2 Copyright (C) Intel Corp. 2006. All Rights Reserved.
3 Intel funded Tungsten Graphics to
4 develop this 3D driver.
6 Permission is hereby granted, free of charge, to any person obtaining
7 a copy of this software and associated documentation files (the
8 "Software"), to deal in the Software without restriction, including
9 without limitation the rights to use, copy, modify, merge, publish,
10 distribute, sublicense, and/or sell copies of the Software, and to
11 permit persons to whom the Software is furnished to do so, subject to
12 the following conditions:
14 The above copyright notice and this permission notice (including the
15 next paragraph) shall be included in all copies or substantial
16 portions of the Software.
18 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
19 EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
20 MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
21 IN NO EVENT SHALL THE COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS BE
22 LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
23 OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
24 WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
26 **********************************************************************/
29 * Keith Whitwell <keithw@vmware.com>
33 #include "brw_context.h"
34 #include "brw_defines.h"
37 #include "util/ralloc.h"
40 * Prior to Sandybridge, the SEND instruction accepted non-MRF source
41 * registers, implicitly moving the operand to a message register.
43 * On Sandybridge, this is no longer the case. This function performs the
44 * explicit move; it should be called before emitting a SEND instruction.
47 gen6_resolve_implied_move(struct brw_codegen
*p
,
51 const struct brw_device_info
*devinfo
= p
->devinfo
;
55 if (src
->file
== BRW_MESSAGE_REGISTER_FILE
)
58 if (src
->file
!= BRW_ARCHITECTURE_REGISTER_FILE
|| src
->nr
!= BRW_ARF_NULL
) {
59 brw_push_insn_state(p
);
60 brw_set_default_exec_size(p
, BRW_EXECUTE_8
);
61 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
62 brw_set_default_compression_control(p
, BRW_COMPRESSION_NONE
);
63 brw_MOV(p
, retype(brw_message_reg(msg_reg_nr
), BRW_REGISTER_TYPE_UD
),
64 retype(*src
, BRW_REGISTER_TYPE_UD
));
65 brw_pop_insn_state(p
);
67 *src
= brw_message_reg(msg_reg_nr
);
71 gen7_convert_mrf_to_grf(struct brw_codegen
*p
, struct brw_reg
*reg
)
73 /* From the Ivybridge PRM, Volume 4 Part 3, page 218 ("send"):
74 * "The send with EOT should use register space R112-R127 for <src>. This is
75 * to enable loading of a new thread into the same slot while the message
76 * with EOT for current thread is pending dispatch."
78 * Since we're pretending to have 16 MRFs anyway, we may as well use the
79 * registers required for messages with EOT.
81 const struct brw_device_info
*devinfo
= p
->devinfo
;
82 if (devinfo
->gen
>= 7 && reg
->file
== BRW_MESSAGE_REGISTER_FILE
) {
83 reg
->file
= BRW_GENERAL_REGISTER_FILE
;
84 reg
->nr
+= GEN7_MRF_HACK_START
;
89 * Convert a brw_reg_type enumeration value into the hardware representation.
91 * The hardware encoding may depend on whether the value is an immediate.
94 brw_reg_type_to_hw_type(const struct brw_device_info
*devinfo
,
95 enum brw_reg_type type
, enum brw_reg_file file
)
97 if (file
== BRW_IMMEDIATE_VALUE
) {
98 static const int imm_hw_types
[] = {
99 [BRW_REGISTER_TYPE_UD
] = BRW_HW_REG_TYPE_UD
,
100 [BRW_REGISTER_TYPE_D
] = BRW_HW_REG_TYPE_D
,
101 [BRW_REGISTER_TYPE_UW
] = BRW_HW_REG_TYPE_UW
,
102 [BRW_REGISTER_TYPE_W
] = BRW_HW_REG_TYPE_W
,
103 [BRW_REGISTER_TYPE_F
] = BRW_HW_REG_TYPE_F
,
104 [BRW_REGISTER_TYPE_UB
] = -1,
105 [BRW_REGISTER_TYPE_B
] = -1,
106 [BRW_REGISTER_TYPE_UV
] = BRW_HW_REG_IMM_TYPE_UV
,
107 [BRW_REGISTER_TYPE_VF
] = BRW_HW_REG_IMM_TYPE_VF
,
108 [BRW_REGISTER_TYPE_V
] = BRW_HW_REG_IMM_TYPE_V
,
109 [BRW_REGISTER_TYPE_DF
] = GEN8_HW_REG_IMM_TYPE_DF
,
110 [BRW_REGISTER_TYPE_HF
] = GEN8_HW_REG_IMM_TYPE_HF
,
111 [BRW_REGISTER_TYPE_UQ
] = GEN8_HW_REG_TYPE_UQ
,
112 [BRW_REGISTER_TYPE_Q
] = GEN8_HW_REG_TYPE_Q
,
114 assert(type
< ARRAY_SIZE(imm_hw_types
));
115 assert(imm_hw_types
[type
] != -1);
116 assert(devinfo
->gen
>= 8 || type
< BRW_REGISTER_TYPE_DF
);
117 return imm_hw_types
[type
];
119 /* Non-immediate registers */
120 static const int hw_types
[] = {
121 [BRW_REGISTER_TYPE_UD
] = BRW_HW_REG_TYPE_UD
,
122 [BRW_REGISTER_TYPE_D
] = BRW_HW_REG_TYPE_D
,
123 [BRW_REGISTER_TYPE_UW
] = BRW_HW_REG_TYPE_UW
,
124 [BRW_REGISTER_TYPE_W
] = BRW_HW_REG_TYPE_W
,
125 [BRW_REGISTER_TYPE_UB
] = BRW_HW_REG_NON_IMM_TYPE_UB
,
126 [BRW_REGISTER_TYPE_B
] = BRW_HW_REG_NON_IMM_TYPE_B
,
127 [BRW_REGISTER_TYPE_F
] = BRW_HW_REG_TYPE_F
,
128 [BRW_REGISTER_TYPE_UV
] = -1,
129 [BRW_REGISTER_TYPE_VF
] = -1,
130 [BRW_REGISTER_TYPE_V
] = -1,
131 [BRW_REGISTER_TYPE_DF
] = GEN7_HW_REG_NON_IMM_TYPE_DF
,
132 [BRW_REGISTER_TYPE_HF
] = GEN8_HW_REG_NON_IMM_TYPE_HF
,
133 [BRW_REGISTER_TYPE_UQ
] = GEN8_HW_REG_TYPE_UQ
,
134 [BRW_REGISTER_TYPE_Q
] = GEN8_HW_REG_TYPE_Q
,
136 assert(type
< ARRAY_SIZE(hw_types
));
137 assert(hw_types
[type
] != -1);
138 assert(devinfo
->gen
>= 7 || type
< BRW_REGISTER_TYPE_DF
);
139 assert(devinfo
->gen
>= 8 || type
< BRW_REGISTER_TYPE_HF
);
140 return hw_types
[type
];
145 brw_set_dest(struct brw_codegen
*p
, brw_inst
*inst
, struct brw_reg dest
)
147 const struct brw_device_info
*devinfo
= p
->devinfo
;
149 if (dest
.file
== BRW_MESSAGE_REGISTER_FILE
)
150 assert((dest
.nr
& ~BRW_MRF_COMPR4
) < BRW_MAX_MRF(devinfo
->gen
));
151 else if (dest
.file
!= BRW_ARCHITECTURE_REGISTER_FILE
)
152 assert(dest
.nr
< 128);
154 gen7_convert_mrf_to_grf(p
, &dest
);
156 brw_inst_set_dst_reg_file(devinfo
, inst
, dest
.file
);
157 brw_inst_set_dst_reg_type(devinfo
, inst
,
158 brw_reg_type_to_hw_type(devinfo
, dest
.type
,
160 brw_inst_set_dst_address_mode(devinfo
, inst
, dest
.address_mode
);
162 if (dest
.address_mode
== BRW_ADDRESS_DIRECT
) {
163 brw_inst_set_dst_da_reg_nr(devinfo
, inst
, dest
.nr
);
165 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
166 brw_inst_set_dst_da1_subreg_nr(devinfo
, inst
, dest
.subnr
);
167 if (dest
.hstride
== BRW_HORIZONTAL_STRIDE_0
)
168 dest
.hstride
= BRW_HORIZONTAL_STRIDE_1
;
169 brw_inst_set_dst_hstride(devinfo
, inst
, dest
.hstride
);
171 brw_inst_set_dst_da16_subreg_nr(devinfo
, inst
, dest
.subnr
/ 16);
172 brw_inst_set_da16_writemask(devinfo
, inst
, dest
.writemask
);
173 if (dest
.file
== BRW_GENERAL_REGISTER_FILE
||
174 dest
.file
== BRW_MESSAGE_REGISTER_FILE
) {
175 assert(dest
.writemask
!= 0);
177 /* From the Ivybridge PRM, Vol 4, Part 3, Section 5.2.4.1:
178 * Although Dst.HorzStride is a don't care for Align16, HW needs
179 * this to be programmed as "01".
181 brw_inst_set_dst_hstride(devinfo
, inst
, 1);
184 brw_inst_set_dst_ia_subreg_nr(devinfo
, inst
, dest
.subnr
);
186 /* These are different sizes in align1 vs align16:
188 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
189 brw_inst_set_dst_ia1_addr_imm(devinfo
, inst
,
190 dest
.indirect_offset
);
191 if (dest
.hstride
== BRW_HORIZONTAL_STRIDE_0
)
192 dest
.hstride
= BRW_HORIZONTAL_STRIDE_1
;
193 brw_inst_set_dst_hstride(devinfo
, inst
, dest
.hstride
);
195 brw_inst_set_dst_ia16_addr_imm(devinfo
, inst
,
196 dest
.indirect_offset
);
197 /* even ignored in da16, still need to set as '01' */
198 brw_inst_set_dst_hstride(devinfo
, inst
, 1);
202 /* Generators should set a default exec_size of either 8 (SIMD4x2 or SIMD8)
203 * or 16 (SIMD16), as that's normally correct. However, when dealing with
204 * small registers, we automatically reduce it to match the register size.
206 * In platforms that support fp64 we can emit instructions with a width of
207 * 4 that need two SIMD8 registers and an exec_size of 8 or 16. In these
208 * cases we need to make sure that these instructions have their exec sizes
209 * set properly when they are emitted and we can't rely on this code to fix
213 if (devinfo
->gen
>= 6)
214 fix_exec_size
= dest
.width
< BRW_EXECUTE_4
;
216 fix_exec_size
= dest
.width
< BRW_EXECUTE_8
;
219 brw_inst_set_exec_size(devinfo
, inst
, dest
.width
);
222 extern int reg_type_size
[];
225 validate_reg(const struct brw_device_info
*devinfo
,
226 brw_inst
*inst
, struct brw_reg reg
)
228 const int hstride_for_reg
[] = {0, 1, 2, 4};
229 const int vstride_for_reg
[] = {0, 1, 2, 4, 8, 16, 32};
230 const int width_for_reg
[] = {1, 2, 4, 8, 16};
231 const int execsize_for_reg
[] = {1, 2, 4, 8, 16, 32};
232 int width
, hstride
, vstride
, execsize
;
234 if (reg
.file
== BRW_IMMEDIATE_VALUE
) {
235 /* 3.3.6: Region Parameters. Restriction: Immediate vectors
236 * mean the destination has to be 128-bit aligned and the
237 * destination horiz stride has to be a word.
239 if (reg
.type
== BRW_REGISTER_TYPE_V
) {
240 assert(hstride_for_reg
[brw_inst_dst_hstride(devinfo
, inst
)] *
241 reg_type_size
[brw_inst_dst_reg_type(devinfo
, inst
)] == 2);
247 if (reg
.file
== BRW_ARCHITECTURE_REGISTER_FILE
&&
248 reg
.file
== BRW_ARF_NULL
)
251 /* From the IVB PRM Vol. 4, Pt. 3, Section 3.3.3.5:
253 * "Swizzling is not allowed when an accumulator is used as an implicit
254 * source or an explicit source in an instruction."
256 if (reg
.file
== BRW_ARCHITECTURE_REGISTER_FILE
&&
257 reg
.nr
== BRW_ARF_ACCUMULATOR
)
258 assert(reg
.swizzle
== BRW_SWIZZLE_XYZW
);
260 assert(reg
.hstride
>= 0 && reg
.hstride
< ARRAY_SIZE(hstride_for_reg
));
261 hstride
= hstride_for_reg
[reg
.hstride
];
263 if (reg
.vstride
== 0xf) {
266 assert(reg
.vstride
>= 0 && reg
.vstride
< ARRAY_SIZE(vstride_for_reg
));
267 vstride
= vstride_for_reg
[reg
.vstride
];
270 assert(reg
.width
>= 0 && reg
.width
< ARRAY_SIZE(width_for_reg
));
271 width
= width_for_reg
[reg
.width
];
273 assert(brw_inst_exec_size(devinfo
, inst
) >= 0 &&
274 brw_inst_exec_size(devinfo
, inst
) < ARRAY_SIZE(execsize_for_reg
));
275 execsize
= execsize_for_reg
[brw_inst_exec_size(devinfo
, inst
)];
277 /* Restrictions from 3.3.10: Register Region Restrictions. */
279 assert(execsize
>= width
);
282 if (execsize
== width
&& hstride
!= 0) {
283 assert(vstride
== -1 || vstride
== width
* hstride
);
287 if (execsize
== width
&& hstride
== 0) {
288 /* no restriction on vstride. */
293 assert(hstride
== 0);
297 if (execsize
== 1 && width
== 1) {
298 assert(hstride
== 0);
299 assert(vstride
== 0);
303 if (vstride
== 0 && hstride
== 0) {
307 /* 10. Check destination issues. */
311 is_compactable_immediate(unsigned imm
)
313 /* We get the low 12 bits as-is. */
316 /* We get one bit replicated through the top 20 bits. */
317 return imm
== 0 || imm
== 0xfffff000;
321 brw_set_src0(struct brw_codegen
*p
, brw_inst
*inst
, struct brw_reg reg
)
323 const struct brw_device_info
*devinfo
= p
->devinfo
;
325 if (reg
.file
== BRW_MESSAGE_REGISTER_FILE
)
326 assert((reg
.nr
& ~BRW_MRF_COMPR4
) < BRW_MAX_MRF(devinfo
->gen
));
327 else if (reg
.file
!= BRW_ARCHITECTURE_REGISTER_FILE
)
328 assert(reg
.nr
< 128);
330 gen7_convert_mrf_to_grf(p
, ®
);
332 if (devinfo
->gen
>= 6 && (brw_inst_opcode(devinfo
, inst
) == BRW_OPCODE_SEND
||
333 brw_inst_opcode(devinfo
, inst
) == BRW_OPCODE_SENDC
)) {
334 /* Any source modifiers or regions will be ignored, since this just
335 * identifies the MRF/GRF to start reading the message contents from.
336 * Check for some likely failures.
340 assert(reg
.address_mode
== BRW_ADDRESS_DIRECT
);
343 validate_reg(devinfo
, inst
, reg
);
345 brw_inst_set_src0_reg_file(devinfo
, inst
, reg
.file
);
346 brw_inst_set_src0_reg_type(devinfo
, inst
,
347 brw_reg_type_to_hw_type(devinfo
, reg
.type
, reg
.file
));
348 brw_inst_set_src0_abs(devinfo
, inst
, reg
.abs
);
349 brw_inst_set_src0_negate(devinfo
, inst
, reg
.negate
);
350 brw_inst_set_src0_address_mode(devinfo
, inst
, reg
.address_mode
);
352 if (reg
.file
== BRW_IMMEDIATE_VALUE
) {
353 if (reg
.type
== BRW_REGISTER_TYPE_DF
)
354 brw_inst_set_imm_df(devinfo
, inst
, reg
.df
);
356 brw_inst_set_imm_ud(devinfo
, inst
, reg
.ud
);
358 /* The Bspec's section titled "Non-present Operands" claims that if src0
359 * is an immediate that src1's type must be the same as that of src0.
361 * The SNB+ DataTypeIndex instruction compaction tables contain mappings
362 * that do not follow this rule. E.g., from the IVB/HSW table:
364 * DataTypeIndex 18-Bit Mapping Mapped Meaning
365 * 3 001000001011111101 r:f | i:vf | a:ud | <1> | dir |
367 * And from the SNB table:
369 * DataTypeIndex 18-Bit Mapping Mapped Meaning
370 * 8 001000000111101100 a:w | i:w | a:ud | <1> | dir |
372 * Neither of these cause warnings from the simulator when used,
373 * compacted or otherwise. In fact, all compaction mappings that have an
374 * immediate in src0 use a:ud for src1.
376 * The GM45 instruction compaction tables do not contain mapped meanings
377 * so it's not clear whether it has the restriction. We'll assume it was
378 * lifted on SNB. (FINISHME: decode the GM45 tables and check.)
380 * Don't do any of this for 64-bit immediates, since the src1 fields
381 * overlap with the immediate and setting them would overwrite the
384 if (type_sz(reg
.type
) < 8) {
385 brw_inst_set_src1_reg_file(devinfo
, inst
,
386 BRW_ARCHITECTURE_REGISTER_FILE
);
387 if (devinfo
->gen
< 6) {
388 brw_inst_set_src1_reg_type(devinfo
, inst
,
389 brw_inst_src0_reg_type(devinfo
, inst
));
391 brw_inst_set_src1_reg_type(devinfo
, inst
, BRW_HW_REG_TYPE_UD
);
395 /* Compacted instructions only have 12-bits (plus 1 for the other 20)
396 * for immediate values. Presumably the hardware engineers realized
397 * that the only useful floating-point value that could be represented
398 * in this format is 0.0, which can also be represented as a VF-typed
399 * immediate, so they gave us the previously mentioned mapping on IVB+.
401 * Strangely, we do have a mapping for imm:f in src1, so we don't need
404 * If we see a 0.0:F, change the type to VF so that it can be compacted.
406 if (brw_inst_imm_ud(devinfo
, inst
) == 0x0 &&
407 brw_inst_src0_reg_type(devinfo
, inst
) == BRW_HW_REG_TYPE_F
) {
408 brw_inst_set_src0_reg_type(devinfo
, inst
, BRW_HW_REG_IMM_TYPE_VF
);
411 /* There are no mappings for dst:d | i:d, so if the immediate is suitable
412 * set the types to :UD so the instruction can be compacted.
