1 /****************************************************************************
2 * Copyright (C) 2015 Intel Corporation. All Rights Reserved.
3 *
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 * and/or sell copies of the Software, and to permit persons to whom the
9 * Software is furnished to do so, subject to the following conditions:
10 *
11 * The above copyright notice and this permission notice (including the next
12 * paragraph) shall be included in all copies or substantial portions of the
13 * Software.
14 *
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
18 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
21 * IN THE SOFTWARE.
22 ***************************************************************************/
23
24 #include <llvm/Config/llvm-config.h>
25
26 #if LLVM_VERSION_MAJOR < 7
27 // llvm redefines DEBUG
28 #pragma push_macro("DEBUG")
29 #undef DEBUG
30 #endif
31
32 #include "JitManager.h"
33 #include "llvm-c/Core.h"
34 #include "llvm/Support/CBindingWrapping.h"
35 #include "llvm/IR/LegacyPassManager.h"
36
37 #if LLVM_VERSION_MAJOR < 7
38 #pragma pop_macro("DEBUG")
39 #endif
40
41 #include "state.h"
42 #include "gen_state_llvm.h"
43 #include "builder.h"
44 #include "functionpasses/passes.h"
45
46 #include "tgsi/tgsi_strings.h"
47 #include "util/format/u_format.h"
48 #include "util/u_prim.h"
49 #include "gallivm/lp_bld_init.h"
50 #include "gallivm/lp_bld_flow.h"
51 #include "gallivm/lp_bld_struct.h"
52 #include "gallivm/lp_bld_tgsi.h"
53 #include "gallivm/lp_bld_const.h"
54 #include "gallivm/lp_bld_printf.h"
55 #include "gallivm/lp_bld_logic.h"
56
57 #include "swr_context.h"
58 #include "gen_surf_state_llvm.h"
59 #include "gen_swr_context_llvm.h"
60 #include "swr_resource.h"
61 #include "swr_state.h"
62 #include "swr_screen.h"
63
64
65 /////////////////////////////////////////////////////////////////////////
66
67 #include <stdio.h>
68 #include <inttypes.h>
69
70 #include "util/u_debug.h"
71 #include "util/u_memory.h"
72 #include "util/u_string.h"
73
74 #include "gallivm/lp_bld_type.h"
75
76 #if defined(DEBUG) && defined(SWR_VERBOSE_SHADER)
77 constexpr bool verbose_shader = true;
78 constexpr bool verbose_tcs_shader_in = true;
79 constexpr bool verbose_tcs_shader_out = true;
80 constexpr bool verbose_tcs_shader_loop = true;
81 constexpr bool verbose_vs_shader = true;
82 #else
83 constexpr bool verbose_shader = false;
84 constexpr bool verbose_tcs_shader_in = false;
85 constexpr bool verbose_tcs_shader_out = false;
86 constexpr bool verbose_tcs_shader_loop = false;
87 constexpr bool verbose_vs_shader = false;
88 #endif
89
90 using namespace SwrJit;
91
92 static unsigned
93 locate_linkage(ubyte name, ubyte index, struct tgsi_shader_info *info);
94
operator ==(const swr_jit_fs_key & lhs,const swr_jit_fs_key & rhs)95 bool operator==(const swr_jit_fs_key &lhs, const swr_jit_fs_key &rhs)
96 {
97 return !memcmp(&lhs, &rhs, sizeof(lhs));
98 }
99
operator ==(const swr_jit_vs_key & lhs,const swr_jit_vs_key & rhs)100 bool operator==(const swr_jit_vs_key &lhs, const swr_jit_vs_key &rhs)
101 {
102 return !memcmp(&lhs, &rhs, sizeof(lhs));
103 }
104
operator ==(const swr_jit_fetch_key & lhs,const swr_jit_fetch_key & rhs)105 bool operator==(const swr_jit_fetch_key &lhs, const swr_jit_fetch_key &rhs)
106 {
107 return !memcmp(&lhs, &rhs, sizeof(lhs));
108 }
109
operator ==(const swr_jit_gs_key & lhs,const swr_jit_gs_key & rhs)110 bool operator==(const swr_jit_gs_key &lhs, const swr_jit_gs_key &rhs)
111 {
112 return !memcmp(&lhs, &rhs, sizeof(lhs));
113 }
114
operator ==(const swr_jit_tcs_key & lhs,const swr_jit_tcs_key & rhs)115 bool operator==(const swr_jit_tcs_key &lhs, const swr_jit_tcs_key &rhs)
116 {
117 return !memcmp(&lhs, &rhs, sizeof(lhs));
118 }
119
operator ==(const swr_jit_tes_key & lhs,const swr_jit_tes_key & rhs)120 bool operator==(const swr_jit_tes_key &lhs, const swr_jit_tes_key &rhs)
121 {
122 return !memcmp(&lhs, &rhs, sizeof(lhs));
123 }
124
125
126 static void
swr_generate_sampler_key(const struct lp_tgsi_info & info,struct swr_context * ctx,enum pipe_shader_type shader_type,struct swr_jit_sampler_key & key)127 swr_generate_sampler_key(const struct lp_tgsi_info &info,
128 struct swr_context *ctx,
129 enum pipe_shader_type shader_type,
130 struct swr_jit_sampler_key &key)
131 {
132 key.nr_samplers = info.base.file_max[TGSI_FILE_SAMPLER] + 1;
133
134 for (unsigned i = 0; i < key.nr_samplers; i++) {
135 if (info.base.file_mask[TGSI_FILE_SAMPLER] & (1 << i)) {
136 lp_sampler_static_sampler_state(
137 &key.sampler[i].sampler_state,
138 ctx->samplers[shader_type][i]);
139 }
140 }
141
142 /*
143 * XXX If TGSI_FILE_SAMPLER_VIEW exists assume all texture opcodes
144 * are dx10-style? Can't really have mixed opcodes, at least not
145 * if we want to skip the holes here (without rescanning tgsi).
146 */
147 if (info.base.file_max[TGSI_FILE_SAMPLER_VIEW] != -1) {
148 key.nr_sampler_views =
149 info.base.file_max[TGSI_FILE_SAMPLER_VIEW] + 1;
150 for (unsigned i = 0; i < key.nr_sampler_views; i++) {
151 if (info.base.file_mask[TGSI_FILE_SAMPLER_VIEW] & (1u << (i & 31))) {
152 const struct pipe_sampler_view *view =
153 ctx->sampler_views[shader_type][i];
154 lp_sampler_static_texture_state(
155 &key.sampler[i].texture_state, view);
156 if (view) {
157 struct swr_resource *swr_res = swr_resource(view->texture);
158 const struct util_format_description *desc =
159 util_format_description(view->format);
160 if (swr_res->has_depth && swr_res->has_stencil &&
161 !util_format_has_depth(desc))
162 key.sampler[i].texture_state.format = PIPE_FORMAT_S8_UINT;
163 }
164 }
165 }
166 } else {
167 key.nr_sampler_views = key.nr_samplers;
168 for (unsigned i = 0; i < key.nr_sampler_views; i++) {
169 if (info.base.file_mask[TGSI_FILE_SAMPLER] & (1 << i)) {
170 const struct pipe_sampler_view *view =
171 ctx->sampler_views[shader_type][i];
172 lp_sampler_static_texture_state(
173 &key.sampler[i].texture_state, view);
174 if (view) {
175 struct swr_resource *swr_res = swr_resource(view->texture);
176 const struct util_format_description *desc =
177 util_format_description(view->format);
178 if (swr_res->has_depth && swr_res->has_stencil &&
179 !util_format_has_depth(desc))
180 key.sampler[i].texture_state.format = PIPE_FORMAT_S8_UINT;
181 }
182 }
183 }
184 }
185 }
186
187 void
swr_generate_fs_key(struct swr_jit_fs_key & key,struct swr_context * ctx,swr_fragment_shader * swr_fs)188 swr_generate_fs_key(struct swr_jit_fs_key &key,
189 struct swr_context *ctx,
190 swr_fragment_shader *swr_fs)
191 {
192 memset((void*)&key, 0, sizeof(key));
193
194 key.nr_cbufs = ctx->framebuffer.nr_cbufs;
195 key.light_twoside = ctx->rasterizer->light_twoside;
196 key.sprite_coord_enable = ctx->rasterizer->sprite_coord_enable;
197
198 struct tgsi_shader_info *pPrevShader;
199 if (ctx->gs)
200 pPrevShader = &ctx->gs->info.base;
201 else if (ctx->tes)
202 pPrevShader = &ctx->tes->info.base;
203 else
204 pPrevShader = &ctx->vs->info.base;
205
206 memcpy(&key.vs_output_semantic_name,
207 &pPrevShader->output_semantic_name,
208 sizeof(key.vs_output_semantic_name));
209 memcpy(&key.vs_output_semantic_idx,
210 &pPrevShader->output_semantic_index,
211 sizeof(key.vs_output_semantic_idx));
212
213 swr_generate_sampler_key(swr_fs->info, ctx, PIPE_SHADER_FRAGMENT, key);
214
215 key.poly_stipple_enable = ctx->rasterizer->poly_stipple_enable &&
216 ctx->poly_stipple.prim_is_poly;
217 }
218
219 void
swr_generate_vs_key(struct swr_jit_vs_key & key,struct swr_context * ctx,swr_vertex_shader * swr_vs)220 swr_generate_vs_key(struct swr_jit_vs_key &key,
221 struct swr_context *ctx,
222 swr_vertex_shader *swr_vs)
223 {
224 memset((void*)&key, 0, sizeof(key));
225
226 key.clip_plane_mask =
227 swr_vs->info.base.clipdist_writemask ?
228 swr_vs->info.base.clipdist_writemask & ctx->rasterizer->clip_plane_enable :
229 ctx->rasterizer->clip_plane_enable;
230
231 swr_generate_sampler_key(swr_vs->info, ctx, PIPE_SHADER_VERTEX, key);
232 }
233
234 void
swr_generate_fetch_key(struct swr_jit_fetch_key & key,struct swr_vertex_element_state * velems)235 swr_generate_fetch_key(struct swr_jit_fetch_key &key,
236 struct swr_vertex_element_state *velems)
237 {
238 memset((void*)&key, 0, sizeof(key));
239
240 key.fsState = velems->fsState;
241 }
242
243 void
swr_generate_gs_key(struct swr_jit_gs_key & key,struct swr_context * ctx,swr_geometry_shader * swr_gs)244 swr_generate_gs_key(struct swr_jit_gs_key &key,
245 struct swr_context *ctx,
246 swr_geometry_shader *swr_gs)
247 {
248 memset((void*)&key, 0, sizeof(key));
249
250 struct tgsi_shader_info *pPrevShader = nullptr;
251
252 if (ctx->tes) {
253 pPrevShader = &ctx->tes->info.base;
254 } else {
255 pPrevShader = &ctx->vs->info.base;
256 }
257
258 memcpy(&key.vs_output_semantic_name,
259 &pPrevShader->output_semantic_name,
260 sizeof(key.vs_output_semantic_name));
261 memcpy(&key.vs_output_semantic_idx,
262 &pPrevShader->output_semantic_index,
263 sizeof(key.vs_output_semantic_idx));
264
265 swr_generate_sampler_key(swr_gs->info, ctx, PIPE_SHADER_GEOMETRY, key);
266 }
267
268 void
swr_generate_tcs_key(struct swr_jit_tcs_key & key,struct swr_context * ctx,swr_tess_control_shader * swr_tcs)269 swr_generate_tcs_key(struct swr_jit_tcs_key &key,
270 struct swr_context *ctx,
271 swr_tess_control_shader *swr_tcs)
272 {
273 memset((void*)&key, 0, sizeof(key));
274
275 struct tgsi_shader_info *pPrevShader = &ctx->vs->info.base;
276
277 memcpy(&key.vs_output_semantic_name,
278 &pPrevShader->output_semantic_name,
279 sizeof(key.vs_output_semantic_name));
280 memcpy(&key.vs_output_semantic_idx,
281 &pPrevShader->output_semantic_index,
282 sizeof(key.vs_output_semantic_idx));
283
284 key.clip_plane_mask =
285 swr_tcs->info.base.clipdist_writemask ?
286 swr_tcs->info.base.clipdist_writemask & ctx->rasterizer->clip_plane_enable :
287 ctx->rasterizer->clip_plane_enable;
288
289 swr_generate_sampler_key(swr_tcs->info, ctx, PIPE_SHADER_TESS_CTRL, key);
290 }
291
292 void
swr_generate_tes_key(struct swr_jit_tes_key & key,struct swr_context * ctx,swr_tess_evaluation_shader * swr_tes)293 swr_generate_tes_key(struct swr_jit_tes_key &key,
294 struct swr_context *ctx,
295 swr_tess_evaluation_shader *swr_tes)
296 {
297 memset((void*)&key, 0, sizeof(key));
298
299 struct tgsi_shader_info *pPrevShader = nullptr;
300
301 if (ctx->tcs) {
302 pPrevShader = &ctx->tcs->info.base;
303 }
304 else {
305 pPrevShader = &ctx->vs->info.base;
306 }
307
308 SWR_ASSERT(pPrevShader != nullptr, "TES: No TCS or VS defined");
309
310 memcpy(&key.prev_output_semantic_name,
311 &pPrevShader->output_semantic_name,
312 sizeof(key.prev_output_semantic_name));
313 memcpy(&key.prev_output_semantic_idx,
314 &pPrevShader->output_semantic_index,
315 sizeof(key.prev_output_semantic_idx));
316
317 key.clip_plane_mask =
318 swr_tes->info.base.clipdist_writemask ?
