1 /**************************************************************************
3 * Copyright 2009 VMware, Inc.
4 * Copyright 2007-2008 Tungsten Graphics, Inc., Cedar Park, Texas.
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 **************************************************************************/
31 * TGSI to LLVM IR translation -- SoA.
33 * @author Jose Fonseca <jfonseca@vmware.com>
35 * Based on tgsi_sse2.c code written by Michal Krol, Keith Whitwell,
36 * Brian Paul, and others.
39 #include "pipe/p_config.h"
40 #include "pipe/p_shader_tokens.h"
41 #include "util/u_debug.h"
42 #include "util/u_math.h"
43 #include "util/u_memory.h"
44 #include "tgsi/tgsi_dump.h"
45 #include "tgsi/tgsi_info.h"
46 #include "tgsi/tgsi_parse.h"
47 #include "tgsi/tgsi_util.h"
48 #include "tgsi/tgsi_scan.h"
49 #include "lp_bld_type.h"
50 #include "lp_bld_const.h"
51 #include "lp_bld_arit.h"
52 #include "lp_bld_bitarit.h"
53 #include "lp_bld_gather.h"
54 #include "lp_bld_logic.h"
55 #include "lp_bld_swizzle.h"
56 #include "lp_bld_flow.h"
57 #include "lp_bld_quad.h"
58 #include "lp_bld_tgsi.h"
59 #include "lp_bld_limits.h"
60 #include "lp_bld_debug.h"
63 #define FOR_EACH_CHANNEL( CHAN )\
64 for (CHAN = 0; CHAN < NUM_CHANNELS; CHAN++)
66 #define IS_DST0_CHANNEL_ENABLED( INST, CHAN )\
67 ((INST)->Dst[0].Register.WriteMask & (1 << (CHAN)))
69 #define IF_IS_DST0_CHANNEL_ENABLED( INST, CHAN )\
70 if (IS_DST0_CHANNEL_ENABLED( INST, CHAN ))
72 #define FOR_EACH_DST0_ENABLED_CHANNEL( INST, CHAN )\
73 FOR_EACH_CHANNEL( CHAN )\
74 IF_IS_DST0_CHANNEL_ENABLED( INST, CHAN )
80 #define NUM_CHANNELS 4
82 #define LP_MAX_INSTRUCTIONS 256
86 struct lp_build_context
*bld
;
90 LLVMTypeRef int_vec_type
;
92 LLVMValueRef cond_stack
[LP_MAX_TGSI_NESTING
];
94 LLVMValueRef cond_mask
;
96 LLVMBasicBlockRef loop_block
;
97 LLVMValueRef cont_mask
;
98 LLVMValueRef break_mask
;
99 LLVMValueRef break_var
;
101 LLVMBasicBlockRef loop_block
;
102 LLVMValueRef cont_mask
;
103 LLVMValueRef break_mask
;
104 LLVMValueRef break_var
;
105 } loop_stack
[LP_MAX_TGSI_NESTING
];
108 LLVMValueRef ret_mask
;
111 LLVMValueRef ret_mask
;
112 } call_stack
[LP_MAX_TGSI_NESTING
];
115 LLVMValueRef exec_mask
;
118 struct lp_build_tgsi_soa_context
120 struct lp_build_context base
;
122 /* Builder for integer masks and indices */
123 struct lp_build_context uint_bld
;
125 LLVMValueRef consts_ptr
;
126 const LLVMValueRef
*pos
;
127 const LLVMValueRef (*inputs
)[NUM_CHANNELS
];
128 LLVMValueRef (*outputs
)[NUM_CHANNELS
];
130 const struct lp_build_sampler_soa
*sampler
;
132 LLVMValueRef immediates
[LP_MAX_TGSI_IMMEDIATES
][NUM_CHANNELS
];
133 LLVMValueRef temps
[LP_MAX_TGSI_TEMPS
][NUM_CHANNELS
];
134 LLVMValueRef addr
[LP_MAX_TGSI_ADDRS
][NUM_CHANNELS
];
135 LLVMValueRef preds
[LP_MAX_TGSI_PREDS
][NUM_CHANNELS
];
137 /* We allocate/use this array of temps if (1 << TGSI_FILE_TEMPORARY) is
138 * set in the indirect_files field.
139 * The temps[] array above is unused then.
141 LLVMValueRef temps_array
;
143 const struct tgsi_shader_info
*info
;
144 /** bitmask indicating which register files are accessed indirectly */
145 unsigned indirect_files
;
147 struct lp_build_mask_context
*mask
;
148 struct lp_exec_mask exec_mask
;
150 struct tgsi_full_instruction
*instructions
;
151 uint max_instructions
;
154 static void lp_exec_mask_init(struct lp_exec_mask
*mask
, struct lp_build_context
*bld
)
157 mask
->has_mask
= FALSE
;
158 mask
->cond_stack_size
= 0;
159 mask
->loop_stack_size
= 0;
160 mask
->call_stack_size
= 0;
162 mask
->int_vec_type
= lp_build_int_vec_type(mask
->bld
->type
);
163 mask
->exec_mask
= mask
->ret_mask
= mask
->break_mask
= mask
->cont_mask
= mask
->cond_mask
=
164 LLVMConstAllOnes(mask
->int_vec_type
);
167 static void lp_exec_mask_update(struct lp_exec_mask
*mask
)
169 if (mask
->loop_stack_size
) {
170 /*for loops we need to update the entire mask at runtime */
172 assert(mask
->break_mask
);
173 tmp
= LLVMBuildAnd(mask
->bld
->builder
,
177 mask
->exec_mask
= LLVMBuildAnd(mask
->bld
->builder
,
182 mask
->exec_mask
= mask
->cond_mask
;
184 if (mask
->call_stack_size
) {
185 mask
->exec_mask
= LLVMBuildAnd(mask
->bld
->builder
,
191 mask
->has_mask
= (mask
->cond_stack_size
> 0 ||
192 mask
->loop_stack_size
> 0 ||
193 mask
->call_stack_size
> 0);
196 static void lp_exec_mask_cond_push(struct lp_exec_mask
*mask
,
199 assert(mask
->cond_stack_size
< LP_MAX_TGSI_NESTING
);
200 if (mask
->cond_stack_size
== 0) {
201 assert(mask
->cond_mask
== LLVMConstAllOnes(mask
->int_vec_type
));
203 mask
->cond_stack
[mask
->cond_stack_size
++] = mask
->cond_mask
;
204 assert(LLVMTypeOf(val
) == mask
->int_vec_type
);
205 mask
->cond_mask
= LLVMBuildAnd(mask
->bld
->builder
,
209 lp_exec_mask_update(mask
);
212 static void lp_exec_mask_cond_invert(struct lp_exec_mask
*mask
)
214 LLVMValueRef prev_mask
;
215 LLVMValueRef inv_mask
;
217 assert(mask
->cond_stack_size
);
218 prev_mask
= mask
->cond_stack
[mask
->cond_stack_size
- 1];
219 if (mask
->cond_stack_size
== 1) {
220 assert(prev_mask
== LLVMConstAllOnes(mask
->int_vec_type
));
223 inv_mask
= LLVMBuildNot(mask
->bld
->builder
, mask
->cond_mask
, "");
225 mask
->cond_mask
= LLVMBuildAnd(mask
->bld
->builder
,
228 lp_exec_mask_update(mask
);
231 static void lp_exec_mask_cond_pop(struct lp_exec_mask
*mask
)
233 assert(mask
->cond_stack_size
);
234 mask
->cond_mask
= mask
->cond_stack
[--mask
->cond_stack_size
];
235 lp_exec_mask_update(mask
);
238 static void lp_exec_bgnloop(struct lp_exec_mask
*mask
)
240 if (mask
->loop_stack_size
== 0) {
241 assert(mask
->loop_block
== NULL
);
242 assert(mask
->cont_mask
== LLVMConstAllOnes(mask
->int_vec_type
));
243 assert(mask
->break_mask
== LLVMConstAllOnes(mask
->int_vec_type
));
244 assert(mask
->break_var
== NULL
);
247 assert(mask
->loop_stack_size
< LP_MAX_TGSI_NESTING
);
249 mask
->loop_stack
[mask
->loop_stack_size
].loop_block
= mask
->loop_block