414 if (is_compactable_immediate(brw_inst_imm_ud(devinfo
, inst
)) &&
415 brw_inst_cond_modifier(devinfo
, inst
) == BRW_CONDITIONAL_NONE
&&
416 brw_inst_src0_reg_type(devinfo
, inst
) == BRW_HW_REG_TYPE_D
&&
417 brw_inst_dst_reg_type(devinfo
, inst
) == BRW_HW_REG_TYPE_D
) {
418 brw_inst_set_src0_reg_type(devinfo
, inst
, BRW_HW_REG_TYPE_UD
);
419 brw_inst_set_dst_reg_type(devinfo
, inst
, BRW_HW_REG_TYPE_UD
);
422 if (reg
.address_mode
== BRW_ADDRESS_DIRECT
) {
423 brw_inst_set_src0_da_reg_nr(devinfo
, inst
, reg
.nr
);
424 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
425 brw_inst_set_src0_da1_subreg_nr(devinfo
, inst
, reg
.subnr
);
427 brw_inst_set_src0_da16_subreg_nr(devinfo
, inst
, reg
.subnr
/ 16);
430 brw_inst_set_src0_ia_subreg_nr(devinfo
, inst
, reg
.subnr
);
432 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
433 brw_inst_set_src0_ia1_addr_imm(devinfo
, inst
, reg
.indirect_offset
);
435 brw_inst_set_src0_ia16_addr_imm(devinfo
, inst
, reg
.indirect_offset
);
439 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
440 if (reg
.width
== BRW_WIDTH_1
&&
441 brw_inst_exec_size(devinfo
, inst
) == BRW_EXECUTE_1
) {
442 brw_inst_set_src0_hstride(devinfo
, inst
, BRW_HORIZONTAL_STRIDE_0
);
443 brw_inst_set_src0_width(devinfo
, inst
, BRW_WIDTH_1
);
444 brw_inst_set_src0_vstride(devinfo
, inst
, BRW_VERTICAL_STRIDE_0
);
446 brw_inst_set_src0_hstride(devinfo
, inst
, reg
.hstride
);
447 brw_inst_set_src0_width(devinfo
, inst
, reg
.width
);
448 brw_inst_set_src0_vstride(devinfo
, inst
, reg
.vstride
);
451 brw_inst_set_src0_da16_swiz_x(devinfo
, inst
,
452 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_X
));
453 brw_inst_set_src0_da16_swiz_y(devinfo
, inst
,
454 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_Y
));
455 brw_inst_set_src0_da16_swiz_z(devinfo
, inst
,
456 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_Z
));
457 brw_inst_set_src0_da16_swiz_w(devinfo
, inst
,
458 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_W
));
460 /* This is an oddity of the fact we're using the same
461 * descriptions for registers in align_16 as align_1:
463 if (reg
.vstride
== BRW_VERTICAL_STRIDE_8
)
464 brw_inst_set_src0_vstride(devinfo
, inst
, BRW_VERTICAL_STRIDE_4
);
466 brw_inst_set_src0_vstride(devinfo
, inst
, reg
.vstride
);
473 brw_set_src1(struct brw_codegen
*p
, brw_inst
*inst
, struct brw_reg reg
)
475 const struct brw_device_info
*devinfo
= p
->devinfo
;
477 if (reg
.file
!= BRW_ARCHITECTURE_REGISTER_FILE
)
478 assert(reg
.nr
< 128);
480 /* From the IVB PRM Vol. 4, Pt. 3, Section 3.3.3.5:
482 * "Accumulator registers may be accessed explicitly as src0
485 assert(reg
.file
!= BRW_ARCHITECTURE_REGISTER_FILE
||
486 reg
.nr
!= BRW_ARF_ACCUMULATOR
);
488 gen7_convert_mrf_to_grf(p
, ®
);
489 assert(reg
.file
!= BRW_MESSAGE_REGISTER_FILE
);
491 validate_reg(devinfo
, inst
, reg
);
493 brw_inst_set_src1_reg_file(devinfo
, inst
, reg
.file
);
494 brw_inst_set_src1_reg_type(devinfo
, inst
,
495 brw_reg_type_to_hw_type(devinfo
, reg
.type
, reg
.file
));
496 brw_inst_set_src1_abs(devinfo
, inst
, reg
.abs
);
497 brw_inst_set_src1_negate(devinfo
, inst
, reg
.negate
);
499 /* Only src1 can be immediate in two-argument instructions.
501 assert(brw_inst_src0_reg_file(devinfo
, inst
) != BRW_IMMEDIATE_VALUE
);
503 if (reg
.file
== BRW_IMMEDIATE_VALUE
) {
504 /* two-argument instructions can only use 32-bit immediates */
505 assert(type_sz(reg
.type
) < 8);
506 brw_inst_set_imm_ud(devinfo
, inst
, reg
.ud
);
508 /* This is a hardware restriction, which may or may not be lifted
511 assert (reg
.address_mode
== BRW_ADDRESS_DIRECT
);
512 /* assert (reg.file == BRW_GENERAL_REGISTER_FILE); */
514 brw_inst_set_src1_da_reg_nr(devinfo
, inst
, reg
.nr
);
515 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
516 brw_inst_set_src1_da1_subreg_nr(devinfo
, inst
, reg
.subnr
);
518 brw_inst_set_src1_da16_subreg_nr(devinfo
, inst
, reg
.subnr
/ 16);
521 if (brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_1
) {
522 if (reg
.width
== BRW_WIDTH_1
&&
523 brw_inst_exec_size(devinfo
, inst
) == BRW_EXECUTE_1
) {
524 brw_inst_set_src1_hstride(devinfo
, inst
, BRW_HORIZONTAL_STRIDE_0
);
525 brw_inst_set_src1_width(devinfo
, inst
, BRW_WIDTH_1
);
526 brw_inst_set_src1_vstride(devinfo
, inst
, BRW_VERTICAL_STRIDE_0
);
528 brw_inst_set_src1_hstride(devinfo
, inst
, reg
.hstride
);
529 brw_inst_set_src1_width(devinfo
, inst
, reg
.width
);
530 brw_inst_set_src1_vstride(devinfo
, inst
, reg
.vstride
);
533 brw_inst_set_src1_da16_swiz_x(devinfo
, inst
,
534 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_X
));
535 brw_inst_set_src1_da16_swiz_y(devinfo
, inst
,
536 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_Y
));
537 brw_inst_set_src1_da16_swiz_z(devinfo
, inst
,
538 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_Z
));
539 brw_inst_set_src1_da16_swiz_w(devinfo
, inst
,
540 BRW_GET_SWZ(reg
.swizzle
, BRW_CHANNEL_W
));
542 /* This is an oddity of the fact we're using the same
543 * descriptions for registers in align_16 as align_1:
545 if (reg
.vstride
== BRW_VERTICAL_STRIDE_8
)
546 brw_inst_set_src1_vstride(devinfo
, inst
, BRW_VERTICAL_STRIDE_4
);
548 brw_inst_set_src1_vstride(devinfo
, inst
, reg
.vstride
);
554 * Set the Message Descriptor and Extended Message Descriptor fields
557 * \note This zeroes out the Function Control bits, so it must be called
558 * \b before filling out any message-specific data. Callers can
559 * choose not to fill in irrelevant bits; they will be zero.
562 brw_set_message_descriptor(struct brw_codegen
*p
,
564 enum brw_message_target sfid
,
566 unsigned response_length
,
570 const struct brw_device_info
*devinfo
= p
->devinfo
;
572 brw_set_src1(p
, inst
, brw_imm_d(0));
574 /* For indirect sends, `inst` will not be the SEND/SENDC instruction
575 * itself; instead, it will be a MOV/OR into the address register.
577 * In this case, we avoid setting the extended message descriptor bits,
578 * since they go on the later SEND/SENDC instead and if set here would
579 * instead clobber the conditionalmod bits.
581 unsigned opcode
= brw_inst_opcode(devinfo
, inst
);
582 if (opcode
== BRW_OPCODE_SEND
|| opcode
== BRW_OPCODE_SENDC
) {
583 brw_inst_set_sfid(devinfo
, inst
, sfid
);
586 brw_inst_set_mlen(devinfo
, inst
, msg_length
);
587 brw_inst_set_rlen(devinfo
, inst
, response_length
);
588 brw_inst_set_eot(devinfo
, inst
, end_of_thread
);
590 if (devinfo
->gen
>= 5) {
591 brw_inst_set_header_present(devinfo
, inst
, header_present
);
595 static void brw_set_math_message( struct brw_codegen
*p
,
598 unsigned integer_type
,
602 const struct brw_device_info
*devinfo
= p
->devinfo
;
604 unsigned response_length
;
606 /* Infer message length from the function */
608 case BRW_MATH_FUNCTION_POW
:
609 case BRW_MATH_FUNCTION_INT_DIV_QUOTIENT
:
610 case BRW_MATH_FUNCTION_INT_DIV_REMAINDER
:
611 case BRW_MATH_FUNCTION_INT_DIV_QUOTIENT_AND_REMAINDER
:
619 /* Infer response length from the function */
621 case BRW_MATH_FUNCTION_SINCOS
:
622 case BRW_MATH_FUNCTION_INT_DIV_QUOTIENT_AND_REMAINDER
:
631 brw_set_message_descriptor(p
, inst
, BRW_SFID_MATH
,
632 msg_length
, response_length
, false, false);
633 brw_inst_set_math_msg_function(devinfo
, inst
, function
);
634 brw_inst_set_math_msg_signed_int(devinfo
, inst
, integer_type
);
635 brw_inst_set_math_msg_precision(devinfo
, inst
, low_precision
);
636 brw_inst_set_math_msg_saturate(devinfo
, inst
, brw_inst_saturate(devinfo
, inst
));
637 brw_inst_set_math_msg_data_type(devinfo
, inst
, dataType
);
638 brw_inst_set_saturate(devinfo
, inst
, 0);
642 static void brw_set_ff_sync_message(struct brw_codegen
*p
,
645 unsigned response_length
,
648 const struct brw_device_info
*devinfo
= p
->devinfo
;
650 brw_set_message_descriptor(p
, insn
, BRW_SFID_URB
,
651 1, response_length
, true, end_of_thread
);
652 brw_inst_set_urb_opcode(devinfo
, insn
, 1); /* FF_SYNC */
653 brw_inst_set_urb_allocate(devinfo
, insn
, allocate
);
654 /* The following fields are not used by FF_SYNC: */
655 brw_inst_set_urb_global_offset(devinfo
, insn
, 0);
656 brw_inst_set_urb_swizzle_control(devinfo
, insn
, 0);
657 brw_inst_set_urb_used(devinfo
, insn
, 0);
658 brw_inst_set_urb_complete(devinfo
, insn
, 0);
661 static void brw_set_urb_message( struct brw_codegen
*p
,
663 enum brw_urb_write_flags flags
,
665 unsigned response_length
,
667 unsigned swizzle_control
)
669 const struct brw_device_info
*devinfo
= p
->devinfo
;
671 assert(devinfo
->gen
< 7 || swizzle_control
!= BRW_URB_SWIZZLE_TRANSPOSE
);
672 assert(devinfo
->gen
< 7 || !(flags
& BRW_URB_WRITE_ALLOCATE
));
673 assert(devinfo
->gen
>= 7 || !(flags
& BRW_URB_WRITE_PER_SLOT_OFFSET
));
675 brw_set_message_descriptor(p
, insn
, BRW_SFID_URB
,
676 msg_length
, response_length
, true,
677 flags
& BRW_URB_WRITE_EOT
);
679 if (flags
& BRW_URB_WRITE_OWORD
) {
680 assert(msg_length
== 2); /* header + one OWORD of data */
681 brw_inst_set_urb_opcode(devinfo
, insn
, BRW_URB_OPCODE_WRITE_OWORD
);
683 brw_inst_set_urb_opcode(devinfo
, insn
, BRW_URB_OPCODE_WRITE_HWORD
);
686 brw_inst_set_urb_global_offset(devinfo
, insn
, offset
);
687 brw_inst_set_urb_swizzle_control(devinfo
, insn
, swizzle_control
);
689 if (devinfo
->gen
< 8) {
690 brw_inst_set_urb_complete(devinfo
, insn
, !!(flags
& BRW_URB_WRITE_COMPLETE
));
693 if (devinfo
->gen
< 7) {
694 brw_inst_set_urb_allocate(devinfo
, insn
, !!(flags
& BRW_URB_WRITE_ALLOCATE
));
695 brw_inst_set_urb_used(devinfo
, insn
, !(flags
& BRW_URB_WRITE_UNUSED
));
697 brw_inst_set_urb_per_slot_offset(devinfo
, insn
,
698 !!(flags
& BRW_URB_WRITE_PER_SLOT_OFFSET
));
703 brw_set_dp_write_message(struct brw_codegen
*p
,
705 unsigned binding_table_index
,
706 unsigned msg_control
,
710 unsigned last_render_target
,
711 unsigned response_length
,
712 unsigned end_of_thread
,
713 unsigned send_commit_msg
)
715 const struct brw_device_info
*devinfo
= p
->devinfo
;
718 if (devinfo
->gen
>= 7) {
719 /* Use the Render Cache for RT writes; otherwise use the Data Cache */
720 if (msg_type
== GEN6_DATAPORT_WRITE_MESSAGE_RENDER_TARGET_WRITE
)
721 sfid
= GEN6_SFID_DATAPORT_RENDER_CACHE
;
723 sfid
= GEN7_SFID_DATAPORT_DATA_CACHE
;
724 } else if (devinfo
->gen
== 6) {
725 /* Use the render cache for all write messages. */
726 sfid
= GEN6_SFID_DATAPORT_RENDER_CACHE
;
728 sfid
= BRW_SFID_DATAPORT_WRITE
;
731 brw_set_message_descriptor(p
, insn
, sfid
, msg_length
, response_length
,
732 header_present
, end_of_thread
);
734 brw_inst_set_binding_table_index(devinfo
, insn
, binding_table_index
);
735 brw_inst_set_dp_write_msg_type(devinfo
, insn
, msg_type
);
736 brw_inst_set_dp_write_msg_control(devinfo
, insn
, msg_control
);
737 brw_inst_set_rt_last(devinfo
, insn
, last_render_target
);
738 if (devinfo
->gen
< 7) {
739 brw_inst_set_dp_write_commit(devinfo
, insn
, send_commit_msg
);
744 brw_set_dp_read_message(struct brw_codegen
*p
,
746 unsigned binding_table_index
,
747 unsigned msg_control
,
749 unsigned target_cache
,
752 unsigned response_length
)
754 const struct brw_device_info
*devinfo
= p
->devinfo
;
757 if (devinfo
->gen
>= 7) {
758 sfid
= GEN7_SFID_DATAPORT_DATA_CACHE
;
759 } else if (devinfo
->gen
== 6) {
760 if (target_cache
== BRW_DATAPORT_READ_TARGET_RENDER_CACHE
)
761 sfid
= GEN6_SFID_DATAPORT_RENDER_CACHE
;
763 sfid
= GEN6_SFID_DATAPORT_SAMPLER_CACHE
;
765 sfid
= BRW_SFID_DATAPORT_READ
;
768 brw_set_message_descriptor(p
, insn
, sfid
, msg_length
, response_length
,
769 header_present
, false);
771 brw_inst_set_binding_table_index(devinfo
, insn
, binding_table_index
);
772 brw_inst_set_dp_read_msg_type(devinfo
, insn
, msg_type
);
773 brw_inst_set_dp_read_msg_control(devinfo
, insn
, msg_control
);
774 if (devinfo
->gen
< 6)
775 brw_inst_set_dp_read_target_cache(devinfo
, insn
, target_cache
);
779 brw_set_sampler_message(struct brw_codegen
*p
,
781 unsigned binding_table_index
,
784 unsigned response_length
,
786 unsigned header_present
,
788 unsigned return_format
)
790 const struct brw_device_info
*devinfo
= p
->devinfo
;
792 brw_set_message_descriptor(p
, inst
, BRW_SFID_SAMPLER
, msg_length
,
793 response_length
, header_present
, false);
795 brw_inst_set_binding_table_index(devinfo
, inst
, binding_table_index
);
796 brw_inst_set_sampler(devinfo
, inst
, sampler
);
797 brw_inst_set_sampler_msg_type(devinfo
, inst
, msg_type
);
798 if (devinfo
->gen
>= 5) {
799 brw_inst_set_sampler_simd_mode(devinfo
, inst
, simd_mode
);
800 } else if (devinfo
->gen
== 4 && !devinfo
->is_g4x
) {
801 brw_inst_set_sampler_return_format(devinfo
, inst
, return_format
);
806 gen7_set_dp_scratch_message(struct brw_codegen
*p
,
810 bool invalidate_after_read
,
812 unsigned addr_offset
,
817 const struct brw_device_info
*devinfo
= p
->devinfo
;
818 assert(num_regs
== 1 || num_regs
== 2 || num_regs
== 4 ||
819 (devinfo
->gen
>= 8 && num_regs
== 8));
820 const unsigned block_size
= (devinfo
->gen
>= 8 ? _mesa_logbase2(num_regs
) :
823 brw_set_message_descriptor(p
, inst
, GEN7_SFID_DATAPORT_DATA_CACHE
,
824 mlen
, rlen
, header_present
, false);
825 brw_inst_set_dp_category(devinfo
, inst
, 1); /* Scratch Block Read/Write msgs */
826 brw_inst_set_scratch_read_write(devinfo
, inst
, write
);
827 brw_inst_set_scratch_type(devinfo
, inst
, dword
);
828 brw_inst_set_scratch_invalidate_after_read(devinfo
, inst
, invalidate_after_read
);
829 brw_inst_set_scratch_block_size(devinfo
, inst
, block_size
);
830 brw_inst_set_scratch_addr_offset(devinfo
, inst
, addr_offset
);
833 #define next_insn brw_next_insn
835 brw_next_insn(struct brw_codegen
*p
, unsigned opcode
)
837 const struct brw_device_info
*devinfo
= p
->devinfo
;
840 if (p
->nr_insn
+ 1 > p
->store_size
) {
842 p
->store
= reralloc(p
->mem_ctx
, p
->store
, brw_inst
, p
->store_size
);
845 p
->next_insn_offset
+= 16;
846 insn
= &p
->store
[p
->nr_insn
++];
847 memcpy(insn
, p
->current
, sizeof(*insn
));
849 brw_inst_set_opcode(devinfo
, insn
, opcode
);
854 brw_alu1(struct brw_codegen
*p
, unsigned opcode
,
855 struct brw_reg dest
, struct brw_reg src
)
857 brw_inst
*insn
= next_insn(p
, opcode
);
858 brw_set_dest(p
, insn
, dest
);
859 brw_set_src0(p
, insn
, src
);
864 brw_alu2(struct brw_codegen
*p
, unsigned opcode
,
865 struct brw_reg dest
, struct brw_reg src0
, struct brw_reg src1
)
867 /* 64-bit immediates are only supported on 1-src instructions */
868 assert(src0
.file
!= BRW_IMMEDIATE_VALUE
|| type_sz(src0
.type
) <= 4);
869 assert(src1
.file
!= BRW_IMMEDIATE_VALUE
|| type_sz(src1
.type
) <= 4);
871 brw_inst
*insn
= next_insn(p
, opcode
);
872 brw_set_dest(p
, insn
, dest
);
873 brw_set_src0(p
, insn
, src0
);
874 brw_set_src1(p
, insn
, src1
);
879 get_3src_subreg_nr(struct brw_reg reg
)
881 /* Normally, SubRegNum is in bytes (0..31). However, 3-src instructions
882 * use 32-bit units (components 0..7). Since they only support F/D/UD
883 * types, this doesn't lose any flexibility, but uses fewer bits.
