Serious-Engine/Sources/Engine/Graphics/Graphics.cpp

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2016-03-11 14:57:17 +01:00
/* Copyright (c) 2002-2012 Croteam Ltd. All rights reserved. */
#include "stdh.h"
#include <Engine/Base/Statistics_internal.h>
#include <Engine/Graphics/GfxLibrary.h>
#include <Engine/Graphics/RenderPoly.h>
#include <Engine/Graphics/Color.h>
#include <Engine/Graphics/Texture.h>
#include <Engine/Graphics/GfxProfile.h>
// asm shortcuts
#define O offset
#define Q qword ptr
#define D dword ptr
#define W word ptr
#define B byte ptr
extern INDEX tex_bProgressiveFilter; // filter mipmaps in creation time (not afterwards)
// returns number of mip-maps to skip from original texture
INDEX ClampTextureSize( PIX pixClampSize, PIX pixClampDimension, PIX pixSizeU, PIX pixSizeV)
{
__int64 pixMaxSize = (__int64)pixSizeU * (__int64)pixSizeV;
PIX pixMaxDimension = Max( pixSizeU, pixSizeV);
INDEX ctSkipMips = 0;
while( (pixMaxSize>pixClampSize || pixMaxDimension>pixClampDimension) && pixMaxDimension>1) {
ctSkipMips++;
pixMaxDimension >>=1;
pixMaxSize >>=2;
}
return ctSkipMips;
}
// retrives memory offset of a specified mip-map or a size of all mip-maps (IN PIXELS!)
// (zero offset means first, i.e. largest mip-map)
PIX GetMipmapOffset( INDEX iMipLevel, PIX pixWidth, PIX pixHeight)
{
PIX pixTexSize = 0;
PIX pixMipSize = pixWidth*pixHeight;
INDEX iMips = GetNoOfMipmaps( pixWidth, pixHeight);
iMips = Min( iMips, iMipLevel);
while( iMips>0) {
pixTexSize +=pixMipSize;
pixMipSize>>=2;
iMips--;
}
return pixTexSize;
}
// return offset, pointer and dimensions of mipmap of specified size inside texture or shadowmap mipmaps
INDEX GetMipmapOfSize( PIX pixWantedSize, ULONG *&pulFrame, PIX &pixWidth, PIX &pixHeight)
{
INDEX iMipOffset = 0;
while( pixWidth>1 && pixHeight>1) {
const PIX pixCurrentSize = pixWidth*pixHeight;
if( pixCurrentSize <= pixWantedSize) break; // found
pulFrame += pixCurrentSize;
pixWidth >>=1;
pixHeight>>=1;
iMipOffset++;
} // done
return iMipOffset;
}
// adds 8-bit opaque alpha channel to 24-bit bitmap (in place supported)
void AddAlphaChannel( UBYTE *pubSrcBitmap, ULONG *pulDstBitmap, PIX pixSize, UBYTE *pubAlphaBitmap)
{
UBYTE ubR,ubG,ubB, ubA=255;
// loop backwards thru all bitmap pixels
for( INDEX iPix=(pixSize-1); iPix>=0; iPix--) {
ubR = pubSrcBitmap[iPix*3 +0];
ubG = pubSrcBitmap[iPix*3 +1];
ubB = pubSrcBitmap[iPix*3 +2];
if( pubAlphaBitmap!=NULL) ubA = pubAlphaBitmap[iPix];
else ubA = 255; // for the sake of forced RGBA internal formats!
pulDstBitmap[iPix] = ByteSwap( RGBAToColor( ubR,ubG,ubB, ubA));
}
}
// removes 8-bit alpha channel from 32-bit bitmap (in place supported)
void RemoveAlphaChannel( ULONG *pulSrcBitmap, UBYTE *pubDstBitmap, PIX pixSize)
{
UBYTE ubR,ubG,ubB;
// loop thru all bitmap pixels
for( INDEX iPix=0; iPix<pixSize; iPix++) {
ColorToRGB( ByteSwap( pulSrcBitmap[iPix]), ubR,ubG,ubB);
pubDstBitmap[iPix*3 +0] = ubR;
pubDstBitmap[iPix*3 +1] = ubG;
pubDstBitmap[iPix*3 +2] = ubB;
}
}
// flips 24 or 32-bit bitmap (iType: 1-horizontal, 2-vertical, 3-diagonal) - in place supported
void FlipBitmap( UBYTE *pubSrc, UBYTE *pubDst, PIX pixWidth, PIX pixHeight, INDEX iFlipType, BOOL bAlphaChannel)
{
// safety
ASSERT( iFlipType>=0 && iFlipType<4);
// no flipping ?
PIX pixSize = pixWidth*pixHeight;
if( iFlipType==0) {
// copy bitmap only if needed
INDEX ctBPP = (bAlphaChannel ? 4 : 3);
if( pubSrc!=pubDst) memcpy( pubDst, pubSrc, pixSize*ctBPP);
return;
}
// prepare images without alpha channels
ULONG *pulNew = NULL;
ULONG *pulNewSrc = (ULONG*)pubSrc;
ULONG *pulNewDst = (ULONG*)pubDst;
if( !bAlphaChannel) {
pulNew = (ULONG*)AllocMemory( pixSize *BYTES_PER_TEXEL);
AddAlphaChannel( pubSrc, pulNew, pixSize);
pulNewSrc = pulNew;
pulNewDst = pulNew;
}
// prepare half-width and half-height rounded
const PIX pixHalfWidth = (pixWidth+1) /2;
const PIX pixHalfHeight = (pixHeight+1)/2;
// flip horizontal
if( iFlipType==2 || iFlipType==3)
{ // for each row
for( INDEX iRow=0; iRow<pixHeight; iRow++)
{ // find row pointer
PIX pixRowOffset = iRow*pixWidth;
// for each pixel in row
for( INDEX iPix=0; iPix<pixHalfWidth; iPix++)
{ // transfer pixels
PIX pixBeg = pulNewSrc[pixRowOffset+iPix];
PIX pixEnd = pulNewSrc[pixRowOffset+(pixWidth-1-iPix)];
pulNewDst[pixRowOffset+iPix] = pixEnd;
pulNewDst[pixRowOffset+(pixWidth-1-iPix)] = pixBeg;
}
}
}
// prepare new pointers
if( iFlipType==3) pulNewSrc = pulNewDst;
// flip vertical/diagonal
if( iFlipType==1 || iFlipType==3)
{ // for each row
for( INDEX iRow=0; iRow<pixHalfHeight; iRow++)
{ // find row pointers
PIX pixBegOffset = iRow*pixWidth;
PIX pixEndOffset = (pixHeight-1-iRow)*pixWidth;
// for each pixel in row
for( INDEX iPix=0; iPix<pixWidth; iPix++)
{ // transfer pixels
PIX pixBeg = pulNewSrc[pixBegOffset+iPix];
PIX pixEnd = pulNewSrc[pixEndOffset+iPix];
pulNewDst[pixBegOffset+iPix] = pixEnd;
pulNewDst[pixEndOffset+iPix] = pixBeg;
}
}
}
// postpare images without alpha channels
if( !bAlphaChannel) {
RemoveAlphaChannel( pulNewDst, pubDst, pixSize);
if( pulNew!=NULL) FreeMemory(pulNew);
}
}
// makes one level lower mipmap (bilinear or nearest-neighbour with border preservance)
static __int64 mmRounder = 0x0002000200020002;
static void MakeOneMipmap( ULONG *pulSrcMipmap, ULONG *pulDstMipmap, PIX pixWidth, PIX pixHeight, BOOL bBilinear)
{
// some safety checks
ASSERT( pixWidth>1 && pixHeight>1);
ASSERT( pixWidth == 1L<<FastLog2(pixWidth));
ASSERT( pixHeight == 1L<<FastLog2(pixHeight));
pixWidth >>=1;
pixHeight>>=1;
if( bBilinear) // type of filtering?
