.386P .model FLAT ; ; d_draw16.s ; x86 assembly-language horizontal 8-bpp span-drawing code, with 16-pixel ; subdivision. ; include qasm.inc include d_if.inc if id386 ;---------------------------------------------------------------------- ; 8-bpp horizontal span drawing code for polygons, with no transparency and ; 16-pixel subdivision. ; ; Assumes there is at least one span in pspans, and that every span ; contains at least one pixel ;---------------------------------------------------------------------- _DATA SEGMENT _DATA ENDS _TEXT SEGMENT ; out-of-line, rarely-needed clamping code LClampHigh0: mov esi,ds:dword ptr[_bbextents] jmp LClampReentry0 LClampHighOrLow0: jg LClampHigh0 xor esi,esi jmp LClampReentry0 LClampHigh1: mov edx,ds:dword ptr[_bbextentt] jmp LClampReentry1 LClampHighOrLow1: jg LClampHigh1 xor edx,edx jmp LClampReentry1 LClampLow2: mov ebp,4096 jmp LClampReentry2 LClampHigh2: mov ebp,ds:dword ptr[_bbextents] jmp LClampReentry2 LClampLow3: mov ecx,4096 jmp LClampReentry3 LClampHigh3: mov ecx,ds:dword ptr[_bbextentt] jmp LClampReentry3 LClampLow4: mov eax,4096 jmp LClampReentry4 LClampHigh4: mov eax,ds:dword ptr[_bbextents] jmp LClampReentry4 LClampLow5: mov ebx,4096 jmp LClampReentry5 LClampHigh5: mov ebx,ds:dword ptr[_bbextentt] jmp LClampReentry5 pspans equ 4+16 align 4 public _D_DrawSpans16 _D_DrawSpans16: push ebp ; preserve caller's stack frame push edi push esi ; preserve register variables push ebx ; ; set up scaled-by-16 steps, for 16-long segments; also set up cacheblock ; and span list pointers ; ; TODO: any overlap from rearranging? fld ds:dword ptr[_d_sdivzstepu] fmul ds:dword ptr[fp_16] mov edx,ds:dword ptr[_cacheblock] fld ds:dword ptr[_d_tdivzstepu] fmul ds:dword ptr[fp_16] mov ebx,ds:dword ptr[pspans+esp] ; point to the first span descriptor fld ds:dword ptr[_d_zistepu] fmul ds:dword ptr[fp_16] mov ds:dword ptr[pbase],edx ; pbase = cacheblock fstp ds:dword ptr[zi16stepu] fstp ds:dword ptr[tdivz16stepu] fstp ds:dword ptr[sdivz16stepu] LSpanLoop: ; ; set up the initial s/z, t/z, and 1/z on the FP stack, and generate the ; initial s and t values ; ; FIXME: pipeline FILD? fild ds:dword ptr[espan_t_v+ebx] fild ds:dword ptr[espan_t_u+ebx] fld st(1) ; dv | du | dv fmul ds:dword ptr[_d_sdivzstepv] ; dv*d_sdivzstepv | du | dv fld st(1) ; du | dv*d_sdivzstepv | du | dv fmul ds:dword ptr[_d_sdivzstepu] ; du*d_sdivzstepu | dv*d_sdivzstepv | du | dv fld st(2) ; du | du*d_sdivzstepu | dv*d_sdivzstepv | du | dv fmul ds:dword ptr[_d_tdivzstepu] ; du*d_tdivzstepu | du*d_sdivzstepu | ; dv*d_sdivzstepv | du | dv fxch st(1) ; du*d_sdivzstepu | du*d_tdivzstepu | ; dv*d_sdivzstepv | du | dv faddp st(2),st(0) ; du*d_tdivzstepu | ; du*d_sdivzstepu + dv*d_sdivzstepv | du | dv fxch st(1) ; du*d_sdivzstepu + dv*d_sdivzstepv | ; du*d_tdivzstepu | du | dv fld st(3) ; dv | du*d_sdivzstepu + dv*d_sdivzstepv | ; du*d_tdivzstepu | du | dv fmul ds:dword ptr[_d_tdivzstepv] ; dv*d_tdivzstepv | ; du*d_sdivzstepu + dv*d_sdivzstepv | ; du*d_tdivzstepu | du | dv fxch st(1) ; du*d_sdivzstepu + dv*d_sdivzstepv | ; dv*d_tdivzstepv | du*d_tdivzstepu | du | dv fadd