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1 /*
2  Copyright (C) Intel Corp.  2006.  All Rights Reserved.
3  Intel funded Tungsten Graphics to
4  develop this 3D driver.
5 
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:
13 
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.
17 
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.
25 
26  **********************************************************************/
27  /*
28   * Authors:
29   *   Keith Whitwell <keithw@vmware.com>
30   */
31 
32 #include <sys/stat.h>
33 #include <fcntl.h>
34 
35 #include "brw_eu_defines.h"
36 #include "brw_eu.h"
37 #include "brw_shader.h"
38 #include "brw_gfx_ver_enum.h"
39 #include "dev/intel_debug.h"
40 
41 #include "util/ralloc.h"
42 
43 /* Returns a conditional modifier that negates the condition. */
44 enum brw_conditional_mod
brw_negate_cmod(enum brw_conditional_mod cmod)45 brw_negate_cmod(enum brw_conditional_mod cmod)
46 {
47    switch (cmod) {
48    case BRW_CONDITIONAL_Z:
49       return BRW_CONDITIONAL_NZ;
50    case BRW_CONDITIONAL_NZ:
51       return BRW_CONDITIONAL_Z;
52    case BRW_CONDITIONAL_G:
53       return BRW_CONDITIONAL_LE;
54    case BRW_CONDITIONAL_GE:
55       return BRW_CONDITIONAL_L;
56    case BRW_CONDITIONAL_L:
57       return BRW_CONDITIONAL_GE;
58    case BRW_CONDITIONAL_LE:
59       return BRW_CONDITIONAL_G;
60    default:
61       unreachable("Can't negate this cmod");
62    }
63 }
64 
65 /* Returns the corresponding conditional mod for swapping src0 and
66  * src1 in e.g. CMP.
67  */
68 enum brw_conditional_mod
brw_swap_cmod(enum brw_conditional_mod cmod)69 brw_swap_cmod(enum brw_conditional_mod cmod)
70 {
71    switch (cmod) {
72    case BRW_CONDITIONAL_Z:
73    case BRW_CONDITIONAL_NZ:
74       return cmod;
75    case BRW_CONDITIONAL_G:
76       return BRW_CONDITIONAL_L;
77    case BRW_CONDITIONAL_GE:
78       return BRW_CONDITIONAL_LE;
79    case BRW_CONDITIONAL_L:
80       return BRW_CONDITIONAL_G;
81    case BRW_CONDITIONAL_LE:
82       return BRW_CONDITIONAL_GE;
83    default:
84       return BRW_CONDITIONAL_NONE;
85    }
86 }
87 
88 /**
89  * Get the least significant bit offset of the i+1-th component of immediate
90  * type \p type.  For \p i equal to the two's complement of j, return the
91  * offset of the j-th component starting from the end of the vector.  For
92  * scalar register types return zero.
93  */
94 static unsigned
imm_shift(enum brw_reg_type type,unsigned i)95 imm_shift(enum brw_reg_type type, unsigned i)
96 {
97    assert(type != BRW_REGISTER_TYPE_UV && type != BRW_REGISTER_TYPE_V &&
98           "Not implemented.");
99 
100    if (type == BRW_REGISTER_TYPE_VF)
101       return 8 * (i & 3);
102    else
103       return 0;
104 }
105 
106 /**
107  * Swizzle an arbitrary immediate \p x of the given type according to the
108  * permutation specified as \p swz.
109  */
110 uint32_t
brw_swizzle_immediate(enum brw_reg_type type,uint32_t x,unsigned swz)111 brw_swizzle_immediate(enum brw_reg_type type, uint32_t x, unsigned swz)
112 {
113    if (imm_shift(type, 1)) {
114       const unsigned n = 32 / imm_shift(type, 1);
115       uint32_t y = 0;
116 
117       for (unsigned i = 0; i < n; i++) {
118          /* Shift the specified component all the way to the right and left to
119           * discard any undesired L/MSBs, then shift it right into component i.
