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[/] [open8_urisc/] [trunk/] [Open8 Tools/] [open8_src/] [open8_as/] [stack.c] - Rev 301
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#include <ctype.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include "defines.h" #include "parse.h" #include "pass_1.h" #include "stack.h" #include "include_file.h" extern int input_number_error_msg, bankheader_status, input_float_mode; extern int i, size, d, macro_active, string_size, section_status, parse_floats; extern char xyz[256], *buffer, tmp[4096], expanded_macro_string[256], label[MAX_NAME_LENGTH]; extern struct definition *defines, *tmp_def, *next_def; extern struct active_file_info *active_file_info_first, *active_file_info_last, *active_file_info_tmp; extern struct macro_runtime *macro_runtime_current; extern struct section_def *sec_tmp; extern double flo; int latest_stack = 0, stacks_inside = 0, stacks_outside = 0, stack_id = 0; struct stack *stacks_first = NULL, *stacks_tmp = NULL, *stacks_last = NULL; struct stack *stacks_header_first = NULL, *stacks_header_last = NULL; extern int stack_inserted; extern int operand_hint; static int _stack_insert(void) { /* outside bankheader sections */ if (bankheader_status == OFF) { if (stacks_first == NULL) { stacks_first = stacks_tmp; stacks_last = stacks_tmp; } else { stacks_last->next = stacks_tmp; stacks_last = stacks_tmp; } stacks_outside++; stack_inserted = STACK_OUTSIDE; } /* inside a bankheader section */ else { if (stacks_header_first == NULL) { stacks_header_first = stacks_tmp; stacks_header_last = stacks_tmp; } else { stacks_header_last->next = stacks_tmp; stacks_header_last = stacks_tmp; } stacks_inside++; stack_inserted = STACK_INSIDE; } stacks_tmp->id = stack_id; stacks_tmp->section_status = section_status; if (section_status == ON) stacks_tmp->section_id = sec_tmp->id; else stacks_tmp->section_id = 0; latest_stack = stack_id; stack_id++; return SUCCEEDED; } int stack_calculate(char *in, int *value) { int q = 0, b = 0, d, k, op[256], n, o, l; struct stack_item si[256], ta[256]; struct stack s; unsigned char e; double dou, dom; /* slice the data into infix format */ while (*in != 0x0A) { /* init the stack item */ si[q].type = 0x123456; si[q].sign = 0x123456; si[q].value = 0x123456; si[q].string[0] = 0; if (*in == ' ') { in++; continue; } else if (*in == '-') { if (*(in + 1) == '-') { si[q].type = STACK_ITEM_TYPE_STRING; si[q].sign = SI_SIGN_POSITIVE; for (k = 0; *in == '-' && k < 32; k++, in++) { si[q].string[k] = '-'; } si[q].string[k] = 0; } else { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_MINUS; in++; } q++; } else if (*in == '+') { if (*(in + 1) == '+') { si[q].type = STACK_ITEM_TYPE_STRING; si[q].sign = SI_SIGN_POSITIVE; for (k = 0; *in == '+' && k < 32; k++, in++) si[q].string[k] = '+'; si[q].string[k] = 0; } else { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_PLUS; in++; } q++; } else if (*in == '*') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_MULTIPLY; q++; in++; } else if (*in == '/') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_DIVIDE; q++; in++; } else if (*in == '|') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_OR; q++; in++; } else if (*in == '&') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_AND; q++; in++; } else if (*in == '^') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_POWER; q++; in++; } else if (*in == '#') { if (q == 0) { if (input_number_error_msg == YES) print_error("Syntax error. Invalid use of modulo.