1 /**************************************************************************
3 * Copyright 2007-2008 Tungsten Graphics, Inc., Cedar Park, Texas.
5 * Copyright 2009-2010 VMware, Inc. All rights Reserved.
7 * Permission is hereby granted, free of charge, to any person obtaining a
8 * copy of this software and associated documentation files (the
9 * "Software"), to deal in the Software without restriction, including
10 * without limitation the rights to use, copy, modify, merge, publish,
11 * distribute, sub license, and/or sell copies of the Software, and to
12 * permit persons to whom the Software is furnished to do so, subject to
13 * the following conditions:
15 * The above copyright notice and this permission notice (including the
16 * next paragraph) shall be included in all copies or substantial portions
19 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
20 * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
21 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT.
22 * IN NO EVENT SHALL TUNGSTEN GRAPHICS AND/OR ITS SUPPLIERS BE LIABLE FOR
23 * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
24 * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
25 * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
27 **************************************************************************/
30 * TGSI interpreter/executor.
32 * Flow control information:
34 * Since we operate on 'quads' (4 pixels or 4 vertices in parallel)
35 * flow control statements (IF/ELSE/ENDIF, LOOP/ENDLOOP) require special
36 * care since a condition may be true for some quad components but false
37 * for other components.
39 * We basically execute all statements (even if they're in the part of
40 * an IF/ELSE clause that's "not taken") and use a special mask to
41 * control writing to destination registers. This is the ExecMask.
44 * The ExecMask is computed from three other masks (CondMask, LoopMask and
45 * ContMask) which are controlled by the flow control instructions (namely:
46 * (IF/ELSE/ENDIF, LOOP/ENDLOOP and CONT).
54 #include "pipe/p_compiler.h"
55 #include "pipe/p_state.h"
56 #include "pipe/p_shader_tokens.h"
57 #include "tgsi/tgsi_dump.h"
58 #include "tgsi/tgsi_parse.h"
59 #include "tgsi/tgsi_util.h"
60 #include "tgsi_exec.h"
61 #include "util/u_memory.h"
62 #include "util/u_math.h"
65 #define DEBUG_EXECUTION 0
70 #define TILE_TOP_LEFT 0
71 #define TILE_TOP_RIGHT 1
72 #define TILE_BOTTOM_LEFT 2
73 #define TILE_BOTTOM_RIGHT 3
76 micro_abs(union tgsi_exec_channel
*dst
,
77 const union tgsi_exec_channel
*src
)
79 dst
->f
[0] = fabsf(src
->f
[0]);
80 dst
->f
[1] = fabsf(src
->f
[1]);
81 dst
->f
[2] = fabsf(src
->f
[2]);
82 dst
->f
[3] = fabsf(src
->f
[3]);
86 micro_arl(union tgsi_exec_channel
*dst
,
87 const union tgsi_exec_channel
*src
)
89 dst
->i
[0] = (int)floorf(src
->f
[0]);
90 dst
->i
[1] = (int)floorf(src
->f
[1]);
91 dst
->i
[2] = (int)floorf(src
->f
[2]);
92 dst
->i
[3] = (int)floorf(src
->f
[3]);
96 micro_arr(union tgsi_exec_channel
*dst
,
97 const union tgsi_exec_channel
*src
)
99 dst
->i
[0] = (int)floorf(src
->f
[0] + 0.5f
);
100 dst
->i
[1] = (int)floorf(src
->f
[1] + 0.5f
);
101 dst
->i
[2] = (int)floorf(src
->f
[2] + 0.5f
);
102 dst
->i
[3] = (int)floorf(src
->f
[3] + 0.5f
);
106 micro_ceil(union tgsi_exec_channel
*dst
,
107 const union tgsi_exec_channel
*src
)
109 dst
->f
[0] = ceilf(src
->f
[0]);
110 dst
->f
[1] = ceilf(src
->f
[1]);
111 dst
->f
[2] = ceilf(src
->f
[2]);
112 dst
->f
[3] = ceilf(src
->f
[3]);
116 micro_clamp(union tgsi_exec_channel
*dst
,
117 const union tgsi_exec_channel
*src0
,
118 const union tgsi_exec_channel
*src1
,
119 const union tgsi_exec_channel
*src2
)
121 dst
->f
[0] = src0
->f
[0] < src1
->f
[0] ? src1
->f
[0] : src0
->f
[0] > src2
->f
[0] ? src2
->f
[0] : src0
->f
[0];
122 dst
->f
[1] = src0
->f
[1] < src1
->f
[1] ? src1
->f
[1] : src0
->f
[1] > src2
->f
[1] ? src2
->f
[1] : src0
->f
[1];
123 dst
->f
[2] = src0
->f
[2] < src1
->f
[2] ? src1
->f
[2] : src0
->f
[2] > src2
->f
[2] ? src2
->f
[2] : src0
->f
[2];
124 dst
->f
[3] = src0
->f
[3] < src1
->f
[3] ? src1
->f
[3] : src0
->f
[3] > src2
->f
[3] ? src2
->f
[3] : src0
->f
[3];
128 micro_cmp(union tgsi_exec_channel
*dst
,
129 const union tgsi_exec_channel
*src0
,
130 const union tgsi_exec_channel
*src1
,
131 const union tgsi_exec_channel
*src2
)
133 dst
->f
[0] = src0
->f
[0] < 0.0f
? src1
->f
[0] : src2
->f
[0];
134 dst
->f
[1] = src0
->f
[1] < 0.0f
? src1
->f
[1] : src2
->f
[1];
135 dst
->f
[2] = src0
->f
[2] < 0.0f
? src1
->f
[2] : src2
->f
[2];
136 dst
->f
[3] = src0
->f
[3] < 0.0f
? src1
->f
[3] : src2
->f
[3];
140 micro_cnd(union tgsi_exec_channel
*dst
,
141 const union tgsi_exec_channel
*src0
,
142 const union tgsi_exec_channel
*src1
,
143 const union tgsi_exec_channel
*src2
)
145 dst
->f
[0] = src2
->f
[0] > 0.5f
? src0
->f
[0] : src1
->f
[0];
146 dst
->f
[1] = src2
->f
[1] > 0.5f
? src0
->f
[1] : src1
->f
[1];
147 dst
->f
[2] = src2
->f
[2] > 0.5f
? src0
->f
[2] : src1
->f
[2];
148 dst
->f
[3] = src2
->f
[3] > 0.5f
? src0
->f
[3] : src1
->f
[3];
152 micro_cos(union tgsi_exec_channel
*dst
,
153 const union tgsi_exec_channel
*src
)
155 dst
->f
[0] = cosf(src
->f
[0]);
156 dst
->f
[1] = cosf(src
->f
[1]);
157 dst
->f
[2] = cosf(src
->f
[2]);
158 dst
->f
[3] = cosf(src
->f
[3]);
162 micro_ddx(union tgsi_exec_channel
*dst
,
163 const union tgsi_exec_channel
*src
)
168 dst
->f
[3] = src
->f
[TILE_BOTTOM_RIGHT
] - src
->f
[TILE_BOTTOM_LEFT
];
172 micro_ddy(union tgsi_exec_channel
*dst
,
173 const union tgsi_exec_channel
*src
)
178 dst
->f
[3] = src
->f
[TILE_BOTTOM_LEFT
] - src
->f
[TILE_TOP_LEFT
];
182 micro_exp2(union tgsi_exec_channel
*dst
,
183 const union tgsi_exec_channel
*src
)
186 dst
->f
[0] = util_fast_exp2(src
->f
[0]);
187 dst
->f
[1] = util_fast_exp2(src
->f
[1]);
188 dst
->f
[2] = util_fast_exp2(src
->f
[2]);
189 dst
->f
[3] = util_fast_exp2(src
->f
[3]);
192 /* Inf is okay for this instruction, so clamp it to silence assertions. */
194 union tgsi_exec_channel clamped
;
196 for (i
= 0; i
< 4; i
++) {
197 if (src
->f
[i
] > 127.99999f
) {
198 clamped
.f
[i
] = 127.99999f
;
199 } else if (src
->f
[i
] < -126.99999f
) {
200 clamped
.f
[i
] = -126.99999f
;
202 clamped
.f
[i
] = src
->f
[i
];
208 dst
->f
[0] = powf(2.0f
, src
->f
[0]);
209 dst
->f
[1] = powf(2.0f
, src
->f
[1]);
210 dst
->f
[2] = powf(2.0f
, src
->f
[2]);
211 dst
->f
[3] = powf(2.0f
, src
->f
[3]);
212 #endif /* FAST_MATH */
216 micro_flr(union tgsi_exec_channel
*dst
,
217 const union tgsi_exec_channel
*src
)
219 dst
->f
[0] = floorf(src
->f
[0]);
220 dst
->f
[1] = floorf(src
->f
[1]);
221 dst
->f
[2] = floorf(src
->f
[2]);
222 dst
->f
[3] = floorf(src
->f
[3]);
226 micro_frc(union tgsi_exec_channel
*dst
,
227 const union tgsi_exec_channel
*src
)
229 dst
->f
[0] = src
->f
[0] - floorf(src
->f
[0]);
230 dst
->f
[1] = src
->f
[1] - floorf(src
->f
[1]);
231 dst
->f
[2] = src
->f
[2] - floorf(src
->f
[2]);
232 dst
->f
[3] = src
->f
[3] - floorf(src
->f
[3]);
236 micro_iabs(union tgsi_exec_channel
*dst
,
237 const union tgsi_exec_channel
*src
)
239 dst
->i
[0] = src
->i
[0] >= 0 ? src
->i
[0] : -src
->i
[0];
240 dst
->i
[1] = src
->i
[1] >= 0 ? src
->i
[1] : -src
->i
[1];
241 dst
->i
[2] = src
->i
[2] >= 0 ? src
->i
[2] : -src
->i
[2];
242 dst
->i
[3] = src
->i
[3] >= 0 ? src
->i
[3] : -src
->i
[3];
246 micro_ineg(union tgsi_exec_channel
*dst
,
247 const union tgsi_exec_channel
*src
)
249 dst
->i
[0] = -src
->i
[0];
250 dst
->i
[1] = -src
->i
[1];
251 dst
->i
[2] = -src
->i
[2];
252 dst
->i
[3] = -src
->i
[3];
256 micro_lg2(union tgsi_exec_channel
*dst
,
257 const union tgsi_exec_channel
*src
)
260 dst
->f
[0] = util_fast_log2(src
->f
[0]);
261 dst
->f
[1] = util_fast_log2(src
->f
[1]);
262 dst
->f
[2] = util_fast_log2(src
->f
[2]);
263 dst
->f
[3] = util_fast_log2(src
->f
[3]);
265 dst
->f
[0] = logf(src
->f
[0]) * 1.442695f
;
266 dst
->f
[1] = logf(src
->f
[1]) * 1.442695f
;
267 dst
->f
[2] = logf(src
->f
[2]) * 1.442695f
;
268 dst
->f
[3] = logf(src
->f
[3]) * 1.442695f
;
273 micro_lrp(union tgsi_exec_channel
*dst
,
274 const union tgsi_exec_channel
*src0
,
275 const union tgsi_exec_channel
*src1
,
276 const union tgsi_exec_channel
*src2
)
278 dst
->f
[0] = src0
->f
[0] * (src1
->f
[0] - src2
->f
[0]) + src2
->f
[0];
279 dst
->f
[1] = src0
->f
[1] * (src1
->f
[1] - src2
->f
[1]) + src2
->f
[1];
280 dst
->f
[2] = src0
->f
[2] * (src1
->f
[2] - src2
->f
[2]) + src2
->f
[2];
281 dst
->f
[3] = src0
->f
[3] * (src1
->f
[3] - src2
->f
[3]) + src2
->f
[3];
285 micro_mad(union tgsi_exec_channel
*dst
,
286 const union tgsi_exec_channel
*src0
,
287 const union tgsi_exec_channel
*src1
,
288 const union tgsi_exec_channel
*src2
)
290 dst
->f
[0] = src0
->f
[0] * src1
->f
[0] + src2
->f
[0];
291 dst
->f
[1] = src0
->f
[1] * src1
->f
[1] + src2
->f
[1];
292 dst
->f
[2] = src0
->f
[2] * src1
->f
[2] + src2
->f
[2];
293 dst
->f
[3] = src0
->f
[3] * src1
->f
[3] + src2
->f
[3];
297 micro_mov(union tgsi_exec_channel
*dst
,
298 const union tgsi_exec_channel
*src
)
300 dst
->u
[0] = src
->u
[0];
301 dst
->u
[1] = src
->u
[1];
302 dst
->u
[2] = src
->u
[2];
303 dst
->u
[3] = src
->u
[3];
307 micro_rcp(union tgsi_exec_channel
*dst
,
308 const union tgsi_exec_channel
*src
)
310 #if 0 /* for debugging */
311 assert(src
->f
[0] != 0.0f
);
312 assert(src
->f
[1] != 0.0f
);
313 assert(src
->f
[2] != 0.0f
);
314 assert(src
->f
[3] != 0.0f
);
316 dst
->f
[0] = 1.0f
/ src
->f
[0];
317 dst
->f
[1] = 1.0f
/ src
->f
[1];
318 dst
->f
[2] = 1.0f
/ src
->f
[2];
319 dst
->f
[3] = 1.0f
/ src
->f
[3];
323 micro_rnd(union tgsi_exec_channel
*dst
,
324 const union tgsi_exec_channel
*src
)
326 dst
->f
[0] = floorf(src
->f
[0] + 0.5f
);
327 dst
->f
[1] = floorf(src
->f
[1] + 0.5f
);
328 dst
->f
[2] = floorf(src
->f
[2] + 0.5f
);
329 dst
->f
[3] = floorf(src
->f
[3] + 0.5f
);
333 micro_rsq(union tgsi_exec_channel
*dst
,
334 const union tgsi_exec_channel
*src
)
336 #if 0 /* for debugging */
337 assert(src
->f
[0] != 0.0f
);
338 assert(src
->f
[1] != 0.0f
);
339 assert(src
->f
[2] != 0.0f
);
340 assert(src
->f
[3] != 0.0f
);
342 dst
->f
[0] = 1.0f
/ sqrtf(fabsf(src
->f
[0]));
343 dst
->f
[1] = 1.0f
/ sqrtf(fabsf(src
->f
[1]));
344 dst
->f
[2] = 1.0f
/ sqrtf(fabsf(src
->f
[2]));
345 dst
->f
[3] = 1.0f
/ sqrtf(fabsf(src
->f
[3]));
349 micro_sqrt(union tgsi_exec_channel
*dst
,
350 const union tgsi_exec_channel
*src
)
352 dst
->f
[0] = sqrtf(fabsf(src
->f
[0]));
353 dst
->f
[1] = sqrtf(fabsf(src
->f
[1]));
354 dst
->f
[2] = sqrtf(fabsf(src
->f
[2]));
355 dst
->f
[3] = sqrtf(fabsf(src
->f
[3]));
359 micro_seq(union tgsi_exec_channel
*dst
,
360 const union tgsi_exec_channel
*src0
,
361 const union tgsi_exec_channel
*src1
)
363 dst
->f
[0] = src0
->f
[0] == src1
->f
[0] ? 1.0f
: 0.0f
;
364 dst
->f
[1] = src0
->f
[1] == src1
->f
[1] ? 1.0f
: 0.0f
;
365 dst
->f
[2] = src0
->f
[2] == src1
->f
[2] ? 1.0f
: 0.0f
;
366 dst
->f
[3] = src0
->f
[3] == src1
->f
[3] ? 1.0f
: 0.0f
;
370 micro_sge(union tgsi_exec_channel
*dst
,
371 const union tgsi_exec_channel
*src0
,
372 const union tgsi_exec_channel
*src1
)
374 dst
->f
[0] = src0
->f
[0] >= src1
->f
[0] ? 1.0f
: 0.0f
;
375 dst
->f
[1] = src0
->f
[1] >= src1
->f
[1] ? 1.0f
: 0.0f
;
376 dst
->f
[2] = src0
->f
[2] >= src1
->f
[2] ? 1.0f
: 0.0f
;
377 dst
->f
[3] = src0
->f
[3] >= src1
->f
[3] ? 1.0f
: 0.0f
;
381 micro_sgn(union tgsi_exec_channel
*dst
,
382 const union tgsi_exec_channel
*src
)
384 dst
->f
[0] = src
->f
[0] < 0.0f
? -1.0f
: src
->f
[0] > 0.0f
? 1.0f
: 0.0f
;
385 dst
->f
[1] = src
->f
[1] < 0.0f
? -1.0f
: src
->f
[1] > 0.0f
? 1.0f
: 0.0f
;
386 dst
->f
[2] = src
->f
[2] < 0.0f
? -1.0f
: src
->f
[2] > 0.0f
? 1.0f
: 0.0f
;
387 dst
->f
[3] = src
->f
[3] < 0.0f
? -1.0f
: src
->f
[3] > 0.0f
? 1.0f
: 0.0f
;
391 micro_isgn(union tgsi_exec_channel
*dst
,
392 const union tgsi_exec_channel
*src
)
394 dst
->i
[0] = src
->i
[0] < 0 ? -1 : src
->i
[0] > 0 ? 1 : 0;
395 dst
->i
[1] = src
->i
[1] < 0 ? -1 : src
->i
[1] > 0 ? 1 : 0;
396 dst
->i
[2] = src
->i
[2] < 0 ? -1 : src
->i
[2] > 0 ? 1 : 0;
397 dst
->i
[3] = src
->i
[3] < 0 ? -1 : src
->i
[3] > 0 ? 1 : 0;
401 micro_sgt(union tgsi_exec_channel
*dst
,
402 const union tgsi_exec_channel
*src0
,
403 const union tgsi_exec_channel
*src1
)
405 dst
->f
[0] = src0
->f
[0] > src1
->f
[0] ? 1.0f
: 0.0f
;
406 dst
->f
[1] = src0
->f
[1] > src1
->f
[1] ? 1.0f
: 0.0f
;
407 dst
->f
[2] = src0
->f
[2] > src1
->f
[2] ? 1.0f
: 0.0f
;
408 dst
->f
[3] = src0
->f
[3] > src1
->f
[3] ? 1.0f
: 0.0f
;
412 micro_sin(union tgsi_exec_channel
*dst
,
413 const union tgsi_exec_channel
*src
)
415 dst
->f
[0] = sinf(src
->f
[0]);
416 dst
->f
[1] = sinf(src
->f
[1]);
417 dst
->f
[2] = sinf(src
->f
[2]);
418 dst
->f
[3] = sinf(src
->f
[3]);
422 micro_sle(union tgsi_exec_channel
*dst
,
423 const union tgsi_exec_channel
*src0
,
424 const union tgsi_exec_channel
*src1
)
426 dst
->f
[0] = src0
->f
[0] <= src1
->f
[0] ? 1.0f
: 0.0f
;
427 dst
->f
[1] = src0
->f
[1] <= src1
->f
[1] ? 1.0f
: 0.0f
;
428 dst
->f
[2] = src0
->f
[2] <= src1
->f
[2] ? 1.0f
: 0.0f
;
429 dst
->f
[3] = src0
->f
[3] <= src1
->f
[3] ? 1.0f
: 0.0f
;
433 micro_slt(union tgsi_exec_channel
*dst
,
434 const union tgsi_exec_channel
*src0
,
435 const union tgsi_exec_channel
*src1
)
437 dst
->f
[0] = src0
->f
[0] < src1
->f
[0] ? 1.0f
: 0.0f
;
438 dst
->f
[1] = src0
->f
[1] < src1
->f
[1] ? 1.0f
: 0.0f
;
439 dst
->f
[2] = src0
->f
[2] < src1
->f
[2] ? 1.0f
: 0.0f
;
440 dst
->f
[3] = src0
->f
[3] < src1
->f
[3] ? 1.0f
: 0.0f
;
444 micro_sne(union tgsi_exec_channel
*dst
,
445 const union tgsi_exec_channel
*src0
,
446 const union tgsi_exec_channel
*src1
)
448 dst
->f
[0] = src0
->f
[0] != src1
->f
[0] ? 1.0f
: 0.0f
;
449 dst
->f
[1] = src0
->f
[1] != src1
->f
[1] ? 1.0f
: 0.0f
;
450 dst
->f
[2] = src0
->f
[2] != src1
->f
[2] ? 1.0f
: 0.0f
;
451 dst
->f
[3] = src0
->f
[3] != src1
->f
[3] ? 1.0f
: 0.0f
;
455 micro_sfl(union tgsi_exec_channel
*dst
)
464 micro_str(union tgsi_exec_channel
*dst
)
473 micro_trunc(union tgsi_exec_channel
*dst
,
474 const union tgsi_exec_channel
*src
)
476 dst
->f
[0] = (float)(int)src
->f
[0];
477 dst
->f
[1] = (float)(int)src
->f
[1];
478 dst
->f
[2] = (float)(int)src
->f
[2];
479 dst
->f
[3] = (float)(int)src
->f
[3];
483 enum tgsi_exec_datatype
{
484 TGSI_EXEC_DATA_FLOAT
,
490 * Shorthand locations of various utility registers (_I = Index, _C = Channel)
492 #define TEMP_KILMASK_I TGSI_EXEC_TEMP_KILMASK_I
493 #define TEMP_KILMASK_C TGSI_EXEC_TEMP_KILMASK_C
494 #define TEMP_OUTPUT_I TGSI_EXEC_TEMP_OUTPUT_I
495 #define TEMP_OUTPUT_C TGSI_EXEC_TEMP_OUTPUT_C
496 #define TEMP_PRIMITIVE_I TGSI_EXEC_TEMP_PRIMITIVE_I
497 #define TEMP_PRIMITIVE_C TGSI_EXEC_TEMP_PRIMITIVE_C
500 /** The execution mask depends on the conditional mask and the loop mask */
501 #define UPDATE_EXEC_MASK(MACH) \
502 MACH->ExecMask = MACH->CondMask & MACH->LoopMask & MACH->ContMask & MACH->Switch.mask & MACH->FuncMask
505 static const union tgsi_exec_channel ZeroVec
=
506 { { 0.0, 0.0, 0.0, 0.0 } };
508 static const union tgsi_exec_channel OneVec
= {
509 {1.0f
, 1.0f
, 1.0f
, 1.0f
}
512 static const union tgsi_exec_channel P128Vec
= {
513 {128.0f
, 128.0f
, 128.0f
, 128.0f
}
516 static const union tgsi_exec_channel M128Vec
= {
517 {-128.0f
, -128.0f
, -128.0f
, -128.0f
}
522 * Assert that none of the float values in 'chan' are infinite or NaN.
