Extract frame tree functionality from View.

This commit is contained in:
Bartosz Taudul 2022-07-02 14:55:09 +02:00
parent 8147eadaf0
commit 585587fa36
No known key found for this signature in database
GPG Key ID: B7FE2008B7575DF3
4 changed files with 801 additions and 790 deletions

View File

@ -144,6 +144,7 @@
<ClCompile Include="..\..\..\server\TracyView_CpuData.cpp" />
<ClCompile Include="..\..\..\server\TracyView_FindZone.cpp" />
<ClCompile Include="..\..\..\server\TracyView_FrameOverview.cpp" />
<ClCompile Include="..\..\..\server\TracyView_FrameTree.cpp" />
<ClCompile Include="..\..\..\server\TracyView_Memory.cpp" />
<ClCompile Include="..\..\..\server\TracyView_Navigation.cpp" />
<ClCompile Include="..\..\..\server\TracyView_NotificationArea.cpp" />

View File

@ -297,6 +297,9 @@
<ClCompile Include="..\..\..\server\TracyView_NotificationArea.cpp">
<Filter>server</Filter>
</ClCompile>
<ClCompile Include="..\..\..\server\TracyView_FrameTree.cpp">
<Filter>server</Filter>
</ClCompile>
</ItemGroup>
<ItemGroup>
<ClInclude Include="..\..\..\common\tracy_lz4.hpp">

View File

@ -6882,796 +6882,6 @@ void View::DrawWaitStacks()
ImGui::End();
}
template<class T>
static tracy_force_inline T* GetFrameTreeItemNoGroup( unordered_flat_map<uint64_t, T>& tree, CallstackFrameId idx, const Worker& worker )
{
auto it = tree.find( idx.data );
if( it == tree.end() )
{
it = tree.emplace( idx.data, T( idx ) ).first;
}
return &it->second;
}
template<class T>
static tracy_force_inline T* GetFrameTreeItemGroup( unordered_flat_map<uint64_t, T>& tree, CallstackFrameId idx, const Worker& worker )
{
auto frameDataPtr = worker.GetCallstackFrame( idx );
if( !frameDataPtr ) return nullptr;
auto& frameData = *frameDataPtr;
auto& frame = frameData.data[frameData.size-1];
auto fidx = frame.name.Idx();
auto it = tree.find( fidx );
if( it == tree.end() )
{
it = tree.emplace( fidx, T( idx ) ).first;
}
return &it->second;
}
template<class T>
static tracy_force_inline T* GetParentFrameTreeItemGroup( unordered_flat_map<uint64_t, T>& tree, CallstackFrameId idx, const Worker& worker )
{
auto frameDataPtr = idx.custom ? worker.GetParentCallstackFrame( idx ) : worker.GetCallstackFrame( idx );
if( !frameDataPtr ) return nullptr;
auto& frameData = *frameDataPtr;
auto& frame = frameData.data[frameData.size-1];
auto fidx = frame.name.Idx();
auto it = tree.find( fidx );
if( it == tree.end() )
{
it = tree.emplace( fidx, T( idx ) ).first;
}
return &it->second;
}
unordered_flat_map<uint32_t, View::MemPathData> View::GetCallstackPaths( const MemData& mem, MemRange memRange ) const
{
unordered_flat_map<uint32_t, MemPathData> pathSum;
pathSum.reserve( m_worker.GetCallstackPayloadCount() );
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; } );
if( memRange != MemRange::Full )
{
while( it != end )
{
auto& ev = *it++;
if( ev.CsAlloc() == 0 ) continue;
if( ( memRange == MemRange::Inactive ) == ( ev.TimeFree() >= 0 && ev.TimeFree() < m_memInfo.range.max ) ) continue;
auto pit = pathSum.find( ev.CsAlloc() );
if( pit == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
pit->second.cnt++;
pit->second.mem += ev.Size();
}
}
}
else
{
while( it != end )
{
auto& ev = *it++;
if( ev.CsAlloc() == 0 ) continue;
auto pit = pathSum.find( ev.CsAlloc() );
if( pit == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
pit->second.cnt++;
pit->second.mem += ev.Size();
}
}
}
}
}
else
{
if( memRange != MemRange::Full )
{
for( auto& ev : mem.data )
{
if( ev.CsAlloc() == 0 ) continue;
if( ( memRange == MemRange::Inactive ) == ( ev.TimeFree() >= 0 ) ) continue;
auto it = pathSum.find( ev.CsAlloc() );
if( it == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
it->second.cnt++;
it->second.mem += ev.Size();
}
}
}
else
{
for( auto& ev : mem.data )
{
if( ev.CsAlloc() == 0 ) continue;
auto it = pathSum.find( ev.CsAlloc() );
if( it == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
it->second.cnt++;