319 swr_tes->info.base.clipdist_writemask & ctx->rasterizer->clip_plane_enable :
320 ctx->rasterizer->clip_plane_enable;
321
322 swr_generate_sampler_key(swr_tes->info, ctx, PIPE_SHADER_TESS_EVAL, key);
323 }
324
325 struct BuilderSWR : public Builder {
BuilderSWRBuilderSWR326 BuilderSWR(JitManager *pJitMgr, const char *pName)
327 : Builder(pJitMgr)
328 {
329 pJitMgr->SetupNewModule();
330 gallivm = gallivm_create(pName, wrap(&JM()->mContext), NULL);
331 pJitMgr->mpCurrentModule = unwrap(gallivm->module);
332 }
333
~BuilderSWRBuilderSWR334 ~BuilderSWR() {
335 gallivm_free_ir(gallivm);
336 }
337
338 void WriteVS(Value *pVal, Value *pVsContext, Value *pVtxOutput,
339 unsigned slot, unsigned channel);
340
341 struct gallivm_state *gallivm;
342 PFN_VERTEX_FUNC CompileVS(struct swr_context *ctx, swr_jit_vs_key &key);
343 PFN_PIXEL_KERNEL CompileFS(struct swr_context *ctx, swr_jit_fs_key &key);
344 PFN_GS_FUNC CompileGS(struct swr_context *ctx, swr_jit_gs_key &key);
345 PFN_TCS_FUNC CompileTCS(struct swr_context *ctx, swr_jit_tcs_key &key);
346 PFN_TES_FUNC CompileTES(struct swr_context *ctx, swr_jit_tes_key &key);
347
348 // GS-specific emit functions
349 LLVMValueRef
350 swr_gs_llvm_fetch_input(const struct lp_build_gs_iface *gs_iface,
351 struct lp_build_context * bld,
352 boolean is_vindex_indirect,
353 LLVMValueRef vertex_index,
354 boolean is_aindex_indirect,
355 LLVMValueRef attrib_index,
356 LLVMValueRef swizzle_index);
357 void
358 swr_gs_llvm_emit_vertex(const struct lp_build_gs_iface *gs_base,
359 struct lp_build_context * bld,
360 LLVMValueRef (*outputs)[4],
361 LLVMValueRef emitted_vertices_vec,
362 LLVMValueRef stream_id);
363
364 void
365 swr_gs_llvm_end_primitive(const struct lp_build_gs_iface *gs_base,
366 struct lp_build_context * bld,
367 LLVMValueRef total_emitted_vertices_vec_ptr,
368 LLVMValueRef verts_per_prim_vec,
369 LLVMValueRef emitted_prims_vec,
370 LLVMValueRef mask_vec);
371
372 void
373 swr_gs_llvm_epilogue(const struct lp_build_gs_iface *gs_base,
374 LLVMValueRef total_emitted_vertices_vec,
375 LLVMValueRef emitted_prims_vec, unsigned stream);
376
377 // TCS-specific emit functions
378 void swr_tcs_llvm_emit_prologue(struct lp_build_tgsi_soa_context* bld);
379 void swr_tcs_llvm_emit_epilogue(struct lp_build_tgsi_soa_context* bld);
380
381 LLVMValueRef
382 swr_tcs_llvm_fetch_input(const struct lp_build_tcs_iface *tcs_iface,
383 struct lp_build_tgsi_context * bld_base,
384 boolean is_vindex_indirect,
385 LLVMValueRef vertex_index,
386 boolean is_aindex_indirect,
387 LLVMValueRef attrib_index,
388 LLVMValueRef swizzle_index);
389
390 LLVMValueRef
391 swr_tcs_llvm_fetch_output(const struct lp_build_tcs_iface *tcs_iface,
392 struct lp_build_tgsi_context * bld_base,
393 boolean is_vindex_indirect,
394 LLVMValueRef vertex_index,
395 boolean is_aindex_indirect,
396 LLVMValueRef attrib_index,
397 LLVMValueRef swizzle_index,
398 uint32_t name);
399
400 void
401 swr_tcs_llvm_store_output(const struct lp_build_tcs_iface *tcs_iface,
402 struct lp_build_tgsi_context * bld_base,
403 unsigned name,
404 boolean is_vindex_indirect,
405 LLVMValueRef vertex_index,
406 boolean is_aindex_indirect,
407 LLVMValueRef attrib_index,
408 LLVMValueRef swizzle_index,
409 LLVMValueRef value,
410 LLVMValueRef mask_vec);
411
412 // Barrier implementation (available only in TCS)
413 void
414 swr_tcs_llvm_emit_barrier(const struct lp_build_tcs_iface *tcs_iface,
415 struct lp_build_tgsi_context *bld_base);
416
417 // TES-specific emit functions
418 LLVMValueRef
419 swr_tes_llvm_fetch_vtx_input(const struct lp_build_tes_iface *tes_iface,
420 struct lp_build_tgsi_context * bld_base,
421 boolean is_vindex_indirect,
422 LLVMValueRef vertex_index,
423 boolean is_aindex_indirect,
424 LLVMValueRef attrib_index,
425 LLVMValueRef swizzle_index);
426
427 LLVMValueRef
428 swr_tes_llvm_fetch_patch_input(const struct lp_build_tes_iface *tes_iface,
429 struct lp_build_tgsi_context * bld_base,
430 boolean is_aindex_indirect,
431 LLVMValueRef attrib_index,
432 LLVMValueRef swizzle_index);
433 };
434
435 struct swr_gs_llvm_iface {
436 struct lp_build_gs_iface base;
437 struct tgsi_shader_info *info;
438
439 BuilderSWR *pBuilder;
440
441 Value *pGsCtx;
442 SWR_GS_STATE *pGsState;
443 uint32_t num_outputs;
444 uint32_t num_verts_per_prim;
445
446 Value *pVtxAttribMap;
447 };
448
449 struct swr_tcs_llvm_iface {
450 struct lp_build_tcs_iface base;
451 struct tgsi_shader_info *info;
452
453 BuilderSWR *pBuilder;
454
455 Value *pTcsCtx;
456 SWR_TS_STATE *pTsState;
457
458 uint32_t output_vertices;
459
460 LLVMValueRef loop_var;
461
462 Value *pVtxAttribMap;
463 Value *pVtxOutputAttribMap;
464 Value *pPatchOutputAttribMap;
465 };
466
467 struct swr_tes_llvm_iface {
468 struct lp_build_tes_iface base;
469 struct tgsi_shader_info *info;
470
471 BuilderSWR *pBuilder;
472
473 Value *pTesCtx;
474 SWR_TS_STATE *pTsState;
475
476 uint32_t num_outputs;
477
478 Value *pVtxAttribMap;
479 Value *pPatchAttribMap;
480 };
481
482 // trampoline functions so we can use the builder llvm construction methods
483 static LLVMValueRef
swr_gs_llvm_fetch_input(const struct lp_build_gs_iface * gs_iface,struct lp_build_context * bld,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index)484 swr_gs_llvm_fetch_input(const struct lp_build_gs_iface *gs_iface,
485 struct lp_build_context * bld,
486 boolean is_vindex_indirect,
487 LLVMValueRef vertex_index,
488 boolean is_aindex_indirect,
489 LLVMValueRef attrib_index,
490 LLVMValueRef swizzle_index)
491 {
492 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_iface;
493
494 return iface->pBuilder->swr_gs_llvm_fetch_input(gs_iface, bld,
495 is_vindex_indirect,
496 vertex_index,
497 is_aindex_indirect,
498 attrib_index,
499 swizzle_index);
500 }
501
502 static void
swr_gs_llvm_emit_vertex(const struct lp_build_gs_iface * gs_base,struct lp_build_context * bld,LLVMValueRef (* outputs)[4],LLVMValueRef emitted_vertices_vec,LLVMValueRef mask_vec,LLVMValueRef stream_id)503 swr_gs_llvm_emit_vertex(const struct lp_build_gs_iface *gs_base,
504 struct lp_build_context * bld,
505 LLVMValueRef (*outputs)[4],
506 LLVMValueRef emitted_vertices_vec,
507 LLVMValueRef mask_vec,
508 LLVMValueRef stream_id)
509 {
510 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_base;
511
512 iface->pBuilder->swr_gs_llvm_emit_vertex(gs_base, bld,
513 outputs,
514 emitted_vertices_vec,
515 stream_id);
516 }
517
518 static void
swr_gs_llvm_end_primitive(const struct lp_build_gs_iface * gs_base,struct lp_build_context * bld,LLVMValueRef total_emitted_vertices_vec_ptr,LLVMValueRef verts_per_prim_vec,LLVMValueRef emitted_prims_vec,LLVMValueRef mask_vec,unsigned stream_id)519 swr_gs_llvm_end_primitive(const struct lp_build_gs_iface *gs_base,
520 struct lp_build_context * bld,
521 LLVMValueRef total_emitted_vertices_vec_ptr,
522 LLVMValueRef verts_per_prim_vec,
523 LLVMValueRef emitted_prims_vec,
524 LLVMValueRef mask_vec, unsigned stream_id)
525 {
526 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_base;
527
528 iface->pBuilder->swr_gs_llvm_end_primitive(gs_base, bld,
529 total_emitted_vertices_vec_ptr,
530 verts_per_prim_vec,
531 emitted_prims_vec,
532 mask_vec);
533 }
534
535 static void
swr_gs_llvm_epilogue(const struct lp_build_gs_iface * gs_base,LLVMValueRef total_emitted_vertices_vec,LLVMValueRef emitted_prims_vec,unsigned stream)536 swr_gs_llvm_epilogue(const struct lp_build_gs_iface *gs_base,
537 LLVMValueRef total_emitted_vertices_vec,
538 LLVMValueRef emitted_prims_vec, unsigned stream)
539 {
540 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_base;
541
542 iface->pBuilder->swr_gs_llvm_epilogue(gs_base,
543 total_emitted_vertices_vec,
544 emitted_prims_vec, stream);
545 }
546
547 static LLVMValueRef
swr_tcs_llvm_fetch_input(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_context * bld,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,boolean is_sindex_indirect,LLVMValueRef swizzle_index)548 swr_tcs_llvm_fetch_input(const struct lp_build_tcs_iface *tcs_iface,
549 struct lp_build_context * bld,
550 boolean is_vindex_indirect,
551 LLVMValueRef vertex_index,
552 boolean is_aindex_indirect,
553 LLVMValueRef attrib_index,
554 boolean is_sindex_indirect,
555 LLVMValueRef swizzle_index)
556 {
557 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
558 struct lp_build_tgsi_context *bld_base = (struct lp_build_tgsi_context*)bld;
559
560 return iface->pBuilder->swr_tcs_llvm_fetch_input(tcs_iface, bld_base,
561 is_vindex_indirect,
562 vertex_index,
563 is_aindex_indirect,
564 attrib_index,
565 swizzle_index);
566 }
567
568 static LLVMValueRef
swr_tcs_llvm_fetch_output(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_context * bld,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,boolean is_sindex_indirect,LLVMValueRef swizzle_index,uint32_t name)569 swr_tcs_llvm_fetch_output(const struct lp_build_tcs_iface *tcs_iface,
570 struct lp_build_context * bld,
571 boolean is_vindex_indirect,
572 LLVMValueRef vertex_index,
573 boolean is_aindex_indirect,
574 LLVMValueRef attrib_index,
575 boolean is_sindex_indirect,
576 LLVMValueRef swizzle_index,
577 uint32_t name)
578 {
579 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
580 struct lp_build_tgsi_context *bld_base = (struct lp_build_tgsi_context*)bld;
581
582 return iface->pBuilder->swr_tcs_llvm_fetch_output(tcs_iface, bld_base,
583 is_vindex_indirect,
584 vertex_index,
585 is_aindex_indirect,
586 attrib_index,
587 swizzle_index,
588 name);
589 }
590
591
592 static void
swr_tcs_llvm_emit_prologue(struct lp_build_context * bld)593 swr_tcs_llvm_emit_prologue(struct lp_build_context* bld)
594 {
595 lp_build_tgsi_soa_context* bld_base = (lp_build_tgsi_soa_context*)bld;
596 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)bld_base->tcs_iface;
597 iface->pBuilder->swr_tcs_llvm_emit_prologue(bld_base);
598 }
599
600 static void
swr_tcs_llvm_emit_epilogue(struct lp_build_context * bld)601 swr_tcs_llvm_emit_epilogue(struct lp_build_context* bld)
602 {
603 lp_build_tgsi_soa_context* bld_base = (lp_build_tgsi_soa_context*)bld;
604 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)bld_base->tcs_iface;
605 iface->pBuilder->swr_tcs_llvm_emit_epilogue(bld_base);
606 }
607
608 static
swr_tcs_llvm_store_output(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_context * bld,unsigned name,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,boolean is_sindex_indirect,LLVMValueRef swizzle_index,LLVMValueRef value,LLVMValueRef mask_vec)609 void swr_tcs_llvm_store_output(const struct lp_build_tcs_iface *tcs_iface,
610 struct lp_build_context * bld,
611 unsigned name,
612 boolean is_vindex_indirect,
613 LLVMValueRef vertex_index,
614 boolean is_aindex_indirect,
615 LLVMValueRef attrib_index,
616 boolean is_sindex_indirect,
617 LLVMValueRef swizzle_index,
618 LLVMValueRef value,
619 LLVMValueRef mask_vec)
620 {
621 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
622 struct lp_build_tgsi_context *bld_base = (struct lp_build_tgsi_context*)bld;
623
624 iface->pBuilder->swr_tcs_llvm_store_output(tcs_iface,
625 bld_base,
626 name,
627 is_vindex_indirect,
628 vertex_index,
629 is_aindex_indirect,
630 attrib_index,
631 swizzle_index,
632 value,
633 mask_vec);
634 }
635
636
637 static
swr_tcs_llvm_emit_barrier(struct lp_build_context * bld)638 void swr_tcs_llvm_emit_barrier(struct lp_build_context *bld)
639 {
640 lp_build_tgsi_soa_context* bld_base = (lp_build_tgsi_soa_context*)bld;
641 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)bld_base->tcs_iface;
642
643 iface->pBuilder->swr_tcs_llvm_emit_barrier(bld_base->tcs_iface, &bld_base->bld_base);
644 }
645
646
647 static LLVMValueRef
swr_tes_llvm_fetch_vtx_input(const struct lp_build_tes_iface * tes_iface,struct lp_build_context * bld,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,boolean is_sindex_indirect,LLVMValueRef swizzle_index)648 swr_tes_llvm_fetch_vtx_input(const struct lp_build_tes_iface *tes_iface,
649 struct lp_build_context * bld,
650 boolean is_vindex_indirect,
651 LLVMValueRef vertex_index,
652 boolean is_aindex_indirect,
653 LLVMValueRef attrib_index,
654 boolean is_sindex_indirect,
655 LLVMValueRef swizzle_index)
656 {
657 swr_tes_llvm_iface *iface = (swr_tes_llvm_iface*)tes_iface;
658 struct lp_build_tgsi_context *bld_base = (struct lp_build_tgsi_context*)bld;
659
660 return iface->pBuilder->swr_tes_llvm_fetch_vtx_input(tes_iface, bld_base,
661 is_vindex_indirect,
662 vertex_index,
663 is_aindex_indirect,
664 attrib_index,
665 swizzle_index);
666 }
667
668 static LLVMValueRef
swr_tes_llvm_fetch_patch_input(const struct lp_build_tes_iface * tes_iface,struct lp_build_context * bld,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index)669 swr_tes_llvm_fetch_patch_input(const struct lp_build_tes_iface *tes_iface,
670 struct lp_build_context * bld,
671 boolean is_aindex_indirect,
672 LLVMValueRef attrib_index,
673 LLVMValueRef swizzle_index)
674 {
675 swr_tes_llvm_iface *iface = (swr_tes_llvm_iface*)tes_iface;
676 struct lp_build_tgsi_context *bld_base = (struct lp_build_tgsi_context*)bld;
677
678 return iface->pBuilder->swr_tes_llvm_fetch_patch_input(tes_iface, bld_base,
679 is_aindex_indirect,
680 attrib_index,
681 swizzle_index);
682 }
683
684 LLVMValueRef
swr_gs_llvm_fetch_input(const struct lp_build_gs_iface * gs_iface,struct lp_build_context * bld,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index)685 BuilderSWR::swr_gs_llvm_fetch_input(const struct lp_build_gs_iface *gs_iface,
686 struct lp_build_context * bld,
687 boolean is_vindex_indirect,
688 LLVMValueRef vertex_index,
689 boolean is_aindex_indirect,
690 LLVMValueRef attrib_index,
691 LLVMValueRef swizzle_index)
692 {
693 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_iface;
694 Value *vert_index = unwrap(vertex_index);
695 Value *attr_index = unwrap(attrib_index);
696
697 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
698
699 if (is_vindex_indirect || is_aindex_indirect) {
700 int i;
701 Value *res = unwrap(bld->zero);
702 struct lp_type type = bld->type;
703
704 for (i = 0; i < type.length; i++) {
705 Value *vert_chan_index = vert_index;
706 Value *attr_chan_index = attr_index;
707
708 if (is_vindex_indirect) {
709 vert_chan_index = VEXTRACT(vert_index, C(i));
710 }
711 if (is_aindex_indirect) {
712 attr_chan_index = VEXTRACT(attr_index, C(i));
713 }
714
715 Value *attrib =
716 LOAD(GEP(iface->pVtxAttribMap, {C(0), attr_chan_index}));
717
718 Value *pVertex = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_pVerts});
719 Value *pInputVertStride = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_inputVertStride});
720
721 Value *pVector = ADD(MUL(vert_chan_index, pInputVertStride), attrib);
722 Value *pInput = LOAD(GEP(pVertex, {pVector, unwrap(swizzle_index)}));
723
724 Value *value = VEXTRACT(pInput, C(i));
725 res = VINSERT(res, value, C(i));
726 }
727
728 return wrap(res);
729 } else {
730 Value *attrib = LOAD(GEP(iface->pVtxAttribMap, {C(0), attr_index}));
731
732 Value *pVertex = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_pVerts});
733 Value *pInputVertStride = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_inputVertStride});
734
735 Value *pVector = ADD(MUL(vert_index, pInputVertStride), attrib);
736
737 Value *pInput = LOAD(GEP(pVertex, {pVector, unwrap(swizzle_index)}));
738
739 return wrap(pInput);
740 }
741 }
742
743 // GS output stream layout
744 #define VERTEX_COUNT_SIZE 32
745 #define CONTROL_HEADER_SIZE (8*32)
746
747 void
swr_gs_llvm_emit_vertex(const struct lp_build_gs_iface * gs_base,struct lp_build_context * bld,LLVMValueRef (* outputs)[4],LLVMValueRef emitted_vertices_vec,LLVMValueRef stream_id)748 BuilderSWR::swr_gs_llvm_emit_vertex(const struct lp_build_gs_iface *gs_base,
749 struct lp_build_context * bld,
750 LLVMValueRef (*outputs)[4],
751 LLVMValueRef emitted_vertices_vec,
752 LLVMValueRef stream_id)
753 {
754 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_base;
755
756 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
757 const uint32_t headerSize = VERTEX_COUNT_SIZE + CONTROL_HEADER_SIZE;
758 const uint32_t attribSize = 4 * sizeof(float);
759 const uint32_t vertSize = attribSize * SWR_VTX_NUM_SLOTS;
760 Value *pVertexOffset = MUL(unwrap(emitted_vertices_vec), VIMMED1(vertSize));
761
762 Value *vMask = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_mask});
763 Value *vMask1 = TRUNC(vMask, getVectorType(mInt1Ty, mVWidth));
764
765 Value *pStack = STACKSAVE();
766 Value *pTmpPtr = ALLOCA(mFP32Ty, C(4)); // used for dummy write for lane masking
767
768 for (uint32_t attrib = 0; attrib < iface->num_outputs; ++attrib) {
769 uint32_t attribSlot = attrib;
770 uint32_t sgvChannel = 0;
771 if (iface->info->output_semantic_name[attrib] == TGSI_SEMANTIC_PSIZE) {
772 attribSlot = VERTEX_SGV_SLOT;
773 sgvChannel = VERTEX_SGV_POINT_SIZE_COMP;
774 } else if (iface->info->output_semantic_name[attrib] == TGSI_SEMANTIC_LAYER) {
775 attribSlot = VERTEX_SGV_SLOT;
776 sgvChannel = VERTEX_SGV_RTAI_COMP;
777 } else if (iface->info->output_semantic_name[attrib] == TGSI_SEMANTIC_VIEWPORT_INDEX) {
778 attribSlot = VERTEX_SGV_SLOT;
779 sgvChannel = VERTEX_SGV_VAI_COMP;
780 } else if (iface->info->output_semantic_name[attrib] == TGSI_SEMANTIC_POSITION) {
781 attribSlot = VERTEX_POSITION_SLOT;
782 } else {
783 attribSlot = VERTEX_ATTRIB_START_SLOT + attrib;
784 if (iface->info->writes_position) {
785 attribSlot--;
786 }
787 }
788
789 Value *pOutputOffset = ADD(pVertexOffset, VIMMED1(headerSize + attribSize * attribSlot)); // + sgvChannel ?
790
791 for (uint32_t lane = 0; lane < mVWidth; ++lane) {
792 Value *pLaneOffset = VEXTRACT(pOutputOffset, C(lane));
793 Value *pStream = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_pStreams, lane});
794 Value *pStreamOffset = GEP(pStream, pLaneOffset);
795 pStreamOffset = BITCAST(pStreamOffset, mFP32PtrTy);
796
797 Value *pLaneMask = VEXTRACT(vMask1, C(lane));
798 pStreamOffset = SELECT(pLaneMask, pStreamOffset, pTmpPtr);
799
800 for (uint32_t channel = 0; channel < 4; ++channel) {
801 Value *vData;
802
803 if (attribSlot == VERTEX_SGV_SLOT)
804 vData = LOAD(unwrap(outputs[attrib][0]));
805 else
806 vData = LOAD(unwrap(outputs[attrib][channel]));
807
808 if (attribSlot != VERTEX_SGV_SLOT ||
809 sgvChannel == channel) {
810 vData = VEXTRACT(vData, C(lane));
811 STORE(vData, pStreamOffset);
812 }
813 pStreamOffset = GEP(pStreamOffset, C(1));
814 }
815 }
816 }
817
818 /* When the output type is not points, the geometry shader may not
819 * output data to multiple streams. So early exit here.
820 */
821 if(iface->pGsState->outputTopology != TOP_POINT_LIST) {
822 STACKRESTORE(pStack);
823 return;
824 }
825
826 // Info about stream id for each vertex
827 // is coded in 2 bits (4 vert per byte "box"):
828 // ----------------- ----------------- ----
829 // |d|d|c|c|b|b|a|a| |h|h|g|g|f|f|e|e| |...
830 // ----------------- ----------------- ----
831
832 // Calculate where need to put stream id for current vert
833 // in 1 byte "box".
834 Value *pShiftControl = MUL(unwrap(emitted_vertices_vec), VIMMED1(2));
835
836 // Calculate in which box put stream id for current vert.
837 Value *pOffsetControl = LSHR(unwrap(emitted_vertices_vec), VIMMED1(2));
838
839 // Skip count header
840 Value *pStreamIdOffset = ADD(pOffsetControl, VIMMED1(VERTEX_COUNT_SIZE));
841
842 for (uint32_t lane = 0; lane < mVWidth; ++lane) {
843 Value *pShift = TRUNC(VEXTRACT(pShiftControl, C(lane)), mInt8Ty);
844 Value *pStream = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_pStreams, lane});
845
846 Value *pStreamOffset = GEP(pStream, VEXTRACT(pStreamIdOffset, C(lane)));
847
848 // Just make sure that not overflow max - stream id = (0,1,2,3)
849 Value *vVal = TRUNC(AND(VEXTRACT(unwrap(stream_id), C(0)), C(0x3)), mInt8Ty);
850
851 // Shift it to correct position in byte "box"
852 vVal = SHL(vVal, pShift);
853
854 // Info about other vertices can be already stored
855 // so we need to read and add bits from current vert info.
856 Value *storedValue = LOAD(pStreamOffset);
857 vVal = OR(storedValue, vVal);
858 STORE(vVal, pStreamOffset);
859 }
860
861 STACKRESTORE(pStack);
862 }
863
864 void
swr_gs_llvm_end_primitive(const struct lp_build_gs_iface * gs_base,struct lp_build_context * bld,LLVMValueRef total_emitted_vertices_vec,LLVMValueRef verts_per_prim_vec,LLVMValueRef emitted_prims_vec,LLVMValueRef mask_vec)865 BuilderSWR::swr_gs_llvm_end_primitive(const struct lp_build_gs_iface *gs_base,
866 struct lp_build_context * bld,
867 LLVMValueRef total_emitted_vertices_vec,
868 LLVMValueRef verts_per_prim_vec,
869 LLVMValueRef emitted_prims_vec,
870 LLVMValueRef mask_vec)
871 {
872 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_base;
873
874 /* When the output type is points, the geometry shader may output data
875 * to multiple streams, and end_primitive has no effect. Info about
876 * stream id for vertices is stored into the same place in memory where
877 * end primitive info is stored so early exit in this case.