{ // BILINEAR
__asm {
pxor mm0,mm0
mov ebx,D [pixWidth]
mov esi,D [pulSrcMipmap]
mov edi,D [pulDstMipmap]
mov edx,D [pixHeight]
rowLoop:
mov ecx,D [pixWidth]
pixLoopN:
movd mm1,D [esi+ 0] // up-left
movd mm2,D [esi+ 4] // up-right
movd mm3,D [esi+ ebx*8 +0] // down-left
movd mm4,D [esi+ ebx*8 +4] // down-right
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
paddw mm1,mm2
paddw mm1,mm3
paddw mm1,mm4
paddw mm1,Q [mmRounder]
psrlw mm1,2
packuswb mm1,mm0
movd D [edi],mm1
// advance to next pixel
add esi,4*2
add edi,4
dec ecx
jnz pixLoopN
// advance to next row
lea esi,[esi+ ebx*8] // skip one row in source mip-map
dec edx
jnz rowLoop
emms
}
}
else
{ // NEAREST-NEIGHBOUR but with border preserving
ULONG ulRowModulo = pixWidth*2 *BYTES_PER_TEXEL;
__asm {
xor ebx,ebx
mov esi,D [pulSrcMipmap]
mov edi,D [pulDstMipmap]
// setup upper half
mov edx,D [pixHeight]
shr edx,1
halfLoop:
mov ecx,D [pixWidth]
shr ecx,1
leftLoop:
mov eax,D [esi+ ebx*8+ 0] // upper-left (or lower-left)
mov D [edi],eax
// advance to next pixel
add esi,4*2
add edi,4
sub ecx,1
jg leftLoop
// do right row half
mov ecx,D [pixWidth]
shr ecx,1
jz halfEnd
rightLoop:
mov eax,D [esi+ ebx*8+ 4] // upper-right (or lower-right)
mov D [edi],eax
// advance to next pixel
add esi,4*2
add edi,4
sub ecx,1
jg rightLoop
halfEnd:
// advance to next row
add esi,D [ulRowModulo] // skip one row in source mip-map
sub edx,1
jg halfLoop
// do eventual lower half loop (if not yet done)
mov edx,D [pixHeight]
shr edx,1
jz fullEnd
cmp ebx,D [pixWidth]
mov ebx,D [pixWidth]
jne halfLoop
fullEnd:
}
}
}
// makes ALL lower mipmaps (to size of 1x1!) of a specified 32-bit bitmap
// and returns pointer to newely created and mipmaped image
// (only first ctFineMips number of mip-maps will be filtered with bilinear subsampling, while
// all others will be downsampled with nearest-neighbour method)
void MakeMipmaps( INDEX ctFineMips, ULONG *pulMipmaps, PIX pixWidth, PIX pixHeight, INDEX iFilter/*=NONE*/)
{
ASSERT( pixWidth>0 && pixHeight>0);
_pfGfxProfile.StartTimer( CGfxProfile::PTI_MAKEMIPMAPS);
// prepare some variables
INDEX ctMipmaps = 1;
PIX pixTexSize = 0;
PIX pixCurrWidth = pixWidth;
PIX pixCurrHeight = pixHeight;
ULONG *pulSrcMipmap, *pulDstMipmap;
// determine filtering mode (-1=prefiltering, 0=none, 1=postfiltering)
INDEX iFilterMode = 0;
if( iFilter!=0) {
iFilterMode = -1;
if( !tex_bProgressiveFilter) iFilterMode = +1;
}
// loop thru mip-map levels
while( pixCurrWidth>1 && pixCurrHeight>1)
{ // determine mip size
PIX pixMipSize = pixCurrWidth*pixCurrHeight;
pulSrcMipmap = pulMipmaps + pixTexSize;
pulDstMipmap = pulSrcMipmap + pixMipSize;
// do pre filter is required
if( iFilterMode<0) FilterBitmap( iFilter, pulSrcMipmap, pulSrcMipmap, pixCurrWidth, pixCurrHeight);
// create one mipmap
MakeOneMipmap( pulSrcMipmap, pulDstMipmap, pixCurrWidth, pixCurrHeight, ctMipmaps<ctFineMips);
// do post filter if required
if( iFilterMode>0) FilterBitmap( iFilter, pulSrcMipmap, pulSrcMipmap, pixCurrWidth, pixCurrHeight);
// advance to next mipmap
pixTexSize += pixMipSize;
pixCurrWidth >>=1;
pixCurrHeight >>=1;
ctMipmaps++;
}
// all done
_pfGfxProfile.StopTimer( CGfxProfile::PTI_MAKEMIPMAPS);
}
// mipmap colorization table (from 1024 to 1)
static COLOR _acolMips[10] = { C_RED, C_GREEN, C_BLUE, C_CYAN, C_MAGENTA, C_YELLOW, C_RED, C_GREEN, C_BLUE, C_WHITE };
// colorize mipmaps
void ColorizeMipmaps( INDEX i1stMipmapToColorize, ULONG *pulMipmaps, PIX pixWidth, PIX pixHeight)
{
// prepare ...
ULONG *pulSrcMipmap = pulMipmaps + GetMipmapOffset( i1stMipmapToColorize, pixWidth, pixHeight);
ULONG *pulDstMipmap;
PIX pixCurrWidth = pixWidth >>i1stMipmapToColorize;
PIX pixCurrHeight = pixHeight>>i1stMipmapToColorize;
PIX pixMipSize;
// skip too large textures
const PIX pixMaxDim = Max( pixCurrWidth, pixCurrHeight);
if( pixMaxDim>1024) return;
INDEX iTableOfs = 10-FastLog2(pixMaxDim);
// loop thru mip-map levels
while( pixCurrWidth>1 && pixCurrHeight>1)
{ // prepare current mip-level
pixMipSize = pixCurrWidth*pixCurrHeight;
pulDstMipmap = pulSrcMipmap + pixMipSize;
// mask mipmap
const ULONG ulColorMask = ByteSwap( _acolMips[iTableOfs] | 0x3F3F3FFF);
for( INDEX iPix=0; iPix<pixMipSize; iPix++) pulSrcMipmap[iPix] &= ulColorMask;
// advance to next mipmap
pulSrcMipmap += pixMipSize;
pixCurrWidth >>=1;
pixCurrHeight >>=1;
iTableOfs++;
}
}
// calculates standard deviation of a bitmap
DOUBLE CalcBitmapDeviation( ULONG *pulBitmap, PIX pixSize)
{
UBYTE ubR,ubG,ubB;
ULONG ulSumR =0, ulSumG =0, ulSumB =0;
__int64 mmSumR2=0, mmSumG2=0, mmSumB2=0;
// calculate sum and sum^2
for( INDEX iPix=0; iPix<pixSize; iPix++) {
ColorToRGB( ByteSwap(pulBitmap[iPix]), ubR,ubG,ubB);
ulSumR += ubR; ulSumG += ubG; ulSumB += ubB;
mmSumR2 += ubR*ubR; mmSumG2 += ubG*ubG; mmSumB2 += ubB*ubB;
}
// calculate deviation of each channel
DOUBLE d1oSize = 1.0 / (DOUBLE) pixSize;
DOUBLE d1oSizeM1 = 1.0 / (DOUBLE)(pixSize-1);
DOUBLE dAvgR = (DOUBLE)ulSumR *d1oSize;
DOUBLE dAvgG = (DOUBLE)ulSumG *d1oSize;
DOUBLE dAvgB = (DOUBLE)ulSumB *d1oSize;
DOUBLE dDevR = Sqrt( ((DOUBLE)mmSumR2 - 2*ulSumR*dAvgR + pixSize*dAvgR*dAvgR) *d1oSizeM1);
DOUBLE dDevG = Sqrt( ((DOUBLE)mmSumG2 - 2*ulSumG*dAvgG + pixSize*dAvgG*dAvgG) *d1oSizeM1);
