Leaked source code of windows server 2003
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;-----------------------------------------------------------------------------
;
; Monolith 21. Perspective Correct Bi-linear gouraud modulated
; X888 input texture 16 bit Z buffered (LE or GT)
; X888 output.
;
; Exactly the same as monolith 7 except color input is 32 bits and
; output is 32 bits
;
;-----------------------------------------------------------------------------
INCLUDE iammx.inc
INCLUDE offs_acp.inc
; Names are read LSB to MSB, so B5G6R5 means five bits of blue starting
; at the LSB, then six bits of green, then five bits of red.
;TBD check to see if this value is correct.
COLOR_SHIFT equ 8
.586
.model flat
; Big seperating lines seperate code into span code
; and loop code. If span and loop are not going to
; end up being combined then it will be easy to
; seperate the code.
.data
; Need externs for all of the variables that are needed for various beads
EXTERN IncHighandLow16:MMWORD
EXTERN UFracVFracMask:MMWORD
EXTERN UV32to15Mask:MMWORD
EXTERN Makelow16one:MMWORD
EXTERN MaskKeepUValues:MMWORD
EXTERN MaskKeepVValues:MMWORD
EXTERN UFrac:MMWORD
EXTERN VFrac:MMWORD
EXTERN Zero:MMWORD
EXTERN memD3DTFG_POINT:MMWORD
EXTERN GiveUp:MMWORD
EXTERN LastW:MMWORD
EXTERN Val0x000a000a:MMWORD
EXTERN Val0xffff:MMWORD
EXTERN Val0x0000002000000020:MMWORD
EXTERN Val0x0000ffff0000ffff:MMWORD
EXTERN MaskRed565to888:MMWORD
EXTERN MaskGreen565to888:MMWORD
EXTERN MaskBlue565to888:MMWORD
EXTERN MaskRed555to888:MMWORD
EXTERN MaskGreen555to888:MMWORD
EXTERN MaskBlue555to888:MMWORD
EXTERN MaskAlpha1555to8888:MMWORD
EXTERN MaskRed1555to8888:MMWORD
EXTERN MaskGreen1555to8888:MMWORD
EXTERN MaskBlue1555to8888:MMWORD
; TBD. I think that I want to do 0xffff instead of 0xff. This will
; have to be checked. There is a value very similiar to this in
; buf write.
EXTERN SetAlphato0xffff:MMWORD
EXTERN SetAlphato0xff:MMWORD
; TODO This equate are identical to the ones in texread.mas. Maybe they should be in a common .inc file.
RedShift565to888 equ 8
GreenShift565to888 equ 5
BlueShift565to888 equ 3
RedShift555to888 equ 9
GreenShift555to888 equ 6
BlueShift555to888 equ 3
AlphaShift1555to8888 equ 16
RedShift1555to8888 equ 9
GreenShift1555to8888 equ 6
BlueShift1555to8888 equ 3
; BEGIN *** Lee Hamel code optimization ***
EXTERN BilinearMaskRed565to888:MMWORD
EXTERN BilinearMaskGreen565to888:MMWORD
EXTERN BilinearMaskBlue565to888:MMWORD
EXTERN BilinearShiftRed565to888:MMWORD
EXTERN BilinearShiftGreen565to888:MMWORD
EXTERN BilinearShiftBlue565to888:MMWORD
; END *** Lee Hamel code optimization ***
EXTERN Zero:MMWORD
EXTERN DW_One_One:MMWORD
EXTERN MaskOffAlpha:MMWORD
EXTERN ShiftTA:MMWORD
EXTERN Val0x00ff00ff00ff00ff:MMWORD
EXTERN Val0x000000ff00ff00ff:MMWORD
EXTERN Val0X0000000001000000:MMWORD
EXTERN AlphaVal128:MMWORD
EXTERN RGBVal128:MMWORD
EXTERN g_uDitherValue:MMWORD
EXTERN SetAlphato0xff:MMWORD
EXTERN u888to565RedBlueMask:MMWORD
EXTERN u888to565GreenMask:MMWORD
EXTERN u888to565Multiplier:MMWORD
EXTERN uVal0x000007ff03ff07ff:MMWORD
EXTERN uVal0x0000078003c00780:MMWORD
EXTERN u888to555RedBlueMask:MMWORD
EXTERN u888to555GreenMask:MMWORD
EXTERN u888to555Multiplier:MMWORD
EXTERN uVal0x000007ff07ff07ff:MMWORD
EXTERN uVal0x0000078007800780:MMWORD
;-----------------------------------------------------------------------------
; Span Variables
StackPos dd ?
uSpans dd ?
