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[/] [forwardcom/] [bintools/] [emulator6.cpp] - Rev 160
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/**************************** emulator6.cpp ******************************** * Author: Agner Fog * date created: 2018-02-18 * Last modified: 2021-02-19 * Version: 1.11 * Project: Binary tools for ForwardCom instruction set * Description: * Emulator: System functions * * Copyright 2018-2021 GNU General Public License http://www.gnu.org/licenses *****************************************************************************/ #include "stdafx.h" // Data encoding names // Interrupt names SIntTxt interruptNames[] = { // Error interrupts {INT_UNKNOWN_INST, "Unknown instruction"}, {INT_WRONG_PARAMETERS, "Illegal instruction code"}, {INT_ACCESS_READ, "Memory read access violation"}, {INT_ACCESS_WRITE, "Memory write access violation"}, {INT_ACCESS_EXE, "Memory execute access violation"}, {INT_CALL_STACK, "Call stack overflow or underflow"}, {INT_ARRAY_BOUNDS, "Array bounds violation"}, {INT_MISALIGNED_JUMP, "Jump to misaligned address"}, {INT_MISALIGNED_MEM, "Misaligned memory address"}, // Software traps. Not necessarily supported {INT_OVERFL_UNSIGN, "Unsigned integer overflow"}, {INT_OVERFL_SIGN, "Signed integer overflow"}, {INT_OVERFL_FLOAT, "Floating point overflow"}, {INT_FLOAT_INVALID, "Floating point invalid operation"}, {INT_FLOAT_UNDERFL, "Floating point underflow"}, {INT_FLOAT_NAN_LOSS, "Floating point NAN in compare or conversion to integer"}, {0xFFFF, "Filler interrupt"}, }; // System function names SIntTxt systemFunctionNames[] = { {SYSF_EXIT, "exit"}, // terminate program {SYSF_ABORT, "abort"}, // abort program {SYSF_TIME, "time"}, // time in seconds since jan 1, 1970 // input/output functions {SYSF_PUTS, "puts"}, // write string to stdout {SYSF_PUTCHAR, "putchar"}, // write character to stdout {SYSF_PRINTF, "printf"}, // write formatted output to stdout {SYSF_FPRINTF, "fprintf"}, // write formatted output to file {SYSF_SNPRINTF, "snprintf"}, // write formatted output to string buffer {SYSF_FOPEN, "fopen"}, // open file {SYSF_FCLOSE, "fclose"}, // SYSF_FCLOSE {SYSF_FREAD, "fread"}, // read from file {SYSF_FWRITE, "fwrite"}, // write to file {SYSF_FFLUSH, "fflush"}, // flush file {SYSF_FEOF, "feof"}, // check if end of file {SYSF_FTELL, "ftell"}, // get file position {SYSF_FSEEK, "fseek"}, // set file position {SYSF_FERROR, "ferror"}, // get file error {SYSF_GETCHAR, "getchar"}, // read character from stdin {SYSF_FGETC, "fgetc"}, // read character from file {SYSF_FGETS, "fgets"}, // read string from file {SYSF_SCANF, "scanf"}, // read formatted input from stdio {SYSF_FSCANF, "fscanf"}, // read formatted input from file {SYSF_SSCANF, "sscanf"}, // read formatted input from string buffer {SYSF_REMOVE, "remove"}, // delete file }; // number of entries in list const int numSystemFunctionNames = sizeof(systemFunctionNames) / sizeof(SIntTxt); // interrupt or trap // To trace a runtime error, set a breakpoint here void CThread::interrupt(uint32_t n) { // check if error is disabled uint32_t capabbit = 0; // bit in capabilities register switch (n) { case INT_BREAKPOINT: // debug breakpoint listOut.tabulate(emulator->disassembler.asmTab0); listOut.put("breakpoint"); listOut.newLine(); return; case INT_UNKNOWN_INST: // unknown instruction capabbit = 1; perfCounters[perf_unknown_instruction]++; break; case INT_WRONG_PARAMETERS: // unsupported parameters for instruction case INT_CALL_STACK: // call stack overflow or underflow capabbit = 2; perfCounters[perf_wrong_operands]++; break; case INT_ACCESS_READ: // memory access violation, read capabbit = 8; perfCounters[perf_read_violation]++; break; case INT_ACCESS_WRITE: // memory access violation, write capabbit = 0x10; perfCounters[perf_write_violation]++; break; case INT_ACCESS_EXE: // memory access violation, execute capabbit = 8; perfCounters[perf_read_violation]++; break; case INT_ARRAY_BOUNDS: // array bounds overflow, unsigned capabbit = 4; perfCounters[perf_array_overflow]++; break; case INT_MISALIGNED_MEM: // misaligned memory access. capabbit = 0x20; perfCounters[perf_misaligned]++; break; case INT_MISALIGNED_JUMP: // jump to an address not divisible by 4 default: capabbit = 0; } if (perfCounters[perf_type_of_first_error] == 0) { // save first error perfCounters[perf_type_of_first_error] = bitScanReverse(capabbit); uint8_t instrLength = pInstr->i[0] >> 30; if (instrLength == 0) instrLength = 1; perfCounters[perf_address_of_first_error] = ((ip - ip0) >> 2) - instrLength; } if (!