510 lines
18 KiB
Python
510 lines
18 KiB
Python
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from sympy.core.add import Add
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from sympy.core.exprtools import factor_terms
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from sympy.core.function import expand_log, _mexpand
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from sympy.core.power import Pow
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from sympy.core.singleton import S
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from sympy.core.sorting import ordered
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from sympy.core.symbol import Dummy
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from sympy.functions.elementary.exponential import (LambertW, exp, log)
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from sympy.functions.elementary.miscellaneous import root
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from sympy.polys.polyroots import roots
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from sympy.polys.polytools import Poly, factor
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from sympy.simplify.simplify import separatevars
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from sympy.simplify.radsimp import collect
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from sympy.simplify.simplify import powsimp
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from sympy.solvers.solvers import solve, _invert
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from sympy.utilities.iterables import uniq
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def _filtered_gens(poly, symbol):
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"""process the generators of ``poly``, returning the set of generators that
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have ``symbol``. If there are two generators that are inverses of each other,
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prefer the one that has no denominator.
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Examples
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========
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>>> from sympy.solvers.bivariate import _filtered_gens
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>>> from sympy import Poly, exp
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>>> from sympy.abc import x
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>>> _filtered_gens(Poly(x + 1/x + exp(x)), x)
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{x, exp(x)}
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"""
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# TODO it would be good to pick the smallest divisible power
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# instead of the base for something like x**4 + x**2 -->
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# return x**2 not x
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gens = {g for g in poly.gens if symbol in g.free_symbols}
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for g in list(gens):
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ag = 1/g
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if g in gens and ag in gens:
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if ag.as_numer_denom()[1] is not S.One:
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g = ag
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gens.remove(g)
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return gens
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def _mostfunc(lhs, func, X=None):
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"""Returns the term in lhs which contains the most of the
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func-type things e.g. log(log(x)) wins over log(x) if both terms appear.
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``func`` can be a function (exp, log, etc...) or any other SymPy object,
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like Pow.
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If ``X`` is not ``None``, then the function returns the term composed with the
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most ``func`` having the specified variable.
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Examples
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========
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>>> from sympy.solvers.bivariate import _mostfunc
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>>> from sympy import exp
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>>> from sympy.abc import x, y
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>>> _mostfunc(exp(x) + exp(exp(x) + 2), exp)
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exp(exp(x) + 2)
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>>> _mostfunc(exp(x) + exp(exp(y) + 2), exp)
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exp(exp(y) + 2)
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>>> _mostfunc(exp(x) + exp(exp(y) + 2), exp, x)
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exp(x)
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>>> _mostfunc(x, exp, x) is None
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True
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>>> _mostfunc(exp(x) + exp(x*y), exp, x)
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exp(x)
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"""
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fterms = [tmp for tmp in lhs.atoms(func) if (not X or
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X.is_Symbol and X in tmp.free_symbols or
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not X.is_Symbol and tmp.has(X))]
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if len(fterms) == 1:
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return fterms[0]
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elif fterms:
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return max(list(ordered(fterms)), key=lambda x: x.count(func))
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return None
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def _linab(arg, symbol):
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"""Return ``a, b, X`` assuming ``arg`` can be written as ``a*X + b``
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where ``X`` is a symbol-dependent factor and ``a`` and ``b`` are
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independent of ``symbol``.
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Examples
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========
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>>> from sympy.solvers.bivariate import _linab
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>>> from sympy.abc import x, y
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>>> from sympy import exp, S
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>>> _linab(S(2), x)
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(2, 0, 1)
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>>> _linab(2*x, x)
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(2, 0, x)
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>>> _linab(y + y*x + 2*x, x)
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(y + 2, y, x)
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>>> _linab(3 + 2*exp(x), x)
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(2, 3, exp(x))
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"""
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arg = factor_terms(arg.expand())
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ind, dep = arg.as_independent(symbol)
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if arg.is_Mul and dep.is_Add:
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a, b, x = _linab(dep, symbol)
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return ind*a, ind*b, x
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if not arg.is_Add:
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b = 0
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a, x = ind, dep
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else:
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b = ind
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a, x = separatevars(dep).as_independent(symbol, as_Add=False)
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if x.could_extract_minus_sign():
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a = -a
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x = -x
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return a, b, x
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def _lambert(eq, x):
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"""
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Given an expression assumed to be in the form
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``F(X, a..f) = a*log(b*X + c) + d*X + f = 0``
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where X = g(x) and x = g^-1(X), return the Lambert solution,
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``x = g^-1(-c/b + (a/d)*W(d/(a*b)*exp(c*d/a/b)*exp(-f/a)))``.
