3879 lines
138 KiB
Python
3879 lines
138 KiB
Python
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"""
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This module contains functions to:
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- solve a single equation for a single variable, in any domain either real or complex.
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- solve a single transcendental equation for a single variable in any domain either real or complex.
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(currently supports solving in real domain only)
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- solve a system of linear equations with N variables and M equations.
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- solve a system of Non Linear Equations with N variables and M equations
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"""
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from sympy.core.sympify import sympify
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from sympy.core import (S, Pow, Dummy, pi, Expr, Wild, Mul, Equality,
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Add, Basic)
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from sympy.core.containers import Tuple
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from sympy.core.function import (Lambda, expand_complex, AppliedUndef,
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expand_log, _mexpand, expand_trig, nfloat)
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from sympy.core.mod import Mod
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from sympy.core.numbers import igcd, I, Number, Rational, oo, ilcm
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from sympy.core.power import integer_log
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from sympy.core.relational import Eq, Ne, Relational
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from sympy.core.sorting import default_sort_key, ordered
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from sympy.core.symbol import Symbol, _uniquely_named_symbol
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from sympy.core.sympify import _sympify
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from sympy.polys.matrices.linsolve import _linear_eq_to_dict
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from sympy.polys.polyroots import UnsolvableFactorError
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from sympy.simplify.simplify import simplify, fraction, trigsimp, nsimplify
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from sympy.simplify import powdenest, logcombine
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from sympy.functions import (log, tan, cot, sin, cos, sec, csc, exp,
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acos, asin, acsc, asec,
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piecewise_fold, Piecewise)
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from sympy.functions.elementary.complexes import Abs, arg, re, im
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from sympy.functions.elementary.hyperbolic import HyperbolicFunction
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from sympy.functions.elementary.miscellaneous import real_root
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from sympy.functions.elementary.trigonometric import TrigonometricFunction
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from sympy.logic.boolalg import And, BooleanTrue
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from sympy.sets import (FiniteSet, imageset, Interval, Intersection,
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Union, ConditionSet, ImageSet, Complement, Contains)
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from sympy.sets.sets import Set, ProductSet
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from sympy.matrices import zeros, Matrix, MatrixBase
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from sympy.ntheory import totient
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from sympy.ntheory.factor_ import divisors
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from sympy.ntheory.residue_ntheory import discrete_log, nthroot_mod
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from sympy.polys import (roots, Poly, degree, together, PolynomialError,
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RootOf, factor, lcm, gcd)
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from sympy.polys.polyerrors import CoercionFailed
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from sympy.polys.polytools import invert, groebner, poly
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from sympy.polys.solvers import (sympy_eqs_to_ring, solve_lin_sys,
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PolyNonlinearError)
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from sympy.polys.matrices.linsolve import _linsolve
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from sympy.solvers.solvers import (checksol, denoms, unrad,
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_simple_dens, recast_to_symbols)
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from sympy.solvers.polysys import solve_poly_system
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from sympy.utilities import filldedent
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from sympy.utilities.iterables import (numbered_symbols, has_dups,
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is_sequence, iterable)
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from sympy.calculus.util import periodicity, continuous_domain, function_range
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from types import GeneratorType
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class NonlinearError(ValueError):
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"""Raised when unexpectedly encountering nonlinear equations"""
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pass
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_rc = Dummy("R", real=True), Dummy("C", complex=True)
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def _masked(f, *atoms):
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"""Return ``f``, with all objects given by ``atoms`` replaced with
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Dummy symbols, ``d``, and the list of replacements, ``(d, e)``,
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where ``e`` is an object of type given by ``atoms`` in which
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any other instances of atoms have been recursively replaced with
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Dummy symbols, too. The tuples are ordered so that if they are
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applied in sequence, the origin ``f`` will be restored.
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Examples
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========
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>>> from sympy import cos
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>>> from sympy.abc import x
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>>> from sympy.solvers.solveset import _masked
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>>> f = cos(cos(x) + 1)
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>>> f, reps = _masked(cos(1 + cos(x)), cos)
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>>> f
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_a1
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>>> reps
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[(_a1, cos(_a0 + 1)), (_a0, cos(x))]
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>>> for d, e in reps:
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... f = f.xreplace({d: e})
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>>> f
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cos(cos(x) + 1)
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"""
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sym = numbered_symbols('a', cls=Dummy, real=True)
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mask = []
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for a in ordered(f.atoms(*atoms)):
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for i in mask:
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a = a.replace(*i)
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mask.append((a, next(sym)))
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for i, (o, n) in enumerate(mask):
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f = f.replace(o, n)
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mask[i] = (n, o)
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mask = list(reversed(mask))
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return f, mask
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def _invert(f_x, y, x, domain=S.Complexes):
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r"""
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Reduce the complex valued equation $f(x) = y$ to a set of equations
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$$\left\{g(x) = h_1(y),\ g(x) = h_2(y),\ \dots,\ g(x) = h_n(y) \right\}$$
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where $g(x)$ is a simpler function than $f(x)$. The return value is a tuple
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$(g(x), \mathrm{set}_h)$, where $g(x)$ is a function of $x$ and $\mathrm{set}_h$ is
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the set of function $\left\{h_1(y), h_2(y), \dots, h_n(y)\right\}$.
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Here, $y$ is not necessarily a symbol.
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$\mathrm{set}_h$ contains the functions, along with the information
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about the domain in which they are valid, through set
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operations. For instance, if :math:`y = |x| - n` is inverted
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in the real domain, then $\mathrm{set}_h$ is not simply
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$\{-n, n\}$ as the nature of `n` is unknown; rather, it is:
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$$ \left(\left[0, \infty\right) \cap \left\{n\right\}\right) \cup
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\left(\left(-\infty, 0\right] \cap \left\{- n\right\}\right)$$
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By default, the complex domain is used which means that inverting even
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seemingly simple functions like $\exp(x)$ will give very different
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results from those obtained in the real domain.
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(In the case of $\exp(x)$, the inversion via $\log$ is multi-valued
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in the complex domain, having infinitely many branches.)
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If you are working with real values only (or you are not sure which
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function to use) you should probably set the domain to
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``S.Reals`` (or use ``invert_real`` which does that automatically).
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Examples
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========
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>>> from sympy.solvers.solveset import invert_complex, invert_real
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>>> from sympy.abc import x, y
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>>> from sympy import exp
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When does exp(x) == y?
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>>> invert_complex(exp(x), y, x)
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(x, ImageSet(Lambda(_n, I*(2*_n*pi + arg(y)) + log(Abs(y))), Integers))
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>>> invert_real(exp(x), y, x)
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(x, Intersection({log(y)}, Reals))
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When does exp(x) == 1?
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>>> invert_complex(exp(x), 1, x)
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(x, ImageSet(Lambda(_n, 2*_n*I*pi), Integers))
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>>> invert_real(exp(x), 1, x)
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(x, {0})
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See Also
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========
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invert_real, invert_complex
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"""
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x = sympify(x)
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if not x.is_Symbol:
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raise ValueError("x must be a symbol")
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f_x = sympify(f_x)
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if x not in f_x.free_symbols:
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raise ValueError("Inverse of constant function doesn't exist")
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y = sympify(y)
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if x in y.free_symbols:
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raise ValueError("y should be independent of x ")
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if domain.is_subset(S.Reals):
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x1, s = _invert_real(f_x, FiniteSet(y), x)
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else:
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x1, s = _invert_complex(f_x, FiniteSet(y), x)
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if not isinstance(s, FiniteSet) or x1 != x:
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return x1, s
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# Avoid adding gratuitous intersections with S.Complexes. Actual
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# conditions should be handled by the respective inverters.
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if domain is S.Complexes:
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return x1, s
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else:
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return x1, s.intersection(domain)
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invert_complex = _invert
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def invert_real(f_x, y, x):
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"""
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Inverts a real-valued function. Same as :func:`invert_complex`, but sets
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the domain to ``S.Reals`` before inverting.
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"""
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return _invert(f_x, y, x, S.Reals)
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def _invert_real(f, g_ys, symbol):
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"""Helper function for _invert."""
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if f == symbol or g_ys is S.EmptySet:
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return (f, g_ys)
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n = Dummy('n', real=True)
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if isinstance(f, exp) or (f.is_Pow and f.base == S.Exp1):
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return _invert_real(f.exp,
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imageset(Lambda(n, log(n)), g_ys),
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symbol)
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if hasattr(f, 'inverse') and f.inverse() is not None and not isinstance(f, (
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TrigonometricFunction,
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HyperbolicFunction,
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)):
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if len(f.args) > 1:
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raise ValueError("Only functions with one argument are supported.")
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return _invert_real(f.args[0],
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imageset(Lambda(n, f.inverse()(n)), g_ys),
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symbol)
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if isinstance(f, Abs):
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return _invert_abs(f.args[0], g_ys, symbol)
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if f.is_Add:
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# f = g + h
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g, h = f.as_independent(symbol)
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if g is not S.Zero:
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return _invert_real(h, imageset(Lambda(n, n - g), g_ys), symbol)
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if f.is_Mul:
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# f = g*h
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g, h = f.as_independent(symbol)
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if g is not S.One:
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return _invert_real(h, imageset(Lambda(n, n/g), g_ys), symbol)
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if f.is_Pow:
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base, expo = f.args
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base_has_sym = base.has(symbol)
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expo_has_sym = expo.has(symbol)
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if not expo_has_sym:
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if expo.is_rational:
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num, den = expo.as_numer_denom()
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if den % 2 == 0 and num % 2 == 1 and den.is_zero is False:
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# Here we have f(x)**(num/den) = y
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# where den is nonzero and even and y is an element
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# of the set g_ys.
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# den is even, so we are only interested in the cases
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# where both f(x) and y are positive.
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# Restricting y to be positive (using the set g_ys_pos)
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# means that y**(den/num) is always positive.
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# Therefore it isn't necessary to also constrain f(x)
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# to be positive because we are only going to
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# find solutions of f(x) = y**(d/n)
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# where the rhs is already required to be positive.
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root = Lambda(n, real_root(n, expo))
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g_ys_pos = g_ys & Interval(0, oo)
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res = imageset(root, g_ys_pos)
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_inv, _set = _invert_real(base, res, symbol)
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return (_inv, _set)
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if den % 2 == 1:
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root = Lambda(n, real_root(n, expo))
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res = imageset(root, g_ys)
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if num % 2 == 0:
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neg_res = imageset(Lambda(n, -n), res)
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return _invert_real(base, res + neg_res, symbol)
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if num % 2 == 1:
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return _invert_real(base, res, symbol)
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elif expo.is_irrational:
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root = Lambda(n, real_root(n, expo))
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g_ys_pos = g_ys & Interval(0, oo)
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res = imageset(root, g_ys_pos)
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return _invert_real(base, res, symbol)
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else:
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# indeterminate exponent, e.g. Float or parity of
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# num, den of rational could not be determined
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pass # use default return
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if not base_has_sym:
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rhs = g_ys.args[0]
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if base.is_positive:
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return _invert_real(expo,
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imageset(Lambda(n, log(n, base, evaluate=False)), g_ys), symbol)
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elif base.is_negative:
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s, b = integer_log(rhs, base)
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if b:
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return _invert_real(expo, FiniteSet(s), symbol)
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else:
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return (expo, S.EmptySet)
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elif base.is_zero:
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one = Eq(rhs, 1)
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if one == S.true:
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# special case: 0**x - 1
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return _invert_real(expo, FiniteSet(0), symbol)
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elif one == S.false:
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return (expo, S.EmptySet)
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if isinstance(f, TrigonometricFunction):
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if isinstance(g_ys, FiniteSet):
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def inv(trig):
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if isinstance(trig, (sin, csc)):
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F = asin if isinstance(trig, sin) else acsc
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return (lambda a: n*pi + S.NegativeOne**n*F(a),)
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if isinstance(trig, (cos, sec)):
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F = acos if isinstance(trig, cos) else asec
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return (
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lambda a: 2*n*pi + F(a),
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lambda a: 2*n*pi - F(a),)
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if isinstance(trig, (tan, cot)):
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return (lambda a: n*pi + trig.inverse()(a),)
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n = Dummy('n', integer=True)
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invs = S.EmptySet
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for L in inv(f):
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invs += Union(*[imageset(Lambda(n, L(g)), S.Integers) for g in g_ys])
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return _invert_real(f.args[0], invs, symbol)
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return (f, g_ys)
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def _invert_complex(f, g_ys, symbol):
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"""Helper function for _invert."""
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if f == symbol or g_ys is S.EmptySet:
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return (f, g_ys)
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n = Dummy('n')
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if f.is_Add:
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# f = g + h
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g, h = f.as_independent(symbol)
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if g is not S.Zero:
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return _invert_complex(h, imageset(Lambda(n, n - g), g_ys), symbol)
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if f.is_Mul:
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# f = g*h
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g, h = f.as_independent(symbol)
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if g is not S.One:
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if g in {S.NegativeInfinity, S.ComplexInfinity, S.Infinity}:
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return (h, S.EmptySet)
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return _invert_complex(h, imageset(Lambda(n, n/g), g_ys), symbol)
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if f.is_Pow:
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base, expo = f.args
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# special case: g**r = 0
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# Could be improved like `_invert_real` to handle more general cases.
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if expo.is_Rational and g_ys == FiniteSet(0):
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if expo.is_positive:
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return _invert_complex(base, g_ys, symbol)
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if hasattr(f, 'inverse') and f.inverse() is not None and \
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not isinstance(f, TrigonometricFunction) and \
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not isinstance(f, HyperbolicFunction) and \
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not isinstance(f, exp):
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if len(f.args) > 1:
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raise ValueError("Only functions with one argument are supported.")
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return _invert_complex(f.args[0],
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imageset(Lambda(n, f.inverse()(n)), g_ys), symbol)
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if isinstance(f, exp) or (f.is_Pow and f.base == S.Exp1):
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if isinstance(g_ys, ImageSet):
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# can solve upto `(d*exp(exp(...(exp(a*x + b))...) + c)` format.
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# Further can be improved to `(d*exp(exp(...(exp(a*x**n + b*x**(n-1) + ... + f))...) + c)`.
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g_ys_expr = g_ys.lamda.expr
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g_ys_vars = g_ys.lamda.variables
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k = Dummy('k{}'.format(len(g_ys_vars)))
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g_ys_vars_1 = (k,) + g_ys_vars
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exp_invs = Union(*[imageset(Lambda((g_ys_vars_1,), (I*(2*k*pi + arg(g_ys_expr))
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+ log(Abs(g_ys_expr)))), S.Integers**(len(g_ys_vars_1)))])
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return _invert_complex(f.exp, exp_invs, symbol)
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elif isinstance(g_ys, FiniteSet):
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exp_invs = Union(*[imageset(Lambda(n, I*(2*n*pi + arg(g_y)) +
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log(Abs(g_y))), S.Integers)
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||
|
for g_y in g_ys if g_y != 0])
|
||
|
return _invert_complex(f.exp, exp_invs, symbol)
|
||
|
|
||
|
return (f, g_ys)
|
||
|
|
||
|
|
||
|
def _invert_abs(f, g_ys, symbol):
|
||
|
"""Helper function for inverting absolute value functions.
|
||
|
|
||
|
Returns the complete result of inverting an absolute value
|
||
|
function along with the conditions which must also be satisfied.
|
||
|
|
||
|
If it is certain that all these conditions are met, a :class:`~.FiniteSet`
|
||
|
of all possible solutions is returned. If any condition cannot be
|
||
|
satisfied, an :class:`~.EmptySet` is returned. Otherwise, a
|
||
|
:class:`~.ConditionSet` of the solutions, with all the required conditions
|
||
|
specified, is returned.
|
||
|
|
||
|
"""
|
||
|
if not g_ys.is_FiniteSet:
|
||
|
# this could be used for FiniteSet, but the
|
||
|
# results are more compact if they aren't, e.g.
|
||
|
# ConditionSet(x, Contains(n, Interval(0, oo)), {-n, n}) vs
|
||
|
# Union(Intersection(Interval(0, oo), {n}), Intersection(Interval(-oo, 0), {-n}))
|
||
|
# for the solution of abs(x) - n
|
||
|
pos = Intersection(g_ys, Interval(0, S.Infinity))
|
||
|
parg = _invert_real(f, pos, symbol)
|
||
|
narg = _invert_real(-f, pos, symbol)
|
||
|
if parg[0] != narg[0]:
|
||
|
raise NotImplementedError
|
||
|
return parg[0], Union(narg[1], parg[1])
|
||
|
|
||
|
# check conditions: all these must be true. If any are unknown
|
||
|
# then return them as conditions which must be satisfied
|
||
|
unknown = []
|
||
|
for a in g_ys.args:
|
||
|
ok = a.is_nonnegative if a.is_Number else a.is_positive
|
||
|
if ok is None:
|
||
|
unknown.append(a)
|
||
|
elif not ok:
|
||
|
return symbol, S.EmptySet
|
||
|
if unknown:
|
||
|
conditions = And(*[Contains(i, Interval(0, oo))
|
||
|
for i in unknown])
|
||
|
else:
|
||
|
conditions = True
|
||
|
n = Dummy('n', real=True)
|
||
|
# this is slightly different than above: instead of solving
|
||
|
# +/-f on positive values, here we solve for f on +/- g_ys
|
||
|
g_x, values = _invert_real(f, Union(
|
||
|
imageset(Lambda(n, n), g_ys),
|
||
|
imageset(Lambda(n, -n), g_ys)), symbol)
|
||
|
return g_x, ConditionSet(g_x, conditions, values)
|
||
|
|
||
|
|
||
|
def domain_check(f, symbol, p):
|
||
|
"""Returns False if point p is infinite or any subexpression of f
|
||
|
is infinite or becomes so after replacing symbol with p. If none of
|
||
|
these conditions is met then True will be returned.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import Mul, oo
|
||
|
>>> from sympy.abc import x
|
||
|
>>> from sympy.solvers.solveset import domain_check
|
||
|
>>> g = 1/(1 + (1/(x + 1))**2)
|
||
|
>>> domain_check(g, x, -1)
|
||
|
False
|
||
|
>>> domain_check(x**2, x, 0)
|
||
|
True
|
||
|
>>> domain_check(1/x, x, oo)
|
||
|
False
|
||
|
|
||
|
* The function relies on the assumption that the original form
|
||
|
of the equation has not been changed by automatic simplification.
|
||
|
|
||
|
>>> domain_check(x/x, x, 0) # x/x is automatically simplified to 1
|
||
|
True
|
||
|
|
||
|
* To deal with automatic evaluations use evaluate=False:
|
||
|
|
||
|
>>> domain_check(Mul(x, 1/x, evaluate=False), x, 0)
|
||
|
False
|
||
|
"""
|
||
|
f, p = sympify(f), sympify(p)
|
||
|
if p.is_infinite:
|
||
|
return False
|
||
|
return _domain_check(f, symbol, p)
|
||
|
|
||
|
|
||
|
def _domain_check(f, symbol, p):
|
||
|
# helper for domain check
|
||
|
if f.is_Atom and f.is_finite:
|
||
|
return True
|
||
|
elif f.subs(symbol, p).is_infinite:
|
||
|
return False
|
||
|
elif isinstance(f, Piecewise):
|
||
|
# Check the cases of the Piecewise in turn. There might be invalid
|
||
|
# expressions in later cases that don't apply e.g.
|
||
|
# solveset(Piecewise((0, Eq(x, 0)), (1/x, True)), x)
|
||
|
for expr, cond in f.args:
|
||
|
condsubs = cond.subs(symbol, p)
|
||
|
if condsubs is S.false:
|
||
|
continue
|
||
|
elif condsubs is S.true:
|
||
|
return _domain_check(expr, symbol, p)
|
||
|
else:
|
||
|
# We don't know which case of the Piecewise holds. On this
|
||
|
# basis we cannot decide whether any solution is in or out of
|
||
|
# the domain. Ideally this function would allow returning a
|
||
|
# symbolic condition for the validity of the solution that
|
||
|
# could be handled in the calling code. In the mean time we'll
|
||
|
# give this particular solution the benefit of the doubt and
|
||
|
# let it pass.
|
||
|
return True
|
||
|
else:
|
||
|
# TODO : We should not blindly recurse through all args of arbitrary expressions like this
|
||
|
return all(_domain_check(g, symbol, p)
|
||
|
for g in f.args)
|
||
|
|
||
|
|
||
|
def _is_finite_with_finite_vars(f, domain=S.Complexes):
|
||
|
"""
|
||
|
Return True if the given expression is finite. For symbols that
|
||
|
do not assign a value for `complex` and/or `real`, the domain will
|
||
|
be used to assign a value; symbols that do not assign a value
|
||
|
for `finite` will be made finite. All other assumptions are
|
||
|
left unmodified.
