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287 lines
8.3 KiB
287 lines
8.3 KiB
5 months ago
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"""Definitions of monomial orderings. """
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from __future__ import annotations
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__all__ = ["lex", "grlex", "grevlex", "ilex", "igrlex", "igrevlex"]
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from sympy.core import Symbol
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from sympy.utilities.iterables import iterable
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class MonomialOrder:
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"""Base class for monomial orderings. """
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alias: str | None = None
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is_global: bool | None = None
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is_default = False
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def __repr__(self):
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return self.__class__.__name__ + "()"
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def __str__(self):
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return self.alias
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def __call__(self, monomial):
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raise NotImplementedError
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def __eq__(self, other):
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return self.__class__ == other.__class__
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def __hash__(self):
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return hash(self.__class__)
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def __ne__(self, other):
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return not (self == other)
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class LexOrder(MonomialOrder):
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"""Lexicographic order of monomials. """
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alias = 'lex'
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is_global = True
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is_default = True
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def __call__(self, monomial):
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return monomial
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class GradedLexOrder(MonomialOrder):
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"""Graded lexicographic order of monomials. """
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alias = 'grlex'
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is_global = True
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def __call__(self, monomial):
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return (sum(monomial), monomial)
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class ReversedGradedLexOrder(MonomialOrder):
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"""Reversed graded lexicographic order of monomials. """
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alias = 'grevlex'
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is_global = True
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def __call__(self, monomial):
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return (sum(monomial), tuple(reversed([-m for m in monomial])))
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class ProductOrder(MonomialOrder):
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"""
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A product order built from other monomial orders.
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Given (not necessarily total) orders O1, O2, ..., On, their product order
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P is defined as M1 > M2 iff there exists i such that O1(M1) = O2(M2),
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..., Oi(M1) = Oi(M2), O{i+1}(M1) > O{i+1}(M2).
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Product orders are typically built from monomial orders on different sets
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of variables.
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ProductOrder is constructed by passing a list of pairs
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[(O1, L1), (O2, L2), ...] where Oi are MonomialOrders and Li are callables.
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Upon comparison, the Li are passed the total monomial, and should filter
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out the part of the monomial to pass to Oi.
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Examples
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========
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We can use a lexicographic order on x_1, x_2 and also on
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y_1, y_2, y_3, and their product on {x_i, y_i} as follows:
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>>> from sympy.polys.orderings import lex, grlex, ProductOrder
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>>> P = ProductOrder(
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... (lex, lambda m: m[:2]), # lex order on x_1 and x_2 of monomial
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... (grlex, lambda m: m[2:]) # grlex on y_1, y_2, y_3
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... )
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>>> P((2, 1, 1, 0, 0)) > P((1, 10, 0, 2, 0))
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True
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Here the exponent `2` of `x_1` in the first monomial
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(`x_1^2 x_2 y_1`) is bigger than the exponent `1` of `x_1` in the
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second monomial (`x_1 x_2^10 y_2^2`), so the first monomial is greater
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in the product ordering.
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>>> P((2, 1, 1, 0, 0)) < P((2, 1, 0, 2, 0))
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True
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Here the exponents of `x_1` and `x_2` agree, so the grlex order on
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`y_1, y_2, y_3` is used to decide the ordering. In this case the monomial
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`y_2^2` is ordered larger than `y_1`, since for the grlex order the degree
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of the monomial is most important.
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"""
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def __init__(self, *args):
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self.args = args
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def __call__(self, monomial):
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return tuple(O(lamda(monomial)) for (O, lamda) in self.args)
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def __repr__(self):
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contents = [repr(x[0]) for x in self.args]
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return self.__class__.__name__ + '(' + ", ".join(contents) + ')'
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def __str__(self):
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contents = [str(x[0]) for x in self.args]
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return self.__class__.__name__ + '(' + ", ".join(contents) + ')'
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def __eq__(self, other):
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if not isinstance(other, ProductOrder):
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return False
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return self.args == other.args
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def __hash__(self):
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return hash((self.__class__, self.args))
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@property
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def is_global(self):
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if all(o.is_global is True for o, _ in self.args):
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return True
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if all(o.is_global is False for o, _ in self.args):
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return False
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return None
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class InverseOrder(MonomialOrder):
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"""
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The "inverse" of another monomial order.