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"""
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eq = _mexpand(expand_log(eq))
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mainlog = _mostfunc(eq, log, x)
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if not mainlog:
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return [] # violated assumptions
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other = eq.subs(mainlog, 0)
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if isinstance(-other, log):
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eq = (eq - other).subs(mainlog, mainlog.args[0])
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mainlog = mainlog.args[0]
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if not isinstance(mainlog, log):
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return [] # violated assumptions
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other = -(-other).args[0]
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eq += other
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if x not in other.free_symbols:
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return [] # violated assumptions
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d, f, X2 = _linab(other, x)
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logterm = collect(eq - other, mainlog)
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a = logterm.as_coefficient(mainlog)
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if a is None or x in a.free_symbols:
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return [] # violated assumptions
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logarg = mainlog.args[0]
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b, c, X1 = _linab(logarg, x)
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if X1 != X2:
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return [] # violated assumptions
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# invert the generator X1 so we have x(u)
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u = Dummy('rhs')
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xusolns = solve(X1 - u, x)
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# There are infinitely many branches for LambertW
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# but only branches for k = -1 and 0 might be real. The k = 0
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# branch is real and the k = -1 branch is real if the LambertW argumen
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# in in range [-1/e, 0]. Since `solve` does not return infinite
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# solutions we will only include the -1 branch if it tests as real.
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# Otherwise, inclusion of any LambertW in the solution indicates to
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# the user that there are imaginary solutions corresponding to
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# different k values.
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lambert_real_branches = [-1, 0]
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sol = []
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# solution of the given Lambert equation is like
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# sol = -c/b + (a/d)*LambertW(arg, k),
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# where arg = d/(a*b)*exp((c*d-b*f)/a/b) and k in lambert_real_branches.
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# Instead of considering the single arg, `d/(a*b)*exp((c*d-b*f)/a/b)`,
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# the individual `p` roots obtained when writing `exp((c*d-b*f)/a/b)`
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# as `exp(A/p) = exp(A)**(1/p)`, where `p` is an Integer, are used.
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# calculating args for LambertW
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num, den = ((c*d-b*f)/a/b).as_numer_denom()
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p, den = den.as_coeff_Mul()
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e = exp(num/den)
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t = Dummy('t')
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args = [d/(a*b)*t for t in roots(t**p - e, t).keys()]
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# calculating solutions from args
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for arg in args:
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for k in lambert_real_branches:
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w = LambertW(arg, k)
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if k and not w.is_real:
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continue
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rhs = -c/b + (a/d)*w
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sol.extend(xu.subs(u, rhs) for xu in xusolns)
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return sol
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def _solve_lambert(f, symbol, gens):
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"""Return solution to ``f`` if it is a Lambert-type expression
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else raise NotImplementedError.
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For ``f(X, a..f) = a*log(b*X + c) + d*X - f = 0`` the solution
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for ``X`` is ``X = -c/b + (a/d)*W(d/(a*b)*exp(c*d/a/b)*exp(f/a))``.
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There are a variety of forms for `f(X, a..f)` as enumerated below:
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1a1)
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if B**B = R for R not in [0, 1] (since those cases would already
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be solved before getting here) then log of both sides gives
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log(B) + log(log(B)) = log(log(R)) and
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X = log(B), a = 1, b = 1, c = 0, d = 1, f = log(log(R))
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1a2)
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if B*(b*log(B) + c)**a = R then log of both sides gives
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log(B) + a*log(b*log(B) + c) = log(R) and
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X = log(B), d=1, f=log(R)
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1b)
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if a*log(b*B + c) + d*B = R and
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X = B, f = R
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2a)
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if (b*B + c)*exp(d*B + g) = R then log of both sides gives
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log(b*B + c) + d*B + g = log(R) and
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X = B, a = 1, f = log(R) - g
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2b)
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if g*exp(d*B + h) - b*B = c then the log form is
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log(g) + d*B + h - log(b*B + c) = 0 and
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X = B, a = -1, f = -h - log(g)
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3)
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if d*p**(a*B + g) - b*B = c then the log form is
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log(d) + (a*B + g)*log(p) - log(b*B + c) = 0 and
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X = B, a = -1, d = a*log(p), f = -log(d) - g*log(p)
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"""
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def _solve_even_degree_expr(expr, t, symbol):
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"""Return the unique solutions of equations derived from
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``expr`` by replacing ``t`` with ``+/- symbol``.
