khanat-opennel-code/code/nel/src/3d/animation_optimizer.cpp

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// NeL - MMORPG Framework <http://dev.ryzom.com/projects/nel/>
// Copyright (C) 2010 Winch Gate Property Limited
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Affero General Public License as
// published by the Free Software Foundation, either version 3 of the
// License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
#include "std3d.h"
#include "nel/3d/animation_optimizer.h"
#include "nel/misc/mem_stream.h"
#include "nel/misc/vectord.h"
#include "nel/3d/track.h"
#include "nel/3d/track_keyframer.h"
#include "nel/3d/animation.h"
#include "nel/3d/track_sampled_quat.h"
#include "nel/3d/track_sampled_vector.h"
using namespace NLMISC;
using namespace std;
namespace NL3D
{
// ***************************************************************************
CAnimationOptimizer::CAnimationOptimizer()
{
_SampleFrameRate= 30;
_QuaternionThresholdLowPrec= 1.0 - 0.0001;
_QuaternionThresholdHighPrec= 1.0 - 0.000001;
_VectorThresholdLowPrec= 0.001;
_VectorThresholdHighPrec= 0.0001;
}
// ***************************************************************************
void CAnimationOptimizer::setQuaternionThreshold(double lowPrecThre, double highPrecThre)
{
nlassert(lowPrecThre>=0);
nlassert(highPrecThre>=0);
_QuaternionThresholdLowPrec= 1.0 - lowPrecThre;
_QuaternionThresholdHighPrec= 1.0 - highPrecThre;
}
// ***************************************************************************
void CAnimationOptimizer::setVectorThreshold(double lowPrecThre, double highPrecThre)
{
nlassert(lowPrecThre>=0);
nlassert(highPrecThre>=0);
_VectorThresholdLowPrec= lowPrecThre;
_VectorThresholdHighPrec= highPrecThre;
}
// ***************************************************************************
void CAnimationOptimizer::setSampleFrameRate(float frameRate)
{
nlassert(frameRate>0);
_SampleFrameRate= frameRate;
}
// ***************************************************************************
void CAnimationOptimizer::optimize(const CAnimation &animIn, CAnimation &animOut)
{
// reset animOut
contReset(animOut);
// Parse all tracks of the animation.
set<string> setString;
animIn.getTrackNames (setString);
set<string>::iterator it;
for(it=setString.begin();it!=setString.end();it++)
{
const string &trackName= *it;
uint trackId= animIn.getIdTrackByName(trackName);
nlassert(trackId!=CAnimation::NotFound);
const ITrack *track= animIn.getTrack(trackId);
// If the track is optimisable.
ITrack *newTrack;
if(isTrackOptimisable(track))
{
// choose the threshold according to precision wanted
if( isLowPrecisionTrack(trackName) )
{
_QuaternionThreshold= _QuaternionThresholdLowPrec;
_VectorThreshold= _VectorThresholdLowPrec;
}
else
{
_QuaternionThreshold= _QuaternionThresholdHighPrec;
_VectorThreshold= _VectorThresholdHighPrec;
}
// optimize it.
newTrack= optimizeTrack(track);
}
else
{
// just clone it.
newTrack= cloneTrack(track);
}
// Add it to the animation
animOut.addTrack(trackName, newTrack);
}
// Parse all SSS shapes of the animation (important for preload of those shapes)
const vector<string> &shapes= animIn.getSSSShapes();
for(uint i=0;i<shapes.size();i++)
animOut.addSSSShape(shapes[i]);
// Set min animation length
animOut.setMinEndTime (animIn.getEndTime ());
nlassert (animOut.getEndTime() == animIn.getEndTime());
}
// ***************************************************************************
ITrack *CAnimationOptimizer::cloneTrack(const ITrack *trackIn)
{
CMemStream memStream;
// write to the stream.
