extern "C" const unsigned * brw_compile_tcs(const struct brw_compiler *compiler, void *log_data, void *mem_ctx, const struct brw_tcs_prog_key *key, struct brw_tcs_prog_data *prog_data, const nir_shader *src_shader, int shader_time_index, unsigned *final_assembly_size, char **error_str) { const struct gen_device_info *devinfo = compiler->devinfo; struct brw_vue_prog_data *vue_prog_data = &prog_data->base; const bool is_scalar = compiler->scalar_stage[MESA_SHADER_TESS_CTRL]; nir_shader *nir = nir_shader_clone(mem_ctx, src_shader); nir->info->outputs_written = key->outputs_written; nir->info->patch_outputs_written = key->patch_outputs_written; struct brw_vue_map input_vue_map; brw_compute_vue_map(devinfo, &input_vue_map, nir->info->inputs_read, nir->info->separate_shader); brw_compute_tess_vue_map(&vue_prog_data->vue_map, nir->info->outputs_written, nir->info->patch_outputs_written); nir = brw_nir_apply_sampler_key(nir, devinfo, &key->tex, is_scalar); brw_nir_lower_vue_inputs(nir, is_scalar, &input_vue_map); brw_nir_lower_tcs_outputs(nir, &vue_prog_data->vue_map); if (key->quads_workaround) brw_nir_apply_tcs_quads_workaround(nir); nir = brw_postprocess_nir(nir, compiler->devinfo, is_scalar); if (is_scalar) prog_data->instances = DIV_ROUND_UP(nir->info->tcs.vertices_out, 8); else prog_data->instances = DIV_ROUND_UP(nir->info->tcs.vertices_out, 2); /* Compute URB entry size. The maximum allowed URB entry size is 32k. * That divides up as follows: * * 32 bytes for the patch header (tessellation factors) * 480 bytes for per-patch varyings (a varying component is 4 bytes and * gl_MaxTessPatchComponents = 120) * 16384 bytes for per-vertex varyings (a varying component is 4 bytes, * gl_MaxPatchVertices = 32 and * gl_MaxTessControlOutputComponents = 128) * * 15808 bytes left for varying packing overhead */ const int num_per_patch_slots = vue_prog_data->vue_map.num_per_patch_slots; const int num_per_vertex_slots = vue_prog_data->vue_map.num_per_vertex_slots; unsigned output_size_bytes = 0; /* Note that the patch header is counted in num_per_patch_slots. */ output_size_bytes += num_per_patch_slots * 16; output_size_bytes += nir->info->tcs.vertices_out * num_per_vertex_slots * 16; assert(output_size_bytes >= 1); if (output_size_bytes > GEN7_MAX_HS_URB_ENTRY_SIZE_BYTES) return NULL; /* URB entry sizes are stored as a multiple of 64 bytes. */ vue_prog_data->urb_entry_size = ALIGN(output_size_bytes, 64) / 64; /* HS does not use the usual payload pushing from URB to GRFs, * because we don't have enough registers for a full-size payload, and * the hardware is broken on Haswell anyway. */ vue_prog_data->urb_read_length = 0; if (unlikely(INTEL_DEBUG & DEBUG_TCS)) { fprintf(stderr, "TCS Input "); brw_print_vue_map(stderr, &input_vue_map); fprintf(stderr, "TCS Output "); brw_print_vue_map(stderr, &vue_prog_data->vue_map); } if (is_scalar) { fs_visitor v(compiler, log_data, mem_ctx, (void *) key, &prog_data->base.base, NULL, nir, 8, shader_time_index, &input_vue_map); if (!v.run_tcs_single_patch()) { if (error_str) *error_str = ralloc_strdup(mem_ctx, v.fail_msg); return NULL; } prog_data->base.base.dispatch_grf_start_reg = v.payload.num_regs; prog_data->base.dispatch_mode = DISPATCH_MODE_SIMD8; fs_generator g(compiler, log_data, mem_ctx, (void *) key, &prog_data->base.base, v.promoted_constants, false, MESA_SHADER_TESS_CTRL); if (unlikely(INTEL_DEBUG & DEBUG_TCS)) { g.enable_debug(ralloc_asprintf(mem_ctx, "%s tessellation control shader %s", nir->info->label ? nir->info->label : "unnamed", nir->info->name)); } g.generate_code(v.cfg, 8); return g.get_assembly(final_assembly_size); } else { vec4_tcs_visitor v(compiler, log_data, key, prog_data, nir, mem_ctx, shader_time_index, &input_vue_map); if (!v.run()) { if (error_str) *error_str = ralloc_strdup(mem_ctx, v.fail_msg); return NULL; } if (unlikely(INTEL_DEBUG & DEBUG_TCS)) v.dump_instructions(); return brw_vec4_generate_assembly(compiler, log_data, mem_ctx, nir, &prog_data->base, v.cfg, final_assembly_size); } }
