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569 lines
14 KiB
C++
569 lines
14 KiB
C++
// NeL - MMORPG Framework <http://dev.ryzom.com/projects/nel/>
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// Copyright (C) 2010 Winch Gate Property Limited
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//
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Affero General Public License as
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// published by the Free Software Foundation, either version 3 of the
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// License, or (at your option) any later version.
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//
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Affero General Public License for more details.
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//
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// You should have received a copy of the GNU Affero General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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#ifndef NL_TRACK_H
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#error "internal file included from track.h"
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#endif
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// ***************************************************************************
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// ***************************************************************************
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// TCB Keyframes.
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// ***************************************************************************
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// ***************************************************************************
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// ***************************************************************************
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/**
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* TCB Track tools (for both normal TCB, and quat TCB). internal use.
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*
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* \author Cyril 'Hulud' Corvazier
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* \author Nevrax France
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* \date 2001
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*/
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template<class CKeyT, class T, class TMapTimeCKey>
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class CTCBTools
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{
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protected:
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typedef typename TMapTimeCKey::iterator TMapTimeCKeyIterator;
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/// compute TCB ease information.
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void compileTCBEase(TMapTimeCKey &mapKey, bool loopMode)
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{
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TMapTimeCKeyIterator it= mapKey.begin();
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for(;it!=mapKey.end();it++)
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{
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TMapTimeCKeyIterator next= it;
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next++;
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// loop mgt. must compute ease from last to first (useful if _RangeLock is false).
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if(next==mapKey.end() && loopMode && mapKey.size()>1)
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next= mapKey.begin();
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// Ease Precompute.
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//=================
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CKeyT &key= it->second;
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if(next!=mapKey.end())
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{
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float e0= it->second.EaseFrom;
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float e1= next->second.EaseTo;
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float s = e0 + e1;
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// "normalize".
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if (s > 1.0f)
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{
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e0 = e0/s;
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e1 = e1/s;
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}
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// precalc ease factors.
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key.Ease0= e0;
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key.Ease1= e1;
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key.EaseK= 1/(2.0f - e0 - e1);
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if(e0)
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key.EaseKOverEase0= key.EaseK / e0;
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if(e1)
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key.EaseKOverEase1= key.EaseK / e1;
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}
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else
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{
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// force ease() to just return d (see ease()).
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key.EaseK = 0.5f;
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}
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}
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}
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// ease time.
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float ease(const CKeyT *key, float d)
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{
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if (d==0.0f || d==1.0f) return d;
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// k==0.5f <=> e0+e1 == 0.
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if (key->EaseK == 0.5f) return d;
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if (d < key->Ease0)
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return key->EaseKOverEase0 * d*d;
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else if (d < 1.0f - key->Ease1)
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return key->EaseK * (2.0f*d - key->Ease0);
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else
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{
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d = 1.0f - d;
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return 1.0f - key->EaseKOverEase1 * d*d;
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}
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}
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// compute hermite factors.
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void computeHermiteBasis(float d, float hb[4])
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{
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float d2,d3,a;
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d2 = d*d;
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d3 = d2*d;
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a = 3.0f*d2 - 2.0f*d3;
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hb[0] = 1.0f - a;
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hb[1] = a;
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hb[2] = d3 - 2.0f*d2 + d;
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hb[3] = d3 - d2;
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}
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// compute TCB tangents factors.
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void computeTCBFactors(const CKeyT &key, float timeBefore, float time, float timeAfter,
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float rangeDelta, bool firstKey, bool endKey, bool isLoop, float &ksm, float &ksp, float &kdm, float &kdp)
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{
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float fp,fn;
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if(isLoop || (!firstKey && !endKey))
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{
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float dtm;
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// Compute Time deltas.
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if (firstKey)
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{
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dtm = 0.5f * (rangeDelta + timeAfter - time);
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fp = rangeDelta / dtm;
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fn = (timeAfter - time) / dtm;
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}
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else if (endKey)
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{
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dtm = 0.5f * (rangeDelta + time - timeBefore);
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fp = rangeDelta / dtm;
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fn = (time - timeBefore) / dtm;
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}
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else
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{
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dtm = 0.5f * (timeAfter - timeBefore);
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fp = (time - timeBefore) / dtm;
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fn = (timeAfter - time) / dtm;
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}
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float c= (float)fabs( key.Continuity );
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fp = fp + c - c * fp;
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fn = fn + c - c * fn;
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}
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else
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{
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// firstkey and lastkey of not loop track.