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If O is any monomial order, we can construct another monomial order iO
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such that `A >_{iO} B` if and only if `B >_O A`. This is useful for
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constructing local orders.
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Note that many algorithms only work with *global* orders.
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For example, in the inverse lexicographic order on a single variable `x`,
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high powers of `x` count as small:
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>>> from sympy.polys.orderings import lex, InverseOrder
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>>> ilex = InverseOrder(lex)
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>>> ilex((5,)) < ilex((0,))
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True
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"""
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def __init__(self, O):
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self.O = O
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def __str__(self):
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return "i" + str(self.O)
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def __call__(self, monomial):
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def inv(l):
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if iterable(l):
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return tuple(inv(x) for x in l)
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return -l
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return inv(self.O(monomial))
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@property
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def is_global(self):
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if self.O.is_global is True:
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return False
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if self.O.is_global is False:
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return True
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return None
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def __eq__(self, other):
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return isinstance(other, InverseOrder) and other.O == self.O
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def __hash__(self):
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return hash((self.__class__, self.O))
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lex = LexOrder()
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grlex = GradedLexOrder()
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grevlex = ReversedGradedLexOrder()
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ilex = InverseOrder(lex)
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igrlex = InverseOrder(grlex)
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igrevlex = InverseOrder(grevlex)
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_monomial_key = {
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'lex': lex,
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'grlex': grlex,
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'grevlex': grevlex,
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'ilex': ilex,
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'igrlex': igrlex,
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'igrevlex': igrevlex
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}
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def monomial_key(order=None, gens=None):
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"""
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Return a function defining admissible order on monomials.
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The result of a call to :func:`monomial_key` is a function which should
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be used as a key to :func:`sorted` built-in function, to provide order
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in a set of monomials of the same length.
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Currently supported monomial orderings are:
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1. lex - lexicographic order (default)
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2. grlex - graded lexicographic order
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3. grevlex - reversed graded lexicographic order
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4. ilex, igrlex, igrevlex - the corresponding inverse orders
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If the ``order`` input argument is not a string but has ``__call__``
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attribute, then it will pass through with an assumption that the
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callable object defines an admissible order on monomials.
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If the ``gens`` input argument contains a list of generators, the
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resulting key function can be used to sort SymPy ``Expr`` objects.
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"""
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if order is None:
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order = lex
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if isinstance(order, Symbol):
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order = str(order)
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if isinstance(order, str):
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try:
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order = _monomial_key[order]
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except KeyError:
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raise ValueError("supported monomial orderings are 'lex', 'grlex' and 'grevlex', got %r" % order)
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if hasattr(order, '__call__'):
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if gens is not None:
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def _order(expr):
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return order(expr.as_poly(*gens).degree_list())
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return _order
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return order
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else:
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raise ValueError("monomial ordering specification must be a string or a callable, got %s" % order)
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class _ItemGetter:
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"""Helper class to return a subsequence of values."""
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def __init__(self, seq):
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self.seq = tuple(seq)
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def __call__(self, m):
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return tuple(m[idx] for idx in self.seq)
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def __eq__(self, other):
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if not isinstance(other, _ItemGetter):
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return False
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return self.seq == other.seq
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def build_product_order(arg, gens):
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"""
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Build a monomial order on ``gens``.
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``arg`` should be a tuple of iterables. The first element of each iterable
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should be a string or monomial order (will be passed to monomial_key),
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the others should be subsets of the generators. This function will build
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the corresponding product order.
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For example, build a product of two grlex orders:
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>>> from sympy.polys.orderings import build_product_order
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>>> from sympy.abc import x, y, z, t
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>>> O = build_product_order((("grlex", x, y), ("grlex", z, t)), [x, y, z, t])
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>>> O((1, 2, 3, 4))
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((3, (1, 2)), (7, (3, 4)))
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"""
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gens2idx = {}
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for i, g in enumerate(gens):
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gens2idx[g] = i
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order = []
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for expr in arg:
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name = expr[0]
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var = expr[1:]
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def makelambda(var):
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return _ItemGetter(gens2idx[g] for g in var)
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order.append((monomial_key(name), makelambda(var)))
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return ProductOrder(*order)
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