Buckets:
MisterAI/LocalAI_Demo_backends / cpu-diffusers.upgrade-tmp /venv /lib /python3.10 /site-packages /sympy /utilities /iterables.py
| from collections import Counter, defaultdict, OrderedDict | |
| from itertools import ( | |
| chain, combinations, combinations_with_replacement, cycle, islice, | |
| permutations, product, groupby | |
| ) | |
| # For backwards compatibility | |
| from itertools import product as cartes # noqa: F401 | |
| from operator import gt | |
| # this is the logical location of these functions | |
| from sympy.utilities.enumerative import ( | |
| multiset_partitions_taocp, list_visitor, MultisetPartitionTraverser) | |
| from sympy.utilities.misc import as_int | |
| from sympy.utilities.decorator import deprecated | |
| def is_palindromic(s, i=0, j=None): | |
| """ | |
| Return True if the sequence is the same from left to right as it | |
| is from right to left in the whole sequence (default) or in the | |
| Python slice ``s[i: j]``; else False. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import is_palindromic | |
| >>> is_palindromic([1, 0, 1]) | |
| True | |
| >>> is_palindromic('abcbb') | |
| False | |
| >>> is_palindromic('abcbb', 1) | |
| False | |
| Normal Python slicing is performed in place so there is no need to | |
| create a slice of the sequence for testing: | |
| >>> is_palindromic('abcbb', 1, -1) | |
| True | |
| >>> is_palindromic('abcbb', -4, -1) | |
| True | |
| See Also | |
| ======== | |
| sympy.ntheory.digits.is_palindromic: tests integers | |
| """ | |
| i, j, _ = slice(i, j).indices(len(s)) | |
| m = (j - i)//2 | |
| # if length is odd, middle element will be ignored | |
| return all(s[i + k] == s[j - 1 - k] for k in range(m)) | |
| def flatten(iterable, levels=None, cls=None): # noqa: F811 | |
| """ | |
| Recursively denest iterable containers. | |
| >>> from sympy import flatten | |
| >>> flatten([1, 2, 3]) | |
| [1, 2, 3] | |
| >>> flatten([1, 2, [3]]) | |
| [1, 2, 3] | |
| >>> flatten([1, [2, 3], [4, 5]]) | |
| [1, 2, 3, 4, 5] | |
| >>> flatten([1.0, 2, (1, None)]) | |
| [1.0, 2, 1, None] | |
| If you want to denest only a specified number of levels of | |
| nested containers, then set ``levels`` flag to the desired | |
| number of levels:: | |
| >>> ls = [[(-2, -1), (1, 2)], [(0, 0)]] | |
| >>> flatten(ls, levels=1) | |
| [(-2, -1), (1, 2), (0, 0)] | |
| If cls argument is specified, it will only flatten instances of that | |
| class, for example: | |
| >>> from sympy import Basic, S | |
| >>> class MyOp(Basic): | |
| ... pass | |
| ... | |
| >>> flatten([MyOp(S(1), MyOp(S(2), S(3)))], cls=MyOp) | |
| [1, 2, 3] | |
| adapted from https://kogs-www.informatik.uni-hamburg.de/~meine/python_tricks | |
| """ | |
| from sympy.tensor.array import NDimArray | |
| if levels is not None: | |
| if not levels: | |
| return iterable | |
| elif levels > 0: | |
| levels -= 1 | |
| else: | |
| raise ValueError( | |
| "expected non-negative number of levels, got %s" % levels) | |
| if cls is None: | |
| def reducible(x): | |
| return is_sequence(x, set) | |
| else: | |
| def reducible(x): | |
| return isinstance(x, cls) | |
| result = [] | |
| for el in iterable: | |
| if reducible(el): | |
| if hasattr(el, 'args') and not isinstance(el, NDimArray): | |
| el = el.args | |
| result.extend(flatten(el, levels=levels, cls=cls)) | |
| else: | |
| result.append(el) | |
| return result | |
| def unflatten(iter, n=2): | |
| """Group ``iter`` into tuples of length ``n``. Raise an error if | |
| the length of ``iter`` is not a multiple of ``n``. | |
| """ | |
| if n < 1 or len(iter) % n: | |
| raise ValueError('iter length is not a multiple of %i' % n) | |
| return list(zip(*(iter[i::n] for i in range(n)))) | |
| def reshape(seq, how): | |
| """Reshape the sequence according to the template in ``how``. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities import reshape | |
| >>> seq = list(range(1, 9)) | |
| >>> reshape(seq, [4]) # lists of 4 | |
| [[1, 2, 3, 4], [5, 6, 7, 8]] | |
| >>> reshape(seq, (4,)) # tuples of 4 | |
| [(1, 2, 3, 4), (5, 6, 7, 8)] | |
| >>> reshape(seq, (2, 2)) # tuples of 4 | |
| [(1, 2, 3, 4), (5, 6, 7, 8)] | |
| >>> reshape(seq, (2, [2])) # (i, i, [i, i]) | |
| [(1, 2, [3, 4]), (5, 6, [7, 8])] | |
| >>> reshape(seq, ((2,), [2])) # etc.... | |
| [((1, 2), [3, 4]), ((5, 6), [7, 8])] | |
| >>> reshape(seq, (1, [2], 1)) | |
| [(1, [2, 3], 4), (5, [6, 7], 8)] | |
| >>> reshape(tuple(seq), ([[1], 1, (2,)],)) | |
| (([[1], 2, (3, 4)],), ([[5], 6, (7, 8)],)) | |
| >>> reshape(tuple(seq), ([1], 1, (2,))) | |
| (([1], 2, (3, 4)), ([5], 6, (7, 8))) | |
| >>> reshape(list(range(12)), [2, [3], {2}, (1, (3,), 1)]) | |
| [[0, 1, [2, 3, 4], {5, 6}, (7, (8, 9, 10), 11)]] | |
| """ | |
| m = sum(flatten(how)) | |
| n, rem = divmod(len(seq), m) | |
| if m < 0 or rem: | |
| raise ValueError('template must sum to positive number ' | |
| 'that divides the length of the sequence') | |
| i = 0 | |
| container = type(how) | |
| rv = [None]*n | |
| for k in range(len(rv)): | |
| _rv = [] | |
| for hi in how: | |
| if isinstance(hi, int): | |
| _rv.extend(seq[i: i + hi]) | |
| i += hi | |
| else: | |
| n = sum(flatten(hi)) | |
| hi_type = type(hi) | |
| _rv.append(hi_type(reshape(seq[i: i + n], hi)[0])) | |
| i += n | |
| rv[k] = container(_rv) | |
| return type(seq)(rv) | |
| def group(seq, multiple=True): | |
| """ | |
| Splits a sequence into a list of lists of equal, adjacent elements. | |
| Examples | |
| ======== | |
| >>> from sympy import group | |
| >>> group([1, 1, 1, 2, 2, 3]) | |
| [[1, 1, 1], [2, 2], [3]] | |
| >>> group([1, 1, 1, 2, 2, 3], multiple=False) | |
| [(1, 3), (2, 2), (3, 1)] | |
| >>> group([1, 1, 3, 2, 2, 1], multiple=False) | |
| [(1, 2), (3, 1), (2, 2), (1, 1)] | |
| See Also | |
| ======== | |
| multiset | |
| """ | |
| if multiple: | |
| return [(list(g)) for _, g in groupby(seq)] | |
| return [(k, len(list(g))) for k, g in groupby(seq)] | |
| def _iproduct2(iterable1, iterable2): | |
| '''Cartesian product of two possibly infinite iterables''' | |
| it1 = iter(iterable1) | |
| it2 = iter(iterable2) | |
| elems1 = [] | |
| elems2 = [] | |
| sentinel = object() | |
| def append(it, elems): | |
| e = next(it, sentinel) | |
| if e is not sentinel: | |
| elems.append(e) | |
| n = 0 | |
| append(it1, elems1) | |
| append(it2, elems2) | |
| while n <= len(elems1) + len(elems2): | |
| for m in range(n-len(elems1)+1, len(elems2)): | |
| yield (elems1[n-m], elems2[m]) | |
| n += 1 | |
| append(it1, elems1) | |
| append(it2, elems2) | |
| def iproduct(*iterables): | |
| ''' | |
| Cartesian product of iterables. | |
| Generator of the Cartesian product of iterables. This is analogous to | |
| itertools.product except that it works with infinite iterables and will | |
| yield any item from the infinite product eventually. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import iproduct | |
| >>> sorted(iproduct([1,2], [3,4])) | |
| [(1, 3), (1, 4), (2, 3), (2, 4)] | |
| With an infinite iterator: | |
| >>> from sympy import S | |
| >>> (3,) in iproduct(S.Integers) | |
| True | |
| >>> (3, 4) in iproduct(S.Integers, S.Integers) | |
| True | |
| .. seealso:: | |
| `itertools.product | |
| <https://docs.python.org/3/library/itertools.html#itertools.product>`_ | |
| ''' | |
| if len(iterables) == 0: | |
| yield () | |
| return | |
| elif len(iterables) == 1: | |
| for e in iterables[0]: | |
| yield (e,) | |
| elif len(iterables) == 2: | |
| yield from _iproduct2(*iterables) | |
| else: | |
| first, others = iterables[0], iterables[1:] | |
| for ef, eo in _iproduct2(first, iproduct(*others)): | |
| yield (ef,) + eo | |
| def multiset(seq): | |
| """Return the hashable sequence in multiset form with values being the | |
| multiplicity of the item in the sequence. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import multiset | |
| >>> multiset('mississippi') | |
| {'i': 4, 'm': 1, 'p': 2, 's': 4} | |
| See Also | |
| ======== | |
| group | |
| """ | |
| return dict(Counter(seq).items()) | |
| def ibin(n, bits=None, str=False): | |
| """Return a list of length ``bits`` corresponding to the binary value | |
| of ``n`` with small bits to the right (last). If bits is omitted, the | |
| length will be the number required to represent ``n``. If the bits are | |
| desired in reversed order, use the ``[::-1]`` slice of the returned list. | |
| If a sequence of all bits-length lists starting from ``[0, 0,..., 0]`` | |
| through ``[1, 1, ..., 1]`` are desired, pass a non-integer for bits, e.g. | |
| ``'all'``. | |
| If the bit *string* is desired pass ``str=True``. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import ibin | |
| >>> ibin(2) | |
| [1, 0] | |
| >>> ibin(2, 4) | |
| [0, 0, 1, 0] | |
| If all lists corresponding to 0 to 2**n - 1, pass a non-integer | |
| for bits: | |
| >>> bits = 2 | |
| >>> for i in ibin(2, 'all'): | |
| ... print(i) | |
| (0, 0) | |
| (0, 1) | |
| (1, 0) | |
| (1, 1) | |
| If a bit string is desired of a given length, use str=True: | |
| >>> n = 123 | |
| >>> bits = 10 | |
| >>> ibin(n, bits, str=True) | |
| '0001111011' | |
| >>> ibin(n, bits, str=True)[::-1] # small bits left | |
| '1101111000' | |
| >>> list(ibin(3, 'all', str=True)) | |
| ['000', '001', '010', '011', '100', '101', '110', '111'] | |
| """ | |
| if n < 0: | |
| raise ValueError("negative numbers are not allowed") | |
| n = as_int(n) | |
| if bits is None: | |
| bits = 0 | |
| else: | |
| try: | |
| bits = as_int(bits) | |
| except ValueError: | |
| bits = -1 | |
| else: | |
| if n.bit_length() > bits: | |
| raise ValueError( | |
| "`bits` must be >= {}".format(n.bit_length())) | |
| if not str: | |
| if bits >= 0: | |
| return [1 if i == "1" else 0 for i in bin(n)[2:].rjust(bits, "0")] | |
| else: | |
| return variations(range(2), n, repetition=True) | |
| else: | |
| if bits >= 0: | |
| return bin(n)[2:].rjust(bits, "0") | |
| else: | |
| return (bin(i)[2:].rjust(n, "0") for i in range(2**n)) | |
| def variations(seq, n, repetition=False): | |
| r"""Returns an iterator over the n-sized variations of ``seq`` (size N). | |
| ``repetition`` controls whether items in ``seq`` can appear more than once; | |
| Examples | |
| ======== | |
| ``variations(seq, n)`` will return `\frac{N!}{(N - n)!}` permutations without | |
| repetition of ``seq``'s elements: | |
| >>> from sympy import variations | |
| >>> list(variations([1, 2], 2)) | |
| [(1, 2), (2, 1)] | |
| ``variations(seq, n, True)`` will return the `N^n` permutations obtained | |
| by allowing repetition of elements: | |
| >>> list(variations([1, 2], 2, repetition=True)) | |
| [(1, 1), (1, 2), (2, 1), (2, 2)] | |
| If you ask for more items than are in the set you get the empty set unless | |
| you allow repetitions: | |
| >>> list(variations([0, 1], 3, repetition=False)) | |
| [] | |
| >>> list(variations([0, 1], 3, repetition=True))[:4] | |
| [(0, 0, 0), (0, 0, 1), (0, 1, 0), (0, 1, 1)] | |
| .. seealso:: | |
