// Copyright 2009 Dolphin Emulator Project // Licensed under GPLv2+ // Refer to the license.txt file included. #include "Common/Common.h" #include "Common/FileUtil.h" #include "Common/StringUtil.h" #include "Core/DSP/DSPCodeUtil.h" #include "Core/DSP/DSPHost.h" #include "Core/DSP/DSPTables.h" // Stub out the dsplib host stuff, since this is just a simple cmdline tools. u8 DSPHost::ReadHostMemory(u32 addr) { return 0; } void DSPHost::WriteHostMemory(u8 value, u32 addr) { } void DSPHost::OSD_AddMessage(const std::string& str, u32 ms) { } bool DSPHost::OnThread() { return false; } bool DSPHost::IsWiiHost() { return false; } void DSPHost::CodeLoaded(const u8* ptr, int size) { } void DSPHost::InterruptRequest() { } void DSPHost::UpdateDebugger() { } // This test goes from text ASM to binary to text ASM and once again back to binary. // Then the two binaries are compared. static bool RoundTrip(const std::vector& code1) { std::vector code2; std::string text; if (!Disassemble(code1, false, text)) { printf("RoundTrip: Disassembly failed.\n"); return false; } if (!Assemble(text.c_str(), code2)) { printf("RoundTrip: Assembly failed.\n"); return false; } if (!Compare(code1, code2)) { Disassemble(code1, true, text); printf("%s", text.c_str()); } return true; } // This test goes from text ASM to binary to text ASM and once again back to binary. // Very convenient for testing. Then the two binaries are compared. static bool SuperTrip(const char* asm_code) { std::vector code1, code2; std::string text; if (!Assemble(asm_code, code1)) { printf("SuperTrip: First assembly failed\n"); return false; } printf("First assembly: %i words\n", (int)code1.size()); if (!Disassemble(code1, false, text)) { printf("SuperTrip: Disassembly failed\n"); return false; } else { printf("Disass:\n"); printf("%s", text.c_str()); } if (!Assemble(text.c_str(), code2)) { printf("SuperTrip: Second assembly failed\n"); return false; } /* std::string text2; Disassemble(code1, true, &text1); Disassemble(code2, true, &text2); File::WriteStringToFile(text1, "code1.txt"); File::WriteStringToFile(text2, "code2.txt"); */ return true; } static void RunAsmTests() { bool fail = false; #define CHK(a) \ if (!SuperTrip(a)) \ printf("FAIL\n%s\n", a), fail = true; // Let's start out easy - a trivial instruction.. CHK(" NOP\n"); // Now let's do several. CHK(" NOP\n" " NOP\n" " NOP\n"); // Turning it up a notch. CHK(" SET16\n" " SET40\n" " CLR15\n" " M0\n" " M2\n"); // Time to try labels and parameters, and comments. CHK("DIRQ_TEST: equ 0xfffb ; DSP Irq Request\n" " si @0xfffc, #0x8888\n" " si @0xfffd, #0xbeef\n" " si @DIRQ_TEST, #0x0001\n"); // Let's see if registers roundtrip. Also try predefined labels. CHK(" si @0xfffc, #0x8888\n" " si @0xfffd, #0xbeef\n" " si @DIRQ, #0x0001\n"); // Let's try some messy extended instructions. // CHK(" MULMV'SN $AX0.L, $AX0.H, $ACC0 : @$AR2, $AC1.M\n"); //" ADDAXL'MV $ACC1, $AX1.L : $AX1.H, $AC1.M\n"); // Let's get brutal. We generate random code bytes and make sure that they can // be roundtripped. We don't expect it to always succeed but it'll be sure to generate // interesting test cases. /* std::vector hermes; if (!LoadBinary("testdata/hermes.bin", &hermes)) PanicAlert("Failed to load hermes rom"); RoundTrip(hermes); */ /* std::vector code; std::string text_orig; File::ReadFileToString("testdata/dsp_test.S", &text_orig); if (!Assemble(text_orig.c_str(), &code)) { printf("SuperTrip: First assembly failed\n"); return; }*/ /* { std::vector code; code.clear(); for (int i = 0; i < sizeof(dsp_test)/4; i++) { code.push_back(dsp_test[i] >> 16); code.push_back(dsp_test[i] & 0xFFFF); } SaveBinary(code, "dsp_test2.bin"); RoundTrip(code); }*/ // if (Compare(code, hermes)) // printf("Successs\n"); /* { std::vector code; std::string text; LoadBinary("testdata/dsp_test.bin", &code); Disassemble(code, true, &text); Assemble(text.c_str(), &code); Disassemble(code, true, &text); printf("%s", text.c_str()); }*/ /* puts("Insane Random Code Test\n"); std::vector rand_code; GenRandomCode(30, &rand_code); std::string rand_code_text; Disassemble(rand_code, true, &rand_code_text); printf("%s", rand_code_text.c_str()); RoundTrip(rand_code); if (File::ReadFileToString("C:/devkitPro/examples/wii/asndlib/dsptest/dsp_test.ds", &dsp_test)) SuperTrip(dsp_test.c_str()); //.File::ReadFileToString("C:/devkitPro/trunk/libogc/libasnd/dsp_mixer/dsp_mixer.s", &dsp_test); // This is CLOSE to working. Sorry about the local path btw. This is preliminary code. */ std::string dsp_test; if (File::ReadFileToString("Testdata/dsp_test.s", dsp_test)) fail = fail || !SuperTrip(dsp_test.c_str()); if (!fail) printf("All passed!