@ -10525,17 +10525,76 @@ void plDXPipeline::LoadResources()
plNetClientApp : : StaticDebugMsg ( " End Device Reload " ) ;
plNetClientApp : : StaticDebugMsg ( " End Device Reload " ) ;
}
}
// Sorry about this, but it really did speed up the skinning.
// inlTESTPOINT /////////////////////////////////////////
// Just some macros for the inner loop of IBlendVertsIntoBuffer.
// Update mins and maxs if destP is outside.
inline void inlTESTPOINT ( const hsPoint3 & destP ,
float & minX , float & minY , float & minZ ,
float & maxX , float & maxY , float & maxZ )
{
if ( destP . fX < minX )
minX = destP . fX ;
else if ( destP . fX > maxX )
maxX = destP . fX ;
if ( destP . fY < minY )
minY = destP . fY ;
else if ( destP . fY > maxY )
maxY = destP . fY ;
if ( destP . fZ < minZ )
minZ = destP . fZ ;
else if ( destP . fZ > maxZ )
maxZ = destP . fZ ;
}
//// IBlendVertsIntoBuffer ////////////////////////////////////////////////////
// Given a pointer into a buffer of verts that have blending data in the D3D
// format, blends them into the destination buffer given without the blending
// info.
// FPU version
# define MATRIXMULTBEGIN_FPU(xfm, wgt) \
float m00 = xfm . fMap [ 0 ] [ 0 ] ; \
float m01 = xfm . fMap [ 0 ] [ 1 ] ; \
float m02 = xfm . fMap [ 0 ] [ 2 ] ; \
float m03 = xfm . fMap [ 0 ] [ 3 ] ; \
float m10 = xfm . fMap [ 1 ] [ 0 ] ; \
float m11 = xfm . fMap [ 1 ] [ 1 ] ; \
float m12 = xfm . fMap [ 1 ] [ 2 ] ; \
float m13 = xfm . fMap [ 1 ] [ 3 ] ; \
float m20 = xfm . fMap [ 2 ] [ 0 ] ; \
float m21 = xfm . fMap [ 2 ] [ 1 ] ; \
float m22 = xfm . fMap [ 2 ] [ 2 ] ; \
float m23 = xfm . fMap [ 2 ] [ 3 ] ; \
float m_wgt = wgt ; \
float srcX , srcY , srcZ ;
# define MATRIXMULTPOINTADD_FPU(dst, src) \
srcX = src . fX ; \
srcY = src . fY ; \
srcZ = src . fZ ; \
\
dst . fX + = ( srcX * m00 + srcY * m01 + srcZ * m02 + m03 ) * m_wgt ; \
dst . fY + = ( srcX * m10 + srcY * m11 + srcZ * m12 + m13 ) * m_wgt ; \
dst . fZ + = ( srcX * m20 + srcY * m21 + srcZ * m22 + m23 ) * m_wgt ;
# define MATRIXMULTVECTORADD_FPU(dst, src) \
srcX = src . fX ; \
srcY = src . fY ; \
srcZ = src . fZ ; \
\
dst . fX + = ( srcX * m00 + srcY * m01 + srcZ * m02 ) * m_wgt ; \
dst . fY + = ( srcX * m10 + srcY * m11 + srcZ * m12 ) * m_wgt ; \
dst . fZ + = ( srcX * m20 + srcY * m21 + srcZ * m22 ) * m_wgt ;
// SSE3 version
# ifdef HS_SSE3
# ifdef HS_SSE3
# define MATRIXMULTBEGIN(xfm, wgt) \
# define MATRIXMULTBEGIN_SSE3 (xfm, wgt) \
__m128 mc0 , mc1 , mc2 , mwt , msr , _x , _y , _z , hbuf1 , hbuf2 ; \
__m128 mc0 , mc1 , mc2 , mwt , msr , _x , _y , _z , hbuf1 , hbuf2 ; \
ALIGN ( 16 ) float hack [ 4 ] ; \
ALIGN ( 16 ) float hack [ 4 ] ; \
mc0 = _mm_loadu_ps ( xfm . fMap [ 0 ] ) ; \
mc0 = _mm_loadu_ps ( xfm . fMap [ 0 ] ) ; \
mc1 = _mm_loadu_ps ( xfm . fMap [ 1 ] ) ; \
mc1 = _mm_loadu_ps ( xfm . fMap [ 1 ] ) ; \
