--[[ This file contains the unit tests for the physical.Dimension class. Copyright (c) 2020 Thomas Jenni Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. ]]-- local lu = require("luaunit") package.path = "../src/?.lua;" .. package.path local physical = require("physical") local D = physical.Dimension local L = D("L") local M = D("M") local T = D("T") local I = D("I") local K = D("K") local N = D("N") local J = D("J") TestDimension = {} --class -- Dimension.new(o=nil) function TestDimension:testEmptyConstructor() local d = D() lu.assertTrue( d:iszero() ) end function TestDimension:testConstructorByString() local d = D("Dimensionless") lu.assertTrue( d:iszero() ) end function TestDimension:testCopyConstructor() local d1, d2 d1 = D("Energy") lu.assertEquals( d1, M*L^2/T^2 ) d2 = D(d1) lu.assertEquals( d2, M*L^2/T^2 ) end function TestDimension:testDefine() local i1 = D("Force")^4 local i2 = D.define("Insanity",i1) local i3 = D("Insanity") lu.assertEquals( i1, L^4 * M^4 * T^-8) lu.assertEquals( i2, L^4 * M^4 * T^-8) lu.assertEquals( i3, L^4 * M^4 * T^-8) end function TestDimension:testToString() local d = D("Force") lu.assertEquals( tostring(d), "[Force]" ) local d = D(L^-1 * T * I^2 * K^3 * N^4 * J^5) lu.assertEquals( tostring(d), "[L]^-1 [T] [I]^2 [K]^3 [N]^4 [J]^5" ) end function TestDimension:testEqual() local d1 = D("Energy") local d2 = D("Force") local d3 = D("Torque") lu.assertEquals( d1==d2, false) lu.assertEquals( d1==d3, true) end function TestDimension:testMultiply() local d1 = D("Force") local d2 = D("Energy") local d3 = d1 * d2 local d4 = d2 * d1 lu.assertEquals( d3, L^3 * M^2 * T^-4) lu.assertEquals( d3, d4) end function TestDimension:testDivide() local d1 = D("Force") local d2 = D("Energy") lu.assertEquals( d1, {1,1,-2,0,0,0,0,0,0}) lu.assertEquals( d2, {2,1,-2,0,0,0,0,0,0}) local d3 = d1 / d2 local d4 = d2 / d1 lu.assertEquals( d3, {-1,0,0,0,0,0,0,0,0}) lu.assertNotEquals( d3, d4) end function TestDimension:testPow() local d = D("Length")^3 lu.assertEquals( d, L^3) end function TestDimension:isequal() local d = D("Length")^3 lu.assertTrue( d == L^3) local d = D("Force") lu.assertTrue( d == L * M / T^2) end -- Test Dimension Definitions function TestDimension:testLength() lu.assertEquals(D("Length"), L) lu.assertEquals(D("L"), L) end function TestDimension:testMass() lu.assertEquals(D("Mass"), M) lu.assertEquals(D("M"), M) end function TestDimension:testTime() lu.assertEquals(D("Time"), T) lu.assertEquals(D("T"), T) end function TestDimension:testCreateByNameForce() lu.assertTrue( D("Force") == M*L/T^2 ) end function TestDimension:testArea() lu.assertEquals(D("Area"), L^2) end function TestDimension:testVolume() lu.assertEquals(D("Volume"), L^3) end function TestDimension:testFrequency() lu.assertEquals(D("Frequency"), T^-1) end function TestDimension:testFrequency() lu.assertEquals(D("Frequency"), T^-1) end function TestDimension:testDensity() lu.assertEquals(D("Density"), M / D("Volume")) end function TestDimension:testVelocity() lu.assertEquals(D("Velocity"), L / T) end function TestDimension:testAcceleration() lu.assertEquals(D("Acceleration"), D("Velocity") / T) end function TestDimension:testForce() lu.assertEquals(D("Force"), M * D("Acceleration")) end function TestDimension:testEnergy() lu.assertEquals(D("Energy"), D("Force") * L) end function TestDimension:testPower() lu.assertEquals(D("Power"), D("Energy") / T) end function TestDimension:testPower() lu.assertEquals(D("Power"), D("Energy") / T) end