DOUBLE dDevB = Sqrt( ((DOUBLE)mmSumB2 - 2*ulSumB*dAvgB + pixSize*dAvgB*dAvgB) *d1oSizeM1);
// return maximum deviation
return Max( Max( dDevR, dDevG), dDevB);
}
// DITHERING ROUTINES
// dither tables
static ULONG ulDither4[4][4] = {
{ 0x0F0F0F0F, 0x07070707, 0x0D0D0D0D, 0x05050505 },
{ 0x03030303, 0x0B0B0B0B, 0x01010101, 0x09090909 },
{ 0x0C0C0C0C, 0x04040404, 0x0E0E0E0E, 0x06060606 },
{ 0x00000000, 0x08080808, 0x02020202, 0x0A0A0A0A }
};
static ULONG ulDither3[4][4] = {
{ 0x06060606, 0x02020202, 0x06060606, 0x02020202 },
{ 0x00000000, 0x04040404, 0x00000000, 0x04040404 },
{ 0x06060606, 0x02020202, 0x06060606, 0x02020202 },
{ 0x00000000, 0x04040404, 0x00000000, 0x04040404 },
};
static ULONG ulDither2[4][4] = {
{ 0x02020202, 0x06060606, 0x02020202, 0x06060606 },
{ 0x06060606, 0x02020202, 0x06060606, 0x02020202 },
{ 0x02020202, 0x06060606, 0x02020202, 0x06060606 },
{ 0x06060606, 0x02020202, 0x06060606, 0x02020202 },
};
static __int64 mmErrDiffMask=0;
static __int64 mmW3 = 0x0003000300030003;
static __int64 mmW5 = 0x0005000500050005;
static __int64 mmW7 = 0x0007000700070007;
static __int64 mmShift = 0;
static __int64 mmMask = 0;
static ULONG *pulDitherTable;
// performs dithering of a 32-bit bipmap (can be in-place)
void DitherBitmap( INDEX iDitherType, ULONG *pulSrc, ULONG *pulDst, PIX pixWidth, PIX pixHeight,
PIX pixCanvasWidth, PIX pixCanvasHeight)
{
_pfGfxProfile.StartTimer( CGfxProfile::PTI_DITHERBITMAP);
// determine row modulo
if( pixCanvasWidth ==0) pixCanvasWidth = pixWidth;
if( pixCanvasHeight==0) pixCanvasHeight = pixHeight;
ASSERT( pixCanvasWidth>=pixWidth && pixCanvasHeight>=pixHeight);
SLONG slModulo = (pixCanvasWidth-pixWidth) *BYTES_PER_TEXEL;
SLONG slWidthModulo = pixWidth*BYTES_PER_TEXEL +slModulo;
// if bitmap is smaller than 4x2 pixels
if( pixWidth<4 || pixHeight<2)
{ // don't dither it at all, rather copy only (if needed)
if( pulDst!=pulSrc) memcpy( pulDst, pulSrc, pixCanvasWidth*pixCanvasHeight *BYTES_PER_TEXEL);
goto theEnd;
}
// determine proper dither type
switch( iDitherType)
{ // low dithers
case 1:
pulDitherTable = &ulDither2[0][0];
mmShift = 2;
mmMask = 0x3F3F3F3F3F3F3F3F;
goto ditherOrder;
case 2:
pulDitherTable = &ulDither2[0][0];
mmShift = 1;
mmMask = 0x7F7F7F7F7F7F7F7F;
goto ditherOrder;
case 3:
mmErrDiffMask = 0x0003000300030003;
goto ditherError;
// medium dithers
case 4:
pulDitherTable = &ulDither2[0][0];
mmShift = 0;
mmMask = 0xFFFFFFFFFFFFFFFF;
goto ditherOrder;
case 5:
pulDitherTable = &ulDither3[0][0];
mmShift = 1;
mmMask = 0x7F7F7F7F7F7F7F7F;
goto ditherOrder;
case 6:
pulDitherTable = &ulDither4[0][0];
mmShift = 1;
mmMask = 0x7F7F7F7F7F7F7F7F;
goto ditherOrder;
case 7:
mmErrDiffMask = 0x0007000700070007;
goto ditherError;
// high dithers
case 8:
pulDitherTable = &ulDither3[0][0];
mmShift = 0;
mmMask = 0xFFFFFFFFFFFFFFFF;
goto ditherOrder;
case 9:
pulDitherTable = &ulDither4[0][0];
mmShift = 0;
mmMask = 0xFFFFFFFFFFFFFFFF;
goto ditherOrder;
case 10:
mmErrDiffMask = 0x000F000F000F000F;
goto ditherError;
default:
// improper dither type
ASSERTALWAYS( "Improper dithering type.");
// if bitmap copying is needed
if( pulDst!=pulSrc) memcpy( pulDst, pulSrc, pixCanvasWidth*pixCanvasHeight *BYTES_PER_TEXEL);
goto theEnd;
}
// ------------------------------- ordered matrix dithering routine
ditherOrder:
__asm {
mov esi,D [pulSrc]
mov edi,D [pulDst]
mov ebx,D [pulDitherTable]
// reset dither line offset
xor eax,eax
mov edx,D [pixHeight]
rowLoopO:
// get horizontal dither patterns
movq mm4,Q [ebx+ eax*4 +0]
movq mm5,Q [ebx+ eax*4 +8]
psrlw mm4,Q [mmShift]
psrlw mm5,Q [mmShift]
pand mm4,Q [mmMask]
pand mm5,Q [mmMask]
// process row
mov ecx,D [pixWidth]
pixLoopO:
movq mm1,Q [esi +0]
movq mm2,Q [esi +8]
paddusb mm1,mm4
paddusb mm2,mm5
movq Q [edi +0],mm1
movq Q [edi +8],mm2
// advance to next pixel
add esi,4*4
add edi,4*4
sub ecx,4
jg pixLoopO // !!!! possible memory leak?
je nextRowO
// backup couple of pixels
lea esi,[esi+ ecx*4]
lea edi,[edi+ ecx*4]
nextRowO:
// get next dither line patterns
add esi,D [slModulo]
add edi,D [slModulo]
add eax,1*4
and eax,4*4-1
// advance to next row
dec edx
jnz rowLoopO
emms;
}
goto theEnd;
// ------------------------------- error diffusion dithering routine
ditherError:
// since error diffusion algorithm requires in-place dithering, original bitmap must be copied if needed
if( pulDst!=pulSrc) memcpy( pulDst, pulSrc, pixCanvasWidth*pixCanvasHeight *BYTES_PER_TEXEL);
// slModulo+=4;
// now, dither destination
__asm {
pxor mm0,mm0
mov esi,D [pulDst]
mov ebx,D [pixCanvasWidth]
mov edx,D [pixHeight]
dec edx // need not to dither last row
rowLoopE:
// left to right
mov ecx,D [pixWidth]
dec ecx
pixLoopEL:
movd mm1,D [esi]
punpcklbw mm1,mm0
pand mm1,Q [mmErrDiffMask]
// determine errors
movq mm3,mm1
movq mm5,mm1
movq mm7,mm1
pmullw mm3,Q [mmW3]
pmullw mm5,Q [mmW5]
pmullw mm7,Q [mmW7]
psrlw mm3,4 // *3/16
psrlw mm5,4 // *5/16
psrlw mm7,4 // *7/16
psubw mm1,mm3
psubw mm1,mm5
psubw mm1,mm7 // *rest/16
packuswb mm1,mm0
packuswb mm3,mm0
packuswb mm5,mm0
packuswb mm7,mm0
// spread errors
paddusb mm7,Q [esi+ +4]
paddusb mm3,Q [esi+ ebx*4 -4]
paddusb mm5,Q [esi+ ebx*4 +0]
paddusb mm1,Q [esi+ ebx*4 +4] // !!!! possible memory leak?