ds:dword ptr[_d_sdivzorigin] ; sdivz = d_sdivzorigin + dv*d_sdivzstepv + ; du*d_sdivzstepu; stays in %st(2) at end fxch st(4) ; dv | dv*d_tdivzstepv | du*d_tdivzstepu | du | ; s/z fmul ds:dword ptr[_d_zistepv] ; dv*d_zistepv | dv*d_tdivzstepv | ; du*d_tdivzstepu | du | s/z fxch st(1) ; dv*d_tdivzstepv | dv*d_zistepv | ; du*d_tdivzstepu | du | s/z faddp st(2),st(0) ; dv*d_zistepv | ; dv*d_tdivzstepv + du*d_tdivzstepu | du | s/z fxch st(2) ; du | dv*d_tdivzstepv + du*d_tdivzstepu | ; dv*d_zistepv | s/z fmul ds:dword ptr[_d_zistepu] ; du*d_zistepu | ; dv*d_tdivzstepv + du*d_tdivzstepu | ; dv*d_zistepv | s/z fxch st(1) ; dv*d_tdivzstepv + du*d_tdivzstepu | ; du*d_zistepu | dv*d_zistepv | s/z fadd ds:dword ptr[_d_tdivzorigin] ; tdivz = d_tdivzorigin + dv*d_tdivzstepv + ; du*d_tdivzstepu; stays in %st(1) at end fxch st(2) ; dv*d_zistepv | du*d_zistepu | t/z | s/z faddp st(1),st(0) ; dv*d_zistepv + du*d_zistepu | t/z | s/z fld ds:dword ptr[fp_64k] ; fp_64k | dv*d_zistepv + du*d_zistepu | t/z | s/z fxch st(1) ; dv*d_zistepv + du*d_zistepu | fp_64k | t/z | s/z fadd ds:dword ptr[_d_ziorigin] ; zi = d_ziorigin + dv*d_zistepv + ; du*d_zistepu; stays in %st(0) at end ; 1/z | fp_64k | t/z | s/z ; ; calculate and clamp s & t ; fdiv st(1),st(0) ; 1/z | z*64k | t/z | s/z ; ; point %edi to the first pixel in the span ; mov ecx,ds:dword ptr[_d_viewbuffer] mov eax,ds:dword ptr[espan_t_v+ebx] mov ds:dword ptr[pspantemp],ebx ; preserve spans pointer mov edx,ds:dword ptr[_tadjust] mov esi,ds:dword ptr[_sadjust] mov edi,ds:dword ptr[_d_scantable+eax*4] ; v * screenwidth add edi,ecx mov ecx,ds:dword ptr[espan_t_u+ebx] add edi,ecx ; pdest = &pdestspan[scans->u]; mov ecx,ds:dword ptr[espan_t_count+ebx] ; ; now start the FDIV for the end of the span ; cmp ecx,16 ja LSetupNotLast1 dec ecx jz LCleanup1 ; if only one pixel, no need to start an FDIV mov ds:dword ptr[spancountminus1],ecx ; finish up the s and t calcs fxch st(1) ; z*64k | 1/z | t/z | s/z fld st(0) ; z*64k | z*64k | 1/z | t/z | s/z fmul st(0),st(4) ; s | z*64k | 1/z | t/z | s/z fxch st(1) ; z*64k | s | 1/z | t/z | s/z fmul st(0),st(3) ; t | s | 1/z | t/z | s/z fxch st(1) ; s | t | 1/z | t/z | s/z fistp ds:dword ptr[s] ; 1/z | t | t/z | s/z fistp ds:dword ptr[t] ; 1/z | t/z | s/z fild ds:dword ptr[spancountminus1] fld ds:dword ptr[_d_tdivzstepu] ; C(d_tdivzstepu) | spancountminus1 fld ds:dword ptr[_d_zistepu] ; C(d_zistepu) | C(d_tdivzstepu) | spancountminus1 fmul st(0),st(2) ; C(d_zistepu)*scm1 | C(d_tdivzstepu) | scm1 fxch st(1) ; C(d_tdivzstepu) | C(d_zistepu)*scm1 | scm1 fmul st(0),st(2) ; C(d_tdivzstepu)*scm1 | C(d_zistepu)*scm1 | scm1 fxch st(2) ; scm1 | C(d_zistepu)*scm1 | C(d_tdivzstepu)*scm1 fmul ds:dword ptr[_d_sdivzstepu] ; C(d_sdivzstepu)*scm1 | C(d_zistepu)*scm1 | ; C(d_tdivzstepu)*scm1 fxch st(1) ; C(d_zistepu)*scm1 | C(d_sdivzstepu)*scm1 | ; C(d_tdivzstepu)*scm1 faddp st(3),st(0) ; C(d_sdivzstepu)*scm1 | C(d_tdivzstepu)*scm1 fxch st(1) ; C(d_tdivzstepu)*scm1 | C(d_sdivzstepu)*scm1 faddp st(3),st(0) ; C(d_sdivzstepu)*scm1 faddp st(3),st(0) fld ds:dword ptr[fp_64k] fdiv st(0),st(1) ; this is what we've gone to all