#ifdef _MSC_VER # include #else # include #endif #include #include #include #include #include "../common/TracyProtocol.hpp" #include "../common/TracySystem.hpp" #include "../common/TracyQueue.hpp" #include "TracyImGui.hpp" #include "TracyView.hpp" namespace tracy { static View* s_instance = nullptr; View::View( const char* addr ) : m_addr( addr ) , m_shutdown( false ) , m_connected( false ) , m_hasData( false ) , m_mbps( 64 ) , m_stream( LZ4_createStreamDecode() ) , m_buffer( new char[TargetFrameSize*3] ) , m_bufferOffset( 0 ) , m_frameScale( 0 ) , m_pause( false ) , m_frameStart( 0 ) , m_zvStart( 0 ) , m_zvEnd( 0 ) { assert( s_instance == nullptr ); s_instance = this; ImGuiStyle& style = ImGui::GetStyle(); style.FrameRounding = 2.f; m_thread = std::thread( [this] { Worker(); } ); SetThreadName( m_thread, "Tracy View" ); } View::~View() { m_shutdown.store( true, std::memory_order_relaxed ); m_thread.join(); delete[] m_buffer; LZ4_freeStreamDecode( m_stream ); assert( s_instance != nullptr ); s_instance = nullptr; } bool View::ShouldExit() { return s_instance->m_shutdown.load( std::memory_order_relaxed ); } void View::Worker() { timeval tv; tv.tv_sec = 0; tv.tv_usec = 10000; for(;;) { if( m_shutdown.load( std::memory_order_relaxed ) ) return; if( !m_sock.Connect( m_addr.c_str(), "8086" ) ) continue; std::chrono::time_point t0; uint8_t lz4; uint64_t bytes = 0; uint64_t timeStart; if( !m_sock.Read( &timeStart, sizeof( timeStart ), &tv, ShouldExit ) ) goto close; if( !m_sock.Read( &lz4, sizeof( lz4 ), &tv, ShouldExit ) ) goto close; m_frames.push_back( timeStart ); 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 ) ) return; if( lz4 ) { auto buf = m_buffer + m_bufferOffset; char lz4buf[LZ4Size]; lz4sz_t lz4sz; if( !m_sock.Read( &lz4sz, sizeof( lz4sz ), &tv, ShouldExit ) ) goto close; if( !m_sock.Read( lz4buf, lz4sz, &tv, ShouldExit ) ) goto close; bytes += sizeof( lz4sz ) + lz4sz; auto sz = LZ4_decompress_safe_continue( m_stream, lz4buf, buf, lz4sz, TargetFrameSize ); assert( sz >= 0 ); const char* ptr = buf; const char* end = buf + sz; while( ptr < end ) { auto ev = (QueueItem*)ptr; DispatchProcess( *ev, ptr ); } m_bufferOffset += sz; if( m_bufferOffset > TargetFrameSize * 2 ) m_bufferOffset = 0; } else { QueueItem ev; if( !m_sock.Read( &ev.hdr, sizeof( QueueHeader ), &tv, ShouldExit ) ) goto close; const auto payload = QueueDataSize[ev.hdr.idx] - sizeof( QueueHeader ); if( payload > 0 ) { if( !m_sock.Read( ((char*)&ev) + sizeof( QueueHeader ), payload, &tv, ShouldExit ) ) goto close; } bytes += sizeof( QueueHeader ) + payload; // ignores string transfer DispatchProcess( ev ); } 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_mbpslock ); m_mbps.erase( m_mbps.begin() ); m_mbps.emplace_back( bytes / ( td * 125.f ) ); t0 = t1; bytes = 0; } } close: m_sock.Close(); m_connected.store( false, std::memory_order_relaxed ); } } void View::DispatchProcess( const QueueItem& ev ) { if( ev.hdr.type == QueueType::StringData || ev.hdr.type == QueueType::ThreadName ) { timeval tv; tv.tv_sec = 0; tv.tv_usec = 10000; char buf[TargetFrameSize]; uint16_t sz; m_sock.Read( &sz, sizeof( sz ), &tv, ShouldExit ); m_sock.Read( buf, sz, &tv, ShouldExit ); if( ev.hdr.type == QueueType::StringData ) { AddString( ev.hdr.id, std::string( buf, buf+sz ) ); } else { AddThreadString( ev.hdr.id, std::string( buf, buf+sz ) ); } } else { Process( ev ); } } void View::DispatchProcess( const QueueItem& ev, const char*& ptr ) { ptr += QueueDataSize[ev.hdr.idx]; if( ev.hdr.type == QueueType::StringData || ev.hdr.type == QueueType::ThreadName ) { uint16_t sz; memcpy( &sz, ptr, sizeof( sz ) ); ptr += sizeof( sz ); if( ev.hdr.type == QueueType::StringData ) { AddString( ev.hdr.id, std::string( ptr, ptr+sz ) ); } else { AddThreadString( ev.hdr.id, std::string( ptr, ptr+sz ) ); } ptr += sz; } else { Process( ev ); } } void View::Process( const QueueItem& ev ) { switch( ev.hdr.type ) { case QueueType::ZoneBegin: ProcessZoneBegin( ev.hdr.id, ev.zoneBegin ); break; case QueueType::ZoneEnd: ProcessZoneEnd( ev.hdr.id, ev.zoneEnd ); break; case QueueType::FrameMark: ProcessFrameMark( ev.hdr.id ); break; default: assert( false ); break; } } void View::ProcessZoneBegin( uint64_t id, const QueueZoneBegin& ev ) { auto it = m_pendingEndZone.find( id ); auto zone = m_slab.Alloc(); CheckString( ev.filename ); CheckString( ev.function ); CheckThreadString( ev.thread ); zone->start = ev.time; SourceLocation srcloc { ev.filename, ev.function, ev.line }; auto lit = m_locationRef.find( srcloc ); std::unique_lock lock( m_lock ); if( lit == m_locationRef.end() ) { const auto ref = uint32_t( m_srcFile.size() ); zone->srcloc = ref; m_locationRef.emplace( srcloc, ref ); m_srcFile.push_back( srcloc ); } else { zone->srcloc = lit->second; } if( it == m_pendingEndZone.end() ) { zone->end = -1; NewZone( zone, ev.thread ); lock.unlock(); m_openZones.emplace( id, zone ); } else { assert( ev.time <= it->second.time ); zone->end = it->second.time; NewZone( zone, ev.thread ); lock.unlock(); m_pendingEndZone.erase( it ); } } void View::ProcessZoneEnd( uint64_t id, const QueueZoneEnd& ev ) { auto it = m_openZones.find( id ); if( it == m_openZones.end() ) { m_pendingEndZone.emplace( id, ev ); } else { auto zone = it->second; std::unique_lock lock( m_lock ); assert( ev.time >= zone->start ); zone->end = ev.time; UpdateZone( zone ); lock.unlock(); m_openZones.erase( it ); } } void View::ProcessFrameMark( uint64_t id ) { assert( !m_frames.empty() ); const auto lastframe = m_frames.back(); if( lastframe < id ) { std::unique_lock lock( m_lock ); m_frames.push_back( id ); } else { auto it = std::lower_bound( m_frames.begin(), m_frames.end(), id ); std::unique_lock lock( m_lock ); m_frames.insert( it, id ); } } void View::CheckString( uint64_t ptr ) { if( m_strings.find( ptr ) != m_strings.end() ) return; if( m_pendingStrings.find( ptr ) != m_pendingStrings.end() ) return; m_pendingStrings.emplace( ptr ); uint8_t type = ServerQueryString; m_sock.Send( &type, sizeof( type ) ); m_sock.Send( &ptr, sizeof( ptr ) ); } void View::CheckThreadString( uint64_t id ) { if( m_threadNames.find( id ) != m_threadNames.end() ) return; if( m_pendingThreads.find( id ) != m_pendingThreads.end() ) return; m_pendingThreads.emplace( id ); uint8_t type = ServerQueryThreadString; m_sock.Send( &type, sizeof( type ) ); m_sock.Send( &id, sizeof( id ) ); } void View::AddString( uint64_t ptr, std::string&& str ) { assert( m_strings.find( ptr ) == m_strings.end() ); auto it = m_pendingStrings.find( ptr ); assert( it != m_pendingStrings.end() ); m_pendingStrings.erase( it ); std::lock_guard lock( m_lock ); m_strings.emplace( ptr, std::move( str ) ); } void View::AddThreadString( uint64_t id, std::string&& str ) { assert( m_threadNames.find( id ) == m_threadNames.end() ); auto it = m_pendingThreads.find( id ); assert( it != m_pendingThreads.end() ); m_pendingThreads.erase( it ); std::lock_guard lock( m_lock ); m_threadNames.emplace( id, std::move( str ) ); } void View::NewZone( Event* zone, uint64_t thread ) { Vector* timeline; auto it = m_threadMap.find( thread ); if( it == m_threadMap.end() ) { m_threadMap.emplace( thread, m_threads.size() ); m_threads.emplace_back( ThreadData { thread } ); timeline = &m_threads.back().timeline; } else { timeline = &m_threads[it->second].timeline; } if( !timeline->empty() ) { const auto lastend = timeline->back()->end; if( lastend != -1 && lastend < zone->start ) { timeline->push_back( zone ); } else { } } else { timeline->push_back( zone ); } } void View::UpdateZone( Event* zone ) { assert( zone->end != -1 ); } uint64_t View::GetFrameTime( size_t idx ) const { if( idx < m_frames.size() - 1 ) { return m_frames[idx+1] - m_frames[idx]; } else { const auto last = GetLastTime(); return last == 0 ? 0 : last - m_frames.back(); } } uint64_t View::GetFrameBegin( size_t idx ) const { assert( idx < m_frames.size() ); return m_frames[idx]; } uint64_t View::GetFrameEnd( size_t idx ) const { if( idx < m_frames.size() - 1 ) { return m_frames[idx+1]; } else { return GetLastTime(); } } uint64_t View::GetLastTime() const { uint64_t last = 0; if( !m_frames.empty() ) last = m_frames.back(); for( auto& v : m_threads ) { if( !v.timeline.empty() ) { auto ev = v.timeline.back(); if( ev->end > (int64_t)last ) last = ev->end; } } return last; } const char* View::TimeToString( uint64_t ns ) const { enum { Pool = 4 }; static char bufpool[Pool][64]; static int bufsel = 0; char* buf = bufpool[bufsel]; bufsel = ( bufsel + 1 ) % Pool; if( ns < 1000 ) { sprintf( buf, "%i ns", ns ); } else if( ns < 1000ull * 1000 ) { sprintf( buf, "%.2f us", ns / 1000. ); } else if( ns < 1000ull * 1000 * 1000 ) { sprintf( buf, "%.2f ms", ns / ( 1000. * 1000. ) ); } else if( ns < 1000ull * 1000 * 1000 * 60 ) { sprintf( buf, "%.2f s", ns / ( 1000. * 1000. * 1000. ) ); } else { const auto m = ns / ( 1000ull * 1000 * 1000 * 60 ); const auto s = ns - m * ( 1000ull * 1000 * 1000 * 60 ); sprintf( buf, "%i:%04.1f", m, s / ( 1000. * 1000. * 1000. ) ); } return buf; } const char* View::GetString( uint64_t ptr ) const { const auto it = m_strings.find( ptr ); if( it == m_strings.end() ) { return "???"; } else { return it->second.c_str(); } } const char* View::GetThreadString( uint64_t id ) const { const auto it = m_threadNames.find( id ); if( it == m_threadNames.end() ) { return "???"; } else { return it->second.c_str(); } } void View::Draw() { s_instance->DrawImpl(); } void View::DrawImpl() { if( !m_hasData.load( std::memory_order_acquire ) ) { ImGui::Begin( m_addr.c_str(), nullptr, ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_ShowBorders ); ImGui::Text( "Waiting for connection..." ); ImGui::End(); return; } // Connection window ImGui::Begin( m_addr.c_str(), nullptr, ImGuiWindowFlags_AlwaysAutoResize | ImGuiWindowFlags_ShowBorders ); { std::lock_guard lock( m_mbpslock ); const auto mbps = m_mbps.back(); char buf[64]; if( mbps < 0.1f ) { sprintf( buf, "%6.2f