/* * Copyright © 2016-2017 Broadcom * * 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 (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 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. */ #include "broadcom/common/v3d_device_info.h" #include "v3d_compiler.h" int vir_get_non_sideband_nsrc(struct qinst *inst) { switch (inst->qpu.type) { case V3D_QPU_INSTR_TYPE_BRANCH: return 0; case V3D_QPU_INSTR_TYPE_ALU: if (inst->qpu.alu.add.op != V3D_QPU_A_NOP) return v3d_qpu_add_op_num_src(inst->qpu.alu.add.op); else return v3d_qpu_mul_op_num_src(inst->qpu.alu.mul.op); } return 0; } int vir_get_nsrc(struct qinst *inst) { int nsrc = vir_get_non_sideband_nsrc(inst); if (vir_has_implicit_uniform(inst)) nsrc++; return nsrc; } bool vir_has_implicit_uniform(struct qinst *inst) { switch (inst->qpu.type) { case V3D_QPU_INSTR_TYPE_BRANCH: return true; case V3D_QPU_INSTR_TYPE_ALU: switch (inst->dst.file) { case QFILE_TLBU: return true; default: return inst->has_implicit_uniform; } } return false; } /* The sideband uniform for textures gets stored after the normal ALU * arguments. */ int vir_get_implicit_uniform_src(struct qinst *inst) { if (!vir_has_implicit_uniform(inst)) return -1; return vir_get_nsrc(inst) - 1; } /** * Returns whether the instruction has any side effects that must be * preserved. */ bool vir_has_side_effects(struct v3d_compile *c, struct qinst *inst) { switch (inst->qpu.type) { case V3D_QPU_INSTR_TYPE_BRANCH: return true; case V3D_QPU_INSTR_TYPE_ALU: switch (inst->qpu.alu.add.op) { case V3D_QPU_A_SETREVF: case V3D_QPU_A_SETMSF: case V3D_QPU_A_VPMSETUP: case V3D_QPU_A_STVPMV: case V3D_QPU_A_STVPMD: case V3D_QPU_A_STVPMP: case V3D_QPU_A_VPMWT: case V3D_QPU_A_TMUWT: return true; default: break; } switch (inst->qpu.alu.mul.op) { case V3D_QPU_M_MULTOP: return true; default: break; } } if (inst->qpu.sig.ldtmu || inst->qpu.sig.ldvary || inst->qpu.sig.wrtmuc || inst->qpu.sig.thrsw) { return true; } return false; } bool vir_is_float_input(struct qinst *inst) { /* XXX: More instrs */ switch (inst->qpu.type) { case V3D_QPU_INSTR_TYPE_BRANCH: return false; case V3D_QPU_INSTR_TYPE_ALU: switch (inst->qpu.alu.add.op) { case V3D_QPU_A_FADD: case V3D_QPU_A_FSUB: case V3D_QPU_A_FMIN: case V3D_QPU_A_FMAX: case V3D_QPU_A_FTOIN: return true; default: break; } switch (inst->qpu.alu.mul.op) { case V3D_QPU_M_FMOV: case V3D_QPU_M_VFMUL: case V3D_QPU_M_FMUL: return true; default: break; } } return false; } bool vir_is_raw_mov(struct qinst *inst) { if (inst->qpu.type != V3D_QPU_INSTR_TYPE_ALU || (inst->qpu.alu.mul.op != V3D_QPU_M_FMOV && inst->qpu.alu.mul.op != V3D_QPU_M_MOV)) { return false; } if (inst->qpu.alu.add.output_pack != V3D_QPU_PACK_NONE || inst->qpu.alu.mul.output_pack != V3D_QPU_PACK_NONE) { return false; } if (inst->qpu.flags.ac != V3D_QPU_COND_NONE || inst->qpu.flags.mc != V3D_QPU_COND_NONE) return false; return true; } bool vir_is_add(struct qinst *inst) { return (inst->qpu.type == V3D_QPU_INSTR_TYPE_ALU && inst->qpu.alu.add.op != V3D_QPU_A_NOP); } bool vir_is_mul(struct qinst *inst) { return (inst->qpu.type == V3D_QPU_INSTR_TYPE_ALU && inst->qpu.alu.mul.op != V3D_QPU_M_NOP); } bool vir_is_tex(struct qinst *inst) { if (inst->dst.file == QFILE_MAGIC) return v3d_qpu_magic_waddr_is_tmu(inst->dst.index); if (inst->qpu.type == V3D_QPU_INSTR_TYPE_ALU && inst->qpu.alu.add.op == V3D_QPU_A_TMUWT) { return true; } return false; } bool vir_depends_on_flags(struct qinst *inst) { if (inst->qpu.type == V3D_QPU_INSTR_TYPE_BRANCH) { return (inst->qpu.branch.cond != V3D_QPU_BRANCH_COND_ALWAYS); } else { return (inst->qpu.flags.ac != V3D_QPU_COND_NONE && inst->qpu.flags.mc != V3D_QPU_COND_NONE); } } bool vir_writes_r3(const struct v3d_device_info *devinfo, struct qinst *inst) { for (int i = 0; i < vir_get_nsrc(inst); i++) { switch (inst->src[i].file) { case QFILE_VPM: return true; default: break; } } if (devinfo->ver < 41 && (inst->qpu.sig.ldvary || inst->qpu.sig.ldtlb || inst->qpu.sig.ldtlbu || inst->qpu.sig.ldvpm)) { return true; } return false; } bool vir_writes_r4(const struct v3d_device_info *devinfo, struct qinst *inst) { switch (inst->dst.file) { case QFILE_MAGIC: switch (inst->dst.index) { case V3D_QPU_WADDR_RECIP: case V3D_QPU_WADDR_RSQRT: case V3D_QPU_WADDR_EXP: case V3D_QPU_WADDR_LOG: case V3D_QPU_WADDR_SIN: return true; } break; default: break; } if (devinfo->ver < 41 && inst->qpu.sig.ldtmu) return true; return false; } void vir_set_unpack(struct qinst *inst, int src, enum v3d_qpu_input_unpack unpack) { assert(src == 0 || src == 1); if (vir_is_add(inst)) { if (src == 0) inst->qpu.alu.add.a_unpack = unpack; else inst->qpu.alu.add.b_unpack = unpack; } else { assert(vir_is_mul(inst)); if (src == 0) inst->qpu.alu.mul.a_unpack = unpack; else inst->qpu.alu.mul.b_unpack = unpack; } } void vir_set_cond(struct qinst *inst, enum v3d_qpu_cond cond) { if (vir_is_add(inst)) { inst->qpu.flags.ac = cond; } else { assert(vir_is_mul(inst)); inst->qpu.flags.mc = cond; } } void vir_set_pf(struct qinst *inst, enum v3d_qpu_pf pf) { if (vir_is_add(inst)) { inst->qpu.flags.apf = pf; } else { assert(vir_is_mul(inst)); inst->qpu.flags.mpf = pf; } } #if 0 uint8_t vir_channels_written(struct qinst *inst) { if (vir_is_mul(inst)) { switch (inst->dst.pack) { case QPU_PACK_MUL_NOP: case QPU_PACK_MUL_8888: return 0xf; case QPU_PACK_MUL_8A: return 0x1; case QPU_PACK_MUL_8B: return 0x2; case QPU_PACK_MUL_8C: return 0x4; case QPU_PACK_MUL_8D: return 0x8; } } else { switch (inst->dst.pack) { case QPU_PACK_A_NOP: case QPU_PACK_A_8888: case QPU_PACK_A_8888_SAT: case QPU_PACK_A_32_SAT: return 0xf; case QPU_PACK_A_8A: case QPU_PACK_A_8A_SAT: return 0x1; case QPU_PACK_A_8B: case QPU_PACK_A_8B_SAT: return 0x2; case QPU_PACK_A_8C: case QPU_PACK_A_8C_SAT: return 0x4; case QPU_PACK_A_8D: case QPU_PACK_A_8D_SAT: return 0x8; case QPU_PACK_A_16A: case QPU_PACK_A_16A_SAT: return 0x3; case QPU_PACK_A_16B: case QPU_PACK_A_16B_SAT: return 0xc; } } unreachable("Bad pack field"); } #endif struct qreg vir_get_temp(struct v3d_compile *c) { struct qreg reg; reg.file = QFILE_TEMP; reg.index = c->num_temps++; if (c->num_temps > c->defs_array_size) { uint32_t old_size = c->defs_array_size; c->defs_array_size = MAX2(old_size * 2, 16); c->defs = reralloc(c, c->defs, struct qinst *, c->defs_array_size); memset(&c->defs[old_size], 0, sizeof(c->defs[0]) * (c->defs_array_size - old_size)); c->spillable = reralloc(c, c->spillable, BITSET_WORD, BITSET_WORDS(c->defs_array_size)); for (int i = old_size; i < c->defs_array_size; i++) BITSET_SET(c->spillable, i); } return reg; } struct qinst * vir_add_inst(enum v3d_qpu_add_op op, struct qreg