;-----------------------------------------------------------------------------
;-----------------------------------------------------------------------------
; Loop Variables
iSurfaceStep dd ?
iZStep dd ?
uPix dd ?
;-----------------------------------------------------------------------------
.code
PUBLIC _MMXMLRast_21
_MMXMLRast_21:
push ebp
mov StackPos, esp
mov eax, esp
sub esp, 0Ch ; This will need to change if stack frame size changes.
push ebx
push esi
push edi
; Put pCtx into ebx
mov ebx, [eax+8]
;PD3DI_RASTPRIM pP = pCtx->pPrim;
mov ecx, [ebx+RASTCTX_pPrim]
;while (pP)
;{
PrimLoop:
cmp ecx, 0
je ExitPrimLoop
;UINT16 uSpans = pP->uSpans;
movzx eax, word ptr [ecx+RASTPRIM_uSpans]
mov uSpans, eax
;PD3DI_RASTSPAN pS = (PD3DI_RASTSPAN)(pP + 1);
mov ebp, ecx
add ebp, SIZEOF_RASTPRIM
;while (uSpans-- > 0)
;{
SpanLoop:
mov edx, uSpans
mov eax, edx
dec eax
mov uSpans, eax
test edx, edx
jle ExitSpanLoop
;pCtx->pfnBegin(pCtx, pP, pS);
;-----------------------------------------------------------------------------
; LoopAny code inserted here. This is to get rid of an extra
; jump.
;-----------------------------------------------------------------------------
; Setup Code begins
; get values to iterate
;uPix = pS->uPix;
movzx eax, word ptr [ebp+RASTSPAN_uPix]
mov uPix, eax
;pCtx->SI.iDW = 0x0;
mov dword ptr [ebx+RASTCTX_SI+SPANITER_iDW], 0
mov esi, [ebp+RASTSPAN_iW]
movq mm5, MMWORD PTR [ebp+RASTSPAN_iUoW1]
;pCtx->SI.iUd_TexNum = d_WTimesUVoW(pS->iW,pS->iUoW1);
;pCtx->SI.iVd_TexNum = d_WTimesUVoW(pS->iW,pS->iVoW1);
pslld mm5, 8
shl esi, 4
movd eax, mm5
psrlq mm5, 32
imul esi
mov [ebx+RASTCTX_SI+SPANITER_iU1], edx
movd eax, mm5
imul esi
mov [ebx+RASTCTX_SI+SPANITER_iV1], edx
;if (pP->iDOoWDX > 0)
;{
cmp dword ptr [ecx+RASTPRIM_iDOoWDX], 0
jg SpecialWLastMonTest
;// iSpecialW should be negative for the first 3 pixels of span
;pCtx->SI.iSpecialW = -3;
mov word ptr [ebx+RASTCTX_SI+SPANITER_iSpecialW], -3
jmp DoneSpecialWifMonTest
;}
;else
;{
SpecialWLastMonTest:
;// iSpecialW should be negative for the last 3 pixels of span
;pCtx->SI.iSpecialW = 0x7fff - uPix;
mov eax, 07fffh
sub eax, uPix
;pCtx->SI.iSpecialW += 5; // this may wrap, but it should
add eax, 5
mov [ebx+RASTCTX_SI+SPANITER_iSpecialW], eax
;}
DoneSpecialWifMonTest:
;if (pP->uFlags & D3DI_RASTPRIM_X_DEC)
;{
mov eax, [ecx+RASTPRIM_uFlags]
and eax, D3DI_RASTPRIM_X_DEC
test eax, eax
jz LeftToRightSpan
;iZStep = -pCtx->iZStep;
mov eax, [ebx+RASTCTX_iZStep]
neg eax
mov iZStep, eax
;iSurfaceStep = -pCtx->iSurfaceStep;
mov eax, [ebx+RASTCTX_iSurfaceStep]
neg eax
mov iSurfaceStep, eax
;}
jmp DoneSpanDirif
