#ifdef _WIN32 # include #endif #ifdef _WIN32 # include #else # include #endif #include #include #include #include #include #if ( defined _MSC_VER && _MSVC_LANG >= 201703L ) || __cplusplus >= 201703L # if __has_include() # include # else # define MY_LIBCPP_SUCKS # endif #else # define MY_LIBCPP_SUCKS #endif #ifdef MY_LIBCPP_SUCKS # include "tracy_pdqsort.h" #endif #include "../common/TracyProtocol.hpp" #include "../common/TracySystem.hpp" #include "TracyFileRead.hpp" #include "TracyFileWrite.hpp" #include "TracyVersion.hpp" #include "TracyWorker.hpp" #include "tracy_flat_hash_map.hpp" namespace tracy { static inline CallstackFrameId PackPointer( uint64_t ptr ) { assert( ( ( ptr & 0x4000000000000000 ) << 1 ) == ( ptr & 0x8000000000000000 ) ); CallstackFrameId id; id.idx = ptr; id.sel = 0; return id; } static constexpr int FileVersion( uint8_t h5, uint8_t h6, uint8_t h7 ) { return ( h5 << 16 ) | ( h6 << 8 ) | h7; } static const uint8_t FileHeader[8] { 't', 'r', 'a', 'c', 'y', Version::Major, Version::Minor, Version::Patch }; enum { FileHeaderMagic = 5 }; static const int CurrentVersion = FileVersion( Version::Major, Version::Minor, Version::Patch ); static void UpdateLockCountLockable( LockMap& lockmap, size_t pos ) { auto& timeline = lockmap.timeline; bool isContended = lockmap.isContended; uint8_t lockingThread; uint8_t lockCount; uint64_t waitList; if( pos == 0 ) { lockingThread = 0; lockCount = 0; waitList = 0; } else { const auto& tl = timeline[pos-1]; lockingThread = tl.lockingThread; lockCount = tl.lockCount; waitList = tl.waitList; } const auto end = timeline.size(); while( pos != end ) { auto& tl = timeline[pos]; const auto tbit = uint64_t( 1 ) << tl.ptr->thread; switch( (LockEvent::Type)tl.ptr->type ) { case LockEvent::Type::Wait: waitList |= tbit; break; case LockEvent::Type::Obtain: assert( lockCount < std::numeric_limits::max() ); assert( ( waitList & tbit ) != 0 ); waitList &= ~tbit; lockingThread = tl.ptr->thread; lockCount++; break; case LockEvent::Type::Release: assert( lockCount > 0 ); lockCount--; break; default: break; } tl.lockingThread = lockingThread; tl.waitList = waitList; tl.lockCount = lockCount; if( !isContended ) isContended = lockCount != 0 && waitList != 0; pos++; } lockmap.isContended = isContended; } static void UpdateLockCountSharedLockable( LockMap& lockmap, size_t pos ) { auto& timeline = lockmap.timeline; bool isContended = lockmap.isContended; uint8_t lockingThread; uint8_t lockCount; uint64_t waitShared; uint64_t waitList; uint64_t sharedList; if( pos == 0 ) { lockingThread = 0; lockCount = 0; waitShared = 0; waitList = 0; sharedList = 0; } else { const auto& tl = timeline[pos-1]; const auto tlp = (LockEventShared*)tl.ptr; lockingThread = tl.lockingThread; lockCount = tl.lockCount; waitShared = tlp->waitShared; waitList = tl.waitList; sharedList = tlp->sharedList; } const auto end = timeline.size(); // ObtainShared and ReleaseShared should assert on lockCount == 0, but // due to the async retrieval of data from threads that's not possible. while( pos != end ) { auto& tl = timeline[pos]; const auto tlp = (LockEventShared*)tl.ptr; const auto tbit = uint64_t( 1 ) << tlp->thread; switch( (LockEvent::Type)tlp->type ) { case LockEvent::Type::Wait: waitList |= tbit; break; case LockEvent::Type::WaitShared: waitShared |= tbit; break; case LockEvent::Type::Obtain: assert( lockCount < std::numeric_limits::max() ); assert( ( waitList & tbit ) != 0 ); waitList &= ~tbit; lockingThread = tlp->thread; lockCount++; break; case LockEvent::Type::Release: assert( lockCount > 0 ); lockCount--; break; case LockEvent::Type::ObtainShared: assert( ( waitShared & tbit ) != 0 ); assert( ( sharedList & tbit ) == 0 ); waitShared &= ~tbit; sharedList |= tbit; break; case LockEvent::Type::ReleaseShared: assert( ( sharedList & tbit ) != 0 ); sharedList &= ~tbit; break; default: break; } tl.lockingThread = lockingThread; tlp->waitShared = waitShared; tl.waitList = waitList; tlp->sharedList = sharedList; tl.lockCount = lockCount; if( !isContended ) isContended = ( lockCount != 0 && ( waitList != 0 || waitShared != 0 ) ) || ( sharedList != 0 && waitList != 0 ); pos++; } lockmap.isContended = isContended; } static inline void UpdateLockCount( LockMap& lockmap, size_t pos ) { if( lockmap.type == LockType::Lockable ) { UpdateLockCountLockable( lockmap, pos ); } else { UpdateLockCountSharedLockable( lockmap, pos ); } } static tracy_force_inline void WriteTimeOffset( FileWrite& f, int64_t& refTime, int64_t time ) { int64_t timeOffset = time - refTime; refTime += timeOffset; f.Write( &timeOffset, sizeof( timeOffset ) ); } static tracy_force_inline int64_t ReadTimeOffset( FileRead& f, int64_t& refTime ) { int64_t timeOffset; f.Read( timeOffset ); refTime += timeOffset; return refTime; } static tracy_force_inline void UpdateLockRange( LockMap& lockmap, const LockEvent& ev ) { const auto lt = ev.time; auto& range = lockmap.range[ev.thread]; if( range.start > lt ) range.start = lt; if( range.end < lt ) range.end = lt; } LoadProgress Worker::s_loadProgress; Worker::Worker( const char* addr ) : m_addr( addr ) , m_hasData( false ) , m_stream( LZ4_createStreamDecode() ) , m_buffer( new char[TargetFrameSize*3 + 1] ) , m_bufferOffset( 0 ) , m_pendingStrings( 0 ) , m_pendingThreads( 0 ) , m_pendingSourceLocation( 0 ) , m_pendingCallstackFrames( 0 ) , m_pendingCallstackSubframes( 0 ) , m_callstackFrameStaging( nullptr ) , m_traceVersion( CurrentVersion ) , m_loadTime( 0 ) { m_data.sourceLocationExpand.push_back( 0 ); m_data.threadExpand.push_back( 0 ); m_data.callstackPayload.push_back( nullptr ); memset( m_gpuCtxMap, 0, sizeof( m_gpuCtxMap ) ); #ifndef TRACY_NO_STATISTICS m_data.sourceLocationZonesReady = true; #endif m_thread = std::thread( [this] { Exec(); } ); SetThreadName( m_thread, "Tracy Worker" ); } Worker::Worker( FileRead& f, EventType::Type eventMask ) : m_hasData( true ) , m_stream( nullptr ) , m_buffer( nullptr ) { auto loadStart = std::chrono::high_resolution_clock::now(); m_data.callstackPayload.push_back( nullptr ); int fileVer = 0; uint8_t hdr[8]; f.Read( hdr, sizeof( hdr ) ); if( memcmp( FileHeader, hdr, FileHeaderMagic ) == 0 ) { fileVer = FileVersion( hdr[FileHeaderMagic], hdr[FileHeaderMagic+1], hdr[FileHeaderMagic+2] ); if( fileVer > CurrentVersion ) { throw UnsupportedVersion( fileVer ); } f.Read( m_delay ); } else { static_assert( sizeof( m_delay ) == sizeof( hdr ), "Size mismatch" ); memcpy( &m_delay, hdr, sizeof( m_delay ) ); } m_traceVersion = fileVer; if( fileVer <= FileVersion( 0, 3, 1 ) ) { s_loadProgress.total.store( 7, std::memory_order_relaxed ); } else if( fileVer <= FileVersion( 0, 4, 8 ) ) { s_loadProgress.total.store( 8, std::memory_order_relaxed ); } else { s_loadProgress.total.store( 9, std::memory_order_relaxed ); } s_loadProgress.subTotal.store( 0, std::memory_order_relaxed ); s_loadProgress.progress.store( LoadProgress::Initialization, std::memory_order_relaxed ); f.Read( m_resolution ); f.Read( m_timerMul ); f.Read( m_data.lastTime ); if( fileVer >= FileVersion( 0, 3, 200 ) ) { f.Read( m_data.frameOffset ); } uint64_t sz; { f.Read( sz ); assert( sz < 1024 ); char tmp[1024]; f.Read( tmp, sz ); m_captureName = std::string( tmp, tmp+sz ); } if( fileVer >= FileVersion( 0, 3, 205 ) ) { f.Read( sz ); assert( sz < 1024 ); char tmp[1024]; f.Read( tmp, sz ); m_captureProgram = std::string( tmp, tmp+sz ); f.Read( m_captureTime ); } else { const auto sz = m_captureName.size(); char tmp[1024]; memcpy( tmp, m_captureName.c_str(), sz ); tmp[sz] = '\0'; auto ptr = tmp + sz - 1; while( *ptr != '@' ) { if( *ptr == '#' ) *ptr = '\0'; ptr--; } m_captureProgram = std::string( tmp, ptr-1 ); tm epoch = {}; sscanf( ptr+1, "%d-%d-%d %d:%d:%d", &epoch.tm_year, &epoch.tm_mon, &epoch.tm_mday, &epoch.tm_hour, &epoch.tm_min, &epoch.tm_sec ); epoch.tm_year -= 1900; epoch.tm_mon--; m_captureTime = (uint64_t)mktime( &epoch ); } if( fileVer >= FileVersion( 0, 3, 203 ) ) { f.Read( sz ); assert( sz < 1024 ); char tmp[1024]; f.Read( tmp, sz ); m_hostInfo = std::string( tmp, tmp+sz ); } if( fileVer >= FileVersion( 0, 3, 204 ) ) { f.Read( &m_data.crashEvent, sizeof( m_data.crashEvent ) ); } if( fileVer >= FileVersion( 0, 3, 202 ) ) { f.Read( sz ); m_data.frames.Data().reserve_exact( sz, m_slab ); for( uint64_t i=0; i(); f.Read( &ptr->name, sizeof( ptr->name ) ); f.Read( &ptr->continuous, sizeof( ptr->continuous ) ); uint64_t fsz; f.Read( &fsz, sizeof( fsz ) ); ptr->frames.reserve_exact( fsz, m_slab ); if( fileVer >= FileVersion( 0, 4, 9 ) ) { int64_t refTime = 0; if( ptr->continuous ) { for( uint64_t j=0; jframes[j].start = ReadTimeOffset( f, refTime ); ptr->frames[j].end = -1; f.Read( &ptr->frames[j].frameImage, sizeof( int32_t ) ); } } else { for( uint64_t j=0; jframes[j].start = ReadTimeOffset( f, refTime ); ptr->frames[j].end = ReadTimeOffset( f, refTime ); f.Read( &ptr->frames[j].frameImage, sizeof( int32_t ) ); } } } else if( fileVer >= FileVersion( 0, 4, 2 ) ) { int64_t refTime = 0; if( ptr->continuous ) { for( uint64_t j=0; jframes[j].start = ReadTimeOffset( f, refTime ); ptr->frames[j].end = -1; ptr->frames[j].frameImage = -1; } } else { for( uint64_t j=0; jframes[j].start = ReadTimeOffset( f, refTime ); ptr->frames[j].end = ReadTimeOffset( f, refTime ); ptr->frames[j].frameImage = -1; } } } else { if( ptr->continuous ) { for( uint64_t j=0; jframes[j].start, sizeof( int64_t ) ); ptr->frames[j].end = -1; ptr->frames[j].frameImage = -1; } } else { for( uint64_t j=0; jframes[j].start, sizeof( int64_t ) ); f.Read( &ptr->frames[j].end, sizeof( int64_t ) ); ptr->frames[j].frameImage = -1; } } } m_data.frames.Data()[i] = ptr; } m_data.framesBase = m_data.frames.Data()[0]; assert( m_data.framesBase->name == 0 ); } else { auto ptr = m_slab.AllocInit(); ptr->name = 0; ptr->continuous = 1; f.Read( sz ); ptr->frames.reserve_exact( sz, m_slab ); for( uint64_t i=0; iframes[i].start, sizeof( int64_t ) ); ptr->frames[i].end = -1; ptr->frames[i].frameImage = -1; } m_data.frames.Data().push_back( ptr ); m_data.framesBase = ptr; } flat_hash_map> pointerMap; f.Read( sz ); m_data.stringData.reserve_exact( sz, m_slab ); for( uint64_t i=0; i( ssz+1 ); f.Read( dst, ssz ); dst[ssz] = '\0'; m_data.stringData[i] = ( dst ); pointerMap.emplace( ptr, dst ); } f.Read( sz ); for( uint64_t i=0; isecond ); } } f.Read( sz ); for( uint64_t i=0; isecond ); } } if( fileVer >= FileVersion( 0, 4, 4 ) ) { f.Read( sz ); m_data.threadExpand.reserve_and_use( sz ); f.Read( m_data.threadExpand.data(), sizeof( uint64_t ) * sz ); m_data.threadMap.reserve( sz ); for( size_t i=0; i= FileVersion( 0, 3, 201 ) ) { f.Read( sz ); m_data.threadExpand.reserve( sz ); m_data.threadExpand.push_back( 0 ); } else { m_data.threadExpand.push_back( 0 ); } f.Read( sz ); for( uint64_t i=0; i(); f.Read( srcloc, sizeof( *srcloc ) ); m_data.sourceLocationPayload[i] = srcloc; m_data.sourceLocationPayloadMap.emplace( srcloc, uint32_t( i ) ); } #ifndef TRACY_NO_STATISTICS m_data.sourceLocationZonesReady = false; m_data.sourceLocationZones.reserve( sle + sz ); if( fileVer >= FileVersion( 0, 3, 201 ) ) { f.Read( sz ); for( uint64_t i=0; isecond.zones.reserve( cnt ); } } else { for( uint64_t i=1; i= FileVersion( 0, 3, 201 ) ) { f.Read( sz ); for( uint64_t i=0; i(); auto& lockmap = *lockmapPtr; uint32_t id; uint64_t tsz; f.Read( id ); f.Read( lockmap.srcloc ); f.Read( lockmap.type ); f.Read( lockmap.valid ); lockmap.isContended = false; if( fileVer >= FileVersion( 0, 4, 1 ) ) { f.Read2( lockmap.timeAnnounce, lockmap.timeTerminate ); } else { lockmap.timeAnnounce = lockmap.timeTerminate = 0; } f.Read( tsz ); for( uint64_t i=0; i= FileVersion( 0, 4, 2 ) ) { int64_t refTime = lockmap.timeAnnounce; if( lockmap.type == LockType::Lockable ) { for( uint64_t i=0; i(); lev->time = ReadTimeOffset( f, refTime ); f.Read( &lev->srcloc, sizeof( LockEvent::srcloc ) + sizeof( LockEvent::thread ) + sizeof( LockEvent::type ) ); *ptr++ = { lev }; UpdateLockRange( lockmap, *lev ); } } else { for( uint64_t i=0; i(); lev->time = ReadTimeOffset( f, refTime ); f.Read( &lev->srcloc, sizeof( LockEventShared::srcloc ) + sizeof( LockEventShared::thread ) + sizeof( LockEventShared::type ) ); *ptr++ = { lev }; UpdateLockRange( lockmap, *lev ); } } } else if( fileVer >= FileVersion( 0, 3, 0 ) ) { if( lockmap.type == LockType::Lockable ) { for( uint64_t i=0; i(); f.Read( lev, sizeof( LockEvent::time ) + sizeof( LockEvent::srcloc ) + sizeof( LockEvent::thread ) + sizeof( LockEvent::type ) ); *ptr++ = { lev }; UpdateLockRange( lockmap, *lev ); } } else { for( uint64_t i=0; i(); f.Read( lev, sizeof( LockEventShared::time ) + sizeof( LockEventShared::srcloc ) + sizeof( LockEventShared::thread ) + sizeof( LockEventShared::type ) ); *ptr++ = { lev }; UpdateLockRange( lockmap, *lev ); } } } else { if( lockmap.type == LockType::Lockable ) { for( uint64_t i=0; i(); f.Read( lev, sizeof( LockEvent::time ) + sizeof( LockEvent::srcloc ) + sizeof( LockEvent::thread ) ); f.Skip( sizeof( uint8_t ) ); f.Read( lev->type ); f.Skip( sizeof( uint8_t ) + sizeof( uint64_t ) ); *ptr++ = { lev }; UpdateLockRange( lockmap, *lev ); } } else { for( uint64_t i=0; i(); f.Read( lev, sizeof( LockEventShared::time ) + sizeof( LockEventShared::srcloc ) + sizeof( LockEventShared::thread ) ); f.Skip( sizeof( uint8_t ) ); f.Read( lev->type ); f.Skip( sizeof( uint8_t ) + sizeof( uint64_t ) * 3 ); *ptr++ = { lev }; UpdateLockRange( lockmap, *lev ); } } } UpdateLockCount( lockmap, 0 ); m_data.lockMap.emplace( id, lockmapPtr ); } } else { for( uint64_t i=0; i= FileVersion( 0, 4, 1 ) ) { f.Skip( sizeof( LockMap::timeAnnounce ) + sizeof( LockMap::timeTerminate ) ); } f.Read( tsz ); f.Skip( tsz * sizeof( uint64_t ) ); f.Read( tsz ); if( fileVer >= FileVersion( 0, 3, 0 ) ) { f.Skip( tsz * ( sizeof( LockEvent::time ) + sizeof( LockEvent::type ) + sizeof( LockEvent::srcloc ) + sizeof( LockEvent::thread ) ) ); } else { f.Skip( tsz * ( type == LockType::Lockable ? 