/* Copyright 2018 Statoil ASA This file is part of the Open Porous Media project (OPM). OPM 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 3 of the License, or (at your option) any later version. OPM 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 OPM. If not, see . */ #define BOOST_TEST_MODULE Aggregate_MSW_Data #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include struct MockIH { MockIH(const int numWells, const int nsegWell = 2, // E100 const int isegPerWell = 22, // E100 const int rsegPerWell = 146, // E100 const int ilbsPerWell = 5, // E100 const int ilbrPerWell = 10); // E100 std::vector value; using Sz = std::vector::size_type; Sz nwells; Sz nsegwl; Sz nswlmx; Sz nsegmx; Sz nlbrmx; Sz nisegz; Sz nrsegz; Sz nilbrz; }; MockIH::MockIH(const int numWells, const int nsegWell, const int isegPerWell, const int rsegPerWell, const int ilbsPerWell, const int ilbrPerWell ) : value(411, 0) { using Ix = ::Opm::RestartIO::Helpers::VectorItems::intehead; this->nwells = this->value[Ix::NWELLS] = numWells; this->nsegwl = this->value[Ix::NSEGWL] = nsegWell; this->nswlmx = this->value[Ix::NSWLMX] = 2; this->nsegmx = this->value[Ix::NSEGMX] = 32; this->nisegz = this->value[Ix::NISEGZ] = isegPerWell; this->nrsegz = this->value[Ix::NRSEGZ] = rsegPerWell; this->nlbrmx = this->value[Ix::NLBRMX] = ilbsPerWell; this->nilbrz = this->value[Ix::NILBRZ] = ilbrPerWell; } namespace { Opm::Deck first_sim() { // Mostly copy of tests/FIRST_SIM.DATA const std::string input = std::string { R"~( RUNSPEC TITLE TWO MULTI-LATERAL WELLS; PRODUCER AND INJECTOR - MULTI-SEGMENT BRANCHES DIMENS 10 5 10 / OIL WATER GAS DISGAS FIELD TABDIMS 1 1 15 15 2 15 / EQLDIMS 2 / WELLDIMS 3 20 1 3 / WSEGDIMS 2 32 5 / UNIFIN UNIFOUT --FMTIN --FMTOUT START 1 'JAN' 2015 / -- RPTRUNSP GRID ========================================================= --NOGGF BOX 1 10 1 5 1 1 / TOPS 50*7000 / BOX 1 10 1 5 1 10 / DXV 10*100 / DYV 5*100 / DZV 2*20 100 7*20 / EQUALS -- 'DX' 100 / -- 'DY' 100 / 'PERMX' 50 / 'PERMZ' 5 / -- 'DZ' 20 / 'PORO' 0.2 / -- 'TOPS' 7000 1 10 1 5 1 1 / -- 'DZ' 100 1 10 1 5 3 3 / -- 'PORO' 0.0 1 10 1 5 3 3 / / COPY PERMX PERMY / / RPTGRID -- Report Levels for Grid Section Data -- / PROPS ========================================================== -- WATER RELATIVE PERMEABILITY AND CAPILLARY PRESSURE ARE TABULATED AS -- A FUNCTION OF WATER SATURATION. -- -- SWAT KRW PCOW SWFN 0.12 0 0 1.0 0.00001 0 / -- SIMILARLY FOR GAS -- -- SGAS KRG PCOG SGFN 0 0 0 0.02 0 0 0.05 0.005 0 0.12 0.025 0 0.2 0.075 0 0.25 0.125 0 0.3 0.19 0 0.4 0.41 0 0.45 0.6 0 0.5 0.72 0 0.6 0.87 0 0.7 0.94 0 0.85 0.98 0 1.0 1.0 0 / -- OIL RELATIVE PERMEABILITY IS TABULATED AGAINST OIL SATURATION -- FOR OIL-WATER AND OIL-GAS-CONNATE WATER CASES -- -- SOIL KROW KROG SOF3 0 0 0 0.18 0 0 0.28 0.0001 0.0001 0.38 0.001 0.001 0.43 0.01 0.01 0.48 0.021 0.021 0.58 0.09 0.09 0.63 0.2 0.2 0.68 0.35 0.35 0.76 0.7 0.7 0.83 0.98 0.98 0.86 0.997 0.997 0.879 1 1 0.88 1 1 / -- PVT PROPERTIES OF WATER -- -- REF. PRES. REF. FVF COMPRESSIBILITY REF VISCOSITY VISCOSIBILITY PVTW 