⎝x + 11⋅x - 2⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = RootSum(x**5 + 11*x - 2, Lambda(z, exp(z))) + ascii_str = \ +"""\ + / 5 z\\\n\ +RootSum\\x + 11*x - 2, z -> e /\ +""" + ucode_str = \ +"""\ + ⎛ 5 z⎞\n\ +RootSum⎝x + 11⋅x - 2, z ↦ ℯ ⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_GroebnerBasis(): + expr = groebner([], x, y) + + ascii_str = \ +"""\ +GroebnerBasis([], x, y, domain=ZZ, order=lex)\ +""" + ucode_str = \ +"""\ +GroebnerBasis([], x, y, domain=ℤ, order=lex)\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + F = [x**2 - 3*y - x + 1, y**2 - 2*x + y - 1] + expr = groebner(F, x, y, order='grlex') + + ascii_str = \ +"""\ + /[ 2 2 ] \\\n\ +GroebnerBasis\\[x - x - 3*y + 1, y - 2*x + y - 1], x, y, domain=ZZ, order=grlex/\ +""" + ucode_str = \ +"""\ + ⎛⎡ 2 2 ⎤ ⎞\n\ +GroebnerBasis⎝⎣x - x - 3⋅y + 1, y - 2⋅x + y - 1⎦, x, y, domain=ℤ, order=grlex⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = expr.fglm('lex') + + ascii_str = \ +"""\ + /[ 2 4 3 2 ] \\\n\ +GroebnerBasis\\[2*x - y - y + 1, y + 2*y - 3*y - 16*y + 7], x, y, domain=ZZ, order=lex/\ +""" + ucode_str = \ +"""\ + ⎛⎡ 2 4 3 2 ⎤ ⎞\n\ +GroebnerBasis⎝⎣2⋅x - y - y + 1, y + 2⋅y - 3⋅y - 16⋅y + 7⎦, x, y, domain=ℤ, order=lex⎠\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_UniversalSet(): + assert pretty(S.UniversalSet) == "UniversalSet" + assert upretty(S.UniversalSet) == '𝕌' + + +def test_pretty_Boolean(): + expr = Not(x, evaluate=False) + + assert pretty(expr) == "Not(x)" + assert upretty(expr) == "¬x" + + expr = And(x, y) + + assert pretty(expr) == "And(x, y)" + assert upretty(expr) == "x ∧ y" + + expr = Or(x, y) + + assert pretty(expr) == "Or(x, y)" + assert upretty(expr) == "x ∨ y" + + syms = symbols('a:f') + expr = And(*syms) + + assert pretty(expr) == "And(a, b, c, d, e, f)" + assert upretty(expr) == "a ∧ b ∧ c ∧ d ∧ e ∧ f" + + expr = Or(*syms) + + assert pretty(expr) == "Or(a, b, c, d, e, f)" + assert upretty(expr) == "a ∨ b ∨ c ∨ d ∨ e ∨ f" + + expr = Xor(x, y, evaluate=False) + + assert pretty(expr) == "Xor(x, y)" + assert upretty(expr) == "x ⊻ y" + + expr = Nand(x, y, evaluate=False) + + assert pretty(expr) == "Nand(x, y)" + assert upretty(expr) == "x ⊼ y" + + expr = Nor(x, y, evaluate=False) + + assert pretty(expr) == "Nor(x, y)" + assert upretty(expr) == "x ⊽ y" + + expr = Implies(x, y, evaluate=False) + + assert pretty(expr) == "Implies(x, y)" + assert upretty(expr) == "x → y" + + # don't sort args + expr = Implies(y, x, evaluate=False) + + assert pretty(expr) == "Implies(y, x)" + assert upretty(expr) == "y → x" + + expr = Equivalent(x, y, evaluate=False) + + assert pretty(expr) == "Equivalent(x, y)" + assert upretty(expr) == "x ⇔ y" + + expr = Equivalent(y, x, evaluate=False) + + assert pretty(expr) == "Equivalent(x, y)" + assert upretty(expr) == "x ⇔ y" + + +def test_pretty_Domain(): + expr = FF(23) + + assert pretty(expr) == "GF(23)" + assert upretty(expr) == "ℤ₂₃" + + expr = ZZ + + assert pretty(expr) == "ZZ" + assert upretty(expr) == "ℤ" + + expr = QQ + + assert pretty(expr) == "QQ" + assert upretty(expr) == "ℚ" + + expr = RR + + assert pretty(expr) == "RR" + assert upretty(expr) == "ℝ" + + expr = QQ[x] + + assert pretty(expr) == "QQ[x]" + assert upretty(expr) == "ℚ[x]" + + expr = QQ[x, y] + + assert pretty(expr) == "QQ[x, y]" + assert upretty(expr) == "ℚ[x, y]" + + expr = ZZ.frac_field(x) + + assert pretty(expr) == "ZZ(x)" + assert upretty(expr) == "ℤ(x)" + + expr = ZZ.frac_field(x, y) + + assert pretty(expr) == "ZZ(x, y)" + assert upretty(expr) == "ℤ(x, y)" + + expr = QQ.poly_ring(x, y, order=grlex) + + assert pretty(expr) == "QQ[x, y, order=grlex]" + assert upretty(expr) == "ℚ[x, y, order=grlex]" + + expr = QQ.poly_ring(x, y, order=ilex) + + assert pretty(expr) == "QQ[x, y, order=ilex]" + assert upretty(expr) == "ℚ[x, y, order=ilex]" + + +def test_pretty_prec(): + assert xpretty(S("0.3"), full_prec=True, wrap_line=False) == "0.300000000000000" + assert xpretty(S("0.3"), full_prec="auto", wrap_line=False) == "0.300000000000000" + assert xpretty(S("0.3"), full_prec=False, wrap_line=False) == "0.3" + assert xpretty(S("0.3")*x, full_prec=True, use_unicode=False, wrap_line=False) in [ + "0.300000000000000*x", + "x*0.300000000000000" + ] + assert xpretty(S("0.3")*x, full_prec="auto", use_unicode=False, wrap_line=False) in [ + "0.3*x", + "x*0.3" + ] + assert xpretty(S("0.3")*x, full_prec=False, use_unicode=False, wrap_line=False) in [ + "0.3*x", + "x*0.3" + ] + + +def test_pprint(): + import sys + from io import StringIO + fd = StringIO() + sso = sys.stdout + sys.stdout = fd + try: + pprint(pi, use_unicode=False, wrap_line=False) + finally: + sys.stdout = sso + assert fd.getvalue() == 'pi\n' + + +def test_pretty_class(): + """Test that the printer dispatcher correctly handles classes.""" + class C: + pass # C has no .__class__ and this was causing problems + + class D: + pass + + assert pretty( C ) == str( C ) + assert pretty( D ) == str( D ) + + +def test_pretty_no_wrap_line(): + huge_expr = 0 + for i in range(20): + huge_expr += i*sin(i + x) + assert xpretty(huge_expr ).find('\n') != -1 + assert xpretty(huge_expr, wrap_line=False).find('\n') == -1 + + +def test_settings(): + raises(TypeError, lambda: pretty(S(4), method="garbage")) + + +def test_pretty_sum(): + from sympy.abc import x, a, b, k, m, n + + expr = Sum(k**k, (k, 0, n)) + ascii_str = \ +"""\ + n \n\ +___ \n\ +\\ ` \n\ + \\ k\n\ + / k \n\ +/__, \n\ +k = 0 \ +""" + ucode_str = \ +"""\ + n \n\ + ___ \n\ + ╲ \n\ + ╲ k\n\ + ╱ k \n\ + ╱ \n\ + ‾‾‾ \n\ +k = 0 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(k**k, (k, oo, n)) + ascii_str = \ +"""\ + n \n\ + ___ \n\ + \\ ` \n\ + \\ k\n\ + / k \n\ + /__, \n\ +k = oo \ +""" + ucode_str = \ +"""\ + n \n\ + ___ \n\ + ╲ \n\ + ╲ k\n\ + ╱ k \n\ + ╱ \n\ + ‾‾‾ \n\ +k = ∞ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(k**(Integral(x**n, (x, -oo, oo))), (k, 0, n**n)) + ascii_str = \ +"""\ + n \n\ + n \n\ +______ \n\ +\\ ` \n\ + \\ oo \n\ + \\ / \n\ + \\ | \n\ + \\ | n \n\ + ) | x dx\n\ + / | \n\ + / / \n\ + / -oo \n\ + / k \n\ +/_____, \n\ + k = 0 \ +""" + ucode_str = \ +"""\ + n \n\ + n \n\ +______ \n\ +╲ \n\ + ╲ \n\ + ╲ ∞ \n\ + ╲ ⌠ \n\ + ╲ ⎮ n \n\ + ╱ ⎮ x dx\n\ + ╱ ⌡ \n\ + ╱ -∞ \n\ + ╱ k \n\ +╱ \n\ +‾‾‾‾‾‾ \n\ +k = 0 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(k**( + Integral(x**n, (x, -oo, oo))), (k, 0, Integral(x**x, (x, -oo, oo)))) + ascii_str = \ +"""\ + oo \n\ + / \n\ + | \n\ + | x \n\ + | x dx \n\ + | \n\ +/ \n\ +-oo \n\ + ______ \n\ + \\ ` \n\ + \\ oo \n\ + \\ / \n\ + \\ | \n\ + \\ | n \n\ + ) | x dx\n\ + / | \n\ + / / \n\ + / -oo \n\ + / k \n\ + /_____, \n\ + k = 0 \ +""" + ucode_str = \ +"""\ +∞ \n\ +⌠ \n\ +⎮ x \n\ +⎮ x dx \n\ +⌡ \n\ +-∞ \n\ + ______ \n\ + ╲ \n\ + ╲ \n\ + ╲ ∞ \n\ + ╲ ⌠ \n\ + ╲ ⎮ n \n\ + ╱ ⎮ x dx\n\ + ╱ ⌡ \n\ + ╱ -∞ \n\ + ╱ k \n\ + ╱ \n\ + ‾‾‾‾‾‾ \n\ + k = 0 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(k**(Integral(x**n, (x, -oo, oo))), ( + k, x + n + x**2 + n**2 + (x/n) + (1/x), Integral(x**x, (x, -oo, oo)))) + ascii_str = \ +"""\ + oo \n\ + / \n\ + | \n\ + | x \n\ + | x dx \n\ + | \n\ + / \n\ + -oo \n\ + ______ \n\ + \\ ` \n\ + \\ oo \n\ + \\ / \n\ + \\ | \n\ + \\ | n \n\ + ) | x dx\n\ + / | \n\ + / / \n\ + / -oo \n\ + / k \n\ + /_____, \n\ + 2 2 1 x \n\ +k = n + n + x + x + - + - \n\ + x n \ +""" + ucode_str = \ +"""\ + ∞ \n\ + ⌠ \n\ + ⎮ x \n\ + ⎮ x dx \n\ + ⌡ \n\ + -∞ \n\ + ______ \n\ + ╲ \n\ + ╲ \n\ + ╲ ∞ \n\ + ╲ ⌠ \n\ + ╲ ⎮ n \n\ + ╱ ⎮ x dx\n\ + ╱ ⌡ \n\ + ╱ -∞ \n\ + ╱ k \n\ + ╱ \n\ + ‾‾‾‾‾‾ \n\ + 2 2 1 x \n\ +k = n + n + x + x + ─ + ─ \n\ + x n \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(k**( + Integral(x**n, (x, -oo, oo))), (k, 0, x + n + x**2 + n**2 + (x/n) + (1/x))) + ascii_str = \ +"""\ + 2 2 1 x \n\ +n + n + x + x + - + - \n\ + x n \n\ + ______ \n\ + \\ ` \n\ + \\ oo \n\ + \\ / \n\ + \\ | \n\ + \\ | n \n\ + ) | x dx\n\ + / | \n\ + / / \n\ + / -oo \n\ + / k \n\ + /_____, \n\ + k = 0 \ +""" + ucode_str = \ +"""\ + 2 2 1 x \n\ +n + n + x + x + ─ + ─ \n\ + x n \n\ + ______ \n\ + ╲ \n\ + ╲ \n\ + ╲ ∞ \n\ + ╲ ⌠ \n\ + ╲ ⎮ n \n\ + ╱ ⎮ x dx\n\ + ╱ ⌡ \n\ + ╱ -∞ \n\ + ╱ k \n\ + ╱ \n\ + ‾‾‾‾‾‾ \n\ + k = 0 \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(x, (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ + __ \n\ + \\ ` \n\ + ) x\n\ + /_, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ + ___ \n\ + ╲ \n\ + ╲ \n\ + ╱ x\n\ + ╱ \n\ + ‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(x**2, (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ +___ \n\ +\\ ` \n\ + \\ 2\n\ + / x \n\ +/__, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ + ___ \n\ + ╲ \n\ + ╲ 2\n\ + ╱ x \n\ + ╱ \n\ + ‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(x/2, (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ +___ \n\ +\\ ` \n\ + \\ x\n\ + ) -\n\ + / 2\n\ +/__, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ +____ \n\ +╲ \n\ + ╲ \n\ + ╲ x\n\ + ╱ ─\n\ + ╱ 2\n\ +╱ \n\ +‾‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(x**3/2, (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ +____ \n\ +\\ ` \n\ + \\ 3\n\ + \\ x \n\ + / --\n\ + / 2 \n\ +/___, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ +____ \n\ +╲ \n\ + ╲ 3\n\ + ╲ x \n\ + ╱ ──\n\ + ╱ 2 \n\ +╱ \n\ +‾‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum((x**3*y**(x/2))**n, (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ +____ \n\ +\\ ` \n\ + \\ n\n\ + \\ / x\\ \n\ + ) | -| \n\ + / | 3 2| \n\ + / \\x *y / \n\ +/___, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ +_____ \n\ +╲ \n\ + ╲ \n\ + ╲ n\n\ + ╲ ⎛ x⎞ \n\ + ╱ ⎜ ─⎟ \n\ + ╱ ⎜ 3 2⎟ \n\ + ╱ ⎝x ⋅y ⎠ \n\ +╱ \n\ +‾‾‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(1/x**2, (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ +____ \n\ +\\ ` \n\ + \\ 1 \n\ + \\ --\n\ + / 2\n\ + / x \n\ +/___, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ +____ \n\ +╲ \n\ + ╲ 1 \n\ + ╲ ──\n\ + ╱ 2\n\ + ╱ x \n\ +╱ \n\ +‾‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(1/y**(a/b), (x, 0, oo)) + ascii_str = \ +"""\ + oo \n\ +____ \n\ +\\ ` \n\ + \\ -a \n\ + \\ ---\n\ + / b \n\ + / y \n\ +/___, \n\ +x = 0 \ +""" + ucode_str = \ +"""\ + ∞ \n\ +____ \n\ +╲ \n\ + ╲ -a \n\ + ╲ ───\n\ + ╱ b \n\ + ╱ y \n\ +╱ \n\ +‾‾‾‾ \n\ +x = 0 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Sum(1/y**(a/b), (x, 0, oo), (y, 1, 2)) + ascii_str = \ +"""\ + 2 oo \n\ +____ ____ \n\ +\\ ` \\ ` \n\ + \\ \\ -a\n\ + \\ \\ --\n\ + / / b \n\ + / / y \n\ +/___, /___, \n\ +y = 1 x = 0 \ +""" + ucode_str = \ +"""\ + 2 ∞ \n\ +____ ____ \n\ +╲ ╲ \n\ + ╲ ╲ -a\n\ + ╲ ╲ ──\n\ + ╱ ╱ b \n\ + ╱ ╱ y \n\ +╱ ╱ \n\ +‾‾‾‾ ‾‾‾‾ \n\ +y = 1 x = 0 \ +""" + expr = Sum(1/(1 + 1/( + 1 + 1/k)) + 1, (k, 111, 1 + 1/n), (k, 1/(1 + m), oo)) + 1/(1 + 1/k) + ascii_str = \ +"""\ + 1 \n\ + 1 + - \n\ + oo n \n\ + _____ _____ \n\ + \\ ` \\ ` \n\ + \\ \\ / 1 \\ \n\ + \\ \\ |1 + ---------| \n\ + \\ \\ | 1 | 1 \n\ + ) ) | 1 + -----| + -----\n\ + / / | 1| 1\n\ + / / | 1 + -| 1 + -\n\ + / / \\ k/ k\n\ + /____, /____, \n\ + 1 k = 111 \n\ +k = ----- \n\ + m + 1 \ +""" + ucode_str = \ +"""\ + 1 \n\ + 1 + ─ \n\ + ∞ n \n\ + ______ ______ \n\ + ╲ ╲ \n\ + ╲ ╲ \n\ + ╲ ╲ ⎛ 1 ⎞ \n\ + ╲ ╲ ⎜1 + ─────────⎟ \n\ + ╲ ╲ ⎜ 1 ⎟ 1 \n\ + ╱ ╱ ⎜ 1 + ─────⎟ + ─────\n\ + ╱ ╱ ⎜ 1⎟ 1\n\ + ╱ ╱ ⎜ 1 + ─⎟ 1 + ─\n\ + ╱ ╱ ⎝ k⎠ k\n\ + ╱ ╱ \n\ + ‾‾‾‾‾‾ ‾‾‾‾‾‾ \n\ + 1 k = 111 \n\ +k = ───── \n\ + m + 1 \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_units(): + expr = joule + ascii_str1 = \ +"""\ + 2\n\ +kilogram*meter \n\ +---------------\n\ + 2 \n\ + second \ +""" + unicode_str1 = \ +"""\ + 2\n\ +kilogram⋅meter \n\ +───────────────\n\ + 2 \n\ + second \ +""" + + ascii_str2 = \ +"""\ + 2\n\ +3*x*y*kilogram*meter \n\ +---------------------\n\ + 2 \n\ + second \ +""" + unicode_str2 = \ +"""\ + 2\n\ +3⋅x⋅y⋅kilogram⋅meter \n\ +─────────────────────\n\ + 2 \n\ + second \ +""" + + from sympy.physics.units import kg, m, s + assert upretty(expr) == "joule" + assert pretty(expr) == "joule" + assert upretty(expr.convert_to(kg*m**2/s**2)) == unicode_str1 + assert pretty(expr.convert_to(kg*m**2/s**2)) == ascii_str1 + assert upretty(3*kg*x*m**2*y/s**2) == unicode_str2 + assert pretty(3*kg*x*m**2*y/s**2) == ascii_str2 + + +def test_pretty_Subs(): + f = Function('f') + expr = Subs(f(x), x, ph**2) + ascii_str = \ +"""\ +(f(x))| 2\n\ + |x=phi \ +""" + unicode_str = \ +"""\ +(f(x))│ 2\n\ + │x=φ \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + + expr = Subs(f(x).diff(x), x, 0) + ascii_str = \ +"""\ +/d \\| \n\ +|--(f(x))|| \n\ +\\dx /|x=0\ +""" + unicode_str = \ +"""\ +⎛d ⎞│ \n\ +⎜──(f(x))⎟│ \n\ +⎝dx ⎠│x=0\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + + expr = Subs(f(x).diff(x)/y, (x, y), (0, Rational(1, 2))) + ascii_str = \ +"""\ +/d \\| \n\ +|--(f(x))|| \n\ +|dx || \n\ +|--------|| \n\ +\\ y /|x=0, y=1/2\ +""" + unicode_str = \ +"""\ +⎛d ⎞│ \n\ +⎜──(f(x))⎟│ \n\ +⎜dx ⎟│ \n\ +⎜────────⎟│ \n\ +⎝ y ⎠│x=0, y=1/2\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == unicode_str + + +def test_gammas(): + assert upretty(lowergamma(x, y)) == "γ(x, y)" + assert upretty(uppergamma(x, y)) == "Γ(x, y)" + assert xpretty(gamma(x), use_unicode=True) == 'Γ(x)' + assert xpretty(gamma, use_unicode=True) == 'Γ' + assert xpretty(symbols('gamma', cls=Function)(x), use_unicode=True) == 'γ(x)' + assert xpretty(symbols('gamma', cls=Function), use_unicode=True) == 'γ' + + +def test_beta(): + assert xpretty(beta(x,y), use_unicode=True) == 'Β(x, y)' + assert xpretty(beta(x,y), use_unicode=False) == 'B(x, y)' + assert xpretty(beta, use_unicode=True) == 'Β' + assert xpretty(beta, use_unicode=False) == 'B' + mybeta = Function('beta') + assert xpretty(mybeta(x), use_unicode=True) == 'β(x)' + assert xpretty(mybeta(x, y, z), use_unicode=False) == 'beta(x, y, z)' + assert xpretty(mybeta, use_unicode=True) == 'β' + + +# test that notation passes to subclasses of the same name only +def test_function_subclass_different_name(): + class mygamma(gamma): + pass + assert xpretty(mygamma, use_unicode=True) == r"mygamma" + assert xpretty(mygamma(x), use_unicode=True) == r"mygamma(x)" + + +def test_SingularityFunction(): + assert xpretty(SingularityFunction(x, 0, n), use_unicode=True) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, 1, n), use_unicode=True) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, -1, n), use_unicode=True) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, a, n), use_unicode=True) == ( +"""\ + n\n\ +<-a + x> \ +""") + assert xpretty(SingularityFunction(x, y, n), use_unicode=True) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, 0, n), use_unicode=False) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, 1, n), use_unicode=False) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, -1, n), use_unicode=False) == ( +"""\ + n\n\ + \ +""") + assert xpretty(SingularityFunction(x, a, n), use_unicode=False) == ( +"""\ + n\n\ +<-a + x> \ +""") + assert xpretty(SingularityFunction(x, y, n), use_unicode=False) == ( +"""\ + n\n\ + \ +""") + + +def test_deltas(): + assert xpretty(DiracDelta(x), use_unicode=True) == 'δ(x)' + assert xpretty(DiracDelta(x, 1), use_unicode=True) == \ +"""\ + (1) \n\ +δ (x)\ +""" + assert xpretty(x*DiracDelta(x, 1), use_unicode=True) == \ +"""\ + (1) \n\ +x⋅δ (x)\ +""" + + +def test_hyper(): + expr = hyper((), (), z) + ucode_str = \ +"""\ + ┌─ ⎛ │ ⎞\n\ + ├─ ⎜ │ z⎟\n\ +0╵ 0 ⎝ │ ⎠\ +""" + ascii_str = \ +"""\ + _ \n\ + |_ / | \\\n\ + | | | z|\n\ +0 0 \\ | /\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hyper((), (1,), x) + ucode_str = \ +"""\ + ┌─ ⎛ │ ⎞\n\ + ├─ ⎜ │ x⎟\n\ +0╵ 1 ⎝1 │ ⎠\ +""" + ascii_str = \ +"""\ + _ \n\ + |_ / | \\\n\ + | | | x|\n\ +0 1 \\1 | /\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hyper([2], [1], x) + ucode_str = \ +"""\ + ┌─ ⎛2 │ ⎞\n\ + ├─ ⎜ │ x⎟\n\ +1╵ 1 ⎝1 │ ⎠\ +""" + ascii_str = \ +"""\ + _ \n\ + |_ /2 | \\\n\ + | | | x|\n\ +1 1 \\1 | /\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hyper((pi/3, -2*k), (3, 4, 5, -3), x) + ucode_str = \ +"""\ + ⎛ π │ ⎞\n\ + ┌─ ⎜ ─, -2⋅k │ ⎟\n\ + ├─ ⎜ 3 │ x⎟\n\ +2╵ 4 ⎜ │ ⎟\n\ + ⎝-3, 3, 4, 5 │ ⎠\ +""" + ascii_str = \ +"""\ + \n\ + _ / pi | \\\n\ + |_ | --, -2*k | |\n\ + | | 3 | x|\n\ +2 4 | | |\n\ + \\-3, 3, 4, 5 | /\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hyper((pi, S('2/3'), -2*k), (3, 4, 5, -3), x**2) + ucode_str = \ +"""\ + ┌─ ⎛2/3, π, -2⋅k │ 2⎞\n\ + ├─ ⎜ │ x ⎟\n\ +3╵ 4 ⎝-3, 3, 4, 5 │ ⎠\ +""" + ascii_str = \ +"""\ + _ \n\ + |_ /2/3, pi, -2*k | 2\\ + | | | x | +3 4 \\ -3, 3, 4, 5 | /""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hyper([1, 2], [3, 4], 1/(1/(1/(1/x + 1) + 1) + 1)) + ucode_str = \ +"""\ + ⎛ │ 1 ⎞\n\ + ⎜ │ ─────────────⎟\n\ + ⎜ │ 1 ⎟\n\ + ┌─ ⎜1, 2 │ 1 + ─────────⎟\n\ + ├─ ⎜ │ 1 ⎟\n\ +2╵ 2 ⎜3, 4 │ 1 + ─────⎟\n\ + ⎜ │ 1⎟\n\ + ⎜ │ 1 + ─⎟\n\ + ⎝ │ x⎠\ +""" + + ascii_str = \ +"""\ + \n\ + / | 1 \\\n\ + | | -------------|\n\ + _ | | 1 |\n\ + |_ |1, 2 | 1 + ---------|\n\ + | | | 1 |\n\ +2 2 |3, 4 | 1 + -----|\n\ + | | 1|\n\ + | | 1 + -|\n\ + \\ | x/\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_meijerg(): + expr = meijerg([pi, pi, x], [1], [0, 1], [1, 2, 3], z) + ucode_str = \ +"""\ +╭─╮2, 3 ⎛π, π, x 1 │ ⎞\n\ +│╶┐ ⎜ │ z⎟\n\ +╰─╯4, 5 ⎝ 0, 1 1, 2, 3 │ ⎠\ +""" + ascii_str = \ +"""\ + __2, 3 /pi, pi, x 1 | \\\n\ +/__ | | z|\n\ +\\_|4, 5 \\ 0, 1 1, 2, 3 | /\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = meijerg([1, pi/7], [2, pi, 5], [], [], z**2) + ucode_str = \ +"""\ + ⎛ π │ ⎞\n\ +╭─╮0, 2 ⎜1, ─ 2, 5, π │ 2⎟\n\ +│╶┐ ⎜ 7 │ z ⎟\n\ +╰─╯5, 0 ⎜ │ ⎟\n\ + ⎝ │ ⎠\ +""" + ascii_str = \ +"""\ + / pi | \\\n\ + __0, 2 |1, -- 2, 5, pi | 2|\n\ +/__ | 7 | z |\n\ +\\_|5, 0 | | |\n\ + \\ | /\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + ucode_str = \ +"""\ +╭─╮ 1, 10 ⎛1, 1, 1, 1, 1, 1, 1, 1, 1, 1 1 │ ⎞\n\ +│╶┐ ⎜ │ z⎟\n\ +╰─╯11, 2 ⎝ 1 1 │ ⎠\ +""" + ascii_str = \ +"""\ + __ 1, 10 /1, 1, 1, 1, 1, 1, 1, 1, 1, 1 1 | \\\n\ +/__ | | z|\n\ +\\_|11, 2 \\ 1 1 | /\ +""" + + expr = meijerg([1]*10, [1], [1], [1], z) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = meijerg([1, 2, ], [4, 3], [3], [4, 5], 1/(1/(1/(1/x + 1) + 1) + 1)) + + ucode_str = \ +"""\ + ⎛ │ 1 ⎞\n\ + ⎜ │ ─────────────⎟\n\ + ⎜ │ 1 ⎟\n\ +╭─╮1, 2 ⎜1, 2 3, 4 │ 1 + ─────────⎟\n\ +│╶┐ ⎜ │ 1 ⎟\n\ +╰─╯4, 3 ⎜ 3 4, 5 │ 1 + ─────⎟\n\ + ⎜ │ 1⎟\n\ + ⎜ │ 1 + ─⎟\n\ + ⎝ │ x⎠\ +""" + + ascii_str = \ +"""\ + / | 1 \\\n\ + | | -------------|\n\ + | | 1 |\n\ + __1, 2 |1, 2 3, 4 | 1 + ---------|\n\ +/__ | | 1 |\n\ +\\_|4, 3 | 3 4, 5 | 1 + -----|\n\ + | | 1|\n\ + | | 1 + -|\n\ + \\ | x/\ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = Integral(expr, x) + + ucode_str = \ +"""\ +⌠ \n\ +⎮ ⎛ │ 1 ⎞ \n\ +⎮ ⎜ │ ─────────────⎟ \n\ +⎮ ⎜ │ 1 ⎟ \n\ +⎮ ╭─╮1, 2 ⎜1, 2 3, 4 │ 1 + ─────────⎟ \n\ +⎮ │╶┐ ⎜ │ 1 ⎟ dx\n\ +⎮ ╰─╯4, 3 ⎜ 3 4, 5 │ 1 + ─────⎟ \n\ +⎮ ⎜ │ 1⎟ \n\ +⎮ ⎜ │ 1 + ─⎟ \n\ +⎮ ⎝ │ x⎠ \n\ +⌡ \ +""" + + ascii_str = \ +"""\ + / \n\ + | \n\ + | / | 1 \\ \n\ + | | | -------------| \n\ + | | | 1 | \n\ + | __1, 2 |1, 2 3, 4 | 1 + ---------| \n\ + | /__ | | 1 | dx\n\ + | \\_|4, 3 | 3 4, 5 | 1 + -----| \n\ + | | | 1| \n\ + | | | 1 + -| \n\ + | \\ | x/ \n\ + | \n\ +/ \ +""" + + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_noncommutative(): + A, B, C = symbols('A,B,C', commutative=False) + + expr = A*B*C**-1 + ascii_str = \ +"""\ + -1\n\ +A*B*C \ +""" + ucode_str = \ +"""\ + -1\n\ +A⋅B⋅C \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = C**-1*A*B + ascii_str = \ +"""\ + -1 \n\ +C *A*B\ +""" + ucode_str = \ +"""\ + -1 \n\ +C ⋅A⋅B\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A*C**-1*B + ascii_str = \ +"""\ + -1 \n\ +A*C *B\ +""" + ucode_str = \ +"""\ + -1 \n\ +A⋅C ⋅B\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A*C**-1*B/x + ascii_str = \ +"""\ + -1 \n\ +A*C *B\n\ +-------\n\ + x \ +""" + ucode_str = \ +"""\ + -1 \n\ +A⋅C ⋅B\n\ +───────\n\ + x \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_special_functions(): + x, y = symbols("x y") + + # atan2 + expr = atan2(y/sqrt(200), sqrt(x)) + ascii_str = \ +"""\ + / ___ \\\n\ + |\\/ 2 *y ___|\n\ +atan2|-------, \\/ x |\n\ + \\ 20 /\ +""" + ucode_str = \ +"""\ + ⎛√2⋅y ⎞\n\ +atan2⎜────, √x⎟\n\ + ⎝ 20 ⎠\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_geometry(): + e = Segment((0, 1), (0, 2)) + assert pretty(e) == 'Segment2D(Point2D(0, 1), Point2D(0, 2))' + e = Ray((1, 1), angle=4.02*pi) + assert pretty(e) == 'Ray2D(Point2D(1, 1), Point2D(2, tan(pi/50) + 1))' + + +def test_expint(): + expr = Ei(x) + string = 'Ei(x)' + assert pretty(expr) == string + assert upretty(expr) == string + + expr = expint(1, z) + ucode_str = "E₁(z)" + ascii_str = "expint(1, z)" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + assert pretty(Shi(x)) == 'Shi(x)' + assert pretty(Si(x)) == 'Si(x)' + assert pretty(Ci(x)) == 'Ci(x)' + assert pretty(Chi(x)) == 'Chi(x)' + assert upretty(Shi(x)) == 'Shi(x)' + assert upretty(Si(x)) == 'Si(x)' + assert upretty(Ci(x)) == 'Ci(x)' + assert upretty(Chi(x)) == 'Chi(x)' + + +def test_elliptic_functions(): + ascii_str = \ +"""\ + / 1 \\\n\ +K|-----|\n\ + \\z + 1/\ +""" + ucode_str = \ +"""\ + ⎛ 1 ⎞\n\ +K⎜─────⎟\n\ + ⎝z + 1⎠\ +""" + expr = elliptic_k(1/(z + 1)) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + ascii_str = \ +"""\ + / | 1 \\\n\ +F|1|-----|\n\ + \\ |z + 1/\ +""" + ucode_str = \ +"""\ + ⎛ │ 1 ⎞\n\ +F⎜1│─────⎟\n\ + ⎝ │z + 1⎠\ +""" + expr = elliptic_f(1, 1/(1 + z)) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + ascii_str = \ +"""\ + / 1 \\\n\ +E|-----|\n\ + \\z + 1/\ +""" + ucode_str = \ +"""\ + ⎛ 1 ⎞\n\ +E⎜─────⎟\n\ + ⎝z + 1⎠\ +""" + expr = elliptic_e(1/(z + 1)) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + ascii_str = \ +"""\ + / | 1 \\\n\ +E|1|-----|\n\ + \\ |z + 1/\ +""" + ucode_str = \ +"""\ + ⎛ │ 1 ⎞\n\ +E⎜1│─────⎟\n\ + ⎝ │z + 1⎠\ +""" + expr = elliptic_e(1, 1/(1 + z)) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + ascii_str = \ +"""\ + / |4\\\n\ +Pi|3|-|\n\ + \\ |x/\ +""" + ucode_str = \ +"""\ + ⎛ │4⎞\n\ +Π⎜3│─⎟\n\ + ⎝ │x⎠\ +""" + expr = elliptic_pi(3, 4/x) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + ascii_str = \ +"""\ + / 4| \\\n\ +Pi|3; -|6|\n\ + \\ x| /\ +""" + ucode_str = \ +"""\ + ⎛ 4│ ⎞\n\ +Π⎜3; ─│6⎟\n\ + ⎝ x│ ⎠\ +""" + expr = elliptic_pi(3, 4/x, 6) + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_RandomDomain(): + from sympy.stats import Normal, Die, Exponential, pspace, where + X = Normal('x1', 0, 1) + assert upretty(where(X > 0)) == "Domain: 0 < x₁ ∧ x₁ < ∞" + + D = Die('d1', 6) + assert upretty(where(D > 4)) == 'Domain: d₁ = 5 ∨ d₁ = 6' + + A = Exponential('a', 1) + B = Exponential('b', 1) + assert upretty(pspace(Tuple(A, B)).domain) == \ + 'Domain: 0 ≤ a ∧ 0 ≤ b ∧ a < ∞ ∧ b < ∞' + + +def test_PrettyPoly(): + F = QQ.frac_field(x, y) + R = QQ.poly_ring(x, y) + + expr = F.convert(x/(x + y)) + assert pretty(expr) == "x/(x + y)" + assert upretty(expr) == "x/(x + y)" + + expr = R.convert(x + y) + assert pretty(expr) == "x + y" + assert upretty(expr) == "x + y" + + +def test_issue_6285(): + assert pretty(Pow(2, -5, evaluate=False)) == '1 \n--\n 5\n2 ' + assert pretty(Pow(x, (1/pi))) == \ + ' 1 \n'\ + ' --\n'\ + ' pi\n'\ + 'x ' + + +def test_issue_6359(): + assert pretty(Integral(x**2, x)**2) == \ +"""\ + 2 +/ / \\ \n\ +| | | \n\ +| | 2 | \n\ +| | x dx| \n\ +| | | \n\ +\\/ / \ +""" + assert upretty(Integral(x**2, x)**2) == \ +"""\ + 2 +⎛⌠ ⎞ \n\ +⎜⎮ 2 ⎟ \n\ +⎜⎮ x dx⎟ \n\ +⎝⌡ ⎠ \ +""" + + assert pretty(Sum(x**2, (x, 0, 1))**2) == \ +"""\ + 2\n\ +/ 1 \\ \n\ +|___ | \n\ +|\\ ` | \n\ +| \\ 2| \n\ +| / x | \n\ +|/__, | \n\ +\\x = 0 / \ +""" + assert upretty(Sum(x**2, (x, 0, 1))**2) == \ +"""\ + 2 +⎛ 1 ⎞ \n\ +⎜ ___ ⎟ \n\ +⎜ ╲ ⎟ \n\ +⎜ ╲ 2⎟ \n\ +⎜ ╱ x ⎟ \n\ +⎜ ╱ ⎟ \n\ +⎜ ‾‾‾ ⎟ \n\ +⎝x = 0 ⎠ \ +""" + + assert pretty(Product(x**2, (x, 1, 2))**2) == \ +"""\ + 2 +/ 2 \\ \n\ +|______ | \n\ +| | | 2| \n\ +| | | x | \n\ +| | | | \n\ +\\x = 1 / \ +""" + assert upretty(Product(x**2, (x, 1, 2))**2) == \ +"""\ + 2 +⎛ 2 ⎞ \n\ +⎜─┬──┬─ ⎟ \n\ +⎜ │ │ 2⎟ \n\ +⎜ │ │ x ⎟ \n\ +⎜ │ │ ⎟ \n\ +⎝x = 1 ⎠ \ +""" + + f = Function('f') + assert pretty(Derivative(f(x), x)**2) == \ +"""\ + 2 +/d \\ \n\ +|--(f(x))| \n\ +\\dx / \ +""" + assert upretty(Derivative(f(x), x)**2) == \ +"""\ + 2 +⎛d ⎞ \n\ +⎜──(f(x))⎟ \n\ +⎝dx ⎠ \ +""" + + +def test_issue_6739(): + ascii_str = \ +"""\ + 1 \n\ +-----\n\ + ___\n\ +\\/ x \ +""" + ucode_str = \ +"""\ +1 \n\ +──\n\ +√x\ +""" + assert pretty(1/sqrt(x)) == ascii_str + assert upretty(1/sqrt(x)) == ucode_str + + +def test_complicated_symbol_unchanged(): + for symb_name in ["dexpr2_d1tau", "dexpr2^d1tau"]: + assert pretty(Symbol(symb_name)) == symb_name + + +def test_categories(): + from sympy.categories import (Object, IdentityMorphism, + NamedMorphism, Category, Diagram, DiagramGrid) + + A1 = Object("A1") + A2 = Object("A2") + A3 = Object("A3") + + f1 = NamedMorphism(A1, A2, "f1") + f2 = NamedMorphism(A2, A3, "f2") + id_A1 = IdentityMorphism(A1) + + K1 = Category("K1") + + assert pretty(A1) == "A1" + assert upretty(A1) == "A₁" + + assert pretty(f1) == "f1:A1-->A2" + assert upretty(f1) == "f₁:A₁——▶A₂" + assert pretty(id_A1) == "id:A1-->A1" + assert upretty(id_A1) == "id:A₁——▶A₁" + + assert pretty(f2*f1) == "f2*f1:A1-->A3" + assert upretty(f2*f1) == "f₂∘f₁:A₁——▶A₃" + + assert pretty(K1) == "K1" + assert upretty(K1) == "K₁" + + # Test how diagrams are printed. + d = Diagram() + assert pretty(d) == "EmptySet" + assert upretty(d) == "∅" + + d = Diagram({f1: "unique", f2: S.EmptySet}) + assert pretty(d) == "{f2*f1:A1-->A3: EmptySet, id:A1-->A1: " \ + "EmptySet, id:A2-->A2: EmptySet, id:A3-->A3: " \ + "EmptySet, f1:A1-->A2: {unique}, f2:A2-->A3: EmptySet}" + + assert upretty(d) == "{f₂∘f₁:A₁——▶A₃: ∅, id:A₁——▶A₁: ∅, " \ + "id:A₂——▶A₂: ∅, id:A₃——▶A₃: ∅, f₁:A₁——▶A₂: {unique}, f₂:A₂——▶A₃: ∅}" + + d = Diagram({f1: "unique", f2: S.EmptySet}, {f2 * f1: "unique"}) + assert pretty(d) == "{f2*f1:A1-->A3: EmptySet, id:A1-->A1: " \ + "EmptySet, id:A2-->A2: EmptySet, id:A3-->A3: " \ + "EmptySet, f1:A1-->A2: {unique}, f2:A2-->A3: EmptySet}" \ + " ==> {f2*f1:A1-->A3: {unique}}" + assert upretty(d) == "{f₂∘f₁:A₁——▶A₃: ∅, id:A₁——▶A₁: ∅, id:A₂——▶A₂: " \ + "∅, id:A₃——▶A₃: ∅, f₁:A₁——▶A₂: {unique}, f₂:A₂——▶A₃: ∅}" \ + " ══▶ {f₂∘f₁:A₁——▶A₃: {unique}}" + + grid = DiagramGrid(d) + assert pretty(grid) == "A1 A2\n \nA3 " + assert upretty(grid) == "A₁ A₂\n \nA₃ " + + +def test_PrettyModules(): + R = QQ.old_poly_ring(x, y) + F = R.free_module(2) + M = F.submodule([x, y], [1, x**2]) + + ucode_str = \ +"""\ + 2\n\ +ℚ[x, y] \ +""" + ascii_str = \ +"""\ + 2\n\ +QQ[x, y] \ +""" + + assert upretty(F) == ucode_str + assert pretty(F) == ascii_str + + ucode_str = \ +"""\ +╱ ⎡ 2⎤╲\n\ +╲[x, y], ⎣1, x ⎦╱\ +""" + ascii_str = \ +"""\ + 2 \n\ +<[x, y], [1, x ]>\ +""" + + assert upretty(M) == ucode_str + assert pretty(M) == ascii_str + + I = R.ideal(x**2, y) + + ucode_str = \ +"""\ +╱ 2 ╲\n\ +╲x , y╱\ +""" + + ascii_str = \ +"""\ + 2 \n\ +\ +""" + + assert upretty(I) == ucode_str + assert pretty(I) == ascii_str + + Q = F / M + + ucode_str = \ +"""\ + 2 \n\ + ℚ[x, y] \n\ +─────────────────\n\ +╱ ⎡ 2⎤╲\n\ +╲[x, y], ⎣1, x ⎦╱\ +""" + + ascii_str = \ +"""\ + 2 \n\ + QQ[x, y] \n\ +-----------------\n\ + 2 \n\ +<[x, y], [1, x ]>\ +""" + + assert upretty(Q) == ucode_str + assert pretty(Q) == ascii_str + + ucode_str = \ +"""\ +╱⎡ 3⎤ ╲\n\ +│⎢ x ⎥ ╱ ⎡ 2⎤╲ ╱ ⎡ 2⎤╲│\n\ +│⎢1, ──⎥ + ╲[x, y], ⎣1, x ⎦╱, [2, y] + ╲[x, y], ⎣1, x ⎦╱│\n\ +╲⎣ 2 ⎦ ╱\ +""" + + ascii_str = \ +"""\ + 3 \n\ + x 2 2 \n\ +<[1, --] + <[x, y], [1, x ]>, [2, y] + <[x, y], [1, x ]>>\n\ + 2 \ +""" + + +def test_QuotientRing(): + R = QQ.old_poly_ring(x)/[x**2 + 1] + + ucode_str = \ +"""\ + ℚ[x] \n\ +────────\n\ +╱ 2 ╲\n\ +╲x + 1╱\ +""" + + ascii_str = \ +"""\ + QQ[x] \n\ +--------\n\ + 2 \n\ +\ +""" + + assert upretty(R) == ucode_str + assert pretty(R) == ascii_str + + ucode_str = \ +"""\ + ╱ 2 ╲\n\ +1 + ╲x + 1╱\ +""" + + ascii_str = \ +"""\ + 2 \n\ +1 + \ +""" + + assert upretty(R.one) == ucode_str + assert pretty(R.one) == ascii_str + + +def test_Homomorphism(): + from sympy.polys.agca import homomorphism + + R = QQ.old_poly_ring(x) + + expr = homomorphism(R.free_module(1), R.free_module(1), [0]) + + ucode_str = \ +"""\ + 1 1\n\ +[0] : ℚ[x] ──> ℚ[x] \ +""" + + ascii_str = \ +"""\ + 1 1\n\ +[0] : QQ[x] --> QQ[x] \ +""" + + assert upretty(expr) == ucode_str + assert pretty(expr) == ascii_str + + expr = homomorphism(R.free_module(2), R.free_module(2), [0, 0]) + + ucode_str = \ +"""\ +⎡0 0⎤ 2 2\n\ +⎢ ⎥ : ℚ[x] ──> ℚ[x] \n\ +⎣0 0⎦ \ +""" + + ascii_str = \ +"""\ +[0 0] 2 2\n\ +[ ] : QQ[x] --> QQ[x] \n\ +[0 0] \ +""" + + assert upretty(expr) == ucode_str + assert pretty(expr) == ascii_str + + expr = homomorphism(R.free_module(1), R.free_module(1) / [[x]], [0]) + + ucode_str = \ +"""\ + 1\n\ + 1 ℚ[x] \n\ +[0] : ℚ[x] ──> ─────\n\ + <[x]>\ +""" + + ascii_str = \ +"""\ + 1\n\ + 1 QQ[x] \n\ +[0] : QQ[x] --> ------\n\ + <[x]> \ +""" + + assert upretty(expr) == ucode_str + assert pretty(expr) == ascii_str + + +def test_Tr(): + A, B = symbols('A B', commutative=False) + t = Tr(A*B) + assert pretty(t) == r'Tr(A*B)' + assert upretty(t) == 'Tr(A⋅B)' + + +def test_pretty_Add(): + eq = Mul(-2, x - 2, evaluate=False) + 5 + assert pretty(eq) == '5 - 2*(x - 2)' + + +def test_issue_7179(): + assert upretty(Not(Equivalent(x, y))) == 'x ⇎ y' + assert upretty(Not(Implies(x, y))) == 'x ↛ y' + + +def test_issue_7180(): + assert upretty(Equivalent(x, y)) == 'x ⇔ y' + + +def test_pretty_Complement(): + assert pretty(S.Reals - S.Naturals) == '(-oo, oo) \\ Naturals' + assert upretty(S.Reals - S.Naturals) == 'ℝ \\ ℕ' + assert pretty(S.Reals - S.Naturals0) == '(-oo, oo) \\ Naturals0' + assert upretty(S.Reals - S.Naturals0) == 'ℝ \\ ℕ₀' + + +def test_pretty_SymmetricDifference(): + from sympy.sets.sets import SymmetricDifference + assert upretty(SymmetricDifference(Interval(2,3), Interval(3,5), \ + evaluate = False)) == '[2, 3] ∆ [3, 5]' + with raises(NotImplementedError): + pretty(SymmetricDifference(Interval(2,3), Interval(3,5), evaluate = False)) + + +def test_pretty_Contains(): + assert pretty(Contains(x, S.Integers)) == 'Contains(x, Integers)' + assert upretty(Contains(x, S.Integers)) == 'x ∈ ℤ' + + +def test_issue_8292(): + from sympy.core import sympify + e = sympify('((x+x**4)/(x-1))-(2*(x-1)**4/(x-1)**4)', evaluate=False) + ucode_str = \ +"""\ + 4 4 \n\ + 2⋅(x - 1) x + x\n\ +- ────────── + ──────\n\ + 4 x - 1 \n\ + (x - 1) \ +""" + ascii_str = \ +"""\ + 4 4 \n\ + 2*(x - 1) x + x\n\ +- ---------- + ------\n\ + 4 x - 1 \n\ + (x - 1) \ +""" + assert pretty(e) == ascii_str + assert upretty(e) == ucode_str + + +def test_issue_4335(): + y = Function('y') + expr = -y(x).diff(x) + ucode_str = \ +"""\ + d \n\ +-──(y(x))\n\ + dx \ +""" + ascii_str = \ +"""\ + d \n\ +- --(y(x))\n\ + dx \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_issue_8344(): + from sympy.core import sympify + e = sympify('2*x*y**2/1**2 + 1', evaluate=False) + ucode_str = \ +"""\ + 2 \n\ +2⋅x⋅y \n\ +────── + 1\n\ + 2 \n\ + 1 \ +""" + assert upretty(e) == ucode_str + + +def test_issue_6324(): + x = Pow(2, 3, evaluate=False) + y = Pow(10, -2, evaluate=False) + e = Mul(x, y, evaluate=False) + ucode_str = \ +"""\ + 3 \n\ +2 \n\ +───\n\ + 2\n\ +10 \ +""" + assert upretty(e) == ucode_str + + +def test_issue_7927(): + e = sin(x/2)**cos(x/2) + ucode_str = \ +"""\ + ⎛x⎞\n\ + cos⎜─⎟\n\ + ⎝2⎠\n\ +⎛ ⎛x⎞⎞ \n\ +⎜sin⎜─⎟⎟ \n\ +⎝ ⎝2⎠⎠ \ +""" + assert upretty(e) == ucode_str + e = sin(x)**(S(11)/13) + ucode_str = \ +"""\ + 11\n\ + ──\n\ + 13\n\ +(sin(x)) \ +""" + assert upretty(e) == ucode_str + + +def test_issue_6134(): + from sympy.abc import lamda, t + phi = Function('phi') + + e = lamda*x*Integral(phi(t)*pi*sin(pi*t), (t, 0, 1)) + lamda*x**2*Integral(phi(t)*2*pi*sin(2*pi*t), (t, 0, 1)) + ucode_str = \ +"""\ + 1 1 \n\ + 2 ⌠ ⌠ \n\ +λ⋅x ⋅⎮ 2⋅π⋅φ(t)⋅sin(2⋅π⋅t) dt + λ⋅x⋅⎮ π⋅φ(t)⋅sin(π⋅t) dt\n\ + ⌡ ⌡ \n\ + 0 0 \ +""" + assert upretty(e) == ucode_str + + +def test_issue_9877(): + ucode_str1 = '(2, 3) ∪ ([1, 2] \\ {x})' + a, b, c = Interval(2, 3, True, True), Interval(1, 2), FiniteSet(x) + assert upretty(Union(a, Complement(b, c))) == ucode_str1 + + ucode_str2 = '{x} ∩ {y} ∩ ({z} \\ [1, 2])' + d, e, f, g = FiniteSet(x), FiniteSet(y), FiniteSet(z), Interval(1, 2) + assert upretty(Intersection(d, e, Complement(f, g))) == ucode_str2 + + +def test_issue_13651(): + expr1 = c + Mul(-1, a + b, evaluate=False) + assert pretty(expr1) == 'c - (a + b)' + expr2 = c + Mul(-1, a - b + d, evaluate=False) + assert pretty(expr2) == 'c - (a - b + d)' + + +def test_pretty_primenu(): + from sympy.functions.combinatorial.numbers import primenu + + ascii_str1 = "nu(n)" + ucode_str1 = "ν(n)" + + n = symbols('n', integer=True) + assert pretty(primenu(n)) == ascii_str1 + assert upretty(primenu(n)) == ucode_str1 + + +def test_pretty_primeomega(): + from sympy.functions.combinatorial.numbers import primeomega + + ascii_str1 = "Omega(n)" + ucode_str1 = "Ω(n)" + + n = symbols('n', integer=True) + assert pretty(primeomega(n)) == ascii_str1 + assert upretty(primeomega(n)) == ucode_str1 + + +def test_pretty_Mod(): + from sympy.core import Mod + + ascii_str1 = "x mod 7" + ucode_str1 = "x mod 7" + + ascii_str2 = "(x + 1) mod 7" + ucode_str2 = "(x + 1) mod 7" + + ascii_str3 = "2*x mod 7" + ucode_str3 = "2⋅x mod 7" + + ascii_str4 = "(x mod 7) + 1" + ucode_str4 = "(x mod 7) + 1" + + ascii_str5 = "2*(x mod 7)" + ucode_str5 = "2⋅(x mod 7)" + + x = symbols('x', integer=True) + assert pretty(Mod(x, 7)) == ascii_str1 + assert upretty(Mod(x, 7)) == ucode_str1 + assert pretty(Mod(x + 1, 7)) == ascii_str2 + assert upretty(Mod(x + 1, 7)) == ucode_str2 + assert pretty(Mod(2 * x, 7)) == ascii_str3 + assert upretty(Mod(2 * x, 7)) == ucode_str3 + assert pretty(Mod(x, 7) + 1) == ascii_str4 + assert upretty(Mod(x, 7) + 1) == ucode_str4 + assert pretty(2 * Mod(x, 7)) == ascii_str5 + assert upretty(2 * Mod(x, 7)) == ucode_str5 + + +def test_issue_11801(): + assert pretty(Symbol("")) == "" + assert upretty(Symbol("")) == "" + + +def test_pretty_UnevaluatedExpr(): + x = symbols('x') + he = UnevaluatedExpr(1/x) + + ucode_str = \ +"""\ +1\n\ +─\n\ +x\ +""" + + assert upretty(he) == ucode_str + + ucode_str = \ +"""\ + 2\n\ +⎛1⎞ \n\ +⎜─⎟ \n\ +⎝x⎠ \ +""" + + assert upretty(he**2) == ucode_str + + ucode_str = \ +"""\ + 1\n\ +1 + ─\n\ + x\ +""" + + assert upretty(he + 1) == ucode_str + + ucode_str = \ +('''\ + 1\n\ +x⋅─\n\ + x\ +''') + assert upretty(x*he) == ucode_str + + +def test_issue_10472(): + M = (Matrix([[0, 0], [0, 0]]), Matrix([0, 0])) + + ucode_str = \ +"""\ +⎛⎡0 0⎤ ⎡0⎤⎞ +⎜⎢ ⎥, ⎢ ⎥⎟ +⎝⎣0 0⎦ ⎣0⎦⎠\ +""" + assert upretty(M) == ucode_str + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + ascii_str1 = "A_00" + ucode_str1 = "A₀₀" + assert pretty(A[0, 0]) == ascii_str1 + assert upretty(A[0, 0]) == ucode_str1 + + ascii_str1 = "3*A_00" + ucode_str1 = "3⋅A₀₀" + assert pretty(3*A[0, 0]) == ascii_str1 + assert upretty(3*A[0, 0]) == ucode_str1 + + ascii_str1 = "(-B + A)[0, 0]" + ucode_str1 = "(-B + A)[0, 0]" + F = C[0, 0].subs(C, A - B) + assert pretty(F) == ascii_str1 + assert upretty(F) == ucode_str1 + + +def test_issue_12675(): + x, y, t, j = symbols('x y t j') + e = CoordSys3D('e') + + ucode_str = \ +"""\ +⎛ t⎞ \n\ +⎜⎛x⎞ ⎟ j_e\n\ +⎜⎜─⎟ ⎟ \n\ +⎝⎝y⎠ ⎠ \ +""" + assert upretty((x/y)**t*e.j) == ucode_str + ucode_str = \ +"""\ +⎛1⎞ \n\ +⎜─⎟ j_e\n\ +⎝y⎠ \ +""" + assert upretty((1/y)*e.j) == ucode_str + + +def test_MatrixSymbol_printing(): + # test cases for issue #14237 + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + C = MatrixSymbol("C", 3, 3) + assert pretty(-A*B*C) == "-A*B*C" + assert pretty(A - B) == "-B + A" + assert pretty(A*B*C - A*B - B*C) == "-A*B -B*C + A*B*C" + + # issue #14814 + x = MatrixSymbol('x', n, n) + y = MatrixSymbol('y*', n, n) + assert pretty(x + y) == "x + y*" + ascii_str = \ +"""\ + 2 \n\ +-2*y* -a*x\ +""" + assert pretty(-a*x + -2*y*y) == ascii_str + + +def test_degree_printing(): + expr1 = 90*degree + assert pretty(expr1) == '90°' + expr2 = x*degree + assert pretty(expr2) == 'x°' + expr3 = cos(x*degree + 90*degree) + assert pretty(expr3) == 'cos(x° + 90°)' + + +def test_vector_expr_pretty_printing(): + A = CoordSys3D('A') + + assert upretty(Cross(A.i, A.x*A.i+3*A.y*A.j)) == "(i_A)×((x_A) i_A + (3⋅y_A) j_A)" + assert upretty(x*Cross(A.i, A.j)) == 'x⋅(i_A)×(j_A)' + + assert upretty(Curl(A.x*A.i + 3*A.y*A.j)) == "∇×((x_A) i_A + (3⋅y_A) j_A)" + + assert upretty(Divergence(A.x*A.i + 3*A.y*A.j)) == "∇⋅((x_A) i_A + (3⋅y_A) j_A)" + + assert upretty(Dot(A.i, A.x*A.i+3*A.y*A.j)) == "(i_A)⋅((x_A) i_A + (3⋅y_A) j_A)" + + assert upretty(Gradient(A.x+3*A.y)) == "∇(x_A + 3⋅y_A)" + assert upretty(Laplacian(A.x+3*A.y)) == "∆(x_A + 3⋅y_A)" + # TODO: add support for ASCII pretty. + + +def test_pretty_print_tensor_expr(): + L = TensorIndexType("L") + i, j, k = tensor_indices("i j k", L) + i0 = tensor_indices("i_0", L) + A, B, C, D = tensor_heads("A B C D", [L]) + H = TensorHead("H", [L, L]) + + expr = -i + ascii_str = \ +"""\ +-i\ +""" + ucode_str = \ +"""\ +-i\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A(i) + ascii_str = \ +"""\ + i\n\ +A \n\ + \ +""" + ucode_str = \ +"""\ + i\n\ +A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A(i0) + ascii_str = \ +"""\ + i_0\n\ +A \n\ + \ +""" + ucode_str = \ +"""\ + i₀\n\ +A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A(-i) + ascii_str = \ +"""\ + \n\ +A \n\ + i\ +""" + ucode_str = \ +"""\ + \n\ +A \n\ + i\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = -3*A(-i) + ascii_str = \ +"""\ + \n\ +-3*A \n\ + i\ +""" + ucode_str = \ +"""\ + \n\ +-3⋅A \n\ + i\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = H(i, -j) + ascii_str = \ +"""\ + i \n\ +H \n\ + j\ +""" + ucode_str = \ +"""\ + i \n\ +H \n\ + j\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = H(i, -i) + ascii_str = \ +"""\ + L_0 \n\ +H \n\ + L_0\ +""" + ucode_str = \ +"""\ + L₀ \n\ +H \n\ + L₀\ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = H(i, -j)*A(j)*B(k) + ascii_str = \ +"""\ + i L_0 k\n\ +H *A *B \n\ + L_0 \ +""" + ucode_str = \ +"""\ + i L₀ k\n\ +H ⋅A ⋅B \n\ + L₀ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (1+x)*A(i) + ascii_str = \ +"""\ + i\n\ +(x + 1)*A \n\ + \ +""" + ucode_str = \ +"""\ + i\n\ +(x + 1)⋅A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A(i) + 3*B(i) + ascii_str = \ +"""\ + i i\n\ +3*B + A \n\ + \ +""" + ucode_str = \ +"""\ + i i\n\ +3⋅B + A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_pretty_print_tensor_partial_deriv(): + from sympy.tensor.toperators import PartialDerivative + + L = TensorIndexType("L") + i, j, k = tensor_indices("i j k", L) + + A, B, C, D = tensor_heads("A B C D", [L]) + + H = TensorHead("H", [L, L]) + + expr = PartialDerivative(A(i), A(j)) + ascii_str = \ +"""\ + d / i\\\n\ +---|A |\n\ + j\\ /\n\ +dA \n\ + \ +""" + ucode_str = \ +"""\ + ∂ ⎛ i⎞\n\ +───⎜A ⎟\n\ + j⎝ ⎠\n\ +∂A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A(i)*PartialDerivative(H(k, -i), A(j)) + ascii_str = \ +"""\ + L_0 d / k \\\n\ +A *---|H |\n\ + j\\ L_0/\n\ + dA \n\ + \ +""" + ucode_str = \ +"""\ + L₀ ∂ ⎛ k ⎞\n\ +A ⋅───⎜H ⎟\n\ + j⎝ L₀⎠\n\ + ∂A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = A(i)*PartialDerivative(B(k)*C(-i) + 3*H(k, -i), A(j)) + ascii_str = \ +"""\ + L_0 d / k k \\\n\ +A *---|3*H + B *C |\n\ + j\\ L_0 L_0/\n\ + dA \n\ + \ +""" + ucode_str = \ +"""\ + L₀ ∂ ⎛ k k ⎞\n\ +A ⋅───⎜3⋅H + B ⋅C ⎟\n\ + j⎝ L₀ L₀⎠\n\ + ∂A \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (A(i) + B(i))*PartialDerivative(C(j), D(j)) + ascii_str = \ +"""\ +/ i i\\ d / L_0\\\n\ +|A + B |*-----|C |\n\ +\\ / L_0\\ /\n\ + dD \n\ + \ +""" + ucode_str = \ +"""\ +⎛ i i⎞ ∂ ⎛ L₀⎞\n\ +⎜A + B ⎟⋅────⎜C ⎟\n\ +⎝ ⎠ L₀⎝ ⎠\n\ + ∂D \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = (A(i) + B(i))*PartialDerivative(C(-i), D(j)) + ascii_str = \ +"""\ +/ L_0 L_0\\ d / \\\n\ +|A + B |*---|C |\n\ +\\ / j\\ L_0/\n\ + dD \n\ + \ +""" + ucode_str = \ +"""\ +⎛ L₀ L₀⎞ ∂ ⎛ ⎞\n\ +⎜A + B ⎟⋅───⎜C ⎟\n\ +⎝ ⎠ j⎝ L₀⎠\n\ + ∂D \n\ + \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = PartialDerivative(B(-i) + A(-i), A(-j), A(-n)) + ucode_str = """\ + 2 \n\ + ∂ ⎛ ⎞\n\ +───────⎜A + B ⎟\n\ + ⎝ i i⎠\n\ +∂A ∂A \n\ + n j \ +""" + assert upretty(expr) == ucode_str + + expr = PartialDerivative(3*A(-i), A(-j), A(-n)) + ucode_str = """\ + 2 \n\ + ∂ ⎛ ⎞\n\ +───────⎜3⋅A ⎟\n\ + ⎝ i⎠\n\ +∂A ∂A \n\ + n j \ +""" + assert upretty(expr) == ucode_str + + expr = TensorElement(H(i, j), {i:1}) + ascii_str = \ +"""\ + i=1,j\n\ +H \n\ + \ +""" + ucode_str = ascii_str + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = TensorElement(H(i, j), {i: 1, j: 1}) + ascii_str = \ +"""\ + i=1,j=1\n\ +H \n\ + \ +""" + ucode_str = ascii_str + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = TensorElement(H(i, j), {j: 1}) + ascii_str = \ +"""\ + i,j=1\n\ +H \n\ + \ +""" + ucode_str = ascii_str + + expr = TensorElement(H(-i, j), {-i: 1}) + ascii_str = \ +"""\ + j\n\ +H \n\ + i=1 \ +""" + ucode_str = ascii_str + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_issue_15560(): + a = MatrixSymbol('a', 1, 1) + e = pretty(a*(KroneckerProduct(a, a))) + result = 'a*(a x a)' + assert e == result + + +def test_print_polylog(): + # Part of issue 6013 + uresult = 'Li₂(3)' + aresult = 'polylog(2, 3)' + assert pretty(polylog(2, 3)) == aresult + assert upretty(polylog(2, 3)) == uresult + + +# Issue #25312 +def test_print_expint_polylog_symbolic_order(): + s, z = symbols("s, z") + uresult = 'Liₛ(z)' + aresult = 'polylog(s, z)' + assert pretty(polylog(s, z)) == aresult + assert upretty(polylog(s, z)) == uresult + # TODO: TBD polylog(s - 1, z) + uresult = 'Eₛ(z)' + aresult = 'expint(s, z)' + assert pretty(expint(s, z)) == aresult + assert upretty(expint(s, z)) == uresult + + + +def test_print_polylog_long_order_issue_25309(): + s, z = symbols("s, z") + ucode_str = \ +"""\ + ⎛ 2 ⎞\n\ +polylog⎝s , z⎠\ +""" + assert upretty(polylog(s**2, z)) == ucode_str + + +def test_print_lerchphi(): + # Part of issue 6013 + a = Symbol('a') + pretty(lerchphi(a, 1, 2)) + uresult = 'Φ(a, 1, 2)' + aresult = 'lerchphi(a, 1, 2)' + assert pretty(lerchphi(a, 1, 2)) == aresult + assert upretty(lerchphi(a, 1, 2)) == uresult + + +def test_issue_15583(): + + N = mechanics.ReferenceFrame('N') + result = '(n_x, n_y, n_z)' + e = pretty((N.x, N.y, N.z)) + assert e == result + + +def test_matrixSymbolBold(): + # Issue 15871 + def boldpretty(expr): + return xpretty(expr, use_unicode=True, wrap_line=False, mat_symbol_style="bold") + + from sympy.matrices.expressions.trace import trace + A = MatrixSymbol("A", 2, 2) + assert boldpretty(trace(A)) == 'tr(𝐀)' + + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + C = MatrixSymbol("C", 3, 3) + + assert boldpretty(-A) == '-𝐀' + assert boldpretty(A - A*B - B) == '-𝐁 -𝐀⋅𝐁 + 𝐀' + assert boldpretty(-A*B - A*B*C - B) == '-𝐁 -𝐀⋅𝐁 -𝐀⋅𝐁⋅𝐂' + + A = MatrixSymbol("Addot", 3, 3) + assert boldpretty(A) == '𝐀̈' + omega = MatrixSymbol("omega", 3, 3) + assert boldpretty(omega) == 'ω' + omega = MatrixSymbol("omeganorm", 3, 3) + assert boldpretty(omega) == '‖ω‖' + + a = Symbol('alpha') + b = Symbol('b') + c = MatrixSymbol("c", 3, 1) + d = MatrixSymbol("d", 3, 1) + + assert boldpretty(a*B*c+b*d) == 'b⋅𝐝 + α⋅𝐁⋅𝐜' + + d = MatrixSymbol("delta", 3, 1) + B = MatrixSymbol("Beta", 3, 3) + + assert boldpretty(a*B*c+b*d) == 'b⋅δ + α⋅Β⋅𝐜' + + A = MatrixSymbol("A_2", 3, 3) + assert boldpretty(A) == '𝐀₂' + + +def test_center_accent(): + assert center_accent('a', '\N{COMBINING TILDE}') == 'ã' + assert center_accent('aa', '\N{COMBINING TILDE}') == 'aã' + assert center_accent('aaa', '\N{COMBINING TILDE}') == 'aãa' + assert center_accent('aaaa', '\N{COMBINING TILDE}') == 'aaãa' + assert center_accent('aaaaa', '\N{COMBINING TILDE}') == 'aaãaa' + assert center_accent('abcdefg', '\N{COMBINING FOUR DOTS ABOVE}') == 'abcd⃜efg' + + +def test_imaginary_unit(): + from sympy.printing.pretty import pretty # b/c it was redefined above + assert pretty(1 + I, use_unicode=False) == '1 + I' + assert pretty(1 + I, use_unicode=True) == '1 + ⅈ' + assert pretty(1 + I, use_unicode=False, imaginary_unit='j') == '1 + I' + assert pretty(1 + I, use_unicode=True, imaginary_unit='j') == '1 + ⅉ' + + raises(TypeError, lambda: pretty(I, imaginary_unit=I)) + raises(ValueError, lambda: pretty(I, imaginary_unit="kkk")) + + +def test_str_special_matrices(): + from sympy.matrices import Identity, ZeroMatrix, OneMatrix + assert pretty(Identity(4)) == 'I' + assert upretty(Identity(4)) == '𝕀' + assert pretty(ZeroMatrix(2, 2)) == '0' + assert upretty(ZeroMatrix(2, 2)) == '𝟘' + assert pretty(OneMatrix(2, 2)) == '1' + assert upretty(OneMatrix(2, 2)) == '𝟙' + + +def test_pretty_misc_functions(): + assert pretty(LambertW(x)) == 'W(x)' + assert upretty(LambertW(x)) == 'W(x)' + assert pretty(LambertW(x, y)) == 'W(x, y)' + assert upretty(LambertW(x, y)) == 'W(x, y)' + assert pretty(airyai(x)) == 'Ai(x)' + assert upretty(airyai(x)) == 'Ai(x)' + assert pretty(airybi(x)) == 'Bi(x)' + assert upretty(airybi(x)) == 'Bi(x)' + assert pretty(airyaiprime(x)) == "Ai'(x)" + assert upretty(airyaiprime(x)) == "Ai'(x)" + assert pretty(airybiprime(x)) == "Bi'(x)" + assert upretty(airybiprime(x)) == "Bi'(x)" + assert pretty(fresnelc(x)) == 'C(x)' + assert upretty(fresnelc(x)) == 'C(x)' + assert pretty(fresnels(x)) == 'S(x)' + assert upretty(fresnels(x)) == 'S(x)' + assert pretty(Heaviside(x)) == 'Heaviside(x)' + assert upretty(Heaviside(x)) == 'θ(x)' + assert pretty(Heaviside(x, y)) == 'Heaviside(x, y)' + assert upretty(Heaviside(x, y)) == 'θ(x, y)' + assert pretty(dirichlet_eta(x)) == 'dirichlet_eta(x)' + assert upretty(dirichlet_eta(x)) == 'η(x)' + + +def test_hadamard_power(): + m, n, p = symbols('m, n, p', integer=True) + A = MatrixSymbol('A', m, n) + B = MatrixSymbol('B', m, n) + + # Testing printer: + expr = hadamard_power(A, n) + ascii_str = \ +"""\ + .n\n\ +A \ +""" + ucode_str = \ +"""\ + ∘n\n\ +A \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hadamard_power(A, 1+n) + ascii_str = \ +"""\ + .(n + 1)\n\ +A \ +""" + ucode_str = \ +"""\ + ∘(n + 1)\n\ +A \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + expr = hadamard_power(A*B.T, 1+n) + ascii_str = \ +"""\ + .(n + 1)\n\ +/ T\\ \n\ +\\A*B / \ +""" + ucode_str = \ +"""\ + ∘(n + 1)\n\ +⎛ T⎞ \n\ +⎝A⋅B ⎠ \ +""" + assert pretty(expr) == ascii_str + assert upretty(expr) == ucode_str + + +def test_issue_17258(): + n = Symbol('n', integer=True) + assert pretty(Sum(n, (n, -oo, 1))) == \ + ' 1 \n'\ + ' __ \n'\ + ' \\ ` \n'\ + ' ) n\n'\ + ' /_, \n'\ + 'n = -oo ' + + assert upretty(Sum(n, (n, -oo, 1))) == \ +"""\ + 1 \n\ + ___ \n\ + ╲ \n\ + ╲ \n\ + ╱ n\n\ + ╱ \n\ + ‾‾‾ \n\ +n = -∞ \ +""" + + +def test_is_combining(): + line = "v̇_m" + assert [is_combining(sym) for sym in line] == \ + [False, True, False, False] + + +def test_issue_17616(): + assert pretty(pi**(1/exp(1))) == \ + ' / -1\\\n'\ + ' \\e /\n'\ + 'pi ' + + assert upretty(pi**(1/exp(1))) == \ + ' ⎛ -1⎞\n'\ + ' ⎝ℯ ⎠\n'\ + 'π ' + + assert pretty(pi**(1/pi)) == \ + ' 1 \n'\ + ' --\n'\ + ' pi\n'\ + 'pi ' + + assert upretty(pi**(1/pi)) == \ + ' 1\n'\ + ' ─\n'\ + ' π\n'\ + 'π ' + + assert pretty(pi**(1/EulerGamma)) == \ + ' 1 \n'\ + ' ----------\n'\ + ' EulerGamma\n'\ + 'pi ' + + assert upretty(pi**(1/EulerGamma)) == \ + ' 1\n'\ + ' ─\n'\ + ' γ\n'\ + 'π ' + + z = Symbol("x_17") + assert upretty(7**(1/z)) == \ + 'x₁₇___\n'\ + ' ╲╱ 7 ' + + assert pretty(7**(1/z)) == \ + 'x_17___\n'\ + ' \\/ 7 ' + + +def test_issue_17857(): + assert pretty(Range(-oo, oo)) == '{..., -1, 0, 1, ...}' + assert pretty(Range(oo, -oo, -1)) == '{..., 1, 0, -1, ...}' + + +def test_issue_18272(): + x = Symbol('x') + n = Symbol('n') + + assert upretty(ConditionSet(x, Eq(-x + exp(x), 0), S.Complexes)) == \ + '⎧ │ ⎛ x ⎞⎫\n'\ + '⎨x │ x ∊ ℂ ∧ ⎝-x + ℯ = 0⎠⎬\n'\ + '⎩ │ ⎭' + assert upretty(ConditionSet(x, Contains(n/2, Interval(0, oo)), FiniteSet(-n/2, n/2))) == \ + '⎧ │ ⎧-n n⎫ ⎛n ⎞⎫\n'\ + '⎨x │ x ∊ ⎨───, ─⎬ ∧ ⎜─ ∈ [0, ∞)⎟⎬\n'\ + '⎩ │ ⎩ 2 2⎭ ⎝2 ⎠⎭' + assert upretty(ConditionSet(x, Eq(Piecewise((1, x >= 3), (x/2 - 1/2, x >= 2), (1/2, x >= 1), + (x/2, True)) - 1/2, 0), Interval(0, 3))) == \ + '⎧ │ ⎛⎛⎧ 1 for x ≥ 3⎞ ⎞⎫\n'\ + '⎪ │ ⎜⎜⎪ ⎟ ⎟⎪\n'\ + '⎪ │ ⎜⎜⎪x ⎟ ⎟⎪\n'\ + '⎪ │ ⎜⎜⎪─ - 0.5 for x ≥ 2⎟ ⎟⎪\n'\ + '⎪ │ ⎜⎜⎪2 ⎟ ⎟⎪\n'\ + '⎨x │ x ∊ [0, 3] ∧ ⎜⎜⎨ ⎟ - 0.5 = 0⎟⎬\n'\ + '⎪ │ ⎜⎜⎪ 0.5 for x ≥ 1⎟ ⎟⎪\n'\ + '⎪ │ ⎜⎜⎪ ⎟ ⎟⎪\n'\ + '⎪ │ ⎜⎜⎪ x ⎟ ⎟⎪\n'\ + '⎪ │ ⎜⎜⎪ ─ otherwise⎟ ⎟⎪\n'\ + '⎩ │ ⎝⎝⎩ 2 ⎠ ⎠⎭' + + +def test_Str(): + from sympy.core.symbol import Str + assert pretty(Str('x')) == 'x' + + +def test_symbolic_probability(): + mu = symbols("mu") + sigma = symbols("sigma", positive=True) + X = Normal("X", mu, sigma) + assert pretty(Expectation(X)) == r'E[X]' + assert pretty(Variance(X)) == r'Var(X)' + assert pretty(Probability(X > 0)) == r'P(X > 0)' + Y = Normal("Y", mu, sigma) + assert pretty(Covariance(X, Y)) == 'Cov(X, Y)' + + +def test_issue_21758(): + from sympy.functions.elementary.piecewise import piecewise_fold + from sympy.series.fourier import FourierSeries + x = Symbol('x') + k, n = symbols('k n') + fo = FourierSeries(x, (x, -pi, pi), (0, SeqFormula(0, (k, 1, oo)), SeqFormula( + Piecewise((-2*pi*cos(n*pi)/n + 2*sin(n*pi)/n**2, (n > -oo) & (n < oo) & Ne(n, 0)), + (0, True))*sin(n*x)/pi, (n, 1, oo)))) + assert upretty(piecewise_fold(fo)) == \ + '⎧ 2⋅sin(3⋅x) \n'\ + '⎪2⋅sin(x) - sin(2⋅x) + ────────── + … for n > -∞ ∧ n < ∞ ∧ n ≠ 0\n'\ + '⎨ 3 \n'\ + '⎪ \n'\ + '⎩ 0 otherwise ' + assert pretty(FourierSeries(x, (x, -pi, pi), (0, SeqFormula(0, (k, 1, oo)), + SeqFormula(0, (n, 1, oo))))) == '0' + + +def test_diffgeom(): + from sympy.diffgeom import Manifold, Patch, CoordSystem, BaseScalarField + x,y = symbols('x y', real=True) + m = Manifold('M', 2) + assert pretty(m) == 'M' + p = Patch('P', m) + assert pretty(p) == "P" + rect = CoordSystem('rect', p, [x, y]) + assert pretty(rect) == "rect" + b = BaseScalarField(rect, 0) + assert pretty(b) == "x" + + +def test_deprecated_prettyForm(): + with warns_deprecated_sympy(): + from sympy.printing.pretty.pretty_symbology import xstr + assert xstr(1) == '1' + + with warns_deprecated_sympy(): + from sympy.printing.pretty.stringpict import prettyForm + p = prettyForm('s', unicode='s') + + with warns_deprecated_sympy(): + assert p.unicode == p.s == 's' + + +def test_center(): + assert center('1', 2) == '1 ' + assert center('1', 3) == ' 1 ' + assert center('1', 3, '-') == '-1-' + assert center('1', 5, '-') == '--1--' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/preview.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/preview.py new file mode 100644 index 0000000000000000000000000000000000000000..b04a344b5b4acc086eb84ff068bc1c6a8b55d811 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/preview.py @@ -0,0 +1,390 @@ +import os +from os.path import join +import shutil +import tempfile +from pathlib import Path + +try: + from subprocess import STDOUT, CalledProcessError, check_output +except ImportError: + pass + +from sympy.utilities.decorator import doctest_depends_on +from sympy.utilities.misc import debug +from .latex import latex + +__doctest_requires__ = {('preview',): ['pyglet']} + + +def _check_output_no_window(*args, **kwargs): + # Avoid showing a cmd.exe window when running this + # on Windows + if os.name == 'nt': + creation_flag = 0x08000000 # CREATE_NO_WINDOW + else: + creation_flag = 0 # Default value + return check_output(*args, creationflags=creation_flag, **kwargs) + + +def system_default_viewer(fname, fmt): + """ Open fname with the default system viewer. + + In practice, it is impossible for python to know when the system viewer is + done. For this reason, we ensure the passed file will not be deleted under + it, and this function does not attempt to block. + """ + # copy to a new temporary file that will not be deleted + with tempfile.NamedTemporaryFile(prefix='sympy-preview-', + suffix=os.path.splitext(fname)[1], + delete=False) as temp_f: + with open(fname, 'rb') as f: + shutil.copyfileobj(f, temp_f) + + import platform + if platform.system() == 'Darwin': + import subprocess + subprocess.call(('open', temp_f.name)) + elif platform.system() == 'Windows': + os.startfile(temp_f.name) + else: + import subprocess + subprocess.call(('xdg-open', temp_f.name)) + + +def pyglet_viewer(fname, fmt): + try: + from pyglet import window, image, gl + from pyglet.window import key + from pyglet.image.codecs import ImageDecodeException + except ImportError: + raise ImportError("pyglet is required for preview.\n visit https://pyglet.org/") + + try: + img = image.load(fname) + except ImageDecodeException: + raise ValueError("pyglet preview does not work for '{}' files.".format(fmt)) + + offset = 25 + + config = gl.Config(double_buffer=False) + win = window.Window( + width=img.width + 2*offset, + height=img.height + 2*offset, + caption="SymPy", + resizable=False, + config=config + ) + + win.set_vsync(False) + + try: + def on_close(): + win.has_exit = True + + win.on_close = on_close + + def on_key_press(symbol, modifiers): + if symbol in [key.Q, key.ESCAPE]: + on_close() + + win.on_key_press = on_key_press + + def on_expose(): + gl.glClearColor(1.0, 1.0, 1.0, 1.0) + gl.glClear(gl.GL_COLOR_BUFFER_BIT) + + img.blit( + (win.width - img.width) / 2, + (win.height - img.height) / 2 + ) + + win.on_expose = on_expose + + while not win.has_exit: + win.dispatch_events() + win.flip() + except KeyboardInterrupt: + pass + + win.close() + + +def _get_latex_main(expr, *, preamble=None, packages=(), extra_preamble=None, + euler=True, fontsize=None, **latex_settings): + """ + Generate string of a LaTeX document rendering ``expr``. + """ + if preamble is None: + actual_packages = packages + ("amsmath", "amsfonts") + if euler: + actual_packages += ("euler",) + package_includes = "\n" + "\n".join(["\\usepackage{%s}" % p + for p in actual_packages]) + if extra_preamble: + package_includes += extra_preamble + + if not fontsize: + fontsize = "12pt" + elif isinstance(fontsize, int): + fontsize = "{}pt".format(fontsize) + preamble = r"""\documentclass[varwidth,%s]{standalone} +%s + +\begin{document} +""" % (fontsize, package_includes) + else: + if packages or extra_preamble: + raise ValueError("The \"packages\" or \"extra_preamble\" keywords" + "must not be set if a " + "custom LaTeX preamble was specified") + + if isinstance(expr, str): + latex_string = expr + else: + latex_string = ('$\\displaystyle ' + + latex(expr, mode='plain', **latex_settings) + + '$') + + return preamble + '\n' + latex_string + '\n\n' + r"\end{document}" + + +@doctest_depends_on(exe=('latex', 'dvipng'), modules=('pyglet',), + disable_viewers=('evince', 'gimp', 'superior-dvi-viewer')) +def preview(expr, output='png', viewer=None, euler=True, packages=(), + filename=None, outputbuffer=None, preamble=None, dvioptions=None, + outputTexFile=None, extra_preamble=None, fontsize=None, + **latex_settings): + r""" + View expression or LaTeX markup in PNG, DVI, PostScript or PDF form. + + If the expr argument is an expression, it will be exported to LaTeX and + then compiled using the available TeX distribution. The first argument, + 'expr', may also be a LaTeX string. The function will then run the + appropriate viewer for the given output format or use the user defined + one. By default png output is generated. + + By default pretty Euler fonts are used for typesetting (they were used to + typeset the well known "Concrete Mathematics" book). For that to work, you + need the 'eulervm.sty' LaTeX style (in Debian/Ubuntu, install the + texlive-fonts-extra package). If you prefer default AMS fonts or your + system lacks 'eulervm' LaTeX package then unset the 'euler' keyword + argument. + + To use viewer auto-detection, lets say for 'png' output, issue + + >>> from sympy import symbols, preview, Symbol + >>> x, y = symbols("x,y") + + >>> preview(x + y, output='png') + + This will choose 'pyglet' by default. To select a different one, do + + >>> preview(x + y, output='png', viewer='gimp') + + The 'png' format is considered special. For all other formats the rules + are slightly different. As an example we will take 'dvi' output format. If + you would run + + >>> preview(x + y, output='dvi') + + then 'view' will look for available 'dvi' viewers on your system + (predefined in the function, so it will try evince, first, then kdvi and + xdvi). If nothing is found, it will fall back to using a system file + association (via ``open`` and ``xdg-open``). To always use your system file + association without searching for the above readers, use + + >>> from sympy.printing.preview import system_default_viewer + >>> preview(x + y, output='dvi', viewer=system_default_viewer) + + If this still does not find the viewer you want, it can be set explicitly. + + >>> preview(x + y, output='dvi', viewer='superior-dvi-viewer') + + This will skip auto-detection and will run user specified + 'superior-dvi-viewer'. If ``view`` fails to find it on your system it will + gracefully raise an exception. + + You may also enter ``'file'`` for the viewer argument. Doing so will cause + this function to return a file object in read-only mode, if ``filename`` + is unset. However, if it was set, then 'preview' writes the generated + file to this filename instead. + + There is also support for writing to a ``io.BytesIO`` like object, which + needs to be passed to the ``outputbuffer`` argument. + + >>> from io import BytesIO + >>> obj = BytesIO() + >>> preview(x + y, output='png', viewer='BytesIO', + ... outputbuffer=obj) + + The LaTeX preamble can be customized by setting the 'preamble' keyword + argument. This can be used, e.g., to set a different font size, use a + custom documentclass or import certain set of LaTeX packages. + + >>> preamble = "\\documentclass[10pt]{article}\n" \ + ... "\\usepackage{amsmath,amsfonts}\\begin{document}" + >>> preview(x + y, output='png', preamble=preamble) + + It is also possible to use the standard preamble and provide additional + information to the preamble using the ``extra_preamble`` keyword argument. + + >>> from sympy import sin + >>> extra_preamble = "\\renewcommand{\\sin}{\\cos}" + >>> preview(sin(x), output='png', extra_preamble=extra_preamble) + + If the value of 'output' is different from 'dvi' then command line + options can be set ('dvioptions' argument) for the execution of the + 'dvi'+output conversion tool. These options have to be in the form of a + list of strings (see ``subprocess.Popen``). + + Additional keyword args will be passed to the :func:`~sympy.printing.latex.latex` call, + e.g., the ``symbol_names`` flag. + + >>> phidd = Symbol('phidd') + >>> preview(phidd, symbol_names={phidd: r'\ddot{\varphi}'}) + + For post-processing the generated TeX File can be written to a file by + passing the desired filename to the 'outputTexFile' keyword + argument. To write the TeX code to a file named + ``"sample.tex"`` and run the default png viewer to display the resulting + bitmap, do + + >>> preview(x + y, outputTexFile="sample.tex") + + + """ + # pyglet is the default for png + if viewer is None and output == "png": + try: + import pyglet # noqa: F401 + except ImportError: + pass + else: + viewer = pyglet_viewer + + # look up a known application + if viewer is None: + # sorted in order from most pretty to most ugly + # very discussable, but indeed 'gv' looks awful :) + candidates = { + "dvi": [ "evince", "okular", "kdvi", "xdvi" ], + "ps": [ "evince", "okular", "gsview", "gv" ], + "pdf": [ "evince", "okular", "kpdf", "acroread", "xpdf", "gv" ], + } + + for candidate in candidates.get(output, []): + path = shutil.which(candidate) + if path is not None: + viewer = path + break + + # otherwise, use the system default for file association + if viewer is None: + viewer = system_default_viewer + + if viewer == "file": + if filename is None: + raise ValueError("filename has to be specified if viewer=\"file\"") + elif viewer == "BytesIO": + if outputbuffer is None: + raise ValueError("outputbuffer has to be a BytesIO " + "compatible object if viewer=\"BytesIO\"") + elif not callable(viewer) and not shutil.which(viewer): + raise OSError("Unrecognized viewer: %s" % viewer) + + latex_main = _get_latex_main(expr, preamble=preamble, packages=packages, + euler=euler, extra_preamble=extra_preamble, + fontsize=fontsize, **latex_settings) + + debug("Latex code:") + debug(latex_main) + with tempfile.TemporaryDirectory() as workdir: + Path(join(workdir, 'texput.tex')).write_text(latex_main, encoding='utf-8') + + if outputTexFile is not None: + shutil.copyfile(join(workdir, 'texput.tex'), outputTexFile) + + if not shutil.which('latex'): + raise RuntimeError("latex program is not installed") + + try: + _check_output_no_window( + ['latex', '-halt-on-error', '-interaction=nonstopmode', + 'texput.tex'], + cwd=workdir, + stderr=STDOUT) + except CalledProcessError as e: + raise RuntimeError( + "'latex' exited abnormally with the following output:\n%s" % + e.output) + + src = "texput.%s" % (output) + + if output != "dvi": + # in order of preference + commandnames = { + "ps": ["dvips"], + "pdf": ["dvipdfmx", "dvipdfm", "dvipdf"], + "png": ["dvipng"], + "svg": ["dvisvgm"], + } + try: + cmd_variants = commandnames[output] + except KeyError: + raise ValueError("Invalid output format: %s" % output) from None + + # find an appropriate command + for cmd_variant in cmd_variants: + cmd_path = shutil.which(cmd_variant) + if cmd_path: + cmd = [cmd_path] + break + else: + if len(cmd_variants) > 1: + raise RuntimeError("None of %s are installed" % ", ".join(cmd_variants)) + else: + raise RuntimeError("%s is not installed" % cmd_variants[0]) + + defaultoptions = { + "dvipng": ["-T", "tight", "-z", "9", "--truecolor"], + "dvisvgm": ["--no-fonts"], + } + + commandend = { + "dvips": ["-o", src, "texput.dvi"], + "dvipdf": ["texput.dvi", src], + "dvipdfm": ["-o", src, "texput.dvi"], + "dvipdfmx": ["-o", src, "texput.dvi"], + "dvipng": ["-o", src, "texput.dvi"], + "dvisvgm": ["-o", src, "texput.dvi"], + } + + if dvioptions is not None: + cmd.extend(dvioptions) + else: + cmd.extend(defaultoptions.get(cmd_variant, [])) + cmd.extend(commandend[cmd_variant]) + + try: + _check_output_no_window(cmd, cwd=workdir, stderr=STDOUT) + except CalledProcessError as e: + raise RuntimeError( + "'%s' exited abnormally with the following output:\n%s" % + (' '.join(cmd), e.output)) + + + if viewer == "file": + shutil.move(join(workdir, src), filename) + elif viewer == "BytesIO": + s = Path(join(workdir, src)).read_bytes() + outputbuffer.write(s) + elif callable(viewer): + viewer(join(workdir, src), fmt=output) + else: + try: + _check_output_no_window( + [viewer, src], cwd=workdir, stderr=STDOUT) + except CalledProcessError as e: + raise RuntimeError( + "'%s %s' exited abnormally with the following output:\n%s" % + (viewer, src, e.output)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/printer.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/printer.py new file mode 100644 index 0000000000000000000000000000000000000000..0c0a6970920cf0928ad330ed9a3ea4291107a29d --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/printer.py @@ -0,0 +1,432 @@ +"""Printing subsystem driver + +SymPy's printing system works the following way: Any expression can be +passed to a designated Printer who then is responsible to return an +adequate representation of that expression. + +**The basic concept is the following:** + +1. Let the object print itself if it knows how. +2. Take the best fitting method defined in the printer. +3. As fall-back use the emptyPrinter method for the printer. + +Which Method is Responsible for Printing? +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +The whole printing process is started by calling ``.doprint(expr)`` on the printer +which you want to use. This method looks for an appropriate method which can +print the given expression in the given style that the printer defines. +While looking for the method, it follows these steps: + +1. **Let the object print itself if it knows how.** + + The printer looks for a specific method in every object. The name of that method + depends on the specific printer and is defined under ``Printer.printmethod``. + For example, StrPrinter calls ``_sympystr`` and LatexPrinter calls ``_latex``. + Look at the documentation of the printer that you want to use. + The name of the method is specified there. + + This was the original way of doing printing in sympy. Every class had + its own latex, mathml, str and repr methods, but it turned out that it + is hard to produce a high quality printer, if all the methods are spread + out that far. Therefore all printing code was combined into the different + printers, which works great for built-in SymPy objects, but not that + good for user defined classes where it is inconvenient to patch the + printers. + +2. **Take the best fitting method defined in the printer.** + + The printer loops through expr classes (class + its bases), and tries + to dispatch the work to ``_print_`` + + e.g., suppose we have the following class hierarchy:: + + Basic + | + Atom + | + Number + | + Rational + + then, for ``expr=Rational(...)``, the Printer will try + to call printer methods in the order as shown in the figure below:: + + p._print(expr) + | + |-- p._print_Rational(expr) + | + |-- p._print_Number(expr) + | + |-- p._print_Atom(expr) + | + `-- p._print_Basic(expr) + + if ``._print_Rational`` method exists in the printer, then it is called, + and the result is returned back. Otherwise, the printer tries to call + ``._print_Number`` and so on. + +3. **As a fall-back use the emptyPrinter method for the printer.** + + As fall-back ``self.emptyPrinter`` will be called with the expression. If + not defined in the Printer subclass this will be the same as ``str(expr)``. + +.. _printer_example: + +Example of Custom Printer +^^^^^^^^^^^^^^^^^^^^^^^^^ + +In the example below, we have a printer which prints the derivative of a function +in a shorter form. + +.. code-block:: python + + from sympy.core.symbol import Symbol + from sympy.printing.latex import LatexPrinter, print_latex + from sympy.core.function import UndefinedFunction, Function + + + class MyLatexPrinter(LatexPrinter): + \"\"\"Print derivative of a function of symbols in a shorter form. + \"\"\" + def _print_Derivative(self, expr): + function, *vars = expr.args + if not isinstance(type(function), UndefinedFunction) or \\ + not all(isinstance(i, Symbol) for i in vars): + return super()._print_Derivative(expr) + + # If you want the printer to work correctly for nested + # expressions then use self._print() instead of str() or latex(). + # See the example of nested modulo below in the custom printing + # method section. + return "{}_{{{}}}".format( + self._print(Symbol(function.func.__name__)), + ''.join(self._print(i) for i in vars)) + + + def print_my_latex(expr): + \"\"\" Most of the printers define their own wrappers for print(). + These wrappers usually take printer settings. Our printer does not have + any settings. + \"\"\" + print(MyLatexPrinter().doprint(expr)) + + + y = Symbol("y") + x = Symbol("x") + f = Function("f") + expr = f(x, y).diff(x, y) + + # Print the expression using the normal latex printer and our custom + # printer. + print_latex(expr) + print_my_latex(expr) + +The output of the code above is:: + + \\frac{\\partial^{2}}{\\partial x\\partial y} f{\\left(x,y \\right)} + f_{xy} + +.. _printer_method_example: + +Example of Custom Printing Method +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +In the example below, the latex printing of the modulo operator is modified. +This is done by overriding the method ``_latex`` of ``Mod``. + +>>> from sympy import Symbol, Mod, Integer, print_latex + +>>> # Always use printer._print() +>>> class ModOp(Mod): +... def _latex(self, printer): +... a, b = [printer._print(i) for i in self.args] +... return r"\\operatorname{Mod}{\\left(%s, %s\\right)}" % (a, b) + +Comparing the output of our custom operator to the builtin one: + +>>> x = Symbol('x') +>>> m = Symbol('m') +>>> print_latex(Mod(x, m)) +x \\bmod m +>>> print_latex(ModOp(x, m)) +\\operatorname{Mod}{\\left(x, m\\right)} + +Common mistakes +~~~~~~~~~~~~~~~ +It's important to always use ``self._print(obj)`` to print subcomponents of +an expression when customizing a printer. Mistakes include: + +1. Using ``self.doprint(obj)`` instead: + + >>> # This example does not work properly, as only the outermost call may use + >>> # doprint. + >>> class ModOpModeWrong(Mod): + ... def _latex(self, printer): + ... a, b = [printer.doprint(i) for i in self.args] + ... return r"\\operatorname{Mod}{\\left(%s, %s\\right)}" % (a, b) + + This fails when the ``mode`` argument is passed to the printer: + + >>> print_latex(ModOp(x, m), mode='inline') # ok + $\\operatorname{Mod}{\\left(x, m\\right)}$ + >>> print_latex(ModOpModeWrong(x, m), mode='inline') # bad + $\\operatorname{Mod}{\\left($x$, $m$\\right)}$ + +2. Using ``str(obj)`` instead: + + >>> class ModOpNestedWrong(Mod): + ... def _latex(self, printer): + ... a, b = [str(i) for i in self.args] + ... return r"\\operatorname{Mod}{\\left(%s, %s\\right)}" % (a, b) + + This fails on nested objects: + + >>> # Nested modulo. + >>> print_latex(ModOp(ModOp(x, m), Integer(7))) # ok + \\operatorname{Mod}{\\left(\\operatorname{Mod}{\\left(x, m\\right)}, 7\\right)} + >>> print_latex(ModOpNestedWrong(ModOpNestedWrong(x, m), Integer(7))) # bad + \\operatorname{Mod}{\\left(ModOpNestedWrong(x, m), 7\\right)} + +3. Using ``LatexPrinter()._print(obj)`` instead. + + >>> from sympy.printing.latex import LatexPrinter + >>> class ModOpSettingsWrong(Mod): + ... def _latex(self, printer): + ... a, b = [LatexPrinter()._print(i) for i in self.args] + ... return r"\\operatorname{Mod}{\\left(%s, %s\\right)}" % (a, b) + + This causes all the settings to be discarded in the subobjects. As an + example, the ``full_prec`` setting which shows floats to full precision is + ignored: + + >>> from sympy import Float + >>> print_latex(ModOp(Float(1) * x, m), full_prec=True) # ok + \\operatorname{Mod}{\\left(1.00000000000000 x, m\\right)} + >>> print_latex(ModOpSettingsWrong(Float(1) * x, m), full_prec=True) # bad + \\operatorname{Mod}{\\left(1.0 x, m\\right)} + +""" + +from __future__ import annotations +import sys +from typing import Any, Type +import inspect +from contextlib import contextmanager +from functools import cmp_to_key, update_wrapper + +from sympy.core.add import Add +from sympy.core.basic import Basic + +from sympy.core.function import AppliedUndef, UndefinedFunction, Function + + + +@contextmanager +def printer_context(printer, **kwargs): + original = printer._context.copy() + try: + printer._context.update(kwargs) + yield + finally: + printer._context = original + + +class Printer: + """ Generic printer + + Its job is to provide infrastructure for implementing new printers easily. + + If you want to define your custom Printer or your custom printing method + for your custom class then see the example above: printer_example_ . + """ + + _global_settings: dict[str, Any] = {} + + _default_settings: dict[str, Any] = {} + + # must be initialized to pass tests and cannot be set to '| None' to pass mypy + printmethod = None # type: str + + @classmethod + def _get_initial_settings(cls): + settings = cls._default_settings.copy() + for key, val in cls._global_settings.items(): + if key in cls._default_settings: + settings[key] = val + return settings + + def __init__(self, settings=None): + self._str = str + + self._settings = self._get_initial_settings() + self._context = {} # mutable during printing + + if settings is not None: + self._settings.update(settings) + + if len(self._settings) > len(self._default_settings): + for key in self._settings: + if key not in self._default_settings: + raise TypeError("Unknown setting '%s'." % key) + + # _print_level is the number of times self._print() was recursively + # called. See StrPrinter._print_Float() for an example of usage + self._print_level = 0 + + @classmethod + def set_global_settings(cls, **settings): + """Set system-wide printing settings. """ + for key, val in settings.items(): + if val is not None: + cls._global_settings[key] = val + + @property + def order(self): + if 'order' in self._settings: + return self._settings['order'] + else: + raise AttributeError("No order defined.") + + def doprint(self, expr): + """Returns printer's representation for expr (as a string)""" + return self._str(self._print(expr)) + + def _print(self, expr, **kwargs) -> str: + """Internal dispatcher + + Tries the following concepts to print an expression: + 1. Let the object print itself if it knows how. + 2. Take the best fitting method defined in the printer. + 3. As fall-back use the emptyPrinter method for the printer. + """ + self._print_level += 1 + try: + # If the printer defines a name for a printing method + # (Printer.printmethod) and the object knows for itself how it + # should be printed, use that method. + if self.printmethod and hasattr(expr, self.printmethod): + if not (isinstance(expr, type) and issubclass(expr, Basic)): + return getattr(expr, self.printmethod)(self, **kwargs) + + # See if the class of expr is known, or if one of its super + # classes is known, and use that print function + # Exception: ignore the subclasses of Undefined, so that, e.g., + # Function('gamma') does not get dispatched to _print_gamma + classes = type(expr).__mro__ + if AppliedUndef in classes: + classes = classes[classes.index(AppliedUndef):] + if UndefinedFunction in classes: + classes = classes[classes.index(UndefinedFunction):] + # Another exception: if someone subclasses a known function, e.g., + # gamma, and changes the name, then ignore _print_gamma + if Function in classes: + i = classes.index(Function) + classes = tuple(c for c in classes[:i] if \ + c.__name__ == classes[0].__name__ or \ + c.__name__.endswith("Base")) + classes[i:] + for cls in classes: + printmethodname = '_print_' + cls.__name__ + printmethod = getattr(self, printmethodname, None) + if printmethod is not None: + return printmethod(expr, **kwargs) + # Unknown object, fall back to the emptyPrinter. + return self.emptyPrinter(expr) + finally: + self._print_level -= 1 + + def emptyPrinter(self, expr): + return str(expr) + + def _as_ordered_terms(self, expr, order=None): + """A compatibility function for ordering terms in Add. """ + order = order or self.order + + if order == 'old': + return sorted(Add.make_args(expr), key=cmp_to_key(self._compare_pretty)) + elif order == 'none': + return list(expr.args) + else: + return expr.as_ordered_terms(order=order) + + def _compare_pretty(self, a, b): + """return -1, 0, 1 if a is canonically less, equal or + greater than b. This is used when 'order=old' is selected + for printing. This puts Order last, orders Rationals + according to value, puts terms in order wrt the power of + the last power appearing in a term. Ties are broken using + Basic.compare. + """ + from sympy.core.numbers import Rational + from sympy.core.symbol import Wild + from sympy.series.order import Order + if isinstance(a, Order) and not isinstance(b, Order): + return 1 + if not isinstance(a, Order) and isinstance(b, Order): + return -1 + + if isinstance(a, Rational) and isinstance(b, Rational): + l = a.p * b.q + r = b.p * a.q + return (l > r) - (l < r) + else: + p1, p2, p3 = Wild("p1"), Wild("p2"), Wild("p3") + r_a = a.match(p1 * p2**p3) + if r_a and p3 in r_a: + a3 = r_a[p3] + r_b = b.match(p1 * p2**p3) + if r_b and p3 in r_b: + b3 = r_b[p3] + c = Basic.compare(a3, b3) + if c != 0: + return c + + # break ties + return Basic.compare(a, b) + + +class _PrintFunction: + """ + Function wrapper to replace ``**settings`` in the signature with printer defaults + """ + def __init__(self, f, print_cls: Type[Printer]): + # find all the non-setting arguments + params = list(inspect.signature(f).parameters.values()) + assert params.pop(-1).kind == inspect.Parameter.VAR_KEYWORD + self.__other_params = params + + self.__print_cls = print_cls + update_wrapper(self, f) + + def __reduce__(self): + # Since this is used as a decorator, it replaces the original function. + # The default pickling will try to pickle self.__wrapped__ and fail + # because the wrapped function can't be retrieved by name. + return self.__wrapped__.__qualname__ + + def __call__(self, *args, **kwargs): + return self.__wrapped__(*args, **kwargs) + + @property + def __signature__(self) -> inspect.Signature: + settings = self.__print_cls._get_initial_settings() + return inspect.Signature( + parameters=self.__other_params + [ + inspect.Parameter(k, inspect.Parameter.KEYWORD_ONLY, default=v) + for k, v in settings.items() + ], + return_annotation=self.__wrapped__.__annotations__.get('return', inspect.Signature.empty) # type:ignore + ) + + +def print_function(print_cls): + """ A decorator to replace kwargs with the printer settings in __signature__ """ + def decorator(f): + if sys.version_info < (3, 9): + # We have to create a subclass so that `help` actually shows the docstring in older Python versions. + # IPython and Sphinx do not need this, only a raw Python console. + cls = type(f'{f.__qualname__}_PrintFunction', (_PrintFunction,), {"__doc__": f.__doc__}) + else: + cls = _PrintFunction + return cls(f, print_cls) + return decorator diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pycode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pycode.py new file mode 100644 index 0000000000000000000000000000000000000000..09bdc6788775d409c06bdaae0a43c54544894602 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pycode.py @@ -0,0 +1,852 @@ +""" +Python code printers + +This module contains Python code printers for plain Python as well as NumPy & SciPy enabled code. +""" +from collections import defaultdict +from itertools import chain +from sympy.core import S +from sympy.core.mod import Mod +from .precedence import precedence +from .codeprinter import CodePrinter + +_kw = { + 'and', 'as', 'assert', 'break', 'class', 'continue', 'def', 'del', 'elif', + 'else', 'except', 'finally', 'for', 'from', 'global', 'if', 'import', 'in', + 'is', 'lambda', 'not', 'or', 'pass', 'raise', 'return', 'try', 'while', + 'with', 'yield', 'None', 'False', 'nonlocal', 'True' +} + +_known_functions = { + 'Abs': 'abs', + 'Min': 'min', + 'Max': 'max', +} +_known_functions_math = { + 'acos': 'acos', + 'acosh': 'acosh', + 'asin': 'asin', + 'asinh': 'asinh', + 'atan': 'atan', + 'atan2': 'atan2', + 'atanh': 'atanh', + 'ceiling': 'ceil', + 'cos': 'cos', + 'cosh': 'cosh', + 'erf': 'erf', + 'erfc': 'erfc', + 'exp': 'exp', + 'expm1': 'expm1', + 'factorial': 'factorial', + 'floor': 'floor', + 'gamma': 'gamma', + 'hypot': 'hypot', + 'isinf': 'isinf', + 'isnan': 'isnan', + 'loggamma': 'lgamma', + 'log': 'log', + 'ln': 'log', + 'log10': 'log10', + 'log1p': 'log1p', + 'log2': 'log2', + 'sin': 'sin', + 'sinh': 'sinh', + 'Sqrt': 'sqrt', + 'tan': 'tan', + 'tanh': 'tanh' +} # Not used from ``math``: [copysign isclose isfinite isinf ldexp frexp pow modf +# radians trunc fmod fsum gcd degrees fabs] +_known_constants_math = { + 'Exp1': 'e', + 'Pi': 'pi', + 'E': 'e', + 'Infinity': 'inf', + 'NaN': 'nan', + 'ComplexInfinity': 'nan' +} + +def _print_known_func(self, expr): + known = self.known_functions[expr.__class__.__name__] + return '{name}({args})'.format(name=self._module_format(known), + args=', '.join((self._print(arg) for arg in expr.args))) + + +def _print_known_const(self, expr): + known = self.known_constants[expr.__class__.__name__] + return self._module_format(known) + + +class AbstractPythonCodePrinter(CodePrinter): + printmethod = "_pythoncode" + language = "Python" + reserved_words = _kw + modules = None # initialized to a set in __init__ + tab = ' ' + _kf = dict(chain( + _known_functions.items(), + [(k, 'math.' + v) for k, v in _known_functions_math.items()] + )) + _kc = {k: 'math.'+v for k, v in _known_constants_math.items()} + _operators = {'and': 'and', 'or': 'or', 'not': 'not'} + _default_settings = dict( + CodePrinter._default_settings, + user_functions={}, + precision=17, + inline=True, + fully_qualified_modules=True, + contract=False, + standard='python3', + ) + + def __init__(self, settings=None): + super().__init__(settings) + + # Python standard handler + std = self._settings['standard'] + if std is None: + import sys + std = 'python{}'.format(sys.version_info.major) + if std != 'python3': + raise ValueError('Only Python 3 is supported.') + self.standard = std + + self.module_imports = defaultdict(set) + + # Known functions and constants handler + self.known_functions = dict(self._kf, **(settings or {}).get( + 'user_functions', {})) + self.known_constants = dict(self._kc, **(settings or {}).get( + 'user_constants', {})) + + def _declare_number_const(self, name, value): + return "%s = %s" % (name, value) + + def _module_format(self, fqn, register=True): + parts = fqn.split('.') + if register and len(parts) > 1: + self.module_imports['.'.join(parts[:-1])].add(parts[-1]) + + if self._settings['fully_qualified_modules']: + return fqn + else: + return fqn.split('(')[0].split('[')[0].split('.')[-1] + + def _format_code(self, lines): + return lines + + def _get_statement(self, codestring): + return "{}".format(codestring) + + def _get_comment(self, text): + return " # {}".format(text) + + def _expand_fold_binary_op(self, op, args): + """ + This method expands a fold on binary operations. + + ``functools.reduce`` is an example of a folded operation. + + For example, the expression + + `A + B + C + D` + + is folded into + + `((A + B) + C) + D` + """ + if len(args) == 1: + return self._print(args[0]) + else: + return "%s(%s, %s)" % ( + self._module_format(op), + self._expand_fold_binary_op(op, args[:-1]), + self._print(args[-1]), + ) + + def _expand_reduce_binary_op(self, op, args): + """ + This method expands a reduction on binary operations. + + Notice: this is NOT the same as ``functools.reduce``. + + For example, the expression + + `A + B + C + D` + + is reduced into: + + `(A + B) + (C + D)` + """ + if len(args) == 1: + return self._print(args[0]) + else: + N = len(args) + Nhalf = N // 2 + return "%s(%s, %s)" % ( + self._module_format(op), + self._expand_reduce_binary_op(args[:Nhalf]), + self._expand_reduce_binary_op(args[Nhalf:]), + ) + + def _print_NaN(self, expr): + return "float('nan')" + + def _print_Infinity(self, expr): + return "float('inf')" + + def _print_NegativeInfinity(self, expr): + return "float('-inf')" + + def _print_ComplexInfinity(self, expr): + return self._print_NaN(expr) + + def _print_Mod(self, expr): + PREC = precedence(expr) + return ('{} % {}'.format(*(self.parenthesize(x, PREC) for x in expr.args))) + + def _print_Piecewise(self, expr): + result = [] + i = 0 + for arg in expr.args: + e = arg.expr + c = arg.cond + if i == 0: + result.append('(') + result.append('(') + result.append(self._print(e)) + result.append(')') + result.append(' if ') + result.append(self._print(c)) + result.append(' else ') + i += 1 + result = result[:-1] + if result[-1] == 'True': + result = result[:-2] + result.append(')') + else: + result.append(' else None)') + return ''.join(result) + + def _print_Relational(self, expr): + "Relational printer for Equality and Unequality" + op = { + '==' :'equal', + '!=' :'not_equal', + '<' :'less', + '<=' :'less_equal', + '>' :'greater', + '>=' :'greater_equal', + } + if expr.rel_op in op: + lhs = self._print(expr.lhs) + rhs = self._print(expr.rhs) + return '({lhs} {op} {rhs})'.format(op=expr.rel_op, lhs=lhs, rhs=rhs) + return super()._print_Relational(expr) + + def _print_ITE(self, expr): + from sympy.functions.elementary.piecewise import Piecewise + return self._print(expr.rewrite(Piecewise)) + + def _print_Sum(self, expr): + loops = ( + 'for {i} in range({a}, {b}+1)'.format( + i=self._print(i), + a=self._print(a), + b=self._print(b)) + for i, a, b in expr.limits[::-1]) + return '(builtins.sum({function} {loops}))'.format( + function=self._print(expr.function), + loops=' '.join(loops)) + + def _print_ImaginaryUnit(self, expr): + return '1j' + + def _print_KroneckerDelta(self, expr): + a, b = expr.args + + return '(1 if {a} == {b} else 0)'.format( + a = self._print(a), + b = self._print(b) + ) + + def _print_MatrixBase(self, expr): + name = expr.__class__.__name__ + func = self.known_functions.get(name, name) + return "%s(%s)" % (func, self._print(expr.tolist())) + + _print_SparseRepMatrix = \ + _print_MutableSparseMatrix = \ + _print_ImmutableSparseMatrix = \ + _print_Matrix = \ + _print_DenseMatrix = \ + _print_MutableDenseMatrix = \ + _print_ImmutableMatrix = \ + _print_ImmutableDenseMatrix = \ + lambda self, expr: self._print_MatrixBase(expr) + + def _indent_codestring(self, codestring): + return '\n'.join([self.tab + line for line in codestring.split('\n')]) + + def _print_FunctionDefinition(self, fd): + body = '\n'.join((self._print(arg) for arg in fd.body)) + return "def {name}({parameters}):\n{body}".format( + name=self._print(fd.name), + parameters=', '.join([self._print(var.symbol) for var in fd.parameters]), + body=self._indent_codestring(body) + ) + + def _print_While(self, whl): + body = '\n'.join((self._print(arg) for arg in whl.body)) + return "while {cond}:\n{body}".format( + cond=self._print(whl.condition), + body=self._indent_codestring(body) + ) + + def _print_Declaration(self, decl): + return '%s = %s' % ( + self._print(decl.variable.symbol), + self._print(decl.variable.value) + ) + + def _print_BreakToken(self, bt): + return 'break' + + def _print_Return(self, ret): + arg, = ret.args + return 'return %s' % self._print(arg) + + def _print_Raise(self, rs): + arg, = rs.args + return 'raise %s' % self._print(arg) + + def _print_RuntimeError_(self, re): + message, = re.args + return "RuntimeError(%s)" % self._print(message) + + def _print_Print(self, prnt): + print_args = ', '.join((self._print(arg) for arg in prnt.print_args)) + from sympy.codegen.ast import none + if prnt.format_string != none: + print_args = '{} % ({}), end=""'.format( + self._print(prnt.format_string), + print_args + ) + if prnt.file != None: # Must be '!= None', cannot be 'is not None' + print_args += ', file=%s' % self._print(prnt.file) + return 'print(%s)' % print_args + + def _print_Stream(self, strm): + if str(strm.name) == 'stdout': + return self._module_format('sys.stdout') + elif str(strm.name) == 'stderr': + return self._module_format('sys.stderr') + else: + return self._print(strm.name) + + def _print_NoneToken(self, arg): + return 'None' + + def _hprint_Pow(self, expr, rational=False, sqrt='math.sqrt'): + """Printing helper function for ``Pow`` + + Notes + ===== + + This preprocesses the ``sqrt`` as math formatter and prints division + + Examples + ======== + + >>> from sympy import sqrt + >>> from sympy.printing.pycode import PythonCodePrinter + >>> from sympy.abc import x + + Python code printer automatically looks up ``math.sqrt``. + + >>> printer = PythonCodePrinter() + >>> printer._hprint_Pow(sqrt(x), rational=True) + 'x**(1/2)' + >>> printer._hprint_Pow(sqrt(x), rational=False) + 'math.sqrt(x)' + >>> printer._hprint_Pow(1/sqrt(x), rational=True) + 'x**(-1/2)' + >>> printer._hprint_Pow(1/sqrt(x), rational=False) + '1/math.sqrt(x)' + >>> printer._hprint_Pow(1/x, rational=False) + '1/x' + >>> printer._hprint_Pow(1/x, rational=True) + 'x**(-1)' + + Using sqrt from numpy or mpmath + + >>> printer._hprint_Pow(sqrt(x), sqrt='numpy.sqrt') + 'numpy.sqrt(x)' + >>> printer._hprint_Pow(sqrt(x), sqrt='mpmath.sqrt') + 'mpmath.sqrt(x)' + + See Also + ======== + + sympy.printing.str.StrPrinter._print_Pow + """ + PREC = precedence(expr) + + if expr.exp == S.Half and not rational: + func = self._module_format(sqrt) + arg = self._print(expr.base) + return '{func}({arg})'.format(func=func, arg=arg) + + if expr.is_commutative and not rational: + if -expr.exp is S.Half: + func = self._module_format(sqrt) + num = self._print(S.One) + arg = self._print(expr.base) + return f"{num}/{func}({arg})" + if expr.exp is S.NegativeOne: + num = self._print(S.One) + arg = self.parenthesize(expr.base, PREC, strict=False) + return f"{num}/{arg}" + + + base_str = self.parenthesize(expr.base, PREC, strict=False) + exp_str = self.parenthesize(expr.exp, PREC, strict=False) + return "{}**{}".format(base_str, exp_str) + + +class ArrayPrinter: + + def _arrayify(self, indexed): + from sympy.tensor.array.expressions.from_indexed_to_array import convert_indexed_to_array + try: + return convert_indexed_to_array(indexed) + except Exception: + return indexed + + def _get_einsum_string(self, subranks, contraction_indices): + letters = self._get_letter_generator_for_einsum() + contraction_string = "" + counter = 0 + d = {j: min(i) for i in contraction_indices for j in i} + indices = [] + for rank_arg in subranks: + lindices = [] + for i in range(rank_arg): + if counter in d: + lindices.append(d[counter]) + else: + lindices.append(counter) + counter += 1 + indices.append(lindices) + mapping = {} + letters_free = [] + letters_dum = [] + for i in indices: + for j in i: + if j not in mapping: + l = next(letters) + mapping[j] = l + else: + l = mapping[j] + contraction_string += l + if j in d: + if l not in letters_dum: + letters_dum.append(l) + else: + letters_free.append(l) + contraction_string += "," + contraction_string = contraction_string[:-1] + return contraction_string, letters_free, letters_dum + + def _get_letter_generator_for_einsum(self): + for i in range(97, 123): + yield chr(i) + for i in range(65, 91): + yield chr(i) + raise ValueError("out of letters") + + def _print_ArrayTensorProduct(self, expr): + letters = self._get_letter_generator_for_einsum() + contraction_string = ",".join(["".join([next(letters) for j in range(i)]) for i in expr.subranks]) + return '%s("%s", %s)' % ( + self._module_format(self._module + "." + self._einsum), + contraction_string, + ", ".join([self._print(arg) for arg in expr.args]) + ) + + def _print_ArrayContraction(self, expr): + from sympy.tensor.array.expressions.array_expressions import ArrayTensorProduct + base = expr.expr + contraction_indices = expr.contraction_indices + + if isinstance(base, ArrayTensorProduct): + elems = ",".join(["%s" % (self._print(arg)) for arg in base.args]) + ranks = base.subranks + else: + elems = self._print(base) + ranks = [len(base.shape)] + + contraction_string, letters_free, letters_dum = self._get_einsum_string(ranks, contraction_indices) + + if not contraction_indices: + return self._print(base) + if isinstance(base, ArrayTensorProduct): + elems = ",".join(["%s" % (self._print(arg)) for arg in base.args]) + else: + elems = self._print(base) + return "%s(\"%s\", %s)" % ( + self._module_format(self._module + "." + self._einsum), + "{}->{}".format(contraction_string, "".join(sorted(letters_free))), + elems, + ) + + def _print_ArrayDiagonal(self, expr): + from sympy.tensor.array.expressions.array_expressions import ArrayTensorProduct + diagonal_indices = list(expr.diagonal_indices) + if isinstance(expr.expr, ArrayTensorProduct): + subranks = expr.expr.subranks + elems = expr.expr.args + else: + subranks = expr.subranks + elems = [expr.expr] + diagonal_string, letters_free, letters_dum = self._get_einsum_string(subranks, diagonal_indices) + elems = [self._print(i) for i in elems] + return '%s("%s", %s)' % ( + self._module_format(self._module + "." + self._einsum), + "{}->{}".format(diagonal_string, "".join(letters_free+letters_dum)), + ", ".join(elems) + ) + + def _print_PermuteDims(self, expr): + return "%s(%s, %s)" % ( + self._module_format(self._module + "." + self._transpose), + self._print(expr.expr), + self._print(expr.permutation.array_form), + ) + + def _print_ArrayAdd(self, expr): + return self._expand_fold_binary_op(self._module + "." + self._add, expr.args) + + def _print_OneArray(self, expr): + return "%s((%s,))" % ( + self._module_format(self._module+ "." + self._ones), + ','.join(map(self._print,expr.args)) + ) + + def _print_ZeroArray(self, expr): + return "%s((%s,))" % ( + self._module_format(self._module+ "." + self._zeros), + ','.join(map(self._print,expr.args)) + ) + + def _print_Assignment(self, expr): + #XXX: maybe this needs to happen at a higher level e.g. at _print or + #doprint? + lhs = self._print(self._arrayify(expr.lhs)) + rhs = self._print(self._arrayify(expr.rhs)) + return "%s = %s" % ( lhs, rhs ) + + def _print_IndexedBase(self, expr): + return self._print_ArraySymbol(expr) + + +class PythonCodePrinter(AbstractPythonCodePrinter): + + def _print_sign(self, e): + return '(0.0 if {e} == 0 else {f}(1, {e}))'.format( + f=self._module_format('math.copysign'), e=self._print(e.args[0])) + + def _print_Not(self, expr): + PREC = precedence(expr) + return self._operators['not'] + ' ' + self.parenthesize(expr.args[0], PREC) + + def _print_IndexedBase(self, expr): + return expr.name + + def _print_Indexed(self, expr): + base = expr.args[0] + index = expr.args[1:] + return "{}[{}]".format(str(base), ", ".join([self._print(ind) for ind in index])) + + def _print_Pow(self, expr, rational=False): + return self._hprint_Pow(expr, rational=rational) + + def _print_Rational(self, expr): + return '{}/{}'.format(expr.p, expr.q) + + def _print_Half(self, expr): + return self._print_Rational(expr) + + def _print_frac(self, expr): + return self._print_Mod(Mod(expr.args[0], 1)) + + def _print_Symbol(self, expr): + + name = super()._print_Symbol(expr) + + if name in self.reserved_words: + if self._settings['error_on_reserved']: + msg = ('This expression includes the symbol "{}" which is a ' + 'reserved keyword in this language.') + raise ValueError(msg.format(name)) + return name + self._settings['reserved_word_suffix'] + elif '{' in name: # Remove curly braces from subscripted variables + return name.replace('{', '').replace('}', '') + else: + return name + + _print_lowergamma = CodePrinter._print_not_supported + _print_uppergamma = CodePrinter._print_not_supported + _print_fresnelc = CodePrinter._print_not_supported + _print_fresnels = CodePrinter._print_not_supported + + +for k in PythonCodePrinter._kf: + setattr(PythonCodePrinter, '_print_%s' % k, _print_known_func) + +for k in _known_constants_math: + setattr(PythonCodePrinter, '_print_%s' % k, _print_known_const) + + +def pycode(expr, **settings): + """ Converts an expr to a string of Python code + + Parameters + ========== + + expr : Expr + A SymPy expression. + fully_qualified_modules : bool + Whether or not to write out full module names of functions + (``math.sin`` vs. ``sin``). default: ``True``. + standard : str or None, optional + Only 'python3' (default) is supported. + This parameter may be removed in the future. + + Examples + ======== + + >>> from sympy import pycode, tan, Symbol + >>> pycode(tan(Symbol('x')) + 1) + 'math.tan(x) + 1' + + """ + return PythonCodePrinter(settings).doprint(expr) + + +from itertools import chain +from sympy.printing.pycode import PythonCodePrinter + +_known_functions_cmath = { + 'exp': 'exp', + 'sqrt': 'sqrt', + 'log': 'log', + 'cos': 'cos', + 'sin': 'sin', + 'tan': 'tan', + 'acos': 'acos', + 'asin': 'asin', + 'atan': 'atan', + 'cosh': 'cosh', + 'sinh': 'sinh', + 'tanh': 'tanh', + 'acosh': 'acosh', + 'asinh': 'asinh', + 'atanh': 'atanh', +} + +_known_constants_cmath = { + 'Pi': 'pi', + 'E': 'e', + 'Infinity': 'inf', + 'NegativeInfinity': '-inf', +} + +class CmathPrinter(PythonCodePrinter): + """ Printer for Python's cmath module """ + printmethod = "_cmathcode" + language = "Python with cmath" + + _kf = dict(chain( + _known_functions_cmath.items() + )) + + _kc = {k: 'cmath.' + v for k, v in _known_constants_cmath.items()} + + def _print_Pow(self, expr, rational=False): + return self._hprint_Pow(expr, rational=rational, sqrt='cmath.sqrt') + + def _print_Float(self, e): + return '{func}({val})'.format(func=self._module_format('cmath.mpf'), val=self._print(e)) + + def _print_known_func(self, expr): + func_name = expr.func.__name__ + if func_name in self._kf: + return f"cmath.{self._kf[func_name]}({', '.join(map(self._print, expr.args))})" + return super()._print_Function(expr) + + def _print_known_const(self, expr): + return self._kc[expr.__class__.__name__] + + def _print_re(self, expr): + """Prints `re(z)` as `z.real`""" + return f"({self._print(expr.args[0])}).real" + + def _print_im(self, expr): + """Prints `im(z)` as `z.imag`""" + return f"({self._print(expr.args[0])}).imag" + + +for k in CmathPrinter._kf: + setattr(CmathPrinter, '_print_%s' % k, CmathPrinter._print_known_func) + +for k in _known_constants_cmath: + setattr(CmathPrinter, '_print_%s' % k, CmathPrinter._print_known_const) + + +_not_in_mpmath = 'log1p log2'.split() +_in_mpmath = [(k, v) for k, v in _known_functions_math.items() if k not in _not_in_mpmath] +_known_functions_mpmath = dict(_in_mpmath, **{ + 'beta': 'beta', + 'frac': 'frac', + 'fresnelc': 'fresnelc', + 'fresnels': 'fresnels', + 'sign': 'sign', + 'loggamma': 'loggamma', + 'hyper': 'hyper', + 'meijerg': 'meijerg', + 'besselj': 'besselj', + 'bessely': 'bessely', + 'besseli': 'besseli', + 'besselk': 'besselk', +}) +_known_constants_mpmath = { + 'Exp1': 'e', + 'Pi': 'pi', + 'GoldenRatio': 'phi', + 'EulerGamma': 'euler', + 'Catalan': 'catalan', + 'NaN': 'nan', + 'Infinity': 'inf', + 'NegativeInfinity': 'ninf' +} + + +def _unpack_integral_limits(integral_expr): + """ helper function for _print_Integral that + - accepts an Integral expression + - returns a tuple of + - a list variables of integration + - a list of tuples of the upper and lower limits of integration + """ + integration_vars = [] + limits = [] + for integration_range in integral_expr.limits: + if len(integration_range) == 3: + integration_var, lower_limit, upper_limit = integration_range + else: + raise NotImplementedError("Only definite integrals are supported") + integration_vars.append(integration_var) + limits.append((lower_limit, upper_limit)) + return integration_vars, limits + + +class MpmathPrinter(PythonCodePrinter): + """ + Lambda printer for mpmath which maintains precision for floats + """ + printmethod = "_mpmathcode" + + language = "Python with mpmath" + + _kf = dict(chain( + _known_functions.items(), + [(k, 'mpmath.' + v) for k, v in _known_functions_mpmath.items()] + )) + _kc = {k: 'mpmath.'+v for k, v in _known_constants_mpmath.items()} + + def _print_Float(self, e): + # XXX: This does not handle setting mpmath.mp.dps. It is assumed that + # the caller of the lambdified function will have set it to sufficient + # precision to match the Floats in the expression. + + # Remove 'mpz' if gmpy is installed. + args = str(tuple(map(int, e._mpf_))) + return '{func}({args})'.format(func=self._module_format('mpmath.mpf'), args=args) + + + def _print_Rational(self, e): + return "{func}({p})/{func}({q})".format( + func=self._module_format('mpmath.mpf'), + q=self._print(e.q), + p=self._print(e.p) + ) + + def _print_Half(self, e): + return self._print_Rational(e) + + def _print_uppergamma(self, e): + return "{}({}, {}, {})".format( + self._module_format('mpmath.gammainc'), + self._print(e.args[0]), + self._print(e.args[1]), + self._module_format('mpmath.inf')) + + def _print_lowergamma(self, e): + return "{}({}, 0, {})".format( + self._module_format('mpmath.gammainc'), + self._print(e.args[0]), + self._print(e.args[1])) + + def _print_log2(self, e): + return '{0}({1})/{0}(2)'.format( + self._module_format('mpmath.log'), self._print(e.args[0])) + + def _print_log1p(self, e): + return '{}({})'.format( + self._module_format('mpmath.log1p'), self._print(e.args[0])) + + def _print_Pow(self, expr, rational=False): + return self._hprint_Pow(expr, rational=rational, sqrt='mpmath.sqrt') + + def _print_Integral(self, e): + integration_vars, limits = _unpack_integral_limits(e) + + return "{}(lambda {}: {}, {})".format( + self._module_format("mpmath.quad"), + ", ".join(map(self._print, integration_vars)), + self._print(e.args[0]), + ", ".join("(%s, %s)" % tuple(map(self._print, l)) for l in limits)) + + + def _print_Derivative_zeta(self, args, seq_orders): + arg, = args + deriv_order, = seq_orders + return '{}({}, derivative={})'.format( + self._module_format('mpmath.zeta'), + self._print(arg), deriv_order + ) + + +for k in MpmathPrinter._kf: + setattr(MpmathPrinter, '_print_%s' % k, _print_known_func) + +for k in _known_constants_mpmath: + setattr(MpmathPrinter, '_print_%s' % k, _print_known_const) + + +class SymPyPrinter(AbstractPythonCodePrinter): + + language = "Python with SymPy" + + _default_settings = dict( + AbstractPythonCodePrinter._default_settings, + strict=False # any class name will per definition be what we target in SymPyPrinter. + ) + + def _print_Function(self, expr): + mod = expr.func.__module__ or '' + return '%s(%s)' % (self._module_format(mod + ('.' if mod else '') + expr.func.__name__), + ', '.join((self._print(arg) for arg in expr.args))) + + def _print_Pow(self, expr, rational=False): + return self._hprint_Pow(expr, rational=rational, sqrt='sympy.sqrt') diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/python.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/python.py new file mode 100644 index 0000000000000000000000000000000000000000..2f6862574d99db90f289de65144c7122ed2d731a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/python.py @@ -0,0 +1,92 @@ +import keyword as kw +import sympy +from .repr import ReprPrinter +from .str import StrPrinter + +# A list of classes that should be printed using StrPrinter +STRPRINT = ("Add", "Infinity", "Integer", "Mul", "NegativeInfinity", "Pow") + + +class PythonPrinter(ReprPrinter, StrPrinter): + """A printer which converts an expression into its Python interpretation.""" + + def __init__(self, settings=None): + super().__init__(settings) + self.symbols = [] + self.functions = [] + + # Create print methods for classes that should use StrPrinter instead + # of ReprPrinter. + for name in STRPRINT: + f_name = "_print_%s" % name + f = getattr(StrPrinter, f_name) + setattr(PythonPrinter, f_name, f) + + def _print_Function(self, expr): + func = expr.func.__name__ + if not hasattr(sympy, func) and func not in self.functions: + self.functions.append(func) + return StrPrinter._print_Function(self, expr) + + # procedure (!) for defining symbols which have be defined in print_python() + def _print_Symbol(self, expr): + symbol = self._str(expr) + if symbol not in self.symbols: + self.symbols.append(symbol) + return StrPrinter._print_Symbol(self, expr) + + def _print_module(self, expr): + raise ValueError('Modules in the expression are unacceptable') + + +def python(expr, **settings): + """Return Python interpretation of passed expression + (can be passed to the exec() function without any modifications)""" + + printer = PythonPrinter(settings) + exprp = printer.doprint(expr) + + result = '' + # Returning found symbols and functions + renamings = {} + for symbolname in printer.symbols: + # Remove curly braces from subscripted variables + if '{' in symbolname: + newsymbolname = symbolname.replace('{', '').replace('}', '') + renamings[sympy.Symbol(symbolname)] = newsymbolname + else: + newsymbolname = symbolname + + # Escape symbol names that are reserved Python keywords + if kw.iskeyword(newsymbolname): + while True: + newsymbolname += "_" + if (newsymbolname not in printer.symbols and + newsymbolname not in printer.functions): + renamings[sympy.Symbol( + symbolname)] = sympy.Symbol(newsymbolname) + break + result += newsymbolname + ' = Symbol(\'' + symbolname + '\')\n' + + for functionname in printer.functions: + newfunctionname = functionname + # Escape function names that are reserved Python keywords + if kw.iskeyword(newfunctionname): + while True: + newfunctionname += "_" + if (newfunctionname not in printer.symbols and + newfunctionname not in printer.functions): + renamings[sympy.Function( + functionname)] = sympy.Function(newfunctionname) + break + result += newfunctionname + ' = Function(\'' + functionname + '\')\n' + + if renamings: + exprp = expr.subs(renamings) + result += 'e = ' + printer._str(exprp) + return result + + +def print_python(expr, **settings): + """Print output of python() function""" + print(python(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pytorch.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pytorch.py new file mode 100644 index 0000000000000000000000000000000000000000..0e8ff01856fa1dce7f8e786065a32bb74d987254 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/pytorch.py @@ -0,0 +1,297 @@ + +from sympy.printing.pycode import AbstractPythonCodePrinter, ArrayPrinter +from sympy.matrices.expressions import MatrixExpr +from sympy.core.mul import Mul +from sympy.printing.precedence import PRECEDENCE +from sympy.external import import_module +from sympy.codegen.cfunctions import Sqrt +from sympy import S +from sympy import Integer + +import sympy + +torch = import_module('torch') + + +class TorchPrinter(ArrayPrinter, AbstractPythonCodePrinter): + + printmethod = "_torchcode" + + mapping = { + sympy.Abs: "torch.abs", + sympy.sign: "torch.sign", + + # XXX May raise error for ints. + sympy.ceiling: "torch.ceil", + sympy.floor: "torch.floor", + sympy.log: "torch.log", + sympy.exp: "torch.exp", + Sqrt: "torch.sqrt", + sympy.cos: "torch.cos", + sympy.acos: "torch.acos", + sympy.sin: "torch.sin", + sympy.asin: "torch.asin", + sympy.tan: "torch.tan", + sympy.atan: "torch.atan", + sympy.atan2: "torch.atan2", + # XXX Also may give NaN for complex results. + sympy.cosh: "torch.cosh", + sympy.acosh: "torch.acosh", + sympy.sinh: "torch.sinh", + sympy.asinh: "torch.asinh", + sympy.tanh: "torch.tanh", + sympy.atanh: "torch.atanh", + sympy.Pow: "torch.pow", + + sympy.re: "torch.real", + sympy.im: "torch.imag", + sympy.arg: "torch.angle", + + # XXX May raise error for ints and complexes + sympy.erf: "torch.erf", + sympy.loggamma: "torch.lgamma", + + sympy.Eq: "torch.eq", + sympy.Ne: "torch.ne", + sympy.StrictGreaterThan: "torch.gt", + sympy.StrictLessThan: "torch.lt", + sympy.LessThan: "torch.le", + sympy.GreaterThan: "torch.ge", + + sympy.And: "torch.logical_and", + sympy.Or: "torch.logical_or", + sympy.Not: "torch.logical_not", + sympy.Max: "torch.max", + sympy.Min: "torch.min", + + # Matrices + sympy.MatAdd: "torch.add", + sympy.HadamardProduct: "torch.mul", + sympy.Trace: "torch.trace", + + # XXX May raise error for integer matrices. + sympy.Determinant: "torch.det", + } + + _default_settings = dict( + AbstractPythonCodePrinter._default_settings, + torch_version=None, + requires_grad=False, + dtype="torch.float64", + ) + + def __init__(self, settings=None): + super().__init__(settings) + + version = self._settings['torch_version'] + self.requires_grad = self._settings['requires_grad'] + self.dtype = self._settings['dtype'] + if version is None and torch: + version = torch.__version__ + self.torch_version = version + + def _print_Function(self, expr): + + op = self.mapping.get(type(expr), None) + if op is None: + return super()._print_Basic(expr) + children = [self._print(arg) for arg in expr.args] + if len(children) == 1: + return "%s(%s)" % ( + self._module_format(op), + children[0] + ) + else: + return self._expand_fold_binary_op(op, children) + + # mirrors the tensorflow version + _print_Expr = _print_Function + _print_Application = _print_Function + _print_MatrixExpr = _print_Function + _print_Relational = _print_Function + _print_Not = _print_Function + _print_And = _print_Function + _print_Or = _print_Function + _print_HadamardProduct = _print_Function + _print_Trace = _print_Function + _print_Determinant = _print_Function + + def _print_Inverse(self, expr): + return '{}({})'.format(self._module_format("torch.linalg.inv"), + self._print(expr.args[0])) + + def _print_Transpose(self, expr): + if expr.arg.is_Matrix and expr.arg.shape[0] == expr.arg.shape[1]: + # For square matrices, we can use the .t() method + return "{}({}).t()".format("torch.transpose", self._print(expr.arg)) + else: + # For non-square matrices or more general cases + # transpose first and second dimensions (typical matrix transpose) + return "{}.permute({})".format( + self._print(expr.arg), + ", ".join([str(i) for i in range(len(expr.arg.shape))])[::-1] + ) + + def _print_PermuteDims(self, expr): + return "%s.permute(%s)" % ( + self._print(expr.expr), + ", ".join(str(i) for i in expr.permutation.array_form) + ) + + def _print_Derivative(self, expr): + # this version handles multi-variable and mixed partial derivatives. The tensorflow version does not. + variables = expr.variables + expr_arg = expr.expr + + # Handle multi-variable or repeated derivatives + if len(variables) > 1 or ( + len(variables) == 1 and not isinstance(variables[0], tuple) and variables.count(variables[0]) > 1): + result = self._print(expr_arg) + var_groups = {} + + # Group variables by base symbol + for var in variables: + if isinstance(var, tuple): + base_var, order = var + var_groups[base_var] = var_groups.get(base_var, 0) + order + else: + var_groups[var] = var_groups.get(var, 0) + 1 + + # Apply gradients in sequence + for var, order in var_groups.items(): + for _ in range(order): + result = "torch.autograd.grad({}, {}, create_graph=True)[0]".format(result, self._print(var)) + return result + + # Handle single variable case + if len(variables) == 1: + variable = variables[0] + if isinstance(variable, tuple) and len(variable) == 2: + base_var, order = variable + if not isinstance(order, Integer): raise NotImplementedError("Only integer orders are supported") + result = self._print(expr_arg) + for _ in range(order): + result = "torch.autograd.grad({}, {}, create_graph=True)[0]".format(result, self._print(base_var)) + return result + return "torch.autograd.grad({}, {})[0]".format(self._print(expr_arg), self._print(variable)) + + return self._print(expr_arg) # Empty variables case + + def _print_Piecewise(self, expr): + from sympy import Piecewise + e, cond = expr.args[0].args + if len(expr.args) == 1: + return '{}({}, {}, {})'.format( + self._module_format("torch.where"), + self._print(cond), + self._print(e), + 0) + + return '{}({}, {}, {})'.format( + self._module_format("torch.where"), + self._print(cond), + self._print(e), + self._print(Piecewise(*expr.args[1:]))) + + def _print_Pow(self, expr): + # XXX May raise error for + # int**float or int**complex or float**complex + base, exp = expr.args + if expr.exp == S.Half: + return "{}({})".format( + self._module_format("torch.sqrt"), self._print(base)) + return "{}({}, {})".format( + self._module_format("torch.pow"), + self._print(base), self._print(exp)) + + def _print_MatMul(self, expr): + # Separate matrix and scalar arguments + mat_args = [arg for arg in expr.args if isinstance(arg, MatrixExpr)] + args = [arg for arg in expr.args if arg not in mat_args] + # Handle scalar multipliers if present + if args: + return "%s*%s" % ( + self.parenthesize(Mul.fromiter(args), PRECEDENCE["Mul"]), + self._expand_fold_binary_op("torch.matmul", mat_args) + ) + else: + return self._expand_fold_binary_op("torch.matmul", mat_args) + + def _print_MatPow(self, expr): + return self._expand_fold_binary_op("torch.mm", [expr.base]*expr.exp) + + def _print_MatrixBase(self, expr): + data = "[" + ", ".join(["[" + ", ".join([self._print(j) for j in i]) + "]" for i in expr.tolist()]) + "]" + params = [str(data)] + params.append(f"dtype={self.dtype}") + if self.requires_grad: + params.append("requires_grad=True") + + return "{}({})".format( + self._module_format("torch.tensor"), + ", ".join(params) + ) + + def _print_isnan(self, expr): + return f'torch.isnan({self._print(expr.args[0])})' + + def _print_isinf(self, expr): + return f'torch.isinf({self._print(expr.args[0])})' + + def _print_Identity(self, expr): + if all(dim.is_Integer for dim in expr.shape): + return "{}({})".format( + self._module_format("torch.eye"), + self._print(expr.shape[0]) + ) + else: + # For symbolic dimensions, fall back to a more general approach + return "{}({}, {})".format( + self._module_format("torch.eye"), + self._print(expr.shape[0]), + self._print(expr.shape[1]) + ) + + def _print_ZeroMatrix(self, expr): + return "{}({})".format( + self._module_format("torch.zeros"), + self._print(expr.shape) + ) + + def _print_OneMatrix(self, expr): + return "{}({})".format( + self._module_format("torch.ones"), + self._print(expr.shape) + ) + + def _print_conjugate(self, expr): + return f"{self._module_format('torch.conj')}({self._print(expr.args[0])})" + + def _print_ImaginaryUnit(self, expr): + return "1j" # uses the Python built-in 1j notation for the imaginary unit + + def _print_Heaviside(self, expr): + args = [self._print(expr.args[0]), "0.5"] + if len(expr.args) > 1: + args[1] = self._print(expr.args[1]) + return f"{self._module_format('torch.heaviside')}({args[0]}, {args[1]})" + + def _print_gamma(self, expr): + return f"{self._module_format('torch.special.gamma')}({self._print(expr.args[0])})" + + def _print_polygamma(self, expr): + if expr.args[0] == S.Zero: + return f"{self._module_format('torch.special.digamma')}({self._print(expr.args[1])})" + else: + raise NotImplementedError("PyTorch only supports digamma (0th order polygamma)") + + _module = "torch" + _einsum = "einsum" + _add = "add" + _transpose = "t" + _ones = "ones" + _zeros = "zeros" + +def torch_code(expr, requires_grad=False, dtype="torch.float64", **settings): + printer = TorchPrinter(settings={'requires_grad': requires_grad, 'dtype': dtype}) + return printer.doprint(expr, **settings) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/rcode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/rcode.py new file mode 100644 index 0000000000000000000000000000000000000000..3107e6e94d5c5acf0b2dc063e4a83af6970f6576 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/rcode.py @@ -0,0 +1,402 @@ +""" +R code printer + +The RCodePrinter converts single SymPy expressions into single R expressions, +using the functions defined in math.h where possible. + + + +""" + +from __future__ import annotations +from typing import Any + +from sympy.core.numbers import equal_valued +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import precedence, PRECEDENCE +from sympy.sets.fancysets import Range + +# dictionary mapping SymPy function to (argument_conditions, C_function). +# Used in RCodePrinter._print_Function(self) +known_functions = { + #"Abs": [(lambda x: not x.is_integer, "fabs")], + "Abs": "abs", + "sin": "sin", + "cos": "cos", + "tan": "tan", + "asin": "asin", + "acos": "acos", + "atan": "atan", + "atan2": "atan2", + "exp": "exp", + "log": "log", + "erf": "erf", + "sinh": "sinh", + "cosh": "cosh", + "tanh": "tanh", + "asinh": "asinh", + "acosh": "acosh", + "atanh": "atanh", + "floor": "floor", + "ceiling": "ceiling", + "sign": "sign", + "Max": "max", + "Min": "min", + "factorial": "factorial", + "gamma": "gamma", + "digamma": "digamma", + "trigamma": "trigamma", + "beta": "beta", + "sqrt": "sqrt", # To enable automatic rewrite +} + +# These are the core reserved words in the R language. Taken from: +# https://cran.r-project.org/doc/manuals/r-release/R-lang.html#Reserved-words + +reserved_words = ['if', + 'else', + 'repeat', + 'while', + 'function', + 'for', + 'in', + 'next', + 'break', + 'TRUE', + 'FALSE', + 'NULL', + 'Inf', + 'NaN', + 'NA', + 'NA_integer_', + 'NA_real_', + 'NA_complex_', + 'NA_character_', + 'volatile'] + + +class RCodePrinter(CodePrinter): + """A printer to convert SymPy expressions to strings of R code""" + printmethod = "_rcode" + language = "R" + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 15, + 'user_functions': {}, + 'contract': True, + 'dereference': set(), + }) + _operators = { + 'and': '&', + 'or': '|', + 'not': '!', + } + + _relationals: dict[str, str] = {} + + def __init__(self, settings={}): + CodePrinter.__init__(self, settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + self._dereference = set(settings.get('dereference', [])) + self.reserved_words = set(reserved_words) + + def _rate_index_position(self, p): + return p*5 + + def _get_statement(self, codestring): + return "%s;" % codestring + + def _get_comment(self, text): + return "// {}".format(text) + + def _declare_number_const(self, name, value): + return "{} = {};".format(name, value) + + def _format_code(self, lines): + return self.indent_code(lines) + + def _traverse_matrix_indices(self, mat): + rows, cols = mat.shape + return ((i, j) for i in range(rows) for j in range(cols)) + + def _get_loop_opening_ending(self, indices): + """Returns a tuple (open_lines, close_lines) containing lists of codelines + """ + open_lines = [] + close_lines = [] + loopstart = "for (%(var)s in %(start)s:%(end)s){" + for i in indices: + # R arrays start at 1 and end at dimension + open_lines.append(loopstart % { + 'var': self._print(i.label), + 'start': self._print(i.lower+1), + 'end': self._print(i.upper + 1)}) + close_lines.append("}") + return open_lines, close_lines + + def _print_Pow(self, expr): + if "Pow" in self.known_functions: + return self._print_Function(expr) + PREC = precedence(expr) + if equal_valued(expr.exp, -1): + return '1.0/%s' % (self.parenthesize(expr.base, PREC)) + elif equal_valued(expr.exp, 0.5): + return 'sqrt(%s)' % self._print(expr.base) + else: + return '%s^%s' % (self.parenthesize(expr.base, PREC), + self.parenthesize(expr.exp, PREC)) + + + def _print_Rational(self, expr): + p, q = int(expr.p), int(expr.q) + return '%d.0/%d.0' % (p, q) + + def _print_Indexed(self, expr): + inds = [ self._print(i) for i in expr.indices ] + return "%s[%s]" % (self._print(expr.base.label), ", ".join(inds)) + + def _print_Exp1(self, expr): + return "exp(1)" + + def _print_Pi(self, expr): + return 'pi' + + def _print_Infinity(self, expr): + return 'Inf' + + def _print_NegativeInfinity(self, expr): + return '-Inf' + + def _print_Assignment(self, expr): + from sympy.codegen.ast import Assignment + + from sympy.matrices.expressions.matexpr import MatrixSymbol + from sympy.tensor.indexed import IndexedBase + lhs = expr.lhs + rhs = expr.rhs + # We special case assignments that take multiple lines + #if isinstance(expr.rhs, Piecewise): + # from sympy.functions.elementary.piecewise import Piecewise + # # Here we modify Piecewise so each expression is now + # # an Assignment, and then continue on the print. + # expressions = [] + # conditions = [] + # for (e, c) in rhs.args: + # expressions.append(Assignment(lhs, e)) + # conditions.append(c) + # temp = Piecewise(*zip(expressions, conditions)) + # return self._print(temp) + #elif isinstance(lhs, MatrixSymbol): + if isinstance(lhs, MatrixSymbol): + # Here we form an Assignment for each element in the array, + # printing each one. + lines = [] + for (i, j) in self._traverse_matrix_indices(lhs): + temp = Assignment(lhs[i, j], rhs[i, j]) + code0 = self._print(temp) + lines.append(code0) + return "\n".join(lines) + elif self._settings["contract"] and (lhs.has(IndexedBase) or + rhs.has(IndexedBase)): + # Here we check if there is looping to be done, and if so + # print the required loops. + return self._doprint_loops(rhs, lhs) + else: + lhs_code = self._print(lhs) + rhs_code = self._print(rhs) + return self._get_statement("%s = %s" % (lhs_code, rhs_code)) + + def _print_Piecewise(self, expr): + # This method is called only for inline if constructs + # Top level piecewise is handled in doprint() + if expr.args[-1].cond == True: + last_line = "%s" % self._print(expr.args[-1].expr) + else: + last_line = "ifelse(%s,%s,NA)" % (self._print(expr.args[-1].cond), self._print(expr.args[-1].expr)) + code=last_line + for e, c in reversed(expr.args[:-1]): + code= "ifelse(%s,%s," % (self._print(c), self._print(e))+code+")" + return(code) + + def _print_ITE(self, expr): + from sympy.functions import Piecewise + return self._print(expr.rewrite(Piecewise)) + + def _print_MatrixElement(self, expr): + return "{}[{}]".format(self.parenthesize(expr.parent, PRECEDENCE["Atom"], + strict=True), expr.j + expr.i*expr.parent.shape[1]) + + def _print_Symbol(self, expr): + name = super()._print_Symbol(expr) + if expr in self._dereference: + return '(*{})'.format(name) + else: + return name + + def _print_Relational(self, expr): + lhs_code = self._print(expr.lhs) + rhs_code = self._print(expr.rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_AugmentedAssignment(self, expr): + lhs_code = self._print(expr.lhs) + op = expr.op + rhs_code = self._print(expr.rhs) + return "{} {} {};".format(lhs_code, op, rhs_code) + + def _print_For(self, expr): + target = self._print(expr.target) + if isinstance(expr.iterable, Range): + start, stop, step = expr.iterable.args + else: + raise NotImplementedError("Only iterable currently supported is Range") + body = self._print(expr.body) + return 'for({target} in seq(from={start}, to={stop}, by={step}){{\n{body}\n}}'.format(target=target, start=start, + stop=stop-1, step=step, body=body) + + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_token = ('{', '(', '{\n', '(\n') + dec_token = ('}', ')') + + code = [ line.lstrip(' \t') for line in code ] + + increase = [ int(any(map(line.endswith, inc_token))) for line in code ] + decrease = [ int(any(map(line.startswith, dec_token))) + for line in code ] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty + + +def rcode(expr, assign_to=None, **settings): + """Converts an expr to a string of r code + + Parameters + ========== + + expr : Expr + A SymPy expression to be converted. + assign_to : optional + When given, the argument is used as the name of the variable to which + the expression is assigned. Can be a string, ``Symbol``, + ``MatrixSymbol``, or ``Indexed`` type. This is helpful in case of + line-wrapping, or for expressions that generate multi-line statements. + precision : integer, optional + The precision for numbers such as pi [default=15]. + user_functions : dict, optional + A dictionary where the keys are string representations of either + ``FunctionClass`` or ``UndefinedFunction`` instances and the values + are their desired R string representations. Alternatively, the + dictionary value can be a list of tuples i.e. [(argument_test, + rfunction_string)] or [(argument_test, rfunction_formater)]. See below + for examples. + human : bool, optional + If True, the result is a single string that may contain some constant + declarations for the number symbols. If False, the same information is + returned in a tuple of (symbols_to_declare, not_supported_functions, + code_text). [default=True]. + contract: bool, optional + If True, ``Indexed`` instances are assumed to obey tensor contraction + rules and the corresponding nested loops over indices are generated. + Setting contract=False will not generate loops, instead the user is + responsible to provide values for the indices in the code. + [default=True]. + + Examples + ======== + + >>> from sympy import rcode, symbols, Rational, sin, ceiling, Abs, Function + >>> x, tau = symbols("x, tau") + >>> rcode((2*tau)**Rational(7, 2)) + '8*sqrt(2)*tau^(7.0/2.0)' + >>> rcode(sin(x), assign_to="s") + 's = sin(x);' + + Simple custom printing can be defined for certain types by passing a + dictionary of {"type" : "function"} to the ``user_functions`` kwarg. + Alternatively, the dictionary value can be a list of tuples i.e. + [(argument_test, cfunction_string)]. + + >>> custom_functions = { + ... "ceiling": "CEIL", + ... "Abs": [(lambda x: not x.is_integer, "fabs"), + ... (lambda x: x.is_integer, "ABS")], + ... "func": "f" + ... } + >>> func = Function('func') + >>> rcode(func(Abs(x) + ceiling(x)), user_functions=custom_functions) + 'f(fabs(x) + CEIL(x))' + + or if the R-function takes a subset of the original arguments: + + >>> rcode(2**x + 3**x, user_functions={'Pow': [ + ... (lambda b, e: b == 2, lambda b, e: 'exp2(%s)' % e), + ... (lambda b, e: b != 2, 'pow')]}) + 'exp2(x) + pow(3, x)' + + ``Piecewise`` expressions are converted into conditionals. If an + ``assign_to`` variable is provided an if statement is created, otherwise + the ternary operator is used. Note that if the ``Piecewise`` lacks a + default term, represented by ``(expr, True)`` then an error will be thrown. + This is to prevent generating an expression that may not evaluate to + anything. + + >>> from sympy import Piecewise + >>> expr = Piecewise((x + 1, x > 0), (x, True)) + >>> print(rcode(expr, assign_to=tau)) + tau = ifelse(x > 0,x + 1,x); + + Support for loops is provided through ``Indexed`` types. With + ``contract=True`` these expressions will be turned into loops, whereas + ``contract=False`` will just print the assignment expression that should be + looped over: + + >>> from sympy import Eq, IndexedBase, Idx + >>> len_y = 5 + >>> y = IndexedBase('y', shape=(len_y,)) + >>> t = IndexedBase('t', shape=(len_y,)) + >>> Dy = IndexedBase('Dy', shape=(len_y-1,)) + >>> i = Idx('i', len_y-1) + >>> e=Eq(Dy[i], (y[i+1]-y[i])/(t[i+1]-t[i])) + >>> rcode(e.rhs, assign_to=e.lhs, contract=False) + 'Dy[i] = (y[i + 1] - y[i])/(t[i + 1] - t[i]);' + + Matrices are also supported, but a ``MatrixSymbol`` of the same dimensions + must be provided to ``assign_to``. Note that any expression that can be + generated normally can also exist inside a Matrix: + + >>> from sympy import Matrix, MatrixSymbol + >>> mat = Matrix([x**2, Piecewise((x + 1, x > 0), (x, True)), sin(x)]) + >>> A = MatrixSymbol('A', 3, 1) + >>> print(rcode(mat, A)) + A[0] = x^2; + A[1] = ifelse(x > 0,x + 1,x); + A[2] = sin(x); + + """ + + return RCodePrinter(settings).doprint(expr, assign_to) + + +def print_rcode(expr, **settings): + """Prints R representation of the given expression.""" + print(rcode(expr, **settings)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/repr.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/repr.py new file mode 100644 index 0000000000000000000000000000000000000000..0a4b756abbab77c3eb0fd77ee1f0bd97382c36fb --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/repr.py @@ -0,0 +1,339 @@ +""" +A Printer for generating executable code. + +The most important function here is srepr that returns a string so that the +relation eval(srepr(expr))=expr holds in an appropriate environment. +""" + +from __future__ import annotations +from typing import Any + +from sympy.core.function import AppliedUndef +from sympy.core.mul import Mul +from mpmath.libmp import repr_dps, to_str as mlib_to_str + +from .printer import Printer, print_function + + +class ReprPrinter(Printer): + printmethod = "_sympyrepr" + + _default_settings: dict[str, Any] = { + "order": None, + "perm_cyclic" : True, + } + + def reprify(self, args, sep): + """ + Prints each item in `args` and joins them with `sep`. + """ + return sep.join([self.doprint(item) for item in args]) + + def emptyPrinter(self, expr): + """ + The fallback printer. + """ + if isinstance(expr, str): + return expr + elif hasattr(expr, "__srepr__"): + return expr.__srepr__() + elif hasattr(expr, "args") and hasattr(expr.args, "__iter__"): + l = [] + for o in expr.args: + l.append(self._print(o)) + return expr.__class__.__name__ + '(%s)' % ', '.join(l) + elif hasattr(expr, "__module__") and hasattr(expr, "__name__"): + return "<'%s.%s'>" % (expr.__module__, expr.__name__) + else: + return str(expr) + + def _print_Add(self, expr, order=None): + args = self._as_ordered_terms(expr, order=order) + args = map(self._print, args) + clsname = type(expr).__name__ + return clsname + "(%s)" % ", ".join(args) + + def _print_Cycle(self, expr): + return expr.__repr__() + + def _print_Permutation(self, expr): + from sympy.combinatorics.permutations import Permutation, Cycle + from sympy.utilities.exceptions import sympy_deprecation_warning + + perm_cyclic = Permutation.print_cyclic + if perm_cyclic is not None: + sympy_deprecation_warning( + f""" + Setting Permutation.print_cyclic is deprecated. Instead use + init_printing(perm_cyclic={perm_cyclic}). + """, + deprecated_since_version="1.6", + active_deprecations_target="deprecated-permutation-print_cyclic", + stacklevel=7, + ) + else: + perm_cyclic = self._settings.get("perm_cyclic", True) + + if perm_cyclic: + if not expr.size: + return 'Permutation()' + # before taking Cycle notation, see if the last element is + # a singleton and move it to the head of the string + s = Cycle(expr)(expr.size - 1).__repr__()[len('Cycle'):] + last = s.rfind('(') + if not last == 0 and ',' not in s[last:]: + s = s[last:] + s[:last] + return 'Permutation%s' %s + else: + s = expr.support() + if not s: + if expr.size < 5: + return 'Permutation(%s)' % str(expr.array_form) + return 'Permutation([], size=%s)' % expr.size + trim = str(expr.array_form[:s[-1] + 1]) + ', size=%s' % expr.size + use = full = str(expr.array_form) + if len(trim) < len(full): + use = trim + return 'Permutation(%s)' % use + + def _print_Function(self, expr): + r = self._print(expr.func) + r += '(%s)' % ', '.join([self._print(a) for a in expr.args]) + return r + + def _print_Heaviside(self, expr): + # Same as _print_Function but uses pargs to suppress default value for + # 2nd arg. + r = self._print(expr.func) + r += '(%s)' % ', '.join([self._print(a) for a in expr.pargs]) + return r + + def _print_FunctionClass(self, expr): + if issubclass(expr, AppliedUndef): + return 'Function(%r)' % (expr.__name__) + else: + return expr.__name__ + + def _print_Half(self, expr): + return 'Rational(1, 2)' + + def _print_RationalConstant(self, expr): + return str(expr) + + def _print_AtomicExpr(self, expr): + return str(expr) + + def _print_NumberSymbol(self, expr): + return str(expr) + + def _print_Integer(self, expr): + return 'Integer(%i)' % expr.p + + def _print_Complexes(self, expr): + return 'Complexes' + + def _print_Integers(self, expr): + return 'Integers' + + def _print_Naturals(self, expr): + return 'Naturals' + + def _print_Naturals0(self, expr): + return 'Naturals0' + + def _print_Rationals(self, expr): + return 'Rationals' + + def _print_Reals(self, expr): + return 'Reals' + + def _print_EmptySet(self, expr): + return 'EmptySet' + + def _print_UniversalSet(self, expr): + return 'UniversalSet' + + def _print_EmptySequence(self, expr): + return 'EmptySequence' + + def _print_list(self, expr): + return "[%s]" % self.reprify(expr, ", ") + + def _print_dict(self, expr): + sep = ", " + dict_kvs = ["%s: %s" % (self.doprint(key), self.doprint(value)) for key, value in expr.items()] + return "{%s}" % sep.join(dict_kvs) + + def _print_set(self, expr): + if not expr: + return "set()" + return "{%s}" % self.reprify(expr, ", ") + + def _print_MatrixBase(self, expr): + # special case for some empty matrices + if (expr.rows == 0) ^ (expr.cols == 0): + return '%s(%s, %s, %s)' % (expr.__class__.__name__, + self._print(expr.rows), + self._print(expr.cols), + self._print([])) + l = [] + for i in range(expr.rows): + l.append([]) + for j in range(expr.cols): + l[-1].append(expr[i, j]) + return '%s(%s)' % (expr.__class__.__name__, self._print(l)) + + def _print_BooleanTrue(self, expr): + return "true" + + def _print_BooleanFalse(self, expr): + return "false" + + def _print_NaN(self, expr): + return "nan" + + def _print_Mul(self, expr, order=None): + if self.order not in ('old', 'none'): + args = expr.as_ordered_factors() + else: + # use make_args in case expr was something like -x -> x + args = Mul.make_args(expr) + + args = map(self._print, args) + clsname = type(expr).__name__ + return clsname + "(%s)" % ", ".join(args) + + def _print_Rational(self, expr): + return 'Rational(%s, %s)' % (self._print(expr.p), self._print(expr.q)) + + def _print_PythonRational(self, expr): + return "%s(%d, %d)" % (expr.__class__.__name__, expr.p, expr.q) + + def _print_Fraction(self, expr): + return 'Fraction(%s, %s)' % (self._print(expr.numerator), self._print(expr.denominator)) + + def _print_Float(self, expr): + r = mlib_to_str(expr._mpf_, repr_dps(expr._prec)) + return "%s('%s', precision=%i)" % (expr.__class__.__name__, r, expr._prec) + + def _print_Sum2(self, expr): + return "Sum2(%s, (%s, %s, %s))" % (self._print(expr.f), self._print(expr.i), + self._print(expr.a), self._print(expr.b)) + + def _print_Str(self, s): + return "%s(%s)" % (s.__class__.__name__, self._print(s.name)) + + def _print_Symbol(self, expr): + d = expr._assumptions_orig + # print the dummy_index like it was an assumption + if expr.is_Dummy: + d = d.copy() + d['dummy_index'] = expr.dummy_index + + if d == {}: + return "%s(%s)" % (expr.__class__.__name__, self._print(expr.name)) + else: + attr = ['%s=%s' % (k, v) for k, v in d.items()] + return "%s(%s, %s)" % (expr.__class__.__name__, + self._print(expr.name), ', '.join(attr)) + + def _print_CoordinateSymbol(self, expr): + d = expr._assumptions.generator + + if d == {}: + return "%s(%s, %s)" % ( + expr.__class__.__name__, + self._print(expr.coord_sys), + self._print(expr.index) + ) + else: + attr = ['%s=%s' % (k, v) for k, v in d.items()] + return "%s(%s, %s, %s)" % ( + expr.__class__.__name__, + self._print(expr.coord_sys), + self._print(expr.index), + ', '.join(attr) + ) + + def _print_Predicate(self, expr): + return "Q.%s" % expr.name + + def _print_AppliedPredicate(self, expr): + # will be changed to just expr.args when args overriding is removed + args = expr._args + return "%s(%s)" % (expr.__class__.__name__, self.reprify(args, ", ")) + + def _print_str(self, expr): + return repr(expr) + + def _print_tuple(self, expr): + if len(expr) == 1: + return "(%s,)" % self._print(expr[0]) + else: + return "(%s)" % self.reprify(expr, ", ") + + def _print_WildFunction(self, expr): + return "%s('%s')" % (expr.__class__.__name__, expr.name) + + def _print_AlgebraicNumber(self, expr): + return "%s(%s, %s)" % (expr.__class__.__name__, + self._print(expr.root), self._print(expr.coeffs())) + + def _print_PolyRing(self, ring): + return "%s(%s, %s, %s)" % (ring.__class__.__name__, + self._print(ring.symbols), self._print(ring.domain), self._print(ring.order)) + + def _print_FracField(self, field): + return "%s(%s, %s, %s)" % (field.__class__.__name__, + self._print(field.symbols), self._print(field.domain), self._print(field.order)) + + def _print_PolyElement(self, poly): + terms = list(poly.terms()) + terms.sort(key=poly.ring.order, reverse=True) + return "%s(%s, %s)" % (poly.__class__.__name__, self._print(poly.ring), self._print(terms)) + + def _print_FracElement(self, frac): + numer_terms = list(frac.numer.terms()) + numer_terms.sort(key=frac.field.order, reverse=True) + denom_terms = list(frac.denom.terms()) + denom_terms.sort(key=frac.field.order, reverse=True) + numer = self._print(numer_terms) + denom = self._print(denom_terms) + return "%s(%s, %s, %s)" % (frac.__class__.__name__, self._print(frac.field), numer, denom) + + def _print_FractionField(self, domain): + cls = domain.__class__.__name__ + field = self._print(domain.field) + return "%s(%s)" % (cls, field) + + def _print_PolynomialRingBase(self, ring): + cls = ring.__class__.__name__ + dom = self._print(ring.domain) + gens = ', '.join(map(self._print, ring.gens)) + order = str(ring.order) + if order != ring.default_order: + orderstr = ", order=" + order + else: + orderstr = "" + return "%s(%s, %s%s)" % (cls, dom, gens, orderstr) + + def _print_DMP(self, p): + cls = p.__class__.__name__ + rep = self._print(p.to_list()) + dom = self._print(p.dom) + return "%s(%s, %s)" % (cls, rep, dom) + + def _print_MonogenicFiniteExtension(self, ext): + # The expanded tree shown by srepr(ext.modulus) + # is not practical. + return "FiniteExtension(%s)" % str(ext.modulus) + + def _print_ExtensionElement(self, f): + rep = self._print(f.rep) + ext = self._print(f.ext) + return "ExtElem(%s, %s)" % (rep, ext) + +@print_function(ReprPrinter) +def srepr(expr, **settings): + """return expr in repr form""" + return ReprPrinter(settings).doprint(expr) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/rust.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/rust.py new file mode 100644 index 0000000000000000000000000000000000000000..5bfd481bec6b7350df281accfb9b7a598cf05baa --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/rust.py @@ -0,0 +1,637 @@ +""" +Rust code printer + +The `RustCodePrinter` converts SymPy expressions into Rust expressions. + +A complete code generator, which uses `rust_code` extensively, can be found +in `sympy.utilities.codegen`. The `codegen` module can be used to generate +complete source code files. + +""" + +# Possible Improvement +# +# * make sure we follow Rust Style Guidelines_ +# * make use of pattern matching +# * better support for reference +# * generate generic code and use trait to make sure they have specific methods +# * use crates_ to get more math support +# - num_ +# + BigInt_, BigUint_ +# + Complex_ +# + Rational64_, Rational32_, BigRational_ +# +# .. _crates: https://crates.io/ +# .. _Guidelines: https://github.com/rust-lang/rust/tree/master/src/doc/style +# .. _num: http://rust-num.github.io/num/num/ +# .. _BigInt: http://rust-num.github.io/num/num/bigint/struct.BigInt.html +# .. _BigUint: http://rust-num.github.io/num/num/bigint/struct.BigUint.html +# .. _Complex: http://rust-num.github.io/num/num/complex/struct.Complex.html +# .. _Rational32: http://rust-num.github.io/num/num/rational/type.Rational32.html +# .. _Rational64: http://rust-num.github.io/num/num/rational/type.Rational64.html +# .. _BigRational: http://rust-num.github.io/num/num/rational/type.BigRational.html + +from __future__ import annotations +from functools import reduce +import operator +from typing import Any + +from sympy.codegen.ast import ( + float32, float64, int32, + real, integer, bool_ +) +from sympy.core import S, Rational, Float, Lambda +from sympy.core.expr import Expr +from sympy.core.numbers import equal_valued +from sympy.functions.elementary.integers import ceiling, floor +from sympy.printing.codeprinter import CodePrinter +from sympy.printing.precedence import PRECEDENCE + +# Rust's methods for integer and float can be found at here : +# +# * `Rust - Primitive Type f64 `_ +# * `Rust - Primitive Type i64 `_ +# +# Function Style : +# +# 1. args[0].func(args[1:]), method with arguments +# 2. args[0].func(), method without arguments +# 3. args[1].func(), method without arguments (e.g. (e, x) => x.exp()) +# 4. func(args), function with arguments + +# dictionary mapping SymPy function to (argument_conditions, Rust_function). +# Used in RustCodePrinter._print_Function(self) + +class float_floor(floor): + """ + Same as `sympy.floor`, but mimics the Rust behavior of returning a float rather than an integer + """ + def _eval_is_integer(self): + return False + +class float_ceiling(ceiling): + """ + Same as `sympy.ceiling`, but mimics the Rust behavior of returning a float rather than an integer + """ + def _eval_is_integer(self): + return False + + +function_overrides = { + "floor": (floor, float_floor), + "ceiling": (ceiling, float_ceiling), +} + +# f64 method in Rust +known_functions = { + # "": "is_nan", + # "": "is_infinite", + # "": "is_finite", + # "": "is_normal", + # "": "classify", + "float_floor": "floor", + "float_ceiling": "ceil", + # "": "round", + # "": "trunc", + # "": "fract", + "Abs": "abs", + # "": "signum", + # "": "is_sign_positive", + # "": "is_sign_negative", + # "": "mul_add", + "Pow": [(lambda base, exp: equal_valued(exp, -1), "recip", 2), # 1.0/x + (lambda base, exp: equal_valued(exp, 0.5), "sqrt", 2), # x ** 0.5 + (lambda base, exp: equal_valued(exp, -0.5), "sqrt().recip", 2), # 1/(x ** 0.5) + (lambda base, exp: exp == Rational(1, 3), "cbrt", 2), # x ** (1/3) + (lambda base, exp: equal_valued(base, 2), "exp2", 3), # 2 ** x + (lambda base, exp: exp.is_integer, "powi", 1), # x ** y, for i32 + (lambda base, exp: not exp.is_integer, "powf", 1)], # x ** y, for f64 + "exp": [(lambda exp: True, "exp", 2)], # e ** x + "log": "ln", + # "": "log", # number.log(base) + # "": "log2", + # "": "log10", + # "": "to_degrees", + # "": "to_radians", + "Max": "max", + "Min": "min", + # "": "hypot", # (x**2 + y**2) ** 0.5 + "sin": "sin", + "cos": "cos", + "tan": "tan", + "asin": "asin", + "acos": "acos", + "atan": "atan", + "atan2": "atan2", + # "": "sin_cos", + # "": "exp_m1", # e ** x - 1 + # "": "ln_1p", # ln(1 + x) + "sinh": "sinh", + "cosh": "cosh", + "tanh": "tanh", + "asinh": "asinh", + "acosh": "acosh", + "atanh": "atanh", + "sqrt": "sqrt", # To enable automatic rewrites +} + +# i64 method in Rust +# known_functions_i64 = { +# "": "min_value", +# "": "max_value", +# "": "from_str_radix", +# "": "count_ones", +# "": "count_zeros", +# "": "leading_zeros", +# "": "trainling_zeros", +# "": "rotate_left", +# "": "rotate_right", +# "": "swap_bytes", +# "": "from_be", +# "": "from_le", +# "": "to_be", # to big endian +# "": "to_le", # to little endian +# "": "checked_add", +# "": "checked_sub", +# "": "checked_mul", +# "": "checked_div", +# "": "checked_rem", +# "": "checked_neg", +# "": "checked_shl", +# "": "checked_shr", +# "": "checked_abs", +# "": "saturating_add", +# "": "saturating_sub", +# "": "saturating_mul", +# "": "wrapping_add", +# "": "wrapping_sub", +# "": "wrapping_mul", +# "": "wrapping_div", +# "": "wrapping_rem", +# "": "wrapping_neg", +# "": "wrapping_shl", +# "": "wrapping_shr", +# "": "wrapping_abs", +# "": "overflowing_add", +# "": "overflowing_sub", +# "": "overflowing_mul", +# "": "overflowing_div", +# "": "overflowing_rem", +# "": "overflowing_neg", +# "": "overflowing_shl", +# "": "overflowing_shr", +# "": "overflowing_abs", +# "Pow": "pow", +# "Abs": "abs", +# "sign": "signum", +# "": "is_positive", +# "": "is_negnative", +# } + +# These are the core reserved words in the Rust language. Taken from: +# https://doc.rust-lang.org/reference/keywords.html + +reserved_words = ['abstract', + 'as', + 'async', + 'await', + 'become', + 'box', + 'break', + 'const', + 'continue', + 'crate', + 'do', + 'dyn', + 'else', + 'enum', + 'extern', + 'false', + 'final', + 'fn', + 'for', + 'gen', + 'if', + 'impl', + 'in', + 'let', + 'loop', + 'macro', + 'match', + 'mod', + 'move', + 'mut', + 'override', + 'priv', + 'pub', + 'ref', + 'return', + 'Self', + 'self', + 'static', + 'struct', + 'super', + 'trait', + 'true', + 'try', + 'type', + 'typeof', + 'unsafe', + 'unsized', + 'use', + 'virtual', + 'where', + 'while', + 'yield'] + + +class TypeCast(Expr): + """ + The type casting operator of the Rust language. + """ + + def __init__(self, expr, type_) -> None: + super().__init__() + self.explicit = expr.is_integer and type_ is not integer + self._assumptions = expr._assumptions + if self.explicit: + setattr(self, 'precedence', PRECEDENCE["Func"] + 10) + + @property + def expr(self): + return self.args[0] + + @property + def type_(self): + return self.args[1] + + def sort_key(self, order=None): + return self.args[0].sort_key(order=order) + + +class RustCodePrinter(CodePrinter): + """A printer to convert SymPy expressions to strings of Rust code""" + printmethod = "_rust_code" + language = "Rust" + + type_aliases = { + integer: int32, + real: float64, + } + + type_mappings = { + int32: 'i32', + float32: 'f32', + float64: 'f64', + bool_: 'bool' + } + + _default_settings: dict[str, Any] = dict(CodePrinter._default_settings, **{ + 'precision': 17, + 'user_functions': {}, + 'contract': True, + 'dereference': set(), + }) + + def __init__(self, settings={}): + CodePrinter.__init__(self, settings) + self.known_functions = dict(known_functions) + userfuncs = settings.get('user_functions', {}) + self.known_functions.update(userfuncs) + self._dereference = set(settings.get('dereference', [])) + self.reserved_words = set(reserved_words) + self.function_overrides = function_overrides + + def _rate_index_position(self, p): + return p*5 + + def _get_statement(self, codestring): + return "%s;" % codestring + + def _get_comment(self, text): + return "// %s" % text + + def _declare_number_const(self, name, value): + type_ = self.type_mappings[self.type_aliases[real]] + return "const %s: %s = %s;" % (name, type_, value) + + def _format_code(self, lines): + return self.indent_code(lines) + + def _traverse_matrix_indices(self, mat): + rows, cols = mat.shape + return ((i, j) for i in range(rows) for j in range(cols)) + + def _get_loop_opening_ending(self, indices): + open_lines = [] + close_lines = [] + loopstart = "for %(var)s in %(start)s..%(end)s {" + for i in indices: + # Rust arrays start at 0 and end at dimension-1 + open_lines.append(loopstart % { + 'var': self._print(i), + 'start': self._print(i.lower), + 'end': self._print(i.upper + 1)}) + close_lines.append("}") + return open_lines, close_lines + + def _print_caller_var(self, expr): + if len(expr.args) > 1: + # for something like `sin(x + y + z)`, + # make sure we can get '(x + y + z).sin()' + # instead of 'x + y + z.sin()' + return '(' + self._print(expr) + ')' + elif expr.is_number: + return self._print(expr, _type=True) + else: + return self._print(expr) + + def _print_Function(self, expr): + """ + basic function for printing `Function` + + Function Style : + + 1. args[0].func(args[1:]), method with arguments + 2. args[0].func(), method without arguments + 3. args[1].func(), method without arguments (e.g. (e, x) => x.exp()) + 4. func(args), function with arguments + """ + + if expr.func.__name__ in self.known_functions: + cond_func = self.known_functions[expr.func.__name__] + func = None + style = 1 + if isinstance(cond_func, str): + func = cond_func + else: + for cond, func, style in cond_func: + if cond(*expr.args): + break + if func is not None: + if style == 1: + ret = "%(var)s.%(method)s(%(args)s)" % { + 'var': self._print_caller_var(expr.args[0]), + 'method': func, + 'args': self.stringify(expr.args[1:], ", ") if len(expr.args) > 1 else '' + } + elif style == 2: + ret = "%(var)s.%(method)s()" % { + 'var': self._print_caller_var(expr.args[0]), + 'method': func, + } + elif style == 3: + ret = "%(var)s.%(method)s()" % { + 'var': self._print_caller_var(expr.args[1]), + 'method': func, + } + else: + ret = "%(func)s(%(args)s)" % { + 'func': func, + 'args': self.stringify(expr.args, ", "), + } + return ret + elif hasattr(expr, '_imp_') and isinstance(expr._imp_, Lambda): + # inlined function + return self._print(expr._imp_(*expr.args)) + else: + return self._print_not_supported(expr) + + def _print_Mul(self, expr): + contains_floats = any(arg.is_real and not arg.is_integer for arg in expr.args) + if contains_floats: + expr = reduce(operator.mul,(self._cast_to_float(arg) if arg != -1 else arg for arg in expr.args)) + + return super()._print_Mul(expr) + + def _print_Add(self, expr, order=None): + contains_floats = any(arg.is_real and not arg.is_integer for arg in expr.args) + if contains_floats: + expr = reduce(operator.add, (self._cast_to_float(arg) for arg in expr.args)) + + return super()._print_Add(expr, order) + + def _print_Pow(self, expr): + if expr.base.is_integer and not expr.exp.is_integer: + expr = type(expr)(Float(expr.base), expr.exp) + return self._print(expr) + return self._print_Function(expr) + + def _print_TypeCast(self, expr): + if not expr.explicit: + return self._print(expr.expr) + else: + return self._print(expr.expr) + ' as %s' % self.type_mappings[self.type_aliases[expr.type_]] + + def _print_Float(self, expr, _type=False): + ret = super()._print_Float(expr) + if _type: + return ret + '_%s' % self.type_mappings[self.type_aliases[real]] + else: + return ret + + def _print_Integer(self, expr, _type=False): + ret = super()._print_Integer(expr) + if _type: + return ret + '_%s' % self.type_mappings[self.type_aliases[integer]] + else: + return ret + + def _print_Rational(self, expr): + p, q = int(expr.p), int(expr.q) + float_suffix = self.type_mappings[self.type_aliases[real]] + return '%d_%s/%d.0' % (p, float_suffix, q) + + def _print_Relational(self, expr): + if (expr.lhs.is_integer and not expr.rhs.is_integer) or (expr.rhs.is_integer and not expr.lhs.is_integer): + lhs = self._cast_to_float(expr.lhs) + rhs = self._cast_to_float(expr.rhs) + else: + lhs = expr.lhs + rhs = expr.rhs + lhs_code = self._print(lhs) + rhs_code = self._print(rhs) + op = expr.rel_op + return "{} {} {}".format(lhs_code, op, rhs_code) + + def _print_Indexed(self, expr): + # calculate index for 1d array + dims = expr.shape + elem = S.Zero + offset = S.One + for i in reversed(range(expr.rank)): + elem += expr.indices[i]*offset + offset *= dims[i] + return "%s[%s]" % (self._print(expr.base.label), self._print(elem)) + + def _print_Idx(self, expr): + return expr.label.name + + def _print_Dummy(self, expr): + return expr.name + + def _print_Exp1(self, expr, _type=False): + return "E" + + def _print_Pi(self, expr, _type=False): + return 'PI' + + def _print_Infinity(self, expr, _type=False): + return 'INFINITY' + + def _print_NegativeInfinity(self, expr, _type=False): + return 'NEG_INFINITY' + + def _print_BooleanTrue(self, expr, _type=False): + return "true" + + def _print_BooleanFalse(self, expr, _type=False): + return "false" + + def _print_bool(self, expr, _type=False): + return str(expr).lower() + + def _print_NaN(self, expr, _type=False): + return "NAN" + + def _print_Piecewise(self, expr): + if expr.args[-1].cond != True: + # We need the last conditional to be a True, otherwise the resulting + # function may not return a result. + raise ValueError("All Piecewise expressions must contain an " + "(expr, True) statement to be used as a default " + "condition. Without one, the generated " + "expression may not evaluate to anything under " + "some condition.") + lines = [] + + for i, (e, c) in enumerate(expr.args): + if i == 0: + lines.append("if (%s) {" % self._print(c)) + elif i == len(expr.args) - 1 and c == True: + lines[-1] += " else {" + else: + lines[-1] += " else if (%s) {" % self._print(c) + code0 = self._print(e) + lines.append(code0) + lines.append("}") + + if self._settings['inline']: + return " ".join(lines) + else: + return "\n".join(lines) + + def _print_ITE(self, expr): + from sympy.functions import Piecewise + return self._print(expr.rewrite(Piecewise, deep=False)) + + def _print_MatrixBase(self, A): + if A.cols == 1: + return "[%s]" % ", ".join(self._print(a) for a in A) + else: + raise ValueError("Full Matrix Support in Rust need Crates (https://crates.io/keywords/matrix).") + + def _print_SparseRepMatrix(self, mat): + # do not allow sparse matrices to be made dense + return self._print_not_supported(mat) + + def _print_MatrixElement(self, expr): + return "%s[%s]" % (expr.parent, + expr.j + expr.i*expr.parent.shape[1]) + + def _print_Symbol(self, expr): + + name = super()._print_Symbol(expr) + + if expr in self._dereference: + return '(*%s)' % name + else: + return name + + def _print_Assignment(self, expr): + from sympy.tensor.indexed import IndexedBase + lhs = expr.lhs + rhs = expr.rhs + if self._settings["contract"] and (lhs.has(IndexedBase) or + rhs.has(IndexedBase)): + # Here we check if there is looping to be done, and if so + # print the required loops. + return self._doprint_loops(rhs, lhs) + else: + lhs_code = self._print(lhs) + rhs_code = self._print(rhs) + return self._get_statement("%s = %s" % (lhs_code, rhs_code)) + + def _print_sign(self, expr): + arg = self._print(expr.args[0]) + return "(if (%s == 0.0) { 0.0 } else { (%s).signum() })" % (arg, arg) + + def _cast_to_float(self, expr): + if not expr.is_number: + return TypeCast(expr, real) + elif expr.is_integer: + return Float(expr) + return expr + + def _can_print(self, name): + """ Check if function ``name`` is either a known function or has its own + printing method. Used to check if rewriting is possible.""" + + # since the whole point of function_overrides is to enable proper printing, + # we presume they all are printable + + return name in self.known_functions or name in function_overrides or getattr(self, '_print_{}'.format(name), False) + + def _collect_functions(self, expr): + functions = set() + if isinstance(expr, Expr): + if expr.is_Function: + functions.add(expr.func) + for arg in expr.args: + functions = functions.union(self._collect_functions(arg)) + return functions + + def _rewrite_known_functions(self, expr): + if not isinstance(expr, Expr): + return expr + + expression_functions = self._collect_functions(expr) + rewriteable_functions = { + name: (target_f, required_fs) + for name, (target_f, required_fs) in self._rewriteable_functions.items() + if self._can_print(target_f) + and all(self._can_print(f) for f in required_fs) + } + for func in expression_functions: + target_f, _ = rewriteable_functions.get(func.__name__, (None, None)) + if target_f: + expr = expr.rewrite(target_f) + return expr + + def indent_code(self, code): + """Accepts a string of code or a list of code lines""" + + if isinstance(code, str): + code_lines = self.indent_code(code.splitlines(True)) + return ''.join(code_lines) + + tab = " " + inc_token = ('{', '(', '{\n', '(\n') + dec_token = ('}', ')') + + code = [ line.lstrip(' \t') for line in code ] + + increase = [ int(any(map(line.endswith, inc_token))) for line in code ] + decrease = [ int(any(map(line.startswith, dec_token))) + for line in code ] + + pretty = [] + level = 0 + for n, line in enumerate(code): + if line in ('', '\n'): + pretty.append(line) + continue + level -= decrease[n] + pretty.append("%s%s" % (tab*level, line)) + level += increase[n] + return pretty diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/smtlib.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/smtlib.py new file mode 100644 index 0000000000000000000000000000000000000000..8fa015c6198cb32837eb3a0d7fe9d61352da25ad --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/smtlib.py @@ -0,0 +1,583 @@ +import typing + +import sympy +from sympy.core import Add, Mul +from sympy.core import Symbol, Expr, Float, Rational, Integer, Basic +from sympy.core.function import UndefinedFunction, Function +from sympy.core.relational import Relational, Unequality, Equality, LessThan, GreaterThan, StrictLessThan, StrictGreaterThan +from sympy.functions.elementary.complexes import Abs +from sympy.functions.elementary.exponential import exp, log, Pow +from sympy.functions.elementary.hyperbolic import sinh, cosh, tanh +from sympy.functions.elementary.miscellaneous import Min, Max +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import sin, cos, tan, asin, acos, atan, atan2 +from sympy.logic.boolalg import And, Or, Xor, Implies, Boolean +from sympy.logic.boolalg import BooleanTrue, BooleanFalse, BooleanFunction, Not, ITE +from sympy.printing.printer import Printer +from sympy.sets import Interval +from mpmath.libmp.libmpf import prec_to_dps, to_str as mlib_to_str +from sympy.assumptions.assume import AppliedPredicate +from sympy.assumptions.relation.binrel import AppliedBinaryRelation +from sympy.assumptions.ask import Q +from sympy.assumptions.relation.equality import StrictGreaterThanPredicate, StrictLessThanPredicate, GreaterThanPredicate, LessThanPredicate, EqualityPredicate + + +class SMTLibPrinter(Printer): + printmethod = "_smtlib" + + # based on dReal, an automated reasoning tool for solving problems that can be encoded as first-order logic formulas over the real numbers. + # dReal's special strength is in handling problems that involve a wide range of nonlinear real functions. + _default_settings: dict = { + 'precision': None, + 'known_types': { + bool: 'Bool', + int: 'Int', + float: 'Real' + }, + 'known_constants': { + # pi: 'MY_VARIABLE_PI_DECLARED_ELSEWHERE', + }, + 'known_functions': { + Add: '+', + Mul: '*', + + Equality: '=', + LessThan: '<=', + GreaterThan: '>=', + StrictLessThan: '<', + StrictGreaterThan: '>', + + EqualityPredicate(): '=', + LessThanPredicate(): '<=', + GreaterThanPredicate(): '>=', + StrictLessThanPredicate(): '<', + StrictGreaterThanPredicate(): '>', + + exp: 'exp', + log: 'log', + Abs: 'abs', + sin: 'sin', + cos: 'cos', + tan: 'tan', + asin: 'arcsin', + acos: 'arccos', + atan: 'arctan', + atan2: 'arctan2', + sinh: 'sinh', + cosh: 'cosh', + tanh: 'tanh', + Min: 'min', + Max: 'max', + Pow: 'pow', + + And: 'and', + Or: 'or', + Xor: 'xor', + Not: 'not', + ITE: 'ite', + Implies: '=>', + } + } + + symbol_table: dict + + def __init__(self, settings: typing.Optional[dict] = None, + symbol_table=None): + settings = settings or {} + self.symbol_table = symbol_table or {} + Printer.__init__(self, settings) + self._precision = self._settings['precision'] + self._known_types = dict(self._settings['known_types']) + self._known_constants = dict(self._settings['known_constants']) + self._known_functions = dict(self._settings['known_functions']) + + for _ in self._known_types.values(): assert self._is_legal_name(_) + for _ in self._known_constants.values(): assert self._is_legal_name(_) + # for _ in self._known_functions.values(): assert self._is_legal_name(_) # +, *, <, >, etc. + + def _is_legal_name(self, s: str): + if not s: return False + if s[0].isnumeric(): return False + return all(_.isalnum() or _ == '_' for _ in s) + + def _s_expr(self, op: str, args: typing.Union[list, tuple]) -> str: + args_str = ' '.join( + a if isinstance(a, str) + else self._print(a) + for a in args + ) + return f'({op} {args_str})' + + def _print_Function(self, e): + if e in self._known_functions: + op = self._known_functions[e] + elif type(e) in self._known_functions: + op = self._known_functions[type(e)] + elif type(type(e)) == UndefinedFunction: + op = e.name + elif isinstance(e, AppliedBinaryRelation) and e.function in self._known_functions: + op = self._known_functions[e.function] + return self._s_expr(op, e.arguments) + else: + op = self._known_functions[e] # throw KeyError + + return self._s_expr(op, e.args) + + def _print_Relational(self, e: Relational): + return self._print_Function(e) + + def _print_BooleanFunction(self, e: BooleanFunction): + return self._print_Function(e) + + def _print_Expr(self, e: Expr): + return self._print_Function(e) + + def _print_Unequality(self, e: Unequality): + if type(e) in self._known_functions: + return self._print_Relational(e) # default + else: + eq_op = self._known_functions[Equality] + not_op = self._known_functions[Not] + return self._s_expr(not_op, [self._s_expr(eq_op, e.args)]) + + def _print_Piecewise(self, e: Piecewise): + def _print_Piecewise_recursive(args: typing.Union[list, tuple]): + e, c = args[0] + if len(args) == 1: + assert (c is True) or isinstance(c, BooleanTrue) + return self._print(e) + else: + ite = self._known_functions[ITE] + return self._s_expr(ite, [ + c, e, _print_Piecewise_recursive(args[1:]) + ]) + + return _print_Piecewise_recursive(e.args) + + def _print_Interval(self, e: Interval): + if e.start.is_infinite and e.end.is_infinite: + return '' + elif e.start.is_infinite != e.end.is_infinite: + raise ValueError(f'One-sided intervals (`{e}`) are not supported in SMT.') + else: + return f'[{e.start}, {e.end}]' + + def _print_AppliedPredicate(self, e: AppliedPredicate): + if e.function == Q.positive: + rel = Q.gt(e.arguments[0],0) + elif e.function == Q.negative: + rel = Q.lt(e.arguments[0], 0) + elif e.function == Q.zero: + rel = Q.eq(e.arguments[0], 0) + elif e.function == Q.nonpositive: + rel = Q.le(e.arguments[0], 0) + elif e.function == Q.nonnegative: + rel = Q.ge(e.arguments[0], 0) + elif e.function == Q.nonzero: + rel = Q.ne(e.arguments[0], 0) + else: + raise ValueError(f"Predicate (`{e}`) is not handled.") + + return self._print_AppliedBinaryRelation(rel) + + def _print_AppliedBinaryRelation(self, e: AppliedPredicate): + if e.function == Q.ne: + return self._print_Unequality(Unequality(*e.arguments)) + else: + return self._print_Function(e) + + # todo: Sympy does not support quantifiers yet as of 2022, but quantifiers can be handy in SMT. + # For now, users can extend this class and build in their own quantifier support. + # See `test_quantifier_extensions()` in test_smtlib.py for an example of how this might look. + + # def _print_ForAll(self, e: ForAll): + # return self._s('forall', [ + # self._s('', [ + # self._s(sym.name, [self._type_name(sym), Interval(start, end)]) + # for sym, start, end in e.limits + # ]), + # e.function + # ]) + + def _print_BooleanTrue(self, x: BooleanTrue): + return 'true' + + def _print_BooleanFalse(self, x: BooleanFalse): + return 'false' + + def _print_Float(self, x: Float): + dps = prec_to_dps(x._prec) + str_real = mlib_to_str(x._mpf_, dps, strip_zeros=True, min_fixed=None, max_fixed=None) + + if 'e' in str_real: + (mant, exp) = str_real.split('e') + + if exp[0] == '+': + exp = exp[1:] + + mul = self._known_functions[Mul] + pow = self._known_functions[Pow] + + return r"(%s %s (%s 10 %s))" % (mul, mant, pow, exp) + elif str_real in ["+inf", "-inf"]: + raise ValueError("Infinite values are not supported in SMT.") + else: + return str_real + + def _print_float(self, x: float): + return self._print(Float(x)) + + def _print_Rational(self, x: Rational): + return self._s_expr('/', [x.p, x.q]) + + def _print_Integer(self, x: Integer): + assert x.q == 1 + return str(x.p) + + def _print_int(self, x: int): + return str(x) + + def _print_Symbol(self, x: Symbol): + assert self._is_legal_name(x.name) + return x.name + + def _print_NumberSymbol(self, x): + name = self._known_constants.get(x) + if name: + return name + else: + f = x.evalf(self._precision) if self._precision else x.evalf() + return self._print_Float(f) + + def _print_UndefinedFunction(self, x): + assert self._is_legal_name(x.name) + return x.name + + def _print_Exp1(self, x): + return ( + self._print_Function(exp(1, evaluate=False)) + if exp in self._known_functions else + self._print_NumberSymbol(x) + ) + + def emptyPrinter(self, expr): + raise NotImplementedError(f'Cannot convert `{repr(expr)}` of type `{type(expr)}` to SMT.') + + +def smtlib_code( + expr, + auto_assert=True, auto_declare=True, + precision=None, + symbol_table=None, + known_types=None, known_constants=None, known_functions=None, + prefix_expressions=None, suffix_expressions=None, + log_warn=None +): + r"""Converts ``expr`` to a string of smtlib code. + + Parameters + ========== + + expr : Expr | List[Expr] + A SymPy expression or system to be converted. + auto_assert : bool, optional + If false, do not modify expr and produce only the S-Expression equivalent of expr. + If true, assume expr is a system and assert each boolean element. + auto_declare : bool, optional + If false, do not produce declarations for the symbols used in expr. + If true, prepend all necessary declarations for variables used in expr based on symbol_table. + precision : integer, optional + The ``evalf(..)`` precision for numbers such as pi. + symbol_table : dict, optional + A dictionary where keys are ``Symbol`` or ``Function`` instances and values are their Python type i.e. ``bool``, ``int``, ``float``, or ``Callable[...]``. + If incomplete, an attempt will be made to infer types from ``expr``. + known_types: dict, optional + A dictionary where keys are ``bool``, ``int``, ``float`` etc. and values are their corresponding SMT type names. + If not given, a partial listing compatible with several solvers will be used. + known_functions : dict, optional + A dictionary where keys are ``Function``, ``Relational``, ``BooleanFunction``, or ``Expr`` instances and values are their SMT string representations. + If not given, a partial listing optimized for dReal solver (but compatible with others) will be used. + known_constants: dict, optional + A dictionary where keys are ``NumberSymbol`` instances and values are their SMT variable names. + When using this feature, extra caution must be taken to avoid naming collisions between user symbols and listed constants. + If not given, constants will be expanded inline i.e. ``3.14159`` instead of ``MY_SMT_VARIABLE_FOR_PI``. + prefix_expressions: list, optional + A list of lists of ``str`` and/or expressions to convert into SMTLib and prefix to the output. + suffix_expressions: list, optional + A list of lists of ``str`` and/or expressions to convert into SMTLib and postfix to the output. + log_warn: lambda function, optional + A function to record all warnings during potentially risky operations. + Soundness is a core value in SMT solving, so it is good to log all assumptions made. + + Examples + ======== + >>> from sympy import smtlib_code, symbols, sin, Eq + >>> x = symbols('x') + >>> smtlib_code(sin(x).series(x).removeO(), log_warn=print) + Could not infer type of `x`. Defaulting to float. + Non-Boolean expression `x**5/120 - x**3/6 + x` will not be asserted. Converting to SMTLib verbatim. + '(declare-const x Real)\n(+ x (* (/ -1 6) (pow x 3)) (* (/ 1 120) (pow x 5)))' + + >>> from sympy import Rational + >>> x, y, tau = symbols("x, y, tau") + >>> smtlib_code((2*tau)**Rational(7, 2), log_warn=print) + Could not infer type of `tau`. Defaulting to float. + Non-Boolean expression `8*sqrt(2)*tau**(7/2)` will not be asserted. Converting to SMTLib verbatim. + '(declare-const tau Real)\n(* 8 (pow 2 (/ 1 2)) (pow tau (/ 7 2)))' + + ``Piecewise`` expressions are implemented with ``ite`` expressions by default. + Note that if the ``Piecewise`` lacks a default term, represented by + ``(expr, True)`` then an error will be thrown. This is to prevent + generating an expression that may not evaluate to anything. + + >>> from sympy import Piecewise + >>> pw = Piecewise((x + 1, x > 0), (x, True)) + >>> smtlib_code(Eq(pw, 3), symbol_table={x: float}, log_warn=print) + '(declare-const x Real)\n(assert (= (ite (> x 0) (+ 1 x) x) 3))' + + Custom printing can be defined for certain types by passing a dictionary of + PythonType : "SMT Name" to the ``known_types``, ``known_constants``, and ``known_functions`` kwargs. + + >>> from typing import Callable + >>> from sympy import Function, Add + >>> f = Function('f') + >>> g = Function('g') + >>> smt_builtin_funcs = { # functions our SMT solver will understand + ... f: "existing_smtlib_fcn", + ... Add: "sum", + ... } + >>> user_def_funcs = { # functions defined by the user must have their types specified explicitly + ... g: Callable[[int], float], + ... } + >>> smtlib_code(f(x) + g(x), symbol_table=user_def_funcs, known_functions=smt_builtin_funcs, log_warn=print) + Non-Boolean expression `f(x) + g(x)` will not be asserted. Converting to SMTLib verbatim. + '(declare-const x Int)\n(declare-fun g (Int) Real)\n(sum (existing_smtlib_fcn x) (g x))' + """ + log_warn = log_warn or (lambda _: None) + + if not isinstance(expr, list): expr = [expr] + expr = [ + sympy.sympify(_, strict=True, evaluate=False, convert_xor=False) + for _ in expr + ] + + if not symbol_table: symbol_table = {} + symbol_table = _auto_infer_smtlib_types( + *expr, symbol_table=symbol_table + ) + # See [FALLBACK RULES] + # Need SMTLibPrinter to populate known_functions and known_constants first. + + settings = {} + if precision: settings['precision'] = precision + del precision + + if known_types: settings['known_types'] = known_types + del known_types + + if known_functions: settings['known_functions'] = known_functions + del known_functions + + if known_constants: settings['known_constants'] = known_constants + del known_constants + + if not prefix_expressions: prefix_expressions = [] + if not suffix_expressions: suffix_expressions = [] + + p = SMTLibPrinter(settings, symbol_table) + del symbol_table + + # [FALLBACK RULES] + for e in expr: + for sym in e.atoms(Symbol, Function): + if ( + sym.is_Symbol and + sym not in p._known_constants and + sym not in p.symbol_table + ): + log_warn(f"Could not infer type of `{sym}`. Defaulting to float.") + p.symbol_table[sym] = float + if ( + sym.is_Function and + type(sym) not in p._known_functions and + type(sym) not in p.symbol_table and + not sym.is_Piecewise + ): raise TypeError( + f"Unknown type of undefined function `{sym}`. " + f"Must be mapped to ``str`` in known_functions or mapped to ``Callable[..]`` in symbol_table." + ) + + declarations = [] + if auto_declare: + constants = {sym.name: sym for e in expr for sym in e.free_symbols + if sym not in p._known_constants} + functions = {fnc.name: fnc for e in expr for fnc in e.atoms(Function) + if type(fnc) not in p._known_functions and not fnc.is_Piecewise} + declarations = \ + [ + _auto_declare_smtlib(sym, p, log_warn) + for sym in constants.values() + ] + [ + _auto_declare_smtlib(fnc, p, log_warn) + for fnc in functions.values() + ] + declarations = [decl for decl in declarations if decl] + + if auto_assert: + expr = [_auto_assert_smtlib(e, p, log_warn) for e in expr] + + # return SMTLibPrinter().doprint(expr) + return '\n'.join([ + # ';; PREFIX EXPRESSIONS', + *[ + e if isinstance(e, str) else p.doprint(e) + for e in prefix_expressions + ], + + # ';; DECLARATIONS', + *sorted(e for e in declarations), + + # ';; EXPRESSIONS', + *[ + e if isinstance(e, str) else p.doprint(e) + for e in expr + ], + + # ';; SUFFIX EXPRESSIONS', + *[ + e if isinstance(e, str) else p.doprint(e) + for e in suffix_expressions + ], + ]) + + +def _auto_declare_smtlib(sym: typing.Union[Symbol, Function], p: SMTLibPrinter, log_warn: typing.Callable[[str], None]): + if sym.is_Symbol: + type_signature = p.symbol_table[sym] + assert isinstance(type_signature, type) + type_signature = p._known_types[type_signature] + return p._s_expr('declare-const', [sym, type_signature]) + + elif sym.is_Function: + type_signature = p.symbol_table[type(sym)] + assert callable(type_signature) + type_signature = [p._known_types[_] for _ in type_signature.__args__] + assert len(type_signature) > 0 + params_signature = f"({' '.join(type_signature[:-1])})" + return_signature = type_signature[-1] + return p._s_expr('declare-fun', [type(sym), params_signature, return_signature]) + + else: + log_warn(f"Non-Symbol/Function `{sym}` will not be declared.") + return None + + +def _auto_assert_smtlib(e: Expr, p: SMTLibPrinter, log_warn: typing.Callable[[str], None]): + if isinstance(e, Boolean) or ( + e in p.symbol_table and p.symbol_table[e] == bool + ) or ( + e.is_Function and + type(e) in p.symbol_table and + p.symbol_table[type(e)].__args__[-1] == bool + ): + return p._s_expr('assert', [e]) + else: + log_warn(f"Non-Boolean expression `{e}` will not be asserted. Converting to SMTLib verbatim.") + return e + + +def _auto_infer_smtlib_types( + *exprs: Basic, + symbol_table: typing.Optional[dict] = None +) -> dict: + # [TYPE INFERENCE RULES] + # X is alone in an expr => X is bool + # X in BooleanFunction.args => X is bool + # X matches to a bool param of a symbol_table function => X is bool + # X matches to an int param of a symbol_table function => X is int + # X.is_integer => X is int + # X == Y, where X is T => Y is T + + # [FALLBACK RULES] + # see _auto_declare_smtlib(..) + # X is not bool and X is not int and X is Symbol => X is float + # else (e.g. X is Function) => error. must be specified explicitly. + + _symbols = dict(symbol_table) if symbol_table else {} + + def safe_update(syms: set, inf): + for s in syms: + assert s.is_Symbol + if (old_type := _symbols.setdefault(s, inf)) != inf: + raise TypeError(f"Could not infer type of `{s}`. Apparently both `{old_type}` and `{inf}`?") + + # EXPLICIT TYPES + safe_update({ + e + for e in exprs + if e.is_Symbol + }, bool) + + safe_update({ + symbol + for e in exprs + for boolfunc in e.atoms(BooleanFunction) + for symbol in boolfunc.args + if symbol.is_Symbol + }, bool) + + safe_update({ + symbol + for e in exprs + for boolfunc in e.atoms(Function) + if type(boolfunc) in _symbols + for symbol, param in zip(boolfunc.args, _symbols[type(boolfunc)].__args__) + if symbol.is_Symbol and param == bool + }, bool) + + safe_update({ + symbol + for e in exprs + for intfunc in e.atoms(Function) + if type(intfunc) in _symbols + for symbol, param in zip(intfunc.args, _symbols[type(intfunc)].__args__) + if symbol.is_Symbol and param == int + }, int) + + safe_update({ + symbol + for e in exprs + for symbol in e.atoms(Symbol) + if symbol.is_integer + }, int) + + safe_update({ + symbol + for e in exprs + for symbol in e.atoms(Symbol) + if symbol.is_real and not symbol.is_integer + }, float) + + # EQUALITY RELATION RULE + rels_eq = [rel for expr in exprs for rel in expr.atoms(Equality)] + rels = [ + (rel.lhs, rel.rhs) for rel in rels_eq if rel.lhs.is_Symbol + ] + [ + (rel.rhs, rel.lhs) for rel in rels_eq if rel.rhs.is_Symbol + ] + for infer, reltd in rels: + inference = ( + _symbols[infer] if infer in _symbols else + _symbols[reltd] if reltd in _symbols else + + _symbols[type(reltd)].__args__[-1] + if reltd.is_Function and type(reltd) in _symbols else + + bool if reltd.is_Boolean else + int if reltd.is_integer or reltd.is_Integer else + float if reltd.is_real else + None + ) + if inference: safe_update({infer}, inference) + + return _symbols diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/str.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/str.py new file mode 100644 index 0000000000000000000000000000000000000000..9975776fbb73bec9c956fe359387fa8036995795 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/str.py @@ -0,0 +1,1021 @@ +""" +A Printer for generating readable representation of most SymPy classes. +""" + +from __future__ import annotations +from typing import Any + +from sympy.core import S, Rational, Pow, Basic, Mul, Number +from sympy.core.mul import _keep_coeff +from sympy.core.numbers import Integer +from sympy.core.relational import Relational +from sympy.core.sorting import default_sort_key +from sympy.utilities.iterables import sift +from .precedence import precedence, PRECEDENCE +from .printer import Printer, print_function + +from mpmath.libmp import prec_to_dps, to_str as mlib_to_str + + +class StrPrinter(Printer): + printmethod = "_sympystr" + _default_settings: dict[str, Any] = { + "order": None, + "full_prec": "auto", + "sympy_integers": False, + "abbrev": False, + "perm_cyclic": True, + "min": None, + "max": None, + "dps" : None + } + + _relationals: dict[str, str] = {} + + def parenthesize(self, item, level, strict=False): + if (precedence(item) < level) or ((not strict) and precedence(item) <= level): + return "(%s)" % self._print(item) + else: + return self._print(item) + + def stringify(self, args, sep, level=0): + return sep.join([self.parenthesize(item, level) for item in args]) + + def emptyPrinter(self, expr): + if isinstance(expr, str): + return expr + elif isinstance(expr, Basic): + return repr(expr) + else: + return str(expr) + + def _print_Add(self, expr, order=None): + terms = self._as_ordered_terms(expr, order=order) + + prec = precedence(expr) + l = [] + for term in terms: + t = self._print(term) + if t.startswith('-') and not term.is_Add: + sign = "-" + t = t[1:] + else: + sign = "+" + if precedence(term) < prec or term.is_Add: + l.extend([sign, "(%s)" % t]) + else: + l.extend([sign, t]) + sign = l.pop(0) + if sign == '+': + sign = "" + return sign + ' '.join(l) + + def _print_BooleanTrue(self, expr): + return "True" + + def _print_BooleanFalse(self, expr): + return "False" + + def _print_Not(self, expr): + return '~%s' %(self.parenthesize(expr.args[0],PRECEDENCE["Not"])) + + def _print_And(self, expr): + args = list(expr.args) + for j, i in enumerate(args): + if isinstance(i, Relational) and ( + i.canonical.rhs is S.NegativeInfinity): + args.insert(0, args.pop(j)) + return self.stringify(args, " & ", PRECEDENCE["BitwiseAnd"]) + + def _print_Or(self, expr): + return self.stringify(expr.args, " | ", PRECEDENCE["BitwiseOr"]) + + def _print_Xor(self, expr): + return self.stringify(expr.args, " ^ ", PRECEDENCE["BitwiseXor"]) + + def _print_AppliedPredicate(self, expr): + return '%s(%s)' % ( + self._print(expr.function), self.stringify(expr.arguments, ", ")) + + def _print_Basic(self, expr): + l = [self._print(o) for o in expr.args] + return expr.__class__.__name__ + "(%s)" % ", ".join(l) + + def _print_BlockMatrix(self, B): + if B.blocks.shape == (1, 1): + self._print(B.blocks[0, 0]) + return self._print(B.blocks) + + def _print_Catalan(self, expr): + return 'Catalan' + + def _print_ComplexInfinity(self, expr): + return 'zoo' + + def _print_ConditionSet(self, s): + args = tuple([self._print(i) for i in (s.sym, s.condition)]) + if s.base_set is S.UniversalSet: + return 'ConditionSet(%s, %s)' % args + args += (self._print(s.base_set),) + return 'ConditionSet(%s, %s, %s)' % args + + def _print_Derivative(self, expr): + dexpr = expr.expr + dvars = [i[0] if i[1] == 1 else i for i in expr.variable_count] + return 'Derivative(%s)' % ", ".join((self._print(arg) for arg in [dexpr] + dvars)) + + def _print_dict(self, d): + keys = sorted(d.keys(), key=default_sort_key) + items = [] + + for key in keys: + item = "%s: %s" % (self._print(key), self._print(d[key])) + items.append(item) + + return "{%s}" % ", ".join(items) + + def _print_Dict(self, expr): + return self._print_dict(expr) + + def _print_RandomDomain(self, d): + if hasattr(d, 'as_boolean'): + return 'Domain: ' + self._print(d.as_boolean()) + elif hasattr(d, 'set'): + return ('Domain: ' + self._print(d.symbols) + ' in ' + + self._print(d.set)) + else: + return 'Domain on ' + self._print(d.symbols) + + def _print_Dummy(self, expr): + return '_' + expr.name + + def _print_EulerGamma(self, expr): + return 'EulerGamma' + + def _print_Exp1(self, expr): + return 'E' + + def _print_ExprCondPair(self, expr): + return '(%s, %s)' % (self._print(expr.expr), self._print(expr.cond)) + + def _print_Function(self, expr): + return expr.func.__name__ + "(%s)" % self.stringify(expr.args, ", ") + + def _print_GoldenRatio(self, expr): + return 'GoldenRatio' + + def _print_Heaviside(self, expr): + # Same as _print_Function but uses pargs to suppress default 1/2 for + # 2nd args + return expr.func.__name__ + "(%s)" % self.stringify(expr.pargs, ", ") + + def _print_TribonacciConstant(self, expr): + return 'TribonacciConstant' + + def _print_ImaginaryUnit(self, expr): + return 'I' + + def _print_Infinity(self, expr): + return 'oo' + + def _print_Integral(self, expr): + def _xab_tostr(xab): + if len(xab) == 1: + return self._print(xab[0]) + else: + return self._print((xab[0],) + tuple(xab[1:])) + L = ', '.join([_xab_tostr(l) for l in expr.limits]) + return 'Integral(%s, %s)' % (self._print(expr.function), L) + + def _print_Interval(self, i): + fin = 'Interval{m}({a}, {b})' + a, b, l, r = i.args + if a.is_infinite and b.is_infinite: + m = '' + elif a.is_infinite and not r: + m = '' + elif b.is_infinite and not l: + m = '' + elif not l and not r: + m = '' + elif l and r: + m = '.open' + elif l: + m = '.Lopen' + else: + m = '.Ropen' + return fin.format(**{'a': a, 'b': b, 'm': m}) + + def _print_AccumulationBounds(self, i): + return "AccumBounds(%s, %s)" % (self._print(i.min), + self._print(i.max)) + + def _print_Inverse(self, I): + return "%s**(-1)" % self.parenthesize(I.arg, PRECEDENCE["Pow"]) + + def _print_Lambda(self, obj): + expr = obj.expr + sig = obj.signature + if len(sig) == 1 and sig[0].is_symbol: + sig = sig[0] + return "Lambda(%s, %s)" % (self._print(sig), self._print(expr)) + + def _print_LatticeOp(self, expr): + args = sorted(expr.args, key=default_sort_key) + return expr.func.__name__ + "(%s)" % ", ".join(self._print(arg) for arg in args) + + def _print_Limit(self, expr): + e, z, z0, dir = expr.args + return "Limit(%s, %s, %s, dir='%s')" % tuple(map(self._print, (e, z, z0, dir))) + + + def _print_list(self, expr): + return "[%s]" % self.stringify(expr, ", ") + + def _print_List(self, expr): + return self._print_list(expr) + + def _print_MatrixBase(self, expr): + return expr._format_str(self) + + def _print_MatrixElement(self, expr): + return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) \ + + '[%s, %s]' % (self._print(expr.i), self._print(expr.j)) + + def _print_MatrixSlice(self, expr): + def strslice(x, dim): + x = list(x) + if x[2] == 1: + del x[2] + if x[0] == 0: + x[0] = '' + if x[1] == dim: + x[1] = '' + return ':'.join((self._print(arg) for arg in x)) + return (self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) + '[' + + strslice(expr.rowslice, expr.parent.rows) + ', ' + + strslice(expr.colslice, expr.parent.cols) + ']') + + def _print_DeferredVector(self, expr): + return expr.name + + def _print_Mul(self, expr): + + prec = precedence(expr) + + # Check for unevaluated Mul. In this case we need to make sure the + # identities are visible, multiple Rational factors are not combined + # etc so we display in a straight-forward form that fully preserves all + # args and their order. + args = expr.args + if args[0] is S.One or any( + isinstance(a, Number) or + a.is_Pow and all(ai.is_Integer for ai in a.args) + for a in args[1:]): + d, n = sift(args, lambda x: + isinstance(x, Pow) and bool(x.exp.as_coeff_Mul()[0] < 0), + binary=True) + for i, di in enumerate(d): + if di.exp.is_Number: + e = -di.exp + else: + dargs = list(di.exp.args) + dargs[0] = -dargs[0] + e = Mul._from_args(dargs) + d[i] = Pow(di.base, e, evaluate=False) if e - 1 else di.base + + pre = [] + # don't parenthesize first factor if negative + if n and not n[0].is_Add and n[0].could_extract_minus_sign(): + pre = [self._print(n.pop(0))] + + nfactors = pre + [self.parenthesize(a, prec, strict=False) + for a in n] + if not nfactors: + nfactors = ['1'] + + # don't parenthesize first of denominator unless singleton + if len(d) > 1 and d[0].could_extract_minus_sign(): + pre = [self._print(d.pop(0))] + else: + pre = [] + dfactors = pre + [self.parenthesize(a, prec, strict=False) + for a in d] + + n = '*'.join(nfactors) + d = '*'.join(dfactors) + if len(dfactors) > 1: + return '%s/(%s)' % (n, d) + elif dfactors: + return '%s/%s' % (n, d) + return n + + c, e = expr.as_coeff_Mul() + if c < 0: + expr = _keep_coeff(-c, e) + sign = "-" + else: + sign = "" + + a = [] # items in the numerator + b = [] # items that are in the denominator (if any) + + pow_paren = [] # Will collect all pow with more than one base element and exp = -1 + + if self.order not in ('old', 'none'): + args = expr.as_ordered_factors() + else: + # use make_args in case expr was something like -x -> x + args = Mul.make_args(expr) + + # Gather args for numerator/denominator + def apow(i): + b, e = i.as_base_exp() + eargs = list(Mul.make_args(e)) + if eargs[0] is S.NegativeOne: + eargs = eargs[1:] + else: + eargs[0] = -eargs[0] + e = Mul._from_args(eargs) + if isinstance(i, Pow): + return i.func(b, e, evaluate=False) + return i.func(e, evaluate=False) + for item in args: + if (item.is_commutative and + isinstance(item, Pow) and + bool(item.exp.as_coeff_Mul()[0] < 0)): + if item.exp is not S.NegativeOne: + b.append(apow(item)) + else: + if (len(item.args[0].args) != 1 and + isinstance(item.base, (Mul, Pow))): + # To avoid situations like #14160 + pow_paren.append(item) + b.append(item.base) + elif item.is_Rational and item is not S.Infinity: + if item.p != 1: + a.append(Rational(item.p)) + if item.q != 1: + b.append(Rational(item.q)) + else: + a.append(item) + + a = a or [S.One] + + a_str = [self.parenthesize(x, prec, strict=False) for x in a] + b_str = [self.parenthesize(x, prec, strict=False) for x in b] + + # To parenthesize Pow with exp = -1 and having more than one Symbol + for item in pow_paren: + if item.base in b: + b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] + + if not b: + return sign + '*'.join(a_str) + elif len(b) == 1: + return sign + '*'.join(a_str) + "/" + b_str[0] + else: + return sign + '*'.join(a_str) + "/(%s)" % '*'.join(b_str) + + def _print_MatMul(self, expr): + c, m = expr.as_coeff_mmul() + + sign = "" + if c.is_number: + re, im = c.as_real_imag() + if im.is_zero and re.is_negative: + expr = _keep_coeff(-c, m) + sign = "-" + elif re.is_zero and im.is_negative: + expr = _keep_coeff(-c, m) + sign = "-" + + return sign + '*'.join( + [self.parenthesize(arg, precedence(expr)) for arg in expr.args] + ) + + def _print_ElementwiseApplyFunction(self, expr): + return "{}.({})".format( + expr.function, + self._print(expr.expr), + ) + + def _print_NaN(self, expr): + return 'nan' + + def _print_NegativeInfinity(self, expr): + return '-oo' + + def _print_Order(self, expr): + if not expr.variables or all(p is S.Zero for p in expr.point): + if len(expr.variables) <= 1: + return 'O(%s)' % self._print(expr.expr) + else: + return 'O(%s)' % self.stringify((expr.expr,) + expr.variables, ', ', 0) + else: + return 'O(%s)' % self.stringify(expr.args, ', ', 0) + + def _print_Ordinal(self, expr): + return expr.__str__() + + def _print_Cycle(self, expr): + return expr.__str__() + + def _print_Permutation(self, expr): + from sympy.combinatorics.permutations import Permutation, Cycle + from sympy.utilities.exceptions import sympy_deprecation_warning + + perm_cyclic = Permutation.print_cyclic + if perm_cyclic is not None: + sympy_deprecation_warning( + f""" + Setting Permutation.print_cyclic is deprecated. Instead use + init_printing(perm_cyclic={perm_cyclic}). + """, + deprecated_since_version="1.6", + active_deprecations_target="deprecated-permutation-print_cyclic", + stacklevel=7, + ) + else: + perm_cyclic = self._settings.get("perm_cyclic", True) + + if perm_cyclic: + if not expr.size: + return '()' + # before taking Cycle notation, see if the last element is + # a singleton and move it to the head of the string + s = Cycle(expr)(expr.size - 1).__repr__()[len('Cycle'):] + last = s.rfind('(') + if not last == 0 and ',' not in s[last:]: + s = s[last:] + s[:last] + s = s.replace(',', '') + return s + else: + s = expr.support() + if not s: + if expr.size < 5: + return 'Permutation(%s)' % self._print(expr.array_form) + return 'Permutation([], size=%s)' % self._print(expr.size) + trim = self._print(expr.array_form[:s[-1] + 1]) + ', size=%s' % self._print(expr.size) + use = full = self._print(expr.array_form) + if len(trim) < len(full): + use = trim + return 'Permutation(%s)' % use + + def _print_Subs(self, obj): + expr, old, new = obj.args + if len(obj.point) == 1: + old = old[0] + new = new[0] + return "Subs(%s, %s, %s)" % ( + self._print(expr), self._print(old), self._print(new)) + + def _print_TensorIndex(self, expr): + return expr._print() + + def _print_TensorHead(self, expr): + return expr._print() + + def _print_Tensor(self, expr): + return expr._print() + + def _print_TensMul(self, expr): + # prints expressions like "A(a)", "3*A(a)", "(1+x)*A(a)" + sign, args = expr._get_args_for_traditional_printer() + return sign + "*".join( + [self.parenthesize(arg, precedence(expr)) for arg in args] + ) + + def _print_TensAdd(self, expr): + return expr._print() + + def _print_ArraySymbol(self, expr): + return self._print(expr.name) + + def _print_ArrayElement(self, expr): + return "%s[%s]" % ( + self.parenthesize(expr.name, PRECEDENCE["Func"], True), ", ".join([self._print(i) for i in expr.indices])) + + def _print_PermutationGroup(self, expr): + p = [' %s' % self._print(a) for a in expr.args] + return 'PermutationGroup([\n%s])' % ',\n'.join(p) + + def _print_Pi(self, expr): + return 'pi' + + def _print_PolyRing(self, ring): + return "Polynomial ring in %s over %s with %s order" % \ + (", ".join((self._print(rs) for rs in ring.symbols)), + self._print(ring.domain), self._print(ring.order)) + + def _print_FracField(self, field): + return "Rational function field in %s over %s with %s order" % \ + (", ".join((self._print(fs) for fs in field.symbols)), + self._print(field.domain), self._print(field.order)) + + def _print_FreeGroupElement(self, elm): + return elm.__str__() + + def _print_GaussianElement(self, poly): + return "(%s + %s*I)" % (poly.x, poly.y) + + def _print_PolyElement(self, poly): + return poly.str(self, PRECEDENCE, "%s**%s", "*") + + def _print_FracElement(self, frac): + if frac.denom == 1: + return self._print(frac.numer) + else: + numer = self.parenthesize(frac.numer, PRECEDENCE["Mul"], strict=True) + denom = self.parenthesize(frac.denom, PRECEDENCE["Atom"], strict=True) + return numer + "/" + denom + + def _print_Poly(self, expr): + ATOM_PREC = PRECEDENCE["Atom"] - 1 + terms, gens = [], [ self.parenthesize(s, ATOM_PREC) for s in expr.gens ] + + for monom, coeff in expr.terms(): + s_monom = [] + + for i, e in enumerate(monom): + if e > 0: + if e == 1: + s_monom.append(gens[i]) + else: + s_monom.append(gens[i] + "**%d" % e) + + s_monom = "*".join(s_monom) + + if coeff.is_Add: + if s_monom: + s_coeff = "(" + self._print(coeff) + ")" + else: + s_coeff = self._print(coeff) + else: + if s_monom: + if coeff is S.One: + terms.extend(['+', s_monom]) + continue + + if coeff is S.NegativeOne: + terms.extend(['-', s_monom]) + continue + + s_coeff = self._print(coeff) + + if not s_monom: + s_term = s_coeff + else: + s_term = s_coeff + "*" + s_monom + + if s_term.startswith('-'): + terms.extend(['-', s_term[1:]]) + else: + terms.extend(['+', s_term]) + + if terms[0] in ('-', '+'): + modifier = terms.pop(0) + + if modifier == '-': + terms[0] = '-' + terms[0] + + format = expr.