/* cpu.c tr3200 cpu description file */ /* (c) in 2014 by Luis Panadero Guardeno */ #include "vasm.h" /*#define CPU_DEBUG (1)*/ #ifdef CPU_DEBUG #define OPERAND_DEBUG (1) #define INSTR_DEBUG (1) #endif char *cpu_copyright="vasm TR3200 cpu module v0.1.2 by Luis Panadero Guardeno"; char *cpuname="tr3200"; int bitsperbyte=8; int bytespertaddr=4; mnemonic mnemonics[]={ #include "opcodes.h" }; int mnemonic_cnt=sizeof(mnemonics)/sizeof(mnemonics[0]); static taddr opsize(operand *p, unsigned char num_operands, section *sec, taddr pc); /* parse instruction */ char *parse_instruction(char *s, int *inst_len, char **ext, int *ext_len, int *ext_cnt) { char* inst = s; #ifdef CPU_DEBUG fprintf(stderr, "parse_inst : \"%.*s\"\n", *inst_len, s); #endif /* while (*s && !isspace((unsigned char)*s)) s++; *inst_len = s - inst; */ return s; } /* Sets op if is a valid register */ static int parse_reg(char **p, int len, operand *op) { char *rp = skip(*p); int reg = -1; if (len < 2) { return 0; } if (*rp != '%') { return 0; } rp++; if (tolower((unsigned char)rp[0]) != 'r') { /* Could be y, bp, sp, ia or flags */ if (len == 2 && tolower((unsigned char)rp[0]) == 'y') { rp++; *p = skip(rp); op->type = OP_GPR; op->reg = 11; return 1; } else if ( len == 3 && (tolower((unsigned char)rp[0]) == 'b') && (tolower((unsigned char)rp[1]) == 'p') ) { rp++; rp++; *p = skip(rp); op->type = OP_GPR; op->reg = 12; return 1; } else if ( len == 3 && (tolower((unsigned char)rp[0]) == 's') && (tolower((unsigned char)rp[1]) == 'p') ) { rp++; rp++; *p = skip(rp); op->type = OP_GPR; op->reg = 13; return 1; } else if ( len == 3 && (tolower((unsigned char)rp[0]) == 'i') && (tolower((unsigned char)rp[1]) == 'a') ) { rp++; rp++; *p = skip(rp); op->type = OP_GPR; op->reg = 14; return 1; } else if ( len == 6 && (tolower((unsigned char)rp[0]) == 'f') && (tolower((unsigned char)rp[1]) == 'l') && (tolower((unsigned char)rp[2]) == 'a') && (tolower((unsigned char)rp[3]) == 'g') && (tolower((unsigned char)rp[4]) == 's') ) { rp += 5; *p = skip(rp); op->type = OP_GPR; op->reg = 14; return 1; } /* It's not a register */ return 0; } rp++; /* Get number */ if (len < 2 || sscanf(rp, "%u", ®) != 1) { return 0; } /* "%r0 .. %r15" are valid */ if (reg < 0 || reg > 15) { return 0; } /* skip digits and return new pointer together with register number */ while ( isdigit((unsigned char)*rp) ) { rp++; } *p = skip(rp); op->type = OP_GPR; op->reg = reg; return 1; } /* Parses operands and reads expressions * *p string * len string length * *op operand * requires Type of operand expected */ int parse_operand(char *p, int len, operand *op, int requires) { op->type = NO_OP; #ifdef OPERAND_DEBUG fprintf(stderr, "parse_operand (reqs=%02x): \"%.*s\"\t", (unsigned)requires, len, p); #endif /* Try to grab the register */ if (1 != parse_reg(&p, len, op) ) { #ifdef OPERAND_DEBUG fprintf(stderr, "imm\t"); #endif /* Its not a register, should be a immediate value or a expression */ if(p[0]=='#') { /* Immediate value */ expr *tree; #ifdef OPERAND_DEBUG fprintf(stderr, "# "); #endif op->type = OP_IMM; p=skip(p+1); tree = parse_expr(&p); if (!tree) { /* It's not a valid expresion */ return PO_NOMATCH; } op->value = tree; } else { /* expresion that would be a immediate value */ #ifdef OPERAND_DEBUG fprintf(stderr, "expr\t"); #endif op->type = OP_IMM; int parent=0; expr *tree; /* if (*p=='(') { parent=1; p=skip(p+1); } */ tree = parse_expr(&p); if (!tree) { /* It's not a valid expresion */ return PO_NOMATCH ; } /* Inside of a ( ) */ /* p=skip(p); if(parent) { if(*p!