tracy/server/TracyTimelineItemThread.cpp

#include <algorithm>
#include <limits>

#include "TracyImGui.hpp"
#include "TracyMouse.hpp"
#include "TracyPrint.hpp"
#include "TracyTimelineContext.hpp"
#include "TracyTimelineItemThread.hpp"
#include "TracyView.hpp"
#include "TracyWorker.hpp"

namespace tracy
{

constexpr float MinVisSize = 3;
constexpr float MinCtxSize = 4;


TimelineItemThread::TimelineItemThread( View& view, Worker& worker, const ThreadData* thread )
    : TimelineItem( view, worker, thread, true )
    , m_thread( thread )
    , m_ghost( false )
{
    auto name = worker.GetThreadName( thread->id );
    if( strncmp( name, "Tracy ", 6 ) == 0 )
    {
        m_showFull = false;
    }
}

bool TimelineItemThread::IsEmpty() const
{
    auto& crash = m_worker.GetCrashEvent();
    return crash.thread != m_thread->id &&
        m_thread->timeline.empty() &&
        m_thread->messages.empty() &&
        m_thread->ghostZones.empty();
}

uint32_t TimelineItemThread::HeaderColor() const
{
    auto& crash = m_worker.GetCrashEvent();
    if( crash.thread == m_thread->id ) return 0xFF2222FF;
    if( m_thread->isFiber ) return 0xFF88FF88;
    return 0xFFFFFFFF;
}

uint32_t TimelineItemThread::HeaderColorInactive() const
{
    auto& crash = m_worker.GetCrashEvent();
    if( crash.thread == m_thread->id ) return 0xFF111188;
    if( m_thread->isFiber ) return 0xFF448844;
    return 0xFF888888;
}

uint32_t TimelineItemThread::HeaderLineColor() const
{
    return 0x33FFFFFF;
}

const char* TimelineItemThread::HeaderLabel() const
{
    return m_worker.GetThreadName( m_thread->id );
}

int64_t TimelineItemThread::RangeBegin() const
{
    int64_t first = std::numeric_limits<int64_t>::max();
    const auto ctx = m_worker.GetContextSwitchData( m_thread->id );
    if( ctx && !ctx->v.empty() )
    {
        first = ctx->v.begin()->Start();
    }
    if( !m_thread->timeline.empty() )
    {
        if( m_thread->timeline.is_magic() )
        {
            auto& tl = *((Vector<ZoneEvent>*)&m_thread->timeline);
            first = std::min( first, tl.front().Start() );
        }
        else
        {
            first = std::min( first, m_thread->timeline.front()->Start() );
        }
    }
    if( !m_thread->messages.empty() )
    {
        first = std::min( first, m_thread->messages.front()->time );
    }
    for( const auto& lock : m_worker.GetLockMap() )
    {
        const auto& lockmap = *lock.second;
        if( !lockmap.valid ) continue;
        auto it = lockmap.threadMap.find( m_thread->id );
        if( it == lockmap.threadMap.end() ) continue;
        const auto thread = it->second;
        auto lptr = lockmap.timeline.data();
        while( lptr->ptr->thread != thread ) lptr++;
        if( lptr->ptr->Time() < first ) first = lptr->ptr->Time();
    }
    return first;
}

int64_t TimelineItemThread::RangeEnd() const
{
    int64_t last = -1;
    const auto ctx = m_worker.GetContextSwitchData( m_thread->id );
    if( ctx && !ctx->v.empty() )
    {
        const auto& back = ctx->v.back();
        last = back.IsEndValid() ? back.End() : back.Start();
    }
    if( !m_thread->timeline.empty() )
    {
        if( m_thread->timeline.is_magic() )
        {
            auto& tl = *((Vector<ZoneEvent>*)&m_thread->timeline);
            last = std::max( last, m_worker.GetZoneEnd( tl.back() ) );
        }
        else
        {
            last = std::max( last, m_worker.GetZoneEnd( *m_thread->timeline.back() ) );
        }
    }
    if( !m_thread->messages.empty() )
    {
        last = std::max( last, m_thread->messages.back()->time );
    }
    for( const auto& lock : m_worker.GetLockMap() )
    {
        const auto& lockmap = *lock.second;
        if( !lockmap.valid ) continue;
        auto it = lockmap.threadMap.find( m_thread->id );
        if( it == lockmap.threadMap.end() ) continue;
        const auto thread = it->second;
        auto eptr = lockmap.timeline.data() + lockmap.timeline.size() - 1;
        while( eptr->ptr->thread != thread ) eptr--;
        if( eptr->ptr->Time() > last ) last = eptr->ptr->Time();
    }
    return last;
}

void TimelineItemThread::HeaderTooltip( const char* label ) const
{
    m_view.HighlightThread( m_thread->id );

    ImGui::BeginTooltip();
    SmallColorBox( GetThreadColor( m_thread->id, 0, m_view.GetViewData().dynamicColors ) );
    ImGui::SameLine();
    ImGui::TextUnformatted( m_worker.GetThreadName( m_thread->id ) );
    ImGui::SameLine();
    ImGui::TextDisabled( "(%s)", RealToString( m_thread->id ) );
    auto& crash = m_worker.GetCrashEvent();
    if( crash.thread == m_thread->id )
    {
        ImGui::SameLine();
        TextColoredUnformatted( ImVec4( 1.f, 0.2f, 0.2f, 1.f ), ICON_FA_SKULL " Crashed" );
    }
    if( m_thread->isFiber )
    {
        ImGui::SameLine();
        TextColoredUnformatted( ImVec4( 0.2f, 0.6f, 0.2f, 1.f ), "Fiber" );
    }

    const auto ctx = m_worker.GetContextSwitchData( m_thread->id );
    const auto first = RangeBegin();
    const auto last = RangeEnd();

