/************************************************************************** * * Copyright 2007 VMware, Inc. * All Rights Reserved. * * 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, sub license, 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 (including the * next paragraph) 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 NON-INFRINGEMENT. * IN NO EVENT SHALL VMWARE AND/OR ITS SUPPLIERS 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. * **************************************************************************/ /* * Authors: * Keith Whitwell * Brian Paul */ #include "main/errors.h" #include "main/imports.h" #include "main/hash.h" #include "main/mtypes.h" #include "program/prog_parameter.h" #include "program/prog_print.h" #include "program/prog_to_nir.h" #include "program/programopt.h" #include "compiler/nir/nir.h" #include "pipe/p_context.h" #include "pipe/p_defines.h" #include "pipe/p_shader_tokens.h" #include "draw/draw_context.h" #include "tgsi/tgsi_dump.h" #include "tgsi/tgsi_emulate.h" #include "tgsi/tgsi_parse.h" #include "tgsi/tgsi_ureg.h" #include "st_debug.h" #include "st_cb_bitmap.h" #include "st_cb_drawpixels.h" #include "st_context.h" #include "st_tgsi_lower_depth_clamp.h" #include "st_tgsi_lower_yuv.h" #include "st_program.h" #include "st_mesa_to_tgsi.h" #include "st_atifs_to_tgsi.h" #include "st_nir.h" #include "st_shader_cache.h" #include "cso_cache/cso_context.h" static void set_affected_state_flags(uint64_t *states, struct gl_program *prog, uint64_t new_constants, uint64_t new_sampler_views, uint64_t new_samplers, uint64_t new_images, uint64_t new_ubos, uint64_t new_ssbos, uint64_t new_atomics) { if (prog->Parameters->NumParameters) *states |= new_constants; if (prog->info.num_textures) *states |= new_sampler_views | new_samplers; if (prog->info.num_images) *states |= new_images; if (prog->info.num_ubos) *states |= new_ubos; if (prog->info.num_ssbos) *states |= new_ssbos; if (prog->info.num_abos) *states |= new_atomics; } /** * This determines which states will be updated when the shader is bound. */ void st_set_prog_affected_state_flags(struct gl_program *prog) { uint64_t *states; switch (prog->info.stage) { case MESA_SHADER_VERTEX: states = &((struct st_vertex_program*)prog)->affected_states; *states = ST_NEW_VS_STATE | ST_NEW_RASTERIZER | ST_NEW_VERTEX_ARRAYS; set_affected_state_flags(states, prog, ST_NEW_VS_CONSTANTS, ST_NEW_VS_SAMPLER_VIEWS, ST_NEW_VS_SAMPLERS, ST_NEW_VS_IMAGES, ST_NEW_VS_UBOS, ST_NEW_VS_SSBOS, ST_NEW_VS_ATOMICS); break; case MESA_SHADER_TESS_CTRL: states = &(st_common_program(prog))->affected_states; *states = ST_NEW_TCS_STATE; set_affected_state_flags(states, prog, ST_NEW_TCS_CONSTANTS, ST_NEW_TCS_SAMPLER_VIEWS, ST_NEW_TCS_SAMPLERS, ST_NEW_TCS_IMAGES, ST_NEW_TCS_UBOS, ST_NEW_TCS_SSBOS, ST_NEW_TCS_ATOMICS); break; case MESA_SHADER_TESS_EVAL: states = &(st_common_program(prog))->affected_states; *states = ST_NEW_TES_STATE | ST_NEW_RASTERIZER; set_affected_state_flags(states, prog, ST_NEW_TES_CONSTANTS, ST_NEW_TES_SAMPLER_VIEWS, ST_NEW_TES_SAMPLERS, ST_NEW_TES_IMAGES, ST_NEW_TES_UBOS, ST_NEW_TES_SSBOS, ST_NEW_TES_ATOMICS); break; case MESA_SHADER_GEOMETRY: states = &(st_common_program(prog))->affected_states; *states = ST_NEW_GS_STATE | ST_NEW_RASTERIZER; set_affected_state_flags(states, prog, ST_NEW_GS_CONSTANTS, ST_NEW_GS_SAMPLER_VIEWS, ST_NEW_GS_SAMPLERS, ST_NEW_GS_IMAGES, ST_NEW_GS_UBOS, ST_NEW_GS_SSBOS, ST_NEW_GS_ATOMICS); break; case MESA_SHADER_FRAGMENT: states = &((struct st_fragment_program*)prog)->affected_states; /* gl_FragCoord and glDrawPixels always use constants. */ *states = ST_NEW_FS_STATE | ST_NEW_SAMPLE_SHADING | ST_NEW_FS_CONSTANTS; set_affected_state_flags(states, prog, ST_NEW_FS_CONSTANTS, ST_NEW_FS_SAMPLER_VIEWS, ST_NEW_FS_SAMPLERS, ST_NEW_FS_IMAGES, ST_NEW_FS_UBOS, ST_NEW_FS_SSBOS, ST_NEW_FS_ATOMICS); break; case MESA_SHADER_COMPUTE: states = &((struct st_common_program*)prog)->affected_states; *states = ST_NEW_CS_STATE; set_affected_state_flags(states, prog, ST_NEW_CS_CONSTANTS, ST_NEW_CS_SAMPLER_VIEWS, ST_NEW_CS_SAMPLERS, ST_NEW_CS_IMAGES, ST_NEW_CS_UBOS, ST_NEW_CS_SSBOS, ST_NEW_CS_ATOMICS); break; default: unreachable("unhandled shader stage"); } } static void delete_ir(struct pipe_shader_state *ir) { if (ir->tokens) { ureg_free_tokens(ir->tokens); ir->tokens = NULL; } /* Note: Any setup of ->ir.nir that has had pipe->create_*_state called on * it has resulted in the driver taking ownership of the NIR. Those * callers should be NULLing out the nir field in any pipe_shader_state * that might have this called in order to indicate that. * * GLSL IR and ARB programs will have set gl_program->nir to the same * shader as ir->ir.nir, so it will be freed by _mesa_delete_program(). */ } /** * Delete a vertex program variant. Note the caller must unlink * the variant from the linked list. */ static void delete_vp_variant(struct st_context *st, struct st_vp_variant *vpv) { if (vpv->driver_shader) { if (st->has_shareable_shaders || vpv->key.st == st) { cso_delete_vertex_shader(st->cso_context, vpv->driver_shader); } else { st_save_zombie_shader(vpv->key.st, PIPE_SHADER_VERTEX, vpv->driver_shader); } } if (vpv->draw_shader) draw_delete_vertex_shader( st->draw, vpv->draw_shader ); delete_ir(&vpv->tgsi); free( vpv ); } /** * Clean out any old compilations: */ void st_release_vp_variants( struct st_context *st, struct st_vertex_program *stvp ) { struct st_vp_variant *vpv; for (vpv = stvp->variants; vpv; ) { struct st_vp_variant *next = vpv->next; delete_vp_variant(st, vpv); vpv = next; } stvp->variants = NULL; delete_ir(&stvp->tgsi); } /** * Delete a fragment program variant. Note the caller must unlink * the variant from the linked list. */ static void delete_fp_variant(struct st_context *st, struct st_fp_variant *fpv) { if (fpv->driver_shader) { if (st->has_shareable_shaders || fpv->key.st == st) { cso_delete_fragment_shader(st->cso_context, fpv->driver_shader); } else { st_save_zombie_shader(fpv->key.st, PIPE_SHADER_FRAGMENT, fpv->driver_shader); } } free(fpv); } /** * Free all variants of a fragment program. */ void st_release_fp_variants(struct