dst, struct qreg src0, struct qreg src1) { struct qinst *inst = calloc(1, sizeof(*inst)); inst->qpu = v3d_qpu_nop(); inst->qpu.alu.add.op = op; inst->dst = dst; inst->src[0] = src0; inst->src[1] = src1; inst->uniform = ~0; return inst; } struct qinst * vir_mul_inst(enum v3d_qpu_mul_op op, struct qreg dst, struct qreg src0, struct qreg src1) { struct qinst *inst = calloc(1, sizeof(*inst)); inst->qpu = v3d_qpu_nop(); inst->qpu.alu.mul.op = op; inst->dst = dst; inst->src[0] = src0; inst->src[1] = src1; inst->uniform = ~0; return inst; } struct qinst * vir_branch_inst(enum v3d_qpu_branch_cond cond, struct qreg src) { struct qinst *inst = calloc(1, sizeof(*inst)); inst->qpu = v3d_qpu_nop(); inst->qpu.type = V3D_QPU_INSTR_TYPE_BRANCH; inst->qpu.branch.cond = cond; inst->qpu.branch.msfign = V3D_QPU_MSFIGN_NONE; inst->qpu.branch.bdi = V3D_QPU_BRANCH_DEST_REL; inst->qpu.branch.ub = true; inst->qpu.branch.bdu = V3D_QPU_BRANCH_DEST_REL; inst->dst = vir_reg(QFILE_NULL, 0); inst->src[0] = src; inst->uniform = ~0; return inst; } static void vir_emit(struct v3d_compile *c, struct qinst *inst) { switch (c->cursor.mode) { case vir_cursor_add: list_add(&inst->link, c->cursor.link); break; case vir_cursor_addtail: list_addtail(&inst->link, c->cursor.link); break; } c->cursor = vir_after_inst(inst); c->live_intervals_valid = false; } /* Updates inst to write to a new temporary, emits it, and notes the def. */ struct qreg vir_emit_def(struct v3d_compile *c, struct qinst *inst) { assert(inst->dst.file == QFILE_NULL); /* If we're emitting an instruction that's a def, it had better be * writing a register. */ if (inst->qpu.type == V3D_QPU_INSTR_TYPE_ALU) { assert(inst->qpu.alu.add.op == V3D_QPU_A_NOP || v3d_qpu_add_op_has_dst(inst->qpu.alu.add.op)); assert(inst->qpu.alu.mul.op == V3D_QPU_M_NOP || v3d_qpu_mul_op_has_dst(inst->qpu.alu.mul.op)); } inst->dst = vir_get_temp(c); if (inst->dst.file == QFILE_TEMP) c->defs[inst->dst.index] = inst; vir_emit(c, inst); return inst->dst; } struct qinst * vir_emit_nondef(struct v3d_compile *c, struct qinst *inst) { if (inst->dst.file == QFILE_TEMP) c->defs[inst->dst.index] = NULL; vir_emit(c, inst); return inst; } struct qblock * vir_new_block(struct v3d_compile *c) { struct qblock *block = rzalloc(c, struct qblock); list_inithead(&block->instructions); block->predecessors = _mesa_set_create(block, _mesa_hash_pointer, _mesa_key_pointer_equal); block->index = c->next_block_index++; return block; } void vir_set_emit_block(struct v3d_compile *c, struct qblock *block) { c->cur_block = block; c->cursor = vir_after_block(block); list_addtail(&block->link, &c->blocks); } struct qblock * vir_entry_block(struct v3d_compile *c) { return list_first_entry(&c->blocks, struct qblock, link); } struct qblock * vir_exit_block(struct v3d_compile *c) { return list_last_entry(&c->blocks, struct qblock, link); } void vir_link_blocks(struct qblock *predecessor, struct qblock *successor) { _mesa_set_add(successor->predecessors, predecessor); if (predecessor->successors[0]) { assert(!predecessor->successors[1]); predecessor->successors[1] = successor; } else { predecessor->successors[0] = successor; } } const struct v3d_compiler * v3d_compiler_init(const struct v3d_device_info *devinfo) { struct v3d_compiler *compiler = rzalloc(NULL, struct