# Copyright (c) 2019-2025, Saransh Chopra, Henry Schreiner, Eduardo Rodrigues, Jonas Eschle, and Jim Pivarski. # # Distributed under the 3-clause BSD license, see accompanying file LICENSE # or https://github.com/scikit-hep/vector for details. from __future__ import annotations import pytest import vector sympy = pytest.importorskip("sympy") pytestmark = pytest.mark.sympy x, y, rho, phi, eta = sympy.symbols("x y rho phi eta", real=True) values = {x: 3, y: 4, rho: 5, phi: 0, eta: 1.4436354751788103} def test_xy_z(): vec = vector.VectorSympy3D( azimuthal=vector.backends.sympy.AzimuthalSympyXY(x, y), longitudinal=vector.backends.sympy.LongitudinalSympyZ( sympy.sqrt(x**2 + y**2) * sympy.sinh(eta) ), ) assert vec.eta.simplify() == sympy.asinh(sympy.sinh(eta)) assert vec.eta.subs(values).evalf() == pytest.approx(1.4436354751788103) def test_xy_theta(): vec = vector.VectorSympy3D( azimuthal=vector.backends.sympy.AzimuthalSympyXY(x, y), longitudinal=vector.backends.sympy.LongitudinalSympyTheta( 2.0 * sympy.atan(sympy.exp(-eta)) ), ) assert vec.eta.simplify() == -sympy.log( sympy.tan(1.0 * sympy.atan(sympy.exp(-eta))) ) assert vec.eta.subs(values).evalf() == pytest.approx(1.4436354751788103) def test_xy_eta(): vec = vector.VectorSympy3D( azimuthal=vector.backends.sympy.AzimuthalSympyXY(x, y), longitudinal=vector.backends.sympy.LongitudinalSympyEta(eta), ) assert vec.eta == eta assert vec.eta.subs(values).evalf() == pytest.approx(1.4436354751788103) def test_rhophi_z(): vec = vector.VectorSympy3D( azimuthal=vector.backends.sympy.AzimuthalSympyRhoPhi(rho, phi), longitudinal=vector.backends.sympy.LongitudinalSympyZ(rho * sympy.sinh(eta)), ) assert vec.eta.simplify() == sympy.asinh(sympy.sinh(eta)) assert vec.eta.subs(values).evalf() == pytest.approx(1.4436354751788103) def test_rhophi_theta(): vec = vector.VectorSympy3D( azimuthal=vector.backends.sympy.AzimuthalSympyRhoPhi(rho, phi), longitudinal=vector.backends.sympy.LongitudinalSympyTheta( 2.0 * sympy.atan(sympy.exp(-eta)) ), ) assert vec.eta.simplify() == -sympy.log( sympy.tan(1.0 * sympy.atan(sympy.exp(-eta))) ) assert vec.eta.subs(values).evalf() == pytest.approx(1.4436354751788103) def test_rhophi_eta(): vec = vector.VectorSympy3D( azimuthal=vector.backends.sympy.AzimuthalSympyRhoPhi(rho, phi), longitudinal=vector.backends.sympy.LongitudinalSympyEta(eta), ) assert vec.eta == eta assert vec.eta.subs(values).evalf() == pytest.approx(1.4436354751788103)