523 * NaN and Inf may occur normally during program execution and should
524 * not lead to crashes, etc. But when debugging, it's helpful to catch
528 check_inf_or_nan(const union tgsi_exec_channel
*chan
)
530 assert(!util_is_inf_or_nan((chan
)->f
[0]));
531 assert(!util_is_inf_or_nan((chan
)->f
[1]));
532 assert(!util_is_inf_or_nan((chan
)->f
[2]));
533 assert(!util_is_inf_or_nan((chan
)->f
[3]));
539 print_chan(const char *msg
, const union tgsi_exec_channel
*chan
)
541 debug_printf("%s = {%f, %f, %f, %f}\n",
542 msg
, chan
->f
[0], chan
->f
[1], chan
->f
[2], chan
->f
[3]);
549 print_temp(const struct tgsi_exec_machine
*mach
, uint index
)
551 const struct tgsi_exec_vector
*tmp
= &mach
->Temps
[index
];
553 debug_printf("Temp[%u] =\n", index
);
554 for (i
= 0; i
< 4; i
++) {
555 debug_printf(" %c: { %f, %f, %f, %f }\n",
567 tgsi_exec_set_constant_buffers(struct tgsi_exec_machine
*mach
,
570 const unsigned *buf_sizes
)
574 for (i
= 0; i
< num_bufs
; i
++) {
575 mach
->Consts
[i
] = bufs
[i
];
576 mach
->ConstsSize
[i
] = buf_sizes
[i
];
582 * Check if there's a potential src/dst register data dependency when
583 * using SOA execution.
586 * This would expand into:
591 * The second instruction will have the wrong value for t0 if executed as-is.
594 tgsi_check_soa_dependencies(const struct tgsi_full_instruction
*inst
)
598 uint writemask
= inst
->Dst
[0].Register
.WriteMask
;
599 if (writemask
== TGSI_WRITEMASK_X
||
600 writemask
== TGSI_WRITEMASK_Y
||
601 writemask
== TGSI_WRITEMASK_Z
||
602 writemask
== TGSI_WRITEMASK_W
||
603 writemask
== TGSI_WRITEMASK_NONE
) {
604 /* no chance of data dependency */
608 /* loop over src regs */
609 for (i
= 0; i
< inst
->Instruction
.NumSrcRegs
; i
++) {
610 if ((inst
->Src
[i
].Register
.File
==
611 inst
->Dst
[0].Register
.File
) &&
612 ((inst
->Src
[i
].Register
.Index
==
613 inst
->Dst
[0].Register
.Index
) ||
614 inst
->Src
[i
].Register
.Indirect
||
615 inst
->Dst
[0].Register
.Indirect
)) {
616 /* loop over dest channels */
617 uint channelsWritten
= 0x0;
618 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
619 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
620 /* check if we're reading a channel that's been written */
621 uint swizzle
= tgsi_util_get_full_src_register_swizzle(&inst
->Src
[i
], chan
);
622 if (channelsWritten
& (1 << swizzle
)) {
626 channelsWritten
|= (1 << chan
);
636 * Initialize machine state by expanding tokens to full instructions,
637 * allocating temporary storage, setting up constants, etc.
638 * After this, we can call tgsi_exec_machine_run() many times.
641 tgsi_exec_machine_bind_shader(
642 struct tgsi_exec_machine
*mach
,
643 const struct tgsi_token
*tokens
,
644 struct tgsi_sampler
*sampler
)
647 struct tgsi_parse_context parse
;
648 struct tgsi_full_instruction
*instructions
;
649 struct tgsi_full_declaration
*declarations
;
650 uint maxInstructions
= 10, numInstructions
= 0;
651 uint maxDeclarations
= 10, numDeclarations
= 0;
654 tgsi_dump(tokens
, 0);
660 mach
->Tokens
= tokens
;
661 mach
->Sampler
= sampler
;
664 /* unbind and free all */
665 FREE(mach
->Declarations
);
666 mach
->Declarations
= NULL
;
667 mach
->NumDeclarations
= 0;
669 FREE(mach
->Instructions
);
670 mach
->Instructions
= NULL
;
671 mach
->NumInstructions
= 0;
676 k
= tgsi_parse_init (&parse
, mach
->Tokens
);
677 if (k
!= TGSI_PARSE_OK
) {
678 debug_printf( "Problem parsing!\n" );
682 mach
->Processor
= parse
.FullHeader
.Processor
.Processor
;
684 mach
->NumOutputs
= 0;
686 if (mach
->Processor
== TGSI_PROCESSOR_GEOMETRY
&&
687 !mach
->UsedGeometryShader
) {
688 struct tgsi_exec_vector
*inputs
;
689 struct tgsi_exec_vector
*outputs
;
691 inputs
= align_malloc(sizeof(struct tgsi_exec_vector
) *
692 TGSI_MAX_PRIM_VERTICES
* PIPE_MAX_ATTRIBS
,
698 outputs
= align_malloc(sizeof(struct tgsi_exec_vector
) *
699 TGSI_MAX_TOTAL_VERTICES
, 16);
706 align_free(mach
->Inputs
);
707 align_free(mach
->Outputs
);
709 mach
->Inputs
= inputs
;
710 mach
->Outputs
= outputs
;
711 mach
->UsedGeometryShader
= TRUE
;
714 declarations
= (struct tgsi_full_declaration
*)
715 MALLOC( maxDeclarations
* sizeof(struct tgsi_full_declaration
) );
721 instructions
= (struct tgsi_full_instruction
*)
722 MALLOC( maxInstructions
* sizeof(struct tgsi_full_instruction
) );
725 FREE( declarations
);
729 while( !tgsi_parse_end_of_tokens( &parse
) ) {
732 tgsi_parse_token( &parse
);
733 switch( parse
.FullToken
.Token
.Type
) {
734 case TGSI_TOKEN_TYPE_DECLARATION
:
735 /* save expanded declaration */
736 if (numDeclarations
== maxDeclarations
) {
737 declarations
= REALLOC(declarations
,
739 * sizeof(struct tgsi_full_declaration
),
740 (maxDeclarations
+ 10)
741 * sizeof(struct tgsi_full_declaration
));
742 maxDeclarations
+= 10;
744 if (parse
.FullToken
.FullDeclaration
.Declaration
.File
== TGSI_FILE_OUTPUT
) {
746 for (reg
= parse
.FullToken
.FullDeclaration
.Range
.First
;
747 reg
<= parse
.FullToken
.FullDeclaration
.Range
.Last
;
752 memcpy(declarations
+ numDeclarations
,
753 &parse
.FullToken
.FullDeclaration
,
754 sizeof(declarations
[0]));
758 case TGSI_TOKEN_TYPE_IMMEDIATE
:
760 uint size
= parse
.FullToken
.FullImmediate
.Immediate
.NrTokens
- 1;
762 assert( mach
->ImmLimit
+ 1 <= TGSI_EXEC_NUM_IMMEDIATES
);
764 for( i
= 0; i
< size
; i
++ ) {
765 mach
->Imms
[mach
->ImmLimit
][i
] =
766 parse
.FullToken
.FullImmediate
.u
[i
].Float
;
772 case TGSI_TOKEN_TYPE_INSTRUCTION
:
774 /* save expanded instruction */
775 if (numInstructions
== maxInstructions
) {
776 instructions
= REALLOC(instructions
,
778 * sizeof(struct tgsi_full_instruction
),
779 (maxInstructions
+ 10)
780 * sizeof(struct tgsi_full_instruction
));
781 maxInstructions
+= 10;
784 memcpy(instructions
+ numInstructions
,
785 &parse
.FullToken
.FullInstruction
,
786 sizeof(instructions
[0]));
791 case TGSI_TOKEN_TYPE_PROPERTY
:
798 tgsi_parse_free (&parse
);
800 FREE(mach
->Declarations
);
801 mach
->Declarations
= declarations
;
802 mach
->NumDeclarations
= numDeclarations
;
804 FREE(mach
->Instructions
);
805 mach
->Instructions
= instructions
;
806 mach
->NumInstructions
= numInstructions
;
810 struct tgsi_exec_machine
*
811 tgsi_exec_machine_create( void )
813 struct tgsi_exec_machine
*mach
;
816 mach
= align_malloc( sizeof *mach
, 16 );
820 memset(mach
, 0, sizeof(*mach
));
822 mach
->Addrs
= &mach
->Temps
[TGSI_EXEC_TEMP_ADDR
];
823 mach
->MaxGeometryShaderOutputs
= TGSI_MAX_TOTAL_VERTICES
;
824 mach
->Predicates
= &mach
->Temps
[TGSI_EXEC_TEMP_P0
];
826 mach
->Inputs
= align_malloc(sizeof(struct tgsi_exec_vector
) * PIPE_MAX_ATTRIBS
, 16);
827 mach
->Outputs
= align_malloc(sizeof(struct tgsi_exec_vector
) * PIPE_MAX_ATTRIBS
, 16);
828 if (!mach
->Inputs
|| !mach
->Outputs
)
831 /* Setup constants needed by the SSE2 executor. */
832 for( i
= 0; i
< 4; i
++ ) {
833 mach
->Temps
[TGSI_EXEC_TEMP_00000000_I
].xyzw
[TGSI_EXEC_TEMP_00000000_C
].u
[i
] = 0x00000000;
834 mach
->Temps
[TGSI_EXEC_TEMP_7FFFFFFF_I
].xyzw
[TGSI_EXEC_TEMP_7FFFFFFF_C
].u
[i
] = 0x7FFFFFFF;
835 mach
->Temps
[TGSI_EXEC_TEMP_80000000_I
].xyzw
[TGSI_EXEC_TEMP_80000000_C
].u
[i
] = 0x80000000;
836 mach
->Temps
[TGSI_EXEC_TEMP_FFFFFFFF_I
].xyzw
[TGSI_EXEC_TEMP_FFFFFFFF_C
].u
[i
] = 0xFFFFFFFF; /* not used */
837 mach
->Temps
[TGSI_EXEC_TEMP_ONE_I
].xyzw
[TGSI_EXEC_TEMP_ONE_C
].f
[i
] = 1.0f
;
838 mach
->Temps
[TGSI_EXEC_TEMP_TWO_I
].xyzw
[TGSI_EXEC_TEMP_TWO_C
].f
[i
] = 2.0f
; /* not used */
839 mach
->Temps
[TGSI_EXEC_TEMP_128_I
].xyzw
[TGSI_EXEC_TEMP_128_C
].f
[i
] = 128.0f
;
840 mach
->Temps
[TGSI_EXEC_TEMP_MINUS_128_I
].xyzw
[TGSI_EXEC_TEMP_MINUS_128_C
].f
[i
] = -128.0f
;
841 mach
->Temps
[TGSI_EXEC_TEMP_THREE_I
].xyzw
[TGSI_EXEC_TEMP_THREE_C
].f
[i
] = 3.0f
;
842 mach
->Temps
[TGSI_EXEC_TEMP_HALF_I
].xyzw
[TGSI_EXEC_TEMP_HALF_C
].f
[i
] = 0.5f
;
846 /* silence warnings */
855 align_free(mach
->Inputs
);
856 align_free(mach
->Outputs
);
864 tgsi_exec_machine_destroy(struct tgsi_exec_machine
*mach
)
867 FREE(mach
->Instructions
);
868 FREE(mach
->Declarations
);
870 align_free(mach
->Inputs
);
871 align_free(mach
->Outputs
);
878 micro_add(union tgsi_exec_channel
*dst
,
879 const union tgsi_exec_channel
*src0
,
880 const union tgsi_exec_channel
*src1
)
882 dst
->f
[0] = src0
->f
[0] + src1
->f
[0];
883 dst
->f
[1] = src0
->f
[1] + src1
->f
[1];
884 dst
->f
[2] = src0
->f
[2] + src1
->f
[2];
885 dst
->f
[3] = src0
->f
[3] + src1
->f
[3];
890 union tgsi_exec_channel
*dst
,
891 const union tgsi_exec_channel
*src0
,
892 const union tgsi_exec_channel
*src1
)
894 if (src1
->f
[0] != 0) {
895 dst
->f
[0] = src0
->f
[0] / src1
->f
[0];
897 if (src1
->f
[1] != 0) {
898 dst
->f
[1] = src0
->f
[1] / src1
->f
[1];
900 if (src1
->f
[2] != 0) {
901 dst
->f
[2] = src0
->f
[2] / src1
->f
[2];
903 if (src1
->f
[3] != 0) {
904 dst
->f
[3] = src0
->f
[3] / src1
->f
[3];
909 micro_rcc(union tgsi_exec_channel
*dst
,
910 const union tgsi_exec_channel
*src
)
914 for (i
= 0; i
< 4; i
++) {
915 float recip
= 1.0f
/ src
->f
[i
];
918 if (recip
> 1.884467e+019f
) {
919 dst
->f
[i
] = 1.884467e+019f
;
921 else if (recip
< 5.42101e-020f
) {
922 dst
->f
[i
] = 5.42101e-020f
;
929 if (recip
< -1.884467e+019f
) {
930 dst
->f
[i
] = -1.884467e+019f
;
932 else if (recip
> -5.42101e-020f
) {
933 dst
->f
[i
] = -5.42101e-020f
;
944 union tgsi_exec_channel
*dst
,
945 const union tgsi_exec_channel
*src0
,
946 const union tgsi_exec_channel
*src1
,
947 const union tgsi_exec_channel
*src2
,
948 const union tgsi_exec_channel
*src3
)
950 dst
->f
[0] = src0
->f
[0] < src1
->f
[0] ? src2
->f
[0] : src3
->f
[0];
951 dst
->f
[1] = src0
->f
[1] < src1
->f
[1] ? src2
->f
[1] : src3
->f
[1];
952 dst
->f
[2] = src0
->f
[2] < src1
->f
[2] ? src2
->f
[2] : src3
->f
[2];
953 dst
->f
[3] = src0
->f
[3] < src1
->f
[3] ? src2
->f
[3] : src3
->f
[3];
957 micro_max(union tgsi_exec_channel
*dst
,
958 const union tgsi_exec_channel
*src0
,
959 const union tgsi_exec_channel
*src1
)
961 dst
->f
[0] = src0
->f
[0] > src1
->f
[0] ? src0
->f
[0] : src1
->f
[0];
962 dst
->f
[1] = src0
->f
[1] > src1
->f
[1] ? src0
->f
[1] : src1
->f
[1];
963 dst
->f
[2] = src0
->f
[2] > src1
->f
[2] ? src0
->f
[2] : src1
->f
[2];
964 dst
->f
[3] = src0
->f
[3] > src1
->f
[3] ? src0
->f
[3] : src1
->f
[3];
968 micro_min(union tgsi_exec_channel
*dst
,
969 const union tgsi_exec_channel
*src0
,
970 const union tgsi_exec_channel
*src1
)
972 dst
->f
[0] = src0
->f
[0] < src1
->f
[0] ? src0
->f
[0] : src1
->f
[0];
973 dst
->f
[1] = src0
->f
[1] < src1
->f
[1] ? src0
->f
[1] : src1
->f
[1];
974 dst
->f
[2] = src0
->f
[2] < src1
->f
[2] ? src0
->f
[2] : src1
->f
[2];
975 dst
->f
[3] = src0
->f
[3] < src1
->f
[3] ? src0
->f
[3] : src1
->f
[3];
979 micro_mul(union tgsi_exec_channel
*dst
,
980 const union tgsi_exec_channel
*src0
,
981 const union tgsi_exec_channel
*src1
)
983 dst
->f
[0] = src0
->f
[0] * src1
->f
[0];
984 dst
->f
[1] = src0
->f
[1] * src1
->f
[1];
985 dst
->f
[2] = src0
->f
[2] * src1
->f
[2];
986 dst
->f
[3] = src0
->f
[3] * src1
->f
[3];
991 union tgsi_exec_channel
*dst
,
992 const union tgsi_exec_channel
*src
)
994 dst
->f
[0] = -src
->f
[0];
995 dst
->f
[1] = -src
->f
[1];
996 dst
->f
[2] = -src
->f
[2];
997 dst
->f
[3] = -src
->f
[3];
1002 union tgsi_exec_channel
*dst
,
1003 const union tgsi_exec_channel
*src0
,
1004 const union tgsi_exec_channel
*src1
)
1007 dst
->f
[0] = util_fast_pow( src0
->f
[0], src1
->f
[0] );
1008 dst
->f
[1] = util_fast_pow( src0
->f
[1], src1
->f
[1] );
1009 dst
->f
[2] = util_fast_pow( src0
->f
[2], src1
->f
[2] );
1010 dst
->f
[3] = util_fast_pow( src0
->f
[3], src1
->f
[3] );
1012 dst
->f
[0] = powf( src0
->f
[0], src1
->f
[0] );
1013 dst
->f
[1] = powf( src0
->f
[1], src1
->f
[1] );
1014 dst
->f
[2] = powf( src0
->f
[2], src1
->f
[2] );
1015 dst
->f
[3] = powf( src0
->f
[3], src1
->f
[3] );
1020 micro_sub(union tgsi_exec_channel
*dst
,
1021 const union tgsi_exec_channel
*src0
,
1022 const union tgsi_exec_channel
*src1
)
1024 dst
->f
[0] = src0
->f
[0] - src1
->f
[0];
1025 dst
->f
[1] = src0
->f
[1] - src1
->f
[1];
1026 dst
->f
[2] = src0
->f
[2] - src1
->f
[2];
1027 dst
->f
[3] = src0
->f
[3] - src1
->f
[3];
1031 fetch_src_file_channel(const struct tgsi_exec_machine
*mach
,
1032 const uint chan_index
,
1035 const union tgsi_exec_channel
*index
,
1036 const union tgsi_exec_channel
*index2D
,
1037 union tgsi_exec_channel
*chan
)
1041 assert(swizzle
< 4);
1044 case TGSI_FILE_CONSTANT
:
1045 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1046 assert(index2D
->i
[i
] >= 0 && index2D
->i
[i
] < PIPE_MAX_CONSTANT_BUFFERS
);
1047 assert(mach
->Consts
[index2D
->i
[i
]]);
1049 if (index
->i
[i
] < 0) {
1052 /* NOTE: copying the const value as a uint instead of float */
1053 const uint constbuf
= index2D
->i
[i
];
1054 const uint
*buf
= (const uint
*)mach
->Consts
[constbuf
];
1055 const int pos
= index
->i
[i
] * 4 + swizzle
;
1056 /* const buffer bounds check */
1057 if (pos
< 0 || pos
>= (int) mach
->ConstsSize
[constbuf
]) {
1059 /* Debug: print warning */
1060 static int count
= 0;
1062 debug_printf("TGSI Exec: const buffer index %d"
1063 " out of bounds\n", pos
);
1068 chan
->u
[i
] = buf
[pos
];
1073 case TGSI_FILE_INPUT
:
1074 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1076 if (TGSI_PROCESSOR_GEOMETRY == mach->Processor) {
1077 debug_printf("Fetching Input[%d] (2d=%d, 1d=%d)\n",
1078 index2D->i[i] * TGSI_EXEC_MAX_INPUT_ATTRIBS + index->i[i],
1079 index2D->i[i], index->i[i]);
1081 int pos
= index2D
->i
[i
] * TGSI_EXEC_MAX_INPUT_ATTRIBS
+ index
->i
[i
];
1083 assert(pos
< TGSI_MAX_PRIM_VERTICES
* PIPE_MAX_ATTRIBS
);
1084 chan
->u
[i
] = mach
->Inputs
[pos
].xyzw
[swizzle
].u
[i
];
1088 case TGSI_FILE_SYSTEM_VALUE
:
1089 /* XXX no swizzling at this point. Will be needed if we put
1090 * gl_FragCoord, for example, in a sys value register.