=')'){ cpu_error(0); return 0; } else p=skip(p+1); } */ op->value=tree; } } #ifdef OPERAND_DEBUG fprintf(stderr, "(type=%02x)\n", (unsigned) op->type); #endif if(requires == op->type) { /* Matched type */ return PO_MATCH; } return PO_NOMATCH; /* Ops! Not match */ } /* Convert an instruction into a DATA atom including relocations, if necessary. */ dblock *eval_instruction (instruction *p, section *sec, taddr pc) { /* Calc instruction size */ size_t size = instruction_size(p, sec, pc); dblock *db = new_dblock(); mnemonic m = mnemonics[p->code]; unsigned char *opcode, *d; /* Data */ taddr val; unsigned char ml_bits = 0; unsigned char num_operands = 0; unsigned char srn = 0; /* Size of Rn */ operand* rn = NULL; symbol *base = NULL; int btype; #ifdef INSTR_DEBUG fprintf(stderr, "eval_instruction code \"%s\" ", m.name); #endif num_operands += (m.operand_type[0] != NO_OP)? 1 : 0; num_operands += (m.operand_type[1] != NO_OP)? 1 : 0; num_operands += (m.operand_type[2] != NO_OP)? 1 : 0; if (num_operands > 0) { rn = p->op[m.ext.rn_pos]; } #ifdef INSTR_DEBUG fprintf(stderr, "P%d ", num_operands); if (num_operands > 0) fprintf(stderr, "rn type=%02x ", (unsigned) rn->type); #endif /* See if Rn is an immediate to set ML bits*/ if (rn != NULL && rn->type == OP_IMM) { srn = opsize(rn, num_operands, sec, pc); ml_bits = 2 | (srn == 4); } ml_bits = ml_bits << 6; /* Emplace ML bits */ #ifdef INSTR_DEBUG fprintf(stderr, "IMM=%d ", srn); fprintf(stderr, "ml %02x ", ml_bits); #endif db->size=size; db->data = mymalloc(size); /* allocate for the data block */ memset(db->data, 0, db->size); /* Here to write data ! */ d = db->data; d[3] = m.ext.opcode; /* Common part */ d[2] = ml_bits; switch (num_operands) { case 3: /* format P3 */ /* Rn is always at the LSBytes side */ if( rn->type == OP_GPR) { /* Is a register */ d[0] = (rn->reg) & 0xF; } else if (ml_bits == 0x80 ) { /* ML are 10 -> immediate */ eval_expr(rn->value, &val, sec, pc); #ifdef INSTR_DEBUG fprintf(stderr, "val %04x ", val); #endif d[1] = (val >>8) & 0x3F; d[0] = (val ) & 0xFF; } else { /* 32 bit immediate */ eval_expr(rn->value, &val, sec, pc); #ifdef INSTR_DEBUG fprintf(stderr, "val %08x ", val); #endif d[7] = (val >>24) & 0xFF; d[6] = (val >>16) & 0xFF; d[5] = (val >>8 ) & 0xFF; d[4] = (val ) & 0xFF; } if (m.ext.rn_pos == 1) { /* Special case of STORE */ d[1] |= (p->op[0]->reg & 0xF) << 6; d[2] |= (p->op[0]->reg & 0xF) >> 2; d[2] |= (p->op[2]->reg) << 2; /* rd */ } else { d[1] |= (p->op[1]->reg & 0xF) << 6; d[2] |= (p->op[1]->reg & 0xF) >> 2; d[2] |= (p->op[0]->reg) << 2; /* rd */ } break; case 2: /* format P2 */ if( rn->type == OP_GPR) { /* Is a register */ d[0] = (rn->reg) & 0xF; } else if (ml_bits == 0x80 ) { /* ML are 10 -> immediate */ eval_expr(rn->value, &val, sec, pc); /* CALL/JUMP stuff */ if (m.ext.opcode == 0x4B || m.ext.opcode == 0x4C ) { val = val >> 2; /* CALL/JMP does a left shift of two bits */ } #ifdef INSTR_DEBUG fprintf(stderr, "val %06x ", val); #endif d[2] |= (val >>16) & 0x03; d[1] = (val >>8) & 0xFF; d[0] = (val ) & 0xFF; } else { /* 32 bit immediate */ eval_expr(rn->value, &val, sec, pc); #ifdef INSTR_DEBUG fprintf(stderr, "val %08x ", val); #endif d[7] = (val >>24) & 0xFF; d[6] = (val >>16) & 0xFF; d[5] = (val >>8 ) & 0xFF; d[4] = (val ) & 0xFF; } if (m.ext.rn_pos == 0) { /* Special case of STORE */ d[2] |= (p->op[1]->reg) << 2; } else { d[2] |= (p->op[0]->reg) << 2; } break; case 1: /* format P1 */ if( rn->type == OP_GPR) { /* Is a register */ d[0] = (rn->reg) & 0xF; } else if (ml_bits == 0x80 ) { /* ML are 10 -> immediate */ if (!eval_expr(rn->value, &val, sec, pc)) btype = find_base(rn->value, &base, sec, pc); /* CALL/JUMP stuff */ if (m.ext.opcode >= 0x27 && m.ext.opcode <= 0x28 ) { if (base != NULL && btype == BASE_OK) { if (is_pc_reloc(base, sec)) add_extnreloc_masked(&db->relocs, base, val-4, REL_PC, 0, 22, 0, 0xfffffc); else if (LOCREF(base)) val = val - pc - 4; /* Relative jump/call (%pc has been increased) */ base = NULL; } else val = val - pc - 4; /* Relative jump/call (%pc has been increased) */ val = val >> 2; /* CALL/JMP does a left shift of two bits */ } else if (m.ext.opcode >= 0x25 && m.ext.opcode <= 0x26 ) { if (base != NULL && btype != BASE_ILLEGAL) { add_extnreloc_masked(&db->relocs, base, val, btype == BASE_PCREL ? REL_PC : REL_ABS, 0, 22, 0, 0xfffffc); base = NULL; } val = val >> 2; /* CALL/JMP does a left shift of two bits */ } #ifdef INSTR_DEBUG fprintf(stderr, "val %06x ", val); #endif d[2] |= (val >>16) & 0x3F; d[1] = (val >>8) & 0xFF; d[0] = (val ) & 0xFF; } else { /* 32 bit immediate */ eval_expr(rn->value, &val, sec, pc); /* CALL/JUMP stuff */ if (m.ext.opcode >= 0x27 && m.ext.opcode <= 0x28 ) { val = val - pc - 4; /* Relative jump/call */ } #ifdef INSTR_DEBUG fprintf(stderr, "val %08x ", val); #endif d[7] = (val >>24) & 0xFF; d[6] = (val >>16) & 0xFF; d[5] = (val >>8 ) & 0xFF; d[4] = (val ) & 0xFF; } break; case 0: /* format NP */ #ifdef INSTR_DEBUG fprintf(stderr, "NP "); #endif default: ; } #ifdef INSTR_DEBUG { int i; for(i= db->size -1; i >= 0; i-- ) { fprintf(stderr, "%02X ", d[i]); } } fprintf(stderr, "\n"); #endif return db; } /* Create a dblock (with relocs, if necessary) for size bits of data. */ dblock *eval_data(operand *op, size_t bitsize, section *sec, taddr pc) { dblock *new=new_dblock(); taddr val; new->size = bitsize >> 3; new->data = mymalloc(new->size); #ifdef CPU_DEBUG fprintf(stderr, "eval_data "); #endif if(op->type != OP_IMM) { /* ??? */ #ifdef CPU_DEBUG fprintf(stderr, "!= OP_IMM\n"); #endif ierror(0); } if(bitsize!=8 && bitsize!=16 && bitsize!=32) { #ifdef CPU_DEBUG fprintf(stderr, "bad data size\n"); #endif cpu_error(2); /* Invalid data size */ } if(!eval_expr(op->value, &val, sec, pc) ) { symbol *base; int btype; btype = find_base(op->value, &base, sec, pc); if (base) add_extnreloc(&new->relocs, base, val, btype==BASE_PCREL ? REL_PC : REL_ABS, 0, bitsize, 0); else if (btype != BASE_NONE) general_error(38); /* illegal relocation */ } if(bitsize == 8){ new->data[0] = val & 0xFF; } else if (bitsize == 16){ new->data[1] = (val>>8) & 0xFF; new->data[0] = val & 0xFF; } else if (bitsize == 32){ new->data[3] = (val>>24) & 0xFF; new->data[2] = (val>>16) & 0xFF; new->data[1] = (val>>8) & 0xFF; new->data[0] = val & 0xFF; } return new; } /* Size of a operand * *p operand * num_operand Total number of operands * */ static taddr opsize(operand *p, unsigned char num_operands, section *sec, taddr pc) { taddr val = 0; if(!p) { return 0; } else if (p->type == OP_IMM ) { eval_expr(p->value, &val, sec, pc); if (num_operands == 3 && (val < -8192 || val > 8191) ) { /* 14 bits */ return 4; /* 32 bit immediate */ } else if (num_operands == 2 && (val < -131072 || val > 131071) ) { /* 18 bits */ return 4; /* 32 bit immediate */ } else if (num_operands == 1 && (val < -2097152 || val > 2097151) ) { /* 22 bits */ return 4; /* 32 bit immediate */ } } return 0; } /* Calculate the size of the current instruction; must be identical to the data created by eval_instruction. */ size_t instruction_size (instruction *p, section *sec, taddr pc) { size_t size = 4; /* four bytes */ unsigned char num_operands = 0; num_operands += (p->op[0] != 0)? 1 : 0; num_operands += (p->op[1] != 0)? 1 : 0; num_operands += (p->op[2] != 0)? 1 : 0; size += opsize(p->op[0], num_operands, sec, pc); size += opsize(p->op[1], num_operands, sec, pc); size += opsize(p->op[2], num_operands, sec, pc); return size; } operand *new_operand() { operand *new = mymalloc(sizeof(*new)); new->type=-1; return new; } /* return true, if initialization was successfull */ int init_cpu() { return 1; } /* return true, if the passed argument is understood */ int cpu_args(char *p) { /* no args */ return 0; } /* parse cpu-specific directives; return pointer to end of cpu-specific text */ char *parse_cpu_special(char *s) { /* no specials */ return s; }