// -*- mode: C++; c-file-style: "cc-mode" -*- //============================================================================= // // Code available from: https://verilator.org // // 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-FileCopyrightText: 2001-2026 Wilson Snyder // SPDX-License-Identifier: LGPL-3.0-only OR Artistic-2.0 // //============================================================================= /// /// \file /// \brief Verilated C++ tracing in SAIF format implementation code /// /// This file must be compiled and linked against all Verilated objects /// that use --trace-saif. /// /// Use "verilator --trace-saif" to add this to the Makefile for the linker. /// //============================================================================= // clang-format off #include "verilatedos.h" #include "verilated.h" #include "verilated_saif_c.h" #include #include #include #include #if defined(_WIN32) && !defined(__MINGW32__) && !defined(__CYGWIN__) # include #else # include #endif #ifndef O_LARGEFILE // WIN32 headers omit this # define O_LARGEFILE 0 #endif #ifndef O_NONBLOCK // WIN32 headers omit this # define O_NONBLOCK 0 #endif #ifndef O_CLOEXEC // WIN32 headers omit this # define O_CLOEXEC 0 #endif // clang-format on //============================================================================= // Specialization of the generics for this trace format #define VL_SUB_T VerilatedSaif #define VL_BUF_T VerilatedSaifBuffer #include "verilated_trace_imp.h" #undef VL_SUB_T #undef VL_BUF_T //============================================================================= // VerilatedSaifActivityBit class VerilatedSaifActivityBit final { // MEMBERS bool m_lastVal = false; // Last emitted activity bit value uint64_t m_highTime = 0; // Total time when bit was high size_t m_transitions = 0; // Total number of bit transitions public: // METHODS VL_ATTR_ALWINLINE void aggregateVal(uint64_t dt, bool newVal) { m_transitions += newVal != m_lastVal ? 1 : 0; m_highTime += m_lastVal ? dt : 0; m_lastVal = newVal; } // ACCESSORS VL_ATTR_ALWINLINE bool bitValue() const { return m_lastVal; } VL_ATTR_ALWINLINE uint64_t highTime() const { return m_highTime; } VL_ATTR_ALWINLINE uint64_t toggleCount() const { return m_transitions; } }; //============================================================================= // VerilatedSaifActivityVar class VerilatedSaifActivityVar final { // MEMBERS uint64_t m_lastTime = 0; // Last time when variable value was updated VerilatedSaifActivityBit* m_bits; // Pointer to variable bits objects uint32_t m_width; // Width of variable (in bits) public: // CONSTRUCTORS VerilatedSaifActivityVar(uint32_t width, VerilatedSaifActivityBit* bits) : m_bits{bits} , m_width{width} {} VerilatedSaifActivityVar(VerilatedSaifActivityVar&&) = default; VerilatedSaifActivityVar& operator=(VerilatedSaifActivityVar&&) = default; // METHODS VL_ATTR_ALWINLINE void emitBit(uint64_t time, CData newval); template VL_ATTR_ALWINLINE void emitData(uint64_t time, DataType newval, uint32_t bits) { static_assert(std::is_integral::value, "The emitted value must be of integral type"); const uint64_t dt = time - m_lastTime; for (size_t i = 0; i < std::min(m_width, bits); ++i) { m_bits[i].aggregateVal(dt, (newval >> i) & 1); } updateLastTime(time); } VL_ATTR_ALWINLINE void emitWData(uint64_t time, const WData* newvalp, uint32_t bits); VL_ATTR_ALWINLINE void updateLastTime(uint64_t val) { m_lastTime = val; } // ACCESSORS VL_ATTR_ALWINLINE uint32_t width() const { return m_width; } VL_ATTR_ALWINLINE VerilatedSaifActivityBit& bit(std::size_t index); VL_ATTR_ALWINLINE uint64_t lastUpdateTime() const { return m_lastTime; } private: // CONSTRUCTORS VL_UNCOPYABLE(VerilatedSaifActivityVar); }; //============================================================================= // VerilatedSaifActivityScope class VerilatedSaifActivityScope final { // MEMBERS // Absolute path to the scope std::string m_scopePath; // Name of the activity scope std::string m_scopeName; // Array indices of child scopes std::vector> m_childScopes{}; // Children signals codes mapped to their names in the current scope std::vector> m_childActivities{}; // Parent scope pointer VerilatedSaifActivityScope* m_parentScope = nullptr; public: // CONSTRUCTORS VerilatedSaifActivityScope(std::string scopePath, std::string name, VerilatedSaifActivityScope* parentScope = nullptr) : m_scopePath{std::move(scopePath)} , m_scopeName{std::move(name)} , m_parentScope{parentScope} {} VerilatedSaifActivityScope(VerilatedSaifActivityScope&&) = default; VerilatedSaifActivityScope& operator=(VerilatedSaifActivityScope&&) = default; // METHODS VL_ATTR_ALWINLINE void addChildScope(std::unique_ptr childScope) { m_childScopes.emplace_back(std::move(childScope)); } VL_ATTR_ALWINLINE void addActivityVar(uint32_t code, std::string name) { m_childActivities.emplace_back(code, std::move(name)); } VL_ATTR_ALWINLINE bool hasParent() const { return m_parentScope; } // ACCESSORS VL_ATTR_ALWINLINE const std::string& path() const { return m_scopePath; } VL_ATTR_ALWINLINE const std::string& name() const { return m_scopeName; } VL_ATTR_ALWINLINE const std::vector>& childScopes() const { return m_childScopes; } VL_ATTR_ALWINLINE const std::vector>& childActivities() const { return m_childActivities; } VL_ATTR_ALWINLINE VerilatedSaifActivityScope* parentScope() const { return m_parentScope; } private: // CONSTRUCTORS VL_UNCOPYABLE(VerilatedSaifActivityScope); }; //============================================================================= // VerilatedSaifActivityAccumulator class VerilatedSaifActivityAccumulator final { // Give access to the private activities friend class VerilatedSaifBuffer; friend class VerilatedSaif; // MEMBERS // Map of scopes paths to codes of activities inside std::unordered_map>> m_scopeToActivities; // Map of variables codes mapped to their activity objects std::unordered_map m_activity; // Memory pool for signals bits objects std::vector> m_activityArena; public: // METHODS void declare(uint32_t code, const std::string& absoluteScopePath, std::string variableName, int bits, bool array, int arraynum); // CONSTRUCTORS VerilatedSaifActivityAccumulator() = default; VerilatedSaifActivityAccumulator(VerilatedSaifActivityAccumulator&&) = default; VerilatedSaifActivityAccumulator& operator=(VerilatedSaifActivityAccumulator&&) = default; private: VL_UNCOPYABLE(VerilatedSaifActivityAccumulator); }; //============================================================================= //============================================================================= //============================================================================= // VerilatedSaifActivityVar implementation VL_ATTR_ALWINLINE void VerilatedSaifActivityVar::emitBit(const uint64_t time, const CData newval) { assert(m_lastTime <= time); m_bits[0].aggregateVal(time - m_lastTime, newval); updateLastTime(time); } VL_ATTR_ALWINLINE void VerilatedSaifActivityVar::emitWData(const uint64_t time, const WData* newvalp, const uint32_t bits) { assert(m_lastTime <= time); const uint64_t dt = time - m_lastTime; for (std::size_t i = 0; i < std::min(m_width, bits); ++i) { const size_t wordIndex = i / VL_EDATASIZE; m_bits[i].aggregateVal(dt, (newvalp[wordIndex] >> VL_BITBIT_E(i)) & 1); } updateLastTime(time); } VerilatedSaifActivityBit& VerilatedSaifActivityVar::bit(const std::size_t index) { assert(index < m_width); return m_bits[index]; } //============================================================================= //============================================================================= //============================================================================= // VerilatedSaifActivityAccumulator implementation void VerilatedSaifActivityAccumulator::declare(uint32_t code, const std::string& absoluteScopePath, std::string variableName, int bits, bool array, int arraynum) { const size_t block_size = 1024; if (m_activityArena.empty() || m_activityArena.back().size() + bits > m_activityArena.back().capacity()) { m_activityArena.emplace_back(); m_activityArena.back().reserve(block_size); } const size_t bitsIdx = m_activityArena.back().size(); m_activityArena.back().resize(m_activityArena.back().size() + bits); if (array) { variableName += '['; variableName += std::to_string(arraynum); variableName += ']'; } m_scopeToActivities[absoluteScopePath].emplace_back(code, variableName); m_activity.emplace(code, VerilatedSaifActivityVar{static_cast(bits), m_activityArena.back().data() + bitsIdx}); } //============================================================================= //============================================================================= //============================================================================= // VerilatedSaif