/* GNU m4 -- A simple macro processor Copyright (C) 1989-1994, 2006-2007, 2009-2013 Free Software Foundation, Inc. This file is part of GNU M4. GNU M4 is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. GNU M4 is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* This file contains the functions to evaluate integer expressions for the "eval" macro. It is a little, fairly self-contained module, with its own scanner, and a recursive descent parser. The only entry point is evaluate (). */ #include "m4.h" /* Evaluates token types. */ typedef enum eval_token { ERROR, BADOP, PLUS, MINUS, EXPONENT, TIMES, DIVIDE, MODULO, ASSIGN, EQ, NOTEQ, GT, GTEQ, LS, LSEQ, LSHIFT, RSHIFT, LNOT, LAND, LOR, NOT, AND, OR, XOR, LEFTP, RIGHTP, NUMBER, EOTEXT } eval_token; /* Error types. */ typedef enum eval_error { NO_ERROR, DIVIDE_ZERO, MODULO_ZERO, NEGATIVE_EXPONENT, /* All errors prior to SYNTAX_ERROR can be ignored in a dead branch of && and ||. All errors after are just more details about a syntax error. */ SYNTAX_ERROR, MISSING_RIGHT, UNKNOWN_INPUT, EXCESS_INPUT, INVALID_OPERATOR } eval_error; static eval_error logical_or_term (eval_token, int32_t *); static eval_error logical_and_term (eval_token, int32_t *); static eval_error or_term (eval_token, int32_t *); static eval_error xor_term (eval_token, int32_t *); static eval_error and_term (eval_token, int32_t *); static eval_error equality_term (eval_token, int32_t *); static eval_error cmp_term (eval_token, int32_t *); static eval_error shift_term (eval_token, int32_t *); static eval_error add_term (eval_token, int32_t *); static eval_error mult_term (eval_token, int32_t *); static eval_error exp_term (eval_token, int32_t *); static eval_error unary_term (eval_token, int32_t *); static eval_error simple_term (eval_token, int32_t *); /*--------------------. | Lexical functions. | `--------------------*/ /* Pointer to next character of input text. */ static const char *eval_text; /* Value of eval_text, from before last call of eval_lex (). This is so we can back up, if we have read too much. */ static const char *last_text; static void eval_init_lex (const char *text) { eval_text = text; last_text = NULL; } static void eval_undo (void) { eval_text = last_text; } /* VAL is numerical value, if any. */ static eval_token eval_lex (int32_t *val) { while (isspace (to_uchar (*eval_text))) eval_text++; last_text = eval_text; if (*eval_text == '\0') return EOTEXT; if (isdigit (to_uchar (*eval_text))) { int base, digit; if (*eval_text == '0') { eval_text++; switch (*eval_text) { case 'x': case 'X': base = 16; eval_text++; break; case 'b': case 'B': base = 2; eval_text++; break; case 'r': case 'R': base = 0; eval_text++; while (isdigit (to_uchar (*eval_text)) && base <= 36) base = 10 * base + *eval_text++ - '0'; if (base == 0 || base > 36 || *eval_text != ':') return ERROR; eval_text++; break; default: base = 8; } } else base = 10; /* FIXME - this calculation can overflow. Consider xstrtol. */ *val = 0; for (; *eval_text; eval_text++) { if (isdigit (to_uchar (*eval_text))) digit = *eval_text - '0'; else if (islower (to_uchar (*eval_text))) digit = *eval_text - 'a' + 10; else if (isupper (to_uchar (*eval_text))) digit = *eval_text - 'A' + 10; else break; if (base == 1) { if (digit == 1) (*val)++; else if (digit == 0 && !