1092 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1093 chan
->u
[i
] = mach
->SystemValue
[index
->i
[i
]].u
[i
];
1097 case TGSI_FILE_TEMPORARY
:
1098 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1099 assert(index
->i
[i
] < TGSI_EXEC_NUM_TEMPS
);
1100 assert(index2D
->i
[i
] == 0);
1102 chan
->u
[i
] = mach
->Temps
[index
->i
[i
]].xyzw
[swizzle
].u
[i
];
1106 case TGSI_FILE_IMMEDIATE
:
1107 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1108 assert(index
->i
[i
] >= 0 && index
->i
[i
] < (int)mach
->ImmLimit
);
1109 assert(index2D
->i
[i
] == 0);
1111 chan
->f
[i
] = mach
->Imms
[index
->i
[i
]][swizzle
];
1115 case TGSI_FILE_ADDRESS
:
1116 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1117 assert(index
->i
[i
] >= 0);
1118 assert(index2D
->i
[i
] == 0);
1120 chan
->u
[i
] = mach
->Addrs
[index
->i
[i
]].xyzw
[swizzle
].u
[i
];
1124 case TGSI_FILE_PREDICATE
:
1125 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1126 assert(index
->i
[i
] >= 0 && index
->i
[i
] < TGSI_EXEC_NUM_PREDS
);
1127 assert(index2D
->i
[i
] == 0);
1129 chan
->u
[i
] = mach
->Predicates
[0].xyzw
[swizzle
].u
[i
];
1133 case TGSI_FILE_OUTPUT
:
1134 /* vertex/fragment output vars can be read too */
1135 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1136 assert(index
->i
[i
] >= 0);
1137 assert(index2D
->i
[i
] == 0);
1139 chan
->u
[i
] = mach
->Outputs
[index
->i
[i
]].xyzw
[swizzle
].u
[i
];
1145 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1152 fetch_source(const struct tgsi_exec_machine
*mach
,
1153 union tgsi_exec_channel
*chan
,
1154 const struct tgsi_full_src_register
*reg
,
1155 const uint chan_index
,
1156 enum tgsi_exec_datatype src_datatype
)
1158 union tgsi_exec_channel index
;
1159 union tgsi_exec_channel index2D
;
1162 /* We start with a direct index into a register file.
1166 * file = Register.File
1167 * [1] = Register.Index
1172 index
.i
[3] = reg
->Register
.Index
;
1174 /* There is an extra source register that indirectly subscripts
1175 * a register file. The direct index now becomes an offset
1176 * that is being added to the indirect register.
1180 * ind = Indirect.File
1181 * [2] = Indirect.Index
1182 * .x = Indirect.SwizzleX
1184 if (reg
->Register
.Indirect
) {
1185 union tgsi_exec_channel index2
;
1186 union tgsi_exec_channel indir_index
;
1187 const uint execmask
= mach
->ExecMask
;
1190 /* which address register (always zero now) */
1194 index2
.i
[3] = reg
->Indirect
.Index
;
1195 /* get current value of address register[swizzle] */
1196 swizzle
= reg
->Indirect
.Swizzle
;
1197 fetch_src_file_channel(mach
,
1205 /* add value of address register to the offset */
1206 index
.i
[0] += indir_index
.i
[0];
1207 index
.i
[1] += indir_index
.i
[1];
1208 index
.i
[2] += indir_index
.i
[2];
1209 index
.i
[3] += indir_index
.i
[3];
1211 /* for disabled execution channels, zero-out the index to
1212 * avoid using a potential garbage value.
1214 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1215 if ((execmask
& (1 << i
)) == 0)
1220 /* There is an extra source register that is a second
1221 * subscript to a register file. Effectively it means that
1222 * the register file is actually a 2D array of registers.
1226 * [3] = Dimension.Index
1228 if (reg
->Register
.Dimension
) {
1232 index2D
.i
[3] = reg
->Dimension
.Index
;
1234 /* Again, the second subscript index can be addressed indirectly
1235 * identically to the first one.
1236 * Nothing stops us from indirectly addressing the indirect register,
1237 * but there is no need for that, so we won't exercise it.
1239 * file[ind[4].y+3][1],
1241 * ind = DimIndirect.File
1242 * [4] = DimIndirect.Index
1243 * .y = DimIndirect.SwizzleX
1245 if (reg
->Dimension
.Indirect
) {
1246 union tgsi_exec_channel index2
;
1247 union tgsi_exec_channel indir_index
;
1248 const uint execmask
= mach
->ExecMask
;
1254 index2
.i
[3] = reg
->DimIndirect
.Index
;
1256 swizzle
= reg
->DimIndirect
.Swizzle
;
1257 fetch_src_file_channel(mach
,
1259 reg
->DimIndirect
.File
,
1265 index2D
.i
[0] += indir_index
.i
[0];
1266 index2D
.i
[1] += indir_index
.i
[1];
1267 index2D
.i
[2] += indir_index
.i
[2];
1268 index2D
.i
[3] += indir_index
.i
[3];
1270 /* for disabled execution channels, zero-out the index to
1271 * avoid using a potential garbage value.
1273 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1274 if ((execmask
& (1 << i
)) == 0) {
1280 /* If by any chance there was a need for a 3D array of register
1281 * files, we would have to check whether Dimension is followed
1282 * by a dimension register and continue the saga.
1291 swizzle
= tgsi_util_get_full_src_register_swizzle( reg
, chan_index
);
1292 fetch_src_file_channel(mach
,
1300 if (reg
->Register
.Absolute
) {
1301 if (src_datatype
== TGSI_EXEC_DATA_FLOAT
) {
1302 micro_abs(chan
, chan
);
1304 micro_iabs(chan
, chan
);
1308 if (reg
->Register
.Negate
) {
1309 if (src_datatype
== TGSI_EXEC_DATA_FLOAT
) {
1310 micro_neg(chan
, chan
);
1312 micro_ineg(chan
, chan
);
1318 store_dest(struct tgsi_exec_machine
*mach
,
1319 const union tgsi_exec_channel
*chan
,
1320 const struct tgsi_full_dst_register
*reg
,
1321 const struct tgsi_full_instruction
*inst
,
1323 enum tgsi_exec_datatype dst_datatype
)
1326 union tgsi_exec_channel null
;
1327 union tgsi_exec_channel
*dst
;
1328 union tgsi_exec_channel index2D
;
1329 uint execmask
= mach
->ExecMask
;
1330 int offset
= 0; /* indirection offset */
1334 if (0 && dst_datatype
== TGSI_EXEC_DATA_FLOAT
) {
1335 check_inf_or_nan(chan
);
1338 /* There is an extra source register that indirectly subscripts
1339 * a register file. The direct index now becomes an offset
1340 * that is being added to the indirect register.
1344 * ind = Indirect.File
1345 * [2] = Indirect.Index
1346 * .x = Indirect.SwizzleX
1348 if (reg
->Register
.Indirect
) {
1349 union tgsi_exec_channel index
;
1350 union tgsi_exec_channel indir_index
;
1353 /* which address register (always zero for now) */
1357 index
.i
[3] = reg
->Indirect
.Index
;
1359 /* get current value of address register[swizzle] */
1360 swizzle
= reg
->Indirect
.Swizzle
;
1362 /* fetch values from the address/indirection register */
1363 fetch_src_file_channel(mach
,
1371 /* save indirection offset */
1372 offset
= indir_index
.i
[0];
1375 /* There is an extra source register that is a second
1376 * subscript to a register file. Effectively it means that
1377 * the register file is actually a 2D array of registers.
1381 * [3] = Dimension.Index
1383 if (reg
->Register
.Dimension
) {
1387 index2D
.i
[3] = reg
->Dimension
.Index
;
1389 /* Again, the second subscript index can be addressed indirectly
1390 * identically to the first one.
1391 * Nothing stops us from indirectly addressing the indirect register,
1392 * but there is no need for that, so we won't exercise it.
1394 * file[ind[4].y+3][1],
1396 * ind = DimIndirect.File
1397 * [4] = DimIndirect.Index
1398 * .y = DimIndirect.SwizzleX
1400 if (reg
->Dimension
.Indirect
) {
1401 union tgsi_exec_channel index2
;
1402 union tgsi_exec_channel indir_index
;
1403 const uint execmask
= mach
->ExecMask
;
1410 index2
.i
[3] = reg
->DimIndirect
.Index
;
1412 swizzle
= reg
->DimIndirect
.Swizzle
;
1413 fetch_src_file_channel(mach
,
1415 reg
->DimIndirect
.File
,
1421 index2D
.i
[0] += indir_index
.i
[0];
1422 index2D
.i
[1] += indir_index
.i
[1];
1423 index2D
.i
[2] += indir_index
.i
[2];
1424 index2D
.i
[3] += indir_index
.i
[3];
1426 /* for disabled execution channels, zero-out the index to
1427 * avoid using a potential garbage value.
1429 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1430 if ((execmask
& (1 << i
)) == 0) {
1436 /* If by any chance there was a need for a 3D array of register
1437 * files, we would have to check whether Dimension is followed
1438 * by a dimension register and continue the saga.
1447 switch (reg
->Register
.File
) {
1448 case TGSI_FILE_NULL
:
1452 case TGSI_FILE_OUTPUT
:
1453 index
= mach
->Temps
[TEMP_OUTPUT_I
].xyzw
[TEMP_OUTPUT_C
].u
[0]
1454 + reg
->Register
.Index
;
1455 dst
= &mach
->Outputs
[offset
+ index
].xyzw
[chan_index
];
1457 debug_printf("NumOutputs = %d, TEMP_O_C/I = %d, redindex = %d\n",
1458 mach
->NumOutputs
, mach
->Temps
[TEMP_OUTPUT_I
].xyzw
[TEMP_OUTPUT_C
].u
[0],
1459 reg
->Register
.Index
);
1460 if (TGSI_PROCESSOR_GEOMETRY
== mach
->Processor
) {
1461 debug_printf("STORING OUT[%d] mask(%d), = (", offset
+ index
, execmask
);
1462 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++)
1463 if (execmask
& (1 << i
))
1464 debug_printf("%f, ", chan
->f
[i
]);
1465 debug_printf(")\n");
1470 case TGSI_FILE_TEMPORARY
:
1471 index
= reg
->Register
.Index
;
1472 assert( index
< TGSI_EXEC_NUM_TEMPS
);
1473 dst
= &mach
->Temps
[offset
+ index
].xyzw
[chan_index
];
1476 case TGSI_FILE_ADDRESS
:
1477 index
= reg
->Register
.Index
;
1478 dst
= &mach
->Addrs
[index
].xyzw
[chan_index
];
1481 case TGSI_FILE_PREDICATE
:
1482 index
= reg
->Register
.Index
;
1483 assert(index
< TGSI_EXEC_NUM_PREDS
);
1484 dst
= &mach
->Predicates
[index
].xyzw
[chan_index
];
1492 if (inst
->Instruction
.Predicate
) {
1494 union tgsi_exec_channel
*pred
;
1496 switch (chan_index
) {
1498 swizzle
= inst
->Predicate
.SwizzleX
;
1501 swizzle
= inst
->Predicate
.SwizzleY
;
1504 swizzle
= inst
->Predicate
.SwizzleZ
;
1507 swizzle
= inst
->Predicate
.SwizzleW
;
1514 assert(inst
->Predicate
.Index
== 0);
1516 pred
= &mach
->Predicates
[inst
->Predicate
.Index
].xyzw
[swizzle
];
1518 if (inst
->Predicate
.Negate
) {
1519 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1521 execmask
&= ~(1 << i
);
1525 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
1527 execmask
&= ~(1 << i
);
1533 switch (inst
->Instruction
.Saturate
) {
1535 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++)
1536 if (execmask
& (1 << i
))
1537 dst
->i
[i
] = chan
->i
[i
];
1540 case TGSI_SAT_ZERO_ONE
:
1541 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++)
1542 if (execmask
& (1 << i
)) {
1543 if (chan
->f
[i
] < 0.0f
)
1545 else if (chan
->f
[i
] > 1.0f
)
1548 dst
->i
[i
] = chan
->i
[i
];
1552 case TGSI_SAT_MINUS_PLUS_ONE
:
1553 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++)
1554 if (execmask
& (1 << i
)) {
1555 if (chan
->f
[i
] < -1.0f
)
1557 else if (chan
->f
[i
] > 1.0f
)
1560 dst
->i
[i
] = chan
->i
[i
];
1569 #define FETCH(VAL,INDEX,CHAN)\
1570 fetch_source(mach, VAL, &inst->Src[INDEX], CHAN, TGSI_EXEC_DATA_FLOAT)
1572 #define IFETCH(VAL,INDEX,CHAN)\
1573 fetch_source(mach, VAL, &inst->Src[INDEX], CHAN, TGSI_EXEC_DATA_INT)
1577 * Execute ARB-style KIL which is predicated by a src register.
1578 * Kill fragment if any of the four values is less than zero.
1581 exec_kil(struct tgsi_exec_machine
*mach
,
1582 const struct tgsi_full_instruction
*inst
)
1586 uint kilmask
= 0; /* bit 0 = pixel 0, bit 1 = pixel 1, etc */
1587 union tgsi_exec_channel r
[1];
1589 /* This mask stores component bits that were already tested. */
1592 for (chan_index
= 0; chan_index
< 4; chan_index
++)
1597 /* unswizzle channel */
1598 swizzle
= tgsi_util_get_full_src_register_swizzle (
1602 /* check if the component has not been already tested */
1603 if (uniquemask
& (1 << swizzle
))
1605 uniquemask
|= 1 << swizzle
;
1607 FETCH(&r
[0], 0, chan_index
);
1608 for (i
= 0; i
< 4; i
++)
1609 if (r
[0].f
[i
] < 0.0f
)
1613 mach
->Temps
[TEMP_KILMASK_I
].xyzw
[TEMP_KILMASK_C
].u
[0] |= kilmask
;
1617 * Execute NVIDIA-style KIL which is predicated by a condition code.
1618 * Kill fragment if the condition code is TRUE.
1621 exec_kilp(struct tgsi_exec_machine
*mach
,
1622 const struct tgsi_full_instruction
*inst
)
1624 uint kilmask
; /* bit 0 = pixel 0, bit 1 = pixel 1, etc */
1626 /* "unconditional" kil */
1627 kilmask
= mach
->ExecMask
;
1628 mach
->Temps
[TEMP_KILMASK_I
].xyzw
[TEMP_KILMASK_C
].u
[0] |= kilmask
;
1632 emit_vertex(struct tgsi_exec_machine
*mach
)
1634 /* FIXME: check for exec mask correctly
1636 for (i = 0; i < TGSI_QUAD_SIZE; ++i) {
1637 if ((mach->ExecMask & (1 << i)))
1639 if (mach
->ExecMask
) {
1640 mach
->Temps
[TEMP_OUTPUT_I
].xyzw
[TEMP_OUTPUT_C
].u
[0] += mach
->NumOutputs
;
1641 mach
->Primitives
[mach
->Temps
[TEMP_PRIMITIVE_I
].xyzw
[TEMP_PRIMITIVE_C
].u
[0]]++;
1646 emit_primitive(struct tgsi_exec_machine
*mach
)
1648 unsigned *prim_count
= &mach
->Temps
[TEMP_PRIMITIVE_I
].xyzw
[TEMP_PRIMITIVE_C
].u
[0];
1649 /* FIXME: check for exec mask correctly
1651 for (i = 0; i < TGSI_QUAD_SIZE; ++i) {
1652 if ((mach->ExecMask & (1 << i)))
1654 if (mach
->ExecMask
) {
1656 debug_assert((*prim_count
* mach
->NumOutputs
) < mach
->MaxGeometryShaderOutputs
);
1657 mach
->Primitives
[*prim_count
] = 0;
1662 conditional_emit_primitive(struct tgsi_exec_machine
*mach
)
1664 if (TGSI_PROCESSOR_GEOMETRY
== mach
->Processor
) {
1666 mach
->Primitives
[mach
->Temps
[TEMP_PRIMITIVE_I
].xyzw
[TEMP_PRIMITIVE_C
].u
[0]];
1667 if (emitted_verts
) {
1668 emit_primitive(mach
);
1675 * Fetch four texture samples using STR texture coordinates.
1678 fetch_texel( struct tgsi_sampler
*sampler
,
1679 const unsigned sview_idx
,
1680 const unsigned sampler_idx
,
1681 const union tgsi_exec_channel
*s
,
1682 const union tgsi_exec_channel
*t
,
1683 const union tgsi_exec_channel
*p
,
1684 const union tgsi_exec_channel
*c0
,
1685 const union tgsi_exec_channel
*c1
,
1686 float derivs
[3][2][TGSI_QUAD_SIZE
],
1687 const int8_t offset
[3],
1688 enum tgsi_sampler_control control
,
1689 union tgsi_exec_channel
*r
,
1690 union tgsi_exec_channel
*g
,
1691 union tgsi_exec_channel
*b
,
1692 union tgsi_exec_channel
*a
)
1695 float rgba
[TGSI_NUM_CHANNELS
][TGSI_QUAD_SIZE
];
1697 /* FIXME: handle explicit derivs, offsets */
1698 sampler
->get_samples(sampler
, sview_idx
, sampler_idx
,
1699 s
->f
, t
->f
, p
->f
, c0
->f
, c1
->f
, derivs
, offset
, control
, rgba
);
1701 for (j
= 0; j
< 4; j
++) {
1702 r
->f
[j
] = rgba
[0][j
];
1703 g
->f
[j
] = rgba
[1][j
];
1704 b
->f
[j
] = rgba
[2][j
];
1705 a
->f
[j
] = rgba
[3][j
];
1710 #define TEX_MODIFIER_NONE 0
1711 #define TEX_MODIFIER_PROJECTED 1
1712 #define TEX_MODIFIER_LOD_BIAS 2
1713 #define TEX_MODIFIER_EXPLICIT_LOD 3
1714 #define TEX_MODIFIER_LEVEL_ZERO 4
1718 * Fetch all 3 (for s,t,r coords) texel offsets, put them into int array.
1721 fetch_texel_offsets(struct tgsi_exec_machine
*mach
,
1722 const struct tgsi_full_instruction
*inst
,
1725 if (inst
->Texture
.NumOffsets
== 1) {
1726 union tgsi_exec_channel index
;
1727 union tgsi_exec_channel offset
[3];
1728 index
.i
[0] = index
.i
[1] = index
.i
[2] = index
.i
[3] = inst
->TexOffsets
[0].Index
;
1729 fetch_src_file_channel(mach
, 0, inst
->TexOffsets
[0].File
,
1730 inst
->TexOffsets
[0].SwizzleX
, &index
, &ZeroVec
, &offset
[0]);
1731 fetch_src_file_channel(mach
, 0, inst
->TexOffsets
[0].File
,
1732 inst
->TexOffsets
[0].SwizzleY
, &index
, &ZeroVec
, &offset
[1]);
1733 fetch_src_file_channel(mach
, 0, inst
->TexOffsets
[0].File
,
1734 inst
->TexOffsets
[0].SwizzleZ
, &index
, &ZeroVec
, &offset
[2]);
1735 offsets
[0] = offset
[0].i
[0];
1736 offsets
[1] = offset
[1].i
[0];
1737 offsets
[2] = offset
[2].i
[0];
1739 assert(inst
->Texture
.NumOffsets
== 0);
1740 offsets
[0] = offsets
[1] = offsets
[2] = 0;
1746 * Fetch dx and dy values for one channel (s, t or r).
