/* * Copyright © 2017 Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ /** * @file iris_program.c * * This file contains the driver interface for compiling shaders. * * See iris_program_cache.c for the in-memory program cache where the * compiled shaders are stored. */ #include #include #include "pipe/p_defines.h" #include "pipe/p_state.h" #include "pipe/p_context.h" #include "pipe/p_screen.h" #include "util/u_atomic.h" #include "compiler/nir/nir.h" #include "compiler/nir/nir_builder.h" #include "intel/compiler/brw_compiler.h" #include "intel/compiler/brw_nir.h" #include "iris_context.h" #define KEY_INIT_NO_ID \ .tex.swizzles[0 ... MAX_SAMPLERS - 1] = 0x688, \ .tex.compressed_multisample_layout_mask = ~0, \ .tex.msaa_16 = ~0 #define KEY_INIT .program_string_id = ish->program_id, KEY_INIT_NO_ID static unsigned get_new_program_id(struct iris_screen *screen) { return p_atomic_inc_return(&screen->program_id); } /** * An uncompiled, API-facing shader. This is the Gallium CSO for shaders. * It primarily contains the NIR for the shader. * * Each API-facing shader can be compiled into multiple shader variants, * based on non-orthogonal state dependencies, recorded in the shader key. * * See iris_compiled_shader, which represents a compiled shader variant. */ struct iris_uncompiled_shader { nir_shader *nir; struct pipe_stream_output_info stream_output; unsigned program_id; /** Bitfield of (1 << IRIS_NOS_*) flags. */ unsigned nos; /** Have any shader variants been compiled yet? */ bool compiled_once; }; static nir_ssa_def * get_aoa_deref_offset(nir_builder *b, nir_deref_instr *deref, unsigned elem_size) { unsigned array_size = elem_size; nir_ssa_def *offset = nir_imm_int(b, 0); while (deref->deref_type != nir_deref_type_var) { assert(deref->deref_type == nir_deref_type_array); /* This level's element size is the previous level's array size */ nir_ssa_def *index = nir_ssa_for_src(b, deref->arr.index, 1); assert(deref->arr.index.ssa); offset = nir_iadd(b, offset, nir_imul(b, index, nir_imm_int(b, array_size))); deref = nir_deref_instr_parent(deref); assert(glsl_type_is_array(deref->type)); array_size *= glsl_get_length(deref->type); } /* Accessing an invalid surface index with the dataport can result in a * hang. According to the spec "if the index used to select an individual * element is negative or greater than or equal to the size of the array, * the results of the operation are undefined but may not lead to * termination" -- which is one of the possible outcomes of the hang. * Clamp the index to prevent access outside of the array bounds. */ return nir_umin(b, offset, nir_imm_int(b, array_size - elem_size)); } static void iris_lower_storage_image_derefs(nir_shader *nir) { nir_function_impl *impl = nir_shader_get_entrypoint(nir); nir_builder b; nir_builder_init(&b, impl); nir_foreach_block(block, impl) { nir_foreach_instr_safe(instr, block) { if (instr->type != nir_instr_type_intrinsic) continue; nir_intrinsic_instr *intrin = nir_instr_as_intrinsic(instr); switch (intrin->intrinsic) { case nir_intrinsic_image_deref_load: case nir_intrinsic_image_deref_store: case nir_intrinsic_image_deref_atomic_add: case nir_intrinsic_image_deref_atomic_min: case nir_intrinsic_image_deref_atomic_max: case nir_intrinsic_image_deref_atomic_and: case nir_intrinsic_image_deref_atomic_or: case nir_intrinsic_image_deref_atomic_xor: case nir_intrinsic_image_deref_atomic_exchange: case nir_intrinsic_image_deref_atomic_comp_swap: case nir_intrinsic_image_deref_size: case nir_intrinsic_image_deref_samples: case nir_intrinsic_image_deref_load_raw_intel: case nir_intrinsic_image_deref_store_raw_intel: { nir_deref_instr *deref = nir_src_as_deref(intrin->src[0]); nir_variable *var = nir_deref_instr_get_variable(deref); b.cursor = nir_before_instr(&intrin->instr); nir_ssa_def *index = nir_iadd(&b, nir_imm_int(&b, var->data.driver_location), get_aoa_deref_offset(&b, deref, 1)); brw_nir_rewrite_image_intrinsic(intrin, index); break; } default: break; } } } } // XXX: need unify_interfaces() at link time... /** * Fix an uncompiled shader's stream output info. * * Core Gallium stores output->register_index as a "slot" number, where * slots are assigned consecutively to all outputs in info->outputs_written. * This naive packing of outputs doesn't work for us - we too have slots, * but the layout is defined by the VUE map, which we won't have until we * compile a specific shader variant. So, we remap these and simply store * VARYING_SLOT_* in our copy's output->register_index fields. * * We also fix up VARYING_SLOT_{LAYER,VIEWPORT,PSIZ} to select the Y/Z/W * components of our VUE header. See brw_vue_map.c for the layout. */ static void update_so_info(struct pipe_stream_output_info *so_info, uint64_t outputs_written) { uint8_t reverse_map[64] = {}; unsigned slot = 0; while (outputs_written) { reverse_map[slot++] = u_bit_scan64(&outputs_written); } for (unsigned i = 0; i < so_info->num_outputs; i++) { struct pipe_stream_output *output = &so_info->output[i]; /* Map Gallium's condensed "slots" back to real VARYING_SLOT_* enums */ output->register_index = reverse_map[output->register_index]; /* The VUE header contains three scalar fields packed together: * - gl_PointSize is stored in VARYING_SLOT_PSIZ.w * - gl_Layer is stored in VARYING_SLOT_PSIZ.y * - gl_ViewportIndex is stored in VARYING_SLOT_PSIZ.z */ switch (output->register_index) { case VARYING_SLOT_LAYER: assert(output->num_components == 1); output->register_index = VARYING_SLOT_PSIZ; output->start_component = 1; break; case VARYING_SLOT_VIEWPORT: assert(output->num_components == 1); output->register_index = VARYING_SLOT_PSIZ; output->start_component = 2; break; case VARYING_SLOT_PSIZ: assert(output->num_components == 1); output->start_component = 3; break; } //info->outputs_written |= 1ull << output->register_index; } } /** * Sets up the starting offsets for the groups of binding table entries * common to all pipeline