• Home
  • Line#
  • Scopes#
  • Navigate#
  • Raw
  • Download
1 /**************************************************************************
2  *
3  * Copyright 2003 VMware, Inc.
4  * All Rights Reserved.
5  *
6  * Permission is hereby granted, free of charge, to any person obtaining a
7  * copy of this software and associated documentation files (the
8  * "Software"), to deal in the Software without restriction, including
9  * without limitation the rights to use, copy, modify, merge, publish,
10  * distribute, sub license, and/or sell copies of the Software, and to
11  * permit persons to whom the Software is furnished to do so, subject to
12  * the following conditions:
13  *
14  * The above copyright notice and this permission notice (including the
15  * next paragraph) shall be included in all copies or substantial portions
16  * of the Software.
17  *
18  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
19  * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
20  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT.
21  * IN NO EVENT SHALL VMWARE AND/OR ITS SUPPLIERS BE LIABLE FOR
22  * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
23  * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
24  * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
25  *
26  **************************************************************************/
27 
28 #include "main/glheader.h"
29 #include "main/macros.h"
30 #include "main/enums.h"
31 
32 #include "program/prog_instruction.h"
33 #include "program/prog_parameter.h"
34 #include "program/program.h"
35 #include "program/programopt.h"
36 #include "program/prog_print.h"
37 
38 #include "tnl/tnl.h"
39 #include "tnl/t_context.h"
40 
41 #include "intel_batchbuffer.h"
42 
43 #include "i915_reg.h"
44 #include "i915_context.h"
45 #include "i915_program.h"
46 
47 static const GLfloat sin_quad_constants[2][4] = {
48    {
49       2.0,
50       -1.0,
51       .5,
52       .75
53    },
54    {
55       4.0,
56       -4.0,
57       1.0 / (2.0 * M_PI),
58       .2225
59    }
60 };
61 
62 static const GLfloat sin_constants[4] = { 1.0,
63    -1.0 / (3 * 2 * 1),
64    1.0 / (5 * 4 * 3 * 2 * 1),
65    -1.0 / (7 * 6 * 5 * 4 * 3 * 2 * 1)
66 };
67 
68 /* 1, -1/2!, 1/4!, -1/6! */
69 static const GLfloat cos_constants[4] = { 1.0,
70    -1.0 / (2 * 1),
71    1.0 / (4 * 3 * 2 * 1),
72    -1.0 / (6 * 5 * 4 * 3 * 2 * 1)
73 };
74 
75 /* texcoord_mapping[unit] = index | TEXCOORD_{TEX,VAR} */
76 #define TEXCOORD_TEX (0<<7)
77 #define TEXCOORD_VAR (1<<7)
78 
79 static unsigned
get_texcoord_mapping(struct i915_fragment_program * p,uint8_t texcoord)80 get_texcoord_mapping(struct i915_fragment_program *p, uint8_t texcoord)
81 {
82    for (unsigned i = 0; i < p->ctx->Const.MaxTextureCoordUnits; i++) {
83       if (p->texcoord_mapping[i] == texcoord)
84          return i;
85    }
86 
87    /* blah */
88    return p->ctx->Const.MaxTextureCoordUnits - 1;
89 }
90 
91 /**
92  * Retrieve a ureg for the given source register.  Will emit
93  * constants, apply swizzling and negation as needed.
94  */
95 static GLuint
src_vector(struct i915_fragment_program * p,const struct prog_src_register * source,const struct gl_program * program)96 src_vector(struct i915_fragment_program *p,
97            const struct prog_src_register *source,
98            const struct gl_program *program)
99 {
100    GLuint src;
101    unsigned unit;
102 
103    switch (source->File) {
104 
105       /* Registers:
106        */
107    case PROGRAM_TEMPORARY:
108       if (source->Index >= I915_MAX_TEMPORARY) {
109          i915_program_error(p, "Exceeded max temporary reg: %d/%d",
110 			    source->Index, I915_MAX_TEMPORARY);
111          return 0;
112       }
113       src = UREG(REG_TYPE_R, source->Index);
114       break;
115    case PROGRAM_INPUT:
116       switch (source->Index) {
117       case VARYING_SLOT_POS:
118          src = i915_emit_decl(p, REG_TYPE_T, p->wpos_tex, D0_CHANNEL_ALL);
119          break;
120       case VARYING_SLOT_COL0:
121          src = i915_emit_decl(p, REG_TYPE_T, T_DIFFUSE, D0_CHANNEL_ALL);
122          break;
123       case VARYING_SLOT_COL1:
124          src = i915_emit_decl(p, REG_TYPE_T, T_SPECULAR, D0_CHANNEL_XYZ);
125          src = swizzle(src, X, Y, Z, ONE);
126          break;
127       case VARYING_SLOT_FOGC:
128          src = i915_emit_decl(p, REG_TYPE_T, T_FOG_W, D0_CHANNEL_W);
129          src = swizzle(src, W, ZERO, ZERO, ONE);
130          break;
131       case VARYING_SLOT_TEX0:
132       case VARYING_SLOT_TEX1:
133       case VARYING_SLOT_TEX2:
134       case VARYING_SLOT_TEX3:
135       case VARYING_SLOT_TEX4:
136       case VARYING_SLOT_TEX5:
137       case VARYING_SLOT_TEX6:
138       case VARYING_SLOT_TEX7:
139          unit = get_texcoord_mapping(p, (source->Index -
140                                          VARYING_SLOT_TEX0) | TEXCOORD_TEX);
141          src = i915_emit_decl(p, REG_TYPE_T,
142                               T_TEX0 + unit,
143                               D0_CHANNEL_ALL);
144 	 break;
145 
146       case VARYING_SLOT_VAR0:
147       case VARYING_SLOT_VAR0 + 1:
148       case VARYING_SLOT_VAR0 + 2:
149       case VARYING_SLOT_VAR0 + 3:
150       case VARYING_SLOT_VAR0 + 4:
151       case VARYING_SLOT_VAR0 + 5:
152       case VARYING_SLOT_VAR0 + 6:
153       case VARYING_SLOT_VAR0 + 7:
154          unit = get_texcoord_mapping(p, (source->Index -
155                                          VARYING_SLOT_VAR0) | TEXCOORD_VAR);
156          src = i915_emit_decl(p, REG_TYPE_T,
157                               T_TEX0 + unit,
158                               D0_CHANNEL_ALL);
159          break;
160 
161       default:
162          i915_program_error(p, "Bad source->Index: %d", source->Index);
163          return 0;
164       }
165       break;
166 
167    case PROGRAM_OUTPUT:
168       switch (source->Index) {
169       case FRAG_RESULT_COLOR:
170       case FRAG_RESULT_DATA0:
171 	 src = UREG(REG_TYPE_OC, 0);
172 	 break;
173       case FRAG_RESULT_DEPTH:
174 	 src = UREG(REG_TYPE_OD, 0);
175 	 break;
176       default:
177 	 i915_program_error(p, "Bad source->Index: %d", source->Index);
178 	 return 0;
179       }
180       break;
181 
182       /* Various paramters and env values.  All emitted to
183        * hardware as program constants.