1747 * Put dx values into one float array, dy values into another.
1750 fetch_assign_deriv_channel(struct tgsi_exec_machine
*mach
,
1751 const struct tgsi_full_instruction
*inst
,
1754 float derivs
[2][TGSI_QUAD_SIZE
])
1756 union tgsi_exec_channel d
;
1757 FETCH(&d
, regdsrcx
, chan
);
1758 derivs
[0][0] = d
.f
[0];
1759 derivs
[0][1] = d
.f
[1];
1760 derivs
[0][2] = d
.f
[2];
1761 derivs
[0][3] = d
.f
[3];
1762 FETCH(&d
, regdsrcx
+ 1, chan
);
1763 derivs
[1][0] = d
.f
[0];
1764 derivs
[1][1] = d
.f
[1];
1765 derivs
[1][2] = d
.f
[2];
1766 derivs
[1][3] = d
.f
[3];
1771 * execute a texture instruction.
1773 * modifier is used to control the channel routing for the\
1774 * instruction variants like proj, lod, and texture with lod bias.
1775 * sampler indicates which src register the sampler is contained in.
1778 exec_tex(struct tgsi_exec_machine
*mach
,
1779 const struct tgsi_full_instruction
*inst
,
1780 uint modifier
, uint sampler
)
1782 const uint unit
= inst
->Src
[sampler
].Register
.Index
;
1783 union tgsi_exec_channel r
[4], cubearraycomp
, cubelod
;
1784 const union tgsi_exec_channel
*lod
= &ZeroVec
;
1785 enum tgsi_sampler_control control
= tgsi_sampler_lod_none
;
1789 /* always fetch all 3 offsets, overkill but keeps code simple */
1790 fetch_texel_offsets(mach
, inst
, offsets
);
1792 assert(modifier
!= TEX_MODIFIER_LEVEL_ZERO
);
1794 if (modifier
!= TEX_MODIFIER_NONE
&& (sampler
== 1)) {
1795 FETCH(&r
[3], 0, TGSI_CHAN_W
);
1796 if (modifier
!= TEX_MODIFIER_PROJECTED
) {
1801 if (modifier
== TEX_MODIFIER_EXPLICIT_LOD
) {
1802 control
= tgsi_sampler_lod_explicit
;
1803 } else if (modifier
== TEX_MODIFIER_LOD_BIAS
){
1804 control
= tgsi_sampler_lod_bias
;
1807 switch (inst
->Texture
.Texture
) {
1808 case TGSI_TEXTURE_1D
:
1809 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1811 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1812 micro_div(&r
[0], &r
[0], &r
[3]);
1815 fetch_texel(mach
->Sampler
, unit
, unit
,
1816 &r
[0], &ZeroVec
, &ZeroVec
, &ZeroVec
, lod
, /* S, T, P, C, LOD */
1817 NULL
, offsets
, control
,
1818 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
1821 case TGSI_TEXTURE_SHADOW1D
:
1822 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1823 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1825 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1826 micro_div(&r
[0], &r
[0], &r
[3]);
1827 micro_div(&r
[2], &r
[2], &r
[3]);
1830 fetch_texel(mach
->Sampler
, unit
, unit
,
1831 &r
[0], &ZeroVec
, &r
[2], &ZeroVec
, lod
, /* S, T, P, C, LOD */
1832 NULL
, offsets
, control
,
1833 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
1836 case TGSI_TEXTURE_2D
:
1837 case TGSI_TEXTURE_RECT
:
1838 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1839 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1841 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1842 micro_div(&r
[0], &r
[0], &r
[3]);
1843 micro_div(&r
[1], &r
[1], &r
[3]);
1846 fetch_texel(mach
->Sampler
, unit
, unit
,
1847 &r
[0], &r
[1], &ZeroVec
, &ZeroVec
, lod
, /* S, T, P, C, LOD */
1848 NULL
, offsets
, control
,
1849 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1852 case TGSI_TEXTURE_SHADOW2D
:
1853 case TGSI_TEXTURE_SHADOWRECT
:
1854 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1855 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1856 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1858 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1859 micro_div(&r
[0], &r
[0], &r
[3]);
1860 micro_div(&r
[1], &r
[1], &r
[3]);
1861 micro_div(&r
[2], &r
[2], &r
[3]);
1864 fetch_texel(mach
->Sampler
, unit
, unit
,
1865 &r
[0], &r
[1], &r
[2], &ZeroVec
, lod
, /* S, T, P, C, LOD */
1866 NULL
, offsets
, control
,
1867 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1870 case TGSI_TEXTURE_1D_ARRAY
:
1871 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1872 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1874 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1875 micro_div(&r
[0], &r
[0], &r
[3]);
1878 fetch_texel(mach
->Sampler
, unit
, unit
,
1879 &r
[0], &r
[1], &ZeroVec
, &ZeroVec
, lod
, /* S, T, P, C, LOD */
1880 NULL
, offsets
, control
,
1881 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1883 case TGSI_TEXTURE_SHADOW1D_ARRAY
:
1884 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1885 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1886 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1888 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1889 micro_div(&r
[0], &r
[0], &r
[3]);
1890 micro_div(&r
[2], &r
[2], &r
[3]);
1893 fetch_texel(mach
->Sampler
, unit
, unit
,
1894 &r
[0], &r
[1], &r
[2], &ZeroVec
, lod
, /* S, T, P, C, LOD */
1895 NULL
, offsets
, control
,
1896 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1899 case TGSI_TEXTURE_2D_ARRAY
:
1900 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1901 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1902 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1904 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1905 micro_div(&r
[0], &r
[0], &r
[3]);
1906 micro_div(&r
[1], &r
[1], &r
[3]);
1909 fetch_texel(mach
->Sampler
, unit
, unit
,
1910 &r
[0], &r
[1], &r
[2], &ZeroVec
, lod
, /* S, T, P, C, LOD */
1911 NULL
, offsets
, control
,
1912 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1914 case TGSI_TEXTURE_SHADOW2D_ARRAY
:
1915 case TGSI_TEXTURE_SHADOWCUBE
:
1916 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1917 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1918 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1919 FETCH(&r
[3], 0, TGSI_CHAN_W
);
1921 fetch_texel(mach
->Sampler
, unit
, unit
,
1922 &r
[0], &r
[1], &r
[2], &r
[3], &ZeroVec
, /* S, T, P, C, LOD */
1923 NULL
, offsets
, control
,
1924 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1926 case TGSI_TEXTURE_CUBE_ARRAY
:
1927 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1928 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1929 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1930 FETCH(&r
[3], 0, TGSI_CHAN_W
);
1932 if (modifier
== TEX_MODIFIER_EXPLICIT_LOD
||
1933 modifier
== TEX_MODIFIER_LOD_BIAS
)
1934 FETCH(&cubelod
, 1, TGSI_CHAN_X
);
1938 fetch_texel(mach
->Sampler
, unit
, unit
,
1939 &r
[0], &r
[1], &r
[2], &r
[3], &cubelod
, /* S, T, P, C, LOD */
1940 NULL
, offsets
, control
,
1941 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1943 case TGSI_TEXTURE_3D
:
1944 case TGSI_TEXTURE_CUBE
:
1945 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1946 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1947 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1949 if (modifier
== TEX_MODIFIER_PROJECTED
) {
1950 micro_div(&r
[0], &r
[0], &r
[3]);
1951 micro_div(&r
[1], &r
[1], &r
[3]);
1952 micro_div(&r
[2], &r
[2], &r
[3]);
1955 fetch_texel(mach
->Sampler
, unit
, unit
,
1956 &r
[0], &r
[1], &r
[2], &ZeroVec
, lod
,
1957 NULL
, offsets
, control
,
1958 &r
[0], &r
[1], &r
[2], &r
[3]);
1961 case TGSI_TEXTURE_SHADOWCUBE_ARRAY
:
1962 FETCH(&r
[0], 0, TGSI_CHAN_X
);
1963 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
1964 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
1965 FETCH(&r
[3], 0, TGSI_CHAN_W
);
1967 FETCH(&cubearraycomp
, 1, TGSI_CHAN_X
);
1969 fetch_texel(mach
->Sampler
, unit
, unit
,
1970 &r
[0], &r
[1], &r
[2], &r
[3], &cubearraycomp
, /* S, T, P, C, LOD */
1971 NULL
, offsets
, control
,
1972 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
1979 debug_printf("fetch r: %g %g %g %g\n",
1980 r
[0].f
[0], r
[0].f
[1], r
[0].f
[2], r
[0].f
[3]);
1981 debug_printf("fetch g: %g %g %g %g\n",
1982 r
[1].f
[0], r
[1].f
[1], r
[1].f
[2], r
[1].f
[3]);
1983 debug_printf("fetch b: %g %g %g %g\n",
1984 r
[2].f
[0], r
[2].f
[1], r
[2].f
[2], r
[2].f
[3]);
1985 debug_printf("fetch a: %g %g %g %g\n",
1986 r
[3].f
[0], r
[3].f
[1], r
[3].f
[2], r
[3].f
[3]);
1989 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
1990 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
1991 store_dest(mach
, &r
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
1998 exec_txd(struct tgsi_exec_machine
*mach
,
1999 const struct tgsi_full_instruction
*inst
)
2001 const uint unit
= inst
->Src
[3].Register
.Index
;
2002 union tgsi_exec_channel r
[4];
2003 float derivs
[3][2][TGSI_QUAD_SIZE
];
2007 /* always fetch all 3 offsets, overkill but keeps code simple */
2008 fetch_texel_offsets(mach
, inst
, offsets
);
2010 switch (inst
->Texture
.Texture
) {
2011 case TGSI_TEXTURE_1D
:
2012 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2014 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_X
, derivs
[0]);
2016 fetch_texel(mach
->Sampler
, unit
, unit
,
2017 &r
[0], &ZeroVec
, &ZeroVec
, &ZeroVec
, &ZeroVec
, /* S, T, P, C, LOD */
2018 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2019 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
2022 case TGSI_TEXTURE_SHADOW1D
:
2023 case TGSI_TEXTURE_1D_ARRAY
:
2024 case TGSI_TEXTURE_SHADOW1D_ARRAY
:
2025 /* SHADOW1D/1D_ARRAY would not need Y/Z respectively, but don't bother */
2026 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2027 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2028 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2030 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_X
, derivs
[0]);
2032 fetch_texel(mach
->Sampler
, unit
, unit
,
2033 &r
[0], &r
[1], &r
[2], &ZeroVec
, &ZeroVec
, /* S, T, P, C, LOD */
2034 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2035 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
2038 case TGSI_TEXTURE_2D
:
2039 case TGSI_TEXTURE_RECT
:
2040 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2041 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2043 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_X
, derivs
[0]);
2044 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_Y
, derivs
[1]);
2046 fetch_texel(mach
->Sampler
, unit
, unit
,
2047 &r
[0], &r
[1], &ZeroVec
, &ZeroVec
, &ZeroVec
, /* S, T, P, C, LOD */
2048 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2049 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
2053 case TGSI_TEXTURE_SHADOW2D
:
2054 case TGSI_TEXTURE_SHADOWRECT
:
2055 case TGSI_TEXTURE_2D_ARRAY
:
2056 case TGSI_TEXTURE_SHADOW2D_ARRAY
:
2057 /* only SHADOW2D_ARRAY actually needs W */
2058 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2059 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2060 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2061 FETCH(&r
[3], 0, TGSI_CHAN_W
);
2063 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_X
, derivs
[0]);
2064 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_Y
, derivs
[1]);
2066 fetch_texel(mach
->Sampler
, unit
, unit
,
2067 &r
[0], &r
[1], &r
[2], &r
[3], &ZeroVec
, /* inputs */
2068 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2069 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
2072 case TGSI_TEXTURE_3D
:
2073 case TGSI_TEXTURE_CUBE
:
2074 case TGSI_TEXTURE_CUBE_ARRAY
:
2075 /* only TEXTURE_CUBE_ARRAY actually needs W */
2076 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2077 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2078 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2079 FETCH(&r
[3], 0, TGSI_CHAN_W
);
2081 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_X
, derivs
[0]);
2082 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_Y
, derivs
[1]);
2083 fetch_assign_deriv_channel(mach
, inst
, 1, TGSI_CHAN_Z
, derivs
[2]);
2085 fetch_texel(mach
->Sampler
, unit
, unit
,
2086 &r
[0], &r
[1], &r
[2], &r
[3], &ZeroVec
, /* inputs */
2087 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2088 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
2095 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2096 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2097 store_dest(mach
, &r
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2104 exec_txf(struct tgsi_exec_machine
*mach
,
2105 const struct tgsi_full_instruction
*inst
)
2107 const uint unit
= inst
->Src
[1].Register
.Index
;
2108 union tgsi_exec_channel r
[4];
2110 float rgba
[TGSI_NUM_CHANNELS
][TGSI_QUAD_SIZE
];
2115 /* always fetch all 3 offsets, overkill but keeps code simple */
2116 fetch_texel_offsets(mach
, inst
, offsets
);
2118 IFETCH(&r
[3], 0, TGSI_CHAN_W
);
2120 if (inst
->Instruction
.Opcode
== TGSI_OPCODE_SAMPLE_I
) {
2121 target
= mach
->SamplerViews
[unit
].Resource
;
2124 target
= inst
->Texture
.Texture
;
2127 case TGSI_TEXTURE_3D
:
2128 case TGSI_TEXTURE_2D_ARRAY
:
2129 case TGSI_TEXTURE_SHADOW2D_ARRAY
:
2130 IFETCH(&r
[2], 0, TGSI_CHAN_Z
);
2132 case TGSI_TEXTURE_2D
:
2133 case TGSI_TEXTURE_RECT
:
2134 case TGSI_TEXTURE_SHADOW1D_ARRAY
:
2135 case TGSI_TEXTURE_SHADOW2D
:
2136 case TGSI_TEXTURE_SHADOWRECT
:
2137 case TGSI_TEXTURE_1D_ARRAY
:
2138 IFETCH(&r
[1], 0, TGSI_CHAN_Y
);
2140 case TGSI_TEXTURE_BUFFER
:
2141 case TGSI_TEXTURE_1D
:
2142 case TGSI_TEXTURE_SHADOW1D
:
2143 IFETCH(&r
[0], 0, TGSI_CHAN_X
);
2150 mach
->Sampler
->get_texel(mach
->Sampler
, unit
, r
[0].i
, r
[1].i
, r
[2].i
, r
[3].i
,
2153 for (j
= 0; j
< TGSI_QUAD_SIZE
; j
++) {
2154 r
[0].f
[j
] = rgba
[0][j
];
2155 r
[1].f
[j
] = rgba
[1][j
];
2156 r
[2].f
[j
] = rgba
[2][j
];
2157 r
[3].f
[j
] = rgba
[3][j
];
2160 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2161 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2162 store_dest(mach
, &r
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2168 exec_txq(struct tgsi_exec_machine
*mach
,
2169 const struct tgsi_full_instruction
*inst
)
2171 const uint unit
= inst
->Src
[1].Register
.Index
;
2173 union tgsi_exec_channel r
[4], src
;
2177 fetch_source(mach
, &src
, &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_INT
);
2179 mach
->Sampler
->get_dims(mach
->Sampler
, unit
, src
.i
[0], result
);
2181 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
2182 for (j
= 0; j
< 4; j
++) {
2183 r
[j
].i
[i
] = result
[j
];
2187 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2188 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2189 store_dest(mach
, &r
[chan
], &inst
->Dst
[0], inst
, chan
,
2190 TGSI_EXEC_DATA_INT
);
2196 exec_sample(struct tgsi_exec_machine
*mach
,
2197 const struct tgsi_full_instruction
*inst
,
2198 uint modifier
, boolean compare
)
2200 const uint resource_unit
= inst
->Src
[1].Register
.Index
;
2201 const uint sampler_unit
= inst
->Src
[2].Register
.Index
;
2202 union tgsi_exec_channel r
[4], c1
;
2203 const union tgsi_exec_channel
*lod
= &ZeroVec
;
2204 enum tgsi_sampler_control control
= tgsi_sampler_lod_none
;
2208 /* always fetch all 3 offsets, overkill but keeps code simple */
2209 fetch_texel_offsets(mach
, inst
, offsets
);
2211 assert(modifier
!= TEX_MODIFIER_PROJECTED
);
2213 if (modifier
!= TEX_MODIFIER_NONE
) {
2214 if (modifier
== TEX_MODIFIER_LOD_BIAS
) {
2215 FETCH(&c1
, 3, TGSI_CHAN_X
);
2217 control
= tgsi_sampler_lod_bias
;
2219 else if (modifier
== TEX_MODIFIER_EXPLICIT_LOD
) {
2220 FETCH(&c1
, 3, TGSI_CHAN_X
);
2222 control
= tgsi_sampler_lod_explicit
;
2225 assert(modifier
== TEX_MODIFIER_LEVEL_ZERO
);
2226 control
= tgsi_sampler_lod_zero
;
2230 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2232 switch (mach
->SamplerViews
[resource_unit
].Resource
) {
2233 case TGSI_TEXTURE_1D
:
2235 FETCH(&r
[2], 3, TGSI_CHAN_X
);
2236 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2237 &r
[0], &ZeroVec
, &r
[2], &ZeroVec
, lod
, /* S, T, P, C, LOD */
2238 NULL
, offsets
, control
,
2239 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
2242 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2243 &r
[0], &ZeroVec
, &ZeroVec
, &ZeroVec
, lod
, /* S, T, P, C, LOD */
2244 NULL
, offsets
, control
,
2245 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
2249 case TGSI_TEXTURE_1D_ARRAY
:
2250 case TGSI_TEXTURE_2D
:
2251 case TGSI_TEXTURE_RECT
:
2252 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2254 FETCH(&r
[2], 3, TGSI_CHAN_X
);
2255 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2256 &r
[0], &r
[1], &r
[2], &ZeroVec
, lod
, /* S, T, P, C, LOD */
2257 NULL
, offsets
, control
,
2258 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
2261 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2262 &r
[0], &r
[1], &ZeroVec
, &ZeroVec
, lod
, /* S, T, P, C, LOD */
2263 NULL
, offsets
, control
,
2264 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
2268 case TGSI_TEXTURE_2D_ARRAY
:
2269 case TGSI_TEXTURE_3D
:
2270 case TGSI_TEXTURE_CUBE
:
2271 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2272 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2274 FETCH(&r
[3], 3, TGSI_CHAN_X
);
2275 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2276 &r
[0], &r
[1], &r
[2], &r
[3], lod
,
2277 NULL
, offsets
, control
,
2278 &r
[0], &r
[1], &r
[2], &r
[3]);
2281 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2282 &r
[0], &r
[1], &r
[2], &ZeroVec
, lod
,
2283 NULL
, offsets
, control
,
2284 &r
[0], &r
[1], &r
[2], &r
[3]);
2288 case TGSI_TEXTURE_CUBE_ARRAY
:
2289 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2290 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2291 FETCH(&r
[3], 0, TGSI_CHAN_W
);
2293 FETCH(&r
[4], 3, TGSI_CHAN_X
);
2294 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2295 &r
[0], &r
[1], &r
[2], &r
[3], &r
[4],
2296 NULL
, offsets
, control
,
2297 &r
[0], &r
[1], &r
[2], &r
[3]);
2300 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2301 &r
[0], &r
[1], &r
[2], &r
[3], lod
,
2302 NULL
, offsets
, control
,
2303 &r
[0], &r
[1], &r
[2], &r
[3]);
2312 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2313 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2314 store_dest(mach
, &r
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2320 exec_sample_d(struct tgsi_exec_machine
*mach
,
2321 const struct tgsi_full_instruction
*inst
)
2323 const uint resource_unit
= inst
->Src
[1].Register
.Index
;
2324 const uint sampler_unit
= inst
->Src
[2].Register
.Index
;
2325 union tgsi_exec_channel r
[4];
2326 float derivs
[3][2][TGSI_QUAD_SIZE
];
2330 /* always fetch all 3 offsets, overkill but keeps code simple */
2331 fetch_texel_offsets(mach
, inst
, offsets
);
2333 FETCH(&r
[0], 0, TGSI_CHAN_X
);
2335 switch (mach
->SamplerViews
[resource_unit
].Resource
) {
2336 case TGSI_TEXTURE_1D
:
2337 case TGSI_TEXTURE_1D_ARRAY
:
2338 /* only 1D array actually needs Y */
2339 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2341 fetch_assign_deriv_channel(mach
, inst
, 3, TGSI_CHAN_X
, derivs
[0]);
2343 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2344 &r
[0], &r
[1], &ZeroVec
, &ZeroVec
, &ZeroVec
, /* S, T, P, C, LOD */
2345 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2346 &r
[0], &r
[1], &r
[2], &r
[3]); /* R, G, B, A */
2349 case TGSI_TEXTURE_2D
:
2350 case TGSI_TEXTURE_RECT
:
2351 case TGSI_TEXTURE_2D_ARRAY
:
2352 /* only 2D array actually needs Z */
2353 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2354 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2356 fetch_assign_deriv_channel(mach
, inst
, 3, TGSI_CHAN_X
, derivs
[0]);
2357 fetch_assign_deriv_channel(mach
, inst
, 3, TGSI_CHAN_Y
, derivs
[1]);
2359 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2360 &r
[0], &r
[1], &r
[2], &ZeroVec
, &ZeroVec
, /* inputs */
2361 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2362 &r
[0], &r
[1], &r
[2], &r
[3]); /* outputs */
2365 case TGSI_TEXTURE_3D
:
2366 case TGSI_TEXTURE_CUBE
:
2367 case TGSI_TEXTURE_CUBE_ARRAY
:
2368 /* only cube array actually needs W */
2369 FETCH(&r
[1], 0, TGSI_CHAN_Y
);
2370 FETCH(&r
[2], 0, TGSI_CHAN_Z
);
2371 FETCH(&r
[3], 0, TGSI_CHAN_W
);
2373 fetch_assign_deriv_channel(mach
, inst
, 3, TGSI_CHAN_X
, derivs
[0]);
2374 fetch_assign_deriv_channel(mach
, inst
, 3, TGSI_CHAN_Y
, derivs
[1]);
2375 fetch_assign_deriv_channel(mach
, inst
, 3, TGSI_CHAN_Z
, derivs
[2]);
2377 fetch_texel(mach
->Sampler
, resource_unit
, sampler_unit
,
2378 &r
[0], &r
[1], &r
[2], &r
[3], &ZeroVec
,
2379 derivs
, offsets
, tgsi_sampler_derivs_explicit
,
2380 &r
[0], &r
[1], &r
[2], &r
[3]);
2387 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2388 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2389 store_dest(mach
, &r
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2396 * Evaluate a constant-valued coefficient at the position of the
2401 struct tgsi_exec_machine
*mach
,
2407 for( i
= 0; i
< TGSI_QUAD_SIZE
; i
++ ) {
2408 mach
->Inputs
[attrib
].xyzw
[chan
].f
[i
] = mach
->InterpCoefs
[attrib
].a0
[chan
];
2413 * Evaluate a linear-valued coefficient at the position of the
2418 struct tgsi_exec_machine
*mach
,
2422 const float x
= mach
->QuadPos
.xyzw
[0].f
[0];
2423 const float y
= mach
->QuadPos
.xyzw
[1].f
[0];
2424 const float dadx
= mach
->InterpCoefs
[attrib
].dadx
[chan
];
2425 const float dady
= mach
->InterpCoefs
[attrib
].dady
[chan
];
2426 const float a0
= mach
->InterpCoefs
[attrib
].a0
[chan
] + dadx
* x
+ dady
* y
;
2427 mach
->Inputs
[attrib
].xyzw
[chan
].f
[0] = a0
;
2428 mach
->Inputs
[attrib
].xyzw
[chan
].f
[1] = a0
+ dadx
;
2429 mach
->Inputs
[attrib
].xyzw
[chan
].f
[2] = a0
+ dady
;
2430 mach
->Inputs
[attrib
].xyzw
[chan
].f
[3] = a0
+ dadx
+ dady
;
2434 * Evaluate a perspective-valued coefficient at the position of the
2438 eval_perspective_coef(
2439 struct tgsi_exec_machine
*mach
,
2443 const float x
= mach
->QuadPos
.xyzw
[0].f
[0];
2444 const float y
= mach
->QuadPos
.xyzw
[1].f
[0];
2445 const float dadx
= mach
->InterpCoefs
[attrib
].dadx
[chan
];
2446 const float dady
= mach
->InterpCoefs
[attrib
].dady
[chan
];
2447 const float a0
= mach
->InterpCoefs
[attrib
].a0
[chan
] + dadx
* x
+ dady
* y
;
2448 const float *w
= mach
->QuadPos
.xyzw
[3].f
;
2449 /* divide by W here */
2450 mach
->Inputs
[attrib
].xyzw
[chan
].f
[0] = a0
/ w
[0];
2451 mach
->Inputs
[attrib
].xyzw
[chan
].f
[1] = (a0
+ dadx
) / w
[1];
2452 mach
->Inputs
[attrib
].xyzw
[chan
].f
[2] = (a0
+ dady
) / w
[2];
2453 mach
->Inputs
[attrib
].xyzw
[chan
].f
[3] = (a0
+ dadx
+ dady
) / w
[3];
2457 typedef void (* eval_coef_func
)(
2458 struct tgsi_exec_machine
*mach
,
2463 exec_declaration(struct tgsi_exec_machine
*mach
,
2464 const struct tgsi_full_declaration
*decl
)
2466 if (decl
->Declaration
.File
== TGSI_FILE_SAMPLER_VIEW
) {
2467 mach
->SamplerViews
[decl
->Range
.First
] = decl
->SamplerView
;
2471 if (mach
->Processor
== TGSI_PROCESSOR_FRAGMENT
) {
2472 if (decl
->Declaration
.File
== TGSI_FILE_INPUT
) {
2473 uint first
, last
, mask
;
2475 first
= decl
->Range
.First
;
2476 last
= decl
->Range
.Last
;
2477 mask
= decl
->Declaration
.UsageMask
;
2479 /* XXX we could remove this special-case code since
2480 * mach->InterpCoefs[first].a0 should already have the
2481 * front/back-face value. But we should first update the
2482 * ureg code to emit the right UsageMask value (WRITEMASK_X).
