isle/LEGO1/mxdirectx/mxstopwatch.h
Christian Semmler dac2a517c3
Implement/match LegoVideoManager::Tickle (#409)
* Implement LegoVideoManager::Tickle

* Match

* Remove duplicate annotations

* Add missing annotations

* Rename list functions

* Fix

* Rename some symbols
2024-01-06 18:06:50 +01:00

181 lines
3.4 KiB
C++

#ifndef _MxStopWatch_h
#define _MxStopWatch_h
#include "assert.h"
#include "winbase.h"
//////////////////////////////////////////////////////////////////////////////
//
// MxStopWatch
//
// NOTE: MxStopWatch measures elapsed (wall clock) time.
//
#define HUGE_VAL_IMMEDIATE 1.7976931348623157e+308
class MxStopWatch {
public:
MxStopWatch();
~MxStopWatch() {}
void Start();
void Stop();
void Reset();
double ElapsedSeconds() const;
protected:
unsigned long TicksPerSeconds() const;
private:
LARGE_INTEGER m_startTick;
// ??? when we provide LARGE_INTEGER arithmetic, use a
// LARGE_INTEGER m_elapsedTicks rather than m_elapsedSeconds
double m_elapsedSeconds;
unsigned long m_ticksPerSeconds;
};
inline MxStopWatch::MxStopWatch()
{
Reset();
m_ticksPerSeconds = TicksPerSeconds();
}
inline void MxStopWatch::Start()
{
QueryPerformanceCounter(&m_startTick);
}
inline void MxStopWatch::Stop()
{
LARGE_INTEGER endTick;
BOOL result;
result = QueryPerformanceCounter(&endTick);
assert(result);
if (endTick.HighPart != m_startTick.HighPart) {
// LARGE_INTEGER arithmetic not yet provided
m_elapsedSeconds = HUGE_VAL_IMMEDIATE;
}
else {
m_elapsedSeconds += ((endTick.LowPart - m_startTick.LowPart) / (double) m_ticksPerSeconds);
}
}
inline void MxStopWatch::Reset()
{
m_startTick.LowPart = 0;
m_startTick.HighPart = 0;
m_elapsedSeconds = 0;
}
inline unsigned long MxStopWatch::TicksPerSeconds() const
{
LARGE_INTEGER ticksPerSeconds;
BOOL result;
result = QueryPerformanceFrequency(&ticksPerSeconds);
assert(result);
if (ticksPerSeconds.HighPart) {
// LARGE_INTEGER arithmetic not yet provided
// timer is too fast (faster than 32bits/s, i.e. faster than 4GHz)
return ULONG_MAX;
}
else {
return ticksPerSeconds.LowPart;
}
}
inline double MxStopWatch::ElapsedSeconds() const
{
return m_elapsedSeconds;
}
//////////////////////////////////////////////////////////////////////////////
//
// MxFrequencyMeter
//
class MxFrequencyMeter {
public:
MxFrequencyMeter();
void StartOperation();
void EndOperation();
double Frequency() const;
void Reset();
unsigned long OperationCount() const;
double ElapsedSeconds() const;
void IncreaseOperationCount(unsigned long);
private:
unsigned long m_operationCount;
MxStopWatch m_stopWatch;
};
//////////////////////////////////////////////////////////////////////////////
//
// MxFrequencyMeter implementation
//
inline MxFrequencyMeter::MxFrequencyMeter() : m_operationCount(0)
{
}
inline void MxFrequencyMeter::StartOperation()
{
m_stopWatch.Start();
}
inline void MxFrequencyMeter::EndOperation()
{
m_stopWatch.Stop();
m_operationCount++;
}
inline double MxFrequencyMeter::Frequency() const
{
double elapsedSeconds = m_stopWatch.ElapsedSeconds();
if (elapsedSeconds > 0) {
return m_operationCount / elapsedSeconds;
}
else {
if (m_operationCount) {
// operations performed - no time elapsed
return HUGE_VAL;
}
else {
// no operations performed - no time elapsed
return 0;
}
}
}
inline void MxFrequencyMeter::Reset()
{
m_stopWatch.Reset();
m_operationCount = 0;
}
inline unsigned long MxFrequencyMeter::OperationCount() const
{
return m_operationCount;
}
inline void MxFrequencyMeter::IncreaseOperationCount(unsigned long delta)
{
m_operationCount += delta;
}
inline double MxFrequencyMeter::ElapsedSeconds() const
{
return m_stopWatch.ElapsedSeconds();
}
#endif /* _MxStopWatch_h */