\n", ERROR_STC); return FAILED; } si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_MODULO; q++; in++; } else if (*in == '<' && *(in + 1) == '<') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_SHIFT_LEFT; q++; in += 2; } else if (*in == '<') { /* should we end parsing here? */ if (b == 0 && q > 0) { if ((si[q-1].type == STACK_ITEM_TYPE_OPERATOR && si[q-1].value == SI_OP_RIGHT) || si[q-1].type == STACK_ITEM_TYPE_VALUE || si[q-1].type == STACK_ITEM_TYPE_STRING) break; } si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_LOW_BYTE; q++; in++; } else if (*in == '>' && *(in + 1) == '>') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_SHIFT_RIGHT; q++; in += 2; } else if (*in == '>') { /* should we end parsing here? */ if (b == 0 && q > 0) { if ((si[q-1].type == STACK_ITEM_TYPE_OPERATOR && si[q-1].value == SI_OP_RIGHT) || si[q-1].type == STACK_ITEM_TYPE_VALUE || si[q-1].type == STACK_ITEM_TYPE_STRING) break; } si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_HIGH_BYTE; q++; in++; } else if (*in == '~') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_XOR; q++; in++; } else if (*in == '=' && *(in + 1) == '=') break; else if (*in == '!' && *(in + 1) == '=') break; else if (*in == '(') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_LEFT; q++; b++; in++; } else if (*in == '.') { in++; d = operand_hint; if (*in == 'b' || *in == 'B') { operand_hint = HINT_8BIT; in++; } else if (*in == 'w' || *in == 'W') { operand_hint = HINT_16BIT; in++; } else break; if (d != HINT_NONE && d != operand_hint) { print_error("Confusing operand hint!\n", ERROR_STC); in++; } } else if (*in == ')') { si[q].type = STACK_ITEM_TYPE_OPERATOR; si[q].value = SI_OP_RIGHT; /* end of expression? */ if (b == 0) break; b--; q++; in++; } else if (*in == ',') break; else if (*in == ']') break; else if (*in == '%') { d = 0; for (k = 0; k < 31; k++, d = d<<1) { in++; e = *in; if (e == '0' || e == '1') d += e - '0'; else if (e == ' ' || e == ')' || e == '|' || e == '&' || e == '+' || e == '-' || e == '*' || e == '/' || e == ',' || e == '^' || e == '<' || e == '>' || e == '#' || e == '~' || e == ']' || e == '.' || e == 0x0A) break; else { if (input_number_error_msg == YES) { sprintf(xyz, "Got '%c' (%d) when expected (0/1).\n", e, e); print_error(xyz, ERROR_NUM); } return FAILED; } } d = d>>1; si[q].type = STACK_ITEM_TYPE_VALUE; si[q].value = d; si[q].sign = SI_SIGN_POSITIVE; q++; } else if (*in == '\'') { in++; d = *in; in++; if (*in != '\'') { sprintf(xyz, "Got '%c' (%d) when expected \"'\".\n", *in, *in); print_error(xyz, ERROR_NUM); return FAILED; } in++; si[q].type = STACK_ITEM_TYPE_VALUE; si[q].value = d; si[q].sign = SI_SIGN_POSITIVE; q++; } else if (*in == '$') { d = 0; for (k = 0; k < 8; k++, d = d << 4) { in++; e = *in; if (e >= '0' && e <= '9') d += e - '0'; else if (e >= 'A' && e <= 'F') d += e - 'A' + 10; else if (e >= 'a' && e <= 'f') d += e - 'a' + 10; else if (e == ' ' || e == ')' || e == '|' || e == '&' || e == '+' || e == '-' || e == '*' || e == '/' || e == ',' || e == '^' || e == '<' || e == '>' || e == '#' || e == '~' || e == ']' || e == '.' || e == 0x0A) break; else { if (input_number_error_msg == YES) { sprintf(xyz, "Got '%c' (%d) when expected (0-F).