it->second.mem += ev.Size();
}
}
}
}
return pathSum;
}
unordered_flat_map<uint64_t, MemCallstackFrameTree> View::GetCallstackFrameTreeBottomUp( const MemData& mem ) const
{
unordered_flat_map<uint64_t, MemCallstackFrameTree> root;
auto pathSum = GetCallstackPaths( mem, m_memRangeBottomUp );
if( m_groupCallstackTreeByNameBottomUp )
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
}
else
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetCallstackFrameTreeBottomUp( const unordered_flat_map<uint32_t, uint64_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetParentsCallstackFrameTreeBottomUp( const unordered_flat_map<uint32_t, uint32_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.back();
auto treePtr = GetParentFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetParentFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
unordered_flat_map<uint64_t, MemCallstackFrameTree> View::GetCallstackFrameTreeTopDown( const MemData& mem ) const
{
unordered_flat_map<uint64_t, MemCallstackFrameTree> root;
auto pathSum = GetCallstackPaths( mem, m_memRangeTopDown );
if( m_groupCallstackTreeByNameTopDown )
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
}
else
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetCallstackFrameTreeTopDown( const unordered_flat_map<uint32_t, uint64_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetParentsCallstackFrameTreeTopDown( const unordered_flat_map<uint32_t, uint32_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.front();
auto treePtr = GetParentFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetParentFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
void View::DrawFrameTreeLevel( const unordered_flat_map<uint64_t, MemCallstackFrameTree>& tree, int& idx )
{
auto& io = ImGui::GetIO();
std::vector<unordered_flat_map<uint64_t, MemCallstackFrameTree>::const_iterator> sorted;
sorted.reserve( tree.size() );
for( auto it = tree.begin(); it != tree.end(); ++it )
{
sorted.emplace_back( it );
}
pdqsort_branchless( sorted.begin(), sorted.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs->second.alloc > rhs->second.alloc; } );
int lidx = 0;
for( auto& _v : sorted )
{
auto& v = _v->second;
const auto isKernel = ( m_worker.GetCanonicalPointer( v.frame ) >> 63 ) != 0;
idx++;
auto frameDataPtr = m_worker.GetCallstackFrame( v.frame );
if( frameDataPtr )
{
auto& frameData = *frameDataPtr;
auto frame = frameData.data[frameData.size-1];
bool expand = false;
const auto frameName = m_worker.GetString( frame.name );
if( v.children.empty() )
{
ImGui::Indent( ImGui::GetTreeNodeToLabelSpacing() );
if( frameName[0] == '[' )
{
TextDisabledUnformatted( frameName );
}
else if( isKernel )
{
TextColoredUnformatted( 0xFF8888FF, frameName );
}
else
{
ImGui::TextUnformatted( frameName );
}
ImGui::Unindent( ImGui::GetTreeNodeToLabelSpacing() );
}
else
{
ImGui::PushID( lidx++ );
if( frameName[0] == '[' ) ImGui::PushStyleColor( ImGuiCol_Text, 0x88FFFFFF );
else if( isKernel ) ImGui::PushStyleColor( ImGuiCol_Text, 0xFF8888FF );
if( tree.size() == 1 )
{
expand = ImGui::TreeNodeEx( frameName, ImGuiTreeNodeFlags_DefaultOpen );
}
else
{
expand = ImGui::TreeNode( frameName );
}
if( isKernel || frameName[0] == '[' ) ImGui::PopStyleColor();
ImGui::PopID();
}
if( ImGui::IsItemClicked( 1 ) )
{
auto& mem = m_worker.GetMemoryNamed( m_memInfo.pool ).data;
const auto sz = mem.size();
m_memInfo.showAllocList = true;
m_memInfo.allocList.clear();
for( size_t i=0; i<sz; i++ )
{
if( v.callstacks.find( mem[i].CsAlloc() ) != v.callstacks.end() )
{
m_memInfo.allocList.emplace_back( i );
}
}
}
if( io.KeyCtrl && ImGui::IsItemHovered() )
{
ImGui::BeginTooltip();
TextFocused( "Allocations size:", MemSizeToString( v.alloc ) );
TextFocused( "Allocations count:", RealToString( v.count ) );
TextFocused( "Mean allocation size:", MemSizeToString( v.alloc / v.count ) );
ImGui::SameLine();
ImGui::EndTooltip();
}