2483 * Then, we could remove the tgsi_exec_machine::Face field.
2485 /* XXX make FACE a system value */
2486 if (decl
->Semantic
.Name
== TGSI_SEMANTIC_FACE
) {
2489 assert(decl
->Semantic
.Index
== 0);
2490 assert(first
== last
);
2492 for (i
= 0; i
< TGSI_QUAD_SIZE
; i
++) {
2493 mach
->Inputs
[first
].xyzw
[0].f
[i
] = mach
->Face
;
2496 eval_coef_func eval
;
2499 switch (decl
->Interp
.Interpolate
) {
2500 case TGSI_INTERPOLATE_CONSTANT
:
2501 eval
= eval_constant_coef
;
2504 case TGSI_INTERPOLATE_LINEAR
:
2505 eval
= eval_linear_coef
;
2508 case TGSI_INTERPOLATE_PERSPECTIVE
:
2509 eval
= eval_perspective_coef
;
2512 case TGSI_INTERPOLATE_COLOR
:
2513 eval
= mach
->flatshade_color
? eval_constant_coef
: eval_perspective_coef
;
2521 for (j
= 0; j
< TGSI_NUM_CHANNELS
; j
++) {
2522 if (mask
& (1 << j
)) {
2523 for (i
= first
; i
<= last
; i
++) {
2530 if (DEBUG_EXECUTION
) {
2532 for (i
= first
; i
<= last
; ++i
) {
2533 debug_printf("IN[%2u] = ", i
);
2534 for (j
= 0; j
< TGSI_NUM_CHANNELS
; j
++) {
2538 debug_printf("(%6f %u, %6f %u, %6f %u, %6f %u)\n",
2539 mach
->Inputs
[i
].xyzw
[0].f
[j
], mach
->Inputs
[i
].xyzw
[0].u
[j
],
2540 mach
->Inputs
[i
].xyzw
[1].f
[j
], mach
->Inputs
[i
].xyzw
[1].u
[j
],
2541 mach
->Inputs
[i
].xyzw
[2].f
[j
], mach
->Inputs
[i
].xyzw
[2].u
[j
],
2542 mach
->Inputs
[i
].xyzw
[3].f
[j
], mach
->Inputs
[i
].xyzw
[3].u
[j
]);
2549 if (decl
->Declaration
.File
== TGSI_FILE_SYSTEM_VALUE
) {
2550 mach
->SysSemanticToIndex
[decl
->Declaration
.Semantic
] = decl
->Range
.First
;
2555 typedef void (* micro_op
)(union tgsi_exec_channel
*dst
);
2558 exec_vector(struct tgsi_exec_machine
*mach
,
2559 const struct tgsi_full_instruction
*inst
,
2561 enum tgsi_exec_datatype dst_datatype
)
2565 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2566 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2567 union tgsi_exec_channel dst
;
2570 store_dest(mach
, &dst
, &inst
->Dst
[0], inst
, chan
, dst_datatype
);
2575 typedef void (* micro_unary_op
)(union tgsi_exec_channel
*dst
,
2576 const union tgsi_exec_channel
*src
);
2579 exec_scalar_unary(struct tgsi_exec_machine
*mach
,
2580 const struct tgsi_full_instruction
*inst
,
2582 enum tgsi_exec_datatype dst_datatype
,
2583 enum tgsi_exec_datatype src_datatype
)
2586 union tgsi_exec_channel src
;
2587 union tgsi_exec_channel dst
;
2589 fetch_source(mach
, &src
, &inst
->Src
[0], TGSI_CHAN_X
, src_datatype
);
2591 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2592 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2593 store_dest(mach
, &dst
, &inst
->Dst
[0], inst
, chan
, dst_datatype
);
2599 exec_vector_unary(struct tgsi_exec_machine
*mach
,
2600 const struct tgsi_full_instruction
*inst
,
2602 enum tgsi_exec_datatype dst_datatype
,
2603 enum tgsi_exec_datatype src_datatype
)
2606 struct tgsi_exec_vector dst
;
2608 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2609 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2610 union tgsi_exec_channel src
;
2612 fetch_source(mach
, &src
, &inst
->Src
[0], chan
, src_datatype
);
2613 op(&dst
.xyzw
[chan
], &src
);
2616 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2617 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2618 store_dest(mach
, &dst
.xyzw
[chan
], &inst
->Dst
[0], inst
, chan
, dst_datatype
);
2623 typedef void (* micro_binary_op
)(union tgsi_exec_channel
*dst
,
2624 const union tgsi_exec_channel
*src0
,
2625 const union tgsi_exec_channel
*src1
);
2628 exec_scalar_binary(struct tgsi_exec_machine
*mach
,
2629 const struct tgsi_full_instruction
*inst
,
2631 enum tgsi_exec_datatype dst_datatype
,
2632 enum tgsi_exec_datatype src_datatype
)
2635 union tgsi_exec_channel src
[2];
2636 union tgsi_exec_channel dst
;
2638 fetch_source(mach
, &src
[0], &inst
->Src
[0], TGSI_CHAN_X
, src_datatype
);
2639 fetch_source(mach
, &src
[1], &inst
->Src
[1], TGSI_CHAN_Y
, src_datatype
);
2640 op(&dst
, &src
[0], &src
[1]);
2641 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2642 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2643 store_dest(mach
, &dst
, &inst
->Dst
[0], inst
, chan
, dst_datatype
);
2649 exec_vector_binary(struct tgsi_exec_machine
*mach
,
2650 const struct tgsi_full_instruction
*inst
,
2652 enum tgsi_exec_datatype dst_datatype
,
2653 enum tgsi_exec_datatype src_datatype
)
2656 struct tgsi_exec_vector dst
;
2658 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2659 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2660 union tgsi_exec_channel src
[2];
2662 fetch_source(mach
, &src
[0], &inst
->Src
[0], chan
, src_datatype
);
2663 fetch_source(mach
, &src
[1], &inst
->Src
[1], chan
, src_datatype
);
2664 op(&dst
.xyzw
[chan
], &src
[0], &src
[1]);
2667 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2668 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2669 store_dest(mach
, &dst
.xyzw
[chan
], &inst
->Dst
[0], inst
, chan
, dst_datatype
);
2674 typedef void (* micro_trinary_op
)(union tgsi_exec_channel
*dst
,
2675 const union tgsi_exec_channel
*src0
,
2676 const union tgsi_exec_channel
*src1
,
2677 const union tgsi_exec_channel
*src2
);
2680 exec_vector_trinary(struct tgsi_exec_machine
*mach
,
2681 const struct tgsi_full_instruction
*inst
,
2682 micro_trinary_op op
,
2683 enum tgsi_exec_datatype dst_datatype
,
2684 enum tgsi_exec_datatype src_datatype
)
2687 struct tgsi_exec_vector dst
;
2689 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2690 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2691 union tgsi_exec_channel src
[3];
2693 fetch_source(mach
, &src
[0], &inst
->Src
[0], chan
, src_datatype
);
2694 fetch_source(mach
, &src
[1], &inst
->Src
[1], chan
, src_datatype
);
2695 fetch_source(mach
, &src
[2], &inst
->Src
[2], chan
, src_datatype
);
2696 op(&dst
.xyzw
[chan
], &src
[0], &src
[1], &src
[2]);
2699 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2700 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2701 store_dest(mach
, &dst
.xyzw
[chan
], &inst
->Dst
[0], inst
, chan
, dst_datatype
);
2707 exec_dp3(struct tgsi_exec_machine
*mach
,
2708 const struct tgsi_full_instruction
*inst
)
2711 union tgsi_exec_channel arg
[3];
2713 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2714 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2715 micro_mul(&arg
[2], &arg
[0], &arg
[1]);
2717 for (chan
= TGSI_CHAN_Y
; chan
<= TGSI_CHAN_Z
; chan
++) {
2718 fetch_source(mach
, &arg
[0], &inst
->Src
[0], chan
, TGSI_EXEC_DATA_FLOAT
);
2719 fetch_source(mach
, &arg
[1], &inst
->Src
[1], chan
, TGSI_EXEC_DATA_FLOAT
);
2720 micro_mad(&arg
[2], &arg
[0], &arg
[1], &arg
[2]);
2723 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2724 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2725 store_dest(mach
, &arg
[2], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2731 exec_dp4(struct tgsi_exec_machine
*mach
,
2732 const struct tgsi_full_instruction
*inst
)
2735 union tgsi_exec_channel arg
[3];
2737 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2738 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2739 micro_mul(&arg
[2], &arg
[0], &arg
[1]);
2741 for (chan
= TGSI_CHAN_Y
; chan
<= TGSI_CHAN_W
; chan
++) {
2742 fetch_source(mach
, &arg
[0], &inst
->Src
[0], chan
, TGSI_EXEC_DATA_FLOAT
);
2743 fetch_source(mach
, &arg
[1], &inst
->Src
[1], chan
, TGSI_EXEC_DATA_FLOAT
);
2744 micro_mad(&arg
[2], &arg
[0], &arg
[1], &arg
[2]);
2747 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2748 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2749 store_dest(mach
, &arg
[2], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2755 exec_dp2a(struct tgsi_exec_machine
*mach
,
2756 const struct tgsi_full_instruction
*inst
)
2759 union tgsi_exec_channel arg
[3];
2761 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2762 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2763 micro_mul(&arg
[2], &arg
[0], &arg
[1]);
2765 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2766 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2767 micro_mad(&arg
[0], &arg
[0], &arg
[1], &arg
[2]);
2769 fetch_source(mach
, &arg
[1], &inst
->Src
[2], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2770 micro_add(&arg
[0], &arg
[0], &arg
[1]);
2772 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2773 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2774 store_dest(mach
, &arg
[0], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2780 exec_dph(struct tgsi_exec_machine
*mach
,
2781 const struct tgsi_full_instruction
*inst
)
2784 union tgsi_exec_channel arg
[3];
2786 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2787 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2788 micro_mul(&arg
[2], &arg
[0], &arg
[1]);
2790 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2791 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2792 micro_mad(&arg
[2], &arg
[0], &arg
[1], &arg
[2]);
2794 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2795 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2796 micro_mad(&arg
[0], &arg
[0], &arg
[1], &arg
[2]);
2798 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
2799 micro_add(&arg
[0], &arg
[0], &arg
[1]);
2801 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2802 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2803 store_dest(mach
, &arg
[0], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2809 exec_dp2(struct tgsi_exec_machine
*mach
,
2810 const struct tgsi_full_instruction
*inst
)
2813 union tgsi_exec_channel arg
[3];
2815 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2816 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2817 micro_mul(&arg
[2], &arg
[0], &arg
[1]);
2819 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2820 fetch_source(mach
, &arg
[1], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2821 micro_mad(&arg
[2], &arg
[0], &arg
[1], &arg
[2]);
2823 for (chan
= 0; chan
< TGSI_NUM_CHANNELS
; chan
++) {
2824 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2825 store_dest(mach
, &arg
[2], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2831 exec_nrm4(struct tgsi_exec_machine
*mach
,
2832 const struct tgsi_full_instruction
*inst
)
2835 union tgsi_exec_channel arg
[4];
2836 union tgsi_exec_channel scale
;
2838 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2839 micro_mul(&scale
, &arg
[0], &arg
[0]);
2841 for (chan
= TGSI_CHAN_Y
; chan
<= TGSI_CHAN_W
; chan
++) {
2842 union tgsi_exec_channel product
;
2844 fetch_source(mach
, &arg
[chan
], &inst
->Src
[0], chan
, TGSI_EXEC_DATA_FLOAT
);
2845 micro_mul(&product
, &arg
[chan
], &arg
[chan
]);
2846 micro_add(&scale
, &scale
, &product
);
2849 micro_rsq(&scale
, &scale
);
2851 for (chan
= TGSI_CHAN_X
; chan
<= TGSI_CHAN_W
; chan
++) {
2852 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2853 micro_mul(&arg
[chan
], &arg
[chan
], &scale
);
2854 store_dest(mach
, &arg
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2860 exec_nrm3(struct tgsi_exec_machine
*mach
,
2861 const struct tgsi_full_instruction
*inst
)
2863 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_XYZ
) {
2865 union tgsi_exec_channel arg
[3];
2866 union tgsi_exec_channel scale
;
2868 fetch_source(mach
, &arg
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2869 micro_mul(&scale
, &arg
[0], &arg
[0]);
2871 for (chan
= TGSI_CHAN_Y
; chan
<= TGSI_CHAN_Z
; chan
++) {
2872 union tgsi_exec_channel product
;
2874 fetch_source(mach
, &arg
[chan
], &inst
->Src
[0], chan
, TGSI_EXEC_DATA_FLOAT
);
2875 micro_mul(&product
, &arg
[chan
], &arg
[chan
]);
2876 micro_add(&scale
, &scale
, &product
);
2879 micro_rsq(&scale
, &scale
);
2881 for (chan
= TGSI_CHAN_X
; chan
<= TGSI_CHAN_Z
; chan
++) {
2882 if (inst
->Dst
[0].Register
.WriteMask
& (1 << chan
)) {
2883 micro_mul(&arg
[chan
], &arg
[chan
], &scale
);
2884 store_dest(mach
, &arg
[chan
], &inst
->Dst
[0], inst
, chan
, TGSI_EXEC_DATA_FLOAT
);
2889 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
2890 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
2895 exec_scs(struct tgsi_exec_machine
*mach
,
2896 const struct tgsi_full_instruction
*inst
)
2898 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_XY
) {
2899 union tgsi_exec_channel arg
;
2900 union tgsi_exec_channel result
;
2902 fetch_source(mach
, &arg
, &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2904 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
2905 micro_cos(&result
, &arg
);
2906 store_dest(mach
, &result
, &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2908 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
2909 micro_sin(&result
, &arg
);
2910 store_dest(mach
, &result
, &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2913 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
2914 store_dest(mach
, &ZeroVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2916 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
2917 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
2922 exec_x2d(struct tgsi_exec_machine
*mach
,
2923 const struct tgsi_full_instruction
*inst
)
2925 union tgsi_exec_channel r
[4];
2926 union tgsi_exec_channel d
[2];
2928 fetch_source(mach
, &r
[0], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2929 fetch_source(mach
, &r
[1], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2930 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_XZ
) {
2931 fetch_source(mach
, &r
[2], &inst
->Src
[2], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2932 micro_mul(&r
[2], &r
[2], &r
[0]);
2933 fetch_source(mach
, &r
[3], &inst
->Src
[2], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2934 micro_mul(&r
[3], &r
[3], &r
[1]);
2935 micro_add(&r
[2], &r
[2], &r
[3]);
2936 fetch_source(mach
, &r
[3], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2937 micro_add(&d
[0], &r
[2], &r
[3]);
2939 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_YW
) {
2940 fetch_source(mach
, &r
[2], &inst
->Src
[2], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2941 micro_mul(&r
[2], &r
[2], &r
[0]);
2942 fetch_source(mach
, &r
[3], &inst
->Src
[2], TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
2943 micro_mul(&r
[3], &r
[3], &r
[1]);
2944 micro_add(&r
[2], &r
[2], &r
[3]);
2945 fetch_source(mach
, &r
[3], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2946 micro_add(&d
[1], &r
[2], &r
[3]);
2948 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
2949 store_dest(mach
, &d