885 return reg
.subnr
/ 4;
889 brw_alu3(struct brw_codegen
*p
, unsigned opcode
, struct brw_reg dest
,
890 struct brw_reg src0
, struct brw_reg src1
, struct brw_reg src2
)
892 const struct brw_device_info
*devinfo
= p
->devinfo
;
893 brw_inst
*inst
= next_insn(p
, opcode
);
895 gen7_convert_mrf_to_grf(p
, &dest
);
897 assert(brw_inst_access_mode(devinfo
, inst
) == BRW_ALIGN_16
);
899 assert(dest
.file
== BRW_GENERAL_REGISTER_FILE
||
900 dest
.file
== BRW_MESSAGE_REGISTER_FILE
);
901 assert(dest
.nr
< 128);
902 assert(dest
.address_mode
== BRW_ADDRESS_DIRECT
);
903 assert(dest
.type
== BRW_REGISTER_TYPE_F
||
904 dest
.type
== BRW_REGISTER_TYPE_DF
||
905 dest
.type
== BRW_REGISTER_TYPE_D
||
906 dest
.type
== BRW_REGISTER_TYPE_UD
);
907 if (devinfo
->gen
== 6) {
908 brw_inst_set_3src_dst_reg_file(devinfo
, inst
,
909 dest
.file
== BRW_MESSAGE_REGISTER_FILE
);
911 brw_inst_set_3src_dst_reg_nr(devinfo
, inst
, dest
.nr
);
912 brw_inst_set_3src_dst_subreg_nr(devinfo
, inst
, dest
.subnr
/ 16);
913 brw_inst_set_3src_dst_writemask(devinfo
, inst
, dest
.writemask
);
915 assert(src0
.file
== BRW_GENERAL_REGISTER_FILE
);
916 assert(src0
.address_mode
== BRW_ADDRESS_DIRECT
);
917 assert(src0
.nr
< 128);
918 brw_inst_set_3src_src0_swizzle(devinfo
, inst
, src0
.swizzle
);
919 brw_inst_set_3src_src0_subreg_nr(devinfo
, inst
, get_3src_subreg_nr(src0
));
920 brw_inst_set_3src_src0_reg_nr(devinfo
, inst
, src0
.nr
);
921 brw_inst_set_3src_src0_abs(devinfo
, inst
, src0
.abs
);
922 brw_inst_set_3src_src0_negate(devinfo
, inst
, src0
.negate
);
923 brw_inst_set_3src_src0_rep_ctrl(devinfo
, inst
,
924 src0
.vstride
== BRW_VERTICAL_STRIDE_0
);
926 assert(src1
.file
== BRW_GENERAL_REGISTER_FILE
);
927 assert(src1
.address_mode
== BRW_ADDRESS_DIRECT
);
928 assert(src1
.nr
< 128);
929 brw_inst_set_3src_src1_swizzle(devinfo
, inst
, src1
.swizzle
);
930 brw_inst_set_3src_src1_subreg_nr(devinfo
, inst
, get_3src_subreg_nr(src1
));
931 brw_inst_set_3src_src1_reg_nr(devinfo
, inst
, src1
.nr
);
932 brw_inst_set_3src_src1_abs(devinfo
, inst
, src1
.abs
);
933 brw_inst_set_3src_src1_negate(devinfo
, inst
, src1
.negate
);
934 brw_inst_set_3src_src1_rep_ctrl(devinfo
, inst
,
935 src1
.vstride
== BRW_VERTICAL_STRIDE_0
);
937 assert(src2
.file
== BRW_GENERAL_REGISTER_FILE
);
938 assert(src2
.address_mode
== BRW_ADDRESS_DIRECT
);
939 assert(src2
.nr
< 128);
940 brw_inst_set_3src_src2_swizzle(devinfo
, inst
, src2
.swizzle
);
941 brw_inst_set_3src_src2_subreg_nr(devinfo
, inst
, get_3src_subreg_nr(src2
));
942 brw_inst_set_3src_src2_reg_nr(devinfo
, inst
, src2
.nr
);
943 brw_inst_set_3src_src2_abs(devinfo
, inst
, src2
.abs
);
944 brw_inst_set_3src_src2_negate(devinfo
, inst
, src2
.negate
);
945 brw_inst_set_3src_src2_rep_ctrl(devinfo
, inst
,
946 src2
.vstride
== BRW_VERTICAL_STRIDE_0
);
948 if (devinfo
->gen
>= 7) {
949 /* Set both the source and destination types based on dest.type,
950 * ignoring the source register types. The MAD and LRP emitters ensure
951 * that all four types are float. The BFE and BFI2 emitters, however,
952 * may send us mixed D and UD types and want us to ignore that and use
953 * the destination type.
956 case BRW_REGISTER_TYPE_F
:
957 brw_inst_set_3src_src_type(devinfo
, inst
, BRW_3SRC_TYPE_F
);
958 brw_inst_set_3src_dst_type(devinfo
, inst
, BRW_3SRC_TYPE_F
);
960 case BRW_REGISTER_TYPE_DF
:
961 brw_inst_set_3src_src_type(devinfo
, inst
, BRW_3SRC_TYPE_DF
);
962 brw_inst_set_3src_dst_type(devinfo
, inst
, BRW_3SRC_TYPE_DF
);
964 case BRW_REGISTER_TYPE_D
:
965 brw_inst_set_3src_src_type(devinfo
, inst
, BRW_3SRC_TYPE_D
);
966 brw_inst_set_3src_dst_type(devinfo
, inst
, BRW_3SRC_TYPE_D
);
968 case BRW_REGISTER_TYPE_UD
:
969 brw_inst_set_3src_src_type(devinfo
, inst
, BRW_3SRC_TYPE_UD
);
970 brw_inst_set_3src_dst_type(devinfo
, inst
, BRW_3SRC_TYPE_UD
);
973 unreachable("not reached");
981 /***********************************************************************
982 * Convenience routines.
985 brw_inst *brw_##OP(struct brw_codegen *p, \
986 struct brw_reg dest, \
987 struct brw_reg src0) \
989 return brw_alu1(p, BRW_OPCODE_##OP, dest, src0); \
993 brw_inst *brw_##OP(struct brw_codegen *p, \
994 struct brw_reg dest, \
995 struct brw_reg src0, \
996 struct brw_reg src1) \
998 return brw_alu2(p, BRW_OPCODE_##OP, dest, src0, src1); \
1002 brw_inst *brw_##OP(struct brw_codegen *p, \
1003 struct brw_reg dest, \
1004 struct brw_reg src0, \
1005 struct brw_reg src1, \
1006 struct brw_reg src2) \
1008 return brw_alu3(p, BRW_OPCODE_##OP, dest, src0, src1, src2); \
1012 brw_inst *brw_##OP(struct brw_codegen *p, \
1013 struct brw_reg dest, \
1014 struct brw_reg src0, \
1015 struct brw_reg src1, \
1016 struct brw_reg src2) \
1018 assert(dest.type == BRW_REGISTER_TYPE_F || \
1019 dest.type == BRW_REGISTER_TYPE_DF); \
1020 if (dest.type == BRW_REGISTER_TYPE_F) { \
1021 assert(src0.type == BRW_REGISTER_TYPE_F); \
1022 assert(src1.type == BRW_REGISTER_TYPE_F); \
1023 assert(src2.type == BRW_REGISTER_TYPE_F); \
1024 } else if (dest.type == BRW_REGISTER_TYPE_DF) { \
1025 assert(src0.type == BRW_REGISTER_TYPE_DF); \
1026 assert(src1.type == BRW_REGISTER_TYPE_DF); \
1027 assert(src2.type == BRW_REGISTER_TYPE_DF); \
1029 return brw_alu3(p, BRW_OPCODE_##OP, dest, src0, src1, src2); \
1032 /* Rounding operations (other than RNDD) require two instructions - the first
1033 * stores a rounded value (possibly the wrong way) in the dest register, but
1034 * also sets a per-channel "increment bit" in the flag register. A predicated
1035 * add of 1.0 fixes dest to contain the desired result.
1037 * Sandybridge and later appear to round correctly without an ADD.
1040 void brw_##OP(struct brw_codegen *p, \
1041 struct brw_reg dest, \
1042 struct brw_reg src) \
1044 const struct brw_device_info *devinfo = p->devinfo; \
1045 brw_inst *rnd, *add; \
1046 rnd = next_insn(p, BRW_OPCODE_##OP); \
1047 brw_set_dest(p, rnd, dest); \
1048 brw_set_src0(p, rnd, src); \
1050 if (devinfo->gen < 6) { \
1051 /* turn on round-increments */ \
1052 brw_inst_set_cond_modifier(devinfo, rnd, BRW_CONDITIONAL_R); \
1053 add = brw_ADD(p, dest, dest, brw_imm_f(1.0f)); \
1054 brw_inst_set_pred_control(devinfo, add, BRW_PREDICATE_NORMAL); \
1094 brw_ADD(struct brw_codegen
*p
, struct brw_reg dest
,
1095 struct brw_reg src0
, struct brw_reg src1
)
1098 if (src0
.type
== BRW_REGISTER_TYPE_F
||
1099 (src0
.file
== BRW_IMMEDIATE_VALUE
&&
1100 src0
.type
== BRW_REGISTER_TYPE_VF
)) {
1101 assert(src1
.type
!= BRW_REGISTER_TYPE_UD
);
1102 assert(src1
.type
!= BRW_REGISTER_TYPE_D
);
1105 if (src1
.type
== BRW_REGISTER_TYPE_F
||
1106 (src1
.file
== BRW_IMMEDIATE_VALUE
&&
1107 src1
.type
== BRW_REGISTER_TYPE_VF
)) {
1108 assert(src0
.type
!= BRW_REGISTER_TYPE_UD
);
1109 assert(src0
.type
!= BRW_REGISTER_TYPE_D
);
1112 return brw_alu2(p
, BRW_OPCODE_ADD
, dest
, src0
, src1
);
1116 brw_AVG(struct brw_codegen
*p
, struct brw_reg dest
,
1117 struct brw_reg src0
, struct brw_reg src1
)
1119 assert(dest
.type
== src0
.type
);
1120 assert(src0
.type
== src1
.type
);
1121 switch (src0
.type
) {
1122 case BRW_REGISTER_TYPE_B
:
1123 case BRW_REGISTER_TYPE_UB
:
1124 case BRW_REGISTER_TYPE_W
:
1125 case BRW_REGISTER_TYPE_UW
:
1126 case BRW_REGISTER_TYPE_D
:
1127 case BRW_REGISTER_TYPE_UD
:
1130 unreachable("Bad type for brw_AVG");
1133 return brw_alu2(p
, BRW_OPCODE_AVG
, dest
, src0
, src1
);
1137 brw_MUL(struct brw_codegen
*p
, struct brw_reg dest
,
1138 struct brw_reg src0
, struct brw_reg src1
)
1141 if (src0
.type
== BRW_REGISTER_TYPE_D
||
1142 src0
.type
== BRW_REGISTER_TYPE_UD
||
1143 src1
.type
== BRW_REGISTER_TYPE_D
||
1144 src1
.type
== BRW_REGISTER_TYPE_UD
) {
1145 assert(dest
.type
!= BRW_REGISTER_TYPE_F
);
1148 if (src0
.type
== BRW_REGISTER_TYPE_F
||
1149 (src0
.file
== BRW_IMMEDIATE_VALUE
&&
1150 src0
.type
== BRW_REGISTER_TYPE_VF
)) {
1151 assert(src1
.type
!= BRW_REGISTER_TYPE_UD
);
1152 assert(src1
.type
!= BRW_REGISTER_TYPE_D
);
1155 if (src1
.type
== BRW_REGISTER_TYPE_F
||
1156 (src1
.file
== BRW_IMMEDIATE_VALUE
&&
1157 src1
.type
== BRW_REGISTER_TYPE_VF
)) {
1158 assert(src0
.type
!= BRW_REGISTER_TYPE_UD
);
1159 assert(src0
.type
!= BRW_REGISTER_TYPE_D
);
1162 assert(src0
.file
!= BRW_ARCHITECTURE_REGISTER_FILE
||
1163 src0
.nr
!= BRW_ARF_ACCUMULATOR
);
1164 assert(src1
.file
!= BRW_ARCHITECTURE_REGISTER_FILE
||
1165 src1
.nr
!= BRW_ARF_ACCUMULATOR
);
1167 return brw_alu2(p
, BRW_OPCODE_MUL
, dest
, src0
, src1
);
1171 brw_LINE(struct brw_codegen
*p
, struct brw_reg dest
,
1172 struct brw_reg src0
, struct brw_reg src1
)
1174 src0
.vstride
= BRW_VERTICAL_STRIDE_0
;
1175 src0
.width
= BRW_WIDTH_1
;
1176 src0
.hstride
= BRW_HORIZONTAL_STRIDE_0
;
1177 return brw_alu2(p
, BRW_OPCODE_LINE
, dest
, src0
, src1
);
1181 brw_PLN(struct brw_codegen
*p
, struct brw_reg dest
,
1182 struct brw_reg src0
, struct brw_reg src1
)
1184 src0
.vstride
= BRW_VERTICAL_STRIDE_0
;
1185 src0
.width
= BRW_WIDTH_1
;
1186 src0
.hstride
= BRW_HORIZONTAL_STRIDE_0
;
1187 src1
.vstride
= BRW_VERTICAL_STRIDE_8
;
1188 src1
.width
= BRW_WIDTH_8
;
1189 src1
.hstride
= BRW_HORIZONTAL_STRIDE_1
;
1190 return brw_alu2(p
, BRW_OPCODE_PLN
, dest
, src0
, src1
);
1194 brw_F32TO16(struct brw_codegen
*p
, struct brw_reg dst
, struct brw_reg src
)
1196 const struct brw_device_info
*devinfo
= p
->devinfo
;
1197 const bool align16
= brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_16
;
1198 /* The F32TO16 instruction doesn't support 32-bit destination types in
1199 * Align1 mode, and neither does the Gen8 implementation in terms of a
1200 * converting MOV. Gen7 does zero out the high 16 bits in Align16 mode as
1201 * an undocumented feature.
1203 const bool needs_zero_fill
= (dst
.type
== BRW_REGISTER_TYPE_UD
&&
1204 (!align16
|| devinfo
->gen
>= 8));
1208 assert(dst
.type
== BRW_REGISTER_TYPE_UD
);
1210 assert(dst
.type
== BRW_REGISTER_TYPE_UD
||
1211 dst
.type
== BRW_REGISTER_TYPE_W
||
1212 dst
.type
== BRW_REGISTER_TYPE_UW
||
1213 dst
.type
== BRW_REGISTER_TYPE_HF
);
1216 brw_push_insn_state(p
);
1218 if (needs_zero_fill
) {
1219 brw_set_default_access_mode(p
, BRW_ALIGN_1
);
1220 dst
= spread(retype(dst
, BRW_REGISTER_TYPE_W
), 2);
1223 if (devinfo
->gen
>= 8) {
1224 inst
= brw_MOV(p
, retype(dst
, BRW_REGISTER_TYPE_HF
), src
);
1226 assert(devinfo
->gen
== 7);
1227 inst
= brw_alu1(p
, BRW_OPCODE_F32TO16
, dst
, src
);
1230 if (needs_zero_fill
) {
1231 brw_inst_set_no_dd_clear(devinfo
, inst
, true);
1232 inst
= brw_MOV(p
, suboffset(dst
, 1), brw_imm_ud(0u));
1233 brw_inst_set_no_dd_check(devinfo
, inst
, true);
1236 brw_pop_insn_state(p
);
1241 brw_F16TO32(struct brw_codegen
*p
, struct brw_reg dst
, struct brw_reg src
)
1243 const struct brw_device_info
*devinfo
= p
->devinfo
;
1244 bool align16
= brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_16
;
1247 assert(src
.type
== BRW_REGISTER_TYPE_UD
);
1249 /* From the Ivybridge PRM, Vol4, Part3, Section 6.26 f16to32:
1251 * Because this instruction does not have a 16-bit floating-point
1252 * type, the source data type must be Word (W). The destination type
1253 * must be F (Float).