st_context *st, struct st_fragment_program *stfp) { struct st_fp_variant *fpv; for (fpv = stfp->variants; fpv; ) { struct st_fp_variant *next = fpv->next; delete_fp_variant(st, fpv); fpv = next; } stfp->variants = NULL; delete_ir(&stfp->tgsi); } /** * Delete a basic program variant. Note the caller must unlink * the variant from the linked list. */ static void delete_basic_variant(struct st_context *st, struct st_basic_variant *v, GLenum target) { if (v->driver_shader) { if (st->has_shareable_shaders || v->key.st == st) { /* The shader's context matches the calling context, or we * don't care. */ switch (target) { case GL_TESS_CONTROL_PROGRAM_NV: cso_delete_tessctrl_shader(st->cso_context, v->driver_shader); break; case GL_TESS_EVALUATION_PROGRAM_NV: cso_delete_tesseval_shader(st->cso_context, v->driver_shader); break; case GL_GEOMETRY_PROGRAM_NV: cso_delete_geometry_shader(st->cso_context, v->driver_shader); break; case GL_COMPUTE_PROGRAM_NV: cso_delete_compute_shader(st->cso_context, v->driver_shader); break; default: unreachable("bad shader type in delete_basic_variant"); } } else { /* We can't delete a shader with a context different from the one * that created it. Add it to the creating context's zombie list. */ enum pipe_shader_type type; switch (target) { case GL_TESS_CONTROL_PROGRAM_NV: type = PIPE_SHADER_TESS_CTRL; break; case GL_TESS_EVALUATION_PROGRAM_NV: type = PIPE_SHADER_TESS_EVAL; break; case GL_GEOMETRY_PROGRAM_NV: type = PIPE_SHADER_GEOMETRY; break; default: unreachable(""); } st_save_zombie_shader(v->key.st, type, v->driver_shader); } } free(v); } /** * Free all basic program variants. */ void st_release_basic_variants(struct st_context *st, struct st_common_program *p) { struct st_basic_variant *v; for (v = p->variants; v; ) { struct st_basic_variant *next = v->next; delete_basic_variant(st, v, p->Base.Target); v = next; } p->variants = NULL; delete_ir(&p->tgsi); } /** * Translate ARB (asm) program to NIR */ static nir_shader * st_translate_prog_to_nir(struct st_context *st, struct gl_program *prog, gl_shader_stage stage) { const struct gl_shader_compiler_options *options = &st->ctx->Const.ShaderCompilerOptions[stage]; /* Translate to NIR */ nir_shader *nir = prog_to_nir(prog, options->NirOptions); NIR_PASS_V(nir, nir_lower_regs_to_ssa); /* turn registers into SSA */ nir_validate_shader(nir, "after st/ptn lower_regs_to_ssa"); NIR_PASS_V(nir, st_nir_lower_wpos_ytransform, prog, st->pipe->screen); NIR_PASS_V(nir, nir_lower_system_values); /* Optimise NIR */ NIR_PASS_V(nir, nir_opt_constant_folding); st_nir_opts(nir); nir_validate_shader(nir, "after st/ptn NIR opts"); return nir; } void st_prepare_vertex_program(struct st_vertex_program *stvp) { stvp->num_inputs = 0; memset(stvp->input_to_index, ~0, sizeof(stvp->input_to_index)); memset(stvp->result_to_output, ~0, sizeof(stvp->result_to_output)); /* Determine number of inputs, the mappings between VERT_ATTRIB_x * and TGSI generic input indexes, plus input attrib semantic info. */ for (unsigned attr = 0; attr < VERT_ATTRIB_MAX; attr++) { if ((stvp->Base.info.inputs_read & BITFIELD64_BIT(attr)) != 0) { stvp->input_to_index[attr] = stvp->num_inputs; stvp->index_to_input[stvp->num_inputs] = attr; stvp->num_inputs++; if ((stvp->Base.DualSlotInputs & BITFIELD64_BIT(attr)) != 0) { /* add placeholder for second part of a double attribute */ stvp->index_to_input[stvp->num_inputs] = ST_DOUBLE_ATTRIB_PLACEHOLDER; stvp->num_inputs++; } } } /* pre-setup potentially unused edgeflag input */ stvp->input_to_index[VERT_ATTRIB_EDGEFLAG] = stvp->num_inputs; stvp->index_to_input[stvp->num_inputs] = VERT_ATTRIB_EDGEFLAG; /* Compute mapping of vertex program outputs to slots. */ unsigned num_outputs = 0; for (unsigned attr = 0; attr < VARYING_SLOT_MAX; attr++) { if (stvp->Base.info.outputs_written & BITFIELD64_BIT(attr)) stvp->result_to_output[attr] = num_outputs++; } /* pre-setup potentially unused edgeflag output */ stvp->result_to_output[VARYING_SLOT_EDGE] = num_outputs; } void st_translate_stream_output_info(struct gl_program *prog) { struct gl_transform_feedback_info *info = prog->sh.LinkedTransformFeedback; if (!info) return; /* Determine the (default) output register mapping for each output. */ unsigned num_outputs = 0; ubyte output_mapping[VARYING_SLOT_TESS_MAX]; memset(output_mapping, 0, sizeof(output_mapping)); for (unsigned attr = 0; attr < VARYING_SLOT_MAX; attr++) { if (prog->info.outputs_written & BITFIELD64_BIT(attr)) output_mapping[attr] = num_outputs++; } /* Translate stream output info. */ struct pipe_stream_output_info *so_info = NULL; if (prog->info.stage == MESA_SHADER_VERTEX) so_info = &((struct st_vertex_program*)prog)->tgsi.stream_output; else so_info = &((struct st_common_program*)prog)->tgsi.stream_output; for (unsigned i = 0; i < info->NumOutputs; i++) { so_info->output[i].register_index = output_mapping[info->Outputs[i].OutputRegister]; so_info->output[i].start_component = info->Outputs[i].ComponentOffset; so_info->output[i].num_components = info->Outputs[i].NumComponents; so_info->output[i].output_buffer = info->Outputs[i].OutputBuffer; so_info->output[i].dst_offset = info->Outputs[i].DstOffset; so_info->output[i].stream = info->Outputs[i].StreamId; } for (unsigned i = 0; i < PIPE_MAX_SO_BUFFERS; i++) { so_info->stride[i] = info->Buffers[i].Stride; } so_info->num_outputs = info->NumOutputs; } /** * Translate a vertex program. */ bool st_translate_vertex_program(struct st_context *st, struct st_vertex_program *stvp) { struct ureg_program *ureg; enum pipe_error error; unsigned num_outputs = 0; unsigned attr; ubyte output_semantic_name[VARYING_SLOT_MAX] = {0}; ubyte output_semantic_index[VARYING_SLOT_MAX] = {0}; if (stvp->Base.arb.IsPositionInvariant) _mesa_insert_mvp_code(st->ctx, &stvp->Base); st_prepare_vertex_program(stvp); /* ARB_vp: */ if (!stvp->glsl_to_tgsi) { _mesa_remove_output_reads(&stvp->Base, PROGRAM_OUTPUT); /* This determines which states will be updated when the assembly * shader is bound. */ stvp->affected_states = ST_NEW_VS_STATE | ST_NEW_RASTERIZER | ST_NEW_VERTEX_ARRAYS; if (stvp->Base.Parameters->NumParameters) stvp->affected_states |= ST_NEW_VS_CONSTANTS; /* No samplers are allowed in ARB_vp. */ } /* Get semantic names and indices. */ for (attr = 0; attr < VARYING_SLOT_MAX; attr++) { if (stvp->Base.info.outputs_written & BITFIELD64_BIT(attr)) { unsigned slot = num_outputs++; unsigned semantic_name, semantic_index; tgsi_get_gl_varying_semantic(attr, st->needs_texcoord_semantic, &semantic_name, &semantic_index); output_semantic_name[slot] = semantic_name; output_semantic_index[slot] = semantic_index; } } /* pre-setup potentially unused edgeflag output */ output_semantic_name[num_outputs] = TGSI_SEMANTIC_EDGEFLAG; output_semantic_index[num_outputs] = 0; ureg = ureg_create_with_screen(PIPE_SHADER_VERTEX, st->pipe->screen); if (ureg == NULL) return false; if (stvp->Base.info.clip_distance_array_size) ureg_property(ureg, TGSI_PROPERTY_NUM_CLIPDIST_ENABLED, stvp->Base.info.clip_distance_array_size); if (stvp->Base.info.cull_distance_array_size) ureg_property(ureg, TGSI_PROPERTY_NUM_CULLDIST_ENABLED, stvp->Base.info.cull_distance_array_size); if (ST_DEBUG & DEBUG_MESA) { _mesa_print_program(&stvp->Base); _mesa_print_program_parameters(st->ctx, &stvp->Base); debug_printf("\n"); } if (stvp->glsl_to_tgsi) { error = st_translate_program(st->ctx, PIPE_SHADER_VERTEX, ureg, stvp->glsl_to_tgsi, &stvp->Base, /* inputs */ stvp->num_inputs, stvp->input_to_index, NULL, /* inputSlotToAttr */ NULL, /* input semantic name */ NULL, /* input semantic index */ NULL, /* interp mode */ /* outputs */ num_outputs, stvp->result_to_output, output_semantic_name, output_semantic_index); st_translate_stream_output_info(&stvp->Base); free_glsl_to_tgsi_visitor(stvp->glsl_to_tgsi); } else error = st_translate_mesa_program(st->ctx, PIPE_SHADER_VERTEX, ureg, &stvp->Base, /* inputs */ stvp->num_inputs, stvp->input_to_index, NULL, /* input semantic name */ NULL, /* input semantic index */ NULL, /* outputs */ num_outputs, stvp->result_to_output, output_semantic_name, output_semantic_index); if (error) { debug_printf("%s: failed to translate Mesa program:\n", __func__); _mesa_print_program(&stvp->Base); debug_assert(0); return false; } stvp->tgsi.tokens = ureg_get_tokens(ureg, &stvp->num_tgsi_tokens); ureg_destroy(ureg); if (stvp->glsl_to_tgsi) { stvp->glsl_to_tgsi = NULL; st_store_ir_in_disk_cache(st, &stvp->Base, false); } /* Translate to NIR. * * This must be done after the translation to TGSI is done, because * we'll pass the NIR shader to the driver and the TGSI version to * the draw module for the select/feedback/rasterpos code. */ if (st->pipe->screen->get_shader_param(st->pipe->screen, PIPE_SHADER_VERTEX, PIPE_SHADER_CAP_PREFERRED_IR)) { assert(!stvp->glsl_to_tgsi); nir_shader *nir = st_translate_prog_to_nir(st, &stvp->Base, MESA_SHADER_VERTEX); if (stvp->tgsi.ir.nir) ralloc_free(stvp->tgsi.ir.nir); stvp->tgsi.type = PIPE_SHADER_IR_NIR; stvp->tgsi.ir.nir = nir; stvp->Base.nir = nir; return true; } return stvp->tgsi.tokens != NULL; } static const gl_state_index16 depth_range_state[STATE_LENGTH] = { STATE_DEPTH_RANGE }; static struct st_vp_variant * st_create_vp_variant(struct st_context *st, struct st_vertex_program *stvp, const struct st_vp_variant_key *key) { struct st_vp_variant *vpv = CALLOC_STRUCT(st_vp_variant); struct pipe_context *pipe = st->pipe; struct gl_program_parameter_list *params = stvp->Base.Parameters; vpv->key = *key; vpv->tgsi.stream_output = stvp->tgsi.stream_output; vpv->num_inputs = stvp->num_inputs; /* When generating a NIR program, we usually don't have TGSI tokens. * However, we do create them for ARB_vertex_program / fixed-function VS * programs which we may need to use with the draw module for legacy * feedback/select emulation. If they exist, copy them. */ if (stvp->tgsi.tokens) vpv->tgsi.tokens = tgsi_dup_tokens(stvp->tgsi.tokens); if (stvp->tgsi.type == PIPE_SHADER_IR_NIR) { vpv->tgsi.type = PIPE_SHADER_IR_NIR; vpv->tgsi.ir.nir = nir_shader_clone(NULL, stvp->tgsi.ir.nir); if (key->clamp_color) NIR_PASS_V(vpv->tgsi.ir.nir, nir_lower_clamp_color_outputs); if (key->passthrough_edgeflags) { NIR_PASS_V(vpv->tgsi.ir.nir, nir_lower_passthrough_edgeflags); vpv->num_inputs++; } st_finalize_nir(st, &stvp->Base, stvp->shader_program, vpv->tgsi.ir.nir); vpv->driver_shader = pipe->create_vs_state(pipe, &vpv->tgsi); /* driver takes ownership of IR: */ vpv->tgsi.ir.nir = NULL; return vpv; } /* Emulate features. */ if (key->clamp_color || key->passthrough_edgeflags) { const struct tgsi_token *tokens; unsigned flags = (key->clamp_color ? TGSI_EMU_CLAMP_COLOR_OUTPUTS : 0) | (key->passthrough_edgeflags ? TGSI_EMU_PASSTHROUGH_EDGEFLAG : 0); tokens = tgsi_emulate(vpv->tgsi.tokens, flags); if (tokens) { tgsi_free_tokens(vpv->tgsi.tokens); vpv->tgsi.tokens = tokens; if (key->passthrough_edgeflags) vpv->num_inputs++; } else fprintf(stderr, "mesa: cannot emulate deprecated features\n"); } if (key->lower_depth_clamp) { unsigned depth_range_const = _mesa_add_state_reference(params, depth_range_state); const struct tgsi_token *tokens; tokens = st_tgsi_lower_depth_clamp(vpv->tgsi.tokens, depth_range_const, key->clip_negative_one_to_one); if (tokens != vpv->tgsi.tokens) tgsi_free_tokens(vpv->tgsi.tokens); vpv->tgsi.tokens = tokens; } if (ST_DEBUG & DEBUG_TGSI) { tgsi_dump(vpv->tgsi.tokens, 0); debug_printf("\n"); } vpv->driver_shader = pipe->create_vs_state(pipe, &vpv->tgsi); return vpv; } /** * Find/create a vertex program variant. */ struct st_vp_variant * st_get_vp_variant(struct st_context *st, struct st_vertex_program *stvp, const struct st_vp_variant_key *key) { struct st_vp_variant *vpv; /* Search for existing variant */ for (vpv = stvp->variants; vpv; vpv = vpv->next) { if (memcmp(&vpv->key, key, sizeof(*key)) == 0) { break; } } if (!vpv) { /* create now */ vpv = st_create_vp_variant(st, stvp, key); if (vpv) { for (unsigned index = 0; index < vpv->num_inputs; ++index) { unsigned attr = stvp->index_to_input[index]; if (attr == ST_DOUBLE_ATTRIB_PLACEHOLDER) continue; vpv->vert_attrib_mask |= 1u << attr; } /* insert into list */ vpv->next = stvp->variants; stvp->variants = vpv; } } return vpv; } /** * Translate a Mesa fragment shader into a TGSI shader. */ bool