ITrack *trackInSerial= const_cast<ITrack*>(trackIn);
memStream.serialPolyPtr(trackInSerial);
// read from the stream.
memStream.invert();
ITrack *ret= NULL;
memStream.serialPolyPtr(ret);
return ret;
}
// ***************************************************************************
bool CAnimationOptimizer::isTrackOptimisable(const ITrack *trackIn)
{
nlassert(trackIn);
// If the track is a Linear, Bezier or a TCB track, suppose we can optimize it. Constant may not be interressant....
if( dynamic_cast<const CTrackKeyFramerTCBQuat*>(trackIn) ||
dynamic_cast<const CTrackKeyFramerBezierQuat*>(trackIn) ||
dynamic_cast<const CTrackKeyFramerLinearQuat*>(trackIn) )
return true;
// If the track is a Linear, Bezier or a TCB track, suppose we can optimize it. Constant may not be interressant....
if( dynamic_cast<const CTrackKeyFramerTCBVector*>(trackIn) ||
dynamic_cast<const CTrackKeyFramerBezierVector*>(trackIn) ||
dynamic_cast<const CTrackKeyFramerLinearVector*>(trackIn) )
return true;
return false;
}
// ***************************************************************************
ITrack *CAnimationOptimizer::optimizeTrack(const ITrack *trackIn)
{
// Get track param.
float beginTime= trackIn->getBeginTime();
float endTime= trackIn->getEndTime();
nlassert(endTime>=beginTime);
// Get num Sample
uint numSamples= (uint)ceil( (endTime-beginTime)*_SampleFrameRate);
numSamples= max(1U, numSamples);
nlassert(numSamples<65535);
// Optimize Quaternion track??
//================
// eval the track only to get its value type!!
CAnimatedValueBlock avBlock;
const IAnimatedValue &valueType= ((ITrack*)trackIn)->eval(0, avBlock);
if( dynamic_cast<const CAnimatedValueQuat *>(&valueType) )
{
// sample the animation. Store result in _TimeList/_QuatKeyList
sampleQuatTrack(trackIn, beginTime, endTime, numSamples);
// check if the sampled track can be reduced to a TrackDefaultQuat. Test _QuatKeyList.
if( testConstantQuatTrack() )
{
// create a default Track Quat.
CTrackDefaultQuat *trackDefault= new CTrackDefaultQuat;
// setup the uniform value.
trackDefault->setDefaultValue(_QuatKeyList[0]);
// return the result.
return trackDefault;
}
// else optimize the sampled animation, and build.
else
{
// optimize.
optimizeQuatTrack();
// Create a sampled quaternion track
CTrackSampledQuat *trackSQ= new CTrackSampledQuat;
// Copy loop from track.
trackSQ->setLoopMode(trackIn->getLoopMode());
// Build it.
trackSQ->build(_TimeList, _QuatKeyList, beginTime, endTime);
// return result.
return trackSQ;
}
}
// Optimize Position track??
//================
else if( dynamic_cast<const CAnimatedValueVector *>(&valueType) )
{
// sample the animation. Store result in _TimeList/_VectorKeyList
sampleVectorTrack(trackIn, beginTime, endTime, numSamples);
// check if the sampled track can be reduced to a TrackDefaultVector. Test _VectorKeyList.
if( testConstantVectorTrack() )
{
// create a default Track Vector.
CTrackDefaultVector *trackDefault= new CTrackDefaultVector;
// setup the uniform value.
trackDefault->setDefaultValue(_VectorKeyList[0]);
// return the result.
return trackDefault;
}
// else optimize the sampled animation, and build.
else
{
// optimize.
optimizeVectorTrack();
// Create a sampled Vector track
CTrackSampledVector *trackSV= new CTrackSampledVector;
// Copy loop from track.
trackSV->setLoopMode(trackIn->getLoopMode());
// Build it.
trackSV->build(_TimeList, _VectorKeyList, beginTime, endTime);
// return result.
return trackSV;
}
}
else
{
// Must be a quaternion track or vector track for now.
nlstop;
// Avoid warning.
return cloneTrack(trackIn);
}
}
// ***************************************************************************
// ***************************************************************************
// Quaternion optimisation
// ***************************************************************************
// ***************************************************************************
// ***************************************************************************
void CAnimationOptimizer::sampleQuatTrack(const ITrack *trackIn, float beginTime, float endTime, uint numSamples)
{
// resize tmp samples
_TimeList.resize(numSamples);
_QuatKeyList.resize(numSamples);
// Sample the animation.
float t= beginTime;
float dt= 0;
if(numSamples>1)
dt= (endTime-beginTime)/(numSamples-1);
for(uint i=0;i<numSamples; i++, t+=dt)
{
CQuat quat;
// make exact endTime match (avoid precision problem)
if(i==numSamples-1)
t= endTime;
// evaluate the track
const_cast<ITrack*>(trackIn)->interpolate(t, quat);
// normalize this quaternion
quat.normalize();
// force on same hemisphere according to precedent frame.
if(i>0)
{
quat.makeClosest(_QuatKeyList[i-1]);
}
// store time and key.