878 */
879 if (iface->pGsState->outputTopology == TOP_POINT_LIST) {
880 return;
881 }
882
883 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
884
885 Value *vMask = LOAD(iface->pGsCtx, { 0, SWR_GS_CONTEXT_mask });
886 Value *vMask1 = TRUNC(vMask, getVectorType(mInt1Ty, 8));
887
888 uint32_t vertsPerPrim = iface->num_verts_per_prim;
889
890 Value *vCount =
891 ADD(MUL(unwrap(emitted_prims_vec), VIMMED1(vertsPerPrim)),
892 unwrap(verts_per_prim_vec));
893
894 vCount = unwrap(total_emitted_vertices_vec);
895
896 Value *mask = unwrap(mask_vec);
897 Value *cmpMask = VMASK(ICMP_NE(unwrap(verts_per_prim_vec), VIMMED1(0)));
898 mask = AND(mask, cmpMask);
899 vMask1 = TRUNC(mask, getVectorType(mInt1Ty, 8));
900
901 vCount = SUB(vCount, VIMMED1(1));
902 Value *vOffset = ADD(UDIV(vCount, VIMMED1(8)), VIMMED1(VERTEX_COUNT_SIZE));
903 Value *vValue = SHL(VIMMED1(1), UREM(vCount, VIMMED1(8)));
904
905 vValue = TRUNC(vValue, getVectorType(mInt8Ty, 8));
906
907 Value *pStack = STACKSAVE();
908 Value *pTmpPtr = ALLOCA(mInt8Ty, C(4)); // used for dummy read/write for lane masking
909
910 for (uint32_t lane = 0; lane < mVWidth; ++lane) {
911 Value *vLaneOffset = VEXTRACT(vOffset, C(lane));
912 Value *pStream = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_pStreams, lane});
913 Value *pStreamOffset = GEP(pStream, vLaneOffset);
914
915 Value *pLaneMask = VEXTRACT(vMask1, C(lane));
916 pStreamOffset = SELECT(pLaneMask, pStreamOffset, pTmpPtr);
917
918 Value *vVal = LOAD(pStreamOffset);
919 vVal = OR(vVal, VEXTRACT(vValue, C(lane)));
920 STORE(vVal, pStreamOffset);
921 }
922
923 STACKRESTORE(pStack);
924 }
925
926 void
swr_gs_llvm_epilogue(const struct lp_build_gs_iface * gs_base,LLVMValueRef total_emitted_vertices_vec,LLVMValueRef emitted_prims_vec,unsigned stream)927 BuilderSWR::swr_gs_llvm_epilogue(const struct lp_build_gs_iface *gs_base,
928 LLVMValueRef total_emitted_vertices_vec,
929 LLVMValueRef emitted_prims_vec, unsigned stream)
930 {
931 swr_gs_llvm_iface *iface = (swr_gs_llvm_iface*)gs_base;
932
933 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
934
935 // Store emit count to each output stream in the first DWORD
936 for (uint32_t lane = 0; lane < mVWidth; ++lane)
937 {
938 Value* pStream = LOAD(iface->pGsCtx, {0, SWR_GS_CONTEXT_pStreams, lane});
939 pStream = BITCAST(pStream, mInt32PtrTy);
940 Value* pLaneCount = VEXTRACT(unwrap(total_emitted_vertices_vec), C(lane));
941 STORE(pLaneCount, pStream);
942 }
943 }
944
945 void
swr_tcs_llvm_emit_prologue(struct lp_build_tgsi_soa_context * bld)946 BuilderSWR::swr_tcs_llvm_emit_prologue(struct lp_build_tgsi_soa_context* bld)
947 {
948 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)bld->tcs_iface;
949
950 Value* loop_var = ALLOCA(mSimdInt32Ty);
951 STORE(VBROADCAST(C(0)), loop_var);
952
953 iface->loop_var = wrap(loop_var);
954
955 lp_exec_bgnloop(&bld->exec_mask, true);
956
957 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
958 bld->system_values.invocation_id = wrap((LOAD(unwrap(iface->loop_var))));
959
960 if (verbose_tcs_shader_loop) {
961 lp_build_print_value(gallivm, "Prologue LOOP Iteration BEGIN:", bld->system_values.invocation_id);
962 }
963
964 }
965
966 void
swr_tcs_llvm_emit_epilogue(struct lp_build_tgsi_soa_context * bld)967 BuilderSWR::swr_tcs_llvm_emit_epilogue(struct lp_build_tgsi_soa_context* bld)
968 {
969 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)bld->tcs_iface;
970
971 struct lp_build_context *uint_bld = &bld->bld_base.uint_bld;
972
973 STORE(ADD(LOAD(unwrap(iface->loop_var)), VBROADCAST(C(1))), unwrap(iface->loop_var));
974 if (verbose_tcs_shader_loop) {
975 lp_build_print_value(gallivm, "Epilogue LOOP: ", wrap(LOAD(unwrap(iface->loop_var))));
976 }
977
978 LLVMValueRef tmp = lp_build_cmp(uint_bld, PIPE_FUNC_GEQUAL, wrap(LOAD(unwrap(iface->loop_var))),
979 wrap(VBROADCAST(C(iface->output_vertices))));
980 lp_exec_mask_cond_push(&bld->exec_mask, tmp);
981 lp_exec_break(&bld->exec_mask, &bld->bld_base.pc, false);
982 lp_exec_mask_cond_pop(&bld->exec_mask);
983 lp_exec_endloop(bld->bld_base.base.gallivm, &bld->exec_mask);
984 }
985
986 LLVMValueRef
swr_tcs_llvm_fetch_input(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_tgsi_context * bld_base,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index)987 BuilderSWR::swr_tcs_llvm_fetch_input(const struct lp_build_tcs_iface *tcs_iface,
988 struct lp_build_tgsi_context * bld_base,
989 boolean is_vindex_indirect,
990 LLVMValueRef vertex_index,
991 boolean is_aindex_indirect,
992 LLVMValueRef attrib_index,
993 LLVMValueRef swizzle_index)
994 {
995 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
996
997 Value *vert_index = unwrap(vertex_index);
998 Value *attr_index = unwrap(attrib_index);
999
1000 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1001
1002 if (verbose_tcs_shader_in) {
1003 lp_build_printf(gallivm, "[TCS IN][VTX] ======================================\n");
1004 lp_build_print_value(gallivm, "[TCS IN][VTX] vertex_index: ", vertex_index);
1005 lp_build_print_value(gallivm, "[TCS IN][VTX] attrib_index: ", attrib_index);
1006 lp_build_printf(gallivm, "[TCS IN][VTX] --------------------------------------\n");
1007 }
1008
1009 Value *res = unwrap(bld_base->base.zero);
1010 if (is_vindex_indirect || is_aindex_indirect) {
1011 int i;
1012 struct lp_type type = bld_base->base.type;
1013
1014 for (i = 0; i < type.length; i++) {
1015 Value *vert_chan_index = vert_index;
1016 Value *attr_chan_index = attr_index;
1017
1018 if (is_vindex_indirect) {
1019 vert_chan_index = VEXTRACT(vert_index, C(i));
1020 }
1021 if (is_aindex_indirect) {
1022 attr_chan_index = VEXTRACT(attr_index, C(i));
1023 }
1024
1025 Value *attrib =
1026 LOAD(GEP(iface->pVtxAttribMap, {C(0), attr_chan_index}));
1027
1028 Value *pBase = GEP(iface->pTcsCtx,
1029 { C(0), C(SWR_HS_CONTEXT_vert), vert_chan_index,
1030 C(simdvertex_attrib), attrib, unwrap(swizzle_index), C(i) });
1031
1032 Value *val = LOAD(pBase);
1033
1034 if (verbose_tcs_shader_in) {
1035 lp_build_print_value(gallivm, "[TCS IN][VTX] vert_chan_index: ", wrap(vert_chan_index));
1036 lp_build_print_value(gallivm, "[TCS IN][VTX] attrib_index: ", attrib_index);
1037 lp_build_print_value(gallivm, "[TCS IN][VTX] attr_chan_index: ", wrap(attr_index));
1038 lp_build_print_value(gallivm, "[TCS IN][VTX] attrib read from map: ", wrap(attrib));
1039 lp_build_print_value(gallivm, "[TCS IN][VTX] swizzle_index: ", swizzle_index);
1040 lp_build_print_value(gallivm, "[TCS IN][VTX] Loaded: ", wrap(val));
1041 }
1042 res = VINSERT(res, val, C(i));
1043 }
1044 } else {
1045 Value *attrib = LOAD(GEP(iface->pVtxAttribMap, {C(0), attr_index}));
1046
1047 Value *pBase = GEP(iface->pTcsCtx,
1048 { C(0), C(SWR_HS_CONTEXT_vert), vert_index,
1049 C(simdvertex_attrib), attrib, unwrap(swizzle_index) });
1050
1051 res = LOAD(pBase);
1052
1053 if (verbose_tcs_shader_in) {
1054 lp_build_print_value(gallivm, "[TCS IN][VTX] attrib_index: ", attrib_index);
1055 lp_build_print_value(gallivm, "[TCS IN][VTX] attr_chan_index: ", wrap(attr_index));
1056 lp_build_print_value(gallivm, "[TCS IN][VTX] attrib read from map: ", wrap(attrib));
1057 lp_build_print_value(gallivm, "[TCS IN][VTX] swizzle_index: ", swizzle_index);
1058 lp_build_print_value(gallivm, "[TCS IN][VTX] Loaded: ", wrap(res));
1059 }
1060 }
1061 if (verbose_tcs_shader_in) {
1062 lp_build_print_value(gallivm, "[TCS IN][VTX] returning: ", wrap(res));
1063 }
1064 return wrap(res);
1065 }
1066
1067 LLVMValueRef
swr_tcs_llvm_fetch_output(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_tgsi_context * bld_base,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index,uint32_t name)1068 BuilderSWR::swr_tcs_llvm_fetch_output(const struct lp_build_tcs_iface *tcs_iface,
1069 struct lp_build_tgsi_context * bld_base,
1070 boolean is_vindex_indirect,
1071 LLVMValueRef vertex_index,
1072 boolean is_aindex_indirect,
1073 LLVMValueRef attrib_index,
1074 LLVMValueRef swizzle_index,
1075 uint32_t name)
1076 {
1077 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
1078
1079 Value *vert_index = unwrap(vertex_index);
1080 Value *attr_index = unwrap(attrib_index);
1081
1082 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1083
1084 if (verbose_tcs_shader_in) {
1085 lp_build_print_value(gallivm, "[TCS INOUT] Vertex index: ", vertex_index);
1086 lp_build_print_value(gallivm, "[TCS INOUT] Attrib index: ", wrap(attr_index));
1087 lp_build_print_value(gallivm, "[TCS INOUT] Swizzle index: ", swizzle_index);
1088 }
1089
1090 Value* res = unwrap(bld_base->base.zero);
1091
1092 for (uint32_t lane = 0; lane < mVWidth; lane++) {
1093 Value* p1 = LOAD(iface->pTcsCtx, {0, SWR_HS_CONTEXT_pCPout});
1094 Value* pCpOut = GEP(p1, {lane});
1095
1096 Value *vert_chan_index = vert_index;
1097 Value *attr_chan_index = attr_index;
1098
1099 if (is_vindex_indirect) {
1100 vert_chan_index = VEXTRACT(vert_index, C(lane));
1101 if (verbose_tcs_shader_in) {
1102 lp_build_print_value(gallivm, "[TCS INOUT] Extracted vertex index: ", wrap(vert_chan_index));
1103 }
1104 }
1105
1106 if (is_aindex_indirect) {
1107 attr_chan_index = VEXTRACT(attr_index, C(lane));
1108 if (verbose_tcs_shader_in) {
1109 lp_build_print_value(gallivm, "[TCS INOUT] Extracted attrib index: ", wrap(attr_chan_index));
1110 }
1111 }
1112
1113 if (name == TGSI_SEMANTIC_TESSOUTER || name == TGSI_SEMANTIC_TESSINNER) {
1114 Value* tessFactors = GEP(pCpOut, {(uint32_t)0, ScalarPatch_tessFactors});
1115 Value* tessFactorArray = nullptr;
1116 if (name == TGSI_SEMANTIC_TESSOUTER) {
1117 tessFactorArray = GEP(tessFactors, {(uint32_t)0, SWR_TESSELLATION_FACTORS_OuterTessFactors});
1118 } else {
1119 tessFactorArray = GEP(tessFactors, {(uint32_t)0, SWR_TESSELLATION_FACTORS_InnerTessFactors});
1120 }
1121 Value* tessFactor = GEP(tessFactorArray, {C(0), unwrap(swizzle_index)});
1122 res = VINSERT(res, LOAD(tessFactor), C(lane));
1123 if (verbose_tcs_shader_in) {
1124 lp_build_print_value(gallivm, "[TCS INOUT][FACTOR] lane (patch-id): ", wrap(C(lane)));
1125 lp_build_print_value(gallivm, "[TCS INOUT][FACTOR] loaded value: ", wrap(res));
1126 }
1127 } else if (name == TGSI_SEMANTIC_PATCH) {
1128 Value* attr_index_from_map = LOAD(GEP(iface->pPatchOutputAttribMap, {C(0), attr_chan_index}));
1129 Value* attr_value = GEP(pCpOut, {C(0), C(ScalarPatch_patchData), C(ScalarCPoint_attrib), attr_index_from_map, unwrap(swizzle_index)});
1130 res = VINSERT(res, LOAD(attr_value), C(lane));
1131 if (verbose_tcs_shader_in) {
1132 lp_build_print_value(gallivm, "[TCS INOUT][PATCH] attr index loaded from map: ", wrap(attr_index_from_map));
1133 lp_build_print_value(gallivm, "[TCS INOUT][PATCH] lane (patch-id): ", wrap(C(lane)));
1134 lp_build_print_value(gallivm, "[TCS INOUT][PATCH] loaded value: ", wrap(res));
1135 }
1136 } else {
1137 // Generic attribute
1138 Value *attrib =
1139 LOAD(GEP(iface->pVtxOutputAttribMap, {C(0), attr_chan_index}));
1140 if (verbose_tcs_shader_in) {
1141 lp_build_print_value(gallivm, "[TCS INOUT][VTX] Attrib index from map: ", wrap(attrib));
1142 }
1143 Value* attr_chan = GEP(pCpOut, {C(0), C(ScalarPatch_cp), vert_chan_index,
1144 C(ScalarCPoint_attrib), attrib, unwrap(swizzle_index)});
1145
1146 res = VINSERT(res, LOAD(attr_chan), C(lane));
1147 if (verbose_tcs_shader_in) {
1148 lp_build_print_value(gallivm, "[TCS INOUT][VTX] loaded value: ", wrap(res));
1149 }
1150 }
1151 }
1152
1153 return wrap(res);
1154 }
1155
1156 void
swr_tcs_llvm_store_output(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_tgsi_context * bld_base,unsigned name,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index,LLVMValueRef value,LLVMValueRef mask_vec)1157 BuilderSWR::swr_tcs_llvm_store_output(const struct lp_build_tcs_iface *tcs_iface,
1158 struct lp_build_tgsi_context *bld_base,
1159 unsigned name,
1160 boolean is_vindex_indirect,
1161 LLVMValueRef vertex_index,
1162 boolean is_aindex_indirect,
1163 LLVMValueRef attrib_index,
1164 LLVMValueRef swizzle_index,
1165 LLVMValueRef value,
1166 LLVMValueRef mask_vec)
1167 {
1168 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
1169 struct lp_build_tgsi_soa_context* bld = (struct lp_build_tgsi_soa_context*)bld_base;
1170
1171 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1172
1173 if (verbose_tcs_shader_out) {
1174 lp_build_printf(gallivm, "[TCS OUT] =============================================\n");
1175 }
1176
1177 if (verbose_tcs_shader_out) {
1178 lp_build_print_value(gallivm, "[TCS OUT] Store mask: ", bld->exec_mask.exec_mask);
1179 lp_build_print_value(gallivm, "[TCS OUT] Store value: ", value);
1180 }
1181
1182 Value *vert_index = unwrap(vertex_index);
1183 Value *attr_index = unwrap(attrib_index);
1184
1185 if (verbose_tcs_shader_out) {
1186 lp_build_print_value(gallivm, "[TCS OUT] Vertex index: ", vertex_index);
1187 lp_build_print_value(gallivm, "[TCS OUT] Attrib index: ", wrap(attr_index));
1188 lp_build_print_value(gallivm, "[TCS OUT] Swizzle index: ", swizzle_index);
1189 }
1190
1191 if (is_vindex_indirect) {
1192 vert_index = VEXTRACT(vert_index, C(0));
1193 if (verbose_tcs_shader_out) {
1194 lp_build_print_value(gallivm, "[TCS OUT] Extracted vertex index: ", vertex_index);
1195 }
1196 }
1197
1198 if (is_aindex_indirect) {
1199 attr_index = VEXTRACT(attr_index, C(0));
1200 if (verbose_tcs_shader_out) {
1201 lp_build_print_value(gallivm, "[TCS OUT] Extracted attrib index: ", wrap(attr_index));
1202 }
1203 }
1204
1205 if (verbose_tcs_shader_out) {
1206 if (bld->exec_mask.has_mask) {
1207 lp_build_print_value(gallivm, "[TCS OUT] Exec mask: ", bld->exec_mask.exec_mask);
1208 }
1209 else {
1210 lp_build_printf(gallivm, "[TCS OUT] has no mask\n");
1211 }
1212 }
1213 for (uint32_t lane = 0; lane < mVWidth; lane++) {
1214 Value* p1 = LOAD(iface->pTcsCtx, {0, SWR_HS_CONTEXT_pCPout});
1215 Value* pCpOut = GEP(p1, {lane});