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Parameters
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==========
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expr : Expr
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The expression which includes a dummy variable t to be
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replaced with +symbol and -symbol.
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symbol : Symbol
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The symbol for which a solution is being sought.
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Returns
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=======
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List of unique solution of the two equations generated by
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replacing ``t`` with positive and negative ``symbol``.
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Notes
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=====
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If ``expr = 2*log(t) + x/2` then solutions for
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``2*log(x) + x/2 = 0`` and ``2*log(-x) + x/2 = 0`` are
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returned by this function. Though this may seem
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counter-intuitive, one must note that the ``expr`` being
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solved here has been derived from a different expression. For
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an expression like ``eq = x**2*g(x) = 1``, if we take the
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log of both sides we obtain ``log(x**2) + log(g(x)) = 0``. If
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x is positive then this simplifies to
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``2*log(x) + log(g(x)) = 0``; the Lambert-solving routines will
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return solutions for this, but we must also consider the
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solutions for ``2*log(-x) + log(g(x))`` since those must also
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be a solution of ``eq`` which has the same value when the ``x``
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in ``x**2`` is negated. If `g(x)` does not have even powers of
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symbol then we do not want to replace the ``x`` there with
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``-x``. So the role of the ``t`` in the expression received by
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this function is to mark where ``+/-x`` should be inserted
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before obtaining the Lambert solutions.
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"""
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nlhs, plhs = [
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expr.xreplace({t: sgn*symbol}) for sgn in (-1, 1)]
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sols = _solve_lambert(nlhs, symbol, gens)
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if plhs != nlhs:
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sols.extend(_solve_lambert(plhs, symbol, gens))
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# uniq is needed for a case like
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# 2*log(t) - log(-z**2) + log(z + log(x) + log(z))
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# where substituting t with +/-x gives all the same solution;
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# uniq, rather than list(set()), is used to maintain canonical
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# order
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return list(uniq(sols))
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nrhs, lhs = f.as_independent(symbol, as_Add=True)
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rhs = -nrhs
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lamcheck = [tmp for tmp in gens
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if (tmp.func in [exp, log] or
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(tmp.is_Pow and symbol in tmp.exp.free_symbols))]
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if not lamcheck:
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raise NotImplementedError()
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if lhs.is_Add or lhs.is_Mul:
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# replacing all even_degrees of symbol with dummy variable t
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# since these will need special handling; non-Add/Mul do not
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# need this handling
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t = Dummy('t', **symbol.assumptions0)
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lhs = lhs.replace(
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lambda i: # find symbol**even
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i.is_Pow and i.base == symbol and i.exp.is_even,
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lambda i: # replace t**even
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t**i.exp)
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if lhs.is_Add and lhs.has(t):
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t_indep = lhs.subs(t, 0)
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t_term = lhs - t_indep
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_rhs = rhs - t_indep
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if not t_term.is_Add and _rhs and not (
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t_term.has(S.ComplexInfinity, S.NaN)):
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eq = expand_log(log(t_term) - log(_rhs))
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return _solve_even_degree_expr(eq, t, symbol)
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elif lhs.is_Mul and rhs:
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# this needs to happen whether t is present or not
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lhs = expand_log(log(lhs), force=True)
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rhs = log(rhs)
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if lhs.has(t) and lhs.is_Add:
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# it expanded from Mul to Add
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eq = lhs - rhs
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return _solve_even_degree_expr(eq, t, symbol)
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# restore symbol in lhs