1255 if (src
.type
== BRW_REGISTER_TYPE_UD
)
1256 src
= spread(retype(src
, BRW_REGISTER_TYPE_W
), 2);
1258 assert(src
.type
== BRW_REGISTER_TYPE_W
||
1259 src
.type
== BRW_REGISTER_TYPE_UW
||
1260 src
.type
== BRW_REGISTER_TYPE_HF
);
1263 if (devinfo
->gen
>= 8) {
1264 return brw_MOV(p
, dst
, retype(src
, BRW_REGISTER_TYPE_HF
));
1266 assert(devinfo
->gen
== 7);
1267 return brw_alu1(p
, BRW_OPCODE_F16TO32
, dst
, src
);
1272 void brw_NOP(struct brw_codegen
*p
)
1274 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_NOP
);
1275 brw_inst_set_exec_size(p
->devinfo
, insn
, BRW_EXECUTE_1
);
1276 brw_set_dest(p
, insn
, retype(brw_vec1_grf(0,0), BRW_REGISTER_TYPE_UD
));
1277 brw_set_src0(p
, insn
, retype(brw_vec1_grf(0,0), BRW_REGISTER_TYPE_UD
));
1278 brw_set_src1(p
, insn
, brw_imm_ud(0x0));
1285 /***********************************************************************
1286 * Comparisons, if/else/endif
1290 brw_JMPI(struct brw_codegen
*p
, struct brw_reg index
,
1291 unsigned predicate_control
)
1293 const struct brw_device_info
*devinfo
= p
->devinfo
;
1294 struct brw_reg ip
= brw_ip_reg();
1295 brw_inst
*inst
= brw_alu2(p
, BRW_OPCODE_JMPI
, ip
, ip
, index
);
1297 brw_inst_set_exec_size(devinfo
, inst
, BRW_EXECUTE_2
);
1298 brw_inst_set_qtr_control(devinfo
, inst
, BRW_COMPRESSION_NONE
);
1299 brw_inst_set_mask_control(devinfo
, inst
, BRW_MASK_DISABLE
);
1300 brw_inst_set_pred_control(devinfo
, inst
, predicate_control
);
1306 push_if_stack(struct brw_codegen
*p
, brw_inst
*inst
)
1308 p
->if_stack
[p
->if_stack_depth
] = inst
- p
->store
;
1310 p
->if_stack_depth
++;
1311 if (p
->if_stack_array_size
<= p
->if_stack_depth
) {
1312 p
->if_stack_array_size
*= 2;
1313 p
->if_stack
= reralloc(p
->mem_ctx
, p
->if_stack
, int,
1314 p
->if_stack_array_size
);
1319 pop_if_stack(struct brw_codegen
*p
)
1321 p
->if_stack_depth
--;
1322 return &p
->store
[p
->if_stack
[p
->if_stack_depth
]];
1326 push_loop_stack(struct brw_codegen
*p
, brw_inst
*inst
)
1328 if (p
->loop_stack_array_size
<= (p
->loop_stack_depth
+ 1)) {
1329 p
->loop_stack_array_size
*= 2;
1330 p
->loop_stack
= reralloc(p
->mem_ctx
, p
->loop_stack
, int,
1331 p
->loop_stack_array_size
);
1332 p
->if_depth_in_loop
= reralloc(p
->mem_ctx
, p
->if_depth_in_loop
, int,
1333 p
->loop_stack_array_size
);
1336 p
->loop_stack
[p
->loop_stack_depth
] = inst
- p
->store
;
1337 p
->loop_stack_depth
++;
1338 p
->if_depth_in_loop
[p
->loop_stack_depth
] = 0;
1342 get_inner_do_insn(struct brw_codegen
*p
)
1344 return &p
->store
[p
->loop_stack
[p
->loop_stack_depth
- 1]];
1347 /* EU takes the value from the flag register and pushes it onto some
1348 * sort of a stack (presumably merging with any flag value already on
1349 * the stack). Within an if block, the flags at the top of the stack
1350 * control execution on each channel of the unit, eg. on each of the
1351 * 16 pixel values in our wm programs.
1353 * When the matching 'else' instruction is reached (presumably by
1354 * countdown of the instruction count patched in by our ELSE/ENDIF
1355 * functions), the relevant flags are inverted.
1357 * When the matching 'endif' instruction is reached, the flags are
1358 * popped off. If the stack is now empty, normal execution resumes.
1361 brw_IF(struct brw_codegen
*p
, unsigned execute_size
)
1363 const struct brw_device_info
*devinfo
= p
->devinfo
;
1366 insn
= next_insn(p
, BRW_OPCODE_IF
);
1368 /* Override the defaults for this instruction:
1370 if (devinfo
->gen
< 6) {
1371 brw_set_dest(p
, insn
, brw_ip_reg());
1372 brw_set_src0(p
, insn
, brw_ip_reg());
1373 brw_set_src1(p
, insn
, brw_imm_d(0x0));
1374 } else if (devinfo
->gen
== 6) {
1375 brw_set_dest(p
, insn
, brw_imm_w(0));
1376 brw_inst_set_gen6_jump_count(devinfo
, insn
, 0);
1377 brw_set_src0(p
, insn
, vec1(retype(brw_null_reg(), BRW_REGISTER_TYPE_D
)));
1378 brw_set_src1(p
, insn
, vec1(retype(brw_null_reg(), BRW_REGISTER_TYPE_D
)));
1379 } else if (devinfo
->gen
== 7) {
1380 brw_set_dest(p
, insn
, vec1(retype(brw_null_reg(), BRW_REGISTER_TYPE_D
)));
1381 brw_set_src0(p
, insn
, vec1(retype(brw_null_reg(), BRW_REGISTER_TYPE_D
)));
1382 brw_set_src1(p
, insn
, brw_imm_w(0));
1383 brw_inst_set_jip(devinfo
, insn
, 0);
1384 brw_inst_set_uip(devinfo
, insn
, 0);
1386 brw_set_dest(p
, insn
, vec1(retype(brw_null_reg(), BRW_REGISTER_TYPE_D
)));
1387 brw_set_src0(p
, insn
, brw_imm_d(0));
1388 brw_inst_set_jip(devinfo
, insn
, 0);
1389 brw_inst_set_uip(devinfo
, insn
, 0);
1392 brw_inst_set_exec_size(devinfo
, insn
, execute_size
);
1393 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1394 brw_inst_set_pred_control(devinfo
, insn
, BRW_PREDICATE_NORMAL
);
1395 brw_inst_set_mask_control(devinfo
, insn
, BRW_MASK_ENABLE
);
1396 if (!p
->single_program_flow
&& devinfo
->gen
< 6)
1397 brw_inst_set_thread_control(devinfo
, insn
, BRW_THREAD_SWITCH
);
1399 push_if_stack(p
, insn
);
1400 p
->if_depth_in_loop
[p
->loop_stack_depth
]++;
1404 /* This function is only used for gen6-style IF instructions with an
1405 * embedded comparison (conditional modifier). It is not used on gen7.
1408 gen6_IF(struct brw_codegen
*p
, enum brw_conditional_mod conditional
,
1409 struct brw_reg src0
, struct brw_reg src1
)
1411 const struct brw_device_info
*devinfo
= p
->devinfo
;
1414 insn
= next_insn(p
, BRW_OPCODE_IF
);
1416 brw_set_dest(p
, insn
, brw_imm_w(0));
1417 brw_inst_set_exec_size(devinfo
, insn
,
1418 brw_inst_exec_size(devinfo
, p
->current
));
1419 brw_inst_set_gen6_jump_count(devinfo
, insn
, 0);
1420 brw_set_src0(p
, insn
, src0
);
1421 brw_set_src1(p
, insn
, src1
);
1423 assert(brw_inst_qtr_control(devinfo
, insn
) == BRW_COMPRESSION_NONE
);
1424 assert(brw_inst_pred_control(devinfo
, insn
) == BRW_PREDICATE_NONE
);
1425 brw_inst_set_cond_modifier(devinfo
, insn
, conditional
);
1427 push_if_stack(p
, insn
);
1432 * In single-program-flow (SPF) mode, convert IF and ELSE into ADDs.
1435 convert_IF_ELSE_to_ADD(struct brw_codegen
*p
,
1436 brw_inst
*if_inst
, brw_inst
*else_inst
)
1438 const struct brw_device_info
*devinfo
= p
->devinfo
;
1440 /* The next instruction (where the ENDIF would be, if it existed) */
1441 brw_inst
*next_inst
= &p
->store
[p
->nr_insn
];
1443 assert(p
->single_program_flow
);
1444 assert(if_inst
!= NULL
&& brw_inst_opcode(devinfo
, if_inst
) == BRW_OPCODE_IF
);
1445 assert(else_inst
== NULL
|| brw_inst_opcode(devinfo
, else_inst
) == BRW_OPCODE_ELSE
);
1446 assert(brw_inst_exec_size(devinfo
, if_inst
) == BRW_EXECUTE_1
);
1448 /* Convert IF to an ADD instruction that moves the instruction pointer
1449 * to the first instruction of the ELSE block. If there is no ELSE
1450 * block, point to where ENDIF would be. Reverse the predicate.
1452 * There's no need to execute an ENDIF since we don't need to do any
1453 * stack operations, and if we're currently executing, we just want to
1454 * continue normally.
1456 brw_inst_set_opcode(devinfo
, if_inst
, BRW_OPCODE_ADD
);
1457 brw_inst_set_pred_inv(devinfo
, if_inst
, true);
1459 if (else_inst
!= NULL
) {
1460 /* Convert ELSE to an ADD instruction that points where the ENDIF
1463 brw_inst_set_opcode(devinfo
, else_inst
, BRW_OPCODE_ADD
);
1465 brw_inst_set_imm_ud(devinfo
, if_inst
, (else_inst
- if_inst
+ 1) * 16);
1466 brw_inst_set_imm_ud(devinfo
, else_inst
, (next_inst
- else_inst
) * 16);
1468 brw_inst_set_imm_ud(devinfo
, if_inst
, (next_inst
- if_inst
) * 16);
1473 * Patch IF and ELSE instructions with appropriate jump targets.
1476 patch_IF_ELSE(struct brw_codegen
*p
,
1477 brw_inst
*if_inst
, brw_inst
*else_inst
, brw_inst
*endif_inst
)
1479 const struct brw_device_info
*devinfo
= p
->devinfo
;
1481 /* We shouldn't be patching IF and ELSE instructions in single program flow
1482 * mode when gen < 6, because in single program flow mode on those
1483 * platforms, we convert flow control instructions to conditional ADDs that
1484 * operate on IP (see brw_ENDIF).
1486 * However, on Gen6, writing to IP doesn't work in single program flow mode
1487 * (see the SandyBridge PRM, Volume 4 part 2, p79: "When SPF is ON, IP may
1488 * not be updated by non-flow control instructions."). And on later
1489 * platforms, there is no significant benefit to converting control flow
1490 * instructions to conditional ADDs. So we do patch IF and ELSE
1491 * instructions in single program flow mode on those platforms.
1493 if (devinfo
->gen
< 6)
1494 assert(!p
->single_program_flow
);
1496 assert(if_inst
!= NULL
&& brw_inst_opcode(devinfo
, if_inst
) == BRW_OPCODE_IF
);
1497 assert(endif_inst
!= NULL
);
1498 assert(else_inst
== NULL
|| brw_inst_opcode(devinfo
, else_inst
) == BRW_OPCODE_ELSE
);
1500 unsigned br
= brw_jump_scale(devinfo
);
1502 assert(brw_inst_opcode(devinfo
, endif_inst
) == BRW_OPCODE_ENDIF
);
1503 brw_inst_set_exec_size(devinfo
, endif_inst
, brw_inst_exec_size(devinfo
, if_inst
));
1505 if (else_inst
== NULL
) {
1506 /* Patch IF -> ENDIF */
1507 if (devinfo
->gen
< 6) {
1508 /* Turn it into an IFF, which means no mask stack operations for
1509 * all-false and jumping past the ENDIF.
1511 brw_inst_set_opcode(devinfo
, if_inst
, BRW_OPCODE_IFF
);
1512 brw_inst_set_gen4_jump_count(devinfo
, if_inst
,
1513 br
* (endif_inst
- if_inst
+ 1));
1514 brw_inst_set_gen4_pop_count(devinfo
, if_inst
, 0);
1515 } else if (devinfo
->gen
== 6) {
1516 /* As of gen6, there is no IFF and IF must point to the ENDIF. */
1517 brw_inst_set_gen6_jump_count(devinfo
, if_inst
, br
*(endif_inst
- if_inst
));
1519 brw_inst_set_uip(devinfo
, if_inst
, br
* (endif_inst
- if_inst
));
1520 brw_inst_set_jip(devinfo
, if_inst
, br
* (endif_inst
- if_inst
));
1523 brw_inst_set_exec_size(devinfo
, else_inst
, brw_inst_exec_size(devinfo
, if_inst
));
1525 /* Patch IF -> ELSE */
1526 if (devinfo
->gen
< 6) {
1527 brw_inst_set_gen4_jump_count(devinfo
, if_inst
,
1528 br
* (else_inst
- if_inst
));
1529 brw_inst_set_gen4_pop_count(devinfo
, if_inst
, 0);
1530 } else if (devinfo
->gen
== 6) {
1531 brw_inst_set_gen6_jump_count(devinfo
, if_inst
,
1532 br
* (else_inst
- if_inst
+ 1));
1535 /* Patch ELSE -> ENDIF */
1536 if (devinfo
->gen
< 6) {
1537 /* BRW_OPCODE_ELSE pre-gen6 should point just past the
1540 brw_inst_set_gen4_jump_count(devinfo
, else_inst
,
1541 br
* (endif_inst
- else_inst
+ 1));
1542 brw_inst_set_gen4_pop_count(devinfo
, else_inst
, 1);
1543 } else if (devinfo
->gen
== 6) {
1544 /* BRW_OPCODE_ELSE on gen6 should point to the matching ENDIF. */
1545 brw_inst_set_gen6_jump_count(devinfo
, else_inst
,
1546 br
* (endif_inst
- else_inst
));
1548 /* The IF instruction's JIP should point just past the ELSE */
1549 brw_inst_set_jip(devinfo
, if_inst
, br
* (else_inst
- if_inst
+ 1));
1550 /* The IF instruction's UIP and ELSE's JIP should point to ENDIF */
1551 brw_inst_set_uip(devinfo
, if_inst
, br
* (endif_inst
- if_inst
));
1552 brw_inst_set_jip(devinfo
, else_inst
, br
* (endif_inst
- else_inst
));
1553 if (devinfo
->gen
>= 8) {
1554 /* Since we don't set branch_ctrl, the ELSE's JIP and UIP both
1555 * should point to ENDIF.
1557 brw_inst_set_uip(devinfo
, else_inst
, br
* (endif_inst
- else_inst
));
1564 brw_ELSE(struct brw_codegen
*p
)
1566 const struct brw_device_info
*devinfo
= p
->devinfo
;
1569 insn
= next_insn(p
, BRW_OPCODE_ELSE
);
1571 if (devinfo
->gen
< 6) {
1572 brw_set_dest(p
, insn
, brw_ip_reg());
1573 brw_set_src0(p
, insn
, brw_ip_reg());
1574 brw_set_src1(p
, insn
, brw_imm_d(0x0));
1575 } else if (devinfo
->gen
== 6) {
1576 brw_set_dest(p
, insn
, brw_imm_w(0));
1577 brw_inst_set_gen6_jump_count(devinfo
, insn
, 0);
1578 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1579 brw_set_src1(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1580 } else if (devinfo
->gen
== 7) {
1581 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1582 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1583 brw_set_src1(p
, insn
, brw_imm_w(0));
1584 brw_inst_set_jip(devinfo
, insn
, 0);
1585 brw_inst_set_uip(devinfo
, insn
, 0);
1587 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1588 brw_set_src0(p
, insn
, brw_imm_d(0));
1589 brw_inst_set_jip(devinfo
, insn
, 0);
1590 brw_inst_set_uip(devinfo
, insn
, 0);
1593 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1594 brw_inst_set_mask_control(devinfo
, insn
, BRW_MASK_ENABLE
);
1595 if (!p
->single_program_flow
&& devinfo
->gen
< 6)
1596 brw_inst_set_thread_control(devinfo
, insn
, BRW_THREAD_SWITCH
);
1598 push_if_stack(p
, insn
);
1602 brw_ENDIF(struct brw_codegen
*p
)
1604 const struct brw_device_info
*devinfo
= p
->devinfo
;
1605 brw_inst
*insn
= NULL
;
1606 brw_inst
*else_inst
= NULL
;
1607 brw_inst
*if_inst
= NULL
;
1609 bool emit_endif
= true;
1611 /* In single program flow mode, we can express IF and ELSE instructions
1612 * equivalently as ADD instructions that operate on IP. On platforms prior
1613 * to Gen6, flow control instructions cause an implied thread switch, so
1614 * this is a significant savings.