    ImGui::Separator();

    size_t lockCnt = 0;
    for( const auto& lock : m_worker.GetLockMap() )
    {
        const auto& lockmap = *lock.second;
        if( !lockmap.valid ) continue;
        auto it = lockmap.threadMap.find( m_thread->id );
        if( it == lockmap.threadMap.end() ) continue;
        lockCnt++;
    }

    if( last >= 0 )
    {
        const auto lifetime = last - first;
        const auto traceLen = m_worker.GetLastTime() - m_worker.GetFirstTime();

        TextFocused( "Appeared at", TimeToString( first ) );
        TextFocused( "Last event at", TimeToString( last ) );
        TextFocused( "Lifetime:", TimeToString( lifetime ) );
        ImGui::SameLine();
        char buf[64];
        PrintStringPercent( buf, lifetime / double( traceLen ) * 100 );
        TextDisabledUnformatted( buf );

        if( ctx )
        {
            TextFocused( "Time in running state:", TimeToString( ctx->runningTime ) );
            ImGui::SameLine();
            PrintStringPercent( buf, ctx->runningTime / double( lifetime ) * 100 );
            TextDisabledUnformatted( buf );
        }
    }

    ImGui::Separator();
    if( !m_thread->timeline.empty() )
    {
        TextFocused( "Zone count:", RealToString( m_thread->count ) );
        TextFocused( "Top-level zones:", RealToString( m_thread->timeline.size() ) );
    }
    if( !m_thread->messages.empty() )
    {
        TextFocused( "Messages:", RealToString( m_thread->messages.size() ) );
    }
    if( lockCnt != 0 )
    {
        TextFocused( "Locks:", RealToString( lockCnt ) );
    }
    if( ctx )
    {
        TextFocused( "Running state regions:", RealToString( ctx->v.size() ) );
    }
    if( !m_thread->samples.empty() )
    {
        TextFocused( "Call stack samples:", RealToString( m_thread->samples.size() ) );
        if( m_thread->kernelSampleCnt != 0 )
        {
            TextFocused( "Kernel samples:", RealToString( m_thread->kernelSampleCnt ) );
            ImGui::SameLine();
            ImGui::TextDisabled( "(%.2f%%)", 100.f * m_thread->kernelSampleCnt / m_thread->samples.size() );
        }
    }
    ImGui::EndTooltip();
}

void TimelineItemThread::HeaderExtraContents( const TimelineContext& ctx, int offset, float labelWidth )
{
    m_view.DrawThreadMessages( ctx, *m_thread, offset );

#ifndef TRACY_NO_STATISTICS
    const bool hasGhostZones = m_worker.AreGhostZonesReady() && !m_thread->ghostZones.empty();
    if( hasGhostZones && !m_thread->timeline.empty() )
    {
        auto draw = ImGui::GetWindowDrawList();
        const auto ty = ImGui::GetTextLineHeight();

        const auto color = m_ghost ? 0xFFAA9999 : 0x88AA7777;
        draw->AddText( ctx.wpos + ImVec2( 1.5f * ty + labelWidth, offset ), color, ICON_FA_GHOST );
        float ghostSz = ImGui::CalcTextSize( ICON_FA_GHOST ).x;

        if( ctx.hover && ImGui::IsMouseHoveringRect( ctx.wpos + ImVec2( 1.5f * ty + labelWidth, offset ), ctx.wpos + ImVec2( 1.5f * ty + labelWidth + ghostSz, offset + ty ) ) )
        {
            if( IsMouseClicked( 0 ) )
            {
                m_ghost = !m_ghost;
            }
        }
    }
#endif
}

bool TimelineItemThread::DrawContents( const TimelineContext& ctx, int& offset )
{
    const auto res = m_view.DrawThread( ctx, *m_thread, m_draw, m_ctxDraw, offset, m_depth );
    if( !res )
    {
        auto& crash = m_worker.GetCrashEvent();
        return crash.thread == m_thread->id;
    }
    return true;
}

void TimelineItemThread::DrawOverlay( const ImVec2& ul, const ImVec2& dr )
{
    m_view.DrawThreadOverlays( *m_thread, ul, dr );
}

void TimelineItemThread::DrawFinished()
{
    m_ctxDraw.clear();
    m_draw.clear();
}

void TimelineItemThread::Preprocess( const TimelineContext& ctx, TaskDispatch& td )
{
    assert( m_ctxDraw.empty() );
    assert( m_draw.empty() );

    td.Queue( [this, &ctx] {
#ifndef TRACY_NO_STATISTICS
        if( m_worker.AreGhostZonesReady() && ( m_ghost || ( m_view.GetViewData().ghostZones && m_thread->timeline.empty() ) ) )
        {
            m_depth = PreprocessGhostLevel( ctx, m_thread->ghostZones, 0 );
        }
        else
#endif
        {
            m_depth = PreprocessZoneLevel( ctx, m_thread->timeline, 0 );
        }
    } );

    if( m_view.GetViewData().drawContextSwitches )
    {
        auto ctxSwitch = m_worker.GetContextSwitchData( m_thread->id );
        if( ctxSwitch )
        {
            td.Queue( [this, &ctx, ctxSwitch] {
                PreprocessContextSwitches( ctx, *ctxSwitch );
            } );
        }
    }
}