24 : 40 ) ); } } } s_loadProgress.subTotal.store( 0, std::memory_order_relaxed ); s_loadProgress.progress.store( LoadProgress::Messages, std::memory_order_relaxed ); flat_hash_map> msgMap; f.Read( sz ); if( eventMask & EventType::Messages ) { m_data.messages.reserve_exact( sz, m_slab ); if( fileVer >= FileVersion( 0, 4, 8 ) ) { int64_t refTime = 0; for( uint64_t i=0; i(); msgdata->time = ReadTimeOffset( f, refTime ); f.Read( msgdata->ref ); f.Read( msgdata->color ); m_data.messages[i] = msgdata; msgMap.emplace( ptr, msgdata ); } } else if( fileVer >= FileVersion( 0, 4, 2 ) ) { int64_t refTime = 0; for( uint64_t i=0; i(); msgdata->time = ReadTimeOffset( f, refTime ); f.Read( msgdata->ref ); msgdata->color = 0xFFFFFFFF; m_data.messages[i] = msgdata; msgMap.emplace( ptr, msgdata ); } } else { for( uint64_t i=0; i(); f.Read( msgdata, sizeof( MessageData::time ) + sizeof( MessageData::ref ) ); if( fileVer <= FileVersion( 0, 3, 0 ) ) f.Skip( 7 ); msgdata->color = 0xFFFFFFFF; m_data.messages[i] = msgdata; msgMap.emplace( ptr, msgdata ); } } } else { // Prior to 0.3.1 MessageData was saved with padding. if( fileVer <= FileVersion( 0, 3, 0 ) ) { f.Skip( sz * ( sizeof( uint64_t ) + 24 ) ); } else if( fileVer <= FileVersion( 0, 4, 7 ) ) { f.Skip( sz * ( sizeof( uint64_t ) + sizeof( MessageData::time ) + sizeof( MessageData::ref ) ) ); } else { f.Skip( sz * ( sizeof( uint64_t ) + sizeof( MessageData::time ) + sizeof( MessageData::ref ) + sizeof( MessageData::color ) ) ); } } s_loadProgress.progress.store( LoadProgress::Zones, std::memory_order_relaxed ); if( fileVer >= FileVersion( 0, 4, 7 ) ) { f.Read( sz ); s_loadProgress.subTotal.store( sz, std::memory_order_relaxed ); s_loadProgress.subProgress.store( 0, std::memory_order_relaxed ); } f.Read( sz ); m_data.threads.reserve_exact( sz, m_slab ); for( uint64_t i=0; i(); uint64_t tid; f.Read( tid ); td->id = tid; f.Read( td->count ); uint64_t tsz; f.Read( tsz ); if( fileVer < FileVersion( 0, 4, 7 ) ) { s_loadProgress.subTotal.store( td->count, std::memory_order_relaxed ); s_loadProgress.subProgress.store( 0, std::memory_order_relaxed ); } if( tsz != 0 ) { if( fileVer <= FileVersion( 0, 4, 1 ) ) { ReadTimelinePre042( f, td->timeline, CompressThread( tid ), tsz, fileVer ); } else { int64_t refTime = 0; ReadTimeline( f, td->timeline, CompressThread( tid ), tsz, refTime ); } } uint64_t msz; f.Read( msz ); if( eventMask & EventType::Messages ) { td->messages.reserve_exact( msz, m_slab ); for( uint64_t j=0; jmessages[j] = md; md->thread = tid; } } else { f.Skip( msz * sizeof( uint64_t ) ); } m_data.threads[i] = td; } s_loadProgress.progress.store( LoadProgress::GpuZones, std::memory_order_relaxed ); if( fileVer >= FileVersion( 0, 4, 7 ) ) { f.Read( sz ); s_loadProgress.subTotal.store( sz, std::memory_order_relaxed ); s_loadProgress.subProgress.store( 0, std::memory_order_relaxed ); } f.Read( sz ); m_data.gpuData.reserve_exact( sz, m_slab ); for( uint64_t i=0; i(); f.Read( ctx->thread ); f.Read( ctx->accuracyBits ); f.Read( ctx->count ); if( fileVer < FileVersion( 0, 4, 7 ) ) { s_loadProgress.subTotal.store( ctx->count, std::memory_order_relaxed ); s_loadProgress.subProgress.store( 0, std::memory_order_relaxed ); } int64_t refTime = 0; int64_t refGpuTime = 0; if( fileVer <= FileVersion( 0, 3, 1 ) ) { ctx->period = 1.f; uint64_t tsz; f.Read( tsz ); if( tsz != 0 ) { ReadTimelinePre044( f, ctx->timeline, tsz, refTime, refGpuTime, fileVer ); } } else { f.Read( ctx->period ); uint64_t tsz; f.Read( tsz ); if( tsz != 0 ) { if( fileVer <= FileVersion( 0, 4, 3 ) ) { ReadTimelinePre044( f, ctx->timeline, tsz, refTime, refGpuTime, fileVer ); } else { ReadTimeline( f, ctx->timeline, tsz, refTime, refGpuTime ); } } } m_data.gpuData[i] = ctx; } s_loadProgress.progress.store( LoadProgress::Plots, std::memory_order_relaxed ); f.Read( sz ); if( eventMask & EventType::Plots ) { m_data.plots.Data().reserve( sz ); s_loadProgress.subTotal.store( sz, std::memory_order_relaxed ); for( uint64_t i=0; i(); if( fileVer >= FileVersion( 0, 4, 5 ) ) { f.Read( pd->type ); } else { pd->type = PlotType::User; } f.Read( pd->name ); f.Read( pd->min ); f.Read( pd->max ); uint64_t psz; f.Read( psz ); pd->data.reserve_exact( psz, m_slab ); if( fileVer >= FileVersion( 0, 4, 2 ) ) { int64_t refTime = 0; for( uint64_t j=0; jdata[j].time = ReadTimeOffset( f, refTime ); f.Read( pd->data[j].val ); } } else { f.Read( pd->data.data(), psz * sizeof( PlotItem ) ); } m_data.plots.Data().push_back_no_space_check( pd ); } } else { for( uint64_t i=0; i= FileVersion( 0, 4, 5 ) ) { f.Skip( sizeof( PlotData::name ) + sizeof( PlotData::min ) + sizeof( PlotData::max ) + sizeof( PlotData::type ) ); } else { f.Skip( sizeof( PlotData::name ) + sizeof( PlotData::min ) + sizeof( PlotData::max ) ); } uint64_t psz; f.Read( psz ); f.Skip( psz * sizeof( PlotItem ) ); } } bool reconstructMemAllocPlot = false; // Support pre-0.3 traces if( fileVer == 0 && f.IsEOF() ) goto finishLoading; s_loadProgress.subTotal.store( 0, std::memory_order_relaxed ); s_loadProgress.progress.store( LoadProgress::Memory, std::memory_order_relaxed ); f.Read( sz ); if( eventMask & EventType::Memory ) { m_data.memory.data.reserve_exact( sz, m_slab ); if( fileVer >= FileVersion( 0, 3, 201 ) ) { uint64_t activeSz, freesSz; f.Read2( activeSz, freesSz ); m_data.memory.active.reserve( activeSz ); m_data.memory.frees.reserve_exact( freesSz, m_slab ); } auto mem = m_data.memory.data.data(); s_loadProgress.subTotal.store( sz, std::memory_order_relaxed ); size_t fidx = 0; int64_t refTime = 0; if( fileVer >= FileVersion( 0, 4, 4 ) ) { auto& frees = m_data.memory.frees; auto& active = m_data.memory.active; for( uint64_t i=0; itimeAlloc; mem->timeAlloc = refTime; if( mem->timeFree >= 0 ) { mem->timeFree += refTime; frees[fidx++] = i; } else { active.emplace( mem->ptr, i ); } mem++; } } else { for( uint64_t i=0; i FileVersion( 0, 4, 1 ) ) { f.Read( mem, sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) + sizeof( MemEvent::csAlloc ) + sizeof( MemEvent::csFree ) ); refTime += mem->timeAlloc; mem->timeAlloc = refTime; if( mem->timeFree >= 0 ) mem->timeFree += refTime; } else if( fileVer > FileVersion( 0, 3, 1 ) ) { f.Read( mem, sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) + sizeof( MemEvent::csAlloc ) + sizeof( MemEvent::csFree ) ); } else { f.Read( mem, sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) ); mem->csAlloc = 0; mem->csFree = 0; } uint64_t t0, t1; f.Read2( t0, t1 ); mem->threadAlloc = CompressThread( t0 ); if( t0 == t1 ) { mem->threadFree = mem->threadAlloc; } else { mem->threadFree = CompressThread( t1 ); } if( mem->timeFree < 0 ) { m_data.memory.active.emplace( mem->ptr, i ); } else { if( fileVer >= FileVersion( 0, 3, 201 ) ) { m_data.memory.frees[fidx++] = i; } else { m_data.memory.frees.push_back( i ); } } mem++; } } f.Read( m_data.memory.high ); f.Read( m_data.memory.low ); f.Read( m_data.memory.usage ); if( sz != 0 ) { reconstructMemAllocPlot = true; } } else { if( fileVer >= FileVersion( 0, 3, 201 ) ) { f.Skip( 2 * sizeof( uint64_t ) ); } if( fileVer >= FileVersion( 0, 4, 4 ) ) { f.Skip( sz * ( sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) + sizeof( MemEvent::csAlloc ) + sizeof( MemEvent::csFree ) + sizeof( MemEvent::threadAlloc ) + sizeof( MemEvent::threadFree ) ) ); } else if( fileVer > FileVersion( 0, 4, 1 ) ) { f.Skip( sz * ( sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) + sizeof( MemEvent::csAlloc ) + sizeof( MemEvent::csFree ) + 2 * sizeof( uint64_t ) ) ); } else if( fileVer > FileVersion( 0, 3, 1 ) ) { f.Skip( sz * ( sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) + sizeof( MemEvent::csAlloc ) + sizeof( MemEvent::csFree ) + 2 * sizeof( uint64_t ) ) ); } else { f.Skip( sz * ( sizeof( MemEvent::ptr ) + sizeof( MemEvent::size ) + sizeof( MemEvent::timeAlloc ) + sizeof( MemEvent::timeFree ) + 2 * sizeof( uint64_t ) ) ); } f.Skip( sizeof( MemData::high ) + sizeof( MemData::low ) + sizeof( MemData::usage ) ); } if( fileVer <= FileVersion( 0, 3, 1 ) ) goto finishLoading; s_loadProgress.subTotal.store( 0, std::memory_order_relaxed ); s_loadProgress.progress.store( LoadProgress::CallStacks, std::memory_order_relaxed ); f.Read( sz ); m_data.callstackPayload.reserve( sz ); if( fileVer >= FileVersion( 0, 4, 6 ) ) { for( uint64_t i=0; i ) + csz * sizeof( CallstackFrameId ); auto mem = (char*)m_slab.AllocRaw( memsize ); auto data = (CallstackFrameId*)mem; f.Read( data, csz * sizeof( CallstackFrameId ) ); auto arr = (VarArray*)( mem + csz * sizeof( CallstackFrameId ) ); new(arr) VarArray( csz, data ); m_data.callstackPayload.push_back_no_space_check( arr ); } } else { for( uint64_t i=0; i ) + csz * sizeof( CallstackFrameId ); auto mem = (char*)m_slab.AllocRaw( memsize ); auto data = (CallstackFrameId*)mem; for( uint8_t j=0; j*)( mem + csz * sizeof( CallstackFrameId ) ); new(arr) VarArray( csz, data ); m_data.callstackPayload.push_back_no_space_check( arr ); } } if( fileVer >= FileVersion( 0, 4, 6 ) ) { f.Read( sz ); m_data.callstackFrameMap.reserve( sz ); for( uint64_t i=0; i(); f.Read( frameData->size ); frameData->data = m_slab.Alloc( frameData->size ); f.Read( frameData->data, sizeof( CallstackFrame ) * frameData->size ); m_data.callstackFrameMap.emplace( id, frameData ); } } else if( fileVer >= FileVersion( 0, 4, 3 ) ) { f.Read( sz ); m_data.callstackFrameMap.reserve( sz ); for( uint64_t i=0; i(); f.Read( frameData->size ); frameData->data = m_slab.Alloc( frameData->size ); f.Read( frameData->data, sizeof( CallstackFrame ) * frameData->size ); m_data.callstackFrameMap.emplace( PackPointer( ptr ), frameData ); } } else { f.Read( sz ); m_data.callstackFrameMap.reserve( sz ); for( uint64_t i=0; i(); frameData->size = 1; frameData->data = m_slab.Alloc(); f.Read( frameData->data, sizeof( CallstackFrame ) ); m_data.callstackFrameMap.emplace( PackPointer( ptr ), frameData ); } } if( fileVer >= FileVersion( 0, 4, 9 ) ) { s_loadProgress.subTotal.store( 0, std::memory_order_relaxed ); s_loadProgress.progress.store( LoadProgress::FrameImages, std::memory_order_relaxed ); if( eventMask & EventType::FrameImages ) { size_t tmpbufsz = 0; char* tmpbuf = nullptr; f.Read( sz ); m_data.frameImage.reserve_exact( sz, m_slab ); s_loadProgress.subTotal.store( sz, std::memory_order_relaxed ); for( uint64_t i=0; i(); f.Read2( fi->w, fi->h ); f.Read( fi->flip ); const auto sz = fi->w * fi->h / 2; if( tmpbufsz < sz ) { tmpbufsz = sz; delete[] tmpbuf; tmpbuf = new char[sz]; } f.Read( tmpbuf, sz ); fi->ptr = PackFrameImage( tmpbuf, fi->w, fi->h, fi->csz ); m_data.frameImage[i] = fi; } delete[] tmpbuf; const auto& frames = GetFramesBase()->frames; const auto fsz = uint32_t( frames.size() ); for( uint32_t i=0; iframeRef = i; } } } else { // Implement skip, if more data is added after frame image section } } finishLoading: s_loadProgress.total.store( 0, std::memory_order_relaxed ); m_loadTime = std::chrono::duration_cast( std::chrono::high_resolution_clock::now() - loadStart ).count(); m_backgroundDone.store( false, std::memory_order_relaxed ); #ifndef TRACY_NO_STATISTICS m_threadBackground = std::thread( [this, reconstructMemAllocPlot] { std::function&, uint16_t)> ProcessTimeline; ProcessTimeline = [this, &ProcessTimeline] ( const Vector& vec, uint16_t thread ) { for( auto& zone : vec ) { ReadTimelineUpdateStatistics( zone, thread ); if( zone->child >= 0 ) { ProcessTimeline( GetZoneChildren( zone->child ), thread ); } } }; for( auto& t : m_data.threads ) { if( !t->timeline.empty() ) { // Don't touch thread compression cache in a thread. auto it = m_data.threadMap.find( t->id ); assert( it != m_data.threadMap.end() ); ProcessTimeline( t->timeline, it->second ); } } for( auto& v : m_data.sourceLocationZones ) { auto& zones = v.second.zones; #ifdef MY_LIBCPP_SUCKS pdqsort_branchless( zones.begin(), zones.end(), []( const auto& lhs, const auto& rhs ) { return lhs.zone->start < rhs.zone->start; } ); #else std::sort( std::execution::par_unseq, zones.begin(), zones.end(), []( const auto& lhs, const auto& rhs ) { return lhs.zone->start < rhs.zone->start; } ); #endif } { std::lock_guard lock( m_data.lock ); m_data.sourceLocationZonesReady = true; } if( reconstructMemAllocPlot ) ReconstructMemAllocPlot(); m_backgroundDone.store( true, std::memory_order_relaxed ); } ); #else if( reconstructMemAllocPlot ) { m_threadBackground = std::thread( [this] { ReconstructMemAllocPlot(); m_backgroundDone.store( true, std::memory_order_relaxed ); } ); } #endif } Worker::~Worker() { Shutdown(); if( m_thread.joinable() ) m_thread.join(); if( m_threadBackground.joinable() ) m_threadBackground.join(); delete[] m_buffer; LZ4_freeStreamDecode( m_stream ); delete[] m_frameImageBuffer; for( auto& v : m_data.threads ) { v->timeline.