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/*==LICENSE==*
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CyanWorlds.com Engine - MMOG client, server and tools
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Copyright (C) 2011 Cyan Worlds, Inc.
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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 General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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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 General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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Additional permissions under GNU GPL version 3 section 7
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If you modify this Program, or any covered work, by linking or
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combining it with any of RAD Game Tools Bink SDK, Autodesk 3ds Max SDK,
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NVIDIA PhysX SDK, Microsoft DirectX SDK, OpenSSL library, Independent
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JPEG Group JPEG library, Microsoft Windows Media SDK, or Apple QuickTime SDK
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(or a modified version of those libraries),
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containing parts covered by the terms of the Bink SDK EULA, 3ds Max EULA,
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PhysX SDK EULA, DirectX SDK EULA, OpenSSL and SSLeay licenses, IJG
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JPEG Library README, Windows Media SDK EULA, or QuickTime SDK EULA, the
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licensors of this Program grant you additional
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permission to convey the resulting work. Corresponding Source for a
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non-source form of such a combination shall include the source code for
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the parts of OpenSSL and IJG JPEG Library used as well as that of the covered
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work.
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You can contact Cyan Worlds, Inc. by email legal@cyan.com
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or by snail mail at:
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Cyan Worlds, Inc.
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14617 N Newport Hwy
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Mead, WA 99021
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*==LICENSE==*/
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#include "hsTypes.h"
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#include "plMorphDelta.h"
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#include "hsStream.h"
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#include "hsMemory.h"
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#include "plAccessGeometry.h"
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#include "plAccessSpan.h"
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#include "plAccessVtxSpan.h"
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#include "plGeometrySpan.h"
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#include "plTweak.h"
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static const hsScalar kMinWeight = 1.e-2f;
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plMorphSpan::plMorphSpan()
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: fUVWs(nil),
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fNumUVWChans(0)
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{
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}
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plMorphSpan::~plMorphSpan()
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{
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delete [] fUVWs;
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}
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plMorphDelta::plMorphDelta()
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: fWeight(0)
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{
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}
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plMorphDelta::~plMorphDelta()
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{
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}
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plMorphDelta::plMorphDelta(const plMorphDelta& src)
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{
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*this = src;
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}
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plMorphDelta& plMorphDelta::operator=(const plMorphDelta& src)
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{
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SetNumSpans(src.GetNumSpans());
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int i;
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for( i = 0; i < fSpans.GetCount(); i++ )
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{
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SetDeltas(i, src.fSpans[i].fDeltas, src.fSpans[i].fNumUVWChans, src.fSpans[i].fUVWs);
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}
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return *this;
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}
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void plMorphDelta::Apply(hsTArray<plAccessSpan>& dst, hsScalar weight /* = -1.f */) const
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{
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if( weight == -1.f)
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weight = fWeight; // None passed in, use our stored value
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if( weight <= kMinWeight )
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return;
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// Easy
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// For each span
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int iSpan;
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for( iSpan = 0; iSpan < fSpans.GetCount(); iSpan++ )
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{
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plAccessVtxSpan& vtxDst = dst[iSpan].AccessVtx();
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plMorphSpan& span = fSpans[iSpan];
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// For each vertDelta
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const hsPoint3* uvwDel = span.fUVWs;
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int iDelta;
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for( iDelta = 0; iDelta < span.fDeltas.GetCount(); iDelta++ )
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{
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const plVertDelta& delta = span.fDeltas[iDelta];
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// Add delPos * wgt to position
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// Add delNorm * wgt to normal
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vtxDst.Position(delta.fIdx) += delta.fPos * weight;
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vtxDst.Normal(delta.fIdx) += delta.fNorm * weight;
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// Leave skin weights and indices alone?
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// Skip color for now, since diffuse and specular are
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// ignored on the avatar?