;
250 mask
->loop_stack
[mask
->loop_stack_size
].cont_mask
= mask
->cont_mask
;
251 mask
->loop_stack
[mask
->loop_stack_size
].break_mask
= mask
->break_mask
;
252 mask
->loop_stack
[mask
->loop_stack_size
].break_var
= mask
->break_var
;
253 ++mask
->loop_stack_size
;
255 mask
->break_var
= lp_build_alloca(mask
->bld
->builder
, mask
->int_vec_type
, "");
256 LLVMBuildStore(mask
->bld
->builder
, mask
->break_mask
, mask
->break_var
);
258 mask
->loop_block
= lp_build_insert_new_block(mask
->bld
->builder
, "bgnloop");
259 LLVMBuildBr(mask
->bld
->builder
, mask
->loop_block
);
260 LLVMPositionBuilderAtEnd(mask
->bld
->builder
, mask
->loop_block
);
262 mask
->break_mask
= LLVMBuildLoad(mask
->bld
->builder
, mask
->break_var
, "");
264 lp_exec_mask_update(mask
);
267 static void lp_exec_break(struct lp_exec_mask
*mask
)
269 LLVMValueRef exec_mask
= LLVMBuildNot(mask
->bld
->builder
,
273 mask
->break_mask
= LLVMBuildAnd(mask
->bld
->builder
,
275 exec_mask
, "break_full");
277 lp_exec_mask_update(mask
);
280 static void lp_exec_continue(struct lp_exec_mask
*mask
)
282 LLVMValueRef exec_mask
= LLVMBuildNot(mask
->bld
->builder
,
286 mask
->cont_mask
= LLVMBuildAnd(mask
->bld
->builder
,
290 lp_exec_mask_update(mask
);
294 static void lp_exec_endloop(struct lp_exec_mask
*mask
)
296 LLVMBasicBlockRef endloop
;
297 LLVMTypeRef reg_type
= LLVMIntType(mask
->bld
->type
.width
*
298 mask
->bld
->type
.length
);
301 assert(mask
->break_mask
);
304 * Restore the cont_mask, but don't pop
306 assert(mask
->loop_stack_size
);
307 mask
->cont_mask
= mask
->loop_stack
[mask
->loop_stack_size
- 1].cont_mask
;
308 lp_exec_mask_update(mask
);
311 * Unlike the continue mask, the break_mask must be preserved across loop
314 LLVMBuildStore(mask
->bld
->builder
, mask
->break_mask
, mask
->break_var
);
316 /* i1cond = (mask == 0) */
317 i1cond
= LLVMBuildICmp(
320 LLVMBuildBitCast(mask
->bld
->builder
, mask
->exec_mask
, reg_type
, ""),
321 LLVMConstNull(reg_type
), "");
323 endloop
= lp_build_insert_new_block(mask
->bld
->builder
, "endloop");
325 LLVMBuildCondBr(mask
->bld
->builder
,
326 i1cond
, mask
->loop_block
, endloop
);
328 LLVMPositionBuilderAtEnd(mask
->bld
->builder
, endloop
);
330 assert(mask
->loop_stack_size
);
331 --mask
->loop_stack_size
;
332 mask
->loop_block
= mask
->loop_stack
[mask
->loop_stack_size
].loop_block
;
333 mask
->cont_mask
= mask
->loop_stack
[mask
->loop_stack_size
].cont_mask
;
334 mask
->break_mask
= mask
->loop_stack
[mask
->loop_stack_size
].break_mask
;
335 mask
->break_var
= mask
->loop_stack
[mask
->loop_stack_size
].break_var
;
337 lp_exec_mask_update(mask
);
340 /* stores val into an address pointed to by dst.
341 * mask->exec_mask is used to figure out which bits of val
342 * should be stored into the address
343 * (0 means don't store this bit, 1 means do store).
345 static void lp_exec_mask_store(struct lp_exec_mask
*mask
,
350 /* Mix the predicate and execution mask */
351 if (mask
->has_mask
) {
353 pred
= LLVMBuildAnd(mask
->bld
->builder
, pred
, mask
->exec_mask
, "");
355 pred
= mask
->exec_mask
;
360 LLVMValueRef real_val
, dst_val
;
362 dst_val
= LLVMBuildLoad(mask
->bld
->builder
, dst
, "");
363 real_val
= lp_build_select(mask
->bld
,
367 LLVMBuildStore(mask
->bld
->builder
, real_val
, dst
);
369 LLVMBuildStore(mask
->bld
->builder
, val
, dst
);
372 static void lp_exec_mask_call(struct lp_exec_mask
*mask
,
376 assert(mask
->call_stack_size
< LP_MAX_TGSI_NESTING
);
377 mask
->call_stack
[mask
->call_stack_size
].pc
= *pc
;
378 mask
->call_stack
[mask
->call_stack_size
].ret_mask
= mask
->ret_mask
;
379 mask
->call_stack_size
++;
383 static void lp_exec_mask_ret(struct lp_exec_mask
*mask
, int *pc
)
385 LLVMValueRef exec_mask
;
387 if (mask
->call_stack_size
== 0) {
388 /* returning from main() */
392 exec_mask
= LLVMBuildNot(mask
->bld
->builder
,
396 mask
->ret_mask
= LLVMBuildAnd(mask
->bld
->builder
,
398 exec_mask
, "ret_full");
400 lp_exec_mask_update(mask
);
403 static void lp_exec_mask_bgnsub(struct lp_exec_mask
*mask
)
407 static void lp_exec_mask_endsub(struct lp_exec_mask
*mask
, int *pc
)
409 assert(mask
->call_stack_size
);
410 mask
->call_stack_size
--;
411 *pc
= mask
->call_stack
[mask
->call_stack_size
].pc
;
412 mask
->ret_mask
= mask
->call_stack
[mask
->call_stack_size
].ret_mask
;
413 lp_exec_mask_update(mask
);
418 * Return pointer to a temporary register channel (src or dest).
419 * Note that indirect addressing cannot be handled here.
420 * \param index which temporary register
421 * \param chan which channel of the temp register.
424 get_temp_ptr(struct lp_build_tgsi_soa_context
*bld
,
429 if (bld
->indirect_files
& (1 << TGSI_FILE_TEMPORARY
)) {
430 LLVMValueRef lindex
= lp_build_const_int32(index
* 4 + chan
);
431 return LLVMBuildGEP(bld
->base
.builder
, bld
->temps_array
, &lindex
, 1, "");
434 return bld
->temps
[index
][chan
];
441 * XXX the lp_build_gather() function should be capable of doing this
442 * with a little work.
445 build_gather(struct lp_build_tgsi_soa_context
*bld
,
446 LLVMValueRef base_ptr
,
447 LLVMValueRef indexes
)
449 LLVMValueRef res
= bld
->base
.undef
;
453 * Loop over elements of index_vec, load scalar value, insert it into 'res'.
455 for (i
= 0; i
< bld
->base
.type
.length
; i
++) {
456 LLVMValueRef ii
= LLVMConstInt(LLVMInt32Type(), i
, 0);
457 LLVMValueRef index
= LLVMBuildExtractElement(bld
->base
.builder
,
459 LLVMValueRef scalar_ptr
= LLVMBuildGEP(bld
->base
.builder
, base_ptr
,
461 LLVMValueRef scalar
= LLVMBuildLoad(bld
->base
.builder
, scalar_ptr
, "");
463 res
= LLVMBuildInsertElement(bld
->base
.builder
, res
, scalar
, ii
, "");
471 * Read the current value of the ADDR register, convert the floats to
472 * ints, multiply by four and return the vector of offsets.
473 * The offsets will be used to index into the constant buffer or
474 * temporary register file.
