diff --git "a/env-llmeval/lib/python3.10/site-packages/sympy/printing/tests/test_latex.py" "b/env-llmeval/lib/python3.10/site-packages/sympy/printing/tests/test_latex.py" new file mode 100644--- /dev/null +++ "b/env-llmeval/lib/python3.10/site-packages/sympy/printing/tests/test_latex.py" @@ -0,0 +1,3123 @@ +from sympy import MatAdd, MatMul, Array +from sympy.algebras.quaternion import Quaternion +from sympy.calculus.accumulationbounds import AccumBounds +from sympy.combinatorics.permutations import Cycle, Permutation, AppliedPermutation +from sympy.concrete.products import Product +from sympy.concrete.summations import Sum +from sympy.core.containers import Tuple, Dict +from sympy.core.expr import UnevaluatedExpr +from sympy.core.function import (Derivative, Function, Lambda, Subs, diff) +from sympy.core.mod import Mod +from sympy.core.mul import Mul +from sympy.core.numbers import (AlgebraicNumber, Float, I, Integer, Rational, oo, pi) +from sympy.core.parameters import evaluate +from sympy.core.power import Pow +from sympy.core.relational import Eq, Ne +from sympy.core.singleton import S +from sympy.core.symbol import (Symbol, Wild, symbols) +from sympy.functions.combinatorial.factorials import (FallingFactorial, RisingFactorial, binomial, factorial, factorial2, subfactorial) +from sympy.functions.combinatorial.numbers import bernoulli, bell, catalan, euler, genocchi, lucas, fibonacci, tribonacci +from sympy.functions.elementary.complexes import (Abs, arg, conjugate, im, polar_lift, re) +from sympy.functions.elementary.exponential import (LambertW, exp, log) +from sympy.functions.elementary.hyperbolic import (asinh, coth) +from sympy.functions.elementary.integers import (ceiling, floor, frac) +from sympy.functions.elementary.miscellaneous import (Max, Min, root, sqrt) +from sympy.functions.elementary.piecewise import Piecewise +from sympy.functions.elementary.trigonometric import (acsc, asin, cos, cot, sin, tan) +from sympy.functions.special.beta_functions import beta +from sympy.functions.special.delta_functions import (DiracDelta, Heaviside) +from sympy.functions.special.elliptic_integrals import (elliptic_e, elliptic_f, elliptic_k, elliptic_pi) +from sympy.functions.special.error_functions import (Chi, Ci, Ei, Shi, Si, expint) +from sympy.functions.special.gamma_functions import (gamma, uppergamma) +from sympy.functions.special.hyper import (hyper, meijerg) +from sympy.functions.special.mathieu_functions import (mathieuc, mathieucprime, mathieus, mathieusprime) +from sympy.functions.special.polynomials import (assoc_laguerre, assoc_legendre, chebyshevt, chebyshevu, gegenbauer, hermite, jacobi, laguerre, legendre) +from sympy.functions.special.singularity_functions import SingularityFunction +from sympy.functions.special.spherical_harmonics import (Ynm, Znm) +from sympy.functions.special.tensor_functions import (KroneckerDelta, LeviCivita) +from sympy.functions.special.zeta_functions import (dirichlet_eta, lerchphi, polylog, stieltjes, zeta) +from sympy.integrals.integrals import Integral +from sympy.integrals.transforms import (CosineTransform, FourierTransform, InverseCosineTransform, InverseFourierTransform, InverseLaplaceTransform, InverseMellinTransform, InverseSineTransform, LaplaceTransform, MellinTransform, SineTransform) +from sympy.logic import Implies +from sympy.logic.boolalg import (And, Or, Xor, Equivalent, false, Not, true) +from sympy.matrices.dense import Matrix +from sympy.matrices.expressions.kronecker import KroneckerProduct +from sympy.matrices.expressions.matexpr import MatrixSymbol +from sympy.matrices.expressions.permutation import PermutationMatrix +from sympy.matrices.expressions.slice import MatrixSlice +from sympy.physics.control.lti import TransferFunction, Series, Parallel, Feedback, TransferFunctionMatrix, MIMOSeries, MIMOParallel, MIMOFeedback +from sympy.ntheory.factor_ import (divisor_sigma, primenu, primeomega, reduced_totient, totient, udivisor_sigma) +from sympy.physics.quantum import Commutator, Operator +from sympy.physics.quantum.trace import Tr +from sympy.physics.units import meter, gibibyte, gram, microgram, second, milli, micro +from sympy.polys.domains.integerring import ZZ +from sympy.polys.fields import field +from sympy.polys.polytools import Poly +from sympy.polys.rings import ring +from sympy.polys.rootoftools import (RootSum, rootof) +from sympy.series.formal import fps +from sympy.series.fourier import fourier_series +from sympy.series.limits import Limit +from sympy.series.order import Order +from sympy.series.sequences import (SeqAdd, SeqFormula, SeqMul, SeqPer) +from sympy.sets.conditionset import ConditionSet +from sympy.sets.contains import Contains +from sympy.sets.fancysets import (ComplexRegion, ImageSet, Range) +from sympy.sets.ordinals import Ordinal, OrdinalOmega, OmegaPower +from sympy.sets.powerset import PowerSet +from sympy.sets.sets import (FiniteSet, Interval, Union, Intersection, Complement, SymmetricDifference, ProductSet) +from sympy.sets.setexpr import SetExpr +from sympy.stats.crv_types import Normal +from sympy.stats.symbolic_probability import (Covariance, Expectation, + Probability, Variance) +from sympy.tensor.array import (ImmutableDenseNDimArray, + ImmutableSparseNDimArray, + MutableSparseNDimArray, + MutableDenseNDimArray, + tensorproduct) +from sympy.tensor.array.expressions.array_expressions import ArraySymbol, ArrayElement +from sympy.tensor.indexed import (Idx, Indexed, IndexedBase) +from sympy.tensor.toperators import PartialDerivative +from sympy.vector import CoordSys3D, Cross, Curl, Dot, Divergence, Gradient, Laplacian + + +from sympy.testing.pytest import (XFAIL, raises, _both_exp_pow, + warns_deprecated_sympy) +from sympy.printing.latex import (latex, translate, greek_letters_set, + tex_greek_dictionary, multiline_latex, + latex_escape, LatexPrinter) + +import sympy as sym + +from sympy.abc import mu, tau + + +class lowergamma(sym.lowergamma): + pass # testing notation inheritance by a subclass with same name + + +x, y, z, t, w, a, b, c, s, p = symbols('x y z t w a b c s p') +k, m, n = symbols('k m n', integer=True) + + +def test_printmethod(): + class R(Abs): + def _latex(self, printer): + return "foo(%s)" % printer._print(self.args[0]) + assert latex(R(x)) == r"foo(x)" + + class R(Abs): + def _latex(self, printer): + return "foo" + assert latex(R(x)) == r"foo" + + +def test_latex_basic(): + assert latex(1 + x) == r"x + 1" + assert latex(x**2) == r"x^{2}" + assert latex(x**(1 + x)) == r"x^{x + 1}" + assert latex(x**3 + x + 1 + x**2) == r"x^{3} + x^{2} + x + 1" + + assert latex(2*x*y) == r"2 x y" + assert latex(2*x*y, mul_symbol='dot') == r"2 \cdot x \cdot y" + assert latex(3*x**2*y, mul_symbol='\\,') == r"3\,x^{2}\,y" + assert latex(1.5*3**x, mul_symbol='\\,') == r"1.5 \cdot 3^{x}" + + assert latex(x**S.Half**5) == r"\sqrt[32]{x}" + assert latex(Mul(S.Half, x**2, -5, evaluate=False)) == r"\frac{1}{2} x^{2} \left(-5\right)" + assert latex(Mul(S.Half, x**2, 5, evaluate=False)) == r"\frac{1}{2} x^{2} \cdot 5" + assert latex(Mul(-5, -5, evaluate=False)) == r"\left(-5\right) \left(-5\right)" + assert latex(Mul(5, -5, evaluate=False)) == r"5 \left(-5\right)" + assert latex(Mul(S.Half, -5, S.Half, evaluate=False)) == r"\frac{1}{2} \left(-5\right) \frac{1}{2}" + assert latex(Mul(5, I, 5, evaluate=False)) == r"5 i 5" + assert latex(Mul(5, I, -5, evaluate=False)) == r"5 i \left(-5\right)" + + assert latex(Mul(0, 1, evaluate=False)) == r'0 \cdot 1' + assert latex(Mul(1, 0, evaluate=False)) == r'1 \cdot 0' + assert latex(Mul(1, 1, evaluate=False)) == r'1 \cdot 1' + assert latex(Mul(-1, 1, evaluate=False)) == r'\left(-1\right) 1' + assert latex(Mul(1, 1, 1, evaluate=False)) == r'1 \cdot 1 \cdot 1' + assert latex(Mul(1, 2, evaluate=False)) == r'1 \cdot 2' + assert latex(Mul(1, S.Half, evaluate=False)) == r'1 \cdot \frac{1}{2}' + assert latex(Mul(1, 1, S.Half, evaluate=False)) == \ + r'1 \cdot 1 \cdot \frac{1}{2}' + assert latex(Mul(1, 1, 2, 3, x, evaluate=False)) == \ + r'1 \cdot 1 \cdot 2 \cdot 3 x' + assert latex(Mul(1, -1, evaluate=False)) == r'1 \left(-1\right)' + assert latex(Mul(4, 3, 2, 1, 0, y, x, evaluate=False)) == \ + r'4 \cdot 3 \cdot 2 \cdot 1 \cdot 0 y x' + assert latex(Mul(4, 3, 2, 1+z, 0, y, x, evaluate=False)) == \ + r'4 \cdot 3 \cdot 2 \left(z + 1\right) 0 y x' + assert latex(Mul(Rational(2, 3), Rational(5, 7), evaluate=False)) == \ + r'\frac{2}{3} \cdot \frac{5}{7}' + + assert latex(1/x) == r"\frac{1}{x}" + assert latex(1/x, fold_short_frac=True) == r"1 / x" + assert latex(-S(3)/2) == r"- \frac{3}{2}" + assert latex(-S(3)/2, fold_short_frac=True) == r"- 3 / 2" + assert latex(1/x**2) == r"\frac{1}{x^{2}}" + assert latex(1/(x + y)/2) == r"\frac{1}{2 \left(x + y\right)}" + assert latex(x/2) == r"\frac{x}{2}" + assert latex(x/2, fold_short_frac=True) == r"x / 2" + assert latex((x + y)/(2*x)) == r"\frac{x + y}{2 x}" + assert latex((x + y)/(2*x), fold_short_frac=True) == \ + r"\left(x + y\right) / 2 x" + assert latex((x + y)/(2*x), long_frac_ratio=0) == \ + r"\frac{1}{2 x} \left(x + y\right)" + assert latex((x + y)/x) == r"\frac{x + y}{x}" + assert latex((x + y)/x, long_frac_ratio=3) == r"\frac{x + y}{x}" + assert latex((2*sqrt(2)*x)/3) == r"\frac{2 \sqrt{2} x}{3}" + assert latex((2*sqrt(2)*x)/3, long_frac_ratio=2) == \ + r"\frac{2 x}{3} \sqrt{2}" + assert latex(binomial(x, y)) == r"{\binom{x}{y}}" + + x_star = Symbol('x^*') + f = Function('f') + assert latex(x_star**2) == r"\left(x^{*}\right)^{2}" + assert latex(x_star**2, parenthesize_super=False) == r"{x^{*}}^{2}" + assert latex(Derivative(f(x_star), x_star,2)) == r"\frac{d^{2}}{d \left(x^{*}\right)^{2}} f{\left(x^{*} \right)}" + assert latex(Derivative(f(x_star), x_star,2), parenthesize_super=False) == r"\frac{d^{2}}{d {x^{*}}^{2}} f{\left(x^{*} \right)}" + + assert latex(2*Integral(x, x)/3) == r"\frac{2 \int x\, dx}{3}" + assert latex(2*Integral(x, x)/3, fold_short_frac=True) == \ + r"\left(2 \int x\, dx\right) / 3" + + assert latex(sqrt(x)) == r"\sqrt{x}" + assert latex(x**Rational(1, 3)) == r"\sqrt[3]{x}" + assert latex(x**Rational(1, 3), root_notation=False) == r"x^{\frac{1}{3}}" + assert latex(sqrt(x)**3) == r"x^{\frac{3}{2}}" + assert latex(sqrt(x), itex=True) == r"\sqrt{x}" + assert latex(x**Rational(1, 3), itex=True) == r"\root{3}{x}" + assert latex(sqrt(x)**3, itex=True) == r"x^{\frac{3}{2}}" + assert latex(x**Rational(3, 4)) == r"x^{\frac{3}{4}}" + assert latex(x**Rational(3, 4), fold_frac_powers=True) == r"x^{3/4}" + assert latex((x + 1)**Rational(3, 4)) == \ + r"\left(x + 1\right)^{\frac{3}{4}}" + assert latex((x + 1)**Rational(3, 4), fold_frac_powers=True) == \ + r"\left(x + 1\right)^{3/4}" + assert latex(AlgebraicNumber(sqrt(2))) == r"\sqrt{2}" + assert latex(AlgebraicNumber(sqrt(2), [3, -7])) == r"-7 + 3 \sqrt{2}" + assert latex(AlgebraicNumber(sqrt(2), alias='alpha')) == r"\alpha" + assert latex(AlgebraicNumber(sqrt(2), [3, -7], alias='alpha')) == \ + r"3 \alpha - 7" + assert latex(AlgebraicNumber(2**(S(1)/3), [1, 3, -7], alias='beta')) == \ + r"\beta^{2} + 3 \beta - 7" + + k = ZZ.cyclotomic_field(5) + assert latex(k.ext.field_element([1, 2, 3, 4])) == \ + r"\zeta^{3} + 2 \zeta^{2} + 3 \zeta + 4" + assert latex(k.ext.field_element([1, 2, 3, 4]), order='old') == \ + r"4 + 3 \zeta + 2 \zeta^{2} + \zeta^{3}" + assert latex(k.primes_above(19)[0]) == \ + r"\left(19, \zeta^{2} + 5 \zeta + 1\right)" + assert latex(k.primes_above(19)[0], order='old') == \ + r"\left(19, 1 + 5 \zeta + \zeta^{2}\right)" + assert latex(k.primes_above(7)[0]) == r"\left(7\right)" + + assert latex(1.5e20*x) == r"1.5 \cdot 10^{20} x" + assert latex(1.5e20*x, mul_symbol='dot') == r"1.5 \cdot 10^{20} \cdot x" + assert latex(1.5e20*x, mul_symbol='times') == \ + r"1.5 \times 10^{20} \times x" + + assert latex(1/sin(x)) == r"\frac{1}{\sin{\left(x \right)}}" + assert latex(sin(x)**-1) == r"\frac{1}{\sin{\left(x \right)}}" + assert latex(sin(x)**Rational(3, 2)) == \ + r"\sin^{\frac{3}{2}}{\left(x \right)}" + assert latex(sin(x)**Rational(3, 2), fold_frac_powers=True) == \ + r"\sin^{3/2}{\left(x \right)}" + + assert latex(~x) == r"\neg x" + assert latex(x & y) == r"x \wedge y" + assert latex(x & y & z) == r"x \wedge y \wedge z" + assert latex(x | y) == r"x \vee y" + assert latex(x | y | z) == r"x \vee y \vee z" + assert latex((x & y) | z) == r"z \vee \left(x \wedge y\right)" + assert latex(Implies(x, y)) == r"x \Rightarrow y" + assert latex(~(x >> ~y)) == r"x \not\Rightarrow \neg y" + assert latex(Implies(Or(x,y), z)) == r"\left(x \vee y\right) \Rightarrow z" + assert latex(Implies(z, Or(x,y))) == r"z \Rightarrow \left(x \vee y\right)" + assert latex(~(x & y)) == r"\neg \left(x \wedge y\right)" + + assert latex(~x, symbol_names={x: "x_i"}) == r"\neg x_i" + assert latex(x & y, symbol_names={x: "x_i", y: "y_i"}) == \ + r"x_i \wedge y_i" + assert latex(x & y & z, symbol_names={x: "x_i", y: "y_i", z: "z_i"}) == \ + r"x_i \wedge y_i \wedge z_i" + assert latex(x | y, symbol_names={x: "x_i", y: "y_i"}) == r"x_i \vee y_i" + assert latex(x | y | z, symbol_names={x: "x_i", y: "y_i", z: "z_i"}) == \ + r"x_i \vee y_i \vee z_i" + assert latex((x & y) | z, symbol_names={x: "x_i", y: "y_i", z: "z_i"}) == \ + r"z_i \vee \left(x_i \wedge y_i\right)" + assert latex(Implies(x, y), symbol_names={x: "x_i", y: "y_i"}) == \ + r"x_i \Rightarrow y_i" + assert latex(Pow(Rational(1, 3), -1, evaluate=False)) == r"\frac{1}{\frac{1}{3}}" + assert latex(Pow(Rational(1, 3), -2, evaluate=False)) == r"\frac{1}{(\frac{1}{3})^{2}}" + assert latex(Pow(Integer(1)/100, -1, evaluate=False)) == r"\frac{1}{\frac{1}{100}}" + + + p = Symbol('p', positive=True) + assert latex(exp(-p)*log(p)) == r"e^{- p} \log{\left(p \right)}" + + +def test_latex_builtins(): + assert latex(True) == r"\text{True}" + assert latex(False) == r"\text{False}" + assert latex(None) == r"\text{None}" + assert latex(true) == r"\text{True}" + assert latex(false) == r'\text{False}' + + +def test_latex_SingularityFunction(): + assert latex(SingularityFunction(x, 4, 5)) == \ + r"{\left\langle x - 4 \right\rangle}^{5}" + assert latex(SingularityFunction(x, -3, 4)) == \ + r"{\left\langle x + 3 \right\rangle}^{4}" + assert latex(SingularityFunction(x, 0, 4)) == \ + r"{\left\langle x \right\rangle}^{4}" + assert latex(SingularityFunction(x, a, n)) == \ + r"{\left\langle - a + x \right\rangle}^{n}" + assert latex(SingularityFunction(x, 4, -2)) == \ + r"{\left\langle x - 4 \right\rangle}^{-2}" + assert latex(SingularityFunction(x, 4, -1)) == \ + r"{\left\langle x - 4 \right\rangle}^{-1}" + + assert latex(SingularityFunction(x, 4, 5)**3) == \ + r"{\left({\langle x - 4 \rangle}^{5}\right)}^{3}" + assert latex(SingularityFunction(x, -3, 4)**3) == \ + r"{\left({\langle x + 3 \rangle}^{4}\right)}^{3}" + assert latex(SingularityFunction(x, 0, 4)**3) == \ + r"{\left({\langle x \rangle}^{4}\right)}^{3}" + assert latex(SingularityFunction(x, a, n)**3) == \ + r"{\left({\langle - a + x \rangle}^{n}\right)}^{3}" + assert latex(SingularityFunction(x, 4, -2)**3) == \ + r"{\left({\langle x - 4 \rangle}^{-2}\right)}^{3}" + assert latex((SingularityFunction(x, 4, -1)**3)**3) == \ + r"{\left({\langle x - 4 \rangle}^{-1}\right)}^{9}" + + +def test_latex_cycle(): + assert latex(Cycle(1, 2, 4)) == r"\left( 1\; 2\; 4\right)" + assert latex(Cycle(1, 2)(4, 5, 6)) == \ + r"\left( 1\; 2\right)\left( 4\; 5\; 6\right)" + assert latex(Cycle()) == r"\left( \right)" + + +def test_latex_permutation(): + assert latex(Permutation(1, 2, 4)) == r"\left( 1\; 2\; 4\right)" + assert latex(Permutation(1, 2)(4, 5, 6)) == \ + r"\left( 1\; 2\right)\left( 4\; 5\; 6\right)" + assert latex(Permutation()) == r"\left( \right)" + assert latex(Permutation(2, 4)*Permutation(5)) == \ + r"\left( 2\; 4\right)\left( 5\right)" + assert latex(Permutation(5)) == r"\left( 5\right)" + + assert latex(Permutation(0, 1), perm_cyclic=False) == \ + r"\begin{pmatrix} 0 & 1 \\ 1 & 0 \end{pmatrix}" + assert latex(Permutation(0, 1)(2, 3), perm_cyclic=False) == \ + r"\begin{pmatrix} 0 & 1 & 2 & 3 \\ 1 & 0 & 3 & 2 \end{pmatrix}" + assert latex(Permutation(), perm_cyclic=False) == \ + r"\left( \right)" + + with warns_deprecated_sympy(): + old_print_cyclic = Permutation.print_cyclic + Permutation.print_cyclic = False + assert latex(Permutation(0, 1)(2, 3)) == \ + r"\begin{pmatrix} 0 & 1 & 2 & 3 \\ 1 & 0 & 3 & 2 \end{pmatrix}" + Permutation.print_cyclic = old_print_cyclic + +def test_latex_Float(): + assert latex(Float(1.0e100)) == r"1.0 \cdot 10^{100}" + assert latex(Float(1.0e-100)) == r"1.0 \cdot 10^{-100}" + assert latex(Float(1.0e-100), mul_symbol="times") == \ + r"1.0 \times 10^{-100}" + assert latex(Float('10000.0'), full_prec=False, min=-2, max=2) == \ + r"1.0 \cdot 10^{4}" + assert latex(Float('10000.0'), full_prec=False, min=-2, max=4) == \ + r"1.0 \cdot 10^{4}" + assert latex(Float('10000.0'), full_prec=False, min=-2, max=5) == \ + r"10000.0" + assert latex(Float('0.099999'), full_prec=True, min=-2, max=5) == \ + r"9.99990000000000 \cdot 10^{-2}" + + +def test_latex_vector_expressions(): + A = CoordSys3D('A') + + assert latex(Cross(A.i, A.j*A.x*3+A.k)) == \ + r"\mathbf{\hat{i}_{A}} \times \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}} + \mathbf{\hat{k}_{A}}\right)" + assert latex(Cross(A.i, A.j)) == \ + r"\mathbf{\hat{i}_{A}} \times \mathbf{\hat{j}_{A}}" + assert latex(x*Cross(A.i, A.j)) == \ + r"x \left(\mathbf{\hat{i}_{A}} \times \mathbf{\hat{j}_{A}}\right)" + assert latex(Cross(x*A.i, A.j)) == \ + r'- \mathbf{\hat{j}_{A}} \times \left(\left(x\right)\mathbf{\hat{i}_{A}}\right)' + + assert latex(Curl(3*A.x*A.j)) == \ + r"\nabla\times \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(Curl(3*A.x*A.j+A.i)) == \ + r"\nabla\times \left(\mathbf{\hat{i}_{A}} + \left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(Curl(3*x*A.x*A.j)) == \ + r"\nabla\times \left(\left(3 \mathbf{{x}_{A}} x\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(x*Curl(3*A.x*A.j)) == \ + r"x \left(\nabla\times \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)\right)" + + assert latex(Divergence(3*A.x*A.j+A.i)) == \ + r"\nabla\cdot \left(\mathbf{\hat{i}_{A}} + \left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(Divergence(3*A.x*A.j)) == \ + r"\nabla\cdot \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)" + assert latex(x*Divergence(3*A.x*A.j)) == \ + r"x \left(\nabla\cdot \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}}\right)\right)" + + assert latex(Dot(A.i, A.j*A.x*3+A.k)) == \ + r"\mathbf{\hat{i}_{A}} \cdot \left(\left(3 \mathbf{{x}_{A}}\right)\mathbf{\hat{j}_{A}} + \mathbf{\hat{k}_{A}}\right)" + assert latex(Dot(A.i, A.j)) == \ + r"\mathbf{\hat{i}_{A}} \cdot \mathbf{\hat{j}_{A}}" + assert latex(Dot(x*A.i, A.j)) == \ + r"\mathbf{\hat{j}_{A}} \cdot \left(\left(x\right)\mathbf{\hat{i}_{A}}\right)" + assert latex(x*Dot(A.i, A.j)) == \ + r"x \left(\mathbf{\hat{i}_{A}} \cdot \mathbf{\hat{j}_{A}}\right)" + + assert latex(Gradient(A.x)) == r"\nabla \mathbf{{x}_{A}}" + assert latex(Gradient(A.x + 3*A.y)) == \ + r"\nabla \left(\mathbf{{x}_{A}} + 3 \mathbf{{y}_{A}}\right)" + assert latex(x*Gradient(A.x)) == r"x \left(\nabla \mathbf{{x}_{A}}\right)" + assert latex(Gradient(x*A.x)) == r"\nabla \left(\mathbf{{x}_{A}} x\right)" + + assert latex(Laplacian(A.x)) == r"\Delta \mathbf{{x}_{A}}" + assert latex(Laplacian(A.x + 3*A.y)) == \ + r"\Delta \left(\mathbf{{x}_{A}} + 3 \mathbf{{y}_{A}}\right)" + assert latex(x*Laplacian(A.x)) == r"x \left(\Delta \mathbf{{x}_{A}}\right)" + assert latex(Laplacian(x*A.x)) == r"\Delta \left(\mathbf{{x}_{A}} x\right)" + +def test_latex_symbols(): + Gamma, lmbda, rho = symbols('Gamma, lambda, rho') + tau, Tau, TAU, taU = symbols('tau, Tau, TAU, taU') + assert latex(tau) == r"\tau" + assert latex(Tau) == r"\mathrm{T}" + assert latex(TAU) == r"\tau" + assert latex(taU) == r"\tau" + # Check that all capitalized greek letters are handled explicitly + capitalized_letters = {l.capitalize() for l in greek_letters_set} + assert len(capitalized_letters - set(tex_greek_dictionary.keys())) == 0 + assert latex(Gamma + lmbda) == r"\Gamma + \lambda" + assert latex(Gamma * lmbda) == r"\Gamma \lambda" + assert latex(Symbol('q1')) == r"q_{1}" + assert latex(Symbol('q21')) == r"q_{21}" + assert latex(Symbol('epsilon0')) == r"\epsilon_{0}" + assert latex(Symbol('omega1')) == r"\omega_{1}" + assert latex(Symbol('91')) == r"91" + assert latex(Symbol('alpha_new')) == r"\alpha_{new}" + assert latex(Symbol('C^orig')) == r"C^{orig}" + assert latex(Symbol('x^alpha')) == r"x^{\alpha}" + assert latex(Symbol('beta^alpha')) == r"\beta^{\alpha}" + assert latex(Symbol('e^Alpha')) == r"e^{\mathrm{A}}" + assert latex(Symbol('omega_alpha^beta')) == r"\omega^{\beta}_{\alpha}" + assert latex(Symbol('omega') ** Symbol('beta')) == r"\omega^{\beta}" + + +@XFAIL +def test_latex_symbols_failing(): + rho, mass, volume = symbols('rho, mass, volume') + assert latex( + volume * rho == mass) == r"\rho \mathrm{volume} = \mathrm{mass}" + assert latex(volume / mass * rho == 1) == \ + r"\rho \mathrm{volume} {\mathrm{mass}}^{(-1)} = 1" + assert latex(mass**3 * volume**3) == \ + r"{\mathrm{mass}}^{3} \cdot {\mathrm{volume}}^{3}" + + +@_both_exp_pow +def test_latex_functions(): + assert latex(exp(x)) == r"e^{x}" + assert latex(exp(1) + exp(2)) == r"e + e^{2}" + + f = Function('f') + assert latex(f(x)) == r'f{\left(x \right)}' + assert latex(f) == r'f' + + g = Function('g') + assert latex(g(x, y)) == r'g{\left(x,y \right)}' + assert latex(g) == r'g' + + h = Function('h') + assert latex(h(x, y, z)) == r'h{\left(x,y,z \right)}' + assert latex(h) == r'h' + + Li = Function('Li') + assert latex(Li) == r'\operatorname{Li}' + assert latex(Li(x)) == r'\operatorname{Li}{\left(x \right)}' + + mybeta = Function('beta') + # not to be confused with the beta function + assert latex(mybeta(x, y, z)) == r"\beta{\left(x,y,z \right)}" + assert latex(beta(x, y)) == r'\operatorname{B}\left(x, y\right)' + assert latex(beta(x, evaluate=False)) == r'\operatorname{B}\left(x, x\right)' + assert latex(beta(x, y)**2) == r'\operatorname{B}^{2}\left(x, y\right)' + assert latex(mybeta(x)) == r"\beta{\left(x \right)}" + assert latex(mybeta) == r"\beta" + + g = Function('gamma') + # not to be confused with the gamma function + assert latex(g(x, y, z)) == r"\gamma{\left(x,y,z \right)}" + assert latex(g(x)) == r"\gamma{\left(x \right)}" + assert latex(g) == r"\gamma" + + a_1 = Function('a_1') + assert latex(a_1) == r"a_{1}" + assert latex(a_1(x)) == r"a_{1}{\left(x \right)}" + assert latex(Function('a_1')) == r"a_{1}" + + # Issue #16925 + # multi letter function names + # > simple + assert latex(Function('ab')) == r"\operatorname{ab}" + assert latex(Function('ab1')) == r"\operatorname{ab}_{1}" + assert latex(Function('ab12')) == r"\operatorname{ab}_{12}" + assert latex(Function('ab_1')) == r"\operatorname{ab}_{1}" + assert latex(Function('ab_12')) == r"\operatorname{ab}_{12}" + assert latex(Function('ab_c')) == r"\operatorname{ab}_{c}" + assert latex(Function('ab_cd')) == r"\operatorname{ab}_{cd}" + # > with argument + assert latex(Function('ab')(Symbol('x'))) == r"\operatorname{ab}{\left(x \right)}" + assert latex(Function('ab1')(Symbol('x'))) == r"\operatorname{ab}_{1}{\left(x \right)}" + assert latex(Function('ab12')(Symbol('x'))) == r"\operatorname{ab}_{12}{\left(x \right)}" + assert latex(Function('ab_1')(Symbol('x'))) == r"\operatorname{ab}_{1}{\left(x \right)}" + assert latex(Function('ab_c')(Symbol('x'))) == r"\operatorname{ab}_{c}{\left(x \right)}" + assert latex(Function('ab_cd')(Symbol('x'))) == r"\operatorname{ab}_{cd}{\left(x \right)}" + + # > with power + # does not work on functions without brackets + + # > with argument and power combined + assert latex(Function('ab')()**2) == r"\operatorname{ab}^{2}{\left( \right)}" + assert latex(Function('ab1')()**2) == r"\operatorname{ab}_{1}^{2}{\left( \right)}" + assert latex(Function('ab12')()**2) == r"\operatorname{ab}_{12}^{2}{\left( \right)}" + assert latex(Function('ab_1')()**2) == r"\operatorname{ab}_{1}^{2}{\left( \right)}" + assert latex(Function('ab_12')()**2) == r"\operatorname{ab}_{12}^{2}{\left( \right)}" + assert latex(Function('ab')(Symbol('x'))**2) == r"\operatorname{ab}^{2}{\left(x \right)}" + assert latex(Function('ab1')(Symbol('x'))**2) == r"\operatorname{ab}_{1}^{2}{\left(x \right)}" + assert latex(Function('ab12')(Symbol('x'))**2) == r"\operatorname{ab}_{12}^{2}{\left(x \right)}" + assert latex(Function('ab_1')(Symbol('x'))**2) == r"\operatorname{ab}_{1}^{2}{\left(x \right)}" + assert latex(Function('ab_12')(Symbol('x'))**2) == \ + r"\operatorname{ab}_{12}^{2}{\left(x \right)}" + + # single letter function names + # > simple + assert latex(Function('a')) == r"a" + assert latex(Function('a1')) == r"a_{1}" + assert latex(Function('a12')) == r"a_{12}" + assert latex(Function('a_1')) == r"a_{1}" + assert latex(Function('a_12')) == r"a_{12}" + + # > with argument + assert latex(Function('a')()) == r"a{\left( \right)}" + assert latex(Function('a1')()) == r"a_{1}{\left( \right)}" + assert latex(Function('a12')()) == r"a_{12}{\left( \right)}" + assert latex(Function('a_1')()) == r"a_{1}{\left( \right)}" + assert latex(Function('a_12')()) == r"a_{12}{\left( \right)}" + + # > with power + # does not work on functions without brackets + + # > with argument and power combined + assert latex(Function('a')()**2) == r"a^{2}{\left( \right)}" + assert latex(Function('a1')()**2) == r"a_{1}^{2}{\left( \right)}" + assert latex(Function('a12')()**2) == r"a_{12}^{2}{\left( \right)}" + assert latex(Function('a_1')()**2) == r"a_{1}^{2}{\left( \right)}" + assert latex(Function('a_12')()**2) == r"a_{12}^{2}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**2) == r"a^{2}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**2) == r"a_{1}^{2}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**2) == r"a_{12}^{2}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**2) == r"a_{1}^{2}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**2) == r"a_{12}^{2}{\left(x \right)}" + + assert latex(Function('a')()**32) == r"a^{32}{\left( \right)}" + assert latex(Function('a1')()**32) == r"a_{1}^{32}{\left( \right)}" + assert latex(Function('a12')()**32) == r"a_{12}^{32}{\left( \right)}" + assert latex(Function('a_1')()**32) == r"a_{1}^{32}{\left( \right)}" + assert latex(Function('a_12')()**32) == r"a_{12}^{32}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**32) == r"a^{32}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**32) == r"a_{1}^{32}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**32) == r"a_{12}^{32}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**32) == r"a_{1}^{32}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**32) == r"a_{12}^{32}{\left(x \right)}" + + assert latex(Function('a')()**a) == r"a^{a}{\left( \right)}" + assert latex(Function('a1')()**a) == r"a_{1}^{a}{\left( \right)}" + assert latex(Function('a12')()**a) == r"a_{12}^{a}{\left( \right)}" + assert latex(Function('a_1')()**a) == r"a_{1}^{a}{\left( \right)}" + assert latex(Function('a_12')()**a) == r"a_{12}^{a}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**a) == r"a^{a}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**a) == r"a_{1}^{a}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**a) == r"a_{12}^{a}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**a) == r"a_{1}^{a}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**a) == r"a_{12}^{a}{\left(x \right)}" + + ab = Symbol('ab') + assert latex(Function('a')()**ab) == r"a^{ab}{\left( \right)}" + assert latex(Function('a1')()**ab) == r"a_{1}^{ab}{\left( \right)}" + assert latex(Function('a12')()**ab) == r"a_{12}^{ab}{\left( \right)}" + assert latex(Function('a_1')()**ab) == r"a_{1}^{ab}{\left( \right)}" + assert latex(Function('a_12')()**ab) == r"a_{12}^{ab}{\left( \right)}" + assert latex(Function('a')(Symbol('x'))**ab) == r"a^{ab}{\left(x \right)}" + assert latex(Function('a1')(Symbol('x'))**ab) == r"a_{1}^{ab}{\left(x \right)}" + assert latex(Function('a12')(Symbol('x'))**ab) == r"a_{12}^{ab}{\left(x \right)}" + assert latex(Function('a_1')(Symbol('x'))**ab) == r"a_{1}^{ab}{\left(x \right)}" + assert latex(Function('a_12')(Symbol('x'))**ab) == r"a_{12}^{ab}{\left(x \right)}" + + assert latex(Function('a^12')(x)) == R"a^{12}{\left(x \right)}" + assert latex(Function('a^12')(x) ** ab) == R"\left(a^{12}\right)^{ab}{\left(x \right)}" + assert latex(Function('a__12')(x)) == R"a^{12}{\left(x \right)}" + assert latex(Function('a__12')(x) ** ab) == R"\left(a^{12}\right)^{ab}{\left(x \right)}" + assert latex(Function('a_1__1_2')(x)) == R"a^{1}_{1 2}{\left(x \right)}" + + # issue 5868 + omega1 = Function('omega1') + assert latex(omega1) == r"\omega_{1}" + assert latex(omega1(x)) == r"\omega_{1}{\left(x \right)}" + + assert latex(sin(x)) == r"\sin{\left(x \right)}" + assert latex(sin(x), fold_func_brackets=True) == r"\sin {x}" + assert latex(sin(2*x**2), fold_func_brackets=True) == \ + r"\sin {2 x^{2}}" + assert latex(sin(x**2), fold_func_brackets=True) == \ + r"\sin {x^{2}}" + + assert latex(asin(x)**2) == r"\operatorname{asin}^{2}{\left(x \right)}" + assert latex(asin(x)**2, inv_trig_style="full") == \ + r"\arcsin^{2}{\left(x \right)}" + assert latex(asin(x)**2, inv_trig_style="power") == \ + r"\sin^{-1}{\left(x \right)}^{2}" + assert latex(asin(x**2), inv_trig_style="power", + fold_func_brackets=True) == \ + r"\sin^{-1} {x^{2}}" + assert latex(acsc(x), inv_trig_style="full") == \ + r"\operatorname{arccsc}{\left(x \right)}" + assert latex(asinh(x), inv_trig_style="full") == \ + r"\operatorname{arsinh}{\left(x \right)}" + + assert latex(factorial(k)) == r"k!" + assert latex(factorial(-k)) == r"\left(- k\right)!" + assert latex(factorial(k)**2) == r"k!^{2}" + + assert latex(subfactorial(k)) == r"!k" + assert latex(subfactorial(-k)) == r"!\left(- k\right)" + assert latex(subfactorial(k)**2) == r"\left(!k\right)^{2}" + + assert latex(factorial2(k)) == r"k!!" + assert latex(factorial2(-k)) == r"\left(- k\right)!!" + assert latex(factorial2(k)**2) == r"k!!