stages. * * Unused groups are initialized to 0xd0d0d0d0 to make it obvious that they're * unused but also make sure that addition of small offsets to them will * trigger some of our asserts that surface indices are < BRW_MAX_SURFACES. */ static uint32_t assign_common_binding_table_offsets(const struct gen_device_info *devinfo, const struct nir_shader *nir, struct brw_stage_prog_data *prog_data, uint32_t next_binding_table_offset, unsigned num_system_values, unsigned num_cbufs) { const struct shader_info *info = &nir->info; unsigned num_textures = util_last_bit(info->textures_used); if (num_textures) { prog_data->binding_table.texture_start = next_binding_table_offset; prog_data->binding_table.gather_texture_start = next_binding_table_offset; next_binding_table_offset += num_textures; } else { prog_data->binding_table.texture_start = 0xd0d0d0d0; prog_data->binding_table.gather_texture_start = 0xd0d0d0d0; } if (info->num_images) { prog_data->binding_table.image_start = next_binding_table_offset; next_binding_table_offset += info->num_images; } else { prog_data->binding_table.image_start = 0xd0d0d0d0; } if (num_cbufs) { //assert(info->num_ubos <= BRW_MAX_UBO); prog_data->binding_table.ubo_start = next_binding_table_offset; next_binding_table_offset += num_cbufs; } else { prog_data->binding_table.ubo_start = 0xd0d0d0d0; } if (info->num_ssbos || info->num_abos) { prog_data->binding_table.ssbo_start = next_binding_table_offset; // XXX: see iris_state "wasting 16 binding table slots for ABOs" comment next_binding_table_offset += IRIS_MAX_ABOS + info->num_ssbos; } else { prog_data->binding_table.ssbo_start = 0xd0d0d0d0; } prog_data->binding_table.shader_time_start = 0xd0d0d0d0; /* Plane 0 is just the regular texture section */ prog_data->binding_table.plane_start[0] = prog_data->binding_table.texture_start; prog_data->binding_table.plane_start[1] = next_binding_table_offset; next_binding_table_offset += num_textures; prog_data->binding_table.plane_start[2] = next_binding_table_offset; next_binding_table_offset += num_textures; /* Set the binding table size */ prog_data->binding_table.size_bytes = next_binding_table_offset * 4; return next_binding_table_offset; } static void setup_vec4_image_sysval(uint32_t *sysvals, uint32_t idx, unsigned offset, unsigned n) { assert(offset % sizeof(uint32_t) == 0); for (unsigned i = 0; i < n; ++i) sysvals[i] = BRW_PARAM_IMAGE(idx, offset / sizeof(uint32_t) + i); for (unsigned i = n; i < 4; ++i) sysvals[i] = BRW_PARAM_BUILTIN_ZERO; } /** * Associate NIR uniform variables with the prog_data->param[] mechanism * used by the backend. Also, decide which UBOs we'd like to push in an * ideal situation (though the backend can reduce this). */ static void iris_setup_uniforms(const struct brw_compiler *compiler, void *mem_ctx, nir_shader *nir, struct brw_stage_prog_data *prog_data, enum brw_param_builtin **out_system_values, unsigned *out_num_system_values, unsigned *out_num_cbufs) { const struct gen_device_info *devinfo = compiler->devinfo; /* The intel compiler assumes that num_uniforms is in bytes. For * scalar that means 4 bytes per uniform slot. * * Ref: brw_nir_lower_uniforms, type_size_scalar_bytes. */ nir->num_uniforms *= 4; const unsigned IRIS_MAX_SYSTEM_VALUES = PIPE_MAX_SHADER_IMAGES * BRW_IMAGE_PARAM_SIZE; enum brw_param_builtin *system_values = rzalloc_array(mem_ctx, enum brw_param_builtin, IRIS_MAX_SYSTEM_VALUES); unsigned num_system_values = 0; unsigned patch_vert_idx = -1; unsigned ucp_idx[IRIS_MAX_CLIP_PLANES]; unsigned img_idx[PIPE_MAX_SHADER_IMAGES]; memset(ucp_idx, -1, sizeof(ucp_idx)); memset(img_idx, -1, sizeof(img_idx)); nir_function_impl *impl = nir_shader_get_entrypoint(nir); nir_builder b; nir_builder_init(&b, impl); b.cursor = nir_before_block(nir_start_block(impl)); nir_ssa_def *temp_ubo_name = nir_ssa_undef(&b, 1, 32); /* Turn system value intrinsics into uniforms */ nir_foreach_block(block, impl) { nir_foreach_instr_safe(instr, block) { if (instr->type != nir_instr_type_intrinsic) continue; nir_intrinsic_instr *intrin = nir_instr_as_intrinsic(instr); nir_ssa_def *offset; switch (intrin->intrinsic) { case nir_intrinsic_load_user_clip_plane: { unsigned ucp = nir_intrinsic_ucp_id(intrin); if (ucp_idx[ucp] == -1) { ucp_idx[ucp] = num_system_values; num_system_values += 4; } for (int i = 0; i < 4; i++) { system_values[ucp_idx[ucp] + i] = BRW_PARAM_BUILTIN_CLIP_PLANE(ucp, i); } b.cursor = nir_before_instr(instr); offset = nir_imm_int(&b, ucp_idx[ucp] * sizeof(uint32_t)); break; } case nir_intrinsic_load_patch_vertices_in: if (patch_vert_idx == -1) patch_vert_idx = num_system_values++; system_values[patch_vert_idx] = BRW_PARAM_BUILTIN_PATCH_VERTICES_IN; b.cursor = nir_before_instr(instr); offset = nir_imm_int(&b, patch_vert_idx * sizeof(uint32_t)); break; case nir_intrinsic_image_deref_load_param_intel: { assert(devinfo->gen < 9); nir_deref_instr *deref = nir_src_as_deref(intrin->src[0]); nir_variable *var = nir_deref_instr_get_variable(deref); /* XXX: var->data.binding is not set properly. We need to run * some form of gl_nir_lower_samplers_as_deref() to get it. * This breaks tests which use more than one image. */ if (img_idx[var->data.binding] == -1) { /* GL only allows arrays of arrays of images. */ assert(glsl_type_is_image(glsl_without_array(var->type))); unsigned num_images = MAX2(1, glsl_get_aoa_size(var->type)); for (int i = 0; i < num_images; i++) { const unsigned img = var->data.binding + i; img_idx[img] = num_system_values; num_system_values += BRW_IMAGE_PARAM_SIZE; uint32_t *img_sv = &system_values[img_idx[img]]; setup_vec4_image_sysval( img_sv + BRW_IMAGE_PARAM_OFFSET_OFFSET, img, offsetof(struct brw_image_param, offset), 2); setup_vec4_image_sysval( img_sv + BRW_IMAGE_PARAM_SIZE_OFFSET, img, offsetof(struct brw_image_param, size), 3); setup_vec4_image_sysval( img_sv + BRW_IMAGE_PARAM_STRIDE_OFFSET, img, offsetof(struct brw_image_param, stride), 4); setup_vec4_image_sysval( img_sv + BRW_IMAGE_PARAM_TILING_OFFSET, img, offsetof(struct brw_image_param, tiling), 3); setup_vec4_image_sysval( img_sv + BRW_IMAGE_PARAM_SWIZZLING_OFFSET, img, offsetof(struct brw_image_param, swizzling), 2); } } b.cursor = nir_before_instr(instr); offset = nir_iadd(&b, get_aoa_deref_offset(&b, deref, BRW_IMAGE_PARAM_SIZE * 4), nir_imm_int(&b, img_idx[var->data.binding] * 4 + nir_intrinsic_base(intrin) * 16)); break; } default: continue; } unsigned comps = nir_intrinsic_dest_components(intrin); nir_intrinsic_instr *load = nir_intrinsic_instr_create(nir, nir_intrinsic_load_ubo); load->num_components = comps; load->src[0] = nir_src_for_ssa(temp_ubo_name); load->src[1] = nir_src_for_ssa(offset); nir_ssa_dest_init(&load->instr, &load->dest, comps, 32, NULL); nir_builder_instr_insert(&b, &load->instr); nir_ssa_def_rewrite_uses(&intrin->dest.ssa, nir_src_for_ssa(&load->dest.ssa)); nir_instr_remove(instr); } } nir_validate_shader(nir, "before remapping"); /* Place the new params at the front of constant buffer 0. */ if (num_system_values > 0) { nir->num_uniforms += num_system_values * sizeof(uint32_t); system_values = reralloc(mem_ctx, system_values, enum brw_param_builtin, num_system_values); nir_foreach_block(block, impl) { nir_foreach_instr_safe(instr, block) { if (instr->type != nir_instr_type_intrinsic) continue; nir_intrinsic_instr *load = nir_instr_as_intrinsic(instr); if (load->intrinsic != nir_intrinsic_load_ubo) continue; b.cursor = nir_before_instr(instr); assert(load->src[0].is_ssa); if (load->src[0].ssa == temp_ubo_name) { nir_instr_rewrite_src(instr, &load->src[0], nir_src_for_ssa(nir_imm_int(&b, 0))); } else if (nir_src_as_uint(load->src[0]) == 0) { nir_ssa_def *offset = nir_iadd(&b, load->src[1].ssa, nir_imm_int(&b, 4 * num_system_values)); nir_instr_rewrite_src(instr, &load->src[1], nir_src_for_ssa(offset)); } } } /* We need to fold the new iadds for brw_nir_analyze_ubo_ranges */ nir_opt_constant_folding(nir); } else { ralloc_free(system_values); system_values = NULL; } nir_validate_shader(nir, "after remap"); if (nir->info.stage != MESA_SHADER_COMPUTE) brw_nir_analyze_ubo_ranges(compiler, nir, NULL, prog_data->ubo_ranges); /* We don't use params[], but fs_visitor::nir_setup_uniforms() asserts * about it for compute shaders, so go ahead and make some fake ones * which the backend will dead code eliminate. */ prog_data->nr_params = nir->num_uniforms / 4; prog_data->param = rzalloc_array(mem_ctx, uint32_t, prog_data->nr_params); /* System values and uniforms are stored in constant buffer 0, the * user-facing UBOs are indexed by one. So if any constant buffer is * needed, the constant buffer 0 will be needed, so account for it. */ unsigned num_cbufs = nir->info.num_ubos; if (num_cbufs || num_system_values || nir->num_uniforms) num_cbufs++; *out_system_values = system_values; *out_num_system_values = num_system_values; *out_num_cbufs = num_cbufs; } /** * Compile a vertex shader, and upload the assembly. */ static struct iris_compiled_shader * iris_compile_vs(struct iris_context *ice, struct iris_uncompiled_shader *ish, const struct brw_vs_prog_key *key) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; const struct brw_compiler *compiler = screen->compiler; const struct gen_device_info *devinfo = &screen->devinfo; void *mem_ctx = ralloc_context(NULL); struct brw_vs_prog_data *vs_prog_data = rzalloc(mem_ctx, struct brw_vs_prog_data); struct brw_vue_prog_data *vue_prog_data = &vs_prog_data->base; struct brw_stage_prog_data *prog_data = &vue_prog_data->base; enum brw_param_builtin *system_values; unsigned num_system_values; unsigned num_cbufs; nir_shader *nir = nir_shader_clone(mem_ctx, ish->nir); if (key->nr_userclip_plane_consts) { nir_function_impl *impl = nir_shader_get_entrypoint(nir); nir_lower_clip_vs(nir, (1 << key->nr_userclip_plane_consts) - 1, true); nir_lower_io_to_temporaries(nir, impl, true, false); nir_lower_global_vars_to_local(nir); nir_lower_vars_to_ssa(nir); nir_shader_gather_info(nir, impl); } if (nir->info.name && strncmp(nir->info.name, "ARB", 3) == 0) prog_data->use_alt_mode = true; iris_setup_uniforms(compiler, mem_ctx, nir, prog_data, &system_values, &num_system_values, &num_cbufs); assign_common_binding_table_offsets(devinfo, nir, prog_data, 0, num_system_values, num_cbufs); brw_compute_vue_map(devinfo, &vue_prog_data->vue_map, nir->info.outputs_written, nir->info.separate_shader); /* Don't tell the backend about our clip plane constants, we've already * lowered them in NIR and we don't want it doing it again. */ struct brw_vs_prog_key key_no_ucp = *key; key_no_ucp.nr_userclip_plane_consts = 0; char *error_str = NULL; const unsigned *program = brw_compile_vs(compiler, &ice->dbg, mem_ctx, &key_no_ucp, vs_prog_data, nir, -1, &error_str); if (program == NULL) { dbg_printf("Failed to compile vertex shader: %s\n", error_str); ralloc_free(mem_ctx); return false; } uint32_t *so_decls = ice->vtbl.create_so_decl_list(&ish->stream_output, &vue_prog_data->vue_map); struct iris_compiled_shader *shader = iris_upload_shader(ice, IRIS_CACHE_VS, sizeof(*key), key, program, prog_data, so_decls, system_values, num_system_values, num_cbufs); if (ish->compiled_once) { perf_debug(&ice->dbg, "Recompiling vertex shader\n"); } else { ish->compiled_once = true; } ralloc_free(mem_ctx); return shader; } /** * Update the current vertex shader variant. * * Fill out the key, look in the cache, compile and bind if needed. */ static void iris_update_compiled_vs(struct iris_context *ice) { struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[MESA_SHADER_VERTEX]; struct brw_vs_prog_key key = { KEY_INIT }; ice->vtbl.populate_vs_key(ice, &ish->nir->info, &key); struct iris_compiled_shader *old = ice->shaders.prog[IRIS_CACHE_VS]; struct iris_compiled_shader *shader = iris_find_cached_shader(ice, IRIS_CACHE_VS, sizeof(key), &key); if (!shader) shader = iris_compile_vs(ice, ish, &key); if (old != shader) { ice->shaders.prog[IRIS_CACHE_VS] = shader; ice->state.dirty |= IRIS_DIRTY_VS | IRIS_DIRTY_BINDINGS_VS | IRIS_DIRTY_CONSTANTS_VS | IRIS_DIRTY_VF_SGVS; } } /** * Get the shader_info for a given stage, or NULL if the stage is disabled. */ const struct shader_info * iris_get_shader_info(const struct iris_context *ice, gl_shader_stage stage) { const struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[stage]; if (!ish) return NULL; const nir_shader *nir = ish->nir; return &nir->info; } /** * Get the union of TCS output and TES input slots. * * TCS and TES need to agree on a common URB entry layout. In particular, * the data for all patch vertices is stored in a single URB entry (unlike * GS which has one entry per input vertex). This means that per-vertex * array indexing needs a stride. * * SSO requires locations to match, but doesn't require the number of * outputs/inputs to match (in fact, the TCS often has extra outputs). * So, we need to take the extra step of unifying these on the fly. */ static void get_unified_tess_slots(const struct iris_context *ice, uint64_t *per_vertex_slots, uint32_t *per_patch_slots) { const struct shader_info *tcs = iris_get_shader_info(ice, MESA_SHADER_TESS_CTRL); const struct shader_info *tes = iris_get_shader_info(ice, MESA_SHADER_TESS_EVAL); *per_vertex_slots = tes->inputs_read; *per_patch_slots = tes->patch_inputs_read; if (tcs) { *per_vertex_slots |= tcs->outputs_written; *per_patch_slots |= tcs->patch_outputs_written; } } /** * Compile a tessellation control shader, and upload the assembly. */ static struct iris_compiled_shader * iris_compile_tcs(struct iris_context *ice, struct iris_uncompiled_shader *ish, const struct brw_tcs_prog_key *key) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; const struct brw_compiler *compiler = screen->compiler; const struct nir_shader_compiler_options *options = compiler->glsl_compiler_options[MESA_SHADER_TESS_CTRL].NirOptions; const struct gen_device_info *devinfo = &screen->devinfo; void *mem_ctx = ralloc_context(NULL); struct brw_tcs_prog_data *tcs_prog_data = rzalloc(mem_ctx, struct brw_tcs_prog_data); struct brw_vue_prog_data *vue_prog_data = &tcs_prog_data->base; struct brw_stage_prog_data *prog_data = &vue_prog_data->base; enum brw_param_builtin *system_values = NULL; unsigned num_system_values = 0; unsigned num_cbufs; nir_shader *nir; if (ish) { nir = nir_shader_clone(mem_ctx, ish->nir); iris_setup_uniforms(compiler, mem_ctx, nir, prog_data, &system_values, &num_system_values, &num_cbufs); assign_common_binding_table_offsets(devinfo, nir, prog_data, 0, num_system_values, num_cbufs); } else { nir = brw_nir_create_passthrough_tcs(mem_ctx, compiler, options, key); /* Reserve space for passing the default tess levels as constants. */ prog_data->param = rzalloc_array(mem_ctx, uint32_t, 8); prog_data->nr_params = 8; prog_data->ubo_ranges[0].length = 1; } char *error_str = NULL; const unsigned *program = brw_compile_tcs(compiler, &ice->dbg, mem_ctx, key, tcs_prog_data, nir, -1, &error_str); if (program == NULL) { dbg_printf("Failed to compile control shader: %s\n", error_str); ralloc_free(mem_ctx); return false; } struct iris_compiled_shader *shader = iris_upload_shader(ice, IRIS_CACHE_TCS, sizeof(*key), key, program, prog_data, NULL, system_values, num_system_values, num_cbufs); if (ish) { if (ish->compiled_once) { perf_debug(&ice->dbg, "Recompiling tessellation control shader\n"); } else { ish->compiled_once = true; } } ralloc_free(mem_ctx); return shader; } /** * Update the current tessellation control shader variant. * * Fill out the key, look in the cache, compile and bind if needed. */ static void iris_update_compiled_tcs(struct iris_context *ice) { struct iris_uncompiled_shader *tcs = ice->shaders.uncompiled[MESA_SHADER_TESS_CTRL]; const struct shader_info *tes_info = iris_get_shader_info(ice, MESA_SHADER_TESS_EVAL); struct brw_tcs_prog_key key = { KEY_INIT_NO_ID, .program_string_id = tcs ? tcs->program_id : 0, .tes_primitive_mode = tes_info->tess.primitive_mode, .input_vertices = ice->state.vertices_per_patch, }; get_unified_tess_slots(ice, &key.outputs_written, &key.patch_outputs_written); ice->vtbl.populate_tcs_key(ice, &key); struct iris_compiled_shader *old = ice->shaders.prog[IRIS_CACHE_TCS]; struct iris_compiled_shader *shader = iris_find_cached_shader(ice, IRIS_CACHE_TCS, sizeof(key), &key); if (!shader) shader = iris_compile_tcs(ice, tcs, &key); if (old != shader) { ice->shaders.prog[IRIS_CACHE_TCS] = shader; ice->state.dirty |= IRIS_DIRTY_TCS | IRIS_DIRTY_BINDINGS_TCS | IRIS_DIRTY_CONSTANTS_TCS; } } /** * Compile a tessellation evaluation shader, and upload the assembly. */ static struct iris_compiled_shader * iris_compile_tes(struct iris_context *ice, struct iris_uncompiled_shader *ish, const struct brw_tes_prog_key *key) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; const struct brw_compiler *compiler = screen->compiler; const struct gen_device_info *devinfo = &screen->devinfo; void *mem_ctx = ralloc_context(NULL); struct brw_tes_prog_data *tes_prog_data = rzalloc(mem_ctx, struct brw_tes_prog_data); struct brw_vue_prog_data *vue_prog_data = &tes_prog_data->base; struct brw_stage_prog_data *prog_data = &vue_prog_data->base; enum brw_param_builtin *system_values; unsigned num_system_values; unsigned num_cbufs; nir_shader *nir = nir_shader_clone(mem_ctx, ish->nir); iris_setup_uniforms(compiler, mem_ctx, nir, prog_data, &system_values, &num_system_values, &num_cbufs); assign_common_binding_table_offsets(devinfo, nir, prog_data, 0, num_system_values, num_cbufs); struct brw_vue_map input_vue_map; brw_compute_tess_vue_map(&input_vue_map, key->inputs_read, key->patch_inputs_read); char *error_str = NULL; const unsigned *program = brw_compile_tes(compiler, &ice->dbg, mem_ctx, key, &input_vue_map, tes_prog_data, nir, NULL, -1, &error_str); if (program == NULL) { dbg_printf("Failed to compile evaluation shader: %s\n", error_str); ralloc_free(mem_ctx); return false; } uint32_t *so_decls = ice->vtbl.create_so_decl_list(&ish->stream_output, &vue_prog_data->vue_map); struct iris_compiled_shader *shader = iris_upload_shader(ice, IRIS_CACHE_TES, sizeof(*key), key, program, prog_data, so_decls, system_values, num_system_values, num_cbufs); if (ish->compiled_once) { perf_debug(&ice->dbg, "Recompiling tessellation evaluation shader\n"); } else { ish->compiled_once = true; } ralloc_free(mem_ctx); return shader; } /** * Update the current tessellation evaluation shader variant. * * Fill out the key, look in the cache, compile and bind if needed. */ static void iris_update_compiled_tes(struct iris_context *ice) { struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[MESA_SHADER_TESS_EVAL]; struct brw_tes_prog_key key = { KEY_INIT }; get_unified_tess_slots(ice, &key.inputs_read, &key.patch_inputs_read); ice->vtbl.populate_tes_key(ice, &key); struct iris_compiled_shader *old = ice->shaders.prog[IRIS_CACHE_TES]; struct iris_compiled_shader *shader = iris_find_cached_shader(ice, IRIS_CACHE_TES, sizeof(key), &key); if (!shader) shader = iris_compile_tes(ice, ish, &key); if (old != shader) { ice->shaders.prog[IRIS_CACHE_TES] = shader; ice->state.dirty |= IRIS_DIRTY_TES | IRIS_DIRTY_BINDINGS_TES | IRIS_DIRTY_CONSTANTS_TES; } } /** * Compile a geometry shader, and upload the assembly. */ static struct iris_compiled_shader * iris_compile_gs(struct iris_context *ice, struct iris_uncompiled_shader *ish, const struct brw_gs_prog_key *key) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; const struct brw_compiler *compiler = screen->compiler; const struct gen_device_info *devinfo = &screen->devinfo; void *mem_ctx = ralloc_context(NULL); struct brw_gs_prog_data *gs_prog_data = rzalloc(mem_ctx, struct brw_gs_prog_data); struct brw_vue_prog_data *vue_prog_data = &gs_prog_data->base; struct brw_stage_prog_data *prog_data = &vue_prog_data->base; enum brw_param_builtin *system_values; unsigned num_system_values; unsigned num_cbufs; nir_shader *nir = nir_shader_clone(mem_ctx, ish->nir); iris_setup_uniforms(compiler, mem_ctx, nir, prog_data, &system_values, &num_system_values, &num_cbufs); assign_common_binding_table_offsets(devinfo, nir, prog_data, 0, num_system_values, num_cbufs); brw_compute_vue_map(devinfo, &vue_prog_data->vue_map, nir->info.outputs_written, nir->info.separate_shader); char *error_str = NULL; const unsigned *program = brw_compile_gs(compiler, &ice->dbg, mem_ctx, key, gs_prog_data, nir, NULL, -1, &error_str); if (program == NULL) { dbg_printf("Failed to compile geometry shader: %s\n", error_str); ralloc_free(mem_ctx); return false; } uint32_t *so_decls = ice->vtbl.create_so_decl_list(&ish->stream_output, &vue_prog_data->vue_map); struct iris_compiled_shader *shader = iris_upload_shader(ice, IRIS_CACHE_GS, sizeof(*key), key, program, prog_data, so_decls, system_values, num_system_values, num_cbufs); if (ish->compiled_once) { perf_debug(&ice->dbg, "Recompiling geometry shader\n"); } else { ish->compiled_once = true; } ralloc_free(mem_ctx); return shader; } /** * Update the current geometry shader variant. * * Fill out the key, look in the cache, compile and bind if needed. */ static void iris_update_compiled_gs(struct iris_context *ice) { struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[MESA_SHADER_GEOMETRY]; struct iris_compiled_shader *old = ice->shaders.prog[IRIS_CACHE_GS]; struct iris_compiled_shader *shader = NULL; if (ish) { struct brw_gs_prog_key key = { KEY_INIT }; ice->vtbl.populate_gs_key(ice, &key); shader = iris_find_cached_shader(ice, IRIS_CACHE_GS, sizeof(key), &key); if (!shader) shader = iris_compile_gs(ice, ish, &key); } if (old != shader) { ice->shaders.prog[IRIS_CACHE_GS] = shader; ice->state.dirty |= IRIS_DIRTY_GS | IRIS_DIRTY_BINDINGS_GS | IRIS_DIRTY_CONSTANTS_GS; } } /** * Compile a fragment (pixel) shader, and upload the assembly. */ static struct iris_compiled_shader * iris_compile_fs(struct iris_context *ice, struct iris_uncompiled_shader *ish, const struct brw_wm_prog_key *key, struct brw_vue_map *vue_map) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; const struct brw_compiler *compiler = screen->compiler; const struct gen_device_info *devinfo = &screen->devinfo; void *mem_ctx = ralloc_context(NULL); struct brw_wm_prog_data *fs_prog_data = rzalloc(mem_ctx, struct brw_wm_prog_data); struct brw_stage_prog_data *prog_data = &fs_prog_data->base; enum brw_param_builtin *system_values; unsigned num_system_values; unsigned num_cbufs; nir_shader *nir = nir_shader_clone(mem_ctx, ish->nir); if (nir->info.name && strncmp(nir->info.name, "ARB", 3) == 0) prog_data->use_alt_mode = true; iris_setup_uniforms(compiler, mem_ctx, nir, prog_data, &system_values, &num_system_values, &num_cbufs); assign_common_binding_table_offsets(devinfo, nir, prog_data, MAX2(key->nr_color_regions, 1), num_system_values, num_cbufs); char *error_str = NULL; const unsigned *program = brw_compile_fs(compiler, &ice->dbg, mem_ctx, key, fs_prog_data, nir, NULL, -1, -1, -1, true, false, vue_map, &error_str); if (program == NULL) { dbg_printf("Failed to compile fragment shader: %s\n", error_str); ralloc_free(mem_ctx); return false; } struct iris_compiled_shader *shader = iris_upload_shader(ice, IRIS_CACHE_FS, sizeof(*key), key, program, prog_data, NULL, system_values, num_system_values, num_cbufs); if (ish->compiled_once) { perf_debug(&ice->dbg, "Recompiling fragment shader\n"); } else { ish->compiled_once = true; } ralloc_free(mem_ctx); return shader; } /** * Update the current fragment shader variant. * * Fill out the key, look in the cache, compile and bind if needed. */ static void iris_update_compiled_fs(struct iris_context *ice) { struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[MESA_SHADER_FRAGMENT]; struct brw_wm_prog_key key = { KEY_INIT }; ice->vtbl.populate_fs_key(ice, &key); if (ish->nos & (1ull << IRIS_NOS_LAST_VUE_MAP)) key.input_slots_valid = ice->shaders.last_vue_map->slots_valid; struct iris_compiled_shader *old = ice->shaders.prog[IRIS_CACHE_FS]; struct iris_compiled_shader *shader = iris_find_cached_shader(ice, IRIS_CACHE_FS, sizeof(key), &key); if (!shader) shader = iris_compile_fs(ice, ish, &key, ice->shaders.last_vue_map); if (old != shader) { // XXX: only need to flag CLIP if barycentric has NONPERSPECTIVE // toggles. might be able to avoid flagging SBE too. ice->shaders.prog[IRIS_CACHE_FS] = shader; ice->state.dirty |= IRIS_DIRTY_FS | IRIS_DIRTY_BINDINGS_FS | IRIS_DIRTY_CONSTANTS_FS | IRIS_DIRTY_WM | IRIS_DIRTY_CLIP | IRIS_DIRTY_SBE; } } /** * Get the compiled shader for the last enabled geometry stage. * * This stage is the one which will feed stream output and the rasterizer. */ static gl_shader_stage last_vue_stage(struct iris_context *ice) { if (ice->shaders.prog[MESA_SHADER_GEOMETRY]) return MESA_SHADER_GEOMETRY; if (ice->shaders.prog[MESA_SHADER_TESS_EVAL]) return MESA_SHADER_TESS_EVAL; return MESA_SHADER_VERTEX; } /** * Update the last enabled stage's VUE map. * * When the shader feeding the rasterizer's output interface changes, we * need to re-emit various packets. */ static void update_last_vue_map(struct iris_context *ice, struct brw_stage_prog_data *prog_data) { struct brw_vue_prog_data *vue_prog_data = (void *) prog_data; struct brw_vue_map *vue_map = &vue_prog_data->vue_map; struct brw_vue_map *old_map = ice->shaders.last_vue_map; const uint64_t changed_slots = (old_map ? old_map->slots_valid : 0ull) ^ vue_map->slots_valid; if (changed_slots & VARYING_BIT_VIEWPORT) { // XXX: could use ctx->Const.MaxViewports for old API efficiency ice->state.num_viewports = (vue_map->slots_valid & VARYING_BIT_VIEWPORT) ? IRIS_MAX_VIEWPORTS : 1; ice->state.dirty |= IRIS_DIRTY_CLIP | IRIS_DIRTY_SF_CL_VIEWPORT | IRIS_DIRTY_CC_VIEWPORT | IRIS_DIRTY_SCISSOR_RECT | IRIS_DIRTY_UNCOMPILED_FS | ice->state.dirty_for_nos[IRIS_NOS_LAST_VUE_MAP]; // XXX: CC_VIEWPORT? } if (changed_slots || (old_map && old_map->separate != vue_map->separate)) { ice->state.dirty |= IRIS_DIRTY_SBE; } ice->shaders.last_vue_map = &vue_prog_data->vue_map; } /** * Get the prog_data for a given stage, or NULL if the stage is disabled. */ static struct brw_vue_prog_data * get_vue_prog_data(struct iris_context *ice, gl_shader_stage stage) { if (!ice->shaders.prog[stage]) return NULL; return (void *) ice->shaders.prog[stage]->prog_data; } // XXX: iris_compiled_shaders are space-leaking :( // XXX: do remember to unbind them if deleting them. /** * Update the current shader variants for the given state. * * This should be called on every draw call to ensure that the correct * shaders are bound. It will also flag any dirty state triggered by * swapping out those shaders. */ void iris_update_compiled_shaders(struct iris_context *ice) { const uint64_t dirty = ice->state.dirty; struct brw_vue_prog_data *old_prog_datas[4]; if (!(dirty & IRIS_DIRTY_URB)) { for (int i = MESA_SHADER_VERTEX; i <= MESA_SHADER_GEOMETRY; i++) old_prog_datas[i] = get_vue_prog_data(ice, i); } if (dirty & (IRIS_DIRTY_UNCOMPILED_TCS | IRIS_DIRTY_UNCOMPILED_TES)) { struct iris_uncompiled_shader *tes = ice->shaders.uncompiled[MESA_SHADER_TESS_EVAL]; if (tes) { iris_update_compiled_tcs(ice); iris_update_compiled_tes(ice); } else { ice->shaders.prog[IRIS_CACHE_TCS] = NULL; ice->shaders.prog[IRIS_CACHE_TES] = NULL; ice->state.dirty |= IRIS_DIRTY_TCS | IRIS_DIRTY_TES | IRIS_DIRTY_BINDINGS_TCS | IRIS_DIRTY_BINDINGS_TES | IRIS_DIRTY_CONSTANTS_TCS | IRIS_DIRTY_CONSTANTS_TES; } } if (dirty & IRIS_DIRTY_UNCOMPILED_VS) iris_update_compiled_vs(ice); if (dirty & IRIS_DIRTY_UNCOMPILED_GS) iris_update_compiled_gs(ice); gl_shader_stage last_stage = last_vue_stage(ice); struct iris_compiled_shader *shader = ice->shaders.prog[last_stage]; struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[last_stage]; update_last_vue_map(ice, shader->prog_data); if (ice->state.streamout != shader->streamout) { ice->state.streamout = shader->streamout; ice->state.dirty |= IRIS_DIRTY_SO_DECL_LIST | IRIS_DIRTY_STREAMOUT; } if (ice->state.streamout_active) { for (int i = 0; i < PIPE_MAX_SO_BUFFERS; i++) { struct iris_stream_output_target *so = (void *) ice->state.so_target[i]; if (so) so->stride = ish->stream_output.stride[i]; } } if (dirty & IRIS_DIRTY_UNCOMPILED_FS) iris_update_compiled_fs(ice); // ... /* Changing shader interfaces may require a URB configuration. */ if (!(dirty & IRIS_DIRTY_URB)) { for (int i = MESA_SHADER_VERTEX; i <= MESA_SHADER_GEOMETRY; i++) { struct brw_vue_prog_data *old = old_prog_datas[i]; struct brw_vue_prog_data *new = get_vue_prog_data(ice, i); if (!!old != !!new || (new && new->urb_entry_size != old->urb_entry_size)) { ice->state.dirty |= IRIS_DIRTY_URB; break; } } } } static struct iris_compiled_shader * iris_compile_cs(struct iris_context *ice, struct iris_uncompiled_shader *ish, const struct brw_cs_prog_key *key) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; const struct brw_compiler *compiler = screen->compiler; const struct gen_device_info *devinfo = &screen->devinfo; void *mem_ctx = ralloc_context(NULL); struct brw_cs_prog_data *cs_prog_data = rzalloc(mem_ctx, struct brw_cs_prog_data); struct brw_stage_prog_data *prog_data = &cs_prog_data->base; enum brw_param_builtin *system_values; unsigned num_system_values; unsigned num_cbufs; nir_shader *nir = nir_shader_clone(mem_ctx, ish->nir); cs_prog_data->binding_table.work_groups_start = 0; prog_data->total_shared = nir->info.cs.shared_size; iris_setup_uniforms(compiler, mem_ctx, nir, prog_data, &system_values, &num_system_values, &num_cbufs); assign_common_binding_table_offsets(devinfo, nir, prog_data, 1, num_system_values, num_cbufs); char *error_str = NULL; const unsigned *program = brw_compile_cs(compiler, &ice->dbg, mem_ctx, key, cs_prog_data, nir, -1, &error_str); if (program == NULL) { dbg_printf("Failed to compile compute shader: %s\n", error_str); ralloc_free(mem_ctx); return false; } struct iris_compiled_shader *shader = iris_upload_shader(ice, IRIS_CACHE_CS, sizeof(*key), key, program, prog_data, NULL, system_values, num_system_values, num_cbufs); if (ish->compiled_once) { perf_debug(&ice->dbg, "Recompiling compute shader\n"); } else { ish->compiled_once = true; } ralloc_free(mem_ctx); return shader; } void iris_update_compiled_compute_shader(struct iris_context *ice) { struct iris_uncompiled_shader *ish = ice->shaders.uncompiled[MESA_SHADER_COMPUTE]; struct brw_cs_prog_key key = { KEY_INIT }; ice->vtbl.populate_cs_key(ice, &key); struct iris_compiled_shader *old = ice->shaders.prog[IRIS_CACHE_CS]; struct iris_compiled_shader *shader = iris_find_cached_shader(ice, IRIS_CACHE_CS, sizeof(key), &key); if (!shader) shader = iris_compile_cs(ice, ish, &key); if (old != shader) { ice->shaders.prog[IRIS_CACHE_CS] = shader; ice->state.dirty |= IRIS_DIRTY_CS | IRIS_DIRTY_BINDINGS_CS | IRIS_DIRTY_CONSTANTS_CS; } } void iris_fill_cs_push_const_buffer(struct brw_cs_prog_data *cs_prog_data, uint32_t *dst) { struct brw_stage_prog_data *prog_data = &cs_prog_data->base; assert(cs_prog_data->push.total.size > 0); assert(cs_prog_data->push.cross_thread.size == 0); assert(cs_prog_data->push.per_thread.dwords == 1); assert(prog_data->param[0] == BRW_PARAM_BUILTIN_SUBGROUP_ID); for (unsigned t = 0; t < cs_prog_data->threads; t++) dst[8 * t] = t; } /** * Allocate scratch BOs as needed for the given per-thread size and stage. */ struct iris_bo * iris_get_scratch_space(struct iris_context *ice, unsigned per_thread_scratch, gl_shader_stage stage) { struct iris_screen *screen = (struct iris_screen *)ice->ctx.screen; struct iris_bufmgr *bufmgr = screen->bufmgr; const struct gen_device_info *devinfo = &screen->devinfo; unsigned encoded_size = ffs(per_thread_scratch) - 11; assert(encoded_size < (1 << 16)); struct iris_bo **bop = &ice->shaders.scratch_bos[encoded_size][stage]; /* The documentation for 3DSTATE_PS "Scratch Space Base Pointer" says: * * "Scratch Space per slice is computed based on 4 sub-slices. SW * must allocate scratch space enough so that each slice has 4 * slices allowed." * * According to the other driver team, this applies to compute shaders * as well. This is not currently documented at all. * * This hack is no longer necessary on Gen11+. */ unsigned subslice_total = screen->subslice_total; if (devinfo->gen < 11) subslice_total = 4 * devinfo->num_slices; assert(subslice_total >= screen->subslice_total); if (!*bop) { unsigned scratch_ids_per_subslice = devinfo->max_cs_threads; uint32_t max_threads[] = { [MESA_SHADER_VERTEX] = devinfo->max_vs_threads, [MESA_SHADER_TESS_CTRL] = devinfo->max_tcs_threads, [MESA_SHADER_TESS_EVAL] = devinfo->max_tes_threads, [MESA_SHADER_GEOMETRY] = devinfo->max_gs_threads, [MESA_SHADER_FRAGMENT] = devinfo->max_wm_threads, [MESA_SHADER_COMPUTE] = scratch_ids_per_subslice * subslice_total, }; uint32_t size = per_thread_scratch * max_threads[stage]; *bop = iris_bo_alloc(bufmgr, "scratch", size, IRIS_MEMZONE_SHADER); } return *bop; } /* ------------------------------------------------------------------- */ /** * The pipe->create_[stage]_state() driver hooks. * * Performs basic NIR preprocessing, records any state dependencies, and * returns an iris_uncompiled_shader as the Gallium CSO. * * Actual shader compilation to assembly happens later, at first use. */ static void * iris_create_uncompiled_shader(struct pipe_context *ctx, nir_shader *nir, const struct pipe_stream_output_info *so_info) { struct iris_screen *screen = (struct iris_screen *)ctx->screen; const struct gen_device_info *devinfo = &screen->devinfo; struct iris_uncompiled_shader *ish = calloc(1, sizeof(struct iris_uncompiled_shader)); if (!ish) return NULL; nir = brw_preprocess_nir(screen->compiler, nir); NIR_PASS_V(nir, brw_nir_lower_image_load_store, devinfo); NIR_PASS_V(nir, iris_lower_storage_image_derefs); ish->program_id = get_new_program_id(screen); ish->nir = nir; if (so_info) { memcpy(&ish->stream_output, so_info, sizeof(*so_info)); update_so_info(&ish->stream_output, nir->info.outputs_written); } return ish; } static struct iris_uncompiled_shader * iris_create_shader_state(struct pipe_context *ctx, const struct pipe_shader_state *state) { assert(state->type == PIPE_SHADER_IR_NIR); return iris_create_uncompiled_shader(ctx, state->ir.nir, &state->stream_output); } static void * iris_create_vs_state(struct pipe_context *ctx, const struct pipe_shader_state *state) { struct iris_context *ice = (void *) ctx; struct iris_screen *screen = (void *) ctx->screen; struct iris_uncompiled_shader *ish = iris_create_shader_state(ctx, state); /* User clip planes */ if (ish->nir->info.clip_distance_array_size == 0) ish->nos |= (1ull << IRIS_NOS_RASTERIZER); if (screen->precompile) { struct brw_vs_prog_key key = { KEY_INIT }; iris_compile_vs(ice, ish, &key); } return ish; } static void * iris_create_tcs_state(struct pipe_context *ctx, const struct pipe_shader_state *state) { struct iris_context *ice = (void *) ctx; struct iris_screen *screen = (void *) ctx->screen; struct iris_uncompiled_shader *ish = iris_create_shader_state(ctx, state); struct shader_info *info = &ish->nir->info; // XXX: NOS? if (screen->precompile) { const unsigned _GL_TRIANGLES = 0x0004; struct brw_tcs_prog_key key = { KEY_INIT, // XXX: make sure the linker fills this out from the TES... .tes_primitive_mode = info->tess.primitive_mode ? info->tess.primitive_mode : _GL_TRIANGLES, .outputs_written = info->outputs_written, .patch_outputs_written = info->patch_outputs_written, }; iris_compile_tcs(ice, ish, &key); } return ish; } static void * iris_create_tes_state(struct pipe_context *ctx, const struct pipe_shader_state *state) { struct iris_context *ice = (void *) ctx; struct iris_screen *screen = (void *) ctx->screen; struct iris_uncompiled_shader *ish = iris_create_shader_state(ctx, state); struct shader_info *info = &ish->nir->info; // XXX: NOS? if (screen->precompile) { struct brw_tes_prog_key key = { KEY_INIT, // XXX: not ideal, need TCS output/TES