/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2020 S.Kocjan * Copyright (C) 2020 KiCad Developers, see AUTHORS.TXT for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ /** * @file * Test suite for NGSPICE_CIRCUIT_MODEL */ #include #include #include #include // Code under test #include #include #include #include class TEST_NGSPICE_HELPERS { public: TEST_NGSPICE_HELPERS() : m_manager( true ), m_schematic( nullptr ), m_exporter( &m_schematic ) { m_manager.LoadProject( "" ); m_schematic.SetProject( &m_manager.Prj() ); } virtual ~TEST_NGSPICE_HELPERS() { m_schematic.Reset(); } SETTINGS_MANAGER m_manager; SCHEMATIC m_schematic; NGSPICE_CIRCUIT_MODEL m_exporter; }; /** * Declare the test suite */ BOOST_FIXTURE_TEST_SUITE( NgspiceCircuitModel, TEST_NGSPICE_HELPERS ) /** * Check if simulation command is recognised properly */ BOOST_AUTO_TEST_CASE( CommandToSimType ) { struct TEST_DATA { wxString command; SIM_TYPE type; }; std::vector testData = { { ".op", ST_OP }, { ".option TEMP=27", ST_UNKNOWN }, { ".tran 0 1 0.1", ST_TRANSIENT }, { ".tran 0 1 0.1 UIC", ST_TRANSIENT }, { ".ac dec 10 1 10K", ST_AC }, { ".ac dec 10 1K 100MEG", ST_AC }, { ".ac lin 100 1 100HZ", ST_AC }, { ".dc VIN 0.25 5.0 0.25", ST_DC }, { ".dc VDS 0 10 .5 VGS 0 5 1", ST_DC }, { ".dc VCE 0 10 .25 IB 0 10u 1u", ST_DC }, { ".dc RLoad 1k 2k 100", ST_DC }, { ".dc TEMP -15 75 5", ST_DC }, { ".disto dec 10 1kHz 100MEG", ST_DISTORTION }, { ".disto dec 10 1kHz 100MEG 0.9", ST_DISTORTION }, { ".noise v(5) VIN dec 10 1kHz 100MEG", ST_NOISE }, { ".noise v(5,3) V1 oct 8 1.0 1.0e6 1", ST_NOISE }, { ".pz 1 0 3 0 cur pol", ST_POLE_ZERO }, { ".pz 2 3 5 0 vol zer", ST_POLE_ZERO }, { ".pz 4 1 4 1 cur pz", ST_POLE_ZERO }, { ".SENS V(1,OUT)", ST_SENSITIVITY }, { ".SENS V(OUT) AC DEC 10 100 100k", ST_SENSITIVITY }, { ".SENS I(VTEST)", ST_SENSITIVITY }, { ".tf v(5, 3) VIN", ST_TRANS_FUNC }, { ".tf i(VLOAD) VIN", ST_TRANS_FUNC }, }; for( auto& step : testData ) { SIM_TYPE result = NGSPICE_CIRCUIT_MODEL::CommandToSimType( step.command ); BOOST_CHECK_EQUAL( result, step.type ); } for( auto& step : testData ) { step.command.Append( "\n" ); SIM_TYPE result = NGSPICE_CIRCUIT_MODEL::CommandToSimType( step.command ); BOOST_CHECK_EQUAL( result, step.type ); } } /** * Check conversion from internal spice vector name to eeschema format */ BOOST_AUTO_TEST_CASE( VectorToSignal ) { struct TEST_DATA { std::string vector; wxString signal; SIM_PLOT_TYPE type; }; std::vector testData = { { "@c3[i]", "I(C3)", SPT_CURRENT }, { "@r12[i]", "I(R12)", SPT_CURRENT }, { "@r7[i]", "I(R7)", SPT_CURRENT }, { "@l2[i]", "I(L2)", SPT_CURRENT }, { "@c2[i]", "I(C2)", SPT_CURRENT }, { "@r6[i]", "I(R6)", SPT_CURRENT }, { "@r5[i]", "I(R5)", SPT_CURRENT }, { "@r10[i]", "I(R10)", SPT_CURRENT }, { "@q3[ie]", "Ie(Q3)", SPT_CURRENT }, { "@q3[ic]", "Ic(Q3)", SPT_CURRENT }, { "@q3[ib]", "Ib(Q3)", SPT_CURRENT }, { "@r11[i]", "I(R11)", SPT_CURRENT }, { "@r8[i]", "I(R8)", SPT_CURRENT }, { "@q1[ie]", "Ie(Q1)", SPT_CURRENT }, { "@q1[ic]", "Ic(Q1)", SPT_CURRENT }, { "@q1[ib]", "Ib(Q1)", SPT_CURRENT }, { "@r1[i]", "I(R1)", SPT_CURRENT }, { "@l1[i]", "I(L1)", SPT_CURRENT }, { "@c4[i]", "I(C4)", SPT_CURRENT }, { "@r2[i]", "I(R2)", SPT_CURRENT }, { "@q2[ig]", "Ig(Q2)", SPT_CURRENT }, { "@q2[id]", "Id(Q2)", SPT_CURRENT }, { "@q2[is]", "Is(Q2)", SPT_CURRENT }, { "@v2[i]", "I(V2)", SPT_CURRENT }, { "@r9[i]", "I(R9)", SPT_CURRENT }, { "@c1[i]", "I(C1)", SPT_CURRENT }, { "@v1[i]", "I(V1)", SPT_CURRENT }, { "@r3[i]", "I(R3)", SPT_CURRENT }, { "@r4[i]", "I(R4)", SPT_CURRENT }, { "vout", "V(vout)", SPT_VOLTAGE }, { "net-_q3-pad2_", "V(net-_q3-pad2_)", SPT_VOLTAGE }, { "net-_q2-pad3_", "V(net-_q2-pad3_)", SPT_VOLTAGE }, { "net-_q2-pad1_", "V(net-_q2-pad1_)", SPT_VOLTAGE }, { "net-_q1-pad3_", "V(net-_q1-pad3_)", SPT_VOLTAGE }, { "net-_l2-pad1_", "V(net-_l2-pad1_)", SPT_VOLTAGE }, { "net-_c4-pad2_", "V(net-_c4-pad2_)", SPT_VOLTAGE }, { "net-_c3-pad1_", "V(net-_c3-pad1_)", SPT_VOLTAGE }, { "net-_c1-pad2_", "V(net-_c1-pad2_)", SPT_VOLTAGE }, { "/vin", "V(/vin)", SPT_VOLTAGE }, { "/vbase", "V(/vbase)", SPT_VOLTAGE }, { "+12v", "V(+12v)", SPT_VOLTAGE }, { "@m1[cgs]", "", SPT_UNKNOWN }, { "@d1[g11]", "", SPT_UNKNOWN }, { "@d1[c12]", "", SPT_UNKNOWN }, { "@d1[y21]", "", SPT_UNKNOWN }, { "@n1[vth0]", "", SPT_UNKNOWN }, { "@mn1[gm]", "", SPT_UNKNOWN }, { "@m.xmos1.xmos2.m1[vdsat]", "", SPT_UNKNOWN } }; for( auto& step : testData ) { wxString outputSignalName; SIM_PLOT_TYPE retVal; retVal = m_exporter.VectorToSignal( step.vector, outputSignalName ); BOOST_CHECK_EQUAL( retVal, step.type ); BOOST_CHECK_EQUAL( outputSignalName.Cmp( step.signal ), 0 ); } } BOOST_AUTO_TEST_SUITE_END()