4014.7 1.029 3.13D-6 0.31 0 / -- ROCK COMPRESSIBILITY -- -- REF. PRES COMPRESSIBILITY ROCK 14.7 3.0D-6 / -- SURFACE DENSITIES OF RESERVOIR FLUIDS -- -- OIL WATER GAS DENSITY 49.1 64.79 0.06054 / -- PVT PROPERTIES OF DRY GAS (NO VAPOURISED OIL) -- WE WOULD USE PVTG TO SPECIFY THE PROPERTIES OF WET GAS -- -- PGAS BGAS VISGAS PVDG 14.7 166.666 0.008 264.7 12.093 0.0096 514.7 6.274 0.0112 1014.7 3.197 0.014 2014.7 1.614 0.0189 2514.7 1.294 0.0208 3014.7 1.080 0.0228 4014.7 0.811 0.0268 5014.7 0.649 0.0309 9014.7 0.386 0.047 / -- PVT PROPERTIES OF LIVE OIL (WITH DISSOLVED GAS) -- WE WOULD USE PVDO TO SPECIFY THE PROPERTIES OF DEAD OIL -- -- FOR EACH VALUE OF RS THE SATURATION PRESSURE, FVF AND VISCOSITY -- ARE SPECIFIED. FOR RS=1.27 AND 1.618, THE FVF AND VISCOSITY OF -- UNDERSATURATED OIL ARE DEFINED AS A FUNCTION OF PRESSURE. DATA -- FOR UNDERSATURATED OIL MAY BE SUPPLIED FOR ANY RS, BUT MUST BE -- SUPPLIED FOR THE HIGHEST RS (1.618). -- -- RS POIL FVFO VISO PVTO 0.001 14.7 1.062 1.04 / 0.0905 264.7 1.15 0.975 / 0.18 514.7 1.207 0.91 / 0.371 1014.7 1.295 0.83 / 0.636 2014.7 1.435 0.695 / 0.775 2514.7 1.5 0.641 / 0.93 3014.7 1.565 0.594 / 1.270 4014.7 1.695 0.51 5014.7 1.671 0.549 9014.7 1.579 0.74 / 1.618 5014.7 1.827 0.449 9014.7 1.726 0.605 / / RPTPROPS -- PROPS Reporting Options -- / REGIONS =========================================================== FIPNUM 100*1 400*2 / EQLNUM 100*1 400*2 / RPTREGS / SOLUTION ============================================================ EQUIL 7020.00 2700.00 7990.00 .00000 7020.00 .00000 0 0 5 / 7200.00 3700.00 7300.00 .00000 7000.00 .00000 1 0 5 / RSVD 2 TABLES 3 NODES IN EACH FIELD 12:00 17 AUG 83 7000.0 1.0000 7990.0 1.0000 / 7000.0 1.0000 7400.0 1.0000 / RPTRST -- Restart File Output Control -- 'BASIC=2' 'FLOWS' 'POT' 'PRES' / --RPTSOL -- -- Initialisation Print Output -- --'PRES' 'SOIL' 'SWAT' 'SGAS' 'RS' 'RESTART=1' 'FIP=2' 'EQUIL' 'RSVD' / SUMMARY =========================================================== FOPR WOPR 'PROD' / FGPR FWPR FWIR FWCT FGOR --RUNSUM ALL MSUMLINS MSUMNEWT SEPARATE SCHEDULE =========================================================== DEBUG 1 3 / DRSDT 1.0E20 / RPTSCHED 'PRES' 'SWAT' 'SGAS' 'RESTART=1' 'RS' 'WELLS=2' 'SUMMARY=2' 'CPU=2' 'WELSPECS' 'NEWTON=2' / NOECHO ECHO WELSPECS 'PROD' 'G' 1 5 7030 'OIL' 0.0 'STD' 'STOP' / 'WINJ' 'G' 10 1 7030 'WAT' 0.0 'STD' 'STOP' / / COMPDAT 'PROD' 1 5 2 2 3* 0.2 3* 'X' / 'PROD' 2 5 2 2 3* 0.2 3* 'X' / 'PROD' 3 5 2 2 3* 0.2 3* 'X' / 'PROD' 4 5 2 2 3* 0.2 3* 'X' / 'PROD' 5 5 2 2 3* 0.2 3* 'X' / 'WINJ' 10 1 9 9 3* 0.2 3* 'X' / 'WINJ' 9 1 9 9 3* 0.2 3* 'X' / 'WINJ' 8 1 9 9 3* 0.2 3* 'X' / 'WINJ' 7 1 9 9 3* 0.2 3* 'X' / 'WINJ' 6 1 9 9 3* 0.2 3* 'X' / / WELSEGS -- Name Dep 1 Tlen 1 Vol 1 'PROD' 7010 10 0.31 'INC' / -- First Last Branch Outlet Length Depth Diam Ruff Area Vol -- Seg Seg Num Seg Chang -- Main Stem 2 12 1 1 20 20 0.2 1.E-3 1* 1* / -- Top Branch 13 13 2 3 50 0 0.2 1.E-3 1* 1* / 14 17 2 13 100 0 0.2 1.E-3 1* 1* / / COMPSEGS -- Name 'PROD' / -- I J K Brn Start End Dirn End -- No Length Length Penet