/* Simple 6502 Assembler * * for C02 Compiler * * Uses DASM Syntax but * * supports 65C02 Op Codes */ #include #include #include #include #include "a02.h" #define DEBUG TRUE enum otypes {BINFIL, PRGFIL}; //Object File Types char objtyp; //Object File Type int orgadr; //Origin Address int curadr; //Current Address int lstadr; //List Address struct sym {int block; char name[MAXLBL+1]; int bytes, value, refrd;}; struct sym symbol; //Current Symbol struct sym symtbl[MAXSYM]; //Global Symbol Table int symcnt; //Number of Global Labels int blknum; //Local Label Block Number (0 = Global) char label[MAXSTR]; //Assembly Line Label char mnmnc[MAXSTR]; //Opcode Mnemonic char oprnd[MAXSTR]; //Opcode Mnemonic char cmmnt[MAXSTR]; //Assembly Line Comment char mcode[MAXSTR]; //Generated Bytes char strng[MAXSTR]; //Parsed String int opridx; //Index into Operand unsigned char token, opmod; //OpCode Token, Modifier unsigned int amode; //Addressing Modes int zpage, opval; //ZeroPage Flag, Operand Value char hexadr[6]; //Current Address in Hexadecimal char bytstr[5]; //String Representation of Byte char inplin[MAXSTR]; //Input Buffer char *linptr; //Pointer into Input Buffer int lineno; //Input File Line Number int savlno; //Line Number (Saved) int passno; //Assembler Pass Number (1 or 2) int endasm; //End Assembly Flag char prgnam[256]; //Assembler Path and Name (from Command Line) char inpnam[256]; //Input File Name char outnam[256]; //Output File Name char lstnam[256]; //List File Name char incnam[256]; //Include File Name FILE *inpfil; //Input File Pointer FILE *outfil; //Output File Pointer FILE *lstfil; //List File Pointer FILE *incfil; //Include File Pointer /* Print Error Message and Exit */ void xerror(char* format, char *s) { if (lineno) fprintf(stderr, "%04d: ", lineno); fprintf(stderr, format, s); exit(EXIT_FAILURE); } /* Open File with Error Checking */ FILE * opnfil(char* name, char* mode) { if (DEBUG) printf("Opening file '%s' with mode '%s'\n", name, mode); FILE *fp = fopen(name, mode); if (!fp) xerror("Error Opening File '%s'\n", name); return fp; } /* Skip Character in Input Line * * Args: c - Character to Skip * * Updates: linptr */ int skpchr(char c) { if (*linptr == c) {linptr++; return TRUE;} else return FALSE; } /* Skip Spaces in Input Line * * Updates: linptr */ void skpspc(void) { while (*linptr && *linptr <= ' ') linptr++; } /* Parse Word from Input Line * * Args: skip - Skip Spaces Flag * * *word - Buffer for Word * * Updates: linptr * * Returns: Word Found (TRUE/FALSE) */ int pword(int skip, char* word) { int wrdlen = 0; if (skip) skpspc(); while (isalnum(*linptr) || *linptr == '_') { word[wrdlen++] = toupper(*linptr); linptr++; } word[wrdlen] = 0; //Terminate String if (wrdlen) return TRUE; else return FALSE; } struct sym *fndsym(int block, char* name) { for (int i=0; i < symcnt; i++) { if (symtbl[i].block != block || strcmp(symtbl[i].name,name)) continue; return &symtbl[i]; } return NULL; } /* Set Symbol Value and Size */ void setsym(int value, int bytes) { if (DEBUG) printf("Setting Symbol %s to %d\n", symbol.name, value); symbol.value = value; if (bytes) symbol.bytes = bytes; else symbol.bytes = (value > 0xFF) ? 