__class__.__name__ + "(%s, %s" + + from sympy.polys.polyerrors import PolynomialError + + try: + format += ", modulus=%s" % expr.get_modulus() + except PolynomialError: + format += ", domain='%s'" % expr.get_domain() + + format += ")" + + for index, item in enumerate(gens): + if len(item) > 2 and (item[:1] == "(" and item[len(item) - 1:] == ")"): + gens[index] = item[1:len(item) - 1] + + return format % (' '.join(terms), ', '.join(gens)) + + def _print_UniversalSet(self, p): + return 'UniversalSet' + + def _print_AlgebraicNumber(self, expr): + if expr.is_aliased: + return self._print(expr.as_poly().as_expr()) + else: + return self._print(expr.as_expr()) + + def _print_Pow(self, expr, rational=False): + """Printing helper function for ``Pow`` + + Parameters + ========== + + rational : bool, optional + If ``True``, it will not attempt printing ``sqrt(x)`` or + ``x**S.Half`` as ``sqrt``, and will use ``x**(1/2)`` + instead. + + See examples for additional details + + Examples + ======== + + >>> from sympy import sqrt, StrPrinter + >>> from sympy.abc import x + + How ``rational`` keyword works with ``sqrt``: + + >>> printer = StrPrinter() + >>> printer._print_Pow(sqrt(x), rational=True) + 'x**(1/2)' + >>> printer._print_Pow(sqrt(x), rational=False) + 'sqrt(x)' + >>> printer._print_Pow(1/sqrt(x), rational=True) + 'x**(-1/2)' + >>> printer._print_Pow(1/sqrt(x), rational=False) + '1/sqrt(x)' + + Notes + ===== + + ``sqrt(x)`` is canonicalized as ``Pow(x, S.Half)`` in SymPy, + so there is no need of defining a separate printer for ``sqrt``. + Instead, it should be handled here as well. + """ + PREC = precedence(expr) + + if expr.exp is S.Half and not rational: + return "sqrt(%s)" % self._print(expr.base) + + if expr.is_commutative: + if -expr.exp is S.Half and not rational: + # Note: Don't test "expr.exp == -S.Half" here, because that will + # match -0.5, which we don't want. + return "%s/sqrt(%s)" % tuple((self._print(arg) for arg in (S.One, expr.base))) + if expr.exp is -S.One: + # Similarly to the S.Half case, don't test with "==" here. + return '%s/%s' % (self._print(S.One), + self.parenthesize(expr.base, PREC, strict=False)) + + e = self.parenthesize(expr.exp, PREC, strict=False) + if self.printmethod == '_sympyrepr' and expr.exp.is_Rational and expr.exp.q != 1: + # the parenthesized exp should be '(Rational(a, b))' so strip parens, + # but just check to be sure. + if e.startswith('(Rational'): + return '%s**%s' % (self.parenthesize(expr.base, PREC, strict=False), e[1:-1]) + return '%s**%s' % (self.parenthesize(expr.base, PREC, strict=False), e) + + def _print_UnevaluatedExpr(self, expr): + return self._print(expr.args[0]) + + def _print_MatPow(self, expr): + PREC = precedence(expr) + return '%s**%s' % (self.parenthesize(expr.base, PREC, strict=False), + self.parenthesize(expr.exp, PREC, strict=False)) + + def _print_Integer(self, expr): + if self._settings.get("sympy_integers", False): + return "S(%s)" % (expr) + return str(expr.p) + + def _print_Integers(self, expr): + return 'Integers' + + def _print_Naturals(self, expr): + return 'Naturals' + + def _print_Naturals0(self, expr): + return 'Naturals0' + + def _print_Rationals(self, expr): + return 'Rationals' + + def _print_Reals(self, expr): + return 'Reals' + + def _print_Complexes(self, expr): + return 'Complexes' + + def _print_EmptySet(self, expr): + return 'EmptySet' + + def _print_EmptySequence(self, expr): + return 'EmptySequence' + + def _print_int(self, expr): + return str(expr) + + def _print_mpz(self, expr): + return str(expr) + + def _print_Rational(self, expr): + if expr.q == 1: + return str(expr.p) + else: + if self._settings.get("sympy_integers", False): + return "S(%s)/%s" % (expr.p, expr.q) + return "%s/%s" % (expr.p, expr.q) + + def _print_PythonRational(self, expr): + if expr.q == 1: + return str(expr.p) + else: + return "%d/%d" % (expr.p, expr.q) + + def _print_Fraction(self, expr): + if expr.denominator == 1: + return str(expr.numerator) + else: + return "%s/%s" % (expr.numerator, expr.denominator) + + def _print_mpq(self, expr): + if expr.denominator == 1: + return str(expr.numerator) + else: + return "%s/%s" % (expr.numerator, expr.denominator) + + def _print_Float(self, expr): + prec = expr._prec + dps = self._settings.get('dps', None) + if dps is None: + dps = 0 if prec < 5 else prec_to_dps(expr._prec) + if self._settings["full_prec"] is True: + strip = False + elif self._settings["full_prec"] is False: + strip = True + elif self._settings["full_prec"] == "auto": + strip = self._print_level > 1 + low = self._settings["min"] if "min" in self._settings else None + high = self._settings["max"] if "max" in self._settings else None + rv = mlib_to_str(expr._mpf_, dps, strip_zeros=strip, min_fixed=low, max_fixed=high) + if rv.startswith('-.0'): + rv = '-0.' + rv[3:] + elif rv.startswith('.0'): + rv = '0.' + rv[2:] + rv = rv.removeprefix('+') # e.g., +inf -> inf + return rv + + def _print_Relational(self, expr): + + charmap = { + "==": "Eq", + "!=": "Ne", + ":=": "Assignment", + '+=': "AddAugmentedAssignment", + "-=": "SubAugmentedAssignment", + "*=": "MulAugmentedAssignment", + "/=": "DivAugmentedAssignment", + "%=": "ModAugmentedAssignment", + } + + if expr.rel_op in charmap: + return '%s(%s, %s)' % (charmap[expr.rel_op], self._print(expr.lhs), + self._print(expr.rhs)) + + return '%s %s %s' % (self.parenthesize(expr.lhs, precedence(expr)), + self._relationals.get(expr.rel_op) or expr.rel_op, + self.parenthesize(expr.rhs, precedence(expr))) + + def _print_ComplexRootOf(self, expr): + return "CRootOf(%s, %d)" % (self._print_Add(expr.expr, order='lex'), + expr.index) + + def _print_RootSum(self, expr): + args = [self._print_Add(expr.expr, order='lex')] + + if expr.fun is not S.IdentityFunction: + args.append(self._print(expr.fun)) + + return "RootSum(%s)" % ", ".join(args) + + def _print_GroebnerBasis(self, basis): + cls = basis.__class__.__name__ + + exprs = [self._print_Add(arg, order=basis.order) for arg in basis.exprs] + exprs = "[%s]" % ", ".join(exprs) + + gens = [ self._print(gen) for gen in basis.gens ] + domain = "domain='%s'" % self._print(basis.domain) + order = "order='%s'" % self._print(basis.order) + + args = [exprs] + gens + [domain, order] + + return "%s(%s)" % (cls, ", ".join(args)) + + def _print_set(self, s): + items = sorted(s, key=default_sort_key) + + args = ', '.join(self._print(item) for item in items) + if not args: + return "set()" + return '{%s}' % args + + def _print_FiniteSet(self, s): + from sympy.sets.sets import FiniteSet + items = sorted(s, key=default_sort_key) + + args = ', '.join(self._print(item) for item in items) + if any(item.has(FiniteSet) for item in items): + return 'FiniteSet({})'.format(args) + return '{{{}}}'.format(args) + + def _print_Partition(self, s): + items = sorted(s, key=default_sort_key) + + args = ', '.join(self._print(arg) for arg in items) + return 'Partition({})'.format(args) + + def _print_frozenset(self, s): + if not s: + return "frozenset()" + return "frozenset(%s)" % self._print_set(s) + + def _print_Sum(self, expr): + def _xab_tostr(xab): + if len(xab) == 1: + return self._print(xab[0]) + else: + return self._print((xab[0],) + tuple(xab[1:])) + L = ', '.join([_xab_tostr(l) for l in expr.limits]) + return 'Sum(%s, %s)' % (self._print(expr.function), L) + + def _print_Symbol(self, expr): + return expr.name + _print_MatrixSymbol = _print_Symbol + _print_RandomSymbol = _print_Symbol + + def _print_Identity(self, expr): + return "I" + + def _print_ZeroMatrix(self, expr): + return "0" + + def _print_OneMatrix(self, expr): + return "1" + + def _print_Predicate(self, expr): + return "Q.%s" % expr.name + + def _print_str(self, expr): + return str(expr) + + def _print_tuple(self, expr): + if len(expr) == 1: + return "(%s,)" % self._print(expr[0]) + else: + return "(%s)" % self.stringify(expr, ", ") + + def _print_Tuple(self, expr): + return self._print_tuple(expr) + + def _print_Transpose(self, T): + return "%s.T" % self.parenthesize(T.arg, PRECEDENCE["Pow"]) + + def _print_Uniform(self, expr): + return "Uniform(%s, %s)" % (self._print(expr.a), self._print(expr.b)) + + def _print_Quantity(self, expr): + if self._settings.get("abbrev", False): + return "%s" % expr.abbrev + return "%s" % expr.name + + def _print_Quaternion(self, expr): + s = [self.parenthesize(i, PRECEDENCE["Mul"], strict=True) for i in expr.args] + a = [s[0]] + [i+"*"+j for i, j in zip(s[1:], "ijk")] + return " + ".join(a) + + def _print_Dimension(self, expr): + return str(expr) + + def _print_Wild(self, expr): + return expr.name + '_' + + def _print_WildFunction(self, expr): + return expr.name + '_' + + def _print_WildDot(self, expr): + return expr.name + + def _print_WildPlus(self, expr): + return expr.name + + def _print_WildStar(self, expr): + return expr.name + + def _print_Zero(self, expr): + if self._settings.get("sympy_integers", False): + return "S(0)" + return self._print_Integer(Integer(0)) + + def _print_DMP(self, p): + cls = p.__class__.__name__ + rep = self._print(p.to_list()) + dom = self._print(p.dom) + + return "%s(%s, %s)" % (cls, rep, dom) + + def _print_DMF(self, expr): + cls = expr.__class__.__name__ + num = self._print(expr.num) + den = self._print(expr.den) + dom = self._print(expr.dom) + + return "%s(%s, %s, %s)" % (cls, num, den, dom) + + def _print_Object(self, obj): + return 'Object("%s")' % obj.name + + def _print_IdentityMorphism(self, morphism): + return 'IdentityMorphism(%s)' % morphism.domain + + def _print_NamedMorphism(self, morphism): + return 'NamedMorphism(%s, %s, "%s")' % \ + (morphism.domain, morphism.codomain, morphism.name) + + def _print_Category(self, category): + return 'Category("%s")' % category.name + + def _print_Manifold(self, manifold): + return manifold.name.name + + def _print_Patch(self, patch): + return patch.name.name + + def _print_CoordSystem(self, coords): + return coords.name.name + + def _print_BaseScalarField(self, field): + return field._coord_sys.symbols[field._index].name + + def _print_BaseVectorField(self, field): + return 'e_%s' % field._coord_sys.symbols[field._index].name + + def _print_Differential(self, diff): + field = diff._form_field + if hasattr(field, '_coord_sys'): + return 'd%s' % field._coord_sys.symbols[field._index].name + else: + return 'd(%s)' % self._print(field) + + def _print_Tr(self, expr): + #TODO : Handle indices + return "%s(%s)" % ("Tr", self._print(expr.args[0])) + + def _print_Str(self, s): + return self._print(s.name) + + def _print_AppliedBinaryRelation(self, expr): + rel = expr.function + return '%s(%s, %s)' % (self._print(rel), + self._print(expr.lhs), + self._print(expr.rhs)) + + +@print_function(StrPrinter) +def sstr(expr, **settings): + """Returns the expression as a string. + + For large expressions where speed is a concern, use the setting + order='none'. If abbrev=True setting is used then units are printed in + abbreviated form. + + Examples + ======== + + >>> from sympy import symbols, Eq, sstr + >>> a, b = symbols('a b') + >>> sstr(Eq(a + b, 0)) + 'Eq(a + b, 0)' + """ + + p = StrPrinter(settings) + s = p.doprint(expr) + + return s + + +class StrReprPrinter(StrPrinter): + """(internal) -- see sstrrepr""" + + def _print_str(self, s): + return repr(s) + + def _print_Str(self, s): + # Str does not to be printed same as str here + return "%s(%s)" % (s.__class__.__name__, self._print(s.name)) + +@print_function(StrReprPrinter) +def sstrrepr(expr, **settings): + """return expr in mixed str/repr form + + i.e. strings are returned in repr form with quotes, and everything else + is returned in str form. + + This function could be useful for hooking into sys.displayhook + """ + + p = StrReprPrinter(settings) + s = p.doprint(expr) + + return s diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tableform.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tableform.py new file mode 100644 index 0000000000000000000000000000000000000000..4a84ef96ae92517a6ec01ca9db1a13e9afa67093 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tableform.py @@ -0,0 +1,366 @@ +from sympy.core.containers import Tuple +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.core.sympify import SympifyError + +from types import FunctionType + + +class TableForm: + r""" + Create a nice table representation of data. + + Examples + ======== + + >>> from sympy import TableForm + >>> t = TableForm([[5, 7], [4, 2], [10, 3]]) + >>> print(t) + 5 7 + 4 2 + 10 3 + + You can use the SymPy's printing system to produce tables in any + format (ascii, latex, html, ...). + + >>> print(t.as_latex()) + \begin{tabular}{l l} + $5$ & $7$ \\ + $4$ & $2$ \\ + $10$ & $3$ \\ + \end{tabular} + + """ + + def __init__(self, data, **kwarg): + """ + Creates a TableForm. + + Parameters: + + data ... + 2D data to be put into the table; data can be + given as a Matrix + + headings ... + gives the labels for rows and columns: + + Can be a single argument that applies to both + dimensions: + + - None ... no labels + - "automatic" ... labels are 1, 2, 3, ... + + Can be a list of labels for rows and columns: + The labels for each dimension can be given + as None, "automatic", or [l1, l2, ...] e.g. + ["automatic", None] will number the rows + + [default: None] + + alignments ... + alignment of the columns with: + + - "left" or "<" + - "center" or "^" + - "right" or ">" + + When given as a single value, the value is used for + all columns. The row headings (if given) will be + right justified unless an explicit alignment is + given for it and all other columns. + + [default: "left"] + + formats ... + a list of format strings or functions that accept + 3 arguments (entry, row number, col number) and + return a string for the table entry. (If a function + returns None then the _print method will be used.) + + wipe_zeros ... + Do not show zeros in the table. + + [default: True] + + pad ... + the string to use to indicate a missing value (e.g. + elements that are None or those that are missing + from the end of a row (i.e. any row that is shorter + than the rest is assumed to have missing values). + When None, nothing will be shown for values that + are missing from the end of a row; values that are + None, however, will be shown. + + [default: None] + + Examples + ======== + + >>> from sympy import TableForm, Symbol + >>> TableForm([[5, 7], [4, 2], [10, 3]]) + 5 7 + 4 2 + 10 3 + >>> TableForm([list('.'*i) for i in range(1, 4)], headings='automatic') + | 1 2 3 + --------- + 1 | . + 2 | . . + 3 | . . . + >>> TableForm([[Symbol('.'*(j if not i%2 else 1)) for i in range(3)] + ... for j in range(4)], alignments='rcl') + . + . . . + .. . .. + ... . ... + """ + from sympy.matrices.dense import Matrix + + # We only support 2D data. Check the consistency: + if isinstance(data, Matrix): + data = data.tolist() + _h = len(data) + + # fill out any short lines + pad = kwarg.get('pad', None) + ok_None = False + if pad is None: + pad = " " + ok_None = True + pad = Symbol(pad) + _w = max(len(line) for line in data) + for i, line in enumerate(data): + if len(line) != _w: + line.extend([pad]*(_w - len(line))) + for j, lj in enumerate(line): + if lj is None: + if not ok_None: + lj = pad + else: + try: + lj = S(lj) + except SympifyError: + lj = Symbol(str(lj)) + line[j] = lj + data[i] = line + _lines = Tuple(*[Tuple(*d) for d in data]) + + headings = kwarg.get("headings", [None, None]) + if headings == "automatic": + _headings = [range(1, _h + 1), range(1, _w + 1)] + else: + h1, h2 = headings + if h1 == "automatic": + h1 = range(1, _h + 1) + if h2 == "automatic": + h2 = range(1, _w + 1) + _headings = [h1, h2] + + allow = ('l', 'r', 'c') + alignments = kwarg.get("alignments", "l") + + def _std_align(a): + a = a.strip().lower() + if len(a) > 1: + return {'left': 'l', 'right': 'r', 'center': 'c'}.get(a, a) + else: + return {'<': 'l', '>': 'r', '^': 'c'}.get(a, a) + std_align = _std_align(alignments) + if std_align in allow: + _alignments = [std_align]*_w + else: + _alignments = [] + for a in alignments: + std_align = _std_align(a) + _alignments.append(std_align) + if std_align not in ('l', 'r', 'c'): + raise ValueError('alignment "%s" unrecognized' % + alignments) + if _headings[0] and len(_alignments) == _w + 1: + _head_align = _alignments[0] + _alignments = _alignments[1:] + else: + _head_align = 'r' + if len(_alignments) != _w: + raise ValueError( + 'wrong number of alignments: expected %s but got %s' % + (_w, len(_alignments))) + + _column_formats = kwarg.get("formats", [None]*_w) + + _wipe_zeros = kwarg.get("wipe_zeros", True) + + self._w = _w + self._h = _h + self._lines = _lines + self._headings = _headings + self._head_align = _head_align + self._alignments = _alignments + self._column_formats = _column_formats + self._wipe_zeros = _wipe_zeros + + def __repr__(self): + from .str import sstr + return sstr(self, order=None) + + def __str__(self): + from .str import sstr + return sstr(self, order=None) + + def as_matrix(self): + """Returns the data of the table in Matrix form. + + Examples + ======== + + >>> from sympy import TableForm + >>> t = TableForm([[5, 7], [4, 2], [10, 3]], headings='automatic') + >>> t + | 1 2 + -------- + 1 | 5 7 + 2 | 4 2 + 3 | 10 3 + >>> t.as_matrix() + Matrix([ + [ 5, 7], + [ 4, 2], + [10, 3]]) + """ + from sympy.matrices.dense import Matrix + return Matrix(self._lines) + + def as_str(self): + # XXX obsolete ? + return str(self) + + def as_latex(self): + from .latex import latex + return latex(self) + + def _sympystr(self, p): + """ + Returns the string representation of 'self'. + + Examples + ======== + + >>> from sympy import TableForm + >>> t = TableForm([[5, 7], [4, 2], [10, 3]]) + >>> s = t.as_str() + + """ + column_widths = [0] * self._w + lines = [] + for line in self._lines: + new_line = [] + for i in range(self._w): + # Format the item somehow if needed: + s = str(line[i]) + if self._wipe_zeros and (s == "0"): + s = " " + w = len(s) + if w > column_widths[i]: + column_widths[i] = w + new_line.append(s) + lines.append(new_line) + + # Check heading: + if self._headings[0]: + self._headings[0] = [str(x) for x in self._headings[0]] + _head_width = max(len(x) for x in self._headings[0]) + + if self._headings[1]: + new_line = [] + for i in range(self._w): + # Format the item somehow if needed: + s = str(self._headings[1][i]) + w = len(s) + if w > column_widths[i]: + column_widths[i] = w + new_line.append(s) + self._headings[1] = new_line + + format_str = [] + + def _align(align, w): + return '%%%s%ss' % ( + ("-" if align == "l" else ""), + str(w)) + format_str = [_align(align, w) for align, w in + zip(self._alignments, column_widths)] + if self._headings[0]: + format_str.insert(0, _align(self._head_align, _head_width)) + format_str.insert(1, '|') + format_str = ' '.join(format_str) + '\n' + + s = [] + if self._headings[1]: + d = self._headings[1] + if self._headings[0]: + d = [""] + d + first_line = format_str % tuple(d) + s.append(first_line) + s.append("-" * (len(first_line) - 1) + "\n") + for i, line in enumerate(lines): + d = [l if self._alignments[j] != 'c' else + l.center(column_widths[j]) for j, l in enumerate(line)] + if self._headings[0]: + l = self._headings[0][i] + l = (l if self._head_align != 'c' else + l.center(_head_width)) + d = [l] + d + s.append(format_str % tuple(d)) + return ''.join(s)[:-1] # don't include trailing newline + + def _latex(self, printer): + """ + Returns the string representation of 'self'. + """ + # Check heading: + if self._headings[1]: + new_line = [] + for i in range(self._w): + # Format the item somehow if needed: + new_line.append(str(self._headings[1][i])) + self._headings[1] = new_line + + alignments = [] + if self._headings[0]: + self._headings[0] = [str(x) for x in self._headings[0]] + alignments = [self._head_align] + alignments.extend(self._alignments) + + s = r"\begin{tabular}{" + " ".join(alignments) + "}\n" + + if self._headings[1]: + d = self._headings[1] + if self._headings[0]: + d = [""] + d + first_line = " & ".join(d) + r" \\" + "\n" + s += first_line + s += r"\hline" + "\n" + for i, line in enumerate(self._lines): + d = [] + for j, x in enumerate(line): + if self._wipe_zeros and (x in (0, "0")): + d.append(" ") + continue + f = self._column_formats[j] + if f: + if isinstance(f, FunctionType): + v = f(x, i, j) + if v is None: + v = printer._print(x) + else: + v = f % x + d.append(v) + else: + v = printer._print(x) + d.append("$%s$" % v) + if self._headings[0]: + d = [self._headings[0][i]] + d + s += " & ".join(d) + r" \\" + "\n" + s += r"\end{tabular}" + return s diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tensorflow.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tensorflow.py new file mode 100644 index 0000000000000000000000000000000000000000..78b0df62b611f336468769e4cee1695bc068eee9 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tensorflow.py @@ -0,0 +1,224 @@ +import sympy.codegen +import sympy.codegen.cfunctions +from sympy.external.importtools import version_tuple +from collections.abc import Iterable + +from sympy.core.mul import Mul +from sympy.core.singleton import S +from sympy.codegen.cfunctions import Sqrt +from sympy.external import import_module +from sympy.printing.precedence import PRECEDENCE +from sympy.printing.pycode import AbstractPythonCodePrinter, ArrayPrinter +import sympy + +tensorflow = import_module('tensorflow') + +class TensorflowPrinter(ArrayPrinter, AbstractPythonCodePrinter): + """ + Tensorflow printer which handles vectorized piecewise functions, + logical operators, max/min, and relational operators. + """ + printmethod = "_tensorflowcode" + + mapping = { + sympy.Abs: "tensorflow.math.abs", + sympy.sign: "tensorflow.math.sign", + + # XXX May raise error for ints. + sympy.ceiling: "tensorflow.math.ceil", + sympy.floor: "tensorflow.math.floor", + sympy.log: "tensorflow.math.log", + sympy.exp: "tensorflow.math.exp", + Sqrt: "tensorflow.math.sqrt", + sympy.cos: "tensorflow.math.cos", + sympy.acos: "tensorflow.math.acos", + sympy.sin: "tensorflow.math.sin", + sympy.asin: "tensorflow.math.asin", + sympy.tan: "tensorflow.math.tan", + sympy.atan: "tensorflow.math.atan", + sympy.atan2: "tensorflow.math.atan2", + # XXX Also may give NaN for complex results. + sympy.cosh: "tensorflow.math.cosh", + sympy.acosh: "tensorflow.math.acosh", + sympy.sinh: "tensorflow.math.sinh", + sympy.asinh: "tensorflow.math.asinh", + sympy.tanh: "tensorflow.math.tanh", + sympy.atanh: "tensorflow.math.atanh", + + sympy.re: "tensorflow.math.real", + sympy.im: "tensorflow.math.imag", + sympy.arg: "tensorflow.math.angle", + + # XXX May raise error for ints and complexes + sympy.erf: "tensorflow.math.erf", + sympy.loggamma: "tensorflow.math.lgamma", + + sympy.Eq: "tensorflow.math.equal", + sympy.Ne: "tensorflow.math.not_equal", + sympy.StrictGreaterThan: "tensorflow.math.greater", + sympy.StrictLessThan: "tensorflow.math.less", + sympy.LessThan: "tensorflow.math.less_equal", + sympy.GreaterThan: "tensorflow.math.greater_equal", + + sympy.And: "tensorflow.math.logical_and", + sympy.Or: "tensorflow.math.logical_or", + sympy.Not: "tensorflow.math.logical_not", + sympy.Max: "tensorflow.math.maximum", + sympy.Min: "tensorflow.math.minimum", + + # Matrices + sympy.MatAdd: "tensorflow.math.add", + sympy.HadamardProduct: "tensorflow.math.multiply", + sympy.Trace: "tensorflow.linalg.trace", + + # XXX May raise error for integer matrices. + sympy.Determinant : "tensorflow.linalg.det", + } + + _default_settings = dict( + AbstractPythonCodePrinter._default_settings, + tensorflow_version=None + ) + + def __init__(self, settings=None): + super().__init__(settings) + + version = self._settings['tensorflow_version'] + if version is None and tensorflow: + version = tensorflow.__version__ + self.tensorflow_version = version + + def _print_Function(self, expr): + op = self.mapping.get(type(expr), None) + if op is None: + return super()._print_Basic(expr) + children = [self._print(arg) for arg in expr.args] + if len(children) == 1: + return "%s(%s)" % ( + self._module_format(op), + children[0] + ) + else: + return self._expand_fold_binary_op(op, children) + + _print_Expr = _print_Function + _print_Application = _print_Function + _print_MatrixExpr = _print_Function + # TODO: a better class structure would avoid this mess: + _print_Relational = _print_Function + _print_Not = _print_Function + _print_And = _print_Function + _print_Or = _print_Function + _print_HadamardProduct = _print_Function + _print_Trace = _print_Function + _print_Determinant = _print_Function + + def _print_Inverse(self, expr): + op = self._module_format('tensorflow.linalg.inv') + return "{}({})".format(op, self._print(expr.arg)) + + def _print_Transpose(self, expr): + version = self.tensorflow_version + if version and version_tuple(version) < version_tuple('1.14'): + op = self._module_format('tensorflow.matrix_transpose') + else: + op = self._module_format('tensorflow.linalg.matrix_transpose') + return "{}({})".format(op, self._print(expr.arg)) + + def _print_Derivative(self, expr): + variables = expr.variables + if any(isinstance(i, Iterable) for i in variables): + raise NotImplementedError("derivation by multiple variables is not supported") + def unfold(expr, args): + if not args: + return self._print(expr) + return "%s(%s, %s)[0]" % ( + self._module_format("tensorflow.gradients"), + unfold(expr, args[:-1]), + self._print(args[-1]), + ) + return unfold(expr.expr, variables) + + def _print_Piecewise(self, expr): + version = self.tensorflow_version + if version and version_tuple(version) < version_tuple('1.0'): + tensorflow_piecewise = "tensorflow.select" + else: + tensorflow_piecewise = "tensorflow.where" + + from sympy.functions.elementary.piecewise import Piecewise + e, cond = expr.args[0].args + if len(expr.args) == 1: + return '{}({}, {}, {})'.format( + self._module_format(tensorflow_piecewise), + self._print(cond), + self._print(e), + 0) + + return '{}({}, {}, {})'.format( + self._module_format(tensorflow_piecewise), + self._print(cond), + self._print(e), + self._print(Piecewise(*expr.args[1:]))) + + def _print_Pow(self, expr): + # XXX May raise error for + # int**float or int**complex or float**complex + base, exp = expr.args + if expr.exp == S.Half: + return "{}({})".format( + self._module_format("tensorflow.math.sqrt"), self._print(base)) + return "{}({}, {})".format( + self._module_format("tensorflow.math.pow"), + self._print(base), self._print(exp)) + + def _print_MatrixBase(self, expr): + tensorflow_f = "tensorflow.Variable" if expr.free_symbols else "tensorflow.constant" + data = "["+", ".join(["["+", ".join([self._print(j) for j in i])+"]" for i in expr.tolist()])+"]" + return "%s(%s)" % ( + self._module_format(tensorflow_f), + data, + ) + + def _print_MatMul(self, expr): + from sympy.matrices.expressions import MatrixExpr + mat_args = [arg for arg in expr.args if isinstance(arg, MatrixExpr)] + args = [arg for arg in expr.args if arg not in mat_args] + if args: + return "%s*%s" % ( + self.parenthesize(Mul.fromiter(args), PRECEDENCE["Mul"]), + self._expand_fold_binary_op( + "tensorflow.linalg.matmul", mat_args) + ) + else: + return self._expand_fold_binary_op( + "tensorflow.linalg.matmul", mat_args) + + def _print_MatPow(self, expr): + return self._expand_fold_binary_op( + "tensorflow.linalg.matmul", [expr.base]*expr.exp) + + def _print_CodeBlock(self, expr): + # TODO: is this necessary? + ret = [] + for subexpr in expr.args: + ret.append(self._print(subexpr)) + return "\n".join(ret) + + def _print_isnan(self, exp): + return f'tensorflow.math.is_nan({self._print(*exp.args)})' + + def _print_isinf(self, exp): + return f'tensorflow.math.is_inf({self._print(*exp.args)})' + + _module = "tensorflow" + _einsum = "linalg.einsum" + _add = "math.add" + _transpose = "transpose" + _ones = "ones" + _zeros = "zeros" + + +def tensorflow_code(expr, **settings): + printer = TensorflowPrinter(settings) + return printer.doprint(expr) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_aesaracode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_aesaracode.py new file mode 100644 index 0000000000000000000000000000000000000000..13308af65b382e77de33302bcd75344d2b00adbf --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_aesaracode.py @@ -0,0 +1,633 @@ +""" +Important note on tests in this module - the Aesara printing functions use a +global cache by default, which means that tests using it will modify global +state and thus not be independent from each other. Instead of using the "cache" +keyword argument each time, this module uses the aesara_code_ and +aesara_function_ functions defined below which default to using a new, empty +cache instead. +""" + +import logging + +from sympy.external import import_module +from sympy.testing.pytest import raises, SKIP, warns_deprecated_sympy + +from sympy.utilities.exceptions import ignore_warnings + + +aesaralogger = logging.getLogger('aesara.configdefaults') +aesaralogger.setLevel(logging.CRITICAL) +aesara = import_module('aesara') +aesaralogger.setLevel(logging.WARNING) + + +if aesara: + import numpy as np + aet = aesara.tensor + from aesara.scalar.basic import ScalarType + from aesara.graph.basic import Variable + from aesara.tensor.var import TensorVariable + from aesara.tensor.elemwise import Elemwise, DimShuffle + from aesara.tensor.math import Dot + + from sympy.printing.aesaracode import true_divide + + xt, yt, zt = [aet.scalar(name, 'floatX') for name in 'xyz'] + Xt, Yt, Zt = [aet.tensor('floatX', (False, False), name=n) for n in 'XYZ'] +else: + #bin/test will not execute any tests now + disabled = True + +import sympy as sy +from sympy.core.singleton import S +from sympy.abc import x, y, z, t +from sympy.printing.aesaracode import (aesara_code, dim_handling, + aesara_function) + + +# Default set of matrix symbols for testing - make square so we can both +# multiply and perform elementwise operations between them. +X, Y, Z = [sy.MatrixSymbol(n, 4, 4) for n in 'XYZ'] + +# For testing AppliedUndef +f_t = sy.Function('f')(t) + + +def aesara_code_(expr, **kwargs): + """ Wrapper for aesara_code that uses a new, empty cache by default. """ + kwargs.setdefault('cache', {}) + with warns_deprecated_sympy(): + return aesara_code(expr, **kwargs) + +def aesara_function_(inputs, outputs, **kwargs): + """ Wrapper for aesara_function that uses a new, empty cache by default. """ + kwargs.setdefault('cache', {}) + with warns_deprecated_sympy(): + return aesara_function(inputs, outputs, **kwargs) + + +def fgraph_of(*exprs): + """ Transform SymPy expressions into Aesara Computation. + + Parameters + ========== + exprs + SymPy expressions + + Returns + ======= + aesara.graph.fg.FunctionGraph + """ + outs = list(map(aesara_code_, exprs)) + ins = list(aesara.graph.basic.graph_inputs(outs)) + ins, outs = aesara.graph.basic.clone(ins, outs) + return aesara.graph.fg.FunctionGraph(ins, outs) + + +def aesara_simplify(fgraph): + """ Simplify a Aesara Computation. + + Parameters + ========== + fgraph : aesara.graph.fg.FunctionGraph + + Returns + ======= + aesara.graph.fg.FunctionGraph + """ + mode = aesara.compile.get_default_mode().excluding("fusion") + fgraph = fgraph.clone() + mode.optimizer.rewrite(fgraph) + return fgraph + + +def theq(a, b): + """ Test two Aesara objects for equality. + + Also accepts numeric types and lists/tuples of supported types. + + Note - debugprint() has a bug where it will accept numeric types but does + not respect the "file" argument and in this case and instead prints the number + to stdout and returns an empty string. This can lead to tests passing where + they should fail because any two numbers will always compare as equal. To + prevent this we treat numbers as a separate case. + """ + numeric_types = (int, float, np.number) + a_is_num = isinstance(a, numeric_types) + b_is_num = isinstance(b, numeric_types) + + # Compare numeric types using regular equality + if a_is_num or b_is_num: + if not (a_is_num and b_is_num): + return False + + return a == b + + # Compare sequences element-wise + a_is_seq = isinstance(a, (tuple, list)) + b_is_seq = isinstance(b, (tuple, list)) + + if a_is_seq or b_is_seq: + if not (a_is_seq and b_is_seq) or type(a) != type(b): + return False + + return list(map(theq, a)) == list(map(theq, b)) + + # Otherwise, assume debugprint() can handle it + astr = aesara.printing.debugprint(a, file='str') + bstr = aesara.printing.debugprint(b, file='str') + + # Check for bug mentioned above + for argname, argval, argstr in [('a', a, astr), ('b', b, bstr)]: + if argstr == '': + raise TypeError( + 'aesara.printing.debugprint(%s) returned empty string ' + '(%s is instance of %r)' + % (argname, argname, type(argval)) + ) + + return astr == bstr + + +def test_example_symbols(): + """ + Check that the example symbols in this module print to their Aesara + equivalents, as many of the other tests depend on this. + """ + assert theq(xt, aesara_code_(x)) + assert theq(yt, aesara_code_(y)) + assert theq(zt, aesara_code_(z)) + assert theq(Xt, aesara_code_(X)) + assert theq(Yt, aesara_code_(Y)) + assert theq(Zt, aesara_code_(Z)) + + +def test_Symbol(): + """ Test printing a Symbol to a aesara variable. """ + xx = aesara_code_(x) + assert isinstance(xx, Variable) + assert xx.broadcastable == () + assert xx.name == x.name + + xx2 = aesara_code_(x, broadcastables={x: (False,)}) + assert xx2.broadcastable == (False,) + assert xx2.name == x.name + +def test_MatrixSymbol(): + """ Test printing a MatrixSymbol to a aesara variable. """ + XX = aesara_code_(X) + assert isinstance(XX, TensorVariable) + assert XX.broadcastable == (False, False) + +@SKIP # TODO - this is currently not checked but should be implemented +def test_MatrixSymbol_wrong_dims(): + """ Test MatrixSymbol with invalid broadcastable. """ + bcs = [(), (False,), (True,), (True, False), (False, True,), (True, True)] + for bc in bcs: + with raises(ValueError): + aesara_code_(X, broadcastables={X: bc}) + +def test_AppliedUndef(): + """ Test printing AppliedUndef instance, which works similarly to Symbol. """ + ftt = aesara_code_(f_t) + assert isinstance(ftt, TensorVariable) + assert ftt.broadcastable == () + assert ftt.name == 'f_t' + + +def test_add(): + expr = x + y + comp = aesara_code_(expr) + assert comp.owner.op == aesara.tensor.add + +def test_trig(): + assert theq(aesara_code_(sy.sin(x)), aet.sin(xt)) + assert theq(aesara_code_(sy.tan(x)), aet.tan(xt)) + +def test_many(): + """ Test printing a complex expression with multiple symbols. """ + expr = sy.exp(x**2 + sy.cos(y)) * sy.log(2*z) + comp = aesara_code_(expr) + expected = aet.exp(xt**2 + aet.cos(yt)) * aet.log(2*zt) + assert theq(comp, expected) + + +def test_dtype(): + """ Test specifying specific data types through the dtype argument. """ + for dtype in ['float32', 'float64', 'int8', 'int16', 'int32', 'int64']: + assert aesara_code_(x, dtypes={x: dtype}).type.dtype == dtype + + # "floatX" type + assert aesara_code_(x, dtypes={x: 'floatX'}).type.dtype in ('float32', 'float64') + + # Type promotion + assert aesara_code_(x + 1, dtypes={x: 'float32'}).type.dtype == 'float32' + assert aesara_code_(x + y, dtypes={x: 'float64', y: 'float32'}).type.dtype == 'float64' + + +def test_broadcastables(): + """ Test the "broadcastables" argument when printing symbol-like objects. """ + + # No restrictions on shape + for s in [x, f_t]: + for bc in [(), (False,), (True,), (False, False), (True, False)]: + assert aesara_code_(s, broadcastables={s: bc}).broadcastable == bc + + # TODO - matrix broadcasting? + +def test_broadcasting(): + """ Test "broadcastable" attribute after applying element-wise binary op. """ + + expr = x + y + + cases = [ + [(), (), ()], + [(False,), (False,), (False,)], + [(True,), (False,), (False,)], + [(False, True), (False, False), (False, False)], + [(True, False), (False, False), (False, False)], + ] + + for bc1, bc2, bc3 in cases: + comp = aesara_code_(expr, broadcastables={x: bc1, y: bc2}) + assert comp.broadcastable == bc3 + + +def test_MatMul(): + expr = X*Y*Z + expr_t = aesara_code_(expr) + assert isinstance(expr_t.owner.op, Dot) + assert theq(expr_t, Xt.dot(Yt).dot(Zt)) + +def test_Transpose(): + assert isinstance(aesara_code_(X.T).owner.op, DimShuffle) + +def test_MatAdd(): + expr = X+Y+Z + assert isinstance(aesara_code_(expr).owner.op, Elemwise) + + +def test_Rationals(): + assert theq(aesara_code_(sy.Integer(2) / 3), true_divide(2, 3)) + assert theq(aesara_code_(S.Half), true_divide(1, 2)) + +def test_Integers(): + assert aesara_code_(sy.Integer(3)) == 3 + +def test_factorial(): + n = sy.Symbol('n') + assert aesara_code_(sy.factorial(n)) + +def test_Derivative(): + with ignore_warnings(UserWarning): + simp = lambda expr: aesara_simplify(fgraph_of(expr)) + assert theq(simp(aesara_code_(sy.Derivative(sy.sin(x), x, evaluate=False))), + simp(aesara.grad(aet.sin(xt), xt))) + + +def test_aesara_function_simple(): + """ Test aesara_function() with single output. """ + f = aesara_function_([x, y], [x+y]) + assert f(2, 3) == 5 + +def test_aesara_function_multi(): + """ Test aesara_function() with multiple outputs. """ + f = aesara_function_([x, y], [x+y, x-y]) + o1, o2 = f(2, 3) + assert o1 == 5 + assert o2 == -1 + +def test_aesara_function_numpy(): + """ Test aesara_function() vs Numpy implementation. """ + f = aesara_function_([x, y], [x+y], dim=1, + dtypes={x: 'float64', y: 'float64'}) + assert np.linalg.norm(f([1, 2], [3, 4]) - np.asarray([4, 6])) < 1e-9 + + f = aesara_function_([x, y], [x+y], dtypes={x: 'float64', y: 'float64'}, + dim=1) + xx = np.arange(3).astype('float64') + yy = 2*np.arange(3).astype('float64') + assert np.linalg.norm(f(xx, yy) - 3*np.arange(3)) < 1e-9 + + +def test_aesara_function_matrix(): + m = sy.Matrix([[x, y], [z, x + y + z]]) + expected = np.array([[1.0, 2.0], [3.0, 1.0 + 2.0 + 3.0]]) + f = aesara_function_([x, y, z], [m]) + np.testing.assert_allclose(f(1.0, 2.0, 3.0), expected) + f = aesara_function_([x, y, z], [m], scalar=True) + np.testing.assert_allclose(f(1.0, 2.0, 3.0), expected) + f = aesara_function_([x, y, z], [m, m]) + assert isinstance(f(1.0, 2.0, 3.0), type([])) + np.testing.assert_allclose(f(1.0, 2.0, 3.0)[0], expected) + np.testing.assert_allclose(f(1.0, 2.0, 3.0)[1], expected) + +def test_dim_handling(): + assert dim_handling([x], dim=2) == {x: (False, False)} + assert dim_handling([x, y], dims={x: 1, y: 2}) == {x: (False, True), + y: (False, False)} + assert dim_handling([x], broadcastables={x: (False,)}) == {x: (False,)} + +def test_aesara_function_kwargs(): + """ + Test passing additional kwargs from aesara_function() to aesara.function(). + """ + import numpy as np + f = aesara_function_([x, y, z], [x+y], dim=1, on_unused_input='ignore', + dtypes={x: 'float64', y: 'float64', z: 'float64'}) + assert np.linalg.norm(f([1, 2], [3, 4], [0, 0]) - np.asarray([4, 6])) < 1e-9 + + f = aesara_function_([x, y, z], [x+y], + dtypes={x: 'float64', y: 'float64', z: 'float64'}, + dim=1, on_unused_input='ignore') + xx = np.arange(3).astype('float64') + yy = 2*np.arange(3).astype('float64') + zz = 2*np.arange(3).astype('float64') + assert np.linalg.norm(f(xx, yy, zz) - 3*np.arange(3)) < 1e-9 + +def test_aesara_function_scalar(): + """ Test the "scalar" argument to aesara_function(). """ + from aesara.compile.function.types import Function + + args = [ + ([x, y], [x + y], None, [0]), # Single 0d output + ([X, Y], [X + Y], None, [2]), # Single 2d output + ([x, y], [x + y], {x: 0, y: 1}, [1]), # Single 1d output + ([x, y], [x + y, x - y], None, [0, 0]), # Two 0d outputs + ([x, y, X, Y], [x + y, X + Y], None, [0, 2]), # One 0d output, one 2d + ] + + # Create and test functions with and without the scalar setting + for inputs, outputs, in_dims, out_dims in args: + for scalar in [False, True]: + + f = aesara_function_(inputs, outputs, dims=in_dims, scalar=scalar) + + # Check the aesara_function attribute is set whether wrapped or not + assert isinstance(f.aesara_function, Function) + + # Feed in inputs of the appropriate size and get outputs + in_values = [ + np.ones([1 if bc else 5 for bc in i.type.broadcastable]) + for i in f.aesara_function.input_storage + ] + out_values = f(*in_values) + if not isinstance(out_values, list): + out_values = [out_values] + + # Check output types and shapes + assert len(out_dims) == len(out_values) + for d, value in zip(out_dims, out_values): + + if scalar and d == 0: + # Should have been converted to a scalar value + assert isinstance(value, np.number) + + else: + # Otherwise should be an array + assert isinstance(value, np.ndarray) + assert value.ndim == d + +def test_aesara_function_bad_kwarg(): + """ + Passing an unknown keyword argument to aesara_function() should raise an + exception. + """ + raises(Exception, lambda : aesara_function_([x], [x+1], foobar=3)) + + +def test_slice(): + assert aesara_code_(slice(1, 2, 3)) == slice(1, 2, 3) + + def theq_slice(s1, s2): + for attr in ['start', 'stop', 'step']: + a1 = getattr(s1, attr) + a2 = getattr(s2, attr) + if a1 is None or a2 is None: + if not (a1 is None or a2 is None): + return False + elif not theq(a1, a2): + return False + return True + + dtypes = {x: 'int32', y: 'int32'} + assert theq_slice(aesara_code_(slice(x, y), dtypes=dtypes), slice(xt, yt)) + assert theq_slice(aesara_code_(slice(1, x, 3), dtypes=dtypes), slice(1, xt, 3)) + +def test_MatrixSlice(): + cache = {} + + n = sy.Symbol('n', integer=True) + X = sy.MatrixSymbol('X', n, n) + + Y = X[1:2:3, 4:5:6] + Yt = aesara_code_(Y, cache=cache) + + s = ScalarType('int64') + assert tuple(Yt.owner.op.idx_list) == (slice(s, s, s), slice(s, s, s)) + assert Yt.owner.inputs[0] == aesara_code_(X, cache=cache) + # == doesn't work in Aesara like it does in SymPy. You have to use + # equals. + assert all(Yt.owner.inputs[i].data == i for i in range(1, 7)) + + k = sy.Symbol('k') + aesara_code_(k, dtypes={k: 'int32'}) + start, stop, step = 4, k, 2 + Y = X[start:stop:step] + Yt = aesara_code_(Y, dtypes={n: 'int32', k: 'int32'}) + # assert Yt.owner.op.idx_list[0].stop == kt + +def test_BlockMatrix(): + n = sy.Symbol('n', integer=True) + A, B, C, D = [sy.MatrixSymbol(name, n, n) for name in 'ABCD'] + At, Bt, Ct, Dt = map(aesara_code_, (A, B, C, D)) + Block = sy.BlockMatrix([[A, B], [C, D]]) + Blockt = aesara_code_(Block) + solutions = [aet.join(0, aet.join(1, At, Bt), aet.join(1, Ct, Dt)), + aet.join(1, aet.join(0, At, Ct), aet.join(0, Bt, Dt))] + assert any(theq(Blockt, solution) for solution in solutions) + +@SKIP +def test_BlockMatrix_Inverse_execution(): + k, n = 2, 4 + dtype = 'float32' + A = sy.MatrixSymbol('A', n, k) + B = sy.MatrixSymbol('B', n, n) + inputs = A, B + output = B.I*A + + cutsizes = {A: [(n//2, n//2), (k//2, k//2)], + B: [(n//2, n//2), (n//2, n//2)]} + cutinputs = [sy.blockcut(i, *cutsizes[i]) for i in inputs] + cutoutput = output.subs(dict(zip(inputs, cutinputs))) + + dtypes = dict(zip(inputs, [dtype]*len(inputs))) + f = aesara_function_(inputs, [output], dtypes=dtypes, cache={}) + fblocked = aesara_function_(inputs, [sy.block_collapse(cutoutput)], + dtypes=dtypes, cache={}) + + ninputs = [np.random.rand(*x.shape).astype(dtype) for x in inputs] + ninputs = [np.arange(n*k).reshape(A.shape).astype(dtype), + np.eye(n).astype(dtype)] + ninputs[1] += np.ones(B.shape)*1e-5 + + assert np.allclose(f(*ninputs), fblocked(*ninputs), rtol=1e-5) + +def test_DenseMatrix(): + from aesara.tensor.basic import Join + + t = sy.Symbol('theta') + for MatrixType in [sy.Matrix, sy.ImmutableMatrix]: + X = MatrixType([[sy.cos(t), -sy.sin(t)], [sy.sin(t), sy.cos(t)]]) + tX = aesara_code_(X) + assert isinstance(tX, TensorVariable) + assert isinstance(tX.owner.op, Join) + + +def test_cache_basic(): + """ Test single symbol-like objects are cached when printed by themselves. """ + + # Pairs of objects which should be considered equivalent with respect to caching + pairs = [ + (x, sy.Symbol('x')), + (X, sy.MatrixSymbol('X', *X.shape)), + (f_t, sy.Function('f')(sy.Symbol('t'))), + ] + + for s1, s2 in pairs: + cache = {} + st = aesara_code_(s1, cache=cache) + + # Test hit with same instance + assert aesara_code_(s1, cache=cache) is st + + # Test miss with same instance but new cache + assert aesara_code_(s1, cache={}) is not st + + # Test hit with different but equivalent instance + assert aesara_code_(s2, cache=cache) is st + +def test_global_cache(): + """ Test use of the global cache. """ + from sympy.printing.aesaracode import global_cache + + backup = dict(global_cache) + try: + # Temporarily empty global cache + global_cache.clear() + + for s in [x, X, f_t]: + with warns_deprecated_sympy(): + st = aesara_code(s) + assert aesara_code(s) is st + + finally: + # Restore global cache + global_cache.update(backup) + +def test_cache_types_distinct(): + """ + Test that symbol-like objects of different types (Symbol, MatrixSymbol, + AppliedUndef) are distinguished by the cache even if they have the same + name. + """ + symbols = [sy.Symbol('f_t'), sy.MatrixSymbol('f_t', 4, 4), f_t] + + cache = {} # Single shared cache + printed = {} + + for s in symbols: + st = aesara_code_(s, cache=cache) + assert st not in printed.values() + printed[s] = st + + # Check all printed objects are distinct + assert len(set(map(id, printed.values()))) == len(symbols) + + # Check retrieving + for s, st in printed.items(): + with warns_deprecated_sympy(): + assert aesara_code(s, cache=cache) is st + +def test_symbols_are_created_once(): + """ + Test that a symbol is cached and reused when it appears in an expression + more than once. + """ + expr = sy.Add(x, x, evaluate=False) + comp = aesara_code_(expr) + + assert theq(comp, xt + xt) + assert not theq(comp, xt + aesara_code_(x)) + +def test_cache_complex(): + """ + Test caching on a complicated expression with multiple symbols appearing + multiple times. + """ + expr = x ** 2 + (y - sy.exp(x)) * sy.sin(z - x * y) + symbol_names = {s.name for s in expr.free_symbols} + expr_t = aesara_code_(expr) + + # Iterate through variables in the Aesara computational graph that the + # printed expression depends on + seen = set() + for v in aesara.graph.basic.ancestors([expr_t]): + # Owner-less, non-constant variables should be our symbols + if v.owner is None and not isinstance(v, aesara.graph.basic.Constant): + # Check it corresponds to a symbol and appears only once + assert v.name in symbol_names + assert v.name not in seen + seen.add(v.name) + + # Check all were present + assert seen == symbol_names + + +def test_Piecewise(): + # A piecewise linear + expr = sy.Piecewise((0, x<0), (x, x<2), (1, True)) # ___/III + result = aesara_code_(expr) + assert result.owner.op == aet.switch + + expected = aet.switch(xt<0, 0, aet.switch(xt<2, xt, 1)) + assert theq(result, expected) + + expr = sy.Piecewise((x, x < 0)) + result = aesara_code_(expr) + expected = aet.switch(xt < 0, xt, np.nan) + assert theq(result, expected) + + expr = sy.Piecewise((0, sy.And(x>0, x<2)), \ + (x, sy.Or(x>2, x<0))) + result = aesara_code_(expr) + expected = aet.switch(aet.and_(xt>0,xt<2), 0, \ + aet.switch(aet.or_(xt>2, xt<0), xt, np.nan)) + assert theq(result, expected) + + +def test_Relationals(): + assert theq(aesara_code_(sy.Eq(x, y)), aet.eq(xt, yt)) + # assert theq(aesara_code_(sy.Ne(x, y)), aet.neq(xt, yt)) # TODO - implement + assert theq(aesara_code_(x > y), xt > yt) + assert theq(aesara_code_(x < y), xt < yt) + assert theq(aesara_code_(x >= y), xt >= yt) + assert theq(aesara_code_(x <= y), xt <= yt) + + +def test_complexfunctions(): + dtypes = {x:'complex128', y:'complex128'} + with warns_deprecated_sympy(): + xt, yt = aesara_code(x, dtypes=dtypes), aesara_code(y, dtypes=dtypes) + from sympy.functions.elementary.complexes import conjugate + from aesara.tensor import as_tensor_variable as atv + from aesara.tensor import complex as cplx + with warns_deprecated_sympy(): + assert theq(aesara_code(y*conjugate(x), dtypes=dtypes), yt*(xt.conj())) + assert theq(aesara_code((1+2j)*x), xt*(atv(1.0)+atv(2.0)*cplx(0,1))) + + +def test_constantfunctions(): + with warns_deprecated_sympy(): + tf = aesara_function([],[1+1j]) + assert(tf()==1+1j) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_c.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_c.py new file mode 100644 index 0000000000000000000000000000000000000000..626e7b6f244ea3227b886cd897d327f5d7bf66ec --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_c.py @@ -0,0 +1,888 @@ +from sympy.core import ( + S, pi, oo, Symbol, symbols, Rational, Integer, Float, Function, Mod, GoldenRatio, EulerGamma, Catalan, + Lambda, Dummy, nan, Mul, Pow, UnevaluatedExpr +) +from sympy.core.relational import (Eq, Ge, Gt, Le, Lt, Ne) +from sympy.functions import ( + Abs, acos, acosh, asin, asinh, atan, atanh, atan2, ceiling, cos, cosh, erf, + erfc, exp, floor, gamma, log, loggamma, Max, Min, Piecewise, sign, sin, sinh, + sqrt, tan, tanh, fibonacci, lucas +) +from sympy.sets import Range +from sympy.logic import ITE, Implies, Equivalent +from sympy.codegen import For, aug_assign, Assignment +from sympy.testing.pytest import raises, XFAIL +from sympy.printing.codeprinter import PrintMethodNotImplementedError +from sympy.printing.c import C89CodePrinter, C99CodePrinter, get_math_macros +from sympy.codegen.ast import ( + AddAugmentedAssignment, Element, Type, FloatType, Declaration, Pointer, Variable, value_const, pointer_const, + While, Scope, Print, FunctionPrototype, FunctionDefinition, FunctionCall, Return, + real, float32, float64, float80, float128, intc, Comment, CodeBlock, stderr, QuotedString +) +from sympy.codegen.cfunctions import expm1, log1p, exp2, log2, fma, log10, Cbrt, hypot, Sqrt, isnan, isinf +from sympy.codegen.cnodes import restrict +from sympy.utilities.lambdify import implemented_function +from sympy.tensor import IndexedBase, Idx +from sympy.matrices import Matrix, MatrixSymbol, SparseMatrix + +from sympy.printing.codeprinter import ccode + +x, y, z = symbols('x,y,z') + + +def test_printmethod(): + class fabs(Abs): + def _ccode(self, printer): + return "fabs(%s)" % printer._print(self.args[0]) + + assert ccode(fabs(x)) == "fabs(x)" + + +def test_ccode_sqrt(): + assert ccode(sqrt(x)) == "sqrt(x)" + assert ccode(x**0.5) == "sqrt(x)" + assert ccode(sqrt(x)) == "sqrt(x)" + + +def test_ccode_Pow(): + assert ccode(x**3) == "pow(x, 3)" + assert ccode(x**(y**3)) == "pow(x, pow(y, 3))" + g = implemented_function('g', Lambda(x, 2*x)) + assert ccode(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "pow(3.5*2*x, -x + pow(y, x))/(pow(x, 2) + y)" + assert ccode(x**-1.0) == '1.0/x' + assert ccode(x**Rational(2, 3)) == 'pow(x, 2.0/3.0)' + assert ccode(x**Rational(2, 3), type_aliases={real: float80}) == 'powl(x, 2.0L/3.0L)' + _cond_cfunc = [(lambda base, exp: exp.is_integer, "dpowi"), + (lambda base, exp: not exp.is_integer, "pow")] + assert ccode(x**3, user_functions={'Pow': _cond_cfunc}) == 'dpowi(x, 3)' + assert ccode(x**0.5, user_functions={'Pow': _cond_cfunc}) == 'pow(x, 0.5)' + assert ccode(x**Rational(16, 5), user_functions={'Pow': _cond_cfunc}) == 'pow(x, 16.0/5.0)' + _cond_cfunc2 = [(lambda base, exp: base == 2, lambda base, exp: 'exp2(%s)' % exp), + (lambda base, exp: base != 2, 'pow')] + # Related to gh-11353 + assert ccode(2**x, user_functions={'Pow': _cond_cfunc2}) == 'exp2(x)' + assert ccode(x**2, user_functions={'Pow': _cond_cfunc2}) == 'pow(x, 2)' + # For issue 14160 + assert ccode(Mul(-2, x, Pow(Mul(y,y,evaluate=False), -1, evaluate=False), + evaluate=False)) == '-2*x/(y*y)' + + +def test_ccode_Max(): + # Test for gh-11926 + assert ccode(Max(x,x*x),user_functions={"Max":"my_max", "Pow":"my_pow"}) == 'my_max(x, my_pow(x, 2))' + + +def test_ccode_Min_performance(): + #Shouldn't take more than a few seconds + big_min = Min(*symbols('a[0:50]')) + for curr_standard in ('c89', 'c99', 'c11'): + output = ccode(big_min, standard=curr_standard) + assert output.count('(') == output.count(')') + + +def test_ccode_constants_mathh(): + assert ccode(exp(1)) == "M_E" + assert ccode(pi) == "M_PI" + assert ccode(oo, standard='c89') == "HUGE_VAL" + assert ccode(-oo, standard='c89') == "-HUGE_VAL" + assert ccode(oo) == "INFINITY" + assert ccode(-oo, standard='c99') == "-INFINITY" + assert ccode(pi, type_aliases={real: float80}) == "M_PIl" + + +def test_ccode_constants_other(): + assert ccode(2*GoldenRatio) == "const double GoldenRatio = %s;\n2*GoldenRatio" % GoldenRatio.evalf(17) + assert ccode( + 2*Catalan) == "const double Catalan = %s;\n2*Catalan" % Catalan.evalf(17) + assert ccode(2*EulerGamma) == "const double EulerGamma = %s;\n2*EulerGamma" % EulerGamma.evalf(17) + + +def test_ccode_Rational(): + assert ccode(Rational(3, 7)) == "3.0/7.0" + assert ccode(Rational(3, 7), type_aliases={real: float80}) == "3.0L/7.0L" + assert ccode(Rational(18, 9)) == "2" + assert ccode(Rational(3, -7)) == "-3.0/7.0" + assert ccode(Rational(3, -7), type_aliases={real: float80}) == "-3.0L/7.0L" + assert ccode(Rational(-3, -7)) == "3.0/7.0" + assert ccode(Rational(-3, -7), type_aliases={real: float80}) == "3.0L/7.0L" + assert ccode(x + Rational(3, 7)) == "x + 3.0/7.0" + assert ccode(x + Rational(3, 7), type_aliases={real: float80}) == "x + 3.0L/7.0L" + assert ccode(Rational(3, 7)*x) == "(3.0/7.0)*x" + assert ccode(Rational(3, 7)*x, type_aliases={real: float80}) == "(3.0L/7.0L)*x" + + +def test_ccode_Integer(): + assert ccode(Integer(67)) == "67" + assert ccode(Integer(-1)) == "-1" + + +def test_ccode_functions(): + assert ccode(sin(x) ** cos(x)) == "pow(sin(x), cos(x))" + + +def test_ccode_inline_function(): + x = symbols('x') + g = implemented_function('g', Lambda(x, 2*x)) + assert ccode(g(x)) == "2*x" + g = implemented_function('g', Lambda(x, 2*x/Catalan)) + assert ccode( + g(x)) == "const double Catalan = %s;\n2*x/Catalan" % Catalan.evalf(17) + A = IndexedBase('A') + i = Idx('i', symbols('n', integer=True)) + g = implemented_function('g', Lambda(x, x*(1 + x)*(2 + x))) + assert ccode(g(A[i]), assign_to=A[i]) == ( + "for (int i=0; i y" + assert ccode(Ge(x, y)) == "x >= y" + + +def test_ccode_Piecewise(): + expr = Piecewise((x, x < 1), (x**2, True)) + assert ccode(expr) == ( + "((x < 1) ? (\n" + " x\n" + ")\n" + ": (\n" + " pow(x, 2)\n" + "))") + assert ccode(expr, assign_to="c") == ( + "if (x < 1) {\n" + " c = x;\n" + "}\n" + "else {\n" + " c = pow(x, 2);\n" + "}") + expr = Piecewise((x, x < 1), (x + 1, x < 2), (x**2, True)) + assert ccode(expr) == ( + "((x < 1) ? (\n" + " x\n" + ")\n" + ": ((x < 2) ? (\n" + " x + 1\n" + ")\n" + ": (\n" + " pow(x, 2)\n" + ")))") + assert ccode(expr, assign_to='c') == ( + "if (x < 1) {\n" + " c = x;\n" + "}\n" + "else if (x < 2) {\n" + " c = x + 1;\n" + "}\n" + "else {\n" + " c = pow(x, 2);\n" + "}") + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) + raises(ValueError, lambda: ccode(expr)) + + +def test_ccode_sinc(): + from sympy.functions.elementary.trigonometric import sinc + expr = sinc(x) + assert ccode(expr) == ( + "(((x != 0) ? (\n" + " sin(x)/x\n" + ")\n" + ": (\n" + " 1\n" + ")))") + + +def test_ccode_Piecewise_deep(): + p = ccode(2*Piecewise((x, x < 1), (x + 1, x < 2), (x**2, True))) + assert p == ( + "2*((x < 1) ? (\n" + " x\n" + ")\n" + ": ((x < 2) ? (\n" + " x + 1\n" + ")\n" + ": (\n" + " pow(x, 2)\n" + ")))") + expr = x*y*z + x**2 + y**2 + Piecewise((0, x < 0.5), (1, True)) + cos(z) - 1 + assert ccode(expr) == ( + "pow(x, 2) + x*y*z + pow(y, 2) + ((x < 0.5) ? (\n" + " 0\n" + ")\n" + ": (\n" + " 1\n" + ")) + cos(z) - 1") + assert ccode(expr, assign_to='c') == ( + "c = pow(x, 2) + x*y*z + pow(y, 2) + ((x < 0.5) ? (\n" + " 0\n" + ")\n" + ": (\n" + " 1\n" + ")) + cos(z) - 1;") + + +def test_ccode_ITE(): + expr = ITE(x < 1, y, z) + assert ccode(expr) == ( + "((x < 1) ? (\n" + " y\n" + ")\n" + ": (\n" + " z\n" + "))") + + +def test_ccode_settings(): + raises(TypeError, lambda: ccode(sin(x), method="garbage")) + + +def test_ccode_Indexed(): + s, n, m, o = symbols('s n m o', integer=True) + i, j, k = Idx('i', n), Idx('j', m), Idx('k', o) + + x = IndexedBase('x')[j] + A = IndexedBase('A')[i, j] + B = IndexedBase('B')[i, j, k] + + p = C99CodePrinter() + + assert p._print_Indexed(x) == 'x[j]' + assert p._print_Indexed(A) == 'A[%s]' % (m*i+j) + assert p._print_Indexed(B) == 'B[%s]' % (i*o*m+j*o+k) + + A = IndexedBase('A', shape=(5,3))[i, j] + assert p._print_Indexed(A) == 'A[%s]' % (3*i + j) + + A = IndexedBase('A', shape=(5,3), strides='F')[i, j] + assert ccode(A) == 'A[%s]' % (i + 5*j) + + A = IndexedBase('A', shape=(29,29), strides=(1, s), offset=o)[i, j] + assert ccode(A) == 'A[o + s*j + i]' + + Abase = IndexedBase('A', strides=(s, m, n), offset=o) + assert ccode(Abase[i, j, k]) == 'A[m*j + n*k + o + s*i]' + assert ccode(Abase[2, 3, k]) == 'A[3*m + n*k + o + 2*s]' + + +def test_Element(): + assert ccode(Element('x', 'ij')) == 'x[i][j]' + assert ccode(Element('x', 'ij', strides='kl', offset='o')) == 'x[i*k + j*l + o]' + assert ccode(Element('x', (3,))) == 'x[3]' + assert ccode(Element('x', (3,4,5))) == 'x[3][4][5]' + + +def test_ccode_Indexed_without_looking_for_contraction(): + len_y = 5 + y = IndexedBase('y', shape=(len_y,)) + x = IndexedBase('x', shape=(len_y,)) + Dy = IndexedBase('Dy', shape=(len_y-1,)) + i = Idx('i', len_y-1) + e = Eq(Dy[i], (y[i+1]-y[i])/(x[i+1]-x[i])) + code0 = ccode(e.rhs, assign_to=e.lhs, contract=False) + assert code0 == 'Dy[i] = (y[%s] - y[i])/(x[%s] - x[i]);' % (i + 1, i + 1) + + +def test_ccode_loops_matrix_vector(): + n, m = symbols('n m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + + s = ( + 'for (int i=0; i0), (y, True)), sin(z)]) + A = MatrixSymbol('A', 3, 1) + assert ccode(mat, A) == ( + "A[0] = x*y;\n" + "if (y > 0) {\n" + " A[1] = x + 2;\n" + "}\n" + "else {\n" + " A[1] = y;\n" + "}\n" + "A[2] = sin(z);") + # Test using MatrixElements in expressions + expr = Piecewise((2*A[2, 0], x > 0), (A[2, 0], True)) + sin(A[1, 0]) + A[0, 0] + assert ccode(expr) == ( + "((x > 0) ? (\n" + " 2*A[2]\n" + ")\n" + ": (\n" + " A[2]\n" + ")) + sin(A[1]) + A[0]") + # Test using MatrixElements in a Matrix + q = MatrixSymbol('q', 5, 1) + M = MatrixSymbol('M', 3, 3) + m = Matrix([[sin(q[1,0]), 0, cos(q[2,0])], + [q[1,0] + q[2,0], q[3, 0], 5], + [2*q[4, 0]/q[1,0], sqrt(q[0,0]) + 4, 0]]) + assert ccode(m, M) == ( + "M[0] = sin(q[1]);\n" + "M[1] = 0;\n" + "M[2] = cos(q[2]);\n" + "M[3] = q[1] + q[2];\n" + "M[4] = q[3];\n" + "M[5] = 5;\n" + "M[6] = 2*q[4]/q[1];\n" + "M[7] = sqrt(q[0]) + 4;\n" + "M[8] = 0;") + + +def test_sparse_matrix(): + # gh-15791 + with raises(PrintMethodNotImplementedError): + ccode(SparseMatrix([[1, 2, 3]])) + + assert 'Not supported in C' in C89CodePrinter({'strict': False}).doprint(SparseMatrix([[1, 2, 3]])) + + + +def test_ccode_reserved_words(): + x, y = symbols('x, if') + with raises(ValueError): + ccode(y**2, error_on_reserved=True, standard='C99') + assert ccode(y**2) == 'pow(if_, 2)' + assert ccode(x * y**2, dereference=[y]) == 'pow((*if_), 2)*x' + assert ccode(y**2, reserved_word_suffix='_unreserved') == 'pow(if_unreserved, 2)' + + +def test_ccode_sign(): + expr1, ref1 = sign(x) * y, 'y*(((x) > 0) - ((x) < 0))' + expr2, ref2 = sign(cos(x)), '(((cos(x)) > 0) - ((cos(x)) < 0))' + expr3, ref3 = sign(2 * x + x**2) * x + x**2, 'pow(x, 2) + x*(((pow(x, 2) + 2*x) > 0) - ((pow(x, 2) + 2*x) < 0))' + assert ccode(expr1) == ref1 + assert ccode(expr1, 'z') == 'z = %s;' % ref1 + assert ccode(expr2) == ref2 + assert ccode(expr3) == ref3 + +def test_ccode_Assignment(): + assert ccode(Assignment(x, y + z)) == 'x = y + z;' + assert ccode(aug_assign(x, '+', y + z)) == 'x += y + z;' + + +def test_ccode_For(): + f = For(x, Range(0, 10, 2), [aug_assign(y, '*', x)]) + assert ccode(f) == ("for (x = 0; x < 10; x += 2) {\n" + " y *= x;\n" + "}") + +def test_ccode_Max_Min(): + assert ccode(Max(x, 0), standard='C89') == '((0 > x) ? 0 : x)' + assert ccode(Max(x, 0), standard='C99') == 'fmax(0, x)' + assert ccode(Min(x, 0, sqrt(x)), standard='c89') == ( + '((0 < ((x < sqrt(x)) ? x : sqrt(x))) ? 0 : ((x < sqrt(x)) ? x : sqrt(x)))' + ) + +def test_ccode_standard(): + assert ccode(expm1(x), standard='c99') == 'expm1(x)' + assert ccode(nan, standard='c99') == 'NAN' + assert ccode(float('nan'), standard='c99') == 'NAN' + + +def test_C89CodePrinter(): + c89printer = C89CodePrinter() + assert c89printer.language == 'C' + assert c89printer.standard == 'C89' + assert 'void' in c89printer.reserved_words + assert 'template' not in c89printer.reserved_words + assert c89printer.doprint(log10(x)) == 'log10(x)' + + +def test_C99CodePrinter(): + assert C99CodePrinter().doprint(expm1(x)) == 'expm1(x)' + assert C99CodePrinter().doprint(log1p(x)) == 'log1p(x)' + assert C99CodePrinter().doprint(exp2(x)) == 'exp2(x)' + assert C99CodePrinter().doprint(log2(x)) == 'log2(x)' + assert C99CodePrinter().doprint(fma(x, y, -z)) == 'fma(x, y, -z)' + assert C99CodePrinter().doprint(log10(x)) == 'log10(x)' + assert C99CodePrinter().doprint(Cbrt(x)) == 'cbrt(x)' # note Cbrt due to cbrt already taken. + assert C99CodePrinter().doprint(hypot(x, y)) == 'hypot(x, y)' + assert C99CodePrinter().doprint(loggamma(x)) == 'lgamma(x)' + assert C99CodePrinter().doprint(Max(x, 3, x**2)) == 'fmax(3, fmax(x, pow(x, 2)))' + assert C99CodePrinter().doprint(Min(x, 3)) == 'fmin(3, x)' + c99printer = C99CodePrinter() + assert c99printer.language == 'C' + assert c99printer.standard == 'C99' + assert 'restrict' in c99printer.reserved_words + assert 'using' not in c99printer.reserved_words + + +@XFAIL +def test_C99CodePrinter__precision_f80(): + f80_printer = C99CodePrinter({"type_aliases": {real: float80}}) + assert f80_printer.doprint(sin(x + Float('2.1'))) == 'sinl(x + 2.1L)' + + +def test_C99CodePrinter__precision(): + n = symbols('n', integer=True) + p = symbols('p', integer=True, positive=True) + f32_printer = C99CodePrinter({"type_aliases": {real: float32}}) + f64_printer = C99CodePrinter({"type_aliases": {real: float64}}) + f80_printer = C99CodePrinter({"type_aliases": {real: float80}}) + assert f32_printer.doprint(sin(x+2.1)) == 'sinf(x + 2.1F)' + assert f64_printer.doprint(sin(x+2.1)) == 'sin(x + 2.1000000000000001)' + assert f80_printer.doprint(sin(x+Float('2.0'))) == 'sinl(x + 2.0L)' + + for printer, suffix in zip([f32_printer, f64_printer, f80_printer], ['f', '', 'l']): + def check(expr, ref): + assert printer.doprint(expr) == ref.format(s=suffix, S=suffix.upper()) + check(Abs(n), 'abs(n)') + check(Abs(x + 2.0), 'fabs{s}(x + 2.0{S})') + check(sin(x + 4.0)**cos(x - 2.0), 'pow{s}(sin{s}(x + 4.0{S}), cos{s}(x - 2.0{S}))') + check(exp(x*8.0), 'exp{s}(8.0{S}*x)') + check(exp2(x), 'exp2{s}(x)') + check(expm1(x*4.0), 'expm1{s}(4.0{S}*x)') + check(Mod(p, 2), 'p % 2') + check(Mod(2*p + 3, 3*p + 5, evaluate=False), '(2*p + 3) % (3*p + 5)') + check(Mod(x + 2.0, 3.0), 'fmod{s}(1.0{S}*x + 2.0{S}, 3.0{S})') + check(Mod(x, 2.0*x + 3.0), 'fmod{s}(1.0{S}*x, 2.0{S}*x + 3.0{S})') + check(log(x/2), 'log{s}((1.0{S}/2.0{S})*x)') + check(log10(3*x/2), 'log10{s}((3.0{S}/2.0{S})*x)') + check(log2(x*8.0), 'log2{s}(8.0{S}*x)') + check(log1p(x), 'log1p{s}(x)') + check(2**x, 'pow{s}(2, x)') + check(2.0**x, 'pow{s}(2.0{S}, x)') + check(x**3, 'pow{s}(x, 3)') + check(x**4.0, 'pow{s}(x, 4.0{S})') + check(sqrt(3+x), 'sqrt{s}(x + 3)') + check(Cbrt(x-2.0), 'cbrt{s}(x - 2.0{S})') + check(hypot(x, y), 'hypot{s}(x, y)') + check(sin(3.*x + 2.), 'sin{s}(3.0{S}*x + 2.0{S})') + check(cos(3.*x - 1.), 'cos{s}(3.0{S}*x - 1.0{S})') + check(tan(4.*y + 2.), 'tan{s}(4.0{S}*y + 2.0{S})') + check(asin(3.*x + 2.), 'asin{s}(3.0{S}*x + 2.0{S})') + check(acos(3.*x + 2.), 'acos{s}(3.0{S}*x + 2.0{S})') + check(atan(3.*x + 2.), 'atan{s}(3.0{S}*x + 2.0{S})') + check(atan2(3.*x, 2.*y), 'atan2{s}(3.0{S}*x, 2.0{S}*y)') + + check(sinh(3.*x + 2.), 'sinh{s}(3.0{S}*x + 2.0{S})') + check(cosh(3.*x - 1.), 'cosh{s}(3.0{S}*x - 1.0{S})') + check(tanh(4.0*y + 2.), 'tanh{s}(4.0{S}*y + 2.0{S})') + check(asinh(3.*x + 2.), 'asinh{s}(3.0{S}*x + 2.0{S})') + check(acosh(3.*x + 2.), 'acosh{s}(3.0{S}*x + 2.0{S})') + check(atanh(3.*x + 2.), 'atanh{s}(3.0{S}*x + 2.0{S})') + check(erf(42.*x), 'erf{s}(42.0{S}*x)') + check(erfc(42.*x), 'erfc{s}(42.0{S}*x)') + check(gamma(x), 'tgamma{s}(x)') + check(loggamma(x), 'lgamma{s}(x)') + + check(ceiling(x + 2.), "ceil{s}(x) + 2") + check(floor(x + 2.), "floor{s}(x) + 2") + check(fma(x, y, -z), 'fma{s}(x, y, -z)') + check(Max(x, 8.0, x**4.0), 'fmax{s}(8.0{S}, fmax{s}(x, pow{s}(x, 4.0{S})))') + check(Min(x, 2.0), 'fmin{s}(2.0{S}, x)') + + +def test_get_math_macros(): + macros = get_math_macros() + assert macros[exp(1)] == 'M_E' + assert macros[1/Sqrt(2)] == 'M_SQRT1_2' + + +def test_ccode_Declaration(): + i = symbols('i', integer=True) + var1 = Variable(i, type=Type.from_expr(i)) + dcl1 = Declaration(var1) + assert ccode(dcl1) == 'int i' + + var2 = Variable(x, type=float32, attrs={value_const}) + dcl2a = Declaration(var2) + assert ccode(dcl2a) == 'const float x' + dcl2b = var2.as_Declaration(value=pi) + assert ccode(dcl2b) == 'const float x = M_PI' + + var3 = Variable(y, type=Type('bool')) + dcl3 = Declaration(var3) + printer = C89CodePrinter() + assert 'stdbool.h' not in printer.headers + assert printer.doprint(dcl3) == 'bool y' + assert 'stdbool.h' in printer.headers + + u = symbols('u', real=True) + ptr4 = Pointer.deduced(u, attrs={pointer_const, restrict}) + dcl4 = Declaration(ptr4) + assert ccode(dcl4) == 'double * const restrict u' + + var5 = Variable(x, Type('__float128'), attrs={value_const}) + dcl5a = Declaration(var5) + assert ccode(dcl5a) == 'const __float128 x' + var5b = Variable(var5.symbol, var5.type, pi, attrs=var5.attrs) + dcl5b = Declaration(var5b) + assert ccode(dcl5b) == 'const __float128 x = M_PI' + + +def test_C99CodePrinter_custom_type(): + # We will look at __float128 (new in glibc 2.26) + f128 = FloatType('_Float128', float128.nbits, float128.nmant, float128.nexp) + p128 = C99CodePrinter({ + "type_aliases": {real: f128}, + "type_literal_suffixes": {f128: 'Q'}, + "type_func_suffixes": {f128: 'f128'}, + "type_math_macro_suffixes": { + real: 'f128', + f128: 'f128' + }, + "type_macros": { + f128: ('__STDC_WANT_IEC_60559_TYPES_EXT__',) + } + }) + assert p128.doprint(x) == 'x' + assert not p128.headers + assert not p128.libraries + assert not p128.macros + assert p128.doprint(2.0) == '2.0Q' + assert not p128.headers + assert not p128.libraries + assert p128.macros == {'__STDC_WANT_IEC_60559_TYPES_EXT__'} + + assert p128.doprint(Rational(1, 2)) == '1.0Q/2.0Q' + assert p128.doprint(sin(x)) == 'sinf128(x)' + assert p128.doprint(cos(2., evaluate=False)) == 'cosf128(2.0Q)' + assert p128.doprint(x**-1.0) == '1.0Q/x' + + var5 = Variable(x, f128, attrs={value_const}) + + dcl5a = Declaration(var5) + assert ccode(dcl5a) == 'const _Float128 x' + var5b = Variable(x, f128, pi, attrs={value_const}) + dcl5b = Declaration(var5b) + assert p128.doprint(dcl5b) == 'const _Float128 x = M_PIf128' + var5b = Variable(x, f128, value=Catalan.evalf(38), attrs={value_const}) + dcl5c = Declaration(var5b) + assert p128.doprint(dcl5c) == 'const _Float128 x = %sQ' % Catalan.evalf(f128.decimal_dig) + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert(ccode(A[0, 0]) == "A[0]") + assert(ccode(3 * A[0, 0]) == "3*A[0]") + + F = C[0, 0].subs(C, A - B) + assert(ccode(F) == "(A - B)[0]") + +def test_ccode_math_macros(): + assert ccode(z + exp(1)) == 'z + M_E' + assert ccode(z + log2(exp(1))) == 'z + M_LOG2E' + assert ccode(z + 1/log(2)) == 'z + M_LOG2E' + assert ccode(z + log(2)) == 'z + M_LN2' + assert ccode(z + log(10)) == 'z + M_LN10' + assert ccode(z + pi) == 'z + M_PI' + assert ccode(z + pi/2) == 'z + M_PI_2' + assert ccode(z + pi/4) == 'z + M_PI_4' + assert ccode(z + 1/pi) == 'z + M_1_PI' + assert ccode(z + 2/pi) == 'z + M_2_PI' + assert ccode(z + 2/sqrt(pi)) == 'z + M_2_SQRTPI' + assert ccode(z + 2/Sqrt(pi)) == 'z + M_2_SQRTPI' + assert ccode(z + sqrt(2)) == 'z + M_SQRT2' + assert ccode(z + Sqrt(2)) == 'z + M_SQRT2' + assert ccode(z + 1/sqrt(2)) == 'z + M_SQRT1_2' + assert ccode(z + 1/Sqrt(2)) == 'z + M_SQRT1_2' + + +def test_ccode_Type(): + assert ccode(Type('float')) == 'float' + assert ccode(intc) == 'int' + + +def test_ccode_codegen_ast(): + # Note that C only allows comments of the form /* ... */, double forward + # slash is not standard C, and some C compilers will grind to a halt upon + # encountering them. + assert ccode(Comment("this is a comment")) == "/* this is a comment */" # not // + assert ccode(While(abs(x) > 1, [aug_assign(x, '-', 1)])) == ( + 'while (fabs(x) > 1) {\n' + ' x -= 1;\n' + '}' + ) + assert ccode(Scope([AddAugmentedAssignment(x, 1)])) == ( + '{\n' + ' x += 1;\n' + '}' + ) + inp_x = Declaration(Variable(x, type=real)) + assert ccode(FunctionPrototype(real, 'pwer', [inp_x])) == 'double pwer(double x)' + assert ccode(FunctionDefinition(real, 'pwer', [inp_x], [Assignment(x, x**2)])) == ( + 'double pwer(double x){\n' + ' x = pow(x, 2);\n' + '}' + ) + + # Elements of CodeBlock are formatted as statements: + block = CodeBlock( + x, + Print([x, y], "%d %d"), + Print([QuotedString('hello'), y], "%s %d", file=stderr), + FunctionCall('pwer', [x]), + Return(x), + ) + assert ccode(block) == '\n'.join([ + 'x;', + 'printf("%d %d", x, y);', + 'fprintf(stderr, "%s %d", "hello", y);', + 'pwer(x);', + 'return x;', + ]) + +def test_ccode_UnevaluatedExpr(): + assert ccode(UnevaluatedExpr(y * x) + z) == "z + x*y" + assert ccode(UnevaluatedExpr(y + x) + z) == "z + (x + y)" # gh-21955 + w = symbols('w') + assert ccode(UnevaluatedExpr(y + x) + UnevaluatedExpr(z + w)) == "(w + z) + (x + y)" + + p, q, r = symbols("p q r", real=True) + q_r = UnevaluatedExpr(q + r) + expr = abs(exp(p+q_r)) + assert ccode(expr) == "exp(p + (q + r))" + + +def test_ccode_array_like_containers(): + assert ccode([2,3,4]) == "{2, 3, 4}" + assert ccode((2,3,4)) == "{2, 3, 4}" + +def test_ccode__isinf_isnan(): + assert ccode(isinf(x)) == 'isinf(x)' + assert ccode(isnan(x)) == 'isnan(x)' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_codeprinter.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_codeprinter.py new file mode 100644 index 0000000000000000000000000000000000000000..4b077037eb84e218fcfd4a05fc03e40b211e45b9 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_codeprinter.py @@ -0,0 +1,77 @@ +from sympy.printing.codeprinter import CodePrinter, PrintMethodNotImplementedError +from sympy.core import symbols +from sympy.core.symbol import Dummy +from sympy.testing.pytest import raises +from sympy import cos +from sympy.utilities.lambdify import lambdify +from math import cos as math_cos +from sympy.printing.lambdarepr import LambdaPrinter + + +def setup_test_printer(**kwargs): + p = CodePrinter(settings=kwargs) + p._not_supported = set() + p._number_symbols = set() + return p + + +def test_print_Dummy(): + d = Dummy('d') + p = setup_test_printer() + assert p._print_Dummy(d) == "d_%i" % d.dummy_index + +def test_print_Symbol(): + + x, y = symbols('x, if') + + p = setup_test_printer() + assert p._print(x) == 'x' + assert p._print(y) == 'if' + + p.reserved_words.update(['if']) + assert p._print(y) == 'if_' + + p = setup_test_printer(error_on_reserved=True) + p.reserved_words.update(['if']) + with raises(ValueError): + p._print(y) + + p = setup_test_printer(reserved_word_suffix='_He_Man') + p.reserved_words.update(['if']) + assert p._print(y) == 'if_He_Man' + + +def test_lambdify_LaTeX_symbols_issue_23374(): + # Create symbols with Latex style names + x1, x2 = symbols("x_{1} x_2") + + # Lambdify the function + f1 = lambdify([x1, x2], cos(x1 ** 2 + x2 ** 2)) + + # Test that the function works correctly (numerically) + assert f1(1, 2) == math_cos(1 ** 2 + 2 ** 2) + + # Explicitly generate a custom printer to verify the naming convention + p = LambdaPrinter() + expr_str = p.doprint(cos(x1 ** 2 + x2 ** 2)) + assert 'x_1' in expr_str + assert 'x_2' in expr_str + + +def test_issue_15791(): + class CrashingCodePrinter(CodePrinter): + def emptyPrinter(self, obj): + raise NotImplementedError + + from sympy.matrices import ( + MutableSparseMatrix, + ImmutableSparseMatrix, + ) + + c = CrashingCodePrinter() + + # these should not silently succeed + with raises(PrintMethodNotImplementedError): + c.doprint(ImmutableSparseMatrix(2, 2, {})) + with raises(PrintMethodNotImplementedError): + c.doprint(MutableSparseMatrix(2, 2, {})) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_conventions.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_conventions.py new file mode 100644 index 0000000000000000000000000000000000000000..e8f1fa8532f96130828b89d1ba5ba11fd5bed7a4 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_conventions.py @@ -0,0 +1,116 @@ +# -*- coding: utf-8 -*- + +from sympy.core.function import (Derivative, Function) +from sympy.core.numbers import oo +from sympy.core.symbol import symbols +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.trigonometric import cos +from sympy.integrals.integrals import Integral +from sympy.functions.special.bessel import besselj +from sympy.functions.special.polynomials import legendre +from sympy.functions.combinatorial.numbers import bell +from sympy.printing.conventions import split_super_sub, requires_partial +from sympy.testing.pytest import XFAIL + +def test_super_sub(): + assert split_super_sub("beta_13_2") == ("beta", [], ["13", "2"]) + assert split_super_sub("beta_132_20") == ("beta", [], ["132", "20"]) + assert split_super_sub("beta_13") == ("beta", [], ["13"]) + assert split_super_sub("x_a_b") == ("x", [], ["a", "b"]) + assert split_super_sub("x_1_2_3") == ("x", [], ["1", "2", "3"]) + assert split_super_sub("x_a_b1") == ("x", [], ["a", "b1"]) + assert split_super_sub("x_a_1") == ("x", [], ["a", "1"]) + assert split_super_sub("x_1_a") == ("x", [], ["1", "a"]) + assert split_super_sub("x_1^aa") == ("x", ["aa"], ["1"]) + assert split_super_sub("x_1__aa") == ("x", ["aa"], ["1"]) + assert split_super_sub("x_11^a") == ("x", ["a"], ["11"]) + assert split_super_sub("x_11__a") == ("x", ["a"], ["11"]) + assert split_super_sub("x_a_b_c_d") == ("x", [], ["a", "b", "c", "d"]) + assert split_super_sub("x_a_b^c^d") == ("x", ["c", "d"], ["a", "b"]) + assert split_super_sub("x_a_b__c__d") == ("x", ["c", "d"], ["a", "b"]) + assert split_super_sub("x_a^b_c^d") == ("x", ["b", "d"], ["a", "c"]) + assert split_super_sub("x_a__b_c__d") == ("x", ["b", "d"], ["a", "c"]) + assert split_super_sub("x^a^b_c_d") == ("x", ["a", "b"], ["c", "d"]) + assert split_super_sub("x__a__b_c_d") == ("x", ["a", "b"], ["c", "d"]) + assert split_super_sub("x^a^b^c^d") == ("x", ["a", "b", "c", "d"], []) + assert split_super_sub("x__a__b__c__d") == ("x", ["a", "b", "c", "d"], []) + assert split_super_sub("alpha_11") == ("alpha", [], ["11"]) + assert split_super_sub("alpha_11_11") == ("alpha", [], ["11", "11"]) + assert split_super_sub("w1") == ("w", [], ["1"]) + assert split_super_sub("w𝟙") == ("w", [], ["𝟙"]) + assert split_super_sub("w11") == ("w", [], ["11"]) + assert split_super_sub("w𝟙𝟙") == ("w", [], ["𝟙𝟙"]) + assert split_super_sub("w𝟙2𝟙") == ("w", [], ["𝟙2𝟙"]) + assert split_super_sub("w1^a") == ("w", ["a"], ["1"]) + assert split_super_sub("ω1") == ("ω", [], ["1"]) + assert split_super_sub("ω11") == ("ω", [], ["11"]) + assert split_super_sub("ω1^a") == ("ω", ["a"], ["1"]) + assert split_super_sub("ω𝟙^α") == ("ω", ["α"], ["𝟙"]) + assert split_super_sub("ω𝟙2^3α") == ("ω", ["3α"], ["𝟙2"]) + assert split_super_sub("") == ("", [], []) + + +def test_requires_partial(): + x, y, z, t, nu = symbols('x y z t nu') + n = symbols('n', integer=True) + + f = x * y + assert requires_partial(Derivative(f, x)) is True + assert requires_partial(Derivative(f, y)) is True + + ## integrating out one of the variables + assert requires_partial(Derivative(Integral(exp(-x * y), (x, 0, oo)), y, evaluate=False)) is False + + ## bessel function with smooth parameter + f = besselj(nu, x) + assert requires_partial(Derivative(f, x)) is True + assert requires_partial(Derivative(f, nu)) is True + + ## bessel function with integer parameter + f = besselj(n, x) + assert requires_partial(Derivative(f, x)) is False + # this is not really valid (differentiating with respect to an integer) + # but there's no reason to use the partial derivative symbol there. make + # sure we don't throw an exception here, though + assert requires_partial(Derivative(f, n)) is False + + ## bell polynomial + f = bell(n, x) + assert requires_partial(Derivative(f, x)) is False + # again, invalid + assert requires_partial(Derivative(f, n)) is False + + ## legendre polynomial + f = legendre(0, x) + assert requires_partial(Derivative(f, x)) is False + + f = legendre(n, x) + assert requires_partial(Derivative(f, x)) is False + # again, invalid + assert requires_partial(Derivative(f, n)) is False + + f = x ** n + assert requires_partial(Derivative(f, x)) is False + + assert requires_partial(Derivative(Integral((x*y) ** n * exp(-x * y), (x, 0, oo)), y, evaluate=False)) is False + + # parametric equation + f = (exp(t), cos(t)) + g = sum(f) + assert requires_partial(Derivative(g, t)) is False + + f = symbols('f', cls=Function) + assert requires_partial(Derivative(f(x), x)) is False + assert requires_partial(Derivative(f(x), y)) is False + assert requires_partial(Derivative(f(x, y), x)) is True + assert requires_partial(Derivative(f(x, y), y)) is True + assert requires_partial(Derivative(f(x, y), z)) is True + assert requires_partial(Derivative(f(x, y), x, y)) is True + +@XFAIL +def test_requires_partial_unspecified_variables(): + x, y = symbols('x y') + # function of unspecified variables + f = symbols('f', cls=Function) + assert requires_partial(Derivative(f, x)) is False + assert requires_partial(Derivative(f, x, y)) is True diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_cupy.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_cupy.py new file mode 100644 index 0000000000000000000000000000000000000000..cf111ec1623390a3dbbf489235d2ed387624a36c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_cupy.py @@ -0,0 +1,56 @@ +from sympy.concrete.summations import Sum +from sympy.functions.elementary.exponential import log +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.utilities.lambdify import lambdify +from sympy.abc import x, i, a, b +from sympy.codegen.numpy_nodes import logaddexp +from sympy.printing.numpy import CuPyPrinter, _cupy_known_constants, _cupy_known_functions + +from sympy.testing.pytest import skip, raises +from sympy.external import import_module + +cp = import_module('cupy') + +def test_cupy_print(): + prntr = CuPyPrinter() + assert prntr.doprint(logaddexp(a, b)) == 'cupy.logaddexp(a, b)' + assert prntr.doprint(sqrt(x)) == 'cupy.sqrt(x)' + assert prntr.doprint(log(x)) == 'cupy.log(x)' + assert prntr.doprint("acos(x)") == 'cupy.arccos(x)' + assert prntr.doprint("exp(x)") == 'cupy.exp(x)' + assert prntr.doprint("Abs(x)") == 'abs(x)' + +def test_not_cupy_print(): + prntr = CuPyPrinter() + with raises(NotImplementedError): + prntr.doprint("abcd(x)") + +def test_cupy_sum(): + if not cp: + skip("CuPy not installed") + + s = Sum(x ** i, (i, a, b)) + f = lambdify((a, b, x), s, 'cupy') + + a_, b_ = 0, 10 + x_ = cp.linspace(-1, +1, 10) + assert cp.allclose(f(a_, b_, x_), sum(x_ ** i_ for i_ in range(a_, b_ + 1))) + + s = Sum(i * x, (i, a, b)) + f = lambdify((a, b, x), s, 'numpy') + + a_, b_ = 0, 10 + x_ = cp.linspace(-1, +1, 10) + assert cp.allclose(f(a_, b_, x_), sum(i_ * x_ for i_ in range(a_, b_ + 1))) + +def test_cupy_known_funcs_consts(): + assert _cupy_known_constants['NaN'] == 'cupy.nan' + assert _cupy_known_constants['EulerGamma'] == 'cupy.euler_gamma' + + assert _cupy_known_functions['acos'] == 'cupy.arccos' + assert _cupy_known_functions['log'] == 'cupy.log' + +def test_cupy_print_methods(): + prntr = CuPyPrinter() + assert hasattr(prntr, '_print_acos') + assert hasattr(prntr, '_print_log') diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_cxx.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_cxx.py new file mode 100644 index 0000000000000000000000000000000000000000..d84ec75cbf0eeb60a1176b9cb3b401a3384454e7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_cxx.py @@ -0,0 +1,86 @@ +from sympy.core.numbers import Float, Integer, Rational +from sympy.core.symbol import symbols +from sympy.functions import beta, Ei, zeta, Max, Min, sqrt, riemann_xi, frac +from sympy.printing.cxx import CXX98CodePrinter, CXX11CodePrinter, CXX17CodePrinter, cxxcode +from sympy.codegen.cfunctions import log1p + + +x, y, u, v = symbols('x y u v') + + +def test_CXX98CodePrinter(): + assert CXX98CodePrinter().doprint(Max(x, 3)) in ('std::max(x, 3)', 'std::max(3, x)') + assert CXX98CodePrinter().doprint(Min(x, 3, sqrt(x))) == 'std::min(3, std::min(x, std::sqrt(x)))' + cxx98printer = CXX98CodePrinter() + assert cxx98printer.language == 'C++' + assert cxx98printer.standard == 'C++98' + assert 'template' in cxx98printer.reserved_words + assert 'alignas' not in cxx98printer.reserved_words + + +def test_CXX11CodePrinter(): + assert CXX11CodePrinter().doprint(log1p(x)) == 'std::log1p(x)' + + cxx11printer = CXX11CodePrinter() + assert cxx11printer.language == 'C++' + assert cxx11printer.standard == 'C++11' + assert 'operator' in cxx11printer.reserved_words + assert 'noexcept' in cxx11printer.reserved_words + assert 'concept' not in cxx11printer.reserved_words + + +def test_subclass_print_method(): + class MyPrinter(CXX11CodePrinter): + def _print_log1p(self, expr): + return 'my_library::log1p(%s)' % ', '.join(map(self._print, expr.args)) + + assert MyPrinter().doprint(log1p(x)) == 'my_library::log1p(x)' + + +def test_subclass_print_method__ns(): + class MyPrinter(CXX11CodePrinter): + _ns = 'my_library::' + + p = CXX11CodePrinter() + myp = MyPrinter() + + assert p.doprint(log1p(x)) == 'std::log1p(x)' + assert myp.doprint(log1p(x)) == 'my_library::log1p(x)' + + +def test_CXX17CodePrinter(): + assert CXX17CodePrinter().doprint(beta(x, y)) == 'std::beta(x, y)' + assert CXX17CodePrinter().doprint(Ei(x)) == 'std::expint(x)' + assert CXX17CodePrinter().doprint(zeta(x)) == 'std::riemann_zeta(x)' + + # Automatic rewrite + assert CXX17CodePrinter().doprint(frac(x)) == '(x - std::floor(x))' + assert CXX17CodePrinter().doprint(riemann_xi(x)) == '((1.0/2.0)*std::pow(M_PI, -1.0/2.0*x)*x*(x - 1)*std::tgamma((1.0/2.0)*x)*std::riemann_zeta(x))' + + +def test_cxxcode(): + assert sorted(cxxcode(sqrt(x)*.5).split('*')) == sorted(['0.5', 'std::sqrt(x)']) + +def test_cxxcode_nested_minmax(): + assert cxxcode(Max(Min(x, y), Min(u, v))) \ + == 'std::max(std::min(u, v), std::min(x, y))' + assert cxxcode(Min(Max(x, y), Max(u, v))) \ + == 'std::min(std::max(u, v), std::max(x, y))' + +def test_subclass_Integer_Float(): + class MyPrinter(CXX17CodePrinter): + def _print_Integer(self, arg): + return 'bigInt("%s")' % super()._print_Integer(arg) + + def _print_Float(self, arg): + rat = Rational(arg) + return 'bigFloat(%s, %s)' % ( + self._print(Integer(rat.p)), + self._print(Integer(rat.q)) + ) + + p = MyPrinter() + for i in range(13): + assert p.doprint(i) == 'bigInt("%d")' % i + assert p.doprint(Float(0.5)) == 'bigFloat(bigInt("1"), bigInt("2"))' + assert p.doprint(x**-1.0) == 'bigFloat(bigInt("1"), bigInt("1"))/x' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_dot.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_dot.py new file mode 100644 index 0000000000000000000000000000000000000000..6213e237fb7aac6460a956b4c9fc1f7c8710fec6 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_dot.py @@ -0,0 +1,134 @@ +from sympy.printing.dot import (purestr, styleof, attrprint, dotnode, + dotedges, dotprint) +from sympy.core.basic import Basic +from sympy.core.expr import Expr +from sympy.core.numbers import (Float, Integer) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.printing.repr import srepr +from sympy.abc import x + + +def test_purestr(): + assert purestr(Symbol('x')) == "Symbol('x')" + assert purestr(Basic(S(1), S(2))) == "Basic(Integer(1), Integer(2))" + assert purestr(Float(2)) == "Float('2.0', precision=53)" + + assert purestr(Symbol('x'), with_args=True) == ("Symbol('x')", ()) + assert purestr(Basic(S(1), S(2)), with_args=True) == \ + ('Basic(Integer(1), Integer(2))', ('Integer(1)', 'Integer(2)')) + assert purestr(Float(2), with_args=True) == \ + ("Float('2.0', precision=53)", ()) + + +def test_styleof(): + styles = [(Basic, {'color': 'blue', 'shape': 'ellipse'}), + (Expr, {'color': 'black'})] + assert styleof(Basic(S(1)), styles) == {'color': 'blue', 'shape': 'ellipse'} + + assert styleof(x + 1, styles) == {'color': 'black', 'shape': 'ellipse'} + + +def test_attrprint(): + assert attrprint({'color': 'blue', 'shape': 'ellipse'}) == \ + '"color"="blue", "shape"="ellipse"' + +def test_dotnode(): + + assert dotnode(x, repeat=False) == \ + '"Symbol(\'x\')" ["color"="black", "label"="x", "shape"="ellipse"];' + assert dotnode(x+2, repeat=False) == \ + '"Add(Integer(2), Symbol(\'x\'))" ' \ + '["color"="black", "label"="Add", "shape"="ellipse"];', \ + dotnode(x+2,repeat=0) + + assert dotnode(x + x**2, repeat=False) == \ + '"Add(Symbol(\'x\'), Pow(Symbol(\'x\'), Integer(2)))" ' \ + '["color"="black", "label"="Add", "shape"="ellipse"];' + assert dotnode(x + x**2, repeat=True) == \ + '"Add(Symbol(\'x\'), Pow(Symbol(\'x\'), Integer(2)))_()" ' \ + '["color"="black", "label"="Add", "shape"="ellipse"];' + +def test_dotedges(): + assert sorted(dotedges(x+2, repeat=False)) == [ + '"Add(Integer(2), Symbol(\'x\'))" -> "Integer(2)";', + '"Add(Integer(2), Symbol(\'x\'))" -> "Symbol(\'x\')";' + ] + assert sorted(dotedges(x + 2, repeat=True)) == [ + '"Add(Integer(2), Symbol(\'x\'))_()" -> "Integer(2)_(0,)";', + '"Add(Integer(2), Symbol(\'x\'))_()" -> "Symbol(\'x\')_(1,)";' + ] + +def test_dotprint(): + text = dotprint(x+2, repeat=False) + assert all(e in text for e in dotedges(x+2, repeat=False)) + assert all( + n in text for n in [dotnode(expr, repeat=False) + for expr in (x, Integer(2), x+2)]) + assert 'digraph' in text + + text = dotprint(x+x**2, repeat=False) + assert all(e in text for e in dotedges(x+x**2, repeat=False)) + assert all( + n in text for n in [dotnode(expr, repeat=False) + for expr in (x, Integer(2), x**2)]) + assert 'digraph' in text + + text = dotprint(x+x**2, repeat=True) + assert all(e in text for e in dotedges(x+x**2, repeat=True)) + assert all( + n in text for n in [dotnode(expr, pos=()) + for expr in [x + x**2]]) + + text = dotprint(x**x, repeat=True) + assert all(e in text for e in dotedges(x**x, repeat=True)) + assert all( + n in text for n in [dotnode(x, pos=(0,)), dotnode(x, pos=(1,))]) + assert 'digraph' in text + +def test_dotprint_depth(): + text = dotprint(3*x+2, depth=1) + assert dotnode(3*x+2) in text + assert dotnode(x) not in text + text = dotprint(3*x+2) + assert "depth" not in text + +def test_Matrix_and_non_basics(): + from sympy.matrices.expressions.matexpr import MatrixSymbol + n = Symbol('n') + assert dotprint(MatrixSymbol('X', n, n)) == \ +"""digraph{ + +# Graph style +"ordering"="out" +"rankdir"="TD" + +######### +# Nodes # +######### + +"MatrixSymbol(Str('X'), Symbol('n'), Symbol('n'))_()" ["color"="black", "label"="MatrixSymbol", "shape"="ellipse"]; +"Str('X')_(0,)" ["color"="blue", "label"="X", "shape"="ellipse"]; +"Symbol('n')_(1,)" ["color"="black", "label"="n", "shape"="ellipse"]; +"Symbol('n')_(2,)" ["color"="black", "label"="n", "shape"="ellipse"]; + +######### +# Edges # +######### + +"MatrixSymbol(Str('X'), Symbol('n'), Symbol('n'))_()" -> "Str('X')_(0,)"; +"MatrixSymbol(Str('X'), Symbol('n'), Symbol('n'))_()" -> "Symbol('n')_(1,)"; +"MatrixSymbol(Str('X'), Symbol('n'), Symbol('n'))_()" -> "Symbol('n')_(2,)"; +}""" + + +def test_labelfunc(): + text = dotprint(x + 2, labelfunc=srepr) + assert "Symbol('x')" in text + assert "Integer(2)" in text + + +def test_commutative(): + x, y = symbols('x y', commutative=False) + assert dotprint(x + y) == dotprint(y + x) + assert dotprint(x*y) != dotprint(y*x) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_fortran.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_fortran.py new file mode 100644 index 0000000000000000000000000000000000000000..c28a1ea16dcf2157b58d763286428dccc1944b71 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_fortran.py @@ -0,0 +1,854 @@ +from sympy.core.add import Add +from sympy.core.expr import Expr +from sympy.core.function import (Function, Lambda, diff) +from sympy.core.mod import Mod +from sympy.core import (Catalan, EulerGamma, GoldenRatio) +from sympy.core.numbers import (E, Float, I, Integer, Rational, pi) +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, symbols) +from sympy.functions.combinatorial.factorials import factorial +from sympy.functions.elementary.complexes import (conjugate, sign) +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (atan2, cos, sin) +from sympy.functions.special.gamma_functions import gamma +from sympy.integrals.integrals import Integral +from sympy.sets.fancysets import Range + +from sympy.codegen import For, Assignment, aug_assign +from sympy.codegen.ast import Declaration, Variable, float32, float64, \ + value_const, real, bool_, While, FunctionPrototype, FunctionDefinition, \ + integer, Return, Element +from sympy.core.expr import UnevaluatedExpr +from sympy.core.relational import Relational +from sympy.logic.boolalg import And, Or, Not, Equivalent, Xor +from sympy.matrices import Matrix, MatrixSymbol +from sympy.printing.fortran import fcode, FCodePrinter +from sympy.tensor import IndexedBase, Idx +from sympy.tensor.array.expressions import ArraySymbol, ArrayElement +from sympy.utilities.lambdify import implemented_function +from sympy.testing.pytest import raises + + +def test_UnevaluatedExpr(): + p, q, r = symbols("p q r", real=True) + q_r = UnevaluatedExpr(q + r) + expr = abs(exp(p+q_r)) + assert fcode(expr, source_format="free") == "exp(p + (q + r))" + x, y, z = symbols("x y z") + y_z = UnevaluatedExpr(y + z) + expr2 = abs(exp(x+y_z)) + assert fcode(expr2, human=False)[2].lstrip() == "exp(re(x) + re(y + z))" + assert fcode(expr2, user_functions={"re": "realpart"}).lstrip() == "exp(realpart(x) + realpart(y + z))" + + +def test_printmethod(): + x = symbols('x') + + class nint(Function): + def _fcode(self, printer): + return "nint(%s)" % printer._print(self.args[0]) + assert fcode(nint(x)) == " nint(x)" + + +def test_fcode_sign(): #issue 12267 + x=symbols('x') + y=symbols('y', integer=True) + z=symbols('z', complex=True) + assert fcode(sign(x), standard=95, source_format='free') == "merge(0d0, dsign(1d0, x), x == 0d0)" + assert fcode(sign(y), standard=95, source_format='free') == "merge(0, isign(1, y), y == 0)" + assert fcode(sign(z), standard=95, source_format='free') == "merge(cmplx(0d0, 0d0), z/abs(z), abs(z) == 0d0)" + raises(NotImplementedError, lambda: fcode(sign(x))) + + +def test_fcode_Pow(): + x, y = symbols('x,y') + n = symbols('n', integer=True) + + assert fcode(x**3) == " x**3" + assert fcode(x**(y**3)) == " x**(y**3)" + assert fcode(1/(sin(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + " (3.5d0*sin(x))**(-x + y**x)/(x**2 + y)" + assert fcode(sqrt(x)) == ' sqrt(x)' + assert fcode(sqrt(n)) == ' sqrt(dble(n))' + assert fcode(x**0.5) == ' sqrt(x)' + assert fcode(sqrt(x)) == ' sqrt(x)' + assert fcode(sqrt(10)) == ' sqrt(10.0d0)' + assert fcode(x**-1.0) == ' 1d0/x' + assert fcode(x**-2.0, 'y', source_format='free') == 'y = x**(-2.0d0)' # 2823 + assert fcode(x**Rational(3, 7)) == ' x**(3.0d0/7.0d0)' + + +def test_fcode_Rational(): + x = symbols('x') + assert fcode(Rational(3, 7)) == " 3.0d0/7.0d0" + assert fcode(Rational(18, 9)) == " 2" + assert fcode(Rational(3, -7)) == " -3.0d0/7.0d0" + assert fcode(Rational(-3, -7)) == " 3.0d0/7.0d0" + assert fcode(x + Rational(3, 7)) == " x + 3.0d0/7.0d0" + assert fcode(Rational(3, 7)*x) == " (3.0d0/7.0d0)*x" + + +def test_fcode_Integer(): + assert fcode(Integer(67)) == " 67" + assert fcode(Integer(-1)) == " -1" + + +def test_fcode_Float(): + assert fcode(Float(42.0)) == " 42.0000000000000d0" + assert fcode(Float(-1e20)) == " -1.00000000000000d+20" + + +def test_fcode_functions(): + x, y = symbols('x,y') + assert fcode(sin(x) ** cos(y)) == " sin(x)**cos(y)" + raises(NotImplementedError, lambda: fcode(Mod(x, y), standard=66)) + raises(NotImplementedError, lambda: fcode(x % y, standard=66)) + raises(NotImplementedError, lambda: fcode(Mod(x, y), standard=77)) + raises(NotImplementedError, lambda: fcode(x % y, standard=77)) + for standard in [90, 95, 2003, 2008]: + assert fcode(Mod(x, y), standard=standard) == " modulo(x, y)" + assert fcode(x % y, standard=standard) == " modulo(x, y)" + + +def test_case(): + ob = FCodePrinter() + x,x_,x__,y,X,X_,Y = symbols('x,x_,x__,y,X,X_,Y') + assert fcode(exp(x_) + sin(x*y) + cos(X*Y)) == \ + ' exp(x_) + sin(x*y) + cos(X__*Y_)' + assert fcode(exp(x__) + 2*x*Y*X_**Rational(7, 2)) == \ + ' 2*X_**(7.0d0/2.0d0)*Y*x + exp(x__)' + assert fcode(exp(x_) + sin(x*y) + cos(X*Y), name_mangling=False) == \ + ' exp(x_) + sin(x*y) + cos(X*Y)' + assert fcode(x - cos(X), name_mangling=False) == ' x - cos(X)' + assert ob.doprint(X*sin(x) + x_, assign_to='me') == ' me = X*sin(x_) + x__' + assert ob.doprint(X*sin(x), assign_to='mu') == ' mu = X*sin(x_)' + assert ob.doprint(x_, assign_to='ad') == ' ad = x__' + n, m = symbols('n,m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx('i', m) + I = Idx('I', n) + assert fcode(A[i, I]*x[I], assign_to=y[i], source_format='free') == ( + "do i = 1, m\n" + " y(i) = 0\n" + "end do\n" + "do i = 1, m\n" + " do I_ = 1, n\n" + " y(i) = A(i, I_)*x(I_) + y(i)\n" + " end do\n" + "end do" ) + + +#issue 6814 +def test_fcode_functions_with_integers(): + x= symbols('x') + log10_17 = log(10).evalf(17) + loglog10_17 = '0.8340324452479558d0' + assert fcode(x * log(10)) == " x*%sd0" % log10_17 + assert fcode(x * log(10)) == " x*%sd0" % log10_17 + assert fcode(x * log(S(10))) == " x*%sd0" % log10_17 + assert fcode(log(S(10))) == " %sd0" % log10_17 + assert fcode(exp(10)) == " %sd0" % exp(10).evalf(17) + assert fcode(x * log(log(10))) == " x*%s" % loglog10_17 + assert fcode(x * log(log(S(10)))) == " x*%s" % loglog10_17 + + +def test_fcode_NumberSymbol(): + prec = 17 + p = FCodePrinter() + assert fcode(Catalan) == ' parameter (Catalan = %sd0)\n Catalan' % Catalan.evalf(prec) + assert fcode(EulerGamma) == ' parameter (EulerGamma = %sd0)\n EulerGamma' % EulerGamma.evalf(prec) + assert fcode(E) == ' parameter (E = %sd0)\n E' % E.evalf(prec) + assert fcode(GoldenRatio) == ' parameter (GoldenRatio = %sd0)\n GoldenRatio' % GoldenRatio.evalf(prec) + assert fcode(pi) == ' parameter (pi = %sd0)\n pi' % pi.evalf(prec) + assert fcode( + pi, precision=5) == ' parameter (pi = %sd0)\n pi' % pi.evalf(5) + assert fcode(Catalan, human=False) == ({ + (Catalan, p._print(Catalan.evalf(prec)))}, set(), ' Catalan') + assert fcode(EulerGamma, human=False) == ({(EulerGamma, p._print( + EulerGamma.evalf(prec)))}, set(), ' EulerGamma') + assert fcode(E, human=False) == ( + {(E, p._print(E.evalf(prec)))}, set(), ' E') + assert fcode(GoldenRatio, human=False) == ({(GoldenRatio, p._print( + GoldenRatio.evalf(prec)))}, set(), ' GoldenRatio') + assert fcode(pi, human=False) == ( + {(pi, p._print(pi.evalf(prec)))}, set(), ' pi') + assert fcode(pi, precision=5, human=False) == ( + {(pi, p._print(pi.evalf(5)))}, set(), ' pi') + + +def test_fcode_complex(): + assert fcode(I) == " cmplx(0,1)" + x = symbols('x') + assert fcode(4*I) == " cmplx(0,4)" + assert fcode(3 + 4*I) == " cmplx(3,4)" + assert fcode(3 + 4*I + x) == " cmplx(3,4) + x" + assert fcode(I*x) == " cmplx(0,1)*x" + assert fcode(3 + 4*I - x) == " cmplx(3,4) - x" + x = symbols('x', imaginary=True) + assert fcode(5*x) == " 5*x" + assert fcode(I*x) == " cmplx(0,1)*x" + assert fcode(3 + x) == " x + 3" + + +def test_implicit(): + x, y = symbols('x,y') + assert fcode(sin(x)) == " sin(x)" + assert fcode(atan2(x, y)) == " atan2(x, y)" + assert fcode(conjugate(x)) == " conjg(x)" + + +def test_not_fortran(): + x = symbols('x') + g = Function('g') + with raises(NotImplementedError): + fcode(gamma(x)) + assert fcode(Integral(sin(x)), strict=False) == "C Not supported in Fortran:\nC Integral\n Integral(sin(x), x)" + with raises(NotImplementedError): + fcode(g(x)) + + +def test_user_functions(): + x = symbols('x') + assert fcode(sin(x), user_functions={"sin": "zsin"}) == " zsin(x)" + x = symbols('x') + assert fcode( + gamma(x), user_functions={"gamma": "mygamma"}) == " mygamma(x)" + g = Function('g') + assert fcode(g(x), user_functions={"g": "great"}) == " great(x)" + n = symbols('n', integer=True) + assert fcode( + factorial(n), user_functions={"factorial": "fct"}) == " fct(n)" + + +def test_inline_function(): + x = symbols('x') + g = implemented_function('g', Lambda(x, 2*x)) + assert fcode(g(x)) == " 2*x" + g = implemented_function('g', Lambda(x, 2*pi/x)) + assert fcode(g(x)) == ( + " parameter (pi = %sd0)\n" + " 2*pi/x" + ) % pi.evalf(17) + A = IndexedBase('A') + i = Idx('i', symbols('n', integer=True)) + g = implemented_function('g', Lambda(x, x*(1 + x)*(2 + x))) + assert fcode(g(A[i]), assign_to=A[i]) == ( + " do i = 1, n\n" + " A(i) = (A(i) + 1)*(A(i) + 2)*A(i)\n" + " end do" + ) + + +def test_assign_to(): + x = symbols('x') + assert fcode(sin(x), assign_to="s") == " s = sin(x)" + + +def test_line_wrapping(): + x, y = symbols('x,y') + assert fcode(((x + y)**10).expand(), assign_to="var") == ( + " var = x**10 + 10*x**9*y + 45*x**8*y**2 + 120*x**7*y**3 + 210*x**6*\n" + " @ y**4 + 252*x**5*y**5 + 210*x**4*y**6 + 120*x**3*y**7 + 45*x**2*y\n" + " @ **8 + 10*x*y**9 + y**10" + ) + e = [x**i for i in range(11)] + assert fcode(Add(*e)) == ( + " x**10 + x**9 + x**8 + x**7 + x**6 + x**5 + x**4 + x**3 + x**2 + x\n" + " @ + 1" + ) + + +def test_fcode_precedence(): + x, y = symbols("x y") + assert fcode(And(x < y, y < x + 1), source_format="free") == \ + "x < y .and. y < x + 1" + assert fcode(Or(x < y, y < x + 1), source_format="free") == \ + "x < y .or. y < x + 1" + assert fcode(Xor(x < y, y < x + 1, evaluate=False), + source_format="free") == "x < y .neqv. y < x + 1" + assert fcode(Equivalent(x < y, y < x + 1), source_format="free") == \ + "x < y .eqv. y < x + 1" + + +def test_fcode_Logical(): + x, y, z = symbols("x y z") + # unary Not + assert fcode(Not(x), source_format="free") == ".not. x" + # binary And + assert fcode(And(x, y), source_format="free") == "x .and. y" + assert fcode(And(x, Not(y)), source_format="free") == "x .and. .not. y" + assert fcode(And(Not(x), y), source_format="free") == "y .and. .not. x" + assert fcode(And(Not(x), Not(y)), source_format="free") == \ + ".not. x .and. .not. y" + assert fcode(Not(And(x, y), evaluate=False), source_format="free") == \ + ".not. (x .and. y)" + # binary Or + assert fcode(Or(x, y), source_format="free") == "x .or. y" + assert fcode(Or(x, Not(y)), source_format="free") == "x .or. .not. y" + assert fcode(Or(Not(x), y), source_format="free") == "y .or. .not. x" + assert fcode(Or(Not(x), Not(y)), source_format="free") == \ + ".not. x .or. .not. y" + assert fcode(Not(Or(x, y), evaluate=False), source_format="free") == \ + ".not. (x .or. y)" + # mixed And/Or + assert fcode(And(Or(y, z), x), source_format="free") == "x .and. (y .or. z)" + assert fcode(And(Or(z, x), y), source_format="free") == "y .and. (x .or. z)" + assert fcode(And(Or(x, y), z), source_format="free") == "z .and. (x .or. y)" + assert fcode(Or(And(y, z), x), source_format="free") == "x .or. y .and. z" + assert fcode(Or(And(z, x), y), source_format="free") == "y .or. x .and. z" + assert fcode(Or(And(x, y), z), source_format="free") == "z .or. x .and. y" + # trinary And + assert fcode(And(x, y, z), source_format="free") == "x .and. y .and. z" + assert fcode(And(x, y, Not(z)), source_format="free") == \ + "x .and. y .and. .not. z" + assert fcode(And(x, Not(y), z), source_format="free") == \ + "x .and. z .and. .not. y" + assert fcode(And(Not(x), y, z), source_format="free") == \ + "y .and. z .and. .not. x" + assert fcode(Not(And(x, y, z), evaluate=False), source_format="free") == \ + ".not. (x .and. y .and. z)" + # trinary Or + assert fcode(Or(x, y, z), source_format="free") == "x .or. y .or. z" + assert fcode(Or(x, y, Not(z)), source_format="free") == \ + "x .or. y .or. .not. z" + assert fcode(Or(x, Not(y), z), source_format="free") == \ + "x .or. z .or. .not. y" + assert fcode(Or(Not(x), y, z), source_format="free") == \ + "y .or. z .or. .not. x" + assert fcode(Not(Or(x, y, z), evaluate=False), source_format="free") == \ + ".not. (x .or. y .or. z)" + + +def test_fcode_Xlogical(): + x, y, z = symbols("x y z") + # binary Xor + assert fcode(Xor(x, y, evaluate=False), source_format="free") == \ + "x .neqv. y" + assert fcode(Xor(x, Not(y), evaluate=False), source_format="free") == \ + "x .neqv. .not. y" + assert fcode(Xor(Not(x), y, evaluate=False), source_format="free") == \ + "y .neqv. .not. x" + assert fcode(Xor(Not(x), Not(y), evaluate=False), + source_format="free") == ".not. x .neqv. .not. y" + assert fcode(Not(Xor(x, y, evaluate=False), evaluate=False), + source_format="free") == ".not. (x .neqv. y)" + # binary Equivalent + assert fcode(Equivalent(x, y), source_format="free") == "x .eqv. y" + assert fcode(Equivalent(x, Not(y)), source_format="free") == \ + "x .eqv. .not. y" + assert fcode(Equivalent(Not(x), y), source_format="free") == \ + "y .eqv. .not. x" + assert fcode(Equivalent(Not(x), Not(y)), source_format="free") == \ + ".not. x .eqv. .not. y" + assert fcode(Not(Equivalent(x, y), evaluate=False), + source_format="free") == ".not. (x .eqv. y)" + # mixed And/Equivalent + assert fcode(Equivalent(And(y, z), x), source_format="free") == \ + "x .eqv. y .and. z" + assert fcode(Equivalent(And(z, x), y), source_format="free") == \ + "y .eqv. x .and. z" + assert fcode(Equivalent(And(x, y), z), source_format="free") == \ + "z .eqv. x .and. y" + assert fcode(And(Equivalent(y, z), x), source_format="free") == \ + "x .and. (y .eqv. z)" + assert fcode(And(Equivalent(z, x), y), source_format="free") == \ + "y .and. (x .eqv. z)" + assert fcode(And(Equivalent(x, y), z), source_format="free") == \ + "z .and. (x .eqv. y)" + # mixed Or/Equivalent + assert fcode(Equivalent(Or(y, z), x), source_format="free") == \ + "x .eqv. y .or. z" + assert fcode(Equivalent(Or(z, x), y), source_format="free") == \ + "y .eqv. x .or. z" + assert fcode(Equivalent(Or(x, y), z), source_format="free") == \ + "z .eqv. x .or. y" + assert fcode(Or(Equivalent(y, z), x), source_format="free") == \ + "x .or. (y .eqv. z)" + assert fcode(Or(Equivalent(z, x), y), source_format="free") == \ + "y .or. (x .eqv. z)" + assert fcode(Or(Equivalent(x, y), z), source_format="free") == \ + "z .or. (x .eqv. y)" + # mixed Xor/Equivalent + assert fcode(Equivalent(Xor(y, z, evaluate=False), x), + source_format="free") == "x .eqv. (y .neqv. z)" + assert fcode(Equivalent(Xor(z, x, evaluate=False), y), + source_format="free") == "y .eqv. (x .neqv. z)" + assert fcode(Equivalent(Xor(x, y, evaluate=False), z), + source_format="free") == "z .eqv. (x .neqv. y)" + assert fcode(Xor(Equivalent(y, z), x, evaluate=False), + source_format="free") == "x .neqv. (y .eqv. z)" + assert fcode(Xor(Equivalent(z, x), y, evaluate=False), + source_format="free") == "y .neqv. (x .eqv. z)" + assert fcode(Xor(Equivalent(x, y), z, evaluate=False), + source_format="free") == "z .neqv. (x .eqv. y)" + # mixed And/Xor + assert fcode(Xor(And(y, z), x, evaluate=False), source_format="free") == \ + "x .neqv. y .and. z" + assert fcode(Xor(And(z, x), y, evaluate=False), source_format="free") == \ + "y .neqv. x .and. z" + assert fcode(Xor(And(x, y), z, evaluate=False), source_format="free") == \ + "z .neqv. x .and. y" + assert fcode(And(Xor(y, z, evaluate=False), x), source_format="free") == \ + "x .and. (y .neqv. z)" + assert fcode(And(Xor(z, x, evaluate=False), y), source_format="free") == \ + "y .and. (x .neqv. z)" + assert fcode(And(Xor(x, y, evaluate=False), z), source_format="free") == \ + "z .and. (x .neqv. y)" + # mixed Or/Xor + assert fcode(Xor(Or(y, z), x, evaluate=False), source_format="free") == \ + "x .neqv. y .or. z" + assert fcode(Xor(Or(z, x), y, evaluate=False), source_format="free") == \ + "y .neqv. x .or. z" + assert fcode(Xor(Or(x, y), z, evaluate=False), source_format="free") == \ + "z .neqv. x .or. y" + assert fcode(Or(Xor(y, z, evaluate=False), x), source_format="free") == \ + "x .or. (y .neqv. z)" + assert fcode(Or(Xor(z, x, evaluate=False), y), source_format="free") == \ + "y .or. (x .neqv. z)" + assert fcode(Or(Xor(x, y, evaluate=False), z), source_format="free") == \ + "z .or. (x .neqv. y)" + # trinary Xor + assert fcode(Xor(x, y, z, evaluate=False), source_format="free") == \ + "x .neqv. y .neqv. z" + assert fcode(Xor(x, y, Not(z), evaluate=False), source_format="free") == \ + "x .neqv. y .neqv. .not. z" + assert fcode(Xor(x, Not(y), z, evaluate=False), source_format="free") == \ + "x .neqv. z .neqv. .not. y" + assert fcode(Xor(Not(x), y, z, evaluate=False), source_format="free") == \ + "y .neqv. z .neqv. .not. x" + + +def test_fcode_Relational(): + x, y = symbols("x y") + assert fcode(Relational(x, y, "=="), source_format="free") == "x == y" + assert fcode(Relational(x, y, "!="), source_format="free") == "x /= y" + assert fcode(Relational(x, y, ">="), source_format="free") == "x >= y" + assert fcode(Relational(x, y, "<="), source_format="free") == "x <= y" + assert fcode(Relational(x, y, ">"), source_format="free") == "x > y" + assert fcode(Relational(x, y, "<"), source_format="free") == "x < y" + + +def test_fcode_Piecewise(): + x = symbols('x') + expr = Piecewise((x, x < 1), (x**2, True)) + # Check that inline conditional (merge) fails if standard isn't 95+ + raises(NotImplementedError, lambda: fcode(expr)) + code = fcode(expr, standard=95) + expected = " merge(x, x**2, x < 1)" + assert code == expected + assert fcode(Piecewise((x, x < 1), (x**2, True)), assign_to="var") == ( + " if (x < 1) then\n" + " var = x\n" + " else\n" + " var = x**2\n" + " end if" + ) + a = cos(x)/x + b = sin(x)/x + for i in range(10): + a = diff(a, x) + b = diff(b, x) + expected = ( + " if (x < 0) then\n" + " weird_name = -cos(x)/x + 10*sin(x)/x**2 + 90*cos(x)/x**3 - 720*\n" + " @ sin(x)/x**4 - 5040*cos(x)/x**5 + 30240*sin(x)/x**6 + 151200*cos(x\n" + " @ )/x**7 - 604800*sin(x)/x**8 - 1814400*cos(x)/x**9 + 3628800*sin(x\n" + " @ )/x**10 + 3628800*cos(x)/x**11\n" + " else\n" + " weird_name = -sin(x)/x - 10*cos(x)/x**2 + 90*sin(x)/x**3 + 720*\n" + " @ cos(x)/x**4 - 5040*sin(x)/x**5 - 30240*cos(x)/x**6 + 151200*sin(x\n" + " @ )/x**7 + 604800*cos(x)/x**8 - 1814400*sin(x)/x**9 - 3628800*cos(x\n" + " @ )/x**10 + 3628800*sin(x)/x**11\n" + " end if" + ) + code = fcode(Piecewise((a, x < 0), (b, True)), assign_to="weird_name") + assert code == expected + code = fcode(Piecewise((x, x < 1), (x**2, x > 1), (sin(x), True)), standard=95) + expected = " merge(x, merge(x**2, sin(x), x > 1), x < 1)" + assert code == expected + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) + raises(ValueError, lambda: fcode(expr)) + + +def test_wrap_fortran(): + # "########################################################################" + printer = FCodePrinter() + lines = [ + "C This is a long comment on a single line that must be wrapped properly to produce nice output", + " this = is + a + long + and + nasty + fortran + statement + that * must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that * must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that * must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that*must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that*must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that*must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that*must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement(that)/must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement(that)/must + be + wrapped + properly", + ] + wrapped_lines = printer._wrap_fortran(lines) + expected_lines = [ + "C This is a long comment on a single line that must be wrapped", + "C properly to produce nice output", + " this = is + a + long + and + nasty + fortran + statement + that *", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that *", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that", + " @ * must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that*", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that*", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that", + " @ *must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement +", + " @ that*must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that**", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that", + " @ **must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement + that", + " @ **must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement +", + " @ that**must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement(that)/", + " @ must + be + wrapped + properly", + " this = is + a + long + and + nasty + fortran + statement(that)", + " @ /must + be + wrapped + properly", + ] + for line in wrapped_lines: + assert len(line) <= 72 + for w, e in zip(wrapped_lines, expected_lines): + assert w == e + assert len(wrapped_lines) == len(expected_lines) + + +def test_wrap_fortran_keep_d0(): + printer = FCodePrinter() + lines = [ + ' this_variable_is_very_long_because_we_try_to_test_line_break=1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break =1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break = 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break = 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break = 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break = 10.0d0' + ] + expected = [ + ' this_variable_is_very_long_because_we_try_to_test_line_break=1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break =', + ' @ 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break =', + ' @ 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break =', + ' @ 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break =', + ' @ 1.0d0', + ' this_variable_is_very_long_because_we_try_to_test_line_break =', + ' @ 10.0d0' + ] + assert printer._wrap_fortran(lines) == expected + + +def test_settings(): + raises(TypeError, lambda: fcode(S(4), method="garbage")) + + +def test_free_form_code_line(): + x, y = symbols('x,y') + assert fcode(cos(x) + sin(y), source_format='free') == "sin(y) + cos(x)" + + +def test_free_form_continuation_line(): + x, y = symbols('x,y') + result = fcode(((cos(x) + sin(y))**(7)).expand(), source_format='free') + expected = ( + 'sin(y)**7 + 7*sin(y)**6*cos(x) + 21*sin(y)**5*cos(x)**2 + 35*sin(y)**4* &\n' + ' cos(x)**3 + 35*sin(y)**3*cos(x)**4 + 21*sin(y)**2*cos(x)**5 + 7* &\n' + ' sin(y)*cos(x)**6 + cos(x)**7' + ) + assert result == expected + + +def test_free_form_comment_line(): + printer = FCodePrinter({'source_format': 'free'}) + lines = [ "! This is a long comment on a single line that must be wrapped properly to produce nice output"] + expected = [ + '! This is a long comment on a single line that must be wrapped properly', + '! to produce nice output'] + assert printer._wrap_fortran(lines) == expected + + +def test_loops(): + n, m = symbols('n,m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + + expected = ( + 'do i = 1, m\n' + ' y(i) = 0\n' + 'end do\n' + 'do i = 1, m\n' + ' do j = 1, n\n' + ' y(i) = %(rhs)s\n' + ' end do\n' + 'end do' + ) + + code = fcode(A[i, j]*x[j], assign_to=y[i], source_format='free') + assert (code == expected % {'rhs': 'y(i) + A(i, j)*x(j)'} or + code == expected % {'rhs': 'y(i) + x(j)*A(i, j)'} or + code == expected % {'rhs': 'x(j)*A(i, j) + y(i)'} or + code == expected % {'rhs': 'A(i, j)*x(j) + y(i)'}) + + +def test_dummy_loops(): + i, m = symbols('i m', integer=True, cls=Dummy) + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx(i, m) + + expected = ( + 'do i_%(icount)i = 1, m_%(mcount)i\n' + ' y(i_%(icount)i) = x(i_%(icount)i)\n' + 'end do' + ) % {'icount': i.label.dummy_index, 'mcount': m.dummy_index} + code = fcode(x[i], assign_to=y[i], source_format='free') + assert code == expected + + +def test_fcode_Indexed_without_looking_for_contraction(): + len_y = 5 + y = IndexedBase('y', shape=(len_y,)) + x = IndexedBase('x', shape=(len_y,)) + Dy = IndexedBase('Dy', shape=(len_y-1,)) + i = Idx('i', len_y-1) + e=Eq(Dy[i], (y[i+1]-y[i])/(x[i+1]-x[i])) + code0 = fcode(e.rhs, assign_to=e.lhs, contract=False) + assert code0.endswith('Dy(i) = (y(i + 1) - y(i))/(x(i + 1) - x(i))') + + +def test_element_like_objects(): + len_y = 5 + y = ArraySymbol('y', shape=(len_y,)) + x = ArraySymbol('x', shape=(len_y,)) + Dy = ArraySymbol('Dy', shape=(len_y-1,)) + i = Idx('i', len_y-1) + e=Eq(Dy[i], (y[i+1]-y[i])/(x[i+1]-x[i])) + code0 = fcode(Assignment(e.lhs, e.rhs)) + assert code0.endswith('Dy(i) = (y(i + 1) - y(i))/(x(i + 1) - x(i))') + + class ElementExpr(Element, Expr): + pass + + e = e.subs((a, ElementExpr(a.name, a.indices)) for a in e.atoms(ArrayElement) ) + e=Eq(Dy[i], (y[i+1]-y[i])/(x[i+1]-x[i])) + code0 = fcode(Assignment(e.lhs, e.rhs)) + assert code0.endswith('Dy(i) = (y(i + 1) - y(i))/(x(i + 1) - x(i))') + + +def test_derived_classes(): + class MyFancyFCodePrinter(FCodePrinter): + _default_settings = FCodePrinter._default_settings.copy() + + printer = MyFancyFCodePrinter() + x = symbols('x') + assert printer.doprint(sin(x), "bork") == " bork = sin(x)" + + +def test_indent(): + codelines = ( + 'subroutine test(a)\n' + 'integer :: a, i, j\n' + '\n' + 'do\n' + 'do \n' + 'do j = 1, 5\n' + 'if (a>b) then\n' + 'if(b>0) then\n' + 'a = 3\n' + 'donot_indent_me = 2\n' + 'do_not_indent_me_either = 2\n' + 'ifIam_indented_something_went_wrong = 2\n' + 'if_I_am_indented_something_went_wrong = 2\n' + 'end should not be unindented here\n' + 'end if\n' + 'endif\n' + 'end do\n' + 'end do\n' + 'enddo\n' + 'end subroutine\n' + '\n' + 'subroutine test2(a)\n' + 'integer :: a\n' + 'do\n' + 'a = a + 1\n' + 'end do \n' + 'end subroutine\n' + ) + expected = ( + 'subroutine test(a)\n' + 'integer :: a, i, j\n' + '\n' + 'do\n' + ' do \n' + ' do j = 1, 5\n' + ' if (a>b) then\n' + ' if(b>0) then\n' + ' a = 3\n' + ' donot_indent_me = 2\n' + ' do_not_indent_me_either = 2\n' + ' ifIam_indented_something_went_wrong = 2\n' + ' if_I_am_indented_something_went_wrong = 2\n' + ' end should not be unindented here\n' + ' end if\n' + ' endif\n' + ' end do\n' + ' end do\n' + 'enddo\n' + 'end subroutine\n' + '\n' + 'subroutine test2(a)\n' + 'integer :: a\n' + 'do\n' + ' a = a + 1\n' + 'end do \n' + 'end subroutine\n' + ) + p = FCodePrinter({'source_format': 'free'}) + result = p.indent_code(codelines) + assert result == expected + +def test_Matrix_printing(): + x, y, z = symbols('x,y,z') + # Test returning a Matrix + mat = Matrix([x*y, Piecewise((2 + x, y>0), (y, True)), sin(z)]) + A = MatrixSymbol('A', 3, 1) + assert fcode(mat, A) == ( + " A(1, 1) = x*y\n" + " if (y > 0) then\n" + " A(2, 1) = x + 2\n" + " else\n" + " A(2, 1) = y\n" + " end if\n" + " A(3, 1) = sin(z)") + # Test using MatrixElements in expressions + expr = Piecewise((2*A[2, 0], x > 0), (A[2, 0], True)) + sin(A[1, 0]) + A[0, 0] + assert fcode(expr, standard=95) == ( + " merge(2*A(3, 1), A(3, 1), x > 0) + sin(A(2, 1)) + A(1, 1)") + # Test using MatrixElements in a Matrix + q = MatrixSymbol('q', 5, 1) + M = MatrixSymbol('M', 3, 3) + m = Matrix([[sin(q[1,0]), 0, cos(q[2,0])], + [q[1,0] + q[2,0], q[3, 0], 5], + [2*q[4, 0]/q[1,0], sqrt(q[0,0]) + 4, 0]]) + assert fcode(m, M) == ( + " M(1, 1) = sin(q(2, 1))\n" + " M(2, 1) = q(2, 1) + q(3, 1)\n" + " M(3, 1) = 2*q(5, 1)/q(2, 1)\n" + " M(1, 2) = 0\n" + " M(2, 2) = q(4, 1)\n" + " M(3, 2) = sqrt(q(1, 1)) + 4\n" + " M(1, 3) = cos(q(3, 1))\n" + " M(2, 3) = 5\n" + " M(3, 3) = 0") + + +def test_fcode_For(): + x, y = symbols('x y') + + f = For(x, Range(0, 10, 2), [Assignment(y, x * y)]) + sol = fcode(f) + assert sol == (" do x = 0, 9, 2\n" + " y = x*y\n" + " end do") + + +def test_fcode_Declaration(): + def check(expr, ref, **kwargs): + assert fcode(expr, standard=95, source_format='free', **kwargs) == ref + + i = symbols('i', integer=True) + var1 = Variable.deduced(i) + dcl1 = Declaration(var1) + check(dcl1, "integer*4 :: i") + + + x, y = symbols('x y') + var2 = Variable(x, float32, value=42, attrs={value_const}) + dcl2b = Declaration(var2) + check(dcl2b, 'real*4, parameter :: x = 42') + + var3 = Variable(y, type=bool_) + dcl3 = Declaration(var3) + check(dcl3, 'logical :: y') + + check(float32, "real*4") + check(float64, "real*8") + check(real, "real*4", type_aliases={real: float32}) + check(real, "real*8", type_aliases={real: float64}) + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert(fcode(A[0, 0]) == " A(1, 1)") + assert(fcode(3 * A[0, 0]) == " 3*A(1, 1)") + + F = C[0, 0].subs(C, A - B) + assert(fcode(F) == " (A - B)(1, 1)") + + +def test_aug_assign(): + x = symbols('x') + assert fcode(aug_assign(x, '+', 1), source_format='free') == 'x = x + 1' + + +def test_While(): + x = symbols('x') + assert fcode(While(abs(x) > 1, [aug_assign(x, '-', 1)]), source_format='free') == ( + 'do while (abs(x) > 1)\n' + ' x = x - 1\n' + 'end do' + ) + + +def test_FunctionPrototype_print(): + x = symbols('x') + n = symbols('n', integer=True) + vx = Variable(x, type=real) + vn = Variable(n, type=integer) + fp1 = FunctionPrototype(real, 'power', [vx, vn]) + # Should be changed to proper test once multi-line generation is working + # see https://github.com/sympy/sympy/issues/15824 + raises(NotImplementedError, lambda: fcode(fp1)) + + +def test_FunctionDefinition_print(): + x = symbols('x') + n = symbols('n', integer=True) + vx = Variable(x, type=real) + vn = Variable(n, type=integer) + body = [Assignment(x, x**n), Return(x)] + fd1 = FunctionDefinition(real, 'power', [vx, vn], body) + # Should be changed to proper test once multi-line generation is working + # see https://github.com/sympy/sympy/issues/15824 + raises(NotImplementedError, lambda: fcode(fd1)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_glsl.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_glsl.py new file mode 100644 index 0000000000000000000000000000000000000000..86ec1dfe4a37d141e8435c369cb692d3a9a3b7bc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_glsl.py @@ -0,0 +1,998 @@ +from sympy.core import (pi, symbols, Rational, Integer, GoldenRatio, EulerGamma, + Catalan, Lambda, Dummy, Eq, Ne, Le, Lt, Gt, Ge) +from sympy.functions import Piecewise, sin, cos, Abs, exp, ceiling, sqrt +from sympy.testing.pytest import raises, warns_deprecated_sympy +from sympy.printing.glsl import GLSLPrinter +from sympy.printing.str import StrPrinter +from sympy.utilities.lambdify import implemented_function +from sympy.tensor import IndexedBase, Idx +from sympy.matrices import Matrix, MatrixSymbol +from sympy.core import Tuple +from sympy.printing.glsl import glsl_code +import textwrap + +x, y, z = symbols('x,y,z') + + +def test_printmethod(): + assert glsl_code(Abs(x)) == "abs(x)" + +def test_print_without_operators(): + assert glsl_code(x*y,use_operators = False) == 'mul(x, y)' + assert glsl_code(x**y+z,use_operators = False) == 'add(pow(x, y), z)' + assert glsl_code(x*(y+z),use_operators = False) == 'mul(x, add(y, z))' + assert glsl_code(x*(y+z),use_operators = False) == 'mul(x, add(y, z))' + assert glsl_code(x*(y+z**y**0.5),use_operators = False) == 'mul(x, add(y, pow(z, sqrt(y))))' + assert glsl_code(-x-y, use_operators=False, zero='zero()') == 'sub(zero(), add(x, y))' + assert glsl_code(-x-y, use_operators=False) == 'sub(0.0, add(x, y))' + +def test_glsl_code_sqrt(): + assert glsl_code(sqrt(x)) == "sqrt(x)" + assert glsl_code(x**0.5) == "sqrt(x)" + assert glsl_code(sqrt(x)) == "sqrt(x)" + + +def test_glsl_code_Pow(): + g = implemented_function('g', Lambda(x, 2*x)) + assert glsl_code(x**3) == "pow(x, 3.0)" + assert glsl_code(x**(y**3)) == "pow(x, pow(y, 3.0))" + assert glsl_code(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "pow(3.5*2*x, -x + pow(y, x))/(pow(x, 2.0) + y)" + assert glsl_code(x**-1.0) == '1.0/x' + + +def test_glsl_code_Relational(): + assert glsl_code(Eq(x, y)) == "x == y" + assert glsl_code(Ne(x, y)) == "x != y" + assert glsl_code(Le(x, y)) == "x <= y" + assert glsl_code(Lt(x, y)) == "x < y" + assert glsl_code(Gt(x, y)) == "x > y" + assert glsl_code(Ge(x, y)) == "x >= y" + + +def test_glsl_code_constants_mathh(): + assert glsl_code(exp(1)) == "float E = 2.71828183;\nE" + assert glsl_code(pi) == "float pi = 3.14159265;\npi" + # assert glsl_code(oo) == "Number.POSITIVE_INFINITY" + # assert glsl_code(-oo) == "Number.NEGATIVE_INFINITY" + + +def test_glsl_code_constants_other(): + assert glsl_code(2*GoldenRatio) == "float GoldenRatio = 1.61803399;\n2*GoldenRatio" + assert glsl_code(2*Catalan) == "float Catalan = 0.915965594;\n2*Catalan" + assert glsl_code(2*EulerGamma) == "float EulerGamma = 0.577215665;\n2*EulerGamma" + + +def test_glsl_code_Rational(): + assert glsl_code(Rational(3, 7)) == "3.0/7.0" + assert glsl_code(Rational(18, 9)) == "2" + assert glsl_code(Rational(3, -7)) == "-3.0/7.0" + assert glsl_code(Rational(-3, -7)) == "3.0/7.0" + + +def test_glsl_code_Integer(): + assert glsl_code(Integer(67)) == "67" + assert glsl_code(Integer(-1)) == "-1" + + +def test_glsl_code_functions(): + assert glsl_code(sin(x) ** cos(x)) == "pow(sin(x), cos(x))" + + +def test_glsl_code_inline_function(): + x = symbols('x') + g = implemented_function('g', Lambda(x, 2*x)) + assert glsl_code(g(x)) == "2*x" + g = implemented_function('g', Lambda(x, 2*x/Catalan)) + assert glsl_code(g(x)) == "float Catalan = 0.915965594;\n2*x/Catalan" + A = IndexedBase('A') + i = Idx('i', symbols('n', integer=True)) + g = implemented_function('g', Lambda(x, x*(1 + x)*(2 + x))) + assert glsl_code(g(A[i]), assign_to=A[i]) == ( + "for (int i=0; i 1), (sin(x), x > 0)) + raises(ValueError, lambda: glsl_code(expr)) + + +def test_glsl_code_Piecewise_deep(): + p = glsl_code(2*Piecewise((x, x < 1), (x**2, True))) + s = \ +"""\ +2*((x < 1) ? ( + x +) +: ( + pow(x, 2.0) +))\ +""" + assert p == s + + +def test_glsl_code_settings(): + raises(TypeError, lambda: glsl_code(sin(x), method="garbage")) + + +def test_glsl_code_Indexed(): + n, m, o = symbols('n m o', integer=True) + i, j, k = Idx('i', n), Idx('j', m), Idx('k', o) + p = GLSLPrinter() + p._not_c = set() + + x = IndexedBase('x')[j] + assert p._print_Indexed(x) == 'x[j]' + A = IndexedBase('A')[i, j] + assert p._print_Indexed(A) == 'A[%s]' % (m*i+j) + B = IndexedBase('B')[i, j, k] + assert p._print_Indexed(B) == 'B[%s]' % (i*o*m+j*o+k) + + assert p._not_c == set() + +def test_glsl_code_list_tuple_Tuple(): + assert glsl_code([1,2,3,4]) == 'vec4(1, 2, 3, 4)' + assert glsl_code([1,2,3],glsl_types=False) == 'float[3](1, 2, 3)' + assert glsl_code([1,2,3]) == glsl_code((1,2,3)) + assert glsl_code([1,2,3]) == glsl_code(Tuple(1,2,3)) + + m = MatrixSymbol('A',3,4) + assert glsl_code([m[0],m[1]]) + +def test_glsl_code_loops_matrix_vector(): + n, m = symbols('n m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + + s = ( + 'for (int i=0; i0), (y, True)), sin(z)]) + A = MatrixSymbol('A', 3, 1) + assert glsl_code(mat, assign_to=A) == ( +'''A[0][0] = x*y; +if (y > 0) { + A[1][0] = x + 2; +} +else { + A[1][0] = y; +} +A[2][0] = sin(z);''' ) + assert glsl_code(Matrix([A[0],A[1]])) + # Test using MatrixElements in expressions + expr = Piecewise((2*A[2, 0], x > 0), (A[2, 0], True)) + sin(A[1, 0]) + A[0, 0] + assert glsl_code(expr) == ( +'''((x > 0) ? ( + 2*A[2][0] +) +: ( + A[2][0] +)) + sin(A[1][0]) + A[0][0]''' ) + + # Test using MatrixElements in a Matrix + q = MatrixSymbol('q', 5, 1) + M = MatrixSymbol('M', 3, 3) + m = Matrix([[sin(q[1,0]), 0, cos(q[2,0])], + [q[1,0] + q[2,0], q[3, 0], 5], + [2*q[4, 0]/q[1,0], sqrt(q[0,0]) + 4, 0]]) + assert glsl_code(m,M) == ( +'''M[0][0] = sin(q[1]); +M[0][1] = 0; +M[0][2] = cos(q[2]); +M[1][0] = q[1] + q[2]; +M[1][1] = q[3]; +M[1][2] = 5; +M[2][0] = 2*q[4]/q[1]; +M[2][1] = sqrt(q[0]) + 4; +M[2][2] = 0;''' + ) + +def test_Matrices_1x7(): + gl = glsl_code + A = Matrix([1,2,3,4,5,6,7]) + assert gl(A) == 'float[7](1, 2, 3, 4, 5, 6, 7)' + assert gl(A.transpose()) == 'float[7](1, 2, 3, 4, 5, 6, 7)' + +def test_Matrices_1x7_array_type_int(): + gl = glsl_code + A = Matrix([1,2,3,4,5,6,7]) + assert gl(A, array_type='int') == 'int[7](1, 2, 3, 4, 5, 6, 7)' + +def test_Tuple_array_type_custom(): + gl = glsl_code + A = symbols('a b c') + assert gl(A, array_type='AbcType', glsl_types=False) == 'AbcType[3](a, b, c)' + +def test_Matrices_1x7_spread_assign_to_symbols(): + gl = glsl_code + A = Matrix([1,2,3,4,5,6,7]) + assign_to = symbols('x.a x.b x.c x.d x.e x.f x.g') + assert gl(A, assign_to=assign_to) == textwrap.dedent('''\ + x.a = 1; + x.b = 2; + x.c = 3; + x.d = 4; + x.e = 5; + x.f = 6; + x.g = 7;''' + ) + +def test_spread_assign_to_nested_symbols(): + gl = glsl_code + expr = ((1,2,3), (1,2,3)) + assign_to = (symbols('a b c'), symbols('x y z')) + assert gl(expr, assign_to=assign_to) == textwrap.dedent('''\ + a = 1; + b = 2; + c = 3; + x = 1; + y = 2; + z = 3;''' + ) + +def test_spread_assign_to_deeply_nested_symbols(): + gl = glsl_code + a, b, c, x, y, z = symbols('a b c x y z') + expr = (((1,2),3), ((1,2),3)) + assign_to = (((a, b), c), ((x, y), z)) + assert gl(expr, assign_to=assign_to) == textwrap.dedent('''\ + a = 1; + b = 2; + c = 3; + x = 1; + y = 2; + z = 3;''' + ) + +def test_matrix_of_tuples_spread_assign_to_symbols(): + gl = glsl_code + with warns_deprecated_sympy(): + expr = Matrix([[(1,2),(3,4)],[(5,6),(7,8)]]) + assign_to = (symbols('a b'), symbols('c d'), symbols('e f'), symbols('g h')) + assert gl(expr, assign_to) == textwrap.dedent('''\ + a = 1; + b = 2; + c = 3; + d = 4; + e = 5; + f = 6; + g = 7; + h = 8;''' + ) + +def test_cannot_assign_to_cause_mismatched_length(): + expr = (1, 2) + assign_to = symbols('x y z') + raises(ValueError, lambda: glsl_code(expr, assign_to)) + +def test_matrix_4x4_assign(): + gl = glsl_code + expr = MatrixSymbol('A',4,4) * MatrixSymbol('B',4,4) + MatrixSymbol('C',4,4) + assign_to = MatrixSymbol('X',4,4) + assert gl(expr, assign_to=assign_to) == textwrap.dedent('''\ + X[0][0] = A[0][0]*B[0][0] + A[0][1]*B[1][0] + A[0][2]*B[2][0] + A[0][3]*B[3][0] + C[0][0]; + X[0][1] = A[0][0]*B[0][1] + A[0][1]*B[1][1] + A[0][2]*B[2][1] + A[0][3]*B[3][1] + C[0][1]; + X[0][2] = A[0][0]*B[0][2] + A[0][1]*B[1][2] + A[0][2]*B[2][2] + A[0][3]*B[3][2] + C[0][2]; + X[0][3] = A[0][0]*B[0][3] + A[0][1]*B[1][3] + A[0][2]*B[2][3] + A[0][3]*B[3][3] + C[0][3]; + X[1][0] = A[1][0]*B[0][0] + A[1][1]*B[1][0] + A[1][2]*B[2][0] + A[1][3]*B[3][0] + C[1][0]; + X[1][1] = A[1][0]*B[0][1] + A[1][1]*B[1][1] + A[1][2]*B[2][1] + A[1][3]*B[3][1] + C[1][1]; + X[1][2] = A[1][0]*B[0][2] + A[1][1]*B[1][2] + A[1][2]*B[2][2] + A[1][3]*B[3][2] + C[1][2]; + X[1][3] = A[1][0]*B[0][3] + A[1][1]*B[1][3] + A[1][2]*B[2][3] + A[1][3]*B[3][3] + C[1][3]; + X[2][0] = A[2][0]*B[0][0] + A[2][1]*B[1][0] + A[2][2]*B[2][0] + A[2][3]*B[3][0] + C[2][0]; + X[2][1] = A[2][0]*B[0][1] + A[2][1]*B[1][1] + A[2][2]*B[2][1] + A[2][3]*B[3][1] + C[2][1]; + X[2][2] = A[2][0]*B[0][2] + A[2][1]*B[1][2] + A[2][2]*B[2][2] + A[2][3]*B[3][2] + C[2][2]; + X[2][3] = A[2][0]*B[0][3] + A[2][1]*B[1][3] + A[2][2]*B[2][3] + A[2][3]*B[3][3] + C[2][3]; + X[3][0] = A[3][0]*B[0][0] + A[3][1]*B[1][0] + A[3][2]*B[2][0] + A[3][3]*B[3][0] + C[3][0]; + X[3][1] = A[3][0]*B[0][1] + A[3][1]*B[1][1] + A[3][2]*B[2][1] + A[3][3]*B[3][1] + C[3][1]; + X[3][2] = A[3][0]*B[0][2] + A[3][1]*B[1][2] + A[3][2]*B[2][2] + A[3][3]*B[3][2] + C[3][2]; + X[3][3] = A[3][0]*B[0][3] + A[3][1]*B[1][3] + A[3][2]*B[2][3] + A[3][3]*B[3][3] + C[3][3];''' + ) + +def test_1xN_vecs(): + gl = glsl_code + for i in range(1,10): + A = Matrix(range(i)) + assert gl(A.transpose()) == gl(A) + assert gl(A,mat_transpose=True) == gl(A) + if i > 1: + if i <= 4: + assert gl(A) == 'vec%s(%s)' % (i,', '.join(str(s) for s in range(i))) + else: + assert gl(A) == 'float[%s](%s)' % (i,', '.join(str(s) for s in range(i))) + +def test_MxN_mats(): + generatedAssertions='def test_misc_mats():\n' + for i in range(1,6): + for j in range(1,6): + A = Matrix([[x + y*j for x in range(j)] for y in range(i)]) + gl = glsl_code(A) + glTransposed = glsl_code(A,mat_transpose=True) + generatedAssertions+=' mat = '+StrPrinter()._print(A)+'\n\n' + generatedAssertions+=' gl = \'\'\''+gl+'\'\'\'\n' + generatedAssertions+=' glTransposed = \'\'\''+glTransposed+'\'\'\'\n\n' + generatedAssertions+=' assert glsl_code(mat) == gl\n' + generatedAssertions+=' assert glsl_code(mat,mat_transpose=True) == glTransposed\n' + if i == 1 and j == 1: + assert gl == '0' + elif i <= 4 and j <= 4 and i>1 and j>1: + assert gl.startswith('mat%s' % j) + assert glTransposed.startswith('mat%s' % i) + elif i == 1 and j <= 4: + assert gl.startswith('vec') + elif j == 1 and i <= 4: + assert gl.startswith('vec') + elif i == 1: + assert gl.startswith('float[%s]('% j*i) + assert glTransposed.startswith('float[%s]('% j*i) + elif j == 1: + assert gl.startswith('float[%s]('% i*j) + assert glTransposed.startswith('float[%s]('% i*j) + else: + assert gl.startswith('float[%s](' % (i*j)) + assert glTransposed.startswith('float[%s](' % (i*j)) + glNested = glsl_code(A,mat_nested=True) + glNestedTransposed = glsl_code(A,mat_transpose=True,mat_nested=True) + assert glNested.startswith('float[%s][%s]' % (i,j)) + assert glNestedTransposed.startswith('float[%s][%s]' % (j,i)) + generatedAssertions+=' glNested = \'\'\''+glNested+'\'\'\'\n' + generatedAssertions+=' glNestedTransposed = \'\'\''+glNestedTransposed+'\'\'\'\n\n' + generatedAssertions+=' assert glsl_code(mat,mat_nested=True) == glNested\n' + generatedAssertions+=' assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed\n\n' + generateAssertions = False # set this to true to write bake these generated tests to a file + if generateAssertions: + gen = open('test_glsl_generated_matrices.py','w') + gen.write(generatedAssertions) + gen.close() + + +# these assertions were generated from the previous function +# glsl has complicated rules and this makes it easier to look over all the cases +def test_misc_mats(): + + mat = Matrix([[0]]) + + gl = '''0''' + glTransposed = '''0''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([[0, 1]]) + + gl = '''vec2(0, 1)''' + glTransposed = '''vec2(0, 1)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([[0, 1, 2]]) + + gl = '''vec3(0, 1, 2)''' + glTransposed = '''vec3(0, 1, 2)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([[0, 1, 2, 3]]) + + gl = '''vec4(0, 1, 2, 3)''' + glTransposed = '''vec4(0, 1, 2, 3)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([[0, 1, 2, 3, 4]]) + + gl = '''float[5](0, 1, 2, 3, 4)''' + glTransposed = '''float[5](0, 1, 2, 3, 4)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0], +[1]]) + + gl = '''vec2(0, 1)''' + glTransposed = '''vec2(0, 1)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1], +[2, 3]]) + + gl = '''mat2(0, 1, 2, 3)''' + glTransposed = '''mat2(0, 2, 1, 3)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1, 2], +[3, 4, 5]]) + + gl = '''mat3x2(0, 1, 2, 3, 4, 5)''' + glTransposed = '''mat2x3(0, 3, 1, 4, 2, 5)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1, 2, 3], +[4, 5, 6, 7]]) + + gl = '''mat4x2(0, 1, 2, 3, 4, 5, 6, 7)''' + glTransposed = '''mat2x4(0, 4, 1, 5, 2, 6, 3, 7)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1, 2, 3, 4], +[5, 6, 7, 8, 9]]) + + gl = '''float[10]( + 0, 1, 2, 3, 4, + 5, 6, 7, 8, 9 +) /* a 2x5 matrix */''' + glTransposed = '''float[10]( + 0, 5, + 1, 6, + 2, 7, + 3, 8, + 4, 9 +) /* a 5x2 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[2][5]( + float[](0, 1, 2, 3, 4), + float[](5, 6, 7, 8, 9) +)''' + glNestedTransposed = '''float[5][2]( + float[](0, 5), + float[](1, 6), + float[](2, 7), + float[](3, 8), + float[](4, 9) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed + + mat = Matrix([ +[0], +[1], +[2]]) + + gl = '''vec3(0, 1, 2)''' + glTransposed = '''vec3(0, 1, 2)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1], +[2, 3], +[4, 5]]) + + gl = '''mat2x3(0, 1, 2, 3, 4, 5)''' + glTransposed = '''mat3x2(0, 2, 4, 1, 3, 5)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1, 2], +[3, 4, 5], +[6, 7, 8]]) + + gl = '''mat3(0, 1, 2, 3, 4, 5, 6, 7, 8)''' + glTransposed = '''mat3(0, 3, 6, 1, 4, 7, 2, 5, 8)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1, 2, 3], +[4, 5, 6, 7], +[8, 9, 10, 11]]) + + gl = '''mat4x3(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11)''' + glTransposed = '''mat3x4(0, 4, 8, 1, 5, 9, 2, 6, 10, 3, 7, 11)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[ 0, 1, 2, 3, 4], +[ 5, 6, 7, 8, 9], +[10, 11, 12, 13, 14]]) + + gl = '''float[15]( + 0, 1, 2, 3, 4, + 5, 6, 7, 8, 9, + 10, 11, 12, 13, 14 +) /* a 3x5 matrix */''' + glTransposed = '''float[15]( + 0, 5, 10, + 1, 6, 11, + 2, 7, 12, + 3, 8, 13, + 4, 9, 14 +) /* a 5x3 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[3][5]( + float[]( 0, 1, 2, 3, 4), + float[]( 5, 6, 7, 8, 9), + float[](10, 11, 12, 13, 14) +)''' + glNestedTransposed = '''float[5][3]( + float[](0, 5, 10), + float[](1, 6, 11), + float[](2, 7, 12), + float[](3, 8, 13), + float[](4, 9, 14) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed + + mat = Matrix([ +[0], +[1], +[2], +[3]]) + + gl = '''vec4(0, 1, 2, 3)''' + glTransposed = '''vec4(0, 1, 2, 3)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1], +[2, 3], +[4, 5], +[6, 7]]) + + gl = '''mat2x4(0, 1, 2, 3, 4, 5, 6, 7)''' + glTransposed = '''mat4x2(0, 2, 4, 6, 1, 3, 5, 7)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1, 2], +[3, 4, 5], +[6, 7, 8], +[9, 10, 11]]) + + gl = '''mat3x4(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11)''' + glTransposed = '''mat4x3(0, 3, 6, 9, 1, 4, 7, 10, 2, 5, 8, 11)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[ 0, 1, 2, 3], +[ 4, 5, 6, 7], +[ 8, 9, 10, 11], +[12, 13, 14, 15]]) + + gl = '''mat4( 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15)''' + glTransposed = '''mat4(0, 4, 8, 12, 1, 5, 9, 13, 2, 6, 10, 14, 3, 7, 11, 15)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[ 0, 1, 2, 3, 4], +[ 5, 6, 7, 8, 9], +[10, 11, 12, 13, 14], +[15, 16, 17, 18, 19]]) + + gl = '''float[20]( + 0, 1, 2, 3, 4, + 5, 6, 7, 8, 9, + 10, 11, 12, 13, 14, + 15, 16, 17, 18, 19 +) /* a 4x5 matrix */''' + glTransposed = '''float[20]( + 0, 5, 10, 15, + 1, 6, 11, 16, + 2, 7, 12, 17, + 3, 8, 13, 18, + 4, 9, 14, 19 +) /* a 5x4 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[4][5]( + float[]( 0, 1, 2, 3, 4), + float[]( 5, 6, 7, 8, 9), + float[](10, 11, 12, 13, 14), + float[](15, 16, 17, 18, 19) +)''' + glNestedTransposed = '''float[5][4]( + float[](0, 5, 10, 15), + float[](1, 6, 11, 16), + float[](2, 7, 12, 17), + float[](3, 8, 13, 18), + float[](4, 9, 14, 19) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed + + mat = Matrix([ +[0], +[1], +[2], +[3], +[4]]) + + gl = '''float[5](0, 1, 2, 3, 4)''' + glTransposed = '''float[5](0, 1, 2, 3, 4)''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + + mat = Matrix([ +[0, 1], +[2, 3], +[4, 5], +[6, 7], +[8, 9]]) + + gl = '''float[10]( + 0, 1, + 2, 3, + 4, 5, + 6, 7, + 8, 9 +) /* a 5x2 matrix */''' + glTransposed = '''float[10]( + 0, 2, 4, 6, 8, + 1, 3, 5, 7, 9 +) /* a 2x5 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[5][2]( + float[](0, 1), + float[](2, 3), + float[](4, 5), + float[](6, 7), + float[](8, 9) +)''' + glNestedTransposed = '''float[2][5]( + float[](0, 2, 4, 6, 8), + float[](1, 3, 5, 7, 9) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed + + mat = Matrix([ +[ 0, 1, 2], +[ 3, 4, 5], +[ 6, 7, 8], +[ 9, 10, 11], +[12, 13, 14]]) + + gl = '''float[15]( + 0, 1, 2, + 3, 4, 5, + 6, 7, 8, + 9, 10, 11, + 12, 13, 14 +) /* a 5x3 matrix */''' + glTransposed = '''float[15]( + 0, 3, 6, 9, 12, + 1, 4, 7, 10, 13, + 2, 5, 8, 11, 14 +) /* a 3x5 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[5][3]( + float[]( 0, 1, 2), + float[]( 3, 4, 5), + float[]( 6, 7, 8), + float[]( 9, 10, 11), + float[](12, 13, 14) +)''' + glNestedTransposed = '''float[3][5]( + float[](0, 3, 6, 9, 12), + float[](1, 4, 7, 10, 13), + float[](2, 5, 8, 11, 14) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed + + mat = Matrix([ +[ 0, 1, 2, 3], +[ 4, 5, 6, 7], +[ 8, 9, 10, 11], +[12, 13, 14, 15], +[16, 17, 18, 19]]) + + gl = '''float[20]( + 0, 1, 2, 3, + 4, 5, 6, 7, + 8, 9, 10, 11, + 12, 13, 14, 15, + 16, 17, 18, 19 +) /* a 5x4 matrix */''' + glTransposed = '''float[20]( + 0, 4, 8, 12, 16, + 1, 5, 9, 13, 17, + 2, 6, 10, 14, 18, + 3, 7, 11, 15, 19 +) /* a 4x5 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[5][4]( + float[]( 0, 1, 2, 3), + float[]( 4, 5, 6, 7), + float[]( 8, 9, 10, 11), + float[](12, 13, 14, 15), + float[](16, 17, 18, 19) +)''' + glNestedTransposed = '''float[4][5]( + float[](0, 4, 8, 12, 16), + float[](1, 5, 9, 13, 17), + float[](2, 6, 10, 14, 18), + float[](3, 7, 11, 15, 19) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed + + mat = Matrix([ +[ 0, 1, 2, 3, 4], +[ 5, 6, 7, 8, 9], +[10, 11, 12, 13, 14], +[15, 16, 17, 18, 19], +[20, 21, 22, 23, 24]]) + + gl = '''float[25]( + 0, 1, 2, 3, 4, + 5, 6, 7, 8, 9, + 10, 11, 12, 13, 14, + 15, 16, 17, 18, 19, + 20, 21, 22, 23, 24 +) /* a 5x5 matrix */''' + glTransposed = '''float[25]( + 0, 5, 10, 15, 20, + 1, 6, 11, 16, 21, + 2, 7, 12, 17, 22, + 3, 8, 13, 18, 23, + 4, 9, 14, 19, 24 +) /* a 5x5 matrix */''' + + assert glsl_code(mat) == gl + assert glsl_code(mat,mat_transpose=True) == glTransposed + glNested = '''float[5][5]( + float[]( 0, 1, 2, 3, 4), + float[]( 5, 6, 7, 8, 9), + float[](10, 11, 12, 13, 14), + float[](15, 16, 17, 18, 19), + float[](20, 21, 22, 23, 24) +)''' + glNestedTransposed = '''float[5][5]( + float[](0, 5, 10, 15, 20), + float[](1, 6, 11, 16, 21), + float[](2, 7, 12, 17, 22), + float[](3, 8, 13, 18, 23), + float[](4, 9, 14, 19, 24) +)''' + + assert glsl_code(mat,mat_nested=True) == glNested + assert glsl_code(mat,mat_nested=True,mat_transpose=True) == glNestedTransposed diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_gtk.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_gtk.py new file mode 100644 index 0000000000000000000000000000000000000000..5a595ab04d3a29d23e06ec12207bf917392aebce --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_gtk.py @@ -0,0 +1,18 @@ +from sympy.functions.elementary.trigonometric import sin +from sympy.printing.gtk import print_gtk +from sympy.testing.pytest import XFAIL, raises + +# this test fails if python-lxml isn't installed. We don't want to depend on +# anything with SymPy + + +@XFAIL +def test_1(): + from sympy.abc import x + print_gtk(x**2, start_viewer=False) + print_gtk(x**2 + sin(x)/4, start_viewer=False) + + +def test_settings(): + from sympy.abc import x + raises(TypeError, lambda: print_gtk(x, method="garbage")) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_jax.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_jax.py new file mode 100644 index 0000000000000000000000000000000000000000..365d87c5b91fdd49a8e46cfde9c2b5792c23a03c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_jax.py @@ -0,0 +1,370 @@ +from sympy.concrete.summations import Sum +from sympy.core.mod import Mod +from sympy.core.relational import (Equality, Unequality) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.piecewise import Piecewise +from sympy.matrices.expressions.blockmatrix import BlockMatrix +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.matrices.expressions.special import Identity +from sympy.utilities.lambdify import lambdify + +from sympy.abc import x, i, j, a, b, c, d +from sympy.core import Function, Pow, Symbol +from sympy.codegen.matrix_nodes import MatrixSolve +from sympy.codegen.numpy_nodes import logaddexp, logaddexp2 +from sympy.codegen.cfunctions import log1p, expm1, hypot, log10, exp2, log2, Sqrt +from sympy.tensor.array import Array +from sympy.tensor.array.expressions.array_expressions import ArrayTensorProduct, ArrayAdd, \ + PermuteDims, ArrayDiagonal +from sympy.printing.numpy import JaxPrinter, _jax_known_constants, _jax_known_functions +from sympy.tensor.array.expressions.from_matrix_to_array import convert_matrix_to_array + +from sympy.testing.pytest import skip, raises +from sympy.external import import_module + +# Unlike NumPy which will aggressively promote operands to double precision, +# jax always uses single precision. Double precision in jax can be +# configured before the call to `import jax`, however this must be explicitly +# configured and is not fully supported. Thus, the tests here have been modified +# from the tests in test_numpy.py, only in the fact that they assert lambdify +# function accuracy to only single precision accuracy. +# https://jax.readthedocs.io/en/latest/notebooks/Common_Gotchas_in_JAX.html#double-64bit-precision + +jax = import_module('jax') + +if jax: + deafult_float_info = jax.numpy.finfo(jax.numpy.array([]).dtype) + JAX_DEFAULT_EPSILON = deafult_float_info.eps + + +def test_jax_piecewise_regression(): + """ + NumPyPrinter needs to print Piecewise()'s choicelist as a list to avoid + breaking compatibility with numpy 1.8. This is not necessary in numpy 1.9+. + See gh-9747 and gh-9749 for details. + """ + printer = JaxPrinter() + p = Piecewise((1, x < 0), (0, True)) + assert printer.doprint(p) == \ + 'jax.numpy.select([jax.numpy.less(x, 0),True], [1,0], default=jax.numpy.nan)' + assert printer.module_imports == {'jax.numpy': {'select', 'less', 'nan'}} + + +def test_jax_logaddexp(): + lae = logaddexp(a, b) + assert JaxPrinter().doprint(lae) == 'jax.numpy.logaddexp(a, b)' + lae2 = logaddexp2(a, b) + assert JaxPrinter().doprint(lae2) == 'jax.numpy.logaddexp2(a, b)' + + +def test_jax_sum(): + if not jax: + skip("JAX not installed") + + s = Sum(x ** i, (i, a, b)) + f = lambdify((a, b, x), s, 'jax') + + a_, b_ = 0, 10 + x_ = jax.numpy.linspace(-1, +1, 10) + assert jax.numpy.allclose(f(a_, b_, x_), sum(x_ ** i_ for i_ in range(a_, b_ + 1))) + + s = Sum(i * x, (i, a, b)) + f = lambdify((a, b, x), s, 'jax') + + a_, b_ = 0, 10 + x_ = jax.numpy.linspace(-1, +1, 10) + assert jax.numpy.allclose(f(a_, b_, x_), sum(i_ * x_ for i_ in range(a_, b_ + 1))) + + +def test_jax_multiple_sums(): + if not jax: + skip("JAX not installed") + + s = Sum((x + j) * i, (i, a, b), (j, c, d)) + f = lambdify((a, b, c, d, x), s, 'jax') + + a_, b_ = 0, 10 + c_, d_ = 11, 21 + x_ = jax.numpy.linspace(-1, +1, 10) + assert jax.numpy.allclose(f(a_, b_, c_, d_, x_), + sum((x_ + j_) * i_ for i_ in range(a_, b_ + 1) for j_ in range(c_, d_ + 1))) + + +def test_jax_codegen_einsum(): + if not jax: + skip("JAX not installed") + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + + cg = convert_matrix_to_array(M * N) + f = lambdify((M, N), cg, 'jax') + + ma = jax.numpy.array([[1, 2], [3, 4]]) + mb = jax.numpy.array([[1,-2], [-1, 3]]) + assert (f(ma, mb) == jax.numpy.matmul(ma, mb)).all() + + +def test_jax_codegen_extra(): + if not jax: + skip("JAX not installed") + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + P = MatrixSymbol("P", 2, 2) + Q = MatrixSymbol("Q", 2, 2) + ma = jax.numpy.array([[1, 2], [3, 4]]) + mb = jax.numpy.array([[1,-2], [-1, 3]]) + mc = jax.numpy.array([[2, 0], [1, 2]]) + md = jax.numpy.array([[1,-1], [4, 7]]) + + cg = ArrayTensorProduct(M, N) + f = lambdify((M, N), cg, 'jax') + assert (f(ma, mb) == jax.numpy.einsum(ma, [0, 1], mb, [2, 3])).all() + + cg = ArrayAdd(M, N) + f = lambdify((M, N), cg, 'jax') + assert (f(ma, mb) == ma+mb).all() + + cg = ArrayAdd(M, N, P) + f = lambdify((M, N, P), cg, 'jax') + assert (f(ma, mb, mc) == ma+mb+mc).all() + + cg = ArrayAdd(M, N, P, Q) + f = lambdify((M, N, P, Q), cg, 'jax') + assert (f(ma, mb, mc, md) == ma+mb+mc+md).all() + + cg = PermuteDims(M, [1, 0]) + f = lambdify((M,), cg, 'jax') + assert (f(ma) == ma.T).all() + + cg = PermuteDims(ArrayTensorProduct(M, N), [1, 2, 3, 0]) + f = lambdify((M, N), cg, 'jax') + assert (f(ma, mb) == jax.numpy.transpose(jax.numpy.einsum(ma, [0, 1], mb, [2, 3]), (1, 2, 3, 0))).all() + + cg = ArrayDiagonal(ArrayTensorProduct(M, N), (1, 2)) + f = lambdify((M, N), cg, 'jax') + assert (f(ma, mb) == jax.numpy.diagonal(jax.numpy.einsum(ma, [0, 1], mb, [2, 3]), axis1=1, axis2=2)).all() + + +def test_jax_relational(): + if not jax: + skip("JAX not installed") + + e = Equality(x, 1) + + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [False, True, False]) + + e = Unequality(x, 1) + + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [True, False, True]) + + e = (x < 1) + + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [True, False, False]) + + e = (x <= 1) + + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [True, True, False]) + + e = (x > 1) + + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [False, False, True]) + + e = (x >= 1) + + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [False, True, True]) + + # Multi-condition expressions + e = (x >= 1) & (x < 2) + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [False, True, False]) + + e = (x >= 1) | (x < 2) + f = lambdify((x,), e, 'jax') + x_ = jax.numpy.array([0, 1, 2]) + assert jax.numpy.array_equal(f(x_), [True, True, True]) + +def test_jax_mod(): + if not jax: + skip("JAX not installed") + + e = Mod(a, b) + f = lambdify((a, b), e, 'jax') + + a_ = jax.numpy.array([0, 1, 2, 3]) + b_ = 2 + assert jax.numpy.array_equal(f(a_, b_), [0, 1, 0, 1]) + + a_ = jax.numpy.array([0, 1, 2, 3]) + b_ = jax.numpy.array([2, 2, 2, 2]) + assert jax.numpy.array_equal(f(a_, b_), [0, 1, 0, 1]) + + a_ = jax.numpy.array([2, 3, 4, 5]) + b_ = jax.numpy.array([2, 3, 4, 5]) + assert jax.numpy.array_equal(f(a_, b_), [0, 0, 0, 0]) + + +def test_jax_pow(): + if not jax: + skip('JAX not installed') + + expr = Pow(2, -1, evaluate=False) + f = lambdify([], expr, 'jax') + assert f() == 0.5 + + +def test_jax_expm1(): + if not jax: + skip("JAX not installed") + + f = lambdify((a,), expm1(a), 'jax') + assert abs(f(1e-10) - 1e-10 - 5e-21) <= 1e-10 * JAX_DEFAULT_EPSILON + + +def test_jax_log1p(): + if not jax: + skip("JAX not installed") + + f = lambdify((a,), log1p(a), 'jax') + assert abs(f(1e-99) - 1e-99) <= 1e-99 * JAX_DEFAULT_EPSILON + +def test_jax_hypot(): + if not jax: + skip("JAX not installed") + assert abs(lambdify((a, b), hypot(a, b), 'jax')(3, 4) - 5) <= JAX_DEFAULT_EPSILON + +def test_jax_log10(): + if not jax: + skip("JAX not installed") + + assert abs(lambdify((a,), log10(a), 'jax')(100) - 2) <= JAX_DEFAULT_EPSILON + + +def test_jax_exp2(): + if not jax: + skip("JAX not installed") + assert abs(lambdify((a,), exp2(a), 'jax')(5) - 32) <= JAX_DEFAULT_EPSILON + + +def test_jax_log2(): + if not jax: + skip("JAX not installed") + assert abs(lambdify((a,), log2(a), 'jax')(256) - 8) <= JAX_DEFAULT_EPSILON + + +def test_jax_Sqrt(): + if not jax: + skip("JAX not installed") + assert abs(lambdify((a,), Sqrt(a), 'jax')(4) - 2) <= JAX_DEFAULT_EPSILON + + +def test_jax_sqrt(): + if not jax: + skip("JAX not installed") + assert abs(lambdify((a,), sqrt(a), 'jax')(4) - 2) <= JAX_DEFAULT_EPSILON + + +def test_jax_matsolve(): + if not jax: + skip("JAX not installed") + + M = MatrixSymbol("M", 3, 3) + x = MatrixSymbol("x", 3, 1) + + expr = M**(-1) * x + x + matsolve_expr = MatrixSolve(M, x) + x + + f = lambdify((M, x), expr, 'jax') + f_matsolve = lambdify((M, x), matsolve_expr, 'jax') + + m0 = jax.numpy.array([[1, 2, 3], [3, 2, 5], [5, 6, 7]]) + assert jax.numpy.linalg.matrix_rank(m0) == 3 + + x0 = jax.numpy.array([3, 4, 5]) + + assert jax.numpy.allclose(f_matsolve(m0, x0), f(m0, x0)) + + +def test_16857(): + if not jax: + skip("JAX not installed") + + a_1 = MatrixSymbol('a_1', 10, 3) + a_2 = MatrixSymbol('a_2', 10, 3) + a_3 = MatrixSymbol('a_3', 10, 3) + a_4 = MatrixSymbol('a_4', 10, 3) + A = BlockMatrix([[a_1, a_2], [a_3, a_4]]) + assert A.shape == (20, 6) + + printer = JaxPrinter() + assert printer.doprint(A) == 'jax.numpy.block([[a_1, a_2], [a_3, a_4]])' + + +def test_issue_17006(): + if not jax: + skip("JAX not installed") + + M = MatrixSymbol("M", 2, 2) + + f = lambdify(M, M + Identity(2), 'jax') + ma = jax.numpy.array([[1, 2], [3, 4]]) + mr = jax.numpy.array([[2, 2], [3, 5]]) + + assert (f(ma) == mr).all() + + from sympy.core.symbol import symbols + n = symbols('n', integer=True) + N = MatrixSymbol("M", n, n) + raises(NotImplementedError, lambda: lambdify(N, N + Identity(n), 'jax')) + + +def test_jax_array(): + assert JaxPrinter().doprint(Array(((1, 2), (3, 5)))) == 'jax.numpy.array([[1, 2], [3, 5]])' + assert JaxPrinter().doprint(Array((1, 2))) == 'jax.numpy.array([1, 2])' + + +def test_jax_known_funcs_consts(): + assert _jax_known_constants['NaN'] == 'jax.numpy.nan' + assert _jax_known_constants['EulerGamma'] == 'jax.numpy.euler_gamma' + + assert _jax_known_functions['acos'] == 'jax.numpy.arccos' + assert _jax_known_functions['log'] == 'jax.numpy.log' + + +def test_jax_print_methods(): + prntr = JaxPrinter() + assert hasattr(prntr, '_print_acos') + assert hasattr(prntr, '_print_log') + + +def test_jax_printmethod(): + printer = JaxPrinter() + assert hasattr(printer, 'printmethod') + assert printer.printmethod == '_jaxcode' + + +def test_jax_custom_print_method(): + + class expm1(Function): + + def _jaxcode(self, printer): + x, = self.args + function = f'expm1({printer._print(x)})' + return printer._module_format(printer._module + '.' + function) + + printer = JaxPrinter() + assert printer.doprint(expm1(Symbol('x'))) == 'jax.numpy.expm1(x)' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_jscode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_jscode.py new file mode 100644 index 0000000000000000000000000000000000000000..9199a8e0d62e87f2e964cb1712726a21c894fd20 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_jscode.py @@ -0,0 +1,396 @@ +from sympy.core import (pi, oo, symbols, Rational, Integer, GoldenRatio, + EulerGamma, Catalan, Lambda, Dummy, S, Eq, Ne, Le, + Lt, Gt, Ge, Mod) +from sympy.functions import (Piecewise, sin, cos, Abs, exp, ceiling, sqrt, + sinh, cosh, tanh, asin, acos, acosh, Max, Min) +from sympy.testing.pytest import raises +from sympy.printing.jscode import JavascriptCodePrinter +from sympy.utilities.lambdify import implemented_function +from sympy.tensor import IndexedBase, Idx +from sympy.matrices import Matrix, MatrixSymbol + +from sympy.printing.jscode import jscode + +x, y, z = symbols('x,y,z') + + +def test_printmethod(): + assert jscode(Abs(x)) == "Math.abs(x)" + + +def test_jscode_sqrt(): + assert jscode(sqrt(x)) == "Math.sqrt(x)" + assert jscode(x**0.5) == "Math.sqrt(x)" + assert jscode(x**(S.One/3)) == "Math.cbrt(x)" + + +def test_jscode_Pow(): + g = implemented_function('g', Lambda(x, 2*x)) + assert jscode(x**3) == "Math.pow(x, 3)" + assert jscode(x**(y**3)) == "Math.pow(x, Math.pow(y, 3))" + assert jscode(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "Math.pow(3.5*2*x, -x + Math.pow(y, x))/(Math.pow(x, 2) + y)" + assert jscode(x**-1.0) == '1/x' + + +def test_jscode_constants_mathh(): + assert jscode(exp(1)) == "Math.E" + assert jscode(pi) == "Math.PI" + assert jscode(oo) == "Number.POSITIVE_INFINITY" + assert jscode(-oo) == "Number.NEGATIVE_INFINITY" + + +def test_jscode_constants_other(): + assert jscode( + 2*GoldenRatio) == "var GoldenRatio = %s;\n2*GoldenRatio" % GoldenRatio.evalf(17) + assert jscode(2*Catalan) == "var Catalan = %s;\n2*Catalan" % Catalan.evalf(17) + assert jscode( + 2*EulerGamma) == "var EulerGamma = %s;\n2*EulerGamma" % EulerGamma.evalf(17) + + +def test_jscode_Rational(): + assert jscode(Rational(3, 7)) == "3/7" + assert jscode(Rational(18, 9)) == "2" + assert jscode(Rational(3, -7)) == "-3/7" + assert jscode(Rational(-3, -7)) == "3/7" + + +def test_Relational(): + assert jscode(Eq(x, y)) == "x == y" + assert jscode(Ne(x, y)) == "x != y" + assert jscode(Le(x, y)) == "x <= y" + assert jscode(Lt(x, y)) == "x < y" + assert jscode(Gt(x, y)) == "x > y" + assert jscode(Ge(x, y)) == "x >= y" + + +def test_Mod(): + assert jscode(Mod(x, y)) == '((x % y) + y) % y' + assert jscode(Mod(x, x + y)) == '((x % (x + y)) + (x + y)) % (x + y)' + p1, p2 = symbols('p1 p2', positive=True) + assert jscode(Mod(p1, p2)) == 'p1 % p2' + assert jscode(Mod(p1, p2 + 3)) == 'p1 % (p2 + 3)' + assert jscode(Mod(-3, -7, evaluate=False)) == '(-3) % (-7)' + assert jscode(-Mod(p1, p2)) == '-(p1 % p2)' + assert jscode(x*Mod(p1, p2)) == 'x*(p1 % p2)' + + +def test_jscode_Integer(): + assert jscode(Integer(67)) == "67" + assert jscode(Integer(-1)) == "-1" + + +def test_jscode_functions(): + assert jscode(sin(x) ** cos(x)) == "Math.pow(Math.sin(x), Math.cos(x))" + assert jscode(sinh(x) * cosh(x)) == "Math.sinh(x)*Math.cosh(x)" + assert jscode(Max(x, y) + Min(x, y)) == "Math.max(x, y) + Math.min(x, y)" + assert jscode(tanh(x)*acosh(y)) == "Math.tanh(x)*Math.acosh(y)" + assert jscode(asin(x)-acos(y)) == "-Math.acos(y) + Math.asin(x)" + + +def test_jscode_inline_function(): + x = symbols('x') + g = implemented_function('g', Lambda(x, 2*x)) + assert jscode(g(x)) == "2*x" + g = implemented_function('g', Lambda(x, 2*x/Catalan)) + assert jscode(g(x)) == "var Catalan = %s;\n2*x/Catalan" % Catalan.evalf(17) + A = IndexedBase('A') + i = Idx('i', symbols('n', integer=True)) + g = implemented_function('g', Lambda(x, x*(1 + x)*(2 + x))) + assert jscode(g(A[i]), assign_to=A[i]) == ( + "for (var i=0; i 1), (sin(x), x > 0)) + raises(ValueError, lambda: jscode(expr)) + + +def test_jscode_Piecewise_deep(): + p = jscode(2*Piecewise((x, x < 1), (x**2, True))) + s = \ +"""\ +2*((x < 1) ? ( + x +) +: ( + Math.pow(x, 2) +))\ +""" + assert p == s + + +def test_jscode_settings(): + raises(TypeError, lambda: jscode(sin(x), method="garbage")) + + +def test_jscode_Indexed(): + n, m, o = symbols('n m o', integer=True) + i, j, k = Idx('i', n), Idx('j', m), Idx('k', o) + p = JavascriptCodePrinter() + p._not_c = set() + + x = IndexedBase('x')[j] + assert p._print_Indexed(x) == 'x[j]' + A = IndexedBase('A')[i, j] + assert p._print_Indexed(A) == 'A[%s]' % (m*i+j) + B = IndexedBase('B')[i, j, k] + assert p._print_Indexed(B) == 'B[%s]' % (i*o*m+j*o+k) + + assert p._not_c == set() + + +def test_jscode_loops_matrix_vector(): + n, m = symbols('n m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + + s = ( + 'for (var i=0; i0), (y, True)), sin(z)]) + A = MatrixSymbol('A', 3, 1) + assert jscode(mat, A) == ( + "A[0] = x*y;\n" + "if (y > 0) {\n" + " A[1] = x + 2;\n" + "}\n" + "else {\n" + " A[1] = y;\n" + "}\n" + "A[2] = Math.sin(z);") + # Test using MatrixElements in expressions + expr = Piecewise((2*A[2, 0], x > 0), (A[2, 0], True)) + sin(A[1, 0]) + A[0, 0] + assert jscode(expr) == ( + "((x > 0) ? (\n" + " 2*A[2]\n" + ")\n" + ": (\n" + " A[2]\n" + ")) + Math.sin(A[1]) + A[0]") + # Test using MatrixElements in a Matrix + q = MatrixSymbol('q', 5, 1) + M = MatrixSymbol('M', 3, 3) + m = Matrix([[sin(q[1,0]), 0, cos(q[2,0])], + [q[1,0] + q[2,0], q[3, 0], 5], + [2*q[4, 0]/q[1,0], sqrt(q[0,0]) + 4, 0]]) + assert jscode(m, M) == ( + "M[0] = Math.sin(q[1]);\n" + "M[1] = 0;\n" + "M[2] = Math.cos(q[2]);\n" + "M[3] = q[1] + q[2];\n" + "M[4] = q[3];\n" + "M[5] = 5;\n" + "M[6] = 2*q[4]/q[1];\n" + "M[7] = Math.sqrt(q[0]) + 4;\n" + "M[8] = 0;") + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert(jscode(A[0, 0]) == "A[0]") + assert(jscode(3 * A[0, 0]) == "3*A[0]") + + F = C[0, 0].subs(C, A - B) + assert(jscode(F) == "(A - B)[0]") diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_julia.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_julia.py new file mode 100644 index 0000000000000000000000000000000000000000..b19c7b4fd4f21d8402ca2f577605322b3ec10f5b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_julia.py @@ -0,0 +1,390 @@ +from sympy.core import (S, pi, oo, symbols, Function, Rational, Integer, + Tuple, Symbol, Eq, Ne, Le, Lt, Gt, Ge) +from sympy.core import EulerGamma, GoldenRatio, Catalan, Lambda, Mul, Pow +from sympy.functions import Piecewise, sqrt, ceiling, exp, sin, cos, sinc +from sympy.testing.pytest import raises +from sympy.utilities.lambdify import implemented_function +from sympy.matrices import (eye, Matrix, MatrixSymbol, Identity, + HadamardProduct, SparseMatrix) +from sympy.functions.special.bessel import (jn, yn, besselj, bessely, besseli, + besselk, hankel1, hankel2, airyai, + airybi, airyaiprime, airybiprime) +from sympy.testing.pytest import XFAIL + +from sympy.printing.julia import julia_code + +x, y, z = symbols('x,y,z') + + +def test_Integer(): + assert julia_code(Integer(67)) == "67" + assert julia_code(Integer(-1)) == "-1" + + +def test_Rational(): + assert julia_code(Rational(3, 7)) == "3 // 7" + assert julia_code(Rational(18, 9)) == "2" + assert julia_code(Rational(3, -7)) == "-3 // 7" + assert julia_code(Rational(-3, -7)) == "3 // 7" + assert julia_code(x + Rational(3, 7)) == "x + 3 // 7" + assert julia_code(Rational(3, 7)*x) == "(3 // 7) * x" + + +def test_Relational(): + assert julia_code(Eq(x, y)) == "x == y" + assert julia_code(Ne(x, y)) == "x != y" + assert julia_code(Le(x, y)) == "x <= y" + assert julia_code(Lt(x, y)) == "x < y" + assert julia_code(Gt(x, y)) == "x > y" + assert julia_code(Ge(x, y)) == "x >= y" + + +def test_Function(): + assert julia_code(sin(x) ** cos(x)) == "sin(x) .^ cos(x)" + assert julia_code(abs(x)) == "abs(x)" + assert julia_code(ceiling(x)) == "ceil(x)" + + +def test_Pow(): + assert julia_code(x**3) == "x .^ 3" + assert julia_code(x**(y**3)) == "x .^ (y .^ 3)" + assert julia_code(x**Rational(2, 3)) == 'x .^ (2 // 3)' + g = implemented_function('g', Lambda(x, 2*x)) + assert julia_code(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "(3.5 * 2 * x) .^ (-x + y .^ x) ./ (x .^ 2 + y)" + # For issue 14160 + assert julia_code(Mul(-2, x, Pow(Mul(y,y,evaluate=False), -1, evaluate=False), + evaluate=False)) == '-2 * x ./ (y .* y)' + + +def test_basic_ops(): + assert julia_code(x*y) == "x .* y" + assert julia_code(x + y) == "x + y" + assert julia_code(x - y) == "x - y" + assert julia_code(-x) == "-x" + + +def test_1_over_x_and_sqrt(): + # 1.0 and 0.5 would do something different in regular StrPrinter, + # but these are exact in IEEE floating point so no different here. + assert julia_code(1/x) == '1 ./ x' + assert julia_code(x**-1) == julia_code(x**-1.0) == '1 ./ x' + assert julia_code(1/sqrt(x)) == '1 ./ sqrt(x)' + assert julia_code(x**-S.Half) == julia_code(x**-0.5) == '1 ./ sqrt(x)' + assert julia_code(sqrt(x)) == 'sqrt(x)' + assert julia_code(x**S.Half) == julia_code(x**0.5) == 'sqrt(x)' + assert julia_code(1/pi) == '1 / pi' + assert julia_code(pi**-1) == julia_code(pi**-1.0) == '1 / pi' + assert julia_code(pi**-0.5) == '1 / sqrt(pi)' + + +def test_mix_number_mult_symbols(): + assert julia_code(3*x) == "3 * x" + assert julia_code(pi*x) == "pi * x" + assert julia_code(3/x) == "3 ./ x" + assert julia_code(pi/x) == "pi ./ x" + assert julia_code(x/3) == "x / 3" + assert julia_code(x/pi) == "x / pi" + assert julia_code(x*y) == "x .* y" + assert julia_code(3*x*y) == "3 * x .* y" + assert julia_code(3*pi*x*y) == "3 * pi * x .* y" + assert julia_code(x/y) == "x ./ y" + assert julia_code(3*x/y) == "3 * x ./ y" + assert julia_code(x*y/z) == "x .* y ./ z" + assert julia_code(x/y*z) == "x .* z ./ y" + assert julia_code(1/x/y) == "1 ./ (x .* y)" + assert julia_code(2*pi*x/y/z) == "2 * pi * x ./ (y .* z)" + assert julia_code(3*pi/x) == "3 * pi ./ x" + assert julia_code(S(3)/5) == "3 // 5" + assert julia_code(S(3)/5*x) == "(3 // 5) * x" + assert julia_code(x/y/z) == "x ./ (y .* z)" + assert julia_code((x+y)/z) == "(x + y) ./ z" + assert julia_code((x+y)/(z+x)) == "(x + y) ./ (x + z)" + assert julia_code((x+y)/EulerGamma) == "(x + y) / eulergamma" + assert julia_code(x/3/pi) == "x / (3 * pi)" + assert julia_code(S(3)/5*x*y/pi) == "(3 // 5) * x .* y / pi" + + +def test_mix_number_pow_symbols(): + assert julia_code(pi**3) == 'pi ^ 3' + assert julia_code(x**2) == 'x .^ 2' + assert julia_code(x**(pi**3)) == 'x .^ (pi ^ 3)' + assert julia_code(x**y) == 'x .^ y' + assert julia_code(x**(y**z)) == 'x .^ (y .^ z)' + assert julia_code((x**y)**z) == '(x .^ y) .^ z' + + +def test_imag(): + I = S('I') + assert julia_code(I) == "im" + assert julia_code(5*I) == "5im" + assert julia_code((S(3)/2)*I) == "(3 // 2) * im" + assert julia_code(3+4*I) == "3 + 4im" + + +def test_constants(): + assert julia_code(pi) == "pi" + assert julia_code(oo) == "Inf" + assert julia_code(-oo) == "-Inf" + assert julia_code(S.NegativeInfinity) == "-Inf" + assert julia_code(S.NaN) == "NaN" + assert julia_code(S.Exp1) == "e" + assert julia_code(exp(1)) == "e" + + +def test_constants_other(): + assert julia_code(2*GoldenRatio) == "2 * golden" + assert julia_code(2*Catalan) == "2 * catalan" + assert julia_code(2*EulerGamma) == "2 * eulergamma" + + +def test_boolean(): + assert julia_code(x & y) == "x && y" + assert julia_code(x | y) == "x || y" + assert julia_code(~x) == "!x" + assert julia_code(x & y & z) == "x && y && z" + assert julia_code(x | y | z) == "x || y || z" + assert julia_code((x & y) | z) == "z || x && y" + assert julia_code((x | y) & z) == "z && (x || y)" + +def test_sinc(): + assert julia_code(sinc(x)) == 'sinc(x / pi)' + assert julia_code(sinc(x + 3)) == 'sinc((x + 3) / pi)' + assert julia_code(sinc(pi * (x + 3))) == 'sinc(x + 3)' + +def test_Matrices(): + assert julia_code(Matrix(1, 1, [10])) == "[10]" + A = Matrix([[1, sin(x/2), abs(x)], + [0, 1, pi], + [0, exp(1), ceiling(x)]]) + expected = ("[1 sin(x / 2) abs(x);\n" + "0 1 pi;\n" + "0 e ceil(x)]") + assert julia_code(A) == expected + # row and columns + assert julia_code(A[:,0]) == "[1, 0, 0]" + assert julia_code(A[0,:]) == "[1 sin(x / 2) abs(x)]" + # empty matrices + assert julia_code(Matrix(0, 0, [])) == 'zeros(0, 0)' + assert julia_code(Matrix(0, 3, [])) == 'zeros(0, 3)' + # annoying to read but correct + assert julia_code(Matrix([[x, x - y, -y]])) == "[x x - y -y]" + + +def test_vector_entries_hadamard(): + # For a row or column, user might to use the other dimension + A = Matrix([[1, sin(2/x), 3*pi/x/5]]) + assert julia_code(A) == "[1 sin(2 ./ x) (3 // 5) * pi ./ x]" + assert julia_code(A.T) == "[1, sin(2 ./ x), (3 // 5) * pi ./ x]" + + +@XFAIL +def test_Matrices_entries_not_hadamard(): + # For Matrix with col >= 2, row >= 2, they need to be scalars + # FIXME: is it worth worrying about this? Its not wrong, just + # leave it user's responsibility to put scalar data for x. + A = Matrix([[1, sin(2/x), 3*pi/x/5], [1, 2, x*y]]) + expected = ("[1 sin(2/x) 3*pi/(5*x);\n" + "1 2 x*y]") # <- we give x.*y + assert julia_code(A) == expected + + +def test_MatrixSymbol(): + n = Symbol('n', integer=True) + A = MatrixSymbol('A', n, n) + B = MatrixSymbol('B', n, n) + assert julia_code(A*B) == "A * B" + assert julia_code(B*A) == "B * A" + assert julia_code(2*A*B) == "2 * A * B" + assert julia_code(B*2*A) == "2 * B * A" + assert julia_code(A*(B + 3*Identity(n))) == "A * (3 * eye(n) + B)" + assert julia_code(A**(x**2)) == "A ^ (x .^ 2)" + assert julia_code(A**3) == "A ^ 3" + assert julia_code(A**S.Half) == "A ^ (1 // 2)" + + +def test_special_matrices(): + assert julia_code(6*Identity(3)) == "6 * eye(3)" + + +def test_containers(): + assert julia_code([1, 2, 3, [4, 5, [6, 7]], 8, [9, 10], 11]) == \ + "Any[1, 2, 3, Any[4, 5, Any[6, 7]], 8, Any[9, 10], 11]" + assert julia_code((1, 2, (3, 4))) == "(1, 2, (3, 4))" + assert julia_code([1]) == "Any[1]" + assert julia_code((1,)) == "(1,)" + assert julia_code(Tuple(*[1, 2, 3])) == "(1, 2, 3)" + assert julia_code((1, x*y, (3, x**2))) == "(1, x .* y, (3, x .^ 2))" + # scalar, matrix, empty matrix and empty list + assert julia_code((1, eye(3), Matrix(0, 0, []), [])) == "(1, [1 0 0;\n0 1 0;\n0 0 1], zeros(0, 0), Any[])" + + +def test_julia_noninline(): + source = julia_code((x+y)/Catalan, assign_to='me', inline=False) + expected = ( + "const Catalan = %s\n" + "me = (x + y) / Catalan" + ) % Catalan.evalf(17) + assert source == expected + + +def test_julia_piecewise(): + expr = Piecewise((x, x < 1), (x**2, True)) + assert julia_code(expr) == "((x < 1) ? (x) : (x .^ 2))" + assert julia_code(expr, assign_to="r") == ( + "r = ((x < 1) ? (x) : (x .^ 2))") + assert julia_code(expr, assign_to="r", inline=False) == ( + "if (x < 1)\n" + " r = x\n" + "else\n" + " r = x .^ 2\n" + "end") + expr = Piecewise((x**2, x < 1), (x**3, x < 2), (x**4, x < 3), (x**5, True)) + expected = ("((x < 1) ? (x .^ 2) :\n" + "(x < 2) ? (x .^ 3) :\n" + "(x < 3) ? (x .^ 4) : (x .^ 5))") + assert julia_code(expr) == expected + assert julia_code(expr, assign_to="r") == "r = " + expected + assert julia_code(expr, assign_to="r", inline=False) == ( + "if (x < 1)\n" + " r = x .^ 2\n" + "elseif (x < 2)\n" + " r = x .^ 3\n" + "elseif (x < 3)\n" + " r = x .^ 4\n" + "else\n" + " r = x .^ 5\n" + "end") + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) + raises(ValueError, lambda: julia_code(expr)) + + +def test_julia_piecewise_times_const(): + pw = Piecewise((x, x < 1), (x**2, True)) + assert julia_code(2*pw) == "2 * ((x < 1) ? (x) : (x .^ 2))" + assert julia_code(pw/x) == "((x < 1) ? (x) : (x .^ 2)) ./ x" + assert julia_code(pw/(x*y)) == "((x < 1) ? (x) : (x .^ 2)) ./ (x .* y)" + assert julia_code(pw/3) == "((x < 1) ? (x) : (x .^ 2)) / 3" + + +def test_julia_matrix_assign_to(): + A = Matrix([[1, 2, 3]]) + assert julia_code(A, assign_to='a') == "a = [1 2 3]" + A = Matrix([[1, 2], [3, 4]]) + assert julia_code(A, assign_to='A') == "A = [1 2;\n3 4]" + + +def test_julia_matrix_assign_to_more(): + # assigning to Symbol or MatrixSymbol requires lhs/rhs match + A = Matrix([[1, 2, 3]]) + B = MatrixSymbol('B', 1, 3) + C = MatrixSymbol('C', 2, 3) + assert julia_code(A, assign_to=B) == "B = [1 2 3]" + raises(ValueError, lambda: julia_code(A, assign_to=x)) + raises(ValueError, lambda: julia_code(A, assign_to=C)) + + +def test_julia_matrix_1x1(): + A = Matrix([[3]]) + B = MatrixSymbol('B', 1, 1) + C = MatrixSymbol('C', 1, 2) + assert julia_code(A, assign_to=B) == "B = [3]" + # FIXME? + #assert julia_code(A, assign_to=x) == "x = [3]" + raises(ValueError, lambda: julia_code(A, assign_to=C)) + + +def test_julia_matrix_elements(): + A = Matrix([[x, 2, x*y]]) + assert julia_code(A[0, 0]**2 + A[0, 1] + A[0, 2]) == "x .^ 2 + x .* y + 2" + A = MatrixSymbol('AA', 1, 3) + assert julia_code(A) == "AA" + assert julia_code(A[0, 0]**2 + sin(A[0,1]) + A[0,2]) == \ + "sin(AA[1,2]) + AA[1,1] .^ 2 + AA[1,3]" + assert julia_code(sum(A)) == "AA[1,1] + AA[1,2] + AA[1,3]" + + +def test_julia_boolean(): + assert julia_code(True) == "true" + assert julia_code(S.true) == "true" + assert julia_code(False) == "false" + assert julia_code(S.false) == "false" + + +def test_julia_not_supported(): + with raises(NotImplementedError): + julia_code(S.ComplexInfinity) + + f = Function('f') + assert julia_code(f(x).diff(x), strict=False) == ( + "# Not supported in Julia:\n" + "# Derivative\n" + "Derivative(f(x), x)" + ) + + +def test_trick_indent_with_end_else_words(): + # words starting with "end" or "else" do not confuse the indenter + t1 = S('endless') + t2 = S('elsewhere') + pw = Piecewise((t1, x < 0), (t2, x <= 1), (1, True)) + assert julia_code(pw, inline=False) == ( + "if (x < 0)\n" + " endless\n" + "elseif (x <= 1)\n" + " elsewhere\n" + "else\n" + " 1\n" + "end") + + +def test_haramard(): + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 3, 3) + v = MatrixSymbol('v', 3, 1) + h = MatrixSymbol('h', 1, 3) + C = HadamardProduct(A, B) + assert julia_code(C) == "A .* B" + assert julia_code(C*v) == "(A .* B) * v" + assert julia_code(h*C*v) == "h * (A .* B) * v" + assert julia_code(C*A) == "(A .* B) * A" + # mixing Hadamard and scalar strange b/c we vectorize scalars + assert julia_code(C*x*y) == "(x .* y) * (A .* B)" + + +def test_sparse(): + M = SparseMatrix(5, 6, {}) + M[2, 2] = 10 + M[1, 2] = 20 + M[1, 3] = 22 + M[0, 3] = 30 + M[3, 0] = x*y + assert julia_code(M) == ( + "sparse([4, 2, 3, 1, 2], [1, 3, 3, 4, 4], [x .* y, 20, 10, 30, 22], 5, 6)" + ) + + +def test_specfun(): + n = Symbol('n') + for f in [besselj, bessely, besseli, besselk]: + assert julia_code(f(n, x)) == f.__name__ + '(n, x)' + for f in [airyai, airyaiprime, airybi, airybiprime]: + assert julia_code(f(x)) == f.__name__ + '(x)' + assert julia_code(hankel1(n, x)) == 'hankelh1(n, x)' + assert julia_code(hankel2(n, x)) == 'hankelh2(n, x)' + assert julia_code(jn(n, x)) == 'sqrt(2) * sqrt(pi) * sqrt(1 ./ x) .* besselj(n + 1 // 2, x) / 2' + assert julia_code(yn(n, x)) == 'sqrt(2) * sqrt(pi) * sqrt(1 ./ x) .* bessely(n + 1 // 2, x) / 2' + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert(julia_code(A[0, 0]) == "A[1,1]") + assert(julia_code(3 * A[0, 0]) == "3 * A[1,1]") + + F = C[0, 0].subs(C, A - B) + assert(julia_code(F) == "(A - B)[1,1]") diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_lambdarepr.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_lambdarepr.py new file mode 100644 index 0000000000000000000000000000000000000000..94e09ada7a9ce7d01667edd8fc6ec35ebfbb9639 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_lambdarepr.py @@ -0,0 +1,246 @@ +from sympy.concrete.summations import Sum +from sympy.core.expr import Expr +from sympy.core.symbol import symbols +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import sin +from sympy.matrices.dense import MutableDenseMatrix as Matrix +from sympy.sets.sets import Interval +from sympy.utilities.lambdify import lambdify +from sympy.testing.pytest import raises + +from sympy.printing.tensorflow import TensorflowPrinter +from sympy.printing.lambdarepr import lambdarepr, LambdaPrinter, NumExprPrinter + + +x, y, z = symbols("x,y,z") +i, a, b = symbols("i,a,b") +j, c, d = symbols("j,c,d") + + +def test_basic(): + assert lambdarepr(x*y) == "x*y" + assert lambdarepr(x + y) in ["y + x", "x + y"] + assert lambdarepr(x**y) == "x**y" + + +def test_matrix(): + # Test printing a Matrix that has an element that is printed differently + # with the LambdaPrinter than with the StrPrinter. + e = x % 2 + assert lambdarepr(e) != str(e) + assert lambdarepr(Matrix([e])) == 'ImmutableDenseMatrix([[x % 2]])' + + +def test_piecewise(): + # In each case, test eval() the lambdarepr() to make sure there are a + # correct number of parentheses. It will give a SyntaxError if there aren't. + + h = "lambda x: " + + p = Piecewise((x, x < 0)) + l = lambdarepr(p) + eval(h + l) + assert l == "((x) if (x < 0) else None)" + + p = Piecewise( + (1, x < 1), + (2, x < 2), + (0, True) + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((1) if (x < 1) else (2) if (x < 2) else (0))" + + p = Piecewise( + (1, x < 1), + (2, x < 2), + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((1) if (x < 1) else (2) if (x < 2) else None)" + + p = Piecewise( + (x, x < 1), + (x**2, Interval(3, 4, True, False).contains(x)), + (0, True), + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((x) if (x < 1) else (x**2) if (((x <= 4)) and ((x > 3))) else (0))" + + p = Piecewise( + (x**2, x < 0), + (x, x < 1), + (2 - x, x >= 1), + (0, True), evaluate=False + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((x**2) if (x < 0) else (x) if (x < 1)"\ + " else (2 - x) if (x >= 1) else (0))" + + p = Piecewise( + (x**2, x < 0), + (x, x < 1), + (2 - x, x >= 1), evaluate=False + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((x**2) if (x < 0) else (x) if (x < 1)"\ + " else (2 - x) if (x >= 1) else None)" + + p = Piecewise( + (1, x >= 1), + (2, x >= 2), + (3, x >= 3), + (4, x >= 4), + (5, x >= 5), + (6, True) + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((1) if (x >= 1) else (2) if (x >= 2) else (3) if (x >= 3)"\ + " else (4) if (x >= 4) else (5) if (x >= 5) else (6))" + + p = Piecewise( + (1, x <= 1), + (2, x <= 2), + (3, x <= 3), + (4, x <= 4), + (5, x <= 5), + (6, True) + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((1) if (x <= 1) else (2) if (x <= 2) else (3) if (x <= 3)"\ + " else (4) if (x <= 4) else (5) if (x <= 5) else (6))" + + p = Piecewise( + (1, x > 1), + (2, x > 2), + (3, x > 3), + (4, x > 4), + (5, x > 5), + (6, True) + ) + l = lambdarepr(p) + eval(h + l) + assert l =="((1) if (x > 1) else (2) if (x > 2) else (3) if (x > 3)"\ + " else (4) if (x > 4) else (5) if (x > 5) else (6))" + + p = Piecewise( + (1, x < 1), + (2, x < 2), + (3, x < 3), + (4, x < 4), + (5, x < 5), + (6, True) + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((1) if (x < 1) else (2) if (x < 2) else (3) if (x < 3)"\ + " else (4) if (x < 4) else (5) if (x < 5) else (6))" + + p = Piecewise( + (Piecewise( + (1, x > 0), + (2, True) + ), y > 0), + (3, True) + ) + l = lambdarepr(p) + eval(h + l) + assert l == "((((1) if (x > 0) else (2))) if (y > 0) else (3))" + + +def test_sum__1(): + # In each case, test eval() the lambdarepr() to make sure that + # it evaluates to the same results as the symbolic expression + s = Sum(x ** i, (i, a, b)) + l = lambdarepr(s) + assert l == "(builtins.sum(x**i for i in range(a, b+1)))" + + args = x, a, b + f = lambdify(args, s) + v = 2, 3, 8 + assert f(*v) == s.subs(zip(args, v)).doit() + +def test_sum__2(): + s = Sum(i * x, (i, a, b)) + l = lambdarepr(s) + assert l == "(builtins.sum(i*x for i in range(a, b+1)))" + + args = x, a, b + f = lambdify(args, s) + v = 2, 3, 8 + assert f(*v) == s.subs(zip(args, v)).doit() + + +def test_multiple_sums(): + s = Sum(i * x + j, (i, a, b), (j, c, d)) + + l = lambdarepr(s) + assert l == "(builtins.sum(i*x + j for j in range(c, d+1) for i in range(a, b+1)))" + + args = x, a, b, c, d + f = lambdify(args, s) + vals = 2, 3, 4, 5, 6 + f_ref = s.subs(zip(args, vals)).doit() + f_res = f(*vals) + assert f_res == f_ref + + +def test_sqrt(): + prntr = LambdaPrinter({'standard' : 'python3'}) + assert prntr._print_Pow(sqrt(x), rational=False) == 'sqrt(x)' + assert prntr._print_Pow(sqrt(x), rational=True) == 'x**(1/2)' + + +def test_settings(): + raises(TypeError, lambda: lambdarepr(sin(x), method="garbage")) + + +def test_numexpr(): + # test ITE rewrite as Piecewise + from sympy.logic.boolalg import ITE + expr = ITE(x > 0, True, False, evaluate=False) + assert NumExprPrinter().doprint(expr) == \ + "numexpr.evaluate('where((x > 0), True, False)', truediv=True)" + + from sympy.codegen.ast import Return, FunctionDefinition, Variable, Assignment + func_def = FunctionDefinition(None, 'foo', [Variable(x)], [Assignment(y,x), Return(y**2)]) + expected = "def foo(x):\n"\ + " y = numexpr.evaluate('x', truediv=True)\n"\ + " return numexpr.evaluate('y**2', truediv=True)" + assert NumExprPrinter().doprint(func_def) == expected + + +class CustomPrintedObject(Expr): + def _lambdacode(self, printer): + return 'lambda' + + def _tensorflowcode(self, printer): + return 'tensorflow' + + def _numpycode(self, printer): + return 'numpy' + + def _numexprcode(self, printer): + return 'numexpr' + + def _mpmathcode(self, printer): + return 'mpmath' + + +def test_printmethod(): + # In each case, printmethod is called to test + # its working + + obj = CustomPrintedObject() + assert LambdaPrinter().doprint(obj) == 'lambda' + assert TensorflowPrinter().doprint(obj) == 'tensorflow' + assert NumExprPrinter().doprint(obj) == "numexpr.evaluate('numexpr', truediv=True)" + + assert NumExprPrinter().doprint(Piecewise((y, x >= 0), (z, x < 0))) == \ + "numexpr.evaluate('where((x >= 0), y, z)', truediv=True)" diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_latex.