Range -- Top Branch 1 5 2 2 30 130 'X' 3* / 2 5 2 2 130 230 'X' 3* / 3 5 2 2 230 330 'X' 3* / 4 5 2 2 330 430 'X' 3* / 5 5 2 2 430 530 'X' 3* / -- Middle Branch / WELSEGS -- Name Dep 1 Tlen 1 Vol 1 'WINJ' 7010 10 0.31 'INC' / -- First Last Branch Outlet Length Depth Diam Ruff Area Vol -- Seg Seg Num Seg Chang -- Main Stem 2 14 1 1 20 20 0.2 1.E-3 1* 1* / -- Bottom Branch 15 15 2 14 50 0 0.2 1.E-3 1* 1* / 16 19 2 15 100 0 0.2 1.E-3 1* 1* / / COMPSEGS -- Name 'WINJ' / -- I J K Brn Start End Dirn End -- No Length Length Penet Range -- Bottom Branch 10 1 9 2 270 370 'X' 3* / 9 1 9 2 370 470 'X' 3* / 8 1 9 2 470 570 'X' 3* / 7 1 9 2 570 670 'X' 3* / 6 1 9 2 670 770 'X' 3* / / WCONPROD 'PROD' 'OPEN' 'LRAT' 3* 2000 1* 2500 1* / / WCONINJE 'WINJ' 'WAT' 'OPEN' 'RESV' 1* 2000 3500 1* / / TUNING / / / TSTEP 2 2 / END )~" }; return Opm::Parser{}.parseString(input); } Opm::SummaryState sim_state() { auto state = Opm::SummaryState{}; state.update("SPR:PROD:1", 235.); state.update("SPR:PROD:2", 237.); state.update("SPR:PROD:3", 239.); state.update("SPR:PROD:4", 243.); state.update("SOFR:PROD:1", 35.); state.update("SOFR:PROD:2", 30.); state.update("SOFR:PROD:3", 25.); state.update("SOFR:PROD:4", 20.); state.update("SGFR:PROD:1", 25.E3); state.update("SGFR:PROD:2", 20.E3); state.update("SGFR:PROD:3", 15.E3); state.update("SGFR:PROD:4", 10.E3); state.update("SWFR:PROD:1", 11.); state.update("SWFR:PROD:2", 12.); state.update("SWFR:PROD:3", 13.); state.update("SWFR:PROD:4", 14.); state.update("SPR:WINJ:1", 310.); state.update("SPR:WINJ:2", 320.); state.update("SPR:WINJ:3", 330.); state.update("SPR:WINJ:4", 340.); state.update("SWFR:WINJ:1", 21.); state.update("SWFR:WINJ:2", 22.); state.update("SWFR:WINJ:3", 23.); state.update("SWFR:WINJ:4", 24.); state.update("WBHP:WINJ", 234.); return state; } Opm::data::WellRates wr() { using o = ::Opm::data::Rates::opt; auto xw = ::Opm::data::WellRates{}; { xw["PROD"].rates .set(o::wat, 1.0) .set(o::oil, 2.0) .set(o::gas, 3.0); xw["PROD"].bhp = 213.0; double qo = 5.; double qw = 4.; double qg = 50.; for (int i = 0; i < 5; i++) { xw["PROD"].connections.emplace_back(); auto& c = xw["PROD"].connections.back(); c.rates.set(o::wat, qw*(float(i)+1.)) .set(o::oil, qo*(float(i)+1.)) .set(o::gas, qg*(float(i)+1.)); } auto seg = Opm::data::Segment{}; for (std::size_t i = 1; i < 5; i++) { xw["PROD"].segments.insert(std::pair(i,seg)); } xw["WINJ"].bhp = 234.0; xw["WINJ"].rates.set(o::wat, 5.0); xw["WINJ"].rates.set(o::oil, 0.0); xw["WINJ"].rates.set(o::gas, 0.0); qw = 7.; for (int i = 0; i < 5; i++) { xw["WINJ"].connections.emplace_back(); auto& c = xw["WINJ"].connections.back(); c.rates.set(o::wat, qw*(float(i)+1.)) .set(o::oil, 0.) .set(o::gas, 0.); } } return xw; } } struct SimulationCase { explicit SimulationCase(const Opm::Deck& deck) : es ( deck ) , grid ( deck ) , sched( deck, es ) {} // Order requirement: 'es' must be declared/initialised before 'sched'. Opm::EclipseState es; Opm::EclipseGrid grid; Opm::Schedule sched; }; // ===================================================================== BOOST_AUTO_TEST_SUITE(Aggregate_MSW) // test