movd D [esi+ +4],mm7
movd D [esi+ ebx*4 -4],mm3
movd D [esi+ ebx*4 +0],mm5
movd D [esi+ ebx*4 +4],mm1
// advance to next pixel
add esi,4
dec ecx
jnz pixLoopEL
// advance to next row
add esi,D [slWidthModulo]
dec edx
jz allDoneE
// right to left
mov ecx,D [pixWidth]
dec ecx
pixLoopER:
movd mm1,D [esi]
punpcklbw mm1,mm0
pand mm1,Q [mmErrDiffMask]
// determine errors
movq mm3,mm1
movq mm5,mm1
movq mm7,mm1
pmullw mm3,Q [mmW3]
pmullw mm5,Q [mmW5]
pmullw mm7,Q [mmW7]
psrlw mm3,4 // *3/16
psrlw mm5,4 // *5/16
psrlw mm7,4 // *7/16
psubw mm1,mm3
psubw mm1,mm5
psubw mm1,mm7 // *rest/16
packuswb mm1,mm0
packuswb mm3,mm0
packuswb mm5,mm0
packuswb mm7,mm0
// spread errors
paddusb mm7,Q [esi+ -4]
paddusb mm1,Q [esi+ ebx*4 -4]
paddusb mm5,Q [esi+ ebx*4 +0]
paddusb mm3,Q [esi+ ebx*4 +4] // !!!! possible memory leak?
movd D [esi+ -4],mm7
movd D [esi+ ebx*4 -4],mm1
movd D [esi+ ebx*4 +0],mm5
movd D [esi+ ebx*4 +4],mm3
// revert to previous pixel
sub esi,4
dec ecx
jnz pixLoopER
// advance to next row
lea esi,[esi+ ebx*4]
dec edx
jnz rowLoopE
allDoneE:
emms;
}
goto theEnd;
// all done
theEnd:
_pfGfxProfile.StopTimer( CGfxProfile::PTI_DITHERBITMAP);
}
// performs dithering of a 32-bit mipmaps (can be in-place)
void DitherMipmaps( INDEX iDitherType, ULONG *pulSrc, ULONG *pulDst, PIX pixWidth, PIX pixHeight)
{
// safety check
ASSERT( pixWidth>0 && pixHeight>0);
// loop thru mipmaps
PIX pixMipSize;
while( pixWidth>0 && pixHeight>0)
{ // dither one mipmap
DitherBitmap( iDitherType, pulSrc, pulDst, pixWidth, pixHeight);
// advance to next mipmap
pixMipSize = pixWidth*pixHeight;
pulSrc += pixMipSize;
pulDst += pixMipSize;
pixWidth >>=1;
pixHeight>>=1;
}
}
// blur/sharpen filters
static INDEX aiFilters[6][3] = {
{ 0, 1, 16 }, // minimum
{ 0, 2, 8 }, // low
{ 1, 2, 7 }, // medium
{ 1, 2, 3 }, // high
{ 3, 4, 5 }, // maximum
{ 1, 1, 1 }}; //
// temp for middle pixels, vertical/horizontal edges, and corners
static __int64 mmMc, mmMe, mmMm; // corner, edge, middle
static __int64 mmEch, mmEm; // corner-high, middle
#define mmEcl mmMc // corner-low
#define mmEe mmMe // edge
static __int64 mmCm; // middle
#define mmCc mmMc // corner
#define mmCe mmEch // edge
static __int64 mmInvDiv;
static __int64 mmAdd = 0x0007000700070007;
// temp rows for in-place filtering support
static ULONG aulRows[2048];
// FilterBitmap() INTERNAL: generates convolution filter matrix if needed
static INDEX iLastFilter;
static void GenerateConvolutionMatrix( INDEX iFilter)
{
// same as last?
if( iLastFilter==iFilter) return;
// update filter
iLastFilter = iFilter;
INDEX iFilterAbs = Abs(iFilter) -1;
// convert convolution values to MMX format
INDEX iMc = aiFilters[iFilterAbs][0]; // corner
INDEX iMe = aiFilters[iFilterAbs][1]; // edge
INDEX iMm = aiFilters[iFilterAbs][2]; // middle
// negate values for sharpen filter case
if( iFilter<0) {
iMm += (iMe+iMc) *8; // (4*Edge + 4*Corner) *2
iMe = -iMe;
iMc = -iMc;
}
// find values for edge and corner cases
INDEX iEch = iMc + iMe;
INDEX iEm = iMm + iMe;
INDEX iCm = iEch + iEm;
// prepare divider
__int64 mm = ((__int64)ceil(65536.0f/(iMc*4+iMe*4+iMm))) & 0xFFFF;
mmInvDiv = (mm<<48) | (mm<<32) | (mm<<16) | mm;
// prepare filter values
mm = iMc & 0xFFFF; mmMc = (mm<<48) | (mm<<32) | (mm<<16) | mm;
mm = iMe & 0xFFFF; mmMe = (mm<<48) | (mm<<32) | (mm<<16) | mm;
mm = iMm & 0xFFFF; mmMm = (mm<<48) | (mm<<32) | (mm<<16) | mm;
mm = iEch & 0xFFFF; mmEch= (mm<<48) | (mm<<32) | (mm<<16) | mm;
mm = iEm & 0xFFFF; mmEm = (mm<<48) | (mm<<32) | (mm<<16) | mm;
mm = iCm & 0xFFFF; mmCm = (mm<<48) | (mm<<32) | (mm<<16) | mm;
}
// applies filter to bitmap
void FilterBitmap( INDEX iFilter, ULONG *pulSrc, ULONG *pulDst, PIX pixWidth, PIX pixHeight,
PIX pixCanvasWidth, PIX pixCanvasHeight)
{
_pfGfxProfile.StartTimer( CGfxProfile::PTI_FILTERBITMAP);
ASSERT( iFilter>=-6 && iFilter<=+6);
// adjust canvas size
if( pixCanvasWidth ==0) pixCanvasWidth = pixWidth;
if( pixCanvasHeight==0) pixCanvasHeight = pixHeight;
ASSERT( pixCanvasWidth>=pixWidth && pixCanvasHeight>=pixHeight);
// if bitmap is smaller than 4x4
if( pixWidth<4 || pixHeight<4)
{ // don't blur it at all, but eventually only copy
if( pulDst!=pulSrc) memcpy( pulDst, pulSrc, pixCanvasWidth*pixCanvasHeight *BYTES_PER_TEXEL);
_pfGfxProfile.StopTimer( CGfxProfile::PTI_FILTERBITMAP);
return;
}
// prepare convolution matrix and row modulo
iFilter = Clamp( iFilter, -6L, +6L);
GenerateConvolutionMatrix( iFilter);
SLONG slModulo1 = (pixCanvasWidth-pixWidth+1) *BYTES_PER_TEXEL;
SLONG slCanvasWidth = pixCanvasWidth *BYTES_PER_TEXEL;
// lets roll ...