if( m_callstackTreeBuzzAnim.Match( idx ) )
{
const auto time = m_callstackTreeBuzzAnim.Time();
const auto indentVal = sin( time * 60.f ) * 10.f * time;
ImGui::SameLine( 0, ImGui::GetStyle().ItemSpacing.x + indentVal );
}
else
{
ImGui::SameLine();
}
const char* fileName = nullptr;
if( frame.line == 0 )
{
if( frameDataPtr->imageName.Active() ) TextDisabledUnformatted( m_worker.GetString( frameDataPtr->imageName ) );
}
else
{
fileName = m_worker.GetString( frame.file );
ImGui::TextDisabled( "%s:%i", fileName, frame.line );
}
if( ImGui::IsItemHovered() )
{
DrawSourceTooltip( fileName, frame.line );
if( ImGui::IsItemClicked( 1 ) )
{
if( !ViewDispatch( fileName, frame.line, frame.symAddr ) )
{
m_callstackTreeBuzzAnim.Enable( idx, 0.5f );
}
}
}
ImGui::SameLine();
if( v.children.empty() )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "%s (%s)", MemSizeToString( v.alloc ), RealToString( v.count ) );
TooltipIfHovered( "Cost in this node" );
}
else
{
uint32_t childCost = 0;
uint64_t childAlloc = 0;
for( auto& c : v.children )
{
childCost += c.second.count;
childAlloc += c.second.alloc;
}
const auto rc = v.count - childCost;
if( rc != 0 )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "%s (%s)", MemSizeToString( v.alloc - childAlloc ), RealToString( rc ) );
TooltipIfHovered( "Cost only in this node" );
ImGui::SameLine();
}
ImGui::TextColored( ImVec4( 0.8, 0.8, 0.2, 1.0 ), "%s (%s)", MemSizeToString( v.alloc ), RealToString( v.count ) );
TooltipIfHovered( "Cost in this node and children" );
}
if( expand )
{
DrawFrameTreeLevel( v.children, idx );
ImGui::TreePop();
}
}
}
}
void View::DrawFrameTreeLevel( const unordered_flat_map<uint64_t, CallstackFrameTree>& tree, int& idx )
{
std::vector<unordered_flat_map<uint64_t, CallstackFrameTree>::const_iterator> sorted;
sorted.reserve( tree.size() );
for( auto it = tree.begin(); it != tree.end(); ++it )
{
sorted.emplace_back( it );
}
pdqsort_branchless( sorted.begin(), sorted.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs->second.count > rhs->second.count; } );
int lidx = 0;
for( auto& _v : sorted )
{
auto& v = _v->second;
const auto isKernel = ( m_worker.GetCanonicalPointer( v.frame ) >> 63 ) != 0;
idx++;
auto frameDataPtr = m_worker.GetCallstackFrame( v.frame );
if( frameDataPtr )
{
auto& frameData = *frameDataPtr;
auto frame = frameData.data[frameData.size-1];
bool expand = false;
const auto frameName = m_worker.GetString( frame.name );
if( v.children.empty() )
{
ImGui::Indent( ImGui::GetTreeNodeToLabelSpacing() );
if( frameName[0] == '[' )
{
TextDisabledUnformatted( frameName );
}
else if( isKernel )
{
TextColoredUnformatted( 0xFF8888FF, frameName );
}
else
{
ImGui::TextUnformatted( frameName );
}
ImGui::Unindent( ImGui::GetTreeNodeToLabelSpacing() );
}
else
{
ImGui::PushID( lidx++ );
if( frameName[0] == '[' ) ImGui::PushStyleColor( ImGuiCol_Text, 0x88FFFFFF );
else if( isKernel ) ImGui::PushStyleColor( ImGuiCol_Text, 0xFF8888FF );
if( tree.size() == 1 )
{
expand = ImGui::TreeNodeEx( frameName, ImGuiTreeNodeFlags_DefaultOpen );
}
else
{
expand = ImGui::TreeNode( frameName );
}
if( isKernel || frameName[0] == '[' ) ImGui::PopStyleColor();
ImGui::PopID();
}
if( m_callstackTreeBuzzAnim.Match( idx ) )
{
const auto time = m_callstackTreeBuzzAnim.Time();
const auto indentVal = sin( time * 60.f ) * 10.f * time;
ImGui::SameLine( 0, ImGui::GetStyle().ItemSpacing.x + indentVal );
}
else
{
ImGui::SameLine();
}
const char* fileName = nullptr;
if( frame.line == 0 )
{
TextDisabledUnformatted( m_worker.GetString( frameDataPtr->imageName ) );
}
else
{
fileName = m_worker.GetString( frame.file );
ImGui::TextDisabled( "%s:%i", fileName, frame.line );
}
if( ImGui::IsItemHovered() )
{
DrawSourceTooltip( fileName, frame.line );
if( ImGui::IsItemClicked( 1 ) )
{
if( !ViewDispatch( fileName, frame.line, frame.symAddr ) )
{
m_callstackTreeBuzzAnim.Enable( idx, 0.5f );
}
}
}
ImGui::SameLine();