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fp = 1.0f;
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fn = 1.0f;
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}
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// Compute tangents factors.
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float tm,cm,cp,bm,bp,tmcm,tmcp;
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cm = 1.0f - key.Continuity;
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tm = 0.5f * ( 1.0f - key.Tension );
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cp = 2.0f - cm;
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bm = 1.0f - key.Bias;
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bp = 2.0f - bm;
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tmcm = tm*cm; tmcp = tm*cp;
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// tgts factors.
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ksm = tmcm*bp*fp; ksp = tmcp*bm*fp;
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kdm = tmcp*bp*fn; kdp = tmcm*bm*fn;
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}
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};
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// ***************************************************************************
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/**
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* ITrack implementation for TCB keyframer.
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*
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* \author Cyril 'Hulud' Corvazier
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* \author Nevrax France
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* \date 2001
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*/
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template<class CKeyT, class T>
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class CTrackKeyFramerTCB : public ITrackKeyFramer<CKeyT>, private CTCBTools<CKeyT, T, std::map<TAnimationTime, CKeyT> >
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{
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public:
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protected:
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typedef typename CKeyT::TValueType TKeyValueType;
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/// \name From ITrackKeyFramer
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// @{
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/// evalKey (runtime).
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virtual void evalKey ( const CKeyT* previous, const CKeyT* next,
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TAnimationTime datePrevious, TAnimationTime /* dateNext */,
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TAnimationTime date, IAnimatedValue &result )
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{
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CAnimatedValueBlendable<T> &resultVal= static_cast<CAnimatedValueBlendable<T>&>(result);
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if(previous && next)
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{
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// lerp from previous to cur.
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date-= datePrevious;
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date*= previous->OODeltaTime;
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NLMISC::clamp(date, 0,1);
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date = this->ease(previous, date);
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float hb[4];
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this->computeHermiteBasis(date, hb);
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copyToValue(resultVal.Value,
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previous->Value*hb[0] + next->Value*hb[1] +
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previous->TanFrom*hb[2] + next->TanTo*hb[3]);
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}
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else
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{
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if (previous)
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copyToValue(resultVal.Value, previous->Value);
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else
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if (next)
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copyToValue(resultVal.Value, next->Value);
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}
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}
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/// compile (precalc).
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virtual void compile()
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{
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ITrackKeyFramer<CKeyT>::compile();
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// Ease Precompute.
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this->compileTCBEase(this->_MapKey, this->getLoopMode());
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// Tangents Precompute.
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sint nKeys= (sint)this->_MapKey.size();
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if(nKeys<=1)
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return;
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typename std::map<TAnimationTime, CKeyT>::iterator it= this->_MapKey.begin(); // first key.
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typename std::map<TAnimationTime, CKeyT>::iterator itNext= it; itNext++; // second key.
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typename std::map<TAnimationTime, CKeyT>::iterator itPrev= this->_MapKey.end(); itPrev--; // last key.
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if(nKeys==2 && !this->getLoopMode())
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{
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computeTCBKeyLinear( it->second, itNext->second );
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}
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else
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{
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// rangeDelta is the length of effective Range - length of LastKey-FirstKey.
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// NB: if RangeLock, rangeDelta==0.
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float rangeDelta;
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// NB: _RangeDelta has just been compiled in ITrackKeyFramer<CKeyT>::compile().
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rangeDelta= this->getCompiledRangeDelta();
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// Compute all middle keys.
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for(;it!=this->_MapKey.end();)
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{
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// Do the first key and the last key only in LoopMode.
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// NB: we are the last if itNext==_MapKey.begin().
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if(this->getLoopMode() || (it!=this->_MapKey.begin() && itNext!=this->_MapKey.begin()) )
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{
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computeTCBKey(itPrev->second, it->second, itNext->second,
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itPrev->first, it->first, itNext->first, rangeDelta,
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it==this->_MapKey.begin(), itNext==this->_MapKey.begin(), this->getLoopMode());
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}
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// Next key!!
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itPrev= it;
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it++;
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itNext++;
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// loop.
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if(itNext==this->_MapKey.end())
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itNext= this->_MapKey.begin();
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}
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// In not loop mode, compute first and last key, AFTER middle keys computed.
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if(!this->getLoopMode())
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{
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typename std::map<TAnimationTime, CKeyT>::iterator it0= this->_MapKey.begin(); // first key.
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typename std::map<TAnimationTime, CKeyT>::iterator it1= it0; it1++; // second key.
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typename std::map<TAnimationTime, CKeyT>::iterator itLast= this->_MapKey.end();itLast--; // last key.
