| | """Sparse rational function fields. """ |
| |
|
| | from __future__ import annotations |
| | from typing import Any |
| | from functools import reduce |
| |
|
| | from operator import add, mul, lt, le, gt, ge |
| |
|
| | from sympy.core.expr import Expr |
| | from sympy.core.mod import Mod |
| | from sympy.core.numbers import Exp1 |
| | from sympy.core.singleton import S |
| | from sympy.core.symbol import Symbol |
| | from sympy.core.sympify import CantSympify, sympify |
| | from sympy.functions.elementary.exponential import ExpBase |
| | from sympy.polys.domains.domainelement import DomainElement |
| | from sympy.polys.domains.fractionfield import FractionField |
| | from sympy.polys.domains.polynomialring import PolynomialRing |
| | from sympy.polys.constructor import construct_domain |
| | from sympy.polys.orderings import lex |
| | from sympy.polys.polyerrors import CoercionFailed |
| | from sympy.polys.polyoptions import build_options |
| | from sympy.polys.polyutils import _parallel_dict_from_expr |
| | from sympy.polys.rings import PolyElement |
| | from sympy.printing.defaults import DefaultPrinting |
| | from sympy.utilities import public |
| | from sympy.utilities.iterables import is_sequence |
| | from sympy.utilities.magic import pollute |
| |
|
| | @public |
| | def field(symbols, domain, order=lex): |
| | """Construct new rational function field returning (field, x1, ..., xn). """ |
| | _field = FracField(symbols, domain, order) |
| | return (_field,) + _field.gens |
| |
|
| | @public |
| | def xfield(symbols, domain, order=lex): |
| | """Construct new rational function field returning (field, (x1, ..., xn)). """ |
| | _field = FracField(symbols, domain, order) |
| | return (_field, _field.gens) |
| |
|
| | @public |
| | def vfield(symbols, domain, order=lex): |
| | """Construct new rational function field and inject generators into global namespace. """ |
| | _field = FracField(symbols, domain, order) |
| | pollute([ sym.name for sym in _field.symbols ], _field.gens) |
| | return _field |
| |
|
| | @public |
| | def sfield(exprs, *symbols, **options): |
| | """Construct a field deriving generators and domain |
| | from options and input expressions. |
| | |
| | Parameters |
| | ========== |
| | |
| | exprs : py:class:`~.Expr` or sequence of :py:class:`~.Expr` (sympifiable) |
| | |
| | symbols : sequence of :py:class:`~.Symbol`/:py:class:`~.Expr` |
| | |
| | options : keyword arguments understood by :py:class:`~.Options` |
| | |
| | Examples |
| | ======== |
| | |
| | >>> from sympy import exp, log, symbols, sfield |
| | |
| | >>> x = symbols("x") |
| | >>> K, f = sfield((x*log(x) + 4*x**2)*exp(1/x + log(x)/3)/x**2) |
| | >>> K |
| | Rational function field in x, exp(1/x), log(x), x**(1/3) over ZZ with lex order |
| | >>> f |
| | (4*x**2*(exp(1/x)) + x*(exp(1/x))*(log(x)))/((x**(1/3))**5) |
| | """ |
| | single = False |
| | if not is_sequence(exprs): |
| | exprs, single = [exprs], True |
| |
|
| | exprs = list(map(sympify, exprs)) |
| | opt = build_options(symbols, options) |
| | numdens = [] |
| | for expr in exprs: |
| | numdens.extend(expr.as_numer_denom()) |
| | reps, opt = _parallel_dict_from_expr(numdens, opt) |
| |
|
| | if opt.domain is None: |
| | |
| | |
| | coeffs = sum([list(rep.values()) for rep in reps], []) |
