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448 lines
11 KiB
448 lines
11 KiB
14 years ago
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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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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 "plVertCoder.h"
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#include "hsStream.h"
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#include "plGBufferGroup.h"
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const hsScalar kPosQuantum = 1.f / hsScalar(1 << 10);
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const hsScalar kWeightQuantum = 1.f / hsScalar(1 << 15);
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const hsScalar kUVWQuantum = 1.f / hsScalar(1 << 16);
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UInt32 plVertCoder::fCodedVerts = 0;
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UInt32 plVertCoder::fCodedBytes = 0;
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UInt32 plVertCoder::fRawBytes = 0;
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UInt32 plVertCoder::fSkippedBytes = 0;
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static const hsScalar kQuanta[plVertCoder::kNumFloatFields] =
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{
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kPosQuantum,
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kWeightQuantum,
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kUVWQuantum,
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kUVWQuantum,
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kUVWQuantum,
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kUVWQuantum,
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kUVWQuantum,
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kUVWQuantum,
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kUVWQuantum,
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kUVWQuantum,
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};
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inline void plVertCoder::ICountFloats(const UInt8* src, UInt16 maxCnt, const hsScalar quant, const UInt32 stride,
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hsScalar& lo, hsBool &allSame, UInt16& count)
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{
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lo = *(hsScalar*)src;
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lo = floor(lo / quant + 0.5f) * quant;
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allSame = false;
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hsScalar hi = lo;
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count = 1;
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const hsScalar maxRange = hsScalar(UInt16(0xffff)) * quant;
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src += stride;
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maxCnt--;
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while( maxCnt-- )
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{
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hsScalar val = *(hsScalar*)src;
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val = floor(val / quant + 0.5f) * quant;
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if( val < lo )
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{
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if( hi - val > maxRange )
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return;
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lo = val;
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}
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else if( val > hi )
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{
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if( val - lo > maxRange )
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return;
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hi = val;
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}
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count++;
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src += stride;
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}
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allSame = (lo == hi);
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}
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static inline void IWriteFloat(hsStream* s, const UInt8*& src, const hsScalar offset, const hsScalar quantum)
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{
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float fval = *(float*)src;
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fval -= offset;
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fval /= quantum;
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// hsAssert(fval < hsScalar(UInt16(0xffff)), "Bad offset?");
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const UInt16 ival = UInt16(floor(fval + 0.5f));
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s->WriteSwap16(ival);
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src += 4;
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}
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static inline void IReadFloat(hsStream* s, UInt8*& dst, const hsScalar offset, const hsScalar quantum)
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{
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const UInt16 ival = s->ReadSwap16();
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float fval = float(ival) * quantum;
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fval += offset;
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hsScalar* val = (hsScalar*)dst;
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*val = fval;
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dst += 4;
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}
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inline void plVertCoder::IEncodeFloat(hsStream* s, const UInt32 vertsLeft, const int field, const int chan, const UInt8*& src, const UInt32 stride)
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{
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if( !fFloats[field][chan].fCount )
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{
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ICountFloats(src, (UInt16)vertsLeft, kQuanta[field], stride, fFloats[field][chan].fOffset, fFloats[field][chan].fAllSame, fFloats[field][chan].fCount);
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s->WriteSwapScalar(fFloats[field][chan].fOffset);
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s->WriteBool(fFloats[field][chan].fAllSame);
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s->WriteSwap16(fFloats[field][chan].fCount);
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}
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if (!fFloats[field][chan].fAllSame)
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IWriteFloat(s, src, fFloats[field][chan].fOffset, kQuanta[field]);
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else
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src += 4;
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fFloats[field][chan].fCount--;
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}
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inline void plVertCoder::IDecodeFloat(hsStream* s, const int field, const int chan, UInt8*& dst, const UInt32 stride)
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{
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if( !fFloats[field][chan].fCount )
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{
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fFloats[field][chan].fOffset = s->ReadSwapScalar();
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fFloats[field][chan].fAllSame = s->ReadBool();
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fFloats[field][chan].fCount = s->ReadSwap16();
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}
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if (!fFloats[field][chan].fAllSame)
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IReadFloat(s, dst, fFloats[field][chan].fOffset, kQuanta[field]);
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else
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{
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*((hsScalar*)dst) = fFloats[field][chan].fOffset;
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dst += 4;
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}
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fFloats[field][chan].fCount--;
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}
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static inline int INumWeights(const UInt8 format)
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{
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return (format & plGBufferGroup::kSkinWeightMask) >> 4;
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}
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static const hsScalar kNormalScale(Int16(0x7fff));
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static const hsScalar kInvNormalScale(1.f / kNormalScale);
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inline void plVertCoder::IEncodeNormal(hsStream* s, const UInt8*& src, const UInt32 stride)
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{
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hsScalar x = *(hsScalar*)src;
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s->WriteByte((UInt8)((x / 2.f + .5f) * 255.9f));
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src += 4;
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x = *(hsScalar*)src;
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s->WriteByte((UInt8)((x / 2.f + .5f) * 255.9f));
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src += 4;
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x = *(hsScalar*)src;