*val) continue; else break; } else if (digit >= base) break; else *val = *val * base + digit; } return NUMBER; } switch (*eval_text++) { case '+': if (*eval_text == '+' || *eval_text == '=') return BADOP; return PLUS; case '-': if (*eval_text == '-' || *eval_text == '=') return BADOP; return MINUS; case '*': if (*eval_text == '*') { eval_text++; return EXPONENT; } else if (*eval_text == '=') return BADOP; return TIMES; case '/': if (*eval_text == '=') return BADOP; return DIVIDE; case '%': if (*eval_text == '=') return BADOP; return MODULO; case '=': if (*eval_text == '=') { eval_text++; return EQ; } return ASSIGN; case '!': if (*eval_text == '=') { eval_text++; return NOTEQ; } return LNOT; case '>': if (*eval_text == '=') { eval_text++; return GTEQ; } else if (*eval_text == '>') { if (*++eval_text == '=') return BADOP; return RSHIFT; } return GT; case '<': if (*eval_text == '=') { eval_text++; return LSEQ; } else if (*eval_text == '<') { if (*++eval_text == '=') return BADOP; return LSHIFT; } return LS; case '^': if (*eval_text == '=') return BADOP; return XOR; case '~': return NOT; case '&': if (*eval_text == '&') { eval_text++; return LAND; } else if (*eval_text == '=') return BADOP; return AND; case '|': if (*eval_text == '|') { eval_text++; return LOR; } else if (*eval_text == '=') return BADOP; return OR; case '(': return LEFTP; case ')': return RIGHTP; default: return ERROR; } } /*---------------------------------------. | Main entry point, called from "eval". | `---------------------------------------*/ bool evaluate (const char *expr, int32_t *val) { eval_token et; eval_error err; eval_init_lex (expr); et = eval_lex (val); err = logical_or_term (et, val); if (err == NO_ERROR && *eval_text != '\0') { if (eval_lex (val) == BADOP) err = INVALID_OPERATOR; else err = EXCESS_INPUT; } switch (err) { case NO_ERROR: break; case MISSING_RIGHT: M4ERROR ((warning_status, 0, "bad expression in eval (missing right parenthesis): %s", expr)); break; case SYNTAX_ERROR: M4ERROR ((warning_status, 0, "bad expression in eval: %s", expr)); break; case UNKNOWN_INPUT: M4ERROR ((warning_status, 0, "bad expression in eval (bad input): %s", expr)); break; case EXCESS_INPUT: M4ERROR ((warning_status, 0, "bad expression in eval (excess input): %s", expr)); break; case INVALID_OPERATOR: M4ERROR ((warning_status, 0, "invalid operator in eval: %s", expr)); retcode = EXIT_FAILURE; break; case DIVIDE_ZERO: M4ERROR ((warning_status, 0, "divide by zero in eval: %s", expr)); break; case MODULO_ZERO: M4ERROR ((warning_status, 0, "modulo by zero in eval: %s", expr)); break; case NEGATIVE_EXPONENT: M4ERROR ((warning_status, 0, "negative exponent in eval: %s", expr)); break; default: M4ERROR ((warning_status, 0, "INTERNAL ERROR: bad error code in evaluate ()")); abort (); } return err != NO_ERROR; } /*---------------------------. | Recursive descent parser. | `---------------------------*/ static eval_error logical_or_term (eval_token et, int32_t *v1) { int32_t v2; eval_error er; if ((er = logical_and_term (et, v1)) != NO_ERROR) return er; while ((et = eval_lex (&v2)) == LOR) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; /* Implement short-circuiting of valid syntax. */ er = logical_and_term (et, &v2); if (er == NO_ERROR) *v1 = *v1 || v2; else if (*v1 != 0 && er < SYNTAX_ERROR) *v1 = 1; else return er; } if (et == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error logical_and_term (eval_token et, int32_t *v1) { int32_t v2; eval_error er; if ((er = or_term (et, v1)) != NO_ERROR) return er; while ((et = eval_lex (&v2)) == LAND) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; /* Implement short-circuiting of valid syntax. */ er = or_term (et, &v2); if (er == NO_ERROR) *v1 = *v1 && v2; else