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typename std::map<TAnimationTime, CKeyT>::iterator itLastPrev= itLast;itLastPrev--; // prev of last key.
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computeFirstKey(it0->second, it1->second);
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computeLastKey(itLast->second, itLastPrev->second);
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}
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}
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}
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// @}
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// *****************
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private:
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void computeTCBKey(CKeyT &keyBefore, CKeyT &key, CKeyT &keyAfter, float timeBefore, float time, float timeAfter,
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float rangeDelta, bool firstKey, bool endKey, bool isLoop)
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{
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float ksm,ksp,kdm,kdp;
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// compute tangents factors.
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this->computeTCBFactors(key, timeBefore, time, timeAfter, rangeDelta, firstKey, endKey, isLoop, ksm,ksp,kdm,kdp);
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// Delta.
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TKeyValueType delm, delp;
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delm = key.Value - keyBefore.Value;
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delp = keyAfter.Value - key.Value;
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// Tangents.
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key.TanTo = delm*ksm + delp*ksp;
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key.TanFrom= delm*kdm + delp*kdp;
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}
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// compute 2 TCB keys for a not-loop track => "linear".
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void computeTCBKeyLinear(CKeyT &key0, CKeyT &key1)
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{
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float f0, f1;
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TKeyValueType dv;
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f0 = 1.0f - key0.Tension;
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f1 = 1.0f - key1.Tension;
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dv = key1.Value - key0.Value;
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key0.TanFrom= dv * f0;
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key1.TanTo= dv * f1;
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}
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// compute this AFTER computing key1.
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void computeFirstKey(CKeyT &keyFirst, CKeyT &keyAfter)
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{
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float tm;
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tm = 0.5f * (1.0f - keyFirst.Tension);
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keyFirst.TanFrom= tm * ((keyAfter.Value - keyFirst.Value) * 3.0f - keyAfter.TanTo);
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}
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// compute this AFTER computing key(n-2).
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void computeLastKey(CKeyT &keyLast, CKeyT &keyBefore)
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{
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float tm;
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tm = 0.5f * (1.0f - keyLast.Tension);
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keyLast.TanTo= tm * ((keyLast.Value - keyBefore.Value) * 3.0f - keyBefore.TanFrom);
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}
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};
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// ***************************************************************************
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/**
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* ITrack implementation for CQuat TCB keyframer.
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*
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* \author Lionel Berenguier
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* \author Nevrax France
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* \date 2001
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*/
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template<> class CTrackKeyFramerTCB<CKeyTCBQuat, NLMISC::CAngleAxis> : public ITrackKeyFramer<CKeyTCBQuat>,
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private CTCBTools<CKeyTCBQuat, NLMISC::CAngleAxis, std::map<TAnimationTime, CKeyTCBQuat> >
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{
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public:
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/// \name From ITrackKeyFramer
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// @{
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/// evalKey (runtime).
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virtual void evalKey ( const CKeyTCBQuat* previous, const CKeyTCBQuat* next,
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TAnimationTime datePrevious, TAnimationTime /* dateNext */,
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TAnimationTime date, IAnimatedValue &result )
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{
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CAnimatedValueQuat &resultVal= static_cast<CAnimatedValueQuat&>(result);
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if(previous && next)
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{
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// lerp from previous to cur.
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date-= datePrevious;
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date*= previous->OODeltaTime;
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NLMISC::clamp(date, 0,1);
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// ease.
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date = ease(previous, date);
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// quad slerp.
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resultVal.Value= CQuat::squadrev(next->LocalAngleAxis, previous->Quat, previous->A, next->B, next->Quat, date);
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}
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else
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{
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if (previous)
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resultVal.Value= previous->Quat;
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else
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if (next)
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resultVal.Value= next->Quat;
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}
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}
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/// compile (precalc).
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virtual void compile()
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{
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ITrackKeyFramer<CKeyTCBQuat>::compile();
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// Ease Precompute.
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this->compileTCBEase(_MapKey, getLoopMode());
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TMapTimeCKey::iterator it;
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TMapTimeCKey::iterator itNext;
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TMapTimeCKey::iterator itPrev;
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// Compute absolute quaternions.
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for (it= _MapKey.begin();it!=_MapKey.end();)
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{
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CKeyTCBQuat &key= it->second;
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// Compute Local AngleAxis.