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s->WriteByte((UInt8)((x / 2.f + .5f) * 255.9f));
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src += 4;
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}
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inline void plVertCoder::IDecodeNormal(hsStream* s, UInt8*& dst, const UInt32 stride)
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{
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UInt8 ix = s->ReadByte();
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hsScalar* x = (hsScalar*)dst;
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*x = (ix / 255.9f - .5f) * 2.f;
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dst += 4;
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ix = s->ReadByte();
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x = (hsScalar*)dst;
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*x = (ix / 255.9f - .5f) * 2.f;
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dst += 4;
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ix = s->ReadByte();
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x = (hsScalar*)dst;
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*x = (ix / 255.9f - .5f) * 2.f;
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dst += 4;
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}
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inline void plVertCoder::ICountBytes(const UInt32 vertsLeft, const UInt8* src, const UInt32 stride, UInt16& len, UInt8& same)
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{
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// We want to run length encode this. So we're looking here for either
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// the number of consecutive bytes of the same value,
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// or the number of consective bytes of different values.
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// The latter is so we don't wind up getting larger when there aren't any
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// runs of the same value (count=1 and val=c1, count=1 and val=c2, etc.).
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// The break-even point is a run of 3, so we'll look for a minimum run of 4.
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if( vertsLeft < 4 )
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{
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len = (UInt16)vertsLeft;
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same = false;
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return;
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}
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// First, count how many values are the same as the first one
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int i;
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for( i = 0; i < vertsLeft; i++ )
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{
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if( src[i * stride] != src[0] )
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break;
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}
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if( i >= 4 )
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{
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// Found a good run.
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len = i;
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same = true;
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return;
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}
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// Okay, we're in a section of varying values. How far to the next
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// section of sameness?
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same = false;
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for( ; i < vertsLeft-4; i++ )
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{
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if( (src[i*stride] == src[(i+1)*stride])
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&&(src[i*stride] == src[(i+2)*stride])
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&&(src[i*stride] == src[(i+3)*stride]) )
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break;
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}
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if( i < vertsLeft-4 )
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{
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len = i;
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return;
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}
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len = (UInt16)vertsLeft;
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return;
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}
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static const UInt16 kSameMask(0x8000);
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inline void plVertCoder::IEncodeByte(hsStream* s, const int chan, const UInt32 vertsLeft, const UInt8*& src, const UInt32 stride)
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{
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if( !fColors[chan].fCount )
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{
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ICountBytes(vertsLeft, src, stride, fColors[chan].fCount, fColors[chan].fSame);
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UInt16 cnt = fColors[chan].fCount;
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if( fColors[chan].fSame )
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cnt |= kSameMask;
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s->WriteSwap16(cnt);
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if( fColors[chan].fSame )
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s->WriteByte(*src);
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}
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if( !fColors[chan].fSame )
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s->WriteByte(*src);
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src++;
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fColors[chan].fCount--;
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}
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inline void plVertCoder::IDecodeByte(hsStream* s, const int chan, UInt8*& dst, const UInt32 stride)
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{
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if( !fColors[chan].fCount )
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{
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UInt16 cnt = s->ReadSwap16();
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if( cnt & kSameMask )
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{
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fColors[chan].fSame = true;
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fColors[chan].fVal = s->ReadByte();
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cnt &= ~kSameMask;
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}
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else
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{
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fColors[chan].fSame = false;
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}
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fColors[chan].fCount = cnt;
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}
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if( !fColors[chan].fSame )
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*dst = s->ReadByte();
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else
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*dst = fColors[chan].fVal;
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dst++;
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fColors[chan].fCount--;
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}
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inline void plVertCoder::IEncodeColor(hsStream* s, const UInt32 vertsLeft, const UInt8*& src, const UInt32 stride)
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{
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IEncodeByte(s, 0, vertsLeft, src, stride);
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IEncodeByte(s, 1, vertsLeft, src, stride);
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IEncodeByte(s, 2, vertsLeft, src, stride);
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IEncodeByte(s, 3, vertsLeft, src, stride);
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}
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inline void plVertCoder::IDecodeColor(hsStream* s, UInt8*& dst, const UInt32 stride)
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{
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IDecodeByte(s, 0, dst, stride);
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IDecodeByte(s, 1, dst, stride);
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IDecodeByte(s, 2, dst, stride);
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IDecodeByte(s, 3, dst, stride);
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}
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inline void plVertCoder::IEncode(hsStream* s, const UInt32 vertsLeft, const UInt8*& src, const UInt32 stride, const UInt8 format)
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{
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IEncodeFloat(s, vertsLeft, kPosition, 0, src, stride);
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IEncodeFloat(s, vertsLeft, kPosition, 1, src, stride);
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IEncodeFloat(s, vertsLeft, kPosition, 2, src, stride);
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// Weights and indices?
