// -*- mode: C++; c-file-style: "cc-mode" -*- //============================================================================= // // THIS MODULE IS PUBLICLY LICENSED // // Copyright 2001-2019 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. // // This 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. // //============================================================================= /// /// \file /// \brief C++ Tracing in FST Format /// //============================================================================= // SPDIFF_OFF #ifndef _VERILATED_FST_C_H_ #define _VERILATED_FST_C_H_ 1 #include "verilatedos.h" #include "verilated.h" #include "gtkwave/fstapi.h" #include #include #include #include class VerilatedFst; class VerilatedFstCallInfo; typedef void (*VerilatedFstCallback_t)(VerilatedFst* vcdp, void* userthis, vluint32_t code); //============================================================================= // VerilatedFst /// Base class to create a Verilator FST dump /// This is an internally used class - see VerilatedFstC for what to call from applications class VerilatedFst { typedef std::map Code2SymbolType; typedef std::map Local2FstDtype; typedef std::vector CallbackVec; private: void* m_fst; VerilatedAssertOneThread m_assertOne; ///< Assert only called from single thread bool m_fullDump; char m_scopeEscape; std::string m_module; CallbackVec m_callbacks; ///< Routines to perform dumping Code2SymbolType m_code2symbol; Local2FstDtype m_local2fstdtype; std::list m_curScope; // CONSTRUCTORS VL_UNCOPYABLE(VerilatedFst); void declSymbol(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum, vluint32_t len); // helpers std::vector m_valueStrBuffer; char* word2Str(vluint32_t newval, int bits); char* quad2Str(vluint64_t newval, int bits); char* array2Str(const vluint32_t *newval, int bits); public: explicit VerilatedFst(void* fst=NULL); ~VerilatedFst() { if (m_fst == NULL) { fstWriterClose(m_fst); } } bool isOpen() const { return m_fst != NULL; } void open(const char* filename) VL_MT_UNSAFE; void flush() VL_MT_UNSAFE { fstWriterFlushContext(m_fst); } void close() VL_MT_UNSAFE { m_assertOne.check(); fstWriterClose(m_fst); m_fst = NULL; } void set_time_unit(const char* unitp) { fstWriterSetTimescaleFromString(m_fst, unitp); } void set_time_unit(const std::string& unit) { set_time_unit(unit.c_str()); } void set_time_resolution(const char* unitp) { if (unitp) {} } void set_time_resolution(const std::string& unit) { set_time_resolution(unit.c_str()); } // double timescaleToDouble(const char* unitp); // std::string doubleToTimescale(double value); /// Change character that splits scopes. Note whitespace are ALWAYS escapes. void scopeEscape(char flag) { m_scopeEscape = flag; } /// Is this an escape? bool isScopeEscape(char c) { return isspace(c) || c==m_scopeEscape; } /// Inside dumping routines, called each cycle to make the dump void dump(vluint64_t timeui); /// Inside dumping routines, declare callbacks for tracings void addCallback(VerilatedFstCallback_t initcb, VerilatedFstCallback_t fullcb, VerilatedFstCallback_t changecb, void* userthis) VL_MT_UNSAFE_ONE; /// Inside dumping routines, declare a module void module(const std::string& name); /// Inside dumping routines, declare a data type void declDTypeEnum(int dtypenum, const char* name, vluint32_t elements, unsigned int minValbits, const char** itemNamesp, const char** itemValuesp); /// Inside dumping routines, declare a signal void declBit(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum) { declSymbol(code, name, dtypenum, vardir, vartype, arraynum, 1); } void declBus(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum, int msb, int lsb) { declSymbol(code, name, dtypenum, vardir, vartype, arraynum, msb - lsb + 1); } void declDouble(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum) { declSymbol(code, name, dtypenum, vardir, vartype, arraynum, 2); } void declFloat(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum) { declSymbol(code, name, dtypenum, vardir, vartype, arraynum, 1); } void declQuad(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum, int msb, int lsb) { declSymbol(code, name, dtypenum, vardir, vartype, arraynum, msb - lsb + 1); } void declArray(vluint32_t code, const char* name, int dtypenum, fstVarDir vardir, fstVarType vartype, int arraynum, int msb, int lsb) { declSymbol(code, name, dtypenum, vardir, vartype, arraynum, msb - lsb + 1); } /// Inside dumping routines, dump one signal if it has changed void chgBit(vluint32_t code, const