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source: trunk/src/opengl/mesa/triangle.c@ 3232

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Last change on this file since 3232 was 2962, checked in by jeroen, 26 years ago
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File size: 60.3 KB

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1	/* $Id: triangle.c,v 1.2 2000-03-01 18:49:38 jeroen Exp $ */
2
3	/*
4	* Mesa 3-D graphics library
5	* Version: 3.1
6	*
7	* Copyright (C) 1999 Brian Paul All Rights Reserved.
8	*
9	* Permission is hereby granted, free of charge, to any person obtaining a
10	* copy of this software and associated documentation files (the "Software"),
11	* to deal in the Software without restriction, including without limitation
12	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
13	* and/or sell copies of the Software, and to permit persons to whom the
14	* Software is furnished to do so, subject to the following conditions:
15	*
16	* The above copyright notice and this permission notice shall be included
17	* in all copies or substantial portions of the Software.
18	*
19	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
20	* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
21	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
22	* BRIAN PAUL BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN
23	* AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
24	* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
25	*/
26
27
28
29
30	/*
31	* Triangle rasterizers
32	* When the device driver doesn't implement triangle rasterization Mesa
33	* will use these functions to draw triangles.
34	*/
35
36
37	#ifdef PC_HEADER
38	#include "all.h"
39	#else
40	#ifndef XFree86Server
41	#include <assert.h>
42	#include <math.h>
43	#include <stdio.h>
44	#else
45	#include "GL/xf86glx.h"
46	#endif
47	#include "types.h"
48	#include "context.h"
49	#include "depth.h"
50	#include "feedback.h"
51	#include "macros.h"
52	#include "mmath.h"
53	#include "span.h"
54	#include "texstate.h"
55	#include "triangle.h"
56	#include "vb.h"
57	#endif
58
59
60	GLboolean gl_cull_triangle( GLcontext *ctx,
61	GLuint v0, GLuint v1, GLuint v2, GLuint pv )
62	{
63	struct vertex_buffer *VB = ctx->VB;
64	GLfloat (*win)[4] = VB->Win.data;
65	GLfloat ex = win[v1][0] - win[v0][0];
66	GLfloat ey = win[v1][1] - win[v0][1];
67	GLfloat fx = win[v2][0] - win[v0][0];
68	GLfloat fy = win[v2][1] - win[v0][1];
69	GLfloat c = exfy-eyfx;
70
71	if (c * ctx->backface_sign > 0)
72	return 0;
73
74	return 1;
75	}
76
77
78
79
80
81
82	/*
83	* Render a flat-shaded color index triangle.
84	*/
85	static void flat_ci_triangle( GLcontext *ctx,
86	GLuint v0, GLuint v1, GLuint v2, GLuint pv )
87	{
88	#define INTERP_Z 1
89
90	#define SETUP_CODE \
91	GLuint index = VB->IndexPtr->data[pv]; \
92	if (1) { \
93	/* set the color index */ \
94	(*ctx->Driver.Index)( ctx, index ); \
95	}
96
97	#define INNER_LOOP( LEFT, RIGHT, Y ) \
98	{ \
99	GLint i, n = RIGHT-LEFT; \
100	GLdepth zspan[MAX_WIDTH]; \
101	if (n>0) { \
102	for (i=0;i<n;i++) { \
103	zspan[i] = FixedToDepth(ffz); \
104	ffz += fdzdx; \
105	} \
106	gl_write_monoindex_span( ctx, n, LEFT, Y, \
107	zspan, index, GL_POLYGON ); \
108	} \
109	}
110
111	#include "tritemp.h"
112	}
113
114
115
116	/*
117	* Render a smooth-shaded color index triangle.
118	*/
119	static void smooth_ci_triangle( GLcontext *ctx,
120	GLuint v0, GLuint v1, GLuint v2, GLuint pv )
121	{
122	(void) pv;
123	#define INTERP_Z 1
124	#define INTERP_INDEX 1
125
126	#define INNER_LOOP( LEFT, RIGHT, Y ) \
127	{ \
128	GLint i, n = RIGHT-LEFT; \
129	GLdepth zspan[MAX_WIDTH]; \
130	GLuint index[MAX_WIDTH]; \
131	if (n>0) { \
132	for (i=0;i<n;i++) { \
133	zspan[i] = FixedToDepth(ffz); \
134	index[i] = FixedToInt(ffi); \
135	ffz += fdzdx; \
136	ffi += fdidx; \
137	} \
138	gl_write_index_span( ctx, n, LEFT, Y, zspan, \
139	index, GL_POLYGON ); \
140	} \
141	}
142
143	#include "tritemp.h"
144	}
145
146
147
148	/*
149	* Render a flat-shaded RGBA triangle.
150	*/
151	static void flat_rgba_triangle( GLcontext *ctx,
152	GLuint v0, GLuint v1, GLuint v2, GLuint pv )
153	{
154	#define INTERP_Z 1
155
156	#define SETUP_CODE \
157	if (1) { \
158	/* set the color */ \
159	GLubyte r = VB->ColorPtr->data[pv][0]; \
160	GLubyte g = VB->ColorPtr->data[pv][1]; \
161	GLubyte b = VB->ColorPtr->data[pv][2]; \
162	GLubyte a = VB->ColorPtr->data[pv][3]; \
163	(*ctx->Driver.Color)( ctx, r, g, b, a ); \
164	}
165
166	#define INNER_LOOP( LEFT, RIGHT, Y ) \
167	{ \
168	GLint i, n = RIGHT-LEFT; \
169	GLdepth zspan[MAX_WIDTH]; \
170	if (n>0) { \
171	for (i=0;i<n;i++) { \
172	zspan[i] = FixedToDepth(ffz); \
173	ffz += fdzdx; \
174	} \
175	gl_write_monocolor_span( ctx, n, LEFT, Y, zspan, \
176	VB->ColorPtr->data[pv], \
177	GL_POLYGON ); \
178	} \
179	}
180
181	#include "tritemp.h"
182
183	ASSERT(!ctx->Texture.ReallyEnabled); /* texturing must be off */
184	ASSERT(ctx->Light.ShadeModel==GL_FLAT);
185	}
186
187
188
189	/*
190	* Render a smooth-shaded RGBA triangle.
191	*/
192	static void smooth_rgba_triangle( GLcontext *ctx,
193	GLuint v0, GLuint v1, GLuint v2, GLuint pv )
194	{
195	(void) pv;
196	#define INTERP_Z 1
197	#define INTERP_RGB 1
198	#define INTERP_ALPHA 1
199
200	#define INNER_LOOP( LEFT, RIGHT, Y ) \
201	{ \
202	GLint i, n = RIGHT-LEFT; \
203	GLdepth zspan[MAX_WIDTH]; \
204	GLubyte rgba[MAX_WIDTH][4]; \
205	if (n>0) { \
206	for (i=0;i<n;i++) { \
207	zspan[i] = FixedToDepth(ffz); \
208	rgba[i][RCOMP] = FixedToInt(ffr); \
209	rgba[i][GCOMP] = FixedToInt(ffg); \
210	rgba[i][BCOMP] = FixedToInt(ffb); \
211	rgba[i][ACOMP] = FixedToInt(ffa); \
212	ffz += fdzdx; \
213	ffr += fdrdx; \
214	ffg += fdgdx; \
215	ffb += fdbdx; \
216	ffa += fdadx; \
217	} \
218	gl_write_rgba_span( ctx, n, LEFT, Y, \
219	(const GLdepth *) zspan, \
220	rgba, GL_POLYGON ); \
221	} \
222	}
223
224	#include "tritemp.h"
225
226	ASSERT(!ctx->Texture.ReallyEnabled); /* texturing must be off */
227	ASSERT(ctx->Light.ShadeModel==GL_SMOOTH);
228	}
229
230
231	/*
232	* Render an RGB, GL_DECAL, textured triangle.
233	* Interpolate S,T only w/out mipmapping or perspective correction.
