#include #include "TracyImGui.hpp" #include "TracyMouse.hpp" #include "TracyPrint.hpp" #include "TracyView.hpp" namespace tracy { enum { ChunkBits = 10 }; enum { PageBits = 10 }; enum { PageSize = 1 << PageBits }; enum { PageChunkBits = ChunkBits + PageBits }; enum { PageChunkSize = 1 << PageChunkBits }; uint32_t MemDecayColor[256] = { 0x0, 0xFF077F07, 0xFF078007, 0xFF078207, 0xFF078307, 0xFF078507, 0xFF078707, 0xFF078807, 0xFF078A07, 0xFF078B07, 0xFF078D07, 0xFF078F07, 0xFF079007, 0xFF089208, 0xFF089308, 0xFF089508, 0xFF089708, 0xFF089808, 0xFF089A08, 0xFF089B08, 0xFF089D08, 0xFF089F08, 0xFF08A008, 0xFF08A208, 0xFF09A309, 0xFF09A509, 0xFF09A709, 0xFF09A809, 0xFF09AA09, 0xFF09AB09, 0xFF09AD09, 0xFF09AF09, 0xFF09B009, 0xFF09B209, 0xFF09B309, 0xFF09B509, 0xFF0AB70A, 0xFF0AB80A, 0xFF0ABA0A, 0xFF0ABB0A, 0xFF0ABD0A, 0xFF0ABF0A, 0xFF0AC00A, 0xFF0AC20A, 0xFF0AC30A, 0xFF0AC50A, 0xFF0AC70A, 0xFF0BC80B, 0xFF0BCA0B, 0xFF0BCB0B, 0xFF0BCD0B, 0xFF0BCF0B, 0xFF0BD00B, 0xFF0BD20B, 0xFF0BD30B, 0xFF0BD50B, 0xFF0BD70B, 0xFF0BD80B, 0xFF0BDA0B, 0xFF0CDB0C, 0xFF0CDD0C, 0xFF0CDF0C, 0xFF0CE00C, 0xFF0CE20C, 0xFF0CE30C, 0xFF0CE50C, 0xFF0CE70C, 0xFF0CE80C, 0xFF0CEA0C, 0xFF0CEB0C, 0xFF0DED0D, 0xFF0DEF0D, 0xFF0DF00D, 0xFF0DF20D, 0xFF0DF30D, 0xFF0DF50D, 0xFF0DF70D, 0xFF0DF80D, 0xFF0DFA0D, 0xFF0DFB0D, 0xFF0DFD0D, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0EFF0E, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF0FFF0F, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF10FF10, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF11FF11, 0xFF12FF12, 0x0, 0xFF1212FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1111FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF1010FF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0F0FFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0E0EFF, 0xFF0D0DFD, 0xFF0D0DFB, 0xFF0D0DFA, 0xFF0D0DF8, 0xFF0D0DF7, 0xFF0D0DF5, 0xFF0D0DF3, 0xFF0D0DF2, 0xFF0D0DF0, 0xFF0D0DEF, 0xFF0D0DED, 0xFF0C0CEB, 0xFF0C0CEA, 0xFF0C0CE8, 0xFF0C0CE7, 0xFF0C0CE5, 0xFF0C0CE3, 0xFF0C0CE2, 0xFF0C0CE0, 0xFF0C0CDF, 0xFF0C0CDD, 0xFF0C0CDB, 0xFF0B0BDA, 0xFF0B0BD8, 0xFF0B0BD7, 0xFF0B0BD5, 0xFF0B0BD3, 0xFF0B0BD2, 0xFF0B0BD0, 0xFF0B0BCF, 0xFF0B0BCD, 0xFF0B0BCB, 0xFF0B0BCA, 0xFF0B0BC8, 0xFF0A0AC7, 0xFF0A0AC5, 0xFF0A0AC3, 0xFF0A0AC2, 0xFF0A0AC0, 0xFF0A0ABF, 0xFF0A0ABD, 0xFF0A0ABB, 0xFF0A0ABA, 0xFF0A0AB8, 0xFF0A0AB7, 0xFF0909B5, 0xFF0909B3, 0xFF0909B2, 0xFF0909B0, 0xFF0909AF, 0xFF0909AD, 0xFF0909AB, 0xFF0909AA, 0xFF0909A8, 0xFF0909A7, 0xFF0909A5, 0xFF0909A3, 0xFF0808A2, 0xFF0808A0, 0xFF08089F, 0xFF08089D, 0xFF08089B, 0xFF08089A, 0xFF080898, 0xFF080897, 0xFF080895, 0xFF080893, 0xFF080892, 0xFF070790, 0xFF07078F, 0xFF07078D, 0xFF07078B, 0xFF07078A, 0xFF070788, 0xFF070787, 0xFF070785, 0xFF070783, 0xFF070782, 0xFF070780, 0xFF07077F, }; struct MemoryPage { uint64_t page; int8_t data[PageSize]; }; static tracy_force_inline MemoryPage& GetPage( unordered_flat_map& memmap, uint64_t page ) { auto it = memmap.find( page ); if( it == memmap.end() ) { it = memmap.emplace( page, MemoryPage { page, {} } ).first; } return it->second; } static tracy_force_inline void FillPages( unordered_flat_map& memmap, uint64_t c0, uint64_t c1, int8_t val ) { auto p0 = c0 >> PageBits; const auto p1 = c1 >> PageBits; if( p0 == p1 ) { const auto a0 = c0 & ( PageSize - 1 ); const