;else
;{
LeftToRightSpan:
;iZStep = pCtx->iZStep;
mov eax, [ebx+RASTCTX_iZStep]
mov iZStep, eax
;iSurfaceStep = pCtx->iSurfaceStep;
mov eax, [ebx+RASTCTX_iSurfaceStep]
mov iSurfaceStep, eax
;}
DoneSpanDirif:
; Setup Code Ends
; ----------------------------------------------------------------------------------------------------------------
; Loop Code Begins
;//while (1)
;//{
PixelLoop:
; Ztestcode
; edx is uZ
; eax is uZB
; 16 bit unsigned format
;UINT16 uZ = (UINT16)(pS->uZ>>15);
;UINT16 uZB = *((UINT16*)pS->pZ);
mov edx, [ebp+RASTSPAN_uZ]
movd mm4, edx
mov esi, [ebp+RASTSPAN_pZ]
shr edx, 15
movzx eax, word ptr [esi]
;pS->uZ += pP->iDZDX;
;if ((pCtx->iZXorMask)^(uZ > uZB))
; !(uZ > uZB) <==>
; (uZ <= uZB) <==>
; (uZ < uZB+1) <==>
;
sub eax, edx
paddd mm4, [ecx+RASTPRIM_iDZDX]
movd [ebp+RASTSPAN_uZ], mm4
xor eax, [ebx+RASTCTX_iZXorMask]
test eax, eax
js FailLabel
mov word ptr [esi], dx
; texturecode
;---------------------------------------------------------------------------
;void Tex1Addr_TexAddrWrapMirror_Persp_Bilinear_NoMip(PD3DI_RASTCTX pCtx, PD3DI_RASTPRIM pP,
; PD3DI_RASTSPAN pS)
;{
;PD3DI_SPANTEX pTex = &pCtx->Texture[0];
mov esi, [ebx+RASTCTX_pTexture]
; ----------------------------------------
; Doing UV calculation a little more accurate
; Exactly like C code.
; I shift iU and iV to the right not by (TEX_FINAL_SHIFT - iShiftU0) but by
; (TEX_FINAL_SHIFT - iShiftU0 - 6). iShiftU0 = pTex->iShiftU - iLOD0
; (TEX_FINAL_SHIFT - (pTex->iShiftU - iLOD0))
; (TEX_FINAL_SHIFT + iLOD0 - pTex->iShiftU)
; COMMENT1**
; If textures have a max of 1024 then shiftU0 would be at most 10 which would
; make (TEXT_FINAL_SHIFT - iShiftU - 6) at most zero. This is why I choose 6
; It will also give bi-linear 6 bits of precision I think it was said that
; only five was needed.
;INT16 iShiftU0 = pTex->iShiftU - iLOD0;
;INT16 iShiftV0 = pTex->iShiftV - iLOD0;
movq mm5, MMWORD PTR Val0x000a000a ; This is TEX_FINAL_SHIFT - 6 = 10.
;iLOD0 is zero in monolithic case so no subtraction needed.
movd mm4, [esi+SPANTEX_iShiftU]
psubw mm5, mm4
movq mm4, mm5
pand mm5, MMWORD PTR Val0xffff
psrld mm4, 16
movd mm1, [ebx+RASTCTX_SI+SPANITER_iU1]
psrad mm1, mm5
movd mm2, [ebx+RASTCTX_SI+SPANITER_iV1]
psrad mm2, mm4
punpckldq mm1, mm2
psubd mm1, MMWORD PTR Val0x0000002000000020
; Texture Pitch cannot be calculated so it must be looked up in the iShiftPitch table
; ----------------- Start of hack
; ATTENTION This is really hacked right now. Just to get it working
; Pitch would be better for me, instead of shift pitch.
; With actual pitch, this would be two moves and a shift.