|
||
|
"""
|
||
|
def assumptions(s):
|
||
|
A = s.assumptions0
|
||
|
A.setdefault('finite', A.get('finite', True))
|
||
|
if domain.is_subset(S.Reals):
|
||
|
# if this gets set it will make complex=True, too
|
||
|
A.setdefault('real', True)
|
||
|
else:
|
||
|
# don't change 'real' because being complex implies
|
||
|
# nothing about being real
|
||
|
A.setdefault('complex', True)
|
||
|
return A
|
||
|
|
||
|
reps = {s: Dummy(**assumptions(s)) for s in f.free_symbols}
|
||
|
return f.xreplace(reps).is_finite
|
||
|
|
||
|
|
||
|
def _is_function_class_equation(func_class, f, symbol):
|
||
|
""" Tests whether the equation is an equation of the given function class.
|
||
|
|
||
|
The given equation belongs to the given function class if it is
|
||
|
comprised of functions of the function class which are multiplied by
|
||
|
or added to expressions independent of the symbol. In addition, the
|
||
|
arguments of all such functions must be linear in the symbol as well.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import _is_function_class_equation
|
||
|
>>> from sympy import tan, sin, tanh, sinh, exp
|
||
|
>>> from sympy.abc import x
|
||
|
>>> from sympy.functions.elementary.trigonometric import TrigonometricFunction
|
||
|
>>> from sympy.functions.elementary.hyperbolic import HyperbolicFunction
|
||
|
>>> _is_function_class_equation(TrigonometricFunction, exp(x) + tan(x), x)
|
||
|
False
|
||
|
>>> _is_function_class_equation(TrigonometricFunction, tan(x) + sin(x), x)
|
||
|
True
|
||
|
>>> _is_function_class_equation(TrigonometricFunction, tan(x**2), x)
|
||
|
False
|
||
|
>>> _is_function_class_equation(TrigonometricFunction, tan(x + 2), x)
|
||
|
True
|
||
|
>>> _is_function_class_equation(HyperbolicFunction, tanh(x) + sinh(x), x)
|
||
|
True
|
||
|
"""
|
||
|
if f.is_Mul or f.is_Add:
|
||
|
return all(_is_function_class_equation(func_class, arg, symbol)
|
||
|
for arg in f.args)
|
||
|
|
||
|
if f.is_Pow:
|
||
|
if not f.exp.has(symbol):
|
||
|
return _is_function_class_equation(func_class, f.base, symbol)
|
||
|
else:
|
||
|
return False
|
||
|
|
||
|
if not f.has(symbol):
|
||
|
return True
|
||
|
|
||
|
if isinstance(f, func_class):
|
||
|
try:
|
||
|
g = Poly(f.args[0], symbol)
|
||
|
return g.degree() <= 1
|
||
|
except PolynomialError:
|
||
|
return False
|
||
|
else:
|
||
|
return False
|
||
|
|
||
|
|
||
|
def _solve_as_rational(f, symbol, domain):
|
||
|
""" solve rational functions"""
|
||
|
f = together(_mexpand(f, recursive=True), deep=True)
|
||
|
g, h = fraction(f)
|
||
|
if not h.has(symbol):
|
||
|
try:
|
||
|
return _solve_as_poly(g, symbol, domain)
|
||
|
except NotImplementedError:
|
||
|
# The polynomial formed from g could end up having
|
||
|
# coefficients in a ring over which finding roots
|
||
|
# isn't implemented yet, e.g. ZZ[a] for some symbol a
|
||
|
return ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
except CoercionFailed:
|
||
|
# contained oo, zoo or nan
|
||
|
return S.EmptySet
|
||
|
else:
|
||
|
valid_solns = _solveset(g, symbol, domain)
|
||
|
invalid_solns = _solveset(h, symbol, domain)
|
||
|
return valid_solns - invalid_solns
|
||
|
|
||
|
|
||
|
class _SolveTrig1Error(Exception):
|
||
|
"""Raised when _solve_trig1 heuristics do not apply"""
|
||
|
|
||
|
def _solve_trig(f, symbol, domain):
|
||
|
"""Function to call other helpers to solve trigonometric equations """
|
||
|
sol = None
|
||
|
try:
|
||
|
sol = _solve_trig1(f, symbol, domain)
|
||
|
except _SolveTrig1Error:
|
||
|
try:
|
||
|
sol = _solve_trig2(f, symbol, domain)
|
||
|
except ValueError:
|
||
|
raise NotImplementedError(filldedent('''
|
||
|
Solution to this kind of trigonometric equations
|
||
|
is yet to be implemented'''))
|
||
|
return sol
|
||
|
|
||
|
|
||
|
def _solve_trig1(f, symbol, domain):
|
||
|
"""Primary solver for trigonometric and hyperbolic equations
|
||
|
|
||
|
Returns either the solution set as a ConditionSet (auto-evaluated to a
|
||
|
union of ImageSets if no variables besides 'symbol' are involved) or
|
||
|
raises _SolveTrig1Error if f == 0 cannot be solved.
|
||
|
|
||
|
Notes
|
||
|
=====
|
||
|
Algorithm:
|
||
|
1. Do a change of variable x -> mu*x in arguments to trigonometric and
|
||
|
hyperbolic functions, in order to reduce them to small integers. (This
|
||
|
step is crucial to keep the degrees of the polynomials of step 4 low.)
|
||
|
2. Rewrite trigonometric/hyperbolic functions as exponentials.
|
||
|
3. Proceed to a 2nd change of variable, replacing exp(I*x) or exp(x) by y.
|
||
|
4. Solve the resulting rational equation.
|
||
|
5. Use invert_complex or invert_real to return to the original variable.
|
||
|
6. If the coefficients of 'symbol' were symbolic in nature, add the
|
||
|
necessary consistency conditions in a ConditionSet.
|
||
|
|
||
|
"""
|
||
|
# Prepare change of variable
|
||
|
x = Dummy('x')
|
||
|
if _is_function_class_equation(HyperbolicFunction, f, symbol):
|
||
|
cov = exp(x)
|
||
|
inverter = invert_real if domain.is_subset(S.Reals) else invert_complex
|
||
|
else:
|
||
|
cov = exp(I*x)
|
||
|
inverter = invert_complex
|
||
|
|
||
|
f = trigsimp(f)
|
||
|
f_original = f
|
||
|
trig_functions = f.atoms(TrigonometricFunction, HyperbolicFunction)
|
||
|
trig_arguments = [e.args[0] for e in trig_functions]
|
||
|
# trigsimp may have reduced the equation to an expression
|
||
|
# that is independent of 'symbol' (e.g. cos**2+sin**2)
|
||
|
if not any(a.has(symbol) for a in trig_arguments):
|
||
|
return solveset(f_original, symbol, domain)
|
||
|
|
||
|
denominators = []
|
||
|
numerators = []
|
||
|
for ar in trig_arguments:
|
||
|
try:
|
||
|
poly_ar = Poly(ar, symbol)
|
||
|
except PolynomialError:
|
||
|
raise _SolveTrig1Error("trig argument is not a polynomial")
|
||
|
if poly_ar.degree() > 1: # degree >1 still bad
|
||
|
raise _SolveTrig1Error("degree of variable must not exceed one")
|
||
|
if poly_ar.degree() == 0: # degree 0, don't care
|
||
|
continue
|
||
|
c = poly_ar.all_coeffs()[0] # got the coefficient of 'symbol'
|
||
|
numerators.append(fraction(c)[0])
|
||
|
denominators.append(fraction(c)[1])
|
||
|
|
||
|
mu = lcm(denominators)/gcd(numerators)
|
||
|
f = f.subs(symbol, mu*x)
|
||
|
f = f.rewrite(exp)
|
||
|
f = together(f)
|
||
|
g, h = fraction(f)
|
||
|
y = Dummy('y')
|
||
|
g, h = g.expand(), h.expand()
|
||
|
g, h = g.subs(cov, y), h.subs(cov, y)
|
||
|
if g.has(x) or h.has(x):
|
||
|
raise _SolveTrig1Error("change of variable not possible")
|
||
|
|
||
|
solns = solveset_complex(g, y) - solveset_complex(h, y)
|
||
|
if isinstance(solns, ConditionSet):
|
||
|
raise _SolveTrig1Error("polynomial has ConditionSet solution")
|
||
|
|
||
|
if isinstance(solns, FiniteSet):
|
||
|
if any(isinstance(s, RootOf) for s in solns):
|
||
|
raise _SolveTrig1Error("polynomial results in RootOf object")
|
||
|
# revert the change of variable
|
||
|
cov = cov.subs(x, symbol/mu)
|
||
|
result = Union(*[inverter(cov, s, symbol)[1] for s in solns])
|
||
|
# In case of symbolic coefficients, the solution set is only valid
|
||
|
# if numerator and denominator of mu are non-zero.
|
||
|
if mu.has(Symbol):
|
||
|
syms = (mu).atoms(Symbol)
|
||
|
munum, muden = fraction(mu)
|
||
|
condnum = munum.as_independent(*syms, as_Add=False)[1]
|
||
|
condden = muden.as_independent(*syms, as_Add=False)[1]
|
||
|
cond = And(Ne(condnum, 0), Ne(condden, 0))
|
||
|
else:
|
||
|
cond = True
|
||
|
# Actual conditions are returned as part of the ConditionSet. Adding an
|
||
|
# intersection with C would only complicate some solution sets due to
|
||
|
# current limitations of intersection code. (e.g. #19154)
|
||
|
if domain is S.Complexes:
|
||
|
# This is a slight abuse of ConditionSet. Ideally this should
|
||
|
# be some kind of "PiecewiseSet". (See #19507 discussion)
|
||
|
return ConditionSet(symbol, cond, result)
|
||
|
else:
|
||
|
return ConditionSet(symbol, cond, Intersection(result, domain))
|
||
|
elif solns is S.EmptySet:
|
||
|
return S.EmptySet
|
||
|
else:
|
||
|
raise _SolveTrig1Error("polynomial solutions must form FiniteSet")
|
||
|
|
||
|
|
||
|
def _solve_trig2(f, symbol, domain):
|
||
|
"""Secondary helper to solve trigonometric equations,
|
||
|
called when first helper fails """
|
||
|
f = trigsimp(f)
|
||
|
f_original = f
|
||
|
trig_functions = f.atoms(sin, cos, tan, sec, cot, csc)
|
||
|
trig_arguments = [e.args[0] for e in trig_functions]
|
||
|
denominators = []
|
||
|
numerators = []
|
||
|
|
||
|
# todo: This solver can be extended to hyperbolics if the
|
||
|
# analogous change of variable to tanh (instead of tan)
|
||
|
# is used.
|
||
|
if not trig_functions:
|
||
|
return ConditionSet(symbol, Eq(f_original, 0), domain)
|
||
|
|
||
|
# todo: The pre-processing below (extraction of numerators, denominators,
|
||
|
# gcd, lcm, mu, etc.) should be updated to the enhanced version in
|
||
|
# _solve_trig1. (See #19507)
|
||
|
for ar in trig_arguments:
|
||
|
try:
|
||
|
poly_ar = Poly(ar, symbol)
|
||
|
except PolynomialError:
|
||
|
raise ValueError("give up, we cannot solve if this is not a polynomial in x")
|
||
|
if poly_ar.degree() > 1: # degree >1 still bad
|
||
|
raise ValueError("degree of variable inside polynomial should not exceed one")
|
||
|
if poly_ar.degree() == 0: # degree 0, don't care
|
||
|
continue
|
||
|
c = poly_ar.all_coeffs()[0] # got the coefficient of 'symbol'
|
||
|
try:
|
||
|
numerators.append(Rational(c).p)
|
||
|
denominators.append(Rational(c).q)
|
||
|
except TypeError:
|
||
|
return ConditionSet(symbol, Eq(f_original, 0), domain)
|
||
|
|
||
|
x = Dummy('x')
|
||
|
|
||
|
# ilcm() and igcd() require more than one argument
|
||
|
if len(numerators) > 1:
|
||
|
mu = Rational(2)*ilcm(*denominators)/igcd(*numerators)
|
||
|
else:
|
||
|
assert len(numerators) == 1
|
||
|
mu = Rational(2)*denominators[0]/numerators[0]
|
||
|
|
||
|
f = f.subs(symbol, mu*x)
|
||
|
f = f.rewrite(tan)
|
||
|
f = expand_trig(f)
|
||
|
f = together(f)
|
||
|
|
||
|
g, h = fraction(f)
|
||
|
y = Dummy('y')
|
||
|
g, h = g.expand(), h.expand()
|
||
|
g, h = g.subs(tan(x), y), h.subs(tan(x), y)
|
||
|
|
||
|
if g.has(x) or h.has(x):
|
||
|
return ConditionSet(symbol, Eq(f_original, 0), domain)
|
||
|
solns = solveset(g, y, S.Reals) - solveset(h, y, S.Reals)
|
||
|
|
||
|
if isinstance(solns, FiniteSet):
|
||
|
result = Union(*[invert_real(tan(symbol/mu), s, symbol)[1]
|
||
|
for s in solns])
|
||
|
dsol = invert_real(tan(symbol/mu), oo, symbol)[1]
|
||
|
if degree(h) > degree(g): # If degree(denom)>degree(num) then there
|
||
|
result = Union(result, dsol) # would be another sol at Lim(denom-->oo)
|
||
|
return Intersection(result, domain)
|
||
|
elif solns is S.EmptySet:
|
||
|
return S.EmptySet
|
||
|
else:
|
||
|
return ConditionSet(symbol, Eq(f_original, 0), S.Reals)
|
||
|
|
||
|
|
||
|
def _solve_as_poly(f, symbol, domain=S.Complexes):
|
||
|
"""
|
||
|
Solve the equation using polynomial techniques if it already is a
|
||
|
polynomial equation or, with a change of variables, can be made so.
|
||
|
"""
|
||
|
result = None
|
||
|
if f.is_polynomial(symbol):
|
||
|
solns = roots(f, symbol, cubics=True, quartics=True,
|
||
|
quintics=True, domain='EX')
|
||
|
num_roots = sum(solns.values())
|
||
|
if degree(f, symbol) <= num_roots:
|
||
|
result = FiniteSet(*solns.keys())
|
||
|
else:
|
||
|
poly = Poly(f, symbol)
|
||
|
solns = poly.all_roots()
|
||
|
if poly.degree() <= len(solns):
|
||
|
result = FiniteSet(*solns)
|
||
|
else:
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
else:
|
||
|
poly = Poly(f)
|
||
|
if poly is None:
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
gens = [g for g in poly.gens if g.has(symbol)]
|
||
|
|
||
|
if len(gens) == 1:
|
||
|
poly = Poly(poly, gens[0])
|
||
|
gen = poly.gen
|
||
|
deg = poly.degree()
|
||
|
poly = Poly(poly.as_expr(), poly.gen, composite=True)
|
||
|
poly_solns = FiniteSet(*roots(poly, cubics=True, quartics=True,
|
||
|
quintics=True).keys())
|
||
|
|
||
|
if len(poly_solns) < deg:
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
if gen != symbol:
|
||
|
y = Dummy('y')
|
||
|
inverter = invert_real if domain.is_subset(S.Reals) else invert_complex
|
||
|
lhs, rhs_s = inverter(gen, y, symbol)
|
||
|
if lhs == symbol:
|
||
|
result = Union(*[rhs_s.subs(y, s) for s in poly_solns])
|
||
|
if isinstance(result, FiniteSet) and isinstance(gen, Pow
|
||
|
) and gen.base.is_Rational:
|
||
|
result = FiniteSet(*[expand_log(i) for i in result])
|
||
|
else:
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
else:
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
if result is not None:
|
||
|
if isinstance(result, FiniteSet):
|
||
|
# this is to simplify solutions like -sqrt(-I) to sqrt(2)/2
|
||
|
# - sqrt(2)*I/2. We are not expanding for solution with symbols
|
||
|
# or undefined functions because that makes the solution more complicated.
|
||
|
# For example, expand_complex(a) returns re(a) + I*im(a)
|
||
|
if all(s.atoms(Symbol, AppliedUndef) == set() and not isinstance(s, RootOf)
|
||
|
for s in result):
|
||
|
s = Dummy('s')
|
||
|
result = imageset(Lambda(s, expand_complex(s)), result)
|
||
|
if isinstance(result, FiniteSet) and domain != S.Complexes:
|
||
|
# Avoid adding gratuitous intersections with S.Complexes. Actual
|
||
|
# conditions should be handled elsewhere.
|
||
|
result = result.intersection(domain)
|
||
|
return result
|
||
|
else:
|
||
|
return ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
|
||
|
def _solve_radical(f, unradf, symbol, solveset_solver):
|
||
|
""" Helper function to solve equations with radicals """
|
||
|
res = unradf
|
||
|
eq, cov = res if res else (f, [])
|
||
|
if not cov:
|
||
|
result = solveset_solver(eq, symbol) - \
|
||
|
Union(*[solveset_solver(g, symbol) for g in denoms(f, symbol)])
|
||
|
else:
|
||
|
y, yeq = cov
|
||
|
if not solveset_solver(y - I, y):
|
||
|
yreal = Dummy('yreal', real=True)
|
||
|
yeq = yeq.xreplace({y: yreal})
|
||
|
eq = eq.xreplace({y: yreal})
|
||
|
y = yreal
|
||
|
g_y_s = solveset_solver(yeq, symbol)
|
||
|
f_y_sols = solveset_solver(eq, y)
|
||
|
result = Union(*[imageset(Lambda(y, g_y), f_y_sols)
|
||
|
for g_y in g_y_s])
|
||
|
|
||
|
def check_finiteset(solutions):
|
||
|
f_set = [] # solutions for FiniteSet
|
||
|
c_set = [] # solutions for ConditionSet
|
||
|
for s in solutions:
|
||
|
if checksol(f, symbol, s):
|
||
|
f_set.append(s)
|
||
|
else:
|
||
|
c_set.append(s)
|
||
|
return FiniteSet(*f_set) + ConditionSet(symbol, Eq(f, 0), FiniteSet(*c_set))
|
||
|
|
||
|
def check_set(solutions):
|
||
|
if solutions is S.EmptySet:
|
||
|
return solutions
|
||
|
elif isinstance(solutions, ConditionSet):
|
||
|
# XXX: Maybe the base set should be checked?
|
||
|
return solutions
|
||
|
elif isinstance(solutions, FiniteSet):
|
||
|
return check_finiteset(solutions)
|
||
|
elif isinstance(solutions, Complement):
|
||
|
A, B = solutions.args
|
||
|
return Complement(check_set(A), B)
|
||
|
elif isinstance(solutions, Union):
|
||
|
return Union(*[check_set(s) for s in solutions.args])
|
||
|
else:
|
||
|
# XXX: There should be more cases checked here. The cases above
|
||
|
# are all those that come up in the test suite for now.
|
||
|
return solutions
|
||
|
|
||
|
solution_set = check_set(result)
|
||
|
|
||
|
return solution_set
|
||
|
|
||
|
|
||
|
def _solve_abs(f, symbol, domain):
|
||
|
""" Helper function to solve equation involving absolute value function """
|
||
|
if not domain.is_subset(S.Reals):
|
||
|
raise ValueError(filldedent('''
|
||
|
Absolute values cannot be inverted in the
|
||
|
complex domain.'''))
|
||
|
p, q, r = Wild('p'), Wild('q'), Wild('r')
|
||
|
pattern_match = f.match(p*Abs(q) + r) or {}
|
||
|
f_p, f_q, f_r = [pattern_match.get(i, S.Zero) for i in (p, q, r)]
|
||
|
|
||
|
if not (f_p.is_zero or f_q.is_zero):
|
||
|
domain = continuous_domain(f_q, symbol, domain)
|
||
|
from .inequalities import solve_univariate_inequality
|
||
|
q_pos_cond = solve_univariate_inequality(f_q >= 0, symbol,
|
||
|
relational=False, domain=domain, continuous=True)
|
||
|
q_neg_cond = q_pos_cond.complement(domain)
|
||
|
|
||
|
sols_q_pos = solveset_real(f_p*f_q + f_r,
|
||
|
symbol).intersect(q_pos_cond)
|
||
|
sols_q_neg = solveset_real(f_p*(-f_q) + f_r,
|
||
|
symbol).intersect(q_neg_cond)
|
||
|
return Union(sols_q_pos, sols_q_neg)
|
||
|
else:
|
||
|
return ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
|
||
|
def solve_decomposition(f, symbol, domain):
|
||
|
"""
|
||
|
Function to solve equations via the principle of "Decomposition
|
||
|
and Rewriting".