120           */
121          y |= x >> imm_shift(type, (i & ~3) + BRW_GET_SWZ(swz, i & 3))
122                 << imm_shift(type, ~0u)
123                 >> imm_shift(type, ~0u - i);
124       }
125 
126       return y;
127    } else {
128       return x;
129    }
130 }
131 
132 unsigned
brw_get_default_exec_size(struct brw_codegen * p)133 brw_get_default_exec_size(struct brw_codegen *p)
134 {
135    return p->current->exec_size;
136 }
137 
138 unsigned
brw_get_default_group(struct brw_codegen * p)139 brw_get_default_group(struct brw_codegen *p)
140 {
141    return p->current->group;
142 }
143 
144 unsigned
brw_get_default_access_mode(struct brw_codegen * p)145 brw_get_default_access_mode(struct brw_codegen *p)
146 {
147    return p->current->access_mode;
148 }
149 
150 tgl_swsb
brw_get_default_swsb(struct brw_codegen * p)151 brw_get_default_swsb(struct brw_codegen *p)
152 {
153    return p->current->swsb;
154 }
155 
156 void
brw_set_default_exec_size(struct brw_codegen * p,unsigned value)157 brw_set_default_exec_size(struct brw_codegen *p, unsigned value)
158 {
159    p->current->exec_size = value;
160 }
161 
brw_set_default_predicate_control(struct brw_codegen * p,enum brw_predicate pc)162 void brw_set_default_predicate_control(struct brw_codegen *p, enum brw_predicate pc)
163 {
164    p->current->predicate = pc;
165 }
166 
brw_set_default_predicate_inverse(struct brw_codegen * p,bool predicate_inverse)167 void brw_set_default_predicate_inverse(struct brw_codegen *p, bool predicate_inverse)
168 {
169    p->current->pred_inv = predicate_inverse;
170 }
171 
brw_set_default_flag_reg(struct brw_codegen * p,int reg,int subreg)172 void brw_set_default_flag_reg(struct brw_codegen *p, int reg, int subreg)
173 {
174    assert(subreg < 2);
175    p->current->flag_subreg = reg * 2 + subreg;
176 }
177 
brw_set_default_access_mode(struct brw_codegen * p,unsigned access_mode)178 void brw_set_default_access_mode( struct brw_codegen *p, unsigned access_mode )
179 {
180    p->current->access_mode = access_mode;
181 }
182 
183 void
brw_set_default_compression_control(struct brw_codegen * p,enum brw_compression compression_control)184 brw_set_default_compression_control(struct brw_codegen *p,
185 			    enum brw_compression compression_control)
186 {
187    switch (compression_control) {
188    case BRW_COMPRESSION_NONE:
189       /* This is the "use the first set of bits of dmask/vmask/arf
190        * according to execsize" option.
191        */
192       p->current->group = 0;
193       break;
194    case BRW_COMPRESSION_2NDHALF:
195       /* For SIMD8, this is "use the second set of 8 bits." */
196       p->current->group = 8;
197       break;
198    case BRW_COMPRESSION_COMPRESSED:
199       /* For SIMD16 instruction compression, use the first set of 16 bits
200        * since we don't do SIMD32 dispatch.
201        */
202       p->current->group = 0;
203       break;
204    default:
205       unreachable("not reached");
206    }
207 
208    if (p->devinfo->ver <= 6) {
209       p->current->compressed =
210          (compression_control == BRW_COMPRESSION_COMPRESSED);
211    }
212 }
213 
214 /**
215  * Enable or disable instruction compression on the given instruction leaving
216  * the currently selected channel enable group untouched.
217  */
218 void
brw_inst_set_compression(const struct intel_device_info * devinfo,brw_inst * inst,bool on)219 brw_inst_set_compression(const struct intel_device_info *devinfo,
220                          brw_inst *inst, bool on)
221 {
222    if (devinfo->ver >= 6) {
223       /* No-op, the EU will figure out for us whether the instruction needs to
224        * be compressed.
225        */
226    } else {
227       /* The channel group and compression controls are non-orthogonal, there
228        * are two possible representations for uncompressed instructions and we
229        * may need to preserve the current one to avoid changing the selected
230        * channel group inadvertently.
231        */
232       if (on)
233          brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_COMPRESSED);
234       else if (brw_inst_qtr_control(devinfo, inst)
235                == BRW_COMPRESSION_COMPRESSED)
236          brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_NONE);
237    }
238 }
239 
240 void
brw_set_default_compression(struct brw_codegen * p,bool on)241 brw_set_default_compression(struct brw_codegen *p, bool on)
242 {
243    p->current->compressed = on;
244 }
245 
246 /**
247  * Apply the range of channel enable signals given by
248  * [group, group + exec_size) to the instruction passed as argument.
249  */
250 void
brw_inst_set_group(const struct intel_device_info * devinfo,brw_inst * inst,unsigned group)251 brw_inst_set_group(const struct intel_device_info *devinfo,
252                    brw_inst *inst, unsigned group)
253 {
254    if (devinfo->ver >= 7) {
255       assert(group % 4 == 0 && group < 32);
256       brw_inst_set_qtr_control(devinfo, inst, group / 8);
257       brw_inst_set_nib_control(devinfo, inst, (group / 4) % 2);
258 
259    } else if (devinfo->ver == 6) {
260       assert(group % 8 == 0 && group < 32);
261       brw_inst_set_qtr_control(devinfo, inst, group / 8);
262 
263    } else {
264       assert(group % 8 == 0 && group < 16);
265       /* The channel group and compression controls are non-orthogonal, there
266        * are two possible representations for group zero and we may need to
267        * preserve the current one to avoid changing the selected compression
268        * enable inadvertently.