auto a1 = c1 & ( PageSize - 1 ); auto& page = GetPage( memmap, p0 ); if( a0 == a1 ) { page.data[a0] = val; } else { memset( page.data + a0, val, a1 - a0 + 1 ); } } else { { const auto a0 = c0 & ( PageSize - 1 ); auto& page = GetPage( memmap, p0 ); memset( page.data + a0, val, PageSize - a0 ); } while( ++p0 < p1 ) { auto& page = GetPage( memmap, p0 ); memset( page.data, val, PageSize ); } { const auto a1 = c1 & ( PageSize - 1 ); auto& page = GetPage( memmap, p1 ); memset( page.data, val, a1 + 1 ); } } } std::vector View::GetMemoryPages() const { std::vector ret; static unordered_flat_map memmap; const auto& mem = m_worker.GetMemoryNamed( m_memInfo.pool ); const auto memlow = mem.low; if( m_memInfo.range.active ) { auto it = std::lower_bound( mem.data.begin(), mem.data.end(), m_memInfo.range.min, []( const auto& lhs, const auto& rhs ) { return lhs.TimeAlloc() < rhs; } ); if( it != mem.data.end() ) { auto end = std::lower_bound( mem.data.begin(), mem.data.end(), m_memInfo.range.max, []( const auto& lhs, const auto& rhs ) { return lhs.TimeAlloc() < rhs; } ); while( it != end ) { auto& alloc = *it++; const auto a0 = alloc.Ptr() - memlow; const auto a1 = a0 + alloc.Size(); int8_t val = alloc.TimeFree() < 0 ? int8_t( std::max( int64_t( 1 ), 127 - ( ( m_memInfo.range.max - alloc.TimeAlloc() ) >> 24 ) ) ) : ( alloc.TimeFree() > m_memInfo.range.max ? int8_t( std::max( int64_t( 1 ), 127 - ( ( m_memInfo.range.max - alloc.TimeAlloc() ) >> 24 ) ) ) : int8_t( -std::max( int64_t( 1 ), 127 - ( ( m_memInfo.range.max - alloc.TimeFree() ) >> 24 ) ) ) ); const auto c0 = a0 >> ChunkBits; const auto c1 = a1 >> ChunkBits; FillPages( memmap, c0, c1, val ); } } } else { const auto lastTime = m_worker.GetLastTime(); for( auto& alloc : mem.data ) { const auto a0 = alloc.Ptr() - memlow; const auto a1 = a0 + alloc.Size(); const int8_t val = alloc.TimeFree() < 0 ? int8_t( std::max( int64_t( 1 ), 127 - ( ( lastTime - std::min( lastTime, alloc.TimeAlloc() ) ) >> 24 ) ) ) : int8_t( -std::max( int64_t( 1 ), 127 - ( ( lastTime - std::min( lastTime, alloc.TimeFree() ) ) >> 24 ) ) ); const auto c0 = a0 >> ChunkBits; const auto c1 = a1 >> ChunkBits; FillPages( memmap, c0, c1, val ); } } std::vector::const_iterator> itmap; itmap.reserve( memmap.size() ); ret.reserve( memmap.size() ); for( auto it = memmap.begin(); it != memmap.end(); ++it ) itmap.emplace_back( it ); pdqsort_branchless( itmap.begin(), itmap.end(), []( const auto& lhs, const auto& rhs ) { return lhs->second.page < rhs->second.page; } ); for( auto& v : itmap ) ret.emplace_back( v->second ); memmap.clear(); return ret; } void View::DrawMemory() { const auto scale = GetScale(); ImGui::SetNextWindowSize( ImVec2( 1100 * scale, 500 * scale ), ImGuiCond_FirstUseEver ); ImGui::Begin( "Memory", &m_memInfo.show, ImGuiWindowFlags_NoScrollbar | ImGuiWindowFlags_NoScrollWithMouse ); if( ImGui::GetCurrentWindowRead()->SkipItems ) { ImGui::End(); return; } auto& memNameMap = m_worker.GetMemNameMap(); if( memNameMap.size() > 1 ) { TextDisabledUnformatted( ICON_FA_BOX_ARCHIVE " Memory pool:" ); ImGui::SameLine(); if( ImGui::BeginCombo( "##memoryPool", m_memInfo.pool == 0 ? "Default allocator" : m_worker.GetString( m_memInfo.pool ) ) ) { for( auto& v : memNameMap ) { if( ImGui::Selectable( v.first == 0 ? "Default