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const int numWeights = INumWeights(format);
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if( numWeights )
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{
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int j;
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for( j = 0; j < numWeights; j++ )
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IEncodeFloat(s, vertsLeft, kWeight, j, src, stride);
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if( format & plGBufferGroup::kSkinIndices )
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{
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const UInt32 idx = *(UInt32*)src;
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s->WriteSwap32(idx);
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src += 4;
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}
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}
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IEncodeNormal(s, src, stride);
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IEncodeColor(s, vertsLeft, src, stride);
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// COLOR2
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src += 4;
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const int numUVWs = format & plGBufferGroup::kUVCountMask;
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int i;
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for( i = 0; i < numUVWs; i++ )
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{
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IEncodeFloat(s, vertsLeft, kUVW + i, 0, src, stride);
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IEncodeFloat(s, vertsLeft, kUVW + i, 1, src, stride);
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IEncodeFloat(s, vertsLeft, kUVW + i, 2, src, stride);
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}
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}
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inline void plVertCoder::IDecode(hsStream* s, UInt8*& dst, const UInt32 stride, const UInt8 format)
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{
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IDecodeFloat(s, kPosition, 0, dst, stride);
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IDecodeFloat(s, kPosition, 1, dst, stride);
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IDecodeFloat(s, kPosition, 2, dst, stride);
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// Weights and indices?
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const int numWeights = INumWeights(format);
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if( numWeights )
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{
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int j;
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for( j = 0; j < numWeights; j++ )
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IDecodeFloat(s, kWeight, j, dst, stride);
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if( format & plGBufferGroup::kSkinIndices )
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{
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UInt32* idx = (UInt32*)dst;
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*idx = s->ReadSwap32();
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dst += 4;
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}
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}
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IDecodeNormal(s, dst, stride);
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IDecodeColor(s, dst, stride);
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// COLOR2
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UInt32* trash = (UInt32*)dst;
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*trash = 0;
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dst += 4;
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const int numUVWs = format & plGBufferGroup::kUVCountMask;
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int i;
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for( i = 0; i < numUVWs; i++ )
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{
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IDecodeFloat(s, kUVW + i, 0, dst, stride);
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IDecodeFloat(s, kUVW + i, 1, dst, stride);
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IDecodeFloat(s, kUVW + i, 2, dst, stride);
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}
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}
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void plVertCoder::Read(hsStream* s, UInt8* dst, const UInt8 format, const UInt32 stride, const UInt16 numVerts)
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{
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Clear();
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int i = numVerts;
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for( i = 0; i < numVerts; i++ )
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IDecode(s, dst, stride, format);
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}
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void plVertCoder::Write(hsStream* s, const UInt8* src, const UInt8 format, const UInt32 stride, const UInt16 numVerts)
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{
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Clear();
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UInt32 streamStart = s->GetPosition();
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int numLeft = numVerts;
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while( numLeft )
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{
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IEncode(s, numLeft, src, stride, format);
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numLeft--;
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}
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fCodedVerts += numVerts;
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fCodedBytes += (s->GetPosition() - streamStart);
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fRawBytes += numVerts * stride;
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}
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plVertCoder::plVertCoder()
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{
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Clear();
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}
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plVertCoder::~plVertCoder()
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{
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}
|
||
|
|
||
|
void plVertCoder::Clear()
|
||
|
{
|
||
|
memset(this, 0, sizeof(*this));
|
||
|
}
|
||
|
|