269        */
270       if (group == 8)
271          brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_2NDHALF);
272       else if (brw_inst_qtr_control(devinfo, inst) == BRW_COMPRESSION_2NDHALF)
273          brw_inst_set_qtr_control(devinfo, inst, BRW_COMPRESSION_NONE);
274    }
275 }
276 
277 void
brw_set_default_group(struct brw_codegen * p,unsigned group)278 brw_set_default_group(struct brw_codegen *p, unsigned group)
279 {
280    p->current->group = group;
281 }
282 
brw_set_default_mask_control(struct brw_codegen * p,unsigned value)283 void brw_set_default_mask_control( struct brw_codegen *p, unsigned value )
284 {
285    p->current->mask_control = value;
286 }
287 
brw_set_default_saturate(struct brw_codegen * p,bool enable)288 void brw_set_default_saturate( struct brw_codegen *p, bool enable )
289 {
290    p->current->saturate = enable;
291 }
292 
brw_set_default_acc_write_control(struct brw_codegen * p,unsigned value)293 void brw_set_default_acc_write_control(struct brw_codegen *p, unsigned value)
294 {
295    p->current->acc_wr_control = value;
296 }
297 
brw_set_default_swsb(struct brw_codegen * p,tgl_swsb value)298 void brw_set_default_swsb(struct brw_codegen *p, tgl_swsb value)
299 {
300    p->current->swsb = value;
301 }
302 
brw_push_insn_state(struct brw_codegen * p)303 void brw_push_insn_state( struct brw_codegen *p )
304 {
305    assert(p->current != &p->stack[BRW_EU_MAX_INSN_STACK-1]);
306    *(p->current + 1) = *p->current;
307    p->current++;
308 }
309 
brw_pop_insn_state(struct brw_codegen * p)310 void brw_pop_insn_state( struct brw_codegen *p )
311 {
312    assert(p->current != p->stack);
313    p->current--;
314 }
315 
316 
317 /***********************************************************************
318  */
319 void
brw_init_codegen(const struct intel_device_info * devinfo,struct brw_codegen * p,void * mem_ctx)320 brw_init_codegen(const struct intel_device_info *devinfo,
321                  struct brw_codegen *p, void *mem_ctx)
322 {
323    memset(p, 0, sizeof(*p));
324 
325    p->devinfo = devinfo;
326    p->automatic_exec_sizes = true;
327    /*
328     * Set the initial instruction store array size to 1024, if found that
329     * isn't enough, then it will double the store size at brw_next_insn()
330     * until out of memory.
331     */
332    p->store_size = 1024;
333    p->store = rzalloc_array(mem_ctx, brw_inst, p->store_size);
334    p->nr_insn = 0;
335    p->current = p->stack;
336    memset(p->current, 0, sizeof(p->current[0]));
337 
338    p->mem_ctx = mem_ctx;
339 
340    /* Some defaults?
341     */
342    brw_set_default_exec_size(p, BRW_EXECUTE_8);
343    brw_set_default_mask_control(p, BRW_MASK_ENABLE); /* what does this do? */
344    brw_set_default_saturate(p, 0);
345    brw_set_default_compression_control(p, BRW_COMPRESSION_NONE);
346 
347    /* Set up control flow stack */
348    p->if_stack_depth = 0;
349    p->if_stack_array_size = 16;
350    p->if_stack = rzalloc_array(mem_ctx, int, p->if_stack_array_size);
351 
352    p->loop_stack_depth = 0;
353    p->loop_stack_array_size = 16;
354    p->loop_stack = rzalloc_array(mem_ctx, int, p->loop_stack_array_size);
355    p->if_depth_in_loop = rzalloc_array(mem_ctx, int, p->loop_stack_array_size);
356 }
357 
358 
brw_get_program(struct brw_codegen * p,unsigned * sz)359 const unsigned *brw_get_program( struct brw_codegen *p,
360 			       unsigned *sz )
361 {
362    *sz = p->next_insn_offset;
363    return (const unsigned *)p->store;
364 }
365 
366 const brw_shader_reloc *
brw_get_shader_relocs(struct brw_codegen * p,unsigned * num_relocs)367 brw_get_shader_relocs(struct brw_codegen *p, unsigned *num_relocs)
368 {
369    *num_relocs = p->num_relocs;
370    return p->relocs;
371 }
372 