\n", e, e); print_error(xyz, ERROR_NUM); } return FAILED; } } d = d >> 4; si[q].type = STACK_ITEM_TYPE_VALUE; si[q].value = d; si[q].sign = SI_SIGN_POSITIVE; q++; } else if (*in >= '0' && *in <= '9') { /* is it a hexadecimal value after all? */ n = 0; for (k = 0; k < 9; k++) { if (in[k] >= '0' && in[k] <= '9') continue; if (in[k] >= 'a' && in[k] <= 'f') { n = 1; break; } if (in[k] >= 'A' && in[k] <= 'F') { n = 1; break; } if (in[k] == 'h' || in[k] == 'H') { n = 1; break; } break; } if (n == 1) { /* it's hex */ d = 0; for (k = 0; k < 8; k++, d = d << 4) { e = *(in++); if (e >= '0' && e <= '9') d += e - '0'; else if (e >= 'A' && e <= 'F') d += e - 'A' + 10; else if (e >= 'a' && e <= 'f') d += e - 'a' + 10; else if (e == ' ' || e == ')' || e == '|' || e == '&' || e == '+' || e == '-' || e == '*' || e == '/' || e == ',' || e == '^' || e == '<' || e == '>' || e == '#' || e == '~' || e == ']' || e == '.' || e == 'h' || e == 'H' || e == 0x0A) break; else { if (input_number_error_msg == YES) { sprintf(xyz, "Got '%c' (%d) when expected (0-F).\n", e, e); print_error(xyz, ERROR_NUM); } return FAILED; } } d = d >> 4; si[q].type = STACK_ITEM_TYPE_VALUE; si[q].value = d; si[q].sign = SI_SIGN_POSITIVE; q++; } else { /* it's decimal */ dou = (*in - '0')*10.0; dom = 1.0; n = 0; for (k = 0; k < 9; k++) { in++; e = *in; if (e >= '0' && e <= '9') { if (n == 0) { dou += e - '0'; dou *= 10.0; } else if (n == 1) { dou += dom*(e - '0'); dom /= 10.0; } } else if (e == ' ' || e == ')' || e == '|' || e == '&' || e == '+' || e == '-' || e == '*' || e == '/' || e == ',' || e == '^' || e == '<' || e == '>' || e == '#' || e == '~' || e == ']' || e == 0x0A) break; else if (e == '.') { if (*(in+1) == 'b' || *(in+1) == 'B' || *(in+1) == 'w' || *(in+1) == 'W') break; if (parse_floats == NO) break; if (n == 1) { if (input_number_error_msg == YES) print_error("Syntax error.\n", ERROR_NUM); return FAILED; } n = 1; } else { if (input_number_error_msg == YES) { sprintf(xyz, "Got '%c' (%d) when expected (0-9).\n", e, e); print_error(xyz, ERROR_NUM); } return FAILED; } } dou /= 10; si[q].type = STACK_ITEM_TYPE_VALUE; si[q].value = dou; si[q].sign = SI_SIGN_POSITIVE; q++; } } else { /* it must be a string! */ si[q].sign = SI_SIGN_POSITIVE; for (k = 0; k < 63; k++) { e = *in; if (e == ' ' || e == ')' || e == '|' || e == '&' || e == '+' || e == '-' || e == '*' || e == '/' || e == ',' || e == '^' || e == '<' || e == '>' || e == '#' || e == ']' || e == '~' || e == 0xA) break; if (e == '.' && (*(in+1) == 'b' || *(in+1) == 'B' || *(in+1) == 'w' || *(in+1) == 'W' || *(in+1) == 'l' || *(in+1) == 'L') && (*(in+2) == ' ' || *(in+2) == ')' || *(in+2) == '|' || *(in+2) == '&' || *(in+2) == '+' || *(in+2) == '-' || *(in+2) == '*' || *(in+2) == '/' || *(in+2) == ',' || *(in+2) == '^' || *(in+2) == '<' || *(in+2) == '>' || *(in+2) == '#' || *(in+2) == ']' || *(in+2) == '~' || *(in+2) == 0xA)) break; si[q].string[k] = e; in++; } si[q].string[k] = 0; si[q].type = STACK_ITEM_TYPE_STRING; q++; } if (q == 255) { print_error("Out of stack space.\n", ERROR_STC); return FAILED; } } if (b != 0) { print_error("Unbalanced parentheses.