if( v.children.empty() )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", RealToString( v.count ) );
TooltipIfHovered( "Cost in this node" );
}
else
{
uint32_t childCost = 0;
for( auto& c : v.children ) childCost += c.second.count;
const auto r = v.count - childCost;
if( r != 0 )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", RealToString( r ) );
TooltipIfHovered( "Cost only in this node" );
ImGui::SameLine();
}
ImGui::TextColored( ImVec4( 0.8, 0.8, 0.2, 1.0 ), "(%s)", RealToString( v.count ) );
TooltipIfHovered( "Cost in this node and children" );
}
if( expand )
{
DrawFrameTreeLevel( v.children, idx );
ImGui::TreePop();
}
}
}
}
void View::DrawParentsFrameTreeLevel( const unordered_flat_map<uint64_t, CallstackFrameTree>& tree, int& idx )
{
std::vector<unordered_flat_map<uint64_t, CallstackFrameTree>::const_iterator> sorted;
sorted.reserve( tree.size() );
for( auto it = tree.begin(); it != tree.end(); ++it )
{
sorted.emplace_back( it );
}
pdqsort_branchless( sorted.begin(), sorted.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs->second.count > rhs->second.count; } );
int lidx = 0;
for( auto& _v : sorted )
{
auto& v = _v->second;
const auto isKernel = ( m_worker.GetCanonicalPointer( v.frame ) >> 63 ) != 0;
idx++;
auto frameDataPtr = v.frame.custom ? m_worker.GetParentCallstackFrame( v.frame ) : m_worker.GetCallstackFrame( v.frame );
if( frameDataPtr )
{
auto& frameData = *frameDataPtr;
auto frame = frameData.data[frameData.size-1];
bool expand = false;
const auto frameName = m_worker.GetString( frame.name );
if( v.children.empty() )
{
ImGui::Indent( ImGui::GetTreeNodeToLabelSpacing() );
if( frameName[0] == '[' )
{
TextDisabledUnformatted( frameName );
}
else if( isKernel )
{
TextColoredUnformatted( 0xFF8888FF, frameName );
}
else
{
ImGui::TextUnformatted( frameName );
}
ImGui::Unindent( ImGui::GetTreeNodeToLabelSpacing() );
}
else
{
ImGui::PushID( lidx++ );
if( frameName[0] == '[' ) ImGui::PushStyleColor( ImGuiCol_Text, 0x88FFFFFF );
else if( isKernel ) ImGui::PushStyleColor( ImGuiCol_Text, 0xFF8888FF );
if( tree.size() == 1 )
{
expand = ImGui::TreeNodeEx( frameName, ImGuiTreeNodeFlags_DefaultOpen );
}
else
{
expand = ImGui::TreeNode( frameName );
}
if( isKernel || frameName[0] == '[' ) ImGui::PopStyleColor();
ImGui::PopID();
}
if( m_callstackTreeBuzzAnim.Match( idx ) )
{
const auto time = m_callstackTreeBuzzAnim.Time();
const auto indentVal = sin( time * 60.f ) * 10.f * time;
ImGui::SameLine( 0, ImGui::GetStyle().ItemSpacing.x + indentVal );
}
else
{
ImGui::SameLine();
}
const char* fileName = nullptr;
if( frame.line == 0 )
{
TextDisabledUnformatted( m_worker.GetString( frameDataPtr->imageName ) );
}
else
{
fileName = m_worker.GetString( frame.file );
ImGui::TextDisabled( "%s:%i", fileName, frame.line );
}
if( ImGui::IsItemHovered() )
{
DrawSourceTooltip( fileName, frame.line );
if( ImGui::IsItemClicked( 1 ) )
{
if( !ViewDispatch( fileName, frame.line, frame.symAddr ) )
{
m_callstackTreeBuzzAnim.Enable( idx, 0.5f );
}
}
}
ImGui::SameLine();
if( v.children.empty() )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", m_statSampleTime ? TimeToString( m_worker.GetSamplingPeriod() * v.count ) : RealToString( v.count ) );
TooltipIfHovered( "Cost in this node" );
}
else
{
uint32_t childCost = 0;
for( auto& c : v.children ) childCost += c.second.count;
const auto r = v.count - childCost;
if( r != 0 )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", m_statSampleTime ? TimeToString( m_worker.GetSamplingPeriod() * r ) : RealToString( r ) );
TooltipIfHovered( "Cost only in this node" );
ImGui::SameLine();
}
ImGui::TextColored( ImVec4( 0.8, 0.8, 0.2, 1.0 ), "(%s)", m_statSampleTime ? TimeToString( m_worker.GetSamplingPeriod() * v.count ) : RealToString( v.count ) );
TooltipIfHovered( "Cost in this node and children" );
}
if( expand )
{
DrawParentsFrameTreeLevel( v.children, idx );
ImGui::TreePop();
}
}
}
}
void View::DrawAllocList()