allocator" : m_worker.GetString( v.first ) ) ) { m_memInfo.pool = v.first; m_memInfo.showAllocList = false; } } ImGui::EndCombo(); } ImGui::Separator(); } auto& mem = m_worker.GetMemoryNamed( m_memInfo.pool ); if( mem.data.empty() ) { ImGui::TextWrapped( "No memory data collected." ); ImGui::End(); return; } TextDisabledUnformatted( "Total allocations:" ); ImGui::SameLine(); ImGui::Text( "%-15s", RealToString( mem.data.size() ) ); ImGui::SameLine(); TextDisabledUnformatted( "Active allocations:" ); ImGui::SameLine(); ImGui::Text( "%-15s", RealToString( mem.active.size() ) ); ImGui::SameLine(); TextDisabledUnformatted( "Memory usage:" ); ImGui::SameLine(); ImGui::Text( "%-15s", MemSizeToString( mem.usage ) ); ImGui::SameLine(); TextFocused( "Memory span:", MemSizeToString( mem.high - mem.low ) ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); DrawHelpMarker( "Click on address to display memory allocation info window. Middle click to zoom to allocation range.\n" "Active allocations are displayed using green color.\n" "A single thread is displayed if alloc and free was performed on the same thread. Otherwise two threads are displayed in order: alloc, free.\n" "If alloc and free is performed in the same zone, the free zone is displayed in yellow color." ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); ImGui::SeparatorEx( ImGuiSeparatorFlags_Vertical ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); ImGui::PushStyleVar( ImGuiStyleVar_FramePadding, ImVec2( 2, 2 ) ); if( ImGui::Checkbox( "Limit range", &m_memInfo.range.active ) ) { if( m_memInfo.range.active && m_memInfo.range.min == 0 && m_memInfo.range.max == 0 ) { m_memInfo.range.min = m_vd.zvStart; m_memInfo.range.max = m_vd.zvEnd; } } if( m_memInfo.range.active ) { ImGui::SameLine(); TextColoredUnformatted( 0xFF00FFFF, ICON_FA_TRIANGLE_EXCLAMATION ); ImGui::SameLine(); ToggleButton( ICON_FA_RULER " Limits", m_showRanges ); } ImGui::PopStyleVar(); ImGui::Separator(); ImGui::BeginChild( "##memory" ); if( ImGui::TreeNode( ICON_FA_AT " Allocations" ) ) { bool findClicked = ImGui::InputTextWithHint( "###address", "Enter memory address to search for", m_memInfo.pattern, 1024, ImGuiInputTextFlags_EnterReturnsTrue ); ImGui::SameLine(); findClicked |= ImGui::Button( ICON_FA_MAGNIFYING_GLASS " Find" ); if( findClicked ) { m_memInfo.ptrFind = strtoull( m_memInfo.pattern, nullptr, 0 ); } ImGui::SameLine(); if( ImGui::Button( ICON_FA_DELETE_LEFT " Clear" ) ) { m_memInfo.ptrFind = 0; m_memInfo.pattern[0] = '\0'; } if( m_memInfo.ptrFind != 0 ) { std::vector match; match.reserve( mem.active.size() ); // heuristic if( m_memInfo.range.active ) { auto it = std::lower_bound( mem.data.begin(), mem.data.end(), m_memInfo.range.min, [] ( const auto& lhs, const auto& rhs ) { return lhs.TimeAlloc() < rhs; } ); if( it != mem.data.end() ) { auto end = std::lower_bound( it, mem.data.end(), m_memInfo.range.max, [] ( const auto& lhs, const auto& rhs ) { return lhs.TimeAlloc() < rhs; } ); while( it != end ) { if( it->Ptr() <= m_memInfo.ptrFind && it->Ptr() + it->Size() > m_memInfo.ptrFind ) { match.emplace_back( it ); } ++it; } } } else { for( auto& v : mem.data ) { if( v.Ptr() <= m_memInfo.ptrFind && v.Ptr() + v.Size() > m_memInfo.ptrFind ) { match.emplace_back( &v ); } } } if( match.empty() ) { ImGui::TextUnformatted( "Found