tracy/server/TracyTimelineItemPlot.cpp

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#include "TracyImGui.hpp"
#include "TracyPrint.hpp"
#include "TracyTimelineContext.hpp"
#include "TracyTimelineItemPlot.hpp"
#include "TracyUtility.hpp"
#include "TracyView.hpp"
#include "TracyWorker.hpp"
namespace tracy
{
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constexpr int PlotHeightPx = 100;
constexpr int MinVisSize = 3;
TimelineItemPlot::TimelineItemPlot( View& view, Worker& worker, PlotData* plot )
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: TimelineItem( view, worker, plot, true )
, m_plot( plot )
{
}
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bool TimelineItemPlot::IsEmpty() const
{
return m_plot->data.empty();
}
const char* TimelineItemPlot::HeaderLabel() const
{
static char tmp[1024];
switch( m_plot->type )
{
case PlotType::User:
return m_worker.GetString( m_plot->name );
case PlotType::Memory:
if( m_plot->name == 0 )
{
return ICON_FA_MEMORY " Memory usage";
}
else
{
sprintf( tmp, ICON_FA_MEMORY " %s", m_worker.GetString( m_plot->name ) );
return tmp;
}
case PlotType::SysTime:
return ICON_FA_GAUGE_HIGH " CPU usage";
case PlotType::Power:
sprintf( tmp, ICON_FA_BOLT " %s", m_worker.GetString( m_plot->name ) );
return tmp;
default:
assert( false );
return nullptr;
}
}
void TimelineItemPlot::HeaderTooltip( const char* label ) const
{
ImGui::BeginTooltip();
SmallColorBox( GetPlotColor( *m_plot, m_worker ) );
ImGui::SameLine();
TextFocused( "Plot", label );
ImGui::Separator();
const auto first = RangeBegin();
const auto last = RangeEnd();
const auto activity = last - first;
const auto traceLen = m_worker.GetLastTime() - m_worker.GetFirstTime();
TextFocused( "Appeared at", TimeToString( first ) );
TextFocused( "Last event at", TimeToString( last ) );
TextFocused( "Activity time:", TimeToString( activity ) );
ImGui::SameLine();
char buf[64];
PrintStringPercent( buf, activity / double( traceLen ) * 100 );
TextDisabledUnformatted( buf );
ImGui::Separator();
TextFocused( "Data points:", RealToString( m_plot->data.size() ) );
TextFocused( "Data range:", FormatPlotValue( m_plot->max - m_plot->min, m_plot->format ) );
TextFocused( "Min value:", FormatPlotValue( m_plot->min, m_plot->format ) );
TextFocused( "Max value:", FormatPlotValue( m_plot->max, m_plot->format ) );
TextFocused( "Avg value:", FormatPlotValue( m_plot->sum / m_plot->data.size(), m_plot->format ) );
TextFocused( "Data/second:", RealToString( double( m_plot->data.size() ) / activity * 1000000000ll ) );
const auto it = std::lower_bound( m_plot->data.begin(), m_plot->data.end(), last - 1000000000ll * 10, [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );
const auto tr10 = last - it->time.Val();
if( tr10 != 0 )
{
TextFocused( "D/s (10s):", RealToString( double( std::distance( it, m_plot->data.end() ) ) / tr10 * 1000000000ll ) );
}
ImGui::EndTooltip();
}
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void TimelineItemPlot::HeaderExtraContents( const TimelineContext& ctx, int offset, float labelWidth )
{
auto draw = ImGui::GetWindowDrawList();
const auto ty = ImGui::GetTextLineHeight();
char tmp[128];
sprintf( tmp, "(y-range: %s, visible data points: %s)", FormatPlotValue( m_plot->rMax - m_plot->rMin, m_plot->format ), RealToString( m_plot->num ) );
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draw->AddText( ctx.wpos + ImVec2( ty * 1.5f + labelWidth, offset ), 0xFF226E6E, tmp );
}