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lhs = lhs.xreplace({t: symbol})
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lhs = powsimp(factor(lhs, deep=True))
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# make sure we have inverted as completely as possible
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r = Dummy()
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i, lhs = _invert(lhs - r, symbol)
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rhs = i.xreplace({r: rhs})
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# For the first forms:
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#
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# 1a1) B**B = R will arrive here as B*log(B) = log(R)
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# lhs is Mul so take log of both sides:
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# log(B) + log(log(B)) = log(log(R))
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# 1a2) B*(b*log(B) + c)**a = R will arrive unchanged so
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# lhs is Mul, so take log of both sides:
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# log(B) + a*log(b*log(B) + c) = log(R)
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# 1b) d*log(a*B + b) + c*B = R will arrive unchanged so
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# lhs is Add, so isolate c*B and expand log of both sides:
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# log(c) + log(B) = log(R - d*log(a*B + b))
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soln = []
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if not soln:
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mainlog = _mostfunc(lhs, log, symbol)
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if mainlog:
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if lhs.is_Mul and rhs != 0:
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soln = _lambert(log(lhs) - log(rhs), symbol)
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elif lhs.is_Add:
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other = lhs.subs(mainlog, 0)
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if other and not other.is_Add and [
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tmp for tmp in other.atoms(Pow)
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if symbol in tmp.free_symbols]:
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if not rhs:
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diff = log(other) - log(other - lhs)
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else:
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diff = log(lhs - other) - log(rhs - other)
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soln = _lambert(expand_log(diff), symbol)
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else:
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#it's ready to go
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soln = _lambert(lhs - rhs, symbol)
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# For the next forms,
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#
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# collect on main exp
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# 2a) (b*B + c)*exp(d*B + g) = R
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# lhs is mul, so take log of both sides:
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# log(b*B + c) + d*B = log(R) - g
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# 2b) g*exp(d*B + h) - b*B = R
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# lhs is add, so add b*B to both sides,
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# take the log of both sides and rearrange to give
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# log(R + b*B) - d*B = log(g) + h
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if not soln:
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mainexp = _mostfunc(lhs, exp, symbol)
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if mainexp:
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lhs = collect(lhs, mainexp)
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if lhs.is_Mul and rhs != 0:
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soln = _lambert(expand_log(log(lhs) - log(rhs)), symbol)
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elif lhs.is_Add:
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# move all but mainexp-containing term to rhs
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other = lhs.subs(mainexp, 0)
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mainterm = lhs - other
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rhs = rhs - other
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||
|
if (mainterm.could_extract_minus_sign() and
|
||
|
rhs.could_extract_minus_sign()):
|
||
|
mainterm *= -1
|
||
|
rhs *= -1
|
||
|
diff = log(mainterm) - log(rhs)
|
||
|
soln = _lambert(expand_log(diff), symbol)
|
||
|
|
||
|
# For the last form:
|
||
|
#
|
||
|
# 3) d*p**(a*B + g) - b*B = c
|
||
|
# collect on main pow, add b*B to both sides,
|
||
|
# take log of both sides and rearrange to give
|
||
|
# a*B*log(p) - log(b*B + c) = -log(d) - g*log(p)
|
||
|
if not soln:
|
||
|
mainpow = _mostfunc(lhs, Pow, symbol)
|
||
|
if mainpow and symbol in mainpow.exp.free_symbols:
|
||
|
lhs = collect(lhs, mainpow)
|
||
|
if lhs.is_Mul and rhs != 0:
|
||
|
# b*B = 0
|
||
|
soln = _lambert(expand_log(log(lhs) - log(rhs)), symbol)
|
||
|
elif lhs.is_Add:
|
||
|
# move all but mainpow-containing term to rhs
|
||
|
other = lhs.subs(mainpow, 0)
|
||
|
mainterm = lhs - other
|
||
|
rhs = rhs - other
|
||
|
diff = log(mainterm) - log(rhs)
|
||
|
soln = _lambert(expand_log(diff), symbol)
|
||
|
|
||
|
if not soln:
|
||
|
raise NotImplementedError('%s does not appear to have a solution in '
|
||
|
'terms of LambertW' % f)
|
||
|
|
||
|
return list(ordered(soln))
|
||
|
|
||
|
|
||
|
def bivariate_type(f, x, y, *, first=True):
|
||
|
"""Given an expression, f, 3 tests will be done to see what type
|
||
|
of composite bivariate it might be, options for u(x, y) are::
|
||
|
|
||
|
x*y
|
||
|
x+y
|
||
|
x*y+x
|
||
|
x*y+y
|
||
|
|
||
|
If it matches one of these types, ``u(x, y)``, ``P(u)`` and dummy
|
||
|
variable ``u`` will be returned. Solving ``P(u)`` for ``u`` and
|
||
|
equating the solutions to ``u(x, y)`` and then solving for ``x`` or
|
||
|
``y`` is equivalent to solving the original expression for ``x`` or
|
||
|
``y``. If ``x`` and ``y`` represent two functions in the same
|
||
|
variable, e.g. ``x = g(t)`` and ``y = h(t)``, then if ``u(x, y) - p``
|
||
|
can be solved for ``t`` then these represent the solutions to
|
||
|
``P(u) = 0`` when ``p`` are the solutions of ``P(u) = 0``.
