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353 lines
11 KiB
353 lines
11 KiB
from sympy.testing.pytest import raises, XFAIL
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from sympy.external import import_module
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from sympy.concrete.products import Product
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from sympy.concrete.summations import Sum
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from sympy.core.add import Add
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from sympy.core.function import (Derivative, Function)
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from sympy.core.mul import Mul
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from sympy.core.numbers import (E, oo)
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from sympy.core.power import Pow
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from sympy.core.relational import (GreaterThan, LessThan, StrictGreaterThan, StrictLessThan, Unequality)
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from sympy.core.symbol import Symbol
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from sympy.functions.combinatorial.factorials import (binomial, factorial)
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from sympy.functions.elementary.complexes import (Abs, conjugate)
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from sympy.functions.elementary.exponential import (exp, log)
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from sympy.functions.elementary.integers import (ceiling, floor)
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from sympy.functions.elementary.miscellaneous import (root, sqrt)
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from sympy.functions.elementary.trigonometric import (asin, cos, csc, sec, sin, tan)
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from sympy.integrals.integrals import Integral
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from sympy.series.limits import Limit
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from sympy.core.relational import Eq, Ne, Lt, Le, Gt, Ge
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from sympy.physics.quantum.state import Bra, Ket
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from sympy.abc import x, y, z, a, b, c, t, k, n
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antlr4 = import_module("antlr4")
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# disable tests if antlr4-python3-runtime is not present
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if not antlr4:
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disabled = True
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theta = Symbol('theta')
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f = Function('f')
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# shorthand definitions
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def _Add(a, b):
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return Add(a, b, evaluate=False)
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def _Mul(a, b):
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return Mul(a, b, evaluate=False)
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def _Pow(a, b):
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return Pow(a, b, evaluate=False)
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def _Sqrt(a):
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return sqrt(a, evaluate=False)
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def _Conjugate(a):
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return conjugate(a, evaluate=False)
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def _Abs(a):
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return Abs(a, evaluate=False)
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def _factorial(a):
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return factorial(a, evaluate=False)
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def _exp(a):
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return exp(a, evaluate=False)
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def _log(a, b):
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return log(a, b, evaluate=False)
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def _binomial(n, k):
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return binomial(n, k, evaluate=False)
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def test_import():
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from sympy.parsing.latex._build_latex_antlr import (
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build_parser,
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check_antlr_version,
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dir_latex_antlr
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)
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# XXX: It would be better to come up with a test for these...
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del build_parser, check_antlr_version, dir_latex_antlr
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# These LaTeX strings should parse to the corresponding SymPy expression
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GOOD_PAIRS = [
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(r"0", 0),
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(r"1", 1),
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(r"-3.14", -3.14),
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(r"(-7.13)(1.5)", _Mul(-7.13, 1.5)),
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(r"x", x),
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(r"2x", 2*x),
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(r"x^2", x**2),
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(r"x^\frac{1}{2}", _Pow(x, _Pow(2, -1))),
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(r"x^{3 + 1}", x**_Add(3, 1)),
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(r"-c", -c),
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(r"a \cdot b", a * b),
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(r"a / b", a / b),
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(r"a \div b", a / b),
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(r"a + b", a + b),
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(r"a + b - a", _Add(a+b, -a)),
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(r"a^2 + b^2 = c^2", Eq(a**2 + b**2, c**2)),
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(r"(x + y) z", _Mul(_Add(x, y), z)),
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(r"a'b+ab'", _Add(_Mul(Symbol("a'"), b), _Mul(a, Symbol("b'")))),
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(r"y''_1", Symbol("y_{1}''")),