[0], &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2951 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
2952 store_dest(mach
, &d
[1], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2954 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
2955 store_dest(mach
, &d
[0], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2957 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
2958 store_dest(mach
, &d
[1], &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
2963 exec_rfl(struct tgsi_exec_machine
*mach
,
2964 const struct tgsi_full_instruction
*inst
)
2966 union tgsi_exec_channel r
[9];
2968 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_XYZ
) {
2969 /* r0 = dp3(src0, src0) */
2970 fetch_source(mach
, &r
[2], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2971 micro_mul(&r
[0], &r
[2], &r
[2]);
2972 fetch_source(mach
, &r
[4], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2973 micro_mul(&r
[8], &r
[4], &r
[4]);
2974 micro_add(&r
[0], &r
[0], &r
[8]);
2975 fetch_source(mach
, &r
[6], &inst
->Src
[0], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2976 micro_mul(&r
[8], &r
[6], &r
[6]);
2977 micro_add(&r
[0], &r
[0], &r
[8]);
2979 /* r1 = dp3(src0, src1) */
2980 fetch_source(mach
, &r
[3], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2981 micro_mul(&r
[1], &r
[2], &r
[3]);
2982 fetch_source(mach
, &r
[5], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
2983 micro_mul(&r
[8], &r
[4], &r
[5]);
2984 micro_add(&r
[1], &r
[1], &r
[8]);
2985 fetch_source(mach
, &r
[7], &inst
->Src
[1], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
2986 micro_mul(&r
[8], &r
[6], &r
[7]);
2987 micro_add(&r
[1], &r
[1], &r
[8]);
2989 /* r1 = 2 * r1 / r0 */
2990 micro_add(&r
[1], &r
[1], &r
[1]);
2991 micro_div(&r
[1], &r
[1], &r
[0]);
2993 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
2994 micro_mul(&r
[2], &r
[2], &r
[1]);
2995 micro_sub(&r
[2], &r
[2], &r
[3]);
2996 store_dest(mach
, &r
[2], &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
2998 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
2999 micro_mul(&r
[4], &r
[4], &r
[1]);
3000 micro_sub(&r
[4], &r
[4], &r
[5]);
3001 store_dest(mach
, &r
[4], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3003 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3004 micro_mul(&r
[6], &r
[6], &r
[1]);
3005 micro_sub(&r
[6], &r
[6], &r
[7]);
3006 store_dest(mach
, &r
[6], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3009 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3010 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3015 exec_xpd(struct tgsi_exec_machine
*mach
,
3016 const struct tgsi_full_instruction
*inst
)
3018 union tgsi_exec_channel r
[6];
3019 union tgsi_exec_channel d
[3];
3021 fetch_source(mach
, &r
[0], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3022 fetch_source(mach
, &r
[1], &inst
->Src
[1], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3024 micro_mul(&r
[2], &r
[0], &r
[1]);
3026 fetch_source(mach
, &r
[3], &inst
->Src
[0], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3027 fetch_source(mach
, &r
[4], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3029 micro_mul(&r
[5], &r
[3], &r
[4] );
3030 micro_sub(&d
[TGSI_CHAN_X
], &r
[2], &r
[5]);
3032 fetch_source(mach
, &r
[2], &inst
->Src
[1], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3034 micro_mul(&r
[3], &r
[3], &r
[2]);
3036 fetch_source(mach
, &r
[5], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3038 micro_mul(&r
[1], &r
[1], &r
[5]);
3039 micro_sub(&d
[TGSI_CHAN_Y
], &r
[3], &r
[1]);
3041 micro_mul(&r
[5], &r
[5], &r
[4]);
3042 micro_mul(&r
[0], &r
[0], &r
[2]);
3043 micro_sub(&d
[TGSI_CHAN_Z
], &r
[5], &r
[0]);
3045 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
3046 store_dest(mach
, &d
[TGSI_CHAN_X
], &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3048 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
3049 store_dest(mach
, &d
[TGSI_CHAN_Y
], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3051 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3052 store_dest(mach
, &d
[TGSI_CHAN_Z
], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3054 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3055 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3060 exec_dst(struct tgsi_exec_machine
*mach
,
3061 const struct tgsi_full_instruction
*inst
)
3063 union tgsi_exec_channel r
[2];
3064 union tgsi_exec_channel d
[4];
3066 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
3067 fetch_source(mach
, &r
[0], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3068 fetch_source(mach
, &r
[1], &inst
->Src
[1], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3069 micro_mul(&d
[TGSI_CHAN_Y
], &r
[0], &r
[1]);
3071 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3072 fetch_source(mach
, &d
[TGSI_CHAN_Z
], &inst
->Src
[0], TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3074 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3075 fetch_source(mach
, &d
[TGSI_CHAN_W
], &inst
->Src
[1], TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3078 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
3079 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3081 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
3082 store_dest(mach
, &d
[TGSI_CHAN_Y
], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3084 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3085 store_dest(mach
, &d
[TGSI_CHAN_Z
], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3087 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3088 store_dest(mach
, &d
[TGSI_CHAN_W
], &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3093 exec_log(struct tgsi_exec_machine
*mach
,
3094 const struct tgsi_full_instruction
*inst
)
3096 union tgsi_exec_channel r
[3];
3098 fetch_source(mach
, &r
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3099 micro_abs(&r
[2], &r
[0]); /* r2 = abs(r0) */
3100 micro_lg2(&r
[1], &r
[2]); /* r1 = lg2(r2) */
3101 micro_flr(&r
[0], &r
[1]); /* r0 = floor(r1) */
3102 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
3103 store_dest(mach
, &r
[0], &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3105 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
3106 micro_exp2(&r
[0], &r
[0]); /* r0 = 2 ^ r0 */
3107 micro_div(&r
[0], &r
[2], &r
[0]); /* r0 = r2 / r0 */
3108 store_dest(mach
, &r
[0], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3110 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3111 store_dest(mach
, &r
[1], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3113 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3114 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3119 exec_exp(struct tgsi_exec_machine
*mach
,
3120 const struct tgsi_full_instruction
*inst
)
3122 union tgsi_exec_channel r
[3];
3124 fetch_source(mach
, &r
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3125 micro_flr(&r
[1], &r
[0]); /* r1 = floor(r0) */
3126 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
3127 micro_exp2(&r
[2], &r
[1]); /* r2 = 2 ^ r1 */
3128 store_dest(mach
, &r
[2], &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3130 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
3131 micro_sub(&r
[2], &r
[0], &r
[1]); /* r2 = r0 - r1 */
3132 store_dest(mach
, &r
[2], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3134 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3135 micro_exp2(&r
[2], &r
[0]); /* r2 = 2 ^ r0 */
3136 store_dest(mach
, &r
[2], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3138 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3139 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3144 exec_lit(struct tgsi_exec_machine
*mach
,
3145 const struct tgsi_full_instruction
*inst
)
3147 union tgsi_exec_channel r
[3];
3148 union tgsi_exec_channel d
[3];
3150 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_YZ
) {
3151 fetch_source(mach
, &r
[0], &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3152 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Z
) {
3153 fetch_source(mach
, &r
[1], &inst
->Src
[0], TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3154 micro_max(&r
[1], &r
[1], &ZeroVec
);
3156 fetch_source(mach
, &r
[2], &inst
->Src
[0], TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3157 micro_min(&r
[2], &r
[2], &P128Vec
);
3158 micro_max(&r
[2], &r
[2], &M128Vec
);
3159 micro_pow(&r
[1], &r
[1], &r
[2]);
3160 micro_lt(&d
[TGSI_CHAN_Z
], &ZeroVec
, &r
[0], &r
[1], &ZeroVec
);
3161 store_dest(mach
, &d
[TGSI_CHAN_Z
], &inst
->Dst
[0], inst
, TGSI_CHAN_Z
, TGSI_EXEC_DATA_FLOAT
);
3163 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_Y
) {
3164 micro_max(&d
[TGSI_CHAN_Y
], &r
[0], &ZeroVec
);
3165 store_dest(mach
, &d
[TGSI_CHAN_Y
], &inst
->Dst
[0], inst
, TGSI_CHAN_Y
, TGSI_EXEC_DATA_FLOAT
);
3168 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_X
) {
3169 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_X
, TGSI_EXEC_DATA_FLOAT
);
3172 if (inst
->Dst
[0].Register
.WriteMask
& TGSI_WRITEMASK_W
) {
3173 store_dest(mach
, &OneVec
, &inst
->Dst
[0], inst
, TGSI_CHAN_W
, TGSI_EXEC_DATA_FLOAT
);
3178 exec_break(struct tgsi_exec_machine
*mach
)
3180 if (mach
->BreakType
== TGSI_EXEC_BREAK_INSIDE_LOOP
) {
3181 /* turn off loop channels for each enabled exec channel */
3182 mach
->LoopMask
&= ~mach
->ExecMask
;
3183 /* Todo: if mach->LoopMask == 0, jump to end of loop */
3184 UPDATE_EXEC_MASK(mach
);
3186 assert(mach
->BreakType
== TGSI_EXEC_BREAK_INSIDE_SWITCH
);
3188 mach
->Switch
.mask
= 0x0;
3190 UPDATE_EXEC_MASK(mach
);
3195 exec_switch(struct tgsi_exec_machine
*mach
,
3196 const struct tgsi_full_instruction
*inst
)
3198 assert(mach
->SwitchStackTop
< TGSI_EXEC_MAX_SWITCH_NESTING
);
3199 assert(mach
->BreakStackTop
< TGSI_EXEC_MAX_BREAK_STACK
);
3201 mach
->SwitchStack
[mach
->SwitchStackTop
++] = mach
->Switch
;
3202 fetch_source(mach
, &mach
->Switch
.selector
, &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_UINT
);
3203 mach
->Switch
.mask
= 0x0;
3204 mach
->Switch
.defaultMask
= 0x0;
3206 mach
->BreakStack
[mach
->BreakStackTop
++] = mach
->BreakType
;
3207 mach
->BreakType
= TGSI_EXEC_BREAK_INSIDE_SWITCH
;
3209 UPDATE_EXEC_MASK(mach
);
3213 exec_case(struct tgsi_exec_machine
*mach
,
3214 const struct tgsi_full_instruction
*inst
)
3216 uint prevMask
= mach
->SwitchStack
[mach
->SwitchStackTop
- 1].mask
;
3217 union tgsi_exec_channel src
;
3220 fetch_source(mach
, &src
, &inst
->Src
[0], TGSI_CHAN_X
, TGSI_EXEC_DATA_UINT
);
3222 if (mach
->Switch
.selector
.u
[0] == src
.u
[0]) {
3225 if (mach
->Switch
.selector
.u
[1] == src
.u
[1]) {
3228 if (mach
->Switch
.selector
.u
[2] == src
.u
[2]) {
3231 if (mach
->Switch
.selector
.u
[3] == src
.u
[3]) {
3235 mach
->Switch
.defaultMask
|= mask
;
3237 mach
->Switch
.mask
|= mask
& prevMask
;
3239 UPDATE_EXEC_MASK(mach
);
3243 exec_default(struct tgsi_exec_machine
*mach
)
3245 uint prevMask
= mach
->SwitchStack
[mach
->SwitchStackTop
- 1].mask
;
3247 mach
->Switch
.mask
|= ~mach
->Switch
.defaultMask
& prevMask
;
3249 UPDATE_EXEC_MASK(mach
);
3253 exec_endswitch(struct tgsi_exec_machine
*mach
)
3255 mach
->Switch
= mach
->SwitchStack
[--mach
->SwitchStackTop
];
3256 mach
->BreakType
= mach
->BreakStack
[--mach
->BreakStackTop
];
3258 UPDATE_EXEC_MASK(mach
);
3262 micro_i2f(union tgsi_exec_channel
*dst
,
3263 const union tgsi_exec_channel
*src
)
3265 dst
->f
[0] = (float)src
->i
[0];
3266 dst
->f
[1] = (float)src
->i
[1];
3267 dst
->f
[2] = (float)src
->i
[2];
3268 dst
->f
[3] = (float)src
->i
[3];
3272 micro_not(union tgsi_exec_channel
*dst
,
3273 const union tgsi_exec_channel
*src
)
3275 dst
->u
[0] = ~src
->u
[0];
3276 dst
->u
[1] = ~src
->u
[1];
3277 dst
->u
[2] = ~src
->u
[2];
3278 dst
->u
[3] = ~src
->u
[3];
3282 micro_shl(union tgsi_exec_channel
*dst
,
3283 const union tgsi_exec_channel
*src0
,
3284 const union tgsi_exec_channel
*src1
)
3286 dst
->u
[0] = src0
->u
[0] << src1
->u
[0];
3287 dst
->u
[1] = src0
->u
[1] << src1
->u
[1];
3288 dst
->u
[2] = src0
->u
[2] << src1
->u
[2];
3289 dst
->u
[3] = src0
->u
[3] << src1
->u
[3];
3293 micro_and(union tgsi_exec_channel
*dst
,
3294 const union tgsi_exec_channel
*src0
,
3295 const union tgsi_exec_channel
*src1
)
3297 dst
->u
[0] = src0
->u
[0] & src1
->u
[0];
3298 dst
->u
[1] = src0
->u
[1] & src1
->u
[1];
3299 dst
->u
[2] = src0
->u
[2] & src1
->u
[2];
3300 dst
->u
[3] = src0
->u
[3] & src1
->u
[3];
3304 micro_or(union tgsi_exec_channel
*dst
,
3305 const union tgsi_exec_channel
*src0
,
3306 const union tgsi_exec_channel
*src1
)
3308 dst
->u
[0] = src0
->u
[0] | src1
->u
[0];
3309 dst
->u
[1] = src0
->u
[1] | src1
->u
[1];
3310 dst
->u
[2] = src0
->u
[2] | src1
->u
[2];
3311 dst
->u
[3] = src0
->u
[3] | src1
->u
[3];
3315 micro_xor(union tgsi_exec_channel
*dst
,
3316 const union tgsi_exec_channel
*src0
,
3317 const union tgsi_exec_channel
*src1
)
3319 dst
->u
[0] = src0
->u
[0] ^ src1
->u
[0];
3320 dst
->u
[1] = src0
->u
[1] ^ src1
->u
[1];
3321 dst
->u
[2] = src0
->u
[2] ^ src1
->u
[2];
3322 dst
->u
[3] = src0
->u
[3] ^ src1
->u
[3];
3326 micro_mod(union tgsi_exec_channel
*dst
,
3327 const union tgsi_exec_channel
*src0
,
3328 const union tgsi_exec_channel
*src1
)
3330 dst
->i
[0] = src0
->i
[0] % src1
->i
[0];
3331 dst
->i
[1] = src0
->i
[1] % src1
->i
[1];
3332 dst
->i
[2] = src0
->i
[2] % src1
->i
[2];
3333 dst
->i
[3] = src0
->i
[3] % src1
->i
[3];
3337 micro_f2i(union tgsi_exec_channel
*dst
,
3338 const union tgsi_exec_channel
*src
)
3340 dst
->i
[0] = (int)src
->f
[0];
3341 dst
->i
[1] = (int)src
->f
[1];
3342 dst
->i
[2] = (int)src
->f
[2];
3343 dst
->i
[3] = (int)src
->f
[3];
3347 micro_idiv(union tgsi_exec_channel
*dst
,
3348 const union tgsi_exec_channel
*src0
,
3349 const union tgsi_exec_channel
*src1
)
3351 dst
->i
[0] = src0
->i
[0] / src1
->i
[0];
3352 dst
->i
[1] = src0
->i
[1] / src1
->i
[1];
3353 dst
->i
[2] = src0
->i
[2] / src1
->i
[2];
3354 dst
->i
[3] = src0
->i
[3] / src1
->i
[3];
3358 micro_imax(union tgsi_exec_channel
*dst
,
3359 const union tgsi_exec_channel
*src0
,
3360 const union tgsi_exec_channel
*src1
)
3362 dst
->i
[0] = src0
->i
[0] > src1
->i
[0] ? src0
->i
[0] : src1
->i
[0];
3363 dst
->i
[1] = src0
->i
[1] > src1
->i
[1] ? src0
->i
[1] : src1
->i
[1];
3364 dst
->i
[2] = src0
->i
[2] > src1
->i
[2] ? src0
->i
[2] : src1
->i
[2];
3365 dst
->i
[3] = src0
->i
[3] > src1
->i
[3] ? src0
->i
[3] : src1
->i
[3];
3369 micro_imin(union tgsi_exec_channel