2 : 1; symbol.refrd = FALSE; } /* Add Character to Beginning of String */ void pfxstr(char c, char* s) { for (int i=strlen(s)+1; i; i--) s[i] = s[i-1]; //Copy All Characters to the Right s[0] = c; //Insert Character at Beginning } /* Parse Label from Input Line * Sets: label * Updates: linptr * Returns: Label Found (TRUE/FALSE) */ int plabel(void) { if (DEBUG) puts("Parsing Label"); int block = (skpchr('.')) ? blknum : 0; //Local Label Block Number int found = pword(FALSE, label); //Parse Word without Skipping Spaces if (DEBUG) { if (found) printf("Found Label %s\n", label); else puts("No Label Found"); } skpchr(':'); //Skip Optional Label Terminator if (found && passno == 1) { if (label[0] && fndsym(block, label)) xerror("Duplicate Label %s Encountered\n", label); if (DEBUG) printf("Initializing Symbol %s\n", label); symbol.block = block; if (strlen(label) > MAXLBL) xerror("Label %s Too Long\n", label); strcpy(symbol.name, label); setsym(curadr, 0); } if (block) pfxstr('.', label); skpspc(); //Skip to Mnemonic, Comment, or EOL return found; } /* Copy Character to Operand and Increment */ int cpychr(int c) { if (c && toupper(*linptr) != c) return FALSE; if (opridx < MAXSTR) oprnd[opridx++] = toupper(*linptr); linptr++; return TRUE; } /* Evaluate Binary Number */ int evlbin() { int result = 0; cpychr('%'); while (isdigit(*linptr)) { if (*linptr > '1') break; result = (result << 1) + *linptr - '0'; cpychr(0); } return result; } /* Evaluate Binary Number */ int evlchr() { int result = 0; cpychr('\''); result = *linptr; cpychr(0); cpychr('\''); return result; } /* Evaluate Decimal Number */ int evldec() { int result = 0; while (isdigit(*linptr)) { result = result * 10 + *linptr - '0'; cpychr(0); } return result; } /* Evaluate Hexadecimal Number */ int evlhex() { int result = 0; cpychr('$'); while (isxdigit(*linptr)) { int digit = *linptr - '0'; if (digit > 9) digit = digit - 7; result = (result << 4) + digit; cpychr(0); } return result; } /* Evaluate Symbol */ struct sym *evlsym() { char name[MAXSTR]; int block = (cpychr('.')) ? blknum : 0; pword(TRUE, name); for (int i=0; name[i]; i++) if (opridxrefrd = TRUE; //Symbol was Referenced return result; } /* Evaluate Term in Operand */ int evltrm() { int result; skpspc(); if (isalpha(*linptr) || *linptr == '.') { struct sym *target = evlsym(); result = (target) ? target->value : 0x100; } else if (isdigit(*linptr)) result = evldec(); else switch(*linptr) { case '$': result = evlhex(); break; case '%': result = evlbin(); break; case '\'': result = evlchr(); break; default: result = -1; } skpspc(); if (DEBUG) printf("Term Evaluated to %d\n", result); return result; } /* Evaluate Operand */ int evlopd(int maxsiz) { int result = 0; int hilo = 0; //Return LSB (1) or MSB (2) int prns; //Optional Parenthesis after Hi/Low Operator if (DEBUG) puts("Evaluating Operand"); skpspc(); if (cpychr('<')) hilo = 1; else if (cpychr('>')) hilo = 2; if (hilo) prns = cpychr('('); result = evltrm(); if (result >= 0) while (cpychr('+')) { int opdval = evltrm(); if (opdval < 0) break; result += opdval; } if (hilo) { if (result < 0) xerror("Hi/Low Operator Requires Operand", ""); if (prns) cpychr(')'); // switch (hilo) { case 1: result = result & 0xFF; break; //LSB case 2: result = result >> 8; break; //MSB } } if (DEBUG) printf("Operand Evaluated to %d\n", result); if (result > maxsiz) xerror("Operand Value too Large\n", ""); return result; } /* Write Byte to Output File */ void outbyt(int b) { if (curadr > -1) curadr++; if (passno != 2) return; fputc(b & 0xFF, outfil); sprintf(bytstr, "%02X ", b); if (strlen(mcode) < 9) strcat(mcode, bytstr); } /* Write Word to Output File */ void outwrd(int w) { outbyt(w & 0xff); outbyt(w >> 8); } /* Assemble BYTE Pseudo-Op */ void asmbyt(void) { if (DEBUG) puts("Assembling BYTE Pseudo-Op"); do { if (cpychr('"')) { //String Operand while (!cpychr('"')) {outbyt(*linptr); cpychr(0); } skpspc(); } else