function TestDimension:testTorque() lu.assertEquals(D("Energy"), D("Torque")) end function TestDimension:testTorque() lu.assertEquals(D("Pressure"), D("Force") / D("Area")) end function TestDimension:testImpulse() lu.assertEquals(D("Impulse"), M * D("Velocity")) end function TestDimension:testSpecificAbsorbedDose() lu.assertEquals(D("Absorbed Dose"), D("Energy") / M) end function TestDimension:testHeatCapacity() lu.assertEquals(D("Heat Capacity"), D("Energy") / K) end function TestDimension:testSpecificHeatCapacity() lu.assertEquals(D("Specific Heat Capacity"), D("Energy") / (M * K) ) end function TestDimension:testAngularMomentum() lu.assertEquals(D("Angular Momentum"), L * D("Impulse") ) end function TestDimension:testAngularMomentofInertia() lu.assertEquals(D("Moment of Inertia"), D("Torque") * T^2 ) end function TestDimension:testEntropy() lu.assertEquals(D("Entropy"), D("Energy") / K ) end function TestDimension:testThermalConductivity() lu.assertEquals(D("Thermal Conductivity"), D("Power") / (L*K) ) end function TestDimension:testElectricCharge() lu.assertEquals(D("Electric Charge"), D("Electric Current") * T ) end function TestDimension:testElectricPermittivity() lu.assertEquals(D("Electric Permittivity"), D("Electric Charge")^2 / ( D("Force") * D("Area") ) ) end function TestDimension:testElectricFieldStrength() lu.assertEquals(D("Electric Field Strength"), D("Force") / D("Electric Charge") ) end function TestDimension:testElectricPotential() lu.assertEquals(D("Electric Potential"), D("Energy") / D("Electric Charge") ) end function TestDimension:testElectricResistance() lu.assertEquals(D("Electric Resistance"), D("Electric Potential") / D("Electric Current") ) end function TestDimension:testElectricConductance() lu.assertEquals(D("Electric Conductance"), 1 / D("Electric Resistance") ) end function TestDimension:testElectricCapacitance() lu.assertEquals(D("Electric Capacitance"), D("Electric Charge") / D("Electric Potential") ) end function TestDimension:testElectricInductance() lu.assertEquals(D("Inductance"), D("Electric Potential") * T / D("Electric Current") ) end function TestDimension:testMagneticFluxDensity() lu.assertEquals(D("Magnetic Flux Density"), D("Force") / (D("Electric Charge") * D("Velocity")) ) end function TestDimension:testMagneticFlux() lu.assertEquals(D("Magnetic Flux"), D("Magnetic Flux Density") * D("Area") ) end function TestDimension:testMagneticPermeability() lu.assertEquals(D("Magnetic Permeability"), D("Magnetic Flux Density") * L / D("Electric Current") ) end function TestDimension:testMagneticFieldStrength() lu.assertEquals(D("Magnetic Field Strength"), D("Magnetic Flux Density") / D("Magnetic Permeability") ) end function TestDimension:testIntensity() lu.assertEquals(D("Intensity"), D("Power") / D("Area") ) end function TestDimension:testReactionRate() lu.assertEquals(D("Reaction Rate"), N / (T * D("Volume")) ) end function TestDimension:testCatalyticActivity() lu.assertEquals(D("Catalytic Activity"), N / T ) end function TestDimension:testChemicalPotential() lu.assertEquals(D("Chemical Potential"), D("Energy") / N ) end function TestDimension:testMolarConcentration() lu.assertEquals(D("Molar Concentration"), N / D("Volume") ) end function TestDimension:testMolarHeatCapacity() lu.assertEquals(D("Molar Heat Capacity"), D("Energy") / (K * N) ) end function TestDimension:testIlluminance() lu.assertEquals(D("Illuminance"), J / D("Area") ) end return TestDimension