1216
1217 if (name == TGSI_SEMANTIC_TESSOUTER || name == TGSI_SEMANTIC_TESSINNER) {
1218 Value* tessFactors = GEP(pCpOut, {(uint32_t)0, ScalarPatch_tessFactors});
1219 Value* tessFactorArray = nullptr;
1220 if (name == TGSI_SEMANTIC_TESSOUTER) {
1221 tessFactorArray = GEP(tessFactors, {(uint32_t)0, SWR_TESSELLATION_FACTORS_OuterTessFactors});
1222 } else {
1223 tessFactorArray = GEP(tessFactors, {(uint32_t)0, SWR_TESSELLATION_FACTORS_InnerTessFactors});
1224 }
1225 Value* tessFactor = GEP(tessFactorArray, {C(0), unwrap(swizzle_index)});
1226 Value* valueToStore = VEXTRACT(unwrap(value), C(lane));
1227 valueToStore = BITCAST(valueToStore, mFP32Ty);
1228 if (mask_vec) {
1229 Value *originalVal = LOAD(tessFactor);
1230 Value *vMask = TRUNC(VEXTRACT(unwrap(mask_vec), C(lane)), mInt1Ty);
1231 valueToStore = SELECT(vMask, valueToStore, originalVal);
1232 }
1233 STORE(valueToStore, tessFactor);
1234 if (verbose_tcs_shader_out)
1235 {
1236 lp_build_print_value(gallivm, "[TCS OUT][FACTOR] Mask_vec mask: ", mask_vec);
1237 lp_build_print_value(gallivm, "[TCS OUT][FACTOR] Stored value: ", wrap(valueToStore));
1238 }
1239 } else if (name == TGSI_SEMANTIC_PATCH) {
1240 Value* attrib = LOAD(GEP(iface->pPatchOutputAttribMap, {C(0), attr_index}));
1241 if (verbose_tcs_shader_out) {
1242 lp_build_print_value(gallivm, "[TCS OUT][PATCH] vert_index: ", wrap(vert_index));
1243 lp_build_print_value(gallivm, "[TCS OUT][PATCH] attr_index: ", wrap(attr_index));
1244 lp_build_print_value(gallivm, "[TCS OUT][PATCH] vert_index_indirect: ", wrap(C(is_vindex_indirect)));
1245 lp_build_print_value(gallivm, "[TCS OUT][PATCH] attr_index_indirect: ", wrap(C(is_aindex_indirect)));
1246 lp_build_print_value(gallivm, "[TCS OUT][PATCH] attr index loaded from map: ", wrap(attrib));
1247 }
1248 Value* attr = GEP(pCpOut, {C(0), C(ScalarPatch_patchData), C(ScalarCPoint_attrib), attrib});
1249 Value* value_to_store = VEXTRACT(unwrap(value), C(lane));
1250 if (verbose_tcs_shader_out) {
1251 lp_build_print_value(gallivm, "[TCS OUT][PATCH] lane (patch-id): ", wrap(C(lane)));
1252 lp_build_print_value(gallivm, "[TCS OUT][PATCH] value to store: ", value);
1253 lp_build_print_value(gallivm, "[TCS OUT][PATCH] per-patch value to store: ", wrap(value_to_store));
1254 lp_build_print_value(gallivm, "[TCS OUT][PATCH] chan_index: ", swizzle_index);
1255 }
1256 value_to_store = BITCAST(value_to_store, mFP32Ty);
1257 if (mask_vec) {
1258 Value *originalVal = LOADV(attr, {C(0), unwrap(swizzle_index)});
1259 Value *vMask = TRUNC(VEXTRACT(unwrap(mask_vec), C(lane)), mInt1Ty);
1260 value_to_store = SELECT(vMask, value_to_store, originalVal);
1261 if (verbose_tcs_shader_out) {
1262 lp_build_print_value(gallivm, "[TCS OUT][PATCH] store mask: ", mask_vec);
1263 lp_build_print_value(gallivm, "[TCS OUT][PATCH] loaded original value: ", wrap(originalVal));
1264 lp_build_print_value(gallivm, "[TCS OUT][PATCH] vMask: ", wrap(vMask));
1265 lp_build_print_value(gallivm, "[TCS OUT][PATCH] selected value to store: ", wrap(value_to_store));
1266 }
1267 }
1268 STOREV(value_to_store, attr, {C(0), unwrap(swizzle_index)});
1269 if (verbose_tcs_shader_out) {
1270 lp_build_print_value(gallivm, "[TCS OUT][PATCH] stored value: ", wrap(value_to_store));
1271 }
1272 } else {
1273 Value* value_to_store = VEXTRACT(unwrap(value), C(lane));
1274 Value* attrib = LOAD(GEP(iface->pVtxOutputAttribMap, {C(0), attr_index}));
1275
1276 if (verbose_tcs_shader_out) {
1277 lp_build_printf(gallivm, "[TCS OUT] Writting attribute\n");
1278 lp_build_print_value(gallivm, "[TCS OUT][VTX] invocation_id: ", bld->system_values.invocation_id);
1279 lp_build_print_value(gallivm, "[TCS OUT][VTX] attribIndex: ", wrap(attr_index));
1280 lp_build_print_value(gallivm, "[TCS OUT][VTX] attrib read from map: ", wrap(attrib));
1281 lp_build_print_value(gallivm, "[TCS OUT][VTX] chan_index: ", swizzle_index);
1282 lp_build_print_value(gallivm, "[TCS OUT][VTX] value: ", value);
1283 lp_build_print_value(gallivm, "[TCS OUT][VTX] value_to_store: ", wrap(value_to_store));
1284 }
1285
1286 Value* attr_chan = GEP(pCpOut, {C(0), C(ScalarPatch_cp),
1287 VEXTRACT(unwrap(bld->system_values.invocation_id), C(0)),
1288 C(ScalarCPoint_attrib), attrib, unwrap(swizzle_index)});
1289
1290 // Mask output values if needed
1291 value_to_store = BITCAST(value_to_store, mFP32Ty);
1292 if (mask_vec) {
1293 Value *originalVal = LOAD(attr_chan);
1294 Value *vMask = TRUNC(VEXTRACT(unwrap(mask_vec), C(lane)), mInt1Ty);
1295 value_to_store = SELECT(vMask, value_to_store, originalVal);
1296 }
1297 STORE(value_to_store, attr_chan);
1298 if (verbose_tcs_shader_out) {
1299 lp_build_print_value(gallivm, "[TCS OUT][VTX] Mask_vec mask: ", mask_vec);
1300 lp_build_print_value(gallivm, "[TCS OUT][VTX] stored: ", wrap(value_to_store));
1301 }
1302 }
1303 }
1304 }
1305
1306 void
swr_tcs_llvm_emit_barrier(const struct lp_build_tcs_iface * tcs_iface,struct lp_build_tgsi_context * bld_base)1307 BuilderSWR::swr_tcs_llvm_emit_barrier(const struct lp_build_tcs_iface *tcs_iface,
1308 struct lp_build_tgsi_context *bld_base)
1309 {
1310 swr_tcs_llvm_iface *iface = (swr_tcs_llvm_iface*)tcs_iface;
1311 struct lp_build_tgsi_soa_context* bld = (struct lp_build_tgsi_soa_context*)bld_base;
1312
1313 if (verbose_tcs_shader_loop) {
1314 lp_build_print_value(gallivm, "Barrier LOOP: Iteration %d END\n", iface->loop_var);
1315 }
1316
1317 struct lp_build_context *uint_bld = &bld->bld_base.uint_bld;
1318
1319 STORE(ADD(LOAD(unwrap(iface->loop_var)), VBROADCAST(C(1))), unwrap(iface->loop_var));
1320
1321 LLVMValueRef tmp = lp_build_cmp(uint_bld, PIPE_FUNC_GEQUAL, wrap(LOAD(unwrap(iface->loop_var))),
1322 wrap(VBROADCAST(C(iface->output_vertices))));
1323
1324 lp_exec_mask_cond_push(&bld->exec_mask, tmp);
1325 lp_exec_break(&bld->exec_mask, &bld->bld_base.pc, false);
1326 lp_exec_mask_cond_pop(&bld->exec_mask);
1327 lp_exec_endloop(bld->bld_base.base.gallivm, &bld->exec_mask);
1328
1329 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1330
1331 STORE(VBROADCAST(C(0)), unwrap(iface->loop_var));
1332 lp_exec_bgnloop(&bld->exec_mask, true);
1333
1334 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1335
1336 bld->system_values.invocation_id = wrap((LOAD(unwrap(iface->loop_var))));
1337
1338 if (verbose_tcs_shader_loop) {
1339 lp_build_print_value(gallivm, "Barrier LOOP: Iteration BEGIN: ", iface->loop_var);
1340 lp_build_print_value(gallivm, "Barrier LOOP: InvocationId: \n", bld->system_values.invocation_id);
1341 }
1342 }
1343
1344
1345 LLVMValueRef
swr_tes_llvm_fetch_patch_input(const struct lp_build_tes_iface * tes_iface,struct lp_build_tgsi_context * bld_base,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index)1346 BuilderSWR::swr_tes_llvm_fetch_patch_input(const struct lp_build_tes_iface *tes_iface,
1347 struct lp_build_tgsi_context * bld_base,
1348 boolean is_aindex_indirect,
1349 LLVMValueRef attrib_index,
1350 LLVMValueRef swizzle_index)
1351 {
1352 swr_tes_llvm_iface *iface = (swr_tes_llvm_iface*)tes_iface;
1353 Value *attr_index = unwrap(attrib_index);
1354 Value *res = unwrap(bld_base->base.zero);
1355
1356 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1357
1358 if (verbose_shader) {
1359 lp_build_printf(gallivm, "[TES IN][PATCH] --------------------------------------\n");
1360 }
1361
1362 if (is_aindex_indirect) {
1363 int i;
1364 struct lp_type type = bld_base->base.type;
1365
1366 for (i = 0; i < type.length; i++) {
1367 Value *attr_chan_index = attr_index;
1368
1369 if (is_aindex_indirect) {
1370 attr_chan_index = VEXTRACT(attr_index, C(i));
1371 }
1372
1373 Value *attrib =
1374 LOAD(GEP(iface->pPatchAttribMap, {C(0), attr_chan_index}));
1375
1376 Value *pCpIn = LOAD(iface->pTesCtx, {0, SWR_DS_CONTEXT_pCpIn}, "pCpIn");
1377 Value *pPatchData = GEP(pCpIn, {(uint32_t)0, ScalarPatch_patchData});
1378 Value *pAttr = GEP(pPatchData, {(uint32_t)0, ScalarCPoint_attrib});
1379 Value *Val = LOADV(pAttr, {C(0), attrib, unwrap(swizzle_index)});
1380 if (verbose_shader) {
1381 lp_build_print_value(gallivm, "[TES IN][PATCH] attrib_index: ", attrib_index);
1382 lp_build_print_value(gallivm, "[TES IN][PATCH] attr_chan_index: ", wrap(attr_chan_index));
1383 lp_build_print_value(gallivm, "[TES IN][PATCH] attrib read from map: ", wrap(attrib));
1384 lp_build_print_value(gallivm, "[TES IN][PATCH] swizzle_index: ", swizzle_index);
1385 lp_build_print_value(gallivm, "[TES IN][PATCH] Loaded: ", wrap(Val));
1386 }
1387 res = VINSERT(res, Val, C(i));
1388 }
1389 } else {
1390 Value *attrib = LOAD(GEP(iface->pPatchAttribMap, {C(0), attr_index}));
1391
1392 Value *pCpIn = LOAD(iface->pTesCtx, {(uint32_t)0, SWR_DS_CONTEXT_pCpIn}, "pCpIn");
1393 Value *pPatchData = GEP(pCpIn, {(uint32_t)0, ScalarPatch_patchData});
1394 Value *pAttr = GEP(pPatchData, {(uint32_t)0, ScalarCPoint_attrib});
1395 Value *Val = LOADV(pAttr, {C(0), attrib, unwrap(swizzle_index)});
1396 if (verbose_shader) {
1397 lp_build_print_value(gallivm, "[TES IN][PATCH] attrib_index: ", attrib_index);
1398 lp_build_print_value(gallivm, "[TES IN][PATCH] attr_chan_index: ", wrap(attr_index));
1399 lp_build_print_value(gallivm, "[TES IN][PATCH] attrib read from map: ", wrap(attrib));
1400 lp_build_print_value(gallivm, "[TES IN][PATCH] swizzle_index: ", swizzle_index);
1401 lp_build_print_value(gallivm, "[TES IN][PATCH] Loaded: ", wrap(Val));
1402 }
1403 res = VBROADCAST(Val);
1404 }
1405 if (verbose_shader) {
1406 lp_build_print_value(gallivm, "[TES IN][PATCH] returning: ", wrap(res));
1407 }
1408 return wrap(res);
1409 }
1410
1411
1412
1413 LLVMValueRef
swr_tes_llvm_fetch_vtx_input(const struct lp_build_tes_iface * tes_iface,struct lp_build_tgsi_context * bld_base,boolean is_vindex_indirect,LLVMValueRef vertex_index,boolean is_aindex_indirect,LLVMValueRef attrib_index,LLVMValueRef swizzle_index)1414 BuilderSWR::swr_tes_llvm_fetch_vtx_input(const struct lp_build_tes_iface *tes_iface,
1415 struct lp_build_tgsi_context * bld_base,
1416 boolean is_vindex_indirect,
1417 LLVMValueRef vertex_index,
1418 boolean is_aindex_indirect,
1419 LLVMValueRef attrib_index,
1420 LLVMValueRef swizzle_index)
1421 {
1422 swr_tes_llvm_iface *iface = (swr_tes_llvm_iface*)tes_iface;
1423 Value *vert_index = unwrap(vertex_index);
1424 Value *attr_index = unwrap(attrib_index);
1425
1426 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1427
1428 if (verbose_shader) {
1429 lp_build_printf(gallivm, "[TES IN][VTX] --------------------------------------\n");
1430 }
1431
1432 Value *res = unwrap(bld_base->base.zero);
1433 if (is_vindex_indirect || is_aindex_indirect) {
1434 int i;
1435 struct lp_type type = bld_base->base.type;
1436
1437 for (i = 0; i < type.length; i++) {
1438 Value *vert_chan_index = vert_index;
1439 Value *attr_chan_index = attr_index;
1440
1441 if (is_vindex_indirect) {
1442 vert_chan_index = VEXTRACT(vert_index, C(i));
1443 }
1444 if (is_aindex_indirect) {
1445 attr_chan_index = VEXTRACT(attr_index, C(i));
1446 }
1447
1448 Value *attrib =
1449 LOAD(GEP(iface->pVtxAttribMap, {C(0), attr_chan_index}));
1450
1451 Value *pCpIn = LOAD(iface->pTesCtx, {0, SWR_DS_CONTEXT_pCpIn}, "pCpIn");
1452 Value *pCp = GEP(pCpIn, {0, ScalarPatch_cp});
1453 Value *pVertex = GEP(pCp, {(Value*)C(0), vert_chan_index});
1454 Value *pAttrTab = GEP(pVertex, {uint32_t(0), uint32_t(0)});
1455 Value *pAttr = GEP(pAttrTab, {(Value*)C(0), attrib});
1456 Value *Val = LOADV(pAttr, {C(0), unwrap(swizzle_index)});
1457 if (verbose_shader) {
1458 lp_build_print_value(gallivm, "[TES IN][VTX] attrib_index: ", attrib_index);
1459 lp_build_print_value(gallivm, "[TES IN][VTX] attr_chan_index: ", wrap(attr_index));
1460 lp_build_print_value(gallivm, "[TES IN][VTX] attrib read from map: ", wrap(attrib));
1461 lp_build_print_value(gallivm, "[TES IN][VTX] swizzle_index: ", swizzle_index);
1462 lp_build_print_value(gallivm, "[TES IN][VTX] Loaded: ", wrap(Val));
1463 }
1464 res = VINSERT(res, Val, C(i));
1465 }
1466 } else {
1467 Value *attrib = LOAD(GEP(iface->pVtxAttribMap, {C(0), attr_index}));
1468
1469 Value *pCpIn = LOAD(iface->pTesCtx, {0, SWR_DS_CONTEXT_pCpIn}, "pCpIn");
1470 Value *pCp = GEP(pCpIn, {0, ScalarPatch_cp});
1471 Value *pVertex = GEP(pCp, {(Value*)C(0), vert_index});
1472 Value *pAttrTab = GEP(pVertex, {uint32_t(0), uint32_t(0)});
1473 Value *pAttr = GEP(pAttrTab, {(Value*)C(0), attrib});
1474 Value *Val = LOADV(pAttr, {C(0), unwrap(swizzle_index)});
1475 if (verbose_shader) {
1476 lp_build_print_value(gallivm, "[TES IN][VTX] attrib_index: ", attrib_index);
1477 lp_build_print_value(gallivm, "[TES IN][VTX] attr_chan_index: ", wrap(attr_index));
1478 lp_build_print_value(gallivm, "[TES IN][VTX] attrib read from map: ", wrap(attrib));
1479 lp_build_print_value(gallivm, "[TES IN][VTX] swizzle_index: ", swizzle_index);
1480 lp_build_print_value(gallivm, "[TES IN][VTX] Loaded: ", wrap(Val));
1481 }
1482 res = VBROADCAST(Val);
1483 }
1484 if (verbose_shader) {
1485 lp_build_print_value(gallivm, "[TES IN][VTX] returning: ", wrap(res));
1486 }
1487 return wrap(res);
1488 }
1489
1490
1491
1492
1493 PFN_GS_FUNC
CompileGS(struct swr_context * ctx,swr_jit_gs_key & key)1494 BuilderSWR::CompileGS(struct swr_context *ctx, swr_jit_gs_key &key)
1495 {
1496 SWR_GS_STATE *pGS = &ctx->gs->gsState;
1497 struct tgsi_shader_info *info = &ctx->gs->info.base;
1498
1499 memset(pGS, 0, sizeof(*pGS));
1500
1501 pGS->gsEnable = true;
1502
1503 pGS->numInputAttribs = (VERTEX_ATTRIB_START_SLOT - VERTEX_POSITION_SLOT) + info->num_inputs;
1504 pGS->outputTopology =
1505 swr_convert_prim_topology(info->properties[TGSI_PROPERTY_GS_OUTPUT_PRIM], 0);
1506
1507 /* It's +1 because emit_vertex in swr is always called exactly one time more
1508 * than max_vertices passed in Geometry Shader. We need to allocate more memory
1509 * to avoid crash/memory overwritten.
