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596 lines
14 KiB
596 lines
14 KiB
//========= Copyright � 1996-2005, Valve Corporation, All rights reserved. ============//
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//
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// Purpose:
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//
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// $NoKeywords: $
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//===========================================================================//
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#ifndef FASTTIMER_H
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#define FASTTIMER_H
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#ifdef _WIN32
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#pragma once
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#endif
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#include <assert.h>
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#include "tier0/platform.h"
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#ifdef _PS3
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#include "sys/sys_time.h"
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#else
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inline uint64 sys_time_get_timebase_frequency()
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{
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DebuggerBreak(); // Error("sys_time_get_timebase_frequency called on non-PS3 platform.");
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return 1; // this function should never ever be called.
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}
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#endif
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PLATFORM_INTERFACE uint64 g_ClockSpeed;
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PLATFORM_INTERFACE unsigned long g_dwClockSpeed;
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PLATFORM_INTERFACE double g_ClockSpeedMicrosecondsMultiplier;
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PLATFORM_INTERFACE double g_ClockSpeedMillisecondsMultiplier;
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PLATFORM_INTERFACE double g_ClockSpeedSecondsMultiplier;
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class CCycleCount
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{
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friend class CFastTimer;
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public:
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CCycleCount();
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CCycleCount( uint64 cycles );
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void Sample(); // Sample the clock. This takes about 34 clocks to execute (or 26,000 calls per millisecond on a P900).
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void Init(); // Set to zero.
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void Init( float initTimeMsec );
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void Init( double initTimeMsec ) { Init( (float)initTimeMsec ); }
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void Init( uint64 cycles );
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bool IsLessThan( CCycleCount const &other ) const; // Compare two counts.
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// Convert to other time representations. These functions are slow, so it's preferable to call them
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// during display rather than inside a timing block.
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unsigned long GetCycles() const;
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uint64 GetLongCycles() const;
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unsigned long GetMicroseconds() const;
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uint64 GetUlMicroseconds() const;
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double GetMicrosecondsF() const;
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void SetMicroseconds( unsigned long nMicroseconds );
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unsigned long GetMilliseconds() const;
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double GetMillisecondsF() const;
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double GetSeconds() const;
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CCycleCount& operator+=( CCycleCount const &other );
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// dest = rSrc1 + rSrc2
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static void Add( CCycleCount const &rSrc1, CCycleCount const &rSrc2, CCycleCount &dest ); // Add two samples together.
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// dest = rSrc1 - rSrc2
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static void Sub( CCycleCount const &rSrc1, CCycleCount const &rSrc2, CCycleCount &dest ); // Add two samples together.
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static uint64 GetTimestamp();
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uint64 m_Int64;
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};
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class CClockSpeedInit
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{
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public:
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CClockSpeedInit()
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{
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Init();
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}
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static void Init()
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{
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const CPUInformation& pi = GetCPUInformation();
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if ( IsX360() )
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{
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// cycle counter runs as doc'd at 1/64 Xbox 3.2GHz clock speed, thus 50 Mhz
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g_ClockSpeed = pi.m_Speed / 64L;
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}
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else if ( IsPS3() )
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{
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g_ClockSpeed = sys_time_get_timebase_frequency(); // CPU clock rate is totally unrelated to time base register frequency on PS3
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}
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else
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{
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g_ClockSpeed = pi.m_Speed;
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}
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g_dwClockSpeed = (unsigned long)g_ClockSpeed;
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g_ClockSpeedMicrosecondsMultiplier = 1000000.0 / (double)g_ClockSpeed;
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g_ClockSpeedMillisecondsMultiplier = 1000.0 / (double)g_ClockSpeed;
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g_ClockSpeedSecondsMultiplier = 1.0f / (double)g_ClockSpeed;
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}
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};
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class CFastTimer
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{
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public:
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// These functions are fast to call and should be called from your sampling code.
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void Start();
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void End();
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const CCycleCount & GetDuration() const; // Get the elapsed time between Start and End calls.
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CCycleCount GetDurationInProgress() const; // Call without ending. Not that cheap.
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// Return number of cycles per second on this processor.
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static inline unsigned long GetClockSpeed();
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private:
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CCycleCount m_Duration;
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#ifdef DEBUG_FASTTIMER
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bool m_bRunning; // Are we currently running?