;shl eax, 1
movzx edx, word ptr [esi+SPANTEX_iShiftPitch]
add edx, 16
movd mm2, edx
movq mm5, MMWORD ptr Makelow16one
pslld mm5, mm2
;pslld mm5, 16 ;. Use this after hack.
; not needed in hacked version since i add to shifted value.
; ----------------- End of hack
por mm5, MMWORD ptr Makelow16one
; Make the low 16 bits of dword one
; This helps in calculating texture address.
; Gets U and V value into mm1 so that it can be mirrored, wrapped or
; clamped. This can be done for two values in the point case
; or four values in the bilinear case.
;INT32 iUFrac = iU00 & 0x03f;
;INT32 iVFrac = iV00 & 0x03f;
;iU00 >>= 6;
;iV00 >>= 6;
movq mm2, mm1
psrad mm1, 6
;pand mm1, MMWORD PTR Val0x0000ffff0000ffff
pand mm2, dword ptr UFracVFracMask ; UFracVFracMask = 0x0000003f0000003f
; Going to use only 8 bits for bi-linear so that I can do a pmullw.
; Currently at 6 bits so shift up by 2.
psllw mm2, 2
movq mm0, mm2
; Replicate VFrac value for bilinear
punpckhwd mm2, mm2
punpcklwd mm2, mm2
; Replicate UFrac Value for bilinear
punpcklwd mm0, mm0
punpcklwd mm0, mm0
movq dword ptr VFrac, mm2
movq dword ptr UFrac, mm0
;INT32 iU01 = iU00 + 1;
;INT32 iV01 = iV00 + 1;
packssdw mm1, mm1 ; replicate U and V value to upper 16 bit locations
paddw mm1, dword ptr IncHighandLow16
; This will make texture values be (High word to low word):
; iV01, iU00, iV00, iU01
; Need to do this to make texture look up for bilinear easier.
; I have to combine to get all combinations anyway. It just
; happens to be better for me to have iV00, iU01 pair first.
;UINT16 uMaskU0 = pTex->uMaskU >> iLOD0; UINT16 uMaskV0 = pTex->uMaskV >> iLOD0;
; put mask in mm3 and replicate to match location for wrap/mirror/clamp
movd mm0, [esi+SPANTEX_uMaskU] ; Load U and V mask
; replicate mask if doing bilinear
punpckldq mm0, mm0
;INT16 iFlip;
; MM1 should contain 16 bit iU and iV for both texture locations
; End Result is MM1 value wrapped or mirrored
; in Bilinear Case, four values can be done
; iU00, iV00, iU01, iV01
; This code really does alot for the bilinear case and is kinda wasteful
; in the normal mode.
;iU00 &= uMaskU0; ;iV00 &= uMaskV0; ;iU01 &= uMaskU0; ;iV01 &= uMaskV0;
pand mm1, mm0
; Result in mm1 now since TexAddrAll ends up that way.
; Making other two cases for texture addressing has to be simplier than
; this and not use so many registers. Puts U1 V0 U0 V1 into mm3.
; TBD Make this better.
; values are still stored as iV01, iU00, iV00, iU01
movq mm2, mm1
movq mm3, mm1
; Calculate 1st and 3rd texel addresses
pmaddwd mm1, mm5 ; Throw in first address calculation.
; values are being changed to iV01, iU01, iV00, iU00
; seven instructions for this seems excessive.
pand mm2, MMWORD ptr MaskKeepUValues
pand mm3, MMWORD ptr MaskKeepVValues
movq mm4, mm2
psllq mm2, 32
psrlq mm4, 32
por mm3, mm2
por mm3, mm4
; From here until mov edi is code that is needed for border.
; all sign bits are stored in bytes so that border code can tell if uv went below zero.
