//-----------------------------------------------------------------------
void Profiler::endProfile(const String& profileName, uint32 groupID)
{
if(!mEnabled)
{
// if the profiler received a request to be enabled or disabled
if(mNewEnableState != mEnabled)
{ // note mNewEnableState == true to reach this.
changeEnableState();
// NOTE we will be in an 'error' state until the next begin. ie endProfile will likely get invoked using a profileName that was never started.
// even then, we can't be sure that the next beginProfile will be the true start of a new frame
}
return;
}
else
{
if(mNewEnableState != mEnabled)
{ // note mNewEnableState == false to reach this.
changeEnableState();
// unwind the hierarchy, should be easy enough
mCurrent = &mRoot;
mLast = NULL;
}
if(&mRoot == mCurrent && mLast)
{ // profiler was enabled this frame, but the first subsequent beginProfile was NOT the beinging of a new frame as we had hoped.
// we have a bogus ProfileInstance in our hierarchy, we will need to remove it, then update the overlays so as not to confuse ze user
// we could use mRoot.children.find() instead of this, except we'd be compairing strings instead of a pointer.
// the string way could be faster, but i don't believe it would.
ProfileChildren::iterator it = mRoot.children.begin(), endit = mRoot.children.end();
for(;it != endit; ++it)
{
if(mLast == it->second)
{
mRoot.children.erase(it);
break;
}
}
// with mLast == NULL we won't reach this code, in case this isn't the end of the top level profile
ProfileInstance* last = mLast;
mLast = NULL;
OGRE_DELETE last;
processFrameStats();
displayResults();
}
}
if(&mRoot == mCurrent)
return;
// mask groups
if ((groupID & mProfileMask) == 0)
return;
// need a timer to profile!
assert (mTimer && "Timer not set!");
// get the end time of this profile
// we do this as close the beginning of this function as possible
// to get more accurate timing results
const ulong endTime = mTimer->getMicroseconds();
// empty string is reserved for designating an empty parent
assert ((profileName != "") && ("Profile name can't be an empty string"));
// we only process this profile if isn't disabled
// we check the current instance name against the provided profileName as a guard against disabling a profile name /after/ said profile began
if(mCurrent->name != profileName && mDisabledProfiles.find(profileName) != mDisabledProfiles.end())
return;
// calculate the elapsed time of this profile
const ulong timeElapsed = endTime - mCurrent->currTime;
// update parent's accumulator if it isn't the root
if (&mRoot != mCurrent->parent)
{
// add this profile's time to the parent's accumlator
mCurrent->parent->accum += timeElapsed;
}
mCurrent->frame.frameTime += timeElapsed;
++mCurrent->frame.calls;
mLast = mCurrent;
mCurrent = mCurrent->parent;
if (&mRoot == mCurrent)
{
// the stack is empty and all the profiles have been completed
// we have reached the end of the frame so process the frame statistics
// we know that the time elapsed of the main loop is the total time the frame took
mTotalFrameTime = timeElapsed;
if(timeElapsed > mMaxTotalFrameTime)
mMaxTotalFrameTime = timeElapsed;
// we got all the information we need, so process the profiles
// for this frame
processFrameStats();
// we display everything to the screen
displayResults();
}
}
//-----------------------------------------------------------------------
void Profiler::endProfile(const String& profileName, uint32 groupID) {
// if the profiler received a request to be enabled or disabled
// we reached the end of the frame so we can safely do this
if (mEnableStateChangePending) {
changeEnableState();
}
// if the profiler is enabled
if(!mEnabled) {
return;
}
// mask groups
if ((groupID & mProfileMask) == 0)
{
return;
}
// we only process this profile if isn't disabled
DisabledProfileMap::iterator dIter;
dIter = mDisabledProfiles.find(profileName);
if ( dIter != mDisabledProfiles.end() ) {
return;
}
// need a timer to profile!