{
const auto scale = GetScale();

View File

@ -0,0 +1,797 @@
#include "TracyPrint.hpp"
#include "TracyView.hpp"
namespace tracy
{
template<class T>
static tracy_force_inline T* GetFrameTreeItemNoGroup( unordered_flat_map<uint64_t, T>& tree, CallstackFrameId idx, const Worker& worker )
{
auto it = tree.find( idx.data );
if( it == tree.end() )
{
it = tree.emplace( idx.data, T( idx ) ).first;
}
return &it->second;
}
template<class T>
static tracy_force_inline T* GetFrameTreeItemGroup( unordered_flat_map<uint64_t, T>& tree, CallstackFrameId idx, const Worker& worker )
{
auto frameDataPtr = worker.GetCallstackFrame( idx );
if( !frameDataPtr ) return nullptr;
auto& frameData = *frameDataPtr;
auto& frame = frameData.data[frameData.size-1];
auto fidx = frame.name.Idx();
auto it = tree.find( fidx );
if( it == tree.end() )
{
it = tree.emplace( fidx, T( idx ) ).first;
}
return &it->second;
}
template<class T>
static tracy_force_inline T* GetParentFrameTreeItemGroup( unordered_flat_map<uint64_t, T>& tree, CallstackFrameId idx, const Worker& worker )
{
auto frameDataPtr = idx.custom ? worker.GetParentCallstackFrame( idx ) : worker.GetCallstackFrame( idx );
if( !frameDataPtr ) return nullptr;
auto& frameData = *frameDataPtr;
auto& frame = frameData.data[frameData.size-1];
auto fidx = frame.name.Idx();
auto it = tree.find( fidx );
if( it == tree.end() )
{
it = tree.emplace( fidx, T( idx ) ).first;
}
return &it->second;
}
unordered_flat_map<uint32_t, View::MemPathData> View::GetCallstackPaths( const MemData& mem, MemRange memRange ) const
{
unordered_flat_map<uint32_t, MemPathData> pathSum;
pathSum.reserve( m_worker.GetCallstackPayloadCount() );
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; } );
if( memRange != MemRange::Full )
{
while( it != end )
{
auto& ev = *it++;
if( ev.CsAlloc() == 0 ) continue;
if( ( memRange == MemRange::Inactive ) == ( ev.TimeFree() >= 0 && ev.TimeFree() < m_memInfo.range.max ) ) continue;
auto pit = pathSum.find( ev.CsAlloc() );
if( pit == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
pit->second.cnt++;
pit->second.mem += ev.Size();
}
}
}
else
{
while( it != end )
{
auto& ev = *it++;
if( ev.CsAlloc() == 0 ) continue;
auto pit = pathSum.find( ev.CsAlloc() );
if( pit == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
pit->second.cnt++;
pit->second.mem += ev.Size();
}
}
}
}
}
else
{
if( memRange != MemRange::Full )
{
for( auto& ev : mem.data )
{
if( ev.CsAlloc() == 0 ) continue;
if( ( memRange == MemRange::Inactive ) == ( ev.TimeFree() >= 0 ) ) continue;
auto it = pathSum.find( ev.CsAlloc() );
if( it == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
it->second.cnt++;
it->second.mem += ev.Size();
}
}
}
else
{
for( auto& ev : mem.data )
{
if( ev.CsAlloc() == 0 ) continue;
auto it = pathSum.find( ev.CsAlloc() );
if( it == pathSum.end() )
{
pathSum.emplace( ev.CsAlloc(), MemPathData { 1, ev.Size() } );
}
else
{
it->second.cnt++;
it->second.mem += ev.Size();
}
}
}
}
return pathSum;
}
unordered_flat_map<uint64_t, MemCallstackFrameTree> View::GetCallstackFrameTreeBottomUp( const MemData& mem ) const
{
unordered_flat_map<uint64_t, MemCallstackFrameTree> root;
auto pathSum = GetCallstackPaths( mem, m_memRangeBottomUp );
if( m_groupCallstackTreeByNameBottomUp )
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
}
else
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetCallstackFrameTreeBottomUp( const unordered_flat_map<uint32_t, uint64_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetParentsCallstackFrameTreeBottomUp( const unordered_flat_map<uint32_t, uint32_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.back();
auto treePtr = GetParentFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetParentFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.back();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( int i = int( cs.size() ) - 2; i >= 0; i-- )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
