/* * Copyright © 2018 Valve Corporation * * SPDX-License-Identifier: MIT */ #include "aco_ir.h" #include "util/u_debug.h" #if AMD_LLVM_AVAILABLE #if defined(_MSC_VER) && defined(restrict) #undef restrict #endif #include "llvm/ac_llvm_util.h" #include "llvm-c/Disassembler.h" #include #include #endif #include #include #include namespace aco { namespace { std::vector get_referenced_blocks(Program* program) { std::vector referenced_blocks(program->blocks.size()); referenced_blocks[0] = true; for (Block& block : program->blocks) { for (unsigned succ : block.linear_succs) referenced_blocks[succ] = true; } return referenced_blocks; } void print_block_markers(FILE* output, Program* program, const std::vector& referenced_blocks, unsigned* next_block, unsigned pos) { while (*next_block < program->blocks.size() && pos == program->blocks[*next_block].offset) { if (referenced_blocks[*next_block]) fprintf(output, "BB%u:\n", *next_block); (*next_block)++; } } void print_instr(FILE* output, const std::vector& binary, char* instr, unsigned size, unsigned pos) { fprintf(output, "%-60s ;", instr); for (unsigned i = 0; i < size; i++) fprintf(output, " %.8x", binary[pos + i]); fputc('\n', output); } void print_constant_data(FILE* output, Program* program) { if (program->constant_data.empty()) return; fputs("\n/* constant data */\n", output); for (unsigned i = 0; i < program->constant_data.size(); i += 32) { fprintf(output, "[%.6u]", i); unsigned line_size = std::min(program->constant_data.size() - i, 32); for (unsigned j = 0; j < line_size; j += 4) { unsigned size = std::min(program->constant_data.size() - (i + j), 4); uint32_t v = 0; memcpy(&v, &program->constant_data[i + j], size); fprintf(output, " %.8x", v); } fputc('\n', output); } } /** * Determines the GPU type to use for CLRXdisasm */ const char* to_clrx_device_name(amd_gfx_level gfx_level, radeon_family family) { switch (gfx_level) { case GFX6: switch (family) { case CHIP_TAHITI: return "tahiti"; case CHIP_PITCAIRN: return "pitcairn"; case CHIP_VERDE: return "capeverde"; case CHIP_OLAND: return "oland"; case CHIP_HAINAN: return "hainan"; default: return nullptr; } case GFX7: switch (family) { case CHIP_BONAIRE: return "bonaire"; case CHIP_KAVERI: return "gfx700"; case CHIP_HAWAII: return "hawaii"; default: return nullptr; } case GFX8: switch (family) { case CHIP_TONGA: return "tonga"; case CHIP_ICELAND: return "iceland"; case CHIP_CARRIZO: return "carrizo"; case CHIP_FIJI: return "fiji"; case CHIP_STONEY: return "stoney"; case CHIP_POLARIS10: return "polaris10"; case CHIP_POLARIS11: return "polaris11"; case CHIP_POLARIS12: return "polaris12"; case CHIP_VEGAM: return "polaris11"; default: return nullptr; } case GFX9: switch (family) { case CHIP_VEGA10: return "vega10"; case CHIP_VEGA12: return "vega12"; case CHIP_VEGA20: return "vega20"; case CHIP_RAVEN: return "raven"; default: return nullptr; } case GFX10: switch (family) { case CHIP_NAVI10: return "gfx1010"; case CHIP_NAVI12: return "gfx1011"; default: return nullptr; } default: return nullptr; } } bool get_branch_target(char** output, Program* program, const std::vector& referenced_blocks, char** line_start) { unsigned pos; if (sscanf(*line_start, ".L%d_0", &pos) != 1) return false; pos /= 4; *line_start = strchr(*line_start, '_') + 2; for (Block& block : program->blocks) { if (referenced_blocks[block.index] && block.offset == pos) { *output += sprintf(*output, "BB%u", block.index); return true; } } return false; } bool print_asm_clrx(Program* program, std::vector& binary, unsigned exec_size, FILE* output) { #ifdef _WIN32 return true; #else char path[] = "/tmp/fileXXXXXX"; char line[2048], command[128]; FILE* p; int fd; const char* gpu_type = to_clrx_device_name(program->gfx_level, program->family); /* Dump the binary into a temporary file. */ fd = mkstemp(path); if (fd < 0) return true; for (unsigned i = 0; i < exec_size; i++) { if (write(fd, &binary[i], 4) == -1) goto fail; } sprintf(command, "clrxdisasm --gpuType=%s -r %s", gpu_type, path); p = popen(command, "r"); if (p) { if (!fgets(line, sizeof(line), p)) { fprintf(output, "clrxdisasm not found\n"); pclose(p); goto fail; } std::vector referenced_blocks = get_referenced_blocks(program); unsigned next_block = 0; char prev_instr[2048]; unsigned prev_pos = 0; do { char* line_start = line; if (strncmp(line_start, "/*", 2)) continue; unsigned pos; if (sscanf(line_start, "/*%x*/", &pos) != 1) continue; pos /= 4u; /* get the dword position */ while (strncmp(line_start, "*/", 2)) line_start++; line_start += 2; while (line_start[0] == ' ') line_start++; *strchr(line_start, '\n') = 0; if (*line_start == 0) continue; /* not an instruction, only a comment */ if (pos != prev_pos) { /* Print the previous instruction, now that we know the encoding size. */ print_instr(output, binary, prev_instr, pos - prev_pos, prev_pos); prev_pos = pos; } print_block_markers(output, program, referenced_blocks, &next_block, pos); char* dest = prev_instr; *(dest++) = '\t'; while (*line_start) { if (!strncmp(line_start, ".L", 2) && get_branch_target(&dest, program, referenced_blocks, &line_start)) continue; *(dest++) = *(line_start++); } *(dest++) = 0; } while (fgets(line, sizeof(line), p)); if (prev_pos != exec_size) print_instr(output, binary, prev_instr, exec_size - prev_pos, prev_pos); pclose(p); print_constant_data(output, program); } return false; fail: close(fd); unlink(path); return true; #endif } #if AMD_LLVM_AVAILABLE std::pair disasm_instr(amd_gfx_level gfx_level, LLVMDisasmContextRef disasm, uint32_t* binary, unsigned exec_size, size_t pos, char* outline, unsigned outline_size) { size_t l = LLVMDisasmInstruction(disasm, (uint8_t*)&binary[pos], (exec_size - pos) * sizeof(uint32_t), pos * 4, outline, outline_size); if (gfx_level >= GFX10 && l == 8 && ((binary[pos] & 0xffff0000) == 0xd7610000) && ((binary[pos + 1] & 0x1ff) == 0xff)) { /* v_writelane with literal uses 3 dwords but llvm consumes only 2 */ l += 4; } bool invalid = false; size_t size; if (!l && ((gfx_level >= GFX9 && (binary[pos] & 0xffff8000) == 0xd1348000) || /* v_add_u32_e64 + clamp */ (gfx_level >= GFX10 && (binary[pos] & 0xffff8000) == 0xd7038000) || /* v_add_u16_e64 + clamp */ (gfx_level <= GFX9 && (binary[pos] & 0xffff8000) == 0xd1268000) || /* v_add_u16_e64 + clamp */ (gfx_level >= GFX10 && (binary[pos] & 0xffff8000) == 0xd76d8000) || /* v_add3_u32 + clamp */ (gfx_level == GFX9 && (binary[pos] & 0xffff8000) == 0xd1ff8000)) /* v_add3_u32 + clamp */) { strcpy(outline, "\tinteger addition + clamp"); bool has_literal = gfx_level >= GFX10 && (((binary[pos + 1] & 0x1ff) == 0xff) || (((binary[pos + 1] >> 9) & 0x1ff) == 0xff)); size = 2 + has_literal; } else if (gfx_level >= GFX10 && l == 4 && ((binary[pos] & 0xfe0001ff) == 