brw_try_override_assembly(struct brw_codegen * p,int start_offset,const char * identifier)373 bool brw_try_override_assembly(struct brw_codegen *p, int start_offset,
374                                const char *identifier)
375 {
376    const char *read_path = getenv("INTEL_SHADER_ASM_READ_PATH");
377    if (!read_path) {
378       return false;
379    }
380 
381    char *name = ralloc_asprintf(NULL, "%s/%s.bin", read_path, identifier);
382 
383    int fd = open(name, O_RDONLY);
384    ralloc_free(name);
385 
386    if (fd == -1) {
387       return false;
388    }
389 
390    struct stat sb;
391    if (fstat(fd, &sb) != 0 || (!S_ISREG(sb.st_mode))) {
392       close(fd);
393       return false;
394    }
395 
396    p->nr_insn -= (p->next_insn_offset - start_offset) / sizeof(brw_inst);
397    p->nr_insn += sb.st_size / sizeof(brw_inst);
398 
399    p->next_insn_offset = start_offset + sb.st_size;
400    p->store_size = (start_offset + sb.st_size) / sizeof(brw_inst);
401    p->store = (brw_inst *)reralloc_size(p->mem_ctx, p->store, p->next_insn_offset);
402    assert(p->store);
403 
404    ssize_t ret = read(fd, (char *)p->store + start_offset, sb.st_size);
405    close(fd);
406    if (ret != sb.st_size) {
407       return false;
408    }
409 
410    ASSERTED bool valid =
411       brw_validate_instructions(p->devinfo, p->store,
412                                 start_offset, p->next_insn_offset,
413                                 NULL);
414    assert(valid);
415 
416    return true;
417 }
418 
419 const struct brw_label *
brw_find_label(const struct brw_label * root,int offset)420 brw_find_label(const struct brw_label *root, int offset)
421 {
422    const struct brw_label *curr = root;
423 
424    if (curr != NULL)
425    {
426       do {
427          if (curr->offset == offset)
428             return curr;
429 
430          curr = curr->next;
431       } while (curr != NULL);
432    }
433 
434    return curr;
435 }
436 
437 void
brw_create_label(struct brw_label ** labels,int offset,void * mem_ctx)438 brw_create_label(struct brw_label **labels, int offset, void *mem_ctx)
439 {
440    if (*labels != NULL) {
441       struct brw_label *curr = *labels;
442       struct brw_label *prev;
443 
444       do {
445          prev = curr;
446 
447          if (curr->offset == offset)
448             return;
449 
450          curr = curr->next;
451       } while (curr != NULL);
452 
453       curr = ralloc(mem_ctx, struct brw_label);
454       curr->offset = offset;
455       curr->number = prev->number + 1;
456       curr->next = NULL;
457       prev->next = curr;
458    } else {
459       struct brw_label *root = ralloc(mem_ctx, struct brw_label);
460       root->number = 0;
461       root->offset = offset;
462       root->next = NULL;
463       *labels = root;
464    }
465 }
466 
467 const struct brw_label *
brw_label_assembly(const struct intel_device_info * devinfo,const void * assembly,int start,int end,void * mem_ctx)468 brw_label_assembly(const struct intel_device_info *devinfo,
469                    const void *assembly, int start, int end, void *mem_ctx)
470 {
471    struct brw_label *root_label = NULL;
472 
473    int to_bytes_scale = sizeof(brw_inst) / brw_jump_scale(devinfo);
474 
475    for (int offset = start; offset < end;) {
476       const brw_inst *inst = (const brw_inst *) ((const char *) assembly + offset);
477       brw_inst uncompacted;
478 
479       bool is_compact = brw_inst_cmpt_control(devinfo, inst);
480 
481       if (is_compact) {
482          brw_compact_inst *compacted = (brw_compact_inst *)inst;
483          brw_uncompact_instruction(devinfo, &uncompacted, compacted);
484          inst = &uncompacted;
485       }
486 
487       if (brw_has_uip(devinfo, brw_inst_opcode(devinfo, inst))) {