dimensions of multisegment data BOOST_AUTO_TEST_CASE (Constructor) { const auto ih = MockIH{ 5 }; const auto amswd = Opm::RestartIO::Helpers::AggregateMSWData{ ih.value }; BOOST_CHECK_EQUAL(amswd.getISeg().size(), ih.nswlmx * ih.nsegmx * ih.nisegz); BOOST_CHECK_EQUAL(amswd.getRSeg().size(), ih.nswlmx * ih.nsegmx * ih.nrsegz); BOOST_CHECK_EQUAL(amswd.getILBs().size(), ih.nswlmx * ih.nlbrmx); BOOST_CHECK_EQUAL(amswd.getILBr().size(), ih.nswlmx * ih.nlbrmx * ih.nilbrz); } BOOST_AUTO_TEST_CASE (Declared_MSW_Data) { const auto simCase = SimulationCase{first_sim()}; // Report Step 1: 2115-01-01 --> 2015-01-03 const auto rptStep = std::size_t{1}; const auto ih = MockIH { static_cast(simCase.sched.getWells(rptStep).size()) }; BOOST_CHECK_EQUAL(ih.nwells, MockIH::Sz{2}); const auto smry = sim_state(); const Opm::data::WellRates wrc = wr(); auto amswd = Opm::RestartIO::Helpers::AggregateMSWData{ih.value}; amswd.captureDeclaredMSWData(simCase.sched, rptStep, simCase.es.getUnits(), ih.value, simCase.grid, smry, wrc ); // ISEG (PROD) { auto start = 2*ih.nisegz; const auto& iSeg = amswd.getISeg(); BOOST_CHECK_EQUAL(iSeg[start + 0] , 15); // PROD-segment 3, ordered segment BOOST_CHECK_EQUAL(iSeg[start + 1] , 2); // PROD-segment 3, outlet segment BOOST_CHECK_EQUAL(iSeg[start + 2] , 4); // PROD-segment 3, inflow segment current branch BOOST_CHECK_EQUAL(iSeg[start + 3] , 1); // PROD-segment 3, branch number BOOST_CHECK_EQUAL(iSeg[start + 4] , 1); // PROD-segment 3, number of inflow branches BOOST_CHECK_EQUAL(iSeg[start + 5] , 1); // PROD-segment 3, Sum number of inflow branches from first segment to current segment BOOST_CHECK_EQUAL(iSeg[start + 6] , 0); // PROD-segment 3, number of connections in segment BOOST_CHECK_EQUAL(iSeg[start + 7] , 0); // PROD-segment 3, sum of connections with lower segmeent number than current segment BOOST_CHECK_EQUAL(iSeg[start + 8] , 15); // PROD-segment 3, ordered segment start = 13*ih.nisegz; BOOST_CHECK_EQUAL(iSeg[start + 0] , 4); // PROD-segment 14, ordered segment BOOST_CHECK_EQUAL(iSeg[start + 1] , 13); // PROD-segment 14, outlet segment BOOST_CHECK_EQUAL(iSeg[start + 2] , 15); // PROD-segment 14, inflow segment current branch BOOST_CHECK_EQUAL(iSeg[start + 3] , 2); // PROD-segment 14, branch number BOOST_CHECK_EQUAL(iSeg[start + 4] , 0); // PROD-segment 14, number of inflow branches BOOST_CHECK_EQUAL(iSeg[start + 5] , 0); // PROD-segment 14, Sum number of inflow branches from first segment to current segment BOOST_CHECK_EQUAL(iSeg[start + 6] , 1); // PROD-segment 14, number of connections in segment BOOST_CHECK_EQUAL(iSeg[start + 7] , 2); // PROD-segment 14, sum of connections with lower segmeent number than current segment BOOST_CHECK_EQUAL(iSeg[start + 8] , 4); // PROD-segment 14, ordered segment } // ISEG (WINJ) { auto start = ih.nisegz*ih.nsegmx + 13*ih.nisegz; const auto& iSeg = amswd.getISeg(); BOOST_CHECK_EQUAL(iSeg[start + 0] , 6); // WINJ-segment 14, ordered segment BOOST_CHECK_EQUAL(iSeg[start + 1] , 13); // WINJ-segment 