1b8e80941Smrg/* 2b8e80941Smrg * Copyright (C) 2017-2018 Rob Clark <robclark@freedesktop.org> 3b8e80941Smrg * 4b8e80941Smrg * Permission is hereby granted, free of charge, to any person obtaining a 5b8e80941Smrg * copy of this software and associated documentation files (the "Software"), 6b8e80941Smrg * to deal in the Software without restriction, including without limitation 7b8e80941Smrg * the rights to use, copy, modify, merge, publish, distribute, sublicense, 8b8e80941Smrg * and/or sell copies of the Software, and to permit persons to whom the 9b8e80941Smrg * Software is furnished to do so, subject to the following conditions: 10b8e80941Smrg * 11b8e80941Smrg * The above copyright notice and this permission notice (including the next 12b8e80941Smrg * paragraph) shall be included in all copies or substantial portions of the 13b8e80941Smrg * Software. 14b8e80941Smrg * 15b8e80941Smrg * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR 16b8e80941Smrg * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, 17b8e80941Smrg * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL 18b8e80941Smrg * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER 19b8e80941Smrg * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, 20b8e80941Smrg * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE 21b8e80941Smrg * SOFTWARE. 22b8e80941Smrg * 23b8e80941Smrg * Authors: 24b8e80941Smrg * Rob Clark <robclark@freedesktop.org> 25b8e80941Smrg */ 26b8e80941Smrg 27b8e80941Smrg#define GPU 400 28b8e80941Smrg 29b8e80941Smrg#include "ir3_context.h" 30b8e80941Smrg#include "ir3_image.h" 31b8e80941Smrg 32b8e80941Smrg/* 33b8e80941Smrg * Handlers for instructions changed/added in a4xx: 34b8e80941Smrg */ 35b8e80941Smrg 36b8e80941Smrg 37b8e80941Smrg/* src[] = { buffer_index, offset }. No const_index */ 38b8e80941Smrgstatic void 39b8e80941Smrgemit_intrinsic_load_ssbo(struct ir3_context *ctx, nir_intrinsic_instr *intr, 40b8e80941Smrg struct ir3_instruction **dst) 41b8e80941Smrg{ 42b8e80941Smrg struct ir3_block *b = ctx->block; 43b8e80941Smrg struct ir3_instruction *ldgb, *src0, *src1, *byte_offset, *offset; 44b8e80941Smrg 45b8e80941Smrg /* can this be non-const buffer_index? how do we handle that? */ 46b8e80941Smrg int ibo_idx = ir3_ssbo_to_ibo(&ctx->so->image_mapping, nir_src_as_uint(intr->src[0])); 47b8e80941Smrg 48b8e80941Smrg byte_offset = ir3_get_src(ctx, &intr->src[1])[0]; 49b8e80941Smrg offset = ir3_get_src(ctx, &intr->src[2])[0]; 50b8e80941Smrg 51b8e80941Smrg /* src0 is uvec2(offset*4, 0), src1 is offset.. nir already *= 4: */ 52b8e80941Smrg src0 = ir3_create_collect(ctx, (struct ir3_instruction*[]){ 53b8e80941Smrg byte_offset, 54b8e80941Smrg create_immed(b, 0), 55b8e80941Smrg }, 2); 56b8e80941Smrg src1 = offset; 57b8e80941Smrg 58b8e80941Smrg ldgb = ir3_LDGB(b, create_immed(b, ibo_idx), 0, 59b8e80941Smrg src0, 0, src1, 0); 60b8e80941Smrg ldgb->regs[0]->wrmask = MASK(intr->num_components); 61b8e80941Smrg ldgb->cat6.iim_val = intr->num_components; 62b8e80941Smrg ldgb->cat6.d = 4; 63b8e80941Smrg