this trouble to ; overlap jmp LFDIVInFlight1 LCleanup1: ; finish up the s and t calcs fxch st(1) ; z*64k | 1/z | t/z | s/z fld st(0) ; z*64k | z*64k | 1/z | t/z | s/z fmul st(0),st(4) ; s | z*64k | 1/z | t/z | s/z fxch st(1) ; z*64k | s | 1/z | t/z | s/z fmul st(0),st(3) ; t | s | 1/z | t/z | s/z fxch st(1) ; s | t | 1/z | t/z | s/z fistp ds:dword ptr[s] ; 1/z | t | t/z | s/z fistp ds:dword ptr[t] ; 1/z | t/z | s/z jmp LFDIVInFlight1 align 4 LSetupNotLast1: ; finish up the s and t calcs fxch st(1) ; z*64k | 1/z | t/z | s/z fld st(0) ; z*64k | z*64k | 1/z | t/z | s/z fmul st(0),st(4) ; s | z*64k | 1/z | t/z | s/z fxch st(1) ; z*64k | s | 1/z | t/z | s/z fmul st(0),st(3) ; t | s | 1/z | t/z | s/z fxch st(1) ; s | t | 1/z | t/z | s/z fistp ds:dword ptr[s] ; 1/z | t | t/z | s/z fistp ds:dword ptr[t] ; 1/z | t/z | s/z fadd ds:dword ptr[zi16stepu] fxch st(2) fadd ds:dword ptr[sdivz16stepu] fxch st(2) fld ds:dword ptr[tdivz16stepu] faddp st(2),st(0) fld ds:dword ptr[fp_64k] fdiv st(0),st(1) ; z = 1/1/z ; this is what we've gone to all this trouble to ; overlap LFDIVInFlight1: add esi,ds:dword ptr[s] add edx,ds:dword ptr[t] mov ebx,ds:dword ptr[_bbextents] mov ebp,ds:dword ptr[_bbextentt] cmp esi,ebx ja LClampHighOrLow0 LClampReentry0: mov ds:dword ptr[s],esi mov ebx,ds:dword ptr[pbase] shl esi,16 cmp edx,ebp mov ds:dword ptr[sfracf],esi ja LClampHighOrLow1 LClampReentry1: mov ds:dword ptr[t],edx mov esi,ds:dword ptr[s] ; sfrac = scans->sfrac; shl edx,16 mov eax,ds:dword ptr[t] ; tfrac = scans->tfrac; sar esi,16 mov ds:dword ptr[tfracf],edx ; ; calculate the texture starting address ; sar eax,16 mov edx,ds:dword ptr[_cachewidth] imul eax,edx ; (tfrac >> 16) * cachewidth add esi,ebx add esi,eax ; psource = pbase + (sfrac >> 16) + ; ((tfrac >> 16) * cachewidth); ; ; determine whether last span or not ; cmp ecx,16 jna LLastSegment ; ; not the last segment; do full 16-wide segment ; LNotLastSegment: ; ; advance s/z, t/z, and 1/z, and calculate s & t at end of span and steps to ; get there ; ; pick up after the FDIV that was left in flight previously fld st(0) ; duplicate it fmul st(0),st(4) ; s = s/z * z fxch st(1) fmul st(0),st(3) ; t = t/z * z fxch st(1) fistp ds:dword ptr[snext] fistp ds:dword ptr[tnext] mov eax,ds:dword ptr[snext] mov edx,ds:dword ptr[tnext] mov bl,ds:byte ptr[esi] ; get first source texel sub ecx,16 ; count off this segments' pixels mov ebp,ds:dword ptr[_sadjust] mov ds:dword ptr[counttemp],ecx ; remember count of remaining pixels mov ecx,ds:dword ptr[_tadjust] mov ds:byte ptr[edi],bl ; store first dest pixel add ebp,eax add ecx,edx mov eax,ds:dword ptr[_bbextents] mov edx,ds:dword ptr[_bbextentt] cmp ebp,4096 jl LClampLow2 cmp ebp,eax ja LClampHigh2 LClampReentry2: cmp ecx,4096 jl LClampLow3 cmp ecx,edx ja LClampHigh3 LClampReentry3: mov ds:dword ptr[snext],ebp mov ds:dword ptr[tnext],ecx sub ebp,ds:dword ptr[s] sub ecx,ds:dword ptr[t] ; ; set up advancetable ; mov eax,ecx mov edx,ebp sar eax,20 ; tstep >>= 16; jz LZero sar edx,20 ; sstep >>= 16; mov ebx,ds:dword ptr[_cachewidth] imul eax,ebx jmp LSetUp1 LZero: sar edx,20 ; sstep >>= 16; mov