184        */
185    case PROGRAM_CONSTANT:
186    case PROGRAM_STATE_VAR:
187    case PROGRAM_UNIFORM: {
188       struct gl_program_parameter_list *params = program->Parameters;
189       unsigned offset = params->ParameterValueOffset[source->Index];
190       src = i915_emit_param4fv(p, &params->ParameterValues[offset].f);
191       break;
192    }
193    default:
194       i915_program_error(p, "Bad source->File: %d", source->File);
195       return 0;
196    }
197 
198    src = swizzle(src,
199                  GET_SWZ(source->Swizzle, 0),
200                  GET_SWZ(source->Swizzle, 1),
201                  GET_SWZ(source->Swizzle, 2), GET_SWZ(source->Swizzle, 3));
202 
203    if (source->Negate)
204       src = negate(src,
205                    GET_BIT(source->Negate, 0),
206                    GET_BIT(source->Negate, 1),
207                    GET_BIT(source->Negate, 2),
208                    GET_BIT(source->Negate, 3));
209 
210    return src;
211 }
212 
213 
214 static GLuint
get_result_vector(struct i915_fragment_program * p,const struct prog_instruction * inst)215 get_result_vector(struct i915_fragment_program *p,
216                   const struct prog_instruction *inst)
217 {
218    switch (inst->DstReg.File) {
219    case PROGRAM_OUTPUT:
220       switch (inst->DstReg.Index) {
221       case FRAG_RESULT_COLOR:
222       case FRAG_RESULT_DATA0:
223          return UREG(REG_TYPE_OC, 0);
224       case FRAG_RESULT_DEPTH:
225          p->depth_written = 1;
226          return UREG(REG_TYPE_OD, 0);
227       default:
228          i915_program_error(p, "Bad inst->DstReg.Index: %d",
229 			    inst->DstReg.Index);
230          return 0;
231       }
232    case PROGRAM_TEMPORARY:
233       return UREG(REG_TYPE_R, inst->DstReg.Index);
234    default:
235       i915_program_error(p, "Bad inst->DstReg.File: %d", inst->DstReg.File);
236       return 0;
237    }
238 }
239 
240 static GLuint
get_result_flags(const struct prog_instruction * inst)241 get_result_flags(const struct prog_instruction *inst)
242 {
243    GLuint flags = 0;
244 
245    if (inst->Saturate)
246       flags |= A0_DEST_SATURATE;
247    if (inst->DstReg.WriteMask & WRITEMASK_X)
248       flags |= A0_DEST_CHANNEL_X;
249    if (inst->DstReg.WriteMask & WRITEMASK_Y)
250       flags |= A0_DEST_CHANNEL_Y;
251    if (inst->DstReg.WriteMask & WRITEMASK_Z)
252       flags |= A0_DEST_CHANNEL_Z;
253    if (inst->DstReg.WriteMask & WRITEMASK_W)
254       flags |= A0_DEST_CHANNEL_W;
255 
256    return flags;
257 }
258 
259 static GLuint
translate_tex_src_target(struct i915_fragment_program * p,GLubyte bit)260 translate_tex_src_target(struct i915_fragment_program *p, GLubyte bit)
261 {
262    switch (bit) {
263    case TEXTURE_1D_INDEX:
264       return D0_SAMPLE_TYPE_2D;
265    case TEXTURE_2D_INDEX:
266       return D0_SAMPLE_TYPE_2D;
267    case TEXTURE_RECT_INDEX:
268       return D0_SAMPLE_TYPE_2D;
269    case TEXTURE_3D_INDEX:
270       return D0_SAMPLE_TYPE_VOLUME;
271    case TEXTURE_CUBE_INDEX:
272       return D0_SAMPLE_TYPE_CUBE;
273    default:
274       i915_program_error(p, "TexSrcBit: %d", bit);
275       return 0;
276    }
277 }
278 
279 #define EMIT_TEX( OP )						\
280 do {								\
281    GLuint dim = translate_tex_src_target( p, inst->TexSrcTarget );	\
282    const struct gl_program *program = &p->FragProg;	\
283    GLuint unit = program->SamplerUnits[inst->TexSrcUnit];	\
284    GLuint sampler = i915_emit_decl(p, REG_TYPE_S,		\
285 				   unit, dim);			\
286    GLuint coord = src_vector( p, &inst->SrcReg[0], program);	\
287    /* Texel lookup */						\
288 								\
289    i915_emit_texld( p, get_live_regs(p, inst),						\
290 	       get_result_vector( p, inst ),			\
291 	       get_result_flags( inst ),			\
292 	       sampler,						\
293 	       coord,						\
294 	       OP);						\
295 } while (0)
296 
297 #define EMIT_ARITH( OP, N )						\
298 do {									\
299    i915_emit_arith( p,							\
300 	       OP,							\
301 	       get_result_vector( p, inst ), 				\
302 	       get_result_flags( inst ), 0,			\
303 	       (N<1)?0:src_vector( p, &inst->SrcReg[0], program),	\
304 	       (N<2)?0:src_vector( p, &inst->SrcReg[1], program),	\
305 	       (N<3)?0:src_vector( p, &inst->SrcReg[2], program));	\
306 } while (0)
307 
308 #define EMIT_1ARG_ARITH( OP ) EMIT_ARITH( OP, 1 )
309 #define EMIT_2ARG_ARITH( OP ) EMIT_ARITH( OP, 2 )
310 #define EMIT_3ARG_ARITH( OP ) EMIT_ARITH( OP, 3 )
311 
312 /*
313  * TODO: consider moving this into core
314  */
calc_live_regs(struct i915_fragment_program * p)315 static bool calc_live_regs( struct i915_fragment_program *p )
316 {
317     const struct gl_program *program = &p->FragProg;
318     GLuint regsUsed = ~((1 << I915_MAX_TEMPORARY) - 1);
319     uint8_t live_components[I915_MAX_TEMPORARY] = { 0, };
320     GLint i;
321 
322     for (i = program->arb.NumInstructions - 1; i >= 0; i--) {
323         struct prog_instruction *inst = &program->arb.Instructions[i];
324         int opArgs = _mesa_num_inst_src_regs(inst->Opcode);
325         int a;
326 
327         /* Register is written to: unmark as live for this and preceeding ops */
328         if (inst->DstReg.File == PROGRAM_TEMPORARY) {
329 	    if (inst->DstReg.Index >= I915_MAX_TEMPORARY)
330 	       return false;
331 
332             live_components[inst->DstReg.Index] &= ~inst->DstReg.WriteMask;
333             if (live_components[inst->DstReg.Index] == 0)
334                 regsUsed &= ~(1 << inst->DstReg.Index);
335         }
336 
337         for (a = 0; a < opArgs; a++) {
338             /* Register is read from: mark as live for this and preceeding ops */
339             if (inst->SrcReg[a].File == PROGRAM_TEMPORARY) {
340                 unsigned c;
341 
342 		if (inst->SrcReg[a].Index >= I915_MAX_TEMPORARY)
343 		   return false;
344 
345                 regsUsed |= 1 << inst->SrcReg[a].Index;
346 
347                 for (c = 0; c < 4; c++) {
348                     const unsigned field = GET_SWZ(inst->SrcReg[a].Swizzle, c);
349 
350                     if (field <= SWIZZLE_W)
351                         live_components[inst->SrcReg[a].Index] |= (1U << field);
352                 }
353             }
354         }
355 
356         p->usedRegs[i] = regsUsed;
357     }
358 
359     return true;
360 }
361 
get_live_regs(struct i915_fragment_program * p,const struct prog_instruction * inst)362 static GLuint get_live_regs( struct i915_fragment_program *p,
363                              const struct prog_instruction *inst )
364 {
365     const struct gl_program *program = &p->FragProg;
366     GLuint nr = inst - program->arb.Instructions;
367 
368     return p->usedRegs[nr];
369 }
370 
371 
372 /* Possible concerns:
373  *
374  * SIN, COS -- could use another taylor step?