; Calculate 2nd and 4th texel addresses
pmaddwd mm3, mm5 ; Calculates iU1+iV0*iShiftU0 and iU0+iV1*iShiftU0
mov edi, [esi+SPANTEX_pBits]
;D3DCOLOR TexRead_B5G6R5_NoBorder(INT32 iU, INT32 iV, INT32 iShiftU, PUINT8 pBits, PD3DI_SPANTEX pTex)
;{
pxor mm2, mm2
; 1st (mm1) and 2nd (mm3) texel
movd eax, mm3 ; load 2nd texel address
movd mm4, dword ptr [edi+4*eax] ; mm4 = 2nd texel
movd eax, mm1 ; load 1st texel address
movd mm7, dword ptr [edi+4*eax] ; mm7 = 1st texel
; mm4 calculated from high 32 bits of mm3 (2nd texel)
; pad high 8 bits of each component with zeros because D3DCOLOR has 16
; bits for each color component
punpcklbw mm4, mm2
; mm7 calculated from low 32 bits of mm1 (1st texel)
; pad high 8 bits of each component with zeros because D3DCOLOR has 16
; bits for each color component
punpcklbw mm7, mm2
psrlq mm3, 32 ; shift 4th texel address into low 32 bits
; mm7 = final calc on 1st and 2nd texel
psubw mm7, mm4
psllw mm4, 8
pmullw mm7, dword ptr UFrac
paddw mm7, mm4
; 3rd (mm1) and 4th (mm3) texel
movd eax, mm3 ; load 4th texel address
psrlq mm1, 32 ; shift 3rd texel address into low 32 bits
movd mm6, dword ptr [edi+4*eax] ; mm6 = 4th texel
movd eax, mm1 ; load 3rd texel address
movd mm4, dword ptr [edi+4*eax] ; mm4 = 3rd texel
; mm6 = 4th texel (high 32 bits), 3rd texel (low 32 bits)
; mm4 calculated from high 32 bits of mm3 (4th texel)
; pad high 8 bits of each component with zeros because D3DCOLOR has 16
; bits for each color component
punpcklbw mm4, mm2
; mm6 calculated from low 32 bits of mm1 (3rd texel)
; pad high 8 bits of each component with zeros because D3DCOLOR has 16
; bits for each color component
punpcklbw mm6, mm2
psubw mm6, mm4
psllw mm4, 8
pmullw mm6, dword ptr UFrac
movq mm1, mm7
; mm6 = final calc on 3rd and 4th texel
paddw mm6, mm4
; mm1 = final calc on 1st+2nd texel and 3rd+4th texel
psrlw mm6, 8
psrlw mm7, 8
psubw mm6, mm7
pmullw mm6, dword ptr VFrac
paddw mm1, mm6
psrlw mm1, 8
;modulate
;UINT16 uB = pS->uB>>COLOR_SHIFT;
;UINT16 uG = pS->uG>>COLOR_SHIFT;
;UINT16 uR = pS->uR>>COLOR_SHIFT;
movq mm4, [ebp+RASTSPAN_uB]
psrlw mm4, COLOR_SHIFT ; COLOR_SHIFT is set to 8.
;UINT16 uTB = (UINT16)(RGBA_GETBLUE(pCtx->SI.TexCol[0]));
;UINT16 uTG = (UINT16)(RGBA_GETGREEN(pCtx->SI.TexCol[0]));
;UINT16 uTR = (UINT16)(RGBA_GETRED(pCtx->SI.TexCol[0]));
;UINT16 uTA = (UINT16)(RGBA_GETALPHA(pCtx->SI.TexCol[0]));
; this is a PMULLW, which works on unsigned 16 bit quantities
;pCtx->SI.uBB = uB*uTB;
;pCtx->SI.uBG = uG*uTG;
;pCtx->SI.uBR = uR*uTR;
;pCtx->SI.uBA = uTA<<COLOR_SHIFT;
pmullw mm4, mm1
; write
;*(PUINT16)pS->pSurface =
; ((pCtx->SI.uBR >> 0) & 0xf800) |
; ((pCtx->SI.uBG >> 5) & 0x07e0) |
; ((pCtx->SI.uBB >> 11) & 0x001f);
mov edi, [ebp+RASTSPAN_pSurface]
psrlw mm4, 8 ; Convert color1 from 8.8 two 0.8
packuswb mm4, mm7 ; pack one color
movd edx, mm4
and edx, 000ffffffh
mov [edi], edx
FailLabel:
;//if (--uPix <= 0)
;// break;
dec uPix ;// BUG BUG?? uPix should never start as zero should it?