__asm {
cld
mov eax,D [pixCanvasWidth] // EAX = positive row offset
mov edx,eax
neg edx // EDX = negative row offset
pxor mm0,mm0
mov esi,D [pulSrc]
mov edi,D [pulDst]
xor ebx,ebx
// ----------------------- process upper left corner
movd mm1,D [esi+ +0]
movd mm2,D [esi+ +4]
movd mm3,D [esi+ eax*4 +0]
movd mm4,D [esi+ eax*4 +4]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
paddw mm2,mm3
pmullw mm1,Q [mmCm]
pmullw mm2,Q [mmCe]
pmullw mm4,Q [mmCc]
paddw mm1,mm2
paddw mm1,mm4
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd D [ebx+ aulRows],mm1
add esi,4
add ebx,4
// ----------------------- process upper edge pixels
mov ecx,D [pixWidth]
sub ecx,2
// for each pixel
upperLoop:
movd mm1,D [esi+ -4]
movd mm2,D [esi+ +0]
movd mm3,D [esi+ +4]
movd mm4,D [esi+ eax*4 -4]
movd mm5,D [esi+ eax*4 +0]
movd mm6,D [esi+ eax*4 +4]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
punpcklbw mm5,mm0
punpcklbw mm6,mm0
paddw mm1,mm3
paddw mm4,mm6
pmullw mm1,Q [mmEch]
pmullw mm2,Q [mmEm]
pmullw mm4,Q [mmEcl]
pmullw mm5,Q [mmEe]
paddw mm1,mm2
paddw mm1,mm4
paddw mm1,mm5
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd D [ebx+ aulRows],mm1
// advance to next pixel
add esi,4
add ebx,4
dec ecx
jnz upperLoop
// ----------------------- process upper right corner
movd mm1,D [esi+ -4]
movd mm2,D [esi+ +0]
movd mm3,D [esi+ eax*4 -4]
movd mm4,D [esi+ eax*4 +0]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
paddw mm1,mm4
pmullw mm1,Q [mmCe]
pmullw mm2,Q [mmCm]
pmullw mm3,Q [mmCc]
paddw mm1,mm2
paddw mm1,mm3
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd D [ebx+ aulRows],mm1
// ----------------------- process bitmap middle pixels
add esi,D [slModulo1]
add edi,D [slCanvasWidth]
mov ebx,D [pixHeight]
sub ebx,2
// for each row
rowLoop:
push ebx
xor ebx,ebx
// process left edge pixel
movd mm1,D [esi+ edx*4 +0]
movd mm2,D [esi+ edx*4 +4]
movd mm3,D [esi+ +0]
movd mm4,D [esi+ +4]
movd mm5,D [esi+ eax*4 +0]
movd mm6,D [esi+ eax*4 +4]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
punpcklbw mm5,mm0
punpcklbw mm6,mm0
paddw mm1,mm5
paddw mm2,mm6
pmullw mm1,Q [mmEch]
pmullw mm2,Q [mmEcl]
pmullw mm3,Q [mmEm]
pmullw mm4,Q [mmEe]
paddw mm1,mm2
paddw mm1,mm3
paddw mm1,mm4
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd mm2,D [ebx+ aulRows]
movd D [ebx+ aulRows],mm1
movd D [edi+ edx*4],mm2
add esi,4
add edi,4
add ebx,4
// for each pixel in current row
mov ecx,D [pixWidth]
sub ecx,2
pixLoop:
// prepare upper convolution row
movd mm1,D [esi+ edx*4 -4]
movd mm2,D [esi+ edx*4 +0]
movd mm3,D [esi+ edx*4 +4]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
// prepare middle convolution row
movd mm4,D [esi+ -4]
movd mm5,D [esi+ +0]
movd mm6,D [esi+ +4]
punpcklbw mm4,mm0
punpcklbw mm5,mm0
punpcklbw mm6,mm0
// free some registers
paddw mm1,mm3
paddw mm2,mm4
pmullw mm5,Q [mmMm]
// prepare lower convolution row
movd mm3,D [esi+ eax*4 -4]
movd mm4,D [esi+ eax*4 +0]
movd mm7,D [esi+ eax*4 +4]
punpcklbw mm3,mm0
punpcklbw mm4,mm0
punpcklbw mm7,mm0
// calc weightened value
paddw mm2,mm6
paddw mm1,mm3
paddw mm2,mm4
paddw mm1,mm7
pmullw mm2,Q [mmMe]
pmullw mm1,Q [mmMc]
paddw mm2,mm5
paddw mm1,mm2
// calc and store wightened value
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd mm2,D [ebx+ aulRows]
movd D [ebx+ aulRows],mm1
movd D [edi+ edx*4],mm2
// advance to next pixel
add esi,4
add edi,4
add ebx,4
dec ecx
jnz pixLoop
// process right edge pixel
movd mm1,D [esi+ edx*4 -4]
movd mm2,D [esi+ edx*4 +0]
movd mm3,D [esi+ -4]
movd mm4,D [esi+ +0]
movd mm5,D [esi+ eax*4 -4]
movd mm6,D [esi+ eax*4 +0]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
punpcklbw mm5,mm0
punpcklbw mm6,mm0
paddw mm1,mm5
paddw mm2,mm6
pmullw mm1,Q [mmEcl]
pmullw mm2,Q [mmEch]
pmullw mm3,Q [mmEe]
pmullw mm4,Q [mmEm]
paddw mm1,mm2
paddw mm1,mm3
paddw mm1,mm4
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd mm2,D [ebx+ aulRows]
movd D [ebx+ aulRows],mm1
movd D [edi+ edx*4],mm2
// advance to next row
add esi,D [slModulo1]
add edi,D [slModulo1]
pop ebx
dec ebx
jnz rowLoop
// ----------------------- process lower left corner
xor ebx,ebx
movd mm1,D [esi+ edx*4 +0]
movd mm2,D [esi+ edx*4 +4]
movd mm3,D [esi+ +0]
movd mm4,D [esi+ +4]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
paddw mm1,mm4
pmullw mm1,Q [mmCe]
pmullw mm2,Q [mmCc]
pmullw mm3,Q [mmCm]
paddw mm1,mm2
paddw mm1,mm3
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd mm2,D [ebx+ aulRows]
movd D [edi],mm1
movd D [edi+ edx*4],mm2
add esi,4
add edi,4
add ebx,4
// ----------------------- process lower edge pixels
mov ecx,D [pixWidth]
sub ecx,2
// for each pixel
lowerLoop:
movd mm1,D [esi+ edx*4 -4]
movd mm2,D [esi+ edx*4 +0]
movd mm3,D [esi+ edx*4 +4]
movd mm4,D [esi+ -4]
movd mm5,D [esi+ +0]
movd mm6,D [esi+ +4]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
punpcklbw mm5,mm0
punpcklbw mm6,mm0
paddw mm1,mm3
paddw mm4,mm6
pmullw mm1,Q [mmEcl]
pmullw mm2,Q [mmEe]
pmullw mm4,Q [mmEch]
pmullw mm5,Q [mmEm]
paddw mm1,mm2
paddw mm1,mm4
paddw mm1,mm5
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd mm2,D [ebx+ aulRows]
movd D [edi],mm1
movd D [edi+ edx*4],mm2
// advance to next pixel