no allocations at given address" ); } else { ListMemData( match, [this]( auto v ) { if( v->Ptr() == m_memInfo.ptrFind ) { ImGui::Text( "0x%" PRIx64, m_memInfo.ptrFind ); } else { ImGui::Text( "0x%" PRIx64 "+%" PRIu64, v->Ptr(), m_memInfo.ptrFind - v->Ptr() ); } }, "##allocations", -1, m_memInfo.pool ); } } ImGui::TreePop(); } ImGui::Separator(); if( ImGui::TreeNode( ICON_FA_HEART_PULSE " Active allocations" ) ) { uint64_t total = 0; std::vector items; items.reserve( mem.active.size() ); if( m_memInfo.range.active ) { auto it = std::lower_bound( mem.data.begin(), mem.data.end(), m_memInfo.range.min, [] ( const auto& lhs, const auto& rhs ) { return lhs.TimeAlloc() < rhs; } ); if( it != mem.data.end() ) { auto end = std::lower_bound( it, mem.data.end(), m_memInfo.range.max, [] ( const auto& lhs, const auto& rhs ) { return lhs.TimeAlloc() < rhs; } ); while( it != end ) { const auto tf = it->TimeFree(); if( tf < 0 || tf >= m_memInfo.range.max ) { items.emplace_back( it ); total += it->Size(); } ++it; } } } else { auto ptr = mem.data.data(); for( auto& v : mem.active ) items.emplace_back( ptr + v.second ); pdqsort_branchless( items.begin(), items.end(), []( const auto& lhs, const auto& rhs ) { return lhs->TimeAlloc() < rhs->TimeAlloc(); } ); total = mem.usage; } ImGui::SameLine(); ImGui::TextDisabled( "(%s)", RealToString( items.size() ) ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); TextFocused( "Memory usage:", MemSizeToString( total ) ); if( !items.empty() ) { ListMemData( items, []( auto v ) { ImGui::Text( "0x%" PRIx64, v->Ptr() ); }, "##activeMem", -1, m_memInfo.pool ); } else { TextDisabledUnformatted( "No active allocations" ); } ImGui::TreePop(); } ImGui::Separator(); if( ImGui::TreeNode( ICON_FA_MAP " Memory map" ) ) { ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); TextFocused( "Single pixel:", MemSizeToString( 1 << ChunkBits ) ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); TextFocused( "Single line:", MemSizeToString( PageChunkSize ) ); auto pages = GetMemoryPages(); const size_t lines = pages.size(); ImGui::BeginChild( "##memMap", ImVec2( PageSize + 2, lines + 2 ), false ); auto draw = ImGui::GetWindowDrawList(); const auto wpos = ImGui::GetCursorScreenPos() + ImVec2( 1, 1 ); const auto dpos = wpos + ImVec2( 0.5f, 0.5f ); draw->AddRect( wpos - ImVec2( 1, 1 ), wpos + ImVec2( PageSize + 1, lines + 1 ), 0xFF666666 ); draw->AddRectFilled( wpos, wpos + ImVec2( PageSize, lines ), 0xFF444444 ); size_t line = 0; for( auto& page : pages ) { size_t idx = 0; while( idx < PageSize ) { if( page.data[idx] == 0 ) { do { idx++; } while( idx < PageSize && page.data[idx] == 0 ); } else { auto val = page.data[idx]; const auto i0 = idx; do { idx++; } while( idx < PageSize && page.data[idx] == val ); DrawLine( draw, dpos + ImVec2( i0, line ), dpos + ImVec2( idx, line ), MemDecayColor[(uint8_t)val] ); } } line++; } ImGui::EndChild(); ImGui::TreePop(); } ImGui::PushID( m_memInfo.pool ); ImGui::Separator(); if( ImGui::TreeNode( ICON_FA_TREE " Bottom-up call stack tree" ) ) { ImGui::SameLine(); DrawHelpMarker( "Press ctrl key to display allocation info tooltip. Right click on function name to display allocations list." ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); SmallCheckbox( "Group by function name", &m_groupCallstackTreeByNameBottomUp ); ImGui::SameLine(); DrawHelpMarker( "If enabled, only one source location will be displayed (which may be incorrect)." ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); bool activeOnlyBottomUp = m_memRangeBottomUp == MemRange::Active; if( SmallCheckbox( "Only active allocations", &activeOnlyBottomUp ) ) m_memRangeBottomUp = activeOnlyBottomUp ? MemRange::Active : MemRange::Full; ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); bool inactiveOnlyBottomUp = m_memRangeBottomUp == MemRange::Inactive; if( SmallCheckbox( "Only inactive allocations", &inactiveOnlyBottomUp ) ) m_memRangeBottomUp = inactiveOnlyBottomUp ? MemRange::Inactive : MemRange::Full; auto tree = GetCallstackFrameTreeBottomUp( mem ); if( !tree.empty() ) { int idx = 0; DrawFrameTreeLevel( tree, idx ); } else { TextDisabledUnformatted( "No call stack data collected" ); } ImGui::TreePop(); } ImGui::Separator(); if( ImGui::TreeNode( ICON_FA_TREE " Top-down call stack tree" ) ) { ImGui::SameLine(); DrawHelpMarker( "Press ctrl key to display allocation info tooltip. Right click on function name to display allocations list." ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); SmallCheckbox( "Group by function name", &m_groupCallstackTreeByNameTopDown ); ImGui::SameLine(); DrawHelpMarker( "If enabled, only one source location will be displayed (which may be incorrect)." ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); bool activeOnlyTopDown = m_memRangeTopDown == MemRange::Active; if( SmallCheckbox( "Only active allocations", &activeOnlyTopDown ) ) m_memRangeTopDown = activeOnlyTopDown ? MemRange::Active : MemRange::Full; ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); bool inactiveOnlyTopDown = m_memRangeTopDown == MemRange::Inactive; if( SmallCheckbox( "Only inactive allocations", &inactiveOnlyTopDown ) ) m_memRangeTopDown = inactiveOnlyTopDown ? MemRange::Inactive : MemRange::Full; auto tree = GetCallstackFrameTreeTopDown( mem ); if( !tree.empty() ) { int idx = 0; DrawFrameTreeLevel( tree, idx ); } else { TextDisabledUnformatted( "No call stack data collected" ); } ImGui::TreePop(); } ImGui::PopID(); ImGui::EndChild(); ImGui::End(); } void View::DrawMemoryAllocWindow() { bool show = true; ImGui::Begin( "Memory allocation", &show, ImGuiWindowFlags_AlwaysAutoResize ); if( !ImGui::GetCurrentWindowRead()->SkipItems ) { const auto& mem = m_worker.GetMemoryNamed( m_memoryAllocInfoPool ); const auto& ev = mem.data[m_memoryAllocInfoWindow]; const auto tidAlloc = m_worker.DecompressThread( ev.ThreadAlloc() ); const auto tidFree = m_worker.DecompressThread( ev.ThreadFree() ); int idx = 0; if( ImGui::Button( ICON_FA_MICROSCOPE " Zoom to allocation" ) ) { ZoomToRange( ev.TimeAlloc(), ev.TimeFree() >= 0 ? ev.TimeFree() : m_worker.GetLastTime() ); } if( m_worker.GetMemNameMap().size() > 1 ) { TextFocused( ICON_FA_BOX_ARCHIVE " Pool:", m_memoryAllocInfoPool == 0 ? "Default allocator" : m_worker.GetString( m_memoryAllocInfoPool ) ); } char buf[64]; sprintf( buf, "0x%" PRIx64, ev.Ptr() ); TextFocused( "Address:", buf ); TextFocused( "Size:", MemSizeToString( ev.Size() ) ); if( ev.Size() >= 10000ll ) { ImGui::SameLine(); ImGui::TextDisabled( "(%s bytes)", RealToString( ev.Size() ) ); } ImGui::Separator(); TextFocused( "Appeared