ebx,ds:dword ptr[_cachewidth] LSetUp1: add eax,edx ; add in sstep ; (tstep >> 16) * cachewidth + (sstep >> 16); mov edx,ds:dword ptr[tfracf] mov ds:dword ptr[advancetable+4],eax ; advance base in t add eax,ebx ; ((tstep >> 16) + 1) * cachewidth + ; (sstep >> 16); shl ebp,12 ; left-justify sstep fractional part mov ebx,ds:dword ptr[sfracf] shl ecx,12 ; left-justify tstep fractional part mov ds:dword ptr[advancetable],eax ; advance extra in t mov ds:dword ptr[tstep],ecx add edx,ecx ; advance tfrac fractional part by tstep frac sbb ecx,ecx ; turn tstep carry into -1 (0 if none) add ebx,ebp ; advance sfrac fractional part by sstep frac adc esi,ds:dword ptr[advancetable+4+ecx*4] ; point to next source texel add edx,ds:dword ptr[tstep] sbb ecx,ecx mov al,ds:byte ptr[esi] add ebx,ebp mov ds:byte ptr[1+edi],al adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[2+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[3+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[4+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[5+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[6+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[7+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] ; ; start FDIV for end of next segment in flight, so it can overlap ; mov ecx,ds:dword ptr[counttemp] cmp ecx,16 ; more than one segment after this? ja LSetupNotLast2 ; yes dec ecx jz LFDIVInFlight2 ; if only one pixel, no need to start an FDIV mov ds:dword ptr[spancountminus1],ecx fild ds:dword ptr[spancountminus1] fld ds:dword ptr[_d_zistepu] ; C(d_zistepu) | spancountminus1 fmul st(0),st(1) ; C(d_zistepu)*scm1 | scm1 fld ds:dword ptr[_d_tdivzstepu] ; C(d_tdivzstepu) | C(d_zistepu)*scm1 | scm1 fmul st(0),st(2) ; C(d_tdivzstepu)*scm1 | C(d_zistepu)*scm1 | scm1 fxch st(1) ; C(d_zistepu)*scm1 | C(d_tdivzstepu)*scm1 | scm1 faddp st(3),st(0) ; C(d_tdivzstepu)*scm1 | scm1 fxch st(1) ; scm1 | C(d_tdivzstepu)*scm1 fmul ds:dword ptr[_d_sdivzstepu] ; C(d_sdivzstepu)*scm1 | C(d_tdivzstepu)*scm1 fxch st(1) ; C(d_tdivzstepu)*scm1 | C(d_sdivzstepu)*scm1 faddp st(3),st(0) ; C(d_sdivzstepu)*scm1 fld ds:dword ptr[fp_64k] ; 64k | C(d_sdivzstepu)*scm1 fxch st(1) ; C(d_sdivzstepu)*scm1 | 64k faddp st(4),st(0) ; 64k fdiv st(0),st(1) ; this is what we've gone to all this trouble to ; overlap jmp LFDIVInFlight2 align 4 LSetupNotLast2: fadd ds:dword ptr[zi16stepu] fxch st(2) fadd ds:dword ptr[sdivz16stepu] fxch st(2) fld ds:dword ptr[tdivz16stepu] faddp st(2),st(0) fld ds:dword ptr[fp_64k] fdiv st(0),st(1) ; z = 1/1/z ; this is what we've gone to all this trouble to ; overlap LFDIVInFlight2: mov ds:dword ptr[counttemp],ecx add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[8+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[9+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[10+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[11+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[12+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[13+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[14+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edi,16 mov ds:dword ptr[tfracf],edx