if (*v1 == 0 && er < SYNTAX_ERROR) ; /* v1 is already 0 */ else return er; } if (et == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error or_term (eval_token et, int32_t *v1) { int32_t v2; eval_error er; if ((er = xor_term (et, v1)) != NO_ERROR) return er; while ((et = eval_lex (&v2)) == OR) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = xor_term (et, &v2)) != NO_ERROR) return er; *v1 |= v2; } if (et == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error xor_term (eval_token et, int32_t *v1) { int32_t v2; eval_error er; if ((er = and_term (et, v1)) != NO_ERROR) return er; while ((et = eval_lex (&v2)) == XOR) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = and_term (et, &v2)) != NO_ERROR) return er; *v1 ^= v2; } if (et == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error and_term (eval_token et, int32_t *v1) { int32_t v2; eval_error er; if ((er = equality_term (et, v1)) != NO_ERROR) return er; while ((et = eval_lex (&v2)) == AND) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = equality_term (et, &v2)) != NO_ERROR) return er; *v1 &= v2; } if (et == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error equality_term (eval_token et, int32_t *v1) { eval_token op; int32_t v2; eval_error er; if ((er = cmp_term (et, v1)) != NO_ERROR) return er; /* In the 1.4.x series, we maintain the traditional behavior that '=' is a synonym for '=='; however, this is contrary to POSIX and we hope to convert '=' to mean assignment in 2.0. */ while ((op = eval_lex (&v2)) == EQ || op == NOTEQ || op == ASSIGN) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = cmp_term (et, &v2)) != NO_ERROR) return er; if (op == ASSIGN) { M4ERROR ((warning_status, 0, "\ Warning: recommend ==, not =, for equality operator")); op = EQ; } *v1 = (op == EQ) == (*v1 == v2); } if (op == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error cmp_term (eval_token et, int32_t *v1) { eval_token op; int32_t v2; eval_error er; if ((er = shift_term (et, v1)) != NO_ERROR) return er; while ((op = eval_lex (&v2)) == GT || op == GTEQ || op == LS || op == LSEQ) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = shift_term (et, &v2)) != NO_ERROR) return er; switch (op) { case GT: *v1 = *v1 > v2; break; case GTEQ: *v1 = *v1 >= v2; break; case LS: *v1 = *v1 < v2; break; case LSEQ: *v1 = *v1 <= v2; break; default: M4ERROR ((warning_status, 0, "INTERNAL ERROR: bad comparison operator in cmp_term ()")); abort (); } } if (op == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error shift_term (eval_token et, int32_t *v1) { eval_token op; int32_t v2; uint32_t u1; eval_error er; if ((er = add_term (et, v1)) != NO_ERROR) return er; while ((op = eval_lex (&v2)) == LSHIFT || op == RSHIFT) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = add_term (et, &v2)) != NO_ERROR) return er; /* Minimize undefined C behavior (shifting by a negative number, shifting by the width or greater, left shift overflow, or right shift of a negative number). Implement Java 32-bit wrap-around semantics. This code assumes that the implementation-defined overflow when casting unsigned to signed is a silent twos-complement wrap-around. */ switch (op) { case LSHIFT: u1 = *v1; u1 <<= (uint32_t) (v2 & 0x1f); *v1 = u1; break; case RSHIFT: u1 = *v1 < 0 ? ~*v1 : *v1; u1 >>= (uint32_t) (v2 & 0x1f); *v1 = *v1 < 0 ? ~u1 : u1; break; default: M4ERROR ((warning_status, 0, "INTERNAL ERROR: bad shift operator in shift_term ()")); abort (); } } if (op == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error