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
>>> from sympy import exp, sin, Symbol, pprint, S
|
||
|
>>> from sympy.solvers.solveset import solve_decomposition as sd
|
||
|
>>> x = Symbol('x')
|
||
|
>>> f1 = exp(2*x) - 3*exp(x) + 2
|
||
|
>>> sd(f1, x, S.Reals)
|
||
|
{0, log(2)}
|
||
|
>>> f2 = sin(x)**2 + 2*sin(x) + 1
|
||
|
>>> pprint(sd(f2, x, S.Reals), use_unicode=False)
|
||
|
3*pi
|
||
|
{2*n*pi + ---- | n in Integers}
|
||
|
2
|
||
|
>>> f3 = sin(x + 2)
|
||
|
>>> pprint(sd(f3, x, S.Reals), use_unicode=False)
|
||
|
{2*n*pi - 2 | n in Integers} U {2*n*pi - 2 + pi | n in Integers}
|
||
|
|
||
|
"""
|
||
|
from sympy.solvers.decompogen import decompogen
|
||
|
# decompose the given function
|
||
|
g_s = decompogen(f, symbol)
|
||
|
# `y_s` represents the set of values for which the function `g` is to be
|
||
|
# solved.
|
||
|
# `solutions` represent the solutions of the equations `g = y_s` or
|
||
|
# `g = 0` depending on the type of `y_s`.
|
||
|
# As we are interested in solving the equation: f = 0
|
||
|
y_s = FiniteSet(0)
|
||
|
for g in g_s:
|
||
|
frange = function_range(g, symbol, domain)
|
||
|
y_s = Intersection(frange, y_s)
|
||
|
result = S.EmptySet
|
||
|
if isinstance(y_s, FiniteSet):
|
||
|
for y in y_s:
|
||
|
solutions = solveset(Eq(g, y), symbol, domain)
|
||
|
if not isinstance(solutions, ConditionSet):
|
||
|
result += solutions
|
||
|
|
||
|
else:
|
||
|
if isinstance(y_s, ImageSet):
|
||
|
iter_iset = (y_s,)
|
||
|
|
||
|
elif isinstance(y_s, Union):
|
||
|
iter_iset = y_s.args
|
||
|
|
||
|
elif y_s is S.EmptySet:
|
||
|
# y_s is not in the range of g in g_s, so no solution exists
|
||
|
#in the given domain
|
||
|
return S.EmptySet
|
||
|
|
||
|
for iset in iter_iset:
|
||
|
new_solutions = solveset(Eq(iset.lamda.expr, g), symbol, domain)
|
||
|
dummy_var = tuple(iset.lamda.expr.free_symbols)[0]
|
||
|
(base_set,) = iset.base_sets
|
||
|
if isinstance(new_solutions, FiniteSet):
|
||
|
new_exprs = new_solutions
|
||
|
|
||
|
elif isinstance(new_solutions, Intersection):
|
||
|
if isinstance(new_solutions.args[1], FiniteSet):
|
||
|
new_exprs = new_solutions.args[1]
|
||
|
|
||
|
for new_expr in new_exprs:
|
||
|
result += ImageSet(Lambda(dummy_var, new_expr), base_set)
|
||
|
|
||
|
if result is S.EmptySet:
|
||
|
return ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
y_s = result
|
||
|
|
||
|
return y_s
|
||
|
|
||
|
|
||
|
def _solveset(f, symbol, domain, _check=False):
|
||
|
"""Helper for solveset to return a result from an expression
|
||
|
that has already been sympify'ed and is known to contain the
|
||
|
given symbol."""
|
||
|
# _check controls whether the answer is checked or not
|
||
|
from sympy.simplify.simplify import signsimp
|
||
|
|
||
|
if isinstance(f, BooleanTrue):
|
||
|
return domain
|
||
|
|
||
|
orig_f = f
|
||
|
if f.is_Mul:
|
||
|
coeff, f = f.as_independent(symbol, as_Add=False)
|
||
|
if coeff in {S.ComplexInfinity, S.NegativeInfinity, S.Infinity}:
|
||
|
f = together(orig_f)
|
||
|
elif f.is_Add:
|
||
|
a, h = f.as_independent(symbol)
|
||
|
m, h = h.as_independent(symbol, as_Add=False)
|
||
|
if m not in {S.ComplexInfinity, S.Zero, S.Infinity,
|
||
|
S.NegativeInfinity}:
|
||
|
f = a/m + h # XXX condition `m != 0` should be added to soln
|
||
|
|
||
|
# assign the solvers to use
|
||
|
solver = lambda f, x, domain=domain: _solveset(f, x, domain)
|
||
|
inverter = lambda f, rhs, symbol: _invert(f, rhs, symbol, domain)
|
||
|
|
||
|
result = S.EmptySet
|
||
|
|
||
|
if f.expand().is_zero:
|
||
|
return domain
|
||
|
elif not f.has(symbol):
|
||
|
return S.EmptySet
|
||
|
elif f.is_Mul and all(_is_finite_with_finite_vars(m, domain)
|
||
|
for m in f.args):
|
||
|
# if f(x) and g(x) are both finite we can say that the solution of
|
||
|
# f(x)*g(x) == 0 is same as Union(f(x) == 0, g(x) == 0) is not true in
|
||
|
# general. g(x) can grow to infinitely large for the values where
|
||
|
# f(x) == 0. To be sure that we are not silently allowing any
|
||
|
# wrong solutions we are using this technique only if both f and g are
|
||
|
# finite for a finite input.
|
||
|
result = Union(*[solver(m, symbol) for m in f.args])
|
||
|
elif _is_function_class_equation(TrigonometricFunction, f, symbol) or \
|
||
|
_is_function_class_equation(HyperbolicFunction, f, symbol):
|
||
|
result = _solve_trig(f, symbol, domain)
|
||
|
elif isinstance(f, arg):
|
||
|
a = f.args[0]
|
||
|
result = Intersection(_solveset(re(a) > 0, symbol, domain),
|
||
|
_solveset(im(a), symbol, domain))
|
||
|
elif f.is_Piecewise:
|
||
|
expr_set_pairs = f.as_expr_set_pairs(domain)
|
||
|
for (expr, in_set) in expr_set_pairs:
|
||
|
if in_set.is_Relational:
|
||
|
in_set = in_set.as_set()
|
||
|
solns = solver(expr, symbol, in_set)
|
||
|
result += solns
|
||
|
elif isinstance(f, Eq):
|
||
|
result = solver(Add(f.lhs, - f.rhs, evaluate=False), symbol, domain)
|
||
|
|
||
|
elif f.is_Relational:
|
||
|
from .inequalities import solve_univariate_inequality
|
||
|
try:
|
||
|
result = solve_univariate_inequality(
|
||
|
f, symbol, domain=domain, relational=False)
|
||
|
except NotImplementedError:
|
||
|
result = ConditionSet(symbol, f, domain)
|
||
|
return result
|
||
|
elif _is_modular(f, symbol):
|
||
|
result = _solve_modular(f, symbol, domain)
|
||
|
else:
|
||
|
lhs, rhs_s = inverter(f, 0, symbol)
|
||
|
if lhs == symbol:
|
||
|
# do some very minimal simplification since
|
||
|
# repeated inversion may have left the result
|
||
|
# in a state that other solvers (e.g. poly)
|
||
|
# would have simplified; this is done here
|
||
|
# rather than in the inverter since here it
|
||
|
# is only done once whereas there it would
|
||
|
# be repeated for each step of the inversion
|
||
|
if isinstance(rhs_s, FiniteSet):
|
||
|
rhs_s = FiniteSet(*[Mul(*
|
||
|
signsimp(i).as_content_primitive())
|
||
|
for i in rhs_s])
|
||
|
result = rhs_s
|
||
|
|
||
|
elif isinstance(rhs_s, FiniteSet):
|
||
|
for equation in [lhs - rhs for rhs in rhs_s]:
|
||
|
if equation == f:
|
||
|
u = unrad(f, symbol)
|
||
|
if u:
|
||
|
result += _solve_radical(equation, u,
|
||
|
symbol,
|
||
|
solver)
|
||
|
elif equation.has(Abs):
|
||
|
result += _solve_abs(f, symbol, domain)
|
||
|
else:
|
||
|
result_rational = _solve_as_rational(equation, symbol, domain)
|
||
|
if not isinstance(result_rational, ConditionSet):
|
||
|
result += result_rational
|
||
|
else:
|
||
|
# may be a transcendental type equation
|
||
|
t_result = _transolve(equation, symbol, domain)
|
||
|
if isinstance(t_result, ConditionSet):
|
||
|
# might need factoring; this is expensive so we
|
||
|
# have delayed until now. To avoid recursion
|
||
|
# errors look for a non-trivial factoring into
|
||
|
# a product of symbol dependent terms; I think
|
||
|
# that something that factors as a Pow would
|
||
|
# have already been recognized by now.
|
||
|
factored = equation.factor()
|
||
|
if factored.is_Mul and equation != factored:
|
||
|
_, dep = factored.as_independent(symbol)
|
||
|
if not dep.is_Add:
|
||
|
# non-trivial factoring of equation
|
||
|
# but use form with constants
|
||
|
# in case they need special handling
|
||
|
t_results = []
|
||
|
for fac in Mul.make_args(factored):
|
||
|
if fac.has(symbol):
|
||
|
t_results.append(solver(fac, symbol))
|
||
|
t_result = Union(*t_results)
|
||
|
result += t_result
|
||
|
else:
|
||
|
result += solver(equation, symbol)
|
||
|
|
||
|
elif rhs_s is not S.EmptySet:
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
if isinstance(result, ConditionSet):
|
||
|
if isinstance(f, Expr):
|
||
|
num, den = f.as_numer_denom()
|
||
|
if den.has(symbol):
|
||
|
_result = _solveset(num, symbol, domain)
|
||
|
if not isinstance(_result, ConditionSet):
|
||
|
singularities = _solveset(den, symbol, domain)
|
||
|
result = _result - singularities
|
||
|
|
||
|
if _check:
|
||
|
if isinstance(result, ConditionSet):
|
||
|
# it wasn't solved or has enumerated all conditions
|
||
|
# -- leave it alone
|
||
|
return result
|
||
|
|
||
|
# whittle away all but the symbol-containing core
|
||
|
# to use this for testing
|
||
|
if isinstance(orig_f, Expr):
|
||
|
fx = orig_f.as_independent(symbol, as_Add=True)[1]
|
||
|
fx = fx.as_independent(symbol, as_Add=False)[1]
|
||
|
else:
|
||
|
fx = orig_f
|
||
|
|
||
|
if isinstance(result, FiniteSet):
|
||
|
# check the result for invalid solutions
|
||
|
result = FiniteSet(*[s for s in result
|
||
|
if isinstance(s, RootOf)
|
||
|
or domain_check(fx, symbol, s)])
|
||
|
|
||
|
return result
|
||
|
|
||
|
|
||
|
def _is_modular(f, symbol):
|
||
|
"""
|
||
|
Helper function to check below mentioned types of modular equations.
|
||
|
``A - Mod(B, C) = 0``
|
||
|
|
||
|
A -> This can or cannot be a function of symbol.
|
||
|
B -> This is surely a function of symbol.
|
||
|
C -> It is an integer.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Expr
|
||
|
The equation to be checked.
|
||
|
|
||
|
symbol : Symbol
|
||
|
The concerned variable for which the equation is to be checked.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, exp, Mod
|
||
|
>>> from sympy.solvers.solveset import _is_modular as check
|
||
|
>>> x, y = symbols('x y')
|
||
|
>>> check(Mod(x, 3) - 1, x)
|
||
|
True
|
||
|
>>> check(Mod(x, 3) - 1, y)
|
||
|
False
|
||
|
>>> check(Mod(x, 3)**2 - 5, x)
|
||
|
False
|
||
|
>>> check(Mod(x, 3)**2 - y, x)
|
||
|
False
|
||
|
>>> check(exp(Mod(x, 3)) - 1, x)
|
||
|
False
|
||
|
>>> check(Mod(3, y) - 1, y)
|
||
|
False
|
||
|
"""
|
||
|
|
||
|
if not f.has(Mod):
|
||
|
return False
|
||
|
|
||
|
# extract modterms from f.
|
||
|
modterms = list(f.atoms(Mod))
|
||
|
|
||
|
return (len(modterms) == 1 and # only one Mod should be present
|
||
|
modterms[0].args[0].has(symbol) and # B-> function of symbol
|
||
|
modterms[0].args[1].is_integer and # C-> to be an integer.
|
||
|
any(isinstance(term, Mod)
|
||
|
for term in list(_term_factors(f))) # free from other funcs
|
||
|
)
|
||
|
|
||
|
|
||
|
def _invert_modular(modterm, rhs, n, symbol):
|
||
|
"""
|
||
|
Helper function to invert modular equation.
|
||
|
``Mod(a, m) - rhs = 0``
|
||
|
|
||
|
Generally it is inverted as (a, ImageSet(Lambda(n, m*n + rhs), S.Integers)).
|
||
|
More simplified form will be returned if possible.
|
||
|
|
||
|
If it is not invertible then (modterm, rhs) is returned.
|
||
|
|
||
|
The following cases arise while inverting equation ``Mod(a, m) - rhs = 0``:
|
||
|
|
||
|
1. If a is symbol then m*n + rhs is the required solution.
|
||
|
|
||
|
2. If a is an instance of ``Add`` then we try to find two symbol independent
|
||
|
parts of a and the symbol independent part gets transferred to the other
|
||
|
side and again the ``_invert_modular`` is called on the symbol
|
||
|
dependent part.
|
||
|
|
||
|
3. If a is an instance of ``Mul`` then same as we done in ``Add`` we separate
|
||
|
out the symbol dependent and symbol independent parts and transfer the
|
||
|
symbol independent part to the rhs with the help of invert and again the
|
||
|
``_invert_modular`` is called on the symbol dependent part.
|
||
|
|
||
|
4. If a is an instance of ``Pow`` then two cases arise as following:
|
||
|
|
||
|
- If a is of type (symbol_indep)**(symbol_dep) then the remainder is
|
||
|
evaluated with the help of discrete_log function and then the least
|
||
|
period is being found out with the help of totient function.
|
||
|
period*n + remainder is the required solution in this case.
|
||
|
For reference: (https://en.wikipedia.org/wiki/Euler's_theorem)
|
||
|
|
||
|
- If a is of type (symbol_dep)**(symbol_indep) then we try to find all
|
||
|
primitive solutions list with the help of nthroot_mod function.
|
||
|
m*n + rem is the general solution where rem belongs to solutions list
|
||
|
from nthroot_mod function.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
modterm, rhs : Expr
|
||
|
The modular equation to be inverted, ``modterm - rhs = 0``
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in the equation to be inverted.
|
||
|
|
||
|
n : Dummy
|
||
|
Dummy variable for output g_n.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A tuple (f_x, g_n) is being returned where f_x is modular independent function
|
||
|
of symbol and g_n being set of values f_x can have.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, exp, Mod, Dummy, S
|
||
|
>>> from sympy.solvers.solveset import _invert_modular as invert_modular
|
||
|
>>> x, y = symbols('x y')
|
||
|
>>> n = Dummy('n')
|
||
|
>>> invert_modular(Mod(exp(x), 7), S(5), n, x)
|
||
|
(Mod(exp(x), 7), 5)
|
||
|
>>> invert_modular(Mod(x, 7), S(5), n, x)
|
||
|
(x, ImageSet(Lambda(_n, 7*_n + 5), Integers))
|
||
|
>>> invert_modular(Mod(3*x + 8, 7), S(5), n, x)
|
||
|
(x, ImageSet(Lambda(_n, 7*_n + 6), Integers))
|
||
|
>>> invert_modular(Mod(x**4, 7), S(5), n, x)
|
||
|
(x, EmptySet)
|
||
|
>>> invert_modular(Mod(2**(x**2 + x + 1), 7), S(2), n, x)
|
||
|
(x**2 + x + 1, ImageSet(Lambda(_n, 3*_n + 1), Naturals0))
|
||
|
|
||
|
"""
|
||
|
a, m = modterm.args
|
||
|
|
||
|
if rhs.is_real is False or any(term.is_real is False
|
||
|
for term in list(_term_factors(a))):
|
||
|
# Check for complex arguments
|
||
|
return modterm, rhs
|
||
|
|
||
|
if abs(rhs) >= abs(m):
|
||
|
# if rhs has value greater than value of m.
|
||
|
return symbol, S.EmptySet
|
||
|
|
||
|
if a == symbol:
|
||
|
return symbol, ImageSet(Lambda(n, m*n + rhs), S.Integers)
|
||
|
|
||
|
if a.is_Add:
|
||
|
# g + h = a
|
||
|
g, h = a.as_independent(symbol)
|
||
|
if g is not S.Zero:
|
||
|
x_indep_term = rhs - Mod(g, m)
|
||
|
return _invert_modular(Mod(h, m), Mod(x_indep_term, m), n, symbol)
|
||
|
|
||
|
if a.is_Mul:
|
||
|
# g*h = a
|
||
|
g, h = a.as_independent(symbol)
|
||
|
if g is not S.One:
|
||
|
x_indep_term = rhs*invert(g, m)
|
||
|
return _invert_modular(Mod(h, m), Mod(x_indep_term, m), n, symbol)
|
||
|
|
||
|
if a.is_Pow:
|
||
|
# base**expo = a
|
||
|
base, expo = a.args
|
||
|
if expo.has(symbol) and not base.has(symbol):
|
||
|
# remainder -> solution independent of n of equation.
|
||
|
# m, rhs are made coprime by dividing igcd(m, rhs)
|
||
|
try:
|
||
|
remainder = discrete_log(m / igcd(m, rhs), rhs, a.base)
|
||
|
except ValueError: # log does not exist
|
||
|
return modterm, rhs
|
||
|
# period -> coefficient of n in the solution and also referred as
|
||
|
# the least period of expo in which it is repeats itself.
|
||
|
# (a**(totient(m)) - 1) divides m. Here is link of theorem:
|
||
|
# (https://en.wikipedia.org/wiki/Euler's_theorem)
|
||
|
period = totient(m)
|
||
|
for p in divisors(period):
|
||
|
# there might a lesser period exist than totient(m).
|
||
|
if pow(a.base, p, m / igcd(m, a.base)) == 1:
|
||
|
period = p
|
||
|
break
|
||
|
# recursion is not applied here since _invert_modular is currently
|
||
|
# not smart enough to handle infinite rhs as here expo has infinite
|
||
|
# rhs = ImageSet(Lambda(n, period*n + remainder), S.Naturals0).
|
||
|
return expo, ImageSet(Lambda(n, period*n + remainder), S.Naturals0)
|
||
|
elif base.has(symbol) and not expo.has(symbol):
|
||
|
try:
|
||
|
remainder_list = nthroot_mod(rhs, expo, m, all_roots=True)
|
||
|
if remainder_list == []:
|
||
|
return symbol, S.EmptySet
|
||
|
except (ValueError, NotImplementedError):
|
||
|
return modterm, rhs
|
||
|
g_n = S.EmptySet
|
||
|
for rem in remainder_list:
|
||
|
g_n += ImageSet(Lambda(n, m*n + rem), S.Integers)
|
||
|
return base, g_n
|
||
|
|
||
|
return modterm, rhs
|
||
|
|
||
|
|
||
|
def _solve_modular(f, symbol, domain):
|
||
|
r"""
|
||
|
Helper function for solving modular equations of type ``A - Mod(B, C) = 0``,
|
||
|
where A can or cannot be a function of symbol, B is surely a function of
|
||
|
symbol and C is an integer.
|
||
|
|
||
|
Currently ``_solve_modular`` is only able to solve cases
|
||
|
where A is not a function of symbol.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Expr
|
||
|
The modular equation to be solved, ``f = 0``
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in the equation to be solved.
|
||
|
|
||
|
domain : Set
|
||
|
A set over which the equation is solved. It has to be a subset of
|
||
|
Integers.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A set of integer solutions satisfying the given modular equation.
|
||
|
A ``ConditionSet`` if the equation is unsolvable.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import _solve_modular as solve_modulo
|
||
|
>>> from sympy import S, Symbol, sin, Intersection, Interval, Mod
|
||
|
>>> x = Symbol('x')
|
||
|
>>> solve_modulo(Mod(5*x - 8, 7) - 3, x, S.Integers)
|
||
|
ImageSet(Lambda(_n, 7*_n + 5), Integers)
|
||
|
>>> solve_modulo(Mod(5*x - 8, 7) - 3, x, S.Reals) # domain should be subset of integers.