outbyt(evlopd(0xFF)); //Evaluate Operand } while (cpychr(',')); } /* Assemble HEX Pseudo-Op */ void asmhex(void) { if (DEBUG) puts("Assembling HEX Pseudo-Op"); do {outbyt(evlhex(0xFF)); } while (cpychr(',')); } /* Assemble WORD Pseudo-Op */ void asmwrd(void) { do { outwrd(evlopd(0xFFFF)); //Evaluate Operand } while (cpychr(',')); } /* Assemble FILL Pseudo-Op */ void asmaln(void) { if (DEBUG) puts("Assembling ALIGN Pseudo-Op"); int size = evlopd(0xFFFF); if (size < 2) return; if (DEBUG) printf("Aligning to %d Bytes\n", size); int fill = size - (curadr % size); if (fill == size) return; if (DEBUG) printf("Filling %d Bytes\n", fill); for (int i=0; ivalue - curadr - 2); } else if (cpychr('+')) offset = evlopd(0xFF); else if (cpychr('-')) offset = -evlopd(0xFF); else xerror("Illegal Branch Operand\n", ""); if ((offset > 127 || offset < -128) && passno == 2) xerror("Branch Out of Range\n", ""); if (DEBUG) printf("Branch Offset %d\n", offset); opval = offset & 0xFF; } /* Assemble Immediate Mode Instruction */ void asmimd(void) { if (DEBUG) printf("Assembling Immediate Opcode Token 0x%02X\n", token); opval = evlopd(0xFF); zpage = TRUE; opmod = 0x08; //Immediate } /* Assemble Indirect Mode Instruction */ void asmind(void) { if (DEBUG) puts("Assembling Indirect Mode Instruction"); zpage = TRUE; opval = evlopd(0xFFFF); if (cpychr(',') && cpychr('X') && chkmod(INDCX)) cpychr(')'); ////(Indirect,X) opmod=0 else if (cpychr(')')) { if (cpychr(',') && cpychr('Y') && chkmod(INDCY)) opmod = 0x10; //(Indirect),Y else if (chkmod(INDCT)) opmod = 0x11; //(Indirect) if (token == 0x4C) zpage = FALSE; //JMP (Indirect Absolute) } else chkmod(0); //Illegal Addressing Mode if (zpage && opval > 0x00FF) xerror("Operand Value too Large\n", ""); } /* Assemble Implied/Accumulator/Absolute/ZeroPage Mode Instruction */ void asmiaz(void) { opval = evlopd(0xFFFF); if (opval < 0) { if (amode != IMPLD) //Implied if (chkmod(ACMLT)) opmod = 0x08; //Accumulator return; } if (DEBUG) printf("Assembling Absolute/ZeroPage 0x%02X\n", token); zpage = (opval <= 0xff) ? TRUE : FALSE; if (zpage && chkmod(ZPAGE)) opmod = 0x04; //ZeroPage else if (chkmod(ABSLT)) opmod = 0x0C; //Absolute if (cpychr(',')) { if (cpychr('X')) { if (zpage && chkmod(ZPAGX)) opmod = 0x14; //ZeroPage,X else if (chkmod(ABSLX)) opmod = 0x1C; //Absolute,X } else if (cpychr('Y')) { if (zpage && (token == 0x82 || token == 0xA2)) opmod = 0x14; //ZeroPage,Y else {zpage = FALSE; opmod = 0x18;} //Absolute,Y } else chkmod(0); //Illegal Addressing Mode } } /* Fix Opcode (if needed) */ unsigned char fixopc(void) { if (DEBUG) printf("Fixing OpCode $%02X+$%02X\n", token, opmod); for (int i=0; opfix[i].token; i++) if (opfix[i].token == token && opfix[i].opmod == opmod) return opfix[i].opcode; return token + opmod; } /* Ouput Opcode Debug Info */ void dbgopc(void) { if (DEBUG) printf("token=$%02X, opmod=$%02X, Address Mode: ", token, opmod); switch (opmod) { case 0x00: if (amode == IMPLD) puts("Implied"); else puts("(Indirect,X)"); break; case 0x08: if (opval < 0) puts("Accumulator"); else puts("#Immediate"); break; case 0x10: puts("(Indirect),Y"); break; case 0x11: puts("(Indirect)"); break; case 0x04: puts("ZeroPage"); break; case 0x0C: puts("Absolute"); break; case 0x14: puts("ZeroPage,X"); break; case 0x1C: puts("Absolute,X"); break; case 0x14: puts("ZeroPage,Y"); break; case 0x18: puts("Absolute,Y"); break; default: puts("UNKOWN"); } if (opval < 0) puts("No Operand"); else { printf("Operand Value %d, ", opval); if (zpage) puts("Zero Page"); else puts("Absolute"); } } /* Assemble Opcode */ int asmopc(int dot) { opmod = 0; if (asmpso(dot)) return TRUE; //Check For/Assemble Pseudo-Op if (lkpopc(opclst) == FALSE) xerror("Invalid Mnemonic %s\n", mnmnc); if (DEBUG) printf("Assembling Opcode Token 0x%02X, ", token); if (DEBUG) printf("Addressing Mode Mask 0x%04X\n", amode); skpspc(); if (amode == RELTV) asmbrn(); //Branch (Relative) Instruction else if (cpychr('#')) asmimd(); //Assemble Implied Instruction else if (cpychr('(')) asmind(); //Assemble Indirect Instruction else asmiaz(); //Assemble Implied/Accumulator/Absolute/ZeroPage Instruction if (DEBUG) dbgopc(); int opcode = fixopc(); if (DEBUG) printf("Writing OpCode $%02X\n", opcode); outbyt(opcode); if (opval >= 0) { if (zpage) outbyt(opval); //Byte Operand else outwrd(opval); //Word Operand } return TRUE; } /* Parse Opcode Mnemonic from Input Line * Sets: mnmnc * Updates: linptr * Returns: Label Found (TRUE/FALSE) */ int pmnmnc(void) { if (DEBUG) puts("Parsing Mnemonic"); int dot = cpychr('.'); //Optional Dot before Pseudo-Op int found = pword(TRUE, mnmnc); opridx = 0; //Initialize Operand Index if (found) asmopc(dot); oprnd[opridx] = 0; //Terminate Operand String return found; } /* Parse Comment from Input Line * Sets: cmmnt * Updates: linptr */ void pcmmnt(void) { skpspc(); int i = 0; while (*linptr >= ' ') cmmnt[i++] = *linptr++; cmmnt[i] = 0; //Terminate Comment if (DEBUG) {if (i) printf("Comment: %s\n"); else puts("No Comment Found");} } /* Add Label to Symbol Table */ void addsym() { if (symbol.value<0) xerror("Origin Not Set", ""); memcpy(&symtbl[symcnt++], &symbol, sizeof(symbol)); } /* Open Include File */ void opninc(void) { if (DEBUG) printf("Opening Include File %s\n", incnam); if (lstfil) fputs("\n", lstfil); incfil = opnfil(incnam, "r"); savlno = lineno; lineno = 1; } /* Close Include File */ void clsinc(void) { if (DEBUG) printf("Closing Include File %s\n", incnam); if (lstfil) fputs("\n", lstfil); fclose(incfil); incfil = NULL; incnam[0] = 0; lineno = savlno; endasm = FALSE; //Clear End Flag for Return to Maun File } /* Assemble Input File (Two Pass) * * Args: pass - Assembly Pass (1 or 2) * * Requires: inpfil - Input File Pointer * * Uses: inplin - Input Line Buffer * * lineno - Input File Line Number */ void asmfil(int pass) { endasm = FALSE; //Reset End Assembly Flag passno = pass; //Assembly Pass Number if (DEBUG) printf("Assembling Pass %d\n", pass); lineno = 1; //Initialize Input File Line Number blknum = 1; //Initialize Local Block Number orgadr = -1; //Origin Address Not Set curadr = orgadr; //Set Current Address to Origin rewind(inpfil); //Start at Beginning of Input File while (TRUE) { if (incfil) linptr = fgets(inplin, MAXSTR, incfil); else linptr = fgets(inplin, MAXSTR, inpfil); if (endasm || linptr == NULL) {if (incfil) {clsinc(); continue;} else break;} if (DEBUG) printf("%05d %04X: %s", lineno, curadr, inplin); lstadr = curadr; //Set List Address mcode[0] = 0; //Clear Generated Macbine Code plabel(); //Parse Label pmnmnc(); //Parse Mnemonic pcmmnt(); //Parse Comment if (passno == 1 && label[0]) addsym(); //Add Label to Table if (passno == 2) { if (lstadr < 0) hexadr[0] = 0; else sprintf(hexadr, "%04X", lstadr); fprintf(lstfil, "%05d %-4s %-9s%-7s %-5s %-16s %s\n", lineno, hexadr, mcode, label, mnmnc, oprnd, cmmnt ); fflush(lstfil); //Flush Output Buffer in case of Segmentation Fault } lineno++; if (incnam[0] && incfil == NULL) opninc(); //Open Include File } } /* Print Symbol Table */ void prtsym(void) { fprintf(lstfil, "\n%s Symbol Table\nBlock Name Size Value Rfd\n", "Global"); for (int i=0; i