0x020000f9)) { strcpy(outline, "\tv_cndmask_b32 + sdwa"); size = 2; } else if (!l) { strcpy(outline, "(invalid instruction)"); size = 1; invalid = true; } else { assert(l % 4 == 0); size = l / 4; } return std::make_pair(invalid, size); } bool print_asm_llvm(Program* program, std::vector& binary, unsigned exec_size, FILE* output) { std::vector referenced_blocks = get_referenced_blocks(program); std::vector symbols; std::vector> block_names; block_names.reserve(program->blocks.size()); for (Block& block : program->blocks) { if (!referenced_blocks[block.index]) continue; std::array name; sprintf(name.data(), "BB%u", block.index); block_names.push_back(name); symbols.emplace_back(block.offset * 4, llvm::StringRef(block_names[block_names.size() - 1].data()), 0); } const char* features = ""; if (program->gfx_level >= GFX10 && program->wave_size == 64) { features = "+wavefrontsize64"; } LLVMDisasmContextRef disasm = LLVMCreateDisasmCPUFeatures("amdgcn-mesa-mesa3d", ac_get_llvm_processor_name(program->family), features, &symbols, 0, NULL, NULL); size_t pos = 0; bool invalid = false; unsigned next_block = 0; unsigned prev_size = 0; unsigned prev_pos = 0; unsigned repeat_count = 0; while (pos <= exec_size) { bool new_block = next_block < program->blocks.size() && pos == program->blocks[next_block].offset; if (pos + prev_size <= exec_size && prev_pos != pos && !new_block && memcmp(&binary[prev_pos], &binary[pos], prev_size * 4) == 0) { repeat_count++; pos += prev_size; continue; } else { if (repeat_count) fprintf(output, "\t(then repeated %u times)\n", repeat_count); repeat_count = 0; } print_block_markers(output, program, referenced_blocks, &next_block, pos); /* For empty last block, only print block marker. */ if (pos == exec_size) break; char outline[1024]; std::pair res = disasm_instr(program->gfx_level, disasm, binary.data(), exec_size, pos, outline, sizeof(outline)); invalid |= res.first; print_instr(output, binary, outline, res.second, pos); prev_size = res.second; prev_pos = pos; pos += res.second; } assert(next_block == program->blocks.size()); LLVMDisasmDispose(disasm); print_constant_data(output, program); return invalid; } #endif /* AMD_LLVM_AVAILABLE */ } /* end namespace */ bool check_print_asm_support(Program* program) { #if AMD_LLVM_AVAILABLE if (program->gfx_level >= GFX8) { /* LLVM disassembler only supports GFX8+ */ const char* name = ac_get_llvm_processor_name(program->family); const char* triple = "amdgcn--"; LLVMTargetRef target = ac_get_llvm_target(triple); LLVMTargetMachineRef tm = LLVMCreateTargetMachine( target, triple, name, "", LLVMCodeGenLevelDefault, LLVMRelocDefault, LLVMCodeModelDefault); bool supported = ac_is_llvm_processor_supported(tm, name); LLVMDisposeTargetMachine(tm); if (supported) return true; } #endif #ifndef _WIN32 /* Check if CLRX disassembler binary is available and can disassemble the program */ return to_clrx_device_name(program->gfx_level, program->family) && system("clrxdisasm --version > /dev/null 2>&1") == 0; #else return false; #endif } /* Returns true on failure */ bool print_asm(Program* program, std::vector& binary, unsigned exec_size, FILE* output) { #if AMD_LLVM_AVAILABLE if (program->gfx_level >= GFX8) { return print_asm_llvm(program, binary, exec_size, output); } #endif return print_asm_clrx(program, binary, exec_size, output); } } // namespace aco