(capabilyReg[disable_errors_capability_register] & capabbit)) { terminate = true; // stop execution unless error is disabled } if (listFileName && cmd.maxLines != 0) { // write interrupt to debug output listOut.tabulate(emulator->disassembler.asmTab0); const char * iname = Lookup(interruptNames, n); listOut.put(iname); if (terminate) listOut.put(". Terminating"); listOut.newLine(); } } /* // give error message if compiled for 32 bit void checkVa_listSize() { // C variable argument list va_list is not compatible with ForwardCom in 32 bit mode if (sizeof(void*) < 8) { // 32 bit host system. va_list has 32-bit entries except for %f puts("\nError: forw must be compiled in 64 bit mode. printf function may fail\n"); } } */ // check if system function has access to a particular address uint64_t CThread::checkSysMemAccess(uint64_t address, uint64_t size, uint8_t rd, uint8_t rs, uint8_t mode) { // rd = register pointing to beginning of shared memory area, rs = size of shared memory area // mode = SHF_READ or SHF_WRITE // return value is possibly reduced size, or zero if no access if ((rd | rs) == 0) return 0; // no access if both are r0 uint64_t base = registers[rd]; // beginning of shared area uint64_t bsize = registers[rs]; // size of shared area if (address + size < address) size = ~address; // avoid overflow if (base + bsize < base) bsize = ~base; // avoid overflow if ((rd & rs & 0x1F) != 0x1F) { // share all if both are r31 // check if within shared area if (address < base) return 0; if (address + size > base + bsize) size = base + bsize - address; } // check application's memory map uint32_t index = mapIndex3; // find index while (address < memoryMap[index].startAddress) { if (index > 0) index--; else return 0; } while (address >= memoryMap[index+1].startAddress) { if (index+2 < memoryMap.numEntries()) index++; else return 0; } // check read/write permission if ((memoryMap[index].access_addend & mode) != mode) return 0; // check if multiple map entries covered uint32_t index2 = index; while (address + size >= memoryMap[index2+1].startAddress && index2+2 < memoryMap.numEntries() && (memoryMap[index2+1].access_addend & mode) == mode) { index2++; } uint64_t size2 = memoryMap[index2+1].startAddress - address; // maximum possible size if (size < size2) size = size2; return size; } // emulate fprintf with ForwardCom argument list int CThread::fprintfEmulated(FILE * stream, const char * format, uint64_t * argumentList) { // a ForwardCom argument list is compatible with a va_list in 64-bit windows but not in Linux static CMemoryBuffer fstringbuf; // buffer containing format string fstringbuf.setSize(0); // discard any previously stored string fstringbuf.pushString(format); // copy format string // split the format string into substrings with a single format specifier in each uint32_t arg = 0; // argument index int returnValue; // return value; int returnSum = 0; // sum of return values; char * startp; // start of current substring in format string char * percentp1; // percent sign in current substring char * percentp2; // next percent sign starting next substring startp = fstringbuf.getString(0); // start of string buffer percentp1 = startp; // search for first % sign while (true) { percentp1 = strchr(percentp1, '%'); if (percentp1 && percentp1[1] == '%') percentp1 += 2; // skip "%%" which is not a format code else break; } // loop for substrings of format string containing