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// // Add delDiff * wgt to diffuse
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// // Add delSpec * wgt to specular
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// For each UVW
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hsPoint3* uvws = vtxDst.UVWs(delta.fIdx);
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int iUVW;
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for( iUVW = 0; iUVW < span.fNumUVWChans; iUVW++ )
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{
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// Add delUVW * wgt to uvw
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*uvws += *uvwDel * weight;
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uvws++;
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uvwDel++;
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}
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}
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}
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}
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// MorphDelta - ComputeDeltas
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void plMorphDelta::ComputeDeltas(const hsTArray<plAccessSpan>& base, const hsTArray<plAccessSpan>& moved)
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{
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SetNumSpans(base.GetCount());
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// For each span
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{
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// for( i = 0; i < numVerts; i++ )
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{
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// NOTE: we want to discard zero deltas, but a
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// delta in any channel forces us to save the whole thing.
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// But we don't want to compare to zero (because we'll end
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// up with a lot of near zero deltas), but the epsilon we
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// compare to needs to be different for comparing something
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// like a normal delta and a position delta.
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//
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// For position, normal, color and all uvws
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// Calc del and delLenSq
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// If any delLenSq big enough, set nonZero to true
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// If nonZero
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{
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// Append to deltas (i, del's)
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}
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}
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}
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}
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// MorphDelta - ComputeDeltas
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void plMorphDelta::ComputeDeltas(const hsTArray<plGeometrySpan*>& base, const hsTArray<plGeometrySpan*>& moved, const hsMatrix44& d2b, const hsMatrix44& d2bTInv)
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{
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SetNumSpans(base.GetCount());
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hsPoint3 delUVWs[8];
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// For each span
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int iSpan;
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for( iSpan = 0; iSpan < base.GetCount(); iSpan++ )
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{
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plAccessSpan baseAcc;
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plAccessGeometry::Instance()->AccessSpanFromGeometrySpan(baseAcc, base[iSpan]);
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plAccessSpan movedAcc;
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plAccessGeometry::Instance()->AccessSpanFromGeometrySpan(movedAcc, moved[iSpan]);
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plAccPosNormUVWIterator baseIter(&baseAcc.AccessVtx());
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plAccPosNormUVWIterator movedIter(&movedAcc.AccessVtx());
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plMorphSpan& dst = fSpans[iSpan];
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const UInt16 numUVWs = baseAcc.AccessVtx().NumUVWs();
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hsTArray<plVertDelta> deltas;
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hsTArray<hsPoint3> uvws;
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deltas.SetCount(0);
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uvws.SetCount(0);
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int iVert = 0;;
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for( baseIter.Begin(), movedIter.Begin(); baseIter.More(); baseIter.Advance(), movedIter.Advance() )
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{
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// NOTE: we want to discard zero deltas, but a
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// delta in any channel forces us to save the whole thing.
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// But we don't want to compare to zero (because we'll end
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// up with a lot of near zero deltas), but the epsilon we
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// compare to needs to be different for comparing something
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// like a normal delta and a position delta.
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//
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// For position, normal, color and all uvws
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// Calc del and delLenSq
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// If any delLenSq big enough, set nonZero to true
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hsBool nonZero = false;
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// These are actually min del SQUARED.
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plConst(hsScalar) kMinDelPos(1.e-4f); // From Budtpueller's Handbook of Constants
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plConst(hsScalar) kMinDelNorm(3.e-2f); // About 10 degrees
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plConst(hsScalar) kMinDelUVW(1.e-4f); // From BHC
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hsPoint3 mPos = d2b * *movedIter.Position();
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hsVector3 delPos( &mPos, baseIter.Position());
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hsScalar delPosSq = delPos.MagnitudeSquared();
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if( delPosSq > kMinDelPos )
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nonZero = true;
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else
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delPos.Set(0,0,0);
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hsVector3 delNorm = (d2bTInv * *movedIter.Normal()) - *baseIter.Normal();
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hsScalar delNormSq = delNorm.MagnitudeSquared();
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if( delNormSq > kMinDelNorm )
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nonZero = true;
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else
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delNorm.Set(0,0,0);
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int i;
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for( i = 0; i < numUVWs; i++ )
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{
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delUVWs[i] = *movedIter.UVW(i) - *baseIter.UVW(i);
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hsScalar delUVWSq = delUVWs[i].MagnitudeSquared();
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if( delUVWSq > kMinDelUVW )
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nonZero = true;
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else
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delUVWs[i].Set(0,0,0);
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}
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if( nonZero )
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{
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// Append to deltas (i, del's)
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plVertDelta del;
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del.fIdx = iVert;
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del.fPos = delPos;
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del.fNorm = delNorm;
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deltas.Append(del);
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for( i = 0; i < numUVWs; i++ )
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uvws.Append(delUVWs[i]);
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}
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else
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{
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nonZero = false; // Breakpoint.