assert (mTimer && "Timer not set!");
// get the end time of this profile
// we do this as close the beginning of this function as possible
// to get more accurate timing results
ulong endTime = mTimer->getMicroseconds();
// empty string is reserved for designating an empty parent
assert ((profileName != "") && ("Profile name can't be an empty string"));
// stack shouldn't be empty
assert (!mProfiles.empty());
// get the start of this profile
ProfileInstance bProfile;
bProfile = mProfiles.back();
mProfiles.pop_back();
// calculate the elapsed time of this profile
ulong timeElapsed = endTime - bProfile.currTime;
// update parent's accumulator if it isn't the root
if (bProfile.parent != "") {
// find the parent
ProfileStack::iterator iter;
for(iter = mProfiles.begin(); iter != mProfiles.end(); ++iter) {
if ((*iter).name == bProfile.parent)
break;
}
// the parent should be found
assert(iter != mProfiles.end());
// add this profile's time to the parent's accumlator
(*iter).accum += timeElapsed;
}
// we find the profile in this frame
ProfileFrameList::iterator iter;
for (iter = mProfileFrame.begin(); iter != mProfileFrame.end(); ++iter) {
if ((*iter).name == bProfile.name)
break;
}
// nested profiles are cumulative
(*iter).frameTime += timeElapsed;
(*iter).calls++;
// the stack is empty and all the profiles have been completed
// we have reached the end of the frame so process the frame statistics
if (mProfiles.empty()) {
// we know that the time elapsed of the main loop is the total time the frame took
mTotalFrameTime = timeElapsed;
if (timeElapsed > mMaxTotalFrameTime)
mMaxTotalFrameTime = timeElapsed;
// we got all the information we need, so process the profiles
// for this frame
processFrameStats();
// clear the frame stats for next frame
mProfileFrame.clear();
// we display everything to the screen
displayResults();
}
}
//--------------------------------------------------------------------
void Profiler::endProfile(const std::string& profileName, bool isSystemProfile) {
// if the profiler is enabled
if (!mEnabled || (isSystemProfile && !mEngineProfileEnabled))
return;
// need a timer to profile!
NR_ASSERT (mTimeSource && "Timer not set!");
// get the end time of this profile
// we do this as close the beginning of this function as possible
// to get more accurate timing results
float64 endTime = mTimeSource->getTime();
// empty string is reserved for designating an empty parent
NR_ASSERT ((profileName != "") && ("Profile name can't be an empty string"));
// stack shouldnt be empty
NR_ASSERT (!mProfiles.empty() && ("You have to begin any profile before stop it"));
// get the start of this profile
ProfileInstance bProfile;
bProfile = mProfiles.back();
mProfiles.pop_back();
// calculate the elapsed time of this profile
float64 timeElapsed = endTime - bProfile.currTime;
// update parent's accumalator if it isn't the root
if (bProfile.parent != "") {
// find the parent
ProfileStack::iterator iter;
for(iter = mProfiles.begin(); iter != mProfiles.end(); iter++)
if ((*iter).name == bProfile.parent)
break;
// the parent should be found
NR_ASSERT(iter != mProfiles.end());
// add this profile's time to the parent's accumulator
(*iter).accum += timeElapsed;
}
// we find the profile in this frame
ProfileFrameList::iterator iter;
for (iter = mProfileFrame.begin(); iter != mProfileFrame.end(); iter++)
if ((*iter).name == bProfile.name)
break;
// we subtract the time the children profiles took from this profile
(*iter).frameTime += timeElapsed - bProfile.accum;
(*iter).frameTotalTime += timeElapsed;
(*iter).calls++;
// the stack is empty and all the profiles have been completed
// we have reached the end of the frame so process the frame statistics
if (mProfiles.empty()) {
// we know that the time elapsed of the main loop is the total time the frame took
mTotalFrameTime = timeElapsed;
// we got all the information we need, so process the profiles
// for this frame
processFrameStats();
// clear the frame stats for next frame
mProfileFrame.clear();
// if the profiler received a request to be enabled or disabled
// we reached the end of the frame so we can safely do this
if (mEnableStateChangePending) {
changeEnableState();
}
}
}