| | opt.domain, _ = construct_domain(coeffs, opt=opt) |
| |
|
| | _field = FracField(opt.gens, opt.domain, opt.order) |
| | fracs = [] |
| | for i in range(0, len(reps), 2): |
| | fracs.append(_field(tuple(reps[i:i+2]))) |
| |
|
| | if single: |
| | return (_field, fracs[0]) |
| | else: |
| | return (_field, fracs) |
| |
|
| | _field_cache: dict[Any, Any] = {} |
| |
|
| | class FracField(DefaultPrinting): |
| | """Multivariate distributed rational function field. """ |
| |
|
| | def __new__(cls, symbols, domain, order=lex): |
| | from sympy.polys.rings import PolyRing |
| | ring = PolyRing(symbols, domain, order) |
| | symbols = ring.symbols |
| | ngens = ring.ngens |
| | domain = ring.domain |
| | order = ring.order |
| |
|
| | _hash_tuple = (cls.__name__, symbols, ngens, domain, order) |
| | obj = _field_cache.get(_hash_tuple) |
| |
|
| | if obj is None: |
| | obj = object.__new__(cls) |
| | obj._hash_tuple = _hash_tuple |
| | obj._hash = hash(_hash_tuple) |
| | obj.ring = ring |
| | obj.dtype = type("FracElement", (FracElement,), {"field": obj}) |
| | obj.symbols = symbols |
| | obj.ngens = ngens |
| | obj.domain = domain |
| | obj.order = order |
| |
|
| | obj.zero = obj.dtype(ring.zero) |
| | obj.one = obj.dtype(ring.one) |
| |
|
| | obj.gens = obj._gens() |
| |
|
| | for symbol, generator in zip(obj.symbols, obj.gens): |
| | if isinstance(symbol, Symbol): |
| | name = symbol.name |
| |
|
| | if not hasattr(obj, name): |
| | setattr(obj, name, generator) |
| |
|
| | _field_cache[_hash_tuple] = obj |
| |
|
| | return obj |
| |
|
| | def _gens(self): |
| | """Return a list of polynomial generators. """ |
| | return tuple([ self.dtype(gen) for gen in self.ring.gens ]) |
| |
|
| | def __getnewargs__(self): |
| | return (self.symbols, self.domain, self.order) |
| |
|
| | def __hash__(self): |
| | return self._hash |
| |
|
| | def index(self, gen): |
| | if isinstance(gen, self.dtype): |
| | return self.ring.index(gen.to_poly()) |
| | else: |
| | raise ValueError("expected a %s, got %s instead" % (self.dtype,gen)) |
| |
|
| | def __eq__(self, other): |
| | return isinstance(other, FracField) and \ |
| | (self.symbols, self.ngens, self.domain, self.order) == \ |
| | (other.symbols, other.ngens, other.domain, other.order) |
| |
|
| | def __ne__(self, other): |
| | return not self == other |
| |
|
| | def raw_new(self, numer, denom=None): |
| | return self.dtype(numer, denom) |
| | def new(self, numer, denom=None): |
| | if denom is None: denom = self.ring.one |
| | numer, denom = numer.cancel(denom) |
| | return self.raw_new(numer, denom) |
| |
|
| | def domain_new(self, element): |
| | return self.domain.convert(element) |
| |
|
| | def ground_new(self, element): |
| | try: |
| | return self.new(self.ring.ground_new(element)) |
| | except CoercionFailed: |
| | domain = self.domain |
| |
|
| | if not domain.is_Field and domain.has_assoc_Field: |
| | ring = self.ring |
| | ground_field = domain.get_field() |
| | element = ground_field.convert(element) |
| | numer = ring.ground_new(ground_field.numer(element)) |
| | denom = ring.ground_new(ground_field.denom(element)) |
| | return self.raw_new(numer, denom) |
| | else: |
| | raise |
| |
|
| | def field_new(self, element): |
| | if isinstance(element, FracElement): |
| | if self == element.field: |
| | return element |
| |
|