477 get_indirect_index(struct lp_build_tgsi_soa_context
*bld
,
478 unsigned reg_file
, unsigned reg_index
,
479 const struct tgsi_src_register
*indirect_reg
)
481 struct lp_build_context
*uint_bld
= &bld
->uint_bld
;
482 /* always use X component of address register */
483 unsigned swizzle
= indirect_reg
->SwizzleX
;
486 LLVMValueRef max_index
;
489 assert(bld
->indirect_files
& (1 << reg_file
));
491 base
= lp_build_const_int_vec(uint_bld
->type
, reg_index
);
494 rel
= LLVMBuildLoad(bld
->base
.builder
,
495 bld
->addr
[indirect_reg
->Index
][swizzle
],
498 /* for indexing we want integers */
499 rel
= LLVMBuildFPToSI(bld
->base
.builder
,
501 uint_bld
->vec_type
, "");
503 index
= lp_build_add(uint_bld
, base
, rel
);
505 max_index
= lp_build_const_int_vec(uint_bld
->type
,
506 bld
->info
->file_max
[reg_file
]);
508 assert(!uint_bld
->type
.sign
);
509 index
= lp_build_min(uint_bld
, index
, max_index
);
520 struct lp_build_tgsi_soa_context
*bld
,
521 const struct tgsi_full_instruction
*inst
,
523 const unsigned chan_index
)
525 struct lp_build_context
*uint_bld
= &bld
->uint_bld
;
526 const struct tgsi_full_src_register
*reg
= &inst
->Src
[src_op
];
527 const unsigned swizzle
=
528 tgsi_util_get_full_src_register_swizzle(reg
, chan_index
);
530 LLVMValueRef indirect_index
= NULL
;
533 assert(0 && "invalid swizzle in emit_fetch()");
534 return bld
->base
.undef
;
537 if (reg
->Register
.Indirect
) {
538 indirect_index
= get_indirect_index(bld
,
543 assert(reg
->Register
.Index
<= bld
->info
->file_max
[reg
->Register
.File
]);
546 switch (reg
->Register
.File
) {
547 case TGSI_FILE_CONSTANT
:
548 if (reg
->Register
.Indirect
) {
549 LLVMValueRef swizzle_vec
=
550 lp_build_const_int_vec(uint_bld
->type
, swizzle
);
551 LLVMValueRef index_vec
; /* index into the const buffer */
553 /* index_vec = indirect_index * 4 + swizzle */
554 index_vec
= lp_build_shl_imm(uint_bld
, indirect_index
, 2);
555 index_vec
= lp_build_add(uint_bld
, index_vec
, swizzle_vec
);
557 /* Gather values from the constant buffer */
558 res
= build_gather(bld
, bld
->consts_ptr
, index_vec
);
561 LLVMValueRef index
; /* index into the const buffer */
562 LLVMValueRef scalar
, scalar_ptr
;
564 index
= lp_build_const_int32(reg
->Register
.Index
*4 + swizzle
);
566 scalar_ptr
= LLVMBuildGEP(bld
->base
.builder
, bld
->consts_ptr
,
568 scalar
= LLVMBuildLoad(bld
->base
.builder
, scalar_ptr
, "");
570 res
= lp_build_broadcast_scalar(&bld
->base
, scalar
);
574 case TGSI_FILE_IMMEDIATE
:
575 res
= bld
->immediates
[reg
->Register
.Index
][swizzle
];
579 case TGSI_FILE_INPUT
:
580 res
= bld
->inputs
[reg
->Register
.Index
][swizzle
];
584 case TGSI_FILE_TEMPORARY
:
585 if (reg
->Register
.Indirect
) {
586 LLVMValueRef swizzle_vec
=
587 lp_build_const_int_vec(uint_bld
->type
, swizzle
);
588 LLVMValueRef length_vec
=
589 lp_build_const_int_vec(uint_bld
->type
, bld
->base
.type
.length
);
590 LLVMValueRef index_vec
; /* index into the const buffer */
591 LLVMValueRef temps_array
;
592 LLVMTypeRef float4_ptr_type
;
594 /* index_vec = (indirect_index * 4 + swizzle) * length */
595 index_vec
= lp_build_shl_imm(uint_bld
, indirect_index
, 2);
596 index_vec
= lp_build_add(uint_bld
, index_vec
, swizzle_vec
);
597 index_vec
= lp_build_mul(uint_bld
, index_vec
, length_vec
);
599 /* cast temps_array pointer to float* */
600 float4_ptr_type
= LLVMPointerType(LLVMFloatType(), 0);
601 temps_array
= LLVMBuildBitCast(uint_bld
->builder
, bld
->temps_array
,
602 float4_ptr_type
, "");
604 /* Gather values from the temporary register array */
605 res
= build_gather(bld
, temps_array
, index_vec
);
608 LLVMValueRef temp_ptr
;
609 temp_ptr
= get_temp_ptr(bld
, reg
->Register
.Index
, swizzle
);
610 res
= LLVMBuildLoad(bld
->base
.builder
, temp_ptr
, "");
612 return bld
->base
.undef
;
617 assert(0 && "invalid src register in emit_fetch()");
618 return bld
->base
.undef
;
621 switch( tgsi_util_get_full_src_register_sign_mode( reg
, chan_index
) ) {
622 case TGSI_UTIL_SIGN_CLEAR
:
623 res
= lp_build_abs( &bld
->base
, res
);
626 case TGSI_UTIL_SIGN_SET
:
627 res
= lp_build_abs( &bld
->base
, res
);
629 case TGSI_UTIL_SIGN_TOGGLE
:
630 res
= lp_build_negate( &bld
->base
, res
);
633 case TGSI_UTIL_SIGN_KEEP
:
642 * Register fetch with derivatives.
646 struct lp_build_tgsi_soa_context
*bld
,
647 const struct tgsi_full_instruction
*inst
,
649 const unsigned chan_index
,
656 src
= emit_fetch(bld
, inst
, index
, chan_index
);
661 /* TODO: use interpolation coeffs for inputs */
664 *ddx
= lp_build_ddx(&bld
->base
, src
);
667 *ddy
= lp_build_ddy(&bld
->base
, src
);
675 emit_fetch_predicate(
676 struct lp_build_tgsi_soa_context
*bld
,
677 const struct tgsi_full_instruction
*inst
,
681 unsigned char swizzles
[4];
682 LLVMValueRef unswizzled
[4] = {NULL
, NULL
, NULL
, NULL
};
686 if (!inst
->Instruction
.Predicate
) {
687 FOR_EACH_CHANNEL( chan
) {
693 swizzles
[0] = inst
->Predicate
.SwizzleX
;
694 swizzles
[1] = inst
->Predicate
.SwizzleY
;
695 swizzles
[2] = inst
->Predicate
.SwizzleZ
;
696 swizzles
[3] = inst
->Predicate
.SwizzleW
;
698 index
= inst
->Predicate
.Index
;
699 assert(index
< LP_MAX_TGSI_PREDS
);
701 FOR_EACH_CHANNEL( chan
) {
702 unsigned swizzle
= swizzles
[chan
];
705 * Only fetch the predicate register channels that are actually listed
708 if (!unswizzled
[swizzle
]) {
709 value
= LLVMBuildLoad(bld
->base
.builder
,
710 bld
->preds
[index
][swizzle
], "");
713 * Convert the value to an integer mask.
715 * TODO: Short-circuit this comparison -- a D3D setp_xx instructions
716 * is needlessly causing two comparisons due to storing the intermediate
717 * result as float vector instead of an integer mask vector.