#ifndef TRACY_NO_STATISTICS
int TimelineItemThread::PreprocessGhostLevel( const TimelineContext& ctx, const Vector<GhostZone>& vec, int depth )
{
    const auto pxns = ctx.pxns;
    const auto nspx = ctx.nspx;
    const auto vStart = ctx.vStart;
    const auto vEnd = ctx.vEnd;

    auto it = std::lower_bound( vec.begin(), vec.end(), std::max<int64_t>( 0, vStart - 2 * MinVisSize * nspx ), [] ( const auto& l, const auto& r ) { return l.end.Val() < r; } );
    if( it == vec.end() ) return depth;

    const auto zitend = std::lower_bound( it, vec.end(), vEnd, [] ( const auto& l, const auto& r ) { return l.start.Val() < r; } );
    if( it == zitend ) return depth;
    if( (zitend-1)->end.Val() < vStart ) return depth;

    const auto MinVisNs = MinVisSize * nspx;
    int maxdepth = depth + 1;

    while( it < zitend )
    {
        auto& ev = *it;
        const auto end = ev.end.Val();
        const auto zsz = std::max( ( end - ev.start.Val() ) * pxns, pxns * 0.5 );
        if( zsz < MinVisSize )
        {
            auto px1ns = ev.end.Val() - vStart;
            auto rend = end;
            auto nextTime = end + MinVisNs;
            for(;;)
            {
                const auto prevIt = it;
                it = std::lower_bound( it, zitend, nextTime, [] ( const auto& l, const auto& r ) { return l.end.Val() < r; } );
                if( it == prevIt ) ++it;
                if( it == zitend ) break;
                const auto nend = it->end.Val();
                const auto nsnext = nend - vStart;
                if( nsnext - px1ns >= MinVisNs * 2 ) break;
                px1ns = nsnext;
                rend = nend;
                nextTime = nend + nspx;
            }
            m_draw.emplace_back( TimelineDraw { TimelineDrawType::GhostFolded, uint16_t( depth ), (void**)&ev, rend } );
        }
        else
        {
            if( ev.child >= 0 )
            {
                const auto d = PreprocessGhostLevel( ctx, m_worker.GetGhostChildren( ev.child ), depth + 1 );
                if( d > maxdepth ) maxdepth = d;
            }
            m_draw.emplace_back( TimelineDraw { TimelineDrawType::Ghost, uint16_t( depth ), (void**)&ev } );
            ++it;
        }
    }

    return maxdepth;
}
#endif

int TimelineItemThread::PreprocessZoneLevel( const TimelineContext& ctx, const Vector<short_ptr<ZoneEvent>>& vec, int depth )
{
    if( vec.is_magic() )
    {
        return PreprocessZoneLevel<VectorAdapterDirect<ZoneEvent>>( ctx, *(Vector<ZoneEvent>*)( &vec ), depth );
    }
    else
    {
        return PreprocessZoneLevel<VectorAdapterPointer<ZoneEvent>>( ctx, vec, depth );
    }
}

template<typename Adapter, typename V>
int TimelineItemThread::PreprocessZoneLevel( const TimelineContext& ctx, const V& vec, int depth )
{
    const auto delay = m_worker.GetDelay();
    const auto resolution = m_worker.GetResolution();
    const auto vStart = ctx.vStart;
    const auto vEnd = ctx.vEnd;
    const auto nspx = ctx.nspx;
    const auto pxns = ctx.pxns;

    // cast to uint64_t, so that unended zones (end = -1) are still drawn
    auto it = std::lower_bound( vec.begin(), vec.end(), std::max<int64_t>( 0, vStart - std::max<int64_t>( delay, 2 * MinVisSize * nspx ) ), [] ( const auto& l, const auto& r ) { Adapter a; return (uint64_t)a(l).End() < (uint64_t)r; } );
    if( it == vec.end() ) return depth;

    const auto zitend = std::lower_bound( it, vec.end(), vEnd + resolution, [] ( const auto& l, const auto& r ) { Adapter a; return a(l).Start() < r; } );
    if( it == zitend ) return depth;
    Adapter a;
    if( !a(*it).IsEndValid() && m_worker.GetZoneEnd( a(*it) ) < vStart ) return depth;
    if( m_worker.GetZoneEnd( a(*(zitend-1)) ) < vStart ) return depth;

    const auto MinVisNs = MinVisSize * nspx;
    int maxdepth = depth + 1;

    while( it < zitend )
    {
        auto& ev = a(*it);
        const auto end = m_worker.GetZoneEnd( ev );
        const auto zsz = std::max( ( end - ev.Start() ) * pxns, pxns * 0.5 );
        if( zsz < MinVisSize )
        {
            int num = 0;
            auto px1ns = end - vStart;
            auto rend = end;
            auto nextTime = end + MinVisNs;
            for(;;)
            {
                const auto prevIt = it;
                it = std::lower_bound( it, zitend, nextTime, [] ( const auto& l, const auto& r ) { Adapter a; return (uint64_t)a(l).End() < (uint64_t)r; } );
                if( it == prevIt ) ++it;
                num += std::distance( prevIt, it );
                if( it == zitend ) break;
                const auto nend = m_worker.GetZoneEnd( a(*it) );
                const auto nsnext = nend - vStart;
                if( nsnext - px1ns >= MinVisNs * 2 ) break;
                px1ns = nsnext;
                rend = nend;
                nextTime = nend + nspx;
            }
            m_draw.emplace_back( TimelineDraw { TimelineDrawType::Folded, uint16_t( depth ), (void**)&ev, rend, num } );
        }
        else
        {
            if( ev.HasChildren() )
            {
                const auto d = PreprocessZoneLevel( ctx, m_worker.GetZoneChildren( ev.Child() ), depth + 1 );
                if( d > maxdepth ) maxdepth = d;
            }
            m_draw.emplace_back( TimelineDraw { TimelineDrawType::Zone, uint16_t( depth ), (void**)&ev } );
            ++it;
        }
    }