\n", ERROR_STC); return FAILED; } /* only one item found -> let the item parser handle it */ if (q == 1) return STACK_CALCULATE_DELAY; /* check if there was data before the computation */ if (q > 1 && (si[0].type == STACK_ITEM_TYPE_STRING || si[0].type == STACK_ITEM_TYPE_VALUE)) { if (si[1].type == STACK_ITEM_TYPE_STRING || si[1].type == STACK_ITEM_TYPE_VALUE) return STACK_CALCULATE_DELAY; if (si[1].type == STACK_ITEM_TYPE_OPERATOR) { if (si[1].value == SI_OP_LEFT) return STACK_CALCULATE_DELAY; } } /* check if the computation is of the form "+-..." and remove that leading "+" */ if (q > 2 && si[0].type == STACK_ITEM_TYPE_OPERATOR && si[0].value == SI_OP_PLUS && si[1].type == STACK_ITEM_TYPE_OPERATOR && si[1].value == SI_OP_MINUS) { si[0].type = STACK_ITEM_TYPE_DELETED; } /* update the source pointer */ i = in - buffer; /* fix the sign in every operand */ for (b = 1, k = 0; k < q; k++) { if ((q - k) != 1 && si[k].type == STACK_ITEM_TYPE_OPERATOR && si[k + 1].type == STACK_ITEM_TYPE_OPERATOR) { if (si[k].value != SI_OP_LEFT && si[k].value != SI_OP_RIGHT && si[k + 1].value != SI_OP_LEFT && si[k + 1].value != SI_OP_RIGHT) { print_error("Error in computation syntax.\n", ERROR_STC); return FAILED; } } if (si[k].type == STACK_ITEM_TYPE_OPERATOR && si[k].value == SI_OP_MINUS && b == 1) { if (si[k + 1].type == STACK_ITEM_TYPE_VALUE || si[k + 1].type == STACK_ITEM_TYPE_STRING) { if (si[k + 1].sign == SI_SIGN_POSITIVE) si[k + 1].sign = SI_SIGN_NEGATIVE; else si[k + 1].sign = SI_SIGN_POSITIVE; /* it wasn't a minus operator, it was a sign */ si[k].type = STACK_ITEM_TYPE_DELETED; } else if (si[k + 1].type == STACK_ITEM_TYPE_OPERATOR && si[k + 1].value == SI_OP_LEFT) { o = 1; l = k + 2; while (o > 0 && l < q) { if (si[l].type == STACK_ITEM_TYPE_VALUE || si[l].type == STACK_ITEM_TYPE_STRING) { if (si[l].sign == SI_SIGN_POSITIVE) si[l].sign = SI_SIGN_NEGATIVE; else si[l].sign = SI_SIGN_POSITIVE; } else if (si[l].type == STACK_ITEM_TYPE_OPERATOR) { if (si[l].value == SI_OP_LEFT) o++; else if (si[l].value == SI_OP_RIGHT) o--; } l++; } if (o != 0) { print_error("Unbalanced parentheses.\n", ERROR_STC); return FAILED; } si[k].type = STACK_ITEM_TYPE_DELETED; } } /* remove unnecessary + */ if (si[k].type == STACK_ITEM_TYPE_OPERATOR && si[k].value == SI_OP_PLUS && b == 1) { if (si[k + 1].type == STACK_ITEM_TYPE_VALUE || si[k + 1].type == STACK_ITEM_TYPE_STRING) si[k].type = STACK_ITEM_TYPE_DELETED; else if (si[k + 1].type == STACK_ITEM_TYPE_OPERATOR && si[k + 1].value == SI_OP_LEFT) si[k].type = STACK_ITEM_TYPE_DELETED; } else if (si[k].type == STACK_ITEM_TYPE_VALUE || si[k].type == STACK_ITEM_TYPE_STRING) b = 0; else if (si[k].type == STACK_ITEM_TYPE_OPERATOR && si[k].value == SI_OP_LEFT) b = 1; } /* convert infix stack into postfix stack */ for (b = 0, k = 0, d = 0; k < q; k++) { /* operands pass through */ if (si[k].type == STACK_ITEM_TYPE_VALUE) { ta[d].type = si[k].type; ta[d].value = si[k].value; ta[d].sign = si[k].sign; d++; } else if (si[k].type == STACK_ITEM_TYPE_STRING) { ta[d].type = si[k].type; strcpy(ta[d].string, si[k].string); ta[d].sign = si[k].sign; d++; } /* operators get inspected */ else if (si[k].type == STACK_ITEM_TYPE_OPERATOR) { if (b == 0) { op[0] = si[k].value; b++; } else { if (si[k].value == SI_OP_PLUS) { b--; while (b != -1 && op[b] != SI_OP_LEFT) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_PLUS; b++; } else if (si[k].value == SI_OP_MINUS) { b--; while (b != -1 && op[b] != SI_OP_LEFT) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_MINUS; b++; } else if (si[k].value == SI_OP_LOW_BYTE) { b--; while (b != -1 && op[b] != SI_OP_LEFT) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_LOW_BYTE; b++; } else if (si[k].value == SI_OP_HIGH_BYTE) { b--; while (b != -1 && op[b] != SI_OP_LEFT) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_HIGH_BYTE; b++; } else if (si[k].value == SI_OP_XOR) { b--; while (b != -1 && op[b] != SI_OP_LEFT) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_XOR; b++; } else if (si[k].value == SI_OP_MULTIPLY) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_MULTIPLY; b++; } else if (si[k].value == SI_OP_DIVIDE) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_DIVIDE; b++; } else if (si[k].value == SI_OP_MODULO) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_MODULO; b++; } else if (si[k].value == SI_OP_POWER) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_POWER; b++; } else if (si[k].value == SI_OP_SHIFT_LEFT) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_SHIFT_LEFT; b++; } else if (si[k].value == SI_OP_SHIFT_RIGHT) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_SHIFT_RIGHT; b++; } else if (si[k].value == SI_OP_AND) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_AND; b++; } else if (si[k].value == SI_OP_OR) { b--; while (b != -1 && op[b] != SI_OP_LEFT && op[b] != SI_OP_PLUS && op[b] != SI_OP_MINUS) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } b++; op[b] = SI_OP_OR; b++; } else if (si[k].value == SI_OP_LEFT) { op[b] = SI_OP_LEFT; b++; } else if (si[k].value == SI_OP_RIGHT) { b--; while (op[b] != SI_OP_LEFT) { ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; b--; d++; } } } } } /* empty the operator stack */ while (b > 0) { b--; ta[d].type = STACK_ITEM_TYPE_OPERATOR; ta[d].value = op[b]; d++; } /* DEBUG output printf("STACK ID %d LINE %d\n", stack_id, active_file_info_last->line_current); for (k = 0; k < d; k++) { char ar[] = "+-*()|&/^«»%~<>"; if (ta[k].type == STACK_ITEM_TYPE_OPERATOR) printf("%c ", ar[((int)ta[k].value)]); else if (ta[k].type == STACK_ITEM_TYPE_VALUE) printf("V(%f) ", ta[k].value); else printf("S(%s) ", ta[k].string); } printf("\n"); */ /* are all the symbols known? */ if (resolve_stack(ta, d) == SUCCEEDED) { s.stack = ta; s.linenumber = active_file_info_last->line_current; s.filename_id = active_file_info_last->filename_id; if (compute_stack(&s, d, &dou) == FAILED) return FAILED; if (input_float_mode == ON) { flo = dou; return INPUT_NUMBER_FLOAT; } *value = (int)dou; return SUCCEEDED; } /* only one string? */ if (d == 1 && ta[0].type == STACK_ITEM_TYPE_STRING) { strcpy(label, ta[0].string); return STACK_RETURN_LABEL; } /* we have a stack full of computation and we save it for wlalink */ stacks_tmp = malloc(sizeof(struct stack)); if (stacks_tmp == NULL) { print_error("Out of memory error while allocating room for a new stack.\n", ERROR_STC); return FAILED; } stacks_tmp->next = NULL; stacks_tmp->type = STACKS_TYPE_UNKNOWN; stacks_tmp->bank = -123456; stacks_tmp->stacksize = d; stacks_tmp->stack = malloc(sizeof(struct stack_item) * d); if (stacks_tmp->stack == NULL) { free(stacks_tmp); print_error("Out of memory error while allocating room for a new stack.