\n"); } // Usage: // Run internal tests: // dsptool test // Disassemble a file: // dsptool -d -o asdf.txt asdf.bin // Disassemble a file, output to standard output: // dsptool -d asdf.bin // Assemble a file: // dsptool [-f] -o asdf.bin asdf.txt // Assemble a file, output header: // dsptool [-f] -h asdf.h asdf.txt // Print results from DSPSpy register dump // dsptool -p dsp_dump0.bin // So far, all this binary can do is test partially that itself works correctly. int main(int argc, const char* argv[]) { if (argc == 1 || (argc == 2 && (!strcmp(argv[1], "--help") || (!strcmp(argv[1], "-?"))))) { printf("USAGE: DSPTool [-?] [--help] [-f] [-d] [-m] [-p ] [-o ] [-h ] \n"); printf("-? / --help: Prints this message\n"); printf("-d: Disassemble\n"); printf("-m: Input file contains a list of files (Header assembly only)\n"); printf("-s: Print the final size in bytes (only)\n"); printf("-f: Force assembly (errors are not critical)\n"); printf("-o : Results from stdout redirected to a file\n"); printf("-h

: Output assembly results to a header\n"); printf("-p : Print results of DSPSpy register dump\n"); printf("-ps : Print results of DSPSpy register dump (disable SR output)\n"); printf("-pm : Print results of DSPSpy register dump (convert PROD values)\n"); printf("-psm : Print results of DSPSpy register dump (convert PROD values/disable " "SR output)\n"); return 0; } if (argc == 2 && !strcmp(argv[1], "test")) { RunAsmTests(); return 0; } std::string input_name; std::string output_header_name; std::string output_name; bool disassemble = false, compare = false, multiple = false, outputSize = false, force = false, print_results = false, print_results_prodhack = false, print_results_srhack = false; for (int i = 1; i < argc; i++) { if (!strcmp(argv[i], "-d")) disassemble = true; else if (!strcmp(argv[i], "-o")) output_name = argv[++i]; else if (!strcmp(argv[i], "-h")) output_header_name = argv[++i]; else if (!strcmp(argv[i], "-c")) compare = true; else if (!strcmp(argv[i], "-s")) outputSize = true; else if (!strcmp(argv[i], "-m")) multiple = true; else if (!strcmp(argv[i], "-f")) force = true; else if (!strcmp(argv[i], "-p")) print_results = true; else if (!strcmp(argv[i], "-ps")) { print_results = true; print_results_srhack = true; } else if (!strcmp(argv[i], "-pm")) { print_results = true; print_results_prodhack = true; } else if (!strcmp(argv[i], "-psm")) { print_results = true; print_results_srhack = true; print_results_prodhack = true; } else { if (!input_name.empty()) { printf("ERROR: Can only take one input file.\n"); return 1; } input_name = argv[i]; if (!File::Exists(input_name)) { printf("ERROR: Input path does not exist.\n"); return 1; } } } if (multiple && (compare || disassemble || !output_name.empty() || input_name.empty())) { printf("ERROR: Multiple files can only be used with assembly " "and must compile a header file.\n"); return 1; } if (compare) { // Two binary inputs, let's diff. std::string binary_code; std::vector code1, code2; File::ReadFileToString(input_name.c_str(), binary_code); BinaryStringBEToCode(binary_code, code1); File::ReadFileToString(output_name.c_str(), binary_code); BinaryStringBEToCode(binary_code, code2); Compare(code1, code2); return 0; } if (print_results) { std::string dumpfile, results; std::vector reg_vector; File::ReadFileToString(input_name.c_str(), dumpfile); BinaryStringBEToCode(dumpfile, reg_vector); results.append("Start:\n"); for (int initial_reg = 0; initial_reg < 32; initial_reg++) { results.append(StringFromFormat("%02x %04x ", initial_reg, reg_vector.at(initial_reg))); if ((initial_reg + 1) % 8 == 0) results.append("\n"); } results.append("\n"); results.append("Step [number]:\n[Reg] [last value] [current value]\n\n"); for (unsigned int step = 1; step < reg_vector.size() / 32; step++) { bool changed = false; u16 current_reg; u16 last_reg; u32 htemp; // results.append(StringFromFormat("Step %3d: (CW 0x%04x) UC:%03d\n", step, 0x8fff+step, // (step-1)/32)); results.append(StringFromFormat("Step %3d:\n", step)); for (int reg = 0; reg < 32; reg++) { if ((reg >= 0x0c) && (reg <= 0x0f)) continue; if (print_results_srhack && (reg == 0x13)) continue; if ((print_results_prodhack) && (reg >= 0x15) && (reg <= 0x17)) { switch (reg) { case 0x15: // DSP_REG_PRODM last_reg = reg_vector.at((step * 32 - 32) + reg) + reg_vector.at((step * 32 - 32) + reg + 2); current_reg = reg_vector.at(step * 32 + reg) + reg_vector.at(step * 32 + reg + 2); break; case 0x16: // DSP_REG_PRODH htemp = ((reg_vector.at(step * 32 + reg - 1) + reg_vector.at(step * 32 + reg + 1)) & ~0xffff) >> 16; current_reg = (u8)(reg_vector.at(step * 32 + reg) + htemp); htemp = ((reg_vector.at(step * 32 - 32 + reg - 1) + reg_vector.at(step * 32 - 32 + reg + 1)) & ~0xffff) >> 16; last_reg = (u8)(reg_vector.at(step * 32 - 32 + reg) + htemp); break; case 0x17: // DSP_REG_PRODM2 default: current_reg = 0; last_reg = 0; break; } } else { current_reg = reg_vector.at(step * 32 + reg); last_reg = reg_vector.at((step * 32 - 32) + reg); } if (last_reg != current_reg) { results.append(StringFromFormat("%02x %-7s: %04x %04x\n", reg, pdregname(reg), last_reg, current_reg)); changed = true; } } if (!changed) results.append("No Change\n\n"); else results.append("\n"); } if (!output_name.empty()) File::WriteStringToFile(results, output_name.c_str()); else printf("%s", results.c_str()); return 0; } if (disassemble) { if (input_name.empty()) { printf("Disassemble: Must specify input.\n"); return 1; } std::string binary_code; std::vector code; File::ReadFileToString(input_name.c_str(), binary_code); BinaryStringBEToCode(binary_code, code); std::string text; Disassemble(code, true, text); if (!output_name.empty()) File::WriteStringToFile(text, output_name.c_str()); else printf("%s", text.c_str()); } else { if (input_name.empty()) { printf("Assemble: Must specify input.\n"); return 1; } std::string source; if (File::ReadFileToString(input_name.c_str(), source)) { if (multiple) { // When specifying a list of files we must compile a header // (we can't assemble multiple files to one binary) // since we checked it before, we assume output_header_name isn't empty int lines; std::vector* codes; std::vector files; std::string header, currentSource; size_t lastPos = 0, pos = 0; source.append("\n"); while ((pos = source.find('\n', lastPos)) != std::string::npos) { std::string temp = source.substr(lastPos, pos - lastPos); if (!temp.empty()) files.push_back(temp); lastPos = pos + 1; } lines = (int)files.size(); if (lines == 0) { printf("ERROR: Must specify at least one file\n"); return 1; } codes = new std::vector[lines]; for (int i = 0; i < lines; i++) { if (!File::ReadFileToString(files[i].c_str(), currentSource)) { printf("ERROR reading %s, skipping...\n", files[i].c_str()); lines--; } else { if (!Assemble(currentSource.c_str(), codes[i], force)) { printf("Assemble: Assembly of %s failed due to errors\n", files[i].c_str()); lines--; } if (outputSize) { printf("%s: %d\n", files[i].c_str(), (int)codes[i].size()); } } } CodesToHeader(codes, &files, lines, output_header_name.c_str(), header); File::WriteStringToFile(header, (output_header_name + ".h").c_str()); delete[] codes; } else { std::vector code; if (!Assemble(source.c_str(), code, force)) { printf("Assemble: Assembly failed due to errors\n"); return 1; } if (outputSize) { printf("%s: %d\n", input_name.c_str(), (int)code.size()); } if (!output_name.empty()) { std::string binary_code; CodeToBinaryStringBE(code, binary_code); File::WriteStringToFile(binary_code, output_name.c_str()); } if (!output_header_name.empty()) { std::string header; CodeToHeader(code, input_name, output_header_name.c_str(), header); File::WriteStringToFile(header, (output_header_name + ".h").c_str()); } } } source.clear(); } if (disassemble) { printf("Disassembly completed successfully!\n"); } else { if (!outputSize) printf("Assembly completed successfully!\n"); } return 0; }