719 value
= lp_build_compare(bld
->base
.builder
,
724 if (inst
->Predicate
.Negate
) {
725 value
= LLVMBuildNot(bld
->base
.builder
, value
, "");
728 unswizzled
[swizzle
] = value
;
730 value
= unswizzled
[swizzle
];
743 struct lp_build_tgsi_soa_context
*bld
,
744 const struct tgsi_full_instruction
*inst
,
750 const struct tgsi_full_dst_register
*reg
= &inst
->Dst
[index
];
751 LLVMValueRef indirect_index
= NULL
;
753 switch( inst
->Instruction
.Saturate
) {
757 case TGSI_SAT_ZERO_ONE
:
758 value
= lp_build_max(&bld
->base
, value
, bld
->base
.zero
);
759 value
= lp_build_min(&bld
->base
, value
, bld
->base
.one
);
762 case TGSI_SAT_MINUS_PLUS_ONE
:
763 value
= lp_build_max(&bld
->base
, value
, lp_build_const_vec(bld
->base
.type
, -1.0));
764 value
= lp_build_min(&bld
->base
, value
, bld
->base
.one
);
771 if (reg
->Register
.Indirect
) {
772 indirect_index
= get_indirect_index(bld
,
777 assert(reg
->Register
.Index
<= bld
->info
->file_max
[reg
->Register
.File
]);
780 switch( reg
->Register
.File
) {
781 case TGSI_FILE_OUTPUT
:
782 lp_exec_mask_store(&bld
->exec_mask
, pred
, value
,
783 bld
->outputs
[reg
->Register
.Index
][chan_index
]);
786 case TGSI_FILE_TEMPORARY
:
787 if (reg
->Register
.Indirect
) {
788 /* XXX not done yet */
789 debug_printf("WARNING: LLVM scatter store of temp regs"
790 " not implemented\n");
793 LLVMValueRef temp_ptr
= get_temp_ptr(bld
, reg
->Register
.Index
,
795 lp_exec_mask_store(&bld
->exec_mask
, pred
, value
, temp_ptr
);
799 case TGSI_FILE_ADDRESS
:
800 lp_exec_mask_store(&bld
->exec_mask
, pred
, value
,
801 bld
->addr
[reg
->Indirect
.Index
][chan_index
]);
804 case TGSI_FILE_PREDICATE
:
805 lp_exec_mask_store(&bld
->exec_mask
, pred
, value
,
806 bld
->preds
[reg
->Register
.Index
][chan_index
]);
816 * High-level instruction translators.
820 emit_tex( struct lp_build_tgsi_soa_context
*bld
,
821 const struct tgsi_full_instruction
*inst
,
822 enum lp_build_tex_modifier modifier
,
826 LLVMValueRef lod_bias
, explicit_lod
;
827 LLVMValueRef oow
= NULL
;
828 LLVMValueRef coords
[3];
835 _debug_printf("warning: found texture instruction but no sampler generator supplied\n");
836 for (i
= 0; i
< 4; i
++) {
837 texel
[i
] = bld
->base
.undef
;
842 switch (inst
->Texture
.Texture
) {
843 case TGSI_TEXTURE_1D
:
846 case TGSI_TEXTURE_2D
:
847 case TGSI_TEXTURE_RECT
:
850 case TGSI_TEXTURE_SHADOW1D
:
851 case TGSI_TEXTURE_SHADOW2D
:
852 case TGSI_TEXTURE_SHADOWRECT
:
853 case TGSI_TEXTURE_3D
:
854 case TGSI_TEXTURE_CUBE
:
862 if (modifier
== LP_BLD_TEX_MODIFIER_LOD_BIAS
) {
863 lod_bias
= emit_fetch( bld
, inst
, 0, 3 );
866 else if (modifier
== LP_BLD_TEX_MODIFIER_EXPLICIT_LOD
) {
868 explicit_lod
= emit_fetch( bld
, inst
, 0, 3 );
875 if (modifier
== LP_BLD_TEX_MODIFIER_PROJECTED
) {
876 oow
= emit_fetch( bld
, inst
, 0, 3 );
877 oow
= lp_build_rcp(&bld
->base
, oow
);
880 for (i
= 0; i
< num_coords
; i
++) {
881 coords
[i
] = emit_fetch( bld
, inst
, 0, i
);
882 if (modifier
== LP_BLD_TEX_MODIFIER_PROJECTED
)
883 coords
[i
] = lp_build_mul(&bld
->base
, coords
[i
], oow
);
885 for (i
= num_coords
; i
< 3; i
++) {
886 coords
[i
] = bld
->base
.undef
;
889 if (modifier
== LP_BLD_TEX_MODIFIER_EXPLICIT_DERIV
) {
890 for (i
= 0; i
< num_coords
; i
++) {
891 ddx
[i
] = emit_fetch( bld
, inst
, 1, i
);
892 ddy
[i
] = emit_fetch( bld
, inst
, 2, i
);
894 unit
= inst
->Src
[3].Register
.Index
;
896 for (i
= 0; i
< num_coords
; i
++) {
897 ddx
[i
] = lp_build_ddx( &bld
->base
, coords
[i
] );
898 ddy
[i
] = lp_build_ddy( &bld
->base
, coords
[i
] );
900 unit
= inst
->Src
[1].Register
.Index
;
902 for (i
= num_coords
; i
< 3; i
++) {
903 ddx
[i
] = bld
->base
.undef
;
904 ddy
[i
] = bld
->base
.undef
;
907 bld
->sampler
->emit_fetch_texel(bld
->sampler
,
910 unit
, num_coords
, coords
,
912 lod_bias
, explicit_lod
,
918 * Kill fragment if any of the src register values are negative.
922 struct lp_build_tgsi_soa_context
*bld
,
923 const struct tgsi_full_instruction
*inst
)
925 const struct tgsi_full_src_register
*reg
= &inst
->Src
[0];
926 LLVMValueRef terms
[NUM_CHANNELS
];
930 memset(&terms
, 0, sizeof terms
);
932 FOR_EACH_CHANNEL( chan_index
) {
935 /* Unswizzle channel */
936 swizzle
= tgsi_util_get_full_src_register_swizzle( reg
, chan_index
);
938 /* Check if the component has not been already tested. */
939 assert(swizzle
< NUM_CHANNELS
);
940 if( !terms
[swizzle
] )
941 /* TODO: change the comparison operator instead of setting the sign */
942 terms
[swizzle
] = emit_fetch(bld
, inst
, 0, chan_index
);
946 FOR_EACH_CHANNEL( chan_index
) {
947 if(terms
[chan_index
]) {
948 LLVMValueRef chan_mask
;
951 * If term < 0 then mask = 0 else mask = ~0.
953 chan_mask
= lp_build_cmp(&bld
->base
, PIPE_FUNC_GEQUAL
, terms
[chan_index
], bld
->base
.zero
);
956 mask
= LLVMBuildAnd(bld
->base
.builder
, mask
, chan_mask
, "");
963 lp_build_mask_update(bld
->mask
, mask
);
968 * Predicated fragment kill.
969 * XXX Actually, we do an unconditional kill (as in tgsi_exec.c).
970 * The only predication is the execution mask which will apply if
971 * we're inside a loop or conditional.
974 emit_kilp(struct lp_build_tgsi_soa_context
*bld
,
975 const struct tgsi_full_instruction
*inst
)
979 /* For those channels which are "alive", disable fragment shader
982 if (bld
->exec_mask
.has_mask
) {
983 mask
= LLVMBuildNot(bld
->base
.builder
, bld
->exec_mask
.exec_mask
, "kilp");
986 mask
= bld
->base
.zero
;
989 lp_build_mask_update(bld
->mask
, mask
);
994 struct lp_build_tgsi_soa_context
*bld
,
995 const struct tgsi_full_declaration
*decl
)
997 LLVMTypeRef vec_type
= bld
->base
.vec_type
;
999 unsigned first
= decl
->Range
.First
;
1000 unsigned last
= decl
->Range
.Last
;
1003 for (idx
= first
; idx
<= last
; ++idx
) {
1004 assert(last
<= bld
->info
->file_max
[decl
->Declaration
.File
]);
1005 switch (decl
->Declaration
.File
) {
1006 case TGSI_FILE_TEMPORARY
:
1007 assert(idx
< LP_MAX_TGSI_TEMPS
);
1008 if (bld
->indirect_files
& (1 << TGSI_FILE_TEMPORARY
)) {
1009 LLVMValueRef array_size
= LLVMConstInt(LLVMInt32Type(),
1011 bld
->temps_array
= lp_build_array_alloca(bld
->base
.builder
,
1012 vec_type
, array_size
, "");
1014 for (i
= 0; i
< NUM_CHANNELS
; i
++)
1015 bld
->temps
[idx
][i
] = lp_build_alloca(bld
->base
.builder
,
1020 case TGSI_FILE_OUTPUT
:
1021 for (i
= 0; i
< NUM_CHANNELS
; i
++)
1022 bld
->outputs
[idx
][i
] = lp_build_alloca(bld
->base
.builder
,
1026 case TGSI_FILE_ADDRESS
:
1027 assert(idx
< LP_MAX_TGSI_ADDRS
);
1028 for (i
= 0; i
< NUM_CHANNELS
; i
++)
1029 bld
->addr
[idx
][i
] = lp_build_alloca(bld
->base
.builder
,
1033 case TGSI_FILE_PREDICATE
:
1034 assert(idx
< LP_MAX_TGSI_PREDS
);
1035 for (i
= 0; i
< NUM_CHANNELS
; i
++)
1036 bld
->preds
[idx
][i
] = lp_build_alloca(bld
->base
.builder
,
1041 /* don't need to declare other vars */
1049 * Emit LLVM for one TGSI instruction.