\n", ERROR_STC); return FAILED; } stacks_tmp->linenumber = active_file_info_last->line_current; stacks_tmp->filename_id = active_file_info_last->filename_id; /* all stacks will be definition stacks by default. pass_4 will mark those that are referenced to be STACK_POSITION_CODE stacks */ stacks_tmp->position = STACK_POSITION_DEFINITION; for (q = 0; q < d; q++) { if (ta[q].type == STACK_ITEM_TYPE_OPERATOR) { stacks_tmp->stack[q].type = STACK_ITEM_TYPE_OPERATOR; stacks_tmp->stack[q].value = ta[q].value; } else if (ta[q].type == STACK_ITEM_TYPE_VALUE) { stacks_tmp->stack[q].type = STACK_ITEM_TYPE_VALUE; stacks_tmp->stack[q].value = ta[q].value; stacks_tmp->stack[q].sign = ta[q].sign; } else if (ta[q].type == STACK_ITEM_TYPE_STACK) { stacks_tmp->stack[q].type = STACK_ITEM_TYPE_STACK; stacks_tmp->stack[q].value = ta[q].value; stacks_tmp->stack[q].sign = ta[q].sign; } else { stacks_tmp->stack[q].type = STACK_ITEM_TYPE_STRING; stacks_tmp->stack[q].sign = ta[q].sign; strcpy(stacks_tmp->stack[q].string, ta[q].string); } } _stack_insert(); return INPUT_NUMBER_STACK; } int resolve_stack(struct stack_item s[], int x) { struct macro_argument *ma; struct stack_item *st; int a, b, k, q = x; char c; st = s; while (x > 0) { if (s->type == STACK_ITEM_TYPE_STRING) { if (macro_active != 0 && s->string[0] == '\\') { if (s->string[1] == '@' && s->string[2] == 0) { s->type = STACK_ITEM_TYPE_VALUE; s->value = macro_runtime_current->macro->calls - 1; } else { for (a = 0, b = 0; s->string[a + 1] != 0 && a < 10; a++) { c = s->string[a + 1]; if (c < '0' && c > '9') { print_error("Error in MACRO argument number definition.\n", ERROR_DIR); return FAILED; } b = (b * 10) + (c - '0'); } if (b > macro_runtime_current->supplied_arguments) { sprintf(xyz, "Reference to MACRO argument number %d is out of range.\n", b); print_error(xyz, ERROR_STC); return FAILED; } /* return the macro argument */ ma = macro_runtime_current->argument_data[b - 1]; k = ma->type; if (k == INPUT_NUMBER_ADDRESS_LABEL) strcpy(label, ma->string); else if (k == INPUT_NUMBER_STRING) { strcpy(label, ma->string); string_size = strlen(ma->string); } else if (k == INPUT_NUMBER_STACK) latest_stack = ma->value; else if (k == SUCCEEDED) d = ma->value; if (!(k == SUCCEEDED || k == INPUT_NUMBER_ADDRESS_LABEL || k == INPUT_NUMBER_STACK)) return FAILED; if (k == SUCCEEDED) { s->type = STACK_ITEM_TYPE_VALUE; s->value = d; } else if (k == INPUT_NUMBER_STACK) { s->type = STACK_ITEM_TYPE_STACK; s->value = latest_stack; } else strcpy(s->string, label); } } else { if (macro_active != 0) { /* expand e.g., \1 and \@ */ d = 0; if (expand_macro_arguments(s->string, &d) == FAILED) return FAILED; strcpy(s->string, expanded_macro_string); } tmp_def = defines; while (tmp_def != NULL) { if (strcmp(tmp_def->alias, s->string) == 0) { if (tmp_def->type == DEFINITION_TYPE_STRING) { sprintf(xyz, "Definition \"%s\" is a string definition.