/* * Copyright (c) 2013, Kelvin W Sherlock * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "loader.h" #include "address_map.h" #include "debugger.h" #include "debugger_internal.h" #include #include #include #include #include #include #include #include namespace { using namespace Debug::Internal; const uint32_t kGlobalSize = 0x10000; const uint32_t kBackTraceSize = 20; bool sigInt = false; bool memBreak = false; void sigIntHandler(int) { sigInt = true; } AddressMap brkMap; // address breaks AddressMap rbrkMap; // read breaks. AddressMap wbrkMap; // write breaks. ToolMap tbrkMap; // tool breaks. struct BackTraceInfo { uint32_t a[8]; uint32_t d[8]; uint32_t pc; uint16_t csr; BackTraceInfo(bool populate = false) { if (populate) { for (unsigned i = 0; i < 8; ++i) a[i] = cpuGetAReg(i); for (unsigned i = 0; i < 8; ++i) d[i] = cpuGetDReg(i); pc = cpuGetPC(); csr = cpuGetSR(); } } }; std::deque BackTrace; void hexdump(const uint8_t *data, ssize_t size, uint32_t address = 0) { const char *HexMap = "0123456789abcdef"; char buffer1[16 * 3 + 1 + 1]; char buffer2[16 + 1]; ssize_t offset = 0; unsigned i, j; while(size > 0) { std::memset(buffer1, ' ', sizeof(buffer1)); std::memset(buffer2, ' ', sizeof(buffer2)); unsigned linelen = (unsigned)std::min(size, (ssize_t)16); for (i = 0, j = 0; i < linelen; i++) { unsigned x = data[i]; buffer1[j++] = HexMap[x >> 4]; buffer1[j++] = HexMap[x & 0x0f]; j++; if (i == 7) j++; // isascii not part of std:: and may be a macro. buffer2[i] = isascii(x) && std::isprint(x) ? x : '.'; } buffer1[sizeof(buffer1)-1] = 0; buffer2[sizeof(buffer2)-1] = 0; std::printf("%06x: %s %s\n", address + (unsigned)offset, buffer1, buffer2); offset += 16; data += 16; size -= 16; } std::printf("\n"); } void printMacsbug(uint32_t pc, uint32_t opcode, uint32_t *newPC = nullptr) { // pc is actually pc after the opcode. unsigned mboffset; switch(opcode) { case 0x4E75: // rts case 0x4ED0: // jmp (a0) mboffset = 2; break; case 0x4E74: // rtd # mboffset = 4; break; default: return; break; } pc += mboffset; // check for MacsBug name after rts. std::string s; unsigned b = Debug::ReadByte(pc); if (b >= 0x80 && b <= 0x9f) { b -= 0x80; pc++; if (!b) b = Debug::ReadByte(pc++); s.reserve(b); for (unsigned i = 0; i < b; ++i) { s.push_back(Debug::ReadByte(pc++)); } printf(" %s\n\n", s.c_str()); // word-align pc = pc + 1 & ~0x01; // and possibly a zero-word after it. if (Debug::ReadWord(pc) == 0x0000) pc += 2; if (newPC) *newPC = pc; } } // TODO -- state indicator for code/data uint32_t disasm(uint32_t pc, uint16_t *op = nullptr) { static char strings[4][256]; if (pc >= Flags.memorySize) { if (op) *op = 0; return pc; } uint16_t opcode = Debug::ReadWord(pc); if (op) *op = opcode; if ((opcode & 0xf000) == 0xa000) { const char *name; name = TrapName(opcode); if (name) { printf("$%08X %-51s ; %04X\n", pc, name, opcode); } else { printf("$%08X Tool #$%04X ; %04X\n", pc, opcode, opcode); } pc += 2; return pc; } for (unsigned j = 0; j < 4; ++j) strings[j][0] = 0; uint32_t newpc = cpuDisOpcode(pc, strings[0], strings[1], strings[2], strings[3]); // replace jsr address w/ jsr macsbug name, if possible. // jsr offset(pc) uint32_t address = 0; switch (opcode) { case 0x4EBA: // jsr offset(pc) { int16_t offset = Debug::ReadWord(pc + 2); address = pc + 2 + offset; break; } case 0x4EB9: // jsr address { address = Debug::ReadLong(pc + 2); break; } case 0x4EF9: // jmp address { address = Debug::ReadLong(pc + 2); break; } case 