;// if so, this is a bug.
jle ExitPixelLoop
; Doing update code after span length test so that an extra update is not done.
;void TestFail_Gouraud_PerspTex1_NoSpecularFog(PD3DI_RASTCTX pCtx, PD3DI_RASTPRIM pP,
; PD3DI_RASTSPAN pS)
;{
;pS->uB += pP->iDBDX; pS->uG += pP->iDGDX;
;pS->uR += pP->iDRDX; pS->uA += pP->iDADX;
movq mm1, [ebp+RASTSPAN_uB]
paddw mm1, [ecx+RASTPRIM_iDBDX]
movq [ebp+RASTSPAN_uB], mm1
;pS->iUoW1 += pP->iDUoW1DX;
;pS->iVoW1 += pP->iDVoW1DX;
movq mm5, [ebp+RASTSPAN_iUoW1]
paddd mm5, [ecx+RASTPRIM_iDUoW1DX]
movq [ebp+RASTSPAN_iUoW1], mm5
;pS->iOoW += pP->iDOoWDX;
mov eax, [ebp+RASTSPAN_iOoW]
add eax, [ecx+RASTPRIM_iDOoWDX]
mov [ebp+RASTSPAN_iOoW], eax
;INT32 iWn0 = pS->iW + pCtx->SI.iDW; // 1.15.16
; TODO Could do this and OoW Add at same time with MMX.
mov edx, [ebp+RASTSPAN_iW]
mov LastW, edx ; Save iW to calc iDW for next time.
add edx, [ebx+RASTCTX_SI+SPANITER_iDW]
;if (pCtx->SI.iSpecialW < 0)
;{
xor edi, edi
cmp di, word ptr [ebx+RASTCTX_SI+SPANITER_iSpecialW]
jle DontDoSpecialW1
;DoSpecialW1:
; This label is a left over from when
;if (iWn0 < 0)
;{
cmp edx, edi
jl WOutOfRange1
;iWn0 = pS->iW >> 1; // use iW/2 as a guess, instead
mov edx, LastW
sar edx, 1
;}
WOutOfRange1:
;VAL32 iWn1;
;INT16 iWnOld = iWn0 + 0x100; // make sure while fails first time
; Dont need to make sure it fails. I do a post test which guarentees it will execute once.
;INT32 iGiveUp = 7;
mov GiveUp, 8 ; Pre decrementing instead of post decrementing.
;while((abs(iWnOld - iWn0) > 0x20) && (iGiveUp-- > 0))
;{
SpecW1Loop1:
; Could move this to bottom of loop and combine results somehow.
; TBD look at it more.
dec GiveUp
jz ExitSpecWLoop1
; Shift iOoW by one since imul cannot have sign bit set
; OoW cannot reach one, only 0x7fffffff
;shr eax, 1 ; 1.31 >> 1 = 1.30
; Get ready to do Two minus iOoW*iW
mov esi, (1 SHL 16)
;iWnOld = iWn0;
mov edi, edx
; Result should be close to one so we want most of the
; precision in the low bits. Need to give more bits
; leaway since these are the bad cases.
; iWn1 = imul32h(pS->iOoW, iWn0); // 1.31*1.15.16 = 1.16.47 >> 32 = 1.16.15
imul edx
;iWn1 = (1L<<16) - iWn1; // 2.0 - iWn1
sub esi, edx
;while(iWn1.i < 0)
;{
SpecW1Loop2:
test esi, esi
jns SpecW1ExitLoop2 ; This jump should be predicted correctly most of the time.