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}
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iVert++;
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}
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SetDeltas(iSpan, deltas, numUVWs, uvws.AcquireArray());
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}
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}
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void plMorphDelta::SetNumSpans(int n)
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{
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fSpans.Reset();
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fSpans.SetCount(n);
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}
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void plMorphDelta::AllocDeltas(int iSpan, int nDel, int nUVW)
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{
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fSpans[iSpan].fDeltas.SetCount(nDel);
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fSpans[iSpan].fNumUVWChans = nUVW;
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delete [] fSpans[iSpan].fUVWs;
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int uvwCnt = nDel * nUVW;
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if( uvwCnt )
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fSpans[iSpan].fUVWs = TRACKED_NEW hsPoint3[uvwCnt];
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else
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fSpans[iSpan].fUVWs = nil;
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}
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void plMorphDelta::SetDeltas(int iSpan, const hsTArray<plVertDelta>& deltas, int numUVWChans, const hsPoint3* uvws)
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{
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AllocDeltas(iSpan, deltas.GetCount(), numUVWChans);
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if( deltas.GetCount() )
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{
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HSMemory::BlockMove(&deltas[0], fSpans[iSpan].fDeltas.AcquireArray(), deltas.GetCount() * sizeof(plVertDelta));
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if( numUVWChans )
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HSMemory::BlockMove(uvws, fSpans[iSpan].fUVWs, deltas.GetCount() * numUVWChans * sizeof(*uvws));
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}
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}
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void plMorphDelta::Read(hsStream* s, hsResMgr* mgr)
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{
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fWeight = s->ReadLEScalar();
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int n = s->ReadLE32();
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SetNumSpans(n);
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int iSpan;
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for( iSpan = 0; iSpan < n; iSpan++ )
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{
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int nDel = s->ReadLE32();
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int nUVW = s->ReadLE32();
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AllocDeltas(iSpan, nDel, nUVW);
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if( nDel )
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{
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s->Read(nDel * sizeof(plVertDelta), fSpans[iSpan].fDeltas.AcquireArray());
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if( nUVW )
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s->Read(nDel * nUVW * sizeof(hsPoint3), fSpans[iSpan].fUVWs);
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}
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}
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}
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void plMorphDelta::Write(hsStream* s, hsResMgr* mgr)
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{
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s->WriteLEScalar(fWeight);
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s->WriteLE32(fSpans.GetCount());
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int iSpan;
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for( iSpan = 0; iSpan < fSpans.GetCount(); iSpan++ )
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{
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int nDel = fSpans[iSpan].fDeltas.GetCount();
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int nUVW = fSpans[iSpan].fNumUVWChans;
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s->WriteLE32(nDel);
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s->WriteLE32(nUVW);
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if( nDel )
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{
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// Initialize our padding here, so we don't write random data
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for (int i = 0; i < nDel; i++)
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{
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plVertDelta& delta = fSpans[iSpan].fDeltas[i];
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delta.fPadding = 0;
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}
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s->Write(nDel * sizeof(plVertDelta), fSpans[iSpan].fDeltas.AcquireArray());
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if( nUVW )
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s->Write(nDel * nUVW * sizeof(hsPoint3), fSpans[iSpan].fUVWs);
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}
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}
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}
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