0x4EAD: // jsr offset(a5) { // check if address is a jmp address (see above) // and follow it. a5 should never change. int16_t offset = Debug::ReadWord(pc + 2); address = cpuGetAReg(5) + offset; if (Debug::ReadWord(address) == 0x4EF9) address = Debug::ReadLong(address + 2); else address = 0; break; } // consider checking branches? } if (address) { auto iter = SymbolTableInvert.find(address); if (iter != SymbolTableInvert.end()) { strncpy(strings[3], iter->second.c_str(), 40); strings[3][40] = 0; } } printf("%s %-10s %-40s ; %s\n", strings[0], strings[2], strings[3], strings[1]); printMacsbug(pc, opcode, &newpc); return newpc; } bool step(bool trace) { // return false to break (toolbreak, address break, etc.) uint16_t op; memBreak = false; //uint32_t prevPC = cpuGetPC(); // backtracing. store contents before the instruction. if (BackTrace.size() == kBackTraceSize) { BackTrace.pop_front(); } BackTrace.emplace_back(true); //BackTrace.back().pc = prevPC; cpuExecuteInstruction(); uint32_t pc = cpuGetPC(); if (trace) disasm(pc, &op); else op = Debug::ReadWord(pc); if (Flags.traceMacsbug && !trace) printMacsbug(pc, op); // will this also be set by an interrupt? if (cpuGetStop()) { if (!trace) disasm(pc); printf("CPU stopped\n"); return false; } if (sigInt) { if (!trace) disasm(pc); printf("^C break\n"); sigInt = false; return false; } if (memBreak) { if (!trace) disasm(pc); printf("Memory break\n"); memBreak = false; return false; } // check for pc breaks if (brkMap.lookup(pc)) { if (!trace) disasm(pc); printf("Address break: $%08x\n", pc); return false; } // todo -- instruction break for rts /rtn // check for toolbreaks. if ((op & 0xf000) == 0xa000) { if (tbrkMap.lookup(op)) { if (!trace) disasm(pc); printf("Tool break: $%04x\n", op); return false; } } if (pc > Flags.memorySize) { printf("PC out of range\n"); return false; } uint32_t sp = cpuGetAReg(7); if (sp < Flags.stackRange.first) { printf("Stack overflow error\n"); return false; } if (sp > Flags.stackRange.second) { printf("Stack underflow error\n"); return false; } return true; } static void LogWrite(int size, uint32_t value) { fprintf(stdout, " write %d bytes", size); switch(size) { case 1: fprintf(stdout, " [%02x]\n", value); break; case 2: fprintf(stdout, " [%04x]\n", value); break; case 3: fprintf(stdout, " [%06x]\n", value); break; case 4: fprintf(stdout, " [%08x]\n", value); break; default: fprintf(stdout, "\n"); break; } } void MemoryLogger(uint32_t address, int size, int readWrite, uint32_t value) { if (address < kGlobalSize && Flags.traceGlobals) { const char *name = GlobalName(address); if (!name) name = "unknown"; fprintf(stdout, "%-20s %08x - ", name, address); if (readWrite) { LogWrite(size, value); } else { fprintf(stdout, " read %d bytes\n", size); } } // check for memory breaks. if (readWrite) { // todo -- what if writing 1 byte 4-bit address? // todo -- if not single stepping at time of break, should // disasm the prev pc before printing. if (!wbrkMap.lookup(address)) return; printf("Memory Break $%08x - ", address); LogWrite(size, value); // todo -- print previous value, old value. memBreak = true; } else { if (!rbrkMap.lookup(address)) return; printf("Memory Break $%08x - read %d bytes\n", address, size); memBreak = true; } } } #pragma mark - Debugger namespace Debug { uint32_t ReadLong(uint32_t address) { uint32_t tmp = 0; for (unsigned i = 0; i < 4; ++i) { if (address < Flags.memorySize) tmp = (tmp << 8) + Flags.memory[address++]; } return