Kbps", mbps * 1000.f ); } else { sprintf( buf, "%6.2f Mbps", mbps ); } ImGui::Dummy( ImVec2( 10, 0 ) ); ImGui::SameLine(); ImGui::PlotLines( buf, m_mbps.data(), m_mbps.size(), 0, nullptr, 0, std::numeric_limits::max(), ImVec2( 150, 0 ) ); } ImGui::Text( "Memory usage: %.2f MB", memUsage.load( std::memory_order_relaxed ) / ( 1024.f * 1024.f ) ); const auto wpos = ImGui::GetWindowPos() + ImGui::GetWindowContentRegionMin(); ImGui::GetWindowDrawList()->AddCircleFilled( wpos + ImVec2( 6, 9 ), 5.f, m_connected.load( std::memory_order_relaxed ) ? 0xFF2222CC : 0xFF444444, 10 ); std::lock_guard lock( m_lock ); { const auto sz = m_frames.size(); if( sz > 1 ) { const auto dt = m_frames[sz-1] - m_frames[sz-2]; const auto dtm = dt / 1000000.f; const auto fps = 1000.f / dtm; ImGui::Text( "FPS: %6.1f Frame time: %.2f ms", fps, dtm ); } } ImGui::End(); // Profiler window ImGui::Begin( "Profiler", nullptr, ImGuiWindowFlags_ShowBorders ); if( ImGui::Button( m_pause ? "Resume" : "Pause", ImVec2( 80, 0 ) ) ) m_pause = !m_pause; ImGui::SameLine(); ImGui::Text( "Frames: %-7i Time span: %-10s View span: %s", m_frames.size(), TimeToString( GetLastTime() - m_frames[0] ), TimeToString( m_zvEnd - m_zvStart ) ); DrawFrames(); DrawZones(); ImGui::End(); ImGui::ShowTestWindow(); } static ImU32 GetFrameColor( uint64_t frameTime ) { enum { BestTime = 1000 * 1000 * 1000 / 143 }; enum { GoodTime = 1000 * 1000 * 1000 / 59 }; enum { BadTime = 1000 * 1000 * 1000 / 29 }; return frameTime > BadTime ? 0xFF2222DD : frameTime > GoodTime ? 0xFF22DDDD : frameTime > BestTime ? 0xFF22DD22 : 0xFFDD9900; } static int GetFrameWidth( int frameScale ) { return frameScale == 0 ? 4 : ( frameScale == -1 ? 6 : 1 ); } static int GetFrameGroup( int frameScale ) { return frameScale < 2 ? 1 : ( 1 << ( frameScale - 1 ) ); } void View::DrawFrames() { assert( !m_frames.empty() ); enum { Height = 40 }; enum { MaxFrameTime = 50 * 1000 * 1000 }; // 50ms ImGuiWindow* window = ImGui::GetCurrentWindow(); if( window->SkipItems ) return; auto& io = ImGui::GetIO(); const auto wpos = ImGui::GetCursorScreenPos(); const auto wspace = ImGui::GetWindowContentRegionMax() - ImGui::GetWindowContentRegionMin(); const auto w = wspace.x; auto draw = ImGui::GetWindowDrawList(); ImGui::InvisibleButton( "##frames", ImVec2( w, Height ) ); bool hover = ImGui::IsItemHovered(); draw->AddRectFilled( wpos, wpos + ImVec2( w, Height ), 0x33FFFFFF ); const auto wheel = io.MouseWheel; const auto prevScale = m_frameScale; if( hover ) { if( wheel > 0 ) { if( m_frameScale > -1 ) m_frameScale--; } else if( wheel < 0 ) { if( m_frameScale < 10 ) m_frameScale++; } } const int fwidth = GetFrameWidth( m_frameScale ); const int group = GetFrameGroup( m_frameScale ); const int total = m_frames.size(); const int onScreen = ( w - 2 ) / fwidth; if( !m_pause ) { m_frameStart = ( total < onScreen * group ) ? 