implementation VerilatedSaif::VerilatedSaif(void* filep) { m_activityAccumulators.emplace_back(std::make_unique()); } void VerilatedSaif::open(const char* filename) VL_MT_SAFE_EXCLUDES(m_mutex) { const VerilatedLockGuard lock{m_mutex}; if (isOpen()) return; m_filename = filename; // "" is ok, as someone may overload open m_filep = ::open(m_filename.c_str(), O_CREAT | O_WRONLY | O_TRUNC | O_LARGEFILE | O_NONBLOCK | O_CLOEXEC, 0666); m_isOpen = true; initializeSaifFileContents(); Super::traceInit(); } void VerilatedSaif::initializeSaifFileContents() { printStr("// Generated by verilated_saif\n"); printStr("(SAIFILE\n"); printStr("(SAIFVERSION \"2.0\")\n"); printStr("(DIRECTION \"backward\")\n"); printStr("(PROGRAM_NAME \"Verilator\")\n"); printStr("(DIVIDER / )\n"); printStr("(TIMESCALE "); printStr(timeResStr()); printStr(")\n"); } void VerilatedSaif::emitTimeChange(uint64_t timeui) { m_time = timeui; } VerilatedSaif::~VerilatedSaif() { close(); } void VerilatedSaif::close() VL_MT_SAFE_EXCLUDES(m_mutex) { // This function is on the flush() call path const VerilatedLockGuard lock{m_mutex}; if (!isOpen()) return; finalizeSaifFileContents(); clearCurrentlyCollectedData(); writeBuffered(true); ::close(m_filep); m_isOpen = false; Super::closeBase(); } void VerilatedSaif::finalizeSaifFileContents() { printStr("(DURATION "); printStr(std::to_string(currentTime())); printStr(")\n"); incrementIndent(); for (const auto& topScope : m_scopes) recursivelyPrintScopes(*topScope); decrementIndent(); printStr(")\n"); // SAIFILE } void VerilatedSaif::recursivelyPrintScopes(const VerilatedSaifActivityScope& scope) { openInstanceScope(scope.name()); printScopeActivities(scope); for (const auto& childScope : scope.childScopes()) recursivelyPrintScopes(*childScope); closeInstanceScope(); } void VerilatedSaif::openInstanceScope(const std::string& instanceName) { printIndent(); printStr("(INSTANCE "); printStr(instanceName); printStr("\n"); incrementIndent(); } void VerilatedSaif::closeInstanceScope() { decrementIndent(); printIndent(); printStr(")\n"); // INSTANCE } void VerilatedSaif::printScopeActivities(const VerilatedSaifActivityScope& scope) { bool anyNetWritten = false; for (auto& accumulator : m_activityAccumulators) { anyNetWritten |= printScopeActivitiesFromAccumulatorIfPresent(scope.path(), *accumulator, anyNetWritten); } if (anyNetWritten) closeNetScope(); } bool VerilatedSaif::printScopeActivitiesFromAccumulatorIfPresent( const std::string& absoluteScopePath, VerilatedSaifActivityAccumulator& accumulator, bool anyNetWritten) { if (accumulator.m_scopeToActivities.count(absoluteScopePath) == 0) return false; for (const auto& childSignal : accumulator.m_scopeToActivities.at(absoluteScopePath)) { VerilatedSaifActivityVar& activityVariable = accumulator.m_activity.at(childSignal.first); anyNetWritten = printActivityStats(activityVariable, childSignal.second.c_str(), anyNetWritten); } return anyNetWritten; } void VerilatedSaif::openNetScope() { printIndent(); printStr("(NET\n"); incrementIndent(); } void VerilatedSaif::closeNetScope() { decrementIndent(); printIndent(); printStr(")\n"); // NET } bool VerilatedSaif::printActivityStats(VerilatedSaifActivityVar& activity, const std::string& activityName, bool anyNetWritten) { for (size_t i = 0; i < activity.width(); ++i) { VerilatedSaifActivityBit& bit = activity.bit(i); bit.aggregateVal(currentTime() - activity.lastUpdateTime(), bit.bitValue()); if (!anyNetWritten) { openNetScope(); anyNetWritten = true; } printIndent(); printStr("("); printStr(activityName); if (activity.width() > 1) { printStr("\\["); printStr(std::to_string(i)); printStr("\\]"); } // We only have two-value logic so TZ, TX and TB will always be 0 printStr(" (T0 "); printStr(std::to_string(currentTime() - bit.highTime())); printStr(") (T1 "); printStr(std::to_string(bit.highTime())); printStr(") (TZ 0) (TX 0) (TB 0) (TC "); printStr(std::to_string(bit.toggleCount())); printStr("))\n"); } activity.updateLastTime(currentTime()); return anyNetWritten; } void VerilatedSaif::clearCurrentlyCollectedData() { m_currentScope = nullptr; m_scopes.clear(); m_activityAccumulators.clear(); } void VerilatedSaif::printStr(const char* str) { m_buffer.append(str); writeBuffered(false); } void VerilatedSaif::printStr(const std::string& str) { m_buffer.append(str); writeBuffered(false); } void VerilatedSaif::writeBuffered(bool