    return maxdepth;
}

void TimelineItemThread::PreprocessContextSwitches( const TimelineContext& ctx, const ContextSwitch& ctxSwitch )
{
    const auto w = ctx.w;
    const auto pxns = ctx.pxns;
    const auto nspx = ctx.nspx;
    const auto vStart = ctx.vStart;
    const auto vEnd = ctx.vEnd;

    auto& vec = ctxSwitch.v;
    auto it = std::lower_bound( vec.begin(), vec.end(), std::max<int64_t>( 0, vStart ), [] ( const auto& l, const auto& r ) { return (uint64_t)l.End() < (uint64_t)r; } );
    if( it == vec.end() ) return;
    if( it != vec.begin() ) --it;

    auto citend = std::lower_bound( it, vec.end(), vEnd, [] ( const auto& l, const auto& r ) { return l.Start() < r; } );
    if( it == citend ) return;
    if( citend != vec.end() ) ++citend;

    const auto MinCtxNs = MinCtxSize * nspx;
    const auto& sampleData = m_thread->samples;

    auto pit = citend;
    double minpx = -10.0;
    while( it < citend )
    {
        auto& ev = *it;
        if( pit != citend )
        {
            Int24 waitStack;
            if( !sampleData.empty() )
            {
                auto sdit = std::lower_bound( sampleData.begin(), sampleData.end(), ev.Start(), [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );
                bool found = sdit != sampleData.end() && sdit->time.Val() == ev.Start();
                if( !found && it != vec.begin() )
                {
                    auto eit = it;
                    --eit;
                    sdit = std::lower_bound( sampleData.begin(), sampleData.end(), eit->End(), [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );
                    found = sdit != sampleData.end() && sdit->time.Val() == eit->End();
                }
                if( found ) waitStack = sdit->callstack;
            }

            auto& ref = m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::Waiting, &ev, float( minpx ) } );
            ref.waiting.prev = pit;
            ref.waiting.waitStack = waitStack;
        }

        const auto end = ev.IsEndValid() ? ev.End() : m_worker.GetLastTime();
        const auto zsz = std::max( ( end - ev.Start() ) * pxns, pxns * 0.5 );
        if( zsz < MinCtxSize )
        {
            int num = 0;
            const auto px0 = std::max( ( ev.Start() - vStart ) * pxns, -10.0 );
            auto px1ns = end - vStart;
            auto rend = end;
            auto nextTime = end + MinCtxNs;
            for(;;)
            {
                const auto prevIt = it;
                it = std::lower_bound( it, citend, nextTime, [] ( const auto& l, const auto& r ) { return (uint64_t)l.End() < (uint64_t)r; } );
                if( it == prevIt ) ++it;
                num += std::distance( prevIt, it );
                if( it == citend ) break;
                const auto nend = it->IsEndValid() ? it->End() : m_worker.GetLastTime();
                const auto nsnext = nend - vStart;
                if( nsnext - px1ns >= MinCtxNs * 2 ) break;
                px1ns = nsnext;
                rend = nend;
                nextTime = nend + nspx;
            }
            minpx = std::min( std::max( px1ns * pxns, px0+MinCtxSize ), double( w + 10 ) );
            if( num == 1 )
            {
                auto& ref = m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::FoldedOne, &ev, float( minpx ) } );
                ref.folded.rend = rend;
            }
            else
            {
                auto& ref = m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::FoldedMulti, &ev, float( minpx ) } );
                ref.folded.rend = rend;
                ref.folded.num = num;
            }
            pit = it-1;
        }
        else
        {
            m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::Running, &ev, float( minpx ) } );
            pit = it;
            ++it;
        }
    }
}

}
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`#include <algorithm>`
			`#include <limits>`

			`#include "TracyImGui.hpp"`
			`#include "TracyMouse.hpp"`
			`#include "TracyPrint.hpp"`
Move TimelineContext struct definition to a separate header. 2023-03-18 16:03:23 +00:00			`#include "TracyTimelineContext.hpp"`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`#include "TracyTimelineItemThread.hpp"`
			`#include "TracyView.hpp"`
			`#include "TracyWorker.hpp"`

			`namespace tracy`
			`{`

Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`constexpr float MinVisSize = 3;`
Preprocess thread context switch data. 2023-03-22 18:38:36 +00:00			`constexpr float MinCtxSize = 4;`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00

Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`TimelineItemThread::TimelineItemThread( View& view, Worker& worker, const ThreadData* thread )`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`: TimelineItem( view, worker, thread, true )`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`, m_thread( thread )`
			`, m_ghost( false )`
			`{`
Collapse Tracy threads by default. Note that this will likely work only when loading existing traces. In live captures the thread name may not have yet been retrieved at the point when timeline item insertion occurs, which will prevent the check from succeeding. 2022-09-03 21:35:35 +00:00			`auto name = worker.GetThreadName( thread->id );`
			`if( strncmp( name, "Tracy ", 6 ) == 0 )`
			`{`
			`m_showFull = false;`
			`}`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`}`

			`bool TimelineItemThread::IsEmpty() const`
			`{`
			`auto& crash = m_worker.GetCrashEvent();`
			`return crash.thread != m_thread->id &&`
			`m_thread->timeline.empty() &&`
			`m_thread->messages.empty() &&`
			`m_thread->ghostZones.empty();`
			`}`

			`uint32_t TimelineItemThread::HeaderColor() const`
			`{`
			`auto& crash = m_worker.GetCrashEvent();`
			`if( crash.thread == m_thread->id ) return 0xFF2222FF;`
			`if( m_thread->isFiber ) return 0xFF88FF88;`
			`return 0xFFFFFFFF;`
			`}`

			`uint32_t TimelineItemThread::HeaderColorInactive() const`
			`{`
			`auto& crash = m_worker.GetCrashEvent();`
			`if( crash.thread == m_thread->id ) return 0xFF111188;`
			`if( m_thread->isFiber ) return 0xFF448844;`
			`return 0xFF888888;`
			`}`