0 : total - onScreen * group; m_zvStart = m_frames[std::max( 0, (int)m_frames.size() - 4 )]; m_zvEnd = m_frames.back(); } if( hover ) { if( ImGui::IsMouseDragging( 1, 0 ) ) { m_pause = true; const auto delta = ImGui::GetMouseDragDelta( 1, 0 ).x; if( abs( delta ) >= fwidth ) { const auto d = (int)delta / fwidth; m_frameStart = std::max( 0, m_frameStart - d * group ); io.MouseClickedPos[1].x = io.MousePos.x + d * fwidth - delta; } } const auto mx = io.MousePos.x; if( mx > wpos.x && mx < wpos.x + w - 1 ) { const auto mo = mx - ( wpos.x + 1 ); const auto off = mo * group / fwidth; const int sel = m_frameStart + off; if( sel < total ) { ImGui::BeginTooltip(); if( group > 1 ) { uint64_t f = GetFrameTime( sel ); auto g = std::min( group, total - sel ); for( int j=1; j 1 ) { g = std::min( group, total - ( m_frameStart + idx ) ); for( int j=1; j( MaxFrameTime, f ) ) / MaxFrameTime * ( Height - 2 ); if( fwidth != 1 ) { draw->AddRectFilled( wpos + ImVec2( 1 + i*fwidth, Height-1-h ), wpos + ImVec2( fwidth + i*fwidth, Height-1 ), GetFrameColor( f ) ); } else { draw->AddLine( wpos + ImVec2( 1+i, Height-2-h ), wpos + ImVec2( 1+i, Height-2 ), GetFrameColor( f ) ); } i++; idx += group; } const auto zitbegin = std::lower_bound( m_frames.begin(), m_frames.end(), m_zvStart ); if( zitbegin == m_frames.end() ) return; const auto zitend = std::lower_bound( m_frames.begin(), m_frames.end(), m_zvEnd ); auto zbegin = (int)std::distance( m_frames.begin(), zitbegin ); if( zbegin > 0 && *zitbegin != m_zvStart ) zbegin--; const auto zend = (int)std::distance( m_frames.begin(), zitend ); if( zend > m_frameStart && zbegin < m_frameStart + onScreen * group ) { auto x0 = std::max( 0, ( zbegin - m_frameStart ) * fwidth / group ); auto x1 = std::min( onScreen * fwidth, ( zend - m_frameStart ) * fwidth / group ); if( x0 == x1 ) x1 = x0 + 1; draw->AddRectFilled( wpos + ImVec2( 1+x0, 0 ), wpos + ImVec2( 1+x1, Height ), 0x55DD22DD ); } } struct TimeScale { uint64_t div; const char* fmt; }; void View::DrawZones() { if( m_zvStart == m_zvEnd ) return; assert( m_zvStart < m_zvEnd ); ImGuiWindow* window = ImGui::GetCurrentWindow(); if( window->SkipItems ) return; auto& io = ImGui::GetIO(); const auto wpos = ImGui::GetCursorScreenPos(); const auto w = ImGui::GetWindowContentRegionWidth(); const auto h = ImGui::GetContentRegionAvail().y; auto draw = ImGui::GetWindowDrawList(); ImGui::InvisibleButton( "##zones", ImVec2( w, h ) ); bool hover = ImGui::IsItemHovered(); auto timespan = m_zvEnd - m_zvStart; auto pxns = w / double( timespan ); if( hover ) { if( ImGui::IsMouseDragging( 1, 0 ) ) { m_pause = true; const auto delta = ImGui::GetMouseDragDelta( 1, 0 ).x; const auto nspx = double( timespan ) / w; const auto dpx = int64_t( delta * nspx ); if( dpx != 0 ) { m_zvStart -= dpx; m_zvEnd -= dpx; io.MouseClickedPos[1].x = io.MousePos.x; } } const auto wheel = io.MouseWheel; if( wheel != 0 ) { m_pause = true; const double mouse = io.MousePos.x - wpos.x; const auto p = mouse / w; const auto p1 = timespan * p; const auto p2 = timespan - p1; if( wheel > 0 ) { m_zvStart += int64_t( p1 * 0.1f ); m_zvEnd -= int64_t( p2 * 0.1f ); } else if( timespan < 1000ull * 1000 * 1000 * 60 ) { m_zvStart -= std::max( 1ll, int64_t( p1 * 0.1f ) ); m_zvEnd += std::max( 1ll, int64_t( p2 * 0.1f ) ); } timespan = m_zvEnd - m_zvStart; pxns = w / double( timespan ); } } // frames do { const auto zitbegin = std::lower_bound( m_frames.begin(), m_frames.end(), m_zvStart ); if( zitbegin == m_frames.end() ) break; const auto zitend = std::lower_bound( m_frames.begin(), m_frames.end(), m_zvEnd ); auto zbegin = (int)std::distance( m_frames.begin(), zitbegin ); if( zbegin > 0 && *zitbegin != m_zvStart ) zbegin--; const auto zend = (int)std::distance( m_frames.begin(), zitend ); for( int