1616 * However, on Gen6, writing to IP doesn't work in single program flow mode
1617 * (see the SandyBridge PRM, Volume 4 part 2, p79: "When SPF is ON, IP may
1618 * not be updated by non-flow control instructions."). And on later
1619 * platforms, there is no significant benefit to converting control flow
1620 * instructions to conditional ADDs. So we only do this trick on Gen4 and
1623 if (devinfo
->gen
< 6 && p
->single_program_flow
)
1627 * A single next_insn() may change the base address of instruction store
1628 * memory(p->store), so call it first before referencing the instruction
1629 * store pointer from an index
1632 insn
= next_insn(p
, BRW_OPCODE_ENDIF
);
1634 /* Pop the IF and (optional) ELSE instructions from the stack */
1635 p
->if_depth_in_loop
[p
->loop_stack_depth
]--;
1636 tmp
= pop_if_stack(p
);
1637 if (brw_inst_opcode(devinfo
, tmp
) == BRW_OPCODE_ELSE
) {
1639 tmp
= pop_if_stack(p
);
1644 /* ENDIF is useless; don't bother emitting it. */
1645 convert_IF_ELSE_to_ADD(p
, if_inst
, else_inst
);
1649 if (devinfo
->gen
< 6) {
1650 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1651 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1652 brw_set_src1(p
, insn
, brw_imm_d(0x0));
1653 } else if (devinfo
->gen
== 6) {
1654 brw_set_dest(p
, insn
, brw_imm_w(0));
1655 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1656 brw_set_src1(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1657 } else if (devinfo
->gen
== 7) {
1658 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1659 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1660 brw_set_src1(p
, insn
, brw_imm_w(0));
1662 brw_set_src0(p
, insn
, brw_imm_d(0));
1665 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1666 brw_inst_set_mask_control(devinfo
, insn
, BRW_MASK_ENABLE
);
1667 if (devinfo
->gen
< 6)
1668 brw_inst_set_thread_control(devinfo
, insn
, BRW_THREAD_SWITCH
);
1670 /* Also pop item off the stack in the endif instruction: */
1671 if (devinfo
->gen
< 6) {
1672 brw_inst_set_gen4_jump_count(devinfo
, insn
, 0);
1673 brw_inst_set_gen4_pop_count(devinfo
, insn
, 1);
1674 } else if (devinfo
->gen
== 6) {
1675 brw_inst_set_gen6_jump_count(devinfo
, insn
, 2);
1677 brw_inst_set_jip(devinfo
, insn
, 2);
1679 patch_IF_ELSE(p
, if_inst
, else_inst
, insn
);
1683 brw_BREAK(struct brw_codegen
*p
)
1685 const struct brw_device_info
*devinfo
= p
->devinfo
;
1688 insn
= next_insn(p
, BRW_OPCODE_BREAK
);
1689 if (devinfo
->gen
>= 8) {
1690 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1691 brw_set_src0(p
, insn
, brw_imm_d(0x0));
1692 } else if (devinfo
->gen
>= 6) {
1693 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1694 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1695 brw_set_src1(p
, insn
, brw_imm_d(0x0));
1697 brw_set_dest(p
, insn
, brw_ip_reg());
1698 brw_set_src0(p
, insn
, brw_ip_reg());
1699 brw_set_src1(p
, insn
, brw_imm_d(0x0));
1700 brw_inst_set_gen4_pop_count(devinfo
, insn
,
1701 p
->if_depth_in_loop
[p
->loop_stack_depth
]);
1703 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1704 brw_inst_set_exec_size(devinfo
, insn
,
1705 brw_inst_exec_size(devinfo
, p
->current
));
1711 brw_CONT(struct brw_codegen
*p
)
1713 const struct brw_device_info
*devinfo
= p
->devinfo
;
1716 insn
= next_insn(p
, BRW_OPCODE_CONTINUE
);
1717 brw_set_dest(p
, insn
, brw_ip_reg());
1718 if (devinfo
->gen
>= 8) {
1719 brw_set_src0(p
, insn
, brw_imm_d(0x0));
1721 brw_set_src0(p
, insn
, brw_ip_reg());
1722 brw_set_src1(p
, insn
, brw_imm_d(0x0));
1725 if (devinfo
->gen
< 6) {
1726 brw_inst_set_gen4_pop_count(devinfo
, insn
,
1727 p
->if_depth_in_loop
[p
->loop_stack_depth
]);
1729 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1730 brw_inst_set_exec_size(devinfo
, insn
,
1731 brw_inst_exec_size(devinfo
, p
->current
));
1736 gen6_HALT(struct brw_codegen
*p
)
1738 const struct brw_device_info
*devinfo
= p
->devinfo
;
1741 insn
= next_insn(p
, BRW_OPCODE_HALT
);
1742 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1743 if (devinfo
->gen
>= 8) {
1744 brw_set_src0(p
, insn
, brw_imm_d(0x0));
1746 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1747 brw_set_src1(p
, insn
, brw_imm_d(0x0)); /* UIP and JIP, updated later. */
1750 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1751 brw_inst_set_exec_size(devinfo
, insn
,
1752 brw_inst_exec_size(devinfo
, p
->current
));
1758 * The DO/WHILE is just an unterminated loop -- break or continue are
1759 * used for control within the loop. We have a few ways they can be
1762 * For uniform control flow, the WHILE is just a jump, so ADD ip, ip,
1763 * jip and no DO instruction.
1765 * For non-uniform control flow pre-gen6, there's a DO instruction to
1766 * push the mask, and a WHILE to jump back, and BREAK to get out and
1769 * For gen6, there's no more mask stack, so no need for DO. WHILE
1770 * just points back to the first instruction of the loop.
1773 brw_DO(struct brw_codegen
*p
, unsigned execute_size
)
1775 const struct brw_device_info
*devinfo
= p
->devinfo
;
1777 if (devinfo
->gen
>= 6 || p
->single_program_flow
) {
1778 push_loop_stack(p
, &p
->store
[p
->nr_insn
]);
1779 return &p
->store
[p
->nr_insn
];
1781 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_DO
);
1783 push_loop_stack(p
, insn
);
1785 /* Override the defaults for this instruction:
1787 brw_set_dest(p
, insn
, brw_null_reg());
1788 brw_set_src0(p
, insn
, brw_null_reg());
1789 brw_set_src1(p
, insn
, brw_null_reg());
1791 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1792 brw_inst_set_exec_size(devinfo
, insn
, execute_size
);
1793 brw_inst_set_pred_control(devinfo
, insn
, BRW_PREDICATE_NONE
);
1800 * For pre-gen6, we patch BREAK/CONT instructions to point at the WHILE
1803 * For gen6+, see brw_set_uip_jip(), which doesn't care so much about the loop
1804 * nesting, since it can always just point to the end of the block/current loop.
1807 brw_patch_break_cont(struct brw_codegen
*p
, brw_inst
*while_inst
)
1809 const struct brw_device_info
*devinfo
= p
->devinfo
;
1810 brw_inst
*do_inst
= get_inner_do_insn(p
);
1812 unsigned br
= brw_jump_scale(devinfo
);
1814 assert(devinfo
->gen
< 6);
1816 for (inst
= while_inst
- 1; inst
!= do_inst
; inst
--) {
1817 /* If the jump count is != 0, that means that this instruction has already
1818 * been patched because it's part of a loop inside of the one we're
1821 if (brw_inst_opcode(devinfo
, inst
) == BRW_OPCODE_BREAK
&&
1822 brw_inst_gen4_jump_count(devinfo
, inst
) == 0) {
1823 brw_inst_set_gen4_jump_count(devinfo
, inst
, br
*((while_inst
- inst
) + 1));
1824 } else if (brw_inst_opcode(devinfo
, inst
) == BRW_OPCODE_CONTINUE
&&
1825 brw_inst_gen4_jump_count(devinfo
, inst
) == 0) {
1826 brw_inst_set_gen4_jump_count(devinfo
, inst
, br
* (while_inst
- inst
));
1832 brw_WHILE(struct brw_codegen
*p
)
1834 const struct brw_device_info
*devinfo
= p
->devinfo
;
1835 brw_inst
*insn
, *do_insn
;
1836 unsigned br
= brw_jump_scale(devinfo
);
1838 if (devinfo
->gen
>= 6) {
1839 insn
= next_insn(p
, BRW_OPCODE_WHILE
);
1840 do_insn
= get_inner_do_insn(p
);
1842 if (devinfo
->gen
>= 8) {
1843 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1844 brw_set_src0(p
, insn
, brw_imm_d(0));
1845 brw_inst_set_jip(devinfo
, insn
, br
* (do_insn
- insn
));
1846 } else if (devinfo
->gen
== 7) {
1847 brw_set_dest(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1848 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1849 brw_set_src1(p
, insn
, brw_imm_w(0));
1850 brw_inst_set_jip(devinfo
, insn
, br
* (do_insn
- insn
));
1852 brw_set_dest(p
, insn
, brw_imm_w(0));
1853 brw_inst_set_gen6_jump_count(devinfo
, insn
, br
* (do_insn
- insn
));
1854 brw_set_src0(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1855 brw_set_src1(p
, insn
, retype(brw_null_reg(), BRW_REGISTER_TYPE_D
));
1858 brw_inst_set_exec_size(devinfo
, insn
,
1859 brw_inst_exec_size(devinfo
, p
->current
));
1862 if (p
->single_program_flow
) {
1863 insn
= next_insn(p
, BRW_OPCODE_ADD
);
1864 do_insn
= get_inner_do_insn(p
);
1866 brw_set_dest(p
, insn
, brw_ip_reg());
1867 brw_set_src0(p
, insn
, brw_ip_reg());
1868 brw_set_src1(p
, insn
, brw_imm_d((do_insn
- insn
) * 16));
1869 brw_inst_set_exec_size(devinfo
, insn
, BRW_EXECUTE_1
);
1871 insn
= next_insn(p
, BRW_OPCODE_WHILE
);
1872 do_insn
= get_inner_do_insn(p
);
1874 assert(brw_inst_opcode(devinfo
, do_insn
) == BRW_OPCODE_DO
);
1876 brw_set_dest(p
, insn
, brw_ip_reg());
1877 brw_set_src0(p
, insn
, brw_ip_reg());
1878 brw_set_src1(p
, insn
, brw_imm_d(0));
1880 brw_inst_set_exec_size(devinfo
, insn
, brw_inst_exec_size(devinfo
, do_insn
));
1881 brw_inst_set_gen4_jump_count(devinfo
, insn
, br
* (do_insn
- insn
+ 1));
1882 brw_inst_set_gen4_pop_count(devinfo
, insn
, 0);
1884 brw_patch_break_cont(p
, insn
);
1887 brw_inst_set_qtr_control(devinfo
, insn
, BRW_COMPRESSION_NONE
);
1889 p
->loop_stack_depth
--;
1896 void brw_land_fwd_jump(struct brw_codegen
*p
, int jmp_insn_idx
)
1898 const struct brw_device_info
*devinfo
= p
->devinfo
;
1899 brw_inst
*jmp_insn
= &p
->store
[jmp_insn_idx
];
1902 if (devinfo
->gen
>= 5)
1905 assert(brw_inst_opcode(devinfo
, jmp_insn
) == BRW_OPCODE_JMPI
);
1906 assert(brw_inst_src1_reg_file(devinfo
, jmp_insn
) == BRW_IMMEDIATE_VALUE
);
1908 brw_inst_set_gen4_jump_count(devinfo
, jmp_insn
,
1909 jmpi
* (p
->nr_insn
- jmp_insn_idx
- 1));
1912 /* To integrate with the above, it makes sense that the comparison
1913 * instruction should populate the flag register. It might be simpler
1914 * just to use the flag reg for most WM tasks?
1916 void brw_CMP(struct brw_codegen
*p
,
1917 struct brw_reg dest
,
1918 unsigned conditional
,
1919 struct brw_reg src0
,
1920 struct brw_reg src1
)
1922 const struct brw_device_info
*devinfo
= p
->devinfo
;
1923 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_CMP
);
1925 brw_inst_set_cond_modifier(devinfo
, insn
, conditional
);
1926 brw_set_dest(p
, insn
, dest
);
1927 brw_set_src0(p
, insn
, src0
);
1928 brw_set_src1(p
, insn
, src1
);
1930 /* Item WaCMPInstNullDstForcesThreadSwitch in the Haswell Bspec workarounds
1932 * "Any CMP instruction with a null destination must use a {switch}."
1934 * It also applies to other Gen7 platforms (IVB, BYT) even though it isn't
1935 * mentioned on their work-arounds pages.
1937 if (devinfo
->gen
== 7) {
1938 if (dest
.file
== BRW_ARCHITECTURE_REGISTER_FILE
&&
1939 dest
.nr
== BRW_ARF_NULL
) {
1940 brw_inst_set_thread_control(devinfo
, insn
, BRW_THREAD_SWITCH
);
1945 /***********************************************************************
1946 * Helpers for the various SEND message types:
1949 /** Extended math function, float[8].
1951 void gen4_math(struct brw_codegen
*p
,
1952 struct brw_reg dest
,
1954 unsigned msg_reg_nr
,
1956 unsigned precision
)
1958 const struct brw_device_info
*devinfo
= p
->devinfo
;
1959 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_SEND
);
1961 if (has_scalar_region(src
)) {
1962 data_type
= BRW_MATH_DATA_SCALAR
;
1964 data_type
= BRW_MATH_DATA_VECTOR
;
1967 assert(devinfo
->gen
< 6);
1969 /* Example code doesn't set predicate_control for send
1972 brw_inst_set_pred_control(devinfo
, insn
, 0);
1973 brw_inst_set_base_mrf(devinfo
, insn
, msg_reg_nr
);
1975 brw_set_dest(p
, insn
, dest
);
1976 brw_set_src0(p
, insn
, src
);
1977 brw_set_math_message(p
,
1980 src
.type
== BRW_REGISTER_TYPE_D
,
1985 void gen6_math(struct brw_codegen
*p
,
1986 struct brw_reg dest
,
1988 struct brw_reg src0
,
1989 struct brw_reg src1
)
1991 const struct brw_device_info
*devinfo
= p
->devinfo
;
1992 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_MATH
);
1994 assert(devinfo
->gen
>= 6);
1996 assert(dest
.file
== BRW_GENERAL_REGISTER_FILE
||
1997 (devinfo
->gen
>= 7 && dest
.file
== BRW_MESSAGE_REGISTER_FILE
));
1998 assert(src0
.file
== BRW_GENERAL_REGISTER_FILE
||
1999 (devinfo
->gen
>= 8 && src0
.file
== BRW_IMMEDIATE_VALUE
));
2001 assert(dest
.hstride
== BRW_HORIZONTAL_STRIDE_1
);
2002 if (devinfo
->gen
== 6) {
2003 assert(src0
.hstride
== BRW_HORIZONTAL_STRIDE_1
);
2004 assert(src1
.hstride
== BRW_HORIZONTAL_STRIDE_1
);
2007 if (function
== BRW_MATH_FUNCTION_INT_DIV_QUOTIENT
||
2008 function
== BRW_MATH_FUNCTION_INT_DIV_REMAINDER
||
2009 function
== BRW_MATH_FUNCTION_INT_DIV_QUOTIENT_AND_REMAINDER
) {
2010 assert(src0
.type
!= BRW_REGISTER_TYPE_F
);
2011 assert(src1
.type
!= BRW_REGISTER_TYPE_F
);
2012 assert(src1
.file
== BRW_GENERAL_REGISTER_FILE
||
2013 (devinfo
->gen
>= 8 && src1
.file
== BRW_IMMEDIATE_VALUE
));
2015 assert(src0
.type
== BRW_REGISTER_TYPE_F
);
2016 assert(src1
.type
== BRW_REGISTER_TYPE_F
);
2017 if (function
== BRW_MATH_FUNCTION_POW
) {
2018 assert(src1
.file
== BRW_GENERAL_REGISTER_FILE
||
2019 (devinfo
->gen
>= 8 && src1
.file
== BRW_IMMEDIATE_VALUE
));
2021 assert(src1
.file
== BRW_ARCHITECTURE_REGISTER_FILE
&&
2022 src1
.nr
== BRW_ARF_NULL
);
2026 /* Source modifiers are ignored for extended math instructions on Gen6. */
2027 if (devinfo
->gen
== 6) {
2028 assert(!src0
.negate
);
2030 assert(!src1
.negate
);
2034 brw_inst_set_math_function(devinfo
, insn
, function
);
2036 brw_set_dest(p
, insn
, dest
);
2037 brw_set_src0(p
, insn
, src0
);
2038 brw_set_src1(p
, insn
, src1
);
2042 * Return the right surface index to access the thread scratch space using
2043 * stateless dataport messages.
2046 brw_scratch_surface_idx(const struct brw_codegen
*p
)
2048 /* The scratch space is thread-local so IA coherency is unnecessary. */
2049 if (p
->devinfo
->gen
>= 8)
2050 return GEN8_BTI_STATELESS_NON_COHERENT
;
2052 return BRW_BTI_STATELESS
;
2056 * Write a block of OWORDs (half a GRF each) from the scratch buffer,
2057 * using a constant offset per channel.
2059 * The offset must be aligned to oword size (16 bytes). Used for
2060 * register spilling.
2062 void brw_oword_block_write_scratch(struct brw_codegen
*p
,
2067 const struct brw_device_info
*devinfo
= p
->devinfo
;
2070 if (devinfo
->gen
>= 6)
2073 mrf
= retype(mrf
, BRW_REGISTER_TYPE_UD
);
2075 const unsigned mlen
= 1 + num_regs
;
2076 const unsigned msg_control
=
2077 (num_regs
== 1 ? BRW_DATAPORT_OWORD_BLOCK_2_OWORDS
:
2078 num_regs
== 2 ? BRW_DATAPORT_OWORD_BLOCK_4_OWORDS
:
2079 num_regs
== 4 ? BRW_DATAPORT_OWORD_BLOCK_8_OWORDS
: 0);
2080 assert(msg_control
);
2082 /* Set up the message header. This is g0, with g0.2 filled with
2083 * the offset. We don't want to leave our offset around in g0 or
2084 * it'll screw up texture samples, so set it up inside the message
2088 brw_push_insn_state(p
);
2089 brw_set_default_exec_size(p
, BRW_EXECUTE_8
);
2090 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
2091 brw_set_default_compression_control(p
, BRW_COMPRESSION_NONE
);
2093 brw_MOV(p
, mrf
, retype(brw_vec8_grf(0, 0), BRW_REGISTER_TYPE_UD
));
2095 /* set message header global offset field (reg 0, element 2) */
2097 retype(brw_vec1_reg(BRW_MESSAGE_REGISTER_FILE
,
2099 2), BRW_REGISTER_TYPE_UD
),
2100 brw_imm_ud(offset
));
2102 brw_pop_insn_state(p
);
2106 struct brw_reg dest
;
2107 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_SEND
);
2108 int send_commit_msg
;
2109 struct brw_reg src_header
= retype(brw_vec8_grf(0, 0),
2110 BRW_REGISTER_TYPE_UW
);
2112 brw_inst_set_compression(devinfo
, insn
, false);
2114 if (brw_inst_exec_size(devinfo
, insn
) >= 16)
2115 src_header
= vec16(src_header
);
2117 assert(brw_inst_pred_control(devinfo
, insn
) == BRW_PREDICATE_NONE
);
2118 if (devinfo
->gen
< 6)
2119 brw_inst_set_base_mrf(devinfo
, insn
, mrf
.nr
);
2121 /* Until gen6, writes followed by reads from the same location
2122 * are not guaranteed to be ordered unless write_commit is set.
2123 * If set, then a no-op write is issued to the destination
2124 * register to set a dependency, and a read from the destination
2125 * can be used to ensure the ordering.
2127 * For gen6, only writes between different threads need ordering
2128 * protection. Our use of DP writes is all about register
2129 * spilling within a thread.