st_translate_fragment_program(struct st_context *st, struct st_fragment_program *stfp) { /* Non-GLSL programs: */ if (!stfp->glsl_to_tgsi) { _mesa_remove_output_reads(&stfp->Base, PROGRAM_OUTPUT); if (st->ctx->Const.GLSLFragCoordIsSysVal) _mesa_program_fragment_position_to_sysval(&stfp->Base); /* This determines which states will be updated when the assembly * shader is bound. * * fragment.position and glDrawPixels always use constants. */ stfp->affected_states = ST_NEW_FS_STATE | ST_NEW_SAMPLE_SHADING | ST_NEW_FS_CONSTANTS; if (stfp->ati_fs) { /* Just set them for ATI_fs unconditionally. */ stfp->affected_states |= ST_NEW_FS_SAMPLER_VIEWS | ST_NEW_FS_SAMPLERS; } else { /* ARB_fp */ if (stfp->Base.SamplersUsed) stfp->affected_states |= ST_NEW_FS_SAMPLER_VIEWS | ST_NEW_FS_SAMPLERS; } /* Translate to NIR. */ if (!stfp->ati_fs && st->pipe->screen->get_shader_param(st->pipe->screen, PIPE_SHADER_FRAGMENT, PIPE_SHADER_CAP_PREFERRED_IR)) { nir_shader *nir = st_translate_prog_to_nir(st, &stfp->Base, MESA_SHADER_FRAGMENT); if (stfp->tgsi.ir.nir) ralloc_free(stfp->tgsi.ir.nir); stfp->tgsi.type = PIPE_SHADER_IR_NIR; stfp->tgsi.ir.nir = nir; stfp->Base.nir = nir; return true; } } ubyte outputMapping[2 * FRAG_RESULT_MAX]; ubyte inputMapping[VARYING_SLOT_MAX]; ubyte inputSlotToAttr[VARYING_SLOT_MAX]; ubyte interpMode[PIPE_MAX_SHADER_INPUTS]; /* XXX size? */ GLuint attr; GLbitfield64 inputsRead; struct ureg_program *ureg; GLboolean write_all = GL_FALSE; ubyte input_semantic_name[PIPE_MAX_SHADER_INPUTS]; ubyte input_semantic_index[PIPE_MAX_SHADER_INPUTS]; uint fs_num_inputs = 0; ubyte fs_output_semantic_name[PIPE_MAX_SHADER_OUTPUTS]; ubyte fs_output_semantic_index[PIPE_MAX_SHADER_OUTPUTS]; uint fs_num_outputs = 0; memset(inputSlotToAttr, ~0, sizeof(inputSlotToAttr)); /* * Convert Mesa program inputs to TGSI input register semantics. */ inputsRead = stfp->Base.info.inputs_read; for (attr = 0; attr < VARYING_SLOT_MAX; attr++) { if ((inputsRead & BITFIELD64_BIT(attr)) != 0) { const GLuint slot = fs_num_inputs++; inputMapping[attr] = slot; inputSlotToAttr[slot] = attr; switch (attr) { case VARYING_SLOT_POS: input_semantic_name[slot] = TGSI_SEMANTIC_POSITION; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_LINEAR; break; case VARYING_SLOT_COL0: input_semantic_name[slot] = TGSI_SEMANTIC_COLOR; input_semantic_index[slot] = 0; interpMode[slot] = stfp->glsl_to_tgsi ? TGSI_INTERPOLATE_COUNT : TGSI_INTERPOLATE_COLOR; break; case VARYING_SLOT_COL1: input_semantic_name[slot] = TGSI_SEMANTIC_COLOR; input_semantic_index[slot] = 1; interpMode[slot] = stfp->glsl_to_tgsi ? TGSI_INTERPOLATE_COUNT : TGSI_INTERPOLATE_COLOR; break; case VARYING_SLOT_FOGC: input_semantic_name[slot] = TGSI_SEMANTIC_FOG; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_PERSPECTIVE; break; case VARYING_SLOT_FACE: input_semantic_name[slot] = TGSI_SEMANTIC_FACE; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_CONSTANT; break; case VARYING_SLOT_PRIMITIVE_ID: input_semantic_name[slot] = TGSI_SEMANTIC_PRIMID; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_CONSTANT; break; case VARYING_SLOT_LAYER: input_semantic_name[slot] = TGSI_SEMANTIC_LAYER; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_CONSTANT; break; case VARYING_SLOT_VIEWPORT: input_semantic_name[slot] = TGSI_SEMANTIC_VIEWPORT_INDEX; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_CONSTANT; break; case VARYING_SLOT_CLIP_DIST0: input_semantic_name[slot] = TGSI_SEMANTIC_CLIPDIST; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_PERSPECTIVE; break; case VARYING_SLOT_CLIP_DIST1: input_semantic_name[slot] = TGSI_SEMANTIC_CLIPDIST; input_semantic_index[slot] = 1; interpMode[slot] = TGSI_INTERPOLATE_PERSPECTIVE; break; case VARYING_SLOT_CULL_DIST0: case VARYING_SLOT_CULL_DIST1: /* these should have been lowered by GLSL */ assert(0); break; /* In most cases, there is nothing special about these * inputs, so adopt a convention to use the generic * semantic name and the mesa VARYING_SLOT_ number as the * index. * * All that is required is that the vertex shader labels * its own outputs similarly, and that the vertex shader * generates at least every output required by the * fragment shader plus fixed-function hardware (such as * BFC). * * However, some drivers may need us to identify the PNTC and TEXi * varyings if, for example, their capability to replace them with * sprite coordinates is limited. */ case VARYING_SLOT_PNTC: if (st->needs_texcoord_semantic) { input_semantic_name[slot] = TGSI_SEMANTIC_PCOORD; input_semantic_index[slot] = 0; interpMode[slot] = TGSI_INTERPOLATE_LINEAR; break; } /* fall through */ case VARYING_SLOT_TEX0: case VARYING_SLOT_TEX1: case VARYING_SLOT_TEX2: case VARYING_SLOT_TEX3: case VARYING_SLOT_TEX4: case VARYING_SLOT_TEX5: case VARYING_SLOT_TEX6: case VARYING_SLOT_TEX7: if (st->needs_texcoord_semantic) { input_semantic_name[slot] = TGSI_SEMANTIC_TEXCOORD; input_semantic_index[slot] = attr - VARYING_SLOT_TEX0; interpMode[slot] = stfp->glsl_to_tgsi ? TGSI_INTERPOLATE_COUNT : TGSI_INTERPOLATE_PERSPECTIVE; break; } /* fall through */ case VARYING_SLOT_VAR0: default: /* Semantic indices should be zero-based because drivers may choose * to assign a fixed slot determined by that index. * This is useful because ARB_separate_shader_objects uses location * qualifiers for linkage, and if the semantic index corresponds to * these locations, linkage passes in the driver become unecessary. * * If needs_texcoord_semantic is true, no semantic indices will be * consumed for the TEXi varyings, and we can base the locations of * the user varyings on VAR0. Otherwise, we use TEX0 as base index. */ assert(attr >= VARYING_SLOT_VAR0 || attr == VARYING_SLOT_PNTC || (attr >= VARYING_SLOT_TEX0 && attr <= VARYING_SLOT_TEX7)); input_semantic_name[slot] = TGSI_SEMANTIC_GENERIC; input_semantic_index[slot] = st_get_generic_varying_index(st, attr); if (attr == VARYING_SLOT_PNTC) interpMode[slot] = TGSI_INTERPOLATE_LINEAR; else { interpMode[slot] = stfp->glsl_to_tgsi ? TGSI_INTERPOLATE_COUNT : TGSI_INTERPOLATE_PERSPECTIVE; } break; } } else { inputMapping[attr] = -1; } } /* * Semantics and mapping for outputs */ GLbitfield64 outputsWritten = stfp->Base.info.outputs_written; /* if z is written, emit that first */ if (outputsWritten & BITFIELD64_BIT(FRAG_RESULT_DEPTH)) { fs_output_semantic_name[fs_num_outputs] = TGSI_SEMANTIC_POSITION; fs_output_semantic_index[fs_num_outputs] = 0; outputMapping[FRAG_RESULT_DEPTH] = fs_num_outputs; fs_num_outputs++; outputsWritten &= ~(1 << FRAG_RESULT_DEPTH); } if (outputsWritten & BITFIELD64_BIT(FRAG_RESULT_STENCIL)) { fs_output_semantic_name[fs_num_outputs] = TGSI_SEMANTIC_STENCIL; fs_output_semantic_index[fs_num_outputs] = 0; outputMapping[FRAG_RESULT_STENCIL] = fs_num_outputs; fs_num_outputs++; outputsWritten &= ~(1 << FRAG_RESULT_STENCIL); } if (outputsWritten & BITFIELD64_BIT(FRAG_RESULT_SAMPLE_MASK)) { fs_output_semantic_name[fs_num_outputs] = TGSI_SEMANTIC_SAMPLEMASK; fs_output_semantic_index[fs_num_outputs] = 0; outputMapping[FRAG_RESULT_SAMPLE_MASK] = fs_num_outputs; fs_num_outputs++; outputsWritten &= ~(1 << FRAG_RESULT_SAMPLE_MASK); } /* handle remaining outputs (color) */ for (attr = 0; attr < ARRAY_SIZE(outputMapping); attr++) { const GLbitfield64 written = attr < FRAG_RESULT_MAX ? outputsWritten : stfp->Base.SecondaryOutputsWritten; const unsigned loc = attr % FRAG_RESULT_MAX; if (written & BITFIELD64_BIT(loc)) { switch (loc) { case FRAG_RESULT_DEPTH: case FRAG_RESULT_STENCIL: case FRAG_RESULT_SAMPLE_MASK: /* handled above */ assert(0); break; case FRAG_RESULT_COLOR: write_all = GL_TRUE; /* fallthrough */ default: { int index; assert(loc == FRAG_RESULT_COLOR || (FRAG_RESULT_DATA0 <= loc && loc < FRAG_RESULT_MAX)); index = (loc == FRAG_RESULT_COLOR) ? 0 : (loc - FRAG_RESULT_DATA0); if (attr >= FRAG_RESULT_MAX) { /* Secondary color for dual source blending. */ assert(index == 0); index++; } fs_output_semantic_name[fs_num_outputs] = TGSI_SEMANTIC_COLOR; fs_output_semantic_index[fs_num_outputs] = index; outputMapping[attr] = fs_num_outputs; break; } } fs_num_outputs++; } } ureg = ureg_create_with_screen(PIPE_SHADER_FRAGMENT, st->pipe->screen); if (ureg == NULL) return false; if (ST_DEBUG & DEBUG_MESA) { _mesa_print_program(&stfp->Base); _mesa_print_program_parameters(st->ctx, &stfp->Base); debug_printf("\n"); } if (write_all == GL_TRUE) ureg_property(ureg, TGSI_PROPERTY_FS_COLOR0_WRITES_ALL_CBUFS, 1); if (stfp->Base.info.fs.depth_layout != FRAG_DEPTH_LAYOUT_NONE) { switch (stfp->Base.info.fs.depth_layout) { case FRAG_DEPTH_LAYOUT_ANY: ureg_property(ureg, TGSI_PROPERTY_FS_DEPTH_LAYOUT, TGSI_FS_DEPTH_LAYOUT_ANY); break; case FRAG_DEPTH_LAYOUT_GREATER: ureg_property(ureg, TGSI_PROPERTY_FS_DEPTH_LAYOUT, TGSI_FS_DEPTH_LAYOUT_GREATER); break; case FRAG_DEPTH_LAYOUT_LESS: ureg_property(ureg, TGSI_PROPERTY_FS_DEPTH_LAYOUT, TGSI_FS_DEPTH_LAYOUT_LESS); break; case FRAG_DEPTH_LAYOUT_UNCHANGED: ureg_property(ureg, TGSI_PROPERTY_FS_DEPTH_LAYOUT, TGSI_FS_DEPTH_LAYOUT_UNCHANGED); break; default: assert(0); } } if (stfp->glsl_to_tgsi) { st_translate_program(st->ctx, PIPE_SHADER_FRAGMENT, ureg, stfp->glsl_to_tgsi, &stfp->Base, /* inputs */ fs_num_inputs, inputMapping, inputSlotToAttr, input_semantic_name, input_semantic_index, interpMode, /* outputs */ fs_num_outputs, outputMapping, fs_output_semantic_name, fs_output_semantic_index); free_glsl_to_tgsi_visitor(stfp->glsl_to_tgsi); } else if (stfp->ati_fs) st_translate_atifs_program(ureg, stfp->ati_fs, &stfp->Base, /* inputs */ fs_num_inputs, inputMapping, input_semantic_name, input_semantic_index, interpMode, /* outputs */ fs_num_outputs, outputMapping, fs_output_semantic_name, fs_output_semantic_index); else st_translate_mesa_program(st->ctx, PIPE_SHADER_FRAGMENT, ureg, &stfp->Base, /* inputs */ fs_num_inputs, inputMapping, input_semantic_name, input_semantic_index, interpMode, /* outputs */ fs_num_outputs, outputMapping, fs_output_semantic_name, fs_output_semantic_index); stfp->tgsi.tokens = ureg_get_tokens(ureg, &stfp->num_tgsi_tokens); ureg_destroy(ureg); if (stfp->glsl_to_tgsi) { stfp->glsl_to_tgsi = NULL; st_store_ir_in_disk_cache(st, &stfp->Base, false); } return stfp->tgsi.tokens != NULL; } static struct st_fp_variant * st_create_fp_variant(struct st_context *st, struct st_fragment_program *stfp, const struct st_fp_variant_key *key) { struct pipe_context *pipe = st->pipe; struct st_fp_variant *variant = CALLOC_STRUCT(st_fp_variant); struct pipe_shader_state tgsi = {0}; struct gl_program_parameter_list *params = stfp->Base.Parameters; static const gl_state_index16 texcoord_state[STATE_LENGTH] = { STATE_INTERNAL, STATE_CURRENT_ATTRIB, VERT_ATTRIB_TEX0 }; static const gl_state_index16 scale_state[STATE_LENGTH] = { STATE_INTERNAL, STATE_PT_SCALE }; static const gl_state_index16 bias_state[STATE_LENGTH] = { STATE_INTERNAL, STATE_PT_BIAS }; if (!variant) return NULL; if (stfp->tgsi.type == PIPE_SHADER_IR_NIR) { tgsi.type = PIPE_SHADER_IR_NIR; tgsi.ir.nir = nir_shader_clone(NULL, stfp->tgsi.ir.nir); if (key->clamp_color) NIR_PASS_V(tgsi.ir.nir, nir_lower_clamp_color_outputs); if (key->lower_flatshade) NIR_PASS_V(tgsi.ir.nir, nir_lower_flatshade); if (key->persample_shading) { nir_shader *shader = tgsi.ir.nir; nir_foreach_variable(var, &shader->inputs) var->data.sample = true; } assert(!(key->bitmap && key->drawpixels)); /* glBitmap */ if (key->bitmap) { nir_lower_bitmap_options options = {0}; variant->bitmap_sampler = ffs(~stfp->Base.SamplersUsed) - 1; options.sampler = variant->bitmap_sampler; options.swizzle_xxxx = st->bitmap.tex_format == PIPE_FORMAT_R8_UNORM; NIR_PASS_V(tgsi.ir.nir, nir_lower_bitmap, &options); } /* glDrawPixels (color only) */ if (key->drawpixels) { nir_lower_drawpixels_options options = {{0}}; unsigned samplers_used = stfp->Base.SamplersUsed; /* Find the first unused slot. */ variant->drawpix_sampler = ffs(~samplers_used) - 1; options.drawpix_sampler = variant->drawpix_sampler; samplers_used |= (1 << variant->drawpix_sampler); options.pixel_maps = key->pixelMaps; if (key->pixelMaps) { variant->pixelmap_sampler = ffs(~samplers_used) - 1; options.pixelmap_sampler = variant->pixelmap_sampler; } options.scale_and_bias = key->scaleAndBias; if (key->scaleAndBias) { _mesa_add_state_reference(params, scale_state); memcpy(options.scale_state_tokens, scale_state, sizeof(options.scale_state_tokens)); _mesa_add_state_reference(params, bias_state); memcpy(options.bias_state_tokens, bias_state, sizeof(options.bias_state_tokens)); } _mesa_add_state_reference(params, texcoord_state); memcpy(options.texcoord_state_tokens, texcoord_state, sizeof(options.texcoord_state_tokens)); NIR_PASS_V(tgsi.ir.nir, nir_lower_drawpixels, &options); } if (unlikely(key->external.lower_nv12 || key->external.lower_iyuv || key->external.lower_xy_uxvx || key->external.lower_yx_xuxv || key->external.lower_ayuv || key->external.lower_xyuv)) { nir_lower_tex_options options = {0}; options.lower_y_uv_external = key->external.lower_nv12; options.lower_y_u_v_external = key->external.lower_iyuv; options.lower_xy_uxvx_external = key->external.lower_xy_uxvx; options.lower_yx_xuxv_external = key->external.lower_yx_xuxv; options.lower_ayuv_external = key->external.lower_ayuv; options.lower_xyuv_external = key->external.lower_xyuv; NIR_PASS_V(tgsi.ir.nir, nir_lower_tex, &options); } st_finalize_nir(st, &stfp->Base, stfp->shader_program, tgsi.ir.nir); if (unlikely(key->external.lower_nv12 || key->external.lower_iyuv || key->external.lower_xy_uxvx || key->external.lower_yx_xuxv)) { /* This pass needs to happen *after* nir_lower_sampler */ NIR_PASS_V(tgsi.ir.nir, st_nir_lower_tex_src_plane, ~stfp->Base.SamplersUsed, key->external.lower_nv12 || key->external.lower_xy_uxvx || key->external.lower_yx_xuxv, key->external.lower_iyuv); } /* Some of the lowering above may have introduced new varyings */ nir_shader_gather_info(tgsi.ir.nir, nir_shader_get_entrypoint(tgsi.ir.nir)); variant->driver_shader = pipe->create_fs_state(pipe, &tgsi); variant->key = *key; return variant; } tgsi.tokens = stfp->tgsi.tokens; assert(!(key->bitmap && key->drawpixels)); /* Fix texture targets and add fog for ATI_fs */ if (stfp->ati_fs) { const struct tgsi_token *tokens = st_fixup_atifs(tgsi.tokens, key); if (tokens) tgsi.tokens = tokens; else fprintf(stderr, "mesa: cannot post-process ATI_fs\n"); } /* Emulate features. */ if (key->clamp_color || key->persample_shading) { const struct tgsi_token *tokens; unsigned flags = (key->clamp_color ? TGSI_EMU_CLAMP_COLOR_OUTPUTS : 0) | (key->persample_shading ? TGSI_EMU_FORCE_PERSAMPLE_INTERP : 0); tokens = tgsi_emulate(tgsi.tokens, flags); if (tokens) { if (tgsi.tokens != stfp->tgsi.tokens) tgsi_free_tokens(tgsi.tokens); tgsi.tokens = tokens; } else fprintf(stderr, "mesa: cannot emulate deprecated features\n"); } /* glBitmap */ if (key->bitmap) { const struct tgsi_token *tokens; variant->bitmap_sampler = ffs(~stfp->Base.SamplersUsed) - 1; tokens = st_get_bitmap_shader(tgsi.tokens, st->internal_target, variant->bitmap_sampler, st->needs_texcoord_semantic, st->bitmap.tex_format == PIPE_FORMAT_R8_UNORM); if (tokens) { if (tgsi.tokens != stfp->tgsi.tokens) tgsi_free_tokens(tgsi.tokens); tgsi.tokens = tokens; } else fprintf(stderr, "mesa: cannot create a shader for glBitmap\n"); } /* glDrawPixels (color only) */ if (key->drawpixels) { const struct tgsi_token *tokens; unsigned scale_const = 0, bias_const = 0, texcoord_const = 0; /* Find the first unused slot. */ variant->drawpix_sampler = ffs(~stfp->Base.SamplersUsed) - 1; if (key->pixelMaps) { unsigned samplers_used = stfp->Base.SamplersUsed | (1 << variant->drawpix_sampler); variant->pixelmap_sampler = ffs(~samplers_used) - 1; } if (key->scaleAndBias) { scale_const = _mesa_add_state_reference(params, scale_state); bias_const = _mesa_add_state_reference(params, bias_state); } texcoord_const = _mesa_add_state_reference(params, texcoord_state); tokens = st_get_drawpix_shader(tgsi.tokens, st->needs_texcoord_semantic, key->scaleAndBias, scale_const, bias_const, key->pixelMaps, variant->drawpix_sampler, variant->pixelmap_sampler, texcoord_const, st->internal_target); if (tokens) { if (tgsi.tokens != stfp->tgsi.tokens) tgsi_free_tokens(tgsi.tokens); tgsi.tokens = tokens; } else fprintf(stderr, "mesa: cannot create a shader for glDrawPixels\n"); } if (unlikely(key->external.lower_nv12 || key->external.lower_iyuv || key->external.lower_xy_uxvx || key->external.lower_yx_xuxv)) { const struct tgsi_token *tokens; /* samplers inserted would conflict, but this should be unpossible: */ assert(!(key->bitmap || key->drawpixels)); tokens = st_tgsi_lower_yuv(tgsi.tokens, ~stfp->Base.SamplersUsed, key->external.lower_nv12 || key->external.lower_xy_uxvx || key->external.lower_yx_xuxv, key->external.lower_iyuv); if (tokens) { if (tgsi.tokens != stfp->tgsi.tokens) tgsi_free_tokens(tgsi.tokens); tgsi.tokens = tokens; } else { fprintf(stderr, "mesa: cannot create a shader for samplerExternalOES\n"); } } if (key->lower_depth_clamp) { unsigned depth_range_const = _mesa_add_state_reference(params, depth_range_state); const struct tgsi_token *tokens; tokens = st_tgsi_lower_depth_clamp_fs(tgsi.tokens, depth_range_const); if (tgsi.tokens != stfp->tgsi.tokens) tgsi_free_tokens(tgsi.tokens); tgsi.tokens = tokens; } if (ST_DEBUG & DEBUG_TGSI) { tgsi_dump(tgsi.tokens, 0); debug_printf("\n"); } /* fill in variant */ variant->driver_shader = pipe->create_fs_state(pipe, &tgsi); variant->key = *key; if (tgsi.tokens != stfp->tgsi.tokens) tgsi_free_tokens(tgsi.tokens); return variant; } /** * Translate fragment program if needed. */ struct st_fp_variant * st_get_fp_variant(struct st_context *st, struct st_fragment_program *stfp, const struct st_fp_variant_key *key) { struct st_fp_variant *fpv; /* Search for existing variant */ for (fpv = stfp->variants; fpv; fpv = fpv->next) { if (memcmp(&fpv->key, key, sizeof(*key)) == 0) { break; } } if (!fpv) { /* create new */ fpv = st_create_fp_variant(st, stfp, key); if (fpv) { if (key->bitmap || key->drawpixels) { /* Regular variants should always come before the * bitmap & drawpixels variants, (unless there * are no regular variants) so that * st_update_fp can take a fast path when * shader_has_one_variant is set. */ if (!stfp->variants) { stfp->variants = fpv; } else { /* insert into list after the first one */ fpv->next = stfp->variants->next; stfp->variants->next = fpv; } } else { /* insert into list */ fpv->next = stfp->variants; stfp->variants = fpv; } } } return fpv; } /** * Translate a program. This is common code for geometry and tessellation * shaders. */ bool st_translate_common_program(struct st_context *st, struct st_common_program *stcp) { struct gl_program *prog = &stcp->Base; enum pipe_shader_type stage = pipe_shader_type_from_mesa(stcp->Base.info.stage); struct ureg_program *ureg = ureg_create_with_screen(stage, st->pipe->screen); if (ureg == NULL) return false; switch (stage) { case PIPE_SHADER_TESS_CTRL: ureg_property(ureg, TGSI_PROPERTY_TCS_VERTICES_OUT, stcp->Base.info.tess.tcs_vertices_out); break; case PIPE_SHADER_TESS_EVAL: if (stcp->Base.info.tess.primitive_mode == GL_ISOLINES) ureg_property(ureg, TGSI_PROPERTY_TES_PRIM_MODE, GL_LINES); else ureg_property(ureg, TGSI_PROPERTY_TES_PRIM_MODE, stcp->Base.info.tess.primitive_mode); STATIC_ASSERT((TESS_SPACING_EQUAL + 1) % 3 == PIPE_TESS_SPACING_EQUAL); STATIC_ASSERT((TESS_SPACING_FRACTIONAL_ODD + 1) % 3 == PIPE_TESS_SPACING_FRACTIONAL_ODD); STATIC_ASSERT((TESS_SPACING_FRACTIONAL_EVEN + 1) % 3 == PIPE_TESS_SPACING_FRACTIONAL_EVEN); ureg_property(ureg, TGSI_PROPERTY_TES_SPACING, (stcp->Base.info.tess.spacing + 1) % 3); ureg_property(ureg, TGSI_PROPERTY_TES_VERTEX_ORDER_CW, !stcp->Base.info.tess.ccw); ureg_property(ureg, TGSI_PROPERTY_TES_POINT_MODE, stcp->Base.info.tess.point_mode); break; case PIPE_SHADER_GEOMETRY: ureg_property(ureg, TGSI_PROPERTY_GS_INPUT_PRIM, stcp->Base.info.gs.input_primitive); ureg_property(ureg, TGSI_PROPERTY_GS_OUTPUT_PRIM, stcp->Base.info.gs.output_primitive); ureg_property(ureg, TGSI_PROPERTY_GS_MAX_OUTPUT_VERTICES, stcp->Base.info.gs.vertices_out); ureg_property(ureg, TGSI_PROPERTY_GS_INVOCATIONS, stcp->Base.info.gs.invocations); break; default: break; } ubyte inputSlotToAttr[VARYING_SLOT_TESS_MAX]; ubyte inputMapping[VARYING_SLOT_TESS_MAX]; ubyte outputMapping[VARYING_SLOT_TESS_MAX]; GLuint attr; ubyte input_semantic_name[PIPE_MAX_SHADER_INPUTS]; ubyte input_semantic_index[PIPE_MAX_SHADER_INPUTS]; uint num_inputs = 0; ubyte output_semantic_name[PIPE_MAX_SHADER_OUTPUTS]; ubyte output_semantic_index[PIPE_MAX_SHADER_OUTPUTS]; uint num_outputs = 0; GLint i; memset(inputSlotToAttr, 0, sizeof(inputSlotToAttr)); memset(inputMapping, 0, sizeof(inputMapping)); memset(outputMapping, 0, sizeof(outputMapping)); memset(&stcp->tgsi, 0, sizeof(stcp->tgsi)); if (prog->info.clip_distance_array_size) ureg_property(ureg, TGSI_PROPERTY_NUM_CLIPDIST_ENABLED, prog->info.clip_distance_array_size); if (prog->info.cull_distance_array_size) ureg_property(ureg, TGSI_PROPERTY_NUM_CULLDIST_ENABLED, prog->info.cull_distance_array_size); /* * Convert Mesa program inputs to TGSI input register semantics. */ for (attr = 0; attr < VARYING_SLOT_MAX; attr++) { if ((prog->info.inputs_read & BITFIELD64_BIT(attr)) == 0) continue; unsigned slot = num_inputs++; inputMapping[attr] = slot; inputSlotToAttr[slot] = attr; unsigned semantic_name, semantic_index; tgsi_get_gl_varying_semantic(attr, st->needs_texcoord_semantic, &semantic_name, &semantic_index); input_semantic_name[slot] = semantic_name; input_semantic_index[slot] = semantic_index; } /* Also add patch inputs. */ for (attr = 0; attr < 32; attr++) { if (prog->info.patch_inputs_read & (1u << attr)) { GLuint slot = num_inputs++; GLuint patch_attr = VARYING_SLOT_PATCH0 + attr; inputMapping[patch_attr] = slot; inputSlotToAttr[slot] = patch_attr; input_semantic_name[slot] = TGSI_SEMANTIC_PATCH; input_semantic_index[slot] = attr; } } /* initialize output semantics to defaults */ for (i = 0; i < PIPE_MAX_SHADER_OUTPUTS; i++) { output_semantic_name[i] = TGSI_SEMANTIC_GENERIC; output_semantic_index[i] = 0; } /* * Determine number of outputs, the (default) output register * mapping and the semantic information for each output. */ for (attr = 0; attr < VARYING_SLOT_MAX; attr++) { if (prog->info.outputs_written & BITFIELD64_BIT(attr)) { GLuint slot = num_outputs++; outputMapping[attr] = slot; unsigned semantic_name, semantic_index; tgsi_get_gl_varying_semantic(attr, st->needs_texcoord_semantic, &semantic_name, &semantic_index); output_semantic_name[slot] = semantic_name; output_semantic_index[slot] = semantic_index; } } /* Also add patch outputs. */ for (attr = 0; attr < 32; attr++) { if (prog->info.patch_outputs_written & (1u << attr)) { GLuint slot = num_outputs++; GLuint patch_attr = VARYING_SLOT_PATCH0 + attr; outputMapping[patch_attr] = slot; output_semantic_name[slot] = TGSI_SEMANTIC_PATCH; output_semantic_index[slot] = attr; } } st_translate_program(st->ctx, stage, ureg, stcp->glsl_to_tgsi, prog, /* inputs */ num_inputs, inputMapping, inputSlotToAttr, input_semantic_name, input_semantic_index, NULL, /* outputs */ num_outputs, outputMapping, output_semantic_name, output_semantic_index); stcp->tgsi.tokens = ureg_get_tokens(ureg, &stcp->num_tgsi_tokens); ureg_destroy(ureg); st_translate_stream_output_info(prog); st_store_ir_in_disk_cache(st, prog, false); if ((ST_DEBUG & DEBUG_TGSI) && (ST_DEBUG & DEBUG_MESA)) { _mesa_print_program(prog); debug_printf("\n"); } if (ST_DEBUG & DEBUG_TGSI) { tgsi_dump(stcp->tgsi.tokens, 0); debug_printf("\n"); } free_glsl_to_tgsi_visitor(stcp->glsl_to_tgsi); stcp->glsl_to_tgsi = NULL; return true; } /** * Get/create a basic program variant. */ struct st_basic_variant * st_get_basic_variant(struct st_context *st, struct st_common_program *prog, const struct st_basic_variant_key *key) { struct pipe_context *pipe = st->pipe; struct st_basic_variant *v; struct pipe_shader_state tgsi = {0}; /* Search for existing variant */ for (v = prog->variants; v; v = v->next) { if (memcmp(&v->key, key, sizeof(*key)) == 0) { break; } } if (!v) { /* create new */ v = CALLOC_STRUCT(st_basic_variant); if (v) { if (prog->tgsi.type == PIPE_SHADER_IR_NIR) { tgsi.type = PIPE_SHADER_IR_NIR; tgsi.ir.nir = nir_shader_clone(NULL, prog->tgsi.ir.nir); if (key->clamp_color) NIR_PASS_V(tgsi.ir.nir, nir_lower_clamp_color_outputs); tgsi.stream_output = prog->tgsi.stream_output; st_finalize_nir(st, &prog->Base, prog->shader_program, tgsi.ir.nir); } else { if (key->lower_depth_clamp) { struct gl_program_parameter_list *params = prog->Base.Parameters; unsigned