mov edx,ds:dword ptr[snext] mov ds:dword ptr[sfracf],ebx mov ebx,ds:dword ptr[tnext] mov ds:dword ptr[s],edx mov ds:dword ptr[t],ebx mov ecx,ds:dword ptr[counttemp] ; retrieve count ; ; determine whether last span or not ; cmp ecx,16 ; are there multiple segments remaining? mov ds:byte ptr[-1+edi],al ja LNotLastSegment ; yes ; ; last segment of scan ; LLastSegment: ; ; advance s/z, t/z, and 1/z, and calculate s & t at end of span and steps to ; get there. The number of pixels left is variable, and we want to land on the ; last pixel, not step one past it, so we can't run into arithmetic problems ; test ecx,ecx jz LNoSteps ; just draw the last pixel and we're done ; pick up after the FDIV that was left in flight previously fld st(0) ; duplicate it fmul st(0),st(4) ; s = s/z * z fxch st(1) fmul st(0),st(3) ; t = t/z * z fxch st(1) fistp ds:dword ptr[snext] fistp ds:dword ptr[tnext] mov al,ds:byte ptr[esi] ; load first texel in segment mov ebx,ds:dword ptr[_tadjust] mov ds:byte ptr[edi],al ; store first pixel in segment mov eax,ds:dword ptr[_sadjust] add eax,ds:dword ptr[snext] add ebx,ds:dword ptr[tnext] mov ebp,ds:dword ptr[_bbextents] mov edx,ds:dword ptr[_bbextentt] cmp eax,4096 jl LClampLow4 cmp eax,ebp ja LClampHigh4 LClampReentry4: mov ds:dword ptr[snext],eax cmp ebx,4096 jl LClampLow5 cmp ebx,edx ja LClampHigh5 LClampReentry5: cmp ecx,1 ; don't bother je LOnlyOneStep ; if two pixels in segment, there's only one step, ; of the segment length sub eax,ds:dword ptr[s] sub ebx,ds:dword ptr[t] add eax,eax ; convert to 15.17 format so multiply by 1.31 add ebx,ebx ; reciprocal yields 16.48 imul ds:dword ptr[reciprocal_table_16-8+ecx*4] ; sstep = (snext - s) / ; (spancount-1) mov ebp,edx mov eax,ebx imul ds:dword ptr[reciprocal_table_16-8+ecx*4] ; tstep = (tnext - t) / ; (spancount-1) LSetEntryvec: ; ; set up advancetable ; mov ebx,ds:dword ptr[entryvec_table_16+ecx*4] mov eax,edx mov ds:dword ptr[jumptemp],ebx ; entry point into code for RET later mov ecx,ebp sar edx,16 ; tstep >>= 16; mov ebx,ds:dword ptr[_cachewidth] sar ecx,16 ; sstep >>= 16; imul edx,ebx add edx,ecx ; add in sstep ; (tstep >> 16) * cachewidth + (sstep >> 16); mov ecx,ds:dword ptr[tfracf] mov ds:dword ptr[advancetable+4],edx ; advance base in t add edx,ebx ; ((tstep >> 16) + 1) * cachewidth + ; (sstep >> 16); shl ebp,16 ; left-justify sstep fractional part mov ebx,ds:dword ptr[sfracf] shl eax,16 ; left-justify tstep fractional part mov ds:dword ptr[advancetable],edx ; advance extra in t mov ds:dword ptr[tstep],eax mov edx,ecx add edx,eax sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] jmp dword ptr[jumptemp] ; jump to the number-of-pixels handler ;---------------------------------------- LNoSteps: mov al,ds:byte ptr[esi] ; load first texel in segment sub edi,15 ; adjust for hardwired offset jmp LEndSpan LOnlyOneStep: sub eax,ds:dword ptr[s] sub ebx,ds:dword ptr[t] mov ebp,eax mov edx,ebx jmp LSetEntryvec ;---------------------------------------- public Entry2_16, Entry3_16, Entry4_16, Entry5_16 public Entry6_16, Entry7_16, Entry8_16, Entry9_16 public Entry10_16, Entry11_16, Entry12_16, Entry13_16 