~Vector(); v->stack.~Vector(); v->messages.~Vector(); v->zoneIdStack.~Vector(); } for( auto& v : m_data.gpuData ) { v->timeline.~Vector(); v->stack.~Vector(); } for( auto& v : m_data.plots.Data() ) { v->~PlotData(); } for( auto& v : m_data.frames.Data() ) { v->~FrameData(); } for( auto& v : m_data.lockMap ) { v.second->~LockMap(); } } uint64_t Worker::GetLockCount() const { uint64_t cnt = 0; for( auto& l : m_data.lockMap ) { cnt += l.second->timeline.size(); } return cnt; } uint64_t Worker::GetPlotCount() const { uint64_t cnt = 0; for( auto& p : m_data.plots.Data() ) { if( p->type != PlotType::Memory ) { cnt += p->data.size(); } } return cnt; } size_t Worker::GetFullFrameCount( const FrameData& fd ) const { const auto sz = fd.frames.size(); assert( sz != 0 ); if( fd.continuous ) { if( IsConnected() ) { return sz - 1; } else { return sz; } } else { const auto& last = fd.frames.back(); if( last.end >= 0 ) { return sz; } else { return sz - 1; } } } int64_t Worker::GetFrameTime( const FrameData& fd, size_t idx ) const { if( fd.continuous ) { if( idx < fd.frames.size() - 1 ) { return fd.frames[idx+1].start - fd.frames[idx].start; } else { assert( m_data.lastTime != 0 ); return m_data.lastTime - fd.frames.back().start; } } else { const auto& frame = fd.frames[idx]; if( frame.end >= 0 ) { return frame.end - frame.start; } else { return m_data.lastTime - fd.frames.back().start; } } } int64_t Worker::GetFrameBegin( const FrameData& fd, size_t idx ) const { assert( idx < fd.frames.size() ); return fd.frames[idx].start; } int64_t Worker::GetFrameEnd( const FrameData& fd, size_t idx ) const { if( fd.continuous ) { if( idx < fd.frames.size() - 1 ) { return fd.frames[idx+1].start; } else { return m_data.lastTime; } } else { if( fd.frames[idx].end >= 0 ) { return fd.frames[idx].end; } else { return m_data.lastTime; } } } const FrameImage* Worker::GetFrameImage( const FrameData& fd, size_t idx ) const { assert( idx < fd.frames.size() ); const auto& v = fd.frames[idx].frameImage; if( v < 0 ) return nullptr; return m_data.frameImage[v]; } std::pair Worker::GetFrameRange( const FrameData& fd, int64_t from, int64_t to ) { auto zitbegin = std::lower_bound( fd.frames.begin(), fd.frames.end(), from, [] ( const auto& lhs, const auto& rhs ) { return lhs.start < rhs; } ); if( zitbegin == fd.frames.end() ) zitbegin--; const auto zitend = std::lower_bound( zitbegin, fd.frames.end(), to, [] ( const auto& lhs, const auto& rhs ) { return lhs.start < rhs; } ); int zbegin = std::distance( fd.frames.begin(), zitbegin ); if( zbegin > 0 && zitbegin->start != from ) --zbegin; const int zend = std::distance( fd.frames.begin(), zitend ); return std::make_pair( zbegin, zend ); } const CallstackFrameData* Worker::GetCallstackFrame( const CallstackFrameId& ptr ) const { auto it = m_data.callstackFrameMap.find( ptr ); if( it == m_data.callstackFrameMap.end() ) { return nullptr; } else { return it->second; } } int64_t Worker::GetZoneEnd( const ZoneEvent& ev ) { auto ptr = &ev; for(;;) { if( ptr->end >= 0 ) return ptr->end; if( ptr->child < 0 ) return ptr->start; ptr = GetZoneChildren( ptr->child ).back(); } } int64_t Worker::GetZoneEnd( const GpuEvent& ev ) { auto ptr = &ev; for(;;) { if( ptr->gpuEnd >= 0 ) return ptr->gpuEnd; if( ptr->child < 0 ) return ptr->gpuStart; ptr = GetGpuChildren( ptr->child ).back(); } } const char* Worker::GetString( uint64_t ptr ) const { const auto it = m_data.strings.find( ptr ); if( it == m_data.strings.end() || it->second == nullptr ) { return "???"; } else { return it->second; } } const char* Worker::GetString( const StringRef& ref ) const { if( ref.isidx ) { assert( ref.active ); return m_data.stringData[ref.str]; } else { if( ref.active ) { return GetString( ref.str ); } else { return "???"; } } } const char* Worker::GetString( const StringIdx& idx ) const { assert( idx.active ); return m_data.stringData[idx.idx]; } const char* Worker::GetThreadString( uint64_t id ) const { const auto it = m_data.threadNames.find( id ); if( it == m_data.threadNames.end() ) { return "???"; } else { return it->second; } } const SourceLocation& Worker::GetSourceLocation( int32_t srcloc ) const { if( srcloc < 0 ) { return *m_data.sourceLocationPayload[-srcloc-1]; } else { const auto it = m_data.sourceLocation.find( m_data.sourceLocationExpand[srcloc] ); assert( it != m_data.sourceLocation.end() ); return it->second; } } const char* Worker::GetZoneName( const SourceLocation& srcloc ) const { if( srcloc.name.active ) { return GetString( srcloc.name ); } else { return GetString( srcloc.function ); } } const char* Worker::GetZoneName( const ZoneEvent& ev ) const { auto& srcloc = GetSourceLocation( ev.srcloc ); return GetZoneName( ev, srcloc ); } const char* Worker::GetZoneName( const ZoneEvent& ev, const SourceLocation& srcloc ) const { if( ev.name.active ) { return GetString( ev.name ); } else if( srcloc.name.active ) { return GetString( srcloc.name ); } else { return GetString( srcloc.function ); } } const char* Worker::GetZoneName( const GpuEvent& ev ) const { auto& srcloc = GetSourceLocation( ev.srcloc ); return GetZoneName( ev, srcloc ); } const char* Worker::GetZoneName( const GpuEvent& ev, const SourceLocation& srcloc ) const { if( srcloc.name.active ) { return GetString( srcloc.name ); } else { return GetString( srcloc.function ); } } static bool strstr_nocase( const char* l, const char* r ) { const auto lsz = strlen( l ); const auto rsz = strlen( r ); auto ll = (char*)alloca( lsz + 1 ); auto rl = (char*)alloca( lsz + 1 ); for( size_t i=0; i Worker::GetMatchingSourceLocation( const char* query, bool ignoreCase ) const { std::vector match; const auto sz = m_data.sourceLocationExpand.size(); for( size_t i=1; isecond; const auto str = GetString( srcloc.name.active ? srcloc.name : srcloc.function ); bool found = false; if( ignoreCase ) { found = strstr_nocase( str, query ); } else { found = strstr( str, query ) != nullptr; } if( found ) { match.push_back( (int32_t)i ); } } for( auto& srcloc : m_data.sourceLocationPayload ) { const auto str = GetString( srcloc->name.active ? srcloc->name : srcloc->function ); bool found = false; if( ignoreCase ) { found = strstr_nocase( str, query ); } else { found = strstr( str, query ) != nullptr; } if( found ) { auto it = m_data.sourceLocationPayloadMap.find( srcloc ); assert( it != m_data.sourceLocationPayloadMap.end() ); match.push_back( -int32_t( it->second + 1 ) ); } } return match; } #ifndef TRACY_NO_STATISTICS const Worker::SourceLocationZones& Worker::GetZonesForSourceLocation( int32_t srcloc ) const { static const SourceLocationZones empty; auto it = m_data.sourceLocationZones.find( srcloc ); return it != m_data.sourceLocationZones.end() ? it->second : empty; } #endif uint16_t Worker::CompressThreadReal( uint64_t thread ) { auto it = m_data.threadMap.find( thread ); if( it != m_data.threadMap.end() ) { m_data.threadLast.first = thread; m_data.threadLast.second = it->second; return it->second; } else { return CompressThreadNew( thread ); } } uint16_t Worker::CompressThreadNew( uint64_t thread ) { auto sz = m_data.threadExpand.size(); m_data.threadExpand.push_back( thread ); m_data.threadMap.emplace( thread, sz ); m_data.threadLast.first = thread; m_data.threadLast.second = sz; return sz; } void Worker::Exec() { auto ShouldExit = [this] { return m_shutdown.load( std::memory_order_relaxed ); }; for(;;) { if( m_shutdown.load( std::memory_order_relaxed ) ) return; if( m_sock.Connect( m_addr.c_str(), "8086" ) ) break; } auto lz4buf = std::make_unique( LZ4Size ); std::chrono::time_point t0; uint64_t bytes = 0; uint64_t decBytes = 0; m_sock.Send( HandshakeShibboleth, HandshakeShibbolethSize ); uint32_t protocolVersion = ProtocolVersion; m_sock.Send( &protocolVersion, sizeof( protocolVersion ) ); HandshakeStatus handshake; if( !m_sock.Read( &handshake, sizeof( handshake ), 10, ShouldExit ) ) { m_handshake.store( HandshakeDropped, std::memory_order_relaxed ); goto close; } m_handshake.store( handshake, std::memory_order_relaxed ); switch( handshake ) { case HandshakeWelcome: break; case HandshakeProtocolMismatch: case HandshakeNotAvailable: default: goto close; } m_data.framesBase = m_data.frames.Retrieve( 0, [this] ( uint64_t name ) { auto fd = m_slab.AllocInit(); fd->name = name; fd->continuous = 1; return fd; }, [this] ( uint64_t name ) { assert( name == 0 ); char tmp[6] = "Frame"; HandleFrameName( name, tmp, 5 ); } ); { WelcomeMessage welcome; if( !m_sock.Read( &welcome, sizeof( welcome ), 10, ShouldExit ) ) { m_handshake.store( HandshakeDropped, std::memory_order_relaxed ); goto close; } m_timerMul = welcome.timerMul; const auto initEnd = TscTime( welcome.initEnd ); m_data.framesBase->frames.push_back( FrameEvent{ TscTime( welcome.initBegin ), -1, -1 } ); m_data.framesBase->frames.push_back( FrameEvent{ initEnd, -1, -1 } ); m_data.lastTime = initEnd; m_delay = TscTime( welcome.delay ); m_resolution = TscTime( welcome.resolution ); m_onDemand = welcome.onDemand; m_captureProgram = welcome.programName; m_captureTime = welcome.epoch; char dtmp[64]; time_t date = welcome.epoch; auto lt = localtime( &date ); strftime( dtmp, 64, "%F %T", lt ); char tmp[1024]; sprintf( tmp, "%s @ %s", welcome.programName, dtmp ); m_captureName = tmp; m_hostInfo = welcome.hostInfo; if( welcome.onDemand != 0 ) { OnDemandPayloadMessage onDemand; if( !m_sock.Read( &onDemand, sizeof( onDemand ), 10, ShouldExit ) ) { m_handshake.store( HandshakeDropped, std::memory_order_relaxed ); goto close; } m_data.frameOffset = onDemand.frames; } } m_serverQuerySpaceLeft = ( m_sock.GetSendBufSize() / ServerQueryPacketSize ) - ServerQueryPacketSize; // leave space for terminate request m_hasData.store( true, std::memory_order_release ); LZ4_setStreamDecode( m_stream, nullptr, 0 ); m_connected.store( true, std::memory_order_relaxed ); t0 = std::chrono::high_resolution_clock::now(); for(;;) { if( m_shutdown.load( std::memory_order_relaxed ) ) { QueryTerminate(); return; } auto buf = m_buffer + m_bufferOffset; lz4sz_t lz4sz; if( !m_sock.Read( &lz4sz, sizeof( lz4sz ), 10, ShouldExit ) ) goto close; if( !m_sock.Read( lz4buf.get(), lz4sz, 10, ShouldExit ) ) goto close; bytes += sizeof( lz4sz ) + lz4sz; auto sz = LZ4_decompress_safe_continue( m_stream, lz4buf.get(), buf, lz4sz, TargetFrameSize ); assert( sz >= 0 ); decBytes += sz; char* ptr = buf; const char* end = buf + sz; { std::lock_guard lock( m_data.lock ); while( ptr < end ) { auto ev = (const QueueItem*)ptr; if( !DispatchProcess( *ev, ptr ) ) { QueryTerminate(); goto close; } } m_bufferOffset += sz; if( m_bufferOffset > TargetFrameSize * 2 ) m_bufferOffset = 0; HandlePostponedPlots(); while( !m_serverQueryQueue.empty() && m_serverQuerySpaceLeft > 0 ) { m_serverQuerySpaceLeft--; const auto& query = m_serverQueryQueue.back(); m_sock.Send( &query, ServerQueryPacketSize ); m_serverQueryQueue.pop_back(); } } auto t1 = std::chrono::high_resolution_clock::now(); auto td = std::chrono::duration_cast( t1 - t0 ).count(); enum { MbpsUpdateTime = 200 }; if( td > MbpsUpdateTime ) { std::lock_guard lock( m_mbpsData.lock ); m_mbpsData.mbps.erase( m_mbpsData.mbps.begin() ); m_mbpsData.mbps.emplace_back( bytes / ( td * 125.f ) ); m_mbpsData.compRatio = float( bytes ) / decBytes; m_mbpsData.queue = m_serverQueryQueue.size(); t0 = t1; bytes = 0; decBytes = 0; } if( m_terminate ) { if( m_pendingStrings != 0 || m_pendingThreads != 0 || m_pendingSourceLocation != 0 || m_pendingCallstackFrames != 0 || !m_pendingCustomStrings.empty() || m_data.plots.IsPending() || m_pendingCallstackPtr != 0 || m_pendingCallstackSubframes != 0 || !m_pendingFrameImageData.empty() ) { continue; } if( !m_crashed ) { bool done = true; for( auto& v : m_data.threads ) { if( !v->stack.empty() ) { done = false; break; } } if( !done ) continue; } Query( ServerQueryTerminate, 0 ); break; } } close: m_sock.Close(); m_connected.store( false, std::memory_order_relaxed ); } void