1050 * \param return TRUE for success, FALSE otherwise
1054 struct lp_build_tgsi_soa_context
*bld
,
1055 const struct tgsi_full_instruction
*inst
,
1056 const struct tgsi_opcode_info
*info
,
1059 unsigned chan_index
;
1060 LLVMValueRef src0
, src1
, src2
;
1061 LLVMValueRef tmp0
, tmp1
, tmp2
;
1062 LLVMValueRef tmp3
= NULL
;
1063 LLVMValueRef tmp4
= NULL
;
1064 LLVMValueRef tmp5
= NULL
;
1065 LLVMValueRef tmp6
= NULL
;
1066 LLVMValueRef tmp7
= NULL
;
1068 LLVMValueRef dst0
[NUM_CHANNELS
];
1071 * Stores and write masks are handled in a general fashion after the long
1072 * instruction opcode switch statement.
1074 * Although not stricitly necessary, we avoid generating instructions for
1075 * channels which won't be stored, in cases where's that easy. For some
1076 * complex instructions, like texture sampling, it is more convenient to
1077 * assume a full writemask and then let LLVM optimization passes eliminate
1083 assert(info
->num_dst
<= 1);
1084 if (info
->num_dst
) {
1085 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1086 dst0
[chan_index
] = bld
->base
.undef
;
1090 switch (inst
->Instruction
.Opcode
) {
1091 case TGSI_OPCODE_ARL
:
1092 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1093 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1094 tmp0
= lp_build_floor(&bld
->base
, tmp0
);
1095 dst0
[chan_index
] = tmp0
;
1099 case TGSI_OPCODE_MOV
:
1100 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1101 dst0
[chan_index
] = emit_fetch( bld
, inst
, 0, chan_index
);
1105 case TGSI_OPCODE_LIT
:
1106 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) ) {
1107 dst0
[CHAN_X
] = bld
->base
.one
;
1109 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) ) {
1110 src0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1111 dst0
[CHAN_Y
] = lp_build_max( &bld
->base
, src0
, bld
->base
.zero
);
1113 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
) ) {
1114 /* XMM[1] = SrcReg[0].yyyy */
1115 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Y
);
1116 /* XMM[1] = max(XMM[1], 0) */
1117 tmp1
= lp_build_max( &bld
->base
, tmp1
, bld
->base
.zero
);
1118 /* XMM[2] = SrcReg[0].wwww */
1119 tmp2
= emit_fetch( bld
, inst
, 0, CHAN_W
);
1120 tmp1
= lp_build_pow( &bld
->base
, tmp1
, tmp2
);
1121 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1122 tmp2
= lp_build_cmp(&bld
->base
, PIPE_FUNC_GREATER
, tmp0
, bld
->base
.zero
);
1123 dst0
[CHAN_Z
] = lp_build_select(&bld
->base
, tmp2
, tmp1
, bld
->base
.zero
);
1125 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_W
) ) {
1126 dst0
[CHAN_W
] = bld
->base
.one
;
1130 case TGSI_OPCODE_RCP
:
1131 /* TGSI_OPCODE_RECIP */
1132 src0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1133 res
= lp_build_rcp(&bld
->base
, src0
);
1134 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1135 dst0
[chan_index
] = res
;
1139 case TGSI_OPCODE_RSQ
:
1140 /* TGSI_OPCODE_RECIPSQRT */
1141 src0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1142 src0
= lp_build_abs(&bld
->base
, src0
);
1143 res
= lp_build_rsqrt(&bld
->base
, src0
);
1144 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1145 dst0
[chan_index
] = res
;
1149 case TGSI_OPCODE_EXP
:
1150 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) ||
1151 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) ||
1152 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
)) {
1153 LLVMValueRef
*p_exp2_int_part
= NULL
;
1154 LLVMValueRef
*p_frac_part
= NULL
;
1155 LLVMValueRef
*p_exp2
= NULL
;
1157 src0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1159 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
))
1160 p_exp2_int_part
= &tmp0
;
1161 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
))
1162 p_frac_part
= &tmp1
;
1163 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
))
1166 lp_build_exp2_approx(&bld
->base
, src0
, p_exp2_int_part
, p_frac_part
, p_exp2
);
1168 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
))
1169 dst0
[CHAN_X
] = tmp0
;
1170 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
))
1171 dst0
[CHAN_Y
] = tmp1
;
1172 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
))
1173 dst0
[CHAN_Z
] = tmp2
;
1176 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_W
)) {
1177 dst0
[CHAN_W
] = bld
->base
.one
;
1181 case TGSI_OPCODE_LOG
:
1182 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) ||
1183 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) ||
1184 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
)) {
1185 LLVMValueRef
*p_floor_log2
= NULL
;
1186 LLVMValueRef
*p_exp
= NULL
;
1187 LLVMValueRef
*p_log2
= NULL
;
1189 src0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1190 src0
= lp_build_abs( &bld
->base
, src0
);
1192 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
))
1193 p_floor_log2
= &tmp0
;
1194 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
))
1196 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
))
1199 lp_build_log2_approx(&bld
->base
, src0
, p_exp
, p_floor_log2
, p_log2
);
1201 /* dst.x = floor(lg2(abs(src.x))) */
1202 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
))
1203 dst0
[CHAN_X
] = tmp0
;
1204 /* dst.y = abs(src)/ex2(floor(lg2(abs(src.x)))) */
1205 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
)) {
1206 dst0
[CHAN_Y
] = lp_build_div( &bld
->base
, src0
, tmp1
);
1208 /* dst.z = lg2(abs(src.x)) */
1209 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
))
1210 dst0
[CHAN_Z
] = tmp2
;
1213 if (IS_DST0_CHANNEL_ENABLED( inst
, CHAN_W
)) {
1214 dst0
[CHAN_W
] = bld
->base
.one
;
1218 case TGSI_OPCODE_MUL
:
1219 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1220 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1221 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1222 dst0
[chan_index
] = lp_build_mul(&bld
->base
, src0
, src1
);
1226 case TGSI_OPCODE_ADD
:
1227 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1228 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1229 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1230 dst0
[chan_index
] = lp_build_add(&bld
->base
, src0
, src1
);
1234 case TGSI_OPCODE_DP3
:
1235 /* TGSI_OPCODE_DOT3 */
1236 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1237 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_X
);
1238 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp1
);
1239 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Y
);
1240 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Y
);
1241 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1242 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1243 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Z
);
1244 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Z
);
1245 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1246 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1247 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1248 dst0
[chan_index
] = tmp0
;
1252 case TGSI_OPCODE_DP4
:
1253 /* TGSI_OPCODE_DOT4 */
1254 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1255 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_X
);
1256 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp1
);
1257 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Y
);
1258 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Y
);
1259 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1260 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1261 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Z
);
1262 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Z
);
1263 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1264 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1265 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_W
);
1266 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_W
);