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#endif
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};
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// This is a helper class that times whatever block of code it's in
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class CTimeScope
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{
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public:
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CTimeScope( CFastTimer *pTimer );
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~CTimeScope();
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private:
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CFastTimer *m_pTimer;
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};
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inline CTimeScope::CTimeScope( CFastTimer *pTotal )
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{
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m_pTimer = pTotal;
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m_pTimer->Start();
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}
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inline CTimeScope::~CTimeScope()
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{
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m_pTimer->End();
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}
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// This is a helper class that times whatever block of code it's in and
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// adds the total (int microseconds) to a global counter.
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class CTimeAdder
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{
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public:
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CTimeAdder( CCycleCount *pTotal );
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~CTimeAdder();
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void End();
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private:
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CCycleCount *m_pTotal;
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CFastTimer m_Timer;
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};
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inline CTimeAdder::CTimeAdder( CCycleCount *pTotal )
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{
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m_pTotal = pTotal;
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m_Timer.Start();
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}
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inline CTimeAdder::~CTimeAdder()
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{
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End();
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}
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inline void CTimeAdder::End()
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{
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if( m_pTotal )
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{
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m_Timer.End();
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*m_pTotal += m_Timer.GetDuration();
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m_pTotal = 0;
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}
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}
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// -------------------------------------------------------------------------- //
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// Simple tool to support timing a block of code, and reporting the results on
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// program exit or at each iteration
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//
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// Macros used because dbg.h uses this header, thus Msg() is unavailable
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// -------------------------------------------------------------------------- //
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#define PROFILE_SCOPE(name) \
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class C##name##ACC : public CAverageCycleCounter \
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{ \
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public: \
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~C##name##ACC() \
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{ \
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Msg("%-48s: %6.3f avg (%8.1f total, %7.3f peak, %5d iters)\n", \
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#name, \
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GetAverageMilliseconds(), \
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GetTotalMilliseconds(), \
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GetPeakMilliseconds(), \
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GetIters() ); \
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} \
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}; \
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static C##name##ACC name##_ACC; \
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CAverageTimeMarker name##_ATM( &name##_ACC )
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#define TIME_SCOPE(name) \
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class CTimeScopeMsg_##name \
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{ \
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public: \
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CTimeScopeMsg_##name() { m_Timer.Start(); } \
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~CTimeScopeMsg_##name() \
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{ \
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m_Timer.End(); \
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Msg( #name "time: %.4fms\n", m_Timer.GetDuration().GetMillisecondsF() ); \
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} \
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private: \
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CFastTimer m_Timer; \
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} name##_TSM;
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// -------------------------------------------------------------------------- //
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class CAverageCycleCounter
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{
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public:
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CAverageCycleCounter();
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void Init();
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void MarkIter( const CCycleCount &duration );
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unsigned GetIters() const;
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double GetAverageMilliseconds() const;
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double GetTotalMilliseconds() const;
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double GetPeakMilliseconds() const;
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private:
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unsigned m_nIters;
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CCycleCount m_Total;
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CCycleCount m_Peak;
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bool m_fReport;
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const tchar *m_pszName;
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};
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// -------------------------------------------------------------------------- //
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class CAverageTimeMarker
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{
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public:
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CAverageTimeMarker( CAverageCycleCounter *pCounter );
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~CAverageTimeMarker();
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private:
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CAverageCycleCounter *m_pCounter;
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CFastTimer m_Timer;
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};
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// -------------------------------------------------------------------------- //
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// CCycleCount inlines.