1510 */
1511 pGS->maxNumVerts = info->properties[TGSI_PROPERTY_GS_MAX_OUTPUT_VERTICES] + 1;
1512 pGS->instanceCount = info->properties[TGSI_PROPERTY_GS_INVOCATIONS];
1513
1514 // If point primitive then assume to use multiple streams
1515 if(pGS->outputTopology == TOP_POINT_LIST) {
1516 pGS->isSingleStream = false;
1517 } else {
1518 pGS->isSingleStream = true;
1519 pGS->singleStreamID = 0;
1520 }
1521
1522 pGS->vertexAttribOffset = VERTEX_POSITION_SLOT;
1523 pGS->inputVertStride = pGS->numInputAttribs + pGS->vertexAttribOffset;
1524 pGS->outputVertexSize = SWR_VTX_NUM_SLOTS;
1525 pGS->controlDataSize = 8; // GS ouputs max of 8 32B units
1526 pGS->controlDataOffset = VERTEX_COUNT_SIZE;
1527 pGS->outputVertexOffset = pGS->controlDataOffset + CONTROL_HEADER_SIZE;
1528
1529 pGS->allocationSize =
1530 VERTEX_COUNT_SIZE + // vertex count
1531 CONTROL_HEADER_SIZE + // control header
1532 (SWR_VTX_NUM_SLOTS * 16) * // sizeof vertex
1533 pGS->maxNumVerts; // num verts
1534
1535 struct swr_geometry_shader *gs = ctx->gs;
1536
1537 LLVMValueRef inputs[PIPE_MAX_SHADER_INPUTS][TGSI_NUM_CHANNELS];
1538 LLVMValueRef outputs[PIPE_MAX_SHADER_OUTPUTS][TGSI_NUM_CHANNELS];
1539
1540 memset(outputs, 0, sizeof(outputs));
1541
1542 AttrBuilder attrBuilder;
1543 attrBuilder.addStackAlignmentAttr(JM()->mVWidth * sizeof(float));
1544
1545 std::vector<Type *> gsArgs{PointerType::get(Gen_swr_draw_context(JM()), 0),
1546 PointerType::get(mInt8Ty, 0),
1547 PointerType::get(Gen_SWR_GS_CONTEXT(JM()), 0)};
1548 FunctionType *vsFuncType =
1549 FunctionType::get(Type::getVoidTy(JM()->mContext), gsArgs, false);
1550
1551 // create new vertex shader function
1552 auto pFunction = Function::Create(vsFuncType,
1553 GlobalValue::ExternalLinkage,
1554 "GS",
1555 JM()->mpCurrentModule);
1556 #if LLVM_VERSION_MAJOR < 5
1557 AttributeSet attrSet = AttributeSet::get(
1558 JM()->mContext, AttributeSet::FunctionIndex, attrBuilder);
1559 pFunction->addAttributes(AttributeSet::FunctionIndex, attrSet);
1560 #else
1561 pFunction->addAttributes(AttributeList::FunctionIndex, attrBuilder);
1562 #endif
1563
1564 BasicBlock *block = BasicBlock::Create(JM()->mContext, "entry", pFunction);
1565 IRB()->SetInsertPoint(block);
1566 LLVMPositionBuilderAtEnd(gallivm->builder, wrap(block));
1567
1568 auto argitr = pFunction->arg_begin();
1569 Value *hPrivateData = &*argitr++;
1570 hPrivateData->setName("hPrivateData");
1571 Value *pWorkerData = &*argitr++;
1572 pWorkerData->setName("pWorkerData");
1573 Value *pGsCtx = &*argitr++;
1574 pGsCtx->setName("gsCtx");
1575
1576 Value *consts_ptr =
1577 GEP(hPrivateData, {C(0), C(swr_draw_context_constantGS)});
1578 consts_ptr->setName("gs_constants");
1579 Value *const_sizes_ptr =
1580 GEP(hPrivateData, {0, swr_draw_context_num_constantsGS});
1581 const_sizes_ptr->setName("num_gs_constants");
1582
1583 struct lp_build_sampler_soa *sampler =
1584 swr_sampler_soa_create(key.sampler, PIPE_SHADER_GEOMETRY);
1585 assert(sampler != nullptr);
1586
1587 struct lp_bld_tgsi_system_values system_values;
1588 memset(&system_values, 0, sizeof(system_values));
1589 system_values.prim_id = wrap(LOAD(pGsCtx, {0, SWR_GS_CONTEXT_PrimitiveID}));
1590 system_values.invocation_id = wrap(LOAD(pGsCtx, {0, SWR_GS_CONTEXT_InstanceID}));
1591
1592 std::vector<Constant*> mapConstants;
1593 Value *vtxAttribMap = ALLOCA(ArrayType::get(mInt32Ty, PIPE_MAX_SHADER_INPUTS));
1594 for (unsigned slot = 0; slot < info->num_inputs; slot++) {
1595 ubyte semantic_name = info->input_semantic_name[slot];
1596 ubyte semantic_idx = info->input_semantic_index[slot];
1597
1598 unsigned vs_slot = locate_linkage(semantic_name, semantic_idx, &ctx->vs->info.base);
1599 assert(vs_slot < PIPE_MAX_SHADER_OUTPUTS);
1600
1601 vs_slot += VERTEX_ATTRIB_START_SLOT;
1602
1603 if (ctx->vs->info.base.output_semantic_name[0] == TGSI_SEMANTIC_POSITION)
1604 vs_slot--;
1605
1606 if (semantic_name == TGSI_SEMANTIC_POSITION)
1607 vs_slot = VERTEX_POSITION_SLOT;
1608
1609 STORE(C(vs_slot), vtxAttribMap, {0, slot});
1610 mapConstants.push_back(C(vs_slot));
1611 }
1612
1613 struct lp_build_mask_context mask;
1614 Value *mask_val = LOAD(pGsCtx, {0, SWR_GS_CONTEXT_mask}, "gsMask");
1615 lp_build_mask_begin(&mask, gallivm,
1616 lp_type_float_vec(32, 32 * 8), wrap(mask_val));
1617
1618 // zero out cut buffer so we can load/modify/store bits
1619 for (uint32_t lane = 0; lane < mVWidth; ++lane)
1620 {
1621 Value* pStream = LOAD(pGsCtx, {0, SWR_GS_CONTEXT_pStreams, lane});
1622 #if LLVM_VERSION_MAJOR >= 10
1623 MEMSET(pStream, C((char)0), VERTEX_COUNT_SIZE + CONTROL_HEADER_SIZE, MaybeAlign(sizeof(float) * KNOB_SIMD_WIDTH));
1624 #else
1625 MEMSET(pStream, C((char)0), VERTEX_COUNT_SIZE + CONTROL_HEADER_SIZE, sizeof(float) * KNOB_SIMD_WIDTH);
1626 #endif
1627 }
1628
1629 struct swr_gs_llvm_iface gs_iface;
1630 gs_iface.base.fetch_input = ::swr_gs_llvm_fetch_input;
1631 gs_iface.base.emit_vertex = ::swr_gs_llvm_emit_vertex;
1632 gs_iface.base.end_primitive = ::swr_gs_llvm_end_primitive;
1633 gs_iface.base.gs_epilogue = ::swr_gs_llvm_epilogue;
1634 gs_iface.pBuilder = this;
1635 gs_iface.pGsCtx = pGsCtx;
1636 gs_iface.pGsState = pGS;
1637 gs_iface.num_outputs = gs->info.base.num_outputs;
1638 gs_iface.num_verts_per_prim =
1639 u_vertices_per_prim((pipe_prim_type)info->properties[TGSI_PROPERTY_GS_OUTPUT_PRIM]);
1640 gs_iface.info = info;
1641 gs_iface.pVtxAttribMap = vtxAttribMap;
1642
1643 struct lp_build_tgsi_params params;
1644 memset(¶ms, 0, sizeof(params));
1645 params.type = lp_type_float_vec(32, 32 * 8);
1646 params.mask = & mask;
1647 params.consts_ptr = wrap(consts_ptr);
1648 params.const_sizes_ptr = wrap(const_sizes_ptr);
1649 params.system_values = &system_values;
1650 params.inputs = inputs;
1651 params.context_ptr = wrap(hPrivateData);
1652 params.sampler = sampler;
1653 params.info = &gs->info.base;
1654 params.gs_iface = &gs_iface.base;
1655
1656 lp_build_tgsi_soa(gallivm,
1657 gs->pipe.tokens,
1658 ¶ms,
1659 outputs);
1660
1661 lp_build_mask_end(&mask);
1662
1663 sampler->destroy(sampler);
1664
1665 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1666
1667 RET_VOID();
1668
1669 gallivm_verify_function(gallivm, wrap(pFunction));
1670 gallivm_compile_module(gallivm);
1671
1672 PFN_GS_FUNC pFunc =
1673 (PFN_GS_FUNC)gallivm_jit_function(gallivm, wrap(pFunction));
1674
1675 debug_printf("geom shader %p\n", pFunc);
1676 assert(pFunc && "Error: GeomShader = NULL");
1677
1678 JM()->mIsModuleFinalized = true;
1679
1680 return pFunc;
1681 }
1682
1683 PFN_TES_FUNC
CompileTES(struct swr_context * ctx,swr_jit_tes_key & key)1684 BuilderSWR::CompileTES(struct swr_context *ctx, swr_jit_tes_key &key)
1685 {
1686 SWR_TS_STATE *pTS = &ctx->tsState;
1687 struct tgsi_shader_info *info = &ctx->tes->info.base;
1688
1689 // tessellation is enabled if TES is present
1690 // clear tessellation state here then
1691 memset(pTS, 0, sizeof(*pTS));
1692
1693 pTS->tsEnable = true;
1694
1695 unsigned tes_prim_mode = info->properties[TGSI_PROPERTY_TES_PRIM_MODE];
1696 unsigned tes_spacing = info->properties[TGSI_PROPERTY_TES_SPACING];
1697 bool tes_vertex_order_cw = info->properties[TGSI_PROPERTY_TES_VERTEX_ORDER_CW];
1698 bool tes_point_mode = info->properties[TGSI_PROPERTY_TES_POINT_MODE];
1699 SWR_TS_DOMAIN type = SWR_TS_ISOLINE;
1700 SWR_TS_PARTITIONING partitioning = SWR_TS_EVEN_FRACTIONAL;
1701 SWR_TS_OUTPUT_TOPOLOGY topology = SWR_TS_OUTPUT_POINT;
1702 PRIMITIVE_TOPOLOGY postDSTopology = TOP_POINT_LIST;
1703
1704 // TESS_TODO: move this to helper functions to improve readability
1705 switch (tes_prim_mode) {
1706 case PIPE_PRIM_LINES:
1707 type = SWR_TS_ISOLINE;
1708 postDSTopology = TOP_LINE_LIST;
1709 break;
1710 case PIPE_PRIM_TRIANGLES:
1711 type = SWR_TS_TRI;
1712 postDSTopology = TOP_TRIANGLE_LIST;
1713 break;
1714 case PIPE_PRIM_QUADS:
1715 type = SWR_TS_QUAD;
1716 // See OpenGL spec - quads are tessellated into triangles
1717 postDSTopology = TOP_TRIANGLE_LIST;
1718 break;
1719 default:
1720 assert(0);
1721 }
1722
1723 switch (tes_spacing) {
1724 case PIPE_TESS_SPACING_FRACTIONAL_ODD:
1725 partitioning = SWR_TS_ODD_FRACTIONAL;
1726 break;
1727 case PIPE_TESS_SPACING_FRACTIONAL_EVEN:
1728 partitioning = SWR_TS_EVEN_FRACTIONAL;
1729 break;
1730 case PIPE_TESS_SPACING_EQUAL:
1731 partitioning = SWR_TS_INTEGER;
1732 break;
1733 default:
1734 assert(0);
1735 }
1736
1737 if (tes_point_mode) {
1738 topology = SWR_TS_OUTPUT_POINT;
1739 postDSTopology = TOP_POINT_LIST;
1740 }
1741 else if (tes_prim_mode == PIPE_PRIM_LINES) {
1742 topology = SWR_TS_OUTPUT_LINE;
1743 }
1744 else if (tes_vertex_order_cw) {
1745 topology = SWR_TS_OUTPUT_TRI_CW;
1746 }
1747 else {
1748 topology = SWR_TS_OUTPUT_TRI_CCW;
1749 }
1750
1751 pTS->domain = type;
1752 pTS->tsOutputTopology = topology;
1753 pTS->partitioning = partitioning;
1754 pTS->numDsOutputAttribs = info->num_outputs;
1755 pTS->postDSTopology = postDSTopology;
1756
1757 pTS->dsAllocationSize = SWR_VTX_NUM_SLOTS * MAX_NUM_VERTS_PER_PRIM;
1758 pTS->vertexAttribOffset = VERTEX_ATTRIB_START_SLOT;
1759 pTS->srcVertexAttribOffset = VERTEX_ATTRIB_START_SLOT;
1760 pTS->dsOutVtxAttribOffset = VERTEX_ATTRIB_START_SLOT;
1761
1762 struct swr_tess_evaluation_shader *tes = ctx->tes;
1763
1764 LLVMValueRef inputs[PIPE_MAX_SHADER_INPUTS][TGSI_NUM_CHANNELS];
1765 LLVMValueRef outputs[PIPE_MAX_SHADER_OUTPUTS][TGSI_NUM_CHANNELS];
1766
1767 memset(outputs, 0, sizeof(outputs));
1768
1769 AttrBuilder attrBuilder;
1770 attrBuilder.addStackAlignmentAttr(JM()->mVWidth * sizeof(float));
1771
1772 std::vector<Type *> tesArgs{PointerType::get(Gen_swr_draw_context(JM()), 0),
1773 PointerType::get(mInt8Ty, 0),
1774 PointerType::get(Gen_SWR_DS_CONTEXT(JM()), 0)};
1775 FunctionType *tesFuncType =
1776 FunctionType::get(Type::getVoidTy(JM()->mContext), tesArgs, false);
1777
1778 // create new vertex shader function
1779 auto pFunction = Function::Create(tesFuncType,
1780 GlobalValue::ExternalLinkage,
1781 "TES",
1782 JM()->mpCurrentModule);
1783
1784 #if LLVM_VERSION_MAJOR < 5
1785 AttributeSet attrSet = AttributeSet::get(
1786 JM()->mContext, AttributeSet::FunctionIndex, attrBuilder);
1787 pFunction->addAttributes(AttributeSet::FunctionIndex, attrSet);
1788 #else
1789 pFunction->addAttributes(AttributeList::FunctionIndex, attrBuilder);
1790 #endif
1791
1792 BasicBlock *block = BasicBlock::Create(JM()->mContext, "entry", pFunction);
1793 IRB()->SetInsertPoint(block);
1794 LLVMPositionBuilderAtEnd(gallivm->builder, wrap(block));
1795
1796 auto argitr = pFunction->arg_begin();
1797 Value *hPrivateData = &*argitr++;
1798 hPrivateData->setName("hPrivateData");
1799 Value *pWorkerData = &*argitr++;
1800 pWorkerData->setName("pWorkerData");
1801 Value *pTesCtx = &*argitr++;
1802 pTesCtx->setName("tesCtx");
1803
1804 Value *consts_ptr =
1805 GEP(hPrivateData, {C(0), C(swr_draw_context_constantTES)});
1806 consts_ptr->setName("tes_constants");
1807 Value *const_sizes_ptr =
1808 GEP(hPrivateData, {0, swr_draw_context_num_constantsTES});
1809 const_sizes_ptr->setName("num_tes_constants");
1810
1811 struct lp_build_sampler_soa *sampler =
1812 swr_sampler_soa_create(key.sampler, PIPE_SHADER_TESS_EVAL);
1813 assert(sampler != nullptr);
1814
1815 struct lp_bld_tgsi_system_values system_values;
1816 memset(&system_values, 0, sizeof(system_values));
1817
1818 // Load and calculate system values
1819 // Tessellation coordinates (gl_TessCoord)
1820 Value *vecOffset = LOAD(pTesCtx, {0, SWR_DS_CONTEXT_vectorOffset}, "vecOffset");
1821 Value *vecStride = LOAD(pTesCtx, {0, SWR_DS_CONTEXT_vectorStride}, "vecStride");
1822 Value *vecIndex = LOAD(pTesCtx, {0, SWR_DS_CONTEXT_vectorOffset});
1823
1824 Value* tess_coord = ALLOCA(ArrayType::get(mSimdFP32Ty, 3));
1825
1826 Value *tessCoordU = LOADV(LOAD(pTesCtx, {0, SWR_DS_CONTEXT_pDomainU}), {vecIndex}, "tessCoordU");
1827 STORE(tessCoordU, tess_coord, {0, 0});
1828 Value *tessCoordV = LOADV(LOAD(pTesCtx, {0, SWR_DS_CONTEXT_pDomainV}), {vecIndex}, "tessCoordV");
1829 STORE(tessCoordV, tess_coord, {0, 1});
1830 Value *tessCoordW = FSUB(FSUB(VIMMED1(1.0f), tessCoordU), tessCoordV, "tessCoordW");
1831 STORE(tessCoordW, tess_coord, {0, 2});
1832 system_values.tess_coord = wrap(tess_coord);
1833
1834 // Primitive ID
1835 system_values.prim_id = wrap(VBROADCAST(LOAD(pTesCtx, {0, SWR_DS_CONTEXT_PrimitiveID}), "PrimitiveID"));
1836
1837 // Tessellation factors
1838 Value* pPatch = LOAD(pTesCtx, {0, SWR_DS_CONTEXT_pCpIn});
1839 Value* pTessFactors = GEP(pPatch, {C(0), C(ScalarPatch_tessFactors)});
1840
1841 assert(SWR_NUM_OUTER_TESS_FACTORS == 4);
1842 Value* sys_value_outer_factors = UndefValue::get(getVectorType(mFP32Ty, 4));
1843 for (unsigned i = 0; i < SWR_NUM_OUTER_TESS_FACTORS; i++) {
1844 Value* v = LOAD(pTessFactors, {0, SWR_TESSELLATION_FACTORS_OuterTessFactors, i});
1845 sys_value_outer_factors = VINSERT(sys_value_outer_factors, v, i, "gl_TessLevelOuter");
1846 }
1847 system_values.tess_outer = wrap(sys_value_outer_factors);
1848
1849 assert(SWR_NUM_INNER_TESS_FACTORS == 2);
1850 Value* sys_value_inner_factors = UndefValue::get(getVectorType(mFP32Ty, 4));
1851 for (unsigned i = 0; i < SWR_NUM_INNER_TESS_FACTORS; i++) {
1852 Value* v = LOAD(pTessFactors, {0, SWR_TESSELLATION_FACTORS_InnerTessFactors, i});
1853 sys_value_inner_factors = VINSERT(sys_value_inner_factors, v, i, "gl_TessLevelInner");
1854 }
1855 system_values.tess_inner = wrap(sys_value_inner_factors);
1856
1857 if (verbose_shader)
1858 {
1859 lp_build_print_value(gallivm, "tess_coord = ", system_values.tess_coord);
1860 }
1861
1862 struct tgsi_shader_info *pPrevShader = nullptr;
1863
1864 if (ctx->tcs) {
1865 pPrevShader = &ctx->tcs->info.base;
1866 }
1867 else {
1868 pPrevShader = &ctx->vs->info.base;
1869 }
1870
1871 // Figure out how many per-patch attributes we have
1872 unsigned perPatchAttrs = 0;
1873 unsigned genericAttrs = 0;
1874 unsigned tessLevelAttrs = 0;
1875 unsigned sgvAttrs = 0;
1876 for (unsigned slot = 0; slot < pPrevShader->num_outputs; slot++) {
1877 switch (pPrevShader->output_semantic_name[slot]) {
1878 case TGSI_SEMANTIC_PATCH:
1879 perPatchAttrs++;
1880 break;
1881 case TGSI_SEMANTIC_GENERIC:
1882 genericAttrs++;
1883 break;
1884 case TGSI_SEMANTIC_TESSINNER:
1885 case TGSI_SEMANTIC_TESSOUTER:
1886 tessLevelAttrs++;
1887 break;
1888 case TGSI_SEMANTIC_POSITION:
1889 case TGSI_SEMANTIC_CLIPDIST:
1890 case TGSI_SEMANTIC_PSIZE:
1891 sgvAttrs++;
1892 break;
1893 default:
1894 assert(!"Unknown semantic input in TES");
1895 }
1896 }
1897
1898 std::vector<Constant *> mapConstants;
1899 Value *vtxAttribMap = ALLOCA(ArrayType::get(mInt32Ty, PIPE_MAX_SHADER_INPUTS));
1900 Value *patchAttribMap = ALLOCA(ArrayType::get(mInt32Ty, PIPE_MAX_SHADER_INPUTS));
1901 for (unsigned slot = 0; slot < info->num_inputs; slot++) {
1902 ubyte semantic_name = info->input_semantic_name[slot];
1903 ubyte semantic_idx = info->input_semantic_index[slot];
1904
1905 // Where in TCS output is my attribute?