| | if isinstance(self.domain, FractionField) and \ |
| | self.domain.field == element.field: |
| | return self.ground_new(element) |
| | elif isinstance(self.domain, PolynomialRing) and \ |
| | self.domain.ring.to_field() == element.field: |
| | return self.ground_new(element) |
| | else: |
| | raise NotImplementedError("conversion") |
| | elif isinstance(element, PolyElement): |
| | denom, numer = element.clear_denoms() |
| |
|
| | if isinstance(self.domain, PolynomialRing) and \ |
| | numer.ring == self.domain.ring: |
| | numer = self.ring.ground_new(numer) |
| | elif isinstance(self.domain, FractionField) and \ |
| | numer.ring == self.domain.field.to_ring(): |
| | numer = self.ring.ground_new(numer) |
| | else: |
| | numer = numer.set_ring(self.ring) |
| |
|
| | denom = self.ring.ground_new(denom) |
| | return self.raw_new(numer, denom) |
| | elif isinstance(element, tuple) and len(element) == 2: |
| | numer, denom = list(map(self.ring.ring_new, element)) |
| | return self.new(numer, denom) |
| | elif isinstance(element, str): |
| | raise NotImplementedError("parsing") |
| | elif isinstance(element, Expr): |
| | return self.from_expr(element) |
| | else: |
| | return self.ground_new(element) |
| |
|
| | __call__ = field_new |
| |
|
| | def _rebuild_expr(self, expr, mapping): |
| | domain = self.domain |
| | powers = tuple((gen, gen.as_base_exp()) for gen in mapping.keys() |
| | if gen.is_Pow or isinstance(gen, ExpBase)) |
| |
|
| | def _rebuild(expr): |
| | generator = mapping.get(expr) |
| |
|
| | if generator is not None: |
| | return generator |
| | elif expr.is_Add: |
| | return reduce(add, list(map(_rebuild, expr.args))) |
| | elif expr.is_Mul: |
| | return reduce(mul, list(map(_rebuild, expr.args))) |
| | elif expr.is_Pow or isinstance(expr, (ExpBase, Exp1)): |
| | b, e = expr.as_base_exp() |
| | |
| | for gen, (bg, eg) in powers: |
| | if bg == b and Mod(e, eg) == 0: |
| | return mapping.get(gen)**int(e/eg) |
| | if e.is_Integer and e is not S.One: |
| | return _rebuild(b)**int(e) |
| | elif mapping.get(1/expr) is not None: |
| | return 1/mapping.get(1/expr) |
| |
|
| | try: |
| | return domain.convert(expr) |
| | except CoercionFailed: |
| | if not domain.is_Field and domain.has_assoc_Field: |
| | return domain.get_field().convert(expr) |
| | else: |
| | raise |
| |
|
| | return _rebuild(expr) |
| |
|
| | def from_expr(self, expr): |
| | mapping = dict(list(zip(self.symbols, self.gens))) |
| |
|
| | try: |
| | frac = self._rebuild_expr(sympify(expr), mapping) |
| | except CoercionFailed: |
| | raise ValueError("expected an expression convertible to a rational function in %s, got %s" % (self, expr)) |
| | else: |
| | return self.field_new(frac) |
| |
|
| | def to_domain(self): |
| | return FractionField(self) |
| |
|
| | def to_ring(self): |
| | from sympy.polys.rings import PolyRing |
| | return PolyRing(self.symbols, self.domain, self.order) |
| |
|
| | class FracElement(DomainElement, DefaultPrinting, CantSympify): |
| | """Element of multivariate distributed rational function field. """ |
| |
|
| | def __init__(self, numer, denom=None): |
| | if denom is None: |
| | denom = self.field.ring.one |
| | elif not denom: |
| | raise ZeroDivisionError("zero denominator") |
| |
|
| | self.numer = numer |
| | self.denom = denom |
| |
|
| | def raw_new(f, numer, denom): |