add esi,4
add edi,4
add ebx,4
dec ecx
jnz lowerLoop
// ----------------------- lower right corners
movd mm1,D [esi+ edx*4 -4]
movd mm2,D [esi+ edx*4 +0]
movd mm3,D [esi+ -4]
movd mm4,D [esi+ +0]
punpcklbw mm1,mm0
punpcklbw mm2,mm0
punpcklbw mm3,mm0
punpcklbw mm4,mm0
paddw mm2,mm3
pmullw mm1,Q [mmCc]
pmullw mm2,Q [mmCe]
pmullw mm4,Q [mmCm]
paddw mm1,mm2
paddw mm1,mm4
paddsw mm1,Q [mmAdd]
pmulhw mm1,Q [mmInvDiv]
packuswb mm1,mm0
movd mm2,D [ebx+ aulRows]
movd D [edi],mm1
movd D [edi+ edx*4],mm2
emms
}
// all done (finally)
_pfGfxProfile.StopTimer( CGfxProfile::PTI_FILTERBITMAP);
}
// saturate color of bitmap
void AdjustBitmapColor( ULONG *pulSrc, ULONG *pulDst, PIX pixWidth, PIX pixHeight,
SLONG const slHueShift, SLONG const slSaturation)
{
for( INDEX i=0; i<(pixWidth*pixHeight); i++) {
pulDst[i] = ByteSwap( AdjustColor( ByteSwap(pulSrc[i]), slHueShift, slSaturation));
}
}
// create mip-map table for texture or shadow of given dimensions
void MakeMipmapTable( PIX pixU, PIX pixV, MipmapTable &mmt)
{
mmt.mmt_pixU = pixU;
mmt.mmt_pixV = pixV;
// start at first mip map
PIX pixCurrentU = mmt.mmt_pixU;
PIX pixCurrentV = mmt.mmt_pixV;
INDEX iMipmapCurrent = 0;
SLONG slOffsetCurrent = 0;
// while the mip-map is not zero-sized
while (pixCurrentU>0 && pixCurrentV>0) {
// remember its offset
mmt.mmt_aslOffsets[iMipmapCurrent] = slOffsetCurrent;
// go to next mip map
slOffsetCurrent+=pixCurrentU*pixCurrentV;
iMipmapCurrent++;
pixCurrentU>>=1;
pixCurrentV>>=1;
}
// remember number of mip maps and total size
mmt.mmt_ctMipmaps = iMipmapCurrent;
mmt.mmt_slTotalSize = slOffsetCurrent;
}
// TRIANGLE MASK RENDERING (FOR MODEL CLUSTER SHADOWS) ROUTINES
static ULONG *_pulTexture;
static PIX _pixTexWidth, _pixTexHeight;
extern BOOL _bSomeDarkExists = FALSE;
// set texture that will be used for all subsequent triangles
void SetTriangleTexture( ULONG *pulCurrentMipmap, PIX pixMipWidth, PIX pixMipHeight)
{
_pulTexture = pulCurrentMipmap;
_pixTexWidth = pixMipWidth;
_pixTexHeight = pixMipHeight;
}
// render one triangle to mask plane for shadow casting purposes
void DrawTriangle_Mask( UBYTE *pubMaskPlane, SLONG slMaskWidth, SLONG slMaskHeight,
struct PolyVertex2D *ppv2Vtx1, struct PolyVertex2D *ppv2Vtx2,
struct PolyVertex2D *ppv2Vtx3, BOOL bTransparency)
{
struct PolyVertex2D *pUpper = ppv2Vtx1;
struct PolyVertex2D *pMiddle = ppv2Vtx2;
struct PolyVertex2D *pLower = ppv2Vtx3;
struct PolyVertex2D *pTmp;
// sort vertices by J position
if( pUpper->pv2_fJ > pMiddle->pv2_fJ) {
pTmp = pUpper; pUpper = pMiddle; pMiddle = pTmp;
}
if( pUpper->pv2_fJ > pLower->pv2_fJ) {
pTmp = pUpper; pUpper = pLower; pLower = pTmp;
}
if( pMiddle->pv2_fJ > pLower->pv2_fJ) {
pTmp = pMiddle; pMiddle = pLower; pLower = pTmp;
}
// determine vertical deltas
FLOAT fDJShort1 = pMiddle->pv2_fJ - pUpper->pv2_fJ;
FLOAT fDJShort2 = pLower->pv2_fJ - pMiddle->pv2_fJ;
FLOAT fDJLong = pLower->pv2_fJ - pUpper->pv2_fJ;
if( fDJLong == 0) return;
// determine horizontal deltas
FLOAT fDIShort1 = pMiddle->pv2_fI - pUpper->pv2_fI;
FLOAT fDIShort2 = pLower->pv2_fI - pMiddle->pv2_fI;
FLOAT fDILong = pLower->pv2_fI - pUpper->pv2_fI;
// determine U/K, V/K and 1/K deltas
FLOAT fD1oKShort1 = pMiddle->pv2_f1oK - pUpper->pv2_f1oK;
FLOAT fD1oKShort2 = pLower->pv2_f1oK - pMiddle->pv2_f1oK;
FLOAT fD1oKLong = pLower->pv2_f1oK - pUpper->pv2_f1oK;
FLOAT fDUoKShort1 = pMiddle->pv2_fUoK - pUpper->pv2_fUoK;
FLOAT fDUoKShort2 = pLower->pv2_fUoK - pMiddle->pv2_fUoK;
FLOAT fDUoKLong = pLower->pv2_fUoK - pUpper->pv2_fUoK;
FLOAT fDVoKShort1 = pMiddle->pv2_fVoK - pUpper->pv2_fVoK;
FLOAT fDVoKShort2 = pLower->pv2_fVoK - pMiddle->pv2_fVoK;
FLOAT fDVoKLong = pLower->pv2_fVoK - pUpper->pv2_fVoK;
// determine stepping factors;
FLOAT f1oDJShort1, f1oDJShort2, f1oDJLong;
if( fDJShort1 != 0) f1oDJShort1 = 1 / fDJShort1; else f1oDJShort1 = 0;
if( fDJShort2 != 0) f1oDJShort2 = 1 / fDJShort2; else f1oDJShort2 = 0;
if( fDJLong != 0) f1oDJLong = 1 / fDJLong; else f1oDJLong = 0;
FLOAT fDIoDJShort1 = fDIShort1 * f1oDJShort1;
FLOAT fDIoDJShort2 = fDIShort2 * f1oDJShort2;
FLOAT fDIoDJLong = fDILong * f1oDJLong;
FLOAT fMaxWidth = fDIoDJLong*fDJShort1 + pUpper->pv2_fI - pMiddle->pv2_fI;
// determine drawing direction and factors by direction
SLONG direction = +1;
if( fMaxWidth > 0) direction = -1;
// find start and end values for J
PIX pixUpJ = FloatToInt(pUpper->pv2_fJ +0.5f);
PIX pixMdJ = FloatToInt(pMiddle->pv2_fJ +0.5f);
PIX pixDnJ = FloatToInt(pLower->pv2_fJ +0.5f);
// clip vertically
if( pixDnJ<0 || pixUpJ>=slMaskHeight) return;
if( pixUpJ<0) pixUpJ=0;
if( pixDnJ>slMaskHeight) pixDnJ=slMaskHeight;
if( pixMdJ<0) pixMdJ=0;
if( pixMdJ>slMaskHeight) pixMdJ=slMaskHeight;
SLONG fixWidth = slMaskWidth<<11;
// find prestepped I
FLOAT fPrestepUp = (FLOAT)pixUpJ - pUpper->pv2_fJ;
FLOAT fPrestepMd = (FLOAT)pixMdJ - pMiddle->pv2_fJ;
SLONG fixILong = FloatToInt((pUpper->pv2_fI + fPrestepUp * fDIoDJLong )*2048.0f) +fixWidth*pixUpJ;
SLONG fixIShort1 = FloatToInt((pUpper->pv2_fI + fPrestepUp * fDIoDJShort1)*2048.0f) +fixWidth*pixUpJ;
SLONG fixIShort2 = FloatToInt((pMiddle->pv2_fI + fPrestepMd * fDIoDJShort2)*2048.0f) +fixWidth*pixMdJ;