			`uint32_t TimelineItemThread::HeaderLineColor() const`
			`{`
			`return 0x33FFFFFF;`
			`}`

			`const char* TimelineItemThread::HeaderLabel() const`
			`{`
			`return m_worker.GetThreadName( m_thread->id );`
			`}`

			`int64_t TimelineItemThread::RangeBegin() const`
			`{`
			`int64_t first = std::numeric_limits<int64_t>::max();`
			`const auto ctx = m_worker.GetContextSwitchData( m_thread->id );`
			`if( ctx && !ctx->v.empty() )`
			`{`
			`first = ctx->v.begin()->Start();`
			`}`
			`if( !m_thread->timeline.empty() )`
			`{`
			`if( m_thread->timeline.is_magic() )`
			`{`
			`auto& tl = ((Vector<ZoneEvent>)&m_thread->timeline);`
			`first = std::min( first, tl.front().Start() );`
			`}`
			`else`
			`{`
			`first = std::min( first, m_thread->timeline.front()->Start() );`
			`}`
			`}`
			`if( !m_thread->messages.empty() )`
			`{`
			`first = std::min( first, m_thread->messages.front()->time );`
			`}`
			`for( const auto& lock : m_worker.GetLockMap() )`
			`{`
			`const auto& lockmap = *lock.second;`
			`if( !lockmap.valid ) continue;`
			`auto it = lockmap.threadMap.find( m_thread->id );`
			`if( it == lockmap.threadMap.end() ) continue;`
			`const auto thread = it->second;`
			`auto lptr = lockmap.timeline.data();`
			`while( lptr->ptr->thread != thread ) lptr++;`
			`if( lptr->ptr->Time() < first ) first = lptr->ptr->Time();`
			`}`
			`return first;`
			`}`

			`int64_t TimelineItemThread::RangeEnd() const`
			`{`
			`int64_t last = -1;`
			`const auto ctx = m_worker.GetContextSwitchData( m_thread->id );`
			`if( ctx && !ctx->v.empty() )`
			`{`
			`const auto& back = ctx->v.back();`
			`last = back.IsEndValid() ? back.End() : back.Start();`
			`}`
			`if( !m_thread->timeline.empty() )`
			`{`
			`if( m_thread->timeline.is_magic() )`
			`{`
			`auto& tl = ((Vector<ZoneEvent>)&m_thread->timeline);`
			`last = std::max( last, m_worker.GetZoneEnd( tl.back() ) );`
			`}`
			`else`
			`{`
			`last = std::max( last, m_worker.GetZoneEnd( *m_thread->timeline.back() ) );`
			`}`
			`}`
			`if( !m_thread->messages.empty() )`
			`{`
			`last = std::max( last, m_thread->messages.back()->time );`
			`}`
			`for( const auto& lock : m_worker.GetLockMap() )`
			`{`
			`const auto& lockmap = *lock.second;`
			`if( !lockmap.valid ) continue;`
			`auto it = lockmap.threadMap.find( m_thread->id );`
			`if( it == lockmap.threadMap.end() ) continue;`
			`const auto thread = it->second;`
			`auto eptr = lockmap.timeline.data() + lockmap.timeline.size() - 1;`
			`while( eptr->ptr->thread != thread ) eptr--;`
			`if( eptr->ptr->Time() > last ) last = eptr->ptr->Time();`
			`}`
			`return last;`
			`}`

			`void TimelineItemThread::HeaderTooltip( const char* label ) const`
			`{`
			`m_view.HighlightThread( m_thread->id );`

			`ImGui::BeginTooltip();`
			`SmallColorBox( GetThreadColor( m_thread->id, 0, m_view.GetViewData().dynamicColors ) );`
			`ImGui::SameLine();`
			`ImGui::TextUnformatted( m_worker.GetThreadName( m_thread->id ) );`
			`ImGui::SameLine();`
			`ImGui::TextDisabled( "(%s)", RealToString( m_thread->id ) );`
			`auto& crash = m_worker.GetCrashEvent();`
			`if( crash.thread == m_thread->id )`
			`{`
			`ImGui::SameLine();`
			`TextColoredUnformatted( ImVec4( 1.f, 0.2f, 0.2f, 1.f ), ICON_FA_SKULL " Crashed" );`
			`}`
			`if( m_thread->isFiber )`
			`{`
			`ImGui::SameLine();`
			`TextColoredUnformatted( ImVec4( 0.2f, 0.6f, 0.2f, 1.f ), "Fiber" );`
			`}`

			`const auto ctx = m_worker.GetContextSwitchData( m_thread->id );`
			`const auto first = RangeBegin();`
			`const auto last = RangeEnd();`

			`ImGui::Separator();`

			`size_t lockCnt = 0;`
			`for( const auto& lock : m_worker.GetLockMap() )`
			`{`
			`const auto& lockmap = *lock.second;`
			`if( !lockmap.valid ) continue;`
			`auto it = lockmap.threadMap.find( m_thread->id );`
			`if( it == lockmap.threadMap.end() ) continue;`
			`lockCnt++;`
			`}`

			`if( last >= 0 )`
			`{`
			`const auto lifetime = last - first;`
Include first time in CPU thread lifetime calculation. 2023-03-03 21:46:25 +00:00			`const auto traceLen = m_worker.GetLastTime() - m_worker.GetFirstTime();`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00
			`TextFocused( "Appeared at", TimeToString( first ) );`
			`TextFocused( "Last event at", TimeToString( last ) );`
			`TextFocused( "Lifetime:", TimeToString( lifetime ) );`
			`ImGui::SameLine();`
			`char buf[64];`
			`PrintStringPercent( buf, lifetime / double( traceLen ) * 100 );`
			`TextDisabledUnformatted( buf );`