ldgb->cat6.type = TYPE_U32; 64b8e80941Smrg ldgb->barrier_class = IR3_BARRIER_BUFFER_R; 65b8e80941Smrg ldgb->barrier_conflict = IR3_BARRIER_BUFFER_W; 66b8e80941Smrg 67b8e80941Smrg ir3_split_dest(b, dst, ldgb, 0, intr->num_components); 68b8e80941Smrg} 69b8e80941Smrg 70b8e80941Smrg/* src[] = { value, block_index, offset }. const_index[] = { write_mask } */ 71b8e80941Smrgstatic void 72b8e80941Smrgemit_intrinsic_store_ssbo(struct ir3_context *ctx, nir_intrinsic_instr *intr) 73b8e80941Smrg{ 74b8e80941Smrg struct ir3_block *b = ctx->block; 75b8e80941Smrg struct ir3_instruction *stgb, *src0, *src1, *src2, *byte_offset, *offset; 76b8e80941Smrg /* TODO handle wrmask properly, see _store_shared().. but I think 77b8e80941Smrg * it is more a PITA than that, since blob ends up loading the 78b8e80941Smrg * masked components and writing them back out. 79b8e80941Smrg */ 80b8e80941Smrg unsigned wrmask = intr->const_index[0]; 81b8e80941Smrg unsigned ncomp = ffs(~wrmask) - 1; 82b8e80941Smrg 83b8e80941Smrg /* can this be non-const buffer_index? how do we handle that? */ 84b8e80941Smrg int ibo_idx = ir3_ssbo_to_ibo(&ctx->so->image_mapping, nir_src_as_uint(intr->src[1])); 85b8e80941Smrg 86b8e80941Smrg byte_offset = ir3_get_src(ctx, &intr->src[2])[0]; 87b8e80941Smrg offset = ir3_get_src(ctx, &intr->src[3])[0]; 88b8e80941Smrg 89b8e80941Smrg /* src0 is value, src1 is offset, src2 is uvec2(offset*4, 0).. 90b8e80941Smrg * nir already *= 4: 91b8e80941Smrg */ 92b8e80941Smrg src0 = ir3_create_collect(ctx, ir3_get_src(ctx, &intr->src[0]), ncomp); 93b8e80941Smrg src1 = offset; 94b8e80941Smrg src2 = ir3_create_collect(ctx, (struct ir3_instruction*[]){ 95b8e80941Smrg byte_offset, 96b8e80941Smrg create_immed(b, 0), 97b8e80941Smrg }, 2); 98b8e80941Smrg 99b8e80941Smrg stgb = ir3_STGB(b, create_immed(b, ibo_idx), 0, src0, 0, src1, 0, src2, 0); 100b8e80941Smrg stgb->cat6.iim_val = ncomp; 101b8e80941Smrg stgb->cat6.d = 4; 102b8e80941Smrg stgb->cat6.type = TYPE_U32; 103b8e80941Smrg stgb->barrier_class = IR3_BARRIER_BUFFER_W; 104b8e80941Smrg stgb->barrier_conflict = IR3_BARRIER_BUFFER_R | IR3_BARRIER_BUFFER_W; 105b8e80941Smrg 106b8e80941Smrg array_insert(b, b->keeps, stgb); 107b8e80941Smrg} 108b8e80941Smrg 109b8e80941Smrg/* 110b8e80941Smrg * SSBO atomic intrinsics 111b8e80941Smrg * 112b8e80941Smrg * All of the SSBO atomic memory operations read a value from memory, 113b8e80941Smrg * compute a new value using one of the operations below, write the new 114b8e80941Smrg * value to memory, and return the original value read. 115b8e80941Smrg * 116b8e80941Smrg * All operations take 3 sources except CompSwap that takes 4. These 117b8e80941Smrg * sources represent: 118b8e80941Smrg * 119b8e80941Smrg * 0: The SSBO buffer index. 120b8e80941Smrg * 1: The offset into the SSBO buffer of the variable that the atomic 121b8e80941Smrg * operation will operate on. 122b8e80941Smrg * 2: The data parameter to the atomic function (i.e. the value to add 123b8e80941Smrg * in ssbo_atomic_add, etc). 124b8e80941Smrg * 3: For CompSwap only: the second data parameter. 