| | return f.__class__(numer, denom) |
| | def new(f, numer, denom): |
| | return f.raw_new(*numer.cancel(denom)) |
| |
|
| | def to_poly(f): |
| | if f.denom != 1: |
| | raise ValueError("f.denom should be 1") |
| | return f.numer |
| |
|
| | def parent(self): |
| | return self.field.to_domain() |
| |
|
| | def __getnewargs__(self): |
| | return (self.field, self.numer, self.denom) |
| |
|
| | _hash = None |
| |
|
| | def __hash__(self): |
| | _hash = self._hash |
| | if _hash is None: |
| | self._hash = _hash = hash((self.field, self.numer, self.denom)) |
| | return _hash |
| |
|
| | def copy(self): |
| | return self.raw_new(self.numer.copy(), self.denom.copy()) |
| |
|
| | def set_field(self, new_field): |
| | if self.field == new_field: |
| | return self |
| | else: |
| | new_ring = new_field.ring |
| | numer = self.numer.set_ring(new_ring) |
| | denom = self.denom.set_ring(new_ring) |
| | return new_field.new(numer, denom) |
| |
|
| | def as_expr(self, *symbols): |
| | return self.numer.as_expr(*symbols)/self.denom.as_expr(*symbols) |
| |
|
| | def __eq__(f, g): |
| | if isinstance(g, FracElement) and f.field == g.field: |
| | return f.numer == g.numer and f.denom == g.denom |
| | else: |
| | return f.numer == g and f.denom == f.field.ring.one |
| |
|
| | def __ne__(f, g): |
| | return not f == g |
| |
|
| | def __bool__(f): |
| | return bool(f.numer) |
| |
|
| | def sort_key(self): |
| | return (self.denom.sort_key(), self.numer.sort_key()) |
| |
|
| | def _cmp(f1, f2, op): |
| | if isinstance(f2, f1.field.dtype): |
| | return op(f1.sort_key(), f2.sort_key()) |
| | else: |
| | return NotImplemented |
| |
|
| | def __lt__(f1, f2): |
| | return f1._cmp(f2, lt) |
| | def __le__(f1, f2): |
| | return f1._cmp(f2, le) |
| | def __gt__(f1, f2): |
| | return f1._cmp(f2, gt) |
| | def __ge__(f1, f2): |
| | return f1._cmp(f2, ge) |
| |
|
| | def __pos__(f): |
| | """Negate all coefficients in ``f``. """ |
| | return f.raw_new(f.numer, f.denom) |
| |
|
| | def __neg__(f): |
| | """Negate all coefficients in ``f``. """ |
| | return f.raw_new(-f.numer, f.denom) |
| |
|
| | def _extract_ground(self, element): |
| | domain = self.field.domain |
| |
|
| | try: |
| | element = domain.convert(element) |
| | except CoercionFailed: |
| | if not domain.is_Field and domain.has_assoc_Field: |
| | ground_field = domain.get_field() |
| |
|
| | try: |
| | element = ground_field.convert(element) |
| | except CoercionFailed: |
| | pass |
| | else: |
| | return -1, ground_field.numer(element), ground_field.denom(element) |
| |
|
| | return 0, None, None |
| | else: |
| | return 1, element, None |
| |
|
| | def __add__(f, g): |
| | """Add rational functions ``f`` and ``g``. """ |
| | field = f.field |
| |
|
| | if not g: |
| | return f |
| | elif not f: |
| | return g |
| | elif isinstance(g, field.dtype): |
| | if f.denom == g.denom: |
| | return f.new(f.numer + g.numer, f.denom) |
| | else: |
| | return f.new(f.numer*g.denom + f.denom*g.numer, f.denom*g.denom) |
| | elif isinstance(g, field.ring.dtype): |
| | return f.new(f.numer + f.denom*g, f.denom) |
| | else: |
| | if isinstance(g, FracElement): |
| | if isinstance(field.domain, FractionField) and field.domain.field == g.field: |
| | pass |
| | elif isinstance(g.field.domain, FractionField) and g.field.domain.field == field: |