mc2 = _mm_loadu_ps ( xfm . fMap [ 2 ] ) ; \
mc2 = _mm_loadu_ps ( xfm . fMap [ 2 ] ) ; \
mwt = _mm_set_ps1 ( wgt ) ;
mwt = _mm_set_ps1 ( wgt ) ;
# define MATRIXMULTPOINTADD(dst, src) \
# define MATRIXMULTPOINTADD_SSE3 (dst, src) \
msr = _mm_set_ps ( 1.f , src . fZ , src . fY , src . fX ) ; \
msr = _mm_set_ps ( 1.f , src . fZ , src . fY , src . fX ) ; \
_x = _mm_mul_ps ( _mm_mul_ps ( mc0 , msr ) , mwt ) ; \
_x = _mm_mul_ps ( _mm_mul_ps ( mc0 , msr ) , mwt ) ; \
_y = _mm_mul_ps ( _mm_mul_ps ( mc1 , msr ) , mwt ) ; \
_y = _mm_mul_ps ( _mm_mul_ps ( mc1 , msr ) , mwt ) ; \
@ -10548,7 +10607,7 @@ void plDXPipeline::LoadResources()
dst . fX + = hack [ 0 ] ; \
dst . fX + = hack [ 0 ] ; \
dst . fY + = hack [ 1 ] ; \
dst . fY + = hack [ 1 ] ; \
dst . fZ + = hack [ 2 ] ;
dst . fZ + = hack [ 2 ] ;
# define MATRIXMULTVECTORADD(dst, src) \
# define MATRIXMULTVECTORADD_SSE3 (dst, src) \
msr = _mm_set_ps ( 0.f , src . fZ , src . fY , src . fX ) ; \
msr = _mm_set_ps ( 0.f , src . fZ , src . fY , src . fX ) ; \
_x = _mm_mul_ps ( _mm_mul_ps ( mc0 , msr ) , mwt ) ; \
_x = _mm_mul_ps ( _mm_mul_ps ( mc0 , msr ) , mwt ) ; \
_y = _mm_mul_ps ( _mm_mul_ps ( mc1 , msr ) , mwt ) ; \
_y = _mm_mul_ps ( _mm_mul_ps ( mc1 , msr ) , mwt ) ; \
@ -10561,250 +10620,214 @@ void plDXPipeline::LoadResources()
dst . fX + = hack [ 0 ] ; \
dst . fX + = hack [ 0 ] ; \
dst . fY + = hack [ 1 ] ; \
dst . fY + = hack [ 1 ] ; \
dst . fZ + = hack [ 2 ] ;
dst . fZ + = hack [ 2 ] ;
# else
# endif
# define MATRIXMULTBEGIN(xfm, wgt) \
float m00 = xfm . fMap [ 0 ] [ 0 ] ; \
float m01 = xfm . fMap [ 0 ] [ 1 ] ; \
float m02 = xfm . fMap [ 0 ] [ 2 ] ; \
float m03 = xfm . fMap [ 0 ] [ 3 ] ; \
float m10 = xfm . fMap [ 1 ] [ 0 ] ; \
float m11 = xfm . fMap [ 1 ] [ 1 ] ; \
float m12 = xfm . fMap [ 1 ] [ 2 ] ; \
float m13 = xfm . fMap [ 1 ] [ 3 ] ; \
float m20 = xfm . fMap [ 2 ] [ 0 ] ; \
float m21 = xfm . fMap [ 2 ] [ 1 ] ; \
float m22 = xfm . fMap [ 2 ] [ 2 ] ; \
float m23 = xfm . fMap [ 2 ] [ 3 ] ; \
float m_wgt = wgt ; \
float srcX , srcY , srcZ ;
# define MATRIXMULTPOINTADD(dst, src) \
srcX = src . fX ; \
srcY = src . fY ; \
srcZ = src . fZ ; \
\
dst . fX + = ( srcX * m00 + srcY * m01 + srcZ * m02 + m03 ) * m_wgt ; \
dst . fY + = ( srcX * m10 + srcY * m11 + srcZ * m12 + m13 ) * m_wgt ; \
dst . fZ + = ( srcX * m20 + srcY * m21 + srcZ * m22 + m23 ) * m_wgt ;
# define MATRIXMULTVECTORADD(dst, src) \
srcX = src . fX ; \
srcY = src . fY ; \
srcZ = src . fZ ; \
\
dst . fX + = ( srcX * m00 + srcY * m01 + srcZ * m02 ) * m_wgt ; \
dst . fY + = ( srcX * m10 + srcY * m11 + srcZ * m12 ) * m_wgt ; \
dst . fZ + = ( srcX * m20 + srcY * m21 + srcZ * m22 ) * m_wgt ;
# endif // HAVE_SSE
// inlTESTPOINT /////////////////////////////////////////
// Update mins and maxs if destP is outside.