			`if( ctx )`
			`{`
			`TextFocused( "Time in running state:", TimeToString( ctx->runningTime ) );`
			`ImGui::SameLine();`
			`PrintStringPercent( buf, ctx->runningTime / double( lifetime ) * 100 );`
			`TextDisabledUnformatted( buf );`
			`}`
			`}`

			`ImGui::Separator();`
			`if( !m_thread->timeline.empty() )`
			`{`
			`TextFocused( "Zone count:", RealToString( m_thread->count ) );`
			`TextFocused( "Top-level zones:", RealToString( m_thread->timeline.size() ) );`
			`}`
			`if( !m_thread->messages.empty() )`
			`{`
			`TextFocused( "Messages:", RealToString( m_thread->messages.size() ) );`
			`}`
			`if( lockCnt != 0 )`
			`{`
			`TextFocused( "Locks:", RealToString( lockCnt ) );`
			`}`
			`if( ctx )`
			`{`
			`TextFocused( "Running state regions:", RealToString( ctx->v.size() ) );`
			`}`
			`if( !m_thread->samples.empty() )`
			`{`
			`TextFocused( "Call stack samples:", RealToString( m_thread->samples.size() ) );`
			`if( m_thread->kernelSampleCnt != 0 )`
			`{`
			`TextFocused( "Kernel samples:", RealToString( m_thread->kernelSampleCnt ) );`
			`ImGui::SameLine();`
			`ImGui::TextDisabled( "(%.2f%%)", 100.f * m_thread->kernelSampleCnt / m_thread->samples.size() );`
			`}`
			`}`
			`ImGui::EndTooltip();`
			`}`

Move hover flag to TimelineContext. 2023-03-18 15:07:56 +00:00			`void TimelineItemThread::HeaderExtraContents( const TimelineContext& ctx, int offset, float labelWidth )`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`{`
Use TimelineContext to draw CPU zones. 2023-03-19 00:14:36 +00:00			`m_view.DrawThreadMessages( ctx, *m_thread, offset );`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00
			`#ifndef TRACY_NO_STATISTICS`
			`const bool hasGhostZones = m_worker.AreGhostZonesReady() && !m_thread->ghostZones.empty();`
			`if( hasGhostZones && !m_thread->timeline.empty() )`
			`{`
			`auto draw = ImGui::GetWindowDrawList();`
			`const auto ty = ImGui::GetTextLineHeight();`

			`const auto color = m_ghost ? 0xFFAA9999 : 0x88AA7777;`
Move hover flag to TimelineContext. 2023-03-18 15:07:56 +00:00			`draw->AddText( ctx.wpos + ImVec2( 1.5f * ty + labelWidth, offset ), color, ICON_FA_GHOST );`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`float ghostSz = ImGui::CalcTextSize( ICON_FA_GHOST ).x;`

Move hover flag to TimelineContext. 2023-03-18 15:07:56 +00:00			`if( ctx.hover && ImGui::IsMouseHoveringRect( ctx.wpos + ImVec2( 1.5f * ty + labelWidth, offset ), ctx.wpos + ImVec2( 1.5f * ty + labelWidth + ghostSz, offset + ty ) ) )`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`{`
			`if( IsMouseClicked( 0 ) )`
			`{`
			`m_ghost = !m_ghost;`
			`}`
			`}`
			`}`
			`#endif`
			`}`

Move hover flag to TimelineContext. 2023-03-18 15:07:56 +00:00			`bool TimelineItemThread::DrawContents( const TimelineContext& ctx, int& offset )`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`{`
Draw thread context switches using precalculated data. 2023-03-22 18:38:58 +00:00			`const auto res = m_view.DrawThread( ctx, *m_thread, m_draw, m_ctxDraw, offset, m_depth );`
Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`if( !res )`
			`{`
			`auto& crash = m_worker.GetCrashEvent();`
			`return crash.thread == m_thread->id;`
			`}`
			`return true;`
			`}`

			`void TimelineItemThread::DrawOverlay( const ImVec2& ul, const ImVec2& dr )`
			`{`
			`m_view.DrawThreadOverlays( *m_thread, ul, dr );`
			`}`

Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`void TimelineItemThread::DrawFinished()`
			`{`
Preprocess thread context switch data. 2023-03-22 18:38:36 +00:00			`m_ctxDraw.clear();`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`m_draw.clear();`
			`}`

Parallelize timeline item preprocessing. 2023-03-19 17:54:32 +00:00			`void TimelineItemThread::Preprocess( const TimelineContext& ctx, TaskDispatch& td )`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`{`
Preprocess thread context switch data. 2023-03-22 18:38:36 +00:00			`assert( m_ctxDraw.empty() );`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`assert( m_draw.empty() );`

Parallelize timeline item preprocessing. 2023-03-19 17:54:32 +00:00			`td.Queue( [this, &ctx] {`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`#ifndef TRACY_NO_STATISTICS`
Parallelize timeline item preprocessing. 2023-03-19 17:54:32 +00:00			`if( m_worker.AreGhostZonesReady() && ( m_ghost \|\| ( m_view.GetViewData().ghostZones && m_thread->timeline.empty() ) ) )`
			`{`
			`m_depth = PreprocessGhostLevel( ctx, m_thread->ghostZones, 0 );`
			`}`
			`else`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`#endif`
Parallelize timeline item preprocessing. 2023-03-19 17:54:32 +00:00			`{`
			`m_depth = PreprocessZoneLevel( ctx, m_thread->timeline, 0 );`
			`}`
			`} );`
Preprocess thread context switch data. 2023-03-22 18:38:36 +00:00
			`if( m_view.GetViewData().drawContextSwitches )`
			`{`
			`auto ctxSwitch = m_worker.GetContextSwitchData( m_thread->id );`
			`if( ctxSwitch )`
			`{`
			`td.Queue( [this, &ctx, ctxSwitch] {`
			`PreprocessContextSwitches( ctx, *ctxSwitch );`
			`} );`
			`}`
			`}`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`}`