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if(it!= _MapKey.begin())
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{
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NLMISC::CMatrix mat;
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mat.setRot(itPrev->second.Quat);
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mat.invert();
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key.LocalAngleAxis.Axis= mat*key.Value.Axis;
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key.LocalAngleAxis.Angle= key.Value.Angle;
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}
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else
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key.LocalAngleAxis= key.Value;
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key.LocalAngleAxis.Axis.normalize();
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// make angle positive.
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if(key.LocalAngleAxis.Angle<0.f)
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{
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key.LocalAngleAxis.Axis= -key.LocalAngleAxis.Axis;
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key.LocalAngleAxis.Angle= -key.LocalAngleAxis.Angle;
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}
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// relative quat
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key.Quat.setAngleAxis(key.LocalAngleAxis);
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// absolute quat
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if (it!= _MapKey.begin())
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key.Quat = itPrev->second.Quat * key.Quat;
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// next key.
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itPrev= it;
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it++;
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}
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// Tangents Precompute.
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sint nKeys= (sint)_MapKey.size();
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if(nKeys<=1)
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return;
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// rangeDelta is the length of effective Range - length of LastKey-FirstKey.
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// NB: if RangeLock, rangeDelta==0.
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float rangeDelta;
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// NB: _RangeDelta has just been compiled in ITrackKeyFramer<CKeyTCBQuat>::compile().
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rangeDelta= getCompiledRangeDelta();
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it= _MapKey.begin(); // first key.
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itNext= it; itNext++; // second key.
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itPrev= _MapKey.end(); itPrev--; // last key.
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// Compute all keys.
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for(;it!=_MapKey.end();)
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{
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// NB: we are the last key if itNext==_MapKey.begin().
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computeTCBKey(itPrev->second, it->second, itNext->second,
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itPrev->first, it->first, itNext->first, rangeDelta, it==_MapKey.begin(), itNext==_MapKey.begin(), getLoopMode());
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// Next key!!
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itPrev= it;
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it++;
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itNext++;
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// loop.
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if(itNext==_MapKey.end())
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itNext= _MapKey.begin();
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}
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}
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// @}
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// *****************
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private:
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void computeTCBKey(CKeyTCBQuat &keyBefore, CKeyTCBQuat &key, CKeyTCBQuat &keyAfter, float timeBefore, float time, float timeAfter,
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float rangeDelta, bool firstKey, bool endKey, bool isLoop)
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{
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CQuat qp, qm;
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// compute qm.
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if (!firstKey || isLoop)
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{
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float angle= key.LocalAngleAxis.Angle;
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CVector &axis= key.LocalAngleAxis.Axis;
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if (angle > 2*NLMISC::Pi- NLMISC::QuatEpsilon)
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{
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qm.set(axis.x, axis.y, axis.z, 0.0f);
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qm = qm.log();
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}
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else
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{
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CQuat qprev= keyBefore.Quat;
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qprev.makeClosest(key.Quat);
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qm = CQuat::lnDif(qprev, key.Quat);
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}
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}
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// compute qp.
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if (!endKey || isLoop)
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{
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float angle= keyAfter.LocalAngleAxis.Angle;
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CVector &axis= keyAfter.LocalAngleAxis.Axis;
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if (angle > 2*NLMISC::Pi- NLMISC::QuatEpsilon)
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|
{
|
|
qp.set(axis.x, axis.y, axis.z, 0.0f);
|
|
qp = qp.log();
|
|
}
|
|
else
|
|
{
|
|
CQuat qnext= keyAfter.Quat;
|
|
qnext.makeClosest(key.Quat);
|
|
qp = CQuat::lnDif(key.Quat, qnext);
|
|
}
|
|
}
|
|
|
|
// not loop mgt.
|
|
if (firstKey && !isLoop)
|
|
qm = qp;
|
|
if (endKey && !isLoop)
|
|
qp = qm;
|
|
|
|
|
|
// compute tangents factors.
|
|
float ksm, ksp, kdm, kdp;
|
|
computeTCBFactors(key, timeBefore, time, timeAfter, rangeDelta, firstKey, endKey, isLoop, ksm,ksp,kdm,kdp);
|
|
|
|
|
|
// A/B.
|
|
CQuat qa, qb;
|
|
qb= (qm * (1.0f-ksm) + qp * (-ksp) ) * 0.5f;
|
|
qa= (qm * kdm + qp * (kdp-1.0f) ) * 0.5f;
|
|
qa = qa.exp();
|
|
qb = qb.exp();
|
|
|
|
key.A = key.Quat * qa;
|
|
key.B = key.Quat * qb;
|
|
}
|
|
|
|
|
|
|
|
};
|
|
|
|
|