125b8e80941Smrg */ 126b8e80941Smrgstatic struct ir3_instruction * 127b8e80941Smrgemit_intrinsic_atomic_ssbo(struct ir3_context *ctx, nir_intrinsic_instr *intr) 128b8e80941Smrg{ 129b8e80941Smrg struct ir3_block *b = ctx->block; 130b8e80941Smrg struct ir3_instruction *atomic, *ssbo, *src0, *src1, *src2, *byte_offset, 131b8e80941Smrg *offset; 132b8e80941Smrg type_t type = TYPE_U32; 133b8e80941Smrg 134b8e80941Smrg /* can this be non-const buffer_index? how do we handle that? */ 135b8e80941Smrg int ibo_idx = ir3_ssbo_to_ibo(&ctx->so->image_mapping, nir_src_as_uint(intr->src[0])); 136b8e80941Smrg ssbo = create_immed(b, ibo_idx); 137b8e80941Smrg 138b8e80941Smrg byte_offset = ir3_get_src(ctx, &intr->src[1])[0]; 139b8e80941Smrg offset = ir3_get_src(ctx, &intr->src[3])[0]; 140b8e80941Smrg 141b8e80941Smrg /* src0 is data (or uvec2(data, compare)) 142b8e80941Smrg * src1 is offset 143b8e80941Smrg * src2 is uvec2(offset*4, 0) (appears to be 64b byte offset) 144b8e80941Smrg * 145b8e80941Smrg * Note that nir already multiplies the offset by four 146b8e80941Smrg */ 147b8e80941Smrg src0 = ir3_get_src(ctx, &intr->src[2])[0]; 148b8e80941Smrg src1 = offset; 149b8e80941Smrg src2 = ir3_create_collect(ctx, (struct ir3_instruction*[]){ 150b8e80941Smrg byte_offset, 151b8e80941Smrg create_immed(b, 0), 152b8e80941Smrg }, 2); 153b8e80941Smrg 154b8e80941Smrg switch (intr->intrinsic) { 155b8e80941Smrg case nir_intrinsic_ssbo_atomic_add_ir3: 156b8e80941Smrg atomic = ir3_ATOMIC_ADD_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 157b8e80941Smrg break; 158b8e80941Smrg case nir_intrinsic_ssbo_atomic_imin_ir3: 159b8e80941Smrg atomic = ir3_ATOMIC_MIN_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 160b8e80941Smrg type = TYPE_S32; 161b8e80941Smrg break; 162b8e80941Smrg case nir_intrinsic_ssbo_atomic_umin_ir3: 163b8e80941Smrg atomic = ir3_ATOMIC_MIN_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 164b8e80941Smrg break; 165b8e80941Smrg case nir_intrinsic_ssbo_atomic_imax_ir3: 166b8e80941Smrg atomic = ir3_ATOMIC_MAX_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 167b8e80941Smrg type = TYPE_S32; 168b8e80941Smrg break; 169b8e80941Smrg case nir_intrinsic_ssbo_atomic_umax_ir3: 170b8e80941Smrg atomic = ir3_ATOMIC_MAX_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 171b8e80941Smrg break; 172b8e80941Smrg case nir_intrinsic_ssbo_atomic_and_ir3: 173b8e80941Smrg atomic = ir3_ATOMIC_AND_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 174b8e80941Smrg break; 175b8e80941Smrg case nir_intrinsic_ssbo_atomic_or_ir3: 176b8e80941Smrg atomic = ir3_ATOMIC_OR_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 177b8e80941Smrg break; 178b8e80941Smrg case nir_intrinsic_ssbo_atomic_xor_ir3: 179b8e80941Smrg atomic = ir3_ATOMIC_XOR_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 180b8e80941Smrg break; 181b8e80941Smrg case nir_intrinsic_ssbo_atomic_exchange_ir3: 182b8e80941Smrg atomic = ir3_ATOMIC_XCHG_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 183b8e80941Smrg break; 