| `itertools.permutations | |
| <https://docs.python.org/3/library/itertools.html#itertools.permutations>`_, | |
| `itertools.product | |
| <https://docs.python.org/3/library/itertools.html#itertools.product>`_ | |
| """ | |
| if not repetition: | |
| seq = tuple(seq) | |
| if len(seq) < n: | |
| return iter(()) # 0 length iterator | |
| return permutations(seq, n) | |
| else: | |
| if n == 0: | |
| return iter(((),)) # yields 1 empty tuple | |
| else: | |
| return product(seq, repeat=n) | |
| def subsets(seq, k=None, repetition=False): | |
| r"""Generates all `k`-subsets (combinations) from an `n`-element set, ``seq``. | |
| A `k`-subset of an `n`-element set is any subset of length exactly `k`. The | |
| number of `k`-subsets of an `n`-element set is given by ``binomial(n, k)``, | |
| whereas there are `2^n` subsets all together. If `k` is ``None`` then all | |
| `2^n` subsets will be returned from shortest to longest. | |
| Examples | |
| ======== | |
| >>> from sympy import subsets | |
| ``subsets(seq, k)`` will return the | |
| `\frac{n!}{k!(n - k)!}` `k`-subsets (combinations) | |
| without repetition, i.e. once an item has been removed, it can no | |
| longer be "taken": | |
| >>> list(subsets([1, 2], 2)) | |
| [(1, 2)] | |
| >>> list(subsets([1, 2])) | |
| [(), (1,), (2,), (1, 2)] | |
| >>> list(subsets([1, 2, 3], 2)) | |
| [(1, 2), (1, 3), (2, 3)] | |
| ``subsets(seq, k, repetition=True)`` will return the | |
| `\frac{(n - 1 + k)!}{k!(n - 1)!}` | |
| combinations *with* repetition: | |
| >>> list(subsets([1, 2], 2, repetition=True)) | |
| [(1, 1), (1, 2), (2, 2)] | |
| If you ask for more items than are in the set you get the empty set unless | |
| you allow repetitions: | |
| >>> list(subsets([0, 1], 3, repetition=False)) | |
| [] | |
| >>> list(subsets([0, 1], 3, repetition=True)) | |
| [(0, 0, 0), (0, 0, 1), (0, 1, 1), (1, 1, 1)] | |
| """ | |
| if k is None: | |
| if not repetition: | |
| return chain.from_iterable((combinations(seq, k) | |
| for k in range(len(seq) + 1))) | |
| else: | |
| return chain.from_iterable((combinations_with_replacement(seq, k) | |
| for k in range(len(seq) + 1))) | |
| else: | |
| if not repetition: | |
| return combinations(seq, k) | |
| else: | |
| return combinations_with_replacement(seq, k) | |
| def filter_symbols(iterator, exclude): | |
| """ | |
| Only yield elements from `iterator` that do not occur in `exclude`. | |
| Parameters | |
| ========== | |
| iterator : iterable | |
| iterator to take elements from | |
| exclude : iterable | |
| elements to exclude | |
| Returns | |
| ======= | |
| iterator : iterator | |
| filtered iterator | |
| """ | |
| exclude = set(exclude) | |
| for s in iterator: | |
| if s not in exclude: | |
| yield s | |
| def numbered_symbols(prefix='x', cls=None, start=0, exclude=(), *args, **assumptions): | |
| """ | |
| Generate an infinite stream of Symbols consisting of a prefix and | |
| increasing subscripts provided that they do not occur in ``exclude``. | |
| Parameters | |
| ========== | |
| prefix : str, optional | |
| The prefix to use. By default, this function will generate symbols of | |
| the form "x0", "x1", etc. | |
| cls : class, optional | |
| The class to use. By default, it uses ``Symbol``, but you can also use ``Wild`` | |
| or ``Dummy``. | |
| start : int, optional | |
| The start number. By default, it is 0. | |
| exclude : list, tuple, set of cls, optional | |
| Symbols to be excluded. | |
| *args, **kwargs | |
| Additional positional and keyword arguments are passed to the *cls* class. | |
| Returns | |
| ======= | |
| sym : Symbol | |
| The subscripted symbols. | |
| """ | |
| exclude = set(exclude or []) | |
| if cls is None: | |
| # We can't just make the default cls=Symbol because it isn't | |
| # imported yet. | |
| from sympy.core import Symbol | |
| cls = Symbol | |
| while True: | |
| name = '%s%s' % (prefix, start) | |
| s = cls(name, *args, **assumptions) | |
| if s not in exclude: | |
| yield s | |
| start += 1 | |
| def capture(func): | |
| """Return the printed output of func(). | |
| ``func`` should be a function without arguments that produces output with | |
| print statements. | |
| >>> from sympy.utilities.iterables import capture | |
| >>> from sympy import pprint | |
| >>> from sympy.abc import x | |
| >>> def foo(): | |
| ... print('hello world!') | |
| ... | |
| >>> 'hello' in capture(foo) # foo, not foo() | |
| True | |
| >>> capture(lambda: pprint(2/x)) | |
| '2\\n-\\nx\\n' | |
| """ | |
| from io import StringIO | |
| import sys | |
| stdout = sys.stdout | |
| sys.stdout = file = StringIO() | |
| try: | |
| func() | |
| finally: | |
| sys.stdout = stdout | |
| return file.getvalue() | |
| def sift(seq, keyfunc, binary=False): | |
| """ | |
| Sift the sequence, ``seq`` according to ``keyfunc``. | |
| Returns | |
| ======= | |
| When ``binary`` is ``False`` (default), the output is a dictionary | |
| where elements of ``seq`` are stored in a list keyed to the value | |
| of keyfunc for that element. If ``binary`` is True then a tuple | |
| with lists ``T`` and ``F`` are returned where ``T`` is a list | |
| containing elements of seq for which ``keyfunc`` was ``True`` and | |
| ``F`` containing those elements for which ``keyfunc`` was ``False``; | |
| a ValueError is raised if the ``keyfunc`` is not binary. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities import sift | |
| >>> from sympy.abc import x, y | |
| >>> from sympy import sqrt, exp, pi, Tuple | |
| >>> sift(range(5), lambda x: x % 2) | |
| {0: [0, 2, 4], 1: [1, 3]} | |
| sift() returns a defaultdict() object, so any key that has no matches will | |
| give []. | |
| >>> sift([x], lambda x: x.is_commutative) | |
| {True: [x]} | |
| >>> _[False] | |
| [] | |
| Sometimes you will not know how many keys you will get: | |
| >>> sift([sqrt(x), exp(x), (y**x)**2], | |
| ... lambda x: x.as_base_exp()[0]) | |
| {E: [exp(x)], x: [sqrt(x)], y: [y**(2*x)]} | |
| Sometimes you expect the results to be binary; the | |
| results can be unpacked by setting ``binary`` to True: | |
| >>> sift(range(4), lambda x: x % 2, binary=True) | |
| ([1, 3], [0, 2]) | |
| >>> sift(Tuple(1, pi), lambda x: x.is_rational, binary=True) | |
| ([1], [pi]) | |
| A ValueError is raised if the predicate was not actually binary | |
| (which is a good test for the logic where sifting is used and | |
| binary results were expected): | |
| >>> unknown = exp(1) - pi # the rationality of this is unknown | |
| >>> args = Tuple(1, pi, unknown) | |
| >>> sift(args, lambda x: x.is_rational, binary=True) | |
| Traceback (most recent call last): | |
| ... | |
| ValueError: keyfunc gave non-binary output | |
| The non-binary sifting shows that there were 3 keys generated: | |
| >>> set(sift(args, lambda x: x.is_rational).keys()) | |
| {None, False, True} | |
| If you need to sort the sifted items it might be better to use | |
| ``ordered`` which can economically apply multiple sort keys | |
| to a sequence while sorting. | |
| See Also | |
| ======== | |
| ordered | |
| """ | |
| if not binary: | |
| m = defaultdict(list) | |
| for i in seq: | |
| m[keyfunc(i)].append(i) | |
| return m | |
| sift = F, T = [], [] | |
| for i in seq: | |
| try: | |
| sift[keyfunc(i)].append(i) | |
| except (IndexError, TypeError): | |
| raise ValueError('keyfunc gave non-binary output') | |
| return T, F | |
| def take(iter, n): | |
| """Return ``n`` items from ``iter`` iterator. """ | |
| return [ value for _, value in zip(range(n), iter) ] | |
| def dict_merge(*dicts): | |
| """Merge dictionaries into a single dictionary. """ | |
| merged = {} | |
| for dict in dicts: | |
| merged.update(dict) | |
| return merged | |
| def common_prefix(*seqs): | |
| """Return the subsequence that is a common start of sequences in ``seqs``. | |
| >>> from sympy.utilities.iterables import common_prefix | |
| >>> common_prefix(list(range(3))) | |
| [0, 1, 2] | |
| >>> common_prefix(list(range(3)), list(range(4))) | |
| [0, 1, 2] | |
| >>> common_prefix([1, 2, 3], [1, 2, 5]) | |
| [1, 2] | |
| >>> common_prefix([1, 2, 3], [1, 3, 5]) | |
| [1] | |
| """ | |
| if not all(seqs): | |
| return [] | |
| elif len(seqs) == 1: | |
| return seqs[0] | |
| i = 0 | |
| for i in range(min(len(s) for s in seqs)): | |
| if not all(seqs[j][i] == seqs[0][i] for j in range(len(seqs))): | |
| break | |
| else: | |
| i += 1 | |
| return seqs[0][:i] | |
| def common_suffix(*seqs): | |
| """Return the subsequence that is a common ending of sequences in ``seqs``. | |
| >>> from sympy.utilities.iterables import common_suffix | |
| >>> common_suffix(list(range(3))) | |
| [0, 1, 2] | |
| >>> common_suffix(list(range(3)), list(range(4))) | |
| [] | |
| >>> common_suffix([1, 2, 3], [9, 2, 3]) | |
| [2, 3] | |
| >>> common_suffix([1, 2, 3], [9, 7, 3]) | |
| [3] | |
| """ | |
| if not all(seqs): | |
| return [] | |
| elif len(seqs) == 1: | |
| return seqs[0] | |
| i = 0 | |
| for i in range(-1, -min(len(s) for s in seqs) - 1, -1): | |
| if not all(seqs[j][i] == seqs[0][i] for j in range(len(seqs))): | |
| break | |
| else: | |
| i -= 1 | |
| if i == -1: | |
| return [] | |
| else: | |
| return seqs[0][i + 1:] | |
| def prefixes(seq): | |
| """ | |
| Generate all prefixes of a sequence. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import prefixes | |
| >>> list(prefixes([1,2,3,4])) | |
| [[1], [1, 2], [1, 2, 3], [1, 2, 3, 4]] | |
| """ | |
| n = len(seq) | |
| for i in range(n): | |
| yield seq[:i + 1] | |
| def postfixes(seq): | |
| """ | |
| Generate all postfixes of a sequence. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import postfixes | |
| >>> list(postfixes([1,2,3,4])) | |
| [[4], [3, 4], [2, 3, 4], [1, 2, 3, 4]] | |
| """ | |
| n = len(seq) | |
| for i in range(n): | |
| yield seq[n - i - 1:] | |
| def topological_sort(graph, key=None): | |
| r""" | |
| Topological sort of graph's vertices. | |
| Parameters | |
| ========== | |
| graph : tuple[list, list[tuple[T, T]] | |
| A tuple consisting of a list of vertices and a list of edges of | |
| a graph to be sorted topologically. | |
| key : callable[T] (optional) | |
| Ordering key for vertices on the same level. By default the natural | |
| (e.g. lexicographic) ordering is used (in this case the base type | |
| must implement ordering relations). | |
| Examples | |
| ======== | |
| Consider a graph:: | |
| +---+ +---+ +---+ | |
| | 7 |\ | 5 | | 3 | | |
| +---+ \ +---+ +---+ | |
| | _\___/ ____ _/ | | |
| | / \___/ \ / | | |
| V V V V | | |
| +----+ +---+ | | |
| | 11 | | 8 | | | |
| +----+ +---+ | | |
| | | \____ ___/ _ | | |
| | \ \ / / \ | | |
| V \ V V / V V | |
| +---+ \ +---+ | +----+ | |
| | 2 | | | 9 | | | 10 | | |
| +---+ | +---+ | +----+ | |
| \________/ | |
| where vertices are integers. This graph can be encoded using | |
| elementary Python's data structures as follows:: | |
| >>> V = [2, 3, 5, 7, 8, 9, 10, 11] | |
| >>> E = [(7, 11), (7, 8), (5, 11), (3, 8), (3, 10), | |