488          /* Instructions that have UIP also have JIP. */
489          brw_create_label(&root_label,
490             offset + brw_inst_uip(devinfo, inst) * to_bytes_scale, mem_ctx);
491          brw_create_label(&root_label,
492             offset + brw_inst_jip(devinfo, inst) * to_bytes_scale, mem_ctx);
493       } else if (brw_has_jip(devinfo, brw_inst_opcode(devinfo, inst))) {
494          int jip;
495          if (devinfo->ver >= 7) {
496             jip = brw_inst_jip(devinfo, inst);
497          } else {
498             jip = brw_inst_gfx6_jump_count(devinfo, inst);
499          }
500 
501          brw_create_label(&root_label, offset + jip * to_bytes_scale, mem_ctx);
502       }
503 
504       if (is_compact) {
505          offset += sizeof(brw_compact_inst);
506       } else {
507          offset += sizeof(brw_inst);
508       }
509    }
510 
511    return root_label;
512 }
513 
514 void
brw_disassemble_with_labels(const struct intel_device_info * devinfo,const void * assembly,int start,int end,FILE * out)515 brw_disassemble_with_labels(const struct intel_device_info *devinfo,
516                             const void *assembly, int start, int end, FILE *out)
517 {
518    void *mem_ctx = ralloc_context(NULL);
519    const struct brw_label *root_label =
520       brw_label_assembly(devinfo, assembly, start, end, mem_ctx);
521 
522    brw_disassemble(devinfo, assembly, start, end, root_label, out);
523 
524    ralloc_free(mem_ctx);
525 }
526 
527 void
brw_disassemble(const struct intel_device_info * devinfo,const void * assembly,int start,int end,const struct brw_label * root_label,FILE * out)528 brw_disassemble(const struct intel_device_info *devinfo,
529                 const void *assembly, int start, int end,
530                 const struct brw_label *root_label, FILE *out)
531 {
532    bool dump_hex = INTEL_DEBUG(DEBUG_HEX);
533 
534    for (int offset = start; offset < end;) {
535       const brw_inst *insn = (const brw_inst *)((char *)assembly + offset);
536       brw_inst uncompacted;
537 
538       if (root_label != NULL) {
539         const struct brw_label *label = brw_find_label(root_label, offset);
540         if (label != NULL) {
541            fprintf(out, "\nLABEL%d:\n", label->number);
542         }
543       }
544 
545       bool compacted = brw_inst_cmpt_control(devinfo, insn);
546       if (0)
547          fprintf(out, "0x%08x: ", offset);
548 
549       if (compacted) {
550          brw_compact_inst *compacted = (brw_compact_inst *)insn;
551          if (dump_hex) {
552             unsigned char * insn_ptr = ((unsigned char *)&insn[0]);
553             const unsigned int blank_spaces = 24;
554             for (int i = 0 ; i < 8; i = i + 4) {
555                fprintf(out, "%02x %02x %02x %02x ",
556                        insn_ptr[i],
557                        insn_ptr[i + 1],
558                        insn_ptr[i + 2],
559                        insn_ptr[i + 3]);
560             }
561             /* Make compacted instructions hex value output vertically aligned
562              * with uncompacted instructions hex value
563              */
564             fprintf(out, "%*c", blank_spaces, ' ');
565          }
566 
567          brw_uncompact_instruction(devinfo, &uncompacted, compacted);
568          insn = &uncompacted;
569       } else {
570          if (dump_hex) {
571             unsigned char * insn_ptr = ((unsigned char *)&insn[0]);
572             for (int i = 0 ; i < 16; i = i + 4) {
573                fprintf(out, "%02x %02x %02x %02x ",
574                        insn_ptr[i],
575                        insn_ptr[i + 1],
576                        insn_ptr[i + 2],
577                        insn_ptr[i + 3]);