Worker::Query( ServerQuery type, uint64_t data ) { ServerQueryPacket query { type, data }; if( m_serverQuerySpaceLeft > 0 ) { m_serverQuerySpaceLeft--; m_sock.Send( &query, ServerQueryPacketSize ); } else { m_serverQueryQueue.insert( m_serverQueryQueue.begin(), query ); } } void Worker::QueryTerminate() { ServerQueryPacket query { ServerQueryTerminate, 0 }; m_sock.Send( &query, ServerQueryPacketSize ); } bool Worker::DispatchProcess( const QueueItem& ev, char*& ptr ) { if( ev.hdr.idx >= (int)QueueType::StringData ) { ptr += sizeof( QueueHeader ) + sizeof( QueueStringTransfer ); if( ev.hdr.type == QueueType::FrameImageData ) { uint32_t sz; memcpy( &sz, ptr, sizeof( sz ) ); ptr += sizeof( sz ); AddFrameImageData( ev.stringTransfer.ptr, ptr, sz ); ptr += sz; } else { uint16_t sz; memcpy( &sz, ptr, sizeof( sz ) ); ptr += sizeof( sz ); switch( ev.hdr.type ) { case QueueType::CustomStringData: AddCustomString( ev.stringTransfer.ptr, ptr, sz ); break; case QueueType::StringData: AddString( ev.stringTransfer.ptr, ptr, sz ); m_serverQuerySpaceLeft++; break; case QueueType::ThreadName: AddThreadString( ev.stringTransfer.ptr, ptr, sz ); m_serverQuerySpaceLeft++; break; case QueueType::PlotName: HandlePlotName( ev.stringTransfer.ptr, ptr, sz ); m_serverQuerySpaceLeft++; break; case QueueType::SourceLocationPayload: AddSourceLocationPayload( ev.stringTransfer.ptr, ptr, sz ); break; case QueueType::CallstackPayload: AddCallstackPayload( ev.stringTransfer.ptr, ptr, sz ); break; case QueueType::FrameName: HandleFrameName( ev.stringTransfer.ptr, ptr, sz ); m_serverQuerySpaceLeft++; break; case QueueType::CallstackAllocPayload: AddCallstackAllocPayload( ev.stringTransfer.ptr, ptr, sz ); break; default: assert( false ); break; } ptr += sz; } return true; } else { ptr += QueueDataSize[ev.hdr.idx]; return Process( ev ); } } void Worker::CheckSourceLocation( uint64_t ptr ) { if( m_data.sourceLocation.find( ptr ) == m_data.sourceLocation.end() ) { NewSourceLocation( ptr ); } } void Worker::NewSourceLocation( uint64_t ptr ) { static const SourceLocation emptySourceLocation = {}; m_data.sourceLocation.emplace( ptr, emptySourceLocation ); m_pendingSourceLocation++; m_sourceLocationQueue.push_back( ptr ); Query( ServerQuerySourceLocation, ptr ); } uint32_t Worker::ShrinkSourceLocation( uint64_t srcloc ) { auto it = m_sourceLocationShrink.find( srcloc ); if( it != m_sourceLocationShrink.end() ) { return it->second; } else { return NewShrinkedSourceLocation( srcloc ); } } uint32_t Worker::NewShrinkedSourceLocation( uint64_t srcloc ) { const auto sz = int32_t( m_data.sourceLocationExpand.size() ); m_data.sourceLocationExpand.push_back( srcloc ); #ifndef TRACY_NO_STATISTICS m_data.sourceLocationZones.emplace( sz, SourceLocationZones() ); #else m_data.sourceLocationZonesCnt.emplace( sz, 0 ); #endif m_sourceLocationShrink.emplace( srcloc, sz ); return sz; } void Worker::InsertMessageData( MessageData* msg, uint64_t thread ) { if( m_data.messages.empty() ) { m_data.messages.push_back( msg ); } else if( m_data.messages.back()->time < msg->time ) { m_data.messages.push_back_non_empty( msg ); } else { auto mit = std::lower_bound( m_data.messages.begin(), m_data.messages.end(), msg->time, [] ( const auto& lhs, const auto& rhs ) { return lhs->time < rhs; } ); m_data.messages.insert( mit, msg ); } auto vec = &NoticeThread( thread )->messages; if( vec->empty() ) { vec->push_back( msg ); } else if( vec->back()->time < msg->time ) { vec->push_back_non_empty( msg ); } else { auto tmit = std::lower_bound( vec->begin(), vec->end(), msg->time, [] ( const auto& lhs, const auto& rhs ) { return lhs->time < rhs; } ); vec->insert( tmit, msg ); } } ThreadData* Worker::NoticeThread( uint64_t thread ) { auto it = m_threadMap.find( thread ); if( it != m_threadMap.end() ) { return it->second; } else { return NewThread( thread ); } } ThreadData* Worker::NewThread( uint64_t thread ) { CheckThreadString( thread ); auto td = m_slab.AllocInit(); td->id = thread; td->count = 0; td->nextZoneId = 0; m_data.threads.push_back( td ); m_threadMap.emplace( thread, td ); return td; } void Worker::NewZone( ZoneEvent* zone, uint64_t thread ) { m_data.zonesCnt++; #ifndef TRACY_NO_STATISTICS auto it = m_data.sourceLocationZones.find( zone->srcloc ); assert( it != m_data.sourceLocationZones.end() ); it->second.zones.push_back( ZoneThreadData { zone, CompressThread( thread ) } ); #else auto it = m_data.sourceLocationZonesCnt.find( zone->srcloc ); assert( it != m_data.sourceLocationZonesCnt.end() ); it->second++; #endif auto td = NoticeThread( thread ); td->count++; if( td->stack.empty() ) { td->stack.push_back( zone ); td->timeline.push_back( zone ); } else { auto back = td->stack.back(); if( back->child < 0 ) { back->child = int32_t( m_data.zoneChildren.size() ); if( m_data.zoneVectorCache.empty() ) { m_data.zoneChildren.push_back( Vector( zone ) ); } else { Vector vze = std::move( m_data.zoneVectorCache.back_and_pop() ); assert( !vze.empty() ); vze.clear(); vze.push_back_non_empty( zone ); m_data.zoneChildren.push_back( std::move( vze ) ); } } else { m_data.zoneChildren[back->child].push_back( zone ); } td->stack.push_back_non_empty( zone ); } td->zoneIdStack.push_back( td->nextZoneId ); td->nextZoneId = 0; } void Worker::InsertLockEvent( LockMap& lockmap, LockEvent* lev, uint64_t thread ) { const auto lt = lev->time; m_data.lastTime = std::max( m_data.lastTime, lt ); NoticeThread( thread ); auto it = lockmap.threadMap.find( thread ); if( it == lockmap.threadMap.end() ) { assert( lockmap.threadList.size() < MaxLockThreads ); it = lockmap.threadMap.emplace( thread, lockmap.threadList.size() ).first; lockmap.threadList.emplace_back( thread ); } lev->thread = it->second; assert( lev->thread == it->second ); auto& timeline = lockmap.timeline; if( timeline.empty() ) { timeline.push_back( { lev } ); UpdateLockCount( lockmap, timeline.size() - 1 ); } else if( timeline.back().ptr->time <= lt ) { timeline.push_back_non_empty( { lev } ); UpdateLockCount( lockmap, timeline.size() - 1 ); } else { auto it = std::upper_bound( timeline.begin(), timeline.end(), lt, [] ( const auto& lhs, const auto& rhs ) { return lhs < rhs.ptr->time; } ); it = timeline.insert( it, { lev } ); UpdateLockCount( lockmap, std::distance( timeline.begin(), it ) ); } auto& range = lockmap.range[it->second]; if( range.start > lt ) range.start = lt; if( range.end < lt ) range.end = lt; } void Worker::CheckString( uint64_t ptr ) { if( ptr == 0 ) return; if( m_data.strings.find( ptr ) != m_data.strings.end() ) return; m_data.strings.emplace( ptr, "???" ); m_pendingStrings++; Query( ServerQueryString, ptr ); } void Worker::CheckThreadString( uint64_t id ) { if( m_data.threadNames.find( id ) != m_data.threadNames.end() ) return; m_data.threadNames.emplace( id, "???" ); m_pendingThreads++; Query( ServerQueryThreadString, id ); } void Worker::AddSourceLocation( const QueueSourceLocation& srcloc ) { assert( m_pendingSourceLocation > 0 ); m_pendingSourceLocation--; const auto ptr = m_sourceLocationQueue.front(); m_sourceLocationQueue.erase( m_sourceLocationQueue.begin() ); auto it = m_data.sourceLocation.find( ptr ); assert( it != m_data.sourceLocation.end() ); CheckString( srcloc.name ); CheckString( srcloc.file ); CheckString( srcloc.function ); const uint32_t color = ( srcloc.r << 16 ) | ( srcloc.g << 8 ) | srcloc.b; it->second = SourceLocation { srcloc.name == 0 ? StringRef() : StringRef( StringRef::Ptr, srcloc.name ), StringRef( StringRef::Ptr, srcloc.function ), StringRef( StringRef::Ptr, srcloc.file ), srcloc.line, color }; } void Worker::AddSourceLocationPayload( uint64_t ptr, char* data, size_t sz ) { const auto start = data; assert( m_pendingSourceLocationPayload.find( ptr ) == m_pendingSourceLocationPayload.end() ); uint32_t color, line; memcpy( &color, data, 4 ); memcpy( &line, data + 4, 4 ); data += 8; auto end = data; while( *end ) end++; const auto func = StoreString( data, end - data ); end++; data = end; while( *end ) end++; const auto source = StoreString( data, end - data ); end++; const auto nsz = sz - ( end - start ); color = ( ( color & 0x00FF0000 ) >> 16 ) | ( ( color & 0x0000FF00 ) ) | ( ( color & 0x000000FF ) << 16 ); SourceLocation srcloc { nsz == 0 ? StringRef() : StringRef( StringRef::Idx, StoreString( end, nsz ).idx ), StringRef( StringRef::Idx, func.idx ), StringRef( StringRef::Idx, source.idx ), line, color }; auto it = m_data.sourceLocationPayloadMap.find( &srcloc ); if( it == m_data.sourceLocationPayloadMap.end() ) { auto slptr = m_slab.Alloc(); memcpy( slptr, &srcloc, sizeof( srcloc ) ); uint32_t idx = m_data.sourceLocationPayload.size(); m_data.sourceLocationPayloadMap.emplace( slptr, idx ); m_pendingSourceLocationPayload.emplace( ptr, -int32_t( idx + 1 ) ); m_data.sourceLocationPayload.push_back( slptr ); #ifndef TRACY_NO_STATISTICS m_data.sourceLocationZones.emplace( -int32_t( idx + 1 ), SourceLocationZones() ); #else m_data.sourceLocationZonesCnt.emplace( -int32_t( idx + 1 ), 0 ); #endif } else { m_pendingSourceLocationPayload.emplace( ptr, -int32_t( it->second + 1 ) ); } } void Worker::AddString( uint64_t ptr, char* str, size_t sz ) { assert( m_pendingStrings > 0 ); m_pendingStrings--; auto it = m_data.strings.find( ptr ); assert( it != m_data.strings.end() && strcmp( it->second, "???" ) == 0 ); const auto sl = StoreString( str, sz ); it->second = sl.ptr; } void Worker::AddThreadString( uint64_t id, char* str, size_t sz ) { assert( m_pendingThreads > 0 ); m_pendingThreads--; auto it = m_data.threadNames.find( id ); assert( it != m_data.threadNames.end() && strcmp( it->second, "???" ) == 0 ); const auto sl = StoreString( str, sz ); it->second = sl.ptr; } void Worker::AddCustomString( uint64_t ptr, char* str, size_t sz ) { assert( m_pendingCustomStrings.find( ptr ) == m_pendingCustomStrings.end() ); m_pendingCustomStrings.emplace( ptr, StoreString( str, sz ) ); } void Worker::AddFrameImageData( uint64_t ptr, char* data, size_t sz ) { assert( m_pendingFrameImageData.find( ptr ) == m_pendingFrameImageData.end() ); auto image = m_slab.AllocBig( sz ); memcpy( image, data, sz ); m_pendingFrameImageData.emplace( ptr, image ); } uint64_t Worker::GetCanonicalPointer( const CallstackFrameId& id ) const { assert( id.sel == 0 ); return ( id.idx & 0x7FFFFFFFFFFFFFFF ) | ( ( id.idx & 0x4000000000000000 ) << 1 ); } void Worker::AddCallstackPayload( uint64_t ptr, char* _data, size_t _sz ) { assert( m_pendingCallstackPtr == 0 ); const auto sz = _sz / sizeof( uint64_t ); const auto memsize = sizeof( VarArray ) + sz * sizeof( CallstackFrameId ); auto mem = (char*)m_slab.AllocRaw( memsize ); auto data = (CallstackFrameId*)mem; auto dst = data; auto src = (uint64_t*)_data; for( size_t i=0; i*)( mem + sz * sizeof( CallstackFrameId ) ); new(arr) VarArray( sz, data ); uint32_t idx; auto it = m_data.callstackMap.find( arr ); if( it == m_data.callstackMap.end() ) { idx = m_data.callstackPayload.size(); m_data.callstackMap.emplace( arr, idx ); m_data.callstackPayload.push_back( arr ); for( auto& frame : *arr ) { auto fit = m_data.callstackFrameMap.find( frame ); if( fit == m_data.callstackFrameMap.end() ) { m_pendingCallstackFrames++; Query( ServerQueryCallstackFrame, GetCanonicalPointer( frame ) ); } } } else { idx = it->second; m_slab.Unalloc( memsize ); } m_pendingCallstackPtr = ptr; m_pendingCallstackId = idx; } void Worker::AddCallstackAllocPayload( uint64_t ptr, char* data, size_t _sz ) { assert( m_pendingCallstackPtr != 0 ); CallstackFrameId stack[64]; const auto sz = *(uint32_t*)data; data += 4; assert( sz <= 64 ); for( uint32_t i=0; i(); memcpy( frame, &cf, sizeof( CallstackFrame ) ); auto frameData = m_slab.Alloc(); frameData->data = frame; frameData->size = 1; id.idx = m_callstackAllocNextIdx++; id.sel = 1; m_data.callstackFrameMap.emplace( id, frameData ); m_data.revFrameMap.emplace( frameData, id ); } else { id = it->second; } stack[i] = id; } const auto nativeCs = m_data.callstackPayload[m_pendingCallstackId]; const auto nsz = nativeCs->size(); const auto tsz = sz + nsz; const auto memsize = sizeof( VarArray ) + tsz * sizeof( CallstackFrameId ); auto mem = (char*)m_slab.AllocRaw( memsize ); memcpy( mem, stack, sizeof( CallstackFrameId ) * sz ); memcpy( mem + sizeof( CallstackFrameId ) * sz, nativeCs->data(), sizeof( CallstackFrameId ) * nsz ); auto arr = (VarArray*)( mem + tsz * sizeof( CallstackFrameId ) ); new(arr) VarArray( tsz, (CallstackFrameId*)mem ); uint32_t idx; auto it = m_data.callstackMap.find( arr ); if( it == m_data.callstackMap.end() ) { idx = m_data.callstackPayload.size(); m_data.callstackMap.emplace( arr, idx ); m_data.callstackPayload.push_back( arr ); for( auto& frame : *arr ) { auto fit = m_data.callstackFrameMap.find( frame ); if( fit == m_data.callstackFrameMap.end() ) { m_pendingCallstackFrames++; Query( ServerQueryCallstackFrame, GetCanonicalPointer( frame ) ); } } } else { idx = it->second; m_slab.Unalloc( memsize ); } m_pendingCallstackPtr = ptr; m_pendingCallstackId = idx; } void Worker::InsertPlot( PlotData* plot, int64_t time, double val ) { if( plot->data.empty() ) { plot->min = val; plot->max = val; plot->data.push_back( { time, val } ); } else if( plot->data.back().time < time ) { if( plot->min > val ) plot->min = val; else if( plot->max < val ) plot->max = val; plot->data.push_back_non_empty( { time, val } ); } else { if( plot->min > val ) plot->min = val; else if( plot->max < val ) plot->max = val; if( plot->postpone.empty() ) { plot->postponeTime = std::chrono::duration_cast( std::chrono::high_resolution_clock::now().time_since_epoch() ).count(); plot->postpone.push_back( { time, val } ); } else { plot->postpone.push_back_non_empty( { time, val } ); } } } void Worker::HandlePlotName( uint64_t name, char* str, size_t sz ) { const auto sl = StoreString( str, sz ); m_data.plots.StringDiscovered( name, sl, m_data.strings, [this] ( PlotData* dst, PlotData* src ) { for( auto& v : src->data ) { InsertPlot( dst, v.time, v.val ); } } ); } void Worker::HandleFrameName( uint64_t name, char* str, size_t sz ) { const auto sl = StoreString( str, sz ); m_data.frames.StringDiscovered( name, sl, m_data.strings, [] ( FrameData* dst, FrameData* src ) { auto sz = dst->frames.size(); dst->frames.insert( dst->frames.end(), src->frames.begin(), src->frames.end() ); std::inplace_merge( dst->frames.begin(), dst->frames.begin() + sz, dst->frames.