| ... (11, 2), (11, 9), (11, 10), (8, 9)] | |
| To compute a topological sort for graph ``(V, E)`` issue:: | |
| >>> from sympy.utilities.iterables import topological_sort | |
| >>> topological_sort((V, E)) | |
| [3, 5, 7, 8, 11, 2, 9, 10] | |
| If specific tie breaking approach is needed, use ``key`` parameter:: | |
| >>> topological_sort((V, E), key=lambda v: -v) | |
| [7, 5, 11, 3, 10, 8, 9, 2] | |
| Only acyclic graphs can be sorted. If the input graph has a cycle, | |
| then ``ValueError`` will be raised:: | |
| >>> topological_sort((V, E + [(10, 7)])) | |
| Traceback (most recent call last): | |
| ... | |
| ValueError: cycle detected | |
| References | |
| ========== | |
| .. [1] https://en.wikipedia.org/wiki/Topological_sorting | |
| """ | |
| V, E = graph | |
| L = [] | |
| S = set(V) | |
| E = list(E) | |
| S.difference_update(u for v, u in E) | |
| if key is None: | |
| def key(value): | |
| return value | |
| S = sorted(S, key=key, reverse=True) | |
| while S: | |
| node = S.pop() | |
| L.append(node) | |
| for u, v in list(E): | |
| if u == node: | |
| E.remove((u, v)) | |
| for _u, _v in E: | |
| if v == _v: | |
| break | |
| else: | |
| kv = key(v) | |
| for i, s in enumerate(S): | |
| ks = key(s) | |
| if kv > ks: | |
| S.insert(i, v) | |
| break | |
| else: | |
| S.append(v) | |
| if E: | |
| raise ValueError("cycle detected") | |
| else: | |
| return L | |
| def strongly_connected_components(G): | |
| r""" | |
| Strongly connected components of a directed graph in reverse topological | |
| order. | |
| Parameters | |
| ========== | |
| G : tuple[list, list[tuple[T, T]] | |
| A tuple consisting of a list of vertices and a list of edges of | |
| a graph whose strongly connected components are to be found. | |
| Examples | |
| ======== | |
| Consider a directed graph (in dot notation):: | |
| digraph { | |
| A -> B | |
| A -> C | |
| B -> C | |
| C -> B | |
| B -> D | |
| } | |
| .. graphviz:: | |
| digraph { | |
| A -> B | |
| A -> C | |
| B -> C | |
| C -> B | |
| B -> D | |
| } | |
| where vertices are the letters A, B, C and D. This graph can be encoded | |
| using Python's elementary data structures as follows:: | |
| >>> V = ['A', 'B', 'C', 'D'] | |
| >>> E = [('A', 'B'), ('A', 'C'), ('B', 'C'), ('C', 'B'), ('B', 'D')] | |
| The strongly connected components of this graph can be computed as | |
| >>> from sympy.utilities.iterables import strongly_connected_components | |
| >>> strongly_connected_components((V, E)) | |
| [['D'], ['B', 'C'], ['A']] | |
| This also gives the components in reverse topological order. | |
| Since the subgraph containing B and C has a cycle they must be together in | |
| a strongly connected component. A and D are connected to the rest of the | |
| graph but not in a cyclic manner so they appear as their own strongly | |
| connected components. | |
| Notes | |
| ===== | |
| The vertices of the graph must be hashable for the data structures used. | |
| If the vertices are unhashable replace them with integer indices. | |
| This function uses Tarjan's algorithm to compute the strongly connected | |
| components in `O(|V|+|E|)` (linear) time. | |
| References | |
| ========== | |
| .. [1] https://en.wikipedia.org/wiki/Strongly_connected_component | |
| .. [2] https://en.wikipedia.org/wiki/Tarjan%27s_strongly_connected_components_algorithm | |
| See Also | |
| ======== | |
| sympy.utilities.iterables.connected_components | |
| """ | |
| # Map from a vertex to its neighbours | |
| V, E = G | |
| Gmap = {vi: [] for vi in V} | |
| for v1, v2 in E: | |
| Gmap[v1].append(v2) | |
| return _strongly_connected_components(V, Gmap) | |
| def _strongly_connected_components(V, Gmap): | |
| """More efficient internal routine for strongly_connected_components""" | |
| # | |
| # Here V is an iterable of vertices and Gmap is a dict mapping each vertex | |
| # to a list of neighbours e.g.: | |
| # | |
| # V = [0, 1, 2, 3] | |
| # Gmap = {0: [2, 3], 1: [0]} | |
| # | |
| # For a large graph these data structures can often be created more | |
| # efficiently then those expected by strongly_connected_components() which | |
| # in this case would be | |
| # | |
| # V = [0, 1, 2, 3] | |
| # Gmap = [(0, 2), (0, 3), (1, 0)] | |
| # | |
| # XXX: Maybe this should be the recommended function to use instead... | |
| # | |
| # Non-recursive Tarjan's algorithm: | |
| lowlink = {} | |
| indices = {} | |
| stack = OrderedDict() | |
| callstack = [] | |
| components = [] | |
| nomore = object() | |
| def start(v): | |
| index = len(stack) | |
| indices[v] = lowlink[v] = index | |
| stack[v] = None | |
| callstack.append((v, iter(Gmap[v]))) | |
| def finish(v1): | |
| # Finished a component? | |
| if lowlink[v1] == indices[v1]: | |
| component = [stack.popitem()[0]] | |
| while component[-1] is not v1: | |
| component.append(stack.popitem()[0]) | |
| components.append(component[::-1]) | |
| v2, _ = callstack.pop() | |
| if callstack: | |
| v1, _ = callstack[-1] | |
| lowlink[v1] = min(lowlink[v1], lowlink[v2]) | |
| for v in V: | |
| if v in indices: | |
| continue | |
| start(v) | |
| while callstack: | |
| v1, it1 = callstack[-1] | |
| v2 = next(it1, nomore) | |
| # Finished children of v1? | |
| if v2 is nomore: | |
| finish(v1) | |
| # Recurse on v2 | |
| elif v2 not in indices: | |
| start(v2) | |
| elif v2 in stack: | |
| lowlink[v1] = min(lowlink[v1], indices[v2]) | |
| # Reverse topological sort order: | |
| return components | |
| def connected_components(G): | |
| r""" | |
| Connected components of an undirected graph or weakly connected components | |
| of a directed graph. | |
| Parameters | |
| ========== | |
| G : tuple[list, list[tuple[T, T]] | |
| A tuple consisting of a list of vertices and a list of edges of | |
| a graph whose connected components are to be found. | |
| Examples | |
| ======== | |
| Given an undirected graph:: | |
| graph { | |
| A -- B | |
| C -- D | |
| } | |
| .. graphviz:: | |
| graph { | |
| A -- B | |
| C -- D | |
| } | |
| We can find the connected components using this function if we include | |
| each edge in both directions:: | |
| >>> from sympy.utilities.iterables import connected_components | |
| >>> V = ['A', 'B', 'C', 'D'] | |
| >>> E = [('A', 'B'), ('B', 'A'), ('C', 'D'), ('D', 'C')] | |
| >>> connected_components((V, E)) | |
| [['A', 'B'], ['C', 'D']] | |
| The weakly connected components of a directed graph can found the same | |
| way. | |
| Notes | |
| ===== | |
| The vertices of the graph must be hashable for the data structures used. | |
| If the vertices are unhashable replace them with integer indices. | |
| This function uses Tarjan's algorithm to compute the connected components | |
| in `O(|V|+|E|)` (linear) time. | |
| References | |
| ========== | |
| .. [1] https://en.wikipedia.org/wiki/Component_%28graph_theory%29 | |
| .. [2] https://en.wikipedia.org/wiki/Tarjan%27s_strongly_connected_components_algorithm | |
| See Also | |
| ======== | |
| sympy.utilities.iterables.strongly_connected_components | |
| """ | |
| # Duplicate edges both ways so that the graph is effectively undirected | |
| # and return the strongly connected components: | |
| V, E = G | |
| E_undirected = [] | |
| for v1, v2 in E: | |
| E_undirected.extend([(v1, v2), (v2, v1)]) | |
| return strongly_connected_components((V, E_undirected)) | |
| def rotate_left(x, y): | |
| """ | |
| Left rotates a list x by the number of steps specified | |
| in y. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import rotate_left | |
| >>> a = [0, 1, 2] | |
| >>> rotate_left(a, 1) | |
| [1, 2, 0] | |
| """ | |
| if len(x) == 0: | |
| return [] | |
| y = y % len(x) | |
| return x[y:] + x[:y] | |
| def rotate_right(x, y): | |
| """ | |
| Right rotates a list x by the number of steps specified | |
| in y. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import rotate_right | |
| >>> a = [0, 1, 2] | |
| >>> rotate_right(a, 1) | |
| [2, 0, 1] | |
| """ | |
| if len(x) == 0: | |
| return [] | |
| y = len(x) - y % len(x) | |
| return x[y:] + x[:y] | |
| def least_rotation(x, key=None): | |
| ''' | |
| Returns the number of steps of left rotation required to | |
| obtain lexicographically minimal string/list/tuple, etc. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import least_rotation, rotate_left | |
| >>> a = [3, 1, 5, 1, 2] | |
| >>> least_rotation(a) | |
| 3 | |
| >>> rotate_left(a, _) | |
| [1, 2, 3, 1, 5] | |
| References | |
| ========== | |
| .. [1] https://en.wikipedia.org/wiki/Lexicographically_minimal_string_rotation | |
| ''' | |
| from sympy.functions.elementary.miscellaneous import Id | |
| if key is None: key = Id | |
| S = x + x # Concatenate string to it self to avoid modular arithmetic | |
| f = [-1] * len(S) # Failure function | |
| k = 0 # Least rotation of string found so far | |
| for j in range(1,len(S)): | |
| sj = S[j] | |
| i = f[j-k-1] | |
| while i != -1 and sj != S[k+i+1]: | |
| if key(sj) < key(S[k+i+1]): | |
| k = j-i-1 | |
| i = f[i] | |
| if sj != S[k+i+1]: | |
| if key(sj) < key(S[k]): | |
| k = j | |
| f[j-k] = -1 | |
| else: | |
| f[j-k] = i+1 | |
| return k | |
| def multiset_combinations(m, n, g=None): | |
| """ | |
| Return the unique combinations of size ``n`` from multiset ``m``. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import multiset_combinations | |
| >>> from itertools import combinations | |
| >>> [''.join(i) for i in multiset_combinations('baby', 3)] | |
| ['abb', 'aby', 'bby'] | |
| >>> def count(f, s): return len(list(f(s, 3))) | |
| The number of combinations depends on the number of letters; the | |
| number of unique combinations depends on how the letters are | |
| repeated. | |
| >>> s1 = 'abracadabra' | |
| >>> s2 = 'banana tree' | |
| >>> count(combinations, s1), count(multiset_combinations, s1) | |
| (165, 23) | |
| >>> count(combinations, s2), count(multiset_combinations, s2) | |
| (165, 54) | |
| """ | |
| from sympy.core.sorting import ordered | |
| if g is None: | |
| if isinstance(m, dict): | |
| if any(as_int(v) < 0 for v in m.values()): | |
| raise ValueError('counts cannot be negative') | |
| N = sum(m.values()) | |
| if n > N: | |
| return | |
| g = [[k, m[k]] for k in ordered(m)] | |
| else: | |
| m = list(m) | |
| N = len(m) | |
| if n > N: | |
| return | |
| try: | |
| m = multiset(m) | |
| g = [(k, m[k]) for k in ordered(m)] | |
| except TypeError: | |
| m = list(ordered(m)) | |
| g = [list(i) for i in group(m, multiple=False)] | |
| del m | |
| else: | |
| # not checking counts since g is intended for internal use | |
| N = sum(v for k, v in g) | |
| if n > N or not n: | |
| yield [] | |
| else: | |
| for i, (k, v) in enumerate(g): | |
| if v >= n: | |
| yield [k]*n | |
| v = n - 1 | |
| for v in range(min(n, v), 0, -1): | |
| for j in multiset_combinations(None, n - v, g[i + 1:]): | |
| rv = [k]*v + j | |
| if len(rv) == n: | |
| yield rv | |
| def multiset_permutations(m, size=None, g=None): | |