1906 // TESS_TODO: revisit after implement pass-through TCS
1907 unsigned tcs_slot = locate_linkage(semantic_name, semantic_idx, pPrevShader);
1908 assert(tcs_slot < PIPE_MAX_SHADER_OUTPUTS);
1909
1910 // Skip tessellation levels - these go to the tessellator, not TES
1911 switch (semantic_name) {
1912 case TGSI_SEMANTIC_GENERIC:
1913 tcs_slot = tcs_slot + VERTEX_ATTRIB_START_SLOT - sgvAttrs - tessLevelAttrs;
1914 break;
1915 case TGSI_SEMANTIC_PATCH:
1916 tcs_slot = semantic_idx;
1917 break;
1918 case TGSI_SEMANTIC_POSITION:
1919 tcs_slot = VERTEX_POSITION_SLOT;
1920 break;
1921 case TGSI_SEMANTIC_CLIPDIST:
1922 case TGSI_SEMANTIC_PSIZE:
1923 break;
1924 default:
1925 assert(!"Unexpected semantic found while builiding TES input map");
1926 }
1927 if (semantic_name == TGSI_SEMANTIC_PATCH) {
1928 STORE(C(tcs_slot), patchAttribMap, {0, slot});
1929 } else {
1930 STORE(C(tcs_slot), vtxAttribMap, {0, slot});
1931 }
1932 mapConstants.push_back(C(tcs_slot));
1933 }
1934
1935 // Build execution mask
1936 struct lp_build_mask_context mask;
1937 Value *mask_val = LOAD(pTesCtx, {0, SWR_DS_CONTEXT_mask}, "tesMask");
1938
1939 if (verbose_shader)
1940 lp_build_print_value(gallivm, "TES execution mask: ", wrap(mask_val));
1941
1942 lp_build_mask_begin(&mask, gallivm,
1943 lp_type_float_vec(32, 32 * 8), wrap(mask_val));
1944
1945 struct swr_tes_llvm_iface tes_iface;
1946
1947 tes_iface.base.fetch_vertex_input = ::swr_tes_llvm_fetch_vtx_input;
1948 tes_iface.base.fetch_patch_input = ::swr_tes_llvm_fetch_patch_input;
1949
1950 tes_iface.pBuilder = this;
1951 tes_iface.pTesCtx = pTesCtx;
1952 tes_iface.pTsState = pTS;
1953 tes_iface.num_outputs = tes->info.base.num_outputs;
1954 tes_iface.info = info;
1955 tes_iface.pVtxAttribMap = vtxAttribMap;
1956 tes_iface.pPatchAttribMap = patchAttribMap;
1957
1958 struct lp_build_tgsi_params params;
1959 memset(¶ms, 0, sizeof(params));
1960 params.type = lp_type_float_vec(32, 32 * 8);
1961 params.mask = & mask;
1962 params.consts_ptr = wrap(consts_ptr);
1963 params.const_sizes_ptr = wrap(const_sizes_ptr);
1964 params.system_values = &system_values;
1965 params.inputs = inputs;
1966 params.context_ptr = wrap(hPrivateData);
1967 params.sampler = sampler;
1968 params.info = &tes->info.base;
1969 params.tes_iface = &tes_iface.base;
1970
1971 // Build LLVM IR
1972 lp_build_tgsi_soa(gallivm,
1973 tes->pipe.tokens,
1974 ¶ms,
1975 outputs);
1976
1977 lp_build_mask_end(&mask);
1978
1979 sampler->destroy(sampler);
1980
1981 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
1982
1983 // Write output attributes
1984 Value *dclOut = LOAD(pTesCtx, {0, SWR_DS_CONTEXT_pOutputData}, "dclOut");
1985
1986 for (uint32_t attrib = 0; attrib < PIPE_MAX_SHADER_OUTPUTS; attrib++) {
1987 for (uint32_t channel = 0; channel < TGSI_NUM_CHANNELS; channel++) {
1988 if (!outputs[attrib][channel])
1989 continue;
1990
1991 Value *val = LOAD(unwrap(outputs[attrib][channel]));;
1992 Value *attribOffset =
1993 LOAD(pTesCtx, {0, SWR_DS_CONTEXT_outVertexAttribOffset});
1994
1995 // Assume we write possition
1996 Value* outputSlot = C(VERTEX_POSITION_SLOT);
1997 if (tes->info.base.output_semantic_name[attrib] != TGSI_SEMANTIC_POSITION) {
1998 // No, it's a generic attribute, not a position - let's calculate output slot
1999 uint32_t outSlot = attrib;
2000 if (tes->info.base.output_semantic_name[0] == TGSI_SEMANTIC_POSITION) {
2001 // this shader will write position, so in shader's term
2002 // output starts at attrib 1, but we will handle that separately,
2003 // so let's fix the outSlot
2004 outSlot--;
2005 }
2006 outputSlot = ADD(attribOffset, C(outSlot));
2007 }
2008
2009 Value *attribVecIndex =
2010 ADD(MUL(vecStride, MUL(outputSlot, C(4))), vecOffset);
2011
2012 uint32_t outputComponent = 0;
2013 uint32_t curComp = outputComponent + channel;
2014 auto outValIndex = ADD(attribVecIndex, MUL(vecStride, C(curComp)));
2015 STOREV(val, dclOut, {outValIndex});
2016
2017 if (verbose_shader) {
2018 lp_build_printf(gallivm,
2019 "TES output [%d][%d]",
2020 C(attrib),
2021 C(channel));
2022 lp_build_print_value(gallivm, " = ", wrap(val));
2023 }
2024 }
2025 }
2026
2027 RET_VOID();
2028
2029 JM()->DumpToFile(pFunction, "src");
2030 gallivm_verify_function(gallivm, wrap(pFunction));
2031
2032 gallivm_compile_module(gallivm);
2033 JM()->DumpToFile(pFunction, "optimized");
2034
2035 PFN_TES_FUNC pFunc =
2036 (PFN_TES_FUNC)gallivm_jit_function(gallivm, wrap(pFunction));
2037
2038 debug_printf("tess evaluation shader %p\n", pFunc);
2039 assert(pFunc && "Error: TessEvaluationShader = NULL");
2040
2041 JM()->DumpAsm(pFunction, "asm");
2042
2043 JM()->mIsModuleFinalized = true;
2044
2045 return pFunc;
2046 }
2047
2048 PFN_TCS_FUNC
CompileTCS(struct swr_context * ctx,swr_jit_tcs_key & key)2049 BuilderSWR::CompileTCS(struct swr_context *ctx, swr_jit_tcs_key &key)
2050 {
2051 SWR_TS_STATE *pTS = &ctx->tsState;
2052 struct tgsi_shader_info *info = &ctx->tcs->info.base;
2053
2054 pTS->numHsInputAttribs = info->num_inputs;
2055 pTS->numHsOutputAttribs = info->num_outputs;
2056
2057 pTS->hsAllocationSize = sizeof(ScalarPatch);
2058
2059 pTS->vertexAttribOffset = VERTEX_ATTRIB_START_SLOT;
2060 pTS->srcVertexAttribOffset = VERTEX_ATTRIB_START_SLOT;
2061
2062 struct swr_tess_control_shader *tcs = ctx->tcs;
2063
2064 LLVMValueRef inputs[PIPE_MAX_SHADER_INPUTS][TGSI_NUM_CHANNELS];
2065 LLVMValueRef outputs[PIPE_MAX_SHADER_OUTPUTS][TGSI_NUM_CHANNELS];
2066
2067 memset(outputs, 0, sizeof(outputs));
2068
2069 AttrBuilder attrBuilder;
2070 attrBuilder.addStackAlignmentAttr(JM()->mVWidth * sizeof(float));
2071
2072 std::vector<Type *> tcsArgs{
2073 PointerType::get(Gen_swr_draw_context(JM()), 0),
2074 PointerType::get(mInt8Ty, 0),
2075 PointerType::get(Gen_SWR_HS_CONTEXT(JM()), 0)};
2076 FunctionType *tcsFuncType =
2077 FunctionType::get(Type::getVoidTy(JM()->mContext), tcsArgs, false);
2078
2079 // create new vertex shader function
2080 auto pFunction = Function::Create(tcsFuncType,
2081 GlobalValue::ExternalLinkage,
2082 "TCS",
2083 JM()->mpCurrentModule);
2084
2085 #if LLVM_VERSION_MAJOR < 5
2086 AttributeSet attrSet = AttributeSet::get(
2087 JM()->mContext, AttributeSet::FunctionIndex, attrBuilder);
2088 pFunction->addAttributes(AttributeSet::FunctionIndex, attrSet);
2089 #else
2090 pFunction->addAttributes(AttributeList::FunctionIndex, attrBuilder);
2091 #endif
2092
2093 BasicBlock *block = BasicBlock::Create(JM()->mContext, "entry", pFunction);
2094 IRB()->SetInsertPoint(block);
2095 LLVMPositionBuilderAtEnd(gallivm->builder, wrap(block));
2096
2097 auto argitr = pFunction->arg_begin();
2098 Value *hPrivateData = &*argitr++;
2099 hPrivateData->setName("hPrivateData");
2100 Value *pWorkerData = &*argitr++;
2101 pWorkerData->setName("pWorkerData");
2102 Value *pTcsCtx = &*argitr++;
2103 pTcsCtx->setName("tcsCtx");
2104
2105 Value *consts_ptr =
2106 GEP(hPrivateData, {C(0), C(swr_draw_context_constantTCS)});
2107 consts_ptr->setName("tcs_constants");
2108 Value *const_sizes_ptr =
2109 GEP(hPrivateData, {0, swr_draw_context_num_constantsTCS});
2110 const_sizes_ptr->setName("num_tcs_constants");
2111
2112 struct lp_build_sampler_soa *sampler =
2113 swr_sampler_soa_create(key.sampler, PIPE_SHADER_TESS_CTRL);
2114 assert(sampler != nullptr);
2115
2116 struct lp_bld_tgsi_system_values system_values;
2117 memset(&system_values, 0, sizeof(system_values));
2118
2119 system_values.prim_id =
2120 wrap(LOAD(pTcsCtx, {0, SWR_HS_CONTEXT_PrimitiveID}));
2121
2122 system_values.invocation_id = wrap(VBROADCAST(C(0)));
2123 system_values.vertices_in = wrap(C(tcs->vertices_per_patch));
2124
2125 if (verbose_shader) {
2126 lp_build_print_value(gallivm, "TCS::prim_id = ", system_values.prim_id);
2127 lp_build_print_value(gallivm, "TCS::invocation_id = ", system_values.invocation_id);
2128 lp_build_print_value(gallivm, "TCS::vertices_in = ", system_values.vertices_in);
2129 }
2130
2131 std::vector<Constant *> mapConstants;
2132 Value *vtxAttribMap =
2133 ALLOCA(ArrayType::get(mInt32Ty, PIPE_MAX_SHADER_INPUTS));
2134
2135 for (unsigned slot = 0; slot < info->num_inputs; slot++) {
2136 ubyte semantic_name = info->input_semantic_name[slot];
2137 ubyte semantic_idx = info->input_semantic_index[slot];
2138
2139 unsigned vs_slot =
2140 locate_linkage(semantic_name, semantic_idx, &ctx->vs->info.base);
2141 assert(vs_slot < PIPE_MAX_SHADER_OUTPUTS);
2142
2143 vs_slot += VERTEX_ATTRIB_START_SLOT;
2144
2145 if (ctx->vs->info.base.output_semantic_name[0]
2146 == TGSI_SEMANTIC_POSITION)
2147 vs_slot--;
2148
2149 if (semantic_name == TGSI_SEMANTIC_POSITION)
2150 vs_slot = VERTEX_POSITION_SLOT;
2151
2152 STORE(C(vs_slot), vtxAttribMap, {0, slot});
2153 mapConstants.push_back(C(vs_slot));
2154 }
2155
2156 // Prepare map of output attributes. Needed when shader instance wants
2157 // to read own output or output of other instance, which is allowed in TCS
2158 Value *vtxOutputAttribMap =
2159 ALLOCA(ArrayType::get(mInt32Ty, PIPE_MAX_SHADER_INPUTS));
2160 // Map for per-patch attributes
2161 Value *patchOutputAttribMap =
2162 ALLOCA(ArrayType::get(mInt32Ty, PIPE_MAX_SHADER_INPUTS));
2163 for (unsigned slot = 0; slot < info->num_outputs; slot++) {
2164 ubyte name = info->output_semantic_name[slot];
2165 int32_t idx = info->output_semantic_index[slot];
2166 if (name == TGSI_SEMANTIC_PATCH) {
2167 STORE(C(idx), patchOutputAttribMap, {0, slot});
2168 } else {
2169 int32_t target_slot = slot;
2170 if (name == TGSI_SEMANTIC_GENERIC) {
2171 target_slot += VERTEX_ATTRIB_START_SLOT;
2172 }
2173 // Now normalize target slot
2174 for (ubyte as = 0; as < slot; as++) {
2175 ubyte name = info->output_semantic_name[as];
2176 switch (name) {
2177 case TGSI_SEMANTIC_TESSOUTER:
2178 case TGSI_SEMANTIC_TESSINNER:
2179 case TGSI_SEMANTIC_PATCH:
2180 case TGSI_SEMANTIC_POSITION:
2181 target_slot--;
2182 }
2183 }
2184 if (name == TGSI_SEMANTIC_POSITION) {
2185 target_slot = VERTEX_POSITION_SLOT;
2186 }
2187 STORE(C(target_slot), vtxOutputAttribMap, {0, slot});
2188 mapConstants.push_back(C(target_slot));
2189 }
2190 }
2191
2192 struct lp_build_mask_context mask;
2193 Value *mask_val = LOAD(pTcsCtx, {0, SWR_HS_CONTEXT_mask}, "tcsMask");
2194 lp_build_mask_begin(
2195 &mask, gallivm, lp_type_float_vec(32, 32 * 8), wrap(mask_val));
2196
2197 struct swr_tcs_llvm_iface tcs_iface;
2198
2199 tcs_iface.base.emit_store_output = ::swr_tcs_llvm_store_output;
2200 tcs_iface.base.emit_fetch_input = ::swr_tcs_llvm_fetch_input;
2201 tcs_iface.base.emit_fetch_output = ::swr_tcs_llvm_fetch_output;
2202 tcs_iface.base.emit_barrier = ::swr_tcs_llvm_emit_barrier;
2203 tcs_iface.base.emit_prologue = ::swr_tcs_llvm_emit_prologue;
2204 tcs_iface.base.emit_epilogue = ::swr_tcs_llvm_emit_epilogue;
2205
2206 tcs_iface.pBuilder = this;
2207 tcs_iface.pTcsCtx = pTcsCtx;
2208 tcs_iface.pTsState = pTS;
2209 tcs_iface.output_vertices = info->properties[TGSI_PROPERTY_TCS_VERTICES_OUT];
2210 tcs_iface.info = info;
2211 tcs_iface.pVtxAttribMap = vtxAttribMap;
2212 tcs_iface.pVtxOutputAttribMap = vtxOutputAttribMap;
2213 tcs_iface.pPatchOutputAttribMap = patchOutputAttribMap;
2214
2215 struct lp_build_tgsi_params params;
2216 memset(¶ms, 0, sizeof(params));
2217 params.type = lp_type_float_vec(32, 32 * 8);
2218 params.mask = &mask;
2219 params.consts_ptr = wrap(consts_ptr);
2220 params.const_sizes_ptr = wrap(const_sizes_ptr);
2221 params.system_values = &system_values;
2222 params.inputs = inputs;
2223 params.context_ptr = wrap(hPrivateData);
2224 params.sampler = sampler;
2225 params.info = &tcs->info.base;
2226 params.tcs_iface = &tcs_iface.base;
2227
2228 lp_build_tgsi_soa(gallivm, tcs->pipe.tokens, ¶ms, outputs);
2229
2230 lp_build_mask_end(&mask);
2231
2232 sampler->destroy(sampler);
2233
2234 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
2235 RET_VOID();
2236
2237 JM()->DumpToFile(pFunction, "src");
2238 gallivm_verify_function(gallivm, wrap(pFunction));
2239 gallivm_compile_module(gallivm);
2240 JM()->DumpToFile(pFunction, "optimized");
2241
2242 PFN_TCS_FUNC pFunc =
2243 (PFN_TCS_FUNC)gallivm_jit_function(gallivm, wrap(pFunction));
2244
2245 debug_printf("tess control shader %p\n", pFunc);
2246 assert(pFunc && "Error: TessControlShader = NULL");
2247 JM()->DumpAsm(pFunction, "asm");
2248
2249 JM()->mIsModuleFinalized = true;
2250
2251 return pFunc;
2252 }
2253
2254
2255 PFN_GS_FUNC
swr_compile_gs(struct swr_context * ctx,swr_jit_gs_key & key)2256 swr_compile_gs(struct swr_context *ctx, swr_jit_gs_key &key)
2257 {
2258 BuilderSWR builder(
2259 reinterpret_cast<JitManager *>(swr_screen(ctx->pipe.screen)->hJitMgr),
2260 "GS");
2261 PFN_GS_FUNC func = builder.CompileGS(ctx, key);
2262
2263 ctx->gs->map.insert(std::make_pair(key, std::unique_ptr<VariantGS>(new VariantGS(builder.gallivm, func))));
2264 return func;
2265 }
2266
2267 PFN_TCS_FUNC
swr_compile_tcs(struct swr_context * ctx,swr_jit_tcs_key & key)2268 swr_compile_tcs(struct swr_context *ctx, swr_jit_tcs_key &key)
2269 {
2270 BuilderSWR builder(
2271 reinterpret_cast<JitManager *>(swr_screen(ctx->pipe.screen)->hJitMgr),
2272 "TCS");
2273 PFN_TCS_FUNC func = builder.CompileTCS(ctx, key);
2274
2275 ctx->tcs->map.insert(
2276 std::make_pair(key, std::unique_ptr<VariantTCS>(new VariantTCS(builder.gallivm, func))));
2277
2278 return func;
2279 }
2280
2281 PFN_TES_FUNC
swr_compile_tes(struct swr_context * ctx,swr_jit_tes_key & key)2282 swr_compile_tes(struct swr_context *ctx, swr_jit_tes_key &key)
2283 {
2284 BuilderSWR builder(
2285 reinterpret_cast<JitManager *>(swr_screen(ctx->pipe.screen)->hJitMgr),
2286 "TES");
2287 PFN_TES_FUNC func = builder.CompileTES(ctx, key);
2288
2289 ctx->tes->map.insert(