184b8e80941Smrg case nir_intrinsic_ssbo_atomic_comp_swap_ir3: 185b8e80941Smrg /* for cmpxchg, src0 is [ui]vec2(data, compare): */ 186b8e80941Smrg src0 = ir3_create_collect(ctx, (struct ir3_instruction*[]){ 187b8e80941Smrg ir3_get_src(ctx, &intr->src[3])[0], 188b8e80941Smrg src0, 189b8e80941Smrg }, 2); 190b8e80941Smrg src1 = ir3_get_src(ctx, &intr->src[4])[0]; 191b8e80941Smrg atomic = ir3_ATOMIC_CMPXCHG_G(b, ssbo, 0, src0, 0, src1, 0, src2, 0); 192b8e80941Smrg break; 193b8e80941Smrg default: 194b8e80941Smrg unreachable("boo"); 195b8e80941Smrg } 196b8e80941Smrg 197b8e80941Smrg atomic->cat6.iim_val = 1; 198b8e80941Smrg atomic->cat6.d = 4; 199b8e80941Smrg atomic->cat6.type = type; 200b8e80941Smrg atomic->barrier_class = IR3_BARRIER_BUFFER_W; 201b8e80941Smrg atomic->barrier_conflict = IR3_BARRIER_BUFFER_R | IR3_BARRIER_BUFFER_W; 202b8e80941Smrg 203b8e80941Smrg /* even if nothing consume the result, we can't DCE the instruction: */ 204b8e80941Smrg array_insert(b, b->keeps, atomic); 205b8e80941Smrg 206b8e80941Smrg return atomic; 207b8e80941Smrg} 208b8e80941Smrg 209b8e80941Smrgstatic struct ir3_instruction * 210b8e80941Smrgget_image_offset(struct ir3_context *ctx, const nir_variable *var, 211b8e80941Smrg struct ir3_instruction * const *coords, bool byteoff) 212b8e80941Smrg{ 213b8e80941Smrg struct ir3_block *b = ctx->block; 214b8e80941Smrg struct ir3_instruction *offset; 215b8e80941Smrg unsigned ncoords = ir3_get_image_coords(var, NULL); 216b8e80941Smrg 217b8e80941Smrg /* to calculate the byte offset (yes, uggg) we need (up to) three 218b8e80941Smrg * const values to know the bytes per pixel, and y and z stride: 219b8e80941Smrg */ 220b8e80941Smrg unsigned cb = regid(ctx->so->constbase.image_dims, 0) + 221b8e80941Smrg ctx->so->const_layout.image_dims.off[var->data.driver_location]; 222b8e80941Smrg 223b8e80941Smrg debug_assert(ctx->so->const_layout.image_dims.mask & 224b8e80941Smrg (1 << var->data.driver_location)); 225b8e80941Smrg 226b8e80941Smrg /* offset = coords.x * bytes_per_pixel: */ 227b8e80941Smrg offset = ir3_MUL_S(b, coords[0], 0, create_uniform(b, cb + 0), 0); 228b8e80941Smrg if (ncoords > 1) { 229b8e80941Smrg /* offset += coords.y * y_pitch: */ 230b8e80941Smrg offset = ir3_MAD_S24(b, create_uniform(b, cb + 1), 0, 231b8e80941Smrg coords[1], 0, offset, 0); 232b8e80941Smrg } 233b8e80941Smrg if (ncoords > 2) { 234b8e80941Smrg /* offset += coords.z * z_pitch: */ 235b8e80941Smrg offset = ir3_MAD_S24(b, create_uniform(b, cb + 2), 0, 236b8e80941Smrg coords[2], 0, offset, 0); 237b8e80941Smrg } 238b8e80941Smrg 239b8e80941Smrg if (!byteoff) { 240b8e80941Smrg /* Some cases, like atomics, seem to use dword offset instead 241b8e80941Smrg * of byte offsets.. blob just puts an extra shr.b in there 242b8e80941Smrg * in those cases: 243b8e80941Smrg */ 244b8e80941Smrg offset = ir3_SHR_B(b, offset, 0, create_immed(b, 2), 0); 245b8e80941Smrg } 246b8e80941Smrg 247b8e80941Smrg return ir3_create_collect(ctx, (struct ir3_instruction*[]){ 248b8e80941Smrg offset, 249b8e80941Smrg create_immed(b, 0), 