| """ | |
| Return the unique permutations of multiset ``m``. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import multiset_permutations | |
| >>> from sympy import factorial | |
| >>> [''.join(i) for i in multiset_permutations('aab')] | |
| ['aab', 'aba', 'baa'] | |
| >>> factorial(len('banana')) | |
| 720 | |
| >>> len(list(multiset_permutations('banana'))) | |
| 60 | |
| """ | |
| from sympy.core.sorting import ordered | |
| if g is None: | |
| if isinstance(m, dict): | |
| if any(as_int(v) < 0 for v in m.values()): | |
| raise ValueError('counts cannot be negative') | |
| g = [[k, m[k]] for k in ordered(m)] | |
| else: | |
| m = list(ordered(m)) | |
| g = [list(i) for i in group(m, multiple=False)] | |
| del m | |
| do = [gi for gi in g if gi[1] > 0] | |
| SUM = sum(gi[1] for gi in do) | |
| if not do or size is not None and (size > SUM or size < 1): | |
| if not do and size is None or size == 0: | |
| yield [] | |
| return | |
| elif size == 1: | |
| for k, v in do: | |
| yield [k] | |
| elif len(do) == 1: | |
| k, v = do[0] | |
| v = v if size is None else (size if size <= v else 0) | |
| yield [k for i in range(v)] | |
| elif all(v == 1 for k, v in do): | |
| for p in permutations([k for k, v in do], size): | |
| yield list(p) | |
| else: | |
| size = size if size is not None else SUM | |
| for i, (k, v) in enumerate(do): | |
| do[i][1] -= 1 | |
| for j in multiset_permutations(None, size - 1, do): | |
| if j: | |
| yield [k] + j | |
| do[i][1] += 1 | |
| def _partition(seq, vector, m=None): | |
| """ | |
| Return the partition of seq as specified by the partition vector. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import _partition | |
| >>> _partition('abcde', [1, 0, 1, 2, 0]) | |
| [['b', 'e'], ['a', 'c'], ['d']] | |
| Specifying the number of bins in the partition is optional: | |
| >>> _partition('abcde', [1, 0, 1, 2, 0], 3) | |
| [['b', 'e'], ['a', 'c'], ['d']] | |
| The output of _set_partitions can be passed as follows: | |
| >>> output = (3, [1, 0, 1, 2, 0]) | |
| >>> _partition('abcde', *output) | |
| [['b', 'e'], ['a', 'c'], ['d']] | |
| See Also | |
| ======== | |
| combinatorics.partitions.Partition.from_rgs | |
| """ | |
| if m is None: | |
| m = max(vector) + 1 | |
| elif isinstance(vector, int): # entered as m, vector | |
| vector, m = m, vector | |
| p = [[] for i in range(m)] | |
| for i, v in enumerate(vector): | |
| p[v].append(seq[i]) | |
| return p | |
| def _set_partitions(n): | |
| """Cycle through all partitions of n elements, yielding the | |
| current number of partitions, ``m``, and a mutable list, ``q`` | |
| such that ``element[i]`` is in part ``q[i]`` of the partition. | |
| NOTE: ``q`` is modified in place and generally should not be changed | |
| between function calls. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import _set_partitions, _partition | |
| >>> for m, q in _set_partitions(3): | |
| ... print('%s %s %s' % (m, q, _partition('abc', q, m))) | |
| 1 [0, 0, 0] [['a', 'b', 'c']] | |
| 2 [0, 0, 1] [['a', 'b'], ['c']] | |
| 2 [0, 1, 0] [['a', 'c'], ['b']] | |
| 2 [0, 1, 1] [['a'], ['b', 'c']] | |
| 3 [0, 1, 2] [['a'], ['b'], ['c']] | |
| Notes | |
| ===== | |
| This algorithm is similar to, and solves the same problem as, | |
| Algorithm 7.2.1.5H, from volume 4A of Knuth's The Art of Computer | |
| Programming. Knuth uses the term "restricted growth string" where | |
| this code refers to a "partition vector". In each case, the meaning is | |
| the same: the value in the ith element of the vector specifies to | |
| which part the ith set element is to be assigned. | |
| At the lowest level, this code implements an n-digit big-endian | |
| counter (stored in the array q) which is incremented (with carries) to | |
| get the next partition in the sequence. A special twist is that a | |
| digit is constrained to be at most one greater than the maximum of all | |
| the digits to the left of it. The array p maintains this maximum, so | |
| that the code can efficiently decide when a digit can be incremented | |
| in place or whether it needs to be reset to 0 and trigger a carry to | |
| the next digit. The enumeration starts with all the digits 0 (which | |
| corresponds to all the set elements being assigned to the same 0th | |
| part), and ends with 0123...n, which corresponds to each set element | |
| being assigned to a different, singleton, part. | |
| This routine was rewritten to use 0-based lists while trying to | |
| preserve the beauty and efficiency of the original algorithm. | |
| References | |
| ========== | |
| .. [1] Nijenhuis, Albert and Wilf, Herbert. (1978) Combinatorial Algorithms, | |
| 2nd Ed, p 91, algorithm "nexequ". Available online from | |
| https://www.math.upenn.edu/~wilf/website/CombAlgDownld.html (viewed | |
| November 17, 2012). | |
| """ | |
| p = [0]*n | |
| q = [0]*n | |
| nc = 1 | |
| yield nc, q | |
| while nc != n: | |
| m = n | |
| while 1: | |
| m -= 1 | |
| i = q[m] | |
| if p[i] != 1: | |
| break | |
| q[m] = 0 | |
| i += 1 | |
| q[m] = i | |
| m += 1 | |
| nc += m - n | |
| p[0] += n - m | |
| if i == nc: | |
| p[nc] = 0 | |
| nc += 1 | |
| p[i - 1] -= 1 | |
| p[i] += 1 | |
| yield nc, q | |
| def multiset_partitions(multiset, m=None): | |
| """ | |
| Return unique partitions of the given multiset (in list form). | |
| If ``m`` is None, all multisets will be returned, otherwise only | |
| partitions with ``m`` parts will be returned. | |
| If ``multiset`` is an integer, a range [0, 1, ..., multiset - 1] | |
| will be supplied. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import multiset_partitions | |
| >>> list(multiset_partitions([1, 2, 3, 4], 2)) | |
| [[[1, 2, 3], [4]], [[1, 2, 4], [3]], [[1, 2], [3, 4]], | |
| [[1, 3, 4], [2]], [[1, 3], [2, 4]], [[1, 4], [2, 3]], | |
| [[1], [2, 3, 4]]] | |
| >>> list(multiset_partitions([1, 2, 3, 4], 1)) | |
| [[[1, 2, 3, 4]]] | |
| Only unique partitions are returned and these will be returned in a | |
| canonical order regardless of the order of the input: | |
| >>> a = [1, 2, 2, 1] | |
| >>> ans = list(multiset_partitions(a, 2)) | |
| >>> a.sort() | |
| >>> list(multiset_partitions(a, 2)) == ans | |
| True | |
| >>> a = range(3, 1, -1) | |
| >>> (list(multiset_partitions(a)) == | |
| ... list(multiset_partitions(sorted(a)))) | |
| True | |
| If m is omitted then all partitions will be returned: | |
| >>> list(multiset_partitions([1, 1, 2])) | |
| [[[1, 1, 2]], [[1, 1], [2]], [[1, 2], [1]], [[1], [1], [2]]] | |
| >>> list(multiset_partitions([1]*3)) | |
| [[[1, 1, 1]], [[1], [1, 1]], [[1], [1], [1]]] | |
| Counting | |
| ======== | |
| The number of partitions of a set is given by the bell number: | |
| >>> from sympy import bell | |
| >>> len(list(multiset_partitions(5))) == bell(5) == 52 | |
| True | |
| The number of partitions of length k from a set of size n is given by the | |
| Stirling Number of the 2nd kind: | |
| >>> from sympy.functions.combinatorial.numbers import stirling | |
| >>> stirling(5, 2) == len(list(multiset_partitions(5, 2))) == 15 | |
| True | |
| These comments on counting apply to *sets*, not multisets. | |
| Notes | |
| ===== | |
| When all the elements are the same in the multiset, the order | |
| of the returned partitions is determined by the ``partitions`` | |
| routine. If one is counting partitions then it is better to use | |
| the ``nT`` function. | |
| See Also | |
| ======== | |
| partitions | |
| sympy.combinatorics.partitions.Partition | |
| sympy.combinatorics.partitions.IntegerPartition | |
| sympy.functions.combinatorial.numbers.nT | |
| """ | |
| # This function looks at the supplied input and dispatches to | |
| # several special-case routines as they apply. | |
| if isinstance(multiset, int): | |
| n = multiset | |
| if m and m > n: | |
| return | |
| multiset = list(range(n)) | |
| if m == 1: | |
| yield [multiset[:]] | |
| return | |
| # If m is not None, it can sometimes be faster to use | |
| # MultisetPartitionTraverser.enum_range() even for inputs | |
| # which are sets. Since the _set_partitions code is quite | |
| # fast, this is only advantageous when the overall set | |
| # partitions outnumber those with the desired number of parts | |
| # by a large factor. (At least 60.) Such a switch is not | |
| # currently implemented. | |
| for nc, q in _set_partitions(n): | |
| if m is None or nc == m: | |
| rv = [[] for i in range(nc)] | |
| for i in range(n): | |
| rv[q[i]].append(multiset[i]) | |
| yield rv | |
| return | |
| if len(multiset) == 1 and isinstance(multiset, str): | |
| multiset = [multiset] | |
| if not has_variety(multiset): | |
| # Only one component, repeated n times. The resulting | |
| # partitions correspond to partitions of integer n. | |
| n = len(multiset) | |
| if m and m > n: | |
| return | |
| if m == 1: | |
| yield [multiset[:]] | |
| return | |
| x = multiset[:1] | |
| for size, p in partitions(n, m, size=True): | |
| if m is None or size == m: | |
| rv = [] | |
| for k in sorted(p): | |
| rv.extend([x*k]*p[k]) | |
| yield rv | |
| else: | |
| from sympy.core.sorting import ordered | |
| multiset = list(ordered(multiset)) | |
| n = len(multiset) | |
| if m and m > n: | |
| return | |
| if m == 1: | |
| yield [multiset[:]] | |
| return | |
| # Split the information of the multiset into two lists - | |
| # one of the elements themselves, and one (of the same length) | |
| # giving the number of repeats for the corresponding element. | |
| elements, multiplicities = zip(*group(multiset, False)) | |
| if len(elements) < len(multiset): | |
| # General case - multiset with more than one distinct element | |
| # and at least one element repeated more than once. | |
| if m: | |
| mpt = MultisetPartitionTraverser() | |
| for state in mpt.enum_range(multiplicities, m-1, m): | |
| yield list_visitor(state, elements) | |
| else: | |
| for state in multiset_partitions_taocp(multiplicities): | |
| yield list_visitor(state, elements) | |
| else: | |
| # Set partitions case - no repeated elements. Pretty much | |
| # same as int argument case above, with same possible, but | |
| # currently unimplemented optimization for some cases when | |
| # m is not None | |
| for nc, q in _set_partitions(n): | |
| if m is None or nc == m: | |
| rv = [[] for i in range(nc)] | |
| for i in range(n): | |
| rv[q[i]].append(i) | |
| yield [[multiset[j] for j in i] for i in rv] | |
| def partitions(n, m=None, k=None, size=False): | |
| """Generate all partitions of positive integer, n. | |
| Each partition is represented as a dictionary, mapping an integer | |
| to the number of copies of that integer in the partition. For example, | |
| the first partition of 4 returned is {4: 1}, "4: one of them". | |
| Parameters | |
| ========== | |
| n : int | |
| m : int, optional | |
| limits number of parts in partition (mnemonic: m, maximum parts) | |
| k : int, optional | |
| limits the numbers that are kept in the partition (mnemonic: k, keys) | |