force) { if (VL_UNLIKELY(m_buffer.size() >= WRITE_BUFFER_SIZE || force)) { if (VL_UNLIKELY(!m_buffer.empty())) { ::write(m_filep, m_buffer.data(), m_buffer.size()); m_buffer = ""; m_buffer.reserve(WRITE_BUFFER_SIZE * 2); } } } //============================================================================= // Definitions void VerilatedSaif::flush() VL_MT_SAFE_EXCLUDES(m_mutex) { const VerilatedLockGuard lock{m_mutex}; Super::flushBase(); } void VerilatedSaif::incrementIndent() { m_indent += 1; } void VerilatedSaif::decrementIndent() { m_indent -= 1; } void VerilatedSaif::printIndent() { printStr(std::string(m_indent, ' ')); // Must use () constructor } void VerilatedSaif::pushPrefix(const char* namep, VerilatedTracePrefixType type) { assert(!m_prefixStack.empty()); // Constructor makes an empty entry const std::string name{namep}; // An empty name means this is the root of a model created with // name()=="". The tools get upset if we try to pass this as empty, so // we put the signals under a new $rootio scope, but the signals // further down will be peers, not children (as usual for name()!=""). const std::string prevPrefix = m_prefixStack.back().first; if (name == "$rootio" && !prevPrefix.empty()) { // Upper has name, we can suppress inserting $rootio, but still push so popPrefix works m_prefixStack.emplace_back(prevPrefix, VerilatedTracePrefixType::ROOTIO_WRAPPER); return; } else if (name.empty()) { m_prefixStack.emplace_back(prevPrefix, VerilatedTracePrefixType::ROOTIO_WRAPPER); return; } if (type != VerilatedTracePrefixType::ARRAY_UNPACKED && type != VerilatedTracePrefixType::ARRAY_PACKED) { std::string scopePath = prevPrefix + name; std::string scopeName = lastWord(scopePath); auto newScope = std::make_unique( std::move(scopePath), std::move(scopeName), m_currentScope); VerilatedSaifActivityScope* newScopePtr = newScope.get(); if (m_currentScope) { m_currentScope->addChildScope(std::move(newScope)); } else { m_scopes.emplace_back(std::move(newScope)); } m_currentScope = newScopePtr; } const std::string newPrefix = prevPrefix + name; bool properScope = (type != VerilatedTracePrefixType::ARRAY_UNPACKED && type != VerilatedTracePrefixType::ARRAY_PACKED && type != VerilatedTracePrefixType::ROOTIO_WRAPPER); m_prefixStack.emplace_back(newPrefix + (properScope ? " " : ""), type); } void VerilatedSaif::popPrefix() { if (m_prefixStack.back().second != VerilatedTracePrefixType::ARRAY_UNPACKED && m_prefixStack.back().second != VerilatedTracePrefixType::ARRAY_PACKED && m_prefixStack.back().second != VerilatedTracePrefixType::ROOTIO_WRAPPER && m_currentScope) { m_currentScope = m_currentScope->parentScope(); } m_prefixStack.pop_back(); assert(!m_prefixStack.empty()); // Always one left, the constructor's initial one } void VerilatedSaif::declare(const uint32_t code, uint32_t fidx, const char* name, const char* wirep, const bool array, const int arraynum, const bool bussed, const int msb, const int lsb) { assert(m_activityAccumulators.size() > fidx); VerilatedSaifActivityAccumulator& accumulator = *m_activityAccumulators.at(fidx); const int bits = ((msb > lsb) ? (msb - lsb) : (lsb - msb)) + 1; const std::string hierarchicalName = m_prefixStack.back().first + name; if (!Super::declCode(code, hierarchicalName, bits)) return; std::string variableName = lastWord(hierarchicalName); m_currentScope->addActivityVar(code, variableName); accumulator.declare(code, m_currentScope->path(), std::move(variableName), bits, array, arraynum); } void VerilatedSaif::declEvent(const uint32_t code, const uint32_t fidx, const char* name, const int dtypenum, const VerilatedTraceSigDirection, const VerilatedTraceSigKind, const VerilatedTraceSigType, const bool array, const int arraynum) { declare(code, fidx, name, "event", array, arraynum, false, 0, 0); } void VerilatedSaif::declBit(const uint32_t code, const uint32_t fidx, const char* name, const int dtypenum, const VerilatedTraceSigDirection, const VerilatedTraceSigKind, const VerilatedTraceSigType, const bool array, const int arraynum) { declare(code, fidx, name, "wire", array, arraynum, false, 0, 0); } void VerilatedSaif::declBus(const uint32_t code, const uint32_t fidx, const char* name, const int dtypenum, const VerilatedTraceSigDirection, const VerilatedTraceSigKind, const VerilatedTraceSigType, const bool array, const int arraynum, const int msb, const int