			`#ifndef TRACY_NO_STATISTICS`
			`int TimelineItemThread::PreprocessGhostLevel( const TimelineContext& ctx, const Vector<GhostZone>& vec, int depth )`
			`{`
			`const auto pxns = ctx.pxns;`
			`const auto nspx = ctx.nspx;`
			`const auto vStart = ctx.vStart;`
			`const auto vEnd = ctx.vEnd;`

			`auto it = std::lower_bound( vec.begin(), vec.end(), std::max<int64_t>( 0, vStart - 2 * MinVisSize * nspx ), [] ( const auto& l, const auto& r ) { return l.end.Val() < r; } );`
			`if( it == vec.end() ) return depth;`

			`const auto zitend = std::lower_bound( it, vec.end(), vEnd, [] ( const auto& l, const auto& r ) { return l.start.Val() < r; } );`
			`if( it == zitend ) return depth;`
			`if( (zitend-1)->end.Val() < vStart ) return depth;`

Move const out of the loop. 2023-03-22 19:38:43 +00:00			`const auto MinVisNs = MinVisSize * nspx;`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`int maxdepth = depth + 1;`

			`while( it < zitend )`
			`{`
			`auto& ev = *it;`
			`const auto end = ev.end.Val();`
			`const auto zsz = std::max( ( end - ev.start.Val() ) * pxns, pxns * 0.5 );`
			`if( zsz < MinVisSize )`
			`{`
			`auto px1ns = ev.end.Val() - vStart;`
			`auto rend = end;`
			`auto nextTime = end + MinVisNs;`
			`for(;;)`
			`{`
			`const auto prevIt = it;`
			`it = std::lower_bound( it, zitend, nextTime, [] ( const auto& l, const auto& r ) { return l.end.Val() < r; } );`
			`if( it == prevIt ) ++it;`
			`if( it == zitend ) break;`
			`const auto nend = it->end.Val();`
			`const auto nsnext = nend - vStart;`
			`if( nsnext - px1ns >= MinVisNs * 2 ) break;`
			`px1ns = nsnext;`
			`rend = nend;`
			`nextTime = nend + nspx;`
			`}`
			`m_draw.emplace_back( TimelineDraw { TimelineDrawType::GhostFolded, uint16_t( depth ), (void**)&ev, rend } );`
			`}`
			`else`
			`{`
			`if( ev.child >= 0 )`
			`{`
			`const auto d = PreprocessGhostLevel( ctx, m_worker.GetGhostChildren( ev.child ), depth + 1 );`
			`if( d > maxdepth ) maxdepth = d;`
			`}`
			`m_draw.emplace_back( TimelineDraw { TimelineDrawType::Ghost, uint16_t( depth ), (void**)&ev } );`
			`++it;`
			`}`
			`}`

			`return maxdepth;`
			`}`
			`#endif`

			`int TimelineItemThread::PreprocessZoneLevel( const TimelineContext& ctx, const Vector<short_ptr<ZoneEvent>>& vec, int depth )`
			`{`
			`if( vec.is_magic() )`
			`{`
			`return PreprocessZoneLevel<VectorAdapterDirect<ZoneEvent>>( ctx, (Vector<ZoneEvent>)( &vec ), depth );`
			`}`
			`else`
			`{`
			`return PreprocessZoneLevel<VectorAdapterPointer<ZoneEvent>>( ctx, vec, depth );`
			`}`
			`}`

			`template<typename Adapter, typename V>`
			`int TimelineItemThread::PreprocessZoneLevel( const TimelineContext& ctx, const V& vec, int depth )`
			`{`
			`const auto delay = m_worker.GetDelay();`
			`const auto resolution = m_worker.GetResolution();`
			`const auto vStart = ctx.vStart;`
			`const auto vEnd = ctx.vEnd;`
			`const auto nspx = ctx.nspx;`
			`const auto pxns = ctx.pxns;`

			`// cast to uint64_t, so that unended zones (end = -1) are still drawn`
			`auto it = std::lower_bound( vec.begin(), vec.end(), std::max<int64_t>( 0, vStart - std::max<int64_t>( delay, 2 * MinVisSize * nspx ) ), [] ( const auto& l, const auto& r ) { Adapter a; return (uint64_t)a(l).End() < (uint64_t)r; } );`
			`if( it == vec.end() ) return depth;`

			`const auto zitend = std::lower_bound( it, vec.end(), vEnd + resolution, [] ( const auto& l, const auto& r ) { Adapter a; return a(l).Start() < r; } );`
			`if( it == zitend ) return depth;`
			`Adapter a;`
			`if( !a(it).IsEndValid() && m_worker.GetZoneEnd( a(it) ) < vStart ) return depth;`
			`if( m_worker.GetZoneEnd( a(*(zitend-1)) ) < vStart ) return depth;`

Move const out of the loop. 2023-03-22 19:38:43 +00:00			`const auto MinVisNs = MinVisSize * nspx;`
Calculate which CPU zones to draw beforehand. 2023-03-19 15:11:18 +00:00			`int maxdepth = depth + 1;`