public Entry14_16, Entry15_16, Entry16_16 Entry2_16: sub edi,14 ; adjust for hardwired offsets mov al,ds:byte ptr[esi] jmp LEntry2_16 ;---------------------------------------- Entry3_16: sub edi,13 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] jmp LEntry3_16 ;---------------------------------------- Entry4_16: sub edi,12 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry4_16 ;---------------------------------------- Entry5_16: sub edi,11 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry5_16 ;---------------------------------------- Entry6_16: sub edi,10 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry6_16 ;---------------------------------------- Entry7_16: sub edi,9 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry7_16 ;---------------------------------------- Entry8_16: sub edi,8 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry8_16 ;---------------------------------------- Entry9_16: sub edi,7 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry9_16 ;---------------------------------------- Entry10_16: sub edi,6 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry10_16 ;---------------------------------------- Entry11_16: sub edi,5 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry11_16 ;---------------------------------------- Entry12_16: sub edi,4 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry12_16 ;---------------------------------------- Entry13_16: sub edi,3 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry13_16 ;---------------------------------------- Entry14_16: sub edi,2 ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry14_16 ;---------------------------------------- Entry15_16: dec edi ; adjust for hardwired offsets add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] jmp LEntry15_16 ;---------------------------------------- Entry16_16: add edx,eax mov al,ds:byte ptr[esi] sbb ecx,ecx add ebx,ebp adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] sbb ecx,ecx mov ds:byte ptr[1+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry15_16: sbb ecx,ecx mov ds:byte ptr[2+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry14_16: sbb ecx,ecx mov ds:byte ptr[3+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry13_16: sbb ecx,ecx mov ds:byte ptr[4+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry12_16: sbb ecx,ecx mov ds:byte ptr[5+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry11_16: sbb ecx,ecx mov ds:byte ptr[6+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry10_16: sbb ecx,ecx mov ds:byte ptr[7+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry9_16: sbb ecx,ecx mov ds:byte ptr[8+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry8_16: sbb ecx,ecx mov ds:byte ptr[9+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry7_16: sbb ecx,ecx mov ds:byte ptr[10+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry6_16: sbb ecx,ecx mov ds:byte ptr[11+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry5_16: sbb ecx,ecx mov ds:byte ptr[12+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] add edx,ds:dword