| size : bool, default: False | |
| If ``True``, (M, P) is returned where M is the sum of the | |
| multiplicities and P is the generated partition. | |
| If ``False``, only the generated partition is returned. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import partitions | |
| The numbers appearing in the partition (the key of the returned dict) | |
| are limited with k: | |
| >>> for p in partitions(6, k=2): # doctest: +SKIP | |
| ... print(p) | |
| {2: 3} | |
| {1: 2, 2: 2} | |
| {1: 4, 2: 1} | |
| {1: 6} | |
| The maximum number of parts in the partition (the sum of the values in | |
| the returned dict) are limited with m (default value, None, gives | |
| partitions from 1 through n): | |
| >>> for p in partitions(6, m=2): # doctest: +SKIP | |
| ... print(p) | |
| ... | |
| {6: 1} | |
| {1: 1, 5: 1} | |
| {2: 1, 4: 1} | |
| {3: 2} | |
| References | |
| ========== | |
| .. [1] modified from Tim Peter's version to allow for k and m values: | |
| https://code.activestate.com/recipes/218332-generator-for-integer-partitions/ | |
| See Also | |
| ======== | |
| sympy.combinatorics.partitions.Partition | |
| sympy.combinatorics.partitions.IntegerPartition | |
| """ | |
| if (n <= 0 or | |
| m is not None and m < 1 or | |
| k is not None and k < 1 or | |
| m and k and m*k < n): | |
| # the empty set is the only way to handle these inputs | |
| # and returning {} to represent it is consistent with | |
| # the counting convention, e.g. nT(0) == 1. | |
| if size: | |
| yield 0, {} | |
| else: | |
| yield {} | |
| return | |
| if m is None: | |
| m = n | |
| else: | |
| m = min(m, n) | |
| k = min(k or n, n) | |
| n, m, k = as_int(n), as_int(m), as_int(k) | |
| q, r = divmod(n, k) | |
| ms = {k: q} | |
| keys = [k] # ms.keys(), from largest to smallest | |
| if r: | |
| ms[r] = 1 | |
| keys.append(r) | |
| room = m - q - bool(r) | |
| if size: | |
| yield sum(ms.values()), ms.copy() | |
| else: | |
| yield ms.copy() | |
| while keys != [1]: | |
| # Reuse any 1's. | |
| if keys[-1] == 1: | |
| del keys[-1] | |
| reuse = ms.pop(1) | |
| room += reuse | |
| else: | |
| reuse = 0 | |
| while 1: | |
| # Let i be the smallest key larger than 1. Reuse one | |
| # instance of i. | |
| i = keys[-1] | |
| newcount = ms[i] = ms[i] - 1 | |
| reuse += i | |
| if newcount == 0: | |
| del keys[-1], ms[i] | |
| room += 1 | |
| # Break the remainder into pieces of size i-1. | |
| i -= 1 | |
| q, r = divmod(reuse, i) | |
| need = q + bool(r) | |
| if need > room: | |
| if not keys: | |
| return | |
| continue | |
| ms[i] = q | |
| keys.append(i) | |
| if r: | |
| ms[r] = 1 | |
| keys.append(r) | |
| break | |
| room -= need | |
| if size: | |
| yield sum(ms.values()), ms.copy() | |
| else: | |
| yield ms.copy() | |
| def ordered_partitions(n, m=None, sort=True): | |
| """Generates ordered partitions of integer *n*. | |
| Parameters | |
| ========== | |
| n : int | |
| m : int, optional | |
| The default value gives partitions of all sizes else only | |
| those with size m. In addition, if *m* is not None then | |
| partitions are generated *in place* (see examples). | |
| sort : bool, default: True | |
| Controls whether partitions are | |
| returned in sorted order when *m* is not None; when False, | |
| the partitions are returned as fast as possible with elements | |
| sorted, but when m|n the partitions will not be in | |
| ascending lexicographical order. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import ordered_partitions | |
| All partitions of 5 in ascending lexicographical: | |
| >>> for p in ordered_partitions(5): | |
| ... print(p) | |
| [1, 1, 1, 1, 1] | |
| [1, 1, 1, 2] | |
| [1, 1, 3] | |
| [1, 2, 2] | |
| [1, 4] | |
| [2, 3] | |
| [5] | |
| Only partitions of 5 with two parts: | |
| >>> for p in ordered_partitions(5, 2): | |
| ... print(p) | |
| [1, 4] | |
| [2, 3] | |
| When ``m`` is given, a given list objects will be used more than | |
| once for speed reasons so you will not see the correct partitions | |
| unless you make a copy of each as it is generated: | |
| >>> [p for p in ordered_partitions(7, 3)] | |
| [[1, 1, 1], [1, 1, 1], [1, 1, 1], [2, 2, 2]] | |
| >>> [list(p) for p in ordered_partitions(7, 3)] | |
| [[1, 1, 5], [1, 2, 4], [1, 3, 3], [2, 2, 3]] | |
| When ``n`` is a multiple of ``m``, the elements are still sorted | |
| but the partitions themselves will be *unordered* if sort is False; | |
| the default is to return them in ascending lexicographical order. | |
| >>> for p in ordered_partitions(6, 2): | |
| ... print(p) | |
| [1, 5] | |
| [2, 4] | |
| [3, 3] | |
| But if speed is more important than ordering, sort can be set to | |
| False: | |
| >>> for p in ordered_partitions(6, 2, sort=False): | |
| ... print(p) | |
| [1, 5] | |
| [3, 3] | |
| [2, 4] | |
| References | |
| ========== | |
| .. [1] Generating Integer Partitions, [online], | |
| Available: https://jeromekelleher.net/generating-integer-partitions.html | |
| .. [2] Jerome Kelleher and Barry O'Sullivan, "Generating All | |
| Partitions: A Comparison Of Two Encodings", [online], | |
| Available: https://arxiv.org/pdf/0909.2331v2.pdf | |
| """ | |
| if n < 1 or m is not None and m < 1: | |
| # the empty set is the only way to handle these inputs | |
| # and returning {} to represent it is consistent with | |
| # the counting convention, e.g. nT(0) == 1. | |
| yield [] | |
| return | |
| if m is None: | |
| # The list `a`'s leading elements contain the partition in which | |
| # y is the biggest element and x is either the same as y or the | |
| # 2nd largest element; v and w are adjacent element indices | |
| # to which x and y are being assigned, respectively. | |
| a = [1]*n | |
| y = -1 | |
| v = n | |
| while v > 0: | |
| v -= 1 | |
| x = a[v] + 1 | |
| while y >= 2 * x: | |
| a[v] = x | |
| y -= x | |
| v += 1 | |
| w = v + 1 | |
| while x <= y: | |
| a[v] = x | |
| a[w] = y | |
| yield a[:w + 1] | |
| x += 1 | |
| y -= 1 | |
| a[v] = x + y | |
| y = a[v] - 1 | |
| yield a[:w] | |
| elif m == 1: | |
| yield [n] | |
| elif n == m: | |
| yield [1]*n | |
| else: | |
| # recursively generate partitions of size m | |
| for b in range(1, n//m + 1): | |
| a = [b]*m | |
| x = n - b*m | |
| if not x: | |
| if sort: | |
| yield a | |
| elif not sort and x <= m: | |
| for ax in ordered_partitions(x, sort=False): | |
| mi = len(ax) | |
| a[-mi:] = [i + b for i in ax] | |
| yield a | |
| a[-mi:] = [b]*mi | |
| else: | |
| for mi in range(1, m): | |
| for ax in ordered_partitions(x, mi, sort=True): | |
| a[-mi:] = [i + b for i in ax] | |
| yield a | |
| a[-mi:] = [b]*mi | |
| def binary_partitions(n): | |
| """ | |
| Generates the binary partition of *n*. | |
| A binary partition consists only of numbers that are | |
| powers of two. Each step reduces a `2^{k+1}` to `2^k` and | |
| `2^k`. Thus 16 is converted to 8 and 8. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import binary_partitions | |
| >>> for i in binary_partitions(5): | |
| ... print(i) | |
| ... | |
| [4, 1] | |
| [2, 2, 1] | |
| [2, 1, 1, 1] | |
| [1, 1, 1, 1, 1] | |
| References | |
| ========== | |
| .. [1] TAOCP 4, section 7.2.1.5, problem 64 | |
| """ | |
| from math import ceil, log2 | |
| power = int(2**(ceil(log2(n)))) | |
| acc = 0 | |
| partition = [] | |
| while power: | |
| if acc + power <= n: | |
| partition.append(power) | |
| acc += power | |
| power >>= 1 | |
| last_num = len(partition) - 1 - (n & 1) | |
| while last_num >= 0: | |
| yield partition | |
| if partition[last_num] == 2: | |
| partition[last_num] = 1 | |
| partition.append(1) | |
| last_num -= 1 | |
| continue | |
| partition.append(1) | |
| partition[last_num] >>= 1 | |
| x = partition[last_num + 1] = partition[last_num] | |
| last_num += 1 | |
| while x > 1: | |
| if x <= len(partition) - last_num - 1: | |
| del partition[-x + 1:] | |
| last_num += 1 | |
| partition[last_num] = x | |
| else: | |
| x >>= 1 | |
| yield [1]*n | |
| def has_dups(seq): | |
| """Return True if there are any duplicate elements in ``seq``. | |
| Examples | |
| ======== | |
| >>> from sympy import has_dups, Dict, Set | |
| >>> has_dups((1, 2, 1)) | |
| True | |
| >>> has_dups(range(3)) | |
| False | |
| >>> all(has_dups(c) is False for c in (set(), Set(), dict(), Dict())) | |
| True | |
| """ | |
| from sympy.core.containers import Dict | |
| from sympy.sets.sets import Set | |
| if isinstance(seq, (dict, set, Dict, Set)): | |
| return False | |
| unique = set() | |
| try: | |
| return any(True for s in seq if s in unique or unique.add(s)) | |
| except TypeError: | |
| return len(seq) != len(list(uniq(seq))) | |
| def has_variety(seq): | |
| """Return True if there are any different elements in ``seq``. | |
| Examples | |
| ======== | |
| >>> from sympy import has_variety | |
| >>> has_variety((1, 2, 1)) | |
| True | |
| >>> has_variety((1, 1, 1)) | |
| False | |
| """ | |
| for i, s in enumerate(seq): | |
| if i == 0: | |
| sentinel = s | |
| else: | |
| if s != sentinel: | |
| return True | |
| return False | |
| def uniq(seq, result=None): | |
| """ | |
| Yield unique elements from ``seq`` as an iterator. The second | |
| parameter ``result`` is used internally; it is not necessary | |
| to pass anything for this. | |
| Note: changing the sequence during iteration will raise a | |
| RuntimeError if the size of the sequence is known; if you pass | |
| an iterator and advance the iterator you will change the | |
| output of this routine but there will be no warning. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import uniq | |
| >>> dat = [1, 4, 1, 5, 4, 2, 1, 2] | |
| >>> type(uniq(dat)) in (list, tuple) | |
| False | |
| >>> list(uniq(dat)) | |
| [1, 4, 5, 2] | |
| >>> list(uniq(x for x in dat)) | |
| [1, 4, 5, 2] | |
| >>> list(uniq([[1], [2, 1], [1]])) | |
| [[1], [2, 1]] | |
| """ | |
| try: | |
| n = len(seq) | |
| except TypeError: | |
| n = None | |
| def check(): | |
| # check that size of seq did not change during iteration; | |
| # if n == None the object won't support size changing, e.g. | |
| # an iterator can't be changed | |
| if n is not None and len(seq) != n: | |
| raise RuntimeError('sequence changed size during iteration') | |
| try: | |
| seen = set() | |
| result = result or [] | |
| for i, s in enumerate(seq): | |
| if not (s in seen or seen.add(s)): | |
| yield s | |
| check() | |
| except TypeError: | |
| if s not in result: | |
| yield s | |
| check() | |
| result.append(s) | |
| if hasattr(seq, '__getitem__'): | |
| yield from uniq(seq[i + 1:], result) | |
| else: | |
| yield from uniq(seq, result) | |
| def generate_bell(n): | |
| """Return permutations of [0, 1, ..., n - 1] such that each permutation | |
| differs from the last by the exchange of a single pair of neighbors. | |
| The ``n!`` permutations are returned as an iterator. In order to obtain | |
| the next permutation from a random starting permutation, use the | |
| ``next_trotterjohnson`` method of the Permutation class (which generates | |