1267 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1268 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1269 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1270 dst0
[chan_index
] = tmp0
;
1274 case TGSI_OPCODE_DST
:
1275 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) {
1276 dst0
[CHAN_X
] = bld
->base
.one
;
1278 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) {
1279 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_Y
);
1280 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_Y
);
1281 dst0
[CHAN_Y
] = lp_build_mul( &bld
->base
, tmp0
, tmp1
);
1283 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
) {
1284 dst0
[CHAN_Z
] = emit_fetch( bld
, inst
, 0, CHAN_Z
);
1286 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_W
) {
1287 dst0
[CHAN_W
] = emit_fetch( bld
, inst
, 1, CHAN_W
);
1291 case TGSI_OPCODE_MIN
:
1292 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1293 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1294 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1295 dst0
[chan_index
] = lp_build_min( &bld
->base
, src0
, src1
);
1299 case TGSI_OPCODE_MAX
:
1300 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1301 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1302 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1303 dst0
[chan_index
] = lp_build_max( &bld
->base
, src0
, src1
);
1307 case TGSI_OPCODE_SLT
:
1308 /* TGSI_OPCODE_SETLT */
1309 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1310 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1311 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1312 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_LESS
, src0
, src1
);
1313 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, bld
->base
.one
, bld
->base
.zero
);
1317 case TGSI_OPCODE_SGE
:
1318 /* TGSI_OPCODE_SETGE */
1319 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1320 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1321 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1322 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_GEQUAL
, src0
, src1
);
1323 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, bld
->base
.one
, bld
->base
.zero
);
1327 case TGSI_OPCODE_MAD
:
1328 /* TGSI_OPCODE_MADD */
1329 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1330 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1331 tmp1
= emit_fetch( bld
, inst
, 1, chan_index
);
1332 tmp2
= emit_fetch( bld
, inst
, 2, chan_index
);
1333 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp1
);
1334 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp2
);
1335 dst0
[chan_index
] = tmp0
;
1339 case TGSI_OPCODE_SUB
:
1340 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1341 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1342 tmp1
= emit_fetch( bld
, inst
, 1, chan_index
);
1343 dst0
[chan_index
] = lp_build_sub( &bld
->base
, tmp0
, tmp1
);
1347 case TGSI_OPCODE_LRP
:
1348 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1349 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1350 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1351 src2
= emit_fetch( bld
, inst
, 2, chan_index
);
1352 tmp0
= lp_build_sub( &bld
->base
, src1
, src2
);
1353 tmp0
= lp_build_mul( &bld
->base
, src0
, tmp0
);
1354 dst0
[chan_index
] = lp_build_add( &bld
->base
, tmp0
, src2
);
1358 case TGSI_OPCODE_CND
:
1359 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1360 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1361 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1362 src2
= emit_fetch( bld
, inst
, 2, chan_index
);
1363 tmp1
= lp_build_const_vec(bld
->base
.type
, 0.5);
1364 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_GREATER
, src2
, tmp1
);
1365 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, src0
, src1
);
1369 case TGSI_OPCODE_DP2A
:
1370 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
); /* xmm0 = src[0].x */
1371 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_X
); /* xmm1 = src[1].x */
1372 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp1
); /* xmm0 = xmm0 * xmm1 */
1373 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Y
); /* xmm1 = src[0].y */
1374 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Y
); /* xmm2 = src[1].y */
1375 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
); /* xmm1 = xmm1 * xmm2 */
1376 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
); /* xmm0 = xmm0 + xmm1 */
1377 tmp1
= emit_fetch( bld
, inst
, 2, CHAN_X
); /* xmm1 = src[2].x */
1378 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
); /* xmm0 = xmm0 + xmm1 */
1379 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1380 dst0
[chan_index
] = tmp0
; /* dest[ch] = xmm0 */
1384 case TGSI_OPCODE_FRC
:
1385 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1386 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1387 tmp0
= lp_build_floor(&bld
->base
, src0
);
1388 tmp0
= lp_build_sub(&bld
->base
, src0
, tmp0
);
1389 dst0
[chan_index
] = tmp0
;
1393 case TGSI_OPCODE_CLAMP
:
1394 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1395 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1396 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1397 src2
= emit_fetch( bld
, inst
, 2, chan_index
);
1398 tmp0
= lp_build_max(&bld
->base
, tmp0
, src1
);
1399 tmp0
= lp_build_min(&bld
->base
, tmp0
, src2
);
1400 dst0
[chan_index
] = tmp0
;
1404 case TGSI_OPCODE_FLR
:
1405 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1406 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1407 dst0
[chan_index
] = lp_build_floor(&bld
->base
, tmp0
);
1411 case TGSI_OPCODE_ROUND
:
1412 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1413 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1414 dst0
[chan_index
] = lp_build_round(&bld
->base
, tmp0
);
1418 case TGSI_OPCODE_EX2
: {
1419 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1420 tmp0
= lp_build_exp2( &bld
->base
, tmp0
);
1421 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1422 dst0
[chan_index
] = tmp0
;
1427 case TGSI_OPCODE_LG2
:
1428 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1429 tmp0
= lp_build_log2( &bld
->base
, tmp0
);
1430 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1431 dst0
[chan_index
] = tmp0
;
1435 case TGSI_OPCODE_POW
:
1436 src0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1437 src1
= emit_fetch( bld
, inst
, 1, CHAN_X
);
1438 res
= lp_build_pow( &bld
->base
, src0
, src1
);
1439 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1440 dst0
[chan_index
] = res
;
1444 case TGSI_OPCODE_XPD
:
1445 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) ||
1446 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) ) {
1447 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_Z
);
1448 tmp3
= emit_fetch( bld
, inst
, 0, CHAN_Z
);
1450 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) ||
1451 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
) ) {
1452 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_Y
);
1453 tmp4
= emit_fetch( bld
, inst
, 1, CHAN_Y
);
1455 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) {
1457 tmp2
= lp_build_mul( &bld
->base
, tmp2
, tmp1
);
1459 tmp5
= lp_build_mul( &bld
->base
, tmp5
, tmp4
);
1460 tmp2
= lp_build_sub( &bld
->base
, tmp2
, tmp5
);
1461 dst0
[CHAN_X
] = tmp2
;
1463 if( IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) ||
1464 IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
) ) {
1465 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_X
);
1466 tmp5
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1468 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) {
1469 tmp3
= lp_build_mul( &bld
->base
, tmp3
, tmp2
);
1470 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp5
);
1471 tmp3
= lp_build_sub( &bld
->base
, tmp3