v3d_compiler); if (!compiler) return NULL; compiler->devinfo = devinfo; if (!vir_init_reg_sets(compiler)) { ralloc_free(compiler); return NULL; } return compiler; } void v3d_compiler_free(const struct v3d_compiler *compiler) { ralloc_free((void *)compiler); } static struct v3d_compile * vir_compile_init(const struct v3d_compiler *compiler, struct v3d_key *key, nir_shader *s, int program_id, int variant_id) { struct v3d_compile *c = rzalloc(NULL, struct v3d_compile); c->compiler = compiler; c->devinfo = compiler->devinfo; c->key = key; c->program_id = program_id; c->variant_id = variant_id; c->threads = 4; s = nir_shader_clone(c, s); c->s = s; list_inithead(&c->blocks); vir_set_emit_block(c, vir_new_block(c)); c->output_position_index = -1; c->output_point_size_index = -1; c->output_sample_mask_index = -1; c->def_ht = _mesa_hash_table_create(c, _mesa_hash_pointer, _mesa_key_pointer_equal); return c; } static int type_size_vec4(const struct glsl_type *type) { return glsl_count_attribute_slots(type, false); } static void v3d_lower_nir(struct v3d_compile *c) { struct nir_lower_tex_options tex_options = { .lower_txd = true, .lower_rect = false, /* XXX: Use this on V3D 3.x */ .lower_txp = ~0, /* Apply swizzles to all samplers. */ .swizzle_result = ~0, }; /* Lower the format swizzle and (for 32-bit returns) * ARB_texture_swizzle-style swizzle. */ for (int i = 0; i < ARRAY_SIZE(c->key->tex); i++) { for (int j = 0; j < 4; j++) tex_options.swizzles[i][j] = c->key->tex[i].swizzle[j]; if (c->key->tex[i].clamp_s) tex_options.saturate_s |= 1 << i; if (c->key->tex[i].clamp_t) tex_options.saturate_t |= 1 << i; if (c->key->tex[i].clamp_r) tex_options.saturate_r |= 1 << i; } NIR_PASS_V(c->s, nir_lower_tex, &tex_options); } static void v3d_lower_nir_late(struct v3d_compile *c) { NIR_PASS_V(c->s, v3d_nir_lower_io, c); NIR_PASS_V(c->s, v3d_nir_lower_txf_ms, c); NIR_PASS_V(c->s, nir_lower_idiv); } static void v3d_set_prog_data_uniforms(struct v3d_compile *c, struct v3d_prog_data *prog_data) { int count = c->num_uniforms; struct v3d_uniform_list *ulist = &prog_data->uniforms; ulist->count = count; ulist->data = ralloc_array(prog_data, uint32_t, count); memcpy(ulist->data, c->uniform_data, count * sizeof(*ulist->data)); ulist->contents = ralloc_array(prog_data, enum quniform_contents, count); memcpy(ulist->contents, c->uniform_contents, count * sizeof(*ulist->contents)); } /* Copy the compiler UBO range state to the compiled shader, dropping out * arrays that were never referenced by an indirect load. * * (Note that QIR dead code elimination of an array access still leaves that * array alive, though) */ static void v3d_set_prog_data_ubo(struct v3d_compile *c, struct v3d_prog_data *prog_data) { if (!c->num_ubo_ranges) return; prog_data->num_ubo_ranges = 0; prog_data->ubo_ranges = ralloc_array(prog_data, struct v3d_ubo_range, c->num_ubo_ranges); for (int i = 0; i < c->num_ubo_ranges; i++) { if (!c->ubo_range_used[i]) continue; struct v3d_ubo_range *range = &c->ubo_ranges[i]; prog_data->ubo_ranges[prog_data->num_ubo_ranges++] = *range; prog_data->ubo_size += range->size; } if (prog_data->ubo_size) { if (V3D_DEBUG & V3D_DEBUG_SHADERDB) { fprintf(stderr, "SHADER-DB: %s prog %d/%d: %d UBO uniforms\n", vir_get_stage_name(c), c->program_id, c->variant_id, prog_data->ubo_size / 4); } } } static void v3d_set_prog_data(struct v3d_compile *c, struct v3d_prog_data *prog_data) { prog_data->threads = c->threads; prog_data->single_seg = !c->last_thrsw; prog_data->spill_size = c->spill_size; v3d_set_prog_data_uniforms(c, prog_data); v3d_set_prog_data_ubo(c, prog_data); } static uint64_t * v3d_return_qpu_insts(struct v3d_compile *c, uint32_t *final_assembly_size) { *final_assembly_size = c->qpu_inst_count * sizeof(uint64_t); uint64_t *qpu_insts = malloc(*final_assembly_size); if (!qpu_insts) return NULL; memcpy(qpu_insts, c->qpu_insts, *final_assembly_size); vir_compile_destroy(c); return qpu_insts; } uint64_t *v3d_compile_vs(const struct v3d_compiler *compiler, struct v3d_vs_key *key, struct v3d_vs_prog_data *prog_data, nir_shader *s, int program_id, int variant_id, uint32_t *final_assembly_size) { struct v3d_compile *c = vir_compile_init(compiler, &key->base, s, program_id, variant_id); c->vs_key = key; /* Split our I/O vars and dead code eliminate the unused * components. */ NIR_PASS_V(c->s, nir_lower_io_to_scalar_early, nir_var_shader_in | nir_var_shader_out); uint64_t used_outputs[4] = {0}; for (int i = 0; i < c->vs_key->num_fs_inputs; i++) { int slot = v3d_slot_get_slot(c->vs_key->fs_inputs[i]); int comp = v3d_slot_get_component(c->vs_key->fs_inputs[i]); used_outputs[comp] |= 1ull << slot; } NIR_PASS_V(c->s, nir_remove_unused_io_vars, &c->s->outputs, used_outputs, NULL); /* demotes to globals */ NIR_PASS_V(c->s, nir_lower_global_vars_to_local); v3d_optimize_nir(c->s); NIR_PASS_V(c->s, nir_remove_dead_variables, nir_var_shader_in); NIR_PASS_V(c->s, nir_lower_io, nir_var_shader_in | nir_var_shader_out, type_size_vec4, (nir_lower_io_options)0); v3d_lower_nir(c); if (key->clamp_color) NIR_PASS_V(c->s, nir_lower_clamp_color_outputs); if (key->base.ucp_enables) { NIR_PASS_V(c->s, nir_lower_clip_vs, key->base.ucp_enables); NIR_PASS_V(c->s, nir_lower_io_to_scalar, nir_var_shader_out); } /* Note: VS output scalarizing must happen after nir_lower_clip_vs. */ NIR_PASS_V(c->s, nir_lower_io_to_scalar, nir_var_shader_out); v3d_lower_nir_late(c); v3d_optimize_nir(c->s); NIR_PASS_V(c->s, nir_convert_from_ssa, true); v3d_nir_to_vir(c); v3d_set_prog_data(c, &prog_data->base); prog_data->base.num_inputs = c->num_inputs; /* The vertex data gets format converted by the VPM so that * each attribute channel takes up a VPM column. Precompute * the sizes for the shader record. */ for (int i = 0; i < ARRAY_SIZE(prog_data->vattr_sizes); i++) { prog_data->vattr_sizes[i] = c->vattr_sizes[i]; prog_data->vpm_input_size += c->vattr_sizes[i]; } prog_data->uses_vid = (s->info.system_values_read & (1ull << SYSTEM_VALUE_VERTEX_ID)); prog_data->uses_iid = (s->info.system_values_read & (1ull << SYSTEM_VALUE_INSTANCE_ID)); if (prog_data->uses_vid) prog_data->vpm_input_size++; if (prog_data->uses_iid) prog_data->vpm_input_size++; /* Input/output segment size are in sectors (8 rows of 32 bits per * channel). */ prog_data->vpm_input_size = align(prog_data->vpm_input_size, 8) / 8; prog_data->vpm_output_size = align(c->num_vpm_writes, 8) / 8; /* Compute VCM cache size. We set up our program to take up less than * half of the VPM, so that any set of bin and render programs won't * run out of space. We need space for at least one input segment, * and