|
||
|
ConditionSet(x, Eq(Mod(5*x + 6, 7) - 3, 0), Reals)
|
||
|
>>> solve_modulo(-7 + Mod(x, 5), x, S.Integers)
|
||
|
EmptySet
|
||
|
>>> solve_modulo(Mod(12**x, 21) - 18, x, S.Integers)
|
||
|
ImageSet(Lambda(_n, 6*_n + 2), Naturals0)
|
||
|
>>> solve_modulo(Mod(sin(x), 7) - 3, x, S.Integers) # not solvable
|
||
|
ConditionSet(x, Eq(Mod(sin(x), 7) - 3, 0), Integers)
|
||
|
>>> solve_modulo(3 - Mod(x, 5), x, Intersection(S.Integers, Interval(0, 100)))
|
||
|
Intersection(ImageSet(Lambda(_n, 5*_n + 3), Integers), Range(0, 101, 1))
|
||
|
"""
|
||
|
# extract modterm and g_y from f
|
||
|
unsolved_result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
modterm = list(f.atoms(Mod))[0]
|
||
|
rhs = -S.One*(f.subs(modterm, S.Zero))
|
||
|
if f.as_coefficients_dict()[modterm].is_negative:
|
||
|
# checks if coefficient of modterm is negative in main equation.
|
||
|
rhs *= -S.One
|
||
|
|
||
|
if not domain.is_subset(S.Integers):
|
||
|
return unsolved_result
|
||
|
|
||
|
if rhs.has(symbol):
|
||
|
# TODO Case: A-> function of symbol, can be extended here
|
||
|
# in future.
|
||
|
return unsolved_result
|
||
|
|
||
|
n = Dummy('n', integer=True)
|
||
|
f_x, g_n = _invert_modular(modterm, rhs, n, symbol)
|
||
|
|
||
|
if f_x == modterm and g_n == rhs:
|
||
|
return unsolved_result
|
||
|
|
||
|
if f_x == symbol:
|
||
|
if domain is not S.Integers:
|
||
|
return domain.intersect(g_n)
|
||
|
return g_n
|
||
|
|
||
|
if isinstance(g_n, ImageSet):
|
||
|
lamda_expr = g_n.lamda.expr
|
||
|
lamda_vars = g_n.lamda.variables
|
||
|
base_sets = g_n.base_sets
|
||
|
sol_set = _solveset(f_x - lamda_expr, symbol, S.Integers)
|
||
|
if isinstance(sol_set, FiniteSet):
|
||
|
tmp_sol = S.EmptySet
|
||
|
for sol in sol_set:
|
||
|
tmp_sol += ImageSet(Lambda(lamda_vars, sol), *base_sets)
|
||
|
sol_set = tmp_sol
|
||
|
else:
|
||
|
sol_set = ImageSet(Lambda(lamda_vars, sol_set), *base_sets)
|
||
|
return domain.intersect(sol_set)
|
||
|
|
||
|
return unsolved_result
|
||
|
|
||
|
|
||
|
def _term_factors(f):
|
||
|
"""
|
||
|
Iterator to get the factors of all terms present
|
||
|
in the given equation.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
f : Expr
|
||
|
Equation that needs to be addressed
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
Factors of all terms present in the equation.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols
|
||
|
>>> from sympy.solvers.solveset import _term_factors
|
||
|
>>> x = symbols('x')
|
||
|
>>> list(_term_factors(-2 - x**2 + x*(x + 1)))
|
||
|
[-2, -1, x**2, x, x + 1]
|
||
|
"""
|
||
|
for add_arg in Add.make_args(f):
|
||
|
yield from Mul.make_args(add_arg)
|
||
|
|
||
|
|
||
|
def _solve_exponential(lhs, rhs, symbol, domain):
|
||
|
r"""
|
||
|
Helper function for solving (supported) exponential equations.
|
||
|
|
||
|
Exponential equations are the sum of (currently) at most
|
||
|
two terms with one or both of them having a power with a
|
||
|
symbol-dependent exponent.
|
||
|
|
||
|
For example
|
||
|
|
||
|
.. math:: 5^{2x + 3} - 5^{3x - 1}
|
||
|
|
||
|
.. math:: 4^{5 - 9x} - e^{2 - x}
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
lhs, rhs : Expr
|
||
|
The exponential equation to be solved, `lhs = rhs`
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in which the equation is solved
|
||
|
|
||
|
domain : Set
|
||
|
A set over which the equation is solved.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A set of solutions satisfying the given equation.
|
||
|
A ``ConditionSet`` if the equation is unsolvable or
|
||
|
if the assumptions are not properly defined, in that case
|
||
|
a different style of ``ConditionSet`` is returned having the
|
||
|
solution(s) of the equation with the desired assumptions.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import _solve_exponential as solve_expo
|
||
|
>>> from sympy import symbols, S
|
||
|
>>> x = symbols('x', real=True)
|
||
|
>>> a, b = symbols('a b')
|
||
|
>>> solve_expo(2**x + 3**x - 5**x, 0, x, S.Reals) # not solvable
|
||
|
ConditionSet(x, Eq(2**x + 3**x - 5**x, 0), Reals)
|
||
|
>>> solve_expo(a**x - b**x, 0, x, S.Reals) # solvable but incorrect assumptions
|
||
|
ConditionSet(x, (a > 0) & (b > 0), {0})
|
||
|
>>> solve_expo(3**(2*x) - 2**(x + 3), 0, x, S.Reals)
|
||
|
{-3*log(2)/(-2*log(3) + log(2))}
|
||
|
>>> solve_expo(2**x - 4**x, 0, x, S.Reals)
|
||
|
{0}
|
||
|
|
||
|
* Proof of correctness of the method
|
||
|
|
||
|
The logarithm function is the inverse of the exponential function.
|
||
|
The defining relation between exponentiation and logarithm is:
|
||
|
|
||
|
.. math:: {\log_b x} = y \enspace if \enspace b^y = x
|
||
|
|
||
|
Therefore if we are given an equation with exponent terms, we can
|
||
|
convert every term to its corresponding logarithmic form. This is
|
||
|
achieved by taking logarithms and expanding the equation using
|
||
|
logarithmic identities so that it can easily be handled by ``solveset``.
|
||
|
|
||
|
For example:
|
||
|
|
||
|
.. math:: 3^{2x} = 2^{x + 3}
|
||
|
|
||
|
Taking log both sides will reduce the equation to
|
||
|
|
||
|
.. math:: (2x)\log(3) = (x + 3)\log(2)
|
||
|
|
||
|
This form can be easily handed by ``solveset``.
|
||
|
"""
|
||
|
unsolved_result = ConditionSet(symbol, Eq(lhs - rhs, 0), domain)
|
||
|
newlhs = powdenest(lhs)
|
||
|
if lhs != newlhs:
|
||
|
# it may also be advantageous to factor the new expr
|
||
|
neweq = factor(newlhs - rhs)
|
||
|
if neweq != (lhs - rhs):
|
||
|
return _solveset(neweq, symbol, domain) # try again with _solveset
|
||
|
|
||
|
if not (isinstance(lhs, Add) and len(lhs.args) == 2):
|
||
|
# solving for the sum of more than two powers is possible
|
||
|
# but not yet implemented
|
||
|
return unsolved_result
|
||
|
|
||
|
if rhs != 0:
|
||
|
return unsolved_result
|
||
|
|
||
|
a, b = list(ordered(lhs.args))
|
||
|
a_term = a.as_independent(symbol)[1]
|
||
|
b_term = b.as_independent(symbol)[1]
|
||
|
|
||
|
a_base, a_exp = a_term.as_base_exp()
|
||
|
b_base, b_exp = b_term.as_base_exp()
|
||
|
|
||
|
if domain.is_subset(S.Reals):
|
||
|
conditions = And(
|
||
|
a_base > 0,
|
||
|
b_base > 0,
|
||
|
Eq(im(a_exp), 0),
|
||
|
Eq(im(b_exp), 0))
|
||
|
else:
|
||
|
conditions = And(
|
||
|
Ne(a_base, 0),
|
||
|
Ne(b_base, 0))
|
||
|
|
||
|
L, R = (expand_log(log(i), force=True) for i in (a, -b))
|
||
|
solutions = _solveset(L - R, symbol, domain)
|
||
|
|
||
|
return ConditionSet(symbol, conditions, solutions)
|
||
|
|
||
|
|
||
|
def _is_exponential(f, symbol):
|
||
|
r"""
|
||
|
Return ``True`` if one or more terms contain ``symbol`` only in
|
||
|
exponents, else ``False``.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Expr
|
||
|
The equation to be checked
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in which the equation is checked
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, cos, exp
|
||
|
>>> from sympy.solvers.solveset import _is_exponential as check
|
||
|
>>> x, y = symbols('x y')
|
||
|
>>> check(y, y)
|
||
|
False
|
||
|
>>> check(x**y - 1, y)
|
||
|
True
|
||
|
>>> check(x**y*2**y - 1, y)
|
||
|
True
|
||
|
>>> check(exp(x + 3) + 3**x, x)
|
||
|
True
|
||
|
>>> check(cos(2**x), x)
|
||
|
False
|
||
|
|
||
|
* Philosophy behind the helper
|
||
|
|
||
|
The function extracts each term of the equation and checks if it is
|
||
|
of exponential form w.r.t ``symbol``.
|
||
|
"""
|
||
|
rv = False
|
||
|
for expr_arg in _term_factors(f):
|
||
|
if symbol not in expr_arg.free_symbols:
|
||
|
continue
|
||
|
if (isinstance(expr_arg, Pow) and
|
||
|
symbol not in expr_arg.base.free_symbols or
|
||
|
isinstance(expr_arg, exp)):
|
||
|
rv = True # symbol in exponent
|
||
|
else:
|
||
|
return False # dependent on symbol in non-exponential way
|
||
|
return rv
|
||
|
|
||
|
|
||
|
def _solve_logarithm(lhs, rhs, symbol, domain):
|
||
|
r"""
|
||
|
Helper to solve logarithmic equations which are reducible
|
||
|
to a single instance of `\log`.
|
||
|
|
||
|
Logarithmic equations are (currently) the equations that contains
|
||
|
`\log` terms which can be reduced to a single `\log` term or
|
||
|
a constant using various logarithmic identities.
|
||
|
|
||
|
For example:
|
||
|
|
||
|
.. math:: \log(x) + \log(x - 4)
|
||
|
|
||
|
can be reduced to:
|
||
|
|
||
|
.. math:: \log(x(x - 4))
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
lhs, rhs : Expr
|
||
|
The logarithmic equation to be solved, `lhs = rhs`
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in which the equation is solved
|
||
|
|
||
|
domain : Set
|
||
|
A set over which the equation is solved.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A set of solutions satisfying the given equation.
|
||
|
A ``ConditionSet`` if the equation is unsolvable.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, log, S
|
||
|
>>> from sympy.solvers.solveset import _solve_logarithm as solve_log
|
||
|
>>> x = symbols('x')
|
||
|
>>> f = log(x - 3) + log(x + 3)
|
||
|
>>> solve_log(f, 0, x, S.Reals)
|
||
|
{-sqrt(10), sqrt(10)}
|
||
|
|
||
|
* Proof of correctness
|
||
|
|
||
|
A logarithm is another way to write exponent and is defined by
|
||
|
|
||
|
.. math:: {\log_b x} = y \enspace if \enspace b^y = x
|
||
|
|
||
|
When one side of the equation contains a single logarithm, the
|
||
|
equation can be solved by rewriting the equation as an equivalent
|
||
|
exponential equation as defined above. But if one side contains
|
||
|
more than one logarithm, we need to use the properties of logarithm
|
||
|
to condense it into a single logarithm.
|
||
|
|
||
|
Take for example
|
||
|
|
||
|
.. math:: \log(2x) - 15 = 0
|
||
|
|
||
|
contains single logarithm, therefore we can directly rewrite it to
|
||
|
exponential form as
|
||
|
|
||
|
.. math:: x = \frac{e^{15}}{2}
|
||
|
|
||
|
But if the equation has more than one logarithm as
|
||
|
|
||
|
.. math:: \log(x - 3) + \log(x + 3) = 0
|
||
|
|
||
|
we use logarithmic identities to convert it into a reduced form
|
||
|
|
||
|
Using,
|
||
|
|
||
|
.. math:: \log(a) + \log(b) = \log(ab)
|
||
|
|
||
|
the equation becomes,
|
||
|
|
||
|
.. math:: \log((x - 3)(x + 3))
|
||
|
|
||
|
This equation contains one logarithm and can be solved by rewriting
|
||
|
to exponents.
|
||
|
"""
|
||
|
new_lhs = logcombine(lhs, force=True)
|
||
|
new_f = new_lhs - rhs
|
||
|
|
||
|
return _solveset(new_f, symbol, domain)
|
||
|
|
||
|
|
||
|
def _is_logarithmic(f, symbol):
|
||
|
r"""
|
||
|
Return ``True`` if the equation is in the form
|
||
|
`a\log(f(x)) + b\log(g(x)) + ... + c` else ``False``.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Expr
|
||
|
The equation to be checked
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in which the equation is checked
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
``True`` if the equation is logarithmic otherwise ``False``.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, tan, log
|
||
|
>>> from sympy.solvers.solveset import _is_logarithmic as check
|
||
|
>>> x, y = symbols('x y')
|
||
|
>>> check(log(x + 2) - log(x + 3), x)
|
||
|
True
|
||
|
>>> check(tan(log(2*x)), x)
|
||
|
False
|
||
|
>>> check(x*log(x), x)
|
||
|
False
|
||
|
>>> check(x + log(x), x)
|
||
|
False
|
||
|
>>> check(y + log(x), x)
|
||
|
True
|
||
|
|
||
|
* Philosophy behind the helper
|
||
|
|
||
|
The function extracts each term and checks whether it is
|
||
|
logarithmic w.r.t ``symbol``.
|
||
|
"""
|
||
|
rv = False
|
||
|
for term in Add.make_args(f):
|
||
|
saw_log = False
|
||
|
for term_arg in Mul.make_args(term):
|
||
|
if symbol not in term_arg.free_symbols:
|
||
|
continue
|
||
|
if isinstance(term_arg, log):
|
||
|
if saw_log:
|
||
|
return False # more than one log in term
|
||
|
saw_log = True
|
||
|
else:
|
||
|
return False # dependent on symbol in non-log way
|
||
|
if saw_log:
|
||
|
rv = True
|
||
|
return rv
|
||
|
|
||
|
|
||
|
def _is_lambert(f, symbol):
|
||
|
r"""
|
||
|
If this returns ``False`` then the Lambert solver (``_solve_lambert``) will not be called.
|
||
|
|
||
|
Explanation
|
||
|
===========
|
||
|
|
||
|
Quick check for cases that the Lambert solver might be able to handle.
|
||
|
|
||
|
1. Equations containing more than two operands and `symbol`s involving any of
|
||
|
`Pow`, `exp`, `HyperbolicFunction`,`TrigonometricFunction`, `log` terms.
|
||
|
|
||
|
2. In `Pow`, `exp` the exponent should have `symbol` whereas for
|
||
|
`HyperbolicFunction`,`TrigonometricFunction`, `log` should contain `symbol`.
|
||
|
|
||
|
3. For `HyperbolicFunction`,`TrigonometricFunction` the number of trigonometric functions in
|
||
|
equation should be less than number of symbols. (since `A*cos(x) + B*sin(x) - c`
|
||
|
is not the Lambert type).
|
||
|
|
||
|
Some forms of lambert equations are:
|
||
|
1. X**X = C
|
||
|
2. X*(B*log(X) + D)**A = C
|
||
|
3. A*log(B*X + A) + d*X = C
|
||
|
4. (B*X + A)*exp(d*X + g) = C
|
||
|
5. g*exp(B*X + h) - B*X = C
|
||
|
6. A*D**(E*X + g) - B*X = C
|
||
|
7. A*cos(X) + B*sin(X) - D*X = C
|
||
|
8. A*cosh(X) + B*sinh(X) - D*X = C
|
||
|
|
||
|
Where X is any variable,
|
||
|
A, B, C, D, E are any constants,
|
||
|
g, h are linear functions or log terms.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Expr
|
||
|
The equation to be checked
|
||
|
|
||
|
symbol : Symbol
|
||
|
The variable in which the equation is checked
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
If this returns ``False`` then the Lambert solver (``_solve_lambert``) will not be called.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import _is_lambert
|
||
|
>>> from sympy import symbols, cosh, sinh, log
|
||
|
>>> x = symbols('x')
|
||
|
|
||
|
>>> _is_lambert(3*log(x) - x*log(3), x)
|
||
|
True
|
||
|
>>> _is_lambert(log(log(x - 3)) + log(x-3), x)
|
||
|
True
|
||
|
>>> _is_lambert(cosh(x) - sinh(x), x)
|
||
|
False
|
||
|
>>> _is_lambert((x**2 - 2*x + 1).subs(x, (log(x) + 3*x)**2 - 1), x)
|
||
|
True
|
||
|
|
||
|
See Also
|
||
|
========
|
||
|
|
||
|
_solve_lambert
|
||
|
|
||
|
"""
|
||
|
term_factors = list(_term_factors(f.expand()))
|
||
|
|
||
|
# total number of symbols in equation
|
||
|
no_of_symbols = len([arg for arg in term_factors if arg.has(symbol)])
|
||
|
# total number of trigonometric terms in equation
|
||
|
no_of_trig = len([arg for arg in term_factors \
|
||
|
if arg.has(HyperbolicFunction, TrigonometricFunction)])
|
||
|
|
||
|
if f.is_Add and no_of_symbols >= 2:
|
||
|
# `log`, `HyperbolicFunction`, `TrigonometricFunction` should have symbols
|
||
|
# and no_of_trig < no_of_symbols
|
||
|
lambert_funcs = (log, HyperbolicFunction, TrigonometricFunction)
|
||
|
if any(isinstance(arg, lambert_funcs)\
|
||
|
for arg in term_factors if arg.has(symbol)):
|
||
|
if no_of_trig < no_of_symbols:
|
||
|
return True
|
||
|
# here, `Pow`, `exp` exponent should have symbols
|
||
|
elif any(isinstance(arg, (Pow, exp)) \
|
||
|
for arg in term_factors if (arg.as_base_exp()[1]).has(symbol)):
|
||
|
return True
|
||
|
return False
|
||
|
|
||
|
|
||
|
def _transolve(f, symbol, domain):
|
||
|
r"""
|
||
|
Function to solve transcendental equations. It is a helper to
|
||
|
``solveset`` and should be used internally. ``_transolve``
|
||
|
currently supports the following class of equations:
|
||
|
|
||
|
- Exponential equations
|
||
|
- Logarithmic equations
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Any transcendental equation that needs to be solved.
|
||
|
This needs to be an expression, which is assumed
|
||
|
to be equal to ``0``.
|
||
|
|
||
|
symbol : The variable for which the equation is solved.
|
||
|
This needs to be of class ``Symbol``.
|
||
|
|
||
|
domain : A set over which the equation is solved.
|
||
|
This needs to be of class ``Set``.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
Set
|
||
|
A set of values for ``symbol`` for which ``f`` is equal to
|
||
|
zero. An ``EmptySet`` is returned if ``f`` does not have solutions
|
||
|
in respective domain. A ``ConditionSet`` is returned as unsolved
|
||
|
object if algorithms to evaluate complete solution are not
|
||
|
yet implemented.
|
||
|
|
||
|
How to use ``_transolve``
|
||
|
=========================
|
||
|
|
||
|
``_transolve`` should not be used as an independent function, because
|
||
|
it assumes that the equation (``f``) and the ``symbol`` comes from
|
||
|
``solveset`` and might have undergone a few modification(s).
|
||
|
To use ``_transolve`` as an independent function the equation (``f``)
|
||
|
and the ``symbol`` should be passed as they would have been by
|
||
|
``solveset``.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import _transolve as transolve
|
||
|
>>> from sympy.solvers.solvers import _tsolve as tsolve
|
||
|
>>> from sympy import symbols, S, pprint
|
||
|
>>> x = symbols('x', real=True) # assumption added
|
||
|
>>> transolve(5**(x - 3) - 3**(2*x + 1), x, S.Reals)
|
||
|
{-(log(3) + 3*log(5))/(-log(5) + 2*log(3))}
|
||
|
|
||
|
How ``_transolve`` works
|
||
|
========================
|
||
|
|
||
|
``_transolve`` uses two types of helper functions to solve equations
|
||
|
of a particular class:
|
||
|
|
||
|
Identifying helpers: To determine whether a given equation
|
||
|
belongs to a certain class of equation or not. Returns either
|
||
|
``True`` or ``False``.
|
||
|
|
||
|
Solving helpers: Once an equation is identified, a corresponding
|
||
|
helper either solves the equation or returns a form of the equation
|
||
|
that ``solveset`` might better be able to handle.
|
||
|
|
||
|
* Philosophy behind the module
|
||
|
|
||
|
The purpose of ``_transolve`` is to take equations which are not
|
||
|
already polynomial in their generator(s) and to either recast them
|
||
|
as such through a valid transformation or to solve them outright.
|
||
|
A pair of helper functions for each class of supported
|
||
|
transcendental functions are employed for this purpose. One
|
||
|
identifies the transcendental form of an equation and the other
|
||
|
either solves it or recasts it into a tractable form that can be
|
||
|
solved by ``solveset``.
|
||
|
For example, an equation in the form `ab^{f(x)} - cd^{g(x)} = 0`
|
||
|
can be transformed to
|
||
|
`\log(a) + f(x)\log(b) - \log(c) - g(x)\log(d) = 0`
|
||
|
(under certain assumptions) and this can be solved with ``solveset``
|
||
|
if `f(x)` and `g(x)` are in polynomial form.
|
||
|
|
||
|
How ``_transolve`` is better than ``_tsolve``
|
||
|
=============================================
|
||
|
|
||
|
1) Better output
|
||
|
|
||
|
``_transolve`` provides expressions in a more simplified form.