375  * LIT      -- results seem a little different to sw mesa
376  * LOG      -- different to mesa on negative numbers, but this is conformant.
377  *
378  * Parse failures -- Mesa doesn't currently give a good indication
379  * internally whether a particular program string parsed or not.  This
380  * can lead to confusion -- hopefully we cope with it ok now.
381  *
382  */
383 static void
upload_program(struct i915_fragment_program * p)384 upload_program(struct i915_fragment_program *p)
385 {
386    const struct gl_program *program = &p->FragProg;
387    const struct prog_instruction *inst = program->arb.Instructions;
388 
389    if (INTEL_DEBUG & DEBUG_WM)
390       _mesa_print_program(program);
391 
392    /* Is this a parse-failed program?  Ensure a valid program is
393     * loaded, as the flagging of an error isn't sufficient to stop
394     * this being uploaded to hardware.
395     */
396    if (inst[0].Opcode == OPCODE_END) {
397       GLuint tmp = i915_get_utemp(p);
398       i915_emit_arith(p,
399                       A0_MOV,
400                       UREG(REG_TYPE_OC, 0),
401                       A0_DEST_CHANNEL_ALL, 0,
402                       swizzle(tmp, ONE, ZERO, ONE, ONE), 0, 0);
403       return;
404    }
405 
406    if (program->arb.NumInstructions > I915_MAX_INSN) {
407       i915_program_error(p, "Exceeded max instructions (%d out of %d)",
408                          program->arb.NumInstructions, I915_MAX_INSN);
409       return;
410    }
411 
412    /* Not always needed:
413     */
414    if (!calc_live_regs(p)) {
415       i915_program_error(p, "Could not allocate registers");
416       return;
417    }
418 
419    while (1) {
420       GLuint src0, src1, src2, flags;
421       GLuint tmp = 0, dst, consts0 = 0, consts1 = 0;
422 
423       switch (inst->Opcode) {
424       case OPCODE_ABS:
425          src0 = src_vector(p, &inst->SrcReg[0], program);
426          i915_emit_arith(p,
427                          A0_MAX,
428                          get_result_vector(p, inst),
429                          get_result_flags(inst), 0,
430                          src0, negate(src0, 1, 1, 1, 1), 0);
431          break;
432 
433       case OPCODE_ADD:
434          EMIT_2ARG_ARITH(A0_ADD);
435          break;
436 
437       case OPCODE_CMP:
438          src0 = src_vector(p, &inst->SrcReg[0], program);
439          src1 = src_vector(p, &inst->SrcReg[1], program);
440          src2 = src_vector(p, &inst->SrcReg[2], program);
441          i915_emit_arith(p, A0_CMP, get_result_vector(p, inst), get_result_flags(inst), 0, src0, src2, src1);   /* NOTE: order of src2, src1 */
442          break;
443 
444       case OPCODE_COS:
445          src0 = src_vector(p, &inst->SrcReg[0], program);
446          tmp = i915_get_utemp(p);
447 	 consts0 = i915_emit_const4fv(p, sin_quad_constants[0]);
448 	 consts1 = i915_emit_const4fv(p, sin_quad_constants[1]);
449 
450 	 /* Reduce range from repeating about [-pi,pi] to [-1,1] */
451          i915_emit_arith(p,
452                          A0_MAD,
453                          tmp, A0_DEST_CHANNEL_X, 0,
454                          src0,
455 			 swizzle(consts1, Z, ZERO, ZERO, ZERO), /* 1/(2pi) */
456 			 swizzle(consts0, W, ZERO, ZERO, ZERO)); /* .75 */
457 
458          i915_emit_arith(p, A0_FRC, tmp, A0_DEST_CHANNEL_X, 0, tmp, 0, 0);
459 
460 	 i915_emit_arith(p,
461 			 A0_MAD,
462 			 tmp, A0_DEST_CHANNEL_X, 0,
463 			 tmp,
464 			 swizzle(consts0, X, ZERO, ZERO, ZERO), /* 2 */
465 			 swizzle(consts0, Y, ZERO, ZERO, ZERO)); /* -1 */
466 
467 	 /* Compute COS with the same calculation used for SIN, but a
468 	  * different source range has been mapped to [-1,1] this time.
469 	  */
470 
471 	 /* tmp.y = abs(tmp.x); {x, abs(x), 0, 0} */
472 	 i915_emit_arith(p,
473                          A0_MAX,
474 			 tmp, A0_DEST_CHANNEL_Y, 0,
475 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
476 			 negate(swizzle(tmp, ZERO, X, ZERO, ZERO), 0, 1, 0, 0),
477 			 0);
478 
479 	 /* tmp.y = tmp.y * tmp.x; {x, x * abs(x), 0, 0} */
480 	 i915_emit_arith(p,
481 			 A0_MUL,
482 			 tmp, A0_DEST_CHANNEL_Y, 0,
483 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
484 			 tmp,
485 			 0);
486 
487 	 /* tmp.x = tmp.xy DP sin_quad_constants[2].xy */
488          i915_emit_arith(p,
489                          A0_DP3,
490                          tmp, A0_DEST_CHANNEL_X, 0,
491 			 tmp,
492                          swizzle(consts1, X, Y, ZERO, ZERO),
493 			 0);
494 
495 	 /* tmp.x now contains a first approximation (y).  Now, weight it
496 	  * against tmp.y**2 to get closer.