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_latex.py new file mode 100644 index 0000000000000000000000000000000000000000..063611d09a923881cd94bd693f3f3f721535fd0c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_latex.py @@ -0,0 +1,3164 @@ +from sympy import MatAdd, MatMul, Array +from sympy.algebras.quaternion import Quaternion +from sympy.calculus.accumulationbounds import AccumBounds +from sympy.combinatorics.permutations import Cycle, Permutation, AppliedPermutation +from sympy.concrete.products import Product +from sympy.concrete.summations import Sum +from sympy.core.containers import Tuple, Dict +from sympy.core.expr import UnevaluatedExpr +from sympy.core.function import (Derivative, Function, Lambda, Subs, diff) +from sympy.core.mod import Mod +from sympy.core.mul import Mul +from sympy.core.numbers import (AlgebraicNumber, Float, I, Integer, Rational, oo, pi) +from sympy.core.parameters import evaluate +from sympy.core.power import Pow +from sympy.core.relational import Eq, Ne +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, Wild, symbols) +from sympy.functions.combinatorial.factorials import (FallingFactorial, RisingFactorial, binomial, factorial, factorial2, subfactorial) +from sympy.functions.combinatorial.numbers import (bernoulli, bell, catalan, euler, genocchi, + lucas, fibonacci, tribonacci, divisor_sigma, udivisor_sigma, + mobius, primenu, primeomega, + totient, reduced_totient) +from sympy.functions.elementary.complexes import (Abs, arg, conjugate, im, polar_lift, re) +from sympy.functions.elementary.exponential import (LambertW, exp, log) +from sympy.functions.elementary.hyperbolic import (asinh, coth) +from sympy.functions.elementary.integers import (ceiling, floor, frac) +from sympy.functions.elementary.miscellaneous import (Max, Min, root, sqrt) +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (acsc, asin, cos, cot, sin, tan) +from sympy.functions.special.beta_functions import beta +from sympy.functions.special.delta_functions import (DiracDelta, Heaviside) +from sympy.functions.special.elliptic_integrals import (elliptic_e, elliptic_f, elliptic_k, elliptic_pi) +from sympy.functions.special.error_functions import (Chi, Ci, Ei, Shi, Si, expint) +from sympy.functions.special.gamma_functions import (gamma, uppergamma) +from sympy.functions.special.hyper import (hyper, meijerg) +from sympy.functions.special.mathieu_functions import (mathieuc, mathieucprime, mathieus, mathieusprime) +from sympy.functions.special.polynomials import (assoc_laguerre, assoc_legendre, chebyshevt, chebyshevu, gegenbauer, hermite, jacobi, laguerre, legendre) +from sympy.functions.special.singularity_functions import SingularityFunction +from sympy.functions.special.spherical_harmonics import (Ynm, Znm) +from sympy.functions.special.tensor_functions import (KroneckerDelta, LeviCivita) +from sympy.functions.special.zeta_functions import (dirichlet_eta, lerchphi, polylog, stieltjes, zeta) +from sympy.integrals.integrals import Integral +from sympy.integrals.transforms import (CosineTransform, FourierTransform, InverseCosineTransform, InverseFourierTransform, InverseLaplaceTransform, InverseMellinTransform, InverseSineTransform, LaplaceTransform, MellinTransform, SineTransform) +from sympy.logic import Implies +from sympy.logic.boolalg import (And, Or, Xor, Equivalent, false, Not, true) +from sympy.matrices.dense import Matrix +from sympy.matrices.expressions.kronecker import KroneckerProduct +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.matrices.expressions.permutation import PermutationMatrix +from sympy.matrices.expressions.slice import MatrixSlice +from sympy.matrices.expressions.dotproduct import DotProduct +from sympy.physics.control.lti import TransferFunction, Series, Parallel, Feedback, TransferFunctionMatrix, MIMOSeries, MIMOParallel, MIMOFeedback +from sympy.physics.quantum import Commutator, Operator +from sympy.physics.quantum.trace import Tr +from sympy.physics.units import meter, gibibyte, gram, microgram, second, milli, micro +from sympy.polys.domains.integerring import ZZ +from sympy.polys.fields import field +from sympy.polys.polytools import Poly +from sympy.polys.rings import ring +from sympy.polys.rootoftools import (RootSum, rootof) +from sympy.series.formal import fps +from sympy.series.fourier import fourier_series +from sympy.series.limits import Limit +from sympy.series.order import Order +from sympy.series.sequences import (SeqAdd, SeqFormula, SeqMul, SeqPer) +from sympy.sets.conditionset import ConditionSet +from sympy.sets.contains import Contains +from sympy.sets.fancysets import (ComplexRegion, ImageSet, Range) +from sympy.sets.ordinals import Ordinal, OrdinalOmega, OmegaPower +from sympy.sets.powerset import PowerSet +from sympy.sets.sets import (FiniteSet, Interval, Union, Intersection, Complement, SymmetricDifference, ProductSet) +from sympy.sets.setexpr import SetExpr +from sympy.stats.crv_types import Normal +from sympy.stats.symbolic_probability import (Covariance, Expectation, + Probability, Variance) +from sympy.tensor.array import (ImmutableDenseNDimArray, + ImmutableSparseNDimArray, + MutableSparseNDimArray, + MutableDenseNDimArray, + tensorproduct) +from sympy.tensor.array.expressions.array_expressions import ArraySymbol, ArrayElement +from sympy.tensor.indexed import (Idx, Indexed, IndexedBase) +from sympy.tensor.toperators import PartialDerivative +from sympy.vector import CoordSys3D, Cross, Curl, Dot, Divergence, Gradient, Laplacian + + +from sympy.testing.pytest import (XFAIL, raises, _both_exp_pow, + warns_deprecated_sympy) +from sympy.printing.latex import (latex, translate, greek_letters_set, + tex_greek_dictionary, multiline_latex, + latex_escape, LatexPrinter) + +import sympy as sym + +from sympy.abc import mu, tau + + +class lowergamma(sym.lowergamma): + pass # testing notation inheritance by a subclass with same name + + +x, y, z, t, w, a, b, c, s, p = symbols('x y z t w a b c s p') +k, m, n = symbols('k m n', integer=True) + + +def test_printmethod(): + class R(Abs): + def _latex(self, printer): + return "foo(%s)" % printer._print(self.args[0]) + assert latex(R(x)) == r"foo(x)" + + class R(Abs): + def _latex(self, printer): + return "foo" + assert latex(R(x)) == r"foo" + + +def test_latex_basic(): + assert latex(1 + x) == r"x + 1" + assert latex(x**2) == r"x^{2}" + assert latex(x**(1 + x)) == r"x^{x + 1}" + assert latex(x**3 + x + 1 + x**2) == r"x^{3} + x^{2} + x + 1" + + assert latex(2*x*y) == r"2 x y" + assert latex(2*x*y, mul_symbol='dot') == r"2 \cdot x \cdot y" + assert latex(3*x**2*y, mul_symbol='\\,') == r"3\,x^{2}\,y" + assert latex(1.5*3**x, mul_symbol='\\,') == r"1.5 \cdot 3^{x}" + + assert latex(x**S.Half**5) == r"\sqrt[32]{x}" + assert latex(Mul(S.Half, x**2, -5, evaluate=False)) == r"\frac{1}{2} x^{2} \left(-5\right)" + assert latex(Mul(S.Half, x**2, 5, evaluate=False)) == r"\frac{1}{2} x^{2} \cdot 5" + assert latex(Mul(-5, -5, evaluate=False)) == r"\left(-5\right) \left(-5\right)" + assert latex(Mul(5, -5, evaluate=False)) == r"5 \left(-5\right)" + assert latex(Mul(S.Half, -5, S.Half, evaluate=False)) == r"\frac{1}{2} \left(-5\right) \frac{1}{2}" + assert latex(Mul(5, I, 5, evaluate=False)) == r"5 i 5" + assert latex(Mul(5, I, -5, evaluate=False)) == r"5 i \left(-5\right)" + assert latex(Mul(Pow(x, 2), S.Half*x + 1)) == r"x^{2} \left(\frac{x}{2} + 1\right)" + assert latex(Mul(Pow(x, 3), Rational(2, 3)*x + 1)) == r"x^{3} \left(\frac{2 x}{3} + 1\right)" + assert latex(Mul(Pow(x, 11), 2*x + 1)) == r"x^{11} \left(2 x + 1\right)" + + assert latex(Mul(0, 1, evaluate=False)) == r'0 \cdot 1' + assert latex(Mul(1, 0, evaluate=False)) == r'1 \cdot 0' + assert latex(Mul(1, 1, evaluate=False)) == r'1 \cdot 1' + assert latex(Mul(-1, 1, evaluate=False)) == r'\left(-1\right) 1' + assert latex(Mul(1, 1, 1, evaluate=False)) == r'1 \cdot 1 \cdot 1' + assert latex(Mul(1, 2, evaluate=False)) == r'1 \cdot 2' + assert latex(Mul(1, S.Half, evaluate=False)) == r'1 \cdot \frac{1}{2}' + assert latex(Mul(1, 1, S.Half, evaluate=False)) == \ + r'1 \cdot 1 \cdot \frac{1}{2}' + assert latex(Mul(1, 1, 2, 3, x, evaluate=False)) == \ + r'1 \cdot 1 \cdot 2 \cdot 3 x' + assert latex(Mul(1, -1, evaluate=False)) == r'1 \left(-1\right)' + assert latex(Mul(4, 3, 2, 1, 0, y, x, evaluate=False)) == \ + r'4 \cdot 3 \cdot 2 \cdot 1 \cdot 0 y x' + assert latex(Mul(4, 3, 2, 1+z, 0, y, x, evaluate=False)) == \ + r'4 \cdot 3 \cdot 2 \left(z + 1\right) 0 y x' + assert latex(Mul(Rational(2, 3), Rational(5, 7), evaluate=False)) == \ + r'\frac{2}{3} \cdot \frac{5}{7}' + + assert latex(1/x) == r"\frac{1}{x}" + assert latex(1/x, fold_short_frac=True) == r"1 / x" + assert latex(-S(3)/2) == r"- \frac{3}{2}" + assert latex(-S(3)/2, fold_short_frac=True) == r"- 3 / 2" + assert latex(1/x**2) == r"\frac{1}{x^{2}}" + assert latex(1/(x + y)/2) == r"\frac{1}{2 \left(x + y\right)}" + assert latex(x/2) == r"\frac{x}{2}" + assert latex(x/2, fold_short_frac=True) == r"x / 2" + assert latex((x + y)/(2*x)) == r"\frac{x + y}{2 x}" + assert latex((x + y)/(2*x), fold_short_frac=True) == \ + r"\left(x + y\right) / 2 x" + assert latex((x + y)/(2*x), long_frac_ratio=0) == \ + r"\frac{1}{2 x} \left(x + y\right)" + assert latex((x + y)/x) == r"\frac{x + y}{x}" + assert latex((x + y)/x, long_frac_ratio=3) == r"\frac{x + y}{x}" + assert latex((2*sqrt(2)*x)/3) == r"\frac{2 \sqrt{2} x}{3}" + assert latex((2*sqrt(2)*x)/3, long_frac_ratio=2) == \ + r"\frac{2 x}{3} \sqrt{2}" + assert latex(binomial(x, y)) == r"{\binom{x}{y}}" + + x_star = Symbol('x^*') + f = Function('f') + assert latex(x_star**2) == r"\left(x^{*}\right)^{2}" + assert latex(x_star**2, parenthesize_super=False) == r"{x^{*}}^{2}" + assert latex(Derivative(f(x_star), x_star,2)) == r"\frac{d^{2}}{d \left(x^{*}\right)^{2}} f{\left(x^{*} \right)}" + assert latex(Derivative(f(x_star), x_star,2), parenthesize_super=False) == r"\frac{d^{2}}{d {x^{*}}^{2}} f{\left(x^{*} \right)}" + + assert latex(2*Integral(x, x)/3) == r"\frac{2 \int x\, dx}{3}" + assert latex(2*Integral(x, x)/3, fold_short_frac=True) == \ + r"\left(2 \int x\, dx\right) / 3" + + assert latex(sqrt(x)) == r"\sqrt{x}" + assert latex(x**Rational(1, 3)) == r"\sqrt[3]{x}" + assert latex(x**Rational(1, 3), root_notation=False) == r"x^{\frac{1}{3}}" + assert latex(sqrt(x)**3) == r"x^{\frac{3}{2}}" + assert latex(sqrt(x), itex=True) == r"\sqrt{x}" + assert latex(x**Rational(1, 3), itex=True) == r"\root{3}{x}" + assert latex(sqrt(x)**3, itex=True) == r"x^{\frac{3}{2}}" + assert latex(x**Rational(3, 4)) == r"x^{\frac{3}{4}}" + assert latex(x**Rational(3, 4), fold_frac_powers=True) == r"x^{3/4}" + assert latex((x + 1)**Rational(3, 4)) == \ + r"\left(x + 1\right)^{\frac{3}{4}}" + assert latex((x + 1)**Rational(3, 4), fold_frac_powers=True) == \ + r"\left(x + 1\right)^{3/4}" + assert latex(AlgebraicNumber(sqrt(2))) == r"\sqrt{2}" + assert latex(AlgebraicNumber(sqrt(2), [3, -7])) == r"-7 + 3 \sqrt{2}" + assert latex(AlgebraicNumber(sqrt(2), alias='alpha')) == r"\alpha" + assert latex(AlgebraicNumber(sqrt(2), [3, -7], alias='alpha')) == \ + r"3 \alpha - 7" + assert latex(AlgebraicNumber(2**(S(1)/3), [1, 3, -7], alias='beta')) == \ + r"\beta^{2} + 3 \beta - 7" + + k = ZZ.cyclotomic_field(5) + assert latex(k.ext.field_element([1, 2, 3, 4])) == \ + r"\zeta^{3} + 2 \zeta^{2} + 3 \zeta + 4" + assert latex(k.ext.field_element([1, 2, 3, 4]), order='old') == \ + r"4 + 3 \zeta + 2 \zeta^{2} + \zeta^{3}" + assert latex(k.primes_above(19)[0]) == \ + r"\left(19, \zeta^{2} + 5 \zeta + 1\right)" + assert latex(k.primes_above(19)[0], order='old') == \ + r"\left(19, 1 + 5 \zeta + \zeta^{2}\right)" + assert latex(k.primes_above(7)[0]) == r"\left(7\right)" + + assert latex(1.5e20*x) == r"1.5 \cdot 10^{20} x" + assert latex(1.5e20*x, mul_symbol='dot') == r"1.5 \cdot 10^{20} \cdot x" + assert latex(1.5e20*x, mul_symbol='times') == \ + r"1.5 \times 10^{20} \times x" + + assert latex(1/sin(x)) == r"\frac{1}{\sin{\left(x \right)}}" + assert latex(sin(x)**-1) == r"\frac{1}{\sin{\left(x \right)}}" + assert latex(sin(x)**Rational(3, 2)) == \ + r"\sin^{\frac{3}{2}}{\left(x \right)}" + assert latex(sin(x)**Rational(3, 2), fold_frac_powers=True) == \ + r"\sin^{3/2}{\left(x \right)}" + + assert latex(~x) == r"\neg x" + assert latex(x & y) == r"x \wedge y" + assert latex(x & y & z) == r"x \wedge y \wedge z" + assert latex(x | y) == r"x \vee y" + assert latex(x | y | z) == r"x \vee y \vee z" + assert latex((x & y) | z) == r"z \vee \left(x \wedge y\right)" + assert latex(Implies(x, y)) == r"x \Rightarrow y" + assert latex(~(x >> ~y)) == r"x \not\Rightarrow \neg y" + assert latex(Implies(Or(x,y), z)) == r"\left(x \vee y\right) \Rightarrow z" + assert latex(Implies(z, Or(x,y))) == r"z \Rightarrow \left(x \vee y\right)" + assert latex(~(x & y)) == r"\neg \left(x \wedge y\right)" + + assert latex(~x, symbol_names={x: "x_i"}) == r"\neg x_i" + assert latex(x & y, symbol_names={x: "x_i", y: "y_i"}) == \ + r"x_i \wedge y_i" + assert latex(x & y & z, symbol_names={x: "x_i", y: "y_i", z: "z_i"}) == \ + r"x_i \wedge y_i \wedge z_i" + assert latex(x | y, symbol_names={x: "x_i", y: "y_i"}) == r"x_i \vee y_i" + assert latex(x | y | z, symbol_names={x: "x_i", y: "y_i", z: "z_i"}) == \ + r"x_i \vee y_i \vee z_i" + assert latex((x & y) | z, symbol_names={x: "x_i", y: "y_i", z: "z_i"}) == \ + r"z_i \vee \left(x_i \wedge y_i\right)" + assert latex(Implies(x, y), symbol_names={x: "x_i", y: "y_i"}) == \ + r"x_i \Rightarrow y_i" + assert latex(Pow(Rational(1, 3), -1, evaluate=False)) == r"\frac{1}{\frac{1}{3}}" + assert latex(Pow(Rational(1, 3), -2, evaluate=False)) == r"\frac{1}{(\frac{1}{3})^{2}}" + assert latex(Pow(Integer(1)/100, -1, evaluate=False)) == r"\frac{1}{\frac{1}{100}}" + + p = Symbol('p', positive=True) + assert latex(exp(-p)*log(p)) == r"e^{- p} \log{\left(p \right)}" + + assert latex(Pow(Rational(2, 3), -1, evaluate=False)) == r'\frac{1}{\frac{2}{3}}' + assert latex(Pow(Rational(4, 3), -1, evaluate=False)) == r'\frac{1}{\frac{4}{3}}' + assert latex(Pow(Rational(-3, 4), -1, evaluate=False)) == r'\frac{1}{- \frac{3}{4}}' + assert latex(Pow(Rational(-4, 4), -1, evaluate=False)) == r'\frac{1}{-1}' + assert latex(Pow(Rational(1, 3), -1, evaluate=False)) == r'\frac{1}{\frac{1}{3}}' + assert latex(Pow(Rational(-1, 3), -1, evaluate=False)) == r'\frac{1}{- \frac{1}{3}}' + + +def test_latex_builtins(): + assert latex(True) == r"\text{True}" + assert latex(False) == r"\text{False}" + assert latex(None) == r"\text{None}" + assert latex(true) == r"\text{True}" + assert latex(false) == r'\text{False}' + + +def test_latex_SingularityFunction(): + assert latex(SingularityFunction(x, 4, 5)) == \ + r"{\left\langle x - 4 \right\rangle}^{5}" + assert latex(SingularityFunction(x, -3, 4)) == \ + r"{\left\langle x + 3 \right\rangle}^{4}" + assert latex(SingularityFunction(x, 0, 4)) == \ + r"{\left\langle x \right\rangle}^{4}" + assert latex(SingularityFunction(x, a, n)) == \ + r"{\left\langle - a + x \right\rangle}^{n}" + assert latex(SingularityFunction(x, 4, -2)) == \ + r"{\left\langle x - 4 \right\rangle}^{-2}" + assert latex(SingularityFunction(x, 4, -1)) == \ + r"{\left\langle x - 4 \right\rangle}^{-1}" + + assert latex(SingularityFunction(x, 4, 5)**3) == \ + r"{\left({\langle x - 4 \rangle}^{5}\right)}^{3}" + assert latex(SingularityFunction(x, -3, 4)**3) == \ + r"{\left({\langle x + 3 \rangle}^{4}\right)}^{3}" + assert latex(SingularityFunction(x, 0, 4)**3) == \ + r"{\left({\langle x \rangle}^{4}\right)}^{3}" + assert latex(SingularityFunction(x, a, n)**3) == \ + r"{\left({\langle - a + x \rangle}^{n}\right)}^{3}" + assert latex(SingularityFunction(x, 4, -2)**3) == \ + r"{\left({\langle x - 4 \rangle}^{-2}\right)}^{3}" + assert latex((SingularityFunction(x, 4, -1)**3)**3) == \ + r"{\left({\langle x - 4 \rangle}^{-1}\right)}^{9}" + + +def test_latex_cycle(): + assert latex(Cycle(1, 2, 4)) == r"\left( 1\; 2\; 4\right)" + assert latex(Cycle(1, 2)(4, 5, 6)) == \ + r"\left( 1\; 2\right)\left( 4\; 5\; 6\right)" + assert latex(Cycle()) == r"\left( \right)" + + +def test_latex_permutation(): + assert latex(Permutation(1, 2, 4)) == r"\left( 1\; 2\; 4\right)" + assert latex(Permutation(1, 2)(4, 5, 6)) == \ + r"\left( 1\; 2\right)\left( 4\; 5\; 6\right)" + assert latex(Permutation()) == r"\left( \right)" + assert latex(Permutation(2, 4)*Permutation(5)) == \ + r"\left( 2\; 4\right)\left( 5\right)" + assert latex(Permutation(5)) == r"\left( 5\right)" + + assert latex(Permutation(0, 1), perm_cyclic=False) == \ + r"\begin{pmatrix} 0 & 1 \\ 1 & 0 \end{pmatrix}" + assert latex(Permutation(0, 1)(2, 3), perm_cyclic=False) == \ + r"\begin{pmatrix} 0 & 1 & 2 & 3 \\ 1 & 0 & 3 & 2 \end{pmatrix}" + assert latex(Permutation(), perm_cyclic=False) == \ + r"\left( \right)" + + with warns_deprecated_sympy(): + old_print_cyclic = Permutation.print_cyclic + Permutation.print_cyclic = False + assert latex(Permutation(0, 1)(2, 3)) == \ + r"\begin{pmatrix} 0 & 1 & 2 & 3 \\ 1 & 0 & 3 & 2 \end{pmatrix}" + Permutation.print_cyclic = old_print_cyclic + +def test_latex_Float(): + assert latex(Float(1.0e100)) == r"1.0 \cdot 10^{100}" + assert latex(Float(1.0e-100)) == r"1.0 \cdot 10^{-100}" + assert latex(Float(1.0e-100), mul_symbol="times") == \ + r"1.0 \times 10^{-100}" + assert latex(Float('10000.0'), full_prec=False, min=-2, max=2) == \ + r"1.0 \cdot 10^{4}" + assert latex(Float('10000.0'), full_prec=False, min=-2, max=4) == \ + r"1.0 \cdot 10^{4}" + assert latex(Float('10000.0'), full_prec=False, min=-2, max=5) == \ + r"10000.0" + assert latex(Float('0.099999'), full_prec=True, min=-2, max=5) == \ + r"9.99990000000000 \cdot 10^{-2}" + + +def test_latex_vector_expressions(): + A = CoordSys3D('A') + + assert latex(Cross(A.i, A.j*A.x*3+A.k)) == \ + r"\mathbf{\hat{i}_{A}} \times \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}} + \mathbf{\hat{k}_{A}}\right)" + assert latex(Cross(A.i, A.j)) == \ + r"\mathbf{\hat{i}_{A}} \times \mathbf{\hat{j}_{A}}" + assert latex(x*Cross(A.i, A.j)) == \ + r"x \left(\mathbf{\hat{i}_{A}} \times \mathbf{\hat{j}_{A}}\right)" + assert latex(Cross(x*A.i, A.j)) == \ + r'- \mathbf{\hat{j}_{A}} \times \left(\left(x\right)\mathbf{\hat{i}_{A}}\right)' + + assert latex(Curl(3*A.x*A.j)) == \ + r"\nabla\times \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(Curl(3*A.x*A.j+A.i)) == \ + r"\nabla\times \left(\mathbf{\hat{i}_{A}} + \left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(Curl(3*x*A.x*A.j)) == \ + r"\nabla\times \left(\left(3 \mathbf{{x}_{A}} x\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(x*Curl(3*A.x*A.j)) == \ + r"x \left(\nabla\times \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)\right)" + + assert latex(Divergence(3*A.x*A.j+A.i)) == \ + r"\nabla\cdot \left(\mathbf{\hat{i}_{A}} + \left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(Divergence(3*A.x*A.j)) == \ + r"\nabla\cdot \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(x*Divergence(3*A.x*A.j)) == \ + r"x \left(\nabla\cdot \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)\right)" + + assert latex(Dot(A.i, A.j*A.x*3+A.k)) == \ + r"\mathbf{\hat{i}_{A}} \cdot \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}} + \mathbf{\hat{k}_{A}}\right)" + assert latex(Dot(A.i, A.j)) == \ + r"\mathbf{\hat{i}_{A}} \cdot \mathbf{\hat{j}_{A}}" + assert latex(Dot(x*A.i, A.j)) == \ + r"\mathbf{\hat{j}_{A}} \cdot \left(\left(x\right)\mathbf{\hat{i}_{A}}\right)" + assert latex(x*Dot(A.i, A.j)) == \ + r"x \left(\mathbf{\hat{i}_{A}} \cdot \mathbf{\hat{j}_{A}}\right)" + + assert latex(Gradient(A.x)) == r"\nabla \mathbf{{x}_{A}}" + assert latex(Gradient(A.x + 3*A.y)) == \ + r"\nabla \left(\mathbf{{x}_{A}} + 3 \mathbf{{y}_{A}}\right)" + assert latex(x*Gradient(A.x)) == r"x \left(\nabla \mathbf{{x}_{A}}\right)" + assert latex(Gradient(x*A.x)) == r"\nabla \left(\mathbf{{x}_{A}} x\right)" + + assert latex(Laplacian(A.x)) == r"\Delta \mathbf{{x}_{A}}" + assert latex(Laplacian(A.x + 3*A.y)) == \ + r"\Delta \left(\mathbf{{x}_{A}} + 3 \mathbf{{y}_{A}}\right)" + assert latex(x*Laplacian(A.x)) == r"x \left(\Delta \mathbf{{x}_{A}}\right)" + assert latex(Laplacian(x*A.x)) == r"\Delta \left(\mathbf{{x}_{A}} x\right)" + +def test_latex_symbols(): + Gamma, lmbda, rho = symbols('Gamma, lambda, rho') + tau, Tau, TAU, taU = symbols('tau, Tau, TAU, taU') + assert latex(tau) == r"\tau" + assert latex(Tau) == r"\mathrm{T}" + assert latex(TAU) == r"\tau" + assert latex(taU) == r"\tau" + # Check that all capitalized greek letters are handled explicitly + capitalized_letters = {l.capitalize() for l in greek_letters_set} + assert len(capitalized_letters - set(tex_greek_dictionary.keys())) == 0 + assert latex(Gamma + lmbda) == r"\Gamma + \lambda" + assert latex(Gamma * lmbda) == r"\Gamma \lambda" + assert latex(Symbol('q1')) == r"q_{1}" + assert latex(Symbol('q21')) == r"q_{21}" + assert latex(Symbol('epsilon0')) == r"\epsilon_{0}" + assert latex(Symbol('omega1')) == r"\omega_{1}" + assert latex(Symbol('91')) == r"91" + assert latex(Symbol('alpha_new')) == r"\alpha_{new}" + assert latex(Symbol('C^orig')) == r"C^{orig}" + assert latex(Symbol('x^alpha')) == r"x^{\alpha}" + assert latex(Symbol('beta^alpha')) == r"\beta^{\alpha}" + assert latex(Symbol('e^Alpha')) == r"e^{\mathrm{A}}" + assert latex(Symbol('omega_alpha^beta')) == r"\omega^{\beta}_{\alpha}" + assert latex(Symbol('omega') ** Symbol('beta')) == r"\omega^{\beta}" + + +@XFAIL +def test_latex_symbols_failing(): + rho, mass, volume = symbols('rho, mass, volume') + assert latex( + volume * rho == mass) == r"\rho \mathrm{volume} = \mathrm{mass}" + assert latex(volume / mass * rho == 1) == \ + r"\rho \mathrm{volume} {\mathrm{mass}}^{(-1)} = 1" + assert latex(mass**3 * volume**3) == \ + r"{\mathrm{mass}}^{3} \cdot {\mathrm{volume}}^{3}" + + +@_both_exp_pow +def test_latex_functions(): + assert latex(exp(x)) == r"e^{x}" + assert latex(exp(1) + exp(2)) == r"e + e^{2}" + + f = Function('f') + assert latex(f(x)) == r'f{\left(x \right)}' + assert latex(f) == r'f' + + g = Function('g') + assert latex(g(x, y)) == r'g{\left(x,y \right)}' + assert latex(g) == r'g' + + h = Function('h') + assert latex(h(x, y, z)) == r'h{\left(x,y,z \right)}' + assert latex(h) == r'h' + + Li = Function('Li') + assert latex(Li) == r'\operatorname{Li}' + assert latex(Li(x)) == r'\operatorname{Li}{\left(x \right)}' + + mybeta = Function('beta') + # not to be confused with the beta function + assert latex(mybeta(x, y, z)) == r"\beta{\left(x,y,z \right)}" + assert latex(beta(x, y)) == r'\operatorname{B}\left(x, y\right)' + assert latex(beta(x, evaluate=False)) == r'\operatorname{B}\left(x, x\right)' + assert latex(beta(x, y)**2) == r'\operatorname{B}^{2}\left(x, y\right)' + assert latex(mybeta(x)) == r"\beta{\left(x \right)}" + assert latex(mybeta) == r"\beta" + + g = Function('gamma') + # not to be confused with the gamma function + assert latex(g(x, y, z)) == r"\gamma{\left(x,y,z \right)}" + assert latex(g(x)) == r"\gamma{\left(x \right)}" + assert latex(g) == r"\gamma" + + a_1 = Function('a_1') + assert latex(a_1) == r"a_{1}" + assert latex(a_1(x)) == r"a_{1}{\left(x \right)}" + assert latex(Function('a_1')) == r"a_{1}" + + # Issue #16925 + # multi letter function names + # > simple + assert latex(Function('ab')) == r"\operatorname{ab}" + assert latex(Function('ab1')) == r"\operatorname{ab}_{1}" + assert latex(Function('ab12')) == r"\operatorname{ab}_{12}" + assert latex(Function('ab_1')) == r"\operatorname{ab}_{1}" + assert latex(Function('ab_12')) == r"\operatorname{ab}_{12}" + assert latex(Function('ab_c')) == r"\operatorname{ab}_{c}" + assert latex(Function('ab_cd')) == r"\operatorname{ab}_{cd}" + # > with argument + assert latex(Function('ab')(Symbol('x'))) == r"\operatorname{ab}{\left(x \right)}" + assert latex(Function('ab1')(Symbol('x'))) == r"\operatorname{ab}_{1}{\left(x \right)}" + assert latex(Function('ab12')(Symbol('x'))) == r"\operatorname{ab}_{12}{\left(x \right)}" + assert latex(Function('ab_1')(Symbol('x'))) == r"\operatorname{ab}_{1}{\left(x \right)}" + assert latex(Function('ab_c')(Symbol('x'))) == r"\operatorname{ab}_{c}{\left(x \right)}" + assert latex(Function('ab_cd')(Symbol('x'))) == r"\operatorname{ab}_{cd}{\left(x \right)}" + + # > with power + # does not work on functions without brackets + + # > with argument and power combined + assert latex(Function('ab')()**2) == r"\operatorname{ab}^{2}{\left( \right)}" + assert latex(Function('ab1')()**2) == r"\operatorname{ab}_{1}^{2}{\left( \right)}" + assert latex(Function('ab12')()**2) == r"\operatorname{ab}_{12}^{2}{\left( \right)}" + assert latex(Function('ab_1')()**2) == r"\operatorname{ab}_{1}^{2}{\left( \right)}" + assert latex(Function('ab_12')()**2) == r"\operatorname{ab}_{12}^{2}{\left( \right)}" + assert latex(Function('ab')(Symbol('x'))**2) == r"\operatorname{ab}^{2}{\left(x \right)}" + assert latex(Function('ab1')(Symbol('x'))**2) == r"\operatorname{ab}_{1}^{2}{\left(x \right)}" + assert latex(Function('ab12')(Symbol('x'))**2) == r"\operatorname{ab}_{12}^{2}{\left(x \right)}" + assert latex(Function('ab_1')(Symbol('x'))**2) == r"\operatorname{ab}_{1}^{2}{\left(x \right)}" + assert latex(Function('ab_12')(Symbol('x'))**2) == \ + r"\operatorname{ab}_{12}^{2}{\left(x \right)}" + + # single letter function names + # > simple + assert latex(Function('a')) == r"a" + assert latex(Function('a1')) == r"a_{1}" + assert latex(Function('a12')) == r"a_{12}" + assert latex(Function('a_1')) == r"a_{1}" + assert latex(Function('a_12')) == r"a_{12}" + + # > with argument + assert latex(Function('a')()) == r"a{\left( \right)}" + assert latex(Function('a1')()) == r"a_{1}{\left( \right)}" + assert latex(Function('a12')()) == r"a_{12}{\left( \right)}" + assert latex(Function('a_1')()) == r"a_{1}{\left( \right)}" + assert latex(Function('a_12')()) == r"a_{12}{\left( \right)}" + + # > with power + # does not work on functions without brackets + + # > with argument and power combined + assert latex(Function('a')()**2) == r"a^{2}{\left( \right)}" + assert latex(Function('a1')()**2) == r"a_{1}^{2}{\left( \right)}" + assert latex(Function('a12')()**2) == r"a_{12}^{2}{\left( \right)}" + assert latex(Function('a_1')()**2) == r"a_{1}^{2}{\left( \right)}" + assert latex(Function('a_12')()**2) == r"a_{12}^{2}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**2) == r"a^{2}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**2) == r"a_{1}^{2}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**2) == r"a_{12}^{2}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**2) == r"a_{1}^{2}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**2) == r"a_{12}^{2}{\left(x \right)}" + + assert latex(Function('a')()**32) == r"a^{32}{\left( \right)}" + assert latex(Function('a1')()**32) == r"a_{1}^{32}{\left( \right)}" + assert latex(Function('a12')()**32) == r"a_{12}^{32}{\left( \right)}" + assert latex(Function('a_1')()**32) == r"a_{1}^{32}{\left( \right)}" + assert latex(Function('a_12')()**32) == r"a_{12}^{32}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**32) == r"a^{32}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**32) == r"a_{1}^{32}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**32) == r"a_{12}^{32}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**32) == r"a_{1}^{32}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**32) == r"a_{12}^{32}{\left(x \right)}" + + assert latex(Function('a')()**a) == r"a^{a}{\left( \right)}" + assert latex(Function('a1')()**a) == r"a_{1}^{a}{\left( \right)}" + assert latex(Function('a12')()**a) == r"a_{12}^{a}{\left( \right)}" + assert latex(Function('a_1')()**a) == r"a_{1}^{a}{\left( \right)}" + assert latex(Function('a_12')()**a) == r"a_{12}^{a}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**a) == r"a^{a}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**a) == r"a_{1}^{a}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**a) == r"a_{12}^{a}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**a) == r"a_{1}^{a}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**a) == r"a_{12}^{a}{\left(x \right)}" + + ab = Symbol('ab') + assert latex(Function('a')()**ab) == r"a^{ab}{\left( \right)}" + assert latex(Function('a1')()**ab) == r"a_{1}^{ab}{\left( \right)}" + assert latex(Function('a12')()**ab) == r"a_{12}^{ab}{\left( \right)}" + assert latex(Function('a_1')()**ab) == r"a_{1}^{ab}{\left( \right)}" + assert latex(Function('a_12')()**ab) == r"a_{12}^{ab}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**ab) == r"a^{ab}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**ab) == r"a_{1}^{ab}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**ab) == r"a_{12}^{ab}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**ab) == r"a_{1}^{ab}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**ab) == r"a_{12}^{ab}{\left(x \right)}" + + assert latex(Function('a^12')(x)) == R"a^{12}{\left(x \right)}" + assert latex(Function('a^12')(x) ** ab) == R"\left(a^{12}\right)^{ab}{\left(x \right)}" + assert latex(Function('a__12')(x)) == R"a^{12}{\left(x \right)}" + assert latex(Function('a__12')(x) ** ab) == R"\left(a^{12}\right)^{ab}{\left(x \right)}" + assert latex(Function('a_1__1_2')(x)) == R"a^{1}_{1 2}{\left(x \right)}" + + # issue 5868 + omega1 = Function('omega1') + assert latex(omega1) == r"\omega_{1}" + assert latex(omega1(x)) == r"\omega_{1}{\left(x \right)}" + + assert latex(sin(x)) == r"\sin{\left(x \right)}" + assert latex(sin(x), fold_func_brackets=True) == r"\sin {x}" + assert latex(sin(2*x**2), fold_func_brackets=True) == \ + r"\sin {2 x^{2}}" + assert latex(sin(x**2), fold_func_brackets=True) == \ + r"\sin {x^{2}}" + + assert latex(asin(x)**2) == r"\operatorname{asin}^{2}{\left(x \right)}" + assert latex(asin(x)**2, inv_trig_style="full") == \ + r"\arcsin^{2}{\left(x \right)}" + assert latex(asin(x)**2, inv_trig_style="power") == \ + r"\sin^{-1}{\left(x \right)}^{2}" + assert latex(asin(x**2), inv_trig_style="power", + fold_func_brackets=True) == \ + r"\sin^{-1} {x^{2}}" + assert latex(acsc(x), inv_trig_style="full") == \ + r"\operatorname{arccsc}{\left(x \right)}" + assert latex(asinh(x), inv_trig_style="full") == \ + r"\operatorname{arsinh}{\left(x \right)}" + + assert latex(factorial(k)) == r"k!" + assert latex(factorial(-k)) == r"\left(- k\right)!" + assert latex(factorial(k)**2) == r"k!^{2}" + + assert latex(subfactorial(k)) == r"!k" + assert latex(subfactorial(-k)) == r"!\left(- k\right)" + assert latex(subfactorial(k)**2) == r"\left(!k\right)^{2}" + + assert latex(factorial2(k)) == r"k!!" + assert latex(factorial2(-k)) == r"\left(- k\right)!!" + assert latex(factorial2(k)**2) == r"k!!^{2}" + + assert latex(binomial(2, k)) == r"{\binom{2}{k}}" + assert latex(binomial(2, k)**2) == r"{\binom{2}{k}}^{2}" + + assert latex(FallingFactorial(3, k)) == r"{\left(3\right)}_{k}" + assert latex(RisingFactorial(3, k)) == r"{3}^{\left(k\right)}" + + assert latex(floor(x)) == r"\left\lfloor{x}\right\rfloor" + assert latex(ceiling(x)) == r"\left\lceil{x}\right\rceil" + assert latex(frac(x)) == r"\operatorname{frac}{\left(x\right)}" + assert latex(floor(x)**2) == r"\left\lfloor{x}\right\rfloor^{2}" + assert latex(ceiling(x)**2) == r"\left\lceil{x}\right\rceil^{2}" + assert latex(frac(x)**2) == r"\operatorname{frac}{\left(x\right)}^{2}" + + assert latex(Min(x, 2, x**3)) == r"\min\left(2, x, x^{3}\right)" + assert latex(Min(x, y)**2) == r"\min\left(x, y\right)^{2}" + assert latex(Max(x, 2, x**3)) == r"\max\left(2, x, x^{3}\right)" + assert latex(Max(x, y)**2) == r"\max\left(x, y\right)^{2}" + assert latex(Abs(x)) == r"\left|{x}\right|" + assert latex(Abs(x)**2) == r"\left|{x}\right|^{2}" + assert latex(re(x)) == r"\operatorname{re}{\left(x\right)}" + assert latex(re(x + y)) == \ + r"\operatorname{re}{\left(x\right)} + \operatorname{re}{\left(y\right)}" + assert latex(im(x)) == r"\operatorname{im}{\left(x\right)}" + assert latex(conjugate(x)) == r"\overline{x}" + assert latex(conjugate(x)**2) == r"\overline{x}^{2}" + assert latex(conjugate(x**2)) == r"\overline{x}^{2}" + assert latex(gamma(x)) == r"\Gamma\left(x\right)" + w = Wild('w') + assert latex(gamma(w)) == r"\Gamma\left(w\right)" + assert latex(Order(x)) == r"O\left(x\right)" + assert latex(Order(x, x)) == r"O\left(x\right)" + assert latex(Order(x, (x, 0))) == r"O\left(x\right)" + assert latex(Order(x, (x, oo))) == r"O\left(x; x\rightarrow \infty\right)" + assert latex(Order(x - y, (x, y))) == \ + r"O\left(x - y; x\rightarrow y\right)" + assert latex(Order(x, x, y)) == \ + r"O\left(x; \left( x, \ y\right)\rightarrow \left( 0, \ 0\right)\right)" + assert latex(Order(x, x, y)) == \ + r"O\left(x; \left( x, \ y\right)\rightarrow \left( 0, \ 0\right)\right)" + assert latex(Order(x, (x, oo), (y, oo))) == \ + r"O\left(x; \left( x, \ y\right)\rightarrow \left( \infty, \ \infty\right)\right)" + assert latex(lowergamma(x, y)) == r'\gamma\left(x, y\right)' + assert latex(lowergamma(x, y)**2) == r'\gamma^{2}\left(x, y\right)' + assert latex(uppergamma(x, y)) == r'\Gamma\left(x, y\right)' + assert latex(uppergamma(x, y)**2) == r'\Gamma^{2}\left(x, y\right)' + + assert latex(cot(x)) == r'\cot{\left(x \right)}' + assert latex(coth(x)) == r'\coth{\left(x \right)}' + assert latex(re(x)) == r'\operatorname{re}{\left(x\right)}' + assert latex(im(x)) == r'\operatorname{im}{\left(x\right)}' + assert latex(root(x, y)) == r'x^{\frac{1}{y}}' + assert latex(arg(x)) == r'\arg{\left(x \right)}' + + assert latex(zeta(x)) == r"\zeta\left(x\right)" + assert latex(zeta(x)**2) == r"\zeta^{2}\left(x\right)" + assert latex(zeta(x, y)) == r"\zeta\left(x, y\right)" + assert latex(zeta(x, y)**2) == r"\zeta^{2}\left(x, y\right)" + assert latex(dirichlet_eta(x)) == r"\eta\left(x\right)" + assert latex(dirichlet_eta(x)**2) == r"\eta^{2}\left(x\right)" + assert latex(polylog(x, y)) == r"\operatorname{Li}_{x}\left(y\right)" + assert latex( + polylog(x, y)**2) == r"\operatorname{Li}_{x}^{2}\left(y\right)" + assert latex(lerchphi(x, y, n)) == r"\Phi\left(x, y, n\right)" + assert latex(lerchphi(x, y, n)**2) == r"\Phi^{2}\left(x, y, n\right)" + assert latex(stieltjes(x)) == r"\gamma_{x}" + assert latex(stieltjes(x)**2) == r"\gamma_{x}^{2}" + assert latex(stieltjes(x, y)) == r"\gamma_{x}\left(y\right)" + assert latex(stieltjes(x, y)**2) == r"\gamma_{x}\left(y\right)^{2}" + + assert latex(elliptic_k(z)) == r"K\left(z\right)" + assert latex(elliptic_k(z)**2) == r"K^{2}\left(z\right)" + assert latex(elliptic_f(x, y)) == r"F\left(x\middle| y\right)" + assert latex(elliptic_f(x, y)**2) == r"F^{2}\left(x\middle| y\right)" + assert latex(elliptic_e(x, y)) == r"E\left(x\middle| y\right)" + assert latex(elliptic_e(x, y)**2) == r"E^{2}\left(x\middle| y\right)" + assert latex(elliptic_e(z)) == r"E\left(z\right)" + assert latex(elliptic_e(z)**2) == r"E^{2}\left(z\right)" + assert latex(elliptic_pi(x, y, z)) == r"\Pi\left(x; y\middle| z\right)" + assert latex(elliptic_pi(x, y, z)**2) == \ + r"\Pi^{2}\left(x; y\middle| z\right)" + assert latex(elliptic_pi(x, y)) == r"\Pi\left(x\middle| y\right)" + assert latex(elliptic_pi(x, y)**2) == r"\Pi^{2}\left(x\middle| y\right)" + + assert latex(Ei(x)) == r'\operatorname{Ei}{\left(x \right)}' + assert latex(Ei(x)**2) == r'\operatorname{Ei}^{2}{\left(x \right)}' + assert latex(expint(x, y)) == r'\operatorname{E}_{x}\left(y\right)' + assert latex(expint(x, y)**2) == r'\operatorname{E}_{x}^{2}\left(y\right)' + assert latex(Shi(x)**2) == r'\operatorname{Shi}^{2}{\left(x \right)}' + assert latex(Si(x)**2) == r'\operatorname{Si}^{2}{\left(x \right)}' + assert latex(Ci(x)**2) == r'\operatorname{Ci}^{2}{\left(x \right)}' + assert latex(Chi(x)**2) == r'\operatorname{Chi}^{2}\left(x\right)' + assert latex(Chi(x)) == r'\operatorname{Chi}\left(x\right)' + assert latex(jacobi(n, a, b, x)) == \ + r'P_{n}^{\left(a,b\right)}\left(x\right)' + assert latex(jacobi(n, a, b, x)**2) == \ + r'\left(P_{n}^{\left(a,b\right)}\left(x\right)\right)^{2}' + assert latex(gegenbauer(n, a, x)) == \ + r'C_{n}^{\left(a\right)}\left(x\right)' + assert latex(gegenbauer(n, a, x)**2) == \ + r'\left(C_{n}^{\left(a\right)}\left(x\right)\right)^{2}' + assert latex(chebyshevt(n, x)) == r'T_{n}\left(x\right)' + assert latex(chebyshevt(n, x)**2) == \ + r'\left(T_{n}\left(x\right)\right)^{2}' + assert latex(chebyshevu(n, x)) == r'U_{n}\left(x\right)' + assert latex(chebyshevu(n, x)**2) == \ + r'\left(U_{n}\left(x\right)\right)^{2}' + assert latex(legendre(n, x)) == r'P_{n}\left(x\right)' + assert latex(legendre(n, x)**2) == r'\left(P_{n}\left(x\right)\right)^{2}' + assert latex(assoc_legendre(n, a, x)) == \ + r'P_{n}^{\left(a\right)}\left(x\right)' + assert latex(assoc_legendre(n, a, x)**2) == \ + r'\left(P_{n}^{\left(a\right)}\left(x\right)\right)^{2}' + assert latex(laguerre(n, x)) == r'L_{n}\left(x\right)' + assert latex(laguerre(n, x)**2) == r'\left(L_{n}\left(x\right)\right)^{2}' + assert latex(assoc_laguerre(n, a, x)) == \ + r'L_{n}^{\left(a\right)}\left(x\right)' + assert latex(assoc_laguerre(n, a, x)**2) == \ + r'\left(L_{n}^{\left(a\right)}\left(x\right)\right)^{2}' + assert latex(hermite(n, x)) == r'H_{n}\left(x\right)' + assert latex(hermite(n, x)**2) == r'\left(H_{n}\left(x\right)\right)^{2}' + + theta = Symbol("theta", real=True) + phi = Symbol("phi", real=True) + assert latex(Ynm(n, m, theta, phi)) == r'Y_{n}^{m}\left(\theta,\phi\right)' + assert latex(Ynm(n, m, theta, phi)**3) == \ + r'\left(Y_{n}^{m}\left(\theta,\phi\right)\right)^{3}' + assert latex(Znm(n, m, theta, phi)) == r'Z_{n}^{m}\left(\theta,\phi\right)' + assert latex(Znm(n, m, theta, phi)**3) == \ + r'\left(Z_{n}^{m}\left(\theta,\phi\right)\right)^{3}' + + # Test latex printing of function names with "_" + assert latex(polar_lift(0)) == \ + r"\operatorname{polar\_lift}{\left(0 \right)}" + assert latex(polar_lift(0)**3) == \ + r"\operatorname{polar\_lift}^{3}{\left(0 \right)}" + + assert latex(totient(n)) == r'\phi\left(n\right)' + assert latex(totient(n) ** 2) == r'\left(\phi\left(n\right)\right)^{2}' + + assert latex(reduced_totient(n)) == r'\lambda\left(n\right)' + assert latex(reduced_totient(n) ** 2) == \ + r'\left(\lambda\left(n\right)\right)^{2}' + + assert latex(divisor_sigma(x)) == r"\sigma\left(x\right)" + assert latex(divisor_sigma(x)**2) == r"\sigma^{2}\left(x\right)" + assert latex(divisor_sigma(x, y)) == r"\sigma_y\left(x\right)" + assert latex(divisor_sigma(x, y)**2) == r"\sigma^{2}_y\left(x\right)" + + assert latex(udivisor_sigma(x)) == r"\sigma^*\left(x\right)" + assert latex(udivisor_sigma(x)**2) == r"\sigma^*^{2}\left(x\right)" + assert latex(udivisor_sigma(x, y)) == r"\sigma^*_y\left(x\right)" + assert latex(udivisor_sigma(x, y)**2) == r"\sigma^*^{2}_y\left(x\right)" + + assert latex(primenu(n)) == r'\nu\left(n\right)' + assert latex(primenu(n) ** 2) == r'\left(\nu\left(n\right)\right)^{2}' + + assert latex(primeomega(n)) == r'\Omega\left(n\right)' + assert latex(primeomega(n) ** 2) == \ + r'\left(\Omega\left(n\right)\right)^{2}' + + assert latex(LambertW(n)) == r'W\left(n\right)' + assert latex(LambertW(n, -1)) == r'W_{-1}\left(n\right)' + assert latex(LambertW(n, k)) == r'W_{k}\left(n\right)' + assert latex(LambertW(n) * LambertW(n)) == r"W^{2}\left(n\right)" + assert latex(Pow(LambertW(n), 2)) == r"W^{2}\left(n\right)" + assert latex(LambertW(n)**k) == r"W^{k}\left(n\right)" + assert latex(LambertW(n, k)**p) == r"W^{p}_{k}\left(n\right)" + + assert latex(Mod(x, 7)) == r'x \bmod 7' + assert latex(Mod(x + 1, 7)) == r'\left(x + 1\right) \bmod 7' + assert latex(Mod(7, x + 1)) == r'7 \bmod \left(x + 1\right)' + assert latex(Mod(2 * x, 7)) == r'2 x \bmod 7' + assert latex(Mod(7, 2 * x)) == r'7 \bmod 2 x' + assert latex(Mod(x, 7) + 1) == r'\left(x \bmod 7\right) + 1' + assert latex(2 * Mod(x, 7)) == r'2 \left(x \bmod 7\right)' + assert latex(Mod(7, 2 * x)**n) == r'\left(7 \bmod 2 x\right)^{n}' + + # some unknown function name should get rendered with \operatorname + fjlkd = Function('fjlkd') + assert latex(fjlkd(x)) == r'\operatorname{fjlkd}{\left(x \right)}' + # even when it is referred to without an argument + assert latex(fjlkd) == r'\operatorname{fjlkd}' + + +# test that notation passes to subclasses of the same name only +def test_function_subclass_different_name(): + class mygamma(gamma): + pass + assert latex(mygamma) == r"\operatorname{mygamma}" + assert latex(mygamma(x)) == r"\operatorname{mygamma}{\left(x \right)}" + + +def test_hyper_printing(): + from sympy.abc import x, z + + assert latex(meijerg(Tuple(pi, pi, x), Tuple(1), + (0, 1), Tuple(1, 2, 3/pi), z)) == \ + r'{G_{4, 5}^{2, 3}\left(\begin{matrix} \pi, \pi, x & 1 \\0, 1 & 1, 2, '\ + r'\frac{3}{\pi} \end{matrix} \middle| {z} \right)}' + assert latex(meijerg(Tuple(), Tuple(1), (0,), Tuple(), z)) == \ + r'{G_{1, 1}^{1, 0}\left(\begin{matrix} & 1 \\0 & \end{matrix} \middle| {z} \right)}' + assert latex(hyper((x, 2), (3,), z)) == \ + r'{{}_{2}F_{1}\left(\begin{matrix} 2, x ' \ + r'\\ 3 \end{matrix}\middle| {z} \right)}' + assert latex(hyper(Tuple(), Tuple(1), z)) == \ + r'{{}_{0}F_{1}\left(\begin{matrix} ' \ + r'\\ 1 \end{matrix}\middle| {z} \right)}' + + +def test_latex_bessel(): + from sympy.functions.special.bessel import (besselj, bessely, besseli, + besselk, hankel1, hankel2, + jn, yn, hn1, hn2) + from sympy.abc import z + assert latex(besselj(n, z**2)**k) == r'J^{k}_{n}\left(z^{2}\right)' + assert latex(bessely(n, z)) == r'Y_{n}\left(z\right)' + assert latex(besseli(n, z)) == r'I_{n}\left(z\right)' + assert latex(besselk(n, z)) == r'K_{n}\left(z\right)' + assert latex(hankel1(n, z**2)**2) == \ + r'\left(H^{(1)}_{n}\left(z^{2}\right)\right)^{2}' + assert latex(hankel2(n, z)) == r'H^{(2)}_{n}\left(z\right)' + assert latex(jn(n, z)) == r'j_{n}\left(z\right)' + assert latex(yn(n, z)) == r'y_{n}\left(z\right)' + assert latex(hn1(n, z)) == r'h^{(1)}_{n}\left(z\right)' + assert latex(hn2(n, z)) == r'h^{(2)}_{n}\left(z\right)' + + +def test_latex_fresnel(): + from sympy.functions.special.error_functions import (fresnels, fresnelc) + from sympy.abc import z + assert latex(fresnels(z)) == r'S\left(z\right)' + assert latex(fresnelc(z)) == r'C\left(z\right)' + assert latex(fresnels(z)**2) == r'S^{2}\left(z\right)' + assert latex(fresnelc(z)**2) == r'C^{2}\left(z\right)' + + +def test_latex_brackets(): + assert latex((-1)**x) == r"\left(-1\right)^{x}" + + +def test_latex_indexed(): + Psi_symbol = Symbol('Psi_0', complex=True, real=False) + Psi_indexed = IndexedBase(Symbol('Psi', complex=True, real=False)) + symbol_latex = latex(Psi_symbol * conjugate(Psi_symbol)) + indexed_latex = latex(Psi_indexed[0] * conjugate(Psi_indexed[0])) + # \\overline{{\\Psi}_{0}} {\\Psi}_{0} vs. \\Psi_{0} \\overline{\\Psi_{0}} + assert symbol_latex == r'\Psi_{0} \overline{\Psi_{0}}' + assert indexed_latex == r'\overline{{\Psi}_{0}} {\Psi}_{0}' + + # Symbol('gamma') gives r'\gamma' + interval = '\\mathrel{..}\\nobreak ' + assert latex(Indexed('x1', Symbol('i'))) == r'{x_{1}}_{i}' + assert latex(Indexed('x2', Idx('i'))) == r'{x_{2}}_{i}' + assert latex(Indexed('x3', Idx('i', Symbol('N')))) == r'{x_{3}}_{{i}_{0'+interval+'N - 1}}' + assert latex(Indexed('x3', Idx('i', Symbol('N')+1))) == r'{x_{3}}_{{i}_{0'+interval+'N}}' + assert latex(Indexed('x4', Idx('i', (Symbol('a'),Symbol('b'))))) == r'{x_{4}}_{{i}_{a'+interval+'b}}' + assert latex(IndexedBase('gamma')) == r'\gamma' + assert latex(IndexedBase('a b')) == r'a b' + assert latex(IndexedBase('a_b')) == r'a_{b}' + + +def test_latex_derivatives(): + # regular "d" for ordinary derivatives + assert latex(diff(x**3, x, evaluate=False)) == \ + r"\frac{d}{d x} x^{3}" + assert latex(diff(sin(x) + x**2, x, evaluate=False)) == \ + r"\frac{d}{d x} \left(x^{2} + \sin{\left(x \right)}\right)" + assert latex(diff(diff(sin(x) + x**2, x, evaluate=False), evaluate=False))\ + == \ + r"\frac{d^{2}}{d x^{2}} \left(x^{2} + \sin{\left(x \right)}\right)" + assert latex(diff(diff(diff(sin(x) + x**2, x, evaluate=False), evaluate=False), evaluate=False)) == \ + r"\frac{d^{3}}{d x^{3}} \left(x^{2} + \sin{\left(x \right)}\right)" + + # \partial for partial derivatives + assert latex(diff(sin(x * y), x, evaluate=False)) == \ + r"\frac{\partial}{\partial x} \sin{\left(x y \right)}" + assert latex(diff(sin(x * y) + x**2, x, evaluate=False)) == \ + r"\frac{\partial}{\partial x} \left(x^{2} + \sin{\left(x y \right)}\right)" + assert latex(diff(diff(sin(x*y) + x**2, x, evaluate=False), x, evaluate=False)) == \ + r"\frac{\partial^{2}}{\partial x^{2}} \left(x^{2} + \sin{\left(x y \right)}\right)" + assert latex(diff(diff(diff(sin(x*y) + x**2, x, evaluate=False), x, evaluate=False), x, evaluate=False)) == \ + r"\frac{\partial^{3}}{\partial x^{3}} \left(x^{2} + \sin{\left(x y \right)}\right)" + + # mixed partial derivatives + f = Function("f") + assert latex(diff(diff(f(x, y), x, evaluate=False), y, evaluate=False)) == \ + r"\frac{\partial^{2}}{\partial y\partial x} " + latex(f(x, y)) + + assert latex(diff(diff(diff(f(x, y), x, evaluate=False), x, evaluate=False), y, evaluate=False)) == \ + r"\frac{\partial^{3}}{\partial y\partial x^{2}} " + latex(f(x, y)) + + # for negative nested Derivative + assert latex(diff(-diff(y**2,x,evaluate=False),x,evaluate=False)) == r'\frac{d}{d x} \left(- \frac{d}{d x} y^{2}\right)' + assert latex(diff(diff(-diff(diff(y,x,evaluate=False),x,evaluate=False),x,evaluate=False),x,evaluate=False)) == \ + r'\frac{d^{2}}{d x^{2}} \left(- \frac{d^{2}}{d x^{2}} y\right)' + + # use ordinary d when one of the variables has been integrated out + assert latex(diff(Integral(exp(-x*y), (x, 0, oo)), y, evaluate=False)) == \ + r"\frac{d}{d y} \int\limits_{0}^{\infty} e^{- x y}\, dx" + + # Derivative wrapped in power: + assert latex(diff(x, x, evaluate=False)**2) == \ + r"\left(\frac{d}{d x} x\right)^{2}" + + assert latex(diff(f(x), x)**2) == \ + r"\left(\frac{d}{d x} f{\left(x \right)}\right)^{2}" + + assert latex(diff(f(x), (x, n))) == \ + r"\frac{d^{n}}{d x^{n}} f{\left(x \right)}" + + x1 = Symbol('x1') + x2 = Symbol('x2') + assert latex(diff(f(x1, x2), x1)) == r'\frac{\partial}{\partial x_{1}} f{\left(x_{1},x_{2} \right)}' + + n1 = Symbol('n1') + assert latex(diff(f(x), (x, n1))) == r'\frac{d^{n_{1}}}{d x^{n_{1}}} f{\left(x \right)}' + + n2 = Symbol('n2') + assert latex(diff(f(x), (x, Max(n1, n2)))) == \ + r'\frac{d^{\max\left(n_{1}, n_{2}\right)}}{d x^{\max\left(n_{1}, n_{2}\right)}} f{\left(x \right)}' + + # set diff operator + assert latex(diff(f(x), x), diff_operator="rd") == r'\frac{\mathrm{d}}{\mathrm{d} x} f{\left(x \right)}' + + +def test_latex_subs(): + assert latex(Subs(x*y, (x, y), (1, 2))) == r'\left. x y \right|_{\substack{ x=1\\ y=2 }}' + + +def test_latex_integrals(): + assert latex(Integral(log(x), x)) == r"\int \log{\left(x \right)}\, dx" + assert latex(Integral(x**2, (x, 0, 1))) == \ + r"\int\limits_{0}^{1} x^{2}\, dx" + assert latex(Integral(x**2, (x, 10, 20))) == \ + r"\int\limits_{10}^{20} x^{2}\, dx" + assert latex(Integral(y*x**2, (x, 0, 1), y)) == \ + r"\int\int\limits_{0}^{1} x^{2} y\, dx\, dy" + assert latex(Integral(y*x**2, (x, 0, 1), y), mode='equation*') == \ + r"\begin{equation*}\int\int\limits_{0}^{1} x^{2} y\, dx\, dy\end{equation*}" + assert latex(Integral(y*x**2, (x, 0, 1), y), mode='equation*', itex=True) \ + == r"$$\int\int_{0}^{1} x^{2} y\, dx\, dy$$" + assert latex(Integral(x, (x, 0))) == r"\int\limits^{0} x\, dx" + assert latex(Integral(x*y, x, y)) == r"\iint x y\, dx\, dy" + assert latex(Integral(x*y*z, x, y, z)) == r"\iiint x y z\, dx\, dy\, dz" + assert latex(Integral(x*y*z*t, x, y, z, t)) == \ + r"\iiiint t x y z\, dx\, dy\, dz\, dt" + assert latex(Integral(x, x, x, x, x, x, x)) == \ + r"\int\int\int\int\int\int x\, dx\, dx\, dx\, dx\, dx\, dx" + assert latex(Integral(x, x, y, (z, 0, 1))) == \ + r"\int\limits_{0}^{1}\int\int x\, dx\, dy\, dz" + + # for negative nested Integral + assert latex(Integral(-Integral(y**2,x),x)) == \ + r'\int \left(- \int y^{2}\, dx\right)\, dx' + assert latex(Integral(-Integral(-Integral(y,x),x),x)) == \ + r'\int \left(- \int \left(- \int y\, dx\right)\, dx\right)\, dx' + + # fix issue #10806 + assert latex(Integral(z, z)**2) == r"\left(\int z\, dz\right)^{2}" + assert latex(Integral(x + z, z)) == r"\int \left(x + z\right)\, dz" + assert latex(Integral(x+z/2, z)) == \ + r"\int \left(x + \frac{z}{2}\right)\, dz" + assert latex(Integral(x**y, z)) == r"\int x^{y}\, dz" + + # set diff operator + assert latex(Integral(x, x), diff_operator="rd") == r'\int x\, \mathrm{d}x' + assert latex(Integral(x, (x, 0, 1)), diff_operator="rd") == r'\int\limits_{0}^{1} x\, \mathrm{d}x' + + +def test_latex_sets(): + for s in (frozenset, set): + assert latex(s([x*y, x**2])) == r"\left\{x^{2}, x y\right\}" + assert latex(s(range(1, 6))) == r"\left\{1, 2, 3, 4, 5\right\}" + assert latex(s(range(1, 13))) == \ + r"\left\{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12\right\}" + + s = FiniteSet + assert latex(s(*[x*y, x**2])) == r"\left\{x^{2}, x y\right\}" + assert latex(s(*range(1, 6))) == r"\left\{1, 2, 3, 4, 5\right\}" + assert latex(s(*range(1, 13))) == \ + r"\left\{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12\right\}" + + +def test_latex_SetExpr(): + iv = Interval(1, 3) + se = SetExpr(iv) + assert latex(se) == r"SetExpr\left(\left[1, 3\right]\right)" + + +def test_latex_Range(): + assert latex(Range(1, 51)) == r'\left\{1, 2, \ldots, 50\right\}' + assert latex(Range(1, 4)) == r'\left\{1, 2, 3\right\}' + assert latex(Range(0, 3, 1)) == r'\left\{0, 1, 2\right\}' + assert latex(Range(0, 30, 1)) == r'\left\{0, 1, \ldots, 29\right\}' + assert latex(Range(30, 1, -1)) == r'\left\{30, 29, \ldots, 2\right\}' + assert latex(Range(0, oo, 2)) == r'\left\{0, 2, \ldots\right\}' + assert latex(Range(oo, -2, -2)) == r'\left\{\ldots, 2, 0\right\}' + assert latex(Range(-2, -oo, -1)) == r'\left\{-2, -3, \ldots\right\}' + assert latex(Range(-oo, oo)) == r'\left\{\ldots, -1, 0, 1, \ldots\right\}' + assert latex(Range(oo, -oo, -1)) == r'\left\{\ldots, 1, 0, -1, \ldots\right\}' + + a, b, c = symbols('a:c') + assert latex(Range(a, b, c)) == r'\text{Range}\left(a, b, c\right)' + assert latex(Range(a, 10, 1)) == r'\text{Range}\left(a, 10\right)' + assert latex(Range(0, b, 1)) == r'\text{Range}\left(b\right)' + assert latex(Range(0, 10, c)) == r'\text{Range}\left(0, 10, c\right)' + + i = Symbol('i', integer=True) + n = Symbol('n', negative=True, integer=True) + p = Symbol('p', positive=True, integer=True) + + assert latex(Range(i, i + 3)) == r'\left\{i, i + 1, i + 2\right\}' + assert latex(Range(-oo, n, 2)) == r'\left\{\ldots, n - 4, n - 2\right\}' + assert latex(Range(p, oo)) == r'\left\{p, p + 1, \ldots\right\}' + # The following will work if __iter__ is improved + # assert latex(Range(-3, p + 7)) == r'\left\{-3, -2, \ldots, p + 6\right\}' + # Must have integer assumptions + assert latex(Range(a, a + 3)) == r'\text{Range}\left(a, a + 3\right)' + + +def test_latex_sequences(): + s1 = SeqFormula(a**2, (0, oo)) + s2 = SeqPer((1, 2)) + + latex_str = r'\left[0, 1, 4, 9, \ldots\right]' + assert latex(s1) == latex_str + + latex_str = r'\left[1, 2, 1, 2, \ldots\right]' + assert latex(s2) == latex_str + + s3 = SeqFormula(a**2, (0, 2)) + s4 = SeqPer((1, 2), (0, 2)) + + latex_str = r'\left[0, 1, 4\right]' + assert latex(s3) == latex_str + + latex_str = r'\left[1, 2, 1\right]' + assert latex(s4) == latex_str + + s5 = SeqFormula(a**2, (-oo, 0)) + s6 = SeqPer((1, 2), (-oo, 0)) + + latex_str = r'\left[\ldots, 9, 4, 1, 0\right]' + assert latex(s5) == latex_str + + latex_str = r'\left[\ldots, 2, 1, 2, 1\right]' + assert latex(s6) == latex_str + + latex_str = r'\left[1, 3, 5, 11, \ldots\right]' + assert latex(SeqAdd(s1, s2)) == latex_str + + latex_str = r'\left[1, 3, 5\right]' + assert latex(SeqAdd(s3, s4)) == latex_str + + latex_str = r'\left[\ldots, 11, 5, 3, 1\right]' + assert latex(SeqAdd(s5, s6)) == latex_str + + latex_str = r'\left[0, 2, 4, 18, \ldots\right]' + assert latex(SeqMul(s1, s2)) == latex_str + + latex_str = r'\left[0, 2, 4\right]' + assert latex(SeqMul(s3, s4)) == latex_str + + latex_str = r'\left[\ldots, 18, 4, 2, 0\right]' + assert latex(SeqMul(s5, s6)) == latex_str + + # Sequences with symbolic limits, issue 12629 + s7 = SeqFormula(a**2, (a, 0, x)) + latex_str = r'\left\{a^{2}\right\}_{a=0}^{x}' + assert latex(s7) == latex_str + + b = Symbol('b') + s8 = SeqFormula(b*a**2, (a, 0, 2)) + latex_str = r'\left[0, b, 4 b\right]' + assert latex(s8) == latex_str + + +def test_latex_FourierSeries(): + latex_str = \ + r'2 \sin{\left(x \right)} - \sin{\left(2 x \right)} + \frac{2 \sin{\left(3 x \right)}}{3} + \ldots' + assert latex(fourier_series(x, (x, -pi, pi))) == latex_str + + +def test_latex_FormalPowerSeries(): + latex_str = r'\sum_{k=1}^{\infty} - \frac{\left(-1\right)^{- k} x^{k}}{k}' + assert latex(fps(log(1 + x))) == latex_str + + +def test_latex_intervals(): + a = Symbol('a', real=True) + assert latex(Interval(0, 0)) == r"\left\{0\right\}" + assert latex(Interval(0, a)) == r"\left[0, a\right]" + assert latex(Interval(0, a, False, False)) == r"\left[0, a\right]" + assert latex(Interval(0, a, True, False)) == r"\left(0, a\right]" + assert latex(Interval(0, a, False, True)) == r"\left[0, a\right)" + assert latex(Interval(0, a, True, True)) == r"\left(0, a\right)" + + +def test_latex_AccumuBounds(): + a = Symbol('a', real=True) + assert latex(AccumBounds(0, 1)) == r"\left\langle 0, 1\right\rangle" + assert latex(AccumBounds(0, a)) == r"\left\langle 0, a\right\rangle" + assert latex(AccumBounds(a + 1, a + 2)) == \ + r"\left\langle a + 1, a + 2\right\rangle" + + +def test_latex_emptyset(): + assert latex(S.EmptySet) == r"\emptyset" + + +def test_latex_universalset(): + assert latex(S.UniversalSet) == r"\mathbb{U}" + + +def test_latex_commutator(): + A = Operator('A') + B = Operator('B') + comm = Commutator(B, A) + assert latex(comm.doit()) == r"- (A B - B A)" + + +def test_latex_union(): + assert latex(Union(Interval(0, 1), Interval(2, 3))) == \ + r"\left[0, 1\right] \cup \left[2, 3\right]" + assert latex(Union(Interval(1, 1), Interval(2, 2), Interval(3, 4))) == \ + r"\left\{1, 2\right\} \cup \left[3, 4\right]" + + +def test_latex_intersection(): + assert latex(Intersection(Interval(0, 1), Interval(x, y))) == \ + r"\left[0, 1\right] \cap \left[x, y\right]" + + +def test_latex_symmetric_difference(): + assert latex(SymmetricDifference(Interval(2, 5), Interval(4, 7), + evaluate=False)) == \ + r'\left[2, 5\right] \triangle \left[4, 7\right]' + + +def test_latex_Complement(): + assert latex(Complement(S.Reals, S.Naturals)) == \ + r"\mathbb{R} \setminus \mathbb{N}" + + +def test_latex_productset(): + line = Interval(0, 1) + bigline = Interval(0, 10) + fset = FiniteSet(1, 2, 3) + assert latex(line**2) == r"%s^{2}" % latex(line) + assert latex(line**10) == r"%s^{10}" % latex(line) + assert latex((line * bigline * fset).flatten()) == r"%s \times %s \times %s" % ( + latex(line), latex(bigline), latex(fset)) + + +def test_latex_powerset(): + fset = FiniteSet(1, 2, 3) + assert latex(PowerSet(fset)) == r'\mathcal{P}\left(\left\{1, 2, 3\right\}\right)' + + +def test_latex_ordinals(): + w = OrdinalOmega() + assert latex(w) == r"\omega" + wp = OmegaPower(2, 3) + assert latex(wp) == r'3 \omega^{2}' + assert latex(Ordinal(wp, OmegaPower(1, 1))) == r'3 \omega^{2} + \omega' + assert latex(Ordinal(OmegaPower(2, 1), OmegaPower(1, 2))) == r'\omega^{2} + 2 \omega' + + +def test_set_operators_parenthesis(): + a, b, c, d = symbols('a:d') + A = FiniteSet(a) + B = FiniteSet(b) + C = FiniteSet(c) + D = FiniteSet(d) + + U1 = Union(A, B, evaluate=False) + U2 = Union(C, D, evaluate=False) + I1 = Intersection(A, B, evaluate=False) + I2 = Intersection(C, D, evaluate=False) + C1 = Complement(A, B, evaluate=False) + C2 = Complement(C, D, evaluate=False) + D1 = SymmetricDifference(A, B, evaluate=False) + D2 = SymmetricDifference(C, D, evaluate=False) + # XXX ProductSet does not support evaluate keyword + P1 = ProductSet(A, B) + P2 = ProductSet(C, D) + + assert latex(Intersection(A, U2, evaluate=False)) == \ + r'\left\{a\right\} \cap ' \ + r'\left(\left\{c\right\} \cup \left\{d\right\}\right)' + assert latex(Intersection(U1, U2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\cap \left(\left\{c\right\} \cup \left\{d\right\}\right)' + assert latex(Intersection(C1, C2, evaluate=False)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \cap \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(Intersection(D1, D2, evaluate=False)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \cap \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + assert latex(Intersection(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) ' \ + r'\cap \left(\left\{c\right\} \times ' \ + r'\left\{d\right\}\right)' + + assert latex(Union(A, I2, evaluate=False)) == \ + r'\left\{a\right\} \cup ' \ + r'\left(\left\{c\right\} \cap \left\{d\right\}\right)' + assert latex(Union(I1, I2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\cup \left(\left\{c\right\} \cap \left\{d\right\}\right)' + assert latex(Union(C1, C2, evaluate=False)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \cup \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(Union(D1, D2, evaluate=False)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \cup \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + assert latex(Union(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) ' \ + r'\cup \left(\left\{c\right\} \times ' \ + r'\left\{d\right\}\right)' + + assert latex(Complement(A, C2, evaluate=False)) == \ + r'\left\{a\right\} \setminus \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(Complement(U1, U2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\setminus \left(\left\{c\right\} \cup ' \ + r'\left\{d\right\}\right)' + assert latex(Complement(I1, I2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\setminus \left(\left\{c\right\} \cap ' \ + r'\left\{d\right\}\right)' + assert latex(Complement(D1, D2, evaluate=False)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \setminus ' \ + r'\left(\left\{c\right\} \triangle \left\{d\right\}\right)' + assert latex(Complement(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) '\ + r'\setminus \left(\left\{c\right\} \times '\ + r'\left\{d\right\}\right)' + + assert latex(SymmetricDifference(A, D2, evaluate=False)) == \ + r'\left\{a\right\} \triangle \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + assert latex(SymmetricDifference(U1, U2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\triangle \left(\left\{c\right\} \cup ' \ + r'\left\{d\right\}\right)' + assert latex(SymmetricDifference(I1, I2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\triangle \left(\left\{c\right\} \cap ' \ + r'\left\{d\right\}\right)' + assert latex(SymmetricDifference(C1, C2, evaluate=False)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \triangle ' \ + r'\left(\left\{c\right\} \setminus \left\{d\right\}\right)' + assert latex(SymmetricDifference(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) ' \ + r'\triangle \left(\left\{c\right\} \times ' \ + r'\left\{d\right\}\right)' + + # XXX This can be incorrect since cartesian product is not associative + assert latex(ProductSet(A, P2).flatten()) == \ + r'\left\{a\right\} \times \left\{c\right\} \times ' \ + r'\left\{d\right\}' + assert latex(ProductSet(U1, U2)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\times \left(\left\{c\right\} \cup ' \ + r'\left\{d\right\}\right)' + assert latex(ProductSet(I1, I2)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\times \left(\left\{c\right\} \cap ' \ + r'\left\{d\right\}\right)' + assert latex(ProductSet(C1, C2)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \times \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(ProductSet(D1, D2)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \times \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + + +def test_latex_Complexes(): + assert latex(S.Complexes) == r"\mathbb{C}" + + +def test_latex_Naturals(): + assert latex(S.Naturals) == r"\mathbb{N}" + + +def test_latex_Naturals0(): + assert latex(S.Naturals0) == r"\mathbb{N}_0" + + +def test_latex_Integers(): + assert latex(S.Integers) == r"\mathbb{Z}" + + +def test_latex_ImageSet(): + x = Symbol('x') + assert latex(ImageSet(Lambda(x, x**2), S.Naturals)) == \ + r"\left\{x^{2}\; \middle|\; x \in \mathbb{N}\right\}" + + y = Symbol('y') + imgset = ImageSet(Lambda((x, y), x + y), {1, 2, 3}, {3, 4}) + assert latex(imgset) == \ + r"\left\{x + y\; \middle|\; x \in \left\{1, 2, 3\right\}, y \in \left\{3, 4\right\}\right\}" + + imgset = ImageSet(Lambda(((x, y),), x + y), ProductSet({1, 2, 3}, {3, 4})) + assert latex(imgset) == \ + r"\left\{x + y\; \middle|\; \left( x, \ y\right) \in \left\{1, 2, 3\right\} \times \left\{3, 4\right\}\right\}" + + +def test_latex_ConditionSet(): + x = Symbol('x') + assert latex(ConditionSet(x, Eq(x**2, 1), S.Reals)) == \ + r"\left\{x\; \middle|\; x \in \mathbb{R} \wedge x^{2} = 1 \right\}" + assert latex(ConditionSet(x, Eq(x**2, 1), S.UniversalSet)) == \ + r"\left\{x\; \middle|\; x^{2} = 1 \right\}" + + +def test_latex_ComplexRegion(): + assert latex(ComplexRegion(Interval(3, 5)*Interval(4, 6))) == \ + r"\left\{x + y i\; \middle|\; x, y \in \left[3, 5\right] \times \left[4, 6\right] \right\}" + assert latex(ComplexRegion(Interval(0, 1)*Interval(0, 2*pi), polar=True)) == \ + r"\left\{r \left(i \sin{\left(\theta \right)} + \cos{\left(\theta "\ + r"\right)}\right)\; \middle|\; r, \theta \in \left[0, 1\right] \times \left[0, 2 \pi\right) \right\}" + + +def test_latex_Contains(): + x = Symbol('x') + assert latex(Contains(x, S.Naturals)) == r"x \in \mathbb{N}" + + +def test_latex_sum(): + assert latex(Sum(x*y**2, (x, -2, 2), (y, -5, 5))) == \ + r"\sum_{\substack{-2 \leq x \leq 2\\-5 \leq y \leq 5}} x y^{2}" + assert latex(Sum(x**2, (x, -2, 2))) == \ + r"\sum_{x=-2}^{2} x^{2}" + assert latex(Sum(x**2 + y, (x, -2, 2))) == \ + r"\sum_{x=-2}^{2} \left(x^{2} + y\right)" + assert latex(Sum(x**2 + y, (x, -2, 2))**2) == \ + r"\left(\sum_{x=-2}^{2} \left(x^{2} + y\right)\right)^{2}" + + +def test_latex_product(): + assert latex(Product(x*y**2, (x, -2, 2), (y, -5, 5))) == \ + r"\prod_{\substack{-2 \leq x \leq 2\\-5 \leq y \leq 5}} x y^{2}" + assert latex(Product(x**2, (x, -2, 2))) == \ + r"\prod_{x=-2}^{2} x^{2}" + assert latex(Product(x**2 + y, (x, -2, 2))) == \ + r"\prod_{x=-2}^{2} \left(x^{2} + y\right)" + + assert latex(Product(x, (x, -2, 2))**2) == \ + r"\left(\prod_{x=-2}^{2} x\right)^{2}" + + +def test_latex_limits(): + assert latex(Limit(x, x, oo)) == r"\lim_{x \to \infty} x" + + # issue 8175 + f = Function('f') + assert latex(Limit(f(x), x, 0)) == r"\lim_{x \to 0^+} f{\left(x \right)}" + assert latex(Limit(f(x), x, 0, "-")) == \ + r"\lim_{x \to 0^-} f{\left(x \right)}" + + # issue #10806 + assert latex(Limit(f(x), x, 0)**2) == \ + r"\left(\lim_{x \to 0^+} f{\left(x \right)}\right)^{2}" + # bi-directional limit + assert latex(Limit(f(x), x, 0, dir='+-')) == \ + r"\lim_{x \to 0} f{\left(x \right)}" + + +def test_latex_log(): + assert latex(log(x)) == r"\log{\left(x \right)}" + assert latex(log(x), ln_notation=True) == r"\ln{\left(x \right)}" + assert latex(log(x) + log(y)) == \ + r"\log{\left(x \right)} + \log{\left(y \right)}" + assert latex(log(x) + log(y), ln_notation=True) == \ + r"\ln{\left(x \right)} + \ln{\left(y \right)}" + assert latex(pow(log(x), x)) == r"\log{\left(x \right)}^{x}" + assert latex(pow(log(x), x), ln_notation=True) == \ + r"\ln{\left(x \right)}^{x}" + + +def test_issue_3568(): + beta = Symbol(r'\beta') + y = beta + x + assert latex(y) in [r'\beta + x', r'x + \beta'] + + beta = Symbol(r'beta') + y = beta + x + assert latex(y) in [r'\beta + x', r'x + \beta'] + + +def test_latex(): + assert latex((2*tau)**Rational(7, 2)) == r"8 \sqrt{2} \tau^{\frac{7}{2}}" + assert latex((2*mu)**Rational(7, 2), mode='equation*') == \ + r"\begin{equation*}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation*}" + assert latex((2*mu)**Rational(7, 2), mode='equation', itex=True) == \ + r"$$8 \sqrt{2} \mu^{\frac{7}{2}}$$" + assert latex([2/x, y]) == r"\left[ \frac{2}{x}, \ y\right]" + + +def test_latex_dict(): + d = {Rational(1): 1, x**2: 2, x: 3, x**3: 4} + assert latex(d) == \ + r'\left\{ 1 : 1, \ x : 3, \ x^{2} : 2, \ x^{3} : 4\right\}' + D = Dict(d) + assert latex(D) == \ + r'\left\{ 1 : 1, \ x : 3, \ x^{2} : 2, \ x^{3} : 4\right\}' + + +def test_latex_list(): + ll = [Symbol('omega1'), Symbol('a'), Symbol('alpha')] + assert latex(ll) == r'\left[ \omega_{1}, \ a, \ \alpha\right]' + + +def test_latex_NumberSymbols(): + assert latex(S.Catalan) == "G" + assert latex(S.EulerGamma) == r"\gamma" + assert latex(S.Exp1) == "e" + assert latex(S.GoldenRatio) == r"\phi" + assert latex(S.Pi) == r"\pi" + assert latex(S.TribonacciConstant) == r"\text{TribonacciConstant}" + + +def test_latex_rational(): + # tests issue 3973 + assert latex(-Rational(1, 2)) == r"- \frac{1}{2}" + assert latex(Rational(-1, 2)) == r"- \frac{1}{2}" + assert latex(Rational(1, -2)) == r"- \frac{1}{2}" + assert latex(-Rational(-1, 2)) == r"\frac{1}{2}" + assert latex(-Rational(1, 2)*x) == r"- \frac{x}{2}" + assert latex(-Rational(1, 2)*x + Rational(-2, 3)*y) == \ + r"- \frac{x}{2} - \frac{2 y}{3}" + + +def test_latex_inverse(): + # tests issue 4129 + assert latex(1/x) == r"\frac{1}{x}" + assert latex(1/(x + y)) == r"\frac{1}{x + y}" + + +def test_latex_DiracDelta(): + assert latex(DiracDelta(x)) == r"\delta\left(x\right)" + assert latex(DiracDelta(x)**2) == r"\left(\delta\left(x\right)\right)^{2}" + assert latex(DiracDelta(x, 0)) == r"\delta\left(x\right)" + assert latex(DiracDelta(x, 5)) == \ + r"\delta^{\left( 5 \right)}\left( x \right)" + assert latex(DiracDelta(x, 5)**2) == \ + r"\left(\delta^{\left( 5 \right)}\left( x \right)\right)^{2}" + + +def test_latex_Heaviside(): + assert latex(Heaviside(x)) == r"\theta\left(x\right)" + assert latex(Heaviside(x)**2) == r"\left(\theta\left(x\right)\right)^{2}" + + +def test_latex_KroneckerDelta(): + assert latex(KroneckerDelta(x, y)) == r"\delta_{x y}" + assert latex(KroneckerDelta(x, y + 1)) == r"\delta_{x, y + 1}" + # issue 6578 + assert latex(KroneckerDelta(x + 1, y)) == r"\delta_{y, x + 1}" + assert latex(Pow(KroneckerDelta(x, y), 2, evaluate=False)) == \ + r"\left(\delta_{x y}\right)^{2}" + + +def test_latex_LeviCivita(): + assert latex(LeviCivita(x, y, z)) == r"\varepsilon_{x y z}" + assert latex(LeviCivita(x, y, z)**2) == \ + r"\left(\varepsilon_{x y z}\right)^{2}" + assert latex(LeviCivita(x, y, z + 1)) == r"\varepsilon_{x, y, z + 1}" + assert latex(LeviCivita(x, y + 1, z)) == r"\varepsilon_{x, y + 1, z}" + assert latex(LeviCivita(x + 1, y, z)) == r"\varepsilon_{x + 1, y, z}" + + +def test_mode(): + expr = x + y + assert latex(expr) == r'x + y' + assert latex(expr, mode='plain') == r'x + y' + assert latex(expr, mode='inline') == r'$x + y$' + assert latex( + expr, mode='equation*') == r'\begin{equation*}x + y\end{equation*}' + assert latex( + expr, mode='equation') == r'\begin{equation}x + y\end{equation}' + raises(ValueError, lambda: latex(expr, mode='foo')) + + +def test_latex_mathieu(): + assert latex(mathieuc(x, y, z)) == r"C\left(x, y, z\right)" + assert latex(mathieus(x, y, z)) == r"S\left(x, y, z\right)" + assert latex(mathieuc(x, y, z)**2) == r"C\left(x, y, z\right)^{2}" + assert latex(mathieus(x, y, z)**2) == r"S\left(x, y, z\right)^{2}" + assert latex(mathieucprime(x, y, z)) == r"C^{\prime}\left(x, y, z\right)" + assert latex(mathieusprime(x, y, z)) == r"S^{\prime}\left(x, y, z\right)" + assert latex(mathieucprime(x, y, z)**2) == r"C^{\prime}\left(x, y, z\right)^{2}" + assert latex(mathieusprime(x, y, z)**2) == r"S^{\prime}\left(x, y, z\right)^{2}" + +def test_latex_Piecewise(): + p = Piecewise((x, x < 1), (x**2, True)) + assert latex(p) == r"\begin{cases} x & \text{for}\: x < 1 \\x^{2} &" \ + r" \text{otherwise} \end{cases}" + assert latex(p, itex=True) == \ + r"\begin{cases} x & \text{for}\: x \lt 1 \\x^{2} &" \ + r" \text{otherwise} \end{cases}" + p = Piecewise((x, x < 0), (0, x >= 0)) + assert latex(p) == r'\begin{cases} x & \text{for}\: x < 0 \\0 &' \ + r' \text{otherwise} \end{cases}' + A, B = symbols("A B", commutative=False) + p = Piecewise((A**2, Eq(A, B)), (A*B, True)) + s = r"\begin{cases} A^{2} & \text{for}\: A = B \\A B & \text{otherwise} \end{cases}" + assert latex(p) == s + assert latex(A*p) == r"A \left(%s\right)" % s + assert latex(p*A) == r"\left(%s\right) A" % s + assert latex(Piecewise((x, x < 1), (x**2, x < 2))) == \ + r'\begin{cases} x & ' \ + r'\text{for}\: x < 1 \\x^{2} & \text{for}\: x < 2 \end{cases}' + + +def test_latex_Matrix(): + M = Matrix([[1 + x, y], [y, x - 1]]) + assert latex(M) == \ + r'\left[\begin{matrix}x + 1 & y\\y & x - 1\end{matrix}\right]' + assert latex(M, mode='inline') == \ + r'$\left[\begin{smallmatrix}x + 1 & y\\' \ + r'y & x - 1\end{smallmatrix}\right]$' + assert latex(M, mat_str='array') == \ + r'\left[\begin{array}{cc}x + 1 & y\\y & x - 1\end{array}\right]' + assert latex(M, mat_str='bmatrix') == \ + r'\left[\begin{bmatrix}x + 1 & y\\y & x - 1\end{bmatrix}\right]' + assert latex(M, mat_delim=None, mat_str='bmatrix') == \ + r'\begin{bmatrix}x + 1 & y\\y & x - 1\end{bmatrix}' + + M2 = Matrix(1, 11, range(11)) + assert latex(M2) == \ + r'\left[\begin{array}{ccccccccccc}' \ + r'0 & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9 & 10\end{array}\right]' + + +def test_latex_matrix_with_functions(): + t = symbols('t') + theta1 = symbols('theta1', cls=Function) + + M = Matrix([[sin(theta1(t)), cos(theta1(t))], + [cos(theta1(t).diff(t)), sin(theta1(t).diff(t))]]) + + expected = (r'\left[\begin{matrix}\sin{\left(' + r'\theta_{1}{\left(t \right)} \right)} & ' + r'\cos{\left(\theta_{1}{\left(t \right)} \right)' + r'}\\\cos{\left(\frac{d}{d t} \theta_{1}{\left(t ' + r'\right)} \right)} & \sin{\left(\frac{d}{d t} ' + r'\theta_{1}{\left(t \right)} \right' + r')}\end{matrix}\right]') + + assert latex(M) == expected + + +def test_latex_NDimArray(): + x, y, z, w = symbols("x y z w") + + for ArrayType in (ImmutableDenseNDimArray, ImmutableSparseNDimArray, + MutableDenseNDimArray, MutableSparseNDimArray): + # Basic: scalar array + M = ArrayType(x) + + assert latex(M) == r"x" + + M = ArrayType([[1 / x, y], [z, w]]) + M1 = ArrayType([1 / x, y, z]) + + M2 = tensorproduct(M1, M) + M3 = tensorproduct(M, M) + + assert latex(M) == \ + r'\left[\begin{matrix}\frac{1}{x} & y\\z & w\end{matrix}\right]' + assert latex(M1) == \ + r"\left[\begin{matrix}\frac{1}{x} & y & z\end{matrix}\right]" + assert latex(M2) == \ + r"\left[\begin{matrix}" \ + r"\left[\begin{matrix}\frac{1}{x^{2}} & \frac{y}{x}\\\frac{z}{x} & \frac{w}{x}\end{matrix}\right] & " \ + r"\left[\begin{matrix}\frac{y}{x} & y^{2}\\y z & w y\end{matrix}\right] & " \ + r"\left[\begin{matrix}\frac{z}{x} & y z\\z^{2} & w z\end{matrix}\right]" \ + r"\end{matrix}\right]" + assert latex(M3) == \ + r"""\left[\begin{matrix}"""\ + r"""\left[\begin{matrix}\frac{1}{x^{2}} & \frac{y}{x}\\\frac{z}{x} & \frac{w}{x}\end{matrix}\right] & """\ + r"""\left[\begin{matrix}\frac{y}{x} & y^{2}\\y z & w y\end{matrix}\right]\\"""\ + r"""\left[\begin{matrix}\frac{z}{x} & y z\\z^{2} & w z\end{matrix}\right] & """\ + r"""\left[\begin{matrix}\frac{w}{x} & w y\\w z & w^{2}\end{matrix}\right]"""\ + r"""\end{matrix}\right]""" + + Mrow = ArrayType([[x, y, 1/z]]) + Mcolumn = ArrayType([[x], [y], [1/z]]) + Mcol2 = ArrayType([Mcolumn.tolist()]) + + assert latex(Mrow) == \ + r"\left[\left[\begin{matrix}x & y & \frac{1}{z}\end{matrix}\right]\right]" + assert latex(Mcolumn) == \ + r"\left[\begin{matrix}x\\y\\\frac{1}{z}\end{matrix}\right]" + assert latex(Mcol2) == \ + r'\left[\begin{matrix}\left[\begin{matrix}x\\y\\\frac{1}{z}\end{matrix}\right]\end{matrix}\right]' + + +def test_latex_mul_symbol(): + assert latex(4*4**x, mul_symbol='times') == r"4 \times 4^{x}" + assert latex(4*4**x, mul_symbol='dot') == r"4 \cdot 4^{x}" + assert latex(4*4**x, mul_symbol='ldot') == r"4 \,.\, 4^{x}" + + assert latex(4*x, mul_symbol='times') == r"4 \times x" + assert latex(4*x, mul_symbol='dot') == r"4 \cdot x" + assert latex(4*x, mul_symbol='ldot') == r"4 \,.\, x" + + +def test_latex_issue_4381(): + y = 4*4**log(2) + assert latex(y) == r'4 \cdot 4^{\log{\left(2 \right)}}' + assert latex(1/y) == r'\frac{1}{4 \cdot 4^{\log{\left(2 \right)}}}' + + +def test_latex_issue_4576(): + assert latex(Symbol("beta_13_2")) == r"\beta_{13 2}" + assert latex(Symbol("beta_132_20")) == r"\beta_{132 20}" + assert latex(Symbol("beta_13")) == r"\beta_{13}" + assert latex(Symbol("x_a_b")) == r"x_{a b}" + assert latex(Symbol("x_1_2_3")) == r"x_{1 2 3}" + assert latex(Symbol("x_a_b1")) == r"x_{a b1}" + assert latex(Symbol("x_a_1")) == r"x_{a 1}" + assert latex(Symbol("x_1_a")) == r"x_{1 a}" + assert latex(Symbol("x_1^aa")) == r"x^{aa}_{1}" + assert latex(Symbol("x_1__aa")) == r"x^{aa}_{1}" + assert latex(Symbol("x_11^a")) == r"x^{a}_{11}" + assert latex(Symbol("x_11__a")) == r"x^{a}_{11}" + assert latex(Symbol("x_a_a_a_a")) == r"x_{a a a a}" + assert latex(Symbol("x_a_a^a^a")) == r"x^{a a}_{a a}" + assert latex(Symbol("x_a_a__a__a")) == r"x^{a a}_{a a}" + assert latex(Symbol("alpha_11")) == r"\alpha_{11}" + assert latex(Symbol("alpha_11_11")) == r"\alpha_{11 11}" + assert latex(Symbol("alpha_alpha")) == r"\alpha_{\alpha}" + assert latex(Symbol("alpha^aleph")) == r"\alpha^{\aleph}" + assert latex(Symbol("alpha__aleph")) == r"\alpha^{\aleph}" + + +def test_latex_pow_fraction(): + x = Symbol('x') + # Testing exp + assert r'e^{-x}' in latex(exp(-x)/2).replace(' ', '') # Remove Whitespace + + # Testing e^{-x} in case future changes alter behavior of muls or fracs + # In particular current output is \frac{1}{2}e^{- x} but perhaps this will + # change to \frac{e^{-x}}{2} + + # Testing general, non-exp, power + assert r'3^{-x}' in latex(3**-x/2).replace(' ', '') + + +def test_noncommutative(): + A, B, C = symbols('A,B,C', commutative=False) + + assert latex(A*B*C**-1) == r"A B C^{-1}" + assert latex(C**-1*A*B) == r"C^{-1} A B" + assert latex(A*C**-1*B) == r"A C^{-1} B" + + +def test_latex_order(): + expr = x**3 + x**2*y + y**4 + 3*x*y**3 + + assert latex(expr, order='lex') == r"x^{3} + x^{2} y + 3 x y^{3} + y^{4}" + assert latex( + expr, order='rev-lex') == r"y^{4} + 3 x y^{3} + x^{2} y + x^{3}" + assert latex(expr, order='none') == r"x^{3} + y^{4} + y x^{2} + 3 x y^{3}" + + +def test_latex_Lambda(): + assert latex(Lambda(x, x + 1)) == r"\left( x \mapsto x + 1 \right)" + assert latex(Lambda((x, y), x + 1)) == r"\left( \left( x, \ y\right) \mapsto x + 1 \right)" + assert latex(Lambda(x, x)) == r"\left( x \mapsto x \right)" + +def test_latex_PolyElement(): + Ruv, u, v = ring("u,v", ZZ) + Rxyz, x, y, z = ring("x,y,z", Ruv) + + assert latex(x - x) == r"0" + assert latex(x - 1) == r"x - 1" + assert latex(x + 1) == r"x + 1" + + assert latex((u**2 + 3*u*v + 1)*x**2*y + u + 1) == \ + r"\left({u}^{2} + 3 u v + 1\right) {x}^{2} y + u + 1" + assert latex((u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x) == \ + r"\left({u}^{2} + 3 u v + 1\right) {x}^{2} y + \left(u + 1\right) x" + assert latex((u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x + 1) == \ + r"\left({u}^{2} + 3 u v + 1\right) {x}^{2} y + \left(u + 1\right) x + 1" + assert latex((-u**2 + 3*u*v - 1)*x**2*y - (u + 1)*x - 1) == \ + r"-\left({u}^{2} - 3 u v + 1\right) {x}^{2} y - \left(u + 1\right) x - 1" + + assert latex(-(v**2 + v + 1)*x + 3*u*v + 1) == \ + r"-\left({v}^{2} + v + 1\right) x + 3 u v + 1" + assert latex(-(v**2 + v + 1)*x - 3*u*v + 1) == \ + r"-\left({v}^{2} + v + 1\right) x - 3 u v + 1" + + +def test_latex_FracElement(): + Fuv, u, v = field("u,v", ZZ) + Fxyzt, x, y, z, t = field("x,y,z,t", Fuv) + + assert latex(x - x) == r"0" + assert latex(x - 1) == r"x - 1" + assert latex(x + 1) == r"x + 1" + + assert latex(x/3) == r"\frac{x}{3}" + assert latex(x/z) == r"\frac{x}{z}" + assert latex(x*y/z) == r"\frac{x y}{z}" + assert latex(x/(z*t)) == r"\frac{x}{z t}" + assert latex(x*y/(z*t)) == r"\frac{x y}{z t}" + + assert latex((x - 1)/y) == r"\frac{x - 1}{y}" + assert latex((x + 1)/y) == r"\frac{x + 1}{y}" + assert latex((-x - 1)/y) == r"\frac{-x - 1}{y}" + assert latex((x + 1)/(y*z)) == r"\frac{x + 1}{y z}" + assert latex(-y/(x + 1)) == r"\frac{-y}{x + 1}" + assert latex(y*z/(x + 1)) == r"\frac{y z}{x + 1}" + + assert latex(((u + 1)*x*y + 1)/((v - 1)*z - 1)) == \ + r"\frac{\left(u + 1\right) x y + 1}{\left(v - 1\right) z - 1}" + assert latex(((u + 1)*x*y + 1)/((v - 1)*z - t*u*v - 1)) == \ + r"\frac{\left(u + 1\right) x y + 1}{\left(v - 1\right) z - u v t - 1}" + + +def test_latex_Poly(): + assert latex(Poly(x**2 + 2 * x, x)) == \ + r"\operatorname{Poly}{\left( x^{2} + 2 x, x, domain=\mathbb{Z} \right)}" + assert latex(Poly(x/y, x)) == \ + r"\operatorname{Poly}{\left( \frac{1}{y} x, x, domain=\mathbb{Z}\left(y\right) \right)}" + assert latex(Poly(2.0*x + y)) == \ + r"\operatorname{Poly}{\left( 2.0 x + 1.0 y, x, y, domain=\mathbb{R} \right)}" + + +def test_latex_Poly_order(): + assert latex(Poly([a, 1, b, 2, c, 3], x)) == \ + r'\operatorname{Poly}{\left( a x^{5} + x^{4} + b x^{3} + 2 x^{2} + c'\ + r' x + 3, x, domain=\mathbb{Z}\left[a, b, c\right] \right)}' + assert latex(Poly([a, 1, b+c, 2, 3], x)) == \ + r'\operatorname{Poly}{\left( a x^{4} + x^{3} + \left(b + c\right) '\ + r'x^{2} + 2 x + 3, x, domain=\mathbb{Z}\left[a, b, c\right] \right)}' + assert latex(Poly(a*x**3 + x**2*y - x*y - c*y**3 - b*x*y**2 + y - a*x + b, + (x, y))) == \ + r'\operatorname{Poly}{\left( a x^{3} + x^{2}y - b xy^{2} - xy - '\ + r'a x - c y^{3} + y + b, x, y, domain=\mathbb{Z}\left[a, b, c\right] \right)}' + + +def test_latex_ComplexRootOf(): + assert latex(rootof(x**5 + x + 3, 0)) == \ + r"\operatorname{CRootOf} {\left(x^{5} + x + 3, 0\right)}" + + +def test_latex_RootSum(): + assert latex(RootSum(x**5 + x + 3, sin)) == \ + r"\operatorname{RootSum} {\left(x^{5} + x + 3, \left( x \mapsto \sin{\left(x \right)} \right)\right)}" + + +def test_settings(): + raises(TypeError, lambda: latex(x*y, method="garbage")) + + +def test_latex_numbers(): + assert latex(catalan(n)) == r"C_{n}" + assert latex(catalan(n)**2) == r"C_{n}^{2}" + assert latex(bernoulli(n)) == r"B_{n}" + assert latex(bernoulli(n, x)) == r"B_{n}\left(x\right)" + assert latex(bernoulli(n)**2) == r"B_{n}^{2}" + assert latex(bernoulli(n, x)**2) == r"B_{n}^{2}\left(x\right)" + assert latex(genocchi(n)) == r"G_{n}" + assert latex(genocchi(n, x)) == r"G_{n}\left(x\right)" + assert latex(genocchi(n)**2) == r"G_{n}^{2}" + assert latex(genocchi(n, x)**2) == r"G_{n}^{2}\left(x\right)" + assert latex(bell(n)) == r"B_{n}" + assert latex(bell(n, x)) == r"B_{n}\left(x\right)" + assert latex(bell(n, m, (x, y))) == r"B_{n, m}\left(x, y\right)" + assert latex(bell(n)**2) == r"B_{n}^{2}" + assert latex(bell(n, x)**2) == r"B_{n}^{2}\left(x\right)" + assert latex(bell(n, m, (x, y))**2) == r"B_{n, m}^{2}\left(x, y\right)" + assert latex(fibonacci(n)) == r"F_{n}" + assert latex(fibonacci(n, x)) == r"F_{n}\left(x\right)" + assert latex(fibonacci(n)**2) == r"F_{n}^{2}" + assert latex(fibonacci(n, x)**2) == r"F_{n}^{2}\left(x\right)" + assert latex(lucas(n)) == r"L_{n}" + assert latex(lucas(n)**2) == r"L_{n}^{2}" + assert latex(tribonacci(n)) == r"T_{n}" + assert latex(tribonacci(n, x)) == r"T_{n}\left(x\right)" + assert latex(tribonacci(n)**2) == r"T_{n}^{2}" + assert latex(tribonacci(n, x)**2) == r"T_{n}^{2}\left(x\right)" + assert latex(mobius(n)) == r"\mu\left(n\right)" + assert latex(mobius(n)**2) == r"\mu^{2}\left(n\right)" + + +def test_latex_euler(): + assert latex(euler(n)) == r"E_{n}" + assert latex(euler(n, x)) == r"E_{n}\left(x\right)" + assert latex(euler(n, x)**2) == r"E_{n}^{2}\left(x\right)" + + +def test_lamda(): + assert latex(Symbol('lamda')) == r"\lambda" + assert latex(Symbol('Lamda')) == r"\Lambda" + + +def test_custom_symbol_names(): + x = Symbol('x') + y = Symbol('y') + assert latex(x) == r"x" + assert latex(x, symbol_names={x: "x_i"}) == r"x_i" + assert latex(x + y, symbol_names={x: "x_i"}) == r"x_i + y" + assert latex(x**2, symbol_names={x: "x_i"}) == r"x_i^{2}" + assert latex(x + y, symbol_names={x: "x_i", y: "y_j"}) == r"x_i + y_j" + + +def test_matAdd(): + C = MatrixSymbol('C', 5, 5) + B = MatrixSymbol('B', 5, 5) + + n = symbols("n") + h = MatrixSymbol("h", 1, 1) + + assert latex(C - 2*B) in [r'- 2 B + C', r'C -2 B'] + assert latex(C + 2*B) in [r'2 B + C', r'C + 2 B'] + assert latex(B - 2*C) in [r'B - 2 C', r'- 2 C + B'] + assert latex(B + 2*C) in [r'B + 2 C', r'2 C + B'] + + assert latex(n * h - (-h + h.T) * (h + h.T)) == 'n h - \\left(- h + h^{T}\\right) \\left(h + h^{T}\\right)' + assert latex(MatAdd(MatAdd(h, h), MatAdd(h, h))) == '\\left(h + h\\right) + \\left(h + h\\right)' + assert latex(MatMul(MatMul(h, h), MatMul(h, h))) == '\\left(h h\\right) \\left(h h\\right)' + + +def test_matMul(): + A = MatrixSymbol('A', 5, 5) + B = MatrixSymbol('B', 5, 5) + x = Symbol('x') + assert latex(2*A) == r'2 A' + assert latex(2*x*A) == r'2 x A' + assert latex(-2*A) == r'- 2 A' + assert latex(1.5*A) == r'1.5 A' + assert latex(sqrt(2)*A) == r'\sqrt{2} A' + assert latex(-sqrt(2)*A) == r'- \sqrt{2} A' + assert latex(2*sqrt(2)*x*A) == r'2 \sqrt{2} x A' + assert latex(-2*A*(A + 2*B)) in [r'- 2 A \left(A + 2 B\right)', + r'- 2 A \left(2 B + A\right)'] + + +def test_latex_MatrixSlice(): + n = Symbol('n', integer=True) + x, y, z, w, t, = symbols('x y z w t') + X = MatrixSymbol('X', n, n) + Y = MatrixSymbol('Y', 10, 10) + Z = MatrixSymbol('Z', 10, 10) + + assert latex(MatrixSlice(X, (None, None, None), (None, None, None))) == r'X\left[:, :\right]' + assert latex(X[x:x + 1, y:y + 1]) == r'X\left[x:x + 1, y:y + 1\right]' + assert latex(X[x:x + 1:2, y:y + 1:2]) == r'X\left[x:x + 1:2, y:y + 1:2\right]' + assert latex(X[:x, y:]) == r'X\left[:x, y:\right]' + assert latex(X[:x, y:]) == r'X\left[:x, y:\right]' + assert latex(X[x:, :y]) == r'X\left[x:, :y\right]' + assert latex(X[x:y, z:w]) == r'X\left[x:y, z:w\right]' + assert latex(X[x:y:t, w:t:x]) == r'X\left[x:y:t, w:t:x\right]' + assert latex(X[x::y, t::w]) == r'X\left[x::y, t::w\right]' + assert latex(X[:x:y, :t:w]) == r'X\left[:x:y, :t:w\right]' + assert latex(X[::x, ::y]) == r'X\left[::x, ::y\right]' + assert latex(MatrixSlice(X, (0, None, None), (0, None, None))) == r'X\left[:, :\right]' + assert latex(MatrixSlice(X, (None, n, None), (None, n, None))) == r'X\left[:, :\right]' + assert latex(MatrixSlice(X, (0, n, None), (0, n, None))) == r'X\left[:, :\right]' + assert latex(MatrixSlice(X, (0, n, 2), (0, n, 2))) == r'X\left[::2, ::2\right]' + assert latex(X[1:2:3, 4:5:6]) == r'X\left[1:2:3, 4:5:6\right]' + assert latex(X[1:3:5, 4:6:8]) == r'X\left[1:3:5, 4:6:8\right]' + assert latex(X[1:10:2]) == r'X\left[1:10:2, :\right]' + assert latex(Y[:5, 1:9:2]) == r'Y\left[:5, 1:9:2\right]' + assert latex(Y[:5, 1:10:2]) == r'Y\left[:5, 1::2\right]' + assert latex(Y[5, :5:2]) == r'Y\left[5:6, :5:2\right]' + assert latex(X[0:1, 0:1]) == r'X\left[:1, :1\right]' + assert latex(X[0:1:2, 0:1:2]) == r'X\left[:1:2, :1:2\right]' + assert latex((Y + Z)[2:, 2:]) == r'\left(Y + Z\right)\left[2:, 2:\right]' + + +def test_latex_RandomDomain(): + from sympy.stats import Normal, Die, Exponential, pspace, where + from sympy.stats.rv import RandomDomain + + X = Normal('x1', 0, 1) + assert latex(where(X > 0)) == r"\text{Domain: }0 < x_{1} \wedge x_{1} < \infty" + + D = Die('d1', 6) + assert latex(where(D > 4)) == r"\text{Domain: }d_{1} = 5 \vee d_{1} = 6" + + A = Exponential('a', 1) + B = Exponential('b', 1) + assert latex( + pspace(Tuple(A, B)).domain) == \ + r"\text{Domain: }0 \leq a \wedge 0 \leq b \wedge a < \infty \wedge b < \infty" + + assert latex(RandomDomain(FiniteSet(x), FiniteSet(1, 2))) == \ + r'\text{Domain: }\left\{x\right\} \in \left\{1, 2\right\}' + +def test_PrettyPoly(): + from sympy.polys.domains import QQ + F = QQ.frac_field(x, y) + R = QQ[x, y] + + assert latex(F.convert(x/(x + y))) == latex(x/(x + y)) + assert latex(R.convert(x + y)) == latex(x + y) + + +def test_integral_transforms(): + x = Symbol("x") + k = Symbol("k") + f = Function("f") + a = Symbol("a") + b = Symbol("b") + + assert latex(MellinTransform(f(x), x, k)) == \ + r"\mathcal{M}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseMellinTransform(f(k), k, x, a, b)) == \ + r"\mathcal{M}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(LaplaceTransform(f(x), x, k)) == \ + r"\mathcal{L}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseLaplaceTransform(f(k), k, x, (a, b))) == \ + r"\mathcal{L}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(FourierTransform(f(x), x, k)) == \ + r"\mathcal{F}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseFourierTransform(f(k), k, x)) == \ + r"\mathcal{F}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(CosineTransform(f(x), x, k)) == \ + r"\mathcal{COS}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseCosineTransform(f(k), k, x)) == \ + r"\mathcal{COS}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(SineTransform(f(x), x, k)) == \ + r"\mathcal{SIN}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseSineTransform(f(k), k, x)) == \ + r"\mathcal{SIN}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + +def test_PolynomialRingBase(): + from sympy.polys.domains import QQ + assert latex(QQ.old_poly_ring(x, y)) == r"\mathbb{Q}\left[x, y\right]" + assert latex(QQ.old_poly_ring(x, y, order="ilex")) == \ + r"S_<^{-1}\mathbb{Q}\left[x, y\right]" + + +def test_categories(): + from sympy.categories import (Object, IdentityMorphism, + NamedMorphism, Category, Diagram, + DiagramGrid) + + A1 = Object("A1") + A2 = Object("A2") + A3 = Object("A3") + + f1 = NamedMorphism(A1, A2, "f1") + f2 = NamedMorphism(A2, A3, "f2") + id_A1 = IdentityMorphism(A1) + + K1 = Category("K1") + + assert latex(A1) == r"A_{1}" + assert latex(f1) == r"f_{1}:A_{1}\rightarrow A_{2}" + assert latex(id_A1) == r"id:A_{1}\rightarrow A_{1}" + assert latex(f2*f1) == r"f_{2}\circ f_{1}:A_{1}\rightarrow A_{3}" + + assert latex(K1) == r"\mathbf{K_{1}}" + + d = Diagram() + assert latex(d) == r"\emptyset" + + d = Diagram({f1: "unique", f2: S.EmptySet}) + assert latex(d) == r"\left\{ f_{2}\circ f_{1}:A_{1}" \ + r"\rightarrow A_{3} : \emptyset, \ id:A_{1}\rightarrow " \ + r"A_{1} : \emptyset, \ id:A_{2}\rightarrow A_{2} : " \ + r"\emptyset, \ id:A_{3}\rightarrow A_{3} : \emptyset, " \ + r"\ f_{1}:A_{1}\rightarrow A_{2} : \left\{unique\right\}, " \ + r"\ f_{2}:A_{2}\rightarrow A_{3} : \emptyset\right\}" + + d = Diagram({f1: "unique", f2: S.EmptySet}, {f2 * f1: "unique"}) + assert latex(d) == r"\left\{ f_{2}\circ f_{1}:A_{1}" \ + r"\rightarrow A_{3} : \emptyset, \ id:A_{1}\rightarrow " \ + r"A_{1} : \emptyset, \ id:A_{2}\rightarrow A_{2} : " \ + r"\emptyset, \ id:A_{3}\rightarrow A_{3} : \emptyset, " \ + r"\ f_{1}:A_{1}\rightarrow A_{2} : \left\{unique\right\}," \ + r" \ f_{2}:A_{2}\rightarrow A_{3} : \emptyset\right\}" \ + r"\Longrightarrow \left\{ f_{2}\circ f_{1}:A_{1}" \ + r"\rightarrow A_{3} : \left\{unique\right\}\right\}" + + # A linear diagram. + A = Object("A") + B = Object("B") + C = Object("C") + f = NamedMorphism(A, B, "f") + g = NamedMorphism(B, C, "g") + d = Diagram([f, g]) + grid = DiagramGrid(d) + + assert latex(grid) == r"\begin{array}{cc}" + "\n" \ + r"A & B \\" + "\n" \ + r" & C " + "\n" \ + r"\end{array}" + "\n" + + +def test_Modules(): + from sympy.polys.domains import QQ + from sympy.polys.agca import homomorphism + + R = QQ.old_poly_ring(x, y) + F = R.free_module(2) + M = F.submodule([x, y], [1, x**2]) + + assert latex(F) == r"{\mathbb{Q}\left[x, y\right]}^{2}" + assert latex(M) == \ + r"\left\langle {\left[ {x},{y} \right]},{\left[ {1},{x^{2}} \right]} \right\rangle" + + I = R.ideal(x**2, y) + assert latex(I) == r"\left\langle {x^{2}},{y} \right\rangle" + + Q = F / M + assert latex(Q) == \ + r"\frac{{\mathbb{Q}\left[x, y\right]}^{2}}{\left\langle {\left[ {x},"\ + r"{y} \right]},{\left[ {1},{x^{2}} \right]} \right\rangle}" + assert latex(Q.submodule([1, x**3/2], [2, y])) == \ + r"\left\langle {{\left[ {1},{\frac{x^{3}}{2}} \right]} + {\left"\ + r"\langle {\left[ {x},{y} \right]},{\left[ {1},{x^{2}} \right]} "\ + r"\right\rangle}},{{\left[ {2},{y} \right]} + {\left\langle {\left[ "\ + r"{x},{y} \right]},{\left[ {1},{x^{2}} \right]} \right\rangle}} \right\rangle" + + h = homomorphism(QQ.old_poly_ring(x).free_module(2), + QQ.old_poly_ring(x).free_module(2), [0, 0]) + + assert latex(h) == \ + r"{\left[\begin{matrix}0 & 0\\0 & 0\end{matrix}\right]} : "\ + r"{{\mathbb{Q}\left[x\right]}^{2}} \to {{\mathbb{Q}\left[x\right]}^{2}}" + + +def test_QuotientRing(): + from sympy.polys.domains import QQ + R = QQ.old_poly_ring(x)/[x**2 + 1] + + assert latex(R) == \ + r"\frac{\mathbb{Q}\left[x\right]}{\left\langle {x^{2} + 1} \right\rangle}" + assert latex(R.one) == r"{1} + {\left\langle {x^{2} + 1} \right\rangle}" + + +def test_Tr(): + #TODO: Handle indices + A, B = symbols('A B', commutative=False) + t = Tr(A*B) + assert latex(t) == r'\operatorname{tr}\left(A B\right)' + + +def test_Determinant(): + from sympy.matrices import Determinant, Inverse, BlockMatrix, OneMatrix, ZeroMatrix + m = Matrix(((1, 2), (3, 4))) + assert latex(Determinant(m)) == '\\left|{\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}}\\right|' + assert latex(Determinant(Inverse(m))) == \ + '\\left|{\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right]^{-1}}\\right|' + X = MatrixSymbol('X', 2, 2) + assert latex(Determinant(X)) == '\\left|{X}\\right|' + assert latex(Determinant(X + m)) == \ + '\\left|{\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] + X}\\right|' + assert latex(Determinant(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '\\left|{\\begin{matrix}1 & X\\\\\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] & 0\\end{matrix}}\\right|' + + +def test_Adjoint(): + from sympy.matrices import Adjoint, Inverse, Transpose + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(Adjoint(X)) == r'X^{\dagger}' + assert latex(Adjoint(X + Y)) == r'\left(X + Y\right)^{\dagger}' + assert latex(Adjoint(X) + Adjoint(Y)) == r'X^{\dagger} + Y^{\dagger}' + assert latex(Adjoint(X*Y)) == r'\left(X Y\right)^{\dagger}' + assert latex(Adjoint(Y)*Adjoint(X)) == r'Y^{\dagger} X^{\dagger}' + assert latex(Adjoint(X**2)) == r'\left(X^{2}\right)^{\dagger}' + assert latex(Adjoint(X)**2) == r'\left(X^{\dagger}\right)^{2}' + assert latex(Adjoint(Inverse(X))) == r'\left(X^{-1}\right)^{\dagger}' + assert latex(Inverse(Adjoint(X))) == r'\left(X^{\dagger}\right)^{-1}' + assert latex(Adjoint(Transpose(X))) == r'\left(X^{T}\right)^{\dagger}' + assert latex(Transpose(Adjoint(X))) == r'\left(X^{\dagger}\right)^{T}' + assert latex(Transpose(Adjoint(X) + Y)) == r'\left(X^{\dagger} + Y\right)^{T}' + m = Matrix(((1, 2), (3, 4))) + assert latex(Adjoint(m)) == '\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right]^{\\dagger}' + assert latex(Adjoint(m+X)) == \ + '\\left(\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] + X\\right)^{\\dagger}' + from sympy.matrices import BlockMatrix, OneMatrix, ZeroMatrix + assert latex(Adjoint(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '\\left[\\begin{matrix}1 & X\\\\\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] & 0\\end{matrix}\\right]^{\\dagger}' + # Issue 20959 + Mx = MatrixSymbol('M^x', 2, 2) + assert latex(Adjoint(Mx)) == r'\left(M^{x}\right)^{\dagger}' + + # adjoint style + assert latex(Adjoint(X), adjoint_style="star") == r'X^{\ast}' + assert latex(Adjoint(X + Y), adjoint_style="hermitian") == r'\left(X + Y\right)^{\mathsf{H}}' + assert latex(Adjoint(X) + Adjoint(Y), adjoint_style="dagger") == r'X^{\dagger} + Y^{\dagger}' + assert latex(Adjoint(Y)*Adjoint(X)) == r'Y^{\dagger} X^{\dagger}' + assert latex(Adjoint(X**2), adjoint_style="star") == r'\left(X^{2}\right)^{\ast}' + assert latex(Adjoint(X)**2, adjoint_style="hermitian") == r'\left(X^{\mathsf{H}}\right)^{2}' + +def test_Transpose(): + from sympy.matrices import Transpose, MatPow, HadamardPower + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(Transpose(X)) == r'X^{T}' + assert latex(Transpose(X + Y)) == r'\left(X + Y\right)^{T}' + + assert latex(Transpose(HadamardPower(X, 2))) == r'\left(X^{\circ {2}}\right)^{T}' + assert latex(HadamardPower(Transpose(X), 2)) == r'\left(X^{T}\right)^{\circ {2}}' + assert latex(Transpose(MatPow(X, 2))) == r'\left(X^{2}\right)^{T}' + assert latex(MatPow(Transpose(X), 2)) == r'\left(X^{T}\right)^{2}' + m = Matrix(((1, 2), (3, 4))) + assert latex(Transpose(m)) == '\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right]^{T}' + assert latex(Transpose(m+X)) == \ + '\\left(\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] + X\\right)^{T}' + from sympy.matrices import BlockMatrix, OneMatrix, ZeroMatrix + assert latex(Transpose(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '\\left[\\begin{matrix}1 & X\\\\\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] & 0\\end{matrix}\\right]^{T}' + # Issue 20959 + Mx = MatrixSymbol('M^x', 2, 2) + assert latex(Transpose(Mx)) == r'\left(M^{x}\right)^{T}' + + +def test_Hadamard(): + from sympy.matrices import HadamardProduct, HadamardPower + from sympy.matrices.expressions import MatAdd, MatMul, MatPow + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(HadamardProduct(X, Y*Y)) == r'X \circ Y^{2}' + assert latex(HadamardProduct(X, Y)*Y) == r'\left(X \circ Y\right) Y' + + assert latex(HadamardPower(X, 2)) == r'X^{\circ {2}}' + assert latex(HadamardPower(X, -1)) == r'X^{\circ \left({-1}\right)}' + assert latex(HadamardPower(MatAdd(X, Y), 2)) == \ + r'\left(X + Y\right)^{\circ {2}}' + assert latex(HadamardPower(MatMul(X, Y), 2)) == \ + r'\left(X Y\right)^{\circ {2}}' + + assert latex(HadamardPower(MatPow(X, -1), -1)) == \ + r'\left(X^{-1}\right)^{\circ \left({-1}\right)}' + assert latex(MatPow(HadamardPower(X, -1), -1)) == \ + r'\left(X^{\circ \left({-1}\right)}\right)^{-1}' + + assert latex(HadamardPower(X, n+1)) == \ + r'X^{\circ \left({n + 1}\right)}' + + +def test_MatPow(): + from sympy.matrices.expressions import MatPow + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(MatPow(X, 2)) == 'X^{2}' + assert latex(MatPow(X*X, 2)) == '\\left(X^{2}\\right)^{2}' + assert latex(MatPow(X*Y, 2)) == '\\left(X Y\\right)^{2}' + assert latex(MatPow(X + Y, 2)) == '\\left(X + Y\\right)^{2}' + assert latex(MatPow(X + X, 2)) == '\\left(2 X\\right)^{2}' + # Issue 20959 + Mx = MatrixSymbol('M^x', 2, 2) + assert latex(MatPow(Mx, 2)) == r'\left(M^{x}\right)^{2}' + + +def test_ElementwiseApplyFunction(): + X = MatrixSymbol('X', 2, 2) + expr = (X.T*X).applyfunc(sin) + assert latex(expr) == r"{\left( d \mapsto \sin{\left(d \right)} \right)}_{\circ}\left({X^{T} X}\right)" + expr = X.applyfunc(Lambda(x, 1/x)) + assert latex(expr) == r'{\left( x \mapsto \frac{1}{x} \right)}_{\circ}\left({X}\right)' + + +def test_ZeroMatrix(): + from sympy.matrices.expressions.special import ZeroMatrix + assert latex(ZeroMatrix(1, 1), mat_symbol_style='plain') == r"0" + assert latex(ZeroMatrix(1, 1), mat_symbol_style='bold') == r"\mathbf{0}" + + +def test_OneMatrix(): + from sympy.matrices.expressions.special import OneMatrix + assert latex(OneMatrix(3, 4), mat_symbol_style='plain') == r"1" + assert latex(OneMatrix(3, 4), mat_symbol_style='bold') == r"\mathbf{1}" + + +def test_Identity(): + from sympy.matrices.expressions.special import Identity + assert latex(Identity(1), mat_symbol_style='plain') == r"\mathbb{I}" + assert latex(Identity(1), mat_symbol_style='bold') == r"\mathbf{I}" + + +def test_latex_DFT_IDFT(): + from sympy.matrices.expressions.fourier import DFT, IDFT + assert latex(DFT(13)) == r"\text{DFT}_{13}" + assert latex(IDFT(x)) == r"\text{IDFT}_{x}" + + +def test_boolean_args_order(): + syms = symbols('a:f') + + expr = And(*syms) + assert latex(expr) == r'a \wedge b \wedge c \wedge d \wedge e \wedge f' + + expr = Or(*syms) + assert latex(expr) == r'a \vee b \vee c \vee d \vee e \vee f' + + expr = Equivalent(*syms) + assert latex(expr) == \ + r'a \Leftrightarrow b \Leftrightarrow c \Leftrightarrow d \Leftrightarrow e \Leftrightarrow f' + + expr = Xor(*syms) + assert latex(expr) == \ + r'a \veebar b \veebar c \veebar d \veebar e \veebar f' + + +def test_imaginary(): + i = sqrt(-1) + assert latex(i) == r'i' + + +def test_builtins_without_args(): + assert latex(sin) == r'\sin' + assert latex(cos) == r'\cos' + assert latex(tan) == r'\tan' + assert latex(log) == r'\log' + assert latex(Ei) == r'\operatorname{Ei}' + assert latex(zeta) == r'\zeta' + + +def test_latex_greek_functions(): + # bug because capital greeks that have roman equivalents should not use + # \Alpha, \Beta, \Eta, etc. + s = Function('Alpha') + assert latex(s) == r'\mathrm{A}' + assert latex(s(x)) == r'\mathrm{A}{\left(x \right)}' + s = Function('Beta') + assert latex(s) == r'\mathrm{B}' + s = Function('Eta') + assert latex(s) == r'\mathrm{H}' + assert latex(s(x)) == r'\mathrm{H}{\left(x \right)}' + + # bug because sympy.core.numbers.Pi is special + p = Function('Pi') + # assert latex(p(x)) == r'\Pi{\left(x \right)}' + assert latex(p) == r'\Pi' + + # bug because not all greeks are included + c = Function('chi') + assert latex(c(x)) == r'\chi{\left(x \right)}' + assert latex(c) == r'\chi' + + +def test_translate(): + s = 'Alpha' + assert translate(s) == r'\mathrm{A}' + s = 'Beta' + assert translate(s) == r'\mathrm{B}' + s = 'Eta' + assert translate(s) == r'\mathrm{H}' + s = 'omicron' + assert translate(s) == r'o' + s = 'Pi' + assert translate(s) == r'\Pi' + s = 'pi' + assert translate(s) == r'\pi' + s = 'LamdaHatDOT' + assert translate(s) == r'\dot{\hat{\Lambda}}' + + +def test_other_symbols(): + from sympy.printing.latex import other_symbols + for s in other_symbols: + assert latex(symbols(s)) == r"" "\\" + s + + +def test_modifiers(): + # Test each modifier individually in the simplest case + # (with funny capitalizations) + assert latex(symbols("xMathring")) == r"\mathring{x}" + assert latex(symbols("xCheck")) == r"\check{x}" + assert latex(symbols("xBreve")) == r"\breve{x}" + assert latex(symbols("xAcute")) == r"\acute{x}" + assert latex(symbols("xGrave")) == r"\grave{x}" + assert latex(symbols("xTilde")) == r"\tilde{x}" + assert latex(symbols("xPrime")) == r"{x}'" + assert latex(symbols("xddDDot")) == r"\ddddot{x}" + assert latex(symbols("xDdDot")) == r"\dddot{x}" + assert latex(symbols("xDDot")) == r"\ddot{x}" + assert latex(symbols("xBold")) == r"\boldsymbol{x}" + assert latex(symbols("xnOrM")) == r"\left\|{x}\right\|" + assert latex(symbols("xAVG")) == r"\left\langle{x}\right\rangle" + assert latex(symbols("xHat")) == r"\hat{x}" + assert latex(symbols("xDot")) == r"\dot{x}" + assert latex(symbols("xBar")) == r"\bar{x}" + assert latex(symbols("xVec")) == r"\vec{x}" + assert latex(symbols("xAbs")) == r"\left|{x}\right|" + assert latex(symbols("xMag")) == r"\left|{x}\right|" + assert latex(symbols("xPrM")) == r"{x}'" + assert latex(symbols("xBM")) == r"\boldsymbol{x}" + # Test strings that are *only* the names of modifiers + assert latex(symbols("Mathring")) == r"Mathring" + assert latex(symbols("Check")) == r"Check" + assert latex(symbols("Breve")) == r"Breve" + assert latex(symbols("Acute")) == r"Acute" + assert latex(symbols("Grave")) == r"Grave" + assert latex(symbols("Tilde")) == r"Tilde" + assert latex(symbols("Prime")) == r"Prime" + assert latex(symbols("DDot")) == r"\dot{D}" + assert latex(symbols("Bold")) == r"Bold" + assert latex(symbols("NORm")) == r"NORm" + assert latex(symbols("AVG")) == r"AVG" + assert latex(symbols("Hat")) == r"Hat" + assert latex(symbols("Dot")) == r"Dot" + assert latex(symbols("Bar")) == r"Bar" + assert latex(symbols("Vec")) == r"Vec" + assert latex(symbols("Abs")) == r"Abs" + assert latex(symbols("Mag")) == r"Mag" + assert latex(symbols("PrM")) == r"PrM" + assert latex(symbols("BM")) == r"BM" + assert latex(symbols("hbar")) == r"\hbar" + # Check a few combinations + assert latex(symbols("xvecdot")) == r"\dot{\vec{x}}" + assert latex(symbols("xDotVec")) == r"\vec{\dot{x}}" + assert latex(symbols("xHATNorm")) == r"\left\|{\hat{x}}\right\|" + # Check a couple big, ugly combinations + assert latex(symbols('xMathringBm_yCheckPRM__zbreveAbs')) == \ + r"\boldsymbol{\mathring{x}}^{\left|{\breve{z}}\right|}_{{\check{y}}'}" + assert latex(symbols('alphadothat_nVECDOT__tTildePrime')) == \ + r"\hat{\dot{\alpha}}^{{\tilde{t}}'}_{\dot{\vec{n}}}" + + +def test_greek_symbols(): + assert latex(Symbol('alpha')) == r'\alpha' + assert latex(Symbol('beta')) == r'\beta' + assert latex(Symbol('gamma')) == r'\gamma' + assert latex(Symbol('delta')) == r'\delta' + assert latex(Symbol('epsilon')) == r'\epsilon' + assert latex(Symbol('zeta')) == r'\zeta' + assert latex(Symbol('eta')) == r'\eta' + assert latex(Symbol('theta')) == r'\theta' + assert latex(Symbol('iota')) == r'\iota' + assert latex(Symbol('kappa')) == r'\kappa' + assert latex(Symbol('lambda')) == r'\lambda' + assert latex(Symbol('mu')) == r'\mu' + assert latex(Symbol('nu')) == r'\nu' + assert latex(Symbol('xi')) == r'\xi' + assert latex(Symbol('omicron')) == r'o' + assert latex(Symbol('pi')) == r'\pi' + assert latex(Symbol('rho')) == r'\rho' + assert latex(Symbol('sigma')) == r'\sigma' + assert latex(Symbol('tau')) == r'\tau' + assert latex(Symbol('upsilon')) == r'\upsilon' + assert latex(Symbol('phi')) == r'\phi' + assert latex(Symbol('chi')) == r'\chi' + assert latex(Symbol('psi')) == r'\psi' + assert latex(Symbol('omega')) == r'\omega' + + assert latex(Symbol('Alpha')) == r'\mathrm{A}' + assert latex(Symbol('Beta')) == r'\mathrm{B}' + assert latex(Symbol('Gamma')) == r'\Gamma' + assert latex(Symbol('Delta')) == r'\Delta' + assert latex(Symbol('Epsilon')) == r'\mathrm{E}' + assert latex(Symbol('Zeta')) == r'\mathrm{Z}' + assert latex(Symbol('Eta')) == r'\mathrm{H}' + assert latex(Symbol('Theta')) == r'\Theta' + assert latex(Symbol('Iota')) == r'\mathrm{I}' + assert latex(Symbol('Kappa')) == r'\mathrm{K}' + assert latex(Symbol('Lambda')) == r'\Lambda' + assert latex(Symbol('Mu')) == r'\mathrm{M}' + assert latex(Symbol('Nu')) == r'\mathrm{N}' + assert latex(Symbol('Xi')) == r'\Xi' + assert latex(Symbol('Omicron')) == r'\mathrm{O}' + assert latex(Symbol('Pi')) == r'\Pi' + assert latex(Symbol('Rho')) == r'\mathrm{P}' + assert latex(Symbol('Sigma')) == r'\Sigma' + assert latex(Symbol('Tau')) == r'\mathrm{T}' + assert latex(Symbol('Upsilon')) == r'\Upsilon' + assert latex(Symbol('Phi')) == r'\Phi' + assert latex(Symbol('Chi')) == r'\mathrm{X}' + assert latex(Symbol('Psi')) == r'\Psi' + assert latex(Symbol('Omega')) == r'\Omega' + + assert latex(Symbol('varepsilon')) == r'\varepsilon' + assert latex(Symbol('varkappa')) == r'\varkappa' + assert latex(Symbol('varphi')) == r'\varphi' + assert latex(Symbol('varpi')) == r'\varpi' + assert latex(Symbol('varrho')) == r'\varrho' + assert latex(Symbol('varsigma')) == r'\varsigma' + assert latex(Symbol('vartheta')) == r'\vartheta' + + +def test_fancyset_symbols(): + assert latex(S.Rationals) == r'\mathbb{Q}' + assert latex(S.Naturals) == r'\mathbb{N}' + assert latex(S.Naturals0) == r'\mathbb{N}_0' + assert latex(S.Integers) == r'\mathbb{Z}' + assert latex(S.Reals) == r'\mathbb{R}' + assert latex(S.Complexes) == r'\mathbb{C}' + + +@XFAIL +def test_builtin_without_args_mismatched_names(): + assert latex(CosineTransform) == r'\mathcal{COS}' + + +def test_builtin_no_args(): + assert latex(Chi) == r'\operatorname{Chi}' + assert latex(beta) == r'\operatorname{B}' + assert latex(gamma) == r'\Gamma' + assert latex(KroneckerDelta) == r'\delta' + assert latex(DiracDelta) == r'\delta' + assert latex(lowergamma) == r'\gamma' + + +def test_issue_6853(): + p = Function('Pi') + assert latex(p(x)) == r"\Pi{\left(x \right)}" + + +def test_Mul(): + e = Mul(-2, x + 1, evaluate=False) + assert latex(e) == r'- 2 \left(x + 1\right)' + e = Mul(2, x + 1, evaluate=False) + assert latex(e) == r'2 \left(x + 1\right)' + e = Mul(S.Half, x + 1, evaluate=False) + assert latex(e) == r'\frac{x + 1}{2}' + e = Mul(y, x + 1, evaluate=False) + assert latex(e) == r'y \left(x + 1\right)' + e = Mul(-y, x + 1, evaluate=False) + assert latex(e) == r'- y \left(x + 1\right)' + e = Mul(-2, x + 1) + assert latex(e) == r'- 2 x - 2' + e = Mul(2, x + 1) + assert latex(e) == r'2 x + 2' + + +def test_Pow(): + e = Pow(2, 2, evaluate=False) + assert latex(e) == r'2^{2}' + assert latex(x**(Rational(-1, 3))) == r'\frac{1}{\sqrt[3]{x}}' + x2 = Symbol(r'x^2') + assert latex(x2**2) == r'\left(x^{2}\right)^{2}' + # Issue 11011 + assert latex(S('1.453e4500')**x) == r'{1.453 \cdot 10^{4500}}^{x}' + + +def test_issue_7180(): + assert latex(Equivalent(x, y)) == r"x \Leftrightarrow y" + assert latex(Not(Equivalent(x, y))) == r"x \not\Leftrightarrow y" + + +def test_issue_8409(): + assert latex(S.Half**n) == r"\left(\frac{1}{2}\right)^{n}" + + +def test_issue_8470(): + from sympy.parsing.sympy_parser import parse_expr + e = parse_expr("-B*A", evaluate=False) + assert latex(e) == r"A \left(- B\right)" + + +def test_issue_15439(): + x = MatrixSymbol('x', 2, 2) + y = MatrixSymbol('y', 2, 2) + assert latex((x * y).subs(y, -y)) == r"x \left(- y\right)" + assert latex((x * y).subs(y, -2*y)) == r"x \left(- 2 y\right)" + assert latex((x * y).subs(x, -x)) == r"\left(- x\right) y" + + +def test_issue_2934(): + assert latex(Symbol(r'\frac{a_1}{b_1}')) == r'\frac{a_1}{b_1}' + + +def test_issue_10489(): + latexSymbolWithBrace = r'C_{x_{0}}' + s = Symbol(latexSymbolWithBrace) + assert latex(s) == latexSymbolWithBrace + assert latex(cos(s)) == r'\cos{\left(C_{x_{0}} \right)}' + + +def test_issue_12886(): + m__1, l__1 = symbols('m__1, l__1') + assert latex(m__1**2 + l__1**2) == \ + r'\left(l^{1}\right)^{2} + \left(m^{1}\right)^{2}' + + +def test_issue_13559(): + from sympy.parsing.sympy_parser import parse_expr + expr = parse_expr('5/1', evaluate=False) + assert latex(expr) == r"\frac{5}{1}" + + +def test_issue_13651(): + expr = c + Mul(-1, a + b, evaluate=False) + assert latex(expr) == r"c - \left(a + b\right)" + + +def test_latex_UnevaluatedExpr(): + x = symbols("x") + he = UnevaluatedExpr(1/x) + assert latex(he) == latex(1/x) == r"\frac{1}{x}" + assert latex(he**2) == r"\left(\frac{1}{x}\right)^{2}" + assert latex(he + 1) == r"1 + \frac{1}{x}" + assert latex(x*he) == r"x \frac{1}{x}" + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert latex(A[0, 0]) == r"{A}_{0,0}" + assert latex(3 * A[0, 0]) == r"3 {A}_{0,0}" + + F = C[0, 0].subs(C, A - B) + assert latex(F) == r"{\left(A - B\right)}_{0,0}" + + i, j, k = symbols("i j k") + M = MatrixSymbol("M", k, k) + N = MatrixSymbol("N", k, k) + assert latex((M*N)[i, j]) == \ + r'\sum_{i_{1}=0}^{k - 1} {M}_{i,i_{1}} {N}_{i_{1},j}' + + X_a = MatrixSymbol('X_a', 3, 3) + assert latex(X_a[0, 0]) == r"{X_{a}}_{0,0}" + + +def test_MatrixSymbol_printing(): + # test cases for issue #14237 + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + C = MatrixSymbol("C", 3, 3) + + assert latex(-A) == r"- A" + assert latex(A - A*B - B) == r"A - A B - B" + assert latex(-A*B - A*B*C - B) == r"- A B - A B C - B" + + +def test_DotProduct_printing(): + X = MatrixSymbol('X', 3, 1) + Y = MatrixSymbol('Y', 3, 1) + a = Symbol('a') + assert latex(DotProduct(X, Y)) == r"X \cdot Y" + assert latex(DotProduct(a * X, Y)) == r"a X \cdot Y" + assert latex(a * DotProduct(X, Y)) == r"a \left(X \cdot Y\right)" + + +def test_KroneckerProduct_printing(): + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 2, 2) + assert latex(KroneckerProduct(A, B)) == r'A \otimes B' + + +def test_Series_printing(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(t*x**2 - t**w*x + w, t - y, y) + assert latex(Series(tf1, tf2)) == \ + r'\left(\frac{x y^{2} - z}{- t^{3} + y^{3}}\right) \left(\frac{x - y}{x + y}\right)' + assert latex(Series(tf1, tf2, tf3)) == \ + r'\left(\frac{x y^{2} - z}{- t^{3} + y^{3}}\right) \left(\frac{x - y}{x + y}\right) \left(\frac{t x^{2} - t^{w} x + w}{t - y}\right)' + assert latex(Series(-tf2, tf1)) == \ + r'\left(\frac{- x + y}{x + y}\right) \left(\frac{x y^{2} - z}{- t^{3} + y^{3}}\right)' + + M_1 = Matrix([[5/s], [5/(2*s)]]) + T_1 = TransferFunctionMatrix.from_Matrix(M_1, s) + M_2 = Matrix([[5, 6*s**3]]) + T_2 = TransferFunctionMatrix.from_Matrix(M_2, s) + # Brackets + assert latex(T_1*(T_2 + T_2)) == \ + r'\left[\begin{matrix}\frac{5}{s}\\\frac{5}{2 s}\end{matrix}\right]_\tau\cdot\left(\left[\begin{matrix}\frac{5}{1} &' \ + r' \frac{6 s^{3}}{1}\end{matrix}\right]_\tau + \left[\begin{matrix}\frac{5}{1} & \frac{6 s^{3}}{1}\end{matrix}\right]_\tau\right)' \ + == latex(MIMOSeries(MIMOParallel(T_2, T_2), T_1)) + # No Brackets + M_3 = Matrix([[5, 6], [6, 5/s]]) + T_3 = TransferFunctionMatrix.from_Matrix(M_3, s) + assert latex(T_1*T_2 + T_3) == r'\left[\begin{matrix}\frac{5}{s}\\\frac{5}{2 s}\end{matrix}\right]_\tau\cdot\left[\begin{matrix}' \ + r'\frac{5}{1} & \frac{6 s^{3}}{1}\end{matrix}\right]_\tau + \left[\begin{matrix}\frac{5}{1} & \frac{6}{1}\\\frac{6}{1} & ' \ + r'\frac{5}{s}\end{matrix}\right]_\tau' == latex(MIMOParallel(MIMOSeries(T_2, T_1), T_3)) + + +def test_TransferFunction_printing(): + tf1 = TransferFunction(x - 1, x + 1, x) + assert latex(tf1) == r"\frac{x - 1}{x + 1}" + tf2 = TransferFunction(x + 1, 2 - y, x) + assert latex(tf2) == r"\frac{x + 1}{2 - y}" + tf3 = TransferFunction(y, y**2 + 2*y + 3, y) + assert latex(tf3) == r"\frac{y}{y^{2} + 2 y + 3}" + + +def test_Parallel_printing(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + assert latex(Parallel(tf1, tf2)) == \ + r'\frac{x y^{2} - z}{- t^{3} + y^{3}} + \frac{x - y}{x + y}' + assert latex(Parallel(-tf2, tf1)) == \ + r'\frac{- x + y}{x + y} + \frac{x y^{2} - z}{- t^{3} + y^{3}}' + + M_1 = Matrix([[5, 6], [6, 5/s]]) + T_1 = TransferFunctionMatrix.from_Matrix(M_1, s) + M_2 = Matrix([[5/s, 6], [6, 5/(s - 1)]]) + T_2 = TransferFunctionMatrix.from_Matrix(M_2, s) + M_3 = Matrix([[6, 5/(s*(s - 1))], [5, 6]]) + T_3 = TransferFunctionMatrix.from_Matrix(M_3, s) + assert latex(T_1 + T_2 + T_3) == r'\left[\begin{matrix}\frac{5}{1} & \frac{6}{1}\\\frac{6}{1} & \frac{5}{s}\end{matrix}\right]' \ + r'_\tau + \left[\begin{matrix}\frac{5}{s} & \frac{6}{1}\\\frac{6}{1} & \frac{5}{s - 1}\end{matrix}\right]_\tau + \left[\begin{matrix}' \ + r'\frac{6}{1} & \frac{5}{s \left(s - 1\right)}\\\frac{5}{1} & \frac{6}{1}\end{matrix}\right]_\tau' \ + == latex(MIMOParallel(T_1, T_2, T_3)) == latex(MIMOParallel(T_1, MIMOParallel(T_2, T_3))) == latex(MIMOParallel(MIMOParallel(T_1, T_2), T_3)) + + +def test_TransferFunctionMatrix_printing(): + tf1 = TransferFunction(p, p + x, p) + tf2 = TransferFunction(-s + p, p + s, p) + tf3 = TransferFunction(p, y**2 + 2*y + 3, p) + assert latex(TransferFunctionMatrix([[tf1], [tf2]])) == \ + r'\left[\begin{matrix}\frac{p}{p + x}\\\frac{p - s}{p + s}\end{matrix}\right]_\tau' + assert latex(TransferFunctionMatrix([[tf1, tf2], [tf3, -tf1]])) == \ + r'\left[\begin{matrix}\frac{p}{p + x} & \frac{p - s}{p + s}\\\frac{p}{y^{2} + 2 y + 3} & \frac{\left(-1\right) p}{p + x}\end{matrix}\right]_\tau' + + +def test_Feedback_printing(): + tf1 = TransferFunction(p, p + x, p) + tf2 = TransferFunction(-s + p, p + s, p) + # Negative Feedback (Default) + assert latex(Feedback(tf1, tf2)) == \ + r'\frac{\frac{p}{p + x}}{\frac{1}{1} + \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + assert latex(Feedback(tf1*tf2, TransferFunction(1, 1, p))) == \ + r'\frac{\left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}{\frac{1}{1} + \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + # Positive Feedback + assert latex(Feedback(tf1, tf2, 1)) == \ + r'\frac{\frac{p}{p + x}}{\frac{1}{1} - \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + assert latex(Feedback(tf1*tf2, sign=1)) == \ + r'\frac{\left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}{\frac{1}{1} - \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + + +def test_MIMOFeedback_printing(): + tf1 = TransferFunction(1, s, s) + tf2 = TransferFunction(s, s**2 - 1, s) + tf3 = TransferFunction(s, s - 1, s) + tf4 = TransferFunction(s**2, s**2 - 1, s) + + tfm_1 = TransferFunctionMatrix([[tf1, tf2], [tf3, tf4]]) + tfm_2 = TransferFunctionMatrix([[tf4, tf3], [tf2, tf1]]) + + # Negative Feedback (Default) + assert latex(MIMOFeedback(tfm_1, tfm_2)) == \ + r'\left(I_{\tau} + \left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\cdot\left[' \ + r'\begin{matrix}\frac{s^{2}}{s^{2} - 1} & \frac{s}{s - 1}\\\frac{s}{s^{2} - 1} & \frac{1}{s}\end{matrix}\right]_\tau\right)^{-1} \cdot \left[\begin{matrix}' \ + r'\frac{1}{s} & \frac{s}{s^{2} - 1}\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau' + + # Positive Feedback + assert latex(MIMOFeedback(tfm_1*tfm_2, tfm_1, 1)) == \ + r'\left(I_{\tau} - \left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\cdot\left' \ + r'[\begin{matrix}\frac{s^{2}}{s^{2} - 1} & \frac{s}{s - 1}\\\frac{s}{s^{2} - 1} & \frac{1}{s}\end{matrix}\right]_\tau\cdot\left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}' \ + r'\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\right)^{-1} \cdot \left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}' \ + r'\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\cdot\left[\begin{matrix}\frac{s^{2}}{s^{2} - 1} & \frac{s}{s - 1}\\\frac{s}{s^{2} - 1}' \ + r' & \frac{1}{s}\end{matrix}\right]_\tau' + + +def test_Quaternion_latex_printing(): + q = Quaternion(x, y, z, t) + assert latex(q) == r"x + y i + z j + t k" + q = Quaternion(x, y, z, x*t) + assert latex(q) == r"x + y i + z j + t x k" + q = Quaternion(x, y, z, x + t) + assert latex(q) == r"x + y i + z j + \left(t + x\right) k" + + +def test_TensorProduct_printing(): + from sympy.tensor.functions import TensorProduct + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + assert latex(TensorProduct(A, B)) == r"A \otimes B" + + +def test_WedgeProduct_printing(): + from sympy.diffgeom.rn import R2 + from sympy.diffgeom import WedgeProduct + wp = WedgeProduct(R2.dx, R2.dy) + assert latex(wp) == r"\operatorname{d}x \wedge \operatorname{d}y" + + +def test_issue_9216(): + expr_1 = Pow(1, -1, evaluate=False) + assert latex(expr_1) == r"1^{-1}" + + expr_2 = Pow(1, Pow(1, -1, evaluate=False), evaluate=False) + assert latex(expr_2) == r"1^{1^{-1}}" + + expr_3 = Pow(3, -2, evaluate=False) + assert latex(expr_3) == r"\frac{1}{9}" + + expr_4 = Pow(1, -2, evaluate=False) + assert latex(expr_4) == r"1^{-2}" + + +def test_latex_printer_tensor(): + from sympy.tensor.tensor import TensorIndexType, tensor_indices, TensorHead, tensor_heads + L = TensorIndexType("L") + i, j, k, l = tensor_indices("i j k l", L) + i0 = tensor_indices("i_0", L) + A, B, C, D = tensor_heads("A B C D", [L]) + H = TensorHead("H", [L, L]) + K = TensorHead("K", [L, L, L, L]) + + assert latex(i) == r"{}^{i}" + assert latex(-i) == r"{}_{i}" + + expr = A(i) + assert latex(expr) == r"A{}^{i}" + + expr = A(i0) + assert latex(expr) == r"A{}^{i_{0}}" + + expr = A(-i) + assert latex(expr) == r"A{}_{i}" + + expr = -3*A(i) + assert latex(expr) == r"-3A{}^{i}" + + expr = K(i, j, -k, -i0) + assert latex(expr) == r"K{}^{ij}{}_{ki_{0}}" + + expr = K(i, -j, -k, i0) + assert latex(expr) == r"K{}^{i}{}_{jk}{}^{i_{0}}" + + expr = K(i, -j, k, -i0) + assert latex(expr) == r"K{}^{i}{}_{j}{}^{k}{}_{i_{0}}" + + expr = H(i, -j) + assert latex(expr) == r"H{}^{i}{}_{j}" + + expr = H(i, j) + assert latex(expr) == r"H{}^{ij}" + + expr = H(-i, -j) + assert latex(expr) == r"H{}_{ij}" + + expr = (1+x)*A(i) + assert latex(expr) == r"\left(x + 1\right)A{}^{i}" + + expr = H(i, -i) + assert latex(expr) == r"H{}^{L_{0}}{}_{L_{0}}" + + expr = H(i, -j)*A(j)*B(k) + assert latex(expr) == r"H{}^{i}{}_{L_{0}}A{}^{L_{0}}B{}^{k}" + + expr = A(i) + 3*B(i) + assert latex(expr) == r"3B{}^{i} + A{}^{i}" + + # Test ``TensorElement``: + from sympy.tensor.tensor import TensorElement + + expr = TensorElement(K(i, j, k, l), {i: 3, k: 2}) + assert latex(expr) == r'K{}^{i=3,j,k=2,l}' + + expr = TensorElement(K(i, j, k, l), {i: 3}) + assert latex(expr) == r'K{}^{i=3,jkl}' + + expr = TensorElement(K(i, -j, k, l), {i: 3, k: 2}) + assert latex(expr) == r'K{}^{i=3}{}_{j}{}^{k=2,l}' + + expr = TensorElement(K(i, -j, k, -l), {i: 3, k: 2}) + assert latex(expr) == r'K{}^{i=3}{}_{j}{}^{k=2}{}_{l}' + + expr = TensorElement(K(i, j, -k, -l), {i: 3, -k: 2}) + assert latex(expr) == r'K{}^{i=3,j}{}_{k=2,l}' + + expr = TensorElement(K(i, j, -k, -l), {i: 3}) + assert latex(expr) == r'K{}^{i=3,j}{}_{kl}' + + expr = PartialDerivative(A(i), A(i)) + assert latex(expr) == r"\frac{\partial}{\partial {A{}^{L_{0}}}}{A{}^{L_{0}}}" + + expr = PartialDerivative(A(-i), A(-j)) + assert latex(expr) == r"\frac{\partial}{\partial {A{}_{j}}}{A{}_{i}}" + + expr = PartialDerivative(K(i, j, -k, -l), A(m), A(-n)) + assert latex(expr) == r"\frac{\partial^{2}}{\partial {A{}^{m}} \partial {A{}_{n}}}{K{}^{ij}{}_{kl}}" + + expr = PartialDerivative(B(-i) + A(-i), A(-j), A(-n)) + assert latex(expr) == r"\frac{\partial^{2}}{\partial {A{}_{j}} \partial {A{}_{n}}}{\left(A{}_{i} + B{}_{i}\right)}" + + expr = PartialDerivative(3*A(-i), A(-j), A(-n)) + assert latex(expr) == r"\frac{\partial^{2}}{\partial {A{}_{j}} \partial {A{}_{n}}}{\left(3A{}_{i}\right)}" + + +def test_multiline_latex(): + a, b, c, d, e, f = symbols('a b c d e f') + expr = -a + 2*b -3*c +4*d -5*e + expected = r"\begin{eqnarray}" + "\n"\ + r"f & = &- a \nonumber\\" + "\n"\ + r"& & + 2 b \nonumber\\" + "\n"\ + r"& & - 3 c \nonumber\\" + "\n"\ + r"& & + 4 d \nonumber\\" + "\n"\ + r"& & - 5 e " + "\n"\ + r"\end{eqnarray}" + assert multiline_latex(f, expr, environment="eqnarray") == expected + + expected2 = r'\begin{eqnarray}' + '\n'\ + r'f & = &- a + 2 b \nonumber\\' + '\n'\ + r'& & - 3 c + 4 d \nonumber\\' + '\n'\ + r'& & - 5 e ' + '\n'\ + r'\end{eqnarray}' + + assert multiline_latex(f, expr, 2, environment="eqnarray") == expected2 + + expected3 = r'\begin{eqnarray}' + '\n'\ + r'f & = &- a + 2 b - 3 c \nonumber\\'+ '\n'\ + r'& & + 4 d - 5 e ' + '\n'\ + r'\end{eqnarray}' + + assert multiline_latex(f, expr, 3, environment="eqnarray") == expected3 + + expected3dots = r'\begin{eqnarray}' + '\n'\ + r'f & = &- a + 2 b - 3 c \dots\nonumber\\'+ '\n'\ + r'& & + 4 d - 5 e ' + '\n'\ + r'\end{eqnarray}' + + assert multiline_latex(f, expr, 3, environment="eqnarray", use_dots=True) == expected3dots + + expected3align = r'\begin{align*}' + '\n'\ + r'f = &- a + 2 b - 3 c \\'+ '\n'\ + r'& + 4 d - 5 e ' + '\n'\ + r'\end{align*}' + + assert multiline_latex(f, expr, 3) == expected3align + assert multiline_latex(f, expr, 3, environment='align*') == expected3align + + expected2ieee = r'\begin{IEEEeqnarray}{rCl}' + '\n'\ + r'f & = &- a + 2 b \nonumber\\' + '\n'\ + r'& & - 3 c + 4 d \nonumber\\' + '\n'\ + r'& & - 5 e ' + '\n'\ + r'\end{IEEEeqnarray}' + + assert multiline_latex(f, expr, 2, environment="IEEEeqnarray") == expected2ieee + + raises(ValueError, lambda: multiline_latex(f, expr, environment="foo")) + +def test_issue_15353(): + a, x = symbols('a x') + # Obtained from nonlinsolve([(sin(a*x)),cos(a*x)],[x,a]) + sol = ConditionSet( + Tuple(x, a), Eq(sin(a*x), 0) & Eq(cos(a*x), 0), S.Complexes**2) + assert latex(sol) == \ + r'\left\{\left( x, \ a\right)\; \middle|\; \left( x, \ a\right) \in ' \ + r'\mathbb{C}^{2} \wedge \sin{\left(a x \right)} = 0 \wedge ' \ + r'\cos{\left(a x \right)} = 0 \right\}' + + +def test_latex_symbolic_probability(): + mu = symbols("mu") + sigma = symbols("sigma", positive=True) + X = Normal("X", mu, sigma) + assert latex(Expectation(X)) == r'\operatorname{E}\left[X\right]' + assert latex(Variance(X)) == r'\operatorname{Var}\left(X\right)' + assert latex(Probability(X > 0)) == r'\operatorname{P}\left(X > 0\right)' + Y = Normal("Y", mu, sigma) + assert latex(Covariance(X, Y)) == r'\operatorname{Cov}\left(X, Y\right)' + + +def test_trace(): + # Issue 15303 + from sympy.matrices.expressions.trace import trace + A = MatrixSymbol("A", 2, 2) + assert latex(trace(A)) == r"\operatorname{tr}\left(A \right)" + assert latex(trace(A**2)) == r"\operatorname{tr}\left(A^{2} \right)" + + +def test_print_basic(): + # Issue 15303 + from sympy.core.basic import Basic + from sympy.core.expr import Expr + + # dummy class for testing printing where the function is not + # implemented in latex.py + class UnimplementedExpr(Expr): + def __new__(cls, e): + return Basic.__new__(cls, e) + + # dummy function for testing + def unimplemented_expr(expr): + return UnimplementedExpr(expr).doit() + + # override class name to use superscript / subscript + def unimplemented_expr_sup_sub(expr): + result = UnimplementedExpr(expr) + result.__class__.__name__ = 'UnimplementedExpr_x^1' + return result + + assert latex(unimplemented_expr(x)) == r'\operatorname{UnimplementedExpr}\left(x\right)' + assert latex(unimplemented_expr(x**2)) == \ + r'\operatorname{UnimplementedExpr}\left(x^{2}\right)' + assert latex(unimplemented_expr_sup_sub(x)) == \ + r'\operatorname{UnimplementedExpr^{1}_{x}}\left(x\right)' + + +def test_MatrixSymbol_bold(): + # Issue #15871 + from sympy.matrices.expressions.trace import trace + A = MatrixSymbol("A", 2, 2) + assert latex(trace(A), mat_symbol_style='bold') == \ + r"\operatorname{tr}\left(\mathbf{A} \right)" + assert latex(trace(A), mat_symbol_style='plain') == \ + r"\operatorname{tr}\left(A \right)" + + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + C = MatrixSymbol("C", 3, 3) + + assert latex(-A, mat_symbol_style='bold') == r"- \mathbf{A}" + assert latex(A - A*B - B, mat_symbol_style='bold') == \ + r"\mathbf{A} - \mathbf{A} \mathbf{B} - \mathbf{B}" + assert latex(-A*B - A*B*C - B, mat_symbol_style='bold') == \ + r"- \mathbf{A} \mathbf{B} - \mathbf{A} \mathbf{B} \mathbf{C} - \mathbf{B}" + + A_k = MatrixSymbol("A_k", 3, 3) + assert latex(A_k, mat_symbol_style='bold') == r"\mathbf{A}_{k}" + + A = MatrixSymbol(r"\nabla_k", 3, 3) + assert latex(A, mat_symbol_style='bold') == r"\mathbf{\nabla}_{k}" + +def test_AppliedPermutation(): + p = Permutation(0, 1, 2) + x = Symbol('x') + assert latex(AppliedPermutation(p, x)) == \ + r'\sigma_{\left( 0\; 1\; 2\right)}(x)' + + +def test_PermutationMatrix(): + p = Permutation(0, 1, 2) + assert latex(PermutationMatrix(p)) == r'P_{\left( 0\; 1\; 2\right)}' + p = Permutation(0, 3)(1, 2) + assert latex(PermutationMatrix(p)) == \ + r'P_{\left( 0\; 3\right)\left( 1\; 2\right)}' + + +def test_issue_21758(): + from sympy.functions.elementary.piecewise import piecewise_fold + from sympy.series.fourier import FourierSeries + x = Symbol('x') + k, n = symbols('k n') + fo = FourierSeries(x, (x, -pi, pi), (0, SeqFormula(0, (k, 1, oo)), SeqFormula( + Piecewise((-2*pi*cos(n*pi)/n + 2*sin(n*pi)/n**2, (n > -oo) & (n < oo) & Ne(n, 0)), + (0, True))*sin(n*x)/pi, (n, 1, oo)))) + assert latex(piecewise_fold(fo)) == '\\begin{cases} 2 \\sin{\\left(x \\right)}' \ + ' - \\sin{\\left(2 x \\right)} + \\frac{2 \\sin{\\left(3 x \\right)}}{3} +' \ + ' \\ldots & \\text{for}\\: n > -\\infty \\wedge n < \\infty \\wedge ' \ + 'n \\neq 0 \\\\0 & \\text{otherwise} \\end{cases}' + assert latex(FourierSeries(x, (x, -pi, pi), (0, SeqFormula(0, (k, 1, oo)), + SeqFormula(0, (n, 1, oo))))) == '0' + + +def test_imaginary_unit(): + assert latex(1 + I) == r'1 + i' + assert latex(1 + I, imaginary_unit='i') == r'1 + i' + assert latex(1 + I, imaginary_unit='j') == r'1 + j' + assert latex(1 + I, imaginary_unit='foo') == r'1 + foo' + assert latex(I, imaginary_unit="ti") == r'\text{i}' + assert latex(I, imaginary_unit="tj") == r'\text{j}' + + +def test_text_re_im(): + assert latex(im(x), gothic_re_im=True) == r'\Im{\left(x\right)}' + assert latex(im(x), gothic_re_im=False) == r'\operatorname{im}{\left(x\right)}' + assert latex(re(x), gothic_re_im=True) == r'\Re{\left(x\right)}' + assert latex(re(x), gothic_re_im=False) == r'\operatorname{re}{\left(x\right)}' + + +def test_latex_diffgeom(): + from sympy.diffgeom import Manifold, Patch, CoordSystem, BaseScalarField, Differential + from sympy.diffgeom.rn import R2 + x,y = symbols('x y', real=True) + m = Manifold('M', 2) + assert latex(m) == r'\text{M}' + p = Patch('P', m) + assert latex(p) == r'\text{P}_{\text{M}}' + rect = CoordSystem('rect', p, [x, y]) + assert latex(rect) == r'\text{rect}^{\text{P}}_{\text{M}}' + b = BaseScalarField(rect, 0) + assert latex(b) == r'\mathbf{x}' + + g = Function('g') + s_field = g(R2.x, R2.y) + assert latex(Differential(s_field)) == \ + r'\operatorname{d}\left(g{\left(\mathbf{x},\mathbf{y} \right)}\right)' + + +def test_unit_printing(): + assert latex(5*meter) == r'5 \text{m}' + assert latex(3*gibibyte) == r'3 \text{gibibyte}' + assert latex(4*microgram/second) == r'\frac{4 \mu\text{g}}{\text{s}}' + assert latex(4*micro*gram/second) == r'\frac{4 \mu \text{g}}{\text{s}}' + assert latex(5*milli*meter) == r'5 \text{m} \text{m}' + assert latex(milli) == r'\text{m}' + + +def test_issue_17092(): + x_star = Symbol('x^*') + assert latex(Derivative(x_star, x_star,2)) == r'\frac{d^{2}}{d \left(x^{*}\right)^{2}} x^{*}' + + +def test_latex_decimal_separator(): + + x, y, z, t = symbols('x y z t') + k, m, n = symbols('k m n', integer=True) + f, g, h = symbols('f g h', cls=Function) + + # comma decimal_separator + assert(latex([1, 2.3, 4.5], decimal_separator='comma') == r'\left[ 1; \ 2{,}3; \ 4{,}5\right]') + assert(latex(FiniteSet(1, 2.3, 4.5), decimal_separator='comma') == r'\left\{1; 2{,}3; 4{,}5\right\}') + assert(latex((1, 2.3, 4.6), decimal_separator = 'comma') == r'\left( 1; \ 2{,}3; \ 4{,}6\right)') + assert(latex((1,), decimal_separator='comma') == r'\left( 1;\right)') + + # period decimal_separator + assert(latex([1, 2.3, 4.5], decimal_separator='period') == r'\left[ 1, \ 2.3, \ 4.5\right]' ) + assert(latex(FiniteSet(1, 2.3, 4.5), decimal_separator='period') == r'\left\{1, 2.3, 4.5\right\}') + assert(latex((1, 2.3, 4.6), decimal_separator = 'period') == r'\left( 1, \ 2.3, \ 4.6\right)') + assert(latex((1,), decimal_separator='period') == r'\left( 1,\right)') + + # default decimal_separator + assert(latex([1, 2.3, 4.5]) == r'\left[ 1, \ 2.3, \ 4.5\right]') + assert(latex(FiniteSet(1, 2.3, 4.5)) == r'\left\{1, 2.3, 4.5\right\}') + assert(latex((1, 2.3, 4.6)) == r'\left( 1, \ 2.3, \ 4.6\right)') + assert(latex((1,)) == r'\left( 1,\right)') + + assert(latex(Mul(3.4,5.3), decimal_separator = 'comma') == r'18{,}02') + assert(latex(3.4*5.3, decimal_separator = 'comma') == r'18{,}02') + x = symbols('x') + y = symbols('y') + z = symbols('z') + assert(latex(x*5.3 + 2**y**3.4 + 4.5 + z, decimal_separator = 'comma') == r'2^{y^{3{,}4}} + 5{,}3 x + z + 4{,}5') + + assert(latex(0.987, decimal_separator='comma') == r'0{,}987') + assert(latex(S(0.987), decimal_separator='comma') == r'0{,}987') + assert(latex(.3, decimal_separator='comma') == r'0{,}3') + assert(latex(S(.3), decimal_separator='comma') == r'0{,}3') + + + assert(latex(5.8*10**(-7), decimal_separator='comma') == r'5{,}8 \cdot 10^{-7}') + assert(latex(S(5.7)*10**(-7), decimal_separator='comma') == r'5{,}7 \cdot 10^{-7}') + assert(latex(S(5.7*10**(-7)), decimal_separator='comma') == r'5{,}7 \cdot 10^{-7}') + + x = symbols('x') + assert(latex(1.2*x+3.4, decimal_separator='comma') == r'1{,}2 x + 3{,}4') + assert(latex(FiniteSet(1, 2.3, 4.5), decimal_separator='period') == r'\left\{1, 2.3, 4.5\right\}') + + # Error Handling tests + raises(ValueError, lambda: latex([1,2.3,4.5], decimal_separator='non_existing_decimal_separator_in_list')) + raises(ValueError, lambda: latex(FiniteSet(1,2.3,4.5), decimal_separator='non_existing_decimal_separator_in_set')) + raises(ValueError, lambda: latex((1,2.3,4.5), decimal_separator='non_existing_decimal_separator_in_tuple')) + +def test_Str(): + from sympy.core.symbol import Str + assert str(Str('x')) == r'x' + +def test_latex_escape(): + assert latex_escape(r"~^\&%$#_{}") == "".join([ + r'\textasciitilde', + r'\textasciicircum', + r'\textbackslash', + r'\&', + r'\%', + r'\$', + r'\#', + r'\_', + r'\{', + r'\}', + ]) + +def test_emptyPrinter(): + class MyObject: + def __repr__(self): + return "" + + # unknown objects are monospaced + assert latex(MyObject()) == r"\mathtt{\text{}}" + + # even if they are nested within other objects + assert latex((MyObject(),)) == r"\left( \mathtt{\text{}},\right)" + +def test_global_settings(): + import inspect + + # settings should be visible in the signature of `latex` + assert inspect.signature(latex).parameters['imaginary_unit'].default == r'i' + assert latex(I) == r'i' + try: + # but changing the defaults... + LatexPrinter.set_global_settings(imaginary_unit='j') + # ... should change the signature + assert inspect.signature(latex).parameters['imaginary_unit'].default == r'j' + assert latex(I) == r'j' + finally: + # there's no public API to undo this, but we need to make sure we do + # so as not to impact other tests + del LatexPrinter._global_settings['imaginary_unit'] + + # check we really did undo it + assert inspect.signature(latex).parameters['imaginary_unit'].default == r'i' + assert latex(I) == r'i' + +def test_pickleable(): + # this tests that the _PrintFunction instance is pickleable + import pickle + assert pickle.loads(pickle.dumps(latex)) is latex + +def test_printing_latex_array_expressions(): + assert latex(ArraySymbol("A", (2, 3, 4))) == "A" + assert latex(ArrayElement("A", (2, 1/(1-x), 0))) == "{{A}_{2, \\frac{1}{1 - x}, 0}}" + M = MatrixSymbol("M", 3, 3) + N = MatrixSymbol("N", 3, 3) + assert latex(ArrayElement(M*N, [x, 0])) == "{{\\left(M N\\right)}_{x, 0}}" + +def test_Array(): + arr = Array(range(10)) + assert latex(arr) == r'\left[\begin{matrix}0 & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9\end{matrix}\right]' + + arr = Array(range(11)) + # fill the empty argument with a bunch of 'c' to avoid latex errors + assert latex(arr) == r'\left[\begin{array}{ccccccccccc}0 & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9 & 10\end{array}\right]' + +def test_latex_with_unevaluated(): + with evaluate(False): + assert latex(a * a) == r"a a" + + +def test_latex_disable_split_super_sub(): + assert latex(Symbol('u^a_b')) == 'u^{a}_{b}' + assert latex(Symbol('u^a_b'), disable_split_super_sub=False) == 'u^{a}_{b}' + assert latex(Symbol('u^a_b'), disable_split_super_sub=True) == 'u\\^a\\_b' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_llvmjit.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_llvmjit.py new file mode 100644 index 0000000000000000000000000000000000000000..709476f1d7517dc629210341594a70dc6f41808f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_llvmjit.py @@ -0,0 +1,224 @@ +from sympy.external import import_module +from sympy.testing.pytest import raises +import ctypes + + +if import_module('llvmlite'): + import sympy.printing.llvmjitcode as g +else: + disabled = True + +import sympy +from sympy.abc import a, b, n + + +# copied from numpy.isclose documentation +def isclose(a, b): + rtol = 1e-5 + atol = 1e-8 + return abs(a-b) <= atol + rtol*abs(b) + + +def test_simple_expr(): + e = a + 1.0 + f = g.llvm_callable([a], e) + res = float(e.subs({a: 4.0}).evalf()) + jit_res = f(4.0) + + assert isclose(jit_res, res) + + +def test_two_arg(): + e = 4.0*a + b + 3.0 + f = g.llvm_callable([a, b], e) + res = float(e.subs({a: 4.0, b: 3.0}).evalf()) + jit_res = f(4.0, 3.0) + + assert isclose(jit_res, res) + + +def test_func(): + e = 4.0*sympy.exp(-a) + f = g.llvm_callable([a], e) + res = float(e.subs({a: 1.5}).evalf()) + jit_res = f(1.5) + + assert isclose(jit_res, res) + + +def test_two_func(): + e = 4.0*sympy.exp(-a) + sympy.exp(b) + f = g.llvm_callable([a, b], e) + res = float(e.subs({a: 1.5, b: 2.0}).evalf()) + jit_res = f(1.5, 2.0) + + assert isclose(jit_res, res) + + +def test_two_sqrt(): + e = 4.0*sympy.sqrt(a) + sympy.sqrt(b) + f = g.llvm_callable([a, b], e) + res = float(e.subs({a: 1.5, b: 2.0}).evalf()) + jit_res = f(1.5, 2.0) + + assert isclose(jit_res, res) + + +def test_two_pow(): + e = a**1.5 + b**7 + f = g.llvm_callable([a, b], e) + res = float(e.subs({a: 1.5, b: 2.0}).evalf()) + jit_res = f(1.5, 2.0) + + assert isclose(jit_res, res) + + +def test_callback(): + e = a + 1.2 + f = g.llvm_callable([a], e, callback_type='scipy.integrate.test') + m = ctypes.c_int(1) + array_type = ctypes.c_double * 1 + inp = {a: 2.2} + array = array_type(inp[a]) + jit_res = f(m, array) + + res = float(e.subs(inp).evalf()) + + assert isclose(jit_res, res) + + +def test_callback_cubature(): + e = a + 1.2 + f = g.llvm_callable([a], e, callback_type='cubature') + m = ctypes.c_int(1) + array_type = ctypes.c_double * 1 + inp = {a: 2.2} + array = array_type(inp[a]) + out_array = array_type(0.0) + jit_ret = f(m, array, None, m, out_array) + + assert jit_ret == 0 + + res = float(e.subs(inp).evalf()) + + assert isclose(out_array[0], res) + + +def test_callback_two(): + e = 3*a*b + f = g.llvm_callable([a, b], e, callback_type='scipy.integrate.test') + m = ctypes.c_int(2) + array_type = ctypes.c_double * 2 + inp = {a: 0.2, b: 1.7} + array = array_type(inp[a], inp[b]) + jit_res = f(m, array) + + res = float(e.subs(inp).evalf()) + + assert isclose(jit_res, res) + + +def test_callback_alt_two(): + d = sympy.IndexedBase('d') + e = 3*d[0]*d[1] + f = g.llvm_callable([n, d], e, callback_type='scipy.integrate.test') + m = ctypes.c_int(2) + array_type = ctypes.c_double * 2 + inp = {d[0]: 0.2, d[1]: 1.7} + array = array_type(inp[d[0]], inp[d[1]]) + jit_res = f(m, array) + + res = float(e.subs(inp).evalf()) + + assert isclose(jit_res, res) + + +def test_multiple_statements(): + # Match return from CSE + e = [[(b, 4.0*a)], [b + 5]] + f = g.llvm_callable([a], e) + b_val = e[0][0][1].subs({a: 1.5}) + res = float(e[1][0].subs({b: b_val}).evalf()) + jit_res = f(1.5) + assert isclose(jit_res, res) + + f_callback = g.llvm_callable([a], e, callback_type='scipy.integrate.test') + m = ctypes.c_int(1) + array_type = ctypes.c_double * 1 + array = array_type(1.5) + jit_callback_res = f_callback(m, array) + assert isclose(jit_callback_res, res) + + +def test_cse(): + e = a*a + b*b + sympy.exp(-a*a - b*b) + e2 = sympy.cse(e) + f = g.llvm_callable([a, b], e2) + res = float(e.subs({a: 2.3, b: 0.1}).evalf()) + jit_res = f(2.3, 0.1) + + assert isclose(jit_res, res) + + +def eval_cse(e, sub_dict): + tmp_dict = {} + for tmp_name, tmp_expr in e[0]: + e2 = tmp_expr.subs(sub_dict) + e3 = e2.subs(tmp_dict) + tmp_dict[tmp_name] = e3 + return [e.subs(sub_dict).subs(tmp_dict) for e in e[1]] + + +def test_cse_multiple(): + e1 = a*a + e2 = a*a + b*b + e3 = sympy.cse([e1, e2]) + + raises(NotImplementedError, + lambda: g.llvm_callable([a, b], e3, callback_type='scipy.integrate')) + + f = g.llvm_callable([a, b], e3) + jit_res = f(0.1, 1.5) + assert len(jit_res) == 2 + res = eval_cse(e3, {a: 0.1, b: 1.5}) + assert isclose(res[0], jit_res[0]) + assert isclose(res[1], jit_res[1]) + + +def test_callback_cubature_multiple(): + e1 = a*a + e2 = a*a + b*b + e3 = sympy.cse([e1, e2, 4*e2]) + f = g.llvm_callable([a, b], e3, callback_type='cubature') + + # Number of input variables + ndim = 2 + # Number of output expression values + outdim = 3 + + m = ctypes.c_int(ndim) + fdim = ctypes.c_int(outdim) + array_type = ctypes.c_double * ndim + out_array_type = ctypes.c_double * outdim + inp = {a: 0.2, b: 1.5} + array = array_type(inp[a], inp[b]) + out_array = out_array_type() + jit_ret = f(m, array, None, fdim, out_array) + + assert jit_ret == 0 + + res = eval_cse(e3, inp) + + assert isclose(out_array[0], res[0]) + assert isclose(out_array[1], res[1]) + assert isclose(out_array[2], res[2]) + + +def test_symbol_not_found(): + e = a*a + b + raises(LookupError, lambda: g.llvm_callable([a], e)) + + +def test_bad_callback(): + e = a + raises(ValueError, lambda: g.llvm_callable([a], e, callback_type='bad_callback')) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_maple.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_maple.py new file mode 100644 index 0000000000000000000000000000000000000000..9bb4c512ad3203bd64ae56b350e15734b3a6afb0 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_maple.py @@ -0,0 +1,381 @@ +from sympy.core import (S, pi, oo, symbols, Function, Rational, Integer, + Tuple, Symbol, Eq, Ne, Le, Lt, Gt, Ge) +from sympy.core import EulerGamma, GoldenRatio, Catalan, Lambda, Mul, Pow +from sympy.functions import Piecewise, sqrt, ceiling, exp, sin, cos, sinc, lucas +from sympy.testing.pytest import raises +from sympy.utilities.lambdify import implemented_function +from sympy.matrices import (eye, Matrix, MatrixSymbol, Identity, + HadamardProduct, SparseMatrix) +from sympy.functions.special.bessel import besseli + +from sympy.printing.maple import maple_code + +x, y, z = symbols('x,y,z') + + +def test_Integer(): + assert maple_code(Integer(67)) == "67" + assert maple_code(Integer(-1)) == "-1" + + +def test_Rational(): + assert maple_code(Rational(3, 7)) == "3/7" + assert maple_code(Rational(18, 9)) == "2" + assert maple_code(Rational(3, -7)) == "-3/7" + assert maple_code(Rational(-3, -7)) == "3/7" + assert maple_code(x + Rational(3, 7)) == "x + 3/7" + assert maple_code(Rational(3, 7) * x) == '(3/7)*x' + + +def test_Relational(): + assert maple_code(Eq(x, y)) == "x = y" + assert maple_code(Ne(x, y)) == "x <> y" + assert maple_code(Le(x, y)) == "x <= y" + assert maple_code(Lt(x, y)) == "x < y" + assert maple_code(Gt(x, y)) == "x > y" + assert maple_code(Ge(x, y)) == "x >= y" + + +def test_Function(): + assert maple_code(sin(x) ** cos(x)) == "sin(x)^cos(x)" + assert maple_code(abs(x)) == "abs(x)" + assert maple_code(ceiling(x)) == "ceil(x)" + + +def test_Pow(): + assert maple_code(x ** 3) == "x^3" + assert maple_code(x ** (y ** 3)) == "x^(y^3)" + + assert maple_code((x ** 3) ** y) == "(x^3)^y" + assert maple_code(x ** Rational(2, 3)) == 'x^(2/3)' + + g = implemented_function('g', Lambda(x, 2 * x)) + assert maple_code(1 / (g(x) * 3.5) ** (x - y ** x) / (x ** 2 + y)) == \ + "(3.5*2*x)^(-x + y^x)/(x^2 + y)" + # For issue 14160 + assert maple_code(Mul(-2, x, Pow(Mul(y, y, evaluate=False), -1, evaluate=False), + evaluate=False)) == '-2*x/(y*y)' + + +def test_basic_ops(): + assert maple_code(x * y) == "x*y" + assert maple_code(x + y) == "x + y" + assert maple_code(x - y) == "x - y" + assert maple_code(-x) == "-x" + + +def test_1_over_x_and_sqrt(): + # 1.0 and 0.5 would do something different in regular StrPrinter, + # but these are exact in IEEE floating point so no different here. + assert maple_code(1 / x) == '1/x' + assert maple_code(x ** -1) == maple_code(x ** -1.0) == '1/x' + assert maple_code(1 / sqrt(x)) == '1/sqrt(x)' + assert maple_code(x ** -S.Half) == maple_code(x ** -0.5) == '1/sqrt(x)' + assert maple_code(sqrt(x)) == 'sqrt(x)' + assert maple_code(x ** S.Half) == maple_code(x ** 0.5) == 'sqrt(x)' + assert maple_code(1 / pi) == '1/Pi' + assert maple_code(pi ** -1) == maple_code(pi ** -1.0) == '1/Pi' + assert maple_code(pi ** -0.5) == '1/sqrt(Pi)' + + +def test_mix_number_mult_symbols(): + assert maple_code(3 * x) == "3*x" + assert maple_code(pi * x) == "Pi*x" + assert maple_code(3 / x) == "3/x" + assert maple_code(pi / x) == "Pi/x" + assert maple_code(x / 3) == '(1/3)*x' + assert maple_code(x / pi) == "x/Pi" + assert maple_code(x * y) == "x*y" + assert maple_code(3 * x * y) == "3*x*y" + assert maple_code(3 * pi * x * y) == "3*Pi*x*y" + assert maple_code(x / y) == "x/y" + assert maple_code(3 * x / y) == "3*x/y" + assert maple_code(x * y / z) == "x*y/z" + assert maple_code(x / y * z) == "x*z/y" + assert maple_code(1 / x / y) == "1/(x*y)" + assert maple_code(2 * pi * x / y / z) == "2*Pi*x/(y*z)" + assert maple_code(3 * pi / x) == "3*Pi/x" + assert maple_code(S(3) / 5) == "3/5" + assert maple_code(S(3) / 5 * x) == '(3/5)*x' + assert maple_code(x / y / z) == "x/(y*z)" + assert maple_code((x + y) / z) == "(x + y)/z" + assert maple_code((x + y) / (z + x)) == "(x + y)/(x + z)" + assert maple_code((x + y) / EulerGamma) == '(x + y)/gamma' + assert maple_code(x / 3 / pi) == '(1/3)*x/Pi' + assert maple_code(S(3) / 5 * x * y / pi) == '(3/5)*x*y/Pi' + + +def test_mix_number_pow_symbols(): + assert maple_code(pi ** 3) == 'Pi^3' + assert maple_code(x ** 2) == 'x^2' + + assert maple_code(x ** (pi ** 3)) == 'x^(Pi^3)' + assert maple_code(x ** y) == 'x^y' + + assert maple_code(x ** (y ** z)) == 'x^(y^z)' + assert maple_code((x ** y) ** z) == '(x^y)^z' + + +def test_imag(): + I = S('I') + assert maple_code(I) == "I" + assert maple_code(5 * I) == "5*I" + + assert maple_code((S(3) / 2) * I) == "(3/2)*I" + assert maple_code(3 + 4 * I) == "3 + 4*I" + + +def test_constants(): + assert maple_code(pi) == "Pi" + assert maple_code(oo) == "infinity" + assert maple_code(-oo) == "-infinity" + assert maple_code(S.NegativeInfinity) == "-infinity" + assert maple_code(S.NaN) == "undefined" + assert maple_code(S.Exp1) == "exp(1)" + assert maple_code(exp(1)) == "exp(1)" + + +def test_constants_other(): + assert maple_code(2 * GoldenRatio) == '2*(1/2 + (1/2)*sqrt(5))' + assert maple_code(2 * Catalan) == '2*Catalan' + assert maple_code(2 * EulerGamma) == "2*gamma" + + +def test_boolean(): + assert maple_code(x & y) == "x and y" + assert maple_code(x | y) == "x or y" + assert maple_code(~x) == "not x" + assert maple_code(x & y & z) == "x and y and z" + assert maple_code(x | y | z) == "x or y or z" + assert maple_code((x & y) | z) == "z or x and y" + assert maple_code((x | y) & z) == "z and (x or y)" + + +def test_Matrices(): + assert maple_code(Matrix(1, 1, [10])) == \ + 'Matrix([[10]], storage = rectangular)' + + A = Matrix([[1, sin(x / 2), abs(x)], + [0, 1, pi], + [0, exp(1), ceiling(x)]]) + expected = \ + 'Matrix(' \ + '[[1, sin((1/2)*x), abs(x)],' \ + ' [0, 1, Pi],' \ + ' [0, exp(1), ceil(x)]], ' \ + 'storage = rectangular)' + assert maple_code(A) == expected + + # row and columns + assert maple_code(A[:, 0]) == \ + 'Matrix([[1], [0], [0]], storage = rectangular)' + assert maple_code(A[0, :]) == \ + 'Matrix([[1, sin((1/2)*x), abs(x)]], storage = rectangular)' + assert maple_code(Matrix([[x, x - y, -y]])) == \ + 'Matrix([[x, x - y, -y]], storage = rectangular)' + + # empty matrices + assert maple_code(Matrix(0, 0, [])) == \ + 'Matrix([], storage = rectangular)' + assert maple_code(Matrix(0, 3, [])) == \ + 'Matrix([], storage = rectangular)' + +def test_SparseMatrices(): + assert maple_code(SparseMatrix(Identity(2))) == 'Matrix([[1, 0], [0, 1]], storage = sparse)' + + +def test_vector_entries_hadamard(): + # For a row or column, user might to use the other dimension + A = Matrix([[1, sin(2 / x), 3 * pi / x / 5]]) + assert maple_code(A) == \ + 'Matrix([[1, sin(2/x), (3/5)*Pi/x]], storage = rectangular)' + assert maple_code(A.T) == \ + 'Matrix([[1], [sin(2/x)], [(3/5)*Pi/x]], storage = rectangular)' + + +def test_Matrices_entries_not_hadamard(): + A = Matrix([[1, sin(2 / x), 3 * pi / x / 5], [1, 2, x * y]]) + expected = \ + 'Matrix([[1, sin(2/x), (3/5)*Pi/x], [1, 2, x*y]], ' \ + 'storage = rectangular)' + assert maple_code(A) == expected + + +def test_MatrixSymbol(): + n = Symbol('n', integer=True) + A = MatrixSymbol('A', n, n) + B = MatrixSymbol('B', n, n) + assert maple_code(A * B) == "A.B" + assert maple_code(B * A) == "B.A" + assert maple_code(2 * A * B) == "2*A.B" + assert maple_code(B * 2 * A) == "2*B.A" + + assert maple_code( + A * (B + 3 * Identity(n))) == "A.(3*Matrix(n, shape = identity) + B)" + + assert maple_code(A ** (x ** 2)) == "MatrixPower(A, x^2)" + assert maple_code(A ** 3) == "MatrixPower(A, 3)" + assert maple_code(A ** (S.Half)) == "MatrixPower(A, 1/2)" + + +def test_special_matrices(): + assert maple_code(6 * Identity(3)) == "6*Matrix([[1, 0, 0], [0, 1, 0], [0, 0, 1]], storage = sparse)" + assert maple_code(Identity(x)) == 'Matrix(x, shape = identity)' + + +def test_containers(): + assert maple_code([1, 2, 3, [4, 5, [6, 7]], 8, [9, 10], 11]) == \ + "[1, 2, 3, [4, 5, [6, 7]], 8, [9, 10], 11]" + + assert maple_code((1, 2, (3, 4))) == "[1, 2, [3, 4]]" + assert maple_code([1]) == "[1]" + assert maple_code((1,)) == "[1]" + assert maple_code(Tuple(*[1, 2, 3])) == "[1, 2, 3]" + assert maple_code((1, x * y, (3, x ** 2))) == "[1, x*y, [3, x^2]]" + # scalar, matrix, empty matrix and empty list + + assert maple_code((1, eye(3), Matrix(0, 0, []), [])) == \ + "[1, Matrix([[1, 0, 0], [0, 1, 0], [0, 0, 1]], storage = rectangular), Matrix([], storage = rectangular), []]" + + +def test_maple_noninline(): + source = maple_code((x + y)/Catalan, assign_to='me', inline=False) + expected = "me := (x + y)/Catalan" + + assert source == expected + + +def test_maple_matrix_assign_to(): + A = Matrix([[1, 2, 3]]) + assert maple_code(A, assign_to='a') == "a := Matrix([[1, 2, 3]], storage = rectangular)" + A = Matrix([[1, 2], [3, 4]]) + assert maple_code(A, assign_to='A') == "A := Matrix([[1, 2], [3, 4]], storage = rectangular)" + + +def test_maple_matrix_assign_to_more(): + # assigning to Symbol or MatrixSymbol requires lhs/rhs match + A = Matrix([[1, 2, 3]]) + B = MatrixSymbol('B', 1, 3) + C = MatrixSymbol('C', 2, 3) + assert maple_code(A, assign_to=B) == "B := Matrix([[1, 2, 3]], storage = rectangular)" + raises(ValueError, lambda: maple_code(A, assign_to=x)) + raises(ValueError, lambda: maple_code(A, assign_to=C)) + + +def test_maple_matrix_1x1(): + A = Matrix([[3]]) + assert maple_code(A, assign_to='B') == "B := Matrix([[3]], storage = rectangular)" + + +def test_maple_matrix_elements(): + A = Matrix([[x, 2, x * y]]) + + assert maple_code(A[0, 0] ** 2 + A[0, 1] + A[0, 2]) == "x^2 + x*y + 2" + AA = MatrixSymbol('AA', 1, 3) + assert maple_code(AA) == "AA" + + assert maple_code(AA[0, 0] ** 2 + sin(AA[0, 1]) + AA[0, 2]) == \ + "sin(AA[1, 2]) + AA[1, 1]^2 + AA[1, 3]" + assert maple_code(sum(AA)) == "AA[1, 1] + AA[1, 2] + AA[1, 3]" + + +def test_maple_boolean(): + assert maple_code(True) == "true" + assert maple_code(S.true) == "true" + assert maple_code(False) == "false" + assert maple_code(S.false) == "false" + + +def test_sparse(): + M = SparseMatrix(5, 6, {}) + M[2, 2] = 10 + M[1, 2] = 20 + M[1, 3] = 22 + M[0, 3] = 30 + M[3, 0] = x * y + assert maple_code(M) == \ + 'Matrix([[0, 0, 0, 30, 0, 0],' \ + ' [0, 0, 20, 22, 0, 0],' \ + ' [0, 0, 10, 0, 0, 0],' \ + ' [x*y, 0, 0, 0, 0, 0],' \ + ' [0, 0, 0, 0, 0, 0]], ' \ + 'storage = sparse)' + +# Not an important point. +def test_maple_not_supported(): + with raises(NotImplementedError): + maple_code(S.ComplexInfinity) + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + + assert (maple_code(A[0, 0]) == "A[1, 1]") + assert (maple_code(3 * A[0, 0]) == "3*A[1, 1]") + + F = A-B + + assert (maple_code(F[0,0]) == "A[1, 1] - B[1, 1]") + + +def test_hadamard(): + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 3, 3) + v = MatrixSymbol('v', 3, 1) + h = MatrixSymbol('h', 1, 3) + C = HadamardProduct(A, B) + assert maple_code(C) == "A*B" + + assert maple_code(C * v) == "(A*B).v" + # HadamardProduct is higher than dot product. + + assert maple_code(h * C * v) == "h.(A*B).v" + + assert maple_code(C * A) == "(A*B).A" + # mixing Hadamard and scalar strange b/c we vectorize scalars + + assert maple_code(C * x * y) == "x*y*(A*B)" + + +def test_maple_piecewise(): + expr = Piecewise((x, x < 1), (x ** 2, True)) + + assert maple_code(expr) == "piecewise(x < 1, x, x^2)" + assert maple_code(expr, assign_to="r") == ( + "r := piecewise(x < 1, x, x^2)") + + expr = Piecewise((x ** 2, x < 1), (x ** 3, x < 2), (x ** 4, x < 3), (x ** 5, True)) + expected = "piecewise(x < 1, x^2, x < 2, x^3, x < 3, x^4, x^5)" + assert maple_code(expr) == expected + assert maple_code(expr, assign_to="r") == "r := " + expected + + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x ** 2, x > 1), (sin(x), x > 0)) + raises(ValueError, lambda: maple_code(expr)) + + +def test_maple_piecewise_times_const(): + pw = Piecewise((x, x < 1), (x ** 2, True)) + + assert maple_code(2 * pw) == "2*piecewise(x < 1, x, x^2)" + assert maple_code(pw / x) == "piecewise(x < 1, x, x^2)/x" + assert maple_code(pw / (x * y)) == "piecewise(x < 1, x, x^2)/(x*y)" + assert maple_code(pw / 3) == "(1/3)*piecewise(x < 1, x, x^2)" + + +def test_maple_derivatives(): + f = Function('f') + assert maple_code(f(x).diff(x)) == 'diff(f(x), x)' + assert maple_code(f(x).diff(x, 2)) == 'diff(f(x), x$2)' + + +def test_automatic_rewrites(): + assert maple_code(lucas(x)) == '(2^(-x)*((1 - sqrt(5))^x + (1 + sqrt(5))^x))' + assert maple_code(sinc(x)) == '(piecewise(x <> 0, sin(x)/x, 1))' + + +def test_specfun(): + assert maple_code('asin(x)') == 'arcsin(x)' + assert maple_code(besseli(x, y)) == 'BesselI(x, y)' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_mathematica.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_mathematica.py new file mode 100644 index 0000000000000000000000000000000000000000..aaf6b537677442ae59a4f1bbd2b5774d6646f4e2 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_mathematica.py @@ -0,0 +1,287 @@ +from sympy.core import (S, pi, oo, symbols, Function, Rational, Integer, Tuple, + Derivative, Eq, Ne, Le, Lt, Gt, Ge) +from sympy.integrals import Integral +from sympy.concrete import Sum +from sympy.functions import (exp, sin, cos, fresnelc, fresnels, conjugate, Max, + Min, gamma, polygamma, loggamma, erf, erfi, erfc, + erf2, expint, erfinv, erfcinv, Ei, Si, Ci, li, + Shi, Chi, uppergamma, beta, subfactorial, erf2inv, + factorial, factorial2, catalan, RisingFactorial, + FallingFactorial, harmonic, atan2, sec, acsc, + hermite, laguerre, assoc_laguerre, jacobi, + gegenbauer, chebyshevt, chebyshevu, legendre, + assoc_legendre, Li, LambertW) + +from sympy.printing.mathematica import mathematica_code as mcode + +x, y, z, w = symbols('x,y,z,w') +f = Function('f') + + +def test_Integer(): + assert mcode(Integer(67)) == "67" + assert mcode(Integer(-1)) == "-1" + + +def test_Rational(): + assert mcode(Rational(3, 7)) == "3/7" + assert mcode(Rational(18, 9)) == "2" + assert mcode(Rational(3, -7)) == "-3/7" + assert mcode(Rational(-3, -7)) == "3/7" + assert mcode(x + Rational(3, 7)) == "x + 3/7" + assert mcode(Rational(3, 7)*x) == "(3/7)*x" + + +def test_Relational(): + assert mcode(Eq(x, y)) == "x == y" + assert mcode(Ne(x, y)) == "x != y" + assert mcode(Le(x, y)) == "x <= y" + assert mcode(Lt(x, y)) == "x < y" + assert mcode(Gt(x, y)) == "x > y" + assert mcode(Ge(x, y)) == "x >= y" + + +def test_Function(): + assert mcode(f(x, y, z)) == "f[x, y, z]" + assert mcode(sin(x) ** cos(x)) == "Sin[x]^Cos[x]" + assert mcode(sec(x) * acsc(x)) == "ArcCsc[x]*Sec[x]" + assert mcode(atan2(y, x)) == "ArcTan[x, y]" + assert mcode(conjugate(x)) == "Conjugate[x]" + assert mcode(Max(x, y, z)*Min(y, z)) == "Max[x, y, z]*Min[y, z]" + assert mcode(fresnelc(x)) == "FresnelC[x]" + assert mcode(fresnels(x)) == "FresnelS[x]" + assert mcode(gamma(x)) == "Gamma[x]" + assert mcode(uppergamma(x, y)) == "Gamma[x, y]" + assert mcode(polygamma(x, y)) == "PolyGamma[x, y]" + assert mcode(loggamma(x)) == "LogGamma[x]" + assert mcode(erf(x)) == "Erf[x]" + assert mcode(erfc(x)) == "Erfc[x]" + assert mcode(erfi(x)) == "Erfi[x]" + assert mcode(erf2(x, y)) == "Erf[x, y]" + assert mcode(expint(x, y)) == "ExpIntegralE[x, y]" + assert mcode(erfcinv(x)) == "InverseErfc[x]" + assert mcode(erfinv(x)) == "InverseErf[x]" + assert mcode(erf2inv(x, y)) == "InverseErf[x, y]" + assert mcode(Ei(x)) == "ExpIntegralEi[x]" + assert mcode(Ci(x)) == "CosIntegral[x]" + assert mcode(li(x)) == "LogIntegral[x]" + assert mcode(Si(x)) == "SinIntegral[x]" + assert mcode(Shi(x)) == "SinhIntegral[x]" + assert mcode(Chi(x)) == "CoshIntegral[x]" + assert mcode(beta(x, y)) == "Beta[x, y]" + assert mcode(factorial(x)) == "Factorial[x]" + assert mcode(factorial2(x)) == "Factorial2[x]" + assert mcode(subfactorial(x)) == "Subfactorial[x]" + assert mcode(FallingFactorial(x, y)) == "FactorialPower[x, y]" + assert mcode(RisingFactorial(x, y)) == "Pochhammer[x, y]" + assert mcode(catalan(x)) == "CatalanNumber[x]" + assert mcode(harmonic(x)) == "HarmonicNumber[x]" + assert mcode(harmonic(x, y)) == "HarmonicNumber[x, y]" + assert mcode(Li(x)) == "LogIntegral[x] - LogIntegral[2]" + assert mcode(LambertW(x)) == "ProductLog[x]" + assert mcode(LambertW(x, -1)) == "ProductLog[-1, x]" + assert mcode(LambertW(x, y)) == "ProductLog[y, x]" + + +def test_special_polynomials(): + assert mcode(hermite(x, y)) == "HermiteH[x, y]" + assert mcode(laguerre(x, y)) == "LaguerreL[x, y]" + assert mcode(assoc_laguerre(x, y, z)) == "LaguerreL[x, y, z]" + assert mcode(jacobi(x, y, z, w)) == "JacobiP[x, y, z, w]" + assert mcode(gegenbauer(x, y, z)) == "GegenbauerC[x, y, z]" + assert mcode(chebyshevt(x, y)) == "ChebyshevT[x, y]" + assert mcode(chebyshevu(x, y)) == "ChebyshevU[x, y]" + assert mcode(legendre(x, y)) == "LegendreP[x, y]" + assert mcode(assoc_legendre(x, y, z)) == "LegendreP[x, y, z]" + + +def test_Pow(): + assert mcode(x**3) == "x^3" + assert mcode(x**(y**3)) == "x^(y^3)" + assert mcode(1/(f(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "(3.5*f[x])^(-x + y^x)/(x^2 + y)" + assert mcode(x**-1.0) == 'x^(-1.0)' + assert mcode(x**Rational(2, 3)) == 'x^(2/3)' + + +def test_Mul(): + A, B, C, D = symbols('A B C D', commutative=False) + assert mcode(x*y*z) == "x*y*z" + assert mcode(x*y*A) == "x*y*A" + assert mcode(x*y*A*B) == "x*y*A**B" + assert mcode(x*y*A*B*C) == "x*y*A**B**C" + assert mcode(x*A*B*(C + D)*A*y) == "x*y*A**B**(C + D)**A" + + +def test_constants(): + assert mcode(S.Zero) == "0" + assert mcode(S.One) == "1" + assert mcode(S.NegativeOne) == "-1" + assert mcode(S.Half) == "1/2" + assert mcode(S.ImaginaryUnit) == "I" + + assert mcode(oo) == "Infinity" + assert mcode(S.NegativeInfinity) == "-Infinity" + assert mcode(S.ComplexInfinity) == "ComplexInfinity" + assert mcode(S.NaN) == "Indeterminate" + + assert mcode(S.Exp1) == "E" + assert mcode(pi) == "Pi" + assert mcode(S.GoldenRatio) == "GoldenRatio" + assert mcode(S.TribonacciConstant) == \ + "(1/3 + (1/3)*(19 - 3*33^(1/2))^(1/3) + " \ + "(1/3)*(3*33^(1/2) + 19)^(1/3))" + assert mcode(2*S.TribonacciConstant) == \ + "2*(1/3 + (1/3)*(19 - 3*33^(1/2))^(1/3) + " \ + "(1/3)*(3*33^(1/2) + 19)^(1/3))" + assert mcode(S.EulerGamma) == "EulerGamma" + assert mcode(S.Catalan) == "Catalan" + + +def test_containers(): + assert mcode([1, 2, 3, [4, 5, [6, 7]], 8, [9, 10], 11]) == \ + "{1, 2, 3, {4, 5, {6, 7}}, 8, {9, 10}, 11}" + assert mcode((1, 2, (3, 4))) == "{1, 2, {3, 4}}" + assert mcode([1]) == "{1}" + assert mcode((1,)) == "{1}" + assert mcode(Tuple(*[1, 2, 3])) == "{1, 2, 3}" + + +def test_matrices(): + from sympy.matrices import MutableDenseMatrix, MutableSparseMatrix, \ + ImmutableDenseMatrix, ImmutableSparseMatrix + A = MutableDenseMatrix( + [[1, -1, 0, 0], + [0, 1, -1, 0], + [0, 0, 1, -1], + [0, 0, 0, 1]] + ) + B = MutableSparseMatrix(A) + C = ImmutableDenseMatrix(A) + D = ImmutableSparseMatrix(A) + + assert mcode(C) == mcode(A) == \ + "{{1, -1, 0, 0}, " \ + "{0, 1, -1, 0}, " \ + "{0, 0, 1, -1}, " \ + "{0, 0, 0, 1}}" + + assert mcode(D) == mcode(B) == \ + "SparseArray[{" \ + "{1, 1} -> 1, {1, 2} -> -1, {2, 2} -> 1, {2, 3} -> -1, " \ + "{3, 3} -> 1, {3, 4} -> -1, {4, 4} -> 1" \ + "}, {4, 4}]" + + # Trivial cases of matrices + assert mcode(MutableDenseMatrix(0, 0, [])) == '{}' + assert mcode(MutableSparseMatrix(0, 0, [])) == 'SparseArray[{}, {0, 0}]' + assert mcode(MutableDenseMatrix(0, 3, [])) == '{}' + assert mcode(MutableSparseMatrix(0, 3, [])) == 'SparseArray[{}, {0, 3}]' + assert mcode(MutableDenseMatrix(3, 0, [])) == '{{}, {}, {}}' + assert mcode(MutableSparseMatrix(3, 0, [])) == 'SparseArray[{}, {3, 0}]' + +def test_NDArray(): + from sympy.tensor.array import ( + MutableDenseNDimArray, ImmutableDenseNDimArray, + MutableSparseNDimArray, ImmutableSparseNDimArray) + + example = MutableDenseNDimArray( + [[[1, 2, 3, 4], + [5, 6, 7, 8], + [9, 10, 11, 12]], + [[13, 14, 15, 16], + [17, 18, 19, 20], + [21, 22, 23, 24]]] + ) + + assert mcode(example) == \ + "{{{1, 2, 3, 4}, {5, 6, 7, 8}, {9, 10, 11, 12}}, " \ + "{{13, 14, 15, 16}, {17, 18, 19, 20}, {21, 22, 23, 24}}}" + + example = ImmutableDenseNDimArray(example) + + assert mcode(example) == \ + "{{{1, 2, 3, 4}, {5, 6, 7, 8}, {9, 10, 11, 12}}, " \ + "{{13, 14, 15, 16}, {17, 18, 19, 20}, {21, 22, 23, 24}}}" + + example = MutableSparseNDimArray(example) + + assert mcode(example) == \ + "SparseArray[{" \ + "{1, 1, 1} -> 1, {1, 1, 2} -> 2, {1, 1, 3} -> 3, " \ + "{1, 1, 4} -> 4, {1, 2, 1} -> 5, {1, 2, 2} -> 6, " \ + "{1, 2, 3} -> 7, {1, 2, 4} -> 8, {1, 3, 1} -> 9, " \ + "{1, 3, 2} -> 10, {1, 3, 3} -> 11, {1, 3, 4} -> 12, " \ + "{2, 1, 1} -> 13, {2, 1, 2} -> 14, {2, 1, 3} -> 15, " \ + "{2, 1, 4} -> 16, {2, 2, 1} -> 17, {2, 2, 2} -> 18, " \ + "{2, 2, 3} -> 19, {2, 2, 4} -> 20, {2, 3, 1} -> 21, " \ + "{2, 3, 2} -> 22, {2, 3, 3} -> 23, {2, 3, 4} -> 24" \ + "}, {2, 3, 4}]" + + example = ImmutableSparseNDimArray(example) + + assert mcode(example) == \ + "SparseArray[{" \ + "{1, 1, 1} -> 1, {1, 1, 2} -> 2, {1, 1, 3} -> 3, " \ + "{1, 1, 4} -> 4, {1, 2, 1} -> 5, {1, 2, 2} -> 6, " \ + "{1, 2, 3} -> 7, {1, 2, 4} -> 8, {1, 3, 1} -> 9, " \ + "{1, 3, 2} -> 10, {1, 3, 3} -> 11, {1, 3, 4} -> 12, " \ + "{2, 1, 1} -> 13, {2, 1, 2} -> 14, {2, 1, 3} -> 15, " \ + "{2, 1, 4} -> 16, {2, 2, 1} -> 17, {2, 2, 2} -> 18, " \ + "{2, 2, 3} -> 19, {2, 2, 4} -> 20, {2, 3, 1} -> 21, " \ + "{2, 3, 2} -> 22, {2, 3, 3} -> 23, {2, 3, 4} -> 24" \ + "}, {2, 3, 4}]" + + +def test_Integral(): + assert mcode(Integral(sin(sin(x)), x)) == "Hold[Integrate[Sin[Sin[x]], x]]" + assert mcode(Integral(exp(-x**2 - y**2), + (x, -oo, oo), + (y, -oo, oo))) == \ + "Hold[Integrate[Exp[-x^2 - y^2], {x, -Infinity, Infinity}, " \ + "{y, -Infinity, Infinity}]]" + + +def test_Derivative(): + assert mcode(Derivative(sin(x), x)) == "Hold[D[Sin[x], x]]" + assert mcode(Derivative(x, x)) == "Hold[D[x, x]]" + assert mcode(Derivative(sin(x)*y**4, x, 2)) == "Hold[D[y^4*Sin[x], {x, 2}]]" + assert mcode(Derivative(sin(x)*y**4, x, y, x)) == "Hold[D[y^4*Sin[x], x, y, x]]" + assert mcode(Derivative(sin(x)*y**4, x, y, 3, x)) == "Hold[D[y^4*Sin[x], x, {y, 3}, x]]" + + +def test_Sum(): + assert mcode(Sum(sin(x), (x, 0, 10))) == "Hold[Sum[Sin[x], {x, 0, 10}]]" + assert mcode(Sum(exp(-x**2 - y**2), + (x, -oo, oo), + (y, -oo, oo))) == \ + "Hold[Sum[Exp[-x^2 - y^2], {x, -Infinity, Infinity}, " \ + "{y, -Infinity, Infinity}]]" + + +def test_comment(): + from sympy.printing.mathematica import MCodePrinter + assert MCodePrinter()._get_comment("Hello World") == \ + "(* Hello World *)" + + +def test_userfuncs(): + # Dictionary mutation test + some_function = symbols("some_function", cls=Function) + my_user_functions = {"some_function": "SomeFunction"} + assert mcode( + some_function(z), + user_functions=my_user_functions) == \ + 'SomeFunction[z]' + assert mcode( + some_function(z), + user_functions=my_user_functions) == \ + 'SomeFunction[z]' + + # List argument test + my_user_functions = \ + {"some_function": [(lambda x: True, "SomeOtherFunction")]} + assert mcode( + some_function(z), + user_functions=my_user_functions) == \ + 'SomeOtherFunction[z]' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_mathml.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_mathml.py new file mode 100644 index 0000000000000000000000000000000000000000..4e7c2253c98fb1a4e99375774ad158df9b80b439 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_mathml.py @@ -0,0 +1,2048 @@ +from sympy.calculus.accumulationbounds import AccumBounds +from sympy.concrete.summations import Sum +from sympy.core.basic import Basic +from sympy.core.containers import Tuple +from sympy.core.function import Derivative, Lambda, diff, Function +from sympy.core.numbers import (zoo, Float, Integer, I, oo, pi, E, + Rational) +from sympy.core.relational import Lt, Ge, Ne, Eq +from sympy.core.singleton import S +from sympy.core.symbol import symbols, Symbol +from sympy.core.sympify import sympify +from sympy.functions.combinatorial.factorials import (factorial2, + binomial, factorial) +from sympy.functions.combinatorial.numbers import (lucas, bell, + catalan, euler, tribonacci, fibonacci, bernoulli, primenu, primeomega, + totient, reduced_totient) +from sympy.functions.elementary.complexes import re, im, conjugate, Abs +from sympy.functions.elementary.exponential import exp, LambertW, log +from sympy.functions.elementary.hyperbolic import (tanh, acoth, atanh, + coth, asinh, acsch, asech, acosh, csch, sinh, cosh, sech) +from sympy.functions.elementary.integers import ceiling, floor +from sympy.functions.elementary.miscellaneous import Max, Min +from sympy.functions.elementary.trigonometric import (csc, sec, tan, + atan, sin, asec, cot, cos, acot, acsc, asin, acos) +from sympy.functions.special.delta_functions import Heaviside +from sympy.functions.special.elliptic_integrals import (elliptic_pi, + elliptic_f, elliptic_k, elliptic_e) +from sympy.functions.special.error_functions import (fresnelc, + fresnels, Ei, expint) +from sympy.functions.special.gamma_functions import (gamma, uppergamma, + lowergamma) +from sympy.functions.special.mathieu_functions import (mathieusprime, + mathieus, mathieucprime, mathieuc) +from sympy.functions.special.polynomials import (jacobi, chebyshevu, + chebyshevt, hermite, assoc_legendre, gegenbauer, assoc_laguerre, + legendre, laguerre) +from sympy.functions.special.singularity_functions import SingularityFunction +from sympy.functions.special.zeta_functions import (polylog, stieltjes, + lerchphi, dirichlet_eta, zeta) +from sympy.integrals.integrals import Integral +from sympy.logic.boolalg import (Xor, Or, false, true, And, Equivalent, + Implies, Not) +from sympy.matrices.dense import Matrix +from sympy.matrices.expressions.determinant import Determinant +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.physics.quantum import (ComplexSpace, FockSpace, hbar, + HilbertSpace, Dagger) +from sympy.printing.mathml import (MathMLPresentationPrinter, + MathMLPrinter, MathMLContentPrinter, mathml) +from sympy.series.limits import Limit +from sympy.sets.contains import Contains +from sympy.sets.fancysets import Range +from sympy.sets.sets import (Interval, Union, SymmetricDifference, + Complement, FiniteSet, Intersection, ProductSet) +from sympy.stats.rv import RandomSymbol +from sympy.tensor.indexed import IndexedBase +from sympy.vector import (Divergence, CoordSys3D, Cross, Curl, Dot, + Laplacian, Gradient) +from sympy.testing.pytest import raises, XFAIL + +x, y, z, a, b, c, d, e, n = symbols('x:z a:e n') +mp = MathMLContentPrinter() +mpp = MathMLPresentationPrinter() + + +def test_mathml_printer(): + m = MathMLPrinter() + assert m.doprint(1+x) == mp.doprint(1+x) + + +def test_content_printmethod(): + assert mp.doprint(1 + x) == 'x1' + + +def test_content_mathml_core(): + mml_1 = mp._print(1 + x) + assert mml_1.nodeName == 'apply' + nodes = mml_1.childNodes + assert len(nodes) == 3 + assert nodes[0].nodeName == 'plus' + assert nodes[0].hasChildNodes() is False + assert nodes[0].nodeValue is None + assert nodes[1].nodeName in ['cn', 'ci'] + if nodes[1].nodeName == 'cn': + assert nodes[1].childNodes[0].nodeValue == '1' + assert nodes[2].childNodes[0].nodeValue == 'x' + else: + assert nodes[1].childNodes[0].nodeValue == 'x' + assert nodes[2].childNodes[0].nodeValue == '1' + + mml_2 = mp._print(x**2) + assert mml_2.nodeName == 'apply' + nodes = mml_2.childNodes + assert nodes[1].childNodes[0].nodeValue == 'x' + assert nodes[2].childNodes[0].nodeValue == '2' + + mml_3 = mp._print(2*x) + assert mml_3.nodeName == 'apply' + nodes = mml_3.childNodes + assert nodes[0].nodeName == 'times' + assert nodes[1].childNodes[0].nodeValue == '2' + assert nodes[2].childNodes[0].nodeValue == 'x' + + mml = mp._print(Float(1.0, 2)*x) + assert mml.nodeName == 'apply' + nodes = mml.childNodes + assert nodes[0].nodeName == 'times' + assert nodes[1].childNodes[0].nodeValue == '1.0' + assert nodes[2].childNodes[0].nodeValue == 'x' + + +def test_content_mathml_functions(): + mml_1 = mp._print(sin(x)) + assert mml_1.nodeName == 'apply' + assert mml_1.childNodes[0].nodeName == 'sin' + assert mml_1.childNodes[1].nodeName == 'ci' + + mml_2 = mp._print(diff(sin(x), x, evaluate=False)) + assert mml_2.nodeName == 'apply' + assert mml_2.childNodes[0].nodeName == 'diff' + assert mml_2.childNodes[1].nodeName == 'bvar' + assert mml_2.childNodes[1].childNodes[ + 0].nodeName == 'ci' # below bvar there's x/ci> + + mml_3 = mp._print(diff(cos(x*y), x, evaluate=False)) + assert mml_3.nodeName == 'apply' + assert mml_3.childNodes[0].nodeName == 'partialdiff' + assert mml_3.childNodes[1].nodeName == 'bvar' + assert mml_3.childNodes[1].childNodes[ + 0].nodeName == 'ci' # below bvar there's x/ci> + + mml_4 = mp._print(Lambda((x, y), x * y)) + assert mml_4.nodeName == 'lambda' + assert mml_4.childNodes[0].nodeName == 'bvar' + assert mml_4.childNodes[0].childNodes[ + 0].nodeName == 'ci' # below bvar there's x/ci> + assert mml_4.childNodes[1].nodeName == 'bvar' + assert mml_4.childNodes[1].childNodes[ + 0].nodeName == 'ci' # below bvar there's y/ci> + assert mml_4.childNodes[2].nodeName == 'apply' + + +def test_content_mathml_limits(): + # XXX No unevaluated limits + lim_fun = sin(x)/x + mml_1 = mp._print(Limit(lim_fun, x, 0)) + assert mml_1.childNodes[0].nodeName == 'limit' + assert mml_1.childNodes[1].nodeName == 'bvar' + assert mml_1.childNodes[2].nodeName == 'lowlimit' + assert mml_1.childNodes[3].toxml() == mp._print(lim_fun).toxml() + + +def test_content_mathml_integrals(): + integrand = x + mml_1 = mp._print(Integral(integrand, (x, 0, 1))) + assert mml_1.childNodes[0].nodeName == 'int' + assert mml_1.childNodes[1].nodeName == 'bvar' + assert mml_1.childNodes[2].nodeName == 'lowlimit' + assert mml_1.childNodes[3].nodeName == 'uplimit' + assert mml_1.childNodes[4].toxml() == mp._print(integrand).toxml() + + +def test_content_mathml_matrices(): + A = Matrix([1, 2, 3]) + B = Matrix([[0, 5, 4], [2, 3, 1], [9, 7, 9]]) + mll_1 = mp._print(A) + assert mll_1.childNodes[0].nodeName == 'matrixrow' + assert mll_1.childNodes[0].childNodes[0].nodeName == 'cn' + assert mll_1.childNodes[0].childNodes[0].childNodes[0].nodeValue == '1' + assert mll_1.childNodes[1].nodeName == 'matrixrow' + assert mll_1.childNodes[1].childNodes[0].nodeName == 'cn' + assert mll_1.childNodes[1].childNodes[0].childNodes[0].nodeValue == '2' + assert mll_1.childNodes[2].nodeName == 'matrixrow' + assert mll_1.childNodes[2].childNodes[0].nodeName == 'cn' + assert mll_1.childNodes[2].childNodes[0].childNodes[0].nodeValue == '3' + mll_2 = mp._print(B) + assert mll_2.childNodes[0].nodeName == 'matrixrow' + assert mll_2.childNodes[0].childNodes[0].nodeName == 'cn' + assert mll_2.childNodes[0].childNodes[0].childNodes[0].nodeValue == '0' + assert mll_2.childNodes[0].childNodes[1].nodeName == 'cn' + assert mll_2.childNodes[0].childNodes[1].childNodes[0].nodeValue == '5' + assert mll_2.childNodes[0].childNodes[2].nodeName == 'cn' + assert mll_2.childNodes[0].childNodes[2].childNodes[0].nodeValue == '4' + assert mll_2.childNodes[1].nodeName == 'matrixrow' + assert mll_2.childNodes[1].childNodes[0].nodeName == 'cn' + assert mll_2.childNodes[1].childNodes[0].childNodes[0].nodeValue == '2' + assert mll_2.childNodes[1].childNodes[1].nodeName == 'cn' + assert mll_2.childNodes[1].childNodes[1].childNodes[0].nodeValue == '3' + assert mll_2.childNodes[1].childNodes[2].nodeName == 'cn' + assert mll_2.childNodes[1].childNodes[2].childNodes[0].nodeValue == '1' + assert mll_2.childNodes[2].nodeName == 'matrixrow' + assert mll_2.childNodes[2].childNodes[0].nodeName == 'cn' + assert mll_2.childNodes[2].childNodes[0].childNodes[0].nodeValue == '9' + assert mll_2.childNodes[2].childNodes[1].nodeName == 'cn' + assert mll_2.childNodes[2].childNodes[1].childNodes[0].nodeValue == '7' + assert mll_2.childNodes[2].childNodes[2].nodeName == 'cn' + assert mll_2.childNodes[2].childNodes[2].childNodes[0].nodeValue == '9' + + +def test_content_mathml_sums(): + summand = x + mml_1 = mp._print(Sum(summand, (x, 1, 10))) + assert mml_1.childNodes[0].nodeName == 'sum' + assert mml_1.childNodes[1].nodeName == 'bvar' + assert mml_1.childNodes[2].nodeName == 'lowlimit' + assert mml_1.childNodes[3].nodeName == 'uplimit' + assert mml_1.childNodes[4].toxml() == mp._print(summand).toxml() + + +def test_content_mathml_tuples(): + mml_1 = mp._print([2]) + assert mml_1.nodeName == 'list' + assert mml_1.childNodes[0].nodeName == 'cn' + assert len(mml_1.childNodes) == 1 + + mml_2 = mp._print([2, Integer(1)]) + assert mml_2.nodeName == 'list' + assert mml_2.childNodes[0].nodeName == 'cn' + assert mml_2.childNodes[1].nodeName == 'cn' + assert len(mml_2.childNodes) == 2 + + +def test_content_mathml_add(): + mml = mp._print(x**5 - x**4 + x) + assert mml.childNodes[0].nodeName == 'plus' + assert mml.childNodes[1].childNodes[0].nodeName == 'minus' + assert mml.childNodes[1].childNodes[1].nodeName == 'apply' + + +def test_content_mathml_Rational(): + mml_1 = mp._print(Rational(1, 1)) + """should just return a number""" + assert mml_1.nodeName == 'cn' + + mml_2 = mp._print(Rational(2, 5)) + assert mml_2.childNodes[0].nodeName == 'divide' + + +def test_content_mathml_constants(): + mml = mp._print(I) + assert mml.nodeName == 'imaginaryi' + + mml = mp._print(E) + assert mml.nodeName == 'exponentiale' + + mml = mp._print(oo) + assert mml.nodeName == 'infinity' + + mml = mp._print(pi) + assert mml.nodeName == 'pi' + + assert mathml(hbar) == '' + assert mathml(S.TribonacciConstant) == '' + assert mathml(S.GoldenRatio) == 'φ' + mml = mathml(S.EulerGamma) + assert mml == '' + + mml = mathml(S.EmptySet) + assert mml == '' + + mml = mathml(S.true) + assert mml == '' + + mml = mathml(S.false) + assert mml == '' + + mml = mathml(S.NaN) + assert mml == '' + + +def test_content_mathml_trig(): + mml = mp._print(sin(x)) + assert mml.childNodes[0].nodeName == 'sin' + + mml = mp._print(cos(x)) + assert mml.childNodes[0].nodeName == 'cos' + + mml = mp._print(tan(x)) + assert mml.childNodes[0].nodeName == 'tan' + + mml = mp._print(cot(x)) + assert mml.childNodes[0].nodeName == 'cot' + + mml = mp._print(csc(x)) + assert mml.childNodes[0].nodeName == 'csc' + + mml = mp._print(sec(x)) + assert mml.childNodes[0].nodeName == 'sec' + + mml = mp._print(asin(x)) + assert mml.childNodes[0].nodeName == 'arcsin' + + mml = mp._print(acos(x)) + assert mml.childNodes[0].nodeName == 'arccos' + + mml = mp._print(atan(x)) + assert mml.childNodes[0].nodeName == 'arctan' + + mml = mp._print(acot(x)) + assert mml.childNodes[0].nodeName == 'arccot' + + mml = mp._print(acsc(x)) + assert mml.childNodes[0].nodeName == 'arccsc' + + mml = mp._print(asec(x)) + assert mml.childNodes[0].nodeName == 'arcsec' + + mml = mp._print(sinh(x)) + assert mml.childNodes[0].nodeName == 'sinh' + + mml = mp._print(cosh(x)) + assert mml.childNodes[0].nodeName == 'cosh' + + mml = mp._print(tanh(x)) + assert mml.childNodes[0].nodeName == 'tanh' + + mml = mp._print(coth(x)) + assert mml.childNodes[0].nodeName == 'coth' + + mml = mp._print(csch(x)) + assert mml.childNodes[0].nodeName == 'csch' + + mml = mp._print(sech(x)) + assert mml.childNodes[0].nodeName == 'sech' + + mml = mp._print(asinh(x)) + assert mml.childNodes[0].nodeName == 'arcsinh' + + mml = mp._print(atanh(x)) + assert mml.childNodes[0].nodeName == 'arctanh' + + mml = mp._print(acosh(x)) + assert mml.childNodes[0].nodeName == 'arccosh' + + mml = mp._print(acoth(x)) + assert mml.childNodes[0].nodeName == 'arccoth' + + mml = mp._print(acsch(x)) + assert mml.childNodes[0].nodeName == 'arccsch' + + mml = mp._print(asech(x)) + assert mml.childNodes[0].nodeName == 'arcsech' + + +def test_content_mathml_relational(): + mml_1 = mp._print(Eq(x, 1)) + assert mml_1.nodeName == 'apply' + assert mml_1.childNodes[0].nodeName == 'eq' + assert mml_1.childNodes[1].nodeName == 'ci' + assert mml_1.childNodes[1].childNodes[0].nodeValue == 'x' + assert mml_1.childNodes[2].nodeName == 'cn' + assert mml_1.childNodes[2].childNodes[0].nodeValue == '1' + + mml_2 = mp._print(Ne(1, x)) + assert mml_2.nodeName == 'apply' + assert mml_2.childNodes[0].nodeName == 'neq' + assert mml_2.childNodes[1].nodeName == 'cn' + assert mml_2.childNodes[1].childNodes[0].nodeValue == '1' + assert mml_2.childNodes[2].nodeName == 'ci' + assert mml_2.childNodes[2].childNodes[0].nodeValue == 'x' + + mml_3 = mp._print(Ge(1, x)) + assert mml_3.nodeName == 'apply' + assert mml_3.childNodes[0].nodeName == 'geq' + assert mml_3.childNodes[1].nodeName == 'cn' + assert mml_3.childNodes[1].childNodes[0].nodeValue == '1' + assert mml_3.childNodes[2].nodeName == 'ci' + assert mml_3.childNodes[2].childNodes[0].nodeValue == 'x' + + mml_4 = mp._print(Lt(1, x)) + assert mml_4.nodeName == 'apply' + assert mml_4.childNodes[0].nodeName == 'lt' + assert mml_4.childNodes[1].nodeName == 'cn' + assert mml_4.childNodes[1].childNodes[0].nodeValue == '1' + assert mml_4.childNodes[2].nodeName == 'ci' + assert mml_4.childNodes[2].childNodes[0].nodeValue == 'x' + + +def test_content_symbol(): + mml = mp._print(x) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeValue == 'x' + del mml + + mml = mp._print(Symbol("x^2")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msup' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '2' + del mml + + mml = mp._print(Symbol("x__2")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msup' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '2' + del mml + + mml = mp._print(Symbol("x_2")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msub' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '2' + del mml + + mml = mp._print(Symbol("x^3_2")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msubsup' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '2' + assert mml.childNodes[0].childNodes[2].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[2].childNodes[0].nodeValue == '3' + del mml + + mml = mp._print(Symbol("x__3_2")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msubsup' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '2' + assert mml.childNodes[0].childNodes[2].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[2].childNodes[0].nodeValue == '3' + del mml + + mml = mp._print(Symbol("x_2_a")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msub' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mrow' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].childNodes[ + 0].nodeValue == '2' + assert mml.childNodes[0].childNodes[1].childNodes[1].nodeName == 'mml:mo' + assert mml.childNodes[0].childNodes[1].childNodes[1].childNodes[ + 0].nodeValue == ' ' + assert mml.childNodes[0].childNodes[1].childNodes[2].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[2].childNodes[ + 0].nodeValue == 'a' + del mml + + mml = mp._print(Symbol("x^2^a")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msup' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mrow' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].childNodes[ + 0].nodeValue == '2' + assert mml.childNodes[0].childNodes[1].childNodes[1].nodeName == 'mml:mo' + assert mml.childNodes[0].childNodes[1].childNodes[1].childNodes[ + 0].nodeValue == ' ' + assert mml.childNodes[0].childNodes[1].childNodes[2].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[2].childNodes[ + 0].nodeValue == 'a' + del mml + + mml = mp._print(Symbol("x__2__a")) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeName == 'mml:msup' + assert mml.childNodes[0].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].nodeName == 'mml:mrow' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[0].childNodes[ + 0].nodeValue == '2' + assert mml.childNodes[0].childNodes[1].childNodes[1].nodeName == 'mml:mo' + assert mml.childNodes[0].childNodes[1].childNodes[1].childNodes[ + 0].nodeValue == ' ' + assert mml.childNodes[0].childNodes[1].childNodes[2].nodeName == 'mml:mi' + assert mml.childNodes[0].childNodes[1].childNodes[2].childNodes[ + 0].nodeValue == 'a' + del mml + + +def test_content_mathml_greek(): + mml = mp._print(Symbol('alpha')) + assert mml.nodeName == 'ci' + assert mml.childNodes[0].nodeValue == '\N{GREEK SMALL LETTER ALPHA}' + + assert mp.doprint(Symbol('alpha')) == 'α' + assert mp.doprint(Symbol('beta')) == 'β' + assert mp.doprint(Symbol('gamma')) == 'γ' + assert mp.doprint(Symbol('delta')) == 'δ' + assert mp.doprint(Symbol('epsilon')) == 'ε' + assert mp.doprint(Symbol('zeta')) == 'ζ' + assert mp.doprint(Symbol('eta')) == 'η' + assert mp.doprint(Symbol('theta')) == 'θ' + assert mp.doprint(Symbol('iota')) == 'ι' + assert mp.doprint(Symbol('kappa')) == 'κ' + assert mp.doprint(Symbol('lambda')) == 'λ' + assert mp.doprint(Symbol('mu')) == 'μ' + assert mp.doprint(Symbol('nu')) == 'ν' + assert mp.doprint(Symbol('xi')) == 'ξ' + assert mp.doprint(Symbol('omicron')) == 'ο' + assert mp.doprint(Symbol('pi')) == 'π' + assert mp.doprint(Symbol('rho')) == 'ρ' + assert mp.doprint(Symbol('varsigma')) == 'ς' + assert mp.doprint(Symbol('sigma')) == 'σ' + assert mp.doprint(Symbol('tau')) == 'τ' + assert mp.doprint(Symbol('upsilon')) == 'υ' + assert mp.doprint(Symbol('phi')) == 'φ' + assert mp.doprint(Symbol('chi')) == 'χ' + assert mp.doprint(Symbol('psi')) == 'ψ' + assert mp.doprint(Symbol('omega')) == 'ω' + + assert mp.doprint(Symbol('Alpha')) == 'Α' + assert mp.doprint(Symbol('Beta')) == 'Β' + assert mp.doprint(Symbol('Gamma')) == 'Γ' + assert mp.doprint(Symbol('Delta')) == 'Δ' + assert mp.doprint(Symbol('Epsilon')) == 'Ε' + assert mp.doprint(Symbol('Zeta')) == 'Ζ' + assert mp.doprint(Symbol('Eta')) == 'Η' + assert mp.doprint(Symbol('Theta')) == 'Θ' + assert mp.doprint(Symbol('Iota')) == 'Ι' + assert mp.doprint(Symbol('Kappa')) == 'Κ' + assert mp.doprint(Symbol('Lambda')) == 'Λ' + assert mp.doprint(Symbol('Mu')) == 'Μ' + assert mp.doprint(Symbol('Nu')) == 'Ν' + assert mp.doprint(Symbol('Xi')) == 'Ξ' + assert mp.doprint(Symbol('Omicron')) == 'Ο' + assert mp.doprint(Symbol('Pi')) == 'Π' + assert mp.doprint(Symbol('Rho')) == 'Ρ' + assert mp.doprint(Symbol('Sigma')) == 'Σ' + assert mp.doprint(Symbol('Tau')) == 'Τ' + assert mp.doprint(Symbol('Upsilon')) == 'Υ' + assert mp.doprint(Symbol('Phi')) == 'Φ' + assert mp.doprint(Symbol('Chi')) == 'Χ' + assert mp.doprint(Symbol('Psi')) == 'Ψ' + assert mp.doprint(Symbol('Omega')) == 'Ω' + + +def test_content_mathml_order(): + expr = x**3 + x**2*y + 3*x*y**3 + y**4 + + mp = MathMLContentPrinter({'order': 'lex'}) + mml = mp._print(expr) + + assert mml.childNodes[1].childNodes[0].nodeName == 'power' + assert mml.childNodes[1].childNodes[1].childNodes[0].data == 'x' + assert mml.childNodes[1].childNodes[2].childNodes[0].data == '3' + + assert mml.childNodes[4].childNodes[0].nodeName == 'power' + assert mml.childNodes[4].childNodes[1].childNodes[0].data == 'y' + assert mml.childNodes[4].childNodes[2].childNodes[0].data == '4' + + mp = MathMLContentPrinter({'order': 'rev-lex'}) + mml = mp._print(expr) + + assert mml.childNodes[1].childNodes[0].nodeName == 'power' + assert mml.childNodes[1].childNodes[1].childNodes[0].data == 'y' + assert mml.childNodes[1].childNodes[2].childNodes[0].data == '4' + + assert mml.childNodes[4].childNodes[0].nodeName == 'power' + assert mml.childNodes[4].childNodes[1].childNodes[0].data == 'x' + assert mml.childNodes[4].childNodes[2].childNodes[0].data == '3' + + +def test_content_settings(): + raises(TypeError, lambda: mathml(x, method="garbage")) + + +def test_content_mathml_logic(): + assert mathml(And(x, y)) == 'xy' + assert mathml(Or(x, y)) == 'xy' + assert mathml(Xor(x, y)) == 'xy' + assert mathml(Implies(x, y)) == 'xy' + assert mathml(Not(x)) == 'x' + + +def test_content_finite_sets(): + assert mathml(FiniteSet(a)) == 'a' + assert mathml(FiniteSet(a, b)) == 'ab' + assert mathml(FiniteSet(FiniteSet(a, b), c)) == \ + 'cab' + + A = FiniteSet(a) + B = FiniteSet(b) + C = FiniteSet(c) + D = FiniteSet(d) + + U1 = Union(A, B, evaluate=False) + U2 = Union(C, D, evaluate=False) + I1 = Intersection(A, B, evaluate=False) + I2 = Intersection(C, D, evaluate=False) + C1 = Complement(A, B, evaluate=False) + C2 = Complement(C, D, evaluate=False) + # XXX ProductSet does not support evaluate keyword + P1 = ProductSet(A, B) + P2 = ProductSet(C, D) + + assert mathml(U1) == \ + 'ab' + assert mathml(I1) == \ + 'ab' \ + '' + assert mathml(C1) == \ + 'ab' + assert mathml(P1) == \ + 'ab' \ + '' + + assert mathml(Intersection(A, U2, evaluate=False)) == \ + 'a' \ + 'cd' + assert mathml(Intersection(U1, U2, evaluate=False)) == \ + 'a' \ + 'bc' \ + 'd' + + # XXX Does the parenthesis appear correctly for these examples in mathjax? + assert mathml(Intersection(C1, C2, evaluate=False)) == \ + 'a' \ + 'bc' \ + 'd' + assert mathml(Intersection(P1, P2, evaluate=False)) == \ + 'a' \ + 'b' \ + 'cd' + + assert mathml(Union(A, I2, evaluate=False)) == \ + 'a' \ + 'cd' + assert mathml(Union(I1, I2, evaluate=False)) == \ + 'a' \ + 'bc' \ + 'd' + assert mathml(Union(C1, C2, evaluate=False)) == \ + 'a' \ + 'bc' \ + 'd' + assert mathml(Union(P1, P2, evaluate=False)) == \ + 'a' \ + 'b' \ + 'cd' + + assert mathml(Complement(A, C2, evaluate=False)) == \ + 'a' \ + 'cd' + assert mathml(Complement(U1, U2, evaluate=False)) == \ + 'a' \ + 'bc' \ + 'd' + assert mathml(Complement(I1, I2, evaluate=False)) == \ + 'a' \ + 'bc' \ + 'd' + assert mathml(Complement(P1, P2, evaluate=False)) == \ + 'a' \ + 'b' \ + 'cd' + + assert mathml(ProductSet(A, P2)) == \ + 'a' \ + 'c' \ + 'd' + assert mathml(ProductSet(U1, U2)) == \ + 'a' \ + 'bc' \ + 'd' + assert mathml(ProductSet(I1, I2)) == \ + 'a' \ + 'b' \ + 'cd' + assert mathml(ProductSet(C1, C2)) == \ + 'a' \ + 'b' \ + 'cd' + + +def test_presentation_printmethod(): + assert mpp.doprint(1 + x) == 'x+1' + assert mpp.doprint(x**2) == 'x2' + assert mpp.doprint(x**-1) == '1x' + assert mpp.doprint(x**-2) == \ + '1x2' + assert mpp.doprint(2*x) == \ + '2x' + + +def test_presentation_mathml_core(): + mml_1 = mpp._print(1 + x) + assert mml_1.nodeName == 'mrow' + nodes = mml_1.childNodes + assert len(nodes) == 3 + assert nodes[0].nodeName in ['mi', 'mn'] + assert nodes[1].nodeName == 'mo' + if nodes[0].nodeName == 'mn': + assert nodes[0].childNodes[0].nodeValue == '1' + assert nodes[2].childNodes[0].nodeValue == 'x' + else: + assert nodes[0].childNodes[0].nodeValue == 'x' + assert nodes[2].childNodes[0].nodeValue == '1' + + mml_2 = mpp._print(x**2) + assert mml_2.nodeName == 'msup' + nodes = mml_2.childNodes + assert nodes[0].childNodes[0].nodeValue == 'x' + assert nodes[1].childNodes[0].nodeValue == '2' + + mml_3 = mpp._print(2*x) + assert mml_3.nodeName == 'mrow' + nodes = mml_3.childNodes + assert nodes[0].childNodes[0].nodeValue == '2' + assert nodes[1].childNodes[0].nodeValue == '⁢' + assert nodes[2].childNodes[0].nodeValue == 'x' + + mml = mpp._print(Float(1.0, 2)*x) + assert mml.nodeName == 'mrow' + nodes = mml.childNodes + assert nodes[0].childNodes[0].nodeValue == '1.0' + assert nodes[1].childNodes[0].nodeValue == '⁢' + assert nodes[2].childNodes[0].nodeValue == 'x' + + +def test_presentation_mathml_functions(): + mml_1 = mpp._print(sin(x)) + assert mml_1.childNodes[0].childNodes[0 + ].nodeValue == 'sin' + assert mml_1.childNodes[1].childNodes[1 + ].childNodes[0].nodeValue == 'x' + + mml_2 = mpp._print(diff(sin(x), x, evaluate=False)) + assert mml_2.nodeName == 'mrow' + assert mml_2.childNodes[0].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == 'ⅆ' + assert mml_2.childNodes[1].childNodes[1 + ].nodeName == 'mrow' + assert mml_2.childNodes[0].childNodes[1 + ].childNodes[0].childNodes[0].nodeValue == 'ⅆ' + + mml_3 = mpp._print(diff(cos(x*y), x, evaluate=False)) + assert mml_3.childNodes[0].nodeName == 'mfrac' + assert mml_3.childNodes[0].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '∂' + assert mml_3.childNodes[1].childNodes[0 + ].childNodes[0].nodeValue == 'cos' + + +def test_print_derivative(): + f = Function('f') + d = Derivative(f(x, y, z), x, z, x, z, z, y) + assert mathml(d) == \ + 'yz2xzxxyz' + assert mathml(d, printer='presentation') == \ + '6y2zxzxf(x,y,z)' + + +def test_presentation_mathml_limits(): + lim_fun = sin(x)/x + mml_1 = mpp._print(Limit(lim_fun, x, 0)) + assert mml_1.childNodes[0].nodeName == 'munder' + assert mml_1.childNodes[0].childNodes[0 + ].childNodes[0].nodeValue == 'lim' + assert mml_1.childNodes[0].childNodes[1 + ].childNodes[0].childNodes[0 + ].nodeValue == 'x' + assert mml_1.childNodes[0].childNodes[1 + ].childNodes[1].childNodes[0 + ].nodeValue == '→' + assert mml_1.childNodes[0].childNodes[1 + ].childNodes[2].childNodes[0 + ].nodeValue == '0' + + +def test_presentation_mathml_integrals(): + assert mpp.doprint(Integral(x, (x, 0, 1))) == \ + '01'\ + 'xx' + assert mpp.doprint(Integral(log(x), x)) == \ + 'log(x' \ + ')x' + assert mpp.doprint(Integral(x*y, x, y)) == \ + 'x'\ + 'yyx' + z, w = symbols('z w') + assert mpp.doprint(Integral(x*y*z, x, y, z)) == \ + 'x'\ + 'yz'\ + 'zyx' + assert mpp.doprint(Integral(x*y*z*w, x, y, z, w)) == \ + ''\ + 'w'\ + 'xy'\ + 'zw'\ + 'zyx' + assert mpp.doprint(Integral(x, x, y, (z, 0, 1))) == \ + '01'\ + 'xz'\ + 'yx' + assert mpp.doprint(Integral(x, (x, 0))) == \ + '0x'\ + 'x' + + +def test_presentation_mathml_matrices(): + A = Matrix([1, 2, 3]) + B = Matrix([[0, 5, 4], [2, 3, 1], [9, 7, 9]]) + mll_1 = mpp._print(A) + assert mll_1.childNodes[1].nodeName == 'mtable' + assert mll_1.childNodes[1].childNodes[0].nodeName == 'mtr' + assert len(mll_1.childNodes[1].childNodes) == 3 + assert mll_1.childNodes[1].childNodes[0].childNodes[0].nodeName == 'mtd' + assert len(mll_1.childNodes[1].childNodes[0].childNodes) == 1 + assert mll_1.childNodes[1].childNodes[0].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '1' + assert mll_1.childNodes[1].childNodes[1].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '2' + assert mll_1.childNodes[1].childNodes[2].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '3' + mll_2 = mpp._print(B) + assert mll_2.childNodes[1].nodeName == 'mtable' + assert mll_2.childNodes[1].childNodes[0].nodeName == 'mtr' + assert len(mll_2.childNodes[1].childNodes) == 3 + assert mll_2.childNodes[1].childNodes[0].childNodes[0].nodeName == 'mtd' + assert len(mll_2.childNodes[1].childNodes[0].childNodes) == 3 + assert mll_2.childNodes[1].childNodes[0].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '0' + assert mll_2.childNodes[1].childNodes[0].childNodes[1 + ].childNodes[0].childNodes[0].nodeValue == '5' + assert mll_2.childNodes[1].childNodes[0].childNodes[2 + ].childNodes[0].childNodes[0].nodeValue == '4' + assert mll_2.childNodes[1].childNodes[1].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '2' + assert mll_2.childNodes[1].childNodes[1].childNodes[1 + ].childNodes[0].childNodes[0].nodeValue == '3' + assert mll_2.childNodes[1].childNodes[1].childNodes[2 + ].childNodes[0].childNodes[0].nodeValue == '1' + assert mll_2.childNodes[1].childNodes[2].childNodes[0 + ].childNodes[0].childNodes[0].nodeValue == '9' + assert mll_2.childNodes[1].childNodes[2].childNodes[1 + ].childNodes[0].childNodes[0].nodeValue == '7' + assert mll_2.childNodes[1].childNodes[2].childNodes[2 + ].childNodes[0].childNodes[0].nodeValue == '9' + + +def test_presentation_mathml_sums(): + mml_1 = mpp._print(Sum(x, (x, 1, 10))) + assert mml_1.childNodes[0].nodeName == 'munderover' + assert len(mml_1.childNodes[0].childNodes) == 3 + assert mml_1.childNodes[0].childNodes[0].childNodes[0 + ].nodeValue == '∑' + assert len(mml_1.childNodes[0].childNodes[1].childNodes) == 3 + assert mml_1.childNodes[0].childNodes[2].childNodes[0 + ].nodeValue == '10' + assert mml_1.childNodes[1].childNodes[0].nodeValue == 'x' + + assert mpp.doprint(Sum(x, (x, 1, 10))) == \ + 'x=110x' + assert mpp.doprint(Sum(x + y, (x, 1, 10))) == \ + 'x=110(x+y)' + + +def test_presentation_mathml_add(): + mml = mpp._print(x**5 - x**4 + x) + assert len(mml.childNodes) == 5 + assert mml.childNodes[0].childNodes[0].childNodes[0 + ].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].childNodes[0 + ].nodeValue == '5' + assert mml.childNodes[1].childNodes[0].nodeValue == '-' + assert mml.childNodes[2].childNodes[0].childNodes[0 + ].nodeValue == 'x' + assert mml.childNodes[2].childNodes[1].childNodes[0 + ].nodeValue == '4' + assert mml.childNodes[3].childNodes[0].nodeValue == '+' + assert mml.childNodes[4].childNodes[0].nodeValue == 'x' + + +def test_presentation_mathml_Rational(): + mml_1 = mpp._print(Rational(1, 1)) + assert mml_1.nodeName == 'mn' + + mml_2 = mpp._print(Rational(2, 5)) + assert mml_2.nodeName == 'mfrac' + assert mml_2.childNodes[0].childNodes[0].nodeValue == '2' + assert mml_2.childNodes[1].childNodes[0].nodeValue == '5' + + +def test_presentation_mathml_constants(): + mml = mpp._print(I) + assert mml.childNodes[0].nodeValue == 'ⅈ' + + mml = mpp._print(E) + assert mml.childNodes[0].nodeValue == 'ⅇ' + + mml = mpp._print(oo) + assert mml.childNodes[0].nodeValue == '∞' + + mml = mpp._print(pi) + assert mml.childNodes[0].nodeValue == 'π' + + assert mathml(hbar, printer='presentation') == '' + assert mathml(S.TribonacciConstant, printer='presentation' + ) == 'TribonacciConstant' + assert mathml(S.EulerGamma, printer='presentation' + ) == 'γ' + assert mathml(S.GoldenRatio, printer='presentation' + ) == 'Φ' + + assert mathml(zoo, printer='presentation') == \ + '~' + + assert mathml(S.NaN, printer='presentation') == 'NaN' + +def test_presentation_mathml_trig(): + mml = mpp._print(sin(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'sin' + + mml = mpp._print(cos(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'cos' + + mml = mpp._print(tan(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'tan' + + mml = mpp._print(asin(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'arcsin' + + mml = mpp._print(acos(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'arccos' + + mml = mpp._print(atan(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'arctan' + + mml = mpp._print(sinh(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'sinh' + + mml = mpp._print(cosh(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'cosh' + + mml = mpp._print(tanh(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'tanh' + + mml = mpp._print(asinh(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'arcsinh' + + mml = mpp._print(atanh(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'arctanh' + + mml = mpp._print(acosh(x)) + assert mml.childNodes[0].childNodes[0].nodeValue == 'arccosh' + + +def test_presentation_mathml_relational(): + mml_1 = mpp._print(Eq(x, 1)) + assert len(mml_1.childNodes) == 3 + assert mml_1.childNodes[0].nodeName == 'mi' + assert mml_1.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml_1.childNodes[1].nodeName == 'mo' + assert mml_1.childNodes[1].childNodes[0].nodeValue == '=' + assert mml_1.childNodes[2].nodeName == 'mn' + assert mml_1.childNodes[2].childNodes[0].nodeValue == '1' + + mml_2 = mpp._print(Ne(1, x)) + assert len(mml_2.childNodes) == 3 + assert mml_2.childNodes[0].nodeName == 'mn' + assert mml_2.childNodes[0].childNodes[0].nodeValue == '1' + assert mml_2.childNodes[1].nodeName == 'mo' + assert mml_2.childNodes[1].childNodes[0].nodeValue == '≠' + assert mml_2.childNodes[2].nodeName == 'mi' + assert mml_2.childNodes[2].childNodes[0].nodeValue == 'x' + + mml_3 = mpp._print(Ge(1, x)) + assert len(mml_3.childNodes) == 3 + assert mml_3.childNodes[0].nodeName == 'mn' + assert mml_3.childNodes[0].childNodes[0].nodeValue == '1' + assert mml_3.childNodes[1].nodeName == 'mo' + assert mml_3.childNodes[1].childNodes[0].nodeValue == '≥' + assert mml_3.childNodes[2].nodeName == 'mi' + assert mml_3.childNodes[2].childNodes[0].nodeValue == 'x' + + mml_4 = mpp._print(Lt(1, x)) + assert len(mml_4.childNodes) == 3 + assert mml_4.childNodes[0].nodeName == 'mn' + assert mml_4.childNodes[0].childNodes[0].nodeValue == '1' + assert mml_4.childNodes[1].nodeName == 'mo' + assert mml_4.childNodes[1].childNodes[0].nodeValue == '<' + assert mml_4.childNodes[2].nodeName == 'mi' + assert mml_4.childNodes[2].childNodes[0].nodeValue == 'x' + + +def test_presentation_symbol(): + mml = mpp._print(x) + assert mml.nodeName == 'mi' + assert mml.childNodes[0].nodeValue == 'x' + del mml + + mml = mpp._print(Symbol("x^2")) + assert mml.nodeName == 'msup' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].nodeValue == '2' + del mml + + mml = mpp._print(Symbol("x__2")) + assert mml.nodeName == 'msup' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].nodeValue == '2' + del mml + + mml = mpp._print(Symbol("x_2")) + assert mml.nodeName == 'msub' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].nodeValue == '2' + del mml + + mml = mpp._print(Symbol("x^3_2")) + assert mml.nodeName == 'msubsup' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].nodeValue == '2' + assert mml.childNodes[2].nodeName == 'mi' + assert mml.childNodes[2].childNodes[0].nodeValue == '3' + del mml + + mml = mpp._print(Symbol("x__3_2")) + assert mml.nodeName == 'msubsup' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].nodeValue == '2' + assert mml.childNodes[2].nodeName == 'mi' + assert mml.childNodes[2].childNodes[0].nodeValue == '3' + del mml + + mml = mpp._print(Symbol("x_2_a")) + assert mml.nodeName == 'msub' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mrow' + assert mml.childNodes[1].childNodes[0].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].childNodes[0].nodeValue == '2' + assert mml.childNodes[1].childNodes[1].nodeName == 'mo' + assert mml.childNodes[1].childNodes[1].childNodes[0].nodeValue == ' ' + assert mml.childNodes[1].childNodes[2].nodeName == 'mi' + assert mml.childNodes[1].childNodes[2].childNodes[0].nodeValue == 'a' + del mml + + mml = mpp._print(Symbol("x^2^a")) + assert mml.nodeName == 'msup' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mrow' + assert mml.childNodes[1].childNodes[0].