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs.start < rhs.start; } ); } ); } void Worker::HandlePostponedPlots() { for( auto& plot : m_data.plots.Data() ) { auto& src = plot->postpone; if( src.empty() ) continue; if( std::chrono::duration_cast( std::chrono::high_resolution_clock::now().time_since_epoch() ).count() - plot->postponeTime < 100 ) continue; auto& dst = plot->data; #ifdef MY_LIBCPP_SUCKS pdqsort_branchless( src.begin(), src.end(), [] ( const auto& l, const auto& r ) { return l.time < r.time; } ); #else std::sort( std::execution::par_unseq, src.begin(), src.end(), [] ( const auto& l, const auto& r ) { return l.time < r.time; } ); #endif const auto ds = std::lower_bound( dst.begin(), dst.end(), src.front().time, [] ( const auto& l, const auto& r ) { return l.time < r; } ); const auto dsd = std::distance( dst.begin(), ds ) ; const auto de = std::lower_bound( ds, dst.end(), src.back().time, [] ( const auto& l, const auto& r ) { return l.time < r; } ); const auto ded = std::distance( dst.begin(), de ); dst.insert( de, src.begin(), src.end() ); std::inplace_merge( dst.begin() + dsd, dst.begin() + ded, dst.begin() + ded + src.size(), [] ( const auto& l, const auto& r ) { return l.time < r.time; } ); src.clear(); } } StringLocation Worker::StoreString( char* str, size_t sz ) { StringLocation ret; const char backup = str[sz]; str[sz] = '\0'; charutil::StringKey key = { str, sz }; auto sit = m_data.stringMap.find( key ); if( sit == m_data.stringMap.end() ) { auto ptr = m_slab.Alloc( sz+1 ); memcpy( ptr, str, sz ); ptr[sz] = '\0'; ret.ptr = ptr; ret.idx = m_data.stringData.size(); m_data.stringMap.emplace( charutil::StringKey { ptr, sz }, m_data.stringData.size() ); m_data.stringData.push_back( ptr ); } else { ret.ptr = sit->first.ptr; ret.idx = sit->second; } str[sz] = backup; return ret; } bool Worker::Process( const QueueItem& ev ) { switch( ev.hdr.type ) { case QueueType::ZoneBegin: ProcessZoneBegin( ev.zoneBegin ); break; case QueueType::ZoneBeginCallstack: ProcessZoneBeginCallstack( ev.zoneBegin ); break; case QueueType::ZoneBeginAllocSrcLoc: ProcessZoneBeginAllocSrcLoc( ev.zoneBegin ); break; case QueueType::ZoneBeginAllocSrcLocCallstack: ProcessZoneBeginAllocSrcLocCallstack( ev.zoneBegin ); break; case QueueType::ZoneEnd: ProcessZoneEnd( ev.zoneEnd ); break; case QueueType::ZoneValidation: ProcessZoneValidation( ev.zoneValidation ); break; case QueueType::FrameMarkMsg: ProcessFrameMark( ev.frameMark ); break; case QueueType::FrameMarkMsgStart: ProcessFrameMarkStart( ev.frameMark ); break; case QueueType::FrameMarkMsgEnd: ProcessFrameMarkEnd( ev.frameMark ); break; case QueueType::FrameImage: ProcessFrameImage( ev.frameImage ); break; case QueueType::SourceLocation: AddSourceLocation( ev.srcloc ); m_serverQuerySpaceLeft++; break; case QueueType::ZoneText: ProcessZoneText( ev.zoneText ); break; case QueueType::ZoneName: ProcessZoneName( ev.zoneText ); break; case QueueType::LockAnnounce: ProcessLockAnnounce( ev.lockAnnounce ); break; case QueueType::LockTerminate: ProcessLockTerminate( ev.lockTerminate ); break; case QueueType::LockWait: ProcessLockWait( ev.lockWait ); break; case QueueType::LockObtain: ProcessLockObtain( ev.lockObtain ); break; case QueueType::LockRelease: ProcessLockRelease( ev.lockRelease ); break; case QueueType::LockSharedWait: ProcessLockSharedWait( ev.lockWait ); break; case QueueType::LockSharedObtain: ProcessLockSharedObtain( ev.lockObtain ); break; case QueueType::LockSharedRelease: ProcessLockSharedRelease( ev.lockRelease ); break; case QueueType::LockMark: ProcessLockMark( ev.lockMark ); break; case QueueType::PlotData: ProcessPlotData( ev.plotData ); break; case QueueType::Message: ProcessMessage( ev.message ); break; case QueueType::MessageLiteral: ProcessMessageLiteral( ev.message ); break; case QueueType::MessageColor: ProcessMessageColor( ev.messageColor ); break; case QueueType::MessageLiteralColor: ProcessMessageLiteralColor( ev.messageColor ); break; case QueueType::GpuNewContext: ProcessGpuNewContext( ev.gpuNewContext ); break; case QueueType::GpuZoneBegin: ProcessGpuZoneBegin( ev.gpuZoneBegin ); break; case QueueType::GpuZoneBeginCallstack: ProcessGpuZoneBeginCallstack( ev.gpuZoneBegin ); break; case QueueType::GpuZoneEnd: ProcessGpuZoneEnd( ev.gpuZoneEnd ); break; case QueueType::GpuTime: ProcessGpuTime( ev.gpuTime ); break; case QueueType::MemAlloc: ProcessMemAlloc( ev.memAlloc ); break; case QueueType::MemFree: ProcessMemFree( ev.memFree ); break; case QueueType::MemAllocCallstack: ProcessMemAllocCallstack( ev.memAlloc ); break; case QueueType::MemFreeCallstack: ProcessMemFreeCallstack( ev.memFree ); break; case QueueType::CallstackMemory: ProcessCallstackMemory( ev.callstackMemory ); break; case QueueType::Callstack: ProcessCallstack( ev.callstack ); break; case QueueType::CallstackAlloc: ProcessCallstackAlloc( ev.callstackAlloc ); break; case QueueType::CallstackFrameSize: ProcessCallstackFrameSize( ev.callstackFrameSize ); m_serverQuerySpaceLeft++; break; case QueueType::CallstackFrame: ProcessCallstackFrame( ev.callstackFrame ); break; case QueueType::Terminate: m_terminate = true; break; case QueueType::KeepAlive: break; case QueueType::Crash: m_crashed = true; break; case QueueType::CrashReport: ProcessCrashReport( ev.crashReport ); break; case QueueType::SysTimeReport: ProcessSysTime( ev.sysTime ); break; default: assert( false ); break; } return m_failure == Failure::None; } void Worker::ProcessZoneBeginImpl( ZoneEvent* zone, const QueueZoneBegin& ev ) { CheckSourceLocation( ev.srcloc ); zone->start = TscTime( ev.time ); zone->end = -1; zone->srcloc = ShrinkSourceLocation( ev.srcloc ); assert( ev.cpu == 0xFFFFFFFF || ev.cpu <= std::numeric_limits::max() ); zone->cpu_start = ev.cpu == 0xFFFFFFFF ? -1 : (int8_t)ev.cpu; zone->callstack = 0; zone->child = -1; m_data.lastTime = std::max( m_data.lastTime, zone->start ); NewZone( zone, ev.thread ); } void Worker::ProcessZoneBegin( const QueueZoneBegin& ev ) { auto zone = m_slab.AllocInit(); ProcessZoneBeginImpl( zone, ev ); } void Worker::ProcessZoneBeginCallstack( const QueueZoneBegin& ev ) { auto zone = m_slab.AllocInit(); ProcessZoneBeginImpl( zone, ev ); auto& next = m_nextCallstack[ev.thread]; next.type = NextCallstackType::Zone; next.zone = zone; } void Worker::ProcessZoneBeginAllocSrcLocImpl( ZoneEvent* zone, const QueueZoneBegin& ev ) { auto it = m_pendingSourceLocationPayload.find( ev.srcloc ); assert( it != m_pendingSourceLocationPayload.end() ); zone->start = TscTime( ev.time ); zone->end = -1; zone->srcloc = it->second; assert( ev.cpu == 0xFFFFFFFF || ev.cpu <= std::numeric_limits::max() ); zone->cpu_start = ev.cpu == 0xFFFFFFFF ? -1 : (int8_t)ev.cpu; zone->callstack = 0; zone->child = -1; m_data.lastTime = std::max( m_data.lastTime, zone->start ); NewZone( zone, ev.thread ); m_pendingSourceLocationPayload.erase( it ); } void Worker::ProcessZoneBeginAllocSrcLoc( const QueueZoneBegin& ev ) { auto zone = m_slab.AllocInit(); ProcessZoneBeginAllocSrcLocImpl( zone, ev ); } void Worker::ProcessZoneBeginAllocSrcLocCallstack( const QueueZoneBegin& ev ) { auto zone = m_slab.AllocInit(); ProcessZoneBeginAllocSrcLocImpl( zone, ev ); auto& next = m_nextCallstack[ev.thread]; next.type = NextCallstackType::Zone; next.zone = zone; } void Worker::ProcessZoneEnd( const QueueZoneEnd& ev ) { auto tit = m_threadMap.find( ev.thread ); if( tit == m_threadMap.end() || tit->second->zoneIdStack.empty() ) { ZoneEndFailure( ev.thread ); return; } auto td = tit->second; auto zoneId = td->zoneIdStack.back_and_pop(); if( zoneId != td->nextZoneId ) { ZoneStackFailure( ev.thread, td->stack.back() ); return; } td->nextZoneId = 0; auto& stack = td->stack; assert( !stack.empty() ); auto zone = stack.back_and_pop(); assert( zone->end == -1 ); zone->end = TscTime( ev.time ); assert( ev.cpu == 0xFFFFFFFF || ev.cpu <= std::numeric_limits::max() ); zone->cpu_end = ev.cpu == 0xFFFFFFFF ? -1 : (int8_t)ev.cpu; assert( zone->end >= zone->start ); m_data.lastTime = std::max( m_data.lastTime, zone->end ); if( zone->child >= 0 ) { auto& childVec = m_data.zoneChildren[zone->child]; const auto sz = childVec.size(); if( sz <= 8 * 1024 ) { Vector fitVec; fitVec.reserve_exact( sz, m_slab ); memcpy( fitVec.data(), childVec.data(), sz * sizeof( ZoneEvent* ) ); fitVec.swap( childVec ); m_data.zoneVectorCache.push_back( std::move( fitVec ) ); } } #ifndef TRACY_NO_STATISTICS auto timeSpan = zone->end - zone->start; if( timeSpan > 0 ) { auto it = m_data.sourceLocationZones.find( zone->srcloc ); assert( it != m_data.sourceLocationZones.end() ); auto& slz = it->second; slz.min = std::min( slz.min, timeSpan ); slz.max = std::max( slz.max, timeSpan ); slz.total += timeSpan; slz.sumSq += double( timeSpan ) * timeSpan; if( zone->child >= 0 ) { for( auto& v : GetZoneChildren( zone->child ) ) { const auto childSpan = std::max( int64_t( 0 ), v->end - v->start ); timeSpan -= childSpan; } } slz.selfMin = std::min( slz.selfMin, timeSpan ); slz.selfMax = std::max( slz.selfMax, timeSpan ); slz.selfTotal += timeSpan; } #endif } void Worker::ZoneStackFailure( uint64_t thread, const ZoneEvent* ev ) { m_failure = Failure::ZoneStack; m_failureData.thread = thread; m_failureData.srcloc = ev->srcloc; } void Worker::ZoneEndFailure( uint64_t thread ) { m_failure = Failure::ZoneEnd; m_failureData.thread = thread; m_failureData.srcloc = 0; } void Worker::ZoneTextFailure( uint64_t thread ) { m_failure = Failure::ZoneText; m_failureData.thread = thread; m_failureData.srcloc = 0; } void Worker::ZoneNameFailure( uint64_t thread ) { m_failure = Failure::ZoneName; m_failureData.thread = thread; m_failureData.srcloc = 0; } void Worker::MemFreeFailure( uint64_t thread ) { m_failure = Failure::MemFree; m_failureData.thread = thread; m_failureData.srcloc = 0; } void Worker::FrameEndFailure() { m_failure = Failure::ZoneEnd; m_failureData.thread = 0; m_failureData.srcloc = 0; } void Worker::FrameImageIndexFailure() { m_failure = Failure::FrameImageIndex; m_failureData.thread = 0; m_failureData.srcloc = 0; } void Worker::FrameImageTwiceFailure() { m_failure = Failure::FrameImageTwice; m_failureData.thread = 0; m_failureData.srcloc = 0; } void Worker::ProcessZoneValidation( const QueueZoneValidation& ev ) { auto td = NoticeThread( ev.thread ); td->nextZoneId = ev.id; } void Worker::ProcessFrameMark( const QueueFrameMark& ev ) { auto fd = m_data.frames.Retrieve( ev.name, [this] ( uint64_t name ) { auto fd = m_slab.AllocInit(); fd->name = name; fd->continuous = 1; return fd; }, [this] ( uint64_t name ) { Query( ServerQueryFrameName, name ); } ); assert( fd->continuous == 1 ); const auto time = TscTime( ev.time ); assert( fd->frames.empty() || fd->frames.back().start <= time ); fd->frames.push_back( FrameEvent{ time, -1, -1 } ); m_data.lastTime = std::max( m_data.lastTime, time ); } void Worker::ProcessFrameMarkStart( const QueueFrameMark& ev ) { auto fd = m_data.frames.Retrieve( ev.name, [this] ( uint64_t name ) { auto fd = m_slab.AllocInit(); fd->name = name; fd->continuous = 0; return fd; }, [this] ( uint64_t name ) { Query( ServerQueryFrameName, name ); } ); assert( fd->continuous == 0 ); const auto time = TscTime( ev.time ); assert( fd->frames.empty() || ( fd->frames.back().end <= time && fd->frames.back().end != -1 ) ); fd->frames.push_back( FrameEvent{ time, -1, -1 } ); m_data.lastTime = std::max( m_data.lastTime, time ); } void Worker::ProcessFrameMarkEnd( const QueueFrameMark& ev ) { auto fd = m_data.frames.Retrieve( ev.name, [this] ( uint64_t name ) { auto fd = m_slab.AllocInit(); fd->name = name; fd->continuous = 0; return fd; }, [this] ( uint64_t name ) { Query( ServerQueryFrameName, name ); } ); assert( fd->continuous == 0 ); const auto time = TscTime( ev.time ); if( fd->frames.empty() ) { FrameEndFailure(); return; } assert( fd->frames.back().end == -1 ); fd->frames.back().end = time; m_data.lastTime = std::max( m_data.lastTime, time ); } void Worker::ProcessFrameImage( const QueueFrameImage& ev ) { auto it = m_pendingFrameImageData.find( ev.image ); assert( it != m_pendingFrameImageData.end() ); auto& frames = m_data.framesBase->frames; const auto fidx = (int64_t)frames.size() - 1 - ev.offset; if( m_onDemand && fidx <= 1 ) { m_pendingFrameImageData.erase( it ); return; } else if( fidx <= 0 ) { FrameImageIndexFailure(); return; } if( frames[fidx].frameImage >= 0 ) { FrameImageTwiceFailure(); return; } auto fi = m_slab.Alloc(); fi->ptr = PackFrameImage( (const char*)it->second, ev.w, ev.h, fi->csz ); fi->w = ev.w; fi->h = ev.h; fi->frameRef = fidx; fi->flip = ev.flip; const auto idx = m_data.frameImage.size(); m_data.frameImage.push_back( fi ); frames[fidx].frameImage = idx; m_pendingFrameImageData.erase( it ); } void Worker::ProcessZoneText( const QueueZoneText& ev ) { auto tit = m_threadMap.find( ev.thread ); if( tit == m_threadMap.end() || tit->second->stack.empty() || tit->second->nextZoneId != tit->second->zoneIdStack.back() ) { ZoneTextFailure( ev.thread ); return; } auto td = tit->second; td->nextZoneId = 0; auto& stack = td->stack; auto zone = stack.back(); auto it = m_pendingCustomStrings.find( ev.text ); assert( it != m_pendingCustomStrings.end() ); zone->text = StringIdx( it->second.idx ); m_pendingCustomStrings.erase( it ); } void Worker::ProcessZoneName( const QueueZoneText& ev ) { auto tit = m_threadMap.find( ev.thread ); if( tit == m_threadMap.end() || tit->second->stack.empty() || tit->second->nextZoneId != tit->second->zoneIdStack.back() ) { ZoneNameFailure( ev.thread ); return; } auto td = tit->second; td->nextZoneId = 0; auto& stack = td->stack; auto zone = stack.back(); auto it = m_pendingCustomStrings.find( ev.text ); assert( it != m_pendingCustomStrings.end() ); zone->name = StringIdx( it->second.idx ); m_pendingCustomStrings.erase( it ); } void Worker::ProcessLockAnnounce( const QueueLockAnnounce& ev ) { auto it = m_data.lockMap.find( ev.id ); if( it == m_data.lockMap.end() ) { auto lm = m_slab.AllocInit(); lm->srcloc = ShrinkSourceLocation( ev.lckloc ); lm->type = ev.type; lm->timeAnnounce = TscTime( ev.time ); lm->timeTerminate = 0; lm->valid = true; lm->isContended = false; m_data.lockMap.emplace( ev.id, lm ); } else { it->second->srcloc = ShrinkSourceLocation( ev.lckloc ); assert( it->second->type == ev.type ); it->second->timeAnnounce = TscTime( ev.time ); it->second->valid = true; } CheckSourceLocation( ev.lckloc ); } void Worker::ProcessLockTerminate( const QueueLockTerminate& ev ) { auto it = m_data.lockMap.find( ev.id ); if( it == m_data.lockMap.end() ) { auto lm = m_slab.AllocInit(); lm->type = ev.type; lm->timeAnnounce = 0; lm->timeTerminate = TscTime( ev.time ); lm->valid = false; lm->isContended = false; m_data.lockMap.emplace( ev.id, lm ); } else { assert( it->second->type == ev.type ); it->second->timeTerminate = TscTime( ev.time ); } } void Worker::ProcessLockWait( const QueueLockWait& ev ) { auto it = m_data.lockMap.find( ev.id ); if( it == m_data.lockMap.end() ) { auto lm = m_slab.AllocInit(); lm->timeAnnounce = 0; lm->timeTerminate = 0; lm->valid = false; lm->type = ev.type; lm->isContended = false; it = m_data.lockMap.emplace( ev.id, lm ).first; } auto lev = ev.type == LockType::Lockable ? m_slab.Alloc() : m_slab.Alloc(); lev->time = TscTime( ev.time ); lev->type = LockEvent::Type::Wait; lev->srcloc = 0; InsertLockEvent( *it->second, lev, ev.thread ); } void Worker::ProcessLockObtain( const QueueLockObtain& ev ) { auto it = m_data.lockMap.find( ev.id ); assert( it != m_data.lockMap.end() ); auto& lock = *it->second; auto lev = lock.type == LockType::Lockable ? m_slab.Alloc() : m_slab.Alloc(); lev->time = TscTime( ev.time ); lev->type = LockEvent::Type::Obtain; lev->srcloc = 0; InsertLockEvent( lock, lev, ev.thread ); } void Worker::ProcessLockRelease( const QueueLockRelease& ev ) { auto it = m_data.lockMap.find( ev.id ); assert( it != m_data.lockMap.end() ); auto& lock = *it->second; auto lev = lock.type == LockType::Lockable ? m_slab.Alloc() : m_slab.Alloc(); lev->time = TscTime( ev.time ); lev->type = LockEvent::Type::Release; lev->srcloc = 0; InsertLockEvent( lock, lev, ev.thread ); } void Worker::ProcessLockSharedWait( const QueueLockWait& ev ) { auto it = m_data.lockMap.find( ev.id ); if( it == m_data.lockMap.end() ) { auto lm = m_slab.AllocInit(); lm->valid = false; lm->type = ev.type; lm->isContended = false; it = m_data.lockMap.emplace( ev.id, lm ).first; } assert( ev.type == LockType::SharedLockable ); auto lev = m_slab.Alloc(); lev->time = TscTime( ev.time ); lev->type = LockEvent::Type::WaitShared; lev->srcloc = 0; InsertLockEvent( *it->second, lev, ev.thread ); } void Worker::ProcessLockSharedObtain( const QueueLockObtain& ev ) { auto it = m_data.lockMap.find( ev.id ); assert( it != m_data.lockMap.end() ); auto& lock = *it->second; assert( lock.type == LockType::SharedLockable ); auto lev = m_slab.Alloc(); lev->time = TscTime( ev.time ); lev->type = LockEvent::Type::ObtainShared; lev->srcloc = 0; InsertLockEvent( lock, lev, ev.thread ); } void Worker::ProcessLockSharedRelease( const QueueLockRelease& ev ) { auto it = m_data.lockMap.find( ev.id ); assert( it != m_data.lockMap.end() ); auto& lock = *it->second; assert( lock.type == LockType::SharedLockable ); auto lev = m_slab.Alloc(); lev->time = TscTime( ev.time ); lev->type = LockEvent::Type::ReleaseShared; lev->srcloc = 0; InsertLockEvent( lock, lev, ev.thread ); } void Worker::ProcessLockMark( const QueueLockMark& ev ) { CheckSourceLocation( ev.srcloc ); auto lit = m_data.lockMap.find( ev.id ); assert( lit != m_data.lockMap.end() ); auto& lockmap = *lit->second; auto tid = lockmap.threadMap.find( ev.thread ); assert( tid != lockmap.threadMap.end() ); const auto thread = tid->second; auto it = lockmap.timeline.end(); for(;;) { --it; if( it->ptr->thread == thread ) { switch( it->ptr->type ) { case LockEvent::Type::Obtain: case LockEvent::Type::ObtainShared: case LockEvent::Type::Wait: case LockEvent::Type::WaitShared: it->ptr->srcloc = ShrinkSourceLocation( ev.srcloc ); return; default: break; } } } } void Worker::ProcessPlotData( const QueuePlotData& ev ) { PlotData* plot = m_data.plots.Retrieve( ev.name, [this] ( uint64_t name ) { auto plot = m_slab.AllocInit(); plot->name = name; plot->type = PlotType::User; return plot; }, [this]( uint64_t name ) { Query( ServerQueryPlotName, name ); } ); const auto time = TscTime( ev.time ); m_data.lastTime = std::max( m_data.lastTime, time ); switch( ev.type ) { case PlotDataType::Double: InsertPlot( plot, time, ev.data.d ); break; case PlotDataType::Float: InsertPlot( plot, time, (double)ev.data.f ); break; case PlotDataType::Int: InsertPlot( plot, time, (double)ev.data.i ); break; default: assert( false ); break; } } void Worker::ProcessMessage( const QueueMessage& ev ) { auto it = m_pendingCustomStrings.find( ev.text ); assert( it != m_pendingCustomStrings.end() ); auto msg = m_slab.Alloc(); msg->time = TscTime( ev.time ); msg->ref = StringRef( StringRef::Type::Idx, it->second.idx ); msg->thread = ev.thread; msg->color = 0xFFFFFFFF; m_data.lastTime = std::max( m_data.lastTime, msg->time ); InsertMessageData( msg, ev.thread ); m_pendingCustomStrings.erase( it ); } void Worker::ProcessMessageLiteral( const QueueMessage& ev ) { CheckString( ev.text ); auto msg = m_slab.Alloc(); msg->time = TscTime( ev.time ); msg->ref = StringRef( StringRef::Type::Ptr, ev.text ); msg->thread = ev.thread; msg->color = 0xFFFFFFFF; m_data.lastTime = std::max( m_data.lastTime, msg->time ); InsertMessageData( msg, ev.thread ); } void Worker::ProcessMessageColor( const QueueMessageColor& ev ) { auto it = m_pendingCustomStrings.find( ev.text ); assert( it != m_pendingCustomStrings.end() ); auto msg = m_slab.Alloc(); msg->time = TscTime( ev.time ); msg->ref = StringRef( StringRef::Type::Idx, it->second.idx ); msg->thread = ev.thread; msg->color = 0xFF000000 | ( ev.r << 16 ) | ( ev.g << 8 ) | ev.b; m_data.lastTime = std::max( m_data.lastTime, msg->time ); InsertMessageData( msg, ev.thread ); m_pendingCustomStrings.erase( it ); } void Worker::ProcessMessageLiteralColor( const QueueMessageColor& ev ) { CheckString( ev.text ); auto msg = m_slab.Alloc(); msg->time = TscTime( ev.time ); msg->ref = StringRef( StringRef::Type::Ptr, ev.text ); msg->thread = ev.thread; msg->color = 0xFF000000 | ( ev.r << 16 ) | ( ev.g << 8 ) | ev.b; m_data.lastTime = std::max( m_data.lastTime, msg->time ); InsertMessageData( msg, ev.thread ); } void Worker::ProcessGpuNewContext( const QueueGpuNewContext& ev ) { assert( !m_gpuCtxMap[ev.context] ); int64_t gpuTime; if( ev.period == 1.f ) { gpuTime = ev.gpuTime; } else { gpuTime = int64_t( double( ev.period ) * ev.gpuTime ); // precision loss } auto gpu = m_slab.AllocInit(); memset( gpu->query, 0, sizeof( gpu->query ) ); gpu->timeDiff = TscTime( ev.cpuTime ) - gpuTime; gpu->thread = ev.thread; gpu->accuracyBits = ev.accuracyBits; gpu->period = ev.period; gpu->count = 0; m_data.gpuData.push_back( gpu ); m_gpuCtxMap[ev.context] = gpu; } void Worker::ProcessGpuZoneBeginImpl( GpuEvent* zone, const QueueGpuZoneBegin& ev ) { auto ctx = m_gpuCtxMap[ev.context]; assert( ctx ); CheckSourceLocation( ev.srcloc ); zone->cpuStart = TscTime( ev.cpuTime ); zone->cpuEnd = -1; zone->gpuStart = std::numeric_limits::max(); zone->gpuEnd = -1; zone->srcloc = ShrinkSourceLocation( ev.srcloc ); zone->callstack = 0; zone->child = -1; if( ctx->thread == 0 ) { // Vulkan context is not bound to any single thread. zone->thread = CompressThread( ev.thread ); } else { // OpenGL doesn't need per-zone thread id. It still can be sent, // because it may be needed for callstack collection purposes. zone->thread = 0; } m_data.lastTime = std::max( m_data.lastTime, zone->cpuStart ); auto timeline = &ctx->timeline; if( !ctx->stack.empty() ) { auto back = ctx->stack.back(); if( back->child < 0 ) { back->child = int32_t( m_data.gpuChildren.size() ); m_data.gpuChildren.push_back( Vector() ); } timeline = &m_data.gpuChildren[back->child]; } timeline->push_back( zone ); ctx->stack.push_back( zone ); assert( !ctx->query[ev.queryId] ); ctx->query[ev.queryId] = zone; } void Worker::ProcessGpuZoneBegin( const QueueGpuZoneBegin& ev ) { auto zone = m_slab.Alloc(); ProcessGpuZoneBeginImpl( zone, ev ); } void Worker::ProcessGpuZoneBeginCallstack( const QueueGpuZoneBegin& ev ) { auto zone = m_slab.Alloc(); ProcessGpuZoneBeginImpl( zone, ev ); auto& next = m_nextCallstack[ev.thread]; next.type = NextCallstackType::Gpu; next.gpu = zone; } void Worker::ProcessGpuZoneEnd( const QueueGpuZoneEnd& ev ) { auto ctx = m_gpuCtxMap[ev.context]; assert( ctx ); assert( !ctx->stack.empty() ); auto zone = ctx->stack.back_and_pop(); assert( !ctx->query[ev.queryId] ); ctx->query[ev.queryId] = zone; zone->cpuEnd = TscTime( ev.cpuTime ); m_data.lastTime = std::max( m_data.lastTime, zone->cpuEnd ); } void Worker::ProcessGpuTime( const QueueGpuTime& ev ) { auto ctx = m_gpuCtxMap[ev.context]; assert( ctx ); int64_t gpuTime; if( ctx->period == 1.f ) { gpuTime = ev.gpuTime; } else { gpuTime = int64_t( double( ctx->period ) * ev.gpuTime ); // precision loss } auto zone = ctx->query[ev.queryId]; assert( zone ); ctx->query[ev.queryId] = nullptr; if( zone->gpuStart == std::numeric_limits::max() ) { zone->gpuStart = ctx->timeDiff + gpuTime; m_data.lastTime = std::max( m_data.lastTime, zone->gpuStart ); ctx->count++; } else { zone->gpuEnd = ctx->timeDiff + gpuTime; m_data.lastTime = std::max( m_data.lastTime, zone->gpuEnd ); if( zone->gpuEnd < zone->gpuStart ) { std::swap( zone->gpuEnd, zone->gpuStart ); } } } void Worker::ProcessMemAlloc( const QueueMemAlloc& ev ) { const auto time = TscTime( ev.time ); m_data.lastTime = std::max( m_data.lastTime, time ); NoticeThread( ev.thread ); assert( m_data.memory.active.find( ev.ptr ) == m_data.memory.active.end() ); assert( m_data.memory.data.empty() || m_data.memory.data.back().timeAlloc <= time ); m_data.memory.active.emplace( ev.ptr, m_data.memory.data.size() ); const auto ptr = ev.ptr; uint32_t lo; uint16_t hi; memcpy( &lo, ev.size, 4 ); memcpy( &hi, ev.size+4, 2 ); const uint64_t size = lo | ( uint64_t( hi ) << 32 ); auto& mem = m_data.memory.data.push_next(); mem.ptr = ptr; mem.size = size; mem.timeAlloc = time; mem.threadAlloc = CompressThread( ev.thread ); mem.timeFree = -1; mem.threadFree = 0; mem.csAlloc = 0; mem.csFree = 0; const auto low = m_data.memory.low; const auto high = m_data.memory.high; const auto ptrend = ptr + size; m_data.memory.low = std::min( low, ptr ); m_data.memory.high = std::max( high, ptrend ); m_data.memory.usage += size; MemAllocChanged( time ); } bool Worker::ProcessMemFree( const QueueMemFree& ev ) { if( ev.ptr == 0 ) return false; auto it = m_data.memory.active.find( ev.ptr ); if( it == m_data.memory.active.end() ) { if( !m_onDemand ) { MemFreeFailure( ev.thread ); } return false; } const auto time = TscTime( ev.time ); m_data.lastTime = std::max( m_data.lastTime, time ); NoticeThread( ev.thread ); m_data.memory.frees.push_back( it->second ); auto& mem = m_data.memory.data[it->second]; mem.timeFree = time; mem.threadFree = CompressThread( ev.thread ); m_data.memory.usage -= mem.size; m_data.memory.active.erase( it ); MemAllocChanged( time ); return true; } void Worker::ProcessMemAllocCallstack( const QueueMemAlloc& ev ) { m_lastMemActionCallstack = m_data.memory.data.size(); ProcessMemAlloc( ev ); m_lastMemActionWasAlloc = true; } void Worker::ProcessMemFreeCallstack( const QueueMemFree& ev ) { if( ProcessMemFree( ev ) ) { m_lastMemActionCallstack = m_data.memory.frees.back(); m_lastMemActionWasAlloc = false; } else { m_lastMemActionCallstack = std::numeric_limits::max(); } } void Worker::ProcessCallstackMemory( const QueueCallstackMemory& ev ) { assert( m_pendingCallstackPtr == ev.ptr ); m_pendingCallstackPtr = 0; if( m_lastMemActionCallstack != std::numeric_limits::max() ) { auto& mem = m_data.memory.data[m_lastMemActionCallstack]; if( m_lastMemActionWasAlloc ) { mem.csAlloc = m_pendingCallstackId; } else { mem.csFree = m_pendingCallstackId; } } } void Worker::ProcessCallstack( const QueueCallstack& ev ) { assert( m_pendingCallstackPtr == ev.ptr ); m_pendingCallstackPtr = 0; auto nit = m_nextCallstack.find( ev.thread ); assert( nit != m_nextCallstack.end() ); auto& next = nit->second; switch( next.type ) { case NextCallstackType::Zone: next.zone->callstack = m_pendingCallstackId; break; case NextCallstackType::Gpu: next.gpu->callstack = m_pendingCallstackId; break; case NextCallstackType::Crash: m_data.crashEvent.callstack = m_pendingCallstackId; break; default: assert( false ); break; } } void Worker::ProcessCallstackAlloc( const QueueCallstackAlloc& ev ) { assert( m_pendingCallstackPtr == ev.ptr ); m_pendingCallstackPtr = 0; auto nit = m_nextCallstack.find( ev.thread ); assert( nit != m_nextCallstack.end() ); auto& next = nit->second; switch( next.type ) { case NextCallstackType::Zone: next.zone->callstack = m_pendingCallstackId; break; case NextCallstackType::Gpu: next.gpu->callstack = m_pendingCallstackId; break; case NextCallstackType::Crash: m_data.crashEvent.callstack = m_pendingCallstackId; break; default: assert( false ); break; } } void Worker::ProcessCallstackFrameSize( const QueueCallstackFrameSize& ev ) { assert( !m_callstackFrameStaging ); assert( m_pendingCallstackSubframes == 0 ); assert( m_pendingCallstackFrames > 0 ); m_pendingCallstackFrames--; m_pendingCallstackSubframes = ev.size; // Frames may be duplicated due to recursion auto fmit = m_data.callstackFrameMap.find( PackPointer( ev.ptr ) ); if( fmit == m_data.callstackFrameMap.end() ) { m_callstackFrameStaging = m_slab.Alloc(); m_callstackFrameStaging->size = ev.size; m_callstackFrameStaging->data = m_slab.Alloc( ev.size ); m_callstackFrameStagingPtr = ev.ptr; } } void Worker::ProcessCallstackFrame( const QueueCallstackFrame& ev ) { assert( m_pendingCallstackSubframes > 0 ); auto nit = m_pendingCustomStrings.find( ev.name ); assert( nit != m_pendingCustomStrings.end() ); auto fit = m_pendingCustomStrings.find( ev.file ); assert( fit != m_pendingCustomStrings.end() ); if( m_callstackFrameStaging ) { const auto idx = m_callstackFrameStaging->size - m_pendingCallstackSubframes; m_callstackFrameStaging->data[idx].name = StringIdx( nit->second.idx ); m_callstackFrameStaging->data[idx].file = StringIdx( fit->second.idx ); m_callstackFrameStaging->data[idx].line = ev.line; if( --m_pendingCallstackSubframes == 0 ) { assert( m_data.callstackFrameMap.find( PackPointer( m_callstackFrameStagingPtr ) ) == m_data.callstackFrameMap.end() ); m_data.callstackFrameMap.emplace( PackPointer( m_callstackFrameStagingPtr ), m_callstackFrameStaging ); m_callstackFrameStaging = nullptr; } } else { m_pendingCallstackSubframes--; } m_pendingCustomStrings.erase( nit ); m_pendingCustomStrings.erase( m_pendingCustomStrings.find( ev.file ) ); } void Worker::ProcessCrashReport( const QueueCrashReport& ev ) { CheckString( ev.text ); auto& next = m_nextCallstack[ev.thread]; next.type = NextCallstackType::Crash; m_data.crashEvent.thread = ev.thread; m_data.crashEvent.time = TscTime( ev.time ); m_data.crashEvent.message = ev.text; m_data.crashEvent.callstack = 0; } void Worker::ProcessSysTime( const QueueSysTime& ev ) { const auto time = TscTime( ev.time ); m_data.lastTime = std::max( m_data.lastTime, time ); const auto val = ev.sysTime; if( !m_sysTimePlot ) { m_sysTimePlot = m_slab.AllocInit(); m_sysTimePlot->name = 0; m_sysTimePlot->type = PlotType::SysTime; m_sysTimePlot->min = val; m_sysTimePlot->max = val; m_sysTimePlot->data.push_back( { time, val } ); m_data.plots.Data().push_back( m_sysTimePlot ); } else { assert( !m_sysTimePlot->data.empty() ); assert( m_sysTimePlot->data.back().time <= time ); if( m_sysTimePlot->min > val ) m_sysTimePlot->min = val; else if( m_sysTimePlot->max < val ) m_sysTimePlot->max = val; m_sysTimePlot->data.push_back_non_empty( { time, val } ); } } void Worker::MemAllocChanged( int64_t time ) { const auto val = (double)m_data.memory.usage; if( !m_data.memory.plot ) { CreateMemAllocPlot(); m_data.memory.plot->min = val; m_data.memory.plot->max = val; m_data.memory.plot->data.push_back( { time, val } ); } else { assert( !m_data.memory.plot->data.empty() ); assert( m_data.memory.plot->data.back().time <= time ); if( m_data.memory.plot->min > val ) m_data.memory.plot->min = val; else if( m_data.memory.plot->max < val ) m_data.memory.plot->max = val; m_data.memory.plot->data.push_back_non_empty( { time, val } ); } } void Worker::CreateMemAllocPlot() { assert( !m_data.memory.plot ); m_data.memory.plot = m_slab.AllocInit(); m_data.memory.plot->name = 0; m_data.memory.plot->type = PlotType::Memory; m_data.memory.plot->data.push_back( { GetFrameBegin( *m_data.framesBase, 0 ), 0. } ); m_data.plots.Data().push_back( m_data.memory.plot ); } void Worker::ReconstructMemAllocPlot() { auto& mem = m_data.memory; #ifdef MY_LIBCPP_SUCKS pdqsort_branchless( mem.frees.begin(), mem.frees.end(), [&mem] ( const auto& lhs, const auto& rhs ) { return mem.data[lhs].timeFree < mem.data[rhs].timeFree; } ); #else std::sort( std::execution::par_unseq, mem.frees.begin(), mem.frees.end(), [&mem] ( const auto& lhs, const auto& rhs ) { return mem.data[lhs].timeFree < mem.data[rhs].timeFree; } ); #endif const auto psz = mem.data.size() + mem.frees.size() + 1; PlotData* plot; { std::lock_guard lock( m_data.lock ); plot = m_slab.AllocInit(); } plot->name = 0; plot->type = PlotType::Memory; plot->data.reserve_exact( psz, m_slab ); auto aptr = mem.data.begin(); auto aend = mem.data.end(); auto fptr = mem.frees.begin(); auto fend = mem.frees.end(); double max = 0; double usage = 0; auto ptr = plot->data.data(); ptr->time = GetFrameBegin( *m_data.framesBase, 0 ); ptr->val = 0; ptr++; if( aptr != aend && fptr != fend ) { auto atime = aptr->timeAlloc; auto ftime = mem.data[*fptr].timeFree; for(;;) { if( atime < ftime ) { usage += int64_t( aptr->size ); assert( usage >= 0 ); if( max < usage ) max = usage; ptr->time = atime; ptr->val = usage; ptr++; aptr++; if( aptr == aend ) break; atime = aptr->timeAlloc; } else { usage -= int64_t( mem.data[*fptr].size ); assert( usage >= 0 ); if( max < usage ) max = usage; ptr->time = ftime; ptr->val = usage; ptr++; fptr++; if( fptr == fend ) break; ftime = mem.data[*fptr].timeFree; } } } while( aptr != aend ) { assert( aptr->timeFree < 0 ); int64_t time = aptr->timeAlloc; usage += int64_t( aptr->size ); assert( usage >= 0 ); if( max < usage ) max = usage; ptr->time = time; ptr->val = usage; ptr++; aptr++; } while( fptr != fend ) { const auto& memData = mem.data[*fptr]; int64_t time = memData.timeFree; usage -= int64_t( memData.size ); assert( usage >= 0 ); assert( max >= usage ); ptr->time = time; ptr->val = usage; ptr++; fptr++; } plot->min = 0; plot->max = max; std::lock_guard lock( m_data.lock ); m_data.plots.Data().insert( m_data.plots.Data().begin(), plot ); m_data.memory.plot = plot; } void Worker::ReadTimeline( FileRead& f, ZoneEvent* zone, uint16_t thread, int64_t& refTime ) { uint64_t sz; f.Read( sz ); if( sz == 0 ) { zone->child = -1; } else { zone->child = m_data.zoneChildren.size(); // Put placeholder to have proper size of zone children in nested calls m_data.zoneChildren.push_back( Vector() ); // Real data buffer. Can't use placeholder, as the vector can be reallocated // and the buffer address will change, but the reference won't. Vector tmp; ReadTimeline( f, tmp, thread, sz, refTime ); m_data.zoneChildren[zone->child] = std::move( tmp ); } } void Worker::ReadTimelinePre042( FileRead& f, ZoneEvent* zone, uint16_t thread, int fileVer ) { uint64_t sz; f.Read( sz ); if( sz == 0 ) { zone->child = -1; } else { zone->child = m_data.zoneChildren.size(); m_data.zoneChildren.push_back( Vector() ); Vector tmp; ReadTimelinePre042( f, tmp, thread, sz, fileVer ); m_data.zoneChildren[zone->child] = std::move( tmp ); } } void Worker::ReadTimeline( FileRead& f, GpuEvent* zone, int64_t& refTime, int64_t& refGpuTime ) { uint64_t sz; f.Read( sz ); if( sz == 0 ) { zone->child = -1; } else { zone->child = m_data.gpuChildren.size(); m_data.gpuChildren.push_back( Vector() ); Vector tmp; ReadTimeline( f, tmp, sz, refTime, refGpuTime ); m_data.gpuChildren[zone->child] = std::move( tmp ); } } void Worker::ReadTimelinePre044( FileRead& f, GpuEvent* zone, int64_t& refTime, int64_t& refGpuTime, int fileVer ) { uint64_t sz; f.Read( sz ); if( sz == 0 ) { zone->child = -1; } else { zone->child = m_data.gpuChildren.size(); m_data.gpuChildren.push_back( Vector() ); Vector tmp; ReadTimelinePre044( f, tmp, sz, refTime, refGpuTime, fileVer ); m_data.gpuChildren[zone->child] = std::move( tmp ); } } void Worker::ReadTimelineUpdateStatistics( ZoneEvent* zone, uint16_t thread ) { #ifndef TRACY_NO_STATISTICS auto it = m_data.sourceLocationZones.find( zone->srcloc ); assert( it != m_data.sourceLocationZones.end() ); auto& slz = it->second; auto& ztd = slz.zones.push_next(); ztd.zone = zone; ztd.thread = thread; if( zone->end >= 0 ) { auto timeSpan = zone->end - zone->start; if( timeSpan > 0 ) { slz.min = std::min( slz.min, timeSpan ); slz.max = std::max( slz.max, timeSpan ); slz.total += timeSpan; slz.sumSq += double( timeSpan ) * timeSpan; if( zone->child >= 0 ) { for( auto& v : GetZoneChildren( zone->child ) ) { const auto childSpan = std::max( int64_t( 0 ), v->end - v->start ); timeSpan -= childSpan; } } slz.selfMin = std::min( slz.selfMin, timeSpan ); slz.selfMax = std::max( slz.selfMax, timeSpan ); slz.selfTotal += timeSpan; } } #else auto it = m_data.sourceLocationZonesCnt.find( zone->srcloc ); assert( it != m_data.sourceLocationZonesCnt.end() ); it->second++; #endif } void Worker::ReadTimeline( FileRead& f, Vector& vec, uint16_t thread, uint64_t size, int64_t& refTime ) { assert( size != 0 ); vec.reserve_exact( size, m_slab ); m_data.zonesCnt += size; auto zone = (ZoneEvent*)m_slab.AllocBig( sizeof( ZoneEvent ) * size ); auto zptr = zone; auto vptr = vec.data(); for( uint64_t i=0; iend as scratch buffer for zone start time offset. f.Read( &zone->end, sizeof( zone->end ) + sizeof( zone->srcloc ) + sizeof( zone->cpu_start ) + sizeof( zone->cpu_end ) + sizeof( zone->text ) + sizeof( zone->callstack ) + sizeof( zone->name ) ); refTime += zone->end; zone->start = refTime; ReadTimeline( f, zone, thread, refTime ); zone->end = ReadTimeOffset( f, refTime ); #ifdef TRACY_NO_STATISTICS ReadTimelineUpdateStatistics( zone, thread ); #endif } while( ++zone != zptr ); } void Worker::ReadTimelinePre042( FileRead& f, Vector& vec, uint16_t thread, uint64_t size, int fileVer ) { assert( size != 0 ); vec.reserve_exact( size, m_slab ); m_data.zonesCnt += size; for( uint64_t i=0; i(); vec[i] = zone; if( fileVer <= FileVersion( 0, 3, 1 ) ) { f.Read( zone, 26 ); zone->callstack = 0; zone->name.__data = 0; } else if( fileVer <= FileVersion( 0, 3, 2 ) ) { f.Read( zone, 30 ); zone->name.