// convert steps from floats to fixints (21:11)
SLONG fixDIoDJLong = FloatToInt(fDIoDJLong *2048.0f) +fixWidth;
SLONG fixDIoDJShort1 = FloatToInt(fDIoDJShort1*2048.0f) +fixWidth;
SLONG fixDIoDJShort2 = FloatToInt(fDIoDJShort2*2048.0f) +fixWidth;
// find row counter and max delta J
SLONG ctJShort1 = pixMdJ - pixUpJ;
SLONG ctJShort2 = pixDnJ - pixMdJ;
SLONG ctJLong = pixDnJ - pixUpJ;
FLOAT currK, curr1oK, currUoK, currVoK;
PIX pixJ = pixUpJ;
// if model has texture and texture has alpha channel, do complex mapping thru texture's alpha channel
if( _pulTexture!=NULL && bTransparency)
{
// calculate some texture variables
FLOAT fD1oKoDJShort1 = fD1oKShort1 * f1oDJShort1;
FLOAT fD1oKoDJShort2 = fD1oKShort2 * f1oDJShort2;
FLOAT fD1oKoDJLong = fD1oKLong * f1oDJLong;
FLOAT fDUoKoDJShort1 = fDUoKShort1 * f1oDJShort1;
FLOAT fDUoKoDJShort2 = fDUoKShort2 * f1oDJShort2;
FLOAT fDUoKoDJLong = fDUoKLong * f1oDJLong;
FLOAT fDVoKoDJShort1 = fDVoKShort1 * f1oDJShort1;
FLOAT fDVoKoDJShort2 = fDVoKShort2 * f1oDJShort2;
FLOAT fDVoKoDJLong = fDVoKLong * f1oDJLong;
;// FactOverDI = (DFoDJ * (J2-J1) + fact1 - fact2) * 1/width
FLOAT f1oMaxWidth = 1 / fMaxWidth;
FLOAT fD1oKoDI = (fD1oKoDJLong * fDJShort1 + pUpper->pv2_f1oK - pMiddle->pv2_f1oK) * f1oMaxWidth;
FLOAT fDUoKoDI = (fDUoKoDJLong * fDJShort1 + pUpper->pv2_fUoK - pMiddle->pv2_fUoK) * f1oMaxWidth;
FLOAT fDVoKoDI = (fDVoKoDJLong * fDJShort1 + pUpper->pv2_fVoK - pMiddle->pv2_fVoK) * f1oMaxWidth;
if( direction == -1) {
fD1oKoDI = -fD1oKoDI;
fDUoKoDI = -fDUoKoDI;
fDVoKoDI = -fDVoKoDI;
}
// find prestepped U/K, V/K, 1/K
FLOAT f1oKLong = pUpper->pv2_f1oK + fPrestepUp * fD1oKoDJLong;
FLOAT f1oKShort1 = pUpper->pv2_f1oK + fPrestepUp * fD1oKoDJShort1;
FLOAT f1oKShort2 = pMiddle->pv2_f1oK + fPrestepMd * fD1oKoDJShort2;
FLOAT fUoKLong = pUpper->pv2_fUoK + fPrestepUp * fDUoKoDJLong;
FLOAT fUoKShort1 = pUpper->pv2_fUoK + fPrestepUp * fDUoKoDJShort1;
FLOAT fUoKShort2 = pMiddle->pv2_fUoK + fPrestepMd * fDUoKoDJShort2;
FLOAT fVoKLong = pUpper->pv2_fVoK + fPrestepUp * fDVoKoDJLong;
FLOAT fVoKShort1 = pUpper->pv2_fVoK + fPrestepUp * fDVoKoDJShort1;
FLOAT fVoKShort2 = pMiddle->pv2_fVoK + fPrestepMd * fDVoKoDJShort2;
// render upper triangle part
PIX pixTexU, pixTexV;
while( ctJShort1>0) {
SLONG currI = fixILong>>11;
SLONG countI = abs( currI - (fixIShort1>>11));
if( countI==0) goto nextLine1;
curr1oK = f1oKLong;
currUoK = fUoKLong;
currVoK = fVoKLong;
if( direction == -1) currI--;
if( countI>0) _bSomeDarkExists = TRUE;
while( countI>0) {
currK = 1.0f/curr1oK;
pixTexU = (FloatToInt(currUoK*currK)) & (_pixTexWidth -1);
pixTexV = (FloatToInt(currVoK*currK)) & (_pixTexHeight-1);
if( _pulTexture[pixTexV*_pixTexWidth+pixTexU] & ((CT_rAMASK<<7)&CT_rAMASK)) pubMaskPlane[currI] = 0;
curr1oK += fD1oKoDI;
currUoK += fDUoKoDI;
currVoK += fDVoKoDI;
currI += direction;
countI--;
}
nextLine1:
pixJ++;
f1oKLong += fD1oKoDJLong;
f1oKShort1 += fD1oKoDJShort1;
fUoKLong += fDUoKoDJLong;
fUoKShort1 += fDUoKoDJShort1;
fVoKLong += fDVoKoDJLong;
fVoKShort1 += fDVoKoDJShort1;
fixILong += fixDIoDJLong;
fixIShort1 += fixDIoDJShort1;
ctJShort1--;
}
// render lower triangle part
while( ctJShort2>0) {
SLONG currI = fixILong>>11;
SLONG countI = abs( currI - (fixIShort2>>11));
if( countI==0) goto nextLine2;
curr1oK = f1oKLong;
currUoK = fUoKLong;
currVoK = fVoKLong;
if( direction == -1) currI--;
if( countI>0) _bSomeDarkExists = TRUE;
while( countI>0) {
currK = 1.0f/curr1oK;
pixTexU = (FloatToInt(currUoK*currK)) & (_pixTexWidth -1);
pixTexV = (FloatToInt(currVoK*currK)) & (_pixTexHeight-1);
if( _pulTexture[pixTexV*_pixTexWidth+pixTexU] & CT_rAMASK) pubMaskPlane[currI] = 0;
curr1oK += fD1oKoDI;
currUoK += fDUoKoDI;
currVoK += fDVoKoDI;
currI += direction;
countI--;
}
nextLine2:
pixJ++;
f1oKLong += fD1oKoDJLong;
f1oKShort2 += fD1oKoDJShort2;
fUoKLong += fDUoKoDJLong;
fUoKShort2 += fDUoKoDJShort2;
fVoKLong += fDVoKoDJLong;
fVoKShort2 += fDVoKoDJShort2;
fixILong += fixDIoDJLong;
fixIShort2 += fixDIoDJShort2;
ctJShort2--;
}
}
// simple flat mapping (no texture at all)
else
{
// render upper triangle part
while( ctJShort1>0) {
SLONG currI = fixILong>>11;
SLONG countI = abs( currI - (fixIShort1>>11));
if( direction == -1) currI--;
if( countI>0) _bSomeDarkExists = TRUE;
while( countI>0) {
pubMaskPlane[currI] = 0;
currI += direction;
countI--;
}
pixJ++;
fixILong += fixDIoDJLong;
fixIShort1 += fixDIoDJShort1;
ctJShort1--;
}
// render lower triangle part
while( ctJShort2>0) {
SLONG currI = fixILong>>11;
SLONG countI = abs( currI - (fixIShort2>>11));
if( countI>0) _bSomeDarkExists = TRUE;
if( direction == -1) currI--;
while( countI>0) {
pubMaskPlane[currI] = 0;
currI += direction;
countI--;
}
pixJ++;
fixILong += fixDIoDJLong;
fixIShort2 += fixDIoDJShort2;
ctJShort2--;
}
}
}
// ---------------------------------------------------------------------------------------------
#if 0
// bilinear filtering of lower mipmap
// row loop
UBYTE r,g,b,a;
for( PIX v=0; v<pixHeight; v++)
{ // column loop
for( PIX u=0; u<pixWidth; u++)
{ // read four neighbour pixels
COLOR colUL = pulSrcMipmap[((v*2+0)*pixCurrWidth*2+u*2) +0];
COLOR colUR = pulSrcMipmap[((v*2+0)*pixCurrWidth*2+u*2) +1];