^{2}" + + assert latex(binomial(2, k)) == r"{\binom{2}{k}}" + assert latex(binomial(2, k)**2) == r"{\binom{2}{k}}^{2}" + + assert latex(FallingFactorial(3, k)) == r"{\left(3\right)}_{k}" + assert latex(RisingFactorial(3, k)) == r"{3}^{\left(k\right)}" + + assert latex(floor(x)) == r"\left\lfloor{x}\right\rfloor" + assert latex(ceiling(x)) == r"\left\lceil{x}\right\rceil" + assert latex(frac(x)) == r"\operatorname{frac}{\left(x\right)}" + assert latex(floor(x)**2) == r"\left\lfloor{x}\right\rfloor^{2}" + assert latex(ceiling(x)**2) == r"\left\lceil{x}\right\rceil^{2}" + assert latex(frac(x)**2) == r"\operatorname{frac}{\left(x\right)}^{2}" + + assert latex(Min(x, 2, x**3)) == r"\min\left(2, x, x^{3}\right)" + assert latex(Min(x, y)**2) == r"\min\left(x, y\right)^{2}" + assert latex(Max(x, 2, x**3)) == r"\max\left(2, x, x^{3}\right)" + assert latex(Max(x, y)**2) == r"\max\left(x, y\right)^{2}" + assert latex(Abs(x)) == r"\left|{x}\right|" + assert latex(Abs(x)**2) == r"\left|{x}\right|^{2}" + assert latex(re(x)) == r"\operatorname{re}{\left(x\right)}" + assert latex(re(x + y)) == \ + r"\operatorname{re}{\left(x\right)} + \operatorname{re}{\left(y\right)}" + assert latex(im(x)) == r"\operatorname{im}{\left(x\right)}" + assert latex(conjugate(x)) == r"\overline{x}" + assert latex(conjugate(x)**2) == r"\overline{x}^{2}" + assert latex(conjugate(x**2)) == r"\overline{x}^{2}" + assert latex(gamma(x)) == r"\Gamma\left(x\right)" + w = Wild('w') + assert latex(gamma(w)) == r"\Gamma\left(w\right)" + assert latex(Order(x)) == r"O\left(x\right)" + assert latex(Order(x, x)) == r"O\left(x\right)" + assert latex(Order(x, (x, 0))) == r"O\left(x\right)" + assert latex(Order(x, (x, oo))) == r"O\left(x; x\rightarrow \infty\right)" + assert latex(Order(x - y, (x, y))) == \ + r"O\left(x - y; x\rightarrow y\right)" + assert latex(Order(x, x, y)) == \ + r"O\left(x; \left( x, \ y\right)\rightarrow \left( 0, \ 0\right)\right)" + assert latex(Order(x, x, y)) == \ + r"O\left(x; \left( x, \ y\right)\rightarrow \left( 0, \ 0\right)\right)" + assert latex(Order(x, (x, oo), (y, oo))) == \ + r"O\left(x; \left( x, \ y\right)\rightarrow \left( \infty, \ \infty\right)\right)" + assert latex(lowergamma(x, y)) == r'\gamma\left(x, y\right)' + assert latex(lowergamma(x, y)**2) == r'\gamma^{2}\left(x, y\right)' + assert latex(uppergamma(x, y)) == r'\Gamma\left(x, y\right)' + assert latex(uppergamma(x, y)**2) == r'\Gamma^{2}\left(x, y\right)' + + assert latex(cot(x)) == r'\cot{\left(x \right)}' + assert latex(coth(x)) == r'\coth{\left(x \right)}' + assert latex(re(x)) == r'\operatorname{re}{\left(x\right)}' + assert latex(im(x)) == r'\operatorname{im}{\left(x\right)}' + assert latex(root(x, y)) == r'x^{\frac{1}{y}}' + assert latex(arg(x)) == r'\arg{\left(x \right)}' + + assert latex(zeta(x)) == r"\zeta\left(x\right)" + assert latex(zeta(x)**2) == r"\zeta^{2}\left(x\right)" + assert latex(zeta(x, y)) == r"\zeta\left(x, y\right)" + assert latex(zeta(x, y)**2) == r"\zeta^{2}\left(x, y\right)" + assert latex(dirichlet_eta(x)) == r"\eta\left(x\right)" + assert latex(dirichlet_eta(x)**2) == r"\eta^{2}\left(x\right)" + assert latex(polylog(x, y)) == r"\operatorname{Li}_{x}\left(y\right)" + assert latex( + polylog(x, y)**2) == r"\operatorname{Li}_{x}^{2}\left(y\right)" + assert latex(lerchphi(x, y, n)) == r"\Phi\left(x, y, n\right)" + assert latex(lerchphi(x, y, n)**2) == r"\Phi^{2}\left(x, y, n\right)" + assert latex(stieltjes(x)) == r"\gamma_{x}" + assert latex(stieltjes(x)**2) == r"\gamma_{x}^{2}" + assert latex(stieltjes(x, y)) == r"\gamma_{x}\left(y\right)" + assert latex(stieltjes(x, y)**2) == r"\gamma_{x}\left(y\right)^{2}" + + assert latex(elliptic_k(z)) == r"K\left(z\right)" + assert latex(elliptic_k(z)**2) == r"K^{2}\left(z\right)" + assert latex(elliptic_f(x, y)) == r"F\left(x\middle| y\right)" + assert latex(elliptic_f(x, y)**2) == r"F^{2}\left(x\middle| y\right)" + assert latex(elliptic_e(x, y)) == r"E\left(x\middle| y\right)" + assert latex(elliptic_e(x, y)**2) == r"E^{2}\left(x\middle| y\right)" + assert latex(elliptic_e(z)) == r"E\left(z\right)" + assert latex(elliptic_e(z)**2) == r"E^{2}\left(z\right)" + assert latex(elliptic_pi(x, y, z)) == r"\Pi\left(x; y\middle| z\right)" + assert latex(elliptic_pi(x, y, z)**2) == \ + r"\Pi^{2}\left(x; y\middle| z\right)" + assert latex(elliptic_pi(x, y)) == r"\Pi\left(x\middle| y\right)" + assert latex(elliptic_pi(x, y)**2) == r"\Pi^{2}\left(x\middle| y\right)" + + assert latex(Ei(x)) == r'\operatorname{Ei}{\left(x \right)}' + assert latex(Ei(x)**2) == r'\operatorname{Ei}^{2}{\left(x \right)}' + assert latex(expint(x, y)) == r'\operatorname{E}_{x}\left(y\right)' + assert latex(expint(x, y)**2) == r'\operatorname{E}_{x}^{2}\left(y\right)' + assert latex(Shi(x)**2) == r'\operatorname{Shi}^{2}{\left(x \right)}' + assert latex(Si(x)**2) == r'\operatorname{Si}^{2}{\left(x \right)}' + assert latex(Ci(x)**2) == r'\operatorname{Ci}^{2}{\left(x \right)}' + assert latex(Chi(x)**2) == r'\operatorname{Chi}^{2}\left(x\right)' + assert latex(Chi(x)) == r'\operatorname{Chi}\left(x\right)' + assert latex(jacobi(n, a, b, x)) == \ + r'P_{n}^{\left(a,b\right)}\left(x\right)' + assert latex(jacobi(n, a, b, x)**2) == \ + r'\left(P_{n}^{\left(a,b\right)}\left(x\right)\right)^{2}' + assert latex(gegenbauer(n, a, x)) == \ + r'C_{n}^{\left(a\right)}\left(x\right)' + assert latex(gegenbauer(n, a, x)**2) == \ + r'\left(C_{n}^{\left(a\right)}\left(x\right)\right)^{2}' + assert latex(chebyshevt(n, x)) == r'T_{n}\left(x\right)' + assert latex(chebyshevt(n, x)**2) == \ + r'\left(T_{n}\left(x\right)\right)^{2}' + assert latex(chebyshevu(n, x)) == r'U_{n}\left(x\right)' + assert latex(chebyshevu(n, x)**2) == \ + r'\left(U_{n}\left(x\right)\right)^{2}' + assert latex(legendre(n, x)) == r'P_{n}\left(x\right)' + assert latex(legendre(n, x)**2) == r'\left(P_{n}\left(x\right)\right)^{2}' + assert latex(assoc_legendre(n, a, x)) == \ + r'P_{n}^{\left(a\right)}\left(x\right)' + assert latex(assoc_legendre(n, a, x)**2) == \ + r'\left(P_{n}^{\left(a\right)}\left(x\right)\right)^{2}' + assert latex(laguerre(n, x)) == r'L_{n}\left(x\right)' + assert latex(laguerre(n, x)**2) == r'\left(L_{n}\left(x\right)\right)^{2}' + assert latex(assoc_laguerre(n, a, x)) == \ + r'L_{n}^{\left(a\right)}\left(x\right)' + assert latex(assoc_laguerre(n, a, x)**2) == \ + r'\left(L_{n}^{\left(a\right)}\left(x\right)\right)^{2}' + assert latex(hermite(n, x)) == r'H_{n}\left(x\right)' + assert latex(hermite(n, x)**2) == r'\left(H_{n}\left(x\right)\right)^{2}' + + theta = Symbol("theta", real=True) + phi = Symbol("phi", real=True) + assert latex(Ynm(n, m, theta, phi)) == r'Y_{n}^{m}\left(\theta,\phi\right)' + assert latex(Ynm(n, m, theta, phi)**3) == \ + r'\left(Y_{n}^{m}\left(\theta,\phi\right)\right)^{3}' + assert latex(Znm(n, m, theta, phi)) == r'Z_{n}^{m}\left(\theta,\phi\right)' + assert latex(Znm(n, m, theta, phi)**3) == \ + r'\left(Z_{n}^{m}\left(\theta,\phi\right)\right)^{3}' + + # Test latex printing of function names with "_" + assert latex(polar_lift(0)) == \ + r"\operatorname{polar\_lift}{\left(0 \right)}" + assert latex(polar_lift(0)**3) == \ + r"\operatorname{polar\_lift}^{3}{\left(0 \right)}" + + assert latex(totient(n)) == r'\phi\left(n\right)' + assert latex(totient(n) ** 2) == r'\left(\phi\left(n\right)\right)^{2}' + + assert latex(reduced_totient(n)) == r'\lambda\left(n\right)' + assert latex(reduced_totient(n) ** 2) == \ + r'\left(\lambda\left(n\right)\right)^{2}' + + assert latex(divisor_sigma(x)) == r"\sigma\left(x\right)" + assert latex(divisor_sigma(x)**2) == r"\sigma^{2}\left(x\right)" + assert latex(divisor_sigma(x, y)) == r"\sigma_y\left(x\right)" + assert latex(divisor_sigma(x, y)**2) == r"\sigma^{2}_y\left(x\right)" + + assert latex(udivisor_sigma(x)) == r"\sigma^*\left(x\right)" + assert latex(udivisor_sigma(x)**2) == r"\sigma^*^{2}\left(x\right)" + assert latex(udivisor_sigma(x, y)) == r"\sigma^*_y\left(x\right)" + assert latex(udivisor_sigma(x, y)**2) == r"\sigma^*^{2}_y\left(x\right)" + + assert latex(primenu(n)) == r'\nu\left(n\right)' + assert latex(primenu(n) ** 2) == r'\left(\nu\left(n\right)\right)^{2}' + + assert latex(primeomega(n)) == r'\Omega\left(n\right)' + assert latex(primeomega(n) ** 2) == \ + r'\left(\Omega\left(n\right)\right)^{2}' + + assert latex(LambertW(n)) == r'W\left(n\right)' + assert latex(LambertW(n, -1)) == r'W_{-1}\left(n\right)' + assert latex(LambertW(n, k)) == r'W_{k}\left(n\right)' + assert latex(LambertW(n) * LambertW(n)) == r"W^{2}\left(n\right)" + assert latex(Pow(LambertW(n), 2)) == r"W^{2}\left(n\right)" + assert latex(LambertW(n)**k) == r"W^{k}\left(n\right)" + assert latex(LambertW(n, k)**p) == r"W^{p}_{k}\left(n\right)" + + assert latex(Mod(x, 7)) == r'x \bmod 7' + assert latex(Mod(x + 1, 7)) == r'\left(x + 1\right) \bmod 7' + assert latex(Mod(7, x + 1)) == r'7 \bmod \left(x + 1\right)' + assert latex(Mod(2 * x, 7)) == r'2 x \bmod 7' + assert latex(Mod(7, 2 * x)) == r'7 \bmod 2 x' + assert latex(Mod(x, 7) + 1) == r'\left(x \bmod 7\right) + 1' + assert latex(2 * Mod(x, 7)) == r'2 \left(x \bmod 7\right)' + assert latex(Mod(7, 2 * x)**n) == r'\left(7 \bmod 2 x\right)^{n}' + + # some unknown function name should get rendered with \operatorname + fjlkd = Function('fjlkd') + assert latex(fjlkd(x)) == r'\operatorname{fjlkd}{\left(x \right)}' + # even when it is referred to without an argument + assert latex(fjlkd) == r'\operatorname{fjlkd}' + + +# test that notation passes to subclasses of the same name only +def test_function_subclass_different_name(): + class mygamma(gamma): + pass + assert latex(mygamma) == r"\operatorname{mygamma}" + assert latex(mygamma(x)) == r"\operatorname{mygamma}{\left(x \right)}" + + +def test_hyper_printing(): + from sympy.abc import x, z + + assert latex(meijerg(Tuple(pi, pi, x), Tuple(1), + (0, 1), Tuple(1, 2, 3/pi), z)) == \ + r'{G_{4, 5}^{2, 3}\left(\begin{matrix} \pi, \pi, x & 1 \\0, 1 & 1, 2, '\ + r'\frac{3}{\pi} \end{matrix} \middle| {z} \right)}' + assert latex(meijerg(Tuple(), Tuple(1), (0,), Tuple(), z)) == \ + r'{G_{1, 1}^{1, 0}\left(\begin{matrix} & 1 \\0 & \end{matrix} \middle| {z} \right)}' + assert latex(hyper((x, 2), (3,), z)) == \ + r'{{}_{2}F_{1}\left(\begin{matrix} x, 2 ' \ + r'\\ 3 \end{matrix}\middle| {z} \right)}' + assert latex(hyper(Tuple(), Tuple(1), z)) == \ + r'{{}_{0}F_{1}\left(\begin{matrix} ' \ + r'\\ 1 \end{matrix}\middle| {z} \right)}' + + +def test_latex_bessel(): + from sympy.functions.special.bessel import (besselj, bessely, besseli, + besselk, hankel1, hankel2, + jn, yn, hn1, hn2) + from sympy.abc import z + assert latex(besselj(n, z**2)**k) == r'J^{k}_{n}\left(z^{2}\right)' + assert latex(bessely(n, z)) == r'Y_{n}\left(z\right)' + assert latex(besseli(n, z)) == r'I_{n}\left(z\right)' + assert latex(besselk(n, z)) == r'K_{n}\left(z\right)' + assert latex(hankel1(n, z**2)**2) == \ + r'\left(H^{(1)}_{n}\left(z^{2}\right)\right)^{2}' + assert latex(hankel2(n, z)) == r'H^{(2)}_{n}\left(z\right)' + assert latex(jn(n, z)) == r'j_{n}\left(z\right)' + assert latex(yn(n, z)) == r'y_{n}\left(z\right)' + assert latex(hn1(n, z)) == r'h^{(1)}_{n}\left(z\right)' + assert latex(hn2(n, z)) == r'h^{(2)}_{n}\left(z\right)' + + +def test_latex_fresnel(): + from sympy.functions.special.error_functions import (fresnels, fresnelc) + from sympy.abc import z + assert latex(fresnels(z)) == r'S\left(z\right)' + assert latex(fresnelc(z)) == r'C\left(z\right)' + assert latex(fresnels(z)**2) == r'S^{2}\left(z\right)' + assert latex(fresnelc(z)**2) == r'C^{2}\left(z\right)' + + +def test_latex_brackets(): + assert latex((-1)**x) == r"\left(-1\right)^{x}" + + +def test_latex_indexed(): + Psi_symbol = Symbol('Psi_0', complex=True, real=False) + Psi_indexed = IndexedBase(Symbol('Psi', complex=True, real=False)) + symbol_latex = latex(Psi_symbol * conjugate(Psi_symbol)) + indexed_latex = latex(Psi_indexed[0] * conjugate(Psi_indexed[0])) + # \\overline{{\\Psi}_{0}} {\\Psi}_{0} vs. \\Psi_{0} \\overline{\\Psi_{0}} + assert symbol_latex == r'\Psi_{0} \overline{\Psi_{0}}' + assert indexed_latex == r'\overline{{\Psi}_{0}} {\Psi}_{0}' + + # Symbol('gamma') gives r'\gamma' + interval = '\\mathrel{..}\\nobreak ' + assert latex(Indexed('x1', Symbol('i'))) == r'{x_{1}}_{i}' + assert latex(Indexed('x2', Idx('i'))) == r'{x_{2}}_{i}' + assert latex(Indexed('x3', Idx('i', Symbol('N')))) == r'{x_{3}}_{{i}_{0'+interval+'N - 1}}' + assert latex(Indexed('x3', Idx('i', Symbol('N')+1))) == r'{x_{3}}_{{i}_{0'+interval+'N}}' + assert latex(Indexed('x4', Idx('i', (Symbol('a'),Symbol('b'))))) == r'{x_{4}}_{{i}_{a'+interval+'b}}' + assert latex(IndexedBase('gamma')) == r'\gamma' + assert latex(IndexedBase('a b')) == r'a b' + assert latex(IndexedBase('a_b')) == r'a_{b}' + + +def test_latex_derivatives(): + # regular "d" for ordinary derivatives + assert latex(diff(x**3, x, evaluate=False)) == \ + r"\frac{d}{d x} x^{3}" + assert latex(diff(sin(x) + x**2, x, evaluate=False)) == \ + r"\frac{d}{d x} \left(x^{2} + \sin{\left(x \right)}\right)" + assert latex(diff(diff(sin(x) + x**2, x, evaluate=False), evaluate=False))\ + == \ + r"\frac{d^{2}}{d x^{2}} \left(x^{2} + \sin{\left(x \right)}\right)" + assert latex(diff(diff(diff(sin(x) + x**2, x, evaluate=False), evaluate=False), evaluate=False)) == \ + r"\frac{d^{3}}{d x^{3}} \left(x^{2} + \sin{\left(x \right)}\right)" + + # \partial for partial derivatives + assert latex(diff(sin(x * y), x, evaluate=False)) == \ + r"\frac{\partial}{\partial x} \sin{\left(x y \right)}" + assert latex(diff(sin(x * y) + x**2, x, evaluate=False)) == \ + r"\frac{\partial}{\partial x} \left(x^{2} + \sin{\left(x y \right)}\right)" + assert latex(diff(diff(sin(x*y) + x**2, x, evaluate=False), x, evaluate=False)) == \ + r"\frac{\partial^{2}}{\partial x^{2}} \left(x^{2} + \sin{\left(x y \right)}\right)" + assert latex(diff(diff(diff(sin(x*y) + x**2, x, evaluate=False), x, evaluate=False), x, evaluate=False)) == \ + r"\frac{\partial^{3}}{\partial x^{3}} \left(x^{2} + \sin{\left(x y \right)}\right)" + + # mixed partial derivatives + f = Function("f") + assert latex(diff(diff(f(x, y), x, evaluate=False), y, evaluate=False)) == \ + r"\frac{\partial^{2}}{\partial y\partial x} " + latex(f(x, y)) + + assert latex(diff(diff(diff(f(x, y), x, evaluate=False), x, evaluate=False), y, evaluate=False)) == \ + r"\frac{\partial^{3}}{\partial y\partial x^{2}} " + latex(f(x, y)) + + # for negative nested Derivative + assert latex(diff(-diff(y**2,x,evaluate=False),x,evaluate=False)) == r'\frac{d}{d x} \left(- \frac{d}{d x} y^{2}\right)' + assert latex(diff(diff(-diff(diff(y,x,evaluate=False),x,evaluate=False),x,evaluate=False),x,evaluate=False)) == \ + r'\frac{d^{2}}{d x^{2}} \left(- \frac{d^{2}}{d x^{2}} y\right)' + + # use ordinary d when one of the variables has been integrated out + assert latex(diff(Integral(exp(-x*y), (x, 0, oo)), y, evaluate=False)) == \ + r"\frac{d}{d y} \int\limits_{0}^{\infty} e^{- x y}\, dx" + + # Derivative wrapped in power: + assert latex(diff(x, x, evaluate=False)**2) == \ + r"\left(\frac{d}{d x} x\right)^{2}" + + assert latex(diff(f(x), x)**2) == \ + r"\left(\frac{d}{d x} f{\left(x \right)}\right)^{2}" + + assert latex(diff(f(x), (x, n))) == \ + r"\frac{d^{n}}{d x^{n}} f{\left(x \right)}" + + x1 = Symbol('x1') + x2 = Symbol('x2') + assert latex(diff(f(x1, x2), x1)) == r'\frac{\partial}{\partial x_{1}} f{\left(x_{1},x_{2} \right)}' + + n1 = Symbol('n1') + assert latex(diff(f(x), (x, n1))) == r'\frac{d^{n_{1}}}{d x^{n_{1}}} f{\left(x \right)}' + + n2 = Symbol('n2') + assert latex(diff(f(x), (x, Max(n1, n2)))) == \ + r'\frac{d^{\max\left(n_{1}, n_{2}\right)}}{d x^{\max\left(n_{1}, n_{2}\right)}} f{\left(x \right)}' + + # set diff operator + assert latex(diff(f(x), x), diff_operator="rd") == r'\frac{\mathrm{d}}{\mathrm{d} x} f{\left(x \right)}' + + +def test_latex_subs(): + assert latex(Subs(x*y, (x, y), (1, 2))) == r'\left. x y \right|_{\substack{ x=1\\ y=2 }}' + + +def test_latex_integrals(): + assert latex(Integral(log(x), x)) == r"\int \log{\left(x \right)}\, dx" + assert latex(Integral(x**2, (x, 0, 1))) == \ + r"\int\limits_{0}^{1} x^{2}\, dx" + assert latex(Integral(x**2, (x, 10, 20))) == \ + r"\int\limits_{10}^{20} x^{2}\, dx" + assert latex(Integral(y*x**2, (x, 0, 1), y)) == \ + r"\int\int\limits_{0}^{1} x^{2} y\, dx\, dy" + assert latex(Integral(y*x**2, (x, 0, 1), y), mode='equation*') == \ + r"\begin{equation*}\int\int\limits_{0}^{1} x^{2} y\, dx\, dy\end{equation*}" + assert latex(Integral(y*x**2, (x, 0, 1), y), mode='equation*', itex=True) \ + == r"$$\int\int_{0}^{1} x^{2} y\, dx\, dy$$" + assert latex(Integral(x, (x, 0))) == r"\int\limits^{0} x\, dx" + assert latex(Integral(x*y, x, y)) == r"\iint x y\, dx\, dy" + assert latex(Integral(x*y*z, x, y, z)) == r"\iiint x y z\, dx\, dy\, dz" + assert latex(Integral(x*y*z*t, x, y, z, t)) == \ + r"\iiiint t x y z\, dx\, dy\, dz\, dt" + assert latex(Integral(x, x, x, x, x, x, x)) == \ + r"\int\int\int\int\int\int x\, dx\, dx\, dx\, dx\, dx\, dx" + assert latex(Integral(x, x, y, (z, 0, 1))) == \ + r"\int\limits_{0}^{1}\int\int x\, dx\, dy\, dz" + + # for negative nested Integral + assert latex(Integral(-Integral(y**2,x),x)) == \ + r'\int \left(- \int y^{2}\, dx\right)\, dx' + assert latex(Integral(-Integral(-Integral(y,x),x),x)) == \ + r'\int \left(- \int \left(- \int y\, dx\right)\, dx\right)\, dx' + + # fix issue #10806 + assert latex(Integral(z, z)**2) == r"\left(\int z\, dz\right)^{2}" + assert latex(Integral(x + z, z)) == r"\int \left(x + z\right)\, dz" + assert latex(Integral(x+z/2, z)) == \ + r"\int \left(x + \frac{z}{2}\right)\, dz" + assert latex(Integral(x**y, z)) == r"\int x^{y}\, dz" + + # set diff operator + assert latex(Integral(x, x), diff_operator="rd") == r'\int x\, \mathrm{d}x' + assert latex(Integral(x, (x, 0, 1)), diff_operator="rd") == r'\int\limits_{0}^{1} x\, \mathrm{d}x' + + +def test_latex_sets(): + for s in (frozenset, set): + assert latex(s([x*y, x**2])) == r"\left\{x^{2}, x y\right\}" + assert latex(s(range(1, 6))) == r"\left\{1, 2, 3, 4, 5\right\}" + assert latex(s(range(1, 13))) == \ + r"\left\{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12\right\}" + + s = FiniteSet + assert latex(s(*[x*y, x**2])) == r"\left\{x^{2}, x y\right\}" + assert latex(s(*range(1, 6))) == r"\left\{1, 2, 3, 4, 5\right\}" + assert latex(s(*range(1, 13))) == \ + r"\left\{1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12\right\}" + + +def test_latex_SetExpr(): + iv = Interval(1, 3) + se = SetExpr(iv) + assert latex(se) == r"SetExpr\left(\left[1, 3\right]\right)" + + +def test_latex_Range(): + assert latex(Range(1, 51)) == r'\left\{1, 2, \ldots, 50\right\}' + assert latex(Range(1, 4)) == r'\left\{1, 2, 3\right\}' + assert latex(Range(0, 3, 1)) == r'\left\{0, 1, 2\right\}' + assert latex(Range(0, 30, 1)) == r'\left\{0, 1, \ldots, 29\right\}' + assert latex(Range(30, 1, -1)) == r'\left\{30, 29, \ldots, 2\right\}' + assert latex(Range(0, oo, 2)) == r'\left\{0, 2, \ldots\right\}' + assert latex(Range(oo, -2, -2)) == r'\left\{\ldots, 2, 0\right\}' + assert latex(Range(-2, -oo, -1)) == r'\left\{-2, -3, \ldots\right\}' + assert latex(Range(-oo, oo)) == r'\left\{\ldots, -1, 0, 1, \ldots\right\}' + assert latex(Range(oo, -oo, -1)) == r'\left\{\ldots, 1, 0, -1, \ldots\right\}' + + a, b, c = symbols('a:c') + assert latex(Range(a, b, c)) == r'\text{Range}\left(a, b, c\right)' + assert latex(Range(a, 10, 1)) == r'\text{Range}\left(a, 10\right)' + assert latex(Range(0, b, 1)) == r'\text{Range}\left(b\right)' + assert latex(Range(0, 10, c)) == r'\text{Range}\left(0, 10, c\right)' + + i = Symbol('i', integer=True) + n = Symbol('n', negative=True, integer=True) + p = Symbol('p', positive=True, integer=True) + + assert latex(Range(i, i + 3)) == r'\left\{i, i + 1, i + 2\right\}' + assert latex(Range(-oo, n, 2)) == r'\left\{\ldots, n - 4, n - 2\right\}' + assert latex(Range(p, oo)) == r'\left\{p, p + 1, \ldots\right\}' + # The following will work if __iter__ is improved + # assert latex(Range(-3, p + 7)) == r'\left\{-3, -2, \ldots, p + 6\right\}' + # Must have integer assumptions + assert latex(Range(a, a + 3)) == r'\text{Range}\left(a, a + 3\right)' + + +def test_latex_sequences(): + s1 = SeqFormula(a**2, (0, oo)) + s2 = SeqPer((1, 2)) + + latex_str = r'\left[0, 1, 4, 9, \ldots\right]' + assert latex(s1) == latex_str + + latex_str = r'\left[1, 2, 1, 2, \ldots\right]' + assert latex(s2) == latex_str + + s3 = SeqFormula(a**2, (0, 2)) + s4 = SeqPer((1, 2), (0, 2)) + + latex_str = r'\left[0, 1, 4\right]' + assert latex(s3) == latex_str + + latex_str = r'\left[1, 2, 1\right]' + assert latex(s4) == latex_str + + s5 = SeqFormula(a**2, (-oo, 0)) + s6 = SeqPer((1, 2), (-oo, 0)) + + latex_str = r'\left[\ldots, 9, 4, 1, 0\right]' + assert latex(s5) == latex_str + + latex_str = r'\left[\ldots, 2, 1, 2, 1\right]' + assert latex(s6) == latex_str + + latex_str = r'\left[1, 3, 5, 11, \ldots\right]' + assert latex(SeqAdd(s1, s2)) == latex_str + + latex_str = r'\left[1, 3, 5\right]' + assert latex(SeqAdd(s3, s4)) == latex_str + + latex_str = r'\left[\ldots, 11, 5, 3, 1\right]' + assert latex(SeqAdd(s5, s6)) == latex_str + + latex_str = r'\left[0, 2, 4, 18, \ldots\right]' + assert latex(SeqMul(s1, s2)) == latex_str + + latex_str = r'\left[0, 2, 4\right]' + assert latex(SeqMul(s3, s4)) == latex_str + + latex_str = r'\left[\ldots, 18, 4, 2, 0\right]' + assert latex(SeqMul(s5, s6)) == latex_str + + # Sequences with symbolic limits, issue 12629 + s7 = SeqFormula(a**2, (a, 0, x)) + latex_str = r'\left\{a^{2}\right\}_{a=0}^{x}' + assert latex(s7) == latex_str + + b = Symbol('b') + s8 = SeqFormula(b*a**2, (a, 0, 2)) + latex_str = r'\left[0, b, 4 b\right]' + assert latex(s8) == latex_str + + +def test_latex_FourierSeries(): + latex_str = \ + r'2 \sin{\left(x \right)} - \sin{\left(2 x \right)} + \frac{2 \sin{\left(3 x \right)}}{3} + \ldots' + assert latex(fourier_series(x, (x, -pi, pi))) == latex_str + + +def test_latex_FormalPowerSeries(): + latex_str = r'\sum_{k=1}^{\infty} - \frac{\left(-1\right)^{- k} x^{k}}{k}' + assert latex(fps(log(1 + x))) == latex_str + + +def test_latex_intervals(): + a = Symbol('a', real=True) + assert latex(Interval(0, 0)) == r"\left\{0\right\}" + assert latex(Interval(0, a)) == r"\left[0, a\right]" + assert latex(Interval(0, a, False, False)) == r"\left[0, a\right]" + assert latex(Interval(0, a, True, False)) == r"\left(0, a\right]" + assert latex(Interval(0, a, False, True)) == r"\left[0, a\right)" + assert latex(Interval(0, a, True, True)) == r"\left(0, a\right)" + + +def test_latex_AccumuBounds(): + a = Symbol('a', real=True) + assert latex(AccumBounds(0, 1)) == r"\left\langle 0, 1\right\rangle" + assert latex(AccumBounds(0, a)) == r"\left\langle 0, a\right\rangle" + assert latex(AccumBounds(a + 1, a + 2)) == \ + r"\left\langle a + 1, a + 2\right\rangle" + + +def test_latex_emptyset(): + assert latex(S.EmptySet) == r"\emptyset" + + +def test_latex_universalset(): + assert latex(S.UniversalSet) == r"\mathbb{U}" + + +def test_latex_commutator(): + A = Operator('A') + B = Operator('B') + comm = Commutator(B, A) + assert latex(comm.doit()) == r"- (A B - B A)" + + +def test_latex_union(): + assert latex(Union(Interval(0, 1), Interval(2, 3))) == \ + r"\left[0, 1\right] \cup \left[2, 3\right]" + assert latex(Union(Interval(1, 1), Interval(2, 2), Interval(3, 4))) == \ + r"\left\{1, 2\right\} \cup \left[3, 4\right]" + + +def test_latex_intersection(): + assert latex(Intersection(Interval(0, 1), Interval(x, y))) == \ + r"\left[0, 1\right] \cap \left[x, y\right]" + + +def test_latex_symmetric_difference(): + assert latex(SymmetricDifference(Interval(2, 5), Interval(4, 7), + evaluate=False)) == \ + r'\left[2, 5\right] \triangle \left[4, 7\right]' + + +def test_latex_Complement(): + assert latex(Complement(S.Reals, S.Naturals)) == \ + r"\mathbb{R} \setminus \mathbb{N}" + + +def test_latex_productset(): + line = Interval(0, 1) + bigline = Interval(0, 10) + fset = FiniteSet(1, 2, 3) + assert latex(line**2) == r"%s^{2}" % latex(line) + assert latex(line**10) == r"%s^{10}" % latex(line) + assert latex((line * bigline * fset).flatten()) == r"%s \times %s \times %s" % ( + latex(line), latex(bigline), latex(fset)) + + +def test_latex_powerset(): + fset = FiniteSet(1, 2, 3) + assert latex(PowerSet(fset)) == r'\mathcal{P}\left(\left\{1, 2, 3\right\}\right)' + + +def test_latex_ordinals(): + w = OrdinalOmega() + assert latex(w) == r"\omega" + wp = OmegaPower(2, 3) + assert latex(wp) == r'3 \omega^{2}' + assert latex(Ordinal(wp, OmegaPower(1, 1))) == r'3 \omega^{2} + \omega' + assert latex(Ordinal(OmegaPower(2, 1), OmegaPower(1, 2))) == r'\omega^{2} + 2 \omega' + + +def test_set_operators_parenthesis(): + a, b, c, d = symbols('a:d') + A = FiniteSet(a) + B = FiniteSet(b) + C = FiniteSet(c) + D = FiniteSet(d) + + U1 = Union(A, B, evaluate=False) + U2 = Union(C, D, evaluate=False) + I1 = Intersection(A, B, evaluate=False) + I2 = Intersection(C, D, evaluate=False) + C1 = Complement(A, B, evaluate=False) + C2 = Complement(C, D, evaluate=False) + D1 = SymmetricDifference(A, B, evaluate=False) + D2 = SymmetricDifference(C, D, evaluate=False) + # XXX ProductSet does not support evaluate keyword + P1 = ProductSet(A, B) + P2 = ProductSet(C, D) + + assert latex(Intersection(A, U2, evaluate=False)) == \ + r'\left\{a\right\} \cap ' \ + r'\left(\left\{c\right\} \cup \left\{d\right\}\right)' + assert latex(Intersection(U1, U2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\cap \left(\left\{c\right\} \cup \left\{d\right\}\right)' + assert latex(Intersection(C1, C2, evaluate=False)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \cap \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(Intersection(D1, D2, evaluate=False)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \cap \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + assert latex(Intersection(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) ' \ + r'\cap \left(\left\{c\right\} \times ' \ + r'\left\{d\right\}\right)' + + assert latex(Union(A, I2, evaluate=False)) == \ + r'\left\{a\right\} \cup ' \ + r'\left(\left\{c\right\} \cap \left\{d\right\}\right)' + assert latex(Union(I1, I2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\cup \left(\left\{c\right\} \cap \left\{d\right\}\right)' + assert latex(Union(C1, C2, evaluate=False)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \cup \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(Union(D1, D2, evaluate=False)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \cup \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + assert latex(Union(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) ' \ + r'\cup \left(\left\{c\right\} \times ' \ + r'\left\{d\right\}\right)' + + assert latex(Complement(A, C2, evaluate=False)) == \ + r'\left\{a\right\} \setminus \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(Complement(U1, U2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\setminus \left(\left\{c\right\} \cup ' \ + r'\left\{d\right\}\right)' + assert latex(Complement(I1, I2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\setminus \left(\left\{c\right\} \cap ' \ + r'\left\{d\right\}\right)' + assert latex(Complement(D1, D2, evaluate=False)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \setminus ' \ + r'\left(\left\{c\right\} \triangle \left\{d\right\}\right)' + assert latex(Complement(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) '\ + r'\setminus \left(\left\{c\right\} \times '\ + r'\left\{d\right\}\right)' + + assert latex(SymmetricDifference(A, D2, evaluate=False)) == \ + r'\left\{a\right\} \triangle \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + assert latex(SymmetricDifference(U1, U2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\triangle \left(\left\{c\right\} \cup ' \ + r'\left\{d\right\}\right)' + assert latex(SymmetricDifference(I1, I2, evaluate=False)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\triangle \left(\left\{c\right\} \cap ' \ + r'\left\{d\right\}\right)' + assert latex(SymmetricDifference(C1, C2, evaluate=False)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \triangle ' \ + r'\left(\left\{c\right\} \setminus \left\{d\right\}\right)' + assert latex(SymmetricDifference(P1, P2, evaluate=False)) == \ + r'\left(\left\{a\right\} \times \left\{b\right\}\right) ' \ + r'\triangle \left(\left\{c\right\} \times ' \ + r'\left\{d\right\}\right)' + + # XXX This can be incorrect since cartesian product is not associative + assert latex(ProductSet(A, P2).flatten()) == \ + r'\left\{a\right\} \times \left\{c\right\} \times ' \ + r'\left\{d\right\}' + assert latex(ProductSet(U1, U2)) == \ + r'\left(\left\{a\right\} \cup \left\{b\right\}\right) ' \ + r'\times \left(\left\{c\right\} \cup ' \ + r'\left\{d\right\}\right)' + assert latex(ProductSet(I1, I2)) == \ + r'\left(\left\{a\right\} \cap \left\{b\right\}\right) ' \ + r'\times \left(\left\{c\right\} \cap ' \ + r'\left\{d\right\}\right)' + assert latex(ProductSet(C1, C2)) == \ + r'\left(\left\{a\right\} \setminus ' \ + r'\left\{b\right\}\right) \times \left(\left\{c\right\} ' \ + r'\setminus \left\{d\right\}\right)' + assert latex(ProductSet(D1, D2)) == \ + r'\left(\left\{a\right\} \triangle ' \ + r'\left\{b\right\}\right) \times \left(\left\{c\right\} ' \ + r'\triangle \left\{d\right\}\right)' + + +def test_latex_Complexes(): + assert latex(S.Complexes) == r"\mathbb{C}" + + +def test_latex_Naturals(): + assert latex(S.Naturals) == r"\mathbb{N}" + + +def test_latex_Naturals0(): + assert latex(S.Naturals0) == r"\mathbb{N}_0" + + +def test_latex_Integers(): + assert latex(S.Integers) == r"\mathbb{Z}" + + +def test_latex_ImageSet(): + x = Symbol('x') + assert latex(ImageSet(Lambda(x, x**2), S.Naturals)) == \ + r"\left\{x^{2}\; \middle|\; x \in \mathbb{N}\right\}" + + y = Symbol('y') + imgset = ImageSet(Lambda((x, y), x + y), {1, 2, 3}, {3, 4}) + assert latex(imgset) == \ + r"\left\{x + y\; \middle|\; x \in \left\{1, 2, 3\right\}, y \in \left\{3, 4\right\}\right\}" + + imgset = ImageSet(Lambda(((x, y),), x + y), ProductSet({1, 2, 3}, {3, 4})) + assert latex(imgset) == \ + r"\left\{x + y\; \middle|\; \left( x, \ y\right) \in \left\{1, 2, 3\right\} \times \left\{3, 4\right\}\right\}" + + +def test_latex_ConditionSet(): + x = Symbol('x') + assert latex(ConditionSet(x, Eq(x**2, 1), S.Reals)) == \ + r"\left\{x\; \middle|\; x \in \mathbb{R} \wedge x^{2} = 1 \right\}" + assert latex(ConditionSet(x, Eq(x**2, 1), S.UniversalSet)) == \ + r"\left\{x\; \middle|\; x^{2} = 1 \right\}" + + +def test_latex_ComplexRegion(): + assert latex(ComplexRegion(Interval(3, 5)*Interval(4, 6))) == \ + r"\left\{x + y i\; \middle|\; x, y \in \left[3, 5\right] \times \left[4, 6\right] \right\}" + assert latex(ComplexRegion(Interval(0, 1)*Interval(0, 2*pi), polar=True)) == \ + r"\left\{r \left(i \sin{\left(\theta \right)} + \cos{\left(\theta "\ + r"\right)}\right)\; \middle|\; r, \theta \in \left[0, 1\right] \times \left[0, 2 \pi\right) \right\}" + + +def test_latex_Contains(): + x = Symbol('x') + assert latex(Contains(x, S.Naturals)) == r"x \in \mathbb{N}" + + +def test_latex_sum(): + assert latex(Sum(x*y**2, (x, -2, 2), (y, -5, 5))) == \ + r"\sum_{\substack{-2 \leq x \leq 2\\-5 \leq y \leq 5}} x y^{2}" + assert latex(Sum(x**2, (x, -2, 2))) == \ + r"\sum_{x=-2}^{2} x^{2}" + assert latex(Sum(x**2 + y, (x, -2, 2))) == \ + r"\sum_{x=-2}^{2} \left(x^{2} + y\right)" + assert latex(Sum(x**2 + y, (x, -2, 2))**2) == \ + r"\left(\sum_{x=-2}^{2} \left(x^{2} + y\right)\right)^{2}" + + +def test_latex_product(): + assert latex(Product(x*y**2, (x, -2, 2), (y, -5, 5))) == \ + r"\prod_{\substack{-2 \leq x \leq 2\\-5 \leq y \leq 5}} x y^{2}" + assert latex(Product(x**2, (x, -2, 2))) == \ + r"\prod_{x=-2}^{2} x^{2}" + assert latex(Product(x**2 + y, (x, -2, 2))) == \ + r"\prod_{x=-2}^{2} \left(x^{2} + y\right)" + + assert latex(Product(x, (x, -2, 2))**2) == \ + r"\left(\prod_{x=-2}^{2} x\right)^{2}" + + +def test_latex_limits(): + assert latex(Limit(x, x, oo)) == r"\lim_{x \to \infty} x" + + # issue 8175 + f = Function('f') + assert latex(Limit(f(x), x, 0)) == r"\lim_{x \to 0^+} f{\left(x \right)}" + assert latex(Limit(f(x), x, 0, "-")) == \ + r"\lim_{x \to 0^-} f{\left(x \right)}" + + # issue #10806 + assert latex(Limit(f(x), x, 0)**2) == \ + r"\left(\lim_{x \to 0^+} f{\left(x \right)}\right)^{2}" + # bi-directional limit + assert latex(Limit(f(x), x, 0, dir='+-')) == \ + r"\lim_{x \to 0} f{\left(x \right)}" + + +def test_latex_log(): + assert latex(log(x)) == r"\log{\left(x \right)}" + assert latex(log(x), ln_notation=True) == r"\ln{\left(x \right)}" + assert latex(log(x) + log(y)) == \ + r"\log{\left(x \right)} + \log{\left(y \right)}" + assert latex(log(x) + log(y), ln_notation=True) == \ + r"\ln{\left(x \right)} + \ln{\left(y \right)}" + assert latex(pow(log(x), x)) == r"\log{\left(x \right)}^{x}" + assert latex(pow(log(x), x), ln_notation=True) == \ + r"\ln{\left(x \right)}^{x}" + + +def test_issue_3568(): + beta = Symbol(r'\beta') + y = beta + x + assert latex(y) in [r'\beta + x', r'x + \beta'] + + beta = Symbol(r'beta') + y = beta + x + assert latex(y) in [r'\beta + x', r'x + \beta'] + + +def test_latex(): + assert latex((2*tau)**Rational(7, 2)) == r"8 \sqrt{2} \tau^{\frac{7}{2}}" + assert latex((2*mu)**Rational(7, 2), mode='equation*') == \ + r"\begin{equation*}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation*}" + assert latex((2*mu)**Rational(7, 2), mode='equation', itex=True) == \ + r"$$8 \sqrt{2} \mu^{\frac{7}{2}}$$" + assert latex([2/x, y]) == r"\left[ \frac{2}{x}, \ y\right]" + + +def test_latex_dict(): + d = {Rational(1): 1, x**2: 2, x: 3, x**3: 4} + assert latex(d) == \ + r'\left\{ 1 : 1, \ x : 3, \ x^{2} : 2, \ x^{3} : 4\right\}' + D = Dict(d) + assert latex(D) == \ + r'\left\{ 1 : 1, \ x : 3, \ x^{2} : 2, \ x^{3} : 4\right\}' + + +def test_latex_list(): + ll = [Symbol('omega1'), Symbol('a'), Symbol('alpha')] + assert latex(ll) == r'\left[ \omega_{1}, \ a, \ \alpha\right]' + + +def test_latex_NumberSymbols(): + assert latex(S.Catalan) == "G" + assert latex(S.EulerGamma) == r"\gamma" + assert latex(S.Exp1) == "e" + assert