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].childNodes[0].nodeValue == '2' + assert mml.childNodes[1].childNodes[1].nodeName == 'mo' + assert mml.childNodes[1].childNodes[1].childNodes[0].nodeValue == ' ' + assert mml.childNodes[1].childNodes[2].nodeName == 'mi' + assert mml.childNodes[1].childNodes[2].childNodes[0].nodeValue == 'a' + del mml + + mml = mpp._print(Symbol("x__2__a")) + assert mml.nodeName == 'msup' + assert mml.childNodes[0].nodeName == 'mi' + assert mml.childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[1].nodeName == 'mrow' + assert mml.childNodes[1].childNodes[0].nodeName == 'mi' + assert mml.childNodes[1].childNodes[0].childNodes[0].nodeValue == '2' + assert mml.childNodes[1].childNodes[1].nodeName == 'mo' + assert mml.childNodes[1].childNodes[1].childNodes[0].nodeValue == ' ' + assert mml.childNodes[1].childNodes[2].nodeName == 'mi' + assert mml.childNodes[1].childNodes[2].childNodes[0].nodeValue == 'a' + del mml + + +def test_presentation_mathml_greek(): + mml = mpp._print(Symbol('alpha')) + assert mml.nodeName == 'mi' + assert mml.childNodes[0].nodeValue == '\N{GREEK SMALL LETTER ALPHA}' + + assert mpp.doprint(Symbol('alpha')) == 'α' + assert mpp.doprint(Symbol('beta')) == 'β' + assert mpp.doprint(Symbol('gamma')) == 'γ' + assert mpp.doprint(Symbol('delta')) == 'δ' + assert mpp.doprint(Symbol('epsilon')) == 'ε' + assert mpp.doprint(Symbol('zeta')) == 'ζ' + assert mpp.doprint(Symbol('eta')) == 'η' + assert mpp.doprint(Symbol('theta')) == 'θ' + assert mpp.doprint(Symbol('iota')) == 'ι' + assert mpp.doprint(Symbol('kappa')) == 'κ' + assert mpp.doprint(Symbol('lambda')) == 'λ' + assert mpp.doprint(Symbol('mu')) == 'μ' + assert mpp.doprint(Symbol('nu')) == 'ν' + assert mpp.doprint(Symbol('xi')) == 'ξ' + assert mpp.doprint(Symbol('omicron')) == 'ο' + assert mpp.doprint(Symbol('pi')) == 'π' + assert mpp.doprint(Symbol('rho')) == 'ρ' + assert mpp.doprint(Symbol('varsigma')) == 'ς' + assert mpp.doprint(Symbol('sigma')) == 'σ' + assert mpp.doprint(Symbol('tau')) == 'τ' + assert mpp.doprint(Symbol('upsilon')) == 'υ' + assert mpp.doprint(Symbol('phi')) == 'φ' + assert mpp.doprint(Symbol('chi')) == 'χ' + assert mpp.doprint(Symbol('psi')) == 'ψ' + assert mpp.doprint(Symbol('omega')) == 'ω' + + assert mpp.doprint(Symbol('Alpha')) == 'Α' + assert mpp.doprint(Symbol('Beta')) == 'Β' + assert mpp.doprint(Symbol('Gamma')) == 'Γ' + assert mpp.doprint(Symbol('Delta')) == 'Δ' + assert mpp.doprint(Symbol('Epsilon')) == 'Ε' + assert mpp.doprint(Symbol('Zeta')) == 'Ζ' + assert mpp.doprint(Symbol('Eta')) == 'Η' + assert mpp.doprint(Symbol('Theta')) == 'Θ' + assert mpp.doprint(Symbol('Iota')) == 'Ι' + assert mpp.doprint(Symbol('Kappa')) == 'Κ' + assert mpp.doprint(Symbol('Lambda')) == 'Λ' + assert mpp.doprint(Symbol('Mu')) == 'Μ' + assert mpp.doprint(Symbol('Nu')) == 'Ν' + assert mpp.doprint(Symbol('Xi')) == 'Ξ' + assert mpp.doprint(Symbol('Omicron')) == 'Ο' + assert mpp.doprint(Symbol('Pi')) == 'Π' + assert mpp.doprint(Symbol('Rho')) == 'Ρ' + assert mpp.doprint(Symbol('Sigma')) == 'Σ' + assert mpp.doprint(Symbol('Tau')) == 'Τ' + assert mpp.doprint(Symbol('Upsilon')) == 'Υ' + assert mpp.doprint(Symbol('Phi')) == 'Φ' + assert mpp.doprint(Symbol('Chi')) == 'Χ' + assert mpp.doprint(Symbol('Psi')) == 'Ψ' + assert mpp.doprint(Symbol('Omega')) == 'Ω' + + +def test_presentation_mathml_order(): + expr = x**3 + x**2*y + 3*x*y**3 + y**4 + + mp = MathMLPresentationPrinter({'order': 'lex'}) + mml = mp._print(expr) + assert mml.childNodes[0].nodeName == 'msup' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '3' + + assert mml.childNodes[6].nodeName == 'msup' + assert mml.childNodes[6].childNodes[0].childNodes[0].nodeValue == 'y' + assert mml.childNodes[6].childNodes[1].childNodes[0].nodeValue == '4' + + mp = MathMLPresentationPrinter({'order': 'rev-lex'}) + mml = mp._print(expr) + + assert mml.childNodes[0].nodeName == 'msup' + assert mml.childNodes[0].childNodes[0].childNodes[0].nodeValue == 'y' + assert mml.childNodes[0].childNodes[1].childNodes[0].nodeValue == '4' + + assert mml.childNodes[6].nodeName == 'msup' + assert mml.childNodes[6].childNodes[0].childNodes[0].nodeValue == 'x' + assert mml.childNodes[6].childNodes[1].childNodes[0].nodeValue == '3' + + +def test_print_intervals(): + a = Symbol('a', real=True) + assert mpp.doprint(Interval(0, a)) == \ + '[0,a]' + assert mpp.doprint(Interval(0, a, False, False)) == \ + '[0,a]' + assert mpp.doprint(Interval(0, a, True, False)) == \ + '(0,a]' + assert mpp.doprint(Interval(0, a, False, True)) == \ + '[0,a)' + assert mpp.doprint(Interval(0, a, True, True)) == \ + '(0,a)' + + +def test_print_tuples(): + assert mpp.doprint(Tuple(0,)) == \ + '(0)' + assert mpp.doprint(Tuple(0, a)) == \ + '(0,a)' + assert mpp.doprint(Tuple(0, a, a)) == \ + '(0,a,a)' + assert mpp.doprint(Tuple(0, 1, 2, 3, 4)) == \ + '(0,1,2,3,4)' + assert mpp.doprint(Tuple(0, 1, Tuple(2, 3, 4))) == \ + '(0,1,(2,3'\ + ',4))' + + +def test_print_re_im(): + assert mpp.doprint(re(x)) == \ + '(x)' + assert mpp.doprint(im(x)) == \ + '(x)' + assert mpp.doprint(re(x + 1, evaluate=False)) == \ + '(x+1)' + assert mpp.doprint(im(x + 1, evaluate=False)) == \ + '(x+1)' + + +def test_print_Abs(): + assert mpp.doprint(Abs(x)) == \ + '|x|' + assert mpp.doprint(Abs(x + 1)) == \ + '|x+1|' + + +def test_print_Determinant(): + assert mpp.doprint(Determinant(Matrix([[1, 2], [3, 4]]))) == \ + '|[1234]|' + + +def test_presentation_settings(): + raises(TypeError, lambda: mathml(x, printer='presentation', + method="garbage")) + + +def test_print_domains(): + from sympy.sets import Integers, Naturals, Naturals0, Reals, Complexes + + assert mpp.doprint(Complexes) == '' + assert mpp.doprint(Integers) == '' + assert mpp.doprint(Naturals) == '' + assert mpp.doprint(Naturals0) == \ + '0' + assert mpp.doprint(Reals) == '' + + +def test_print_expression_with_minus(): + assert mpp.doprint(-x) == '-x' + assert mpp.doprint(-x/y) == \ + '-xy' + assert mpp.doprint(-Rational(1, 2)) == \ + '-12' + + +def test_print_AssocOp(): + from sympy.core.operations import AssocOp + + class TestAssocOp(AssocOp): + identity = 0 + + expr = TestAssocOp(1, 2) + assert mpp.doprint(expr) == \ + 'testassocop12' + + +def test_print_basic(): + expr = Basic(S(1), S(2)) + assert mpp.doprint(expr) == \ + 'basic(1,2)' + assert mp.doprint(expr) == '12' + + +def test_mat_delim_print(): + expr = Matrix([[1, 2], [3, 4]]) + assert mathml(expr, printer='presentation', mat_delim='[') == \ + '[1'\ + '234'\ + ']' + assert mathml(expr, printer='presentation', mat_delim='(') == \ + '(12'\ + '34)' + assert mathml(expr, printer='presentation', mat_delim='') == \ + '12'\ + '34' + + +def test_ln_notation_print(): + expr = log(x) + assert mathml(expr, printer='presentation') == \ + 'log(x)' + assert mathml(expr, printer='presentation', ln_notation=False) == \ + 'log(x)' + assert mathml(expr, printer='presentation', ln_notation=True) == \ + 'ln(x)' + + +def test_mul_symbol_print(): + expr = x * y + assert mathml(expr, printer='presentation') == \ + 'xy' + assert mathml(expr, printer='presentation', mul_symbol=None) == \ + 'xy' + assert mathml(expr, printer='presentation', mul_symbol='dot') == \ + 'x·y' + assert mathml(expr, printer='presentation', mul_symbol='ldot') == \ + 'xy' + assert mathml(expr, printer='presentation', mul_symbol='times') == \ + 'x×y' + + +def test_print_lerchphi(): + assert mpp.doprint(lerchphi(1, 2, 3)) == \ + 'Φ(1,2,3)' + + +def test_print_polylog(): + assert mp.doprint(polylog(x, y)) == \ + 'xy' + assert mpp.doprint(polylog(x, y)) == \ + 'Lix(y)' + + +def test_print_set_frozenset(): + f = frozenset({1, 5, 3}) + assert mpp.doprint(f) == \ + '{1,3,5}' + s = set({1, 2, 3}) + assert mpp.doprint(s) == \ + '{1,2,3}' + + +def test_print_FiniteSet(): + f1 = FiniteSet(x, 1, 3) + assert mpp.doprint(f1) == \ + '{1,3,x}' + + +def test_print_LambertW(): + assert mpp.doprint(LambertW(x)) == 'W(x)' + assert mpp.doprint(LambertW(x, y)) == 'W(x,y)' + + +def test_print_EmptySet(): + assert mpp.doprint(S.EmptySet) == '' + + +def test_print_UniversalSet(): + assert mpp.doprint(S.UniversalSet) == '𝕌' + + +def test_print_spaces(): + assert mpp.doprint(HilbertSpace()) == '' + assert mpp.doprint(ComplexSpace(2)) == '𝒞2' + assert mpp.doprint(FockSpace()) == '' + + +def test_print_constants(): + assert mpp.doprint(hbar) == '' + assert mpp.doprint(S.TribonacciConstant) == 'TribonacciConstant' + assert mpp.doprint(S.GoldenRatio) == 'Φ' + assert mpp.doprint(S.EulerGamma) == 'γ' + + +def test_print_Contains(): + assert mpp.doprint(Contains(x, S.Naturals)) == \ + 'x' + + +def test_print_Dagger(): + x = symbols('x', commutative=False) + assert mpp.doprint(Dagger(x)) == 'x' + + +def test_print_SetOp(): + f1 = FiniteSet(x, 1, 3) + f2 = FiniteSet(y, 2, 4) + + prntr = lambda x: mathml(x, printer='presentation') + + assert prntr(Union(f1, f2, evaluate=False)) == \ + '{1,3,x'\ + '}{2,'\ + '4,y}' + assert prntr(Intersection(f1, f2, evaluate=False)) == \ + '{1,3,x'\ + '}{2'\ + ',4,y}' + assert prntr(Complement(f1, f2, evaluate=False)) == \ + '{1,3,x'\ + '}{2'\ + ',4,y}' + assert prntr(SymmetricDifference(f1, f2, evaluate=False)) == \ + '{1,3,x'\ + '}{2'\ + ',4,y}' + + A = FiniteSet(a) + C = FiniteSet(c) + D = FiniteSet(d) + + U1 = Union(C, D, evaluate=False) + I1 = Intersection(C, D, evaluate=False) + C1 = Complement(C, D, evaluate=False) + D1 = SymmetricDifference(C, D, evaluate=False) + # XXX ProductSet does not support evaluate keyword + P1 = ProductSet(C, D) + + assert prntr(Union(A, I1, evaluate=False)) == \ + '{a}' \ + '({' \ + 'c}{' \ + 'd})' + assert prntr(Intersection(A, C1, evaluate=False)) == \ + '{a}' \ + '({' \ + 'c}{' \ + 'd})' + assert prntr(Complement(A, D1, evaluate=False)) == \ + '{a}' \ + '({' \ + 'c}{' \ + 'd})' + assert prntr(SymmetricDifference(A, P1, evaluate=False)) == \ + '{a}' \ + '({' \ + 'c}×{' \ + 'd})' + assert prntr(ProductSet(A, U1)) == \ + '{a}' \ + '×({' \ + 'c}{' \ + 'd})' + + +def test_print_logic(): + assert mpp.doprint(And(x, y)) == \ + 'xy' + assert mpp.doprint(Or(x, y)) == \ + 'xy' + assert mpp.doprint(Xor(x, y)) == \ + 'xy' + assert mpp.doprint(Implies(x, y)) == \ + 'xy' + assert mpp.doprint(Equivalent(x, y)) == \ + 'xy' + + assert mpp.doprint(And(Eq(x, y), x > 4)) == \ + 'x=y'\ + 'x>4' + assert mpp.doprint(And(Eq(x, 3), y < 3, x > y + 1)) == \ + 'x=3'\ + 'x>y+1'\ + 'y<3' + assert mpp.doprint(Or(Eq(x, y), x > 4)) == \ + 'x=y'\ + 'x>4' + assert mpp.doprint(And(Eq(x, 3), Or(y < 3, x > y + 1))) == \ + 'x=3'\ + '(x>'\ + 'y+1'\ + 'y<3)' + + assert mpp.doprint(Not(x)) == '¬x' + assert mpp.doprint(Not(And(x, y))) == \ + '¬(xy)' + + +def test_root_notation_print(): + assert mathml(x**(S.One/3), printer='presentation') == \ + 'x3' + assert mathml(x**(S.One/3), printer='presentation', root_notation=False) ==\ + 'x13' + assert mathml(x**(S.One/3), printer='content') == \ + '3x' + assert mathml(x**(S.One/3), printer='content', root_notation=False) == \ + 'x13' + assert mathml(x**(Rational(-1, 3)), printer='presentation') == \ + '1x3' + assert mathml(x**(Rational(-1, 3)), printer='presentation', root_notation=False) \ + == '1x13' + + +def test_fold_frac_powers_print(): + expr = x ** Rational(5, 2) + assert mathml(expr, printer='presentation') == \ + 'x52' + assert mathml(expr, printer='presentation', fold_frac_powers=True) == \ + 'x52' + assert mathml(expr, printer='presentation', fold_frac_powers=False) == \ + 'x52' + + +def test_fold_short_frac_print(): + expr = Rational(2, 5) + assert mathml(expr, printer='presentation') == \ + '25' + assert mathml(expr, printer='presentation', fold_short_frac=True) == \ + '25' + assert mathml(expr, printer='presentation', fold_short_frac=False) == \ + '25' + + +def test_print_factorials(): + assert mpp.doprint(factorial(x)) == 'x!' + assert mpp.doprint(factorial(x + 1)) == \ + '(x+1)!' + assert mpp.doprint(factorial2(x)) == 'x!!' + assert mpp.doprint(factorial2(x + 1)) == \ + '(x+1)!!' + assert mpp.doprint(binomial(x, y)) == \ + '(xy)' + assert mpp.doprint(binomial(4, x + y)) == \ + '(4x'\ + '+y)' + + +def test_print_floor(): + expr = floor(x) + assert mathml(expr, printer='presentation') == \ + 'x' + + +def test_print_ceiling(): + expr = ceiling(x) + assert mathml(expr, printer='presentation') == \ + 'x' + + +def test_print_Lambda(): + expr = Lambda(x, x+1) + assert mathml(expr, printer='presentation') == \ + '(xx+1)' + expr = Lambda((x, y), x + y) + assert mathml(expr, printer='presentation') == \ + '((x,y)x+y)' + + +def test_print_conjugate(): + assert mpp.doprint(conjugate(x)) == \ + 'x' + assert mpp.doprint(conjugate(x + 1)) == \ + 'x+1' + + +def test_print_AccumBounds(): + a = Symbol('a', real=True) + assert mpp.doprint(AccumBounds(0, 1)) == '0,1' + assert mpp.doprint(AccumBounds(0, a)) == '0,a' + assert mpp.doprint(AccumBounds(a + 1, a + 2)) == 'a+1,a+2' + + +def test_print_Float(): + assert mpp.doprint(Float(1e100)) == '1.0·10100' + assert mpp.doprint(Float(1e-100)) == '1.0·10-100' + assert mpp.doprint(Float(-1e100)) == '-1.0·10100' + assert mpp.doprint(Float(1.0*oo)) == '' + assert mpp.doprint(Float(-1.0*oo)) == '-' + + +def test_print_different_functions(): + assert mpp.doprint(gamma(x)) == 'Γ(x)' + assert mpp.doprint(lowergamma(x, y)) == 'γ(x,y)' + assert mpp.doprint(uppergamma(x, y)) == 'Γ(x,y)' + assert mpp.doprint(zeta(x)) == 'ζ(x)' + assert mpp.doprint(zeta(x, y)) == 'ζ(x,y)' + assert mpp.doprint(dirichlet_eta(x)) == 'η(x)' + assert mpp.doprint(elliptic_k(x)) == 'Κ(x)' + assert mpp.doprint(totient(x)) == 'ϕ(x)' + assert mpp.doprint(reduced_totient(x)) == 'λ(x)' + assert mpp.doprint(primenu(x)) == 'ν(x)' + assert mpp.doprint(primeomega(x)) == 'Ω(x)' + assert mpp.doprint(fresnels(x)) == 'S(x)' + assert mpp.doprint(fresnelc(x)) == 'C(x)' + assert mpp.doprint(Heaviside(x)) == 'Θ(x,12)' + + +def test_mathml_builtins(): + assert mpp.doprint(None) == 'None' + assert mpp.doprint(true) == 'True' + assert mpp.doprint(false) == 'False' + + +def test_mathml_Range(): + assert mpp.doprint(Range(1, 51)) == \ + '{1,2,,50}' + assert mpp.doprint(Range(1, 4)) == \ + '{1,2,3}' + assert mpp.doprint(Range(0, 3, 1)) == \ + '{0,1,2}' + assert mpp.doprint(Range(0, 30, 1)) == \ + '{0,1,,29}' + assert mpp.doprint(Range(30, 1, -1)) == \ + '{30,29,,2}' + assert mpp.doprint(Range(0, oo, 2)) == \ + '{0,2,}' + assert mpp.doprint(Range(oo, -2, -2)) == \ + '{,2,0}' + assert mpp.doprint(Range(-2, -oo, -1)) == \ + '{-2,-3,}' + + +def test_print_exp(): + assert mpp.doprint(exp(x)) == \ + 'x' + assert mpp.doprint(exp(1) + exp(2)) == \ + '+2' + + +def test_print_MinMax(): + assert mpp.doprint(Min(x, y)) == \ + 'min(x,y)' + assert mpp.doprint(Min(x, 2, x**3)) == \ + 'min(2,x,x3)' + assert mpp.doprint(Max(x, y)) == \ + 'max(x,y)' + assert mpp.doprint(Max(x, 2, x**3)) == \ + 'max(2,x,x3)' + + +def test_mathml_presentation_numbers(): + n = Symbol('n') + assert mathml(catalan(n), printer='presentation') == \ + 'Cn' + assert mathml(bernoulli(n), printer='presentation') == \ + 'Bn' + assert mathml(bell(n), printer='presentation') == \ + 'Bn' + assert mathml(euler(n), printer='presentation') == \ + 'En' + assert mathml(fibonacci(n), printer='presentation') == \ + 'Fn' + assert mathml(lucas(n), printer='presentation') == \ + 'Ln' + assert mathml(tribonacci(n), printer='presentation') == \ + 'Tn' + assert mathml(bernoulli(n, x), printer='presentation') == \ + mathml(bell(n, x), printer='presentation') == \ + 'Bn(x)' + assert mathml(euler(n, x), printer='presentation') == \ + 'En(x)' + assert mathml(fibonacci(n, x), printer='presentation') == \ + 'Fn(x)' + assert mathml(tribonacci(n, x), printer='presentation') == \ + 'Tn(x)' + + +def test_mathml_presentation_mathieu(): + assert mathml(mathieuc(x, y, z), printer='presentation') == \ + 'C(x,y,z)' + assert mathml(mathieus(x, y, z), printer='presentation') == \ + 'S(x,y,z)' + assert mathml(mathieucprime(x, y, z), printer='presentation') == \ + 'C′(x,y,z)' + assert mathml(mathieusprime(x, y, z), printer='presentation') == \ + 'S′(x,y,z)' + + +def test_mathml_presentation_stieltjes(): + assert mathml(stieltjes(n), printer='presentation') == \ + 'γn' + assert mathml(stieltjes(n, x), printer='presentation') == \ + 'γn(x)' + + +def test_print_matrix_symbol(): + A = MatrixSymbol('A', 1, 2) + assert mpp.doprint(A) == 'A' + assert mp.doprint(A) == 'A' + assert mathml(A, printer='presentation', mat_symbol_style="bold") == \ + 'A' + # No effect in content printer + assert mathml(A, mat_symbol_style="bold") == 'A' + + +def test_print_hadamard(): + from sympy.matrices.expressions import HadamardProduct + from sympy.matrices.expressions import Transpose + + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + + assert mathml(HadamardProduct(X, Y*Y), printer="presentation") == \ + '' \ + 'X' \ + '' \ + 'Y2' \ + '' + + assert mathml(HadamardProduct(X, Y)*Y, printer="presentation") == \ + '' \ + '(' \ + 'XY' \ + ')' \ + 'Y' \ + '' + + assert mathml(HadamardProduct(X, Y, Y), printer="presentation") == \ + '' \ + 'X' \ + 'Y' \ + 'Y' \ + '' + + assert mathml( + Transpose(HadamardProduct(X, Y)), printer="presentation") == \ + '' \ + '(' \ + 'XY' \ + ')' \ + 'T' \ + '' + + +def test_print_random_symbol(): + R = RandomSymbol(Symbol('R')) + assert mpp.doprint(R) == 'R' + assert mp.doprint(R) == 'R' + + +def test_print_IndexedBase(): + assert mathml(IndexedBase(a)[b], printer='presentation') == \ + 'ab' + assert mathml(IndexedBase(a)[b, c, d], printer='presentation') == \ + 'a(b,c,d)' + assert mathml(IndexedBase(a)[b]*IndexedBase(c)[d]*IndexedBase(e), + printer='presentation') == \ + 'ab⁢'\ + 'cde' + + +def test_print_Indexed(): + assert mathml(IndexedBase(a), printer='presentation') == 'a' + assert mathml(IndexedBase(a/b), printer='presentation') == \ + 'ab' + assert mathml(IndexedBase((a, b)), printer='presentation') == \ + '(a,b)' + +def test_print_MatrixElement(): + i, j = symbols('i j') + A = MatrixSymbol('A', i, j) + assert mathml(A[0,0],printer = 'presentation') == \ + 'A0,0' + assert mathml(A[i,j], printer = 'presentation') == \ + 'Ai,j' + assert mathml(A[i*j,0], printer = 'presentation') == \ + 'Aij,0' + + +def test_print_Vector(): + ACS = CoordSys3D('A') + assert mathml(Cross(ACS.i, ACS.j*ACS.x*3 + ACS.k), printer='presentation') == \ + 'i^'\ + 'A×('\ + '(3'\ + 'xA'\ + ')'\ + 'j^'\ + 'A+'\ + 'k^'\ + 'A)' + assert mathml(Cross(ACS.i, ACS.j), printer='presentation') == \ + 'i^'\ + 'A×'\ + 'j^'\ + 'A' + assert mathml(x*Cross(ACS.i, ACS.j), printer='presentation') == \ + 'x('\ + 'i^'\ + 'A×'\ + 'j^'\ + 'A)' + assert mathml(Cross(x*ACS.i, ACS.j), printer='presentation') == \ + '-j'\ + '^A'\ + '×((x)'\ + 'i'\ + '^A'\ + ')' + assert mathml(Curl(3*ACS.x*ACS.j), printer='presentation') == \ + '×(('\ + '3x'\ + 'A)'\ + 'j^'\ + 'A)' + assert mathml(Curl(3*x*ACS.x*ACS.j), printer='presentation') == \ + '×(('\ + '3x'\ + 'A'\ + 'x)'\ + 'j^'\ + 'A)' + assert mathml(x*Curl(3*ACS.x*ACS.j), printer='presentation') == \ + 'x('\ + '×((3'\ + 'x'\ + 'A)'\ + 'j'\ + '^A)'\ + ')' + assert mathml(Curl(3*x*ACS.x*ACS.j + ACS.i), printer='presentation') == \ + '×('\ + 'i^'\ + 'A+('\ + '3x'\ + 'A'\ + 'x)'\ + 'j^'\ + 'A)' + assert mathml(Divergence(3*ACS.x*ACS.j), printer='presentation') == \ + '·(('\ + '3x'\ + 'A)'\ + 'j'\ + '^A)' + assert mathml(x*Divergence(3*ACS.x*ACS.j), printer='presentation') == \ + 'x('\ + '·((3'\ + 'x'\ + 'A)'\ + 'j'\ + '^A'\ + '))' + assert mathml(Divergence(3*x*ACS.x*ACS.j + ACS.i), printer='presentation') == \ + '·('\ + 'i^'\ + 'A+('\ + '3'\ + 'xA'\ + 'x)'\ + 'j'\ + '^A'\ + ')' + assert mathml(Dot(ACS.i, ACS.j*ACS.x*3+ACS.k), printer='presentation') == \ + 'i^'\ + 'A·('\ + '(3'\ + 'xA'\ + ')'\ + 'j^'\ + 'A+'\ + 'k^'\ + 'A)' + assert mathml(Dot(ACS.i, ACS.j), printer='presentation') == \ + 'i^'\ + 'A·'\ + 'j^'\ + 'A' + assert mathml(Dot(x*ACS.i, ACS.j), printer='presentation') == \ + 'j^'\ + 'A·('\ + '(x)'\ + 'i^'\ + 'A)' + assert mathml(x*Dot(ACS.i, ACS.j), printer='presentation') == \ + 'x('\ + 'i^'\ + 'A·'\ + 'j^'\ + 'A)' + assert mathml(Gradient(ACS.x), printer='presentation') == \ + 'x'\ + 'A' + assert mathml(Gradient(ACS.x + 3*ACS.y), printer='presentation') == \ + '('\ + 'xA+3'\ + 'y'\ + 'A)' + assert mathml(x*Gradient(ACS.x), printer='presentation') == \ + 'x('\ + 'xA'\ + ')' + assert mathml(Gradient(x*ACS.x), printer='presentation') == \ + '('\ + 'xA'\ + 'x)' + assert mathml(Cross(ACS.z, ACS.x), printer='presentation') == \ + '-x'\ + 'A×'\ + 'zA' + assert mathml(Laplacian(ACS.x), printer='presentation') == \ + 'x'\ + 'A' + assert mathml(Laplacian(ACS.x + 3*ACS.y), printer='presentation') == \ + '('\ + 'xA+3'\ + 'y'\ + 'A)' + assert mathml(x*Laplacian(ACS.x), printer='presentation') == \ + 'x('\ + 'xA'\ + ')' + assert mathml(Laplacian(x*ACS.x), printer='presentation') == \ + '('\ + 'xA'\ + 'x)' + +@XFAIL +def test_vector_cross_xfail(): + ACS = CoordSys3D('A') + assert mathml(Cross(ACS.x, ACS.z) + Cross(ACS.z, ACS.x), printer='presentation') == \ + '0^' + +def test_print_elliptic_f(): + assert mathml(elliptic_f(x, y), printer = 'presentation') == \ + '𝖥(x|y)' + assert mathml(elliptic_f(x/y, y), printer = 'presentation') == \ + '𝖥(xy|y)' + +def test_print_elliptic_e(): + assert mathml(elliptic_e(x), printer = 'presentation') == \ + '𝖤(x)' + assert mathml(elliptic_e(x, y), printer = 'presentation') == \ + '𝖤(x|y)' + +def test_print_elliptic_pi(): + assert mathml(elliptic_pi(x, y), printer = 'presentation') == \ + '𝛱(x|y)' + assert mathml(elliptic_pi(x, y, z), printer = 'presentation') == \ + '𝛱(x;y|z)' + +def test_print_Ei(): + assert mathml(Ei(x), printer = 'presentation') == \ + 'Ei(x)' + assert mathml(Ei(x**y), printer = 'presentation') == \ + 'Ei(xy)' + +def test_print_expint(): + assert mathml(expint(x, y), printer = 'presentation') == \ + 'Ex(y)' + assert mathml(expint(IndexedBase(x)[1], IndexedBase(x)[2]), printer = 'presentation') == \ + 'Ex1(x2)' + +def test_print_jacobi(): + assert mathml(jacobi(n, a, b, x), printer = 'presentation') == \ + 'Pn(a,b)(x)' + +def test_print_gegenbauer(): + assert mathml(gegenbauer(n, a, x), printer = 'presentation') == \ + 'Cn(a)(x)' + +def test_print_chebyshevt(): + assert mathml(chebyshevt(n, x), printer = 'presentation') == \ + 'Tn(x)' + +def test_print_chebyshevu(): + assert mathml(chebyshevu(n, x), printer = 'presentation') == \ + 'Un(x)' + +def test_print_legendre(): + assert mathml(legendre(n, x), printer = 'presentation') == \ + 'Pn(x)' + +def test_print_assoc_legendre(): + assert mathml(assoc_legendre(n, a, x), printer = 'presentation') == \ + 'Pn(a)(x)' + +def test_print_laguerre(): + assert mathml(laguerre(n, x), printer = 'presentation') == \ + 'Ln(x)' + +def test_print_assoc_laguerre(): + assert mathml(assoc_laguerre(n, a, x), printer = 'presentation') == \ + 'Ln(a)(x)' + +def test_print_hermite(): + assert mathml(hermite(n, x), printer = 'presentation') == \ + 'Hn(x)' + +def test_mathml_SingularityFunction(): + assert mathml(SingularityFunction(x, 4, 5), printer='presentation') == \ + 'x-45' + assert mathml(SingularityFunction(x, -3, 4), printer='presentation') == \ + 'x+34' + assert mathml(SingularityFunction(x, 0, 4), printer='presentation') == \ + 'x4' + assert mathml(SingularityFunction(x, a, n), printer='presentation') == \ + '-a+xn' + assert mathml(SingularityFunction(x, 4, -2), printer='presentation') == \ + 'x-4-2' + assert mathml(SingularityFunction(x, 4, -1), printer='presentation') == \ + 'x-4-1' + + +def test_mathml_matrix_functions(): + from sympy.matrices import Adjoint, Inverse, Transpose + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert mathml(Adjoint(X), printer='presentation') == \ + 'X' + assert mathml(Adjoint(X + Y), printer='presentation') == \ + '(X+Y)' + assert mathml(Adjoint(X) + Adjoint(Y), printer='presentation') == \ + 'X+' \ + 'Y' + assert mathml(Adjoint(X*Y), printer='presentation') == \ + '(X' \ + 'Y)' + assert mathml(Adjoint(Y)*Adjoint(X), printer='presentation') == \ + 'Y⁢' \ + 'X' + assert mathml(Adjoint(X**2), printer='presentation') == \ + '(X2)' + assert mathml(Adjoint(X)**2, printer='presentation') == \ + '(X)2' + assert mathml(Adjoint(Inverse(X)), printer='presentation') == \ + '(X-1)' + assert mathml(Inverse(Adjoint(X)), printer='presentation') == \ + '(X)-1' + assert mathml(Adjoint(Transpose(X)), printer='presentation') == \ + '(XT)' + assert mathml(Transpose(Adjoint(X)), printer='presentation') == \ + '(X)T' + assert mathml(Transpose(Adjoint(X) + Y), printer='presentation') == \ + '(X' \ + '+Y)T' + assert mathml(Transpose(X), printer='presentation') == \ + 'XT' + assert mathml(Transpose(X + Y), printer='presentation') == \ + '(X+Y)T' + + +def test_mathml_special_matrices(): + from sympy.matrices import Identity, ZeroMatrix, OneMatrix + assert mathml(Identity(4), printer='presentation') == '𝕀' + assert mathml(ZeroMatrix(2, 2), printer='presentation') == '𝟘' + assert mathml(OneMatrix(2, 2), printer='presentation') == '𝟙' + +def test_mathml_piecewise(): + from sympy.functions.elementary.piecewise import Piecewise + # Content MathML + assert mathml(Piecewise((x, x <= 1), (x**2, True))) == \ + 'xx1x2' + + raises(ValueError, lambda: mathml(Piecewise((x, x <= 1)))) + + +def test_issue_17857(): + assert mathml(Range(-oo, oo), printer='presentation') == \ + '{,-1,0,1,}' + assert mathml(Range(oo, -oo, -1), printer='presentation') == \ + '{,1,0,-1,}' + + +def test_float_roundtrip(): + x = sympify(0.8975979010256552) + y = float(mp.doprint(x).strip('')) + assert x == y + + +def test_content_mathml_disable_split_super_sub(): + mp = MathMLContentPrinter() + assert mp.doprint(Symbol('u_b')) == 'ub' + mp = MathMLContentPrinter({'disable_split_super_sub': False}) + assert mp.doprint(Symbol('u_b')) == 'ub' + mp = MathMLContentPrinter({'disable_split_super_sub': True}) + assert mp.doprint(Symbol('u_b')) == 'u_b' + +def test_presentation_mathml_disable_split_super_sub(): + mpp = MathMLPresentationPrinter() + assert mpp.doprint(Symbol('u_b')) == 'ub' + mpp = MathMLPresentationPrinter({'disable_split_super_sub': False}) + assert mpp.doprint(Symbol('u_b')) == 'ub' + mpp = MathMLPresentationPrinter({'disable_split_super_sub': True}) + assert mpp.doprint(Symbol('u_b')) == 'u_b' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_numpy.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_numpy.py new file mode 100644 index 0000000000000000000000000000000000000000..fee1c6bd95e54790a048220f37b8e5de79017d2f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_numpy.py @@ -0,0 +1,381 @@ +from sympy.concrete.summations import Sum +from sympy.core.mod import Mod +from sympy.core.relational import (Equality, Unequality) +from sympy.core.symbol import Symbol +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.special.gamma_functions import polygamma +from sympy.functions.special.error_functions import (Si, Ci) +from sympy.matrices import Matrix +from sympy.matrices.expressions.blockmatrix import BlockMatrix +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.matrices.expressions.special import Identity +from sympy.utilities.lambdify import lambdify +from sympy import symbols, Min, Max + +from sympy.abc import x, i, j, a, b, c, d +from sympy.core import Pow +from sympy.codegen.matrix_nodes import MatrixSolve +from sympy.codegen.numpy_nodes import logaddexp, logaddexp2 +from sympy.codegen.cfunctions import log1p, expm1, hypot, log10, exp2, log2, Sqrt +from sympy.tensor.array import Array +from sympy.tensor.array.expressions.array_expressions import ArrayTensorProduct, ArrayAdd, \ + PermuteDims, ArrayDiagonal +from sympy.printing.numpy import NumPyPrinter, SciPyPrinter, _numpy_known_constants, \ + _numpy_known_functions, _scipy_known_constants, _scipy_known_functions +from sympy.tensor.array.expressions.from_matrix_to_array import convert_matrix_to_array + +from sympy.testing.pytest import skip, raises +from sympy.external import import_module + +np = import_module('numpy') +jax = import_module('jax') + +if np: + deafult_float_info = np.finfo(np.array([]).dtype) + NUMPY_DEFAULT_EPSILON = deafult_float_info.eps + +def test_numpy_piecewise_regression(): + """ + NumPyPrinter needs to print Piecewise()'s choicelist as a list to avoid + breaking compatibility with numpy 1.8. This is not necessary in numpy 1.9+. + See gh-9747 and gh-9749 for details. + """ + printer = NumPyPrinter() + p = Piecewise((1, x < 0), (0, True)) + assert printer.doprint(p) == \ + 'numpy.select([numpy.less(x, 0),True], [1,0], default=numpy.nan)' + assert printer.module_imports == {'numpy': {'select', 'less', 'nan'}} + +def test_numpy_logaddexp(): + lae = logaddexp(a, b) + assert NumPyPrinter().doprint(lae) == 'numpy.logaddexp(a, b)' + lae2 = logaddexp2(a, b) + assert NumPyPrinter().doprint(lae2) == 'numpy.logaddexp2(a, b)' + + +def test_sum(): + if not np: + skip("NumPy not installed") + + s = Sum(x ** i, (i, a, b)) + f = lambdify((a, b, x), s, 'numpy') + + a_, b_ = 0, 10 + x_ = np.linspace(-1, +1, 10) + assert np.allclose(f(a_, b_, x_), sum(x_ ** i_ for i_ in range(a_, b_ + 1))) + + s = Sum(i * x, (i, a, b)) + f = lambdify((a, b, x), s, 'numpy') + + a_, b_ = 0, 10 + x_ = np.linspace(-1, +1, 10) + assert np.allclose(f(a_, b_, x_), sum(i_ * x_ for i_ in range(a_, b_ + 1))) + + +def test_multiple_sums(): + if not np: + skip("NumPy not installed") + + s = Sum((x + j) * i, (i, a, b), (j, c, d)) + f = lambdify((a, b, c, d, x), s, 'numpy') + + a_, b_ = 0, 10 + c_, d_ = 11, 21 + x_ = np.linspace(-1, +1, 10) + assert np.allclose(f(a_, b_, c_, d_, x_), + sum((x_ + j_) * i_ for i_ in range(a_, b_ + 1) for j_ in range(c_, d_ + 1))) + + +def test_codegen_einsum(): + if not np: + skip("NumPy not installed") + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + + cg = convert_matrix_to_array(M * N) + f = lambdify((M, N), cg, 'numpy') + + ma = np.array([[1, 2], [3, 4]]) + mb = np.array([[1,-2], [-1, 3]]) + assert (f(ma, mb) == np.matmul(ma, mb)).all() + + +def test_codegen_extra(): + if not np: + skip("NumPy not installed") + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + P = MatrixSymbol("P", 2, 2) + Q = MatrixSymbol("Q", 2, 2) + ma = np.array([[1, 2], [3, 4]]) + mb = np.array([[1,-2], [-1, 3]]) + mc = np.array([[2, 0], [1, 2]]) + md = np.array([[1,-1], [4, 7]]) + + cg = ArrayTensorProduct(M, N) + f = lambdify((M, N), cg, 'numpy') + assert (f(ma, mb) == np.einsum(ma, [0, 1], mb, [2, 3])).all() + + cg = ArrayAdd(M, N) + f = lambdify((M, N), cg, 'numpy') + assert (f(ma, mb) == ma+mb).all() + + cg = ArrayAdd(M, N, P) + f = lambdify((M, N, P), cg, 'numpy') + assert (f(ma, mb, mc) == ma+mb+mc).all() + + cg = ArrayAdd(M, N, P, Q) + f = lambdify((M, N, P, Q), cg, 'numpy') + assert (f(ma, mb, mc, md) == ma+mb+mc+md).all() + + cg = PermuteDims(M, [1, 0]) + f = lambdify((M,), cg, 'numpy') + assert (f(ma) == ma.T).all() + + cg = PermuteDims(ArrayTensorProduct(M, N), [1, 2, 3, 0]) + f = lambdify((M, N), cg, 'numpy') + assert (f(ma, mb) == np.transpose(np.einsum(ma, [0, 1], mb, [2, 3]), (1, 2, 3, 0))).all() + + cg = ArrayDiagonal(ArrayTensorProduct(M, N), (1, 2)) + f = lambdify((M, N), cg, 'numpy') + assert (f(ma, mb) == np.diagonal(np.einsum(ma, [0, 1], mb, [2, 3]), axis1=1, axis2=2)).all() + + +def test_relational(): + if not np: + skip("NumPy not installed") + + e = Equality(x, 1) + + f = lambdify((x,), e) + x_ = np.array([0, 1, 2]) + assert np.array_equal(f(x_), [False, True, False]) + + e = Unequality(x, 1) + + f = lambdify((x,), e) + x_ = np.array([0, 1, 2]) + assert np.array_equal(f(x_), [True, False, True]) + + e = (x < 1) + + f = lambdify((x,), e) + x_ = np.array([0, 1, 2]) + assert np.array_equal(f(x_), [True, False, False]) + + e = (x <= 1) + + f = lambdify((x,), e) + x_ = np.array([0, 1, 2]) + assert np.array_equal(f(x_), [True, True, False]) + + e = (x > 1) + + f = lambdify((x,), e) + x_ = np.array([0, 1, 2]) + assert np.array_equal(f(x_), [False, False, True]) + + e = (x >= 1) + + f = lambdify((x,), e) + x_ = np.array([0, 1, 2]) + assert np.array_equal(f(x_), [False, True, True]) + + +def test_mod(): + if not np: + skip("NumPy not installed") + + e = Mod(a, b) + f = lambdify((a, b), e) + + a_ = np.array([0, 1, 2, 3]) + b_ = 2 + assert np.array_equal(f(a_, b_), [0, 1, 0, 1]) + + a_ = np.array([0, 1, 2, 3]) + b_ = np.array([2, 2, 2, 2]) + assert np.array_equal(f(a_, b_), [0, 1, 0, 1]) + + a_ = np.array([2, 3, 4, 5]) + b_ = np.array([2, 3, 4, 5]) + assert np.array_equal(f(a_, b_), [0, 0, 0, 0]) + + +def test_pow(): + if not np: + skip('NumPy not installed') + + expr = Pow(2, -1, evaluate=False) + f = lambdify([], expr, 'numpy') + assert f() == 0.5 + + +def test_expm1(): + if not np: + skip("NumPy not installed") + + f = lambdify((a,), expm1(a), 'numpy') + assert abs(f(1e-10) - 1e-10 - 5e-21) <= 1e-10 * NUMPY_DEFAULT_EPSILON + + +def test_log1p(): + if not np: + skip("NumPy not installed") + + f = lambdify((a,), log1p(a), 'numpy') + assert abs(f(1e-99) - 1e-99) <= 1e-99 * NUMPY_DEFAULT_EPSILON + +def test_hypot(): + if not np: + skip("NumPy not installed") + assert abs(lambdify((a, b), hypot(a, b), 'numpy')(3, 4) - 5) <= NUMPY_DEFAULT_EPSILON + +def test_log10(): + if not np: + skip("NumPy not installed") + assert abs(lambdify((a,), log10(a), 'numpy')(100) - 2) <= NUMPY_DEFAULT_EPSILON + + +def test_exp2(): + if not np: + skip("NumPy not installed") + assert abs(lambdify((a,), exp2(a), 'numpy')(5) - 32) <= NUMPY_DEFAULT_EPSILON + + +def test_log2(): + if not np: + skip("NumPy not installed") + assert abs(lambdify((a,), log2(a), 'numpy')(256) - 8) <= NUMPY_DEFAULT_EPSILON + + +def test_Sqrt(): + if not np: + skip("NumPy not installed") + assert abs(lambdify((a,), Sqrt(a), 'numpy')(4) - 2) <= NUMPY_DEFAULT_EPSILON + + +def test_sqrt(): + if not np: + skip("NumPy not installed") + assert abs(lambdify((a,), sqrt(a), 'numpy')(4) - 2) <= NUMPY_DEFAULT_EPSILON + + +def test_matsolve(): + if not np: + skip("NumPy not installed") + + M = MatrixSymbol("M", 3, 3) + x = MatrixSymbol("x", 3, 1) + + expr = M**(-1) * x + x + matsolve_expr = MatrixSolve(M, x) + x + + f = lambdify((M, x), expr) + f_matsolve = lambdify((M, x), matsolve_expr) + + m0 = np.array([[1, 2, 3], [3, 2, 5], [5, 6, 7]]) + assert np.linalg.matrix_rank(m0) == 3 + + x0 = np.array([3, 4, 5]) + + assert np.allclose(f_matsolve(m0, x0), f(m0, x0)) + + +def test_16857(): + if not np: + skip("NumPy not installed") + + a_1 = MatrixSymbol('a_1', 10, 3) + a_2 = MatrixSymbol('a_2', 10, 3) + a_3 = MatrixSymbol('a_3', 10, 3) + a_4 = MatrixSymbol('a_4', 10, 3) + A = BlockMatrix([[a_1, a_2], [a_3, a_4]]) + assert A.shape == (20, 6) + + printer = NumPyPrinter() + assert printer.doprint(A) == 'numpy.block([[a_1, a_2], [a_3, a_4]])' + + +def test_issue_17006(): + if not np: + skip("NumPy not installed") + + M = MatrixSymbol("M", 2, 2) + + f = lambdify(M, M + Identity(2)) + ma = np.array([[1, 2], [3, 4]]) + mr = np.array([[2, 2], [3, 5]]) + + assert (f(ma) == mr).all() + + from sympy.core.symbol import symbols + n = symbols('n', integer=True) + N = MatrixSymbol("M", n, n) + raises(NotImplementedError, lambda: lambdify(N, N + Identity(n))) + +def test_jax_tuple_compatibility(): + if not jax: + skip("Jax not installed") + + x, y, z = symbols('x y z') + expr = Max(x, y, z) + Min(x, y, z) + func = lambdify((x, y, z), expr, 'jax') + input_tuple1, input_tuple2 = (1, 2, 3), (4, 5, 6) + input_array1, input_array2 = jax.numpy.asarray(input_tuple1), jax.numpy.asarray(input_tuple2) + assert np.allclose(func(*input_tuple1), func(*input_array1)) + assert np.allclose(func(*input_tuple2), func(*input_array2)) + +def test_numpy_array(): + p = NumPyPrinter() + assert p.doprint(Array([[1, 2], [3, 5]])) == 'numpy.array([[1, 2], [3, 5]])' + assert p.doprint(Array([1, 2])) == 'numpy.array([1, 2])' + assert p.doprint(Array([[[1, 2, 3]]])) == 'numpy.array([[[1, 2, 3]]])' + assert p.doprint(Array([], (0,))) == 'numpy.zeros((0,))' + assert p.doprint(Array([], (0, 0))) == 'numpy.zeros((0, 0))' + assert p.doprint(Array([], (0, 1))) == 'numpy.zeros((0, 1))' + assert p.doprint(Array([], (1, 0))) == 'numpy.zeros((1, 0))' + assert p.doprint(Array([1], ())) == 'numpy.array(1)' + +def test_numpy_matrix(): + p = NumPyPrinter() + assert p.doprint(Matrix([[1, 2], [3, 5]])) == 'numpy.array([[1, 2], [3, 5]])' + assert p.doprint(Matrix([1, 2])) == 'numpy.array([[1], [2]])' + assert p.doprint(Matrix(0, 0, [])) == 'numpy.zeros((0, 0))' + assert p.doprint(Matrix(0, 1, [])) == 'numpy.zeros((0, 1))' + assert p.doprint(Matrix(1, 0, [])) == 'numpy.zeros((1, 0))' + +def test_numpy_known_funcs_consts(): + assert _numpy_known_constants['NaN'] == 'numpy.nan' + assert _numpy_known_constants['EulerGamma'] == 'numpy.euler_gamma' + + assert _numpy_known_functions['acos'] == 'numpy.arccos' + assert _numpy_known_functions['log'] == 'numpy.log' + +def test_scipy_known_funcs_consts(): + assert _scipy_known_constants['GoldenRatio'] == 'scipy.constants.golden_ratio' + assert _scipy_known_constants['Pi'] == 'scipy.constants.pi' + + assert _scipy_known_functions['erf'] == 'scipy.special.erf' + assert _scipy_known_functions['factorial'] == 'scipy.special.factorial' + +def test_numpy_print_methods(): + prntr = NumPyPrinter() + assert hasattr(prntr, '_print_acos') + assert hasattr(prntr, '_print_log') + +def test_scipy_print_methods(): + prntr = SciPyPrinter() + assert hasattr(prntr, '_print_acos') + assert hasattr(prntr, '_print_log') + assert hasattr(prntr, '_print_erf') + assert hasattr(prntr, '_print_factorial') + assert hasattr(prntr, '_print_chebyshevt') + k = Symbol('k', integer=True, nonnegative=True) + x = Symbol('x', real=True) + assert prntr.doprint(polygamma(k, x)) == "scipy.special.polygamma(k, x)" + assert prntr.doprint(Si(x)) == "scipy.special.sici(x)[0]" + assert prntr.doprint(Ci(x)) == "scipy.special.sici(x)[1]" diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_octave.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_octave.py new file mode 100644 index 0000000000000000000000000000000000000000..1aba318f873c48ec702f1b4e3a6cc047f75d647d --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_octave.py @@ -0,0 +1,515 @@ +from sympy.core import (S, pi, oo, symbols, Function, Rational, Integer, + Tuple, Symbol, EulerGamma, GoldenRatio, Catalan, + Lambda, Mul, Pow, Mod, Eq, Ne, Le, Lt, Gt, Ge) +from sympy.codegen.matrix_nodes import MatrixSolve +from sympy.functions import (arg, atan2, bernoulli, beta, ceiling, chebyshevu, + chebyshevt, conjugate, DiracDelta, exp, expint, + factorial, floor, harmonic, Heaviside, im, + laguerre, LambertW, log, Max, Min, Piecewise, + polylog, re, RisingFactorial, sign, sinc, sqrt, + zeta, binomial, legendre, dirichlet_eta, + riemann_xi) +from sympy.functions import (sin, cos, tan, cot, sec, csc, asin, acos, acot, + atan, asec, acsc, sinh, cosh, tanh, coth, csch, + sech, asinh, acosh, atanh, acoth, asech, acsch) +from sympy.testing.pytest import raises, XFAIL +from sympy.utilities.lambdify import implemented_function +from sympy.matrices import (eye, Matrix, MatrixSymbol, Identity, + HadamardProduct, SparseMatrix, HadamardPower) +from sympy.functions.special.bessel import (jn, yn, besselj, bessely, besseli, + besselk, hankel1, hankel2, airyai, + airybi, airyaiprime, airybiprime) +from sympy.functions.special.gamma_functions import (gamma, lowergamma, + uppergamma, loggamma, + polygamma) +from sympy.functions.special.error_functions import (Chi, Ci, erf, erfc, erfi, + erfcinv, erfinv, fresnelc, + fresnels, li, Shi, Si, Li, + erf2, Ei) +from sympy.printing.octave import octave_code, octave_code as mcode + +x, y, z = symbols('x,y,z') + + +def test_Integer(): + assert mcode(Integer(67)) == "67" + assert mcode(Integer(-1)) == "-1" + + +def test_Rational(): + assert mcode(Rational(3, 7)) == "3/7" + assert mcode(Rational(18, 9)) == "2" + assert mcode(Rational(3, -7)) == "-3/7" + assert mcode(Rational(-3, -7)) == "3/7" + assert mcode(x + Rational(3, 7)) == "x + 3/7" + assert mcode(Rational(3, 7)*x) == "3*x/7" + + +def test_Relational(): + assert mcode(Eq(x, y)) == "x == y" + assert mcode(Ne(x, y)) == "x != y" + assert mcode(Le(x, y)) == "x <= y" + assert mcode(Lt(x, y)) == "x < y" + assert mcode(Gt(x, y)) == "x > y" + assert mcode(Ge(x, y)) == "x >= y" + + +def test_Function(): + assert mcode(sin(x) ** cos(x)) == "sin(x).^cos(x)" + assert mcode(sign(x)) == "sign(x)" + assert mcode(exp(x)) == "exp(x)" + assert mcode(log(x)) == "log(x)" + assert mcode(factorial(x)) == "factorial(x)" + assert mcode(floor(x)) == "floor(x)" + assert mcode(atan2(y, x)) == "atan2(y, x)" + assert mcode(beta(x, y)) == 'beta(x, y)' + assert mcode(polylog(x, y)) == 'polylog(x, y)' + assert mcode(harmonic(x)) == 'harmonic(x)' + assert mcode(bernoulli(x)) == "bernoulli(x)" + assert mcode(bernoulli(x, y)) == "bernoulli(x, y)" + assert mcode(legendre(x, y)) == "legendre(x, y)" + + +def test_Function_change_name(): + assert mcode(abs(x)) == "abs(x)" + assert mcode(ceiling(x)) == "ceil(x)" + assert mcode(arg(x)) == "angle(x)" + assert mcode(im(x)) == "imag(x)" + assert mcode(re(x)) == "real(x)" + assert mcode(conjugate(x)) == "conj(x)" + assert mcode(chebyshevt(y, x)) == "chebyshevT(y, x)" + assert mcode(chebyshevu(y, x)) == "chebyshevU(y, x)" + assert mcode(laguerre(x, y)) == "laguerreL(x, y)" + assert mcode(Chi(x)) == "coshint(x)" + assert mcode(Shi(x)) == "sinhint(x)" + assert mcode(Ci(x)) == "cosint(x)" + assert mcode(Si(x)) == "sinint(x)" + assert mcode(li(x)) == "logint(x)" + assert mcode(loggamma(x)) == "gammaln(x)" + assert mcode(polygamma(x, y)) == "psi(x, y)" + assert mcode(RisingFactorial(x, y)) == "pochhammer(x, y)" + assert mcode(DiracDelta(x)) == "dirac(x)" + assert mcode(DiracDelta(x, 3)) == "dirac(3, x)" + assert mcode(Heaviside(x)) == "heaviside(x, 1/2)" + assert mcode(Heaviside(x, y)) == "heaviside(x, y)" + assert mcode(binomial(x, y)) == "bincoeff(x, y)" + assert mcode(Mod(x, y)) == "mod(x, y)" + + +def test_minmax(): + assert mcode(Max(x, y) + Min(x, y)) == "max(x, y) + min(x, y)" + assert mcode(Max(x, y, z)) == "max(x, max(y, z))" + assert mcode(Min(x, y, z)) == "min(x, min(y, z))" + + +def test_Pow(): + assert mcode(x**3) == "x.^3" + assert mcode(x**(y**3)) == "x.^(y.^3)" + assert mcode(x**Rational(2, 3)) == 'x.^(2/3)' + g = implemented_function('g', Lambda(x, 2*x)) + assert mcode(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "(3.5*2*x).^(-x + y.^x)./(x.^2 + y)" + # For issue 14160 + assert mcode(Mul(-2, x, Pow(Mul(y,y,evaluate=False), -1, evaluate=False), + evaluate=False)) == '-2*x./(y.*y)' + + +def test_basic_ops(): + assert mcode(x*y) == "x.*y" + assert mcode(x + y) == "x + y" + assert mcode(x - y) == "x - y" + assert mcode(-x) == "-x" + + +def test_1_over_x_and_sqrt(): + # 1.0 and 0.5 would do something different in regular StrPrinter, + # but these are exact in IEEE floating point so no different here. + assert mcode(1/x) == '1./x' + assert mcode(x**-1) == mcode(x**-1.0) == '1./x' + assert mcode(1/sqrt(x)) == '1./sqrt(x)' + assert mcode(x**-S.Half) == mcode(x**-0.5) == '1./sqrt(x)' + assert mcode(sqrt(x)) == 'sqrt(x)' + assert mcode(x**S.Half) == mcode(x**0.5) == 'sqrt(x)' + assert mcode(1/pi) == '1/pi' + assert mcode(pi**-1) == mcode(pi**-1.0) == '1/pi' + assert mcode(pi**-0.5) == '1/sqrt(pi)' + + +def test_mix_number_mult_symbols(): + assert mcode(3*x) == "3*x" + assert mcode(pi*x) == "pi*x" + assert mcode(3/x) == "3./x" + assert mcode(pi/x) == "pi./x" + assert mcode(x/3) == "x/3" + assert mcode(x/pi) == "x/pi" + assert mcode(x*y) == "x.*y" + assert mcode(3*x*y) == "3*x.*y" + assert mcode(3*pi*x*y) == "3*pi*x.*y" + assert mcode(x/y) == "x./y" + assert mcode(3*x/y) == "3*x./y" + assert mcode(x*y/z) == "x.*y./z" + assert mcode(x/y*z) == "x.*z./y" + assert mcode(1/x/y) == "1./(x.*y)" + assert mcode(2*pi*x/y/z) == "2*pi*x./(y.*z)" + assert mcode(3*pi/x) == "3*pi./x" + assert mcode(S(3)/5) == "3/5" + assert mcode(S(3)/5*x) == "3*x/5" + assert mcode(x/y/z) == "x./(y.*z)" + assert mcode((x+y)/z) == "(x + y)./z" + assert mcode((x+y)/(z+x)) == "(x + y)./(x + z)" + assert mcode((x+y)/EulerGamma) == "(x + y)/%s" % EulerGamma.evalf(17) + assert mcode(x/3/pi) == "x/(3*pi)" + assert mcode(S(3)/5*x*y/pi) == "3*x.*y/(5*pi)" + + +def test_mix_number_pow_symbols(): + assert mcode(pi**3) == 'pi^3' + assert mcode(x**2) == 'x.^2' + assert mcode(x**(pi**3)) == 'x.^(pi^3)' + assert mcode(x**y) == 'x.^y' + assert mcode(x**(y**z)) == 'x.^(y.^z)' + assert mcode((x**y)**z) == '(x.^y).^z' + + +def test_imag(): + I = S('I') + assert mcode(I) == "1i" + assert mcode(5*I) == "5i" + assert mcode((S(3)/2)*I) == "3*1i/2" + assert mcode(3+4*I) == "3 + 4i" + assert mcode(sqrt(3)*I) == "sqrt(3)*1i" + + +def test_constants(): + assert mcode(pi) == "pi" + assert mcode(oo) == "inf" + assert mcode(-oo) == "-inf" + assert mcode(S.NegativeInfinity) == "-inf" + assert mcode(S.NaN) == "NaN" + assert mcode(S.Exp1) == "exp(1)" + assert mcode(exp(1)) == "exp(1)" + + +def test_constants_other(): + assert mcode(2*GoldenRatio) == "2*(1+sqrt(5))/2" + assert mcode(2*Catalan) == "2*%s" % Catalan.evalf(17) + assert mcode(2*EulerGamma) == "2*%s" % EulerGamma.evalf(17) + + +def test_boolean(): + assert mcode(x & y) == "x & y" + assert mcode(x | y) == "x | y" + assert mcode(~x) == "~x" + assert mcode(x & y & z) == "x & y & z" + assert mcode(x | y | z) == "x | y | z" + assert mcode((x & y) | z) == "z | x & y" + assert mcode((x | y) & z) == "z & (x | y)" + + +def test_KroneckerDelta(): + from sympy.functions import KroneckerDelta + assert mcode(KroneckerDelta(x, y)) == "double(x == y)" + assert mcode(KroneckerDelta(x, y + 1)) == "double(x == (y + 1))" + assert mcode(KroneckerDelta(2**x, y)) == "double((2.^x) == y)" + + +def test_Matrices(): + assert mcode(Matrix(1, 1, [10])) == "10" + A = Matrix([[1, sin(x/2), abs(x)], + [0, 1, pi], + [0, exp(1), ceiling(x)]]) + expected = "[1 sin(x/2) abs(x); 0 1 pi; 0 exp(1) ceil(x)]" + assert mcode(A) == expected + # row and columns + assert mcode(A[:,0]) == "[1; 0; 0]" + assert mcode(A[0,:]) == "[1 sin(x/2) abs(x)]" + # empty matrices + assert mcode(Matrix(0, 0, [])) == '[]' + assert mcode(Matrix(0, 3, [])) == 'zeros(0, 3)' + # annoying to read but correct + assert mcode(Matrix([[x, x - y, -y]])) == "[x x - y -y]" + + +def test_vector_entries_hadamard(): + # For a row or column, user might to use the other dimension + A = Matrix([[1, sin(2/x), 3*pi/x/5]]) + assert mcode(A) == "[1 sin(2./x) 3*pi./(5*x)]" + assert mcode(A.T) == "[1; sin(2./x); 3*pi./(5*x)]" + + +@XFAIL +def test_Matrices_entries_not_hadamard(): + # For Matrix with col >= 2, row >= 2, they need to be scalars + # FIXME: is it worth worrying about this? Its not wrong, just + # leave it user's responsibility to put scalar data for x. + A = Matrix([[1, sin(2/x), 3*pi/x/5], [1, 2, x*y]]) + expected = ("[1 sin(2/x) 3*pi/(5*x);\n" + "1 2 x*y]") # <- we give x.*y + assert mcode(A) == expected + + +def test_MatrixSymbol(): + n = Symbol('n', integer=True) + A = MatrixSymbol('A', n, n) + B = MatrixSymbol('B', n, n) + assert mcode(A*B) == "A*B" + assert mcode(B*A) == "B*A" + assert mcode(2*A*B) == "2*A*B" + assert mcode(B*2*A) == "2*B*A" + assert mcode(A*(B + 3*Identity(n))) == "A*(3*eye(n) + B)" + assert mcode(A**(x**2)) == "A^(x.^2)" + assert mcode(A**3) == "A^3" + assert mcode(A**S.Half) == "A^(1/2)" + + +def test_MatrixSolve(): + n = Symbol('n', integer=True) + A = MatrixSymbol('A', n, n) + x = MatrixSymbol('x', n, 1) + assert mcode(MatrixSolve(A, x)) == "A \\ x" + +def test_special_matrices(): + assert mcode(6*Identity(3)) == "6*eye(3)" + + +def test_containers(): + assert mcode([1, 2, 3, [4, 5, [6, 7]], 8, [9, 10], 11]) == \ + "{1, 2, 3, {4, 5, {6, 7}}, 8, {9, 10}, 11}" + assert mcode((1, 2, (3, 4))) == "{1, 2, {3, 4}}" + assert mcode([1]) == "{1}" + assert mcode((1,)) == "{1}" + assert mcode(Tuple(*[1, 2, 3])) == "{1, 2, 3}" + assert mcode((1, x*y, (3, x**2))) == "{1, x.*y, {3, x.^2}}" + # scalar, matrix, empty matrix and empty list + assert mcode((1, eye(3), Matrix(0, 0, []), [])) == "{1, [1 0 0; 0 1 0; 0 0 1], [], {}}" + + +def test_octave_noninline(): + source = mcode((x+y)/Catalan, assign_to='me', inline=False) + expected = ( + "Catalan = %s;\n" + "me = (x + y)/Catalan;" + ) % Catalan.evalf(17) + assert source == expected + + +def test_octave_piecewise(): + expr = Piecewise((x, x < 1), (x**2, True)) + assert mcode(expr) == "((x < 1).*(x) + (~(x < 1)).*(x.^2))" + assert mcode(expr, assign_to="r") == ( + "r = ((x < 1).*(x) + (~(x < 1)).*(x.^2));") + assert mcode(expr, assign_to="r", inline=False) == ( + "if (x < 1)\n" + " r = x;\n" + "else\n" + " r = x.^2;\n" + "end") + expr = Piecewise((x**2, x < 1), (x**3, x < 2), (x**4, x < 3), (x**5, True)) + expected = ("((x < 1).*(x.^2) + (~(x < 1)).*( ...\n" + "(x < 2).*(x.^3) + (~(x < 2)).*( ...\n" + "(x < 3).*(x.^4) + (~(x < 3)).*(x.^5))))") + assert mcode(expr) == expected + assert mcode(expr, assign_to="r") == "r = " + expected + ";" + assert mcode(expr, assign_to="r", inline=False) == ( + "if (x < 1)\n" + " r = x.^2;\n" + "elseif (x < 2)\n" + " r = x.^3;\n" + "elseif (x < 3)\n" + " r = x.^4;\n" + "else\n" + " r = x.^5;\n" + "end") + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) + raises(ValueError, lambda: mcode(expr)) + + +def test_octave_piecewise_times_const(): + pw = Piecewise((x, x < 1), (x**2, True)) + assert mcode(2*pw) == "2*((x < 1).*(x) + (~(x < 1)).*(x.^2))" + assert mcode(pw/x) == "((x < 1).*(x) + (~(x < 1)).*(x.^2))./x" + assert mcode(pw/(x*y)) == "((x < 1).*(x) + (~(x < 1)).*(x.^2))./(x.*y)" + assert mcode(pw/3) == "((x < 1).*(x) + (~(x < 1)).*(x.^2))/3" + + +def test_octave_matrix_assign_to(): + A = Matrix([[1, 2, 3]]) + assert mcode(A, assign_to='a') == "a = [1 2 3];" + A = Matrix([[1, 2], [3, 4]]) + assert mcode(A, assign_to='A') == "A = [1 2; 3 4];" + + +def test_octave_matrix_assign_to_more(): + # assigning to Symbol or MatrixSymbol requires lhs/rhs match + A = Matrix([[1, 2, 3]]) + B = MatrixSymbol('B', 1, 3) + C = MatrixSymbol('C', 2, 3) + assert mcode(A, assign_to=B) == "B = [1 2 3];" + raises(ValueError, lambda: mcode(A, assign_to=x)) + raises(ValueError, lambda: mcode(A, assign_to=C)) + + +def test_octave_matrix_1x1(): + A = Matrix([[3]]) + B = MatrixSymbol('B', 1, 1) + C = MatrixSymbol('C', 1, 2) + assert mcode(A, assign_to=B) == "B = 3;" + # FIXME? + #assert mcode(A, assign_to=x) == "x = 3;" + raises(ValueError, lambda: mcode(A, assign_to=C)) + + +def test_octave_matrix_elements(): + A = Matrix([[x, 2, x*y]]) + assert mcode(A[0, 0]**2 + A[0, 1] + A[0, 2]) == "x.^2 + x.*y + 2" + A = MatrixSymbol('AA', 1, 3) + assert mcode(A) == "AA" + assert mcode(A[0, 0]**2 + sin(A[0,1]) + A[0,2]) == \ + "sin(AA(1, 2)) + AA(1, 1).^2 + AA(1, 3)" + assert mcode(sum(A)) == "AA(1, 1) + AA(1, 2) + AA(1, 3)" + + +def test_octave_boolean(): + assert mcode(True) == "true" + assert mcode(S.true) == "true" + assert mcode(False) == "false" + assert mcode(S.false) == "false" + + +def test_octave_not_supported(): + with raises(NotImplementedError): + mcode(S.ComplexInfinity) + f = Function('f') + assert mcode(f(x).diff(x), strict=False) == ( + "% Not supported in Octave:\n" + "% Derivative\n" + "Derivative(f(x), x)" + ) + + +def test_octave_not_supported_not_on_whitelist(): + from sympy.functions.special.polynomials import assoc_laguerre + with raises(NotImplementedError): + mcode(assoc_laguerre(x, y, z)) + + +def test_octave_expint(): + assert mcode(expint(1, x)) == "expint(x)" + with raises(NotImplementedError): + mcode(expint(2, x)) + assert mcode(expint(y, x), strict=False) == ( + "% Not supported in Octave:\n" + "% expint\n" + "expint(y, x)" + ) + + +def test_trick_indent_with_end_else_words(): + # words starting with "end" or "else" do not confuse the indenter + t1 = S('endless') + t2 = S('elsewhere') + pw = Piecewise((t1, x < 0), (t2, x <= 1), (1, True)) + assert mcode(pw, inline=False) == ( + "if (x < 0)\n" + " endless\n" + "elseif (x <= 1)\n" + " elsewhere\n" + "else\n" + " 1\n" + "end") + + +def test_hadamard(): + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 3, 3) + v = MatrixSymbol('v', 3, 1) + h = MatrixSymbol('h', 1, 3) + C = HadamardProduct(A, B) + n = Symbol('n') + assert mcode(C) == "A.*B" + assert mcode(C*v) == "(A.*B)*v" + assert mcode(h*C*v) == "h*(A.*B)*v" + assert mcode(C*A) == "(A.*B)*A" + # mixing Hadamard and scalar strange b/c we vectorize scalars + assert mcode(C*x*y) == "(x.*y)*(A.*B)" + + # Testing HadamardPower: + assert mcode(HadamardPower(A, n)) == "A.**n" + assert mcode(HadamardPower(A, 1+n)) == "A.**(n + 1)" + assert mcode(HadamardPower(A*B.T, 1+n)) == "(A*B.T).**(n + 1)" + + +def test_sparse(): + M = SparseMatrix(5, 6, {}) + M[2, 2] = 10 + M[1, 2] = 20 + M[1, 3] = 22 + M[0, 3] = 30 + M[3, 0] = x*y + assert mcode(M) == ( + "sparse([4 2 3 1 2], [1 3 3 4 4], [x.*y 20 10 30 22], 5, 6)" + ) + + +def test_sinc(): + assert mcode(sinc(x)) == 'sinc(x/pi)' + assert mcode(sinc(x + 3)) == 'sinc((x + 3)/pi)' + assert mcode(sinc(pi*(x + 3))) == 'sinc(x + 3)' + + +def test_trigfun(): + for f in (sin, cos, tan, cot, sec, csc, asin, acos, acot, atan, asec, acsc, + sinh, cosh, tanh, coth, csch, sech, asinh, acosh, atanh, acoth, + asech, acsch): + assert octave_code(f(x) == f.__name__ + '(x)') + + +def test_specfun(): + n = Symbol('n') + for f in [besselj, bessely, besseli, besselk]: + assert octave_code(f(n, x)) == f.__name__ + '(n, x)' + for f in (erfc, erfi, erf, erfinv, erfcinv, fresnelc, fresnels, gamma): + assert octave_code(f(x)) == f.__name__ + '(x)' + assert octave_code(hankel1(n, x)) == 'besselh(n, 1, x)' + assert octave_code(hankel2(n, x)) == 'besselh(n, 2, x)' + assert octave_code(airyai(x)) == 'airy(0, x)' + assert octave_code(airyaiprime(x)) == 'airy(1, x)' + assert octave_code(airybi(x)) == 'airy(2, x)' + assert octave_code(airybiprime(x)) == 'airy(3, x)' + assert octave_code(uppergamma(n, x)) == '(gammainc(x, n, \'upper\').*gamma(n))' + assert octave_code(lowergamma(n, x)) == '(gammainc(x, n).*gamma(n))' + assert octave_code(z**lowergamma(n, x)) == 'z.^(gammainc(x, n).*gamma(n))' + assert octave_code(jn(n, x)) == 'sqrt(2)*sqrt(pi)*sqrt(1./x).*besselj(n + 1/2, x)/2' + assert octave_code(yn(n, x)) == 'sqrt(2)*sqrt(pi)*sqrt(1./x).*bessely(n + 1/2, x)/2' + assert octave_code(LambertW(x)) == 'lambertw(x)' + assert octave_code(LambertW(x, n)) == 'lambertw(n, x)' + + # Automatic rewrite + assert octave_code(Ei(x)) == '(logint(exp(x)))' + assert octave_code(dirichlet_eta(x)) == '(((x == 1).*(log(2)) + (~(x == 1)).*((1 - 2.^(1 - x)).*zeta(x))))' + assert octave_code(riemann_xi(x)) == '(pi.^(-x/2).*x.*(x - 1).*gamma(x/2).*zeta(x)/2)' + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert mcode(A[0, 0]) == "A(1, 1)" + assert mcode(3 * A[0, 0]) == "3*A(1, 1)" + + F = C[0, 0].subs(C, A - B) + assert mcode(F) == "(A - B)(1, 1)" + + +def test_zeta_printing_issue_14820(): + assert octave_code(zeta(x)) == 'zeta(x)' + with raises(NotImplementedError): + octave_code(zeta(x, y)) + + +def test_automatic_rewrite(): + assert octave_code(Li(x)) == '(logint(x) - logint(2))' + assert octave_code(erf2(x, y)) == '(-erf(x) + erf(y))' diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_precedence.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_precedence.py new file mode 100644 index 0000000000000000000000000000000000000000..d08ea07483857e8c2ee7f930aa53d2dacdc58193 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_precedence.py @@ -0,0 +1,128 @@ +from sympy.concrete.products import Product +from sympy.concrete.summations import Sum +from sympy.core.function import Derivative, Function +from sympy.core.numbers import Integer, Rational, Float, oo +from sympy.core.relational import Rel +from sympy.core.symbol import symbols +from sympy.functions import sin +from sympy.integrals.integrals import Integral +from sympy.series.order import Order + +from sympy.printing.precedence import precedence, PRECEDENCE + +x, y = symbols("x,y") + + +def test_Add(): + assert precedence(x + y) == PRECEDENCE["Add"] + assert precedence(x*y + 1) == PRECEDENCE["Add"] + + +def test_Function(): + assert precedence(sin(x)) == PRECEDENCE["Func"] + +def test_Derivative(): + assert precedence(Derivative(x, y)) == PRECEDENCE["Atom"] + +def test_Integral(): + assert precedence(Integral(x, y)) == PRECEDENCE["Atom"] + + +def test_Mul(): + assert precedence(x*y) == PRECEDENCE["Mul"] + assert precedence(-x*y) == PRECEDENCE["Add"] + + +def test_Number(): + assert precedence(Integer(0)) == PRECEDENCE["Atom"] + assert precedence(Integer(1)) == PRECEDENCE["Atom"] + assert precedence(Integer(-1)) == PRECEDENCE["Add"] + assert precedence(Integer(10)) == PRECEDENCE["Atom"] + assert precedence(Rational(5, 2)) == PRECEDENCE["Mul"] + assert precedence(Rational(-5, 2)) == PRECEDENCE["Add"] + assert precedence(Float(5)) == PRECEDENCE["Atom"] + assert precedence(Float(-5)) == PRECEDENCE["Add"] + assert precedence(oo) == PRECEDENCE["Atom"] + assert precedence(-oo) == PRECEDENCE["Add"] + + +def test_Order(): + assert precedence(Order(x)) == PRECEDENCE["Atom"] + + +def test_Pow(): + assert precedence(x**y) == PRECEDENCE["Pow"] + assert precedence(-x**y) == PRECEDENCE["Add"] + assert precedence(x**-y) == PRECEDENCE["Pow"] + + +def test_Product(): + assert precedence(Product(x, (x, y, y + 1))) == PRECEDENCE["Atom"] + + +def test_Relational(): + assert precedence(Rel(x + y, y, "<")) == PRECEDENCE["Relational"] + + +def test_Sum(): + assert precedence(Sum(x, (x, y, y + 1))) == PRECEDENCE["Atom"] + + +def test_Symbol(): + assert precedence(x) == PRECEDENCE["Atom"] + + +def test_And_Or(): + # precedence relations between logical operators, ... + assert precedence(x & y) > precedence(x | y) + assert precedence(~y) > precedence(x & y) + # ... and with other operators (cfr. other programming languages) + assert precedence(x + y) > precedence(x | y) + assert precedence(x + y) > precedence(x & y) + assert precedence(x*y) > precedence(x | y) + assert precedence(x*y) > precedence(x & y) + assert precedence(~y) > precedence(x*y) + assert precedence(~y) > precedence(x - y) + # double checks + assert precedence(x & y) == PRECEDENCE["And"] + assert precedence(x | y) == PRECEDENCE["Or"] + assert precedence(~y) == PRECEDENCE["Not"] + + +def test_custom_function_precedence_comparison(): + """ + Test cases for custom functions with different precedence values, + specifically handling: + 1. Functions with precedence < PRECEDENCE["Mul"] (50) + 2. Functions with precedence = Func (70) + + Key distinction: + 1. Lower precedence functions (45) need parentheses: -2*(x F y) + 2. Higher precedence functions (70) don't: -2*x F y + """ + class LowPrecedenceF(Function): + precedence = PRECEDENCE["Mul"] - 5 + def _sympystr(self, printer): + return f"{printer._print(self.args[0])} F {printer._print(self.args[1])}" + + class HighPrecedenceF(Function): + precedence = PRECEDENCE["Func"] + def _sympystr(self, printer): + return f"{printer._print(self.args[0])} F {printer._print(self.args[1])}" + + def test_low_precedence(): + expr1 = 2 * LowPrecedenceF(x, y) + assert str(expr1) == "2*(x F y)" + + expr2 = -2 * LowPrecedenceF(x, y) + assert str(expr2) == "-2*(x F y)" + + def test_high_precedence(): + expr1 = 2 * HighPrecedenceF(x, y) + assert str(expr1) == "2*x F y" + + expr2 = -2 * HighPrecedenceF(x, y) + assert str(expr2) == "-2*x F y" + + test_low_precedence() + test_high_precedence() diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_preview.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_preview.py new file mode 100644 index 0000000000000000000000000000000000000000..91771ceb0466d6b0fee00570426713d02da14872 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_preview.py @@ -0,0 +1,38 @@ +# -*- coding: utf-8 -*- + +from sympy.core.relational import Eq +from sympy.core.symbol import Symbol +from sympy.functions.elementary.piecewise import Piecewise +from sympy.printing.preview import preview + +from io import BytesIO + + +def test_preview(): + x = Symbol('x') + obj = BytesIO() + try: + preview(x, output='png', viewer='BytesIO', outputbuffer=obj) + except RuntimeError: + pass # latex not installed on CI server + + +def test_preview_unicode_symbol(): + # issue 9107 + a = Symbol('α') + obj = BytesIO() + try: + preview(a, output='png', viewer='BytesIO', outputbuffer=obj) + except RuntimeError: + pass # latex not installed on CI server + + +def test_preview_latex_construct_in_expr(): + # see PR 9801 + x = Symbol('x') + pw = Piecewise((1, Eq(x, 0)), (0, True)) + obj = BytesIO() + try: + preview(pw, output='png', viewer='BytesIO', outputbuffer=obj) + except RuntimeError: + pass # latex not installed on CI server diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_pycode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_pycode.py new file mode 100644 index 0000000000000000000000000000000000000000..2c38fe81d830149cdce6b55f15e6e07513fdd146 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_pycode.py @@ -0,0 +1,493 @@ +from sympy import Not +from sympy.codegen import Assignment +from sympy.codegen.ast import none +from sympy.codegen.cfunctions import expm1, log1p +from sympy.codegen.scipy_nodes import cosm1 +from sympy.codegen.matrix_nodes import MatrixSolve +from sympy.core import Expr, Mod, symbols, Eq, Le, Gt, zoo, oo, Rational, Pow +from sympy.core.function import Derivative +from sympy.core.numbers import pi +from sympy.core.singleton import S +from sympy.functions import acos, KroneckerDelta, Piecewise, sign, sqrt, Min, Max, cot, acsch, asec, coth, sec, log, sin, cos, tan, asin, atan, sinh, cosh, tanh, asinh, acosh, atanh +from sympy.functions.elementary.trigonometric import atan2 +from sympy.logic import And, Or +from sympy.matrices import SparseMatrix, MatrixSymbol, Identity +from sympy.printing.codeprinter import PrintMethodNotImplementedError +from sympy.printing.pycode import ( + MpmathPrinter, CmathPrinter, PythonCodePrinter, pycode, SymPyPrinter +) +from sympy.printing.tensorflow import TensorflowPrinter +from sympy.printing.numpy import NumPyPrinter, SciPyPrinter +from sympy.testing.pytest import raises, skip +from sympy.tensor import IndexedBase, Idx +from sympy.tensor.array.expressions.array_expressions import ArraySymbol, ArrayDiagonal, ArrayContraction, ZeroArray, OneArray +from sympy.external import import_module +from sympy.functions.special.gamma_functions import loggamma + + + +x, y, z = symbols('x y z') +p = IndexedBase("p") + + +def test_PythonCodePrinter(): + prntr = PythonCodePrinter() + + assert not prntr.module_imports + + assert prntr.doprint(x**y) == 'x**y' + assert prntr.doprint(Mod(x, 2)) == 'x % 2' + assert prntr.doprint(-Mod(x, y)) == '-(x % y)' + assert prntr.doprint(Mod(-x, y)) == '(-x) % y' + assert prntr.doprint(And(x, y)) == 'x and y' + assert prntr.doprint(Or(x, y)) == 'x or y' + assert prntr.doprint(1/(x+y)) == '1/(x + y)' + assert prntr.doprint(Not(x)) == 'not x' + assert not prntr.module_imports + + assert prntr.doprint(pi) == 'math.pi' + assert prntr.module_imports == {'math': {'pi'}} + + assert prntr.doprint(x**Rational(1, 2)) == 'math.sqrt(x)' + assert prntr.doprint(sqrt(x)) == 'math.sqrt(x)' + assert prntr.module_imports == {'math': {'pi', 'sqrt'}} + + assert prntr.doprint(acos(x)) == 'math.acos(x)' + assert prntr.doprint(cot(x)) == '(1/math.tan(x))' + assert prntr.doprint(coth(x)) == '((math.exp(x) + math.exp(-x))/(math.exp(x) - math.exp(-x)))' + assert prntr.doprint(asec(x)) == '(math.acos(1/x))' + assert prntr.doprint(acsch(x)) == '(math.log(math.sqrt(1 + x**(-2)) + 1/x))' + + assert prntr.doprint(Assignment(x, 2)) == 'x = 2' + assert prntr.doprint(Piecewise((1, Eq(x, 0)), + (2, x>6))) == '((1) if (x == 0) else (2) if (x > 6) else None)' + assert prntr.doprint(Piecewise((2, Le(x, 0)), + (3, Gt(x, 0)), evaluate=False)) == '((2) if (x <= 0) else'\ + ' (3) if (x > 0) else None)' + assert prntr.doprint(sign(x)) == '(0.0 if x == 0 else math.copysign(1, x))' + assert prntr.doprint(p[0, 1]) == 'p[0, 1]' + assert prntr.doprint(KroneckerDelta(x,y)) == '(1 if x == y else 0)' + + assert prntr.doprint((2,3)) == "(2, 3)" + assert prntr.doprint([2,3]) == "[2, 3]" + + assert prntr.doprint(Min(x, y)) == "min(x, y)" + assert prntr.doprint(Max(x, y)) == "max(x, y)" + + +def test_PythonCodePrinter_standard(): + prntr = PythonCodePrinter() + + assert prntr.standard == 'python3' + + raises(ValueError, lambda: PythonCodePrinter({'standard':'python4'})) + + +def test_CmathPrinter(): + p = CmathPrinter() + + assert p.doprint(sqrt(x)) == 'cmath.sqrt(x)' + assert p.doprint(log(x)) == 'cmath.log(x)' + + assert p.doprint(sin(x)) == 'cmath.sin(x)' + assert p.doprint(cos(x)) == 'cmath.cos(x)' + assert p.doprint(tan(x)) == 'cmath.tan(x)' + + assert p.doprint(asin(x)) == 'cmath.asin(x)' + assert p.doprint(acos(x)) == 'cmath.acos(x)' + assert p.doprint(atan(x)) == 'cmath.atan(x)' + + assert p.doprint(sinh(x)) == 'cmath.sinh(x)' + assert p.doprint(cosh(x)) == 'cmath.cosh(x)' + assert p.doprint(tanh(x)) == 'cmath.tanh(x)' + + assert p.doprint(asinh(x)) == 'cmath.asinh(x)' + assert p.doprint(acosh(x)) == 'cmath.acosh(x)' + assert p.doprint(atanh(x)) == 'cmath.atanh(x)' + + +def test_MpmathPrinter(): + p = MpmathPrinter() + assert p.doprint(sign(x)) == 'mpmath.sign(x)' + assert p.doprint(Rational(1, 2)) == 'mpmath.mpf(1)/mpmath.mpf(2)' + + assert p.doprint(S.Exp1) == 'mpmath.e' + assert p.doprint(S.Pi) == 'mpmath.pi' + assert p.doprint(S.GoldenRatio) == 'mpmath.phi' + assert p.doprint(S.EulerGamma) == 'mpmath.euler' + assert p.doprint(S.NaN) == 'mpmath.nan' + assert p.doprint(S.Infinity) == 'mpmath.inf' + assert p.doprint(S.NegativeInfinity) == 'mpmath.ninf' + assert p.doprint(loggamma(x)) == 'mpmath.loggamma(x)' + + +def test_NumPyPrinter(): + from sympy.core.function import Lambda + from sympy.matrices.expressions.adjoint import Adjoint + from sympy.matrices.expressions.diagonal import (DiagMatrix, DiagonalMatrix, DiagonalOf) + from sympy.matrices.expressions.funcmatrix import FunctionMatrix + from sympy.matrices.expressions.hadamard import HadamardProduct + from sympy.matrices.expressions.kronecker import KroneckerProduct + from sympy.matrices.expressions.special import (OneMatrix, ZeroMatrix) + from sympy.abc import a, b + p = NumPyPrinter() + assert p.doprint(sign(x)) == 'numpy.sign(x)' + A = MatrixSymbol("A", 2, 2) + B = MatrixSymbol("B", 2, 2) + C = MatrixSymbol("C", 1, 5) + D = MatrixSymbol("D", 3, 4) + assert p.doprint(A**(-1)) == "numpy.linalg.inv(A)" + assert p.doprint(A**5) == "numpy.linalg.matrix_power(A, 5)" + assert p.doprint(Identity(3)) == "numpy.eye(3)" + + u = MatrixSymbol('x', 2, 1) + v = MatrixSymbol('y', 2, 1) + assert p.doprint(MatrixSolve(A, u)) == 'numpy.linalg.solve(A, x)' + assert p.doprint(MatrixSolve(A, u) + v) == 'numpy.linalg.solve(A, x) + y' + + assert p.doprint(ZeroMatrix(2, 3)) == "numpy.zeros((2, 3))" + assert p.doprint(OneMatrix(2, 3)) == "numpy.ones((2, 3))" + assert p.doprint(FunctionMatrix(4, 5, Lambda((a, b), a + b))) == \ + "numpy.fromfunction(lambda a, b: a + b, (4, 5))" + assert p.doprint(HadamardProduct(A, B)) == "numpy.multiply(A, B)" + assert p.doprint(KroneckerProduct(A, B)) == "numpy.kron(A, B)" + assert p.doprint(Adjoint(A)) == "numpy.conjugate(numpy.transpose(A))" + assert p.doprint(DiagonalOf(A)) == "numpy.reshape(numpy.diag(A), (-1, 1))" + assert p.doprint(DiagMatrix(C)) == "numpy.diagflat(C)" + assert p.doprint(DiagonalMatrix(D)) == "numpy.multiply(D, numpy.eye(3, 4))" + + # Workaround for numpy negative integer power errors + assert p.doprint(x**-1) == 'x**(-1.0)' + assert p.doprint(x**-2) == 'x**(-2.0)' + + expr = Pow(2, -1, evaluate=False) + assert p.doprint(expr) == "2**(-1.0)" + + assert p.doprint(S.Exp1) == 'numpy.e' + assert p.doprint(S.Pi) == 'numpy.pi' + assert p.doprint(S.EulerGamma) == 'numpy.euler_gamma' + assert p.doprint(S.NaN) == 'numpy.nan' + assert p.doprint(S.Infinity) == 'numpy.inf' + assert p.doprint(S.NegativeInfinity) == '-numpy.inf' + + # Function rewriting operator precedence fix + assert p.doprint(sec(x)**2) == '(numpy.cos(x)**(-1.0))**2' + + +def test_issue_18770(): + numpy = import_module('numpy') + if not numpy: + skip("numpy not installed.") + + from sympy.functions.elementary.miscellaneous import (Max, Min) + from sympy.utilities.lambdify import lambdify + + expr1 = Min(0.1*x + 3, x + 1, 0.5*x + 1) + func = lambdify(x, expr1, "numpy") + assert (func(numpy.linspace(0, 3, 3)) == [1.0, 1.75, 2.5 ]).all() + assert func(4) == 3 + + expr1 = Max(x**2, x**3) + func = lambdify(x,expr1, "numpy") + assert (func(numpy.linspace(-1, 2, 4)) == [1, 0, 1, 8] ).all() + assert func(4) == 64 + + +def test_SciPyPrinter(): + p = SciPyPrinter() + expr = acos(x) + assert 'numpy' not in p.module_imports + assert p.doprint(expr) == 'numpy.arccos(x)' + assert 'numpy' in p.module_imports + assert not any(m.startswith('scipy') for m in p.module_imports) + smat = SparseMatrix(2, 5, {(0, 1): 3}) + assert p.doprint(smat) == \ + 'scipy.sparse.coo_matrix(([3], ([0], [1])), shape=(2, 5))' + assert 'scipy.sparse' in p.module_imports + + assert p.doprint(S.GoldenRatio) == 'scipy.constants.golden_ratio' + assert p.doprint(S.Pi) == 'scipy.constants.pi' + assert p.doprint(S.Exp1) == 'numpy.e' + + +def test_pycode_reserved_words(): + s1, s2 = symbols('if else') + raises(ValueError, lambda: pycode(s1 + s2, error_on_reserved=True)) + py_str = pycode(s1 + s2) + assert py_str in ('else_ + if_', 'if_ + else_') + + +def test_issue_20762(): + # Make sure pycode removes curly braces from subscripted variables + a_b, b, a_11 = symbols('a_{b} b a_{11}') + expr = a_b*b + assert pycode(expr) == 'a_b*b' + expr = a_11*b + assert pycode(expr) == 'a_11*b' + + +def test_sqrt(): + prntr = PythonCodePrinter() + assert prntr._print_Pow(sqrt(x), rational=False) == 'math.sqrt(x)' + assert prntr._print_Pow(1/sqrt(x), rational=False) == '1/math.sqrt(x)' + + prntr = PythonCodePrinter({'standard' : 'python3'}) + assert prntr._print_Pow(sqrt(x), rational=True) == 'x**(1/2)' + assert prntr._print_Pow(1/sqrt(x), rational=True) == 'x**(-1/2)' + + prntr = MpmathPrinter() + assert prntr._print_Pow(sqrt(x), rational=False) == 'mpmath.sqrt(x)' + assert prntr._print_Pow(sqrt(x), rational=True) == \ + "x**(mpmath.mpf(1)/mpmath.mpf(2))" + + prntr = NumPyPrinter() + assert prntr._print_Pow(sqrt(x), rational=False) == 'numpy.sqrt(x)' + assert prntr._print_Pow(sqrt(x), rational=True) == 'x**(1/2)' + + prntr = SciPyPrinter() + assert prntr._print_Pow(sqrt(x), rational=False) == 'numpy.sqrt(x)' + assert prntr._print_Pow(sqrt(x), rational=True) == 'x**(1/2)' + + prntr = SymPyPrinter() + assert prntr._print_Pow(sqrt(x), rational=False) == 'sympy.sqrt(x)' + assert prntr._print_Pow(sqrt(x), rational=True) == 'x**(1/2)' + + +def test_frac(): + from sympy.functions.elementary.integers import frac + + expr = frac(x) + prntr = NumPyPrinter() + assert prntr.doprint(expr) == 'numpy.mod(x, 1)' + + prntr = SciPyPrinter() + assert prntr.doprint(expr) == 'numpy.mod(x, 1)' + + prntr = PythonCodePrinter() + assert prntr.doprint(expr) == 'x % 1' + + prntr = MpmathPrinter() + assert prntr.doprint(expr) == 'mpmath.frac(x)' + + prntr = SymPyPrinter() + assert prntr.doprint(expr) == 'sympy.functions.elementary.integers.frac(x)' + + +class CustomPrintedObject(Expr): + def _numpycode(self, printer): + return 'numpy' + + def _mpmathcode(self, printer): + return 'mpmath' + + +def test_printmethod(): + obj = CustomPrintedObject() + assert NumPyPrinter().doprint(obj) == 'numpy' + assert MpmathPrinter().doprint(obj) == 'mpmath' + + +def test_codegen_ast_nodes(): + assert pycode(none) == 'None' + + +def test_issue_14283(): + prntr = PythonCodePrinter() + + assert prntr.doprint(zoo) == "math.nan" + assert prntr.doprint(-oo) == "float('-inf')" + + +def test_NumPyPrinter_print_seq(): + n = NumPyPrinter() + + assert n._print_seq(range(2)) == '(0, 1,)' + + +def test_issue_16535_16536(): + from sympy.functions.special.gamma_functions import (lowergamma, uppergamma) + + a = symbols('a') + expr1 = lowergamma(a, x) + expr2 = uppergamma(a, x) + + prntr = SciPyPrinter() + assert prntr.doprint(expr1) == 'scipy.special.gamma(a)*scipy.special.gammainc(a, x)' + assert prntr.doprint(expr2) == 'scipy.special.gamma(a)*scipy.special.gammaincc(a, x)' + + p_numpy = NumPyPrinter() + p_pycode = PythonCodePrinter({'strict': False}) + + for expr in [expr1, expr2]: + with raises(NotImplementedError): + p_numpy.doprint(expr1) + assert "Not supported" in p_pycode.doprint(expr) + + +def test_Integral(): + from sympy.functions.elementary.exponential import exp + from sympy.integrals.integrals import Integral + + single = Integral(exp(-x), (x, 0, oo)) + double = Integral(x**2*exp(x*y), (x, -z, z), (y, 0, z)) + indefinite = Integral(x**2, x) + evaluateat = Integral(x**2, (x, 1)) + + prntr = SciPyPrinter() + assert prntr.doprint(single) == 'scipy.integrate.quad(lambda x: numpy.exp(-x), 0, numpy.inf)[0]' + assert prntr.doprint(double) == 'scipy.integrate.nquad(lambda x, y: x**2*numpy.exp(x*y), ((-z, z), (0, z)))[0]' + raises(NotImplementedError, lambda: prntr.doprint(indefinite)) + raises(NotImplementedError, lambda: prntr.doprint(evaluateat)) + + prntr = MpmathPrinter() + assert prntr.doprint(single) == 'mpmath.quad(lambda x: mpmath.exp(-x), (0, mpmath.inf))' + assert prntr.doprint(double) == 'mpmath.quad(lambda x, y: x**2*mpmath.exp(x*y), (-z, z), (0, z))' + raises(NotImplementedError, lambda: prntr.doprint(indefinite)) + raises(NotImplementedError, lambda: prntr.doprint(evaluateat)) + + +def test_fresnel_integrals(): + from sympy.functions.special.error_functions import (fresnelc, fresnels) + + expr1 = fresnelc(x) + expr2 = fresnels(x) + + prntr = SciPyPrinter() + assert prntr.doprint(expr1) == 'scipy.special.fresnel(x)[1]' + assert prntr.doprint(expr2) == 'scipy.special.fresnel(x)[0]' + + p_numpy = NumPyPrinter() + p_pycode = PythonCodePrinter() + p_mpmath = MpmathPrinter() + for expr in [expr1, expr2]: + with raises(NotImplementedError): + p_numpy.doprint(expr) + with raises(NotImplementedError): + p_pycode.doprint(expr) + + assert p_mpmath.doprint(expr1) == 'mpmath.fresnelc(x)' + assert p_mpmath.doprint(expr2) == 'mpmath.fresnels(x)' + + +def test_beta(): + from sympy.functions.special.beta_functions import beta + + expr = beta(x, y) + + prntr = SciPyPrinter() + assert prntr.doprint(expr) == 'scipy.special.beta(x, y)' + + prntr = NumPyPrinter() + assert prntr.doprint(expr) == '(math.gamma(x)*math.gamma(y)/math.gamma(x + y))' + + prntr = PythonCodePrinter() + assert prntr.doprint(expr) == '(math.gamma(x)*math.gamma(y)/math.gamma(x + y))' + + prntr = PythonCodePrinter({'allow_unknown_functions': True}) + assert prntr.doprint(expr) == '(math.gamma(x)*math.gamma(y)/math.gamma(x + y))' + + prntr = MpmathPrinter() + assert prntr.doprint(expr) == 'mpmath.beta(x, y)' + +def test_airy(): + from sympy.functions.special.bessel import (airyai, airybi) + + expr1 = airyai(x) + expr2 = airybi(x) + + prntr = SciPyPrinter() + assert prntr.doprint(expr1) == 'scipy.special.airy(x)[0]' + assert prntr.doprint(expr2) == 'scipy.special.airy(x)[2]' + + prntr = NumPyPrinter({'strict': False}) + assert "Not supported" in prntr.doprint(expr1) + assert "Not supported" in prntr.doprint(expr2) + + prntr = PythonCodePrinter({'strict': False}) + assert "Not supported" in prntr.doprint(expr1) + assert "Not supported" in prntr.doprint(expr2) + +def test_airy_prime(): + from sympy.functions.special.bessel import (airyaiprime, airybiprime) + + expr1 = airyaiprime(x) + expr2 = airybiprime(x) + + prntr = SciPyPrinter() + assert prntr.doprint(expr1) == 'scipy.special.airy(x)[1]' + assert prntr.doprint(expr2) == 'scipy.special.airy(x)[3]' + + prntr = NumPyPrinter({'strict': False}) + assert "Not supported" in prntr.doprint(expr1) + assert "Not supported" in prntr.doprint(expr2) + + prntr = PythonCodePrinter({'strict': False}) + assert "Not supported" in prntr.doprint(expr1) + assert "Not supported" in prntr.doprint(expr2) + + +def test_numerical_accuracy_functions(): + prntr = SciPyPrinter() + assert prntr.doprint(expm1(x)) == 'numpy.expm1(x)' + assert prntr.doprint(log1p(x)) == 'numpy.log1p(x)' + assert prntr.doprint(cosm1(x)) == 'scipy.special.cosm1(x)' + +def test_array_printer(): + A = ArraySymbol('A', (4,4,6,6,6)) + I = IndexedBase('I') + i,j,k = Idx('i', (0,1)), Idx('j', (2,3)), Idx('k', (4,5)) + + prntr = NumPyPrinter() + assert prntr.doprint(ZeroArray(5)) == 'numpy.zeros((5,))' + assert prntr.doprint(OneArray(5)) == 'numpy.ones((5,))' + assert prntr.doprint(ArrayContraction(A, [2,3])) == 'numpy.einsum("abccd->abd", A)' + assert prntr.doprint(I) == 'I' + assert prntr.doprint(ArrayDiagonal(A, [2,3,4])) == 'numpy.einsum("abccc->abc", A)' + assert prntr.doprint(ArrayDiagonal(A, [0,1], [2,3])) == 'numpy.einsum("aabbc->cab", A)' + assert prntr.doprint(ArrayContraction(A, [2], [3])) == 'numpy.einsum("abcde->abe", A)' + assert prntr.doprint(Assignment(I[i,j,k], I[i,j,k])) == 'I = I' + + prntr = TensorflowPrinter() + assert prntr.doprint(ZeroArray(5)) == 'tensorflow.zeros((5,))' + assert prntr.doprint(OneArray(5)) == 'tensorflow.ones((5,))' + assert prntr.doprint(ArrayContraction(A, [2,3])) == 'tensorflow.linalg.einsum("abccd->abd", A)' + assert prntr.doprint(I) == 'I' + assert prntr.doprint(ArrayDiagonal(A, [2,3,4])) == 'tensorflow.linalg.einsum("abccc->abc", A)' + assert prntr.doprint(ArrayDiagonal(A, [0,1], [2,3])) == 'tensorflow.linalg.einsum("aabbc->cab", A)' + assert prntr.doprint(ArrayContraction(A, [2], [3])) == 'tensorflow.linalg.einsum("abcde->abe", A)' + assert prntr.doprint(Assignment(I[i,j,k], I[i,j,k])) == 'I = I' + + +def test_custom_Derivative_methods(): + class MyPrinter(SciPyPrinter): + def _print_Derivative_cosm1(self, args, seq_orders): + arg, = args + order, = seq_orders + return 'my_custom_cosm1(%s, deriv_order=%d)' % (self._print(arg), order) + + def _print_Derivative_atan2(self, args, seq_orders): + arg1, arg2 = args + ord1, ord2 = seq_orders + return 'my_custom_atan2(%s, %s, deriv1=%d, deriv2=%d)' % ( + self._print(arg1), self._print(arg2), ord1, ord2 + ) + + p = MyPrinter() + cosm1_1 = cosm1(x).diff(x, evaluate=False) + assert p.doprint(cosm1_1) == 'my_custom_cosm1(x, deriv_order=1)' + atan2_2_3 = atan2(x, y).diff(x, 2, y, 3, evaluate=False) + assert p.doprint(atan2_2_3) == 'my_custom_atan2(x, y, deriv1=2, deriv2=3)' + + try: + p.doprint(expm1(x).diff(x, evaluate=False)) + except PrintMethodNotImplementedError as e: + assert '_print_Derivative_expm1' in repr(e) + else: + assert False # should have thrown + + try: + p.doprint(Derivative(cosm1(x**2),x)) + except ValueError as e: + assert '_print_Derivative(' in repr(e) + else: + assert False # should have thrown diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_python.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_python.py new file mode 100644 index 0000000000000000000000000000000000000000..fb94a662be90934a672d08b3de44a22e2580d8b6 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_python.py @@ -0,0 +1,203 @@ +from sympy.core.function import (Derivative, Function) +from sympy.core.numbers import (I, Rational, oo, pi) +from sympy.core.relational import (Eq, Ge, Gt, Le, Lt, Ne) +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.elementary.complexes import (Abs, conjugate) +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import sin +from sympy.integrals.integrals import Integral +from sympy.matrices.dense import Matrix +from sympy.series.limits import limit + +from sympy.printing.python import python + +from sympy.testing.pytest import raises, XFAIL + +x, y = symbols('x,y') +th = Symbol('theta') +ph = Symbol('phi') + + +def test_python_basic(): + # Simple numbers/symbols + assert python(-Rational(1)/2) == "e = Rational(-1, 2)" + assert python(-Rational(13)/22) == "e = Rational(-13, 22)" + assert python(oo) == "e = oo" + + # Powers + assert python(x**2) == "x = Symbol(\'x\')\ne = x**2" + assert python(1/x) == "x = Symbol('x')\ne = 1/x" + assert python(y*x**-2) == "y = Symbol('y')\nx = Symbol('x')\ne = y/x**2" + assert python( + x**Rational(-5, 2)) == "x = Symbol('x')\ne = x**Rational(-5, 2)" + + # Sums of terms + assert python(x**2 + x + 1) in [ + "x = Symbol('x')\ne = 1 + x + x**2", + "x = Symbol('x')\ne = x + x**2 + 1", + "x = Symbol('x')\ne = x**2 + x + 1", ] + assert python(1 - x) in [ + "x = Symbol('x')\ne = 1 - x", + "x = Symbol('x')\ne = -x + 1"] + assert python(1 - 2*x) in [ + "x = Symbol('x')\ne = 1 - 2*x", + "x = Symbol('x')\ne = -2*x + 1"] + assert python(1 - Rational(3, 2)*y/x) in [ + "y = Symbol('y')\nx = Symbol('x')\ne = 1 - 3/2*y/x", + "y = Symbol('y')\nx = Symbol('x')\ne = -3/2*y/x + 1", + "y = Symbol('y')\nx = Symbol('x')\ne = 1 - 3*y/(2*x)"] + + # Multiplication + assert python(x/y) == "x = Symbol('x')\ny = Symbol('y')\ne = x/y" + assert python(-x/y) == "x = Symbol('x')\ny = Symbol('y')\ne = -x/y" + assert python((x + 2)/y) in [ + "y = Symbol('y')\nx = Symbol('x')\ne = 1/y*(2 + x)", + "y = Symbol('y')\nx = Symbol('x')\ne = 1/y*(x + 2)", + "x = Symbol('x')\ny = Symbol('y')\ne = 1/y*(2 + x)", + "x = Symbol('x')\ny = Symbol('y')\ne = (2 + x)/y", + "x = Symbol('x')\ny = Symbol('y')\ne = (x + 2)/y"] + assert python((1 + x)*y) in [ + "y = Symbol('y')\nx = Symbol('x')\ne = y*(1 + x)", + "y = Symbol('y')\nx = Symbol('x')\ne = y*(x + 1)", ] + + # Check for proper placement of negative sign + assert python(-5*x/(x + 10)) == "x = Symbol('x')\ne = -5*x/(x + 10)" + assert python(1 - Rational(3, 2)*(x + 1)) in [ + "x = Symbol('x')\ne = Rational(-3, 2)*x + Rational(-1, 2)", + "x = Symbol('x')\ne = -3*x/2 + Rational(-1, 2)", + "x = Symbol('x')\ne = -3*x/2 + Rational(-1, 2)" + ] + + +def test_python_keyword_symbol_name_escaping(): + # Check for escaping of keywords + assert python( + 5*Symbol("lambda")) == "lambda_ = Symbol('lambda')\ne = 5*lambda_" + assert (python(5*Symbol("lambda") + 7*Symbol("lambda_")) == + "lambda__ = Symbol('lambda')\nlambda_ = Symbol('lambda_')\ne = 7*lambda_ + 5*lambda__") + assert (python(5*Symbol("for") + Function("for_")(8)) == + "for__ = Symbol('for')\nfor_ = Function('for_')\ne = 5*for__ + for_(8)") + + +def test_python_keyword_function_name_escaping(): + assert python( + 5*Function("for")(8)) == "for_ = Function('for')\ne = 5*for_(8)" + + +def test_python_relational(): + assert python(Eq(x, y)) == "x = Symbol('x')\ny = Symbol('y')\ne = Eq(x, y)" + assert python(Ge(x, y)) == "x = Symbol('x')\ny = Symbol('y')\ne = x >= y" + assert python(Le(x, y)) == "x = Symbol('x')\ny = Symbol('y')\ne = x <= y" + assert python(Gt(x, y)) == "x = Symbol('x')\ny = Symbol('y')\ne = x > y" + assert python(Lt(x, y)) == "x = Symbol('x')\ny = Symbol('y')\ne = x < y" + assert python(Ne(x/(y + 1), y**2)) in [ + "x = Symbol('x')\ny = Symbol('y')\ne = Ne(x/(1 + y), y**2)", + "x = Symbol('x')\ny = Symbol('y')\ne = Ne(x/(y + 1), y**2)"] + + +def test_python_functions(): + # Simple + assert python(2*x + exp(x)) in "x = Symbol('x')\ne = 2*x + exp(x)" + assert python(sqrt(2)) == 'e = sqrt(2)' + assert python(2**Rational(1, 3)) == 'e = 2**Rational(1, 3)' + assert python(sqrt(2 + pi)) == 'e = sqrt(2 + pi)' + assert python((2 + pi)**Rational(1, 3)) == 'e = (2 + pi)**Rational(1, 3)' + assert python(2**Rational(1, 4)) == 'e = 2**Rational(1, 4)' + assert python(Abs(x)) == "x = Symbol('x')\ne = Abs(x)" + assert python( + Abs(x/(x**2 + 1))) in ["x = Symbol('x')\ne = Abs(x/(1 + x**2))", + "x = Symbol('x')\ne = Abs(x/(x**2 + 1))"] + + # Univariate/Multivariate functions + f = Function('f') + assert python(f(x)) == "x = Symbol('x')\nf = Function('f')\ne = f(x)" + assert python(f(x, y)) == "x = Symbol('x')\ny = Symbol('y')\nf = Function('f')\ne = f(x, y)" + assert python(f(x/(y + 1), y)) in [ + "x = Symbol('x')\ny = Symbol('y')\nf = Function('f')\ne = f(x/(1 + y), y)", + "x = Symbol('x')\ny = Symbol('y')\nf = Function('f')\ne = f(x/(y + 1), y)"] + + # Nesting of square roots + assert python(sqrt((sqrt(x + 1)) + 1)) in [ + "x = Symbol('x')\ne = sqrt(1 + sqrt(1 + x))", + "x = Symbol('x')\ne = sqrt(sqrt(x + 1) + 1)"] + + # Nesting of powers + assert python((((x + 1)**Rational(1, 3)) + 1)**Rational(1, 3)) in [ + "x = Symbol('x')\ne = (1 + (1 + x)**Rational(1, 3))**Rational(1, 3)", + "x = Symbol('x')\ne = ((x + 1)**Rational(1, 3) + 1)**Rational(1, 3)"] + + # Function powers + assert python(sin(x)**2) == "x = Symbol('x')\ne = sin(x)**2" + + +@XFAIL +def test_python_functions_conjugates(): + a, b = map(Symbol, 'ab') + assert python( conjugate(a + b*I) ) == '_ _\na - I*b' + assert python( conjugate(exp(a + b*I)) ) == ' _ _\n a - I*b\ne ' + + +def test_python_derivatives(): + # Simple + f_1 = Derivative(log(x), x, evaluate=False) + assert python(f_1) == "x = Symbol('x')\ne = Derivative(log(x), x)" + + f_2 = Derivative(log(x), x, evaluate=False) + x + assert python(f_2) == "x = Symbol('x')\ne = x + Derivative(log(x), x)" + + # Multiple symbols + f_3 = Derivative(log(x) + x**2, x, y, evaluate=False) + assert python(f_3) == \ + "x = Symbol('x')\ny = Symbol('y')\ne = Derivative(x**2 + log(x), x, y)" + + f_4 = Derivative(2*x*y, y, x, evaluate=False) + x**2 + assert python(f_4) in [ + "x = Symbol('x')\ny = Symbol('y')\ne = x**2 + Derivative(2*x*y, y, x)", + "x = Symbol('x')\ny = Symbol('y')\ne = Derivative(2*x*y, y, x) + x**2"] + + +def test_python_integrals(): + # Simple + f_1 = Integral(log(x), x) + assert python(f_1) == "x = Symbol('x')\ne = Integral(log(x), x)" + + f_2 = Integral(x**2, x) + assert python(f_2) == "x = Symbol('x')\ne = Integral(x**2, x)" + + # Double nesting of pow + f_3 = Integral(x**(2**x), x) + assert python(f_3) == "x = Symbol('x')\ne = Integral(x**(2**x), x)" + + # Definite integrals + f_4 = Integral(x**2, (x, 1, 2)) + assert python(f_4) == "x = Symbol('x')\ne = Integral(x**2, (x, 1, 2))" + + f_5 = Integral(x**2, (x, Rational(1, 2), 10)) + assert python( + f_5) == "x = Symbol('x')\ne = Integral(x**2, (x, Rational(1, 2), 10))" + + # Nested integrals + f_6 = Integral(x**2*y**2, x, y) + assert python(f_6) == "x = Symbol('x')\ny = Symbol('y')\ne = Integral(x**2*y**2, x, y)" + + +def test_python_matrix(): + p = python(Matrix([[x**2+1, 1], [y, x+y]])) + s = "x = Symbol('x')\ny = Symbol('y')\ne = MutableDenseMatrix([[x**2 + 1, 1], [y, x + y]])" + assert p == s + +def test_python_limits(): + assert python(limit(x, x, oo)) == 'e = oo' + assert python(limit(x**2, x, 0)) == 'e = 0' + +def test_issue_20762(): + # Make sure Python removes curly braces from subscripted variables + a_b = Symbol('a_{b}') + b = Symbol('b') + expr = a_b*b + assert python(expr) == "a_b = Symbol('a_{b}')\nb = Symbol('b')\ne = a_b*b" + + +def test_settings(): + raises(TypeError, lambda: python(x, method="garbage")) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_rcode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_rcode.py new file mode 100644 index 0000000000000000000000000000000000000000..a83235b0654c6bf24c30846dbf68678d29cd3c80 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_rcode.py @@ -0,0 +1,476 @@ +from sympy.core import (S, pi, oo, Symbol, symbols, Rational, Integer, + GoldenRatio, EulerGamma, Catalan, Lambda, Dummy) +from sympy.functions import (Piecewise, sin, cos, Abs, exp, ceiling, sqrt, + gamma, sign, Max, Min, factorial, beta) +from sympy.core.relational import (Eq, Ge, Gt, Le, Lt, Ne) +from sympy.sets import Range +from sympy.logic import ITE +from sympy.codegen import For, aug_assign, Assignment +from sympy.testing.pytest import raises +from sympy.printing.rcode import RCodePrinter +from sympy.utilities.lambdify import implemented_function +from sympy.tensor import IndexedBase, Idx +from sympy.matrices import Matrix, MatrixSymbol + +from sympy.printing.rcode import rcode + +x, y, z = symbols('x,y,z') + + +def test_printmethod(): + class fabs(Abs): + def _rcode(self, printer): + return "abs(%s)" % printer._print(self.args[0]) + + assert rcode(fabs(x)) == "abs(x)" + + +def test_rcode_sqrt(): + assert rcode(sqrt(x)) == "sqrt(x)" + assert rcode(x**0.5) == "sqrt(x)" + assert rcode(sqrt(x)) == "sqrt(x)" + + +def test_rcode_Pow(): + assert rcode(x**3) == "x^3" + assert rcode(x**(y**3)) == "x^(y^3)" + g = implemented_function('g', Lambda(x, 2*x)) + assert rcode(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "(3.5*2*x)^(-x + y^x)/(x^2 + y)" + assert rcode(x**-1.0) == '1.0/x' + assert rcode(x**Rational(2, 3)) == 'x^(2.0/3.0)' + _cond_cfunc = [(lambda base, exp: exp.is_integer, "dpowi"), + (lambda base, exp: not exp.is_integer, "pow")] + assert rcode(x**3, user_functions={'Pow': _cond_cfunc}) == 'dpowi(x, 3)' + assert rcode(x**3.2, user_functions={'Pow': _cond_cfunc}) == 'pow(x, 3.2)' + + +def test_rcode_Max(): + # Test for gh-11926 + assert rcode(Max(x,x*x),user_functions={"Max":"my_max", "Pow":"my_pow"}) == 'my_max(x, my_pow(x, 2))' + + +def test_rcode_constants_mathh(): + assert rcode(exp(1)) == "exp(1)" + assert rcode(pi) == "pi" + assert rcode(oo) == "Inf" + assert rcode(-oo) == "-Inf" + + +def test_rcode_constants_other(): + assert rcode(2*GoldenRatio) == "GoldenRatio = 1.61803398874989;\n2*GoldenRatio" + assert rcode( + 2*Catalan) == "Catalan = 0.915965594177219;\n2*Catalan" + assert rcode(2*EulerGamma) == "EulerGamma = 0.577215664901533;\n2*EulerGamma" + + +def test_rcode_Rational(): + assert rcode(Rational(3, 7)) == "3.0/7.0" + assert rcode(Rational(18, 9)) == "2" + assert rcode(Rational(3, -7)) == "-3.0/7.0" + assert rcode(Rational(-3, -7)) == "3.0/7.0" + assert rcode(x + Rational(3, 7)) == "x + 3.0/7.0" + assert rcode(Rational(3, 7)*x) == "(3.0/7.0)*x" + + +def test_rcode_Integer(): + assert rcode(Integer(67)) == "67" + assert rcode(Integer(-1)) == "-1" + + +def test_rcode_functions(): + assert rcode(sin(x) ** cos(x)) == "sin(x)^cos(x)" + assert rcode(factorial(x) + gamma(y)) == "factorial(x) + gamma(y)" + assert rcode(beta(Min(x, y), Max(x, y))) == "beta(min(x, y), max(x, y))" + + +def test_rcode_inline_function(): + x = symbols('x') + g = implemented_function('g', Lambda(x, 2*x)) + assert rcode(g(x)) == "2*x" + g = implemented_function('g', Lambda(x, 2*x/Catalan)) + assert rcode( + g(x)) == "Catalan = %s;\n2*x/Catalan" % Catalan.n() + A = IndexedBase('A') + i = Idx('i', symbols('n', integer=True)) + g = implemented_function('g', Lambda(x, x*(1 + x)*(2 + x))) + res=rcode(g(A[i]), assign_to=A[i]) + ref=( + "for (i in 1:n){\n" + " A[i] = (A[i] + 1)*(A[i] + 2)*A[i];\n" + "}" + ) + assert res == ref + + +def test_rcode_exceptions(): + assert rcode(ceiling(x)) == "ceiling(x)" + assert rcode(Abs(x)) == "abs(x)" + assert rcode(gamma(x)) == "gamma(x)" + + +def test_rcode_user_functions(): + x = symbols('x', integer=False) + n = symbols('n', integer=True) + custom_functions = { + "ceiling": "myceil", + "Abs": [(lambda x: not x.is_integer, "fabs"), (lambda x: x.is_integer, "abs")], + } + assert rcode(ceiling(x), user_functions=custom_functions) == "myceil(x)" + assert rcode(Abs(x), user_functions=custom_functions) == "fabs(x)" + assert rcode(Abs(n), user_functions=custom_functions) == "abs(n)" + + +def test_rcode_boolean(): + assert rcode(True) == "True" + assert rcode(S.true) == "True" + assert rcode(False) == "False" + assert rcode(S.false) == "False" + assert rcode(x & y) == "x & y" + assert rcode(x | y) == "x | y" + assert rcode(~x) == "!x" + assert rcode(x & y & z) == "x & y & z" + assert rcode(x | y | z) == "x | y | z" + assert rcode((x & y) | z) == "z | x & y" + assert rcode((x | y) & z) == "z & (x | y)" + +def test_rcode_Relational(): + assert rcode(Eq(x, y)) == "x == y" + assert rcode(Ne(x, y)) == "x != y" + assert rcode(Le(x, y)) == "x <= y" + assert rcode(Lt(x, y)) == "x < y" + assert rcode(Gt(x, y)) == "x > y" + assert rcode(Ge(x, y)) == "x >= y" + + +def test_rcode_Piecewise(): + expr = Piecewise((x, x < 1), (x**2, True)) + res=rcode(expr) + ref="ifelse(x < 1,x,x^2)" + assert res == ref + tau=Symbol("tau") + res=rcode(expr,tau) + ref="tau = ifelse(x < 1,x,x^2);" + assert res == ref + + expr = 2*Piecewise((x, x < 1), (x**2, x<2), (x**3,True)) + assert rcode(expr) == "2*ifelse(x < 1,x,ifelse(x < 2,x^2,x^3))" + res = rcode(expr, assign_to='c') + assert res == "c = 2*ifelse(x < 1,x,ifelse(x < 2,x^2,x^3));" + + # Check that Piecewise without a True (default) condition error + #expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) + #raises(ValueError, lambda: rcode(expr)) + expr = 2*Piecewise((x, x < 1), (x**2, x<2)) + assert(rcode(expr))== "2*ifelse(x < 1,x,ifelse(x < 2,x^2,NA))" + + +def test_rcode_sinc(): + from sympy.functions.elementary.trigonometric import sinc + expr = sinc(x) + res = rcode(expr) + ref = "(ifelse(x != 0,sin(x)/x,1))" + assert res == ref + + +def test_rcode_Piecewise_deep(): + p = rcode(2*Piecewise((x, x < 1), (x + 1, x < 2), (x**2, True))) + assert p == "2*ifelse(x < 1,x,ifelse(x < 2,x + 1,x^2))" + expr = x*y*z + x**2 + y**2 + Piecewise((0, x < 0.5), (1, True)) + cos(z) - 1 + p = rcode(expr) + ref="x^2 + x*y*z + y^2 + ifelse(x < 0.5,0,1) + cos(z) - 1" + assert p == ref + + ref="c = x^2 + x*y*z + y^2 + ifelse(x < 0.5,0,1) + cos(z) - 1;" + p = rcode(expr, assign_to='c') + assert p == ref + + +def test_rcode_ITE(): + expr = ITE(x < 1, y, z) + p = rcode(expr) + ref="ifelse(x < 1,y,z)" + assert p == ref + + +def test_rcode_settings(): + raises(TypeError, lambda: rcode(sin(x), method="garbage")) + + +def test_rcode_Indexed(): + n, m, o = symbols('n m o', integer=True) + i, j, k = Idx('i', n), Idx('j', m), Idx('k', o) + p = RCodePrinter() + p._not_r = set() + + x = IndexedBase('x')[j] + assert p._print_Indexed(x) == 'x[j]' + A = IndexedBase('A')[i, j] + assert p._print_Indexed(A) == 'A[i, j]' + B = IndexedBase('B')[i, j, k] + assert p._print_Indexed(B) == 'B[i, j, k]' + + assert p._not_r == set() + +def test_rcode_Indexed_without_looking_for_contraction(): + len_y = 5 + y = IndexedBase('y', shape=(len_y,)) + x = IndexedBase('x', shape=(len_y,)) + Dy = IndexedBase('Dy', shape=(len_y-1,)) + i = Idx('i', len_y-1) + e=Eq(Dy[i], (y[i+1]-y[i])/(x[i+1]-x[i])) + code0 = rcode(e.rhs, assign_to=e.lhs, contract=False) + assert code0 == 'Dy[i] = (y[%s] - y[i])/(x[%s] - x[i]);' % (i + 1, i + 1) + + +def test_rcode_loops_matrix_vector(): + n, m = symbols('n m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + + s = ( + 'for (i in 1:m){\n' + ' y[i] = 0;\n' + '}\n' + 'for (i in 1:m){\n' + ' for (j in 1:n){\n' + ' y[i] = A[i, j]*x[j] + y[i];\n' + ' }\n' + '}' + ) + c = rcode(A[i, j]*x[j], assign_to=y[i]) + assert c == s + + +def test_dummy_loops(): + # the following line could also be + # [Dummy(s, integer=True) for s in 'im'] + # or [Dummy(integer=True) for s in 'im'] + i, m = symbols('i m', integer=True, cls=Dummy) + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx(i, m) + + expected = ( + 'for (i_%(icount)i in 1:m_%(mcount)i){\n' + ' y[i_%(icount)i] = x[i_%(icount)i];\n' + '}' + ) % {'icount': i.label.dummy_index, 'mcount': m.dummy_index} + code = rcode(x[i], assign_to=y[i]) + assert code == expected + + +def test_rcode_loops_add(): + n, m = symbols('n m', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + z = IndexedBase('z') + i = Idx('i', m) + j = Idx('j', n) + + s = ( + 'for (i in 1:m){\n' + ' y[i] = x[i] + z[i];\n' + '}\n' + 'for (i in 1:m){\n' + ' for (j in 1:n){\n' + ' y[i] = A[i, j]*x[j] + y[i];\n' + ' }\n' + '}' + ) + c = rcode(A[i, j]*x[j] + x[i] + z[i], assign_to=y[i]) + assert c == s + + +def test_rcode_loops_multiple_contractions(): + n, m, o, p = symbols('n m o p', integer=True) + a = IndexedBase('a') + b = IndexedBase('b') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + k = Idx('k', o) + l = Idx('l', p) + + s = ( + 'for (i in 1:m){\n' + ' y[i] = 0;\n' + '}\n' + 'for (i in 1:m){\n' + ' for (j in 1:n){\n' + ' for (k in 1:o){\n' + ' for (l in 1:p){\n' + ' y[i] = a[i, j, k, l]*b[j, k, l] + y[i];\n' + ' }\n' + ' }\n' + ' }\n' + '}' + ) + c = rcode(b[j, k, l]*a[i, j, k, l], assign_to=y[i]) + assert c == s + + +def test_rcode_loops_addfactor(): + n, m, o, p = symbols('n m o p', integer=True) + a = IndexedBase('a') + b = IndexedBase('b') + c = IndexedBase('c') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + k = Idx('k', o) + l = Idx('l', p) + + s = ( + 'for (i in 1:m){\n' + ' y[i] = 0;\n' + '}\n' + 'for (i in 1:m){\n' + ' for (j in 1:n){\n' + ' for (k in 1:o){\n' + ' for (l in 1:p){\n' + ' y[i] = (a[i, j, k, l] + b[i, j, k, l])*c[j, k, l] + y[i];\n' + ' }\n' + ' }\n' + ' }\n' + '}' + ) + c = rcode((a[i, j, k, l] + b[i, j, k, l])*c[j, k, l], assign_to=y[i]) + assert c == s + + +def test_rcode_loops_multiple_terms(): + n, m, o, p = symbols('n m o p', integer=True) + a = IndexedBase('a') + b = IndexedBase('b') + c = IndexedBase('c') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + k = Idx('k', o) + + s0 = ( + 'for (i in 1:m){\n' + ' y[i] = 0;\n' + '}\n' + ) + s1 = ( + 'for (i in 1:m){\n' + ' for (j in 1:n){\n' + ' for (k in 1:o){\n' + ' y[i] = b[j]*b[k]*c[i, j, k] + y[i];\n' + ' }\n' + ' }\n' + '}\n' + ) + s2 = ( + 'for (i in 1:m){\n' + ' for (k in 1:o){\n' + ' y[i] = a[i, k]*b[k] + y[i];\n' + ' }\n' + '}\n' + ) + s3 = ( + 'for (i in 1:m){\n' + ' for (j in 1:n){\n' + ' y[i] = a[i, j]*b[j] + y[i];\n' + ' }\n' + '}\n' + ) + c = rcode( + b[j]*a[i, j] + b[k]*a[i, k] + b[j]*b[k]*c[i, j, k], assign_to=y[i]) + + ref={} + ref[0] = s0 + s1 + s2 + s3[:-1] + ref[1] = s0 + s1 + s3 + s2[:-1] + ref[2] = s0 + s2 + s1 + s3[:-1] + ref[3] = s0 + s2 + s3 + s1[:-1] + ref[4] = s0 + s3 + s1 + s2[:-1] + ref[5] = s0 + s3 + s2 + s1[:-1] + + assert (c == ref[0] or + c == ref[1] or + c == ref[2] or + c == ref[3] or + c == ref[4] or + c == ref[5]) + + +def test_dereference_printing(): + expr = x + y + sin(z) + z + assert rcode(expr, dereference=[z]) == "x + y + (*z) + sin((*z))" + + +def test_Matrix_printing(): + # Test returning a Matrix + mat = Matrix([x*y, Piecewise((2 + x, y>0), (y, True)), sin(z)]) + A = MatrixSymbol('A', 3, 1) + p = rcode(mat, A) + assert p == ( + "A[0] = x*y;\n" + "A[1] = ifelse(y > 0,x + 2,y);\n" + "A[2] = sin(z);") + # Test using MatrixElements in expressions + expr = Piecewise((2*A[2, 0], x > 0), (A[2, 0], True)) + sin(A[1, 0]) + A[0, 0] + p = rcode(expr) + assert p == ("ifelse(x > 0,2*A[2],A[2]) + sin(A[1]) + A[0]") + # Test using MatrixElements in a Matrix + q = MatrixSymbol('q', 5, 1) + M = MatrixSymbol('M', 3, 3) + m = Matrix([[sin(q[1,0]), 0, cos(q[2,0])], + [q[1,0] + q[2,0], q[3, 0], 5], + [2*q[4, 0]/q[1,0], sqrt(q[0,0]) + 4, 0]]) + assert rcode(m, M) == ( + "M[0] = sin(q[1]);\n" + "M[1] = 0;\n" + "M[2] = cos(q[2]);\n" + "M[3] = q[1] + q[2];\n" + "M[4] = q[3];\n" + "M[5] = 5;\n" + "M[6] = 2*q[4]/q[1];\n" + "M[7] = sqrt(q[0]) + 4;\n" + "M[8] = 0;") + + +def test_rcode_sgn(): + + expr = sign(x) * y + assert rcode(expr) == 'y*sign(x)' + p = rcode(expr, 'z') + assert p == 'z = y*sign(x);' + + p = rcode(sign(2 * x + x**2) * x + x**2) + assert p == "x^2 + x*sign(x^2 + 2*x)" + + expr = sign(cos(x)) + p = rcode(expr) + assert p == 'sign(cos(x))' + +def test_rcode_Assignment(): + assert rcode(Assignment(x, y + z)) == 'x = y + z;' + assert rcode(aug_assign(x, '+', y + z)) == 'x += y + z;' + + +def test_rcode_For(): + f = For(x, Range(0, 10, 2), [aug_assign(y, '*', x)]) + sol = rcode(f) + assert sol == ("for(x in seq(from=0, to=9, by=2){\n" + " y *= x;\n" + "}") + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert(rcode(A[0, 0]) == "A[0]") + assert(rcode(3 * A[0, 0]) == "3*A[0]") + + F = C[0, 0].subs(C, A - B) + assert(rcode(F) == "(A - B)[0]") diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_repr.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_repr.py new file mode 100644 index 0000000000000000000000000000000000000000..da58883b4fb027ed82db842a0a1ce5f76a49a8bb --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_repr.py @@ -0,0 +1,382 @@ +from __future__ import annotations +from typing import Any + +from sympy.external.gmpy import GROUND_TYPES +from sympy.testing.pytest import raises, warns_deprecated_sympy +from sympy.assumptions.ask import Q +from sympy.core.function import (Function, WildFunction) +from sympy.core.numbers import (AlgebraicNumber, Float, Integer, Rational) +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, Symbol, Wild, symbols) +from sympy.core.sympify import sympify +from sympy.functions.elementary.complexes import Abs +from sympy.functions.elementary.miscellaneous import (root, sqrt) +from sympy.functions.elementary.trigonometric import sin +from sympy.functions.special.delta_functions import Heaviside +from sympy.logic.boolalg import (false, true) +from sympy.matrices.dense import (Matrix, ones) +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.matrices.immutable import ImmutableDenseMatrix +from sympy.combinatorics import Cycle, Permutation +from sympy.core.symbol import Str +from sympy.geometry import Point, Ellipse +from sympy.printing import srepr +from sympy.polys import ring, field, ZZ, QQ, lex, grlex, Poly +from sympy.polys.polyclasses import DMP +from sympy.polys.agca.extensions import FiniteExtension + +x, y = symbols('x,y') + +# eval(srepr(expr)) == expr has to succeed in the right environment. The right +# environment is the scope of "from sympy import *" for most cases. +ENV: dict[str, Any] = {"Str": Str} +exec("from sympy import *", ENV) + + +def sT(expr, string, import_stmt=None, **kwargs): + """ + sT := sreprTest + + Tests that srepr delivers the expected string and that + the condition eval(srepr(expr))==expr holds. + """ + if import_stmt is None: + ENV2 = ENV + else: + ENV2 = ENV.copy() + exec(import_stmt, ENV2) + + assert srepr(expr, **kwargs) == string + assert eval(string, ENV2) == expr + + +def test_printmethod(): + class R(Abs): + def _sympyrepr(self, printer): + return "foo(%s)" % printer._print(self.args[0]) + assert srepr(R(x)) == "foo(Symbol('x'))" + + +def test_Add(): + sT(x + y, "Add(Symbol('x'), Symbol('y'))") + assert srepr(x**2 + 1, order='lex') == "Add(Pow(Symbol('x'), Integer(2)), Integer(1))" + assert srepr(x**2 + 1, order='old') == "Add(Integer(1), Pow(Symbol('x'), Integer(2)))" + assert srepr(sympify('x + 3 - 2', evaluate=False), order='none') == "Add(Symbol('x'), Integer(3), Mul(Integer(-1), Integer(2)))" + + +def test_more_than_255_args_issue_10259(): + from sympy.core.add import Add + from sympy.core.mul import Mul + for op in (Add, Mul): + expr = op(*symbols('x:256')) + assert eval(srepr(expr)) == expr + + +def test_Function(): + sT(Function("f")(x), "Function('f')(Symbol('x'))") + # test unapplied Function + sT(Function('f'), "Function('f')") + + sT(sin(x), "sin(Symbol('x'))") + sT(sin, "sin") + + +def test_Heaviside(): + sT(Heaviside(x), "Heaviside(Symbol('x'))") + sT(Heaviside(x, 1), "Heaviside(Symbol('x'), Integer(1))") + + +def test_Geometry(): + sT(Point(0, 0), "Point2D(Integer(0), Integer(0))") + sT(Ellipse(Point(0, 0), 5, 1), + "Ellipse(Point2D(Integer(0), Integer(0)), Integer(5), Integer(1))") + # TODO more tests + + +def test_Singletons(): + sT(S.Catalan, 'Catalan') + sT(S.ComplexInfinity, 'zoo') + sT(S.EulerGamma, 'EulerGamma') + sT(S.Exp1, 'E') + sT(S.GoldenRatio, 'GoldenRatio') + sT(S.TribonacciConstant, 'TribonacciConstant') + sT(S.Half, 'Rational(1, 2)') + sT(S.ImaginaryUnit, 'I') + sT(S.Infinity, 'oo') + sT(S.NaN, 'nan') + sT(S.NegativeInfinity, '-oo') + sT(S.NegativeOne, 'Integer(-1)') + sT(S.One, 'Integer(1)') + sT(S.Pi, 'pi') + sT(S.Zero, 'Integer(0)') + sT(S.Complexes, 'Complexes') + sT(S.EmptySequence, 'EmptySequence') + sT(S.EmptySet, 'EmptySet') + # sT(S.IdentityFunction, 'Lambda(_x, _x)') + sT(S.Naturals, 'Naturals') + sT(S.Naturals0, 'Naturals0') + sT(S.Rationals, 'Rationals') + sT(S.Reals, 'Reals') + sT(S.UniversalSet, 'UniversalSet') + + +def test_Integer(): + sT(Integer(4), "Integer(4)") + + +def test_list(): + sT([x, Integer(4)], "[Symbol('x'), Integer(4)]") + + +def test_Matrix(): + for cls, name in [(Matrix, "MutableDenseMatrix"), (ImmutableDenseMatrix, "ImmutableDenseMatrix")]: + sT(cls([[x**+1, 1], [y, x + y]]), + "%s([[Symbol('x'), Integer(1)], [Symbol('y'), Add(Symbol('x'), Symbol('y'))]])" % name) + + sT(cls(), "%s([])" % name) + + sT(cls([[x**+1, 1], [y, x + y]]), "%s([[Symbol('x'), Integer(1)], [Symbol('y'), Add(Symbol('x'), Symbol('y'))]])" % name) + + +def test_empty_Matrix(): + sT(ones(0, 3), "MutableDenseMatrix(0, 3, [])") + sT(ones(4, 0), "MutableDenseMatrix(4, 0, [])") + sT(ones(0, 0), "MutableDenseMatrix([])") + + +def test_Rational(): + sT(Rational(1, 3), "Rational(1, 3)") + sT(Rational(-1, 3), "Rational(-1, 3)") + + +def test_Float(): + sT(Float('1.23', dps=3), "Float('1.22998', precision=13)") + sT(Float('1.23456789', dps=9), "Float('1.23456788994', precision=33)") + sT(Float('1.234567890123456789', dps=19), + "Float('1.234567890123456789013', precision=66)") + sT(Float('0.60038617995049726', dps=15), + "Float('0.60038617995049726', precision=53)") + + sT(Float('1.23', precision=13), "Float('1.22998', precision=13)") + sT(Float('1.23456789', precision=33), + "Float('1.23456788994', precision=33)") + sT(Float('1.234567890123456789', precision=66), + "Float('1.234567890123456789013', precision=66)") + sT(Float('0.60038617995049726', precision=53), + "Float('0.60038617995049726', precision=53)") + + sT(Float('0.60038617995049726', 15), + "Float('0.60038617995049726', precision=53)") + + +def test_Symbol(): + sT(x, "Symbol('x')") + sT(y, "Symbol('y')") + sT(Symbol('x', negative=True), "Symbol('x', negative=True)") + + +def test_Symbol_two_assumptions(): + x = Symbol('x', negative=0, integer=1) + # order could vary + s1 = "Symbol('x', integer=True, negative=False)" + s2 = "Symbol('x', negative=False, integer=True)" + assert srepr(x) in (s1, s2) + assert eval(srepr(x), ENV) == x + + +def test_Symbol_no_special_commutative_treatment(): + sT(Symbol('x'), "Symbol('x')") + sT(Symbol('x', commutative=False), "Symbol('x', commutative=False)") + sT(Symbol('x', commutative=0), "Symbol('x', commutative=False)") + sT(Symbol('x', commutative=True), "Symbol('x', commutative=True)") + sT(Symbol('x', commutative=1), "Symbol('x', commutative=True)") + + +def test_Wild(): + sT(Wild('x', even=True), "Wild('x', even=True)") + + +def test_Dummy(): + d = Dummy('d') + sT(d, "Dummy('d', dummy_index=%s)" % str(d.dummy_index)) + + +def test_Dummy_assumption(): + d = Dummy('d', nonzero=True) + assert d == eval(srepr(d)) + s1 = "Dummy('d', dummy_index=%s, nonzero=True)" % str(d.dummy_index) + s2 = "Dummy('d', nonzero=True, dummy_index=%s)" % str(d.dummy_index) + assert srepr(d) in (s1, s2) + + +def test_Dummy_from_Symbol(): + # should not get the full dictionary of assumptions + n = Symbol('n', integer=True) + d = n.as_dummy() + assert srepr(d + ) == "Dummy('n', dummy_index=%s)" % str(d.dummy_index) + + +def test_tuple(): + sT((x,), "(Symbol('x'),)") + sT((x, y), "(Symbol('x'), Symbol('y'))") + + +def test_WildFunction(): + sT(WildFunction('w'), "WildFunction('w')") + + +def test_settins(): + raises(TypeError, lambda: srepr(x, method="garbage")) + + +def test_Mul(): + sT(3*x**3*y, "Mul(Integer(3), Pow(Symbol('x'), Integer(3)), Symbol('y'))") + assert srepr(3*x**3*y, order='old') == "Mul(Integer(3), Symbol('y'), Pow(Symbol('x'), Integer(3)))" + assert srepr(sympify('(x+4)*2*x*7', evaluate=False), order='none') == "Mul(Add(Symbol('x'), Integer(4)), Integer(2), Symbol('x'), Integer(7))" + + +def test_AlgebraicNumber(): + a = AlgebraicNumber(sqrt(2)) + sT(a, "AlgebraicNumber(Pow(Integer(2), Rational(1, 2)), [Integer(1), Integer(0)])") + a = AlgebraicNumber(root(-2, 3)) + sT(a, "AlgebraicNumber(Pow(Integer(-2), Rational(1, 3)), [Integer(1), Integer(0)])") + + +def test_PolyRing(): + assert srepr(ring("x", ZZ, lex)[0]) == "PolyRing((Symbol('x'),), ZZ, lex)" + assert srepr(ring("x,y", QQ, grlex)[0]) == "PolyRing((Symbol('x'), Symbol('y')), QQ, grlex)" + assert srepr(ring("x,y,z", ZZ["t"], lex)[0]) == "PolyRing((Symbol('x'), Symbol('y'), Symbol('z')), ZZ[t], lex)" + + +def test_FracField(): + assert srepr(field("x", ZZ, lex)[0]) == "FracField((Symbol('x'),), ZZ, lex)" + assert srepr(field("x,y", QQ, grlex)[0]) == "FracField((Symbol('x'), Symbol('y')), QQ, grlex)" + assert srepr(field("x,y,z", ZZ["t"], lex)[0]) == "FracField((Symbol('x'), Symbol('y'), Symbol('z')), ZZ[t], lex)" + + +def test_PolyElement(): + R, x, y = ring("x,y", ZZ) + assert srepr(3*x**2*y + 1) == "PolyElement(PolyRing((Symbol('x'), Symbol('y')), ZZ, lex), [((2, 1), 3), ((0, 0), 1)])" + + +def test_FracElement(): + F, x, y = field("x,y", ZZ) + assert srepr((3*x**2*y + 1)/(x - y**2)) == "FracElement(FracField((Symbol('x'), Symbol('y')), ZZ, lex), [((2, 1), 3), ((0, 0), 1)], [((1, 0), 1), ((0, 2), -1)])" + + +def test_FractionField(): + assert srepr(QQ.frac_field(x)) == \ + "FractionField(FracField((Symbol('x'),), QQ, lex))" + assert srepr(QQ.frac_field(x, y, order=grlex)) == \ + "FractionField(FracField((Symbol('x'), Symbol('y')), QQ, grlex))" + + +def test_PolynomialRingBase(): + assert srepr(ZZ.old_poly_ring(x)) == \ + "GlobalPolynomialRing(ZZ, Symbol('x'))" + assert srepr(ZZ[x].old_poly_ring(y)) == \ + "GlobalPolynomialRing(ZZ[x], Symbol('y'))" + assert srepr(QQ.frac_field(x).old_poly_ring(y)) == \ + "GlobalPolynomialRing(FractionField(FracField((Symbol('x'),), QQ, lex)), Symbol('y'))" + + +def test_DMP(): + p1 = DMP([1, 2], ZZ) + p2 = ZZ.old_poly_ring(x)([1, 2]) + if GROUND_TYPES != 'flint': + assert srepr(p1) == "DMP_Python([1, 2], ZZ)" + assert srepr(p2) == "DMP_Python([1, 2], ZZ)" + else: + assert srepr(p1) == "DUP_Flint([1, 2], ZZ)" + assert srepr(p2) == "DUP_Flint([1, 2], ZZ)" + + +def test_FiniteExtension(): + assert srepr(FiniteExtension(Poly(x**2 + 1, x))) == \ + "FiniteExtension(Poly(x**2 + 1, x, domain='ZZ'))" + + +def test_ExtensionElement(): + A = FiniteExtension(Poly(x**2 + 1, x)) + if GROUND_TYPES != 'flint': + ans = "ExtElem(DMP_Python([1, 0], ZZ), FiniteExtension(Poly(x**2 + 1, x, domain='ZZ')))" + else: + ans = "ExtElem(DUP_Flint([1, 0], ZZ), FiniteExtension(Poly(x**2 + 1, x, domain='ZZ')))" + assert srepr(A.generator) == ans + +def test_BooleanAtom(): + assert srepr(true) == "true" + assert srepr(false) == "false" + + +def test_Integers(): + sT(S.Integers, "Integers") + + +def test_Naturals(): + sT(S.Naturals, "Naturals") + + +def test_Naturals0(): + sT(S.Naturals0, "Naturals0") + + +def test_Reals(): + sT(S.Reals, "Reals") + + +def test_matrix_expressions(): + n = symbols('n', integer=True) + A = MatrixSymbol("A", n, n) + B = MatrixSymbol("B", n, n) + sT(A, "MatrixSymbol(Str('A'), Symbol('n', integer=True), Symbol('n', integer=True))") + sT(A*B, "MatMul(MatrixSymbol(Str('A'), Symbol('n', integer=True), Symbol('n', integer=True)), MatrixSymbol(Str('B'), Symbol('n', integer=True), Symbol('n', integer=True)))") + sT(A + B, "MatAdd(MatrixSymbol(Str('A'), Symbol('n', integer=True), Symbol('n', integer=True)), MatrixSymbol(Str('B'), Symbol('n', integer=True), Symbol('n', integer=True)))") + + +def test_Cycle(): + # FIXME: sT fails because Cycle is not immutable and calling srepr(Cycle(1, 2)) + # adds keys to the Cycle dict (GH-17661) + #import_stmt = "from sympy.combinatorics import Cycle" + #sT(Cycle(1, 2), "Cycle(1, 2)", import_stmt) + assert srepr(Cycle(1, 2)) == "Cycle(1, 2)" + + +def test_Permutation(): + import_stmt = "from sympy.combinatorics import Permutation" + sT(Permutation(1, 2)(3, 4), "Permutation([0, 2, 1, 4, 3])", import_stmt, perm_cyclic=False) + sT(Permutation(1, 2)(3, 4), "Permutation(1, 2)(3, 4)", import_stmt, perm_cyclic=True) + + with warns_deprecated_sympy(): + old_print_cyclic = Permutation.print_cyclic + Permutation.print_cyclic = False + sT(Permutation(1, 2)(3, 4), "Permutation([0, 2, 1, 4, 3])", import_stmt) + Permutation.print_cyclic = old_print_cyclic + +def test_dict(): + from sympy.abc import x, y, z + d = {} + assert srepr(d) == "{}" + d = {x: y} + assert srepr(d) == "{Symbol('x'): Symbol('y')}" + d = {x: y, y: z} + assert srepr(d) in ( + "{Symbol('x'): Symbol('y'), Symbol('y'): Symbol('z')}", + "{Symbol('y'): Symbol('z'), Symbol('x'): Symbol('y')}", + ) + d = {x: {y: z}} + assert srepr(d) == "{Symbol('x'): {Symbol('y'): Symbol('z')}}" + +def test_set(): + from sympy.abc import x, y + s = set() + assert srepr(s) == "set()" + s = {x, y} + assert srepr(s) in ("{Symbol('x'), Symbol('y')}", "{Symbol('y'), Symbol('x')}") + +def test_Predicate(): + sT(Q.even, "Q.even") + +def test_AppliedPredicate(): + sT(Q.even(Symbol('z')), "AppliedPredicate(Q.even, Symbol('z'))") diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_rust.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_rust.py new file mode 100644 index 0000000000000000000000000000000000000000..c81d592faca0d4a31e5a9618a48d67cb19ca94d8 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_rust.py @@ -0,0 +1,363 @@ +from sympy.core import (S, pi, oo, symbols, Rational, Integer, + GoldenRatio, EulerGamma, Catalan, Lambda, Dummy, + Eq, Ne, Le, Lt, Gt, Ge, Mod) +from sympy.functions import (Piecewise, sin, cos, Abs, exp, ceiling, sqrt, + sign, floor) +from sympy.logic import ITE +from sympy.testing.pytest import raises +from sympy.utilities.lambdify import implemented_function +from sympy.tensor import IndexedBase, Idx +from sympy.matrices import MatrixSymbol, SparseMatrix, Matrix + +from sympy.printing.codeprinter import rust_code + +x, y, z = symbols('x,y,z', integer=False, real=True) +k, m, n = symbols('k,m,n', integer=True) + + +def test_Integer(): + assert rust_code(Integer(42)) == "42" + assert rust_code(Integer(-56)) == "-56" + + +def test_Relational(): + assert rust_code(Eq(x, y)) == "x == y" + assert rust_code(Ne(x, y)) == "x != y" + assert rust_code(Le(x, y)) == "x <= y" + assert rust_code(Lt(x, y)) == "x < y" + assert rust_code(Gt(x, y)) == "x > y" + assert rust_code(Ge(x, y)) == "x >= y" + + +def test_Rational(): + assert rust_code(Rational(3, 7)) == "3_f64/7.0" + assert rust_code(Rational(18, 9)) == "2" + assert rust_code(Rational(3, -7)) == "-3_f64/7.0" + assert rust_code(Rational(-3, -7)) == "3_f64/7.0" + assert rust_code(x + Rational(3, 7)) == "x + 3_f64/7.0" + assert rust_code(Rational(3, 7)*x) == "(3_f64/7.0)*x" + + +def test_basic_ops(): + assert rust_code(x + y) == "x + y" + assert rust_code(x - y) == "x - y" + assert rust_code(x * y) == "x*y" + assert rust_code(x / y) == "x*y.recip()" + assert rust_code(-x) == "-x" + assert rust_code(2 * x) == "2.0*x" + assert rust_code(y + 2) == "y + 2.0" + assert rust_code(x + n) == "n as f64 + x" + +def test_printmethod(): + class fabs(Abs): + def _rust_code(self, printer): + return "%s.fabs()" % printer._print(self.args[0]) + assert rust_code(fabs(x)) == "x.fabs()" + a = MatrixSymbol("a", 1, 3) + assert rust_code(a[0,0]) == 'a[0]' + + +def test_Functions(): + assert rust_code(sin(x) ** cos(x)) == "x.sin().powf(x.cos())" + assert rust_code(abs(x)) == "x.abs()" + assert rust_code(ceiling(x)) == "x.ceil()" + assert rust_code(floor(x)) == "x.floor()" + + # Automatic rewrite + assert rust_code(Mod(x, 3)) == 'x - 3.0*((1_f64/3.0)*x).floor()' + + +def test_Pow(): + assert rust_code(1/x) == "x.recip()" + assert rust_code(x**-1) == rust_code(x**-1.0) == "x.recip()" + assert rust_code(sqrt(x)) == "x.sqrt()" + assert rust_code(x**S.Half) == rust_code(x**0.5) == "x.sqrt()" + + assert rust_code(1/sqrt(x)) == "x.sqrt().recip()" + assert rust_code(x**-S.Half) == rust_code(x**-0.5) == "x.sqrt().recip()" + + assert rust_code(1/pi) == "PI.recip()" + assert rust_code(pi**-1) == rust_code(pi**-1.0) == "PI.recip()" + assert rust_code(pi**-0.5) == "PI.sqrt().recip()" + + assert rust_code(x**Rational(1, 3)) == "x.cbrt()" + assert rust_code(2**x) == "x.exp2()" + assert rust_code(exp(x)) == "x.exp()" + assert rust_code(x**3) == "x.powi(3)" + assert rust_code(x**(y**3)) == "x.powf(y.powi(3))" + assert rust_code(x**Rational(2, 3)) == "x.powf(2_f64/3.0)" + + g = implemented_function('g', Lambda(x, 2*x)) + assert rust_code(1/(g(x)*3.5)**(x - y**x)/(x**2 + y)) == \ + "(3.5*2.0*x).powf(-x + y.powf(x))/(x.powi(2) + y)" + _cond_cfunc = [(lambda base, exp: exp.is_integer, "dpowi", 1), + (lambda base, exp: not exp.is_integer, "pow", 1)] + assert rust_code(x**3, user_functions={'Pow': _cond_cfunc}) == 'x.dpowi(3)' + assert rust_code(x**3.2, user_functions={'Pow': _cond_cfunc}) == 'x.pow(3.2)' + + +def test_constants(): + assert rust_code(pi) == "PI" + assert rust_code(oo) == "INFINITY" + assert rust_code(S.Infinity) == "INFINITY" + assert rust_code(-oo) == "NEG_INFINITY" + assert rust_code(S.NegativeInfinity) == "NEG_INFINITY" + assert rust_code(S.NaN) == "NAN" + assert rust_code(exp(1)) == "E" + assert rust_code(S.Exp1) == "E" + + +def test_constants_other(): + assert rust_code(2*GoldenRatio) == "const GoldenRatio: f64 = %s;\n2.0*GoldenRatio" % GoldenRatio.evalf(17) + assert rust_code( + 2*Catalan) == "const Catalan: f64 = %s;\n2.0*Catalan" % Catalan.evalf(17) + assert rust_code(2*EulerGamma) == "const EulerGamma: f64 = %s;\n2.0*EulerGamma" % EulerGamma.evalf(17) + + +def test_boolean(): + assert rust_code(True) == "true" + assert rust_code(S.true) == "true" + assert rust_code(False) == "false" + assert rust_code(S.false) == "false" + assert rust_code(k & m) == "k && m" + assert rust_code(k | m) == "k || m" + assert rust_code(~k) == "!k" + assert rust_code(k & m & n) == "k && m && n" + assert rust_code(k | m | n) == "k || m || n" + assert rust_code((k & m) | n) == "n || k && m" + assert rust_code((k | m) & n) == "n && (k || m)" + + +def test_Piecewise(): + expr = Piecewise((x, x < 1), (x + 2, True)) + assert rust_code(expr) == ( + "if (x < 1.0) {\n" + " x\n" + "} else {\n" + " x + 2.0\n" + "}") + assert rust_code(expr, assign_to="r") == ( + "r = if (x < 1.0) {\n" + " x\n" + "} else {\n" + " x + 2.0\n" + "};") + assert rust_code(expr, assign_to="r", inline=True) == ( + "r = if (x < 1.0) { x } else { x + 2.0 };") + expr = Piecewise((x, x < 1), (x + 1, x < 5), (x + 2, True)) + assert rust_code(expr, inline=True) == ( + "if (x < 1.0) { x } else if (x < 5.0) { x + 1.0 } else { x + 2.0 }") + assert rust_code(expr, assign_to="r", inline=True) == ( + "r = if (x < 1.0) { x } else if (x < 5.0) { x + 1.0 } else { x + 2.0 };") + assert rust_code(expr, assign_to="r") == ( + "r = if (x < 1.0) {\n" + " x\n" + "} else if (x < 5.0) {\n" + " x + 1.0\n" + "} else {\n" + " x + 2.0\n" + "};") + expr = 2*Piecewise((x, x < 1), (x + 1, x < 5), (x + 2, True)) + assert rust_code(expr, inline=True) == ( + "2.0*if (x < 1.0) { x } else if (x < 5.0) { x + 1.0 } else { x + 2.0 }") + expr = 2*Piecewise((x, x < 1), (x + 1, x < 5), (x + 2, True)) - 42 + assert rust_code(expr, inline=True) == ( + "2.0*if (x < 1.0) { x } else if (x < 5.0) { x + 1.0 } else { x + 2.0 } - 42.0") + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x**2, x > 1), (sin(x), x > 0)) + raises(ValueError, lambda: rust_code(expr)) + + +def test_dereference_printing(): + expr = x + y + sin(z) + z + assert rust_code(expr, dereference=[z]) == "x + y + (*z) + (*z).sin()" + + +def test_sign(): + expr = sign(x) * y + assert rust_code(expr) == "y*(if (x == 0.0) { 0.0 } else { (x).signum() }) as f64" + assert rust_code(expr, assign_to='r') == "r = y*(if (x == 0.0) { 0.0 } else { (x).signum() }) as f64;" + + expr = sign(x + y) + 42 + assert rust_code(expr) == "(if (x + y == 0.0) { 0.0 } else { (x + y).signum() }) + 42" + assert rust_code(expr, assign_to='r') == "r = (if (x + y == 0.0) { 0.0 } else { (x + y).signum() }) + 42;" + + expr = sign(cos(x)) + assert rust_code(expr) == "(if (x.cos() == 0.0) { 0.0 } else { (x.cos()).signum() })" + + +def test_reserved_words(): + + x, y = symbols("x if") + + expr = sin(y) + assert rust_code(expr) == "if_.sin()" + assert rust_code(expr, dereference=[y]) == "(*if_).sin()" + assert rust_code(expr, reserved_word_suffix='_unreserved') == "if_unreserved.sin()" + + with raises(ValueError): + rust_code(expr, error_on_reserved=True) + + +def test_ITE(): + ekpr = ITE(k < 1, m, n) + assert rust_code(ekpr) == ( + "if (k < 1) {\n" + " m\n" + "} else {\n" + " n\n" + "}") + + +def test_Indexed(): + n, m, o = symbols('n m o', integer=True) + i, j, k = Idx('i', n), Idx('j', m), Idx('k', o) + + x = IndexedBase('x')[j] + assert rust_code(x) == "x[j]" + + A = IndexedBase('A')[i, j] + assert rust_code(A) == "A[m*i + j]" + + B = IndexedBase('B')[i, j, k] + assert rust_code(B) == "B[m*o*i + o*j + k]" + + +def test_dummy_loops(): + i, m = symbols('i m', integer=True, cls=Dummy) + x = IndexedBase('x') + y = IndexedBase('y') + i = Idx(i, m) + + assert rust_code(x[i], assign_to=y[i]) == ( + "for i in 0..m {\n" + " y[i] = x[i];\n" + "}") + + +def test_loops(): + m, n = symbols('m n', integer=True) + A = IndexedBase('A') + x = IndexedBase('x') + y = IndexedBase('y') + z = IndexedBase('z') + i = Idx('i', m) + j = Idx('j', n) + + assert rust_code(A[i, j]*x[j], assign_to=y[i]) == ( + "for i in 0..m {\n" + " y[i] = 0;\n" + "}\n" + "for i in 0..m {\n" + " for j in 0..n {\n" + " y[i] = A[n*i + j]*x[j] + y[i];\n" + " }\n" + "}") + + assert rust_code(A[i, j]*x[j] + x[i] + z[i], assign_to=y[i]) == ( + "for i in 0..m {\n" + " y[i] = x[i] + z[i];\n" + "}\n" + "for i in 0..m {\n" + " for j in 0..n {\n" + " y[i] = A[n*i + j]*x[j] + y[i];\n" + " }\n" + "}") + + +def test_loops_multiple_contractions(): + n, m, o, p = symbols('n m o p', integer=True) + a = IndexedBase('a') + b = IndexedBase('b') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + k = Idx('k', o) + l = Idx('l', p) + + assert rust_code(b[j, k, l]*a[i, j, k, l], assign_to=y[i]) == ( + "for i in 0..m {\n" + " y[i] = 0;\n" + "}\n" + "for i in 0..m {\n" + " for j in 0..n {\n" + " for k in 0..o {\n" + " for l in 0..p {\n" + " y[i] = a[%s]*b[%s] + y[i];\n" % (i*n*o*p + j*o*p + k*p + l, j*o*p + k*p + l) +\ + " }\n" + " }\n" + " }\n" + "}") + + +def test_loops_addfactor(): + m, n, o, p = symbols('m n o p', integer=True) + a = IndexedBase('a') + b = IndexedBase('b') + c = IndexedBase('c') + y = IndexedBase('y') + i = Idx('i', m) + j = Idx('j', n) + k = Idx('k', o) + l = Idx('l', p) + + code = rust_code((a[i, j, k, l] + b[i, j, k, l])*c[j, k, l], assign_to=y[i]) + assert code == ( + "for i in 0..m {\n" + " y[i] = 0;\n" + "}\n" + "for i in 0..m {\n" + " for j in 0..n {\n" + " for k in 0..o {\n" + " for l in 0..p {\n" + " y[i] = (a[%s] + b[%s])*c[%s] + y[i];\n" % (i*n*o*p + j*o*p + k*p + l, i*n*o*p + j*o*p + k*p + l, j*o*p + k*p + l) +\ + " }\n" + " }\n" + " }\n" + "}") + + +def test_settings(): + raises(TypeError, lambda: rust_code(sin(x), method="garbage")) + + +def test_inline_function(): + x = symbols('x') + g = implemented_function('g', Lambda(x, 2*x)) + assert rust_code(g(x)) == "2*x" + + g = implemented_function('g', Lambda(x, 2*x/Catalan)) + assert rust_code(g(x)) == ( + "const Catalan: f64 = %s;\n2.0*x/Catalan" % Catalan.evalf(17)) + + A = IndexedBase('A') + i = Idx('i', symbols('n', integer=True)) + g = implemented_function('g', Lambda(x, x*(1 + x)*(2 + x))) + assert rust_code(g(A[i]), assign_to=A[i]) == ( + "for i in 0..n {\n" + " A[i] = (A[i] + 1)*(A[i] + 2)*A[i];\n" + "}") + + +def test_user_functions(): + x = symbols('x', integer=False) + n = symbols('n', integer=True) + custom_functions = { + "ceiling": "ceil", + "Abs": [(lambda x: not x.is_integer, "fabs", 4), (lambda x: x.is_integer, "abs", 4)], + } + assert rust_code(ceiling(x), user_functions=custom_functions) == "x.ceil()" + assert rust_code(Abs(x), user_functions=custom_functions) == "fabs(x)" + assert rust_code(Abs(n), user_functions=custom_functions) == "abs(n)" + + +def test_matrix(): + assert rust_code(Matrix([1, 2, 3])) == '[1, 2, 3]' + with raises(ValueError): + rust_code(Matrix([[1, 2, 3]])) + + +def test_sparse_matrix(): + # gh-15791 + with raises(NotImplementedError): + rust_code(SparseMatrix([[1, 2, 3]])) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_smtlib.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_smtlib.py new file mode 100644 index 0000000000000000000000000000000000000000..48ff3d432d9042bf178f4e52dc46c787059937a3 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_smtlib.py @@ -0,0 +1,553 @@ +import contextlib +import itertools +import re +import typing +from enum import Enum +from typing import Callable + +import sympy +from sympy import Add, Implies, sqrt +from sympy.core import Mul, Pow +from sympy.core import (S, pi, symbols, Function, Rational, Integer, + Symbol, Eq, Ne, Le, Lt, Gt, Ge) +from sympy.functions import Piecewise, exp, sin, cos +from sympy.assumptions.ask import Q +from sympy.printing.smtlib import smtlib_code +from sympy.testing.pytest import raises, Failed + +x, y, z = symbols('x,y,z') + + +class _W(Enum): + DEFAULTING_TO_FLOAT = re.compile("Could not infer type of `.+`. Defaulting to float.", re.IGNORECASE) + WILL_NOT_DECLARE = re.compile("Non-Symbol/Function `.+` will not be declared.", re.IGNORECASE) + WILL_NOT_ASSERT = re.compile("Non-Boolean expression `.+` will not be asserted. Converting to SMTLib verbatim.", re.IGNORECASE) + + +@contextlib.contextmanager +def _check_warns(expected: typing.Iterable[_W]): + warns: typing.List[str] = [] + log_warn = warns.append + yield log_warn + + errors = [] + for i, (w, e) in enumerate(itertools.zip_longest(warns, expected)): + if not e: + errors += [f"[{i}] Received unexpected warning `{w}`."] + elif not w: + errors += [f"[{i}] Did not receive expected warning `{e.name}`."] + elif not e.value.match(w): + errors += [f"[{i}] Warning `{w}` does not match expected {e.name}."] + + if errors: raise Failed('\n'.join(errors)) + + +def test_Integer(): + with _check_warns([_W.WILL_NOT_ASSERT] * 2) as w: + assert smtlib_code(Integer(67), log_warn=w) == "67" + assert smtlib_code(Integer(-1), log_warn=w) == "-1" + with _check_warns([]) as w: + assert smtlib_code(Integer(67)) == "67" + assert smtlib_code(Integer(-1)) == "-1" + + +def test_Rational(): + with _check_warns([_W.WILL_NOT_ASSERT] * 4) as w: + assert smtlib_code(Rational(3, 7), log_warn=w) == "(/ 3 7)" + assert smtlib_code(Rational(18, 9), log_warn=w) == "2" + assert smtlib_code(Rational(3, -7), log_warn=w) == "(/ -3 7)" + assert smtlib_code(Rational(-3, -7), log_warn=w) == "(/ 3 7)" + + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT] * 2) as w: + assert smtlib_code(x + Rational(3, 7), auto_declare=False, log_warn=w) == "(+ (/ 3 7) x)" + assert smtlib_code(Rational(3, 7) * x, log_warn=w) == "(declare-const x Real)\n" \ + "(* (/ 3 7) x)" + + +def test_Relational(): + with _check_warns([_W.DEFAULTING_TO_FLOAT] * 12) as w: + assert smtlib_code(Eq(x, y), auto_declare=False, log_warn=w) == "(assert (= x y))" + assert smtlib_code(Ne(x, y), auto_declare=False, log_warn=w) == "(assert (not (= x y)))" + assert smtlib_code(Le(x, y), auto_declare=False, log_warn=w) == "(assert (<= x y))" + assert smtlib_code(Lt(x, y), auto_declare=False, log_warn=w) == "(assert (< x y))" + assert smtlib_code(Gt(x, y), auto_declare=False, log_warn=w) == "(assert (> x y))" + assert smtlib_code(Ge(x, y), auto_declare=False, log_warn=w) == "(assert (>= x y))" + + +def test_AppliedBinaryRelation(): + with _check_warns([_W.DEFAULTING_TO_FLOAT] * 12) as w: + assert smtlib_code(Q.eq(x, y), auto_declare=False, log_warn=w) == "(assert (= x y))" + assert smtlib_code(Q.ne(x, y), auto_declare=False, log_warn=w) == "(assert (not (= x y)))" + assert smtlib_code(Q.lt(x, y), auto_declare=False, log_warn=w) == "(assert (< x y))" + assert smtlib_code(Q.le(x, y), auto_declare=False, log_warn=w) == "(assert (<= x y))" + assert smtlib_code(Q.gt(x, y), auto_declare=False, log_warn=w) == "(assert (> x y))" + assert smtlib_code(Q.ge(x, y), auto_declare=False, log_warn=w) == "(assert (>= x y))" + + raises(ValueError, lambda: smtlib_code(Q.complex(x), log_warn=w)) + + +def test_AppliedPredicate(): + with _check_warns([_W.DEFAULTING_TO_FLOAT] * 6) as w: + assert smtlib_code(Q.positive(x), auto_declare=False, log_warn=w) == "(assert (> x 0))" + assert smtlib_code(Q.negative(x), auto_declare=False, log_warn=w) == "(assert (< x 0))" + assert smtlib_code(Q.zero(x), auto_declare=False, log_warn=w) == "(assert (= x 0))" + assert smtlib_code(Q.nonpositive(x), auto_declare=False, log_warn=w) == "(assert (<= x 0))" + assert smtlib_code(Q.nonnegative(x), auto_declare=False, log_warn=w) == "(assert (>= x 0))" + assert smtlib_code(Q.nonzero(x), auto_declare=False, log_warn=w) == "(assert (not (= x 0)))" + +def test_Function(): + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(sin(x) ** cos(x), auto_declare=False, log_warn=w) == "(pow (sin x) (cos x))" + + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + abs(x), + symbol_table={x: int, y: bool}, + known_types={int: "INTEGER_TYPE"}, + known_functions={sympy.Abs: "ABSOLUTE_VALUE_OF"}, + log_warn=w + ) == "(declare-const x INTEGER_TYPE)\n" \ + "(ABSOLUTE_VALUE_OF x)" + + my_fun1 = Function('f1') + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + my_fun1(x), + symbol_table={my_fun1: Callable[[bool], float]}, + log_warn=w + ) == "(declare-const x Bool)\n" \ + "(declare-fun f1 (Bool) Real)\n" \ + "(f1 x)" + + with _check_warns([]) as w: + assert smtlib_code( + my_fun1(x), + symbol_table={my_fun1: Callable[[bool], bool]}, + log_warn=w + ) == "(declare-const x Bool)\n" \ + "(declare-fun f1 (Bool) Bool)\n" \ + "(assert (f1 x))" + + assert smtlib_code( + Eq(my_fun1(x, z), y), + symbol_table={my_fun1: Callable[[int, bool], bool]}, + log_warn=w + ) == "(declare-const x Int)\n" \ + "(declare-const y Bool)\n" \ + "(declare-const z Bool)\n" \ + "(declare-fun f1 (Int Bool) Bool)\n" \ + "(assert (= (f1 x z) y))" + + assert smtlib_code( + Eq(my_fun1(x, z), y), + symbol_table={my_fun1: Callable[[int, bool], bool]}, + known_functions={my_fun1: "MY_KNOWN_FUN", Eq: '=='}, + log_warn=w + ) == "(declare-const x Int)\n" \ + "(declare-const y Bool)\n" \ + "(declare-const z Bool)\n" \ + "(assert (== (MY_KNOWN_FUN x z) y))" + + with _check_warns([_W.DEFAULTING_TO_FLOAT] * 3) as w: + assert smtlib_code( + Eq(my_fun1(x, z), y), + known_functions={my_fun1: "MY_KNOWN_FUN", Eq: '=='}, + log_warn=w + ) == "(declare-const x Real)\n" \ + "(declare-const y Real)\n" \ + "(declare-const z Real)\n" \ + "(assert (== (MY_KNOWN_FUN x z) y))" + + +def test_Pow(): + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(x ** 3, auto_declare=False, log_warn=w) == "(pow x 3)" + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(x ** (y ** 3), auto_declare=False, log_warn=w) == "(pow x (pow y 3))" + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(x ** Rational(2, 3), auto_declare=False, log_warn=w) == '(pow x (/ 2 3))' + + a = Symbol('a', integer=True) + b = Symbol('b', real=True) + c = Symbol('c') + + def g(x): return 2 * x + + # if x=1, y=2, then expr=2.333... + expr = 1 / (g(a) * 3.5) ** (a - b ** a) / (a ** 2 + b) + + with _check_warns([]) as w: + assert smtlib_code( + [ + Eq(a < 2, c), + Eq(b > a, c), + c & True, + Eq(expr, 2 + Rational(1, 3)) + ], + log_warn=w + ) == '(declare-const a Int)\n' \ + '(declare-const b Real)\n' \ + '(declare-const c Bool)\n' \ + '(assert (= (< a 2) c))\n' \ + '(assert (= (> b a) c))\n' \ + '(assert c)\n' \ + '(assert (= ' \ + '(* (pow (* 7.0 a) (+ (pow b a) (* -1 a))) (pow (+ b (pow a 2)) -1)) ' \ + '(/ 7 3)' \ + '))' + + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Mul(-2, c, Pow(Mul(b, b, evaluate=False), -1, evaluate=False), evaluate=False), + log_warn=w + ) == '(declare-const b Real)\n' \ + '(declare-const c Real)\n' \ + '(* -2 c (pow (* b b) -1))' + + +def test_basic_ops(): + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(x * y, auto_declare=False, log_warn=w) == "(* x y)" + + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(x + y, auto_declare=False, log_warn=w) == "(+ x y)" + + # with _check_warns([_SmtlibWarnings.DEFAULTING_TO_FLOAT, _SmtlibWarnings.DEFAULTING_TO_FLOAT, _SmtlibWarnings.WILL_NOT_ASSERT]) as w: + # todo: implement re-write, currently does '(+ x (* -1 y))' instead + # assert smtlib_code(x - y, auto_declare=False, log_warn=w) == "(- x y)" + + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(-x, auto_declare=False, log_warn=w) == "(* -1 x)" + + +def test_quantifier_extensions(): + from sympy.logic.boolalg import Boolean + from sympy import Interval, Tuple, sympify + + # start For-all quantifier class example + class ForAll(Boolean): + def _smtlib(self, printer): + bound_symbol_declarations = [ + printer._s_expr(sym.name, [ + printer._known_types[printer.symbol_table[sym]], + Interval(start, end) + ]) for sym, start, end in self.limits + ] + return printer._s_expr('forall', [ + printer._s_expr('', bound_symbol_declarations), + self.function + ]) + + @property + def bound_symbols(self): + return {s for s, _, _ in self.limits} + + @property + def free_symbols(self): + bound_symbol_names = {s.name for s in self.bound_symbols} + return { + s for s in self.function.free_symbols + if s.name not in bound_symbol_names + } + + def __new__(cls, *args): + limits = [sympify(a) for a in args if isinstance(a, (tuple, Tuple))] + function = [sympify(a) for a in args if isinstance(a, Boolean)] + assert len(limits) + len(function) == len(args) + assert len(function) == 1 + function = function[0] + + if isinstance(function, ForAll): return ForAll.__new__( + ForAll, *(limits + function.limits), function.function + ) + inst = Boolean.__new__(cls) + inst._args = tuple(limits + [function]) + inst.limits = limits + inst.function = function + return inst + + # end For-All Quantifier class example + + f = Function('f') + with _check_warns([_W.DEFAULTING_TO_FLOAT]) as w: + assert smtlib_code( + ForAll((x, -42, +21), Eq(f(x), f(x))), + symbol_table={f: Callable[[float], float]}, + log_warn=w + ) == '(assert (forall ( (x Real [-42, 21])) true))' + + with _check_warns([_W.DEFAULTING_TO_FLOAT] * 2) as w: + assert smtlib_code( + ForAll( + (x, -42, +21), (y, -100, 3), + Implies(Eq(x, y), Eq(f(x), f(y))) + ), + symbol_table={f: Callable[[float], float]}, + log_warn=w + ) == '(declare-fun f (Real) Real)\n' \ + '(assert (' \ + 'forall ( (x Real [-42, 21]) (y Real [-100, 3])) ' \ + '(=> (= x y) (= (f x) (f y)))' \ + '))' + + a = Symbol('a', integer=True) + b = Symbol('b', real=True) + c = Symbol('c') + + with _check_warns([]) as w: + assert smtlib_code( + ForAll( + (a, 2, 100), ForAll( + (b, 2, 100), + Implies(a < b, sqrt(a) < b) | c + )), + log_warn=w + ) == '(declare-const c Bool)\n' \ + '(assert (forall ( (a Int [2, 100]) (b Real [2, 100])) ' \ + '(or c (=> (< a b) (< (pow a (/ 1 2)) b)))' \ + '))' + + +def test_mix_number_mult_symbols(): + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + 1 / pi, + known_constants={pi: "MY_PI"}, + log_warn=w + ) == '(pow MY_PI -1)' + + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + [ + Eq(pi, 3.14, evaluate=False), + 1 / pi, + ], + known_constants={pi: "MY_PI"}, + log_warn=w + ) == '(assert (= MY_PI 3.14))\n' \ + '(pow MY_PI -1)' + + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Add(S.Zero, S.One, S.NegativeOne, S.Half, + S.Exp1, S.Pi, S.GoldenRatio, evaluate=False), + known_constants={ + S.Pi: 'p', S.GoldenRatio: 'g', + S.Exp1: 'e' + }, + known_functions={ + Add: 'plus', + exp: 'exp' + }, + precision=3, + log_warn=w + ) == '(plus 0 1 -1 (/ 1 2) (exp 1) p g)' + + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Add(S.Zero, S.One, S.NegativeOne, S.Half, + S.Exp1, S.Pi, S.GoldenRatio, evaluate=False), + known_constants={ + S.Pi: 'p' + }, + known_functions={ + Add: 'plus', + exp: 'exp' + }, + precision=3, + log_warn=w + ) == '(plus 0 1 -1 (/ 1 2) (exp 1) p 1.62)' + + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Add(S.Zero, S.One, S.NegativeOne, S.Half, + S.Exp1, S.Pi, S.GoldenRatio, evaluate=False), + known_functions={Add: 'plus'}, + precision=3, + log_warn=w + ) == '(plus 0 1 -1 (/ 1 2) 2.72 3.14 1.62)' + + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Add(S.Zero, S.One, S.NegativeOne, S.Half, + S.Exp1, S.Pi, S.GoldenRatio, evaluate=False), + known_constants={S.Exp1: 'e'}, + known_functions={Add: 'plus'}, + precision=3, + log_warn=w + ) == '(plus 0 1 -1 (/ 1 2) e 3.14 1.62)' + + +def test_boolean(): + with _check_warns([]) as w: + assert smtlib_code(x & y, log_warn=w) == '(declare-const x Bool)\n' \ + '(declare-const y Bool)\n' \ + '(assert (and x y))' + assert smtlib_code(x | y, log_warn=w) == '(declare-const x Bool)\n' \ + '(declare-const y Bool)\n' \ + '(assert (or x y))' + assert smtlib_code(~x, log_warn=w) == '(declare-const x Bool)\n' \ + '(assert (not x))' + assert smtlib_code(x & y & z, log_warn=w) == '(declare-const x Bool)\n' \ + '(declare-const y Bool)\n' \ + '(declare-const z Bool)\n' \ + '(assert (and x y z))' + + with _check_warns([_W.DEFAULTING_TO_FLOAT]) as w: + assert smtlib_code((x & ~y) | (z > 3), log_warn=w) == '(declare-const x Bool)\n' \ + '(declare-const y Bool)\n' \ + '(declare-const z Real)\n' \ + '(assert (or (> z 3) (and x (not y))))' + + f = Function('f') + g = Function('g') + h = Function('h') + with _check_warns([_W.DEFAULTING_TO_FLOAT]) as w: + assert smtlib_code( + [Gt(f(x), y), + Lt(y, g(z))], + symbol_table={ + f: Callable[[bool], int], g: Callable[[bool], int], + }, log_warn=w + ) == '(declare-const x Bool)\n' \ + '(declare-const y Real)\n' \ + '(declare-const z Bool)\n' \ + '(declare-fun f (Bool) Int)\n' \ + '(declare-fun g (Bool) Int)\n' \ + '(assert (> (f x) y))\n' \ + '(assert (< y (g z)))' + + with _check_warns([]) as w: + assert smtlib_code( + [Eq(f(x), y), + Lt(y, g(z))], + symbol_table={ + f: Callable[[bool], int], g: Callable[[bool], int], + }, log_warn=w + ) == '(declare-const x Bool)\n' \ + '(declare-const y Int)\n' \ + '(declare-const z Bool)\n' \ + '(declare-fun f (Bool) Int)\n' \ + '(declare-fun g (Bool) Int)\n' \ + '(assert (= (f x) y))\n' \ + '(assert (< y (g z)))' + + with _check_warns([]) as w: + assert smtlib_code( + [Eq(f(x), y), + Eq(g(f(x)), z), + Eq(h(g(f(x))), x)], + symbol_table={ + f: Callable[[float], int], + g: Callable[[int], bool], + h: Callable[[bool], float] + }, + log_warn=w + ) == '(declare-const x Real)\n' \ + '(declare-const y Int)\n' \ + '(declare-const z Bool)\n' \ + '(declare-fun f (Real) Int)\n' \ + '(declare-fun g (Int) Bool)\n' \ + '(declare-fun h (Bool) Real)\n' \ + '(assert (= (f x) y))\n' \ + '(assert (= (g (f x)) z))\n' \ + '(assert (= (h (g (f x))) x))' + + +# todo: make smtlib_code support arrays +# def test_containers(): +# assert julia_code([1, 2, 3, [4, 5, [6, 7]], 8, [9, 10], 11]) == \ +# "Any[1, 2, 3, Any[4, 5, Any[6, 7]], 8, Any[9, 10], 11]" +# assert julia_code((1, 2, (3, 4))) == "(1, 2, (3, 4))" +# assert julia_code([1]) == "Any[1]" +# assert julia_code((1,)) == "(1,)" +# assert julia_code(Tuple(*[1, 2, 3])) == "(1, 2, 3)" +# assert julia_code((1, x * y, (3, x ** 2))) == "(1, x .* y, (3, x .^ 2))" +# # scalar, matrix, empty matrix and empty list +# assert julia_code((1, eye(3), Matrix(0, 0, []), [])) == "(1, [1 0 0;\n0 1 0;\n0 0 1], zeros(0, 0), Any[])" + +def test_smtlib_piecewise(): + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Piecewise((x, x < 1), + (x ** 2, True)), + auto_declare=False, + log_warn=w + ) == '(ite (< x 1) x (pow x 2))' + + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code( + Piecewise((x ** 2, x < 1), + (x ** 3, x < 2), + (x ** 4, x < 3), + (x ** 5, True)), + auto_declare=False, + log_warn=w + ) == '(ite (< x 1) (pow x 2) ' \ + '(ite (< x 2) (pow x 3) ' \ + '(ite (< x 3) (pow x 4) ' \ + '(pow x 5))))' + + # Check that Piecewise without a True (default) condition error + expr = Piecewise((x, x < 1), (x ** 2, x > 1), (sin(x), x > 0)) + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + raises(AssertionError, lambda: smtlib_code(expr, log_warn=w)) + + +def test_smtlib_piecewise_times_const(): + pw = Piecewise((x, x < 1), (x ** 2, True)) + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(2 * pw, log_warn=w) == '(declare-const x Real)\n(* 2 (ite (< x 1) x (pow x 2)))' + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(pw / x, log_warn=w) == '(declare-const x Real)\n(* (pow x -1) (ite (< x 1) x (pow x 2)))' + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(pw / (x * y), log_warn=w) == '(declare-const x Real)\n(declare-const y Real)\n(* (pow x -1) (pow y -1) (ite (< x 1) x (pow x 2)))' + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + assert smtlib_code(pw / 3, log_warn=w) == '(declare-const x Real)\n(* (/ 1 3) (ite (< x 1) x (pow x 2)))' + + +# todo: make smtlib_code support arrays / matrices ? +# def test_smtlib_matrix_assign_to(): +# A = Matrix([[1, 2, 3]]) +# assert smtlib_code(A, assign_to='a') == "a = [1 2 3]" +# A = Matrix([[1, 2], [3, 4]]) +# assert smtlib_code(A, assign_to='A') == "A = [1 2;\n3 4]" + +# def test_julia_matrix_1x1(): +# A = Matrix([[3]]) +# B = MatrixSymbol('B', 1, 1) +# C = MatrixSymbol('C', 1, 2) +# assert julia_code(A, assign_to=B) == "B = [3]" +# raises(ValueError, lambda: julia_code(A, assign_to=C)) + +# def test_julia_matrix_elements(): +# A = Matrix([[x, 2, x * y]]) +# assert julia_code(A[0, 0] ** 2 + A[0, 1] + A[0, 2]) == "x .^ 2 + x .* y + 2" +# A = MatrixSymbol('AA', 1, 3) +# assert julia_code(A) == "AA" +# assert julia_code(A[0, 0] ** 2 + sin(A[0, 1]) + A[0, 2]) == \ +# "sin(AA[1,2]) + AA[1,1] .^ 2 + AA[1,3]" +# assert julia_code(sum(A)) == "AA[1,1] + AA[1,2] + AA[1,3]" + +def test_smtlib_boolean(): + with _check_warns([]) as w: + assert smtlib_code(True, auto_assert=False, log_warn=w) == 'true' + assert smtlib_code(True, log_warn=w) == '(assert true)' + assert smtlib_code(S.true, log_warn=w) == '(assert true)' + assert smtlib_code(S.false, log_warn=w) == '(assert false)' + assert smtlib_code(False, log_warn=w) == '(assert false)' + assert smtlib_code(False, auto_assert=False, log_warn=w) == 'false' + + +def test_not_supported(): + f = Function('f') + with _check_warns([_W.DEFAULTING_TO_FLOAT, _W.WILL_NOT_ASSERT]) as w: + raises(KeyError, lambda: smtlib_code(f(x).diff(x), symbol_table={f: Callable[[float], float]}, log_warn=w)) + with _check_warns([_W.WILL_NOT_ASSERT]) as w: + raises(KeyError, lambda: smtlib_code(S.ComplexInfinity, log_warn=w)) + + +def test_Float(): + assert smtlib_code(0.0) == "0.0" + assert smtlib_code(0.000000000000000003) == '(* 3.0 (pow 10 -18))' + assert smtlib_code(5.3) == "5.3" diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_str.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_str.py new file mode 100644 index 0000000000000000000000000000000000000000..675212964b03bf9a9806088225c28d7f70971ca7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_str.py @@ -0,0 +1,1206 @@ +from sympy import MatAdd +from sympy.algebras.quaternion import Quaternion +from sympy.assumptions.ask import Q +from sympy.calculus.accumulationbounds import AccumBounds +from sympy.combinatorics.partitions import Partition +from sympy.concrete.summations import (Sum, summation) +from sympy.core.add import Add +from sympy.core.containers import (Dict, Tuple) +from sympy.core.expr import UnevaluatedExpr, Expr +from sympy.core.function import (Derivative, Function, Lambda, Subs, WildFunction) +from sympy.core.mul import Mul +from sympy.core import (Catalan, EulerGamma, GoldenRatio, TribonacciConstant) +from sympy.core.numbers import (E, Float, I, Integer, Rational, nan, oo, pi, zoo) +from sympy.core.parameters import _exp_is_pow +from sympy.core.power import Pow +from sympy.core.relational import (Eq, Rel, Ne) +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, Symbol, Wild, symbols) +from sympy.functions.combinatorial.factorials import (factorial, factorial2, subfactorial) +from sympy.functions.elementary.complexes import Abs +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.functions.special.delta_functions import Heaviside +from sympy.functions.special.zeta_functions import zeta +from sympy.integrals.integrals import Integral +from sympy.logic.boolalg import (Equivalent, false, true, Xor) +from sympy.matrices.dense import Matrix +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.matrices.expressions import Identity +from sympy.matrices.expressions.slice import MatrixSlice +from sympy.matrices import SparseMatrix +from sympy.polys.polytools import factor +from sympy.series.limits import Limit +from sympy.series.order import O +from sympy.sets.sets import (Complement, FiniteSet, Interval, SymmetricDifference) +from sympy.stats import (Covariance, Expectation, Probability, Variance) +from sympy.stats.rv import RandomSymbol +from sympy.external import import_module +from sympy.physics.control.lti import TransferFunction, Series, Parallel, \ + Feedback, TransferFunctionMatrix, MIMOSeries, MIMOParallel, MIMOFeedback +from sympy.physics.units import second, joule +from sympy.polys import (Poly, rootof, RootSum, groebner, ring, field, ZZ, QQ, + ZZ_I, QQ_I, lex, grlex) +from sympy.geometry import Point, Circle, Polygon, Ellipse, Triangle +from sympy.tensor import NDimArray +from sympy.tensor.array.expressions.array_expressions import ArraySymbol, ArrayElement + +from sympy.testing.pytest import raises, warns_deprecated_sympy + +from sympy.printing import sstr, sstrrepr, StrPrinter +from sympy.physics.quantum.trace import Tr + +x, y, z, w, t = symbols('x,y,z,w,t') +d = Dummy('d') + + +def test_printmethod(): + class R(Abs): + def _sympystr(self, printer): + return "foo(%s)" % printer._print(self.args[0]) + assert sstr(R(x)) == "foo(x)" + + class R(Abs): + def _sympystr(self, printer): + return "foo" + assert sstr(R(x)) == "foo" + + +def test_Abs(): + assert str(Abs(x)) == "Abs(x)" + assert str(Abs(Rational(1, 6))) == "1/6" + assert str(Abs(Rational(-1, 6))) == "1/6" + + +def test_Add(): + assert str(x + y) == "x + y" + assert str(x + 1) == "x + 1" + assert str(x + x**2) == "x**2 + x" + assert str(Add(0, 1, evaluate=False)) == "0 + 1" + assert str(Add(0, 0, 1, evaluate=False)) == "0 + 0 + 1" + assert str(1.0*x) == "1.0*x" + assert str(5 + x + y + x*y + x**2 + y**2) == "x**2 + x*y + x + y**2 + y + 5" + assert str(1 + x + x**2/2 + x**3/3) == "x**3/3 + x**2/2 + x + 1" + assert str(2*x - 7*x**2 + 2 + 3*y) == "-7*x**2 + 2*x + 3*y + 2" + assert str(x - y) == "x - y" + assert str(2 - x) == "2 - x" + assert str(x - 2) == "x - 2" + assert str(x - y - z - w) == "-w + x - y - z" + assert str(x - z*y**2*z*w) == "-w*y**2*z**2 + x" + assert str(x - 1*y*x*y) == "-x*y**2 + x" + assert str(sin(x).series(x, 0, 15)) == "x - x**3/6 + x**5/120 - x**7/5040 + x**9/362880 - x**11/39916800 + x**13/6227020800 + O(x**15)" + assert str(Add(Add(-w, x, evaluate=False), Add(-y, z, evaluate=False), evaluate=False)) == "(-w + x) + (-y + z)" + assert str(Add(Add(-x, -y, evaluate=False), -z, evaluate=False)) == "-z + (-x - y)" + assert str(Add(Add(Add(-x, -y, evaluate=False), -z, evaluate=False), -t, evaluate=False)) == "-t + (-z + (-x - y))" + + +def test_Catalan(): + assert str(Catalan) == "Catalan" + + +def test_ComplexInfinity(): + assert str(zoo) == "zoo" + + +def test_Derivative(): + assert str(Derivative(x, y)) == "Derivative(x, y)" + assert str(Derivative(x**2, x, evaluate=False)) == "Derivative(x**2, x)" + assert str(Derivative( + x**2/y, x, y, evaluate=False)) == "Derivative(x**2/y, x, y)" + + +def test_dict(): + assert str({1: 1 + x}) == sstr({1: 1 + x}) == "{1: x + 1}" + assert str({1: x**2, 2: y*x}) in ("{1: x**2, 2: x*y}", "{2: x*y, 1: x**2}") + assert sstr({1: x**2, 2: y*x}) == "{1: x**2, 2: x*y}" + + +def test_Dict(): + assert str(Dict({1: 1 + x})) == sstr({1: 1 + x}) == "{1: x + 1}" + assert str(Dict({1: x**2, 2: y*x})) in ( + "{1: x**2, 2: x*y}", "{2: x*y, 1: x**2}") + assert sstr(Dict({1: x**2, 2: y*x})) == "{1: x**2, 2: x*y}" + + +def test_Dummy(): + assert str(d) == "_d" + assert str(d + x) == "_d + x" + + +def test_EulerGamma(): + assert str(EulerGamma) == "EulerGamma" + + +def test_Exp(): + assert str(E) == "E" + with _exp_is_pow(True): + assert str(exp(x)) == "E**x" + + +def test_factorial(): + n = Symbol('n', integer=True) + assert str(factorial(-2)) == "zoo" + assert str(factorial(0)) == "1" + assert str(factorial(7)) == "5040" + assert str(factorial(n)) == "factorial(n)" + assert str(factorial(2*n)) == "factorial(2*n)" + assert str(factorial(factorial(n))) == 'factorial(factorial(n))' + assert str(factorial(factorial2(n))) == 'factorial(factorial2(n))' + assert str(factorial2(factorial(n))) == 'factorial2(factorial(n))' + assert str(factorial2(factorial2(n))) == 'factorial2(factorial2(n))' + assert str(subfactorial(3)) == "2" + assert str(subfactorial(n)) == "subfactorial(n)" + assert str(subfactorial(2*n)) == "subfactorial(2*n)" + + +def test_Function(): + f = Function('f') + fx = f(x) + w = WildFunction('w') + assert str(f) == "f" + assert str(fx) == "f(x)" + assert str(w) == "w_" + + +def test_Geometry(): + assert sstr(Point(0, 0)) == 'Point2D(0, 0)' + assert sstr(Circle(Point(0, 0), 3)) == 'Circle(Point2D(0, 0), 3)' + assert sstr(Ellipse(Point(1, 2), 3, 4)) == 'Ellipse(Point2D(1, 2), 3, 4)' + assert sstr(Triangle(Point(1, 1), Point(7, 8), Point(0, -1))) == \ + 'Triangle(Point2D(1, 1), Point2D(7, 8), Point2D(0, -1))' + assert sstr(Polygon(Point(5, 6), Point(-2, -3), Point(0, 0), Point(4, 7))) == \ + 'Polygon(Point2D(5, 6), Point2D(-2, -3), Point2D(0, 0), Point2D(4, 7))' + assert sstr(Triangle(Point(0, 0), Point(1, 0), Point(0, 1)), sympy_integers=True) == \ + 'Triangle(Point2D(S(0), S(0)), Point2D(S(1), S(0)), Point2D(S(0), S(1)))' + assert sstr(Ellipse(Point(1, 2), 3, 4), sympy_integers=True) == \ + 'Ellipse(Point2D(S(1), S(2)), S(3), S(4))' + + +def test_GoldenRatio(): + assert str(GoldenRatio) == "GoldenRatio" + + +def test_Heaviside(): + assert str(Heaviside(x)) == str(Heaviside(x, S.Half)) == "Heaviside(x)" + assert str(Heaviside(x, 1)) == "Heaviside(x, 1)" + + +def test_TribonacciConstant(): + assert str(TribonacciConstant) == "TribonacciConstant" + + +def test_ImaginaryUnit(): + assert str(I) == "I" + + +def test_Infinity(): + assert str(oo) == "oo" + assert str(oo*I) == "oo*I" + + +def test_Integer(): + assert str(Integer(-1)) == "-1" + assert str(Integer(1)) == "1" + assert str(Integer(-3)) == "-3" + assert str(Integer(0)) == "0" + assert str(Integer(25)) == "25" + + +def test_Integral(): + assert str(Integral(sin(x), y)) == "Integral(sin(x), y)" + assert str(Integral(sin(x), (y, 0, 1))) == "Integral(sin(x), (y, 0, 1))" + + +def test_Interval(): + n = (S.NegativeInfinity, 1, 2, S.Infinity) + for i in range(len(n)): + for j in range(i + 1, len(n)): + for l in (True, False): + for r in (True, False): + ival = Interval(n[i], n[j], l, r) + assert S(str(ival)) == ival + + +def test_AccumBounds(): + a = Symbol('a', real=True) + assert str(AccumBounds(0, a)) == "AccumBounds(0, a)" + assert str(AccumBounds(0, 1)) == "AccumBounds(0, 1)" + + +def test_Lambda(): + assert str(Lambda(d, d**2)) == "Lambda(_d, _d**2)" + # issue 2908 + assert str(Lambda((), 1)) == "Lambda((), 1)" + assert str(Lambda((), x)) == "Lambda((), x)" + assert str(Lambda((x, y), x+y)) == "Lambda((x, y), x + y)" + assert str(Lambda(((x, y),), x+y)) == "Lambda(((x, y),), x + y)" + + +def test_Limit(): + assert str(Limit(sin(x)/x, x, y)) == "Limit(sin(x)/x, x, y, dir='+')" + assert str(Limit(1/x, x, 0)) == "Limit(1/x, x, 0, dir='+')" + assert str( + Limit(sin(x)/x, x, y, dir="-")) == "Limit(sin(x)/x, x, y, dir='-')" + + +def test_list(): + assert str([x]) == sstr([x]) == "[x]" + assert str([x**2, x*y + 1]) == sstr([x**2, x*y + 1]) == "[x**2, x*y + 1]" + assert str([x**2, [y + x]]) == sstr([x**2, [y + x]]) == "[x**2, [x + y]]" + + +def test_Matrix_str(): + M = Matrix([[x**+1, 1], [y, x + y]]) + assert str(M) == "Matrix([[x, 1], [y, x + y]])" + assert sstr(M) == "Matrix([\n[x, 1],\n[y, x + y]])" + M = Matrix([[1]]) + assert str(M) == sstr(M) == "Matrix([[1]])" + M = Matrix([[1, 2]]) + assert str(M) == sstr(M) == "Matrix([[1, 2]])" + M = Matrix() + assert str(M) == sstr(M) == "Matrix(0, 0, [])" + M = Matrix(0, 1, lambda i, j: 0) + assert str(M) == sstr(M) == "Matrix(0, 1, [])" + + +def test_Mul(): + assert str(x/y) == "x/y" + assert str(y/x) == "y/x" + assert str(x/y/z) == "x/(y*z)" + assert str((x + 1)/(y + 2)) == "(x + 1)/(y + 2)" + assert str(2*x/3) == '2*x/3' + assert str(-2*x/3) == '-2*x/3' + assert str(-1.0*x) == '-1.0*x' + assert str(1.0*x) == '1.0*x' + assert str(Mul(0, 1, evaluate=False)) == '0*1' + assert str(Mul(1, 0, evaluate=False)) == '1*0' + assert str(Mul(1, 1, evaluate=False)) == '1*1' + assert str(Mul(1, 1, 1, evaluate=False)) == '1*1*1' + assert str(Mul(1, 2, evaluate=False)) == '1*2' + assert str(Mul(1, S.Half, evaluate=False)) == '1*(1/2)' + assert str(Mul(1, 1, S.Half, evaluate=False)) == '1*1*(1/2)' + assert str(Mul(1, 1, 2, 3, x, evaluate=False)) == '1*1*2*3*x' + assert str(Mul(1, -1, evaluate=False)) == '1*(-1)' + assert str(Mul(-1, 1, evaluate=False)) == '-1*1' + assert str(Mul(4, 3, 2, 1, 0, y, x, evaluate=False)) == '4*3*2*1*0*y*x' + assert str(Mul(4, 3, 2, 1+z, 0, y, x, evaluate=False)) == '4*3*2*(z + 1)*0*y*x' + assert str(Mul(Rational(2, 3), Rational(5, 7), evaluate=False)) == '(2/3)*(5/7)' + # For issue 14160 + assert str(Mul(-2, x, Pow(Mul(y,y,evaluate=False), -1, evaluate=False), + evaluate=False)) == '-2*x/(y*y)' + # issue 21537 + assert str(Mul(x, Pow(1/y, -1, evaluate=False), evaluate=False)) == 'x/(1/y)' + + # Issue 24108 + from sympy.core.parameters import evaluate + with evaluate(False): + assert str(Mul(Pow(Integer(2), Integer(-1)), Add(Integer(-1), Mul(Integer(-1), Integer(1))))) == "(-1 - 1*1)/2" + + class CustomClass1(Expr): + is_commutative = True + + class CustomClass2(Expr): + is_commutative = True + cc1 = CustomClass1() + cc2 = CustomClass2() + assert str(Rational(2)*cc1) == '2*CustomClass1()' + assert str(cc1*Rational(2)) == '2*CustomClass1()' + assert str(cc1*Float("1.5")) == '1.5*CustomClass1()' + assert str(cc2*Rational(2)) == '2*CustomClass2()' + assert str(cc2*Rational(2)*cc1) == '2*CustomClass1()*CustomClass2()' + assert str(cc1*Rational(2)*cc2) == '2*CustomClass1()*CustomClass2()' + + +def test_NaN(): + assert str(nan) == "nan" + + +def test_NegativeInfinity(): + assert str(-oo) == "-oo" + +def test_Order(): + assert str(O(x)) == "O(x)" + assert str(O(x**2)) == "O(x**2)" + assert str(O(x*y)) == "O(x*y, x, y)" + assert str(O(x, x)) == "O(x)" + assert str(O(x, (x, 0))) == "O(x)" + assert str(O(x, (x, oo))) == "O(x, (x, oo))" + assert str(O(x, x, y)) == "O(x, x, y)" + assert str(O(x, x, y)) == "O(x, x, y)" + assert str(O(x, (x, oo), (y, oo))) == "O(x, (x, oo), (y, oo))" + + +def test_Permutation_Cycle(): + from sympy.combinatorics import Permutation, Cycle + + # general principle: economically, canonically show all moved elements + # and the size of the permutation. + + for p, s in [ + (Cycle(), + '()'), + (Cycle(2), + '(2)'), + (Cycle(2, 1), + '(1 2)'), + (Cycle(1, 2)(5)(6, 7)(10), + '(1 2)(6 7)(10)'), + (Cycle(3, 4)(1, 2)(3, 4), + '(1 2)(4)'), + ]: + assert sstr(p) == s + + for p, s in [ + (Permutation([]), + 'Permutation([])'), + (Permutation([], size=1), + 'Permutation([0])'), + (Permutation([], size=2), + 'Permutation([0, 1])'), + (Permutation([], size=10), + 'Permutation([], size=10)'), + (Permutation([1, 0, 2]), + 'Permutation([1, 0, 2])'), + (Permutation([1, 0, 2, 3, 4, 5]), + 'Permutation([1, 0], size=6)'), + (Permutation([1, 0, 2, 3, 4, 5], size=10), + 'Permutation([1, 0], size=10)'), + ]: + assert sstr(p, perm_cyclic=False) == s + + for p, s in [ + (Permutation([]), + '()'), + (Permutation([], size=1), + '(0)'), + (Permutation([], size=2), + '(1)'), + (Permutation([], size=10), + '(9)'), + (Permutation([1, 0, 2]), + '(2)(0 1)'), + (Permutation([1, 0, 2, 3, 4, 5]), + '(5)(0 1)'), + (Permutation([1, 0, 2, 3, 4, 5], size=10), + '(9)(0 1)'), + (Permutation([0, 1, 3, 2, 4, 5], size=10), + '(9)(2 3)'), + ]: + assert sstr(p) == s + + + with warns_deprecated_sympy(): + old_print_cyclic = Permutation.print_cyclic + Permutation.print_cyclic = False + assert sstr(Permutation([1, 0, 2])) == 'Permutation([1, 0, 2])' + Permutation.print_cyclic = old_print_cyclic + +def test_Pi(): + assert str(pi) == "pi" + + +def test_Poly(): + assert str(Poly(0, x)) == "Poly(0, x, domain='ZZ')" + assert str(Poly(1, x)) == "Poly(1, x, domain='ZZ')" + assert str(Poly(x, x)) == "Poly(x, x, domain='ZZ')" + + assert str(Poly(2*x + 1, x)) == "Poly(2*x + 1, x, domain='ZZ')" + assert str(Poly(2*x - 1, x)) == "Poly(2*x - 1, x, domain='ZZ')" + + assert str(Poly(-1, x)) == "Poly(-1, x, domain='ZZ')" + assert str(Poly(-x, x)) == "Poly(-x, x, domain='ZZ')" + + assert str(Poly(-2*x + 1, x)) == "Poly(-2*x + 1, x, domain='ZZ')" + assert str(Poly(-2*x - 1, x)) == "Poly(-2*x - 1, x, domain='ZZ')" + + assert str(Poly(x - 1, x)) == "Poly(x - 1, x, domain='ZZ')" + assert str(Poly(2*x + x**5, x)) == "Poly(x**5 + 2*x, x, domain='ZZ')" + + assert str(Poly(3**(2*x), 3**x)) == "Poly((3**x)**2, 3**x, domain='ZZ')" + assert str(Poly((x**2)**x)) == "Poly(((x**2)**x), (x**2)**x, domain='ZZ')" + + assert str(Poly((x + y)**3, (x + y), expand=False) + ) == "Poly((x + y)**3, x + y, domain='ZZ')" + assert str(Poly((x - 1)**2, (x - 1), expand=False) + ) == "Poly((x - 1)**2, x - 1, domain='ZZ')" + + assert str( + Poly(x**2 + 1 + y, x)) == "Poly(x**2 + y + 1, x, domain='ZZ[y]')" + assert str( + Poly(x**2 - 1 + y, x)) == "Poly(x**2 + y - 1, x, domain='ZZ[y]')" + + assert str(Poly(x**2 + I*x, x)) == "Poly(x**2 + I*x, x, domain='ZZ_I')" + assert str(Poly(x**2 - I*x, x)) == "Poly(x**2 - I*x, x, domain='ZZ_I')" + + assert str(Poly(-x*y*z + x*y - 1, x, y, z) + ) == "Poly(-x*y*z + x*y - 1, x, y, z, domain='ZZ')" + assert str(Poly(-w*x**21*y**7*z + (1 + w)*z**3 - 2*x*z + 1, x, y, z)) == \ + "Poly(-w*x**21*y**7*z - 2*x*z + (w + 1)*z**3 + 1, x, y, z, domain='ZZ[w]')" + + assert str(Poly(x**2 + 1, x, modulus=2)) == "Poly(x**2 + 1, x, modulus=2)" + assert str(Poly(2*x**2 + 3*x + 4, x, modulus=17)) == "Poly(2*x**2 + 3*x + 4, x, modulus=17)" + + +def test_PolyRing(): + assert str(ring("x", ZZ, lex)[0]) == "Polynomial ring in x over ZZ with lex order" + assert str(ring("x,y", QQ, grlex)[0]) == "Polynomial ring in x, y over QQ with grlex order" + assert str(ring("x,y,z", ZZ["t"], lex)[0]) == "Polynomial ring in x, y, z over ZZ[t] with lex order" + + +def test_FracField(): + assert str(field("x", ZZ, lex)[0]) == "Rational function field in x over ZZ with lex order" + assert str(field("x,y", QQ, grlex)[0]) == "Rational function field in x, y over QQ with grlex order" + assert str(field("x,y,z", ZZ["t"], lex)[0]) == "Rational function field in x, y, z over ZZ[t] with lex order" + + +def test_PolyElement(): + Ruv, u,v = ring("u,v", ZZ) + Rxyz, x,y,z = ring("x,y,z", Ruv) + Rx_zzi, xz = ring("x", ZZ_I) + + assert str(x - x) == "0" + assert str(x - 1) == "x - 1" + assert str(x + 1) == "x + 1" + assert str(x**2) == "x**2" + + assert str((u**2 + 3*u*v + 1)*x**2*y + u + 1) == "(u**2 + 3*u*v + 1)*x**2*y + u + 1" + assert str((u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x) == "(u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x" + assert str((u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x + 1) == "(u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x + 1" + assert str((-u**2 + 3*u*v - 1)*x**2*y - (u + 1)*x - 1) == "-(u**2 - 3*u*v + 1)*x**2*y - (u + 1)*x - 1" + + assert str(-(v**2 + v + 1)*x + 3*u*v + 1) == "-(v**2 + v + 1)*x + 3*u*v + 1" + assert str(-(v**2 + v + 1)*x - 3*u*v + 1) == "-(v**2 + v + 1)*x - 3*u*v + 1" + + assert str((1+I)*xz + 2) == "(1 + 1*I)*x + (2 + 0*I)" + + +def test_FracElement(): + Fuv, u,v = field("u,v", ZZ) + Fxyzt, x,y,z,t = field("x,y,z,t", Fuv) + Rx_zzi, xz = field("x", QQ_I) + i = QQ_I(0, 1) + + assert str(x - x) == "0" + assert str(x - 1) == "x - 1" + assert str(x + 1) == "x + 1" + + assert str(x/3) == "x/3" + assert str(x/z) == "x/z" + assert str(x*y/z) == "x*y/z" + assert str(x/(z*t)) == "x/(z*t)" + assert str(x*y/(z*t)) == "x*y/(z*t)" + + assert str((x - 1)/y) == "(x - 1)/y" + assert str((x + 1)/y) == "(x + 1)/y" + assert str((-x - 1)/y) == "(-x - 1)/y" + assert str((x + 1)/(y*z)) == "(x + 1)/(y*z)" + assert str(-y/(x + 1)) == "-y/(x + 1)" + assert str(y*z/(x + 1)) == "y*z/(x + 1)" + + assert str(((u + 1)*x*y + 1)/((v - 1)*z - 1)) == "((u + 1)*x*y + 1)/((v - 1)*z - 1)" + assert str(((u + 1)*x*y + 1)/((v - 1)*z - t*u*v - 1)) == "((u + 1)*x*y + 1)/((v - 1)*z - u*v*t - 1)" + + assert str((1+i)/xz) == "(1 + 1*I)/x" + assert str(((1+i)*xz - i)/xz) == "((1 + 1*I)*x + (0 + -1*I))/x" + + +def test_GaussianInteger(): + assert str(ZZ_I(1, 0)) == "1" + assert str(ZZ_I(-1, 0)) == "-1" + assert str(ZZ_I(0, 1)) == "I" + assert str(ZZ_I(0, -1)) == "-I" + assert str(ZZ_I(0, 2)) == "2*I" + assert str(ZZ_I(0, -2)) == "-2*I" + assert str(ZZ_I(1, 1)) == "1 + I" + assert str(ZZ_I(-1, -1)) == "-1 - I" + assert str(ZZ_I(-1, -2)) == "-1 - 2*I" + + +def test_GaussianRational(): + assert str(QQ_I(1, 0)) == "1" + assert str(QQ_I(QQ(2, 3), 0)) == "2/3" + assert str(QQ_I(0, QQ(2, 3))) == "2*I/3" + assert str(QQ_I(QQ(1, 2), QQ(-2, 3))) == "1/2 - 2*I/3" + + +def test_Pow(): + assert str(x**-1) == "1/x" + assert str(x**-2) == "x**(-2)" + assert str(x**2) == "x**2" + assert str((x + y)**-1) == "1/(x + y)" + assert str((x + y)**-2) == "(x + y)**(-2)" + assert str((x + y)**2) == "(x + y)**2" + assert str((x + y)**(1 + x)) == "(x + y)**(x + 1)" + assert str(x**Rational(1, 3)) == "x**(1/3)" + assert str(1/x**Rational(1, 3)) == "x**(-1/3)" + assert str(sqrt(sqrt(x))) == "x**(1/4)" + # not the same as x**-1 + assert str(x**-1.0) == 'x**(-1.0)' + # see issue #2860 + assert str(Pow(S(2), -1.0, evaluate=False)) == '2**(-1.0)' + + +def test_sqrt(): + assert str(sqrt(x)) == "sqrt(x)" + assert str(sqrt(x**2)) == "sqrt(x**2)" + assert str(1/sqrt(x)) == "1/sqrt(x)" + assert str(1/sqrt(x**2)) == "1/sqrt(x**2)" + assert str(y/sqrt(x)) == "y/sqrt(x)" + assert str(x**0.5) == "x**0.5" + assert str(1/x**0.5) == "x**(-0.5)" + + +def test_Rational(): + n1 = Rational(1, 4) + n2 = Rational(1, 3) + n3 = Rational(2, 4) + n4 = Rational(2, -4) + n5 = Rational(0) + n7 = Rational(3) + n8 = Rational(-3) + assert str(n1*n2) == "1/12" + assert str(n1*n2) == "1/12" + assert str(n3) == "1/2" + assert str(n1*n3) == "1/8" + assert str(n1 + n3) == "3/4" + assert str(n1 + n2) == "7/12" + assert str(n1 + n4) == "-1/4" + assert str(n4*n4) == "1/4" + assert str(n4 + n2) == "-1/6" + assert str(n4 + n5) == "-1/2" + assert str(n4*n5) == "0" + assert str(n3 + n4) == "0" + assert str(n1**n7) == "1/64" + assert str(n2**n7) == "1/27" + assert str(n2**n8) == "27" + assert str(n7**n8) == "1/27" + assert str(Rational("-25")) == "-25" + assert str(Rational("1.25")) == "5/4" + assert str(Rational("-2.6e-2")) == "-13/500" + assert str(S("25/7")) == "25/7" + assert str(S("-123/569")) == "-123/569" + assert str(S("0.1[23]", rational=1)) == "61/495" + assert str(S("5.1[666]", rational=1)) == "31/6" + assert str(S("-5.1[666]", rational=1)) == "-31/6" + assert str(S("0.[9]", rational=1)) == "1" + assert str(S("-0.[9]", rational=1)) == "-1" + + assert str(sqrt(Rational(1, 4))) == "1/2" + assert str(sqrt(Rational(1, 36))) == "1/6" + + assert str((123**25) ** Rational(1, 25)) == "123" + assert str((123**25 + 1)**Rational(1, 25)) != "123" + assert str((123**25 - 1)**Rational(1, 25)) != "123" + assert str((123**25 - 1)**Rational(1, 25)) != "122" + + assert str(sqrt(Rational(81, 36))**3) == "27/8" + assert str(1/sqrt(Rational(81, 36))**3) == "8/27" + + assert str(sqrt(-4)) == str(2*I) + assert str(2**Rational(1, 10**10)) == "2**(1/10000000000)" + + assert sstr(Rational(2, 3), sympy_integers=True) == "S(2)/3" + x = Symbol("x") + assert sstr(x**Rational(2, 3), sympy_integers=True) == "x**(S(2)/3)" + assert sstr(Eq(x, Rational(2, 3)), sympy_integers=True) == "Eq(x, S(2)/3)" + assert sstr(Limit(x, x, Rational(7, 2)), sympy_integers=True) == \ + "Limit(x, x, S(7)/2, dir='+')" + + +def test_Float(): + # NOTE dps is the whole number of decimal digits + assert str(Float('1.23', dps=1 + 2)) == '1.23' + assert str(Float('1.23456789', dps=1 + 8)) == '1.23456789' + assert str( + Float('1.234567890123456789', dps=1 + 18)) == '1.234567890123456789' + assert str(pi.evalf(1 + 2)) == '3.14' + assert str(pi.evalf(1 + 14)) == '3.14159265358979' + assert str(pi.evalf(1 + 64)) == ('3.141592653589793238462643383279' + '5028841971693993751058209749445923') + assert str(pi.round(-1)) == '0.0' + assert str((pi**400 - (pi**400).round(1)).n(2)) == '-0.e+88' + assert sstr(Float("100"), full_prec=False, min=-2, max=2) == '1.0e+2' + assert sstr(Float("100"), full_prec=False, min=-2, max=3) == '100.0' + assert sstr(Float("0.1"), full_prec=False, min=-2, max=3) == '0.1' + assert sstr(Float("0.099"), min=-2, max=3) == '9.90000000000000e-2' + + +def test_Relational(): + assert str(Rel(x, y, "<")) == "x < y" + assert str(Rel(x + y, y, "==")) == "Eq(x + y, y)" + assert str(Rel(x, y, "!=")) == "Ne(x, y)" + assert str(Eq(x, 1) | Eq(x, 2)) == "Eq(x, 1) | Eq(x, 2)" + assert str(Ne(x, 1) & Ne(x, 2)) == "Ne(x, 1) & Ne(x, 2)" + + +def test_AppliedBinaryRelation(): + assert str(Q.eq(x, y)) == "Q.eq(x, y)" + assert str(Q.ne(x, y)) == "Q.ne(x, y)" + + +def test_CRootOf(): + assert str(rootof(x**5 + 2*x - 1, 0)) == "CRootOf(x**5 + 2*x - 1, 0)" + + +def test_RootSum(): + f = x**5 + 2*x - 1 + + assert str( + RootSum(f, Lambda(z, z), auto=False)) == "RootSum(x**5 + 2*x - 1)" + assert str(RootSum(f, Lambda( + z, z**2), auto=False)) == "RootSum(x**5 + 2*x - 1, Lambda(z, z**2))" + + +def test_GroebnerBasis(): + assert str(groebner( + [], x, y)) == "GroebnerBasis([], x, y, domain='ZZ', order='lex')" + + F = [x**2 - 3*y - x + 1, y**2 - 2*x + y - 1] + + assert str(groebner(F, order='grlex')) == \ + "GroebnerBasis([x**2 - x - 3*y + 1, y**2 - 2*x + y - 1], x, y, domain='ZZ', order='grlex')" + assert str(groebner(F, order='lex')) == \ + "GroebnerBasis([2*x - y**2 - y + 1, y**4 + 2*y**3 - 3*y**2 - 16*y + 7], x, y, domain='ZZ', order='lex')" + +def test_set(): + assert sstr(set()) == 'set()' + assert sstr(frozenset()) == 'frozenset()' + + assert sstr({1}) == '{1}' + assert sstr(frozenset([1])) == 'frozenset({1})' + assert sstr({1, 2, 3}) == '{1, 2, 3}' + assert sstr(frozenset([1, 2, 3])) == 'frozenset({1, 2, 3})' + + assert sstr( + {1, x, x**2, x**3, x**4}) == '{1, x, x**2, x**3, x**4}' + assert sstr( + frozenset([1, x, x**2, x**3, x**4])) == 'frozenset({1, x, x**2, x**3, x**4})' + + +def test_SparseMatrix(): + M = SparseMatrix([[x**+1, 1], [y, x + y]]) + assert str(M) == "Matrix([[x, 1], [y, x + y]])" + assert sstr(M) == "Matrix([\n[x, 1],\n[y, x + y]])" + + +def test_Sum(): + assert str(summation(cos(3*z), (z, x, y))) == "Sum(cos(3*z), (z, x, y))" + assert str(Sum(x*y**2, (x, -2, 2), (y, -5, 5))) == \ + "Sum(x*y**2, (x, -2, 2), (y, -5, 5))" + + +def test_Symbol(): + assert str(y) == "y" + assert str(x) == "x" + e = x + assert str(e) == "x" + + +def test_tuple(): + assert str((x,)) == sstr((x,)) == "(x,)" + assert str((x + y, 1 + x)) == sstr((x + y, 1 + x)) == "(x + y, x + 1)" + assert str((x + y, ( + 1 + x, x**2))) == sstr((x + y, (1 + x, x**2))) == "(x + y, (x + 1, x**2))" + + +def test_Series_str(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(t*x**2 - t**w*x + w, t - y, y) + assert str(Series(tf1, tf2)) == \ + "Series(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y))" + assert str(Series(tf1, tf2, tf3)) == \ + "Series(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y), TransferFunction(t*x**2 - t**w*x + w, t - y, y))" + assert str(Series(-tf2, tf1)) == \ + "Series(TransferFunction(-x + y, x + y, y), TransferFunction(x*y**2 - z, -t**3 + y**3, y))" + + +def test_MIMOSeries_str(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tfm_1 = TransferFunctionMatrix([[tf1, tf2], [tf2, tf1]]) + tfm_2 = TransferFunctionMatrix([[tf2, tf1], [tf1, tf2]]) + assert str(MIMOSeries(tfm_1, tfm_2)) == \ + "MIMOSeries(TransferFunctionMatrix(((TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y)), "\ + "(TransferFunction(x - y, x + y, y), TransferFunction(x*y**2 - z, -t**3 + y**3, y)))), "\ + "TransferFunctionMatrix(((TransferFunction(x - y, x + y, y), TransferFunction(x*y**2 - z, -t**3 + y**3, y)), "\ + "(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y)))))" + + +def test_TransferFunction_str(): + tf1 = TransferFunction(x - 1, x + 1, x) + assert str(tf1) == "TransferFunction(x - 1, x + 1, x)" + tf2 = TransferFunction(x + 1, 2 - y, x) + assert str(tf2) == "TransferFunction(x + 1, 2 - y, x)" + tf3 = TransferFunction(y, y**2 + 2*y + 3, y) + assert str(tf3) == "TransferFunction(y, y**2 + 2*y + 3, y)" + + +def test_Parallel_str(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(t*x**2 - t**w*x + w, t - y, y) + assert str(Parallel(tf1, tf2)) == \ + "Parallel(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y))" + assert str(Parallel(tf1, tf2, tf3)) == \ + "Parallel(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y), TransferFunction(t*x**2 - t**w*x + w, t - y, y))" + assert str(Parallel(-tf2, tf1)) == \ + "Parallel(TransferFunction(-x + y, x + y, y), TransferFunction(x*y**2 - z, -t**3 + y**3, y))" + + +def test_MIMOParallel_str(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tfm_1 = TransferFunctionMatrix([[tf1, tf2], [tf2, tf1]]) + tfm_2 = TransferFunctionMatrix([[tf2, tf1], [tf1, tf2]]) + assert str(MIMOParallel(tfm_1, tfm_2)) == \ + "MIMOParallel(TransferFunctionMatrix(((TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y)), "\ + "(TransferFunction(x - y, x + y, y), TransferFunction(x*y**2 - z, -t**3 + y**3, y)))), "\ + "TransferFunctionMatrix(((TransferFunction(x - y, x + y, y), TransferFunction(x*y**2 - z, -t**3 + y**3, y)), "\ + "(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y)))))" + + +def test_Feedback_str(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(t*x**2 - t**w*x + w, t - y, y) + assert str(Feedback(tf1*tf2, tf3)) == \ + "Feedback(Series(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y)), " \ + "TransferFunction(t*x**2 - t**w*x + w, t - y, y), -1)" + assert str(Feedback(tf1, TransferFunction(1, 1, y), 1)) == \ + "Feedback(TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(1, 1, y), 1)" + + +def test_MIMOFeedback_str(): + tf1 = TransferFunction(x**2 - y**3, y - z, x) + tf2 = TransferFunction(y - x, z + y, x) + tfm_1 = TransferFunctionMatrix([[tf2, tf1], [tf1, tf2]]) + tfm_2 = TransferFunctionMatrix([[tf1, tf2], [tf2, tf1]]) + assert (str(MIMOFeedback(tfm_1, tfm_2)) \ + == "MIMOFeedback(TransferFunctionMatrix(((TransferFunction(-x + y, y + z, x), TransferFunction(x**2 - y**3, y - z, x))," \ + " (TransferFunction(x**2 - y**3, y - z, x), TransferFunction(-x + y, y + z, x)))), " \ + "TransferFunctionMatrix(((TransferFunction(x**2 - y**3, y - z, x), " \ + "TransferFunction(-x + y, y + z, x)), (TransferFunction(-x + y, y + z, x), TransferFunction(x**2 - y**3, y - z, x)))), -1)") + assert (str(MIMOFeedback(tfm_1, tfm_2, 1)) \ + == "MIMOFeedback(TransferFunctionMatrix(((TransferFunction(-x + y, y + z, x), TransferFunction(x**2 - y**3, y - z, x)), " \ + "(TransferFunction(x**2 - y**3, y - z, x), TransferFunction(-x + y, y + z, x)))), " \ + "TransferFunctionMatrix(((TransferFunction(x**2 - y**3, y - z, x), TransferFunction(-x + y, y + z, x)), "\ + "(TransferFunction(-x + y, y + z, x), TransferFunction(x**2 - y**3, y - z, x)))), 1)") + + +def test_TransferFunctionMatrix_str(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(t*x**2 - t**w*x + w, t - y, y) + assert str(TransferFunctionMatrix([[tf1], [tf2]])) == \ + "TransferFunctionMatrix(((TransferFunction(x*y**2 - z, -t**3 + y**3, y),), (TransferFunction(x - y, x + y, y),)))" + assert str(TransferFunctionMatrix([[tf1, tf2], [tf3, tf2]])) == \ + "TransferFunctionMatrix(((TransferFunction(x*y**2 - z, -t**3 + y**3, y), TransferFunction(x - y, x + y, y)), (TransferFunction(t*x**2 - t**w*x + w, t - y, y), TransferFunction(x - y, x + y, y))))" + + +def test_Quaternion_str_printer(): + q = Quaternion(x, y, z, t) + assert str(q) == "x + y*i + z*j + t*k" + q = Quaternion(x,y,z,x*t) + assert str(q) == "x + y*i + z*j + t*x*k" + q = Quaternion(x,y,z,x+t) + assert str(q) == "x + y*i + z*j + (t + x)*k" + + +def test_Quantity_str(): + assert sstr(second, abbrev=True) == "s" + assert sstr(joule, abbrev=True) == "J" + assert str(second) == "second" + assert str(joule) == "joule" + + +def test_wild_str(): + # Check expressions containing Wild not causing infinite recursion + w = Wild('x') + assert str(w + 1) == 'x_ + 1' + assert str(exp(2**w) + 5) == 'exp(2**x_) + 5' + assert str(3*w + 1) == '3*x_ + 1' + assert str(1/w + 1) == '1 + 1/x_' + assert str(w**2 + 1) == 'x_**2 + 1' + assert str(1/(1 - w)) == '1/(1 - x_)' + + +def test_wild_matchpy(): + from sympy.utilities.matchpy_connector import WildDot, WildPlus, WildStar + + matchpy = import_module("matchpy") + + if matchpy is None: + return + + wd = WildDot('w_') + wp = WildPlus('w__') + ws = WildStar('w___') + + assert str(wd) == 'w_' + assert str(wp) == 'w__' + assert str(ws) == 'w___' + + assert str(wp/ws + 2**wd) == '2**w_ + w__/w___' + assert str(sin(wd)*cos(wp)*sqrt(ws)) == 'sqrt(w___)*sin(w_)*cos(w__)' + + +def test_zeta(): + assert str(zeta(3)) == "zeta(3)" + + +def test_issue_3101(): + e = x - y + a = str(e) + b = str(e) + assert a == b + + +def test_issue_3103(): + e = -2*sqrt(x) - y/sqrt(x)/2 + assert str(e) not in ["(-2)*x**1/2(-1/2)*x**(-1/2)*y", + "-2*x**1/2(-1/2)*x**(-1/2)*y", "-2*x**1/2-1/2*x**-1/2*w"] + assert str(e) == "-2*sqrt(x) - y/(2*sqrt(x))" + + +def test_issue_4021(): + e = Integral(x, x) + 1 + assert str(e) == 'Integral(x, x) + 1' + + +def test_sstrrepr(): + assert sstr('abc') == 'abc' + assert sstrrepr('abc') == "'abc'" + + e = ['a', 'b', 'c', x] + assert sstr(e) == "[a, b, c, x]" + assert sstrrepr(e) == "['a', 'b', 'c', x]" + + +def test_infinity(): + assert sstr(oo*I) == "oo*I" + + +def test_full_prec(): + assert sstr(S("0.3"), full_prec=True) == "0.300000000000000" + assert sstr(S("0.3"), full_prec="auto") == "0.300000000000000" + assert sstr(S("0.3"), full_prec=False) == "0.3" + assert sstr(S("0.3")*x, full_prec=True) in [ + "0.300000000000000*x", + "x*0.300000000000000" + ] + assert sstr(S("0.3")*x, full_prec="auto") in [ + "0.3*x", + "x*0.3" + ] + assert sstr(S("0.3")*x, full_prec=False) in [ + "0.3*x", + "x*0.3" + ] + + +def test_noncommutative(): + A, B, C = symbols('A,B,C', commutative=False) + + assert sstr(A*B*C**-1) == "A*B*C**(-1)" + assert sstr(C**-1*A*B) == "C**(-1)*A*B" + assert sstr(A*C**-1*B) == "A*C**(-1)*B" + assert sstr(sqrt(A)) == "sqrt(A)" + assert sstr(1/sqrt(A)) == "A**(-1/2)" + + +def test_empty_printer(): + str_printer = StrPrinter() + assert str_printer.emptyPrinter("foo") == "foo" + assert str_printer.emptyPrinter(x*y) == "x*y" + assert str_printer.emptyPrinter(32) == "32" + +def test_decimal_printer(): + dec_printer = StrPrinter(settings={"dps":3}) + f = Function('f') + assert dec_printer.doprint(f(1.329294)) == "f(1.33)" + + +def test_settings(): + raises(TypeError, lambda: sstr(S(4), method="garbage")) + + +def test_RandomDomain(): + from sympy.stats import Normal, Die, Exponential, pspace, where + X = Normal('x1', 0, 1) + assert str(where(X > 0)) == "Domain: (0 < x1) & (x1 < oo)" + + D = Die('d1', 6) + assert str(where(D > 4)) == "Domain: Eq(d1, 5) | Eq(d1, 6)" + + A = Exponential('a', 1) + B = Exponential('b', 1) + assert str(pspace(Tuple(A, B)).domain) == "Domain: (0 <= a) & (0 <= b) & (a < oo) & (b < oo)" + + +def test_FiniteSet(): + assert str(FiniteSet(*range(1, 51))) == ( + '{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17,' + ' 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34,' + ' 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50}' + ) + assert str(FiniteSet(*range(1, 6))) == '{1, 2, 3, 4, 5}' + assert str(FiniteSet(*[x*y, x**2])) == '{x**2, x*y}' + assert str(FiniteSet(FiniteSet(FiniteSet(x, y), 5), FiniteSet(x,y), 5) + ) == 'FiniteSet(5, FiniteSet(5, {x, y}), {x, y})' + + +def test_Partition(): + assert str(Partition(FiniteSet(x, y), {z})) == 'Partition({z}, {x, y})' + +def test_UniversalSet(): + assert str(S.UniversalSet) == 'UniversalSet' + + +def test_PrettyPoly(): + F = QQ.frac_field(x, y) + R = QQ[x, y] + assert sstr(F.convert(x/(x + y))) == sstr(x/(x + y)) + assert sstr(R.convert(x + y)) == sstr(x + y) + + +def test_categories(): + from sympy.categories import (Object, NamedMorphism, + IdentityMorphism, Category) + + A = Object("A") + B = Object("B") + + f = NamedMorphism(A, B, "f") + id_A = IdentityMorphism(A) + + K = Category("K") + + assert str(A) == 'Object("A")' + assert str(f) == 'NamedMorphism(Object("A"), Object("B"), "f")' + assert str(id_A) == 'IdentityMorphism(Object("A"))' + + assert str(K) == 'Category("K")' + + +def test_Tr(): + A, B = symbols('A B', commutative=False) + t = Tr(A*B) + assert str(t) == 'Tr(A*B)' + + +def test_issue_6387(): + assert str(factor(-3.0*z + 3)) == '-3.0*(1.0*z - 1.0)' + + +def test_MatMul_MatAdd(): + X, Y = MatrixSymbol("X", 2, 2), MatrixSymbol("Y", 2, 2) + assert str(2*(X + Y)) == "2*X + 2*Y" + + assert str(I*X) == "I*X" + assert str(-I*X) == "-I*X" + assert str((1 + I)*X) == '(1 + I)*X' + assert str(-(1 + I)*X) == '(-1 - I)*X' + assert str(MatAdd(MatAdd(X, Y), MatAdd(X, Y))) == '(X + Y) + (X + Y)' + + +def test_MatrixSlice(): + n = Symbol('n', integer=True) + X = MatrixSymbol('X', n, n) + Y = MatrixSymbol('Y', 10, 10) + Z = MatrixSymbol('Z', 10, 10) + + assert str(MatrixSlice(X, (None, None, None), (None, None, None))) == 'X[:, :]' + assert str(X[x:x + 1, y:y + 1]) == 'X[x:x + 1, y:y + 1]' + assert str(X[x:x + 1:2, y:y + 1:2]) == 'X[x:x + 1:2, y:y + 1:2]' + assert str(X[:x, y:]) == 'X[:x, y:]' + assert str(X[:x, y:]) == 'X[:x, y:]' + assert str(X[x:, :y]) == 'X[x:, :y]' + assert str(X[x:y, z:w]) == 'X[x:y, z:w]' + assert str(X[x:y:t, w:t:x]) == 'X[x:y:t, w:t:x]' + assert str(X[x::y, t::w]) == 'X[x::y, t::w]' + assert str(X[:x:y, :t:w]) == 'X[:x:y, :t:w]' + assert str(X[::x, ::y]) == 'X[::x, ::y]' + assert str(MatrixSlice(X, (0, None, None), (0, None, None))) == 'X[:, :]' + assert str(MatrixSlice(X, (None, n, None), (None, n, None))) == 'X[:, :]' + assert str(MatrixSlice(X, (0, n, None), (0, n, None))) == 'X[:, :]' + assert str(MatrixSlice(X, (0, n, 2), (0, n, 2))) == 'X[::2, ::2]' + assert str(X[1:2:3, 4:5:6]) == 'X[1:2:3, 4:5:6]' + assert str(X[1:3:5, 4:6:8]) == 'X[1:3:5, 4:6:8]' + assert str(X[1:10:2]) == 'X[1:10:2, :]' + assert str(Y[:5, 1:9:2]) == 'Y[:5, 1:9:2]' + assert str(Y[:5, 1:10:2]) == 'Y[:5, 1::2]' + assert str(Y[5, :5:2]) == 'Y[5:6, :5:2]' + assert str(X[0:1, 0:1]) == 'X[:1, :1]' + assert str(X[0:1:2, 0:1:2]) == 'X[:1:2, :1:2]' + assert str((Y + Z)[2:, 2:]) == '(Y + Z)[2:, 2:]' + +def test_true_false(): + assert str(true) == repr(true) == sstr(true) == "True" + assert str(false) == repr(false) == sstr(false) == "False" + +def test_Equivalent(): + assert str(Equivalent(y, x)) == "Equivalent(x, y)" + +def test_Xor(): + assert str(Xor(y, x, evaluate=False)) == "x ^ y" + +def test_Complement(): + assert str(Complement(S.Reals, S.Naturals)) == 'Complement(Reals, Naturals)' + +def test_SymmetricDifference(): + assert str(SymmetricDifference(Interval(2, 3), Interval(3, 4),evaluate=False)) == \ + 'SymmetricDifference(Interval(2, 3), Interval(3, 4))' + + +def test_UnevaluatedExpr(): + a, b = symbols("a b") + expr1 = 2*UnevaluatedExpr(a+b) + assert str(expr1) == "2*(a + b)" + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert(str(A[0, 0]) == "A[0, 0]") + assert(str(3 * A[0, 0]) == "3*A[0, 0]") + + F = C[0, 0].subs(C, A - B) + assert str(F) == "(A - B)[0, 0]" + + +def test_MatrixSymbol_printing(): + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + + assert str(A - A*B - B) == "A - A*B - B" + assert str(A*B - (A+B)) == "-A + A*B - B" + assert str(A**(-1)) == "A**(-1)" + assert str(A**3) == "A**3" + + +def test_MatrixExpressions(): + n = Symbol('n', integer=True) + X = MatrixSymbol('X', n, n) + + assert str(X) == "X" + + # Apply function elementwise (`ElementwiseApplyFunc`): + + expr = (X.T*X).applyfunc(sin) + assert str(expr) == 'Lambda(_d, sin(_d)).(X.T*X)' + + lamda = Lambda(x, 1/x) + expr = (n*X).applyfunc(lamda) + assert str(expr) == 'Lambda(x, 1/x).(n*X)' + + +def test_Subs_printing(): + assert str(Subs(x, (x,), (1,))) == 'Subs(x, x, 1)' + assert str(Subs(x + y, (x, y), (1, 2))) == 'Subs(x + y, (x, y), (1, 2))' + + +def test_issue_15716(): + e = Integral(factorial(x), (x, -oo, oo)) + assert e.as_terms() == ([(e, ((1.0, 0.0), (1,), ()))], [e]) + + +def test_str_special_matrices(): + from sympy.matrices import Identity, ZeroMatrix, OneMatrix + assert str(Identity(4)) == 'I' + assert str(ZeroMatrix(2, 2)) == '0' + assert str(OneMatrix(2, 2)) == '1' + + +def test_issue_14567(): + assert factorial(Sum(-1, (x, 0, 0))) + y # doesn't raise an error + + +def test_issue_21823(): + assert str(Partition([1, 2])) == 'Partition({1, 2})' + assert str(Partition({1, 2})) == 'Partition({1, 2})' + + +def test_issue_22689(): + assert str(Mul(Pow(x,-2, evaluate=False), Pow(3,-1,evaluate=False), evaluate=False)) == "1/(x**2*3)" + + +def test_issue_21119_21460(): + ss = lambda x: str(S(x, evaluate=False)) + assert ss('4/2') == '4/2' + assert ss('4/-2') == '4/(-2)' + assert ss('-4/2') == '-4/2' + assert ss('-4/-2') == '-4/(-2)' + assert ss('-2*3/-1') == '-2*3/(-1)' + assert ss('-2*3/-1/2') == '-2*3/(-1*2)' + assert ss('4/2/1') == '4/(2*1)' + assert ss('-2/-1/2') == '-2/(-1*2)' + assert ss('2*3*4**(-2*3)') == '2*3/4**(2*3)' + assert ss('2*3*1*4**(-2*3)') == '2*3*1/4**(2*3)' + + +def test_Str(): + from sympy.core.symbol import Str + assert str(Str('x')) == 'x' + assert sstrrepr(Str('x')) == "Str('x')" + + +def test_diffgeom(): + from sympy.diffgeom import Manifold, Patch, CoordSystem, BaseScalarField + x,y = symbols('x y', real=True) + m = Manifold('M', 2) + assert str(m) == "M" + p = Patch('P', m) + assert str(p) == "P" + rect = CoordSystem('rect', p, [x, y]) + assert str(rect) == "rect" + b = BaseScalarField(rect, 0) + assert str(b) == "x" + +def test_NDimArray(): + assert sstr(NDimArray(1.0), full_prec=True) == '1.00000000000000' + assert sstr(NDimArray(1.0), full_prec=False) == '1.0' + assert sstr(NDimArray([1.0, 2.0]), full_prec=True) == '[1.00000000000000, 2.00000000000000]' + assert sstr(NDimArray([1.0, 2.0]), full_prec=False) == '[1.0, 2.0]' + assert sstr(NDimArray([], (0,))) == 'ImmutableDenseNDimArray([], (0,))' + assert sstr(NDimArray([], (0, 0))) == 'ImmutableDenseNDimArray([], (0, 0))' + assert sstr(NDimArray([], (0, 1))) == 'ImmutableDenseNDimArray([], (0, 1))' + assert sstr(NDimArray([], (1, 0))) == 'ImmutableDenseNDimArray([], (1, 0))' + +def test_Predicate(): + assert sstr(Q.even) == 'Q.even' + +def test_AppliedPredicate(): + assert sstr(Q.even(x)) == 'Q.even(x)' + +def test_printing_str_array_expressions(): + assert sstr(ArraySymbol("A", (2, 3, 4))) == "A" + assert sstr(ArrayElement("A", (2, 1/(1-x), 0))) == "A[2, 1/(1 - x), 0]" + M = MatrixSymbol("M", 3, 3) + N = MatrixSymbol("N", 3, 3) + assert sstr(ArrayElement(M*N, [x, 0])) == "(M*N)[x, 0]" + +def test_printing_stats(): + # issue 24132 + x = RandomSymbol("x") + y = RandomSymbol("y") + z1 = Probability(x > 0)*Identity(2) + z2 = Expectation(x)*Identity(2) + z3 = Variance(x)*Identity(2) + z4 = Covariance(x, y) * Identity(2) + + assert str(z1) == "Probability(x > 0)*I" + assert str(z2) == "Expectation(x)*I" + assert str(z3) == "Variance(x)*I" + assert str(z4) == "Covariance(x, y)*I" + assert z1.is_commutative == False + assert z2.is_commutative == False + assert z3.is_commutative == False + assert z4.is_commutative == False + assert z2._eval_is_commutative() == False + assert z3._eval_is_commutative() == False + assert z4._eval_is_commutative() == False diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tableform.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tableform.py new file mode 100644 index 0000000000000000000000000000000000000000..05802dd104a12f2f53d137167ecf31d201ff8dfc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tableform.py @@ -0,0 +1,182 @@ +from sympy.core.singleton import S +from sympy.printing.tableform import TableForm +from sympy.printing.latex import latex +from sympy.abc import x +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import sin +from sympy.testing.pytest import raises + +from textwrap import dedent + + +def test_TableForm(): + s = str(TableForm([["a", "b"], ["c", "d"], ["e", 0]], + headings="automatic")) + assert s == ( + ' | 1 2\n' + '-------\n' + '1 | a b\n' + '2 | c d\n' + '3 | e ' + ) + s = str(TableForm([["a", "b"], ["c", "d"], ["e", 0]], + headings="automatic", wipe_zeros=False)) + assert s == dedent('''\ + | 1 2 + ------- + 1 | a b + 2 | c d + 3 | e 0''') + s = str(TableForm([[x**2, "b"], ["c", x**2], ["e", "f"]], + headings=("automatic", None))) + assert s == ( + '1 | x**2 b \n' + '2 | c x**2\n' + '3 | e f ' + ) + s = str(TableForm([["a", "b"], ["c", "d"], ["e", "f"]], + headings=(None, "automatic"))) + assert s == dedent('''\ + 1 2 + --- + a b + c d + e f''') + s = str(TableForm([[5, 7], [4, 2], [10, 3]], + headings=[["Group A", "Group B", "Group C"], ["y1", "y2"]])) + assert s == ( + ' | y1 y2\n' + '---------------\n' + 'Group A | 5 7 \n' + 'Group B | 4 2 \n' + 'Group C | 10 3 ' + ) + raises( + ValueError, + lambda: + TableForm( + [[5, 7], [4, 2], [10, 3]], + headings=[["Group A", "Group B", "Group C"], ["y1", "y2"]], + alignments="middle") + ) + s = str(TableForm([[5, 7], [4, 2], [10, 3]], + headings=[["Group A", "Group B", "Group C"], ["y1", "y2"]], + alignments="right")) + assert s == dedent('''\ + | y1 y2 + --------------- + Group A | 5 7 + Group B | 4 2 + Group C | 10 3''') + + # other alignment permutations + d = [[1, 100], [100, 1]] + s = TableForm(d, headings=(('xxx', 'x'), None), alignments='l') + assert str(s) == ( + 'xxx | 1 100\n' + ' x | 100 1 ' + ) + s = TableForm(d, headings=(('xxx', 'x'), None), alignments='lr') + assert str(s) == dedent('''\ + xxx | 1 100 + x | 100 1''') + s = TableForm(d, headings=(('xxx', 'x'), None), alignments='clr') + assert str(s) == dedent('''\ + xxx | 1 100 + x | 100 1''') + + s = TableForm(d, headings=(('xxx', 'x'), None)) + assert str(s) == ( + 'xxx | 1 100\n' + ' x | 100 1 ' + ) + + raises(ValueError, lambda: TableForm(d, alignments='clr')) + + #pad + s = str(TableForm([[None, "-", 2], [1]], pad='?')) + assert s == dedent('''\ + ? - 2 + 1 ? ?''') + + +def test_TableForm_latex(): + s = latex(TableForm([[0, x**3], ["c", S.One/4], [sqrt(x), sin(x**2)]], + wipe_zeros=True, headings=("automatic", "automatic"))) + assert s == ( + '\\begin{tabular}{r l l}\n' + ' & 1 & 2 \\\\\n' + '\\hline\n' + '1 & & $x^{3}$ \\\\\n' + '2 & $c$ & $\\frac{1}{4}$ \\\\\n' + '3 & $\\sqrt{x}$ & $\\sin{\\left(x^{2} \\right)}$ \\\\\n' + '\\end{tabular}' + ) + s = latex(TableForm([[0, x**3], ["c", S.One/4], [sqrt(x), sin(x**2)]], + wipe_zeros=True, headings=("automatic", "automatic"), alignments='l')) + assert s == ( + '\\begin{tabular}{r l l}\n' + ' & 1 & 2 \\\\\n' + '\\hline\n' + '1 & & $x^{3}$ \\\\\n' + '2 & $c$ & $\\frac{1}{4}$ \\\\\n' + '3 & $\\sqrt{x}$ & $\\sin{\\left(x^{2} \\right)}$ \\\\\n' + '\\end{tabular}' + ) + s = latex(TableForm([[0, x**3], ["c", S.One/4], [sqrt(x), sin(x**2)]], + wipe_zeros=True, headings=("automatic", "automatic"), alignments='l'*3)) + assert s == ( + '\\begin{tabular}{l l l}\n' + ' & 1 & 2 \\\\\n' + '\\hline\n' + '1 & & $x^{3}$ \\\\\n' + '2 & $c$ & $\\frac{1}{4}$ \\\\\n' + '3 & $\\sqrt{x}$ & $\\sin{\\left(x^{2} \\right)}$ \\\\\n' + '\\end{tabular}' + ) + s = latex(TableForm([["a", x**3], ["c", S.One/4], [sqrt(x), sin(x**2)]], + headings=("automatic", "automatic"))) + assert s == ( + '\\begin{tabular}{r l l}\n' + ' & 1 & 2 \\\\\n' + '\\hline\n' + '1 & $a$ & $x^{3}$ \\\\\n' + '2 & $c$ & $\\frac{1}{4}$ \\\\\n' + '3 & $\\sqrt{x}$ & $\\sin{\\left(x^{2} \\right)}$ \\\\\n' + '\\end{tabular}' + ) + s = latex(TableForm([["a", x**3], ["c", S.One/4], [sqrt(x), sin(x**2)]], + formats=['(%s)', None], headings=("automatic", "automatic"))) + assert s == ( + '\\begin{tabular}{r l l}\n' + ' & 1 & 2 \\\\\n' + '\\hline\n' + '1 & (a) & $x^{3}$ \\\\\n' + '2 & (c) & $\\frac{1}{4}$ \\\\\n' + '3 & (sqrt(x)) & $\\sin{\\left(x^{2} \\right)}$ \\\\\n' + '\\end{tabular}' + ) + + def neg_in_paren(x, i, j): + if i % 2: + return ('(%s)' if x < 0 else '%s') % x + else: + pass # use default print + s = latex(TableForm([[-1, 2], [-3, 4]], + formats=[neg_in_paren]*2, headings=("automatic", "automatic"))) + assert s == ( + '\\begin{tabular}{r l l}\n' + ' & 1 & 2 \\\\\n' + '\\hline\n' + '1 & -1 & 2 \\\\\n' + '2 & (-3) & 4 \\\\\n' + '\\end{tabular}' + ) + s = latex(TableForm([["a", x**3], ["c", S.One/4], [sqrt(x), sin(x**2)]])) + assert s == ( + '\\begin{tabular}{l l}\n' + '$a$ & $x^{3}$ \\\\\n' + '$c$ & $\\frac{1}{4}$ \\\\\n' + '$\\sqrt{x}$ & $\\sin{\\left(x^{2} \\right)}$ \\\\\n' + '\\end{tabular}' + ) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tensorflow.