234	*/
235	static void simple_textured_triangle( GLcontext *ctx, GLuint v0, GLuint v1,
236	GLuint v2, GLuint pv )
237	{
238	#define INTERP_INT_ST 1
239	#define S_SCALE twidth
240	#define T_SCALE theight
241	#define SETUP_CODE \
242	struct gl_texture_object *obj = ctx->Texture.Unit[0].CurrentD[2]; \
243	GLint b = obj->BaseLevel; \
244	GLfloat twidth = (GLfloat) obj->Image[b]->Width; \
245	GLfloat theight = (GLfloat) obj->Image[b]->Height; \
246	GLint twidth_log2 = obj->Image[b]->WidthLog2; \
247	GLubyte *texture = obj->Image[b]->Data; \
248	GLint smask = obj->Image[b]->Width - 1; \
249	GLint tmask = obj->Image[b]->Height - 1;
250	(void) pv;
251
252	#define INNER_LOOP( LEFT, RIGHT, Y ) \
253	{ \
254	GLint i, n = RIGHT-LEFT; \
255	GLubyte rgb[MAX_WIDTH][3]; \
256	if (n>0) { \
257	ffs -= FIXED_HALF; /* off-by-one error? */ \
258	fft -= FIXED_HALF; \
259	for (i=0;i<n;i++) { \
260	GLint s = FixedToInt(ffs) & smask; \
261	GLint t = FixedToInt(fft) & tmask; \
262	GLint pos = (t << twidth_log2) + s; \
263	pos = pos + pos + pos; /* multiply by 3 */ \
264	rgb[i][RCOMP] = texture[pos]; \
265	rgb[i][GCOMP] = texture[pos+1]; \
266	rgb[i][BCOMP] = texture[pos+2]; \
267	ffs += fdsdx; \
268	fft += fdtdx; \
269	} \
270	(*ctx->Driver.WriteRGBSpan)( ctx, n, LEFT, Y, \
271	(const GLubyte (*)[3]) rgb, NULL ); \
272	} \
273	}
274
275	#include "tritemp.h"
276	}
277
278
279	/*
280	* Render an RGB, GL_DECAL, textured triangle.
281	* Interpolate S,T, GL_LESS depth test, w/out mipmapping or
282	* perspective correction.
283	*/
284	static void simple_z_textured_triangle( GLcontext *ctx, GLuint v0, GLuint v1,
285	GLuint v2, GLuint pv )
286	{
287	#define INTERP_Z 1
288	#define INTERP_INT_ST 1
289	#define S_SCALE twidth
290	#define T_SCALE theight
291	#define SETUP_CODE \
292	struct gl_texture_object *obj = ctx->Texture.Unit[0].CurrentD[2]; \
293	GLint b = obj->BaseLevel; \
294	GLfloat twidth = (GLfloat) obj->Image[b]->Width; \
295	GLfloat theight = (GLfloat) obj->Image[b]->Height; \
296	GLint twidth_log2 = obj->Image[b]->WidthLog2; \
297	GLubyte *texture = obj->Image[b]->Data; \
298	GLint smask = obj->Image[b]->Width - 1; \
299	GLint tmask = obj->Image[b]->Height - 1;
300	(void) pv;
301
302	#define INNER_LOOP( LEFT, RIGHT, Y ) \
303	{ \
304	GLint i, n = RIGHT-LEFT; \
305	GLubyte rgb[MAX_WIDTH][3]; \
306	GLubyte mask[MAX_WIDTH]; \
307	if (n>0) { \
308	ffs -= FIXED_HALF; /* off-by-one error? */ \
309	fft -= FIXED_HALF; \
310	for (i=0;i<n;i++) { \
311	GLdepth z = FixedToDepth(ffz); \
312	if (z < zRow[i]) { \
313	GLint s = FixedToInt(ffs) & smask; \
314	GLint t = FixedToInt(fft) & tmask; \
315	GLint pos = (t << twidth_log2) + s; \
316	pos = pos + pos + pos; /* multiply by 3 */ \
317	rgb[i][RCOMP] = texture[pos]; \
318	rgb[i][GCOMP] = texture[pos+1]; \
319	rgb[i][BCOMP] = texture[pos+2]; \
320	zRow[i] = z; \
321	mask[i] = 1; \
322	} \
323	else { \
324	mask[i] = 0; \
325	} \
326	ffz += fdzdx; \
327	ffs += fdsdx; \
328	fft += fdtdx; \
329	} \
330	(*ctx->Driver.WriteRGBSpan)( ctx, n, LEFT, Y, \
331	(const GLubyte (*)[3]) rgb, mask ); \
332	} \
333	}
334
335	#include "tritemp.h"
336	}
337
338
339
340	/*
341	* Render an RGB/RGBA textured triangle without perspective correction.
342	*/
343	static void affine_textured_triangle( GLcontext *ctx, GLuint v0, GLuint v1,
344	GLuint v2, GLuint pv )
345	{
346	#define INTERP_Z 1
347	#define INTERP_RGB 1
348	#define INTERP_ALPHA 1
349	#define INTERP_INT_ST 1
350	#define S_SCALE twidth
351	#define T_SCALE theight
352	#define SETUP_CODE \
353	struct gl_texture_unit *unit = ctx->Texture.Unit+0; \
354	struct gl_texture_object *obj = unit->CurrentD[2]; \
355	GLint b = obj->BaseLevel; \
356	GLfloat twidth = (GLfloat) obj->Image[b]->Width; \
357	GLfloat theight = (GLfloat) obj->Image[b]->Height; \
358	GLint twidth_log2 = obj->Image[b]->WidthLog2; \
359	GLubyte *texture = obj->Image[b]->Data; \
360	GLint smask = obj->Image[b]->Width - 1; \
361	GLint tmask = obj->Image[b]->Height - 1; \
362	GLint format = obj->Image[b]->Format; \
363	GLint filter = obj->MinFilter; \
364	GLint envmode = unit->EnvMode; \
365	GLint comp, tbytesline, tsize; \
366	GLfixed er, eg, eb, ea; \
367	GLint tr, tg, tb, ta; \
368	if (envmode == GL_BLEND \|\| envmode == GL_ADD) { \
369	/* potential off-by-one error here? (1.0f -> 2048 -> 0) */ \
370	er = FloatToFixed(unit->EnvColor[0]); \
371	eg = FloatToFixed(unit->EnvColor[1]); \
372	eb = FloatToFixed(unit->EnvColor[2]); \
373	ea = FloatToFixed(unit->EnvColor[3]); \
374	} \
375	switch (format) { \
376	case GL_ALPHA: \
377	case GL_LUMINANCE: \
378	case GL_INTENSITY: \
379	comp = 1; \
380	break; \
381	case GL_LUMINANCE_ALPHA: \
382	comp = 2; \
383	break; \
384	case GL_RGB: \
385	comp = 3; \
386	break; \
387	case GL_RGBA: \
388	comp = 4; \
389	break; \
390	default: \
391	gl_problem(NULL, "Bad texture format in affine_texture_triangle");\
392	return; \
393	} \
394	tbytesline = obj->Image[b]->Width * comp; \
395	tsize = theight * tbytesline;
396	(void) pv;
397
398	/* Instead of defining a function for each mode, a test is done
399	* between the outer and inner loops. This is to reduce code size
400	* and complexity. Observe that an optimizing compiler kills
401	* unused variables (for instance tf,sf,ti,si in case of GL_NEAREST).