extern "C" const unsigned * brw_compile_gs(const struct brw_compiler *compiler, void *log_data, void *mem_ctx, const struct brw_gs_prog_key *key, struct brw_gs_prog_data *prog_data, const nir_shader *src_shader, struct gl_shader_program *shader_prog, int shader_time_index, unsigned *final_assembly_size, char **error_str) { struct brw_gs_compile c; memset(&c, 0, sizeof(c)); c.key = *key; const bool is_scalar = compiler->scalar_stage[MESA_SHADER_GEOMETRY]; nir_shader *shader = nir_shader_clone(mem_ctx, src_shader); /* The GLSL linker will have already matched up GS inputs and the outputs * of prior stages. The driver does extend VS outputs in some cases, but * only for legacy OpenGL or Gen4-5 hardware, neither of which offer * geometry shader support. So we can safely ignore that. * * For SSO pipelines, we use a fixed VUE map layout based on variable * locations, so we can rely on rendezvous-by-location making this work. */ GLbitfield64 inputs_read = shader->info->inputs_read; brw_compute_vue_map(compiler->devinfo, &c.input_vue_map, inputs_read, shader->info->separate_shader); shader = brw_nir_apply_sampler_key(shader, compiler->devinfo, &key->tex, is_scalar); brw_nir_lower_vue_inputs(shader, is_scalar, &c.input_vue_map); brw_nir_lower_vue_outputs(shader, is_scalar); shader = brw_postprocess_nir(shader, compiler->devinfo, is_scalar); prog_data->base.clip_distance_mask = ((1 << shader->info->clip_distance_array_size) - 1); prog_data->base.cull_distance_mask = ((1 << shader->info->cull_distance_array_size) - 1) << shader->info->clip_distance_array_size; prog_data->include_primitive_id = (shader->info->system_values_read & (1 << SYSTEM_VALUE_PRIMITIVE_ID)) != 0; prog_data->invocations = shader->info->gs.invocations; if (compiler->devinfo->gen >= 8) prog_data->static_vertex_count = nir_gs_count_vertices(shader); if (compiler->devinfo->gen >= 7) { if (shader->info->gs.output_primitive == GL_POINTS) { /* When the output type is points, the geometry shader may output data * to multiple streams, and EndPrimitive() has no effect. So we * configure the hardware to interpret the control data as stream ID. */ prog_data->control_data_format = GEN7_GS_CONTROL_DATA_FORMAT_GSCTL_SID; /* We only have to emit control bits if we are using streams */ if (shader_prog && shader_prog->Geom.UsesStreams) c.control_data_bits_per_vertex = 2; else c.control_data_bits_per_vertex = 0; } else { /* When the output type is triangle_strip or line_strip, EndPrimitive() * may be used to terminate the current strip and start a new one * (similar to primitive restart), and outputting data to multiple * streams is not supported. So we configure the hardware to interpret * the control data as EndPrimitive information (a.k.a. "cut bits"). */ prog_data->control_data_format = GEN7_GS_CONTROL_DATA_FORMAT_GSCTL_CUT; /* We only need to output control data if the shader actually calls * EndPrimitive(). */ c.control_data_bits_per_vertex = shader->info->gs.uses_end_primitive ? 1 : 0; } } else { /* There are no control data bits in gen6. */ c.control_data_bits_per_vertex = 0; /* If it is using transform feedback, enable it */ if (shader->info->has_transform_feedback_varyings) prog_data->gen6_xfb_enabled = true; else prog_data->gen6_xfb_enabled = false; } c.control_data_header_size_bits = shader->info->gs.vertices_out * c.control_data_bits_per_vertex; /* 1 HWORD = 32 bytes = 256 bits */ prog_data->control_data_header_size_hwords = ALIGN(c.control_data_header_size_bits, 256) / 256; /* Compute the output vertex size. * * From the Ivy Bridge PRM, Vol2 Part1 7.2.1.1 STATE_GS - Output Vertex * Size (p168): * * [0,62] indicating [1,63] 16B units * * Specifies the size of each vertex stored in the GS output entry * (following any Control Header data) as a number of 128-bit units * (minus one). * * Programming Restrictions: The vertex size must be programmed as a * multiple of 32B units with the following exception: Rendering is * disabled (as per SOL stage state) and the vertex size output by the * GS thread is 16B. * * If rendering is enabled (as per SOL state) the vertex size must be * programmed as a multiple of 32B units. In other words, the only time * software can program a vertex size with an odd number of 16B