i=zbegin; i= m_zvStart ) { draw->AddLine( wpos + ImVec2( ( fbegin - m_zvStart ) * pxns, 0 ), wpos + ImVec2( ( fbegin - m_zvStart ) * pxns, h ), 0x22FFFFFF ); } if( fsz >= 5 ) { if( fbegin >= m_zvStart ) { draw->AddLine( wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + 2, 1 ), wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + 2, tsz.y - 1 ), 0xFFFFFFFF ); } if( fend <= m_zvEnd ) { draw->AddLine( wpos + ImVec2( ( fend - m_zvStart ) * pxns - 2, 1 ), wpos + ImVec2( ( fend - m_zvStart ) * pxns - 2, tsz.y - 1 ), 0xFFFFFFFF ); } if( fsz - 5 > tsz.x ) { const auto part = ( fsz - 5 - tsz.x ) / 2; draw->AddLine( wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + 2, tsz.y / 2 ), wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + part, tsz.y / 2 ), 0xFFFFFFFF ); draw->AddText( wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + 2 + part, 0 ), 0xFFFFFFFF, buf ); draw->AddLine( wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + 2 + part + tsz.x, tsz.y / 2 ), wpos + ImVec2( ( fend - m_zvStart ) * pxns - 2, tsz.y / 2 ), 0xFFFFFFFF ); } else { draw->AddLine( wpos + ImVec2( ( fbegin - m_zvStart ) * pxns + 2, tsz.y / 2 ), wpos + ImVec2( ( fend - m_zvStart ) * pxns - 2, tsz.y / 2 ), 0xFFFFFFFF ); } } } const auto fend = GetFrameEnd( zend-1 ); if( fend == m_zvEnd ) { draw->AddLine( wpos + ImVec2( ( fend - m_zvStart ) * pxns, 0 ), wpos + ImVec2( ( fend - m_zvStart ) * pxns, h ), 0x22FFFFFF ); } } while( false ); // zones int offset = 20; for( auto& v : m_threads ) { auto& timeline = v.timeline; auto it = std::lower_bound( timeline.begin(), timeline.end(), m_zvStart, [] ( const auto& l, const auto& r ) { return l->end < r; } ); if( it != timeline.end() ) { const auto zitend = std::lower_bound( timeline.begin(), timeline.end(), m_zvEnd, [] ( const auto& l, const auto& r ) { return l->start < r; } ); while( it < zitend ) { auto& ev = **it; const auto& srcFile = m_srcFile[ev.srcloc]; const char* func = GetString( srcFile.function ); const auto zsz = ( ev.end - ev.start ) * pxns; const auto tsz = ImGui::CalcTextSize( func ); draw->AddRectFilled( wpos + ImVec2( ( ev.start - m_zvStart ) * pxns, offset ), wpos + ImVec2( ( ev.end - m_zvStart ) * pxns, offset + tsz.y ), 0xDDDD6666, 2.f ); draw->AddRect( wpos + ImVec2( ( ev.start - m_zvStart ) * pxns, offset ), wpos + ImVec2( ( ev.end - m_zvStart ) * pxns, offset + tsz.y ), 0xAAAAAAAA, 2.f ); if( tsz.x < zsz ) { draw->AddText( wpos + ImVec2( ( ev.start - m_zvStart ) * pxns + ( ( ev.end - ev.start ) * pxns - tsz.x ) / 2, offset ), 0xFFFFFFFF, func ); } else { ImGui::PushClipRect( wpos + ImVec2( ( ev.start - m_zvStart ) * pxns, offset ), wpos + ImVec2( ( ev.end - m_zvStart ) * pxns, offset + tsz.y ), true ); draw->AddText( wpos + ImVec2( ( ev.start - m_zvStart ) * pxns, offset ), 0xFFFFFFFF, func ); ImGui::PopClipRect(); } if( hover && ImGui::IsMouseHoveringRect( wpos + ImVec2( ( ev.start - m_zvStart ) * pxns, offset ), wpos + ImVec2( ( ev.end - m_zvStart ) * pxns, offset + tsz.y ) ) ) { ImGui::BeginTooltip(); ImGui::Text( func ); ImGui::Text( "%s:%i", GetString( srcFile.filename ), srcFile.line ); ImGui::Text( "Execution time: %s", TimeToString( ev.end - ev.start ) ); ImGui::EndTooltip(); } it++; } } draw->AddText( wpos + ImVec2( 0, offset ), 0xFFFFFFFF, GetThreadString( v.id ) ); offset += 20; } } }