| | return g.__radd__(f) |
| | else: |
| | return NotImplemented |
| | elif isinstance(g, PolyElement): |
| | if isinstance(field.domain, PolynomialRing) and field.domain.ring == g.ring: |
| | pass |
| | else: |
| | return g.__radd__(f) |
| |
|
| | return f.__radd__(g) |
| |
|
| | def __radd__(f, c): |
| | if isinstance(c, f.field.ring.dtype): |
| | return f.new(f.numer + f.denom*c, f.denom) |
| |
|
| | op, g_numer, g_denom = f._extract_ground(c) |
| |
|
| | if op == 1: |
| | return f.new(f.numer + f.denom*g_numer, f.denom) |
| | elif not op: |
| | return NotImplemented |
| | else: |
| | return f.new(f.numer*g_denom + f.denom*g_numer, f.denom*g_denom) |
| |
|
| | def __sub__(f, g): |
| | """Subtract rational functions ``f`` and ``g``. """ |
| | field = f.field |
| |
|
| | if not g: |
| | return f |
| | elif not f: |
| | return -g |
| | elif isinstance(g, field.dtype): |
| | if f.denom == g.denom: |
| | return f.new(f.numer - g.numer, f.denom) |
| | else: |
| | return f.new(f.numer*g.denom - f.denom*g.numer, f.denom*g.denom) |
| | elif isinstance(g, field.ring.dtype): |
| | return f.new(f.numer - f.denom*g, f.denom) |
| | else: |
| | if isinstance(g, FracElement): |
| | if isinstance(field.domain, FractionField) and field.domain.field == g.field: |
| | pass |
| | elif isinstance(g.field.domain, FractionField) and g.field.domain.field == field: |
| | return g.__rsub__(f) |
| | else: |
| | return NotImplemented |
| | elif isinstance(g, PolyElement): |
| | if isinstance(field.domain, PolynomialRing) and field.domain.ring == g.ring: |
| | pass |
| | else: |
| | return g.__rsub__(f) |
| |
|
| | op, g_numer, g_denom = f._extract_ground(g) |
| |
|
| | if op == 1: |
| | return f.new(f.numer - f.denom*g_numer, f.denom) |
| | elif not op: |
| | return NotImplemented |
| | else: |
| | return f.new(f.numer*g_denom - f.denom*g_numer, f.denom*g_denom) |
| |
|
| | def __rsub__(f, c): |
| | if isinstance(c, f.field.ring.dtype): |
| | return f.new(-f.numer + f.denom*c, f.denom) |
| |
|
| | op, g_numer, g_denom = f._extract_ground(c) |
| |
|
| | if op == 1: |
| | return f.new(-f.numer + f.denom*g_numer, f.denom) |
| | elif not op: |
| | return NotImplemented |
| | else: |
| | return f.new(-f.numer*g_denom + f.denom*g_numer, f.denom*g_denom) |
| |
|
| | def __mul__(f, g): |
| | """Multiply rational functions ``f`` and ``g``. """ |
| | field = f.field |
| |
|
| | if not f or not g: |
| | return field.zero |
| | elif isinstance(g, field.dtype): |
| | return f.new(f.numer*g.numer, f.denom*g.denom) |
| | elif isinstance(g, field.ring.dtype): |
| | return f.new(f.numer*g, f.denom) |
| | else: |
| | if isinstance(g, FracElement): |
| | if isinstance(field.domain, FractionField) and field.domain.field == g.field: |
| | pass |
| | elif isinstance(g.field.domain, FractionField) and g.field.domain.field == field: |
| | return g.__rmul__(f) |
| | else: |
| | return NotImplemented |
| | elif isinstance(g, PolyElement): |
| | if isinstance(field.domain, PolynomialRing) and field.domain.ring == g.ring: |
| | pass |
| | else: |
| | return g.__rmul__(f) |
| |
|
| | return f.__rmul__(g) |
| |
|
| | def __rmul__(f, c): |
| | if isinstance(c, f.field.ring.dtype): |
| | return f.new(f.numer*c, f.denom) |
| |
|
| | op, g_numer, g_denom = f._extract_ground(c) |
| |
|
| | if op == 1: |