ptr[tstep] LEntry4_16: sbb ecx,ecx mov ds:byte ptr[13+edi],al add ebx,ebp mov al,ds:byte ptr[esi] adc esi,ds:dword ptr[advancetable+4+ecx*4] LEntry3_16: mov ds:byte ptr[14+edi],al mov al,ds:byte ptr[esi] LEntry2_16: LEndSpan: ; ; clear s/z, t/z, 1/z from FP stack ; fstp st(0) fstp st(0) fstp st(0) mov ebx,ds:dword ptr[pspantemp] ; restore spans pointer mov ebx,ds:dword ptr[espan_t_pnext+ebx] ; point to next span test ebx,ebx ; any more spans? mov ds:byte ptr[15+edi],al jnz LSpanLoop ; more spans pop ebx ; restore register variables pop esi pop edi pop ebp ; restore the caller's stack frame ret ;---------------------------------------------------------------------- ; 8-bpp horizontal span z drawing codefor polygons, with no transparency. ; ; Assumes there is at least one span in pzspans, and that every span ; contains at least one pixel ;---------------------------------------------------------------------- ; z-clamp on a non-negative gradient span LClamp: mov edx,040000000h xor ebx,ebx fstp st(0) jmp LZDraw ; z-clamp on a negative gradient span LClampNeg: mov edx,040000000h xor ebx,ebx fstp st(0) jmp LZDrawNeg pzspans equ 4+16 public _D_DrawZSpans _D_DrawZSpans: push ebp ; preserve caller's stack frame push edi push esi ; preserve register variables push ebx fld ds:dword ptr[_d_zistepu] mov eax,ds:dword ptr[_d_zistepu] mov esi,ds:dword ptr[pzspans+esp] test eax,eax jz LFNegSpan fmul ds:dword ptr[Float2ToThe31nd] fistp ds:dword ptr[izistep] ; note: we are relying on FP exceptions being turned ; off here to avoid range problems mov ebx,ds:dword ptr[izistep] ; remains loaded for all spans LFSpanLoop: ; set up the initial 1/z value fild ds:dword ptr[espan_t_v+esi] fild ds:dword ptr[espan_t_u+esi] mov ecx,ds:dword ptr[espan_t_v+esi] mov edi,ds:dword ptr[_d_pzbuffer] fmul ds:dword ptr[_d_zistepu] fxch st(1) fmul ds:dword ptr[_d_zistepv] fxch st(1) fadd ds:dword ptr[_d_ziorigin] imul ecx,ds:dword ptr[_d_zrowbytes] faddp st(1),st(0) ; clamp if z is nearer than 2 (1/z > 0.5) fcom ds:dword ptr[float_point5] add edi,ecx mov edx,ds:dword ptr[espan_t_u+esi] add edx,edx ; word count mov ecx,ds:dword ptr[espan_t_count+esi] add edi,edx ; pdest = &pdestspan[scans->u]; push esi ; preserve spans pointer fnstsw ax test ah,045h jz LClamp fmul ds:dword ptr[Float2ToThe31nd] fistp ds:dword ptr[izi] ; note: we are relying on FP exceptions being turned ; off here to avoid problems when the span is closer ; than 1/(2**31) mov edx,ds:dword ptr[izi] ; at this point: ; %ebx = izistep ; %ecx = count ; %edx = izi ; %edi = pdest LZDraw: ; do a single pixel up front, if necessary to dword align the destination test edi,2 jz LFMiddle mov eax,edx add edx,ebx shr eax,16 dec ecx mov ds:word ptr[edi],ax add edi,2 ; do middle a pair of aligned dwords at a time LFMiddle: push ecx shr ecx,1 ; count / 2 jz LFLast ; no aligned dwords to do shr ecx,1 ; (count / 2) / 2 jnc LFMiddleLoop ; even number of aligned dwords to do mov eax,edx add edx,ebx shr eax,16 mov esi,edx add edx,ebx and esi,0FFFF0000h or eax,esi mov ds:dword ptr[edi],eax add edi,4 and ecx,ecx jz LFLast LFMiddleLoop: mov eax,edx add edx,ebx shr