unordered_flat_map<uint64_t, MemCallstackFrameTree> View::GetCallstackFrameTreeTopDown( const MemData& mem ) const
{
unordered_flat_map<uint64_t, MemCallstackFrameTree> root;
auto pathSum = GetCallstackPaths( mem, m_memRangeTopDown );
if( m_groupCallstackTreeByNameTopDown )
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
}
else
{
for( auto& path : pathSum )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second.cnt;
treePtr->alloc += path.second.mem;
treePtr->callstacks.emplace( path.first );
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetCallstackFrameTreeTopDown( const unordered_flat_map<uint32_t, uint64_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
unordered_flat_map<uint64_t, CallstackFrameTree> View::GetParentsCallstackFrameTreeTopDown( const unordered_flat_map<uint32_t, uint32_t>& stacks, bool group ) const
{
unordered_flat_map<uint64_t, CallstackFrameTree> root;
if( group )
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.front();
auto treePtr = GetParentFrameTreeItemGroup( root, base, m_worker );
if( treePtr )
{
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetParentFrameTreeItemGroup( treePtr->children, cs[i], m_worker );
if( !treePtr ) break;
treePtr->count += path.second;
}
}
}
}
else
{
for( auto& path : stacks )
{
auto& cs = m_worker.GetParentCallstack( path.first );
auto base = cs.front();
auto treePtr = GetFrameTreeItemNoGroup( root, base, m_worker );
treePtr->count += path.second;
for( uint16_t i = 1; i < cs.size(); i++ )
{
treePtr = GetFrameTreeItemNoGroup( treePtr->children, cs[i], m_worker );
treePtr->count += path.second;
}
}
}
return root;
}
void View::DrawFrameTreeLevel( const unordered_flat_map<uint64_t, MemCallstackFrameTree>& tree, int& idx )
{
auto& io = ImGui::GetIO();
std::vector<unordered_flat_map<uint64_t, MemCallstackFrameTree>::const_iterator> sorted;
sorted.reserve( tree.size() );
for( auto it = tree.begin(); it != tree.end(); ++it )
{
sorted.emplace_back( it );
}
pdqsort_branchless( sorted.begin(), sorted.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs->second.alloc > rhs->second.alloc; } );
int lidx = 0;
for( auto& _v : sorted )
{
auto& v = _v->second;
const auto isKernel = ( m_worker.GetCanonicalPointer( v.frame ) >> 63 ) != 0;
idx++;
auto frameDataPtr = m_worker.GetCallstackFrame( v.frame );
if( frameDataPtr )
{
auto& frameData = *frameDataPtr;
auto frame = frameData.data[frameData.size-1];
bool expand = false;
const auto frameName = m_worker.GetString( frame.name );
if( v.children.empty() )
{
ImGui::Indent( ImGui::GetTreeNodeToLabelSpacing() );
if( frameName[0] == '[' )
{
TextDisabledUnformatted( frameName );
}
else if( isKernel )
{
TextColoredUnformatted( 0xFF8888FF, frameName );
}
else
{
ImGui::TextUnformatted( frameName );
}
ImGui::Unindent( ImGui::GetTreeNodeToLabelSpacing() );
}
else
{
ImGui::PushID( lidx++ );
if( frameName[0] == '[' ) ImGui::PushStyleColor( ImGuiCol_Text, 0x88FFFFFF );
else if( isKernel ) ImGui::PushStyleColor( ImGuiCol_Text, 0xFF8888FF );
if( tree.size() == 1 )
{
expand = ImGui::TreeNodeEx( frameName, ImGuiTreeNodeFlags_DefaultOpen );
}
else
{
expand = ImGui::TreeNode( frameName );
}
if( isKernel || frameName[0] == '[' ) ImGui::PopStyleColor();
ImGui::PopID();
}
if( ImGui::IsItemClicked( 1 ) )
{
auto& mem = m_worker.GetMemoryNamed( m_memInfo.pool ).data;
const auto sz = mem.size();
m_memInfo.showAllocList = true;
m_memInfo.allocList.clear();
for( size_t i=0; i<sz; i++ )
{
if( v.callstacks.find( mem[i].CsAlloc() ) != v.callstacks.end() )
{
m_memInfo.allocList.emplace_back( i );
}
}
}
if( io.KeyCtrl && ImGui::IsItemHovered() )
{
ImGui::BeginTooltip();
TextFocused( "Allocations size:", MemSizeToString( v.alloc ) );
TextFocused( "Allocations count:", RealToString( v.count ) );
TextFocused( "Mean allocation size:", MemSizeToString( v.alloc / v.count ) );
ImGui::SameLine();
ImGui::EndTooltip();