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tensorflow.py new file mode 100644 index 0000000000000000000000000000000000000000..e9c92cd17b13e1148ebf83f13f66854b983491fe --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tensorflow.py @@ -0,0 +1,493 @@ +import random +from sympy.core.function import Derivative +from sympy.core.symbol import symbols +from sympy import Piecewise +from sympy.tensor.array.expressions.array_expressions import ArrayTensorProduct, ArrayAdd, \ + PermuteDims, ArrayDiagonal +from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt +from sympy.external import import_module +from sympy.functions import \ + Abs, ceiling, exp, floor, sign, sin, asin, sqrt, cos, \ + acos, tan, atan, atan2, cosh, acosh, sinh, asinh, tanh, atanh, \ + re, im, arg, erf, loggamma, log +from sympy.codegen.cfunctions import isnan, isinf +from sympy.matrices import Matrix, MatrixBase, eye, randMatrix +from sympy.matrices.expressions import \ + Determinant, HadamardProduct, Inverse, MatrixSymbol, Trace +from sympy.printing.tensorflow import tensorflow_code +from sympy.tensor.array.expressions.from_matrix_to_array import convert_matrix_to_array +from sympy.utilities.lambdify import lambdify +from sympy.testing.pytest import skip +from sympy.testing.pytest import XFAIL + + +tf = tensorflow = import_module("tensorflow") + +if tensorflow: + # Hide Tensorflow warnings + import os + os.environ['TF_CPP_MIN_LOG_LEVEL'] = '2' + + +M = MatrixSymbol("M", 3, 3) +N = MatrixSymbol("N", 3, 3) +P = MatrixSymbol("P", 3, 3) +Q = MatrixSymbol("Q", 3, 3) + +x, y, z, t = symbols("x y z t") + +if tf is not None: + llo = [list(range(i, i+3)) for i in range(0, 9, 3)] + m3x3 = tf.constant(llo) + m3x3sympy = Matrix(llo) + + +def _compare_tensorflow_matrix(variables, expr, use_float=False): + f = lambdify(variables, expr, 'tensorflow') + if not use_float: + random_matrices = [randMatrix(v.rows, v.cols) for v in variables] + else: + random_matrices = [randMatrix(v.rows, v.cols)/100. for v in variables] + + graph = tf.Graph() + r = None + with graph.as_default(): + random_variables = [eval(tensorflow_code(i)) for i in random_matrices] + session = tf.compat.v1.Session(graph=graph) + r = session.run(f(*random_variables)) + + e = expr.subs(dict(zip(variables, random_matrices))) + e = e.doit() + if e.is_Matrix: + if not isinstance(e, MatrixBase): + e = e.as_explicit() + e = e.tolist() + + if not use_float: + assert (r == e).all() + else: + r = [i for row in r for i in row] + e = [i for row in e for i in row] + assert all( + abs(a-b) < 10**-(4-int(log(abs(a), 10))) for a, b in zip(r, e)) + + +# Creating a custom inverse test. +# See https://github.com/sympy/sympy/issues/18469 +def _compare_tensorflow_matrix_inverse(variables, expr, use_float=False): + f = lambdify(variables, expr, 'tensorflow') + if not use_float: + random_matrices = [eye(v.rows, v.cols)*4 for v in variables] + else: + random_matrices = [eye(v.rows, v.cols)*3.14 for v in variables] + + graph = tf.Graph() + r = None + with graph.as_default(): + random_variables = [eval(tensorflow_code(i)) for i in random_matrices] + session = tf.compat.v1.Session(graph=graph) + r = session.run(f(*random_variables)) + + e = expr.subs(dict(zip(variables, random_matrices))) + e = e.doit() + if e.is_Matrix: + if not isinstance(e, MatrixBase): + e = e.as_explicit() + e = e.tolist() + + if not use_float: + assert (r == e).all() + else: + r = [i for row in r for i in row] + e = [i for row in e for i in row] + assert all( + abs(a-b) < 10**-(4-int(log(abs(a), 10))) for a, b in zip(r, e)) + + +def _compare_tensorflow_matrix_scalar(variables, expr): + f = lambdify(variables, expr, 'tensorflow') + random_matrices = [ + randMatrix(v.rows, v.cols).evalf() / 100 for v in variables] + + graph = tf.Graph() + r = None + with graph.as_default(): + random_variables = [eval(tensorflow_code(i)) for i in random_matrices] + session = tf.compat.v1.Session(graph=graph) + r = session.run(f(*random_variables)) + + e = expr.subs(dict(zip(variables, random_matrices))) + e = e.doit() + assert abs(r-e) < 10**-6 + + +def _compare_tensorflow_scalar( + variables, expr, rng=lambda: random.randint(0, 10)): + f = lambdify(variables, expr, 'tensorflow') + rvs = [rng() for v in variables] + + graph = tf.Graph() + r = None + with graph.as_default(): + tf_rvs = [eval(tensorflow_code(i)) for i in rvs] + session = tf.compat.v1.Session(graph=graph) + r = session.run(f(*tf_rvs)) + + e = expr.subs(dict(zip(variables, rvs))).evalf().doit() + assert abs(r-e) < 10**-6 + + +def _compare_tensorflow_relational( + variables, expr, rng=lambda: random.randint(0, 10)): + f = lambdify(variables, expr, 'tensorflow') + rvs = [rng() for v in variables] + + graph = tf.Graph() + r = None + with graph.as_default(): + tf_rvs = [eval(tensorflow_code(i)) for i in rvs] + session = tf.compat.v1.Session(graph=graph) + r = session.run(f(*tf_rvs)) + + e = expr.subs(dict(zip(variables, rvs))).doit() + assert r == e + + +def test_tensorflow_printing(): + assert tensorflow_code(eye(3)) == \ + "tensorflow.constant([[1, 0, 0], [0, 1, 0], [0, 0, 1]])" + + expr = Matrix([[x, sin(y)], [exp(z), -t]]) + assert tensorflow_code(expr) == \ + "tensorflow.Variable(" \ + "[[x, tensorflow.math.sin(y)]," \ + " [tensorflow.math.exp(z), -t]])" + + +# This (random) test is XFAIL because it fails occasionally +# See https://github.com/sympy/sympy/issues/18469 +@XFAIL +def test_tensorflow_math(): + if not tf: + skip("TensorFlow not installed") + + expr = Abs(x) + assert tensorflow_code(expr) == "tensorflow.math.abs(x)" + _compare_tensorflow_scalar((x,), expr) + + expr = sign(x) + assert tensorflow_code(expr) == "tensorflow.math.sign(x)" + _compare_tensorflow_scalar((x,), expr) + + expr = ceiling(x) + assert tensorflow_code(expr) == "tensorflow.math.ceil(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = floor(x) + assert tensorflow_code(expr) == "tensorflow.math.floor(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = exp(x) + assert tensorflow_code(expr) == "tensorflow.math.exp(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = sqrt(x) + assert tensorflow_code(expr) == "tensorflow.math.sqrt(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = x ** 4 + assert tensorflow_code(expr) == "tensorflow.math.pow(x, 4)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = cos(x) + assert tensorflow_code(expr) == "tensorflow.math.cos(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = acos(x) + assert tensorflow_code(expr) == "tensorflow.math.acos(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.uniform(0, 0.95)) + + expr = sin(x) + assert tensorflow_code(expr) == "tensorflow.math.sin(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = asin(x) + assert tensorflow_code(expr) == "tensorflow.math.asin(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = tan(x) + assert tensorflow_code(expr) == "tensorflow.math.tan(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = atan(x) + assert tensorflow_code(expr) == "tensorflow.math.atan(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = atan2(y, x) + assert tensorflow_code(expr) == "tensorflow.math.atan2(y, x)" + _compare_tensorflow_scalar((y, x), expr, rng=lambda: random.random()) + + expr = cosh(x) + assert tensorflow_code(expr) == "tensorflow.math.cosh(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.random()) + + expr = acosh(x) + assert tensorflow_code(expr) == "tensorflow.math.acosh(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.uniform(1, 2)) + + expr = sinh(x) + assert tensorflow_code(expr) == "tensorflow.math.sinh(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.uniform(1, 2)) + + expr = asinh(x) + assert tensorflow_code(expr) == "tensorflow.math.asinh(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.uniform(1, 2)) + + expr = tanh(x) + assert tensorflow_code(expr) == "tensorflow.math.tanh(x)" + _compare_tensorflow_scalar((x,), expr, rng=lambda: random.uniform(1, 2)) + + expr = atanh(x) + assert tensorflow_code(expr) == "tensorflow.math.atanh(x)" + _compare_tensorflow_scalar( + (x,), expr, rng=lambda: random.uniform(-.5, .5)) + + expr = erf(x) + assert tensorflow_code(expr) == "tensorflow.math.erf(x)" + _compare_tensorflow_scalar( + (x,), expr, rng=lambda: random.random()) + + expr = loggamma(x) + assert tensorflow_code(expr) == "tensorflow.math.lgamma(x)" + _compare_tensorflow_scalar( + (x,), expr, rng=lambda: random.random()) + + +def test_tensorflow_complexes(): + assert tensorflow_code(re(x)) == "tensorflow.math.real(x)" + assert tensorflow_code(im(x)) == "tensorflow.math.imag(x)" + assert tensorflow_code(arg(x)) == "tensorflow.math.angle(x)" + + +def test_tensorflow_relational(): + if not tf: + skip("TensorFlow not installed") + + expr = Eq(x, y) + assert tensorflow_code(expr) == "tensorflow.math.equal(x, y)" + _compare_tensorflow_relational((x, y), expr) + + expr = Ne(x, y) + assert tensorflow_code(expr) == "tensorflow.math.not_equal(x, y)" + _compare_tensorflow_relational((x, y), expr) + + expr = Ge(x, y) + assert tensorflow_code(expr) == "tensorflow.math.greater_equal(x, y)" + _compare_tensorflow_relational((x, y), expr) + + expr = Gt(x, y) + assert tensorflow_code(expr) == "tensorflow.math.greater(x, y)" + _compare_tensorflow_relational((x, y), expr) + + expr = Le(x, y) + assert tensorflow_code(expr) == "tensorflow.math.less_equal(x, y)" + _compare_tensorflow_relational((x, y), expr) + + expr = Lt(x, y) + assert tensorflow_code(expr) == "tensorflow.math.less(x, y)" + _compare_tensorflow_relational((x, y), expr) + + +# This (random) test is XFAIL because it fails occasionally +# See https://github.com/sympy/sympy/issues/18469 +@XFAIL +def test_tensorflow_matrices(): + if not tf: + skip("TensorFlow not installed") + + expr = M + assert tensorflow_code(expr) == "M" + _compare_tensorflow_matrix((M,), expr) + + expr = M + N + assert tensorflow_code(expr) == "tensorflow.math.add(M, N)" + _compare_tensorflow_matrix((M, N), expr) + + expr = M * N + assert tensorflow_code(expr) == "tensorflow.linalg.matmul(M, N)" + _compare_tensorflow_matrix((M, N), expr) + + expr = HadamardProduct(M, N) + assert tensorflow_code(expr) == "tensorflow.math.multiply(M, N)" + _compare_tensorflow_matrix((M, N), expr) + + expr = M*N*P*Q + assert tensorflow_code(expr) == \ + "tensorflow.linalg.matmul(" \ + "tensorflow.linalg.matmul(" \ + "tensorflow.linalg.matmul(M, N), P), Q)" + _compare_tensorflow_matrix((M, N, P, Q), expr) + + expr = M**3 + assert tensorflow_code(expr) == \ + "tensorflow.linalg.matmul(tensorflow.linalg.matmul(M, M), M)" + _compare_tensorflow_matrix((M,), expr) + + expr = Trace(M) + assert tensorflow_code(expr) == "tensorflow.linalg.trace(M)" + _compare_tensorflow_matrix((M,), expr) + + expr = Determinant(M) + assert tensorflow_code(expr) == "tensorflow.linalg.det(M)" + _compare_tensorflow_matrix_scalar((M,), expr) + + expr = Inverse(M) + assert tensorflow_code(expr) == "tensorflow.linalg.inv(M)" + _compare_tensorflow_matrix_inverse((M,), expr, use_float=True) + + expr = M.T + assert tensorflow_code(expr, tensorflow_version='1.14') == \ + "tensorflow.linalg.matrix_transpose(M)" + assert tensorflow_code(expr, tensorflow_version='1.13') == \ + "tensorflow.matrix_transpose(M)" + + _compare_tensorflow_matrix((M,), expr) + + +def test_codegen_einsum(): + if not tf: + skip("TensorFlow not installed") + + graph = tf.Graph() + with graph.as_default(): + session = tf.compat.v1.Session(graph=graph) + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + + cg = convert_matrix_to_array(M * N) + f = lambdify((M, N), cg, 'tensorflow') + + ma = tf.constant([[1, 2], [3, 4]]) + mb = tf.constant([[1,-2], [-1, 3]]) + y = session.run(f(ma, mb)) + c = session.run(tf.matmul(ma, mb)) + assert (y == c).all() + + +def test_codegen_extra(): + if not tf: + skip("TensorFlow not installed") + + graph = tf.Graph() + with graph.as_default(): + session = tf.compat.v1.Session() + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + P = MatrixSymbol("P", 2, 2) + Q = MatrixSymbol("Q", 2, 2) + ma = tf.constant([[1, 2], [3, 4]]) + mb = tf.constant([[1,-2], [-1, 3]]) + mc = tf.constant([[2, 0], [1, 2]]) + md = tf.constant([[1,-1], [4, 7]]) + + cg = ArrayTensorProduct(M, N) + assert tensorflow_code(cg) == \ + 'tensorflow.linalg.einsum("ab,cd", M, N)' + f = lambdify((M, N), cg, 'tensorflow') + y = session.run(f(ma, mb)) + c = session.run(tf.einsum("ij,kl", ma, mb)) + assert (y == c).all() + + cg = ArrayAdd(M, N) + assert tensorflow_code(cg) == 'tensorflow.math.add(M, N)' + f = lambdify((M, N), cg, 'tensorflow') + y = session.run(f(ma, mb)) + c = session.run(ma + mb) + assert (y == c).all() + + cg = ArrayAdd(M, N, P) + assert tensorflow_code(cg) == \ + 'tensorflow.math.add(tensorflow.math.add(M, N), P)' + f = lambdify((M, N, P), cg, 'tensorflow') + y = session.run(f(ma, mb, mc)) + c = session.run(ma + mb + mc) + assert (y == c).all() + + cg = ArrayAdd(M, N, P, Q) + assert tensorflow_code(cg) == \ + 'tensorflow.math.add(' \ + 'tensorflow.math.add(tensorflow.math.add(M, N), P), Q)' + f = lambdify((M, N, P, Q), cg, 'tensorflow') + y = session.run(f(ma, mb, mc, md)) + c = session.run(ma + mb + mc + md) + assert (y == c).all() + + cg = PermuteDims(M, [1, 0]) + assert tensorflow_code(cg) == 'tensorflow.transpose(M, [1, 0])' + f = lambdify((M,), cg, 'tensorflow') + y = session.run(f(ma)) + c = session.run(tf.transpose(ma)) + assert (y == c).all() + + cg = PermuteDims(ArrayTensorProduct(M, N), [1, 2, 3, 0]) + assert tensorflow_code(cg) == \ + 'tensorflow.transpose(' \ + 'tensorflow.linalg.einsum("ab,cd", M, N), [1, 2, 3, 0])' + f = lambdify((M, N), cg, 'tensorflow') + y = session.run(f(ma, mb)) + c = session.run(tf.transpose(tf.einsum("ab,cd", ma, mb), [1, 2, 3, 0])) + assert (y == c).all() + + cg = ArrayDiagonal(ArrayTensorProduct(M, N), (1, 2)) + assert tensorflow_code(cg) == \ + 'tensorflow.linalg.einsum("ab,bc->acb", M, N)' + f = lambdify((M, N), cg, 'tensorflow') + y = session.run(f(ma, mb)) + c = session.run(tf.einsum("ab,bc->acb", ma, mb)) + assert (y == c).all() + + +def test_MatrixElement_printing(): + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert tensorflow_code(A[0, 0]) == "A[0, 0]" + assert tensorflow_code(3 * A[0, 0]) == "3*A[0, 0]" + + F = C[0, 0].subs(C, A - B) + assert tensorflow_code(F) == "(tensorflow.math.add((-1)*B, A))[0, 0]" + + +def test_tensorflow_Derivative(): + expr = Derivative(sin(x), x) + assert tensorflow_code(expr) == \ + "tensorflow.gradients(tensorflow.math.sin(x), x)[0]" + +def test_tensorflow_isnan_isinf(): + if not tf: + skip("TensorFlow not installed") + + # Test for isnan + x = symbols("x") + # Return 0 if x is of nan value, and 1 otherwise + expression = Piecewise((0.0, isnan(x)), (1.0, True)) + printed_code = tensorflow_code(expression) + expected_printed_code = "tensorflow.where(tensorflow.math.is_nan(x), 0.0, 1.0)" + assert tensorflow_code(expression) == expected_printed_code, f"Incorrect printed result {printed_code}, expected {expected_printed_code}" + for _input, _expected in [(float('nan'), 0.0), (float('inf'), 1.0), (float('-inf'), 1.0), (1.0, 1.0)]: + _output = lambdify((x), expression, modules="tensorflow")(x=tf.constant([_input])) + assert (_output == _expected).numpy().all() + + # Test for isinf + x = symbols("x") + # Return 0 if x is of nan value, and 1 otherwise + expression = Piecewise((0.0, isinf(x)), (1.0, True)) + printed_code = tensorflow_code(expression) + expected_printed_code = "tensorflow.where(tensorflow.math.is_inf(x), 0.0, 1.0)" + assert tensorflow_code(expression) == expected_printed_code, f"Incorrect printed result {printed_code}, expected {expected_printed_code}" + for _input, _expected in [(float('inf'), 0.0), (float('-inf'), 0.0), (float('nan'), 1.0), (1.0, 1.0)]: + _output = lambdify((x), expression, modules="tensorflow")(x=tf.constant([_input])) + assert (_output == _expected).numpy().all() diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_theanocode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_theanocode.py new file mode 100644 index 0000000000000000000000000000000000000000..6ff40f78cb4de16149cb5e780756b7e32b574b71 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_theanocode.py @@ -0,0 +1,639 @@ +""" +Important note on tests in this module - the Theano printing functions use a +global cache by default, which means that tests using it will modify global +state and thus not be independent from each other. Instead of using the "cache" +keyword argument each time, this module uses the theano_code_ and +theano_function_ functions defined below which default to using a new, empty +cache instead. +""" + +import logging + +from sympy.external import import_module +from sympy.testing.pytest import raises, SKIP, warns_deprecated_sympy + +theanologger = logging.getLogger('theano.configdefaults') +theanologger.setLevel(logging.CRITICAL) +theano = import_module('theano') +theanologger.setLevel(logging.WARNING) + + +if theano: + import numpy as np + ts = theano.scalar + tt = theano.tensor + xt, yt, zt = [tt.scalar(name, 'floatX') for name in 'xyz'] + Xt, Yt, Zt = [tt.tensor('floatX', (False, False), name=n) for n in 'XYZ'] +else: + #bin/test will not execute any tests now + disabled = True + +import sympy as sy +from sympy.core.singleton import S +from sympy.abc import x, y, z, t +from sympy.printing.theanocode import (theano_code, dim_handling, + theano_function) + + +# Default set of matrix symbols for testing - make square so we can both +# multiply and perform elementwise operations between them. +X, Y, Z = [sy.MatrixSymbol(n, 4, 4) for n in 'XYZ'] + +# For testing AppliedUndef +f_t = sy.Function('f')(t) + + +def theano_code_(expr, **kwargs): + """ Wrapper for theano_code that uses a new, empty cache by default. """ + kwargs.setdefault('cache', {}) + with warns_deprecated_sympy(): + return theano_code(expr, **kwargs) + +def theano_function_(inputs, outputs, **kwargs): + """ Wrapper for theano_function that uses a new, empty cache by default. """ + kwargs.setdefault('cache', {}) + with warns_deprecated_sympy(): + return theano_function(inputs, outputs, **kwargs) + + +def fgraph_of(*exprs): + """ Transform SymPy expressions into Theano Computation. + + Parameters + ========== + exprs + SymPy expressions + + Returns + ======= + theano.gof.FunctionGraph + """ + outs = list(map(theano_code_, exprs)) + ins = theano.gof.graph.inputs(outs) + ins, outs = theano.gof.graph.clone(ins, outs) + return theano.gof.FunctionGraph(ins, outs) + + +def theano_simplify(fgraph): + """ Simplify a Theano Computation. + + Parameters + ========== + fgraph : theano.gof.FunctionGraph + + Returns + ======= + theano.gof.FunctionGraph + """ + mode = theano.compile.get_default_mode().excluding("fusion") + fgraph = fgraph.clone() + mode.optimizer.optimize(fgraph) + return fgraph + + +def theq(a, b): + """ Test two Theano objects for equality. + + Also accepts numeric types and lists/tuples of supported types. + + Note - debugprint() has a bug where it will accept numeric types but does + not respect the "file" argument and in this case and instead prints the number + to stdout and returns an empty string. This can lead to tests passing where + they should fail because any two numbers will always compare as equal. To + prevent this we treat numbers as a separate case. + """ + numeric_types = (int, float, np.number) + a_is_num = isinstance(a, numeric_types) + b_is_num = isinstance(b, numeric_types) + + # Compare numeric types using regular equality + if a_is_num or b_is_num: + if not (a_is_num and b_is_num): + return False + + return a == b + + # Compare sequences element-wise + a_is_seq = isinstance(a, (tuple, list)) + b_is_seq = isinstance(b, (tuple, list)) + + if a_is_seq or b_is_seq: + if not (a_is_seq and b_is_seq) or type(a) != type(b): + return False + + return list(map(theq, a)) == list(map(theq, b)) + + # Otherwise, assume debugprint() can handle it + astr = theano.printing.debugprint(a, file='str') + bstr = theano.printing.debugprint(b, file='str') + + # Check for bug mentioned above + for argname, argval, argstr in [('a', a, astr), ('b', b, bstr)]: + if argstr == '': + raise TypeError( + 'theano.printing.debugprint(%s) returned empty string ' + '(%s is instance of %r)' + % (argname, argname, type(argval)) + ) + + return astr == bstr + + +def test_example_symbols(): + """ + Check that the example symbols in this module print to their Theano + equivalents, as many of the other tests depend on this. + """ + assert theq(xt, theano_code_(x)) + assert theq(yt, theano_code_(y)) + assert theq(zt, theano_code_(z)) + assert theq(Xt, theano_code_(X)) + assert theq(Yt, theano_code_(Y)) + assert theq(Zt, theano_code_(Z)) + + +def test_Symbol(): + """ Test printing a Symbol to a theano variable. """ + xx = theano_code_(x) + assert isinstance(xx, (tt.TensorVariable, ts.ScalarVariable)) + assert xx.broadcastable == () + assert xx.name == x.name + + xx2 = theano_code_(x, broadcastables={x: (False,)}) + assert xx2.broadcastable == (False,) + assert xx2.name == x.name + +def test_MatrixSymbol(): + """ Test printing a MatrixSymbol to a theano variable. """ + XX = theano_code_(X) + assert isinstance(XX, tt.TensorVariable) + assert XX.broadcastable == (False, False) + +@SKIP # TODO - this is currently not checked but should be implemented +def test_MatrixSymbol_wrong_dims(): + """ Test MatrixSymbol with invalid broadcastable. """ + bcs = [(), (False,), (True,), (True, False), (False, True,), (True, True)] + for bc in bcs: + with raises(ValueError): + theano_code_(X, broadcastables={X: bc}) + +def test_AppliedUndef(): + """ Test printing AppliedUndef instance, which works similarly to Symbol. """ + ftt = theano_code_(f_t) + assert isinstance(ftt, tt.TensorVariable) + assert ftt.broadcastable == () + assert ftt.name == 'f_t' + + +def test_add(): + expr = x + y + comp = theano_code_(expr) + assert comp.owner.op == theano.tensor.add + +def test_trig(): + assert theq(theano_code_(sy.sin(x)), tt.sin(xt)) + assert theq(theano_code_(sy.tan(x)), tt.tan(xt)) + +def test_many(): + """ Test printing a complex expression with multiple symbols. """ + expr = sy.exp(x**2 + sy.cos(y)) * sy.log(2*z) + comp = theano_code_(expr) + expected = tt.exp(xt**2 + tt.cos(yt)) * tt.log(2*zt) + assert theq(comp, expected) + + +def test_dtype(): + """ Test specifying specific data types through the dtype argument. """ + for dtype in ['float32', 'float64', 'int8', 'int16', 'int32', 'int64']: + assert theano_code_(x, dtypes={x: dtype}).type.dtype == dtype + + # "floatX" type + assert theano_code_(x, dtypes={x: 'floatX'}).type.dtype in ('float32', 'float64') + + # Type promotion + assert theano_code_(x + 1, dtypes={x: 'float32'}).type.dtype == 'float32' + assert theano_code_(x + y, dtypes={x: 'float64', y: 'float32'}).type.dtype == 'float64' + + +def test_broadcastables(): + """ Test the "broadcastables" argument when printing symbol-like objects. """ + + # No restrictions on shape + for s in [x, f_t]: + for bc in [(), (False,), (True,), (False, False), (True, False)]: + assert theano_code_(s, broadcastables={s: bc}).broadcastable == bc + + # TODO - matrix broadcasting? + +def test_broadcasting(): + """ Test "broadcastable" attribute after applying element-wise binary op. """ + + expr = x + y + + cases = [ + [(), (), ()], + [(False,), (False,), (False,)], + [(True,), (False,), (False,)], + [(False, True), (False, False), (False, False)], + [(True, False), (False, False), (False, False)], + ] + + for bc1, bc2, bc3 in cases: + comp = theano_code_(expr, broadcastables={x: bc1, y: bc2}) + assert comp.broadcastable == bc3 + + +def test_MatMul(): + expr = X*Y*Z + expr_t = theano_code_(expr) + assert isinstance(expr_t.owner.op, tt.Dot) + assert theq(expr_t, Xt.dot(Yt).dot(Zt)) + +def test_Transpose(): + assert isinstance(theano_code_(X.T).owner.op, tt.DimShuffle) + +def test_MatAdd(): + expr = X+Y+Z + assert isinstance(theano_code_(expr).owner.op, tt.Elemwise) + + +def test_Rationals(): + assert theq(theano_code_(sy.Integer(2) / 3), tt.true_div(2, 3)) + assert theq(theano_code_(S.Half), tt.true_div(1, 2)) + +def test_Integers(): + assert theano_code_(sy.Integer(3)) == 3 + +def test_factorial(): + n = sy.Symbol('n') + assert theano_code_(sy.factorial(n)) + +def test_Derivative(): + simp = lambda expr: theano_simplify(fgraph_of(expr)) + assert theq(simp(theano_code_(sy.Derivative(sy.sin(x), x, evaluate=False))), + simp(theano.grad(tt.sin(xt), xt))) + + +def test_theano_function_simple(): + """ Test theano_function() with single output. """ + f = theano_function_([x, y], [x+y]) + assert f(2, 3) == 5 + +def test_theano_function_multi(): + """ Test theano_function() with multiple outputs. """ + f = theano_function_([x, y], [x+y, x-y]) + o1, o2 = f(2, 3) + assert o1 == 5 + assert o2 == -1 + +def test_theano_function_numpy(): + """ Test theano_function() vs Numpy implementation. """ + f = theano_function_([x, y], [x+y], dim=1, + dtypes={x: 'float64', y: 'float64'}) + assert np.linalg.norm(f([1, 2], [3, 4]) - np.asarray([4, 6])) < 1e-9 + + f = theano_function_([x, y], [x+y], dtypes={x: 'float64', y: 'float64'}, + dim=1) + xx = np.arange(3).astype('float64') + yy = 2*np.arange(3).astype('float64') + assert np.linalg.norm(f(xx, yy) - 3*np.arange(3)) < 1e-9 + + +def test_theano_function_matrix(): + m = sy.Matrix([[x, y], [z, x + y + z]]) + expected = np.array([[1.0, 2.0], [3.0, 1.0 + 2.0 + 3.0]]) + f = theano_function_([x, y, z], [m]) + np.testing.assert_allclose(f(1.0, 2.0, 3.0), expected) + f = theano_function_([x, y, z], [m], scalar=True) + np.testing.assert_allclose(f(1.0, 2.0, 3.0), expected) + f = theano_function_([x, y, z], [m, m]) + assert isinstance(f(1.0, 2.0, 3.0), type([])) + np.testing.assert_allclose(f(1.0, 2.0, 3.0)[0], expected) + np.testing.assert_allclose(f(1.0, 2.0, 3.0)[1], expected) + +def test_dim_handling(): + assert dim_handling([x], dim=2) == {x: (False, False)} + assert dim_handling([x, y], dims={x: 1, y: 2}) == {x: (False, True), + y: (False, False)} + assert dim_handling([x], broadcastables={x: (False,)}) == {x: (False,)} + +def test_theano_function_kwargs(): + """ + Test passing additional kwargs from theano_function() to theano.function(). + """ + import numpy as np + f = theano_function_([x, y, z], [x+y], dim=1, on_unused_input='ignore', + dtypes={x: 'float64', y: 'float64', z: 'float64'}) + assert np.linalg.norm(f([1, 2], [3, 4], [0, 0]) - np.asarray([4, 6])) < 1e-9 + + f = theano_function_([x, y, z], [x+y], + dtypes={x: 'float64', y: 'float64', z: 'float64'}, + dim=1, on_unused_input='ignore') + xx = np.arange(3).astype('float64') + yy = 2*np.arange(3).astype('float64') + zz = 2*np.arange(3).astype('float64') + assert np.linalg.norm(f(xx, yy, zz) - 3*np.arange(3)) < 1e-9 + +def test_theano_function_scalar(): + """ Test the "scalar" argument to theano_function(). """ + + args = [ + ([x, y], [x + y], None, [0]), # Single 0d output + ([X, Y], [X + Y], None, [2]), # Single 2d output + ([x, y], [x + y], {x: 0, y: 1}, [1]), # Single 1d output + ([x, y], [x + y, x - y], None, [0, 0]), # Two 0d outputs + ([x, y, X, Y], [x + y, X + Y], None, [0, 2]), # One 0d output, one 2d + ] + + # Create and test functions with and without the scalar setting + for inputs, outputs, in_dims, out_dims in args: + for scalar in [False, True]: + + f = theano_function_(inputs, outputs, dims=in_dims, scalar=scalar) + + # Check the theano_function attribute is set whether wrapped or not + assert isinstance(f.theano_function, theano.compile.function_module.Function) + + # Feed in inputs of the appropriate size and get outputs + in_values = [ + np.ones([1 if bc else 5 for bc in i.type.broadcastable]) + for i in f.theano_function.input_storage + ] + out_values = f(*in_values) + if not isinstance(out_values, list): + out_values = [out_values] + + # Check output types and shapes + assert len(out_dims) == len(out_values) + for d, value in zip(out_dims, out_values): + + if scalar and d == 0: + # Should have been converted to a scalar value + assert isinstance(value, np.number) + + else: + # Otherwise should be an array + assert isinstance(value, np.ndarray) + assert value.ndim == d + +def test_theano_function_bad_kwarg(): + """ + Passing an unknown keyword argument to theano_function() should raise an + exception. + """ + raises(Exception, lambda : theano_function_([x], [x+1], foobar=3)) + + +def test_slice(): + assert theano_code_(slice(1, 2, 3)) == slice(1, 2, 3) + + def theq_slice(s1, s2): + for attr in ['start', 'stop', 'step']: + a1 = getattr(s1, attr) + a2 = getattr(s2, attr) + if a1 is None or a2 is None: + if not (a1 is None or a2 is None): + return False + elif not theq(a1, a2): + return False + return True + + dtypes = {x: 'int32', y: 'int32'} + assert theq_slice(theano_code_(slice(x, y), dtypes=dtypes), slice(xt, yt)) + assert theq_slice(theano_code_(slice(1, x, 3), dtypes=dtypes), slice(1, xt, 3)) + +def test_MatrixSlice(): + from theano import Constant + + cache = {} + + n = sy.Symbol('n', integer=True) + X = sy.MatrixSymbol('X', n, n) + + Y = X[1:2:3, 4:5:6] + Yt = theano_code_(Y, cache=cache) + + s = ts.Scalar('int64') + assert tuple(Yt.owner.op.idx_list) == (slice(s, s, s), slice(s, s, s)) + assert Yt.owner.inputs[0] == theano_code_(X, cache=cache) + # == doesn't work in theano like it does in SymPy. You have to use + # equals. + assert all(Yt.owner.inputs[i].equals(Constant(s, i)) for i in range(1, 7)) + + k = sy.Symbol('k') + theano_code_(k, dtypes={k: 'int32'}) + start, stop, step = 4, k, 2 + Y = X[start:stop:step] + Yt = theano_code_(Y, dtypes={n: 'int32', k: 'int32'}) + # assert Yt.owner.op.idx_list[0].stop == kt + +def test_BlockMatrix(): + n = sy.Symbol('n', integer=True) + A, B, C, D = [sy.MatrixSymbol(name, n, n) for name in 'ABCD'] + At, Bt, Ct, Dt = map(theano_code_, (A, B, C, D)) + Block = sy.BlockMatrix([[A, B], [C, D]]) + Blockt = theano_code_(Block) + solutions = [tt.join(0, tt.join(1, At, Bt), tt.join(1, Ct, Dt)), + tt.join(1, tt.join(0, At, Ct), tt.join(0, Bt, Dt))] + assert any(theq(Blockt, solution) for solution in solutions) + +@SKIP +def test_BlockMatrix_Inverse_execution(): + k, n = 2, 4 + dtype = 'float32' + A = sy.MatrixSymbol('A', n, k) + B = sy.MatrixSymbol('B', n, n) + inputs = A, B + output = B.I*A + + cutsizes = {A: [(n//2, n//2), (k//2, k//2)], + B: [(n//2, n//2), (n//2, n//2)]} + cutinputs = [sy.blockcut(i, *cutsizes[i]) for i in inputs] + cutoutput = output.subs(dict(zip(inputs, cutinputs))) + + dtypes = dict(zip(inputs, [dtype]*len(inputs))) + f = theano_function_(inputs, [output], dtypes=dtypes, cache={}) + fblocked = theano_function_(inputs, [sy.block_collapse(cutoutput)], + dtypes=dtypes, cache={}) + + ninputs = [np.random.rand(*x.shape).astype(dtype) for x in inputs] + ninputs = [np.arange(n*k).reshape(A.shape).astype(dtype), + np.eye(n).astype(dtype)] + ninputs[1] += np.ones(B.shape)*1e-5 + + assert np.allclose(f(*ninputs), fblocked(*ninputs), rtol=1e-5) + +def test_DenseMatrix(): + t = sy.Symbol('theta') + for MatrixType in [sy.Matrix, sy.ImmutableMatrix]: + X = MatrixType([[sy.cos(t), -sy.sin(t)], [sy.sin(t), sy.cos(t)]]) + tX = theano_code_(X) + assert isinstance(tX, tt.TensorVariable) + assert tX.owner.op == tt.join_ + + +def test_cache_basic(): + """ Test single symbol-like objects are cached when printed by themselves. """ + + # Pairs of objects which should be considered equivalent with respect to caching + pairs = [ + (x, sy.Symbol('x')), + (X, sy.MatrixSymbol('X', *X.shape)), + (f_t, sy.Function('f')(sy.Symbol('t'))), + ] + + for s1, s2 in pairs: + cache = {} + st = theano_code_(s1, cache=cache) + + # Test hit with same instance + assert theano_code_(s1, cache=cache) is st + + # Test miss with same instance but new cache + assert theano_code_(s1, cache={}) is not st + + # Test hit with different but equivalent instance + assert theano_code_(s2, cache=cache) is st + +def test_global_cache(): + """ Test use of the global cache. """ + from sympy.printing.theanocode import global_cache + + backup = dict(global_cache) + try: + # Temporarily empty global cache + global_cache.clear() + + for s in [x, X, f_t]: + with warns_deprecated_sympy(): + st = theano_code(s) + assert theano_code(s) is st + + finally: + # Restore global cache + global_cache.update(backup) + +def test_cache_types_distinct(): + """ + Test that symbol-like objects of different types (Symbol, MatrixSymbol, + AppliedUndef) are distinguished by the cache even if they have the same + name. + """ + symbols = [sy.Symbol('f_t'), sy.MatrixSymbol('f_t', 4, 4), f_t] + + cache = {} # Single shared cache + printed = {} + + for s in symbols: + st = theano_code_(s, cache=cache) + assert st not in printed.values() + printed[s] = st + + # Check all printed objects are distinct + assert len(set(map(id, printed.values()))) == len(symbols) + + # Check retrieving + for s, st in printed.items(): + with warns_deprecated_sympy(): + assert theano_code(s, cache=cache) is st + +def test_symbols_are_created_once(): + """ + Test that a symbol is cached and reused when it appears in an expression + more than once. + """ + expr = sy.Add(x, x, evaluate=False) + comp = theano_code_(expr) + + assert theq(comp, xt + xt) + assert not theq(comp, xt + theano_code_(x)) + +def test_cache_complex(): + """ + Test caching on a complicated expression with multiple symbols appearing + multiple times. + """ + expr = x ** 2 + (y - sy.exp(x)) * sy.sin(z - x * y) + symbol_names = {s.name for s in expr.free_symbols} + expr_t = theano_code_(expr) + + # Iterate through variables in the Theano computational graph that the + # printed expression depends on + seen = set() + for v in theano.gof.graph.ancestors([expr_t]): + # Owner-less, non-constant variables should be our symbols + if v.owner is None and not isinstance(v, theano.gof.graph.Constant): + # Check it corresponds to a symbol and appears only once + assert v.name in symbol_names + assert v.name not in seen + seen.add(v.name) + + # Check all were present + assert seen == symbol_names + + +def test_Piecewise(): + # A piecewise linear + expr = sy.Piecewise((0, x<0), (x, x<2), (1, True)) # ___/III + result = theano_code_(expr) + assert result.owner.op == tt.switch + + expected = tt.switch(xt<0, 0, tt.switch(xt<2, xt, 1)) + assert theq(result, expected) + + expr = sy.Piecewise((x, x < 0)) + result = theano_code_(expr) + expected = tt.switch(xt < 0, xt, np.nan) + assert theq(result, expected) + + expr = sy.Piecewise((0, sy.And(x>0, x<2)), \ + (x, sy.Or(x>2, x<0))) + result = theano_code_(expr) + expected = tt.switch(tt.and_(xt>0,xt<2), 0, \ + tt.switch(tt.or_(xt>2, xt<0), xt, np.nan)) + assert theq(result, expected) + + +def test_Relationals(): + assert theq(theano_code_(sy.Eq(x, y)), tt.eq(xt, yt)) + # assert theq(theano_code_(sy.Ne(x, y)), tt.neq(xt, yt)) # TODO - implement + assert theq(theano_code_(x > y), xt > yt) + assert theq(theano_code_(x < y), xt < yt) + assert theq(theano_code_(x >= y), xt >= yt) + assert theq(theano_code_(x <= y), xt <= yt) + + +def test_complexfunctions(): + with warns_deprecated_sympy(): + xt, yt = theano_code_(x, dtypes={x:'complex128'}), theano_code_(y, dtypes={y: 'complex128'}) + from sympy.functions.elementary.complexes import conjugate + from theano.tensor import as_tensor_variable as atv + from theano.tensor import complex as cplx + with warns_deprecated_sympy(): + assert theq(theano_code_(y*conjugate(x)), yt*(xt.conj())) + assert theq(theano_code_((1+2j)*x), xt*(atv(1.0)+atv(2.0)*cplx(0,1))) + + +def test_constantfunctions(): + with warns_deprecated_sympy(): + tf = theano_function_([],[1+1j]) + assert(tf()==1+1j) + + +def test_Exp1(): + """ + Test that exp(1) prints without error and evaluates close to SymPy's E + """ + # sy.exp(1) should yield same instance of E as sy.E (singleton), but extra + # check added for sanity + e_a = sy.exp(1) + e_b = sy.E + + np.testing.assert_allclose(float(e_a), np.e) + np.testing.assert_allclose(float(e_b), np.e) + + e = theano_code_(e_a) + np.testing.assert_allclose(float(e_a), e.eval()) + + e = theano_code_(e_b) + np.testing.assert_allclose(float(e_b), e.eval()) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_torch.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_torch.py new file mode 100644 index 0000000000000000000000000000000000000000..8ce2c6cec75e03264f93b472a79eb073742e3486 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_torch.py @@ -0,0 +1,531 @@ +import random +import math + +from sympy import symbols, Derivative +from sympy.printing.pytorch import torch_code +from sympy import (eye, MatrixSymbol, Matrix) +from sympy.tensor.array import NDimArray +from sympy.tensor.array.expressions.array_expressions import ( + ArrayTensorProduct, ArrayAdd, + PermuteDims, ArrayDiagonal, _CodegenArrayAbstract) +from sympy.utilities.lambdify import lambdify +from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt +from sympy.functions import \ + Abs, ceiling, exp, floor, sign, sin, asin, cos, \ + acos, tan, atan, atan2, cosh, acosh, sinh, asinh, tanh, atanh, \ + re, im, arg, erf, loggamma, sqrt +from sympy.testing.pytest import skip +from sympy.external import import_module +from sympy.matrices.expressions import \ + Determinant, HadamardProduct, Inverse, Trace +from sympy.matrices import randMatrix +from sympy.matrices import Identity, ZeroMatrix, OneMatrix +from sympy import conjugate, I +from sympy import Heaviside, gamma, polygamma + + + +torch = import_module("torch") + +M = MatrixSymbol("M", 3, 3) +N = MatrixSymbol("N", 3, 3) +P = MatrixSymbol("P", 3, 3) +Q = MatrixSymbol("Q", 3, 3) + +x, y, z, t = symbols("x y z t") + +if torch is not None: + llo = [list(range(i, i + 3)) for i in range(0, 9, 3)] + m3x3 = torch.tensor(llo, dtype=torch.float64) + m3x3sympy = Matrix(llo) + + +def _compare_torch_matrix(variables, expr): + f = lambdify(variables, expr, 'torch') + + random_matrices = [randMatrix(i.shape[0], i.shape[1]) for i in variables] + random_variables = [torch.tensor(i.tolist(), dtype=torch.float64) for i in random_matrices] + r = f(*random_variables) + e = expr.subs(dict(zip(variables, random_matrices))).doit() + + if isinstance(e, _CodegenArrayAbstract): + e = e.doit() + + if hasattr(e, 'is_number') and e.is_number: + if isinstance(r, torch.Tensor) and r.dim() == 0: + r = r.item() + e = float(e) + assert abs(r - e) < 1e-6 + return + + if e.is_Matrix or isinstance(e, NDimArray): + e = torch.tensor(e.tolist(), dtype=torch.float64) + assert torch.allclose(r, e, atol=1e-6) + else: + raise TypeError(f"Cannot compare {type(r)} with {type(e)}") + + +def _compare_torch_scalar(variables, expr, rng=lambda: random.uniform(-5, 5)): + f = lambdify(variables, expr, 'torch') + rvs = [rng() for v in variables] + t_rvs = [torch.tensor(i, dtype=torch.float64) for i in rvs] + r = f(*t_rvs) + if isinstance(r, torch.Tensor): + r = r.item() + e = expr.subs(dict(zip(variables, rvs))).doit() + assert abs(r - e) < 1e-6 + + +def _compare_torch_relational(variables, expr, rng=lambda: random.randint(0, 10)): + f = lambdify(variables, expr, 'torch') + rvs = [rng() for v in variables] + t_rvs = [torch.tensor(i, dtype=torch.float64) for i in rvs] + r = f(*t_rvs) + e = bool(expr.subs(dict(zip(variables, rvs))).doit()) + assert r.item() == e + + +def test_torch_math(): + if not torch: + skip("PyTorch not installed") + + expr = Abs(x) + assert torch_code(expr) == "torch.abs(x)" + f = lambdify(x, expr, 'torch') + ma = torch.tensor([[-1, 2, -3, -4]], dtype=torch.float64) + y_abs = f(ma) + c = torch.abs(ma) + assert torch.all(y_abs == c) + + expr = sign(x) + assert torch_code(expr) == "torch.sign(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-10, 10)) + + expr = ceiling(x) + assert torch_code(expr) == "torch.ceil(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.random()) + + expr = floor(x) + assert torch_code(expr) == "torch.floor(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.random()) + + expr = exp(x) + assert torch_code(expr) == "torch.exp(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-2, 2)) + + expr = sqrt(x) + assert torch_code(expr) == "torch.sqrt(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.random()) + + expr = x ** 4 + assert torch_code(expr) == "torch.pow(x, 4)" + _compare_torch_scalar((x,), expr, rng=lambda: random.random()) + + expr = cos(x) + assert torch_code(expr) == "torch.cos(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.random()) + + expr = acos(x) + assert torch_code(expr) == "torch.acos(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-0.99, 0.99)) + + expr = sin(x) + assert torch_code(expr) == "torch.sin(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.random()) + + expr = asin(x) + assert torch_code(expr) == "torch.asin(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-0.99, 0.99)) + + expr = tan(x) + assert torch_code(expr) == "torch.tan(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-1.5, 1.5)) + + expr = atan(x) + assert torch_code(expr) == "torch.atan(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-5, 5)) + + expr = atan2(y, x) + assert torch_code(expr) == "torch.atan2(y, x)" + _compare_torch_scalar((y, x), expr, rng=lambda: random.uniform(-5, 5)) + + expr = cosh(x) + assert torch_code(expr) == "torch.cosh(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-2, 2)) + + expr = acosh(x) + assert torch_code(expr) == "torch.acosh(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(1.1, 5)) + + expr = sinh(x) + assert torch_code(expr) == "torch.sinh(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-2, 2)) + + expr = asinh(x) + assert torch_code(expr) == "torch.asinh(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-5, 5)) + + expr = tanh(x) + assert torch_code(expr) == "torch.tanh(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-2, 2)) + + expr = atanh(x) + assert torch_code(expr) == "torch.atanh(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-0.9, 0.9)) + + expr = erf(x) + assert torch_code(expr) == "torch.erf(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(-2, 2)) + + expr = loggamma(x) + assert torch_code(expr) == "torch.lgamma(x)" + _compare_torch_scalar((x,), expr, rng=lambda: random.uniform(0.5, 5)) + + +def test_torch_complexes(): + assert torch_code(re(x)) == "torch.real(x)" + assert torch_code(im(x)) == "torch.imag(x)" + assert torch_code(arg(x)) == "torch.angle(x)" + + +def test_torch_relational(): + if not torch: + skip("PyTorch not installed") + + expr = Eq(x, y) + assert torch_code(expr) == "torch.eq(x, y)" + _compare_torch_relational((x, y), expr) + + expr = Ne(x, y) + assert torch_code(expr) == "torch.ne(x, y)" + _compare_torch_relational((x, y), expr) + + expr = Ge(x, y) + assert torch_code(expr) == "torch.ge(x, y)" + _compare_torch_relational((x, y), expr) + + expr = Gt(x, y) + assert torch_code(expr) == "torch.gt(x, y)" + _compare_torch_relational((x, y), expr) + + expr = Le(x, y) + assert torch_code(expr) == "torch.le(x, y)" + _compare_torch_relational((x, y), expr) + + expr = Lt(x, y) + assert torch_code(expr) == "torch.lt(x, y)" + _compare_torch_relational((x, y), expr) + + +def test_torch_matrix(): + if torch is None: + skip("PyTorch not installed") + + expr = M + assert torch_code(expr) == "M" + f = lambdify((M,), expr, "torch") + eye_mat = eye(3) + eye_tensor = torch.tensor(eye_mat.tolist(), dtype=torch.float64) + assert torch.allclose(f(eye_tensor), eye_tensor) + + expr = M * N + assert torch_code(expr) == "torch.matmul(M, N)" + _compare_torch_matrix((M, N), expr) + + expr = M ** 3 + assert torch_code(expr) == "torch.mm(torch.mm(M, M), M)" + _compare_torch_matrix((M,), expr) + + expr = M * N * P * Q + assert torch_code(expr) == "torch.matmul(torch.matmul(torch.matmul(M, N), P), Q)" + _compare_torch_matrix((M, N, P, Q), expr) + + expr = Trace(M) + assert torch_code(expr) == "torch.trace(M)" + _compare_torch_matrix((M,), expr) + + expr = Determinant(M) + assert torch_code(expr) == "torch.det(M)" + _compare_torch_matrix((M,), expr) + + expr = HadamardProduct(M, N) + assert torch_code(expr) == "torch.mul(M, N)" + _compare_torch_matrix((M, N), expr) + + expr = Inverse(M) + assert torch_code(expr) == "torch.linalg.inv(M)" + + # For inverse, use a matrix that's guaranteed to be invertible + eye_mat = eye(3) + eye_tensor = torch.tensor(eye_mat.tolist(), dtype=torch.float64) + f = lambdify((M,), expr, "torch") + result = f(eye_tensor) + expected = torch.linalg.inv(eye_tensor) + assert torch.allclose(result, expected) + + +def test_torch_array_operations(): + if not torch: + skip("PyTorch not installed") + + M = MatrixSymbol("M", 2, 2) + N = MatrixSymbol("N", 2, 2) + P = MatrixSymbol("P", 2, 2) + Q = MatrixSymbol("Q", 2, 2) + + ma = torch.tensor([[1., 2.], [3., 4.]], dtype=torch.float64) + mb = torch.tensor([[1., -2.], [-1., 3.]], dtype=torch.float64) + mc = torch.tensor([[2., 0.], [1., 2.]], dtype=torch.float64) + md = torch.tensor([[1., -1.], [4., 7.]], dtype=torch.float64) + + cg = ArrayTensorProduct(M, N) + assert torch_code(cg) == 'torch.einsum("ab,cd", M, N)' + f = lambdify((M, N), cg, 'torch') + y = f(ma, mb) + c = torch.einsum("ij,kl", ma, mb) + assert torch.allclose(y, c) + + cg = ArrayAdd(M, N) + assert torch_code(cg) == 'torch.add(M, N)' + f = lambdify((M, N), cg, 'torch') + y = f(ma, mb) + c = ma + mb + assert torch.allclose(y, c) + + cg = ArrayAdd(M, N, P) + assert torch_code(cg) == 'torch.add(torch.add(M, N), P)' + f = lambdify((M, N, P), cg, 'torch') + y = f(ma, mb, mc) + c = ma + mb + mc + assert torch.allclose(y, c) + + cg = ArrayAdd(M, N, P, Q) + assert torch_code(cg) == 'torch.add(torch.add(torch.add(M, N), P), Q)' + f = lambdify((M, N, P, Q), cg, 'torch') + y = f(ma, mb, mc, md) + c = ma + mb + mc + md + assert torch.allclose(y, c) + + cg = PermuteDims(M, [1, 0]) + assert torch_code(cg) == 'M.permute(1, 0)' + f = lambdify((M,), cg, 'torch') + y = f(ma) + c = ma.T + assert torch.allclose(y, c) + + cg = PermuteDims(ArrayTensorProduct(M, N), [1, 2, 3, 0]) + assert torch_code(cg) == 'torch.einsum("ab,cd", M, N).permute(1, 2, 3, 0)' + f = lambdify((M, N), cg, 'torch') + y = f(ma, mb) + c = torch.einsum("ab,cd", ma, mb).permute(1, 2, 3, 0) + assert torch.allclose(y, c) + + cg = ArrayDiagonal(ArrayTensorProduct(M, N), (1, 2)) + assert torch_code(cg) == 'torch.einsum("ab,bc->acb", M, N)' + f = lambdify((M, N), cg, 'torch') + y = f(ma, mb) + c = torch.einsum("ab,bc->acb", ma, mb) + assert torch.allclose(y, c) + + +def test_torch_derivative(): + """Test derivative handling.""" + expr = Derivative(sin(x), x) + assert torch_code(expr) == 'torch.autograd.grad(torch.sin(x), x)[0]' + + +def test_torch_printing_dtype(): + if not torch: + skip("PyTorch not installed") + + # matrix printing with default dtype + expr = Matrix([[x, sin(y)], [exp(z), -t]]) + assert "dtype=torch.float64" in torch_code(expr) + + # explicit dtype + assert "dtype=torch.float32" in torch_code(expr, dtype="torch.float32") + + # with requires_grad + result = torch_code(expr, requires_grad=True) + assert "requires_grad=True" in result + assert "dtype=torch.float64" in result + + # both + result = torch_code(expr, requires_grad=True, dtype="torch.float32") + assert "requires_grad=True" in result + assert "dtype=torch.float32" in result + + +def test_requires_grad(): + if not torch: + skip("PyTorch not installed") + + expr = sin(x) + cos(y) + f = lambdify([x, y], expr, 'torch') + + # make sure the gradients flow + x_val = torch.tensor(1.0, requires_grad=True) + y_val = torch.tensor(2.0, requires_grad=True) + result = f(x_val, y_val) + assert result.requires_grad + result.backward() + + # x_val.grad should be cos(x_val) which is close to cos(1.0) + assert abs(x_val.grad.item() - float(cos(1.0).evalf())) < 1e-6 + + # y_val.grad should be -sin(y_val) which is close to -sin(2.0) + assert abs(y_val.grad.item() - float(-sin(2.0).evalf())) < 1e-6 + + +def test_torch_multi_variable_derivatives(): + if not torch: + skip("PyTorch not installed") + + x, y, z = symbols("x y z") + + expr = Derivative(sin(x), x) + assert torch_code(expr) == "torch.autograd.grad(torch.sin(x), x)[0]" + + expr = Derivative(sin(x), (x, 2)) + assert torch_code( + expr) == "torch.autograd.grad(torch.autograd.grad(torch.sin(x), x, create_graph=True)[0], x, create_graph=True)[0]" + + expr = Derivative(sin(x * y), x, y) + result = torch_code(expr) + expected = "torch.autograd.grad(torch.autograd.grad(torch.sin(x*y), x, create_graph=True)[0], y, create_graph=True)[0]" + normalized_result = result.replace(" ", "") + normalized_expected = expected.replace(" ", "") + assert normalized_result == normalized_expected + + expr = Derivative(sin(x), x, x) + result = torch_code(expr) + expected = "torch.autograd.grad(torch.autograd.grad(torch.sin(x), x, create_graph=True)[0], x, create_graph=True)[0]" + assert result == expected + + expr = Derivative(sin(x * y * z), x, (y, 2), z) + result = torch_code(expr) + expected = "torch.autograd.grad(torch.autograd.grad(torch.autograd.grad(torch.autograd.grad(torch.sin(x*y*z), x, create_graph=True)[0], y, create_graph=True)[0], y, create_graph=True)[0], z, create_graph=True)[0]" + normalized_result = result.replace(" ", "") + normalized_expected = expected.replace(" ", "") + assert normalized_result == normalized_expected + + +def test_torch_derivative_lambdify(): + if not torch: + skip("PyTorch not installed") + + x = symbols("x") + y = symbols("y") + + expr = Derivative(x ** 2, x) + f = lambdify(x, expr, 'torch') + x_val = torch.tensor(2.0, requires_grad=True) + result = f(x_val) + assert torch.isclose(result, torch.tensor(4.0)) + + expr = Derivative(sin(x), (x, 2)) + f = lambdify(x, expr, 'torch') + # Second derivative of sin(x) at x=0 is 0, not -1 + x_val = torch.tensor(0.0, requires_grad=True) + result = f(x_val) + assert torch.isclose(result, torch.tensor(0.0), atol=1e-5) + + x_val = torch.tensor(math.pi / 2, requires_grad=True) + result = f(x_val) + assert torch.isclose(result, torch.tensor(-1.0), atol=1e-5) + + expr = Derivative(x * y ** 2, x, y) + f = lambdify((x, y), expr, 'torch') + x_val = torch.tensor(2.0, requires_grad=True) + y_val = torch.tensor(3.0, requires_grad=True) + result = f(x_val, y_val) + assert torch.isclose(result, torch.tensor(6.0)) + + +def test_torch_special_matrices(): + if not torch: + skip("PyTorch not installed") + + expr = Identity(3) + assert torch_code(expr) == "torch.eye(3)" + + n = symbols("n") + expr = Identity(n) + assert torch_code(expr) == "torch.eye(n, n)" + + expr = ZeroMatrix(2, 3) + assert torch_code(expr) == "torch.zeros((2, 3))" + + m, n = symbols("m n") + expr = ZeroMatrix(m, n) + assert torch_code(expr) == "torch.zeros((m, n))" + + expr = OneMatrix(2, 3) + assert torch_code(expr) == "torch.ones((2, 3))" + + expr = OneMatrix(m, n) + assert torch_code(expr) == "torch.ones((m, n))" + + +def test_torch_special_matrices_lambdify(): + if not torch: + skip("PyTorch not installed") + + expr = Identity(3) + f = lambdify([], expr, 'torch') + result = f() + expected = torch.eye(3) + assert torch.allclose(result, expected) + + expr = ZeroMatrix(2, 3) + f = lambdify([], expr, 'torch') + result = f() + expected = torch.zeros((2, 3)) + assert torch.allclose(result, expected) + + expr = OneMatrix(2, 3) + f = lambdify([], expr, 'torch') + result = f() + expected = torch.ones((2, 3)) + assert torch.allclose(result, expected) + + +def test_torch_complex_operations(): + if not torch: + skip("PyTorch not installed") + + expr = conjugate(x) + assert torch_code(expr) == "torch.conj(x)" + + # SymPy distributes conjugate over addition and applies specific rules for each term + expr = conjugate(sin(x) + I * cos(y)) + assert torch_code(expr) == "torch.sin(torch.conj(x)) - 1j*torch.cos(torch.conj(y))" + + expr = I + assert torch_code(expr) == "1j" + + expr = 2 * I + x + assert torch_code(expr) == "x + 2*1j" + + expr = exp(I * x) + assert torch_code(expr) == "torch.exp(1j*x)" + + +def test_torch_special_functions(): + if not torch: + skip("PyTorch not installed") + + expr = Heaviside(x) + assert torch_code(expr) == "torch.heaviside(x, 1/2)" + + expr = Heaviside(x, 0) + assert torch_code(expr) == "torch.heaviside(x, 0)" + + expr = gamma(x) + assert torch_code(expr) == "torch.special.gamma(x)" + + expr = polygamma(0, x) # Use polygamma instead of digamma because sympy will default to that anyway + assert torch_code(expr) == "torch.special.digamma(x)" + + expr = gamma(sin(x)) + assert torch_code(expr) == "torch.special.gamma(torch.sin(x))" diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tree.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tree.py new file mode 100644 index 0000000000000000000000000000000000000000..cf116d0cac5d38f225815fcd2d4ac90cd0dd96d7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tests/test_tree.py @@ -0,0 +1,196 @@ +from sympy.printing.tree import tree +from sympy.testing.pytest import XFAIL + + +# Remove this flag after making _assumptions cache deterministic. +@XFAIL +def test_print_tree_MatAdd(): + from sympy.matrices.expressions import MatrixSymbol + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 3, 3) + + test_str = [ + 'MatAdd: A + B\n', + 'algebraic: False\n', + 'commutative: False\n', + 'complex: False\n', + 'composite: False\n', + 'even: False\n', + 'extended_negative: False\n', + 'extended_nonnegative: False\n', + 'extended_nonpositive: False\n', + 'extended_nonzero: False\n', + 'extended_positive: False\n', + 'extended_real: False\n', + 'imaginary: False\n', + 'integer: False\n', + 'irrational: False\n', + 'negative: False\n', + 'noninteger: False\n', + 'nonnegative: False\n', + 'nonpositive: False\n', + 'nonzero: False\n', + 'odd: False\n', + 'positive: False\n', + 'prime: False\n', + 'rational: False\n', + 'real: False\n', + 'transcendental: False\n', + 'zero: False\n', + '+-MatrixSymbol: A\n', + '| algebraic: False\n', + '| commutative: False\n', + '| complex: False\n', + '| composite: False\n', + '| even: False\n', + '| extended_negative: False\n', + '| extended_nonnegative: False\n', + '| extended_nonpositive: False\n', + '| extended_nonzero: False\n', + '| extended_positive: False\n', + '| extended_real: False\n', + '| imaginary: False\n', + '| integer: False\n', + '| irrational: False\n', + '| negative: False\n', + '| noninteger: False\n', + '| nonnegative: False\n', + '| nonpositive: False\n', + '| nonzero: False\n', + '| odd: False\n', + '| positive: False\n', + '| prime: False\n', + '| rational: False\n', + '| real: False\n', + '| transcendental: False\n', + '| zero: False\n', + '| +-Symbol: A\n', + '| | commutative: True\n', + '| +-Integer: 3\n', + '| | algebraic: True\n', + '| | commutative: True\n', + '| | complex: True\n', + '| | extended_negative: False\n', + '| | extended_nonnegative: True\n', + '| | extended_real: True\n', + '| | finite: True\n', + '| | hermitian: True\n', + '| | imaginary: False\n', + '| | infinite: False\n', + '| | integer: True\n', + '| | irrational: False\n', + '| | negative: False\n', + '| | noninteger: False\n', + '| | nonnegative: True\n', + '| | rational: True\n', + '| | real: True\n', + '| | transcendental: False\n', + '| +-Integer: 3\n', + '| algebraic: True\n', + '| commutative: True\n', + '| complex: True\n', + '| extended_negative: False\n', + '| extended_nonnegative: True\n', + '| extended_real: True\n', + '| finite: True\n', + '| hermitian: True\n', + '| imaginary: False\n', + '| infinite: False\n', + '| integer: True\n', + '| irrational: False\n', + '| negative: False\n', + '| noninteger: False\n', + '| nonnegative: True\n', + '| rational: True\n', + '| real: True\n', + '| transcendental: False\n', + '+-MatrixSymbol: B\n', + ' algebraic: False\n', + ' commutative: False\n', + ' complex: False\n', + ' composite: False\n', + ' even: False\n', + ' extended_negative: False\n', + ' extended_nonnegative: False\n', + ' extended_nonpositive: False\n', + ' extended_nonzero: False\n', + ' extended_positive: False\n', + ' extended_real: False\n', + ' imaginary: False\n', + ' integer: False\n', + ' irrational: False\n', + ' negative: False\n', + ' noninteger: False\n', + ' nonnegative: False\n', + ' nonpositive: False\n', + ' nonzero: False\n', + ' odd: False\n', + ' positive: False\n', + ' prime: False\n', + ' rational: False\n', + ' real: False\n', + ' transcendental: False\n', + ' zero: False\n', + ' +-Symbol: B\n', + ' | commutative: True\n', + ' +-Integer: 3\n', + ' | algebraic: True\n', + ' | commutative: True\n', + ' | complex: True\n', + ' | extended_negative: False\n', + ' | extended_nonnegative: True\n', + ' | extended_real: True\n', + ' | finite: True\n', + ' | hermitian: True\n', + ' | imaginary: False\n', + ' | infinite: False\n', + ' | integer: True\n', + ' | irrational: False\n', + ' | negative: False\n', + ' | noninteger: False\n', + ' | nonnegative: True\n', + ' | rational: True\n', + ' | real: True\n', + ' | transcendental: False\n', + ' +-Integer: 3\n', + ' algebraic: True\n', + ' commutative: True\n', + ' complex: True\n', + ' extended_negative: False\n', + ' extended_nonnegative: True\n', + ' extended_real: True\n', + ' finite: True\n', + ' hermitian: True\n', + ' imaginary: False\n', + ' infinite: False\n', + ' integer: True\n', + ' irrational: False\n', + ' negative: False\n', + ' noninteger: False\n', + ' nonnegative: True\n', + ' rational: True\n', + ' real: True\n', + ' transcendental: False\n' + ] + + assert tree(A + B) == "".join(test_str) + + +def test_print_tree_MatAdd_noassumptions(): + from sympy.matrices.expressions import MatrixSymbol + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 3, 3) + + test_str = \ +"""MatAdd: A + B ++-MatrixSymbol: A +| +-Str: A +| +-Integer: 3 +| +-Integer: 3 ++-MatrixSymbol: B + +-Str: B + +-Integer: 3 + +-Integer: 3 +""" + + assert tree(A + B, assumptions=False) == test_str diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/theanocode.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/theanocode.py new file mode 100644 index 0000000000000000000000000000000000000000..dce908865d426dabede2b6749ad944e5a420e4cf --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/theanocode.py @@ -0,0 +1,571 @@ +""" +.. deprecated:: 1.8 + + ``sympy.printing.theanocode`` is deprecated. Theano has been renamed to + Aesara. Use ``sympy.printing.aesaracode`` instead. See + :ref:`theanocode-deprecated` for more information. + +""" +from __future__ import annotations +import math +from typing import Any + +from sympy.external import import_module +from sympy.printing.printer import Printer +from sympy.utilities.iterables import is_sequence +import sympy +from functools import partial + +from sympy.utilities.decorator import doctest_depends_on +from sympy.utilities.exceptions import sympy_deprecation_warning + + +__doctest_requires__ = {('theano_function',): ['theano']} + + +theano = import_module('theano') + + +if theano: + ts = theano.scalar + tt = theano.tensor + from theano.sandbox import linalg as tlinalg + + mapping = { + sympy.Add: tt.add, + sympy.Mul: tt.mul, + sympy.Abs: tt.abs_, + sympy.sign: tt.sgn, + sympy.ceiling: tt.ceil, + sympy.floor: tt.floor, + sympy.log: tt.log, + sympy.exp: tt.exp, + sympy.sqrt: tt.sqrt, + sympy.cos: tt.cos, + sympy.acos: tt.arccos, + sympy.sin: tt.sin, + sympy.asin: tt.arcsin, + sympy.tan: tt.tan, + sympy.atan: tt.arctan, + sympy.atan2: tt.arctan2, + sympy.cosh: tt.cosh, + sympy.acosh: tt.arccosh, + sympy.sinh: tt.sinh, + sympy.asinh: tt.arcsinh, + sympy.tanh: tt.tanh, + sympy.atanh: tt.arctanh, + sympy.re: tt.real, + sympy.im: tt.imag, + sympy.arg: tt.angle, + sympy.erf: tt.erf, + sympy.gamma: tt.gamma, + sympy.loggamma: tt.gammaln, + sympy.Pow: tt.pow, + sympy.Eq: tt.eq, + sympy.StrictGreaterThan: tt.gt, + sympy.StrictLessThan: tt.lt, + sympy.LessThan: tt.le, + sympy.GreaterThan: tt.ge, + sympy.And: tt.and_, + sympy.Or: tt.or_, + sympy.Max: tt.maximum, # SymPy accept >2 inputs, Theano only 2 + sympy.Min: tt.minimum, # SymPy accept >2 inputs, Theano only 2 + sympy.conjugate: tt.conj, + sympy.core.numbers.ImaginaryUnit: lambda:tt.complex(0,1), + # Matrices + sympy.MatAdd: tt.Elemwise(ts.add), + sympy.HadamardProduct: tt.Elemwise(ts.mul), + sympy.Trace: tlinalg.trace, + sympy.Determinant : tlinalg.det, + sympy.Inverse: tlinalg.matrix_inverse, + sympy.Transpose: tt.DimShuffle((False, False), [1, 0]), + } + + +class TheanoPrinter(Printer): + """ Code printer which creates Theano symbolic expression graphs. + + Parameters + ========== + + cache : dict + Cache dictionary to use. If None (default) will use + the global cache. To create a printer which does not depend on or alter + global state pass an empty dictionary. Note: the dictionary is not + copied on initialization of the printer and will be updated in-place, + so using the same dict object when creating multiple printers or making + multiple calls to :func:`.theano_code` or :func:`.theano_function` means + the cache is shared between all these applications. + + Attributes + ========== + + cache : dict + A cache of Theano variables which have been created for SymPy + symbol-like objects (e.g. :class:`sympy.core.symbol.Symbol` or + :class:`sympy.matrices.expressions.MatrixSymbol`). This is used to + ensure that all references to a given symbol in an expression (or + multiple expressions) are printed as the same Theano variable, which is + created only once. Symbols are differentiated only by name and type. The + format of the cache's contents should be considered opaque to the user. + """ + printmethod = "_theano" + + def __init__(self, *args, **kwargs): + self.cache = kwargs.pop('cache', {}) + super().__init__(*args, **kwargs) + + def _get_key(self, s, name=None, dtype=None, broadcastable=None): + """ Get the cache key for a SymPy object. + + Parameters + ========== + + s : sympy.core.basic.Basic + SymPy object to get key for. + + name : str + Name of object, if it does not have a ``name`` attribute. + """ + + if name is None: + name = s.name + + return (name, type(s), s.args, dtype, broadcastable) + + def _get_or_create(self, s, name=None, dtype=None, broadcastable=None): + """ + Get the Theano variable for a SymPy symbol from the cache, or create it + if it does not exist. + """ + + # Defaults + if name is None: + name = s.name + if dtype is None: + dtype = 'floatX' + if broadcastable is None: + broadcastable = () + + key = self._get_key(s, name, dtype=dtype, broadcastable=broadcastable) + + if key in self.cache: + return self.cache[key] + + value = tt.tensor(name=name, dtype=dtype, broadcastable=broadcastable) + self.cache[key] = value + return value + + def _print_Symbol(self, s, **kwargs): + dtype = kwargs.get('dtypes', {}).get(s) + bc = kwargs.get('broadcastables', {}).get(s) + return self._get_or_create(s, dtype=dtype, broadcastable=bc) + + def _print_AppliedUndef(self, s, **kwargs): + name = str(type(s)) + '_' + str(s.args[0]) + dtype = kwargs.get('dtypes', {}).get(s) + bc = kwargs.get('broadcastables', {}).get(s) + return self._get_or_create(s, name=name, dtype=dtype, broadcastable=bc) + + def _print_Basic(self, expr, **kwargs): + op = mapping[type(expr)] + children = [self._print(arg, **kwargs) for arg in expr.args] + return op(*children) + + def _print_Number(self, n, **kwargs): + # Integers already taken care of below, interpret as float + return float(n.evalf()) + + def _print_MatrixSymbol(self, X, **kwargs): + dtype = kwargs.get('dtypes', {}).get(X) + return self._get_or_create(X, dtype=dtype, broadcastable=(None, None)) + + def _print_DenseMatrix(self, X, **kwargs): + if not hasattr(tt, 'stacklists'): + raise NotImplementedError( + "Matrix translation not yet supported in this version of Theano") + + return tt.stacklists([ + [self._print(arg, **kwargs) for arg in L] + for L in X.tolist() + ]) + + _print_ImmutableMatrix = _print_ImmutableDenseMatrix = _print_DenseMatrix + + def _print_MatMul(self, expr, **kwargs): + children = [self._print(arg, **kwargs) for arg in expr.args] + result = children[0] + for child in children[1:]: + result = tt.dot(result, child) + return result + + def _print_MatPow(self, expr, **kwargs): + children = [self._print(arg, **kwargs) for arg in expr.args] + result = 1 + if isinstance(children[1], int) and children[1] > 0: + for i in range(children[1]): + result = tt.dot(result, children[0]) + else: + raise NotImplementedError('''Only non-negative integer + powers of matrices can be handled by Theano at the moment''') + return result + + def _print_MatrixSlice(self, expr, **kwargs): + parent = self._print(expr.parent, **kwargs) + rowslice = self._print(slice(*expr.rowslice), **kwargs) + colslice = self._print(slice(*expr.colslice), **kwargs) + return parent[rowslice, colslice] + + def _print_BlockMatrix(self, expr, **kwargs): + nrows, ncols = expr.blocks.shape + blocks = [[self._print(expr.blocks[r, c], **kwargs) + for c in range(ncols)] + for r in range(nrows)] + return tt.join(0, *[tt.join(1, *row) for row in blocks]) + + + def _print_slice(self, expr, **kwargs): + return slice(*[self._print(i, **kwargs) + if isinstance(i, sympy.Basic) else i + for i in (expr.start, expr.stop, expr.step)]) + + def _print_Pi(self, expr, **kwargs): + return math.pi + + def _print_Exp1(self, expr, **kwargs): + return ts.exp(1) + + def _print_Piecewise(self, expr, **kwargs): + import numpy as np + e, cond = expr.args[0].args # First condition and corresponding value + + # Print conditional expression and value for first condition + p_cond = self._print(cond, **kwargs) + p_e = self._print(e, **kwargs) + + # One condition only + if len(expr.args) == 1: + # Return value if condition else NaN + return tt.switch(p_cond, p_e, np.nan) + + # Return value_1 if condition_1 else evaluate remaining conditions + p_remaining = self._print(sympy.Piecewise(*expr.args[1:]), **kwargs) + return tt.switch(p_cond, p_e, p_remaining) + + def _print_Rational(self, expr, **kwargs): + return tt.true_div(self._print(expr.p, **kwargs), + self._print(expr.q, **kwargs)) + + def _print_Integer(self, expr, **kwargs): + return expr.p + + def _print_factorial(self, expr, **kwargs): + return self._print(sympy.gamma(expr.args[0] + 1), **kwargs) + + def _print_Derivative(self, deriv, **kwargs): + rv = self._print(deriv.expr, **kwargs) + for var in deriv.variables: + var = self._print(var, **kwargs) + rv = tt.Rop(rv, var, tt.ones_like(var)) + return rv + + def emptyPrinter(self, expr): + return expr + + def doprint(self, expr, dtypes=None, broadcastables=None): + """ Convert a SymPy expression to a Theano graph variable. + + The ``dtypes`` and ``broadcastables`` arguments are used to specify the + data type, dimension, and broadcasting behavior of the Theano variables + corresponding to the free symbols in ``expr``. Each is a mapping from + SymPy symbols to the value of the corresponding argument to + ``theano.tensor.Tensor``. + + See the corresponding `documentation page`__ for more information on + broadcasting in Theano. + + .. __: http://deeplearning.net/software/theano/tutorial/broadcasting.html + + Parameters + ========== + + expr : sympy.core.expr.Expr + SymPy expression to print. + + dtypes : dict + Mapping from SymPy symbols to Theano datatypes to use when creating + new Theano variables for those symbols. Corresponds to the ``dtype`` + argument to ``theano.tensor.Tensor``. Defaults to ``'floatX'`` + for symbols not included in the mapping. + + broadcastables : dict + Mapping from SymPy symbols to the value of the ``broadcastable`` + argument to ``theano.tensor.Tensor`` to use when creating Theano + variables for those symbols. Defaults to the empty tuple for symbols + not included in the mapping (resulting in a scalar). + + Returns + ======= + + theano.gof.graph.Variable + A variable corresponding to the expression's value in a Theano + symbolic expression graph. + + """ + if dtypes is None: + dtypes = {} + if broadcastables is None: + broadcastables = {} + + return self._print(expr, dtypes=dtypes, broadcastables=broadcastables) + + +global_cache: dict[Any, Any] = {} + + +def theano_code(expr, cache=None, **kwargs): + """ + Convert a SymPy expression into a Theano graph variable. + + .. deprecated:: 1.8 + + ``sympy.printing.theanocode`` is deprecated. Theano has been renamed to + Aesara. Use ``sympy.printing.aesaracode`` instead. See + :ref:`theanocode-deprecated` for more information. + + Parameters + ========== + + expr : sympy.core.expr.Expr + SymPy expression object to convert. + + cache : dict + Cached Theano variables (see :class:`TheanoPrinter.cache + `). Defaults to the module-level global cache. + + dtypes : dict + Passed to :meth:`.TheanoPrinter.doprint`. + + broadcastables : dict + Passed to :meth:`.TheanoPrinter.doprint`. + + Returns + ======= + + theano.gof.graph.Variable + A variable corresponding to the expression's value in a Theano symbolic + expression graph. + + """ + sympy_deprecation_warning( + """ + sympy.printing.theanocode is deprecated. Theano has been renamed to + Aesara. Use sympy.printing.aesaracode instead.""", + deprecated_since_version="1.8", + active_deprecations_target='theanocode-deprecated') + + if not theano: + raise ImportError("theano is required for theano_code") + + if cache is None: + cache = global_cache + + return TheanoPrinter(cache=cache, settings={}).doprint(expr, **kwargs) + + +def dim_handling(inputs, dim=None, dims=None, broadcastables=None): + r""" + Get value of ``broadcastables`` argument to :func:`.theano_code` from + keyword arguments to :func:`.theano_function`. + + Included for backwards compatibility. + + Parameters + ========== + + inputs + Sequence of input symbols. + + dim : int + Common number of dimensions for all inputs. Overrides other arguments + if given. + + dims : dict + Mapping from input symbols to number of dimensions. Overrides + ``broadcastables`` argument if given. + + broadcastables : dict + Explicit value of ``broadcastables`` argument to + :meth:`.TheanoPrinter.doprint`. If not None function will return this value unchanged. + + Returns + ======= + dict + Dictionary mapping elements of ``inputs`` to their "broadcastable" + values (tuple of ``bool``\ s). + """ + if dim is not None: + return dict.fromkeys(inputs, (False,) * dim) + + if dims is not None: + maxdim = max(dims.values()) + return { + s: (False,) * d + (True,) * (maxdim - d) + for s, d in dims.items() + } + + if broadcastables is not None: + return broadcastables + + return {} + + +@doctest_depends_on(modules=('theano',)) +def theano_function(inputs, outputs, scalar=False, *, + dim=None, dims=None, broadcastables=None, **kwargs): + """ + Create a Theano function from SymPy expressions. + + .. deprecated:: 1.8 + + ``sympy.printing.theanocode`` is deprecated. Theano has been renamed to + Aesara. Use ``sympy.printing.aesaracode`` instead. See + :ref:`theanocode-deprecated` for more information. + + The inputs and outputs are converted to Theano variables using + :func:`.theano_code` and then passed to ``theano.function``. + + Parameters + ========== + + inputs + Sequence of symbols which constitute the inputs of the function. + + outputs + Sequence of expressions which constitute the outputs(s) of the + function. The free symbols of each expression must be a subset of + ``inputs``. + + scalar : bool + Convert 0-dimensional arrays in output to scalars. This will return a + Python wrapper function around the Theano function object. + + cache : dict + Cached Theano variables (see :class:`TheanoPrinter.cache + `). Defaults to the module-level global cache. + + dtypes : dict + Passed to :meth:`.TheanoPrinter.doprint`. + + broadcastables : dict + Passed to :meth:`.TheanoPrinter.doprint`. + + dims : dict + Alternative to ``broadcastables`` argument. Mapping from elements of + ``inputs`` to integers indicating the dimension of their associated + arrays/tensors. Overrides ``broadcastables`` argument if given. + + dim : int + Another alternative to the ``broadcastables`` argument. Common number of + dimensions to use for all arrays/tensors. + ``theano_function([x, y], [...], dim=2)`` is equivalent to using + ``broadcastables={x: (False, False), y: (False, False)}``. + + Returns + ======= + callable + A callable object which takes values of ``inputs`` as positional + arguments and returns an output array for each of the expressions + in ``outputs``. If ``outputs`` is a single expression the function will + return a Numpy array, if it is a list of multiple expressions the + function will return a list of arrays. See description of the ``squeeze`` + argument above for the behavior when a single output is passed in a list. + The returned object will either be an instance of + ``theano.compile.function_module.Function`` or a Python wrapper + function around one. In both cases, the returned value will have a + ``theano_function`` attribute which points to the return value of + ``theano.function``. + + Examples + ======== + + >>> from sympy.abc import x, y, z + >>> from sympy.printing.theanocode import theano_function + + A simple function with one input and one output: + + >>> f1 = theano_function([x], [x**2 - 1], scalar=True) + >>> f1(3) + 8.0 + + A function with multiple inputs and one output: + + >>> f2 = theano_function([x, y, z], [(x**z + y**z)**(1/z)], scalar=True) + >>> f2(3, 4, 2) + 5.0 + + A function with multiple inputs and multiple outputs: + + >>> f3 = theano_function([x, y], [x**2 + y**2, x**2 - y**2], scalar=True) + >>> f3(2, 3) + [13.0, -5.0] + + See also + ======== + + dim_handling + + """ + sympy_deprecation_warning( + """ + sympy.printing.theanocode is deprecated. Theano has been renamed to Aesara. Use sympy.printing.aesaracode instead""", + deprecated_since_version="1.8", + active_deprecations_target='theanocode-deprecated') + + if not theano: + raise ImportError("theano is required for theano_function") + + # Pop off non-theano keyword args + cache = kwargs.pop('cache', {}) + dtypes = kwargs.pop('dtypes', {}) + + broadcastables = dim_handling( + inputs, dim=dim, dims=dims, broadcastables=broadcastables, + ) + + # Print inputs/outputs + code = partial(theano_code, cache=cache, dtypes=dtypes, + broadcastables=broadcastables) + tinputs = list(map(code, inputs)) + toutputs = list(map(code, outputs)) + + #fix constant expressions as variables + toutputs = [output if isinstance(output, theano.Variable) else tt.as_tensor_variable(output) for output in toutputs] + + if len(toutputs) == 1: + toutputs = toutputs[0] + + # Compile theano func + func = theano.function(tinputs, toutputs, **kwargs) + + is_0d = [len(o.variable.broadcastable) == 0 for o in func.outputs] + + # No wrapper required + if not scalar or not any(is_0d): + func.theano_function = func + return func + + # Create wrapper to convert 0-dimensional outputs to scalars + def wrapper(*args): + out = func(*args) + # out can be array(1.0) or [array(1.0), array(2.0)] + + if is_sequence(out): + return [o[()] if is_0d[i] else o for i, o in enumerate(out)] + else: + return out[()] + + wrapper.__wrapped__ = func + wrapper.__doc__ = func.__doc__ + wrapper.theano_function = func + return wrapper diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tree.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tree.py new file mode 100644 index 0000000000000000000000000000000000000000..82dac013419fbe93f63dcf5b90b3a529d72a32bc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/printing/tree.py @@ -0,0 +1,175 @@ +def pprint_nodes(subtrees): + """ + Prettyprints systems of nodes. + + Examples + ======== + + >>> from sympy.printing.tree import pprint_nodes + >>> print(pprint_nodes(["a", "b1\\nb2", "c"])) + +-a + +-b1 + | b2 + +-c + + """ + def indent(s, type=1): + x = s.split("\n") + r = "+-%s\n" % x[0] + for a in x[1:]: + if a == "": + continue + if type == 1: + r += "| %s\n" % a + else: + r += " %s\n" % a + return r + if not subtrees: + return "" + f = "" + for a in subtrees[:-1]: + f += indent(a) + f += indent(subtrees[-1], 2) + return f + + +def print_node(node, assumptions=True): + """ + Returns information about the "node". + + This includes class name, string representation and assumptions. + + Parameters + ========== + + assumptions : bool, optional + See the ``assumptions`` keyword in ``tree`` + """ + s = "%s: %s\n" % (node.__class__.__name__, str(node)) + + if assumptions: + d = node._assumptions + else: + d = None + + if d: + for a in sorted(d): + v = d[a] + if v is None: + continue + s += "%s: %s\n" % (a, v) + + return s + + +def tree(node, assumptions=True): + """ + Returns a tree representation of "node" as a string. + + It uses print_node() together with pprint_nodes() on node.args recursively. + + Parameters + ========== + + assumptions : bool, optional + The flag to decide whether to print out all the assumption data + (such as ``is_integer`, ``is_real``) associated with the + expression or not. + + Enabling the flag makes the result verbose, and the printed + result may not be deterministic because of the randomness used + in backtracing the assumptions. + + See Also + ======== + + print_tree + + """ + subtrees = [] + for arg in node.args: + subtrees.append(tree(arg, assumptions=assumptions)) + s = print_node(node, assumptions=assumptions) + pprint_nodes(subtrees) + return s + + +def print_tree(node, assumptions=True): + """ + Prints a tree representation of "node". + + Parameters + ========== + + assumptions : bool, optional + The flag to decide whether to print out all the assumption data + (such as ``is_integer`, ``is_real``) associated with the + expression or not. + + Enabling the flag makes the result verbose, and the printed + result may not be deterministic because of the randomness used + in backtracing the assumptions. + + Examples + ======== + + >>> from sympy.printing import print_tree + >>> from sympy import Symbol + >>> x = Symbol('x', odd=True) + >>> y = Symbol('y', even=True) + + Printing with full assumptions information: + + >>> print_tree(y**x) + Pow: y**x + +-Symbol: y + | algebraic: True + | commutative: True + | complex: True + | even: True + | extended_real: True + | finite: True + | hermitian: True + | imaginary: False + | infinite: False + | integer: True + | irrational: False + | noninteger: False + | odd: False + | rational: True + | real: True + | transcendental: False + +-Symbol: x + algebraic: True + commutative: True + complex: True + even: False + extended_nonzero: True + extended_real: True + finite: True + hermitian: True + imaginary: False + infinite: False + integer: True + irrational: False + noninteger: False + nonzero: True + odd: True + rational: True + real: True + transcendental: False + zero: False + + Hiding the assumptions: + + >>> print_tree(y**x, assumptions=False) + Pow: y**x + +-Symbol: y + +-Symbol: x + + See Also + ======== + + tree + + """ + print(tree(node, assumptions=assumptions)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..3a84b7517819bb2fc9886274e09d955a74cabca1 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/__init__.py @@ -0,0 +1,8 @@ +""" +Sandbox module of SymPy. + +This module contains experimental code, use at your own risk! + +There is no warranty that this code will still be located here in future +versions of SymPy. +""" diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/indexed_integrals.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/indexed_integrals.py new file mode 100644 index 0000000000000000000000000000000000000000..c0c17d141448b5a71cb814bff76a710a5bd43f88 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/indexed_integrals.py @@ -0,0 +1,72 @@ +from sympy.tensor import Indexed +from sympy.core.containers import Tuple +from sympy.core.symbol import Dummy +from sympy.core.sympify import sympify +from sympy.integrals.integrals import Integral + + +class IndexedIntegral(Integral): + """ + Experimental class to test integration by indexed variables. + + Usage is analogue to ``Integral``, it simply adds awareness of + integration over indices. + + Contraction of non-identical index symbols referring to the same + ``IndexedBase`` is not yet supported. + + Examples + ======== + + >>> from sympy.sandbox.indexed_integrals import IndexedIntegral + >>> from sympy import IndexedBase, symbols + >>> A = IndexedBase('A') + >>> i, j = symbols('i j', integer=True) + >>> ii = IndexedIntegral(A[i], A[i]) + >>> ii + Integral(_A[i], _A[i]) + >>> ii.doit() + A[i]**2/2 + + If the indices are different, indexed objects are considered to be + different variables: + + >>> i2 = IndexedIntegral(A[j], A[i]) + >>> i2 + Integral(A[j], _A[i]) + >>> i2.doit() + A[i]*A[j] + """ + + def __new__(cls, function, *limits, **assumptions): + repl, limits = IndexedIntegral._indexed_process_limits(limits) + function = sympify(function) + function = function.xreplace(repl) + obj = Integral.__new__(cls, function, *limits, **assumptions) + obj._indexed_repl = repl + obj._indexed_reverse_repl = {val: key for key, val in repl.items()} + return obj + + def doit(self): + res = super().doit() + return res.xreplace(self._indexed_reverse_repl) + + @staticmethod + def _indexed_process_limits(limits): + repl = {} + newlimits = [] + for i in limits: + if isinstance(i, (tuple, list, Tuple)): + v = i[0] + vrest = i[1:] + else: + v = i + vrest = () + if isinstance(v, Indexed): + if v not in repl: + r = Dummy(str(v)) + repl[v] = r + newlimits.append((r,)+vrest) + else: + newlimits.append(i) + return repl, newlimits diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/tests/test_indexed_integrals.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/tests/test_indexed_integrals.py new file mode 100644 index 0000000000000000000000000000000000000000..61b98f0ffec29e026f6dfe8e16fde8b5818b0b09 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sandbox/tests/test_indexed_integrals.py @@ -0,0 +1,25 @@ +from sympy.sandbox.indexed_integrals import IndexedIntegral +from sympy.core.symbol import symbols +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.tensor.indexed import (Idx, IndexedBase) + + +def test_indexed_integrals(): + A = IndexedBase('A') + i, j = symbols('i j', integer=True) + a1, a2 = symbols('a1:3', cls=Idx) + assert isinstance(a1, Idx) + + assert IndexedIntegral(1, A[i]).doit() == A[i] + assert IndexedIntegral(A[i], A[i]).doit() == A[i] ** 2 / 2 + assert IndexedIntegral(A[j], A[i]).doit() == A[i] * A[j] + assert IndexedIntegral(A[i] * A[j], A[i]).doit() == A[i] ** 2 * A[j] / 2 + assert IndexedIntegral(sin(A[i]), A[i]).doit() == -cos(A[i]) + assert IndexedIntegral(sin(A[j]), A[i]).doit() == sin(A[j]) * A[i] + + assert IndexedIntegral(1, A[a1]).doit() == A[a1] + assert IndexedIntegral(A[a1], A[a1]).doit() == A[a1] ** 2 / 2 + assert IndexedIntegral(A[a2], A[a1]).doit() == A[a1] * A[a2] + assert IndexedIntegral(A[a1] * A[a2], A[a1]).doit() == A[a1] ** 2 * A[a2] / 2 + assert IndexedIntegral(sin(A[a1]), A[a1]).doit() == -cos(A[a1]) + assert IndexedIntegral(sin(A[a2]), A[a1]).doit() == sin(A[a2]) * A[a1] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..953653e21856b82bc0b708ccd922efb728a084ed --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/__init__.py @@ -0,0 +1,23 @@ +"""A module that handles series: find a limit, order the series etc. +""" +from .order import Order +from .limits import limit, Limit +from .gruntz import gruntz +from .series import series +from .approximants import approximants +from .residues import residue +from .sequences import SeqPer, SeqFormula, sequence, SeqAdd, SeqMul +from .fourier import fourier_series +from .formal import fps +from .limitseq import difference_delta, limit_seq + +from sympy.core.singleton import S +EmptySequence = S.EmptySequence + +O = Order + +__all__ = ['Order', 'O', 'limit', 'Limit', 'gruntz', 'series', 'approximants', + 'residue', 'EmptySequence', 'SeqPer', 'SeqFormula', 'sequence', + 'SeqAdd', 'SeqMul', 'fourier_series', 'fps', 'difference_delta', + 'limit_seq' + ] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/acceleration.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/acceleration.py new file mode 100644 index 0000000000000000000000000000000000000000..e2c7c1629a4b0d52e2aa33bd415886dfed515693 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/acceleration.py @@ -0,0 +1,101 @@ +""" +Convergence acceleration / extrapolation methods for series and +sequences. + +References: +Carl M. Bender & Steven A. Orszag, "Advanced Mathematical Methods for +Scientists and Engineers: Asymptotic Methods and Perturbation Theory", +Springer 1999. (Shanks transformation: pp. 368-375, Richardson +extrapolation: pp. 375-377.) +""" + +from sympy.core.numbers import Integer +from sympy.core.singleton import S +from sympy.functions.combinatorial.factorials import factorial + + +def richardson(A, k, n, N): + """ + Calculate an approximation for lim k->oo A(k) using Richardson + extrapolation with the terms A(n), A(n+1), ..., A(n+N+1). + Choosing N ~= 2*n often gives good results. + + Examples + ======== + + A simple example is to calculate exp(1) using the limit definition. + This limit converges slowly; n = 100 only produces two accurate + digits: + + >>> from sympy.abc import n + >>> e = (1 + 1/n)**n + >>> print(round(e.subs(n, 100).evalf(), 10)) + 2.7048138294 + + Richardson extrapolation with 11 appropriately chosen terms gives + a value that is accurate to the indicated precision: + + >>> from sympy import E + >>> from sympy.series.acceleration import richardson + >>> print(round(richardson(e, n, 10, 20).evalf(), 10)) + 2.7182818285 + >>> print(round(E.evalf(), 10)) + 2.7182818285 + + Another useful application is to speed up convergence of series. + Computing 100 terms of the zeta(2) series 1/k**2 yields only + two accurate digits: + + >>> from sympy.abc import k, n + >>> from sympy import Sum + >>> A = Sum(k**-2, (k, 1, n)) + >>> print(round(A.subs(n, 100).evalf(), 10)) + 1.6349839002 + + Richardson extrapolation performs much better: + + >>> from sympy import pi + >>> print(round(richardson(A, n, 10, 20).evalf(), 10)) + 1.6449340668 + >>> print(round(((pi**2)/6).evalf(), 10)) # Exact value + 1.6449340668 + + """ + s = S.Zero + for j in range(0, N + 1): + s += (A.subs(k, Integer(n + j)).doit() * (n + j)**N * + S.NegativeOne**(j + N) / (factorial(j) * factorial(N - j))) + return s + + +def shanks(A, k, n, m=1): + """ + Calculate an approximation for lim k->oo A(k) using the n-term Shanks + transformation S(A)(n). With m > 1, calculate the m-fold recursive + Shanks transformation S(S(...S(A)...))(n). + + The Shanks transformation is useful for summing Taylor series that + converge slowly near a pole or singularity, e.g. for log(2): + + >>> from sympy.abc import k, n + >>> from sympy import Sum, Integer + >>> from sympy.series.acceleration import shanks + >>> A = Sum(Integer(-1)**(k+1) / k, (k, 1, n)) + >>> print(round(A.subs(n, 100).doit().evalf(), 10)) + 0.6881721793 + >>> print(round(shanks(A, n, 25).evalf(), 10)) + 0.6931396564 + >>> print(round(shanks(A, n, 25, 5).evalf(), 10)) + 0.6931471806 + + The correct value is 0.6931471805599453094172321215. + """ + table = [A.subs(k, Integer(j)).doit() for j in range(n + m + 2)] + table2 = table.copy() + + for i in range(1, m + 1): + for j in range(i, n + m + 1): + x, y, z = table[j - 1], table[j], table[j + 1] + table2[j] = (z*x - y**2) / (z + x - 2*y) + table = table2.copy() + return table[n] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/approximants.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/approximants.py new file mode 100644 index 0000000000000000000000000000000000000000..3d54ce41bc7367606ae6260f8e9ac00149cedc0f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/approximants.py @@ -0,0 +1,103 @@ +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.polys.polytools import lcm +from sympy.utilities import public + +@public +def approximants(l, X=Symbol('x'), simplify=False): + """ + Return a generator for consecutive Pade approximants for a series. + It can also be used for computing the rational generating function of a + series when possible, since the last approximant returned by the generator + will be the generating function (if any). + + Explanation + =========== + + The input list can contain more complex expressions than integer or rational + numbers; symbols may also be involved in the computation. An example below + show how to compute the generating function of the whole Pascal triangle. + + The generator can be asked to apply the sympy.simplify function on each + generated term, which will make the computation slower; however it may be + useful when symbols are involved in the expressions. + + Examples + ======== + + >>> from sympy.series import approximants + >>> from sympy import lucas, fibonacci, symbols, binomial + >>> g = [lucas(k) for k in range(16)] + >>> [e for e in approximants(g)] + [2, -4/(x - 2), (5*x - 2)/(3*x - 1), (x - 2)/(x**2 + x - 1)] + + >>> h = [fibonacci(k) for k in range(16)] + >>> [e for e in approximants(h)] + [x, -x/(x - 1), (x**2 - x)/(2*x - 1), -x/(x**2 + x - 1)] + + >>> x, t = symbols("x,t") + >>> p=[sum(binomial(k,i)*x**i for i in range(k+1)) for k in range(16)] + >>> y = approximants(p, t) + >>> for k in range(3): print(next(y)) + 1 + (x + 1)/((-x - 1)*(t*(x + 1) + (x + 1)/(-x - 1))) + nan + + >>> y = approximants(p, t, simplify=True) + >>> for k in range(3): print(next(y)) + 1 + -1/(t*(x + 1) - 1) + nan + + See Also + ======== + + sympy.concrete.guess.guess_generating_function_rational + mpmath.pade + """ + from sympy.simplify import simplify as simp + from sympy.simplify.radsimp import denom + p1, q1 = [S.One], [S.Zero] + p2, q2 = [S.Zero], [S.One] + while len(l): + b = 0 + while l[b]==0: + b += 1 + if b == len(l): + return + m = [S.One/l[b]] + for k in range(b+1, len(l)): + s = 0 + for j in range(b, k): + s -= l[j+1] * m[b-j-1] + m.append(s/l[b]) + l = m + a, l[0] = l[0], 0 + p = [0] * max(len(p2), b+len(p1)) + q = [0] * max(len(q2), b+len(q1)) + for k in range(len(p2)): + p[k] = a*p2[k] + for k in range(b, b+len(p1)): + p[k] += p1[k-b] + for k in range(len(q2)): + q[k] = a*q2[k] + for k in range(b, b+len(q1)): + q[k] += q1[k-b] + while p[-1]==0: p.pop() + while q[-1]==0: q.pop() + p1, p2 = p2, p + q1, q2 = q2, q + + # yield result + c = 1 + for x in p: + c = lcm(c, denom(x)) + for x in q: + c = lcm(c, denom(x)) + out = ( sum(c*e*X**k for k, e in enumerate(p)) + / sum(c*e*X**k for k, e in enumerate(q)) ) + if simplify: + yield(simp(out)) + else: + yield out + return diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/aseries.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/aseries.py new file mode 100644 index 0000000000000000000000000000000000000000..dbbe0664e6d43a9329f37789c16c48143eda5413 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/aseries.py @@ -0,0 +1,10 @@ +from sympy.core.sympify import sympify + + +def aseries(expr, x=None, n=6, bound=0, hir=False): + """ + See the docstring of Expr.aseries() for complete details of this wrapper. + + """ + expr = sympify(expr) + return expr.aseries(x, n, bound, hir) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/bench_limit.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/bench_limit.py new file mode 100644 index 0000000000000000000000000000000000000000..eafc28328848dad4b3ea433537971f5785253afe --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/bench_limit.py @@ -0,0 +1,9 @@ +from sympy.core.numbers import oo +from sympy.core.symbol import Symbol +from sympy.series.limits import limit + +x = Symbol('x') + + +def timeit_limit_1x(): + limit(1/x, x, oo) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/bench_order.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/bench_order.py new file mode 100644 index 0000000000000000000000000000000000000000..1c85fa173dfc2a478792de8ab816c23ba9d408ef --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/benchmarks/bench_order.py @@ -0,0 +1,10 @@ +from sympy.core.add import Add +from sympy.core.symbol import Symbol +from sympy.series.order import O + +x = Symbol('x') +l = [x**i for i in range(1000)] +l.append(O(x**1001)) + +def timeit_order_1x(): + Add(*l) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/formal.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/formal.py new file mode 100644 index 0000000000000000000000000000000000000000..ada591e03dd607daf8f8a5da1cf38cf283a3ed86 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/formal.py @@ -0,0 +1,1863 @@ +"""Formal Power Series""" + +from collections import defaultdict + +from sympy.core.numbers import (nan, oo, zoo) +from sympy.core.add import Add +from sympy.core.expr import Expr +from sympy.core.function import Derivative, Function, expand +from sympy.core.mul import Mul +from sympy.core.numbers import Rational +from sympy.core.relational import Eq +from sympy.sets.sets import Interval +from sympy.core.singleton import S +from sympy.core.symbol import Wild, Dummy, symbols, Symbol +from sympy.core.sympify import sympify +from sympy.discrete.convolutions import convolution +from sympy.functions.combinatorial.factorials import binomial, factorial, rf +from sympy.functions.combinatorial.numbers import bell +from sympy.functions.elementary.integers import floor, frac, ceiling +from sympy.functions.elementary.miscellaneous import Min, Max +from sympy.functions.elementary.piecewise import Piecewise +from sympy.series.limits import Limit +from sympy.series.order import Order +from sympy.series.sequences import sequence +from sympy.series.series_class import SeriesBase +from sympy.utilities.iterables import iterable + + + +def rational_algorithm(f, x, k, order=4, full=False): + """ + Rational algorithm for computing + formula of coefficients of Formal Power Series + of a function. + + Explanation + =========== + + Applicable when f(x) or some derivative of f(x) + is a rational function in x. + + :func:`rational_algorithm` uses :func:`~.apart` function for partial fraction + decomposition. :func:`~.apart` by default uses 'undetermined coefficients + method'. By setting ``full=True``, 'Bronstein's algorithm' can be used + instead. + + Looks for derivative of a function up to 4'th order (by default). + This can be overridden using order option. + + Parameters + ========== + + x : Symbol + order : int, optional + Order of the derivative of ``f``, Default is 4. + full : bool + + Returns + ======= + + formula : Expr + ind : Expr + Independent terms. + order : int + full : bool + + Examples + ======== + + >>> from sympy import log, atan + >>> from sympy.series.formal import rational_algorithm as ra + >>> from sympy.abc import x, k + + >>> ra(1 / (1 - x), x, k) + (1, 0, 0) + >>> ra(log(1 + x), x, k) + (-1/((-1)**k*k), 0, 1) + + >>> ra(atan(x), x, k, full=True) + ((-I/(2*(-I)**k) + I/(2*I**k))/k, 0, 1) + + Notes + ===== + + By setting ``full=True``, range of admissible functions to be solved using + ``rational_algorithm`` can be increased. This option should be used + carefully as it can significantly slow down the computation as ``doit`` is + performed on the :class:`~.RootSum` object returned by the :func:`~.apart` + function. Use ``full=False`` whenever possible. + + See Also + ======== + + sympy.polys.partfrac.apart + + References + ========== + + .. [1] Formal Power Series - Dominik Gruntz, Wolfram Koepf + .. [2] Power Series in Computer Algebra - Wolfram Koepf + + """ + from sympy.polys import RootSum, apart + from sympy.integrals import integrate + + diff = f + ds = [] # list of diff + + for i in range(order + 1): + if i: + diff = diff.diff(x) + + if diff.is_rational_function(x): + coeff, sep = S.Zero, S.Zero + + terms = apart(diff, x, full=full) + if terms.has(RootSum): + terms = terms.doit() + + for t in Add.make_args(terms): + num, den = t.as_numer_denom() + if not den.has(x): + sep += t + else: + if isinstance(den, Mul): + # m*(n*x - a)**j -> (n*x - a)**j + ind = den.as_independent(x) + den = ind[1] + num /= ind[0] + + # (n*x - a)**j -> (x - b) + den, j = den.as_base_exp() + a, xterm = den.as_coeff_add(x) + + # term -> m/x**n + if not a: + sep += t + continue + + xc = xterm[0].coeff(x) + a /= -xc + num /= xc**j + + ak = ((-1)**j * num * + binomial(j + k - 1, k).rewrite(factorial) / + a**(j + k)) + coeff += ak + + # Hacky, better way? + if coeff.is_zero: + return None + if (coeff.has(x) or coeff.has(zoo) or coeff.has(oo) or + coeff.has(nan)): + return None + + for j in range(i): + coeff = (coeff / (k + j + 1)) + sep = integrate(sep, x) + sep += (ds.pop() - sep).limit(x, 0) # constant of integration + return (coeff.subs(k, k - i), sep, i) + + else: + ds.append(diff) + + return None + + +def rational_independent(terms, x): + """ + Returns a list of all the rationally independent terms. + + Examples + ======== + + >>> from sympy import sin, cos + >>> from sympy.series.formal import rational_independent + >>> from sympy.abc import x + + >>> rational_independent([cos(x), sin(x)], x) + [cos(x), sin(x)] + >>> rational_independent([x**2, sin(x), x*sin(x), x**3], x) + [x**3 + x**2, x*sin(x) + sin(x)] + """ + if not terms: + return [] + + ind = terms[0:1] + + for t in terms[1:]: + n = t.as_independent(x)[1] + for i, term in enumerate(ind): + d = term.as_independent(x)[1] + q = (n / d).cancel() + if q.is_rational_function(x): + ind[i] += t + break + else: + ind.append(t) + return ind + + +def simpleDE(f, x, g, order=4): + r""" + Generates simple DE. + + Explanation + =========== + + DE is of the form + + .. math:: + f^k(x) + \sum\limits_{j=0}^{k-1} A_j f^j(x) = 0 + + where :math:`A_j` should be rational function in x. + + Generates DE's upto order 4 (default). DE's can also have free parameters. + + By increasing order, higher order DE's can be found. + + Yields a tuple of (DE, order). + """ + from sympy.solvers.solveset import linsolve + + a = symbols('a:%d' % (order)) + + def _makeDE(k): + eq = f.diff(x, k) + Add(*[a[i]*f.diff(x, i) for i in range(0, k)]) + DE = g(x).diff(x, k) + Add(*[a[i]*g(x).diff(x, i) for i in range(0, k)]) + return eq, DE + + found = False + for k in range(1, order + 1): + eq, DE = _makeDE(k) + eq = eq.expand() + terms = eq.as_ordered_terms() + ind = rational_independent(terms, x) + if found or len(ind) == k: + sol = dict(zip(a, (i for s in linsolve(ind, a[:k]) for i in s))) + if sol: + found = True + DE = DE.subs(sol) + DE = DE.as_numer_denom()[0] + DE = DE.factor().as_coeff_mul(Derivative)[1][0] + yield DE.collect(Derivative(g(x))), k + + +def exp_re(DE, r, k): + """Converts a DE with constant coefficients (explike) into a RE. + + Explanation + =========== + + Performs the substitution: + + .. math:: + f^j(x) \\to r(k + j) + + Normalises the terms so that lowest order of a term is always r(k). + + Examples + ======== + + >>> from sympy import Function, Derivative + >>> from sympy.series.formal import exp_re + >>> from sympy.abc import x, k + >>> f, r = Function('f'), Function('r') + + >>> exp_re(-f(x) + Derivative(f(x)), r, k) + -r(k) + r(k + 1) + >>> exp_re(Derivative(f(x), x) + Derivative(f(x), (x, 2)), r, k) + r(k) + r(k + 1) + + See Also + ======== + + sympy.series.formal.hyper_re + """ + RE = S.Zero + + g = DE.atoms(Function).pop() + + mini = None + for t in Add.make_args(DE): + coeff, d = t.as_independent(g) + if isinstance(d, Derivative): + j = d.derivative_count + else: + j = 0 + if mini is None or j < mini: + mini = j + RE += coeff * r(k + j) + if mini: + RE = RE.subs(k, k - mini) + return RE + + +def hyper_re(DE, r, k): + """ + Converts a DE into a RE. + + Explanation + =========== + + Performs the substitution: + + .. math:: + x^l f^j(x) \\to (k + 1 - l)_j . a_{k + j - l} + + Normalises the terms so that lowest order of a term is always r(k). + + Examples + ======== + + >>> from sympy import Function, Derivative + >>> from sympy.series.formal import hyper_re + >>> from sympy.abc import x, k + >>> f, r = Function('f'), Function('r') + + >>> hyper_re(-f(x) + Derivative(f(x)), r, k) + (k + 1)*r(k + 1) - r(k) + >>> hyper_re(-x*f(x) + Derivative(f(x), (x, 2)), r, k) + (k + 2)*(k + 3)*r(k + 3) - r(k) + + See Also + ======== + + sympy.series.formal.exp_re + """ + RE = S.Zero + + g = DE.atoms(Function).pop() + x = g.atoms(Symbol).pop() + + mini = None + for t in Add.make_args(DE.expand()): + coeff, d = t.as_independent(g) + c, v = coeff.as_independent(x) + l = v.as_coeff_exponent(x)[1] + if isinstance(d, Derivative): + j = d.derivative_count + else: + j = 0 + RE += c * rf(k + 1 - l, j) * r(k + j - l) + if mini is None or j - l < mini: + mini = j - l + + RE = RE.subs(k, k - mini) + + m = Wild('m') + return RE.collect(r(k + m)) + + +def _transformation_a(f, x, P, Q, k, m, shift): + f *= x**(-shift) + P = P.subs(k, k + shift) + Q = Q.subs(k, k + shift) + return f, P, Q, m + + +def _transformation_c(f, x, P, Q, k, m, scale): + f = f.subs(x, x**scale) + P = P.subs(k, k / scale) + Q = Q.subs(k, k / scale) + m *= scale + return f, P, Q, m + + +def _transformation_e(f, x, P, Q, k, m): + f = f.diff(x) + P = P.subs(k, k + 1) * (k + m + 1) + Q = Q.subs(k, k + 1) * (k + 1) + return f, P, Q, m + + +def _apply_shift(sol, shift): + return [(res, cond + shift) for res, cond in sol] + + +def _apply_scale(sol, scale): + return [(res, cond / scale) for res, cond in sol] + + +def _apply_integrate(sol, x, k): + return [(res / ((cond + 1)*(cond.as_coeff_Add()[1].coeff(k))), cond + 1) + for res, cond in sol] + + +def _compute_formula(f, x, P, Q, k, m, k_max): + """Computes the formula for f.""" + from sympy.polys import roots + + sol = [] + for i in range(k_max + 1, k_max + m + 1): + if (i < 0) == True: + continue + r = f.diff(x, i).limit(x, 0) / factorial(i) + if r.is_zero: + continue + + kterm = m*k + i + res = r + + p = P.subs(k, kterm) + q = Q.subs(k, kterm) + c1 = p.subs(k, 1/k).leadterm(k)[0] + c2 = q.subs(k, 1/k).leadterm(k)[0] + res *= (-c1 / c2)**k + + res *= Mul(*[rf(-r, k)**mul for r, mul in roots(p, k).items()]) + res /= Mul(*[rf(-r, k)**mul for r, mul in roots(q, k).items()]) + + sol.append((res, kterm)) + + return sol + + +def _rsolve_hypergeometric(f, x, P, Q, k, m): + """ + Recursive wrapper to rsolve_hypergeometric. + + Explanation + =========== + + Returns a Tuple of (formula, series independent terms, + maximum power of x in independent terms) if successful + otherwise ``None``. + + See :func:`rsolve_hypergeometric` for details. + """ + from sympy.polys import lcm, roots + from sympy.integrals import integrate + + # transformation - c + proots, qroots = roots(P, k), roots(Q, k) + all_roots = dict(proots) + all_roots.update(qroots) + scale = lcm([r.as_numer_denom()[1] for r, t in all_roots.items() + if r.is_rational]) + f, P, Q, m = _transformation_c(f, x, P, Q, k, m, scale) + + # transformation - a + qroots = roots(Q, k) + if qroots: + k_min = Min(*qroots.keys()) + else: + k_min = S.Zero + shift = k_min + m + f, P, Q, m = _transformation_a(f, x, P, Q, k, m, shift) + + l = (x*f).limit(x, 0) + if not isinstance(l, Limit) and l != 0: # Ideally should only be l != 0 + return None + + qroots = roots(Q, k) + if qroots: + k_max = Max(*qroots.keys()) + else: + k_max = S.Zero + + ind, mp = S.Zero, -oo + for i in range(k_max + m + 1): + r = f.diff(x, i).limit(x, 0) / factorial(i) + if r.is_finite is False: + old_f = f + f, P, Q, m = _transformation_a(f, x, P, Q, k, m, i) + f, P, Q, m = _transformation_e(f, x, P, Q, k, m) + sol, ind, mp = _rsolve_hypergeometric(f, x, P, Q, k, m) + sol = _apply_integrate(sol, x, k) + sol = _apply_shift(sol, i) + ind = integrate(ind, x) + ind += (old_f - ind).limit(x, 0) # constant of integration + mp += 1 + return sol, ind, mp + elif r: + ind += r*x**(i + shift) + pow_x = Rational((i + shift), scale) + if pow_x > mp: + mp = pow_x # maximum power of x + ind = ind.subs(x, x**(1/scale)) + + sol = _compute_formula(f, x, P, Q, k, m, k_max) + sol = _apply_shift(sol, shift) + sol = _apply_scale(sol, scale) + + return sol, ind, mp + + +def rsolve_hypergeometric(f, x, P, Q, k, m): + """ + Solves RE of hypergeometric type. + + Explanation + =========== + + Attempts to solve RE of the form + + Q(k)*a(k + m) - P(k)*a(k) + + Transformations that preserve Hypergeometric type: + + a. x**n*f(x): b(k + m) = R(k - n)*b(k) + b. f(A*x): b(k + m) = A**m*R(k)*b(k) + c. f(x**n): b(k + n*m) = R(k/n)*b(k) + d. f(x**(1/m)): b(k + 1) = R(k*m)*b(k) + e. f'(x): b(k + m) = ((k + m + 1)/(k + 1))*R(k + 1)*b(k) + + Some of these transformations have been used to solve the RE. + + Returns + ======= + + formula : Expr + ind : Expr + Independent terms. + order : int + + Examples + ======== + + >>> from sympy import exp, ln, S + >>> from sympy.series.formal import rsolve_hypergeometric as rh + >>> from sympy.abc import x, k + + >>> rh(exp(x), x, -S.One, (k + 1), k, 1) + (Piecewise((1/factorial(k), Eq(Mod(k, 1), 0)), (0, True)), 1, 1) + + >>> rh(ln(1 + x), x, k**2, k*(k + 1), k, 1) + (Piecewise(((-1)**(k - 1)*factorial(k - 1)/RisingFactorial(2, k - 1), + Eq(Mod(k, 1), 0)), (0, True)), x, 2) + + References + ========== + + .. [1] Formal Power Series - Dominik Gruntz, Wolfram Koepf + .. [2] Power Series in Computer Algebra - Wolfram Koepf + """ + result = _rsolve_hypergeometric(f, x, P, Q, k, m) + + if result is None: + return None + + sol_list, ind, mp = result + + sol_dict = defaultdict(lambda: S.Zero) + for res, cond in sol_list: + j, mk = cond.as_coeff_Add() + c = mk.coeff(k) + + if j.is_integer is False: + res *= x**frac(j) + j = floor(j) + + res = res.subs(k, (k - j) / c) + cond = Eq(k % c, j % c) + sol_dict[cond] += res # Group together formula for same conditions + + sol = [(res, cond) for cond, res in sol_dict.items()] + sol.append((S.Zero, True)) + sol = Piecewise(*sol) + + if mp is -oo: + s = S.Zero + elif mp.is_integer is False: + s = ceiling(mp) + else: + s = mp + 1 + + # save all the terms of + # form 1/x**k in ind + if s < 0: + ind += sum(sequence(sol * x**k, (k, s, -1))) + s = S.Zero + + return (sol, ind, s) + + +def _solve_hyper_RE(f, x, RE, g, k): + """See docstring of :func:`rsolve_hypergeometric` for details.""" + terms = Add.make_args(RE) + + if len(terms) == 2: + gs = list(RE.atoms(Function)) + P, Q = map(RE.coeff, gs) + m = gs[1].args[0] - gs[0].args[0] + if m < 0: + P, Q = Q, P + m = abs(m) + return rsolve_hypergeometric(f, x, P, Q, k, m) + + +def _solve_explike_DE(f, x, DE, g, k): + """Solves DE with constant coefficients.""" + from sympy.solvers import rsolve + + for t in Add.make_args(DE): + coeff, d = t.as_independent(g) + if coeff.free_symbols: + return + + RE = exp_re(DE, g, k) + + init = {} + for i in range(len(Add.make_args(RE))): + if i: + f = f.diff(x) + init[g(k).subs(k, i)] = f.limit(x, 0) + + sol = rsolve(RE, g(k), init) + + if sol: + return (sol / factorial(k), S.Zero, S.Zero) + + +def _solve_simple(f, x, DE, g, k): + """Converts DE into RE and solves using :func:`rsolve`.""" + from sympy.solvers import rsolve + + RE = hyper_re(DE, g, k) + + init = {} + for i in range(len(Add.make_args(RE))): + if i: + f = f.diff(x) + init[g(k).subs(k, i)] = f.limit(x, 0) / factorial(i) + + sol = rsolve(RE, g(k), init) + + if sol: + return (sol, S.Zero, S.Zero) + + +def _transform_explike_DE(DE, g, x, order, syms): + """Converts DE with free parameters into DE with constant coefficients.""" + from sympy.solvers.solveset import linsolve + + eq = [] + highest_coeff = DE.coeff(Derivative(g(x), x, order)) + for i in range(order): + coeff = DE.coeff(Derivative(g(x), x, i)) + coeff = (coeff / highest_coeff).expand().collect(x) + eq.extend(Add.make_args(coeff)) + temp = [] + for e in eq: + if e.has(x): + break + elif e.has(Symbol): + temp.append(e) + else: + eq = temp + if eq: + sol = dict(zip(syms, (i for s in linsolve(eq, list(syms)) for i in s))) + if sol: + DE = DE.subs(sol) + DE = DE.factor().as_coeff_mul(Derivative)[1][0] + DE = DE.collect(Derivative(g(x))) + return DE + + +def _transform_DE_RE(DE, g, k, order, syms): + """Converts DE with free parameters into RE of hypergeometric type.""" + from sympy.solvers.solveset import linsolve + + RE = hyper_re(DE, g, k) + + eq = [RE.coeff(g(k + i)) for i in range(1, order)] + sol = dict(zip(syms, (i for s in linsolve(eq, list(syms)) for i in s))) + if sol: + m = Wild('m') + RE = RE.subs(sol) + RE = RE.factor().as_numer_denom()[0].collect(g(k + m)) + RE = RE.as_coeff_mul(g)[1][0] + for i in range(order): # smallest order should be g(k) + if RE.coeff(g(k + i)) and i: + RE = RE.subs(k, k - i) + break + return RE + + +def solve_de(f, x, DE, order, g, k): + """ + Solves the DE. + + Explanation + =========== + + Tries to solve DE by either converting into a RE containing two terms or + converting into a DE having constant coefficients. + + Returns + ======= + + formula : Expr + ind : Expr + Independent terms. + order : int + + Examples + ======== + + >>> from sympy import Derivative as D, Function + >>> from sympy import exp, ln + >>> from sympy.series.formal import solve_de + >>> from sympy.abc import x, k + >>> f = Function('f') + + >>> solve_de(exp(x), x, D(f(x), x) - f(x), 1, f, k) + (Piecewise((1/factorial(k), Eq(Mod(k, 1), 0)), (0, True)), 1, 1) + + >>> solve_de(ln(1 + x), x, (x + 1)*D(f(x), x, 2) + D(f(x)), 2, f, k) + (Piecewise(((-1)**(k - 1)*factorial(k - 1)/RisingFactorial(2, k - 1), + Eq(Mod(k, 1), 0)), (0, True)), x, 2) + """ + sol = None + syms = DE.free_symbols.difference({g, x}) + + if syms: + RE = _transform_DE_RE(DE, g, k, order, syms) + else: + RE = hyper_re(DE, g, k) + if not RE.free_symbols.difference({k}): + sol = _solve_hyper_RE(f, x, RE, g, k) + + if sol: + return sol + + if syms: + DE = _transform_explike_DE(DE, g, x, order, syms) + if not DE.free_symbols.difference({x}): + sol = _solve_explike_DE(f, x, DE, g, k) + + if sol: + return sol + + +def hyper_algorithm(f, x, k, order=4): + """ + Hypergeometric algorithm for computing Formal Power Series. + + Explanation + =========== + + Steps: + * Generates DE + * Convert the DE into RE + * Solves the RE + + Examples + ======== + + >>> from sympy import exp, ln + >>> from sympy.series.formal import hyper_algorithm + + >>> from sympy.abc import x, k + + >>> hyper_algorithm(exp(x), x, k) + (Piecewise((1/factorial(k), Eq(Mod(k, 1), 0)), (0, True)), 1, 1) + + >>> hyper_algorithm(ln(1 + x), x, k) + (Piecewise(((-1)**(k - 1)*factorial(k - 1)/RisingFactorial(2, k - 1), + Eq(Mod(k, 1), 0)), (0, True)), x, 2) + + See Also + ======== + + sympy.series.formal.simpleDE + sympy.series.formal.solve_de + """ + g = Function('g') + + des = [] # list of DE's + sol = None + for DE, i in simpleDE(f, x, g, order): + if DE is not None: + sol = solve_de(f, x, DE, i, g, k) + if sol: + return sol + if not DE.free_symbols.difference({x}): + des.append(DE) + + # If nothing works + # Try plain rsolve + for DE in des: + sol = _solve_simple(f, x, DE, g, k) + if sol: + return sol + + +def _compute_fps(f, x, x0, dir, hyper, order, rational, full): + """Recursive wrapper to compute fps. + + See :func:`compute_fps` for details. + """ + if x0 in [S.Infinity, S.NegativeInfinity]: + dir = S.One if x0 is S.Infinity else -S.One + temp = f.subs(x, 1/x) + result = _compute_fps(temp, x, 0, dir, hyper, order, rational, full) + if result is None: + return None + return (result[0], result[1].subs(x, 1/x), result[2].subs(x, 1/x)) + elif x0 or dir == -S.One: + if dir == -S.One: + rep = -x + x0 + rep2 = -x + rep2b = x0 + else: + rep = x + x0 + rep2 = x + rep2b = -x0 + temp = f.subs(x, rep) + result = _compute_fps(temp, x, 0, S.One, hyper, order, rational, full) + if result is None: + return None + return (result[0], result[1].subs(x, rep2 + rep2b), + result[2].subs(x, rep2 + rep2b)) + + if f.is_polynomial(x): + k = Dummy('k') + ak = sequence(Coeff(f, x, k), (k, 1, oo)) + xk = sequence(x**k, (k, 0, oo)) + ind = f.coeff(x, 0) + return ak, xk, ind + + # Break instances of Add + # this allows application of different + # algorithms on different terms increasing the + # range of admissible functions. + if isinstance(f, Add): + result = False + ak = sequence(S.Zero, (0, oo)) + ind, xk = S.Zero, None + for t in Add.make_args(f): + res = _compute_fps(t, x, 0, S.One, hyper, order, rational, full) + if res: + if not result: + result = True + xk = res[1] + if res[0].start > ak.start: + seq = ak + s, f = ak.start, res[0].start + else: + seq = res[0] + s, f = res[0].start, ak.start + save = Add(*[z[0]*z[1] for z in zip(seq[0:(f - s)], xk[s:f])]) + ak += res[0] + ind += res[2] + save + else: + ind += t + if result: + return ak, xk, ind + return None + + # The symbolic term - symb, if present, is being separated from the function + # Otherwise symb is being set to S.One + syms = f.free_symbols.difference({x}) + (f, symb) = expand(f).as_independent(*syms) + + result = None + + # from here on it's x0=0 and dir=1 handling + k = Dummy('k') + if rational: + result = rational_algorithm(f, x, k, order, full) + + if result is None and hyper: + result = hyper_algorithm(f, x, k, order) + + if result is None: + return None + + from sympy.simplify.powsimp import powsimp + if symb.is_zero: + symb = S.One + else: + symb = powsimp(symb) + ak = sequence(result[0], (k, result[2], oo)) + xk_formula = powsimp(x**k * symb) + xk = sequence(xk_formula, (k, 0, oo)) + ind = powsimp(result[1] * symb) + + return ak, xk, ind + + +def compute_fps(f, x, x0=0, dir=1, hyper=True, order=4, rational=True, + full=False): + """ + Computes the formula for Formal Power Series of a function. + + Explanation + =========== + + Tries to compute the formula by applying the following techniques + (in order): + + * rational_algorithm + * Hypergeometric algorithm + + Parameters + ========== + + x : Symbol + x0 : number, optional + Point to perform series expansion about. Default is 0. + dir : {1, -1, '+', '-'}, optional + If dir is 1 or '+' the series is calculated from the right and + for -1 or '-' the series is calculated from the left. For smooth + functions this flag will not alter the results. Default is 1. + hyper : {True, False}, optional + Set hyper to False to skip the hypergeometric algorithm. + By default it is set to False. + order : int, optional + Order of the derivative of ``f``, Default is 4. + rational : {True, False}, optional + Set rational to False to skip rational algorithm. By default it is set + to True. + full : {True, False}, optional + Set full to True to increase the range of rational algorithm. + See :func:`rational_algorithm` for details. By default it is set to + False. + + Returns + ======= + + ak : sequence + Sequence of coefficients. + xk : sequence + Sequence of powers of x. + ind : Expr + Independent terms. + mul : Pow + Common terms. + + See Also + ======== + + sympy.series.formal.rational_algorithm + sympy.series.formal.hyper_algorithm + """ + f = sympify(f) + x = sympify(x) + + if not f.has(x): + return None + + x0 = sympify(x0) + + if dir == '+': + dir = S.One + elif dir == '-': + dir = -S.One + elif dir not in [S.One, -S.One]: + raise ValueError("Dir must be '+' or '-'") + else: + dir = sympify(dir) + + return _compute_fps(f, x, x0, dir, hyper, order, rational, full) + + +class Coeff(Function): + """ + Coeff(p, x, n) represents the nth coefficient of the polynomial p in x + """ + @classmethod + def eval(cls, p, x, n): + if p.is_polynomial(x) and n.is_integer: + return p.coeff(x, n) + + +class FormalPowerSeries(SeriesBase): + """ + Represents Formal Power Series of a function. + + Explanation + =========== + + No computation is performed. This class should only to be used to represent + a series. No checks are performed. + + For computing a series use :func:`fps`. + + See Also + ======== + + sympy.series.formal.fps + """ + def __new__(cls, *args): + args = map(sympify, args) + return Expr.__new__(cls, *args) + + def __init__(self, *args): + ak = args[4][0] + k = ak.variables[0] + self.ak_seq = sequence(ak.formula, (k, 1, oo)) + self.fact_seq = sequence(factorial(k), (k, 1, oo)) + self.bell_coeff_seq = self.ak_seq * self.fact_seq + self.sign_seq = sequence((-1, 1), (k, 1, oo)) + + @property + def function(self): + return self.args[0] + + @property + def x(self): + return self.args[1] + + @property + def x0(self): + return self.args[2] + + @property + def dir(self): + return self.args[3] + + @property + def ak(self): + return self.args[4][0] + + @property + def xk(self): + return self.args[4][1] + + @property + def ind(self): + return self.args[4][2] + + @property + def interval(self): + return Interval(0, oo) + + @property + def start(self): + return self.interval.inf + + @property + def stop(self): + return self.interval.sup + + @property + def length(self): + return oo + + @property + def infinite(self): + """Returns an infinite representation of the series""" + from sympy.concrete import Sum + ak, xk = self.ak, self.xk + k = ak.variables[0] + inf_sum = Sum(ak.formula * xk.formula, (k, ak.start, ak.stop)) + + return self.ind + inf_sum + + def _get_pow_x(self, term): + """Returns the power of x in a term.""" + xterm, pow_x = term.as_independent(self.x)[1].as_base_exp() + if not xterm.has(self.x): + return S.Zero + return pow_x + + def polynomial(self, n=6): + """ + Truncated series as polynomial. + + Explanation + =========== + + Returns series expansion of ``f`` upto order ``O(x**n)`` + as a polynomial(without ``O`` term). + """ + terms = [] + sym = self.free_symbols + for i, t in enumerate(self): + xp = self._get_pow_x(t) + if xp.has(*sym): + xp = xp.as_coeff_add(*sym)[0] + if xp >= n: + break + elif xp.is_integer is True and i == n + 1: + break + elif t is not S.Zero: + terms.append(t) + + return Add(*terms) + + def truncate(self, n=6): + """ + Truncated series. + + Explanation + =========== + + Returns truncated series expansion of f upto + order ``O(x**n)``. + + If n is ``None``, returns an infinite iterator. + """ + if n is None: + return iter(self) + + x, x0 = self.x, self.x0 + pt_xk = self.xk.coeff(n) + if x0 is S.NegativeInfinity: + x0 = S.Infinity + + return self.polynomial(n) + Order(pt_xk, (x, x0)) + + def zero_coeff(self): + return self._eval_term(0) + + def _eval_term(self, pt): + try: + pt_xk = self.xk.coeff(pt) + pt_ak = self.ak.coeff(pt).simplify() # Simplify the coefficients + except IndexError: + term = S.Zero + else: + term = (pt_ak * pt_xk) + + if self.ind: + ind = S.Zero + sym = self.free_symbols + for t in Add.make_args(self.ind): + pow_x = self._get_pow_x(t) + if pow_x.has(*sym): + pow_x = pow_x.as_coeff_add(*sym)[0] + if pt == 0 and pow_x < 1: + ind += t + elif pow_x >= pt and pow_x < pt + 1: + ind += t + term += ind + + return term.collect(self.x) + + def _eval_subs(self, old, new): + x = self.x + if old.has(x): + return self + + def _eval_as_leading_term(self, x, logx, cdir): + for t in self: + if t is not S.Zero: + return t + + def _eval_derivative(self, x): + f = self.function.diff(x) + ind = self.ind.diff(x) + + pow_xk = self._get_pow_x(self.xk.formula) + ak = self.ak + k = ak.variables[0] + if ak.formula.has(x): + form = [] + for e, c in ak.formula.args: + temp = S.Zero + for t in Add.make_args(e): + pow_x = self._get_pow_x(t) + temp += t * (pow_xk + pow_x) + form.append((temp, c)) + form = Piecewise(*form) + ak = sequence(form.subs(k, k + 1), (k, ak.start - 1, ak.stop)) + else: + ak = sequence((ak.formula * pow_xk).subs(k, k + 1), + (k, ak.start - 1, ak.stop)) + + return self.func(f, self.x, self.x0, self.dir, (ak, self.xk, ind)) + + def integrate(self, x=None, **kwargs): + """ + Integrate Formal Power Series. + + Examples + ======== + + >>> from sympy import fps, sin, integrate + >>> from sympy.abc import x + >>> f = fps(sin(x)) + >>> f.integrate(x).truncate() + -1 + x**2/2 - x**4/24 + O(x**6) + >>> integrate(f, (x, 0, 1)) + 1 - cos(1) + """ + from sympy.integrals import integrate + + if x is None: + x = self.x + elif iterable(x): + return integrate(self.function, x) + + f = integrate(self.function, x) + ind = integrate(self.ind, x) + ind += (f - ind).limit(x, 0) # constant of integration + + pow_xk = self._get_pow_x(self.xk.formula) + ak = self.ak + k = ak.variables[0] + if ak.formula.has(x): + form = [] + for e, c in ak.formula.args: + temp = S.Zero + for t in Add.make_args(e): + pow_x = self._get_pow_x(t) + temp += t / (pow_xk + pow_x + 1) + form.append((temp, c)) + form = Piecewise(*form) + ak = sequence(form.subs(k, k - 1), (k, ak.start + 1, ak.stop)) + else: + ak = sequence((ak.formula / (pow_xk + 1)).subs(k, k - 1), + (k, ak.start + 1, ak.stop)) + + return self.func(f, self.x, self.x0, self.dir, (ak, self.xk, ind)) + + def product(self, other, x=None, n=6): + """ + Multiplies two Formal Power Series, using discrete convolution and + return the truncated terms upto specified order. + + Parameters + ========== + + n : Number, optional + Specifies the order of the term up to which the polynomial should + be truncated. + + Examples + ======== + + >>> from sympy import fps, sin, exp + >>> from sympy.abc import x + >>> f1 = fps(sin(x)) + >>> f2 = fps(exp(x)) + + >>> f1.product(f2, x).truncate(4) + x + x**2 + x**3/3 + O(x**4) + + See Also + ======== + + sympy.discrete.convolutions + sympy.series.formal.FormalPowerSeriesProduct + + """ + + if n is None: + return iter(self) + + other = sympify(other) + + if not isinstance(other, FormalPowerSeries): + raise ValueError("Both series should be an instance of FormalPowerSeries" + " class.") + + if self.dir != other.dir: + raise ValueError("Both series should be calculated from the" + " same direction.") + elif self.x0 != other.x0: + raise ValueError("Both series should be calculated about the" + " same point.") + + elif self.x != other.x: + raise ValueError("Both series should have the same symbol.") + + return FormalPowerSeriesProduct(self, other) + + def coeff_bell(self, n): + r""" + self.coeff_bell(n) returns a sequence of Bell polynomials of the second kind. + Note that ``n`` should be a integer. + + The second kind of Bell polynomials (are sometimes called "partial" Bell + polynomials or incomplete Bell polynomials) are defined as + + .. math:: + B_{n,k}(x_1, x_2,\dotsc x_{n-k+1}) = + \sum_{j_1+j_2+j_2+\dotsb=k \atop j_1+2j_2+3j_2+\dotsb=n} + \frac{n!}{j_1!j_2!\dotsb j_{n-k+1}!} + \left(\frac{x_1}{1!} \right)^{j_1} + \left(\frac{x_2}{2!} \right)^{j_2} \dotsb + \left(\frac{x_{n-k+1}}{(n-k+1)!} \right) ^{j_{n-k+1}}. + + * ``bell(n, k, (x1, x2, ...))`` gives Bell polynomials of the second kind, + `B_{n,k}(x_1, x_2, \dotsc, x_{n-k+1})`. + + See Also + ======== + + sympy.functions.combinatorial.numbers.bell + + """ + + inner_coeffs = [bell(n, j, tuple(self.bell_coeff_seq[:n-j+1])) for j in range(1, n+1)] + + k = Dummy('k') + return sequence(tuple(inner_coeffs), (k, 1, oo)) + + def compose(self, other, x=None, n=6): + r""" + Returns the truncated terms of the formal power series of the composed function, + up to specified ``n``. + + Explanation + =========== + + If ``f`` and ``g`` are two formal power series of two different functions, + then the coefficient sequence ``ak`` of the composed formal power series `fp` + will be as follows. + + .. math:: + \sum\limits_{k=0}^{n} b_k B_{n,k}(x_1, x_2, \dotsc, x_{n-k+1}) + + Parameters + ========== + + n : Number, optional + Specifies the order of the term up to which the polynomial should + be truncated. + + Examples + ======== + + >>> from sympy import fps, sin, exp + >>> from sympy.abc import x + >>> f1 = fps(exp(x)) + >>> f2 = fps(sin(x)) + + >>> f1.compose(f2, x).truncate() + 1 + x + x**2/2 - x**4/8 - x**5/15 + O(x**6) + + >>> f1.compose(f2, x).truncate(8) + 1 + x + x**2/2 - x**4/8 - x**5/15 - x**6/240 + x**7/90 + O(x**8) + + See Also + ======== + + sympy.functions.combinatorial.numbers.bell + sympy.series.formal.FormalPowerSeriesCompose + + References + ========== + + .. [1] Comtet, Louis: Advanced combinatorics; the art of finite and infinite expansions. Reidel, 1974. + + """ + + if n is None: + return iter(self) + + other = sympify(other) + + if not isinstance(other, FormalPowerSeries): + raise ValueError("Both series should be an instance of FormalPowerSeries" + " class.") + + if self.dir != other.dir: + raise ValueError("Both series should be calculated from the" + " same direction.") + elif self.x0 != other.x0: + raise ValueError("Both series should be calculated about the" + " same point.") + + elif self.x != other.x: + raise ValueError("Both series should have the same symbol.") + + if other._eval_term(0).as_coeff_mul(other.x)[0] is not S.Zero: + raise ValueError("The formal power series of the inner function should not have any " + "constant coefficient term.") + + return FormalPowerSeriesCompose(self, other) + + def inverse(self, x=None, n=6): + r""" + Returns the truncated terms of the inverse of the formal power series, + up to specified ``n``. + + Explanation + =========== + + If ``f`` and ``g`` are two formal power series of two different functions, + then the coefficient sequence ``ak`` of the composed formal power series ``fp`` + will be as follows. + + .. math:: + \sum\limits_{k=0}^{n} (-1)^{k} x_0^{-k-1} B_{n,k}(x_1, x_2, \dotsc, x_{n-k+1}) + + Parameters + ========== + + n : Number, optional + Specifies the order of the term up to which the polynomial should + be truncated. + + Examples + ======== + + >>> from sympy import fps, exp, cos + >>> from sympy.abc import x + >>> f1 = fps(exp(x)) + >>> f2 = fps(cos(x)) + + >>> f1.inverse(x).truncate() + 1 - x + x**2/2 - x**3/6 + x**4/24 - x**5/120 + O(x**6) + + >>> f2.inverse(x).truncate(8) + 1 + x**2/2 + 5*x**4/24 + 61*x**6/720 + O(x**8) + + See Also + ======== + + sympy.functions.combinatorial.numbers.bell + sympy.series.formal.FormalPowerSeriesInverse + + References + ========== + + .. [1] Comtet, Louis: Advanced combinatorics; the art of finite and infinite expansions. Reidel, 1974. + + """ + + if n is None: + return iter(self) + + if self._eval_term(0).is_zero: + raise ValueError("Constant coefficient should exist for an inverse of a formal" + " power series to exist.") + + return FormalPowerSeriesInverse(self) + + def __add__(self, other): + other = sympify(other) + + if isinstance(other, FormalPowerSeries): + if self.dir != other.dir: + raise ValueError("Both series should be calculated from the" + " same direction.") + elif self.x0 != other.x0: + raise ValueError("Both series should be calculated about the" + " same point.") + + x, y = self.x, other.x + f = self.function + other.function.subs(y, x) + + if self.x not in f.free_symbols: + return f + + ak = self.ak + other.ak + if self.ak.start > other.ak.start: + seq = other.ak + s, e = other.ak.start, self.ak.start + else: + seq = self.ak + s, e = self.ak.start, other.ak.start + save = Add(*[z[0]*z[1] for z in zip(seq[0:(e - s)], self.xk[s:e])]) + ind = self.ind + other.ind + save + + return self.func(f, x, self.x0, self.dir, (ak, self.xk, ind)) + + elif not other.has(self.x): + f = self.function + other + ind = self.ind + other + + return self.func(f, self.x, self.x0, self.dir, + (self.ak, self.xk, ind)) + + return Add(self, other) + + def __radd__(self, other): + return self.__add__(other) + + def __neg__(self): + return self.func(-self.function, self.x, self.x0, self.dir, + (-self.ak, self.xk, -self.ind)) + + def __sub__(self, other): + return self.__add__(-other) + + def __rsub__(self, other): + return (-self).__add__(other) + + def __mul__(self, other): + other = sympify(other) + + if other.has(self.x): + return Mul(self, other) + + f = self.function * other + ak = self.ak.coeff_mul(other) + ind = self.ind * other + + return self.func(f, self.x, self.x0, self.dir, (ak, self.xk, ind)) + + def __rmul__(self, other): + return self.__mul__(other) + + +class FiniteFormalPowerSeries(FormalPowerSeries): + """Base Class for Product, Compose and Inverse classes""" + + def __init__(self, *args): + pass + + @property + def ffps(self): + return self.args[0] + + @property + def gfps(self): + return self.args[1] + + @property + def f(self): + return self.ffps.function + + @property + def g(self): + return self.gfps.function + + @property + def infinite(self): + raise NotImplementedError("No infinite version for an object of" + " FiniteFormalPowerSeries class.") + + def _eval_terms(self, n): + raise NotImplementedError("(%s)._eval_terms()" % self) + + def _eval_term(self, pt): + raise NotImplementedError("By the current logic, one can get terms" + "upto a certain order, instead of getting term by term.") + + def polynomial(self, n): + return self._eval_terms(n) + + def truncate(self, n=6): + ffps = self.ffps + pt_xk = ffps.xk.coeff(n) + x, x0 = ffps.x, ffps.x0 + + return self.polynomial(n) + Order(pt_xk, (x, x0)) + + def _eval_derivative(self, x): + raise NotImplementedError + + def integrate(self, x): + raise NotImplementedError + + +class FormalPowerSeriesProduct(FiniteFormalPowerSeries): + """Represents the product of two formal power series of two functions. + + Explanation + =========== + + No computation is performed. Terms are calculated using a term by term logic, + instead of a point by point logic. + + There are two differences between a :obj:`FormalPowerSeries` object and a + :obj:`FormalPowerSeriesProduct` object. The first argument contains the two + functions involved in the product. Also, the coefficient sequence contains + both the coefficient sequence of the formal power series of the involved functions. + + See Also + ======== + + sympy.series.formal.FormalPowerSeries + sympy.series.formal.FiniteFormalPowerSeries + + """ + + def __init__(self, *args): + ffps, gfps = self.ffps, self.gfps + + k = ffps.ak.variables[0] + self.coeff1 = sequence(ffps.ak.formula, (k, 0, oo)) + + k = gfps.ak.variables[0] + self.coeff2 = sequence(gfps.ak.formula, (k, 0, oo)) + + @property + def function(self): + """Function of the product of two formal power series.""" + return self.f * self.g + + def _eval_terms(self, n): + """ + Returns the first ``n`` terms of the product formal power series. + Term by term logic is implemented here. + + Examples + ======== + + >>> from sympy import fps, sin, exp + >>> from sympy.abc import x + >>> f1 = fps(sin(x)) + >>> f2 = fps(exp(x)) + >>> fprod = f1.product(f2, x) + + >>> fprod._eval_terms(4) + x**3/3 + x**2 + x + + See Also + ======== + + sympy.series.formal.FormalPowerSeries.product + + """ + coeff1, coeff2 = self.coeff1, self.coeff2 + + aks = convolution(coeff1[:n], coeff2[:n]) + + terms = [] + for i in range(0, n): + terms.append(aks[i] * self.ffps.xk.coeff(i)) + + return Add(*terms) + + +class FormalPowerSeriesCompose(FiniteFormalPowerSeries): + """ + Represents the composed formal power series of two functions. + + Explanation + =========== + + No computation is performed. Terms are calculated using a term by term logic, + instead of a point by point logic. + + There are two differences between a :obj:`FormalPowerSeries` object and a + :obj:`FormalPowerSeriesCompose` object. The first argument contains the outer + function and the inner function involved in the omposition. Also, the + coefficient sequence contains the generic sequence which is to be multiplied + by a custom ``bell_seq`` finite sequence. The finite terms will then be added up to + get the final terms. + + See Also + ======== + + sympy.series.formal.FormalPowerSeries + sympy.series.formal.FiniteFormalPowerSeries + + """ + + @property + def function(self): + """Function for the composed formal power series.""" + f, g, x = self.f, self.g, self.ffps.x + return f.subs(x, g) + + def _eval_terms(self, n): + """ + Returns the first `n` terms of the composed formal power series. + Term by term logic is implemented here. + + Explanation + =========== + + The coefficient sequence of the :obj:`FormalPowerSeriesCompose` object is the generic sequence. + It is multiplied by ``bell_seq`` to get a sequence, whose terms are added up to get + the final terms for the polynomial. + + Examples + ======== + + >>> from sympy import fps, sin, exp + >>> from sympy.abc import x + >>> f1 = fps(exp(x)) + >>> f2 = fps(sin(x)) + >>> fcomp = f1.compose(f2, x) + + >>> fcomp._eval_terms(6) + -x**5/15 - x**4/8 + x**2/2 + x + 1 + + >>> fcomp._eval_terms(8) + x**7/90 - x**6/240 - x**5/15 - x**4/8 + x**2/2 + x + 1 + + See Also + ======== + + sympy.series.formal.FormalPowerSeries.compose + sympy.series.formal.FormalPowerSeries.coeff_bell + + """ + + ffps, gfps = self.ffps, self.gfps + terms = [ffps.zero_coeff()] + + for i in range(1, n): + bell_seq = gfps.coeff_bell(i) + seq = (ffps.bell_coeff_seq * bell_seq) + terms.append(Add(*(seq[:i])) / ffps.fact_seq[i-1] * ffps.xk.coeff(i)) + + return Add(*terms) + + +class FormalPowerSeriesInverse(FiniteFormalPowerSeries): + """ + Represents the Inverse of a formal power series. + + Explanation + =========== + + No computation is performed. Terms are calculated using a term by term logic, + instead of a point by point logic. + + There is a single difference between a :obj:`FormalPowerSeries` object and a + :obj:`FormalPowerSeriesInverse` object. The coefficient sequence contains the + generic sequence which is to be multiplied by a custom ``bell_seq`` finite sequence. + The finite terms will then be added up to get the final terms. + + See Also + ======== + + sympy.series.formal.FormalPowerSeries + sympy.series.formal.FiniteFormalPowerSeries + + """ + def __init__(self, *args): + ffps = self.ffps + k = ffps.xk.variables[0] + + inv = ffps.zero_coeff() + inv_seq = sequence(inv ** (-(k + 1)), (k, 1, oo)) + self.aux_seq = ffps.sign_seq * ffps.fact_seq * inv_seq + + @property + def function(self): + """Function for the inverse of a formal power series.""" + f = self.f + return 1 / f + + @property + def g(self): + raise ValueError("Only one function is considered while performing" + "inverse of a formal power series.") + + @property + def gfps(self): + raise ValueError("Only one function is considered while performing" + "inverse of a formal power series.") + + def _eval_terms(self, n): + """ + Returns the first ``n`` terms of the composed formal power series. + Term by term logic is implemented here. + + Explanation + =========== + + The coefficient sequence of the `FormalPowerSeriesInverse` object is the generic sequence. + It is multiplied by ``bell_seq`` to get a sequence, whose terms are added up to get + the final terms for the polynomial. + + Examples + ======== + + >>> from sympy import fps, exp, cos + >>> from sympy.abc import x + >>> f1 = fps(exp(x)) + >>> f2 = fps(cos(x)) + >>> finv1, finv2 = f1.inverse(), f2.inverse() + + >>> finv1._eval_terms(6) + -x**5/120 + x**4/24 - x**3/6 + x**2/2 - x + 1 + + >>> finv2._eval_terms(8) + 61*x**6/720 + 5*x**4/24 + x**2/2 + 1 + + See Also + ======== + + sympy.series.formal.FormalPowerSeries.inverse + sympy.series.formal.FormalPowerSeries.coeff_bell + + """ + ffps = self.ffps + terms = [ffps.zero_coeff()] + + for i in range(1, n): + bell_seq = ffps.coeff_bell(i) + seq = (self.aux_seq * bell_seq) + terms.append(Add(*(seq[:i])) / ffps.fact_seq[i-1] * ffps.xk.coeff(i)) + + return Add(*terms) + + +def fps(f, x=None, x0=0, dir=1, hyper=True, order=4, rational=True, full=False): + """ + Generates Formal Power Series of ``f``. + + Explanation + =========== + + Returns the formal series expansion of ``f`` around ``x = x0`` + with respect to ``x`` in the form of a ``FormalPowerSeries`` object. + + Formal Power Series is represented using an explicit formula + computed using different algorithms. + + See :func:`compute_fps` for the more details regarding the computation + of formula. + + Parameters + ========== + + x : Symbol, optional + If x is None and ``f`` is univariate, the univariate symbols will be + supplied, otherwise an error will be raised. + x0 : number, optional + Point to perform series expansion about. Default is 0. + dir : {1, -1, '+', '-'}, optional + If dir is 1 or '+' the series is calculated from the right and + for -1 or '-' the series is calculated from the left. For smooth + functions this flag will not alter the results. Default is 1. + hyper : {True, False}, optional + Set hyper to False to skip the hypergeometric algorithm. + By default it is set to False. + order : int, optional + Order of the derivative of ``f``, Default is 4. + rational : {True, False}, optional + Set rational to False to skip rational algorithm. By default it is set + to True. + full : {True, False}, optional + Set full to True to increase the range of rational algorithm. + See :func:`rational_algorithm` for details. By default it is set to + False. + + Examples + ======== + + >>> from sympy import fps, ln, atan, sin + >>> from sympy.abc import x, n + + Rational Functions + + >>> fps(ln(1 + x)).truncate() + x - x**2/2 + x**3/3 - x**4/4 + x**5/5 + O(x**6) + + >>> fps(atan(x), full=True).truncate() + x - x**3/3 + x**5/5 + O(x**6) + + Symbolic Functions + + >>> fps(x**n*sin(x**2), x).truncate(8) + -x**(n + 6)/6 + x**(n + 2) + O(x**(n + 8)) + + See Also + ======== + + sympy.series.formal.FormalPowerSeries + sympy.series.formal.compute_fps + """ + f = sympify(f) + + if x is None: + free = f.free_symbols + if len(free) == 1: + x = free.pop() + elif not free: + return f + else: + raise NotImplementedError("multivariate formal power series") + + result = compute_fps(f, x, x0, dir, hyper, order, rational, full) + + if result is None: + return f + + return FormalPowerSeries(f, x, x0, dir, result) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/fourier.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/fourier.py new file mode 100644 index 0000000000000000000000000000000000000000..c4ad43a75d0e1d24bfc591383f68965fd8b504c7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/fourier.py @@ -0,0 +1,811 @@ +"""Fourier Series""" + +from sympy.core.numbers import (oo, pi) +from sympy.core.symbol import Wild +from sympy.core.expr import Expr +from sympy.core.add import Add +from sympy.core.containers import Tuple +from sympy.core.singleton import S +from sympy.core.symbol import Dummy, Symbol +from sympy.core.sympify import sympify +from sympy.functions.elementary.trigonometric import sin, cos, sinc +from sympy.series.series_class import SeriesBase +from sympy.series.sequences import SeqFormula +from sympy.sets.sets import Interval +from sympy.utilities.iterables import is_sequence + + +__doctest_requires__ = {('fourier_series',): ['matplotlib']} + + +def fourier_cos_seq(func, limits, n): + """Returns the cos sequence in a Fourier series""" + from sympy.integrals import integrate + x, L = limits[0], limits[2] - limits[1] + cos_term = cos(2*n*pi*x / L) + formula = 2 * cos_term * integrate(func * cos_term, limits) / L + a0 = formula.subs(n, S.Zero) / 2 + return a0, SeqFormula(2 * cos_term * integrate(func * cos_term, limits) + / L, (n, 1, oo)) + + +def fourier_sin_seq(func, limits, n): + """Returns the sin sequence in a Fourier series""" + from sympy.integrals import integrate + x, L = limits[0], limits[2] - limits[1] + sin_term = sin(2*n*pi*x / L) + return SeqFormula(2 * sin_term * integrate(func * sin_term, limits) + / L, (n, 1, oo)) + + +def _process_limits(func, limits): + """ + Limits should be of the form (x, start, stop). + x should be a symbol. Both start and stop should be bounded. + + Explanation + =========== + + * If x is not given, x is determined from func. + * If limits is None. Limit of the form (x, -pi, pi) is returned. + + Examples + ======== + + >>> from sympy.series.fourier import _process_limits as pari + >>> from sympy.abc import x + >>> pari(x**2, (x, -2, 2)) + (x, -2, 2) + >>> pari(x**2, (-2, 2)) + (x, -2, 2) + >>> pari(x**2, None) + (x, -pi, pi) + """ + def _find_x(func): + free = func.free_symbols + if len(free) == 1: + return free.pop() + elif not free: + return Dummy('k') + else: + raise ValueError( + " specify dummy variables for %s. If the function contains" + " more than one free symbol, a dummy variable should be" + " supplied explicitly e.g. FourierSeries(m*n**2, (n, -pi, pi))" + % func) + + x, start, stop = None, None, None + if limits is None: + x, start, stop = _find_x(func), -pi, pi + if is_sequence(limits, Tuple): + if len(limits) == 3: + x, start, stop = limits + elif len(limits) == 2: + x = _find_x(func) + start, stop = limits + + if not isinstance(x, Symbol) or start is None or stop is None: + raise ValueError('Invalid limits given: %s' % str(limits)) + + unbounded = [S.NegativeInfinity, S.Infinity] + if start in unbounded or stop in unbounded: + raise ValueError("Both the start and end value should be bounded") + + return sympify((x, start, stop)) + + +def finite_check(f, x, L): + + def check_fx(exprs, x): + return x not in exprs.free_symbols + + def check_sincos(_expr, x, L): + if isinstance(_expr, (sin, cos)): + sincos_args = _expr.args[0] + + if sincos_args.match(a*(pi/L)*x + b) is not None: + return True + else: + return False + + from sympy.simplify.fu import TR2, TR1, sincos_to_sum + _expr = sincos_to_sum(TR2(TR1(f))) + add_coeff = _expr.as_coeff_add() + + a = Wild('a', properties=[lambda k: k.is_Integer, lambda k: k != S.Zero, ]) + b = Wild('b', properties=[lambda k: x not in k.free_symbols, ]) + + for s in add_coeff[1]: + mul_coeffs = s.as_coeff_mul()[1] + for t in mul_coeffs: + if not (check_fx(t, x) or check_sincos(t, x, L)): + return False, f + + return True, _expr + + +class FourierSeries(SeriesBase): + r"""Represents Fourier sine/cosine series. + + Explanation + =========== + + This class only represents a fourier series. + No computation is performed. + + For how to compute Fourier series, see the :func:`fourier_series` + docstring. + + See Also + ======== + + sympy.series.fourier.fourier_series + """ + def __new__(cls, *args): + args = map(sympify, args) + return Expr.__new__(cls, *args) + + @property + def function(self): + return self.args[0] + + @property + def x(self): + return self.args[1][0] + + @property + def period(self): + return (self.args[1][1], self.args[1][2]) + + @property + def a0(self): + return self.args[2][0] + + @property + def an(self): + return self.args[2][1] + + @property + def bn(self): + return self.args[2][2] + + @property + def interval(self): + return Interval(0, oo) + + @property + def start(self): + return self.interval.inf + + @property + def stop(self): + return self.interval.sup + + @property + def length(self): + return oo + + @property + def L(self): + return abs(self.period[1] - self.period[0]) / 2 + + def _eval_subs(self, old, new): + x = self.x + if old.has(x): + return self + + def truncate(self, n=3): + """ + Return the first n nonzero terms of the series. + + If ``n`` is None return an iterator. + + Parameters + ========== + + n : int or None + Amount of non-zero terms in approximation or None. + + Returns + ======= + + Expr or iterator : + Approximation of function expanded into Fourier series. + + Examples + ======== + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> s = fourier_series(x, (x, -pi, pi)) + >>> s.truncate(4) + 2*sin(x) - sin(2*x) + 2*sin(3*x)/3 - sin(4*x)/2 + + See Also + ======== + + sympy.series.fourier.FourierSeries.sigma_approximation + """ + if n is None: + return iter(self) + + terms = [] + for t in self: + if len(terms) == n: + break + if t is not S.Zero: + terms.append(t) + + return Add(*terms) + + def sigma_approximation(self, n=3): + r""" + Return :math:`\sigma`-approximation of Fourier series with respect + to order n. + + Explanation + =========== + + Sigma approximation adjusts a Fourier summation to eliminate the Gibbs + phenomenon which would otherwise occur at discontinuities. + A sigma-approximated summation for a Fourier series of a T-periodical + function can be written as + + .. math:: + s(\theta) = \frac{1}{2} a_0 + \sum _{k=1}^{m-1} + \operatorname{sinc} \Bigl( \frac{k}{m} \Bigr) \cdot + \left[ a_k \cos \Bigl( \frac{2\pi k}{T} \theta \Bigr) + + b_k \sin \Bigl( \frac{2\pi k}{T} \theta \Bigr) \right], + + where :math:`a_0, a_k, b_k, k=1,\ldots,{m-1}` are standard Fourier + series coefficients and + :math:`\operatorname{sinc} \Bigl( \frac{k}{m} \Bigr)` is a Lanczos + :math:`\sigma` factor (expressed in terms of normalized + :math:`\operatorname{sinc}` function). + + Parameters + ========== + + n : int + Highest order of the terms taken into account in approximation. + + Returns + ======= + + Expr : + Sigma approximation of function expanded into Fourier series. + + Examples + ======== + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> s = fourier_series(x, (x, -pi, pi)) + >>> s.sigma_approximation(4) + 2*sin(x)*sinc(pi/4) - 2*sin(2*x)/pi + 2*sin(3*x)*sinc(3*pi/4)/3 + + See Also + ======== + + sympy.series.fourier.FourierSeries.truncate + + Notes + ===== + + The behaviour of + :meth:`~sympy.series.fourier.FourierSeries.sigma_approximation` + is different from :meth:`~sympy.series.fourier.FourierSeries.truncate` + - it takes all nonzero terms of degree smaller than n, rather than + first n nonzero ones. + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Gibbs_phenomenon + .. [2] https://en.wikipedia.org/wiki/Sigma_approximation + """ + terms = [sinc(pi * i / n) * t for i, t in enumerate(self[:n]) + if t is not S.Zero] + return Add(*terms) + + def shift(self, s): + """ + Shift the function by a term independent of x. + + Explanation + =========== + + f(x) -> f(x) + s + + This is fast, if Fourier series of f(x) is already + computed. + + Examples + ======== + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> s = fourier_series(x**2, (x, -pi, pi)) + >>> s.shift(1).truncate() + -4*cos(x) + cos(2*x) + 1 + pi**2/3 + """ + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + a0 = self.a0 + s + sfunc = self.function + s + + return self.func(sfunc, self.args[1], (a0, self.an, self.bn)) + + def shiftx(self, s): + """ + Shift x by a term independent of x. + + Explanation + =========== + + f(x) -> f(x + s) + + This is fast, if Fourier series of f(x) is already + computed. + + Examples + ======== + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> s = fourier_series(x**2, (x, -pi, pi)) + >>> s.shiftx(1).truncate() + -4*cos(x + 1) + cos(2*x + 2) + pi**2/3 + """ + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + an = self.an.subs(x, x + s) + bn = self.bn.subs(x, x + s) + sfunc = self.function.subs(x, x + s) + + return self.func(sfunc, self.args[1], (self.a0, an, bn)) + + def scale(self, s): + """ + Scale the function by a term independent of x. + + Explanation + =========== + + f(x) -> s * f(x) + + This is fast, if Fourier series of f(x) is already + computed. + + Examples + ======== + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> s = fourier_series(x**2, (x, -pi, pi)) + >>> s.scale(2).truncate() + -8*cos(x) + 2*cos(2*x) + 2*pi**2/3 + """ + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + an = self.an.coeff_mul(s) + bn = self.bn.coeff_mul(s) + a0 = self.a0 * s + sfunc = self.args[0] * s + + return self.func(sfunc, self.args[1], (a0, an, bn)) + + def scalex(self, s): + """ + Scale x by a term independent of x. + + Explanation + =========== + + f(x) -> f(s*x) + + This is fast, if Fourier series of f(x) is already + computed. + + Examples + ======== + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> s = fourier_series(x**2, (x, -pi, pi)) + >>> s.scalex(2).truncate() + -4*cos(2*x) + cos(4*x) + pi**2/3 + """ + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + an = self.an.subs(x, x * s) + bn = self.bn.subs(x, x * s) + sfunc = self.function.subs(x, x * s) + + return self.func(sfunc, self.args[1], (self.a0, an, bn)) + + def _eval_as_leading_term(self, x, logx, cdir): + for t in self: + if t is not S.Zero: + return t + + def _eval_term(self, pt): + if pt == 0: + return self.a0 + return self.an.coeff(pt) + self.bn.coeff(pt) + + def __neg__(self): + return self.scale(-1) + + def __add__(self, other): + if isinstance(other, FourierSeries): + if self.period != other.period: + raise ValueError("Both the series should have same periods") + + x, y = self.x, other.x + function = self.function + other.function.subs(y, x) + + if self.x not in function.free_symbols: + return function + + an = self.an + other.an + bn = self.bn + other.bn + a0 = self.a0 + other.a0 + + return self.func(function, self.args[1], (a0, an, bn)) + + return Add(self, other) + + def __sub__(self, other): + return self.__add__(-other) + + +class FiniteFourierSeries(FourierSeries): + r"""Represents Finite Fourier sine/cosine series. + + For how to compute Fourier series, see the :func:`fourier_series` + docstring. + + Parameters + ========== + + f : Expr + Expression for finding fourier_series + + limits : ( x, start, stop) + x is the independent variable for the expression f + (start, stop) is the period of the fourier series + + exprs: (a0, an, bn) or Expr + a0 is the constant term a0 of the fourier series + an is a dictionary of coefficients of cos terms + an[k] = coefficient of cos(pi*(k/L)*x) + bn is a dictionary of coefficients of sin terms + bn[k] = coefficient of sin(pi*(k/L)*x) + + or exprs can be an expression to be converted to fourier form + + Methods + ======= + + This class is an extension of FourierSeries class. + Please refer to sympy.series.fourier.FourierSeries for + further information. + + See Also + ======== + + sympy.series.fourier.FourierSeries + sympy.series.fourier.fourier_series + """ + + def __new__(cls, f, limits, exprs): + f = sympify(f) + limits = sympify(limits) + exprs = sympify(exprs) + + if not (isinstance(exprs, Tuple) and len(exprs) == 3): # exprs is not of form (a0, an, bn) + # Converts the expression to fourier form + c, e = exprs.as_coeff_add() + from sympy.simplify.fu import TR10 + rexpr = c + Add(*[TR10(i) for i in e]) + a0, exp_ls = rexpr.expand(trig=False, power_base=False, power_exp=False, log=False).as_coeff_add() + + x = limits[0] + L = abs(limits[2] - limits[1]) / 2 + + a = Wild('a', properties=[lambda k: k.is_Integer, lambda k: k is not S.Zero, ]) + b = Wild('b', properties=[lambda k: x not in k.free_symbols, ]) + + an = {} + bn = {} + + # separates the coefficients of sin and cos terms in dictionaries an, and bn + for p in exp_ls: + t = p.match(b * cos(a * (pi / L) * x)) + q = p.match(b * sin(a * (pi / L) * x)) + if t: + an[t[a]] = t[b] + an.get(t[a], S.Zero) + elif q: + bn[q[a]] = q[b] + bn.get(q[a], S.Zero) + else: + a0 += p + + exprs = Tuple(a0, an, bn) + + return Expr.__new__(cls, f, limits, exprs) + + @property + def interval(self): + _length = 1 if self.a0 else 0 + _length += max(set(self.an.keys()).union(set(self.bn.keys()))) + 1 + return Interval(0, _length) + + @property + def length(self): + return self.stop - self.start + + def shiftx(self, s): + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + _expr = self.truncate().subs(x, x + s) + sfunc = self.function.subs(x, x + s) + + return self.func(sfunc, self.args[1], _expr) + + def scale(self, s): + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + _expr = self.truncate() * s + sfunc = self.function * s + + return self.func(sfunc, self.args[1], _expr) + + def scalex(self, s): + s, x = sympify(s), self.x + + if x in s.free_symbols: + raise ValueError("'%s' should be independent of %s" % (s, x)) + + _expr = self.truncate().subs(x, x * s) + sfunc = self.function.subs(x, x * s) + + return self.func(sfunc, self.args[1], _expr) + + def _eval_term(self, pt): + if pt == 0: + return self.a0 + + _term = self.an.get(pt, S.Zero) * cos(pt * (pi / self.L) * self.x) \ + + self.bn.get(pt, S.Zero) * sin(pt * (pi / self.L) * self.x) + return _term + + def __add__(self, other): + if isinstance(other, FourierSeries): + return other.__add__(fourier_series(self.function, self.args[1],\ + finite=False)) + elif isinstance(other, FiniteFourierSeries): + if self.period != other.period: + raise ValueError("Both the series should have same periods") + + x, y = self.x, other.x + function = self.function + other.function.subs(y, x) + + if self.x not in function.free_symbols: + return function + + return fourier_series(function, limits=self.args[1]) + + +def fourier_series(f, limits=None, finite=True): + r"""Computes the Fourier trigonometric series expansion. + + Explanation + =========== + + Fourier trigonometric series of $f(x)$ over the interval $(a, b)$ + is defined as: + + .. math:: + \frac{a_0}{2} + \sum_{n=1}^{\infty} + (a_n \cos(\frac{2n \pi x}{L}) + b_n \sin(\frac{2n \pi x}{L})) + + where the coefficients are: + + .. math:: + L = b - a + + .. math:: + a_0 = \frac{2}{L} \int_{a}^{b}{f(x) dx} + + .. math:: + a_n = \frac{2}{L} \int_{a}^{b}{f(x) \cos(\frac{2n \pi x}{L}) dx} + + .. math:: + b_n = \frac{2}{L} \int_{a}^{b}{f(x) \sin(\frac{2n \pi x}{L}) dx} + + The condition whether the function $f(x)$ given should be periodic + or not is more than necessary, because it is sufficient to consider + the series to be converging to $f(x)$ only in the given interval, + not throughout the whole real line. + + This also brings a lot of ease for the computation because + you do not have to make $f(x)$ artificially periodic by + wrapping it with piecewise, modulo operations, + but you can shape the function to look like the desired periodic + function only in the interval $(a, b)$, and the computed series will + automatically become the series of the periodic version of $f(x)$. + + This property is illustrated in the examples section below. + + Parameters + ========== + + limits : (sym, start, end), optional + *sym* denotes the symbol the series is computed with respect to. + + *start* and *end* denotes the start and the end of the interval + where the fourier series converges to the given function. + + Default range is specified as $-\pi$ and $\pi$. + + Returns + ======= + + FourierSeries + A symbolic object representing the Fourier trigonometric series. + + Examples + ======== + + Computing the Fourier series of $f(x) = x^2$: + + >>> from sympy import fourier_series, pi + >>> from sympy.abc import x + >>> f = x**2 + >>> s = fourier_series(f, (x, -pi, pi)) + >>> s1 = s.truncate(n=3) + >>> s1 + -4*cos(x) + cos(2*x) + pi**2/3 + + Shifting of the Fourier series: + + >>> s.shift(1).truncate() + -4*cos(x) + cos(2*x) + 1 + pi**2/3 + >>> s.shiftx(1).truncate() + -4*cos(x + 1) + cos(2*x + 2) + pi**2/3 + + Scaling of the Fourier series: + + >>> s.scale(2).truncate() + -8*cos(x) + 2*cos(2*x) + 2*pi**2/3 + >>> s.scalex(2).truncate() + -4*cos(2*x) + cos(4*x) + pi**2/3 + + Computing the Fourier series of $f(x) = x$: + + This illustrates how truncating to the higher order gives better + convergence. + + .. plot:: + :context: reset + :format: doctest + :include-source: True + + >>> from sympy import fourier_series, pi, plot + >>> from sympy.abc import x + >>> f = x + >>> s = fourier_series(f, (x, -pi, pi)) + >>> s1 = s.truncate(n = 3) + >>> s2 = s.truncate(n = 5) + >>> s3 = s.truncate(n = 7) + >>> p = plot(f, s1, s2, s3, (x, -pi, pi), show=False, legend=True) + + >>> p[0].line_color = (0, 0, 0) + >>> p[0].label = 'x' + >>> p[1].line_color = (0.7, 0.7, 0.7) + >>> p[1].label = 'n=3' + >>> p[2].line_color = (0.5, 0.5, 0.5) + >>> p[2].label = 'n=5' + >>> p[3].line_color = (0.3, 0.3, 0.3) + >>> p[3].label = 'n=7' + + >>> p.show() + + This illustrates how the series converges to different sawtooth + waves if the different ranges are specified. + + .. plot:: + :context: close-figs + :format: doctest + :include-source: True + + >>> s1 = fourier_series(x, (x, -1, 1)).truncate(10) + >>> s2 = fourier_series(x, (x, -pi, pi)).truncate(10) + >>> s3 = fourier_series(x, (x, 0, 1)).truncate(10) + >>> p = plot(x, s1, s2, s3, (x, -5, 5), show=False, legend=True) + + >>> p[0].line_color = (0, 0, 0) + >>> p[0].label = 'x' + >>> p[1].line_color = (0.7, 0.7, 0.7) + >>> p[1].label = '[-1, 1]' + >>> p[2].line_color = (0.5, 0.5, 0.5) + >>> p[2].label = '[-pi, pi]' + >>> p[3].line_color = (0.3, 0.3, 0.3) + >>> p[3].label = '[0, 1]' + + >>> p.show() + + Notes + ===== + + Computing Fourier series can be slow + due to the integration required in computing + an, bn. + + It is faster to compute Fourier series of a function + by using shifting and scaling on an already + computed Fourier series rather than computing + again. + + e.g. If the Fourier series of ``x**2`` is known + the Fourier series of ``x**2 - 1`` can be found by shifting by ``-1``. + + See Also + ======== + + sympy.series.fourier.FourierSeries + + References + ========== + + .. [1] https://mathworld.wolfram.com/FourierSeries.html + """ + f = sympify(f) + + limits = _process_limits(f, limits) + x = limits[0] + + if x not in f.free_symbols: + return f + + if finite: + L = abs(limits[2] - limits[1]) / 2 + is_finite, res_f = finite_check(f, x, L) + if is_finite: + return FiniteFourierSeries(f, limits, res_f) + + n = Dummy('n') + center = (limits[1] + limits[2]) / 2 + if center.is_zero: + neg_f = f.subs(x, -x) + if f == neg_f: + a0, an = fourier_cos_seq(f, limits, n) + bn = SeqFormula(0, (1, oo)) + return FourierSeries(f, limits, (a0, an, bn)) + elif f == -neg_f: + a0 = S.Zero + an = SeqFormula(0, (1, oo)) + bn = fourier_sin_seq(f, limits, n) + return FourierSeries(f, limits, (a0, an, bn)) + a0, an = fourier_cos_seq(f, limits, n) + bn = fourier_sin_seq(f, limits, n) + return FourierSeries(f, limits, (a0, an, bn)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/gruntz.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/gruntz.py new file mode 100644 index 0000000000000000000000000000000000000000..20ba3150e9918384141e755a39f5bacb0e76db55 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/gruntz.py @@ -0,0 +1,701 @@ +""" +Limits +====== + +Implemented according to the PhD thesis +https://www.cybertester.com/data/gruntz.pdf, which contains very thorough +descriptions of the algorithm including many examples. We summarize here +the gist of it. + +All functions are sorted according to how rapidly varying they are at +infinity using the following rules. Any two functions f and g can be +compared using the properties of L: + +L=lim log|f(x)| / log|g(x)| (for x -> oo) + +We define >, < ~ according to:: + + 1. f > g .... L=+-oo + + we say that: + - f is greater than any power of g + - f is more rapidly varying than g + - f goes to infinity/zero faster than g + + 2. f < g .... L=0 + + we say that: + - f is lower than any power of g + + 3. f ~ g .... L!=0, +-oo + + we say that: + - both f and g are bounded from above and below by suitable integral + powers of the other + +Examples +======== +:: + 2 < x < exp(x) < exp(x**2) < exp(exp(x)) + 2 ~ 3 ~ -5 + x ~ x**2 ~ x**3 ~ 1/x ~ x**m ~ -x + exp(x) ~ exp(-x) ~ exp(2x) ~ exp(x)**2 ~ exp(x+exp(-x)) + f ~ 1/f + +So we can divide all the functions into comparability classes (x and x^2 +belong to one class, exp(x) and exp(-x) belong to some other class). In +principle, we could compare any two functions, but in our algorithm, we +do not compare anything below the class 2~3~-5 (for example log(x) is +below this), so we set 2~3~-5 as the lowest comparability class. + +Given the function f, we find the list of most rapidly varying (mrv set) +subexpressions of it. This list belongs to the same comparability class. +Let's say it is {exp(x), exp(2x)}. Using the rule f ~ 1/f we find an +element "w" (either from the list or a new one) from the same +comparability class which goes to zero at infinity. In our example we +set w=exp(-x) (but we could also set w=exp(-2x) or w=exp(-3x) ...). We +rewrite the mrv set using w, in our case {1/w, 1/w^2}, and substitute it +into f. Then we expand f into a series in w:: + + f = c0*w^e0 + c1*w^e1 + ... + O(w^en), where e0oo, lim f = lim c0*w^e0, because all the other terms go to zero, +because w goes to zero faster than the ci and ei. So:: + + for e0>0, lim f = 0 + for e0<0, lim f = +-oo (the sign depends on the sign of c0) + for e0=0, lim f = lim c0 + +We need to recursively compute limits at several places of the algorithm, but +as is shown in the PhD thesis, it always finishes. + +Important functions from the implementation: + +compare(a, b, x) compares "a" and "b" by computing the limit L. +mrv(e, x) returns list of most rapidly varying (mrv) subexpressions of "e" +rewrite(e, Omega, x, wsym) rewrites "e" in terms of w +leadterm(f, x) returns the lowest power term in the series of f +mrv_leadterm(e, x) returns the lead term (c0, e0) for e +limitinf(e, x) computes lim e (for x->oo) +limit(e, z, z0) computes any limit by converting it to the case x->oo + +All the functions are really simple and straightforward except +rewrite(), which is the most difficult/complex part of the algorithm. +When the algorithm fails, the bugs are usually in the series expansion +(i.e. in SymPy) or in rewrite. + +This code is almost exact rewrite of the Maple code inside the Gruntz +thesis. + +Debugging +--------- + +Because the gruntz algorithm is highly recursive, it's difficult to +figure out what went wrong inside a debugger. Instead, turn on nice +debug prints by defining the environment variable SYMPY_DEBUG. For +example: + +[user@localhost]: SYMPY_DEBUG=True ./bin/isympy + +In [1]: limit(sin(x)/x, x, 0) +limitinf(_x*sin(1/_x), _x) = 1 ++-mrv_leadterm(_x*sin(1/_x), _x) = (1, 0) +| +-mrv(_x*sin(1/_x), _x) = set([_x]) +| | +-mrv(_x, _x) = set([_x]) +| | +-mrv(sin(1/_x), _x) = set([_x]) +| | +-mrv(1/_x, _x) = set([_x]) +| | +-mrv(_x, _x) = set([_x]) +| +-mrv_leadterm(exp(_x)*sin(exp(-_x)), _x, set([exp(_x)])) = (1, 0) +| +-rewrite(exp(_x)*sin(exp(-_x)), set([exp(_x)]), _x, _w) = (1/_w*sin(_w), -_x) +| +-sign(_x, _x) = 1 +| +-mrv_leadterm(1, _x) = (1, 0) ++-sign(0, _x) = 0 ++-limitinf(1, _x) = 1 + +And check manually which line is wrong. Then go to the source code and +debug this function to figure out the exact problem. + +""" +from functools import reduce + +from sympy.core import Basic, S, Mul, PoleError +from sympy.core.cache import cacheit +from sympy.core.function import AppliedUndef +from sympy.core.intfunc import ilcm +from sympy.core.numbers import I, oo +from sympy.core.symbol import Dummy, Wild +from sympy.core.traversal import bottom_up + +from sympy.functions import log, exp, sign as _sign +from sympy.series.order import Order +from sympy.utilities.misc import debug_decorator as debug +from sympy.utilities.timeutils import timethis + +timeit = timethis('gruntz') + + +def compare(a, b, x): + """Returns "<" if a" for a>b""" + # log(exp(...)) must always be simplified here for termination + la, lb = log(a), log(b) + if isinstance(a, Basic) and (isinstance(a, exp) or (a.is_Pow and a.base == S.Exp1)): + la = a.exp + if isinstance(b, Basic) and (isinstance(b, exp) or (b.is_Pow and b.base == S.Exp1)): + lb = b.exp + + c = limitinf(la/lb, x) + if c == 0: + return "<" + elif c.is_infinite: + return ">" + else: + return "=" + + +class SubsSet(dict): + """ + Stores (expr, dummy) pairs, and how to rewrite expr-s. + + Explanation + =========== + + The gruntz algorithm needs to rewrite certain expressions in term of a new + variable w. We cannot use subs, because it is just too smart for us. For + example:: + + > Omega=[exp(exp(_p - exp(-_p))/(1 - 1/_p)), exp(exp(_p))] + > O2=[exp(-exp(_p) + exp(-exp(-_p))*exp(_p)/(1 - 1/_p))/_w, 1/_w] + > e = exp(exp(_p - exp(-_p))/(1 - 1/_p)) - exp(exp(_p)) + > e.subs(Omega[0],O2[0]).subs(Omega[1],O2[1]) + -1/w + exp(exp(p)*exp(-exp(-p))/(1 - 1/p)) + + is really not what we want! + + So we do it the hard way and keep track of all the things we potentially + want to substitute by dummy variables. Consider the expression:: + + exp(x - exp(-x)) + exp(x) + x. + + The mrv set is {exp(x), exp(-x), exp(x - exp(-x))}. + We introduce corresponding dummy variables d1, d2, d3 and rewrite:: + + d3 + d1 + x. + + This class first of all keeps track of the mapping expr->variable, i.e. + will at this stage be a dictionary:: + + {exp(x): d1, exp(-x): d2, exp(x - exp(-x)): d3}. + + [It turns out to be more convenient this way round.] + But sometimes expressions in the mrv set have other expressions from the + mrv set as subexpressions, and we need to keep track of that as well. In + this case, d3 is really exp(x - d2), so rewrites at this stage is:: + + {d3: exp(x-d2)}. + + The function rewrite uses all this information to correctly rewrite our + expression in terms of w. In this case w can be chosen to be exp(-x), + i.e. d2. The correct rewriting then is:: + + exp(-w)/w + 1/w + x. + """ + def __init__(self): + self.rewrites = {} + + def __repr__(self): + return super().__repr__() + ', ' + self.rewrites.__repr__() + + def __getitem__(self, key): + if key not in self: + self[key] = Dummy() + return dict.__getitem__(self, key) + + def do_subs(self, e): + """Substitute the variables with expressions""" + for expr, var in self.items(): + e = e.xreplace({var: expr}) + return e + + def meets(self, s2): + """Tell whether or not self and s2 have non-empty intersection""" + return set(self.keys()).intersection(list(s2.keys())) != set() + + def union(self, s2, exps=None): + """Compute the union of self and s2, adjusting exps""" + res = self.copy() + tr = {} + for expr, var in s2.items(): + if expr in self: + if exps: + exps = exps.xreplace({var: res[expr]}) + tr[var] = res[expr] + else: + res[expr] = var + for var, rewr in s2.rewrites.items(): + res.rewrites[var] = rewr.xreplace(tr) + return res, exps + + def copy(self): + """Create a shallow copy of SubsSet""" + r = SubsSet() + r.rewrites = self.rewrites.copy() + for expr, var in self.items(): + r[expr] = var + return r + + +@debug +def mrv(e, x): + """Returns a SubsSet of most rapidly varying (mrv) subexpressions of 'e', + and e rewritten in terms of these""" + from sympy.simplify.powsimp import powsimp + e = powsimp(e, deep=True, combine='exp') + if not isinstance(e, Basic): + raise TypeError("e should be an instance of Basic") + if not e.has(x): + return SubsSet(), e + elif e == x: + s = SubsSet() + return s, s[x] + elif e.is_Mul or e.is_Add: + i, d = e.as_independent(x) # throw away x-independent terms + if d.func != e.func: + s, expr = mrv(d, x) + return s, e.func(i, expr) + a, b = d.as_two_terms() + s1, e1 = mrv(a, x) + s2, e2 = mrv(b, x) + return mrv_max1(s1, s2, e.func(i, e1, e2), x) + elif e.is_Pow and e.base != S.Exp1: + e1 = S.One + while e.is_Pow: + b1 = e.base + e1 *= e.exp + e = b1 + if b1 == 1: + return SubsSet(), b1 + if e1.has(x): + return mrv(exp(e1*log(b1)), x) + else: + s, expr = mrv(b1, x) + return s, expr**e1 + elif isinstance(e, log): + s, expr = mrv(e.args[0], x) + return s, log(expr) + elif isinstance(e, exp) or (e.is_Pow and e.base == S.Exp1): + # We know from the theory of this algorithm that exp(log(...)) may always + # be simplified here, and doing so is vital for termination. + if isinstance(e.exp, log): + return mrv(e.exp.args[0], x) + # if a product has an infinite factor the result will be + # infinite if there is no zero, otherwise NaN; here, we + # consider the result infinite if any factor is infinite + li = limitinf(e.exp, x) + if any(_.is_infinite for _ in Mul.make_args(li)): + s1 = SubsSet() + e1 = s1[e] + s2, e2 = mrv(e.exp, x) + su = s1.union(s2)[0] + su.rewrites[e1] = exp(e2) + return mrv_max3(s1, e1, s2, exp(e2), su, e1, x) + else: + s, expr = mrv(e.exp, x) + return s, exp(expr) + elif isinstance(e, AppliedUndef): + raise ValueError("MRV set computation for UndefinedFunction is not allowed") + elif e.is_Function: + l = [mrv(a, x) for a in e.args] + l2 = [s for (s, _) in l if s != SubsSet()] + if len(l2) != 1: + # e.g. something like BesselJ(x, x) + raise NotImplementedError("MRV set computation for functions in" + " several variables not implemented.") + s, ss = l2[0], SubsSet() + args = [ss.do_subs(x[1]) for x in l] + return s, e.func(*args) + elif e.is_Derivative: + raise NotImplementedError("MRV set computation for derivatives" + " not implemented yet.") + raise NotImplementedError( + "Don't know how to calculate the mrv of '%s'" % e) + + +def mrv_max3(f, expsf, g, expsg, union, expsboth, x): + """ + Computes the maximum of two sets of expressions f and g, which + are in the same comparability class, i.e. max() compares (two elements of) + f and g and returns either (f, expsf) [if f is larger], (g, expsg) + [if g is larger] or (union, expsboth) [if f, g are of the same class]. + """ + if not isinstance(f, SubsSet): + raise TypeError("f should be an instance of SubsSet") + if not isinstance(g, SubsSet): + raise TypeError("g should be an instance of SubsSet") + if f == SubsSet(): + return g, expsg + elif g == SubsSet(): + return f, expsf + elif f.meets(g): + return union, expsboth + + c = compare(list(f.keys())[0], list(g.keys())[0], x) + if c == ">": + return f, expsf + elif c == "<": + return g, expsg + else: + if c != "=": + raise ValueError("c should be =") + return union, expsboth + + +def mrv_max1(f, g, exps, x): + """Computes the maximum of two sets of expressions f and g, which + are in the same comparability class, i.e. mrv_max1() compares (two elements of) + f and g and returns the set, which is in the higher comparability class + of the union of both, if they have the same order of variation. + Also returns exps, with the appropriate substitutions made. + """ + u, b = f.union(g, exps) + return mrv_max3(f, g.do_subs(exps), g, f.do_subs(exps), + u, b, x) + + +@debug +@cacheit +@timeit +def sign(e, x): + """ + Returns a sign of an expression e(x) for x->oo. + + :: + + e > 0 for x sufficiently large ... 1 + e == 0 for x sufficiently large ... 0 + e < 0 for x sufficiently large ... -1 + + The result of this function is currently undefined if e changes sign + arbitrarily often for arbitrarily large x (e.g. sin(x)). + + Note that this returns zero only if e is *constantly* zero + for x sufficiently large. [If e is constant, of course, this is just + the same thing as the sign of e.] + """ + if not isinstance(e, Basic): + raise TypeError("e should be an instance of Basic") + + if e.is_positive: + return 1 + elif e.is_negative: + return -1 + elif e.is_zero: + return 0 + + elif not e.has(x): + from sympy.simplify import logcombine + e = logcombine(e) + return _sign(e) + elif e == x: + return 1 + elif e.is_Mul: + a, b = e.as_two_terms() + sa = sign(a, x) + if not sa: + return 0 + return sa * sign(b, x) + elif isinstance(e, exp): + return 1 + elif e.is_Pow: + if e.base == S.Exp1: + return 1 + s = sign(e.base, x) + if s == 1: + return 1 + if e.exp.is_Integer: + return s**e.exp + elif isinstance(e, log) and e.args[0].is_positive: + return sign(e.args[0] - 1, x) + + # if all else fails, do it the hard way + c0, e0 = mrv_leadterm(e, x) + return sign(c0, x) + + +@debug +@timeit +@cacheit +def limitinf(e, x): + """Limit e(x) for x-> oo.""" + # rewrite e in terms of tractable functions only + + old = e + if not e.has(x): + return e # e is a constant + from sympy.simplify.powsimp import powdenest + from sympy.calculus.util import AccumBounds + if e.has(Order): + e = e.expand().removeO() + if not x.is_positive or x.is_integer: + # We make sure that x.is_positive is True and x.is_integer is None + # so we get all the correct mathematical behavior from the expression. + # We need a fresh variable. + p = Dummy('p', positive=True) + e = e.subs(x, p) + x = p + e = e.rewrite('tractable', deep=True, limitvar=x) + e = powdenest(e) + if isinstance(e, AccumBounds): + if mrv_leadterm(e.min, x) != mrv_leadterm(e.max, x): + raise NotImplementedError + c0, e0 = mrv_leadterm(e.min, x) + else: + c0, e0 = mrv_leadterm(e, x) + sig = sign(e0, x) + if sig == 1: + return S.Zero # e0>0: lim f = 0 + elif sig == -1: # e0<0: lim f = +-oo (the sign depends on the sign of c0) + if c0.match(I*Wild("a", exclude=[I])): + return c0*oo + s = sign(c0, x) + # the leading term shouldn't be 0: + if s == 0: + raise ValueError("Leading term should not be 0") + return s*oo + elif sig == 0: + if c0 == old: + c0 = c0.cancel() + return limitinf(c0, x) # e0=0: lim f = lim c0 + else: + raise ValueError("{} could not be evaluated".format(sig)) + + +def moveup2(s, x): + r = SubsSet() + for expr, var in s.items(): + r[expr.xreplace({x: exp(x)})] = var + for var, expr in s.rewrites.items(): + r.rewrites[var] = s.rewrites[var].xreplace({x: exp(x)}) + return r + + +def moveup(l, x): + return [e.xreplace({x: exp(x)}) for e in l] + + +@debug +@timeit +@cacheit +def mrv_leadterm(e, x): + """Returns (c0, e0) for e.""" + Omega = SubsSet() + if not e.has(x): + return (e, S.Zero) + if Omega == SubsSet(): + Omega, exps = mrv(e, x) + if not Omega: + # e really does not depend on x after simplification + return exps, S.Zero + if x in Omega: + # move the whole omega up (exponentiate each term): + Omega_up = moveup2(Omega, x) + exps_up = moveup([exps], x)[0] + # NOTE: there is no need to move this down! + Omega = Omega_up + exps = exps_up + # + # The positive dummy, w, is used here so log(w*2) etc. will expand; + # a unique dummy is needed in this algorithm + # + # For limits of complex functions, the algorithm would have to be + # improved, or just find limits of Re and Im components separately. + # + w = Dummy("w", positive=True) + f, logw = rewrite(exps, Omega, x, w) + + # Ensure expressions of the form exp(log(...)) don't get simplified automatically in the previous steps. + # see: https://github.com/sympy/sympy/issues/15323#issuecomment-478639399 + f = f.replace(lambda f: f.is_Pow and f.has(x), lambda f: exp(log(f.base)*f.exp)) + + try: + lt = f.leadterm(w, logx=logw) + except (NotImplementedError, PoleError, ValueError): + n0 = 1 + _series = Order(1) + incr = S.One + while _series.is_Order: + _series = f._eval_nseries(w, n=n0+incr, logx=logw) + incr *= 2 + series = _series.expand().removeO() + try: + lt = series.leadterm(w, logx=logw) + except (NotImplementedError, PoleError, ValueError): + lt = f.as_coeff_exponent(w) + if lt[0].has(w): + base = f.as_base_exp()[0].as_coeff_exponent(w) + ex = f.as_base_exp()[1] + lt = (base[0]**ex, base[1]*ex) + return (lt[0].subs(log(w), logw), lt[1]) + + +def build_expression_tree(Omega, rewrites): + r""" Helper function for rewrite. + + We need to sort Omega (mrv set) so that we replace an expression before + we replace any expression in terms of which it has to be rewritten:: + + e1 ---> e2 ---> e3 + \ + -> e4 + + Here we can do e1, e2, e3, e4 or e1, e2, e4, e3. + To do this we assemble the nodes into a tree, and sort them by height. + + This function builds the tree, rewrites then sorts the nodes. + """ + class Node: + def __init__(self): + self.before = [] + self.expr = None + self.var = None + def ht(self): + return reduce(lambda x, y: x + y, + [x.ht() for x in self.before], 1) + nodes = {} + for expr, v in Omega: + n = Node() + n.var = v + n.expr = expr + nodes[v] = n + for _, v in Omega: + if v in rewrites: + n = nodes[v] + r = rewrites[v] + for _, v2 in Omega: + if r.has(v2): + n.before.append(nodes[v2]) + + return nodes + + +@debug +@timeit +def rewrite(e, Omega, x, wsym): + """e(x) ... the function + Omega ... the mrv set + wsym ... the symbol which is going to be used for w + + Returns the rewritten e in terms of w and log(w). See test_rewrite1() + for examples and correct results. + """ + + from sympy import AccumBounds + if not isinstance(Omega, SubsSet): + raise TypeError("Omega should be an instance of SubsSet") + if len(Omega) == 0: + raise ValueError("Length cannot be 0") + # all items in Omega must be exponentials + for t in Omega.keys(): + if not isinstance(t, exp): + raise ValueError("Value should be exp") + rewrites = Omega.rewrites + Omega = list(Omega.items()) + + nodes = build_expression_tree(Omega, rewrites) + Omega.sort(key=lambda x: nodes[x[1]].ht(), reverse=True) + + # make sure we know the sign of each exp() term; after the loop, + # g is going to be the "w" - the simplest one in the mrv set + for g, _ in Omega: + sig = sign(g.exp, x) + if sig != 1 and sig != -1 and not sig.has(AccumBounds): + raise NotImplementedError('Result depends on the sign of %s' % sig) + if sig == 1: + wsym = 1/wsym # if g goes to oo, substitute 1/w + # O2 is a list, which results by rewriting each item in Omega using "w" + O2 = [] + denominators = [] + for f, var in Omega: + c = limitinf(f.exp/g.exp, x) + if c.is_Rational: + denominators.append(c.q) + arg = f.exp + if var in rewrites: + if not isinstance(rewrites[var], exp): + raise ValueError("Value should be exp") + arg = rewrites[var].args[0] + O2.append((var, exp((arg - c*g.exp))*wsym**c)) + + # Remember that Omega contains subexpressions of "e". So now we find + # them in "e" and substitute them for our rewriting, stored in O2 + + # the following powsimp is necessary to automatically combine exponentials, + # so that the .xreplace() below succeeds: + # TODO this should not be necessary + from sympy.simplify.powsimp import powsimp + f = powsimp(e, deep=True, combine='exp') + for a, b in O2: + f = f.xreplace({a: b}) + + for _, var in Omega: + assert not f.has(var) + + # finally compute the logarithm of w (logw). + logw = g.exp + if sig == 1: + logw = -logw # log(w)->log(1/w)=-log(w) + + # Some parts of SymPy have difficulty computing series expansions with + # non-integral exponents. The following heuristic improves the situation: + exponent = reduce(ilcm, denominators, 1) + f = f.subs({wsym: wsym**exponent}) + logw /= exponent + + # bottom_up function is required for a specific case - when f is + # -exp(p/(p + 1)) + exp(-p**2/(p + 1) + p). No current simplification + # methods reduce this to 0 while not expanding polynomials. + f = bottom_up(f, lambda w: getattr(w, 'normal', lambda: w)()) + + return f, logw + + +def gruntz(e, z, z0, dir="+"): + """ + Compute the limit of e(z) at the point z0 using the Gruntz algorithm. + + Explanation + =========== + + ``z0`` can be any expression, including oo and -oo. + + For ``dir="+"`` (default) it calculates the limit from the right + (z->z0+) and for ``dir="-"`` the limit from the left (z->z0-). For infinite z0 + (oo or -oo), the dir argument does not matter. + + This algorithm is fully described in the module docstring in the gruntz.py + file. It relies heavily on the series expansion. Most frequently, gruntz() + is only used if the faster limit() function (which uses heuristics) fails. + """ + if not z.is_symbol: + raise NotImplementedError("Second argument must be a Symbol") + + # convert all limits to the limit z->oo; sign of z is handled in limitinf + r = None + if z0 in (oo, I*oo): + e0 = e + elif z0 in (-oo, -I*oo): + e0 = e.subs(z, -z) + else: + if str(dir) == "-": + e0 = e.subs(z, z0 - 1/z) + elif str(dir) == "+": + e0 = e.subs(z, z0 + 1/z) + else: + raise NotImplementedError("dir must be '+' or '-'") + + r = limitinf(e0, z) + + # This is a bit of a heuristic for nice results... we always rewrite + # tractable functions in terms of familiar intractable ones. + # It might be nicer to rewrite the exactly to what they were initially, + # but that would take some work to implement. + return r.rewrite('intractable', deep=True) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/kauers.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/kauers.py new file mode 100644 index 0000000000000000000000000000000000000000..9e9645ff15ee5ae3c1d1c8709f76aed1b366f50a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/kauers.py @@ -0,0 +1,51 @@ +def finite_diff(expression, variable, increment=1): + """ + Takes as input a polynomial expression and the variable used to construct + it and returns the difference between function's value when the input is + incremented to 1 and the original function value. If you want an increment + other than one supply it as a third argument. + + Examples + ======== + + >>> from sympy.abc import x, y, z + >>> from sympy.series.kauers import finite_diff + >>> finite_diff(x**2, x) + 2*x + 1 + >>> finite_diff(y**3 + 2*y**2 + 3*y + 4, y) + 3*y**2 + 7*y + 6 + >>> finite_diff(x**2 + 3*x + 8, x, 2) + 4*x + 10 + >>> finite_diff(z**3 + 8*z, z, 3) + 9*z**2 + 27*z + 51 + """ + expression = expression.expand() + expression2 = expression.subs(variable, variable + increment) + expression2 = expression2.expand() + return expression2 - expression + +def finite_diff_kauers(sum): + """ + Takes as input a Sum instance and returns the difference between the sum + with the upper index incremented by 1 and the original sum. For example, + if S(n) is a sum, then finite_diff_kauers will return S(n + 1) - S(n). + + Examples + ======== + + >>> from sympy.series.kauers import finite_diff_kauers + >>> from sympy import Sum + >>> from sympy.abc import x, y, m, n, k + >>> finite_diff_kauers(Sum(k, (k, 1, n))) + n + 1 + >>> finite_diff_kauers(Sum(1/k, (k, 1, n))) + 1/(n + 1) + >>> finite_diff_kauers(Sum((x*y**2), (x, 1, n), (y, 1, m))) + (m + 1)**2*(n + 1) + >>> finite_diff_kauers(Sum((x*y), (x, 1, m), (y, 1, n))) + (m + 1)*(n + 1) + """ + function = sum.function + for l in sum.limits: + function = function.subs(l[0], l[- 1] + 1) + return function diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/limits.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/limits.py new file mode 100644 index 0000000000000000000000000000000000000000..e15f7a1243452075a76553903cabf60e43942d8c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/limits.py @@ -0,0 +1,394 @@ +from sympy.calculus.accumulationbounds import AccumBounds +from sympy.core import S, Symbol, Add, sympify, Expr, PoleError, Mul +from sympy.core.exprtools import factor_terms +from sympy.core.numbers import Float, _illegal +from sympy.core.function import AppliedUndef +from sympy.core.symbol import Dummy +from sympy.functions.combinatorial.factorials import factorial +from sympy.functions.elementary.complexes import (Abs, sign, arg, re) +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.special.gamma_functions import gamma +from sympy.polys import PolynomialError, factor +from sympy.series.order import Order +from .gruntz import gruntz + +def limit(e, z, z0, dir="+"): + """Computes the limit of ``e(z)`` at the point ``z0``. + + Parameters + ========== + + e : expression, the limit of which is to be taken + + z : symbol representing the variable in the limit. + Other symbols are treated as constants. Multivariate limits + are not supported. + + z0 : the value toward which ``z`` tends. Can be any expression, + including ``oo`` and ``-oo``. + + dir : string, optional (default: "+") + The limit is bi-directional if ``dir="+-"``, from the right + (z->z0+) if ``dir="+"``, and from the left (z->z0-) if + ``dir="-"``. For infinite ``z0`` (``oo`` or ``-oo``), the ``dir`` + argument is determined from the direction of the infinity + (i.e., ``dir="-"`` for ``oo``). + + Examples + ======== + + >>> from sympy import limit, sin, oo + >>> from sympy.abc import x + >>> limit(sin(x)/x, x, 0) + 1 + >>> limit(1/x, x, 0) # default dir='+' + oo + >>> limit(1/x, x, 0, dir="-") + -oo + >>> limit(1/x, x, 0, dir='+-') + zoo + >>> limit(1/x, x, oo) + 0 + + Notes + ===== + + First we try some heuristics for easy and frequent cases like "x", "1/x", + "x**2" and similar, so that it's fast. For all other cases, we use the + Gruntz algorithm (see the gruntz() function). + + See Also + ======== + + limit_seq : returns the limit of a sequence. + """ + + return Limit(e, z, z0, dir).doit(deep=False) + + +def heuristics(e, z, z0, dir): + """Computes the limit of an expression term-wise. + Parameters are the same as for the ``limit`` function. + Works with the arguments of expression ``e`` one by one, computing + the limit of each and then combining the results. This approach + works only for simple limits, but it is fast. + """ + + rv = None + if z0 is S.Infinity: + rv = limit(e.subs(z, 1/z), z, S.Zero, "+") + if isinstance(rv, Limit): + return + elif (e.is_Mul or e.is_Add or e.is_Pow or (e.is_Function and not isinstance(e, AppliedUndef))): + r = [] + from sympy.simplify.simplify import together + for a in e.args: + l = limit(a, z, z0, dir) + if l.has(S.Infinity) and l.is_finite is None: + if isinstance(e, Add): + m = factor_terms(e) + if not isinstance(m, Mul): # try together + m = together(m) + if not isinstance(m, Mul): # try factor if the previous methods failed + m = factor(e) + if isinstance(m, Mul): + return heuristics(m, z, z0, dir) + return + return + elif isinstance(l, Limit): + return + elif l is S.NaN: + return + else: + r.append(l) + if r: + rv = e.func(*r) + if rv is S.NaN and e.is_Mul and any(isinstance(rr, AccumBounds) for rr in r): + r2 = [] + e2 = [] + for ii, rval in enumerate(r): + if isinstance(rval, AccumBounds): + r2.append(rval) + else: + e2.append(e.args[ii]) + + if len(e2) > 0: + e3 = Mul(*e2).simplify() + l = limit(e3, z, z0, dir) + rv = l * Mul(*r2) + + if rv is S.NaN: + try: + from sympy.simplify.ratsimp import ratsimp + rat_e = ratsimp(e) + except PolynomialError: + return + if rat_e is S.NaN or rat_e == e: + return + return limit(rat_e, z, z0, dir) + return rv + + +class Limit(Expr): + """Represents an unevaluated limit. + + Examples + ======== + + >>> from sympy import Limit, sin + >>> from sympy.abc import x + >>> Limit(sin(x)/x, x, 0) + Limit(sin(x)/x, x, 0, dir='+') + >>> Limit(1/x, x, 0, dir="-") + Limit(1/x, x, 0, dir='-') + + """ + + def __new__(cls, e, z, z0, dir="+"): + e = sympify(e) + z = sympify(z) + z0 = sympify(z0) + + if z0 in (S.Infinity, S.ImaginaryUnit*S.Infinity): + dir = "-" + elif z0 in (S.NegativeInfinity, S.ImaginaryUnit*S.NegativeInfinity): + dir = "+" + + if(z0.has(z)): + raise NotImplementedError("Limits approaching a variable point are" + " not supported (%s -> %s)" % (z, z0)) + if isinstance(dir, str): + dir = Symbol(dir) + elif not isinstance(dir, Symbol): + raise TypeError("direction must be of type basestring or " + "Symbol, not %s" % type(dir)) + if str(dir) not in ('+', '-', '+-'): + raise ValueError("direction must be one of '+', '-' " + "or '+-', not %s" % dir) + + obj = Expr.__new__(cls) + obj._args = (e, z, z0, dir) + return obj + + + @property + def free_symbols(self): + e = self.args[0] + isyms = e.free_symbols + isyms.difference_update(self.args[1].free_symbols) + isyms.update(self.args[2].free_symbols) + return isyms + + + def pow_heuristics(self, e): + _, z, z0, _ = self.args + b1, e1 = e.base, e.exp + if not b1.has(z): + res = limit(e1*log(b1), z, z0) + return exp(res) + + ex_lim = limit(e1, z, z0) + base_lim = limit(b1, z, z0) + + if base_lim is S.One: + if ex_lim in (S.Infinity, S.NegativeInfinity): + res = limit(e1*(b1 - 1), z, z0) + return exp(res) + if base_lim is S.NegativeInfinity and ex_lim is S.Infinity: + return S.ComplexInfinity + + + def doit(self, **hints): + """Evaluates the limit. + + Parameters + ========== + + deep : bool, optional (default: True) + Invoke the ``doit`` method of the expressions involved before + taking the limit. + + hints : optional keyword arguments + To be passed to ``doit`` methods; only used if deep is True. + """ + + e, z, z0, dir = self.args + + if str(dir) == '+-': + r = limit(e, z, z0, dir='+') + l = limit(e, z, z0, dir='-') + if isinstance(r, Limit) and isinstance(l, Limit): + if r.args[0] == l.args[0]: + return self + if r == l: + return l + if r.is_infinite and l.is_infinite: + return S.ComplexInfinity + raise ValueError("The limit does not exist since " + "left hand limit = %s and right hand limit = %s" + % (l, r)) + + if z0 is S.ComplexInfinity: + raise NotImplementedError("Limits at complex " + "infinity are not implemented") + + if z0.is_infinite: + cdir = sign(z0) + cdir = cdir/abs(cdir) + e = e.subs(z, cdir*z) + dir = "-" + z0 = S.Infinity + + if hints.get('deep', True): + e = e.doit(**hints) + z = z.doit(**hints) + z0 = z0.doit(**hints) + + if e == z: + return z0 + + if not e.has(z): + return e + + if z0 is S.NaN: + return S.NaN + + if e.has(*_illegal): + return self + + if e.is_Order: + return Order(limit(e.expr, z, z0), *e.args[1:]) + + cdir = S.Zero + if str(dir) == "+": + cdir = S.One + elif str(dir) == "-": + cdir = S.NegativeOne + + def set_signs(expr): + if not expr.args: + return expr + newargs = tuple(set_signs(arg) for arg in expr.args) + if newargs != expr.args: + expr = expr.func(*newargs) + abs_flag = isinstance(expr, Abs) + arg_flag = isinstance(expr, arg) + sign_flag = isinstance(expr, sign) + if abs_flag or sign_flag or arg_flag: + try: + sig = limit(expr.args[0], z, z0, dir) + if sig.is_zero: + sig = limit(1/expr.args[0], z, z0, dir) + except NotImplementedError: + return expr + else: + if sig.is_extended_real: + if (sig < 0) == True: + return (-expr.args[0] if abs_flag else + S.NegativeOne if sign_flag else S.Pi) + elif (sig > 0) == True: + return (expr.args[0] if abs_flag else + S.One if sign_flag else S.Zero) + return expr + + if e.has(Float): + # Convert floats like 0.5 to exact SymPy numbers like S.Half, to + # prevent rounding errors which can lead to unexpected execution + # of conditional blocks that work on comparisons + # Also see comments in https://github.com/sympy/sympy/issues/19453 + from sympy.simplify.simplify import nsimplify + e = nsimplify(e) + e = set_signs(e) + + + if e.is_meromorphic(z, z0): + if z0 is S.Infinity: + newe = e.subs(z, 1/z) + # cdir changes sign as oo- should become 0+ + cdir = -cdir + else: + newe = e.subs(z, z + z0) + try: + coeff, ex = newe.leadterm(z, cdir=cdir) + except ValueError: + pass + else: + if ex > 0: + return S.Zero + elif ex == 0: + return coeff + if cdir == 1 or not(int(ex) & 1): + return S.Infinity*sign(coeff) + elif cdir == -1: + return S.NegativeInfinity*sign(coeff) + else: + return S.ComplexInfinity + + if z0 is S.Infinity: + if e.is_Mul: + e = factor_terms(e) + dummy = Dummy('z', positive=z.is_positive, negative=z.is_negative, real=z.is_real) + newe = e.subs(z, 1/dummy) + # cdir changes sign as oo- should become 0+ + cdir = -cdir + newz = dummy + else: + newe = e.subs(z, z + z0) + newz = z + try: + coeff, ex = newe.leadterm(newz, cdir=cdir) + except (ValueError, NotImplementedError, PoleError): + # The NotImplementedError catching is for custom functions + from sympy.simplify.powsimp import powsimp + e = powsimp(e) + if e.is_Pow: + r = self.pow_heuristics(e) + if r is not None: + return r + try: + coeff = newe.as_leading_term(newz, cdir=cdir) + if coeff != newe and (coeff.has(exp) or coeff.has(S.Exp1)): + return gruntz(coeff, newz, 0, "-" if re(cdir).is_negative else "+") + except (ValueError, NotImplementedError, PoleError): + pass + else: + if isinstance(coeff, AccumBounds) and ex == S.Zero: + return coeff + if coeff.has(S.Infinity, S.NegativeInfinity, S.ComplexInfinity, S.NaN): + return self + if not coeff.has(newz): + if ex.is_positive: + return S.Zero + elif ex == 0: + return coeff + elif ex.is_negative: + if cdir == 1: + return S.Infinity*sign(coeff) + elif cdir == -1: + return S.NegativeInfinity*sign(coeff)*S.NegativeOne**(S.One + ex) + else: + return S.ComplexInfinity + else: + raise NotImplementedError("Not sure of sign of %s" % ex) + + # gruntz fails on factorials but works with the gamma function + # If no factorial term is present, e should remain unchanged. + # factorial is defined to be zero for negative inputs (which + # differs from gamma) so only rewrite for non-negative z0. + if z0.is_extended_nonnegative: + e = e.rewrite(factorial, gamma) + + l = None + + try: + r = gruntz(e, z, z0, dir) + if r is S.NaN or l is S.NaN: + raise PoleError() + except (PoleError, ValueError): + if l is not None: + raise + r = heuristics(e, z, z0, dir) + if r is None: + return self + + return r diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/limitseq.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/limitseq.py new file mode 100644 index 0000000000000000000000000000000000000000..ceac4e7b63bfc09d9dfc26c12c7d2acc8b8d44da --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/limitseq.py @@ -0,0 +1,257 @@ +"""Limits of sequences""" + +from sympy.calculus.accumulationbounds import AccumulationBounds +from sympy.core.add import Add +from sympy.core.function import PoleError +from sympy.core.power import Pow +from sympy.core.singleton import S +from sympy.core.symbol import Dummy +from sympy.core.sympify import sympify +from sympy.functions.combinatorial.numbers import fibonacci +from sympy.functions.combinatorial.factorials import factorial, subfactorial +from sympy.functions.special.gamma_functions import gamma +from sympy.functions.elementary.complexes import Abs +from sympy.functions.elementary.miscellaneous import Max, Min +from sympy.functions.elementary.trigonometric import cos, sin +from sympy.series.limits import Limit + + +def difference_delta(expr, n=None, step=1): + """Difference Operator. + + Explanation + =========== + + Discrete analog of differential operator. Given a sequence x[n], + returns the sequence x[n + step] - x[n]. + + Examples + ======== + + >>> from sympy import difference_delta as dd + >>> from sympy.abc import n + >>> dd(n*(n + 1), n) + 2*n + 2 + >>> dd(n*(n + 1), n, 2) + 4*n + 6 + + References + ========== + + .. [1] https://reference.wolfram.com/language/ref/DifferenceDelta.html + """ + expr = sympify(expr) + + if n is None: + f = expr.free_symbols + if len(f) == 1: + n = f.pop() + elif len(f) == 0: + return S.Zero + else: + raise ValueError("Since there is more than one variable in the" + " expression, a variable must be supplied to" + " take the difference of %s" % expr) + step = sympify(step) + if step.is_number is False or step.is_finite is False: + raise ValueError("Step should be a finite number.") + + if hasattr(expr, '_eval_difference_delta'): + result = expr._eval_difference_delta(n, step) + if result: + return result + + return expr.subs(n, n + step) - expr + + +def dominant(expr, n): + """Finds the dominant term in a sum, that is a term that dominates + every other term. + + Explanation + =========== + + If limit(a/b, n, oo) is oo then a dominates b. + If limit(a/b, n, oo) is 0 then b dominates a. + Otherwise, a and b are comparable. + + If there is no unique dominant term, then returns ``None``. + + Examples + ======== + + >>> from sympy import Sum + >>> from sympy.series.limitseq import dominant + >>> from sympy.abc import n, k + >>> dominant(5*n**3 + 4*n**2 + n + 1, n) + 5*n**3 + >>> dominant(2**n + Sum(k, (k, 0, n)), n) + 2**n + + See Also + ======== + + sympy.series.limitseq.dominant + """ + terms = Add.make_args(expr.expand(func=True)) + term0 = terms[-1] + comp = [term0] # comparable terms + for t in terms[:-1]: + r = term0/t + e = r.gammasimp() + if e == r: + e = r.factor() + l = limit_seq(e, n) + if l is None: + return None + elif l.is_zero: + term0 = t + comp = [term0] + elif l not in [S.Infinity, S.NegativeInfinity]: + comp.append(t) + if len(comp) > 1: + return None + return term0 + + +def _limit_inf(expr, n): + try: + return Limit(expr, n, S.Infinity).doit(deep=False) + except (NotImplementedError, PoleError): + return None + + +def _limit_seq(expr, n, trials): + from sympy.concrete.summations import Sum + + for i in range(trials): + if not expr.has(Sum): + result = _limit_inf(expr, n) + if result is not None: + return result + + num, den = expr.as_numer_denom() + if not den.has(n) or not num.has(n): + result = _limit_inf(expr.doit(), n) + if result is not None: + return result + return None + + num, den = (difference_delta(t.expand(), n) for t in [num, den]) + expr = (num / den).gammasimp() + + if not expr.has(Sum): + result = _limit_inf(expr, n) + if result is not None: + return result + + num, den = expr.as_numer_denom() + + num = dominant(num, n) + if num is None: + return None + + den = dominant(den, n) + if den is None: + return None + + expr = (num / den).gammasimp() + + +def limit_seq(expr, n=None, trials=5): + """Finds the limit of a sequence as index ``n`` tends to infinity. + + Parameters + ========== + + expr : Expr + SymPy expression for the ``n-th`` term of the sequence + n : Symbol, optional + The index of the sequence, an integer that tends to positive + infinity. If None, inferred from the expression unless it has + multiple symbols. + trials: int, optional + The algorithm is highly recursive. ``trials`` is a safeguard from + infinite recursion in case the limit is not easily computed by the + algorithm. Try increasing ``trials`` if the algorithm returns ``None``. + + Admissible Terms + ================ + + The algorithm is designed for sequences built from rational functions, + indefinite sums, and indefinite products over an indeterminate n. Terms of + alternating sign are also allowed, but more complex oscillatory behavior is + not supported. + + Examples + ======== + + >>> from sympy import limit_seq, Sum, binomial + >>> from sympy.abc import n, k, m + >>> limit_seq((5*n**3 + 3*n**2 + 4) / (3*n**3 + 4*n - 5), n) + 5/3 + >>> limit_seq(binomial(2*n, n) / Sum(binomial(2*k, k), (k, 1, n)), n) + 3/4 + >>> limit_seq(Sum(k**2 * Sum(2**m/m, (m, 1, k)), (k, 1, n)) / (2**n*n), n) + 4 + + See Also + ======== + + sympy.series.limitseq.dominant + + References + ========== + + .. [1] Computing Limits of Sequences - Manuel Kauers + """ + + from sympy.concrete.summations import Sum + if n is None: + free = expr.free_symbols + if len(free) == 1: + n = free.pop() + elif not free: + return expr + else: + raise ValueError("Expression has more than one variable. " + "Please specify a variable.") + elif n not in expr.free_symbols: + return expr + + expr = expr.rewrite(fibonacci, S.GoldenRatio) + expr = expr.rewrite(factorial, subfactorial, gamma) + n_ = Dummy("n", integer=True, positive=True) + n1 = Dummy("n", odd=True, positive=True) + n2 = Dummy("n", even=True, positive=True) + + # If there is a negative term raised to a power involving n, or a + # trigonometric function, then consider even and odd n separately. + powers = (p.as_base_exp() for p in expr.atoms(Pow)) + if (any(b.is_negative and e.has(n) for b, e in powers) or + expr.has(cos, sin)): + L1 = _limit_seq(expr.xreplace({n: n1}), n1, trials) + if L1 is not None: + L2 = _limit_seq(expr.xreplace({n: n2}), n2, trials) + if L1 != L2: + if L1.is_comparable and L2.is_comparable: + return AccumulationBounds(Min(L1, L2), Max(L1, L2)) + else: + return None + else: + L1 = _limit_seq(expr.xreplace({n: n_}), n_, trials) + if L1 is not None: + return L1 + else: + if expr.is_Add: + limits = [limit_seq(term, n, trials) for term in expr.args] + if any(result is None for result in limits): + return None + else: + return Add(*limits) + # Maybe the absolute value is easier to deal with (though not if + # it has a Sum). If it tends to 0, the limit is 0. + elif not expr.has(Sum): + lim = _limit_seq(Abs(expr.xreplace({n: n_})), n_, trials) + if lim is not None and lim.is_zero: + return S.Zero diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/order.