2290 std::make_pair(key, std::unique_ptr<VariantTES>(new VariantTES(builder.gallivm, func))));
2291
2292 return func;
2293 }
2294
2295 void
WriteVS(Value * pVal,Value * pVsContext,Value * pVtxOutput,unsigned slot,unsigned channel)2296 BuilderSWR::WriteVS(Value *pVal, Value *pVsContext, Value *pVtxOutput, unsigned slot, unsigned channel)
2297 {
2298 #if USE_SIMD16_FRONTEND && !USE_SIMD16_VS
2299 // interleave the simdvertex components into the dest simd16vertex
2300 // slot16offset = slot8offset * 2
2301 // comp16offset = comp8offset * 2 + alternateOffset
2302
2303 Value *offset = LOAD(pVsContext, { 0, SWR_VS_CONTEXT_AlternateOffset });
2304 Value *pOut = GEP(pVtxOutput, { C(0), C(0), C(slot * 2), offset } );
2305 STORE(pVal, pOut, {channel * 2});
2306 #else
2307 Value *pOut = GEP(pVtxOutput, {0, 0, slot});
2308 STORE(pVal, pOut, {0, channel});
2309 if (verbose_vs_shader) {
2310 lp_build_printf(gallivm, "VS: Storing on slot %d, channel %d: ", C(slot), C(channel));
2311 lp_build_print_value(gallivm, "", wrap(pVal));
2312 }
2313 #endif
2314 }
2315
2316 PFN_VERTEX_FUNC
CompileVS(struct swr_context * ctx,swr_jit_vs_key & key)2317 BuilderSWR::CompileVS(struct swr_context *ctx, swr_jit_vs_key &key)
2318 {
2319 struct swr_vertex_shader *swr_vs = ctx->vs;
2320
2321 LLVMValueRef inputs[PIPE_MAX_SHADER_INPUTS][TGSI_NUM_CHANNELS];
2322 LLVMValueRef outputs[PIPE_MAX_SHADER_OUTPUTS][TGSI_NUM_CHANNELS];
2323
2324 memset(outputs, 0, sizeof(outputs));
2325
2326 AttrBuilder attrBuilder;
2327 attrBuilder.addStackAlignmentAttr(JM()->mVWidth * sizeof(float));
2328
2329 std::vector<Type *> vsArgs{PointerType::get(Gen_swr_draw_context(JM()), 0),
2330 PointerType::get(mInt8Ty, 0),
2331 PointerType::get(Gen_SWR_VS_CONTEXT(JM()), 0)};
2332 FunctionType *vsFuncType =
2333 FunctionType::get(Type::getVoidTy(JM()->mContext), vsArgs, false);
2334
2335 // create new vertex shader function
2336 auto pFunction = Function::Create(vsFuncType,
2337 GlobalValue::ExternalLinkage,
2338 "VS",
2339 JM()->mpCurrentModule);
2340 #if LLVM_VERSION_MAJOR < 5
2341 AttributeSet attrSet = AttributeSet::get(
2342 JM()->mContext, AttributeSet::FunctionIndex, attrBuilder);
2343 pFunction->addAttributes(AttributeSet::FunctionIndex, attrSet);
2344 #else
2345 pFunction->addAttributes(AttributeList::FunctionIndex, attrBuilder);
2346 #endif
2347
2348 BasicBlock *block = BasicBlock::Create(JM()->mContext, "entry", pFunction);
2349 IRB()->SetInsertPoint(block);
2350 LLVMPositionBuilderAtEnd(gallivm->builder, wrap(block));
2351
2352 auto argitr = pFunction->arg_begin();
2353 Value *hPrivateData = &*argitr++;
2354 hPrivateData->setName("hPrivateData");
2355 Value *pWorkerData = &*argitr++;
2356 pWorkerData->setName("pWorkerData");
2357 Value *pVsCtx = &*argitr++;
2358 pVsCtx->setName("vsCtx");
2359
2360 Value *consts_ptr = GEP(hPrivateData, {C(0), C(swr_draw_context_constantVS)});
2361
2362 consts_ptr->setName("vs_constants");
2363 Value *const_sizes_ptr =
2364 GEP(hPrivateData, {0, swr_draw_context_num_constantsVS});
2365 const_sizes_ptr->setName("num_vs_constants");
2366
2367 Value *vtxInput = LOAD(pVsCtx, {0, SWR_VS_CONTEXT_pVin});
2368 #if USE_SIMD16_VS
2369 vtxInput = BITCAST(vtxInput, PointerType::get(Gen_simd16vertex(JM()), 0));
2370 #endif
2371
2372 for (uint32_t attrib = 0; attrib < PIPE_MAX_SHADER_INPUTS; attrib++) {
2373 const unsigned mask = swr_vs->info.base.input_usage_mask[attrib];
2374 for (uint32_t channel = 0; channel < TGSI_NUM_CHANNELS; channel++) {
2375 if (mask & (1 << channel)) {
2376 inputs[attrib][channel] =
2377 wrap(LOAD(vtxInput, {0, 0, attrib, channel}));
2378 }
2379 }
2380 }
2381
2382 struct lp_build_sampler_soa *sampler =
2383 swr_sampler_soa_create(key.sampler, PIPE_SHADER_VERTEX);
2384 assert(sampler != nullptr);
2385
2386 struct lp_bld_tgsi_system_values system_values;
2387 memset(&system_values, 0, sizeof(system_values));
2388 system_values.instance_id = wrap(LOAD(pVsCtx, {0, SWR_VS_CONTEXT_InstanceID}));
2389
2390 #if USE_SIMD16_VS
2391 system_values.vertex_id = wrap(LOAD(pVsCtx, {0, SWR_VS_CONTEXT_VertexID16}));
2392 #else
2393 system_values.vertex_id = wrap(LOAD(pVsCtx, {0, SWR_VS_CONTEXT_VertexID}));
2394 #endif
2395
2396 #if USE_SIMD16_VS
2397 uint32_t vectorWidth = mVWidth16;
2398 #else
2399 uint32_t vectorWidth = mVWidth;
2400 #endif
2401
2402 struct lp_build_tgsi_params params;
2403 memset(¶ms, 0, sizeof(params));
2404 params.type = lp_type_float_vec(32, 32 * vectorWidth);
2405 params.consts_ptr = wrap(consts_ptr);
2406 params.const_sizes_ptr = wrap(const_sizes_ptr);
2407 params.system_values = &system_values;
2408 params.inputs = inputs;
2409 params.context_ptr = wrap(hPrivateData);
2410 params.sampler = sampler;
2411 params.info = &swr_vs->info.base;
2412
2413 lp_build_tgsi_soa(gallivm,
2414 swr_vs->pipe.tokens,
2415 ¶ms,
2416 outputs);
2417
2418 sampler->destroy(sampler);
2419
2420 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
2421
2422 Value *vtxOutput = LOAD(pVsCtx, {0, SWR_VS_CONTEXT_pVout});
2423 #if USE_SIMD16_VS
2424 vtxOutput = BITCAST(vtxOutput, PointerType::get(Gen_simd16vertex(JM()), 0));
2425 #endif
2426
2427 for (uint32_t channel = 0; channel < TGSI_NUM_CHANNELS; channel++) {
2428 for (uint32_t attrib = 0; attrib < PIPE_MAX_SHADER_OUTPUTS; attrib++) {
2429 if (!outputs[attrib][channel])
2430 continue;
2431
2432 Value *val;
2433 uint32_t outSlot;
2434
2435 if (swr_vs->info.base.output_semantic_name[attrib] == TGSI_SEMANTIC_PSIZE) {
2436 if (channel != VERTEX_SGV_POINT_SIZE_COMP)
2437 continue;
2438 val = LOAD(unwrap(outputs[attrib][0]));
2439 outSlot = VERTEX_SGV_SLOT;
2440 } else if (swr_vs->info.base.output_semantic_name[attrib] == TGSI_SEMANTIC_POSITION) {
2441 val = LOAD(unwrap(outputs[attrib][channel]));
2442 outSlot = VERTEX_POSITION_SLOT;
2443 } else {
2444 val = LOAD(unwrap(outputs[attrib][channel]));
2445 outSlot = VERTEX_ATTRIB_START_SLOT + attrib;
2446 if (swr_vs->info.base.output_semantic_name[0] == TGSI_SEMANTIC_POSITION)
2447 outSlot--;
2448 }
2449
2450 WriteVS(val, pVsCtx, vtxOutput, outSlot, channel);
2451 }
2452 }
2453
2454 if (ctx->rasterizer->clip_plane_enable ||
2455 swr_vs->info.base.culldist_writemask) {
2456 unsigned clip_mask = ctx->rasterizer->clip_plane_enable;
2457
2458 unsigned cv = 0;
2459 if (swr_vs->info.base.writes_clipvertex) {
2460 cv = locate_linkage(TGSI_SEMANTIC_CLIPVERTEX, 0,
2461 &swr_vs->info.base);
2462 } else {
2463 for (int i = 0; i < PIPE_MAX_SHADER_OUTPUTS; i++) {
2464 if (swr_vs->info.base.output_semantic_name[i] == TGSI_SEMANTIC_POSITION &&
2465 swr_vs->info.base.output_semantic_index[i] == 0) {
2466 cv = i;
2467 break;
2468 }
2469 }
2470 }
2471 assert(cv < PIPE_MAX_SHADER_OUTPUTS);
2472 LLVMValueRef cx = LLVMBuildLoad(gallivm->builder, outputs[cv][0], "");
2473 LLVMValueRef cy = LLVMBuildLoad(gallivm->builder, outputs[cv][1], "");
2474 LLVMValueRef cz = LLVMBuildLoad(gallivm->builder, outputs[cv][2], "");
2475 LLVMValueRef cw = LLVMBuildLoad(gallivm->builder, outputs[cv][3], "");
2476
2477 tgsi_shader_info *pLastFE = &ctx->vs->info.base;
2478
2479 if (ctx->gs) {
2480 pLastFE = &ctx->gs->info.base;
2481 }
2482 else if (ctx->tes) {
2483 pLastFE = &ctx->tes->info.base;
2484 }
2485 else if (ctx->tcs) {
2486 pLastFE = &ctx->tcs->info.base;
2487 }
2488
2489 for (unsigned val = 0; val < PIPE_MAX_CLIP_PLANES; val++) {
2490 // clip distance overrides user clip planes
2491 if ((pLastFE->clipdist_writemask & clip_mask & (1 << val)) ||
2492 ((pLastFE->culldist_writemask << pLastFE->num_written_clipdistance) & (1 << val))) {
2493 unsigned cv = locate_linkage(TGSI_SEMANTIC_CLIPDIST, val < 4 ? 0 : 1, pLastFE);
2494 assert(cv < PIPE_MAX_SHADER_OUTPUTS);
2495 if (val < 4) {
2496 LLVMValueRef dist = LLVMBuildLoad(gallivm->builder, outputs[cv][val], "");
2497 WriteVS(unwrap(dist), pVsCtx, vtxOutput, VERTEX_CLIPCULL_DIST_LO_SLOT, val);
2498 } else {
2499 LLVMValueRef dist = LLVMBuildLoad(gallivm->builder, outputs[cv][val - 4], "");
2500 WriteVS(unwrap(dist), pVsCtx, vtxOutput, VERTEX_CLIPCULL_DIST_HI_SLOT, val - 4);
2501 }
2502 continue;
2503 }
2504
2505 if (!(clip_mask & (1 << val)))
2506 continue;
2507
2508 Value *px = LOAD(GEP(hPrivateData, {0, swr_draw_context_userClipPlanes, val, 0}));
2509 Value *py = LOAD(GEP(hPrivateData, {0, swr_draw_context_userClipPlanes, val, 1}));
2510 Value *pz = LOAD(GEP(hPrivateData, {0, swr_draw_context_userClipPlanes, val, 2}));
2511 Value *pw = LOAD(GEP(hPrivateData, {0, swr_draw_context_userClipPlanes, val, 3}));
2512 #if USE_SIMD16_VS
2513 Value *bpx = VBROADCAST_16(px);
2514 Value *bpy = VBROADCAST_16(py);
2515 Value *bpz = VBROADCAST_16(pz);
2516 Value *bpw = VBROADCAST_16(pw);
2517 #else
2518 Value *bpx = VBROADCAST(px);
2519 Value *bpy = VBROADCAST(py);
2520 Value *bpz = VBROADCAST(pz);
2521 Value *bpw = VBROADCAST(pw);
2522 #endif
2523 Value *dist = FADD(FMUL(unwrap(cx), bpx),
2524 FADD(FMUL(unwrap(cy), bpy),
2525 FADD(FMUL(unwrap(cz), bpz),
2526 FMUL(unwrap(cw), bpw))));
2527
2528 if (val < 4)
2529 WriteVS(dist, pVsCtx, vtxOutput, VERTEX_CLIPCULL_DIST_LO_SLOT, val);
2530 else
2531 WriteVS(dist, pVsCtx, vtxOutput, VERTEX_CLIPCULL_DIST_HI_SLOT, val - 4);
2532 }
2533 }
2534
2535 RET_VOID();
2536
2537 JM()->DumpToFile(pFunction, "vs_function1");
2538 gallivm_verify_function(gallivm, wrap(pFunction));
2539 gallivm_compile_module(gallivm);
2540 JM()->DumpToFile(pFunction, "vs_function2");
2541
2542 // lp_debug_dump_value(func);
2543
2544 PFN_VERTEX_FUNC pFunc =
2545 (PFN_VERTEX_FUNC)gallivm_jit_function(gallivm, wrap(pFunction));
2546
2547 JM()->DumpAsm(pFunction, "vs_function_asm");
2548 debug_printf("vert shader %p\n", pFunc);
2549 assert(pFunc && "Error: VertShader = NULL");
2550
2551 JM()->mIsModuleFinalized = true;
2552
2553 return pFunc;
2554 }
2555
2556 PFN_VERTEX_FUNC
swr_compile_vs(struct swr_context * ctx,swr_jit_vs_key & key)2557 swr_compile_vs(struct swr_context *ctx, swr_jit_vs_key &key)
2558 {
2559 if (!ctx->vs->pipe.tokens)
2560 return NULL;
2561
2562 BuilderSWR builder(
2563 reinterpret_cast<JitManager *>(swr_screen(ctx->pipe.screen)->hJitMgr),
2564 "VS");
2565 PFN_VERTEX_FUNC func = builder.CompileVS(ctx, key);
2566
2567 ctx->vs->map.insert(std::make_pair(key, std::unique_ptr<VariantVS>(new VariantVS(builder.gallivm, func))));
2568 return func;
2569 }
2570
2571 unsigned
swr_so_adjust_attrib(unsigned in_attrib,swr_vertex_shader * swr_vs)2572 swr_so_adjust_attrib(unsigned in_attrib,
2573 swr_vertex_shader *swr_vs)
2574 {
2575 ubyte semantic_name;
2576 unsigned attrib;
2577
2578 attrib = in_attrib + VERTEX_ATTRIB_START_SLOT;
2579
2580 if (swr_vs) {
2581 semantic_name = swr_vs->info.base.output_semantic_name[in_attrib];
2582 if (semantic_name == TGSI_SEMANTIC_POSITION) {
2583 attrib = VERTEX_POSITION_SLOT;
2584 } else if (semantic_name == TGSI_SEMANTIC_PSIZE) {
2585 attrib = VERTEX_SGV_SLOT;
2586 } else if (semantic_name == TGSI_SEMANTIC_LAYER) {
2587 attrib = VERTEX_SGV_SLOT;
2588 } else {
2589 if (swr_vs->info.base.writes_position) {
2590 attrib--;
2591 }
2592 }
2593 }
2594
2595 return attrib;
2596 }
2597
2598 static unsigned
locate_linkage(ubyte name,ubyte index,struct tgsi_shader_info * info)2599 locate_linkage(ubyte name, ubyte index, struct tgsi_shader_info *info)
2600 {
2601 for (int i = 0; i < PIPE_MAX_SHADER_OUTPUTS; i++) {
2602 if ((info->output_semantic_name[i] == name)
2603 && (info->output_semantic_index[i] == index)) {
2604 return i;
2605 }
2606 }
2607
2608 return 0xFFFFFFFF;
2609 }
2610
2611 PFN_PIXEL_KERNEL
CompileFS(struct swr_context * ctx,swr_jit_fs_key & key)2612 BuilderSWR::CompileFS(struct swr_context *ctx, swr_jit_fs_key &key)
2613 {
2614 struct swr_fragment_shader *swr_fs = ctx->fs;
2615
2616 struct tgsi_shader_info *pPrevShader;
2617 if (ctx->gs)
2618 pPrevShader = &ctx->gs->info.base;
2619 else if (ctx->tes)
2620 pPrevShader = &ctx->tes->info.base;
2621 else
2622 pPrevShader = &ctx->vs->info.base;
2623
2624 LLVMValueRef inputs[PIPE_MAX_SHADER_INPUTS][TGSI_NUM_CHANNELS];
2625 LLVMValueRef outputs[PIPE_MAX_SHADER_OUTPUTS][TGSI_NUM_CHANNELS];
2626
2627 memset(inputs, 0, sizeof(inputs));
2628 memset(outputs, 0, sizeof(outputs));
2629
2630 struct lp_build_sampler_soa *sampler = NULL;
2631
2632 AttrBuilder attrBuilder;
2633 attrBuilder.addStackAlignmentAttr(JM()->mVWidth * sizeof(float));
2634
2635 std::vector<Type *> fsArgs{PointerType::get(Gen_swr_draw_context(JM()), 0),
2636 PointerType::get(mInt8Ty, 0),
2637 PointerType::get(Gen_SWR_PS_CONTEXT(JM()), 0)};
2638 FunctionType *funcType =
2639 FunctionType::get(Type::getVoidTy(JM()->mContext), fsArgs, false);
2640
2641 auto pFunction = Function::Create(funcType,
2642 GlobalValue::ExternalLinkage,
2643 "FS",
2644 JM()->mpCurrentModule);
2645 #if LLVM_VERSION_MAJOR < 5
2646 AttributeSet attrSet = AttributeSet::get(
2647 JM()->mContext, AttributeSet::FunctionIndex, attrBuilder);
2648 pFunction->addAttributes(AttributeSet::FunctionIndex, attrSet);
2649 #else
2650 pFunction->addAttributes(AttributeList::FunctionIndex, attrBuilder);
2651 #endif
2652
2653 BasicBlock *block = BasicBlock::Create(JM()->mContext, "entry", pFunction);
2654 IRB()->SetInsertPoint(block);
2655 LLVMPositionBuilderAtEnd(gallivm->builder, wrap(block));
2656
2657 auto args = pFunction->arg_begin();
2658 Value *hPrivateData = &*args++;
2659 hPrivateData->setName("hPrivateData");
2660 Value *pWorkerData = &*args++;
2661 pWorkerData->setName("pWorkerData");
2662 Value *pPS = &*args++;
2663 pPS->setName("psCtx");
2664
2665 Value *consts_ptr = GEP(hPrivateData, {0, swr_draw_context_constantFS});
2666 consts_ptr->setName("fs_constants");
2667 Value *const_sizes_ptr =
2668 GEP(hPrivateData, {0, swr_draw_context_num_constantsFS});