			`while( it < zitend )`
			`{`
			`auto& ev = a(*it);`
			`const auto end = m_worker.GetZoneEnd( ev );`
			`const auto zsz = std::max( ( end - ev.Start() ) * pxns, pxns * 0.5 );`
			`if( zsz < MinVisSize )`
			`{`
			`int num = 0;`
			`auto px1ns = end - vStart;`
			`auto rend = end;`
			`auto nextTime = end + MinVisNs;`
			`for(;;)`
			`{`
			`const auto prevIt = it;`
			`it = std::lower_bound( it, zitend, nextTime, [] ( const auto& l, const auto& r ) { Adapter a; return (uint64_t)a(l).End() < (uint64_t)r; } );`
			`if( it == prevIt ) ++it;`
			`num += std::distance( prevIt, it );`
			`if( it == zitend ) break;`
			`const auto nend = m_worker.GetZoneEnd( a(*it) );`
			`const auto nsnext = nend - vStart;`
			`if( nsnext - px1ns >= MinVisNs * 2 ) break;`
			`px1ns = nsnext;`
			`rend = nend;`
			`nextTime = nend + nspx;`
			`}`
			`m_draw.emplace_back( TimelineDraw { TimelineDrawType::Folded, uint16_t( depth ), (void**)&ev, rend, num } );`
			`}`
			`else`
			`{`
			`if( ev.HasChildren() )`
			`{`
			`const auto d = PreprocessZoneLevel( ctx, m_worker.GetZoneChildren( ev.Child() ), depth + 1 );`
			`if( d > maxdepth ) maxdepth = d;`
			`}`
			`m_draw.emplace_back( TimelineDraw { TimelineDrawType::Zone, uint16_t( depth ), (void**)&ev } );`
			`++it;`
			`}`
			`}`

			`return maxdepth;`
			`}`

Preprocess thread context switch data. 2023-03-22 18:38:36 +00:00			`void TimelineItemThread::PreprocessContextSwitches( const TimelineContext& ctx, const ContextSwitch& ctxSwitch )`
			`{`
			`const auto w = ctx.w;`
			`const auto pxns = ctx.pxns;`
			`const auto nspx = ctx.nspx;`
			`const auto vStart = ctx.vStart;`
			`const auto vEnd = ctx.vEnd;`

			`auto& vec = ctxSwitch.v;`
			`auto it = std::lower_bound( vec.begin(), vec.end(), std::max<int64_t>( 0, vStart ), [] ( const auto& l, const auto& r ) { return (uint64_t)l.End() < (uint64_t)r; } );`
			`if( it == vec.end() ) return;`
			`if( it != vec.begin() ) --it;`

			`auto citend = std::lower_bound( it, vec.end(), vEnd, [] ( const auto& l, const auto& r ) { return l.Start() < r; } );`
			`if( it == citend ) return;`
			`if( citend != vec.end() ) ++citend;`

			`const auto MinCtxNs = MinCtxSize * nspx;`
			`const auto& sampleData = m_thread->samples;`

			`auto pit = citend;`
			`double minpx = -10.0;`
			`while( it < citend )`
			`{`
			`auto& ev = *it;`
			`if( pit != citend )`
			`{`
			`Int24 waitStack;`
			`if( !sampleData.empty() )`
			`{`
			`auto sdit = std::lower_bound( sampleData.begin(), sampleData.end(), ev.Start(), [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );`
			`bool found = sdit != sampleData.end() && sdit->time.Val() == ev.Start();`
			`if( !found && it != vec.begin() )`
			`{`
			`auto eit = it;`
			`--eit;`
			`sdit = std::lower_bound( sampleData.begin(), sampleData.end(), eit->End(), [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );`
			`found = sdit != sampleData.end() && sdit->time.Val() == eit->End();`
			`}`
			`if( found ) waitStack = sdit->callstack;`
			`}`

			`auto& ref = m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::Waiting, &ev, float( minpx ) } );`
			`ref.waiting.prev = pit;`
			`ref.waiting.waitStack = waitStack;`
			`}`

			`const auto end = ev.IsEndValid() ? ev.End() : m_worker.GetLastTime();`
			`const auto zsz = std::max( ( end - ev.Start() ) * pxns, pxns * 0.5 );`
			`if( zsz < MinCtxSize )`
			`{`
			`int num = 0;`
			`const auto px0 = std::max( ( ev.Start() - vStart ) * pxns, -10.0 );`
			`auto px1ns = end - vStart;`
			`auto rend = end;`
			`auto nextTime = end + MinCtxNs;`
			`for(;;)`
			`{`
			`const auto prevIt = it;`
			`it = std::lower_bound( it, citend, nextTime, [] ( const auto& l, const auto& r ) { return (uint64_t)l.End() < (uint64_t)r; } );`
			`if( it == prevIt ) ++it;`
			`num += std::distance( prevIt, it );`
			`if( it == citend ) break;`
			`const auto nend = it->IsEndValid() ? it->End() : m_worker.GetLastTime();`
			`const auto nsnext = nend - vStart;`
			`if( nsnext - px1ns >= MinCtxNs * 2 ) break;`
			`px1ns = nsnext;`
			`rend = nend;`
			`nextTime = nend + nspx;`
			`}`
			`minpx = std::min( std::max( px1ns * pxns, px0+MinCtxSize ), double( w + 10 ) );`
			`if( num == 1 )`
			`{`
			`auto& ref = m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::FoldedOne, &ev, float( minpx ) } );`
			`ref.folded.rend = rend;`
			`}`
			`else`
			`{`
			`auto& ref = m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::FoldedMulti, &ev, float( minpx ) } );`
			`ref.folded.rend = rend;`
			`ref.folded.num = num;`
			`}`
			`pit = it-1;`
			`}`
			`else`
			`{`
			`m_ctxDraw.emplace_back( ContextSwitchDraw { ContextSwitchDrawType::Running, &ev, float( minpx ) } );`
			`pit = it;`
			`++it;`
			`}`
			`}`
			`}`

Migrate drawing CPU threads to the new timeline item system. 2022-09-03 21:28:54 +00:00			`}`