402	*/
403
404	#define NEAREST_RGB \
405	tr = tex00[0]; \
406	tg = tex00[1]; \
407	tb = tex00[2]; \
408	ta = 0xff
409
410	#define LINEAR_RGB \
411	tr = (ti * (si * tex00[0] + sf * tex01[0]) + \
412	tf * (si * tex10[0] + sf * tex11[0])) >> 2 * FIXED_SHIFT; \
413	tg = (ti * (si * tex00[1] + sf * tex01[1]) + \
414	tf * (si * tex10[1] + sf * tex11[1])) >> 2 * FIXED_SHIFT; \
415	tb = (ti * (si * tex00[2] + sf * tex01[2]) + \
416	tf * (si * tex10[2] + sf * tex11[2])) >> 2 * FIXED_SHIFT; \
417	ta = 0xff
418
419	#define NEAREST_RGBA \
420	tr = tex00[0]; \
421	tg = tex00[1]; \
422	tb = tex00[2]; \
423	ta = tex00[3]
424
425	#define LINEAR_RGBA \
426	tr = (ti * (si * tex00[0] + sf * tex01[0]) + \
427	tf * (si * tex10[0] + sf * tex11[0])) >> 2 * FIXED_SHIFT; \
428	tg = (ti * (si * tex00[1] + sf * tex01[1]) + \
429	tf * (si * tex10[1] + sf * tex11[1])) >> 2 * FIXED_SHIFT; \
430	tb = (ti * (si * tex00[2] + sf * tex01[2]) + \
431	tf * (si * tex10[2] + sf * tex11[2])) >> 2 * FIXED_SHIFT; \
432	ta = (ti * (si * tex00[3] + sf * tex01[3]) + \
433	tf * (si * tex10[3] + sf * tex11[3])) >> 2 * FIXED_SHIFT
434
435	#define MODULATE \
436	dest[0] = ffr * (tr + 1) >> (FIXED_SHIFT + 8); \
437	dest[1] = ffg * (tg + 1) >> (FIXED_SHIFT + 8); \
438	dest[2] = ffb * (tb + 1) >> (FIXED_SHIFT + 8); \
439	dest[3] = ffa * (ta + 1) >> (FIXED_SHIFT + 8)
440
441	#define DECAL \
442	dest[0] = ((0xff - ta) * ffr + ((ta + 1) * tr << FIXED_SHIFT)) >> (FIXED_SHIFT + 8); \
443	dest[1] = ((0xff - ta) * ffg + ((ta + 1) * tg << FIXED_SHIFT)) >> (FIXED_SHIFT + 8); \
444	dest[2] = ((0xff - ta) * ffb + ((ta + 1) * tb << FIXED_SHIFT)) >> (FIXED_SHIFT + 8); \
445	dest[3] = FixedToInt(ffa)
446
447	#define BLEND \
448	dest[0] = ((0xff - tr) * ffr + (tr + 1) * er) >> (FIXED_SHIFT + 8); \
449	dest[1] = ((0xff - tg) * ffg + (tg + 1) * eg) >> (FIXED_SHIFT + 8); \
450	dest[2] = ((0xff - tb) * ffb + (tb + 1) * eb) >> (FIXED_SHIFT + 8); \
451	dest[3] = ffa * (ta + 1) >> (FIXED_SHIFT + 8)
452
453	#define REPLACE \
454	dest[0] = tr; \
455	dest[1] = tg; \
456	dest[2] = tb; \
457	dest[3] = ta
458
459	#define ADD \
460	dest[0] = ((ffr << 8) + (tr + 1) * er) >> (FIXED_SHIFT + 8); \
461	dest[1] = ((ffg << 8) + (tg + 1) * eg) >> (FIXED_SHIFT + 8); \
462	dest[2] = ((ffb << 8) + (tb + 1) * eb) >> (FIXED_SHIFT + 8); \
463	dest[3] = ffa * (ta + 1) >> (FIXED_SHIFT + 8)
464
465	/* shortcuts */
466
467	#define NEAREST_RGB_REPLACE NEAREST_RGB;REPLACE
468
469	#define NEAREST_RGBA_REPLACE (GLint )dest = (GLint )tex00
470
471	#define SPAN1(DO_TEX,COMP) \
472	for (i=0;i<n;i++) { \
473	GLint s = FixedToInt(ffs) & smask; \
474	GLint t = FixedToInt(fft) & tmask; \
475	GLint pos = (t << twidth_log2) + s; \
476	GLubyte tex00 = texture + COMP pos; \
477	zspan[i] = FixedToDepth(ffz); \
478	DO_TEX; \
479	ffz += fdzdx; \
480	ffr += fdrdx; \
481	ffg += fdgdx; \
482	ffb += fdbdx; \
483	ffa += fdadx; \
484	ffs += fdsdx; \
485	fft += fdtdx; \
486	dest += 4; \
487	}
488
489	#define SPAN2(DO_TEX,COMP) \
490	for (i=0;i<n;i++) { \
491	GLint s = FixedToInt(ffs) & smask; \
492	GLint t = FixedToInt(fft) & tmask; \
493	GLint sf = ffs & FIXED_FRAC_MASK; \
494	GLint tf = fft & FIXED_FRAC_MASK; \
495	GLint si = FIXED_FRAC_MASK - sf; \
496	GLint ti = FIXED_FRAC_MASK - tf; \
497	GLint pos = (t << twidth_log2) + s; \
498	GLubyte tex00 = texture + COMP pos; \
499	GLubyte *tex10 = tex00 + tbytesline; \
500	GLubyte *tex01 = tex00 + COMP; \
501	GLubyte *tex11 = tex10 + COMP; \
502	if (t == tmask) { \
503	tex10 -= tsize; \
504	tex11 -= tsize; \
505	} \
506	if (s == smask) { \
507	tex01 -= tbytesline; \
508	tex11 -= tbytesline; \
509	} \
510	zspan[i] = FixedToDepth(ffz); \
511	DO_TEX; \
512	ffz += fdzdx; \
513	ffr += fdrdx; \
514	ffg += fdgdx; \
515	ffb += fdbdx; \
516	ffa += fdadx; \
517	ffs += fdsdx; \
518	fft += fdtdx; \
519	dest += 4; \
520	}
521
522	/* here comes the heavy part.. (something for the compiler to chew on) */
523	#define INNER_LOOP( LEFT, RIGHT, Y ) \
524	{ \
525	GLint i, n = RIGHT-LEFT; \
526	GLdepth zspan[MAX_WIDTH]; \
527	GLubyte rgba[MAX_WIDTH][4]; \
528	if (n>0) { \
529	GLubyte *dest = rgba[0]; \
530	ffs -= FIXED_HALF; /* off-by-one error? */ \
531	fft -= FIXED_HALF; \
532	switch (filter) { \
533	case GL_NEAREST: \
534	switch (format) { \
535	case GL_RGB: \
536	switch (envmode) { \
537	case GL_MODULATE: \
538	SPAN1(NEAREST_RGB;MODULATE,3); \
539	break; \
540	case GL_DECAL: \
541	case GL_REPLACE: \
542	SPAN1(NEAREST_RGB_REPLACE,3); \
543	break; \
544	case GL_BLEND: \
545	SPAN1(NEAREST_RGB;BLEND,3); \
546	break; \
547	case GL_ADD: \
548	SPAN1(NEAREST_RGB;ADD,3); \
549	break; \
550	} \
551	break; \
552	case GL_RGBA: \
553	switch(envmode) { \
554	case GL_MODULATE: \
555	SPAN1(NEAREST_RGBA;MODULATE,4); \
556	break; \
557	case GL_DECAL: \
558	SPAN1(NEAREST_RGBA;DECAL,4); \
559	break; \
560	case GL_BLEND: \
561	SPAN1(NEAREST_RGBA;BLEND,4); \
562	break; \
563	case GL_REPLACE: \
564	SPAN1(NEAREST_RGBA_REPLACE,4); \
565	break; \
566	case GL_ADD: \
567	SPAN1(NEAREST_RGBA;ADD,4); \
568	break; \
569	} \
570	break; \
571	} \
572	break; \
573	case GL_LINEAR: \
574	ffs -= FIXED_HALF; \
575	fft -= FIXED_HALF; \
576	switch (format) { \
577	case GL_RGB: \
578	switch (envmode) { \
579	case GL_MODULATE: \
580	SPAN2(LINEAR_RGB;MODULATE,3); \
581	break; \
582	case GL_DECAL: \
583	case GL_REPLACE: \
584	SPAN2(LINEAR_RGB;REPLACE,3); \
585	break; \
586	case GL_BLEND: \
587	SPAN2(LINEAR_RGB;BLEND,3); \
588	break; \
589	case GL_ADD: \
590	SPAN2(LINEAR_RGB;ADD,3); \
591	break; \
592	} \
593	break; \
594	case GL_RGBA: \
595	switch (envmode) { \
596	case GL_MODULATE: \
597	SPAN2(LINEAR_RGBA;MODULATE,4); \
598	break; \
599	case GL_DECAL: \
600	SPAN2(LINEAR_RGBA;DECAL,4); \
601	break; \
602	case GL_BLEND: \
603	SPAN2(LINEAR_RGBA;BLEND,4); \
604	break; \
605	case GL_REPLACE: \
606	SPAN2(LINEAR_RGBA;REPLACE,4); \
607	break; \
608	case GL_ADD: \
609	SPAN2(LINEAR_RGBA;ADD,4); \
610	break; \
611	} \
612	break; \
613	} \
614	break; \
615	} \
616	gl_write_rgba_span(ctx, n, LEFT, Y, zspan, \
617	rgba, GL_POLYGON); \
618	/* explicit kill of variables: */ \
619	ffr = ffg = ffb = ffa = 0; \
620	} \
621	}
622
623	#include "tritemp.h"
624	#undef SPAN1
625	#undef SPAN2
626	}
627
628
629	/*
630	* Render an perspective corrected RGB/RGBA textured triangle.
631	* The Q (aka V in Mesa) coordinate must be zero such that the divide
632	* by interpolated Q/W comes out right.