_TimeList[i]= i;
_QuatKeyList[i]= quat;
}
}
// ***************************************************************************
bool CAnimationOptimizer::testConstantQuatTrack()
{
uint numSamples= (uint)_QuatKeyList.size();
nlassert(numSamples>0);
// Get the first sample as the reference quaternion, and test others from this one.
CQuat quatRef= _QuatKeyList[0];
for(uint i=0;i<numSamples;i++)
{
// All values must be nearly equal to the reference quaternion.
if(!nearlySameQuaternion(quatRef, _QuatKeyList[i]))
return false;
}
// ok.
return true;
}
// ***************************************************************************
void CAnimationOptimizer::optimizeQuatTrack()
{
uint numSamples= (uint)_QuatKeyList.size();
nlassert(numSamples>0);
// <=2 key? => no opt possible..
if(numSamples<=2)
return;
// prepare dest opt
std::vector<uint16> optTimeList;
std::vector<CQuat> optKeyList;
optTimeList.reserve(numSamples);
optKeyList.reserve(numSamples);
// Add the first key.
optTimeList.push_back(_TimeList[0]);
optKeyList.push_back(_QuatKeyList[0]);
double timeRef= _TimeList[0];
CQuatD quatRef= _QuatKeyList[0];
// For all keys, but the first and the last, test if can remove them.
for(uint i=1; i<numSamples-1; i++)
{
CQuatD quatCur= _QuatKeyList[i];
CQuatD quatNext= _QuatKeyList[i+1];
double timeCur= _TimeList[i];
double timeNext= _TimeList[i+1];
// must add the key?
bool mustAdd= false;
// If the Delta time are too big, abort (CTrackSampledQuat limitation)
if(timeNext-timeRef>255)
{
mustAdd= true;
}
// If the next quaternion or the current quaternion are not on same hemisphere than ref, abort.
else if( CQuatD::dotProduct(quatCur, quatRef)<0 || CQuatD::dotProduct(quatNext, quatRef)<0 )
{
mustAdd= true;
}
// else, test interpolation
else
{
// If the 3 quats are nearly equals, it is ok (avoid interpolation)
if( nearlySameQuaternion(quatRef, quatCur) && nearlySameQuaternion(quatRef, quatNext) )
mustAdd= false;
else
{
// interpolate.
CQuatD quatInterpolated;
double t= (timeCur-timeRef)/(timeNext/timeRef);
quatInterpolated= CQuatD::slerp(quatRef, quatNext, (float)t);
// test if cur and interpolate are equal.
if( !nearlySameQuaternion(quatCur, quatInterpolated) )
mustAdd= true;
}
}
// If must add the key to the optimized track.
if(mustAdd)
{
optTimeList.push_back(_TimeList[i]);
optKeyList.push_back(_QuatKeyList[i]);
timeRef= _TimeList[i];
quatRef= _QuatKeyList[i];
}
}
// Add the last key.
optTimeList.push_back(_TimeList[numSamples-1]);
optKeyList.push_back(_QuatKeyList[numSamples-1]);
// copy the optimized track to the main one.
_TimeList= optTimeList;
_QuatKeyList= optKeyList;
}
// ***************************************************************************
bool CAnimationOptimizer::nearlySameQuaternion(const CQuatD &quat0, const CQuatD &quat1)
{
// true if exactly same, or exactly inverse
if(quat0==quat1 || quat0==-quat1)
return true;
// Else compute the rotation to go from qRef to q. Use double for better presion.
CQuatD quatDif;
quatDif= quat1 * quat0.conjugate();
// inverse the quaternion if necessary. ie make closest to the identity quaternion.
if(quatDif.w<0)
quatDif= -quatDif;
// compare "angle threshold"
return (quatDif.w >= _QuaternionThreshold);
}
// ***************************************************************************
// ***************************************************************************
// Vector optimisation
// ***************************************************************************
// ***************************************************************************
// ***************************************************************************
void CAnimationOptimizer::sampleVectorTrack(const ITrack *trackIn, float beginTime, float endTime, uint numSamples)
{
// resize tmp samples
_TimeList.resize(numSamples);
_VectorKeyList.resize(numSamples);
// Sample the animation.
float t= beginTime;
float dt= 0;
if(numSamples>1)
dt= (endTime-beginTime)/(numSamples-1);
for(uint i=0;i<numSamples; i++, t+=dt)
{
CVector vector;
// make exact endTime match (avoid precision problem)
if(i==numSamples-1)
t= endTime;
// evaluate the track
const_cast<ITrack*>(trackIn)->interpolate(t, vector);
// store time and key.