lsb) { declare(code, fidx, name, "wire", array, arraynum, true, msb, lsb); } void VerilatedSaif::declQuad(const uint32_t code, const uint32_t fidx, const char* name, const int dtypenum, const VerilatedTraceSigDirection, const VerilatedTraceSigKind, const VerilatedTraceSigType, const bool array, const int arraynum, const int msb, const int lsb) { declare(code, fidx, name, "wire", array, arraynum, true, msb, lsb); } void VerilatedSaif::declArray(const uint32_t code, const uint32_t fidx, const char* name, const int dtypenum, const VerilatedTraceSigDirection, const VerilatedTraceSigKind, const VerilatedTraceSigType, const bool array, const int arraynum, const int msb, const int lsb) { declare(code, fidx, name, "wire", array, arraynum, true, msb, lsb); } void VerilatedSaif::declDouble(const uint32_t code, const uint32_t fidx, const char* name, const int dtypenum, const VerilatedTraceSigDirection, const VerilatedTraceSigKind, const VerilatedTraceSigType, const bool array, const int arraynum) { declare(code, fidx, name, "real", array, arraynum, false, 63, 0); } //============================================================================= // Get/commit trace buffer VerilatedSaif::Buffer* VerilatedSaif::getTraceBuffer(uint32_t fidx) { return new Buffer{*this}; } void VerilatedSaif::commitTraceBuffer(VerilatedSaif::Buffer* bufp) { delete bufp; } //============================================================================= //============================================================================= //============================================================================= // VerilatedSaifBuffer implementation //============================================================================= // emit* trace routines // Note: emit* are only ever called from one place (full* in // verilated_trace_imp.h, which is included in this file at the top), // so always inline them. VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitEvent(const uint32_t code) { // NOP } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitBit(const uint32_t code, const CData newval) { assert(m_owner.m_activityAccumulators.at(m_fidx)->m_activity.count(code) && "Activity must be declared earlier"); VerilatedSaifActivityVar& activity = m_owner.m_activityAccumulators.at(m_fidx)->m_activity.at(code); activity.emitBit(m_owner.currentTime(), newval); } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitCData(const uint32_t code, const CData newval, const int bits) { assert(m_owner.m_activityAccumulators.at(m_fidx)->m_activity.count(code) && "Activity must be declared earlier"); VerilatedSaifActivityVar& activity = m_owner.m_activityAccumulators.at(m_fidx)->m_activity.at(code); activity.emitData(m_owner.currentTime(), newval, bits); } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitSData(const uint32_t code, const SData newval, const int bits) { assert(m_owner.m_activityAccumulators.at(m_fidx)->m_activity.count(code) && "Activity must be declared earlier"); VerilatedSaifActivityVar& activity = m_owner.m_activityAccumulators.at(m_fidx)->m_activity.at(code); activity.emitData(m_owner.currentTime(), newval, bits); } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitIData(const uint32_t code, const IData newval, const int bits) { assert(m_owner.m_activityAccumulators.at(m_fidx)->m_activity.count(code) && "Activity must be declared earlier"); VerilatedSaifActivityVar& activity = m_owner.m_activityAccumulators.at(m_fidx)->m_activity.at(code); activity.emitData(m_owner.currentTime(), newval, bits); } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitQData(const uint32_t code, const QData newval, const int bits) { assert(m_owner.m_activityAccumulators.at(m_fidx)->m_activity.count(code) && "Activity must be declared earlier"); VerilatedSaifActivityVar& activity = m_owner.m_activityAccumulators.at(m_fidx)->m_activity.at(code); activity.emitData(m_owner.currentTime(), newval, bits); } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitWData(const uint32_t code, const WData* newvalp, const int bits) { assert(m_owner.m_activityAccumulators.at(m_fidx)->m_activity.count(code) && "Activity must be declared earlier"); VerilatedSaifActivityVar& activity = m_owner.m_activityAccumulators.at(m_fidx)->m_activity.at(code); activity.emitWData(m_owner.currentTime(), newvalp, bits); } VL_ATTR_ALWINLINE void VerilatedSaifBuffer::emitDouble(const uint32_t code, const double newval) { // NOP }