633	*
634	* XXX (May 15, 1999) this function not used for now because repeating
635	* of negative texture coords not handled correctly!!!
636	*/
637	#if 000
638	static void persp_textured_triangle( GLcontext *ctx, GLuint v0, GLuint v1,
639	GLuint v2, GLuint pv )
640	{
641
642	#define INTERP_Z 1
643	#define INTERP_RGB 1
644	#define INTERP_ALPHA 1
645	#define INTERP_STUV 1
646	#define SETUP_CODE \
647	struct gl_texture_unit *unit = ctx->Texture.Unit+0; \
648	struct gl_texture_object *obj = unit->CurrentD[2]; \
649	GLint b = obj->BaseLevel; \
650	GLfloat twidth = (GLfloat) obj->Image[b]->Width; \
651	GLfloat theight = (GLfloat) obj->Image[b]->Height; \
652	GLint twidth_log2 = obj->Image[b]->WidthLog2; \
653	GLubyte *texture = obj->Image[b]->Data; \
654	GLint smask = (obj->Image[b]->Width - 1); \
655	GLint tmask = (obj->Image[b]->Height - 1); \
656	GLint format = obj->Image[b]->Format; \
657	GLint filter = obj->MinFilter; \
658	GLint envmode = unit->EnvMode; \
659	GLfloat sscale, tscale; \
660	GLint comp, tbytesline, tsize; \
661	GLfixed er, eg, eb, ea; \
662	GLint tr, tg, tb, ta; \
663	if (envmode == GL_BLEND \|\| envmode == GL_ADD) { \
664	er = FloatToFixed(unit->EnvColor[0]); \
665	eg = FloatToFixed(unit->EnvColor[1]); \
666	eb = FloatToFixed(unit->EnvColor[2]); \
667	ea = FloatToFixed(unit->EnvColor[3]); \
668	} \
669	switch (format) { \
670	case GL_ALPHA: \
671	case GL_LUMINANCE: \
672	case GL_INTENSITY: \
673	comp = 1; \
674	break; \
675	case GL_LUMINANCE_ALPHA: \
676	comp = 2; \
677	break; \
678	case GL_RGB: \
679	comp = 3; \
680	break; \
681	case GL_RGBA: \
682	comp = 4; \
683	break; \
684	default: \
685	gl_problem(NULL, "Bad texture format in persp_texture_triangle"); \
686	return; \
687	} \
688	if (filter == GL_NEAREST) { \
689	sscale = twidth; \
690	tscale = theight; \
691	} \
692	else { \
693	sscale = FIXED_SCALE * twidth; \
694	tscale = FIXED_SCALE * theight; \
695	} \
696	tbytesline = obj->Image[b]->Width * comp; \
697	tsize = theight * tbytesline;
698	(void) pv;
699
700	#define SPAN1(DO_TEX,COMP) \
701	for (i=0;i<n;i++) { \
702	GLfloat invQ = 1.0f / vv; \
703	GLint s = (int)(SS * invQ) & smask; \
704	GLint t = (int)(TT * invQ) & tmask; \
705	GLint pos = COMP * ((t << twidth_log2) + s); \
706	GLubyte *tex00 = texture + pos; \
707	zspan[i] = FixedToDepth(ffz); \
708	DO_TEX; \
709	ffz += fdzdx; \
710	ffr += fdrdx; \
711	ffg += fdgdx; \
712	ffb += fdbdx; \
713	ffa += fdadx; \
714	SS += dSdx; \
715	TT += dTdx; \
716	vv += dvdx; \
717	dest += 4; \
718	}
719
720	#define SPAN2(DO_TEX,COMP) \
721	for (i=0;i<n;i++) { \
722	GLfloat invQ = 1.0f / vv; \
723	GLfixed ffs = (int)(SS * invQ); \
724	GLfixed fft = (int)(TT * invQ); \
725	GLint s = FixedToInt(ffs) & smask; \
726	GLint t = FixedToInt(fft) & tmask; \
727	GLint sf = ffs & FIXED_FRAC_MASK; \
728	GLint tf = fft & FIXED_FRAC_MASK; \
729	GLint si = FIXED_FRAC_MASK - sf; \
730	GLint ti = FIXED_FRAC_MASK - tf; \
731	GLint pos = COMP * ((t << twidth_log2) + s); \
732	GLubyte *tex00 = texture + pos; \
733	GLubyte *tex10 = tex00 + tbytesline; \
734	GLubyte *tex01 = tex00 + COMP; \
735	GLubyte *tex11 = tex10 + COMP; \
736	if (t == tmask) { \
737	tex10 -= tsize; \
738	tex11 -= tsize; \
739	} \
740	if (s == smask) { \
741	tex01 -= tbytesline; \
742	tex11 -= tbytesline; \
743	} \
744	zspan[i] = FixedToDepth(ffz); \
745	DO_TEX; \
746	ffz += fdzdx; \
747	ffr += fdrdx; \
748	ffg += fdgdx; \
749	ffb += fdbdx; \
750	ffa += fdadx; \
751	SS += dSdx; \
752	TT += dTdx; \
753	vv += dvdx; \
754	dest += 4; \
755	}
756
757	#define INNER_LOOP( LEFT, RIGHT, Y ) \
758	{ \
759	GLint i, n = RIGHT-LEFT; \
760	GLdepth zspan[MAX_WIDTH]; \
761	GLubyte rgba[MAX_WIDTH][4]; \
762	(void)uu; /* please GCC */ \
763	if (n>0) { \
764	GLfloat SS = ss * sscale; \
765	GLfloat TT = tt * tscale; \
766	GLfloat dSdx = dsdx * sscale; \
767	GLfloat dTdx = dtdx * tscale; \
768	GLubyte *dest = rgba[0]; \
769	switch (filter) { \
770	case GL_NEAREST: \
771	switch (format) { \
772	case GL_RGB: \
773	switch (envmode) { \
774	case GL_MODULATE: \
775	SPAN1(NEAREST_RGB;MODULATE,3); \
776	break; \
777	case GL_DECAL: \
778	case GL_REPLACE: \
779	SPAN1(NEAREST_RGB_REPLACE,3); \
780	break; \
781	case GL_BLEND: \
782	SPAN1(NEAREST_RGB;BLEND,3); \
783	break; \
784	case GL_ADD: \
785	SPAN1(NEAREST_RGB;ADD,3); \
786	break; \
787	} \
788	break; \
789	case GL_RGBA: \
790	switch(envmode) { \
791	case GL_MODULATE: \
792	SPAN1(NEAREST_RGBA;MODULATE,4); \
793	break; \
794	case GL_DECAL: \
795	SPAN1(NEAREST_RGBA;DECAL,4); \
796	break; \
797	case GL_BLEND: \
798	SPAN1(NEAREST_RGBA;BLEND,4); \
799	break; \
800	case GL_REPLACE: \
801	SPAN1(NEAREST_RGBA_REPLACE,4); \
802	break; \
803	case GL_ADD: \
804	SPAN1(NEAREST_RGBA;ADD,4); \
805	break; \
806	} \
807	break; \
808	} \
809	break; \
810	case GL_LINEAR: \
811	SS -= 0.5f * FIXED_SCALE * vv; \
812	TT -= 0.5f * FIXED_SCALE * vv; \
813	switch (format) { \
814	case GL_RGB: \
815	switch (envmode) { \
816	case GL_MODULATE: \
817	SPAN2(LINEAR_RGB;MODULATE,3); \
818	break; \
819	case GL_DECAL: \
820	case GL_REPLACE: \
821	SPAN2(LINEAR_RGB;REPLACE,3); \
822	break; \
823	case GL_BLEND: \
824	SPAN2(LINEAR_RGB;BLEND,3); \
825	break; \
826	case GL_ADD: \
827	SPAN2(LINEAR_RGB;ADD,3); \
828	break; \
829	} \
830	break; \
831	case GL_RGBA: \
832	switch (envmode) { \
833	case GL_MODULATE: \
834	SPAN2(LINEAR_RGBA;MODULATE,4); \
835	break; \
836	case GL_DECAL: \
837	SPAN2(LINEAR_RGBA;DECAL,4); \
838	break; \
839	case GL_BLEND: \
840	SPAN2(LINEAR_RGBA;BLEND,4); \
841	break; \
842	case GL_REPLACE: \
843	SPAN2(LINEAR_RGBA;REPLACE,4); \
844	break; \
845	case GL_ADD: \
846	SPAN2(LINEAR_RGBA;ADD,4); \
847	break; \
848	} \
849	break; \
850	} \
851	break; \
852	} \
853	gl_write_rgba_span( ctx, n, LEFT, Y, zspan, \
854	rgba, GL_POLYGON ); \
855	ffr = ffg = ffb = ffa = 0; \
856	} \
857	}
858
859
860	#include "tritemp.h"
861	#undef SPAN1
862	#undef SPAN2
863	}
864	#endif
865
866
867
868	/*
869	* Render a smooth-shaded, textured, RGBA triangle.