add_term (eval_token et, int32_t *v1) { eval_token op; int32_t v2; eval_error er; if ((er = mult_term (et, v1)) != NO_ERROR) return er; while ((op = eval_lex (&v2)) == PLUS || op == MINUS) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = mult_term (et, &v2)) != NO_ERROR) return er; /* Minimize undefined C behavior on overflow. This code assumes that the implementation-defined overflow when casting unsigned to signed is a silent twos-complement wrap-around. */ if (op == PLUS) *v1 = (int32_t) ((uint32_t) *v1 + (uint32_t) v2); else *v1 = (int32_t) ((uint32_t) *v1 - (uint32_t) v2); } if (op == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error mult_term (eval_token et, int32_t *v1) { eval_token op; int32_t v2; eval_error er; if ((er = exp_term (et, v1)) != NO_ERROR) return er; while ((op = eval_lex (&v2)) == TIMES || op == DIVIDE || op == MODULO) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = exp_term (et, &v2)) != NO_ERROR) return er; /* Minimize undefined C behavior on overflow. This code assumes that the implementation-defined overflow when casting unsigned to signed is a silent twos-complement wrap-around. */ switch (op) { case TIMES: *v1 = (int32_t) ((uint32_t) *v1 * (uint32_t) v2); break; case DIVIDE: if (v2 == 0) return DIVIDE_ZERO; else if (v2 == -1) /* Avoid overflow, and the x86 SIGFPE on INT_MIN / -1. */ *v1 = (int32_t) -(uint32_t) *v1; else *v1 /= v2; break; case MODULO: if (v2 == 0) return MODULO_ZERO; else if (v2 == -1) /* Avoid the x86 SIGFPE on INT_MIN % -1. */ *v1 = 0; else *v1 %= v2; break; default: M4ERROR ((warning_status, 0, "INTERNAL ERROR: bad operator in mult_term ()")); abort (); } } if (op == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error exp_term (eval_token et, int32_t *v1) { uint32_t result; int32_t v2; eval_error er; if ((er = unary_term (et, v1)) != NO_ERROR) return er; while ((et = eval_lex (&v2)) == EXPONENT) { et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if ((er = exp_term (et, &v2)) != NO_ERROR) return er; /* Minimize undefined C behavior on overflow. This code assumes that the implementation-defined overflow when casting unsigned to signed is a silent twos-complement wrap-around. */ result = 1; if (v2 < 0) return NEGATIVE_EXPONENT; if (*v1 == 0 && v2 == 0) return DIVIDE_ZERO; while (v2-- > 0) result *= (uint32_t) *v1; *v1 = result; } if (et == ERROR) return UNKNOWN_INPUT; eval_undo (); return NO_ERROR; } static eval_error unary_term (eval_token et, int32_t *v1) { eval_error er; if (et == PLUS || et == MINUS || et == NOT || et == LNOT) { eval_token et2 = eval_lex (v1); if (et2 == ERROR) return UNKNOWN_INPUT; if ((er = unary_term (et2, v1)) != NO_ERROR) return er; /* Minimize undefined C behavior on overflow. This code assumes that the implementation-defined overflow when casting unsigned to signed is a silent twos-complement wrap-around. */ if (et == MINUS) *v1 = (int32_t) -(uint32_t) *v1; else if (et == NOT) *v1 = ~*v1; else if (et == LNOT) *v1 = *v1 == 0 ? 1 : 0; } else if ((er = simple_term (et, v1)) != NO_ERROR) return er; return NO_ERROR; } static eval_error simple_term (eval_token et, int32_t *v1) { int32_t v2; eval_error er; switch (et) { case LEFTP: et = eval_lex (v1); if (et == ERROR) return UNKNOWN_INPUT; if ((er = logical_or_term (et, v1)) != NO_ERROR) return er; et = eval_lex (&v2); if (et == ERROR) return UNKNOWN_INPUT; if (et != RIGHTP) return MISSING_RIGHT; break; case NUMBER: break; case BADOP: return INVALID_OPERATOR; default: return SYNTAX_ERROR; } return NO_ERROR; }