578             }
579          }
580       }
581 
582       brw_disassemble_inst(out, devinfo, insn, compacted, offset, root_label);
583 
584       if (compacted) {
585          offset += sizeof(brw_compact_inst);
586       } else {
587          offset += sizeof(brw_inst);
588       }
589    }
590 }
591 
592 static const struct opcode_desc opcode_descs[] = {
593    /* IR,                 HW,  name,      nsrc, ndst, gfx_vers */
594    { BRW_OPCODE_ILLEGAL,  0,   "illegal", 0,    0,    GFX_ALL },
595    { BRW_OPCODE_SYNC,     1,   "sync",    1,    0,    GFX_GE(GFX12) },
596    { BRW_OPCODE_MOV,      1,   "mov",     1,    1,    GFX_LT(GFX12) },
597    { BRW_OPCODE_MOV,      97,  "mov",     1,    1,    GFX_GE(GFX12) },
598    { BRW_OPCODE_SEL,      2,   "sel",     2,    1,    GFX_LT(GFX12) },
599    { BRW_OPCODE_SEL,      98,  "sel",     2,    1,    GFX_GE(GFX12) },
600    { BRW_OPCODE_MOVI,     3,   "movi",    2,    1,    GFX_GE(GFX45) & GFX_LT(GFX12) },
601    { BRW_OPCODE_MOVI,     99,  "movi",    2,    1,    GFX_GE(GFX12) },
602    { BRW_OPCODE_NOT,      4,   "not",     1,    1,    GFX_LT(GFX12) },
603    { BRW_OPCODE_NOT,      100, "not",     1,    1,    GFX_GE(GFX12) },
604    { BRW_OPCODE_AND,      5,   "and",     2,    1,    GFX_LT(GFX12) },
605    { BRW_OPCODE_AND,      101, "and",     2,    1,    GFX_GE(GFX12) },
606    { BRW_OPCODE_OR,       6,   "or",      2,    1,    GFX_LT(GFX12) },
607    { BRW_OPCODE_OR,       102, "or",      2,    1,    GFX_GE(GFX12) },
608    { BRW_OPCODE_XOR,      7,   "xor",     2,    1,    GFX_LT(GFX12) },
609    { BRW_OPCODE_XOR,      103, "xor",     2,    1,    GFX_GE(GFX12) },
610    { BRW_OPCODE_SHR,      8,   "shr",     2,    1,    GFX_LT(GFX12) },
611    { BRW_OPCODE_SHR,      104, "shr",     2,    1,    GFX_GE(GFX12) },
612    { BRW_OPCODE_SHL,      9,   "shl",     2,    1,    GFX_LT(GFX12) },
613    { BRW_OPCODE_SHL,      105, "shl",     2,    1,    GFX_GE(GFX12) },
614    { BRW_OPCODE_DIM,      10,  "dim",     1,    1,    GFX75 },
615    { BRW_OPCODE_SMOV,     10,  "smov",    0,    0,    GFX_GE(GFX8) & GFX_LT(GFX12) },
616    { BRW_OPCODE_SMOV,     106, "smov",    0,    0,    GFX_GE(GFX12) },
617    { BRW_OPCODE_ASR,      12,  "asr",     2,    1,    GFX_LT(GFX12) },
618    { BRW_OPCODE_ASR,      108, "asr",     2,    1,    GFX_GE(GFX12) },
619    { BRW_OPCODE_ROR,      14,  "ror",     2,    1,    GFX11 },
620    { BRW_OPCODE_ROR,      110, "ror",     2,    1,    GFX_GE(GFX12) },
621    { BRW_OPCODE_ROL,      15,  "rol",     2,    1,    GFX11 },
622    { BRW_OPCODE_ROL,      111, "rol",     2,    1,    GFX_GE(GFX12) },
623    { BRW_OPCODE_CMP,      16,  "cmp",     2,    1,    GFX_LT(GFX12) },
624    { BRW_OPCODE_CMP,      112, "cmp",     2,    1,    GFX_GE(GFX12) },
625    { BRW_OPCODE_CMPN,     17,  "cmpn",    2,    1,    GFX_LT(GFX12) },
626    { BRW_OPCODE_CMPN,     113, "cmpn",    2,    1,    GFX_GE(GFX12) },
627    { BRW_OPCODE_CSEL,     18,  "csel",    3,    1,    GFX_GE(GFX8) & GFX_LT(GFX12) },
628    { BRW_OPCODE_CSEL,     114, "csel",    3,    1,    GFX_GE(GFX12) },
629    { BRW_OPCODE_F32TO16,  19,  "f32to16", 1,    1,    GFX7 | GFX75 },
630    { BRW_OPCODE_F16TO32,  20,  "f16to32", 1,    1,    GFX7 | GFX75 },
631    { BRW_OPCODE_BFREV,    23,  "bfrev",   1,    1,    GFX_GE(GFX7) & GFX_LT(GFX12) },
632    { BRW_OPCODE_BFREV,    119, "bfrev",   1,    1,    GFX_GE(GFX12) },
633    { BRW_OPCODE_BFE,      24,  "bfe",     3,    1,    GFX_GE(GFX7) & GFX_LT(GFX12) },
634    { BRW_OPCODE_BFE,      120, "bfe",     3,    1,    GFX_GE(GFX12) },
635    { BRW_OPCODE_BFI1,     25,  "bfi1",    2,    1,    GFX_GE(GFX7) & GFX_LT(GFX12) },
636    { BRW_OPCODE_BFI1,     121, "bfi1",    2,    1,    GFX_GE(GFX12) },