870	* Interpolate S,T,U with perspective correction, w/out mipmapping.
871	* Note: we use texture coordinates S,T,U,V instead of S,T,R,Q because
872	* R is already used for red.
873	*/
874	static void general_textured_triangle( GLcontext *ctx, GLuint v0, GLuint v1,
875	GLuint v2, GLuint pv )
876	{
877	#define INTERP_Z 1
878	#define INTERP_RGB 1
879	#define INTERP_ALPHA 1
880	#define INTERP_STUV 1
881	#define SETUP_CODE \
882	GLboolean flat_shade = (ctx->Light.ShadeModel==GL_FLAT); \
883	GLint r, g, b, a; \
884	if (flat_shade) { \
885	r = VB->ColorPtr->data[pv][0]; \
886	g = VB->ColorPtr->data[pv][1]; \
887	b = VB->ColorPtr->data[pv][2]; \
888	a = VB->ColorPtr->data[pv][3]; \
889	}
890	#define INNER_LOOP( LEFT, RIGHT, Y ) \
891	{ \
892	GLint i, n = RIGHT-LEFT; \
893	GLdepth zspan[MAX_WIDTH]; \
894	GLubyte rgba[MAX_WIDTH][4]; \
895	GLfloat s[MAX_WIDTH], t[MAX_WIDTH], u[MAX_WIDTH]; \
896	if (n>0) { \
897	if (flat_shade) { \
898	for (i=0;i<n;i++) { \
899	GLdouble invQ = 1.0 / vv; \
900	zspan[i] = FixedToDepth(ffz); \
901	rgba[i][RCOMP] = r; \
902	rgba[i][GCOMP] = g; \
903	rgba[i][BCOMP] = b; \
904	rgba[i][ACOMP] = a; \
905	s[i] = ss*invQ; \
906	t[i] = tt*invQ; \
907	u[i] = uu*invQ; \
908	ffz += fdzdx; \
909	ss += dsdx; \
910	tt += dtdx; \
911	uu += dudx; \
912	vv += dvdx; \
913	} \
914	} \
915	else { \
916	for (i=0;i<n;i++) { \
917	GLdouble invQ = 1.0 / vv; \
918	zspan[i] = FixedToDepth(ffz); \
919	rgba[i][RCOMP] = FixedToInt(ffr); \
920	rgba[i][GCOMP] = FixedToInt(ffg); \
921	rgba[i][BCOMP] = FixedToInt(ffb); \
922	rgba[i][ACOMP] = FixedToInt(ffa); \
923	s[i] = ss*invQ; \
924	t[i] = tt*invQ; \
925	u[i] = uu*invQ; \
926	ffz += fdzdx; \
927	ffr += fdrdx; \
928	ffg += fdgdx; \
929	ffb += fdbdx; \
930	ffa += fdadx; \
931	ss += dsdx; \
932	tt += dtdx; \
933	uu += dudx; \
934	vv += dvdx; \
935	} \
936	} \
937	gl_write_texture_span( ctx, n, LEFT, Y, zspan, \
938	s, t, u, NULL, \
939	rgba, \
940	NULL, GL_POLYGON ); \
941	} \
942	}
943
944	#include "tritemp.h"
945	}
946
947
948	/*
949	* Render a smooth-shaded, textured, RGBA triangle with separate specular
950	* color interpolation.
951	* Interpolate S,T,U with perspective correction, w/out mipmapping.
952	* Note: we use texture coordinates S,T,U,V instead of S,T,R,Q because
953	* R is already used for red.
954	*/
955	static void general_textured_spec_triangle1( GLcontext *ctx, GLuint v0,
956	GLuint v1, GLuint v2, GLuint pv,
957	GLdepth zspan[MAX_WIDTH],
958	GLubyte rgba[MAX_WIDTH][4],
959	GLubyte spec[MAX_WIDTH][4] )
960	{
961	#define INTERP_Z 1
962	#define INTERP_RGB 1
963	#define INTERP_SPEC 1
964	#define INTERP_ALPHA 1
965	#define INTERP_STUV 1
966	#define SETUP_CODE \
967	GLboolean flat_shade = (ctx->Light.ShadeModel==GL_FLAT); \
968	GLint r, g, b, a, sr, sg, sb; \
969	if (flat_shade) { \
970	r = VB->ColorPtr->data[pv][0]; \
971	g = VB->ColorPtr->data[pv][1]; \
972	b = VB->ColorPtr->data[pv][2]; \
973	a = VB->ColorPtr->data[pv][3]; \
974	sr = VB->Specular[pv][0]; \
975	sg = VB->Specular[pv][1]; \
976	sb = VB->Specular[pv][2]; \
977	}
978	#define INNER_LOOP( LEFT, RIGHT, Y ) \
979	{ \
980	GLint i, n = RIGHT-LEFT; \
981	GLfloat s[MAX_WIDTH], t[MAX_WIDTH], u[MAX_WIDTH]; \
982	if (n>0) { \
983	if (flat_shade) { \
984	for (i=0;i<n;i++) { \
985	GLdouble invQ = 1.0 / vv; \
986	zspan[i] = FixedToDepth(ffz); \
987	rgba[i][RCOMP] = r; \
988	rgba[i][GCOMP] = g; \
989	rgba[i][BCOMP] = b; \
990	rgba[i][ACOMP] = a; \
991	spec[i][RCOMP] = sr; \
992	spec[i][GCOMP] = sg; \
993	spec[i][BCOMP] = sb; \
994	s[i] = ss*invQ; \
995	t[i] = tt*invQ; \
996	u[i] = uu*invQ; \
997	ffz += fdzdx; \
998	ss += dsdx; \
999	tt += dtdx; \
1000	uu += dudx; \
1001	vv += dvdx; \
1002	} \
1003	} \
1004	else { \
1005	for (i=0;i<n;i++) { \
1006	GLdouble invQ = 1.0 / vv; \
1007	zspan[i] = FixedToDepth(ffz); \
1008	rgba[i][RCOMP] = FixedToInt(ffr); \
1009	rgba[i][GCOMP] = FixedToInt(ffg); \
1010	rgba[i][BCOMP] = FixedToInt(ffb); \
1011	rgba[i][ACOMP] = FixedToInt(ffa); \
1012	spec[i][RCOMP] = FixedToInt(ffsr); \
1013	spec[i][GCOMP] = FixedToInt(ffsg); \
1014	spec[i][BCOMP] = FixedToInt(ffsb); \
1015	s[i] = ss*invQ; \
1016	t[i] = tt*invQ; \
1017	u[i] = uu*invQ; \
1018	ffz += fdzdx; \
1019	ffr += fdrdx; \
1020	ffg += fdgdx; \
1021	ffb += fdbdx; \
1022	ffa += fdadx; \
1023	ffsr += fdsrdx; \
1024	ffsg += fdsgdx; \
1025	ffsb += fdsbdx; \
1026	ss += dsdx; \
1027	tt += dtdx; \
1028	uu += dudx; \
1029	vv += dvdx; \
1030	} \
1031	} \
1032	gl_write_texture_span( ctx, n, LEFT, Y, zspan, \
1033	s, t, u, NULL, rgba, \
1034	(const GLubyte (*)[4]) spec, \
1035	GL_POLYGON ); \
1036	} \
1037	}
1038
1039	#include "tritemp.h"
1040	}
1041
1042
1043
1044	/*
1045	* Compute the lambda value (texture level value) for a fragment.