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/order.py new file mode 100644 index 0000000000000000000000000000000000000000..9cfd4309c2b7094ce02feab129e5f051c442d8cd --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/order.py @@ -0,0 +1,522 @@ +from sympy.core import S, sympify, Expr, Dummy, Add, Mul +from sympy.core.cache import cacheit +from sympy.core.containers import Tuple +from sympy.core.function import Function, PoleError, expand_power_base, expand_log +from sympy.core.sorting import default_sort_key +from sympy.functions.elementary.exponential import exp, log +from sympy.sets.sets import Complement +from sympy.utilities.iterables import uniq, is_sequence + + +class Order(Expr): + r""" Represents the limiting behavior of some function. + + Explanation + =========== + + The order of a function characterizes the function based on the limiting + behavior of the function as it goes to some limit. Only taking the limit + point to be a number is currently supported. This is expressed in + big O notation [1]_. + + The formal definition for the order of a function `g(x)` about a point `a` + is such that `g(x) = O(f(x))` as `x \rightarrow a` if and only if there + exists a `\delta > 0` and an `M > 0` such that `|g(x)| \leq M|f(x)|` for + `|x-a| < \delta`. This is equivalent to `\limsup_{x \rightarrow a} + |g(x)/f(x)| < \infty`. + + Let's illustrate it on the following example by taking the expansion of + `\sin(x)` about 0: + + .. math :: + \sin(x) = x - x^3/3! + O(x^5) + + where in this case `O(x^5) = x^5/5! - x^7/7! + \cdots`. By the definition + of `O`, there is a `\delta > 0` and an `M` such that: + + .. math :: + |x^5/5! - x^7/7! + ....| <= M|x^5| \text{ for } |x| < \delta + + or by the alternate definition: + + .. math :: + \lim_{x \rightarrow 0} | (x^5/5! - x^7/7! + ....) / x^5| < \infty + + which surely is true, because + + .. math :: + \lim_{x \rightarrow 0} | (x^5/5! - x^7/7! + ....) / x^5| = 1/5! + + + As it is usually used, the order of a function can be intuitively thought + of representing all terms of powers greater than the one specified. For + example, `O(x^3)` corresponds to any terms proportional to `x^3, + x^4,\ldots` and any higher power. For a polynomial, this leaves terms + proportional to `x^2`, `x` and constants. + + Examples + ======== + + >>> from sympy import O, oo, cos, pi + >>> from sympy.abc import x, y + + >>> O(x + x**2) + O(x) + >>> O(x + x**2, (x, 0)) + O(x) + >>> O(x + x**2, (x, oo)) + O(x**2, (x, oo)) + + >>> O(1 + x*y) + O(1, x, y) + >>> O(1 + x*y, (x, 0), (y, 0)) + O(1, x, y) + >>> O(1 + x*y, (x, oo), (y, oo)) + O(x*y, (x, oo), (y, oo)) + + >>> O(1) in O(1, x) + True + >>> O(1, x) in O(1) + False + >>> O(x) in O(1, x) + True + >>> O(x**2) in O(x) + True + + >>> O(x)*x + O(x**2) + >>> O(x) - O(x) + O(x) + >>> O(cos(x)) + O(1) + >>> O(cos(x), (x, pi/2)) + O(x - pi/2, (x, pi/2)) + + References + ========== + + .. [1] `Big O notation `_ + + Notes + ===== + + In ``O(f(x), x)`` the expression ``f(x)`` is assumed to have a leading + term. ``O(f(x), x)`` is automatically transformed to + ``O(f(x).as_leading_term(x),x)``. + + ``O(expr*f(x), x)`` is ``O(f(x), x)`` + + ``O(expr, x)`` is ``O(1)`` + + ``O(0, x)`` is 0. + + Multivariate O is also supported: + + ``O(f(x, y), x, y)`` is transformed to + ``O(f(x, y).as_leading_term(x,y).as_leading_term(y), x, y)`` + + In the multivariate case, it is assumed the limits w.r.t. the various + symbols commute. + + If no symbols are passed then all symbols in the expression are used + and the limit point is assumed to be zero. + + """ + + is_Order = True + + __slots__ = () + + @cacheit + def __new__(cls, expr, *args, **kwargs): + expr = sympify(expr) + + if not args: + if expr.is_Order: + variables = expr.variables + point = expr.point + else: + variables = list(expr.free_symbols) + point = [S.Zero]*len(variables) + else: + args = list(args if is_sequence(args) else [args]) + variables, point = [], [] + if is_sequence(args[0]): + for a in args: + v, p = list(map(sympify, a)) + variables.append(v) + point.append(p) + else: + variables = list(map(sympify, args)) + point = [S.Zero]*len(variables) + + if not all(v.is_symbol for v in variables): + raise TypeError('Variables are not symbols, got %s' % variables) + + if len(list(uniq(variables))) != len(variables): + raise ValueError('Variables are supposed to be unique symbols, got %s' % variables) + + if expr.is_Order: + expr_vp = dict(expr.args[1:]) + new_vp = dict(expr_vp) + vp = dict(zip(variables, point)) + for v, p in vp.items(): + if v in new_vp.keys(): + if p != new_vp[v]: + raise NotImplementedError( + "Mixing Order at different points is not supported.") + else: + new_vp[v] = p + if set(expr_vp.keys()) == set(new_vp.keys()): + return expr + else: + variables = list(new_vp.keys()) + point = [new_vp[v] for v in variables] + + if expr is S.NaN: + return S.NaN + + if any(x in p.free_symbols for x in variables for p in point): + raise ValueError('Got %s as a point.' % point) + + if variables: + if any(p != point[0] for p in point): + raise NotImplementedError( + "Multivariable orders at different points are not supported.") + if point[0] in (S.Infinity, S.Infinity*S.ImaginaryUnit): + s = {k: 1/Dummy() for k in variables} + rs = {1/v: 1/k for k, v in s.items()} + ps = [S.Zero for p in point] + elif point[0] in (S.NegativeInfinity, S.NegativeInfinity*S.ImaginaryUnit): + s = {k: -1/Dummy() for k in variables} + rs = {-1/v: -1/k for k, v in s.items()} + ps = [S.Zero for p in point] + elif point[0] is not S.Zero: + s = {k: Dummy() + point[0] for k in variables} + rs = {(v - point[0]).together(): k - point[0] for k, v in s.items()} + ps = [S.Zero for p in point] + else: + s = () + rs = () + ps = list(point) + + expr = expr.subs(s) + + if expr.is_Add: + expr = expr.factor() + + if s: + args = tuple([r[0] for r in rs.items()]) + else: + args = tuple(variables) + + if len(variables) > 1: + # XXX: better way? We need this expand() to + # workaround e.g: expr = x*(x + y). + # (x*(x + y)).as_leading_term(x, y) currently returns + # x*y (wrong order term!). That's why we want to deal with + # expand()'ed expr (handled in "if expr.is_Add" branch below). + expr = expr.expand() + + old_expr = None + while old_expr != expr: + old_expr = expr + if expr.is_Add: + lst = expr.extract_leading_order(args) + expr = Add(*[f.expr for (e, f) in lst]) + + elif expr: + try: + expr = expr.as_leading_term(*args) + except PoleError: + if isinstance(expr, Function) or\ + all(isinstance(arg, Function) for arg in expr.args): + # It is not possible to simplify an expression + # containing only functions (which raise error on + # call to leading term) further + pass + else: + orders = [] + pts = tuple(zip(args, ps)) + for arg in expr.args: + try: + lt = arg.as_leading_term(*args) + except PoleError: + lt = arg + if lt not in args: + order = Order(lt) + else: + order = Order(lt, *pts) + orders.append(order) + if expr.is_Add: + new_expr = Order(Add(*orders), *pts) + if new_expr.is_Add: + new_expr = Order(Add(*[a.expr for a in new_expr.args]), *pts) + expr = new_expr.expr + elif expr.is_Mul: + expr = Mul(*[a.expr for a in orders]) + elif expr.is_Pow: + e = expr.exp + b = expr.base + expr = exp(e * log(b)) + + # It would probably be better to handle this somewhere + # else. This is needed for a testcase in which there is a + # symbol with the assumptions zero=True. + if expr.is_zero: + expr = S.Zero + else: + expr = expr.as_independent(*args, as_Add=False)[1] + + expr = expand_power_base(expr) + expr = expand_log(expr) + + if len(args) == 1: + # The definition of O(f(x)) symbol explicitly stated that + # the argument of f(x) is irrelevant. That's why we can + # combine some power exponents (only "on top" of the + # expression tree for f(x)), e.g.: + # x**p * (-x)**q -> x**(p+q) for real p, q. + x = args[0] + margs = list(Mul.make_args( + expr.as_independent(x, as_Add=False)[1])) + + for i, t in enumerate(margs): + if t.is_Pow: + b, q = t.args + if b in (x, -x) and q.is_real and not q.has(x): + margs[i] = x**q + elif b.is_Pow and not b.exp.has(x): + b, r = b.args + if b in (x, -x) and r.is_real: + margs[i] = x**(r*q) + elif b.is_Mul and b.args[0] is S.NegativeOne: + b = -b + if b.is_Pow and not b.exp.has(x): + b, r = b.args + if b in (x, -x) and r.is_real: + margs[i] = x**(r*q) + + expr = Mul(*margs) + + expr = expr.subs(rs) + + if expr.is_Order: + expr = expr.expr + + if not expr.has(*variables) and not expr.is_zero: + expr = S.One + + # create Order instance: + vp = dict(zip(variables, point)) + variables.sort(key=default_sort_key) + point = [vp[v] for v in variables] + args = (expr,) + Tuple(*zip(variables, point)) + obj = Expr.__new__(cls, *args) + return obj + + def _eval_nseries(self, x, n, logx, cdir=0): + return self + + @property + def expr(self): + return self.args[0] + + @property + def variables(self): + if self.args[1:]: + return tuple(x[0] for x in self.args[1:]) + else: + return () + + @property + def point(self): + if self.args[1:]: + return tuple(x[1] for x in self.args[1:]) + else: + return () + + @property + def free_symbols(self): + return self.expr.free_symbols | set(self.variables) + + def _eval_power(b, e): + if e.is_Number and e.is_nonnegative: + return b.func(b.expr ** e, *b.args[1:]) + if e == O(1): + return b + return + + def as_expr_variables(self, order_symbols): + if order_symbols is None: + order_symbols = self.args[1:] + else: + if (not all(o[1] == order_symbols[0][1] for o in order_symbols) and + not all(p == self.point[0] for p in self.point)): # pragma: no cover + raise NotImplementedError('Order at points other than 0 ' + 'or oo not supported, got %s as a point.' % self.point) + if order_symbols and order_symbols[0][1] != self.point[0]: + raise NotImplementedError( + "Multiplying Order at different points is not supported.") + order_symbols = dict(order_symbols) + for s, p in dict(self.args[1:]).items(): + if s not in order_symbols.keys(): + order_symbols[s] = p + order_symbols = sorted(order_symbols.items(), key=lambda x: default_sort_key(x[0])) + return self.expr, tuple(order_symbols) + + def removeO(self): + return S.Zero + + def getO(self): + return self + + @cacheit + def contains(self, expr): + r""" + Return True if expr belongs to Order(self.expr, \*self.variables). + Return False if self belongs to expr. + Return None if the inclusion relation cannot be determined + (e.g. when self and expr have different symbols). + """ + expr = sympify(expr) + if expr.is_zero: + return True + if expr is S.NaN: + return False + point = self.point[0] if self.point else S.Zero + if expr.is_Order: + if (any(p != point for p in expr.point) or + any(p != point for p in self.point)): + return None + if expr.expr == self.expr: + # O(1) + O(1), O(1) + O(1, x), etc. + return all(x in self.args[1:] for x in expr.args[1:]) + if expr.expr.is_Add: + return all(self.contains(x) for x in expr.expr.args) + if self.expr.is_Add and point.is_zero: + return any(self.func(x, *self.args[1:]).contains(expr) + for x in self.expr.args) + if self.variables and expr.variables: + common_symbols = tuple( + [s for s in self.variables if s in expr.variables]) + elif self.variables: + common_symbols = self.variables + else: + common_symbols = expr.variables + if not common_symbols: + return None + if (self.expr.is_Pow and len(self.variables) == 1 + and self.variables == expr.variables): + symbol = self.variables[0] + other = expr.expr.as_independent(symbol, as_Add=False)[1] + if (other.is_Pow and other.base == symbol and + self.expr.base == symbol): + if point.is_zero: + rv = (self.expr.exp - other.exp).is_nonpositive + if point.is_infinite: + rv = (self.expr.exp - other.exp).is_nonnegative + if rv is not None: + return rv + + from sympy.simplify.powsimp import powsimp + r = None + ratio = self.expr/expr.expr + ratio = powsimp(ratio, deep=True, combine='exp') + for s in common_symbols: + from sympy.series.limits import Limit + l = Limit(ratio, s, point).doit(heuristics=False) + if not isinstance(l, Limit): + l = l != 0 + else: + l = None + if r is None: + r = l + else: + if r != l: + return + return r + + if self.expr.is_Pow and len(self.variables) == 1: + symbol = self.variables[0] + other = expr.as_independent(symbol, as_Add=False)[1] + if (other.is_Pow and other.base == symbol and + self.expr.base == symbol): + if point.is_zero: + rv = (self.expr.exp - other.exp).is_nonpositive + if point.is_infinite: + rv = (self.expr.exp - other.exp).is_nonnegative + if rv is not None: + return rv + + obj = self.func(expr, *self.args[1:]) + return self.contains(obj) + + def __contains__(self, other): + result = self.contains(other) + if result is None: + raise TypeError('contains did not evaluate to a bool') + return result + + def _eval_subs(self, old, new): + if old in self.variables: + newexpr = self.expr.subs(old, new) + i = self.variables.index(old) + newvars = list(self.variables) + newpt = list(self.point) + if new.is_symbol: + newvars[i] = new + else: + syms = new.free_symbols + if len(syms) == 1 or old in syms: + if old in syms: + var = self.variables[i] + else: + var = syms.pop() + # First, try to substitute self.point in the "new" + # expr to see if this is a fixed point. + # E.g. O(y).subs(y, sin(x)) + from sympy import limit + if new.has(Order) and limit(new.getO().expr, var, new.getO().point[0]) == self.point[i]: + point = new.getO().point[0] + return Order(newexpr, *zip([var], [point])) + else: + point = new.subs(var, self.point[i]) + if point != self.point[i]: + from sympy.solvers.solveset import solveset + d = Dummy() + sol = solveset(old - new.subs(var, d), d) + if isinstance(sol, Complement): + e1 = sol.args[0] + e2 = sol.args[1] + sol = set(e1) - set(e2) + res = [dict(zip((d, ), sol))] + point = d.subs(res[0]).limit(old, self.point[i]) + newvars[i] = var + newpt[i] = point + elif old not in syms: + del newvars[i], newpt[i] + if not syms and new == self.point[i]: + newvars.extend(syms) + newpt.extend([S.Zero]*len(syms)) + else: + return + return Order(newexpr, *zip(newvars, newpt)) + + def _eval_conjugate(self): + expr = self.expr._eval_conjugate() + if expr is not None: + return self.func(expr, *self.args[1:]) + + def _eval_derivative(self, x): + return self.func(self.expr.diff(x), *self.args[1:]) or self + + def _eval_transpose(self): + expr = self.expr._eval_transpose() + if expr is not None: + return self.func(expr, *self.args[1:]) + + def __neg__(self): + return self + +O = Order diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/residues.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/residues.py new file mode 100644 index 0000000000000000000000000000000000000000..a426f9e799bd040eea5124f718c2fa43e5de026b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/residues.py @@ -0,0 +1,73 @@ +""" +This module implements the Residue function and related tools for working +with residues. +""" + +from sympy.core.mul import Mul +from sympy.core.singleton import S +from sympy.core.sympify import sympify +from sympy.utilities.timeutils import timethis + + +@timethis('residue') +def residue(expr, x, x0): + """ + Finds the residue of ``expr`` at the point x=x0. + + The residue is defined as the coefficient of ``1/(x-x0)`` in the power series + expansion about ``x=x0``. + + Examples + ======== + + >>> from sympy import Symbol, residue, sin + >>> x = Symbol("x") + >>> residue(1/x, x, 0) + 1 + >>> residue(1/x**2, x, 0) + 0 + >>> residue(2/sin(x), x, 0) + 2 + + This function is essential for the Residue Theorem [1]. + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Residue_theorem + """ + # The current implementation uses series expansion to + # calculate it. A more general implementation is explained in + # the section 5.6 of the Bronstein's book {M. Bronstein: + # Symbolic Integration I, Springer Verlag (2005)}. For purely + # rational functions, the algorithm is much easier. See + # sections 2.4, 2.5, and 2.7 (this section actually gives an + # algorithm for computing any Laurent series coefficient for + # a rational function). The theory in section 2.4 will help to + # understand why the resultant works in the general algorithm. + # For the definition of a resultant, see section 1.4 (and any + # previous sections for more review). + + from sympy.series.order import Order + from sympy.simplify.radsimp import collect + expr = sympify(expr) + if x0 != 0: + expr = expr.subs(x, x + x0) + for n in (0, 1, 2, 4, 8, 16, 32): + s = expr.nseries(x, n=n) + if not s.has(Order) or s.getn() >= 0: + break + s = collect(s.removeO(), x) + if s.is_Add: + args = s.args + else: + args = [s] + res = S.Zero + for arg in args: + c, m = arg.as_coeff_mul(x) + m = Mul(*m) + if not (m in (S.One, x) or (m.is_Pow and m.exp.is_Integer)): + raise NotImplementedError('term of unexpected form: %s' % m) + if m == 1/x: + res += c + return res diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/sequences.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/sequences.py new file mode 100644 index 0000000000000000000000000000000000000000..7787515ddb05afaf34751bf451544935723d0921 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/sequences.py @@ -0,0 +1,1239 @@ +from sympy.core.basic import Basic +from sympy.core.cache import cacheit +from sympy.core.containers import Tuple +from sympy.core.decorators import call_highest_priority +from sympy.core.parameters import global_parameters +from sympy.core.function import AppliedUndef, expand +from sympy.core.mul import Mul +from sympy.core.numbers import Integer +from sympy.core.relational import Eq +from sympy.core.singleton import S, Singleton +from sympy.core.sorting import ordered +from sympy.core.symbol import Dummy, Symbol, Wild +from sympy.core.sympify import sympify +from sympy.matrices import Matrix +from sympy.polys import lcm, factor +from sympy.sets.sets import Interval, Intersection +from sympy.tensor.indexed import Idx +from sympy.utilities.iterables import flatten, is_sequence, iterable + + +############################################################################### +# SEQUENCES # +############################################################################### + + +class SeqBase(Basic): + """Base class for sequences""" + + is_commutative = True + _op_priority = 15 + + @staticmethod + def _start_key(expr): + """Return start (if possible) else S.Infinity. + + adapted from Set._infimum_key + """ + try: + start = expr.start + except NotImplementedError: + start = S.Infinity + return start + + def _intersect_interval(self, other): + """Returns start and stop. + + Takes intersection over the two intervals. + """ + interval = Intersection(self.interval, other.interval) + return interval.inf, interval.sup + + @property + def gen(self): + """Returns the generator for the sequence""" + raise NotImplementedError("(%s).gen" % self) + + @property + def interval(self): + """The interval on which the sequence is defined""" + raise NotImplementedError("(%s).interval" % self) + + @property + def start(self): + """The starting point of the sequence. This point is included""" + raise NotImplementedError("(%s).start" % self) + + @property + def stop(self): + """The ending point of the sequence. This point is included""" + raise NotImplementedError("(%s).stop" % self) + + @property + def length(self): + """Length of the sequence""" + raise NotImplementedError("(%s).length" % self) + + @property + def variables(self): + """Returns a tuple of variables that are bounded""" + return () + + @property + def free_symbols(self): + """ + This method returns the symbols in the object, excluding those + that take on a specific value (i.e. the dummy symbols). + + Examples + ======== + + >>> from sympy import SeqFormula + >>> from sympy.abc import n, m + >>> SeqFormula(m*n**2, (n, 0, 5)).free_symbols + {m} + """ + return ({j for i in self.args for j in i.free_symbols + .difference(self.variables)}) + + @cacheit + def coeff(self, pt): + """Returns the coefficient at point pt""" + if pt < self.start or pt > self.stop: + raise IndexError("Index %s out of bounds %s" % (pt, self.interval)) + return self._eval_coeff(pt) + + def _eval_coeff(self, pt): + raise NotImplementedError("The _eval_coeff method should be added to" + "%s to return coefficient so it is available" + "when coeff calls it." + % self.func) + + def _ith_point(self, i): + """Returns the i'th point of a sequence. + + Explanation + =========== + + If start point is negative infinity, point is returned from the end. + Assumes the first point to be indexed zero. + + Examples + ========= + + >>> from sympy import oo + >>> from sympy.series.sequences import SeqPer + + bounded + + >>> SeqPer((1, 2, 3), (-10, 10))._ith_point(0) + -10 + >>> SeqPer((1, 2, 3), (-10, 10))._ith_point(5) + -5 + + End is at infinity + + >>> SeqPer((1, 2, 3), (0, oo))._ith_point(5) + 5 + + Starts at negative infinity + + >>> SeqPer((1, 2, 3), (-oo, 0))._ith_point(5) + -5 + """ + if self.start is S.NegativeInfinity: + initial = self.stop + else: + initial = self.start + + if self.start is S.NegativeInfinity: + step = -1 + else: + step = 1 + + return initial + i*step + + def _add(self, other): + """ + Should only be used internally. + + Explanation + =========== + + self._add(other) returns a new, term-wise added sequence if self + knows how to add with other, otherwise it returns ``None``. + + ``other`` should only be a sequence object. + + Used within :class:`SeqAdd` class. + """ + return None + + def _mul(self, other): + """ + Should only be used internally. + + Explanation + =========== + + self._mul(other) returns a new, term-wise multiplied sequence if self + knows how to multiply with other, otherwise it returns ``None``. + + ``other`` should only be a sequence object. + + Used within :class:`SeqMul` class. + """ + return None + + def coeff_mul(self, other): + """ + Should be used when ``other`` is not a sequence. Should be + defined to define custom behaviour. + + Examples + ======== + + >>> from sympy import SeqFormula + >>> from sympy.abc import n + >>> SeqFormula(n**2).coeff_mul(2) + SeqFormula(2*n**2, (n, 0, oo)) + + Notes + ===== + + '*' defines multiplication of sequences with sequences only. + """ + return Mul(self, other) + + def __add__(self, other): + """Returns the term-wise addition of 'self' and 'other'. + + ``other`` should be a sequence. + + Examples + ======== + + >>> from sympy import SeqFormula + >>> from sympy.abc import n + >>> SeqFormula(n**2) + SeqFormula(n**3) + SeqFormula(n**3 + n**2, (n, 0, oo)) + """ + if not isinstance(other, SeqBase): + raise TypeError('cannot add sequence and %s' % type(other)) + return SeqAdd(self, other) + + @call_highest_priority('__add__') + def __radd__(self, other): + return self + other + + def __sub__(self, other): + """Returns the term-wise subtraction of ``self`` and ``other``. + + ``other`` should be a sequence. + + Examples + ======== + + >>> from sympy import SeqFormula + >>> from sympy.abc import n + >>> SeqFormula(n**2) - (SeqFormula(n)) + SeqFormula(n**2 - n, (n, 0, oo)) + """ + if not isinstance(other, SeqBase): + raise TypeError('cannot subtract sequence and %s' % type(other)) + return SeqAdd(self, -other) + + @call_highest_priority('__sub__') + def __rsub__(self, other): + return (-self) + other + + def __neg__(self): + """Negates the sequence. + + Examples + ======== + + >>> from sympy import SeqFormula + >>> from sympy.abc import n + >>> -SeqFormula(n**2) + SeqFormula(-n**2, (n, 0, oo)) + """ + return self.coeff_mul(-1) + + def __mul__(self, other): + """Returns the term-wise multiplication of 'self' and 'other'. + + ``other`` should be a sequence. For ``other`` not being a + sequence see :func:`coeff_mul` method. + + Examples + ======== + + >>> from sympy import SeqFormula + >>> from sympy.abc import n + >>> SeqFormula(n**2) * (SeqFormula(n)) + SeqFormula(n**3, (n, 0, oo)) + """ + if not isinstance(other, SeqBase): + raise TypeError('cannot multiply sequence and %s' % type(other)) + return SeqMul(self, other) + + @call_highest_priority('__mul__') + def __rmul__(self, other): + return self * other + + def __iter__(self): + for i in range(self.length): + pt = self._ith_point(i) + yield self.coeff(pt) + + def __getitem__(self, index): + if isinstance(index, int): + index = self._ith_point(index) + return self.coeff(index) + elif isinstance(index, slice): + start, stop = index.start, index.stop + if start is None: + start = 0 + if stop is None: + stop = self.length + return [self.coeff(self._ith_point(i)) for i in + range(start, stop, index.step or 1)] + + def find_linear_recurrence(self,n,d=None,gfvar=None): + r""" + Finds the shortest linear recurrence that satisfies the first n + terms of sequence of order `\leq` ``n/2`` if possible. + If ``d`` is specified, find shortest linear recurrence of order + `\leq` min(d, n/2) if possible. + Returns list of coefficients ``[b(1), b(2), ...]`` corresponding to the + recurrence relation ``x(n) = b(1)*x(n-1) + b(2)*x(n-2) + ...`` + Returns ``[]`` if no recurrence is found. + If gfvar is specified, also returns ordinary generating function as a + function of gfvar. + + Examples + ======== + + >>> from sympy import sequence, sqrt, oo, lucas + >>> from sympy.abc import n, x, y + >>> sequence(n**2).find_linear_recurrence(10, 2) + [] + >>> sequence(n**2).find_linear_recurrence(10) + [3, -3, 1] + >>> sequence(2**n).find_linear_recurrence(10) + [2] + >>> sequence(23*n**4+91*n**2).find_linear_recurrence(10) + [5, -10, 10, -5, 1] + >>> sequence(sqrt(5)*(((1 + sqrt(5))/2)**n - (-(1 + sqrt(5))/2)**(-n))/5).find_linear_recurrence(10) + [1, 1] + >>> sequence(x+y*(-2)**(-n), (n, 0, oo)).find_linear_recurrence(30) + [1/2, 1/2] + >>> sequence(3*5**n + 12).find_linear_recurrence(20,gfvar=x) + ([6, -5], 3*(5 - 21*x)/((x - 1)*(5*x - 1))) + >>> sequence(lucas(n)).find_linear_recurrence(15,gfvar=x) + ([1, 1], (x - 2)/(x**2 + x - 1)) + """ + from sympy.simplify import simplify + x = [simplify(expand(t)) for t in self[:n]] + lx = len(x) + if d is None: + r = lx//2 + else: + r = min(d,lx//2) + coeffs = [] + for l in range(1, r+1): + l2 = 2*l + mlist = [] + for k in range(l): + mlist.append(x[k:k+l]) + m = Matrix(mlist) + if m.det() != 0: + y = simplify(m.LUsolve(Matrix(x[l:l2]))) + if lx == l2: + coeffs = flatten(y[::-1]) + break + mlist = [] + for k in range(l,lx-l): + mlist.append(x[k:k+l]) + m = Matrix(mlist) + if m*y == Matrix(x[l2:]): + coeffs = flatten(y[::-1]) + break + if gfvar is None: + return coeffs + else: + l = len(coeffs) + if l == 0: + return [], None + else: + n, d = x[l-1]*gfvar**(l-1), 1 - coeffs[l-1]*gfvar**l + for i in range(l-1): + n += x[i]*gfvar**i + for j in range(l-i-1): + n -= coeffs[i]*x[j]*gfvar**(i+j+1) + d -= coeffs[i]*gfvar**(i+1) + return coeffs, simplify(factor(n)/factor(d)) + +class EmptySequence(SeqBase, metaclass=Singleton): + """Represents an empty sequence. + + The empty sequence is also available as a singleton as + ``S.EmptySequence``. + + Examples + ======== + + >>> from sympy import EmptySequence, SeqPer + >>> from sympy.abc import x + >>> EmptySequence + EmptySequence + >>> SeqPer((1, 2), (x, 0, 10)) + EmptySequence + SeqPer((1, 2), (x, 0, 10)) + >>> SeqPer((1, 2)) * EmptySequence + EmptySequence + >>> EmptySequence.coeff_mul(-1) + EmptySequence + """ + + @property + def interval(self): + return S.EmptySet + + @property + def length(self): + return S.Zero + + def coeff_mul(self, coeff): + """See docstring of SeqBase.coeff_mul""" + return self + + def __iter__(self): + return iter([]) + + +class SeqExpr(SeqBase): + """Sequence expression class. + + Various sequences should inherit from this class. + + Examples + ======== + + >>> from sympy.series.sequences import SeqExpr + >>> from sympy.abc import x + >>> from sympy import Tuple + >>> s = SeqExpr(Tuple(1, 2, 3), Tuple(x, 0, 10)) + >>> s.gen + (1, 2, 3) + >>> s.interval + Interval(0, 10) + >>> s.length + 11 + + See Also + ======== + + sympy.series.sequences.SeqPer + sympy.series.sequences.SeqFormula + """ + + @property + def gen(self): + return self.args[0] + + @property + def interval(self): + return Interval(self.args[1][1], self.args[1][2]) + + @property + def start(self): + return self.interval.inf + + @property + def stop(self): + return self.interval.sup + + @property + def length(self): + return self.stop - self.start + 1 + + @property + def variables(self): + return (self.args[1][0],) + + +class SeqPer(SeqExpr): + """ + Represents a periodic sequence. + + The elements are repeated after a given period. + + Examples + ======== + + >>> from sympy import SeqPer, oo + >>> from sympy.abc import k + + >>> s = SeqPer((1, 2, 3), (0, 5)) + >>> s.periodical + (1, 2, 3) + >>> s.period + 3 + + For value at a particular point + + >>> s.coeff(3) + 1 + + supports slicing + + >>> s[:] + [1, 2, 3, 1, 2, 3] + + iterable + + >>> list(s) + [1, 2, 3, 1, 2, 3] + + sequence starts from negative infinity + + >>> SeqPer((1, 2, 3), (-oo, 0))[0:6] + [1, 2, 3, 1, 2, 3] + + Periodic formulas + + >>> SeqPer((k, k**2, k**3), (k, 0, oo))[0:6] + [0, 1, 8, 3, 16, 125] + + See Also + ======== + + sympy.series.sequences.SeqFormula + """ + + def __new__(cls, periodical, limits=None): + periodical = sympify(periodical) + + def _find_x(periodical): + free = periodical.free_symbols + if len(periodical.free_symbols) == 1: + return free.pop() + else: + return Dummy('k') + + x, start, stop = None, None, None + if limits is None: + x, start, stop = _find_x(periodical), 0, S.Infinity + if is_sequence(limits, Tuple): + if len(limits) == 3: + x, start, stop = limits + elif len(limits) == 2: + x = _find_x(periodical) + start, stop = limits + + if not isinstance(x, (Symbol, Idx)) or start is None or stop is None: + raise ValueError('Invalid limits given: %s' % str(limits)) + + if start is S.NegativeInfinity and stop is S.Infinity: + raise ValueError("Both the start and end value" + "cannot be unbounded") + + limits = sympify((x, start, stop)) + + if is_sequence(periodical, Tuple): + periodical = sympify(tuple(flatten(periodical))) + else: + raise ValueError("invalid period %s should be something " + "like e.g (1, 2) " % periodical) + + if Interval(limits[1], limits[2]) is S.EmptySet: + return S.EmptySequence + + return Basic.__new__(cls, periodical, limits) + + @property + def period(self): + return len(self.gen) + + @property + def periodical(self): + return self.gen + + def _eval_coeff(self, pt): + if self.start is S.NegativeInfinity: + idx = (self.stop - pt) % self.period + else: + idx = (pt - self.start) % self.period + return self.periodical[idx].subs(self.variables[0], pt) + + def _add(self, other): + """See docstring of SeqBase._add""" + if isinstance(other, SeqPer): + per1, lper1 = self.periodical, self.period + per2, lper2 = other.periodical, other.period + + per_length = lcm(lper1, lper2) + + new_per = [] + for x in range(per_length): + ele1 = per1[x % lper1] + ele2 = per2[x % lper2] + new_per.append(ele1 + ele2) + + start, stop = self._intersect_interval(other) + return SeqPer(new_per, (self.variables[0], start, stop)) + + def _mul(self, other): + """See docstring of SeqBase._mul""" + if isinstance(other, SeqPer): + per1, lper1 = self.periodical, self.period + per2, lper2 = other.periodical, other.period + + per_length = lcm(lper1, lper2) + + new_per = [] + for x in range(per_length): + ele1 = per1[x % lper1] + ele2 = per2[x % lper2] + new_per.append(ele1 * ele2) + + start, stop = self._intersect_interval(other) + return SeqPer(new_per, (self.variables[0], start, stop)) + + def coeff_mul(self, coeff): + """See docstring of SeqBase.coeff_mul""" + coeff = sympify(coeff) + per = [x * coeff for x in self.periodical] + return SeqPer(per, self.args[1]) + + +class SeqFormula(SeqExpr): + """ + Represents sequence based on a formula. + + Elements are generated using a formula. + + Examples + ======== + + >>> from sympy import SeqFormula, oo, Symbol + >>> n = Symbol('n') + >>> s = SeqFormula(n**2, (n, 0, 5)) + >>> s.formula + n**2 + + For value at a particular point + + >>> s.coeff(3) + 9 + + supports slicing + + >>> s[:] + [0, 1, 4, 9, 16, 25] + + iterable + + >>> list(s) + [0, 1, 4, 9, 16, 25] + + sequence starts from negative infinity + + >>> SeqFormula(n**2, (-oo, 0))[0:6] + [0, 1, 4, 9, 16, 25] + + See Also + ======== + + sympy.series.sequences.SeqPer + """ + + def __new__(cls, formula, limits=None): + formula = sympify(formula) + + def _find_x(formula): + free = formula.free_symbols + if len(free) == 1: + return free.pop() + elif not free: + return Dummy('k') + else: + raise ValueError( + " specify dummy variables for %s. If the formula contains" + " more than one free symbol, a dummy variable should be" + " supplied explicitly e.g., SeqFormula(m*n**2, (n, 0, 5))" + % formula) + + x, start, stop = None, None, None + if limits is None: + x, start, stop = _find_x(formula), 0, S.Infinity + if is_sequence(limits, Tuple): + if len(limits) == 3: + x, start, stop = limits + elif len(limits) == 2: + x = _find_x(formula) + start, stop = limits + + if not isinstance(x, (Symbol, Idx)) or start is None or stop is None: + raise ValueError('Invalid limits given: %s' % str(limits)) + + if start is S.NegativeInfinity and stop is S.Infinity: + raise ValueError("Both the start and end value " + "cannot be unbounded") + limits = sympify((x, start, stop)) + + if Interval(limits[1], limits[2]) is S.EmptySet: + return S.EmptySequence + + return Basic.__new__(cls, formula, limits) + + @property + def formula(self): + return self.gen + + def _eval_coeff(self, pt): + d = self.variables[0] + return self.formula.subs(d, pt) + + def _add(self, other): + """See docstring of SeqBase._add""" + if isinstance(other, SeqFormula): + form1, v1 = self.formula, self.variables[0] + form2, v2 = other.formula, other.variables[0] + formula = form1 + form2.subs(v2, v1) + start, stop = self._intersect_interval(other) + return SeqFormula(formula, (v1, start, stop)) + + def _mul(self, other): + """See docstring of SeqBase._mul""" + if isinstance(other, SeqFormula): + form1, v1 = self.formula, self.variables[0] + form2, v2 = other.formula, other.variables[0] + formula = form1 * form2.subs(v2, v1) + start, stop = self._intersect_interval(other) + return SeqFormula(formula, (v1, start, stop)) + + def coeff_mul(self, coeff): + """See docstring of SeqBase.coeff_mul""" + coeff = sympify(coeff) + formula = self.formula * coeff + return SeqFormula(formula, self.args[1]) + + def expand(self, *args, **kwargs): + return SeqFormula(expand(self.formula, *args, **kwargs), self.args[1]) + +class RecursiveSeq(SeqBase): + """ + A finite degree recursive sequence. + + Explanation + =========== + + That is, a sequence a(n) that depends on a fixed, finite number of its + previous values. The general form is + + a(n) = f(a(n - 1), a(n - 2), ..., a(n - d)) + + for some fixed, positive integer d, where f is some function defined by a + SymPy expression. + + Parameters + ========== + + recurrence : SymPy expression defining recurrence + This is *not* an equality, only the expression that the nth term is + equal to. For example, if :code:`a(n) = f(a(n - 1), ..., a(n - d))`, + then the expression should be :code:`f(a(n - 1), ..., a(n - d))`. + + yn : applied undefined function + Represents the nth term of the sequence as e.g. :code:`y(n)` where + :code:`y` is an undefined function and `n` is the sequence index. + + n : symbolic argument + The name of the variable that the recurrence is in, e.g., :code:`n` if + the recurrence function is :code:`y(n)`. + + initial : iterable with length equal to the degree of the recurrence + The initial values of the recurrence. + + start : start value of sequence (inclusive) + + Examples + ======== + + >>> from sympy import Function, symbols + >>> from sympy.series.sequences import RecursiveSeq + >>> y = Function("y") + >>> n = symbols("n") + >>> fib = RecursiveSeq(y(n - 1) + y(n - 2), y(n), n, [0, 1]) + + >>> fib.coeff(3) # Value at a particular point + 2 + + >>> fib[:6] # supports slicing + [0, 1, 1, 2, 3, 5] + + >>> fib.recurrence # inspect recurrence + Eq(y(n), y(n - 2) + y(n - 1)) + + >>> fib.degree # automatically determine degree + 2 + + >>> for x in zip(range(10), fib): # supports iteration + ... print(x) + (0, 0) + (1, 1) + (2, 1) + (3, 2) + (4, 3) + (5, 5) + (6, 8) + (7, 13) + (8, 21) + (9, 34) + + See Also + ======== + + sympy.series.sequences.SeqFormula + + """ + + def __new__(cls, recurrence, yn, n, initial=None, start=0): + if not isinstance(yn, AppliedUndef): + raise TypeError("recurrence sequence must be an applied undefined function" + ", found `{}`".format(yn)) + + if not isinstance(n, Basic) or not n.is_symbol: + raise TypeError("recurrence variable must be a symbol" + ", found `{}`".format(n)) + + if yn.args != (n,): + raise TypeError("recurrence sequence does not match symbol") + + y = yn.func + + k = Wild("k", exclude=(n,)) + degree = 0 + + # Find all applications of y in the recurrence and check that: + # 1. The function y is only being used with a single argument; and + # 2. All arguments are n + k for constant negative integers k. + + prev_ys = recurrence.find(y) + for prev_y in prev_ys: + if len(prev_y.args) != 1: + raise TypeError("Recurrence should be in a single variable") + + shift = prev_y.args[0].match(n + k)[k] + if not (shift.is_constant() and shift.is_integer and shift < 0): + raise TypeError("Recurrence should have constant," + " negative, integer shifts" + " (found {})".format(prev_y)) + + if -shift > degree: + degree = -shift + + if not initial: + initial = [Dummy("c_{}".format(k)) for k in range(degree)] + + if len(initial) != degree: + raise ValueError("Number of initial terms must equal degree") + + degree = Integer(degree) + start = sympify(start) + + initial = Tuple(*(sympify(x) for x in initial)) + + seq = Basic.__new__(cls, recurrence, yn, n, initial, start) + + seq.cache = {y(start + k): init for k, init in enumerate(initial)} + seq.degree = degree + + return seq + + @property + def _recurrence(self): + """Equation defining recurrence.""" + return self.args[0] + + @property + def recurrence(self): + """Equation defining recurrence.""" + return Eq(self.yn, self.args[0]) + + @property + def yn(self): + """Applied function representing the nth term""" + return self.args[1] + + @property + def y(self): + """Undefined function for the nth term of the sequence""" + return self.yn.func + + @property + def n(self): + """Sequence index symbol""" + return self.args[2] + + @property + def initial(self): + """The initial values of the sequence""" + return self.args[3] + + @property + def start(self): + """The starting point of the sequence. This point is included""" + return self.args[4] + + @property + def stop(self): + """The ending point of the sequence. (oo)""" + return S.Infinity + + @property + def interval(self): + """Interval on which sequence is defined.""" + return (self.start, S.Infinity) + + def _eval_coeff(self, index): + if index - self.start < len(self.cache): + return self.cache[self.y(index)] + + for current in range(len(self.cache), index + 1): + # Use xreplace over subs for performance. + # See issue #10697. + seq_index = self.start + current + current_recurrence = self._recurrence.xreplace({self.n: seq_index}) + new_term = current_recurrence.xreplace(self.cache) + + self.cache[self.y(seq_index)] = new_term + + return self.cache[self.y(self.start + current)] + + def __iter__(self): + index = self.start + while True: + yield self._eval_coeff(index) + index += 1 + + +def sequence(seq, limits=None): + """ + Returns appropriate sequence object. + + Explanation + =========== + + If ``seq`` is a SymPy sequence, returns :class:`SeqPer` object + otherwise returns :class:`SeqFormula` object. + + Examples + ======== + + >>> from sympy import sequence + >>> from sympy.abc import n + >>> sequence(n**2, (n, 0, 5)) + SeqFormula(n**2, (n, 0, 5)) + >>> sequence((1, 2, 3), (n, 0, 5)) + SeqPer((1, 2, 3), (n, 0, 5)) + + See Also + ======== + + sympy.series.sequences.SeqPer + sympy.series.sequences.SeqFormula + """ + seq = sympify(seq) + + if is_sequence(seq, Tuple): + return SeqPer(seq, limits) + else: + return SeqFormula(seq, limits) + + +############################################################################### +# OPERATIONS # +############################################################################### + + +class SeqExprOp(SeqBase): + """ + Base class for operations on sequences. + + Examples + ======== + + >>> from sympy.series.sequences import SeqExprOp, sequence + >>> from sympy.abc import n + >>> s1 = sequence(n**2, (n, 0, 10)) + >>> s2 = sequence((1, 2, 3), (n, 5, 10)) + >>> s = SeqExprOp(s1, s2) + >>> s.gen + (n**2, (1, 2, 3)) + >>> s.interval + Interval(5, 10) + >>> s.length + 6 + + See Also + ======== + + sympy.series.sequences.SeqAdd + sympy.series.sequences.SeqMul + """ + @property + def gen(self): + """Generator for the sequence. + + returns a tuple of generators of all the argument sequences. + """ + return tuple(a.gen for a in self.args) + + @property + def interval(self): + """Sequence is defined on the intersection + of all the intervals of respective sequences + """ + return Intersection(*(a.interval for a in self.args)) + + @property + def start(self): + return self.interval.inf + + @property + def stop(self): + return self.interval.sup + + @property + def variables(self): + """Cumulative of all the bound variables""" + return tuple(flatten([a.variables for a in self.args])) + + @property + def length(self): + return self.stop - self.start + 1 + + +class SeqAdd(SeqExprOp): + """Represents term-wise addition of sequences. + + Rules: + * The interval on which sequence is defined is the intersection + of respective intervals of sequences. + * Anything + :class:`EmptySequence` remains unchanged. + * Other rules are defined in ``_add`` methods of sequence classes. + + Examples + ======== + + >>> from sympy import EmptySequence, oo, SeqAdd, SeqPer, SeqFormula + >>> from sympy.abc import n + >>> SeqAdd(SeqPer((1, 2), (n, 0, oo)), EmptySequence) + SeqPer((1, 2), (n, 0, oo)) + >>> SeqAdd(SeqPer((1, 2), (n, 0, 5)), SeqPer((1, 2), (n, 6, 10))) + EmptySequence + >>> SeqAdd(SeqPer((1, 2), (n, 0, oo)), SeqFormula(n**2, (n, 0, oo))) + SeqAdd(SeqFormula(n**2, (n, 0, oo)), SeqPer((1, 2), (n, 0, oo))) + >>> SeqAdd(SeqFormula(n**3), SeqFormula(n**2)) + SeqFormula(n**3 + n**2, (n, 0, oo)) + + See Also + ======== + + sympy.series.sequences.SeqMul + """ + + def __new__(cls, *args, **kwargs): + evaluate = kwargs.get('evaluate', global_parameters.evaluate) + + # flatten inputs + args = list(args) + + # adapted from sympy.sets.sets.Union + def _flatten(arg): + if isinstance(arg, SeqBase): + if isinstance(arg, SeqAdd): + return sum(map(_flatten, arg.args), []) + else: + return [arg] + if iterable(arg): + return sum(map(_flatten, arg), []) + raise TypeError("Input must be Sequences or " + " iterables of Sequences") + args = _flatten(args) + + args = [a for a in args if a is not S.EmptySequence] + + # Addition of no sequences is EmptySequence + if not args: + return S.EmptySequence + + if Intersection(*(a.interval for a in args)) is S.EmptySet: + return S.EmptySequence + + # reduce using known rules + if evaluate: + return SeqAdd.reduce(args) + + args = list(ordered(args, SeqBase._start_key)) + + return Basic.__new__(cls, *args) + + @staticmethod + def reduce(args): + """Simplify :class:`SeqAdd` using known rules. + + Iterates through all pairs and ask the constituent + sequences if they can simplify themselves with any other constituent. + + Notes + ===== + + adapted from ``Union.reduce`` + + """ + new_args = True + while new_args: + for id1, s in enumerate(args): + new_args = False + for id2, t in enumerate(args): + if id1 == id2: + continue + new_seq = s._add(t) + # This returns None if s does not know how to add + # with t. Returns the newly added sequence otherwise + if new_seq is not None: + new_args = [a for a in args if a not in (s, t)] + new_args.append(new_seq) + break + if new_args: + args = new_args + break + + if len(args) == 1: + return args.pop() + else: + return SeqAdd(args, evaluate=False) + + def _eval_coeff(self, pt): + """adds up the coefficients of all the sequences at point pt""" + return sum(a.coeff(pt) for a in self.args) + + +class SeqMul(SeqExprOp): + r"""Represents term-wise multiplication of sequences. + + Explanation + =========== + + Handles multiplication of sequences only. For multiplication + with other objects see :func:`SeqBase.coeff_mul`. + + Rules: + * The interval on which sequence is defined is the intersection + of respective intervals of sequences. + * Anything \* :class:`EmptySequence` returns :class:`EmptySequence`. + * Other rules are defined in ``_mul`` methods of sequence classes. + + Examples + ======== + + >>> from sympy import EmptySequence, oo, SeqMul, SeqPer, SeqFormula + >>> from sympy.abc import n + >>> SeqMul(SeqPer((1, 2), (n, 0, oo)), EmptySequence) + EmptySequence + >>> SeqMul(SeqPer((1, 2), (n, 0, 5)), SeqPer((1, 2), (n, 6, 10))) + EmptySequence + >>> SeqMul(SeqPer((1, 2), (n, 0, oo)), SeqFormula(n**2)) + SeqMul(SeqFormula(n**2, (n, 0, oo)), SeqPer((1, 2), (n, 0, oo))) + >>> SeqMul(SeqFormula(n**3), SeqFormula(n**2)) + SeqFormula(n**5, (n, 0, oo)) + + See Also + ======== + + sympy.series.sequences.SeqAdd + """ + + def __new__(cls, *args, **kwargs): + evaluate = kwargs.get('evaluate', global_parameters.evaluate) + + # flatten inputs + args = list(args) + + # adapted from sympy.sets.sets.Union + def _flatten(arg): + if isinstance(arg, SeqBase): + if isinstance(arg, SeqMul): + return sum(map(_flatten, arg.args), []) + else: + return [arg] + elif iterable(arg): + return sum(map(_flatten, arg), []) + raise TypeError("Input must be Sequences or " + " iterables of Sequences") + args = _flatten(args) + + # Multiplication of no sequences is EmptySequence + if not args: + return S.EmptySequence + + if Intersection(*(a.interval for a in args)) is S.EmptySet: + return S.EmptySequence + + # reduce using known rules + if evaluate: + return SeqMul.reduce(args) + + args = list(ordered(args, SeqBase._start_key)) + + return Basic.__new__(cls, *args) + + @staticmethod + def reduce(args): + """Simplify a :class:`SeqMul` using known rules. + + Explanation + =========== + + Iterates through all pairs and ask the constituent + sequences if they can simplify themselves with any other constituent. + + Notes + ===== + + adapted from ``Union.reduce`` + + """ + new_args = True + while new_args: + for id1, s in enumerate(args): + new_args = False + for id2, t in enumerate(args): + if id1 == id2: + continue + new_seq = s._mul(t) + # This returns None if s does not know how to multiply + # with t. Returns the newly multiplied sequence otherwise + if new_seq is not None: + new_args = [a for a in args if a not in (s, t)] + new_args.append(new_seq) + break + if new_args: + args = new_args + break + + if len(args) == 1: + return args.pop() + else: + return SeqMul(args, evaluate=False) + + def _eval_coeff(self, pt): + """multiplies the coefficients of all the sequences at point pt""" + val = 1 + for a in self.args: + val *= a.coeff(pt) + return val diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/series.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/series.py new file mode 100644 index 0000000000000000000000000000000000000000..e9feec7d3b1987bfaa5238969f531e9f98b88b25 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/series.py @@ -0,0 +1,63 @@ +from sympy.core.sympify import sympify + + +def series(expr, x=None, x0=0, n=6, dir="+"): + """Series expansion of expr around point `x = x0`. + + Parameters + ========== + + expr : Expression + The expression whose series is to be expanded. + + x : Symbol + It is the variable of the expression to be calculated. + + x0 : Value + The value around which ``x`` is calculated. Can be any value + from ``-oo`` to ``oo``. + + n : Value + The number of terms upto which the series is to be expanded. + + dir : String, optional + The series-expansion can be bi-directional. If ``dir="+"``, + then (x->x0+). If ``dir="-"``, then (x->x0-). For infinite + ``x0`` (``oo`` or ``-oo``), the ``dir`` argument is determined + from the direction of the infinity (i.e., ``dir="-"`` for + ``oo``). + + Examples + ======== + + >>> from sympy import series, tan, oo + >>> from sympy.abc import x + >>> f = tan(x) + >>> series(f, x, 2, 6, "+") + tan(2) + (1 + tan(2)**2)*(x - 2) + (x - 2)**2*(tan(2)**3 + tan(2)) + + (x - 2)**3*(1/3 + 4*tan(2)**2/3 + tan(2)**4) + (x - 2)**4*(tan(2)**5 + + 5*tan(2)**3/3 + 2*tan(2)/3) + (x - 2)**5*(2/15 + 17*tan(2)**2/15 + + 2*tan(2)**4 + tan(2)**6) + O((x - 2)**6, (x, 2)) + + >>> series(f, x, 2, 3, "-") + tan(2) + (2 - x)*(-tan(2)**2 - 1) + (2 - x)**2*(tan(2)**3 + tan(2)) + + O((x - 2)**3, (x, 2)) + + >>> series(f, x, 2, oo, "+") + Traceback (most recent call last): + ... + TypeError: 'Infinity' object cannot be interpreted as an integer + + Returns + ======= + + Expr + Series expansion of the expression about x0 + + See Also + ======== + + sympy.core.expr.Expr.series: See the docstring of Expr.series() for complete details of this wrapper. + """ + expr = sympify(expr) + return expr.series(x, x0, n, dir) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/series_class.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/series_class.py new file mode 100644 index 0000000000000000000000000000000000000000..ff04993b266a3cbd3f767042d4325fb11edb2168 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/series_class.py @@ -0,0 +1,99 @@ +""" +Contains the base class for series +Made using sequences in mind +""" + +from sympy.core.expr import Expr +from sympy.core.singleton import S +from sympy.core.cache import cacheit + + +class SeriesBase(Expr): + """Base Class for series""" + + @property + def interval(self): + """The interval on which the series is defined""" + raise NotImplementedError("(%s).interval" % self) + + @property + def start(self): + """The starting point of the series. This point is included""" + raise NotImplementedError("(%s).start" % self) + + @property + def stop(self): + """The ending point of the series. This point is included""" + raise NotImplementedError("(%s).stop" % self) + + @property + def length(self): + """Length of the series expansion""" + raise NotImplementedError("(%s).length" % self) + + @property + def variables(self): + """Returns a tuple of variables that are bounded""" + return () + + @property + def free_symbols(self): + """ + This method returns the symbols in the object, excluding those + that take on a specific value (i.e. the dummy symbols). + """ + return ({j for i in self.args for j in i.free_symbols} + .difference(self.variables)) + + @cacheit + def term(self, pt): + """Term at point pt of a series""" + if pt < self.start or pt > self.stop: + raise IndexError("Index %s out of bounds %s" % (pt, self.interval)) + return self._eval_term(pt) + + def _eval_term(self, pt): + raise NotImplementedError("The _eval_term method should be added to" + "%s to return series term so it is available" + "when 'term' calls it." + % self.func) + + def _ith_point(self, i): + """ + Returns the i'th point of a series + If start point is negative infinity, point is returned from the end. + Assumes the first point to be indexed zero. + + Examples + ======== + + TODO + """ + if self.start is S.NegativeInfinity: + initial = self.stop + step = -1 + else: + initial = self.start + step = 1 + + return initial + i*step + + def __iter__(self): + i = 0 + while i < self.length: + pt = self._ith_point(i) + yield self.term(pt) + i += 1 + + def __getitem__(self, index): + if isinstance(index, int): + index = self._ith_point(index) + return self.term(index) + elif isinstance(index, slice): + start, stop = index.start, index.stop + if start is None: + start = 0 + if stop is None: + stop = self.length + return [self.term(self._ith_point(i)) for i in + range(start, stop, index.step or 1)] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_approximants.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_approximants.py new file mode 100644 index 0000000000000000000000000000000000000000..9c03d2ce38add99b0dce8725b6c8d8844b31f76b --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_approximants.py @@ -0,0 +1,23 @@ +from sympy.series import approximants +from sympy.core.symbol import symbols +from sympy.functions.combinatorial.factorials import binomial +from sympy.functions.combinatorial.numbers import (fibonacci, lucas) + + +def test_approximants(): + x, t = symbols("x,t") + g = [lucas(k) for k in range(16)] + assert list(approximants(g)) == ( + [2, -4/(x - 2), (5*x - 2)/(3*x - 1), (x - 2)/(x**2 + x - 1)] ) + g = [lucas(k)+fibonacci(k+2) for k in range(16)] + assert list(approximants(g)) == ( + [3, -3/(x - 1), (3*x - 3)/(2*x - 1), -3/(x**2 + x - 1)] ) + g = [lucas(k)**2 for k in range(16)] + assert list(approximants(g)) == ( + [4, -16/(x - 4), (35*x - 4)/(9*x - 1), (37*x - 28)/(13*x**2 + 11*x - 7), + (50*x**2 + 63*x - 52)/(37*x**2 + 19*x - 13), + (-x**2 - 7*x + 4)/(x**3 - 2*x**2 - 2*x + 1)] ) + p = [sum(binomial(k,i)*x**i for i in range(k+1)) for k in range(16)] + y = approximants(p, t, simplify=True) + assert next(y) == 1 + assert next(y) == -1/(t*(x + 1) - 1) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_aseries.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_aseries.py new file mode 100644 index 0000000000000000000000000000000000000000..cae0ac0a43f2406dd96e45c6a31939ac6b4cdcaa --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_aseries.py @@ -0,0 +1,55 @@ +from sympy.core.function import PoleError +from sympy.core.numbers import oo +from sympy.core.symbol import Symbol +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.series.order import O +from sympy.abc import x + +from sympy.testing.pytest import raises + +def test_simple(): + # Gruntz' theses pp. 91 to 96 + # 6.6 + e = sin(1/x + exp(-x)) - sin(1/x) + assert e.aseries(x) == (1/(24*x**4) - 1/(2*x**2) + 1 + O(x**(-6), (x, oo)))*exp(-x) + + e = exp(x) * (exp(1/x + exp(-x)) - exp(1/x)) + assert e.aseries(x, n=4) == 1/(6*x**3) + 1/(2*x**2) + 1/x + 1 + O(x**(-4), (x, oo)) + + e = exp(exp(x) / (1 - 1/x)) + assert e.aseries(x) == exp(exp(x) / (1 - 1/x)) + + # The implementation of bound in aseries is incorrect currently. This test + # should be commented out when that is fixed. + # assert e.aseries(x, bound=3) == exp(exp(x) / x**2)*exp(exp(x) / x)*exp(-exp(x) + exp(x)/(1 - 1/x) - \ + # exp(x) / x - exp(x) / x**2) * exp(exp(x)) + + e = exp(sin(1/x + exp(-exp(x)))) - exp(sin(1/x)) + assert e.aseries(x, n=4) == (-1/(2*x**3) + 1/x + 1 + O(x**(-4), (x, oo)))*exp(-exp(x)) + + e3 = lambda x:exp(exp(exp(x))) + e = e3(x)/e3(x - 1/e3(x)) + assert e.aseries(x, n=3) == 1 + exp(2*x + 2*exp(x))*exp(-2*exp(exp(x)))/2\ + - exp(2*x + exp(x))*exp(-2*exp(exp(x)))/2 - exp(x + exp(x))*exp(-2*exp(exp(x)))/2\ + + exp(x + exp(x))*exp(-exp(exp(x))) + O(exp(-3*exp(exp(x))), (x, oo)) + + e = exp(exp(x)) * (exp(sin(1/x + 1/exp(exp(x)))) - exp(sin(1/x))) + assert e.aseries(x, n=4) == -1/(2*x**3) + 1/x + 1 + O(x**(-4), (x, oo)) + + n = Symbol('n', integer=True) + e = (sqrt(n)*log(n)**2*exp(sqrt(log(n))*log(log(n))**2*exp(sqrt(log(log(n)))*log(log(log(n)))**3)))/n + assert e.aseries(n) == \ + exp(exp(sqrt(log(log(n)))*log(log(log(n)))**3)*sqrt(log(n))*log(log(n))**2)*log(n)**2/sqrt(n) + + +def test_hierarchical(): + e = sin(1/x + exp(-x)) + assert e.aseries(x, n=3, hir=True) == -exp(-2*x)*sin(1/x)/2 + \ + exp(-x)*cos(1/x) + sin(1/x) + O(exp(-3*x), (x, oo)) + + e = sin(x) * cos(exp(-x)) + assert e.aseries(x, hir=True) == exp(-4*x)*sin(x)/24 - \ + exp(-2*x)*sin(x)/2 + sin(x) + O(exp(-6*x), (x, oo)) + raises(PoleError, lambda: e.aseries(x)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_demidovich.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_demidovich.py new file mode 100644 index 0000000000000000000000000000000000000000..98cafbae6f019dd3d97d306099d5780ed2f37f04 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_demidovich.py @@ -0,0 +1,143 @@ +from sympy.core.numbers import (Rational, oo, pi) +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import (root, sqrt) +from sympy.functions.elementary.trigonometric import (asin, cos, sin, tan) +from sympy.polys.rationaltools import together +from sympy.series.limits import limit + +# Numbers listed with the tests refer to problem numbers in the book +# "Anti-demidovich, problemas resueltos, Ed. URSS" + +x = Symbol("x") + + +def test_leadterm(): + assert (3 + 2*x**(log(3)/log(2) - 1)).leadterm(x) == (3, 0) + + +def root3(x): + return root(x, 3) + + +def root4(x): + return root(x, 4) + + +def test_Limits_simple_0(): + assert limit((2**(x + 1) + 3**(x + 1))/(2**x + 3**x), x, oo) == 3 # 175 + + +def test_Limits_simple_1(): + assert limit((x + 1)*(x + 2)*(x + 3)/x**3, x, oo) == 1 # 172 + assert limit(sqrt(x + 1) - sqrt(x), x, oo) == 0 # 179 + assert limit((2*x - 3)*(3*x + 5)*(4*x - 6)/(3*x**3 + x - 1), x, oo) == 8 # Primjer 1 + assert limit(x/root3(x**3 + 10), x, oo) == 1 # Primjer 2 + assert limit((x + 1)**2/(x**2 + 1), x, oo) == 1 # 181 + + +def test_Limits_simple_2(): + assert limit(1000*x/(x**2 - 1), x, oo) == 0 # 182 + assert limit((x**2 - 5*x + 1)/(3*x + 7), x, oo) is oo # 183 + assert limit((2*x**2 - x + 3)/(x**3 - 8*x + 5), x, oo) == 0 # 184 + assert limit((2*x**2 - 3*x - 4)/sqrt(x**4 + 1), x, oo) == 2 # 186 + assert limit((2*x + 3)/(x + root3(x)), x, oo) == 2 # 187 + assert limit(x**2/(10 + x*sqrt(x)), x, oo) is oo # 188 + assert limit(root3(x**2 + 1)/(x + 1), x, oo) == 0 # 189 + assert limit(sqrt(x)/sqrt(x + sqrt(x + sqrt(x))), x, oo) == 1 # 190 + + +def test_Limits_simple_3a(): + a = Symbol('a') + #issue 3513 + assert together(limit((x**2 - (a + 1)*x + a)/(x**3 - a**3), x, a)) == \ + (a - 1)/(3*a**2) # 196 + + +def test_Limits_simple_3b(): + h = Symbol("h") + assert limit(((x + h)**3 - x**3)/h, h, 0) == 3*x**2 # 197 + assert limit((1/(1 - x) - 3/(1 - x**3)), x, 1) == -1 # 198 + assert limit((sqrt(1 + x) - 1)/(root3(1 + x) - 1), x, 0) == Rational(3)/2 # Primer 4 + assert limit((sqrt(x) - 1)/(x - 1), x, 1) == Rational(1)/2 # 199 + assert limit((sqrt(x) - 8)/(root3(x) - 4), x, 64) == 3 # 200 + assert limit((root3(x) - 1)/(root4(x) - 1), x, 1) == Rational(4)/3 # 201 + assert limit( + (root3(x**2) - 2*root3(x) + 1)/(x - 1)**2, x, 1) == Rational(1)/9 # 202 + + +def test_Limits_simple_4a(): + a = Symbol('a') + assert limit((sqrt(x) - sqrt(a))/(x - a), x, a) == 1/(2*sqrt(a)) # Primer 5 + assert limit((sqrt(x) - 1)/(root3(x) - 1), x, 1) == Rational(3, 2) # 205 + assert limit((sqrt(1 + x) - sqrt(1 - x))/x, x, 0) == 1 # 207 + assert limit(sqrt(x**2 - 5*x + 6) - x, x, oo) == Rational(-5, 2) # 213 + + +def test_limits_simple_4aa(): + assert limit(x*(sqrt(x**2 + 1) - x), x, oo) == Rational(1)/2 # 214 + + +def test_Limits_simple_4b(): + #issue 3511 + assert limit(x - root3(x**3 - 1), x, oo) == 0 # 215 + + +def test_Limits_simple_4c(): + assert limit(log(1 + exp(x))/x, x, -oo) == 0 # 267a + assert limit(log(1 + exp(x))/x, x, oo) == 1 # 267b + + +def test_bounded(): + assert limit(sin(x)/x, x, oo) == 0 # 216b + assert limit(x*sin(1/x), x, 0) == 0 # 227a + + +def test_f1a(): + #issue 3508: + assert limit((sin(2*x)/x)**(1 + x), x, 0) == 2 # Primer 7 + + +def test_f1a2(): + #issue 3509: + assert limit(((x - 1)/(x + 1))**x, x, oo) == exp(-2) # Primer 9 + + +def test_f1b(): + m = Symbol("m") + n = Symbol("n") + h = Symbol("h") + a = Symbol("a") + assert limit(sin(x)/x, x, 2) == sin(2)/2 # 216a + assert limit(sin(3*x)/x, x, 0) == 3 # 217 + assert limit(sin(5*x)/sin(2*x), x, 0) == Rational(5, 2) # 218 + assert limit(sin(pi*x)/sin(3*pi*x), x, 0) == Rational(1, 3) # 219 + assert limit(x*sin(pi/x), x, oo) == pi # 220 + assert limit((1 - cos(x))/x**2, x, 0) == S.Half # 221 + assert limit(x*sin(1/x), x, oo) == 1 # 227b + assert limit((cos(m*x) - cos(n*x))/x**2, x, 0) == -m**2/2 + n**2/2 # 232 + assert limit((tan(x) - sin(x))/x**3, x, 0) == S.Half # 233 + assert limit((x - sin(2*x))/(x + sin(3*x)), x, 0) == -Rational(1, 4) # 237 + assert limit((1 - sqrt(cos(x)))/x**2, x, 0) == Rational(1, 4) # 239 + assert limit((sqrt(1 + sin(x)) - sqrt(1 - sin(x)))/x, x, 0) == 1 # 240 + + assert limit((1 + h/x)**x, x, oo) == exp(h) # Primer 9 + assert limit((sin(x) - sin(a))/(x - a), x, a) == cos(a) # 222, *176 + assert limit((cos(x) - cos(a))/(x - a), x, a) == -sin(a) # 223 + assert limit((sin(x + h) - sin(x))/h, h, 0) == cos(x) # 225 + + +def test_f2a(): + assert limit(((x + 1)/(2*x + 1))**(x**2), x, oo) == 0 # Primer 8 + + +def test_f2(): + assert limit((sqrt( + cos(x)) - root3(cos(x)))/(sin(x)**2), x, 0) == -Rational(1, 12) # *184 + + +def test_f3(): + a = Symbol('a') + #issue 3504 + assert limit(asin(a*x)/x, x, 0) == a diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_formal.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_formal.py new file mode 100644 index 0000000000000000000000000000000000000000..cac60b12534152a5783bb8f0faab2c06da6691fb --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_formal.py @@ -0,0 +1,618 @@ +from sympy.concrete.summations import Sum +from sympy.core.add import Add +from sympy.core.function import (Derivative, Function) +from sympy.core.mul import Mul +from sympy.core.numbers import (I, Rational, oo, pi) +from sympy.core.singleton import S +from sympy.core.symbol import symbols +from sympy.functions.combinatorial.factorials import factorial +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.hyperbolic import (acosh, asech) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (acos, asin, atan, cos, sin) +from sympy.functions.special.bessel import airyai +from sympy.functions.special.error_functions import erf +from sympy.functions.special.gamma_functions import gamma +from sympy.integrals.integrals import integrate +from sympy.series.formal import fps +from sympy.series.order import O +from sympy.series.formal import (rational_algorithm, FormalPowerSeries, + FormalPowerSeriesProduct, FormalPowerSeriesCompose, + FormalPowerSeriesInverse, simpleDE, + rational_independent, exp_re, hyper_re) +from sympy.testing.pytest import raises, XFAIL, slow + +x, y, z = symbols('x y z') +n, m, k = symbols('n m k', integer=True) +f, r = Function('f'), Function('r') + + +def test_rational_algorithm(): + f = 1 / ((x - 1)**2 * (x - 2)) + assert rational_algorithm(f, x, k) == \ + (-2**(-k - 1) + 1 - (factorial(k + 1) / factorial(k)), 0, 0) + + f = (1 + x + x**2 + x**3) / ((x - 1) * (x - 2)) + assert rational_algorithm(f, x, k) == \ + (-15*2**(-k - 1) + 4, x + 4, 0) + + f = z / (y*m - m*x - y*x + x**2) + assert rational_algorithm(f, x, k) == \ + (((-y**(-k - 1)*z) / (y - m)) + ((m**(-k - 1)*z) / (y - m)), 0, 0) + + f = x / (1 - x - x**2) + assert rational_algorithm(f, x, k) is None + assert rational_algorithm(f, x, k, full=True) == \ + (((Rational(-1, 2) + sqrt(5)/2)**(-k - 1) * + (-sqrt(5)/10 + S.Half)) + + ((-sqrt(5)/2 - S.Half)**(-k - 1) * + (sqrt(5)/10 + S.Half)), 0, 0) + + f = 1 / (x**2 + 2*x + 2) + assert rational_algorithm(f, x, k) is None + assert rational_algorithm(f, x, k, full=True) == \ + ((I*(-1 + I)**(-k - 1)) / 2 - (I*(-1 - I)**(-k - 1)) / 2, 0, 0) + + f = log(1 + x) + assert rational_algorithm(f, x, k) == \ + (-(-1)**(-k) / k, 0, 1) + + f = atan(x) + assert rational_algorithm(f, x, k) is None + assert rational_algorithm(f, x, k, full=True) == \ + (((I*I**(-k)) / 2 - (I*(-I)**(-k)) / 2) / k, 0, 1) + + f = x*atan(x) - log(1 + x**2) / 2 + assert rational_algorithm(f, x, k) is None + assert rational_algorithm(f, x, k, full=True) == \ + (((I*I**(-k + 1)) / 2 - (I*(-I)**(-k + 1)) / 2) / + (k*(k - 1)), 0, 2) + + f = log((1 + x) / (1 - x)) / 2 - atan(x) + assert rational_algorithm(f, x, k) is None + assert rational_algorithm(f, x, k, full=True) == \ + ((-(-1)**(-k) / 2 - (I*I**(-k)) / 2 + (I*(-I)**(-k)) / 2 + + S.Half) / k, 0, 1) + + assert rational_algorithm(cos(x), x, k) is None + + +def test_rational_independent(): + ri = rational_independent + assert ri([], x) == [] + assert ri([cos(x), sin(x)], x) == [cos(x), sin(x)] + assert ri([x**2, sin(x), x*sin(x), x**3], x) == \ + [x**3 + x**2, x*sin(x) + sin(x)] + assert ri([S.One, x*log(x), log(x), sin(x)/x, cos(x), sin(x), x], x) == \ + [x + 1, x*log(x) + log(x), sin(x)/x + sin(x), cos(x)] + + +def test_simpleDE(): + # Tests just the first valid DE + for DE in simpleDE(exp(x), x, f): + assert DE == (-f(x) + Derivative(f(x), x), 1) + break + for DE in simpleDE(sin(x), x, f): + assert DE == (f(x) + Derivative(f(x), x, x), 2) + break + for DE in simpleDE(log(1 + x), x, f): + assert DE == ((x + 1)*Derivative(f(x), x, 2) + Derivative(f(x), x), 2) + break + for DE in simpleDE(asin(x), x, f): + assert DE == (x*Derivative(f(x), x) + (x**2 - 1)*Derivative(f(x), x, x), + 2) + break + for DE in simpleDE(exp(x)*sin(x), x, f): + assert DE == (2*f(x) - 2*Derivative(f(x)) + Derivative(f(x), x, x), 2) + break + for DE in simpleDE(((1 + x)/(1 - x))**n, x, f): + assert DE == (2*n*f(x) + (x**2 - 1)*Derivative(f(x), x), 1) + break + for DE in simpleDE(airyai(x), x, f): + assert DE == (-x*f(x) + Derivative(f(x), x, x), 2) + break + + +def test_exp_re(): + d = -f(x) + Derivative(f(x), x) + assert exp_re(d, r, k) == -r(k) + r(k + 1) + + d = f(x) + Derivative(f(x), x, x) + assert exp_re(d, r, k) == r(k) + r(k + 2) + + d = f(x) + Derivative(f(x), x) + Derivative(f(x), x, x) + assert exp_re(d, r, k) == r(k) + r(k + 1) + r(k + 2) + + d = Derivative(f(x), x) + Derivative(f(x), x, x) + assert exp_re(d, r, k) == r(k) + r(k + 1) + + d = Derivative(f(x), x, 3) + Derivative(f(x), x, 4) + Derivative(f(x)) + assert exp_re(d, r, k) == r(k) + r(k + 2) + r(k + 3) + + +def test_hyper_re(): + d = f(x) + Derivative(f(x), x, x) + assert hyper_re(d, r, k) == r(k) + (k+1)*(k+2)*r(k + 2) + + d = -x*f(x) + Derivative(f(x), x, x) + assert hyper_re(d, r, k) == (k + 2)*(k + 3)*r(k + 3) - r(k) + + d = 2*f(x) - 2*Derivative(f(x), x) + Derivative(f(x), x, x) + assert hyper_re(d, r, k) == \ + (-2*k - 2)*r(k + 1) + (k + 1)*(k + 2)*r(k + 2) + 2*r(k) + + d = 2*n*f(x) + (x**2 - 1)*Derivative(f(x), x) + assert hyper_re(d, r, k) == \ + k*r(k) + 2*n*r(k + 1) + (-k - 2)*r(k + 2) + + d = (x**10 + 4)*Derivative(f(x), x) + x*(x**10 - 1)*Derivative(f(x), x, x) + assert hyper_re(d, r, k) == \ + (k*(k - 1) + k)*r(k) + (4*k - (k + 9)*(k + 10) + 40)*r(k + 10) + + d = ((x**2 - 1)*Derivative(f(x), x, 3) + 3*x*Derivative(f(x), x, x) + + Derivative(f(x), x)) + assert hyper_re(d, r, k) == \ + ((k*(k - 2)*(k - 1) + 3*k*(k - 1) + k)*r(k) + + (-k*(k + 1)*(k + 2))*r(k + 2)) + + +def test_fps(): + assert fps(1) == 1 + assert fps(2, x) == 2 + assert fps(2, x, dir='+') == 2 + assert fps(2, x, dir='-') == 2 + assert fps(1/x + 1/x**2) == 1/x + 1/x**2 + assert fps(log(1 + x), hyper=False, rational=False) == log(1 + x) + + f = fps(x**2 + x + 1) + assert isinstance(f, FormalPowerSeries) + assert f.function == x**2 + x + 1 + assert f[0] == 1 + assert f[2] == x**2 + assert f.truncate(4) == x**2 + x + 1 + O(x**4) + assert f.polynomial() == x**2 + x + 1 + + f = fps(log(1 + x)) + assert isinstance(f, FormalPowerSeries) + assert f.function == log(1 + x) + assert f.subs(x, y) == f + assert f[:5] == [0, x, -x**2/2, x**3/3, -x**4/4] + assert f.as_leading_term(x) == x + assert f.polynomial(6) == x - x**2/2 + x**3/3 - x**4/4 + x**5/5 + + k = f.ak.variables[0] + assert f.infinite == Sum((-(-1)**(-k)*x**k)/k, (k, 1, oo)) + + ft, s = f.truncate(n=None), f[:5] + for i, t in enumerate(ft): + if i == 5: + break + assert s[i] == t + + f = sin(x).fps(x) + assert isinstance(f, FormalPowerSeries) + assert f.truncate() == x - x**3/6 + x**5/120 + O(x**6) + + raises(NotImplementedError, lambda: fps(y*x)) + raises(ValueError, lambda: fps(x, dir=0)) + + +@slow +def test_fps__rational(): + assert fps(1/x) == (1/x) + assert fps((x**2 + x + 1) / x**3, dir=-1) == (x**2 + x + 1) / x**3 + + f = 1 / ((x - 1)**2 * (x - 2)) + assert fps(f, x).truncate() == \ + (Rational(-1, 2) - x*Rational(5, 4) - 17*x**2/8 - 49*x**3/16 - 129*x**4/32 - + 321*x**5/64 + O(x**6)) + + f = (1 + x + x**2 + x**3) / ((x - 1) * (x - 2)) + assert fps(f, x).truncate() == \ + (S.Half + x*Rational(5, 4) + 17*x**2/8 + 49*x**3/16 + 113*x**4/32 + + 241*x**5/64 + O(x**6)) + + f = x / (1 - x - x**2) + assert fps(f, x, full=True).truncate() == \ + x + x**2 + 2*x**3 + 3*x**4 + 5*x**5 + O(x**6) + + f = 1 / (x**2 + 2*x + 2) + assert fps(f, x, full=True).truncate() == \ + S.Half - x/2 + x**2/4 - x**4/8 + x**5/8 + O(x**6) + + f = log(1 + x) + assert fps(f, x).truncate() == \ + x - x**2/2 + x**3/3 - x**4/4 + x**5/5 + O(x**6) + assert fps(f, x, dir=1).truncate() == fps(f, x, dir=-1).truncate() + assert fps(f, x, 2).truncate() == \ + (log(3) - Rational(2, 3) - (x - 2)**2/18 + (x - 2)**3/81 - + (x - 2)**4/324 + (x - 2)**5/1215 + x/3 + O((x - 2)**6, (x, 2))) + assert fps(f, x, 2, dir=-1).truncate() == \ + (log(3) - Rational(2, 3) - (-x + 2)**2/18 - (-x + 2)**3/81 - + (-x + 2)**4/324 - (-x + 2)**5/1215 + x/3 + O((x - 2)**6, (x, 2))) + + f = atan(x) + assert fps(f, x, full=True).truncate() == x - x**3/3 + x**5/5 + O(x**6) + assert fps(f, x, full=True, dir=1).truncate() == \ + fps(f, x, full=True, dir=-1).truncate() + assert fps(f, x, 2, full=True).truncate() == \ + (atan(2) - Rational(2, 5) - 2*(x - 2)**2/25 + 11*(x - 2)**3/375 - + 6*(x - 2)**4/625 + 41*(x - 2)**5/15625 + x/5 + O((x - 2)**6, (x, 2))) + assert fps(f, x, 2, full=True, dir=-1).truncate() == \ + (atan(2) - Rational(2, 5) - 2*(-x + 2)**2/25 - 11*(-x + 2)**3/375 - + 6*(-x + 2)**4/625 - 41*(-x + 2)**5/15625 + x/5 + O((x - 2)**6, (x, 2))) + + f = x*atan(x) - log(1 + x**2) / 2 + assert fps(f, x, full=True).truncate() == x**2/2 - x**4/12 + O(x**6) + + f = log((1 + x) / (1 - x)) / 2 - atan(x) + assert fps(f, x, full=True).truncate(n=10) == 2*x**3/3 + 2*x**7/7 + O(x**10) + + +@slow +def test_fps__hyper(): + f = sin(x) + assert fps(f, x).truncate() == x - x**3/6 + x**5/120 + O(x**6) + + f = cos(x) + assert fps(f, x).truncate() == 1 - x**2/2 + x**4/24 + O(x**6) + + f = exp(x) + assert fps(f, x).truncate() == \ + 1 + x + x**2/2 + x**3/6 + x**4/24 + x**5/120 + O(x**6) + + f = atan(x) + assert fps(f, x).truncate() == x - x**3/3 + x**5/5 + O(x**6) + + f = exp(acos(x)) + assert fps(f, x).truncate() == \ + (exp(pi/2) - x*exp(pi/2) + x**2*exp(pi/2)/2 - x**3*exp(pi/2)/3 + + 5*x**4*exp(pi/2)/24 - x**5*exp(pi/2)/6 + O(x**6)) + + f = exp(acosh(x)) + assert fps(f, x).truncate() == I + x - I*x**2/2 - I*x**4/8 + O(x**6) + + f = atan(1/x) + assert fps(f, x).truncate() == pi/2 - x + x**3/3 - x**5/5 + O(x**6) + + f = x*atan(x) - log(1 + x**2) / 2 + assert fps(f, x, rational=False).truncate() == x**2/2 - x**4/12 + O(x**6) + + f = log(1 + x) + assert fps(f, x, rational=False).truncate() == \ + x - x**2/2 + x**3/3 - x**4/4 + x**5/5 + O(x**6) + + f = airyai(x**2) + assert fps(f, x).truncate() == \ + (3**Rational(5, 6)*gamma(Rational(1, 3))/(6*pi) - + 3**Rational(2, 3)*x**2/(3*gamma(Rational(1, 3))) + O(x**6)) + + f = exp(x)*sin(x) + assert fps(f, x).truncate() == x + x**2 + x**3/3 - x**5/30 + O(x**6) + + f = exp(x)*sin(x)/x + assert fps(f, x).truncate() == 1 + x + x**2/3 - x**4/30 - x**5/90 + O(x**6) + + f = sin(x) * cos(x) + assert fps(f, x).truncate() == x - 2*x**3/3 + 2*x**5/15 + O(x**6) + + +def test_fps_shift(): + f = x**-5*sin(x) + assert fps(f, x).truncate() == \ + 1/x**4 - 1/(6*x**2) + Rational(1, 120) - x**2/5040 + x**4/362880 + O(x**6) + + f = x**2*atan(x) + assert fps(f, x, rational=False).truncate() == \ + x**3 - x**5/3 + O(x**6) + + f = cos(sqrt(x))*x + assert fps(f, x).truncate() == \ + x - x**2/2 + x**3/24 - x**4/720 + x**5/40320 + O(x**6) + + f = x**2*cos(sqrt(x)) + assert fps(f, x).truncate() == \ + x**2 - x**3/2 + x**4/24 - x**5/720 + O(x**6) + + +def test_fps__Add_expr(): + f = x*atan(x) - log(1 + x**2) / 2 + assert fps(f, x).truncate() == x**2/2 - x**4/12 + O(x**6) + + f = sin(x) + cos(x) - exp(x) + log(1 + x) + assert fps(f, x).truncate() == x - 3*x**2/2 - x**4/4 + x**5/5 + O(x**6) + + f = 1/x + sin(x) + assert fps(f, x).truncate() == 1/x + x - x**3/6 + x**5/120 + O(x**6) + + f = sin(x) - cos(x) + 1/(x - 1) + assert fps(f, x).truncate() == \ + -2 - x**2/2 - 7*x**3/6 - 25*x**4/24 - 119*x**5/120 + O(x**6) + + +def test_fps__asymptotic(): + f = exp(x) + assert fps(f, x, oo) == f + assert fps(f, x, -oo).truncate() == O(1/x**6, (x, oo)) + + f = erf(x) + assert fps(f, x, oo).truncate() == 1 + O(1/x**6, (x, oo)) + assert fps(f, x, -oo).truncate() == -1 + O(1/x**6, (x, oo)) + + f = atan(x) + assert fps(f, x, oo, full=True).truncate() == \ + -1/(5*x**5) + 1/(3*x**3) - 1/x + pi/2 + O(1/x**6, (x, oo)) + assert fps(f, x, -oo, full=True).truncate() == \ + -1/(5*x**5) + 1/(3*x**3) - 1/x - pi/2 + O(1/x**6, (x, oo)) + + f = log(1 + x) + assert fps(f, x, oo) != \ + (-1/(5*x**5) - 1/(4*x**4) + 1/(3*x**3) - 1/(2*x**2) + 1/x - log(1/x) + + O(1/x**6, (x, oo))) + assert fps(f, x, -oo) != \ + (-1/(5*x**5) - 1/(4*x**4) + 1/(3*x**3) - 1/(2*x**2) + 1/x + I*pi - + log(-1/x) + O(1/x**6, (x, oo))) + + +def test_fps__fractional(): + f = sin(sqrt(x)) / x + assert fps(f, x).truncate() == \ + (1/sqrt(x) - sqrt(x)/6 + x**Rational(3, 2)/120 - + x**Rational(5, 2)/5040 + x**Rational(7, 2)/362880 - + x**Rational(9, 2)/39916800 + x**Rational(11, 2)/6227020800 + O(x**6)) + + f = sin(sqrt(x)) * x + assert fps(f, x).truncate() == \ + (x**Rational(3, 2) - x**Rational(5, 2)/6 + x**Rational(7, 2)/120 - + x**Rational(9, 2)/5040 + x**Rational(11, 2)/362880 + O(x**6)) + + f = atan(sqrt(x)) / x**2 + assert fps(f, x).truncate() == \ + (x**Rational(-3, 2) - x**Rational(-1, 2)/3 + x**S.Half/5 - + x**Rational(3, 2)/7 + x**Rational(5, 2)/9 - x**Rational(7, 2)/11 + + x**Rational(9, 2)/13 - x**Rational(11, 2)/15 + O(x**6)) + + f = exp(sqrt(x)) + assert fps(f, x).truncate().expand() == \ + (1 + x/2 + x**2/24 + x**3/720 + x**4/40320 + x**5/3628800 + sqrt(x) + + x**Rational(3, 2)/6 + x**Rational(5, 2)/120 + x**Rational(7, 2)/5040 + + x**Rational(9, 2)/362880 + x**Rational(11, 2)/39916800 + O(x**6)) + + f = exp(sqrt(x))*x + assert fps(f, x).truncate().expand() == \ + (x + x**2/2 + x**3/24 + x**4/720 + x**5/40320 + x**Rational(3, 2) + + x**Rational(5, 2)/6 + x**Rational(7, 2)/120 + x**Rational(9, 2)/5040 + + x**Rational(11, 2)/362880 + O(x**6)) + + +def test_fps__logarithmic_singularity(): + f = log(1 + 1/x) + assert fps(f, x) != \ + -log(x) + x - x**2/2 + x**3/3 - x**4/4 + x**5/5 + O(x**6) + assert fps(f, x, rational=False) != \ + -log(x) + x - x**2/2 + x**3/3 - x**4/4 + x**5/5 + O(x**6) + + +@XFAIL +def test_fps__logarithmic_singularity_fail(): + f = asech(x) # Algorithms for computing limits probably needs improvements + assert fps(f, x) == log(2) - log(x) - x**2/4 - 3*x**4/64 + O(x**6) + + +def test_fps_symbolic(): + f = x**n*sin(x**2) + assert fps(f, x).truncate(8) == x**(n + 2) - x**(n + 6)/6 + O(x**(n + 8), x) + + f = x**n*log(1 + x) + fp = fps(f, x) + k = fp.ak.variables[0] + assert fp.infinite == \ + Sum((-(-1)**(-k)*x**(k + n))/k, (k, 1, oo)) + + f = (x - 2)**n*log(1 + x) + assert fps(f, x, 2).truncate() == \ + ((x - 2)**n*log(3) + (x - 2)**(n + 1)/3 - (x - 2)**(n + 2)/18 + (x - 2)**(n + 3)/81 - + (x - 2)**(n + 4)/324 + (x - 2)**(n + 5)/1215 + O((x - 2)**(n + 6), (x, 2))) + + f = x**(n - 2)*cos(x) + assert fps(f, x).truncate() == \ + (x**(n - 2) - x**n/2 + x**(n + 2)/24 + O(x**(n + 4), x)) + + f = x**(n - 2)*sin(x) + x**n*exp(x) + assert fps(f, x).truncate() == \ + (x**(n - 1) + x**(n + 1) + x**(n + 2)/2 + x**n + + x**(n + 4)/24 + x**(n + 5)/60 + O(x**(n + 6), x)) + + f = x**n*atan(x) + assert fps(f, x, oo).truncate() == \ + (-x**(n - 5)/5 + x**(n - 3)/3 + x**n*(pi/2 - 1/x) + + O((1/x)**(-n)/x**6, (x, oo))) + + f = x**(n/2)*cos(x) + assert fps(f, x).truncate() == \ + x**(n/2) - x**(n/2 + 2)/2 + x**(n/2 + 4)/24 + O(x**(n/2 + 6), x) + + f = x**(n + m)*sin(x) + assert fps(f, x).truncate() == \ + x**(m + n + 1) - x**(m + n + 3)/6 + x**(m + n + 5)/120 + O(x**(m + n + 6), x) + + +def test_fps__slow(): + f = x*exp(x)*sin(2*x) # TODO: rsolve needs improvement + assert fps(f, x).truncate() == 2*x**2 + 2*x**3 - x**4/3 - x**5 + O(x**6) + + +def test_fps__operations(): + f1, f2 = fps(sin(x)), fps(cos(x)) + + fsum = f1 + f2 + assert fsum.function == sin(x) + cos(x) + assert fsum.truncate() == \ + 1 + x - x**2/2 - x**3/6 + x**4/24 + x**5/120 + O(x**6) + + fsum = f1 + 1 + assert fsum.function == sin(x) + 1 + assert fsum.truncate() == 1 + x - x**3/6 + x**5/120 + O(x**6) + + fsum = 1 + f2 + assert fsum.function == cos(x) + 1 + assert fsum.truncate() == 2 - x**2/2 + x**4/24 + O(x**6) + + assert (f1 + x) == Add(f1, x) + + assert -f2.truncate() == -1 + x**2/2 - x**4/24 + O(x**6) + assert (f1 - f1) is S.Zero + + fsub = f1 - f2 + assert fsub.function == sin(x) - cos(x) + assert fsub.truncate() == \ + -1 + x + x**2/2 - x**3/6 - x**4/24 + x**5/120 + O(x**6) + + fsub = f1 - 1 + assert fsub.function == sin(x) - 1 + assert fsub.truncate() == -1 + x - x**3/6 + x**5/120 + O(x**6) + + fsub = 1 - f2 + assert fsub.function == -cos(x) + 1 + assert fsub.truncate() == x**2/2 - x**4/24 + O(x**6) + + raises(ValueError, lambda: f1 + fps(exp(x), dir=-1)) + raises(ValueError, lambda: f1 + fps(exp(x), x0=1)) + + fm = f1 * 3 + + assert fm.function == 3*sin(x) + assert fm.truncate() == 3*x - x**3/2 + x**5/40 + O(x**6) + + fm = 3 * f2 + + assert fm.function == 3*cos(x) + assert fm.truncate() == 3 - 3*x**2/2 + x**4/8 + O(x**6) + + assert (f1 * f2) == Mul(f1, f2) + assert (f1 * x) == Mul(f1, x) + + fd = f1.diff() + assert fd.function == cos(x) + assert fd.truncate() == 1 - x**2/2 + x**4/24 + O(x**6) + + fd = f2.diff() + assert fd.function == -sin(x) + assert fd.truncate() == -x + x**3/6 - x**5/120 + O(x**6) + + fd = f2.diff().diff() + assert fd.function == -cos(x) + assert fd.truncate() == -1 + x**2/2 - x**4/24 + O(x**6) + + f3 = fps(exp(sqrt(x))) + fd = f3.diff() + assert fd.truncate().expand() == \ + (1/(2*sqrt(x)) + S.Half + x/12 + x**2/240 + x**3/10080 + x**4/725760 + + x**5/79833600 + sqrt(x)/4 + x**Rational(3, 2)/48 + x**Rational(5, 2)/1440 + + x**Rational(7, 2)/80640 + x**Rational(9, 2)/7257600 + x**Rational(11, 2)/958003200 + + O(x**6)) + + assert f1.integrate((x, 0, 1)) == -cos(1) + 1 + assert integrate(f1, (x, 0, 1)) == -cos(1) + 1 + + fi = integrate(f1, x) + assert fi.function == -cos(x) + assert fi.truncate() == -1 + x**2/2 - x**4/24 + O(x**6) + + fi = f2.integrate(x) + assert fi.function == sin(x) + assert fi.truncate() == x - x**3/6 + x**5/120 + O(x**6) + +def test_fps__product(): + f1, f2, f3 = fps(sin(x)), fps(exp(x)), fps(cos(x)) + + raises(ValueError, lambda: f1.product(exp(x), x)) + raises(ValueError, lambda: f1.product(fps(exp(x), dir=-1), x, 4)) + raises(ValueError, lambda: f1.product(fps(exp(x), x0=1), x, 4)) + raises(ValueError, lambda: f1.product(fps(exp(y)), x, 4)) + + fprod = f1.product(f2, x) + assert isinstance(fprod, FormalPowerSeriesProduct) + assert isinstance(fprod.ffps, FormalPowerSeries) + assert isinstance(fprod.gfps, FormalPowerSeries) + assert fprod.f == sin(x) + assert fprod.g == exp(x) + assert fprod.function == sin(x) * exp(x) + assert fprod._eval_terms(4) == x + x**2 + x**3/3 + assert fprod.truncate(4) == x + x**2 + x**3/3 + O(x**4) + assert fprod.polynomial(4) == x + x**2 + x**3/3 + + raises(NotImplementedError, lambda: fprod._eval_term(5)) + raises(NotImplementedError, lambda: fprod.infinite) + raises(NotImplementedError, lambda: fprod._eval_derivative(x)) + raises(NotImplementedError, lambda: fprod.integrate(x)) + + assert f1.product(f3, x)._eval_terms(4) == x - 2*x**3/3 + assert f1.product(f3, x).truncate(4) == x - 2*x**3/3 + O(x**4) + + +def test_fps__compose(): + f1, f2, f3 = fps(exp(x)), fps(sin(x)), fps(cos(x)) + + raises(ValueError, lambda: f1.compose(sin(x), x)) + raises(ValueError, lambda: f1.compose(fps(sin(x), dir=-1), x, 4)) + raises(ValueError, lambda: f1.compose(fps(sin(x), x0=1), x, 4)) + raises(ValueError, lambda: f1.compose(fps(sin(y)), x, 4)) + + raises(ValueError, lambda: f1.compose(f3, x)) + raises(ValueError, lambda: f2.compose(f3, x)) + + fcomp = f1.compose(f2, x) + assert isinstance(fcomp, FormalPowerSeriesCompose) + assert isinstance(fcomp.ffps, FormalPowerSeries) + assert isinstance(fcomp.gfps, FormalPowerSeries) + assert fcomp.f == exp(x) + assert fcomp.g == sin(x) + assert fcomp.function == exp(sin(x)) + assert fcomp._eval_terms(6) == 1 + x + x**2/2 - x**4/8 - x**5/15 + assert fcomp.truncate() == 1 + x + x**2/2 - x**4/8 - x**5/15 + O(x**6) + assert fcomp.truncate(5) == 1 + x + x**2/2 - x**4/8 + O(x**5) + + raises(NotImplementedError, lambda: fcomp._eval_term(5)) + raises(NotImplementedError, lambda: fcomp.infinite) + raises(NotImplementedError, lambda: fcomp._eval_derivative(x)) + raises(NotImplementedError, lambda: fcomp.integrate(x)) + + assert f1.compose(f2, x).truncate(4) == 1 + x + x**2/2 + O(x**4) + assert f1.compose(f2, x).truncate(8) == \ + 1 + x + x**2/2 - x**4/8 - x**5/15 - x**6/240 + x**7/90 + O(x**8) + assert f1.compose(f2, x).truncate(6) == \ + 1 + x + x**2/2 - x**4/8 - x**5/15 + O(x**6) + + assert f2.compose(f2, x).truncate(4) == x - x**3/3 + O(x**4) + assert f2.compose(f2, x).truncate(8) == x - x**3/3 + x**5/10 - 8*x**7/315 + O(x**8) + assert f2.compose(f2, x).truncate(6) == x - x**3/3 + x**5/10 + O(x**6) + + +def test_fps__inverse(): + f1, f2, f3 = fps(sin(x)), fps(exp(x)), fps(cos(x)) + + raises(ValueError, lambda: f1.inverse(x)) + + finv = f2.inverse(x) + assert isinstance(finv, FormalPowerSeriesInverse) + assert isinstance(finv.ffps, FormalPowerSeries) + raises(ValueError, lambda: finv.gfps) + + assert finv.f == exp(x) + assert finv.function == exp(-x) + assert finv._eval_terms(5) == 1 - x + x**2/2 - x**3/6 + x**4/24 + assert finv.truncate() == 1 - x + x**2/2 - x**3/6 + x**4/24 - x**5/120 + O(x**6) + assert finv.truncate(5) == 1 - x + x**2/2 - x**3/6 + x**4/24 + O(x**5) + + raises(NotImplementedError, lambda: finv._eval_term(5)) + raises(ValueError, lambda: finv.g) + raises(NotImplementedError, lambda: finv.infinite) + raises(NotImplementedError, lambda: finv._eval_derivative(x)) + raises(NotImplementedError, lambda: finv.integrate(x)) + + assert f2.inverse(x).truncate(8) == \ + 1 - x + x**2/2 - x**3/6 + x**4/24 - x**5/120 + x**6/720 - x**7/5040 + O(x**8) + + assert f3.inverse(x).truncate() == 1 + x**2/2 + 5*x**4/24 + O(x**6) + assert f3.inverse(x).truncate(8) == 1 + x**2/2 + 5*x**4/24 + 61*x**6/720 + O(x**8) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_fourier.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_fourier.py new file mode 100644 index 0000000000000000000000000000000000000000..994f182088b09b038e0e1b3885fec1c27f69f2b0 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_fourier.py @@ -0,0 +1,165 @@ +from sympy.core.add import Add +from sympy.core.numbers import (Rational, oo, pi) +from sympy.core.singleton import S +from sympy.core.symbol import symbols +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (cos, sin, sinc, tan) +from sympy.series.fourier import fourier_series +from sympy.series.fourier import FourierSeries +from sympy.testing.pytest import raises +from functools import lru_cache + +x, y, z = symbols('x y z') + +# Don't declare these during import because they are slow +@lru_cache() +def _get_examples(): + fo = fourier_series(x, (x, -pi, pi)) + fe = fourier_series(x**2, (-pi, pi)) + fp = fourier_series(Piecewise((0, x < 0), (pi, True)), (x, -pi, pi)) + return fo, fe, fp + + +def test_FourierSeries(): + fo, fe, fp = _get_examples() + + assert fourier_series(1, (-pi, pi)) == 1 + assert (Piecewise((0, x < 0), (pi, True)). + fourier_series((x, -pi, pi)).truncate()) == fp.truncate() + assert isinstance(fo, FourierSeries) + assert fo.function == x + assert fo.x == x + assert fo.period == (-pi, pi) + + assert fo.term(3) == 2*sin(3*x) / 3 + assert fe.term(3) == -4*cos(3*x) / 9 + assert fp.term(3) == 2*sin(3*x) / 3 + + assert fo.as_leading_term(x) == 2*sin(x) + assert fe.as_leading_term(x) == pi**2 / 3 + assert fp.as_leading_term(x) == pi / 2 + + assert fo.truncate() == 2*sin(x) - sin(2*x) + (2*sin(3*x) / 3) + assert fe.truncate() == -4*cos(x) + cos(2*x) + pi**2 / 3 + assert fp.truncate() == 2*sin(x) + (2*sin(3*x) / 3) + pi / 2 + + fot = fo.truncate(n=None) + s = [0, 2*sin(x), -sin(2*x)] + for i, t in enumerate(fot): + if i == 3: + break + assert s[i] == t + + def _check_iter(f, i): + for ind, t in enumerate(f): + assert t == f[ind] # noqa: PLR1736 + if ind == i: + break + + _check_iter(fo, 3) + _check_iter(fe, 3) + _check_iter(fp, 3) + + assert fo.subs(x, x**2) == fo + + raises(ValueError, lambda: fourier_series(x, (0, 1, 2))) + raises(ValueError, lambda: fourier_series(x, (x, 0, oo))) + raises(ValueError, lambda: fourier_series(x*y, (0, oo))) + + +def test_FourierSeries_2(): + p = Piecewise((0, x < 0), (x, True)) + f = fourier_series(p, (x, -2, 2)) + + assert f.term(3) == (2*sin(3*pi*x / 2) / (3*pi) - + 4*cos(3*pi*x / 2) / (9*pi**2)) + assert f.truncate() == (2*sin(pi*x / 2) / pi - sin(pi*x) / pi - + 4*cos(pi*x / 2) / pi**2 + S.Half) + + +def test_square_wave(): + """Test if fourier_series approximates discontinuous function correctly.""" + square_wave = Piecewise((1, x < pi), (-1, True)) + s = fourier_series(square_wave, (x, 0, 2*pi)) + + assert s.truncate(3) == 4 / pi * sin(x) + 4 / (3 * pi) * sin(3 * x) + \ + 4 / (5 * pi) * sin(5 * x) + assert s.sigma_approximation(4) == 4 / pi * sin(x) * sinc(pi / 4) + \ + 4 / (3 * pi) * sin(3 * x) * sinc(3 * pi / 4) + + +def test_sawtooth_wave(): + s = fourier_series(x, (x, 0, pi)) + assert s.truncate(4) == \ + pi/2 - sin(2*x) - sin(4*x)/2 - sin(6*x)/3 + s = fourier_series(x, (x, 0, 1)) + assert s.truncate(4) == \ + S.Half - sin(2*pi*x)/pi - sin(4*pi*x)/(2*pi) - sin(6*pi*x)/(3*pi) + + +def test_FourierSeries__operations(): + fo, fe, fp = _get_examples() + + fes = fe.scale(-1).shift(pi**2) + assert fes.truncate() == 4*cos(x) - cos(2*x) + 2*pi**2 / 3 + + assert fp.shift(-pi/2).truncate() == (2*sin(x) + (2*sin(3*x) / 3) + + (2*sin(5*x) / 5)) + + fos = fo.scale(3) + assert fos.truncate() == 6*sin(x) - 3*sin(2*x) + 2*sin(3*x) + + fx = fe.scalex(2).shiftx(1) + assert fx.truncate() == -4*cos(2*x + 2) + cos(4*x + 4) + pi**2 / 3 + + fl = fe.scalex(3).shift(-pi).scalex(2).shiftx(1).scale(4) + assert fl.truncate() == (-16*cos(6*x + 6) + 4*cos(12*x + 12) - + 4*pi + 4*pi**2 / 3) + + raises(ValueError, lambda: fo.shift(x)) + raises(ValueError, lambda: fo.shiftx(sin(x))) + raises(ValueError, lambda: fo.scale(x*y)) + raises(ValueError, lambda: fo.scalex(x**2)) + + +def test_FourierSeries__neg(): + fo, fe, fp = _get_examples() + + assert (-fo).truncate() == -2*sin(x) + sin(2*x) - (2*sin(3*x) / 3) + assert (-fe).truncate() == +4*cos(x) - cos(2*x) - pi**2 / 3 + + +def test_FourierSeries__add__sub(): + fo, fe, fp = _get_examples() + + assert fo + fo == fo.scale(2) + assert fo - fo == 0 + assert -fe - fe == fe.scale(-2) + + assert (fo + fe).truncate() == 2*sin(x) - sin(2*x) - 4*cos(x) + cos(2*x) \ + + pi**2 / 3 + assert (fo - fe).truncate() == 2*sin(x) - sin(2*x) + 4*cos(x) - cos(2*x) \ + - pi**2 / 3 + + assert isinstance(fo + 1, Add) + + raises(ValueError, lambda: fo + fourier_series(x, (x, 0, 2))) + + +def test_FourierSeries_finite(): + + assert fourier_series(sin(x)).truncate(1) == sin(x) + # assert type(fourier_series(sin(x)*log(x))).truncate() == FourierSeries + # assert type(fourier_series(sin(x**2+6))).truncate() == FourierSeries + assert fourier_series(sin(x)*log(y)*exp(z),(x,pi,-pi)).truncate() == sin(x)*log(y)*exp(z) + assert fourier_series(sin(x)**6).truncate(oo) == -15*cos(2*x)/32 + 3*cos(4*x)/16 - cos(6*x)/32 \ + + Rational(5, 16) + assert fourier_series(sin(x) ** 6).truncate() == -15 * cos(2 * x) / 32 + 3 * cos(4 * x) / 16 \ + + Rational(5, 16) + assert fourier_series(sin(4*x+3) + cos(3*x+4)).truncate(oo) == -sin(4)*sin(3*x) + sin(4*x)*cos(3) \ + + cos(4)*cos(3*x) + sin(3)*cos(4*x) + assert fourier_series(sin(x)+cos(x)*tan(x)).truncate(oo) == 2*sin(x) + assert fourier_series(cos(pi*x), (x, -1, 1)).truncate(oo) == cos(pi*x) + assert fourier_series(cos(3*pi*x + 4) - sin(4*pi*x)*log(pi*y), (x, -1, 1)).truncate(oo) == -log(pi*y)*sin(4*pi*x)\ + - sin(4)*sin(3*pi*x) + cos(4)*cos(3*pi*x) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_gruntz.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_gruntz.py new file mode 100644 index 0000000000000000000000000000000000000000..4cae15297048bc52a69a3d9ca57a7614cfcdc61c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_gruntz.py @@ -0,0 +1,490 @@ +from sympy.core import EulerGamma +from sympy.core.function import Function +from sympy.core.numbers import (E, I, Integer, Rational, oo, pi) +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (acot, atan, cos, sin) +from sympy.functions.special.error_functions import (Ei, erf) +from sympy.functions.special.gamma_functions import (digamma, gamma, loggamma) +from sympy.functions.special.zeta_functions import zeta +from sympy.polys.polytools import cancel +from sympy.functions.elementary.hyperbolic import cosh, coth, sinh, tanh +from sympy.series.gruntz import compare, mrv, rewrite, mrv_leadterm, gruntz, \ + sign +from sympy.testing.pytest import XFAIL, raises, skip, slow + +""" +This test suite is testing the limit algorithm using the bottom up approach. +See the documentation in limits2.py. The algorithm itself is highly recursive +by nature, so "compare" is logically the lowest part of the algorithm, yet in +some sense it's the most complex part, because it needs to calculate a limit +to return the result. + +Nevertheless, the rest of the algorithm depends on compare working correctly. +""" + +x = Symbol('x', real=True) +m = Symbol('m', real=True) + + +runslow = False + + +def _sskip(): + if not runslow: + skip("slow") + + +@slow +def test_gruntz_evaluation(): + # Gruntz' thesis pp. 122 to 123 + # 8.1 + assert gruntz(exp(x)*(exp(1/x - exp(-x)) - exp(1/x)), x, oo) == -1 + # 8.2 + assert gruntz(exp(x)*(exp(1/x + exp(-x) + exp(-x**2)) + - exp(1/x - exp(-exp(x)))), x, oo) == 1 + # 8.3 + assert gruntz(exp(exp(x - exp(-x))/(1 - 1/x)) - exp(exp(x)), x, oo) is oo + # 8.5 + assert gruntz(exp(exp(exp(x + exp(-x)))) / exp(exp(exp(x))), x, oo) is oo + # 8.6 + assert gruntz(exp(exp(exp(x))) / exp(exp(exp(x - exp(-exp(x))))), + x, oo) is oo + # 8.7 + assert gruntz(exp(exp(exp(x))) / exp(exp(exp(x - exp(-exp(exp(x)))))), + x, oo) == 1 + # 8.8 + assert gruntz(exp(exp(x)) / exp(exp(x - exp(-exp(exp(x))))), x, oo) == 1 + # 8.9 + assert gruntz(log(x)**2 * exp(sqrt(log(x))*(log(log(x)))**2 + * exp(sqrt(log(log(x))) * (log(log(log(x))))**3)) / sqrt(x), + x, oo) == 0 + # 8.10 + assert gruntz((x*log(x)*(log(x*exp(x) - x**2))**2) + / (log(log(x**2 + 2*exp(exp(3*x**3*log(x)))))), x, oo) == Rational(1, 3) + # 8.11 + assert gruntz((exp(x*exp(-x)/(exp(-x) + exp(-2*x**2/(x + 1)))) - exp(x))/x, + x, oo) == -exp(2) + # 8.12 + assert gruntz((3**x + 5**x)**(1/x), x, oo) == 5 + # 8.13 + assert gruntz(x/log(x**(log(x**(log(2)/log(x))))), x, oo) is oo + # 8.14 + assert gruntz(exp(exp(2*log(x**5 + x)*log(log(x)))) + / exp(exp(10*log(x)*log(log(x)))), x, oo) is oo + # 8.15 + assert gruntz(exp(exp(Rational(5, 2)*x**Rational(-5, 7) + Rational(21, 8)*x**Rational(6, 11) + + 2*x**(-8) + Rational(54, 17)*x**Rational(49, 45)))**8 + / log(log(-log(Rational(4, 3)*x**Rational(-5, 14))))**Rational(7, 6), x, oo) is oo + # 8.16 + assert gruntz((exp(4*x*exp(-x)/(1/exp(x) + 1/exp(2*x**2/(x + 1)))) - exp(x)) + / exp(x)**4, x, oo) == 1 + # 8.17 + assert gruntz(exp(x*exp(-x)/(exp(-x) + exp(-2*x**2/(x + 1))))/exp(x), x, oo) \ + == 1 + # 8.19 + assert gruntz(log(x)*(log(log(x) + log(log(x))) - log(log(x))) + / (log(log(x) + log(log(log(x))))), x, oo) == 1 + # 8.20 + assert gruntz(exp((log(log(x + exp(log(x)*log(log(x)))))) + / (log(log(log(exp(x) + x + log(x)))))), x, oo) == E + # Another + assert gruntz(exp(exp(exp(x + exp(-x)))) / exp(exp(x)), x, oo) is oo + + +def test_gruntz_evaluation_slow(): + _sskip() + # 8.4 + assert gruntz(exp(exp(exp(x)/(1 - 1/x))) + - exp(exp(exp(x)/(1 - 1/x - log(x)**(-log(x))))), x, oo) is -oo + # 8.18 + assert gruntz((exp(exp(-x/(1 + exp(-x))))*exp(-x/(1 + exp(-x/(1 + exp(-x))))) + *exp(exp(-x + exp(-x/(1 + exp(-x)))))) + / (exp(-x/(1 + exp(-x))))**2 - exp(x) + x, x, oo) == 2 + + +@slow +def test_gruntz_eval_special(): + # Gruntz, p. 126 + assert gruntz(exp(x)*(sin(1/x + exp(-x)) - sin(1/x + exp(-x**2))), x, oo) == 1 + assert gruntz((erf(x - exp(-exp(x))) - erf(x)) * exp(exp(x)) * exp(x**2), + x, oo) == -2/sqrt(pi) + assert gruntz(exp(exp(x)) * (exp(sin(1/x + exp(-exp(x)))) - exp(sin(1/x))), + x, oo) == 1 + assert gruntz(exp(x)*(gamma(x + exp(-x)) - gamma(x)), x, oo) is oo + assert gruntz(exp(exp(digamma(digamma(x))))/x, x, oo) == exp(Rational(-1, 2)) + assert gruntz(exp(exp(digamma(log(x))))/x, x, oo) == exp(Rational(-1, 2)) + assert gruntz(digamma(digamma(digamma(x))), x, oo) is oo + assert gruntz(loggamma(loggamma(x)), x, oo) is oo + assert gruntz(((gamma(x + 1/gamma(x)) - gamma(x))/log(x) - cos(1/x)) + * x*log(x), x, oo) == Rational(-1, 2) + assert gruntz(x * (gamma(x - 1/gamma(x)) - gamma(x) + log(x)), x, oo) \ + == S.Half + assert gruntz((gamma(x + 1/gamma(x)) - gamma(x)) / log(x), x, oo) == 1 + + +def test_gruntz_eval_special_slow(): + _sskip() + assert gruntz(gamma(x + 1)/sqrt(2*pi) + - exp(-x)*(x**(x + S.Half) + x**(x - S.Half)/12), x, oo) is oo + assert gruntz(exp(exp(exp(digamma(digamma(digamma(x))))))/x, x, oo) == 0 + + +@XFAIL +def test_grunts_eval_special_slow_sometimes_fail(): + _sskip() + # XXX This sometimes fails!!! + assert gruntz(exp(gamma(x - exp(-x))*exp(1/x)) - exp(gamma(x)), x, oo) is oo + + +def test_gruntz_Ei(): + assert gruntz((Ei(x - exp(-exp(x))) - Ei(x)) *exp(-x)*exp(exp(x))*x, x, oo) == -1 + + +@XFAIL +def test_gruntz_eval_special_fail(): + # TODO zeta function series + assert gruntz( + exp((log(2) + 1)*x) * (zeta(x + exp(-x)) - zeta(x)), x, oo) == -log(2) + + # TODO 8.35 - 8.37 (bessel, max-min) + + +def test_gruntz_hyperbolic(): + assert gruntz(cosh(x), x, oo) is oo + assert gruntz(cosh(x), x, -oo) is oo + assert gruntz(sinh(x), x, oo) is oo + assert gruntz(sinh(x), x, -oo) is -oo + assert gruntz(2*cosh(x)*exp(x), x, oo) is oo + assert gruntz(2*cosh(x)*exp(x), x, -oo) == 1 + assert gruntz(2*sinh(x)*exp(x), x, oo) is oo + assert gruntz(2*sinh(x)*exp(x), x, -oo) == -1 + assert gruntz(tanh(x), x, oo) == 1 + assert gruntz(tanh(x), x, -oo) == -1 + assert gruntz(coth(x), x, oo) == 1 + assert gruntz(coth(x), x, -oo) == -1 + + +def test_compare1(): + assert compare(2, x, x) == "<" + assert compare(x, exp(x), x) == "<" + assert compare(exp(x), exp(x**2), x) == "<" + assert compare(exp(x**2), exp(exp(x)), x) == "<" + assert compare(1, exp(exp(x)), x) == "<" + + assert compare(x, 2, x) == ">" + assert compare(exp(x), x, x) == ">" + assert compare(exp(x**2), exp(x), x) == ">" + assert compare(exp(exp(x)), exp(x**2), x) == ">" + assert compare(exp(exp(x)), 1, x) == ">" + + assert compare(2, 3, x) == "=" + assert compare(3, -5, x) == "=" + assert compare(2, -5, x) == "=" + + assert compare(x, x**2, x) == "=" + assert compare(x**2, x**3, x) == "=" + assert compare(x**3, 1/x, x) == "=" + assert compare(1/x, x**m, x) == "=" + assert compare(x**m, -x, x) == "=" + + assert compare(exp(x), exp(-x), x) == "=" + assert compare(exp(-x), exp(2*x), x) == "=" + assert compare(exp(2*x), exp(x)**2, x) == "=" + assert compare(exp(x)**2, exp(x + exp(-x)), x) == "=" + assert compare(exp(x), exp(x + exp(-x)), x) == "=" + + assert compare(exp(x**2), 1/exp(x**2), x) == "=" + + +def test_compare2(): + assert compare(exp(x), x**5, x) == ">" + assert compare(exp(x**2), exp(x)**2, x) == ">" + assert compare(exp(x), exp(x + exp(-x)), x) == "=" + assert compare(exp(x + exp(-x)), exp(x), x) == "=" + assert compare(exp(x + exp(-x)), exp(-x), x) == "=" + assert compare(exp(-x), x, x) == ">" + assert compare(x, exp(-x), x) == "<" + assert compare(exp(x + 1/x), x, x) == ">" + assert compare(exp(-exp(x)), exp(x), x) == ">" + assert compare(exp(exp(-exp(x)) + x), exp(-exp(x)), x) == "<" + + +def test_compare3(): + assert compare(exp(exp(x)), exp(x + exp(-exp(x))), x) == ">" + + +def test_sign1(): + assert sign(Rational(0), x) == 0 + assert sign(Rational(3), x) == 1 + assert sign(Rational(-5), x) == -1 + assert sign(log(x), x) == 1 + assert sign(exp(-x), x) == 1 + assert sign(exp(x), x) == 1 + assert sign(-exp(x), x) == -1 + assert sign(3 - 1/x, x) == 1 + assert sign(-3 - 1/x, x) == -1 + assert sign(sin(1/x), x) == 1 + assert sign((x**Integer(2)), x) == 1 + assert sign(x**2, x) == 1 + assert sign(x**5, x) == 1 + + +def test_sign2(): + assert sign(x, x) == 1 + assert sign(-x, x) == -1 + y = Symbol("y", positive=True) + assert sign(y, x) == 1 + assert sign(-y, x) == -1 + assert sign(y*x, x) == 1 + assert sign(-y*x, x) == -1 + + +def mmrv(a, b): + return set(mrv(a, b)[0].keys()) + + +def test_mrv1(): + assert mmrv(x, x) == {x} + assert mmrv(x + 1/x, x) == {x} + assert mmrv(x**2, x) == {x} + assert mmrv(log(x), x) == {x} + assert mmrv(exp(x), x) == {exp(x)} + assert mmrv(exp(-x), x) == {exp(-x)} + assert mmrv(exp(x**2), x) == {exp(x**2)} + assert mmrv(-exp(1/x), x) == {x} + assert mmrv(exp(x + 1/x), x) == {exp(x + 1/x)} + + +def test_mrv2a(): + assert mmrv(exp(x + exp(-exp(x))), x) == {exp(-exp(x))} + assert mmrv(exp(x + exp(-x)), x) == {exp(x + exp(-x)), exp(-x)} + assert mmrv(exp(1/x + exp(-x)), x) == {exp(-x)} + +#sometimes infinite recursion due to log(exp(x**2)) not simplifying + + +def test_mrv2b(): + assert mmrv(exp(x + exp(-x**2)), x) == {exp(-x**2)} + +#sometimes infinite recursion due to log(exp(x**2)) not simplifying + + +def test_mrv2c(): + assert mmrv( + exp(-x + 1/x**2) - exp(x + 1/x), x) == {exp(x + 1/x), exp(1/x**2 - x)} + +#sometimes infinite recursion due to log(exp(x**2)) not simplifying + + +def test_mrv3(): + assert mmrv(exp(x**2) + x*exp(x) + log(x)**x/x, x) == {exp(x**2)} + assert mmrv( + exp(x)*(exp(1/x + exp(-x)) - exp(1/x)), x) == {exp(x), exp(-x)} + assert mmrv(log( + x**2 + 2*exp(exp(3*x**3*log(x)))), x) == {exp(exp(3*x**3*log(x)))} + assert mmrv(log(x - log(x))/log(x), x) == {x} + assert mmrv( + (exp(1/x - exp(-x)) - exp(1/x))*exp(x), x) == {exp(x), exp(-x)} + assert mmrv( + 1/exp(-x + exp(-x)) - exp(x), x) == {exp(x), exp(-x), exp(x - exp(-x))} + assert mmrv(log(log(x*exp(x*exp(x)) + 1)), x) == {exp(x*exp(x))} + assert mmrv(exp(exp(log(log(x) + 1/x))), x) == {x} + + +def test_mrv4(): + ln = log + assert mmrv((ln(ln(x) + ln(ln(x))) - ln(ln(x)))/ln(ln(x) + ln(ln(ln(x))))*ln(x), + x) == {x} + assert mmrv(log(log(x*exp(x*exp(x)) + 1)) - exp(exp(log(log(x) + 1/x))), x) == \ + {exp(x*exp(x))} + + +def mrewrite(a, b, c): + return rewrite(a[1], a[0], b, c) + + +def test_rewrite1(): + e = exp(x) + assert mrewrite(mrv(e, x), x, m) == (1/m, -x) + e = exp(x**2) + assert mrewrite(mrv(e, x), x, m) == (1/m, -x**2) + e = exp(x + 1/x) + assert mrewrite(mrv(e, x), x, m) == (1/m, -x - 1/x) + e = 1/exp(-x + exp(-x)) - exp(x) + assert mrewrite(mrv(e, x), x, m) == ((-m*exp(m) + m)*exp(-m)/m**2, -x) + + +def test_rewrite2(): + e = exp(x)*log(log(exp(x))) + assert mmrv(e, x) == {exp(x)} + assert mrewrite(mrv(e, x), x, m) == (1/m*log(x), -x) + +#sometimes infinite recursion due to log(exp(x**2)) not simplifying + + +def test_rewrite3(): + e = exp(-x + 1/x**2) - exp(x + 1/x) + #both of these are correct and should be equivalent: + assert mrewrite(mrv(e, x), x, m) in [(-1/m + m*exp( + (x**2 + x)/x**3), -x - 1/x), ((m**2 - exp((x**2 + x)/x**3))/m, x**(-2) - x)] + + +def test_mrv_leadterm1(): + assert mrv_leadterm(-exp(1/x), x) == (-1, 0) + assert mrv_leadterm(1/exp(-x + exp(-x)) - exp(x), x) == (-1, 0) + assert mrv_leadterm( + (exp(1/x - exp(-x)) - exp(1/x))*exp(x), x) == (-exp(1/x), 0) + + +def test_mrv_leadterm2(): + #Gruntz: p51, 3.25 + assert mrv_leadterm((log(exp(x) + x) - x)/log(exp(x) + log(x))*exp(x), x) == \ + (1, 0) + + +def test_mrv_leadterm3(): + #Gruntz: p56, 3.27 + assert mmrv(exp(-x + exp(-x)*exp(-x*log(x))), x) == {exp(-x - x*log(x))} + assert mrv_leadterm(exp(-x + exp(-x)*exp(-x*log(x))), x) == (exp(-x), 0) + + +def test_limit1(): + assert gruntz(x, x, oo) is oo + assert gruntz(x, x, -oo) is -oo + assert gruntz(-x, x, oo) is -oo + assert gruntz(x**2, x, -oo) is oo + assert gruntz(-x**2, x, oo) is -oo + assert gruntz(x*log(x), x, 0, dir="+") == 0 + assert gruntz(1/x, x, oo) == 0 + assert gruntz(exp(x), x, oo) is oo + assert gruntz(-exp(x), x, oo) is -oo + assert gruntz(exp(x)/x, x, oo) is oo + assert gruntz(1/x - exp(-x), x, oo) == 0 + assert gruntz(x + 1/x, x, oo) is oo + + +def test_limit2(): + assert gruntz(x**x, x, 0, dir="+") == 1 + assert gruntz((exp(x) - 1)/x, x, 0) == 1 + assert gruntz(1 + 1/x, x, oo) == 1 + assert gruntz(-exp(1/x), x, oo) == -1 + assert gruntz(x + exp(-x), x, oo) is oo + assert gruntz(x + exp(-x**2), x, oo) is oo + assert gruntz(x + exp(-exp(x)), x, oo) is oo + assert gruntz(13 + 1/x - exp(-x), x, oo) == 13 + + +def test_limit3(): + a = Symbol('a') + assert gruntz(x - log(1 + exp(x)), x, oo) == 0 + assert gruntz(x - log(a + exp(x)), x, oo) == 0 + assert gruntz(exp(x)/(1 + exp(x)), x, oo) == 1 + assert gruntz(exp(x)/(a + exp(x)), x, oo) == 1 + + +def test_limit4(): + #issue 3463 + assert gruntz((3**x + 5**x)**(1/x), x, oo) == 5 + #issue 3463 + assert gruntz((3**(1/x) + 5**(1/x))**x, x, 0) == 5 + + +@XFAIL +def test_MrvTestCase_page47_ex3_21(): + h = exp(-x/(1 + exp(-x))) + expr = exp(h)*exp(-x/(1 + h))*exp(exp(-x + h))/h**2 - exp(x) + x + assert mmrv(expr, x) == {1/h, exp(-x), exp(x), exp(x - h), exp(x/(1 + h))} + + +def test_gruntz_I(): + y = Symbol("y") + assert gruntz(I*x, x, oo) == I*oo + assert gruntz(y*I*x, x, oo) == y*I*oo + assert gruntz(y*3*I*x, x, oo) == y*I*oo + assert gruntz(y*3*sin(I)*x, x, oo) == y*I*oo + + +def test_issue_4814(): + assert gruntz((x + 1)**(1/log(x + 1)), x, oo) == E + + +def test_intractable(): + assert gruntz(1/gamma(x), x, oo) == 0 + assert gruntz(1/loggamma(x), x, oo) == 0 + assert gruntz(gamma(x)/loggamma(x), x, oo) is oo + assert gruntz(exp(gamma(x))/gamma(x), x, oo) is oo + assert gruntz(gamma(x), x, 3) == 2 + assert gruntz(gamma(Rational(1, 7) + 1/x), x, oo) == gamma(Rational(1, 7)) + assert gruntz(log(x**x)/log(gamma(x)), x, oo) == 1 + assert gruntz(log(gamma(gamma(x)))/exp(x), x, oo) is oo + + +def test_aseries_trig(): + assert cancel(gruntz(1/log(atan(x)), x, oo) + - 1/(log(pi) + log(S.Half))) == 0 + assert gruntz(1/acot(x), x, -oo) is -oo + + +def test_exp_log_series(): + assert gruntz(x/log(log(x*exp(x))), x, oo) is oo + + +def test_issue_3644(): + assert gruntz(((x**7 + x + 1)/(2**x + x**2))**(-1/x), x, oo) == 2 + + +def test_issue_6843(): + n = Symbol('n', integer=True, positive=True) + r = (n + 1)*x**(n + 1)/(x**(n + 1) - 1) - x/(x - 1) + assert gruntz(r, x, 1).simplify() == n/2 + + +def test_issue_4190(): + assert gruntz(x - gamma(1/x), x, oo) == S.EulerGamma + + +@XFAIL +def test_issue_5172(): + n = Symbol('n') + r = Symbol('r', positive=True) + c = Symbol('c') + p = Symbol('p', positive=True) + m = Symbol('m', negative=True) + expr = ((2*n*(n - r + 1)/(n + r*(n - r + 1)))**c + \ + (r - 1)*(n*(n - r + 2)/(n + r*(n - r + 1)))**c - n)/(n**c - n) + expr = expr.subs(c, c + 1) + assert gruntz(expr.subs(c, m), n, oo) == 1 + # fail: + assert gruntz(expr.subs(c, p), n, oo).simplify() == \ + (2**(p + 1) + r - 1)/(r + 1)**(p + 1) + + +def test_issue_4109(): + assert gruntz(1/gamma(x), x, 0) == 0 + assert gruntz(x*gamma(x), x, 0) == 1 + + +def test_issue_6682(): + assert gruntz(exp(2*Ei(-x))/x**2, x, 0) == exp(2*EulerGamma) + + +def test_issue_7096(): + from sympy.functions import sign + assert gruntz(x**-pi, x, 0, dir='-') == oo*sign((-1)**(-pi)) + + +def test_issue_7391_8166(): + f = Function('f') + # limit should depend on the continuity of the expression at the point passed + raises(ValueError, lambda: gruntz(f(x), x, 4)) + raises(ValueError, lambda: gruntz(x*f(x)**2/(x**2 + f(x)**4), x, 0)) + + +def test_issue_24210_25885(): + eq = exp(x)/(1+1/x)**x**2 + ans = sqrt(E) + assert gruntz(eq, x, oo) == ans + assert gruntz(1/eq, x, oo) == 1/ans diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_kauers.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_kauers.py new file mode 100644 index 0000000000000000000000000000000000000000..bfb9044b33416bc38879649b258150ba2906250c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_kauers.py @@ -0,0 +1,23 @@ +from sympy.series.kauers import finite_diff +from sympy.series.kauers import finite_diff_kauers +from sympy.abc import x, y, z, m, n, w +from sympy.core.numbers import pi +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.concrete.summations import Sum + + +def test_finite_diff(): + assert finite_diff(x**2 + 2*x + 1, x) == 2*x + 3 + assert finite_diff(y**3 + 2*y**2 + 3*y + 5, y) == 3*y**2 + 7*y + 6 + assert finite_diff(z**2 - 2*z + 3, z) == 2*z - 1 + assert finite_diff(w**2 + 3*w - 2, w) == 2*w + 4 + assert finite_diff(sin(x), x, pi/6) == -sin(x) + sin(x + pi/6) + assert finite_diff(cos(y), y, pi/3) == -cos(y) + cos(y + pi/3) + assert finite_diff(x**2 - 2*x + 3, x, 2) == 4*x + assert finite_diff(n**2 - 2*n + 3, n, 3) == 6*n + 3 + +def test_finite_diff_kauers(): + assert finite_diff_kauers(Sum(x**2, (x, 1, n))) == (n + 1)**2 + assert finite_diff_kauers(Sum(y, (y, 1, m))) == (m + 1) + assert finite_diff_kauers(Sum((x*y), (x, 1, m), (y, 1, n))) == (m + 1)*(n + 1) + assert finite_diff_kauers(Sum((x*y**2), (x, 1, m), (y, 1, n))) == (n + 1)**2*(m + 1) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_limits.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_limits.py new file mode 100644 index 0000000000000000000000000000000000000000..aa3ab7683f057424f1c3215a06381d27687710dc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_limits.py @@ -0,0 +1,1440 @@ +from itertools import product + +from sympy.concrete.summations import Sum +from sympy.core.function import (Function, diff) +from sympy.core import EulerGamma, GoldenRatio +from sympy.core.mod import Mod +from sympy.core.numbers import (E, I, Rational, oo, pi, zoo) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.combinatorial.numbers import fibonacci +from sympy.functions.combinatorial.factorials import (binomial, factorial, subfactorial) +from sympy.functions.elementary.complexes import (Abs, re, sign) +from sympy.functions.elementary.exponential import (LambertW, exp, log) +from sympy.functions.elementary.hyperbolic import (atanh, asinh, acosh, acoth, acsch, asech, tanh, sinh) +from sympy.functions.elementary.integers import (ceiling, floor, frac) +from sympy.functions.elementary.miscellaneous import (cbrt, real_root, sqrt) +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (acos, acot, acsc, asec, asin, + atan, cos, cot, csc, sec, sin, tan) +from sympy.functions.special.bessel import (besseli, bessely, besselj, besselk) +from sympy.functions.special.error_functions import (Ei, erf, erfc, erfi, fresnelc, fresnels) +from sympy.functions.special.gamma_functions import (digamma, gamma, uppergamma) +from sympy.functions.special.hyper import meijerg +from sympy.integrals.integrals import (Integral, integrate) +from sympy.series.limits import (Limit, limit) +from sympy.simplify.simplify import (logcombine, simplify) +from sympy.simplify.hyperexpand import hyperexpand + +from sympy.calculus.accumulationbounds import AccumBounds +from sympy.core.mul import Mul +from sympy.series.limits import heuristics +from sympy.series.order import Order +from sympy.testing.pytest import XFAIL, raises + +from sympy import elliptic_e, elliptic_k + +from sympy.abc import x, y, z, k +n = Symbol('n', integer=True, positive=True) + + +def test_basic1(): + assert limit(x, x, oo) is oo + assert limit(x, x, -oo) is -oo + assert limit(-x, x, oo) is -oo + assert limit(x**2, x, -oo) is oo + assert limit(-x**2, x, oo) is -oo + assert limit(x*log(x), x, 0, dir="+") == 0 + assert limit(1/x, x, oo) == 0 + assert limit(exp(x), x, oo) is oo + assert limit(-exp(x), x, oo) is -oo + assert limit(exp(x)/x, x, oo) is oo + assert limit(1/x - exp(-x), x, oo) == 0 + assert limit(x + 1/x, x, oo) is oo + assert limit(x - x**2, x, oo) is -oo + assert limit((1 + x)**(1 + sqrt(2)), x, 0) == 1 + assert limit((1 + x)**oo, x, 0) == Limit((x + 1)**oo, x, 0) + assert limit((1 + x)**oo, x, 0, dir='-') == Limit((x + 1)**oo, x, 0, dir='-') + assert limit((1 + x + y)**oo, x, 0, dir='-') == Limit((1 + x + y)**oo, x, 0, dir='-') + assert limit(y/x/log(x), x, 0) == -oo*sign(y) + assert limit(cos(x + y)/x, x, 0) == sign(cos(y))*oo + assert limit(gamma(1/x + 3), x, oo) == 2 + assert limit(S.NaN, x, -oo) is S.NaN + assert limit(Order(2)*x, x, S.NaN) is S.NaN + assert limit(1/(x - 1), x, 1, dir="+") is oo + assert limit(1/(x - 1), x, 1, dir="-") is -oo + assert limit(1/(5 - x)**3, x, 5, dir="+") is -oo + assert limit(1/(5 - x)**3, x, 5, dir="-") is oo + assert limit(1/sin(x), x, pi, dir="+") is -oo + assert limit(1/sin(x), x, pi, dir="-") is oo + assert limit(1/cos(x), x, pi/2, dir="+") is -oo + assert limit(1/cos(x), x, pi/2, dir="-") is oo + assert limit(1/tan(x**3), x, (2*pi)**Rational(1, 3), dir="+") is oo + assert limit(1/tan(x**3), x, (2*pi)**Rational(1, 3), dir="-") is -oo + assert limit(1/cot(x)**3, x, (pi*Rational(3, 2)), dir="+") is -oo + assert limit(1/cot(x)**3, x, (pi*Rational(3, 2)), dir="-") is oo + assert limit(tan(x), x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + assert limit(cot(x), x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + assert limit(sec(x), x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + assert limit(csc(x), x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + + # test bi-directional limits + assert limit(sin(x)/x, x, 0, dir="+-") == 1 + assert limit(x**2, x, 0, dir="+-") == 0 + assert limit(1/x**2, x, 0, dir="+-") is oo + + # test failing bi-directional limits + assert limit(1/x, x, 0, dir="+-") is zoo + # approaching 0 + # from dir="+" + assert limit(1 + 1/x, x, 0) is oo + # from dir='-' + # Add + assert limit(1 + 1/x, x, 0, dir='-') is -oo + # Pow + assert limit(x**(-2), x, 0, dir='-') is oo + assert limit(x**(-3), x, 0, dir='-') is -oo + assert limit(1/sqrt(x), x, 0, dir='-') == (-oo)*I + assert limit(x**2, x, 0, dir='-') == 0 + assert limit(sqrt(x), x, 0, dir='-') == 0 + assert limit(x**-pi, x, 0, dir='-') == -oo*(-1)**(1 - pi) + assert limit((1 + cos(x))**oo, x, 0) == Limit((cos(x) + 1)**oo, x, 0) + + # test pull request 22491 + assert limit(1/asin(x), x, 0, dir = '+') == oo + assert limit(1/asin(x), x, 0, dir = '-') == -oo + assert limit(1/sinh(x), x, 0, dir = '+') == oo + assert limit(1/sinh(x), x, 0, dir = '-') == -oo + assert limit(log(1/x) + 1/sin(x), x, 0, dir = '+') == oo + assert limit(log(1/x) + 1/x, x, 0, dir = '+') == oo + + +def test_basic2(): + assert limit(x**x, x, 0, dir="+") == 1 + assert limit((exp(x) - 1)/x, x, 0) == 1 + assert limit(1 + 1/x, x, oo) == 1 + assert limit(-exp(1/x), x, oo) == -1 + assert limit(x + exp(-x), x, oo) is oo + assert limit(x + exp(-x**2), x, oo) is oo + assert limit(x + exp(-exp(x)), x, oo) is oo + assert limit(13 + 1/x - exp(-x), x, oo) == 13 + + +def test_basic3(): + assert limit(1/x, x, 0, dir="+") is oo + assert limit(1/x, x, 0, dir="-") is -oo + + +def test_basic4(): + assert limit(2*x + y*x, x, 0) == 0 + assert limit(2*x + y*x, x, 1) == 2 + y + assert limit(2*x**8 + y*x**(-3), x, -2) == 512 - y/8 + assert limit(sqrt(x + 1) - sqrt(x), x, oo) == 0 + assert integrate(1/(x**3 + 1), (x, 0, oo)) == 2*pi*sqrt(3)/9 + + +def test_log(): + # https://github.com/sympy/sympy/issues/21598 + a, b, c = symbols('a b c', positive=True) + A = log(a/b) - (log(a) - log(b)) + assert A.limit(a, oo) == 0 + assert (A * c).limit(a, oo) == 0 + + tau, x = symbols('tau x', positive=True) + # The value of manualintegrate in the issue + expr = tau**2*((tau - 1)*(tau + 1)*log(x + 1)/(tau**2 + 1)**2 + 1/((tau**2\ + + 1)*(x + 1)) - (-2*tau*atan(x/tau) + (tau**2/2 - 1/2)*log(tau**2\ + + x**2))/(tau**2 + 1)**2) + assert limit(expr, x, oo) == pi*tau**3/(tau**2 + 1)**2 + + +def test_piecewise(): + # https://github.com/sympy/sympy/issues/18363 + assert limit((real_root(x - 6, 3) + 2)/(x + 2), x, -2, '+') == Rational(1, 12) + + +def test_piecewise2(): + func1 = 2*sqrt(x)*Piecewise(((4*x - 2)/Abs(sqrt(4 - 4*(2*x - 1)**2)), 4*x - 2\ + >= 0), ((2 - 4*x)/Abs(sqrt(4 - 4*(2*x - 1)**2)), True)) + func2 = Piecewise((x**2/2, x <= 0.5), (x/2 - 0.125, True)) + func3 = Piecewise(((x - 9) / 5, x < -1), ((x - 9) / 5, x > 4), (sqrt(Abs(x - 3)), True)) + assert limit(func1, x, 0) == 1 + assert limit(func2, x, 0) == 0 + assert limit(func3, x, -1) == 2 + + +def test_basic5(): + class my(Function): + @classmethod + def eval(cls, arg): + if arg is S.Infinity: + return S.NaN + assert limit(my(x), x, oo) == Limit(my(x), x, oo) + + +def test_issue_3885(): + assert limit(x*y + x*z, z, 2) == x*y + 2*x + + +def test_Limit(): + assert Limit(sin(x)/x, x, 0) != 1 + assert Limit(sin(x)/x, x, 0).doit() == 1 + assert Limit(x, x, 0, dir='+-').args == (x, x, 0, Symbol('+-')) + + +def test_floor(): + assert limit(floor(x), x, -2, "+") == -2 + assert limit(floor(x), x, -2, "-") == -3 + assert limit(floor(x), x, -1, "+") == -1 + assert limit(floor(x), x, -1, "-") == -2 + assert limit(floor(x), x, 0, "+") == 0 + assert limit(floor(x), x, 0, "-") == -1 + assert limit(floor(x), x, 1, "+") == 1 + assert limit(floor(x), x, 1, "-") == 0 + assert limit(floor(x), x, 2, "+") == 2 + assert limit(floor(x), x, 2, "-") == 1 + assert limit(floor(x), x, 248, "+") == 248 + assert limit(floor(x), x, 248, "-") == 247 + + # https://github.com/sympy/sympy/issues/14478 + assert limit(x*floor(3/x)/2, x, 0, '+') == Rational(3, 2) + assert limit(floor(x + 1/2) - floor(x), x, oo) == AccumBounds(-S.Half, S(3)/2) + + # test issue 9158 + assert limit(floor(atan(x)), x, oo) == 1 + assert limit(floor(atan(x)), x, -oo) == -2 + assert limit(ceiling(atan(x)), x, oo) == 2 + assert limit(ceiling(atan(x)), x, -oo) == -1 + + +def test_floor_requires_robust_assumptions(): + assert limit(floor(sin(x)), x, 0, "+") == 0 + assert limit(floor(sin(x)), x, 0, "-") == -1 + assert limit(floor(cos(x)), x, 0, "+") == 0 + assert limit(floor(cos(x)), x, 0, "-") == 0 + assert limit(floor(5 + sin(x)), x, 0, "+") == 5 + assert limit(floor(5 + sin(x)), x, 0, "-") == 4 + assert limit(floor(5 + cos(x)), x, 0, "+") == 5 + assert limit(floor(5 + cos(x)), x, 0, "-") == 5 + + +def test_ceiling(): + assert limit(ceiling(x), x, -2, "+") == -1 + assert limit(ceiling(x), x, -2, "-") == -2 + assert limit(ceiling(x), x, -1, "+") == 0 + assert limit(ceiling(x), x, -1, "-") == -1 + assert limit(ceiling(x), x, 0, "+") == 1 + assert limit(ceiling(x), x, 0, "-") == 0 + assert limit(ceiling(x), x, 1, "+") == 2 + assert limit(ceiling(x), x, 1, "-") == 1 + assert limit(ceiling(x), x, 2, "+") == 3 + assert limit(ceiling(x), x, 2, "-") == 2 + assert limit(ceiling(x), x, 248, "+") == 249 + assert limit(ceiling(x), x, 248, "-") == 248 + + # https://github.com/sympy/sympy/issues/14478 + assert limit(x*ceiling(3/x)/2, x, 0, '+') == Rational(3, 2) + assert limit(ceiling(x + 1/2) - ceiling(x), x, oo) == AccumBounds(-S.Half, S(3)/2) + + +def test_ceiling_requires_robust_assumptions(): + assert limit(ceiling(sin(x)), x, 0, "+") == 1 + assert limit(ceiling(sin(x)), x, 0, "-") == 0 + assert limit(ceiling(cos(x)), x, 0, "+") == 1 + assert limit(ceiling(cos(x)), x, 0, "-") == 1 + assert limit(ceiling(5 + sin(x)), x, 0, "+") == 6 + assert limit(ceiling(5 + sin(x)), x, 0, "-") == 5 + assert limit(ceiling(5 + cos(x)), x, 0, "+") == 6 + assert limit(ceiling(5 + cos(x)), x, 0, "-") == 6 + + +def test_frac(): + assert limit(frac(x), x, oo) == AccumBounds(0, 1) + assert limit(frac(x)**(1/x), x, oo) == AccumBounds(0, 1) + assert limit(frac(x)**(1/x), x, -oo) == AccumBounds(1, oo) + assert limit(frac(x)**x, x, oo) == AccumBounds(0, oo) # wolfram gives (0, 1) + assert limit(frac(sin(x)), x, 0, "+") == 0 + assert limit(frac(sin(x)), x, 0, "-") == 1 + assert limit(frac(cos(x)), x, 0, "+-") == 1 + assert limit(frac(x**2), x, 0, "+-") == 0 + raises(ValueError, lambda: limit(frac(x), x, 0, '+-')) + assert limit(frac(-2*x + 1), x, 0, "+") == 1 + assert limit(frac(-2*x + 1), x, 0, "-") == 0 + assert limit(frac(x + S.Half), x, 0, "+-") == S(1)/2 + assert limit(frac(1/x), x, 0) == AccumBounds(0, 1) + + +def test_issue_14355(): + assert limit(floor(sin(x)/x), x, 0, '+') == 0 + assert limit(floor(sin(x)/x), x, 0, '-') == 0 + # test comment https://github.com/sympy/sympy/issues/14355#issuecomment-372121314 + assert limit(floor(-tan(x)/x), x, 0, '+') == -2 + assert limit(floor(-tan(x)/x), x, 0, '-') == -2 + + +def test_atan(): + x = Symbol("x", real=True) + assert limit(atan(x)*sin(1/x), x, 0) == 0 + assert limit(atan(x) + sqrt(x + 1) - sqrt(x), x, oo) == pi/2 + + +def test_set_signs(): + assert limit(abs(x), x, 0) == 0 + assert limit(abs(sin(x)), x, 0) == 0 + assert limit(abs(cos(x)), x, 0) == 1 + assert limit(abs(sin(x + 1)), x, 0) == sin(1) + + # https://github.com/sympy/sympy/issues/9449 + assert limit((Abs(x + y) - Abs(x - y))/(2*x), x, 0) == sign(y) + + # https://github.com/sympy/sympy/issues/12398 + assert limit(Abs(log(x)/x**3), x, oo) == 0 + assert limit(x*(Abs(log(x)/x**3)/Abs(log(x + 1)/(x + 1)**3) - 1), x, oo) == 3 + + # https://github.com/sympy/sympy/issues/18501 + assert limit(Abs(log(x - 1)**3 - 1), x, 1, '+') == oo + + # https://github.com/sympy/sympy/issues/18997 + assert limit(Abs(log(x)), x, 0) == oo + assert limit(Abs(log(Abs(x))), x, 0) == oo + + # https://github.com/sympy/sympy/issues/19026 + z = Symbol('z', positive=True) + assert limit(Abs(log(z) + 1)/log(z), z, oo) == 1 + + # https://github.com/sympy/sympy/issues/20704 + assert limit(z*(Abs(1/z + y) - Abs(y - 1/z))/2, z, 0) == 0 + + # https://github.com/sympy/sympy/issues/21606 + assert limit(cos(z)/sign(z), z, pi, '-') == -1 + + +def test_heuristic(): + x = Symbol("x", real=True) + assert heuristics(sin(1/x) + atan(x), x, 0, '+') == AccumBounds(-1, 1) + assert limit(log(2 + sqrt(atan(x))*sqrt(sin(1/x))), x, 0) == log(2) + + +def test_issue_3871(): + z = Symbol("z", positive=True) + f = -1/z*exp(-z*x) + assert limit(f, x, oo) == 0 + assert f.limit(x, oo) == 0 + + +def test_exponential(): + n = Symbol('n') + x = Symbol('x', real=True) + assert limit((1 + x/n)**n, n, oo) == exp(x) + assert limit((1 + x/(2*n))**n, n, oo) == exp(x/2) + assert limit((1 + x/(2*n + 1))**n, n, oo) == exp(x/2) + assert limit(((x - 1)/(x + 1))**x, x, oo) == exp(-2) + assert limit(1 + (1 + 1/x)**x, x, oo) == 1 + S.Exp1 + assert limit((2 + 6*x)**x/(6*x)**x, x, oo) == exp(S('1/3')) + + +def test_exponential2(): + n = Symbol('n') + assert limit((1 + x/(n + sin(n)))**n, n, oo) == exp(x) + + +def test_doit(): + f = Integral(2 * x, x) + l = Limit(f, x, oo) + assert l.doit() is oo + + +def test_series_AccumBounds(): + assert limit(sin(k) - sin(k + 1), k, oo) == AccumBounds(-2, 2) + assert limit(cos(k) - cos(k + 1) + 1, k, oo) == AccumBounds(-1, 3) + + # not the exact bound + assert limit(sin(k) - sin(k)*cos(k), k, oo) == AccumBounds(-2, 2) + + # test for issue #9934 + lo = (-3 + cos(1))/2 + hi = (1 + cos(1))/2 + t1 = Mul(AccumBounds(lo, hi), 1/(-1 + cos(1)), evaluate=False) + assert limit(simplify(Sum(cos(n).rewrite(exp), (n, 0, k)).doit().rewrite(sin)), k, oo) == t1 + + t2 = Mul(AccumBounds(-1 + sin(1)/2, sin(1)/2 + 1), 1/(1 - cos(1))) + assert limit(simplify(Sum(sin(n).rewrite(exp), (n, 0, k)).doit().rewrite(sin)), k, oo) == t2 + + assert limit(((sin(x) + 1)/2)**x, x, oo) == AccumBounds(0, oo) # wolfram says 0 + + # https://github.com/sympy/sympy/issues/12312 + e = 2**(-x)*(sin(x) + 1)**x + assert limit(e, x, oo) == AccumBounds(0, oo) + + +def test_bessel_functions_at_infinity(): + # Pull Request 23844 implements limits for all bessel and modified bessel + # functions approaching infinity along any direction i.e. abs(z0) tends to oo + + assert limit(besselj(1, x), x, oo) == 0 + assert limit(besselj(1, x), x, -oo) == 0 + assert limit(besselj(1, x), x, I*oo) == oo*I + assert limit(besselj(1, x), x, -I*oo) == -oo*I + assert limit(bessely(1, x), x, oo) == 0 + assert limit(bessely(1, x), x, -oo) == 0 + assert limit(bessely(1, x), x, I*oo) == -oo + assert limit(bessely(1, x), x, -I*oo) == -oo + assert limit(besseli(1, x), x, oo) == oo + assert limit(besseli(1, x), x, -oo) == -oo + assert limit(besseli(1, x), x, I*oo) == 0 + assert limit(besseli(1, x), x, -I*oo) == 0 + assert limit(besselk(1, x), x, oo) == 0 + assert limit(besselk(1, x), x, -oo) == -oo*I + assert limit(besselk(1, x), x, I*oo) == 0 + assert limit(besselk(1, x), x, -I*oo) == 0 + + # test issue 14874 + assert limit(besselk(0, x), x, oo) == 0 + + +@XFAIL +def test_doit2(): + f = Integral(2 * x, x) + l = Limit(f, x, oo) + # limit() breaks on the contained Integral. + assert l.doit(deep=False) == l + + +def test_issue_2929(): + assert limit((x * exp(x))/(exp(x) - 1), x, -oo) == 0 + + +def test_issue_3792(): + assert limit((1 - cos(x))/x**2, x, S.Half) == 4 - 4*cos(S.Half) + assert limit(sin(sin(x + 1) + 1), x, 0) == sin(1 + sin(1)) + assert limit(abs(sin(x + 1) + 1), x, 0) == 1 + sin(1) + + +def test_issue_4090(): + assert limit(1/(x + 3), x, 2) == Rational(1, 5) + assert limit(1/(x + pi), x, 2) == S.One/(2 + pi) + assert limit(log(x)/(x**2 + 3), x, 2) == log(2)/7 + assert limit(log(x)/(x**2 + pi), x, 2) == log(2)/(4 + pi) + + +def test_issue_4547(): + assert limit(cot(x), x, 0, dir='+') is oo + assert limit(cot(x), x, pi/2, dir='+') == 0 + + +def test_issue_5164(): + assert limit(x**0.5, x, oo) == oo**0.5 is oo + assert limit(x**0.5, x, 16) == 4 # Should this be a float? + assert limit(x**0.5, x, 0) == 0 + assert limit(x**(-0.5), x, oo) == 0 + assert limit(x**(-0.5), x, 4) == S.Half # Should this be a float? + + +def test_issue_5383(): + func = (1.0 * 1 + 1.0 * x)**(1.0 * 1 / x) + assert limit(func, x, 0) == E + + +def test_issue_14793(): + expr = ((x + S(1)/2) * log(x) - x + log(2*pi)/2 - \ + log(factorial(x)) + S(1)/(12*x))*x**3 + assert limit(expr, x, oo) == S(1)/360 + + +def test_issue_5183(): + # using list(...) so py.test can recalculate values + tests = list(product([x, -x], + [-1, 1], + [2, 3, S.Half, Rational(2, 3)], + ['-', '+'])) + results = (oo, oo, -oo, oo, -oo*I, oo, -oo*(-1)**Rational(1, 3), oo, + 0, 0, 0, 0, 0, 0, 0, 0, + oo, oo, oo, -oo, oo, -oo*I, oo, -oo*(-1)**Rational(1, 3), + 0, 0, 0, 0, 0, 0, 0, 0) + assert len(tests) == len(results) + for i, (args, res) in enumerate(zip(tests, results)): + y, s, e, d = args + eq = y**(s*e) + try: + assert limit(eq, x, 0, dir=d) == res + except AssertionError: + if 0: # change to 1 if you want to see the failing tests + print() + print(i, res, eq, d, limit(eq, x, 0, dir=d)) + else: + assert None + + +def test_issue_5184(): + assert limit(sin(x)/x, x, oo) == 0 + assert limit(atan(x), x, oo) == pi/2 + assert limit(gamma(x), x, oo) is oo + assert limit(cos(x)/x, x, oo) == 0 + assert limit(gamma(x), x, S.Half) == sqrt(pi) + + r = Symbol('r', real=True) + assert limit(r*sin(1/r), r, 0) == 0 + + +def test_issue_5229(): + assert limit((1 + y)**(1/y) - S.Exp1, y, 0) == 0 + + +def test_issue_4546(): + # using list(...) so py.test can recalculate values + tests = list(product([cot, tan], + [-pi/2, 0, pi/2, pi, pi*Rational(3, 2)], + ['-', '+'])) + results = (0, 0, -oo, oo, 0, 0, -oo, oo, 0, 0, + oo, -oo, 0, 0, oo, -oo, 0, 0, oo, -oo) + assert len(tests) == len(results) + for i, (args, res) in enumerate(zip(tests, results)): + f, l, d = args + eq = f(x) + try: + assert limit(eq, x, l, dir=d) == res + except AssertionError: + if 0: # change to 1 if you want to see the failing tests + print() + print(i, res, eq, l, d, limit(eq, x, l, dir=d)) + else: + assert None + + +def test_issue_3934(): + assert limit((1 + x**log(3))**(1/x), x, 0) == 1 + assert limit((5**(1/x) + 3**(1/x))**x, x, 0) == 5 + + +def test_issue_5955(): + assert limit((x**16)/(1 + x**16), x, oo) == 1 + assert limit((x**100)/(1 + x**100), x, oo) == 1 + assert limit((x**1885)/(1 + x**1885), x, oo) == 1 + assert limit((x**1000/((x + 1)**1000 + exp(-x))), x, oo) == 1 + + +def test_newissue(): + assert limit(exp(1/sin(x))/exp(cot(x)), x, 0) == 1 + + +def test_extended_real_line(): + assert limit(x - oo, x, oo) == Limit(x - oo, x, oo) + assert limit(1/(x + sin(x)) - oo, x, 0) == Limit(1/(x + sin(x)) - oo, x, 0) + assert limit(oo/x, x, oo) == Limit(oo/x, x, oo) + assert limit(x - oo + 1/x, x, oo) == Limit(x - oo + 1/x, x, oo) + + +@XFAIL +def test_order_oo(): + x = Symbol('x', positive=True) + assert Order(x)*oo != Order(1, x) + assert limit(oo/(x**2 - 4), x, oo) is oo + + +def test_issue_5436(): + raises(NotImplementedError, lambda: limit(exp(x*y), x, oo)) + raises(NotImplementedError, lambda: limit(exp(-x*y), x, oo)) + + +def test_Limit_dir(): + raises(TypeError, lambda: Limit(x, x, 0, dir=0)) + raises(ValueError, lambda: Limit(x, x, 0, dir='0')) + + +def test_polynomial(): + assert limit((x + 1)**1000/((x + 1)**1000 + 1), x, oo) == 1 + assert limit((x + 1)**1000/((x + 1)**1000 + 1), x, -oo) == 1 + assert limit(x ** Rational(77, 3) / (1 + x ** Rational(77, 3)), x, oo) == 1 + assert limit(x ** 101.1 / (1 + x ** 101.1), x, oo) == 1 + + +def test_rational(): + assert limit(1/y - (1/(y + x) + x/(y + x)/y)/z, x, oo) == (z - 1)/(y*z) + assert limit(1/y - (1/(y + x) + x/(y + x)/y)/z, x, -oo) == (z - 1)/(y*z) + + +def test_issue_5740(): + assert limit(log(x)*z - log(2*x)*y, x, 0) == oo*sign(y - z) + + +def test_issue_6366(): + n = Symbol('n', integer=True, positive=True) + r = (n + 1)*x**(n + 1)/(x**(n + 1) - 1) - x/(x - 1) + assert limit(r, x, 1).cancel() == n/2 + + +def test_factorial(): + f = factorial(x) + assert limit(f, x, oo) is oo + assert limit(x/f, x, oo) == 0 + # see Stirling's approximation: + # https://en.wikipedia.org/wiki/Stirling's_approximation + assert limit(f/(sqrt(2*pi*x)*(x/E)**x), x, oo) == 1 + assert limit(f, x, -oo) == gamma(-oo) + + +def test_issue_6560(): + e = (5*x**3/4 - x*Rational(3, 4) + (y*(3*x**2/2 - S.Half) + + 35*x**4/8 - 15*x**2/4 + Rational(3, 8))/(2*(y + 1))) + assert limit(e, y, oo) == 5*x**3/4 + 3*x**2/4 - 3*x/4 - Rational(1, 4) + +@XFAIL +def test_issue_5172(): + n = Symbol('n') + r = Symbol('r', positive=True) + c = Symbol('c') + p = Symbol('p', positive=True) + m = Symbol('m', negative=True) + expr = ((2*n*(n - r + 1)/(n + r*(n - r + 1)))**c + + (r - 1)*(n*(n - r + 2)/(n + r*(n - r + 1)))**c - n)/(n**c - n) + expr = expr.subs(c, c + 1) + raises(NotImplementedError, lambda: limit(expr, n, oo)) + assert limit(expr.subs(c, m), n, oo) == 1 + assert limit(expr.subs(c, p), n, oo).simplify() == \ + (2**(p + 1) + r - 1)/(r + 1)**(p + 1) + + +def test_issue_7088(): + a = Symbol('a') + assert limit(sqrt(x/(x + a)), x, oo) == 1 + + +def test_branch_cuts(): + assert limit(asin(I*x + 2), x, 0) == pi - asin(2) + assert limit(asin(I*x + 2), x, 0, '-') == asin(2) + assert limit(asin(I*x - 2), x, 0) == -asin(2) + assert limit(asin(I*x - 2), x, 0, '-') == -pi + asin(2) + assert limit(acos(I*x + 2), x, 0) == -acos(2) + assert limit(acos(I*x + 2), x, 0, '-') == acos(2) + assert limit(acos(I*x - 2), x, 0) == acos(-2) + assert limit(acos(I*x - 2), x, 0, '-') == 2*pi - acos(-2) + assert limit(atan(x + 2*I), x, 0) == I*atanh(2) + assert limit(atan(x + 2*I), x, 0, '-') == -pi + I*atanh(2) + assert limit(atan(x - 2*I), x, 0) == pi - I*atanh(2) + assert limit(atan(x - 2*I), x, 0, '-') == -I*atanh(2) + assert limit(atan(1/x), x, 0) == pi/2 + assert limit(atan(1/x), x, 0, '-') == -pi/2 + assert limit(atan(x), x, oo) == pi/2 + assert limit(atan(x), x, -oo) == -pi/2 + assert limit(acot(x + S(1)/2*I), x, 0) == pi - I*acoth(S(1)/2) + assert limit(acot(x + S(1)/2*I), x, 0, '-') == -I*acoth(S(1)/2) + assert limit(acot(x - S(1)/2*I), x, 0) == I*acoth(S(1)/2) + assert limit(acot(x - S(1)/2*I), x, 0, '-') == -pi + I*acoth(S(1)/2) + assert limit(acot(x), x, 0) == pi/2 + assert limit(acot(x), x, 0, '-') == -pi/2 + assert limit(asec(I*x + S(1)/2), x, 0) == asec(S(1)/2) + assert limit(asec(I*x + S(1)/2), x, 0, '-') == -asec(S(1)/2) + assert limit(asec(I*x - S(1)/2), x, 0) == 2*pi - asec(-S(1)/2) + assert limit(asec(I*x - S(1)/2), x, 0, '-') == asec(-S(1)/2) + assert limit(acsc(I*x + S(1)/2), x, 0) == acsc(S(1)/2) + assert limit(acsc(I*x + S(1)/2), x, 0, '-') == pi - acsc(S(1)/2) + assert limit(acsc(I*x - S(1)/2), x, 0) == -pi + acsc(S(1)/2) + assert limit(acsc(I*x - S(1)/2), x, 0, '-') == -acsc(S(1)/2) + + assert limit(log(I*x - 1), x, 0) == I*pi + assert limit(log(I*x - 1), x, 0, '-') == -I*pi + assert limit(log(-I*x - 1), x, 0) == -I*pi + assert limit(log(-I*x - 1), x, 0, '-') == I*pi + + assert limit(sqrt(I*x - 1), x, 0) == I + assert limit(sqrt(I*x - 1), x, 0, '-') == -I + assert limit(sqrt(-I*x - 1), x, 0) == -I + assert limit(sqrt(-I*x - 1), x, 0, '-') == I + + assert limit(cbrt(I*x - 1), x, 0) == (-1)**(S(1)/3) + assert limit(cbrt(I*x - 1), x, 0, '-') == -(-1)**(S(2)/3) + assert limit(cbrt(-I*x - 1), x, 0) == -(-1)**(S(2)/3) + assert limit(cbrt(-I*x - 1), x, 0, '-') == (-1)**(S(1)/3) + + +def test_issue_6364(): + a = Symbol('a') + e = z/(1 - sqrt(1 + z)*sin(a)**2 - sqrt(1 - z)*cos(a)**2) + assert limit(e, z, 0) == 1/(cos(a)**2 - S.Half) + + +def test_issue_6682(): + assert limit(exp(2*Ei(-x))/x**2, x, 0) == exp(2*EulerGamma) + + +def test_issue_4099(): + a = Symbol('a') + assert limit(a/x, x, 0) == oo*sign(a) + assert limit(-a/x, x, 0) == -oo*sign(a) + assert limit(-a*x, x, oo) == -oo*sign(a) + assert limit(a*x, x, oo) == oo*sign(a) + + +def test_issue_4503(): + dx = Symbol('dx') + assert limit((sqrt(1 + exp(x + dx)) - sqrt(1 + exp(x)))/dx, dx, 0) == \ + exp(x)/(2*sqrt(exp(x) + 1)) + + +def test_issue_6052(): + G = meijerg((), (), (1,), (0,), -x) + g = hyperexpand(G) + assert limit(g, x, 0, '+-') == 0 + assert limit(g, x, oo) == -oo + + +def test_issue_7224(): + expr = sqrt(x)*besseli(1,sqrt(8*x)) + assert limit(x*diff(expr, x, x)/expr, x, 0) == 2 + assert limit(x*diff(expr, x, x)/expr, x, 1).evalf() == 2.0 + + +def test_issue_7391_8166(): + f = Function('f') + # limit should depend on the continuity of the expression at the point passed + assert limit(f(x), x, 4) == Limit(f(x), x, 4, dir='+') + assert limit(x*f(x)**2/(x**2 + f(x)**4), x, 0) == Limit(x*f(x)**2/(x**2 + f(x)**4), x, 0, dir='+') + + +def test_issue_8208(): + assert limit(n**(Rational(1, 1e9) - 1), n, oo) == 0 + + +def test_issue_8229(): + assert limit((x**Rational(1, 4) - 2)/(sqrt(x) - 4)**Rational(2, 3), x, 16) == 0 + + +def test_issue_8433(): + d, t = symbols('d t', positive=True) + assert limit(erf(1 - t/d), t, oo) == -1 + + +def test_issue_8481(): + k = Symbol('k', integer=True, nonnegative=True) + lamda = Symbol('lamda', positive=True) + assert limit(lamda**k * exp(-lamda) / factorial(k), k, oo) == 0 + + +def test_issue_8462(): + assert limit(binomial(n, n/2), n, oo) == oo + assert limit(binomial(n, n/2) * 3 ** (-n), n, oo) == 0 + + +def test_issue_8634(): + n = Symbol('n', integer=True, positive=True) + x = Symbol('x') + assert limit(x**n, x, -oo) == oo*sign((-1)**n) + + +def test_issue_8635_18176(): + x = Symbol('x', real=True) + k = Symbol('k', positive=True) + assert limit(x**n - x**(n - 0), x, oo) == 0 + assert limit(x**n - x**(n - 5), x, oo) == oo + assert limit(x**n - x**(n - 2.5), x, oo) == oo + assert limit(x**n - x**(n - k - 1), x, oo) == oo + x = Symbol('x', positive=True) + assert limit(x**n - x**(n - 1), x, oo) == oo + assert limit(x**n - x**(n + 2), x, oo) == -oo + + +def test_issue_8730(): + assert limit(subfactorial(x), x, oo) is oo + + +def test_issue_9252(): + n = Symbol('n', integer=True) + c = Symbol('c', positive=True) + assert limit((log(n))**(n/log(n)) / (1 + c)**n, n, oo) == 0 + # limit should depend on the value of c + raises(NotImplementedError, lambda: limit((log(n))**(n/log(n)) / c**n, n, oo)) + + +def test_issue_9558(): + assert limit(sin(x)**15, x, 0, '-') == 0 + + +def test_issue_10801(): + # make sure limits work with binomial + assert limit(16**k / (k * binomial(2*k, k)**2), k, oo) == pi + + +def test_issue_10976(): + s, x = symbols('s x', real=True) + assert limit(erf(s*x)/erf(s), s, 0) == x + + +def test_issue_9041(): + assert limit(factorial(n) / ((n/exp(1))**n * sqrt(2*pi*n)), n, oo) == 1 + + +def test_issue_9205(): + x, y, a = symbols('x, y, a') + assert Limit(x, x, a).free_symbols == {a} + assert Limit(x, x, a, '-').free_symbols == {a} + assert Limit(x + y, x + y, a).free_symbols == {a} + assert Limit(-x**2 + y, x**2, a).free_symbols == {y, a} + + +def test_issue_9471(): + assert limit(((27**(log(n,3)))/n**3),n,oo) == 1 + assert limit(((27**(log(n,3)+1))/n**3),n,oo) == 27 + + +def test_issue_10382(): + assert limit(fibonacci(n + 1)/fibonacci(n), n, oo) == GoldenRatio + + +def test_issue_11496(): + assert limit(erfc(log(1/x)), x, oo) == 2 + + +def test_issue_11879(): + assert simplify(limit(((x+y)**n-x**n)/y, y, 0)) == n*x**(n-1) + + +def test_limit_with_Float(): + k = symbols("k") + assert limit(1.0 ** k, k, oo) == 1 + assert limit(0.3*1.0**k, k, oo) == Rational(3, 10) + + +def test_issue_10610(): + assert limit(3**x*3**(-x - 1)*(x + 1)**2/x**2, x, oo) == Rational(1, 3) + + +def test_issue_10868(): + assert limit(log(x) + asech(x), x, 0, '+') == log(2) + assert limit(log(x) + asech(x), x, 0, '-') == log(2) + 2*I*pi + raises(ValueError, lambda: limit(log(x) + asech(x), x, 0, '+-')) + assert limit(log(x) + asech(x), x, oo) == oo + assert limit(log(x) + acsch(x), x, 0, '+') == log(2) + assert limit(log(x) + acsch(x), x, 0, '-') == -oo + raises(ValueError, lambda: limit(log(x) + acsch(x), x, 0, '+-')) + assert limit(log(x) + acsch(x), x, oo) == oo + + +def test_issue_6599(): + assert limit((n + cos(n))/n, n, oo) == 1 + + +def test_issue_12555(): + assert limit((3**x + 2* x**10) / (x**10 + exp(x)), x, -oo) == 2 + assert limit((3**x + 2* x**10) / (x**10 + exp(x)), x, oo) is oo + + +def test_issue_12769(): + r, z, x = symbols('r z x', real=True) + a, b, s0, K, F0, s, T = symbols('a b s0 K F0 s T', positive=True, real=True) + fx = (F0**b*K**b*r*s0 - sqrt((F0**2*K**(2*b)*a**2*(b - 1) + \ + F0**(2*b)*K**2*a**2*(b - 1) + F0**(2*b)*K**(2*b)*s0**2*(b - 1)*(b**2 - 2*b + 1) - \ + 2*F0**(2*b)*K**(b + 1)*a*r*s0*(b**2 - 2*b + 1) + \ + 2*F0**(b + 1)*K**(2*b)*a*r*s0*(b**2 - 2*b + 1) - \ + 2*F0**(b + 1)*K**(b + 1)*a**2*(b - 1))/((b - 1)*(b**2 - 2*b + 1))))*(b*r - b - r + 1) + + assert fx.subs(K, F0).factor(deep=True) == limit(fx, K, F0).factor(deep=True) + + +def test_issue_13332(): + assert limit(sqrt(30)*5**(-5*x - 1)*(46656*x)**x*(5*x + 2)**(5*x + 5*S.Half) * + (6*x + 2)**(-6*x - 5*S.Half), x, oo) == Rational(25, 36) + + +def test_issue_12564(): + assert limit(x**2 + x*sin(x) + cos(x), x, -oo) is oo + assert limit(x**2 + x*sin(x) + cos(x), x, oo) is oo + assert limit(((x + cos(x))**2).expand(), x, oo) is oo + assert limit(((x + sin(x))**2).expand(), x, oo) is oo + assert limit(((x + cos(x))**2).expand(), x, -oo) is oo + assert limit(((x + sin(x))**2).expand(), x, -oo) is oo + + +def test_issue_14456(): + raises(NotImplementedError, lambda: Limit(exp(x), x, zoo).doit()) + raises(NotImplementedError, lambda: Limit(x**2/(x+1), x, zoo).doit()) + + +def test_issue_14411(): + assert limit(3*sec(4*pi*x - x/3), x, 3*pi/(24*pi - 2)) is -oo + + +def test_issue_13382(): + assert limit(x*(((x + 1)**2 + 1)/(x**2 + 1) - 1), x, oo) == 2 + + +def test_issue_13403(): + assert limit(x*(-1 + (x + log(x + 1) + 1)/(x + log(x))), x, oo) == 1 + + +def test_issue_13416(): + assert limit((-x**3*log(x)**3 + (x - 1)*(x + 1)**2*log(x + 1)**3)/(x**2*log(x)**3), x, oo) == 1 + + +def test_issue_13462(): + assert limit(n**2*(2*n*(-(1 - 1/(2*n))**x + 1) - x - (-x**2/4 + x/4)/n), n, oo) == x**3/24 - x**2/8 + x/12 + + +def test_issue_13750(): + a = Symbol('a') + assert limit(erf(a - x), x, oo) == -1 + assert limit(erf(sqrt(x) - x), x, oo) == -1 + + +def test_issue_14276(): + assert isinstance(limit(sin(x)**log(x), x, oo), Limit) + assert isinstance(limit(sin(x)**cos(x), x, oo), Limit) + assert isinstance(limit(sin(log(cos(x))), x, oo), Limit) + assert limit((1 + 1/(x**2 + cos(x)))**(x**2 + x), x, oo) == E + + +def test_issue_14514(): + assert limit((1/(log(x)**log(x)))**(1/x), x, oo) == 1 + + +def test_issues_14525(): + assert limit(sin(x)**2 - cos(x) + tan(x)*csc(x), x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + assert limit(sin(x)**2 - cos(x) + sin(x)*cot(x), x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + assert limit(cot(x) - tan(x)**2, x, oo) == AccumBounds(S.NegativeInfinity, S.Infinity) + assert limit(cos(x) - tan(x)**2, x, oo) == AccumBounds(S.NegativeInfinity, S.One) + assert limit(sin(x) - tan(x)**2, x, oo) == AccumBounds(S.NegativeInfinity, S.One) + assert limit(cos(x)**2 - tan(x)**2, x, oo) == AccumBounds(S.NegativeInfinity, S.One) + assert limit(tan(x)**2 + sin(x)**2 - cos(x), x, oo) == AccumBounds(-S.One, S.Infinity) + + +def test_issue_14574(): + assert limit(sqrt(x)*cos(x - x**2) / (x + 1), x, oo) == 0 + + +def test_issue_10102(): + assert limit(fresnels(x), x, oo) == S.Half + assert limit(3 + fresnels(x), x, oo) == 3 + S.Half + assert limit(5*fresnels(x), x, oo) == Rational(5, 2) + assert limit(fresnelc(x), x, oo) == S.Half + assert limit(fresnels(x), x, -oo) == Rational(-1, 2) + assert limit(4*fresnelc(x), x, -oo) == -2 + + +def test_issue_14377(): + raises(NotImplementedError, lambda: limit(exp(I*x)*sin(pi*x), x, oo)) + + +def test_issue_15146(): + e = (x/2) * (-2*x**3 - 2*(x**3 - 1) * x**2 * digamma(x**3 + 1) + \ + 2*(x**3 - 1) * x**2 * digamma(x**3 + x + 1) + x + 3) + assert limit(e, x, oo) == S(1)/3 + + +def test_issue_15202(): + e = (2**x*(2 + 2**(-x)*(-2*2**x + x + 2))/(x + 1))**(x + 1) + assert limit(e, x, oo) == exp(1) + + e = (log(x, 2)**7 + 10*x*factorial(x) + 5**x) / (factorial(x + 1) + 3*factorial(x) + 10**x) + assert limit(e, x, oo) == 10 + + +def test_issue_15282(): + assert limit((x**2000 - (x + 1)**2000) / x**1999, x, oo) == -2000 + + +def test_issue_15984(): + assert limit((-x + log(exp(x) + 1))/x, x, oo, dir='-') == 0 + + +def test_issue_13571(): + assert limit(uppergamma(x, 1) / gamma(x), x, oo) == 1 + + +def test_issue_13575(): + assert limit(acos(erfi(x)), x, 1) == acos(erfi(S.One)) + + +def test_issue_17325(): + assert Limit(sin(x)/x, x, 0, dir="+-").doit() == 1 + assert Limit(x**2, x, 0, dir="+-").doit() == 0 + assert Limit(1/x**2, x, 0, dir="+-").doit() is oo + assert Limit(1/x, x, 0, dir="+-").doit() is zoo + + +def test_issue_10978(): + assert LambertW(x).limit(x, 0) == 0 + + +def test_issue_14313_comment(): + assert limit(floor(n/2), n, oo) is oo + + +def test_issue_15323(): + d = ((1 - 1/x)**x).diff(x) + assert limit(d, x, 1, dir='+') == 1 + + +def test_issue_12571(): + assert limit(-LambertW(-log(x))/log(x), x, 1) == 1 + + +def test_issue_14590(): + assert limit((x**3*((x + 1)/x)**x)/((x + 1)*(x + 2)*(x + 3)), x, oo) == exp(1) + + +def test_issue_14393(): + a, b = symbols('a b') + assert limit((x**b - y**b)/(x**a - y**a), x, y) == b*y**(-a + b)/a + + +def test_issue_14556(): + assert limit(factorial(n + 1)**(1/(n + 1)) - factorial(n)**(1/n), n, oo) == exp(-1) + + +def test_issue_14811(): + assert limit(((1 + ((S(2)/3)**(x + 1)))**(2**x))/(2**((S(4)/3)**(x - 1))), x, oo) == oo + + +def test_issue_16222(): + assert limit(exp(x), x, 1000000000) == exp(1000000000) + + +def test_issue_16714(): + assert limit(((x**(x + 1) + (x + 1)**x) / x**(x + 1))**x, x, oo) == exp(exp(1)) + + +def test_issue_16722(): + z = symbols('z', positive=True) + assert limit(binomial(n + z, n)*n**-z, n, oo) == 1/gamma(z + 1) + z = symbols('z', positive=True, integer=True) + assert limit(binomial(n + z, n)*n**-z, n, oo) == 1/gamma(z + 1) + + +def test_issue_17431(): + assert limit(((n + 1) + 1) / (((n + 1) + 2) * factorial(n + 1)) * + (n + 2) * factorial(n) / (n + 1), n, oo) == 0 + assert limit((n + 2)**2*factorial(n)/((n + 1)*(n + 3)*factorial(n + 1)) + , n, oo) == 0 + assert limit((n + 1) * factorial(n) / (n * factorial(n + 1)), n, oo) == 0 + + +def test_issue_17671(): + assert limit(Ei(-log(x)) - log(log(x))/x, x, 1) == EulerGamma + + +def test_issue_17751(): + a, b, c, x = symbols('a b c x', positive=True) + assert limit((a + 1)*x - sqrt((a + 1)**2*x**2 + b*x + c), x, oo) == -b/(2*a + 2) + + +def test_issue_17792(): + assert limit(factorial(n)/sqrt(n)*(exp(1)/n)**n, n, oo) == sqrt(2)*sqrt(pi) + + +def test_issue_18118(): + assert limit(sign(sin(x)), x, 0, "-") == -1 + assert limit(sign(sin(x)), x, 0, "+") == 1 + + +def test_issue_18306(): + assert limit(sin(sqrt(x))/sqrt(sin(x)), x, 0, '+') == 1 + + +def test_issue_18378(): + assert limit(log(exp(3*x) + x)/log(exp(x) + x**100), x, oo) == 3 + + +def test_issue_18399(): + assert limit((1 - S(1)/2*x)**(3*x), x, oo) is zoo + assert limit((-x)**x, x, oo) is zoo + + +def test_issue_18442(): + assert limit(tan(x)**(2**(sqrt(pi))), x, oo, dir='-') == Limit(tan(x)**(2**(sqrt(pi))), x, oo, dir='-') + + +def test_issue_18452(): + assert limit(abs(log(x))**x, x, 0) == 1 + assert limit(abs(log(x))**x, x, 0, "-") == 1 + + +def test_issue_18473(): + assert limit(sin(x)**(1/x), x, oo) == Limit(sin(x)**(1/x), x, oo, dir='-') + assert limit(cos(x)**(1/x), x, oo) == Limit(cos(x)**(1/x), x, oo, dir='-') + assert limit(tan(x)**(1/x), x, oo) == Limit(tan(x)**(1/x), x, oo, dir='-') + assert limit((cos(x) + 2)**(1/x), x, oo) == 1 + assert limit((sin(x) + 10)**(1/x), x, oo) == 1 + assert limit((cos(x) - 2)**(1/x), x, oo) == Limit((cos(x) - 2)**(1/x), x, oo, dir='-') + assert limit((cos(x) + 1)**(1/x), x, oo) == AccumBounds(0, 1) + assert limit((tan(x)**2)**(2/x) , x, oo) == AccumBounds(0, oo) + assert limit((sin(x)**2)**(1/x), x, oo) == AccumBounds(0, 1) + # Tests for issue #23751 + assert limit((cos(x) + 1)**(1/x), x, -oo) == AccumBounds(1, oo) + assert limit((sin(x)**2)**(1/x), x, -oo) == AccumBounds(1, oo) + assert limit((tan(x)**2)**(2/x) , x, -oo) == AccumBounds(0, oo) + + +def test_issue_18482(): + assert limit((2*exp(3*x)/(exp(2*x) + 1))**(1/x), x, oo) == exp(1) + + +def test_issue_18508(): + assert limit(sin(x)/sqrt(1-cos(x)), x, 0) == sqrt(2) + assert limit(sin(x)/sqrt(1-cos(x)), x, 0, dir='+') == sqrt(2) + assert limit(sin(x)/sqrt(1-cos(x)), x, 0, dir='-') == -sqrt(2) + + +def test_issue_18521(): + raises(NotImplementedError, lambda: limit(exp((2 - n) * x), x, oo)) + + +def test_issue_18969(): + a, b = symbols('a b', positive=True) + assert limit(LambertW(a), a, b) == LambertW(b) + assert limit(exp(LambertW(a)), a, b) == exp(LambertW(b)) + + +def test_issue_18992(): + assert limit(n/(factorial(n)**(1/n)), n, oo) == exp(1) + + +def test_issue_19067(): + x = Symbol('x') + assert limit(gamma(x)/(gamma(x - 1)*gamma(x + 2)), x, 0) == -1 + + +def test_issue_19586(): + assert limit(x**(2**x*3**(-x)), x, oo) == 1 + + +def test_issue_13715(): + n = Symbol('n') + p = Symbol('p', zero=True) + assert limit(n + p, n, 0) == 0 + + +def test_issue_15055(): + assert limit(n**3*((-n - 1)*sin(1/n) + (n + 2)*sin(1/(n + 1)))/(-n + 1), n, oo) == 1 + + +def test_issue_16708(): + m, vi = symbols('m vi', positive=True) + B, ti, d = symbols('B ti d') + assert limit((B*ti*vi - sqrt(m)*sqrt(-2*B*d*vi + m*(vi)**2) + m*vi)/(B*vi), B, 0) == (d + ti*vi)/vi + + +def test_issue_19154(): + assert limit(besseli(1, 3 *x)/(x *besseli(1, x)**3), x , oo) == 2*sqrt(3)*pi/3 + assert limit(besseli(1, 3 *x)/(x *besseli(1, x)**3), x , -oo) == -2*sqrt(3)*pi/3 + + +def test_issue_19453(): + beta = Symbol("beta", positive=True) + h = Symbol("h", positive=True) + m = Symbol("m", positive=True) + w = Symbol("omega", positive=True) + g = Symbol("g", positive=True) + + e = exp(1) + q = 3*h**2*beta*g*e**(0.5*h*beta*w) + p = m**2*w**2 + s = e**(h*beta*w) - 1 + Z = -q/(4*p*s) - q/(2*p*s**2) - q*(e**(h*beta*w) + 1)/(2*p*s**3)\ + + e**(0.5*h*beta*w)/s + E = -diff(log(Z), beta) + + assert limit(E - 0.5*h*w, beta, oo) == 0 + assert limit(E.simplify() - 0.5*h*w, beta, oo) == 0 + + +def test_issue_19739(): + assert limit((-S(1)/4)**x, x, oo) == 0 + + +def test_issue_19766(): + assert limit(2**(-x)*sqrt(4**(x + 1) + 1), x, oo) == 2 + + +def test_issue_19770(): + m = Symbol('m') + # the result is not 0 for non-real m + assert limit(cos(m*x)/x, x, oo) == Limit(cos(m*x)/x, x, oo, dir='-') + m = Symbol('m', real=True) + # can be improved to give the correct result 0 + assert limit(cos(m*x)/x, x, oo) == Limit(cos(m*x)/x, x, oo, dir='-') + m = Symbol('m', nonzero=True) + assert limit(cos(m*x), x, oo) == AccumBounds(-1, 1) + assert limit(cos(m*x)/x, x, oo) == 0 + + +def test_issue_7535(): + assert limit(tan(x)/sin(tan(x)), x, pi/2) == Limit(tan(x)/sin(tan(x)), x, pi/2, dir='+') + assert limit(tan(x)/sin(tan(x)), x, pi/2, dir='-') == Limit(tan(x)/sin(tan(x)), x, pi/2, dir='-') + assert limit(tan(x)/sin(tan(x)), x, pi/2, dir='+-') == Limit(tan(x)/sin(tan(x)), x, pi/2, dir='+-') + assert limit(sin(tan(x)),x,pi/2) == AccumBounds(-1, 1) + assert -oo*(1/sin(-oo)) == AccumBounds(-oo, oo) + assert oo*(1/sin(oo)) == AccumBounds(-oo, oo) + assert oo*(1/sin(-oo)) == AccumBounds(-oo, oo) + assert -oo*(1/sin(oo)) == AccumBounds(-oo, oo) + + +def test_issue_20365(): + assert limit(((x + 1)**(1/x) - E)/x, x, 0) == -E/2 + + +def test_issue_21031(): + assert limit(((1 + x)**(1/x) - (1 + 2*x)**(1/(2*x)))/asin(x), x, 0) == E/2 + + +def test_issue_21038(): + assert limit(sin(pi*x)/(3*x - 12), x, 4) == pi/3 + + +def test_issue_20578(): + expr = abs(x) * sin(1/x) + assert limit(expr,x,0,'+') == 0 + assert limit(expr,x,0,'-') == 0 + assert limit(expr,x,0,'+-') == 0 + + +def test_issue_21227(): + f = log(x) + + assert f.nseries(x, logx=y) == y + assert f.nseries(x, logx=-x) == -x + + f = log(-log(x)) + + assert f.nseries(x, logx=y) == log(-y) + assert f.nseries(x, logx=-x) == log(x) + + f = log(log(x)) + + assert f.nseries(x, logx=y) == log(y) + assert f.nseries(x, logx=-x) == log(-x) + assert f.nseries(x, logx=x) == log(x) + + f = log(log(log(1/x))) + + assert f.nseries(x, logx=y) == log(log(-y)) + assert f.nseries(x, logx=-y) == log(log(y)) + assert f.nseries(x, logx=x) == log(log(-x)) + assert f.nseries(x, logx=-x) == log(log(x)) + + +def test_issue_21415(): + exp = (x-1)*cos(1/(x-1)) + assert exp.limit(x,1) == 0 + assert exp.expand().limit(x,1) == 0 + + +def test_issue_21530(): + assert limit(sinh(n + 1)/sinh(n), n, oo) == E + + +def test_issue_21550(): + r = (sqrt(5) - 1)/2 + assert limit((x - r)/(x**2 + x - 1), x, r) == sqrt(5)/5 + + +def test_issue_21661(): + out = limit((x**(x + 1) * (log(x) + 1) + 1) / x, x, 11) + assert out == S(3138428376722)/11 + 285311670611*log(11) + + +def test_issue_21701(): + assert limit((besselj(z, x)/x**z).subs(z, 7), x, 0) == S(1)/645120 + + +def test_issue_21721(): + a = Symbol('a', real=True) + I = integrate(1/(pi*(1 + (x - a)**2)), x) + assert I.limit(x, oo) == S.Half + + +def test_issue_21756(): + term = (1 - exp(-2*I*pi*z))/(1 - exp(-2*I*pi*z/5)) + assert term.limit(z, 0) == 5 + assert re(term).limit(z, 0) == 5 + + +def test_issue_21785(): + a = Symbol('a') + assert sqrt((-a**2 + x**2)/(1 - x**2)).limit(a, 1, '-') == I + + +def test_issue_22181(): + assert limit((-1)**x * 2**(-x), x, oo) == 0 + + +def test_issue_22220(): + e1 = sqrt(30)*atan(sqrt(30)*tan(x/2)/6)/30 + e2 = sqrt(30)*I*(-log(sqrt(2)*tan(x/2) - 2*sqrt(15)*I/5) + + +log(sqrt(2)*tan(x/2) + 2*sqrt(15)*I/5))/60 + + assert limit(e1, x, -pi) == -sqrt(30)*pi/60 + assert limit(e2, x, -pi) == -sqrt(30)*pi/30 + + assert limit(e1, x, -pi, '-') == sqrt(30)*pi/60 + assert limit(e2, x, -pi, '-') == 0 + + # test https://github.com/sympy/sympy/issues/22220#issuecomment-972727694 + expr = log(x - I) - log(-x - I) + expr2 = logcombine(expr, force=True) + assert limit(expr, x, oo) == limit(expr2, x, oo) == I*pi + + # test https://github.com/sympy/sympy/issues/22220#issuecomment-1077618340 + expr = expr = (-log(tan(x/2) - I) +log(tan(x/2) + I)) + assert limit(expr, x, pi, '+') == 2*I*pi + assert limit(expr, x, pi, '-') == 0 + + +def test_issue_22334(): + k, n = symbols('k, n', positive=True) + assert limit((n+1)**k/((n+1)**(k+1) - (n)**(k+1)), n, oo) == 1/(k + 1) + assert limit((n+1)**k/((n+1)**(k+1) - (n)**(k+1)).expand(), n, oo) == 1/(k + 1) + assert limit((n+1)**k/(n*(-n**k + (n + 1)**k) + (n + 1)**k), n, oo) == 1/(k + 1) + + +def test_issue_22836_limit(): + assert limit(2**(1/x)/factorial(1/(x)), x, 0) == S.Zero + + +def test_sympyissue_22986(): + assert limit(acosh(1 + 1/x)*sqrt(x), x, oo) == sqrt(2) + + +def test_issue_23231(): + f = (2**x - 2**(-x))/(2**x + 2**(-x)) + assert limit(f, x, -oo) == -1 + + +def test_issue_23596(): + assert integrate(((1 + x)/x**2)*exp(-1/x), (x, 0, oo)) == oo + + +def test_issue_23752(): + expr1 = sqrt(-I*x**2 + x - 3) + expr2 = sqrt(-I*x**2 + I*x - 3) + assert limit(expr1, x, 0, '+') == -sqrt(3)*I + assert limit(expr1, x, 0, '-') == -sqrt(3)*I + assert limit(expr2, x, 0, '+') == sqrt(3)*I + assert limit(expr2, x, 0, '-') == -sqrt(3)*I + + +def test_issue_24276(): + fx = log(tan(pi/2*tanh(x))).diff(x) + assert fx.limit(x, oo) == 2 + assert fx.simplify().limit(x, oo) == 2 + assert fx.rewrite(sin).limit(x, oo) == 2 + assert fx.rewrite(sin).simplify().limit(x, oo) == 2 + +def test_issue_25230(): + a = Symbol('a', real = True) + b = Symbol('b', positive = True) + c = Symbol('c', negative = True) + n = Symbol('n', integer = True) + raises(NotImplementedError, lambda: limit(Mod(x, a), x, a)) + assert limit(Mod(x, b), x, n*b, '+') == 0 + assert limit(Mod(x, b), x, n*b, '-') == b + assert limit(Mod(x, c), x, n*c, '+') == c + assert limit(Mod(x, c), x, n*c, '-') == 0 + + +def test_issue_25582(): + + assert limit(asin(exp(x)), x, oo, '-') == -oo*I + assert limit(acos(exp(x)), x, oo, '-') == oo*I + assert limit(atan(exp(x)), x, oo, '-') == pi/2 + assert limit(acot(exp(x)), x, oo, '-') == 0 + assert limit(asec(exp(x)), x, oo, '-') == pi/2 + assert limit(acsc(exp(x)), x, oo, '-') == 0 + + +def test_issue_25847(): + #atan + assert limit(atan(sin(x)/x), x, 0, '+-') == pi/4 + assert limit(atan(exp(1/x)), x, 0, '+') == pi/2 + assert limit(atan(exp(1/x)), x, 0, '-') == 0 + + #asin + assert limit(asin(sin(x)/x), x, 0, '+-') == pi/2 + assert limit(asin(exp(1/x)), x, 0, '+') == -oo*I + assert limit(asin(exp(1/x)), x, 0, '-') == 0 + + #acos + assert limit(acos(sin(x)/x), x, 0, '+-') == 0 + assert limit(acos(exp(1/x)), x, 0, '+') == oo*I + assert limit(acos(exp(1/x)), x, 0, '-') == pi/2 + + #acot + assert limit(acot(sin(x)/x), x, 0, '+-') == pi/4 + assert limit(acot(exp(1/x)), x, 0, '+') == 0 + assert limit(acot(exp(1/x)), x, 0, '-') == pi/2 + + #asec + assert limit(asec(sin(x)/x), x, 0, '+-') == 0 + assert limit(asec(exp(1/x)), x, 0, '+') == pi/2 + assert limit(asec(exp(1/x)), x, 0, '-') == oo*I + + #acsc + assert limit(acsc(sin(x)/x), x, 0, '+-') == pi/2 + assert limit(acsc(exp(1/x)), x, 0, '+') == 0 + assert limit(acsc(exp(1/x)), x, 0, '-') == -oo*I + + #atanh + assert limit(atanh(sin(x)/x), x, 0, '+-') == oo + assert limit(atanh(exp(1/x)), x, 0, '+') == -I*pi/2 + assert limit(atanh(exp(1/x)), x, 0, '-') == 0 + + #asinh + assert limit(asinh(sin(x)/x), x, 0, '+-') == log(1 + sqrt(2)) + assert limit(asinh(exp(1/x)), x, 0, '+') == oo + assert limit(asinh(exp(1/x)), x, 0, '-') == 0 + + #acosh + assert limit(acosh(sin(x)/x), x, 0, '+-') == 0 + assert limit(acosh(exp(1/x)), x, 0, '+') == oo + assert limit(acosh(exp(1/x)), x, 0, '-') == I*pi/2 + + #acoth + assert limit(acoth(sin(x)/x), x, 0, '+-') == oo + assert limit(acoth(exp(1/x)), x, 0, '+') == 0 + assert limit(acoth(exp(1/x)), x, 0, '-') == -I*pi/2 + + #asech + assert limit(asech(sin(x)/x), x, 0, '+-') == 0 + assert limit(asech(exp(1/x)), x, 0, '+') == I*pi/2 + assert limit(asech(exp(1/x)), x, 0, '-') == oo + + #acsch + assert limit(acsch(sin(x)/x), x, 0, '+-') == log(1 + sqrt(2)) + assert limit(acsch(exp(1/x)), x, 0, '+') == 0 + assert limit(acsch(exp(1/x)), x, 0, '-') == oo + + +def test_issue_26040(): + assert limit(besseli(0, x + 1)/besseli(0, x), x, oo) == S.Exp1 + + +def test_issue_26250(): + e = elliptic_e(4*x/(x**2 + 2*x + 1)) + k = elliptic_k(4*x/(x**2 + 2*x + 1)) + e1 = ((1-3*x**2)*e**2/2 - (x**2-2*x+1)*e*k/2) + e2 = pi**2*(x**8 - 2*x**7 - x**6 + 4*x**5 - x**4 - 2*x**3 + x**2) + assert limit(e1/e2, x, 0) == -S(1)/8 + + +def test_issue_26513(): + assert limit(abs((-x/(x+1))**x), x ,oo) == exp(-1) + assert limit((x/(x + 1))**x, x, oo) == exp(-1) + raises (NotImplementedError, lambda: limit((-x/(x+1))**x, x, oo)) + + +def test_issue_26916(): + assert limit(Ei(x)*exp(-x), x, +oo) == 0 + assert limit(Ei(x)*exp(-x), x, -oo) == 0 + + +def test_issue_22982_15323(): + assert limit((log(E + 1/x) - 1)**(1 - sqrt(E + 1/x)), x, oo) == oo + assert limit((1 - 1/x)**x*(log(1 - 1/x) + 1/(x*(1 - 1/x))), x, 1, dir='+') == 1 + assert limit((log(E + 1/x) )**(1 - sqrt(E + 1/x)), x, oo) == 1 + assert limit((log(E + 1/x) - 1)**(- sqrt(E + 1/x)), x, oo) == oo + + +def test_issue_26991(): + assert limit(x/((x - 6)*sinh(tanh(0.03*x)) + tanh(x) - 0.5), x, oo) == 1/sinh(1) + +def test_issue_27278(): + expr = (1/(x*log((x + 3)/x)))**x*((x + 1)*log((x + 4)/(x + 1)))**(x + 1)/3 + assert limit(expr, x, oo) == 1 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_limitseq.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_limitseq.py new file mode 100644 index 0000000000000000000000000000000000000000..362bb0397feb0ec63929920855c81279eca0bd6a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_limitseq.py @@ -0,0 +1,177 @@ +from sympy.concrete.summations import Sum +from sympy.core.add import Add +from sympy.core.numbers import (I, Rational, oo, pi) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.combinatorial.factorials import (binomial, factorial, subfactorial) +from sympy.functions.combinatorial.numbers import (fibonacci, harmonic) +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.functions.special.gamma_functions import gamma +from sympy.series.limitseq import limit_seq +from sympy.series.limitseq import difference_delta as dd +from sympy.testing.pytest import raises, XFAIL +from sympy.calculus.accumulationbounds import AccumulationBounds + +n, m, k = symbols('n m k', integer=True) + + +def test_difference_delta(): + e = n*(n + 1) + e2 = e * k + + assert dd(e) == 2*n + 2 + assert dd(e2, n, 2) == k*(4*n + 6) + + raises(ValueError, lambda: dd(e2)) + raises(ValueError, lambda: dd(e2, n, oo)) + + +def test_difference_delta__Sum(): + e = Sum(1/k, (k, 1, n)) + assert dd(e, n) == 1/(n + 1) + assert dd(e, n, 5) == Add(*[1/(i + n + 1) for i in range(5)]) + + e = Sum(1/k, (k, 1, 3*n)) + assert dd(e, n) == Add(*[1/(i + 3*n + 1) for i in range(3)]) + + e = n * Sum(1/k, (k, 1, n)) + assert dd(e, n) == 1 + Sum(1/k, (k, 1, n)) + + e = Sum(1/k, (k, 1, n), (m, 1, n)) + assert dd(e, n) == harmonic(n) + + +def test_difference_delta__Add(): + e = n + n*(n + 1) + assert dd(e, n) == 2*n + 3 + assert dd(e, n, 2) == 4*n + 8 + + e = n + Sum(1/k, (k, 1, n)) + assert dd(e, n) == 1 + 1/(n + 1) + assert dd(e, n, 5) == 5 + Add(*[1/(i + n + 1) for i in range(5)]) + + +def test_difference_delta__Pow(): + e = 4**n + assert dd(e, n) == 3*4**n + assert dd(e, n, 2) == 15*4**n + + e = 4**(2*n) + assert dd(e, n) == 15*4**(2*n) + assert dd(e, n, 2) == 255*4**(2*n) + + e = n**4 + assert dd(e, n) == (n + 1)**4 - n**4 + + e = n**n + assert dd(e, n) == (n + 1)**(n + 1) - n**n + + +def test_limit_seq(): + e = binomial(2*n, n) / Sum(binomial(2*k, k), (k, 1, n)) + assert limit_seq(e) == S(3) / 4 + assert limit_seq(e, m) == e + + e = (5*n**3 + 3*n**2 + 4) / (3*n**3 + 4*n - 5) + assert limit_seq(e, n) == S(5) / 3 + + e = (harmonic(n) * Sum(harmonic(k), (k, 1, n))) / (n * harmonic(2*n)**2) + assert limit_seq(e, n) == 1 + + e = Sum(k**2 * Sum(2**m/m, (m, 1, k)), (k, 1, n)) / (2**n*n) + assert limit_seq(e, n) == 4 + + e = (Sum(binomial(3*k, k) * binomial(5*k, k), (k, 1, n)) / + (binomial(3*n, n) * binomial(5*n, n))) + assert limit_seq(e, n) == S(84375) / 83351 + + e = Sum(harmonic(k)**2/k, (k, 1, 2*n)) / harmonic(n)**3 + assert limit_seq(e, n) == S.One / 3 + + raises(ValueError, lambda: limit_seq(e * m)) + + +def test_alternating_sign(): + assert limit_seq((-1)**n/n**2, n) == 0 + assert limit_seq((-2)**(n+1)/(n + 3**n), n) == 0 + assert limit_seq((2*n + (-1)**n)/(n + 1), n) == 2 + assert limit_seq(sin(pi*n), n) == 0 + assert limit_seq(cos(2*pi*n), n) == 1 + assert limit_seq((S.NegativeOne/5)**n, n) == 0 + assert limit_seq((Rational(-1, 5))**n, n) == 0 + assert limit_seq((I/3)**n, n) == 0 + assert limit_seq(sqrt(n)*(I/2)**n, n) == 0 + assert limit_seq(n**7*(I/3)**n, n) == 0 + assert limit_seq(n/(n + 1) + (I/2)**n, n) == 1 + + +def test_accum_bounds(): + assert limit_seq((-1)**n, n) == AccumulationBounds(-1, 1) + assert limit_seq(cos(pi*n), n) == AccumulationBounds(-1, 1) + assert limit_seq(sin(pi*n/2)**2, n) == AccumulationBounds(0, 1) + assert limit_seq(2*(-3)**n/(n + 3**n), n) == AccumulationBounds(-2, 2) + assert limit_seq(3*n/(n + 1) + 2*(-1)**n, n) == AccumulationBounds(1, 5) + + +def test_limitseq_sum(): + from sympy.abc import x, y, z + assert limit_seq(Sum(1/x, (x, 1, y)) - log(y), y) == S.EulerGamma + assert limit_seq(Sum(1/x, (x, 1, y)) - 1/y, y) is S.Infinity + assert (limit_seq(binomial(2*x, x) / Sum(binomial(2*y, y), (y, 1, x)), x) == + S(3) / 4) + assert (limit_seq(Sum(y**2 * Sum(2**z/z, (z, 1, y)), (y, 1, x)) / + (2**x*x), x) == 4) + + +def test_issue_9308(): + assert limit_seq(subfactorial(n)/factorial(n), n) == exp(-1) + + +def test_issue_10382(): + n = Symbol('n', integer=True) + assert limit_seq(fibonacci(n+1)/fibonacci(n), n).together() == S.GoldenRatio + + +def test_issue_11672(): + assert limit_seq(Rational(-1, 2)**n, n) == 0 + + +def test_issue_14196(): + k, n = symbols('k, n', positive=True) + m = Symbol('m') + assert limit_seq(Sum(m**k, (m, 1, n)).doit()/(n**(k + 1)), n) == 1/(k + 1) + + +def test_issue_16735(): + assert limit_seq(5**n/factorial(n), n) == 0 + + +def test_issue_19868(): + assert limit_seq(1/gamma(n + S.One/2), n) == 0 + + +@XFAIL +def test_limit_seq_fail(): + # improve Summation algorithm or add ad-hoc criteria + e = (harmonic(n)**3 * Sum(1/harmonic(k), (k, 1, n)) / + (n * Sum(harmonic(k)/k, (k, 1, n)))) + assert limit_seq(e, n) == 2 + + # No unique dominant term + e = (Sum(2**k * binomial(2*k, k) / k**2, (k, 1, n)) / + (Sum(2**k/k*2, (k, 1, n)) * Sum(binomial(2*k, k), (k, 1, n)))) + assert limit_seq(e, n) == S(3) / 7 + + # Simplifications of summations needs to be improved. + e = n**3*Sum(2**k/k**2, (k, 1, n))**2 / (2**n * Sum(2**k/k, (k, 1, n))) + assert limit_seq(e, n) == 2 + + e = (harmonic(n) * Sum(2**k/k, (k, 1, n)) / + (n * Sum(2**k*harmonic(k)/k**2, (k, 1, n)))) + assert limit_seq(e, n) == 1 + + e = (Sum(2**k*factorial(k) / k**2, (k, 1, 2*n)) / + (Sum(4**k/k**2, (k, 1, n)) * Sum(factorial(k), (k, 1, 2*n)))) + assert limit_seq(e, n) == S(3) / 16 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_lseries.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_lseries.py new file mode 100644 index 0000000000000000000000000000000000000000..42d327bf60c76eebdc4570d631efef4bc84b58e3 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_lseries.py @@ -0,0 +1,65 @@ +from sympy.core.numbers import E +from sympy.core.singleton import S +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.hyperbolic import tanh +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.series.order import Order +from sympy.abc import x, y + + +def test_sin(): + e = sin(x).lseries(x) + assert next(e) == x + assert next(e) == -x**3/6 + assert next(e) == x**5/120 + + +def test_cos(): + e = cos(x).lseries(x) + assert next(e) == 1 + assert next(e) == -x**2/2 + assert next(e) == x**4/24 + + +def test_exp(): + e = exp(x).lseries(x) + assert next(e) == 1 + assert next(e) == x + assert next(e) == x**2/2 + assert next(e) == x**3/6 + + +def test_exp2(): + e = exp(cos(x)).lseries(x) + assert next(e) == E + assert next(e) == -E*x**2/2 + assert next(e) == E*x**4/6 + assert next(e) == -31*E*x**6/720 + + +def test_simple(): + assert list(x.lseries()) == [x] + assert list(S.One.lseries(x)) == [1] + assert not next((x/(x + y)).lseries(y)).has(Order) + + +def test_issue_5183(): + s = (x + 1/x).lseries() + assert list(s) == [1/x, x] + assert next((x + x**2).lseries()) == x + assert next(((1 + x)**7).lseries(x)) == 1 + assert next((sin(x + y)).series(x, n=3).lseries(y)) == x + # it would be nice if all terms were grouped, but in the + # following case that would mean that all the terms would have + # to be known since, for example, every term has a constant in it. + s = ((1 + x)**7).series(x, 1, n=None) + assert [next(s) for i in range(2)] == [128, -448 + 448*x] + + +def test_issue_6999(): + s = tanh(x).lseries(x, 1) + assert next(s) == tanh(1) + assert next(s) == x - (x - 1)*tanh(1)**2 - 1 + assert next(s) == -(x - 1)**2*tanh(1) + (x - 1)**2*tanh(1)**3 + assert next(s) == -(x - 1)**3*tanh(1)**4 - (x - 1)**3/3 + \ + 4*(x - 1)**3*tanh(1)**2/3 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_nseries.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_nseries.py new file mode 100644 index 0000000000000000000000000000000000000000..a2f20add82d3e858e2ce145fc9fcd4a6548a48cc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_nseries.py @@ -0,0 +1,557 @@ +from sympy.calculus.util import AccumBounds +from sympy.core.function import (Derivative, PoleError) +from sympy.core.numbers import (E, I, Integer, Rational, pi) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.elementary.complexes import sign +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.hyperbolic import (acosh, acoth, asinh, atanh, cosh, coth, sinh, tanh) +from sympy.functions.elementary.integers import (ceiling, floor, frac) +from sympy.functions.elementary.miscellaneous import (cbrt, sqrt) +from sympy.functions.elementary.trigonometric import (asin, cos, cot, sin, tan) +from sympy.series.limits import limit +from sympy.series.order import O +from sympy.abc import x, y, z + +from sympy.testing.pytest import raises, XFAIL + + +def test_simple_1(): + assert x.nseries(x, n=5) == x + assert y.nseries(x, n=5) == y + assert (1/(x*y)).nseries(y, n=5) == 1/(x*y) + assert Rational(3, 4).nseries(x, n=5) == Rational(3, 4) + assert x.nseries() == x + + +def test_mul_0(): + assert (x*log(x)).nseries(x, n=5) == x*log(x) + + +def test_mul_1(): + assert (x*log(2 + x)).nseries(x, n=5) == x*log(2) + x**2/2 - x**3/8 + \ + x**4/24 + O(x**5) + assert (x*log(1 + x)).nseries( + x, n=5) == x**2 - x**3/2 + x**4/3 + O(x**5) + + +def test_pow_0(): + assert (x**2).nseries(x, n=5) == x**2 + assert (1/x).nseries(x, n=5) == 1/x + assert (1/x**2).nseries(x, n=5) == 1/x**2 + assert (x**Rational(2, 3)).nseries(x, n=5) == (x**Rational(2, 3)) + assert (sqrt(x)**3).nseries(x, n=5) == (sqrt(x)**3) + + +def test_pow_1(): + assert ((1 + x)**2).nseries(x, n=5) == x**2 + 2*x + 1 + + # https://github.com/sympy/sympy/issues/21075 + assert ((sqrt(x) + 1)**2).nseries(x) == 2*sqrt(x) + x + 1 + assert ((sqrt(x) + cbrt(x))**2).nseries(x) == 2*x**Rational(5, 6)\ + + x**Rational(2, 3) + x + + +def test_geometric_1(): + assert (1/(1 - x)).nseries(x, n=5) == 1 + x + x**2 + x**3 + x**4 + O(x**5) + assert (x/(1 - x)).nseries(x, n=6) == x + x**2 + x**3 + x**4 + x**5 + O(x**6) + assert (x**3/(1 - x)).nseries(x, n=8) == x**3 + x**4 + x**5 + x**6 + \ + x**7 + O(x**8) + + +def test_sqrt_1(): + assert sqrt(1 + x).nseries(x, n=5) == 1 + x/2 - x**2/8 + x**3/16 - 5*x**4/128 + O(x**5) + + +def test_exp_1(): + assert exp(x).nseries(x, n=5) == 1 + x + x**2/2 + x**3/6 + x**4/24 + O(x**5) + assert exp(x).nseries(x, n=12) == 1 + x + x**2/2 + x**3/6 + x**4/24 + x**5/120 + \ + x**6/720 + x**7/5040 + x**8/40320 + x**9/362880 + x**10/3628800 + \ + x**11/39916800 + O(x**12) + assert exp(1/x).nseries(x, n=5) == exp(1/x) + assert exp(1/(1 + x)).nseries(x, n=4) == \ + (E*(1 - x - 13*x**3/6 + 3*x**2/2)).expand() + O(x**4) + assert exp(2 + x).nseries(x, n=5) == \ + (exp(2)*(1 + x + x**2/2 + x**3/6 + x**4/24)).expand() + O(x**5) + + +def test_exp_sqrt_1(): + assert exp(1 + sqrt(x)).nseries(x, n=3) == \ + (exp(1)*(1 + sqrt(x) + x/2 + sqrt(x)*x/6)).expand() + O(sqrt(x)**3) + + +def test_power_x_x1(): + assert (exp(x*log(x))).nseries(x, n=4) == \ + 1 + x*log(x) + x**2*log(x)**2/2 + x**3*log(x)**3/6 + O(x**4*log(x)**4) + + +def test_power_x_x2(): + assert (x**x).nseries(x, n=4) == \ + 1 + x*log(x) + x**2*log(x)**2/2 + x**3*log(x)**3/6 + O(x**4*log(x)**4) + + +def test_log_singular1(): + assert log(1 + 1/x).nseries(x, n=5) == x - log(x) - x**2/2 + x**3/3 - \ + x**4/4 + O(x**5) + + +def test_log_power1(): + e = 1 / (1/x + x ** (log(3)/log(2))) + assert e.nseries(x, n=5) == -x**(log(3)/log(2) + 2) + x + O(x**5) + + +def test_log_series(): + l = Symbol('l') + e = 1/(1 - log(x)) + assert e.nseries(x, n=5, logx=l) == 1/(1 - l) + + +def test_log2(): + e = log(-1/x) + assert e.nseries(x, n=5) == -log(x) + log(-1) + + +def test_log3(): + l = Symbol('l') + e = 1/log(-1/x) + assert e.nseries(x, n=4, logx=l) == 1/(-l + log(-1)) + + +def test_series1(): + e = sin(x) + assert e.nseries(x, 0, 0) != 0 + assert e.nseries(x, 0, 0) == O(1, x) + assert e.nseries(x, 0, 1) == O(x, x) + assert e.nseries(x, 0, 2) == x + O(x**2, x) + assert e.nseries(x, 0, 3) == x + O(x**3, x) + assert e.nseries(x, 0, 4) == x - x**3/6 + O(x**4, x) + + e = (exp(x) - 1)/x + assert e.nseries(x, 0, 3) == 1 + x/2 + x**2/6 + O(x**3) + + assert x.nseries(x, 0, 2) == x + + +@XFAIL +def test_series1_failing(): + assert x.nseries(x, 0, 0) == O(1, x) + assert x.nseries(x, 0, 1) == O(x, x) + + +def test_seriesbug1(): + assert (1/x).nseries(x, 0, 3) == 1/x + assert (x + 1/x).nseries(x, 0, 3) == x + 1/x + + +def test_series2x(): + assert ((x + 1)**(-2)).nseries(x, 0, 4) == 1 - 2*x + 3*x**2 - 4*x**3 + O(x**4, x) + assert ((x + 1)**(-1)).nseries(x, 0, 4) == 1 - x + x**2 - x**3 + O(x**4, x) + assert ((x + 1)**0).nseries(x, 0, 3) == 1 + assert ((x + 1)**1).nseries(x, 0, 3) == 1 + x + assert ((x + 1)**2).nseries(x, 0, 3) == x**2 + 2*x + 1 + assert ((x + 1)**3).nseries(x, 0, 3) == 1 + 3*x + 3*x**2 + O(x**3) + + assert (1/(1 + x)).nseries(x, 0, 4) == 1 - x + x**2 - x**3 + O(x**4, x) + assert (x + 3/(1 + 2*x)).nseries(x, 0, 4) == 3 - 5*x + 12*x**2 - 24*x**3 + O(x**4, x) + + assert ((1/x + 1)**3).nseries(x, 0, 3) == 1 + 3/x + 3/x**2 + x**(-3) + assert (1/(1 + 1/x)).nseries(x, 0, 4) == x - x**2 + x**3 - O(x**4, x) + assert (1/(1 + 1/x**2)).nseries(x, 0, 6) == x**2 - x**4 + O(x**6, x) + + +def test_bug2(): # 1/log(0)*log(0) problem + w = Symbol("w") + e = (w**(-1) + w**( + -log(3)*log(2)**(-1)))**(-1)*(3*w**(-log(3)*log(2)**(-1)) + 2*w**(-1)) + e = e.expand() + assert e.nseries(w, 0, 4).subs(w, 0) == 3 + + +def test_exp(): + e = (1 + x)**(1/x) + assert e.nseries(x, n=3) == exp(1) - x*exp(1)/2 + 11*exp(1)*x**2/24 + O(x**3) + + +def test_exp2(): + w = Symbol("w") + e = w**(1 - log(x)/(log(2) + log(x))) + logw = Symbol("logw") + assert e.nseries( + w, 0, 1, logx=logw) == exp(logw*log(2)/(log(x) + log(2))) + + +def test_bug3(): + e = (2/x + 3/x**2)/(1/x + 1/x**2) + assert e.nseries(x, n=3) == 3 - x + x**2 + O(x**3) + + +def test_generalexponent(): + p = 2 + e = (2/x + 3/x**p)/(1/x + 1/x**p) + assert e.nseries(x, 0, 3) == 3 - x + x**2 + O(x**3) + p = S.Half + e = (2/x + 3/x**p)/(1/x + 1/x**p) + assert e.nseries(x, 0, 2) == 2 - x + sqrt(x) + x**(S(3)/2) + O(x**2) + + e = 1 + sqrt(x) + assert e.nseries(x, 0, 4) == 1 + sqrt(x) + +# more complicated example + + +def test_genexp_x(): + e = 1/(1 + sqrt(x)) + assert e.nseries(x, 0, 2) == \ + 1 + x - sqrt(x) - sqrt(x)**3 + O(x**2, x) + +# more complicated example + + +def test_genexp_x2(): + p = Rational(3, 2) + e = (2/x + 3/x**p)/(1/x + 1/x**p) + assert e.nseries(x, 0, 3) == 3 + x + x**2 - sqrt(x) - x**(S(3)/2) - x**(S(5)/2) + O(x**3) + + +def test_seriesbug2(): + w = Symbol("w") + #simple case (1): + e = ((2*w)/w)**(1 + w) + assert e.nseries(w, 0, 1) == 2 + O(w, w) + assert e.nseries(w, 0, 1).subs(w, 0) == 2 + + +def test_seriesbug2b(): + w = Symbol("w") + #test sin + e = sin(2*w)/w + assert e.nseries(w, 0, 3) == 2 - 4*w**2/3 + O(w**3) + + +def test_seriesbug2d(): + w = Symbol("w", real=True) + e = log(sin(2*w)/w) + assert e.series(w, n=5) == log(2) - 2*w**2/3 - 4*w**4/45 + O(w**5) + + +def test_seriesbug2c(): + w = Symbol("w", real=True) + #more complicated case, but sin(x)~x, so the result is the same as in (1) + e = (sin(2*w)/w)**(1 + w) + assert e.series(w, 0, 1) == 2 + O(w) + assert e.series(w, 0, 3) == 2 + 2*w*log(2) + \ + w**2*(Rational(-4, 3) + log(2)**2) + O(w**3) + assert e.series(w, 0, 2).subs(w, 0) == 2 + + +def test_expbug4(): + x = Symbol("x", real=True) + assert (log( + sin(2*x)/x)*(1 + x)).series(x, 0, 2) == log(2) + x*log(2) + O(x**2, x) + assert exp( + log(sin(2*x)/x)*(1 + x)).series(x, 0, 2) == 2 + 2*x*log(2) + O(x**2) + + assert exp(log(2) + O(x)).nseries(x, 0, 2) == 2 + O(x) + assert ((2 + O(x))**(1 + x)).nseries(x, 0, 2) == 2 + O(x) + + +def test_logbug4(): + assert log(2 + O(x)).nseries(x, 0, 2) == log(2) + O(x, x) + + +def test_expbug5(): + assert exp(log(1 + x)/x).nseries(x, n=3) == exp(1) + -exp(1)*x/2 + 11*exp(1)*x**2/24 + O(x**3) + + assert exp(O(x)).nseries(x, 0, 2) == 1 + O(x) + + +def test_sinsinbug(): + assert sin(sin(x)).nseries(x, 0, 8) == x - x**3/3 + x**5/10 - 8*x**7/315 + O(x**8) + + +def test_issue_3258(): + a = x/(exp(x) - 1) + assert a.nseries(x, 0, 5) == 1 - x/2 - x**4/720 + x**2/12 + O(x**5) + + +def test_issue_3204(): + x = Symbol("x", nonnegative=True) + f = sin(x**3)**Rational(1, 3) + assert f.nseries(x, 0, 17) == x - x**7/18 - x**13/3240 + O(x**17) + + +def test_issue_3224(): + f = sqrt(1 - sqrt(y)) + assert f.nseries(y, 0, 2) == 1 - sqrt(y)/2 - y/8 - sqrt(y)**3/16 + O(y**2) + + +def test_issue_3463(): + w, i = symbols('w,i') + r = log(5)/log(3) + p = w**(-1 + r) + e = 1/x*(-log(w**(1 + r)) + log(w + w**r)) + e_ser = -r*log(w)/x + p/x - p**2/(2*x) + O(w) + assert e.nseries(w, n=1) == e_ser + + +def test_sin(): + assert sin(8*x).nseries(x, n=4) == 8*x - 256*x**3/3 + O(x**4) + assert sin(x + y).nseries(x, n=1) == sin(y) + O(x) + assert sin(x + y).nseries(x, n=2) == sin(y) + cos(y)*x + O(x**2) + assert sin(x + y).nseries(x, n=5) == sin(y) + cos(y)*x - sin(y)*x**2/2 - \ + cos(y)*x**3/6 + sin(y)*x**4/24 + O(x**5) + + +def test_issue_3515(): + e = sin(8*x)/x + assert e.nseries(x, n=6) == 8 - 256*x**2/3 + 4096*x**4/15 + O(x**6) + + +def test_issue_3505(): + e = sin(x)**(-4)*(sqrt(cos(x))*sin(x)**2 - + cos(x)**Rational(1, 3)*sin(x)**2) + assert e.nseries(x, n=9) == Rational(-1, 12) - 7*x**2/288 - \ + 43*x**4/10368 - 1123*x**6/2488320 + 377*x**8/29859840 + O(x**9) + + +def test_issue_3501(): + a = Symbol("a") + e = x**(-2)*(x*sin(a + x) - x*sin(a)) + assert e.nseries(x, n=6) == cos(a) - sin(a)*x/2 - cos(a)*x**2/6 + \ + x**3*sin(a)/24 + x**4*cos(a)/120 - x**5*sin(a)/720 + O(x**6) + e = x**(-2)*(x*cos(a + x) - x*cos(a)) + assert e.nseries(x, n=6) == -sin(a) - cos(a)*x/2 + sin(a)*x**2/6 + \ + cos(a)*x**3/24 - x**4*sin(a)/120 - x**5*cos(a)/720 + O(x**6) + + +def test_issue_3502(): + e = sin(5*x)/sin(2*x) + assert e.nseries(x, n=2) == Rational(5, 2) + O(x**2) + assert e.nseries(x, n=6) == \ + Rational(5, 2) - 35*x**2/4 + 329*x**4/48 + O(x**6) + + +def test_issue_3503(): + e = sin(2 + x)/(2 + x) + assert e.nseries(x, n=2) == sin(2)/2 + x*cos(2)/2 - x*sin(2)/4 + O(x**2) + + +def test_issue_3506(): + e = (x + sin(3*x))**(-2)*(x*(x + sin(3*x)) - (x + sin(3*x))*sin(2*x)) + assert e.nseries(x, n=7) == \ + Rational(-1, 4) + 5*x**2/96 + 91*x**4/768 + 11117*x**6/129024 + O(x**7) + + +def test_issue_3508(): + x = Symbol("x", real=True) + assert log(sin(x)).series(x, n=5) == log(x) - x**2/6 - x**4/180 + O(x**5) + e = -log(x) + x*(-log(x) + log(sin(2*x))) + log(sin(2*x)) + assert e.series(x, n=5) == \ + log(2) + log(2)*x - 2*x**2/3 - 2*x**3/3 - 4*x**4/45 + O(x**5) + + +def test_issue_3507(): + e = x**(-4)*(x**2 - x**2*sqrt(cos(x))) + assert e.nseries(x, n=9) == \ + Rational(1, 4) + x**2/96 + 19*x**4/5760 + 559*x**6/645120 + 29161*x**8/116121600 + O(x**9) + + +def test_issue_3639(): + assert sin(cos(x)).nseries(x, n=5) == \ + sin(1) - x**2*cos(1)/2 - x**4*sin(1)/8 + x**4*cos(1)/24 + O(x**5) + + +def test_hyperbolic(): + assert sinh(x).nseries(x, n=6) == x + x**3/6 + x**5/120 + O(x**6) + assert cosh(x).nseries(x, n=5) == 1 + x**2/2 + x**4/24 + O(x**5) + assert tanh(x).nseries(x, n=6) == x - x**3/3 + 2*x**5/15 + O(x**6) + assert coth(x).nseries(x, n=6) == \ + 1/x - x**3/45 + x/3 + 2*x**5/945 + O(x**6) + assert asinh(x).nseries(x, n=6) == x - x**3/6 + 3*x**5/40 + O(x**6) + assert acosh(x).nseries(x, n=6) == \ + pi*I/2 - I*x - 3*I*x**5/40 - I*x**3/6 + O(x**6) + assert atanh(x).nseries(x, n=6) == x + x**3/3 + x**5/5 + O(x**6) + assert acoth(x).nseries(x, n=6) == -I*pi/2 + x + x**3/3 + x**5/5 + O(x**6) + + +def test_series2(): + w = Symbol("w", real=True) + x = Symbol("x", real=True) + e = w**(-2)*(w*exp(1/x - w) - w*exp(1/x)) + assert e.nseries(w, n=4) == -exp(1/x) + w*exp(1/x)/2 - w**2*exp(1/x)/6 + w**3*exp(1/x)/24 + O(w**4) + + +def test_series3(): + w = Symbol("w", real=True) + e = w**(-6)*(w**3*tan(w) - w**3*sin(w)) + assert e.nseries(w, n=8) == Integer(1)/2 + w**2/8 + 13*w**4/240 + 529*w**6/24192 + O(w**8) + + +def test_bug4(): + w = Symbol("w") + e = x/(w**4 + x**2*w**4 + 2*x*w**4)*w**4 + assert e.nseries(w, n=2).removeO().expand() in [x/(1 + 2*x + x**2), + 1/(1 + x/2 + 1/x/2)/2, 1/x/(1 + 2/x + x**(-2))] + + +def test_bug5(): + w = Symbol("w") + l = Symbol('l') + e = (-log(w) + log(1 + w*log(x)))**(-2)*w**(-2)*((-log(w) + + log(1 + x*w))*(-log(w) + log(1 + w*log(x)))*w - x*(-log(w) + + log(1 + w*log(x)))*w) + assert e.nseries(w, n=0, logx=l) == x/w/l + 1/w + O(1, w) + assert e.nseries(w, n=1, logx=l) == x/w/l + 1/w - x/l + 1/l*log(x) \ + + x*log(x)/l**2 + O(w) + + +def test_issue_4115(): + assert (sin(x)/(1 - cos(x))).nseries(x, n=1) == 2/x + O(x) + assert (sin(x)**2/(1 - cos(x))).nseries(x, n=1) == 2 + O(x) + + +def test_pole(): + raises(PoleError, lambda: sin(1/x).series(x, 0, 5)) + raises(PoleError, lambda: sin(1 + 1/x).series(x, 0, 5)) + raises(PoleError, lambda: (x*sin(1/x)).series(x, 0, 5)) + + +def test_expsinbug(): + assert exp(sin(x)).series(x, 0, 0) == O(1, x) + assert exp(sin(x)).series(x, 0, 1) == 1 + O(x) + assert exp(sin(x)).series(x, 0, 2) == 1 + x + O(x**2) + assert exp(sin(x)).series(x, 0, 3) == 1 + x + x**2/2 + O(x**3) + assert exp(sin(x)).series(x, 0, 4) == 1 + x + x**2/2 + O(x**4) + assert exp(sin(x)).series(x, 0, 5) == 1 + x + x**2/2 - x**4/8 + O(x**5) + + +def test_floor(): + x = Symbol('x') + assert floor(x).series(x) == 0 + assert floor(-x).series(x) == -1 + assert floor(sin(x)).series(x) == 0 + assert floor(sin(-x)).series(x) == -1 + assert floor(x**3).series(x) == 0 + assert floor(-x**3).series(x) == -1 + assert floor(cos(x)).series(x) == 0 + assert floor(cos(-x)).series(x) == 0 + assert floor(5 + sin(x)).series(x) == 5 + assert floor(5 + sin(-x)).series(x) == 4 + + assert floor(x).series(x, 2) == 2 + assert floor(-x).series(x, 2) == -3 + + x = Symbol('x', negative=True) + assert floor(x + 1.5).series(x) == 1 + + +def test_frac(): + assert frac(x).series(x, cdir=1) == x + assert frac(x).series(x, cdir=-1) == 1 + x + assert frac(2*x + 1).series(x, cdir=1) == 2*x + assert frac(2*x + 1).series(x, cdir=-1) == 1 + 2*x + assert frac(x**2).series(x, cdir=1) == x**2 + assert frac(x**2).series(x, cdir=-1) == x**2 + assert frac(sin(x) + 5).series(x, cdir=1) == x - x**3/6 + x**5/120 + O(x**6) + assert frac(sin(x) + 5).series(x, cdir=-1) == 1 + x - x**3/6 + x**5/120 + O(x**6) + assert frac(sin(x) + S.Half).series(x) == S.Half + x - x**3/6 + x**5/120 + O(x**6) + assert frac(x**8).series(x, cdir=1) == O(x**6) + assert frac(1/x).series(x) == AccumBounds(0, 1) + O(x**6) + + +def test_ceiling(): + assert ceiling(x).series(x) == 1 + assert ceiling(-x).series(x) == 0 + assert ceiling(sin(x)).series(x) == 1 + assert ceiling(sin(-x)).series(x) == 0 + assert ceiling(1 - cos(x)).series(x) == 1 + assert ceiling(1 - cos(-x)).series(x) == 1 + assert ceiling(x).series(x, 2) == 3 + assert ceiling(-x).series(x, 2) == -2 + + +def test_abs(): + a = Symbol('a') + assert abs(x).nseries(x, n=4) == x + assert abs(-x).nseries(x, n=4) == x + assert abs(x + 1).nseries(x, n=4) == x + 1 + assert abs(sin(x)).nseries(x, n=4) == x - Rational(1, 6)*x**3 + O(x**4) + assert abs(sin(-x)).nseries(x, n=4) == x - Rational(1, 6)*x**3 + O(x**4) + assert abs(x - a).nseries(x, 1) == -a*sign(1 - a) + (x - 1)*sign(1 - a) + sign(1 - a) + + +def test_dir(): + assert abs(x).series(x, 0, dir="+") == x + assert abs(x).series(x, 0, dir="-") == -x + assert floor(x + 2).series(x, 0, dir='+') == 2 + assert floor(x + 2).series(x, 0, dir='-') == 1 + assert floor(x + 2.2).series(x, 0, dir='-') == 2 + assert ceiling(x + 2.2).series(x, 0, dir='-') == 3 + assert sin(x + y).series(x, 0, dir='-') == sin(x + y).series(x, 0, dir='+') + + +def test_cdir(): + assert abs(x).series(x, 0, cdir=1) == x + assert abs(x).series(x, 0, cdir=-1) == -x + assert floor(x + 2).series(x, 0, cdir=1) == 2 + assert floor(x + 2).series(x, 0, cdir=-1) == 1 + assert floor(x + 2.2).series(x, 0, cdir=1) == 2 + assert ceiling(x + 2.2).series(x, 0, cdir=-1) == 3 + assert sin(x + y).series(x, 0, cdir=-1) == sin(x + y).series(x, 0, cdir=1) + + +def test_issue_3504(): + a = Symbol("a") + e = asin(a*x)/x + assert e.series(x, 4, n=2).removeO() == \ + (x - 4)*(a/(4*sqrt(-16*a**2 + 1)) - asin(4*a)/16) + asin(4*a)/4 + + +def test_issue_4441(): + a, b = symbols('a,b') + f = 1/(1 + a*x) + assert f.series(x, 0, 5) == 1 - a*x + a**2*x**2 - a**3*x**3 + \ + a**4*x**4 + O(x**5) + f = 1/(1 + (a + b)*x) + assert f.series(x, 0, 3) == 1 + x*(-a - b)\ + + x**2*(a + b)**2 + O(x**3) + + +def test_issue_4329(): + assert tan(x).series(x, pi/2, n=3).removeO() == \ + -pi/6 + x/3 - 1/(x - pi/2) + assert cot(x).series(x, pi, n=3).removeO() == \ + -x/3 + pi/3 + 1/(x - pi) + assert limit(tan(x)**tan(2*x), x, pi/4) == exp(-1) + + +def test_issue_5183(): + assert abs(x + x**2).series(n=1) == O(x) + assert abs(x + x**2).series(n=2) == x + O(x**2) + assert ((1 + x)**2).series(x, n=6) == x**2 + 2*x + 1 + assert (1 + 1/x).series() == 1 + 1/x + assert Derivative(exp(x).series(), x).doit() == \ + 1 + x + x**2/2 + x**3/6 + x**4/24 + O(x**5) + + +def test_issue_5654(): + a = Symbol('a') + assert (1/(x**2+a**2)**2).nseries(x, x0=I*a, n=0) == \ + -I/(4*a**3*(-I*a + x)) - 1/(4*a**2*(-I*a + x)**2) + O(1, (x, I*a)) + assert (1/(x**2+a**2)**2).nseries(x, x0=I*a, n=1) == 3/(16*a**4) \ + -I/(4*a**3*(-I*a + x)) - 1/(4*a**2*(-I*a + x)**2) + O(-I*a + x, (x, I*a)) + + +def test_issue_5925(): + sx = sqrt(x + z).series(z, 0, 1) + sxy = sqrt(x + y + z).series(z, 0, 1) + s1, s2 = sx.subs(x, x + y), sxy + assert (s1 - s2).expand().removeO().simplify() == 0 + + sx = sqrt(x + z).series(z, 0, 1) + sxy = sqrt(x + y + z).series(z, 0, 1) + assert sxy.subs({x:1, y:2}) == sx.subs(x, 3) + + +def test_exp_2(): + assert exp(x**3).nseries(x, 0, 14) == 1 + x**3 + x**6/2 + x**9/6 + x**12/24 + O(x**14) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_order.