at", TimeToStringExact( ev.TimeAlloc() ) ); if( ImGui::IsItemClicked() ) CenterAtTime( ev.TimeAlloc() ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); SmallColorBox( GetThreadColor( tidAlloc, 0 ) ); ImGui::SameLine(); TextFocused( "Thread:", m_worker.GetThreadName( tidAlloc ) ); ImGui::SameLine(); ImGui::TextDisabled( "(%s)", RealToString( tidAlloc ) ); if( m_worker.IsThreadFiber( tidAlloc ) ) { ImGui::SameLine(); TextColoredUnformatted( ImVec4( 0.2f, 0.6f, 0.2f, 1.f ), "Fiber" ); } if( ev.CsAlloc() != 0 ) { const auto cs = ev.CsAlloc(); SmallCallstackButton( ICON_FA_ALIGN_JUSTIFY, cs, idx ); ImGui::SameLine(); DrawCallstackCalls( cs, 4 ); } if( ev.TimeFree() < 0 ) { TextDisabledUnformatted( "Allocation still active" ); } else { TextFocused( "Freed at", TimeToStringExact( ev.TimeFree() ) ); if( ImGui::IsItemClicked() ) CenterAtTime( ev.TimeFree() ); ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); SmallColorBox( GetThreadColor( tidFree, 0 ) ); ImGui::SameLine(); TextFocused( "Thread:", m_worker.GetThreadName( tidFree ) ); ImGui::SameLine(); ImGui::TextDisabled( "(%s)", RealToString( tidFree ) ); if( m_worker.IsThreadFiber( tidFree ) ) { ImGui::SameLine(); TextColoredUnformatted( ImVec4( 0.2f, 0.6f, 0.2f, 1.f ), "Fiber" ); } if( ev.csFree.Val() != 0 ) { const auto cs = ev.csFree.Val(); SmallCallstackButton( ICON_FA_ALIGN_JUSTIFY, cs, idx ); ImGui::SameLine(); DrawCallstackCalls( cs, 4 ); } TextFocused( "Duration:", TimeToString( ev.TimeFree() - ev.TimeAlloc() ) ); } bool sep = false; auto zoneAlloc = FindZoneAtTime( tidAlloc, ev.TimeAlloc() ); if( zoneAlloc ) { ImGui::Separator(); sep = true; const auto& srcloc = m_worker.GetSourceLocation( zoneAlloc->SrcLoc() ); const auto txt = srcloc.name.active ? m_worker.GetString( srcloc.name ) : m_worker.GetString( srcloc.function ); ImGui::PushID( idx++ ); TextFocused( "Zone alloc:", txt ); auto hover = ImGui::IsItemHovered(); ImGui::PopID(); if( ImGui::IsItemClicked() ) { ShowZoneInfo( *zoneAlloc ); } if( hover ) { m_zoneHighlight = zoneAlloc; if( IsMouseClicked( 2 ) ) { ZoomToZone( *zoneAlloc ); } ZoneTooltip( *zoneAlloc ); } } if( ev.TimeFree() >= 0 ) { auto zoneFree = FindZoneAtTime( tidFree, ev.TimeFree() ); if( zoneFree ) { if( !sep ) ImGui::Separator(); const auto& srcloc = m_worker.GetSourceLocation( zoneFree->SrcLoc() ); const auto txt = srcloc.name.active ? m_worker.GetString( srcloc.name ) : m_worker.GetString( srcloc.function ); TextFocused( "Zone free:", txt ); auto hover = ImGui::IsItemHovered(); if( ImGui::IsItemClicked() ) { ShowZoneInfo( *zoneFree ); } if( hover ) { m_zoneHighlight = zoneFree; if( IsMouseClicked( 2 ) ) { ZoomToZone( *zoneFree ); } ZoneTooltip( *zoneFree ); } if( zoneAlloc != 0 && zoneAlloc == zoneFree ) { ImGui::SameLine(); TextDisabledUnformatted( "(same zone)" ); } } } } ImGui::End(); if( !show ) m_memoryAllocInfoWindow = -1; } void View::ListMemData( std::vector& vec, std::function DrawAddress, const char* id, int64_t startTime, uint64_t pool ) { if( startTime == -1 ) startTime = 0; if( ImGui::BeginTable( "##mem", 8, ImGuiTableFlags_Resizable | ImGuiTableFlags_Reorderable | ImGuiTableFlags_Hideable | ImGuiTableFlags_Sortable | ImGuiTableFlags_BordersInnerV | ImGuiTableFlags_ScrollY, ImVec2( 0, ImGui::GetTextLineHeightWithSpacing() * std::min( 1+vec.size(), 