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(r"y_1''", Symbol("y_{1}''")),
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(r"\left(x + y\right) z", _Mul(_Add(x, y), z)),
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(r"\left( x + y\right ) z", _Mul(_Add(x, y), z)),
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(r"\left( x + y\right ) z", _Mul(_Add(x, y), z)),
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(r"\left[x + y\right] z", _Mul(_Add(x, y), z)),
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(r"\left\{x + y\right\} z", _Mul(_Add(x, y), z)),
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(r"1+1", _Add(1, 1)),
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(r"0+1", _Add(0, 1)),
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(r"1*2", _Mul(1, 2)),
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(r"0*1", _Mul(0, 1)),
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(r"1 \times 2 ", _Mul(1, 2)),
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(r"x = y", Eq(x, y)),
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(r"x \neq y", Ne(x, y)),
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(r"x < y", Lt(x, y)),
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(r"x > y", Gt(x, y)),
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(r"x \leq y", Le(x, y)),
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(r"x \geq y", Ge(x, y)),
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(r"x \le y", Le(x, y)),
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(r"x \ge y", Ge(x, y)),
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(r"\lfloor x \rfloor", floor(x)),
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(r"\lceil x \rceil", ceiling(x)),
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(r"\langle x |", Bra('x')),
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(r"| x \rangle", Ket('x')),
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(r"\sin \theta", sin(theta)),
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(r"\sin(\theta)", sin(theta)),
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(r"\sin^{-1} a", asin(a)),
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(r"\sin a \cos b", _Mul(sin(a), cos(b))),
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(r"\sin \cos \theta", sin(cos(theta))),
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(r"\sin(\cos \theta)", sin(cos(theta))),
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(r"\frac{a}{b}", a / b),
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(r"\dfrac{a}{b}", a / b),
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(r"\tfrac{a}{b}", a / b),
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(r"\frac12", _Pow(2, -1)),
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(r"\frac12y", _Mul(_Pow(2, -1), y)),
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(r"\frac1234", _Mul(_Pow(2, -1), 34)),
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(r"\frac2{3}", _Mul(2, _Pow(3, -1))),
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(r"\frac{\sin{x}}2", _Mul(sin(x), _Pow(2, -1))),
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(r"\frac{a + b}{c}", _Mul(a + b, _Pow(c, -1))),
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(r"\frac{7}{3}", _Mul(7, _Pow(3, -1))),
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(r"(\csc x)(\sec y)", csc(x)*sec(y)),
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(r"\lim_{x \to 3} a", Limit(a, x, 3, dir='+-')),
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(r"\lim_{x \rightarrow 3} a", Limit(a, x, 3, dir='+-')),
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(r"\lim_{x \Rightarrow 3} a", Limit(a, x, 3, dir='+-')),
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(r"\lim_{x \longrightarrow 3} a", Limit(a, x, 3, dir='+-')),
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(r"\lim_{x \Longrightarrow 3} a", Limit(a, x, 3, dir='+-')),
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(r"\lim_{x \to 3^{+}} a", Limit(a, x, 3, dir='+')),
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(r"\lim_{x \to 3^{-}} a", Limit(a, x, 3, dir='-')),
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(r"\lim_{x \to 3^+} a", Limit(a, x, 3, dir='+')),
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(r"\lim_{x \to 3^-} a", Limit(a, x, 3, dir='-')),
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(r"\infty", oo),
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(r"\lim_{x \to \infty} \frac{1}{x}", Limit(_Pow(x, -1), x, oo)),
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(r"\frac{d}{dx} x", Derivative(x, x)),
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(r"\frac{d}{dt} x", Derivative(x, t)),
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(r"f(x)", f(x)),
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(r"f(x, y)", f(x, y)),
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(r"f(x, y, z)", f(x, y, z)),
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(r"f'_1(x)", Function("f_{1}'")(x)),
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(r"f_{1}''(x+y)", Function("f_{1}''")(x+y)),
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(r"\frac{d f(x)}{dx}", Derivative(f(x), x)),
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(r"\frac{d\theta(x)}{dx}", Derivative(Function('theta')(x), x)),
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(r"x \neq y", Unequality(x, y)),
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(r"|x|", _Abs(x)),
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(r"||x||", _Abs(Abs(x))),
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(r"|x||y|", _Abs(x)*_Abs(y)),
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(r"||x||y||", _Abs(_Abs(x)*_Abs(y))),
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(r"\pi^{|xy|}", Symbol('pi')**_Abs(x*y)),
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(r"\int x dx", Integral(x, x)),
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(r"\int x d\theta", Integral(x, theta)),
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(r"\int (x^2 - y)dx", Integral(x**2 - y, x)),
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(r"\int x + a dx", Integral(_Add(x, a), x)),
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(r"\int da", Integral(1, a)),
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(r"\int_0^7 dx", Integral(1, (x, 0, 7))),
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(r"\int\limits_{0}^{1} x dx", Integral(x, (x, 0, 1))),
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(r"\int_a^b x dx", Integral(x, (x, a, b))),
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(r"\int^b_a x dx", Integral(x, (x, a, b))),