|
||
|
|
||
|
Consider a simple exponential equation
|
||
|
|
||
|
>>> f = 3**(2*x) - 2**(x + 3)
|
||
|
>>> pprint(transolve(f, x, S.Reals), use_unicode=False)
|
||
|
-3*log(2)
|
||
|
{------------------}
|
||
|
-2*log(3) + log(2)
|
||
|
>>> pprint(tsolve(f, x), use_unicode=False)
|
||
|
/ 3 \
|
||
|
| --------|
|
||
|
| log(2/9)|
|
||
|
[-log\2 /]
|
||
|
|
||
|
2) Extensible
|
||
|
|
||
|
The API of ``_transolve`` is designed such that it is easily
|
||
|
extensible, i.e. the code that solves a given class of
|
||
|
equations is encapsulated in a helper and not mixed in with
|
||
|
the code of ``_transolve`` itself.
|
||
|
|
||
|
3) Modular
|
||
|
|
||
|
``_transolve`` is designed to be modular i.e, for every class of
|
||
|
equation a separate helper for identification and solving is
|
||
|
implemented. This makes it easy to change or modify any of the
|
||
|
method implemented directly in the helpers without interfering
|
||
|
with the actual structure of the API.
|
||
|
|
||
|
4) Faster Computation
|
||
|
|
||
|
Solving equation via ``_transolve`` is much faster as compared to
|
||
|
``_tsolve``. In ``solve``, attempts are made computing every possibility
|
||
|
to get the solutions. This series of attempts makes solving a bit
|
||
|
slow. In ``_transolve``, computation begins only after a particular
|
||
|
type of equation is identified.
|
||
|
|
||
|
How to add new class of equations
|
||
|
=================================
|
||
|
|
||
|
Adding a new class of equation solver is a three-step procedure:
|
||
|
|
||
|
- Identify the type of the equations
|
||
|
|
||
|
Determine the type of the class of equations to which they belong:
|
||
|
it could be of ``Add``, ``Pow``, etc. types. Separate internal functions
|
||
|
are used for each type. Write identification and solving helpers
|
||
|
and use them from within the routine for the given type of equation
|
||
|
(after adding it, if necessary). Something like:
|
||
|
|
||
|
.. code-block:: python
|
||
|
|
||
|
def add_type(lhs, rhs, x):
|
||
|
....
|
||
|
if _is_exponential(lhs, x):
|
||
|
new_eq = _solve_exponential(lhs, rhs, x)
|
||
|
....
|
||
|
rhs, lhs = eq.as_independent(x)
|
||
|
if lhs.is_Add:
|
||
|
result = add_type(lhs, rhs, x)
|
||
|
|
||
|
- Define the identification helper.
|
||
|
|
||
|
- Define the solving helper.
|
||
|
|
||
|
Apart from this, a few other things needs to be taken care while
|
||
|
adding an equation solver:
|
||
|
|
||
|
- Naming conventions:
|
||
|
Name of the identification helper should be as
|
||
|
``_is_class`` where class will be the name or abbreviation
|
||
|
of the class of equation. The solving helper will be named as
|
||
|
``_solve_class``.
|
||
|
For example: for exponential equations it becomes
|
||
|
``_is_exponential`` and ``_solve_expo``.
|
||
|
- The identifying helpers should take two input parameters,
|
||
|
the equation to be checked and the variable for which a solution
|
||
|
is being sought, while solving helpers would require an additional
|
||
|
domain parameter.
|
||
|
- Be sure to consider corner cases.
|
||
|
- Add tests for each helper.
|
||
|
- Add a docstring to your helper that describes the method
|
||
|
implemented.
|
||
|
The documentation of the helpers should identify:
|
||
|
|
||
|
- the purpose of the helper,
|
||
|
- the method used to identify and solve the equation,
|
||
|
- a proof of correctness
|
||
|
- the return values of the helpers
|
||
|
"""
|
||
|
|
||
|
def add_type(lhs, rhs, symbol, domain):
|
||
|
"""
|
||
|
Helper for ``_transolve`` to handle equations of
|
||
|
``Add`` type, i.e. equations taking the form as
|
||
|
``a*f(x) + b*g(x) + .... = c``.
|
||
|
For example: 4**x + 8**x = 0
|
||
|
"""
|
||
|
result = ConditionSet(symbol, Eq(lhs - rhs, 0), domain)
|
||
|
|
||
|
# check if it is exponential type equation
|
||
|
if _is_exponential(lhs, symbol):
|
||
|
result = _solve_exponential(lhs, rhs, symbol, domain)
|
||
|
# check if it is logarithmic type equation
|
||
|
elif _is_logarithmic(lhs, symbol):
|
||
|
result = _solve_logarithm(lhs, rhs, symbol, domain)
|
||
|
|
||
|
return result
|
||
|
|
||
|
result = ConditionSet(symbol, Eq(f, 0), domain)
|
||
|
|
||
|
# invert_complex handles the call to the desired inverter based
|
||
|
# on the domain specified.
|
||
|
lhs, rhs_s = invert_complex(f, 0, symbol, domain)
|
||
|
|
||
|
if isinstance(rhs_s, FiniteSet):
|
||
|
assert (len(rhs_s.args)) == 1
|
||
|
rhs = rhs_s.args[0]
|
||
|
|
||
|
if lhs.is_Add:
|
||
|
result = add_type(lhs, rhs, symbol, domain)
|
||
|
else:
|
||
|
result = rhs_s
|
||
|
|
||
|
return result
|
||
|
|
||
|
|
||
|
def solveset(f, symbol=None, domain=S.Complexes):
|
||
|
r"""Solves a given inequality or equation with set as output
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
f : Expr or a relational.
|
||
|
The target equation or inequality
|
||
|
symbol : Symbol
|
||
|
The variable for which the equation is solved
|
||
|
domain : Set
|
||
|
The domain over which the equation is solved
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
Set
|
||
|
A set of values for `symbol` for which `f` is True or is equal to
|
||
|
zero. An :class:`~.EmptySet` is returned if `f` is False or nonzero.
|
||
|
A :class:`~.ConditionSet` is returned as unsolved object if algorithms
|
||
|
to evaluate complete solution are not yet implemented.
|
||
|
|
||
|
``solveset`` claims to be complete in the solution set that it returns.
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
NotImplementedError
|
||
|
The algorithms to solve inequalities in complex domain are
|
||
|
not yet implemented.
|
||
|
ValueError
|
||
|
The input is not valid.
|
||
|
RuntimeError
|
||
|
It is a bug, please report to the github issue tracker.
|
||
|
|
||
|
|
||
|
Notes
|
||
|
=====
|
||
|
|
||
|
Python interprets 0 and 1 as False and True, respectively, but
|
||
|
in this function they refer to solutions of an expression. So 0 and 1
|
||
|
return the domain and EmptySet, respectively, while True and False
|
||
|
return the opposite (as they are assumed to be solutions of relational
|
||
|
expressions).
|
||
|
|
||
|
|
||
|
See Also
|
||
|
========
|
||
|
|
||
|
solveset_real: solver for real domain
|
||
|
solveset_complex: solver for complex domain
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import exp, sin, Symbol, pprint, S, Eq
|
||
|
>>> from sympy.solvers.solveset import solveset, solveset_real
|
||
|
|
||
|
* The default domain is complex. Not specifying a domain will lead
|
||
|
to the solving of the equation in the complex domain (and this
|
||
|
is not affected by the assumptions on the symbol):
|
||
|
|
||
|
>>> x = Symbol('x')
|
||
|
>>> pprint(solveset(exp(x) - 1, x), use_unicode=False)
|
||
|
{2*n*I*pi | n in Integers}
|
||
|
|
||
|
>>> x = Symbol('x', real=True)
|
||
|
>>> pprint(solveset(exp(x) - 1, x), use_unicode=False)
|
||
|
{2*n*I*pi | n in Integers}
|
||
|
|
||
|
* If you want to use ``solveset`` to solve the equation in the
|
||
|
real domain, provide a real domain. (Using ``solveset_real``
|
||
|
does this automatically.)
|
||
|
|
||
|
>>> R = S.Reals
|
||
|
>>> x = Symbol('x')
|
||
|
>>> solveset(exp(x) - 1, x, R)
|
||
|
{0}
|
||
|
>>> solveset_real(exp(x) - 1, x)
|
||
|
{0}
|
||
|
|
||
|
The solution is unaffected by assumptions on the symbol:
|
||
|
|
||
|
>>> p = Symbol('p', positive=True)
|
||
|
>>> pprint(solveset(p**2 - 4))
|
||
|
{-2, 2}
|
||
|
|
||
|
When a :class:`~.ConditionSet` is returned, symbols with assumptions that
|
||
|
would alter the set are replaced with more generic symbols:
|
||
|
|
||
|
>>> i = Symbol('i', imaginary=True)
|
||
|
>>> solveset(Eq(i**2 + i*sin(i), 1), i, domain=S.Reals)
|
||
|
ConditionSet(_R, Eq(_R**2 + _R*sin(_R) - 1, 0), Reals)
|
||
|
|
||
|
* Inequalities can be solved over the real domain only. Use of a complex
|
||
|
domain leads to a NotImplementedError.
|
||
|
|
||
|
>>> solveset(exp(x) > 1, x, R)
|
||
|
Interval.open(0, oo)
|
||
|
|
||
|
"""
|
||
|
f = sympify(f)
|
||
|
symbol = sympify(symbol)
|
||
|
|
||
|
if f is S.true:
|
||
|
return domain
|
||
|
|
||
|
if f is S.false:
|
||
|
return S.EmptySet
|
||
|
|
||
|
if not isinstance(f, (Expr, Relational, Number)):
|
||
|
raise ValueError("%s is not a valid SymPy expression" % f)
|
||
|
|
||
|
if not isinstance(symbol, (Expr, Relational)) and symbol is not None:
|
||
|
raise ValueError("%s is not a valid SymPy symbol" % (symbol,))
|
||
|
|
||
|
if not isinstance(domain, Set):
|
||
|
raise ValueError("%s is not a valid domain" %(domain))
|
||
|
|
||
|
free_symbols = f.free_symbols
|
||
|
|
||
|
if f.has(Piecewise):
|
||
|
f = piecewise_fold(f)
|
||
|
|
||
|
if symbol is None and not free_symbols:
|
||
|
b = Eq(f, 0)
|
||
|
if b is S.true:
|
||
|
return domain
|
||
|
elif b is S.false:
|
||
|
return S.EmptySet
|
||
|
else:
|
||
|
raise NotImplementedError(filldedent('''
|
||
|
relationship between value and 0 is unknown: %s''' % b))
|
||
|
|
||
|
if symbol is None:
|
||
|
if len(free_symbols) == 1:
|
||
|
symbol = free_symbols.pop()
|
||
|
elif free_symbols:
|
||
|
raise ValueError(filldedent('''
|
||
|
The independent variable must be specified for a
|
||
|
multivariate equation.'''))
|
||
|
elif not isinstance(symbol, Symbol):
|
||
|
f, s, swap = recast_to_symbols([f], [symbol])
|
||
|
# the xreplace will be needed if a ConditionSet is returned
|
||
|
return solveset(f[0], s[0], domain).xreplace(swap)
|
||
|
|
||
|
# solveset should ignore assumptions on symbols
|
||
|
if symbol not in _rc:
|
||
|
x = _rc[0] if domain.is_subset(S.Reals) else _rc[1]
|
||
|
rv = solveset(f.xreplace({symbol: x}), x, domain)
|
||
|
# try to use the original symbol if possible
|
||
|
try:
|
||
|
_rv = rv.xreplace({x: symbol})
|
||
|
except TypeError:
|
||
|
_rv = rv
|
||
|
if rv.dummy_eq(_rv):
|
||
|
rv = _rv
|
||
|
return rv
|
||
|
|
||
|
# Abs has its own handling method which avoids the
|
||
|
# rewriting property that the first piece of abs(x)
|
||
|
# is for x >= 0 and the 2nd piece for x < 0 -- solutions
|
||
|
# can look better if the 2nd condition is x <= 0. Since
|
||
|
# the solution is a set, duplication of results is not
|
||
|
# an issue, e.g. {y, -y} when y is 0 will be {0}
|
||
|
f, mask = _masked(f, Abs)
|
||
|
f = f.rewrite(Piecewise) # everything that's not an Abs
|
||
|
for d, e in mask:
|
||
|
# everything *in* an Abs
|
||
|
e = e.func(e.args[0].rewrite(Piecewise))
|
||
|
f = f.xreplace({d: e})
|
||
|
f = piecewise_fold(f)
|
||
|
|
||
|
return _solveset(f, symbol, domain, _check=True)
|
||
|
|
||
|
|
||
|
def solveset_real(f, symbol):
|
||
|
return solveset(f, symbol, S.Reals)
|
||
|
|
||
|
|
||
|
def solveset_complex(f, symbol):
|
||
|
return solveset(f, symbol, S.Complexes)
|
||
|
|
||
|
|
||
|
def _solveset_multi(eqs, syms, domains):
|
||
|
'''Basic implementation of a multivariate solveset.
|
||
|
|
||
|
For internal use (not ready for public consumption)'''
|
||
|
|
||
|
rep = {}
|
||
|
for sym, dom in zip(syms, domains):
|
||
|
if dom is S.Reals:
|
||
|
rep[sym] = Symbol(sym.name, real=True)
|
||
|
eqs = [eq.subs(rep) for eq in eqs]
|
||
|
syms = [sym.subs(rep) for sym in syms]
|
||
|
|
||
|
syms = tuple(syms)
|
||
|
|
||
|
if len(eqs) == 0:
|
||
|
return ProductSet(*domains)
|
||
|
|
||
|
if len(syms) == 1:
|
||
|
sym = syms[0]
|
||
|
domain = domains[0]
|
||
|
solsets = [solveset(eq, sym, domain) for eq in eqs]
|
||
|
solset = Intersection(*solsets)
|
||
|
return ImageSet(Lambda((sym,), (sym,)), solset).doit()
|
||
|
|
||
|
eqs = sorted(eqs, key=lambda eq: len(eq.free_symbols & set(syms)))
|
||
|
|
||
|
for n, eq in enumerate(eqs):
|
||
|
sols = []
|
||
|
all_handled = True
|
||
|
for sym in syms:
|
||
|
if sym not in eq.free_symbols:
|
||
|
continue
|
||
|
sol = solveset(eq, sym, domains[syms.index(sym)])
|
||
|
|
||
|
if isinstance(sol, FiniteSet):
|
||
|
i = syms.index(sym)
|
||
|
symsp = syms[:i] + syms[i+1:]
|
||
|
domainsp = domains[:i] + domains[i+1:]
|
||
|
eqsp = eqs[:n] + eqs[n+1:]
|
||
|
for s in sol:
|
||
|
eqsp_sub = [eq.subs(sym, s) for eq in eqsp]
|
||
|
sol_others = _solveset_multi(eqsp_sub, symsp, domainsp)
|
||
|
fun = Lambda((symsp,), symsp[:i] + (s,) + symsp[i:])
|
||
|
sols.append(ImageSet(fun, sol_others).doit())
|
||
|
else:
|
||
|
all_handled = False
|
||
|
if all_handled:
|
||
|
return Union(*sols)
|
||
|
|
||
|
|
||
|
def solvify(f, symbol, domain):
|
||
|
"""Solves an equation using solveset and returns the solution in accordance
|
||
|
with the `solve` output API.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
We classify the output based on the type of solution returned by `solveset`.
|
||
|
|
||
|
Solution | Output
|
||
|
----------------------------------------
|
||
|
FiniteSet | list
|
||
|
|
||
|
ImageSet, | list (if `f` is periodic)
|
||
|
Union |
|
||
|
|
||
|
Union | list (with FiniteSet)
|
||
|
|
||
|
EmptySet | empty list
|
||
|
|
||
|
Others | None
|
||
|
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
NotImplementedError
|
||
|
A ConditionSet is the input.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import solvify
|
||
|
>>> from sympy.abc import x
|
||
|
>>> from sympy import S, tan, sin, exp
|
||
|
>>> solvify(x**2 - 9, x, S.Reals)
|
||
|
[-3, 3]
|
||
|
>>> solvify(sin(x) - 1, x, S.Reals)
|
||
|
[pi/2]
|
||
|
>>> solvify(tan(x), x, S.Reals)
|
||
|
[0]
|
||
|
>>> solvify(exp(x) - 1, x, S.Complexes)
|
||
|
|
||
|
>>> solvify(exp(x) - 1, x, S.Reals)
|
||
|
[0]
|
||
|
|
||
|
"""
|
||
|
solution_set = solveset(f, symbol, domain)
|
||
|
result = None
|
||
|
if solution_set is S.EmptySet:
|
||
|
result = []
|
||
|
|
||
|
elif isinstance(solution_set, ConditionSet):
|
||
|
raise NotImplementedError('solveset is unable to solve this equation.')
|
||
|
|
||
|
elif isinstance(solution_set, FiniteSet):
|
||
|
result = list(solution_set)
|
||
|
|
||
|
else:
|
||
|
period = periodicity(f, symbol)
|
||
|
if period is not None:
|
||
|
solutions = S.EmptySet
|
||
|
iter_solutions = ()
|
||
|
if isinstance(solution_set, ImageSet):
|
||
|
iter_solutions = (solution_set,)
|
||
|
elif isinstance(solution_set, Union):
|
||
|
if all(isinstance(i, ImageSet) for i in solution_set.args):
|
||
|
iter_solutions = solution_set.args
|
||
|
|
||
|
for solution in iter_solutions:
|
||
|
solutions += solution.intersect(Interval(0, period, False, True))
|
||
|
|
||
|
if isinstance(solutions, FiniteSet):
|
||
|
result = list(solutions)
|
||
|
|
||
|
else:
|
||
|
solution = solution_set.intersect(domain)
|
||
|
if isinstance(solution, Union):
|
||
|
# concerned about only FiniteSet with Union but not about ImageSet
|
||
|
# if required could be extend
|
||
|
if any(isinstance(i, FiniteSet) for i in solution.args):
|
||
|
result = [sol for soln in solution.args \
|
||
|
for sol in soln.args if isinstance(soln,FiniteSet)]
|
||
|
else:
|
||
|
return None
|
||
|
|
||
|
elif isinstance(solution, FiniteSet):
|
||
|
result += solution
|
||
|
|
||
|
return result
|
||
|
|
||
|
|
||
|
###############################################################################
|
||
|
################################ LINSOLVE #####################################
|
||
|
###############################################################################
|
||
|
|
||
|
|
||
|
def linear_coeffs(eq, *syms, dict=False):
|
||
|
"""Return a list whose elements are the coefficients of the
|
||
|
corresponding symbols in the sum of terms in ``eq``.
|
||
|
The additive constant is returned as the last element of the
|
||
|
list.
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
NonlinearError
|
||
|
The equation contains a nonlinear term
|
||
|
ValueError
|
||
|
duplicate or unordered symbols are passed
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
dict - (default False) when True, return coefficients as a
|
||
|
dictionary with coefficients keyed to syms that were present;
|
||
|
key 1 gives the constant term
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.solvers.solveset import linear_coeffs
|
||
|
>>> from sympy.abc import x, y, z
|
||
|
>>> linear_coeffs(3*x + 2*y - 1, x, y)
|
||
|
[3, 2, -1]
|
||
|
|
||
|
It is not necessary to expand the expression:
|
||
|
|
||
|
>>> linear_coeffs(x + y*(z*(x*3 + 2) + 3), x)
|
||
|
[3*y*z + 1, y*(2*z + 3)]
|
||
|
|
||
|
When nonlinear is detected, an error will be raised:
|
||
|
|
||
|
* even if they would cancel after expansion (so the
|
||
|
situation does not pass silently past the caller's
|
||
|
attention)
|
||
|
|
||
|
>>> eq = 1/x*(x - 1) + 1/x
|
||
|
>>> linear_coeffs(eq.expand(), x)
|
||
|
[0, 1]
|
||
|
>>> linear_coeffs(eq, x)
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError:
|
||
|
nonlinear in given generators
|
||
|
|
||
|
* when there are cross terms
|
||
|
|
||
|
>>> linear_coeffs(x*(y + 1), x, y)
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError:
|
||
|
symbol-dependent cross-terms encountered
|
||
|
|
||
|
* when there are terms that contain an expression
|
||
|
dependent on the symbols that is not linear
|
||
|
|
||
|
>>> linear_coeffs(x**2, x)
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError:
|
||
|
nonlinear in given generators
|
||
|
"""
|
||
|
eq = _sympify(eq)
|
||
|
if len(syms) == 1 and iterable(syms[0]) and not isinstance(syms[0], Basic):
|
||
|
raise ValueError('expecting unpacked symbols, *syms')
|
||
|
symset = set(syms)
|
||
|
if len(symset) != len(syms):
|
||
|
raise ValueError('duplicate symbols given')
|
||
|
try:
|
||
|
d, c = _linear_eq_to_dict([eq], symset)
|
||
|
d = d[0]
|
||
|
c = c[0]
|
||
|
except PolyNonlinearError as err:
|
||
|
raise NonlinearError(str(err))
|
||
|
if dict:
|
||
|
if c:
|
||
|
d[S.One] = c
|
||
|
return d
|
||
|
rv = [S.Zero]*(len(syms) + 1)
|
||
|
rv[-1] = c
|
||
|
for i, k in enumerate(syms):
|
||
|
if k not in d:
|
||
|
continue
|
||
|
rv[i] = d[k]
|
||
|
return rv
|
||
|
|
||
|
|
||
|
def linear_eq_to_matrix(equations, *symbols):
|
||
|
r"""
|
||
|
Converts a given System of Equations into Matrix form.
|
||
|
Here `equations` must be a linear system of equations in
|
||
|
`symbols`. Element ``M[i, j]`` corresponds to the coefficient
|
||
|
of the jth symbol in the ith equation.
|
||
|
|
||
|
The Matrix form corresponds to the augmented matrix form.
|
||
|
For example:
|
||
|
|
||
|
.. math:: 4x + 2y + 3z = 1
|
||
|
.. math:: 3x + y + z = -6
|
||
|
.. math:: 2x + 4y + 9z = 2
|
||
|
|
||
|
This system will return $A$ and $b$ as:
|
||
|
|
||
|
$$ A = \left[\begin{array}{ccc}
|
||
|
4 & 2 & 3 \\
|
||
|
3 & 1 & 1 \\
|
||
|
2 & 4 & 9
|
||
|
\end{array}\right] \ \ b = \left[\begin{array}{c}
|
||
|
1 \\ -6 \\ 2
|
||
|
\end{array}\right] $$
|
||
|
|
||
|
The only simplification performed is to convert
|
||
|
``Eq(a, b)`` $\Rightarrow a - b$.