vluint32_t newval) { fstWriterEmitValueChange(m_fst, m_code2symbol[code], newval ? "1" : "0"); } void chgBus(vluint32_t code, const vluint32_t newval, int bits) { fstWriterEmitValueChange(m_fst, m_code2symbol[code], word2Str(newval, bits)); } void chgDouble(vluint32_t code, const double newval) { double val = newval; fstWriterEmitValueChange(m_fst, m_code2symbol[code], &val); } void chgFloat(vluint32_t code, const float newval) { double val = (double)newval; fstWriterEmitValueChange(m_fst, m_code2symbol[code], &val); } void chgQuad(vluint32_t code, const vluint64_t newval, int bits) { fstWriterEmitValueChange(m_fst, m_code2symbol[code], quad2Str(newval, bits)); } void chgArray(vluint32_t code, const vluint32_t* newval, int bits) { fstWriterEmitValueChange(m_fst, m_code2symbol[code], array2Str(newval, bits)); } void fullBit(vluint32_t code, const vluint32_t newval) { chgBit(code, newval); } void fullBus(vluint32_t code, const vluint32_t newval, int bits) { chgBus(code, newval, bits); } void fullDouble(vluint32_t code, const double newval) { chgDouble(code, newval); } void fullFloat(vluint32_t code, const float newval) { chgFloat(code, newval); } void fullQuad(vluint32_t code, const vluint64_t newval, int bits) { chgQuad(code, newval, bits); } void fullArray(vluint32_t code, const vluint32_t* newval, int bits) { chgArray(code, newval, bits); } void declTriBit (vluint32_t code, const char* name, int arraynum); void declTriBus (vluint32_t code, const char* name, int arraynum, int msb, int lsb); void declTriQuad (vluint32_t code, const char* name, int arraynum, int msb, int lsb); void declTriArray (vluint32_t code, const char* name, int arraynum, int msb, int lsb); void fullTriBit(vluint32_t code, const vluint32_t newval, const vluint32_t newtri); void fullTriBus(vluint32_t code, const vluint32_t newval, const vluint32_t newtri, int bits); void fullTriQuad(vluint32_t code, const vluint64_t newval, const vluint32_t newtri, int bits); void fullTriArray(vluint32_t code, const vluint32_t* newvalp, const vluint32_t* newtrip, int bits); void fullBitX(vluint32_t code); void fullBusX(vluint32_t code, int bits); void fullQuadX(vluint32_t code, int bits); void fullArrayX(vluint32_t code, int bits); void chgTriBit(vluint32_t code, const vluint32_t newval, const vluint32_t newtri); void chgTriBus(vluint32_t code, const vluint32_t newval, const vluint32_t newtri, int bits); void chgTriQuad(vluint32_t code, const vluint64_t newval, const vluint32_t newtri, int bits); void chgTriArray(vluint32_t code, const vluint32_t* newvalp, const vluint32_t* newtrip, int bits); }; //============================================================================= // VerilatedFstC /// Create a FST dump file in C standalone (no SystemC) simulations. /// Also derived for use in SystemC simulations. /// Thread safety: Unless otherwise indicated, every function is VL_MT_UNSAFE_ONE class VerilatedFstC { VerilatedFst m_sptrace; ///< Trace file being created // CONSTRUCTORS VL_UNCOPYABLE(VerilatedFstC); public: explicit VerilatedFstC(void* filep=NULL) : m_sptrace(filep) {} ~VerilatedFstC() {} public: // ACCESSORS /// Is file open? bool isOpen() const { return m_sptrace.isOpen(); } // METHODS /// Open a new FST file void open(const char* filename) VL_MT_UNSAFE_ONE { m_sptrace.open(filename); } /// Close dump void close() VL_MT_UNSAFE_ONE { m_sptrace.close(); } /// Flush dump void flush() VL_MT_UNSAFE_ONE { m_sptrace.flush(); } /// Write one cycle of dump data void dump(vluint64_t timeui) { m_sptrace.dump(timeui); } /// Write one cycle of dump data - backward compatible and to reduce /// conversion warnings. It's better to use a vluint64_t time instead. void dump(double timestamp) { dump(static_cast(timestamp)); } void dump(vluint32_t timestamp) { dump(static_cast(timestamp)); } void dump(int timestamp) { dump(static_cast(timestamp)); } /// Set time units (s/ms, defaults to ns) /// See also VL_TIME_PRECISION, and VL_TIME_MULTIPLIER in verilated.h void set_time_unit(const char* unitp) { m_sptrace.set_time_unit(unitp); } void set_time_unit(const std::string& unit) { set_time_unit(unit.c_str()); } /// Set time resolution (s/ms, defaults to ns) /// See also VL_TIME_PRECISION, and VL_TIME_MULTIPLIER in verilated.h void set_time_resolution(const char* unitp) { m_sptrace.set_time_resolution(unitp); } void set_time_resolution(const std::string& unit) { set_time_resolution(unit.c_str()); } /// Internal class access inline VerilatedFst* spTrace() { return &m_sptrace; }; }; #endif // guard