latex(S.GoldenRatio) == r"\phi" + assert latex(S.Pi) == r"\pi" + assert latex(S.TribonacciConstant) == r"\text{TribonacciConstant}" + + +def test_latex_rational(): + # tests issue 3973 + assert latex(-Rational(1, 2)) == r"- \frac{1}{2}" + assert latex(Rational(-1, 2)) == r"- \frac{1}{2}" + assert latex(Rational(1, -2)) == r"- \frac{1}{2}" + assert latex(-Rational(-1, 2)) == r"\frac{1}{2}" + assert latex(-Rational(1, 2)*x) == r"- \frac{x}{2}" + assert latex(-Rational(1, 2)*x + Rational(-2, 3)*y) == \ + r"- \frac{x}{2} - \frac{2 y}{3}" + + +def test_latex_inverse(): + # tests issue 4129 + assert latex(1/x) == r"\frac{1}{x}" + assert latex(1/(x + y)) == r"\frac{1}{x + y}" + + +def test_latex_DiracDelta(): + assert latex(DiracDelta(x)) == r"\delta\left(x\right)" + assert latex(DiracDelta(x)**2) == r"\left(\delta\left(x\right)\right)^{2}" + assert latex(DiracDelta(x, 0)) == r"\delta\left(x\right)" + assert latex(DiracDelta(x, 5)) == \ + r"\delta^{\left( 5 \right)}\left( x \right)" + assert latex(DiracDelta(x, 5)**2) == \ + r"\left(\delta^{\left( 5 \right)}\left( x \right)\right)^{2}" + + +def test_latex_Heaviside(): + assert latex(Heaviside(x)) == r"\theta\left(x\right)" + assert latex(Heaviside(x)**2) == r"\left(\theta\left(x\right)\right)^{2}" + + +def test_latex_KroneckerDelta(): + assert latex(KroneckerDelta(x, y)) == r"\delta_{x y}" + assert latex(KroneckerDelta(x, y + 1)) == r"\delta_{x, y + 1}" + # issue 6578 + assert latex(KroneckerDelta(x + 1, y)) == r"\delta_{y, x + 1}" + assert latex(Pow(KroneckerDelta(x, y), 2, evaluate=False)) == \ + r"\left(\delta_{x y}\right)^{2}" + + +def test_latex_LeviCivita(): + assert latex(LeviCivita(x, y, z)) == r"\varepsilon_{x y z}" + assert latex(LeviCivita(x, y, z)**2) == \ + r"\left(\varepsilon_{x y z}\right)^{2}" + assert latex(LeviCivita(x, y, z + 1)) == r"\varepsilon_{x, y, z + 1}" + assert latex(LeviCivita(x, y + 1, z)) == r"\varepsilon_{x, y + 1, z}" + assert latex(LeviCivita(x + 1, y, z)) == r"\varepsilon_{x + 1, y, z}" + + +def test_mode(): + expr = x + y + assert latex(expr) == r'x + y' + assert latex(expr, mode='plain') == r'x + y' + assert latex(expr, mode='inline') == r'$x + y$' + assert latex( + expr, mode='equation*') == r'\begin{equation*}x + y\end{equation*}' + assert latex( + expr, mode='equation') == r'\begin{equation}x + y\end{equation}' + raises(ValueError, lambda: latex(expr, mode='foo')) + + +def test_latex_mathieu(): + assert latex(mathieuc(x, y, z)) == r"C\left(x, y, z\right)" + assert latex(mathieus(x, y, z)) == r"S\left(x, y, z\right)" + assert latex(mathieuc(x, y, z)**2) == r"C\left(x, y, z\right)^{2}" + assert latex(mathieus(x, y, z)**2) == r"S\left(x, y, z\right)^{2}" + assert latex(mathieucprime(x, y, z)) == r"C^{\prime}\left(x, y, z\right)" + assert latex(mathieusprime(x, y, z)) == r"S^{\prime}\left(x, y, z\right)" + assert latex(mathieucprime(x, y, z)**2) == r"C^{\prime}\left(x, y, z\right)^{2}" + assert latex(mathieusprime(x, y, z)**2) == r"S^{\prime}\left(x, y, z\right)^{2}" + +def test_latex_Piecewise(): + p = Piecewise((x, x < 1), (x**2, True)) + assert latex(p) == r"\begin{cases} x & \text{for}\: x < 1 \\x^{2} &" \ + r" \text{otherwise} \end{cases}" + assert latex(p, itex=True) == \ + r"\begin{cases} x & \text{for}\: x \lt 1 \\x^{2} &" \ + r" \text{otherwise} \end{cases}" + p = Piecewise((x, x < 0), (0, x >= 0)) + assert latex(p) == r'\begin{cases} x & \text{for}\: x < 0 \\0 &' \ + r' \text{otherwise} \end{cases}' + A, B = symbols("A B", commutative=False) + p = Piecewise((A**2, Eq(A, B)), (A*B, True)) + s = r"\begin{cases} A^{2} & \text{for}\: A = B \\A B & \text{otherwise} \end{cases}" + assert latex(p) == s + assert latex(A*p) == r"A \left(%s\right)" % s + assert latex(p*A) == r"\left(%s\right) A" % s + assert latex(Piecewise((x, x < 1), (x**2, x < 2))) == \ + r'\begin{cases} x & ' \ + r'\text{for}\: x < 1 \\x^{2} & \text{for}\: x < 2 \end{cases}' + + +def test_latex_Matrix(): + M = Matrix([[1 + x, y], [y, x - 1]]) + assert latex(M) == \ + r'\left[\begin{matrix}x + 1 & y\\y & x - 1\end{matrix}\right]' + assert latex(M, mode='inline') == \ + r'$\left[\begin{smallmatrix}x + 1 & y\\' \ + r'y & x - 1\end{smallmatrix}\right]$' + assert latex(M, mat_str='array') == \ + r'\left[\begin{array}{cc}x + 1 & y\\y & x - 1\end{array}\right]' + assert latex(M, mat_str='bmatrix') == \ + r'\left[\begin{bmatrix}x + 1 & y\\y & x - 1\end{bmatrix}\right]' + assert latex(M, mat_delim=None, mat_str='bmatrix') == \ + r'\begin{bmatrix}x + 1 & y\\y & x - 1\end{bmatrix}' + + M2 = Matrix(1, 11, range(11)) + assert latex(M2) == \ + r'\left[\begin{array}{ccccccccccc}' \ + r'0 & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9 & 10\end{array}\right]' + + +def test_latex_matrix_with_functions(): + t = symbols('t') + theta1 = symbols('theta1', cls=Function) + + M = Matrix([[sin(theta1(t)), cos(theta1(t))], + [cos(theta1(t).diff(t)), sin(theta1(t).diff(t))]]) + + expected = (r'\left[\begin{matrix}\sin{\left(' + r'\theta_{1}{\left(t \right)} \right)} & ' + r'\cos{\left(\theta_{1}{\left(t \right)} \right)' + r'}\\\cos{\left(\frac{d}{d t} \theta_{1}{\left(t ' + r'\right)} \right)} & \sin{\left(\frac{d}{d t} ' + r'\theta_{1}{\left(t \right)} \right' + r')}\end{matrix}\right]') + + assert latex(M) == expected + + +def test_latex_NDimArray(): + x, y, z, w = symbols("x y z w") + + for ArrayType in (ImmutableDenseNDimArray, ImmutableSparseNDimArray, + MutableDenseNDimArray, MutableSparseNDimArray): + # Basic: scalar array + M = ArrayType(x) + + assert latex(M) == r"x" + + M = ArrayType([[1 / x, y], [z, w]]) + M1 = ArrayType([1 / x, y, z]) + + M2 = tensorproduct(M1, M) + M3 = tensorproduct(M, M) + + assert latex(M) == \ + r'\left[\begin{matrix}\frac{1}{x} & y\\z & w\end{matrix}\right]' + assert latex(M1) == \ + r"\left[\begin{matrix}\frac{1}{x} & y & z\end{matrix}\right]" + assert latex(M2) == \ + r"\left[\begin{matrix}" \ + r"\left[\begin{matrix}\frac{1}{x^{2}} & \frac{y}{x}\\\frac{z}{x} & \frac{w}{x}\end{matrix}\right] & " \ + r"\left[\begin{matrix}\frac{y}{x} & y^{2}\\y z & w y\end{matrix}\right] & " \ + r"\left[\begin{matrix}\frac{z}{x} & y z\\z^{2} & w z\end{matrix}\right]" \ + r"\end{matrix}\right]" + assert latex(M3) == \ + r"""\left[\begin{matrix}"""\ + r"""\left[\begin{matrix}\frac{1}{x^{2}} & \frac{y}{x}\\\frac{z}{x} & \frac{w}{x}\end{matrix}\right] & """\ + r"""\left[\begin{matrix}\frac{y}{x} & y^{2}\\y z & w y\end{matrix}\right]\\"""\ + r"""\left[\begin{matrix}\frac{z}{x} & y z\\z^{2} & w z\end{matrix}\right] & """\ + r"""\left[\begin{matrix}\frac{w}{x} & w y\\w z & w^{2}\end{matrix}\right]"""\ + r"""\end{matrix}\right]""" + + Mrow = ArrayType([[x, y, 1/z]]) + Mcolumn = ArrayType([[x], [y], [1/z]]) + Mcol2 = ArrayType([Mcolumn.tolist()]) + + assert latex(Mrow) == \ + r"\left[\left[\begin{matrix}x & y & \frac{1}{z}\end{matrix}\right]\right]" + assert latex(Mcolumn) == \ + r"\left[\begin{matrix}x\\y\\\frac{1}{z}\end{matrix}\right]" + assert latex(Mcol2) == \ + r'\left[\begin{matrix}\left[\begin{matrix}x\\y\\\frac{1}{z}\end{matrix}\right]\end{matrix}\right]' + + +def test_latex_mul_symbol(): + assert latex(4*4**x, mul_symbol='times') == r"4 \times 4^{x}" + assert latex(4*4**x, mul_symbol='dot') == r"4 \cdot 4^{x}" + assert latex(4*4**x, mul_symbol='ldot') == r"4 \,.\, 4^{x}" + + assert latex(4*x, mul_symbol='times') == r"4 \times x" + assert latex(4*x, mul_symbol='dot') == r"4 \cdot x" + assert latex(4*x, mul_symbol='ldot') == r"4 \,.\, x" + + +def test_latex_issue_4381(): + y = 4*4**log(2) + assert latex(y) == r'4 \cdot 4^{\log{\left(2 \right)}}' + assert latex(1/y) == r'\frac{1}{4 \cdot 4^{\log{\left(2 \right)}}}' + + +def test_latex_issue_4576(): + assert latex(Symbol("beta_13_2")) == r"\beta_{13 2}" + assert latex(Symbol("beta_132_20")) == r"\beta_{132 20}" + assert latex(Symbol("beta_13")) == r"\beta_{13}" + assert latex(Symbol("x_a_b")) == r"x_{a b}" + assert latex(Symbol("x_1_2_3")) == r"x_{1 2 3}" + assert latex(Symbol("x_a_b1")) == r"x_{a b1}" + assert latex(Symbol("x_a_1")) == r"x_{a 1}" + assert latex(Symbol("x_1_a")) == r"x_{1 a}" + assert latex(Symbol("x_1^aa")) == r"x^{aa}_{1}" + assert latex(Symbol("x_1__aa")) == r"x^{aa}_{1}" + assert latex(Symbol("x_11^a")) == r"x^{a}_{11}" + assert latex(Symbol("x_11__a")) == r"x^{a}_{11}" + assert latex(Symbol("x_a_a_a_a")) == r"x_{a a a a}" + assert latex(Symbol("x_a_a^a^a")) == r"x^{a a}_{a a}" + assert latex(Symbol("x_a_a__a__a")) == r"x^{a a}_{a a}" + assert latex(Symbol("alpha_11")) == r"\alpha_{11}" + assert latex(Symbol("alpha_11_11")) == r"\alpha_{11 11}" + assert latex(Symbol("alpha_alpha")) == r"\alpha_{\alpha}" + assert latex(Symbol("alpha^aleph")) == r"\alpha^{\aleph}" + assert latex(Symbol("alpha__aleph")) == r"\alpha^{\aleph}" + + +def test_latex_pow_fraction(): + x = Symbol('x') + # Testing exp + assert r'e^{-x}' in latex(exp(-x)/2).replace(' ', '') # Remove Whitespace + + # Testing e^{-x} in case future changes alter behavior of muls or fracs + # In particular current output is \frac{1}{2}e^{- x} but perhaps this will + # change to \frac{e^{-x}}{2} + + # Testing general, non-exp, power + assert r'3^{-x}' in latex(3**-x/2).replace(' ', '') + + +def test_noncommutative(): + A, B, C = symbols('A,B,C', commutative=False) + + assert latex(A*B*C**-1) == r"A B C^{-1}" + assert latex(C**-1*A*B) == r"C^{-1} A B" + assert latex(A*C**-1*B) == r"A C^{-1} B" + + +def test_latex_order(): + expr = x**3 + x**2*y + y**4 + 3*x*y**3 + + assert latex(expr, order='lex') == r"x^{3} + x^{2} y + 3 x y^{3} + y^{4}" + assert latex( + expr, order='rev-lex') == r"y^{4} + 3 x y^{3} + x^{2} y + x^{3}" + assert latex(expr, order='none') == r"x^{3} + y^{4} + y x^{2} + 3 x y^{3}" + + +def test_latex_Lambda(): + assert latex(Lambda(x, x + 1)) == r"\left( x \mapsto x + 1 \right)" + assert latex(Lambda((x, y), x + 1)) == r"\left( \left( x, \ y\right) \mapsto x + 1 \right)" + assert latex(Lambda(x, x)) == r"\left( x \mapsto x \right)" + +def test_latex_PolyElement(): + Ruv, u, v = ring("u,v", ZZ) + Rxyz, x, y, z = ring("x,y,z", Ruv) + + assert latex(x - x) == r"0" + assert latex(x - 1) == r"x - 1" + assert latex(x + 1) == r"x + 1" + + assert latex((u**2 + 3*u*v + 1)*x**2*y + u + 1) == \ + r"\left({u}^{2} + 3 u v + 1\right) {x}^{2} y + u + 1" + assert latex((u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x) == \ + r"\left({u}^{2} + 3 u v + 1\right) {x}^{2} y + \left(u + 1\right) x" + assert latex((u**2 + 3*u*v + 1)*x**2*y + (u + 1)*x + 1) == \ + r"\left({u}^{2} + 3 u v + 1\right) {x}^{2} y + \left(u + 1\right) x + 1" + assert latex((-u**2 + 3*u*v - 1)*x**2*y - (u + 1)*x - 1) == \ + r"-\left({u}^{2} - 3 u v + 1\right) {x}^{2} y - \left(u + 1\right) x - 1" + + assert latex(-(v**2 + v + 1)*x + 3*u*v + 1) == \ + r"-\left({v}^{2} + v + 1\right) x + 3 u v + 1" + assert latex(-(v**2 + v + 1)*x - 3*u*v + 1) == \ + r"-\left({v}^{2} + v + 1\right) x - 3 u v + 1" + + +def test_latex_FracElement(): + Fuv, u, v = field("u,v", ZZ) + Fxyzt, x, y, z, t = field("x,y,z,t", Fuv) + + assert latex(x - x) == r"0" + assert latex(x - 1) == r"x - 1" + assert latex(x + 1) == r"x + 1" + + assert latex(x/3) == r"\frac{x}{3}" + assert latex(x/z) == r"\frac{x}{z}" + assert latex(x*y/z) == r"\frac{x y}{z}" + assert latex(x/(z*t)) == r"\frac{x}{z t}" + assert latex(x*y/(z*t)) == r"\frac{x y}{z t}" + + assert latex((x - 1)/y) == r"\frac{x - 1}{y}" + assert latex((x + 1)/y) == r"\frac{x + 1}{y}" + assert latex((-x - 1)/y) == r"\frac{-x - 1}{y}" + assert latex((x + 1)/(y*z)) == r"\frac{x + 1}{y z}" + assert latex(-y/(x + 1)) == r"\frac{-y}{x + 1}" + assert latex(y*z/(x + 1)) == r"\frac{y z}{x + 1}" + + assert latex(((u + 1)*x*y + 1)/((v - 1)*z - 1)) == \ + r"\frac{\left(u + 1\right) x y + 1}{\left(v - 1\right) z - 1}" + assert latex(((u + 1)*x*y + 1)/((v - 1)*z - t*u*v - 1)) == \ + r"\frac{\left(u + 1\right) x y + 1}{\left(v - 1\right) z - u v t - 1}" + + +def test_latex_Poly(): + assert latex(Poly(x**2 + 2 * x, x)) == \ + r"\operatorname{Poly}{\left( x^{2} + 2 x, x, domain=\mathbb{Z} \right)}" + assert latex(Poly(x/y, x)) == \ + r"\operatorname{Poly}{\left( \frac{1}{y} x, x, domain=\mathbb{Z}\left(y\right) \right)}" + assert latex(Poly(2.0*x + y)) == \ + r"\operatorname{Poly}{\left( 2.0 x + 1.0 y, x, y, domain=\mathbb{R} \right)}" + + +def test_latex_Poly_order(): + assert latex(Poly([a, 1, b, 2, c, 3], x)) == \ + r'\operatorname{Poly}{\left( a x^{5} + x^{4} + b x^{3} + 2 x^{2} + c'\ + r' x + 3, x, domain=\mathbb{Z}\left[a, b, c\right] \right)}' + assert latex(Poly([a, 1, b+c, 2, 3], x)) == \ + r'\operatorname{Poly}{\left( a x^{4} + x^{3} + \left(b + c\right) '\ + r'x^{2} + 2 x + 3, x, domain=\mathbb{Z}\left[a, b, c\right] \right)}' + assert latex(Poly(a*x**3 + x**2*y - x*y - c*y**3 - b*x*y**2 + y - a*x + b, + (x, y))) == \ + r'\operatorname{Poly}{\left( a x^{3} + x^{2}y - b xy^{2} - xy - '\ + r'a x - c y^{3} + y + b, x, y, domain=\mathbb{Z}\left[a, b, c\right] \right)}' + + +def test_latex_ComplexRootOf(): + assert latex(rootof(x**5 + x + 3, 0)) == \ + r"\operatorname{CRootOf} {\left(x^{5} + x + 3, 0\right)}" + + +def test_latex_RootSum(): + assert latex(RootSum(x**5 + x + 3, sin)) == \ + r"\operatorname{RootSum} {\left(x^{5} + x + 3, \left( x \mapsto \sin{\left(x \right)} \right)\right)}" + + +def test_settings(): + raises(TypeError, lambda: latex(x*y, method="garbage")) + + +def test_latex_numbers(): + assert latex(catalan(n)) == r"C_{n}" + assert latex(catalan(n)**2) == r"C_{n}^{2}" + assert latex(bernoulli(n)) == r"B_{n}" + assert latex(bernoulli(n, x)) == r"B_{n}\left(x\right)" + assert latex(bernoulli(n)**2) == r"B_{n}^{2}" + assert latex(bernoulli(n, x)**2) == r"B_{n}^{2}\left(x\right)" + assert latex(genocchi(n)) == r"G_{n}" + assert latex(genocchi(n, x)) == r"G_{n}\left(x\right)" + assert latex(genocchi(n)**2) == r"G_{n}^{2}" + assert latex(genocchi(n, x)**2) == r"G_{n}^{2}\left(x\right)" + assert latex(bell(n)) == r"B_{n}" + assert latex(bell(n, x)) == r"B_{n}\left(x\right)" + assert latex(bell(n, m, (x, y))) == r"B_{n, m}\left(x, y\right)" + assert latex(bell(n)**2) == r"B_{n}^{2}" + assert latex(bell(n, x)**2) == r"B_{n}^{2}\left(x\right)" + assert latex(bell(n, m, (x, y))**2) == r"B_{n, m}^{2}\left(x, y\right)" + assert latex(fibonacci(n)) == r"F_{n}" + assert latex(fibonacci(n, x)) == r"F_{n}\left(x\right)" + assert latex(fibonacci(n)**2) == r"F_{n}^{2}" + assert latex(fibonacci(n, x)**2) == r"F_{n}^{2}\left(x\right)" + assert latex(lucas(n)) == r"L_{n}" + assert latex(lucas(n)**2) == r"L_{n}^{2}" + assert latex(tribonacci(n)) == r"T_{n}" + assert latex(tribonacci(n, x)) == r"T_{n}\left(x\right)" + assert latex(tribonacci(n)**2) == r"T_{n}^{2}" + assert latex(tribonacci(n, x)**2) == r"T_{n}^{2}\left(x\right)" + + +def test_latex_euler(): + assert latex(euler(n)) == r"E_{n}" + assert latex(euler(n, x)) == r"E_{n}\left(x\right)" + assert latex(euler(n, x)**2) == r"E_{n}^{2}\left(x\right)" + + +def test_lamda(): + assert latex(Symbol('lamda')) == r"\lambda" + assert latex(Symbol('Lamda')) == r"\Lambda" + + +def test_custom_symbol_names(): + x = Symbol('x') + y = Symbol('y') + assert latex(x) == r"x" + assert latex(x, symbol_names={x: "x_i"}) == r"x_i" + assert latex(x + y, symbol_names={x: "x_i"}) == r"x_i + y" + assert latex(x**2, symbol_names={x: "x_i"}) == r"x_i^{2}" + assert latex(x + y, symbol_names={x: "x_i", y: "y_j"}) == r"x_i + y_j" + + +def test_matAdd(): + C = MatrixSymbol('C', 5, 5) + B = MatrixSymbol('B', 5, 5) + + n = symbols("n") + h = MatrixSymbol("h", 1, 1) + + assert latex(C - 2*B) in [r'- 2 B + C', r'C -2 B'] + assert latex(C + 2*B) in [r'2 B + C', r'C + 2 B'] + assert latex(B - 2*C) in [r'B - 2 C', r'- 2 C + B'] + assert latex(B + 2*C) in [r'B + 2 C', r'2 C + B'] + + assert latex(n * h - (-h + h.T) * (h + h.T)) == 'n h - \\left(- h + h^{T}\\right) \\left(h + h^{T}\\right)' + assert latex(MatAdd(MatAdd(h, h), MatAdd(h, h))) == '\\left(h + h\\right) + \\left(h + h\\right)' + assert latex(MatMul(MatMul(h, h), MatMul(h, h))) == '\\left(h h\\right) \\left(h h\\right)' + + +def test_matMul(): + A = MatrixSymbol('A', 5, 5) + B = MatrixSymbol('B', 5, 5) + x = Symbol('x') + assert latex(2*A) == r'2 A' + assert latex(2*x*A) == r'2 x A' + assert latex(-2*A) == r'- 2 A' + assert latex(1.5*A) == r'1.5 A' + assert latex(sqrt(2)*A) == r'\sqrt{2} A' + assert latex(-sqrt(2)*A) == r'- \sqrt{2} A' + assert latex(2*sqrt(2)*x*A) == r'2 \sqrt{2} x A' + assert latex(-2*A*(A + 2*B)) in [r'- 2 A \left(A + 2 B\right)', + r'- 2 A \left(2 B + A\right)'] + + +def test_latex_MatrixSlice(): + n = Symbol('n', integer=True) + x, y, z, w, t, = symbols('x y z w t') + X = MatrixSymbol('X', n, n) + Y = MatrixSymbol('Y', 10, 10) + Z = MatrixSymbol('Z', 10, 10) + + assert latex(MatrixSlice(X, (None, None, None), (None, None, None))) == r'X\left[:, :\right]' + assert latex(X[x:x + 1, y:y + 1]) == r'X\left[x:x + 1, y:y + 1\right]' + assert latex(X[x:x + 1:2, y:y + 1:2]) == r'X\left[x:x + 1:2, y:y + 1:2\right]' + assert latex(X[:x, y:]) == r'X\left[:x, y:\right]' + assert latex(X[:x, y:]) == r'X\left[:x, y:\right]' + assert latex(X[x:, :y]) == r'X\left[x:, :y\right]' + assert latex(X[x:y, z:w]) == r'X\left[x:y, z:w\right]' + assert latex(X[x:y:t, w:t:x]) == r'X\left[x:y:t, w:t:x\right]' + assert latex(X[x::y, t::w]) == r'X\left[x::y, t::w\right]' + assert latex(X[:x:y, :t:w]) == r'X\left[:x:y, :t:w\right]' + assert latex(X[::x, ::y]) == r'X\left[::x, ::y\right]' + assert latex(MatrixSlice(X, (0, None, None), (0, None, None))) == r'X\left[:, :\right]' + assert latex(MatrixSlice(X, (None, n, None), (None, n, None))) == r'X\left[:, :\right]' + assert latex(MatrixSlice(X, (0, n, None), (0, n, None))) == r'X\left[:, :\right]' + assert latex(MatrixSlice(X, (0, n, 2), (0, n, 2))) == r'X\left[::2, ::2\right]' + assert latex(X[1:2:3, 4:5:6]) == r'X\left[1:2:3, 4:5:6\right]' + assert latex(X[1:3:5, 4:6:8]) == r'X\left[1:3:5, 4:6:8\right]' + assert latex(X[1:10:2]) == r'X\left[1:10:2, :\right]' + assert latex(Y[:5, 1:9:2]) == r'Y\left[:5, 1:9:2\right]' + assert latex(Y[:5, 1:10:2]) == r'Y\left[:5, 1::2\right]' + assert latex(Y[5, :5:2]) == r'Y\left[5:6, :5:2\right]' + assert latex(X[0:1, 0:1]) == r'X\left[:1, :1\right]' + assert latex(X[0:1:2, 0:1:2]) == r'X\left[:1:2, :1:2\right]' + assert latex((Y + Z)[2:, 2:]) == r'\left(Y + Z\right)\left[2:, 2:\right]' + + +def test_latex_RandomDomain(): + from sympy.stats import Normal, Die, Exponential, pspace, where + from sympy.stats.rv import RandomDomain + + X = Normal('x1', 0, 1) + assert latex(where(X > 0)) == r"\text{Domain: }0 < x_{1} \wedge x_{1} < \infty" + + D = Die('d1', 6) + assert latex(where(D > 4)) == r"\text{Domain: }d_{1} = 5 \vee d_{1} = 6" + + A = Exponential('a', 1) + B = Exponential('b', 1) + assert latex( + pspace(Tuple(A, B)).domain) == \ + r"\text{Domain: }0 \leq a \wedge 0 \leq b \wedge a < \infty \wedge b < \infty" + + assert latex(RandomDomain(FiniteSet(x), FiniteSet(1, 2))) == \ + r'\text{Domain: }\left\{x\right\} \in \left\{1, 2\right\}' + +def test_PrettyPoly(): + from sympy.polys.domains import QQ + F = QQ.frac_field(x, y) + R = QQ[x, y] + + assert latex(F.convert(x/(x + y))) == latex(x/(x + y)) + assert latex(R.convert(x + y)) == latex(x + y) + + +def test_integral_transforms(): + x = Symbol("x") + k = Symbol("k") + f = Function("f") + a = Symbol("a") + b = Symbol("b") + + assert latex(MellinTransform(f(x), x, k)) == \ + r"\mathcal{M}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseMellinTransform(f(k), k, x, a, b)) == \ + r"\mathcal{M}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(LaplaceTransform(f(x), x, k)) == \ + r"\mathcal{L}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseLaplaceTransform(f(k), k, x, (a, b))) == \ + r"\mathcal{L}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(FourierTransform(f(x), x, k)) == \ + r"\mathcal{F}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseFourierTransform(f(k), k, x)) == \ + r"\mathcal{F}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(CosineTransform(f(x), x, k)) == \ + r"\mathcal{COS}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseCosineTransform(f(k), k, x)) == \ + r"\mathcal{COS}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + assert latex(SineTransform(f(x), x, k)) == \ + r"\mathcal{SIN}_{x}\left[f{\left(x \right)}\right]\left(k\right)" + assert latex(InverseSineTransform(f(k), k, x)) == \ + r"\mathcal{SIN}^{-1}_{k}\left[f{\left(k \right)}\right]\left(x\right)" + + +def test_PolynomialRingBase(): + from sympy.polys.domains import QQ + assert latex(QQ.old_poly_ring(x, y)) == r"\mathbb{Q}\left[x, y\right]" + assert latex(QQ.old_poly_ring(x, y, order="ilex")) == \ + r"S_<^{-1}\mathbb{Q}\left[x, y\right]" + + +def test_categories(): + from sympy.categories import (Object, IdentityMorphism, + NamedMorphism, Category, Diagram, + DiagramGrid) + + A1 = Object("A1") + A2 = Object("A2") + A3 = Object("A3") + + f1 = NamedMorphism(A1, A2, "f1") + f2 = NamedMorphism(A2, A3, "f2") + id_A1 = IdentityMorphism(A1) + + K1 = Category("K1") + + assert latex(A1) == r"A_{1}" + assert latex(f1) == r"f_{1}:A_{1}\rightarrow A_{2}" + assert latex(id_A1) == r"id:A_{1}\rightarrow A_{1}" + assert latex(f2*f1) == r"f_{2}\circ f_{1}:A_{1}\rightarrow A_{3}" + + assert latex(K1) == r"\mathbf{K_{1}}" + + d = Diagram() + assert latex(d) == r"\emptyset" + + d = Diagram({f1: "unique", f2: S.EmptySet}) + assert latex(d) == r"\left\{ f_{2}\circ f_{1}:A_{1}" \ + r"\rightarrow A_{3} : \emptyset, \ id:A_{1}\rightarrow " \ + r"A_{1} : \emptyset, \ id:A_{2}\rightarrow A_{2} : " \ + r"\emptyset, \ id:A_{3}\rightarrow A_{3} : \emptyset, " \ + r"\ f_{1}:A_{1}\rightarrow A_{2} : \left\{unique\right\}, " \ + r"\ f_{2}:A_{2}\rightarrow A_{3} : \emptyset\right\}" + + d = Diagram({f1: "unique", f2: S.EmptySet}, {f2 * f1: "unique"}) + assert latex(d) == r"\left\{ f_{2}\circ f_{1}:A_{1}" \ + r"\rightarrow A_{3} : \emptyset, \ id:A_{1}\rightarrow " \ + r"A_{1} : \emptyset, \ id:A_{2}\rightarrow A_{2} : " \ + r"\emptyset, \ id:A_{3}\rightarrow A_{3} : \emptyset, " \ + r"\ f_{1}:A_{1}\rightarrow A_{2} : \left\{unique\right\}," \ + r" \ f_{2}:A_{2}\rightarrow A_{3} : \emptyset\right\}" \ + r"\Longrightarrow \left\{ f_{2}\circ f_{1}:A_{1}" \ + r"\rightarrow A_{3} : \left\{unique\right\}\right\}" + + # A linear diagram. + A = Object("A") + B = Object("B") + C = Object("C") + f = NamedMorphism(A, B, "f") + g = NamedMorphism(B, C, "g") + d = Diagram([f, g]) + grid = DiagramGrid(d) + + assert latex(grid) == r"\begin{array}{cc}" + "\n" \ + r"A & B \\" + "\n" \ + r" & C " + "\n" \ + r"\end{array}" + "\n" + + +def test_Modules(): + from sympy.polys.domains import QQ + from sympy.polys.agca import homomorphism + + R = QQ.old_poly_ring(x, y) + F = R.free_module(2) + M = F.submodule([x, y], [1, x**2]) + + assert latex(F) == r"{\mathbb{Q}\left[x, y\right]}^{2}" + assert latex(M) == \ + r"\left\langle {\left[ {x},{y} \right]},{\left[ {1},{x^{2}} \right]} \right\rangle" + + I = R.ideal(x**2, y) + assert latex(I) == r"\left\langle {x^{2}},{y} \right\rangle" + + Q = F / M + assert latex(Q) == \ + r"\frac{{\mathbb{Q}\left[x, y\right]}^{2}}{\left\langle {\left[ {x},"\ + r"{y} \right]},{\left[ {1},{x^{2}} \right]} \right\rangle}" + assert latex(Q.submodule([1, x**3/2], [2, y])) == \ + r"\left\langle {{\left[ {1},{\frac{x^{3}}{2}} \right]} + {\left"\ + r"\langle {\left[ {x},{y} \right]},{\left[ {1},{x^{2}} \right]} "\ + r"\right\rangle}},{{\left[ {2},{y} \right]} + {\left\langle {\left[ "\ + r"{x},{y} \right]},{\left[ {1},{x^{2}} \right]} \right\rangle}} \right\rangle" + + h = homomorphism(QQ.old_poly_ring(x).free_module(2), + QQ.old_poly_ring(x).free_module(2), [0, 0]) + + assert latex(h) == \ + r"{\left[\begin{matrix}0 & 0\\0 & 0\end{matrix}\right]} : "\ + r"{{\mathbb{Q}\left[x\right]}^{2}} \to {{\mathbb{Q}\left[x\right]}^{2}}" + + +def test_QuotientRing(): + from sympy.polys.domains import QQ + R = QQ.old_poly_ring(x)/[x**2 + 1] + + assert latex(R) == \ + r"\frac{\mathbb{Q}\left[x\right]}{\left\langle {x^{2} + 1} \right\rangle}" + assert latex(R.one) == r"{1} + {\left\langle {x^{2} + 1} \right\rangle}" + + +def test_Tr(): + #TODO: Handle indices + A, B = symbols('A B', commutative=False) + t = Tr(A*B) + assert latex(t) == r'\operatorname{tr}\left(A B\right)' + + +def test_Determinant(): + from sympy.matrices import Determinant, Inverse, BlockMatrix, OneMatrix, ZeroMatrix + m = Matrix(((1, 2), (3, 4))) + assert latex(Determinant(m)) == '\\left|{\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}}\\right|' + assert latex(Determinant(Inverse(m))) == \ + '\\left|{\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right]^{-1}}\\right|' + X = MatrixSymbol('X', 2, 2) + assert latex(Determinant(X)) == '\\left|{X}\\right|' + assert latex(Determinant(X + m)) == \ + '\\left|{\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] + X}\\right|' + assert latex(Determinant(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '\\left|{\\begin{matrix}1 & X\\\\\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] & 0\\end{matrix}}\\right|' + + +def test_Adjoint(): + from sympy.matrices import Adjoint, Inverse, Transpose + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(Adjoint(X)) == r'X^{\dagger}' + assert latex(Adjoint(X + Y)) == r'\left(X + Y\right)^{\dagger}' + assert latex(Adjoint(X) + Adjoint(Y)) == r'X^{\dagger} + Y^{\dagger}' + assert latex(Adjoint(X*Y)) == r'\left(X Y\right)^{\dagger}' + assert latex(Adjoint(Y)*Adjoint(X)) == r'Y^{\dagger} X^{\dagger}' + assert latex(Adjoint(X**2)) == r'\left(X^{2}\right)^{\dagger}' + assert latex(Adjoint(X)**2) == r'\left(X^{\dagger}\right)^{2}' + assert latex(Adjoint(Inverse(X))) == r'\left(X^{-1}\right)^{\dagger}' + assert latex(Inverse(Adjoint(X))) == r'\left(X^{\dagger}\right)^{-1}' + assert latex(Adjoint(Transpose(X))) == r'\left(X^{T}\right)^{\dagger}' + assert latex(Transpose(Adjoint(X))) == r'\left(X^{\dagger}\right)^{T}' + assert latex(Transpose(Adjoint(X) + Y)) == r'\left(X^{\dagger} + Y\right)^{T}' + m = Matrix(((1, 2), (3, 4))) + assert latex(Adjoint(m)) == '\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right]^{\\dagger}' + assert latex(Adjoint(m+X)) == \ + '\\left(\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] + X\\right)^{\\dagger}' + from sympy.matrices import BlockMatrix, OneMatrix, ZeroMatrix + assert latex(Adjoint(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '\\left[\\begin{matrix}1 & X\\\\\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] & 0\\end{matrix}\\right]^{\\dagger}' + # Issue 20959 + Mx = MatrixSymbol('M^x', 2, 2) + assert latex(Adjoint(Mx)) == r'\left(M^{x}\right)^{\dagger}' + + +def test_Transpose(): + from sympy.matrices import Transpose, MatPow, HadamardPower + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(Transpose(X)) == r'X^{T}' + assert latex(Transpose(X + Y)) == r'\left(X + Y\right)^{T}' + + assert latex(Transpose(HadamardPower(X, 2))) == r'\left(X^{\circ {2}}\right)^{T}' + assert latex(HadamardPower(Transpose(X), 2)) == r'\left(X^{T}\right)^{\circ {2}}' + assert latex(Transpose(MatPow(X, 2))) == r'\left(X^{2}\right)^{T}' + assert latex(MatPow(Transpose(X), 2)) == r'\left(X^{T}\right)^{2}' + m = Matrix(((1, 2), (3, 4))) + assert latex(Transpose(m)) == '\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right]^{T}' + assert latex(Transpose(m+X)) == \ + '\\left(\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] + X\\right)^{T}' + from sympy.matrices import BlockMatrix, OneMatrix, ZeroMatrix + assert latex(Transpose(BlockMatrix(((OneMatrix(2, 2), X), + (m, ZeroMatrix(2, 2)))))) == \ + '\\left[\\begin{matrix}1 & X\\\\\\left[\\begin{matrix}1 & 2\\\\3 & 4\\end{matrix}\\right] & 0\\end{matrix}\\right]^{T}' + # Issue 20959 + Mx = MatrixSymbol('M^x', 2, 2) + assert latex(Transpose(Mx)) == r'\left(M^{x}\right)^{T}' + + +def test_Hadamard(): + from sympy.matrices import HadamardProduct, HadamardPower + from sympy.matrices.expressions import MatAdd, MatMul, MatPow + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(HadamardProduct(X, Y*Y)) == r'X \circ Y^{2}' + assert latex(HadamardProduct(X, Y)*Y) == r'\left(X \circ Y\right) Y' + + assert latex(HadamardPower(X, 2)) == r'X^{\circ {2}}' + assert latex(HadamardPower(X, -1)) == r'X^{\circ \left({-1}\right)}' + assert latex(HadamardPower(MatAdd(X, Y), 2)) == \ + r'\left(X + Y\right)^{\circ {2}}' + assert latex(HadamardPower(MatMul(X, Y), 2)) == \ + r'\left(X Y\right)^{\circ {2}}' + + assert latex(HadamardPower(MatPow(X, -1), -1)) == \ + r'\left(X^{-1}\right)^{\circ \left({-1}\right)}' + assert latex(MatPow(HadamardPower(X, -1), -1)) == \ + r'\left(X^{\circ \left({-1}\right)}\right)^{-1}' + + assert latex(HadamardPower(X, n+1)) == \ + r'X^{\circ \left({n + 1}\right)}' + + +def test_MatPow(): + from sympy.matrices.expressions import MatPow + X = MatrixSymbol('X', 2, 2) + Y = MatrixSymbol('Y', 2, 2) + assert latex(MatPow(X, 2)) == 'X^{2}' + assert latex(MatPow(X*X, 2)) == '\\left(X^{2}\\right)^{2}' + assert latex(MatPow(X*Y, 2)) == '\\left(X Y\\right)^{2}' + assert latex(MatPow(X + Y, 2)) == '\\left(X + Y\\right)^{2}' + assert latex(MatPow(X + X, 2)) == '\\left(2 X\\right)^{2}' + # Issue 20959 + Mx = MatrixSymbol('M^x', 2, 2) + assert latex(MatPow(Mx, 2)) == r'\left(M^{x}\right)^{2}' + + +def test_ElementwiseApplyFunction(): + X = MatrixSymbol('X', 2, 2) + expr = (X.T*X).applyfunc(sin) + assert latex(expr) == r"{\left( d \mapsto \sin{\left(d \right)} \right)}_{\circ}\left({X^{T} X}\right)" + expr = X.applyfunc(Lambda(x, 1/x)) + assert latex(expr) == r'{\left( x \mapsto \frac{1}{x} \right)}_{\circ}\left({X}\right)' + + +def test_ZeroMatrix(): + from sympy.matrices.expressions.special import ZeroMatrix + assert latex(ZeroMatrix(1, 1), mat_symbol_style='plain') == r"0" + assert latex(ZeroMatrix(1, 1), mat_symbol_style='bold') == r"\mathbf{0}" + + +def test_OneMatrix(): + from sympy.matrices.expressions.special import OneMatrix + assert latex(OneMatrix(3, 4), mat_symbol_style='plain') == r"1" + assert latex(OneMatrix(3, 4), mat_symbol_style='bold') == r"\mathbf{1}" + + +def test_Identity(): + from sympy.matrices.expressions.special import Identity + assert latex(Identity(1), mat_symbol_style='plain') == r"\mathbb{I}" + assert latex(Identity(1), mat_symbol_style='bold') == r"\mathbf{I}" + + +def test_latex_DFT_IDFT(): + from sympy.matrices.expressions.fourier import DFT, IDFT + assert latex(DFT(13)) == r"\text{DFT}_{13}" + assert latex(IDFT(x)) == r"\text{IDFT}_{x}" + + +def test_boolean_args_order(): + syms = symbols('a:f') + + expr = And(*syms) + assert latex(expr) == r'a \wedge b \wedge c \wedge d \wedge e \wedge f' + + expr = Or(*syms) + assert latex(expr) == r'a \vee b \vee c \vee d \vee e \vee f' + + expr = Equivalent(*syms) + assert latex(expr) == \ + r'a \Leftrightarrow b \Leftrightarrow c \Leftrightarrow d \Leftrightarrow e \Leftrightarrow f' + + expr = Xor(*syms) + assert latex(expr) == \ + r'a \veebar b \veebar c \veebar d \veebar e \veebar f' + + +def test_imaginary(): + i = sqrt(-1) + assert latex(i) == r'i' + + +def test_builtins_without_args(): + assert latex(sin) == r'\sin' + assert latex(cos) == r'\cos' + assert latex(tan) == r'\tan' + assert latex(log) == r'\log' + assert latex(Ei) == r'\operatorname{Ei}' + assert latex(zeta) == r'\zeta' + + +def test_latex_greek_functions(): + # bug because capital greeks that have roman equivalents should not use + # \Alpha, \Beta, \Eta, etc. + s = Function('Alpha') + assert latex(s) == r'\mathrm{A}' + assert latex(s(x)) == r'\mathrm{A}{\left(x \right)}' + s = Function('Beta') + assert latex(s) == r'\mathrm{B}' + s = Function('Eta') + assert latex(s) == r'\mathrm{H}' + assert latex(s(x)) == r'\mathrm{H}{\left(x \right)}' + + # bug because sympy.core.numbers.Pi is special + p = Function('Pi') + # assert latex(p(x)) == r'\Pi{\left(x \right)}' + assert latex(p) == r'\Pi' + + # bug because not all greeks are included + c = Function('chi') + assert latex(c(x)) == r'\chi{\left(x \right)}' + assert latex(c) == r'\chi' + + +def test_translate(): + s = 'Alpha' + assert translate(s) == r'\mathrm{A}' + s = 'Beta' + assert translate(s) == r'\mathrm{B}' + s = 'Eta' + assert