int64_t TimelineItemPlot::RangeBegin() const
{
return m_plot->data.front().time.Val();
}
int64_t TimelineItemPlot::RangeEnd() const
{
return m_plot->data.back().time.Val();
}
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bool TimelineItemPlot::DrawContents( const TimelineContext& ctx, int& offset )
{
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return m_view.DrawPlot( ctx, *m_plot, m_draw, offset );
}
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void TimelineItemPlot::DrawFinished()
{
m_draw.clear();
}
void TimelineItemPlot::Preprocess( const TimelineContext& ctx, TaskDispatch& td, bool visible, int yPos )
{
assert( m_draw.empty() );
if( !visible ) return;
if( yPos > ctx.yMax ) return;
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if( m_plot->data.empty() ) return;
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const auto PlotHeight = int( round( PlotHeightPx * GetScale() ) );
if( yPos + PlotHeight < ctx.yMin ) return;
td.Queue( [this, &ctx] {
const auto vStart = ctx.vStart;
const auto vEnd = ctx.vEnd;
const auto nspx = ctx.nspx;
const auto MinVisNs = int64_t( round( MinVisSize * nspx ) );
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auto& vec = m_plot->data;
vec.ensure_sorted();
if( vec.front().time.Val() > vEnd || vec.back().time.Val() < vStart )
{
m_plot->rMin = 0;
m_plot->rMax = 0;
m_plot->num = 0;
return;
}
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auto it = std::lower_bound( vec.begin(), vec.end(), vStart, [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );
auto end = std::lower_bound( it, vec.end(), vEnd, [] ( const auto& l, const auto& r ) { return l.time.Val() < r; } );
if( end != vec.end() ) end++;
if( it != vec.begin() ) it--;
double min = it->val;
double max = it->val;
const auto num = end - it;
if( num > 1000000 )
{
min = m_plot->min;
max = m_plot->max;
}
else
{
auto tmp = it;
while( ++tmp < end )
{
if( tmp->val < min ) min = tmp->val;
else if( tmp->val > max ) max = tmp->val;
}
}
if( min == max )
{
min--;
max++;
}
m_plot->rMin = min;
m_plot->rMax = max;
m_plot->num = num;
m_draw.emplace_back( 0 );
m_draw.emplace_back( it - vec.begin() );
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++it;
while( it < end )
{
auto next = std::upper_bound( it, end, int64_t( it->time.Val() + MinVisNs ), [] ( const auto& l, const auto& r ) { return l < r.time.Val(); } );
assert( next > it );
const auto rsz = uint32_t( next - it );
if( rsz < 4 )
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{
for( int i=0; i<rsz; i++ )
{
m_draw.emplace_back( 0 );
m_draw.emplace_back( it - vec.begin() );
++it;
}
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}
else
{
// Sync with View::DrawPlot()!
constexpr int NumSamples = 256;
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uint32_t samples[NumSamples];
uint32_t cnt = 0;
uint32_t offset = it - vec.begin();
if( rsz < NumSamples )
{
for( cnt=0; cnt<rsz; cnt++ )
{
samples[cnt] = offset + cnt;
}
}
else
{
const auto skip = ( rsz + NumSamples - 1 ) / NumSamples;
const auto limit = rsz / skip;
for( cnt=0; cnt<limit; cnt++ )
{
samples[cnt] = offset + cnt * skip;
}
if( cnt == limit ) cnt--;
samples[cnt++] = offset + rsz - 1;
}
it = next;
pdqsort_branchless( samples, samples+cnt, [&vec] ( const auto& l, const auto& r ) { return vec[l].val < vec[r].val; } );
assert( rsz > 0 );
m_draw.emplace_back( rsz );
m_draw.emplace_back( offset );
m_draw.emplace_back( samples[0] );
m_draw.emplace_back( samples[cnt-1] );
}
}
} );
}
}