tmp; } uint16_t ReadWord(uint32_t address) { uint16_t tmp = 0; for (unsigned i = 0; i < 2; ++i) { if (address < Flags.memorySize) tmp = (tmp << 8) + Flags.memory[address++]; } return tmp; } uint8_t ReadByte(uint32_t address) { if (address < Flags.memorySize) return Flags.memory[address]; return 0; } void Help() { printf("help\n"); printf("break expression\n"); printf("step\n"); printf("continue\n"); printf("\n"); printf("print expression\n"); printf("list expression\n"); printf("dump expression\n"); printf("register=expression\n"); printf("bt | backtrace -- print cpu backtrace\n"); printf("expression;h -- print hexdump\n"); printf("expression;i -- print information\n"); printf("expression;l -- print assembly listing\n"); printf("\n"); printf("registers: a0-7, d0-7, pc, sp, fp, csr\n"); printf("\n"); } void Print(uint32_t data) { // 32-bit unsigned int printf("$%08x", data); // 32-but unsigned printf(" %12u", data); // 32-bit signed int int32_t negValue = 0; if (data & 0x80000000) negValue = (int32_t)data; if ((data & 0xffff8000) == 0x8000) negValue = (int16_t)data; if (negValue != 0) printf(" %12d", negValue); else printf(" "); // print binary value { std::string bins; bins.reserve(32); bins.push_back('%'); if (data > 0xffff) { for (unsigned i = 0, mask = 0x80000000; i < 16; ++i, mask >>= 1) bins.push_back( data & mask ? '1' : '0'); } if (data > 0xff) { for (unsigned i = 0, mask = 0x8000; i < 8; ++i, mask >>= 1) bins.push_back( data & mask ? '1' : '0'); } for (unsigned i = 0, mask = 0x80; i < 8; ++i, mask >>= 1) bins.push_back( data & mask ? '1' : '0'); printf(" %33s", bins.c_str()); } // 4-cc code? 2-cc code? 1-cc code? char tmp[5]; int bits = 0; tmp[0] = (data >> 24) & 0xff; tmp[1] = (data >> 16) & 0xff; tmp[2] = (data >> 8) & 0xff; tmp[3] = (data >> 0) & 0xff; tmp[4] = 0; if (isprint(tmp[0])) bits |= (1 << 0); if (isprint(tmp[1])) bits |= (1 << 1); if (isprint(tmp[2])) bits |= (1 << 2); if (isprint(tmp[3])) bits |= (1 << 3); switch(bits) { case 0x0f: printf(" '%s'", tmp); break; case 0x0e: if (data <= 0xffffff) printf(" '%s'", tmp + 1); break; case 0x0c: if (data <= 0xffff) printf(" '%s'", tmp + 2); break; case 0x08: if (data <= 0xff) printf(" '%s'", tmp + 3); break; } printf("\n"); } void Dump(uint32_t start, int size) { // TODO -- if no address, use previous address. // TODO -- support range? if (size <= 0) return; uint32_t end = start + size; if (start >= Flags.memorySize) return; end = std::min(end, Flags.memorySize); size = end - start; hexdump(Flags.memory + start, size, start); } // grr... need separate count/range options. void List(uint32_t pc, int count) { // TODO -- if no address, use previous address. if (pc & 0x01) { printf("address is not aligned: $%08x\n", pc); return; } for (int i = 0; i < count; ++i) { if (pc >= Flags.memorySize) break; pc = disasm(pc); } } void List(uint32_t pc, uint32_t endpc) { if (endpc < pc) return; if (pc & 0x01) { printf("address is not aligned: $%08x\n", pc); return; } while (pc <= endpc) { if (pc >= Flags.memorySize) break; pc = disasm(pc); } } const char *srBits(uint16_t sr) { static char srbits[20]; srbits[0] = sr & (1 << 15) ? 'T' : ' '; srbits[1] = sr & (1 << 14) ? 'T' : ' '; srbits[2] = sr & (1 << 13) ? 'S' : ' '; srbits[3] = sr & (1 << 12) ? 'M' : ' '; srbits[4] = ' '; srbits[5] = sr & (1 << 10) ? 'I' : ' '; srbits[6] = sr & (1 << 9) ? 'I' : ' '; srbits[7] = sr & (1 << 8) ? 'I' : ' '; srbits[8] = ' '; srbits[9] = ' '; srbits[10] = ' '; srbits[11] = sr & (1 << 4) ? 