637    { BRW_OPCODE_BFI2,     26,  "bfi2",    3,    1,    GFX_GE(GFX7) & GFX_LT(GFX12) },
638    { BRW_OPCODE_BFI2,     122, "bfi2",    3,    1,    GFX_GE(GFX12) },
639    { BRW_OPCODE_JMPI,     32,  "jmpi",    0,    0,    GFX_ALL },
640    { BRW_OPCODE_BRD,      33,  "brd",     0,    0,    GFX_GE(GFX7) },
641    { BRW_OPCODE_IF,       34,  "if",      0,    0,    GFX_ALL },
642    { BRW_OPCODE_IFF,      35,  "iff",     0,    0,    GFX_LE(GFX5) },
643    { BRW_OPCODE_BRC,      35,  "brc",     0,    0,    GFX_GE(GFX7) },
644    { BRW_OPCODE_ELSE,     36,  "else",    0,    0,    GFX_ALL },
645    { BRW_OPCODE_ENDIF,    37,  "endif",   0,    0,    GFX_ALL },
646    { BRW_OPCODE_DO,       38,  "do",      0,    0,    GFX_LE(GFX5) },
647    { BRW_OPCODE_CASE,     38,  "case",    0,    0,    GFX6 },
648    { BRW_OPCODE_WHILE,    39,  "while",   0,    0,    GFX_ALL },
649    { BRW_OPCODE_BREAK,    40,  "break",   0,    0,    GFX_ALL },
650    { BRW_OPCODE_CONTINUE, 41,  "cont",    0,    0,    GFX_ALL },
651    { BRW_OPCODE_HALT,     42,  "halt",    0,    0,    GFX_ALL },
652    { BRW_OPCODE_CALLA,    43,  "calla",   0,    0,    GFX_GE(GFX75) },
653    { BRW_OPCODE_MSAVE,    44,  "msave",   0,    0,    GFX_LE(GFX5) },
654    { BRW_OPCODE_CALL,     44,  "call",    0,    0,    GFX_GE(GFX6) },
655    { BRW_OPCODE_MREST,    45,  "mrest",   0,    0,    GFX_LE(GFX5) },
656    { BRW_OPCODE_RET,      45,  "ret",     0,    0,    GFX_GE(GFX6) },
657    { BRW_OPCODE_PUSH,     46,  "push",    0,    0,    GFX_LE(GFX5) },
658    { BRW_OPCODE_FORK,     46,  "fork",    0,    0,    GFX6 },
659    { BRW_OPCODE_GOTO,     46,  "goto",    0,    0,    GFX_GE(GFX8) },
660    { BRW_OPCODE_POP,      47,  "pop",     2,    0,    GFX_LE(GFX5) },
661    { BRW_OPCODE_WAIT,     48,  "wait",    0,    1,    GFX_LT(GFX12) },
662    { BRW_OPCODE_SEND,     49,  "send",    1,    1,    GFX_LT(GFX12) },
663    { BRW_OPCODE_SENDC,    50,  "sendc",   1,    1,    GFX_LT(GFX12) },
664    { BRW_OPCODE_SEND,     49,  "send",    2,    1,    GFX_GE(GFX12) },
665    { BRW_OPCODE_SENDC,    50,  "sendc",   2,    1,    GFX_GE(GFX12) },
666    { BRW_OPCODE_SENDS,    51,  "sends",   2,    1,    GFX_GE(GFX9) & GFX_LT(GFX12) },
667    { BRW_OPCODE_SENDSC,   52,  "sendsc",  2,    1,    GFX_GE(GFX9) & GFX_LT(GFX12) },
668    { BRW_OPCODE_MATH,     56,  "math",    2,    1,    GFX_GE(GFX6) },
669    { BRW_OPCODE_ADD,      64,  "add",     2,    1,    GFX_ALL },
670    { BRW_OPCODE_MUL,      65,  "mul",     2,    1,    GFX_ALL },
671    { BRW_OPCODE_AVG,      66,  "avg",     2,    1,    GFX_ALL },
672    { BRW_OPCODE_FRC,      67,  "frc",     1,    1,    GFX_ALL },
673    { BRW_OPCODE_RNDU,     68,  "rndu",    1,    1,    GFX_ALL },
674    { BRW_OPCODE_RNDD,     69,  "rndd",    1,    1,    GFX_ALL },
675    { BRW_OPCODE_RNDE,     70,  "rnde",    1,    1,    GFX_ALL },
676    { BRW_OPCODE_RNDZ,     71,  "rndz",    1,    1,    GFX_ALL },
677    { BRW_OPCODE_MAC,      72,  "mac",     2,    1,    GFX_ALL },
678    { BRW_OPCODE_MACH,     73,  "mach",    2,    1,    GFX_ALL },
679    { BRW_OPCODE_LZD,      74,  "lzd",     1,    1,    GFX_ALL },
680    { BRW_OPCODE_FBH,      75,  "fbh",     1,    1,    GFX_GE(GFX7) },
681    { BRW_OPCODE_FBL,      76,  "fbl",     1,    1,    GFX_GE(GFX7) },
682    { BRW_OPCODE_CBIT,     77,  "cbit",    1,    1,    GFX_GE(GFX7) },
683    { BRW_OPCODE_ADDC,     78,  "addc",    2,    1,    GFX_GE(GFX7) },
684    { BRW_OPCODE_SUBB,     79,  "subb",    2,    1,    GFX_GE(GFX7) },
685    { BRW_OPCODE_SAD2,     80,  "sad2",    2,    1,    GFX_ALL },
686    { BRW_OPCODE_SADA2,    81,  "sada2",   2,    1,    GFX_ALL },
687    { BRW_OPCODE_ADD3,     82,  "add3",    3,    1,    GFX_GE(GFX125) },
688    { BRW_OPCODE_DP4,      84,  "dp4",     2,    1,    GFX_LT(GFX11) },