}
if( m_callstackTreeBuzzAnim.Match( idx ) )
{
const auto time = m_callstackTreeBuzzAnim.Time();
const auto indentVal = sin( time * 60.f ) * 10.f * time;
ImGui::SameLine( 0, ImGui::GetStyle().ItemSpacing.x + indentVal );
}
else
{
ImGui::SameLine();
}
const char* fileName = nullptr;
if( frame.line == 0 )
{
if( frameDataPtr->imageName.Active() ) TextDisabledUnformatted( m_worker.GetString( frameDataPtr->imageName ) );
}
else
{
fileName = m_worker.GetString( frame.file );
ImGui::TextDisabled( "%s:%i", fileName, frame.line );
}
if( ImGui::IsItemHovered() )
{
DrawSourceTooltip( fileName, frame.line );
if( ImGui::IsItemClicked( 1 ) )
{
if( !ViewDispatch( fileName, frame.line, frame.symAddr ) )
{
m_callstackTreeBuzzAnim.Enable( idx, 0.5f );
}
}
}
ImGui::SameLine();
if( v.children.empty() )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "%s (%s)", MemSizeToString( v.alloc ), RealToString( v.count ) );
TooltipIfHovered( "Cost in this node" );
}
else
{
uint32_t childCost = 0;
uint64_t childAlloc = 0;
for( auto& c : v.children )
{
childCost += c.second.count;
childAlloc += c.second.alloc;
}
const auto rc = v.count - childCost;
if( rc != 0 )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "%s (%s)", MemSizeToString( v.alloc - childAlloc ), RealToString( rc ) );
TooltipIfHovered( "Cost only in this node" );
ImGui::SameLine();
}
ImGui::TextColored( ImVec4( 0.8, 0.8, 0.2, 1.0 ), "%s (%s)", MemSizeToString( v.alloc ), RealToString( v.count ) );
TooltipIfHovered( "Cost in this node and children" );
}
if( expand )
{
DrawFrameTreeLevel( v.children, idx );
ImGui::TreePop();
}
}
}
}
void View::DrawFrameTreeLevel( const unordered_flat_map<uint64_t, CallstackFrameTree>& tree, int& idx )
{
std::vector<unordered_flat_map<uint64_t, CallstackFrameTree>::const_iterator> sorted;
sorted.reserve( tree.size() );
for( auto it = tree.begin(); it != tree.end(); ++it )
{
sorted.emplace_back( it );
}
pdqsort_branchless( sorted.begin(), sorted.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs->second.count > rhs->second.count; } );
int lidx = 0;
for( auto& _v : sorted )
{
auto& v = _v->second;
const auto isKernel = ( m_worker.GetCanonicalPointer( v.frame ) >> 63 ) != 0;
idx++;
auto frameDataPtr = m_worker.GetCallstackFrame( v.frame );
if( frameDataPtr )
{
auto& frameData = *frameDataPtr;
auto frame = frameData.data[frameData.size-1];
bool expand = false;
const auto frameName = m_worker.GetString( frame.name );
if( v.children.empty() )
{
ImGui::Indent( ImGui::GetTreeNodeToLabelSpacing() );
if( frameName[0] == '[' )
{
TextDisabledUnformatted( frameName );
}
else if( isKernel )
{
TextColoredUnformatted( 0xFF8888FF, frameName );
}
else
{
ImGui::TextUnformatted( frameName );
}
ImGui::Unindent( ImGui::GetTreeNodeToLabelSpacing() );
}
else
{
ImGui::PushID( lidx++ );
if( frameName[0] == '[' ) ImGui::PushStyleColor( ImGuiCol_Text, 0x88FFFFFF );
else if( isKernel ) ImGui::PushStyleColor( ImGuiCol_Text, 0xFF8888FF );
if( tree.size() == 1 )
{
expand = ImGui::TreeNodeEx( frameName, ImGuiTreeNodeFlags_DefaultOpen );
}
else
{
expand = ImGui::TreeNode( frameName );
}
if( isKernel || frameName[0] == '[' ) ImGui::PopStyleColor();
ImGui::PopID();
}
if( m_callstackTreeBuzzAnim.Match( idx ) )
{
const auto time = m_callstackTreeBuzzAnim.Time();
const auto indentVal = sin( time * 60.f ) * 10.f * time;
ImGui::SameLine( 0, ImGui::GetStyle().ItemSpacing.x + indentVal );
}
else
{
ImGui::SameLine();
}
const char* fileName = nullptr;
if( frame.line == 0 )
{
TextDisabledUnformatted( m_worker.GetString( frameDataPtr->imageName ) );
}
else
{
fileName = m_worker.GetString( frame.file );
ImGui::TextDisabled( "%s:%i", fileName, frame.line );
}
if( ImGui::IsItemHovered() )
{
DrawSourceTooltip( fileName, frame.line );
if( ImGui::IsItemClicked( 1 ) )
{
if( !ViewDispatch( fileName, frame.line, frame.symAddr ) )
{
m_callstackTreeBuzzAnim.Enable( idx, 0.5f );
}
}
}
ImGui::SameLine();