15 ) ) ) ) { ImGui::TableSetupScrollFreeze( 0, 1 ); ImGui::TableSetupColumn( "Address", ImGuiTableColumnFlags_NoHide ); ImGui::TableSetupColumn( "Size", ImGuiTableColumnFlags_PreferSortDescending ); ImGui::TableSetupColumn( "Appeared at", ImGuiTableColumnFlags_DefaultSort ); ImGui::TableSetupColumn( "Duration", ImGuiTableColumnFlags_PreferSortDescending ); ImGui::TableSetupColumn( "Thread", ImGuiTableColumnFlags_NoSort ); ImGui::TableSetupColumn( "Zone alloc", ImGuiTableColumnFlags_NoSort ); ImGui::TableSetupColumn( "Zone free", ImGuiTableColumnFlags_NoSort ); ImGui::TableSetupColumn( "Call stack", ImGuiTableColumnFlags_NoSort ); ImGui::TableHeadersRow(); const auto& mem = m_worker.GetMemoryNamed( pool ); const auto& sortspec = *ImGui::TableGetSortSpecs()->Specs; switch( sortspec.ColumnIndex ) { case 0: if( sortspec.SortDirection == ImGuiSortDirection_Ascending ) { pdqsort_branchless( vec.begin(), vec.end(), []( const auto& l, const auto& r ) { return l->Ptr() < r->Ptr(); } ); } else { pdqsort_branchless( vec.begin(), vec.end(), []( const auto& l, const auto& r ) { return l->Ptr() > r->Ptr(); } ); } break; case 1: if( sortspec.SortDirection == ImGuiSortDirection_Ascending ) { pdqsort_branchless( vec.begin(), vec.end(), []( const auto& l, const auto& r ) { return l->Size() < r->Size(); } ); } else { pdqsort_branchless( vec.begin(), vec.end(), []( const auto& l, const auto& r ) { return l->Size() > r->Size(); } ); } break; case 2: if( sortspec.SortDirection == ImGuiSortDirection_Descending ) { std::reverse( vec.begin(), vec.end() ); } break; case 3: if( sortspec.SortDirection == ImGuiSortDirection_Ascending ) { pdqsort_branchless( vec.begin(), vec.end(), []( const auto& l, const auto& r ) { return ( l->TimeFree() - l->TimeAlloc() ) < ( r->TimeFree() - r->TimeAlloc() ); } ); } else { pdqsort_branchless( vec.begin(), vec.end(), []( const auto& l, const auto& r ) { return ( l->TimeFree() - l->TimeAlloc() ) > ( r->TimeFree() - r->TimeAlloc() ); } ); } break; default: assert( false ); break; } int idx = 0; ImGuiListClipper clipper; clipper.Begin( vec.end() - vec.begin() ); while( clipper.Step() ) { for( auto i=clipper.DisplayStart; iTimeAlloc(), v->TimeFree() >= 0 ? v->TimeFree() : m_worker.GetLastTime() ); } if( ImGui::IsItemHovered() ) { m_memoryAllocHover = arrIdx; m_memoryAllocHoverWait = 2; m_memoryAllocHoverPool = pool; } ImGui::TableNextColumn(); ImGui::TextUnformatted( MemSizeToString( v->Size() ) ); ImGui::TableNextColumn(); ImGui::PushID( idx++ ); if( ImGui::Selectable( TimeToStringExact( v->TimeAlloc() - startTime ) ) ) { CenterAtTime( v->TimeAlloc() ); } ImGui::PopID(); ImGui::TableNextColumn(); if( v->TimeFree() < 0 ) { TextColoredUnformatted( ImVec4( 0.6f, 1.f, 0.6f, 1.f ), TimeToString( m_worker.GetLastTime() - v->TimeAlloc() ) ); ImGui::TableNextColumn(); const auto tid = m_worker.DecompressThread( v->ThreadAlloc() ); SmallColorBox( GetThreadColor( tid, 0 ) ); ImGui::SameLine(); ImGui::TextUnformatted( m_worker.GetThreadName( tid ) ); } else { ImGui::PushID( idx++ ); if( ImGui::Selectable( TimeToString( v->TimeFree() - v->TimeAlloc() ) ) ) { CenterAtTime( v->TimeFree() ); } ImGui::PopID(); ImGui::TableNextColumn(); if( v->ThreadAlloc() == v->ThreadFree() ) { const auto tid = m_worker.DecompressThread( v->ThreadAlloc() ); SmallColorBox( GetThreadColor( tid, 