1046	*/
1047	static GLfloat compute_lambda( GLfloat s, GLfloat dsdx, GLfloat dsdy,
1048	GLfloat t, GLfloat dtdx, GLfloat dtdy,
1049	GLfloat invQ, GLfloat dqdx, GLfloat dqdy,
1050	GLfloat width, GLfloat height )
1051	{
1052	GLfloat dudx, dudy, dvdx, dvdy;
1053	GLfloat r1, r2, rho2;
1054	GLfloat invQ_width = invQ * width;
1055	GLfloat invQ_height = invQ * height;
1056
1057	dudx = (dsdx - sdqdx) invQ_width;
1058	dudy = (dsdy - sdqdy) invQ_width;
1059	dvdx = (dtdx - tdqdx) invQ_height;
1060	dvdy = (dtdy - tdqdy) invQ_height;
1061
1062	r1 = dudx * dudx + dudy * dudy;
1063	r2 = dvdx * dvdx + dvdy * dvdy;
1064
1065	rho2 = r1 + r2; /* used to be: rho2 = MAX2(r1,r2); */
1066	ASSERT( rho2 >= 0.0 );
1067
1068	/* return log base 2 of rho */
1069	return log(rho2) * 1.442695 * 0.5; /* 1.442695 = 1/log(2) */
1070	}
1071
1072
1073	/*
1074	* Render a smooth-shaded, textured, RGBA triangle.
1075	* Interpolate S,T,U with perspective correction and compute lambda for
1076	* each fragment. Lambda is used to determine whether to use the
1077	* minification or magnification filter. If minification and using
1078	* mipmaps, lambda is also used to select the texture level of detail.
1079	*/
1080	static void lambda_textured_triangle1( GLcontext *ctx, GLuint v0, GLuint v1,
1081	GLuint v2, GLuint pv,
1082	GLfloat s[MAX_WIDTH],
1083	GLfloat t[MAX_WIDTH],
1084	GLfloat u[MAX_WIDTH] )
1085	{
1086	#define INTERP_Z 1
1087	#define INTERP_RGB 1
1088	#define INTERP_ALPHA 1
1089	#define INTERP_STUV 1
1090
1091	#define SETUP_CODE \
1092	const struct gl_texture_object *obj = ctx->Texture.Unit[0].Current; \
1093	const GLint baseLevel = obj->BaseLevel; \
1094	const struct gl_texture_image *texImage = obj->Image[baseLevel]; \
1095	const GLfloat twidth = (GLfloat) texImage->Width; \
1096	const GLfloat theight = (GLfloat) texImage->Height; \
1097	const GLboolean flat_shade = (ctx->Light.ShadeModel==GL_FLAT); \
1098	GLint r, g, b, a; \
1099	if (flat_shade) { \
1100	r = VB->ColorPtr->data[pv][0]; \
1101	g = VB->ColorPtr->data[pv][1]; \
1102	b = VB->ColorPtr->data[pv][2]; \
1103	a = VB->ColorPtr->data[pv][3]; \
1104	}
1105
1106	#define INNER_LOOP( LEFT, RIGHT, Y ) \
1107	{ \
1108	GLint i, n = RIGHT-LEFT; \
1109	GLdepth zspan[MAX_WIDTH]; \
1110	GLubyte rgba[MAX_WIDTH][4]; \
1111	GLfloat lambda[MAX_WIDTH]; \
1112	if (n>0) { \
1113	if (flat_shade) { \
1114	for (i=0;i<n;i++) { \
1115	GLdouble invQ = 1.0 / vv; \
1116	zspan[i] = FixedToDepth(ffz); \
1117	rgba[i][RCOMP] = r; \
1118	rgba[i][GCOMP] = g; \
1119	rgba[i][BCOMP] = b; \
1120	rgba[i][ACOMP] = a; \
1121	s[i] = ss*invQ; \
1122	t[i] = tt*invQ; \
1123	u[i] = uu*invQ; \
1124	lambda[i] = compute_lambda( s[i], dsdx, dsdy, \
1125	t[i], dtdx, dtdy, \
1126	invQ, dvdx, dvdy, \
1127	twidth, theight ); \
1128	ffz += fdzdx; \
1129	ss += dsdx; \
1130	tt += dtdx; \
1131	uu += dudx; \
1132	vv += dvdx; \
1133	} \
1134	} \
1135	else { \
1136	for (i=0;i<n;i++) { \
1137	GLdouble invQ = 1.0 / vv; \
1138	zspan[i] = FixedToDepth(ffz); \
1139	rgba[i][RCOMP] = FixedToInt(ffr); \
1140	rgba[i][GCOMP] = FixedToInt(ffg); \
1141	rgba[i][BCOMP] = FixedToInt(ffb); \
1142	rgba[i][ACOMP] = FixedToInt(ffa); \
1143	s[i] = ss*invQ; \
1144	t[i] = tt*invQ; \
1145	u[i] = uu*invQ; \
1146	lambda[i] = compute_lambda( s[i], dsdx, dsdy, \
1147	t[i], dtdx, dtdy, \
1148	invQ, dvdx, dvdy, \
1149	twidth, theight ); \
1150	ffz += fdzdx; \
1151	ffr += fdrdx; \
1152	ffg += fdgdx; \
1153	ffb += fdbdx; \
1154	ffa += fdadx; \
1155	ss += dsdx; \
1156	tt += dtdx; \
1157	uu += dudx; \
1158	vv += dvdx; \
1159	} \
1160	} \
1161	gl_write_texture_span( ctx, n, LEFT, Y, zspan, \
1162	s, t, u, lambda, \
1163	rgba, NULL, GL_POLYGON ); \
1164	} \
1165	}
1166
1167	#include "tritemp.h"
1168	}
1169
1170
1171	/*
1172	* Render a smooth-shaded, textured, RGBA triangle with separate specular
1173	* interpolation.
1174	* Interpolate S,T,U with perspective correction and compute lambda for
1175	* each fragment. Lambda is used to determine whether to use the
1176	* minification or magnification filter. If minification and using
1177	* mipmaps, lambda is also used to select the texture level of detail.
1178	*/
1179	static void lambda_textured_spec_triangle1( GLcontext *ctx, GLuint v0,
1180	GLuint v1, GLuint v2, GLuint pv,
1181	GLfloat s[MAX_WIDTH],
1182	GLfloat t[MAX_WIDTH],
1183	GLfloat u[MAX_WIDTH] )
1184	{
1185	#define INTERP_Z 1
1186	#define INTERP_RGB 1
1187	#define INTERP_SPEC 1
1188	#define INTERP_ALPHA 1
1189	#define INTERP_STUV 1
1190
1191	#define SETUP_CODE \
1192	const struct gl_texture_object *obj = ctx->Texture.Unit[0].Current; \
1193	const GLint baseLevel = obj->BaseLevel; \
1194	const struct gl_texture_image *texImage = obj->Image[baseLevel]; \
1195	const GLfloat twidth = (GLfloat) texImage->Width; \
1196	const GLfloat theight = (GLfloat) texImage->Height; \
1197	const GLboolean flat_shade = (ctx->Light.ShadeModel==GL_FLAT); \
1198	GLint r, g, b, a, sr, sg, sb; \
1199	if (flat_shade) { \
1200	r = VB->ColorPtr->data[pv][0]; \
1201	g = VB->ColorPtr->data[pv][1]; \
1202	b = VB->ColorPtr->data[pv][2]; \
1203	a = VB->ColorPtr->data[pv][3]; \
1204	sr = VB->Specular[pv][0]; \
1205	sg = VB->Specular[pv][1]; \
1206	sb = VB->Specular[pv][2]; \
1207	}
1208
1209	#define INNER_LOOP( LEFT, RIGHT, Y ) \
1210	{ \
1211	GLint i, n = RIGHT-LEFT; \
1212	GLdepth zspan[MAX_WIDTH]; \
1213	GLubyte spec[MAX_WIDTH][4]; \
1214	GLubyte rgba[MAX_WIDTH][4]; \
1215	GLfloat lambda[MAX_WIDTH]; \
1216	if (n>0) { \
1217	if (flat_shade) { \
1218	for (i=0;i<n;i++) { \
1219	GLdouble invQ = 1.0 / vv; \
1220	zspan[i] = FixedToDepth(ffz); \
1221	rgba[i][RCOMP] = r; \
1222	rgba[i][GCOMP] = g; \
1223	rgba[i][BCOMP] = b; \
1224	rgba[i][ACOMP] = a; \
1225	spec[i][RCOMP] = sr; \
1226	spec[i][GCOMP] = sg; \
1227	spec[i][BCOMP] = sb; \
1228	s[i] = ss*invQ; \
1229	t[i] = tt*invQ; \
1230	u[i] = uu*invQ; \
1231	lambda[i] = compute_lambda( s[i], dsdx, dsdy, \
1232	t[i], dtdx, dtdy, \
1233	invQ, dvdx, dvdy, \
1234	twidth, theight ); \
1235	ffz += fdzdx; \
1236	ss += dsdx; \
1237	tt += dtdx; \
1238	uu += dudx; \
1239	vv += dvdx; \
1240	} \
1241	} \
1242	else { \
1243	for (i=0;i<n;i++) { \
1244	GLdouble invQ = 1.0 / vv; \
1245	zspan[i] = FixedToDepth(ffz); \
1246	rgba[i][RCOMP] = FixedToInt(ffr); \
1247	rgba[i][GCOMP] = FixedToInt(ffg); \
1248	rgba[i][BCOMP] = FixedToInt(ffb); \
1249	rgba[i][ACOMP] = FixedToInt(ffa); \
1250	spec[i][RCOMP] = FixedToInt(ffsr); \
1251	spec[i][GCOMP] = FixedToInt(ffsg); \
1252	spec[i][BCOMP] = FixedToInt(ffsb); \
1253	s[i] = ss*invQ; \
1254	t[i] = tt*invQ; \
1255	u[i] = uu*invQ; \
1256	lambda[i] = compute_lambda( s[i], dsdx, dsdy, \
1257	t[i], dtdx, dtdy, \
1258	invQ, dvdx, dvdy, \
1259	twidth, theight ); \
1260	ffz += fdzdx; \
1261	ffr += fdrdx; \
1262	ffg += fdgdx; \
1263	ffb += fdbdx; \
1264	ffa += fdadx; \
1265	ffsr += fdsrdx; \
1266	ffsg += fdsgdx; \
1267	ffsb += fdsbdx; \
1268	ss += dsdx; \
1269	tt += dtdx; \
1270	uu += dudx; \
1271	vv += dvdx; \
1272	} \
1273	} \
1274	gl_write_texture_span( ctx, n, LEFT, Y, zspan, \
1275	s, t, u, lambda, \
1276	rgba, (const GLubyte (*)[4]) spec, \
1277	GL_POLYGON ); \
1278	} \
1279	}
1280
1281	#include "tritemp.h"
1282	}
1283
1284
1285	/*
1286	* This is the big one!