input unification .inputs_read = info->inputs_read, .patch_inputs_read = info->patch_inputs_read, }; iris_compile_tes(ice, ish, &key); } return ish; } static void * iris_create_gs_state(struct pipe_context *ctx, const struct pipe_shader_state *state) { struct iris_context *ice = (void *) ctx; struct iris_screen *screen = (void *) ctx->screen; struct iris_uncompiled_shader *ish = iris_create_shader_state(ctx, state); // XXX: NOS? if (screen->precompile) { struct brw_gs_prog_key key = { KEY_INIT }; iris_compile_gs(ice, ish, &key); } return ish; } static void * iris_create_fs_state(struct pipe_context *ctx, const struct pipe_shader_state *state) { struct iris_context *ice = (void *) ctx; struct iris_screen *screen = (void *) ctx->screen; struct iris_uncompiled_shader *ish = iris_create_shader_state(ctx, state); struct shader_info *info = &ish->nir->info; ish->nos |= (1ull << IRIS_NOS_FRAMEBUFFER) | (1ull << IRIS_NOS_DEPTH_STENCIL_ALPHA) | (1ull << IRIS_NOS_RASTERIZER) | (1ull << IRIS_NOS_BLEND); /* The program key needs the VUE map if there are > 16 inputs */ if (util_bitcount64(ish->nir->info.inputs_read & BRW_FS_VARYING_INPUT_MASK) > 16) { ish->nos |= (1ull << IRIS_NOS_LAST_VUE_MAP); } if (screen->precompile) { const uint64_t color_outputs = info->outputs_written & ~(BITFIELD64_BIT(FRAG_RESULT_DEPTH) | BITFIELD64_BIT(FRAG_RESULT_STENCIL) | BITFIELD64_BIT(FRAG_RESULT_SAMPLE_MASK)); bool can_rearrange_varyings = util_bitcount64(info->inputs_read & BRW_FS_VARYING_INPUT_MASK) <= 16; struct brw_wm_prog_key key = { KEY_INIT, .nr_color_regions = util_bitcount(color_outputs), .coherent_fb_fetch = true, .input_slots_valid = can_rearrange_varyings ? 0 : info->inputs_read | VARYING_BIT_POS, }; iris_compile_fs(ice, ish, &key, NULL); } return ish; } static void * iris_create_compute_state(struct pipe_context *ctx, const struct pipe_compute_state *state) { assert(state->ir_type == PIPE_SHADER_IR_NIR); struct iris_context *ice = (void *) ctx; struct iris_screen *screen = (void *) ctx->screen; struct iris_uncompiled_shader *ish = iris_create_uncompiled_shader(ctx, (void *) state->prog, NULL); // XXX: disallow more than 64KB of shared variables if (screen->precompile) { struct brw_cs_prog_key key = { KEY_INIT }; iris_compile_cs(ice, ish, &key); } return ish; } /** * The pipe->delete_[stage]_state() driver hooks. * * Frees the iris_uncompiled_shader. */ static void iris_delete_shader_state(struct pipe_context *ctx, void *state) { struct iris_uncompiled_shader *ish = state; ralloc_free(ish->nir); free(ish); } /** * The pipe->bind_[stage]_state() driver hook. * * Binds an uncompiled shader as the current one for a particular stage. * Updates dirty tracking to account for the shader's NOS. */ static void bind_state(struct iris_context *ice, struct iris_uncompiled_shader *ish, gl_shader_stage stage) { uint64_t dirty_bit = IRIS_DIRTY_UNCOMPILED_VS << stage; const uint64_t nos = ish ? ish->nos : 0; ice->shaders.uncompiled[stage] = ish; ice->state.dirty |= dirty_bit; /* Record that CSOs need to mark IRIS_DIRTY_UNCOMPILED_XS when they change * (or that they no longer need to do so). */ for (int i = 0; i < IRIS_NOS_COUNT; i++) { if (nos & (1 << i)) ice->state.dirty_for_nos[i] |= dirty_bit; else ice->state.dirty_for_nos[i] &= ~dirty_bit; } } static void iris_bind_vs_state(struct pipe_context *ctx, void *state) { bind_state((void *) ctx, state, MESA_SHADER_VERTEX); } static void iris_bind_tcs_state(struct pipe_context *ctx, void *state) { bind_state((void *) ctx, state, MESA_SHADER_TESS_CTRL); } static void iris_bind_tes_state(struct pipe_context *ctx, void *state) { struct iris_context *ice = (struct iris_context *)ctx; /* Enabling/disabling optional stages requires a URB reconfiguration. */ if (!!state != !!ice->shaders.uncompiled[MESA_SHADER_TESS_EVAL]) ice->state.dirty |= IRIS_DIRTY_URB; bind_state((void *) ctx, state, MESA_SHADER_TESS_EVAL); } static void iris_bind_gs_state(struct pipe_context *ctx, void *state) { struct iris_context *ice = (struct iris_context *)ctx; /* Enabling/disabling optional stages requires a URB reconfiguration. */ if (!!state != !!ice->shaders.uncompiled[MESA_SHADER_GEOMETRY]) ice->state.dirty |= IRIS_DIRTY_URB; bind_state((void *) ctx, state, MESA_SHADER_GEOMETRY); } static void iris_bind_fs_state(struct pipe_context *ctx, void *state) { struct iris_context *ice = (struct iris_context *) ctx; struct iris_uncompiled_shader *old_ish = ice->shaders.uncompiled[MESA_SHADER_FRAGMENT]; struct iris_uncompiled_shader *new_ish = state; const unsigned color_bits = BITFIELD64_BIT(FRAG_RESULT_COLOR) | BITFIELD64_RANGE(FRAG_RESULT_DATA0, BRW_MAX_DRAW_BUFFERS); /* Fragment shader outputs influence HasWriteableRT */ if (!old_ish || !new_ish || (old_ish->nir->info.outputs_written & color_bits) != (new_ish->nir->info.outputs_written & color_bits)) ice->state.dirty |= IRIS_DIRTY_PS_BLEND; bind_state((void *) ctx, state, MESA_SHADER_FRAGMENT); } static void iris_bind_cs_state(struct pipe_context *ctx, void *state) { bind_state((void *) ctx, state, MESA_SHADER_COMPUTE); } void iris_init_program_functions(struct pipe_context *ctx) { ctx->create_vs_state = iris_create_vs_state; ctx->create_tcs_state = iris_create_tcs_state; ctx->create_tes_state = iris_create_tes_state; ctx->create_gs_state = iris_create_gs_state; ctx->create_fs_state = iris_create_fs_state; ctx->create_compute_state = iris_create_compute_state; ctx->delete_vs_state = iris_delete_shader_state; ctx->delete_tcs_state = iris_delete_shader_state; ctx->delete_tes_state = iris_delete_shader_state; ctx->delete_gs_state = iris_delete_shader_state; ctx->delete_fs_state = iris_delete_shader_state; ctx->delete_compute_state = iris_delete_shader_state; ctx->bind_vs_state = iris_bind_vs_state; ctx->bind_tcs_state = iris_bind_tcs_state; ctx->bind_tes_state = iris_bind_tes_state; ctx->bind_gs_state = iris_bind_gs_state; ctx->bind_fs_state = iris_bind_fs_state; ctx->bind_compute_state = iris_bind_cs_state; }