, tmp1
);
1472 dst0
[CHAN_Y
] = tmp3
;
1474 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
) {
1475 tmp5
= lp_build_mul( &bld
->base
, tmp5
, tmp4
);
1476 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp2
);
1477 tmp5
= lp_build_sub( &bld
->base
, tmp5
, tmp0
);
1478 dst0
[CHAN_Z
] = tmp5
;
1480 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_W
) {
1481 dst0
[CHAN_W
] = bld
->base
.one
;
1485 case TGSI_OPCODE_ABS
:
1486 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1487 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1488 dst0
[chan_index
] = lp_build_abs( &bld
->base
, tmp0
);
1492 case TGSI_OPCODE_RCC
:
1497 case TGSI_OPCODE_DPH
:
1498 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1499 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_X
);
1500 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp1
);
1501 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Y
);
1502 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Y
);
1503 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1504 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1505 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Z
);
1506 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Z
);
1507 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
);
1508 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1509 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_W
);
1510 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1511 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1512 dst0
[chan_index
] = tmp0
;
1516 case TGSI_OPCODE_COS
:
1517 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1518 tmp0
= lp_build_cos( &bld
->base
, tmp0
);
1519 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1520 dst0
[chan_index
] = tmp0
;
1524 case TGSI_OPCODE_DDX
:
1525 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1526 emit_fetch_deriv( bld
, inst
, 0, chan_index
, NULL
, &dst0
[chan_index
], NULL
);
1530 case TGSI_OPCODE_DDY
:
1531 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1532 emit_fetch_deriv( bld
, inst
, 0, chan_index
, NULL
, NULL
, &dst0
[chan_index
]);
1536 case TGSI_OPCODE_KILP
:
1537 /* predicated kill */
1538 emit_kilp( bld
, inst
);
1541 case TGSI_OPCODE_KIL
:
1542 /* conditional kill */
1543 emit_kil( bld
, inst
);
1546 case TGSI_OPCODE_PK2H
:
1550 case TGSI_OPCODE_PK2US
:
1554 case TGSI_OPCODE_PK4B
:
1558 case TGSI_OPCODE_PK4UB
:
1562 case TGSI_OPCODE_RFL
:
1566 case TGSI_OPCODE_SEQ
:
1567 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1568 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1569 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1570 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_EQUAL
, src0
, src1
);
1571 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, bld
->base
.one
, bld
->base
.zero
);
1575 case TGSI_OPCODE_SFL
:
1576 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1577 dst0
[chan_index
] = bld
->base
.zero
;
1581 case TGSI_OPCODE_SGT
:
1582 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1583 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1584 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1585 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_GREATER
, src0
, src1
);
1586 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, bld
->base
.one
, bld
->base
.zero
);
1590 case TGSI_OPCODE_SIN
:
1591 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1592 tmp0
= lp_build_sin( &bld
->base
, tmp0
);
1593 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1594 dst0
[chan_index
] = tmp0
;
1598 case TGSI_OPCODE_SLE
:
1599 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1600 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1601 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1602 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_LEQUAL
, src0
, src1
);
1603 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, bld
->base
.one
, bld
->base
.zero
);
1607 case TGSI_OPCODE_SNE
:
1608 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1609 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1610 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1611 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_NOTEQUAL
, src0
, src1
);
1612 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, bld
->base
.one
, bld
->base
.zero
);
1616 case TGSI_OPCODE_STR
:
1617 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1618 dst0
[chan_index
] = bld
->base
.one
;
1622 case TGSI_OPCODE_TEX
:
1623 emit_tex( bld
, inst
, LP_BLD_TEX_MODIFIER_NONE
, dst0
);
1626 case TGSI_OPCODE_TXD
:
1627 emit_tex( bld
, inst
, LP_BLD_TEX_MODIFIER_EXPLICIT_DERIV
, dst0
);
1630 case TGSI_OPCODE_UP2H
:
1636 case TGSI_OPCODE_UP2US
:
1642 case TGSI_OPCODE_UP4B
:
1648 case TGSI_OPCODE_UP4UB
:
1654 case TGSI_OPCODE_X2D
:
1660 case TGSI_OPCODE_ARA
:
1666 case TGSI_OPCODE_ARR
:
1667 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1668 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1669 tmp0
= lp_build_round(&bld
->base
, tmp0
);
1670 dst0
[chan_index
] = tmp0
;
1674 case TGSI_OPCODE_BRA
:
1680 case TGSI_OPCODE_CAL
:
1681 lp_exec_mask_call(&bld
->exec_mask
,
1687 case TGSI_OPCODE_RET
:
1688 lp_exec_mask_ret(&bld
->exec_mask
, pc
);
1691 case TGSI_OPCODE_END
:
1695 case TGSI_OPCODE_SSG
:
1696 /* TGSI_OPCODE_SGN */
1697 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1698 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1699 dst0
[chan_index
] = lp_build_sgn( &bld
->base
, tmp0
);
1703 case TGSI_OPCODE_CMP
:
1704 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1705 src0
= emit_fetch( bld
, inst
, 0, chan_index
);
1706 src1
= emit_fetch( bld
, inst
, 1, chan_index
);
1707 src2
= emit_fetch( bld
, inst
, 2, chan_index
);
1708 tmp0
= lp_build_cmp( &bld
->base
, PIPE_FUNC_LESS
, src0
, bld
->base
.zero
);
1709 dst0
[chan_index
] = lp_build_select( &bld
->base
, tmp0
, src1
, src2
);
1713 case TGSI_OPCODE_SCS
:
1714 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_X
) {
1715 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1716 dst0
[CHAN_X
] = lp_build_cos( &bld
->base
, tmp0
);
1718 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Y
) {
1719 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
);
1720 dst0
[CHAN_Y
] = lp_build_sin( &bld
->base
, tmp0
);
1722 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_Z
) {
1723 dst0
[CHAN_Z
] = bld
->base
.zero
;
1725 IF_IS_DST0_CHANNEL_ENABLED( inst
, CHAN_W
) {
1726 dst0
[CHAN_W
] = bld
->base
.one
;
1730 case TGSI_OPCODE_TXB
:
1731 emit_tex( bld
, inst
, LP_BLD_TEX_MODIFIER_LOD_BIAS
, dst0
);
1734 case TGSI_OPCODE_NRM
:
1736 case TGSI_OPCODE_NRM4
:
1737 /* 3 or 4-component normalization */
1739 uint dims
= (inst
->Instruction
.Opcode
== TGSI_OPCODE_NRM
) ? 3 : 4;
1741 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_X
) ||
1742 IS_DST0_CHANNEL_ENABLED(inst
, CHAN_Y
) ||
1743 IS_DST0_CHANNEL_ENABLED(inst
, CHAN_Z
) ||
1744 (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_W
) && dims
== 4)) {
1746 /* NOTE: Cannot use xmm regs 2/3 here (see emit_rsqrt() above). */
1749 /* xmm0 = src.x * src.x */
1750 tmp0
= emit_fetch(bld
, inst
, 0, CHAN_X
);
1751 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_X
)) {
1754 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp0
);
1757 /* xmm0 = xmm0 + src.y * src.y */
1758 tmp1
= emit_fetch(bld
, inst
, 0, CHAN_Y
);
1759 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_Y
)) {
1762 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp1
);
1763 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1766 /* xmm0 = xmm0 + src.z * src.z */
1767 tmp1
= emit_fetch(bld
, inst
, 0, CHAN_Z
);
1768 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_Z
)) {
1771 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp1
