// -*- mode: C++; c-file-style: "cc-mode" -*- //************************************************************************* // // Copyright 2010-2011 by Wilson Snyder. This program is free software; you can // redistribute it and/or modify it under the terms of either the GNU // Lesser General Public License Version 3 or the Perl Artistic License // Version 2.0. // SPDX-License-Identifier: LGPL-3.0-only OR Artistic-2.0 // //************************************************************************* #ifdef IS_VPI #include "vpi_user.h" #include #else #include "verilated.h" #include "verilated_vcd_c.h" #include "verilated_vpi.h" #include "Vt_vpi_memory.h" #include "Vt_vpi_memory__Dpi.h" #include "svdpi.h" #endif #include #include #include // These require the above. Comment prevents clang-format moving them #include "TestCheck.h" #include "TestSimulator.h" #include "TestVpi.h" // __FILE__ is too long #define FILENM "t_vpi_memory.cpp" #define DEBUG \ if (0) printf int errors = 0; //====================================================================== void _mon_check_range(const TestVpiHandle& handle, int size, int left, int right) { s_vpi_value value; value.format = vpiIntVal; value.value.integer = 0; // check size of object { int vpisize = vpi_get(vpiSize, handle); TEST_CHECK_EQ(vpisize, size); } int coherency; { // check left hand side of range TestVpiHandle left_h = vpi_handle(vpiLeftRange, handle); TEST_CHECK_NZ(left_h); vpi_get_value(left_h, &value); TEST_CHECK_EQ(value.value.integer, left); coherency = value.value.integer; } { // check right hand side of range TestVpiHandle right_h = vpi_handle(vpiRightRange, handle); TEST_CHECK_NZ(right_h); vpi_get_value(right_h, &value); TEST_CHECK_EQ(value.value.integer, right); coherency -= value.value.integer; } // calculate size & check coherency = abs(coherency) + 1; TEST_CHECK_EQ(coherency, size); } void _mem_check(const char* name, int size, int left, int right, int words) { s_vpi_value value; s_vpi_error_info e; vpi_printf((PLI_BYTE8*)"Check memory vpi (%s) ...\n", name); TestVpiHandle mem_h = vpi_handle_by_name((PLI_BYTE8*)TestSimulator::rooted(name), NULL); TEST_CHECK_NZ(mem_h); // check type int vpitype = vpi_get(vpiType, mem_h); if (vpitype != vpiMemory && vpitype != vpiReg) { printf("%%Error: %s:%d vpiType neither vpiMemory or vpiReg: %d\n", FILENM, __LINE__, vpitype); errors++; } std::string binStr; for (int i = words; i >= 1; i--) { for (int pos = size - 1; pos >= 0; pos--) { int posValue = (i >> pos) & 0x1; binStr += posValue ? "1" : "0"; } } // iterate and store if (vpitype == vpiMemory) { _mon_check_range(mem_h, words, words, 1); TestVpiHandle iter_h = vpi_iterate(vpiMemoryWord, mem_h); int cnt = 0; while (TestVpiHandle lcl_h = vpi_scan(iter_h)) { value.format = vpiIntVal; value.value.integer = ++cnt; vpi_put_value(lcl_h, &value, NULL, vpiNoDelay); TEST_CHECK_Z(vpi_chk_error(&e)); // check size and range _mon_check_range(lcl_h, size, left, right); } iter_h.freed(); // IEEE 37.2.2 vpi_scan at end does a vpi_release_handle TEST_CHECK_EQ(cnt, words); // should be words addresses } else { int expSize = size * words; _mon_check_range(mem_h, expSize, expSize - 1, 0); value.format = vpiBinStrVal; value.value.str = const_cast(binStr.c_str()); vpi_put_value(mem_h, &value, NULL, vpiNoDelay); TEST_CHECK_Z(vpi_chk_error(&e)); } if (vpitype == vpiMemory) { // iterate and accumulate TestVpiHandle iter_h = vpi_iterate(vpiMemoryWord, mem_h); int cnt = 0; while (TestVpiHandle lcl_h = vpi_scan(iter_h)) { ++cnt; value.format = vpiIntVal; vpi_get_value(lcl_h, &value); TEST_CHECK_Z(vpi_chk_error(&e)); TEST_CHECK_EQ(value.value.integer, cnt); } iter_h.freed(); // IEEE 37.2.2 vpi_scan at end does a vpi_release_handle TEST_CHECK_EQ(cnt, words); // should be words addresses } else { value.format = vpiBinStrVal; vpi_get_value(mem_h, &value); TEST_CHECK_Z(vpi_chk_error(&e)); TEST_CHECK_EQ(std::string{value.value.str}, binStr); } // don't care for non verilator // (crashes on Icarus) if (TestSimulator::is_icarus()) { vpi_printf((PLI_BYTE8*)"Skipping property checks for simulator %s\n", TestSimulator::get_info().product); return; // Ok } { // make sure trying to get properties that don't exist // doesn't crash TestVpiHandle iter_h = vpi_iterate(vpiMemoryWord, mem_h); int should_be_0 = vpi_get(vpiSize, iter_h); TEST_CHECK_EQ(should_be_0, 0); should_be_0 = vpi_get(vpiIndex, iter_h); TEST_CHECK_EQ(should_be_0, 0); vpiHandle should_be_NULL = vpi_handle(vpiLeftRange, iter_h); TEST_CHECK_EQ(should_be_NULL, 0); should_be_NULL = vpi_handle(vpiRightRange, iter_h); TEST_CHECK_EQ(should_be_NULL, 0); should_be_NULL = vpi_handle(vpiScope, iter_h); TEST_CHECK_EQ(should_be_NULL, 0); } if (vpitype == vpiMemory) { // check vpiRange TestVpiHandle iter_h = vpi_iterate(vpiRange, mem_h); TEST_CHECK_NZ(iter_h); TestVpiHandle lcl_h = vpi_scan(iter_h); TEST_CHECK_NZ(lcl_h); { TestVpiHandle side_h = vpi_handle(vpiLeftRange, lcl_h); TEST_CHECK_NZ(side_h); vpi_get_value(side_h, &value); TEST_CHECK_EQ(value.value.integer, 16); } { TestVpiHandle side_h = vpi_handle(vpiRightRange, lcl_h); TEST_CHECK_NZ(side_h); vpi_get_value(side_h, &value); TEST_CHECK_EQ(value.value.integer, 1); // check writing to vpiConstant vpi_put_value(side_h, &value, NULL, vpiNoDelay); TEST_CHECK_NZ(vpi_chk_error(&e)); } { // iterator should exhaust after 1 dimension TestVpiHandle zero_h = vpi_scan(iter_h); iter_h.freed(); // IEEE 37.2.2 vpi_scan at end does a vpi_release_handle TEST_CHECK_EQ(zero_h, 0); } } } struct params { const char* name; int size; int left; int right; int words; }; void _mon_check_memory() { // See note in t_vpi_get.cpp about static static struct params values[] = {{"mem0", 32, 31, 0, 16}, {"memp32", 32, 31, 0, 16}, {"memp31", 31, 30, 0, 16}, {"memp33", 33, 32, 0, 15}, {"memw", 32, 31, 0, 16}, {NULL, 0, 0, 0, 0}}; struct params* value = values; while (value->name) { _mem_check(value->name, value->size, value->left, value->right, value->words); value++; } } extern "C" int mon_check() { // Callback from initial block in monitor _mon_check_memory(); return errors; } //====================================================================== #ifdef IS_VPI static int mon_check_vpi() { TestVpiHandle href = vpi_handle(vpiSysTfCall, 0); s_vpi_value vpi_value; vpi_value.format = vpiIntVal; vpi_value.value.integer = mon_check(); vpi_put_value(href, &vpi_value, NULL, vpiNoDelay); return 0; } static s_vpi_systf_data vpi_systf_data[] = {{vpiSysFunc, vpiIntFunc, (PLI_BYTE8*)"$mon_check", (PLI_INT32(*)(PLI_BYTE8*))mon_check_vpi, 0, 0, 0}, 0}; // cver entry void vpi_compat_bootstrap(void) { p_vpi_systf_data systf_data_p; systf_data_p = &(vpi_systf_data[0]); while (systf_data_p->type != 0) vpi_register_systf(systf_data_p++); } // icarus entry void (*vlog_startup_routines[])() = {vpi_compat_bootstrap, 0}; #else int main(int argc, char** argv) { const std::unique_ptr contextp{new VerilatedContext}; uint64_t sim_time = 1100; contextp->debug(0); contextp->commandArgs(argc, argv); // We're going to be checking for these errors so don't crash out contextp->fatalOnVpiError(0); const std::unique_ptr topp{new VM_PREFIX{contextp.get(), // Note null name - we're flattening it out ""}}; #ifdef VERILATOR #ifdef TEST_VERBOSE contextp->scopesDump(); #endif #endif #if VM_TRACE contextp->traceEverOn(true); VL_PRINTF("Enabling waves...\n"); VerilatedVcdC* tfp = new VerilatedVcdC; topp->trace(tfp, 99); tfp->open(VL_STRINGIFY(TEST_OBJ_DIR) "/simx.vcd"); #endif topp->eval(); topp->clk = 0; contextp->timeInc(10); while (contextp->time() < sim_time && !contextp->gotFinish()) { contextp->timeInc(1); topp->eval(); VerilatedVpi::callValueCbs(); topp->clk = !topp->clk; // mon_do(); #if VM_TRACE if (tfp) tfp->dump(contextp->time()); #endif } if (!contextp->gotFinish()) { vl_fatal(FILENM, __LINE__, "main", "%Error: Timeout; never got a $finish"); } topp->final(); #if VM_TRACE if (tfp) tfp->close(); #endif return 0; } #endif