only one format specifier each do { char c = 0; // format character int asterisks = 0; bool isString = false; if (percentp1) { percentp2 = percentp1 + 1; // search for next % sign while (true) { percentp2 = strchr(percentp2, '%'); if (percentp2 && percentp2[1] == '%') percentp2 += 2; // skip "%%" which is not a format code else break; } if (percentp2) *percentp2 = 0; // put temporary end of string at next % sign // check if argument is a string, and count asterisks int i = 1; while (true) { c = percentp1[i++]; // read character in format specifier if (c == 0) break; // end of string if (c == '*') asterisks++; // count asterisks c |= 0x20; // lower case if (c == 's') isString = true; // %s means string if (c >= 'a' && c <= 'z') break; // a letter terminates the format specifier } } else { percentp2 = 0; } uint64_t argument = argumentList[arg]; // The argument list can contain any type of argument with size up to 64 bits union { uint64_t a; double d; } uu; if (isString) argument += (uint64_t)memory; // translate string address // Print current argument with format substring. if (asterisks) { // asterisks indicate extra arguments if (c == 'a' || c == 'e' || c == 'f' || c == 'g') { // floating point argument if (asterisks == 1) { uu.a = argumentList[arg+1]; returnValue = fprintf(stream, startp, argument, uu.d, argumentList[arg+2]); } else { // asterisks = 2 uu.a = argumentList[arg+2]; returnValue = fprintf(stream, startp, argument, argumentList[arg+1], uu.d); } } else { // integer argument returnValue = fprintf(stream, startp, argument, argumentList[arg+1], argumentList[arg+2]); } arg += asterisks + 1; } else { if (c == 'a' || c == 'e' || c == 'f' || c == 'g') { // floating point argument uu.a = argument; returnValue = fprintf(stream, startp, uu.d); } else { returnValue = fprintf(stream, startp, argument); } arg++; } if (returnValue < 0) return returnValue; // return error else returnSum += returnValue; // sum of return values if (percentp2) *percentp2 = '%'; // re-insert next % sign startp = percentp1 = percentp2; } while (startp); // loop to next substring return returnSum; // return total number of characters written } // entry for system calls void CThread::systemCall(uint32_t mod, uint32_t funcid, uint8_t rd, uint8_t rs) { if (listFileName) { // debug listing listOut.tabulate(emulator->disassembler.asmTab0); listOut.put("system call: "); if (mod == SYSM_SYSTEM) { // search for function name for (int i = 0; i < numSystemFunctionNames; i++) { if (systemFunctionNames[i].a == funcid) { // name is in list listOut.put(systemFunctionNames[i].b); goto NAME_WRITTEN; } } } // name not found. write id listOut.putHex(mod); listOut.put(":"); listOut.putHex(funcid); NAME_WRITTEN: listOut.newLine(); } uint64_t temp; // temporary uint64_t dsize; // data size const char * str = 0; // string if (mod == SYSM_SYSTEM) {// system function // dispatch by function id switch (funcid) { case SYSF_EXIT: // terminate program cmd.mainReturnValue = (int)registers[0]; terminate = true; break; case SYSF_ABORT: // abort program cmd.mainReturnValue = (int)registers[0]; terminate = true; break; case SYSF_TIME: // time temp = time(0); if (registers[0] && checkSysMemAccess(registers[0], 8, rd, rs, SHF_WRITE)) *(uint64_t*)(memory + registers[0]) = temp; registers[0] = temp; break; case SYSF_PUTS: // write string to stdout str = (const char*)memory + registers[0]; if (strlen(str) > checkSysMemAccess(registers[0], -1, rd, rs, SHF_READ)) { interrupt(INT_ACCESS_READ); } else puts(str); break; case SYSF_PUTCHAR: // write character to stdout putchar((char)registers[0]); break; case SYSF_PRINTF: // write formatted output to stdout registers[0] = fprintfEmulated(stdout, (const char*)memory + registers[0], (uint64_t*)(memory + registers[1])); break; case SYSF_FPRINTF: // write formatted output to file registers[0] = fprintfEmulated((FILE *)(registers[0]), (const char*)memory + registers[1], (uint64_t*)(memory + registers[2])); break; /* case SYSF_SNPRINTF: // write