14, outlet segment BOOST_CHECK_EQUAL(iSeg[start + 2] , 0); // WINJ-segment 14, inflow segment current branch BOOST_CHECK_EQUAL(iSeg[start + 3] , 1); // WINJ-segment 14, branch number BOOST_CHECK_EQUAL(iSeg[start + 4] , 1); // WINJ-segment 14, number of inflow branches BOOST_CHECK_EQUAL(iSeg[start + 5] , 1); // WINJ-segment 14, Sum number of inflow branches from first segment to current segment BOOST_CHECK_EQUAL(iSeg[start + 6] , 0); // WINJ-segment 14, number of connections in segment BOOST_CHECK_EQUAL(iSeg[start + 7] , 0); // WINJ-segment 14, sum of connections with lower segmeent number than current segment BOOST_CHECK_EQUAL(iSeg[start + 8] , 6); // WINJ-segment 14, ordered segment start = ih.nisegz*ih.nsegmx + 16*ih.nisegz; BOOST_CHECK_EQUAL(iSeg[start + 0] , 3); // WINJ-segment 17, ordered segment BOOST_CHECK_EQUAL(iSeg[start + 1] , 16); // WINJ-segment 17, outlet segment BOOST_CHECK_EQUAL(iSeg[start + 2] , 18); // WINJ-segment 17, inflow segment current branch BOOST_CHECK_EQUAL(iSeg[start + 3] , 2); // WINJ-segment 17, branch number BOOST_CHECK_EQUAL(iSeg[start + 4] , 0); // WINJ-segment 17, number of inflow branches BOOST_CHECK_EQUAL(iSeg[start + 5] , 0); // WINJ-segment 17, Sum number of inflow branches from first segment to current segment BOOST_CHECK_EQUAL(iSeg[start + 6] , 1); // WINJ-segment 17, number of connections in segment BOOST_CHECK_EQUAL(iSeg[start + 7] , 3); // WINJ-segment 17, sum of connections with lower segmeent number than current segment BOOST_CHECK_EQUAL(iSeg[start + 8] , 3); // WINJ-segment 17, ordered segment } // RSEG (PROD) + (WINJ) { // well no 1 - PROD const std::string wname = "PROD"; int segNo = 1; // 'stringSegNum' is one-based (1 .. #segments inclusive) std::string stringSegNo = std::to_string(segNo); const auto i0 = (segNo-1)*ih.nrsegz; const auto& units = simCase.es.getUnits(); const auto gfactor = (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_FIELD) ? 0.1781076 : 0.001; const auto& rseg = amswd.getRSeg(); BOOST_CHECK_CLOSE(rseg[i0 ], 10. , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 1], 7010. , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 5], 0.31 , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 6], 10. , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 7], 7010. , 1.0e-10); const double temp_o = smry.get("SOFR:PROD:1"); const double temp_w = smry.get("SWFR:PROD:1")*0.1; const double temp_g = smry.get("SGFR:PROD:1")*gfactor; auto t0 = temp_o + temp_w + temp_g; double t1 = (std::abs(temp_w) > 0) ? temp_w / t0 : 0.; double t2 = (std::abs(temp_g) > 0) ? temp_g / t0 : 0.; BOOST_CHECK_CLOSE(rseg[i0 + 8], t0, 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 9], t1, 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 10], t2, 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 11], 235., 1.0e-10); } { // well no 2 - WINJ const std::string wname = "WINJ"; int segNo = 1; // 'stringSegNum' is one-based (1 .. #segments inclusive) std::string stringSegNo = std::to_string(segNo); const auto i0 = ih.nrsegz*ih.nsegmx + (segNo-1)*ih.nrsegz; const auto& units = simCase.es.getUnits(); using M = ::Opm::UnitSystem::measure; const auto gfactor = (units.getType() == Opm::UnitSystem::UnitType::UNIT_TYPE_FIELD) ? 