'X' : ' '; srbits[12] = sr & (1 << 3) ? 'N' : ' '; srbits[13] = sr & (1 << 2) ? 'Z' : ' '; srbits[14] = sr & (1 << 1) ? 'V' : ' '; srbits[15] = sr & (1 << 0) ? 'C' : ' '; srbits[16] = 0; return srbits; } void PrintRegisters(const BackTraceInfo &i) { const char *srbits = srBits(i.csr); printf(" 0 1 2 3 4 5 6 7\n"); printf("D: %08x %08x %08x %08x %08x %08x %08x %08x\n", i.d[0], i.d[1], i.d[2], i.d[3], i.d[4], i.d[5], i.d[6], i.d[7] ); printf("A: %08x %08x %08x %08x %08x %08x %08x %08x\n", i.a[0], i.a[1], i.a[2], i.a[3], i.a[4], i.a[5], i.a[6], i.a[7] ); printf("PC: %08X CSR: %04x %s\n", i.pc, i.csr, srbits); } void PrintRegisters() { uint16_t sr = cpuGetSR(); const char *srbits = srBits(sr); printf(" 0 1 2 3 4 5 6 7\n"); printf("D: %08x %08x %08x %08x %08x %08x %08x %08x\n", cpuGetDReg(0), cpuGetDReg(1), cpuGetDReg(2), cpuGetDReg(3), cpuGetDReg(4), cpuGetDReg(5), cpuGetDReg(6), cpuGetDReg(7) ); printf("A: %08x %08x %08x %08x %08x %08x %08x %08x\n", cpuGetAReg(0), cpuGetAReg(1), cpuGetAReg(2), cpuGetAReg(3), cpuGetAReg(4), cpuGetAReg(5), cpuGetAReg(6), cpuGetAReg(7) ); printf("PC: %08X CSR: %04x %s\n", cpuGetPC(), sr, srbits); } void btdiff(const BackTraceInfo &prev, const BackTraceInfo ¤t) { bool nl = false; for (unsigned i = 0; i < 8; ++i) if (current.d[i] != prev.d[i]) { printf(" D%u: %08x\n", i, current.d[i]); nl = true; } for (unsigned i = 0; i < 8; ++i) if (current.a[i] != prev.a[i]) { printf(" A%u: %08x\n", i, current.a[i]); nl = true; } // pc always changes, but it's included in the listing. //printf("PC: %08x\n", current.pc); if (current.csr != prev.csr) { printf(" CSR: %04x %s\n", current.csr, srBits(current.csr)); nl = true; } if (nl) printf("\n"); } void PrintBackTrace() { // backtrace. auto iter = BackTrace.cbegin(); auto end = BackTrace.cend(); if (iter == end) return; const BackTraceInfo *prev; { const BackTraceInfo &info = *iter; // print all registers for the first entry. // for subsequent entries, print changed registers. //disasm(info.pc); PrintRegisters(info); printf("\n"); prev = &info; ++iter; } for ( ; iter != end; ++iter) { const BackTraceInfo ¤t = *iter; disasm(prev->pc); btdiff(*prev, current); // prev = ¤t; } // print current registers. { BackTraceInfo current(true); disasm(prev->pc); btdiff(*prev, current); } // finally, print the current instruction. printf("---------\n"); disasm(cpuGetPC()); } void ToolBreak(int32_t tool) { bool remove = false; if (tool < 0) { tool = -tool; remove = true; } if (tool >= 0xa000 && tool <= 0xafff) { if (remove) tbrkMap.remove(tool); else tbrkMap.add(tool); } else { fprintf(stderr, "Invalid tool: $%04x\n", tool); } } void ToolBreak() { // list all tool breaks. if (!tbrkMap.size()) { printf("No tool breaks\n"); return; } std::vector v; v.reserve(tbrkMap.size()); for (auto kv : tbrkMap) { v.push_back(kv.first); } std::sort(v.begin(), v.end()); for (auto trap : v) { const char *name = TrapName(trap); if (!name) name = ""; printf("$%04x %s\n", trap, name); } } void Break(int32_t address) { // 24-bit only, - address to remove. bool remove = false; if (address < 0) { address = -address; remove = true; } // what was I thinking? only allow 24-bit addresses? if ((address & 0xff000000) == 0) { if (remove) brkMap.remove(address); else brkMap.add(address); } else { fprintf(stderr, "Invalid address: $%08x\n", address); } } void Break() { // list all tool breaks. if (!brkMap.size()) { printf("No breaks\n"); return; } std::vector