*dst
,
3370 const union tgsi_exec_channel
*src0
,
3371 const union tgsi_exec_channel
*src1
)
3373 dst
->i
[0] = src0
->i
[0] < src1
->i
[0] ? src0
->i
[0] : src1
->i
[0];
3374 dst
->i
[1] = src0
->i
[1] < src1
->i
[1] ? src0
->i
[1] : src1
->i
[1];
3375 dst
->i
[2] = src0
->i
[2] < src1
->i
[2] ? src0
->i
[2] : src1
->i
[2];
3376 dst
->i
[3] = src0
->i
[3] < src1
->i
[3] ? src0
->i
[3] : src1
->i
[3];
3380 micro_isge(union tgsi_exec_channel
*dst
,
3381 const union tgsi_exec_channel
*src0
,
3382 const union tgsi_exec_channel
*src1
)
3384 dst
->i
[0] = src0
->i
[0] >= src1
->i
[0] ? -1 : 0;
3385 dst
->i
[1] = src0
->i
[1] >= src1
->i
[1] ? -1 : 0;
3386 dst
->i
[2] = src0
->i
[2] >= src1
->i
[2] ? -1 : 0;
3387 dst
->i
[3] = src0
->i
[3] >= src1
->i
[3] ? -1 : 0;
3391 micro_ishr(union tgsi_exec_channel
*dst
,
3392 const union tgsi_exec_channel
*src0
,
3393 const union tgsi_exec_channel
*src1
)
3395 dst
->i
[0] = src0
->i
[0] >> src1
->i
[0];
3396 dst
->i
[1] = src0
->i
[1] >> src1
->i
[1];
3397 dst
->i
[2] = src0
->i
[2] >> src1
->i
[2];
3398 dst
->i
[3] = src0
->i
[3] >> src1
->i
[3];
3402 micro_islt(union tgsi_exec_channel
*dst
,
3403 const union tgsi_exec_channel
*src0
,
3404 const union tgsi_exec_channel
*src1
)
3406 dst
->i
[0] = src0
->i
[0] < src1
->i
[0] ? -1 : 0;
3407 dst
->i
[1] = src0
->i
[1] < src1
->i
[1] ? -1 : 0;
3408 dst
->i
[2] = src0
->i
[2] < src1
->i
[2] ? -1 : 0;
3409 dst
->i
[3] = src0
->i
[3] < src1
->i
[3] ? -1 : 0;
3413 micro_f2u(union tgsi_exec_channel
*dst
,
3414 const union tgsi_exec_channel
*src
)
3416 dst
->u
[0] = (uint
)src
->f
[0];
3417 dst
->u
[1] = (uint
)src
->f
[1];
3418 dst
->u
[2] = (uint
)src
->f
[2];
3419 dst
->u
[3] = (uint
)src
->f
[3];
3423 micro_u2f(union tgsi_exec_channel
*dst
,
3424 const union tgsi_exec_channel
*src
)
3426 dst
->f
[0] = (float)src
->u
[0];
3427 dst
->f
[1] = (float)src
->u
[1];
3428 dst
->f
[2] = (float)src
->u
[2];
3429 dst
->f
[3] = (float)src
->u
[3];
3433 micro_uadd(union tgsi_exec_channel
*dst
,
3434 const union tgsi_exec_channel
*src0
,
3435 const union tgsi_exec_channel
*src1
)
3437 dst
->u
[0] = src0
->u
[0] + src1
->u
[0];
3438 dst
->u
[1] = src0
->u
[1] + src1
->u
[1];
3439 dst
->u
[2] = src0
->u
[2] + src1
->u
[2];
3440 dst
->u
[3] = src0
->u
[3] + src1
->u
[3];
3444 micro_udiv(union tgsi_exec_channel
*dst
,
3445 const union tgsi_exec_channel
*src0
,
3446 const union tgsi_exec_channel
*src1
)
3448 dst
->u
[0] = src1
->u
[0] ? src0
->u
[0] / src1
->u
[0] : ~0u;
3449 dst
->u
[1] = src1
->u
[1] ? src0
->u
[1] / src1
->u
[1] : ~0u;
3450 dst
->u
[2] = src1
->u
[2] ? src0
->u
[2] / src1
->u
[2] : ~0u;
3451 dst
->u
[3] = src1
->u
[3] ? src0
->u
[3] / src1
->u
[3] : ~0u;
3455 micro_umad(union tgsi_exec_channel
*dst
,
3456 const union tgsi_exec_channel
*src0
,
3457 const union tgsi_exec_channel
*src1
,
3458 const union tgsi_exec_channel
*src2
)
3460 dst
->u
[0] = src0
->u
[0] * src1
->u
[0] + src2
->u
[0];
3461 dst
->u
[1] = src0
->u
[1] * src1
->u
[1] + src2
->u
[1];
3462 dst
->u
[2] = src0
->u
[2] * src1
->u
[2] + src2
->u
[2];
3463 dst
->u
[3] = src0
->u
[3] * src1
->u
[3] + src2
->u
[3];
3467 micro_umax(union tgsi_exec_channel
*dst
,
3468 const union tgsi_exec_channel
*src0
,
3469 const union tgsi_exec_channel
*src1
)
3471 dst
->u
[0] = src0
->u
[0] > src1
->u
[0] ? src0
->u
[0] : src1
->u
[0];
3472 dst
->u
[1] = src0
->u
[1] > src1
->u
[1] ? src0
->u
[1] : src1
->u
[1];
3473 dst
->u
[2] = src0
->u
[2] > src1
->u
[2] ? src0
->u
[2] : src1
->u
[2];
3474 dst
->u
[3] = src0
->u
[3] > src1
->u
[3] ? src0
->u
[3] : src1
->u
[3];
3478 micro_umin(union tgsi_exec_channel
*dst
,
3479 const union tgsi_exec_channel
*src0
,
3480 const union tgsi_exec_channel
*src1
)
3482 dst
->u
[0] = src0
->u
[0] < src1
->u
[0] ? src0
->u
[0] : src1
->u
[0];
3483 dst
->u
[1] = src0
->u
[1] < src1
->u
[1] ? src0
->u
[1] : src1
->u
[1];
3484 dst
->u
[2] = src0
->u
[2] < src1
->u
[2] ? src0
->u
[2] : src1
->u
[2];
3485 dst
->u
[3] = src0
->u
[3] < src1
->u
[3] ? src0
->u
[3] : src1
->u
[3];
3489 micro_umod(union tgsi_exec_channel
*dst
,
3490 const union tgsi_exec_channel
*src0
,
3491 const union tgsi_exec_channel
*src1
)
3493 dst
->u
[0] = src1
->u
[0] ? src0
->u
[0] % src1
->u
[0] : ~0u;
3494 dst
->u
[1] = src1
->u
[1] ? src0
->u
[1] % src1
->u
[1] : ~0u;
3495 dst
->u
[2] = src1
->u
[2] ? src0
->u
[2] % src1
->u
[2] : ~0u;
3496 dst
->u
[3] = src1
->u
[3] ? src0
->u
[3] % src1
->u
[3] : ~0u;
3500 micro_umul(union tgsi_exec_channel
*dst
,
3501 const union tgsi_exec_channel
*src0
,
3502 const union tgsi_exec_channel
*src1
)
3504 dst
->u
[0] = src0
->u
[0] * src1
->u
[0];
3505 dst
->u
[1] = src0
->u
[1] * src1
->u
[1];
3506 dst
->u
[2] = src0
->u
[2] * src1
->u
[2];
3507 dst
->u
[3] = src0
->u
[3] * src1
->u
[3];
3511 micro_useq(union tgsi_exec_channel
*dst
,
3512 const union tgsi_exec_channel
*src0
,
3513 const union tgsi_exec_channel
*src1
)
3515 dst
->u
[0] = src0
->u
[0] == src1
->u
[0] ? ~0 : 0;
3516 dst
->u
[1] = src0
->u
[1] == src1
->u
[1] ? ~0 : 0;
3517 dst
->u
[2] = src0
->u
[2] == src1
->u
[2] ? ~0 : 0;
3518 dst
->u
[3] = src0
->u
[3] == src1
->u
[3] ? ~0 : 0;
3522 micro_usge(union tgsi_exec_channel
*dst
,
3523 const union tgsi_exec_channel
*src0
,
3524 const union tgsi_exec_channel
*src1
)
3526 dst
->u
[0] = src0
->u
[0] >= src1
->u
[0] ? ~0 : 0;
3527 dst
->u
[1] = src0
->u
[1] >= src1
->u
[1] ? ~0 : 0;
3528 dst
->u
[2] = src0
->u
[2] >= src1
->u
[2] ? ~0 : 0;
3529 dst
->u
[3] = src0
->u
[3] >= src1
->u
[3] ? ~0 : 0;
3533 micro_ushr(union tgsi_exec_channel
*dst
,
3534 const union tgsi_exec_channel
*src0
,
3535 const union tgsi_exec_channel
*src1
)
3537 dst
->u
[0] = src0
->u
[0] >> src1
->u
[0];
3538 dst
->u
[1] = src0
->u
[1] >> src1
->u
[1];
3539 dst
->u
[2] = src0
->u
[2] >> src1
->u
[2];
3540 dst
->u
[3] = src0
->u
[3] >> src1
->u
[3];
3544 micro_uslt(union tgsi_exec_channel
*dst
,
3545 const union tgsi_exec_channel
*src0
,
3546 const union tgsi_exec_channel
*src1
)
3548 dst
->u
[0] = src0
->u
[0] < src1
->u
[0] ? ~0 : 0;
3549 dst
->u
[1] = src0
->u
[1] < src1
->u
[1] ? ~0 : 0;
3550 dst
->u
[2] = src0
->u
[2] < src1
->u
[2] ? ~0 : 0;
3551 dst
->u
[3] = src0
->u
[3] < src1
->u
[3] ? ~0 : 0;
3555 micro_usne(union tgsi_exec_channel
*dst
,
3556 const union tgsi_exec_channel
*src0
,
3557 const union tgsi_exec_channel
*src1
)
3559 dst
->u
[0] = src0
->u
[0] != src1
->u
[0] ? ~0 : 0;
3560 dst
->u
[1] = src0
->u
[1] != src1
->u
[1] ? ~0 : 0;
3561 dst
->u
[2] = src0
->u
[2] != src1
->u
[2] ? ~0 : 0;
3562 dst
->u
[3] = src0
->u
[3] != src1
->u
[3] ? ~0 : 0;
3566 micro_uarl(union tgsi_exec_channel
*dst
,
3567 const union tgsi_exec_channel
*src
)
3569 dst
->i
[0] = src
->u
[0];
3570 dst
->i
[1] = src
->u
[1];
3571 dst
->i
[2] = src
->u
[2];
3572 dst
->i
[3] = src
->u
[3];
3576 micro_ucmp(union tgsi_exec_channel
*dst
,
3577 const union tgsi_exec_channel
*src0
,
3578 const union tgsi_exec_channel
*src1
,
3579 const union tgsi_exec_channel
*src2
)
3581 dst
->u
[0] = src0
->u
[0] ? src1
->u
[0] : src2
->u
[0];
3582 dst
->u
[1] = src0
->u
[1] ? src1
->u
[1] : src2
->u
[1];
3583 dst
->u
[2] = src0
->u
[2] ? src1
->u
[2] : src2
->u
[2];
3584 dst
->u
[3] = src0
->u
[3] ? src1
->u
[3] : src2
->u
[3];
3589 struct tgsi_exec_machine
*mach
,
3590 const struct tgsi_full_instruction
*inst
,
3593 union tgsi_exec_channel r
[10];
3597 switch (inst
->Instruction
.Opcode
) {
3598 case TGSI_OPCODE_ARL
:
3599 exec_vector_unary(mach
, inst
, micro_arl
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_FLOAT
);
3602 case TGSI_OPCODE_MOV
:
3603 exec_vector_unary(mach
, inst
, micro_mov
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_FLOAT
);
3606 case TGSI_OPCODE_LIT
:
3607 exec_lit(mach
, inst
);
3610 case TGSI_OPCODE_RCP
:
3611 exec_scalar_unary(mach
, inst
, micro_rcp
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3614 case TGSI_OPCODE_RSQ
:
3615 exec_scalar_unary(mach
, inst
, micro_rsq
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3618 case TGSI_OPCODE_EXP
:
3619 exec_exp(mach
, inst
);
3622 case TGSI_OPCODE_LOG
:
3623 exec_log(mach
, inst
);
3626 case TGSI_OPCODE_MUL
:
3627 exec_vector_binary(mach
, inst
, micro_mul
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3630 case TGSI_OPCODE_ADD
:
3631 exec_vector_binary(mach
, inst
, micro_add
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3634 case TGSI_OPCODE_DP3
:
3635 exec_dp3(mach
, inst
);
3638 case TGSI_OPCODE_DP4
:
3639 exec_dp4(mach
, inst
);
3642 case TGSI_OPCODE_DST
:
3643 exec_dst(mach
, inst
);
3646 case TGSI_OPCODE_MIN
:
3647 exec_vector_binary(mach
, inst
, micro_min
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3650 case TGSI_OPCODE_MAX
:
3651 exec_vector_binary(mach
, inst
, micro_max
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3654 case TGSI_OPCODE_SLT
:
3655 exec_vector_binary(mach
, inst
, micro_slt
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3658 case TGSI_OPCODE_SGE
:
3659 exec_vector_binary(mach
, inst
, micro_sge
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3662 case TGSI_OPCODE_MAD
:
3663 exec_vector_trinary(mach
, inst
, micro_mad
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3666 case TGSI_OPCODE_SUB
:
3667 exec_vector_binary(mach
, inst
, micro_sub
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3670 case TGSI_OPCODE_LRP
:
3671 exec_vector_trinary(mach
, inst
, micro_lrp
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3674 case TGSI_OPCODE_CND
:
3675 exec_vector_trinary(mach
, inst
, micro_cnd
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3678 case TGSI_OPCODE_SQRT
:
3679 exec_vector_unary(mach
, inst
, micro_sqrt
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3682 case TGSI_OPCODE_DP2A
:
3683 exec_dp2a(mach
, inst
);
3686 case TGSI_OPCODE_FRC
:
3687 exec_vector_unary(mach
, inst
, micro_frc
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3690 case TGSI_OPCODE_CLAMP
:
3691 exec_vector_trinary(mach
, inst
, micro_clamp
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3694 case TGSI_OPCODE_FLR
:
3695 exec_vector_unary(mach
, inst
, micro_flr
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3698 case TGSI_OPCODE_ROUND
:
3699 exec_vector_unary(mach
, inst
, micro_rnd
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3702 case TGSI_OPCODE_EX2
:
3703 exec_scalar_unary(mach
, inst
, micro_exp2
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3706 case TGSI_OPCODE_LG2
:
3707 exec_scalar_unary(mach
, inst
, micro_lg2
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3710 case TGSI_OPCODE_POW
:
3711 exec_scalar_binary(mach
, inst
, micro_pow
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3714 case TGSI_OPCODE_XPD
:
3715 exec_xpd(mach
, inst
);
3718 case TGSI_OPCODE_ABS
:
3719 exec_vector_unary(mach
, inst
, micro_abs
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3722 case TGSI_OPCODE_RCC
:
3723 exec_scalar_unary(mach
, inst
, micro_rcc
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3726 case TGSI_OPCODE_DPH
:
3727 exec_dph(mach
, inst
);
3730 case TGSI_OPCODE_COS
:
3731 exec_scalar_unary(mach
, inst
, micro_cos
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3734 case TGSI_OPCODE_DDX
:
3735 exec_vector_unary(mach
, inst
, micro_ddx
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3738 case TGSI_OPCODE_DDY
:
3739 exec_vector_unary(mach
, inst
, micro_ddy
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3742 case TGSI_OPCODE_KILP
:
3743 exec_kilp (mach
, inst
);
3746 case TGSI_OPCODE_KIL
:
3747 exec_kil (mach
, inst
);
3750 case TGSI_OPCODE_PK2H
:
3754 case TGSI_OPCODE_PK2US
:
3758 case TGSI_OPCODE_PK4B
:
3762 case TGSI_OPCODE_PK4UB
:
3766 case TGSI_OPCODE_RFL
:
3767 exec_rfl(mach
, inst
);
3770 case TGSI_OPCODE_SEQ
:
3771 exec_vector_binary(mach
, inst
, micro_seq
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3774 case TGSI_OPCODE_SFL
:
3775 exec_vector(mach
, inst
, micro_sfl
, TGSI_EXEC_DATA_FLOAT
);
3778 case TGSI_OPCODE_SGT
:
3779 exec_vector_binary(mach
, inst
, micro_sgt
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3782 case TGSI_OPCODE_SIN
:
3783 exec_scalar_unary(mach
, inst
, micro_sin
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3786 case TGSI_OPCODE_SLE
:
3787 exec_vector_binary(mach
, inst
, micro_sle
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3790 case TGSI_OPCODE_SNE
:
3791 exec_vector_binary(mach
, inst
, micro_sne
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3794 case TGSI_OPCODE_STR
:
3795 exec_vector(mach
, inst
, micro_str
, TGSI_EXEC_DATA_FLOAT
);
3798 case TGSI_OPCODE_TEX
:
3799 /* simple texture lookup */
3800 /* src[0] = texcoord */
3801 /* src[1] = sampler unit */
3802 exec_tex(mach
, inst
, TEX_MODIFIER_NONE
, 1);
3805 case TGSI_OPCODE_TXB
:
3806 /* Texture lookup with lod bias */
3807 /* src[0] = texcoord (src[0].w = LOD bias) */
3808 /* src[1] = sampler unit */
3809 exec_tex(mach
, inst
, TEX_MODIFIER_LOD_BIAS
, 1);
3812 case TGSI_OPCODE_TXD
:
3813 /* Texture lookup with explict partial derivatives */
3814 /* src[0] = texcoord */
3815 /* src[1] = d[strq]/dx */
3816 /* src[2] = d[strq]/dy */
3817 /* src[3] = sampler unit */
3818 exec_txd(mach
, inst
);
3821 case TGSI_OPCODE_TXL
:
3822 /* Texture lookup with explit LOD */
3823 /* src[0] = texcoord (src[0].w = LOD) */
3824 /* src[1] = sampler unit */
3825 exec_tex(mach
, inst
, TEX_MODIFIER_EXPLICIT_LOD
, 1);
3828 case TGSI_OPCODE_TXP
:
3829 /* Texture lookup with projection */
3830 /* src[0] = texcoord (src[0].w = projection) */
3831 /* src[1] = sampler unit */
3832 exec_tex(mach
, inst
, TEX_MODIFIER_PROJECTED
, 1);
3835 case TGSI_OPCODE_UP2H
:
3839 case TGSI_OPCODE_UP2US
:
3843 case TGSI_OPCODE_UP4B
:
3847 case TGSI_OPCODE_UP4UB
:
3851 case TGSI_OPCODE_X2D
:
3852 exec_x2d(mach
, inst
);
3855 case TGSI_OPCODE_ARA
:
3859 case TGSI_OPCODE_ARR
:
3860 exec_vector_unary(mach
, inst
, micro_arr
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_FLOAT
);
3863 case TGSI_OPCODE_BRA
:
3867 case TGSI_OPCODE_CAL
:
3868 /* skip the call if no execution channels are enabled */
3869 if (mach
->ExecMask
) {
3872 /* First, record the depths of the execution stacks.
3873 * This is important for deeply nested/looped return statements.
3874 * We have to unwind the stacks by the correct amount. For a
3875 * real code generator, we could determine the number of entries
3876 * to pop off each stack with simple static analysis and avoid
3877 * implementing this data structure at run time.