| the same sequence in a different manner). | |
| Examples | |
| ======== | |
| >>> from itertools import permutations | |
| >>> from sympy.utilities.iterables import generate_bell | |
| >>> from sympy import zeros, Matrix | |
| This is the sort of permutation used in the ringing of physical bells, | |
| and does not produce permutations in lexicographical order. Rather, the | |
| permutations differ from each other by exactly one inversion, and the | |
| position at which the swapping occurs varies periodically in a simple | |
| fashion. Consider the first few permutations of 4 elements generated | |
| by ``permutations`` and ``generate_bell``: | |
| >>> list(permutations(range(4)))[:5] | |
| [(0, 1, 2, 3), (0, 1, 3, 2), (0, 2, 1, 3), (0, 2, 3, 1), (0, 3, 1, 2)] | |
| >>> list(generate_bell(4))[:5] | |
| [(0, 1, 2, 3), (0, 1, 3, 2), (0, 3, 1, 2), (3, 0, 1, 2), (3, 0, 2, 1)] | |
| Notice how the 2nd and 3rd lexicographical permutations have 3 elements | |
| out of place whereas each "bell" permutation always has only two | |
| elements out of place relative to the previous permutation (and so the | |
| signature (+/-1) of a permutation is opposite of the signature of the | |
| previous permutation). | |
| How the position of inversion varies across the elements can be seen | |
| by tracing out where the largest number appears in the permutations: | |
| >>> m = zeros(4, 24) | |
| >>> for i, p in enumerate(generate_bell(4)): | |
| ... m[:, i] = Matrix([j - 3 for j in list(p)]) # make largest zero | |
| >>> m.print_nonzero('X') | |
| [XXX XXXXXX XXXXXX XXX] | |
| [XX XX XXXX XX XXXX XX XX] | |
| [X XXXX XX XXXX XX XXXX X] | |
| [ XXXXXX XXXXXX XXXXXX ] | |
| See Also | |
| ======== | |
| sympy.combinatorics.permutations.Permutation.next_trotterjohnson | |
| References | |
| ========== | |
| .. [1] https://en.wikipedia.org/wiki/Method_ringing | |
| .. [2] https://stackoverflow.com/questions/4856615/recursive-permutation/4857018 | |
| .. [3] https://web.archive.org/web/20160313023044/http://programminggeeks.com/bell-algorithm-for-permutation/ | |
| .. [4] https://en.wikipedia.org/wiki/Steinhaus%E2%80%93Johnson%E2%80%93Trotter_algorithm | |
| .. [5] Generating involutions, derangements, and relatives by ECO | |
| Vincent Vajnovszki, DMTCS vol 1 issue 12, 2010 | |
| """ | |
| n = as_int(n) | |
| if n < 1: | |
| raise ValueError('n must be a positive integer') | |
| if n == 1: | |
| yield (0,) | |
| elif n == 2: | |
| yield (0, 1) | |
| yield (1, 0) | |
| elif n == 3: | |
| yield from [(0, 1, 2), (0, 2, 1), (2, 0, 1), (2, 1, 0), (1, 2, 0), (1, 0, 2)] | |
| else: | |
| m = n - 1 | |
| op = [0] + [-1]*m | |
| l = list(range(n)) | |
| while True: | |
| yield tuple(l) | |
| # find biggest element with op | |
| big = None, -1 # idx, value | |
| for i in range(n): | |
| if op[i] and l[i] > big[1]: | |
| big = i, l[i] | |
| i, _ = big | |
| if i is None: | |
| break # there are no ops left | |
| # swap it with neighbor in the indicated direction | |
| j = i + op[i] | |
| l[i], l[j] = l[j], l[i] | |
| op[i], op[j] = op[j], op[i] | |
| # if it landed at the end or if the neighbor in the same | |
| # direction is bigger then turn off op | |
| if j == 0 or j == m or l[j + op[j]] > l[j]: | |
| op[j] = 0 | |
| # any element bigger to the left gets +1 op | |
| for i in range(j): | |
| if l[i] > l[j]: | |
| op[i] = 1 | |
| # any element bigger to the right gets -1 op | |
| for i in range(j + 1, n): | |
| if l[i] > l[j]: | |
| op[i] = -1 | |
| def generate_involutions(n): | |
| """ | |
| Generates involutions. | |
| An involution is a permutation that when multiplied | |
| by itself equals the identity permutation. In this | |
| implementation the involutions are generated using | |
| Fixed Points. | |
| Alternatively, an involution can be considered as | |
| a permutation that does not contain any cycles with | |
| a length that is greater than two. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import generate_involutions | |
| >>> list(generate_involutions(3)) | |
| [(0, 1, 2), (0, 2, 1), (1, 0, 2), (2, 1, 0)] | |
| >>> len(list(generate_involutions(4))) | |
| 10 | |
| References | |
| ========== | |
| .. [1] https://mathworld.wolfram.com/PermutationInvolution.html | |
| """ | |
| idx = list(range(n)) | |
| for p in permutations(idx): | |
| for i in idx: | |
| if p[p[i]] != i: | |
| break | |
| else: | |
| yield p | |
| def multiset_derangements(s): | |
| """Generate derangements of the elements of s *in place*. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import multiset_derangements, uniq | |
| Because the derangements of multisets (not sets) are generated | |
| in place, copies of the return value must be made if a collection | |
| of derangements is desired or else all values will be the same: | |
| >>> list(uniq([i for i in multiset_derangements('1233')])) | |
| [[None, None, None, None]] | |
| >>> [i.copy() for i in multiset_derangements('1233')] | |
| [['3', '3', '1', '2'], ['3', '3', '2', '1']] | |
| >>> [''.join(i) for i in multiset_derangements('1233')] | |
| ['3312', '3321'] | |
| """ | |
| from sympy.core.sorting import ordered | |
| # create multiset dictionary of hashable elements or else | |
| # remap elements to integers | |
| try: | |
| ms = multiset(s) | |
| except TypeError: | |
| # give each element a canonical integer value | |
| key = dict(enumerate(ordered(uniq(s)))) | |
| h = [] | |
| for si in s: | |
| for k in key: | |
| if key[k] == si: | |
| h.append(k) | |
| break | |
| for i in multiset_derangements(h): | |
| yield [key[j] for j in i] | |
| return | |
| mx = max(ms.values()) # max repetition of any element | |
| n = len(s) # the number of elements | |
| ## special cases | |
| # 1) one element has more than half the total cardinality of s: no | |
| # derangements are possible. | |
| if mx*2 > n: | |
| return | |
| # 2) all elements appear once: singletons | |
| if len(ms) == n: | |
| yield from _set_derangements(s) | |
| return | |
| # find the first element that is repeated the most to place | |
| # in the following two special cases where the selection | |
| # is unambiguous: either there are two elements with multiplicity | |
| # of mx or else there is only one with multiplicity mx | |
| for M in ms: | |
| if ms[M] == mx: | |
| break | |
| inonM = [i for i in range(n) if s[i] != M] # location of non-M | |
| iM = [i for i in range(n) if s[i] == M] # locations of M | |
| rv = [None]*n | |
| # 3) half are the same | |
| if 2*mx == n: | |
| # M goes into non-M locations | |
| for i in inonM: | |
| rv[i] = M | |
| # permutations of non-M go to M locations | |
| for p in multiset_permutations([s[i] for i in inonM]): | |
| for i, pi in zip(iM, p): | |
| rv[i] = pi | |
| yield rv | |
| # clean-up (and encourages proper use of routine) | |
| rv[:] = [None]*n | |
| return | |
| # 4) single repeat covers all but 1 of the non-repeats: | |
| # if there is one repeat then the multiset of the values | |
| # of ms would be {mx: 1, 1: n - mx}, i.e. there would | |
| # be n - mx + 1 values with the condition that n - 2*mx = 1 | |
| if n - 2*mx == 1 and len(ms.values()) == n - mx + 1: | |
| for i, i1 in enumerate(inonM): | |
| ifill = inonM[:i] + inonM[i+1:] | |
| for j in ifill: | |
| rv[j] = M | |
| for p in permutations([s[j] for j in ifill]): | |
| rv[i1] = s[i1] | |
| for j, pi in zip(iM, p): | |
| rv[j] = pi | |
| k = i1 | |
| for j in iM: | |
| rv[j], rv[k] = rv[k], rv[j] | |
| yield rv | |
| k = j | |
| # clean-up (and encourages proper use of routine) | |
| rv[:] = [None]*n | |
| return | |
| ## general case is handled with 3 helpers: | |
| # 1) `finish_derangements` will place the last two elements | |
| # which have arbitrary multiplicities, e.g. for multiset | |
| # {c: 3, a: 2, b: 2}, the last two elements are a and b | |
| # 2) `iopen` will tell where a given element can be placed | |
| # 3) `do` will recursively place elements into subsets of | |
| # valid locations | |
| def finish_derangements(): | |
| """Place the last two elements into the partially completed | |
| derangement, and yield the results. | |
| """ | |
| a = take[1][0] # penultimate element | |
| a_ct = take[1][1] | |
| b = take[0][0] # last element to be placed | |
| b_ct = take[0][1] | |
| # split the indexes of the not-already-assigned elements of rv into | |
| # three categories | |
| forced_a = [] # positions which must have an a | |
| forced_b = [] # positions which must have a b | |
| open_free = [] # positions which could take either | |
| for i in range(len(s)): | |
| if rv[i] is None: | |
| if s[i] == a: | |
| forced_b.append(i) | |
| elif s[i] == b: | |
| forced_a.append(i) | |
| else: | |
| open_free.append(i) | |
| if len(forced_a) > a_ct or len(forced_b) > b_ct: | |
| # No derangement possible | |
| return | |
| for i in forced_a: | |
| rv[i] = a | |
| for i in forced_b: | |
| rv[i] = b | |
| for a_place in combinations(open_free, a_ct - len(forced_a)): | |
| for a_pos in a_place: | |
| rv[a_pos] = a | |
| for i in open_free: | |
| if rv[i] is None: # anything not in the subset is set to b | |
| rv[i] = b | |
| yield rv | |
| # Clean up/undo the final placements | |
| for i in open_free: | |
| rv[i] = None | |
| # additional cleanup - clear forced_a, forced_b | |
| for i in forced_a: | |
| rv[i] = None | |
| for i in forced_b: | |
| rv[i] = None | |
| def iopen(v): | |
| # return indices at which element v can be placed in rv: | |
| # locations which are not already occupied if that location | |
| # does not already contain v in the same location of s | |
| return [i for i in range(n) if rv[i] is None and s[i] != v] | |
| def do(j): | |
| if j == 1: | |
| # handle the last two elements (regardless of multiplicity) | |
| # with a special method | |
| yield from finish_derangements() | |
| else: | |
| # place the mx elements of M into a subset of places | |
| # into which it can be replaced | |
| M, mx = take[j] | |
| for i in combinations(iopen(M), mx): | |
| # place M | |
| for ii in i: | |
| rv[ii] = M | |
| # recursively place the next element | |
| yield from do(j - 1) | |
| # mark positions where M was placed as once again | |
| # open for placement of other elements | |
| for ii in i: | |
| rv[ii] = None | |
| # process elements in order of canonically decreasing multiplicity | |
| take = sorted(ms.items(), key=lambda x:(x[1], x[0])) | |
| yield from do(len(take) - 1) | |
| rv[:] = [None]*n | |
| def random_derangement(t, choice=None, strict=True): | |
| """Return a list of elements in which none are in the same positions | |
| as they were originally. If an element fills more than half of the positions | |
| then an error will be raised since no derangement is possible. To obtain | |
| a derangement of as many items as possible--with some of the most numerous | |
| remaining in their original positions--pass `strict=False`. To produce a | |
| pseudorandom derangment, pass a pseudorandom selector like `choice` (see | |