689    { BRW_OPCODE_DPH,      85,  "dph",     2,    1,    GFX_LT(GFX11) },
690    { BRW_OPCODE_DP3,      86,  "dp3",     2,    1,    GFX_LT(GFX11) },
691    { BRW_OPCODE_DP2,      87,  "dp2",     2,    1,    GFX_LT(GFX11) },
692    { BRW_OPCODE_DP4A,     88,  "dp4a",    3,    1,    GFX_GE(GFX12) },
693    { BRW_OPCODE_LINE,     89,  "line",    2,    1,    GFX_LE(GFX10) },
694    { BRW_OPCODE_PLN,      90,  "pln",     2,    1,    GFX_GE(GFX45) & GFX_LE(GFX10) },
695    { BRW_OPCODE_MAD,      91,  "mad",     3,    1,    GFX_GE(GFX6) },
696    { BRW_OPCODE_LRP,      92,  "lrp",     3,    1,    GFX_GE(GFX6) & GFX_LE(GFX10) },
697    { BRW_OPCODE_MADM,     93,  "madm",    3,    1,    GFX_GE(GFX8) },
698    { BRW_OPCODE_NENOP,    125, "nenop",   0,    0,    GFX45 },
699    { BRW_OPCODE_NOP,      126, "nop",     0,    0,    GFX_LT(GFX12) },
700    { BRW_OPCODE_NOP,      96,  "nop",     0,    0,    GFX_GE(GFX12) }
701 };
702 
703 /**
704  * Look up the opcode_descs[] entry with \p key member matching \p k which is
705  * supported by the device specified by \p devinfo, or NULL if there is no
706  * matching entry.
707  *
708  * This is implemented by using an index data structure (storage for which is
709  * provided by the caller as \p index_ver and \p index_descs) in order to
710  * provide efficient constant-time look-up.
711  */
712 static const opcode_desc *
lookup_opcode_desc(gfx_ver * index_ver,const opcode_desc ** index_descs,unsigned index_size,unsigned opcode_desc::* key,const intel_device_info * devinfo,unsigned k)713 lookup_opcode_desc(gfx_ver *index_ver,
714                    const opcode_desc **index_descs,
715                    unsigned index_size,
716                    unsigned opcode_desc::*key,
717                    const intel_device_info *devinfo,
718                    unsigned k)
719 {
720    if (*index_ver != gfx_ver_from_devinfo(devinfo)) {
721       *index_ver = gfx_ver_from_devinfo(devinfo);
722 
723       for (unsigned l = 0; l < index_size; l++)
724          index_descs[l] = NULL;
725 
726       for (unsigned i = 0; i < ARRAY_SIZE(opcode_descs); i++) {
727          if (opcode_descs[i].gfx_vers & *index_ver) {
728             const unsigned l = opcode_descs[i].*key;
729             assert(l < index_size && !index_descs[l]);
730             index_descs[l] = &opcode_descs[i];
731          }
732       }
733    }
734 
735    if (k < index_size)
736       return index_descs[k];
737    else
738       return NULL;
739 }
740 
741 /**
742  * Return the matching opcode_desc for the specified IR opcode and hardware
743  * generation, or NULL if the opcode is not supported by the device.
744  */
745 const struct opcode_desc *
brw_opcode_desc(const struct intel_device_info * devinfo,enum opcode opcode)746 brw_opcode_desc(const struct intel_device_info *devinfo, enum opcode opcode)
747 {
748    static __thread gfx_ver index_ver = {};
749    static __thread const opcode_desc *index_descs[NUM_BRW_OPCODES];
750    return lookup_opcode_desc(&index_ver, index_descs, ARRAY_SIZE(index_descs),
751                              &opcode_desc::ir, devinfo, opcode);
752 }
753 
754 /**
755  * Return the matching opcode_desc for the specified HW opcode and hardware
756  * generation, or NULL if the opcode is not supported by the device.
757  */
758 const struct opcode_desc *
brw_opcode_desc_from_hw(const struct intel_device_info * devinfo,unsigned hw)759 brw_opcode_desc_from_hw(const struct intel_device_info *devinfo, unsigned hw)
760 {
761    static __thread gfx_ver index_ver = {};
762    static __thread const opcode_desc *index_descs[128];
763    return lookup_opcode_desc(&index_ver, index_descs, ARRAY_SIZE(index_descs),
764                              &opcode_desc::hw, devinfo, hw);
765 }
766