if( v.children.empty() )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", RealToString( v.count ) );
TooltipIfHovered( "Cost in this node" );
}
else
{
uint32_t childCost = 0;
for( auto& c : v.children ) childCost += c.second.count;
const auto r = v.count - childCost;
if( r != 0 )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", RealToString( r ) );
TooltipIfHovered( "Cost only in this node" );
ImGui::SameLine();
}
ImGui::TextColored( ImVec4( 0.8, 0.8, 0.2, 1.0 ), "(%s)", RealToString( v.count ) );
TooltipIfHovered( "Cost in this node and children" );
}
if( expand )
{
DrawFrameTreeLevel( v.children, idx );
ImGui::TreePop();
}
}
}
}
void View::DrawParentsFrameTreeLevel( const unordered_flat_map<uint64_t, CallstackFrameTree>& tree, int& idx )
{
std::vector<unordered_flat_map<uint64_t, CallstackFrameTree>::const_iterator> sorted;
sorted.reserve( tree.size() );
for( auto it = tree.begin(); it != tree.end(); ++it )
{
sorted.emplace_back( it );
}
pdqsort_branchless( sorted.begin(), sorted.end(), [] ( const auto& lhs, const auto& rhs ) { return lhs->second.count > rhs->second.count; } );
int lidx = 0;
for( auto& _v : sorted )
{
auto& v = _v->second;
const auto isKernel = ( m_worker.GetCanonicalPointer( v.frame ) >> 63 ) != 0;
idx++;
auto frameDataPtr = v.frame.custom ? m_worker.GetParentCallstackFrame( v.frame ) : m_worker.GetCallstackFrame( v.frame );
if( frameDataPtr )
{
auto& frameData = *frameDataPtr;
auto frame = frameData.data[frameData.size-1];
bool expand = false;
const auto frameName = m_worker.GetString( frame.name );
if( v.children.empty() )
{
ImGui::Indent( ImGui::GetTreeNodeToLabelSpacing() );
if( frameName[0] == '[' )
{
TextDisabledUnformatted( frameName );
}
else if( isKernel )
{
TextColoredUnformatted( 0xFF8888FF, frameName );
}
else
{
ImGui::TextUnformatted( frameName );
}
ImGui::Unindent( ImGui::GetTreeNodeToLabelSpacing() );
}
else
{
ImGui::PushID( lidx++ );
if( frameName[0] == '[' ) ImGui::PushStyleColor( ImGuiCol_Text, 0x88FFFFFF );
else if( isKernel ) ImGui::PushStyleColor( ImGuiCol_Text, 0xFF8888FF );
if( tree.size() == 1 )
{
expand = ImGui::TreeNodeEx( frameName, ImGuiTreeNodeFlags_DefaultOpen );
}
else
{
expand = ImGui::TreeNode( frameName );
}
if( isKernel || frameName[0] == '[' ) ImGui::PopStyleColor();
ImGui::PopID();
}
if( m_callstackTreeBuzzAnim.Match( idx ) )
{
const auto time = m_callstackTreeBuzzAnim.Time();
const auto indentVal = sin( time * 60.f ) * 10.f * time;
ImGui::SameLine( 0, ImGui::GetStyle().ItemSpacing.x + indentVal );
}
else
{
ImGui::SameLine();
}
const char* fileName = nullptr;
if( frame.line == 0 )
{
TextDisabledUnformatted( m_worker.GetString( frameDataPtr->imageName ) );
}
else
{
fileName = m_worker.GetString( frame.file );
ImGui::TextDisabled( "%s:%i", fileName, frame.line );
}
if( ImGui::IsItemHovered() )
{
DrawSourceTooltip( fileName, frame.line );
if( ImGui::IsItemClicked( 1 ) )
{
if( !ViewDispatch( fileName, frame.line, frame.symAddr ) )
{
m_callstackTreeBuzzAnim.Enable( idx, 0.5f );
}
}
}
ImGui::SameLine();
if( v.children.empty() )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", m_statSampleTime ? TimeToString( m_worker.GetSamplingPeriod() * v.count ) : RealToString( v.count ) );
TooltipIfHovered( "Cost in this node" );
}
else
{
uint32_t childCost = 0;
for( auto& c : v.children ) childCost += c.second.count;
const auto r = v.count - childCost;
if( r != 0 )
{
ImGui::TextColored( ImVec4( 0.2, 0.8, 0.8, 1.0 ), "(%s)", m_statSampleTime ? TimeToString( m_worker.GetSamplingPeriod() * r ) : RealToString( r ) );
TooltipIfHovered( "Cost only in this node" );
ImGui::SameLine();
}
ImGui::TextColored( ImVec4( 0.8, 0.8, 0.2, 1.0 ), "(%s)", m_statSampleTime ? TimeToString( m_worker.GetSamplingPeriod() * v.count ) : RealToString( v.count ) );
TooltipIfHovered( "Cost in this node and children" );
}
if( expand )
{
DrawParentsFrameTreeLevel( v.children, idx );
ImGui::TreePop();
}
}
}
}
}