translate(s) == r'\mathrm{H}' + s = 'omicron' + assert translate(s) == r'o' + s = 'Pi' + assert translate(s) == r'\Pi' + s = 'pi' + assert translate(s) == r'\pi' + s = 'LamdaHatDOT' + assert translate(s) == r'\dot{\hat{\Lambda}}' + + +def test_other_symbols(): + from sympy.printing.latex import other_symbols + for s in other_symbols: + assert latex(symbols(s)) == r"" "\\" + s + + +def test_modifiers(): + # Test each modifier individually in the simplest case + # (with funny capitalizations) + assert latex(symbols("xMathring")) == r"\mathring{x}" + assert latex(symbols("xCheck")) == r"\check{x}" + assert latex(symbols("xBreve")) == r"\breve{x}" + assert latex(symbols("xAcute")) == r"\acute{x}" + assert latex(symbols("xGrave")) == r"\grave{x}" + assert latex(symbols("xTilde")) == r"\tilde{x}" + assert latex(symbols("xPrime")) == r"{x}'" + assert latex(symbols("xddDDot")) == r"\ddddot{x}" + assert latex(symbols("xDdDot")) == r"\dddot{x}" + assert latex(symbols("xDDot")) == r"\ddot{x}" + assert latex(symbols("xBold")) == r"\boldsymbol{x}" + assert latex(symbols("xnOrM")) == r"\left\|{x}\right\|" + assert latex(symbols("xAVG")) == r"\left\langle{x}\right\rangle" + assert latex(symbols("xHat")) == r"\hat{x}" + assert latex(symbols("xDot")) == r"\dot{x}" + assert latex(symbols("xBar")) == r"\bar{x}" + assert latex(symbols("xVec")) == r"\vec{x}" + assert latex(symbols("xAbs")) == r"\left|{x}\right|" + assert latex(symbols("xMag")) == r"\left|{x}\right|" + assert latex(symbols("xPrM")) == r"{x}'" + assert latex(symbols("xBM")) == r"\boldsymbol{x}" + # Test strings that are *only* the names of modifiers + assert latex(symbols("Mathring")) == r"Mathring" + assert latex(symbols("Check")) == r"Check" + assert latex(symbols("Breve")) == r"Breve" + assert latex(symbols("Acute")) == r"Acute" + assert latex(symbols("Grave")) == r"Grave" + assert latex(symbols("Tilde")) == r"Tilde" + assert latex(symbols("Prime")) == r"Prime" + assert latex(symbols("DDot")) == r"\dot{D}" + assert latex(symbols("Bold")) == r"Bold" + assert latex(symbols("NORm")) == r"NORm" + assert latex(symbols("AVG")) == r"AVG" + assert latex(symbols("Hat")) == r"Hat" + assert latex(symbols("Dot")) == r"Dot" + assert latex(symbols("Bar")) == r"Bar" + assert latex(symbols("Vec")) == r"Vec" + assert latex(symbols("Abs")) == r"Abs" + assert latex(symbols("Mag")) == r"Mag" + assert latex(symbols("PrM")) == r"PrM" + assert latex(symbols("BM")) == r"BM" + assert latex(symbols("hbar")) == r"\hbar" + # Check a few combinations + assert latex(symbols("xvecdot")) == r"\dot{\vec{x}}" + assert latex(symbols("xDotVec")) == r"\vec{\dot{x}}" + assert latex(symbols("xHATNorm")) == r"\left\|{\hat{x}}\right\|" + # Check a couple big, ugly combinations + assert latex(symbols('xMathringBm_yCheckPRM__zbreveAbs')) == \ + r"\boldsymbol{\mathring{x}}^{\left|{\breve{z}}\right|}_{{\check{y}}'}" + assert latex(symbols('alphadothat_nVECDOT__tTildePrime')) == \ + r"\hat{\dot{\alpha}}^{{\tilde{t}}'}_{\dot{\vec{n}}}" + + +def test_greek_symbols(): + assert latex(Symbol('alpha')) == r'\alpha' + assert latex(Symbol('beta')) == r'\beta' + assert latex(Symbol('gamma')) == r'\gamma' + assert latex(Symbol('delta')) == r'\delta' + assert latex(Symbol('epsilon')) == r'\epsilon' + assert latex(Symbol('zeta')) == r'\zeta' + assert latex(Symbol('eta')) == r'\eta' + assert latex(Symbol('theta')) == r'\theta' + assert latex(Symbol('iota')) == r'\iota' + assert latex(Symbol('kappa')) == r'\kappa' + assert latex(Symbol('lambda')) == r'\lambda' + assert latex(Symbol('mu')) == r'\mu' + assert latex(Symbol('nu')) == r'\nu' + assert latex(Symbol('xi')) == r'\xi' + assert latex(Symbol('omicron')) == r'o' + assert latex(Symbol('pi')) == r'\pi' + assert latex(Symbol('rho')) == r'\rho' + assert latex(Symbol('sigma')) == r'\sigma' + assert latex(Symbol('tau')) == r'\tau' + assert latex(Symbol('upsilon')) == r'\upsilon' + assert latex(Symbol('phi')) == r'\phi' + assert latex(Symbol('chi')) == r'\chi' + assert latex(Symbol('psi')) == r'\psi' + assert latex(Symbol('omega')) == r'\omega' + + assert latex(Symbol('Alpha')) == r'\mathrm{A}' + assert latex(Symbol('Beta')) == r'\mathrm{B}' + assert latex(Symbol('Gamma')) == r'\Gamma' + assert latex(Symbol('Delta')) == r'\Delta' + assert latex(Symbol('Epsilon')) == r'\mathrm{E}' + assert latex(Symbol('Zeta')) == r'\mathrm{Z}' + assert latex(Symbol('Eta')) == r'\mathrm{H}' + assert latex(Symbol('Theta')) == r'\Theta' + assert latex(Symbol('Iota')) == r'\mathrm{I}' + assert latex(Symbol('Kappa')) == r'\mathrm{K}' + assert latex(Symbol('Lambda')) == r'\Lambda' + assert latex(Symbol('Mu')) == r'\mathrm{M}' + assert latex(Symbol('Nu')) == r'\mathrm{N}' + assert latex(Symbol('Xi')) == r'\Xi' + assert latex(Symbol('Omicron')) == r'\mathrm{O}' + assert latex(Symbol('Pi')) == r'\Pi' + assert latex(Symbol('Rho')) == r'\mathrm{P}' + assert latex(Symbol('Sigma')) == r'\Sigma' + assert latex(Symbol('Tau')) == r'\mathrm{T}' + assert latex(Symbol('Upsilon')) == r'\Upsilon' + assert latex(Symbol('Phi')) == r'\Phi' + assert latex(Symbol('Chi')) == r'\mathrm{X}' + assert latex(Symbol('Psi')) == r'\Psi' + assert latex(Symbol('Omega')) == r'\Omega' + + assert latex(Symbol('varepsilon')) == r'\varepsilon' + assert latex(Symbol('varkappa')) == r'\varkappa' + assert latex(Symbol('varphi')) == r'\varphi' + assert latex(Symbol('varpi')) == r'\varpi' + assert latex(Symbol('varrho')) == r'\varrho' + assert latex(Symbol('varsigma')) == r'\varsigma' + assert latex(Symbol('vartheta')) == r'\vartheta' + + +def test_fancyset_symbols(): + assert latex(S.Rationals) == r'\mathbb{Q}' + assert latex(S.Naturals) == r'\mathbb{N}' + assert latex(S.Naturals0) == r'\mathbb{N}_0' + assert latex(S.Integers) == r'\mathbb{Z}' + assert latex(S.Reals) == r'\mathbb{R}' + assert latex(S.Complexes) == r'\mathbb{C}' + + +@XFAIL +def test_builtin_without_args_mismatched_names(): + assert latex(CosineTransform) == r'\mathcal{COS}' + + +def test_builtin_no_args(): + assert latex(Chi) == r'\operatorname{Chi}' + assert latex(beta) == r'\operatorname{B}' + assert latex(gamma) == r'\Gamma' + assert latex(KroneckerDelta) == r'\delta' + assert latex(DiracDelta) == r'\delta' + assert latex(lowergamma) == r'\gamma' + + +def test_issue_6853(): + p = Function('Pi') + assert latex(p(x)) == r"\Pi{\left(x \right)}" + + +def test_Mul(): + e = Mul(-2, x + 1, evaluate=False) + assert latex(e) == r'- 2 \left(x + 1\right)' + e = Mul(2, x + 1, evaluate=False) + assert latex(e) == r'2 \left(x + 1\right)' + e = Mul(S.Half, x + 1, evaluate=False) + assert latex(e) == r'\frac{x + 1}{2}' + e = Mul(y, x + 1, evaluate=False) + assert latex(e) == r'y \left(x + 1\right)' + e = Mul(-y, x + 1, evaluate=False) + assert latex(e) == r'- y \left(x + 1\right)' + e = Mul(-2, x + 1) + assert latex(e) == r'- 2 x - 2' + e = Mul(2, x + 1) + assert latex(e) == r'2 x + 2' + + +def test_Pow(): + e = Pow(2, 2, evaluate=False) + assert latex(e) == r'2^{2}' + assert latex(x**(Rational(-1, 3))) == r'\frac{1}{\sqrt[3]{x}}' + x2 = Symbol(r'x^2') + assert latex(x2**2) == r'\left(x^{2}\right)^{2}' + + +def test_issue_7180(): + assert latex(Equivalent(x, y)) == r"x \Leftrightarrow y" + assert latex(Not(Equivalent(x, y))) == r"x \not\Leftrightarrow y" + + +def test_issue_8409(): + assert latex(S.Half**n) == r"\left(\frac{1}{2}\right)^{n}" + + +def test_issue_8470(): + from sympy.parsing.sympy_parser import parse_expr + e = parse_expr("-B*A", evaluate=False) + assert latex(e) == r"A \left(- B\right)" + + +def test_issue_15439(): + x = MatrixSymbol('x', 2, 2) + y = MatrixSymbol('y', 2, 2) + assert latex((x * y).subs(y, -y)) == r"x \left(- y\right)" + assert latex((x * y).subs(y, -2*y)) == r"x \left(- 2 y\right)" + assert latex((x * y).subs(x, -x)) == r"\left(- x\right) y" + + +def test_issue_2934(): + assert latex(Symbol(r'\frac{a_1}{b_1}')) == r'\frac{a_1}{b_1}' + + +def test_issue_10489(): + latexSymbolWithBrace = r'C_{x_{0}}' + s = Symbol(latexSymbolWithBrace) + assert latex(s) == latexSymbolWithBrace + assert latex(cos(s)) == r'\cos{\left(C_{x_{0}} \right)}' + + +def test_issue_12886(): + m__1, l__1 = symbols('m__1, l__1') + assert latex(m__1**2 + l__1**2) == \ + r'\left(l^{1}\right)^{2} + \left(m^{1}\right)^{2}' + + +def test_issue_13559(): + from sympy.parsing.sympy_parser import parse_expr + expr = parse_expr('5/1', evaluate=False) + assert latex(expr) == r"\frac{5}{1}" + + +def test_issue_13651(): + expr = c + Mul(-1, a + b, evaluate=False) + assert latex(expr) == r"c - \left(a + b\right)" + + +def test_latex_UnevaluatedExpr(): + x = symbols("x") + he = UnevaluatedExpr(1/x) + assert latex(he) == latex(1/x) == r"\frac{1}{x}" + assert latex(he**2) == r"\left(\frac{1}{x}\right)^{2}" + assert latex(he + 1) == r"1 + \frac{1}{x}" + assert latex(x*he) == r"x \frac{1}{x}" + + +def test_MatrixElement_printing(): + # test cases for issue #11821 + A = MatrixSymbol("A", 1, 3) + B = MatrixSymbol("B", 1, 3) + C = MatrixSymbol("C", 1, 3) + + assert latex(A[0, 0]) == r"A_{0, 0}" + assert latex(3 * A[0, 0]) == r"3 A_{0, 0}" + + F = C[0, 0].subs(C, A - B) + assert latex(F) == r"\left(A - B\right)_{0, 0}" + + i, j, k = symbols("i j k") + M = MatrixSymbol("M", k, k) + N = MatrixSymbol("N", k, k) + assert latex((M*N)[i, j]) == \ + r'\sum_{i_{1}=0}^{k - 1} M_{i, i_{1}} N_{i_{1}, j}' + + +def test_MatrixSymbol_printing(): + # test cases for issue #14237 + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + C = MatrixSymbol("C", 3, 3) + + assert latex(-A) == r"- A" + assert latex(A - A*B - B) == r"A - A B - B" + assert latex(-A*B - A*B*C - B) == r"- A B - A B C - B" + + +def test_KroneckerProduct_printing(): + A = MatrixSymbol('A', 3, 3) + B = MatrixSymbol('B', 2, 2) + assert latex(KroneckerProduct(A, B)) == r'A \otimes B' + + +def test_Series_printing(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + tf3 = TransferFunction(t*x**2 - t**w*x + w, t - y, y) + assert latex(Series(tf1, tf2)) == \ + r'\left(\frac{x y^{2} - z}{- t^{3} + y^{3}}\right) \left(\frac{x - y}{x + y}\right)' + assert latex(Series(tf1, tf2, tf3)) == \ + r'\left(\frac{x y^{2} - z}{- t^{3} + y^{3}}\right) \left(\frac{x - y}{x + y}\right) \left(\frac{t x^{2} - t^{w} x + w}{t - y}\right)' + assert latex(Series(-tf2, tf1)) == \ + r'\left(\frac{- x + y}{x + y}\right) \left(\frac{x y^{2} - z}{- t^{3} + y^{3}}\right)' + + M_1 = Matrix([[5/s], [5/(2*s)]]) + T_1 = TransferFunctionMatrix.from_Matrix(M_1, s) + M_2 = Matrix([[5, 6*s**3]]) + T_2 = TransferFunctionMatrix.from_Matrix(M_2, s) + # Brackets + assert latex(T_1*(T_2 + T_2)) == \ + r'\left[\begin{matrix}\frac{5}{s}\\\frac{5}{2 s}\end{matrix}\right]_\tau\cdot\left(\left[\begin{matrix}\frac{5}{1} &' \ + r' \frac{6 s^{3}}{1}\end{matrix}\right]_\tau + \left[\begin{matrix}\frac{5}{1} & \frac{6 s^{3}}{1}\end{matrix}\right]_\tau\right)' \ + == latex(MIMOSeries(MIMOParallel(T_2, T_2), T_1)) + # No Brackets + M_3 = Matrix([[5, 6], [6, 5/s]]) + T_3 = TransferFunctionMatrix.from_Matrix(M_3, s) + assert latex(T_1*T_2 + T_3) == r'\left[\begin{matrix}\frac{5}{s}\\\frac{5}{2 s}\end{matrix}\right]_\tau\cdot\left[\begin{matrix}' \ + r'\frac{5}{1} & \frac{6 s^{3}}{1}\end{matrix}\right]_\tau + \left[\begin{matrix}\frac{5}{1} & \frac{6}{1}\\\frac{6}{1} & ' \ + r'\frac{5}{s}\end{matrix}\right]_\tau' == latex(MIMOParallel(MIMOSeries(T_2, T_1), T_3)) + + +def test_TransferFunction_printing(): + tf1 = TransferFunction(x - 1, x + 1, x) + assert latex(tf1) == r"\frac{x - 1}{x + 1}" + tf2 = TransferFunction(x + 1, 2 - y, x) + assert latex(tf2) == r"\frac{x + 1}{2 - y}" + tf3 = TransferFunction(y, y**2 + 2*y + 3, y) + assert latex(tf3) == r"\frac{y}{y^{2} + 2 y + 3}" + + +def test_Parallel_printing(): + tf1 = TransferFunction(x*y**2 - z, y**3 - t**3, y) + tf2 = TransferFunction(x - y, x + y, y) + assert latex(Parallel(tf1, tf2)) == \ + r'\frac{x y^{2} - z}{- t^{3} + y^{3}} + \frac{x - y}{x + y}' + assert latex(Parallel(-tf2, tf1)) == \ + r'\frac{- x + y}{x + y} + \frac{x y^{2} - z}{- t^{3} + y^{3}}' + + M_1 = Matrix([[5, 6], [6, 5/s]]) + T_1 = TransferFunctionMatrix.from_Matrix(M_1, s) + M_2 = Matrix([[5/s, 6], [6, 5/(s - 1)]]) + T_2 = TransferFunctionMatrix.from_Matrix(M_2, s) + M_3 = Matrix([[6, 5/(s*(s - 1))], [5, 6]]) + T_3 = TransferFunctionMatrix.from_Matrix(M_3, s) + assert latex(T_1 + T_2 + T_3) == r'\left[\begin{matrix}\frac{5}{1} & \frac{6}{1}\\\frac{6}{1} & \frac{5}{s}\end{matrix}\right]' \ + r'_\tau + \left[\begin{matrix}\frac{5}{s} & \frac{6}{1}\\\frac{6}{1} & \frac{5}{s - 1}\end{matrix}\right]_\tau + \left[\begin{matrix}' \ + r'\frac{6}{1} & \frac{5}{s \left(s - 1\right)}\\\frac{5}{1} & \frac{6}{1}\end{matrix}\right]_\tau' \ + == latex(MIMOParallel(T_1, T_2, T_3)) == latex(MIMOParallel(T_1, MIMOParallel(T_2, T_3))) == latex(MIMOParallel(MIMOParallel(T_1, T_2), T_3)) + + +def test_TransferFunctionMatrix_printing(): + tf1 = TransferFunction(p, p + x, p) + tf2 = TransferFunction(-s + p, p + s, p) + tf3 = TransferFunction(p, y**2 + 2*y + 3, p) + assert latex(TransferFunctionMatrix([[tf1], [tf2]])) == \ + r'\left[\begin{matrix}\frac{p}{p + x}\\\frac{p - s}{p + s}\end{matrix}\right]_\tau' + assert latex(TransferFunctionMatrix([[tf1, tf2], [tf3, -tf1]])) == \ + r'\left[\begin{matrix}\frac{p}{p + x} & \frac{p - s}{p + s}\\\frac{p}{y^{2} + 2 y + 3} & \frac{\left(-1\right) p}{p + x}\end{matrix}\right]_\tau' + + +def test_Feedback_printing(): + tf1 = TransferFunction(p, p + x, p) + tf2 = TransferFunction(-s + p, p + s, p) + # Negative Feedback (Default) + assert latex(Feedback(tf1, tf2)) == \ + r'\frac{\frac{p}{p + x}}{\frac{1}{1} + \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + assert latex(Feedback(tf1*tf2, TransferFunction(1, 1, p))) == \ + r'\frac{\left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}{\frac{1}{1} + \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + # Positive Feedback + assert latex(Feedback(tf1, tf2, 1)) == \ + r'\frac{\frac{p}{p + x}}{\frac{1}{1} - \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + assert latex(Feedback(tf1*tf2, sign=1)) == \ + r'\frac{\left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}{\frac{1}{1} - \left(\frac{p}{p + x}\right) \left(\frac{p - s}{p + s}\right)}' + + +def test_MIMOFeedback_printing(): + tf1 = TransferFunction(1, s, s) + tf2 = TransferFunction(s, s**2 - 1, s) + tf3 = TransferFunction(s, s - 1, s) + tf4 = TransferFunction(s**2, s**2 - 1, s) + + tfm_1 = TransferFunctionMatrix([[tf1, tf2], [tf3, tf4]]) + tfm_2 = TransferFunctionMatrix([[tf4, tf3], [tf2, tf1]]) + + # Negative Feedback (Default) + assert latex(MIMOFeedback(tfm_1, tfm_2)) == \ + r'\left(I_{\tau} + \left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\cdot\left[' \ + r'\begin{matrix}\frac{s^{2}}{s^{2} - 1} & \frac{s}{s - 1}\\\frac{s}{s^{2} - 1} & \frac{1}{s}\end{matrix}\right]_\tau\right)^{-1} \cdot \left[\begin{matrix}' \ + r'\frac{1}{s} & \frac{s}{s^{2} - 1}\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau' + + # Positive Feedback + assert latex(MIMOFeedback(tfm_1*tfm_2, tfm_1, 1)) == \ + r'\left(I_{\tau} - \left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\cdot\left' \ + r'[\begin{matrix}\frac{s^{2}}{s^{2} - 1} & \frac{s}{s - 1}\\\frac{s}{s^{2} - 1} & \frac{1}{s}\end{matrix}\right]_\tau\cdot\left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}' \ + r'\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\right)^{-1} \cdot \left[\begin{matrix}\frac{1}{s} & \frac{s}{s^{2} - 1}' \ + r'\\\frac{s}{s - 1} & \frac{s^{2}}{s^{2} - 1}\end{matrix}\right]_\tau\cdot\left[\begin{matrix}\frac{s^{2}}{s^{2} - 1} & \frac{s}{s - 1}\\\frac{s}{s^{2} - 1}' \ + r' & \frac{1}{s}\end{matrix}\right]_\tau' + + +def test_Quaternion_latex_printing(): + q = Quaternion(x, y, z, t) + assert latex(q) == r"x + y i + z j + t k" + q = Quaternion(x, y, z, x*t) + assert latex(q) == r"x + y i + z j + t x k" + q = Quaternion(x, y, z, x + t) + assert latex(q) == r"x + y i + z j + \left(t + x\right) k" + + +def test_TensorProduct_printing(): + from sympy.tensor.functions import TensorProduct + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + assert