inline void inlTESTPOINT ( const hsPoint3 & destP ,
float & minX , float & minY , float & minZ ,
float & maxX , float & maxY , float & maxZ )
{
if ( destP . fX < minX )
minX = destP . fX ;
else if ( destP . fX > maxX )
maxX = destP . fX ;
if ( destP . fY < minY )
minY = destP . fY ;
else if ( destP . fY > maxY )
maxY = destP . fY ;
if ( destP . fZ < minZ )
minZ = destP . fZ ;
else if ( destP . fZ > maxZ )
maxZ = destP . fZ ;
}
//// IBlendVertsIntoBuffer ////////////////////////////////////////////////////
// Given a pointer into a buffer of verts that have blending data in the D3D
// format, blends them into the destination buffer given without the blending
// info.
void plDXPipeline : : IBlendVertsIntoBuffer ( plSpan * span ,
hsMatrix44 * matrixPalette , int numMatrices ,
const uint8_t * src , uint8_t format , uint32_t srcStride ,
uint8_t * dest , uint32_t destStride , uint32_t count ,
uint16_t localUVWChans )
{
uint8_t numUVs , numWeights ;
uint32_t i , j , indices , color , specColor , uvChanSize ;
float weights [ 4 ] , weightSum ;
hsPoint3 pt , tempPt , destPt ;
hsVector3 vec , tempNorm , destNorm ;
/// Get some counts
switch ( format & plGBufferGroup : : kSkinWeightMask )
{
case plGBufferGroup : : kSkin1Weight : numWeights = 1 ; break ;
case plGBufferGroup : : kSkin2Weights : numWeights = 2 ; break ;
case plGBufferGroup : : kSkin3Weights : numWeights = 3 ; break ;
default : hsAssert ( false , " Invalid weight count in IBlendVertsIntoBuffer() " ) ;
}
numUVs = plGBufferGroup : : CalcNumUVs ( format ) ;
uvChanSize = numUVs * sizeof ( float ) * 3 ;
//#define MF_RECALC_BOUNDS
# ifdef MF_RECALC_BOUNDS
float minX = 1.e33 f ;
float minY = 1.e33 f ;
float minZ = 1.e33 f ;
float maxX = - 1.e33 f ;
// CPU-optimized functions requiring dispatch
float maxY = - 1.e33 f ;
hsFunctionDispatcher < plDXPipeline : : blend_vert_buffer_ptr > plDXPipeline : : blend_vert_buffer ( plDXPipeline : : blend_vert_buffer_fpu , 0 , 0 , plDXPipeline : : blend_vert_buffer_sse3 ) ;
float maxZ = - 1.e33 f ;
# endif // MF_RECALC_BOUNDS
// localUVWChans is bump mapping tangent space vectors, which need to
// Temporary macros for IBlendVertsIntoBuffer dispatch code de-duplication
# define BLENDVERTSTART \
uint8_t numUVs , numWeights ; \
uint32_t i , j , indices , color , specColor , uvChanSize ; \
float weights [ 4 ] , weightSum ; \
hsPoint3 pt , tempPt , destPt ; \
hsVector3 vec , tempNorm , destNorm ; \
\
/* Get some counts */ \
switch ( format & plGBufferGroup : : kSkinWeightMask ) \
{ \
case plGBufferGroup : : kSkin1Weight : numWeights = 1 ; break ; \
case plGBufferGroup : : kSkin2Weights : numWeights = 2 ; break ; \
case plGBufferGroup : : kSkin3Weights : numWeights = 3 ; break ; \
default : hsAssert ( false , " Invalid weight count in IBlendVertsIntoBuffer() " ) ; \
} \
\
numUVs = plGBufferGroup : : CalcNumUVs ( format ) ; \
uvChanSize = numUVs * sizeof ( float ) * 3 ; \
\
/* localUVWChans is bump mapping tangent space vectors, which need to
// be skinned like the normal, as opposed to passed through like
// be skinned like the normal, as opposed to passed through like
// garden variety UVW coordinates.
// garden variety UVW coordinates.
// There are no localUVWChans that I know of in production assets (i.e.
