// -*- mode: C++; c-file-style: "cc-mode" -*- //============================================================================= // // Code available from: https://verilator.org // // Copyright 2001-2022 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 // //============================================================================= /// /// \file /// \brief Verilated tracing in VCD format header /// /// User wrapper code should use this header when creating VCD traces. /// //============================================================================= #ifndef VERILATOR_VERILATED_VCD_C_H_ #define VERILATOR_VERILATED_VCD_C_H_ #include "verilated.h" #include "verilated_trace.h" #include #include #include class VerilatedVcd; //============================================================================= // VerilatedFile /// Class representing a file to write to. These virtual methods can be /// overrode for e.g. socket I/O. class VerilatedVcdFile VL_NOT_FINAL { private: int m_fd = 0; // File descriptor we're writing to public: // METHODS /// Construct a (as yet) closed file VerilatedVcdFile() = default; /// Close and destruct virtual ~VerilatedVcdFile() = default; /// Open a file with given filename virtual bool open(const std::string& name) VL_MT_UNSAFE; /// Close object's file virtual void close() VL_MT_UNSAFE; /// Write data to file (if it is open) virtual ssize_t write(const char* bufp, ssize_t len) VL_MT_UNSAFE; }; //============================================================================= // VerilatedVcd // Base class to create a Verilator VCD dump // This is an internally used class - see VerilatedVcdC for what to call from applications class VerilatedVcd VL_NOT_FINAL : public VerilatedTrace { private: // Give the superclass access to private bits (to avoid virtual functions) friend class VerilatedTrace; //========================================================================= // VCD specific internals VerilatedVcdFile* m_filep; // File we're writing to bool m_fileNewed; // m_filep needs destruction bool m_isOpen = false; // True indicates open file bool m_evcd = false; // True for evcd format std::string m_filename; // Filename we're writing to (if open) vluint64_t m_rolloverMB = 0; // MB of file size to rollover at int m_modDepth = 0; // Depth of module hierarchy char* m_wrBufp; // Output buffer const char* m_wrFlushp; // Output buffer flush trigger location char* m_writep; // Write pointer into output buffer vluint64_t m_wrChunkSize; // Output buffer size vluint64_t m_wroteBytes = 0; // Number of bytes written to this file std::vector m_suffixes; // VCD line end string codes + metadata using NameMap = std::map; NameMap* m_namemapp = nullptr; // List of names for the header void bufferResize(vluint64_t minsize); void bufferFlush() VL_MT_UNSAFE_ONE; inline void bufferCheck() { // Flush the write buffer if there's not enough space left for new information // We only call this once per vector, so we need enough slop for a very wide "b###" line if (VL_UNLIKELY(m_writep > m_wrFlushp)) bufferFlush(); } void openNextImp(bool incFilename); void closePrev(); void closeErr(); void makeNameMap(); void deleteNameMap(); void printIndent(int level_change); void printStr(const char* str); void printQuad(vluint64_t n); void printTime(vluint64_t timeui); void declare(vluint32_t code, const char* name, const char* wirep, bool array, int arraynum, bool tri, bool bussed, int msb, int lsb); void dumpHeader(); static char* writeCode(char* writep, vluint32_t code); void finishLine(vluint32_t code, char* writep); // CONSTRUCTORS VL_UNCOPYABLE(VerilatedVcd); protected: //========================================================================= // Implementation of VerilatedTrace interface // Implementations of protected virtual