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
NonlinearError
|
||
|
The equations contain a nonlinear term.
|
||
|
ValueError
|
||
|
The symbols are not given or are not unique.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import linear_eq_to_matrix, symbols
|
||
|
>>> c, x, y, z = symbols('c, x, y, z')
|
||
|
|
||
|
The coefficients (numerical or symbolic) of the symbols will
|
||
|
be returned as matrices:
|
||
|
|
||
|
>>> eqns = [c*x + z - 1 - c, y + z, x - y]
|
||
|
>>> A, b = linear_eq_to_matrix(eqns, [x, y, z])
|
||
|
>>> A
|
||
|
Matrix([
|
||
|
[c, 0, 1],
|
||
|
[0, 1, 1],
|
||
|
[1, -1, 0]])
|
||
|
>>> b
|
||
|
Matrix([
|
||
|
[c + 1],
|
||
|
[ 0],
|
||
|
[ 0]])
|
||
|
|
||
|
This routine does not simplify expressions and will raise an error
|
||
|
if nonlinearity is encountered:
|
||
|
|
||
|
>>> eqns = [
|
||
|
... (x**2 - 3*x)/(x - 3) - 3,
|
||
|
... y**2 - 3*y - y*(y - 4) + x - 4]
|
||
|
>>> linear_eq_to_matrix(eqns, [x, y])
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError:
|
||
|
symbol-dependent term can be ignored using `strict=False`
|
||
|
|
||
|
Simplifying these equations will discard the removable singularity
|
||
|
in the first and reveal the linear structure of the second:
|
||
|
|
||
|
>>> [e.simplify() for e in eqns]
|
||
|
[x - 3, x + y - 4]
|
||
|
|
||
|
Any such simplification needed to eliminate nonlinear terms must
|
||
|
be done *before* calling this routine.
|
||
|
"""
|
||
|
if not symbols:
|
||
|
raise ValueError(filldedent('''
|
||
|
Symbols must be given, for which coefficients
|
||
|
are to be found.
|
||
|
'''))
|
||
|
|
||
|
if hasattr(symbols[0], '__iter__'):
|
||
|
symbols = symbols[0]
|
||
|
|
||
|
if has_dups(symbols):
|
||
|
raise ValueError('Symbols must be unique')
|
||
|
|
||
|
equations = sympify(equations)
|
||
|
if isinstance(equations, MatrixBase):
|
||
|
equations = list(equations)
|
||
|
elif isinstance(equations, (Expr, Eq)):
|
||
|
equations = [equations]
|
||
|
elif not is_sequence(equations):
|
||
|
raise ValueError(filldedent('''
|
||
|
Equation(s) must be given as a sequence, Expr,
|
||
|
Eq or Matrix.
|
||
|
'''))
|
||
|
|
||
|
# construct the dictionaries
|
||
|
try:
|
||
|
eq, c = _linear_eq_to_dict(equations, symbols)
|
||
|
except PolyNonlinearError as err:
|
||
|
raise NonlinearError(str(err))
|
||
|
# prepare output matrices
|
||
|
n, m = shape = len(eq), len(symbols)
|
||
|
ix = dict(zip(symbols, range(m)))
|
||
|
A = zeros(*shape)
|
||
|
for row, d in enumerate(eq):
|
||
|
for k in d:
|
||
|
col = ix[k]
|
||
|
A[row, col] = d[k]
|
||
|
b = Matrix(n, 1, [-i for i in c])
|
||
|
return A, b
|
||
|
|
||
|
|
||
|
def linsolve(system, *symbols):
|
||
|
r"""
|
||
|
Solve system of $N$ linear equations with $M$ variables; both
|
||
|
underdetermined and overdetermined systems are supported.
|
||
|
The possible number of solutions is zero, one or infinite.
|
||
|
Zero solutions throws a ValueError, whereas infinite
|
||
|
solutions are represented parametrically in terms of the given
|
||
|
symbols. For unique solution a :class:`~.FiniteSet` of ordered tuples
|
||
|
is returned.
|
||
|
|
||
|
All standard input formats are supported:
|
||
|
For the given set of equations, the respective input types
|
||
|
are given below:
|
||
|
|
||
|
.. math:: 3x + 2y - z = 1
|
||
|
.. math:: 2x - 2y + 4z = -2
|
||
|
.. math:: 2x - y + 2z = 0
|
||
|
|
||
|
* Augmented matrix form, ``system`` given below:
|
||
|
|
||
|
$$ \text{system} = \left[{array}{cccc}
|
||
|
3 & 2 & -1 & 1\\
|
||
|
2 & -2 & 4 & -2\\
|
||
|
2 & -1 & 2 & 0
|
||
|
\end{array}\right] $$
|
||
|
|
||
|
::
|
||
|
|
||
|
system = Matrix([[3, 2, -1, 1], [2, -2, 4, -2], [2, -1, 2, 0]])
|
||
|
|
||
|
* List of equations form
|
||
|
|
||
|
::
|
||
|
|
||
|
system = [3x + 2y - z - 1, 2x - 2y + 4z + 2, 2x - y + 2z]
|
||
|
|
||
|
* Input $A$ and $b$ in matrix form (from $Ax = b$) are given as:
|
||
|
|
||
|
$$ A = \left[\begin{array}{ccc}
|
||
|
3 & 2 & -1 \\
|
||
|
2 & -2 & 4 \\
|
||
|
2 & -1 & 2
|
||
|
\end{array}\right] \ \ b = \left[\begin{array}{c}
|
||
|
1 \\ -2 \\ 0
|
||
|
\end{array}\right] $$
|
||
|
|
||
|
::
|
||
|
|
||
|
A = Matrix([[3, 2, -1], [2, -2, 4], [2, -1, 2]])
|
||
|
b = Matrix([[1], [-2], [0]])
|
||
|
system = (A, b)
|
||
|
|
||
|
Symbols can always be passed but are actually only needed
|
||
|
when 1) a system of equations is being passed and 2) the
|
||
|
system is passed as an underdetermined matrix and one wants
|
||
|
to control the name of the free variables in the result.
|
||
|
An error is raised if no symbols are used for case 1, but if
|
||
|
no symbols are provided for case 2, internally generated symbols
|
||
|
will be provided. When providing symbols for case 2, there should
|
||
|
be at least as many symbols are there are columns in matrix A.
|
||
|
|
||
|
The algorithm used here is Gauss-Jordan elimination, which
|
||
|
results, after elimination, in a row echelon form matrix.
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A FiniteSet containing an ordered tuple of values for the
|
||
|
unknowns for which the `system` has a solution. (Wrapping
|
||
|
the tuple in FiniteSet is used to maintain a consistent
|
||
|
output format throughout solveset.)
|
||
|
|
||
|
Returns EmptySet, if the linear system is inconsistent.
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
ValueError
|
||
|
The input is not valid.
|
||
|
The symbols are not given.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import Matrix, linsolve, symbols
|
||
|
>>> x, y, z = symbols("x, y, z")
|
||
|
>>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 10]])
|
||
|
>>> b = Matrix([3, 6, 9])
|
||
|
>>> A
|
||
|
Matrix([
|
||
|
[1, 2, 3],
|
||
|
[4, 5, 6],
|
||
|
[7, 8, 10]])
|
||
|
>>> b
|
||
|
Matrix([
|
||
|
[3],
|
||
|
[6],
|
||
|
[9]])
|
||
|
>>> linsolve((A, b), [x, y, z])
|
||
|
{(-1, 2, 0)}
|
||
|
|
||
|
* Parametric Solution: In case the system is underdetermined, the
|
||
|
function will return a parametric solution in terms of the given
|
||
|
symbols. Those that are free will be returned unchanged. e.g. in
|
||
|
the system below, `z` is returned as the solution for variable z;
|
||
|
it can take on any value.
|
||
|
|
||
|
>>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]])
|
||
|
>>> b = Matrix([3, 6, 9])
|
||
|
>>> linsolve((A, b), x, y, z)
|
||
|
{(z - 1, 2 - 2*z, z)}
|
||
|
|
||
|
If no symbols are given, internally generated symbols will be used.
|
||
|
The ``tau0`` in the third position indicates (as before) that the third
|
||
|
variable -- whatever it is named -- can take on any value:
|
||
|
|
||
|
>>> linsolve((A, b))
|
||
|
{(tau0 - 1, 2 - 2*tau0, tau0)}
|
||
|
|
||
|
* List of equations as input
|
||
|
|
||
|
>>> Eqns = [3*x + 2*y - z - 1, 2*x - 2*y + 4*z + 2, - x + y/2 - z]
|
||
|
>>> linsolve(Eqns, x, y, z)
|
||
|
{(1, -2, -2)}
|
||
|
|
||
|
* Augmented matrix as input
|
||
|
|
||
|
>>> aug = Matrix([[2, 1, 3, 1], [2, 6, 8, 3], [6, 8, 18, 5]])
|
||
|
>>> aug
|
||
|
Matrix([
|
||
|
[2, 1, 3, 1],
|
||
|
[2, 6, 8, 3],
|
||
|
[6, 8, 18, 5]])
|
||
|
>>> linsolve(aug, x, y, z)
|
||
|
{(3/10, 2/5, 0)}
|
||
|
|
||
|
* Solve for symbolic coefficients
|
||
|
|
||
|
>>> a, b, c, d, e, f = symbols('a, b, c, d, e, f')
|
||
|
>>> eqns = [a*x + b*y - c, d*x + e*y - f]
|
||
|
>>> linsolve(eqns, x, y)
|
||
|
{((-b*f + c*e)/(a*e - b*d), (a*f - c*d)/(a*e - b*d))}
|
||
|
|
||
|
* A degenerate system returns solution as set of given
|
||
|
symbols.
|
||
|
|
||
|
>>> system = Matrix(([0, 0, 0], [0, 0, 0], [0, 0, 0]))
|
||
|
>>> linsolve(system, x, y)
|
||
|
{(x, y)}
|
||
|
|
||
|
* For an empty system linsolve returns empty set
|
||
|
|
||
|
>>> linsolve([], x)
|
||
|
EmptySet
|
||
|
|
||
|
* An error is raised if any nonlinearity is detected, even
|
||
|
if it could be removed with expansion
|
||
|
|
||
|
>>> linsolve([x*(1/x - 1)], x)
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError: nonlinear term: 1/x
|
||
|
|
||
|
>>> linsolve([x*(y + 1)], x, y)
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError: nonlinear cross-term: x*(y + 1)
|
||
|
|
||
|
>>> linsolve([x**2 - 1], x)
|
||
|
Traceback (most recent call last):
|
||
|
...
|
||
|
NonlinearError: nonlinear term: x**2
|
||
|
"""
|
||
|
if not system:
|
||
|
return S.EmptySet
|
||
|
|
||
|
# If second argument is an iterable
|
||
|
if symbols and hasattr(symbols[0], '__iter__'):
|
||
|
symbols = symbols[0]
|
||
|
sym_gen = isinstance(symbols, GeneratorType)
|
||
|
dup_msg = 'duplicate symbols given'
|
||
|
|
||
|
|
||
|
b = None # if we don't get b the input was bad
|
||
|
# unpack system
|
||
|
|
||
|
if hasattr(system, '__iter__'):
|
||
|
|
||
|
# 1). (A, b)
|
||
|
if len(system) == 2 and isinstance(system[0], MatrixBase):
|
||
|
A, b = system
|
||
|
|
||
|
# 2). (eq1, eq2, ...)
|
||
|
if not isinstance(system[0], MatrixBase):
|
||
|
if sym_gen or not symbols:
|
||
|
raise ValueError(filldedent('''
|
||
|
When passing a system of equations, the explicit
|
||
|
symbols for which a solution is being sought must
|
||
|
be given as a sequence, too.
|
||
|
'''))
|
||
|
if len(set(symbols)) != len(symbols):
|
||
|
raise ValueError(dup_msg)
|
||
|
|
||
|
#
|
||
|
# Pass to the sparse solver implemented in polys. It is important
|
||
|
# that we do not attempt to convert the equations to a matrix
|
||
|
# because that would be very inefficient for large sparse systems
|
||
|
# of equations.
|
||
|
#
|
||
|
eqs = system
|
||
|
eqs = [sympify(eq) for eq in eqs]
|
||
|
try:
|
||
|
sol = _linsolve(eqs, symbols)
|
||
|
except PolyNonlinearError as exc:
|
||
|
# e.g. cos(x) contains an element of the set of generators
|
||
|
raise NonlinearError(str(exc))
|
||
|
|
||
|
if sol is None:
|
||
|
return S.EmptySet
|
||
|
|
||
|
sol = FiniteSet(Tuple(*(sol.get(sym, sym) for sym in symbols)))
|
||
|
return sol
|
||
|
|
||
|
elif isinstance(system, MatrixBase) and not (
|
||
|
symbols and not isinstance(symbols, GeneratorType) and
|
||
|
isinstance(symbols[0], MatrixBase)):
|
||
|
# 3). A augmented with b
|
||
|
A, b = system[:, :-1], system[:, -1:]
|
||
|
|
||
|
if b is None:
|
||
|
raise ValueError("Invalid arguments")
|
||
|
if sym_gen:
|
||
|
symbols = [next(symbols) for i in range(A.cols)]
|
||
|
symset = set(symbols)
|
||
|
if any(symset & (A.free_symbols | b.free_symbols)):
|
||
|
raise ValueError(filldedent('''
|
||
|
At least one of the symbols provided
|
||
|
already appears in the system to be solved.
|
||
|
One way to avoid this is to use Dummy symbols in
|
||
|
the generator, e.g. numbered_symbols('%s', cls=Dummy)
|
||
|
''' % symbols[0].name.rstrip('1234567890')))
|
||
|
elif len(symset) != len(symbols):
|
||
|
raise ValueError(dup_msg)
|
||
|
|
||
|
if not symbols:
|
||
|
symbols = [Dummy() for _ in range(A.cols)]
|
||
|
name = _uniquely_named_symbol('tau', (A, b),
|
||
|
compare=lambda i: str(i).rstrip('1234567890')).name
|
||
|
gen = numbered_symbols(name)
|
||
|
else:
|
||
|
gen = None
|
||
|
|
||
|
# This is just a wrapper for solve_lin_sys
|
||
|
eqs = []
|
||
|
rows = A.tolist()
|
||
|
for rowi, bi in zip(rows, b):
|
||
|
terms = [elem * sym for elem, sym in zip(rowi, symbols) if elem]
|
||
|
terms.append(-bi)
|
||
|
eqs.append(Add(*terms))
|
||
|
|
||
|
eqs, ring = sympy_eqs_to_ring(eqs, symbols)
|
||
|
sol = solve_lin_sys(eqs, ring, _raw=False)
|
||
|
if sol is None:
|
||
|
return S.EmptySet
|
||
|
#sol = {sym:val for sym, val in sol.items() if sym != val}
|
||
|
sol = FiniteSet(Tuple(*(sol.get(sym, sym) for sym in symbols)))
|
||
|
|
||
|
if gen is not None:
|
||
|
solsym = sol.free_symbols
|
||
|
rep = {sym: next(gen) for sym in symbols if sym in solsym}
|
||
|
sol = sol.subs(rep)
|
||
|
|
||
|
return sol
|
||
|
|
||
|
|
||
|
##############################################################################
|
||
|
# ------------------------------nonlinsolve ---------------------------------#
|
||
|
##############################################################################
|
||
|
|
||
|
|
||
|
def _return_conditionset(eqs, symbols):
|
||
|
# return conditionset
|
||
|
eqs = (Eq(lhs, 0) for lhs in eqs)
|
||
|
condition_set = ConditionSet(
|
||
|
Tuple(*symbols), And(*eqs), S.Complexes**len(symbols))
|
||
|
return condition_set
|
||
|
|
||
|
|
||
|
def substitution(system, symbols, result=[{}], known_symbols=[],
|
||
|
exclude=[], all_symbols=None):
|
||
|
r"""
|
||
|
Solves the `system` using substitution method. It is used in
|
||
|
:func:`~.nonlinsolve`. This will be called from :func:`~.nonlinsolve` when any
|
||
|
equation(s) is non polynomial equation.
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
system : list of equations
|
||
|
The target system of equations
|
||
|
symbols : list of symbols to be solved.
|
||
|
The variable(s) for which the system is solved
|
||
|
known_symbols : list of solved symbols
|
||
|
Values are known for these variable(s)
|
||
|
result : An empty list or list of dict
|
||
|
If No symbol values is known then empty list otherwise
|
||
|
symbol as keys and corresponding value in dict.
|
||
|
exclude : Set of expression.
|
||
|
Mostly denominator expression(s) of the equations of the system.
|
||
|
Final solution should not satisfy these expressions.
|
||
|
all_symbols : known_symbols + symbols(unsolved).
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A FiniteSet of ordered tuple of values of `all_symbols` for which the
|
||
|
`system` has solution. Order of values in the tuple is same as symbols
|
||
|
present in the parameter `all_symbols`. If parameter `all_symbols` is None
|
||
|
then same as symbols present in the parameter `symbols`.
|
||
|
|
||
|
Please note that general FiniteSet is unordered, the solution returned
|
||
|
here is not simply a FiniteSet of solutions, rather it is a FiniteSet of
|
||
|
ordered tuple, i.e. the first & only argument to FiniteSet is a tuple of
|
||
|
solutions, which is ordered, & hence the returned solution is ordered.
|
||
|
|
||
|
Also note that solution could also have been returned as an ordered tuple,
|
||
|
FiniteSet is just a wrapper `{}` around the tuple. It has no other
|
||
|
significance except for the fact it is just used to maintain a consistent
|
||
|
output format throughout the solveset.