// There are no localUVWChans that I know of in production assets (i.e.
// the avatar is not skinned).
/ / the avatar is not skinned ) . */ \
if ( ! localUVWChans )
if ( ! localUVWChans ) \
{
{ \
/// Copy whilst blending
/* Copy whilst blending */ \
for ( i = 0 ; i < count ; i + + )
for ( i = 0 ; i < count ; i + + ) \
{
{ \
// Extract data
/* Extract data */ \
src = inlExtractPoint ( src , pt ) ;
src = inlExtractPoint ( src , pt ) ; \
for ( j = 0 , weightSum = 0 ; j < numWeights ; j + + )
for ( j = 0 , weightSum = 0 ; j < numWeights ; j + + ) \
{
{ \
src = inlExtractFloat ( src , weights [ j ] ) ;
src = inlExtractFloat ( src , weights [ j ] ) ; \
weightSum + = weights [ j ] ;
weightSum + = weights [ j ] ; \
}
} \
weights [ j ] = 1 - weightSum ;
weights [ j ] = 1 - weightSum ; \
\
if ( format & plGBufferGroup : : kSkinIndices )
if ( format & plGBufferGroup : : kSkinIndices ) \
{
{ \
src = inlExtractUInt32 ( src , indices ) ;
src = inlExtractUInt32 ( src , indices ) ; \
}
} \
else
else \
{
{ \
indices = 1 < < 8 ;
indices = 1 < < 8 ; \
}
} \
src = inlExtractPoint ( src , vec ) ;
src = inlExtractPoint ( src , vec ) ; \
src = inlExtractUInt32 ( src , color ) ;
src = inlExtractUInt32 ( src , color ) ; \
src = inlExtractUInt32 ( src , specColor ) ;
src = inlExtractUInt32 ( src , specColor ) ; \
\
// Blend
/* Blend */ \
destPt . Set ( 0 , 0 , 0 ) ;
destPt . Set ( 0 , 0 , 0 ) ; \
destNorm . Set ( 0 , 0 , 0 ) ;
destNorm . Set ( 0 , 0 , 0 ) ; \
for ( j = 0 ; j < numWeights + 1 ; j + + )
for ( j = 0 ; j < numWeights + 1 ; j + + ) \
{
{ \
if ( weights [ j ] )
if ( weights [ j ] ) \
{
{
/*
MATRIXMULTBEGIN ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
MATRIXMULTBEGIN ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
MATRIXMULTPOINTADD ( destPt , pt ) ;
MATRIXMULTPOINTADD ( destPt , pt ) ;
MATRIXMULTVECTORADD ( destNorm , vec ) ;
MATRIXMULTVECTORADD ( destNorm , vec ) ;
}
*/
# define BLENDVERTMID \
indices > > = 8 ;
} \
}
\
// Probably don't really need to renormalize this. There errors are
indices > > = 8 ; \
// going to be subtle and "smooth".
} \
// hsFastMath::NormalizeAppr(destNorm);
/* Probably don't really need to renormalize this. There errors are
/ / going to be subtle and " smooth " . */ \
# ifdef MF_RECALC_BOUNDS
/* hsFastMath::NormalizeAppr(destNorm);*/ \
inlTESTPOINT ( destPt , minX , minY , minZ , maxX , maxY , maxZ ) ;
\
# endif // MF_RECALC_BOUNDS
/* Slam data into position now */ \
dest = inlStuffPoint ( dest , destPt ) ; \
// Slam data into position now
dest = inlStuffPoint ( dest , destNorm ) ; \
dest = inlStuffPoint ( dest , destPt ) ;
dest = inlStuffUInt32 ( dest , color ) ; \
dest = inlStuffPoint ( dest , destNorm ) ;
dest = inlStuffUInt32 ( dest , specColor ) ; \
dest = inlStuffUInt32 ( dest , color ) ;
memcpy ( dest , src , uvChanSize ) ; \
dest = inlStuffUInt32 ( dest , specColor ) ;
src + = uvChanSize ; \
memcpy ( dest , src , uvChanSize ) ;
dest + = uvChanSize ; \
src + = uvChanSize ;
} \
dest + = uvChanSize ;
} \
}
else \
}
{ \
else
uint8_t hiChan = localUVWChans > > 8 ; \
{
uint8_t loChan = localUVWChans & 0xff ; \
uint8_t hiChan = localUVWChans > > 8 ;
/* Copy whilst blending */ \
uint8_t loChan = localUVWChans & 0xff ;
for ( i = 0 ; i < count ; i + + ) \
/// Copy whilst blending
{ \
for ( i = 0 ; i < count ; i + + )
hsVector3 srcUVWs [ plGeometrySpan : : kMaxNumUVChannels ] ; \
{