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// -------------------------------------------------------------------------- //
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inline CCycleCount::CCycleCount()
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{
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Init( (uint64)0 );
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}
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inline CCycleCount::CCycleCount( uint64 cycles )
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{
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Init( cycles );
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}
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inline void CCycleCount::Init()
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{
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Init( (uint64)0 );
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}
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inline void CCycleCount::Init( float initTimeMsec )
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{
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if ( g_ClockSpeedMillisecondsMultiplier > 0 )
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Init( (uint64)(initTimeMsec / g_ClockSpeedMillisecondsMultiplier) );
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else
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Init( (uint64)0 );
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}
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inline void CCycleCount::Init( uint64 cycles )
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{
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m_Int64 = cycles;
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}
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inline void CCycleCount::Sample()
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{
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m_Int64 = Plat_Rdtsc();
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}
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inline CCycleCount& CCycleCount::operator+=( CCycleCount const &other )
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{
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m_Int64 += other.m_Int64;
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return *this;
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}
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inline void CCycleCount::Add( CCycleCount const &rSrc1, CCycleCount const &rSrc2, CCycleCount &dest )
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{
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dest.m_Int64 = rSrc1.m_Int64 + rSrc2.m_Int64;
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}
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inline void CCycleCount::Sub( CCycleCount const &rSrc1, CCycleCount const &rSrc2, CCycleCount &dest )
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{
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dest.m_Int64 = rSrc1.m_Int64 - rSrc2.m_Int64;
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}
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inline uint64 CCycleCount::GetTimestamp()
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{
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CCycleCount c;
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c.Sample();
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return c.GetLongCycles();
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}
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inline bool CCycleCount::IsLessThan(CCycleCount const &other) const
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{
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return m_Int64 < other.m_Int64;
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}
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inline unsigned long CCycleCount::GetCycles() const
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{
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return (unsigned long)m_Int64;
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}
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inline uint64 CCycleCount::GetLongCycles() const
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{
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return m_Int64;
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}
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inline unsigned long CCycleCount::GetMicroseconds() const
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{
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return (unsigned long)((m_Int64 * 1000000) / g_ClockSpeed);
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}
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inline uint64 CCycleCount::GetUlMicroseconds() const
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{
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return ((m_Int64 * 1000000) / g_ClockSpeed);
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}
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inline double CCycleCount::GetMicrosecondsF() const
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{
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return (double)( m_Int64 * g_ClockSpeedMicrosecondsMultiplier );
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}
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inline void CCycleCount::SetMicroseconds( unsigned long nMicroseconds )
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{
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m_Int64 = ((uint64)nMicroseconds * g_ClockSpeed) / 1000000;
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}
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inline unsigned long CCycleCount::GetMilliseconds() const
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{
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return (unsigned long)((m_Int64 * 1000) / g_ClockSpeed);
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}
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inline double CCycleCount::GetMillisecondsF() const
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{
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return (double)( m_Int64 * g_ClockSpeedMillisecondsMultiplier );
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}
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inline double CCycleCount::GetSeconds() const
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{
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return (double)( m_Int64 * g_ClockSpeedSecondsMultiplier );
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}
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// -------------------------------------------------------------------------- //
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// CFastTimer inlines.
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// -------------------------------------------------------------------------- //
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inline void CFastTimer::Start()
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{
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m_Duration.Sample();
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#ifdef DEBUG_FASTTIMER
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m_bRunning = true;
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#endif
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}
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inline void CFastTimer::End()
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{
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CCycleCount cnt;
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cnt.Sample();
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if ( IsX360() )
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{
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// have to handle rollover, hires timer is only accurate to 32 bits
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// more than one overflow should not have occurred, otherwise caller should use a slower timer
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if ( (uint64)cnt.m_Int64 <= (uint64)m_Duration.m_Int64 )
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{
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// rollover occurred
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cnt.m_Int64 += 0x100000000LL;
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}
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}
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m_Duration.m_Int64 = cnt.m_Int64 - m_Duration.m_Int64;
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#ifdef DEBUG_FASTTIMER
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m_bRunning = false;
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#endif
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}
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inline CCycleCount CFastTimer::GetDurationInProgress() const
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{
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CCycleCount cnt;
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cnt.Sample();
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if ( IsX360() )
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{
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// have to handle rollover, hires timer is only accurate to 32 bits
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// more than one overflow should not have occurred, otherwise caller should use a slower timer
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if ( (uint64)cnt.m_Int64 <= (uint64)m_Duration.m_Int64 )
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{
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// rollover occurred
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cnt.m_Int64 += 0x100000000LL;
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}
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}
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CCycleCount result;
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result.m_Int64 = cnt.m_Int64 - m_Duration.m_Int64;
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return result;
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}
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inline unsigned long CFastTimer::GetClockSpeed()