1287	* Interpolate Z, RGB, Alpha, and two sets of texture coordinates.
1288	* Yup, it's slow.
1289	*/
1290	static void lambda_multitextured_triangle1( GLcontext *ctx, GLuint v0,
1291	GLuint v1, GLuint v2, GLuint pv,
1292	GLfloat s[MAX_TEXTURE_UNITS][MAX_WIDTH],
1293	GLfloat t[MAX_TEXTURE_UNITS][MAX_WIDTH],
1294	GLfloat u[MAX_TEXTURE_UNITS][MAX_WIDTH]
1295	)
1296	{
1297	GLubyte rgba[MAX_WIDTH][4];
1298	#define INTERP_Z 1
1299	#define INTERP_RGB 1
1300	#define INTERP_ALPHA 1
1301	#define INTERP_STUV 1
1302	#define INTERP_STUV1 1
1303
1304	#define SETUP_CODE \
1305	const struct gl_texture_object *obj0 = ctx->Texture.Unit[0].Current; \
1306	const GLint baseLevel0 = obj0->BaseLevel; \
1307	const struct gl_texture_image *texImage0 = obj0->Image[baseLevel0]; \
1308	const GLfloat twidth0 = (GLfloat) texImage0->Width; \
1309	const GLfloat theight0 = (GLfloat) texImage0->Height; \
1310	const struct gl_texture_object *obj1 = ctx->Texture.Unit[1].Current; \
1311	const GLint baseLevel1 = obj1->BaseLevel; \
1312	const struct gl_texture_image *texImage1 = obj1->Image[baseLevel1]; \
1313	const GLfloat twidth1 = (GLfloat) texImage1->Width; \
1314	const GLfloat theight1 = (GLfloat) texImage1->Height; \
1315	const GLboolean flat_shade = (ctx->Light.ShadeModel==GL_FLAT); \
1316	GLint r, g, b, a; \
1317	if (flat_shade) { \
1318	r = VB->ColorPtr->data[pv][0]; \
1319	g = VB->ColorPtr->data[pv][1]; \
1320	b = VB->ColorPtr->data[pv][2]; \
1321	a = VB->ColorPtr->data[pv][3]; \
1322	}
1323
1324	#define INNER_LOOP( LEFT, RIGHT, Y ) \
1325	{ \
1326	GLint i, n = RIGHT-LEFT; \
1327	GLdepth zspan[MAX_WIDTH]; \
1328	GLfloat lambda[MAX_TEXTURE_UNITS][MAX_WIDTH]; \
1329	if (n>0) { \
1330	if (flat_shade) { \
1331	for (i=0;i<n;i++) { \
1332	GLdouble invQ = 1.0 / vv; \
1333	GLdouble invQ1 = 1.0 / vv1; \
1334	zspan[i] = FixedToDepth(ffz); \
1335	rgba[i][RCOMP] = r; \
1336	rgba[i][GCOMP] = g; \
1337	rgba[i][BCOMP] = b; \
1338	rgba[i][ACOMP] = a; \
1339	s[0][i] = ss*invQ; \
1340	t[0][i] = tt*invQ; \
1341	u[0][i] = uu*invQ; \
1342	lambda[0][i] = compute_lambda( s[0][i], dsdx, dsdy, \
1343	t[0][i], dtdx, dtdy, \
1344	invQ, dvdx, dvdy, \
1345	twidth0, theight0 ); \
1346	s[1][i] = ss1*invQ1; \
1347	t[1][i] = tt1*invQ1; \
1348	u[1][i] = uu1*invQ1; \
1349	lambda[1][i] = compute_lambda( s[1][i], ds1dx, ds1dy, \
1350	t[1][i], dt1dx, dt1dy, \
1351	invQ1, dvdx, dvdy, \
1352	twidth1, theight1 ); \
1353	ffz += fdzdx; \
1354	ss += dsdx; \
1355	tt += dtdx; \
1356	uu += dudx; \
1357	vv += dvdx; \
1358	ss1 += ds1dx; \
1359	tt1 += dt1dx; \
1360	uu1 += du1dx; \
1361	vv1 += dv1dx; \
1362	} \
1363	} \
1364	else { \
1365	for (i=0;i<n;i++) { \
1366	GLdouble invQ = 1.0 / vv; \
1367	GLdouble invQ1 = 1.0 / vv1; \
1368	zspan[i] = FixedToDepth(ffz); \
1369	rgba[i][RCOMP] = FixedToInt(ffr); \
1370	rgba[i][GCOMP] = FixedToInt(ffg); \
1371	rgba[i][BCOMP] = FixedToInt(ffb); \
1372	rgba[i][ACOMP] = FixedToInt(ffa); \
1373	s[0][i] = ss*invQ; \
1374	t[0][i] = tt*invQ; \
1375	u[0][i] = uu*invQ; \
1376	lambda[0][i] = compute_lambda( s[0][i], dsdx, dsdy, \
1377	t[0][i], dtdx, dtdy, \
1378	invQ, dvdx, dvdy, \
1379	twidth0, theight0 ); \
1380	s[1][i] = ss1*invQ1; \
1381	t[1][i] = tt1*invQ1; \
1382	u[1][i] = uu1*invQ1; \
1383	lambda[1][i] = compute_lambda( s[1][i], ds1dx, ds1dy, \
1384	t[1][i], dt1dx, dt1dy, \
1385	invQ1, dvdx, dvdy, \
1386	twidth1, theight1 ); \
1387	ffz += fdzdx; \
1388	ffr += fdrdx; \
1389	ffg += fdgdx; \
1390	ffb += fdbdx; \
1391	ffa += fdadx; \
1392	ss += dsdx; \
1393	tt += dtdx; \
1394	uu += dudx; \
1395	vv += dvdx; \
1396	ss1 += ds1dx; \
1397	tt1 += dt1dx; \
1398	uu1 += du1dx; \
1399	vv1 += dv1dx; \
1400	} \
1401	} \
1402	gl_write_multitexture_span( ctx, 2, n, LEFT, Y, zspan, \
1403	(const GLfloat (*)[MAX_WIDTH]) s, \
1404	(const GLfloat (*)[MAX_WIDTH]) t, \
1405	(const GLfloat (*)[MAX_WIDTH]) u, \
1406	(GLfloat (*)[MAX_WIDTH]) lambda, \
1407	rgba, NULL, GL_POLYGON ); \
1408	} \
1409	}
1410
1411	#include "tritemp.h"
1412	}
1413
1414
1415	/*
1416	* These wrappers are needed to deal with the 32KB / stack frame limit
1417	* on Mac / PowerPC systems.