methods for VerilatedTrace virtual void emitTimeChange(vluint64_t timeui) override; // Hooks called from VerilatedTrace virtual bool preFullDump() override { return isOpen(); } virtual bool preChangeDump() override; // Implementations of duck-typed methods for VerilatedTrace. These are // called from only one place (namely full*) so always inline them. inline void emitBit(vluint32_t code, CData newval); inline void emitCData(vluint32_t code, CData newval, int bits); inline void emitSData(vluint32_t code, SData newval, int bits); inline void emitIData(vluint32_t code, IData newval, int bits); inline void emitQData(vluint32_t code, QData newval, int bits); inline void emitWData(vluint32_t code, const WData* newvalp, int bits); inline void emitDouble(vluint32_t code, double newval); public: //========================================================================= // External interface to client code explicit VerilatedVcd(VerilatedVcdFile* filep = nullptr); ~VerilatedVcd(); // ACCESSORS // Set size in megabytes after which new file should be created void rolloverMB(vluint64_t rolloverMB) { m_rolloverMB = rolloverMB; } // METHODS // Open the file; call isOpen() to see if errors void open(const char* filename) VL_MT_SAFE_EXCLUDES(m_mutex); // Open next data-only file void openNext(bool incFilename) VL_MT_SAFE_EXCLUDES(m_mutex); // Close the file void close() VL_MT_SAFE_EXCLUDES(m_mutex); // Flush any remaining data to this file void flush() VL_MT_SAFE_EXCLUDES(m_mutex); // Return if file is open bool isOpen() const VL_MT_SAFE { return m_isOpen; } //========================================================================= // Internal interface to Verilator generated code void declBit(vluint32_t code, const char* name, bool array, int arraynum); void declBus(vluint32_t code, const char* name, bool array, int arraynum, int msb, int lsb); void declQuad(vluint32_t code, const char* name, bool array, int arraynum, int msb, int lsb); void declArray(vluint32_t code, const char* name, bool array, int arraynum, int msb, int lsb); void declDouble(vluint32_t code, const char* name, bool array, int arraynum); #ifdef VL_TRACE_VCD_OLD_API //========================================================================= // Note: These are only for testing for backward compatibility with foreign // code and is not used by Verilator. Do not use these as there is no // guarantee of functionality. void declTriBit(vluint32_t code, const char* name, bool array, int arraynum); void declTriBus(vluint32_t code, const char* name, bool array, int arraynum, int msb, int lsb); void declTriQuad(vluint32_t code, const char* name, bool array, int arraynum, int msb, int lsb); void declTriArray(vluint32_t code, const char* name, bool array, int arraynum, int msb, int lsb); void fullBit(vluint32_t* oldp, CData newval) { fullBit(oldp - this->oldp(0), newval); } void fullCData(vluint32_t* oldp, CData newval, int bits) { fullBus(oldp - this->oldp(0), newval, bits); } void fullSData(vluint32_t* oldp, SData newval, int bits) { fullBus(oldp - this->oldp(0), newval, bits); } void fullIData(vluint32_t* oldp, IData newval, int bits) { fullBus(oldp - this->oldp(0), newval, bits); } void fullQData(vluint32_t* oldp, QData newval, int bits) { fullQuad(oldp - this->oldp(0), newval, bits); } void fullWData(vluint32_t* oldp, const WData* newvalp, int bits) { fullArray(oldp - this->oldp(0), newvalp, bits); } void fullDouble(vluint32_t* oldp, double newval) { fullDouble(oldp - this->oldp(0), newval); } inline void chgBit(vluint32_t* oldp, CData newval) { chgBit(oldp - this->oldp(0), newval); } inline void chgCData(vluint32_t* oldp, CData newval, int bits) { chgBus(oldp - this->oldp(0), newval, bits); } inline void chgSData(vluint32_t* oldp, SData newval, int bits) { chgBus(oldp - this->oldp(0), newval, bits); } inline void chgIData(vluint32_t* oldp, IData newval, int bits) { chgBus(oldp - this->oldp(0), newval, bits); } inline void chgQData(vluint32_t* oldp, QData newval, int bits) { chgQuad(oldp - this->oldp(0), newval, bits); } inline void chgWData(vluint32_t* oldp, const WData* newvalp, int bits) { chgArray(oldp - this->oldp(0), newvalp, bits); } inline void chgDouble(vluint32_t* oldp, double newval) { chgDouble(oldp - this->oldp(0), newval); } // Inside dumping routines, dump one signal, faster when not inlined // due to code size reduction. void fullBit(vluint32_t code, const vluint32_t newval); void fullBus(vluint32_t code, const vluint32_t newval, int bits); void fullQuad(vluint32_t code, const vluint64_t newval, int bits); void fullArray(vluint32_t code, const vluint32_t* newvalp, int bits); void fullArray(vluint32_t code, const vluint64_t* newvalp, int bits); 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 vluint64_t newtri, int bits); void fullTriArray(vluint32_t code, const vluint32_t* newvalp, const vluint32_t* newtrip, int bits); void fullDouble(vluint32_t code, const double newval); // Inside dumping routines, dump one signal if it has changed. // We do want to inline these to avoid calls when the value did not change. inline void chgBit(vluint32_t code, const vluint32_t newval) { const vluint32_t diff = oldp(code)[0] ^ newval; if (VL_UNLIKELY(diff)) fullBit(code, newval); } inline void chgBus(vluint32_t code, const vluint32_t newval, int bits) { const vluint32_t diff = oldp(code)[0] ^ newval; if (VL_UNLIKELY(diff)) { if (VL_UNLIKELY(bits == 32 || (diff & ((1U << bits) - 1)))) { fullBus(code, newval, bits); } } } inline void chgQuad(vluint32_t code, const vluint64_t newval, int bits) { const vluint64_t diff = (*(reinterpret_cast(oldp(code)))) ^ newval; if (VL_UNLIKELY(diff)) { if (VL_UNLIKELY(bits == 64 || (diff & ((1ULL << bits) - 1)))) { fullQuad(code, newval, bits); } } } inline void chgArray(vluint32_t code, const vluint32_t* newvalp, int bits) { for (int word = 0; word < (((bits - 1) / 32) + 1); ++word) { if (VL_UNLIKELY(oldp(code)[word] ^ newvalp[word])) { fullArray(code, newvalp, bits); return; } } } inline void chgArray(vluint32_t code, const vluint64_t* newvalp, int bits) { for (int word = 0; word < (((bits - 1) / 64) + 1); ++word) { if (VL_UNLIKELY(*(reinterpret_cast(oldp(code + 2 * word))) ^ newvalp[word])) { fullArray(code, newvalp, bits); return; } } } inline void chgTriBit(vluint32_t code, const vluint32_t newval, const vluint32_t newtri) { const vluint32_t diff = ((oldp(code)[0] ^ newval) | (oldp(code)[1] ^ newtri)); if (VL_UNLIKELY(diff)) { // Verilator 3.510 and newer provide clean input, so the below // is only for back compatibility if (VL_UNLIKELY(diff & 1)) { // Change after clean? fullTriBit(code, newval, newtri); } } } inline void chgTriBus(vluint32_t code, const vluint32_t newval, const vluint32_t newtri, int bits) { const vluint32_t diff = ((oldp(code)[0] ^ newval) | (oldp(code)[1] ^ newtri)); if (VL_UNLIKELY(diff)) { if (VL_UNLIKELY(bits == 32 || (diff & ((1U << bits) - 1)))) { fullTriBus(code, newval, newtri, bits); } } } inline void chgTriQuad(vluint32_t code, const vluint64_t newval, const vluint64_t newtri, int bits) { const vluint64_t diff = (((*(reinterpret_cast(oldp(code)))) ^ newval) | ((*(reinterpret_cast(oldp(code + 1)))) ^ newtri)); if (VL_UNLIKELY(diff)) { if (VL_UNLIKELY(bits == 64 || (diff & ((1ULL << bits) - 1)))) { fullTriQuad(code, newval, newtri, bits); } } } inline void chgTriArray(vluint32_t code, const vluint32_t* newvalp, const vluint32_t* newtrip, int bits) { for (int word = 0; word < (((bits - 1) / 32) + 1); ++word) { if (VL_UNLIKELY((oldp(code)[word * 2] ^ newvalp[word]) | (oldp(code)[word * 2 + 1] ^ newtrip[word]))) { fullTriArray(code, newvalp, newtrip, bits); return; } } } inline void chgDouble(vluint32_t code, const double newval) { // cppcheck-suppress invalidPointerCast if (VL_UNLIKELY((*(reinterpret_cast(oldp(code)))) != newval)) { fullDouble(code, newval); } } // METHODS // Old/standalone API only void evcd(bool flag) { m_evcd = flag; } #endif // VL_TRACE_VCD_OLD_API }; #ifndef DOXYGEN // Declare specializations here they are used in VerilatedVcdC just below template <> void VerilatedTrace::dump(vluint64_t timeui); template <> void VerilatedTrace::set_time_unit(const char* unitp); template <> void VerilatedTrace::set_time_unit(const std::string& unit); template <> void VerilatedTrace::set_time_resolution(const char* unitp); template <> void VerilatedTrace::set_time_resolution(const std::string& unit); #endif // DOXYGEN //============================================================================= // VerilatedVcdC /// Class representing a VCD dump file in C standalone (no SystemC) /// simulations. Also derived for use in SystemC simulations. class VerilatedVcdC VL_NOT_FINAL { VerilatedVcd m_sptrace; // Trace file being created // CONSTRUCTORS VL_UNCOPYABLE(VerilatedVcdC); public: /// Construct the dump. Optional argument is a preconstructed file. explicit VerilatedVcdC(VerilatedVcdFile* filep = nullptr) : m_sptrace{filep} {} /// Destruct, flush, and close the dump virtual ~VerilatedVcdC() { close(); } public: // METHODS - User called /// Return if file is open bool isOpen() const VL_MT_SAFE { return m_sptrace.isOpen(); } /// Open a new VCD file /// This includes a complete header dump each time it is called, /// just as if this object was deleted and reconstructed. virtual void open(const char* filename) VL_MT_SAFE { m_sptrace.open(filename); } /// Continue a VCD dump by rotating to a new file name /// The header is only in the first file created, this allows /// "cat" to be used to combine the header plus any number of data files. void openNext(bool incFilename = true) VL_MT_SAFE { m_sptrace.openNext(incFilename); } /// Set size in megabytes after which new file should be created void rolloverMB(size_t rolloverMB) VL_MT_SAFE { m_sptrace.rolloverMB(rolloverMB); } /// Close dump void close() VL_MT_SAFE { m_sptrace.close(); } /// Flush dump void flush() VL_MT_SAFE { m_sptrace.flush(); } /// Write one cycle of dump data /// Call with the current context's time just after eval'ed, /// e.g. ->dump(contextp->time()) void dump(vluint64_t timeui) VL_MT_SAFE { 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)); } // METHODS - Internal/backward compatible // \protectedsection // Set time units (s/ms, defaults to ns) // Users should not need to call this, as for Verilated models, these // propage from the Verilated default timeunit void set_time_unit(const char* unit) VL_MT_SAFE { m_sptrace.set_time_unit(unit); } void set_time_unit(const std::string& unit) VL_MT_SAFE { m_sptrace.set_time_unit(unit); } // Set time resolution (s/ms, defaults to ns) // Users should not need to call this, as for Verilated models, these // propage from the Verilated default timeprecision void set_time_resolution(const char* unit) VL_MT_SAFE { m_sptrace.set_time_resolution(unit); } void set_time_resolution(const std::string& unit) VL_MT_SAFE { m_sptrace.set_time_resolution(unit); } // Internal class access inline VerilatedVcd* spTrace() { return &m_sptrace; } #ifdef VL_TRACE_VCD_OLD_API //========================================================================= // Note: These are only for testing for backward compatibility with foreign // code and is not used by Verilator. Do not use these as there is no // guarantee of functionality. // Use evcd format void evcd(bool flag) VL_MT_UNSAFE_ONE { m_sptrace.evcd(flag); } #endif }; #endif // guard