hsVector3 dstUVWs [ plGeometrySpan : : kMaxNumUVChannels ] ; \
hsVector3 srcUVWs [ plGeometrySpan : : kMaxNumUVChannels ] ;
\
hsVector3 dstUVWs [ plGeometrySpan : : kMaxNumUVChannels ] ;
/* Extract data */ \
src = inlExtractPoint ( src , pt ) ; \
// Extract data
for ( j = 0 , weightSum = 0 ; j < numWeights ; j + + ) \
src = inlExtractPoint ( src , pt ) ;
{ \
for ( j = 0 , weightSum = 0 ; j < numWeights ; j + + )
src = inlExtractFloat ( src , weights [ j ] ) ; \
{
weightSum + = weights [ j ] ; \
src = inlExtractFloat ( src , weights [ j ] ) ;
} \
weightSum + = weights [ j ] ;
weights [ j ] = 1 - weightSum ; \
}
\
weights [ j ] = 1 - weightSum ;
if ( format & plGBufferGroup : : kSkinIndices ) \
{ \
if ( format & plGBufferGroup : : kSkinIndices )
src = inlExtractUInt32 ( src , indices ) ; \
{
} \
src = inlExtractUInt32 ( src , indices ) ;
else \
}
{ \
else
indices = 1 < < 8 ; \
{
} \
indices = 1 < < 8 ;
\
}
src = inlExtractPoint ( src , vec ) ; \
src = inlExtractUInt32 ( src , color ) ; \
src = inlExtractPoint ( src , vec ) ;
src = inlExtractUInt32 ( src , specColor ) ; \
src = inlExtractUInt32 ( src , color ) ;
\
src = inlExtractUInt32 ( src , specColor ) ;
uint8_t k ; \
for ( k = 0 ; k < numUVs ; k + + ) \
uint8_t k ;
{ \
for ( k = 0 ; k < numUVs ; k + + )
src = inlExtractPoint ( src , srcUVWs [ k ] ) ; \
{
} \
src = inlExtractPoint ( src , srcUVWs [ k ] ) ;
memcpy ( dstUVWs , srcUVWs , uvChanSize ) ; \
}
dstUVWs [ loChan ] . Set ( 0 , 0 , 0 ) ; \
memcpy ( dstUVWs , srcUVWs , uvChanSize ) ;
dstUVWs [ hiChan ] . Set ( 0 , 0 , 0 ) ; \
dstUVWs [ loChan ] . Set ( 0 , 0 , 0 ) ;
\
dstUVWs [ hiChan ] . Set ( 0 , 0 , 0 ) ;
/* Blend */ \
destPt . Set ( 0 , 0 , 0 ) ; \
// Blend
destNorm . Set ( 0 , 0 , 0 ) ; \
destPt . Set ( 0 , 0 , 0 ) ;
for ( j = 0 ; j < numWeights + 1 ; j + + ) \
destNorm . Set ( 0 , 0 , 0 ) ;
{ \
for ( j = 0 ; j < numWeights + 1 ; j + + )
if ( weights [ j ] ) \
{
{ \
if ( weights [ j ] )
/*
{
MATRIXMULTBEGIN ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
MATRIXMULTBEGIN ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
MATRIXMULTPOINTADD ( destPt , pt ) ;
MATRIXMULTPOINTADD ( destPt , pt ) ;
MATRIXMULTVECTORADD ( destNorm , vec ) ;
MATRIXMULTVECTORADD ( destNorm , vec ) ;
MATRIXMULTVECTORADD ( dstUVWs [ loChan ] , srcUVWs [ loChan ] ) ;
MATRIXMULTVECTORADD ( dstUVWs [ loChan ] , srcUVWs [ loChan ] ) ;
MATRIXMULTVECTORADD ( dstUVWs [ hiChan ] , srcUVWs [ hiChan ] ) ;
MATRIXMULTVECTORADD ( dstUVWs [ hiChan ] , srcUVWs [ hiChan ] ) ;
*/
# define BLENDVERTEND \
} \
\
indices > > = 8 ; \
} \
/* Probably don't really need to renormalize this. There errors are
/ / going to be subtle and " smooth " . */ \
/* hsFastMath::NormalizeAppr(destNorm); */ \
/* hsFastMath::NormalizeAppr(dstUVWs[loChan]); */ \
/* hsFastMath::NormalizeAppr(dstUVWs[hiChan]); */ \
\
/* Slam data into position now */ \
dest = inlStuffPoint ( dest , destPt ) ; \
dest = inlStuffPoint ( dest , destNorm ) ; \
dest = inlStuffUInt32 ( dest , color ) ; \
dest = inlStuffUInt32 ( dest , specColor ) ; \
memcpy ( dest , dstUVWs , uvChanSize ) ; \
dest + = uvChanSize ; \
} \
}
}
indices > > = 8 ;
void plDXPipeline : : blend_vert_buffer_fpu ( plSpan * span ,
}
hsMatrix44 * matrixPalette , int numMatrices ,
// Probably don't really need to renormalize this. There errors are
const uint8_t * src , uint8_t format , uint32_t srcStride ,
// going to be subtle and "smooth".