\n", tmp_def->alias); print_error(xyz, ERROR_STC); return FAILED; } else if (tmp_def->type == DEFINITION_TYPE_STACK) { /* skip stack definitions -> use its name instead */ } else { s->type = STACK_ITEM_TYPE_VALUE; s->value = tmp_def->value; break; } } tmp_def = tmp_def->next; } } } s++; x--; } /* find a string or a stack and fail */ while (q > 0) { if (st->type == STACK_ITEM_TYPE_STRING || st->type == STACK_ITEM_TYPE_STACK) return FAILED; q--; st++; } return SUCCEEDED; } int compute_stack(struct stack *sta, int x, double *result) { struct stack_item *s; double v[256], q; int r, t, z; s = sta->stack; for (r = 0, t = 0; r < x; r++, s++) { if (s->type == STACK_ITEM_TYPE_VALUE) { if (s->sign == SI_SIGN_NEGATIVE) v[t] = -s->value; else v[t] = s->value; t++; } else { switch ((int)s->value) { case SI_OP_PLUS: v[t - 2] += v[t - 1]; t--; break; case SI_OP_MINUS: v[t - 2] -= v[t - 1]; t--; break; case SI_OP_MULTIPLY: v[t - 2] *= v[t - 1]; t--; break; case SI_OP_LOW_BYTE: z = (int)v[t - 1]; v[t - 1] = z & 0xFF; break; case SI_OP_HIGH_BYTE: z = (int)v[t - 1]; v[t - 1] = (z>>8) & 0xFF; break; case SI_OP_XOR: /* 16bit XOR? */ if (v[t - 2] > 0xFF || v[t - 2] < -128 || v[t - 1] > 0xFF || v[t - 1] < -128) v[t - 2] = ((int)v[t - 1] ^ (int)v[t - 2]) & 0xFFFF; /* 8bit XOR */ else v[t - 2] = ((int)v[t - 1] ^ (int)v[t - 2]) & 0xFF; t--; break; case SI_OP_OR: v[t - 2] = (int)v[t - 1] | (int)v[t - 2]; t--; break; case SI_OP_AND: v[t - 2] = (int)v[t - 1] & (int)v[t - 2]; t--; break; case SI_OP_MODULO: if (((int)v[t - 1]) == 0) { fprintf(stderr, "%s:%d: COMPUTE_STACK: Modulo by zero.\n", get_file_name(sta->filename_id), sta->linenumber); return FAILED; } v[t - 2] = (int)v[t - 2] % (int)v[t - 1]; t--; break; case SI_OP_DIVIDE: if (((int)v[t - 1]) == 0) { fprintf(stderr, "%s:%d: COMPUTE_STACK: Division by zero.\n", get_file_name(sta->filename_id), sta->linenumber); return FAILED; } v[t - 2] /= v[t - 1]; t--; break; case SI_OP_POWER: q = 1; for (z = 0; z < v[t - 1]; z++) q *= v[t - 2]; v[t - 2] = q; t--; break; case SI_OP_SHIFT_LEFT: v[t - 2] = (int)v[t - 2] << (int)v[t - 1]; t--; break; case SI_OP_SHIFT_RIGHT: v[t - 2] = (int)v[t - 2] >> (int)v[t - 1]; t--; break; } } } if (v[0] < -32768 || v[0] > 65536) { print_error("Out of 16bit range.\n", ERROR_STC); return FAILED; } *result = v[0]; return SUCCEEDED; } int stack_create_label_stack(char *label) { if (label == NULL) return FAILED; /* we need to create a stack that holds just one label */ stacks_tmp = malloc(sizeof(struct stack)); if (stacks_tmp == NULL) { print_error("Out of memory error while allocating room for a new stack.\n", ERROR_STC); return FAILED; } stacks_tmp->next = NULL; stacks_tmp->type = STACKS_TYPE_UNKNOWN; stacks_tmp->bank = -123456; stacks_tmp->stacksize = 1; stacks_tmp->stack = malloc(sizeof(struct stack_item) * 1); if (stacks_tmp->stack == NULL) { free(stacks_tmp); print_error("Out of memory error while allocating room for a new stack.\n", ERROR_STC); return FAILED; } stacks_tmp->linenumber = active_file_info_last->line_current; stacks_tmp->filename_id = active_file_info_last->filename_id; /* all stacks will be definition stacks by default. pass_4 will mark those that are referenced to be STACK_POSITION_CODE stacks */ stacks_tmp->position = STACK_POSITION_DEFINITION; stacks_tmp->stack[0].type = STACK_ITEM_TYPE_STRING; stacks_tmp->stack[0].sign = SI_SIGN_POSITIVE; strcpy(stacks_tmp->stack[0].string, label); _stack_insert(); return SUCCEEDED; }
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