497 	  */
498 	 i915_emit_arith(p,
499                          A0_MAX,
500 			 tmp, A0_DEST_CHANNEL_Y, 0,
501 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
502 			 negate(swizzle(tmp, ZERO, X, ZERO, ZERO), 0, 1, 0, 0),
503 			 0);
504 
505 	 /* tmp.y = tmp.x * tmp.y - tmp.x; {y, y * abs(y) - y, 0, 0} */
506 	 i915_emit_arith(p,
507 			 A0_MAD,
508 			 tmp, A0_DEST_CHANNEL_Y, 0,
509 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
510 			 swizzle(tmp, ZERO, Y, ZERO, ZERO),
511 			 negate(swizzle(tmp, ZERO, X, ZERO, ZERO), 0, 1, 0, 0));
512 
513 	 /* result = .2225 * tmp.y + tmp.x =.2225(y * abs(y) - y) + y= */
514 	 i915_emit_arith(p,
515 			 A0_MAD,
516                          get_result_vector(p, inst),
517                          get_result_flags(inst), 0,
518 			 swizzle(consts1, W, W, W, W),
519 			 swizzle(tmp, Y, Y, Y, Y),
520 			 swizzle(tmp, X, X, X, X));
521          break;
522 
523       case OPCODE_DP2:
524          src0 = src_vector(p, &inst->SrcReg[0], program);
525          src1 = src_vector(p, &inst->SrcReg[1], program);
526 	 i915_emit_arith(p,
527 			 A0_DP3,
528                          get_result_vector(p, inst),
529                          get_result_flags(inst), 0,
530 			 swizzle(src0, X, Y, ZERO, ZERO),
531 			 swizzle(src1, X, Y, ZERO, ZERO),
532 			 0);
533          break;
534 
535       case OPCODE_DP3:
536          EMIT_2ARG_ARITH(A0_DP3);
537          break;
538 
539       case OPCODE_DP4:
540          EMIT_2ARG_ARITH(A0_DP4);
541          break;
542 
543       case OPCODE_DPH:
544          src0 = src_vector(p, &inst->SrcReg[0], program);
545          src1 = src_vector(p, &inst->SrcReg[1], program);
546 
547          i915_emit_arith(p,
548                          A0_DP4,
549                          get_result_vector(p, inst),
550                          get_result_flags(inst), 0,
551                          swizzle(src0, X, Y, Z, ONE), src1, 0);
552          break;
553 
554       case OPCODE_DST:
555          src0 = src_vector(p, &inst->SrcReg[0], program);
556          src1 = src_vector(p, &inst->SrcReg[1], program);
557 
558          /* result[0] = 1    * 1;
559           * result[1] = a[1] * b[1];
560           * result[2] = a[2] * 1;
561           * result[3] = 1    * b[3];
562           */
563          i915_emit_arith(p,
564                          A0_MUL,
565                          get_result_vector(p, inst),
566                          get_result_flags(inst), 0,
567                          swizzle(src0, ONE, Y, Z, ONE),
568                          swizzle(src1, ONE, Y, ONE, W), 0);
569          break;
570 
571       case OPCODE_EX2:
572          src0 = src_vector(p, &inst->SrcReg[0], program);
573 
574          i915_emit_arith(p,
575                          A0_EXP,
576                          get_result_vector(p, inst),
577                          get_result_flags(inst), 0,
578                          swizzle(src0, X, X, X, X), 0, 0);
579          break;
580 
581       case OPCODE_FLR:
582          EMIT_1ARG_ARITH(A0_FLR);
583          break;
584 
585       case OPCODE_TRUNC:
586 	 EMIT_1ARG_ARITH(A0_TRC);
587 	 break;
588 
589       case OPCODE_FRC:
590          EMIT_1ARG_ARITH(A0_FRC);
591          break;
592 
593       case OPCODE_KIL:
594          src0 = src_vector(p, &inst->SrcReg[0], program);
595          tmp = i915_get_utemp(p);
596 
597          i915_emit_texld(p, get_live_regs(p, inst),
598                          tmp, A0_DEST_CHANNEL_ALL,   /* use a dummy dest reg */
599                          0, src0, T0_TEXKILL);
600          break;
601 
602       case OPCODE_LG2:
603          src0 = src_vector(p, &inst->SrcReg[0], program);
604 
605          i915_emit_arith(p,
606                          A0_LOG,
607                          get_result_vector(p, inst),
608                          get_result_flags(inst), 0,
609                          swizzle(src0, X, X, X, X), 0, 0);
610          break;
611 
612       case OPCODE_LIT:
613          src0 = src_vector(p, &inst->SrcReg[0], program);
614          tmp = i915_get_utemp(p);
615 
616          /* tmp = max( a.xyzw, a.00zw )
617           * XXX: Clamp tmp.w to -128..128
618           * tmp.y = log(tmp.y)
619           * tmp.y = tmp.w * tmp.y
620           * tmp.y = exp(tmp.y)
621           * result = cmp (a.11-x1, a.1x01, a.1xy1 )
622           */
623          i915_emit_arith(p, A0_MAX, tmp, A0_DEST_CHANNEL_ALL, 0,
624                          src0, swizzle(src0, ZERO, ZERO, Z, W), 0);
625 
626          i915_emit_arith(p, A0_LOG, tmp, A0_DEST_CHANNEL_Y, 0,
627                          swizzle(tmp, Y, Y, Y, Y), 0, 0);
628 
629          i915_emit_arith(p, A0_MUL, tmp, A0_DEST_CHANNEL_Y, 0,
630                          swizzle(tmp, ZERO, Y, ZERO, ZERO),
631                          swizzle(tmp, ZERO, W, ZERO, ZERO), 0);
632 
633          i915_emit_arith(p, A0_EXP, tmp, A0_DEST_CHANNEL_Y, 0,
634                          swizzle(tmp, Y, Y, Y, Y), 0, 0);
635 
636          i915_emit_arith(p, A0_CMP,
637                          get_result_vector(p, inst),
638                          get_result_flags(inst), 0,
639                          negate(swizzle(tmp, ONE, ONE, X, ONE), 0, 0, 1, 0),
640                          swizzle(tmp, ONE, X, ZERO, ONE),
641                          swizzle(tmp, ONE, X, Y, ONE));
642 
643          break;
644 
645       case OPCODE_LRP:
646          src0 = src_vector(p, &inst->SrcReg[0], program);
647          src1 = src_vector(p, &inst->SrcReg[1], program);
648          src2 = src_vector(p, &inst->SrcReg[2], program);
649          flags = get_result_flags(inst);
650          tmp = i915_get_utemp(p);
651 
652          /* b*a + c*(1-a)
653           *
654           * b*a + c - ca
655           *
656           * tmp = b*a + c,
657           * result = (-c)*a + tmp
658           */
659          i915_emit_arith(p, A0_MAD, tmp,
660                          flags & A0_DEST_CHANNEL_ALL, 0, src1, src0, src2);
661 
662          i915_emit_arith(p, A0_MAD,
663                          get_result_vector(p, inst),
664                          flags, 0, negate(src2, 1, 1, 1, 1), src0, tmp);
665          break;
666 
667       case OPCODE_MAD:
668          EMIT_3ARG_ARITH(A0_MAD);
669          break;
670 
671       case OPCODE_MAX:
672          EMIT_2ARG_ARITH(A0_MAX);
673          break;
674 
675       case OPCODE_MIN:
676          EMIT_2ARG_ARITH(A0_MIN);
677          break;
678 
679       case OPCODE_MOV:
680          EMIT_1ARG_ARITH(A0_MOV);
681          break;
682 
683       case OPCODE_MUL:
684          EMIT_2ARG_ARITH(A0_MUL);
685          break;
686 
687       case OPCODE_POW:
688          src0 = src_vector(p, &inst->SrcReg[0], program);
689          src1 = src_vector(p, &inst->SrcReg[1], program);
690          tmp = i915_get_utemp(p);
691          flags = get_result_flags(inst);
692 
693          /* XXX: masking on intermediate values, here and elsewhere.