then allocate the rest to output segments (one for the current * program, the rest to VCM). The valid range of the VCM cache size * field is 1-4 16-vertex batches, but GFXH-1744 limits us to 2-4 * batches. */ assert(c->devinfo->vpm_size); int sector_size = 16 * sizeof(uint32_t) * 8; int vpm_size_in_sectors = c->devinfo->vpm_size / sector_size; int half_vpm = vpm_size_in_sectors / 2; int vpm_output_sectors = half_vpm - prog_data->vpm_input_size; int vpm_output_batches = vpm_output_sectors / prog_data->vpm_output_size; assert(vpm_output_batches >= 2); prog_data->vcm_cache_size = CLAMP(vpm_output_batches - 1, 2, 4); return v3d_return_qpu_insts(c, final_assembly_size); } static void v3d_set_fs_prog_data_inputs(struct v3d_compile *c, struct v3d_fs_prog_data *prog_data) { prog_data->base.num_inputs = c->num_inputs; memcpy(prog_data->input_slots, c->input_slots, c->num_inputs * sizeof(*c->input_slots)); STATIC_ASSERT(ARRAY_SIZE(prog_data->flat_shade_flags) > (V3D_MAX_FS_INPUTS - 1) / 24); for (int i = 0; i < V3D_MAX_FS_INPUTS; i++) { if (BITSET_TEST(c->flat_shade_flags, i)) prog_data->flat_shade_flags[i / 24] |= 1 << (i % 24); if (BITSET_TEST(c->noperspective_flags, i)) prog_data->noperspective_flags[i / 24] |= 1 << (i % 24); if (BITSET_TEST(c->centroid_flags, i)) prog_data->centroid_flags[i / 24] |= 1 << (i % 24); } } static void v3d_fixup_fs_output_types(struct v3d_compile *c) { nir_foreach_variable(var, &c->s->outputs) { uint32_t mask = 0; switch (var->data.location) { case FRAG_RESULT_COLOR: mask = ~0; break; case FRAG_RESULT_DATA0: case FRAG_RESULT_DATA1: case FRAG_RESULT_DATA2: case FRAG_RESULT_DATA3: mask = 1 << (var->data.location - FRAG_RESULT_DATA0); break; } if (c->fs_key->int_color_rb & mask) { var->type = glsl_vector_type(GLSL_TYPE_INT, glsl_get_components(var->type)); } else if (c->fs_key->uint_color_rb & mask) { var->type = glsl_vector_type(GLSL_TYPE_UINT, glsl_get_components(var->type)); } } } uint64_t *v3d_compile_fs(const struct v3d_compiler *compiler, struct v3d_fs_key *key, struct v3d_fs_prog_data *prog_data, nir_shader *s, int program_id, int variant_id, uint32_t *final_assembly_size) { struct v3d_compile *c = vir_compile_init(compiler, &key->base, s, program_id, variant_id); c->fs_key = key; if (key->int_color_rb || key->uint_color_rb) v3d_fixup_fs_output_types(c); v3d_lower_nir(c); if (key->light_twoside) NIR_PASS_V(c->s, nir_lower_two_sided_color); if (key->clamp_color) NIR_PASS_V(c->s, nir_lower_clamp_color_outputs); if (key->alpha_test) { NIR_PASS_V(c->s, nir_lower_alpha_test, key->alpha_test_func, false); } if (key->base.ucp_enables) NIR_PASS_V(c->s, nir_lower_clip_fs, key->base.ucp_enables); /* Note: FS input scalarizing must happen after * nir_lower_two_sided_color, which only handles a vec4 at a time. */ NIR_PASS_V(c->s, nir_lower_io_to_scalar, nir_var_shader_in); v3d_lower_nir_late(c); v3d_optimize_nir(c->s); NIR_PASS_V(c->s, nir_convert_from_ssa, true); v3d_nir_to_vir(c); v3d_set_prog_data(c, &prog_data->base); v3d_set_fs_prog_data_inputs(c, prog_data); prog_data->writes_z = (c->s->info.outputs_written & (1 << FRAG_RESULT_DEPTH)); prog_data->discard = (c->s->info.fs.uses_discard || c->fs_key->sample_alpha_to_coverage); prog_data->uses_center_w = c->uses_center_w; return v3d_return_qpu_insts(c, final_assembly_size); } void