| below). | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import random_derangement | |
| >>> t = 'SymPy: a CAS in pure Python' | |
| >>> d = random_derangement(t) | |
| >>> all(i != j for i, j in zip(d, t)) | |
| True | |
| A predictable result can be obtained by using a pseudorandom | |
| generator for the choice: | |
| >>> from sympy.core.random import seed, choice as c | |
| >>> seed(1) | |
| >>> d = [''.join(random_derangement(t, c)) for i in range(5)] | |
| >>> assert len(set(d)) != 1 # we got different values | |
| By reseeding, the same sequence can be obtained: | |
| >>> seed(1) | |
| >>> d2 = [''.join(random_derangement(t, c)) for i in range(5)] | |
| >>> assert d == d2 | |
| """ | |
| if choice is None: | |
| import secrets | |
| choice = secrets.choice | |
| def shuffle(rv): | |
| '''Knuth shuffle''' | |
| for i in range(len(rv) - 1, 0, -1): | |
| x = choice(rv[:i + 1]) | |
| j = rv.index(x) | |
| rv[i], rv[j] = rv[j], rv[i] | |
| def pick(rv, n): | |
| '''shuffle rv and return the first n values | |
| ''' | |
| shuffle(rv) | |
| return rv[:n] | |
| ms = multiset(t) | |
| tot = len(t) | |
| ms = sorted(ms.items(), key=lambda x: x[1]) | |
| # if there are not enough spaces for the most | |
| # plentiful element to move to then some of them | |
| # will have to stay in place | |
| M, mx = ms[-1] | |
| n = len(t) | |
| xs = 2*mx - tot | |
| if xs > 0: | |
| if strict: | |
| raise ValueError('no derangement possible') | |
| opts = [i for (i, c) in enumerate(t) if c == ms[-1][0]] | |
| pick(opts, xs) | |
| stay = sorted(opts[:xs]) | |
| rv = list(t) | |
| for i in reversed(stay): | |
| rv.pop(i) | |
| rv = random_derangement(rv, choice) | |
| for i in stay: | |
| rv.insert(i, ms[-1][0]) | |
| return ''.join(rv) if type(t) is str else rv | |
| # the normal derangement calculated from here | |
| if n == len(ms): | |
| # approx 1/3 will succeed | |
| rv = list(t) | |
| while True: | |
| shuffle(rv) | |
| if all(i != j for i,j in zip(rv, t)): | |
| break | |
| else: | |
| # general case | |
| rv = [None]*n | |
| while True: | |
| j = 0 | |
| while j > -len(ms): # do most numerous first | |
| j -= 1 | |
| e, c = ms[j] | |
| opts = [i for i in range(n) if rv[i] is None and t[i] != e] | |
| if len(opts) < c: | |
| for i in range(n): | |
| rv[i] = None | |
| break # try again | |
| pick(opts, c) | |
| for i in range(c): | |
| rv[opts[i]] = e | |
| else: | |
| return rv | |
| return rv | |
| def _set_derangements(s): | |
| """ | |
| yield derangements of items in ``s`` which are assumed to contain | |
| no repeated elements | |
| """ | |
| if len(s) < 2: | |
| return | |
| if len(s) == 2: | |
| yield [s[1], s[0]] | |
| return | |
| if len(s) == 3: | |
| yield [s[1], s[2], s[0]] | |
| yield [s[2], s[0], s[1]] | |
| return | |
| for p in permutations(s): | |
| if not any(i == j for i, j in zip(p, s)): | |
| yield list(p) | |
| def generate_derangements(s): | |
| """ | |
| Return unique derangements of the elements of iterable ``s``. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import generate_derangements | |
| >>> list(generate_derangements([0, 1, 2])) | |
| [[1, 2, 0], [2, 0, 1]] | |
| >>> list(generate_derangements([0, 1, 2, 2])) | |
| [[2, 2, 0, 1], [2, 2, 1, 0]] | |
| >>> list(generate_derangements([0, 1, 1])) | |
| [] | |
| See Also | |
| ======== | |
| sympy.functions.combinatorial.factorials.subfactorial | |
| """ | |
| if not has_dups(s): | |
| yield from _set_derangements(s) | |
| else: | |
| for p in multiset_derangements(s): | |
| yield list(p) | |
| def necklaces(n, k, free=False): | |
| """ | |
| A routine to generate necklaces that may (free=True) or may not | |
| (free=False) be turned over to be viewed. The "necklaces" returned | |
| are comprised of ``n`` integers (beads) with ``k`` different | |
| values (colors). Only unique necklaces are returned. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import necklaces, bracelets | |
| >>> def show(s, i): | |
| ... return ''.join(s[j] for j in i) | |
| The "unrestricted necklace" is sometimes also referred to as a | |
| "bracelet" (an object that can be turned over, a sequence that can | |
| be reversed) and the term "necklace" is used to imply a sequence | |
| that cannot be reversed. So ACB == ABC for a bracelet (rotate and | |
| reverse) while the two are different for a necklace since rotation | |
| alone cannot make the two sequences the same. | |
| (mnemonic: Bracelets can be viewed Backwards, but Not Necklaces.) | |
| >>> B = [show('ABC', i) for i in bracelets(3, 3)] | |
| >>> N = [show('ABC', i) for i in necklaces(3, 3)] | |
| >>> set(N) - set(B) | |
| {'ACB'} | |
| >>> list(necklaces(4, 2)) | |
| [(0, 0, 0, 0), (0, 0, 0, 1), (0, 0, 1, 1), | |
| (0, 1, 0, 1), (0, 1, 1, 1), (1, 1, 1, 1)] | |
| >>> [show('.o', i) for i in bracelets(4, 2)] | |
| ['....', '...o', '..oo', '.o.o', '.ooo', 'oooo'] | |
| References | |
| ========== | |
| .. [1] https://mathworld.wolfram.com/Necklace.html | |
| .. [2] Frank Ruskey, Carla Savage, and Terry Min Yih Wang, | |
| Generating necklaces, Journal of Algorithms 13 (1992), 414-430; | |
| https://doi.org/10.1016/0196-6774(92)90047-G | |
| """ | |
| # The FKM algorithm | |
| if k == 0 and n > 0: | |
| return | |
| a = [0]*n | |
| yield tuple(a) | |
| if n == 0: | |
| return | |
| while True: | |
| i = n - 1 | |
| while a[i] == k - 1: | |
| i -= 1 | |
| if i == -1: | |
| return | |
| a[i] += 1 | |
| for j in range(n - i - 1): | |
| a[j + i + 1] = a[j] | |
| if n % (i + 1) == 0 and (not free or all(a <= a[j::-1] + a[-1:j:-1] for j in range(n - 1))): | |
| # No need to test j = n - 1. | |
| yield tuple(a) | |
| def bracelets(n, k): | |
| """Wrapper to necklaces to return a free (unrestricted) necklace.""" | |
| return necklaces(n, k, free=True) | |
| def generate_oriented_forest(n): | |
| """ | |
| This algorithm generates oriented forests. | |
| An oriented graph is a directed graph having no symmetric pair of directed | |
| edges. A forest is an acyclic graph, i.e., it has no cycles. A forest can | |
| also be described as a disjoint union of trees, which are graphs in which | |
| any two vertices are connected by exactly one simple path. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import generate_oriented_forest | |
| >>> list(generate_oriented_forest(4)) | |
| [[0, 1, 2, 3], [0, 1, 2, 2], [0, 1, 2, 1], [0, 1, 2, 0], \ | |
| [0, 1, 1, 1], [0, 1, 1, 0], [0, 1, 0, 1], [0, 1, 0, 0], [0, 0, 0, 0]] | |
| References | |
| ========== | |
| .. [1] T. Beyer and S.M. Hedetniemi: constant time generation of | |
| rooted trees, SIAM J. Computing Vol. 9, No. 4, November 1980 | |
| .. [2] https://stackoverflow.com/questions/1633833/oriented-forest-taocp-algorithm-in-python | |
| """ | |
| P = list(range(-1, n)) | |
| while True: | |
| yield P[1:] | |
| if P[n] > 0: | |
| P[n] = P[P[n]] | |
| else: | |
| for p in range(n - 1, 0, -1): | |
| if P[p] != 0: | |
| target = P[p] - 1 | |
| for q in range(p - 1, 0, -1): | |
| if P[q] == target: | |
| break | |
| offset = p - q | |
| for i in range(p, n + 1): | |
| P[i] = P[i - offset] | |
| break | |
| else: | |
| break | |
| def minlex(seq, directed=True, key=None): | |
| r""" | |
| Return the rotation of the sequence in which the lexically smallest | |
| elements appear first, e.g. `cba \rightarrow acb`. | |
| The sequence returned is a tuple, unless the input sequence is a string | |
| in which case a string is returned. | |
| If ``directed`` is False then the smaller of the sequence and the | |
| reversed sequence is returned, e.g. `cba \rightarrow abc`. | |
| If ``key`` is not None then it is used to extract a comparison key from each element in iterable. | |
| Examples | |
| ======== | |
| >>> from sympy.combinatorics.polyhedron import minlex | |
| >>> minlex((1, 2, 0)) | |
| (0, 1, 2) | |
| >>> minlex((1, 0, 2)) | |
| (0, 2, 1) | |
| >>> minlex((1, 0, 2), directed=False) | |
| (0, 1, 2) | |
| >>> minlex('11010011000', directed=True) | |
| '00011010011' | |
| >>> minlex('11010011000', directed=False) | |
| '00011001011' | |
| >>> minlex(('bb', 'aaa', 'c', 'a')) | |
| ('a', 'bb', 'aaa', 'c') | |
| >>> minlex(('bb', 'aaa', 'c', 'a'), key=len) | |
| ('c', 'a', 'bb', 'aaa') | |
| """ | |
| from sympy.functions.elementary.miscellaneous import Id | |
| if key is None: key = Id | |
| best = rotate_left(seq, least_rotation(seq, key=key)) | |
| if not directed: | |
| rseq = seq[::-1] | |
| rbest = rotate_left(rseq, least_rotation(rseq, key=key)) | |
| best = min(best, rbest, key=key) | |
| # Convert to tuple, unless we started with a string. | |
| return tuple(best) if not isinstance(seq, str) else best | |
| def runs(seq, op=gt): | |
| """Group the sequence into lists in which successive elements | |
| all compare the same with the comparison operator, ``op``: | |
| op(seq[i + 1], seq[i]) is True from all elements in a run. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import runs | |
| >>> from operator import ge | |
| >>> runs([0, 1, 2, 2, 1, 4, 3, 2, 2]) | |
| [[0, 1, 2], [2], [1, 4], [3], [2], [2]] | |
| >>> runs([0, 1, 2, 2, 1, 4, 3, 2, 2], op=ge) | |
| [[0, 1, 2, 2], [1, 4], [3], [2, 2]] | |
| """ | |
| cycles = [] | |
| seq = iter(seq) | |
| try: | |
| run = [next(seq)] | |
| except StopIteration: | |
| return [] | |
| while True: | |
| try: | |
| ei = next(seq) | |
| except StopIteration: | |
| break | |
| if op(ei, run[-1]): | |
| run.append(ei) | |
| continue | |
| else: | |
| cycles.append(run) | |
| run = [ei] | |
| if run: | |
| cycles.append(run) | |
| return cycles | |
| def sequence_partitions(l, n, /): | |
| r"""Returns the partition of sequence $l$ into $n$ bins | |
| Explanation | |
| =========== | |
| Given the sequence $l_1 \cdots l_m \in V^+$ where | |
| $V^+$ is the Kleene plus of $V$ | |
| The set of $n$ partitions of $l$ is defined as: | |
| .. math:: | |
| \{(s_1, \cdots, s_n) | s_1 \in V^+, \cdots, s_n \in V^+, | |
| s_1 \cdots s_n = l_1 \cdots l_m\} | |
| Parameters | |
| ========== | |
| l : Sequence[T] | |
| A nonempty sequence of any Python objects | |
| n : int | |
| A positive integer | |
| Yields | |
| ====== | |
| out : list[Sequence[T]] | |
| A list of sequences with concatenation equals $l$. | |
| This should conform with the type of $l$. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import sequence_partitions | |
| >>> for out in sequence_partitions([1, 2, 3, 4], 2): | |
| ... print(out) | |
| [[1], [2, 3, 4]] | |
| [[1, 2], [3, 4]] | |
| [[1, 2, 3], [4]] | |
| Notes | |
| ===== | |
| This is modified version of EnricoGiampieri's partition generator | |
| from https://stackoverflow.com/questions/13131491/partition-n-items-into-k-bins-in-python-lazily | |
| See Also | |
| ======== | |
| sequence_partitions_empty | |
| """ | |
| # Asserting l is nonempty is done only for sanity check | |
| if n == 1 and l: | |
| yield [l] | |
| return | |
| for i in range(1, len(l)): | |