694           */
695          i915_emit_arith(p,
696                          A0_LOG,
697                          tmp, A0_DEST_CHANNEL_X, 0,
698                          swizzle(src0, X, X, X, X), 0, 0);
699 
700          i915_emit_arith(p, A0_MUL, tmp, A0_DEST_CHANNEL_X, 0, tmp, src1, 0);
701 
702 
703          i915_emit_arith(p,
704                          A0_EXP,
705                          get_result_vector(p, inst),
706                          flags, 0, swizzle(tmp, X, X, X, X), 0, 0);
707 
708          break;
709 
710       case OPCODE_RCP:
711          src0 = src_vector(p, &inst->SrcReg[0], program);
712 
713          i915_emit_arith(p,
714                          A0_RCP,
715                          get_result_vector(p, inst),
716                          get_result_flags(inst), 0,
717                          swizzle(src0, X, X, X, X), 0, 0);
718          break;
719 
720       case OPCODE_RSQ:
721 
722          src0 = src_vector(p, &inst->SrcReg[0], program);
723 
724          i915_emit_arith(p,
725                          A0_RSQ,
726                          get_result_vector(p, inst),
727                          get_result_flags(inst), 0,
728                          swizzle(src0, X, X, X, X), 0, 0);
729          break;
730 
731       case OPCODE_SCS:
732          src0 = src_vector(p, &inst->SrcReg[0], program);
733          tmp = i915_get_utemp(p);
734 
735          /*
736           * t0.xy = MUL x.xx11, x.x1111  ; x^2, x, 1, 1
737           * t0 = MUL t0.xyxy t0.xx11 ; x^4, x^3, x^2, x
738           * t1 = MUL t0.xyyw t0.yz11    ; x^7 x^5 x^3 x
739           * scs.x = DP4 t1, sin_constants
740           * t1 = MUL t0.xxz1 t0.z111    ; x^6 x^4 x^2 1
741           * scs.y = DP4 t1, cos_constants
742           */
743          i915_emit_arith(p,
744                          A0_MUL,
745                          tmp, A0_DEST_CHANNEL_XY, 0,
746                          swizzle(src0, X, X, ONE, ONE),
747                          swizzle(src0, X, ONE, ONE, ONE), 0);
748 
749          i915_emit_arith(p,
750                          A0_MUL,
751                          tmp, A0_DEST_CHANNEL_ALL, 0,
752                          swizzle(tmp, X, Y, X, Y),
753                          swizzle(tmp, X, X, ONE, ONE), 0);
754 
755          if (inst->DstReg.WriteMask & WRITEMASK_Y) {
756             GLuint tmp1;
757 
758             if (inst->DstReg.WriteMask & WRITEMASK_X)
759                tmp1 = i915_get_utemp(p);
760             else
761                tmp1 = tmp;
762 
763             i915_emit_arith(p,
764                             A0_MUL,
765                             tmp1, A0_DEST_CHANNEL_ALL, 0,
766                             swizzle(tmp, X, Y, Y, W),
767                             swizzle(tmp, X, Z, ONE, ONE), 0);
768 
769             i915_emit_arith(p,
770                             A0_DP4,
771                             get_result_vector(p, inst),
772                             A0_DEST_CHANNEL_Y, 0,
773                             swizzle(tmp1, W, Z, Y, X),
774                             i915_emit_const4fv(p, sin_constants), 0);
775          }
776 
777          if (inst->DstReg.WriteMask & WRITEMASK_X) {
778             i915_emit_arith(p,
779                             A0_MUL,
780                             tmp, A0_DEST_CHANNEL_XYZ, 0,
781                             swizzle(tmp, X, X, Z, ONE),
782                             swizzle(tmp, Z, ONE, ONE, ONE), 0);
783 
784             i915_emit_arith(p,
785                             A0_DP4,
786                             get_result_vector(p, inst),
787                             A0_DEST_CHANNEL_X, 0,
788                             swizzle(tmp, ONE, Z, Y, X),
789                             i915_emit_const4fv(p, cos_constants), 0);
790          }
791          break;
792 
793       case OPCODE_SIN:
794          src0 = src_vector(p, &inst->SrcReg[0], program);
795          tmp = i915_get_utemp(p);
796 	 consts0 = i915_emit_const4fv(p, sin_quad_constants[0]);
797 	 consts1 = i915_emit_const4fv(p, sin_quad_constants[1]);
798 
799 	 /* Reduce range from repeating about [-pi,pi] to [-1,1] */
800          i915_emit_arith(p,
801                          A0_MAD,
802                          tmp, A0_DEST_CHANNEL_X, 0,
803                          src0,
804 			 swizzle(consts1, Z, ZERO, ZERO, ZERO), /* 1/(2pi) */
805 			 swizzle(consts0, Z, ZERO, ZERO, ZERO)); /* .5 */
806 
807          i915_emit_arith(p, A0_FRC, tmp, A0_DEST_CHANNEL_X, 0, tmp, 0, 0);
808 
809 	 i915_emit_arith(p,
810 			 A0_MAD,
811 			 tmp, A0_DEST_CHANNEL_X, 0,
812 			 tmp,
813 			 swizzle(consts0, X, ZERO, ZERO, ZERO), /* 2 */
814 			 swizzle(consts0, Y, ZERO, ZERO, ZERO)); /* -1 */
815 
816 	 /* Compute sin using a quadratic and quartic.  It gives continuity
817 	  * that repeating the Taylor series lacks every 2*pi, and has
818 	  * reduced error.
819 	  *
820 	  * The idea was described at:
821 	  * http://www.devmaster.net/forums/showthread.php?t=5784
822 	  */
823 
824 	 /* tmp.y = abs(tmp.x); {x, abs(x), 0, 0} */
825 	 i915_emit_arith(p,
826                          A0_MAX,
827 			 tmp, A0_DEST_CHANNEL_Y, 0,
828 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
829 			 negate(swizzle(tmp, ZERO, X, ZERO, ZERO), 0, 1, 0, 0),
830 			 0);
831 
832 	 /* tmp.y = tmp.y * tmp.x; {x, x * abs(x), 0, 0} */
833 	 i915_emit_arith(p,
834 			 A0_MUL,
835 			 tmp, A0_DEST_CHANNEL_Y, 0,
836 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
837 			 tmp,
838 			 0);
839 
840 	 /* tmp.x = tmp.xy DP sin_quad_constants[2].xy */
841          i915_emit_arith(p,
842                          A0_DP3,
843                          tmp, A0_DEST_CHANNEL_X, 0,
844 			 tmp,
845                          swizzle(consts1, X, Y, ZERO, ZERO),
846 			 0);
847 
848 	 /* tmp.x now contains a first approximation (y).  Now, weight it
849 	  * against tmp.y**2 to get closer.