depth_range_const = _mesa_add_state_reference(params, depth_range_state); const struct tgsi_token *tokens; tokens = st_tgsi_lower_depth_clamp(prog->tgsi.tokens, depth_range_const, key->clip_negative_one_to_one); if (tokens != prog->tgsi.tokens) tgsi_free_tokens(prog->tgsi.tokens); prog->tgsi.tokens = tokens; prog->num_tgsi_tokens = tgsi_num_tokens(tokens); } tgsi = prog->tgsi; } /* fill in new variant */ switch (prog->Base.info.stage) { case MESA_SHADER_TESS_CTRL: v->driver_shader = pipe->create_tcs_state(pipe, &tgsi); break; case MESA_SHADER_TESS_EVAL: v->driver_shader = pipe->create_tes_state(pipe, &tgsi); break; case MESA_SHADER_GEOMETRY: v->driver_shader = pipe->create_gs_state(pipe, &tgsi); break; case MESA_SHADER_COMPUTE: { struct pipe_compute_state cs = {0}; cs.ir_type = tgsi.type; cs.req_local_mem = prog->Base.info.cs.shared_size; if (tgsi.type == PIPE_SHADER_IR_NIR) cs.prog = tgsi.ir.nir; else cs.prog = tgsi.tokens; v->driver_shader = pipe->create_compute_state(pipe, &cs); break; } default: assert(!"unhandled shader type"); free(v); return NULL; } v->key = *key; /* insert into list */ v->next = prog->variants; prog->variants = v; } } return v; } /** * Vert/Geom/Frag programs have per-context variants. Free all the * variants attached to the given program which match the given context. */ static void destroy_program_variants(struct st_context *st, struct gl_program *target) { if (!target || target == &_mesa_DummyProgram) return; switch (target->Target) { case GL_VERTEX_PROGRAM_ARB: { struct st_vertex_program *stvp = (struct st_vertex_program *) target; struct st_vp_variant *vpv, **prevPtr = &stvp->variants; for (vpv = stvp->variants; vpv; ) { struct st_vp_variant *next = vpv->next; if (vpv->key.st == st) { /* unlink from list */ *prevPtr = next; /* destroy this variant */ delete_vp_variant(st, vpv); } else { prevPtr = &vpv->next; } vpv = next; } } break; case GL_FRAGMENT_PROGRAM_ARB: { struct st_fragment_program *stfp = (struct st_fragment_program *) target; struct st_fp_variant *fpv, **prevPtr = &stfp->variants; for (fpv = stfp->variants; fpv; ) { struct st_fp_variant *next = fpv->next; if (fpv->key.st == st) { /* unlink from list */ *prevPtr = next; /* destroy this variant */ delete_fp_variant(st, fpv); } else { prevPtr = &fpv->next; } fpv = next; } } break; case GL_GEOMETRY_PROGRAM_NV: case GL_TESS_CONTROL_PROGRAM_NV: case GL_TESS_EVALUATION_PROGRAM_NV: case GL_COMPUTE_PROGRAM_NV: { struct st_common_program *p = st_common_program(target); struct st_basic_variant *v, **prevPtr = &p->variants; for (v = p->variants; v; ) { struct st_basic_variant *next = v->next; if (v->key.st == st) { /* unlink from list */ *prevPtr = next; /* destroy this variant */ delete_basic_variant(st, v, target->Target); } else { prevPtr = &v->next; } v = next; } } break; default: _mesa_problem(NULL, "Unexpected program target 0x%x in " "destroy_program_variants_cb()", target->Target); } } /** * Callback for _mesa_HashWalk. Free all the shader's program variants * which match the given context. */ static void destroy_shader_program_variants_cb(GLuint key, void *data, void *userData) { struct st_context *st = (struct st_context *) userData; struct gl_shader *shader = (struct gl_shader *) data; switch (shader->Type) { case GL_SHADER_PROGRAM_MESA: { struct gl_shader_program *shProg = (struct gl_shader_program *) data; GLuint i; for (i = 0; i < ARRAY_SIZE(shProg->_LinkedShaders); i++) { if (shProg->_LinkedShaders[i]) destroy_program_variants(st, shProg->_LinkedShaders[i]->Program); } } break; case GL_VERTEX_SHADER: case GL_FRAGMENT_SHADER: case GL_GEOMETRY_SHADER: case GL_TESS_CONTROL_SHADER: case GL_TESS_EVALUATION_SHADER: case GL_COMPUTE_SHADER: break; default: assert(0); } } /** * Callback for _mesa_HashWalk. Free all the program variants which match * the given context. */ static void destroy_program_variants_cb(GLuint key, void *data, void *userData) { struct st_context *st = (struct st_context *) userData; struct gl_program *program = (struct gl_program *) data; destroy_program_variants(st, program); } /** * Walk over all shaders and programs to delete any variants which * belong to the given context. * This is called during context tear-down. */ void st_destroy_program_variants(struct st_context *st) { /* If shaders can be shared with other contexts, the last context will * call DeleteProgram on all shaders, releasing everything. */ if (st->has_shareable_shaders) return; /* ARB vert/frag program */ _mesa_HashWalk(st->ctx->Shared->Programs, destroy_program_variants_cb, st); /* GLSL vert/frag/geom shaders */ _mesa_HashWalk(st->ctx->Shared->ShaderObjects, destroy_shader_program_variants_cb, st); } /** * For debugging, print/dump the current vertex program. */ void st_print_current_vertex_program(void) { GET_CURRENT_CONTEXT(ctx); if (ctx->VertexProgram._Current) { struct st_vertex_program *stvp = (struct st_vertex_program *) ctx->VertexProgram._Current; struct st_vp_variant *stv; debug_printf("Vertex program %u\n", stvp->Base.Id); for (stv = stvp->variants; stv; stv = stv->next) { debug_printf("variant %p\n", stv); tgsi_dump(stv->tgsi.tokens, 0); } } } /** * Compile one shader variant. */ void st_precompile_shader_variant(struct st_context *st, struct gl_program *prog) { switch (prog->Target) { case GL_VERTEX_PROGRAM_ARB: { struct st_vertex_program *p = (struct st_vertex_program *)prog; struct st_vp_variant_key key; memset(&key, 0, sizeof(key)); key.st = st->has_shareable_shaders ? NULL : st; st_get_vp_variant(st, p, &key); break; } case GL_FRAGMENT_PROGRAM_ARB: { struct st_fragment_program *p = (struct st_fragment_program *)prog; struct st_fp_variant_key key; memset(&key, 0, sizeof(key)); key.st = st->has_shareable_shaders ? NULL : st; st_get_fp_variant(st, p, &key); break; } case GL_TESS_CONTROL_PROGRAM_NV: case GL_TESS_EVALUATION_PROGRAM_NV: case GL_GEOMETRY_PROGRAM_NV: case GL_COMPUTE_PROGRAM_NV: { struct st_common_program *p = st_common_program(prog); struct st_basic_variant_key key; memset(&key, 0, sizeof(key)); key.st = st->has_shareable_shaders ? NULL : st; st_get_basic_variant(st, p, &key); break; } default: assert(0); } }