2131 if (devinfo
->gen
>= 6) {
2132 dest
= retype(vec16(brw_null_reg()), BRW_REGISTER_TYPE_UW
);
2133 send_commit_msg
= 0;
2136 send_commit_msg
= 1;
2139 brw_set_dest(p
, insn
, dest
);
2140 if (devinfo
->gen
>= 6) {
2141 brw_set_src0(p
, insn
, mrf
);
2143 brw_set_src0(p
, insn
, brw_null_reg());
2146 if (devinfo
->gen
>= 6)
2147 msg_type
= GEN6_DATAPORT_WRITE_MESSAGE_OWORD_BLOCK_WRITE
;
2149 msg_type
= BRW_DATAPORT_WRITE_MESSAGE_OWORD_BLOCK_WRITE
;
2151 brw_set_dp_write_message(p
,
2153 brw_scratch_surface_idx(p
),
2157 true, /* header_present */
2158 0, /* not a render target */
2159 send_commit_msg
, /* response_length */
2167 * Read a block of owords (half a GRF each) from the scratch buffer
2168 * using a constant index per channel.
2170 * Offset must be aligned to oword size (16 bytes). Used for register
2174 brw_oword_block_read_scratch(struct brw_codegen
*p
,
2175 struct brw_reg dest
,
2180 const struct brw_device_info
*devinfo
= p
->devinfo
;
2182 if (devinfo
->gen
>= 6)
2185 if (p
->devinfo
->gen
>= 7) {
2186 /* On gen 7 and above, we no longer have message registers and we can
2187 * send from any register we want. By using the destination register
2188 * for the message, we guarantee that the implied message write won't
2189 * accidentally overwrite anything. This has been a problem because
2190 * the MRF registers and source for the final FB write are both fixed
2193 mrf
= retype(dest
, BRW_REGISTER_TYPE_UD
);
2195 mrf
= retype(mrf
, BRW_REGISTER_TYPE_UD
);
2197 dest
= retype(dest
, BRW_REGISTER_TYPE_UW
);
2199 const unsigned rlen
= num_regs
;
2200 const unsigned msg_control
=
2201 (num_regs
== 1 ? BRW_DATAPORT_OWORD_BLOCK_2_OWORDS
:
2202 num_regs
== 2 ? BRW_DATAPORT_OWORD_BLOCK_4_OWORDS
:
2203 num_regs
== 4 ? BRW_DATAPORT_OWORD_BLOCK_8_OWORDS
: 0);
2204 assert(msg_control
);
2207 brw_push_insn_state(p
);
2208 brw_set_default_exec_size(p
, BRW_EXECUTE_8
);
2209 brw_set_default_compression_control(p
, BRW_COMPRESSION_NONE
);
2210 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
2212 brw_MOV(p
, mrf
, retype(brw_vec8_grf(0, 0), BRW_REGISTER_TYPE_UD
));
2214 /* set message header global offset field (reg 0, element 2) */
2215 brw_MOV(p
, get_element_ud(mrf
, 2), brw_imm_ud(offset
));
2217 brw_pop_insn_state(p
);
2221 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_SEND
);
2223 assert(brw_inst_pred_control(devinfo
, insn
) == 0);
2224 brw_inst_set_compression(devinfo
, insn
, false);
2226 brw_set_dest(p
, insn
, dest
); /* UW? */
2227 if (devinfo
->gen
>= 6) {
2228 brw_set_src0(p
, insn
, mrf
);
2230 brw_set_src0(p
, insn
, brw_null_reg());
2231 brw_inst_set_base_mrf(devinfo
, insn
, mrf
.nr
);
2234 brw_set_dp_read_message(p
,
2236 brw_scratch_surface_idx(p
),
2238 BRW_DATAPORT_READ_MESSAGE_OWORD_BLOCK_READ
, /* msg_type */
2239 BRW_DATAPORT_READ_TARGET_RENDER_CACHE
,
2241 true, /* header_present */
2247 gen7_block_read_scratch(struct brw_codegen
*p
,
2248 struct brw_reg dest
,
2252 const struct brw_device_info
*devinfo
= p
->devinfo
;
2253 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_SEND
);
2254 assert(brw_inst_pred_control(devinfo
, insn
) == BRW_PREDICATE_NONE
);
2256 brw_set_dest(p
, insn
, retype(dest
, BRW_REGISTER_TYPE_UW
));
2258 /* The HW requires that the header is present; this is to get the g0.5
2261 brw_set_src0(p
, insn
, brw_vec8_grf(0, 0));
2263 /* According to the docs, offset is "A 12-bit HWord offset into the memory
2264 * Immediate Memory buffer as specified by binding table 0xFF." An HWORD
2265 * is 32 bytes, which happens to be the size of a register.
2268 assert(offset
< (1 << 12));
2270 gen7_set_dp_scratch_message(p
, insn
,
2271 false, /* scratch read */
2273 false, /* invalidate after read */
2276 1, /* mlen: just g0 */
2277 num_regs
, /* rlen */
2278 true); /* header present */
2282 * Read a float[4] vector from the data port Data Cache (const buffer).
2283 * Location (in buffer) should be a multiple of 16.
2284 * Used for fetching shader constants.
2286 void brw_oword_block_read(struct brw_codegen
*p
,
2287 struct brw_reg dest
,
2290 uint32_t bind_table_index
)
2292 const struct brw_device_info
*devinfo
= p
->devinfo
;
2294 /* On newer hardware, offset is in units of owords. */
2295 if (devinfo
->gen
>= 6)
2298 mrf
= retype(mrf
, BRW_REGISTER_TYPE_UD
);
2300 brw_push_insn_state(p
);
2301 brw_set_default_exec_size(p
, BRW_EXECUTE_8
);
2302 brw_set_default_predicate_control(p
, BRW_PREDICATE_NONE
);
2303 brw_set_default_compression_control(p
, BRW_COMPRESSION_NONE
);
2304 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
2306 brw_MOV(p
, mrf
, retype(brw_vec8_grf(0, 0), BRW_REGISTER_TYPE_UD
));
2308 /* set message header global offset field (reg 0, element 2) */
2310 retype(brw_vec1_reg(BRW_MESSAGE_REGISTER_FILE
,
2312 2), BRW_REGISTER_TYPE_UD
),
2313 brw_imm_ud(offset
));
2315 brw_inst
*insn
= next_insn(p
, BRW_OPCODE_SEND
);
2317 /* cast dest to a uword[8] vector */
2318 dest
= retype(vec8(dest
), BRW_REGISTER_TYPE_UW
);
2320 brw_set_dest(p
, insn
, dest
);
2321 if (devinfo
->gen
>= 6) {
2322 brw_set_src0(p
, insn
, mrf
);
2324 brw_set_src0(p
, insn
, brw_null_reg());
2325 brw_inst_set_base_mrf(devinfo
, insn
, mrf
.nr
);
2328 brw_set_dp_read_message(p
,
2331 BRW_DATAPORT_OWORD_BLOCK_1_OWORDLOW
,
2332 BRW_DATAPORT_READ_MESSAGE_OWORD_BLOCK_READ
,
2333 BRW_DATAPORT_READ_TARGET_DATA_CACHE
,
2335 true, /* header_present */
2336 1); /* response_length (1 reg, 2 owords!) */
2338 brw_pop_insn_state(p
);
2342 void brw_fb_WRITE(struct brw_codegen
*p
,
2343 struct brw_reg payload
,
2344 struct brw_reg implied_header
,
2345 unsigned msg_control
,
2346 unsigned binding_table_index
,
2347 unsigned msg_length
,
2348 unsigned response_length
,
2350 bool last_render_target
,
2351 bool header_present
)
2353 const struct brw_device_info
*devinfo
= p
->devinfo
;
2356 struct brw_reg dest
, src0
;
2358 if (brw_inst_exec_size(devinfo
, p
->current
) >= BRW_EXECUTE_16
)
2359 dest
= retype(vec16(brw_null_reg()), BRW_REGISTER_TYPE_UW
);
2361 dest
= retype(vec8(brw_null_reg()), BRW_REGISTER_TYPE_UW
);
2363 if (devinfo
->gen
>= 6) {
2364 insn
= next_insn(p
, BRW_OPCODE_SENDC
);
2366 insn
= next_insn(p
, BRW_OPCODE_SEND
);
2368 brw_inst_set_compression(devinfo
, insn
, false);
2370 if (devinfo
->gen
>= 6) {
2371 /* headerless version, just submit color payload */
2374 msg_type
= GEN6_DATAPORT_WRITE_MESSAGE_RENDER_TARGET_WRITE
;
2376 assert(payload
.file
== BRW_MESSAGE_REGISTER_FILE
);
2377 brw_inst_set_base_mrf(devinfo
, insn
, payload
.nr
);
2378 src0
= implied_header
;
2380 msg_type
= BRW_DATAPORT_WRITE_MESSAGE_RENDER_TARGET_WRITE
;
2383 brw_set_dest(p
, insn
, dest
);
2384 brw_set_src0(p
, insn
, src0
);
2385 brw_set_dp_write_message(p
,
2387 binding_table_index
,
2395 0 /* send_commit_msg */);
2400 * Texture sample instruction.
2401 * Note: the msg_type plus msg_length values determine exactly what kind
2402 * of sampling operation is performed. See volume 4, page 161 of docs.
2404 void brw_SAMPLE(struct brw_codegen
*p
,
2405 struct brw_reg dest
,
2406 unsigned msg_reg_nr
,
2407 struct brw_reg src0
,
2408 unsigned binding_table_index
,
2411 unsigned response_length
,
2412 unsigned msg_length
,
2413 unsigned header_present
,
2415 unsigned return_format
)
2417 const struct brw_device_info
*devinfo
= p
->devinfo
;
2420 if (msg_reg_nr
!= -1)
2421 gen6_resolve_implied_move(p
, &src0
, msg_reg_nr
);
2423 insn
= next_insn(p
, BRW_OPCODE_SEND
);
2424 brw_inst_set_pred_control(devinfo
, insn
, BRW_PREDICATE_NONE
); /* XXX */
2426 /* From the 965 PRM (volume 4, part 1, section 14.2.41):
2428 * "Instruction compression is not allowed for this instruction (that
2429 * is, send). The hardware behavior is undefined if this instruction is
2430 * set as compressed. However, compress control can be set to "SecHalf"
2431 * to affect the EMask generation."
2433 * No similar wording is found in later PRMs, but there are examples
2434 * utilizing send with SecHalf. More importantly, SIMD8 sampler messages
2435 * are allowed in SIMD16 mode and they could not work without SecHalf. For
2436 * these reasons, we allow BRW_COMPRESSION_2NDHALF here.
2438 brw_inst_set_compression(devinfo
, insn
, false);
2440 if (devinfo
->gen
< 6)
2441 brw_inst_set_base_mrf(devinfo
, insn
, msg_reg_nr
);
2443 brw_set_dest(p
, insn
, dest
);
2444 brw_set_src0(p
, insn
, src0
);
2445 brw_set_sampler_message(p
, insn
,
2446 binding_table_index
,
2456 /* Adjust the message header's sampler state pointer to
2457 * select the correct group of 16 samplers.
2459 void brw_adjust_sampler_state_pointer(struct brw_codegen
*p
,
2460 struct brw_reg header
,
2461 struct brw_reg sampler_index
)
2463 /* The "Sampler Index" field can only store values between 0 and 15.
2464 * However, we can add an offset to the "Sampler State Pointer"
2465 * field, effectively selecting a different set of 16 samplers.
2467 * The "Sampler State Pointer" needs to be aligned to a 32-byte
2468 * offset, and each sampler state is only 16-bytes, so we can't
2469 * exclusively use the offset - we have to use both.
2472 const struct brw_device_info
*devinfo
= p
->devinfo
;
2474 if (sampler_index
.file
== BRW_IMMEDIATE_VALUE
) {
2475 const int sampler_state_size
= 16; /* 16 bytes */
2476 uint32_t sampler
= sampler_index
.ud
;
2478 if (sampler
>= 16) {
2479 assert(devinfo
->is_haswell
|| devinfo
->gen
>= 8);
2481 get_element_ud(header
, 3),
2482 get_element_ud(brw_vec8_grf(0, 0), 3),
2483 brw_imm_ud(16 * (sampler
/ 16) * sampler_state_size
));
2486 /* Non-const sampler array indexing case */
2487 if (devinfo
->gen
< 8 && !devinfo
->is_haswell
) {
2491 struct brw_reg temp
= get_element_ud(header
, 3);
2493 brw_AND(p
, temp
, get_element_ud(sampler_index
, 0), brw_imm_ud(0x0f0));
2494 brw_SHL(p
, temp
, temp
, brw_imm_ud(4));
2496 get_element_ud(header
, 3),
2497 get_element_ud(brw_vec8_grf(0, 0), 3),
2502 /* All these variables are pretty confusing - we might be better off
2503 * using bitmasks and macros for this, in the old style. Or perhaps
2504 * just having the caller instantiate the fields in dword3 itself.
2506 void brw_urb_WRITE(struct brw_codegen
*p
,
2507 struct brw_reg dest
,
2508 unsigned msg_reg_nr
,
2509 struct brw_reg src0
,
2510 enum brw_urb_write_flags flags
,
2511 unsigned msg_length
,
2512 unsigned response_length
,
2516 const struct brw_device_info
*devinfo
= p
->devinfo
;
2519 gen6_resolve_implied_move(p
, &src0
, msg_reg_nr
);
2521 if (devinfo
->gen
>= 7 && !(flags
& BRW_URB_WRITE_USE_CHANNEL_MASKS
)) {
2522 /* Enable Channel Masks in the URB_WRITE_HWORD message header */
2523 brw_push_insn_state(p
);
2524 brw_set_default_access_mode(p
, BRW_ALIGN_1
);
2525 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
2526 brw_OR(p
, retype(brw_vec1_reg(BRW_MESSAGE_REGISTER_FILE
, msg_reg_nr
, 5),
2527 BRW_REGISTER_TYPE_UD
),
2528 retype(brw_vec1_grf(0, 5), BRW_REGISTER_TYPE_UD
),
2529 brw_imm_ud(0xff00));
2530 brw_pop_insn_state(p
);
2533 insn
= next_insn(p
, BRW_OPCODE_SEND
);
2535 assert(msg_length
< BRW_MAX_MRF(devinfo
->gen
));
2537 brw_set_dest(p
, insn
, dest
);
2538 brw_set_src0(p
, insn
, src0
);
2539 brw_set_src1(p
, insn
, brw_imm_d(0));
2541 if (devinfo
->gen
< 6)
2542 brw_inst_set_base_mrf(devinfo
, insn
, msg_reg_nr
);
2544 brw_set_urb_message(p
,
2554 brw_send_indirect_message(struct brw_codegen
*p
,
2557 struct brw_reg payload
,
2558 struct brw_reg desc
)
2560 const struct brw_device_info
*devinfo
= p
->devinfo
;
2561 struct brw_inst
*send
;
2564 dst
= retype(dst
, BRW_REGISTER_TYPE_UW
);
2566 assert(desc
.type
== BRW_REGISTER_TYPE_UD
);
2568 /* We hold on to the setup instruction (the SEND in the direct case, the OR
2569 * in the indirect case) by its index in the instruction store. The
2570 * pointer returned by next_insn() may become invalid if emitting the SEND
2571 * in the indirect case reallocs the store.
2574 if (desc
.file
== BRW_IMMEDIATE_VALUE
) {
2576 send
= next_insn(p
, BRW_OPCODE_SEND
);
2577 brw_set_src1(p
, send
, desc
);
2580 struct brw_reg addr
= retype(brw_address_reg(0), BRW_REGISTER_TYPE_UD
);
2582 brw_push_insn_state(p
);
2583 brw_set_default_access_mode(p
, BRW_ALIGN_1
);
2584 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
2585 brw_set_default_predicate_control(p
, BRW_PREDICATE_NONE
);
2587 /* Load the indirect descriptor to an address register using OR so the
2588 * caller can specify additional descriptor bits with the usual
2589 * brw_set_*_message() helper functions.
2592 brw_OR(p
, addr
, desc
, brw_imm_ud(0));
2594 brw_pop_insn_state(p
);
2596 send
= next_insn(p
, BRW_OPCODE_SEND
);
2597 brw_set_src1(p
, send
, addr
);
2600 if (dst
.width
< BRW_EXECUTE_8
)
2601 brw_inst_set_exec_size(devinfo
, send
, dst
.width
);
2603 brw_set_dest(p
, send
, dst
);
2604 brw_set_src0(p
, send
, retype(payload
, BRW_REGISTER_TYPE_UD
));
2605 brw_inst_set_sfid(devinfo
, send
, sfid
);
2607 return &p
->store
[setup
];
2610 static struct brw_inst
*
2611 brw_send_indirect_surface_message(struct brw_codegen
*p
,
2614 struct brw_reg payload
,
2615 struct brw_reg surface
,
2616 unsigned message_len
,
2617 unsigned response_len
,
2618 bool header_present
)
2620 const struct brw_device_info
*devinfo
= p
->devinfo
;
2621 struct brw_inst
*insn
;
2623 if (surface
.file
!= BRW_IMMEDIATE_VALUE
) {
2624 struct brw_reg addr
= retype(brw_address_reg(0), BRW_REGISTER_TYPE_UD
);
2626 brw_push_insn_state(p
);
2627 brw_set_default_access_mode(p
, BRW_ALIGN_1
);
2628 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
2629 brw_set_default_predicate_control(p
, BRW_PREDICATE_NONE
);
2631 /* Mask out invalid bits from the surface index to avoid hangs e.g. when
2632 * some surface array is accessed out of bounds.