250b8e80941Smrg }, 2); 251b8e80941Smrg} 252b8e80941Smrg 253b8e80941Smrg/* src[] = { deref, coord, sample_index, value }. const_index[] = {} */ 254b8e80941Smrgstatic void 255b8e80941Smrgemit_intrinsic_store_image(struct ir3_context *ctx, nir_intrinsic_instr *intr) 256b8e80941Smrg{ 257b8e80941Smrg struct ir3_block *b = ctx->block; 258b8e80941Smrg const nir_variable *var = nir_intrinsic_get_var(intr, 0); 259b8e80941Smrg struct ir3_instruction *stib, *offset; 260b8e80941Smrg struct ir3_instruction * const *value = ir3_get_src(ctx, &intr->src[3]); 261b8e80941Smrg struct ir3_instruction * const *coords = ir3_get_src(ctx, &intr->src[1]); 262b8e80941Smrg unsigned ncoords = ir3_get_image_coords(var, NULL); 263b8e80941Smrg unsigned slot = ir3_get_image_slot(nir_src_as_deref(intr->src[0])); 264b8e80941Smrg unsigned ibo_idx = ir3_image_to_ibo(&ctx->so->image_mapping, slot); 265b8e80941Smrg unsigned ncomp = ir3_get_num_components_for_glformat(var->data.image.format); 266b8e80941Smrg 267b8e80941Smrg /* src0 is value 268b8e80941Smrg * src1 is coords 269b8e80941Smrg * src2 is 64b byte offset 270b8e80941Smrg */ 271b8e80941Smrg 272b8e80941Smrg offset = get_image_offset(ctx, var, coords, true); 273b8e80941Smrg 274b8e80941Smrg /* NOTE: stib seems to take byte offset, but stgb.typed can be used 275b8e80941Smrg * too and takes a dword offset.. not quite sure yet why blob uses 276b8e80941Smrg * one over the other in various cases. 277b8e80941Smrg */ 278b8e80941Smrg 279b8e80941Smrg stib = ir3_STIB(b, create_immed(b, ibo_idx), 0, 280b8e80941Smrg ir3_create_collect(ctx, value, ncomp), 0, 281b8e80941Smrg ir3_create_collect(ctx, coords, ncoords), 0, 282b8e80941Smrg offset, 0); 283b8e80941Smrg stib->cat6.iim_val = ncomp; 284b8e80941Smrg stib->cat6.d = ncoords; 285b8e80941Smrg stib->cat6.type = ir3_get_image_type(var); 286b8e80941Smrg stib->cat6.typed = true; 287b8e80941Smrg stib->barrier_class = IR3_BARRIER_IMAGE_W; 288b8e80941Smrg stib->barrier_conflict = IR3_BARRIER_IMAGE_R | IR3_BARRIER_IMAGE_W; 289b8e80941Smrg 290b8e80941Smrg array_insert(b, b->keeps, stib); 291b8e80941Smrg} 292b8e80941Smrg 293b8e80941Smrg/* src[] = { deref, coord, sample_index, value, compare }. const_index[] = {} */ 294b8e80941Smrgstatic struct ir3_instruction * 295b8e80941Smrgemit_intrinsic_atomic_image(struct ir3_context *ctx, nir_intrinsic_instr *intr) 296b8e80941Smrg{ 297b8e80941Smrg struct ir3_block *b = ctx->block; 298b8e80941Smrg const nir_variable *var = nir_intrinsic_get_var(intr, 0); 299b8e80941Smrg struct ir3_instruction *atomic, *image, *src0, *src1, *src2; 300b8e80941Smrg struct ir3_instruction * const *coords = ir3_get_src(ctx, &intr->src[1]); 301b8e80941Smrg unsigned ncoords = ir3_get_image_coords(var, NULL); 302b8e80941Smrg unsigned slot = ir3_get_image_slot(nir_src_as_deref(intr->src[0])); 303b8e80941Smrg unsigned ibo_idx = ir3_image_to_ibo(&ctx->so->image_mapping, slot); 304b8e80941Smrg 305b8e80941Smrg image = create_immed(b, ibo_idx); 306b8e80941Smrg 307b8e80941Smrg /* src0 is value (or uvec2(value, compare)) 