0.1781076 : 0.001; const auto& rseg = amswd.getRSeg(); BOOST_CHECK_CLOSE(rseg[i0 ], 10. , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 1], 7010. , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 5], 0.31 , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 6], 10. , 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 7], 7010. , 1.0e-10); const double temp_o = 0.; const double temp_w = -units.from_si(M::liquid_surface_rate,105.)*0.1; const double temp_g = 0.0*gfactor; auto t0 = temp_o + temp_w + temp_g; double t1 = (std::abs(temp_w) > 0) ? temp_w / t0 : 0.; double t2 = (std::abs(temp_g) > 0) ? temp_g / t0 : 0.; BOOST_CHECK_CLOSE(rseg[i0 + 8], t0, 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 9], t1, 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 10], t2, 1.0e-10); BOOST_CHECK_CLOSE(rseg[i0 + 11], 234., 1.0e-10); } // ILBR { auto start = 0*ih.nilbrz; const auto& iLBr = amswd.getILBr(); //PROD BOOST_CHECK_EQUAL(iLBr[start + 0] , 0); // PROD-branch 1, outlet segment BOOST_CHECK_EQUAL(iLBr[start + 1] , 12); // PROD-branch 1, No of segments in branch BOOST_CHECK_EQUAL(iLBr[start + 2] , 1); // PROD-branch 1, first segment BOOST_CHECK_EQUAL(iLBr[start + 3] , 12); // PROD-branch 1, last segment BOOST_CHECK_EQUAL(iLBr[start + 4] , 0); // PROD-branch 1, branch no - 1 //PROD start = 1*ih.nilbrz; BOOST_CHECK_EQUAL(iLBr[start + 0] , 3); // PROD-branch 2, outlet segment BOOST_CHECK_EQUAL(iLBr[start + 1] , 5); // PROD-branch 2, No of segments in branch BOOST_CHECK_EQUAL(iLBr[start + 2] , 13); // PROD-branch 2, first segment BOOST_CHECK_EQUAL(iLBr[start + 3] , 17); // PROD-branch 2, last segment BOOST_CHECK_EQUAL(iLBr[start + 4] , 1); // PROD-branch 2, branch no - 1 start = ih.nilbrz*ih.nlbrmx + 0*ih.nilbrz; //WINJ BOOST_CHECK_EQUAL(iLBr[start + 0] , 0); // WINJ-branch 1, outlet segment BOOST_CHECK_EQUAL(iLBr[start + 1] , 14); // WINJ-branch 1, No of segments in branch BOOST_CHECK_EQUAL(iLBr[start + 2] , 1); // WINJ-branch 1, first segment BOOST_CHECK_EQUAL(iLBr[start + 3] , 14); // WINJ-branch 1, last segment BOOST_CHECK_EQUAL(iLBr[start + 4] , 0); // WINJ-branch 1, branch no - 1 start = ih.nilbrz*ih.nlbrmx + 1*ih.nilbrz; //WINJ BOOST_CHECK_EQUAL(iLBr[start + 0] , 14); // WINJ-branch 2, outlet segment BOOST_CHECK_EQUAL(iLBr[start + 1] , 5); // WINJ-branch 2, No of segments in branch BOOST_CHECK_EQUAL(iLBr[start + 2] , 15); // WINJ-branch 2, first segment BOOST_CHECK_EQUAL(iLBr[start + 3] , 19); // WINJ-branch 2, last segment BOOST_CHECK_EQUAL(iLBr[start + 4] , 1); // WINJ-branch 2, branch no - 1 } // ILBS { auto start = 0*ih.nlbrmx; const auto& iLBs = amswd.getILBs(); //PROD BOOST_CHECK_EQUAL(iLBs[start + 0] , 13); // PROD-branch 2, first segment in branch start = ih.nlbrmx + 0*ih.nlbrmx; //WINJ BOOST_CHECK_EQUAL(iLBs[start + 0] , 15); // WINJ-branch 2, first segment in branch } } BOOST_AUTO_TEST_SUITE_END()