units * is when rendering is disabled. * * Note: B=bytes in the above text. * * It doesn't seem worth the extra trouble to optimize the case where the * vertex size is 16B (especially since this would require special-casing * the GEN assembly that writes to the URB). So we just set the vertex * size to a multiple of 32B (2 vec4's) in all cases. * * The maximum output vertex size is 62*16 = 992 bytes (31 hwords). We * budget that as follows: * * 512 bytes for varyings (a varying component is 4 bytes and * gl_MaxGeometryOutputComponents = 128) * 16 bytes overhead for VARYING_SLOT_PSIZ (each varying slot is 16 * bytes) * 16 bytes overhead for gl_Position (we allocate it a slot in the VUE * even if it's not used) * 32 bytes overhead for gl_ClipDistance (we allocate it 2 VUE slots * whenever clip planes are enabled, even if the shader doesn't * write to gl_ClipDistance) * 16 bytes overhead since the VUE size must be a multiple of 32 bytes * (see below)--this causes up to 1 VUE slot to be wasted * 400 bytes available for varying packing overhead * * Worst-case varying packing overhead is 3/4 of a varying slot (12 bytes) * per interpolation type, so this is plenty. * */ unsigned output_vertex_size_bytes = prog_data->base.vue_map.num_slots * 16; assert(compiler->devinfo->gen == 6 || output_vertex_size_bytes <= GEN7_MAX_GS_OUTPUT_VERTEX_SIZE_BYTES); prog_data->output_vertex_size_hwords = ALIGN(output_vertex_size_bytes, 32) / 32; /* Compute URB entry size. The maximum allowed URB entry size is 32k. * That divides up as follows: * * 64 bytes for the control data header (cut indices or StreamID bits) * 4096 bytes for varyings (a varying component is 4 bytes and * gl_MaxGeometryTotalOutputComponents = 1024) * 4096 bytes overhead for VARYING_SLOT_PSIZ (each varying slot is 16 * bytes/vertex and gl_MaxGeometryOutputVertices is 256) * 4096 bytes overhead for gl_Position (we allocate it a slot in the VUE * even if it's not used) * 8192 bytes overhead for gl_ClipDistance (we allocate it 2 VUE slots * whenever clip planes are enabled, even if the shader doesn't * write to gl_ClipDistance) * 4096 bytes overhead since the VUE size must be a multiple of 32 * bytes (see above)--this causes up to 1 VUE slot to be wasted * 8128 bytes available for varying packing overhead * * Worst-case varying packing overhead is 3/4 of a varying slot per * interpolation type, which works out to 3072 bytes, so this would allow * us to accommodate 2 interpolation types without any danger of running * out of URB space. * * In practice, the risk of running out of URB space is very small, since * the above figures are all worst-case, and most of them scale with the * number of output vertices. So we'll just calculate the amount of space * we need, and if it's too large, fail to compile. * * The above is for gen7+ where we have a single URB entry that will hold * all the output. In gen6, we will have to allocate URB entries for every * vertex we emit, so our URB entries only need to be large enough to hold * a single vertex. Also, gen6 does not have a control data header. */ unsigned output_size_bytes; if (compiler->devinfo->gen >= 7) { output_size_bytes = prog_data->output_vertex_size_hwords * 32 * shader->info->gs.vertices_out; output_size_bytes += 32 * prog_data->control_data_header_size_hwords; } else { output_size_bytes = prog_data->output_vertex_size_hwords * 32; } /* Broadwell stores "Vertex Count" as a full 8 DWord (32 byte) URB output, * which comes before the control header. */ if (compiler->devinfo->gen >= 8) output_size_bytes += 32; /* Shaders can technically set max_vertices = 0, at which point we * may have a URB size of 0 bytes. Nothing good can come from that, * so enforce a minimum size. */ if (output_size_bytes == 0) output_size_bytes = 1; unsigned max_output_size_bytes = GEN7_MAX_GS_URB_ENTRY_SIZE_BYTES; if (compiler->devinfo->gen == 6) max_output_size_bytes = GEN6_MAX_GS_URB_ENTRY_SIZE_BYTES; if (output_size_bytes > max_output_size_bytes) return NULL; /* URB entry sizes are stored as a multiple of 64 bytes in gen7+ and * a multiple of 128 bytes in gen6. */ if (compiler->devinfo->gen >= 7) prog_data->base.urb_entry_size = ALIGN(output_size_bytes, 64) / 64; else prog_data->base.urb_entry_size = ALIGN(output_size_bytes, 128) / 128; prog_data->output_topology = get_hw_prim_for_gl_prim(shader->info->gs.output_primitive); prog_data->vertices_in = shader->info->gs.vertices_in; /* GS inputs are read from the VUE 256 bits (2 vec4's) at a time, so we * need to program a URB read length of ceiling(num_slots / 2). */ prog_data->base.urb_read_length = (c.input_vue_map.num_slots + 1) / 2; /* Now that prog_data setup is done, we are ready to actually compile the * program. */ if (unlikely(INTEL_DEBUG & DEBUG_GS)) { fprintf(stderr, "GS Input "); brw_print_vue_map(stderr, &c.input_vue_map); fprintf(stderr, "GS Output "); brw_print_vue_map(stderr, &prog_data->base.vue_map); } if (is_scalar) { fs_visitor v(compiler, log_data, mem_ctx, &c, prog_data, shader, shader_time_index); if (v.run_gs()) { prog_data->base.dispatch_mode = DISPATCH_MODE_SIMD8; prog_data->base.base.dispatch_grf_start_reg = v.payload.num_regs; fs_generator g(compiler, log_data, mem_ctx, &c.key, &prog_data->base.base, v.promoted_constants, false, MESA_SHADER_GEOMETRY); if (unlikely(INTEL_DEBUG & DEBUG_GS)) { const char *label = shader->info->label ? shader->info->label : "unnamed"; char *name = ralloc_asprintf(mem_ctx, "%s geometry shader %s", label, shader->info->name); g.enable_debug(name); } g.generate_code(v.cfg, 8); return g.get_assembly(final_assembly_size); } } if (compiler->devinfo->gen >= 7) { /* Compile the geometry shader in DUAL_OBJECT dispatch mode, if we can do * so without spilling. If the GS invocations count > 1, then we can't use * dual object mode. */ if (prog_data->invocations <= 1 && likely(!(INTEL_DEBUG & DEBUG_NO_DUAL_OBJECT_GS))) { prog_data->base.dispatch_mode = DISPATCH_MODE_4X2_DUAL_OBJECT; vec4_gs_visitor v(compiler, log_data, &c, prog_data, shader, mem_ctx, true /* no_spills */, shader_time_index); if (v.run()) { return brw_vec4_generate_assembly(compiler, log_data, mem_ctx, shader, &prog_data->base, v.cfg, final_assembly_size); } } } /* Either we failed to compile in DUAL_OBJECT mode (probably because it * would have required spilling) or DUAL_OBJECT mode is disabled. So fall * back to DUAL_INSTANCED or SINGLE mode, which consumes fewer registers. * * FIXME: Single dispatch mode requires that the driver can handle * interleaving of input registers, but this is already supported (dual * instance mode has the same requirement). However, to take full advantage * of single dispatch mode to reduce register pressure we would also need to * do interleaved outputs, but currently, the vec4 visitor and generator * classes do not support this, so at the moment register pressure in * single and dual instance modes is the same. * * From the Ivy Bridge PRM, Vol2 Part1 7.2.1.1 "3DSTATE_GS" * "If InstanceCount>1, DUAL_OBJECT mode is invalid. Software will likely * want to use DUAL_INSTANCE mode for higher performance, but SINGLE mode * is also supported. When InstanceCount=1 (one instance per object) software * can decide which dispatch mode to use. DUAL_OBJECT mode would likely be * the best choice for performance, followed by SINGLE mode." * * So SINGLE mode is more performant when invocations == 1 and DUAL_INSTANCE * mode is more performant when invocations > 1. Gen6 only supports * SINGLE mode. */ if (prog_data->invocations <= 1 || compiler->devinfo->gen < 7) prog_data->base.dispatch_mode = DISPATCH_MODE_4X1_SINGLE; else prog_data->base.dispatch_mode = DISPATCH_MODE_4X2_DUAL_INSTANCE; vec4_gs_visitor *gs = NULL; const unsigned *ret = NULL; if (compiler->devinfo->gen >= 7) gs = new vec4_gs_visitor(compiler, log_data, &c, prog_data, shader, mem_ctx, false /* no_spills */, shader_time_index); else gs = new gen6_gs_visitor(compiler, log_data, &c, prog_data, shader_prog, shader, mem_ctx, false /* no_spills */, shader_time_index); if (!gs->run()) { if (error_str) *error_str = ralloc_strdup(mem_ctx, gs->fail_msg); } else { ret = brw_vec4_generate_assembly(compiler, log_data, mem_ctx, shader, &prog_data->base, gs->cfg, final_assembly_size); } delete gs; return ret; }