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(r"\int_{a}^b x dx", Integral(x, (x, a, b))),
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(r"\int^{b}_a x dx", Integral(x, (x, a, b))),
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(r"\int_{a}^{b} x dx", Integral(x, (x, a, b))),
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(r"\int^{b}_{a} x dx", Integral(x, (x, a, b))),
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(r"\int_{f(a)}^{f(b)} f(z) dz", Integral(f(z), (z, f(a), f(b)))),
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(r"\int (x+a)", Integral(_Add(x, a), x)),
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(r"\int a + b + c dx", Integral(_Add(_Add(a, b), c), x)),
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(r"\int \frac{dz}{z}", Integral(Pow(z, -1), z)),
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(r"\int \frac{3 dz}{z}", Integral(3*Pow(z, -1), z)),
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(r"\int \frac{1}{x} dx", Integral(Pow(x, -1), x)),
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(r"\int \frac{1}{a} + \frac{1}{b} dx",
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Integral(_Add(_Pow(a, -1), Pow(b, -1)), x)),
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(r"\int \frac{3 \cdot d\theta}{\theta}",
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Integral(3*_Pow(theta, -1), theta)),
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(r"\int \frac{1}{x} + 1 dx", Integral(_Add(_Pow(x, -1), 1), x)),
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(r"x_0", Symbol('x_{0}')),
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(r"x_{1}", Symbol('x_{1}')),
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(r"x_a", Symbol('x_{a}')),
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(r"x_{b}", Symbol('x_{b}')),
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(r"h_\theta", Symbol('h_{theta}')),
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(r"h_{\theta}", Symbol('h_{theta}')),
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(r"h_{\theta}(x_0, x_1)",
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Function('h_{theta}')(Symbol('x_{0}'), Symbol('x_{1}'))),
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(r"x!", _factorial(x)),
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(r"100!", _factorial(100)),
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(r"\theta!", _factorial(theta)),
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(r"(x + 1)!", _factorial(_Add(x, 1))),
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(r"(x!)!", _factorial(_factorial(x))),
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(r"x!!!", _factorial(_factorial(_factorial(x)))),
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(r"5!7!", _Mul(_factorial(5), _factorial(7))),
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(r"\sqrt{x}", sqrt(x)),
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(r"\sqrt{x + b}", sqrt(_Add(x, b))),
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(r"\sqrt[3]{\sin x}", root(sin(x), 3)),
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(r"\sqrt[y]{\sin x}", root(sin(x), y)),
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(r"\sqrt[\theta]{\sin x}", root(sin(x), theta)),
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(r"\sqrt{\frac{12}{6}}", _Sqrt(_Mul(12, _Pow(6, -1)))),
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(r"\overline{z}", _Conjugate(z)),
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(r"\overline{\overline{z}}", _Conjugate(_Conjugate(z))),
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(r"\overline{x + y}", _Conjugate(_Add(x, y))),
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(r"\overline{x} + \overline{y}", _Conjugate(x) + _Conjugate(y)),
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(r"x < y", StrictLessThan(x, y)),
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(r"x \leq y", LessThan(x, y)),
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(r"x > y", StrictGreaterThan(x, y)),
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(r"x \geq y", GreaterThan(x, y)),
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(r"\mathit{x}", Symbol('x')),
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(r"\mathit{test}", Symbol('test')),
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(r"\mathit{TEST}", Symbol('TEST')),
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(r"\mathit{HELLO world}", Symbol('HELLO world')),
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(r"\sum_{k = 1}^{3} c", Sum(c, (k, 1, 3))),
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(r"\sum_{k = 1}^3 c", Sum(c, (k, 1, 3))),
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(r"\sum^{3}_{k = 1} c", Sum(c, (k, 1, 3))),
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(r"\sum^3_{k = 1} c", Sum(c, (k, 1, 3))),
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(r"\sum_{k = 1}^{10} k^2", Sum(k**2, (k, 1, 10))),
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(r"\sum_{n = 0}^{\infty} \frac{1}{n!}",
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Sum(_Pow(_factorial(n), -1), (n, 0, oo))),
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(r"\prod_{a = b}^{c} x", Product(x, (a, b, c))),
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(r"\prod_{a = b}^c x", Product(x, (a, b, c))),
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(r"\prod^{c}_{a = b} x", Product(x, (a, b, c))),
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(r"\prod^c_{a = b} x", Product(x, (a, b, c))),
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(r"\exp x", _exp(x)),
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(r"\exp(x)", _exp(x)),
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(r"\lg x", _log(x, 10)),
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(r"\ln x", _log(x, E)),
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(r"\ln xy", _log(x*y, E)),
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(r"\log x", _log(x, E)),
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(r"\log xy", _log(x*y, E)),
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(r"\log_{2} x", _log(x, 2)),
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(r"\log_{a} x", _log(x, a)),
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(r"\log_{11} x", _log(x, 11)),
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(r"\log_{a^2} x", _log(x, _Pow(a, 2))),
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(r"[x]", x),
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(r"[a + b]", _Add(a, b)),
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(r"\frac{d}{dx} [ \tan x ]", Derivative(tan(x), x)),
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(r"\binom{n}{k}", _binomial(n, k)),