formatted output to string buffer // this works only in 64 bit windows dsize = registers[1]; // size of data to read if (checkSysMemAccess(registers[0], dsize, rd, rs, SHF_WRITE) < dsize) { interrupt(INT_ACCESS_WRITE); // write access violation ret = 0; } else ret = snprintf((char*)memory + registers[0], registers[1], (const char*)memory + registers[2], (const char*)memory + registers[3]); registers[0] = ret; break;*/ case SYSF_FOPEN: // open file registers[0] = (uint64_t)fopen((const char*)memory + registers[0], (const char*)memory + registers[1]); break; case SYSF_FCLOSE: // SYSF_FCLOSE registers[0] = (uint64_t)fclose((FILE*)registers[0]); break; case SYSF_FREAD: // read from file dsize = registers[1] * registers[2]; // size of data to read if (checkSysMemAccess(registers[0], dsize, rd, rs, SHF_WRITE) < dsize) { interrupt(INT_ACCESS_WRITE); // write access violation registers[0] = 0; } else registers[0] = (uint64_t)fread(memory + registers[0], (size_t)registers[1], (size_t)registers[2], (FILE *)(size_t)registers[3]); break; case SYSF_FWRITE: // write to file dsize = registers[1] * registers[2]; // size of data to write if (checkSysMemAccess(registers[0], dsize, rd, rs, SHF_READ) < dsize) { interrupt(INT_ACCESS_READ); // write access violation registers[0] = 0; } else registers[0] = (uint64_t)fwrite(memory + registers[0], (size_t)registers[1], (size_t)registers[2], (FILE *)(size_t)registers[3]); break; case SYSF_FFLUSH: // flush file registers[0] = (uint64_t)fflush((FILE *)registers[0]); break; case SYSF_FEOF: // check if end of file registers[0] = (uint64_t)feof((FILE *)registers[0]); break; case SYSF_FTELL: // get file position registers[0] = (uint64_t)ftell((FILE *)registers[0]); break; case SYSF_FSEEK: // set file position registers[0] = (uint64_t)fseek((FILE *)registers[0], (long int)registers[1], (int)registers[2]); break; case SYSF_FERROR: // get file error registers[0] = (uint64_t)ferror((FILE *)registers[0]); break; case SYSF_GETCHAR: // read character from stdin registers[0] = (uint64_t)getchar(); break; case SYSF_FGETC: // read character from file registers[0] = (uint64_t)fgetc((FILE *)registers[0]); break; case SYSF_FGETS: // read string from file dsize = registers[1]; // size of data to read if (checkSysMemAccess(registers[0], dsize, rd, rs, SHF_WRITE) < dsize) { interrupt(INT_ACCESS_WRITE); // write access violation registers[0] = 0; } else { registers[0] = (uint64_t)fgets((char *)(memory+registers[0]), (int)registers[1], (FILE *)registers[2]); } break; case SYSF_GETS_S: // read string from stdin dsize = registers[1]; // size of data to read if (checkSysMemAccess(registers[0], dsize, rd, rs, SHF_WRITE) < dsize) { interrupt(INT_ACCESS_WRITE); // write access violation registers[0] = 0; } else { char * r = fgets((char *)(memory+registers[0]), (int)registers[1], stdin); if (r == 0) registers[0] = 0; // registers[0] unchanged if success } break; /* case SYSF_SCANF: // read formatted input from stdio ret = vscanf((char *)(memory+registers[0]), (va_list)(memory + registers[1])); if (checkSysMemAccess(registers[0], ret, rd, rs, SHF_WRITE) < ret) { interrupt(INT_ACCESS_WRITE); // write access violation } registers[0] = ret; break; case SYSF_FSCANF: // read formatted input from file ret = vfscanf((FILE *)registers[0], (char *)(memory+registers[1]), (va_list)(memory + registers[2])); if (checkSysMemAccess(registers[0], ret, rd, rs, SHF_WRITE) < ret) { interrupt(INT_ACCESS_WRITE); // write access violation } registers[0] = ret; break; case SYSF_SSCANF: // read formatted input from string buffer ret = vsscanf((char *)(memory+registers[0]), (char *)(memory+registers[1]), (va_list)(memory + registers[2])); if (checkSysMemAccess(registers[0], ret, rd, rs, SHF_WRITE) < ret) { interrupt(INT_ACCESS_WRITE); // write access violation } registers[0] = ret; break; */ case SYSF_REMOVE: // delete file registers[0] = (uint64_t)remove((char *)(memory+registers[0])); break; } } }
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