__data = 0; } else { assert( fileVer <= FileVersion( 0, 4, 1 ) ); f.Read( zone, sizeof( ZoneEvent ) - sizeof( ZoneEvent::child ) ); } ReadTimelinePre042( f, zone, thread, fileVer ); #ifdef TRACY_NO_STATISTICS ReadTimelineUpdateStatistics( zone, thread ); #endif } } void Worker::ReadTimeline( FileRead& f, Vector& vec, uint64_t size, int64_t& refTime, int64_t& refGpuTime ) { assert( size != 0 ); vec.reserve_exact( size, m_slab ); auto zone = (GpuEvent*)m_slab.AllocBig( sizeof( GpuEvent ) * size ); auto zptr = zone; auto vptr = vec.data(); for( uint64_t i=0; igpuStart as scratch buffer for CPU zone start time offset. // Use zone->gpuEnd as scratch buffer for GPU zone start time offset. f.Read( &zone->gpuStart, sizeof( zone->gpuStart ) + sizeof( zone->gpuEnd ) + sizeof( zone->srcloc ) + sizeof( zone->callstack ) + sizeof( zone->thread ) ); refTime += zone->gpuStart; refGpuTime += zone->gpuEnd; zone->cpuStart = refTime; zone->gpuStart = refGpuTime; ReadTimeline( f, zone, refTime, refGpuTime ); zone->cpuEnd = ReadTimeOffset( f, refTime ); zone->gpuEnd = ReadTimeOffset( f, refGpuTime ); } while( ++zone != zptr ); } void Worker::ReadTimelinePre044( FileRead& f, Vector& vec, uint64_t size, int64_t& refTime, int64_t& refGpuTime, int fileVer ) { assert( size != 0 ); vec.reserve_exact( size, m_slab ); for( uint64_t i=0; i(); vec[i] = zone; if( fileVer <= FileVersion( 0, 3, 1 ) ) { f.Read( zone, 36 ); zone->thread = 0; zone->callstack = 0; } else if( fileVer <= FileVersion( 0, 4, 1 ) ) { f.Read( zone, sizeof( GpuEvent::cpuStart ) + sizeof( GpuEvent::cpuEnd ) + sizeof( GpuEvent::gpuStart ) + sizeof( GpuEvent::gpuEnd ) + sizeof( GpuEvent::srcloc ) + sizeof( GpuEvent::callstack ) ); uint64_t thread; f.Read( thread ); if( thread == 0 ) { zone->thread = 0; } else { zone->thread = CompressThread( thread ); } } else { assert( fileVer <= FileVersion( 0, 4, 3 ) ); f.Read( &zone->gpuStart, sizeof( zone->gpuStart ) + sizeof( zone->gpuEnd ) + sizeof( zone->srcloc ) + sizeof( zone->callstack ) ); refTime += zone->gpuStart; refGpuTime += zone->gpuEnd; zone->cpuStart = refTime; zone->gpuStart = refGpuTime; uint64_t thread; f.Read( thread ); if( thread == 0 ) { zone->thread = 0; } else { zone->thread = CompressThread( thread ); } } ReadTimelinePre044( f, zone, refTime, refGpuTime, fileVer ); if( fileVer > FileVersion( 0, 4, 1 ) ) { assert( fileVer <= FileVersion( 0, 4, 3 ) ); zone->cpuEnd = ReadTimeOffset( f, refTime ); zone->gpuEnd = ReadTimeOffset( f, refGpuTime ); } } } void Worker::Write( FileWrite& f ) { f.Write( FileHeader, sizeof( FileHeader ) ); f.Write( &m_delay, sizeof( m_delay ) ); f.Write( &m_resolution, sizeof( m_resolution ) ); f.Write( &m_timerMul, sizeof( m_timerMul ) ); f.Write( &m_data.lastTime, sizeof( m_data.lastTime ) ); f.Write( &m_data.frameOffset, sizeof( m_data.frameOffset ) ); uint64_t sz = m_captureName.size(); f.Write( &sz, sizeof( sz ) ); f.Write( m_captureName.c_str(), sz ); sz = m_captureProgram.size(); f.Write( &sz, sizeof( sz ) ); f.Write( m_captureProgram.c_str(), sz ); f.Write( &m_captureTime, sizeof( m_captureTime ) ); sz = m_hostInfo.size(); f.Write( &sz, sizeof( sz ) ); f.Write( m_hostInfo.c_str(), sz ); f.Write( &m_data.crashEvent, sizeof( m_data.crashEvent ) ); sz = m_data.frames.Data().size(); f.Write( &sz, sizeof( sz ) ); for( auto& fd : m_data.frames.Data() ) { int64_t refTime = 0; f.Write( &fd->name, sizeof( fd->name ) ); f.Write( &fd->continuous, sizeof( fd->continuous ) ); sz = fd->frames.size(); f.Write( &sz, sizeof( sz ) ); if( fd->continuous ) { for( auto& fe : fd->frames ) { WriteTimeOffset( f, refTime, fe.start ); f.Write( &fe.frameImage, sizeof( fe.frameImage ) ); } } else { for( auto& fe : fd->frames ) { WriteTimeOffset( f, refTime, fe.start ); WriteTimeOffset( f, refTime, fe.end ); f.Write( &fe.frameImage, sizeof( fe.frameImage ) ); } } } sz = m_data.stringData.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.stringData ) { uint64_t ptr = (uint64_t)v; f.Write( &ptr, sizeof( ptr ) ); sz = strlen( v ); f.Write( &sz, sizeof( sz ) ); f.Write( v, sz ); } sz = m_data.strings.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.strings ) { f.Write( &v.first, sizeof( v.first ) ); uint64_t ptr = (uint64_t)v.second; f.Write( &ptr, sizeof( ptr ) ); } sz = m_data.threadNames.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.threadNames ) { f.Write( &v.first, sizeof( v.first ) ); uint64_t ptr = (uint64_t)v.second; f.Write( &ptr, sizeof( ptr ) ); } sz = m_data.threadExpand.size(); f.Write( &sz, sizeof( sz ) ); f.Write( m_data.threadExpand.data(), sz * sizeof( uint64_t ) ); sz = m_data.sourceLocation.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.sourceLocation ) { f.Write( &v.first, sizeof( v.first ) ); f.Write( &v.second, sizeof( v.second ) ); } sz = m_data.sourceLocationExpand.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.sourceLocationExpand ) { f.Write( &v, sizeof( v ) ); } sz = m_data.sourceLocationPayload.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.sourceLocationPayload ) { f.Write( v, sizeof( *v ) ); } #ifndef TRACY_NO_STATISTICS sz = m_data.sourceLocationZones.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.sourceLocationZones ) { int32_t id = v.first; uint64_t cnt = v.second.zones.size(); f.Write( &id, sizeof( id ) ); f.Write( &cnt, sizeof( cnt ) ); } #else sz = m_data.sourceLocationZonesCnt.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.sourceLocationZonesCnt ) { int32_t id = v.first; uint64_t cnt = v.second; f.Write( &id, sizeof( id ) ); f.Write( &cnt, sizeof( cnt ) ); } #endif sz = m_data.lockMap.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.lockMap ) { f.Write( &v.first, sizeof( v.first ) ); f.Write( &v.second->srcloc, sizeof( v.second->srcloc ) ); f.Write( &v.second->type, sizeof( v.second->type ) ); f.Write( &v.second->valid, sizeof( v.second->valid ) ); f.Write( &v.second->timeAnnounce, sizeof( v.second->timeAnnounce ) ); f.Write( &v.second->timeTerminate, sizeof( v.second->timeTerminate ) ); sz = v.second->threadList.size(); f.Write( &sz, sizeof( sz ) ); for( auto& t : v.second->threadList ) { f.Write( &t, sizeof( t ) ); } int64_t refTime = v.second->timeAnnounce; sz = v.second->timeline.size(); f.Write( &sz, sizeof( sz ) ); for( auto& lev : v.second->timeline ) { WriteTimeOffset( f, refTime, lev.ptr->time ); f.Write( &lev.ptr->srcloc, sizeof( lev.ptr->srcloc ) ); f.Write( &lev.ptr->thread, sizeof( lev.ptr->thread ) ); f.Write( &lev.ptr->type, sizeof( lev.ptr->type ) ); } } { int64_t refTime = 0; sz = m_data.messages.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : m_data.messages ) { const auto ptr = (uint64_t)v; f.Write( &ptr, sizeof( ptr ) ); WriteTimeOffset( f, refTime, v->time ); f.Write( &v->ref, sizeof( v->ref ) ); f.Write( &v->color, sizeof( v->color ) ); } } sz = 0; for( auto& v : m_data.threads ) sz += v->count; f.Write( &sz, sizeof( sz ) ); sz = m_data.threads.size(); f.Write( &sz, sizeof( sz ) ); for( auto& thread : m_data.threads ) { int64_t refTime = 0; f.Write( &thread->id, sizeof( thread->id ) ); f.Write( &thread->count, sizeof( thread->count ) ); WriteTimeline( f, thread->timeline, refTime ); sz = thread->messages.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : thread->messages ) { auto ptr = uint64_t( v ); f.Write( &ptr, sizeof( ptr ) ); } } sz = 0; for( auto& v : m_data.gpuData ) sz += v->count; f.Write( &sz, sizeof( sz ) ); sz = m_data.gpuData.size(); f.Write( &sz, sizeof( sz ) ); for( auto& ctx : m_data.gpuData ) { int64_t refTime = 0; int64_t refGpuTime = 0; f.Write( &ctx->thread, sizeof( ctx->thread ) ); f.Write( &ctx->accuracyBits, sizeof( ctx->accuracyBits ) ); f.Write( &ctx->count, sizeof( ctx->count ) ); f.Write( &ctx->period, sizeof( ctx->period ) ); WriteTimeline( f, ctx->timeline, refTime, refGpuTime ); } sz = m_data.plots.Data().size(); for( auto& plot : m_data.plots.Data() ) { if( plot->type == PlotType::Memory ) sz--; } f.Write( &sz, sizeof( sz ) ); for( auto& plot : m_data.plots.Data() ) { if( plot->type == PlotType::Memory ) continue; f.Write( &plot->type, sizeof( plot->type ) ); f.Write( &plot->name, sizeof( plot->name ) ); f.Write( &plot->min, sizeof( plot->min ) ); f.Write( &plot->max, sizeof( plot->max ) ); int64_t refTime = 0; sz = plot->data.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : plot->data ) { WriteTimeOffset( f, refTime, v.time ); f.Write( &v.val, sizeof( v.val ) ); } } { int64_t refTime = 0; sz = m_data.memory.data.size(); f.Write( &sz, sizeof( sz ) ); sz = m_data.memory.active.size(); f.Write( &sz, sizeof( sz ) ); sz = m_data.memory.frees.size(); f.Write( &sz, sizeof( sz ) ); for( auto& mem : m_data.memory.data ) { f.Write( &mem.ptr, sizeof( mem.ptr ) ); f.Write( &mem.size, sizeof( mem.size ) ); WriteTimeOffset( f, refTime, mem.timeAlloc ); int64_t freeOffset = mem.timeFree < 0 ? mem.timeFree : mem.timeFree - mem.timeAlloc; f.Write( &freeOffset, sizeof( freeOffset ) ); f.Write( &mem.csAlloc, sizeof( mem.csAlloc ) ); f.Write( &mem.csFree, sizeof( mem.csFree ) ); f.Write( &mem.threadAlloc, sizeof( mem.threadAlloc ) ); f.Write( &mem.threadFree, sizeof( mem.threadFree ) ); } f.Write( &m_data.memory.high, sizeof( m_data.memory.high ) ); f.Write( &m_data.memory.low, sizeof( m_data.memory.low ) ); f.Write( &m_data.memory.usage, sizeof( m_data.memory.usage ) ); } sz = m_data.callstackPayload.size() - 1; f.Write( &sz, sizeof( sz ) ); for( size_t i=1; i<=sz; i++ ) { auto cs = m_data.callstackPayload[i]; uint8_t csz = cs->size(); f.Write( &csz, sizeof( csz ) ); f.Write( cs->data(), sizeof( CallstackFrameId ) * csz ); } sz = m_data.callstackFrameMap.size(); f.Write( &sz, sizeof( sz ) ); for( auto& frame : m_data.callstackFrameMap ) { f.Write( &frame.first, sizeof( CallstackFrameId ) ); f.Write( &frame.second->size, sizeof( frame.second->size ) ); f.Write( frame.second->data, sizeof( CallstackFrame ) * frame.second->size ); } sz = m_data.frameImage.size(); f.Write( &sz, sizeof( sz ) ); for( auto& fi : m_data.frameImage ) { f.Write( &fi->w, sizeof( fi->w ) ); f.Write( &fi->h, sizeof( fi->h ) ); f.Write( &fi->flip, sizeof( fi->flip ) ); const auto image = UnpackFrameImage( *fi ); f.Write( image, fi->w * fi->h / 2 ); } } void Worker::WriteTimeline( FileWrite& f, const Vector& vec, int64_t& refTime ) { uint64_t sz = vec.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : vec ) { WriteTimeOffset( f, refTime, v->start ); f.Write( &v->srcloc, sizeof( v->srcloc ) ); f.Write( &v->cpu_start, sizeof( v->cpu_start ) ); f.Write( &v->cpu_end, sizeof( v->cpu_end ) ); f.Write( &v->text, sizeof( v->text ) ); f.Write( &v->callstack, sizeof( v->callstack ) ); f.Write( &v->name, sizeof( v->name ) ); if( v->child < 0 ) { sz = 0; f.Write( &sz, sizeof( sz ) ); } else { WriteTimeline( f, GetZoneChildren( v->child ), refTime ); } WriteTimeOffset( f, refTime, v->end ); } } void Worker::WriteTimeline( FileWrite& f, const Vector& vec, int64_t& refTime, int64_t& refGpuTime ) { uint64_t sz = vec.size(); f.Write( &sz, sizeof( sz ) ); for( auto& v : vec ) { WriteTimeOffset( f, refTime, v->cpuStart ); WriteTimeOffset( f, refGpuTime, v->gpuStart ); f.Write( &v->srcloc, sizeof( v->srcloc ) ); f.Write( &v->callstack, sizeof( v->callstack ) ); f.Write( &v->thread, sizeof( v->thread ) ); if( v->child < 0 ) { sz = 0; f.Write( &sz, sizeof( sz ) ); } else { WriteTimeline( f, GetGpuChildren( v->child ), refTime, refGpuTime ); } WriteTimeOffset( f, refTime, v->cpuEnd ); WriteTimeOffset( f, refGpuTime, v->gpuEnd ); } } static const char* s_failureReasons[] = { "", "Invalid order of zone begin and end events.", "Received zone end event without a matching zone begin event.", "Zone text transfer destination doesn't match active zone.", "Zone name transfer destination doesn't match active zone.", "Memory free event without a matching allocation.", "Discontinuous frame begin/end mismatch.", "Frame image offset is invalid.", "Multiple frame images were sent for a single frame.", }; static_assert( sizeof( s_failureReasons ) / sizeof( *s_failureReasons ) == (int)Worker::Failure::NUM_FAILURES, "Missing failure reason description." ); const char* Worker::GetFailureString( Worker::Failure failure ) { return s_failureReasons[(int)failure]; } const char* Worker::PackFrameImage( const char* image, uint16_t w, uint16_t h, uint32_t& csz ) { const auto insz = size_t( w ) * size_t( h ) / 2; const auto maxout = LZ4_COMPRESSBOUND( insz ); if( m_frameImageBufferSize < maxout ) { m_frameImageBufferSize = maxout; delete[] m_frameImageBuffer; m_frameImageBuffer = new char[maxout]; } const auto outsz = LZ4_compress_default( image, m_frameImageBuffer, insz, maxout ); csz = uint32_t( outsz ); auto ptr = (char*)m_slab.AllocBig( outsz ); memcpy( ptr, m_frameImageBuffer, outsz ); return ptr; } const char* Worker::UnpackFrameImage( const FrameImage& image ) { const auto outsz = size_t( image.w ) * size_t( image.h ) / 2; if( m_frameImageBufferSize < outsz ) { m_frameImageBufferSize = outsz; delete[] m_frameImageBuffer; m_frameImageBuffer = new char[outsz]; } LZ4_decompress_safe( image.ptr, m_frameImageBuffer, image.csz, outsz ); return m_frameImageBuffer; } }