vir_remove_instruction(struct v3d_compile *c, struct qinst *qinst) { if (qinst->dst.file == QFILE_TEMP) c->defs[qinst->dst.index] = NULL; assert(&qinst->link != c->cursor.link); list_del(&qinst->link); free(qinst); c->live_intervals_valid = false; } struct qreg vir_follow_movs(struct v3d_compile *c, struct qreg reg) { /* XXX int pack = reg.pack; while (reg.file == QFILE_TEMP && c->defs[reg.index] && (c->defs[reg.index]->op == QOP_MOV || c->defs[reg.index]->op == QOP_FMOV) && !c->defs[reg.index]->dst.pack && !c->defs[reg.index]->src[0].pack) { reg = c->defs[reg.index]->src[0]; } reg.pack = pack; */ return reg; } void vir_compile_destroy(struct v3d_compile *c) { /* Defuse the assert that we aren't removing the cursor's instruction. */ c->cursor.link = NULL; vir_for_each_block(block, c) { while (!list_empty(&block->instructions)) { struct qinst *qinst = list_first_entry(&block->instructions, struct qinst, link); vir_remove_instruction(c, qinst); } } ralloc_free(c); } struct qreg vir_uniform(struct v3d_compile *c, enum quniform_contents contents, uint32_t data) { for (int i = 0; i < c->num_uniforms; i++) { if (c->uniform_contents[i] == contents && c->uniform_data[i] == data) { return vir_reg(QFILE_UNIF, i); } } uint32_t uniform = c->num_uniforms++; if (uniform >= c->uniform_array_size) { c->uniform_array_size = MAX2(MAX2(16, uniform + 1), c->uniform_array_size * 2); c->uniform_data = reralloc(c, c->uniform_data, uint32_t, c->uniform_array_size); c->uniform_contents = reralloc(c, c->uniform_contents, enum quniform_contents, c->uniform_array_size); } c->uniform_contents[uniform] = contents; c->uniform_data[uniform] = data; return vir_reg(QFILE_UNIF, uniform); } static bool vir_can_set_flags(struct v3d_compile *c, struct qinst *inst) { if (c->devinfo->ver >= 40 && (v3d_qpu_reads_vpm(&inst->qpu) || v3d_qpu_uses_sfu(&inst->qpu))) { return false; } return true; } void vir_PF(struct v3d_compile *c, struct qreg src, enum v3d_qpu_pf pf) { struct qinst *last_inst = NULL; if (!list_empty(&c->cur_block->instructions)) { last_inst = (struct qinst *)c->cur_block->instructions.prev; /* Can't stuff the PF into the last last inst if our cursor * isn't pointing after it. */ struct vir_cursor after_inst = vir_after_inst(last_inst); if (c->cursor.mode != after_inst.mode || c->cursor.link != after_inst.link) last_inst = NULL; } if (src.file != QFILE_TEMP || !c->defs[src.index] || last_inst != c->defs[src.index] || !vir_can_set_flags(c, last_inst)) { /* XXX: Make the MOV be the appropriate type */ last_inst = vir_MOV_dest(c, vir_reg(QFILE_NULL, 0), src); } vir_set_pf(last_inst, pf); } #define OPTPASS(func) \ do { \ bool stage_progress = func(c); \ if (stage_progress) { \ progress = true; \ if (print_opt_debug) { \ fprintf(stderr, \ "VIR opt pass %2d: %s progress\n", \ pass, #func); \ } \ /*XXX vir_validate(c);*/ \ } \ } while (0) void vir_optimize(struct v3d_compile *c) { bool print_opt_debug = false; int pass = 1; while (true) { bool progress = false; OPTPASS(vir_opt_copy_propagate); OPTPASS(vir_opt_dead_code); OPTPASS(vir_opt_small_immediates); if (!progress) break; pass++; } } const char * vir_get_stage_name(struct v3d_compile *c) { if (c->vs_key && c->vs_key->is_coord) return "MESA_SHADER_COORD"; else return gl_shader_stage_name(c->s->info.stage); }