latex(TensorProduct(A, B)) == r"A \otimes B" + + +def test_WedgeProduct_printing(): + from sympy.diffgeom.rn import R2 + from sympy.diffgeom import WedgeProduct + wp = WedgeProduct(R2.dx, R2.dy) + assert latex(wp) == r"\operatorname{d}x \wedge \operatorname{d}y" + + +def test_issue_9216(): + expr_1 = Pow(1, -1, evaluate=False) + assert latex(expr_1) == r"1^{-1}" + + expr_2 = Pow(1, Pow(1, -1, evaluate=False), evaluate=False) + assert latex(expr_2) == r"1^{1^{-1}}" + + expr_3 = Pow(3, -2, evaluate=False) + assert latex(expr_3) == r"\frac{1}{9}" + + expr_4 = Pow(1, -2, evaluate=False) + assert latex(expr_4) == r"1^{-2}" + + +def test_latex_printer_tensor(): + from sympy.tensor.tensor import TensorIndexType, tensor_indices, TensorHead, tensor_heads + L = TensorIndexType("L") + i, j, k, l = tensor_indices("i j k l", L) + i0 = tensor_indices("i_0", L) + A, B, C, D = tensor_heads("A B C D", [L]) + H = TensorHead("H", [L, L]) + K = TensorHead("K", [L, L, L, L]) + + assert latex(i) == r"{}^{i}" + assert latex(-i) == r"{}_{i}" + + expr = A(i) + assert latex(expr) == r"A{}^{i}" + + expr = A(i0) + assert latex(expr) == r"A{}^{i_{0}}" + + expr = A(-i) + assert latex(expr) == r"A{}_{i}" + + expr = -3*A(i) + assert latex(expr) == r"-3A{}^{i}" + + expr = K(i, j, -k, -i0) + assert latex(expr) == r"K{}^{ij}{}_{ki_{0}}" + + expr = K(i, -j, -k, i0) + assert latex(expr) == r"K{}^{i}{}_{jk}{}^{i_{0}}" + + expr = K(i, -j, k, -i0) + assert latex(expr) == r"K{}^{i}{}_{j}{}^{k}{}_{i_{0}}" + + expr = H(i, -j) + assert latex(expr) == r"H{}^{i}{}_{j}" + + expr = H(i, j) + assert latex(expr) == r"H{}^{ij}" + + expr = H(-i, -j) + assert latex(expr) == r"H{}_{ij}" + + expr = (1+x)*A(i) + assert latex(expr) == r"\left(x + 1\right)A{}^{i}" + + expr = H(i, -i) + assert latex(expr) == r"H{}^{L_{0}}{}_{L_{0}}" + + expr = H(i, -j)*A(j)*B(k) + assert latex(expr) == r"H{}^{i}{}_{L_{0}}A{}^{L_{0}}B{}^{k}" + + expr = A(i) + 3*B(i) + assert latex(expr) == r"3B{}^{i} + A{}^{i}" + + # Test ``TensorElement``: + from sympy.tensor.tensor import TensorElement + + expr = TensorElement(K(i, j, k, l), {i: 3, k: 2}) + assert latex(expr) == r'K{}^{i=3,j,k=2,l}' + + expr = TensorElement(K(i, j, k, l), {i: 3}) + assert latex(expr) == r'K{}^{i=3,jkl}' + + expr = TensorElement(K(i, -j, k, l), {i: 3, k: 2}) + assert latex(expr) == r'K{}^{i=3}{}_{j}{}^{k=2,l}' + + expr = TensorElement(K(i, -j, k, -l), {i: 3, k: 2}) + assert latex(expr) == r'K{}^{i=3}{}_{j}{}^{k=2}{}_{l}' + + expr = TensorElement(K(i, j, -k, -l), {i: 3, -k: 2}) + assert latex(expr) == r'K{}^{i=3,j}{}_{k=2,l}' + + expr = TensorElement(K(i, j, -k, -l), {i: 3}) + assert latex(expr) == r'K{}^{i=3,j}{}_{kl}' + + expr = PartialDerivative(A(i), A(i)) + assert latex(expr) == r"\frac{\partial}{\partial {A{}^{L_{0}}}}{A{}^{L_{0}}}" + + expr = PartialDerivative(A(-i), A(-j)) + assert latex(expr) == r"\frac{\partial}{\partial {A{}_{j}}}{A{}_{i}}" + + expr = PartialDerivative(K(i, j, -k, -l), A(m), A(-n)) + assert latex(expr) == r"\frac{\partial^{2}}{\partial {A{}^{m}} \partial {A{}_{n}}}{K{}^{ij}{}_{kl}}" + + expr = PartialDerivative(B(-i) + A(-i), A(-j), A(-n)) + assert latex(expr) == r"\frac{\partial^{2}}{\partial {A{}_{j}} \partial {A{}_{n}}}{\left(A{}_{i} + B{}_{i}\right)}" + + expr = PartialDerivative(3*A(-i), A(-j), A(-n)) + assert latex(expr) == r"\frac{\partial^{2}}{\partial {A{}_{j}} \partial {A{}_{n}}}{\left(3A{}_{i}\right)}" + + +def test_multiline_latex(): + a, b, c, d, e, f = symbols('a b c d e f') + expr = -a + 2*b -3*c +4*d -5*e + expected = r"\begin{eqnarray}" + "\n"\ + r"f & = &- a \nonumber\\" + "\n"\ + r"& & + 2 b \nonumber\\" + "\n"\ + r"& & - 3 c \nonumber\\" + "\n"\ + r"& & + 4 d \nonumber\\" + "\n"\ + r"& & - 5 e " + "\n"\ + r"\end{eqnarray}" + assert multiline_latex(f, expr, environment="eqnarray") == expected + + expected2 = r'\begin{eqnarray}' + '\n'\ + r'f & = &- a + 2 b \nonumber\\' + '\n'\ + r'& & - 3 c + 4 d \nonumber\\' + '\n'\ + r'& & - 5 e ' + '\n'\ + r'\end{eqnarray}' + + assert multiline_latex(f, expr, 2, environment="eqnarray") == expected2 + + expected3 = r'\begin{eqnarray}' + '\n'\ + r'f & = &- a + 2 b - 3 c \nonumber\\'+ '\n'\ + r'& & + 4 d - 5 e ' + '\n'\ + r'\end{eqnarray}' + + assert multiline_latex(f, expr, 3, environment="eqnarray") == expected3 + + expected3dots = r'\begin{eqnarray}' + '\n'\ + r'f & = &- a + 2 b - 3 c \dots\nonumber\\'+ '\n'\ + r'& & + 4 d - 5 e ' + '\n'\ + r'\end{eqnarray}' + + assert multiline_latex(f, expr, 3, environment="eqnarray", use_dots=True) == expected3dots + + expected3align = r'\begin{align*}' + '\n'\ + r'f = &- a + 2 b - 3 c \\'+ '\n'\ + r'& + 4 d - 5 e ' + '\n'\ + r'\end{align*}' + + assert multiline_latex(f, expr, 3) == expected3align + assert multiline_latex(f, expr, 3, environment='align*') == expected3align + + expected2ieee = r'\begin{IEEEeqnarray}{rCl}' + '\n'\ + r'f & = &- a + 2 b \nonumber\\' + '\n'\ + r'& & - 3 c + 4 d \nonumber\\' + '\n'\ + r'& & - 5 e ' + '\n'\ + r'\end{IEEEeqnarray}' + + assert multiline_latex(f, expr, 2, environment="IEEEeqnarray") == expected2ieee + + raises(ValueError, lambda: multiline_latex(f, expr, environment="foo")) + +def test_issue_15353(): + a, x = symbols('a x') + # Obtained from nonlinsolve([(sin(a*x)),cos(a*x)],[x,a]) + sol = ConditionSet( + Tuple(x, a), Eq(sin(a*x), 0) & Eq(cos(a*x), 0), S.Complexes**2) + assert latex(sol) == \ + r'\left\{\left( x, \ a\right)\; \middle|\; \left( x, \ a\right) \in ' \ + r'\mathbb{C}^{2} \wedge \sin{\left(a x \right)} = 0 \wedge ' \ + r'\cos{\left(a x \right)} = 0 \right\}' + + +def test_latex_symbolic_probability(): + mu = symbols("mu") + sigma = symbols("sigma", positive=True) + X = Normal("X", mu, sigma) + assert latex(Expectation(X)) == r'\operatorname{E}\left[X\right]' + assert latex(Variance(X)) == r'\operatorname{Var}\left(X\right)' + assert latex(Probability(X > 0)) == r'\operatorname{P}\left(X > 0\right)' + Y = Normal("Y", mu, sigma) + assert latex(Covariance(X, Y)) == r'\operatorname{Cov}\left(X, Y\right)' + + +def test_trace(): + # Issue 15303 + from sympy.matrices.expressions.trace import trace + A = MatrixSymbol("A", 2, 2) + assert latex(trace(A)) == r"\operatorname{tr}\left(A \right)" + assert latex(trace(A**2)) == r"\operatorname{tr}\left(A^{2} \right)" + + +def test_print_basic(): + # Issue 15303 + from sympy.core.basic import Basic + from sympy.core.expr import Expr + + # dummy class for testing printing where the function is not + # implemented in latex.py + class UnimplementedExpr(Expr): + def __new__(cls, e): + return Basic.__new__(cls, e) + + # dummy function for testing + def unimplemented_expr(expr): + return UnimplementedExpr(expr).doit() + + # override class name to use superscript / subscript + def unimplemented_expr_sup_sub(expr): + result = UnimplementedExpr(expr) + result.__class__.__name__ = 'UnimplementedExpr_x^1' + return result + + assert latex(unimplemented_expr(x)) == r'\operatorname{UnimplementedExpr}\left(x\right)' + assert latex(unimplemented_expr(x**2)) == \ + r'\operatorname{UnimplementedExpr}\left(x^{2}\right)' + assert latex(unimplemented_expr_sup_sub(x)) == \ + r'\operatorname{UnimplementedExpr^{1}_{x}}\left(x\right)' + + +def test_MatrixSymbol_bold(): + # Issue #15871 + from sympy.matrices.expressions.trace import trace + A = MatrixSymbol("A", 2, 2) + assert latex(trace(A), mat_symbol_style='bold') == \ + r"\operatorname{tr}\left(\mathbf{A} \right)" + assert latex(trace(A), mat_symbol_style='plain') == \ + r"\operatorname{tr}\left(A \right)" + + A = MatrixSymbol("A", 3, 3) + B = MatrixSymbol("B", 3, 3) + C = MatrixSymbol("C", 3, 3) + + assert latex(-A, mat_symbol_style='bold') == r"- \mathbf{A}" + assert latex(A - A*B - B, mat_symbol_style='bold') == \ + r"\mathbf{A} - \mathbf{A} \mathbf{B} - \mathbf{B}" + assert latex(-A*B - A*B*C - B, mat_symbol_style='bold') == \ + r"- \mathbf{A} \mathbf{B} - \mathbf{A} \mathbf{B} \mathbf{C} - \mathbf{B}" + + A_k = MatrixSymbol("A_k", 3, 3) + assert latex(A_k, mat_symbol_style='bold') == r"\mathbf{A}_{k}" + + A = MatrixSymbol(r"\nabla_k", 3, 3) + assert latex(A, mat_symbol_style='bold') == r"\mathbf{\nabla}_{k}" + +def test_AppliedPermutation(): + p = Permutation(0, 1, 2) + x = Symbol('x') + assert latex(AppliedPermutation(p, x)) == \ + r'\sigma_{\left( 0\; 1\; 2\right)}(x)' + + +def test_PermutationMatrix(): + p = Permutation(0, 1, 2) + assert latex(PermutationMatrix(p)) == r'P_{\left( 0\; 1\; 2\right)}' + p = Permutation(0, 3)(1, 2) + assert latex(PermutationMatrix(p)) == \ + r'P_{\left( 0\; 3\right)\left( 1\; 2\right)}' + + +def test_issue_21758(): + from sympy.functions.elementary.piecewise import piecewise_fold + from sympy.series.fourier import FourierSeries + x = Symbol('x') + k, n = symbols('k n') + fo = FourierSeries(x, (x, -pi, pi), (0, SeqFormula(0, (k, 1, oo)), SeqFormula( + Piecewise((-2*pi*cos(n*pi)/n + 2*sin(n*pi)/n**2, (n > -oo) & (n < oo) & Ne(n, 0)), + (0, True))*sin(n*x)/pi, (n, 1, oo)))) + assert latex(piecewise_fold(fo)) == '\\begin{cases} 2 \\sin{\\left(x \\right)}' \ + ' - \\sin{\\left(2 x \\right)} + \\frac{2 \\sin{\\left(3 x \\right)}}{3} +' \ + ' \\ldots & \\text{for}\\: n > -\\infty \\wedge n < \\infty \\wedge ' \ + 'n \\neq 0 \\\\0 & \\text{otherwise} \\end{cases}' + assert latex(FourierSeries(x, (x, -pi, pi), (0, SeqFormula(0, (k, 1, oo)), + SeqFormula(0, (n, 1, oo))))) == '0' + + +def test_imaginary_unit(): + assert latex(1 + I) == r'1 + i' + assert latex(1 + I, imaginary_unit='i') == r'1 + i' + assert latex(1 + I, imaginary_unit='j') == r'1 + j' + assert latex(1 + I, imaginary_unit='foo') == r'1 + foo' + assert latex(I, imaginary_unit="ti") == r'\text{i}' + assert latex(I, imaginary_unit="tj") == r'\text{j}' + + +def test_text_re_im(): + assert latex(im(x), gothic_re_im=True) == r'\Im{\left(x\right)}' + assert latex(im(x), gothic_re_im=False) == r'\operatorname{im}{\left(x\right)}' + assert latex(re(x), gothic_re_im=True) == r'\Re{\left(x\right)}' + assert latex(re(x), gothic_re_im=False) == r'\operatorname{re}{\left(x\right)}' + + +def test_latex_diffgeom(): + from sympy.diffgeom import Manifold, Patch, CoordSystem, BaseScalarField, Differential + from sympy.diffgeom.rn import R2 + x,y = symbols('x y', real=True) + m = Manifold('M', 2) + assert latex(m) == r'\text{M}' + p = Patch('P', m) + assert latex(p) == r'\text{P}_{\text{M}}' + rect = CoordSystem('rect', p, [x, y]) + assert latex(rect) == r'\text{rect}^{\text{P}}_{\text{M}}' + b = BaseScalarField(rect, 0) + assert latex(b) == r'\mathbf{x}' + + g = Function('g') + s_field = g(R2.x, R2.y) + assert latex(Differential(s_field)) == \ + r'\operatorname{d}\left(g{\left(\mathbf{x},\mathbf{y} \right)}\right)' + + +def test_unit_printing(): + assert latex(5*meter) == r'5 \text{m}' + assert latex(3*gibibyte) == r'3 \text{gibibyte}' + assert latex(4*microgram/second) == r'\frac{4 \mu\text{g}}{\text{s}}' + assert latex(4*micro*gram/second) == r'\frac{4 \mu \text{g}}{\text{s}}' + assert latex(5*milli*meter) == r'5 \text{m} \text{m}' + assert latex(milli) == r'\text{m}' + + +def test_issue_17092(): + x_star = Symbol('x^*') + assert latex(Derivative(x_star, x_star,2)) == r'\frac{d^{2}}{d \left(x^{*}\right)^{2}} x^{*}' + + +def test_latex_decimal_separator(): + + x, y, z, t = symbols('x y z t') + k, m, n = symbols('k m n', integer=True) + f, g, h = symbols('f g h', cls=Function) + + # comma decimal_separator + assert(latex([1, 2.3, 4.5], decimal_separator='comma') == r'\left[ 1; \ 2{,}3; \ 4{,}5\right]') + assert(latex(FiniteSet(1, 2.3, 4.5), decimal_separator='comma') == r'\left\{1; 2{,}3; 4{,}5\right\}') + assert(latex((1, 2.3, 4.6), decimal_separator = 'comma') == r'\left( 1; \ 2{,}3; \ 4{,}6\right)') + assert(latex((1,), decimal_separator='comma') == r'\left( 1;\right)') + + # period decimal_separator + assert(latex([1, 2.3, 4.5], decimal_separator='period') == r'\left[ 1, \ 2.3, \ 4.5\right]' ) + assert(latex(FiniteSet(1, 2.3, 4.5), decimal_separator='period') == r'\left\{1, 2.3, 4.5\right\}') + assert(latex((1, 2.3, 4.6), decimal_separator = 'period') == r'\left( 1, \ 2.3, \ 4.6\right)') + assert(latex((1,), decimal_separator='period') == r'\left( 1,\right)') + + # default decimal_separator + assert(latex([1, 2.3, 4.5]) == r'\left[ 1, \ 2.3, \ 4.5\right]') + assert(latex(FiniteSet(1, 2.3, 4.5)) == r'\left\{1, 2.3, 4.5\right\}') + assert(latex((1, 2.3, 4.6)) == r'\left( 1, \ 2.3, \ 4.6\right)') + assert(latex((1,)) == r'\left( 1,\right)') + + assert(latex(Mul(3.4,5.3), decimal_separator = 'comma') == r'18{,}02') + assert(latex(3.4*5.3, decimal_separator = 'comma') == r'18{,}02') + x = symbols('x') + y = symbols('y') + z = symbols('z') + assert(latex(x*5.3 + 2**y**3.4 + 4.5 + z, decimal_separator = 'comma') == r'2^{y^{3{,}4}} + 5{,}3 x + z + 4{,}5') + + assert(latex(0.987, decimal_separator='comma') == r'0{,}987') + assert(latex(S(0.987), decimal_separator='comma') == r'0{,}987') + assert(latex(.3, decimal_separator='comma') == r'0{,}3') + assert(latex(S(.3), decimal_separator='comma') == r'0{,}3') + + + assert(latex(5.8*10**(-7), decimal_separator='comma') == r'5{,}8 \cdot 10^{-7}') + assert(latex(S(5.7)*10**(-7), decimal_separator='comma') == r'5{,}7 \cdot 10^{-7}') + assert(latex(S(5.7*10**(-7)), decimal_separator='comma') == r'5{,}7 \cdot 10^{-7}') + + x = symbols('x') + assert(latex(1.2*x+3.4, decimal_separator='comma') == r'1{,}2 x + 3{,}4') + assert(latex(FiniteSet(1, 2.3, 4.5), decimal_separator='period') == r'\left\{1, 2.3, 4.5\right\}') + + # Error Handling tests + raises(ValueError, lambda: latex([1,2.3,4.5], decimal_separator='non_existing_decimal_separator_in_list')) + raises(ValueError, lambda: latex(FiniteSet(1,2.3,4.5), decimal_separator='non_existing_decimal_separator_in_set')) + raises(ValueError, lambda: latex((1,2.3,4.5), decimal_separator='non_existing_decimal_separator_in_tuple')) + +def test_Str(): + from sympy.core.symbol import Str + assert str(Str('x')) == r'x' + +def test_latex_escape(): + assert latex_escape(r"~^\&%$#_{}") == "".join([ + r'\textasciitilde', + r'\textasciicircum', + r'\textbackslash', + r'\&', + r'\%', + r'\$', + r'\#', + r'\_', + r'\{', + r'\}', + ]) + +def test_emptyPrinter(): + class MyObject: + def __repr__(self): + return "" + + # unknown objects are monospaced + assert latex(MyObject()) == r"\mathtt{\text{}}" + + # even if they are nested within other objects + assert latex((MyObject(),)) == r"\left( \mathtt{\text{}},\right)" + +def test_global_settings(): + import inspect + + # settings should be visible in the signature of `latex` + assert inspect.signature(latex).parameters['imaginary_unit'].default == r'i' + assert latex(I) == r'i' + try: + # but changing the defaults... + LatexPrinter.set_global_settings(imaginary_unit='j') + # ... should change the signature + assert inspect.signature(latex).parameters['imaginary_unit'].default == r'j' + assert latex(I) == r'j' + finally: + # there's no public API to undo this, but we need to make sure we do + # so as not to impact other tests + del LatexPrinter._global_settings['imaginary_unit'] + + # check we really did undo it + assert inspect.signature(latex).parameters['imaginary_unit'].default == r'i' + assert latex(I) == r'i' + +def test_pickleable(): + # this tests that the _PrintFunction instance is pickleable + import pickle + assert pickle.loads(pickle.dumps(latex)) is latex + +def test_printing_latex_array_expressions(): + assert latex(ArraySymbol("A", (2, 3, 4))) == "A" + assert latex(ArrayElement("A", (2, 1/(1-x), 0))) == "{{A}_{2, \\frac{1}{1 - x}, 0}}" + M = MatrixSymbol("M", 3, 3) + N = MatrixSymbol("N", 3, 3) + assert latex(ArrayElement(M*N, [x, 0])) == "{{\\left(M N\\right)}_{x, 0}}" + +def test_Array(): + arr = Array(range(10)) + assert latex(arr) == r'\left[\begin{matrix}0 & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9\end{matrix}\right]' + + arr = Array(range(11)) + # added empty arguments {} + assert latex(arr) == r'\left[\begin{array}{}0 & 1 & 2 & 3 & 4 & 5 & 6 & 7 & 8 & 9 & 10\end{array}\right]' + +def test_latex_with_unevaluated(): + with evaluate(False): + assert latex(a * a) == r"a a"