/* * Copyright © 2018 Google * * 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 "aco_interface.h" #include "aco_ir.h" #include "util/memstream.h" #include "vulkan/radv_shader.h" #include "vulkan/radv_shader_args.h" #include #include static aco_compiler_statistic_info statistic_infos[] = { [aco::statistic_hash] = {"Hash", "CRC32 hash of code and constant data"}, [aco::statistic_instructions] = {"Instructions", "Instruction count"}, [aco::statistic_copies] = {"Copies", "Copy instructions created for pseudo-instructions"}, [aco::statistic_branches] = {"Branches", "Branch instructions"}, [aco::statistic_cycles] = {"Busy Cycles", "Estimate of busy cycles"}, [aco::statistic_vmem_clauses] = {"VMEM Clause", "Number of VMEM clauses (includes 1-sized clauses)"}, [aco::statistic_smem_clauses] = {"SMEM Clause", "Number of SMEM clauses (includes 1-sized clauses)"}, [aco::statistic_vmem_score] = {"VMEM Score", "Average VMEM def-use distances"}, [aco::statistic_smem_score] = {"SMEM Score", "Average SMEM def-use distances"}, [aco::statistic_sgpr_presched] = {"Pre-Sched SGPRs", "SGPR usage before scheduling"}, [aco::statistic_vgpr_presched] = {"Pre-Sched VGPRs", "VGPR usage before scheduling"}, }; static void validate(aco::Program *program) { if (!(aco::debug_flags & aco::DEBUG_VALIDATE_IR)) return; ASSERTED bool is_valid = aco::validate_ir(program); assert(is_valid); } void aco_compile_shader(unsigned shader_count, struct nir_shader *const *shaders, struct radv_shader_binary **binary, struct radv_shader_args *args) { aco::init(); ac_shader_config config = {0}; std::unique_ptr program{new aco::Program}; program->collect_statistics = args->options->record_stats; if (program->collect_statistics) memset(program->statistics, 0, sizeof(program->statistics)); program->debug.func = args->options->debug.func; program->debug.private_data = args->options->debug.private_data; /* Instruction Selection */ if (args->is_gs_copy_shader) aco::select_gs_copy_shader(program.get(), shaders[0], &config, args); else if (args->is_trap_handler_shader) aco::select_trap_handler_shader(program.get(), shaders[0], &config, args); else aco::select_program(program.get(), shader_count, shaders, &config, args); if (args->options->dump_preoptir) { std::cerr << "After Instruction Selection:\n"; aco_print_program(program.get(), stderr); } aco::live live_vars; if (!args->is_trap_handler_shader) { /* Phi lowering */ aco::lower_phis(program.get()); aco::dominator_tree(program.get()); validate(program.get()); /* Optimization */ if (!args->options->disable_optimizations) { if (!(aco::debug_flags & aco::DEBUG_NO_VN)) aco::value_numbering(program.get()); if (!(aco::debug_flags & aco::DEBUG_NO_OPT)) aco::optimize(program.get()); } /* cleanup and exec mask handling */ aco::setup_reduce_temp(program.get()); aco::insert_exec_mask(program.get()); validate(program.get()); /* spilling and scheduling */ live_vars = aco::live_var_analysis(program.get()); aco::spill(program.get(), live_vars); } std::string llvm_ir; if (args->options->record_ir) { char *data = NULL; size_t size = 0; u_memstream mem; if (u_memstream_open(&mem, &data, &size)) { FILE *const memf = u_memstream_get(&mem); aco_print_program(program.get(), memf); fputc(0, memf); u_memstream_close(&mem); } llvm_ir = std::string(data, data + size); free(data); } if (program->collect_statistics) aco::collect_presched_stats(program.get()); if (!args->is_trap_handler_shader) { if (!args->options->disable_optimizations && !(aco::debug_flags & aco::DEBUG_NO_SCHED)) aco::schedule_program(program.get(), live_vars); validate(program.get()); /* Register Allocation */ aco::register_allocation(program.get(), live_vars.live_out); if (args->options->dump_shader) { std::cerr << "After RA:\n"; aco_print_program(program.get(), stderr); } if (aco::validate_ra(program.get())) { std::cerr << "Program after RA validation failure:\n"; aco_print_program(program.get(), stderr); abort(); } validate(program.get()); aco::ssa_elimination(program.get()); } /* Lower to HW Instructions */ aco::lower_to_hw_instr(program.get()); /* Insert Waitcnt */ aco::insert_wait_states(program.get()); aco::insert_NOPs(program.get()); if (program->collect_statistics) aco::collect_preasm_stats(program.get()); /* Assembly */ std::vector code; unsigned exec_size = aco::emit_program(program.get(), code); if (program->collect_statistics) aco::collect_postasm_stats(program.get(), code); bool get_disasm = args->options->dump_shader || args->options->record_ir; size_t size = llvm_ir.size(); std::string disasm; if (get_disasm) { std::ostringstream stream; if (aco::print_asm(program.get(), code, exec_size / 4u, stream)) { std::cerr << "Failed to disassemble program:\n"; aco_print_program(program.get(), stderr); std::cerr << stream.str() << std::endl; abort(); } stream << '\0'; disasm = stream.str(); size += disasm.size(); } size_t stats_size = 0; if (program->collect_statistics) stats_size = sizeof(aco_compiler_statistics) + aco::num_statistics * sizeof(uint32_t); size += stats_size; size += code.size() * sizeof(uint32_t) + sizeof(radv_shader_binary_legacy); /* We need to calloc to prevent unintialized data because this will be used * directly for the disk cache. Uninitialized data can appear because of * padding in the struct or because legacy_binary->data can be at an offset * from the start less than sizeof(radv_shader_binary_legacy). */ radv_shader_binary_legacy* legacy_binary = (radv_shader_binary_legacy*) calloc(size, 1); legacy_binary->base.type = RADV_BINARY_TYPE_LEGACY; legacy_binary->base.stage = shaders[shader_count-1]->info.stage; legacy_binary->base.is_gs_copy_shader = args->is_gs_copy_shader; legacy_binary->base.total_size = size; if (program->collect_statistics) { aco_compiler_statistics *statistics = (aco_compiler_statistics *)legacy_binary->data; statistics->count = aco::num_statistics; statistics->infos = statistic_infos; memcpy(statistics->values, program->statistics, aco::num_statistics * sizeof(uint32_t)); } legacy_binary->stats_size = stats_size; memcpy(legacy_binary->data + legacy_binary->stats_size, code.data(), code.size() * sizeof(uint32_t)); legacy_binary->exec_size = exec_size; legacy_binary->code_size = code.size() * sizeof(uint32_t); legacy_binary->config = config; legacy_binary->disasm_size = 0; legacy_binary->ir_size = llvm_ir.size(); llvm_ir.copy((char*) legacy_binary->data + legacy_binary->stats_size + legacy_binary->code_size, llvm_ir.size()); if (get_disasm) { disasm.copy((char*) legacy_binary->data + legacy_binary->stats_size + legacy_binary->code_size + llvm_ir.size(), disasm.size()); legacy_binary->disasm_size = disasm.size(); } *binary = (radv_shader_binary*) legacy_binary; }