850 	  */
851 	 i915_emit_arith(p,
852                          A0_MAX,
853 			 tmp, A0_DEST_CHANNEL_Y, 0,
854 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
855 			 negate(swizzle(tmp, ZERO, X, ZERO, ZERO), 0, 1, 0, 0),
856 			 0);
857 
858 	 /* tmp.y = tmp.x * tmp.y - tmp.x; {y, y * abs(y) - y, 0, 0} */
859 	 i915_emit_arith(p,
860 			 A0_MAD,
861 			 tmp, A0_DEST_CHANNEL_Y, 0,
862 			 swizzle(tmp, ZERO, X, ZERO, ZERO),
863 			 swizzle(tmp, ZERO, Y, ZERO, ZERO),
864 			 negate(swizzle(tmp, ZERO, X, ZERO, ZERO), 0, 1, 0, 0));
865 
866 	 /* result = .2225 * tmp.y + tmp.x =.2225(y * abs(y) - y) + y= */
867 	 i915_emit_arith(p,
868 			 A0_MAD,
869                          get_result_vector(p, inst),
870                          get_result_flags(inst), 0,
871 			 swizzle(consts1, W, W, W, W),
872 			 swizzle(tmp, Y, Y, Y, Y),
873 			 swizzle(tmp, X, X, X, X));
874 
875          break;
876 
877       case OPCODE_SGE:
878 	 EMIT_2ARG_ARITH(A0_SGE);
879 	 break;
880 
881       case OPCODE_SLT:
882          EMIT_2ARG_ARITH(A0_SLT);
883          break;
884 
885       case OPCODE_SSG:
886 	 dst = get_result_vector(p, inst);
887 	 flags = get_result_flags(inst);
888          src0 = src_vector(p, &inst->SrcReg[0], program);
889 	 tmp = i915_get_utemp(p);
890 
891 	 /* tmp = (src < 0.0) */
892 	 i915_emit_arith(p,
893 			 A0_SLT,
894 			 tmp,
895 			 flags, 0,
896 			 src0,
897 			 swizzle(src0, ZERO, ZERO, ZERO, ZERO),
898 			 0);
899 
900 	 /* dst = (0.0 < src) */
901 	 i915_emit_arith(p,
902 			 A0_SLT,
903 			 dst,
904 			 flags, 0,
905 			 swizzle(src0, ZERO, ZERO, ZERO, ZERO),
906 			 src0,
907 			 0);
908 
909 	 /* dst = (src > 0.0) - (src < 0.0) */
910 	 i915_emit_arith(p,
911 			 A0_ADD,
912 			 dst,
913 			 flags, 0,
914 			 dst,
915 			 negate(tmp, 1, 1, 1, 1),
916 			 0);
917 
918          break;
919 
920       case OPCODE_SUB:
921          src0 = src_vector(p, &inst->SrcReg[0], program);
922          src1 = src_vector(p, &inst->SrcReg[1], program);
923 
924          i915_emit_arith(p,
925                          A0_ADD,
926                          get_result_vector(p, inst),
927                          get_result_flags(inst), 0,
928                          src0, negate(src1, 1, 1, 1, 1), 0);
929          break;
930 
931       case OPCODE_SWZ:
932          EMIT_1ARG_ARITH(A0_MOV);       /* extended swizzle handled natively */
933          break;
934 
935       case OPCODE_TEX:
936          EMIT_TEX(T0_TEXLD);
937          break;
938 
939       case OPCODE_TXB:
940          EMIT_TEX(T0_TEXLDB);
941          break;
942 
943       case OPCODE_TXP:
944          EMIT_TEX(T0_TEXLDP);
945          break;
946 
947       case OPCODE_XPD:
948          /* Cross product:
949           *      result.x = src0.y * src1.z - src0.z * src1.y;
950           *      result.y = src0.z * src1.x - src0.x * src1.z;
951           *      result.z = src0.x * src1.y - src0.y * src1.x;
952           *      result.w = undef;
953           */
954          src0 = src_vector(p, &inst->SrcReg[0], program);
955          src1 = src_vector(p, &inst->SrcReg[1], program);
956          tmp = i915_get_utemp(p);
957 
958          i915_emit_arith(p,
959                          A0_MUL,
960                          tmp, A0_DEST_CHANNEL_ALL, 0,
961                          swizzle(src0, Z, X, Y, ONE),
962                          swizzle(src1, Y, Z, X, ONE), 0);
963 
964          i915_emit_arith(p,
965                          A0_MAD,
966                          get_result_vector(p, inst),
967                          get_result_flags(inst), 0,
968                          swizzle(src0, Y, Z, X, ONE),
969                          swizzle(src1, Z, X, Y, ONE),
970                          negate(tmp, 1, 1, 1, 0));
971          break;
972 
973       case OPCODE_END:
974          return;
975 
976       case OPCODE_BGNLOOP:
977       case OPCODE_BGNSUB:
978       case OPCODE_BRK:
979       case OPCODE_CAL:
980       case OPCODE_CONT:
981       case OPCODE_DDX:
982       case OPCODE_DDY:
983       case OPCODE_ELSE:
984       case OPCODE_ENDIF:
985       case OPCODE_ENDLOOP:
986       case OPCODE_ENDSUB:
987       case OPCODE_IF:
988       case OPCODE_RET:
989 	 p->error = 1;
990 	 i915_program_error(p, "Unsupported opcode: %s",
991 			    _mesa_opcode_string(inst->Opcode));
992 	 return;
993 
994       case OPCODE_EXP:
995       case OPCODE_LOG:
996 	 /* These opcodes are claimed as GLSL, NV_vp, and ARB_vp in
997 	  * prog_instruction.h, but apparently GLSL doesn't ever emit them.
998 	  * Instead, it translates to EX2 or LG2.
999 	  */
1000       case OPCODE_TXD:
1001       case OPCODE_TXL:
1002 	 /* These opcodes are claimed by GLSL in prog_instruction.h, but
1003 	  * only NV_vp/fp appears to emit them.