| | return f.new(f.numer*g_numer, f.denom) |
| | elif not op: |
| | return NotImplemented |
| | else: |
| | return f.new(f.numer*g_numer, f.denom*g_denom) |
| |
|
| | def __truediv__(f, g): |
| | """Computes quotient of fractions ``f`` and ``g``. """ |
| | field = f.field |
| |
|
| | if not g: |
| | raise ZeroDivisionError |
| | elif isinstance(g, field.dtype): |
| | return f.new(f.numer*g.denom, f.denom*g.numer) |
| | elif isinstance(g, field.ring.dtype): |
| | return f.new(f.numer, f.denom*g) |
| | else: |
| | if isinstance(g, FracElement): |
| | if isinstance(field.domain, FractionField) and field.domain.field == g.field: |
| | pass |
| | elif isinstance(g.field.domain, FractionField) and g.field.domain.field == field: |
| | return g.__rtruediv__(f) |
| | else: |
| | return NotImplemented |
| | elif isinstance(g, PolyElement): |
| | if isinstance(field.domain, PolynomialRing) and field.domain.ring == g.ring: |
| | pass |
| | else: |
| | return g.__rtruediv__(f) |
| |
|
| | op, g_numer, g_denom = f._extract_ground(g) |
| |
|
| | if op == 1: |
| | return f.new(f.numer, f.denom*g_numer) |
| | elif not op: |
| | return NotImplemented |
| | else: |
| | return f.new(f.numer*g_denom, f.denom*g_numer) |
| |
|
| | def __rtruediv__(f, c): |
| | if not f: |
| | raise ZeroDivisionError |
| | elif isinstance(c, f.field.ring.dtype): |
| | return f.new(f.denom*c, f.numer) |
| |
|
| | op, g_numer, g_denom = f._extract_ground(c) |
| |
|
| | if op == 1: |
| | return f.new(f.denom*g_numer, f.numer) |
| | elif not op: |
| | return NotImplemented |
| | else: |
| | return f.new(f.denom*g_numer, f.numer*g_denom) |
| |
|
| | def __pow__(f, n): |
| | """Raise ``f`` to a non-negative power ``n``. """ |
| | if n >= 0: |
| | return f.raw_new(f.numer**n, f.denom**n) |
| | elif not f: |
| | raise ZeroDivisionError |
| | else: |
| | return f.raw_new(f.denom**-n, f.numer**-n) |
| |
|
| | def diff(f, x): |
| | """Computes partial derivative in ``x``. |
| | |
| | Examples |
| | ======== |
| | |
| | >>> from sympy.polys.fields import field |
| | >>> from sympy.polys.domains import ZZ |
| | |
| | >>> _, x, y, z = field("x,y,z", ZZ) |
| | >>> ((x**2 + y)/(z + 1)).diff(x) |
| | 2*x/(z + 1) |
| | |
| | """ |
| | x = x.to_poly() |
| | return f.new(f.numer.diff(x)*f.denom - f.numer*f.denom.diff(x), f.denom**2) |
| |
|
| | def __call__(f, *values): |
| | if 0 < len(values) <= f.field.ngens: |
| | return f.evaluate(list(zip(f.field.gens, values))) |
| | else: |
| | raise ValueError("expected at least 1 and at most %s values, got %s" % (f.field.ngens, len(values))) |
| |
|
| | def evaluate(f, x, a=None): |
| | if isinstance(x, list) and a is None: |
| | x = [ (X.to_poly(), a) for X, a in x ] |
| | numer, denom = f.numer.evaluate(x), f.denom.evaluate(x) |
| | else: |
| | x = x.to_poly() |
| | numer, denom = f.numer.evaluate(x, a), f.denom.evaluate(x, a) |
| |
|
| | field = numer.ring.to_field() |
| | return field.new(numer, denom) |
| |
|
| | def subs(f, x, a=None): |
| | if isinstance(x, list) and a is None: |
| | x = [ (X.to_poly(), a) for X, a in x ] |
| | numer, denom = f.numer.subs(x), f.denom.subs(x) |
| | else: |
| | x = x.to_poly() |
| | numer, denom = f.numer.subs(x, a), f.denom.subs(x, a) |
| |
|
| | return f.new(numer, denom) |
| |
|
| | def compose(f, x, a=None): |
| | raise NotImplementedError |
| |
|