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(r"\tbinom{n}{k}", _binomial(n, k)),
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(r"\dbinom{n}{k}", _binomial(n, k)),
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(r"\binom{n}{0}", _binomial(n, 0)),
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(r"x^\binom{n}{k}", _Pow(x, _binomial(n, k))),
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(r"a \, b", _Mul(a, b)),
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(r"a \thinspace b", _Mul(a, b)),
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(r"a \: b", _Mul(a, b)),
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(r"a \medspace b", _Mul(a, b)),
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(r"a \; b", _Mul(a, b)),
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(r"a \thickspace b", _Mul(a, b)),
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(r"a \quad b", _Mul(a, b)),
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(r"a \qquad b", _Mul(a, b)),
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(r"a \! b", _Mul(a, b)),
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(r"a \negthinspace b", _Mul(a, b)),
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(r"a \negmedspace b", _Mul(a, b)),
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(r"a \negthickspace b", _Mul(a, b)),
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(r"\int x \, dx", Integral(x, x)),
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(r"\log_2 x", _log(x, 2)),
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(r"\log_a x", _log(x, a)),
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(r"5^0 - 4^0", _Add(_Pow(5, 0), _Mul(-1, _Pow(4, 0)))),
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(r"3x - 1", _Add(_Mul(3, x), -1))
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]
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def test_parseable():
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from sympy.parsing.latex import parse_latex
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for latex_str, sympy_expr in GOOD_PAIRS:
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assert parse_latex(latex_str) == sympy_expr, latex_str
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# These bad LaTeX strings should raise a LaTeXParsingError when parsed
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BAD_STRINGS = [
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r"(",
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r")",
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r"\frac{d}{dx}",
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r"(\frac{d}{dx})",
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r"\sqrt{}",
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r"\sqrt",
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r"\overline{}",
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r"\overline",
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r"{",
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r"}",
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r"\mathit{x + y}",
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r"\mathit{21}",
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r"\frac{2}{}",
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r"\frac{}{2}",
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r"\int",
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r"!",
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r"!0",
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r"_",
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r"^",
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r"|",
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r"||x|",
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r"()",
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r"((((((((((((((((()))))))))))))))))",
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r"-",
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r"\frac{d}{dx} + \frac{d}{dt}",
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r"f(x,,y)",
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r"f(x,y,",
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r"\sin^x",
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r"\cos^2",
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r"@",
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r"#",
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r"$",
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r"%",
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r"&",
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r"*",
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r"" "\\",
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r"~",
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r"\frac{(2 + x}{1 - x)}",
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]
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def test_not_parseable():
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from sympy.parsing.latex import parse_latex, LaTeXParsingError
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for latex_str in BAD_STRINGS:
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with raises(LaTeXParsingError):
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parse_latex(latex_str)
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# At time of migration from latex2sympy, should fail but doesn't
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FAILING_BAD_STRINGS = [
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r"\cos 1 \cos",
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r"f(,",
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r"f()",
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r"a \div \div b",
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r"a \cdot \cdot b",
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r"a // b",
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r"a +",
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r"1.1.1",
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r"1 +",
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r"a / b /",
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]
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@XFAIL
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def test_failing_not_parseable():
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from sympy.parsing.latex import parse_latex, LaTeXParsingError
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for latex_str in FAILING_BAD_STRINGS:
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with raises(LaTeXParsingError):
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parse_latex(latex_str)
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