| for part in sequence_partitions(l[i:], n - 1): | |
| yield [l[:i]] + part | |
| def sequence_partitions_empty(l, n, /): | |
| r"""Returns the partition of sequence $l$ into $n$ bins with | |
| empty sequence | |
| Explanation | |
| =========== | |
| Given the sequence $l_1 \cdots l_m \in V^*$ where | |
| $V^*$ is the Kleene star of $V$ | |
| The set of $n$ partitions of $l$ is defined as: | |
| .. math:: | |
| \{(s_1, \cdots, s_n) | s_1 \in V^*, \cdots, s_n \in V^*, | |
| s_1 \cdots s_n = l_1 \cdots l_m\} | |
| There are more combinations than :func:`sequence_partitions` because | |
| empty sequence can fill everywhere, so we try to provide different | |
| utility for this. | |
| Parameters | |
| ========== | |
| l : Sequence[T] | |
| A sequence of any Python objects (can be possibly empty) | |
| n : int | |
| A positive integer | |
| Yields | |
| ====== | |
| out : list[Sequence[T]] | |
| A list of sequences with concatenation equals $l$. | |
| This should conform with the type of $l$. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import sequence_partitions_empty | |
| >>> for out in sequence_partitions_empty([1, 2, 3, 4], 2): | |
| ... print(out) | |
| [[], [1, 2, 3, 4]] | |
| [[1], [2, 3, 4]] | |
| [[1, 2], [3, 4]] | |
| [[1, 2, 3], [4]] | |
| [[1, 2, 3, 4], []] | |
| See Also | |
| ======== | |
| sequence_partitions | |
| """ | |
| if n < 1: | |
| return | |
| if n == 1: | |
| yield [l] | |
| return | |
| for i in range(0, len(l) + 1): | |
| for part in sequence_partitions_empty(l[i:], n - 1): | |
| yield [l[:i]] + part | |
| def kbins(l, k, ordered=None): | |
| """ | |
| Return sequence ``l`` partitioned into ``k`` bins. | |
| Examples | |
| ======== | |
| The default is to give the items in the same order, but grouped | |
| into k partitions without any reordering: | |
| >>> from sympy.utilities.iterables import kbins | |
| >>> for p in kbins(list(range(5)), 2): | |
| ... print(p) | |
| ... | |
| [[0], [1, 2, 3, 4]] | |
| [[0, 1], [2, 3, 4]] | |
| [[0, 1, 2], [3, 4]] | |
| [[0, 1, 2, 3], [4]] | |
| The ``ordered`` flag is either None (to give the simple partition | |
| of the elements) or is a 2 digit integer indicating whether the order of | |
| the bins and the order of the items in the bins matters. Given:: | |
| A = [[0], [1, 2]] | |
| B = [[1, 2], [0]] | |
| C = [[2, 1], [0]] | |
| D = [[0], [2, 1]] | |
| the following values for ``ordered`` have the shown meanings:: | |
| 00 means A == B == C == D | |
| 01 means A == B | |
| 10 means A == D | |
| 11 means A == A | |
| >>> for ordered_flag in [None, 0, 1, 10, 11]: | |
| ... print('ordered = %s' % ordered_flag) | |
| ... for p in kbins(list(range(3)), 2, ordered=ordered_flag): | |
| ... print(' %s' % p) | |
| ... | |
| ordered = None | |
| [[0], [1, 2]] | |
| [[0, 1], [2]] | |
| ordered = 0 | |
| [[0, 1], [2]] | |
| [[0, 2], [1]] | |
| [[0], [1, 2]] | |
| ordered = 1 | |
| [[0], [1, 2]] | |
| [[0], [2, 1]] | |
| [[1], [0, 2]] | |
| [[1], [2, 0]] | |
| [[2], [0, 1]] | |
| [[2], [1, 0]] | |
| ordered = 10 | |
| [[0, 1], [2]] | |
| [[2], [0, 1]] | |
| [[0, 2], [1]] | |
| [[1], [0, 2]] | |
| [[0], [1, 2]] | |
| [[1, 2], [0]] | |
| ordered = 11 | |
| [[0], [1, 2]] | |
| [[0, 1], [2]] | |
| [[0], [2, 1]] | |
| [[0, 2], [1]] | |
| [[1], [0, 2]] | |
| [[1, 0], [2]] | |
| [[1], [2, 0]] | |
| [[1, 2], [0]] | |
| [[2], [0, 1]] | |
| [[2, 0], [1]] | |
| [[2], [1, 0]] | |
| [[2, 1], [0]] | |
| See Also | |
| ======== | |
| partitions, multiset_partitions | |
| """ | |
| if ordered is None: | |
| yield from sequence_partitions(l, k) | |
| elif ordered == 11: | |
| for pl in multiset_permutations(l): | |
| pl = list(pl) | |
| yield from sequence_partitions(pl, k) | |
| elif ordered == 00: | |
| yield from multiset_partitions(l, k) | |
| elif ordered == 10: | |
| for p in multiset_partitions(l, k): | |
| for perm in permutations(p): | |
| yield list(perm) | |
| elif ordered == 1: | |
| for kgot, p in partitions(len(l), k, size=True): | |
| if kgot != k: | |
| continue | |
| for li in multiset_permutations(l): | |
| rv = [] | |
| i = j = 0 | |
| li = list(li) | |
| for size, multiplicity in sorted(p.items()): | |
| for m in range(multiplicity): | |
| j = i + size | |
| rv.append(li[i: j]) | |
| i = j | |
| yield rv | |
| else: | |
| raise ValueError( | |
| 'ordered must be one of 00, 01, 10 or 11, not %s' % ordered) | |
| def permute_signs(t): | |
| """Return iterator in which the signs of non-zero elements | |
| of t are permuted. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import permute_signs | |
| >>> list(permute_signs((0, 1, 2))) | |
| [(0, 1, 2), (0, -1, 2), (0, 1, -2), (0, -1, -2)] | |
| """ | |
| for signs in product(*[(1, -1)]*(len(t) - t.count(0))): | |
| signs = list(signs) | |
| yield type(t)([i*signs.pop() if i else i for i in t]) | |
| def signed_permutations(t): | |
| """Return iterator in which the signs of non-zero elements | |
| of t and the order of the elements are permuted and all | |
| returned values are unique. | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import signed_permutations | |
| >>> list(signed_permutations((0, 1, 2))) | |
| [(0, 1, 2), (0, -1, 2), (0, 1, -2), (0, -1, -2), (0, 2, 1), | |
| (0, -2, 1), (0, 2, -1), (0, -2, -1), (1, 0, 2), (-1, 0, 2), | |
| (1, 0, -2), (-1, 0, -2), (1, 2, 0), (-1, 2, 0), (1, -2, 0), | |
| (-1, -2, 0), (2, 0, 1), (-2, 0, 1), (2, 0, -1), (-2, 0, -1), | |
| (2, 1, 0), (-2, 1, 0), (2, -1, 0), (-2, -1, 0)] | |
| """ | |
| return (type(t)(i) for j in multiset_permutations(t) | |
| for i in permute_signs(j)) | |
| def rotations(s, dir=1): | |
| """Return a generator giving the items in s as list where | |
| each subsequent list has the items rotated to the left (default) | |
| or right (``dir=-1``) relative to the previous list. | |
| Examples | |
| ======== | |
| >>> from sympy import rotations | |
| >>> list(rotations([1,2,3])) | |
| [[1, 2, 3], [2, 3, 1], [3, 1, 2]] | |
| >>> list(rotations([1,2,3], -1)) | |
| [[1, 2, 3], [3, 1, 2], [2, 3, 1]] | |
| """ | |
| seq = list(s) | |
| for i in range(len(seq)): | |
| yield seq | |
| seq = rotate_left(seq, dir) | |
| def roundrobin(*iterables): | |
| """roundrobin recipe taken from itertools documentation: | |
| https://docs.python.org/3/library/itertools.html#itertools-recipes | |
| roundrobin('ABC', 'D', 'EF') --> A D E B F C | |
| Recipe credited to George Sakkis | |
| """ | |
| nexts = cycle(iter(it).__next__ for it in iterables) | |
| pending = len(iterables) | |
| while pending: | |
| try: | |
| for nxt in nexts: | |
| yield nxt() | |
| except StopIteration: | |
| pending -= 1 | |
| nexts = cycle(islice(nexts, pending)) | |
| class NotIterable: | |
| """ | |
| Use this as mixin when creating a class which is not supposed to | |
| return true when iterable() is called on its instances because | |
| calling list() on the instance, for example, would result in | |
| an infinite loop. | |
| """ | |
| pass | |
| def iterable(i, exclude=(str, dict, NotIterable)): | |
| """ | |
| Return a boolean indicating whether ``i`` is SymPy iterable. | |
| True also indicates that the iterator is finite, e.g. you can | |
| call list(...) on the instance. | |
| When SymPy is working with iterables, it is almost always assuming | |
| that the iterable is not a string or a mapping, so those are excluded | |
| by default. If you want a pure Python definition, make exclude=None. To | |
| exclude multiple items, pass them as a tuple. | |
| You can also set the _iterable attribute to True or False on your class, | |
| which will override the checks here, including the exclude test. | |
| As a rule of thumb, some SymPy functions use this to check if they should | |
| recursively map over an object. If an object is technically iterable in | |
| the Python sense but does not desire this behavior (e.g., because its | |
| iteration is not finite, or because iteration might induce an unwanted | |
| computation), it should disable it by setting the _iterable attribute to False. | |
| See also: is_sequence | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import iterable | |
| >>> from sympy import Tuple | |
| >>> things = [[1], (1,), set([1]), Tuple(1), (j for j in [1, 2]), {1:2}, '1', 1] | |
| >>> for i in things: | |
| ... print('%s %s' % (iterable(i), type(i))) | |
| True <... 'list'> | |
| True <... 'tuple'> | |
| True <... 'set'> | |
| True <class 'sympy.core.containers.Tuple'> | |
| True <... 'generator'> | |
| False <... 'dict'> | |
| False <... 'str'> | |
| False <... 'int'> | |
| >>> iterable({}, exclude=None) | |
| True | |
| >>> iterable({}, exclude=str) | |
| True | |
| >>> iterable("no", exclude=str) | |
| False | |
| """ | |
| if hasattr(i, '_iterable'): | |
| return i._iterable | |
| try: | |
| iter(i) | |
| except TypeError: | |
| return False | |
| if exclude: | |
| return not isinstance(i, exclude) | |
| return True | |
| def is_sequence(i, include=None): | |
| """ | |
| Return a boolean indicating whether ``i`` is a sequence in the SymPy | |
| sense. If anything that fails the test below should be included as | |
| being a sequence for your application, set 'include' to that object's | |
| type; multiple types should be passed as a tuple of types. | |
| Note: although generators can generate a sequence, they often need special | |
| handling to make sure their elements are captured before the generator is | |
| exhausted, so these are not included by default in the definition of a | |
| sequence. | |
| See also: iterable | |
| Examples | |
| ======== | |
| >>> from sympy.utilities.iterables import is_sequence | |
| >>> from types import GeneratorType | |
| >>> is_sequence([]) | |
| True | |
| >>> is_sequence(set()) | |
| False | |
| >>> is_sequence('abc') | |
| False | |
| >>> is_sequence('abc', include=str) | |
| True | |
| >>> generator = (c for c in 'abc') | |
| >>> is_sequence(generator) | |
| False | |
| >>> is_sequence(generator, include=(str, GeneratorType)) | |
| True | |
| """ | |
| return (hasattr(i, '__getitem__') and | |
| iterable(i) or | |
| bool(include) and | |
| isinstance(i, include)) | |
| def postorder_traversal(node, keys=None): | |
| from sympy.core.traversal import postorder_traversal as _postorder_traversal | |
| return _postorder_traversal(node, keys=keys) | |
| def interactive_traversal(expr): | |
| from sympy.interactive.traversal import interactive_traversal as _interactive_traversal | |
| return _interactive_traversal(expr) | |
| def default_sort_key(*args, **kwargs): | |
| from sympy import default_sort_key as _default_sort_key | |
| return _default_sort_key(*args, **kwargs) | |
| def ordered(*args, **kwargs): | |
| from sympy import ordered as _ordered | |
| return _ordered(*args, **kwargs) | |
Xet Storage Details
- Size:
- 91.1 kB
- Xet hash:
- 7702825e653bff5ddbd89ba41697f3c65bdfbb38f89103d791242ae903b0b85b
·
Xet efficiently stores files, intelligently splitting them into unique chunks and accelerating uploads and downloads. More info.