);
1772 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1776 /* xmm0 = xmm0 + src.w * src.w */
1777 tmp1
= emit_fetch(bld
, inst
, 0, CHAN_W
);
1778 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_W
)) {
1781 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp1
);
1782 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
);
1785 /* xmm1 = 1 / sqrt(xmm0) */
1786 tmp1
= lp_build_rsqrt( &bld
->base
, tmp0
);
1788 /* dst.x = xmm1 * src.x */
1789 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_X
)) {
1790 dst0
[CHAN_X
] = lp_build_mul( &bld
->base
, tmp4
, tmp1
);
1793 /* dst.y = xmm1 * src.y */
1794 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_Y
)) {
1795 dst0
[CHAN_Y
] = lp_build_mul( &bld
->base
, tmp5
, tmp1
);
1798 /* dst.z = xmm1 * src.z */
1799 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_Z
)) {
1800 dst0
[CHAN_Z
] = lp_build_mul( &bld
->base
, tmp6
, tmp1
);
1803 /* dst.w = xmm1 * src.w */
1804 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_X
) && dims
== 4) {
1805 dst0
[CHAN_W
] = lp_build_mul( &bld
->base
, tmp7
, tmp1
);
1810 if (IS_DST0_CHANNEL_ENABLED(inst
, CHAN_W
) && dims
== 3) {
1811 dst0
[CHAN_W
] = bld
->base
.one
;
1816 case TGSI_OPCODE_DIV
:
1822 case TGSI_OPCODE_DP2
:
1823 tmp0
= emit_fetch( bld
, inst
, 0, CHAN_X
); /* xmm0 = src[0].x */
1824 tmp1
= emit_fetch( bld
, inst
, 1, CHAN_X
); /* xmm1 = src[1].x */
1825 tmp0
= lp_build_mul( &bld
->base
, tmp0
, tmp1
); /* xmm0 = xmm0 * xmm1 */
1826 tmp1
= emit_fetch( bld
, inst
, 0, CHAN_Y
); /* xmm1 = src[0].y */
1827 tmp2
= emit_fetch( bld
, inst
, 1, CHAN_Y
); /* xmm2 = src[1].y */
1828 tmp1
= lp_build_mul( &bld
->base
, tmp1
, tmp2
); /* xmm1 = xmm1 * xmm2 */
1829 tmp0
= lp_build_add( &bld
->base
, tmp0
, tmp1
); /* xmm0 = xmm0 + xmm1 */
1830 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1831 dst0
[chan_index
] = tmp0
; /* dest[ch] = xmm0 */
1835 case TGSI_OPCODE_TXL
:
1836 emit_tex( bld
, inst
, LP_BLD_TEX_MODIFIER_EXPLICIT_LOD
, dst0
);
1839 case TGSI_OPCODE_TXP
:
1840 emit_tex( bld
, inst
, LP_BLD_TEX_MODIFIER_PROJECTED
, dst0
);
1843 case TGSI_OPCODE_BRK
:
1844 lp_exec_break(&bld
->exec_mask
);
1847 case TGSI_OPCODE_IF
:
1848 tmp0
= emit_fetch(bld
, inst
, 0, CHAN_X
);
1849 tmp0
= lp_build_cmp(&bld
->base
, PIPE_FUNC_NOTEQUAL
,
1850 tmp0
, bld
->base
.zero
);
1851 lp_exec_mask_cond_push(&bld
->exec_mask
, tmp0
);
1854 case TGSI_OPCODE_BGNLOOP
:
1855 lp_exec_bgnloop(&bld
->exec_mask
);
1858 case TGSI_OPCODE_BGNSUB
:
1859 lp_exec_mask_bgnsub(&bld
->exec_mask
);
1862 case TGSI_OPCODE_ELSE
:
1863 lp_exec_mask_cond_invert(&bld
->exec_mask
);
1866 case TGSI_OPCODE_ENDIF
:
1867 lp_exec_mask_cond_pop(&bld
->exec_mask
);
1870 case TGSI_OPCODE_ENDLOOP
:
1871 lp_exec_endloop(&bld
->exec_mask
);
1874 case TGSI_OPCODE_ENDSUB
:
1875 lp_exec_mask_endsub(&bld
->exec_mask
, pc
);
1878 case TGSI_OPCODE_PUSHA
:
1884 case TGSI_OPCODE_POPA
:
1890 case TGSI_OPCODE_CEIL
:
1891 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1892 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1893 dst0
[chan_index
] = lp_build_ceil(&bld
->base
, tmp0
);
1897 case TGSI_OPCODE_I2F
:
1903 case TGSI_OPCODE_NOT
:
1909 case TGSI_OPCODE_TRUNC
:
1910 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1911 tmp0
= emit_fetch( bld
, inst
, 0, chan_index
);
1912 dst0
[chan_index
] = lp_build_trunc(&bld
->base
, tmp0
);
1916 case TGSI_OPCODE_SHL
:
1922 case TGSI_OPCODE_ISHR
:
1928 case TGSI_OPCODE_AND
:
1934 case TGSI_OPCODE_OR
:
1940 case TGSI_OPCODE_MOD
:
1946 case TGSI_OPCODE_XOR
:
1952 case TGSI_OPCODE_SAD
:
1958 case TGSI_OPCODE_TXF
:
1964 case TGSI_OPCODE_TXQ
:
1970 case TGSI_OPCODE_CONT
:
1971 lp_exec_continue(&bld
->exec_mask
);
1974 case TGSI_OPCODE_EMIT
:
1978 case TGSI_OPCODE_ENDPRIM
:
1982 case TGSI_OPCODE_NOP
:
1990 LLVMValueRef pred
[NUM_CHANNELS
];
1992 emit_fetch_predicate( bld
, inst
, pred
);
1994 FOR_EACH_DST0_ENABLED_CHANNEL( inst
, chan_index
) {
1995 emit_store( bld
, inst
, 0, chan_index
, pred
[chan_index
], dst0
[chan_index
]);
2004 lp_build_tgsi_soa(LLVMBuilderRef builder
,
2005 const struct tgsi_token
*tokens
,
2006 struct lp_type type
,
2007 struct lp_build_mask_context
*mask
,
2008 LLVMValueRef consts_ptr
,
2009 const LLVMValueRef
*pos
,
2010 const LLVMValueRef (*inputs
)[NUM_CHANNELS
],
2011 LLVMValueRef (*outputs
)[NUM_CHANNELS
],
2012 struct lp_build_sampler_soa
*sampler
,
2013 const struct tgsi_shader_info
*info
)
2015 struct lp_build_tgsi_soa_context bld
;
2016 struct tgsi_parse_context parse
;
2017 uint num_immediates
= 0;
2018 uint num_instructions
= 0;
2022 struct lp_type res_type
;
2024 assert(type
.length
<= LP_MAX_VECTOR_LENGTH
);
2025 memset(&res_type
, 0, sizeof res_type
);
2026 res_type
.width
= type
.width
;
2027 res_type
.length
= type
.length
;
2030 /* Setup build context */
2031 memset(&bld
, 0, sizeof bld
);
2032 lp_build_context_init(&bld
.base
, builder
, type
);
2033 lp_build_context_init(&bld
.uint_bld
, builder
, lp_uint_type(type
));
2036 bld
.inputs
= inputs
;
2037 bld
.outputs
= outputs
;
2038 bld
.consts_ptr
= consts_ptr
;
2039 bld
.sampler
= sampler
;
2041 bld
.indirect_files
= info
->indirect_files
;
2042 bld
.instructions
= (struct tgsi_full_instruction
*)
2043 MALLOC( LP_MAX_INSTRUCTIONS
* sizeof(struct tgsi_full_instruction
) );
2044 bld
.max_instructions
= LP_MAX_INSTRUCTIONS
;
2046 if (!bld
.instructions
) {
2050 lp_exec_mask_init(&bld
.exec_mask
, &bld
.base
);
2052 tgsi_parse_init( &parse
, tokens
);
2054 while( !tgsi_parse_end_of_tokens( &parse
) ) {
2055 tgsi_parse_token( &parse
);
2057 switch( parse
.FullToken
.Token
.Type
) {
2058 case TGSI_TOKEN_TYPE_DECLARATION
:
2059 /* Inputs already interpolated */
2060 emit_declaration( &bld
, &parse
.FullToken
.FullDeclaration
);
2063 case TGSI_TOKEN_TYPE_INSTRUCTION
:
2065 /* save expanded instruction */
2066 if (num_instructions
== bld
.max_instructions
) {
2067 struct tgsi_full_instruction
*instructions
;
2068 instructions
= REALLOC(bld
.instructions
,
2069 bld
.max_instructions
2070 * sizeof(struct tgsi_full_instruction
),
2071 (bld
.max_instructions
+ LP_MAX_INSTRUCTIONS
)
2072 * sizeof(struct tgsi_full_instruction
));
2073 if (!instructions
) {
2076 bld
.instructions
= instructions
;
2077 bld
.max_instructions
+= LP_MAX_INSTRUCTIONS
;
2080 memcpy(bld
.instructions
+ num_instructions
,
2081 &parse
.FullToken
.FullInstruction
,
2082 sizeof(bld
.instructions
[0]));
2089 case TGSI_TOKEN_TYPE_IMMEDIATE
:
2090 /* simply copy the immediate values into the next immediates[] slot */
2092 const uint size
= parse
.FullToken
.FullImmediate
.Immediate
.NrTokens
- 1;
2094 assert(num_immediates
< LP_MAX_TGSI_IMMEDIATES
);
2095 for( i
= 0; i
< size
; ++i
)
2096 bld
.immediates
[num_immediates
][i
] =
2097 lp_build_const_vec(type
, parse
.FullToken
.FullImmediate
.u
[i
].Float
);
2098 for( i
= size
; i
< 4; ++i
)
2099 bld
.immediates
[num_immediates
][i
] = bld
.base
.undef
;
2104 case TGSI_TOKEN_TYPE_PROPERTY
:
2113 struct tgsi_full_instruction
*instr
= bld
.instructions
+ pc
;
2114 const struct tgsi_opcode_info
*opcode_info
=
2115 tgsi_get_opcode_info(instr
->Instruction
.Opcode
);
2116 if (!emit_instruction( &bld
, instr
, opcode_info
, &pc
))
2117 _debug_printf("warning: failed to translate tgsi opcode %s to LLVM\n",
2118 opcode_info
->mnemonic
);
2122 LLVMBasicBlockRef block
= LLVMGetInsertBlock(builder
);
2123 LLVMValueRef function
= LLVMGetBasicBlockParent(block
);
2124 debug_printf("11111111111111111111111111111 \n");
2125 tgsi_dump(tokens
, 0);
2126 lp_debug_dump_value(function
);
2127 debug_printf("2222222222222222222222222222 \n");
2129 tgsi_parse_free( &parse
);
2132 LLVMModuleRef module
= LLVMGetGlobalParent(
2133 LLVMGetBasicBlockParent(LLVMGetInsertBlock(bld
.base
.builder
)));
2134 LLVMDumpModule(module
);
2138 FREE( bld
.instructions
);