;iWn1=(iWn1+(1L<<15))>>1; // iWn1 = (iWn1 + 1.0)/2
add esi, (1 SHL 15)
sar esi, 1
jmp SpecW1Loop2
;}
SpecW1ExitLoop2:
;iWn1 <<= 15; // 1.16.15 << 15 = 1.1.30
mov eax, edi
shl eax, 5 ; 1.15.16 << 5 = 1.10.21 TBD Can I shift off upper bits??
shl esi, 12 ; 4.15 << 12 = 4.27 ;
;iWn0 = imul32h(iWn1, iWn0)<<2; // 1.1.30 * 1.15.16 = 1.17.46 >> 32 = 1.17.14 << 2 = 1.15.16
; Actually 4.27 * 1.10.21 = 1.14.48 >> 32 = 1.14.16. No need for post shift.
mul esi
; Have to do (abs(iWnOld - iWn0) > 0x20) code here.
sub edi, edx
; These four lines are abs code.
mov eax, edi
sar eax, 31
xor edi, eax
sub edi, eax
cmp edi, 020h ;Assuming that loop will only happen once.
jbe ExitSpecWLoop1
; Reload eax with iOoW.
mov eax, [ebp+RASTSPAN_iOoW]
jmp SpecW1Loop1
;}
;else
;{
DontDoSpecialW1:
; Everything should be positive in Non-SpecialW case.
;INT32 iWn1;
mov esi, (1 SHL 16)
mov edi, edx
; This should be close to one so Low bits are most important.
;iWn1 = (iOoW*iWn0)>>15; // 1.31*0.15.16 == 0.16.47 >> 32 = 0.16.15
mul edx
;iWn1 = (1L<<16) - iWn1; // 2.0 - iWn1
sub esi, edx
;iWn1 <<= 15; // 1.16.15 << 15 = 1.1.30
shl esi, 15 ; 0.16.15 << 15 = 0.2.30
mov eax, esi
;iWn0 = imul32h(iWn1, iWn0)<<2; // 1.1.30 * 1.15.16 = 1.17.46 >> 32 = 1.17.14 << 2 = 1.15.16
mul edi ; 0.2.30 * 1.15.16 = 1.17.46 >> 32 = 1.17.14
shl edx, 2 ; 1.17.14 << 2 = 1.15.16
;}
;}
ExitSpecWLoop1:
;pCtx->SI.iDW = iWn0 - (UINT16)pS->iW;
;pS->iW = iWn0;
mov [ebp+RASTSPAN_iW], edx
mov esi, edx ; Save W for multiplying by UoW and VoW
sub edx, LastW
mov [ebx+RASTCTX_SI+SPANITER_iDW], edx
;pCtx->SI.iSpecialW += 1; // this is supposed to wrap past 0x7fff sometimes
inc word ptr [ebx+RASTCTX_SI+SPANITER_iSpecialW]
;pCtx->SI.iU1 = d_WTimesUVoW(pS->iW,pS->iUoW1);
;pCtx->SI.iV1 = d_WTimesUVoW(pS->iW,pS->iVoW1);
pslld mm5, 8
shl esi, 4
movd eax, mm5
psrlq mm5, 32
imul esi
mov [ebx+RASTCTX_SI+SPANITER_iU1], edx
movd eax, mm5
imul esi
mov [ebx+RASTCTX_SI+SPANITER_iV1], edx
;//pS->pZ += iZStep;
;//pS->pSurface += iSurfaceStep;
mov eax, dword ptr [ebp+RASTSPAN_pZ]
mov edx, dword ptr [ebp+RASTSPAN_pSurface]
add eax, iZStep
add edx, iSurfaceStep
mov dword ptr [ebp+RASTSPAN_pZ], eax
mov dword ptr [ebp+RASTSPAN_pSurface], edx
;#ifdef DBG
;// handy for debug to see where we are
;//pS->uX += (INT16)pCtx->SI.iXStep;
;#endif
;// } // while
jmp PixelLoop
ExitPixelLoop:
; Loop code ends
;-----------------------------------------------------------------------------
; LoopAny code ends here
;-----------------------------------------------------------------------------
;pS++;
add ebp, SIZEOF_RASTSPAN
;}
jmp SpanLoop
ExitSpanLoop:
;pP = pP->pNext;
mov ecx, [ecx+RASTPRIM_pNext]
;}
jmp PrimLoop
ExitPrimLoop:
;_asm{
emms
;}
;return S_OK;
xor eax, eax
;}
pop edi
pop esi
pop ebx
mov esp, StackPos
pop ebp
ret
END