v; v.reserve(brkMap.size()); for (auto kv : brkMap) { v.push_back(kv.first); } std::sort(v.begin(), v.end()); for (auto address : v) { printf("$%08x\n", address); } } void ReadBreak() {} void WriteBreak() {} void ReadWriteBreak() { } void ReadBreak(int32_t address) { // sanity check address? if (address < 0) rbrkMap.remove(-address); else rbrkMap.add(address); } void WriteBreak(int32_t address) { // sanity check address? if (address < 0) wbrkMap.remove(-address); else wbrkMap.add(address); } void ReadWriteBreak(int32_t address) { ReadBreak(address); WriteBreak(address); } void Step(const Command &cmd) { // TODO - step n to step specified # of instructions. // TODO -- step @address to step until address? // disasm 1 line, execute it. int count = 0; if (cmd.argc == 1) count = (int)cmd.argv[0]; if (count < 1) count = 1; // TODO -- move to common function... for (int i = 0; i < count; ++i) { if (!step(true)) break; } } void Continue(const Command &cmd) { while (step(false)) ; } void SetARegister(unsigned reg, uint32_t value) { if (reg > 7) return; if (reg == 7) { // sp/7 must be aligned. if (value & 0x01) { fprintf(stderr, "Address is not aligned: $%08x\n", value); return; } } if (value > Flags.memorySize) { fprintf(stderr, "Warning: address exceeeds memory size: $%08x\n", value); } cpuSetAReg(reg, value); } void SetDRegister(unsigned reg, uint32_t value) { if (reg > 7) return; cpuSetDReg(reg, value); } void SetXRegister(unsigned reg, uint32_t value) { if (reg == 0) { if (value & 0x01) { fprintf(stderr, "Address is not aligned: $%08x\n", value); return; } if (value > Flags.memorySize) { fprintf(stderr, "Warning: address exceeeds memory size: $%08x\n", value); } //cpuSetPC(value); cpuInitializeFromNewPC(value); return; } if (reg == 1) { cpuSetSR(value & 0xffff); } } // todo -- return a range uint32_t VariableGet(const std::string &s) { auto iter = SymbolTable.find(s); if (iter == SymbolTable.end()) return 0; return iter->second.first; } // TODO -- take a Token and construct a pair, if it's a range. // var = expr : expr or var = expr@count void VariableSet(const std::string &key, uint32_t value) { SymbolTable.emplace(key, std::make_pair(value, 0)); } void Info(uint32_t address) { // print info on the value. Print(address); // 1. as a pointer. MM::Native::MemoryInfo(address); // 2. (todo) - check SymbolTable for procedure address. for (const auto &kv : SymbolTable) { const auto &name = kv.first; auto range = kv.second; //printf("%s: %x %x\n", name.c_str(), range.first, range.second); // range end may be 0 if ((address == range.first) || (address >= range.first && address < range.second)) { uint32_t offset = address - range.first; if (offset) printf("Routine: %s+$%x\n", name.c_str(), offset); else printf("Routine: %s\n", name.c_str()); break; } } // 2. as a tool trap. if (address >= 0xa000 && address <= 0xafff) { const char *cp = TrapName(address); if (cp) printf("Tool: %s\n", cp); } // 3. as a global if (address <= 0xffff) { const char *cp = GlobalName(address); if (cp) printf("Global: %s\n", cp); } // 4 as an error // almost all are negative 16-bit values, // but may also be a positive 16-bit value. uint16_t error = 0; if (address <= 0xffff) error = address; if ((address & 0xffff8000) == 0xffff8000) error = address; if (error) { const char *cp = ErrorName(error); // find returns an iterator to the hash bucket, which may contain // other errors. auto range = ErrorTableInvert.equal_range(error); for(auto