0 ) ); ImGui::SameLine(); ImGui::TextUnformatted( m_worker.GetThreadName( tid ) ); } else { const auto tidAlloc = m_worker.DecompressThread( v->ThreadAlloc() ); const auto tidFree = m_worker.DecompressThread( v->ThreadFree() ); SmallColorBox( GetThreadColor( tidAlloc, 0 ) ); ImGui::SameLine(); ImGui::TextUnformatted( m_worker.GetThreadName( tidAlloc ) ); ImGui::SameLine(); ImGui::TextUnformatted( "/" ); ImGui::SameLine(); SmallColorBox( GetThreadColor( tidFree, 0 ) ); ImGui::SameLine(); ImGui::TextUnformatted( m_worker.GetThreadName( tidFree ) ); } } ImGui::TableNextColumn(); auto zone = FindZoneAtTime( m_worker.DecompressThread( v->ThreadAlloc() ), v->TimeAlloc() ); if( !zone ) { ImGui::TextUnformatted( "-" ); } else { const auto& srcloc = m_worker.GetSourceLocation( zone->SrcLoc() ); const auto txt = srcloc.name.active ? m_worker.GetString( srcloc.name ) : m_worker.GetString( srcloc.function ); ImGui::PushID( idx++ ); auto sel = ImGui::Selectable( txt, m_zoneInfoWindow == zone ); auto hover = ImGui::IsItemHovered(); ImGui::PopID(); if( sel ) { ShowZoneInfo( *zone ); } if( hover ) { m_zoneHighlight = zone; if( IsMouseClicked( 2 ) ) { ZoomToZone( *zone ); } ZoneTooltip( *zone ); } } ImGui::TableNextColumn(); if( v->TimeFree() < 0 ) { TextColoredUnformatted( ImVec4( 0.6f, 1.f, 0.6f, 1.f ), "active" ); } else { auto zoneFree = FindZoneAtTime( m_worker.DecompressThread( v->ThreadFree() ), v->TimeFree() ); if( !zoneFree ) { ImGui::TextUnformatted( "-" ); } else { const auto& srcloc = m_worker.GetSourceLocation( zoneFree->SrcLoc() ); const auto txt = srcloc.name.active ? m_worker.GetString( srcloc.name ) : m_worker.GetString( srcloc.function ); ImGui::PushID( idx++ ); bool sel; if( zoneFree == zone ) { ImGui::PushStyleColor( ImGuiCol_Text, ImVec4( 1.f, 1.f, 0.6f, 1.f ) ); sel = ImGui::Selectable( txt, m_zoneInfoWindow == zoneFree ); ImGui::PopStyleColor( 1 ); } else { sel = ImGui::Selectable( txt, m_zoneInfoWindow == zoneFree ); } auto hover = ImGui::IsItemHovered(); ImGui::PopID(); if( sel ) { ShowZoneInfo( *zoneFree ); } if( hover ) { m_zoneHighlight = zoneFree; if( IsMouseClicked( 2 ) ) { ZoomToZone( *zoneFree ); } ZoneTooltip( *zoneFree ); } } } ImGui::TableNextColumn(); if( v->CsAlloc() == 0 ) { TextDisabledUnformatted( "[alloc]" ); } else { SmallCallstackButton( "alloc", v->CsAlloc(), idx ); } ImGui::SameLine(); ImGui::Spacing(); ImGui::SameLine(); if( v->csFree.Val() == 0 ) { TextDisabledUnformatted( "[free]" ); } else { SmallCallstackButton( "free", v->csFree.Val(), idx ); } } } ImGui::EndTable(); } } void View::DrawAllocList() { const auto scale = GetScale(); ImGui::SetNextWindowSize( ImVec2( 1100 * scale, 500 * scale ), ImGuiCond_FirstUseEver ); ImGui::Begin( "Allocations list", &m_memInfo.showAllocList ); if( ImGui::GetCurrentWindowRead()->SkipItems ) { ImGui::End(); return; } std::vector data; auto basePtr = m_worker.GetMemoryNamed( m_memInfo.pool ).data.data(); data.reserve( m_memInfo.allocList.size() ); for( auto& idx : m_memInfo.allocList ) { data.emplace_back( basePtr + idx ); } TextFocused( "Number of allocations:", RealToString( m_memInfo.allocList.size() ) ); ListMemData( data, []( auto v ) { ImGui::Text( "0x%" PRIx64, v->Ptr() ); }, "##allocations", -1, m_memInfo.pool ); ImGui::End(); } }