3879 mach
->CallStack
[mach
->CallStackTop
].CondStackTop
= mach
->CondStackTop
;
3880 mach
->CallStack
[mach
->CallStackTop
].LoopStackTop
= mach
->LoopStackTop
;
3881 mach
->CallStack
[mach
->CallStackTop
].ContStackTop
= mach
->ContStackTop
;
3882 mach
->CallStack
[mach
->CallStackTop
].SwitchStackTop
= mach
->SwitchStackTop
;
3883 mach
->CallStack
[mach
->CallStackTop
].BreakStackTop
= mach
->BreakStackTop
;
3884 /* note that PC was already incremented above */
3885 mach
->CallStack
[mach
->CallStackTop
].ReturnAddr
= *pc
;
3887 mach
->CallStackTop
++;
3889 /* Second, push the Cond, Loop, Cont, Func stacks */
3890 assert(mach
->CondStackTop
< TGSI_EXEC_MAX_COND_NESTING
);
3891 assert(mach
->LoopStackTop
< TGSI_EXEC_MAX_LOOP_NESTING
);
3892 assert(mach
->ContStackTop
< TGSI_EXEC_MAX_LOOP_NESTING
);
3893 assert(mach
->SwitchStackTop
< TGSI_EXEC_MAX_SWITCH_NESTING
);
3894 assert(mach
->BreakStackTop
< TGSI_EXEC_MAX_BREAK_STACK
);
3895 assert(mach
->FuncStackTop
< TGSI_EXEC_MAX_CALL_NESTING
);
3897 mach
->CondStack
[mach
->CondStackTop
++] = mach
->CondMask
;
3898 mach
->LoopStack
[mach
->LoopStackTop
++] = mach
->LoopMask
;
3899 mach
->ContStack
[mach
->ContStackTop
++] = mach
->ContMask
;
3900 mach
->SwitchStack
[mach
->SwitchStackTop
++] = mach
->Switch
;
3901 mach
->BreakStack
[mach
->BreakStackTop
++] = mach
->BreakType
;
3902 mach
->FuncStack
[mach
->FuncStackTop
++] = mach
->FuncMask
;
3904 /* Finally, jump to the subroutine */
3905 *pc
= inst
->Label
.Label
;
3909 case TGSI_OPCODE_RET
:
3910 mach
->FuncMask
&= ~mach
->ExecMask
;
3911 UPDATE_EXEC_MASK(mach
);
3913 if (mach
->FuncMask
== 0x0) {
3914 /* really return now (otherwise, keep executing */
3916 if (mach
->CallStackTop
== 0) {
3917 /* returning from main() */
3918 mach
->CondStackTop
= 0;
3919 mach
->LoopStackTop
= 0;
3924 assert(mach
->CallStackTop
> 0);
3925 mach
->CallStackTop
--;
3927 mach
->CondStackTop
= mach
->CallStack
[mach
->CallStackTop
].CondStackTop
;
3928 mach
->CondMask
= mach
->CondStack
[mach
->CondStackTop
];
3930 mach
->LoopStackTop
= mach
->CallStack
[mach
->CallStackTop
].LoopStackTop
;
3931 mach
->LoopMask
= mach
->LoopStack
[mach
->LoopStackTop
];
3933 mach
->ContStackTop
= mach
->CallStack
[mach
->CallStackTop
].ContStackTop
;
3934 mach
->ContMask
= mach
->ContStack
[mach
->ContStackTop
];
3936 mach
->SwitchStackTop
= mach
->CallStack
[mach
->CallStackTop
].SwitchStackTop
;
3937 mach
->Switch
= mach
->SwitchStack
[mach
->SwitchStackTop
];
3939 mach
->BreakStackTop
= mach
->CallStack
[mach
->CallStackTop
].BreakStackTop
;
3940 mach
->BreakType
= mach
->BreakStack
[mach
->BreakStackTop
];
3942 assert(mach
->FuncStackTop
> 0);
3943 mach
->FuncMask
= mach
->FuncStack
[--mach
->FuncStackTop
];
3945 *pc
= mach
->CallStack
[mach
->CallStackTop
].ReturnAddr
;
3947 UPDATE_EXEC_MASK(mach
);
3951 case TGSI_OPCODE_SSG
:
3952 exec_vector_unary(mach
, inst
, micro_sgn
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3955 case TGSI_OPCODE_CMP
:
3956 exec_vector_trinary(mach
, inst
, micro_cmp
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3959 case TGSI_OPCODE_SCS
:
3960 exec_scs(mach
, inst
);
3963 case TGSI_OPCODE_NRM
:
3964 exec_nrm3(mach
, inst
);
3967 case TGSI_OPCODE_NRM4
:
3968 exec_nrm4(mach
, inst
);
3971 case TGSI_OPCODE_DIV
:
3972 exec_vector_binary(mach
, inst
, micro_div
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
3975 case TGSI_OPCODE_DP2
:
3976 exec_dp2(mach
, inst
);
3979 case TGSI_OPCODE_IF
:
3981 assert(mach
->CondStackTop
< TGSI_EXEC_MAX_COND_NESTING
);
3982 mach
->CondStack
[mach
->CondStackTop
++] = mach
->CondMask
;
3983 FETCH( &r
[0], 0, TGSI_CHAN_X
);
3984 /* update CondMask */
3986 mach
->CondMask
&= ~0x1;
3989 mach
->CondMask
&= ~0x2;
3992 mach
->CondMask
&= ~0x4;
3995 mach
->CondMask
&= ~0x8;
3997 UPDATE_EXEC_MASK(mach
);
3998 /* Todo: If CondMask==0, jump to ELSE */
4001 case TGSI_OPCODE_UIF
:
4003 assert(mach
->CondStackTop
< TGSI_EXEC_MAX_COND_NESTING
);
4004 mach
->CondStack
[mach
->CondStackTop
++] = mach
->CondMask
;
4005 IFETCH( &r
[0], 0, TGSI_CHAN_X
);
4006 /* update CondMask */
4008 mach
->CondMask
&= ~0x1;
4011 mach
->CondMask
&= ~0x2;
4014 mach
->CondMask
&= ~0x4;
4017 mach
->CondMask
&= ~0x8;
4019 UPDATE_EXEC_MASK(mach
);
4020 /* Todo: If CondMask==0, jump to ELSE */
4023 case TGSI_OPCODE_ELSE
:
4024 /* invert CondMask wrt previous mask */
4027 assert(mach
->CondStackTop
> 0);
4028 prevMask
= mach
->CondStack
[mach
->CondStackTop
- 1];
4029 mach
->CondMask
= ~mach
->CondMask
& prevMask
;
4030 UPDATE_EXEC_MASK(mach
);
4031 /* Todo: If CondMask==0, jump to ENDIF */
4035 case TGSI_OPCODE_ENDIF
:
4037 assert(mach
->CondStackTop
> 0);
4038 mach
->CondMask
= mach
->CondStack
[--mach
->CondStackTop
];
4039 UPDATE_EXEC_MASK(mach
);
4042 case TGSI_OPCODE_END
:
4043 /* make sure we end primitives which haven't
4044 * been explicitly emitted */
4045 conditional_emit_primitive(mach
);
4046 /* halt execution */
4050 case TGSI_OPCODE_PUSHA
:
4054 case TGSI_OPCODE_POPA
:
4058 case TGSI_OPCODE_CEIL
:
4059 exec_vector_unary(mach
, inst
, micro_ceil
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
4062 case TGSI_OPCODE_I2F
:
4063 exec_vector_unary(mach
, inst
, micro_i2f
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_INT
);
4066 case TGSI_OPCODE_NOT
:
4067 exec_vector_unary(mach
, inst
, micro_not
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4070 case TGSI_OPCODE_TRUNC
:
4071 exec_vector_unary(mach
, inst
, micro_trunc
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_FLOAT
);
4074 case TGSI_OPCODE_SHL
:
4075 exec_vector_binary(mach
, inst
, micro_shl
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4078 case TGSI_OPCODE_AND
:
4079 exec_vector_binary(mach
, inst
, micro_and
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4082 case TGSI_OPCODE_OR
:
4083 exec_vector_binary(mach
, inst
, micro_or
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4086 case TGSI_OPCODE_MOD
:
4087 exec_vector_binary(mach
, inst
, micro_mod
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4090 case TGSI_OPCODE_XOR
:
4091 exec_vector_binary(mach
, inst
, micro_xor
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4094 case TGSI_OPCODE_SAD
:
4098 case TGSI_OPCODE_TXF
:
4099 exec_txf(mach
, inst
);
4102 case TGSI_OPCODE_TXQ
:
4103 exec_txq(mach
, inst
);
4106 case TGSI_OPCODE_EMIT
:
4110 case TGSI_OPCODE_ENDPRIM
:
4111 emit_primitive(mach
);
4114 case TGSI_OPCODE_BGNLOOP
:
4115 /* push LoopMask and ContMasks */
4116 assert(mach
->LoopStackTop
< TGSI_EXEC_MAX_LOOP_NESTING
);
4117 assert(mach
->ContStackTop
< TGSI_EXEC_MAX_LOOP_NESTING
);
4118 assert(mach
->LoopLabelStackTop
< TGSI_EXEC_MAX_LOOP_NESTING
);
4119 assert(mach
->BreakStackTop
< TGSI_EXEC_MAX_BREAK_STACK
);
4121 mach
->LoopStack
[mach
->LoopStackTop
++] = mach
->LoopMask
;
4122 mach
->ContStack
[mach
->ContStackTop
++] = mach
->ContMask
;
4123 mach
->LoopLabelStack
[mach
->LoopLabelStackTop
++] = *pc
- 1;
4124 mach
->BreakStack
[mach
->BreakStackTop
++] = mach
->BreakType
;
4125 mach
->BreakType
= TGSI_EXEC_BREAK_INSIDE_LOOP
;
4128 case TGSI_OPCODE_ENDLOOP
:
4129 /* Restore ContMask, but don't pop */
4130 assert(mach
->ContStackTop
> 0);
4131 mach
->ContMask
= mach
->ContStack
[mach
->ContStackTop
- 1];
4132 UPDATE_EXEC_MASK(mach
);
4133 if (mach
->ExecMask
) {
4134 /* repeat loop: jump to instruction just past BGNLOOP */
4135 assert(mach
->LoopLabelStackTop
> 0);
4136 *pc
= mach
->LoopLabelStack
[mach
->LoopLabelStackTop
- 1] + 1;
4139 /* exit loop: pop LoopMask */
4140 assert(mach
->LoopStackTop
> 0);
4141 mach
->LoopMask
= mach
->LoopStack
[--mach
->LoopStackTop
];
4143 assert(mach
->ContStackTop
> 0);
4144 mach
->ContMask
= mach
->ContStack
[--mach
->ContStackTop
];
4145 assert(mach
->LoopLabelStackTop
> 0);
4146 --mach
->LoopLabelStackTop
;
4148 mach
->BreakType
= mach
->BreakStack
[--mach
->BreakStackTop
];
4150 UPDATE_EXEC_MASK(mach
);
4153 case TGSI_OPCODE_BRK
:
4157 case TGSI_OPCODE_CONT
:
4158 /* turn off cont channels for each enabled exec channel */
4159 mach
->ContMask
&= ~mach
->ExecMask
;
4160 /* Todo: if mach->LoopMask == 0, jump to end of loop */
4161 UPDATE_EXEC_MASK(mach
);
4164 case TGSI_OPCODE_BGNSUB
:
4168 case TGSI_OPCODE_ENDSUB
:
4170 * XXX: This really should be a no-op. We should never reach this opcode.
4173 assert(mach
->CallStackTop
> 0);
4174 mach
->CallStackTop
--;
4176 mach
->CondStackTop
= mach
->CallStack
[mach
->CallStackTop
].CondStackTop
;
4177 mach
->CondMask
= mach
->CondStack
[mach
->CondStackTop
];
4179 mach
->LoopStackTop
= mach
->CallStack
[mach
->CallStackTop
].LoopStackTop
;
4180 mach
->LoopMask
= mach
->LoopStack
[mach
->LoopStackTop
];
4182 mach
->ContStackTop
= mach
->CallStack
[mach
->CallStackTop
].ContStackTop
;
4183 mach
->ContMask
= mach
->ContStack
[mach
->ContStackTop
];
4185 mach
->SwitchStackTop
= mach
->CallStack
[mach
->CallStackTop
].SwitchStackTop
;
4186 mach
->Switch
= mach
->SwitchStack
[mach
->SwitchStackTop
];
4188 mach
->BreakStackTop
= mach
->CallStack
[mach
->CallStackTop
].BreakStackTop
;
4189 mach
->BreakType
= mach
->BreakStack
[mach
->BreakStackTop
];
4191 assert(mach
->FuncStackTop
> 0);
4192 mach
->FuncMask
= mach
->FuncStack
[--mach
->FuncStackTop
];
4194 *pc
= mach
->CallStack
[mach
->CallStackTop
].ReturnAddr
;
4196 UPDATE_EXEC_MASK(mach
);
4199 case TGSI_OPCODE_NOP
:
4202 case TGSI_OPCODE_BREAKC
:
4203 FETCH(&r
[0], 0, TGSI_CHAN_X
);
4204 /* update CondMask */
4205 if (r
[0].u
[0] && (mach
->ExecMask
& 0x1)) {
4206 mach
->LoopMask
&= ~0x1;
4208 if (r
[0].u
[1] && (mach
->ExecMask
& 0x2)) {
4209 mach
->LoopMask
&= ~0x2;
4211 if (r
[0].u
[2] && (mach
->ExecMask
& 0x4)) {
4212 mach
->LoopMask
&= ~0x4;
4214 if (r
[0].u
[3] && (mach
->ExecMask
& 0x8)) {
4215 mach
->LoopMask
&= ~0x8;
4217 /* Todo: if mach->LoopMask == 0, jump to end of loop */
4218 UPDATE_EXEC_MASK(mach
);
4221 case TGSI_OPCODE_F2I
:
4222 exec_vector_unary(mach
, inst
, micro_f2i
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_FLOAT
);
4225 case TGSI_OPCODE_IDIV
:
4226 exec_vector_binary(mach
, inst
, micro_idiv
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4229 case TGSI_OPCODE_IMAX
:
4230 exec_vector_binary(mach
, inst
, micro_imax
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4233 case TGSI_OPCODE_IMIN
:
4234 exec_vector_binary(mach
, inst
, micro_imin
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4237 case TGSI_OPCODE_INEG
:
4238 exec_vector_unary(mach
, inst
, micro_ineg
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4241 case TGSI_OPCODE_ISGE
:
4242 exec_vector_binary(mach
, inst
, micro_isge
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4245 case TGSI_OPCODE_ISHR
:
4246 exec_vector_binary(mach
, inst
, micro_ishr
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4249 case TGSI_OPCODE_ISLT
:
4250 exec_vector_binary(mach
, inst
, micro_islt
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4253 case TGSI_OPCODE_F2U
:
4254 exec_vector_unary(mach
, inst
, micro_f2u
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_FLOAT
);
4257 case TGSI_OPCODE_U2F
:
4258 exec_vector_unary(mach
, inst
, micro_u2f
, TGSI_EXEC_DATA_FLOAT
, TGSI_EXEC_DATA_UINT
);
4261 case TGSI_OPCODE_UADD
:
4262 exec_vector_binary(mach
, inst
, micro_uadd
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4265 case TGSI_OPCODE_UDIV
:
4266 exec_vector_binary(mach
, inst
, micro_udiv
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4269 case TGSI_OPCODE_UMAD
:
4270 exec_vector_trinary(mach
, inst
, micro_umad
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4273 case TGSI_OPCODE_UMAX
:
4274 exec_vector_binary(mach
, inst
, micro_umax
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4277 case TGSI_OPCODE_UMIN
:
4278 exec_vector_binary(mach
, inst
, micro_umin
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4281 case TGSI_OPCODE_UMOD
:
4282 exec_vector_binary(mach
, inst
, micro_umod
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4285 case TGSI_OPCODE_UMUL
:
4286 exec_vector_binary(mach
, inst
, micro_umul
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4289 case TGSI_OPCODE_USEQ
:
4290 exec_vector_binary(mach
, inst
, micro_useq
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4293 case TGSI_OPCODE_USGE
:
4294 exec_vector_binary(mach
, inst
, micro_usge
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4297 case TGSI_OPCODE_USHR
:
4298 exec_vector_binary(mach
, inst
, micro_ushr
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4301 case TGSI_OPCODE_USLT
:
4302 exec_vector_binary(mach
, inst
, micro_uslt
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4305 case TGSI_OPCODE_USNE
:
4306 exec_vector_binary(mach
, inst
, micro_usne
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4309 case TGSI_OPCODE_SWITCH
:
4310 exec_switch(mach
, inst
);
4313 case TGSI_OPCODE_CASE
:
4314 exec_case(mach
, inst
);
4317 case TGSI_OPCODE_DEFAULT
:
4321 case TGSI_OPCODE_ENDSWITCH
:
4322 exec_endswitch(mach
);
4325 case TGSI_OPCODE_SAMPLE_I
:
4326 exec_txf(mach
, inst
);
4329 case TGSI_OPCODE_SAMPLE_I_MS
:
4333 case TGSI_OPCODE_SAMPLE
:
4334 exec_sample(mach
, inst
, TEX_MODIFIER_NONE
, FALSE
);
4337 case TGSI_OPCODE_SAMPLE_B
:
4338 exec_sample(mach
, inst
, TEX_MODIFIER_LOD_BIAS
, FALSE
);
4341 case TGSI_OPCODE_SAMPLE_C
:
4342 exec_sample(mach
, inst
, TEX_MODIFIER_NONE
, TRUE
);
4345 case TGSI_OPCODE_SAMPLE_C_LZ
:
4346 exec_sample(mach
, inst
, TEX_MODIFIER_LEVEL_ZERO
, TRUE
);
4349 case TGSI_OPCODE_SAMPLE_D
:
4350 exec_sample_d(mach
, inst
);
4353 case TGSI_OPCODE_SAMPLE_L
:
4354 exec_sample(mach
, inst
, TEX_MODIFIER_EXPLICIT_LOD
, FALSE
);
4357 case TGSI_OPCODE_GATHER4
:
4361 case TGSI_OPCODE_SVIEWINFO
:
4362 exec_txq(mach
, inst
);
4365 case TGSI_OPCODE_SAMPLE_POS
:
4369 case TGSI_OPCODE_SAMPLE_INFO
:
4373 case TGSI_OPCODE_UARL
:
4374 exec_vector_unary(mach
, inst
, micro_uarl
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_UINT
);
4377 case TGSI_OPCODE_UCMP
:
4378 exec_vector_trinary(mach
, inst
, micro_ucmp
, TGSI_EXEC_DATA_UINT
, TGSI_EXEC_DATA_UINT
);
4381 case TGSI_OPCODE_IABS
:
4382 exec_vector_unary(mach
, inst
, micro_iabs
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4385 case TGSI_OPCODE_ISSG
:
4386 exec_vector_unary(mach
, inst
, micro_isgn
, TGSI_EXEC_DATA_INT
, TGSI_EXEC_DATA_INT
);
4389 case TGSI_OPCODE_TEX2
:
4390 /* simple texture lookup */
4391 /* src[0] = texcoord */
4392 /* src[1] = compare */
4393 /* src[2] = sampler unit */
4394 exec_tex(mach
, inst
, TEX_MODIFIER_NONE
, 2);
4396 case TGSI_OPCODE_TXB2
:
4397 /* simple texture lookup */
4398 /* src[0] = texcoord */
4400 /* src[2] = sampler unit */
4401 exec_tex(mach
, inst
, TEX_MODIFIER_LOD_BIAS
, 2);
4403 case TGSI_OPCODE_TXL2
:
4404 /* simple texture lookup */
4405 /* src[0] = texcoord */
4407 /* src[2] = sampler unit */
4408 exec_tex(mach
, inst
, TEX_MODIFIER_EXPLICIT_LOD
, 2);
4417 * Run TGSI interpreter.
4418 * \return bitmask of "alive" quad components
4421 tgsi_exec_machine_run( struct tgsi_exec_machine
*mach
)
4426 mach
->CondMask
= 0xf;
4427 mach
->LoopMask
= 0xf;
4428 mach
->ContMask
= 0xf;
4429 mach
->FuncMask
= 0xf;
4430 mach
->ExecMask
= 0xf;
4432 mach
->Switch
.mask
= 0xf;
4434 assert(mach
->CondStackTop
== 0);
4435 assert(mach
->LoopStackTop
== 0);
4436 assert(mach
->ContStackTop
== 0);
4437 assert(mach
->SwitchStackTop
== 0);
4438 assert(mach
->BreakStackTop
== 0);
4439 assert(mach
->CallStackTop
== 0);
4441 mach
->Temps
[TEMP_KILMASK_I
].xyzw
[TEMP_KILMASK_C
].u
[0] = 0;
4442 mach
->Temps
[TEMP_OUTPUT_I
].xyzw
[TEMP_OUTPUT_C
].u
[0] = 0;
4444 if( mach
->Processor
== TGSI_PROCESSOR_GEOMETRY
) {
4445 mach
->Temps
[TEMP_PRIMITIVE_I
].xyzw
[TEMP_PRIMITIVE_C
].u
[0] = 0;
4446 mach
->Primitives
[0] = 0;
4449 /* execute declarations (interpolants) */
4450 for (i
= 0; i
< mach
->NumDeclarations
; i
++) {
4451 exec_declaration( mach
, mach
->Declarations
+i
);
4456 struct tgsi_exec_vector temps
[TGSI_EXEC_NUM_TEMPS
+ TGSI_EXEC_NUM_TEMP_EXTRAS
];
4457 struct tgsi_exec_vector outputs
[PIPE_MAX_ATTRIBS
];
4460 memset(mach
->Temps
, 0, sizeof(temps
));
4461 memset(mach
->Outputs
, 0, sizeof(outputs
));
4462 memset(temps
, 0, sizeof(temps
));
4463 memset(outputs
, 0, sizeof(outputs
));
4466 /* execute instructions, until pc is set to -1 */
4472 tgsi_dump_instruction(&mach
->Instructions
[pc
], inst
++);
4475 assert(pc
< (int) mach
->NumInstructions
);
4476 exec_instruction(mach
, mach
->Instructions
+ pc
, &pc
);
4479 for (i
= 0; i
< TGSI_EXEC_NUM_TEMPS
+ TGSI_EXEC_NUM_TEMP_EXTRAS
; i
++) {
4480 if (memcmp(&temps
[i
], &mach
->Temps
[i
], sizeof(temps
[i
]))) {
4483 memcpy(&temps
[i
], &mach
->Temps
[i
], sizeof(temps
[i
]));
4484 debug_printf("TEMP[%2u] = ", i
);
4485 for (j
= 0; j
< 4; j
++) {
4489 debug_printf("(%6f %u, %6f %u, %6f %u, %6f %u)\n",
4490 temps
[i
].xyzw
[0].f
[j
], temps
[i
].xyzw
[0].u
[j
],
4491 temps
[i
].xyzw
[1].f
[j
], temps
[i
].xyzw
[1].u
[j
],
4492 temps
[i
].xyzw
[2].f
[j
], temps
[i
].xyzw
[2].u
[j
],
4493 temps
[i
].xyzw
[3].f
[j
], temps
[i
].xyzw
[3].u
[j
]);
4497 for (i
= 0; i
< PIPE_MAX_ATTRIBS
; i
++) {
4498 if (memcmp(&outputs
[i
], &mach
->Outputs
[i
], sizeof(outputs
[i
]))) {
4501 memcpy(&outputs
[i
], &mach
->Outputs
[i
], sizeof(outputs
[i
]));
4502 debug_printf("OUT[%2u] = ", i
);
4503 for (j
= 0; j
< 4; j
++) {
4507 debug_printf("(%6f %u, %6f %u, %6f %u, %6f %u)\n",
4508 outputs
[i
].xyzw
[0].f
[j
], outputs
[i
].xyzw
[0].u
[j
],
4509 outputs
[i
].xyzw
[1].f
[j
], outputs
[i
].xyzw
[1].u
[j
],
4510 outputs
[i
].xyzw
[2].f
[j
], outputs
[i
].xyzw
[2].u
[j
],
4511 outputs
[i
].xyzw
[3].f
[j
], outputs
[i
].xyzw
[3].u
[j
]);
4520 /* we scale from floats in [0,1] to Zbuffer ints in sp_quad_depth_test.c */
4521 if (mach
->Processor
== TGSI_PROCESSOR_FRAGMENT
) {
4523 * Scale back depth component.
4525 for (i
= 0; i
< 4; i
++)
4526 mach
->Outputs
[0].xyzw
[2].f
[i
] *= ctx
->DrawBuffer
->_DepthMaxF
;
4530 /* Strictly speaking, these assertions aren't really needed but they
4531 * can potentially catch some bugs in the control flow code.
4533 assert(mach
->CondStackTop
== 0);
4534 assert(mach
->LoopStackTop
== 0);
4535 assert(mach
->ContStackTop
== 0);
4536 assert(mach
->SwitchStackTop
== 0);
4537 assert(mach
->BreakStackTop
== 0);
4538 assert(mach
->CallStackTop
== 0);
4540 return ~mach
->Temps
[TEMP_KILMASK_I
].xyzw
[TEMP_KILMASK_C
].u
[0];