eax,16 mov esi,edx add edx,ebx and esi,0FFFF0000h or eax,esi mov ebp,edx mov ds:dword ptr[edi],eax add edx,ebx shr ebp,16 mov esi,edx add edx,ebx and esi,0FFFF0000h or ebp,esi mov ds:dword ptr[4+edi],ebp ; FIXME: eliminate register contention add edi,8 dec ecx jnz LFMiddleLoop LFLast: pop ecx ; retrieve count pop esi ; retrieve span pointer ; do the last, unaligned pixel, if there is one and ecx,1 ; is there an odd pixel left to do? jz LFSpanDone ; no shr edx,16 mov ds:word ptr[edi],dx ; do the final pixel's z LFSpanDone: mov esi,ds:dword ptr[espan_t_pnext+esi] test esi,esi jnz LFSpanLoop jmp LFDone LFNegSpan: fmul ds:dword ptr[FloatMinus2ToThe31nd] fistp ds:dword ptr[izistep] ; note: we are relying on FP exceptions being turned ; off here to avoid range problems mov ebx,ds:dword ptr[izistep] ; remains loaded for all spans LFNegSpanLoop: ; set up the initial 1/z value fild ds:dword ptr[espan_t_v+esi] fild ds:dword ptr[espan_t_u+esi] mov ecx,ds:dword ptr[espan_t_v+esi] mov edi,ds:dword ptr[_d_pzbuffer] fmul ds:dword ptr[_d_zistepu] fxch st(1) fmul ds:dword ptr[_d_zistepv] fxch st(1) fadd ds:dword ptr[_d_ziorigin] imul ecx,ds:dword ptr[_d_zrowbytes] faddp st(1),st(0) ; clamp if z is nearer than 2 (1/z > 0.5) fcom ds:dword ptr[float_point5] add edi,ecx mov edx,ds:dword ptr[espan_t_u+esi] add edx,edx ; word count mov ecx,ds:dword ptr[espan_t_count+esi] add edi,edx ; pdest = &pdestspan[scans->u]; push esi ; preserve spans pointer fnstsw ax test ah,045h jz LClampNeg fmul ds:dword ptr[Float2ToThe31nd] fistp ds:dword ptr[izi] ; note: we are relying on FP exceptions being turned ; off here to avoid problems when the span is closer ; than 1/(2**31) mov edx,ds:dword ptr[izi] ; at this point: ; %ebx = izistep ; %ecx = count ; %edx = izi ; %edi = pdest LZDrawNeg: ; do a single pixel up front, if necessary to dword align the destination test edi,2 jz LFNegMiddle mov eax,edx sub edx,ebx shr eax,16 dec ecx mov ds:word ptr[edi],ax add edi,2 ; do middle a pair of aligned dwords at a time LFNegMiddle: push ecx shr ecx,1 ; count / 2 jz LFNegLast ; no aligned dwords to do shr ecx,1 ; (count / 2) / 2 jnc LFNegMiddleLoop ; even number of aligned dwords to do mov eax,edx sub edx,ebx shr eax,16 mov esi,edx sub edx,ebx and esi,0FFFF0000h or eax,esi mov ds:dword ptr[edi],eax add edi,4 and ecx,ecx jz LFNegLast LFNegMiddleLoop: mov eax,edx sub edx,ebx shr eax,16 mov esi,edx sub edx,ebx and esi,0FFFF0000h or eax,esi mov ebp,edx mov ds:dword ptr[edi],eax sub edx,ebx shr ebp,16 mov esi,edx sub edx,ebx and esi,0FFFF0000h or ebp,esi mov ds:dword ptr[4+edi],ebp ; FIXME: eliminate register contention add edi,8 dec ecx jnz LFNegMiddleLoop LFNegLast: pop ecx ; retrieve count pop esi ; retrieve span pointer ; do the last, unaligned pixel, if there is one and ecx,1 ; is there an odd pixel left to do? jz LFNegSpanDone ; no shr edx,16 mov ds:word ptr[edi],dx ; do the final pixel's z LFNegSpanDone: mov esi,ds:dword ptr[espan_t_pnext+esi] test esi,esi jnz LFNegSpanLoop LFDone: pop ebx ; restore register variables pop esi pop edi pop ebp ; restore the caller's stack frame ret _TEXT ENDS endif ;id386 END