_TimeList[i]= i;
_VectorKeyList[i]= vector;
}
}
// ***************************************************************************
bool CAnimationOptimizer::testConstantVectorTrack()
{
uint numSamples= (uint)_VectorKeyList.size();
nlassert(numSamples>0);
// Get the first sample as the reference Vectorer, and test others from this one.
CVector vectorRef= _VectorKeyList[0];
for(uint i=0;i<numSamples;i++)
{
// All values must be nearly equal to the reference vector.
if(!nearlySameVector(vectorRef, _VectorKeyList[i]))
return false;
}
// ok.
return true;
}
// ***************************************************************************
void CAnimationOptimizer::optimizeVectorTrack()
{
uint numSamples= (uint)_VectorKeyList.size();
nlassert(numSamples>0);
// <=2 key? => no opt possible..
if(numSamples<=2)
return;
// prepare dest opt
std::vector<uint16> optTimeList;
std::vector<CVector> optKeyList;
optTimeList.reserve(numSamples);
optKeyList.reserve(numSamples);
// Add the first key.
optTimeList.push_back(_TimeList[0]);
optKeyList.push_back(_VectorKeyList[0]);
double timeRef= _TimeList[0];
CVectorD vectorRef= _VectorKeyList[0];
// For all keys, but the first and the last, test if can remove them.
for(uint i=1; i<numSamples-1; i++)
{
CVectorD vectorCur= _VectorKeyList[i];
CVectorD vectorNext= _VectorKeyList[i+1];
double timeCur= _TimeList[i];
double timeNext= _TimeList[i+1];
// must add the key?
bool mustAdd= false;
// If the Delta time are too big, abort (CTrackSampledVector limitation)
if(timeNext-timeRef>255)
{
mustAdd= true;
}
// else, test interpolation
else
{
// If the 3 Vectors are nearly equals, it is ok (avoid interpolation)
if( nearlySameVector(vectorRef, vectorCur) && nearlySameVector(vectorRef, vectorNext) )
mustAdd= false;
else
{
// interpolate.
CVectorD vectorInterpolated;
double t= (timeCur-timeRef)/(timeNext/timeRef);
vectorInterpolated= vectorRef*(1-t) + vectorNext*t;
// test if cur and interpolate are equal.
if( !nearlySameVector(vectorCur, vectorInterpolated) )
mustAdd= true;
}
}
// If must add the key to the optimized track.
if(mustAdd)
{
optTimeList.push_back(_TimeList[i]);
optKeyList.push_back(_VectorKeyList[i]);
timeRef= _TimeList[i];
vectorRef= _VectorKeyList[i];
}
}
// Add the last key.
optTimeList.push_back(_TimeList[numSamples-1]);
optKeyList.push_back(_VectorKeyList[numSamples-1]);
// copy the optimized track to the main one.
_TimeList= optTimeList;
_VectorKeyList= optKeyList;
}
// ***************************************************************************
bool CAnimationOptimizer::nearlySameVector(const CVectorD &v0, const CVectorD &v1)
{
// true if exactly same
if(v0==v1)
return true;
// Else compute the dif, use double for better precision
CVectorD vDif;
vDif= v1-v0;
// compare norm
return (vDif.norm() <= _VectorThreshold);
}
// ***************************************************************************
// ***************************************************************************
// LowPrecisionTrack
// ***************************************************************************
// ***************************************************************************
// ***************************************************************************
void CAnimationOptimizer::addLowPrecisionTrack(const std::string &name)
{
_LowPrecTrackKeyName.push_back(name);
}
// ***************************************************************************
void CAnimationOptimizer::clearLowPrecisionTracks()
{
_LowPrecTrackKeyName.clear();
}
// ***************************************************************************
bool CAnimationOptimizer::isLowPrecisionTrack(const std::string &trackName)
{
for(uint i=0; i<_LowPrecTrackKeyName.size(); i++)
{
// if find a substr of the key, it is a low prec track
if( trackName.find(_LowPrecTrackKeyName[i]) != string::npos )
return true;
}
// no key found
return false;
}
} // NL3D