2634 insn
= brw_AND(p
, addr
,
2635 suboffset(vec1(retype(surface
, BRW_REGISTER_TYPE_UD
)),
2636 BRW_GET_SWZ(surface
.swizzle
, 0)),
2639 brw_pop_insn_state(p
);
2644 insn
= brw_send_indirect_message(p
, sfid
, dst
, payload
, surface
);
2645 brw_inst_set_mlen(devinfo
, insn
, message_len
);
2646 brw_inst_set_rlen(devinfo
, insn
, response_len
);
2647 brw_inst_set_header_present(devinfo
, insn
, header_present
);
2653 while_jumps_before_offset(const struct brw_device_info
*devinfo
,
2654 brw_inst
*insn
, int while_offset
, int start_offset
)
2656 int scale
= 16 / brw_jump_scale(devinfo
);
2657 int jip
= devinfo
->gen
== 6 ? brw_inst_gen6_jump_count(devinfo
, insn
)
2658 : brw_inst_jip(devinfo
, insn
);
2659 return while_offset
+ jip
* scale
<= start_offset
;
2664 brw_find_next_block_end(struct brw_codegen
*p
, int start_offset
)
2667 void *store
= p
->store
;
2668 const struct brw_device_info
*devinfo
= p
->devinfo
;
2672 for (offset
= next_offset(devinfo
, store
, start_offset
);
2673 offset
< p
->next_insn_offset
;
2674 offset
= next_offset(devinfo
, store
, offset
)) {
2675 brw_inst
*insn
= store
+ offset
;
2677 switch (brw_inst_opcode(devinfo
, insn
)) {
2681 case BRW_OPCODE_ENDIF
:
2686 case BRW_OPCODE_WHILE
:
2687 /* If the while doesn't jump before our instruction, it's the end
2688 * of a sibling do...while loop. Ignore it.
2690 if (!while_jumps_before_offset(devinfo
, insn
, offset
, start_offset
))
2693 case BRW_OPCODE_ELSE
:
2694 case BRW_OPCODE_HALT
:
2703 /* There is no DO instruction on gen6, so to find the end of the loop
2704 * we have to see if the loop is jumping back before our start
2708 brw_find_loop_end(struct brw_codegen
*p
, int start_offset
)
2710 const struct brw_device_info
*devinfo
= p
->devinfo
;
2712 void *store
= p
->store
;
2714 assert(devinfo
->gen
>= 6);
2716 /* Always start after the instruction (such as a WHILE) we're trying to fix
2719 for (offset
= next_offset(devinfo
, store
, start_offset
);
2720 offset
< p
->next_insn_offset
;
2721 offset
= next_offset(devinfo
, store
, offset
)) {
2722 brw_inst
*insn
= store
+ offset
;
2724 if (brw_inst_opcode(devinfo
, insn
) == BRW_OPCODE_WHILE
) {
2725 if (while_jumps_before_offset(devinfo
, insn
, offset
, start_offset
))
2729 assert(!"not reached");
2730 return start_offset
;
2733 /* After program generation, go back and update the UIP and JIP of
2734 * BREAK, CONT, and HALT instructions to their correct locations.
2737 brw_set_uip_jip(struct brw_codegen
*p
)
2739 const struct brw_device_info
*devinfo
= p
->devinfo
;
2741 int br
= brw_jump_scale(devinfo
);
2742 int scale
= 16 / br
;
2743 void *store
= p
->store
;
2745 if (devinfo
->gen
< 6)
2748 for (offset
= 0; offset
< p
->next_insn_offset
;
2749 offset
= next_offset(devinfo
, store
, offset
)) {
2750 brw_inst
*insn
= store
+ offset
;
2752 if (brw_inst_cmpt_control(devinfo
, insn
)) {
2753 /* Fixups for compacted BREAK/CONTINUE not supported yet. */
2754 assert(brw_inst_opcode(devinfo
, insn
) != BRW_OPCODE_BREAK
&&
2755 brw_inst_opcode(devinfo
, insn
) != BRW_OPCODE_CONTINUE
&&
2756 brw_inst_opcode(devinfo
, insn
) != BRW_OPCODE_HALT
);
2760 int block_end_offset
= brw_find_next_block_end(p
, offset
);
2761 switch (brw_inst_opcode(devinfo
, insn
)) {
2762 case BRW_OPCODE_BREAK
:
2763 assert(block_end_offset
!= 0);
2764 brw_inst_set_jip(devinfo
, insn
, (block_end_offset
- offset
) / scale
);
2765 /* Gen7 UIP points to WHILE; Gen6 points just after it */
2766 brw_inst_set_uip(devinfo
, insn
,
2767 (brw_find_loop_end(p
, offset
) - offset
+
2768 (devinfo
->gen
== 6 ? 16 : 0)) / scale
);
2770 case BRW_OPCODE_CONTINUE
:
2771 assert(block_end_offset
!= 0);
2772 brw_inst_set_jip(devinfo
, insn
, (block_end_offset
- offset
) / scale
);
2773 brw_inst_set_uip(devinfo
, insn
,
2774 (brw_find_loop_end(p
, offset
) - offset
) / scale
);
2776 assert(brw_inst_uip(devinfo
, insn
) != 0);
2777 assert(brw_inst_jip(devinfo
, insn
) != 0);
2780 case BRW_OPCODE_ENDIF
: {
2781 int32_t jump
= (block_end_offset
== 0) ?
2782 1 * br
: (block_end_offset
- offset
) / scale
;
2783 if (devinfo
->gen
>= 7)
2784 brw_inst_set_jip(devinfo
, insn
, jump
);
2786 brw_inst_set_gen6_jump_count(devinfo
, insn
, jump
);
2790 case BRW_OPCODE_HALT
:
2791 /* From the Sandy Bridge PRM (volume 4, part 2, section 8.3.19):
2793 * "In case of the halt instruction not inside any conditional
2794 * code block, the value of <JIP> and <UIP> should be the
2795 * same. In case of the halt instruction inside conditional code
2796 * block, the <UIP> should be the end of the program, and the
2797 * <JIP> should be end of the most inner conditional code block."
2799 * The uip will have already been set by whoever set up the
2802 if (block_end_offset
== 0) {
2803 brw_inst_set_jip(devinfo
, insn
, brw_inst_uip(devinfo
, insn
));
2805 brw_inst_set_jip(devinfo
, insn
, (block_end_offset
- offset
) / scale
);
2807 assert(brw_inst_uip(devinfo
, insn
) != 0);
2808 assert(brw_inst_jip(devinfo
, insn
) != 0);
2814 void brw_ff_sync(struct brw_codegen
*p
,
2815 struct brw_reg dest
,
2816 unsigned msg_reg_nr
,
2817 struct brw_reg src0
,
2819 unsigned response_length
,
2822 const struct brw_device_info
*devinfo
= p
->devinfo
;
2825 gen6_resolve_implied_move(p
, &src0
, msg_reg_nr
);
2827 insn
= next_insn(p
, BRW_OPCODE_SEND
);
2828 brw_set_dest(p
, insn
, dest
);
2829 brw_set_src0(p
, insn
, src0
);
2830 brw_set_src1(p
, insn
, brw_imm_d(0));
2832 if (devinfo
->gen
< 6)
2833 brw_inst_set_base_mrf(devinfo
, insn
, msg_reg_nr
);
2835 brw_set_ff_sync_message(p
,
2843 * Emit the SEND instruction necessary to generate stream output data on Gen6
2844 * (for transform feedback).
2846 * If send_commit_msg is true, this is the last piece of stream output data
2847 * from this thread, so send the data as a committed write. According to the
2848 * Sandy Bridge PRM (volume 2 part 1, section 4.5.1):
2850 * "Prior to End of Thread with a URB_WRITE, the kernel must ensure all
2851 * writes are complete by sending the final write as a committed write."
2854 brw_svb_write(struct brw_codegen
*p
,
2855 struct brw_reg dest
,
2856 unsigned msg_reg_nr
,
2857 struct brw_reg src0
,
2858 unsigned binding_table_index
,
2859 bool send_commit_msg
)
2863 gen6_resolve_implied_move(p
, &src0
, msg_reg_nr
);
2865 insn
= next_insn(p
, BRW_OPCODE_SEND
);
2866 brw_set_dest(p
, insn
, dest
);
2867 brw_set_src0(p
, insn
, src0
);
2868 brw_set_src1(p
, insn
, brw_imm_d(0));
2869 brw_set_dp_write_message(p
, insn
,
2870 binding_table_index
,
2871 0, /* msg_control: ignored */
2872 GEN6_DATAPORT_WRITE_MESSAGE_STREAMED_VB_WRITE
,
2874 true, /* header_present */
2875 0, /* last_render_target: ignored */
2876 send_commit_msg
, /* response_length */
2877 0, /* end_of_thread */
2878 send_commit_msg
); /* send_commit_msg */
2882 brw_surface_payload_size(struct brw_codegen
*p
,
2883 unsigned num_channels
,
2888 brw_inst_access_mode(p
->devinfo
, p
->current
) == BRW_ALIGN_16
)
2890 else if (has_simd16
&&
2891 brw_inst_exec_size(p
->devinfo
, p
->current
) == BRW_EXECUTE_16
)
2892 return 2 * num_channels
;
2894 return num_channels
;
2898 brw_set_dp_untyped_atomic_message(struct brw_codegen
*p
,
2901 bool response_expected
)
2903 const struct brw_device_info
*devinfo
= p
->devinfo
;
2904 unsigned msg_control
=
2905 atomic_op
| /* Atomic Operation Type: BRW_AOP_* */
2906 (response_expected
? 1 << 5 : 0); /* Return data expected */
2908 if (devinfo
->gen
>= 8 || devinfo
->is_haswell
) {
2909 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
2910 if (brw_inst_exec_size(devinfo
, p
->current
) == BRW_EXECUTE_8
)
2911 msg_control
|= 1 << 4; /* SIMD8 mode */
2913 brw_inst_set_dp_msg_type(devinfo
, insn
,
2914 HSW_DATAPORT_DC_PORT1_UNTYPED_ATOMIC_OP
);
2916 brw_inst_set_dp_msg_type(devinfo
, insn
,
2917 HSW_DATAPORT_DC_PORT1_UNTYPED_ATOMIC_OP_SIMD4X2
);
2920 brw_inst_set_dp_msg_type(devinfo
, insn
,
2921 GEN7_DATAPORT_DC_UNTYPED_ATOMIC_OP
);
2923 if (brw_inst_exec_size(devinfo
, p
->current
) == BRW_EXECUTE_8
)
2924 msg_control
|= 1 << 4; /* SIMD8 mode */
2927 brw_inst_set_dp_msg_control(devinfo
, insn
, msg_control
);
2931 brw_untyped_atomic(struct brw_codegen
*p
,
2933 struct brw_reg payload
,
2934 struct brw_reg surface
,
2936 unsigned msg_length
,
2937 bool response_expected
)
2939 const struct brw_device_info
*devinfo
= p
->devinfo
;
2940 const unsigned sfid
= (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
2941 HSW_SFID_DATAPORT_DATA_CACHE_1
:
2942 GEN7_SFID_DATAPORT_DATA_CACHE
);
2943 const bool align1
= brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
;
2944 /* Mask out unused components -- This is especially important in Align16
2945 * mode on generations that don't have native support for SIMD4x2 atomics,
2946 * because unused but enabled components will cause the dataport to perform
2947 * additional atomic operations on the addresses that happen to be in the
2948 * uninitialized Y, Z and W coordinates of the payload.
2950 const unsigned mask
= align1
? WRITEMASK_XYZW
: WRITEMASK_X
;
2951 struct brw_inst
*insn
= brw_send_indirect_surface_message(
2952 p
, sfid
, brw_writemask(dst
, mask
), payload
, surface
, msg_length
,
2953 brw_surface_payload_size(p
, response_expected
,
2954 devinfo
->gen
>= 8 || devinfo
->is_haswell
, true),
2957 brw_set_dp_untyped_atomic_message(
2958 p
, insn
, atomic_op
, response_expected
);
2962 brw_set_dp_untyped_surface_read_message(struct brw_codegen
*p
,
2963 struct brw_inst
*insn
,
2964 unsigned num_channels
)
2966 const struct brw_device_info
*devinfo
= p
->devinfo
;
2967 /* Set mask of 32-bit channels to drop. */
2968 unsigned msg_control
= 0xf & (0xf << num_channels
);
2970 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
2971 if (brw_inst_exec_size(devinfo
, p
->current
) == BRW_EXECUTE_16
)
2972 msg_control
|= 1 << 4; /* SIMD16 mode */
2974 msg_control
|= 2 << 4; /* SIMD8 mode */
2977 brw_inst_set_dp_msg_type(devinfo
, insn
,
2978 (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
2979 HSW_DATAPORT_DC_PORT1_UNTYPED_SURFACE_READ
:
2980 GEN7_DATAPORT_DC_UNTYPED_SURFACE_READ
));
2981 brw_inst_set_dp_msg_control(devinfo
, insn
, msg_control
);
2985 brw_untyped_surface_read(struct brw_codegen
*p
,
2987 struct brw_reg payload
,
2988 struct brw_reg surface
,
2989 unsigned msg_length
,
2990 unsigned num_channels
)
2992 const struct brw_device_info
*devinfo
= p
->devinfo
;
2993 const unsigned sfid
= (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
2994 HSW_SFID_DATAPORT_DATA_CACHE_1
:
2995 GEN7_SFID_DATAPORT_DATA_CACHE
);
2996 struct brw_inst
*insn
= brw_send_indirect_surface_message(
2997 p
, sfid
, dst
, payload
, surface
, msg_length
,
2998 brw_surface_payload_size(p
, num_channels
, true, true),
3001 brw_set_dp_untyped_surface_read_message(
3002 p
, insn
, num_channels
);
3006 brw_set_dp_untyped_surface_write_message(struct brw_codegen
*p
,
3007 struct brw_inst
*insn
,
3008 unsigned num_channels
)
3010 const struct brw_device_info
*devinfo
= p
->devinfo
;
3011 /* Set mask of 32-bit channels to drop. */
3012 unsigned msg_control
= 0xf & (0xf << num_channels
);
3014 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3015 if (brw_inst_exec_size(devinfo
, p
->current
) == BRW_EXECUTE_16
)
3016 msg_control
|= 1 << 4; /* SIMD16 mode */
3018 msg_control
|= 2 << 4; /* SIMD8 mode */
3020 if (devinfo
->gen
>= 8 || devinfo
->is_haswell
)
3021 msg_control
|= 0 << 4; /* SIMD4x2 mode */
3023 msg_control
|= 2 << 4; /* SIMD8 mode */
3026 brw_inst_set_dp_msg_type(devinfo
, insn
,
3027 devinfo
->gen
>= 8 || devinfo
->is_haswell
?
3028 HSW_DATAPORT_DC_PORT1_UNTYPED_SURFACE_WRITE
:
3029 GEN7_DATAPORT_DC_UNTYPED_SURFACE_WRITE
);
3030 brw_inst_set_dp_msg_control(devinfo
, insn
, msg_control
);
3034 brw_untyped_surface_write(struct brw_codegen
*p
,
3035 struct brw_reg payload
,
3036 struct brw_reg surface
,
3037 unsigned msg_length
,
3038 unsigned num_channels
)
3040 const struct brw_device_info
*devinfo
= p
->devinfo
;
3041 const unsigned sfid
= (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
3042 HSW_SFID_DATAPORT_DATA_CACHE_1
:
3043 GEN7_SFID_DATAPORT_DATA_CACHE
);
3044 const bool align1
= brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
;
3045 /* Mask out unused components -- See comment in brw_untyped_atomic(). */
3046 const unsigned mask
= devinfo
->gen
== 7 && !devinfo
->is_haswell
&& !align1
?