1418	*/
1419
1420	static void general_textured_spec_triangle(GLcontext *ctx, GLuint v0,
1421	GLuint v1, GLuint v2, GLuint pv)
1422	{
1423	GLdepth zspan[MAX_WIDTH];
1424	GLubyte rgba[MAX_WIDTH][4], spec[MAX_WIDTH][4];
1425	general_textured_spec_triangle1(ctx,v0,v1,v2,pv,zspan,rgba,spec);
1426	}
1427
1428	static void lambda_textured_triangle( GLcontext *ctx, GLuint v0,
1429	GLuint v1, GLuint v2, GLuint pv )
1430	{
1431	GLfloat s[MAX_WIDTH], t[MAX_WIDTH], u[MAX_WIDTH];
1432	lambda_textured_triangle1(ctx,v0,v1,v2,pv,s,t,u);
1433	}
1434
1435	static void lambda_textured_spec_triangle( GLcontext *ctx, GLuint v0,
1436	GLuint v1, GLuint v2, GLuint pv )
1437	{
1438	GLfloat s[MAX_WIDTH];
1439	GLfloat t[MAX_WIDTH];
1440	GLfloat u[MAX_WIDTH];
1441	lambda_textured_spec_triangle1(ctx,v0,v1,v2,pv,s,t,u);
1442	}
1443
1444
1445	static void lambda_multitextured_triangle( GLcontext *ctx, GLuint v0,
1446	GLuint v1, GLuint v2, GLuint pv)
1447	{
1448
1449	GLfloat s[MAX_TEXTURE_UNITS][MAX_WIDTH];
1450	GLfloat t[MAX_TEXTURE_UNITS][MAX_WIDTH];
1451	DEFMARRAY(GLfloat,u,MAX_TEXTURE_UNITS,MAX_WIDTH);
1452	CHECKARRAY(u,return);
1453
1454	lambda_multitextured_triangle1(ctx,v0,v1,v2,pv,s,t,u);
1455
1456	UNDEFARRAY(u);
1457	}
1458
1459
1460	/*
1461	* Null rasterizer for measuring transformation speed.
1462	*/
1463	static void null_triangle( GLcontext *ctx, GLuint v0, GLuint v1,
1464	GLuint v2, GLuint pv )
1465	{
1466	(void) ctx;
1467	(void) v0;
1468	(void) v1;
1469	(void) v2;
1470	(void) pv;
1471	}
1472
1473
1474	#if 0
1475	# define dputs(s) puts(s)
1476	#else
1477	# define dputs(s)
1478	#endif
1479
1480	/*
1481	* Determine which triangle rendering function to use given the current
1482	* rendering context.
1483	*/
1484	void gl_set_triangle_function( GLcontext *ctx )
1485	{
1486	GLboolean rgbmode = ctx->Visual->RGBAflag;
1487
1488	if (ctx->RenderMode==GL_RENDER) {
1489	if (ctx->NoRaster) {
1490	ctx->Driver.TriangleFunc = null_triangle;
1491	return;
1492	}
1493	if (ctx->Driver.TriangleFunc) {
1494	/* Device driver will draw triangles. */
1495	return;
1496	}
1497
1498	if (ctx->Texture.ReallyEnabled) {
1499	/* Ugh, we do a _lot_ of tests to pick the best textured tri func */
1500	int format, filter;
1501	const struct gl_texture_object *current2Dtex = ctx->Texture.Unit[0].CurrentD[2];
1502	const struct gl_texture_image *image;
1503	/* First see if we can used an optimized 2-D texture function */
1504	if (ctx->Texture.ReallyEnabled==TEXTURE0_2D
1505	&& current2Dtex->WrapS==GL_REPEAT
1506	&& current2Dtex->WrapT==GL_REPEAT
1507	&& ((image = current2Dtex->Image[current2Dtex->BaseLevel]) != 0) /* correct! */
1508	&& image->Border==0
1509	&& ((format = image->Format)==GL_RGB \|\| format==GL_RGBA)
1510	&& (filter = current2Dtex->MinFilter)==current2Dtex->MagFilter
1511	&& ctx->Light.Model.ColorControl==GL_SINGLE_COLOR) {
1512
1513	if (ctx->Hint.PerspectiveCorrection==GL_FASTEST) {
1514
1515	if (filter==GL_NEAREST
1516	&& format==GL_RGB
1517	&& (ctx->Texture.Unit[0].EnvMode==GL_REPLACE
1518	\|\| ctx->Texture.Unit[0].EnvMode==GL_DECAL)
1519	&& ((ctx->RasterMask==DEPTH_BIT
1520	&& ctx->Depth.Func==GL_LESS
1521	&& ctx->Depth.Mask==GL_TRUE)
1522	\|\| ctx->RasterMask==0)
1523	&& ctx->Polygon.StippleFlag==GL_FALSE) {
1524
1525	if (ctx->RasterMask==DEPTH_BIT) {
1526	ctx->Driver.TriangleFunc = simple_z_textured_triangle;
1527	dputs("simple_z_textured_triangle");
1528	}
1529	else {
1530	ctx->Driver.TriangleFunc = simple_textured_triangle;
1531	dputs("simple_textured_triangle");
1532	}
1533	}
1534	else {
1535	ctx->Driver.TriangleFunc = affine_textured_triangle;
1536	dputs("affine_textured_triangle");
1537	}
1538	}
1539	else {
1540	/ctx->Driver.TriangleFunc = persp_textured_triangle;/
1541	ctx->Driver.TriangleFunc = general_textured_triangle;
1542	dputs("persp_textured_triangle");
1543	}
1544	}
1545	else {
1546	/* More complicated textures (mipmap, multi-tex, sep specular) */
1547	GLboolean needLambda;
1548	/* if mag filter != min filter we need to compute lambda */
1549	const struct gl_texture_object *obj0 = ctx->Texture.Unit[0].Current;
1550	const struct gl_texture_object *obj1 = ctx->Texture.Unit[1].Current;
1551	if (obj0 && obj0->MinFilter != obj0->MagFilter)
1552	needLambda = GL_TRUE;
1553	else if (obj1 && obj1->MinFilter != obj1->MagFilter)
1554	needLambda = GL_TRUE;
1555	else
1556	needLambda = GL_FALSE;
1557	if (ctx->Texture.ReallyEnabled >= TEXTURE1_1D) {
1558	/* multi-texture! */
1559	ctx->Driver.TriangleFunc = lambda_multitextured_triangle;
1560	dputs("lambda_multitextured_triangle");
1561	}
1562	else if (ctx->Light.Enabled &&
1563	ctx->Light.Model.ColorControl==GL_SEPARATE_SPECULAR_COLOR) {
1564	/* separate specular color interpolation */
1565	if (needLambda) {
1566	ctx->Driver.TriangleFunc = lambda_textured_spec_triangle;
1567	dputs("lambda_textured_spec_triangle");
1568	}
1569	else {
1570	ctx->Driver.TriangleFunc = general_textured_spec_triangle;
1571	dputs("general_textured_spec_triangle");
1572	}
1573	}
1574	else {
1575	if (needLambda) {
1576	ctx->Driver.TriangleFunc = lambda_textured_triangle;
1577	dputs("lambda_textured_triangle");
1578	}
1579	else {
1580	ctx->Driver.TriangleFunc = general_textured_triangle;
1581	dputs("general_textured_triangle");
1582	}
1583	}
1584	}
1585	}
1586	else {
1587	if (ctx->Light.ShadeModel==GL_SMOOTH) {
1588	/* smooth shaded, no texturing, stippled or some raster ops */
1589	if (rgbmode)
1590	ctx->Driver.TriangleFunc = smooth_rgba_triangle;
1591	else
1592	ctx->Driver.TriangleFunc = smooth_ci_triangle;
1593	}
1594	else {
1595	/* flat shaded, no texturing, stippled or some raster ops */
1596	if (rgbmode)
1597	ctx->Driver.TriangleFunc = flat_rgba_triangle;
1598	else
1599	ctx->Driver.TriangleFunc = flat_ci_triangle;
1600	}
1601	}
1602	}
1603	else if (ctx->RenderMode==GL_FEEDBACK) {
1604	ctx->Driver.TriangleFunc = gl_feedback_triangle;
1605	}
1606	else {
1607	/* GL_SELECT mode */
1608	ctx->Driver.TriangleFunc = gl_select_triangle;
1609	}
1610	}

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