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
ValueError
|
||
|
The input is not valid.
|
||
|
The symbols are not given.
|
||
|
AttributeError
|
||
|
The input symbols are not :class:`~.Symbol` type.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, substitution
|
||
|
>>> x, y = symbols('x, y', real=True)
|
||
|
>>> substitution([x + y], [x], [{y: 1}], [y], set([]), [x, y])
|
||
|
{(-1, 1)}
|
||
|
|
||
|
* When you want a soln not satisfying $x + 1 = 0$
|
||
|
|
||
|
>>> substitution([x + y], [x], [{y: 1}], [y], set([x + 1]), [y, x])
|
||
|
EmptySet
|
||
|
>>> substitution([x + y], [x], [{y: 1}], [y], set([x - 1]), [y, x])
|
||
|
{(1, -1)}
|
||
|
>>> substitution([x + y - 1, y - x**2 + 5], [x, y])
|
||
|
{(-3, 4), (2, -1)}
|
||
|
|
||
|
* Returns both real and complex solution
|
||
|
|
||
|
>>> x, y, z = symbols('x, y, z')
|
||
|
>>> from sympy import exp, sin
|
||
|
>>> substitution([exp(x) - sin(y), y**2 - 4], [x, y])
|
||
|
{(ImageSet(Lambda(_n, I*(2*_n*pi + pi) + log(sin(2))), Integers), -2),
|
||
|
(ImageSet(Lambda(_n, 2*_n*I*pi + log(sin(2))), Integers), 2)}
|
||
|
|
||
|
>>> eqs = [z**2 + exp(2*x) - sin(y), -3 + exp(-y)]
|
||
|
>>> substitution(eqs, [y, z])
|
||
|
{(-log(3), -sqrt(-exp(2*x) - sin(log(3)))),
|
||
|
(-log(3), sqrt(-exp(2*x) - sin(log(3)))),
|
||
|
(ImageSet(Lambda(_n, 2*_n*I*pi - log(3)), Integers),
|
||
|
ImageSet(Lambda(_n, -sqrt(-exp(2*x) + sin(2*_n*I*pi - log(3)))), Integers)),
|
||
|
(ImageSet(Lambda(_n, 2*_n*I*pi - log(3)), Integers),
|
||
|
ImageSet(Lambda(_n, sqrt(-exp(2*x) + sin(2*_n*I*pi - log(3)))), Integers))}
|
||
|
|
||
|
"""
|
||
|
|
||
|
if not system:
|
||
|
return S.EmptySet
|
||
|
|
||
|
if not symbols:
|
||
|
msg = ('Symbols must be given, for which solution of the '
|
||
|
'system is to be found.')
|
||
|
raise ValueError(filldedent(msg))
|
||
|
|
||
|
if not is_sequence(symbols):
|
||
|
msg = ('symbols should be given as a sequence, e.g. a list.'
|
||
|
'Not type %s: %s')
|
||
|
raise TypeError(filldedent(msg % (type(symbols), symbols)))
|
||
|
|
||
|
if not getattr(symbols[0], 'is_Symbol', False):
|
||
|
msg = ('Iterable of symbols must be given as '
|
||
|
'second argument, not type %s: %s')
|
||
|
raise ValueError(filldedent(msg % (type(symbols[0]), symbols[0])))
|
||
|
|
||
|
# By default `all_symbols` will be same as `symbols`
|
||
|
if all_symbols is None:
|
||
|
all_symbols = symbols
|
||
|
|
||
|
old_result = result
|
||
|
# storing complements and intersection for particular symbol
|
||
|
complements = {}
|
||
|
intersections = {}
|
||
|
|
||
|
# when total_solveset_call equals total_conditionset
|
||
|
# it means that solveset failed to solve all eqs.
|
||
|
total_conditionset = -1
|
||
|
total_solveset_call = -1
|
||
|
|
||
|
def _unsolved_syms(eq, sort=False):
|
||
|
"""Returns the unsolved symbol present
|
||
|
in the equation `eq`.
|
||
|
"""
|
||
|
free = eq.free_symbols
|
||
|
unsolved = (free - set(known_symbols)) & set(all_symbols)
|
||
|
if sort:
|
||
|
unsolved = list(unsolved)
|
||
|
unsolved.sort(key=default_sort_key)
|
||
|
return unsolved
|
||
|
# end of _unsolved_syms()
|
||
|
|
||
|
# sort such that equation with the fewest potential symbols is first.
|
||
|
# means eq with less number of variable first in the list.
|
||
|
eqs_in_better_order = list(
|
||
|
ordered(system, lambda _: len(_unsolved_syms(_))))
|
||
|
|
||
|
def add_intersection_complement(result, intersection_dict, complement_dict):
|
||
|
# If solveset has returned some intersection/complement
|
||
|
# for any symbol, it will be added in the final solution.
|
||
|
final_result = []
|
||
|
for res in result:
|
||
|
res_copy = res
|
||
|
for key_res, value_res in res.items():
|
||
|
intersect_set, complement_set = None, None
|
||
|
for key_sym, value_sym in intersection_dict.items():
|
||
|
if key_sym == key_res:
|
||
|
intersect_set = value_sym
|
||
|
for key_sym, value_sym in complement_dict.items():
|
||
|
if key_sym == key_res:
|
||
|
complement_set = value_sym
|
||
|
if intersect_set or complement_set:
|
||
|
new_value = FiniteSet(value_res)
|
||
|
if intersect_set and intersect_set != S.Complexes:
|
||
|
new_value = Intersection(new_value, intersect_set)
|
||
|
if complement_set:
|
||
|
new_value = Complement(new_value, complement_set)
|
||
|
if new_value is S.EmptySet:
|
||
|
res_copy = None
|
||
|
break
|
||
|
elif new_value.is_FiniteSet and len(new_value) == 1:
|
||
|
res_copy[key_res] = set(new_value).pop()
|
||
|
else:
|
||
|
res_copy[key_res] = new_value
|
||
|
|
||
|
if res_copy is not None:
|
||
|
final_result.append(res_copy)
|
||
|
return final_result
|
||
|
# end of def add_intersection_complement()
|
||
|
|
||
|
def _extract_main_soln(sym, sol, soln_imageset):
|
||
|
"""Separate the Complements, Intersections, ImageSet lambda expr and
|
||
|
its base_set. This function returns the unmasks sol from different classes
|
||
|
of sets and also returns the appended ImageSet elements in a
|
||
|
soln_imageset (dict: where key as unmasked element and value as ImageSet).
|
||
|
"""
|
||
|
# if there is union, then need to check
|
||
|
# Complement, Intersection, Imageset.
|
||
|
# Order should not be changed.
|
||
|
if isinstance(sol, ConditionSet):
|
||
|
# extracts any solution in ConditionSet
|
||
|
sol = sol.base_set
|
||
|
|
||
|
if isinstance(sol, Complement):
|
||
|
# extract solution and complement
|
||
|
complements[sym] = sol.args[1]
|
||
|
sol = sol.args[0]
|
||
|
# complement will be added at the end
|
||
|
# using `add_intersection_complement` method
|
||
|
|
||
|
# if there is union of Imageset or other in soln.
|
||
|
# no testcase is written for this if block
|
||
|
if isinstance(sol, Union):
|
||
|
sol_args = sol.args
|
||
|
sol = S.EmptySet
|
||
|
# We need in sequence so append finteset elements
|
||
|
# and then imageset or other.
|
||
|
for sol_arg2 in sol_args:
|
||
|
if isinstance(sol_arg2, FiniteSet):
|
||
|
sol += sol_arg2
|
||
|
else:
|
||
|
# ImageSet, Intersection, complement then
|
||
|
# append them directly
|
||
|
sol += FiniteSet(sol_arg2)
|
||
|
|
||
|
if isinstance(sol, Intersection):
|
||
|
# Interval/Set will be at 0th index always
|
||
|
if sol.args[0] not in (S.Reals, S.Complexes):
|
||
|
# Sometimes solveset returns soln with intersection
|
||
|
# S.Reals or S.Complexes. We don't consider that
|
||
|
# intersection.
|
||
|
intersections[sym] = sol.args[0]
|
||
|
sol = sol.args[1]
|
||
|
# after intersection and complement Imageset should
|
||
|
# be checked.
|
||
|
if isinstance(sol, ImageSet):
|
||
|
soln_imagest = sol
|
||
|
expr2 = sol.lamda.expr
|
||
|
sol = FiniteSet(expr2)
|
||
|
soln_imageset[expr2] = soln_imagest
|
||
|
|
||
|
if not isinstance(sol, FiniteSet):
|
||
|
sol = FiniteSet(sol)
|
||
|
return sol, soln_imageset
|
||
|
# end of def _extract_main_soln()
|
||
|
|
||
|
# helper function for _append_new_soln
|
||
|
def _check_exclude(rnew, imgset_yes):
|
||
|
rnew_ = rnew
|
||
|
if imgset_yes:
|
||
|
# replace all dummy variables (Imageset lambda variables)
|
||
|
# with zero before `checksol`. Considering fundamental soln
|
||
|
# for `checksol`.
|
||
|
rnew_copy = rnew.copy()
|
||
|
dummy_n = imgset_yes[0]
|
||
|
for key_res, value_res in rnew_copy.items():
|
||
|
rnew_copy[key_res] = value_res.subs(dummy_n, 0)
|
||
|
rnew_ = rnew_copy
|
||
|
# satisfy_exclude == true if it satisfies the expr of `exclude` list.
|
||
|
try:
|
||
|
# something like : `Mod(-log(3), 2*I*pi)` can't be
|
||
|
# simplified right now, so `checksol` returns `TypeError`.
|
||
|
# when this issue is fixed this try block should be
|
||
|
# removed. Mod(-log(3), 2*I*pi) == -log(3)
|
||
|
satisfy_exclude = any(
|
||
|
checksol(d, rnew_) for d in exclude)
|
||
|
except TypeError:
|
||
|
satisfy_exclude = None
|
||
|
return satisfy_exclude
|
||
|
# end of def _check_exclude()
|
||
|
|
||
|
# helper function for _append_new_soln
|
||
|
def _restore_imgset(rnew, original_imageset, newresult):
|
||
|
restore_sym = set(rnew.keys()) & \
|
||
|
set(original_imageset.keys())
|
||
|
for key_sym in restore_sym:
|
||
|
img = original_imageset[key_sym]
|
||
|
rnew[key_sym] = img
|
||
|
if rnew not in newresult:
|
||
|
newresult.append(rnew)
|
||
|
# end of def _restore_imgset()
|
||
|
|
||
|
def _append_eq(eq, result, res, delete_soln, n=None):
|
||
|
u = Dummy('u')
|
||
|
if n:
|
||
|
eq = eq.subs(n, 0)
|
||
|
satisfy = eq if eq in (True, False) else checksol(u, u, eq, minimal=True)
|
||
|
if satisfy is False:
|
||
|
delete_soln = True
|
||
|
res = {}
|
||
|
else:
|
||
|
result.append(res)
|
||
|
return result, res, delete_soln
|
||
|
|
||
|
def _append_new_soln(rnew, sym, sol, imgset_yes, soln_imageset,
|
||
|
original_imageset, newresult, eq=None):
|
||
|
"""If `rnew` (A dict <symbol: soln>) contains valid soln
|
||
|
append it to `newresult` list.
|
||
|
`imgset_yes` is (base, dummy_var) if there was imageset in previously
|
||
|
calculated result(otherwise empty tuple). `original_imageset` is dict
|
||
|
of imageset expr and imageset from this result.
|
||
|
`soln_imageset` dict of imageset expr and imageset of new soln.
|
||
|
"""
|
||
|
satisfy_exclude = _check_exclude(rnew, imgset_yes)
|
||
|
delete_soln = False
|
||
|
# soln should not satisfy expr present in `exclude` list.
|
||
|
if not satisfy_exclude:
|
||
|
local_n = None
|
||
|
# if it is imageset
|
||
|
if imgset_yes:
|
||
|
local_n = imgset_yes[0]
|
||
|
base = imgset_yes[1]
|
||
|
if sym and sol:
|
||
|
# when `sym` and `sol` is `None` means no new
|
||
|
# soln. In that case we will append rnew directly after
|
||
|
# substituting original imagesets in rnew values if present
|
||
|
# (second last line of this function using _restore_imgset)
|
||
|
dummy_list = list(sol.atoms(Dummy))
|
||
|
# use one dummy `n` which is in
|
||
|
# previous imageset
|
||
|
local_n_list = [
|
||
|
local_n for i in range(
|
||
|
0, len(dummy_list))]
|
||
|
|
||
|
dummy_zip = zip(dummy_list, local_n_list)
|
||
|
lam = Lambda(local_n, sol.subs(dummy_zip))
|
||
|
rnew[sym] = ImageSet(lam, base)
|
||
|
if eq is not None:
|
||
|
newresult, rnew, delete_soln = _append_eq(
|
||
|
eq, newresult, rnew, delete_soln, local_n)
|
||
|
elif eq is not None:
|
||
|
newresult, rnew, delete_soln = _append_eq(
|
||
|
eq, newresult, rnew, delete_soln)
|
||
|
elif sol in soln_imageset.keys():
|
||
|
rnew[sym] = soln_imageset[sol]
|
||
|
# restore original imageset
|
||
|
_restore_imgset(rnew, original_imageset, newresult)
|
||
|
else:
|
||
|
newresult.append(rnew)
|
||
|
elif satisfy_exclude:
|
||
|
delete_soln = True
|
||
|
rnew = {}
|
||
|
_restore_imgset(rnew, original_imageset, newresult)
|
||
|
return newresult, delete_soln
|
||
|
# end of def _append_new_soln()
|
||
|
|
||
|
def _new_order_result(result, eq):
|
||
|
# separate first, second priority. `res` that makes `eq` value equals
|
||
|
# to zero, should be used first then other result(second priority).
|
||
|
# If it is not done then we may miss some soln.
|
||
|
first_priority = []
|
||
|
second_priority = []
|
||
|
for res in result:
|
||
|
if not any(isinstance(val, ImageSet) for val in res.values()):
|
||
|
if eq.subs(res) == 0:
|
||
|
first_priority.append(res)
|
||
|
else:
|
||
|
second_priority.append(res)
|
||
|
if first_priority or second_priority:
|
||
|
return first_priority + second_priority
|
||
|
return result
|
||
|
|
||
|
def _solve_using_known_values(result, solver):
|
||
|
"""Solves the system using already known solution
|
||
|
(result contains the dict <symbol: value>).
|
||
|
solver is :func:`~.solveset_complex` or :func:`~.solveset_real`.
|
||
|
"""
|
||
|
# stores imageset <expr: imageset(Lambda(n, expr), base)>.
|
||
|
soln_imageset = {}
|
||
|
total_solvest_call = 0
|
||
|
total_conditionst = 0
|
||
|
|
||
|
# sort such that equation with the fewest potential symbols is first.
|
||
|
# means eq with less variable first
|
||
|
for index, eq in enumerate(eqs_in_better_order):
|
||
|
newresult = []
|
||
|
original_imageset = {}
|
||
|
# if imageset expr is used to solve other symbol
|
||
|
imgset_yes = False
|
||
|
result = _new_order_result(result, eq)
|
||
|
for res in result:
|
||
|
got_symbol = set() # symbols solved in one iteration
|
||
|
# find the imageset and use its expr.
|
||
|
for key_res, value_res in res.items():
|
||
|
if isinstance(value_res, ImageSet):
|
||
|
res[key_res] = value_res.lamda.expr
|
||
|
original_imageset[key_res] = value_res
|
||
|
dummy_n = value_res.lamda.expr.atoms(Dummy).pop()
|
||
|
(base,) = value_res.base_sets
|
||
|
imgset_yes = (dummy_n, base)
|
||
|
# update eq with everything that is known so far
|
||
|
eq2 = eq.subs(res).expand()
|
||
|
unsolved_syms = _unsolved_syms(eq2, sort=True)
|
||
|
if not unsolved_syms:
|
||
|
if res:
|
||
|
newresult, delete_res = _append_new_soln(
|
||
|
res, None, None, imgset_yes, soln_imageset,
|
||
|
original_imageset, newresult, eq2)
|
||
|
if delete_res:
|
||
|
# `delete_res` is true, means substituting `res` in
|
||
|
# eq2 doesn't return `zero` or deleting the `res`
|
||
|
# (a soln) since it staisfies expr of `exclude`
|
||
|
# list.
|
||
|
result.remove(res)
|
||
|
continue # skip as it's independent of desired symbols
|
||
|
depen1, depen2 = (eq2.rewrite(Add)).as_independent(*unsolved_syms)
|
||
|
if (depen1.has(Abs) or depen2.has(Abs)) and solver == solveset_complex:
|
||
|
# Absolute values cannot be inverted in the
|
||
|
# complex domain
|
||
|
continue
|
||
|
soln_imageset = {}
|
||
|
for sym in unsolved_syms:
|
||
|
not_solvable = False
|
||
|
try:
|
||
|
soln = solver(eq2, sym)
|
||
|
total_solvest_call += 1
|
||
|
soln_new = S.EmptySet
|
||
|
if isinstance(soln, Complement):
|
||
|
# separate solution and complement
|
||
|
complements[sym] = soln.args[1]
|
||
|
soln = soln.args[0]
|
||
|
# complement will be added at the end
|
||
|
if isinstance(soln, Intersection):
|
||
|
# Interval will be at 0th index always
|
||
|
if soln.args[0] != Interval(-oo, oo):
|
||
|
# sometimes solveset returns soln
|
||
|
# with intersection S.Reals, to confirm that
|
||
|
# soln is in domain=S.Reals
|
||
|
intersections[sym] = soln.args[0]
|
||
|
soln_new += soln.args[1]
|
||
|
soln = soln_new if soln_new else soln
|
||
|
if index > 0 and solver == solveset_real:
|
||
|
# one symbol's real soln, another symbol may have
|
||
|
# corresponding complex soln.
|
||
|
if not isinstance(soln, (ImageSet, ConditionSet)):
|
||
|
soln += solveset_complex(eq2, sym) # might give ValueError with Abs
|
||
|
except (NotImplementedError, ValueError):
|
||
|
# If solveset is not able to solve equation `eq2`. Next
|
||
|
# time we may get soln using next equation `eq2`
|
||
|
continue
|
||
|
if isinstance(soln, ConditionSet):
|
||
|
if soln.base_set in (S.Reals, S.Complexes):
|
||
|
soln = S.EmptySet
|
||
|
# don't do `continue` we may get soln
|
||
|
# in terms of other symbol(s)
|
||
|
not_solvable = True
|
||
|
total_conditionst += 1
|
||
|
else:
|
||
|
soln = soln.base_set
|
||
|
|
||
|
if soln is not S.EmptySet:
|
||
|
soln, soln_imageset = _extract_main_soln(
|
||
|
sym, soln, soln_imageset)
|
||
|
|
||
|
for sol in soln:
|
||
|
# sol is not a `Union` since we checked it
|
||
|
# before this loop
|
||
|
sol, soln_imageset = _extract_main_soln(
|
||
|
sym, sol, soln_imageset)
|
||
|
sol = set(sol).pop()
|
||
|
free = sol.free_symbols
|
||
|
if got_symbol and any(
|
||
|
ss in free for ss in got_symbol
|
||
|
):
|
||
|
# sol depends on previously solved symbols
|
||
|
# then continue
|
||
|
continue
|
||
|
rnew = res.copy()
|
||
|
# put each solution in res and append the new result
|
||
|
# in the new result list (solution for symbol `s`)
|
||
|
# along with old results.
|
||
|
for k, v in res.items():
|
||
|
if isinstance(v, Expr) and isinstance(sol, Expr):
|
||
|
# if any unsolved symbol is present
|
||
|
# Then subs known value
|
||
|
rnew[k] = v.subs(sym, sol)
|
||
|
# and add this new solution
|
||
|
if sol in soln_imageset.keys():
|
||
|
# replace all lambda variables with 0.
|
||
|
imgst = soln_imageset[sol]
|
||
|
rnew[sym] = imgst.lamda(
|
||
|
*[0 for i in range(0, len(
|
||
|
imgst.lamda.variables))])
|
||
|
else:
|
||
|
rnew[sym] = sol
|
||
|
newresult, delete_res = _append_new_soln(
|
||
|
rnew, sym, sol, imgset_yes, soln_imageset,
|
||
|
original_imageset, newresult)
|
||
|
if delete_res:
|
||
|
# deleting the `res` (a soln) since it staisfies
|
||
|
# eq of `exclude` list
|
||
|
result.remove(res)
|
||
|
# solution got for sym
|
||
|
if not not_solvable:
|
||
|
got_symbol.add(sym)
|
||
|
# next time use this new soln
|
||
|
if newresult:
|
||
|
result = newresult
|
||
|
return result, total_solvest_call, total_conditionst
|
||
|
# end def _solve_using_know_values()
|
||
|
|
||
|
new_result_real, solve_call1, cnd_call1 = _solve_using_known_values(
|
||
|
old_result, solveset_real)
|
||
|
new_result_complex, solve_call2, cnd_call2 = _solve_using_known_values(
|
||
|
old_result, solveset_complex)
|
||
|
|
||
|
# If total_solveset_call is equal to total_conditionset
|
||
|
# then solveset failed to solve all of the equations.
|
||
|
# In this case we return a ConditionSet here.
|
||
|
total_conditionset += (cnd_call1 + cnd_call2)
|
||
|
total_solveset_call += (solve_call1 + solve_call2)
|
||
|
|
||
|
if total_conditionset == total_solveset_call and total_solveset_call != -1:
|
||
|
return _return_conditionset(eqs_in_better_order, all_symbols)
|
||
|
|
||
|
# don't keep duplicate solutions
|
||
|
filtered_complex = []
|
||
|
for i in list(new_result_complex):
|
||
|
for j in list(new_result_real):
|
||
|
if i.keys() != j.keys():
|
||
|
continue
|
||
|
if all(a.dummy_eq(b) for a, b in zip(i.values(), j.values()) \
|
||
|
if not (isinstance(a, int) and isinstance(b, int))):
|
||
|
break
|
||
|
else:
|
||
|
filtered_complex.append(i)
|
||
|
# overall result
|
||
|
result = new_result_real + filtered_complex
|
||
|
|
||
|
result_all_variables = []
|
||
|
result_infinite = []
|
||
|
for res in result:
|
||
|
if not res:
|
||
|
# means {None : None}
|
||
|
continue
|
||
|
# If length < len(all_symbols) means infinite soln.
|
||
|
# Some or all the soln is dependent on 1 symbol.
|
||
|
# eg. {x: y+2} then final soln {x: y+2, y: y}
|
||
|
if len(res) < len(all_symbols):
|
||
|
solved_symbols = res.keys()
|
||
|
unsolved = list(filter(
|
||
|
lambda x: x not in solved_symbols, all_symbols))
|
||
|
for unsolved_sym in unsolved:
|
||
|
res[unsolved_sym] = unsolved_sym
|
||
|
result_infinite.append(res)
|
||
|
if res not in result_all_variables:
|
||
|
result_all_variables.append(res)
|
||
|
|
||
|
if result_infinite:
|
||
|
# we have general soln
|
||
|
# eg : [{x: -1, y : 1}, {x : -y, y: y}] then
|
||
|
# return [{x : -y, y : y}]
|
||
|
result_all_variables = result_infinite
|
||
|
if intersections or complements:
|
||
|
result_all_variables = add_intersection_complement(
|
||
|
result_all_variables, intersections, complements)
|
||
|
|
||
|
# convert to ordered tuple
|
||
|
result = S.EmptySet
|
||
|
for r in result_all_variables:
|
||
|
temp = [r[symb] for symb in all_symbols]
|
||
|
result += FiniteSet(tuple(temp))
|
||
|
return result
|
||
|
# end of def substitution()
|
||
|
|
||
|
|
||
|
def _solveset_work(system, symbols):
|
||
|
soln = solveset(system[0], symbols[0])
|
||
|
if isinstance(soln, FiniteSet):
|
||
|
_soln = FiniteSet(*[(s,) for s in soln])
|
||
|
return _soln
|
||
|
else:
|
||
|
return FiniteSet(tuple(FiniteSet(soln)))
|
||
|
|
||
|
|
||
|
def _handle_positive_dimensional(polys, symbols, denominators):
|
||
|
from sympy.polys.polytools import groebner
|
||
|
# substitution method where new system is groebner basis of the system
|
||
|
_symbols = list(symbols)
|
||
|
_symbols.sort(key=default_sort_key)
|
||
|
basis = groebner(polys, _symbols, polys=True)
|
||
|
new_system = []
|
||
|
for poly_eq in basis:
|
||
|
new_system.append(poly_eq.as_expr())
|
||
|
result = [{}]
|
||
|
result = substitution(
|
||
|
new_system, symbols, result, [],
|
||
|
denominators)
|
||
|
return result
|
||
|
# end of def _handle_positive_dimensional()
|
||
|
|
||
|
|
||
|
def _handle_zero_dimensional(polys, symbols, system):
|
||
|
# solve 0 dimensional poly system using `solve_poly_system`
|
||
|
result = solve_poly_system(polys, *symbols)
|
||
|
# May be some extra soln is added because
|
||
|
# we used `unrad` in `_separate_poly_nonpoly`, so
|
||
|
# need to check and remove if it is not a soln.
|
||
|
result_update = S.EmptySet
|
||
|
for res in result:
|
||
|
dict_sym_value = dict(list(zip(symbols, res)))
|
||
|
if all(checksol(eq, dict_sym_value) for eq in system):
|
||
|
result_update += FiniteSet(res)
|
||
|
return result_update
|
||
|
# end of def _handle_zero_dimensional()
|
||
|
|
||
|
|
||
|
def _separate_poly_nonpoly(system, symbols):
|
||
|
polys = []
|
||
|
polys_expr = []
|
||
|
nonpolys = []
|
||
|
# unrad_changed stores a list of expressions containing
|
||
|
# radicals that were processed using unrad
|
||
|
# this is useful if solutions need to be checked later.
|
||
|
unrad_changed = []
|
||
|
denominators = set()
|
||
|
poly = None
|
||
|
for eq in system:
|
||
|
# Store denom expressions that contain symbols
|
||
|
denominators.update(_simple_dens(eq, symbols))
|
||
|
# Convert equality to expression
|
||
|
if isinstance(eq, Equality):
|
||
|
eq = eq.rewrite(Add)
|
||
|
# try to remove sqrt and rational power
|
||
|
without_radicals = unrad(simplify(eq), *symbols)
|
||
|
if without_radicals:
|
||
|
unrad_changed.append(eq)
|
||
|
eq_unrad, cov = without_radicals
|
||
|
if not cov:
|
||
|
eq = eq_unrad
|
||
|
if isinstance(eq, Expr):
|
||
|
eq = eq.as_numer_denom()[0]
|
||
|
poly = eq.as_poly(*symbols, extension=True)
|
||
|
elif simplify(eq).is_number:
|
||
|
continue
|
||
|
if poly is not None:
|
||
|
polys.append(poly)
|
||
|
polys_expr.append(poly.as_expr())
|
||
|
else:
|
||
|
nonpolys.append(eq)
|
||
|
return polys, polys_expr, nonpolys, denominators, unrad_changed
|
||
|
# end of def _separate_poly_nonpoly()
|
||
|
|
||
|
|
||
|
def _handle_poly(polys, symbols):
|
||
|
# _handle_poly(polys, symbols) -> (poly_sol, poly_eqs)
|
||
|
#
|
||
|
# We will return possible solution information to nonlinsolve as well as a
|
||
|
# new system of polynomial equations to be solved if we cannot solve
|
||
|
# everything directly here. The new system of polynomial equations will be
|
||
|
# a lex-order Groebner basis for the original system. The lex basis
|
||
|
# hopefully separate some of the variables and equations and give something
|
||
|
# easier for substitution to work with.
|
||
|
|
||
|
# The format for representing solution sets in nonlinsolve and substitution
|
||
|
# is a list of dicts. These are the special cases:
|
||
|
no_information = [{}] # No equations solved yet
|
||
|
no_solutions = [] # The system is inconsistent and has no solutions.
|
||
|
|
||
|
# If there is no need to attempt further solution of these equations then
|
||
|
# we return no equations:
|
||
|
no_equations = []
|
||
|
|
||
|
inexact = any(not p.domain.is_Exact for p in polys)
|
||
|
if inexact:
|
||
|
# The use of Groebner over RR is likely to result incorrectly in an
|
||
|
# inconsistent Groebner basis. So, convert any float coefficients to
|
||
|
# Rational before computing the Groebner basis.
|
||
|
polys = [poly(nsimplify(p, rational=True)) for p in polys]
|
||
|
|
||
|
# Compute a Groebner basis in grevlex order wrt the ordering given. We will
|
||
|
# try to convert this to lex order later. Usually it seems to be more
|
||
|
# efficient to compute a lex order basis by computing a grevlex basis and
|
||
|
# converting to lex with fglm.
|
||
|
basis = groebner(polys, symbols, order='grevlex', polys=False)
|
||
|
|
||
|
#
|
||
|
# No solutions (inconsistent equations)?
|
||
|
#
|
||
|
if 1 in basis:
|
||
|
|
||
|
# No solutions:
|
||
|
poly_sol = no_solutions
|
||
|
poly_eqs = no_equations
|
||
|
|
||
|
#
|
||
|
# Finite number of solutions (zero-dimensional case)
|
||
|
#
|
||
|
elif basis.is_zero_dimensional:
|
||
|
|
||
|
# Convert Groebner basis to lex ordering
|
||
|
basis = basis.fglm('lex')
|
||
|
|
||
|
# Convert polynomial coefficients back to float before calling
|
||
|
# solve_poly_system
|
||
|
if inexact:
|
||
|
basis = [nfloat(p) for p in basis]
|
||
|
|
||
|
# Solve the zero-dimensional case using solve_poly_system if possible.
|
||
|
# If some polynomials have factors that cannot be solved in radicals
|
||
|
# then this will fail. Using solve_poly_system(..., strict=True)
|
||
|
# ensures that we either get a complete solution set in radicals or
|
||
|
# UnsolvableFactorError will be raised.
|
||
|
try:
|
||
|
result = solve_poly_system(basis, *symbols, strict=True)
|
||
|
except UnsolvableFactorError:
|
||
|
# Failure... not fully solvable in radicals. Return the lex-order
|
||
|
# basis for substitution to handle.
|
||
|
poly_sol = no_information
|
||
|
poly_eqs = list(basis)
|
||
|
else:
|
||
|
# Success! We have a finite solution set and solve_poly_system has
|
||
|
# succeeded in finding all solutions. Return the solutions and also
|
||
|
# an empty list of remaining equations to be solved.
|
||
|
poly_sol = [dict(zip(symbols, res)) for res in result]
|
||
|
poly_eqs = no_equations
|
||
|
|
||
|
#
|
||
|
# Infinite families of solutions (positive-dimensional case)
|
||
|
#
|
||
|
else:
|
||
|
# In this case the grevlex basis cannot be converted to lex using the
|
||
|
# fglm method and also solve_poly_system cannot solve the equations. We
|
||
|
# would like to return a lex basis but since we can't use fglm we
|
||
|
# compute the lex basis directly here. The time required to recompute
|
||
|
# the basis is generally significantly less than the time required by
|
||
|
# substitution to solve the new system.
|
||
|
poly_sol = no_information
|
||
|
poly_eqs = list(groebner(polys, symbols, order='lex', polys=False))
|
||
|
|
||
|
if inexact:
|
||
|
poly_eqs = [nfloat(p) for p in poly_eqs]
|
||
|
|
||
|
return poly_sol, poly_eqs
|
||
|
|
||
|
|
||
|
def nonlinsolve(system, *symbols):
|
||
|
r"""
|
||
|
Solve system of $N$ nonlinear equations with $M$ variables, which means both
|
||
|
under and overdetermined systems are supported. Positive dimensional
|
||
|
system is also supported (A system with infinitely many solutions is said
|
||
|
to be positive-dimensional). In a positive dimensional system the solution will
|
||
|
be dependent on at least one symbol. Returns both real solution
|
||
|
and complex solution (if they exist).
|
||
|
|
||
|
Parameters
|
||
|
==========
|
||
|
|
||
|
system : list of equations
|
||
|
The target system of equations
|
||
|
symbols : list of Symbols
|
||
|
symbols should be given as a sequence eg. list
|
||
|
|
||
|
Returns
|
||
|
=======
|
||
|
|
||
|
A :class:`~.FiniteSet` of ordered tuple of values of `symbols` for which the `system`
|
||
|
has solution. Order of values in the tuple is same as symbols present in
|
||
|
the parameter `symbols`.
|
||
|
|
||
|
Please note that general :class:`~.FiniteSet` is unordered, the solution
|
||
|
returned here is not simply a :class:`~.FiniteSet` of solutions, rather it
|
||
|
is a :class:`~.FiniteSet` of ordered tuple, i.e. the first and only
|
||
|
argument to :class:`~.FiniteSet` is a tuple of solutions, which is
|
||
|
ordered, and, hence ,the returned solution is ordered.
|
||
|
|
||
|
Also note that solution could also have been returned as an ordered tuple,
|
||
|
FiniteSet is just a wrapper ``{}`` around the tuple. It has no other
|
||
|
significance except for the fact it is just used to maintain a consistent
|
||
|
output format throughout the solveset.
|
||
|
|
||
|
For the given set of equations, the respective input types
|
||
|
are given below:
|
||
|
|
||
|
.. math:: xy - 1 = 0
|
||
|
.. math:: 4x^2 + y^2 - 5 = 0
|
||
|
|
||
|
::
|
||
|
|
||
|
system = [x*y - 1, 4*x**2 + y**2 - 5]
|
||
|
symbols = [x, y]
|
||
|
|
||
|
Raises
|
||
|
======
|
||
|
|
||
|
ValueError
|
||
|
The input is not valid.
|
||
|
The symbols are not given.
|
||
|
AttributeError
|
||
|
The input symbols are not `Symbol` type.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import symbols, nonlinsolve
|
||
|
>>> x, y, z = symbols('x, y, z', real=True)
|
||
|
>>> nonlinsolve([x*y - 1, 4*x**2 + y**2 - 5], [x, y])
|
||
|
{(-1, -1), (-1/2, -2), (1/2, 2), (1, 1)}
|
||
|
|
||
|
1. Positive dimensional system and complements:
|
||
|
|
||
|
>>> from sympy import pprint
|
||
|
>>> from sympy.polys.polytools import is_zero_dimensional
|
||
|
>>> a, b, c, d = symbols('a, b, c, d', extended_real=True)
|
||
|
>>> eq1 = a + b + c + d
|
||
|
>>> eq2 = a*b + b*c + c*d + d*a
|
||
|
>>> eq3 = a*b*c + b*c*d + c*d*a + d*a*b
|
||
|
>>> eq4 = a*b*c*d - 1
|
||
|
>>> system = [eq1, eq2, eq3, eq4]
|
||
|
>>> is_zero_dimensional(system)
|
||
|
False
|
||
|
>>> pprint(nonlinsolve(system, [a, b, c, d]), use_unicode=False)
|
||
|
-1 1 1 -1
|
||
|
{(---, -d, -, {d} \ {0}), (-, -d, ---, {d} \ {0})}
|
||
|
d d d d
|
||
|
>>> nonlinsolve([(x+y)**2 - 4, x + y - 2], [x, y])
|
||
|
{(2 - y, y)}
|
||
|
|
||
|
2. If some of the equations are non-polynomial then `nonlinsolve`
|
||
|
will call the ``substitution`` function and return real and complex solutions,
|
||
|
if present.
|
||
|
|
||
|
>>> from sympy import exp, sin
|
||
|
>>> nonlinsolve([exp(x) - sin(y), y**2 - 4], [x, y])
|
||
|
{(ImageSet(Lambda(_n, I*(2*_n*pi + pi) + log(sin(2))), Integers), -2),
|
||
|
(ImageSet(Lambda(_n, 2*_n*I*pi + log(sin(2))), Integers), 2)}
|
||
|
|
||
|
3. If system is non-linear polynomial and zero-dimensional then it
|
||
|
returns both solution (real and complex solutions, if present) using
|
||
|
:func:`~.solve_poly_system`:
|
||
|
|
||
|
>>> from sympy import sqrt
|
||
|
>>> nonlinsolve([x**2 - 2*y**2 -2, x*y - 2], [x, y])
|
||
|
{(-2, -1), (2, 1), (-sqrt(2)*I, sqrt(2)*I), (sqrt(2)*I, -sqrt(2)*I)}
|
||
|
|
||
|
4. ``nonlinsolve`` can solve some linear (zero or positive dimensional)
|
||
|
system (because it uses the :func:`sympy.polys.polytools.groebner` function to get the
|
||
|
groebner basis and then uses the ``substitution`` function basis as the
|
||
|
new `system`). But it is not recommended to solve linear system using
|
||
|
``nonlinsolve``, because :func:`~.linsolve` is better for general linear systems.
|
||
|
|
||
|
>>> nonlinsolve([x + 2*y -z - 3, x - y - 4*z + 9, y + z - 4], [x, y, z])
|
||
|
{(3*z - 5, 4 - z, z)}
|
||
|
|
||
|
5. System having polynomial equations and only real solution is
|
||
|
solved using :func:`~.solve_poly_system`:
|
||
|
|
||
|
>>> e1 = sqrt(x**2 + y**2) - 10
|
||
|
>>> e2 = sqrt(y**2 + (-x + 10)**2) - 3
|
||
|
>>> nonlinsolve((e1, e2), (x, y))
|
||
|
{(191/20, -3*sqrt(391)/20), (191/20, 3*sqrt(391)/20)}
|
||
|
>>> nonlinsolve([x**2 + 2/y - 2, x + y - 3], [x, y])
|
||
|
{(1, 2), (1 - sqrt(5), 2 + sqrt(5)), (1 + sqrt(5), 2 - sqrt(5))}
|
||
|
>>> nonlinsolve([x**2 + 2/y - 2, x + y - 3], [y, x])
|
||
|
{(2, 1), (2 - sqrt(5), 1 + sqrt(5)), (2 + sqrt(5), 1 - sqrt(5))}
|
||
|
|
||
|
6. It is better to use symbols instead of trigonometric functions or
|
||
|
:class:`~.Function`. For example, replace $\sin(x)$ with a symbol, replace
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$f(x)$ with a symbol and so on. Get a solution from ``nonlinsolve`` and then
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use :func:`~.solveset` to get the value of $x$.
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How nonlinsolve is better than old solver ``_solve_system`` :
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=============================================================
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|
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1. A positive dimensional system solver: nonlinsolve can return
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solution for positive dimensional system. It finds the
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|
Groebner Basis of the positive dimensional system(calling it as
|
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|
basis) then we can start solving equation(having least number of
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|
variable first in the basis) using solveset and substituting that
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solved solutions into other equation(of basis) to get solution in
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terms of minimum variables. Here the important thing is how we
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are substituting the known values and in which equations.
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2. Real and complex solutions: nonlinsolve returns both real
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and complex solution. If all the equations in the system are polynomial
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then using :func:`~.solve_poly_system` both real and complex solution is returned.
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If all the equations in the system are not polynomial equation then goes to
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``substitution`` method with this polynomial and non polynomial equation(s),
|
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|
to solve for unsolved variables. Here to solve for particular variable
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|
solveset_real and solveset_complex is used. For both real and complex
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solution ``_solve_using_known_values`` is used inside ``substitution``
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(``substitution`` will be called when any non-polynomial equation is present).
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If a solution is valid its general solution is added to the final result.
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|
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3. :class:`~.Complement` and :class:`~.Intersection` will be added:
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nonlinsolve maintains dict for complements and intersections. If solveset
|
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|
find complements or/and intersections with any interval or set during the
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execution of ``substitution`` function, then complement or/and
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intersection for that variable is added before returning final solution.
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|
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|
"""
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if not system:
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return S.EmptySet
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|
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|
if not symbols:
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|
msg = ('Symbols must be given, for which solution of the '
|
||
|
'system is to be found.')
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|
raise ValueError(filldedent(msg))
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|
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|
if hasattr(symbols[0], '__iter__'):
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|
symbols = symbols[0]
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|
|
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|
if not is_sequence(symbols) or not symbols:
|
||
|
msg = ('Symbols must be given, for which solution of the '
|
||
|
'system is to be found.')
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|
raise IndexError(filldedent(msg))
|
||
|
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symbols = list(map(_sympify, symbols))
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|
system, symbols, swap = recast_to_symbols(system, symbols)
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|
if swap:
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|
soln = nonlinsolve(system, symbols)
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|
return FiniteSet(*[tuple(i.xreplace(swap) for i in s) for s in soln])
|
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|
|
||
|
if len(system) == 1 and len(symbols) == 1:
|
||
|
return _solveset_work(system, symbols)
|
||
|
|
||
|
# main code of def nonlinsolve() starts from here
|
||
|
|
||
|
polys, polys_expr, nonpolys, denominators, unrad_changed = \
|
||
|
_separate_poly_nonpoly(system, symbols)
|
||
|
|
||
|
poly_eqs = []
|
||
|
poly_sol = [{}]
|
||
|
|
||
|
if polys:
|
||
|
poly_sol, poly_eqs = _handle_poly(polys, symbols)
|
||
|
if poly_sol and poly_sol[0]:
|
||
|
poly_syms = set().union(*(eq.free_symbols for eq in polys))
|
||
|
unrad_syms = set().union(*(eq.free_symbols for eq in unrad_changed))
|
||
|
if unrad_syms == poly_syms and unrad_changed:
|
||
|
# if all the symbols have been solved by _handle_poly
|
||
|
# and unrad has been used then check solutions
|
||
|
poly_sol = [sol for sol in poly_sol if checksol(unrad_changed, sol)]
|
||
|
|
||
|
# Collect together the unsolved polynomials with the non-polynomial
|
||
|
# equations.
|
||
|
remaining = poly_eqs + nonpolys
|
||
|
|
||
|
# to_tuple converts a solution dictionary to a tuple containing the
|
||
|
# value for each symbol
|
||
|
to_tuple = lambda sol: tuple(sol[s] for s in symbols)
|
||
|
|
||
|
if not remaining:
|
||
|
# If there is nothing left to solve then return the solution from
|
||
|
# solve_poly_system directly.
|
||
|
return FiniteSet(*map(to_tuple, poly_sol))
|
||
|
else:
|
||
|
# Here we handle:
|
||
|
#
|
||
|
# 1. The Groebner basis if solve_poly_system failed.
|
||
|
# 2. The Groebner basis in the positive-dimensional case.
|
||
|
# 3. Any non-polynomial equations
|
||
|
#
|
||
|
# If solve_poly_system did succeed then we pass those solutions in as
|
||
|
# preliminary results.
|
||
|
subs_res = substitution(remaining, symbols, result=poly_sol, exclude=denominators)
|
||
|
|
||
|
if not isinstance(subs_res, FiniteSet):
|
||
|
return subs_res
|
||
|
|
||
|
# check solutions produced by substitution. Currently, checking is done for
|
||
|
# only those solutions which have non-Set variable values.
|
||
|
if unrad_changed:
|
||
|
result = [dict(zip(symbols, sol)) for sol in subs_res.args]
|
||
|
correct_sols = [sol for sol in result if any(isinstance(v, Set) for v in sol)
|
||
|
or checksol(unrad_changed, sol) != False]
|
||
|
return FiniteSet(*map(to_tuple, correct_sols))
|
||
|
else:
|
||
|
return subs_res
|