3047 WRITEMASK_X
: WRITEMASK_XYZW
;
3048 struct brw_inst
*insn
= brw_send_indirect_surface_message(
3049 p
, sfid
, brw_writemask(brw_null_reg(), mask
),
3050 payload
, surface
, msg_length
, 0, align1
);
3052 brw_set_dp_untyped_surface_write_message(
3053 p
, insn
, num_channels
);
3057 brw_set_dp_typed_atomic_message(struct brw_codegen
*p
,
3058 struct brw_inst
*insn
,
3060 bool response_expected
)
3062 const struct brw_device_info
*devinfo
= p
->devinfo
;
3063 unsigned msg_control
=
3064 atomic_op
| /* Atomic Operation Type: BRW_AOP_* */
3065 (response_expected
? 1 << 5 : 0); /* Return data expected */
3067 if (devinfo
->gen
>= 8 || devinfo
->is_haswell
) {
3068 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3069 if (brw_inst_qtr_control(devinfo
, p
->current
) % 2 == 1)
3070 msg_control
|= 1 << 4; /* Use high 8 slots of the sample mask */
3072 brw_inst_set_dp_msg_type(devinfo
, insn
,
3073 HSW_DATAPORT_DC_PORT1_TYPED_ATOMIC_OP
);
3075 brw_inst_set_dp_msg_type(devinfo
, insn
,
3076 HSW_DATAPORT_DC_PORT1_TYPED_ATOMIC_OP_SIMD4X2
);
3080 brw_inst_set_dp_msg_type(devinfo
, insn
,
3081 GEN7_DATAPORT_RC_TYPED_ATOMIC_OP
);
3083 if (brw_inst_qtr_control(devinfo
, p
->current
) % 2 == 1)
3084 msg_control
|= 1 << 4; /* Use high 8 slots of the sample mask */
3087 brw_inst_set_dp_msg_control(devinfo
, insn
, msg_control
);
3091 brw_typed_atomic(struct brw_codegen
*p
,
3093 struct brw_reg payload
,
3094 struct brw_reg surface
,
3096 unsigned msg_length
,
3097 bool response_expected
) {
3098 const struct brw_device_info
*devinfo
= p
->devinfo
;
3099 const unsigned sfid
= (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
3100 HSW_SFID_DATAPORT_DATA_CACHE_1
:
3101 GEN6_SFID_DATAPORT_RENDER_CACHE
);
3102 const bool align1
= (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
);
3103 /* Mask out unused components -- See comment in brw_untyped_atomic(). */
3104 const unsigned mask
= align1
? WRITEMASK_XYZW
: WRITEMASK_X
;
3105 struct brw_inst
*insn
= brw_send_indirect_surface_message(
3106 p
, sfid
, brw_writemask(dst
, mask
), payload
, surface
, msg_length
,
3107 brw_surface_payload_size(p
, response_expected
,
3108 devinfo
->gen
>= 8 || devinfo
->is_haswell
, false),
3111 brw_set_dp_typed_atomic_message(
3112 p
, insn
, atomic_op
, response_expected
);
3116 brw_set_dp_typed_surface_read_message(struct brw_codegen
*p
,
3117 struct brw_inst
*insn
,
3118 unsigned num_channels
)
3120 const struct brw_device_info
*devinfo
= p
->devinfo
;
3121 /* Set mask of unused channels. */
3122 unsigned msg_control
= 0xf & (0xf << num_channels
);
3124 if (devinfo
->gen
>= 8 || devinfo
->is_haswell
) {
3125 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3126 if (brw_inst_qtr_control(devinfo
, p
->current
) % 2 == 1)
3127 msg_control
|= 2 << 4; /* Use high 8 slots of the sample mask */
3129 msg_control
|= 1 << 4; /* Use low 8 slots of the sample mask */
3132 brw_inst_set_dp_msg_type(devinfo
, insn
,
3133 HSW_DATAPORT_DC_PORT1_TYPED_SURFACE_READ
);
3135 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3136 if (brw_inst_qtr_control(devinfo
, p
->current
) % 2 == 1)
3137 msg_control
|= 1 << 5; /* Use high 8 slots of the sample mask */
3140 brw_inst_set_dp_msg_type(devinfo
, insn
,
3141 GEN7_DATAPORT_RC_TYPED_SURFACE_READ
);
3144 brw_inst_set_dp_msg_control(devinfo
, insn
, msg_control
);
3148 brw_typed_surface_read(struct brw_codegen
*p
,
3150 struct brw_reg payload
,
3151 struct brw_reg surface
,
3152 unsigned msg_length
,
3153 unsigned num_channels
)
3155 const struct brw_device_info
*devinfo
= p
->devinfo
;
3156 const unsigned sfid
= (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
3157 HSW_SFID_DATAPORT_DATA_CACHE_1
:
3158 GEN6_SFID_DATAPORT_RENDER_CACHE
);
3159 struct brw_inst
*insn
= brw_send_indirect_surface_message(
3160 p
, sfid
, dst
, payload
, surface
, msg_length
,
3161 brw_surface_payload_size(p
, num_channels
,
3162 devinfo
->gen
>= 8 || devinfo
->is_haswell
, false),
3165 brw_set_dp_typed_surface_read_message(
3166 p
, insn
, num_channels
);
3170 brw_set_dp_typed_surface_write_message(struct brw_codegen
*p
,
3171 struct brw_inst
*insn
,
3172 unsigned num_channels
)
3174 const struct brw_device_info
*devinfo
= p
->devinfo
;
3175 /* Set mask of unused channels. */
3176 unsigned msg_control
= 0xf & (0xf << num_channels
);
3178 if (devinfo
->gen
>= 8 || devinfo
->is_haswell
) {
3179 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3180 if (brw_inst_qtr_control(devinfo
, p
->current
) % 2 == 1)
3181 msg_control
|= 2 << 4; /* Use high 8 slots of the sample mask */
3183 msg_control
|= 1 << 4; /* Use low 8 slots of the sample mask */
3186 brw_inst_set_dp_msg_type(devinfo
, insn
,
3187 HSW_DATAPORT_DC_PORT1_TYPED_SURFACE_WRITE
);
3190 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3191 if (brw_inst_qtr_control(devinfo
, p
->current
) % 2 == 1)
3192 msg_control
|= 1 << 5; /* Use high 8 slots of the sample mask */
3195 brw_inst_set_dp_msg_type(devinfo
, insn
,
3196 GEN7_DATAPORT_RC_TYPED_SURFACE_WRITE
);
3199 brw_inst_set_dp_msg_control(devinfo
, insn
, msg_control
);
3203 brw_typed_surface_write(struct brw_codegen
*p
,
3204 struct brw_reg payload
,
3205 struct brw_reg surface
,
3206 unsigned msg_length
,
3207 unsigned num_channels
)
3209 const struct brw_device_info
*devinfo
= p
->devinfo
;
3210 const unsigned sfid
= (devinfo
->gen
>= 8 || devinfo
->is_haswell
?
3211 HSW_SFID_DATAPORT_DATA_CACHE_1
:
3212 GEN6_SFID_DATAPORT_RENDER_CACHE
);
3213 const bool align1
= (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
);
3214 /* Mask out unused components -- See comment in brw_untyped_atomic(). */
3215 const unsigned mask
= (devinfo
->gen
== 7 && !devinfo
->is_haswell
&& !align1
?
3216 WRITEMASK_X
: WRITEMASK_XYZW
);
3217 struct brw_inst
*insn
= brw_send_indirect_surface_message(
3218 p
, sfid
, brw_writemask(brw_null_reg(), mask
),
3219 payload
, surface
, msg_length
, 0, true);
3221 brw_set_dp_typed_surface_write_message(
3222 p
, insn
, num_channels
);
3226 brw_set_memory_fence_message(struct brw_codegen
*p
,
3227 struct brw_inst
*insn
,
3228 enum brw_message_target sfid
,
3231 const struct brw_device_info
*devinfo
= p
->devinfo
;
3233 brw_set_message_descriptor(p
, insn
, sfid
,
3234 1 /* message length */,
3235 (commit_enable
? 1 : 0) /* response length */,
3236 true /* header present */,
3240 case GEN6_SFID_DATAPORT_RENDER_CACHE
:
3241 brw_inst_set_dp_msg_type(devinfo
, insn
, GEN7_DATAPORT_RC_MEMORY_FENCE
);
3243 case GEN7_SFID_DATAPORT_DATA_CACHE
:
3244 brw_inst_set_dp_msg_type(devinfo
, insn
, GEN7_DATAPORT_DC_MEMORY_FENCE
);
3247 unreachable("Not reached");
3251 brw_inst_set_dp_msg_control(devinfo
, insn
, 1 << 5);
3255 brw_memory_fence(struct brw_codegen
*p
,
3258 const struct brw_device_info
*devinfo
= p
->devinfo
;
3259 const bool commit_enable
= devinfo
->gen
== 7 && !devinfo
->is_haswell
;
3260 struct brw_inst
*insn
;
3262 brw_push_insn_state(p
);
3263 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
3264 brw_set_default_exec_size(p
, BRW_EXECUTE_1
);
3267 /* Set dst as destination for dependency tracking, the MEMORY_FENCE
3268 * message doesn't write anything back.
3270 insn
= next_insn(p
, BRW_OPCODE_SEND
);
3271 dst
= retype(dst
, BRW_REGISTER_TYPE_UW
);
3272 brw_set_dest(p
, insn
, dst
);
3273 brw_set_src0(p
, insn
, dst
);
3274 brw_set_memory_fence_message(p
, insn
, GEN7_SFID_DATAPORT_DATA_CACHE
,
3277 if (devinfo
->gen
== 7 && !devinfo
->is_haswell
) {
3278 /* IVB does typed surface access through the render cache, so we need to
3279 * flush it too. Use a different register so both flushes can be
3280 * pipelined by the hardware.
3282 insn
= next_insn(p
, BRW_OPCODE_SEND
);
3283 brw_set_dest(p
, insn
, offset(dst
, 1));
3284 brw_set_src0(p
, insn
, offset(dst
, 1));
3285 brw_set_memory_fence_message(p
, insn
, GEN6_SFID_DATAPORT_RENDER_CACHE
,
3288 /* Now write the response of the second message into the response of the
3289 * first to trigger a pipeline stall -- This way future render and data
3290 * cache messages will be properly ordered with respect to past data and
3291 * render cache messages.
3293 brw_MOV(p
, dst
, offset(dst
, 1));
3296 brw_pop_insn_state(p
);
3300 brw_pixel_interpolator_query(struct brw_codegen
*p
,
3301 struct brw_reg dest
,
3305 struct brw_reg data
,
3306 unsigned msg_length
,
3307 unsigned response_length
)
3309 const struct brw_device_info
*devinfo
= p
->devinfo
;
3310 struct brw_inst
*insn
;
3311 const uint16_t exec_size
= brw_inst_exec_size(devinfo
, p
->current
);
3313 /* brw_send_indirect_message will automatically use a direct send message
3314 * if data is actually immediate.
3316 insn
= brw_send_indirect_message(p
,
3317 GEN7_SFID_PIXEL_INTERPOLATOR
,
3321 brw_inst_set_mlen(devinfo
, insn
, msg_length
);
3322 brw_inst_set_rlen(devinfo
, insn
, response_length
);
3324 brw_inst_set_pi_simd_mode(devinfo
, insn
, exec_size
== BRW_EXECUTE_16
);
3325 brw_inst_set_pi_slot_group(devinfo
, insn
, 0); /* zero unless 32/64px dispatch */
3326 brw_inst_set_pi_nopersp(devinfo
, insn
, noperspective
);
3327 brw_inst_set_pi_message_type(devinfo
, insn
, mode
);
3331 brw_find_live_channel(struct brw_codegen
*p
, struct brw_reg dst
)
3333 const struct brw_device_info
*devinfo
= p
->devinfo
;
3336 assert(devinfo
->gen
>= 7);
3338 brw_push_insn_state(p
);
3340 if (brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
) {
3341 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
3343 if (devinfo
->gen
>= 8) {
3344 /* Getting the first active channel index is easy on Gen8: Just find
3345 * the first bit set in the mask register. The same register exists
3346 * on HSW already but it reads back as all ones when the current
3347 * instruction has execution masking disabled, so it's kind of
3350 inst
= brw_FBL(p
, vec1(dst
),
3351 retype(brw_mask_reg(0), BRW_REGISTER_TYPE_UD
));
3353 /* Quarter control has the effect of magically shifting the value of
3354 * this register. Make sure it's set to zero.
3356 brw_inst_set_qtr_control(devinfo
, inst
, GEN6_COMPRESSION_1Q
);
3358 const struct brw_reg flag
= retype(brw_flag_reg(1, 0),
3359 BRW_REGISTER_TYPE_UD
);
3361 brw_MOV(p
, flag
, brw_imm_ud(0));
3363 /* Run a 16-wide instruction returning zero with execution masking
3364 * and a conditional modifier enabled in order to get the current
3365 * execution mask in f1.0.
3367 inst
= brw_MOV(p
, brw_null_reg(), brw_imm_ud(0));
3368 brw_inst_set_exec_size(devinfo
, inst
, BRW_EXECUTE_16
);
3369 brw_inst_set_mask_control(devinfo
, inst
, BRW_MASK_ENABLE
);
3370 brw_inst_set_cond_modifier(devinfo
, inst
, BRW_CONDITIONAL_Z
);
3371 brw_inst_set_flag_reg_nr(devinfo
, inst
, 1);
3373 brw_FBL(p
, vec1(dst
), flag
);
3376 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
3378 if (devinfo
->gen
>= 8) {
3379 /* In SIMD4x2 mode the first active channel index is just the
3380 * negation of the first bit of the mask register.
3382 inst
= brw_AND(p
, brw_writemask(dst
, WRITEMASK_X
),
3383 negate(retype(brw_mask_reg(0), BRW_REGISTER_TYPE_UD
)),
3387 /* Overwrite the destination without and with execution masking to
3388 * find out which of the channels is active.
3390 brw_push_insn_state(p
);
3391 brw_set_default_exec_size(p
, BRW_EXECUTE_4
);
3392 brw_MOV(p
, brw_writemask(vec4(dst
), WRITEMASK_X
),
3395 inst
= brw_MOV(p
, brw_writemask(vec4(dst
), WRITEMASK_X
),
3397 brw_pop_insn_state(p
);
3398 brw_inst_set_mask_control(devinfo
, inst
, BRW_MASK_ENABLE
);
3402 brw_pop_insn_state(p
);
3406 brw_broadcast(struct brw_codegen
*p
,
3411 const struct brw_device_info
*devinfo
= p
->devinfo
;
3412 const bool align1
= brw_inst_access_mode(devinfo
, p
->current
) == BRW_ALIGN_1
;
3415 assert(src
.file
== BRW_GENERAL_REGISTER_FILE
&&
3416 src
.address_mode
== BRW_ADDRESS_DIRECT
);
3418 if ((src
.vstride
== 0 && (src
.hstride
== 0 || !align1
)) ||
3419 idx
.file
== BRW_IMMEDIATE_VALUE
) {
3420 /* Trivial, the source is already uniform or the index is a constant.
3421 * We will typically not get here if the optimizer is doing its job, but
3422 * asserting would be mean.
3424 const unsigned i
= idx
.file
== BRW_IMMEDIATE_VALUE
? idx
.ud
: 0;
3426 (align1
? stride(suboffset(src
, i
), 0, 1, 0) :
3427 stride(suboffset(src
, 4 * i
), 0, 4, 1)));
3430 const struct brw_reg addr
=
3431 retype(brw_address_reg(0), BRW_REGISTER_TYPE_UD
);
3432 const unsigned offset
= src
.nr
* REG_SIZE
+ src
.subnr
;
3433 /* Limit in bytes of the signed indirect addressing immediate. */
3434 const unsigned limit
= 512;
3436 brw_push_insn_state(p
);
3437 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
3438 brw_set_default_predicate_control(p
, BRW_PREDICATE_NONE
);
3440 /* Take into account the component size and horizontal stride. */
3441 assert(src
.vstride
== src
.hstride
+ src
.width
);
3442 brw_SHL(p
, addr
, vec1(idx
),
3443 brw_imm_ud(_mesa_logbase2(type_sz(src
.type
)) +
3446 /* We can only address up to limit bytes using the indirect
3447 * addressing immediate, account for the difference if the source
3448 * register is above this limit.
3450 if (offset
>= limit
)
3451 brw_ADD(p
, addr
, addr
, brw_imm_ud(offset
- offset
% limit
));
3453 brw_pop_insn_state(p
);
3455 /* Use indirect addressing to fetch the specified component. */
3457 retype(brw_vec1_indirect(addr
.subnr
, offset
% limit
),
3460 /* In SIMD4x2 mode the index can be either zero or one, replicate it
3461 * to all bits of a flag register,
3465 stride(brw_swizzle(idx
, BRW_SWIZZLE_XXXX
), 0, 4, 1));
3466 brw_inst_set_pred_control(devinfo
, inst
, BRW_PREDICATE_NONE
);
3467 brw_inst_set_cond_modifier(devinfo
, inst
, BRW_CONDITIONAL_NZ
);
3468 brw_inst_set_flag_reg_nr(devinfo
, inst
, 1);
3470 /* and use predicated SEL to pick the right channel. */
3471 inst
= brw_SEL(p
, dst
,
3472 stride(suboffset(src
, 4), 0, 4, 1),
3473 stride(src
, 0, 4, 1));
3474 brw_inst_set_pred_control(devinfo
, inst
, BRW_PREDICATE_NORMAL
);
3475 brw_inst_set_flag_reg_nr(devinfo
, inst
, 1);
3481 * This instruction is generated as a single-channel align1 instruction by
3482 * both the VS and FS stages when using INTEL_DEBUG=shader_time.
3484 * We can't use the typed atomic op in the FS because that has the execution
3485 * mask ANDed with the pixel mask, but we just want to write the one dword for
3488 * We don't use the SIMD4x2 atomic ops in the VS because want to just write
3489 * one u32. So we use the same untyped atomic write message as the pixel
3492 * The untyped atomic operation requires a BUFFER surface type with RAW
3493 * format, and is only accessible through the legacy DATA_CACHE dataport
3496 void brw_shader_time_add(struct brw_codegen
*p
,
3497 struct brw_reg payload
,
3498 uint32_t surf_index
)
3500 const unsigned sfid
= (p
->devinfo
->gen
>= 8 || p
->devinfo
->is_haswell
?
3501 HSW_SFID_DATAPORT_DATA_CACHE_1
:
3502 GEN7_SFID_DATAPORT_DATA_CACHE
);
3503 assert(p
->devinfo
->gen
>= 7);
3505 brw_push_insn_state(p
);
3506 brw_set_default_access_mode(p
, BRW_ALIGN_1
);
3507 brw_set_default_mask_control(p
, BRW_MASK_DISABLE
);
3508 brw_set_default_compression_control(p
, BRW_COMPRESSION_NONE
);
3509 brw_inst
*send
= brw_next_insn(p
, BRW_OPCODE_SEND
);
3511 /* We use brw_vec1_reg and unmasked because we want to increment the given
3514 brw_set_dest(p
, send
, brw_vec1_reg(BRW_ARCHITECTURE_REGISTER_FILE
,
3516 brw_set_src0(p
, send
, brw_vec1_reg(payload
.file
,
3518 brw_set_src1(p
, send
, brw_imm_ud(0));
3519 brw_set_message_descriptor(p
, send
, sfid
, 2, 0, false, false);
3520 brw_inst_set_binding_table_index(p
->devinfo
, send
, surf_index
);
3521 brw_set_dp_untyped_atomic_message(p
, send
, BRW_AOP_ADD
, false);
3523 brw_pop_insn_state(p
);
3528 * Emit the SEND message for a barrier
3531 brw_barrier(struct brw_codegen
*p
, struct brw_reg src
)
3533 const struct brw_device_info
*devinfo
= p
->devinfo
;
3534 struct brw_inst
*inst
;
3536 assert(devinfo
->gen
>= 7);
3538 inst
= next_insn(p
, BRW_OPCODE_SEND
);
3539 brw_set_dest(p
, inst
, retype(brw_null_reg(), BRW_REGISTER_TYPE_UW
));
3540 brw_set_src0(p
, inst
, src
);
3541 brw_set_src1(p
, inst
, brw_null_reg());
3543 brw_set_message_descriptor(p
, inst
, BRW_SFID_MESSAGE_GATEWAY
,
3545 0 /* response_length */,
3546 false /* header_present */,
3547 false /* end_of_thread */);
3549 brw_inst_set_gateway_notify(devinfo
, inst
, 1);
3550 brw_inst_set_gateway_subfuncid(devinfo
, inst
,
3551 BRW_MESSAGE_GATEWAY_SFID_BARRIER_MSG
);
3553 brw_inst_set_mask_control(devinfo
, inst
, BRW_MASK_DISABLE
);
3558 * Emit the wait instruction for a barrier
3561 brw_WAIT(struct brw_codegen
*p
)
3563 const struct brw_device_info
*devinfo
= p
->devinfo
;
3564 struct brw_inst
*insn
;
3566 struct brw_reg src
= brw_notification_reg();
3568 insn
= next_insn(p
, BRW_OPCODE_WAIT
);
3569 brw_set_dest(p
, insn
, src
);
3570 brw_set_src0(p
, insn
, src
);
3571 brw_set_src1(p
, insn
, brw_null_reg());
3573 brw_inst_set_exec_size(devinfo
, insn
, BRW_EXECUTE_1
);
3574 brw_inst_set_mask_control(devinfo
, insn
, BRW_MASK_DISABLE
);