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_order.py new file mode 100644 index 0000000000000000000000000000000000000000..50fcb861ee2a76c730baae6d26cc1e7a00347176 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_order.py @@ -0,0 +1,503 @@ +from sympy.core.add import Add +from sympy.core.function import (Function, expand) +from sympy.core.numbers import (I, Rational, nan, oo, pi) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.combinatorial.factorials import factorial +from sympy.functions.elementary.complexes import (conjugate, transpose) +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.integrals.integrals import Integral +from sympy.series.order import O, Order +from sympy.core.expr import unchanged +from sympy.testing.pytest import raises +from sympy.abc import w, x, y, z +from sympy.testing.pytest import XFAIL + + +def test_caching_bug(): + #needs to be a first test, so that all caches are clean + #cache it + O(w) + #and test that this won't raise an exception + O(w**(-1/x/log(3)*log(5)), w) + + +def test_free_symbols(): + assert Order(1).free_symbols == set() + assert Order(x).free_symbols == {x} + assert Order(1, x).free_symbols == {x} + assert Order(x*y).free_symbols == {x, y} + assert Order(x, x, y).free_symbols == {x, y} + + +def test_simple_1(): + o = Rational(0) + assert Order(2*x) == Order(x) + assert Order(x)*3 == Order(x) + assert -28*Order(x) == Order(x) + assert Order(Order(x)) == Order(x) + assert Order(Order(x), y) == Order(Order(x), x, y) + assert Order(-23) == Order(1) + assert Order(exp(x)) == Order(1, x) + assert Order(exp(1/x)).expr == exp(1/x) + assert Order(x*exp(1/x)).expr == x*exp(1/x) + assert Order(x**(o/3)).expr == x**(o/3) + assert Order(x**(o*Rational(5, 3))).expr == x**(o*Rational(5, 3)) + assert Order(x**2 + x + y, x) == O(1, x) + assert Order(x**2 + x + y, y) == O(1, y) + raises(ValueError, lambda: Order(exp(x), x, x)) + raises(TypeError, lambda: Order(x, 2 - x)) + + +def test_simple_2(): + assert Order(2*x)*x == Order(x**2) + assert Order(2*x)/x == Order(1, x) + assert Order(2*x)*x*exp(1/x) == Order(x**2*exp(1/x)) + assert (Order(2*x)*x*exp(1/x)/log(x)**3).expr == x**2*exp(1/x)*log(x)**-3 + + +def test_simple_3(): + assert Order(x) + x == Order(x) + assert Order(x) + 2 == 2 + Order(x) + assert Order(x) + x**2 == Order(x) + assert Order(x) + 1/x == 1/x + Order(x) + assert Order(1/x) + 1/x**2 == 1/x**2 + Order(1/x) + assert Order(x) + exp(1/x) == Order(x) + exp(1/x) + + +def test_simple_4(): + assert Order(x)**2 == Order(x**2) + + +def test_simple_5(): + assert Order(x) + Order(x**2) == Order(x) + assert Order(x) + Order(x**-2) == Order(x**-2) + assert Order(x) + Order(1/x) == Order(1/x) + + +def test_simple_6(): + assert Order(x) - Order(x) == Order(x) + assert Order(x) + Order(1) == Order(1) + assert Order(x) + Order(x**2) == Order(x) + assert Order(1/x) + Order(1) == Order(1/x) + assert Order(x) + Order(exp(1/x)) == Order(exp(1/x)) + assert Order(x**3) + Order(exp(2/x)) == Order(exp(2/x)) + assert Order(x**-3) + Order(exp(2/x)) == Order(exp(2/x)) + + +def test_simple_7(): + assert 1 + O(1) == O(1) + assert 2 + O(1) == O(1) + assert x + O(1) == O(1) + assert 1/x + O(1) == 1/x + O(1) + + +def test_simple_8(): + assert O(sqrt(-x)) == O(sqrt(x)) + assert O(x**2*sqrt(x)) == O(x**Rational(5, 2)) + assert O(x**3*sqrt(-(-x)**3)) == O(x**Rational(9, 2)) + assert O(x**Rational(3, 2)*sqrt((-x)**3)) == O(x**3) + assert O(x*(-2*x)**(I/2)) == O(x*(-x)**(I/2)) + + +def test_as_expr_variables(): + assert Order(x).as_expr_variables(None) == (x, ((x, 0),)) + assert Order(x).as_expr_variables(((x, 0),)) == (x, ((x, 0),)) + assert Order(y).as_expr_variables(((x, 0),)) == (y, ((x, 0), (y, 0))) + assert Order(y).as_expr_variables(((x, 0), (y, 0))) == (y, ((x, 0), (y, 0))) + + +def test_contains_0(): + assert Order(1, x).contains(Order(1, x)) + assert Order(1, x).contains(Order(1)) + assert Order(1).contains(Order(1, x)) is False + + +def test_contains_1(): + assert Order(x).contains(Order(x)) + assert Order(x).contains(Order(x**2)) + assert not Order(x**2).contains(Order(x)) + assert not Order(x).contains(Order(1/x)) + assert not Order(1/x).contains(Order(exp(1/x))) + assert not Order(x).contains(Order(exp(1/x))) + assert Order(1/x).contains(Order(x)) + assert Order(exp(1/x)).contains(Order(x)) + assert Order(exp(1/x)).contains(Order(1/x)) + assert Order(exp(1/x)).contains(Order(exp(1/x))) + assert Order(exp(2/x)).contains(Order(exp(1/x))) + assert not Order(exp(1/x)).contains(Order(exp(2/x))) + + +def test_contains_2(): + assert Order(x).contains(Order(y)) is None + assert Order(x).contains(Order(y*x)) + assert Order(y*x).contains(Order(x)) + assert Order(y).contains(Order(x*y)) + assert Order(x).contains(Order(y**2*x)) + + +def test_contains_3(): + assert Order(x*y**2).contains(Order(x**2*y)) is None + assert Order(x**2*y).contains(Order(x*y**2)) is None + + +def test_contains_4(): + assert Order(sin(1/x**2)).contains(Order(cos(1/x**2))) is True + assert Order(cos(1/x**2)).contains(Order(sin(1/x**2))) is True + + +def test_contains(): + assert Order(1, x) not in Order(1) + assert Order(1) in Order(1, x) + raises(TypeError, lambda: Order(x*y**2) in Order(x**2*y)) + + +def test_add_1(): + assert Order(x + x) == Order(x) + assert Order(3*x - 2*x**2) == Order(x) + assert Order(1 + x) == Order(1, x) + assert Order(1 + 1/x) == Order(1/x) + # TODO : A better output for Order(log(x) + 1/log(x)) + # could be Order(log(x)). Currently Order for expressions + # where all arguments would involve a log term would fall + # in this category and outputs for these should be improved. + assert Order(log(x) + 1/log(x)) == Order((log(x)**2 + 1)/log(x)) + assert Order(exp(1/x) + x) == Order(exp(1/x)) + assert Order(exp(1/x) + 1/x**20) == Order(exp(1/x)) + + +def test_ln_args(): + assert O(log(x)) + O(log(2*x)) == O(log(x)) + assert O(log(x)) + O(log(x**3)) == O(log(x)) + assert O(log(x*y)) + O(log(x) + log(y)) == O(log(x) + log(y), x, y) + + +def test_multivar_0(): + assert Order(x*y).expr == x*y + assert Order(x*y**2).expr == x*y**2 + assert Order(x*y, x).expr == x + assert Order(x*y**2, y).expr == y**2 + assert Order(x*y*z).expr == x*y*z + assert Order(x/y).expr == x/y + assert Order(x*exp(1/y)).expr == x*exp(1/y) + assert Order(exp(x)*exp(1/y)).expr == exp(x)*exp(1/y) + + +def test_multivar_0a(): + assert Order(exp(1/x)*exp(1/y)).expr == exp(1/x)*exp(1/y) + + +def test_multivar_1(): + assert Order(x + y).expr == x + y + assert Order(x + 2*y).expr == x + y + assert (Order(x + y) + x).expr == (x + y) + assert (Order(x + y) + x**2) == Order(x + y) + assert (Order(x + y) + 1/x) == 1/x + Order(x + y) + assert Order(x**2 + y*x).expr == x**2 + y*x + + +def test_multivar_2(): + assert Order(x**2*y + y**2*x, x, y).expr == x**2*y + y**2*x + + +def test_multivar_mul_1(): + assert Order(x + y)*x == Order(x**2 + y*x, x, y) + + +def test_multivar_3(): + assert (Order(x) + Order(y)).args in [ + (Order(x), Order(y)), + (Order(y), Order(x))] + assert Order(x) + Order(y) + Order(x + y) == Order(x + y) + assert (Order(x**2*y) + Order(y**2*x)).args in [ + (Order(x*y**2), Order(y*x**2)), + (Order(y*x**2), Order(x*y**2))] + assert (Order(x**2*y) + Order(y*x)) == Order(x*y) + + +def test_issue_3468(): + y = Symbol('y', negative=True) + z = Symbol('z', complex=True) + + # check that Order does not modify assumptions about symbols + Order(x) + Order(y) + Order(z) + + assert x.is_positive is None + assert y.is_positive is False + assert z.is_positive is None + + +def test_leading_order(): + assert (x + 1 + 1/x**5).extract_leading_order(x) == ((1/x**5, O(1/x**5)),) + assert (1 + 1/x).extract_leading_order(x) == ((1/x, O(1/x)),) + assert (1 + x).extract_leading_order(x) == ((1, O(1, x)),) + assert (1 + x**2).extract_leading_order(x) == ((1, O(1, x)),) + assert (2 + x**2).extract_leading_order(x) == ((2, O(1, x)),) + assert (x + x**2).extract_leading_order(x) == ((x, O(x)),) + + +def test_leading_order2(): + assert set((2 + pi + x**2).extract_leading_order(x)) == {(pi, O(1, x)), + (S(2), O(1, x))} + assert set((2*x + pi*x + x**2).extract_leading_order(x)) == {(2*x, O(x)), + (x*pi, O(x))} + + +def test_order_leadterm(): + assert O(x**2)._eval_as_leading_term(x, None, 1) == O(x**2) + + +def test_order_symbols(): + e = x*y*sin(x)*Integral(x, (x, 1, 2)) + assert O(e) == O(x**2*y, x, y) + assert O(e, x) == O(x**2) + + +def test_nan(): + assert O(nan) is nan + assert not O(x).contains(nan) + + +def test_O1(): + assert O(1, x) * x == O(x) + assert O(1, y) * x == O(1, y) + + +def test_getn(): + # other lines are tested incidentally by the suite + assert O(x).getn() == 1 + assert O(x/log(x)).getn() == 1 + assert O(x**2/log(x)**2).getn() == 2 + assert O(x*log(x)).getn() == 1 + raises(NotImplementedError, lambda: (O(x) + O(y)).getn()) + + +def test_diff(): + assert O(x**2).diff(x) == O(x) + + +def test_getO(): + assert (x).getO() is None + assert (x).removeO() == x + assert (O(x)).getO() == O(x) + assert (O(x)).removeO() == 0 + assert (z + O(x) + O(y)).getO() == O(x) + O(y) + assert (z + O(x) + O(y)).removeO() == z + raises(NotImplementedError, lambda: (O(x) + O(y)).getn()) + + +def test_leading_term(): + from sympy.functions.special.gamma_functions import digamma + assert O(1/digamma(1/x)) == O(1/log(x)) + + +def test_eval(): + assert Order(x).subs(Order(x), 1) == 1 + assert Order(x).subs(x, y) == Order(y) + assert Order(x).subs(y, x) == Order(x) + assert Order(x).subs(x, x + y) == Order(x + y, (x, -y)) + assert (O(1)**x).is_Pow + + +def test_issue_4279(): + a, b = symbols('a b') + assert O(a, a, b) + O(1, a, b) == O(1, a, b) + assert O(b, a, b) + O(1, a, b) == O(1, a, b) + assert O(a + b, a, b) + O(1, a, b) == O(1, a, b) + assert O(1, a, b) + O(a, a, b) == O(1, a, b) + assert O(1, a, b) + O(b, a, b) == O(1, a, b) + assert O(1, a, b) + O(a + b, a, b) == O(1, a, b) + + +def test_issue_4855(): + assert 1/O(1) != O(1) + assert 1/O(x) != O(1/x) + assert 1/O(x, (x, oo)) != O(1/x, (x, oo)) + + f = Function('f') + assert 1/O(f(x)) != O(1/x) + + +def test_order_conjugate_transpose(): + x = Symbol('x', real=True) + y = Symbol('y', imaginary=True) + assert conjugate(Order(x)) == Order(conjugate(x)) + assert conjugate(Order(y)) == Order(conjugate(y)) + assert conjugate(Order(x**2)) == Order(conjugate(x)**2) + assert conjugate(Order(y**2)) == Order(conjugate(y)**2) + assert transpose(Order(x)) == Order(transpose(x)) + assert transpose(Order(y)) == Order(transpose(y)) + assert transpose(Order(x**2)) == Order(transpose(x)**2) + assert transpose(Order(y**2)) == Order(transpose(y)**2) + + +def test_order_noncommutative(): + A = Symbol('A', commutative=False) + assert Order(A + A*x, x) == Order(1, x) + assert (A + A*x)*Order(x) == Order(x) + assert (A*x)*Order(x) == Order(x**2, x) + assert expand((1 + Order(x))*A*A*x) == A*A*x + Order(x**2, x) + assert expand((A*A + Order(x))*x) == A*A*x + Order(x**2, x) + assert expand((A + Order(x))*A*x) == A*A*x + Order(x**2, x) + + +def test_issue_6753(): + assert (1 + x**2)**10000*O(x) == O(x) + + +def test_order_at_infinity(): + assert Order(1 + x, (x, oo)) == Order(x, (x, oo)) + assert Order(3*x, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo))*3 == Order(x, (x, oo)) + assert -28*Order(x, (x, oo)) == Order(x, (x, oo)) + assert Order(Order(x, (x, oo)), (x, oo)) == Order(x, (x, oo)) + assert Order(Order(x, (x, oo)), (y, oo)) == Order(x, (x, oo), (y, oo)) + assert Order(3, (x, oo)) == Order(1, (x, oo)) + assert Order(x**2 + x + y, (x, oo)) == O(x**2, (x, oo)) + assert Order(x**2 + x + y, (y, oo)) == O(y, (y, oo)) + + assert Order(2*x, (x, oo))*x == Order(x**2, (x, oo)) + assert Order(2*x, (x, oo))/x == Order(1, (x, oo)) + assert Order(2*x, (x, oo))*x*exp(1/x) == Order(x**2*exp(1/x), (x, oo)) + assert Order(2*x, (x, oo))*x*exp(1/x)/log(x)**3 == Order(x**2*exp(1/x)*log(x)**-3, (x, oo)) + + assert Order(x, (x, oo)) + 1/x == 1/x + Order(x, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo)) + 1 == 1 + Order(x, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo)) + x == x + Order(x, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo)) + x**2 == x**2 + Order(x, (x, oo)) + assert Order(1/x, (x, oo)) + 1/x**2 == 1/x**2 + Order(1/x, (x, oo)) == Order(1/x, (x, oo)) + assert Order(x, (x, oo)) + exp(1/x) == exp(1/x) + Order(x, (x, oo)) + + assert Order(x, (x, oo))**2 == Order(x**2, (x, oo)) + + assert Order(x, (x, oo)) + Order(x**2, (x, oo)) == Order(x**2, (x, oo)) + assert Order(x, (x, oo)) + Order(x**-2, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo)) + Order(1/x, (x, oo)) == Order(x, (x, oo)) + + assert Order(x, (x, oo)) - Order(x, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo)) + Order(1, (x, oo)) == Order(x, (x, oo)) + assert Order(x, (x, oo)) + Order(x**2, (x, oo)) == Order(x**2, (x, oo)) + assert Order(1/x, (x, oo)) + Order(1, (x, oo)) == Order(1, (x, oo)) + assert Order(x, (x, oo)) + Order(exp(1/x), (x, oo)) == Order(x, (x, oo)) + assert Order(x**3, (x, oo)) + Order(exp(2/x), (x, oo)) == Order(x**3, (x, oo)) + assert Order(x**-3, (x, oo)) + Order(exp(2/x), (x, oo)) == Order(exp(2/x), (x, oo)) + + # issue 7207 + assert Order(exp(x), (x, oo)).expr == Order(2*exp(x), (x, oo)).expr == exp(x) + assert Order(y**x, (x, oo)).expr == Order(2*y**x, (x, oo)).expr == exp(x*log(y)) + + # issue 19545 + assert Order(1/x - 3/(3*x + 2), (x, oo)).expr == x**(-2) + +def test_mixing_order_at_zero_and_infinity(): + assert (Order(x, (x, 0)) + Order(x, (x, oo))).is_Add + assert Order(x, (x, 0)) + Order(x, (x, oo)) == Order(x, (x, oo)) + Order(x, (x, 0)) + assert Order(Order(x, (x, oo))) == Order(x, (x, oo)) + + # not supported (yet) + raises(NotImplementedError, lambda: Order(x, (x, 0))*Order(x, (x, oo))) + raises(NotImplementedError, lambda: Order(x, (x, oo))*Order(x, (x, 0))) + raises(NotImplementedError, lambda: Order(Order(x, (x, oo)), y)) + raises(NotImplementedError, lambda: Order(Order(x), (x, oo))) + + +def test_order_at_some_point(): + assert Order(x, (x, 1)) == Order(1, (x, 1)) + assert Order(2*x - 2, (x, 1)) == Order(x - 1, (x, 1)) + assert Order(-x + 1, (x, 1)) == Order(x - 1, (x, 1)) + assert Order(x - 1, (x, 1))**2 == Order((x - 1)**2, (x, 1)) + assert Order(x - 2, (x, 2)) - O(x - 2, (x, 2)) == Order(x - 2, (x, 2)) + + +def test_order_subs_limits(): + # issue 3333 + assert (1 + Order(x)).subs(x, 1/x) == 1 + Order(1/x, (x, oo)) + assert (1 + Order(x)).limit(x, 0) == 1 + # issue 5769 + assert ((x + Order(x**2))/x).limit(x, 0) == 1 + + assert Order(x**2).subs(x, y - 1) == Order((y - 1)**2, (y, 1)) + assert Order(10*x**2, (x, 2)).subs(x, y - 1) == Order(1, (y, 3)) + + #issue 19120 + assert O(x).subs(x, O(x)) == O(x) + assert O(x**2).subs(x, x + O(x)) == O(x**2) + assert O(x, (x, oo)).subs(x, O(x, (x, oo))) == O(x, (x, oo)) + assert O(x**2, (x, oo)).subs(x, x + O(x, (x, oo))) == O(x**2, (x, oo)) + assert (x + O(x**2)).subs(x, x + O(x**2)) == x + O(x**2) + assert (x**2 + O(x**2) + 1/x**2).subs(x, x + O(x**2)) == (x + O(x**2))**(-2) + O(x**2) + assert (x**2 + O(x**2) + 1).subs(x, x + O(x**2)) == 1 + O(x**2) + assert O(x, (x, oo)).subs(x, x + O(x**2, (x, oo))) == O(x**2, (x, oo)) + assert sin(x).series(n=8).subs(x,sin(x).series(n=8)).expand() == x - x**3/3 + x**5/10 - 8*x**7/315 + O(x**8) + assert cos(x).series(n=8).subs(x,sin(x).series(n=8)).expand() == 1 - x**2/2 + 5*x**4/24 - 37*x**6/720 + O(x**8) + assert O(x).subs(x, O(1/x, (x, oo))) == O(1/x, (x, oo)) + +@XFAIL +def test_order_failing_due_to_solveset(): + assert O(x**3).subs(x, exp(-x**2)) == O(exp(-3*x**2), (x, -oo)) + raises(NotImplementedError, lambda: O(x).subs(x, O(1/x))) # mixing of order at different points + + +def test_issue_9351(): + assert exp(x).series(x, 10, 1) == exp(10) + Order(x - 10, (x, 10)) + + +def test_issue_9192(): + assert O(1)*O(1) == O(1) + assert O(1)**O(1) == O(1) + + +def test_issue_9910(): + assert O(x*log(x) + sin(x), (x, oo)) == O(x*log(x), (x, oo)) + + +def test_performance_of_adding_order(): + l = [x**i for i in range(1000)] + l.append(O(x**1001)) + assert Add(*l).subs(x,1) == O(1) + +def test_issue_14622(): + assert (x**(-4) + x**(-3) + x**(-1) + O(x**(-6), (x, oo))).as_numer_denom() == ( + x**4 + x**5 + x**7 + O(x**2, (x, oo)), x**8) + assert (x**3 + O(x**2, (x, oo))).is_Add + assert O(x**2, (x, oo)).contains(x**3) is False + assert O(x, (x, oo)).contains(O(x, (x, 0))) is None + assert O(x, (x, 0)).contains(O(x, (x, oo))) is None + raises(NotImplementedError, lambda: O(x**3).contains(x**w)) + + +def test_issue_15539(): + assert O(1/x**2 + 1/x**4, (x, -oo)) == O(1/x**2, (x, -oo)) + assert O(1/x**4 + exp(x), (x, -oo)) == O(1/x**4, (x, -oo)) + assert O(1/x**4 + exp(-x), (x, -oo)) == O(exp(-x), (x, -oo)) + assert O(1/x, (x, oo)).subs(x, -x) == O(-1/x, (x, -oo)) + +def test_issue_18606(): + assert unchanged(Order, 0) + + +def test_issue_22165(): + assert O(log(x)).contains(2) + + +def test_issue_23231(): + # This test checks Order for expressions having + # arguments containing variables in exponents/powers. + assert O(x**x + 2**x, (x, oo)) == O(exp(x*log(x)), (x, oo)) + assert O(x**x + x**2, (x, oo)) == O(exp(x*log(x)), (x, oo)) + assert O(x**x + 1/x**2, (x, oo)) == O(exp(x*log(x)), (x, oo)) + assert O(2**x + 3**x , (x, oo)) == O(exp(x*log(3)), (x, oo)) + + +def test_issue_9917(): + assert O(x*sin(x) + 1, (x, oo)) == O(x, (x, oo)) + + +def test_issue_22836(): + assert O(2**x + factorial(x), (x, oo)) == O(factorial(x), (x, oo)) + assert O(2**x + factorial(x) + x**x, (x, oo)) == O(exp(x*log(x)), (x, oo)) + assert O(x + factorial(x), (x, oo)) == O(factorial(x), (x, oo)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_residues.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_residues.py new file mode 100644 index 0000000000000000000000000000000000000000..9f7d075a56500d008e3c8b46c1fda5db890fd76a --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_residues.py @@ -0,0 +1,101 @@ +from sympy.core.function import Function +from sympy.core.numbers import (I, Rational, pi) +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.functions.combinatorial.factorials import factorial +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.hyperbolic import tanh +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cot, sin, tan) +from sympy.series.residues import residue +from sympy.testing.pytest import XFAIL, raises +from sympy.abc import x, z, a, s, k + + +def test_basic1(): + assert residue(1/x, x, 0) == 1 + assert residue(-2/x, x, 0) == -2 + assert residue(81/x, x, 0) == 81 + assert residue(1/x**2, x, 0) == 0 + assert residue(0, x, 0) == 0 + assert residue(5, x, 0) == 0 + assert residue(x, x, 0) == 0 + assert residue(x**2, x, 0) == 0 + + +def test_basic2(): + assert residue(1/x, x, 1) == 0 + assert residue(-2/x, x, 1) == 0 + assert residue(81/x, x, -1) == 0 + assert residue(1/x**2, x, 1) == 0 + assert residue(0, x, 1) == 0 + assert residue(5, x, 1) == 0 + assert residue(x, x, 1) == 0 + assert residue(x**2, x, 5) == 0 + + +def test_f(): + f = Function("f") + assert residue(f(x)/x**5, x, 0) == f(x).diff(x, 4).subs(x, 0)/24 + + +def test_functions(): + assert residue(1/sin(x), x, 0) == 1 + assert residue(2/sin(x), x, 0) == 2 + assert residue(1/sin(x)**2, x, 0) == 0 + assert residue(1/sin(x)**5, x, 0) == Rational(3, 8) + + +def test_expressions(): + assert residue(1/(x + 1), x, 0) == 0 + assert residue(1/(x + 1), x, -1) == 1 + assert residue(1/(x**2 + 1), x, -1) == 0 + assert residue(1/(x**2 + 1), x, I) == -I/2 + assert residue(1/(x**2 + 1), x, -I) == I/2 + assert residue(1/(x**4 + 1), x, 0) == 0 + assert residue(1/(x**4 + 1), x, exp(I*pi/4)).equals(-(Rational(1, 4) + I/4)/sqrt(2)) + assert residue(1/(x**2 + a**2)**2, x, a*I) == -I/4/a**3 + + +@XFAIL +def test_expressions_failing(): + n = Symbol('n', integer=True, positive=True) + assert residue(exp(z)/(z - pi*I/4*a)**n, z, I*pi*a) == \ + exp(I*pi*a/4)/factorial(n - 1) + + +def test_NotImplemented(): + raises(NotImplementedError, lambda: residue(exp(1/z), z, 0)) + + +def test_bug(): + assert residue(2**(z)*(s + z)*(1 - s - z)/z**2, z, 0) == \ + 1 + s*log(2) - s**2*log(2) - 2*s + + +def test_issue_5654(): + assert residue(1/(x**2 + a**2)**2, x, a*I) == -I/(4*a**3) + assert residue(1/s*1/(z - exp(s)), s, 0) == 1/(z - 1) + assert residue((1 + k)/s*1/(z - exp(s)), s, 0) == k/(z - 1) + 1/(z - 1) + + +def test_issue_6499(): + assert residue(1/(exp(z) - 1), z, 0) == 1 + + +def test_issue_14037(): + assert residue(sin(x**50)/x**51, x, 0) == 1 + + +def test_issue_21176(): + f = x**2*cot(pi*x)/(x**4 + 1) + assert residue(f, x, -sqrt(2)/2 - sqrt(2)*I/2).cancel().together(deep=True)\ + == sqrt(2)*(1 - I)/(8*tan(sqrt(2)*pi*(1 + I)/2)) + + +def test_issue_21177(): + r = -sqrt(3)*tanh(sqrt(3)*pi/2)/3 + a = residue(cot(pi*x)/((x - 1)*(x - 2) + 1), x, S(3)/2 - sqrt(3)*I/2) + b = residue(cot(pi*x)/(x**2 - 3*x + 3), x, S(3)/2 - sqrt(3)*I/2) + assert a == r + assert (b - a).cancel() == 0 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_sequences.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_sequences.py new file mode 100644 index 0000000000000000000000000000000000000000..61e276ad67982f0a9877de3548d70238976d28a5 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_sequences.py @@ -0,0 +1,312 @@ +from sympy.core.containers import Tuple +from sympy.core.function import Function +from sympy.core.numbers import oo, Rational +from sympy.core.singleton import S +from sympy.core.symbol import symbols, Symbol +from sympy.functions.combinatorial.numbers import tribonacci, fibonacci +from sympy.functions.elementary.exponential import exp +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import cos, sin +from sympy.series import EmptySequence +from sympy.series.sequences import (SeqMul, SeqAdd, SeqPer, SeqFormula, + sequence) +from sympy.sets.sets import Interval +from sympy.tensor.indexed import Indexed, Idx +from sympy.series.sequences import SeqExpr, SeqExprOp, RecursiveSeq +from sympy.testing.pytest import raises, slow + +x, y, z = symbols('x y z') +n, m = symbols('n m') + + +def test_EmptySequence(): + assert S.EmptySequence is EmptySequence + + assert S.EmptySequence.interval is S.EmptySet + assert S.EmptySequence.length is S.Zero + + assert list(S.EmptySequence) == [] + + +def test_SeqExpr(): + #SeqExpr is a baseclass and does not take care of + #ensuring all arguments are Basics hence the use of + #Tuple(...) here. + s = SeqExpr(Tuple(1, n, y), Tuple(x, 0, 10)) + + assert isinstance(s, SeqExpr) + assert s.gen == (1, n, y) + assert s.interval == Interval(0, 10) + assert s.start == 0 + assert s.stop == 10 + assert s.length == 11 + assert s.variables == (x,) + + assert SeqExpr(Tuple(1, 2, 3), Tuple(x, 0, oo)).length is oo + + +def test_SeqPer(): + s = SeqPer((1, n, 3), (x, 0, 5)) + + assert isinstance(s, SeqPer) + assert s.periodical == Tuple(1, n, 3) + assert s.period == 3 + assert s.coeff(3) == 1 + assert s.free_symbols == {n} + + assert list(s) == [1, n, 3, 1, n, 3] + assert s[:] == [1, n, 3, 1, n, 3] + assert SeqPer((1, n, 3), (x, -oo, 0))[0:6] == [1, n, 3, 1, n, 3] + + raises(ValueError, lambda: SeqPer((1, 2, 3), (0, 1, 2))) + raises(ValueError, lambda: SeqPer((1, 2, 3), (x, -oo, oo))) + raises(ValueError, lambda: SeqPer(n**2, (0, oo))) + + assert SeqPer((n, n**2, n**3), (m, 0, oo))[:6] == \ + [n, n**2, n**3, n, n**2, n**3] + assert SeqPer((n, n**2, n**3), (n, 0, oo))[:6] == [0, 1, 8, 3, 16, 125] + assert SeqPer((n, m), (n, 0, oo))[:6] == [0, m, 2, m, 4, m] + + +def test_SeqFormula(): + s = SeqFormula(n**2, (n, 0, 5)) + + assert isinstance(s, SeqFormula) + assert s.formula == n**2 + assert s.coeff(3) == 9 + + assert list(s) == [i**2 for i in range(6)] + assert s[:] == [i**2 for i in range(6)] + assert SeqFormula(n**2, (n, -oo, 0))[0:6] == [i**2 for i in range(6)] + + assert SeqFormula(n**2, (0, oo)) == SeqFormula(n**2, (n, 0, oo)) + + assert SeqFormula(n**2, (0, m)).subs(m, x) == SeqFormula(n**2, (0, x)) + assert SeqFormula(m*n**2, (n, 0, oo)).subs(m, x) == \ + SeqFormula(x*n**2, (n, 0, oo)) + + raises(ValueError, lambda: SeqFormula(n**2, (0, 1, 2))) + raises(ValueError, lambda: SeqFormula(n**2, (n, -oo, oo))) + raises(ValueError, lambda: SeqFormula(m*n**2, (0, oo))) + + seq = SeqFormula(x*(y**2 + z), (z, 1, 100)) + assert seq.expand() == SeqFormula(x*y**2 + x*z, (z, 1, 100)) + seq = SeqFormula(sin(x*(y**2 + z)),(z, 1, 100)) + assert seq.expand(trig=True) == SeqFormula(sin(x*y**2)*cos(x*z) + sin(x*z)*cos(x*y**2), (z, 1, 100)) + assert seq.expand() == SeqFormula(sin(x*y**2 + x*z), (z, 1, 100)) + assert seq.expand(trig=False) == SeqFormula(sin(x*y**2 + x*z), (z, 1, 100)) + seq = SeqFormula(exp(x*(y**2 + z)), (z, 1, 100)) + assert seq.expand() == SeqFormula(exp(x*y**2)*exp(x*z), (z, 1, 100)) + assert seq.expand(power_exp=False) == SeqFormula(exp(x*y**2 + x*z), (z, 1, 100)) + assert seq.expand(mul=False, power_exp=False) == SeqFormula(exp(x*(y**2 + z)), (z, 1, 100)) + +def test_sequence(): + form = SeqFormula(n**2, (n, 0, 5)) + per = SeqPer((1, 2, 3), (n, 0, 5)) + inter = SeqFormula(n**2) + + assert sequence(n**2, (n, 0, 5)) == form + assert sequence((1, 2, 3), (n, 0, 5)) == per + assert sequence(n**2) == inter + + +def test_SeqExprOp(): + form = SeqFormula(n**2, (n, 0, 10)) + per = SeqPer((1, 2, 3), (m, 5, 10)) + + s = SeqExprOp(form, per) + assert s.gen == (n**2, (1, 2, 3)) + assert s.interval == Interval(5, 10) + assert s.start == 5 + assert s.stop == 10 + assert s.length == 6 + assert s.variables == (n, m) + + +def test_SeqAdd(): + per = SeqPer((1, 2, 3), (n, 0, oo)) + form = SeqFormula(n**2) + + per_bou = SeqPer((1, 2), (n, 1, 5)) + form_bou = SeqFormula(n**2, (6, 10)) + form_bou2 = SeqFormula(n**2, (1, 5)) + + assert SeqAdd() == S.EmptySequence + assert SeqAdd(S.EmptySequence) == S.EmptySequence + assert SeqAdd(per) == per + assert SeqAdd(per, S.EmptySequence) == per + assert SeqAdd(per_bou, form_bou) == S.EmptySequence + + s = SeqAdd(per_bou, form_bou2, evaluate=False) + assert s.args == (form_bou2, per_bou) + assert s[:] == [2, 6, 10, 18, 26] + assert list(s) == [2, 6, 10, 18, 26] + + assert isinstance(SeqAdd(per, per_bou, evaluate=False), SeqAdd) + + s1 = SeqAdd(per, per_bou) + assert isinstance(s1, SeqPer) + assert s1 == SeqPer((2, 4, 4, 3, 3, 5), (n, 1, 5)) + s2 = SeqAdd(form, form_bou) + assert isinstance(s2, SeqFormula) + assert s2 == SeqFormula(2*n**2, (6, 10)) + + assert SeqAdd(form, form_bou, per) == \ + SeqAdd(per, SeqFormula(2*n**2, (6, 10))) + assert SeqAdd(form, SeqAdd(form_bou, per)) == \ + SeqAdd(per, SeqFormula(2*n**2, (6, 10))) + assert SeqAdd(per, SeqAdd(form, form_bou), evaluate=False) == \ + SeqAdd(per, SeqFormula(2*n**2, (6, 10))) + + assert SeqAdd(SeqPer((1, 2), (n, 0, oo)), SeqPer((1, 2), (m, 0, oo))) == \ + SeqPer((2, 4), (n, 0, oo)) + + +def test_SeqMul(): + per = SeqPer((1, 2, 3), (n, 0, oo)) + form = SeqFormula(n**2) + + per_bou = SeqPer((1, 2), (n, 1, 5)) + form_bou = SeqFormula(n**2, (n, 6, 10)) + form_bou2 = SeqFormula(n**2, (1, 5)) + + assert SeqMul() == S.EmptySequence + assert SeqMul(S.EmptySequence) == S.EmptySequence + assert SeqMul(per) == per + assert SeqMul(per, S.EmptySequence) == S.EmptySequence + assert SeqMul(per_bou, form_bou) == S.EmptySequence + + s = SeqMul(per_bou, form_bou2, evaluate=False) + assert s.args == (form_bou2, per_bou) + assert s[:] == [1, 8, 9, 32, 25] + assert list(s) == [1, 8, 9, 32, 25] + + assert isinstance(SeqMul(per, per_bou, evaluate=False), SeqMul) + + s1 = SeqMul(per, per_bou) + assert isinstance(s1, SeqPer) + assert s1 == SeqPer((1, 4, 3, 2, 2, 6), (n, 1, 5)) + s2 = SeqMul(form, form_bou) + assert isinstance(s2, SeqFormula) + assert s2 == SeqFormula(n**4, (6, 10)) + + assert SeqMul(form, form_bou, per) == \ + SeqMul(per, SeqFormula(n**4, (6, 10))) + assert SeqMul(form, SeqMul(form_bou, per)) == \ + SeqMul(per, SeqFormula(n**4, (6, 10))) + assert SeqMul(per, SeqMul(form, form_bou2, + evaluate=False), evaluate=False) == \ + SeqMul(form, per, form_bou2, evaluate=False) + + assert SeqMul(SeqPer((1, 2), (n, 0, oo)), SeqPer((1, 2), (n, 0, oo))) == \ + SeqPer((1, 4), (n, 0, oo)) + + +def test_add(): + per = SeqPer((1, 2), (n, 0, oo)) + form = SeqFormula(n**2) + + assert per + (SeqPer((2, 3))) == SeqPer((3, 5), (n, 0, oo)) + assert form + SeqFormula(n**3) == SeqFormula(n**2 + n**3) + + assert per + form == SeqAdd(per, form) + + raises(TypeError, lambda: per + n) + raises(TypeError, lambda: n + per) + + +def test_sub(): + per = SeqPer((1, 2), (n, 0, oo)) + form = SeqFormula(n**2) + + assert per - (SeqPer((2, 3))) == SeqPer((-1, -1), (n, 0, oo)) + assert form - (SeqFormula(n**3)) == SeqFormula(n**2 - n**3) + + assert per - form == SeqAdd(per, -form) + + raises(TypeError, lambda: per - n) + raises(TypeError, lambda: n - per) + + +def test_mul__coeff_mul(): + assert SeqPer((1, 2), (n, 0, oo)).coeff_mul(2) == SeqPer((2, 4), (n, 0, oo)) + assert SeqFormula(n**2).coeff_mul(2) == SeqFormula(2*n**2) + assert S.EmptySequence.coeff_mul(100) == S.EmptySequence + + assert SeqPer((1, 2), (n, 0, oo)) * (SeqPer((2, 3))) == \ + SeqPer((2, 6), (n, 0, oo)) + assert SeqFormula(n**2) * SeqFormula(n**3) == SeqFormula(n**5) + + assert S.EmptySequence * SeqFormula(n**2) == S.EmptySequence + assert SeqFormula(n**2) * S.EmptySequence == S.EmptySequence + + raises(TypeError, lambda: sequence(n**2) * n) + raises(TypeError, lambda: n * sequence(n**2)) + + +def test_neg(): + assert -SeqPer((1, -2), (n, 0, oo)) == SeqPer((-1, 2), (n, 0, oo)) + assert -SeqFormula(n**2) == SeqFormula(-n**2) + + +def test_operations(): + per = SeqPer((1, 2), (n, 0, oo)) + per2 = SeqPer((2, 4), (n, 0, oo)) + form = SeqFormula(n**2) + form2 = SeqFormula(n**3) + + assert per + form + form2 == SeqAdd(per, form, form2) + assert per + form - form2 == SeqAdd(per, form, -form2) + assert per + form - S.EmptySequence == SeqAdd(per, form) + assert per + per2 + form == SeqAdd(SeqPer((3, 6), (n, 0, oo)), form) + assert S.EmptySequence - per == -per + assert form + form == SeqFormula(2*n**2) + + assert per * form * form2 == SeqMul(per, form, form2) + assert form * form == SeqFormula(n**4) + assert form * -form == SeqFormula(-n**4) + + assert form * (per + form2) == SeqMul(form, SeqAdd(per, form2)) + assert form * (per + per) == SeqMul(form, per2) + + assert form.coeff_mul(m) == SeqFormula(m*n**2, (n, 0, oo)) + assert per.coeff_mul(m) == SeqPer((m, 2*m), (n, 0, oo)) + + +def test_Idx_limits(): + i = symbols('i', cls=Idx) + r = Indexed('r', i) + + assert SeqFormula(r, (i, 0, 5))[:] == [r.subs(i, j) for j in range(6)] + assert SeqPer((1, 2), (i, 0, 5))[:] == [1, 2, 1, 2, 1, 2] + + +@slow +def test_find_linear_recurrence(): + assert sequence((0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55), \ + (n, 0, 10)).find_linear_recurrence(11) == [1, 1] + assert sequence((1, 2, 4, 7, 28, 128, 582, 2745, 13021, 61699, 292521, \ + 1387138), (n, 0, 11)).find_linear_recurrence(12) == [5, -2, 6, -11] + assert sequence(x*n**3+y*n, (n, 0, oo)).find_linear_recurrence(10) \ + == [4, -6, 4, -1] + assert sequence(x**n, (n,0,20)).find_linear_recurrence(21) == [x] + assert sequence((1,2,3)).find_linear_recurrence(10, 5) == [0, 0, 1] + assert sequence(((1 + sqrt(5))/2)**n + \ + (-(1 + sqrt(5))/2)**(-n)).find_linear_recurrence(10) == [1, 1] + assert sequence(x*((1 + sqrt(5))/2)**n + y*(-(1 + sqrt(5))/2)**(-n), \ + (n,0,oo)).find_linear_recurrence(10) == [1, 1] + assert sequence((1,2,3,4,6),(n, 0, 4)).find_linear_recurrence(5) == [] + assert sequence((2,3,4,5,6,79),(n, 0, 5)).find_linear_recurrence(6,gfvar=x) \ + == ([], None) + assert sequence((2,3,4,5,8,30),(n, 0, 5)).find_linear_recurrence(6,gfvar=x) \ + == ([Rational(19, 2), -20, Rational(27, 2)], (-31*x**2 + 32*x - 4)/(27*x**3 - 40*x**2 + 19*x -2)) + assert sequence(fibonacci(n)).find_linear_recurrence(30,gfvar=x) \ + == ([1, 1], -x/(x**2 + x - 1)) + assert sequence(tribonacci(n)).find_linear_recurrence(30,gfvar=x) \ + == ([1, 1, 1], -x/(x**3 + x**2 + x - 1)) + +def test_RecursiveSeq(): + y = Function('y') + n = Symbol('n') + fib = RecursiveSeq(y(n - 1) + y(n - 2), y(n), n, [0, 1]) + assert fib.coeff(3) == 2 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_series.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_series.py new file mode 100644 index 0000000000000000000000000000000000000000..e3f3c122b98c14a58c6d5c6636cbb53e1e66a75d --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/series/tests/test_series.py @@ -0,0 +1,421 @@ +from sympy.core.evalf import N +from sympy.core.function import (Derivative, Function, PoleError, Subs) +from sympy.core.numbers import (E, Float, Rational, oo, pi, I) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.elementary.exponential import (LambertW, exp, log) +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (atan, cos, sin) +from sympy.functions.special.gamma_functions import gamma +from sympy.integrals.integrals import Integral, integrate +from sympy.series.order import O +from sympy.series.series import series +from sympy.abc import x, y, n, k +from sympy.testing.pytest import raises +from sympy.core import EulerGamma + + +def test_sin(): + e1 = sin(x).series(x, 0) + e2 = series(sin(x), x, 0) + assert e1 == e2 + + +def test_cos(): + e1 = cos(x).series(x, 0) + e2 = series(cos(x), x, 0) + assert e1 == e2 + + +def test_exp(): + e1 = exp(x).series(x, 0) + e2 = series(exp(x), x, 0) + assert e1 == e2 + + +def test_exp2(): + e1 = exp(cos(x)).series(x, 0) + e2 = series(exp(cos(x)), x, 0) + assert e1 == e2 + + +def test_issue_5223(): + assert series(1, x) == 1 + assert next(S.Zero.lseries(x)) == 0 + assert cos(x).series() == cos(x).series(x) + raises(ValueError, lambda: cos(x + y).series()) + raises(ValueError, lambda: x.series(dir="")) + + assert (cos(x).series(x, 1) - + cos(x + 1).series(x).subs(x, x - 1)).removeO() == 0 + e = cos(x).series(x, 1, n=None) + assert [next(e) for i in range(2)] == [cos(1), -((x - 1)*sin(1))] + e = cos(x).series(x, 1, n=None, dir='-') + assert [next(e) for i in range(2)] == [cos(1), (1 - x)*sin(1)] + # the following test is exact so no need for x -> x - 1 replacement + assert abs(x).series(x, 1, dir='-') == x + assert exp(x).series(x, 1, dir='-', n=3).removeO() == \ + E - E*(-x + 1) + E*(-x + 1)**2/2 + + D = Derivative + assert D(x**2 + x**3*y**2, x, 2, y, 1).series(x).doit() == 12*x*y + assert next(D(cos(x), x).lseries()) == D(1, x) + assert D( + exp(x), x).series(n=3) == D(1, x) + D(x, x) + D(x**2/2, x) + D(x**3/6, x) + O(x**3) + + assert Integral(x, (x, 1, 3), (y, 1, x)).series(x) == -4 + 4*x + + assert (1 + x + O(x**2)).getn() == 2 + assert (1 + x).getn() is None + + raises(PoleError, lambda: ((1/sin(x))**oo).series()) + logx = Symbol('logx') + assert ((sin(x))**y).nseries(x, n=1, logx=logx) == \ + exp(y*logx) + O(x*exp(y*logx), x) + + assert sin(1/x).series(x, oo, n=5) == 1/x - 1/(6*x**3) + O(x**(-5), (x, oo)) + assert abs(x).series(x, oo, n=5, dir='+') == x + assert abs(x).series(x, -oo, n=5, dir='-') == -x + assert abs(-x).series(x, oo, n=5, dir='+') == x + assert abs(-x).series(x, -oo, n=5, dir='-') == -x + + assert exp(x*log(x)).series(n=3) == \ + 1 + x*log(x) + x**2*log(x)**2/2 + O(x**3*log(x)**3) + # XXX is this right? If not, fix "ngot > n" handling in expr. + p = Symbol('p', positive=True) + assert exp(sqrt(p)**3*log(p)).series(n=3) == \ + 1 + p**S('3/2')*log(p) + O(p**3*log(p)**3) + + assert exp(sin(x)*log(x)).series(n=2) == 1 + x*log(x) + O(x**2*log(x)**2) + + +def test_issue_6350(): + expr = integrate(exp(k*(y**3 - 3*y)), (y, 0, oo), conds='none') + assert expr.series(k, 0, 3) == -(-1)**(S(2)/3)*sqrt(3)*gamma(S(1)/3)**2*gamma(S(2)/3)/(6*pi*k**(S(1)/3)) - \ + sqrt(3)*k*gamma(-S(2)/3)*gamma(-S(1)/3)/(6*pi) - \ + (-1)**(S(1)/3)*sqrt(3)*k**(S(1)/3)*gamma(-S(1)/3)*gamma(S(1)/3)*gamma(S(2)/3)/(6*pi) - \ + (-1)**(S(2)/3)*sqrt(3)*k**(S(5)/3)*gamma(S(1)/3)**2*gamma(S(2)/3)/(4*pi) - \ + (-1)**(S(1)/3)*sqrt(3)*k**(S(7)/3)*gamma(-S(1)/3)*gamma(S(1)/3)*gamma(S(2)/3)/(8*pi) + O(k**3) + + +def test_issue_11313(): + assert Integral(cos(x), x).series(x) == sin(x).series(x) + assert Derivative(sin(x), x).series(x, n=3).doit() == cos(x).series(x, n=3) + + assert Derivative(x**3, x).as_leading_term(x) == 3*x**2 + assert Derivative(x**3, y).as_leading_term(x) == 0 + assert Derivative(sin(x), x).as_leading_term(x) == 1 + assert Derivative(cos(x), x).as_leading_term(x) == -x + + # This result is equivalent to zero, zero is not return because + # `Expr.series` doesn't currently detect an `x` in its `free_symbol`s. + assert Derivative(1, x).as_leading_term(x) == Derivative(1, x) + + assert Derivative(exp(x), x).series(x).doit() == exp(x).series(x) + assert 1 + Integral(exp(x), x).series(x) == exp(x).series(x) + + assert Derivative(log(x), x).series(x).doit() == (1/x).series(x) + assert Integral(log(x), x).series(x) == Integral(log(x), x).doit().series(x).removeO() + + +def test_series_of_Subs(): + from sympy.abc import z + + subs1 = Subs(sin(x), x, y) + subs2 = Subs(sin(x) * cos(z), x, y) + subs3 = Subs(sin(x * z), (x, z), (y, x)) + + assert subs1.series(x) == subs1 + subs1_series = (Subs(x, x, y) + Subs(-x**3/6, x, y) + + Subs(x**5/120, x, y) + O(y**6)) + assert subs1.series() == subs1_series + assert subs1.series(y) == subs1_series + assert subs1.series(z) == subs1 + assert subs2.series(z) == (Subs(z**4*sin(x)/24, x, y) + + Subs(-z**2*sin(x)/2, x, y) + Subs(sin(x), x, y) + O(z**6)) + assert subs3.series(x).doit() == subs3.doit().series(x) + assert subs3.series(z).doit() == sin(x*y) + + raises(ValueError, lambda: Subs(x + 2*y, y, z).series()) + assert Subs(x + y, y, z).series(x).doit() == x + z + + +def test_issue_3978(): + f = Function('f') + assert f(x).series(x, 0, 3, dir='-') == \ + f(0) + x*Subs(Derivative(f(x), x), x, 0) + \ + x**2*Subs(Derivative(f(x), x, x), x, 0)/2 + O(x**3) + assert f(x).series(x, 0, 3) == \ + f(0) + x*Subs(Derivative(f(x), x), x, 0) + \ + x**2*Subs(Derivative(f(x), x, x), x, 0)/2 + O(x**3) + assert f(x**2).series(x, 0, 3) == \ + f(0) + x**2*Subs(Derivative(f(x), x), x, 0) + O(x**3) + assert f(x**2+1).series(x, 0, 3) == \ + f(1) + x**2*Subs(Derivative(f(x), x), x, 1) + O(x**3) + + class TestF(Function): + pass + + assert TestF(x).series(x, 0, 3) == TestF(0) + \ + x*Subs(Derivative(TestF(x), x), x, 0) + \ + x**2*Subs(Derivative(TestF(x), x, x), x, 0)/2 + O(x**3) + +from sympy.series.acceleration import richardson, shanks +from sympy.concrete.summations import Sum +from sympy.core.numbers import Integer + + +def test_acceleration(): + e = (1 + 1/n)**n + assert round(richardson(e, n, 10, 20).evalf(), 10) == round(E.evalf(), 10) + + A = Sum(Integer(-1)**(k + 1) / k, (k, 1, n)) + assert round(shanks(A, n, 25).evalf(), 4) == round(log(2).evalf(), 4) + assert round(shanks(A, n, 25, 5).evalf(), 10) == round(log(2).evalf(), 10) + + +def test_issue_5852(): + assert series(1/cos(x/log(x)), x, 0) == 1 + x**2/(2*log(x)**2) + \ + 5*x**4/(24*log(x)**4) + O(x**6) + + +def test_issue_4583(): + assert cos(1 + x + x**2).series(x, 0, 5) == cos(1) - x*sin(1) + \ + x**2*(-sin(1) - cos(1)/2) + x**3*(-cos(1) + sin(1)/6) + \ + x**4*(-11*cos(1)/24 + sin(1)/2) + O(x**5) + + +def test_issue_6318(): + eq = (1/x)**Rational(2, 3) + assert (eq + 1).as_leading_term(x) == eq + + +def test_x_is_base_detection(): + eq = (x**2)**Rational(2, 3) + assert eq.series() == x**Rational(4, 3) + + +def test_issue_7203(): + assert series(cos(x), x, pi, 3) == \ + -1 + (x - pi)**2/2 + O((x - pi)**3, (x, pi)) + + +def test_exp_product_positive_factors(): + a, b = symbols('a, b', positive=True) + x = a * b + assert series(exp(x), x, n=8) == 1 + a*b + a**2*b**2/2 + \ + a**3*b**3/6 + a**4*b**4/24 + a**5*b**5/120 + a**6*b**6/720 + \ + a**7*b**7/5040 + O(a**8*b**8, a, b) + + +def test_issue_8805(): + assert series(1, n=8) == 1 + + +def test_issue_9173(): + p0,p1,p2,p3,b0,b1,b2=symbols('p0 p1 p2 p3 b0 b1 b2') + Q=(p0+(p1+(p2+p3/y)/y)/y)/(1+((p3/(b0*y)+(b0*p2-b1*p3)/b0**2)/y+\ + (b0**2*p1-b0*b1*p2-p3*(b0*b2-b1**2))/b0**3)/y) + + series = Q.series(y,n=3) + + assert series == y*(b0*p2/p3+b0*(-p2/p3+b1/b0))+y**2*(b0*p1/p3+b0*p2*\ + (-p2/p3+b1/b0)/p3+b0*(-p1/p3+(p2/p3-b1/b0)**2+b1*p2/(b0*p3)+\ + b2/b0-b1**2/b0**2))+b0+O(y**3) + assert series.simplify() == b2*y**2 + b1*y + b0 + O(y**3) + + +def test_issue_9549(): + y = (x**2 + x + 1) / (x**3 + x**2) + assert series(y, x, oo) == x**(-5) - 1/x**4 + x**(-3) + 1/x + O(x**(-6), (x, oo)) + + +def test_issue_10761(): + assert series(1/(x**-2 + x**-3), x, 0) == x**3 - x**4 + x**5 + O(x**6) + + +def test_issue_12578(): + y = (1 - 1/(x/2 - 1/(2*x))**4)**(S(1)/8) + assert y.series(x, 0, n=17) == 1 - 2*x**4 - 8*x**6 - 34*x**8 - 152*x**10 - 714*x**12 - \ + 3472*x**14 - 17318*x**16 + O(x**17) + + +def test_issue_12791(): + beta = symbols('beta', positive=True) + theta, varphi = symbols('theta varphi', real=True) + + expr = (-beta**2*varphi*sin(theta) + beta**2*cos(theta) + \ + beta*varphi*sin(theta) - beta*cos(theta) - beta + 1)/(beta*cos(theta) - 1)**2 + + sol = (0.5/(0.5*cos(theta) - 1.0)**2 - 0.25*cos(theta)/(0.5*cos(theta) - 1.0)**2 + + (beta - 0.5)*(-0.25*varphi*sin(2*theta) - 1.5*cos(theta) + + 0.25*cos(2*theta) + 1.25)/((0.5*cos(theta) - 1.0)**2*(0.5*cos(theta) - 1.0)) + + 0.25*varphi*sin(theta)/(0.5*cos(theta) - 1.0)**2 + + O((beta - S.Half)**2, (beta, S.Half))) + + assert expr.series(beta, 0.5, 2).trigsimp() == sol + + +def test_issue_14384(): + x, a = symbols('x a') + assert series(x**a, x) == x**a + assert series(x**(-2*a), x) == x**(-2*a) + assert series(exp(a*log(x)), x) == exp(a*log(x)) + raises(PoleError, lambda: series(x**I, x)) + raises(PoleError, lambda: series(x**(I + 1), x)) + raises(PoleError, lambda: series(exp(I*log(x)), x)) + + +def test_issue_14885(): + assert series(x**Rational(-3, 2)*exp(x), x, 0) == (x**Rational(-3, 2) + 1/sqrt(x) + + sqrt(x)/2 + x**Rational(3, 2)/6 + x**Rational(5, 2)/24 + x**Rational(7, 2)/120 + + x**Rational(9, 2)/720 + x**Rational(11, 2)/5040 + O(x**6)) + + +def test_issue_15539(): + assert series(atan(x), x, -oo) == (-1/(5*x**5) + 1/(3*x**3) - 1/x - pi/2 + + O(x**(-6), (x, -oo))) + assert series(atan(x), x, oo) == (-1/(5*x**5) + 1/(3*x**3) - 1/x + pi/2 + + O(x**(-6), (x, oo))) + + +def test_issue_7259(): + assert series(LambertW(x), x) == x - x**2 + 3*x**3/2 - 8*x**4/3 + 125*x**5/24 + O(x**6) + assert series(LambertW(x**2), x, n=8) == x**2 - x**4 + 3*x**6/2 + O(x**8) + assert series(LambertW(sin(x)), x, n=4) == x - x**2 + 4*x**3/3 + O(x**4) + +def test_issue_11884(): + assert cos(x).series(x, 1, n=1) == cos(1) + O(x - 1, (x, 1)) + + +def test_issue_18008(): + y = x*(1 + x*(1 - x))/((1 + x*(1 - x)) - (1 - x)*(1 - x)) + assert y.series(x, oo, n=4) == -9/(32*x**3) - 3/(16*x**2) - 1/(8*x) + S(1)/4 + x/2 + \ + O(x**(-4), (x, oo)) + + +def test_issue_18842(): + f = log(x/(1 - x)) + assert f.series(x, 0.491, n=1).removeO().nsimplify() == \ + -S(180019443780011)/5000000000000000 + + +def test_issue_19534(): + dt = symbols('dt', real=True) + expr = 16*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0)/45 + \ + 49*dt*(-0.049335189898860408029*dt*(2.0*dt + 1.0) + \ + 0.29601113939316244817*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) - \ + 0.12564355335492979587*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) + 0.051640768506639183825*dt + \ + dt*(1/2 - sqrt(21)/14) + 1.0)/180 + 49*dt*(-0.23637909581542530626*dt*(2.0*dt + 1.0) - \ + 0.74817562366625959291*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.88085458023927036857*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) + \ + 2.1165151389911680013*dt*(-0.049335189898860408029*dt*(2.0*dt + 1.0) + \ + 0.29601113939316244817*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) - \ + 0.12564355335492979587*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) + 0.22431393315265061193*dt + 1.0) - \ + 1.1854881643947648988*dt + dt*(sqrt(21)/14 + 1/2) + 1.0)/180 + \ + dt*(0.66666666666666666667*dt*(2.0*dt + 1.0) + \ + 6.0173399699313066769*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) - \ + 4.1117044797036320069*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) - \ + 7.0189140975801991157*dt*(-0.049335189898860408029*dt*(2.0*dt + 1.0) + \ + 0.29601113939316244817*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) - \ + 0.12564355335492979587*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) + 0.22431393315265061193*dt + 1.0) + \ + 0.94010945196161777522*dt*(-0.23637909581542530626*dt*(2.0*dt + 1.0) - \ + 0.74817562366625959291*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.88085458023927036857*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) + \ + 2.1165151389911680013*dt*(-0.049335189898860408029*dt*(2.0*dt + 1.0) + \ + 0.29601113939316244817*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) - \ + 0.12564355335492979587*dt*(0.074074074074074074074*dt*(2.0*dt + 1.0) + \ + 0.2962962962962962963*dt*(0.125*dt*(2.0*dt + 1.0) + 0.875*dt + 1.0) + \ + 0.96296296296296296296*dt + 1.0) + 0.22431393315265061193*dt + 1.0) - \ + 0.35816132904077632692*dt + 1.0) + 5.5065024887242400038*dt + 1.0)/20 + dt/20 + 1 + + assert N(expr.series(dt, 0, 8), 20) == ( + - Float('0.00092592592592592596126289', precision=70) * dt**7 + + Float('0.0027777777777777783174695', precision=70) * dt**6 + + Float('0.016666666666666656027029', precision=70) * dt**5 + + Float('0.083333333333333300951828', precision=70) * dt**4 + + Float('0.33333333333333337034077', precision=70) * dt**3 + + Float('1.0', precision=70) * dt**2 + + Float('1.0', precision=70) * dt + + Float('1.0', precision=70) + ) + + +def test_issue_11407(): + a, b, c, x = symbols('a b c x') + assert series(sqrt(a + b + c*x), x, 0, 1) == sqrt(a + b) + O(x) + assert series(sqrt(a + b + c + c*x), x, 0, 1) == sqrt(a + b + c) + O(x) + + +def test_issue_14037(): + assert (sin(x**50)/x**51).series(x, n=0) == 1/x + O(1, x) + + +def test_issue_20551(): + expr = (exp(x)/x).series(x, n=None) + terms = [ next(expr) for i in range(3) ] + assert terms == [1/x, 1, x/2] + + +def test_issue_20697(): + p_0, p_1, p_2, p_3, b_0, b_1, b_2 = symbols('p_0 p_1 p_2 p_3 b_0 b_1 b_2') + Q = (p_0 + (p_1 + (p_2 + p_3/y)/y)/y)/(1 + ((p_3/(b_0*y) + (b_0*p_2\ + - b_1*p_3)/b_0**2)/y + (b_0**2*p_1 - b_0*b_1*p_2 - p_3*(b_0*b_2\ + - b_1**2))/b_0**3)/y) + assert Q.series(y, n=3).ratsimp() == b_2*y**2 + b_1*y + b_0 + O(y**3) + + +def test_issue_21245(): + fi = (1 + sqrt(5))/2 + assert (1/(1 - x - x**2)).series(x, 1/fi, 1).factor() == \ + (-37*sqrt(5) - 83 + 13*sqrt(5)*x + 29*x + O((x - 2/(1 + sqrt(5)))**2, (x\ + , 2/(1 + sqrt(5)))))/((2*sqrt(5) + 5)**2*(x + sqrt(5)*x - 2)) + + + +def test_issue_21938(): + expr = sin(1/x + exp(-x)) - sin(1/x) + assert expr.series(x, oo) == (1/(24*x**4) - 1/(2*x**2) + 1 + O(x**(-6), (x, oo)))*exp(-x) + + +def test_issue_23432(): + expr = 1/sqrt(1 - x**2) + result = expr.series(x, 0.5) + assert result.is_Add and len(result.args) == 7 + + +def test_issue_23727(): + res = series(sqrt(1 - x**2), x, 0.1) + assert res.is_Add == True + + +def test_issue_24266(): + #type1: exp(f(x)) + assert (exp(-I*pi*(2*x+1))).series(x, 0, 3) == -1 + 2*I*pi*x + 2*pi**2*x**2 + O(x**3) + assert (exp(-I*pi*(2*x+1))*gamma(1+x)).series(x, 0, 3) == -1 + x*(EulerGamma + 2*I*pi) + \ + x**2*(-EulerGamma**2/2 + 23*pi**2/12 - 2*EulerGamma*I*pi) + O(x**3) + + #type2: c**f(x) + assert ((2*I)**(-I*pi*(2*x+1))).series(x, 0, 2) == exp(pi**2/2 - I*pi*log(2)) + \ + x*(pi**2*exp(pi**2/2 - I*pi*log(2)) - 2*I*pi*exp(pi**2/2 - I*pi*log(2))*log(2)) + O(x**2) + assert ((2)**(-I*pi*(2*x+1))).series(x, 0, 2) == exp(-I*pi*log(2)) - 2*I*pi*x*exp(-I*pi*log(2))*log(2) + O(x**2) + + #type3: f(y)**g(x) + assert ((y)**(I*pi*(2*x+1))).series(x, 0, 2) == exp(I*pi*log(y)) + 2*I*pi*x*exp(I*pi*log(y))*log(y) + O(x**2) + assert ((I*y)**(I*pi*(2*x+1))).series(x, 0, 2) == exp(I*pi*log(I*y)) + 2*I*pi*x*exp(I*pi*log(I*y))*log(I*y) + O(x**2) + + +def test_issue_26856(): + raises(ValueError, lambda: (2**x).series(x, oo, -1)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..8b909c0b5ef03b1e1e76dfbf4288f61860575da7 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/__init__.py @@ -0,0 +1,36 @@ +from .sets import (Set, Interval, Union, FiniteSet, ProductSet, + Intersection, imageset, Complement, SymmetricDifference, + DisjointUnion) + +from .fancysets import ImageSet, Range, ComplexRegion +from .contains import Contains +from .conditionset import ConditionSet +from .ordinals import Ordinal, OmegaPower, ord0 +from .powerset import PowerSet +from ..core.singleton import S +from .handlers.comparison import _eval_is_eq # noqa:F401 +Complexes = S.Complexes +EmptySet = S.EmptySet +Integers = S.Integers +Naturals = S.Naturals +Naturals0 = S.Naturals0 +Rationals = S.Rationals +Reals = S.Reals +UniversalSet = S.UniversalSet + +__all__ = [ + 'Set', 'Interval', 'Union', 'EmptySet', 'FiniteSet', 'ProductSet', + 'Intersection', 'imageset', 'Complement', 'SymmetricDifference', 'DisjointUnion', + + 'ImageSet', 'Range', 'ComplexRegion', 'Reals', + + 'Contains', + + 'ConditionSet', + + 'Ordinal', 'OmegaPower', 'ord0', + + 'PowerSet', + + 'Reals', 'Naturals', 'Naturals0', 'UniversalSet', 'Integers', 'Rationals', +] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/conditionset.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/conditionset.py new file mode 100644 index 0000000000000000000000000000000000000000..e847e60ce97d7e9922ce907042ace941838b0ab1 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/conditionset.py @@ -0,0 +1,246 @@ +from sympy.core.singleton import S +from sympy.core.basic import Basic +from sympy.core.containers import Tuple +from sympy.core.function import Lambda, BadSignatureError +from sympy.core.logic import fuzzy_bool +from sympy.core.relational import Eq +from sympy.core.symbol import Dummy +from sympy.core.sympify import _sympify +from sympy.logic.boolalg import And, as_Boolean +from sympy.utilities.iterables import sift, flatten, has_dups +from sympy.utilities.exceptions import sympy_deprecation_warning +from .contains import Contains +from .sets import Set, Union, FiniteSet, SetKind + + +adummy = Dummy('conditionset') + + +class ConditionSet(Set): + r""" + Set of elements which satisfies a given condition. + + .. math:: \{x \mid \textrm{condition}(x) = \texttt{True}, x \in S\} + + Examples + ======== + + >>> from sympy import Symbol, S, ConditionSet, pi, Eq, sin, Interval + >>> from sympy.abc import x, y, z + + >>> sin_sols = ConditionSet(x, Eq(sin(x), 0), Interval(0, 2*pi)) + >>> 2*pi in sin_sols + True + >>> pi/2 in sin_sols + False + >>> 3*pi in sin_sols + False + >>> 5 in ConditionSet(x, x**2 > 4, S.Reals) + True + + If the value is not in the base set, the result is false: + + >>> 5 in ConditionSet(x, x**2 > 4, Interval(2, 4)) + False + + Notes + ===== + + Symbols with assumptions should be avoided or else the + condition may evaluate without consideration of the set: + + >>> n = Symbol('n', negative=True) + >>> cond = (n > 0); cond + False + >>> ConditionSet(n, cond, S.Integers) + EmptySet + + Only free symbols can be changed by using `subs`: + + >>> c = ConditionSet(x, x < 1, {x, z}) + >>> c.subs(x, y) + ConditionSet(x, x < 1, {y, z}) + + To check if ``pi`` is in ``c`` use: + + >>> pi in c + False + + If no base set is specified, the universal set is implied: + + >>> ConditionSet(x, x < 1).base_set + UniversalSet + + Only symbols or symbol-like expressions can be used: + + >>> ConditionSet(x + 1, x + 1 < 1, S.Integers) + Traceback (most recent call last): + ... + ValueError: non-symbol dummy not recognized in condition + + When the base set is a ConditionSet, the symbols will be + unified if possible with preference for the outermost symbols: + + >>> ConditionSet(x, x < y, ConditionSet(z, z + y < 2, S.Integers)) + ConditionSet(x, (x < y) & (x + y < 2), Integers) + + """ + def __new__(cls, sym, condition, base_set=S.UniversalSet): + sym = _sympify(sym) + flat = flatten([sym]) + if has_dups(flat): + raise BadSignatureError("Duplicate symbols detected") + base_set = _sympify(base_set) + if not isinstance(base_set, Set): + raise TypeError( + 'base set should be a Set object, not %s' % base_set) + condition = _sympify(condition) + + if isinstance(condition, FiniteSet): + condition_orig = condition + temp = (Eq(lhs, 0) for lhs in condition) + condition = And(*temp) + sympy_deprecation_warning( + f""" +Using a set for the condition in ConditionSet is deprecated. Use a boolean +instead. + +In this case, replace + + {condition_orig} + +with + + {condition} +""", + deprecated_since_version='1.5', + active_deprecations_target="deprecated-conditionset-set", + ) + + condition = as_Boolean(condition) + + if condition is S.true: + return base_set + + if condition is S.false: + return S.EmptySet + + if base_set is S.EmptySet: + return S.EmptySet + + # no simple answers, so now check syms + for i in flat: + if not getattr(i, '_diff_wrt', False): + raise ValueError('`%s` is not symbol-like' % i) + + if base_set.contains(sym) is S.false: + raise TypeError('sym `%s` is not in base_set `%s`' % (sym, base_set)) + + know = None + if isinstance(base_set, FiniteSet): + sifted = sift( + base_set, lambda _: fuzzy_bool(condition.subs(sym, _))) + if sifted[None]: + know = FiniteSet(*sifted[True]) + base_set = FiniteSet(*sifted[None]) + else: + return FiniteSet(*sifted[True]) + + if isinstance(base_set, cls): + s, c, b = base_set.args + def sig(s): + return cls(s, Eq(adummy, 0)).as_dummy().sym + sa, sb = map(sig, (sym, s)) + if sa != sb: + raise BadSignatureError('sym does not match sym of base set') + reps = dict(zip(flatten([sym]), flatten([s]))) + if s == sym: + condition = And(condition, c) + base_set = b + elif not c.free_symbols & sym.free_symbols: + reps = {v: k for k, v in reps.items()} + condition = And(condition, c.xreplace(reps)) + base_set = b + elif not condition.free_symbols & s.free_symbols: + sym = sym.xreplace(reps) + condition = And(condition.xreplace(reps), c) + base_set = b + + # flatten ConditionSet(Contains(ConditionSet())) expressions + if isinstance(condition, Contains) and (sym == condition.args[0]): + if isinstance(condition.args[1], Set): + return condition.args[1].intersect(base_set) + + rv = Basic.__new__(cls, sym, condition, base_set) + return rv if know is None else Union(know, rv) + + sym = property(lambda self: self.args[0]) + condition = property(lambda self: self.args[1]) + base_set = property(lambda self: self.args[2]) + + @property + def free_symbols(self): + cond_syms = self.condition.free_symbols - self.sym.free_symbols + return cond_syms | self.base_set.free_symbols + + @property + def bound_symbols(self): + return flatten([self.sym]) + + def _contains(self, other): + def ok_sig(a, b): + tuples = [isinstance(i, Tuple) for i in (a, b)] + c = tuples.count(True) + if c == 1: + return False + if c == 0: + return True + return len(a) == len(b) and all( + ok_sig(i, j) for i, j in zip(a, b)) + if not ok_sig(self.sym, other): + return S.false + + # try doing base_cond first and return + # False immediately if it is False + base_cond = Contains(other, self.base_set) + if base_cond is S.false: + return S.false + + # Substitute other into condition. This could raise e.g. for + # ConditionSet(x, 1/x >= 0, Reals).contains(0) + lamda = Lambda((self.sym,), self.condition) + try: + lambda_cond = lamda(other) + except TypeError: + return None + else: + return And(base_cond, lambda_cond) + + def as_relational(self, other): + f = Lambda(self.sym, self.condition) + if isinstance(self.sym, Tuple): + f = f(*other) + else: + f = f(other) + return And(f, self.base_set.contains(other)) + + def _eval_subs(self, old, new): + sym, cond, base = self.args + dsym = sym.subs(old, adummy) + insym = dsym.has(adummy) + # prioritize changing a symbol in the base + newbase = base.subs(old, new) + if newbase != base: + if not insym: + cond = cond.subs(old, new) + return self.func(sym, cond, newbase) + if insym: + pass # no change of bound symbols via subs + elif getattr(new, '_diff_wrt', False): + cond = cond.subs(old, new) + else: + pass # let error about the symbol raise from __new__ + return self.func(sym, cond, base) + + def _kind(self): + return SetKind(self.sym.kind) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/contains.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/contains.py new file mode 100644 index 0000000000000000000000000000000000000000..403d4875279d718724a898efa5cba41bc7bed6ea --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/contains.py @@ -0,0 +1,63 @@ +from sympy.core import S +from sympy.core.sympify import sympify +from sympy.core.relational import Eq, Ne +from sympy.core.parameters import global_parameters +from sympy.logic.boolalg import Boolean +from sympy.utilities.misc import func_name +from .sets import Set + + +class Contains(Boolean): + """ + Asserts that x is an element of the set S. + + Examples + ======== + + >>> from sympy import Symbol, Integer, S, Contains + >>> Contains(Integer(2), S.Integers) + True + >>> Contains(Integer(-2), S.Naturals) + False + >>> i = Symbol('i', integer=True) + >>> Contains(i, S.Naturals) + Contains(i, Naturals) + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Element_%28mathematics%29 + """ + def __new__(cls, x, s, evaluate=None): + x = sympify(x) + s = sympify(s) + + if evaluate is None: + evaluate = global_parameters.evaluate + + if not isinstance(s, Set): + raise TypeError('expecting Set, not %s' % func_name(s)) + + if evaluate: + # _contains can return symbolic booleans that would be returned by + # s.contains(x) but here for Contains(x, s) we only evaluate to + # true, false or return the unevaluated Contains. + result = s._contains(x) + + if isinstance(result, Boolean): + if result in (S.true, S.false): + return result + elif result is not None: + raise TypeError("_contains() should return Boolean or None") + + return super().__new__(cls, x, s) + + @property + def binary_symbols(self): + return set().union(*[i.binary_symbols + for i in self.args[1].args + if i.is_Boolean or i.is_Symbol or + isinstance(i, (Eq, Ne))]) + + def as_set(self): + return self.args[1] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/fancysets.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/fancysets.py new file mode 100644 index 0000000000000000000000000000000000000000..e0e24a2a864222d16ba1a697558b5211127fb2ad --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/fancysets.py @@ -0,0 +1,1523 @@ +from functools import reduce +from itertools import product + +from sympy.core.basic import Basic +from sympy.core.containers import Tuple +from sympy.core.expr import Expr +from sympy.core.function import Lambda +from sympy.core.logic import fuzzy_not, fuzzy_or, fuzzy_and +from sympy.core.mod import Mod +from sympy.core.intfunc import igcd +from sympy.core.numbers import oo, Rational, Integer +from sympy.core.relational import Eq, is_eq +from sympy.core.kind import NumberKind +from sympy.core.singleton import Singleton, S +from sympy.core.symbol import Dummy, symbols, Symbol +from sympy.core.sympify import _sympify, sympify, _sympy_converter +from sympy.functions.elementary.integers import ceiling, floor +from sympy.functions.elementary.trigonometric import sin, cos +from sympy.logic.boolalg import And, Or +from .sets import tfn, Set, Interval, Union, FiniteSet, ProductSet, SetKind +from sympy.utilities.misc import filldedent + + +class Rationals(Set, metaclass=Singleton): + """ + Represents the rational numbers. This set is also available as + the singleton ``S.Rationals``. + + Examples + ======== + + >>> from sympy import S + >>> S.Half in S.Rationals + True + >>> iterable = iter(S.Rationals) + >>> [next(iterable) for i in range(12)] + [0, 1, -1, 1/2, 2, -1/2, -2, 1/3, 3, -1/3, -3, 2/3] + """ + + is_iterable = True + _inf = S.NegativeInfinity + _sup = S.Infinity + is_empty = False + is_finite_set = False + + def _contains(self, other): + if not isinstance(other, Expr): + return S.false + return tfn[other.is_rational] + + def __iter__(self): + yield S.Zero + yield S.One + yield S.NegativeOne + d = 2 + while True: + for n in range(d): + if igcd(n, d) == 1: + yield Rational(n, d) + yield Rational(d, n) + yield Rational(-n, d) + yield Rational(-d, n) + d += 1 + + @property + def _boundary(self): + return S.Reals + + def _kind(self): + return SetKind(NumberKind) + + +class Naturals(Set, metaclass=Singleton): + """ + Represents the natural numbers (or counting numbers) which are all + positive integers starting from 1. This set is also available as + the singleton ``S.Naturals``. + + Examples + ======== + + >>> from sympy import S, Interval, pprint + >>> 5 in S.Naturals + True + >>> iterable = iter(S.Naturals) + >>> next(iterable) + 1 + >>> next(iterable) + 2 + >>> next(iterable) + 3 + >>> pprint(S.Naturals.intersect(Interval(0, 10))) + {1, 2, ..., 10} + + See Also + ======== + + Naturals0 : non-negative integers (i.e. includes 0, too) + Integers : also includes negative integers + """ + + is_iterable = True + _inf: Integer = S.One + _sup = S.Infinity + is_empty = False + is_finite_set = False + + def _contains(self, other): + if not isinstance(other, Expr): + return S.false + elif other.is_positive and other.is_integer: + return S.true + elif other.is_integer is False or other.is_positive is False: + return S.false + + def _eval_is_subset(self, other): + return Range(1, oo).is_subset(other) + + def _eval_is_superset(self, other): + return Range(1, oo).is_superset(other) + + def __iter__(self): + i = self._inf + while True: + yield i + i = i + 1 + + @property + def _boundary(self): + return self + + def as_relational(self, x): + return And(Eq(floor(x), x), x >= self.inf, x < oo) + + def _kind(self): + return SetKind(NumberKind) + + +class Naturals0(Naturals): + """Represents the whole numbers which are all the non-negative integers, + inclusive of zero. + + See Also + ======== + + Naturals : positive integers; does not include 0 + Integers : also includes the negative integers + """ + _inf = S.Zero + + def _contains(self, other): + if not isinstance(other, Expr): + return S.false + elif other.is_integer and other.is_nonnegative: + return S.true + elif other.is_integer is False or other.is_nonnegative is False: + return S.false + + def _eval_is_subset(self, other): + return Range(oo).is_subset(other) + + def _eval_is_superset(self, other): + return Range(oo).is_superset(other) + + +class Integers(Set, metaclass=Singleton): + """ + Represents all integers: positive, negative and zero. This set is also + available as the singleton ``S.Integers``. + + Examples + ======== + + >>> from sympy import S, Interval, pprint + >>> 5 in S.Naturals + True + >>> iterable = iter(S.Integers) + >>> next(iterable) + 0 + >>> next(iterable) + 1 + >>> next(iterable) + -1 + >>> next(iterable) + 2 + + >>> pprint(S.Integers.intersect(Interval(-4, 4))) + {-4, -3, ..., 4} + + See Also + ======== + + Naturals0 : non-negative integers + Integers : positive and negative integers and zero + """ + + is_iterable = True + is_empty = False + is_finite_set = False + + def _contains(self, other): + if not isinstance(other, Expr): + return S.false + return tfn[other.is_integer] + + def __iter__(self): + yield S.Zero + i = S.One + while True: + yield i + yield -i + i = i + 1 + + @property + def _inf(self): + return S.NegativeInfinity + + @property + def _sup(self): + return S.Infinity + + @property + def _boundary(self): + return self + + def _kind(self): + return SetKind(NumberKind) + + def as_relational(self, x): + return And(Eq(floor(x), x), -oo < x, x < oo) + + def _eval_is_subset(self, other): + return Range(-oo, oo).is_subset(other) + + def _eval_is_superset(self, other): + return Range(-oo, oo).is_superset(other) + + +class Reals(Interval, metaclass=Singleton): + """ + Represents all real numbers + from negative infinity to positive infinity, + including all integer, rational and irrational numbers. + This set is also available as the singleton ``S.Reals``. + + + Examples + ======== + + >>> from sympy import S, Rational, pi, I + >>> 5 in S.Reals + True + >>> Rational(-1, 2) in S.Reals + True + >>> pi in S.Reals + True + >>> 3*I in S.Reals + False + >>> S.Reals.contains(pi) + True + + + See Also + ======== + + ComplexRegion + """ + @property + def start(self): + return S.NegativeInfinity + + @property + def end(self): + return S.Infinity + + @property + def left_open(self): + return True + + @property + def right_open(self): + return True + + def __eq__(self, other): + return other == Interval(S.NegativeInfinity, S.Infinity) + + def __hash__(self): + return hash(Interval(S.NegativeInfinity, S.Infinity)) + + +class ImageSet(Set): + """ + Image of a set under a mathematical function. The transformation + must be given as a Lambda function which has as many arguments + as the elements of the set upon which it operates, e.g. 1 argument + when acting on the set of integers or 2 arguments when acting on + a complex region. + + This function is not normally called directly, but is called + from ``imageset``. + + + Examples + ======== + + >>> from sympy import Symbol, S, pi, Dummy, Lambda + >>> from sympy import FiniteSet, ImageSet, Interval + + >>> x = Symbol('x') + >>> N = S.Naturals + >>> squares = ImageSet(Lambda(x, x**2), N) # {x**2 for x in N} + >>> 4 in squares + True + >>> 5 in squares + False + + >>> FiniteSet(0, 1, 2, 3, 4, 5, 6, 7, 9, 10).intersect(squares) + {1, 4, 9} + + >>> square_iterable = iter(squares) + >>> for i in range(4): + ... next(square_iterable) + 1 + 4 + 9 + 16 + + If you want to get value for `x` = 2, 1/2 etc. (Please check whether the + `x` value is in ``base_set`` or not before passing it as args) + + >>> squares.lamda(2) + 4 + >>> squares.lamda(S(1)/2) + 1/4 + + >>> n = Dummy('n') + >>> solutions = ImageSet(Lambda(n, n*pi), S.Integers) # solutions of sin(x) = 0 + >>> dom = Interval(-1, 1) + >>> dom.intersect(solutions) + {0} + + See Also + ======== + + sympy.sets.sets.imageset + """ + def __new__(cls, flambda, *sets): + if not isinstance(flambda, Lambda): + raise ValueError('First argument must be a Lambda') + + signature = flambda.signature + + if len(signature) != len(sets): + raise ValueError('Incompatible signature') + + sets = [_sympify(s) for s in sets] + + if not all(isinstance(s, Set) for s in sets): + raise TypeError("Set arguments to ImageSet should of type Set") + + if not all(cls._check_sig(sg, st) for sg, st in zip(signature, sets)): + raise ValueError("Signature %s does not match sets %s" % (signature, sets)) + + if flambda is S.IdentityFunction and len(sets) == 1: + return sets[0] + + if not set(flambda.variables) & flambda.expr.free_symbols: + is_empty = fuzzy_or(s.is_empty for s in sets) + if is_empty == True: + return S.EmptySet + elif is_empty == False: + return FiniteSet(flambda.expr) + + return Basic.__new__(cls, flambda, *sets) + + lamda = property(lambda self: self.args[0]) + base_sets = property(lambda self: self.args[1:]) + + @property + def base_set(self): + # XXX: Maybe deprecate this? It is poorly defined in handling + # the multivariate case... + sets = self.base_sets + if len(sets) == 1: + return sets[0] + else: + return ProductSet(*sets).flatten() + + @property + def base_pset(self): + return ProductSet(*self.base_sets) + + @classmethod + def _check_sig(cls, sig_i, set_i): + if sig_i.is_symbol: + return True + elif isinstance(set_i, ProductSet): + sets = set_i.sets + if len(sig_i) != len(sets): + return False + # Recurse through the signature for nested tuples: + return all(cls._check_sig(ts, ps) for ts, ps in zip(sig_i, sets)) + else: + # XXX: Need a better way of checking whether a set is a set of + # Tuples or not. For example a FiniteSet can contain Tuples + # but so can an ImageSet or a ConditionSet. Others like + # Integers, Reals etc can not contain Tuples. We could just + # list the possibilities here... Current code for e.g. + # _contains probably only works for ProductSet. + return True # Give the benefit of the doubt + + def __iter__(self): + already_seen = set() + for i in self.base_pset: + val = self.lamda(*i) + if val in already_seen: + continue + else: + already_seen.add(val) + yield val + + def _is_multivariate(self): + return len(self.lamda.variables) > 1 + + def _contains(self, other): + from sympy.solvers.solveset import _solveset_multi + + def get_symsetmap(signature, base_sets): + '''Attempt to get a map of symbols to base_sets''' + queue = list(zip(signature, base_sets)) + symsetmap = {} + for sig, base_set in queue: + if sig.is_symbol: + symsetmap[sig] = base_set + elif base_set.is_ProductSet: + sets = base_set.sets + if len(sig) != len(sets): + raise ValueError("Incompatible signature") + # Recurse + queue.extend(zip(sig, sets)) + else: + # If we get here then we have something like sig = (x, y) and + # base_set = {(1, 2), (3, 4)}. For now we give up. + return None + + return symsetmap + + def get_equations(expr, candidate): + '''Find the equations relating symbols in expr and candidate.''' + queue = [(expr, candidate)] + for e, c in queue: + if not isinstance(e, Tuple): + yield Eq(e, c) + elif not isinstance(c, Tuple) or len(e) != len(c): + yield False + return + else: + queue.extend(zip(e, c)) + + # Get the basic objects together: + other = _sympify(other) + expr = self.lamda.expr + sig = self.lamda.signature + variables = self.lamda.variables + base_sets = self.base_sets + + # Use dummy symbols for ImageSet parameters so they don't match + # anything in other + rep = {v: Dummy(v.name) for v in variables} + variables = [v.subs(rep) for v in variables] + sig = sig.subs(rep) + expr = expr.subs(rep) + + # Map the parts of other to those in the Lambda expr + equations = [] + for eq in get_equations(expr, other): + # Unsatisfiable equation? + if eq is False: + return S.false + equations.append(eq) + + # Map the symbols in the signature to the corresponding domains + symsetmap = get_symsetmap(sig, base_sets) + if symsetmap is None: + # Can't factor the base sets to a ProductSet + return None + + # Which of the variables in the Lambda signature need to be solved for? + symss = (eq.free_symbols for eq in equations) + variables = set(variables) & reduce(set.union, symss, set()) + + # Use internal multivariate solveset + variables = tuple(variables) + base_sets = [symsetmap[v] for v in variables] + solnset = _solveset_multi(equations, variables, base_sets) + if solnset is None: + return None + return tfn[fuzzy_not(solnset.is_empty)] + + @property + def is_iterable(self): + return all(s.is_iterable for s in self.base_sets) + + def doit(self, **hints): + from sympy.sets.setexpr import SetExpr + f = self.lamda + sig = f.signature + if len(sig) == 1 and sig[0].is_symbol and isinstance(f.expr, Expr): + base_set = self.base_sets[0] + return SetExpr(base_set)._eval_func(f).set + if all(s.is_FiniteSet for s in self.base_sets): + return FiniteSet(*(f(*a) for a in product(*self.base_sets))) + return self + + def _kind(self): + return SetKind(self.lamda.expr.kind) + + +class Range(Set): + """ + Represents a range of integers. Can be called as ``Range(stop)``, + ``Range(start, stop)``, or ``Range(start, stop, step)``; when ``step`` is + not given it defaults to 1. + + ``Range(stop)`` is the same as ``Range(0, stop, 1)`` and the stop value + (just as for Python ranges) is not included in the Range values. + + >>> from sympy import Range + >>> list(Range(3)) + [0, 1, 2] + + The step can also be negative: + + >>> list(Range(10, 0, -2)) + [10, 8, 6, 4, 2] + + The stop value is made canonical so equivalent ranges always + have the same args: + + >>> Range(0, 10, 3) + Range(0, 12, 3) + + Infinite ranges are allowed. ``oo`` and ``-oo`` are never included in the + set (``Range`` is always a subset of ``Integers``). If the starting point + is infinite, then the final value is ``stop - step``. To iterate such a + range, it needs to be reversed: + + >>> from sympy import oo + >>> r = Range(-oo, 1) + >>> r[-1] + 0 + >>> next(iter(r)) + Traceback (most recent call last): + ... + TypeError: Cannot iterate over Range with infinite start + >>> next(iter(r.reversed)) + 0 + + Although ``Range`` is a :class:`Set` (and supports the normal set + operations) it maintains the order of the elements and can + be used in contexts where ``range`` would be used. + + >>> from sympy import Interval + >>> Range(0, 10, 2).intersect(Interval(3, 7)) + Range(4, 8, 2) + >>> list(_) + [4, 6] + + Although slicing of a Range will always return a Range -- possibly + empty -- an empty set will be returned from any intersection that + is empty: + + >>> Range(3)[:0] + Range(0, 0, 1) + >>> Range(3).intersect(Interval(4, oo)) + EmptySet + >>> Range(3).intersect(Range(4, oo)) + EmptySet + + Range will accept symbolic arguments but has very limited support + for doing anything other than displaying the Range: + + >>> from sympy import Symbol, pprint + >>> from sympy.abc import i, j, k + >>> Range(i, j, k).start + i + >>> Range(i, j, k).inf + Traceback (most recent call last): + ... + ValueError: invalid method for symbolic range + + Better success will be had when using integer symbols: + + >>> n = Symbol('n', integer=True) + >>> r = Range(n, n + 20, 3) + >>> r.inf + n + >>> pprint(r) + {n, n + 3, ..., n + 18} + """ + + def __new__(cls, *args): + if len(args) == 1: + if isinstance(args[0], range): + raise TypeError( + 'use sympify(%s) to convert range to Range' % args[0]) + + # expand range + slc = slice(*args) + + if slc.step == 0: + raise ValueError("step cannot be 0") + + start, stop, step = slc.start or 0, slc.stop, slc.step or 1 + try: + ok = [] + for w in (start, stop, step): + w = sympify(w) + if w in [S.NegativeInfinity, S.Infinity] or ( + w.has(Symbol) and w.is_integer != False): + ok.append(w) + elif not w.is_Integer: + if w.is_infinite: + raise ValueError('infinite symbols not allowed') + raise ValueError + else: + ok.append(w) + except ValueError: + raise ValueError(filldedent(''' + Finite arguments to Range must be integers; `imageset` can define + other cases, e.g. use `imageset(i, i/10, Range(3))` to give + [0, 1/10, 1/5].''')) + start, stop, step = ok + + null = False + if any(i.has(Symbol) for i in (start, stop, step)): + dif = stop - start + n = dif/step + if n.is_Rational: + if dif == 0: + null = True + else: # (x, x + 5, 2) or (x, 3*x, x) + n = floor(n) + end = start + n*step + if dif.is_Rational: # (x, x + 5, 2) + if (end - stop).is_negative: + end += step + else: # (x, 3*x, x) + if (end/stop - 1).is_negative: + end += step + elif n.is_extended_negative: + null = True + else: + end = stop # other methods like sup and reversed must fail + elif start.is_infinite: + span = step*(stop - start) + if span is S.NaN or span <= 0: + null = True + elif step.is_Integer and stop.is_infinite and abs(step) != 1: + raise ValueError(filldedent(''' + Step size must be %s in this case.''' % (1 if step > 0 else -1))) + else: + end = stop + else: + oostep = step.is_infinite + if oostep: + step = S.One if step > 0 else S.NegativeOne + n = ceiling((stop - start)/step) + if n <= 0: + null = True + elif oostep: + step = S.One # make it canonical + end = start + step + else: + end = start + n*step + if null: + start = end = S.Zero + step = S.One + return Basic.__new__(cls, start, end, step) + + start = property(lambda self: self.args[0]) + stop = property(lambda self: self.args[1]) + step = property(lambda self: self.args[2]) + + @property + def reversed(self): + """Return an equivalent Range in the opposite order. + + Examples + ======== + + >>> from sympy import Range + >>> Range(10).reversed + Range(9, -1, -1) + """ + if self.has(Symbol): + n = (self.stop - self.start)/self.step + if not n.is_extended_positive or not all( + i.is_integer or i.is_infinite for i in self.args): + raise ValueError('invalid method for symbolic range') + if self.start == self.stop: + return self + return self.func( + self.stop - self.step, self.start - self.step, -self.step) + + def _kind(self): + return SetKind(NumberKind) + + def _contains(self, other): + if self.start == self.stop: + return S.false + if other.is_infinite: + return S.false + if not other.is_integer: + return tfn[other.is_integer] + if self.has(Symbol): + n = (self.stop - self.start)/self.step + if not n.is_extended_positive or not all( + i.is_integer or i.is_infinite for i in self.args): + return + else: + n = self.size + if self.start.is_finite: + ref = self.start + elif self.stop.is_finite: + ref = self.stop + else: # both infinite; step is +/- 1 (enforced by __new__) + return S.true + if n == 1: + return Eq(other, self[0]) + res = (ref - other) % self.step + if res == S.Zero: + if self.has(Symbol): + d = Dummy('i') + return self.as_relational(d).subs(d, other) + return And(other >= self.inf, other <= self.sup) + elif res.is_Integer: # off sequence + return S.false + else: # symbolic/unsimplified residue modulo step + return None + + def __iter__(self): + n = self.size # validate + if not (n.has(S.Infinity) or n.has(S.NegativeInfinity) or n.is_Integer): + raise TypeError("Cannot iterate over symbolic Range") + if self.start in [S.NegativeInfinity, S.Infinity]: + raise TypeError("Cannot iterate over Range with infinite start") + elif self.start != self.stop: + i = self.start + if n.is_infinite: + while True: + yield i + i += self.step + else: + for _ in range(n): + yield i + i += self.step + + @property + def is_iterable(self): + # Check that size can be determined, used by __iter__ + dif = self.stop - self.start + n = dif/self.step + if not (n.has(S.Infinity) or n.has(S.NegativeInfinity) or n.is_Integer): + return False + if self.start in [S.NegativeInfinity, S.Infinity]: + return False + if not (n.is_extended_nonnegative and all(i.is_integer for i in self.args)): + return False + return True + + def __len__(self): + rv = self.size + if rv is S.Infinity: + raise ValueError('Use .size to get the length of an infinite Range') + return int(rv) + + @property + def size(self): + if self.start == self.stop: + return S.Zero + dif = self.stop - self.start + n = dif/self.step + if n.is_infinite: + return S.Infinity + if n.is_extended_nonnegative and all(i.is_integer for i in self.args): + return abs(floor(n)) + raise ValueError('Invalid method for symbolic Range') + + @property + def is_finite_set(self): + if self.start.is_integer and self.stop.is_integer: + return True + return self.size.is_finite + + @property + def is_empty(self): + try: + return self.size.is_zero + except ValueError: + return None + + def __bool__(self): + # this only distinguishes between definite null range + # and non-null/unknown null; getting True doesn't mean + # that it actually is not null + b = is_eq(self.start, self.stop) + if b is None: + raise ValueError('cannot tell if Range is null or not') + return not bool(b) + + def __getitem__(self, i): + ooslice = "cannot slice from the end with an infinite value" + zerostep = "slice step cannot be zero" + infinite = "slicing not possible on range with infinite start" + # if we had to take every other element in the following + # oo, ..., 6, 4, 2, 0 + # we might get oo, ..., 4, 0 or oo, ..., 6, 2 + ambiguous = "cannot unambiguously re-stride from the end " + \ + "with an infinite value" + if isinstance(i, slice): + if self.size.is_finite: # validates, too + if self.start == self.stop: + return Range(0) + start, stop, step = i.indices(self.size) + n = ceiling((stop - start)/step) + if n <= 0: + return Range(0) + canonical_stop = start + n*step + end = canonical_stop - step + ss = step*self.step + return Range(self[start], self[end] + ss, ss) + else: # infinite Range + start = i.start + stop = i.stop + if i.step == 0: + raise ValueError(zerostep) + step = i.step or 1 + ss = step*self.step + #--------------------- + # handle infinite Range + # i.e. Range(-oo, oo) or Range(oo, -oo, -1) + # -------------------- + if self.start.is_infinite and self.stop.is_infinite: + raise ValueError(infinite) + #--------------------- + # handle infinite on right + # e.g. Range(0, oo) or Range(0, -oo, -1) + # -------------------- + if self.stop.is_infinite: + # start and stop are not interdependent -- + # they only depend on step --so we use the + # equivalent reversed values + return self.reversed[ + stop if stop is None else -stop + 1: + start if start is None else -start: + step].reversed + #--------------------- + # handle infinite on the left + # e.g. Range(oo, 0, -1) or Range(-oo, 0) + # -------------------- + # consider combinations of + # start/stop {== None, < 0, == 0, > 0} and + # step {< 0, > 0} + if start is None: + if stop is None: + if step < 0: + return Range(self[-1], self.start, ss) + elif step > 1: + raise ValueError(ambiguous) + else: # == 1 + return self + elif stop < 0: + if step < 0: + return Range(self[-1], self[stop], ss) + else: # > 0 + return Range(self.start, self[stop], ss) + elif stop == 0: + if step > 0: + return Range(0) + else: # < 0 + raise ValueError(ooslice) + elif stop == 1: + if step > 0: + raise ValueError(ooslice) # infinite singleton + else: # < 0 + raise ValueError(ooslice) + else: # > 1 + raise ValueError(ooslice) + elif start < 0: + if stop is None: + if step < 0: + return Range(self[start], self.start, ss) + else: # > 0 + return Range(self[start], self.stop, ss) + elif stop < 0: + return Range(self[start], self[stop], ss) + elif stop == 0: + if step < 0: + raise ValueError(ooslice) + else: # > 0 + return Range(0) + elif stop > 0: + raise ValueError(ooslice) + elif start == 0: + if stop is None: + if step < 0: + raise ValueError(ooslice) # infinite singleton + elif step > 1: + raise ValueError(ambiguous) + else: # == 1 + return self + elif stop < 0: + if step > 1: + raise ValueError(ambiguous) + elif step == 1: + return Range(self.start, self[stop], ss) + else: # < 0 + return Range(0) + else: # >= 0 + raise ValueError(ooslice) + elif start > 0: + raise ValueError(ooslice) + else: + if self.start == self.stop: + raise IndexError('Range index out of range') + if not (all(i.is_integer or i.is_infinite + for i in self.args) and ((self.stop - self.start)/ + self.step).is_extended_positive): + raise ValueError('Invalid method for symbolic Range') + if i == 0: + if self.start.is_infinite: + raise ValueError(ooslice) + return self.start + if i == -1: + if self.stop.is_infinite: + raise ValueError(ooslice) + return self.stop - self.step + n = self.size # must be known for any other index + rv = (self.stop if i < 0 else self.start) + i*self.step + if rv.is_infinite: + raise ValueError(ooslice) + val = (rv - self.start)/self.step + rel = fuzzy_or([val.is_infinite, + fuzzy_and([val.is_nonnegative, (n-val).is_nonnegative])]) + if rel: + return rv + if rel is None: + raise ValueError('Invalid method for symbolic Range') + raise IndexError("Range index out of range") + + @property + def _inf(self): + if not self: + return S.EmptySet.inf + if self.has(Symbol): + if all(i.is_integer or i.is_infinite for i in self.args): + dif = self.stop - self.start + if self.step.is_positive and dif.is_positive: + return self.start + elif self.step.is_negative and dif.is_negative: + return self.stop - self.step + raise ValueError('invalid method for symbolic range') + if self.step > 0: + return self.start + else: + return self.stop - self.step + + @property + def _sup(self): + if not self: + return S.EmptySet.sup + if self.has(Symbol): + if all(i.is_integer or i.is_infinite for i in self.args): + dif = self.stop - self.start + if self.step.is_positive and dif.is_positive: + return self.stop - self.step + elif self.step.is_negative and dif.is_negative: + return self.start + raise ValueError('invalid method for symbolic range') + if self.step > 0: + return self.stop - self.step + else: + return self.start + + @property + def _boundary(self): + return self + + def as_relational(self, x): + """Rewrite a Range in terms of equalities and logic operators. """ + if self.start.is_infinite: + assert not self.stop.is_infinite # by instantiation + a = self.reversed.start + else: + a = self.start + step = self.step + in_seq = Eq(Mod(x - a, step), 0) + ints = And(Eq(Mod(a, 1), 0), Eq(Mod(step, 1), 0)) + n = (self.stop - self.start)/self.step + if n == 0: + return S.EmptySet.as_relational(x) + if n == 1: + return And(Eq(x, a), ints) + try: + a, b = self.inf, self.sup + except ValueError: + a = None + if a is not None: + range_cond = And( + x > a if a.is_infinite else x >= a, + x < b if b.is_infinite else x <= b) + else: + a, b = self.start, self.stop - self.step + range_cond = Or( + And(self.step >= 1, x > a if a.is_infinite else x >= a, + x < b if b.is_infinite else x <= b), + And(self.step <= -1, x < a if a.is_infinite else x <= a, + x > b if b.is_infinite else x >= b)) + return And(in_seq, ints, range_cond) + + +_sympy_converter[range] = lambda r: Range(r.start, r.stop, r.step) + +def normalize_theta_set(theta): + r""" + Normalize a Real Set `theta` in the interval `[0, 2\pi)`. It returns + a normalized value of theta in the Set. For Interval, a maximum of + one cycle $[0, 2\pi]$, is returned i.e. for theta equal to $[0, 10\pi]$, + returned normalized value would be $[0, 2\pi)$. As of now intervals + with end points as non-multiples of ``pi`` is not supported. + + Raises + ====== + + NotImplementedError + The algorithms for Normalizing theta Set are not yet + implemented. + ValueError + The input is not valid, i.e. the input is not a real set. + RuntimeError + It is a bug, please report to the github issue tracker. + + Examples + ======== + + >>> from sympy.sets.fancysets import normalize_theta_set + >>> from sympy import Interval, FiniteSet, pi + >>> normalize_theta_set(Interval(9*pi/2, 5*pi)) + Interval(pi/2, pi) + >>> normalize_theta_set(Interval(-3*pi/2, pi/2)) + Interval.Ropen(0, 2*pi) + >>> normalize_theta_set(Interval(-pi/2, pi/2)) + Union(Interval(0, pi/2), Interval.Ropen(3*pi/2, 2*pi)) + >>> normalize_theta_set(Interval(-4*pi, 3*pi)) + Interval.Ropen(0, 2*pi) + >>> normalize_theta_set(Interval(-3*pi/2, -pi/2)) + Interval(pi/2, 3*pi/2) + >>> normalize_theta_set(FiniteSet(0, pi, 3*pi)) + {0, pi} + + """ + from sympy.functions.elementary.trigonometric import _pi_coeff + + if theta.is_Interval: + interval_len = theta.measure + # one complete circle + if interval_len >= 2*S.Pi: + if interval_len == 2*S.Pi and theta.left_open and theta.right_open: + k = _pi_coeff(theta.start) + return Union(Interval(0, k*S.Pi, False, True), + Interval(k*S.Pi, 2*S.Pi, True, True)) + return Interval(0, 2*S.Pi, False, True) + + k_start, k_end = _pi_coeff(theta.start), _pi_coeff(theta.end) + + if k_start is None or k_end is None: + raise NotImplementedError("Normalizing theta without pi as coefficient is " + "not yet implemented") + new_start = k_start*S.Pi + new_end = k_end*S.Pi + + if new_start > new_end: + return Union(Interval(S.Zero, new_end, False, theta.right_open), + Interval(new_start, 2*S.Pi, theta.left_open, True)) + else: + return Interval(new_start, new_end, theta.left_open, theta.right_open) + + elif theta.is_FiniteSet: + new_theta = [] + for element in theta: + k = _pi_coeff(element) + if k is None: + raise NotImplementedError('Normalizing theta without pi as ' + 'coefficient, is not Implemented.') + else: + new_theta.append(k*S.Pi) + return FiniteSet(*new_theta) + + elif theta.is_Union: + return Union(*[normalize_theta_set(interval) for interval in theta.args]) + + elif theta.is_subset(S.Reals): + raise NotImplementedError("Normalizing theta when, it is of type %s is not " + "implemented" % type(theta)) + else: + raise ValueError(" %s is not a real set" % (theta)) + + +class ComplexRegion(Set): + r""" + Represents the Set of all Complex Numbers. It can represent a + region of Complex Plane in both the standard forms Polar and + Rectangular coordinates. + + * Polar Form + Input is in the form of the ProductSet or Union of ProductSets + of the intervals of ``r`` and ``theta``, and use the flag ``polar=True``. + + .. math:: Z = \{z \in \mathbb{C} \mid z = r\times (\cos(\theta) + I\sin(\theta)), r \in [\texttt{r}], \theta \in [\texttt{theta}]\} + + * Rectangular Form + Input is in the form of the ProductSet or Union of ProductSets + of interval of x and y, the real and imaginary parts of the Complex numbers in a plane. + Default input type is in rectangular form. + + .. math:: Z = \{z \in \mathbb{C} \mid z = x + Iy, x \in [\operatorname{re}(z)], y \in [\operatorname{im}(z)]\} + + Examples + ======== + + >>> from sympy import ComplexRegion, Interval, S, I, Union + >>> a = Interval(2, 3) + >>> b = Interval(4, 6) + >>> c1 = ComplexRegion(a*b) # Rectangular Form + >>> c1 + CartesianComplexRegion(ProductSet(Interval(2, 3), Interval(4, 6))) + + * c1 represents the rectangular region in complex plane + surrounded by the coordinates (2, 4), (3, 4), (3, 6) and + (2, 6), of the four vertices. + + >>> c = Interval(1, 8) + >>> c2 = ComplexRegion(Union(a*b, b*c)) + >>> c2 + CartesianComplexRegion(Union(ProductSet(Interval(2, 3), Interval(4, 6)), ProductSet(Interval(4, 6), Interval(1, 8)))) + + * c2 represents the Union of two rectangular regions in complex + plane. One of them surrounded by the coordinates of c1 and + other surrounded by the coordinates (4, 1), (6, 1), (6, 8) and + (4, 8). + + >>> 2.5 + 4.5*I in c1 + True + >>> 2.5 + 6.5*I in c1 + False + + >>> r = Interval(0, 1) + >>> theta = Interval(0, 2*S.Pi) + >>> c2 = ComplexRegion(r*theta, polar=True) # Polar Form + >>> c2 # unit Disk + PolarComplexRegion(ProductSet(Interval(0, 1), Interval.Ropen(0, 2*pi))) + + * c2 represents the region in complex plane inside the + Unit Disk centered at the origin. + + >>> 0.5 + 0.5*I in c2 + True + >>> 1 + 2*I in c2 + False + + >>> unit_disk = ComplexRegion(Interval(0, 1)*Interval(0, 2*S.Pi), polar=True) + >>> upper_half_unit_disk = ComplexRegion(Interval(0, 1)*Interval(0, S.Pi), polar=True) + >>> intersection = unit_disk.intersect(upper_half_unit_disk) + >>> intersection + PolarComplexRegion(ProductSet(Interval(0, 1), Interval(0, pi))) + >>> intersection == upper_half_unit_disk + True + + See Also + ======== + + CartesianComplexRegion + PolarComplexRegion + Complexes + + """ + is_ComplexRegion = True + + def __new__(cls, sets, polar=False): + if polar is False: + return CartesianComplexRegion(sets) + elif polar is True: + return PolarComplexRegion(sets) + else: + raise ValueError("polar should be either True or False") + + @property + def sets(self): + """ + Return raw input sets to the self. + + Examples + ======== + + >>> from sympy import Interval, ComplexRegion, Union + >>> a = Interval(2, 3) + >>> b = Interval(4, 5) + >>> c = Interval(1, 7) + >>> C1 = ComplexRegion(a*b) + >>> C1.sets + ProductSet(Interval(2, 3), Interval(4, 5)) + >>> C2 = ComplexRegion(Union(a*b, b*c)) + >>> C2.sets + Union(ProductSet(Interval(2, 3), Interval(4, 5)), ProductSet(Interval(4, 5), Interval(1, 7))) + + """ + return self.args[0] + + @property + def psets(self): + """ + Return a tuple of sets (ProductSets) input of the self. + + Examples + ======== + + >>> from sympy import Interval, ComplexRegion, Union + >>> a = Interval(2, 3) + >>> b = Interval(4, 5) + >>> c = Interval(1, 7) + >>> C1 = ComplexRegion(a*b) + >>> C1.psets + (ProductSet(Interval(2, 3), Interval(4, 5)),) + >>> C2 = ComplexRegion(Union(a*b, b*c)) + >>> C2.psets + (ProductSet(Interval(2, 3), Interval(4, 5)), ProductSet(Interval(4, 5), Interval(1, 7))) + + """ + if self.sets.is_ProductSet: + psets = () + psets = psets + (self.sets, ) + else: + psets = self.sets.args + return psets + + @property + def a_interval(self): + """ + Return the union of intervals of `x` when, self is in + rectangular form, or the union of intervals of `r` when + self is in polar form. + + Examples + ======== + + >>> from sympy import Interval, ComplexRegion, Union + >>> a = Interval(2, 3) + >>> b = Interval(4, 5) + >>> c = Interval(1, 7) + >>> C1 = ComplexRegion(a*b) + >>> C1.a_interval + Interval(2, 3) + >>> C2 = ComplexRegion(Union(a*b, b*c)) + >>> C2.a_interval + Union(Interval(2, 3), Interval(4, 5)) + + """ + a_interval = [] + for element in self.psets: + a_interval.append(element.args[0]) + + a_interval = Union(*a_interval) + return a_interval + + @property + def b_interval(self): + """ + Return the union of intervals of `y` when, self is in + rectangular form, or the union of intervals of `theta` + when self is in polar form. + + Examples + ======== + + >>> from sympy import Interval, ComplexRegion, Union + >>> a = Interval(2, 3) + >>> b = Interval(4, 5) + >>> c = Interval(1, 7) + >>> C1 = ComplexRegion(a*b) + >>> C1.b_interval + Interval(4, 5) + >>> C2 = ComplexRegion(Union(a*b, b*c)) + >>> C2.b_interval + Interval(1, 7) + + """ + b_interval = [] + for element in self.psets: + b_interval.append(element.args[1]) + + b_interval = Union(*b_interval) + return b_interval + + @property + def _measure(self): + """ + The measure of self.sets. + + Examples + ======== + + >>> from sympy import Interval, ComplexRegion, S + >>> a, b = Interval(2, 5), Interval(4, 8) + >>> c = Interval(0, 2*S.Pi) + >>> c1 = ComplexRegion(a*b) + >>> c1.measure + 12 + >>> c2 = ComplexRegion(a*c, polar=True) + >>> c2.measure + 6*pi + + """ + return self.sets._measure + + def _kind(self): + return self.args[0].kind + + @classmethod + def from_real(cls, sets): + """ + Converts given subset of real numbers to a complex region. + + Examples + ======== + + >>> from sympy import Interval, ComplexRegion + >>> unit = Interval(0,1) + >>> ComplexRegion.from_real(unit) + CartesianComplexRegion(ProductSet(Interval(0, 1), {0})) + + """ + if not sets.is_subset(S.Reals): + raise ValueError("sets must be a subset of the real line") + + return CartesianComplexRegion(sets * FiniteSet(0)) + + def _contains(self, other): + from sympy.functions import arg, Abs + + isTuple = isinstance(other, Tuple) + if isTuple and len(other) != 2: + raise ValueError('expecting Tuple of length 2') + + # If the other is not an Expression, and neither a Tuple + if not isinstance(other, (Expr, Tuple)): + return S.false + + # self in rectangular form + if not self.polar: + re, im = other if isTuple else other.as_real_imag() + return tfn[fuzzy_or(fuzzy_and([ + pset.args[0]._contains(re), + pset.args[1]._contains(im)]) + for pset in self.psets)] + + # self in polar form + elif self.polar: + if other.is_zero: + # ignore undefined complex argument + return tfn[fuzzy_or(pset.args[0]._contains(S.Zero) + for pset in self.psets)] + if isTuple: + r, theta = other + else: + r, theta = Abs(other), arg(other) + if theta.is_real and theta.is_number: + # angles in psets are normalized to [0, 2pi) + theta %= 2*S.Pi + return tfn[fuzzy_or(fuzzy_and([ + pset.args[0]._contains(r), + pset.args[1]._contains(theta)]) + for pset in self.psets)] + + +class CartesianComplexRegion(ComplexRegion): + r""" + Set representing a square region of the complex plane. + + .. math:: Z = \{z \in \mathbb{C} \mid z = x + Iy, x \in [\operatorname{re}(z)], y \in [\operatorname{im}(z)]\} + + Examples + ======== + + >>> from sympy import ComplexRegion, I, Interval + >>> region = ComplexRegion(Interval(1, 3) * Interval(4, 6)) + >>> 2 + 5*I in region + True + >>> 5*I in region + False + + See also + ======== + + ComplexRegion + PolarComplexRegion + Complexes + """ + + polar = False + variables = symbols('x, y', cls=Dummy) + + def __new__(cls, sets): + + if sets == S.Reals*S.Reals: + return S.Complexes + + if all(_a.is_FiniteSet for _a in sets.args) and (len(sets.args) == 2): + + # ** ProductSet of FiniteSets in the Complex Plane. ** + # For Cases like ComplexRegion({2, 4}*{3}), It + # would return {2 + 3*I, 4 + 3*I} + + # FIXME: This should probably be handled with something like: + # return ImageSet(Lambda((x, y), x+I*y), sets).rewrite(FiniteSet) + complex_num = [] + for x in sets.args[0]: + for y in sets.args[1]: + complex_num.append(x + S.ImaginaryUnit*y) + return FiniteSet(*complex_num) + else: + return Set.__new__(cls, sets) + + @property + def expr(self): + x, y = self.variables + return x + S.ImaginaryUnit*y + + +class PolarComplexRegion(ComplexRegion): + r""" + Set representing a polar region of the complex plane. + + .. math:: Z = \{z \in \mathbb{C} \mid z = r\times (\cos(\theta) + I\sin(\theta)), r \in [\texttt{r}], \theta \in [\texttt{theta}]\} + + Examples + ======== + + >>> from sympy import ComplexRegion, Interval, oo, pi, I + >>> rset = Interval(0, oo) + >>> thetaset = Interval(0, pi) + >>> upper_half_plane = ComplexRegion(rset * thetaset, polar=True) + >>> 1 + I in upper_half_plane + True + >>> 1 - I in upper_half_plane + False + + See also + ======== + + ComplexRegion + CartesianComplexRegion + Complexes + + """ + + polar = True + variables = symbols('r, theta', cls=Dummy) + + def __new__(cls, sets): + + new_sets = [] + # sets is Union of ProductSets + if not sets.is_ProductSet: + for k in sets.args: + new_sets.append(k) + # sets is ProductSets + else: + new_sets.append(sets) + # Normalize input theta + for k, v in enumerate(new_sets): + new_sets[k] = ProductSet(v.args[0], + normalize_theta_set(v.args[1])) + sets = Union(*new_sets) + return Set.__new__(cls, sets) + + @property + def expr(self): + r, theta = self.variables + return r*(cos(theta) + S.ImaginaryUnit*sin(theta)) + + +class Complexes(CartesianComplexRegion, metaclass=Singleton): + """ + The :class:`Set` of all complex numbers + + Examples + ======== + + >>> from sympy import S, I + >>> S.Complexes + Complexes + >>> 1 + I in S.Complexes + True + + See also + ======== + + Reals + ComplexRegion + + """ + + is_empty = False + is_finite_set = False + + # Override property from superclass since Complexes has no args + @property + def sets(self): + return ProductSet(S.Reals, S.Reals) + + def __new__(cls): + return Set.__new__(cls) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/add.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/add.py new file mode 100644 index 0000000000000000000000000000000000000000..8c07b25ed19d21febffd6b23a92b34b787179f44 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/add.py @@ -0,0 +1,79 @@ +from sympy.core.numbers import oo, Infinity, NegativeInfinity +from sympy.core.singleton import S +from sympy.core import Basic, Expr +from sympy.multipledispatch import Dispatcher +from sympy.sets import Interval, FiniteSet + + + +# XXX: The functions in this module are clearly not tested and are broken in a +# number of ways. + +_set_add = Dispatcher('_set_add') +_set_sub = Dispatcher('_set_sub') + + +@_set_add.register(Basic, Basic) +def _(x, y): + return None + + +@_set_add.register(Expr, Expr) +def _(x, y): + return x+y + + +@_set_add.register(Interval, Interval) +def _(x, y): + """ + Additions in interval arithmetic + https://en.wikipedia.org/wiki/Interval_arithmetic + """ + return Interval(x.start + y.start, x.end + y.end, + x.left_open or y.left_open, x.right_open or y.right_open) + + +@_set_add.register(Interval, Infinity) +def _(x, y): + if x.start is S.NegativeInfinity: + return Interval(-oo, oo) + return FiniteSet({S.Infinity}) + +@_set_add.register(Interval, NegativeInfinity) +def _(x, y): + if x.end is S.Infinity: + return Interval(-oo, oo) + return FiniteSet({S.NegativeInfinity}) + + +@_set_sub.register(Basic, Basic) +def _(x, y): + return None + + +@_set_sub.register(Expr, Expr) +def _(x, y): + return x-y + + +@_set_sub.register(Interval, Interval) +def _(x, y): + """ + Subtractions in interval arithmetic + https://en.wikipedia.org/wiki/Interval_arithmetic + """ + return Interval(x.start - y.end, x.end - y.start, + x.left_open or y.right_open, x.right_open or y.left_open) + + +@_set_sub.register(Interval, Infinity) +def _(x, y): + if x.start is S.NegativeInfinity: + return Interval(-oo, oo) + return FiniteSet(-oo) + +@_set_sub.register(Interval, NegativeInfinity) +def _(x, y): + if x.start is S.NegativeInfinity: + return Interval(-oo, oo) + return FiniteSet(-oo) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/comparison.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/comparison.py new file mode 100644 index 0000000000000000000000000000000000000000..b64d1a2a22e15d09f6f10fb4fef730163d468d45 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/comparison.py @@ -0,0 +1,53 @@ +from sympy.core.relational import Eq, is_eq +from sympy.core.basic import Basic +from sympy.core.logic import fuzzy_and, fuzzy_bool +from sympy.logic.boolalg import And +from sympy.multipledispatch import dispatch +from sympy.sets.sets import tfn, ProductSet, Interval, FiniteSet, Set + + +@dispatch(Interval, FiniteSet) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + return False + + +@dispatch(FiniteSet, Interval) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + return False + + +@dispatch(Interval, Interval) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + return And(Eq(lhs.left, rhs.left), + Eq(lhs.right, rhs.right), + lhs.left_open == rhs.left_open, + lhs.right_open == rhs.right_open) + +@dispatch(FiniteSet, FiniteSet) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + def all_in_both(): + s_set = set(lhs.args) + o_set = set(rhs.args) + yield fuzzy_and(lhs._contains(e) for e in o_set - s_set) + yield fuzzy_and(rhs._contains(e) for e in s_set - o_set) + + return tfn[fuzzy_and(all_in_both())] + + +@dispatch(ProductSet, ProductSet) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + if len(lhs.sets) != len(rhs.sets): + return False + + eqs = (is_eq(x, y) for x, y in zip(lhs.sets, rhs.sets)) + return tfn[fuzzy_and(map(fuzzy_bool, eqs))] + + +@dispatch(Set, Basic) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + return False + + +@dispatch(Set, Set) # type:ignore +def _eval_is_eq(lhs, rhs): # noqa: F811 + return tfn[fuzzy_and(a.is_subset(b) for a, b in [(lhs, rhs), (rhs, lhs)])] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/functions.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/functions.py new file mode 100644 index 0000000000000000000000000000000000000000..2529dbfd458451d7d09e91c717b170df77b1d9fe --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/functions.py @@ -0,0 +1,262 @@ +from sympy.core.singleton import S +from sympy.sets.sets import Set +from sympy.calculus.singularities import singularities +from sympy.core import Expr, Add +from sympy.core.function import Lambda, FunctionClass, diff, expand_mul +from sympy.core.numbers import Float, oo +from sympy.core.symbol import Dummy, symbols, Wild +from sympy.functions.elementary.exponential import exp, log +from sympy.functions.elementary.miscellaneous import Min, Max +from sympy.logic.boolalg import true +from sympy.multipledispatch import Dispatcher +from sympy.sets import (imageset, Interval, FiniteSet, Union, ImageSet, + Intersection, Range, Complement) +from sympy.sets.sets import EmptySet, is_function_invertible_in_set +from sympy.sets.fancysets import Integers, Naturals, Reals +from sympy.functions.elementary.exponential import match_real_imag + + +_x, _y = symbols("x y") + +FunctionUnion = (FunctionClass, Lambda) + +_set_function = Dispatcher('_set_function') + + +@_set_function.register(FunctionClass, Set) +def _(f, x): + return None + +@_set_function.register(FunctionUnion, FiniteSet) +def _(f, x): + return FiniteSet(*map(f, x)) + +@_set_function.register(Lambda, Interval) +def _(f, x): + from sympy.solvers.solveset import solveset + from sympy.series import limit + # TODO: handle functions with infinitely many solutions (eg, sin, tan) + # TODO: handle multivariate functions + + expr = f.expr + if len(expr.free_symbols) > 1 or len(f.variables) != 1: + return + var = f.variables[0] + if not var.is_real: + if expr.subs(var, Dummy(real=True)).is_real is False: + return + + if expr.is_Piecewise: + result = S.EmptySet + domain_set = x + for (p_expr, p_cond) in expr.args: + if p_cond is true: + intrvl = domain_set + else: + intrvl = p_cond.as_set() + intrvl = Intersection(domain_set, intrvl) + + if p_expr.is_Number: + image = FiniteSet(p_expr) + else: + image = imageset(Lambda(var, p_expr), intrvl) + result = Union(result, image) + + # remove the part which has been `imaged` + domain_set = Complement(domain_set, intrvl) + if domain_set is S.EmptySet: + break + return result + + if not x.start.is_comparable or not x.end.is_comparable: + return + + try: + from sympy.polys.polyutils import _nsort + sing = list(singularities(expr, var, x)) + if len(sing) > 1: + sing = _nsort(sing) + except NotImplementedError: + return + + if x.left_open: + _start = limit(expr, var, x.start, dir="+") + elif x.start not in sing: + _start = f(x.start) + if x.right_open: + _end = limit(expr, var, x.end, dir="-") + elif x.end not in sing: + _end = f(x.end) + + if len(sing) == 0: + soln_expr = solveset(diff(expr, var), var) + if not (isinstance(soln_expr, FiniteSet) + or soln_expr is S.EmptySet): + return + solns = list(soln_expr) + + extr = [_start, _end] + [f(i) for i in solns + if i.is_real and i in x] + start, end = Min(*extr), Max(*extr) + + left_open, right_open = False, False + if _start <= _end: + # the minimum or maximum value can occur simultaneously + # on both the edge of the interval and in some interior + # point + if start == _start and start not in solns: + left_open = x.left_open + if end == _end and end not in solns: + right_open = x.right_open + else: + if start == _end and start not in solns: + left_open = x.right_open + if end == _start and end not in solns: + right_open = x.left_open + + return Interval(start, end, left_open, right_open) + else: + return imageset(f, Interval(x.start, sing[0], + x.left_open, True)) + \ + Union(*[imageset(f, Interval(sing[i], sing[i + 1], True, True)) + for i in range(0, len(sing) - 1)]) + \ + imageset(f, Interval(sing[-1], x.end, True, x.right_open)) + +@_set_function.register(FunctionClass, Interval) +def _(f, x): + if f == exp: + return Interval(exp(x.start), exp(x.end), x.left_open, x.right_open) + elif f == log: + return Interval(log(x.start), log(x.end), x.left_open, x.right_open) + return ImageSet(Lambda(_x, f(_x)), x) + +@_set_function.register(FunctionUnion, Union) +def _(f, x): + return Union(*(imageset(f, arg) for arg in x.args)) + +@_set_function.register(FunctionUnion, Intersection) +def _(f, x): + # If the function is invertible, intersect the maps of the sets. + if is_function_invertible_in_set(f, x): + return Intersection(*(imageset(f, arg) for arg in x.args)) + else: + return ImageSet(Lambda(_x, f(_x)), x) + +@_set_function.register(FunctionUnion, EmptySet) +def _(f, x): + return x + +@_set_function.register(FunctionUnion, Set) +def _(f, x): + return ImageSet(Lambda(_x, f(_x)), x) + +@_set_function.register(FunctionUnion, Range) +def _(f, self): + if not self: + return S.EmptySet + if not isinstance(f.expr, Expr): + return + if self.size == 1: + return FiniteSet(f(self[0])) + if f is S.IdentityFunction: + return self + + x = f.variables[0] + expr = f.expr + # handle f that is linear in f's variable + if x not in expr.free_symbols or x in expr.diff(x).free_symbols: + return + if self.start.is_finite: + F = f(self.step*x + self.start) # for i in range(len(self)) + else: + F = f(-self.step*x + self[-1]) + F = expand_mul(F) + if F != expr: + return imageset(x, F, Range(self.size)) + +@_set_function.register(FunctionUnion, Integers) +def _(f, self): + expr = f.expr + if not isinstance(expr, Expr): + return + + n = f.variables[0] + if expr == abs(n): + return S.Naturals0 + + # f(x) + c and f(-x) + c cover the same integers + # so choose the form that has the fewest negatives + c = f(0) + fx = f(n) - c + f_x = f(-n) - c + neg_count = lambda e: sum(_.could_extract_minus_sign() + for _ in Add.make_args(e)) + if neg_count(f_x) < neg_count(fx): + expr = f_x + c + + a = Wild('a', exclude=[n]) + b = Wild('b', exclude=[n]) + match = expr.match(a*n + b) + if match and match[a] and ( + not match[a].atoms(Float) and + not match[b].atoms(Float)): + # canonical shift + a, b = match[a], match[b] + if a in [1, -1]: + # drop integer addends in b + nonint = [] + for bi in Add.make_args(b): + if not bi.is_integer: + nonint.append(bi) + b = Add(*nonint) + if b.is_number and a.is_real: + # avoid Mod for complex numbers, #11391 + br, bi = match_real_imag(b) + if br and br.is_comparable and a.is_comparable: + br %= a + b = br + S.ImaginaryUnit*bi + elif b.is_number and a.is_imaginary: + br, bi = match_real_imag(b) + ai = a/S.ImaginaryUnit + if bi and bi.is_comparable and ai.is_comparable: + bi %= ai + b = br + S.ImaginaryUnit*bi + expr = a*n + b + + if expr != f.expr: + return ImageSet(Lambda(n, expr), S.Integers) + + +@_set_function.register(FunctionUnion, Naturals) +def _(f, self): + expr = f.expr + if not isinstance(expr, Expr): + return + + x = f.variables[0] + if not expr.free_symbols - {x}: + if expr == abs(x): + if self is S.Naturals: + return self + return S.Naturals0 + step = expr.coeff(x) + c = expr.subs(x, 0) + if c.is_Integer and step.is_Integer and expr == step*x + c: + if self is S.Naturals: + c += step + if step > 0: + if step == 1: + if c == 0: + return S.Naturals0 + elif c == 1: + return S.Naturals + return Range(c, oo, step) + return Range(c, -oo, step) + + +@_set_function.register(FunctionUnion, Reals) +def _(f, self): + expr = f.expr + if not isinstance(expr, Expr): + return + return _set_function(f, Interval(-oo, oo)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/intersection.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/intersection.py new file mode 100644 index 0000000000000000000000000000000000000000..fcb9309ef3e9d2722ab1bfe664f1d1644f17da5d --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/intersection.py @@ -0,0 +1,533 @@ +from sympy.core.basic import _aresame +from sympy.core.function import Lambda, expand_complex +from sympy.core.mul import Mul +from sympy.core.numbers import ilcm, Float +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, symbols) +from sympy.core.sorting import ordered +from sympy.functions.elementary.complexes import sign +from sympy.functions.elementary.integers import floor, ceiling +from sympy.sets.fancysets import ComplexRegion +from sympy.sets.sets import (FiniteSet, Intersection, Interval, Set, Union) +from sympy.multipledispatch import Dispatcher +from sympy.sets.conditionset import ConditionSet +from sympy.sets.fancysets import (Integers, Naturals, Reals, Range, + ImageSet, Rationals) +from sympy.sets.sets import EmptySet, UniversalSet, imageset, ProductSet +from sympy.simplify.radsimp import numer + + +intersection_sets = Dispatcher('intersection_sets') + + +@intersection_sets.register(ConditionSet, ConditionSet) +def _(a, b): + return None + +@intersection_sets.register(ConditionSet, Set) +def _(a, b): + return ConditionSet(a.sym, a.condition, Intersection(a.base_set, b)) + +@intersection_sets.register(Naturals, Integers) +def _(a, b): + return a + +@intersection_sets.register(Naturals, Naturals) +def _(a, b): + return a if a is S.Naturals else b + +@intersection_sets.register(Interval, Naturals) +def _(a, b): + return intersection_sets(b, a) + +@intersection_sets.register(ComplexRegion, Set) +def _(self, other): + if other.is_ComplexRegion: + # self in rectangular form + if (not self.polar) and (not other.polar): + return ComplexRegion(Intersection(self.sets, other.sets)) + + # self in polar form + elif self.polar and other.polar: + r1, theta1 = self.a_interval, self.b_interval + r2, theta2 = other.a_interval, other.b_interval + new_r_interval = Intersection(r1, r2) + new_theta_interval = Intersection(theta1, theta2) + + # 0 and 2*Pi means the same + if ((2*S.Pi in theta1 and S.Zero in theta2) or + (2*S.Pi in theta2 and S.Zero in theta1)): + new_theta_interval = Union(new_theta_interval, + FiniteSet(0)) + return ComplexRegion(new_r_interval*new_theta_interval, + polar=True) + + + if other.is_subset(S.Reals): + new_interval = [] + x = symbols("x", cls=Dummy, real=True) + + # self in rectangular form + if not self.polar: + for element in self.psets: + if S.Zero in element.args[1]: + new_interval.append(element.args[0]) + new_interval = Union(*new_interval) + return Intersection(new_interval, other) + + # self in polar form + elif self.polar: + for element in self.psets: + if S.Zero in element.args[1]: + new_interval.append(element.args[0]) + if S.Pi in element.args[1]: + new_interval.append(ImageSet(Lambda(x, -x), element.args[0])) + if S.Zero in element.args[0]: + new_interval.append(FiniteSet(0)) + new_interval = Union(*new_interval) + return Intersection(new_interval, other) + +@intersection_sets.register(Integers, Reals) +def _(a, b): + return a + +@intersection_sets.register(Range, Interval) +def _(a, b): + # Check that there are no symbolic arguments + if not all(i.is_number for i in a.args + b.args[:2]): + return + + # In case of null Range, return an EmptySet. + if a.size == 0: + return S.EmptySet + + # trim down to self's size, and represent + # as a Range with step 1. + start = ceiling(max(b.inf, a.inf)) + if start not in b: + start += 1 + end = floor(min(b.sup, a.sup)) + if end not in b: + end -= 1 + return intersection_sets(a, Range(start, end + 1)) + +@intersection_sets.register(Range, Naturals) +def _(a, b): + return intersection_sets(a, Interval(b.inf, S.Infinity)) + +@intersection_sets.register(Range, Range) +def _(a, b): + # Check that there are no symbolic range arguments + if not all(all(v.is_number for v in r.args) for r in [a, b]): + return None + + # non-overlap quick exits + if not b: + return S.EmptySet + if not a: + return S.EmptySet + if b.sup < a.inf: + return S.EmptySet + if b.inf > a.sup: + return S.EmptySet + + # work with finite end at the start + r1 = a + if r1.start.is_infinite: + r1 = r1.reversed + r2 = b + if r2.start.is_infinite: + r2 = r2.reversed + + # If both ends are infinite then it means that one Range is just the set + # of all integers (the step must be 1). + if r1.start.is_infinite: + return b + if r2.start.is_infinite: + return a + + from sympy.solvers.diophantine.diophantine import diop_linear + + # this equation represents the values of the Range; + # it's a linear equation + eq = lambda r, i: r.start + i*r.step + + # we want to know when the two equations might + # have integer solutions so we use the diophantine + # solver + va, vb = diop_linear(eq(r1, Dummy('a')) - eq(r2, Dummy('b'))) + + # check for no solution + no_solution = va is None and vb is None + if no_solution: + return S.EmptySet + + # there is a solution + # ------------------- + + # find the coincident point, c + a0 = va.as_coeff_Add()[0] + c = eq(r1, a0) + + # find the first point, if possible, in each range + # since c may not be that point + def _first_finite_point(r1, c): + if c == r1.start: + return c + # st is the signed step we need to take to + # get from c to r1.start + st = sign(r1.start - c)*step + # use Range to calculate the first point: + # we want to get as close as possible to + # r1.start; the Range will not be null since + # it will at least contain c + s1 = Range(c, r1.start + st, st)[-1] + if s1 == r1.start: + pass + else: + # if we didn't hit r1.start then, if the + # sign of st didn't match the sign of r1.step + # we are off by one and s1 is not in r1 + if sign(r1.step) != sign(st): + s1 -= st + if s1 not in r1: + return + return s1 + + # calculate the step size of the new Range + step = abs(ilcm(r1.step, r2.step)) + s1 = _first_finite_point(r1, c) + if s1 is None: + return S.EmptySet + s2 = _first_finite_point(r2, c) + if s2 is None: + return S.EmptySet + + # replace the corresponding start or stop in + # the original Ranges with these points; the + # result must have at least one point since + # we know that s1 and s2 are in the Ranges + def _updated_range(r, first): + st = sign(r.step)*step + if r.start.is_finite: + rv = Range(first, r.stop, st) + else: + rv = Range(r.start, first + st, st) + return rv + r1 = _updated_range(a, s1) + r2 = _updated_range(b, s2) + + # work with them both in the increasing direction + if sign(r1.step) < 0: + r1 = r1.reversed + if sign(r2.step) < 0: + r2 = r2.reversed + + # return clipped Range with positive step; it + # can't be empty at this point + start = max(r1.start, r2.start) + stop = min(r1.stop, r2.stop) + return Range(start, stop, step) + + +@intersection_sets.register(Range, Integers) +def _(a, b): + return a + + +@intersection_sets.register(Range, Rationals) +def _(a, b): + return a + + +@intersection_sets.register(ImageSet, Set) +def _(self, other): + from sympy.solvers.diophantine import diophantine + + # Only handle the straight-forward univariate case + if (len(self.lamda.variables) > 1 + or self.lamda.signature != self.lamda.variables): + return None + base_set = self.base_sets[0] + + # Intersection between ImageSets with Integers as base set + # For {f(n) : n in Integers} & {g(m) : m in Integers} we solve the + # diophantine equations f(n)=g(m). + # If the solutions for n are {h(t) : t in Integers} then we return + # {f(h(t)) : t in integers}. + # If the solutions for n are {n_1, n_2, ..., n_k} then we return + # {f(n_i) : 1 <= i <= k}. + if base_set is S.Integers: + gm = None + if isinstance(other, ImageSet) and other.base_sets == (S.Integers,): + gm = other.lamda.expr + var = other.lamda.variables[0] + # Symbol of second ImageSet lambda must be distinct from first + m = Dummy('m') + gm = gm.subs(var, m) + elif other is S.Integers: + m = gm = Dummy('m') + if gm is not None: + fn = self.lamda.expr + n = self.lamda.variables[0] + try: + solns = list(diophantine(fn - gm, syms=(n, m), permute=True)) + except (TypeError, NotImplementedError): + # TypeError if equation not polynomial with rational coeff. + # NotImplementedError if correct format but no solver. + return + # 3 cases are possible for solns: + # - empty set, + # - one or more parametric (infinite) solutions, + # - a finite number of (non-parametric) solution couples. + # Among those, there is one type of solution set that is + # not helpful here: multiple parametric solutions. + if len(solns) == 0: + return S.EmptySet + elif any(s.free_symbols for tupl in solns for s in tupl): + if len(solns) == 1: + soln, solm = solns[0] + (t,) = soln.free_symbols + expr = fn.subs(n, soln.subs(t, n)).expand() + return imageset(Lambda(n, expr), S.Integers) + else: + return + else: + return FiniteSet(*(fn.subs(n, s[0]) for s in solns)) + + if other == S.Reals: + from sympy.solvers.solvers import denoms, solve_linear + + def _solution_union(exprs, sym): + # return a union of linear solutions to i in expr; + # if i cannot be solved, use a ConditionSet for solution + sols = [] + for i in exprs: + x, xis = solve_linear(i, 0, [sym]) + if x == sym: + sols.append(FiniteSet(xis)) + else: + sols.append(ConditionSet(sym, Eq(i, 0))) + return Union(*sols) + + f = self.lamda.expr + n = self.lamda.variables[0] + + n_ = Dummy(n.name, real=True) + f_ = f.subs(n, n_) + + re, im = f_.as_real_imag() + im = expand_complex(im) + + re = re.subs(n_, n) + im = im.subs(n_, n) + ifree = im.free_symbols + lam = Lambda(n, re) + if im.is_zero: + # allow re-evaluation + # of self in this case to make + # the result canonical + pass + elif im.is_zero is False: + return S.EmptySet + elif ifree != {n}: + return None + else: + # univarite imaginary part in same variable; + # use numer instead of as_numer_denom to keep + # this as fast as possible while still handling + # simple cases + base_set &= _solution_union( + Mul.make_args(numer(im)), n) + # exclude values that make denominators 0 + base_set -= _solution_union(denoms(f), n) + return imageset(lam, base_set) + + elif isinstance(other, Interval): + from sympy.solvers.solveset import (invert_real, invert_complex, + solveset) + + f = self.lamda.expr + n = self.lamda.variables[0] + new_inf, new_sup = None, None + new_lopen, new_ropen = other.left_open, other.right_open + + if f.is_real: + inverter = invert_real + else: + inverter = invert_complex + + g1, h1 = inverter(f, other.inf, n) + g2, h2 = inverter(f, other.sup, n) + + if all(isinstance(i, FiniteSet) for i in (h1, h2)): + if g1 == n: + if len(h1) == 1: + new_inf = h1.args[0] + if g2 == n: + if len(h2) == 1: + new_sup = h2.args[0] + # TODO: Design a technique to handle multiple-inverse + # functions + + # Any of the new boundary values cannot be determined + if any(i is None for i in (new_sup, new_inf)): + return + + + range_set = S.EmptySet + + if all(i.is_real for i in (new_sup, new_inf)): + # this assumes continuity of underlying function + # however fixes the case when it is decreasing + if new_inf > new_sup: + new_inf, new_sup = new_sup, new_inf + new_interval = Interval(new_inf, new_sup, new_lopen, new_ropen) + range_set = base_set.intersect(new_interval) + else: + if other.is_subset(S.Reals): + solutions = solveset(f, n, S.Reals) + if not isinstance(range_set, (ImageSet, ConditionSet)): + range_set = solutions.intersect(other) + else: + return + + if range_set is S.EmptySet: + return S.EmptySet + elif isinstance(range_set, Range) and range_set.size is not S.Infinity: + range_set = FiniteSet(*list(range_set)) + + if range_set is not None: + return imageset(Lambda(n, f), range_set) + return + else: + return + + +@intersection_sets.register(ProductSet, ProductSet) +def _(a, b): + if len(b.args) != len(a.args): + return S.EmptySet + return ProductSet(*(i.intersect(j) for i, j in zip(a.sets, b.sets))) + + +@intersection_sets.register(Interval, Interval) +def _(a, b): + # handle (-oo, oo) + infty = S.NegativeInfinity, S.Infinity + if a == Interval(*infty): + l, r = a.left, a.right + if l.is_real or l in infty or r.is_real or r in infty: + return b + + # We can't intersect [0,3] with [x,6] -- we don't know if x>0 or x<0 + if not a._is_comparable(b): + return None + + empty = False + + if a.start <= b.end and b.start <= a.end: + # Get topology right. + if a.start < b.start: + start = b.start + left_open = b.left_open + elif a.start > b.start: + start = a.start + left_open = a.left_open + else: + start = a.start + if not _aresame(a.start, b.start): + # For example Integer(2) != Float(2) + # Prefer the Float boundary because Floats should be + # contagious in calculations. + if b.start.has(Float) and not a.start.has(Float): + start = b.start + elif a.start.has(Float) and not b.start.has(Float): + start = a.start + else: + #this is to ensure that if Eq(a.start, b.start) but + #type(a.start) != type(b.start) the order of a and b + #does not matter for the result + start = list(ordered([a,b]))[0].start + left_open = a.left_open or b.left_open + + if a.end < b.end: + end = a.end + right_open = a.right_open + elif a.end > b.end: + end = b.end + right_open = b.right_open + else: + # see above for logic with start + end = a.end + if not _aresame(a.end, b.end): + if b.end.has(Float) and not a.end.has(Float): + end = b.end + elif a.end.has(Float) and not b.end.has(Float): + end = a.end + else: + end = list(ordered([a,b]))[0].end + right_open = a.right_open or b.right_open + + if end - start == 0 and (left_open or right_open): + empty = True + else: + empty = True + + if empty: + return S.EmptySet + + return Interval(start, end, left_open, right_open) + +@intersection_sets.register(EmptySet, Set) +def _(a, b): + return S.EmptySet + +@intersection_sets.register(UniversalSet, Set) +def _(a, b): + return b + +@intersection_sets.register(FiniteSet, FiniteSet) +def _(a, b): + return FiniteSet(*(a._elements & b._elements)) + +@intersection_sets.register(FiniteSet, Set) +def _(a, b): + try: + return FiniteSet(*[el for el in a if el in b]) + except TypeError: + return None # could not evaluate `el in b` due to symbolic ranges. + +@intersection_sets.register(Set, Set) +def _(a, b): + return None + +@intersection_sets.register(Integers, Rationals) +def _(a, b): + return a + +@intersection_sets.register(Naturals, Rationals) +def _(a, b): + return a + +@intersection_sets.register(Rationals, Reals) +def _(a, b): + return a + +def _intlike_interval(a, b): + try: + if b._inf is S.NegativeInfinity and b._sup is S.Infinity: + return a + s = Range(max(a.inf, ceiling(b.left)), floor(b.right) + 1) + return intersection_sets(s, b) # take out endpoints if open interval + except ValueError: + return None + +@intersection_sets.register(Integers, Interval) +def _(a, b): + return _intlike_interval(a, b) + +@intersection_sets.register(Naturals, Interval) +def _(a, b): + return _intlike_interval(a, b) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/issubset.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/issubset.py new file mode 100644 index 0000000000000000000000000000000000000000..cc23e8bf56f1743cd7f08452dd09a0acf981f5da --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/issubset.py @@ -0,0 +1,144 @@ +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.core.logic import fuzzy_and, fuzzy_bool, fuzzy_not, fuzzy_or +from sympy.core.relational import Eq +from sympy.sets.sets import FiniteSet, Interval, Set, Union, ProductSet +from sympy.sets.fancysets import Complexes, Reals, Range, Rationals +from sympy.multipledispatch import Dispatcher + + +_inf_sets = [S.Naturals, S.Naturals0, S.Integers, S.Rationals, S.Reals, S.Complexes] + + +is_subset_sets = Dispatcher('is_subset_sets') + + +@is_subset_sets.register(Set, Set) +def _(a, b): + return None + +@is_subset_sets.register(Interval, Interval) +def _(a, b): + # This is correct but can be made more comprehensive... + if fuzzy_bool(a.start < b.start): + return False + if fuzzy_bool(a.end > b.end): + return False + if (b.left_open and not a.left_open and fuzzy_bool(Eq(a.start, b.start))): + return False + if (b.right_open and not a.right_open and fuzzy_bool(Eq(a.end, b.end))): + return False + +@is_subset_sets.register(Interval, FiniteSet) +def _(a_interval, b_fs): + # An Interval can only be a subset of a finite set if it is finite + # which can only happen if it has zero measure. + if fuzzy_not(a_interval.measure.is_zero): + return False + +@is_subset_sets.register(Interval, Union) +def _(a_interval, b_u): + if all(isinstance(s, (Interval, FiniteSet)) for s in b_u.args): + intervals = [s for s in b_u.args if isinstance(s, Interval)] + if all(fuzzy_bool(a_interval.start < s.start) for s in intervals): + return False + if all(fuzzy_bool(a_interval.end > s.end) for s in intervals): + return False + if a_interval.measure.is_nonzero: + no_overlap = lambda s1, s2: fuzzy_or([ + fuzzy_bool(s1.end <= s2.start), + fuzzy_bool(s1.start >= s2.end), + ]) + if all(no_overlap(s, a_interval) for s in intervals): + return False + +@is_subset_sets.register(Range, Range) +def _(a, b): + if a.step == b.step == 1: + return fuzzy_and([fuzzy_bool(a.start >= b.start), + fuzzy_bool(a.stop <= b.stop)]) + +@is_subset_sets.register(Range, Interval) +def _(a_range, b_interval): + if a_range.step.is_positive: + if b_interval.left_open and a_range.inf.is_finite: + cond_left = a_range.inf > b_interval.left + else: + cond_left = a_range.inf >= b_interval.left + if b_interval.right_open and a_range.sup.is_finite: + cond_right = a_range.sup < b_interval.right + else: + cond_right = a_range.sup <= b_interval.right + return fuzzy_and([cond_left, cond_right]) + +@is_subset_sets.register(Range, FiniteSet) +def _(a_range, b_finiteset): + try: + a_size = a_range.size + except ValueError: + # symbolic Range of unknown size + return None + if a_size > len(b_finiteset): + return False + elif any(arg.has(Symbol) for arg in a_range.args): + return fuzzy_and(b_finiteset.contains(x) for x in a_range) + else: + # Checking A \ B == EmptySet is more efficient than repeated naive + # membership checks on an arbitrary FiniteSet. + a_set = set(a_range) + b_remaining = len(b_finiteset) + # Symbolic expressions and numbers of unknown type (integer or not) are + # all counted as "candidates", i.e. *potentially* matching some a in + # a_range. + cnt_candidate = 0 + for b in b_finiteset: + if b.is_Integer: + a_set.discard(b) + elif fuzzy_not(b.is_integer): + pass + else: + cnt_candidate += 1 + b_remaining -= 1 + if len(a_set) > b_remaining + cnt_candidate: + return False + if len(a_set) == 0: + return True + return None + +@is_subset_sets.register(Interval, Range) +def _(a_interval, b_range): + if a_interval.measure.is_extended_nonzero: + return False + +@is_subset_sets.register(Interval, Rationals) +def _(a_interval, b_rationals): + if a_interval.measure.is_extended_nonzero: + return False + +@is_subset_sets.register(Range, Complexes) +def _(a, b): + return True + +@is_subset_sets.register(Complexes, Interval) +def _(a, b): + return False + +@is_subset_sets.register(Complexes, Range) +def _(a, b): + return False + +@is_subset_sets.register(Complexes, Rationals) +def _(a, b): + return False + +@is_subset_sets.register(Rationals, Reals) +def _(a, b): + return True + +@is_subset_sets.register(Rationals, Range) +def _(a, b): + return False + +@is_subset_sets.register(ProductSet, FiniteSet) +def _(a_ps, b_fs): + return fuzzy_and(b_fs.contains(x) for x in a_ps) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/mul.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/mul.py new file mode 100644 index 0000000000000000000000000000000000000000..0dedc8068b7973fd4cb6fbf2854e5fa671d188de --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/mul.py @@ -0,0 +1,79 @@ +from sympy.core import Basic, Expr +from sympy.core.numbers import oo +from sympy.core.symbol import symbols +from sympy.multipledispatch import Dispatcher +from sympy.sets.setexpr import set_mul +from sympy.sets.sets import Interval, Set + + +_x, _y = symbols("x y") + + +_set_mul = Dispatcher('_set_mul') +_set_div = Dispatcher('_set_div') + + +@_set_mul.register(Basic, Basic) +def _(x, y): + return None + +@_set_mul.register(Set, Set) +def _(x, y): + return None + +@_set_mul.register(Expr, Expr) +def _(x, y): + return x*y + +@_set_mul.register(Interval, Interval) +def _(x, y): + """ + Multiplications in interval arithmetic + https://en.wikipedia.org/wiki/Interval_arithmetic + """ + # TODO: some intervals containing 0 and oo will fail as 0*oo returns nan. + comvals = ( + (x.start * y.start, bool(x.left_open or y.left_open)), + (x.start * y.end, bool(x.left_open or y.right_open)), + (x.end * y.start, bool(x.right_open or y.left_open)), + (x.end * y.end, bool(x.right_open or y.right_open)), + ) + # TODO: handle symbolic intervals + minval, minopen = min(comvals) + maxval, maxopen = max(comvals) + return Interval( + minval, + maxval, + minopen, + maxopen + ) + +@_set_div.register(Basic, Basic) +def _(x, y): + return None + +@_set_div.register(Expr, Expr) +def _(x, y): + return x/y + +@_set_div.register(Set, Set) +def _(x, y): + return None + +@_set_div.register(Interval, Interval) +def _(x, y): + """ + Divisions in interval arithmetic + https://en.wikipedia.org/wiki/Interval_arithmetic + """ + if (y.start*y.end).is_negative: + return Interval(-oo, oo) + if y.start == 0: + s2 = oo + else: + s2 = 1/y.start + if y.end == 0: + s1 = -oo + else: + s1 = 1/y.end + return set_mul(x, Interval(s1, s2, y.right_open, y.left_open)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/power.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/power.py new file mode 100644 index 0000000000000000000000000000000000000000..3cad4ee49ab27770143bc121d1fbcd024bf01548 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/power.py @@ -0,0 +1,107 @@ +from sympy.core import Basic, Expr +from sympy.core.function import Lambda +from sympy.core.numbers import oo, Infinity, NegativeInfinity, Zero, Integer +from sympy.core.singleton import S +from sympy.core.symbol import symbols +from sympy.functions.elementary.miscellaneous import (Max, Min) +from sympy.sets.fancysets import ImageSet +from sympy.sets.setexpr import set_div +from sympy.sets.sets import Set, Interval, FiniteSet, Union +from sympy.multipledispatch import Dispatcher + + +_x, _y = symbols("x y") + + +_set_pow = Dispatcher('_set_pow') + + +@_set_pow.register(Basic, Basic) +def _(x, y): + return None + +@_set_pow.register(Set, Set) +def _(x, y): + return ImageSet(Lambda((_x, _y), (_x ** _y)), x, y) + +@_set_pow.register(Expr, Expr) +def _(x, y): + return x**y + +@_set_pow.register(Interval, Zero) +def _(x, z): + return FiniteSet(S.One) + +@_set_pow.register(Interval, Integer) +def _(x, exponent): + """ + Powers in interval arithmetic + https://en.wikipedia.org/wiki/Interval_arithmetic + """ + s1 = x.start**exponent + s2 = x.end**exponent + if ((s2 > s1) if exponent > 0 else (x.end > -x.start)) == True: + left_open = x.left_open + right_open = x.right_open + # TODO: handle unevaluated condition. + sleft = s2 + else: + # TODO: `s2 > s1` could be unevaluated. + left_open = x.right_open + right_open = x.left_open + sleft = s1 + + if x.start.is_positive: + return Interval( + Min(s1, s2), + Max(s1, s2), left_open, right_open) + elif x.end.is_negative: + return Interval( + Min(s1, s2), + Max(s1, s2), left_open, right_open) + + # Case where x.start < 0 and x.end > 0: + if exponent.is_odd: + if exponent.is_negative: + if x.start.is_zero: + return Interval(s2, oo, x.right_open) + if x.end.is_zero: + return Interval(-oo, s1, True, x.left_open) + return Union(Interval(-oo, s1, True, x.left_open), Interval(s2, oo, x.right_open)) + else: + return Interval(s1, s2, x.left_open, x.right_open) + elif exponent.is_even: + if exponent.is_negative: + if x.start.is_zero: + return Interval(s2, oo, x.right_open) + if x.end.is_zero: + return Interval(s1, oo, x.left_open) + return Interval(0, oo) + else: + return Interval(S.Zero, sleft, S.Zero not in x, left_open) + +@_set_pow.register(Interval, Infinity) +def _(b, e): + # TODO: add logic for open intervals? + if b.start.is_nonnegative: + if b.end < 1: + return FiniteSet(S.Zero) + if b.start > 1: + return FiniteSet(S.Infinity) + return Interval(0, oo) + elif b.end.is_negative: + if b.start > -1: + return FiniteSet(S.Zero) + if b.end < -1: + return FiniteSet(-oo, oo) + return Interval(-oo, oo) + else: + if b.start > -1: + if b.end < 1: + return FiniteSet(S.Zero) + return Interval(0, oo) + return Interval(-oo, oo) + +@_set_pow.register(Interval, NegativeInfinity) +def _(b, e): + return _set_pow(set_div(S.One, b), oo) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/union.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/union.py new file mode 100644 index 0000000000000000000000000000000000000000..75d867b49969ae2aeea76155dbaae7e05c1a6847 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/handlers/union.py @@ -0,0 +1,147 @@ +from sympy.core.singleton import S +from sympy.core.sympify import sympify +from sympy.functions.elementary.miscellaneous import Min, Max +from sympy.sets.sets import (EmptySet, FiniteSet, Intersection, + Interval, ProductSet, Set, Union, UniversalSet) +from sympy.sets.fancysets import (ComplexRegion, Naturals, Naturals0, + Integers, Rationals, Reals) +from sympy.multipledispatch import Dispatcher + + +union_sets = Dispatcher('union_sets') + + +@union_sets.register(Naturals0, Naturals) +def _(a, b): + return a + +@union_sets.register(Rationals, Naturals) +def _(a, b): + return a + +@union_sets.register(Rationals, Naturals0) +def _(a, b): + return a + +@union_sets.register(Reals, Naturals) +def _(a, b): + return a + +@union_sets.register(Reals, Naturals0) +def _(a, b): + return a + +@union_sets.register(Reals, Rationals) +def _(a, b): + return a + +@union_sets.register(Integers, Set) +def _(a, b): + intersect = Intersection(a, b) + if intersect == a: + return b + elif intersect == b: + return a + +@union_sets.register(ComplexRegion, Set) +def _(a, b): + if b.is_subset(S.Reals): + # treat a subset of reals as a complex region + b = ComplexRegion.from_real(b) + + if b.is_ComplexRegion: + # a in rectangular form + if (not a.polar) and (not b.polar): + return ComplexRegion(Union(a.sets, b.sets)) + # a in polar form + elif a.polar and b.polar: + return ComplexRegion(Union(a.sets, b.sets), polar=True) + return None + +@union_sets.register(EmptySet, Set) +def _(a, b): + return b + + +@union_sets.register(UniversalSet, Set) +def _(a, b): + return a + +@union_sets.register(ProductSet, ProductSet) +def _(a, b): + if b.is_subset(a): + return a + if len(b.sets) != len(a.sets): + return None + if len(a.sets) == 2: + a1, a2 = a.sets + b1, b2 = b.sets + if a1 == b1: + return a1 * Union(a2, b2) + if a2 == b2: + return Union(a1, b1) * a2 + return None + +@union_sets.register(ProductSet, Set) +def _(a, b): + if b.is_subset(a): + return a + return None + +@union_sets.register(Interval, Interval) +def _(a, b): + if a._is_comparable(b): + # Non-overlapping intervals + end = Min(a.end, b.end) + start = Max(a.start, b.start) + if (end < start or + (end == start and (end not in a and end not in b))): + return None + else: + start = Min(a.start, b.start) + end = Max(a.end, b.end) + + left_open = ((a.start != start or a.left_open) and + (b.start != start or b.left_open)) + right_open = ((a.end != end or a.right_open) and + (b.end != end or b.right_open)) + return Interval(start, end, left_open, right_open) + +@union_sets.register(Interval, UniversalSet) +def _(a, b): + return S.UniversalSet + +@union_sets.register(Interval, Set) +def _(a, b): + # If I have open end points and these endpoints are contained in b + # But only in case, when endpoints are finite. Because + # interval does not contain oo or -oo. + open_left_in_b_and_finite = (a.left_open and + sympify(b.contains(a.start)) is S.true and + a.start.is_finite) + open_right_in_b_and_finite = (a.right_open and + sympify(b.contains(a.end)) is S.true and + a.end.is_finite) + if open_left_in_b_and_finite or open_right_in_b_and_finite: + # Fill in my end points and return + open_left = a.left_open and a.start not in b + open_right = a.right_open and a.end not in b + new_a = Interval(a.start, a.end, open_left, open_right) + return {new_a, b} + return None + +@union_sets.register(FiniteSet, FiniteSet) +def _(a, b): + return FiniteSet(*(a._elements | b._elements)) + +@union_sets.register(FiniteSet, Set) +def _(a, b): + # If `b` set contains one of my elements, remove it from `a` + if any(b.contains(x) == True for x in a): + return { + FiniteSet(*[x for x in a if b.contains(x) != True]), b} + return None + +@union_sets.register(Set, Set) +def _(a, b): + return None diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/ordinals.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/ordinals.py new file mode 100644 index 0000000000000000000000000000000000000000..cfe062354cfe58a4747998e51fa0d261e67576cc --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/ordinals.py @@ -0,0 +1,282 @@ +from sympy.core import Basic, Integer +import operator + + +class OmegaPower(Basic): + """ + Represents ordinal exponential and multiplication terms one of the + building blocks of the :class:`Ordinal` class. + In ``OmegaPower(a, b)``, ``a`` represents exponent and ``b`` represents multiplicity. + """ + def __new__(cls, a, b): + if isinstance(b, int): + b = Integer(b) + if not isinstance(b, Integer) or b <= 0: + raise TypeError("multiplicity must be a positive integer") + + if not isinstance(a, Ordinal): + a = Ordinal.convert(a) + + return Basic.__new__(cls, a, b) + + @property + def exp(self): + return self.args[0] + + @property + def mult(self): + return self.args[1] + + def _compare_term(self, other, op): + if self.exp == other.exp: + return op(self.mult, other.mult) + else: + return op(self.exp, other.exp) + + def __eq__(self, other): + if not isinstance(other, OmegaPower): + try: + other = OmegaPower(0, other) + except TypeError: + return NotImplemented + return self.args == other.args + + def __hash__(self): + return Basic.__hash__(self) + + def __lt__(self, other): + if not isinstance(other, OmegaPower): + try: + other = OmegaPower(0, other) + except TypeError: + return NotImplemented + return self._compare_term(other, operator.lt) + + +class Ordinal(Basic): + """ + Represents ordinals in Cantor normal form. + + Internally, this class is just a list of instances of OmegaPower. + + Examples + ======== + >>> from sympy import Ordinal, OmegaPower + >>> from sympy.sets.ordinals import omega + >>> w = omega + >>> w.is_limit_ordinal + True + >>> Ordinal(OmegaPower(w + 1, 1), OmegaPower(3, 2)) + w**(w + 1) + w**3*2 + >>> 3 + w + w + >>> (w + 1) * w + w**2 + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Ordinal_arithmetic + """ + def __new__(cls, *terms): + obj = super().__new__(cls, *terms) + powers = [i.exp for i in obj.args] + if not all(powers[i] >= powers[i+1] for i in range(len(powers) - 1)): + raise ValueError("powers must be in decreasing order") + return obj + + @property + def terms(self): + return self.args + + @property + def leading_term(self): + if self == ord0: + raise ValueError("ordinal zero has no leading term") + return self.terms[0] + + @property + def trailing_term(self): + if self == ord0: + raise ValueError("ordinal zero has no trailing term") + return self.terms[-1] + + @property + def is_successor_ordinal(self): + try: + return self.trailing_term.exp == ord0 + except ValueError: + return False + + @property + def is_limit_ordinal(self): + try: + return not self.trailing_term.exp == ord0 + except ValueError: + return False + + @property + def degree(self): + return self.leading_term.exp + + @classmethod + def convert(cls, integer_value): + if integer_value == 0: + return ord0 + return Ordinal(OmegaPower(0, integer_value)) + + def __eq__(self, other): + if not isinstance(other, Ordinal): + try: + other = Ordinal.convert(other) + except TypeError: + return NotImplemented + return self.terms == other.terms + + def __hash__(self): + return hash(self.args) + + def __lt__(self, other): + if not isinstance(other, Ordinal): + try: + other = Ordinal.convert(other) + except TypeError: + return NotImplemented + for term_self, term_other in zip(self.terms, other.terms): + if term_self != term_other: + return term_self < term_other + return len(self.terms) < len(other.terms) + + def __le__(self, other): + return (self == other or self < other) + + def __gt__(self, other): + return not self <= other + + def __ge__(self, other): + return not self < other + + def __str__(self): + net_str = "" + plus_count = 0 + if self == ord0: + return 'ord0' + for i in self.terms: + if plus_count: + net_str += " + " + + if i.exp == ord0: + net_str += str(i.mult) + elif i.exp == 1: + net_str += 'w' + elif len(i.exp.terms) > 1 or i.exp.is_limit_ordinal: + net_str += 'w**(%s)'%i.exp + else: + net_str += 'w**%s'%i.exp + + if not i.mult == 1 and not i.exp == ord0: + net_str += '*%s'%i.mult + + plus_count += 1 + return(net_str) + + __repr__ = __str__ + + def __add__(self, other): + if not isinstance(other, Ordinal): + try: + other = Ordinal.convert(other) + except TypeError: + return NotImplemented + if other == ord0: + return self + a_terms = list(self.terms) + b_terms = list(other.terms) + r = len(a_terms) - 1 + b_exp = other.degree + while r >= 0 and a_terms[r].exp < b_exp: + r -= 1 + if r < 0: + terms = b_terms + elif a_terms[r].exp == b_exp: + sum_term = OmegaPower(b_exp, a_terms[r].mult + other.leading_term.mult) + terms = a_terms[:r] + [sum_term] + b_terms[1:] + else: + terms = a_terms[:r+1] + b_terms + return Ordinal(*terms) + + def __radd__(self, other): + if not isinstance(other, Ordinal): + try: + other = Ordinal.convert(other) + except TypeError: + return NotImplemented + return other + self + + def __mul__(self, other): + if not isinstance(other, Ordinal): + try: + other = Ordinal.convert(other) + except TypeError: + return NotImplemented + if ord0 in (self, other): + return ord0 + a_exp = self.degree + a_mult = self.leading_term.mult + summation = [] + if other.is_limit_ordinal: + for arg in other.terms: + summation.append(OmegaPower(a_exp + arg.exp, arg.mult)) + + else: + for arg in other.terms[:-1]: + summation.append(OmegaPower(a_exp + arg.exp, arg.mult)) + b_mult = other.trailing_term.mult + summation.append(OmegaPower(a_exp, a_mult*b_mult)) + summation += list(self.terms[1:]) + return Ordinal(*summation) + + def __rmul__(self, other): + if not isinstance(other, Ordinal): + try: + other = Ordinal.convert(other) + except TypeError: + return NotImplemented + return other * self + + def __pow__(self, other): + if not self == omega: + return NotImplemented + return Ordinal(OmegaPower(other, 1)) + + +class OrdinalZero(Ordinal): + """The ordinal zero. + + OrdinalZero can be imported as ``ord0``. + """ + pass + + +class OrdinalOmega(Ordinal): + """The ordinal omega which forms the base of all ordinals in cantor normal form. + + OrdinalOmega can be imported as ``omega``. + + Examples + ======== + + >>> from sympy.sets.ordinals import omega + >>> omega + omega + w*2 + """ + def __new__(cls): + return Ordinal.__new__(cls) + + @property + def terms(self): + return (OmegaPower(1, 1),) + + +ord0 = OrdinalZero() +omega = OrdinalOmega() diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/powerset.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/powerset.py new file mode 100644 index 0000000000000000000000000000000000000000..2eb3b41b9859281480bc9517a1cad0abe7a5683f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/powerset.py @@ -0,0 +1,119 @@ +from sympy.core.decorators import _sympifyit +from sympy.core.parameters import global_parameters +from sympy.core.logic import fuzzy_bool +from sympy.core.singleton import S +from sympy.core.sympify import _sympify + +from .sets import Set, FiniteSet, SetKind + + +class PowerSet(Set): + r"""A symbolic object representing a power set. + + Parameters + ========== + + arg : Set + The set to take power of. + + evaluate : bool + The flag to control evaluation. + + If the evaluation is disabled for finite sets, it can take + advantage of using subset test as a membership test. + + Notes + ===== + + Power set `\mathcal{P}(S)` is defined as a set containing all the + subsets of `S`. + + If the set `S` is a finite set, its power set would have + `2^{\left| S \right|}` elements, where `\left| S \right|` denotes + the cardinality of `S`. + + Examples + ======== + + >>> from sympy import PowerSet, S, FiniteSet + + A power set of a finite set: + + >>> PowerSet(FiniteSet(1, 2, 3)) + PowerSet({1, 2, 3}) + + A power set of an empty set: + + >>> PowerSet(S.EmptySet) + PowerSet(EmptySet) + >>> PowerSet(PowerSet(S.EmptySet)) + PowerSet(PowerSet(EmptySet)) + + A power set of an infinite set: + + >>> PowerSet(S.Reals) + PowerSet(Reals) + + Evaluating the power set of a finite set to its explicit form: + + >>> PowerSet(FiniteSet(1, 2, 3)).rewrite(FiniteSet) + FiniteSet(EmptySet, {1}, {2}, {3}, {1, 2}, {1, 3}, {2, 3}, {1, 2, 3}) + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Power_set + + .. [2] https://en.wikipedia.org/wiki/Axiom_of_power_set + """ + def __new__(cls, arg, evaluate=None): + if evaluate is None: + evaluate=global_parameters.evaluate + + arg = _sympify(arg) + + if not isinstance(arg, Set): + raise ValueError('{} must be a set.'.format(arg)) + + return super().__new__(cls, arg) + + @property + def arg(self): + return self.args[0] + + def _eval_rewrite_as_FiniteSet(self, *args, **kwargs): + arg = self.arg + if arg.is_FiniteSet: + return arg.powerset() + return None + + @_sympifyit('other', NotImplemented) + def _contains(self, other): + if not isinstance(other, Set): + return None + + return fuzzy_bool(self.arg.is_superset(other)) + + def _eval_is_subset(self, other): + if isinstance(other, PowerSet): + return self.arg.is_subset(other.arg) + + def __len__(self): + return 2 ** len(self.arg) + + def __iter__(self): + found = [S.EmptySet] + yield S.EmptySet + + for x in self.arg: + temp = [] + x = FiniteSet(x) + for y in found: + new = x + y + yield new + temp.append(new) + found.extend(temp) + + @property + def kind(self): + return SetKind(self.arg.kind) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/setexpr.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/setexpr.py new file mode 100644 index 0000000000000000000000000000000000000000..94d77d5293617a620b70a945888987ce6cc61157 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/setexpr.py @@ -0,0 +1,97 @@ +from sympy.core import Expr +from sympy.core.decorators import call_highest_priority, _sympifyit +from .fancysets import ImageSet +from .sets import set_add, set_sub, set_mul, set_div, set_pow, set_function + + +class SetExpr(Expr): + """An expression that can take on values of a set. + + Examples + ======== + + >>> from sympy import Interval, FiniteSet + >>> from sympy.sets.setexpr import SetExpr + + >>> a = SetExpr(Interval(0, 5)) + >>> b = SetExpr(FiniteSet(1, 10)) + >>> (a + b).set + Union(Interval(1, 6), Interval(10, 15)) + >>> (2*a + b).set + Interval(1, 20) + """ + _op_priority = 11.0 + + def __new__(cls, setarg): + return Expr.__new__(cls, setarg) + + set = property(lambda self: self.args[0]) + + def _latex(self, printer): + return r"SetExpr\left({}\right)".format(printer._print(self.set)) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__radd__') + def __add__(self, other): + return _setexpr_apply_operation(set_add, self, other) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__add__') + def __radd__(self, other): + return _setexpr_apply_operation(set_add, other, self) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__rmul__') + def __mul__(self, other): + return _setexpr_apply_operation(set_mul, self, other) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__mul__') + def __rmul__(self, other): + return _setexpr_apply_operation(set_mul, other, self) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__rsub__') + def __sub__(self, other): + return _setexpr_apply_operation(set_sub, self, other) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__sub__') + def __rsub__(self, other): + return _setexpr_apply_operation(set_sub, other, self) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__rpow__') + def __pow__(self, other): + return _setexpr_apply_operation(set_pow, self, other) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__pow__') + def __rpow__(self, other): + return _setexpr_apply_operation(set_pow, other, self) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__rtruediv__') + def __truediv__(self, other): + return _setexpr_apply_operation(set_div, self, other) + + @_sympifyit('other', NotImplemented) + @call_highest_priority('__truediv__') + def __rtruediv__(self, other): + return _setexpr_apply_operation(set_div, other, self) + + def _eval_func(self, func): + # TODO: this could be implemented straight into `imageset`: + res = set_function(func, self.set) + if res is None: + return SetExpr(ImageSet(func, self.set)) + return SetExpr(res) + + +def _setexpr_apply_operation(op, x, y): + if isinstance(x, SetExpr): + x = x.set + if isinstance(y, SetExpr): + y = y.set + out = op(x, y) + return SetExpr(out) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/sets.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/sets.py new file mode 100644 index 0000000000000000000000000000000000000000..3c85ce87c515cfd4520dcc6b9265fe76d8c6163f --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/sets.py @@ -0,0 +1,2804 @@ +from __future__ import annotations + +from typing import Any, Callable, TYPE_CHECKING, overload +from functools import reduce +from collections import defaultdict +from collections.abc import Mapping, Iterable +import inspect + +from sympy.core.kind import Kind, UndefinedKind, NumberKind +from sympy.core.basic import Basic +from sympy.core.containers import Tuple, TupleKind +from sympy.core.decorators import sympify_method_args, sympify_return +from sympy.core.evalf import EvalfMixin +from sympy.core.expr import Expr +from sympy.core.function import Lambda +from sympy.core.logic import (FuzzyBool, fuzzy_bool, fuzzy_or, fuzzy_and, + fuzzy_not) +from sympy.core.numbers import Float, Integer +from sympy.core.operations import LatticeOp +from sympy.core.parameters import global_parameters +from sympy.core.relational import Eq, Ne, is_lt +from sympy.core.singleton import Singleton, S +from sympy.core.sorting import ordered +from sympy.core.symbol import symbols, Symbol, Dummy, uniquely_named_symbol +from sympy.core.sympify import _sympify, sympify, _sympy_converter +from sympy.functions.elementary.exponential import exp, log +from sympy.functions.elementary.miscellaneous import Max, Min +from sympy.logic.boolalg import And, Or, Not, Xor, true, false +from sympy.utilities.decorator import deprecated +from sympy.utilities.exceptions import sympy_deprecation_warning +from sympy.utilities.iterables import (iproduct, sift, roundrobin, iterable, + subsets) +from sympy.utilities.misc import func_name, filldedent + +from mpmath import mpi, mpf + +from mpmath.libmp.libmpf import prec_to_dps + + +tfn = defaultdict(lambda: None, { + True: S.true, + S.true: S.true, + False: S.false, + S.false: S.false}) + + +@sympify_method_args +class Set(Basic, EvalfMixin): + """ + The base class for any kind of set. + + Explanation + =========== + + This is not meant to be used directly as a container of items. It does not + behave like the builtin ``set``; see :class:`FiniteSet` for that. + + Real intervals are represented by the :class:`Interval` class and unions of + sets by the :class:`Union` class. The empty set is represented by the + :class:`EmptySet` class and available as a singleton as ``S.EmptySet``. + """ + + __slots__: tuple[()] = () + + is_number = False + is_iterable = False + is_interval = False + + is_FiniteSet = False + is_Interval = False + is_ProductSet = False + is_Union = False + is_Intersection: FuzzyBool = None + is_UniversalSet: FuzzyBool = None + is_Complement: FuzzyBool = None + is_ComplexRegion = False + + is_empty: FuzzyBool = None + is_finite_set: FuzzyBool = None + + @property # type: ignore + @deprecated( + """ + The is_EmptySet attribute of Set objects is deprecated. + Use 's is S.EmptySet" or 's.is_empty' instead. + """, + deprecated_since_version="1.5", + active_deprecations_target="deprecated-is-emptyset", + ) + def is_EmptySet(self): + return None + + if TYPE_CHECKING: + + def __new__(cls, *args: Basic | complex) -> Set: + ... + + @overload # type: ignore + def subs(self, arg1: Mapping[Basic | complex, Set | complex], arg2: None=None) -> Set: ... + @overload + def subs(self, arg1: Iterable[tuple[Basic | complex, Set | complex]], arg2: None=None, **kwargs: Any) -> Set: ... + @overload + def subs(self, arg1: Set | complex, arg2: Set | complex) -> Set: ... + @overload + def subs(self, arg1: Mapping[Basic | complex, Basic | complex], arg2: None=None, **kwargs: Any) -> Basic: ... + @overload + def subs(self, arg1: Iterable[tuple[Basic | complex, Basic | complex]], arg2: None=None, **kwargs: Any) -> Basic: ... + @overload + def subs(self, arg1: Basic | complex, arg2: Basic | complex, **kwargs: Any) -> Basic: ... + + def subs(self, arg1: Mapping[Basic | complex, Basic | complex] | Basic | complex, # type: ignore + arg2: Basic | complex | None = None, **kwargs: Any) -> Basic: + ... + + def simplify(self, **kwargs) -> Set: + assert False + + def evalf(self, n: int = 15, subs: dict[Basic, Basic | float] | None = None, + maxn: int = 100, chop: bool = False, strict: bool = False, + quad: str | None = None, verbose: bool = False) -> Set: + ... + + n = evalf + + @staticmethod + def _infimum_key(expr): + """ + Return infimum (if possible) else S.Infinity. + """ + try: + infimum = expr.inf + assert infimum.is_comparable + infimum = infimum.evalf() # issue #18505 + except (NotImplementedError, + AttributeError, AssertionError, ValueError): + infimum = S.Infinity + return infimum + + def union(self, other): + """ + Returns the union of ``self`` and ``other``. + + Examples + ======== + + As a shortcut it is possible to use the ``+`` operator: + + >>> from sympy import Interval, FiniteSet + >>> Interval(0, 1).union(Interval(2, 3)) + Union(Interval(0, 1), Interval(2, 3)) + >>> Interval(0, 1) + Interval(2, 3) + Union(Interval(0, 1), Interval(2, 3)) + >>> Interval(1, 2, True, True) + FiniteSet(2, 3) + Union({3}, Interval.Lopen(1, 2)) + + Similarly it is possible to use the ``-`` operator for set differences: + + >>> Interval(0, 2) - Interval(0, 1) + Interval.Lopen(1, 2) + >>> Interval(1, 3) - FiniteSet(2) + Union(Interval.Ropen(1, 2), Interval.Lopen(2, 3)) + + """ + return Union(self, other) + + def intersect(self, other): + """ + Returns the intersection of 'self' and 'other'. + + Examples + ======== + + >>> from sympy import Interval + + >>> Interval(1, 3).intersect(Interval(1, 2)) + Interval(1, 2) + + >>> from sympy import imageset, Lambda, symbols, S + >>> n, m = symbols('n m') + >>> a = imageset(Lambda(n, 2*n), S.Integers) + >>> a.intersect(imageset(Lambda(m, 2*m + 1), S.Integers)) + EmptySet + + """ + return Intersection(self, other) + + def intersection(self, other): + """ + Alias for :meth:`intersect()` + """ + return self.intersect(other) + + def is_disjoint(self, other): + """ + Returns True if ``self`` and ``other`` are disjoint. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 2).is_disjoint(Interval(1, 2)) + False + >>> Interval(0, 2).is_disjoint(Interval(3, 4)) + True + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Disjoint_sets + """ + return self.intersect(other) == S.EmptySet + + def isdisjoint(self, other): + """ + Alias for :meth:`is_disjoint()` + """ + return self.is_disjoint(other) + + def complement(self, universe): + r""" + The complement of 'self' w.r.t the given universe. + + Examples + ======== + + >>> from sympy import Interval, S + >>> Interval(0, 1).complement(S.Reals) + Union(Interval.open(-oo, 0), Interval.open(1, oo)) + + >>> Interval(0, 1).complement(S.UniversalSet) + Complement(UniversalSet, Interval(0, 1)) + + """ + return Complement(universe, self) + + def _complement(self, other): + # this behaves as other - self + if isinstance(self, ProductSet) and isinstance(other, ProductSet): + # If self and other are disjoint then other - self == self + if len(self.sets) != len(other.sets): + return other + + # There can be other ways to represent this but this gives: + # (A x B) - (C x D) = ((A - C) x B) U (A x (B - D)) + overlaps = [] + pairs = list(zip(self.sets, other.sets)) + for n in range(len(pairs)): + sets = (o if i != n else o-s for i, (s, o) in enumerate(pairs)) + overlaps.append(ProductSet(*sets)) + return Union(*overlaps) + + elif isinstance(other, Interval): + if isinstance(self, (Interval, FiniteSet)): + return Intersection(other, self.complement(S.Reals)) + + elif isinstance(other, Union): + return Union(*(o - self for o in other.args)) + + elif isinstance(other, Complement): + return Complement(other.args[0], Union(other.args[1], self), evaluate=False) + + elif other is S.EmptySet: + return S.EmptySet + + elif isinstance(other, FiniteSet): + sifted = sift(other, lambda x: fuzzy_bool(self.contains(x))) + # ignore those that are contained in self + return Union(FiniteSet(*(sifted[False])), + Complement(FiniteSet(*(sifted[None])), self, evaluate=False) + if sifted[None] else S.EmptySet) + + def symmetric_difference(self, other): + """ + Returns symmetric difference of ``self`` and ``other``. + + Examples + ======== + + >>> from sympy import Interval, S + >>> Interval(1, 3).symmetric_difference(S.Reals) + Union(Interval.open(-oo, 1), Interval.open(3, oo)) + >>> Interval(1, 10).symmetric_difference(S.Reals) + Union(Interval.open(-oo, 1), Interval.open(10, oo)) + + >>> from sympy import S, EmptySet + >>> S.Reals.symmetric_difference(EmptySet) + Reals + + References + ========== + .. [1] https://en.wikipedia.org/wiki/Symmetric_difference + + """ + return SymmetricDifference(self, other) + + def _symmetric_difference(self, other): + return Union(Complement(self, other), Complement(other, self)) + + @property + def inf(self): + """ + The infimum of ``self``. + + Examples + ======== + + >>> from sympy import Interval, Union + >>> Interval(0, 1).inf + 0 + >>> Union(Interval(0, 1), Interval(2, 3)).inf + 0 + + """ + return self._inf + + @property + def _inf(self): + raise NotImplementedError("(%s)._inf" % self) + + @property + def sup(self): + """ + The supremum of ``self``. + + Examples + ======== + + >>> from sympy import Interval, Union + >>> Interval(0, 1).sup + 1 + >>> Union(Interval(0, 1), Interval(2, 3)).sup + 3 + + """ + return self._sup + + @property + def _sup(self): + raise NotImplementedError("(%s)._sup" % self) + + def contains(self, other): + """ + Returns a SymPy value indicating whether ``other`` is contained + in ``self``: ``true`` if it is, ``false`` if it is not, else + an unevaluated ``Contains`` expression (or, as in the case of + ConditionSet and a union of FiniteSet/Intervals, an expression + indicating the conditions for containment). + + Examples + ======== + + >>> from sympy import Interval, S + >>> from sympy.abc import x + + >>> Interval(0, 1).contains(0.5) + True + + As a shortcut it is possible to use the ``in`` operator, but that + will raise an error unless an affirmative true or false is not + obtained. + + >>> Interval(0, 1).contains(x) + (0 <= x) & (x <= 1) + >>> x in Interval(0, 1) + Traceback (most recent call last): + ... + TypeError: did not evaluate to a bool: None + + The result of 'in' is a bool, not a SymPy value + + >>> 1 in Interval(0, 2) + True + >>> _ is S.true + False + """ + from .contains import Contains + other = sympify(other, strict=True) + + c = self._contains(other) + if isinstance(c, Contains): + return c + if c is None: + return Contains(other, self, evaluate=False) + b = tfn[c] + if b is None: + return c + return b + + def _contains(self, other): + """Test if ``other`` is an element of the set ``self``. + + This is an internal method that is expected to be overridden by + subclasses of ``Set`` and will be called by the public + :func:`Set.contains` method or the :class:`Contains` expression. + + Parameters + ========== + + other: Sympified :class:`Basic` instance + The object whose membership in ``self`` is to be tested. + + Returns + ======= + + Symbolic :class:`Boolean` or ``None``. + + A return value of ``None`` indicates that it is unknown whether + ``other`` is contained in ``self``. Returning ``None`` from here + ensures that ``self.contains(other)`` or ``Contains(self, other)`` will + return an unevaluated :class:`Contains` expression. + + If not ``None`` then the returned value is a :class:`Boolean` that is + logically equivalent to the statement that ``other`` is an element of + ``self``. Usually this would be either ``S.true`` or ``S.false`` but + not always. + """ + raise NotImplementedError(f"{type(self).__name__}._contains") + + def is_subset(self, other): + """ + Returns True if ``self`` is a subset of ``other``. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 0.5).is_subset(Interval(0, 1)) + True + >>> Interval(0, 1).is_subset(Interval(0, 1, left_open=True)) + False + + """ + if not isinstance(other, Set): + raise ValueError("Unknown argument '%s'" % other) + + # Handle the trivial cases + if self == other: + return True + is_empty = self.is_empty + if is_empty is True: + return True + elif fuzzy_not(is_empty) and other.is_empty: + return False + if self.is_finite_set is False and other.is_finite_set: + return False + + # Dispatch on subclass rules + ret = self._eval_is_subset(other) + if ret is not None: + return ret + ret = other._eval_is_superset(self) + if ret is not None: + return ret + + # Use pairwise rules from multiple dispatch + from sympy.sets.handlers.issubset import is_subset_sets + ret = is_subset_sets(self, other) + if ret is not None: + return ret + + # Fall back on computing the intersection + # XXX: We shouldn't do this. A query like this should be handled + # without evaluating new Set objects. It should be the other way round + # so that the intersect method uses is_subset for evaluation. + if self.intersect(other) == self: + return True + + def _eval_is_subset(self, other): + '''Returns a fuzzy bool for whether self is a subset of other.''' + return None + + def _eval_is_superset(self, other): + '''Returns a fuzzy bool for whether self is a subset of other.''' + return None + + # This should be deprecated: + def issubset(self, other): + """ + Alias for :meth:`is_subset()` + """ + return self.is_subset(other) + + def is_proper_subset(self, other): + """ + Returns True if ``self`` is a proper subset of ``other``. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 0.5).is_proper_subset(Interval(0, 1)) + True + >>> Interval(0, 1).is_proper_subset(Interval(0, 1)) + False + + """ + if isinstance(other, Set): + return self != other and self.is_subset(other) + else: + raise ValueError("Unknown argument '%s'" % other) + + def is_superset(self, other): + """ + Returns True if ``self`` is a superset of ``other``. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 0.5).is_superset(Interval(0, 1)) + False + >>> Interval(0, 1).is_superset(Interval(0, 1, left_open=True)) + True + + """ + if isinstance(other, Set): + return other.is_subset(self) + else: + raise ValueError("Unknown argument '%s'" % other) + + # This should be deprecated: + def issuperset(self, other): + """ + Alias for :meth:`is_superset()` + """ + return self.is_superset(other) + + def is_proper_superset(self, other): + """ + Returns True if ``self`` is a proper superset of ``other``. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 1).is_proper_superset(Interval(0, 0.5)) + True + >>> Interval(0, 1).is_proper_superset(Interval(0, 1)) + False + + """ + if isinstance(other, Set): + return self != other and self.is_superset(other) + else: + raise ValueError("Unknown argument '%s'" % other) + + def _eval_powerset(self): + from .powerset import PowerSet + return PowerSet(self) + + def powerset(self): + """ + Find the Power set of ``self``. + + Examples + ======== + + >>> from sympy import EmptySet, FiniteSet, Interval + + A power set of an empty set: + + >>> A = EmptySet + >>> A.powerset() + {EmptySet} + + A power set of a finite set: + + >>> A = FiniteSet(1, 2) + >>> a, b, c = FiniteSet(1), FiniteSet(2), FiniteSet(1, 2) + >>> A.powerset() == FiniteSet(a, b, c, EmptySet) + True + + A power set of an interval: + + >>> Interval(1, 2).powerset() + PowerSet(Interval(1, 2)) + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Power_set + + """ + return self._eval_powerset() + + @property + def measure(self): + """ + The (Lebesgue) measure of ``self``. + + Examples + ======== + + >>> from sympy import Interval, Union + >>> Interval(0, 1).measure + 1 + >>> Union(Interval(0, 1), Interval(2, 3)).measure + 2 + + """ + return self._measure + + @property + def kind(self): + """ + The kind of a Set + + Explanation + =========== + + Any :class:`Set` will have kind :class:`SetKind` which is + parametrised by the kind of the elements of the set. For example + most sets are sets of numbers and will have kind + ``SetKind(NumberKind)``. If elements of sets are different in kind than + their kind will ``SetKind(UndefinedKind)``. See + :class:`sympy.core.kind.Kind` for an explanation of the kind system. + + Examples + ======== + + >>> from sympy import Interval, Matrix, FiniteSet, EmptySet, ProductSet, PowerSet + + >>> FiniteSet(Matrix([1, 2])).kind + SetKind(MatrixKind(NumberKind)) + + >>> Interval(1, 2).kind + SetKind(NumberKind) + + >>> EmptySet.kind + SetKind() + + A :class:`sympy.sets.powerset.PowerSet` is a set of sets: + + >>> PowerSet({1, 2, 3}).kind + SetKind(SetKind(NumberKind)) + + A :class:`ProductSet` represents the set of tuples of elements of + other sets. Its kind is :class:`sympy.core.containers.TupleKind` + parametrised by the kinds of the elements of those sets: + + >>> p = ProductSet(FiniteSet(1, 2), FiniteSet(3, 4)) + >>> list(p) + [(1, 3), (2, 3), (1, 4), (2, 4)] + >>> p.kind + SetKind(TupleKind(NumberKind, NumberKind)) + + When all elements of the set do not have same kind, the kind + will be returned as ``SetKind(UndefinedKind)``: + + >>> FiniteSet(0, Matrix([1, 2])).kind + SetKind(UndefinedKind) + + The kind of the elements of a set are given by the ``element_kind`` + attribute of ``SetKind``: + + >>> Interval(1, 2).kind.element_kind + NumberKind + + See Also + ======== + + NumberKind + sympy.core.kind.UndefinedKind + sympy.core.containers.TupleKind + MatrixKind + sympy.matrices.expressions.sets.MatrixSet + sympy.sets.conditionset.ConditionSet + Rationals + Naturals + Integers + sympy.sets.fancysets.ImageSet + sympy.sets.fancysets.Range + sympy.sets.fancysets.ComplexRegion + sympy.sets.powerset.PowerSet + sympy.sets.sets.ProductSet + sympy.sets.sets.Interval + sympy.sets.sets.Union + sympy.sets.sets.Intersection + sympy.sets.sets.Complement + sympy.sets.sets.EmptySet + sympy.sets.sets.UniversalSet + sympy.sets.sets.FiniteSet + sympy.sets.sets.SymmetricDifference + sympy.sets.sets.DisjointUnion + """ + return self._kind() + + @property + def boundary(self): + """ + The boundary or frontier of a set. + + Explanation + =========== + + A point x is on the boundary of a set S if + + 1. x is in the closure of S. + I.e. Every neighborhood of x contains a point in S. + 2. x is not in the interior of S. + I.e. There does not exist an open set centered on x contained + entirely within S. + + There are the points on the outer rim of S. If S is open then these + points need not actually be contained within S. + + For example, the boundary of an interval is its start and end points. + This is true regardless of whether or not the interval is open. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 1).boundary + {0, 1} + >>> Interval(0, 1, True, False).boundary + {0, 1} + """ + return self._boundary + + @property + def is_open(self): + """ + Property method to check whether a set is open. + + Explanation + =========== + + A set is open if and only if it has an empty intersection with its + boundary. In particular, a subset A of the reals is open if and only + if each one of its points is contained in an open interval that is a + subset of A. + + Examples + ======== + >>> from sympy import S + >>> S.Reals.is_open + True + >>> S.Rationals.is_open + False + """ + return Intersection(self, self.boundary).is_empty + + @property + def is_closed(self): + """ + A property method to check whether a set is closed. + + Explanation + =========== + + A set is closed if its complement is an open set. The closedness of a + subset of the reals is determined with respect to R and its standard + topology. + + Examples + ======== + >>> from sympy import Interval + >>> Interval(0, 1).is_closed + True + """ + return self.boundary.is_subset(self) + + @property + def closure(self): + """ + Property method which returns the closure of a set. + The closure is defined as the union of the set itself and its + boundary. + + Examples + ======== + >>> from sympy import S, Interval + >>> S.Reals.closure + Reals + >>> Interval(0, 1).closure + Interval(0, 1) + """ + return self + self.boundary + + @property + def interior(self): + """ + Property method which returns the interior of a set. + The interior of a set S consists all points of S that do not + belong to the boundary of S. + + Examples + ======== + >>> from sympy import Interval + >>> Interval(0, 1).interior + Interval.open(0, 1) + >>> Interval(0, 1).boundary.interior + EmptySet + """ + return self - self.boundary + + @property + def _boundary(self): + raise NotImplementedError() + + @property + def _measure(self): + raise NotImplementedError("(%s)._measure" % self) + + def _kind(self): + return SetKind(UndefinedKind) + + def _eval_evalf(self, prec): + dps = prec_to_dps(prec) + return self.func(*[arg.evalf(n=dps) for arg in self.args]) + + @sympify_return([('other', 'Set')], NotImplemented) + def __add__(self, other): + return self.union(other) + + @sympify_return([('other', 'Set')], NotImplemented) + def __or__(self, other): + return self.union(other) + + @sympify_return([('other', 'Set')], NotImplemented) + def __and__(self, other): + return self.intersect(other) + + @sympify_return([('other', 'Set')], NotImplemented) + def __mul__(self, other): + return ProductSet(self, other) + + @sympify_return([('other', 'Set')], NotImplemented) + def __xor__(self, other): + return SymmetricDifference(self, other) + + @sympify_return([('exp', Expr)], NotImplemented) + def __pow__(self, exp): + if not (exp.is_Integer and exp >= 0): + raise ValueError("%s: Exponent must be a positive Integer" % exp) + return ProductSet(*[self]*exp) + + @sympify_return([('other', 'Set')], NotImplemented) + def __sub__(self, other): + return Complement(self, other) + + def __contains__(self, other): + other = _sympify(other) + c = self._contains(other) + b = tfn[c] + if b is None: + # x in y must evaluate to T or F; to entertain a None + # result with Set use y.contains(x) + raise TypeError('did not evaluate to a bool: %r' % c) + return b + + +class ProductSet(Set): + """ + Represents a Cartesian Product of Sets. + + Explanation + =========== + + Returns a Cartesian product given several sets as either an iterable + or individual arguments. + + Can use ``*`` operator on any sets for convenient shorthand. + + Examples + ======== + + >>> from sympy import Interval, FiniteSet, ProductSet + >>> I = Interval(0, 5); S = FiniteSet(1, 2, 3) + >>> ProductSet(I, S) + ProductSet(Interval(0, 5), {1, 2, 3}) + + >>> (2, 2) in ProductSet(I, S) + True + + >>> Interval(0, 1) * Interval(0, 1) # The unit square + ProductSet(Interval(0, 1), Interval(0, 1)) + + >>> coin = FiniteSet('H', 'T') + >>> set(coin**2) + {(H, H), (H, T), (T, H), (T, T)} + + The Cartesian product is not commutative or associative e.g.: + + >>> I*S == S*I + False + >>> (I*I)*I == I*(I*I) + False + + Notes + ===== + + - Passes most operations down to the argument sets + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Cartesian_product + """ + is_ProductSet = True + + def __new__(cls, *sets, **assumptions): + if len(sets) == 1 and iterable(sets[0]) and not isinstance(sets[0], (Set, set)): + sympy_deprecation_warning( + """ +ProductSet(iterable) is deprecated. Use ProductSet(*iterable) instead. + """, + deprecated_since_version="1.5", + active_deprecations_target="deprecated-productset-iterable", + ) + sets = tuple(sets[0]) + + sets = [sympify(s) for s in sets] + + if not all(isinstance(s, Set) for s in sets): + raise TypeError("Arguments to ProductSet should be of type Set") + + # Nullary product of sets is *not* the empty set + if len(sets) == 0: + return FiniteSet(()) + + if S.EmptySet in sets: + return S.EmptySet + + return Basic.__new__(cls, *sets, **assumptions) + + @property + def sets(self): + return self.args + + def flatten(self): + def _flatten(sets): + for s in sets: + if s.is_ProductSet: + yield from _flatten(s.sets) + else: + yield s + return ProductSet(*_flatten(self.sets)) + + + + def _contains(self, element): + """ + ``in`` operator for ProductSets. + + Examples + ======== + + >>> from sympy import Interval + >>> (2, 3) in Interval(0, 5) * Interval(0, 5) + True + + >>> (10, 10) in Interval(0, 5) * Interval(0, 5) + False + + Passes operation on to constituent sets + """ + if element.is_Symbol: + return None + + if not isinstance(element, Tuple) or len(element) != len(self.sets): + return S.false + + return And(*[s.contains(e) for s, e in zip(self.sets, element)]) + + def as_relational(self, *symbols): + symbols = [_sympify(s) for s in symbols] + if len(symbols) != len(self.sets) or not all( + i.is_Symbol for i in symbols): + raise ValueError( + 'number of symbols must match the number of sets') + return And(*[s.as_relational(i) for s, i in zip(self.sets, symbols)]) + + @property + def _boundary(self): + return Union(*(ProductSet(*(b + b.boundary if i != j else b.boundary + for j, b in enumerate(self.sets))) + for i, a in enumerate(self.sets))) + + @property + def is_iterable(self): + """ + A property method which tests whether a set is iterable or not. + Returns True if set is iterable, otherwise returns False. + + Examples + ======== + + >>> from sympy import FiniteSet, Interval + >>> I = Interval(0, 1) + >>> A = FiniteSet(1, 2, 3, 4, 5) + >>> I.is_iterable + False + >>> A.is_iterable + True + + """ + return all(set.is_iterable for set in self.sets) + + def __iter__(self): + """ + A method which implements is_iterable property method. + If self.is_iterable returns True (both constituent sets are iterable), + then return the Cartesian Product. Otherwise, raise TypeError. + """ + return iproduct(*self.sets) + + @property + def is_empty(self): + return fuzzy_or(s.is_empty for s in self.sets) + + @property + def is_finite_set(self): + all_finite = fuzzy_and(s.is_finite_set for s in self.sets) + return fuzzy_or([self.is_empty, all_finite]) + + @property + def _measure(self): + measure = 1 + for s in self.sets: + measure *= s.measure + return measure + + def _kind(self): + return SetKind(TupleKind(*(i.kind.element_kind for i in self.args))) + + def __len__(self): + return reduce(lambda a, b: a*b, (len(s) for s in self.args)) + + def __bool__(self): + return all(self.sets) + + +class Interval(Set): + """ + Represents a real interval as a Set. + + Usage: + Returns an interval with end points ``start`` and ``end``. + + For ``left_open=True`` (default ``left_open`` is ``False``) the interval + will be open on the left. Similarly, for ``right_open=True`` the interval + will be open on the right. + + Examples + ======== + + >>> from sympy import Symbol, Interval + >>> Interval(0, 1) + Interval(0, 1) + >>> Interval.Ropen(0, 1) + Interval.Ropen(0, 1) + >>> Interval.Ropen(0, 1) + Interval.Ropen(0, 1) + >>> Interval.Lopen(0, 1) + Interval.Lopen(0, 1) + >>> Interval.open(0, 1) + Interval.open(0, 1) + + >>> a = Symbol('a', real=True) + >>> Interval(0, a) + Interval(0, a) + + Notes + ===== + - Only real end points are supported + - ``Interval(a, b)`` with $a > b$ will return the empty set + - Use the ``evalf()`` method to turn an Interval into an mpmath + ``mpi`` interval instance + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Interval_%28mathematics%29 + """ + is_Interval = True + + def __new__(cls, start, end, left_open=False, right_open=False): + + start = _sympify(start) + end = _sympify(end) + left_open = _sympify(left_open) + right_open = _sympify(right_open) + + if not all(isinstance(a, (type(true), type(false))) + for a in [left_open, right_open]): + raise NotImplementedError( + "left_open and right_open can have only true/false values, " + "got %s and %s" % (left_open, right_open)) + + # Only allow real intervals + if fuzzy_not(fuzzy_and(i.is_extended_real for i in (start, end, end-start))): + raise ValueError("Non-real intervals are not supported") + + # evaluate if possible + if is_lt(end, start): + return S.EmptySet + elif (end - start).is_negative: + return S.EmptySet + + if end == start and (left_open or right_open): + return S.EmptySet + if end == start and not (left_open or right_open): + if start is S.Infinity or start is S.NegativeInfinity: + return S.EmptySet + return FiniteSet(end) + + # Make sure infinite interval end points are open. + if start is S.NegativeInfinity: + left_open = true + if end is S.Infinity: + right_open = true + if start == S.Infinity or end == S.NegativeInfinity: + return S.EmptySet + + return Basic.__new__(cls, start, end, left_open, right_open) + + @property + def start(self): + """ + The left end point of the interval. + + This property takes the same value as the ``inf`` property. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 1).start + 0 + + """ + return self._args[0] + + @property + def end(self): + """ + The right end point of the interval. + + This property takes the same value as the ``sup`` property. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 1).end + 1 + + """ + return self._args[1] + + @property + def left_open(self): + """ + True if interval is left-open. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 1, left_open=True).left_open + True + >>> Interval(0, 1, left_open=False).left_open + False + + """ + return self._args[2] + + @property + def right_open(self): + """ + True if interval is right-open. + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(0, 1, right_open=True).right_open + True + >>> Interval(0, 1, right_open=False).right_open + False + + """ + return self._args[3] + + @classmethod + def open(cls, a, b): + """Return an interval including neither boundary.""" + return cls(a, b, True, True) + + @classmethod + def Lopen(cls, a, b): + """Return an interval not including the left boundary.""" + return cls(a, b, True, False) + + @classmethod + def Ropen(cls, a, b): + """Return an interval not including the right boundary.""" + return cls(a, b, False, True) + + @property + def _inf(self): + return self.start + + @property + def _sup(self): + return self.end + + @property + def left(self): + return self.start + + @property + def right(self): + return self.end + + @property + def is_empty(self): + if self.left_open or self.right_open: + cond = self.start >= self.end # One/both bounds open + else: + cond = self.start > self.end # Both bounds closed + return fuzzy_bool(cond) + + @property + def is_finite_set(self): + return self.measure.is_zero + + def _complement(self, other): + if other == S.Reals: + a = Interval(S.NegativeInfinity, self.start, + True, not self.left_open) + b = Interval(self.end, S.Infinity, not self.right_open, True) + return Union(a, b) + + if isinstance(other, FiniteSet): + nums = [m for m in other.args if m.is_number] + if nums == []: + return None + + return Set._complement(self, other) + + @property + def _boundary(self): + finite_points = [p for p in (self.start, self.end) + if abs(p) != S.Infinity] + return FiniteSet(*finite_points) + + def _contains(self, other): + if (not isinstance(other, Expr) or other is S.NaN + or other.is_real is False or other.has(S.ComplexInfinity)): + # if an expression has zoo it will be zoo or nan + # and neither of those is real + return false + + if self.start is S.NegativeInfinity and self.end is S.Infinity: + if other.is_real is not None: + return tfn[other.is_real] + + d = Dummy() + return self.as_relational(d).subs(d, other) + + def as_relational(self, x): + """Rewrite an interval in terms of inequalities and logic operators.""" + x = sympify(x) + if self.right_open: + right = x < self.end + else: + right = x <= self.end + if self.left_open: + left = self.start < x + else: + left = self.start <= x + return And(left, right) + + @property + def _measure(self): + return self.end - self.start + + def _kind(self): + return SetKind(NumberKind) + + def to_mpi(self, prec=53): + return mpi(mpf(self.start._eval_evalf(prec)), + mpf(self.end._eval_evalf(prec))) + + def _eval_evalf(self, prec): + return Interval(self.left._evalf(prec), self.right._evalf(prec), + left_open=self.left_open, right_open=self.right_open) + + def _is_comparable(self, other): + is_comparable = self.start.is_comparable + is_comparable &= self.end.is_comparable + is_comparable &= other.start.is_comparable + is_comparable &= other.end.is_comparable + + return is_comparable + + @property + def is_left_unbounded(self): + """Return ``True`` if the left endpoint is negative infinity. """ + return self.left is S.NegativeInfinity or self.left == Float("-inf") + + @property + def is_right_unbounded(self): + """Return ``True`` if the right endpoint is positive infinity. """ + return self.right is S.Infinity or self.right == Float("+inf") + + def _eval_Eq(self, other): + if not isinstance(other, Interval): + if isinstance(other, FiniteSet): + return false + elif isinstance(other, Set): + return None + return false + + +class Union(Set, LatticeOp): + """ + Represents a union of sets as a :class:`Set`. + + Examples + ======== + + >>> from sympy import Union, Interval + >>> Union(Interval(1, 2), Interval(3, 4)) + Union(Interval(1, 2), Interval(3, 4)) + + The Union constructor will always try to merge overlapping intervals, + if possible. For example: + + >>> Union(Interval(1, 2), Interval(2, 3)) + Interval(1, 3) + + See Also + ======== + + Intersection + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Union_%28set_theory%29 + """ + is_Union = True + + @property + def identity(self): + return S.EmptySet + + @property + def zero(self): + return S.UniversalSet + + def __new__(cls, *args, **kwargs): + evaluate = kwargs.get('evaluate', global_parameters.evaluate) + + # flatten inputs to merge intersections and iterables + args = _sympify(args) + + # Reduce sets using known rules + if evaluate: + args = list(cls._new_args_filter(args)) + return simplify_union(args) + + args = list(ordered(args, Set._infimum_key)) + + obj = Basic.__new__(cls, *args) + obj._argset = frozenset(args) + return obj + + @property + def args(self): + return self._args + + def _complement(self, universe): + # DeMorgan's Law + return Intersection(s.complement(universe) for s in self.args) + + @property + def _inf(self): + # We use Min so that sup is meaningful in combination with symbolic + # interval end points. + return Min(*[set.inf for set in self.args]) + + @property + def _sup(self): + # We use Max so that sup is meaningful in combination with symbolic + # end points. + return Max(*[set.sup for set in self.args]) + + @property + def is_empty(self): + return fuzzy_and(set.is_empty for set in self.args) + + @property + def is_finite_set(self): + return fuzzy_and(set.is_finite_set for set in self.args) + + @property + def _measure(self): + # Measure of a union is the sum of the measures of the sets minus + # the sum of their pairwise intersections plus the sum of their + # triple-wise intersections minus ... etc... + + # Sets is a collection of intersections and a set of elementary + # sets which made up those intersections (called "sos" for set of sets) + # An example element might of this list might be: + # ( {A,B,C}, A.intersect(B).intersect(C) ) + + # Start with just elementary sets ( ({A}, A), ({B}, B), ... ) + # Then get and subtract ( ({A,B}, (A int B), ... ) while non-zero + sets = [(FiniteSet(s), s) for s in self.args] + measure = 0 + parity = 1 + while sets: + # Add up the measure of these sets and add or subtract it to total + measure += parity * sum(inter.measure for sos, inter in sets) + + # For each intersection in sets, compute the intersection with every + # other set not already part of the intersection. + sets = ((sos + FiniteSet(newset), newset.intersect(intersection)) + for sos, intersection in sets for newset in self.args + if newset not in sos) + + # Clear out sets with no measure + sets = [(sos, inter) for sos, inter in sets if inter.measure != 0] + + # Clear out duplicates + sos_list = [] + sets_list = [] + for _set in sets: + if _set[0] in sos_list: + continue + else: + sos_list.append(_set[0]) + sets_list.append(_set) + sets = sets_list + + # Flip Parity - next time subtract/add if we added/subtracted here + parity *= -1 + return measure + + def _kind(self): + kinds = tuple(arg.kind for arg in self.args if arg is not S.EmptySet) + if not kinds: + return SetKind() + elif all(i == kinds[0] for i in kinds): + return kinds[0] + else: + return SetKind(UndefinedKind) + + @property + def _boundary(self): + def boundary_of_set(i): + """ The boundary of set i minus interior of all other sets """ + b = self.args[i].boundary + for j, a in enumerate(self.args): + if j != i: + b = b - a.interior + return b + return Union(*map(boundary_of_set, range(len(self.args)))) + + def _contains(self, other): + return Or(*[s.contains(other) for s in self.args]) + + def is_subset(self, other): + return fuzzy_and(s.is_subset(other) for s in self.args) + + def as_relational(self, symbol): + """Rewrite a Union in terms of equalities and logic operators. """ + if (len(self.args) == 2 and + all(isinstance(i, Interval) for i in self.args)): + # optimization to give 3 args as (x > 1) & (x < 5) & Ne(x, 3) + # instead of as 4, ((1 <= x) & (x < 3)) | ((x <= 5) & (3 < x)) + # XXX: This should be ideally be improved to handle any number of + # intervals and also not to assume that the intervals are in any + # particular sorted order. + a, b = self.args + if a.sup == b.inf and a.right_open and b.left_open: + mincond = symbol > a.inf if a.left_open else symbol >= a.inf + maxcond = symbol < b.sup if b.right_open else symbol <= b.sup + necond = Ne(symbol, a.sup) + return And(necond, mincond, maxcond) + return Or(*[i.as_relational(symbol) for i in self.args]) + + @property + def is_iterable(self): + return all(arg.is_iterable for arg in self.args) + + def __iter__(self): + return roundrobin(*(iter(arg) for arg in self.args)) + + +class Intersection(Set, LatticeOp): + """ + Represents an intersection of sets as a :class:`Set`. + + Examples + ======== + + >>> from sympy import Intersection, Interval + >>> Intersection(Interval(1, 3), Interval(2, 4)) + Interval(2, 3) + + We often use the .intersect method + + >>> Interval(1,3).intersect(Interval(2,4)) + Interval(2, 3) + + See Also + ======== + + Union + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Intersection_%28set_theory%29 + """ + is_Intersection = True + + @property + def identity(self): + return S.UniversalSet + + @property + def zero(self): + return S.EmptySet + + def __new__(cls, *args , evaluate=None): + if evaluate is None: + evaluate = global_parameters.evaluate + + # flatten inputs to merge intersections and iterables + args = list(ordered(set(_sympify(args)))) + + # Reduce sets using known rules + if evaluate: + args = list(cls._new_args_filter(args)) + return simplify_intersection(args) + + args = list(ordered(args, Set._infimum_key)) + + obj = Basic.__new__(cls, *args) + obj._argset = frozenset(args) + return obj + + @property + def args(self): + return self._args + + @property + def is_iterable(self): + return any(arg.is_iterable for arg in self.args) + + @property + def is_finite_set(self): + if fuzzy_or(arg.is_finite_set for arg in self.args): + return True + + def _kind(self): + kinds = tuple(arg.kind for arg in self.args if arg is not S.UniversalSet) + if not kinds: + return SetKind(UndefinedKind) + elif all(i == kinds[0] for i in kinds): + return kinds[0] + else: + return SetKind() + + @property + def _inf(self): + raise NotImplementedError() + + @property + def _sup(self): + raise NotImplementedError() + + def _contains(self, other): + return And(*[set.contains(other) for set in self.args]) + + def __iter__(self): + sets_sift = sift(self.args, lambda x: x.is_iterable) + + completed = False + candidates = sets_sift[True] + sets_sift[None] + + finite_candidates, others = [], [] + for candidate in candidates: + length = None + try: + length = len(candidate) + except TypeError: + others.append(candidate) + + if length is not None: + finite_candidates.append(candidate) + finite_candidates.sort(key=len) + + for s in finite_candidates + others: + other_sets = set(self.args) - {s} + other = Intersection(*other_sets, evaluate=False) + completed = True + for x in s: + try: + if x in other: + yield x + except TypeError: + completed = False + if completed: + return + + if not completed: + if not candidates: + raise TypeError("None of the constituent sets are iterable") + raise TypeError( + "The computation had not completed because of the " + "undecidable set membership is found in every candidates.") + + @staticmethod + def _handle_finite_sets(args): + '''Simplify intersection of one or more FiniteSets and other sets''' + + # First separate the FiniteSets from the others + fs_args, others = sift(args, lambda x: x.is_FiniteSet, binary=True) + + # Let the caller handle intersection of non-FiniteSets + if not fs_args: + return + + # Convert to Python sets and build the set of all elements + fs_sets = [set(fs) for fs in fs_args] + all_elements = reduce(lambda a, b: a | b, fs_sets, set()) + + # Extract elements that are definitely in or definitely not in the + # intersection. Here we check contains for all of args. + definite = set() + for e in all_elements: + inall = fuzzy_and(s.contains(e) for s in args) + if inall is True: + definite.add(e) + if inall is not None: + for s in fs_sets: + s.discard(e) + + # At this point all elements in all of fs_sets are possibly in the + # intersection. In some cases this is because they are definitely in + # the intersection of the finite sets but it's not clear if they are + # members of others. We might have {m, n}, {m}, and Reals where we + # don't know if m or n is real. We want to remove n here but it is + # possibly in because it might be equal to m. So what we do now is + # extract the elements that are definitely in the remaining finite + # sets iteratively until we end up with {n}, {}. At that point if we + # get any empty set all remaining elements are discarded. + + fs_elements = reduce(lambda a, b: a | b, fs_sets, set()) + + # Need fuzzy containment testing + fs_symsets = [FiniteSet(*s) for s in fs_sets] + + while fs_elements: + for e in fs_elements: + infs = fuzzy_and(s.contains(e) for s in fs_symsets) + if infs is True: + definite.add(e) + if infs is not None: + for n, s in enumerate(fs_sets): + # Update Python set and FiniteSet + if e in s: + s.remove(e) + fs_symsets[n] = FiniteSet(*s) + fs_elements.remove(e) + break + # If we completed the for loop without removing anything we are + # done so quit the outer while loop + else: + break + + # If any of the sets of remainder elements is empty then we discard + # all of them for the intersection. + if not all(fs_sets): + fs_sets = [set()] + + # Here we fold back the definitely included elements into each fs. + # Since they are definitely included they must have been members of + # each FiniteSet to begin with. We could instead fold these in with a + # Union at the end to get e.g. {3}|({x}&{y}) rather than {3,x}&{3,y}. + if definite: + fs_sets = [fs | definite for fs in fs_sets] + + if fs_sets == [set()]: + return S.EmptySet + + sets = [FiniteSet(*s) for s in fs_sets] + + # Any set in others is redundant if it contains all the elements that + # are in the finite sets so we don't need it in the Intersection + all_elements = reduce(lambda a, b: a | b, fs_sets, set()) + is_redundant = lambda o: all(fuzzy_bool(o.contains(e)) for e in all_elements) + others = [o for o in others if not is_redundant(o)] + + if others: + rest = Intersection(*others) + # XXX: Maybe this shortcut should be at the beginning. For large + # FiniteSets it could much more efficient to process the other + # sets first... + if rest is S.EmptySet: + return S.EmptySet + # Flatten the Intersection + if rest.is_Intersection: + sets.extend(rest.args) + else: + sets.append(rest) + + if len(sets) == 1: + return sets[0] + else: + return Intersection(*sets, evaluate=False) + + def as_relational(self, symbol): + """Rewrite an Intersection in terms of equalities and logic operators""" + return And(*[set.as_relational(symbol) for set in self.args]) + + +class Complement(Set): + r"""Represents the set difference or relative complement of a set with + another set. + + $$A - B = \{x \in A \mid x \notin B\}$$ + + + Examples + ======== + + >>> from sympy import Complement, FiniteSet + >>> Complement(FiniteSet(0, 1, 2), FiniteSet(1)) + {0, 2} + + See Also + ========= + + Intersection, Union + + References + ========== + + .. [1] https://mathworld.wolfram.com/ComplementSet.html + """ + + is_Complement = True + + def __new__(cls, a, b, evaluate=True): + a, b = map(_sympify, (a, b)) + if evaluate: + return Complement.reduce(a, b) + + return Basic.