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{
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return g_dwClockSpeed;
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}
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inline CCycleCount const& CFastTimer::GetDuration() const
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{
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#ifdef DEBUG_FASTTIMER
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assert( !m_bRunning );
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#endif
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return m_Duration;
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}
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// -------------------------------------------------------------------------- //
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// CAverageCycleCounter inlines
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inline CAverageCycleCounter::CAverageCycleCounter()
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: m_nIters( 0 )
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{
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}
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inline void CAverageCycleCounter::Init()
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{
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m_Total.Init();
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m_Peak.Init();
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m_nIters = 0;
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}
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inline void CAverageCycleCounter::MarkIter( const CCycleCount &duration )
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{
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++m_nIters;
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m_Total += duration;
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if ( m_Peak.IsLessThan( duration ) )
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m_Peak = duration;
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}
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inline unsigned CAverageCycleCounter::GetIters() const
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{
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return m_nIters;
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}
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inline double CAverageCycleCounter::GetAverageMilliseconds() const
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{
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if ( m_nIters )
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return (m_Total.GetMillisecondsF() / (double)m_nIters);
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else
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return 0;
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}
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inline double CAverageCycleCounter::GetTotalMilliseconds() const
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{
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return m_Total.GetMillisecondsF();
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}
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inline double CAverageCycleCounter::GetPeakMilliseconds() const
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{
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return m_Peak.GetMillisecondsF();
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}
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// -------------------------------------------------------------------------- //
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inline CAverageTimeMarker::CAverageTimeMarker( CAverageCycleCounter *pCounter )
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{
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m_pCounter = pCounter;
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m_Timer.Start();
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}
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inline CAverageTimeMarker::~CAverageTimeMarker()
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{
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m_Timer.End();
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m_pCounter->MarkIter( m_Timer.GetDuration() );
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}
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// CLimitTimer
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// Use this to time whether a desired interval of time has passed. It's extremely fast
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// to check while running. NOTE: CMicroSecOverage() and CMicroSecLeft() are not as fast to check.
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class CLimitTimer
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{
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public:
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CLimitTimer() {}
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CLimitTimer( uint64 cMicroSecDuration ) { SetLimit( cMicroSecDuration ); }
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void SetLimit( uint64 m_cMicroSecDuration );
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bool BLimitReached() const;
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int CMicroSecOverage() const;
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uint64 CMicroSecLeft() const;
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private:
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uint64 m_lCycleLimit;
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};
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//-----------------------------------------------------------------------------
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// Purpose: Initializes the limit timer with a period of time to measure.
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// Input : cMicroSecDuration - How long a time period to measure
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//-----------------------------------------------------------------------------
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inline void CLimitTimer::SetLimit( uint64 cMicroSecDuration )
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{
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uint64 dlCycles = ( ( uint64 ) cMicroSecDuration * ( uint64 ) g_dwClockSpeed ) / ( uint64 ) 1000000L;
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CCycleCount cycleCount;
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cycleCount.Sample();
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m_lCycleLimit = cycleCount.GetLongCycles() + dlCycles;
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}
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//-----------------------------------------------------------------------------
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// Purpose: Determines whether our specified time period has passed
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// Output: true if at least the specified time period has passed
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//-----------------------------------------------------------------------------
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inline bool CLimitTimer::BLimitReached() const
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{
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CCycleCount cycleCount;
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cycleCount.Sample();
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return ( cycleCount.GetLongCycles() >= m_lCycleLimit );
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}
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//-----------------------------------------------------------------------------
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// Purpose: If we're over our specified time period, return the amount of the overage.
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// Output: # of microseconds since we reached our specified time period.
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//-----------------------------------------------------------------------------
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inline int CLimitTimer::CMicroSecOverage() const
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{
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CCycleCount cycleCount;
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cycleCount.Sample();
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uint64 lcCycles = cycleCount.GetLongCycles();
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if ( lcCycles < m_lCycleLimit )
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return 0;
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return( ( int ) ( ( lcCycles - m_lCycleLimit ) * ( uint64 ) 1000000L / g_dwClockSpeed ) );
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}
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//-----------------------------------------------------------------------------
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// Purpose: If we're under our specified time period, return the amount under.
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// Output: # of microseconds until we reached our specified time period, 0 if we've passed it
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//-----------------------------------------------------------------------------
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inline uint64 CLimitTimer::CMicroSecLeft() const
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{
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CCycleCount cycleCount;
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cycleCount.Sample();
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uint64 lcCycles = cycleCount.GetLongCycles();
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if ( lcCycles >= m_lCycleLimit )
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return 0;
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return( ( uint64 ) ( ( m_lCycleLimit - lcCycles ) * ( uint64 ) 1000000L / g_dwClockSpeed ) );
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}
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#endif // FASTTIMER_H
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