COLOR colDL = pulSrcMipmap[((v*2+1)*pixCurrWidth*2+u*2) +0];
COLOR colDR = pulSrcMipmap[((v*2+1)*pixCurrWidth*2+u*2) +1];
// separate and add channels
ULONG rRes=0, gRes=0, bRes=0, aRes=0;
ColorToRGBA( colUL, r,g,b,a); rRes += r; gRes += g; bRes += b; aRes += a;
ColorToRGBA( colUR, r,g,b,a); rRes += r; gRes += g; bRes += b; aRes += a;
ColorToRGBA( colDL, r,g,b,a); rRes += r; gRes += g; bRes += b; aRes += a;
ColorToRGBA( colDR, r,g,b,a); rRes += r; gRes += g; bRes += b; aRes += a;
// round, average and store
rRes += 2; gRes += 2; bRes += 2; aRes += 2;
rRes >>=2; gRes >>=2; bRes >>=2; aRes >>=2;
pulDstMipmap[v*pixCurrWidth+u] = RGBAToColor( rRes,gRes,bRes,aRes);
}
}
// nearest-neighbouring of lower mipmap (with border preservance)
// row loop
PIX u,v;
for( v=0; v<pixCurrHeight/2; v++) {
for( u=0; u<pixCurrWidth/2; u++) { // mipmap upper left pixel
pulDstMipmap[v*pixCurrWidth+u] = pulSrcMipmap[((v*2+0)*pixCurrWidth*2+u*2) +0];
}
for( u=pixCurrWidth/2; u<pixCurrWidth; u++) { // mipmap upper right pixel
pulDstMipmap[v*pixCurrWidth+u] = pulSrcMipmap[((v*2+0)*pixCurrWidth*2+u*2) +1];
}
}
for( v=pixCurrHeight/2; v<pixCurrHeight; v++) {
for( u=0; u<pixCurrWidth/2; u++) { // mipmap upper left pixel
pulDstMipmap[v*pixCurrWidth+u] = pulSrcMipmap[((v*2+1)*pixCurrWidth*2+u*2) +0];
}
for( u=pixCurrWidth/2; u<pixCurrWidth; u++) { // mipmap upper right pixel
pulDstMipmap[v*pixCurrWidth+u] = pulSrcMipmap[((v*2+1)*pixCurrWidth*2+u*2) +1];
}
}
// left to right error diffusion dithering
__asm {
pxor mm0,mm0
mov esi,D [pulDst]
mov ebx,D [pixCanvasWidth]
mov edx,D [pixHeight]
dec edx // need not to dither last row
rowLoopE:
mov ecx,D [pixWidth]
dec ecx
pixLoopE:
movd mm1,D [esi]
punpcklbw mm1,mm0
pand mm1,Q [mmErrDiffMask]
// determine errors
movq mm3,mm1
paddw mm3,mm3 // *2
movq mm5,mm3
paddw mm5,mm5 // *4
movq mm7,mm5
paddw mm7,mm7 // *8
paddw mm3,mm1 // *3
paddw mm5,mm1 // *5
psubw mm7,mm1 // *7
psrlw mm1,4
psrlw mm3,4
psrlw mm5,4
psrlw mm7,4
packuswb mm1,mm0
packuswb mm3,mm0
packuswb mm5,mm0
packuswb mm7,mm0
// spread errors
movd mm2,D [esi+ ebx*4 +4]
paddusb mm1,mm2
paddusb mm3,Q [esi+ ebx*4 -4]
paddusb mm5,Q [esi+ ebx*4 +0]
paddusb mm7,Q [esi+ +4]
movd D [esi+ ebx*4 +4],mm1
movd D [esi+ ebx*4 -4],mm3
movd D [esi+ ebx*4 +0],mm5
movd D [esi+ +4],mm7
// advance to next pixel
add esi,4
dec ecx
jnz pixLoopE
// advance to next row
add esi,D [slModulo]
dec edx
jnz rowLoopE
emms
}
// left to right and right to left error diffusion dithering
__asm {
pxor mm0,mm0
mov esi,D [pulDst]
mov ebx,D [pixCanvasWidth]
mov edx,D [pixHeight]
dec edx // need not to dither last row
rowLoopE:
// left to right
mov ecx,D [pixWidth]
dec ecx
pixLoopEL:
movd mm1,D [esi]
punpcklbw mm1,mm0
pand mm1,Q [mmErrDiffMask]
// determine errors
movq mm3,mm1
paddw mm3,mm3 // *2
movq mm5,mm3
paddw mm5,mm5 // *4
movq mm7,mm5
paddw mm7,mm7 // *8
paddw mm3,mm1 // *3
paddw mm5,mm1 // *5
psubw mm7,mm1 // *7
psrlw mm1,4
psrlw mm3,4
psrlw mm5,4
psrlw mm7,4
packuswb mm1,mm0
packuswb mm3,mm0
packuswb mm5,mm0
packuswb mm7,mm0
// spread errors
movd mm2,D [esi+ ebx*4 +4]
paddusb mm1,mm2
paddusb mm3,Q [esi+ ebx*4 -4]
paddusb mm5,Q [esi+ ebx*4 +0]
paddusb mm7,Q [esi+ +4]
movd D [esi+ ebx*4 +4],mm1
movd D [esi+ ebx*4 -4],mm3
movd D [esi+ ebx*4 +0],mm5
movd D [esi+ +4],mm7
// advance to next pixel
add esi,4
dec ecx
jnz pixLoopEL
// advance to next row
add esi,D [slWidthModulo]
dec edx
jz allDoneE
// right to left
mov ecx,D [pixWidth]
dec ecx
pixLoopER:
movd mm1,D [esi]
punpcklbw mm1,mm0
pand mm1,Q [mmErrDiffMask]
// determine errors
movq mm3,mm1
paddw mm3,mm3 // *2
movq mm5,mm3
paddw mm5,mm5 // *4
movq mm7,mm5
paddw mm7,mm7 // *8
paddw mm3,mm1 // *3
paddw mm5,mm1 // *5
psubw mm7,mm1 // *7
psrlw mm1,4
psrlw mm3,4
psrlw mm5,4
psrlw mm7,4
packuswb mm1,mm0
packuswb mm3,mm0
packuswb mm5,mm0
packuswb mm7,mm0
// spread errors
paddusb mm1,Q [esi+ ebx*4 -4]
paddusb mm3,Q [esi+ ebx*4 +4]
paddusb mm5,Q [esi+ ebx*4 +0]
paddusb mm7,Q [esi+ -4]
movd D [esi+ ebx*4 -4],mm1
movd D [esi+ ebx*4 +4],mm3
movd D [esi+ ebx*4 +0],mm5
movd D [esi+ -4],mm7
// revert to previous pixel
sub esi,4
dec ecx
jnz pixLoopER
// advance to next row
add esi,D [slCanvasWidth]
dec edx
jnz rowLoopE
allDoneE:
emms
}
// bicubic
static INDEX aiWeights[4][4] = {
{ -1, 9, 9, -1, },
{ 9, 47, 47, 9, },
{ 9, 47, 47, 9, },
{ -1, 9, 9, -1 }
};
const SLONG slMaskU=pixWidth *2 -1;
const SLONG slMaskV=pixHeight*2 -1;
// bicubic?
if( pixWidth>4 && pixHeight>4 /*&& tex_bBicubicMipmaps*/)
{
for( INDEX j=0; j<pixHeight; j++) {
for( INDEX i=0; i<pixWidth; i++) {
COLOR col;
UBYTE ubR, ubG, ubB, ubA;
SLONG slR=0, slG=0, slB=0, slA=0;
for( INDEX v=0; v<4; v++) {
const INDEX iRowSrc = ((v-1)+j*2) & slMaskV;
for( INDEX u=0; u<4; u++) {
const INDEX iColSrc = ((u-1)+i*2) & slMaskU;
const INDEX iWeight = aiWeights[u][v];
col = ByteSwap( pulSrcMipmap[iRowSrc*(slMaskU+1)+iColSrc]);
ColorToRGBA( col, ubR,ubG,ubB,ubA);
slR += ubR*iWeight;
slG += ubG*iWeight;
slB += ubB*iWeight;
slA += ubA*iWeight;
}
}
col = RGBAToColor( slR>>8, slG>>8, slB>>8, slA>>8);
pulDstMipmap[j*pixWidth+i] = ByteSwap(col);
}
}
}
// bilinear!
else
{
}
#endif