1004 	  */
1005       default:
1006          i915_program_error(p, "bad opcode: %s",
1007 			    _mesa_opcode_string(inst->Opcode));
1008          return;
1009       }
1010 
1011       inst++;
1012       i915_release_utemps(p);
1013    }
1014 }
1015 
1016 /* Rather than trying to intercept and jiggle depth writes during
1017  * emit, just move the value into its correct position at the end of
1018  * the program:
1019  */
1020 static void
fixup_depth_write(struct i915_fragment_program * p)1021 fixup_depth_write(struct i915_fragment_program *p)
1022 {
1023    if (p->depth_written) {
1024       GLuint depth = UREG(REG_TYPE_OD, 0);
1025 
1026       i915_emit_arith(p,
1027                       A0_MOV,
1028                       depth, A0_DEST_CHANNEL_W, 0,
1029                       swizzle(depth, X, Y, Z, Z), 0, 0);
1030    }
1031 }
1032 
1033 static void
check_texcoord_mapping(struct i915_fragment_program * p)1034 check_texcoord_mapping(struct i915_fragment_program *p)
1035 {
1036    GLbitfield64 inputs = p->FragProg.info.inputs_read;
1037    unsigned unit = 0;
1038 
1039    for (unsigned i = 0; i < p->ctx->Const.MaxTextureCoordUnits; i++) {
1040       if (inputs & VARYING_BIT_TEX(i)) {
1041          if (unit >= p->ctx->Const.MaxTextureCoordUnits) {
1042             unit++;
1043             break;
1044          }
1045          p->texcoord_mapping[unit++] = i | TEXCOORD_TEX;
1046       }
1047       if (inputs & VARYING_BIT_VAR(i)) {
1048          if (unit >= p->ctx->Const.MaxTextureCoordUnits) {
1049             unit++;
1050             break;
1051          }
1052          p->texcoord_mapping[unit++] = i | TEXCOORD_VAR;
1053       }
1054    }
1055 
1056    if (unit > p->ctx->Const.MaxTextureCoordUnits)
1057       i915_program_error(p, "Too many texcoord units");
1058 }
1059 
1060 static void
check_wpos(struct i915_fragment_program * p)1061 check_wpos(struct i915_fragment_program *p)
1062 {
1063    GLbitfield64 inputs = p->FragProg.info.inputs_read;
1064    GLint i;
1065    unsigned unit = 0;
1066 
1067    p->wpos_tex = I915_WPOS_TEX_INVALID;
1068 
1069    if ((inputs & VARYING_BIT_POS) == 0)
1070       return;
1071 
1072    for (i = 0; i < p->ctx->Const.MaxTextureCoordUnits; i++) {
1073       unit += !!(inputs & VARYING_BIT_TEX(i));
1074       unit += !!(inputs & VARYING_BIT_VAR(i));
1075    }
1076 
1077    if (unit < p->ctx->Const.MaxTextureCoordUnits)
1078       p->wpos_tex = unit;
1079    else
1080       i915_program_error(p, "No free texcoord for wpos value");
1081 }
1082 
1083 
1084 static void
translate_program(struct i915_fragment_program * p)1085 translate_program(struct i915_fragment_program *p)
1086 {
1087    struct i915_context *i915 = I915_CONTEXT(p->ctx);
1088 
1089    if (INTEL_DEBUG & DEBUG_WM) {
1090       printf("fp:\n");
1091       _mesa_print_program(&p->FragProg);
1092       printf("\n");
1093    }
1094 
1095    i915_init_program(i915, p);
1096    check_texcoord_mapping(p);
1097    check_wpos(p);
1098    upload_program(p);
1099    fixup_depth_write(p);
1100    i915_fini_program(p);
1101 
1102    p->translated = 1;
1103 }
1104 
1105 
1106 static void
track_params(struct i915_fragment_program * p)1107 track_params(struct i915_fragment_program *p)
1108 {
1109    GLint i;
1110 
1111    if (p->nr_params)
1112       _mesa_load_state_parameters(p->ctx, p->FragProg.Parameters);
1113 
1114    for (i = 0; i < p->nr_params; i++) {
1115       GLint reg = p->param[i].reg;
1116       COPY_4V(p->constant[reg], p->param[i].values);
1117    }
1118 
1119    p->params_uptodate = 1;
1120    p->on_hardware = 0;          /* overkill */
1121 }
1122 
1123 static struct gl_program *
i915NewProgram(struct gl_context * ctx,gl_shader_stage stage,GLuint id,bool is_arb_asm)1124 i915NewProgram(struct gl_context * ctx, gl_shader_stage stage, GLuint id,
1125                bool is_arb_asm)
1126 {
1127    switch (stage) {
1128    case MESA_SHADER_VERTEX: {
1129       struct gl_program *prog = rzalloc(NULL, struct gl_program);
1130       return _mesa_init_gl_program(prog, stage, id, is_arb_asm);
1131    }
1132 
1133    case MESA_SHADER_FRAGMENT:{
1134          struct i915_fragment_program *prog =
1135             rzalloc(NULL, struct i915_fragment_program);
1136          if (prog) {
1137             i915_init_program(I915_CONTEXT(ctx), prog);
1138 
1139             return _mesa_init_gl_program(&prog->FragProg, stage, id,
1140                                          is_arb_asm);
1141          }
1142          else
1143             return NULL;
1144       }
1145 
1146    default:
1147       /* Just fallback:
1148        */
1149       return _mesa_new_program(ctx, stage, id, is_arb_asm);
1150    }
1151 }
1152 
1153 static void
i915DeleteProgram(struct gl_context * ctx,struct gl_program * prog)1154 i915DeleteProgram(struct gl_context * ctx, struct gl_program *prog)
1155 {
1156    if (prog->Target == GL_FRAGMENT_PROGRAM_ARB) {
1157       struct i915_context *i915 = I915_CONTEXT(ctx);
1158       struct i915_fragment_program *p = (struct i915_fragment_program *) prog;
1159 
1160       if (i915->current_program == p)
1161          i915->current_program = 0;
1162    }
1163 
1164    _mesa_delete_program(ctx, prog);
1165 }
1166 
1167 
1168 static GLboolean
i915IsProgramNative(struct gl_context * ctx,GLenum target,struct gl_program * prog)1169 i915IsProgramNative(struct gl_context * ctx, GLenum target, struct gl_program *prog)
1170 {
1171    if (target == GL_FRAGMENT_PROGRAM_ARB) {
1172       struct i915_fragment_program *p = (struct i915_fragment_program *) prog;
1173 
1174       if (!p->translated)
1175          translate_program(p);
1176 
1177       return !p->error;
1178    }
1179    else
1180       return true;
1181 }
1182 
1183 static GLboolean
i915ProgramStringNotify(struct gl_context * ctx,GLenum target,struct gl_program * prog)1184 i915ProgramStringNotify(struct gl_context * ctx,
1185                         GLenum target, struct gl_program *prog)
1186 {
1187    if (target == GL_FRAGMENT_PROGRAM_ARB) {
1188       struct i915_fragment_program *p = (struct i915_fragment_program *) prog;
1189       p->translated = 0;
1190    }
1191 
1192    (void) _tnl_program_string(ctx, target, prog);
1193 
1194    /* XXX check if program is legal, within limits */
1195    return true;
1196 }
1197 
1198 static void
i915SamplerUniformChange(struct gl_context * ctx,GLenum target,struct gl_program * prog)1199 i915SamplerUniformChange(struct gl_context *ctx,
1200                          GLenum target, struct gl_program *prog)
1201 {
1202    i915ProgramStringNotify(ctx, target, prog);
1203 }
1204 
1205 void
i915_update_program(struct gl_context * ctx)1206 i915_update_program(struct gl_context *ctx)
1207 {
1208    struct intel_context *intel = intel_context(ctx);
1209    struct i915_context *i915 = i915_context(&intel->ctx);
1210    struct i915_fragment_program *fp =
1211       (struct i915_fragment_program *) ctx->FragmentProgram._Current;
1212 
1213    if (i915->current_program != fp) {
1214       if (i915->current_program) {
1215          i915->current_program->on_hardware = 0;
1216          i915->current_program->params_uptodate = 0;
1217       }
1218 
1219       i915->current_program = fp;
1220    }
1221 
1222    if (!fp->translated)
1223       translate_program(fp);
1224 
1225    FALLBACK(&i915->intel, I915_FALLBACK_PROGRAM, fp->error);
1226 }
1227 
1228 void
i915ValidateFragmentProgram(struct i915_context * i915)1229 i915ValidateFragmentProgram(struct i915_context *i915)
1230 {
1231    struct gl_context *ctx = &i915->intel.ctx;
1232    struct intel_context *intel = intel_context(ctx);
1233    TNLcontext *tnl = TNL_CONTEXT(ctx);
1234    struct vertex_buffer *VB = &tnl->vb;
1235 
1236    struct i915_fragment_program *p =
1237       (struct i915_fragment_program *) ctx->FragmentProgram._Current;
1238 
1239    const GLbitfield64 inputsRead = p->FragProg.info.inputs_read;
1240    GLuint s4 = i915->state.Ctx[I915_CTXREG_LIS4] & ~S4_VFMT_MASK;
1241    GLuint s2 = S2_TEXCOORD_NONE;
1242    GLuint s3 = 0;
1243    int i, offset = 0;
1244 
1245    /* Important:
1246     */
1247    VB->AttribPtr[VERT_ATTRIB_POS] = VB->NdcPtr;
1248 
1249    if (!p->translated)
1250       translate_program(p);
1251 
1252    intel->vertex_attr_count = 0;
1253    intel->wpos_offset = 0;
1254    intel->coloroffset = 0;
1255    intel->specoffset = 0;
1256 
1257    /* Always emit W to get consistent perspective
1258     * correct interpolation of primary/secondary colors.