2669 const_sizes_ptr->setName("num_fs_constants");
2670
2671 // load *pAttribs, *pPerspAttribs
2672 Value *pRawAttribs = LOAD(pPS, {0, SWR_PS_CONTEXT_pAttribs}, "pRawAttribs");
2673 Value *pPerspAttribs =
2674 LOAD(pPS, {0, SWR_PS_CONTEXT_pPerspAttribs}, "pPerspAttribs");
2675
2676 swr_fs->constantMask = 0;
2677 swr_fs->flatConstantMask = 0;
2678 swr_fs->pointSpriteMask = 0;
2679
2680 for (int attrib = 0; attrib < PIPE_MAX_SHADER_INPUTS; attrib++) {
2681 const unsigned mask = swr_fs->info.base.input_usage_mask[attrib];
2682 const unsigned interpMode = swr_fs->info.base.input_interpolate[attrib];
2683 const unsigned interpLoc = swr_fs->info.base.input_interpolate_loc[attrib];
2684
2685 if (!mask)
2686 continue;
2687
2688 // load i,j
2689 Value *vi = nullptr, *vj = nullptr;
2690 switch (interpLoc) {
2691 case TGSI_INTERPOLATE_LOC_CENTER:
2692 vi = LOAD(pPS, {0, SWR_PS_CONTEXT_vI, PixelPositions_center}, "i");
2693 vj = LOAD(pPS, {0, SWR_PS_CONTEXT_vJ, PixelPositions_center}, "j");
2694 break;
2695 case TGSI_INTERPOLATE_LOC_CENTROID:
2696 vi = LOAD(pPS, {0, SWR_PS_CONTEXT_vI, PixelPositions_centroid}, "i");
2697 vj = LOAD(pPS, {0, SWR_PS_CONTEXT_vJ, PixelPositions_centroid}, "j");
2698 break;
2699 case TGSI_INTERPOLATE_LOC_SAMPLE:
2700 vi = LOAD(pPS, {0, SWR_PS_CONTEXT_vI, PixelPositions_sample}, "i");
2701 vj = LOAD(pPS, {0, SWR_PS_CONTEXT_vJ, PixelPositions_sample}, "j");
2702 break;
2703 }
2704
2705 // load/compute w
2706 Value *vw = nullptr, *pAttribs;
2707 if (interpMode == TGSI_INTERPOLATE_PERSPECTIVE ||
2708 interpMode == TGSI_INTERPOLATE_COLOR) {
2709 pAttribs = pPerspAttribs;
2710 switch (interpLoc) {
2711 case TGSI_INTERPOLATE_LOC_CENTER:
2712 vw = VRCP(LOAD(pPS, {0, SWR_PS_CONTEXT_vOneOverW, PixelPositions_center}));
2713 break;
2714 case TGSI_INTERPOLATE_LOC_CENTROID:
2715 vw = VRCP(LOAD(pPS, {0, SWR_PS_CONTEXT_vOneOverW, PixelPositions_centroid}));
2716 break;
2717 case TGSI_INTERPOLATE_LOC_SAMPLE:
2718 vw = VRCP(LOAD(pPS, {0, SWR_PS_CONTEXT_vOneOverW, PixelPositions_sample}));
2719 break;
2720 }
2721 } else {
2722 pAttribs = pRawAttribs;
2723 vw = VIMMED1(1.f);
2724 }
2725
2726 vw->setName("w");
2727
2728 ubyte semantic_name = swr_fs->info.base.input_semantic_name[attrib];
2729 ubyte semantic_idx = swr_fs->info.base.input_semantic_index[attrib];
2730
2731 if (semantic_name == TGSI_SEMANTIC_FACE) {
2732 Value *ff =
2733 UI_TO_FP(LOAD(pPS, {0, SWR_PS_CONTEXT_frontFace}), mFP32Ty);
2734 ff = FSUB(FMUL(ff, C(2.0f)), C(1.0f));
2735 ff = VECTOR_SPLAT(JM()->mVWidth, ff, "vFrontFace");
2736
2737 inputs[attrib][0] = wrap(ff);
2738 inputs[attrib][1] = wrap(VIMMED1(0.0f));
2739 inputs[attrib][2] = wrap(VIMMED1(0.0f));
2740 inputs[attrib][3] = wrap(VIMMED1(1.0f));
2741 continue;
2742 } else if (semantic_name == TGSI_SEMANTIC_POSITION) { // gl_FragCoord
2743 if (swr_fs->info.base.properties[TGSI_PROPERTY_FS_COORD_PIXEL_CENTER] ==
2744 TGSI_FS_COORD_PIXEL_CENTER_HALF_INTEGER) {
2745 inputs[attrib][0] = wrap(LOAD(pPS, {0, SWR_PS_CONTEXT_vX, PixelPositions_center}, "vX"));
2746 inputs[attrib][1] = wrap(LOAD(pPS, {0, SWR_PS_CONTEXT_vY, PixelPositions_center}, "vY"));
2747 } else {
2748 inputs[attrib][0] = wrap(LOAD(pPS, {0, SWR_PS_CONTEXT_vX, PixelPositions_UL}, "vX"));
2749 inputs[attrib][1] = wrap(LOAD(pPS, {0, SWR_PS_CONTEXT_vY, PixelPositions_UL}, "vY"));
2750 }
2751 inputs[attrib][2] = wrap(LOAD(pPS, {0, SWR_PS_CONTEXT_vZ}, "vZ"));
2752 inputs[attrib][3] =
2753 wrap(LOAD(pPS, {0, SWR_PS_CONTEXT_vOneOverW, PixelPositions_center}, "vOneOverW"));
2754 continue;
2755 } else if (semantic_name == TGSI_SEMANTIC_LAYER) { // gl_Layer
2756 Value *ff = LOAD(pPS, {0, SWR_PS_CONTEXT_renderTargetArrayIndex});
2757 ff = VECTOR_SPLAT(JM()->mVWidth, ff, "vRenderTargetArrayIndex");
2758 inputs[attrib][0] = wrap(ff);
2759 inputs[attrib][1] = wrap(VIMMED1(0.0f));
2760 inputs[attrib][2] = wrap(VIMMED1(0.0f));
2761 inputs[attrib][3] = wrap(VIMMED1(0.0f));
2762 continue;
2763 } else if (semantic_name == TGSI_SEMANTIC_VIEWPORT_INDEX) { // gl_ViewportIndex
2764 Value *ff = LOAD(pPS, {0, SWR_PS_CONTEXT_viewportIndex});
2765 ff = VECTOR_SPLAT(JM()->mVWidth, ff, "vViewportIndex");
2766 inputs[attrib][0] = wrap(ff);
2767 inputs[attrib][1] = wrap(VIMMED1(0.0f));
2768 inputs[attrib][2] = wrap(VIMMED1(0.0f));
2769 inputs[attrib][3] = wrap(VIMMED1(0.0f));
2770 continue;
2771 }
2772 unsigned linkedAttrib =
2773 locate_linkage(semantic_name, semantic_idx, pPrevShader) - 1;
2774
2775 uint32_t extraAttribs = 0;
2776 if (semantic_name == TGSI_SEMANTIC_PRIMID && !ctx->gs) {
2777 /* non-gs generated primID - need to grab from swizzleMap override */
2778 linkedAttrib = pPrevShader->num_outputs - 1;
2779 swr_fs->constantMask |= 1 << linkedAttrib;
2780 extraAttribs++;
2781 } else if (semantic_name == TGSI_SEMANTIC_GENERIC &&
2782 key.sprite_coord_enable & (1 << semantic_idx)) {
2783 /* we add an extra attrib to the backendState in swr_update_derived. */
2784 linkedAttrib = pPrevShader->num_outputs + extraAttribs - 1;
2785 swr_fs->pointSpriteMask |= (1 << linkedAttrib);
2786 extraAttribs++;
2787 } else if (linkedAttrib + 1 == 0xFFFFFFFF) {
2788 inputs[attrib][0] = wrap(VIMMED1(0.0f));
2789 inputs[attrib][1] = wrap(VIMMED1(0.0f));
2790 inputs[attrib][2] = wrap(VIMMED1(0.0f));
2791 inputs[attrib][3] = wrap(VIMMED1(1.0f));
2792 /* If we're reading in color and 2-sided lighting is enabled, we have
2793 * to keep going.
2794 */
2795 if (semantic_name != TGSI_SEMANTIC_COLOR || !key.light_twoside)
2796 continue;
2797 } else {
2798 if (interpMode == TGSI_INTERPOLATE_CONSTANT) {
2799 swr_fs->constantMask |= 1 << linkedAttrib;
2800 } else if (interpMode == TGSI_INTERPOLATE_COLOR) {
2801 swr_fs->flatConstantMask |= 1 << linkedAttrib;
2802 }
2803 }
2804
2805 unsigned bcolorAttrib = 0xFFFFFFFF;
2806 Value *offset = NULL;
2807 if (semantic_name == TGSI_SEMANTIC_COLOR && key.light_twoside) {
2808 bcolorAttrib = locate_linkage(
2809 TGSI_SEMANTIC_BCOLOR, semantic_idx, pPrevShader);
2810 /* Neither front nor back colors were available. Nothing to load. */
2811 if (bcolorAttrib == 0xFFFFFFFF && linkedAttrib == 0xFFFFFFFF)
2812 continue;
2813 /* If there is no front color, just always use the back color. */
2814 if (linkedAttrib + 1 == 0xFFFFFFFF)
2815 linkedAttrib = bcolorAttrib;
2816
2817 if (bcolorAttrib != 0xFFFFFFFF) {
2818 bcolorAttrib -= 1;
2819 if (interpMode == TGSI_INTERPOLATE_CONSTANT) {
2820 swr_fs->constantMask |= 1 << bcolorAttrib;
2821 } else if (interpMode == TGSI_INTERPOLATE_COLOR) {
2822 swr_fs->flatConstantMask |= 1 << bcolorAttrib;
2823 }
2824
2825 unsigned diff = 12 * (bcolorAttrib - linkedAttrib);
2826
2827 if (diff) {
2828 Value *back =
2829 XOR(C(1), LOAD(pPS, {0, SWR_PS_CONTEXT_frontFace}), "backFace");
2830
2831 offset = MUL(back, C(diff));
2832 offset->setName("offset");
2833 }
2834 }
2835 }
2836
2837 for (int channel = 0; channel < TGSI_NUM_CHANNELS; channel++) {
2838 if (mask & (1 << channel)) {
2839 Value *indexA = C(linkedAttrib * 12 + channel);
2840 Value *indexB = C(linkedAttrib * 12 + channel + 4);
2841 Value *indexC = C(linkedAttrib * 12 + channel + 8);
2842
2843 if (offset) {
2844 indexA = ADD(indexA, offset);
2845 indexB = ADD(indexB, offset);
2846 indexC = ADD(indexC, offset);
2847 }
2848
2849 Value *va = VBROADCAST(LOAD(GEP(pAttribs, indexA)));
2850 Value *vb = VBROADCAST(LOAD(GEP(pAttribs, indexB)));
2851 Value *vc = VBROADCAST(LOAD(GEP(pAttribs, indexC)));
2852
2853 if (interpMode == TGSI_INTERPOLATE_CONSTANT) {
2854 inputs[attrib][channel] = wrap(va);
2855 } else {
2856 Value *vk = FSUB(FSUB(VIMMED1(1.0f), vi), vj);
2857
2858 vc = FMUL(vk, vc);
2859
2860 Value *interp = FMUL(va, vi);
2861 Value *interp1 = FMUL(vb, vj);
2862 interp = FADD(interp, interp1);
2863 interp = FADD(interp, vc);
2864 if (interpMode == TGSI_INTERPOLATE_PERSPECTIVE ||
2865 interpMode == TGSI_INTERPOLATE_COLOR)
2866 interp = FMUL(interp, vw);
2867 inputs[attrib][channel] = wrap(interp);
2868 }
2869 }
2870 }
2871 }
2872
2873 sampler = swr_sampler_soa_create(key.sampler, PIPE_SHADER_FRAGMENT);
2874 assert(sampler != nullptr);
2875
2876 struct lp_bld_tgsi_system_values system_values;
2877 memset(&system_values, 0, sizeof(system_values));
2878
2879 struct lp_build_mask_context mask;
2880 bool uses_mask = false;
2881
2882 if (swr_fs->info.base.uses_kill ||
2883 key.poly_stipple_enable) {
2884 Value *vActiveMask = NULL;
2885 if (swr_fs->info.base.uses_kill) {
2886 vActiveMask = LOAD(pPS, {0, SWR_PS_CONTEXT_activeMask}, "activeMask");
2887 }
2888 if (key.poly_stipple_enable) {
2889 // first get fragment xy coords and clip to stipple bounds
2890 Value *vXf = LOAD(pPS, {0, SWR_PS_CONTEXT_vX, PixelPositions_UL});
2891 Value *vYf = LOAD(pPS, {0, SWR_PS_CONTEXT_vY, PixelPositions_UL});
2892 Value *vXu = FP_TO_UI(vXf, mSimdInt32Ty);
2893 Value *vYu = FP_TO_UI(vYf, mSimdInt32Ty);
2894
2895 // stipple pattern is 32x32, which means that one line of stipple
2896 // is stored in one word:
2897 // vXstipple is bit offset inside 32-bit stipple word
2898 // vYstipple is word index is stipple array
2899 Value *vXstipple = AND(vXu, VIMMED1(0x1f)); // & (32-1)
2900 Value *vYstipple = AND(vYu, VIMMED1(0x1f)); // & (32-1)
2901
2902 // grab stipple pattern base address
2903 Value *stipplePtr = GEP(hPrivateData, {0, swr_draw_context_polyStipple, 0});
2904 stipplePtr = BITCAST(stipplePtr, mInt8PtrTy);
2905
2906 // peform a gather to grab stipple words for each lane
2907 Value *vStipple = GATHERDD(VUNDEF_I(), stipplePtr, vYstipple,
2908 VIMMED1(0xffffffff), 4);
2909
2910 // create a mask with one bit corresponding to the x stipple
2911 // and AND it with the pattern, to see if we have a bit
2912 Value *vBitMask = LSHR(VIMMED1(0x80000000), vXstipple);
2913 Value *vStippleMask = AND(vStipple, vBitMask);
2914 vStippleMask = ICMP_NE(vStippleMask, VIMMED1(0));
2915 vStippleMask = VMASK(vStippleMask);
2916
2917 if (swr_fs->info.base.uses_kill) {
2918 vActiveMask = AND(vActiveMask, vStippleMask);
2919 } else {
2920 vActiveMask = vStippleMask;
2921 }
2922 }
2923 lp_build_mask_begin(
2924 &mask, gallivm, lp_type_float_vec(32, 32 * 8), wrap(vActiveMask));
2925 uses_mask = true;
2926 }
2927
2928 struct lp_build_tgsi_params params;
2929 memset(¶ms, 0, sizeof(params));
2930 params.type = lp_type_float_vec(32, 32 * 8);
2931 params.mask = uses_mask ? &mask : NULL;
2932 params.consts_ptr = wrap(consts_ptr);
2933 params.const_sizes_ptr = wrap(const_sizes_ptr);
2934 params.system_values = &system_values;
2935 params.inputs = inputs;
2936 params.context_ptr = wrap(hPrivateData);
2937 params.sampler = sampler;
2938 params.info = &swr_fs->info.base;
2939
2940 lp_build_tgsi_soa(gallivm,
2941 swr_fs->pipe.tokens,
2942 ¶ms,
2943 outputs);
2944
2945 sampler->destroy(sampler);
2946
2947 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
2948
2949 for (uint32_t attrib = 0; attrib < swr_fs->info.base.num_outputs;
2950 attrib++) {
2951 switch (swr_fs->info.base.output_semantic_name[attrib]) {
2952 case TGSI_SEMANTIC_POSITION: {
2953 // write z
2954 LLVMValueRef outZ =
2955 LLVMBuildLoad(gallivm->builder, outputs[attrib][2], "");
2956 STORE(unwrap(outZ), pPS, {0, SWR_PS_CONTEXT_vZ});
2957 break;
2958 }
2959 case TGSI_SEMANTIC_COLOR: {
2960 for (uint32_t channel = 0; channel < TGSI_NUM_CHANNELS; channel++) {
2961 if (!outputs[attrib][channel])
2962 continue;
2963
2964 LLVMValueRef out =
2965 LLVMBuildLoad(gallivm->builder, outputs[attrib][channel], "");
2966 if (swr_fs->info.base.properties[TGSI_PROPERTY_FS_COLOR0_WRITES_ALL_CBUFS] &&
2967 swr_fs->info.base.output_semantic_index[attrib] == 0) {
2968 for (uint32_t rt = 0; rt < key.nr_cbufs; rt++) {
2969 STORE(unwrap(out),
2970 pPS,
2971 {0, SWR_PS_CONTEXT_shaded, rt, channel});
2972 }
2973 } else {
2974 STORE(unwrap(out),
2975 pPS,
2976 {0,
2977 SWR_PS_CONTEXT_shaded,
2978 swr_fs->info.base.output_semantic_index[attrib],
2979 channel});
2980 }
2981 }
2982 break;
2983 }
2984 default: {
2985 fprintf(stderr,
2986 "unknown output from FS %s[%d]\n",
2987 tgsi_semantic_names[swr_fs->info.base
2988 .output_semantic_name[attrib]],
2989 swr_fs->info.base.output_semantic_index[attrib]);
2990 break;
2991 }
2992 }
2993 }
2994
2995 LLVMValueRef mask_result = 0;
2996 if (uses_mask) {
2997 mask_result = lp_build_mask_end(&mask);
2998 }
2999
3000 IRB()->SetInsertPoint(unwrap(LLVMGetInsertBlock(gallivm->builder)));
3001
3002 if (uses_mask) {
3003 STORE(unwrap(mask_result), pPS, {0, SWR_PS_CONTEXT_activeMask});
3004 }
3005
3006 RET_VOID();
3007
3008 gallivm_verify_function(gallivm, wrap(pFunction));
3009
3010 gallivm_compile_module(gallivm);
3011
3012 // after the gallivm passes, we have to lower the core's intrinsics
3013 llvm::legacy::FunctionPassManager lowerPass(JM()->mpCurrentModule);
3014 lowerPass.add(createLowerX86Pass(this));
3015 lowerPass.run(*pFunction);
3016
3017 PFN_PIXEL_KERNEL kernel =
3018 (PFN_PIXEL_KERNEL)gallivm_jit_function(gallivm, wrap(pFunction));
3019 debug_printf("frag shader %p\n", kernel);
3020 assert(kernel && "Error: FragShader = NULL");
3021
3022 JM()->mIsModuleFinalized = true;
3023
3024 return kernel;
3025 }
3026
3027 PFN_PIXEL_KERNEL
swr_compile_fs(struct swr_context * ctx,swr_jit_fs_key & key)3028 swr_compile_fs(struct swr_context *ctx, swr_jit_fs_key &key)
3029 {
3030 if (!ctx->fs->pipe.tokens)
3031 return NULL;
3032
3033 BuilderSWR builder(
3034 reinterpret_cast<JitManager *>(swr_screen(ctx->pipe.screen)->hJitMgr),
3035 "FS");
3036 PFN_PIXEL_KERNEL func = builder.CompileFS(ctx, key);
3037
3038 ctx->fs->map.insert(std::make_pair(key, std::unique_ptr<VariantFS>(new VariantFS(builder.gallivm, func))));
3039 return func;
3040 }
3041