|
||
|
|
||
|
Only positive values of ``u`` are considered.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy import solve
|
||
|
>>> from sympy.solvers.bivariate import bivariate_type
|
||
|
>>> from sympy.abc import x, y
|
||
|
>>> eq = (x**2 - 3).subs(x, x + y)
|
||
|
>>> bivariate_type(eq, x, y)
|
||
|
(x + y, _u**2 - 3, _u)
|
||
|
>>> uxy, pu, u = _
|
||
|
>>> usol = solve(pu, u); usol
|
||
|
[sqrt(3)]
|
||
|
>>> [solve(uxy - s) for s in solve(pu, u)]
|
||
|
[[{x: -y + sqrt(3)}]]
|
||
|
>>> all(eq.subs(s).equals(0) for sol in _ for s in sol)
|
||
|
True
|
||
|
|
||
|
"""
|
||
|
|
||
|
u = Dummy('u', positive=True)
|
||
|
|
||
|
if first:
|
||
|
p = Poly(f, x, y)
|
||
|
f = p.as_expr()
|
||
|
_x = Dummy()
|
||
|
_y = Dummy()
|
||
|
rv = bivariate_type(Poly(f.subs({x: _x, y: _y}), _x, _y), _x, _y, first=False)
|
||
|
if rv:
|
||
|
reps = {_x: x, _y: y}
|
||
|
return rv[0].xreplace(reps), rv[1].xreplace(reps), rv[2]
|
||
|
return
|
||
|
|
||
|
p = f
|
||
|
f = p.as_expr()
|
||
|
|
||
|
# f(x*y)
|
||
|
args = Add.make_args(p.as_expr())
|
||
|
new = []
|
||
|
for a in args:
|
||
|
a = _mexpand(a.subs(x, u/y))
|
||
|
free = a.free_symbols
|
||
|
if x in free or y in free:
|
||
|
break
|
||
|
new.append(a)
|
||
|
else:
|
||
|
return x*y, Add(*new), u
|
||
|
|
||
|
def ok(f, v, c):
|
||
|
new = _mexpand(f.subs(v, c))
|
||
|
free = new.free_symbols
|
||
|
return None if (x in free or y in free) else new
|
||
|
|
||
|
# f(a*x + b*y)
|
||
|
new = []
|
||
|
d = p.degree(x)
|
||
|
if p.degree(y) == d:
|
||
|
a = root(p.coeff_monomial(x**d), d)
|
||
|
b = root(p.coeff_monomial(y**d), d)
|
||
|
new = ok(f, x, (u - b*y)/a)
|
||
|
if new is not None:
|
||
|
return a*x + b*y, new, u
|
||
|
|
||
|
# f(a*x*y + b*y)
|
||
|
new = []
|
||
|
d = p.degree(x)
|
||
|
if p.degree(y) == d:
|
||
|
for itry in range(2):
|
||
|
a = root(p.coeff_monomial(x**d*y**d), d)
|
||
|
b = root(p.coeff_monomial(y**d), d)
|
||
|
new = ok(f, x, (u - b*y)/a/y)
|
||
|
if new is not None:
|
||
|
return a*x*y + b*y, new, u
|
||
|
x, y = y, x
|