__new__(cls, a, b) + + @staticmethod + def reduce(A, B): + """ + Simplify a :class:`Complement`. + + """ + if B == S.UniversalSet or A.is_subset(B): + return S.EmptySet + + if isinstance(B, Union): + return Intersection(*(s.complement(A) for s in B.args)) + + result = B._complement(A) + if result is not None: + return result + else: + return Complement(A, B, evaluate=False) + + def _contains(self, other): + A = self.args[0] + B = self.args[1] + return And(A.contains(other), Not(B.contains(other))) + + def as_relational(self, symbol): + """Rewrite a complement in terms of equalities and logic + operators""" + A, B = self.args + + A_rel = A.as_relational(symbol) + B_rel = Not(B.as_relational(symbol)) + + return And(A_rel, B_rel) + + def _kind(self): + return self.args[0].kind + + @property + def is_iterable(self): + if self.args[0].is_iterable: + return True + + @property + def is_finite_set(self): + A, B = self.args + a_finite = A.is_finite_set + if a_finite is True: + return True + elif a_finite is False and B.is_finite_set: + return False + + def __iter__(self): + A, B = self.args + for a in A: + if a not in B: + yield a + else: + continue + + +class EmptySet(Set, metaclass=Singleton): + """ + Represents the empty set. The empty set is available as a singleton + as ``S.EmptySet``. + + Examples + ======== + + >>> from sympy import S, Interval + >>> S.EmptySet + EmptySet + + >>> Interval(1, 2).intersect(S.EmptySet) + EmptySet + + See Also + ======== + + UniversalSet + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Empty_set + """ + is_empty = True + is_finite_set = True + is_FiniteSet = True + + @property # type: ignore + @deprecated( + """ + The is_EmptySet attribute of Set objects is deprecated. + Use 's is S.EmptySet" or 's.is_empty' instead. + """, + deprecated_since_version="1.5", + active_deprecations_target="deprecated-is-emptyset", + ) + def is_EmptySet(self): + return True + + @property + def _measure(self): + return 0 + + def _contains(self, other): + return false + + def as_relational(self, symbol): + return false + + def __len__(self): + return 0 + + def __iter__(self): + return iter([]) + + def _eval_powerset(self): + return FiniteSet(self) + + @property + def _boundary(self): + return self + + def _complement(self, other): + return other + + def _kind(self): + return SetKind() + + def _symmetric_difference(self, other): + return other + + +class UniversalSet(Set, metaclass=Singleton): + """ + Represents the set of all things. + The universal set is available as a singleton as ``S.UniversalSet``. + + Examples + ======== + + >>> from sympy import S, Interval + >>> S.UniversalSet + UniversalSet + + >>> Interval(1, 2).intersect(S.UniversalSet) + Interval(1, 2) + + See Also + ======== + + EmptySet + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Universal_set + """ + + is_UniversalSet = True + is_empty = False + is_finite_set = False + + def _complement(self, other): + return S.EmptySet + + def _symmetric_difference(self, other): + return other + + @property + def _measure(self): + return S.Infinity + + def _kind(self): + return SetKind(UndefinedKind) + + def _contains(self, other): + return true + + def as_relational(self, symbol): + return true + + @property + def _boundary(self): + return S.EmptySet + + +class FiniteSet(Set): + """ + Represents a finite set of Sympy expressions. + + Examples + ======== + + >>> from sympy import FiniteSet, Symbol, Interval, Naturals0 + >>> FiniteSet(1, 2, 3, 4) + {1, 2, 3, 4} + >>> 3 in FiniteSet(1, 2, 3, 4) + True + >>> FiniteSet(1, (1, 2), Symbol('x')) + {1, x, (1, 2)} + >>> FiniteSet(Interval(1, 2), Naturals0, {1, 2}) + FiniteSet({1, 2}, Interval(1, 2), Naturals0) + >>> members = [1, 2, 3, 4] + >>> f = FiniteSet(*members) + >>> f + {1, 2, 3, 4} + >>> f - FiniteSet(2) + {1, 3, 4} + >>> f + FiniteSet(2, 5) + {1, 2, 3, 4, 5} + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Finite_set + """ + is_FiniteSet = True + is_iterable = True + is_empty = False + is_finite_set = True + + def __new__(cls, *args, **kwargs): + evaluate = kwargs.get('evaluate', global_parameters.evaluate) + if evaluate: + args = list(map(sympify, args)) + + if len(args) == 0: + return S.EmptySet + else: + args = list(map(sympify, args)) + + # keep the form of the first canonical arg + dargs = {} + for i in reversed(list(ordered(args))): + if i.is_Symbol: + dargs[i] = i + else: + try: + dargs[i.as_dummy()] = i + except TypeError: + # e.g. i = class without args like `Interval` + dargs[i] = i + _args_set = set(dargs.values()) + args = list(ordered(_args_set, Set._infimum_key)) + obj = Basic.__new__(cls, *args) + obj._args_set = _args_set + return obj + + + def __iter__(self): + return iter(self.args) + + def _complement(self, other): + if isinstance(other, Interval): + # Splitting in sub-intervals is only done for S.Reals; + # other cases that need splitting will first pass through + # Set._complement(). + nums, syms = [], [] + for m in self.args: + if m.is_number and m.is_real: + nums.append(m) + elif m.is_real == False: + pass # drop non-reals + else: + syms.append(m) # various symbolic expressions + if other == S.Reals and nums != []: + nums.sort() + intervals = [] # Build up a list of intervals between the elements + intervals += [Interval(S.NegativeInfinity, nums[0], True, True)] + for a, b in zip(nums[:-1], nums[1:]): + intervals.append(Interval(a, b, True, True)) # both open + intervals.append(Interval(nums[-1], S.Infinity, True, True)) + if syms != []: + return Complement(Union(*intervals, evaluate=False), + FiniteSet(*syms), evaluate=False) + else: + return Union(*intervals, evaluate=False) + elif nums == []: # no splitting necessary or possible: + if syms: + return Complement(other, FiniteSet(*syms), evaluate=False) + else: + return other + + elif isinstance(other, FiniteSet): + unk = [] + for i in self: + c = sympify(other.contains(i)) + if c is not S.true and c is not S.false: + unk.append(i) + unk = FiniteSet(*unk) + if unk == self: + return + not_true = [] + for i in other: + c = sympify(self.contains(i)) + if c is not S.true: + not_true.append(i) + return Complement(FiniteSet(*not_true), unk) + + return Set._complement(self, other) + + def _contains(self, other): + """ + Tests whether an element, other, is in the set. + + Explanation + =========== + + The actual test is for mathematical equality (as opposed to + syntactical equality). In the worst case all elements of the + set must be checked. + + Examples + ======== + + >>> from sympy import FiniteSet + >>> 1 in FiniteSet(1, 2) + True + >>> 5 in FiniteSet(1, 2) + False + + """ + if other in self._args_set: + return S.true + else: + # evaluate=True is needed to override evaluate=False context; + # we need Eq to do the evaluation + return Or(*[Eq(e, other, evaluate=True) for e in self.args]) + + def _eval_is_subset(self, other): + return fuzzy_and(other._contains(e) for e in self.args) + + @property + def _boundary(self): + return self + + @property + def _inf(self): + return Min(*self) + + @property + def _sup(self): + return Max(*self) + + @property + def measure(self): + return 0 + + def _kind(self): + if not self.args: + return SetKind() + elif all(i.kind == self.args[0].kind for i in self.args): + return SetKind(self.args[0].kind) + else: + return SetKind(UndefinedKind) + + def __len__(self): + return len(self.args) + + def as_relational(self, symbol): + """Rewrite a FiniteSet in terms of equalities and logic operators. """ + return Or(*[Eq(symbol, elem) for elem in self]) + + def compare(self, other): + return (hash(self) - hash(other)) + + def _eval_evalf(self, prec): + dps = prec_to_dps(prec) + return FiniteSet(*[elem.evalf(n=dps) for elem in self]) + + def _eval_simplify(self, **kwargs): + from sympy.simplify import simplify + return FiniteSet(*[simplify(elem, **kwargs) for elem in self]) + + @property + def _sorted_args(self): + return self.args + + def _eval_powerset(self): + return self.func(*[self.func(*s) for s in subsets(self.args)]) + + def _eval_rewrite_as_PowerSet(self, *args, **kwargs): + """Rewriting method for a finite set to a power set.""" + from .powerset import PowerSet + + is2pow = lambda n: bool(n and not n & (n - 1)) + if not is2pow(len(self)): + return None + + fs_test = lambda arg: isinstance(arg, Set) and arg.is_FiniteSet + if not all(fs_test(arg) for arg in args): + return None + + biggest = max(args, key=len) + for arg in subsets(biggest.args): + arg_set = FiniteSet(*arg) + if arg_set not in args: + return None + return PowerSet(biggest) + + def __ge__(self, other): + if not isinstance(other, Set): + raise TypeError("Invalid comparison of set with %s" % func_name(other)) + return other.is_subset(self) + + def __gt__(self, other): + if not isinstance(other, Set): + raise TypeError("Invalid comparison of set with %s" % func_name(other)) + return self.is_proper_superset(other) + + def __le__(self, other): + if not isinstance(other, Set): + raise TypeError("Invalid comparison of set with %s" % func_name(other)) + return self.is_subset(other) + + def __lt__(self, other): + if not isinstance(other, Set): + raise TypeError("Invalid comparison of set with %s" % func_name(other)) + return self.is_proper_subset(other) + + def __eq__(self, other): + if isinstance(other, (set, frozenset)): + return self._args_set == other + return super().__eq__(other) + + __hash__ : Callable[[Basic], Any] = Basic.__hash__ + +_sympy_converter[set] = lambda x: FiniteSet(*x) +_sympy_converter[frozenset] = lambda x: FiniteSet(*x) + + +class SymmetricDifference(Set): + """Represents the set of elements which are in either of the + sets and not in their intersection. + + Examples + ======== + + >>> from sympy import SymmetricDifference, FiniteSet + >>> SymmetricDifference(FiniteSet(1, 2, 3), FiniteSet(3, 4, 5)) + {1, 2, 4, 5} + + See Also + ======== + + Complement, Union + + References + ========== + + .. [1] https://en.wikipedia.org/wiki/Symmetric_difference + """ + + is_SymmetricDifference = True + + def __new__(cls, a, b, evaluate=True): + if evaluate: + return SymmetricDifference.reduce(a, b) + + return Basic.__new__(cls, a, b) + + @staticmethod + def reduce(A, B): + result = B._symmetric_difference(A) + if result is not None: + return result + else: + return SymmetricDifference(A, B, evaluate=False) + + def as_relational(self, symbol): + """Rewrite a symmetric_difference in terms of equalities and + logic operators""" + A, B = self.args + + A_rel = A.as_relational(symbol) + B_rel = B.as_relational(symbol) + + return Xor(A_rel, B_rel) + + @property + def is_iterable(self): + if all(arg.is_iterable for arg in self.args): + return True + + def __iter__(self): + + args = self.args + union = roundrobin(*(iter(arg) for arg in args)) + + for item in union: + count = 0 + for s in args: + if item in s: + count += 1 + + if count % 2 == 1: + yield item + + + +class DisjointUnion(Set): + """ Represents the disjoint union (also known as the external disjoint union) + of a finite number of sets. + + Examples + ======== + + >>> from sympy import DisjointUnion, FiniteSet, Interval, Union, Symbol + >>> A = FiniteSet(1, 2, 3) + >>> B = Interval(0, 5) + >>> DisjointUnion(A, B) + DisjointUnion({1, 2, 3}, Interval(0, 5)) + >>> DisjointUnion(A, B).rewrite(Union) + Union(ProductSet({1, 2, 3}, {0}), ProductSet(Interval(0, 5), {1})) + >>> C = FiniteSet(Symbol('x'), Symbol('y'), Symbol('z')) + >>> DisjointUnion(C, C) + DisjointUnion({x, y, z}, {x, y, z}) + >>> DisjointUnion(C, C).rewrite(Union) + ProductSet({x, y, z}, {0, 1}) + + References + ========== + + https://en.wikipedia.org/wiki/Disjoint_union + """ + + def __new__(cls, *sets): + dj_collection = [] + for set_i in sets: + if isinstance(set_i, Set): + dj_collection.append(set_i) + else: + raise TypeError("Invalid input: '%s', input args \ + to DisjointUnion must be Sets" % set_i) + obj = Basic.__new__(cls, *dj_collection) + return obj + + @property + def sets(self): + return self.args + + @property + def is_empty(self): + return fuzzy_and(s.is_empty for s in self.sets) + + @property + def is_finite_set(self): + all_finite = fuzzy_and(s.is_finite_set for s in self.sets) + return fuzzy_or([self.is_empty, all_finite]) + + @property + def is_iterable(self): + if self.is_empty: + return False + iter_flag = True + for set_i in self.sets: + if not set_i.is_empty: + iter_flag = iter_flag and set_i.is_iterable + return iter_flag + + def _eval_rewrite_as_Union(self, *sets, **kwargs): + """ + Rewrites the disjoint union as the union of (``set`` x {``i``}) + where ``set`` is the element in ``sets`` at index = ``i`` + """ + + dj_union = S.EmptySet + index = 0 + for set_i in sets: + if isinstance(set_i, Set): + cross = ProductSet(set_i, FiniteSet(index)) + dj_union = Union(dj_union, cross) + index = index + 1 + return dj_union + + def _contains(self, element): + """ + ``in`` operator for DisjointUnion + + Examples + ======== + + >>> from sympy import Interval, DisjointUnion + >>> D = DisjointUnion(Interval(0, 1), Interval(0, 2)) + >>> (0.5, 0) in D + True + >>> (0.5, 1) in D + True + >>> (1.5, 0) in D + False + >>> (1.5, 1) in D + True + + Passes operation on to constituent sets + """ + if not isinstance(element, Tuple) or len(element) != 2: + return S.false + + if not element[1].is_Integer: + return S.false + + if element[1] >= len(self.sets) or element[1] < 0: + return S.false + + return self.sets[element[1]]._contains(element[0]) + + def _kind(self): + if not self.args: + return SetKind() + elif all(i.kind == self.args[0].kind for i in self.args): + return self.args[0].kind + else: + return SetKind(UndefinedKind) + + def __iter__(self): + if self.is_iterable: + + iters = [] + for i, s in enumerate(self.sets): + iters.append(iproduct(s, {Integer(i)})) + + return iter(roundrobin(*iters)) + else: + raise ValueError("'%s' is not iterable." % self) + + def __len__(self): + """ + Returns the length of the disjoint union, i.e., the number of elements in the set. + + Examples + ======== + + >>> from sympy import FiniteSet, DisjointUnion, EmptySet + >>> D1 = DisjointUnion(FiniteSet(1, 2, 3, 4), EmptySet, FiniteSet(3, 4, 5)) + >>> len(D1) + 7 + >>> D2 = DisjointUnion(FiniteSet(3, 5, 7), EmptySet, FiniteSet(3, 5, 7)) + >>> len(D2) + 6 + >>> D3 = DisjointUnion(EmptySet, EmptySet) + >>> len(D3) + 0 + + Adds up the lengths of the constituent sets. + """ + + if self.is_finite_set: + size = 0 + for set in self.sets: + size += len(set) + return size + else: + raise ValueError("'%s' is not a finite set." % self) + + +def imageset(*args): + r""" + Return an image of the set under transformation ``f``. + + Explanation + =========== + + If this function cannot compute the image, it returns an + unevaluated ImageSet object. + + .. math:: + \{ f(x) \mid x \in \mathrm{self} \} + + Examples + ======== + + >>> from sympy import S, Interval, imageset, sin, Lambda + >>> from sympy.abc import x + + >>> imageset(x, 2*x, Interval(0, 2)) + Interval(0, 4) + + >>> imageset(lambda x: 2*x, Interval(0, 2)) + Interval(0, 4) + + >>> imageset(Lambda(x, sin(x)), Interval(-2, 1)) + ImageSet(Lambda(x, sin(x)), Interval(-2, 1)) + + >>> imageset(sin, Interval(-2, 1)) + ImageSet(Lambda(x, sin(x)), Interval(-2, 1)) + >>> imageset(lambda y: x + y, Interval(-2, 1)) + ImageSet(Lambda(y, x + y), Interval(-2, 1)) + + Expressions applied to the set of Integers are simplified + to show as few negatives as possible and linear expressions + are converted to a canonical form. If this is not desirable + then the unevaluated ImageSet should be used. + + >>> imageset(x, -2*x + 5, S.Integers) + ImageSet(Lambda(x, 2*x + 1), Integers) + + See Also + ======== + + sympy.sets.fancysets.ImageSet + + """ + from .fancysets import ImageSet + from .setexpr import set_function + + if len(args) < 2: + raise ValueError('imageset expects at least 2 args, got: %s' % len(args)) + + if isinstance(args[0], (Symbol, tuple)) and len(args) > 2: + f = Lambda(args[0], args[1]) + set_list = args[2:] + else: + f = args[0] + set_list = args[1:] + + if isinstance(f, Lambda): + pass + elif callable(f): + nargs = getattr(f, 'nargs', {}) + if nargs: + if len(nargs) != 1: + raise NotImplementedError(filldedent(''' + This function can take more than 1 arg + but the potentially complicated set input + has not been analyzed at this point to + know its dimensions. TODO + ''')) + N = nargs.args[0] + if N == 1: + s = 'x' + else: + s = [Symbol('x%i' % i) for i in range(1, N + 1)] + else: + s = inspect.signature(f).parameters + + dexpr = _sympify(f(*[Dummy() for i in s])) + var = tuple(uniquely_named_symbol( + Symbol(i), dexpr) for i in s) + f = Lambda(var, f(*var)) + else: + raise TypeError(filldedent(''' + expecting lambda, Lambda, or FunctionClass, + not \'%s\'.''' % func_name(f))) + + if any(not isinstance(s, Set) for s in set_list): + name = [func_name(s) for s in set_list] + raise ValueError( + 'arguments after mapping should be sets, not %s' % name) + + if len(set_list) == 1: + set = set_list[0] + try: + # TypeError if arg count != set dimensions + r = set_function(f, set) + if r is None: + raise TypeError + if not r: + return r + except TypeError: + r = ImageSet(f, set) + if isinstance(r, ImageSet): + f, set = r.args + + if f.variables[0] == f.expr: + return set + + if isinstance(set, ImageSet): + # XXX: Maybe this should just be: + # f2 = set.lambda + # fun = Lambda(f2.signature, f(*f2.expr)) + # return imageset(fun, *set.base_sets) + if len(set.lamda.variables) == 1 and len(f.variables) == 1: + x = set.lamda.variables[0] + y = f.variables[0] + return imageset( + Lambda(x, f.expr.subs(y, set.lamda.expr)), *set.base_sets) + + if r is not None: + return r + + return ImageSet(f, *set_list) + + +def is_function_invertible_in_set(func, setv): + """ + Checks whether function ``func`` is invertible when the domain is + restricted to set ``setv``. + """ + # Functions known to always be invertible: + if func in (exp, log): + return True + u = Dummy("u") + fdiff = func(u).diff(u) + # monotonous functions: + # TODO: check subsets (`func` in `setv`) + if (fdiff > 0) == True or (fdiff < 0) == True: + return True + # TODO: support more + return None + + +def simplify_union(args): + """ + Simplify a :class:`Union` using known rules. + + Explanation + =========== + + We first start with global rules like 'Merge all FiniteSets' + + Then we iterate through all pairs and ask the constituent sets if they + can simplify themselves with any other constituent. This process depends + on ``union_sets(a, b)`` functions. + """ + from sympy.sets.handlers.union import union_sets + + # ===== Global Rules ===== + if not args: + return S.EmptySet + + for arg in args: + if not isinstance(arg, Set): + raise TypeError("Input args to Union must be Sets") + + # Merge all finite sets + finite_sets = [x for x in args if x.is_FiniteSet] + if len(finite_sets) > 1: + a = (x for set in finite_sets for x in set) + finite_set = FiniteSet(*a) + args = [finite_set] + [x for x in args if not x.is_FiniteSet] + + # ===== Pair-wise Rules ===== + # Here we depend on rules built into the constituent sets + args = set(args) + new_args = True + while new_args: + for s in args: + new_args = False + for t in args - {s}: + new_set = union_sets(s, t) + # This returns None if s does not know how to intersect + # with t. Returns the newly intersected set otherwise + if new_set is not None: + if not isinstance(new_set, set): + new_set = {new_set} + new_args = (args - {s, t}).union(new_set) + break + if new_args: + args = new_args + break + + if len(args) == 1: + return args.pop() + else: + return Union(*args, evaluate=False) + + +def simplify_intersection(args): + """ + Simplify an intersection using known rules. + + Explanation + =========== + + We first start with global rules like + 'if any empty sets return empty set' and 'distribute any unions' + + Then we iterate through all pairs and ask the constituent sets if they + can simplify themselves with any other constituent + """ + + # ===== Global Rules ===== + if not args: + return S.UniversalSet + + for arg in args: + if not isinstance(arg, Set): + raise TypeError("Input args to Union must be Sets") + + # If any EmptySets return EmptySet + if S.EmptySet in args: + return S.EmptySet + + # Handle Finite sets + rv = Intersection._handle_finite_sets(args) + + if rv is not None: + return rv + + # If any of the sets are unions, return a Union of Intersections + for s in args: + if s.is_Union: + other_sets = set(args) - {s} + if len(other_sets) > 0: + other = Intersection(*other_sets) + return Union(*(Intersection(arg, other) for arg in s.args)) + else: + return Union(*s.args) + + for s in args: + if s.is_Complement: + args.remove(s) + other_sets = args + [s.args[0]] + return Complement(Intersection(*other_sets), s.args[1]) + + from sympy.sets.handlers.intersection import intersection_sets + + # At this stage we are guaranteed not to have any + # EmptySets, FiniteSets, or Unions in the intersection + + # ===== Pair-wise Rules ===== + # Here we depend on rules built into the constituent sets + args = set(args) + new_args = True + while new_args: + for s in args: + new_args = False + for t in args - {s}: + new_set = intersection_sets(s, t) + # This returns None if s does not know how to intersect + # with t. Returns the newly intersected set otherwise + + if new_set is not None: + new_args = (args - {s, t}).union({new_set}) + break + if new_args: + args = new_args + break + + if len(args) == 1: + return args.pop() + else: + return Intersection(*args, evaluate=False) + + +def _handle_finite_sets(op, x, y, commutative): + # Handle finite sets: + fs_args, other = sift([x, y], lambda x: isinstance(x, FiniteSet), binary=True) + if len(fs_args) == 2: + return FiniteSet(*[op(i, j) for i in fs_args[0] for j in fs_args[1]]) + elif len(fs_args) == 1: + sets = [_apply_operation(op, other[0], i, commutative) for i in fs_args[0]] + return Union(*sets) + else: + return None + + +def _apply_operation(op, x, y, commutative): + from .fancysets import ImageSet + d = Dummy('d') + + out = _handle_finite_sets(op, x, y, commutative) + if out is None: + out = op(x, y) + + if out is None and commutative: + out = op(y, x) + if out is None: + _x, _y = symbols("x y") + if isinstance(x, Set) and not isinstance(y, Set): + out = ImageSet(Lambda(d, op(d, y)), x).doit() + elif not isinstance(x, Set) and isinstance(y, Set): + out = ImageSet(Lambda(d, op(x, d)), y).doit() + else: + out = ImageSet(Lambda((_x, _y), op(_x, _y)), x, y) + return out + + +def set_add(x, y): + from sympy.sets.handlers.add import _set_add + return _apply_operation(_set_add, x, y, commutative=True) + + +def set_sub(x, y): + from sympy.sets.handlers.add import _set_sub + return _apply_operation(_set_sub, x, y, commutative=False) + + +def set_mul(x, y): + from sympy.sets.handlers.mul import _set_mul + return _apply_operation(_set_mul, x, y, commutative=True) + + +def set_div(x, y): + from sympy.sets.handlers.mul import _set_div + return _apply_operation(_set_div, x, y, commutative=False) + + +def set_pow(x, y): + from sympy.sets.handlers.power import _set_pow + return _apply_operation(_set_pow, x, y, commutative=False) + + +def set_function(f, x): + from sympy.sets.handlers.functions import _set_function + return _set_function(f, x) + + +class SetKind(Kind): + """ + SetKind is kind for all Sets + + Every instance of Set will have kind ``SetKind`` parametrised by the kind + of the elements of the ``Set``. The kind of the elements might be + ``NumberKind``, or ``TupleKind`` or something else. When not all elements + have the same kind then the kind of the elements will be given as + ``UndefinedKind``. + + Parameters + ========== + + element_kind: Kind (optional) + The kind of the elements of the set. In a well defined set all elements + will have the same kind. Otherwise the kind should + :class:`sympy.core.kind.UndefinedKind`. The ``element_kind`` argument is optional but + should only be omitted in the case of ``EmptySet`` whose kind is simply + ``SetKind()`` + + Examples + ======== + + >>> from sympy import Interval + >>> Interval(1, 2).kind + SetKind(NumberKind) + >>> Interval(1,2).kind.element_kind + NumberKind + + See Also + ======== + + sympy.core.kind.NumberKind + sympy.matrices.kind.MatrixKind + sympy.core.containers.TupleKind + """ + def __new__(cls, element_kind=None): + obj = super().__new__(cls, element_kind) + obj.element_kind = element_kind + return obj + + def __repr__(self): + if not self.element_kind: + return "SetKind()" + else: + return "SetKind(%s)" % self.element_kind diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..e69de29bb2d1d6434b8b29ae775ad8c2e48c5391 diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_conditionset.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_conditionset.py new file mode 100644 index 0000000000000000000000000000000000000000..4818246f306afd46a09a2cbea1faab858a9e7806 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_conditionset.py @@ -0,0 +1,294 @@ +from sympy.core.expr import unchanged +from sympy.sets import (ConditionSet, Intersection, FiniteSet, + EmptySet, Union, Contains, ImageSet) +from sympy.sets.sets import SetKind +from sympy.core.function import (Function, Lambda) +from sympy.core.mod import Mod +from sympy.core.kind import NumberKind +from sympy.core.numbers import (oo, pi) +from sympy.core.relational import (Eq, Ne) +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.functions.elementary.complexes import Abs +from sympy.functions.elementary.trigonometric import (asin, sin) +from sympy.logic.boolalg import And +from sympy.matrices.dense import Matrix +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.sets.sets import Interval +from sympy.testing.pytest import raises, warns_deprecated_sympy + + +w = Symbol('w') +x = Symbol('x') +y = Symbol('y') +z = Symbol('z') +f = Function('f') + + +def test_CondSet(): + sin_sols_principal = ConditionSet(x, Eq(sin(x), 0), + Interval(0, 2*pi, False, True)) + assert pi in sin_sols_principal + assert pi/2 not in sin_sols_principal + assert 3*pi not in sin_sols_principal + assert oo not in sin_sols_principal + assert 5 in ConditionSet(x, x**2 > 4, S.Reals) + assert 1 not in ConditionSet(x, x**2 > 4, S.Reals) + # in this case, 0 is not part of the base set so + # it can't be in any subset selected by the condition + assert 0 not in ConditionSet(x, y > 5, Interval(1, 7)) + # since 'in' requires a true/false, the following raises + # an error because the given value provides no information + # for the condition to evaluate (since the condition does + # not depend on the dummy symbol): the result is `y > 5`. + # In this case, ConditionSet is just acting like + # Piecewise((Interval(1, 7), y > 5), (S.EmptySet, True)). + raises(TypeError, lambda: 6 in ConditionSet(x, y > 5, + Interval(1, 7))) + + X = MatrixSymbol('X', 2, 2) + matrix_set = ConditionSet(X, Eq(X*Matrix([[1, 1], [1, 1]]), X)) + Y = Matrix([[0, 0], [0, 0]]) + assert matrix_set.contains(Y).doit() is S.true + Z = Matrix([[1, 2], [3, 4]]) + assert matrix_set.contains(Z).doit() is S.false + + assert isinstance(ConditionSet(x, x < 1, {x, y}).base_set, + FiniteSet) + raises(TypeError, lambda: ConditionSet(x, x + 1, {x, y})) + raises(TypeError, lambda: ConditionSet(x, x, 1)) + + I = S.Integers + U = S.UniversalSet + C = ConditionSet + assert C(x, False, I) is S.EmptySet + assert C(x, True, I) is I + assert C(x, x < 1, C(x, x < 2, I) + ) == C(x, (x < 1) & (x < 2), I) + assert C(y, y < 1, C(x, y < 2, I) + ) == C(x, (x < 1) & (y < 2), I), C(y, y < 1, C(x, y < 2, I)) + assert C(y, y < 1, C(x, x < 2, I) + ) == C(y, (y < 1) & (y < 2), I) + assert C(y, y < 1, C(x, y < x, I) + ) == C(x, (x < 1) & (y < x), I) + assert unchanged(C, y, x < 1, C(x, y < x, I)) + assert ConditionSet(x, x < 1).base_set is U + # arg checking is not done at instantiation but this + # will raise an error when containment is tested + assert ConditionSet((x,), x < 1).base_set is U + + c = ConditionSet((x, y), x < y, I**2) + assert (1, 2) in c + assert (1, pi) not in c + + raises(TypeError, lambda: C(x, x > 1, C((x, y), x > 1, I**2))) + # signature mismatch since only 3 args are accepted + raises(TypeError, lambda: C((x, y), x + y < 2, U, U)) + + +def test_CondSet_intersect(): + input_conditionset = ConditionSet(x, x**2 > 4, Interval(1, 4, False, + False)) + other_domain = Interval(0, 3, False, False) + output_conditionset = ConditionSet(x, x**2 > 4, Interval( + 1, 3, False, False)) + assert Intersection(input_conditionset, other_domain + ) == output_conditionset + + +def test_issue_9849(): + assert ConditionSet(x, Eq(x, x), S.Naturals + ) is S.Naturals + assert ConditionSet(x, Eq(Abs(sin(x)), -1), S.Naturals + ) == S.EmptySet + + +def test_simplified_FiniteSet_in_CondSet(): + assert ConditionSet(x, And(x < 1, x > -3), FiniteSet(0, 1, 2) + ) == FiniteSet(0) + assert ConditionSet(x, x < 0, FiniteSet(0, 1, 2)) == EmptySet + assert ConditionSet(x, And(x < -3), EmptySet) == EmptySet + y = Symbol('y') + assert (ConditionSet(x, And(x > 0), FiniteSet(-1, 0, 1, y)) == + Union(FiniteSet(1), ConditionSet(x, And(x > 0), FiniteSet(y)))) + assert (ConditionSet(x, Eq(Mod(x, 3), 1), FiniteSet(1, 4, 2, y)) == + Union(FiniteSet(1, 4), ConditionSet(x, Eq(Mod(x, 3), 1), + FiniteSet(y)))) + + +def test_free_symbols(): + assert ConditionSet(x, Eq(y, 0), FiniteSet(z) + ).free_symbols == {y, z} + assert ConditionSet(x, Eq(x, 0), FiniteSet(z) + ).free_symbols == {z} + assert ConditionSet(x, Eq(x, 0), FiniteSet(x, z) + ).free_symbols == {x, z} + assert ConditionSet(x, Eq(x, 0), ImageSet(Lambda(y, y**2), + S.Integers)).free_symbols == set() + + +def test_bound_symbols(): + assert ConditionSet(x, Eq(y, 0), FiniteSet(z) + ).bound_symbols == [x] + assert ConditionSet(x, Eq(x, 0), FiniteSet(x, y) + ).bound_symbols == [x] + assert ConditionSet(x, x < 10, ImageSet(Lambda(y, y**2), S.Integers) + ).bound_symbols == [x] + assert ConditionSet(x, x < 10, ConditionSet(y, y > 1, S.Integers) + ).bound_symbols == [x] + + +def test_as_dummy(): + _0, _1 = symbols('_0 _1') + assert ConditionSet(x, x < 1, Interval(y, oo) + ).as_dummy() == ConditionSet(_0, _0 < 1, Interval(y, oo)) + assert ConditionSet(x, x < 1, Interval(x, oo) + ).as_dummy() == ConditionSet(_0, _0 < 1, Interval(x, oo)) + assert ConditionSet(x, x < 1, ImageSet(Lambda(y, y**2), S.Integers) + ).as_dummy() == ConditionSet( + _0, _0 < 1, ImageSet(Lambda(_0, _0**2), S.Integers)) + e = ConditionSet((x, y), x <= y, S.Reals**2) + assert e.bound_symbols == [x, y] + assert e.as_dummy() == ConditionSet((_0, _1), _0 <= _1, S.Reals**2) + assert e.as_dummy() == ConditionSet((y, x), y <= x, S.Reals**2 + ).as_dummy() + + +def test_subs_CondSet(): + s = FiniteSet(z, y) + c = ConditionSet(x, x < 2, s) + assert c.subs(x, y) == c + assert c.subs(z, y) == ConditionSet(x, x < 2, FiniteSet(y)) + assert c.xreplace({x: y}) == ConditionSet(y, y < 2, s) + + assert ConditionSet(x, x < y, s + ).subs(y, w) == ConditionSet(x, x < w, s.subs(y, w)) + # if the user uses assumptions that cause the condition + # to evaluate, that can't be helped from SymPy's end + n = Symbol('n', negative=True) + assert ConditionSet(n, 0 < n, S.Integers) is S.EmptySet + p = Symbol('p', positive=True) + assert ConditionSet(n, n < y, S.Integers + ).subs(n, x) == ConditionSet(n, n < y, S.Integers) + raises(ValueError, lambda: ConditionSet( + x + 1, x < 1, S.Integers)) + assert ConditionSet( + p, n < x, Interval(-5, 5)).subs(x, p) == Interval(-5, 5), ConditionSet( + p, n < x, Interval(-5, 5)).subs(x, p) + assert ConditionSet( + n, n < x, Interval(-oo, 0)).subs(x, p + ) == Interval(-oo, 0) + + assert ConditionSet(f(x), f(x) < 1, {w, z} + ).subs(f(x), y) == ConditionSet(f(x), f(x) < 1, {w, z}) + + # issue 17341 + k = Symbol('k') + img1 = ImageSet(Lambda(k, 2*k*pi + asin(y)), S.Integers) + img2 = ImageSet(Lambda(k, 2*k*pi + asin(S.One/3)), S.Integers) + assert ConditionSet(x, Contains( + y, Interval(-1,1)), img1).subs(y, S.One/3).dummy_eq(img2) + + assert (0, 1) in ConditionSet((x, y), x + y < 3, S.Integers**2) + + raises(TypeError, lambda: ConditionSet(n, n < -10, Interval(0, 10))) + + +def test_subs_CondSet_tebr(): + with warns_deprecated_sympy(): + assert ConditionSet((x, y), {x + 1, x + y}, S.Reals**2) == \ + ConditionSet((x, y), Eq(x + 1, 0) & Eq(x + y, 0), S.Reals**2) + + +def test_dummy_eq(): + C = ConditionSet + I = S.Integers + c = C(x, x < 1, I) + assert c.dummy_eq(C(y, y < 1, I)) + assert c.dummy_eq(1) == False + assert c.dummy_eq(C(x, x < 1, S.Reals)) == False + + c1 = ConditionSet((x, y), Eq(x + 1, 0) & Eq(x + y, 0), S.Reals**2) + c2 = ConditionSet((x, y), Eq(x + 1, 0) & Eq(x + y, 0), S.Reals**2) + c3 = ConditionSet((x, y), Eq(x + 1, 0) & Eq(x + y, 0), S.Complexes**2) + assert c1.dummy_eq(c2) + assert c1.dummy_eq(c3) is False + assert c.dummy_eq(c1) is False + assert c1.dummy_eq(c) is False + + # issue 19496 + m = Symbol('m') + n = Symbol('n') + a = Symbol('a') + d1 = ImageSet(Lambda(m, m*pi), S.Integers) + d2 = ImageSet(Lambda(n, n*pi), S.Integers) + c1 = ConditionSet(x, Ne(a, 0), d1) + c2 = ConditionSet(x, Ne(a, 0), d2) + assert c1.dummy_eq(c2) + + +def test_contains(): + assert 6 in ConditionSet(x, x > 5, Interval(1, 7)) + assert (8 in ConditionSet(x, y > 5, Interval(1, 7))) is False + # `in` should give True or False; in this case there is not + # enough information for that result + raises(TypeError, + lambda: 6 in ConditionSet(x, y > 5, Interval(1, 7))) + # here, there is enough information but the comparison is + # not defined + raises(TypeError, lambda: 0 in ConditionSet(x, 1/x >= 0, S.Reals)) + assert ConditionSet(x, y > 5, Interval(1, 7) + ).contains(6) == (y > 5) + assert ConditionSet(x, y > 5, Interval(1, 7) + ).contains(8) is S.false + assert ConditionSet(x, y > 5, Interval(1, 7) + ).contains(w) == And(Contains(w, Interval(1, 7)), y > 5) + # This returns an unevaluated Contains object + # because 1/0 should not be defined for 1 and 0 in the context of + # reals. + assert ConditionSet(x, 1/x >= 0, S.Reals).contains(0) == \ + Contains(0, ConditionSet(x, 1/x >= 0, S.Reals), evaluate=False) + c = ConditionSet((x, y), x + y > 1, S.Integers**2) + assert not c.contains(1) + assert c.contains((2, 1)) + assert not c.contains((0, 1)) + c = ConditionSet((w, (x, y)), w + x + y > 1, S.Integers*S.Integers**2) + assert not c.contains(1) + assert not c.contains((1, 2)) + assert not c.contains(((1, 2), 3)) + assert not c.contains(((1, 2), (3, 4))) + assert c.contains((1, (3, 4))) + + +def test_as_relational(): + assert ConditionSet((x, y), x > 1, S.Integers**2).as_relational((x, y) + ) == (x > 1) & Contains(x, S.Integers) & Contains(y, S.Integers) + assert ConditionSet(x, x > 1, S.Integers).as_relational(x + ) == Contains(x, S.Integers) & (x > 1) + + +def test_flatten(): + """Tests whether there is basic denesting functionality""" + inner = ConditionSet(x, sin(x) + x > 0) + outer = ConditionSet(x, Contains(x, inner), S.Reals) + assert outer == ConditionSet(x, sin(x) + x > 0, S.Reals) + + inner = ConditionSet(y, sin(y) + y > 0) + outer = ConditionSet(x, Contains(y, inner), S.Reals) + assert outer != ConditionSet(x, sin(x) + x > 0, S.Reals) + + inner = ConditionSet(x, sin(x) + x > 0).intersect(Interval(-1, 1)) + outer = ConditionSet(x, Contains(x, inner), S.Reals) + assert outer == ConditionSet(x, sin(x) + x > 0, Interval(-1, 1)) + + +def test_duplicate(): + from sympy.core.function import BadSignatureError + # test coverage for line 95 in conditionset.py, check for duplicates in symbols + dup = symbols('a,a') + raises(BadSignatureError, lambda: ConditionSet(dup, x < 0)) + + +def test_SetKind_ConditionSet(): + assert ConditionSet(x, Eq(sin(x), 0), Interval(0, 2*pi)).kind is SetKind(NumberKind) + assert ConditionSet(x, x < 0).kind is SetKind(NumberKind) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_contains.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_contains.py new file mode 100644 index 0000000000000000000000000000000000000000..bb6b98940946f98bf377aad6810f5b32eb6dd069 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_contains.py @@ -0,0 +1,52 @@ +from sympy.core.expr import unchanged +from sympy.core.numbers import oo +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.sets.contains import Contains +from sympy.sets.sets import (FiniteSet, Interval) +from sympy.testing.pytest import raises + + +def test_contains_basic(): + raises(TypeError, lambda: Contains(S.Integers, 1)) + assert Contains(2, S.Integers) is S.true + assert Contains(-2, S.Naturals) is S.false + + i = Symbol('i', integer=True) + assert Contains(i, S.Naturals) == Contains(i, S.Naturals, evaluate=False) + + +def test_issue_6194(): + x = Symbol('x') + assert unchanged(Contains, x, Interval(0, 1)) + assert Interval(0, 1).contains(x) == (S.Zero <= x) & (x <= 1) + assert Contains(x, FiniteSet(0)) != S.false + assert Contains(x, Interval(1, 1)) != S.false + assert Contains(x, S.Integers) != S.false + + +def test_issue_10326(): + assert Contains(oo, Interval(-oo, oo)) == False + assert Contains(-oo, Interval(-oo, oo)) == False + + +def test_binary_symbols(): + x = Symbol('x') + y = Symbol('y') + z = Symbol('z') + assert Contains(x, FiniteSet(y, Eq(z, True)) + ).binary_symbols == {y, z} + + +def test_as_set(): + x = Symbol('x') + y = Symbol('y') + assert Contains(x, FiniteSet(y)).as_set() == FiniteSet(y) + assert Contains(x, S.Integers).as_set() == S.Integers + assert Contains(x, S.Reals).as_set() == S.Reals + + +def test_type_error(): + # Pass in a parameter not of type "set" + raises(TypeError, lambda: Contains(2, None)) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_fancysets.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_fancysets.py new file mode 100644 index 0000000000000000000000000000000000000000..b23c2a99fce0af5bfe7c667185465ee417de19ce --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_fancysets.py @@ -0,0 +1,1313 @@ + +from sympy.core.expr import unchanged +from sympy.sets.contains import Contains +from sympy.sets.fancysets import (ImageSet, Range, normalize_theta_set, + ComplexRegion) +from sympy.sets.sets import (FiniteSet, Interval, Union, imageset, + Intersection, ProductSet, SetKind) +from sympy.sets.conditionset import ConditionSet +from sympy.simplify.simplify import simplify +from sympy.core.basic import Basic +from sympy.core.containers import Tuple, TupleKind +from sympy.core.function import Lambda +from sympy.core.kind import NumberKind +from sympy.core.numbers import (I, Rational, oo, pi) +from sympy.core.relational import Eq +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, Symbol, symbols) +from sympy.functions.elementary.complexes import Abs +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.integers import floor +from sympy.functions.elementary.miscellaneous import sqrt +from sympy.functions.elementary.trigonometric import (cos, sin, tan) +from sympy.logic.boolalg import And +from sympy.matrices.dense import eye +from sympy.testing.pytest import XFAIL, raises +from sympy.abc import x, y, t, z +from sympy.core.mod import Mod + +import itertools + + +def test_naturals(): + N = S.Naturals + assert 5 in N + assert -5 not in N + assert 5.5 not in N + ni = iter(N) + a, b, c, d = next(ni), next(ni), next(ni), next(ni) + assert (a, b, c, d) == (1, 2, 3, 4) + assert isinstance(a, Basic) + + assert N.intersect(Interval(-5, 5)) == Range(1, 6) + assert N.intersect(Interval(-5, 5, True, True)) == Range(1, 5) + + assert N.boundary == N + assert N.is_open == False + assert N.is_closed == True + + assert N.inf == 1 + assert N.sup is oo + assert not N.contains(oo) + for s in (S.Naturals0, S.Naturals): + assert s.intersection(S.Reals) is s + assert s.is_subset(S.Reals) + + assert N.as_relational(x) == And(Eq(floor(x), x), x >= 1, x < oo) + + +def test_naturals0(): + N = S.Naturals0 + assert 0 in N + assert -1 not in N + assert next(iter(N)) == 0 + assert not N.contains(oo) + assert N.contains(sin(x)) == Contains(sin(x), N) + + +def test_integers(): + Z = S.Integers + assert 5 in Z + assert -5 in Z + assert 5.5 not in Z + assert not Z.contains(oo) + assert not Z.contains(-oo) + + zi = iter(Z) + a, b, c, d = next(zi), next(zi), next(zi), next(zi) + assert (a, b, c, d) == (0, 1, -1, 2) + assert isinstance(a, Basic) + + assert Z.intersect(Interval(-5, 5)) == Range(-5, 6) + assert Z.intersect(Interval(-5, 5, True, True)) == Range(-4, 5) + assert Z.intersect(Interval(5, S.Infinity)) == Range(5, S.Infinity) + assert Z.intersect(Interval.Lopen(5, S.Infinity)) == Range(6, S.Infinity) + + assert Z.inf is -oo + assert Z.sup is oo + + assert Z.boundary == Z + assert Z.is_open == False + assert Z.is_closed == True + + assert Z.as_relational(x) == And(Eq(floor(x), x), -oo < x, x < oo) + + +def test_ImageSet(): + raises(ValueError, lambda: ImageSet(x, S.Integers)) + assert ImageSet(Lambda(x, 1), S.Integers) == FiniteSet(1) + assert ImageSet(Lambda(x, y), S.Integers) == {y} + assert ImageSet(Lambda(x, 1), S.EmptySet) == S.EmptySet + empty = Intersection(FiniteSet(log(2)/pi), S.Integers) + assert unchanged(ImageSet, Lambda(x, 1), empty) # issue #17471 + squares = ImageSet(Lambda(x, x**2), S.Naturals) + assert 4 in squares + assert 5 not in squares + assert FiniteSet(*range(10)).intersect(squares) == FiniteSet(1, 4, 9) + + assert 16 not in squares.intersect(Interval(0, 10)) + + si = iter(squares) + a, b, c, d = next(si), next(si), next(si), next(si) + assert (a, b, c, d) == (1, 4, 9, 16) + + harmonics = ImageSet(Lambda(x, 1/x), S.Naturals) + assert Rational(1, 5) in harmonics + assert Rational(.25) in harmonics + assert harmonics.contains(.25) == Contains( + 0.25, ImageSet(Lambda(x, 1/x), S.Naturals), evaluate=False) + assert Rational(.3) not in harmonics + assert (1, 2) not in harmonics + + assert harmonics.is_iterable + + assert imageset(x, -x, Interval(0, 1)) == Interval(-1, 0) + + assert ImageSet(Lambda(x, x**2), Interval(0, 2)).doit() == Interval(0, 4) + assert ImageSet(Lambda((x, y), 2*x), {4}, {3}).doit() == FiniteSet(8) + assert (ImageSet(Lambda((x, y), x+y), {1, 2, 3}, {10, 20, 30}).doit() == + FiniteSet(11, 12, 13, 21, 22, 23, 31, 32, 33)) + + c = Interval(1, 3) * Interval(1, 3) + assert Tuple(2, 6) in ImageSet(Lambda(((x, y),), (x, 2*y)), c) + assert Tuple(2, S.Half) in ImageSet(Lambda(((x, y),), (x, 1/y)), c) + assert Tuple(2, -2) not in ImageSet(Lambda(((x, y),), (x, y**2)), c) + assert Tuple(2, -2) in ImageSet(Lambda(((x, y),), (x, -2)), c) + c3 = ProductSet(Interval(3, 7), Interval(8, 11), Interval(5, 9)) + assert Tuple(8, 3, 9) in ImageSet(Lambda(((t, y, x),), (y, t, x)), c3) + assert Tuple(Rational(1, 8), 3, 9) in ImageSet(Lambda(((t, y, x),), (1/y, t, x)), c3) + assert 2/pi not in ImageSet(Lambda(((x, y),), 2/x), c) + assert 2/S(100) not in ImageSet(Lambda(((x, y),), 2/x), c) + assert Rational(2, 3) in ImageSet(Lambda(((x, y),), 2/x), c) + + S1 = imageset(lambda x, y: x + y, S.Integers, S.Naturals) + assert S1.base_pset == ProductSet(S.Integers, S.Naturals) + assert S1.base_sets == (S.Integers, S.Naturals) + + # Passing a set instead of a FiniteSet shouldn't raise + assert unchanged(ImageSet, Lambda(x, x**2), {1, 2, 3}) + + S2 = ImageSet(Lambda(((x, y),), x+y), {(1, 2), (3, 4)}) + assert 3 in S2.doit() + # FIXME: This doesn't yet work: + #assert 3 in S2 + assert S2._contains(3) is None + + raises(TypeError, lambda: ImageSet(Lambda(x, x**2), 1)) + + +def test_image_is_ImageSet(): + assert isinstance(imageset(x, sqrt(sin(x)), Range(5)), ImageSet) + + +def test_halfcircle(): + r, th = symbols('r, theta', real=True) + L = Lambda(((r, th),), (r*cos(th), r*sin(th))) + halfcircle = ImageSet(L, Interval(0, 1)*Interval(0, pi)) + + assert (1, 0) in halfcircle + assert (0, -1) not in halfcircle + assert (0, 0) in halfcircle + assert halfcircle._contains((r, 0)) is None + assert not halfcircle.is_iterable + + +@XFAIL +def test_halfcircle_fail(): + r, th = symbols('r, theta', real=True) + L = Lambda(((r, th),), (r*cos(th), r*sin(th))) + halfcircle = ImageSet(L, Interval(0, 1)*Interval(0, pi)) + assert (r, 2*pi) not in halfcircle + + +def test_ImageSet_iterator_not_injective(): + L = Lambda(x, x - x % 2) # produces 0, 2, 2, 4, 4, 6, 6, ... + evens = ImageSet(L, S.Naturals) + i = iter(evens) + # No repeats here + assert (next(i), next(i), next(i), next(i)) == (0, 2, 4, 6) + + +def test_inf_Range_len(): + raises(ValueError, lambda: len(Range(0, oo, 2))) + assert Range(0, oo, 2).size is S.Infinity + assert Range(0, -oo, -2).size is S.Infinity + assert Range(oo, 0, -2).size is S.Infinity + assert Range(-oo, 0, 2).size is S.Infinity + + +def test_Range_set(): + empty = Range(0) + + assert Range(5) == Range(0, 5) == Range(0, 5, 1) + + r = Range(10, 20, 2) + assert 12 in r + assert 8 not in r + assert 11 not in r + assert 30 not in r + + assert list(Range(0, 5)) == list(range(5)) + assert list(Range(5, 0, -1)) == list(range(5, 0, -1)) + + + assert Range(5, 15).sup == 14 + assert Range(5, 15).inf == 5 + assert Range(15, 5, -1).sup == 15 + assert Range(15, 5, -1).inf == 6 + assert Range(10, 67, 10).sup == 60 + assert Range(60, 7, -10).inf == 10 + + assert len(Range(10, 38, 10)) == 3 + + assert Range(0, 0, 5) == empty + assert Range(oo, oo, 1) == empty + assert Range(oo, 1, 1) == empty + assert Range(-oo, 1, -1) == empty + assert Range(1, oo, -1) == empty + assert Range(1, -oo, 1) == empty + assert Range(1, -4, oo) == empty + ip = symbols('ip', positive=True) + assert Range(0, ip, -1) == empty + assert Range(0, -ip, 1) == empty + assert Range(1, -4, -oo) == Range(1, 2) + assert Range(1, 4, oo) == Range(1, 2) + assert Range(-oo, oo).size == oo + assert Range(oo, -oo, -1).size == oo + raises(ValueError, lambda: Range(-oo, oo, 2)) + raises(ValueError, lambda: Range(x, pi, y)) + raises(ValueError, lambda: Range(x, y, 0)) + + assert 5 in Range(0, oo, 5) + assert -5 in Range(-oo, 0, 5) + assert oo not in Range(0, oo) + ni = symbols('ni', integer=False) + assert ni not in Range(oo) + u = symbols('u', integer=None) + assert Range(oo).contains(u) is not False + inf = symbols('inf', infinite=True) + assert inf not in Range(-oo, oo) + raises(ValueError, lambda: Range(0, oo, 2)[-1]) + raises(ValueError, lambda: Range(0, -oo, -2)[-1]) + assert Range(-oo, 1, 1)[-1] is S.Zero + assert Range(oo, 1, -1)[-1] == 2 + assert inf not in Range(oo) + assert Range(1, 10, 1)[-1] == 9 + assert all(i.is_Integer for i in Range(0, -1, 1)) + it = iter(Range(-oo, 0, 2)) + raises(TypeError, lambda: next(it)) + + assert empty.intersect(S.Integers) == empty + assert Range(-1, 10, 1).intersect(S.Complexes) == Range(-1, 10, 1) + assert Range(-1, 10, 1).intersect(S.Reals) == Range(-1, 10, 1) + assert Range(-1, 10, 1).intersect(S.Rationals) == Range(-1, 10, 1) + assert Range(-1, 10, 1).intersect(S.Integers) == Range(-1, 10, 1) + assert Range(-1, 10, 1).intersect(S.Naturals) == Range(1, 10, 1) + assert Range(-1, 10, 1).intersect(S.Naturals0) == Range(0, 10, 1) + + # test slicing + assert Range(1, 10, 1)[5] == 6 + assert Range(1, 12, 2)[5] == 11 + assert Range(1, 10, 1)[-1] == 9 + assert Range(1, 10, 3)[-1] == 7 + raises(ValueError, lambda: Range(oo,0,-1)[1:3:0]) + raises(ValueError, lambda: Range(oo,0,-1)[:1]) + raises(ValueError, lambda: Range(1, oo)[-2]) + raises(ValueError, lambda: Range(-oo, 1)[2]) + raises(IndexError, lambda: Range(10)[-20]) + raises(IndexError, lambda: Range(10)[20]) + raises(ValueError, lambda: Range(2, -oo, -2)[2:2:0]) + assert Range(2, -oo, -2)[2:2:2] == empty + assert Range(2, -oo, -2)[:2:2] == Range(2, -2, -4) + raises(ValueError, lambda: Range(-oo, 4, 2)[:2:2]) + assert Range(-oo, 4, 2)[::-2] == Range(2, -oo, -4) + raises(ValueError, lambda: Range(-oo, 4, 2)[::2]) + assert Range(oo, 2, -2)[::] == Range(oo, 2, -2) + assert Range(-oo, 4, 2)[:-2:-2] == Range(2, 0, -4) + assert Range(-oo, 4, 2)[:-2:2] == Range(-oo, 0, 4) + raises(ValueError, lambda: Range(-oo, 4, 2)[:0:-2]) + raises(ValueError, lambda: Range(-oo, 4, 2)[:2:-2]) + assert Range(-oo, 4, 2)[-2::-2] == Range(0, -oo, -4) + raises(ValueError, lambda: Range(-oo, 4, 2)[-2:0:-2]) + raises(ValueError, lambda: Range(-oo, 4, 2)[0::2]) + assert Range(oo, 2, -2)[0::] == Range(oo, 2, -2) + raises(ValueError, lambda: Range(-oo, 4, 2)[0:-2:2]) + assert Range(oo, 2, -2)[0:-2:] == Range(oo, 6, -2) + raises(ValueError, lambda: Range(oo, 2, -2)[0:2:]) + raises(ValueError, lambda: Range(-oo, 4, 2)[2::-1]) + assert Range(-oo, 4, 2)[-2::2] == Range(0, 4, 4) + assert Range(oo, 0, -2)[-10:0:2] == empty + raises(ValueError, lambda: Range(oo, 0, -2)[0]) + raises(ValueError, lambda: Range(oo, 0, -2)[-10:10:2]) + raises(ValueError, lambda: Range(oo, 0, -2)[0::-2]) + assert Range(oo, 0, -2)[0:-4:-2] == empty + assert Range(oo, 0, -2)[:0:2] == empty + raises(ValueError, lambda: Range(oo, 0, -2)[:1:-1]) + + # test empty Range + assert Range(x, x, y) == empty + assert empty.reversed == empty + assert 0 not in empty + assert list(empty) == [] + assert len(empty) == 0 + assert empty.size is S.Zero + assert empty.intersect(FiniteSet(0)) is S.EmptySet + assert bool(empty) is False + raises(IndexError, lambda: empty[0]) + assert empty[:0] == empty + raises(NotImplementedError, lambda: empty.inf) + raises(NotImplementedError, lambda: empty.sup) + assert empty.as_relational(x) is S.false + + AB = [None] + list(range(12)) + for R in [ + Range(1, 10), + Range(1, 10, 2), + ]: + r = list(R) + for a, b, c in itertools.product(AB, AB, [-3, -1, None, 1, 3]): + for reverse in range(2): + r = list(reversed(r)) + R = R.reversed + result = list(R[a:b:c]) + ans = r[a:b:c] + txt = ('\n%s[%s:%s:%s] = %s -> %s' % ( + R, a, b, c, result, ans)) + check = ans == result + assert check, txt + + assert Range(1, 10, 1).boundary == Range(1, 10, 1) + + for r in (Range(1, 10, 2), Range(1, oo, 2)): + rev = r.reversed + assert r.inf == rev.inf and r.sup == rev.sup + assert r.step == -rev.step + + builtin_range = range + + raises(TypeError, lambda: Range(builtin_range(1))) + assert S(builtin_range(10)) == Range(10) + assert S(builtin_range(1000000000000)) == Range(1000000000000) + + # test Range.as_relational + assert Range(1, 4).as_relational(x) == (x >= 1) & (x <= 3) & Eq(Mod(x, 1), 0) + assert Range(oo, 1, -2).as_relational(x) == (x >= 3) & (x < oo) & Eq(Mod(x + 1, -2), 0) + + +def test_Range_symbolic(): + # symbolic Range + xr = Range(x, x + 4, 5) + sr = Range(x, y, t) + i = Symbol('i', integer=True) + ip = Symbol('i', integer=True, positive=True) + ipr = Range(ip) + inr = Range(0, -ip, -1) + ir = Range(i, i + 19, 2) + ir2 = Range(i, i*8, 3*i) + i = Symbol('i', integer=True) + inf = symbols('inf', infinite=True) + raises(ValueError, lambda: Range(inf)) + raises(ValueError, lambda: Range(inf, 0, -1)) + raises(ValueError, lambda: Range(inf, inf, 1)) + raises(ValueError, lambda: Range(1, 1, inf)) + # args + assert xr.args == (x, x + 5, 5) + assert sr.args == (x, y, t) + assert ir.args == (i, i + 20, 2) + assert ir2.args == (i, 10*i, 3*i) + # reversed + raises(ValueError, lambda: xr.reversed) + raises(ValueError, lambda: sr.reversed) + assert ipr.reversed.args == (ip - 1, -1, -1) + assert inr.reversed.args == (-ip + 1, 1, 1) + assert ir.reversed.args == (i + 18, i - 2, -2) + assert ir2.reversed.args == (7*i, -2*i, -3*i) + # contains + assert inf not in sr + assert inf not in ir + assert 0 in ipr + assert 0 in inr + raises(TypeError, lambda: 1 in ipr) + raises(TypeError, lambda: -1 in inr) + assert .1 not in sr + assert .1 not in ir + assert i + 1 not in ir + assert i + 2 in ir + raises(TypeError, lambda: x in xr) # XXX is this what contains is supposed to do? + raises(TypeError, lambda: 1 in sr) # XXX is this what contains is supposed to do? + # iter + raises(ValueError, lambda: next(iter(xr))) + raises(ValueError, lambda: next(iter(sr))) + assert next(iter(ir)) == i + assert next(iter(ir2)) == i + assert sr.intersect(S.Integers) == sr + assert sr.intersect(FiniteSet(x)) == Intersection({x}, sr) + raises(ValueError, lambda: sr[:2]) + raises(ValueError, lambda: xr[0]) + raises(ValueError, lambda: sr[0]) + # len + assert len(ir) == ir.size == 10 + assert len(ir2) == ir2.size == 3 + raises(ValueError, lambda: len(xr)) + raises(ValueError, lambda: xr.size) + raises(ValueError, lambda: len(sr)) + raises(ValueError, lambda: sr.size) + # bool + assert bool(Range(0)) == False + assert bool(xr) + assert bool(ir) + assert bool(ipr) + assert bool(inr) + raises(ValueError, lambda: bool(sr)) + raises(ValueError, lambda: bool(ir2)) + # inf + raises(ValueError, lambda: xr.inf) + raises(ValueError, lambda: sr.inf) + assert ipr.inf == 0 + assert inr.inf == -ip + 1 + assert ir.inf == i + raises(ValueError, lambda: ir2.inf) + # sup + raises(ValueError, lambda: xr.sup) + raises(ValueError, lambda: sr.sup) + assert ipr.sup == ip - 1 + assert inr.sup == 0 + assert ir.inf == i + raises(ValueError, lambda: ir2.sup) + # getitem + raises(ValueError, lambda: xr[0]) + raises(ValueError, lambda: sr[0]) + raises(ValueError, lambda: sr[-1]) + raises(ValueError, lambda: sr[:2]) + assert ir[:2] == Range(i, i + 4, 2) + assert ir[0] == i + assert ir[-2] == i + 16 + assert ir[-1] == i + 18 + assert ir2[:2] == Range(i, 7*i, 3*i) + assert ir2[0] == i + assert ir2[-2] == 4*i + assert ir2[-1] == 7*i + raises(ValueError, lambda: Range(i)[-1]) + assert ipr[0] == ipr.inf == 0 + assert ipr[-1] == ipr.sup == ip - 1 + assert inr[0] == inr.sup == 0 + assert inr[-1] == inr.inf == -ip + 1 + raises(ValueError, lambda: ipr[-2]) + assert ir.inf == i + assert ir.sup == i + 18 + raises(ValueError, lambda: Range(i).inf) + # as_relational + assert ir.as_relational(x) == ((x >= i) & (x <= i + 18) & + Eq(Mod(-i + x, 2), 0)) + assert ir2.as_relational(x) == Eq( + Mod(-i + x, 3*i), 0) & (((x >= i) & (x <= 7*i) & (3*i >= 1)) | + ((x <= i) & (x >= 7*i) & (3*i <= -1))) + assert Range(i, i + 1).as_relational(x) == Eq(x, i) + assert sr.as_relational(z) == Eq( + Mod(t, 1), 0) & Eq(Mod(x, 1), 0) & Eq(Mod(-x + z, t), 0 + ) & (((z >= x) & (z <= -t + y) & (t >= 1)) | + ((z <= x) & (z >= -t + y) & (t <= -1))) + assert xr.as_relational(z) == Eq(z, x) & Eq(Mod(x, 1), 0) + # symbols can clash if user wants (but it must be integer) + assert xr.as_relational(x) == Eq(Mod(x, 1), 0) + # contains() for symbolic values (issue #18146) + e = Symbol('e', integer=True, even=True) + o = Symbol('o', integer=True, odd=True) + assert Range(5).contains(i) == And(i >= 0, i <= 4) + assert Range(1).contains(i) == Eq(i, 0) + assert Range(-oo, 5, 1).contains(i) == (i <= 4) + assert Range(-oo, oo).contains(i) == True + assert Range(0, 8, 2).contains(i) == Contains(i, Range(0, 8, 2)) + assert Range(0, 8, 2).contains(e) == And(e >= 0, e <= 6) + assert Range(0, 8, 2).contains(2*i) == And(2*i >= 0, 2*i <= 6) + assert Range(0, 8, 2).contains(o) == False + assert Range(1, 9, 2).contains(e) == False + assert Range(1, 9, 2).contains(o) == And(o >= 1, o <= 7) + assert Range(8, 0, -2).contains(o) == False + assert Range(9, 1, -2).contains(o) == And(o >= 3, o <= 9) + assert Range(-oo, 8, 2).contains(i) == Contains(i, Range(-oo, 8, 2)) + + +def test_range_range_intersection(): + for a, b, r in [ + (Range(0), Range(1), S.EmptySet), + (Range(3), Range(4, oo), S.EmptySet), + (Range(3), Range(-3, -1), S.EmptySet), + (Range(1, 3), Range(0, 3), Range(1, 3)), + (Range(1, 3), Range(1, 4), Range(1, 3)), + (Range(1, oo, 2), Range(2, oo, 2), S.EmptySet), + (Range(0, oo, 2), Range(oo), Range(0, oo, 2)), + (Range(0, oo, 2), Range(100), Range(0, 100, 2)), + (Range(2, oo, 2), Range(oo), Range(2, oo, 2)), + (Range(0, oo, 2), Range(5, 6), S.EmptySet), + (Range(2, 80, 1), Range(55, 71, 4), Range(55, 71, 4)), + (Range(0, 6, 3), Range(-oo, 5, 3), S.EmptySet), + (Range(0, oo, 2), Range(5, oo, 3), Range(8, oo, 6)), + (Range(4, 6, 2), Range(2, 16, 7), S.EmptySet),]: + assert a.intersect(b) == r + assert a.intersect(b.reversed) == r + assert a.reversed.intersect(b) == r + assert a.reversed.intersect(b.reversed) == r + a, b = b, a + assert a.intersect(b) == r + assert a.intersect(b.reversed) == r + assert a.reversed.intersect(b) == r + assert a.reversed.intersect(b.reversed) == r + + +def test_range_interval_intersection(): + p = symbols('p', positive=True) + assert isinstance(Range(3).intersect(Interval(p, p + 2)), Intersection) + assert Range(4).intersect(Interval(0, 3)) == Range(4) + assert Range(4).intersect(Interval(-oo, oo)) == Range(4) + assert Range(4).intersect(Interval(1, oo)) == Range(1, 4) + assert Range(4).intersect(Interval(1.1, oo)) == Range(2, 4) + assert Range(4).intersect(Interval(0.1, 3)) == Range(1, 4) + assert Range(4).intersect(Interval(0.1, 3.1)) == Range(1, 4) + assert Range(4).intersect(Interval.open(0, 3)) == Range(1, 3) + assert Range(4).intersect(Interval.open(0.1, 0.5)) is S.EmptySet + assert Interval(-1, 5).intersect(S.Complexes) == Interval(-1, 5) + assert Interval(-1, 5).intersect(S.Reals) == Interval(-1, 5) + assert Interval(-1, 5).intersect(S.Integers) == Range(-1, 6) + assert Interval(-1, 5).intersect(S.Naturals) == Range(1, 6) + assert Interval(-1, 5).intersect(S.Naturals0) == Range(0, 6) + + # Null Range intersections + assert Range(0).intersect(Interval(0.2, 0.8)) is S.EmptySet + assert Range(0).intersect(Interval(-oo, oo)) is S.EmptySet + + +def test_range_is_finite_set(): + assert Range(-100, 100).is_finite_set is True + assert Range(2, oo).is_finite_set is False + assert Range(-oo, 50).is_finite_set is False + assert Range(-oo, oo).is_finite_set is False + assert Range(oo, -oo).is_finite_set is True + assert Range(0, 0).is_finite_set is True + assert Range(oo, oo).is_finite_set is True + assert Range(-oo, -oo).is_finite_set is True + n = Symbol('n', integer=True) + m = Symbol('m', integer=True) + assert Range(n, n + 49).is_finite_set is True + assert Range(n, 0).is_finite_set is True + assert Range(-3, n + 7).is_finite_set is True + assert Range(n, m).is_finite_set is True + assert Range(n + m, m - n).is_finite_set is True + assert Range(n, n + m + n).is_finite_set is True + assert Range(n, oo).is_finite_set is False + assert Range(-oo, n).is_finite_set is False + assert Range(n, -oo).is_finite_set is True + assert Range(oo, n).is_finite_set is True + + +def test_Range_is_iterable(): + assert Range(-100, 100).is_iterable is True + assert Range(2, oo).is_iterable is False + assert Range(-oo, 50).is_iterable is False + assert Range(-oo, oo).is_iterable is False + assert Range(oo, -oo).is_iterable is True + assert Range(0, 0).is_iterable is True + assert Range(oo, oo).is_iterable is True + assert Range(-oo, -oo).is_iterable is True + n = Symbol('n', integer=True) + m = Symbol('m', integer=True) + p = Symbol('p', integer=True, positive=True) + assert Range(n, n + 49).is_iterable is True + assert Range(n, 0).is_iterable is False + assert Range(-3, n + 7).is_iterable is False + assert Range(-3, p + 7).is_iterable is False # Should work with better __iter__ + assert Range(n, m).is_iterable is False + assert Range(n + m, m - n).is_iterable is False + assert Range(n, n + m + n).is_iterable is False + assert Range(n, oo).is_iterable is False + assert Range(-oo, n).is_iterable is False + x = Symbol('x') + assert Range(x, x + 49).is_iterable is False + assert Range(x, 0).is_iterable is False + assert Range(-3, x + 7).is_iterable is False + assert Range(x, m).is_iterable is False + assert Range(x + m, m - x).is_iterable is False + assert Range(x, x + m + x).is_iterable is False + assert Range(x, oo).is_iterable is False + assert Range(-oo, x).is_iterable is False + + +def test_Integers_eval_imageset(): + ans = ImageSet(Lambda(x, 2*x + Rational(3, 7)), S.Integers) + im = imageset(Lambda(x, -2*x + Rational(3, 7)), S.Integers) + assert im == ans + im = imageset(Lambda(x, -2*x - Rational(11, 7)), S.Integers) + assert im == ans + y = Symbol('y') + L = imageset(x, 2*x + y, S.Integers) + assert y + 4 in L + a, b, c = 0.092, 0.433, 0.341 + assert a in imageset(x, a + c*x, S.Integers) + assert b in imageset(x, b + c*x, S.Integers) + + _x = symbols('x', negative=True) + eq = _x**2 - _x + 1 + assert imageset(_x, eq, S.Integers).lamda.expr == _x**2 + _x + 1 + eq = 3*_x - 1 + assert imageset(_x, eq, S.Integers).lamda.expr == 3*_x + 2 + + assert imageset(x, (x, 1/x), S.Integers) == \ + ImageSet(Lambda(x, (x, 1/x)), S.Integers) + + +def test_Range_eval_imageset(): + a, b, c = symbols('a b c') + assert imageset(x, a*(x + b) + c, Range(3)) == \ + imageset(x, a*x + a*b + c, Range(3)) + eq = (x + 1)**2 + assert imageset(x, eq, Range(3)).lamda.expr == eq + eq = a*(x + b) + c + r = Range(3, -3, -2) + imset = imageset(x, eq, r) + assert imset.lamda.expr != eq + assert list(imset) == [eq.subs(x, i).expand() for i in list(r)] + + +def test_fun(): + assert (FiniteSet(*ImageSet(Lambda(x, sin(pi*x/4)), + Range(-10, 11))) == FiniteSet(-1, -sqrt(2)/2, 0, sqrt(2)/2, 1)) + + +def test_Range_is_empty(): + i = Symbol('i', integer=True) + n = Symbol('n', negative=True, integer=True) + p = Symbol('p', positive=True, integer=True) + + assert Range(0).is_empty + assert not Range(1).is_empty + assert Range(1, 0).is_empty + assert not Range(-1, 0).is_empty + assert Range(i).is_empty is None + assert Range(n).is_empty + assert Range(p).is_empty is False + assert Range(n, 0).is_empty is False + assert Range(n, p).is_empty is False + assert Range(p, n).is_empty + assert Range(n, -1).is_empty is None + assert Range(p, n, -1).is_empty is False + + +def test_Reals(): + assert 5 in S.Reals + assert S.Pi in S.Reals + assert -sqrt(2) in S.Reals + assert (2, 5) not in S.Reals + assert sqrt(-1) not in S.Reals + assert S.Reals == Interval(-oo, oo) + assert S.Reals != Interval(0, oo) + assert S.Reals.is_subset(Interval(-oo, oo)) + assert S.Reals.intersect(Range(-oo, oo)) == Range(-oo, oo) + assert S.ComplexInfinity not in S.Reals + assert S.NaN not in S.Reals + assert x + S.ComplexInfinity not in S.Reals + + +def test_Complex(): + assert 5 in S.Complexes + assert 5 + 4*I in S.Complexes + assert S.Pi in S.Complexes + assert -sqrt(2) in S.Complexes + assert -I in S.Complexes + assert sqrt(-1) in S.Complexes + assert S.Complexes.intersect(S.Reals) == S.Reals + assert S.Complexes.union(S.Reals) == S.Complexes + assert S.Complexes == ComplexRegion(S.Reals*S.Reals) + assert (S.Complexes == ComplexRegion(Interval(1, 2)*Interval(3, 4))) == False + assert str(S.Complexes) == "Complexes" + assert repr(S.Complexes) == "Complexes" + + +def take(n, iterable): + "Return first n items of the iterable as a list" + return list(itertools.islice(iterable, n)) + + +def test_intersections(): + assert S.Integers.intersect(S.Reals) == S.Integers + assert 5 in S.Integers.intersect(S.Reals) + assert 5 in S.Integers.intersect(S.Reals) + assert -5 not in S.Naturals.intersect(S.Reals) + assert 5.5 not in S.Integers.intersect(S.Reals) + assert 5 in S.Integers.intersect(Interval(3, oo)) + assert -5 in S.Integers.intersect(Interval(-oo, 3)) + assert all(x.is_Integer + for x in take(10, S.Integers.intersect(Interval(3, oo)) )) + + +def test_infinitely_indexed_set_1(): + from sympy.abc import n, m + assert imageset(Lambda(n, n), S.Integers) == imageset(Lambda(m, m), S.Integers) + + assert imageset(Lambda(n, 2*n), S.Integers).intersect( + imageset(Lambda(m, 2*m + 1), S.Integers)) is S.EmptySet + + assert imageset(Lambda(n, 2*n), S.Integers).intersect( + imageset(Lambda(n, 2*n + 1), S.Integers)) is S.EmptySet + + assert imageset(Lambda(m, 2*m), S.Integers).intersect( + imageset(Lambda(n, 3*n), S.Integers)).dummy_eq( + ImageSet(Lambda(t, 6*t), S.Integers)) + + assert imageset(x, x/2 + Rational(1, 3), S.Integers).intersect(S.Integers) is S.EmptySet + assert imageset(x, x/2 + S.Half, S.Integers).intersect(S.Integers) is S.Integers + + # https://github.com/sympy/sympy/issues/17355 + S53 = ImageSet(Lambda(n, 5*n + 3), S.Integers) + assert S53.intersect(S.Integers) == S53 + + +def test_infinitely_indexed_set_2(): + from sympy.abc import n + a = Symbol('a', integer=True) + assert imageset(Lambda(n, n), S.Integers) == \ + imageset(Lambda(n, n + a), S.Integers) + assert imageset(Lambda(n, n + pi), S.Integers) == \ + imageset(Lambda(n, n + a + pi), S.Integers) + assert imageset(Lambda(n, n), S.Integers) == \ + imageset(Lambda(n, -n + a), S.Integers) + assert imageset(Lambda(n, -6*n), S.Integers) == \ + ImageSet(Lambda(n, 6*n), S.Integers) + assert imageset(Lambda(n, 2*n + pi), S.Integers) == \ + ImageSet(Lambda(n, 2*n + pi - 2), S.Integers) + + +def test_imageset_intersect_real(): + from sympy.abc import n + assert imageset(Lambda(n, n + (n - 1)*(n + 1)*I), S.Integers).intersect(S.Reals) == FiniteSet(-1, 1) + im = (n - 1)*(n + S.Half) + assert imageset(Lambda(n, n + im*I), S.Integers + ).intersect(S.Reals) == FiniteSet(1) + assert imageset(Lambda(n, n + im*(n + 1)*I), S.Naturals0 + ).intersect(S.Reals) == FiniteSet(1) + assert imageset(Lambda(n, n/2 + im.expand()*I), S.Integers + ).intersect(S.Reals) == ImageSet(Lambda(x, x/2), ConditionSet( + n, Eq(n**2 - n/2 - S(1)/2, 0), S.Integers)) + assert imageset(Lambda(n, n/(1/n - 1) + im*(n + 1)*I), S.Integers + ).intersect(S.Reals) == FiniteSet(S.Half) + assert imageset(Lambda(n, n/(n - 6) + + (n - 3)*(n + 1)*I/(2*n + 2)), S.Integers).intersect( + S.Reals) == FiniteSet(-1) + assert imageset(Lambda(n, n/(n**2 - 9) + + (n - 3)*(n + 1)*I/(2*n + 2)), S.Integers).intersect( + S.Reals) is S.EmptySet + s = ImageSet( + Lambda(n, -I*(I*(2*pi*n - pi/4) + log(Abs(sqrt(-I))))), + S.Integers) + # s is unevaluated, but after intersection the result + # should be canonical + assert s.intersect(S.Reals) == imageset( + Lambda(n, 2*n*pi - pi/4), S.Integers) == ImageSet( + Lambda(n, 2*pi*n + pi*Rational(7, 4)), S.Integers) + + +def test_imageset_intersect_interval(): + from sympy.abc import n + f1 = ImageSet(Lambda(n, n*pi), S.Integers) + f2 = ImageSet(Lambda(n, 2*n), Interval(0, pi)) + f3 = ImageSet(Lambda(n, 2*n*pi + pi/2), S.Integers) + # complex expressions + f4 = ImageSet(Lambda(n, n*I*pi), S.Integers) + f5 = ImageSet(Lambda(n, 2*I*n*pi + pi/2), S.Integers) + # non-linear expressions + f6 = ImageSet(Lambda(n, log(n)), S.Integers) + f7 = ImageSet(Lambda(n, n**2), S.Integers) + f8 = ImageSet(Lambda(n, Abs(n)), S.Integers) + f9 = ImageSet(Lambda(n, exp(n)), S.Naturals0) + + assert f1.intersect(Interval(-1, 1)) == FiniteSet(0) + assert f1.intersect(Interval(0, 2*pi, False, True)) == FiniteSet(0, pi) + assert f2.intersect(Interval(1, 2)) == Interval(1, 2) + assert f3.intersect(Interval(-1, 1)) == S.EmptySet + assert f3.intersect(Interval(-5, 5)) == FiniteSet(pi*Rational(-3, 2), pi/2) + assert f4.intersect(Interval(-1, 1)) == FiniteSet(0) + assert f4.intersect(Interval(1, 2)) == S.EmptySet + assert f5.intersect(Interval(0, 1)) == S.EmptySet + assert f6.intersect(Interval(0, 1)) == FiniteSet(S.Zero, log(2)) + assert f7.intersect(Interval(0, 10)) == Intersection(f7, Interval(0, 10)) + assert f8.intersect(Interval(0, 2)) == Intersection(f8, Interval(0, 2)) + assert f9.intersect(Interval(1, 2)) == Intersection(f9, Interval(1, 2)) + + +def test_imageset_intersect_diophantine(): + from sympy.abc import m, n + # Check that same lambda variable for both ImageSets is handled correctly + img1 = ImageSet(Lambda(n, 2*n + 1), S.Integers) + img2 = ImageSet(Lambda(n, 4*n + 1), S.Integers) + assert img1.intersect(img2) == img2 + # Empty solution set returned by diophantine: + assert ImageSet(Lambda(n, 2*n), S.Integers).intersect( + ImageSet(Lambda(n, 2*n + 1), S.Integers)) == S.EmptySet + # Check intersection with S.Integers: + assert ImageSet(Lambda(n, 9/n + 20*n/3), S.Integers).intersect( + S.Integers) == FiniteSet(-61, -23, 23, 61) + # Single solution (2, 3) for diophantine solution: + assert ImageSet(Lambda(n, (n - 2)**2), S.Integers).intersect( + ImageSet(Lambda(n, -(n - 3)**2), S.Integers)) == FiniteSet(0) + # Single parametric solution for diophantine solution: + assert ImageSet(Lambda(n, n**2 + 5), S.Integers).intersect( + ImageSet(Lambda(m, 2*m), S.Integers)).dummy_eq(ImageSet( + Lambda(n, 4*n**2 + 4*n + 6), S.Integers)) + # 4 non-parametric solution couples for dioph. equation: + assert ImageSet(Lambda(n, n**2 - 9), S.Integers).intersect( + ImageSet(Lambda(m, -m**2), S.Integers)) == FiniteSet(-9, 0) + # Double parametric solution for diophantine solution: + assert ImageSet(Lambda(m, m**2 + 40), S.Integers).intersect( + ImageSet(Lambda(n, 41*n), S.Integers)).dummy_eq(Intersection( + ImageSet(Lambda(m, m**2 + 40), S.Integers), + ImageSet(Lambda(n, 41*n), S.Integers))) + # Check that diophantine returns *all* (8) solutions (permute=True) + assert ImageSet(Lambda(n, n**4 - 2**4), S.Integers).intersect( + ImageSet(Lambda(m, -m**4 + 3**4), S.Integers)) == FiniteSet(0, 65) + assert ImageSet(Lambda(n, pi/12 + n*5*pi/12), S.Integers).intersect( + ImageSet(Lambda(n, 7*pi/12 + n*11*pi/12), S.Integers)).dummy_eq(ImageSet( + Lambda(n, 55*pi*n/12 + 17*pi/4), S.Integers)) + # TypeError raised by diophantine (#18081) + assert ImageSet(Lambda(n, n*log(2)), S.Integers).intersection( + S.Integers).dummy_eq(Intersection(ImageSet( + Lambda(n, n*log(2)), S.Integers), S.Integers)) + # NotImplementedError raised by diophantine (no solver for cubic_thue) + assert ImageSet(Lambda(n, n**3 + 1), S.Integers).intersect( + ImageSet(Lambda(n, n**3), S.Integers)).dummy_eq(Intersection( + ImageSet(Lambda(n, n**3 + 1), S.Integers), + ImageSet(Lambda(n, n**3), S.Integers))) + + +def test_infinitely_indexed_set_3(): + from sympy.abc import n, m + assert imageset(Lambda(m, 2*pi*m), S.Integers).intersect( + imageset(Lambda(n, 3*pi*n), S.Integers)).dummy_eq( + ImageSet(Lambda(t, 6*pi*t), S.Integers)) + assert imageset(Lambda(n, 2*n + 1), S.Integers) == \ + imageset(Lambda(n, 2*n - 1), S.Integers) + assert imageset(Lambda(n, 3*n + 2), S.Integers) == \ + imageset(Lambda(n, 3*n - 1), S.Integers) + + +def test_ImageSet_simplification(): + from sympy.abc import n, m + assert imageset(Lambda(n, n), S.Integers) == S.Integers + assert imageset(Lambda(n, sin(n)), + imageset(Lambda(m, tan(m)), S.Integers)) == \ + imageset(Lambda(m, sin(tan(m))), S.Integers) + assert imageset(n, 1 + 2*n, S.Naturals) == Range(3, oo, 2) + assert imageset(n, 1 + 2*n, S.Naturals0) == Range(1, oo, 2) + assert imageset(n, 1 - 2*n, S.Naturals) == Range(-1, -oo, -2) + + +def test_ImageSet_contains(): + assert (2, S.Half) in imageset(x, (x, 1/x), S.Integers) + assert imageset(x, x + I*3, S.Integers).intersection(S.Reals) is S.EmptySet + i = Dummy(integer=True) + q = imageset(x, x + I*y, S.Integers).intersection(S.Reals) + assert q.subs(y, I*i).intersection(S.Integers) is S.Integers + q = imageset(x, x + I*y/x, S.Integers).intersection(S.Reals) + assert q.subs(y, 0) is S.Integers + assert q.subs(y, I*i*x).intersection(S.Integers) is S.Integers + z = cos(1)**2 + sin(1)**2 - 1 + q = imageset(x, x + I*z, S.Integers).intersection(S.Reals) + assert q is not S.EmptySet + + +def test_ComplexRegion_contains(): + r = Symbol('r', real=True) + # contains in ComplexRegion + a = Interval(2, 3) + b = Interval(4, 6) + c = Interval(7, 9) + c1 = ComplexRegion(a*b) + c2 = ComplexRegion(Union(a*b, c*a)) + assert 2.5 + 4.5*I in c1 + assert 2 + 4*I in c1 + assert 3 + 4*I in c1 + assert 8 + 2.5*I in c2 + assert 2.5 + 6.1*I not in c1 + assert 4.5 + 3.2*I not in c1 + assert c1.contains(x) == Contains(x, c1, evaluate=False) + assert c1.contains(r) == False + assert c2.contains(x) == Contains(x, c2, evaluate=False) + assert c2.contains(r) == False + + r1 = Interval(0, 1) + theta1 = Interval(0, 2*S.Pi) + c3 = ComplexRegion(r1*theta1, polar=True) + assert (0.5 + I*6/10) in c3 + assert (S.Half + I*6/10) in c3 + assert (S.Half + .6*I) in c3 + assert (0.5 + .6*I) in c3 + assert I in c3 + assert 1 in c3 + assert 0 in c3 + assert 1 + I not in c3 + assert 1 - I not in c3 + assert c3.contains(x) == Contains(x, c3, evaluate=False) + assert c3.contains(r + 2*I) == Contains( + r + 2*I, c3, evaluate=False) # is in fact False + assert c3.contains(1/(1 + r**2)) == Contains( + 1/(1 + r**2), c3, evaluate=False) # is in fact True + + r2 = Interval(0, 3) + theta2 = Interval(pi, 2*pi, left_open=True) + c4 = ComplexRegion(r2*theta2, polar=True) + assert c4.contains(0) == True + assert c4.contains(2 + I) == False + assert c4.contains(-2 + I) == False + assert c4.contains(-2 - I) == True + assert c4.contains(2 - I) == True + assert c4.contains(-2) == False + assert c4.contains(2) == True + assert c4.contains(x) == Contains(x, c4, evaluate=False) + assert c4.contains(3/(1 + r**2)) == Contains( + 3/(1 + r**2), c4, evaluate=False) # is in fact True + + raises(ValueError, lambda: ComplexRegion(r1*theta1, polar=2)) + + +def test_symbolic_Range(): + n = Symbol('n') + raises(ValueError, lambda: Range(n)[0]) + raises(IndexError, lambda: Range(n, n)[0]) + raises(ValueError, lambda: Range(n, n+1)[0]) + raises(ValueError, lambda: Range(n).size) + + n = Symbol('n', integer=True) + raises(ValueError, lambda: Range(n)[0]) + raises(IndexError, lambda: Range(n, n)[0]) + assert Range(n, n+1)[0] == n + raises(ValueError, lambda: Range(n).size) + assert Range(n, n+1).size == 1 + + n = Symbol('n', integer=True, nonnegative=True) + raises(ValueError, lambda: Range(n)[0]) + raises(IndexError, lambda: Range(n, n)[0]) + assert Range(n+1)[0] == 0 + assert Range(n, n+1)[0] == n + assert Range(n).size == n + assert Range(n+1).size == n+1 + assert Range(n, n+1).size == 1 + + n = Symbol('n', integer=True, positive=True) + assert Range(n)[0] == 0 + assert Range(n, n+1)[0] == n + assert Range(n).size == n + assert Range(n, n+1).size == 1 + + m = Symbol('m', integer=True, positive=True) + + assert Range(n, n+m)[0] == n + assert Range(n, n+m).size == m + assert Range(n, n+1).size == 1 + assert Range(n, n+m, 2).size == floor(m/2) + + m = Symbol('m', integer=True, positive=True, even=True) + assert Range(n, n+m, 2).size == m/2 + + +def test_issue_18400(): + n = Symbol('n', integer=True) + raises(ValueError, lambda: imageset(lambda x: x*2, Range(n))) + + n = Symbol('n', integer=True, positive=True) + # No exception + assert imageset(lambda x: x*2, Range(n)) == imageset(lambda x: x*2, Range(n)) + + +def test_ComplexRegion_intersect(): + # Polar form + X_axis = ComplexRegion(Interval(0, oo)*FiniteSet(0, S.Pi), polar=True) + + unit_disk = ComplexRegion(Interval(0, 1)*Interval(0, 2*S.Pi), polar=True) + upper_half_unit_disk = ComplexRegion(Interval(0, 1)*Interval(0, S.Pi), polar=True) + upper_half_disk = ComplexRegion(Interval(0, oo)*Interval(0, S.Pi), polar=True) + lower_half_disk = ComplexRegion(Interval(0, oo)*Interval(S.Pi, 2*S.Pi), polar=True) + right_half_disk = ComplexRegion(Interval(0, oo)*Interval(-S.Pi/2, S.Pi/2), polar=True) + first_quad_disk = ComplexRegion(Interval(0, oo)*Interval(0, S.Pi/2), polar=True) + + assert upper_half_disk.intersect(unit_disk) == upper_half_unit_disk + assert right_half_disk.intersect(first_quad_disk) == first_quad_disk + assert upper_half_disk.intersect(right_half_disk) == first_quad_disk + assert upper_half_disk.intersect(lower_half_disk) == X_axis + + c1 = ComplexRegion(Interval(0, 4)*Interval(0, 2*S.Pi), polar=True) + assert c1.intersect(Interval(1, 5)) == Interval(1, 4) + assert c1.intersect(Interval(4, 9)) == FiniteSet(4) + assert c1.intersect(Interval(5, 12)) is S.EmptySet + + # Rectangular form + X_axis = ComplexRegion(Interval(-oo, oo)*FiniteSet(0)) + + unit_square = ComplexRegion(Interval(-1, 1)*Interval(-1, 1)) + upper_half_unit_square = ComplexRegion(Interval(-1, 1)*Interval(0, 1)) + upper_half_plane = ComplexRegion(Interval(-oo, oo)*Interval(0, oo)) + lower_half_plane = ComplexRegion(Interval(-oo, oo)*Interval(-oo, 0)) + right_half_plane = ComplexRegion(Interval(0, oo)*Interval(-oo, oo)) + first_quad_plane = ComplexRegion(Interval(0, oo)*Interval(0, oo)) + + assert upper_half_plane.intersect(unit_square) == upper_half_unit_square + assert right_half_plane.intersect(first_quad_plane) == first_quad_plane + assert upper_half_plane.intersect(right_half_plane) == first_quad_plane + assert upper_half_plane.intersect(lower_half_plane) == X_axis + + c1 = ComplexRegion(Interval(-5, 5)*Interval(-10, 10)) + assert c1.intersect(Interval(2, 7)) == Interval(2, 5) + assert c1.intersect(Interval(5, 7)) == FiniteSet(5) + assert c1.intersect(Interval(6, 9)) is S.EmptySet + + # unevaluated object + C1 = ComplexRegion(Interval(0, 1)*Interval(0, 2*S.Pi), polar=True) + C2 = ComplexRegion(Interval(-1, 1)*Interval(-1, 1)) + assert C1.intersect(C2) == Intersection(C1, C2, evaluate=False) + + +def test_ComplexRegion_union(): + # Polar form + c1 = ComplexRegion(Interval(0, 1)*Interval(0, 2*S.Pi), polar=True) + c2 = ComplexRegion(Interval(0, 1)*Interval(0, S.Pi), polar=True) + c3 = ComplexRegion(Interval(0, oo)*Interval(0, S.Pi), polar=True) + c4 = ComplexRegion(Interval(0, oo)*Interval(S.Pi, 2*S.Pi), polar=True) + + p1 = Union(Interval(0, 1)*Interval(0, 2*S.Pi), Interval(0, 1)*Interval(0, S.Pi)) + p2 = Union(Interval(0, oo)*Interval(0, S.Pi), Interval(0, oo)*Interval(S.Pi, 2*S.Pi)) + + assert c1.union(c2) == ComplexRegion(p1, polar=True) + assert c3.union(c4) == ComplexRegion(p2, polar=True) + + # Rectangular form + c5 = ComplexRegion(Interval(2, 5)*Interval(6, 9)) + c6 = ComplexRegion(Interval(4, 6)*Interval(10, 12)) + c7 = ComplexRegion(Interval(0, 10)*Interval(-10, 0)) + c8 = ComplexRegion(Interval(12, 16)*Interval(14, 20)) + + p3 = Union(Interval(2, 5)*Interval(6, 9), Interval(4, 6)*Interval(10, 12)) + p4 = Union(Interval(0, 10)*Interval(-10, 0), Interval(12, 16)*Interval(14, 20)) + + assert c5.union(c6) == ComplexRegion(p3) + assert c7.union(c8) == ComplexRegion(p4) + + assert c1.union(Interval(2, 4)) == Union(c1, Interval(2, 4), evaluate=False) + assert c5.union(Interval(2, 4)) == Union(c5, ComplexRegion.from_real(Interval(2, 4))) + + +def test_ComplexRegion_from_real(): + c1 = ComplexRegion(Interval(0, 1) * Interval(0, 2 * S.Pi), polar=True) + + raises(ValueError, lambda: c1.from_real(c1)) + assert c1.from_real(Interval(-1, 1)) == ComplexRegion(Interval(-1, 1) * FiniteSet(0), False) + + +def test_ComplexRegion_measure(): + a, b = Interval(2, 5), Interval(4, 8) + theta1, theta2 = Interval(0, 2*S.Pi), Interval(0, S.Pi) + c1 = ComplexRegion(a*b) + c2 = ComplexRegion(Union(a*theta1, b*theta2), polar=True) + + assert c1.measure == 12 + assert c2.measure == 9*pi + + +def test_normalize_theta_set(): + # Interval + assert normalize_theta_set(Interval(pi, 2*pi)) == \ + Union(FiniteSet(0), Interval.Ropen(pi, 2*pi)) + assert normalize_theta_set(Interval(pi*Rational(9, 2), 5*pi)) == Interval(pi/2, pi) + assert normalize_theta_set(Interval(pi*Rational(-3, 2), pi/2)) == Interval.Ropen(0, 2*pi) + assert normalize_theta_set(Interval.open(pi*Rational(-3, 2), pi/2)) == \ + Union(Interval.Ropen(0, pi/2), Interval.open(pi/2, 2*pi)) + assert normalize_theta_set(Interval.open(pi*Rational(-7, 2), pi*Rational(-3, 2))) == \ + Union(Interval.Ropen(0, pi/2), Interval.open(pi/2, 2*pi)) + assert normalize_theta_set(Interval(-pi/2, pi/2)) == \ + Union(Interval(0, pi/2), Interval.Ropen(pi*Rational(3, 2), 2*pi)) + assert normalize_theta_set(Interval.open(-pi/2, pi/2)) == \ + Union(Interval.Ropen(0, pi/2), Interval.open(pi*Rational(3, 2), 2*pi)) + assert normalize_theta_set(Interval(-4*pi, 3*pi)) == Interval.Ropen(0, 2*pi) + assert normalize_theta_set(Interval(pi*Rational(-3, 2), -pi/2)) == Interval(pi/2, pi*Rational(3, 2)) + assert normalize_theta_set(Interval.open(0, 2*pi)) == Interval.open(0, 2*pi) + assert normalize_theta_set(Interval.Ropen(-pi/2, pi/2)) == \ + Union(Interval.Ropen(0, pi/2), Interval.Ropen(pi*Rational(3, 2), 2*pi)) + assert normalize_theta_set(Interval.Lopen(-pi/2, pi/2)) == \ + Union(Interval(0, pi/2), Interval.open(pi*Rational(3, 2), 2*pi)) + assert normalize_theta_set(Interval(-pi/2, pi/2)) == \ + Union(Interval(0, pi/2), Interval.Ropen(pi*Rational(3, 2), 2*pi)) + assert normalize_theta_set(Interval.open(4*pi, pi*Rational(9, 2))) == Interval.open(0, pi/2) + assert normalize_theta_set(Interval.Lopen(4*pi, pi*Rational(9, 2))) == Interval.Lopen(0, pi/2) + assert normalize_theta_set(Interval.Ropen(4*pi, pi*Rational(9, 2))) == Interval.Ropen(0, pi/2) + assert normalize_theta_set(Interval.open(3*pi, 5*pi)) == \ + Union(Interval.Ropen(0, pi), Interval.open(pi, 2*pi)) + + # FiniteSet + assert normalize_theta_set(FiniteSet(0, pi, 3*pi)) == FiniteSet(0, pi) + assert normalize_theta_set(FiniteSet(0, pi/2, pi, 2*pi)) == FiniteSet(0, pi/2, pi) + assert normalize_theta_set(FiniteSet(0, -pi/2, -pi, -2*pi)) == FiniteSet(0, pi, pi*Rational(3, 2)) + assert normalize_theta_set(FiniteSet(pi*Rational(-3, 2), pi/2)) == \ + FiniteSet(pi/2) + assert normalize_theta_set(FiniteSet(2*pi)) == FiniteSet(0) + + # Unions + assert normalize_theta_set(Union(Interval(0, pi/3), Interval(pi/2, pi))) == \ + Union(Interval(0, pi/3), Interval(pi/2, pi)) + assert normalize_theta_set(Union(Interval(0, pi), Interval(2*pi, pi*Rational(7, 3)))) == \ + Interval(0, pi) + + # ValueError for non-real sets + raises(ValueError, lambda: normalize_theta_set(S.Complexes)) + + # NotImplementedError for subset of reals + raises(NotImplementedError, lambda: normalize_theta_set(Interval(0, 1))) + + # NotImplementedError without pi as coefficient + raises(NotImplementedError, lambda: normalize_theta_set(Interval(1, 2*pi))) + raises(NotImplementedError, lambda: normalize_theta_set(Interval(2*pi, 10))) + raises(NotImplementedError, lambda: normalize_theta_set(FiniteSet(0, 3, 3*pi))) + + +def test_ComplexRegion_FiniteSet(): + x, y, z, a, b, c = symbols('x y z a b c') + + # Issue #9669 + assert ComplexRegion(FiniteSet(a, b, c)*FiniteSet(x, y, z)) == \ + FiniteSet(a + I*x, a + I*y, a + I*z, b + I*x, b + I*y, + b + I*z, c + I*x, c + I*y, c + I*z) + assert ComplexRegion(FiniteSet(2)*FiniteSet(3)) == FiniteSet(2 + 3*I) + + +def test_union_RealSubSet(): + assert (S.Complexes).union(Interval(1, 2)) == S.Complexes + assert (S.Complexes).union(S.Integers) == S.Complexes + + +def test_SetKind_fancySet(): + G = lambda *args: ImageSet(Lambda(x, x ** 2), *args) + assert G(Interval(1, 4)).kind is SetKind(NumberKind) + assert G(FiniteSet(1, 4)).kind is SetKind(NumberKind) + assert S.Rationals.kind is SetKind(NumberKind) + assert S.Naturals.kind is SetKind(NumberKind) + assert S.Integers.kind is SetKind(NumberKind) + assert Range(3).kind is SetKind(NumberKind) + a = Interval(2, 3) + b = Interval(4, 6) + c1 = ComplexRegion(a*b) + assert c1.kind is SetKind(TupleKind(NumberKind, NumberKind)) + + +def test_issue_9980(): + c1 = ComplexRegion(Interval(1, 2)*Interval(2, 3)) + c2 = ComplexRegion(Interval(1, 5)*Interval(1, 3)) + R = Union(c1, c2) + assert simplify(R) == ComplexRegion(Union(Interval(1, 2)*Interval(2, 3), \ + Interval(1, 5)*Interval(1, 3)), False) + assert c1.func(*c1.args) == c1 + assert R.func(*R.args) == R + + +def test_issue_11732(): + interval12 = Interval(1, 2) + finiteset1234 = FiniteSet(1, 2, 3, 4) + pointComplex = Tuple(1, 5) + + assert (interval12 in S.Naturals) == False + assert (interval12 in S.Naturals0) == False + assert (interval12 in S.Integers) == False + assert (interval12 in S.Complexes) == False + + assert (finiteset1234 in S.Naturals) == False + assert (finiteset1234 in S.Naturals0) == False + assert (finiteset1234 in S.Integers) == False + assert (finiteset1234 in S.Complexes) == False + + assert (pointComplex in S.Naturals) == False + assert (pointComplex in S.Naturals0) == False + assert (pointComplex in S.Integers) == False + assert (pointComplex in S.Complexes) == True + + +def test_issue_11730(): + unit = Interval(0, 1) + square = ComplexRegion(unit ** 2) + + assert Union(S.Complexes, FiniteSet(oo)) != S.Complexes + assert Union(S.Complexes, FiniteSet(eye(4))) != S.Complexes + assert Union(unit, square) == square + assert Intersection(S.Reals, square) == unit + + +def test_issue_11938(): + unit = Interval(0, 1) + ival = Interval(1, 2) + cr1 = ComplexRegion(ival * unit) + + assert Intersection(cr1, S.Reals) == ival + assert Intersection(cr1, unit) == FiniteSet(1) + + arg1 = Interval(0, S.Pi) + arg2 = FiniteSet(S.Pi) + arg3 = Interval(S.Pi / 4, 3 * S.Pi / 4) + cp1 = ComplexRegion(unit * arg1, polar=True) + cp2 = ComplexRegion(unit * arg2, polar=True) + cp3 = ComplexRegion(unit * arg3, polar=True) + + assert Intersection(cp1, S.Reals) == Interval(-1, 1) + assert Intersection(cp2, S.Reals) == Interval(-1, 0) + assert Intersection(cp3, S.Reals) == FiniteSet(0) + + +def test_issue_11914(): + a, b = Interval(0, 1), Interval(0, pi) + c, d = Interval(2, 3), Interval(pi, 3 * pi / 2) + cp1 = ComplexRegion(a * b, polar=True) + cp2 = ComplexRegion(c * d, polar=True) + + assert -3 in cp1.union(cp2) + assert -3 in cp2.union(cp1) + assert -5 not in cp1.union(cp2) + + +def test_issue_9543(): + assert ImageSet(Lambda(x, x**2), S.Naturals).is_subset(S.Reals) + + +def test_issue_16871(): + assert ImageSet(Lambda(x, x), FiniteSet(1)) == {1} + assert ImageSet(Lambda(x, x - 3), S.Integers + ).intersection(S.Integers) is S.Integers + + +@XFAIL +def test_issue_16871b(): + assert ImageSet(Lambda(x, x - 3), S.Integers).is_subset(S.Integers) + + +def test_issue_18050(): + assert imageset(Lambda(x, I*x + 1), S.Integers + ) == ImageSet(Lambda(x, I*x + 1), S.Integers) + assert imageset(Lambda(x, 3*I*x + 4 + 8*I), S.Integers + ) == ImageSet(Lambda(x, 3*I*x + 4 + 2*I), S.Integers) + # no 'Mod' for next 2 tests: + assert imageset(Lambda(x, 2*x + 3*I), S.Integers + ) == ImageSet(Lambda(x, 2*x + 3*I), S.Integers) + r = Symbol('r', positive=True) + assert imageset(Lambda(x, r*x + 10), S.Integers + ) == ImageSet(Lambda(x, r*x + 10), S.Integers) + # reduce real part: + assert imageset(Lambda(x, 3*x + 8 + 5*I), S.Integers + ) == ImageSet(Lambda(x, 3*x + 2 + 5*I), S.Integers) + + +def test_Rationals(): + assert S.Integers.is_subset(S.Rationals) + assert S.Naturals.is_subset(S.Rationals) + assert S.Naturals0.is_subset(S.Rationals) + assert S.Rationals.is_subset(S.Reals) + assert S.Rationals.inf is -oo + assert S.Rationals.sup is oo + it = iter(S.Rationals) + assert [next(it) for i in range(12)] == [ + 0, 1, -1, S.Half, 2, Rational(-1, 2), -2, + Rational(1, 3), 3, Rational(-1, 3), -3, Rational(2, 3)] + assert Basic() not in S.Rationals + assert S.Half in S.Rationals + assert S.Rationals.contains(0.5) == Contains( + 0.5, S.Rationals, evaluate=False) + assert 2 in S.Rationals + r = symbols('r', rational=True) + assert r in S.Rationals + raises(TypeError, lambda: x in S.Rationals) + # issue #18134: + assert S.Rationals.boundary == S.Reals + assert S.Rationals.closure == S.Reals + assert S.Rationals.is_open == False + assert S.Rationals.is_closed == False + + +def test_NZQRC_unions(): + # check that all trivial number set unions are simplified: + nbrsets = (S.Naturals, S.Naturals0, S.Integers, S.Rationals, + S.Reals, S.Complexes) + unions = (Union(a, b) for a in nbrsets for b in nbrsets) + assert all(u.is_Union is False for u in unions) + + +def test_imageset_intersection(): + n = Dummy() + s = ImageSet(Lambda(n, -I*(I*(2*pi*n - pi/4) + + log(Abs(sqrt(-I))))), S.Integers) + assert s.intersect(S.Reals) == ImageSet( + Lambda(n, 2*pi*n + pi*Rational(7, 4)), S.Integers) + + +def test_issue_17858(): + assert 1 in Range(-oo, oo) + assert 0 in Range(oo, -oo, -1) + assert oo not in Range(-oo, oo) + assert -oo not in Range(-oo, oo) + +def test_issue_17859(): + r = Range(-oo,oo) + raises(ValueError,lambda: r[::2]) + raises(ValueError, lambda: r[::-2]) + r = Range(oo,-oo,-1) + raises(ValueError,lambda: r[::2]) + raises(ValueError, lambda: r[::-2]) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_ordinals.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_ordinals.py new file mode 100644 index 0000000000000000000000000000000000000000..973ca329586f3e904f9377c44022c266f81c805c --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_ordinals.py @@ -0,0 +1,67 @@ +from sympy.sets.ordinals import Ordinal, OmegaPower, ord0, omega +from sympy.testing.pytest import raises + +def test_string_ordinals(): + assert str(omega) == 'w' + assert str(Ordinal(OmegaPower(5, 3), OmegaPower(3, 2))) == 'w**5*3 + w**3*2' + assert str(Ordinal(OmegaPower(5, 3), OmegaPower(0, 5))) == 'w**5*3 + 5' + assert str(Ordinal(OmegaPower(1, 3), OmegaPower(0, 5))) == 'w*3 + 5' + assert str(Ordinal(OmegaPower(omega + 1, 1), OmegaPower(3, 2))) == 'w**(w + 1) + w**3*2' + +def test_addition_with_integers(): + assert 3 + Ordinal(OmegaPower(5, 3)) == Ordinal(OmegaPower(5, 3)) + assert Ordinal(OmegaPower(5, 3))+3 == Ordinal(OmegaPower(5, 3), OmegaPower(0, 3)) + assert Ordinal(OmegaPower(5, 3), OmegaPower(0, 2))+3 == \ + Ordinal(OmegaPower(5, 3), OmegaPower(0, 5)) + + +def test_addition_with_ordinals(): + assert Ordinal(OmegaPower(5, 3), OmegaPower(3, 2)) + Ordinal(OmegaPower(3, 3)) == \ + Ordinal(OmegaPower(5, 3), OmegaPower(3, 5)) + assert Ordinal(OmegaPower(5, 3), OmegaPower(3, 2)) + Ordinal(OmegaPower(4, 2)) == \ + Ordinal(OmegaPower(5, 3), OmegaPower(4, 2)) + assert Ordinal(OmegaPower(omega, 2), OmegaPower(3, 2)) + Ordinal(OmegaPower(4, 2)) == \ + Ordinal(OmegaPower(omega, 2), OmegaPower(4, 2)) + +def test_comparison(): + assert Ordinal(OmegaPower(5, 3)) > Ordinal(OmegaPower(4, 3), OmegaPower(2, 1)) + assert Ordinal(OmegaPower(5, 3), OmegaPower(3, 2)) < Ordinal(OmegaPower(5, 4)) + assert Ordinal(OmegaPower(5, 4)) < Ordinal(OmegaPower(5, 5), OmegaPower(4, 1)) + + assert Ordinal(OmegaPower(5, 3), OmegaPower(3, 2)) == \ + Ordinal(OmegaPower(5, 3), OmegaPower(3, 2)) + assert not Ordinal(OmegaPower(5, 3), OmegaPower(3, 2)) == Ordinal(OmegaPower(5, 3)) + assert Ordinal(OmegaPower(omega, 3)) > Ordinal(OmegaPower(5, 3)) + +def test_multiplication_with_integers(): + w = omega + assert 3*w == w + assert w*9 == Ordinal(OmegaPower(1, 9)) + +def test_multiplication(): + w = omega + assert w*(w + 1) == w*w + w + assert (w + 1)*(w + 1) == w*w + w + 1 + assert w*1 == w + assert 1*w == w + assert w*ord0 == ord0 + assert ord0*w == ord0 + assert w**w == w * w**w + assert (w**w)*w*w == w**(w + 2) + +def test_exponentiation(): + w = omega + assert w**2 == w*w + assert w**3 == w*w*w + assert w**(w + 1) == Ordinal(OmegaPower(omega + 1, 1)) + assert (w**w)*(w**w) == w**(w*2) + +def test_comapre_not_instance(): + w = OmegaPower(omega + 1, 1) + assert(not (w == None)) + assert(not (w < 5)) + raises(TypeError, lambda: w < 6.66) + +def test_is_successort(): + w = Ordinal(OmegaPower(5, 1)) + assert not w.is_successor_ordinal diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_powerset.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_powerset.py new file mode 100644 index 0000000000000000000000000000000000000000..2e3a407d565f6b9537a296af103ec0a4e137cff9 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_powerset.py @@ -0,0 +1,141 @@ +from sympy.core.expr import unchanged +from sympy.core.singleton import S +from sympy.core.symbol import Symbol +from sympy.sets.contains import Contains +from sympy.sets.fancysets import Interval +from sympy.sets.powerset import PowerSet +from sympy.sets.sets import FiniteSet +from sympy.testing.pytest import raises, XFAIL + + +def test_powerset_creation(): + assert unchanged(PowerSet, FiniteSet(1, 2)) + assert unchanged(PowerSet, S.EmptySet) + raises(ValueError, lambda: PowerSet(123)) + assert unchanged(PowerSet, S.Reals) + assert unchanged(PowerSet, S.Integers) + + +def test_powerset_rewrite_FiniteSet(): + assert PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) == \ + FiniteSet(S.EmptySet, FiniteSet(1), FiniteSet(2), FiniteSet(1, 2)) + assert PowerSet(S.EmptySet).rewrite(FiniteSet) == FiniteSet(S.EmptySet) + assert PowerSet(S.Naturals).rewrite(FiniteSet) == PowerSet(S.Naturals) + + +def test_finiteset_rewrite_powerset(): + assert FiniteSet(S.EmptySet).rewrite(PowerSet) == PowerSet(S.EmptySet) + assert FiniteSet( + S.EmptySet, FiniteSet(1), + FiniteSet(2), FiniteSet(1, 2)).rewrite(PowerSet) == \ + PowerSet(FiniteSet(1, 2)) + assert FiniteSet(1, 2, 3).rewrite(PowerSet) == FiniteSet(1, 2, 3) + + +def test_powerset__contains__(): + subset_series = [ + S.EmptySet, + FiniteSet(1, 2), + S.Naturals, + S.Naturals0, + S.Integers, + S.Rationals, + S.Reals, + S.Complexes] + + l = len(subset_series) + for i in range(l): + for j in range(l): + if i <= j: + assert subset_series[i] in \ + PowerSet(subset_series[j], evaluate=False) + else: + assert subset_series[i] not in \ + PowerSet(subset_series[j], evaluate=False) + + +@XFAIL +def test_failing_powerset__contains__(): + # XXX These are failing when evaluate=True, + # but using unevaluated PowerSet works fine. + assert FiniteSet(1, 2) not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Naturals not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Naturals not in PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) + assert S.Naturals0 not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Naturals0 not in PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) + assert S.Integers not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Integers not in PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) + assert S.Rationals not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Rationals not in PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) + assert S.Reals not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Reals not in PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) + assert S.Complexes not in PowerSet(S.EmptySet).rewrite(FiniteSet) + assert S.Complexes not in PowerSet(FiniteSet(1, 2)).rewrite(FiniteSet) + + +def test_powerset__len__(): + A = PowerSet(S.EmptySet, evaluate=False) + assert len(A) == 1 + A = PowerSet(A, evaluate=False) + assert len(A) == 2 + A = PowerSet(A, evaluate=False) + assert len(A) == 4 + A = PowerSet(A, evaluate=False) + assert len(A) == 16 + + +def test_powerset__iter__(): + a = PowerSet(FiniteSet(1, 2)).__iter__() + assert next(a) == S.EmptySet + assert next(a) == FiniteSet(1) + assert next(a) == FiniteSet(2) + assert next(a) == FiniteSet(1, 2) + + a = PowerSet(S.Naturals).__iter__() + assert next(a) == S.EmptySet + assert next(a) == FiniteSet(1) + assert next(a) == FiniteSet(2) + assert next(a) == FiniteSet(1, 2) + assert next(a) == FiniteSet(3) + assert next(a) == FiniteSet(1, 3) + assert next(a) == FiniteSet(2, 3) + assert next(a) == FiniteSet(1, 2, 3) + + +def test_powerset_contains(): + A = PowerSet(FiniteSet(1), evaluate=False) + assert A.contains(2) == Contains(2, A) + + x = Symbol('x') + + A = PowerSet(FiniteSet(x), evaluate=False) + assert A.contains(FiniteSet(1)) == Contains(FiniteSet(1), A) + + +def test_powerset_method(): + # EmptySet + A = FiniteSet() + pset = A.powerset() + assert len(pset) == 1 + assert pset == FiniteSet(S.EmptySet) + + # FiniteSets + A = FiniteSet(1, 2) + pset = A.powerset() + assert len(pset) == 2**len(A) + assert pset == FiniteSet(FiniteSet(), FiniteSet(1), + FiniteSet(2), A) + # Not finite sets + A = Interval(0, 1) + assert A.powerset() == PowerSet(A) + +def test_is_subset(): + # covers line 101-102 + # initialize powerset(1), which is a subset of powerset(1,2) + subset = PowerSet(FiniteSet(1)) + pset = PowerSet(FiniteSet(1, 2)) + bad_set = PowerSet(FiniteSet(2, 3)) + # assert "subset" is subset of pset == True + assert subset.is_subset(pset) + # assert "bad_set" is subset of pset == False + assert not pset.is_subset(bad_set) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_setexpr.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_setexpr.py new file mode 100644 index 0000000000000000000000000000000000000000..faab1261c8d3e86901b04d30e8bc94de31642b93 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_setexpr.py @@ -0,0 +1,317 @@ +from sympy.sets.setexpr import SetExpr +from sympy.sets import Interval, FiniteSet, Intersection, ImageSet, Union + +from sympy.core.expr import Expr +from sympy.core.function import Lambda +from sympy.core.numbers import (I, Rational, oo) +from sympy.core.singleton import S +from sympy.core.symbol import (Dummy, Symbol, symbols) +from sympy.functions.elementary.exponential import (exp, log) +from sympy.functions.elementary.miscellaneous import (Max, Min, sqrt) +from sympy.functions.elementary.trigonometric import cos +from sympy.sets.sets import Set + + +a, x = symbols("a, x") +_d = Dummy("d") + + +def test_setexpr(): + se = SetExpr(Interval(0, 1)) + assert isinstance(se.set, Set) + assert isinstance(se, Expr) + + +def test_scalar_funcs(): + assert SetExpr(Interval(0, 1)).set == Interval(0, 1) + a, b = Symbol('a', real=True), Symbol('b', real=True) + a, b = 1, 2 + # TODO: add support for more functions in the future: + for f in [exp, log]: + input_se = f(SetExpr(Interval(a, b))) + output = input_se.set + expected = Interval(Min(f(a), f(b)), Max(f(a), f(b))) + assert output == expected + + +def test_Add_Mul(): + assert (SetExpr(Interval(0, 1)) + 1).set == Interval(1, 2) + assert (SetExpr(Interval(0, 1))*2).set == Interval(0, 2) + + +def test_Pow(): + assert (SetExpr(Interval(0, 2))**2).set == Interval(0, 4) + + +def test_compound(): + assert (exp(SetExpr(Interval(0, 1))*2 + 1)).set == \ + Interval(exp(1), exp(3)) + + +def test_Interval_Interval(): + assert (SetExpr(Interval(1, 2)) + SetExpr(Interval(10, 20))).set == \ + Interval(11, 22) + assert (SetExpr(Interval(1, 2))*SetExpr(Interval(10, 20))).set == \ + Interval(10, 40) + + +def test_FiniteSet_FiniteSet(): + assert (SetExpr(FiniteSet(1, 2, 3)) + SetExpr(FiniteSet(1, 2))).set == \ + FiniteSet(2, 3, 4, 5) + assert (SetExpr(FiniteSet(1, 2, 3))*SetExpr(FiniteSet(1, 2))).set == \ + FiniteSet(1, 2, 3, 4, 6) + + +def test_Interval_FiniteSet(): + assert (SetExpr(FiniteSet(1, 2)) + SetExpr(Interval(0, 10))).set == \ + Interval(1, 12) + + +def test_Many_Sets(): + assert (SetExpr(Interval(0, 1)) + + SetExpr(Interval(2, 3)) + + SetExpr(FiniteSet(10, 11, 12))).set == Interval(12, 16) + + +def test_same_setexprs_are_not_identical(): + a = SetExpr(FiniteSet(0, 1)) + b = SetExpr(FiniteSet(0, 1)) + assert (a + b).set == FiniteSet(0, 1, 2) + + # Cannot detect the set being the same: + # assert (a + a).set == FiniteSet(0, 2) + + +def test_Interval_arithmetic(): + i12cc = SetExpr(Interval(1, 2)) + i12lo = SetExpr(Interval.Lopen(1, 2)) + i12ro = SetExpr(Interval.Ropen(1, 2)) + i12o = SetExpr(Interval.open(1, 2)) + + n23cc = SetExpr(Interval(-2, 3)) + n23lo = SetExpr(Interval.Lopen(-2, 3)) + n23ro = SetExpr(Interval.Ropen(-2, 3)) + n23o = SetExpr(Interval.open(-2, 3)) + + n3n2cc = SetExpr(Interval(-3, -2)) + + assert i12cc + i12cc == SetExpr(Interval(2, 4)) + assert i12cc - i12cc == SetExpr(Interval(-1, 1)) + assert i12cc*i12cc == SetExpr(Interval(1, 4)) + assert i12cc/i12cc == SetExpr(Interval(S.Half, 2)) + assert i12cc**2 == SetExpr(Interval(1, 4)) + assert i12cc**3 == SetExpr(Interval(1, 8)) + + assert i12lo + i12ro == SetExpr(Interval.open(2, 4)) + assert i12lo - i12ro == SetExpr(Interval.Lopen(-1, 1)) + assert i12lo*i12ro == SetExpr(Interval.open(1, 4)) + assert i12lo/i12ro == SetExpr(Interval.Lopen(S.Half, 2)) + assert i12lo + i12lo == SetExpr(Interval.Lopen(2, 4)) + assert i12lo - i12lo == SetExpr(Interval.open(-1, 1)) + assert i12lo*i12lo == SetExpr(Interval.Lopen(1, 4)) + assert i12lo/i12lo == SetExpr(Interval.open(S.Half, 2)) + assert i12lo + i12cc == SetExpr(Interval.Lopen(2, 4)) + assert i12lo - i12cc == SetExpr(Interval.Lopen(-1, 1)) + assert i12lo*i12cc == SetExpr(Interval.Lopen(1, 4)) + assert i12lo/i12cc == SetExpr(Interval.Lopen(S.Half, 2)) + assert i12lo + i12o == SetExpr(Interval.open(2, 4)) + assert i12lo - i12o == SetExpr(Interval.open(-1, 1)) + assert i12lo*i12o == SetExpr(Interval.open(1, 4)) + assert i12lo/i12o == SetExpr(Interval.open(S.Half, 2)) + assert i12lo**2 == SetExpr(Interval.Lopen(1, 4)) + assert i12lo**3 == SetExpr(Interval.Lopen(1, 8)) + + assert i12ro + i12ro == SetExpr(Interval.Ropen(2, 4)) + assert i12ro - i12ro == SetExpr(Interval.open(-1, 1)) + assert i12ro*i12ro == SetExpr(Interval.Ropen(1, 4)) + assert i12ro/i12ro == SetExpr(Interval.open(S.Half, 2)) + assert i12ro + i12cc == SetExpr(Interval.Ropen(2, 4)) + assert i12ro - i12cc == SetExpr(Interval.Ropen(-1, 1)) + assert i12ro*i12cc == SetExpr(Interval.Ropen(1, 4)) + assert i12ro/i12cc == SetExpr(Interval.Ropen(S.Half, 2)) + assert i12ro + i12o == SetExpr(Interval.open(2, 4)) + assert i12ro - i12o == SetExpr(Interval.open(-1, 1)) + assert i12ro*i12o == SetExpr(Interval.open(1, 4)) + assert i12ro/i12o == SetExpr(Interval.open(S.Half, 2)) + assert i12ro**2 == SetExpr(Interval.Ropen(1, 4)) + assert i12ro**3 == SetExpr(Interval.Ropen(1, 8)) + + assert i12o + i12lo == SetExpr(Interval.open(2, 4)) + assert i12o - i12lo == SetExpr(Interval.open(-1, 1)) + assert i12o*i12lo == SetExpr(Interval.open(1, 4)) + assert i12o/i12lo == SetExpr(Interval.open(S.Half, 2)) + assert i12o + i12ro == SetExpr(Interval.open(2, 4)) + assert i12o - i12ro == SetExpr(Interval.open(-1, 1)) + assert i12o*i12ro == SetExpr(Interval.open(1, 4)) + assert i12o/i12ro == SetExpr(Interval.open(S.Half, 2)) + assert i12o + i12cc == SetExpr(Interval.open(2, 4)) + assert i12o - i12cc == SetExpr(Interval.open(-1, 1)) + assert i12o*i12cc == SetExpr(Interval.open(1, 4)) + assert i12o/i12cc == SetExpr(Interval.open(S.Half, 2)) + assert i12o**2 == SetExpr(Interval.open(1, 4)) + assert i12o**3 == SetExpr(Interval.open(1, 8)) + + assert n23cc + n23cc == SetExpr(Interval(-4, 6)) + assert n23cc - n23cc == SetExpr(Interval(-5, 5)) + assert n23cc*n23cc == SetExpr(Interval(-6, 9)) + assert n23cc/n23cc == SetExpr(Interval.open(-oo, oo)) + assert n23cc + n23ro == SetExpr(Interval.Ropen(-4, 6)) + assert n23cc - n23ro == SetExpr(Interval.Lopen(-5, 5)) + assert n23cc*n23ro == SetExpr(Interval.Ropen(-6, 9)) + assert n23cc/n23ro == SetExpr(Interval.Lopen(-oo, oo)) + assert n23cc + n23lo == SetExpr(Interval.Lopen(-4, 6)) + assert n23cc - n23lo == SetExpr(Interval.Ropen(-5, 5)) + assert n23cc*n23lo == SetExpr(Interval(-6, 9)) + assert n23cc/n23lo == SetExpr(Interval.open(-oo, oo)) + assert n23cc + n23o == SetExpr(Interval.open(-4, 6)) + assert n23cc - n23o == SetExpr(Interval.open(-5, 5)) + assert n23cc*n23o == SetExpr(Interval.open(-6, 9)) + assert n23cc/n23o == SetExpr(Interval.open(-oo, oo)) + assert n23cc**2 == SetExpr(Interval(0, 9)) + assert n23cc**3 == SetExpr(Interval(-8, 27)) + + n32cc = SetExpr(Interval(-3, 2)) + n32lo = SetExpr(Interval.Lopen(-3, 2)) + n32ro = SetExpr(Interval.Ropen(-3, 2)) + assert n32cc*n32lo == SetExpr(Interval.Ropen(-6, 9)) + assert n32cc*n32cc == SetExpr(Interval(-6, 9)) + assert n32lo*n32cc == SetExpr(Interval.Ropen(-6, 9)) + assert n32cc*n32ro == SetExpr(Interval(-6, 9)) + assert n32lo*n32ro == SetExpr(Interval.Ropen(-6, 9)) + assert n32cc/n32lo == SetExpr(Interval.Ropen(-oo, oo)) + assert i12cc/n32lo == SetExpr(Interval.Ropen(-oo, oo)) + + assert n3n2cc**2 == SetExpr(Interval(4, 9)) + assert n3n2cc**3 == SetExpr(Interval(-27, -8)) + + assert n23cc + i12cc == SetExpr(Interval(-1, 5)) + assert n23cc - i12cc == SetExpr(Interval(-4, 2)) + assert n23cc*i12cc == SetExpr(Interval(-4, 6)) + assert n23cc/i12cc == SetExpr(Interval(-2, 3)) + + +def test_SetExpr_Intersection(): + x, y, z, w = symbols("x y z w") + set1 = Interval(x, y) + set2 = Interval(w, z) + inter = Intersection(set1, set2) + se = SetExpr(inter) + assert exp(se).set == Intersection( + ImageSet(Lambda(x, exp(x)), set1), + ImageSet(Lambda(x, exp(x)), set2)) + assert cos(se).set == ImageSet(Lambda(x, cos(x)), inter) + + +def test_SetExpr_Interval_div(): + # TODO: some expressions cannot be calculated due to bugs (currently + # commented): + assert SetExpr(Interval(-3, -2))/SetExpr(Interval(-2, 1)) == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(2, 3))/SetExpr(Interval(-2, 2)) == SetExpr(Interval(-oo, oo)) + + assert SetExpr(Interval(-3, -2))/SetExpr(Interval(0, 4)) == SetExpr(Interval(-oo, Rational(-1, 2))) + assert SetExpr(Interval(2, 4))/SetExpr(Interval(-3, 0)) == SetExpr(Interval(-oo, Rational(-2, 3))) + assert SetExpr(Interval(2, 4))/SetExpr(Interval(0, 3)) == SetExpr(Interval(Rational(2, 3), oo)) + + # assert SetExpr(Interval(0, 1))/SetExpr(Interval(0, 1)) == SetExpr(Interval(0, oo)) + # assert SetExpr(Interval(-1, 0))/SetExpr(Interval(0, 1)) == SetExpr(Interval(-oo, 0)) + assert SetExpr(Interval(-1, 2))/SetExpr(Interval(-2, 2)) == SetExpr(Interval(-oo, oo)) + + assert 1/SetExpr(Interval(-1, 2)) == SetExpr(Union(Interval(-oo, -1), Interval(S.Half, oo))) + + assert 1/SetExpr(Interval(0, 2)) == SetExpr(Interval(S.Half, oo)) + assert (-1)/SetExpr(Interval(0, 2)) == SetExpr(Interval(-oo, Rational(-1, 2))) + assert 1/SetExpr(Interval(-oo, 0)) == SetExpr(Interval.open(-oo, 0)) + assert 1/SetExpr(Interval(-1, 0)) == SetExpr(Interval(-oo, -1)) + # assert (-2)/SetExpr(Interval(-oo, 0)) == SetExpr(Interval(0, oo)) + # assert 1/SetExpr(Interval(-oo, -1)) == SetExpr(Interval(-1, 0)) + + # assert SetExpr(Interval(1, 2))/a == Mul(SetExpr(Interval(1, 2)), 1/a, evaluate=False) + + # assert SetExpr(Interval(1, 2))/0 == SetExpr(Interval(1, 2))*zoo + # assert SetExpr(Interval(1, oo))/oo == SetExpr(Interval(0, oo)) + # assert SetExpr(Interval(1, oo))/(-oo) == SetExpr(Interval(-oo, 0)) + # assert SetExpr(Interval(-oo, -1))/oo == SetExpr(Interval(-oo, 0)) + # assert SetExpr(Interval(-oo, -1))/(-oo) == SetExpr(Interval(0, oo)) + # assert SetExpr(Interval(-oo, oo))/oo == SetExpr(Interval(-oo, oo)) + # assert SetExpr(Interval(-oo, oo))/(-oo) == SetExpr(Interval(-oo, oo)) + # assert SetExpr(Interval(-1, oo))/oo == SetExpr(Interval(0, oo)) + # assert SetExpr(Interval(-1, oo))/(-oo) == SetExpr(Interval(-oo, 0)) + # assert SetExpr(Interval(-oo, 1))/oo == SetExpr(Interval(-oo, 0)) + # assert SetExpr(Interval(-oo, 1))/(-oo) == SetExpr(Interval(0, oo)) + + +def test_SetExpr_Interval_pow(): + assert SetExpr(Interval(0, 2))**2 == SetExpr(Interval(0, 4)) + assert SetExpr(Interval(-1, 1))**2 == SetExpr(Interval(0, 1)) + assert SetExpr(Interval(1, 2))**2 == SetExpr(Interval(1, 4)) + assert SetExpr(Interval(-1, 2))**3 == SetExpr(Interval(-1, 8)) + assert SetExpr(Interval(-1, 1))**0 == SetExpr(FiniteSet(1)) + + + assert SetExpr(Interval(1, 2))**Rational(5, 2) == SetExpr(Interval(1, 4*sqrt(2))) + #assert SetExpr(Interval(-1, 2))**Rational(1, 3) == SetExpr(Interval(-1, 2**Rational(1, 3))) + #assert SetExpr(Interval(0, 2))**S.Half == SetExpr(Interval(0, sqrt(2))) + + #assert SetExpr(Interval(-4, 2))**Rational(2, 3) == SetExpr(Interval(0, 2*2**Rational(1, 3))) + + #assert SetExpr(Interval(-1, 5))**S.Half == SetExpr(Interval(0, sqrt(5))) + #assert SetExpr(Interval(-oo, 2))**S.Half == SetExpr(Interval(0, sqrt(2))) + #assert SetExpr(Interval(-2, 3))**(Rational(-1, 4)) == SetExpr(Interval(0, oo)) + + assert SetExpr(Interval(1, 5))**(-2) == SetExpr(Interval(Rational(1, 25), 1)) + assert SetExpr(Interval(-1, 3))**(-2) == SetExpr(Interval(0, oo)) + + assert SetExpr(Interval(0, 2))**(-2) == SetExpr(Interval(Rational(1, 4), oo)) + assert SetExpr(Interval(-1, 2))**(-3) == SetExpr(Union(Interval(-oo, -1), Interval(Rational(1, 8), oo))) + assert SetExpr(Interval(-3, -2))**(-3) == SetExpr(Interval(Rational(-1, 8), Rational(-1, 27))) + assert SetExpr(Interval(-3, -2))**(-2) == SetExpr(Interval(Rational(1, 9), Rational(1, 4))) + #assert SetExpr(Interval(0, oo))**S.Half == SetExpr(Interval(0, oo)) + #assert SetExpr(Interval(-oo, -1))**Rational(1, 3) == SetExpr(Interval(-oo, -1)) + #assert SetExpr(Interval(-2, 3))**(Rational(-1, 3)) == SetExpr(Interval(-oo, oo)) + + assert SetExpr(Interval(-oo, 0))**(-2) == SetExpr(Interval.open(0, oo)) + assert SetExpr(Interval(-2, 0))**(-2) == SetExpr(Interval(Rational(1, 4), oo)) + + assert SetExpr(Interval(Rational(1, 3), S.Half))**oo == SetExpr(FiniteSet(0)) + assert SetExpr(Interval(0, S.Half))**oo == SetExpr(FiniteSet(0)) + assert SetExpr(Interval(S.Half, 1))**oo == SetExpr(Interval(0, oo)) + assert SetExpr(Interval(0, 1))**oo == SetExpr(Interval(0, oo)) + assert SetExpr(Interval(2, 3))**oo == SetExpr(FiniteSet(oo)) + assert SetExpr(Interval(1, 2))**oo == SetExpr(Interval(0, oo)) + assert SetExpr(Interval(S.Half, 3))**oo == SetExpr(Interval(0, oo)) + assert SetExpr(Interval(Rational(-1, 3), Rational(-1, 4)))**oo == SetExpr(FiniteSet(0)) + assert SetExpr(Interval(-1, Rational(-1, 2)))**oo == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(-3, -2))**oo == SetExpr(FiniteSet(-oo, oo)) + assert SetExpr(Interval(-2, -1))**oo == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(-2, Rational(-1, 2)))**oo == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(Rational(-1, 2), S.Half))**oo == SetExpr(FiniteSet(0)) + assert SetExpr(Interval(Rational(-1, 2), 1))**oo == SetExpr(Interval(0, oo)) + assert SetExpr(Interval(Rational(-2, 3), 2))**oo == SetExpr(Interval(0, oo)) + assert SetExpr(Interval(-1, 1))**oo == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(-1, S.Half))**oo == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(-1, 2))**oo == SetExpr(Interval(-oo, oo)) + assert SetExpr(Interval(-2, S.Half))**oo == SetExpr(Interval(-oo, oo)) + + assert (SetExpr(Interval(1, 2))**x).dummy_eq(SetExpr(ImageSet(Lambda(_d, _d**x), Interval(1, 2)))) + + assert SetExpr(Interval(2, 3))**(-oo) == SetExpr(FiniteSet(0)) + assert SetExpr(Interval(0, 2))**(-oo) == SetExpr(Interval(0, oo)) + assert (SetExpr(Interval(-1, 2))**(-oo)).dummy_eq(SetExpr(ImageSet(Lambda(_d, _d**(-oo)), Interval(-1, 2)))) + + +def test_SetExpr_Integers(): + assert SetExpr(S.Integers) + 1 == SetExpr(S.Integers) + assert (SetExpr(S.Integers) + I).dummy_eq( + SetExpr(ImageSet(Lambda(_d, _d + I), S.Integers))) + assert SetExpr(S.Integers)*(-1) == SetExpr(S.Integers) + assert (SetExpr(S.Integers)*2).dummy_eq( + SetExpr(ImageSet(Lambda(_d, 2*_d), S.Integers))) + assert (SetExpr(S.Integers)*I).dummy_eq( + SetExpr(ImageSet(Lambda(_d, I*_d), S.Integers))) + # issue #18050: + assert SetExpr(S.Integers)._eval_func(Lambda(x, I*x + 1)).dummy_eq( + SetExpr(ImageSet(Lambda(_d, I*_d + 1), S.Integers))) + # needs improvement: + assert (SetExpr(S.Integers)*I + 1).dummy_eq( + SetExpr(ImageSet(Lambda(x, x + 1), + ImageSet(Lambda(_d, _d*I), S.Integers)))) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_sets.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_sets.py new file mode 100644 index 0000000000000000000000000000000000000000..657ab19a90eb88ca48f266f7a5cf050504caed43 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/sets/tests/test_sets.py @@ -0,0 +1,1753 @@ +from sympy.concrete.summations import Sum +from sympy.core.add import Add +from sympy.core.containers import TupleKind +from sympy.core.function import Lambda +from sympy.core.kind import NumberKind, UndefinedKind +from sympy.core.numbers import (Float, I, Rational, nan, oo, pi, zoo) +from sympy.core.power import Pow +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, symbols) +from sympy.core.sympify import sympify +from sympy.functions.elementary.miscellaneous import (Max, Min, sqrt) +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (cos, sin) +from sympy.logic.boolalg import (false, true) +from sympy.matrices.kind import MatrixKind +from sympy.matrices.dense import Matrix +from sympy.polys.rootoftools import rootof +from sympy.sets.contains import Contains +from sympy.sets.fancysets import (ImageSet, Range) +from sympy.sets.sets import (Complement, DisjointUnion, FiniteSet, Intersection, Interval, ProductSet, Set, SymmetricDifference, Union, imageset, SetKind) +from mpmath import mpi + +from sympy.core.expr import unchanged +from sympy.core.relational import Eq, Ne, Le, Lt, LessThan +from sympy.logic import And, Or, Xor +from sympy.testing.pytest import raises, XFAIL, warns_deprecated_sympy +from sympy.utilities.iterables import cartes + +from sympy.abc import x, y, z, m, n + +EmptySet = S.EmptySet + +def test_imageset(): + ints = S.Integers + assert imageset(x, x - 1, S.Naturals) is S.Naturals0 + assert imageset(x, x + 1, S.Naturals0) is S.Naturals + assert imageset(x, abs(x), S.Naturals0) is S.Naturals0 + assert imageset(x, abs(x), S.Naturals) is S.Naturals + assert imageset(x, abs(x), S.Integers) is S.Naturals0 + # issue 16878a + r = symbols('r', real=True) + assert imageset(x, (x, x), S.Reals)._contains((1, r)) == None + assert imageset(x, (x, x), S.Reals)._contains((1, 2)) == False + assert (r, r) in imageset(x, (x, x), S.Reals) + assert 1 + I in imageset(x, x + I, S.Reals) + assert {1} not in imageset(x, (x,), S.Reals) + assert (1, 1) not in imageset(x, (x,), S.Reals) + raises(TypeError, lambda: imageset(x, ints)) + raises(ValueError, lambda: imageset(x, y, z, ints)) + raises(ValueError, lambda: imageset(Lambda(x, cos(x)), y)) + assert (1, 2) in imageset(Lambda((x, y), (x, y)), ints, ints) + raises(ValueError, lambda: imageset(Lambda(x, x), ints, ints)) + assert imageset(cos, ints) == ImageSet(Lambda(x, cos(x)), ints) + def f(x): + return cos(x) + assert imageset(f, ints) == imageset(x, cos(x), ints) + f = lambda x: cos(x) + assert imageset(f, ints) == ImageSet(Lambda(x, cos(x)), ints) + assert imageset(x, 1, ints) == FiniteSet(1) + assert imageset(x, y, ints) == {y} + assert imageset((x, y), (1, z), ints, S.Reals) == {(1, z)} + clash = Symbol('x', integer=true) + assert (str(imageset(lambda x: x + clash, Interval(-2, 1)).lamda.expr) + in ('x0 + x', 'x + x0')) + x1, x2 = symbols("x1, x2") + assert imageset(lambda x, y: + Add(x, y), Interval(1, 2), Interval(2, 3)).dummy_eq( + ImageSet(Lambda((x1, x2), x1 + x2), + Interval(1, 2), Interval(2, 3))) + + +def test_is_empty(): + for s in [S.Naturals, S.Naturals0, S.Integers, S.Rationals, S.Reals, + S.UniversalSet]: + assert s.is_empty is False + + assert S.EmptySet.is_empty is True + + +def test_is_finiteset(): + for s in [S.Naturals, S.Naturals0, S.Integers, S.Rationals, S.Reals, + S.UniversalSet]: + assert s.is_finite_set is False + + assert S.EmptySet.is_finite_set is True + + assert FiniteSet(1, 2).is_finite_set is True + assert Interval(1, 2).is_finite_set is False + assert Interval(x, y).is_finite_set is None + assert ProductSet(FiniteSet(1), FiniteSet(2)).is_finite_set is True + assert ProductSet(FiniteSet(1), Interval(1, 2)).is_finite_set is False + assert ProductSet(FiniteSet(1), Interval(x, y)).is_finite_set is None + assert Union(Interval(0, 1), Interval(2, 3)).is_finite_set is False + assert Union(FiniteSet(1), Interval(2, 3)).is_finite_set is False + assert Union(FiniteSet(1), FiniteSet(2)).is_finite_set is True + assert Union(FiniteSet(1), Interval(x, y)).is_finite_set is None + assert Intersection(Interval(x, y), FiniteSet(1)).is_finite_set is True + assert Intersection(Interval(x, y), Interval(1, 2)).is_finite_set is None + assert Intersection(FiniteSet(x), FiniteSet(y)).is_finite_set is True + assert Complement(FiniteSet(1), Interval(x, y)).is_finite_set is True + assert Complement(Interval(x, y), FiniteSet(1)).is_finite_set is None + assert Complement(Interval(1, 2), FiniteSet(x)).is_finite_set is False + assert DisjointUnion(Interval(-5, 3), FiniteSet(x, y)).is_finite_set is False + assert DisjointUnion(S.EmptySet, FiniteSet(x, y), S.EmptySet).is_finite_set is True + + +def test_deprecated_is_EmptySet(): + with warns_deprecated_sympy(): + S.EmptySet.is_EmptySet + + with warns_deprecated_sympy(): + FiniteSet(1).is_EmptySet + + +def test_interval_arguments(): + assert Interval(0, oo) == Interval(0, oo, False, True) + assert Interval(0, oo).right_open is true + assert Interval(-oo, 0) == Interval(-oo, 0, True, False) + assert Interval(-oo, 0).left_open is true + assert Interval(oo, -oo) == S.EmptySet + assert Interval(oo, oo) == S.EmptySet + assert Interval(-oo, -oo) == S.EmptySet + assert Interval(oo, x) == S.EmptySet + assert Interval(oo, oo) == S.EmptySet + assert Interval(x, -oo) == S.EmptySet + assert Interval(x, x) == {x} + + assert isinstance(Interval(1, 1), FiniteSet) + e = Sum(x, (x, 1, 3)) + assert isinstance(Interval(e, e), FiniteSet) + + assert Interval(1, 0) == S.EmptySet + assert Interval(1, 1).measure == 0 + + assert Interval(1, 1, False, True) == S.EmptySet + assert Interval(1, 1, True, False) == S.EmptySet + assert Interval(1, 1, True, True) == S.EmptySet + + + assert isinstance(Interval(0, Symbol('a')), Interval) + assert Interval(Symbol('a', positive=True), 0) == S.EmptySet + raises(ValueError, lambda: Interval(0, S.ImaginaryUnit)) + raises(ValueError, lambda: Interval(0, Symbol('z', extended_real=False))) + raises(ValueError, lambda: Interval(x, x + S.ImaginaryUnit)) + + raises(NotImplementedError, lambda: Interval(0, 1, And(x, y))) + raises(NotImplementedError, lambda: Interval(0, 1, False, And(x, y))) + raises(NotImplementedError, lambda: Interval(0, 1, z, And(x, y))) + + +def test_interval_symbolic_end_points(): + a = Symbol('a', real=True) + + assert Union(Interval(0, a), Interval(0, 3)).sup == Max(a, 3) + assert Union(Interval(a, 0), Interval(-3, 0)).inf == Min(-3, a) + + assert Interval(0, a).contains(1) == LessThan(1, a) + + +def test_interval_is_empty(): + x, y = symbols('x, y') + r = Symbol('r', real=True) + p = Symbol('p', positive=True) + n = Symbol('n', negative=True) + nn = Symbol('nn', nonnegative=True) + assert Interval(1, 2).is_empty == False + assert Interval(3, 3).is_empty == False # FiniteSet + assert Interval(r, r).is_empty == False # FiniteSet + assert Interval(r, r + nn).is_empty == False + assert Interval(x, x).is_empty == False + assert Interval(1, oo).is_empty == False + assert Interval(-oo, oo).is_empty == False + assert Interval(-oo, 1).is_empty == False + assert Interval(x, y).is_empty == None + assert Interval(r, oo).is_empty == False # real implies finite + assert Interval(n, 0).is_empty == False + assert Interval(n, 0, left_open=True).is_empty == False + assert Interval(p, 0).is_empty == True # EmptySet + assert Interval(nn, 0).is_empty == None + assert Interval(n, p).is_empty == False + assert Interval(0, p, left_open=True).is_empty == False + assert Interval(0, p, right_open=True).is_empty == False + assert Interval(0, nn, left_open=True).is_empty == None + assert Interval(0, nn, right_open=True).is_empty == None + + +def test_union(): + assert Union(Interval(1, 2), Interval(2, 3)) == Interval(1, 3) + assert Union(Interval(1, 2), Interval(2, 3, True)) == Interval(1, 3) + assert Union(Interval(1, 3), Interval(2, 4)) == Interval(1, 4) + assert Union(Interval(1, 2), Interval(1, 3)) == Interval(1, 3) + assert Union(Interval(1, 3), Interval(1, 2)) == Interval(1, 3) + assert Union(Interval(1, 3, False, True), Interval(1, 2)) == \ + Interval(1, 3, False, True) + assert Union(Interval(1, 3), Interval(1, 2, False, True)) == Interval(1, 3) + assert Union(Interval(1, 2, True), Interval(1, 3)) == Interval(1, 3) + assert Union(Interval(1, 2, True), Interval(1, 3, True)) == \ + Interval(1, 3, True) + assert Union(Interval(1, 2, True), Interval(1, 3, True, True)) == \ + Interval(1, 3, True, True) + assert Union(Interval(1, 2, True, True), Interval(1, 3, True)) == \ + Interval(1, 3, True) + assert Union(Interval(1, 3), Interval(2, 3)) == Interval(1, 3) + assert Union(Interval(1, 3, False, True), Interval(2, 3)) == \ + Interval(1, 3) + assert Union(Interval(1, 2, False, True), Interval(2, 3, True)) != \ + Interval(1, 3) + assert Union(Interval(1, 2), S.EmptySet) == Interval(1, 2) + assert Union(S.EmptySet) == S.EmptySet + + assert Union(Interval(0, 1), *[FiniteSet(1.0/n) for n in range(1, 10)]) == \ + Interval(0, 1) + # issue #18241: + x = Symbol('x') + assert Union(Interval(0, 1), FiniteSet(1, x)) == Union( + Interval(0, 1), FiniteSet(x)) + assert unchanged(Union, Interval(0, 1), FiniteSet(2, x)) + + assert Interval(1, 2).union(Interval(2, 3)) == \ + Interval(1, 2) + Interval(2, 3) + + assert Interval(1, 2).union(Interval(2, 3)) == Interval(1, 3) + + assert Union(Set()) == Set() + + assert FiniteSet(1) + FiniteSet(2) + FiniteSet(3) == FiniteSet(1, 2, 3) + assert FiniteSet('ham') + FiniteSet('eggs') == FiniteSet('ham', 'eggs') + assert FiniteSet(1, 2, 3) + S.EmptySet == FiniteSet(1, 2, 3) + + assert FiniteSet(1, 2, 3) & FiniteSet(2, 3, 4) == FiniteSet(2, 3) + assert FiniteSet(1, 2, 3) | FiniteSet(2, 3, 4) == FiniteSet(1, 2, 3, 4) + + assert FiniteSet(1, 2, 3) & S.EmptySet == S.EmptySet + assert FiniteSet(1, 2, 3) | S.EmptySet == FiniteSet(1, 2, 3) + + x = Symbol("x") + y = Symbol("y") + z = Symbol("z") + assert S.EmptySet | FiniteSet(x, FiniteSet(y, z)) == \ + FiniteSet(x, FiniteSet(y, z)) + + # Test that Intervals and FiniteSets play nicely + assert Interval(1, 3) + FiniteSet(2) == Interval(1, 3) + assert Interval(1, 3, True, True) + FiniteSet(3) == \ + Interval(1, 3, True, False) + X = Interval(1, 3) + FiniteSet(5) + Y = Interval(1, 2) + FiniteSet(3) + XandY = X.intersect(Y) + assert 2 in X and 3 in X and 3 in XandY + assert XandY.is_subset(X) and XandY.is_subset(Y) + + raises(TypeError, lambda: Union(1, 2, 3)) + + assert X.is_iterable is False + + # issue 7843 + assert Union(S.EmptySet, FiniteSet(-sqrt(-I), sqrt(-I))) == \ + FiniteSet(-sqrt(-I), sqrt(-I)) + + assert Union(S.Reals, S.Integers) == S.Reals + + +def test_union_iter(): + # Use Range because it is ordered + u = Union(Range(3), Range(5), Range(4), evaluate=False) + + # Round robin + assert list(u) == [0, 0, 0, 1, 1, 1, 2, 2, 2, 3, 3, 4] + + +def test_union_is_empty(): + assert (Interval(x, y) + FiniteSet(1)).is_empty == False + assert (Interval(x, y) + Interval(-x, y)).is_empty == None + + +def test_difference(): + assert Interval(1, 3) - Interval(1, 2) == Interval(2, 3, True) + assert Interval(1, 3) - Interval(2, 3) == Interval(1, 2, False, True) + assert Interval(1, 3, True) - Interval(2, 3) == Interval(1, 2, True, True) + assert Interval(1, 3, True) - Interval(2, 3, True) == \ + Interval(1, 2, True, False) + assert Interval(0, 2) - FiniteSet(1) == \ + Union(Interval(0, 1, False, True), Interval(1, 2, True, False)) + + # issue #18119 + assert S.Reals - FiniteSet(I) == S.Reals + assert S.Reals - FiniteSet(-I, I) == S.Reals + assert Interval(0, 10) - FiniteSet(-I, I) == Interval(0, 10) + assert Interval(0, 10) - FiniteSet(1, I) == Union( + Interval.Ropen(0, 1), Interval.Lopen(1, 10)) + assert S.Reals - FiniteSet(1, 2 + I, x, y**2) == Complement( + Union(Interval.open(-oo, 1), Interval.open(1, oo)), FiniteSet(x, y**2), + evaluate=False) + + assert FiniteSet(1, 2, 3) - FiniteSet(2) == FiniteSet(1, 3) + assert FiniteSet('ham', 'eggs') - FiniteSet('eggs') == FiniteSet('ham') + assert FiniteSet(1, 2, 3, 4) - Interval(2, 10, True, False) == \ + FiniteSet(1, 2) + assert FiniteSet(1, 2, 3, 4) - S.EmptySet == FiniteSet(1, 2, 3, 4) + assert Union(Interval(0, 2), FiniteSet(2, 3, 4)) - Interval(1, 3) == \ + Union(Interval(0, 1, False, True), FiniteSet(4)) + + assert -1 in S.Reals - S.Naturals + + +def test_Complement(): + A = FiniteSet(1, 3, 4) + B = FiniteSet(3, 4) + C = Interval(1, 3) + D = Interval(1, 2) + + assert Complement(A, B, evaluate=False).is_iterable is True + assert Complement(A, C, evaluate=False).is_iterable is True + assert Complement(C, D, evaluate=False).is_iterable is None + + assert FiniteSet(*Complement(A, B, evaluate=False)) == FiniteSet(1) + assert FiniteSet(*Complement(A, C, evaluate=False)) == FiniteSet(4) + raises(TypeError, lambda: FiniteSet(*Complement(C, A, evaluate=False))) + + assert Complement(Interval(1, 3), Interval(1, 2)) == Interval(2, 3, True) + assert Complement(FiniteSet(1, 3, 4), FiniteSet(3, 4)) == FiniteSet(1) + assert Complement(Union(Interval(0, 2), FiniteSet(2, 3, 4)), + Interval(1, 3)) == \ + Union(Interval(0, 1, False, True), FiniteSet(4)) + + assert 3 not in Complement(Interval(0, 5), Interval(1, 4), evaluate=False) + assert -1 in Complement(S.Reals, S.Naturals, evaluate=False) + assert 1 not in Complement(S.Reals, S.Naturals, evaluate=False) + + assert Complement(S.Integers, S.UniversalSet) == EmptySet + assert S.UniversalSet.complement(S.Integers) == EmptySet + + assert (0 not in S.Reals.intersect(S.Integers - FiniteSet(0))) + + assert S.EmptySet - S.Integers == S.EmptySet + + assert (S.Integers - FiniteSet(0)) - FiniteSet(1) == S.Integers - FiniteSet(0, 1) + + assert S.Reals - Union(S.Naturals, FiniteSet(pi)) == \ + Intersection(S.Reals - S.Naturals, S.Reals - FiniteSet(pi)) + # issue 12712 + assert Complement(FiniteSet(x, y, 2), Interval(-10, 10)) == \ + Complement(FiniteSet(x, y), Interval(-10, 10)) + + A = FiniteSet(*symbols('a:c')) + B = FiniteSet(*symbols('d:f')) + assert unchanged(Complement, ProductSet(A, A), B) + + A2 = ProductSet(A, A) + B3 = ProductSet(B, B, B) + assert A2 - B3 == A2 + assert B3 - A2 == B3 + + +def test_set_operations_nonsets(): + '''Tests that e.g. FiniteSet(1) * 2 raises TypeError''' + ops = [ + lambda a, b: a + b, + lambda a, b: a - b, + lambda a, b: a * b, + lambda a, b: a / b, + lambda a, b: a // b, + lambda a, b: a | b, + lambda a, b: a & b, + lambda a, b: a ^ b, + # FiniteSet(1) ** 2 gives a ProductSet + #lambda a, b: a ** b, + ] + Sx = FiniteSet(x) + Sy = FiniteSet(y) + sets = [ + {1}, + FiniteSet(1), + Interval(1, 2), + Union(Sx, Interval(1, 2)), + Intersection(Sx, Sy), + Complement(Sx, Sy), + ProductSet(Sx, Sy), + S.EmptySet, + ] + nums = [0, 1, 2, S(0), S(1), S(2)] + + for si in sets: + for ni in nums: + for op in ops: + raises(TypeError, lambda : op(si, ni)) + raises(TypeError, lambda : op(ni, si)) + raises(TypeError, lambda: si ** object()) + raises(TypeError, lambda: si ** {1}) + + +def test_complement(): + assert Complement({1, 2}, {1}) == {2} + assert Interval(0, 1).complement(S.Reals) == \ + Union(Interval(-oo, 0, True, True), Interval(1, oo, True, True)) + assert Interval(0, 1, True, False).complement(S.Reals) == \ + Union(Interval(-oo, 0, True, False), Interval(1, oo, True, True)) + assert Interval(0, 1, False, True).complement(S.Reals) == \ + Union(Interval(-oo, 0, True, True), Interval(1, oo, False, True)) + assert Interval(0, 1, True, True).complement(S.Reals) == \ + Union(Interval(-oo, 0, True, False), Interval(1, oo, False, True)) + + assert S.UniversalSet.complement(S.EmptySet) == S.EmptySet + assert S.UniversalSet.complement(S.Reals) == S.EmptySet + assert S.UniversalSet.complement(S.UniversalSet) == S.EmptySet + + assert S.EmptySet.complement(S.Reals) == S.Reals + + assert Union(Interval(0, 1), Interval(2, 3)).complement(S.Reals) == \ + Union(Interval(-oo, 0, True, True), Interval(1, 2, True, True), + Interval(3, oo, True, True)) + + assert FiniteSet(0).complement(S.Reals) == \ + Union(Interval(-oo, 0, True, True), Interval(0, oo, True, True)) + + assert (FiniteSet(5) + Interval(S.NegativeInfinity, + 0)).complement(S.Reals) == \ + Interval(0, 5, True, True) + Interval(5, S.Infinity, True, True) + + assert FiniteSet(1, 2, 3).complement(S.Reals) == \ + Interval(S.NegativeInfinity, 1, True, True) + \ + Interval(1, 2, True, True) + Interval(2, 3, True, True) +\ + Interval(3, S.Infinity, True, True) + + assert FiniteSet(x).complement(S.Reals) == Complement(S.Reals, FiniteSet(x)) + + assert FiniteSet(0, x).complement(S.Reals) == Complement(Interval(-oo, 0, True, True) + + Interval(0, oo, True, True) + , FiniteSet(x), evaluate=False) + + square = Interval(0, 1) * Interval(0, 1) + notsquare = square.complement(S.Reals*S.Reals) + + assert all(pt in square for pt in [(0, 0), (.5, .5), (1, 0), (1, 1)]) + assert not any( + pt in notsquare for pt in [(0, 0), (.5, .5), (1, 0), (1, 1)]) + assert not any(pt in square for pt in [(-1, 0), (1.5, .5), (10, 10)]) + assert all(pt in notsquare for pt in [(-1, 0), (1.5, .5), (10, 10)]) + + +def test_intersect1(): + assert all(S.Integers.intersection(i) is i for i in + (S.Naturals, S.Naturals0)) + assert all(i.intersection(S.Integers) is i for i in + (S.Naturals, S.Naturals0)) + s = S.Naturals0 + assert S.Naturals.intersection(s) is S.Naturals + assert s.intersection(S.Naturals) is S.Naturals + x = Symbol('x') + assert Interval(0, 2).intersect(Interval(1, 2)) == Interval(1, 2) + assert Interval(0, 2).intersect(Interval(1, 2, True)) == \ + Interval(1, 2, True) + assert Interval(0, 2, True).intersect(Interval(1, 2)) == \ + Interval(1, 2, False, False) + assert Interval(0, 2, True, True).intersect(Interval(1, 2)) == \ + Interval(1, 2, False, True) + assert Interval(0, 2).intersect(Union(Interval(0, 1), Interval(2, 3))) == \ + Union(Interval(0, 1), Interval(2, 2)) + + assert FiniteSet(1, 2).intersect(FiniteSet(1, 2, 3)) == FiniteSet(1, 2) + assert FiniteSet(1, 2, x).intersect(FiniteSet(x)) == FiniteSet(x) + assert FiniteSet('ham', 'eggs').intersect(FiniteSet('ham')) == \ + FiniteSet('ham') + assert FiniteSet(1, 2, 3, 4, 5).intersect(S.EmptySet) == S.EmptySet + + assert Interval(0, 5).intersect(FiniteSet(1, 3)) == FiniteSet(1, 3) + assert Interval(0, 1, True, True).intersect(FiniteSet(1)) == S.EmptySet + + assert Union(Interval(0, 1), Interval(2, 3)).intersect(Interval(1, 2)) == \ + Union(Interval(1, 1), Interval(2, 2)) + assert Union(Interval(0, 1), Interval(2, 3)).intersect(Interval(0, 2)) == \ + Union(Interval(0, 1), Interval(2, 2)) + assert Union(Interval(0, 1), Interval(2, 3)).intersect(Interval(1, 2, True, True)) == \ + S.EmptySet + assert Union(Interval(0, 1), Interval(2, 3)).intersect(S.EmptySet) == \ + S.EmptySet + assert Union(Interval(0, 5), FiniteSet('ham')).intersect(FiniteSet(2, 3, 4, 5, 6)) == \ + Intersection(FiniteSet(2, 3, 4, 5, 6), Union(FiniteSet('ham'), Interval(0, 5))) + assert Intersection(FiniteSet(1, 2, 3), Interval(2, x), Interval(3, y)) == \ + Intersection(FiniteSet(3), Interval(2, x), Interval(3, y), evaluate=False) + assert Intersection(FiniteSet(1, 2), Interval(0, 3), Interval(x, y)) == \ + Intersection({1, 2}, Interval(x, y), evaluate=False) + assert Intersection(FiniteSet(1, 2, 4), Interval(0, 3), Interval(x, y)) == \ + Intersection({1, 2}, Interval(x, y), evaluate=False) + # XXX: Is the real=True necessary here? + # https://github.com/sympy/sympy/issues/17532 + m, n = symbols('m, n', real=True) + assert Intersection(FiniteSet(m), FiniteSet(m, n), Interval(m, m+1)) == \ + FiniteSet(m) + + # issue 8217 + assert Intersection(FiniteSet(x), FiniteSet(y)) == \ + Intersection(FiniteSet(x), FiniteSet(y), evaluate=False) + assert FiniteSet(x).intersect(S.Reals) == \ + Intersection(S.Reals, FiniteSet(x), evaluate=False) + + # tests for the intersection alias + assert Interval(0, 5).intersection(FiniteSet(1, 3)) == FiniteSet(1, 3) + assert Interval(0, 1, True, True).intersection(FiniteSet(1)) == S.EmptySet + + assert Union(Interval(0, 1), Interval(2, 3)).intersection(Interval(1, 2)) == \ + Union(Interval(1, 1), Interval(2, 2)) + + # canonical boundary selected + a = sqrt(2*sqrt(6) + 5) + b = sqrt(2) + sqrt(3) + assert Interval(a, 4).intersection(Interval(b, 5)) == Interval(b, 4) + assert Interval(1, a).intersection(Interval(0, b)) == Interval(1, b) + + +def test_intersection_interval_float(): + # intersection of Intervals with mixed Rational/Float boundaries should + # lead to Float boundaries in all cases regardless of which Interval is + # open or closed. + typs = [ + (Interval, Interval, Interval), + (Interval, Interval.open, Interval.open), + (Interval, Interval.Lopen, Interval.Lopen), + (Interval, Interval.Ropen, Interval.Ropen), + (Interval.open, Interval.open, Interval.open), + (Interval.open, Interval.Lopen, Interval.open), + (Interval.open, Interval.Ropen, Interval.open), + (Interval.Lopen, Interval.Lopen, Interval.Lopen), + (Interval.Lopen, Interval.Ropen, Interval.open), + (Interval.Ropen, Interval.Ropen, Interval.Ropen), + ] + + as_float = lambda a1, a2: a2 if isinstance(a2, float) else a1 + + for t1, t2, t3 in typs: + for t1i, t2i in [(t1, t2), (t2, t1)]: + for a1, a2, b1, b2 in cartes([2, 2.0], [2, 2.0], [3, 3.0], [3, 3.0]): + I1 = t1(a1, b1) + I2 = t2(a2, b2) + I3 = t3(as_float(a1, a2), as_float(b1, b2)) + assert I1.intersect(I2) == I3 + + +def test_intersection(): + # iterable + i = Intersection(FiniteSet(1, 2, 3), Interval(2, 5), evaluate=False) + assert i.is_iterable + assert set(i) == {S(2), S(3)} + + # challenging intervals + x = Symbol('x', real=True) + i = Intersection(Interval(0, 3), Interval(x, 6)) + assert (5 in i) is False + raises(TypeError, lambda: 2 in i) + + # Singleton special cases + assert Intersection(Interval(0, 1), S.EmptySet) == S.EmptySet + assert Intersection(Interval(-oo, oo), Interval(-oo, x)) == Interval(-oo, x) + + # Products + line = Interval(0, 5) + i = Intersection(line**2, line**3, evaluate=False) + assert (2, 2) not in i + assert (2, 2, 2) not in i + raises(TypeError, lambda: list(i)) + + a = Intersection(Intersection(S.Integers, S.Naturals, evaluate=False), S.Reals, evaluate=False) + assert a._argset == frozenset([Intersection(S.Naturals, S.Integers, evaluate=False), S.Reals]) + + assert Intersection(S.Complexes, FiniteSet(S.ComplexInfinity)) == S.EmptySet + + # issue 12178 + assert Intersection() == S.UniversalSet + + # issue 16987 + assert Intersection({1}, {1}, {x}) == Intersection({1}, {x}) + + +def test_issue_9623(): + n = Symbol('n') + + a = S.Reals + b = Interval(0, oo) + c = FiniteSet(n) + + assert Intersection(a, b, c) == Intersection(b, c) + assert Intersection(Interval(1, 2), Interval(3, 4), FiniteSet(n)) == EmptySet + + +def test_is_disjoint(): + assert Interval(0, 2).is_disjoint(Interval(1, 2)) == False + assert Interval(0, 2).is_disjoint(Interval(3, 4)) == True + + +def test_ProductSet__len__(): + A = FiniteSet(1, 2) + B = FiniteSet(1, 2, 3) + assert ProductSet(A).__len__() == 2 + assert ProductSet(A).__len__() is not S(2) + assert ProductSet(A, B).__len__() == 6 + assert ProductSet(A, B).__len__() is not S(6) + + +def test_ProductSet(): + # ProductSet is always a set of Tuples + assert ProductSet(S.Reals) == S.Reals ** 1 + assert ProductSet(S.Reals, S.Reals) == S.Reals ** 2 + assert ProductSet(S.Reals, S.Reals, S.Reals) == S.Reals ** 3 + + assert ProductSet(S.Reals) != S.Reals + assert ProductSet(S.Reals, S.Reals) == S.Reals * S.Reals + assert ProductSet(S.Reals, S.Reals, S.Reals) != S.Reals * S.Reals * S.Reals + assert ProductSet(S.Reals, S.Reals, S.Reals) == (S.Reals * S.Reals * S.Reals).flatten() + + assert 1 not in ProductSet(S.Reals) + assert (1,) in ProductSet(S.Reals) + + assert 1 not in ProductSet(S.Reals, S.Reals) + assert (1, 2) in ProductSet(S.Reals, S.Reals) + assert (1, I) not in ProductSet(S.Reals, S.Reals) + + assert (1, 2, 3) in ProductSet(S.Reals, S.Reals, S.Reals) + assert (1, 2, 3) in S.Reals ** 3 + assert (1, 2, 3) not in S.Reals * S.Reals * S.Reals + assert ((1, 2), 3) in S.Reals * S.Reals * S.Reals + assert (1, (2, 3)) not in S.Reals * S.Reals * S.Reals + assert (1, (2, 3)) in S.Reals * (S.Reals * S.Reals) + + assert ProductSet() == FiniteSet(()) + assert ProductSet(S.Reals, S.EmptySet) == S.EmptySet + + # See GH-17458 + + for ni in range(5): + Rn = ProductSet(*(S.Reals,) * ni) + assert (1,) * ni in Rn + assert 1 not in Rn + + assert (S.Reals * S.Reals) * S.Reals != S.Reals * (S.Reals * S.Reals) + + S1 = S.Reals + S2 = S.Integers + x1 = pi + x2 = 3 + assert x1 in S1 + assert x2 in S2 + assert (x1, x2) in S1 * S2 + S3 = S1 * S2 + x3 = (x1, x2) + assert x3 in S3 + assert (x3, x3) in S3 * S3 + assert x3 + x3 not in S3 * S3 + + raises(ValueError, lambda: S.Reals**-1) + with warns_deprecated_sympy(): + ProductSet(FiniteSet(s) for s in range(2)) + raises(TypeError, lambda: ProductSet(None)) + + S1 = FiniteSet(1, 2) + S2 = FiniteSet(3, 4) + S3 = ProductSet(S1, S2) + assert (S3.as_relational(x, y) + == And(S1.as_relational(x), S2.as_relational(y)) + == And(Or(Eq(x, 1), Eq(x, 2)), Or(Eq(y, 3), Eq(y, 4)))) + raises(ValueError, lambda: S3.as_relational(x)) + raises(ValueError, lambda: S3.as_relational(x, 1)) + raises(ValueError, lambda: ProductSet(Interval(0, 1)).as_relational(x, y)) + + Z2 = ProductSet(S.Integers, S.Integers) + assert Z2.contains((1, 2)) is S.true + assert Z2.contains((1,)) is S.false + assert Z2.contains(x) == Contains(x, Z2, evaluate=False) + assert Z2.contains(x).subs(x, 1) is S.false + assert Z2.contains((x, 1)).subs(x, 2) is S.true + assert Z2.contains((x, y)) == Contains(x, S.Integers) & Contains(y, S.Integers) + assert unchanged(Contains, (x, y), Z2) + assert Contains((1, 2), Z2) is S.true + + +def test_ProductSet_of_single_arg_is_not_arg(): + assert unchanged(ProductSet, Interval(0, 1)) + assert unchanged(ProductSet, ProductSet(Interval(0, 1))) + + +def test_ProductSet_is_empty(): + assert ProductSet(S.Integers, S.Reals).is_empty == False + assert ProductSet(Interval(x, 1), S.Reals).is_empty == None + + +def test_interval_subs(): + a = Symbol('a', real=True) + + assert Interval(0, a).subs(a, 2) == Interval(0, 2) + assert Interval(a, 0).subs(a, 2) == S.EmptySet + + +def test_interval_to_mpi(): + assert Interval(0, 1).to_mpi() == mpi(0, 1) + assert Interval(0, 1, True, False).to_mpi() == mpi(0, 1) + assert type(Interval(0, 1).to_mpi()) == type(mpi(0, 1)) + + +def test_set_evalf(): + assert Interval(S(11)/64, S.Half).evalf() == Interval( + Float('0.171875'), Float('0.5')) + assert Interval(x, S.Half, right_open=True).evalf() == Interval( + x, Float('0.5'), right_open=True) + assert Interval(-oo, S.Half).evalf() == Interval(-oo, Float('0.5')) + assert FiniteSet(2, x).evalf() == FiniteSet(Float('2.0'), x) + + +def test_measure(): + a = Symbol('a', real=True) + + assert Interval(1, 3).measure == 2 + assert Interval(0, a).measure == a + assert Interval(1, a).measure == a - 1 + + assert Union(Interval(1, 2), Interval(3, 4)).measure == 2 + assert Union(Interval(1, 2), Interval(3, 4), FiniteSet(5, 6, 7)).measure \ + == 2 + + assert FiniteSet(1, 2, oo, a, -oo, -5).measure == 0 + + assert S.EmptySet.measure == 0 + + square = Interval(0, 10) * Interval(0, 10) + offsetsquare = Interval(5, 15) * Interval(5, 15) + band = Interval(-oo, oo) * Interval(2, 4) + + assert square.measure == offsetsquare.measure == 100 + assert (square + offsetsquare).measure == 175 # there is some overlap + assert (square - offsetsquare).measure == 75 + assert (square * FiniteSet(1, 2, 3)).measure == 0 + assert (square.intersect(band)).measure == 20 + assert (square + band).measure is oo + assert (band * FiniteSet(1, 2, 3)).measure is nan + + +def test_is_subset(): + assert Interval(0, 1).is_subset(Interval(0, 2)) is True + assert Interval(0, 3).is_subset(Interval(0, 2)) is False + assert Interval(0, 1).is_subset(FiniteSet(0, 1)) is False + + assert FiniteSet(1, 2).is_subset(FiniteSet(1, 2, 3, 4)) + assert FiniteSet(4, 5).is_subset(FiniteSet(1, 2, 3, 4)) is False + assert FiniteSet(1).is_subset(Interval(0, 2)) + assert FiniteSet(1, 2).is_subset(Interval(0, 2, True, True)) is False + assert (Interval(1, 2) + FiniteSet(3)).is_subset( + Interval(0, 2, False, True) + FiniteSet(2, 3)) + + assert Interval(3, 4).is_subset(Union(Interval(0, 1), Interval(2, 5))) is True + assert Interval(3, 6).is_subset(Union(Interval(0, 1), Interval(2, 5))) is False + + assert FiniteSet(1, 2, 3, 4).is_subset(Interval(0, 5)) is True + assert S.EmptySet.is_subset(FiniteSet(1, 2, 3)) is True + + assert Interval(0, 1).is_subset(S.EmptySet) is False + assert S.EmptySet.is_subset(S.EmptySet) is True + + raises(ValueError, lambda: S.EmptySet.is_subset(1)) + + # tests for the issubset alias + assert FiniteSet(1, 2, 3, 4).issubset(Interval(0, 5)) is True + assert S.EmptySet.issubset(FiniteSet(1, 2, 3)) is True + + assert S.Naturals.is_subset(S.Integers) + assert S.Naturals0.is_subset(S.Integers) + + assert FiniteSet(x).is_subset(FiniteSet(y)) is None + assert FiniteSet(x).is_subset(FiniteSet(y).subs(y, x)) is True + assert FiniteSet(x).is_subset(FiniteSet(y).subs(y, x+1)) is False + + assert Interval(0, 1).is_subset(Interval(0, 1, left_open=True)) is False + assert Interval(-2, 3).is_subset(Union(Interval(-oo, -2), Interval(3, oo))) is False + + n = Symbol('n', integer=True) + assert Range(-3, 4, 1).is_subset(FiniteSet(-10, 10)) is False + assert Range(S(10)**100).is_subset(FiniteSet(0, 1, 2)) is False + assert Range(6, 0, -2).is_subset(FiniteSet(2, 4, 6)) is True + assert Range(1, oo).is_subset(FiniteSet(1, 2)) is False + assert Range(-oo, 1).is_subset(FiniteSet(1)) is False + assert Range(3).is_subset(FiniteSet(0, 1, n)) is None + assert Range(n, n + 2).is_subset(FiniteSet(n, n + 1)) is True + assert Range(5).is_subset(Interval(0, 4, right_open=True)) is False + #issue 19513 + assert imageset(Lambda(n, 1/n), S.Integers).is_subset(S.Reals) is None + +def test_is_proper_subset(): + assert Interval(0, 1).is_proper_subset(Interval(0, 2)) is True + assert Interval(0, 3).is_proper_subset(Interval(0, 2)) is False + assert S.EmptySet.is_proper_subset(FiniteSet(1, 2, 3)) is True + + raises(ValueError, lambda: Interval(0, 1).is_proper_subset(0)) + + +def test_is_superset(): + assert Interval(0, 1).is_superset(Interval(0, 2)) == False + assert Interval(0, 3).is_superset(Interval(0, 2)) + + assert FiniteSet(1, 2).is_superset(FiniteSet(1, 2, 3, 4)) == False + assert FiniteSet(4, 5).is_superset(FiniteSet(1, 2, 3, 4)) == False + assert FiniteSet(1).is_superset(Interval(0, 2)) == False + assert FiniteSet(1, 2).is_superset(Interval(0, 2, True, True)) == False + assert (Interval(1, 2) + FiniteSet(3)).is_superset( + Interval(0, 2, False, True) + FiniteSet(2, 3)) == False + + assert Interval(3, 4).is_superset(Union(Interval(0, 1), Interval(2, 5))) == False + + assert FiniteSet(1, 2, 3, 4).is_superset(Interval(0, 5)) == False + assert S.EmptySet.is_superset(FiniteSet(1, 2, 3)) == False + + assert Interval(0, 1).is_superset(S.EmptySet) == True + assert S.EmptySet.is_superset(S.EmptySet) == True + + raises(ValueError, lambda: S.EmptySet.is_superset(1)) + + # tests for the issuperset alias + assert Interval(0, 1).issuperset(S.EmptySet) == True + assert S.EmptySet.issuperset(S.EmptySet) == True + + +def test_is_proper_superset(): + assert Interval(0, 1).is_proper_superset(Interval(0, 2)) is False + assert Interval(0, 3).is_proper_superset(Interval(0, 2)) is True + assert FiniteSet(1, 2, 3).is_proper_superset(S.EmptySet) is True + + raises(ValueError, lambda: Interval(0, 1).is_proper_superset(0)) + + +def test_contains(): + assert Interval(0, 2).contains(1) is S.true + assert Interval(0, 2).contains(3) is S.false + assert Interval(0, 2, True, False).contains(0) is S.false + assert Interval(0, 2, True, False).contains(2) is S.true + assert Interval(0, 2, False, True).contains(0) is S.true + assert Interval(0, 2, False, True).contains(2) is S.false + assert Interval(0, 2, True, True).contains(0) is S.false + assert Interval(0, 2, True, True).contains(2) is S.false + + assert (Interval(0, 2) in Interval(0, 2)) is False + + assert FiniteSet(1, 2, 3).contains(2) is S.true + assert FiniteSet(1, 2, Symbol('x')).contains(Symbol('x')) is S.true + + assert FiniteSet(y)._contains(x) == Eq(y, x, evaluate=False) + raises(TypeError, lambda: x in FiniteSet(y)) + assert FiniteSet({x, y})._contains({x}) == Eq({x, y}, {x}, evaluate=False) + assert FiniteSet({x, y}).subs(y, x)._contains({x}) is S.true + assert FiniteSet({x, y}).subs(y, x+1)._contains({x}) is S.false + + # issue 8197 + from sympy.abc import a, b + assert FiniteSet(b).contains(-a) == Eq(b, -a) + assert FiniteSet(b).contains(a) == Eq(b, a) + assert FiniteSet(a).contains(1) == Eq(a, 1) + raises(TypeError, lambda: 1 in FiniteSet(a)) + + # issue 8209 + rad1 = Pow(Pow(2, Rational(1, 3)) - 1, Rational(1, 3)) + rad2 = Pow(Rational(1, 9), Rational(1, 3)) - Pow(Rational(2, 9), Rational(1, 3)) + Pow(Rational(4, 9), Rational(1, 3)) + s1 = FiniteSet(rad1) + s2 = FiniteSet(rad2) + assert s1 - s2 == S.EmptySet + + items = [1, 2, S.Infinity, S('ham'), -1.1] + fset = FiniteSet(*items) + assert all(item in fset for item in items) + assert all(fset.contains(item) is S.true for item in items) + + assert Union(Interval(0, 1), Interval(2, 5)).contains(3) is S.true + assert Union(Interval(0, 1), Interval(2, 5)).contains(6) is S.false + assert Union(Interval(0, 1), FiniteSet(2, 5)).contains(3) is S.false + + assert S.EmptySet.contains(1) is S.false + assert FiniteSet(rootof(x**3 + x - 1, 0)).contains(S.Infinity) is S.false + + assert rootof(x**5 + x**3 + 1, 0) in S.Reals + assert not rootof(x**5 + x**3 + 1, 1) in S.Reals + + # non-bool results + assert Union(Interval(1, 2), Interval(3, 4)).contains(x) == \ + Or(And(S.One <= x, x <= 2), And(S(3) <= x, x <= 4)) + assert Intersection(Interval(1, x), Interval(2, 3)).contains(y) == \ + And(y <= 3, y <= x, S.One <= y, S(2) <= y) + + assert (S.Complexes).contains(S.ComplexInfinity) == S.false + + +def test_interval_symbolic(): + x = Symbol('x') + e = Interval(0, 1) + assert e.contains(x) == And(S.Zero <= x, x <= 1) + raises(TypeError, lambda: x in e) + e = Interval(0, 1, True, True) + assert e.contains(x) == And(S.Zero < x, x < 1) + c = Symbol('c', real=False) + assert Interval(x, x + 1).contains(c) == False + e = Symbol('e', extended_real=True) + assert Interval(-oo, oo).contains(e) == And( + S.NegativeInfinity < e, e < S.Infinity) + + +def test_union_contains(): + x = Symbol('x') + i1 = Interval(0, 1) + i2 = Interval(2, 3) + i3 = Union(i1, i2) + assert i3.as_relational(x) == Or(And(S.Zero <= x, x <= 1), And(S(2) <= x, x <= 3)) + raises(TypeError, lambda: x in i3) + e = i3.contains(x) + assert e == i3.as_relational(x) + assert e.subs(x, -0.5) is false + assert e.subs(x, 0.5) is true + assert e.subs(x, 1.5) is false + assert e.subs(x, 2.5) is true + assert e.subs(x, 3.5) is false + + U = Interval(0, 2, True, True) + Interval(10, oo) + FiniteSet(-1, 2, 5, 6) + assert all(el not in U for el in [0, 4, -oo]) + assert all(el in U for el in [2, 5, 10]) + + +def test_is_number(): + assert Interval(0, 1).is_number is False + assert Set().is_number is False + + +def test_Interval_is_left_unbounded(): + assert Interval(3, 4).is_left_unbounded is False + assert Interval(-oo, 3).is_left_unbounded is True + assert Interval(Float("-inf"), 3).is_left_unbounded is True + + +def test_Interval_is_right_unbounded(): + assert Interval(3, 4).is_right_unbounded is False + assert Interval(3, oo).is_right_unbounded is True + assert Interval(3, Float("+inf")).is_right_unbounded is True + + +def test_Interval_as_relational(): + x = Symbol('x') + + assert Interval(-1, 2, False, False).as_relational(x) == \ + And(Le(-1, x), Le(x, 2)) + assert Interval(-1, 2, True, False).as_relational(x) == \ + And(Lt(-1, x), Le(x, 2)) + assert Interval(-1, 2, False, True).as_relational(x) == \ + And(Le(-1, x), Lt(x, 2)) + assert Interval(-1, 2, True, True).as_relational(x) == \ + And(Lt(-1, x), Lt(x, 2)) + + assert Interval(-oo, 2, right_open=False).as_relational(x) == And(Lt(-oo, x), Le(x, 2)) + assert Interval(-oo, 2, right_open=True).as_relational(x) == And(Lt(-oo, x), Lt(x, 2)) + + assert Interval(-2, oo, left_open=False).as_relational(x) == And(Le(-2, x), Lt(x, oo)) + assert Interval(-2, oo, left_open=True).as_relational(x) == And(Lt(-2, x), Lt(x, oo)) + + assert Interval(-oo, oo).as_relational(x) == And(Lt(-oo, x), Lt(x, oo)) + x = Symbol('x', real=True) + y = Symbol('y', real=True) + assert Interval(x, y).as_relational(x) == (x <= y) + assert Interval(y, x).as_relational(x) == (y <= x) + + +def test_Finite_as_relational(): + x = Symbol('x') + y = Symbol('y') + + assert FiniteSet(1, 2).as_relational(x) == Or(Eq(x, 1), Eq(x, 2)) + assert FiniteSet(y, -5).as_relational(x) == Or(Eq(x, y), Eq(x, -5)) + + +def test_Union_as_relational(): + x = Symbol('x') + assert (Interval(0, 1) + FiniteSet(2)).as_relational(x) == \ + Or(And(Le(0, x), Le(x, 1)), Eq(x, 2)) + assert (Interval(0, 1, True, True) + FiniteSet(1)).as_relational(x) == \ + And(Lt(0, x), Le(x, 1)) + assert Or(x < 0, x > 0).as_set().as_relational(x) == \ + And((x > -oo), (x < oo), Ne(x, 0)) + assert (Interval.Ropen(1, 3) + Interval.Lopen(3, 5) + ).as_relational(x) == And(Ne(x,3),(x>=1),(x<=5)) + + +def test_Intersection_as_relational(): + x = Symbol('x') + assert (Intersection(Interval(0, 1), FiniteSet(2), + evaluate=False).as_relational(x) + == And(And(Le(0, x), Le(x, 1)), Eq(x, 2))) + + +def test_Complement_as_relational(): + x = Symbol('x') + expr = Complement(Interval(0, 1), FiniteSet(2), evaluate=False) + assert expr.as_relational(x) == \ + And(Le(0, x), Le(x, 1), Ne(x, 2)) + + +@XFAIL +def test_Complement_as_relational_fail(): + x = Symbol('x') + expr = Complement(Interval(0, 1), FiniteSet(2), evaluate=False) + # XXX This example fails because 0 <= x changes to x >= 0 + # during the evaluation. + assert expr.as_relational(x) == \ + (0 <= x) & (x <= 1) & Ne(x, 2) + + +def test_SymmetricDifference_as_relational(): + x = Symbol('x') + expr = SymmetricDifference(Interval(0, 1), FiniteSet(2), evaluate=False) + assert expr.as_relational(x) == Xor(Eq(x, 2), Le(0, x) & Le(x, 1)) + + +def test_EmptySet(): + assert S.EmptySet.as_relational(Symbol('x')) is S.false + assert S.EmptySet.intersect(S.UniversalSet) == S.EmptySet + assert S.EmptySet.boundary == S.EmptySet + + +def test_finite_basic(): + x = Symbol('x') + A = FiniteSet(1, 2, 3) + B = FiniteSet(3, 4, 5) + AorB = Union(A, B) + AandB = A.intersect(B) + assert A.is_subset(AorB) and B.is_subset(AorB) + assert AandB.is_subset(A) + assert AandB == FiniteSet(3) + + assert A.inf == 1 and A.sup == 3 + assert AorB.inf == 1 and AorB.sup == 5 + assert FiniteSet(x, 1, 5).sup == Max(x, 5) + assert FiniteSet(x, 1, 5).inf == Min(x, 1) + + # issue 7335 + assert FiniteSet(S.EmptySet) != S.EmptySet + assert FiniteSet(FiniteSet(1, 2, 3)) != FiniteSet(1, 2, 3) + assert FiniteSet((1, 2, 3)) != FiniteSet(1, 2, 3) + + # Ensure a variety of types can exist in a FiniteSet + assert FiniteSet((1, 2), A, -5, x, 'eggs', x**2) + + assert (A > B) is False + assert (A >= B) is False + assert (A < B) is False + assert (A <= B) is False + assert AorB > A and AorB > B + assert AorB >= A and AorB >= B + assert A >= A and A <= A + assert A >= AandB and B >= AandB + assert A > AandB and B > AandB + + +def test_product_basic(): + H, T = 'H', 'T' + unit_line = Interval(0, 1) + d6 = FiniteSet(1, 2, 3, 4, 5, 6) + d4 = FiniteSet(1, 2, 3, 4) + coin = FiniteSet(H, T) + + square = unit_line * unit_line + + assert (0, 0) in square + assert 0 not in square + assert (H, T) in coin ** 2 + assert (.5, .5, .5) in (square * unit_line).flatten() + assert ((.5, .5), .5) in square * unit_line + assert (H, 3, 3) in (coin * d6 * d6).flatten() + assert ((H, 3), 3) in coin * d6 * d6 + HH, TT = sympify(H), sympify(T) + assert set(coin**2) == {(HH, HH), (HH, TT), (TT, HH), (TT, TT)} + + assert (d4*d4).is_subset(d6*d6) + + assert square.complement(Interval(-oo, oo)*Interval(-oo, oo)) == Union( + (Interval(-oo, 0, True, True) + + Interval(1, oo, True, True))*Interval(-oo, oo), + Interval(-oo, oo)*(Interval(-oo, 0, True, True) + + Interval(1, oo, True, True))) + + assert (Interval(-5, 5)**3).is_subset(Interval(-10, 10)**3) + assert not (Interval(-10, 10)**3).is_subset(Interval(-5, 5)**3) + assert not (Interval(-5, 5)**2).is_subset(Interval(-10, 10)**3) + + assert (Interval(.2, .5)*FiniteSet(.5)).is_subset(square) # segment in square + + assert len(coin*coin*coin) == 8 + assert len(S.EmptySet*S.EmptySet) == 0 + assert len(S.EmptySet*coin) == 0 + raises(TypeError, lambda: len(coin*Interval(0, 2))) + + +def test_real(): + x = Symbol('x', real=True) + + I = Interval(0, 5) + J = Interval(10, 20) + A = FiniteSet(1, 2, 30, x, S.Pi) + B = FiniteSet(-4, 0) + C = FiniteSet(100) + D = FiniteSet('Ham', 'Eggs') + + assert all(s.is_subset(S.Reals) for s in [I, J, A, B, C]) + assert not D.is_subset(S.Reals) + assert all((a + b).is_subset(S.Reals) for a in [I, J, A, B, C] for b in [I, J, A, B, C]) + assert not any((a + D).is_subset(S.Reals) for a in [I, J, A, B, C, D]) + + assert not (I + A + D).is_subset(S.Reals) + + +def test_supinf(): + x = Symbol('x', real=True) + y = Symbol('y', real=True) + + assert (Interval(0, 1) + FiniteSet(2)).sup == 2 + assert (Interval(0, 1) + FiniteSet(2)).inf == 0 + assert (Interval(0, 1) + FiniteSet(x)).sup == Max(1, x) + assert (Interval(0, 1) + FiniteSet(x)).inf == Min(0, x) + assert FiniteSet(5, 1, x).sup == Max(5, x) + assert FiniteSet(5, 1, x).inf == Min(1, x) + assert FiniteSet(5, 1, x, y).sup == Max(5, x, y) + assert FiniteSet(5, 1, x, y).inf == Min(1, x, y) + assert FiniteSet(5, 1, x, y, S.Infinity, S.NegativeInfinity).sup == \ + S.Infinity + assert FiniteSet(5, 1, x, y, S.Infinity, S.NegativeInfinity).inf == \ + S.NegativeInfinity + assert FiniteSet('Ham', 'Eggs').sup == Max('Ham', 'Eggs') + + +def test_universalset(): + U = S.UniversalSet + x = Symbol('x') + assert U.as_relational(x) is S.true + assert U.union(Interval(2, 4)) == U + + assert U.intersect(Interval(2, 4)) == Interval(2, 4) + assert U.measure is S.Infinity + assert U.boundary == S.EmptySet + assert U.contains(0) is S.true + + +def test_Union_of_ProductSets_shares(): + line = Interval(0, 2) + points = FiniteSet(0, 1, 2) + assert Union(line * line, line * points) == line * line + + +def test_Interval_free_symbols(): + # issue 6211 + assert Interval(0, 1).free_symbols == set() + x = Symbol('x', real=True) + assert Interval(0, x).free_symbols == {x} + + +def test_image_interval(): + x = Symbol('x', real=True) + a = Symbol('a', real=True) + assert imageset(x, 2*x, Interval(-2, 1)) == Interval(-4, 2) + assert imageset(x, 2*x, Interval(-2, 1, True, False)) == \ + Interval(-4, 2, True, False) + assert imageset(x, x**2, Interval(-2, 1, True, False)) == \ + Interval(0, 4, False, True) + assert imageset(x, x**2, Interval(-2, 1)) == Interval(0, 4) + assert imageset(x, x**2, Interval(-2, 1, True, False)) == \ + Interval(0, 4, False, True) + assert imageset(x, x**2, Interval(-2, 1, True, True)) == \ + Interval(0, 4, False, True) + assert imageset(x, (x - 2)**2, Interval(1, 3)) == Interval(0, 1) + assert imageset(x, 3*x**4 - 26*x**3 + 78*x**2 - 90*x, Interval(0, 4)) == \ + Interval(-35, 0) # Multiple Maxima + assert imageset(x, x + 1/x, Interval(-oo, oo)) == Interval(-oo, -2) \ + + Interval(2, oo) # Single Infinite discontinuity + assert imageset(x, 1/x + 1/(x-1)**2, Interval(0, 2, True, False)) == \ + Interval(Rational(3, 2), oo, False) # Multiple Infinite discontinuities + + # Test for Python lambda + assert imageset(lambda x: 2*x, Interval(-2, 1)) == Interval(-4, 2) + + assert imageset(Lambda(x, a*x), Interval(0, 1)) == \ + ImageSet(Lambda(x, a*x), Interval(0, 1)) + + assert imageset(Lambda(x, sin(cos(x))), Interval(0, 1)) == \ + ImageSet(Lambda(x, sin(cos(x))), Interval(0, 1)) + + +def test_image_piecewise(): + f = Piecewise((x, x <= -1), (1/x**2, x <= 5), (x**3, True)) + f1 = Piecewise((0, x <= 1), (1, x <= 2), (2, True)) + assert imageset(x, f, Interval(-5, 5)) == Union(Interval(-5, -1), Interval(Rational(1, 25), oo)) + assert imageset(x, f1, Interval(1, 2)) == FiniteSet(0, 1) + + +@XFAIL # See: https://github.com/sympy/sympy/pull/2723#discussion_r8659826 +def test_image_Intersection(): + x = Symbol('x', real=True) + y = Symbol('y', real=True) + assert imageset(x, x**2, Interval(-2, 0).intersect(Interval(x, y))) == \ + Interval(0, 4).intersect(Interval(Min(x**2, y**2), Max(x**2, y**2))) + + +def test_image_FiniteSet(): + x = Symbol('x', real=True) + assert imageset(x, 2*x, FiniteSet(1, 2, 3)) == FiniteSet(2, 4, 6) + + +def test_image_Union(): + x = Symbol('x', real=True) + assert imageset(x, x**2, Interval(-2, 0) + FiniteSet(1, 2, 3)) == \ + (Interval(0, 4) + FiniteSet(9)) + + +def test_image_EmptySet(): + x = Symbol('x', real=True) + assert imageset(x, 2*x, S.EmptySet) == S.EmptySet + + +def test_issue_5724_7680(): + assert I not in S.Reals # issue 7680 + assert Interval(-oo, oo).contains(I) is S.false + + +def test_boundary(): + assert FiniteSet(1).boundary == FiniteSet(1) + assert all(Interval(0, 1, left_open, right_open).boundary == FiniteSet(0, 1) + for left_open in (true, false) for right_open in (true, false)) + + +def test_boundary_Union(): + assert (Interval(0, 1) + Interval(2, 3)).boundary == FiniteSet(0, 1, 2, 3) + assert ((Interval(0, 1, False, True) + + Interval(1, 2, True, False)).boundary == FiniteSet(0, 1, 2)) + + assert (Interval(0, 1) + FiniteSet(2)).boundary == FiniteSet(0, 1, 2) + assert Union(Interval(0, 10), Interval(5, 15), evaluate=False).boundary \ + == FiniteSet(0, 15) + + assert Union(Interval(0, 10), Interval(0, 1), evaluate=False).boundary \ + == FiniteSet(0, 10) + assert Union(Interval(0, 10, True, True), + Interval(10, 15, True, True), evaluate=False).boundary \ + == FiniteSet(0, 10, 15) + + +@XFAIL +def test_union_boundary_of_joining_sets(): + """ Testing the boundary of unions is a hard problem """ + assert Union(Interval(0, 10), Interval(10, 15), evaluate=False).boundary \ + == FiniteSet(0, 15) + + +def test_boundary_ProductSet(): + open_square = Interval(0, 1, True, True) ** 2 + assert open_square.boundary == (FiniteSet(0, 1) * Interval(0, 1) + + Interval(0, 1) * FiniteSet(0, 1)) + + second_square = Interval(1, 2, True, True) * Interval(0, 1, True, True) + assert (open_square + second_square).boundary == ( + FiniteSet(0, 1) * Interval(0, 1) + + FiniteSet(1, 2) * Interval(0, 1) + + Interval(0, 1) * FiniteSet(0, 1) + + Interval(1, 2) * FiniteSet(0, 1)) + + +def test_boundary_ProductSet_line(): + line_in_r2 = Interval(0, 1) * FiniteSet(0) + assert line_in_r2.boundary == line_in_r2 + + +def test_is_open(): + assert Interval(0, 1, False, False).is_open is False + assert Interval(0, 1, True, False).is_open is False + assert Interval(0, 1, True, True).is_open is True + assert FiniteSet(1, 2, 3).is_open is False + + +def test_is_closed(): + assert Interval(0, 1, False, False).is_closed is True + assert Interval(0, 1, True, False).is_closed is False + assert FiniteSet(1, 2, 3).is_closed is True + + +def test_closure(): + assert Interval(0, 1, False, True).closure == Interval(0, 1, False, False) + + +def test_interior(): + assert Interval(0, 1, False, True).interior == Interval(0, 1, True, True) + + +def test_issue_7841(): + raises(TypeError, lambda: x in S.Reals) + + +def test_Eq(): + assert Eq(Interval(0, 1), Interval(0, 1)) + assert Eq(Interval(0, 1), Interval(0, 2)) == False + + s1 = FiniteSet(0, 1) + s2 = FiniteSet(1, 2) + + assert Eq(s1, s1) + assert Eq(s1, s2) == False + + assert Eq(s1*s2, s1*s2) + assert Eq(s1*s2, s2*s1) == False + + assert unchanged(Eq, FiniteSet({x, y}), FiniteSet({x})) + assert Eq(FiniteSet({x, y}).subs(y, x), FiniteSet({x})) is S.true + assert Eq(FiniteSet({x, y}), FiniteSet({x})).subs(y, x) is S.true + assert Eq(FiniteSet({x, y}).subs(y, x+1), FiniteSet({x})) is S.false + assert Eq(FiniteSet({x, y}), FiniteSet({x})).subs(y, x+1) is S.false + + assert Eq(ProductSet({1}, {2}), Interval(1, 2)) is S.false + assert Eq(ProductSet({1}), ProductSet({1}, {2})) is S.false + + assert Eq(FiniteSet(()), FiniteSet(1)) is S.false + assert Eq(ProductSet(), FiniteSet(1)) is S.false + + i1 = Interval(0, 1) + i2 = Interval(x, y) + assert unchanged(Eq, ProductSet(i1, i1), ProductSet(i2, i2)) + + +def test_SymmetricDifference(): + A = FiniteSet(0, 1, 2, 3, 4, 5) + B = FiniteSet(2, 4, 6, 8, 10) + C = Interval(8, 10) + + assert SymmetricDifference(A, B, evaluate=False).is_iterable is True + assert SymmetricDifference(A, C, evaluate=False).is_iterable is None + assert FiniteSet(*SymmetricDifference(A, B, evaluate=False)) == \ + FiniteSet(0, 1, 3, 5, 6, 8, 10) + raises(TypeError, + lambda: FiniteSet(*SymmetricDifference(A, C, evaluate=False))) + + assert SymmetricDifference(FiniteSet(0, 1, 2, 3, 4, 5), \ + FiniteSet(2, 4, 6, 8, 10)) == FiniteSet(0, 1, 3, 5, 6, 8, 10) + assert SymmetricDifference(FiniteSet(2, 3, 4), FiniteSet(2, 3, 4 ,5)) \ + == FiniteSet(5) + assert FiniteSet(1, 2, 3, 4, 5) ^ FiniteSet(1, 2, 5, 6) == \ + FiniteSet(3, 4, 6) + assert Set(S(1), S(2), S(3)) ^ Set(S(2), S(3), S(4)) == Union(Set(S(1), S(2), S(3)) - Set(S(2), S(3), S(4)), \ + Set(S(2), S(3), S(4)) - Set(S(1), S(2), S(3))) + assert Interval(0, 4) ^ Interval(2, 5) == Union(Interval(0, 4) - \ + Interval(2, 5), Interval(2, 5) - Interval(0, 4)) + + +def test_issue_9536(): + from sympy.functions.elementary.exponential import log + a = Symbol('a', real=True) + assert FiniteSet(log(a)).intersect(S.Reals) == Intersection(S.Reals, FiniteSet(log(a))) + + +def test_issue_9637(): + n = Symbol('n') + a = FiniteSet(n) + b = FiniteSet(2, n) + assert Complement(S.Reals, a) == Complement(S.Reals, a, evaluate=False) + assert Complement(Interval(1, 3), a) == Complement(Interval(1, 3), a, evaluate=False) + assert Complement(Interval(1, 3), b) == \ + Complement(Union(Interval(1, 2, False, True), Interval(2, 3, True, False)), a) + assert Complement(a, S.Reals) == Complement(a, S.Reals, evaluate=False) + assert Complement(a, Interval(1, 3)) == Complement(a, Interval(1, 3), evaluate=False) + + +def test_issue_9808(): + # See https://github.com/sympy/sympy/issues/16342 + assert Complement(FiniteSet(y), FiniteSet(1)) == Complement(FiniteSet(y), FiniteSet(1), evaluate=False) + assert Complement(FiniteSet(1, 2, x), FiniteSet(x, y, 2, 3)) == \ + Complement(FiniteSet(1), FiniteSet(y), evaluate=False) + + +def test_issue_9956(): + assert Union(Interval(-oo, oo), FiniteSet(1)) == Interval(-oo, oo) + assert Interval(-oo, oo).contains(1) is S.true + + +def test_issue_Symbol_inter(): + i = Interval(0, oo) + r = S.Reals + mat = Matrix([0, 0, 0]) + assert Intersection(r, i, FiniteSet(m), FiniteSet(m, n)) == \ + Intersection(i, FiniteSet(m)) + assert Intersection(FiniteSet(1, m, n), FiniteSet(m, n, 2), i) == \ + Intersection(i, FiniteSet(m, n)) + assert Intersection(FiniteSet(m, n, x), FiniteSet(m, z), r) == \ + Intersection(Intersection({m, z}, {m, n, x}), r) + assert Intersection(FiniteSet(m, n, 3), FiniteSet(m, n, x), r) == \ + Intersection(FiniteSet(3, m, n), FiniteSet(m, n, x), r, evaluate=False) + assert Intersection(FiniteSet(m, n, 3), FiniteSet(m, n, 2, 3), r) == \ + Intersection(FiniteSet(3, m, n), r) + assert Intersection(r, FiniteSet(mat, 2, n), FiniteSet(0, mat, n)) == \ + Intersection(r, FiniteSet(n)) + assert Intersection(FiniteSet(sin(x), cos(x)), FiniteSet(sin(x), cos(x), 1), r) == \ + Intersection(r, FiniteSet(sin(x), cos(x))) + assert Intersection(FiniteSet(x**2, 1, sin(x)), FiniteSet(x**2, 2, sin(x)), r) == \ + Intersection(r, FiniteSet(x**2, sin(x))) + + +def test_issue_11827(): + assert S.Naturals0**4 + + +def test_issue_10113(): + f = x**2/(x**2 - 4) + assert imageset(x, f, S.Reals) == Union(Interval(-oo, 0), Interval(1, oo, True, True)) + assert imageset(x, f, Interval(-2, 2)) == Interval(-oo, 0) + assert imageset(x, f, Interval(-2, 3)) == Union(Interval(-oo, 0), Interval(Rational(9, 5), oo)) + + +def test_issue_10248(): + raises( + TypeError, lambda: list(Intersection(S.Reals, FiniteSet(x))) + ) + A = Symbol('A', real=True) + assert list(Intersection(S.Reals, FiniteSet(A))) == [A] + + +def test_issue_9447(): + a = Interval(0, 1) + Interval(2, 3) + assert Complement(S.UniversalSet, a) == Complement( + S.UniversalSet, Union(Interval(0, 1), Interval(2, 3)), evaluate=False) + assert Complement(S.Naturals, a) == Complement( + S.Naturals, Union(Interval(0, 1), Interval(2, 3)), evaluate=False) + + +def test_issue_10337(): + assert (FiniteSet(2) == 3) is False + assert (FiniteSet(2) != 3) is True + raises(TypeError, lambda: FiniteSet(2) < 3) + raises(TypeError, lambda: FiniteSet(2) <= 3) + raises(TypeError, lambda: FiniteSet(2) > 3) + raises(TypeError, lambda: FiniteSet(2) >= 3) + + +def test_issue_10326(): + bad = [ + EmptySet, + FiniteSet(1), + Interval(1, 2), + S.ComplexInfinity, + S.ImaginaryUnit, + S.Infinity, + S.NaN, + S.NegativeInfinity, + ] + interval = Interval(0, 5) + for i in bad: + assert i not in interval + + x = Symbol('x', real=True) + nr = Symbol('nr', extended_real=False) + assert x + 1 in Interval(x, x + 4) + assert nr not in Interval(x, x + 4) + assert Interval(1, 2) in FiniteSet(Interval(0, 5), Interval(1, 2)) + assert Interval(-oo, oo).contains(oo) is S.false + assert Interval(-oo, oo).contains(-oo) is S.false + + +def test_issue_2799(): + U = S.UniversalSet + a = Symbol('a', real=True) + inf_interval = Interval(a, oo) + R = S.Reals + + assert U + inf_interval == inf_interval + U + assert U + R == R + U + assert R + inf_interval == inf_interval + R + + +def test_issue_9706(): + assert Interval(-oo, 0).closure == Interval(-oo, 0, True, False) + assert Interval(0, oo).closure == Interval(0, oo, False, True) + assert Interval(-oo, oo).closure == Interval(-oo, oo) + + +def test_issue_8257(): + reals_plus_infinity = Union(Interval(-oo, oo), FiniteSet(oo)) + reals_plus_negativeinfinity = Union(Interval(-oo, oo), FiniteSet(-oo)) + assert Interval(-oo, oo) + FiniteSet(oo) == reals_plus_infinity + assert FiniteSet(oo) + Interval(-oo, oo) == reals_plus_infinity + assert Interval(-oo, oo) + FiniteSet(-oo) == reals_plus_negativeinfinity + assert FiniteSet(-oo) + Interval(-oo, oo) == reals_plus_negativeinfinity + + +def test_issue_10931(): + assert S.Integers - S.Integers == EmptySet + assert S.Integers - S.Reals == EmptySet + + +def test_issue_11174(): + soln = Intersection(Interval(-oo, oo), FiniteSet(-x), evaluate=False) + assert Intersection(FiniteSet(-x), S.Reals) == soln + + soln = Intersection(S.Reals, FiniteSet(x), evaluate=False) + assert Intersection(FiniteSet(x), S.Reals) == soln + + +def test_issue_18505(): + assert ImageSet(Lambda(n, sqrt(pi*n/2 - 1 + pi/2)), S.Integers).contains(0) == \ + Contains(0, ImageSet(Lambda(n, sqrt(pi*n/2 - 1 + pi/2)), S.Integers)) + + +def test_finite_set_intersection(): + # The following should not produce recursion errors + # Note: some of these are not completely correct. See + # https://github.com/sympy/sympy/issues/16342. + assert Intersection(FiniteSet(-oo, x), FiniteSet(x)) == FiniteSet(x) + assert Intersection._handle_finite_sets([FiniteSet(-oo, x), FiniteSet(0, x)]) == FiniteSet(x) + + assert Intersection._handle_finite_sets([FiniteSet(-oo, x), FiniteSet(x)]) == FiniteSet(x) + assert Intersection._handle_finite_sets([FiniteSet(2, 3, x, y), FiniteSet(1, 2, x)]) == \ + Intersection._handle_finite_sets([FiniteSet(1, 2, x), FiniteSet(2, 3, x, y)]) == \ + Intersection(FiniteSet(1, 2, x), FiniteSet(2, 3, x, y)) == \ + Intersection(FiniteSet(1, 2, x), FiniteSet(2, x, y)) + + assert FiniteSet(1+x-y) & FiniteSet(1) == \ + FiniteSet(1) & FiniteSet(1+x-y) == \ + Intersection(FiniteSet(1+x-y), FiniteSet(1), evaluate=False) + + assert FiniteSet(1) & FiniteSet(x) == FiniteSet(x) & FiniteSet(1) == \ + Intersection(FiniteSet(1), FiniteSet(x), evaluate=False) + + assert FiniteSet({x}) & FiniteSet({x, y}) == \ + Intersection(FiniteSet({x}), FiniteSet({x, y}), evaluate=False) + + +def test_union_intersection_constructor(): + # The actual exception does not matter here, so long as these fail + sets = [FiniteSet(1), FiniteSet(2)] + raises(Exception, lambda: Union(sets)) + raises(Exception, lambda: Intersection(sets)) + raises(Exception, lambda: Union(tuple(sets))) + raises(Exception, lambda: Intersection(tuple(sets))) + raises(Exception, lambda: Union(i for i in sets)) + raises(Exception, lambda: Intersection(i for i in sets)) + + # Python sets are treated the same as FiniteSet + # The union of a single set (of sets) is the set (of sets) itself + assert Union(set(sets)) == FiniteSet(*sets) + assert Intersection(set(sets)) == FiniteSet(*sets) + + assert Union({1}, {2}) == FiniteSet(1, 2) + assert Intersection({1, 2}, {2, 3}) == FiniteSet(2) + + +def test_Union_contains(): + assert zoo not in Union( + Interval.open(-oo, 0), Interval.open(0, oo)) + + +@XFAIL +def test_issue_16878b(): + # in intersection_sets for (ImageSet, Set) there is no code + # that handles the base_set of S.Reals like there is + # for Integers + assert imageset(x, (x, x), S.Reals).is_subset(S.Reals**2) is True + +def test_DisjointUnion(): + assert DisjointUnion(FiniteSet(1, 2, 3), FiniteSet(1, 2, 3), FiniteSet(1, 2, 3)).rewrite(Union) == (FiniteSet(1, 2, 3) * FiniteSet(0, 1, 2)) + assert DisjointUnion(Interval(1, 3), Interval(2, 4)).rewrite(Union) == Union(Interval(1, 3) * FiniteSet(0), Interval(2, 4) * FiniteSet(1)) + assert DisjointUnion(Interval(0, 5), Interval(0, 5)).rewrite(Union) == Union(Interval(0, 5) * FiniteSet(0), Interval(0, 5) * FiniteSet(1)) + assert DisjointUnion(Interval(-1, 2), S.EmptySet, S.EmptySet).rewrite(Union) == Interval(-1, 2) * FiniteSet(0) + assert DisjointUnion(Interval(-1, 2)).rewrite(Union) == Interval(-1, 2) * FiniteSet(0) + assert DisjointUnion(S.EmptySet, Interval(-1, 2), S.EmptySet).rewrite(Union) == Interval(-1, 2) * FiniteSet(1) + assert DisjointUnion(Interval(-oo, oo)).rewrite(Union) == Interval(-oo, oo) * FiniteSet(0) + assert DisjointUnion(S.EmptySet).rewrite(Union) == S.EmptySet + assert DisjointUnion().rewrite(Union) == S.EmptySet + raises(TypeError, lambda: DisjointUnion(Symbol('n'))) + + x = Symbol("x") + y = Symbol("y") + z = Symbol("z") + assert DisjointUnion(FiniteSet(x), FiniteSet(y, z)).rewrite(Union) == (FiniteSet(x) * FiniteSet(0)) + (FiniteSet(y, z) * FiniteSet(1)) + +def test_DisjointUnion_is_empty(): + assert DisjointUnion(S.EmptySet).is_empty is True + assert DisjointUnion(S.EmptySet, S.EmptySet).is_empty is True + assert DisjointUnion(S.EmptySet, FiniteSet(1, 2, 3)).is_empty is False + +def test_DisjointUnion_is_iterable(): + assert DisjointUnion(S.Integers, S.Naturals, S.Rationals).is_iterable is True + assert DisjointUnion(S.EmptySet, S.Reals).is_iterable is False + assert DisjointUnion(FiniteSet(1, 2, 3), S.EmptySet, FiniteSet(x, y)).is_iterable is True + assert DisjointUnion(S.EmptySet, S.EmptySet).is_iterable is False + +def test_DisjointUnion_contains(): + assert (0, 0) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (0, 1) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (0, 2) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (1, 0) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (1, 1) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (1, 2) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (2, 0) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (2, 1) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (2, 2) in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (0, 1, 2) not in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (0, 0.5) not in DisjointUnion(FiniteSet(0.5)) + assert (0, 5) not in DisjointUnion(FiniteSet(0, 1, 2), FiniteSet(0, 1, 2), FiniteSet(0, 1, 2)) + assert (x, 0) in DisjointUnion(FiniteSet(x, y, z), S.EmptySet, FiniteSet(y)) + assert (y, 0) in DisjointUnion(FiniteSet(x, y, z), S.EmptySet, FiniteSet(y)) + assert (z, 0) in DisjointUnion(FiniteSet(x, y, z), S.EmptySet, FiniteSet(y)) + assert (y, 2) in DisjointUnion(FiniteSet(x, y, z), S.EmptySet, FiniteSet(y)) + assert (0.5, 0) in DisjointUnion(Interval(0, 1), Interval(0, 2)) + assert (0.5, 1) in DisjointUnion(Interval(0, 1), Interval(0, 2)) + assert (1.5, 0) not in DisjointUnion(Interval(0, 1), Interval(0, 2)) + assert (1.5, 1) in DisjointUnion(Interval(0, 1), Interval(0, 2)) + +def test_DisjointUnion_iter(): + D = DisjointUnion(FiniteSet(3, 5, 7, 9), FiniteSet(x, y, z)) + it = iter(D) + L1 = [(x, 1), (y, 1), (z, 1)] + L2 = [(3, 0), (5, 0), (7, 0), (9, 0)] + nxt = next(it) + assert nxt in L2 + L2.remove(nxt) + nxt = next(it) + assert nxt in L1 + L1.remove(nxt) + nxt = next(it) + assert nxt in L2 + L2.remove(nxt) + nxt = next(it) + assert nxt in L1 + L1.remove(nxt) + nxt = next(it) + assert nxt in L2 + L2.remove(nxt) + nxt = next(it) + assert nxt in L1 + L1.remove(nxt) + nxt = next(it) + assert nxt in L2 + L2.remove(nxt) + raises(StopIteration, lambda: next(it)) + + raises(ValueError, lambda: iter(DisjointUnion(Interval(0, 1), S.EmptySet))) + +def test_DisjointUnion_len(): + assert len(DisjointUnion(FiniteSet(3, 5, 7, 9), FiniteSet(x, y, z))) == 7 + assert len(DisjointUnion(S.EmptySet, S.EmptySet, FiniteSet(x, y, z), S.EmptySet)) == 3 + raises(ValueError, lambda: len(DisjointUnion(Interval(0, 1), S.EmptySet))) + +def test_SetKind_ProductSet(): + p = ProductSet(FiniteSet(Matrix([1, 2])), FiniteSet(Matrix([1, 2]))) + mk = MatrixKind(NumberKind) + k = SetKind(TupleKind(mk, mk)) + assert p.kind is k + assert ProductSet(Interval(1, 2), FiniteSet(Matrix([1, 2]))).kind is SetKind(TupleKind(NumberKind, mk)) + +def test_SetKind_Interval(): + assert Interval(1, 2).kind is SetKind(NumberKind) + +def test_SetKind_EmptySet_UniversalSet(): + assert S.UniversalSet.kind is SetKind(UndefinedKind) + assert EmptySet.kind is SetKind() + +def test_SetKind_FiniteSet(): + assert FiniteSet(1, Matrix([1, 2])).kind is SetKind(UndefinedKind) + assert FiniteSet(1, 2).kind is SetKind(NumberKind) + +def test_SetKind_Unions(): + assert Union(FiniteSet(Matrix([1, 2])), Interval(1, 2)).kind is SetKind(UndefinedKind) + assert Union(Interval(1, 2), Interval(1, 7)).kind is SetKind(NumberKind) + +def test_SetKind_DisjointUnion(): + A = FiniteSet(1, 2, 3) + B = Interval(0, 5) + assert DisjointUnion(A, B).kind is SetKind(NumberKind) + +def test_SetKind_evaluate_False(): + U = lambda *args: Union(*args, evaluate=False) + assert U({1}, EmptySet).kind is SetKind(NumberKind) + assert U(Interval(1, 2), EmptySet).kind is SetKind(NumberKind) + assert U({1}, S.UniversalSet).kind is SetKind(UndefinedKind) + assert U(Interval(1, 2), Interval(4, 5), + FiniteSet(1)).kind is SetKind(NumberKind) + I = lambda *args: Intersection(*args, evaluate=False) + assert I({1}, S.UniversalSet).kind is SetKind(NumberKind) + assert I({1}, EmptySet).kind is SetKind() + C = lambda *args: Complement(*args, evaluate=False) + assert C(S.UniversalSet, {1, 2, 4, 5}).kind is SetKind(UndefinedKind) + assert C({1, 2, 3, 4, 5}, EmptySet).kind is SetKind(NumberKind) + assert C(EmptySet, {1, 2, 3, 4, 5}).kind is SetKind() + +def test_SetKind_ImageSet_Special(): + f = ImageSet(Lambda(n, n ** 2), Interval(1, 4)) + assert (f - FiniteSet(3)).kind is SetKind(NumberKind) + assert (f + Interval(16, 17)).kind is SetKind(NumberKind) + assert (f + FiniteSet(17)).kind is SetKind(NumberKind) + +def test_issue_20089(): + B = FiniteSet(FiniteSet(1, 2), FiniteSet(1)) + assert 1 not in B + assert 1.0 not in B + assert not Eq(1, FiniteSet(1, 2)) + assert FiniteSet(1) in B + A = FiniteSet(1, 2) + assert A in B + assert B.issubset(B) + assert not A.issubset(B) + assert 1 in A + C = FiniteSet(FiniteSet(1, 2), FiniteSet(1), 1, 2) + assert A.issubset(C) + assert B.issubset(C) + +def test_issue_19378(): + a = FiniteSet(1, 2) + b = ProductSet(a, a) + c = FiniteSet((1, 1), (1, 2), (2, 1), (2, 2)) + assert b.is_subset(c) is True + d = FiniteSet(1) + assert b.is_subset(d) is False + assert Eq(c, b).simplify() is S.true + assert Eq(a, c).simplify() is S.false + assert Eq({1}, {x}).simplify() == Eq({1}, {x}) + +def test_intersection_symbolic(): + n = Symbol('n') + # These should not throw an error + assert isinstance(Intersection(Range(n), Range(100)), Intersection) + assert isinstance(Intersection(Range(n), Interval(1, 100)), Intersection) + assert isinstance(Intersection(Range(100), Interval(1, n)), Intersection) + + +@XFAIL +def test_intersection_symbolic_failing(): + n = Symbol('n', integer=True, positive=True) + assert Intersection(Range(10, n), Range(4, 500, 5)) == Intersection( + Range(14, n), Range(14, 500, 5)) + assert Intersection(Interval(10, n), Range(4, 500, 5)) == Intersection( + Interval(14, n), Range(14, 500, 5)) + + +def test_issue_20379(): + #https://github.com/sympy/sympy/issues/20379 + x = pi - 3.14159265358979 + assert FiniteSet(x).evalf(2) == FiniteSet(Float('3.23108914886517e-15', 2)) + +def test_finiteset_simplify(): + S = FiniteSet(1, cos(1)**2 + sin(1)**2) + assert S.simplify() == {1} + +def test_issue_14336(): + #https://github.com/sympy/sympy/issues/14336 + U = S.Complexes + x = Symbol("x") + U -= U.intersect(Ne(x, 1).as_set()) + U -= U.intersect(S.true.as_set()) + +def test_issue_9855(): + #https://github.com/sympy/sympy/issues/9855 + x, y, z = symbols('x, y, z', real=True) + s1 = Interval(1, x) & Interval(y, 2) + s2 = Interval(1, 2) + assert s1.is_subset(s2) == None diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/__init__.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/__init__.py new file mode 100644 index 0000000000000000000000000000000000000000..0619d1c3ebbd6c6a7d663093c7ed2202114148af --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/__init__.py @@ -0,0 +1,60 @@ +"""The module helps converting SymPy expressions into shorter forms of them. + +for example: +the expression E**(pi*I) will be converted into -1 +the expression (x+x)**2 will be converted into 4*x**2 +""" +from .simplify import (simplify, hypersimp, hypersimilar, + logcombine, separatevars, posify, besselsimp, kroneckersimp, + signsimp, nsimplify) + +from .fu import FU, fu + +from .sqrtdenest import sqrtdenest + +from .cse_main import cse + +from .epathtools import epath, EPath + +from .hyperexpand import hyperexpand + +from .radsimp import collect, rcollect, radsimp, collect_const, fraction, numer, denom + +from .trigsimp import trigsimp, exptrigsimp + +from .powsimp import powsimp, powdenest + +from .combsimp import combsimp + +from .gammasimp import gammasimp + +from .ratsimp import ratsimp, ratsimpmodprime + +__all__ = [ + 'simplify', 'hypersimp', 'hypersimilar', 'logcombine', 'separatevars', + 'posify', 'besselsimp', 'kroneckersimp', 'signsimp', + 'nsimplify', + + 'FU', 'fu', + + 'sqrtdenest', + + 'cse', + + 'epath', 'EPath', + + 'hyperexpand', + + 'collect', 'rcollect', 'radsimp', 'collect_const', 'fraction', 'numer', + 'denom', + + 'trigsimp', 'exptrigsimp', + + 'powsimp', 'powdenest', + + 'combsimp', + + 'gammasimp', + + 'ratsimp', 'ratsimpmodprime', +] diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/_cse_diff.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/_cse_diff.py new file mode 100644 index 0000000000000000000000000000000000000000..3496ad3b31a4f45312cac002429be40aa9aa0868 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/_cse_diff.py @@ -0,0 +1,291 @@ +"""Module for differentiation using CSE.""" + +from sympy import cse, Matrix, Derivative, MatrixBase +from sympy.utilities.iterables import iterable + + +def _remove_cse_from_derivative(replacements, reduced_expressions): + """ + This function is designed to postprocess the output of a common subexpression + elimination (CSE) operation. Specifically, it removes any CSE replacement + symbols from the arguments of ``Derivative`` terms in the expression. This + is necessary to ensure that the forward Jacobian function correctly handles + derivative terms. + + Parameters + ========== + + replacements : list of (Symbol, expression) pairs + Replacement symbols and relative common subexpressions that have been + replaced during a CSE operation. + + reduced_expressions : list of SymPy expressions + The reduced expressions with all the replacements from the + replacements list above. + + Returns + ======= + + processed_replacements : list of (Symbol, expression) pairs + Processed replacement list, in the same format of the + ``replacements`` input list. + + processed_reduced : list of SymPy expressions + Processed reduced list, in the same format of the + ``reduced_expressions`` input list. + """ + + def traverse(node, repl_dict): + if isinstance(node, Derivative): + return replace_all(node, repl_dict) + if not node.args: + return node + new_args = [traverse(arg, repl_dict) for arg in node.args] + return node.func(*new_args) + + def replace_all(node, repl_dict): + result = node + while True: + free_symbols = result.free_symbols + symbols_dict = {k: repl_dict[k] for k in free_symbols if k in repl_dict} + if not symbols_dict: + break + result = result.xreplace(symbols_dict) + return result + + repl_dict = dict(replacements) + processed_replacements = [ + (rep_sym, traverse(sub_exp, repl_dict)) + for rep_sym, sub_exp in replacements + ] + processed_reduced = [ + red_exp.__class__([traverse(exp, repl_dict) for exp in red_exp]) + for red_exp in reduced_expressions + ] + + return processed_replacements, processed_reduced + + +def _forward_jacobian_cse(replacements, reduced_expr, wrt): + """ + Core function to compute the Jacobian of an input Matrix of expressions + through forward accumulation. Takes directly the output of a CSE operation + (replacements and reduced_expr), and an iterable of variables (wrt) with + respect to which to differentiate the reduced expression and returns the + reduced Jacobian matrix and the ``replacements`` list. + + The function also returns a list of precomputed free symbols for each + subexpression, which are useful in the substitution process. + + Parameters + ========== + + replacements : list of (Symbol, expression) pairs + Replacement symbols and relative common subexpressions that have been + replaced during a CSE operation. + + reduced_expr : list of SymPy expressions + The reduced expressions with all the replacements from the + replacements list above. + + wrt : iterable + Iterable of expressions with respect to which to compute the + Jacobian matrix. + + Returns + ======= + + replacements : list of (Symbol, expression) pairs + Replacement symbols and relative common subexpressions that have been + replaced during a CSE operation. Compared to the input replacement list, + the output one doesn't contain replacement symbols inside + ``Derivative``'s arguments. + + jacobian : list of SymPy expressions + The list only contains one element, which is the Jacobian matrix with + elements in reduced form (replacement symbols are present). + + precomputed_fs: list + List of sets, which store the free symbols present in each sub-expression. + Useful in the substitution process. + """ + + if not isinstance(reduced_expr[0], MatrixBase): + raise TypeError("``expr`` must be of matrix type") + + if not (reduced_expr[0].shape[0] == 1 or reduced_expr[0].shape[1] == 1): + raise TypeError("``expr`` must be a row or a column matrix") + + if not iterable(wrt): + raise TypeError("``wrt`` must be an iterable of variables") + + elif not isinstance(wrt, MatrixBase): + wrt = Matrix(wrt) + + if not (wrt.shape[0] == 1 or wrt.shape[1] == 1): + raise TypeError("``wrt`` must be a row or a column matrix") + + replacements, reduced_expr = _remove_cse_from_derivative(replacements, reduced_expr) + + if replacements: + rep_sym, sub_expr = map(Matrix, zip(*replacements)) + else: + rep_sym, sub_expr = Matrix([]), Matrix([]) + + l_sub, l_wrt, l_red = len(sub_expr), len(wrt), len(reduced_expr[0]) + + f1 = reduced_expr[0].__class__.from_dok(l_red, l_wrt, + { + (i, j): diff_value + for i, r in enumerate(reduced_expr[0]) + for j, w in enumerate(wrt) + if (diff_value := r.diff(w)) != 0 + }, + ) + + if not replacements: + return [], [f1], [] + + f2 = Matrix.from_dok(l_red, l_sub, + { + (i, j): diff_value + for i, (r, fs) in enumerate([(r, r.free_symbols) for r in reduced_expr[0]]) + for j, s in enumerate(rep_sym) + if s in fs and (diff_value := r.diff(s)) != 0 + }, + ) + + rep_sym_set = set(rep_sym) + precomputed_fs = [s.free_symbols & rep_sym_set for s in sub_expr ] + + c_matrix = Matrix.from_dok(1, l_wrt, + {(0, j): diff_value for j, w in enumerate(wrt) + if (diff_value := sub_expr[0].diff(w)) != 0}) + + for i in range(1, l_sub): + + bi_matrix = Matrix.from_dok(1, i, + {(0, j): diff_value for j in range(i + 1) + if rep_sym[j] in precomputed_fs[i] + and (diff_value := sub_expr[i].diff(rep_sym[j])) != 0}) + + ai_matrix = Matrix.from_dok(1, l_wrt, + {(0, j): diff_value for j, w in enumerate(wrt) + if (diff_value := sub_expr[i].diff(w)) != 0}) + + if bi_matrix._rep.nnz(): + ci_matrix = bi_matrix.multiply(c_matrix).add(ai_matrix) + c_matrix = Matrix.vstack(c_matrix, ci_matrix) + else: + c_matrix = Matrix.vstack(c_matrix, ai_matrix) + + jacobian = f2.multiply(c_matrix).add(f1) + jacobian = [reduced_expr[0].__class__(jacobian)] + + return replacements, jacobian, precomputed_fs + + +def _forward_jacobian_norm_in_cse_out(expr, wrt): + """ + Function to compute the Jacobian of an input Matrix of expressions through + forward accumulation. Takes a sympy Matrix of expressions (expr) as input + and an iterable of variables (wrt) with respect to which to compute the + Jacobian matrix. The matrix is returned in reduced form (containing + replacement symbols) along with the ``replacements`` list. + + The function also returns a list of precomputed free symbols for each + subexpression, which are useful in the substitution process. + + Parameters + ========== + + expr : Matrix + The vector to be differentiated. + + wrt : iterable + The vector with respect to which to perform the differentiation. + Can be a matrix or an iterable of variables. + + Returns + ======= + + replacements : list of (Symbol, expression) pairs + Replacement symbols and relative common subexpressions that have been + replaced during a CSE operation. The output replacement list doesn't + contain replacement symbols inside ``Derivative``'s arguments. + + jacobian : list of SymPy expressions + The list only contains one element, which is the Jacobian matrix with + elements in reduced form (replacement symbols are present). + + precomputed_fs: list + List of sets, which store the free symbols present in each + sub-expression. Useful in the substitution process. + """ + + replacements, reduced_expr = cse(expr) + replacements, jacobian, precomputed_fs = _forward_jacobian_cse(replacements, reduced_expr, wrt) + + return replacements, jacobian, precomputed_fs + + +def _forward_jacobian(expr, wrt): + """ + Function to compute the Jacobian of an input Matrix of expressions through + forward accumulation. Takes a sympy Matrix of expressions (expr) as input + and an iterable of variables (wrt) with respect to which to compute the + Jacobian matrix. + + Explanation + =========== + + Expressions often contain repeated subexpressions. Using a tree structure, + these subexpressions are duplicated and differentiated multiple times, + leading to inefficiency. + + Instead, if a data structure called a directed acyclic graph (DAG) is used + then each of these repeated subexpressions will only exist a single time. + This function uses a combination of representing the expression as a DAG and + a forward accumulation algorithm (repeated application of the chain rule + symbolically) to more efficiently calculate the Jacobian matrix of a target + expression ``expr`` with respect to an expression or set of expressions + ``wrt``. + + Note that this function is intended to improve performance when + differentiating large expressions that contain many common subexpressions. + For small and simple expressions it is likely less performant than using + SymPy's standard differentiation functions and methods. + + Parameters + ========== + + expr : Matrix + The vector to be differentiated. + + wrt : iterable + The vector with respect to which to do the differentiation. + Can be a matrix or an iterable of variables. + + See Also + ======== + + Direct Acyclic Graph : https://en.wikipedia.org/wiki/Directed_acyclic_graph + """ + + replacements, reduced_expr = cse(expr) + + if replacements: + rep_sym, _ = map(Matrix, zip(*replacements)) + else: + rep_sym = Matrix([]) + + replacements, jacobian, precomputed_fs = _forward_jacobian_cse(replacements, reduced_expr, wrt) + + if not replacements: return jacobian[0] + + sub_rep = dict(replacements) + for i, ik in enumerate(precomputed_fs): + sub_dict = {j: sub_rep[j] for j in ik} + sub_rep[rep_sym[i]] = sub_rep[rep_sym[i]].xreplace(sub_dict) + + return jacobian[0].xreplace(sub_rep) diff --git a/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/combsimp.py b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/combsimp.py new file mode 100644 index 0000000000000000000000000000000000000000..8b0b3cefcba11b4b7759b7d3ec3c2d4415cfd849 --- /dev/null +++ b/miniconda3/envs/ladir/lib/python3.10/site-packages/sympy/simplify/combsimp.py @@ -0,0 +1,114 @@ +from sympy.core import Mul +from sympy.core.function import count_ops +from sympy.core.traversal import preorder_traversal, bottom_up +from sympy.functions.combinatorial.factorials import binomial, factorial +from sympy.functions import gamma +from sympy.simplify.gammasimp import gammasimp, _gammasimp + +from sympy.utilities.timeutils import timethis + + +@timethis('combsimp') +def combsimp(expr): + r""" + Simplify combinatorial expressions. + + Explanation + =========== + + This function takes as input an expression containing factorials, + binomials, Pochhammer symbol and other "combinatorial" functions, + and tries to minimize the number of those functions and reduce + the size of their arguments. + + The algorithm works by rewriting all combinatorial functions as + gamma functions and applying gammasimp() except simplification + steps that may make an integer argument non-integer. See docstring + of gammasimp for more information. + + Then it rewrites expression in terms of factorials and binomials by + rewriting gammas as factorials and converting (a+b)!/a!b! into + binomials. + + If expression has gamma functions or combinatorial functions + with non-integer argument, it is automatically passed to gammasimp. + + Examples + ======== + + >>> from sympy.simplify import combsimp + >>> from sympy import factorial, binomial, symbols + >>> n, k = symbols('n k', integer = True) + + >>> combsimp(factorial(n)/factorial(n - 3)) + n*(n - 2)*(n - 1) + >>> combsimp(binomial(n+1, k+1)/binomial(n, k)) + (n + 1)/(k + 1) + + """ + + expr = expr.rewrite(gamma, piecewise=False) + if any(isinstance(node, gamma) and not node.args[0].is_integer + for node in preorder_traversal(expr)): + return gammasimp(expr) + + expr = _gammasimp(expr, as_comb = True) + expr = _gamma_as_comb(expr) + return expr + + +def _gamma_as_comb(expr): + """ + Helper function for combsimp. + + Rewrites expression in terms of factorials and binomials + """ + + expr = expr.rewrite(factorial) + + def f(rv): + if not rv.is_Mul: + return rv + rvd = rv.as_powers_dict() + nd_fact_args = [[], []] # numerator, denominator + + for k in rvd: + if isinstance(k, factorial) and rvd[k].is_Integer: + if rvd[k].is_positive: + nd_fact_args[0].extend([k.args[0]]*rvd[k]) + else: + nd_fact_args[1].extend([k.args[0]]*-rvd[k]) + rvd[k] = 0 + if not nd_fact_args[0] or not nd_fact_args[1]: + return rv + + hit = False + for m in range(2): + i = 0 + while i < len(nd_fact_args[m]): + ai = nd_fact_args[m][i] + for j in range(i + 1, len(nd_fact_args[m])): + aj = nd_fact_args[m][j] + + sum = ai + aj + if sum in nd_fact_args[1 - m]: + hit = True + + nd_fact_args[1 - m].remove(sum) + del nd_fact_args[m][j] + del nd_fact_args[m][i] + + rvd[binomial(sum, ai if count_ops(ai) < + count_ops(aj) else aj)] += ( + -1 if m == 0 else 1) + break + else: + i += 1 + + if hit: + return Mul(*([k**rvd[k] for k in rvd] + [factorial(k) + for k in nd_fact_args[0]]))/Mul(*[factorial(k) + for k in nd_fact_args[1]]) + return rv + + return bottom_up(expr, f)