iter = range.first; iter != range.second; ++iter) { printf("Error: %s", iter->second.c_str()); if (cp) printf(" %s", cp); printf("\n"); cp = nullptr; } } } namespace { /* * returns a list of possible matches. * Item[0] is the longest match. */ char **mpw_attempted_completion_function(const char* text, int _start, int _end) { std::string s(text); // returns iter to first element _not less_ than key // ie, >= key. auto iter = SymbolTable.lower_bound(s); unsigned count = 0; unsigned length = s.length(); auto begin = iter; for (;;) { if (iter == SymbolTable.end()) break; if (iter->first.compare(0, length, s) != 0) break; ++count; ++iter; } auto end = iter; if (!count) return NULL; if (count > 100) return NULL; if (count == 1) { char **buffer = (char **)malloc(2 * sizeof(char *)); buffer[0] = strdup(begin->first.c_str()); buffer[1] = NULL; return buffer; } char **buffer = (char **)malloc((count + 2) * sizeof(char *)); unsigned i = 0; auto min_length = begin->first.length(); // item 0 is the longest match. (fill in later.) buffer[i++] = NULL; for (iter = begin; iter != end; ++iter) { buffer[i++] = strdup(iter->first.c_str()); min_length = std::min(min_length, iter->first.length()); } buffer[i] = NULL; // assume the first is the longest, then search until not true. buffer[0] = strdup(begin->first.c_str()); for (unsigned i = length; ; ++i) { if (i >= min_length) { buffer[0][i] = 0; break; } char c = buffer[0][i]; if (!c) break; bool nomatch = false; for (int j = 1; ; ++j) { char *cp = buffer[j]; if (!cp) break; if (cp[i] != c) nomatch = true; } if (nomatch) { buffer[0][i] = 0; break; } } return buffer; } // this is here to prevent filename tab completion, for now. char *mpw_completion_entry_function(const char *text, int state) { return NULL; } void readline_init() { rl_readline_name = (char *)"mpw"; rl_attempted_completion_function = mpw_attempted_completion_function; rl_completion_entry_function = (Function *)mpw_completion_entry_function; } } // TODO -- RUN command - reload, re-initialize, re-execute // TODO -- parser calls commands directly (except trace/step/run/etc) void Shell() { char *cp; readline_init(); add_history("!Andy, it still has history!"); Loader::Native::LoadDebugNames(SymbolTable); LoadTrapFile(MPW::RootDirPathForFile("Errors.text"), ErrorTable); LoadTrapFile(MPW::RootDirPathForFile("Globals.text"), GlobalTable); LoadTrapFile(MPW::RootDirPathForFile("Traps.text"), TrapTable); // load the error code to error mnemonic ErrorTableInvert.reserve(ErrorTable.size()); for (const auto kv : ErrorTable) { ErrorTableInvert.emplace(std::make_pair(kv.second, kv.first)); } // address to function name. SymbolTableInvert.reserve(SymbolTable.size()); for (const auto kv : SymbolTable) { SymbolTableInvert.emplace(std::make_pair(kv.second.first, kv.first)); } // start it up printf("MPW Debugger shell\n\n"); disasm(cpuGetPC()); signal(SIGINT, sigIntHandler); memorySetLoggingFunc(MemoryLogger); for(;;) { cp = readline("] "); if (!cp) { printf("\n"); break; // prompt for exit? } // parse the command... const char *iter = cp; while (*iter && isspace(*iter)) ++iter; if (*iter) { Command cmd; std::memset(&cmd, 0, sizeof(cmd)); if (ParseLine(iter, &cmd)) { switch(cmd.action) { case cmdNull: break; case cmdStep: Step(cmd); break; case cmdContinue: Continue(cmd); break; default: Help(); break; } } // todo -- don't add if same as previous command. add_history(cp); } free(cp); } } } // namespace Debugger