308b8e80941Smrg * src1 is coords 309b8e80941Smrg * src2 is 64b byte offset 310b8e80941Smrg */ 311b8e80941Smrg src0 = ir3_get_src(ctx, &intr->src[3])[0]; 312b8e80941Smrg src1 = ir3_create_collect(ctx, coords, ncoords); 313b8e80941Smrg src2 = get_image_offset(ctx, var, coords, false); 314b8e80941Smrg 315b8e80941Smrg switch (intr->intrinsic) { 316b8e80941Smrg case nir_intrinsic_image_deref_atomic_add: 317b8e80941Smrg atomic = ir3_ATOMIC_ADD_G(b, image, 0, src0, 0, src1, 0, src2, 0); 318b8e80941Smrg break; 319b8e80941Smrg case nir_intrinsic_image_deref_atomic_min: 320b8e80941Smrg atomic = ir3_ATOMIC_MIN_G(b, image, 0, src0, 0, src1, 0, src2, 0); 321b8e80941Smrg break; 322b8e80941Smrg case nir_intrinsic_image_deref_atomic_max: 323b8e80941Smrg atomic = ir3_ATOMIC_MAX_G(b, image, 0, src0, 0, src1, 0, src2, 0); 324b8e80941Smrg break; 325b8e80941Smrg case nir_intrinsic_image_deref_atomic_and: 326b8e80941Smrg atomic = ir3_ATOMIC_AND_G(b, image, 0, src0, 0, src1, 0, src2, 0); 327b8e80941Smrg break; 328b8e80941Smrg case nir_intrinsic_image_deref_atomic_or: 329b8e80941Smrg atomic = ir3_ATOMIC_OR_G(b, image, 0, src0, 0, src1, 0, src2, 0); 330b8e80941Smrg break; 331b8e80941Smrg case nir_intrinsic_image_deref_atomic_xor: 332b8e80941Smrg atomic = ir3_ATOMIC_XOR_G(b, image, 0, src0, 0, src1, 0, src2, 0); 333b8e80941Smrg break; 334b8e80941Smrg case nir_intrinsic_image_deref_atomic_exchange: 335b8e80941Smrg atomic = ir3_ATOMIC_XCHG_G(b, image, 0, src0, 0, src1, 0, src2, 0); 336b8e80941Smrg break; 337b8e80941Smrg case nir_intrinsic_image_deref_atomic_comp_swap: 338b8e80941Smrg /* for cmpxchg, src0 is [ui]vec2(data, compare): */ 339b8e80941Smrg src0 = ir3_create_collect(ctx, (struct ir3_instruction*[]){ 340b8e80941Smrg ir3_get_src(ctx, &intr->src[4])[0], 341b8e80941Smrg src0, 342b8e80941Smrg }, 2); 343b8e80941Smrg atomic = ir3_ATOMIC_CMPXCHG_G(b, image, 0, src0, 0, src1, 0, src2, 0); 344b8e80941Smrg break; 345b8e80941Smrg default: 346b8e80941Smrg unreachable("boo"); 347b8e80941Smrg } 348b8e80941Smrg 349b8e80941Smrg atomic->cat6.iim_val = 1; 350b8e80941Smrg atomic->cat6.d = ncoords; 351b8e80941Smrg atomic->cat6.type = ir3_get_image_type(var); 352b8e80941Smrg atomic->cat6.typed = true; 353b8e80941Smrg atomic->barrier_class = IR3_BARRIER_IMAGE_W; 354b8e80941Smrg atomic->barrier_conflict = IR3_BARRIER_IMAGE_R | IR3_BARRIER_IMAGE_W; 355b8e80941Smrg 356b8e80941Smrg /* even if nothing consume the result, we can't DCE the instruction: */ 357b8e80941Smrg array_insert(b, b->keeps, atomic); 358b8e80941Smrg 359b8e80941Smrg return atomic; 360b8e80941Smrg} 361b8e80941Smrg 362b8e80941Smrgconst struct ir3_context_funcs ir3_a4xx_funcs = { 363b8e80941Smrg .emit_intrinsic_load_ssbo = emit_intrinsic_load_ssbo, 364b8e80941Smrg .emit_intrinsic_store_ssbo = emit_intrinsic_store_ssbo, 365b8e80941Smrg .emit_intrinsic_atomic_ssbo = emit_intrinsic_atomic_ssbo, 366b8e80941Smrg .emit_intrinsic_store_image = emit_intrinsic_store_image, 367b8e80941Smrg .emit_intrinsic_atomic_image = emit_intrinsic_atomic_image, 368b8e80941Smrg}; 369