1259     */
1260    EMIT_ATTR(_TNL_ATTRIB_POS, EMIT_4F_VIEWPORT, S4_VFMT_XYZW, 16);
1261 
1262    /* Handle gl_PointSize builtin var here */
1263    if (ctx->Point._Attenuated || ctx->VertexProgram.PointSizeEnabled)
1264       EMIT_ATTR(_TNL_ATTRIB_POINTSIZE, EMIT_1F, S4_VFMT_POINT_WIDTH, 4);
1265 
1266    if (inputsRead & VARYING_BIT_COL0) {
1267       intel->coloroffset = offset / 4;
1268       EMIT_ATTR(_TNL_ATTRIB_COLOR0, EMIT_4UB_4F_BGRA, S4_VFMT_COLOR, 4);
1269    }
1270 
1271    if (inputsRead & VARYING_BIT_COL1) {
1272        intel->specoffset = offset / 4;
1273        EMIT_ATTR(_TNL_ATTRIB_COLOR1, EMIT_4UB_4F_BGRA, S4_VFMT_SPEC_FOG, 4);
1274    }
1275 
1276    if ((inputsRead & VARYING_BIT_FOGC)) {
1277       EMIT_ATTR(_TNL_ATTRIB_FOG, EMIT_1F, S4_VFMT_FOG_PARAM, 4);
1278    }
1279 
1280    for (i = 0; i < p->ctx->Const.MaxTextureCoordUnits; i++) {
1281       if (inputsRead & VARYING_BIT_TEX(i)) {
1282          int unit = get_texcoord_mapping(p, i | TEXCOORD_TEX);
1283          int sz = VB->AttribPtr[_TNL_ATTRIB_TEX0 + i]->size;
1284 
1285          s2 &= ~S2_TEXCOORD_FMT(unit, S2_TEXCOORD_FMT0_MASK);
1286          s2 |= S2_TEXCOORD_FMT(unit, SZ_TO_HW(sz));
1287 
1288          EMIT_ATTR(_TNL_ATTRIB_TEX0 + i, EMIT_SZ(sz), 0, sz * 4);
1289       }
1290       if (inputsRead & VARYING_BIT_VAR(i)) {
1291          int unit = get_texcoord_mapping(p, i | TEXCOORD_VAR);
1292          int sz = VB->AttribPtr[_TNL_ATTRIB_GENERIC0 + i]->size;
1293 
1294          s2 &= ~S2_TEXCOORD_FMT(unit, S2_TEXCOORD_FMT0_MASK);
1295          s2 |= S2_TEXCOORD_FMT(unit, SZ_TO_HW(sz));
1296 
1297          EMIT_ATTR(_TNL_ATTRIB_GENERIC0 + i, EMIT_SZ(sz), 0, sz * 4);
1298       }
1299       if (i == p->wpos_tex) {
1300 	 int wpos_size = 4 * sizeof(float);
1301          /* If WPOS is required, duplicate the XYZ position data in an
1302           * unused texture coordinate:
1303           */
1304          s2 &= ~S2_TEXCOORD_FMT(i, S2_TEXCOORD_FMT0_MASK);
1305          s2 |= S2_TEXCOORD_FMT(i, SZ_TO_HW(wpos_size));
1306          s3 |= S3_TEXCOORD_PERSPECTIVE_DISABLE(i);
1307 
1308          intel->wpos_offset = offset;
1309          EMIT_PAD(wpos_size);
1310       }
1311    }
1312 
1313    if (s2 != i915->state.Ctx[I915_CTXREG_LIS2] ||
1314        s3 != i915->state.Ctx[I915_CTXREG_LIS3] ||
1315        s4 != i915->state.Ctx[I915_CTXREG_LIS4]) {
1316       I915_STATECHANGE(i915, I915_UPLOAD_CTX);
1317 
1318       /* Must do this *after* statechange, so as not to affect
1319        * buffered vertices reliant on the old state:
1320        */
1321       intel->vertex_size = _tnl_install_attrs(&intel->ctx,
1322                                               intel->vertex_attrs,
1323                                               intel->vertex_attr_count,
1324                                               intel->ViewportMatrix.m, 0);
1325 
1326       assert(intel->prim.current_offset == intel->prim.start_offset);
1327       intel->prim.start_offset = (intel->prim.current_offset + intel->vertex_size-1) / intel->vertex_size * intel->vertex_size;
1328       intel->prim.current_offset = intel->prim.start_offset;
1329 
1330       intel->vertex_size >>= 2;
1331 
1332       i915->state.Ctx[I915_CTXREG_LIS2] = s2;
1333       i915->state.Ctx[I915_CTXREG_LIS3] = s3;
1334       i915->state.Ctx[I915_CTXREG_LIS4] = s4;
1335 
1336       assert(intel->vtbl.check_vertex_size(intel, intel->vertex_size));
1337    }
1338 
1339    if (!p->params_uptodate)
1340       track_params(p);
1341 
1342    if (!p->on_hardware)
1343       i915_upload_program(i915, p);
1344 
1345    if (INTEL_DEBUG & DEBUG_WM) {
1346       printf("i915:\n");
1347       i915_disassemble_program(i915->state.Program, i915->state.ProgramSize);
1348    }
1349 }
1350 
1351 void
i915InitFragProgFuncs(struct dd_function_table * functions)1352 i915InitFragProgFuncs(struct dd_function_table *functions)
1353 {
1354    functions->NewProgram = i915NewProgram;
1355    functions->DeleteProgram = i915DeleteProgram;
1356    functions->IsProgramNative = i915IsProgramNative;
1357    functions->ProgramStringNotify = i915ProgramStringNotify;
1358    functions->SamplerUniformChange = i915SamplerUniformChange;
1359 }
1360