uint8_t * dest , uint32_t destStride , uint32_t count ,
// hsFastMath::NormalizeAppr(destNorm);
uint16_t localUVWChans )
// hsFastMath::NormalizeAppr(dstUVWs[loChan]);
{
// hsFastMath::NormalizeAppr(dstUVWs[hiChan]);
BLENDVERTSTART
MATRIXMULTBEGIN_FPU ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
# ifdef MF_RECALC_BOUNDS
MATRIXMULTPOINTADD_FPU ( destPt , pt ) ;
inlTESTPOINT ( destPt , minX , minY , minZ , maxX , maxY , maxZ ) ;
MATRIXMULTVECTORADD_FPU ( destNorm , vec ) ;
# endif // MF_RECALC_BOUNDS
BLENDVERTMID
MATRIXMULTBEGIN_FPU ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
// Slam data into position now
MATRIXMULTPOINTADD_FPU ( destPt , pt ) ;
dest = inlStuffPoint ( dest , destPt ) ;
MATRIXMULTVECTORADD_FPU ( destNorm , vec ) ;
dest = inlStuffPoint ( dest , destNorm ) ;
MATRIXMULTVECTORADD_FPU ( dstUVWs [ loChan ] , srcUVWs [ loChan ] ) ;
dest = inlStuffUInt32 ( dest , color ) ;
MATRIXMULTVECTORADD_FPU ( dstUVWs [ hiChan ] , srcUVWs [ hiChan ] ) ;
dest = inlStuffUInt32 ( dest , specColor ) ;
memcpy ( dest , dstUVWs , uvChanSize ) ;
BLENDVERTEND
dest + = uvChanSize ;
}
}
}
# ifdef MF_RECALC_BOUNDS
hsBounds3Ext wBnd ;
void plDXPipeline : : blend_vert_buffer_sse3 ( plSpan * span ,
wBnd . Reset ( & hsPoint3 ( minX , minY , minZ ) ) ;
hsMatrix44 * matrixPalette , int numMatrices ,
wBnd . Union ( & hsPoint3 ( maxX , maxY , maxZ ) ) ;
const uint8_t * src , uint8_t format , uint32_t srcStride ,
span - > fWorldBounds = wBnd ;
uint8_t * dest , uint32_t destStride , uint32_t count ,
# endif // MF_RECALC_BOUNDS
uint16_t localUVWChans )
{
# ifdef HS_SSE3
BLENDVERTSTART
MATRIXMULTBEGIN_SSE3 ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
MATRIXMULTPOINTADD_SSE3 ( destPt , pt ) ;
MATRIXMULTVECTORADD_SSE3 ( destNorm , vec ) ;
BLENDVERTMID
MATRIXMULTBEGIN_SSE3 ( matrixPalette [ indices & 0xff ] , weights [ j ] ) ;
MATRIXMULTPOINTADD_SSE3 ( destPt , pt ) ;
MATRIXMULTVECTORADD_SSE3 ( destNorm , vec ) ;
MATRIXMULTVECTORADD_SSE3 ( dstUVWs [ loChan ] , srcUVWs [ loChan ] ) ;
MATRIXMULTVECTORADD_SSE3 ( dstUVWs [ hiChan ] , srcUVWs [ hiChan ] ) ;
BLENDVERTEND
# endif // HS_SSE3
}
}
// ISetPipeConsts //////////////////////////////////////////////////////////////////
// ISetPipeConsts //////////////////////////////////////////////////////////////////