/* Copyright (C) 1991-1992, 1997, 1999, 2003, 2006, 2008-2021 Free Software Foundation, Inc. This program 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. This program 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 . */ #if ! defined USE_LONG_DOUBLE # include #endif /* Specification. */ #include #include /* isspace() */ #include #include /* {DBL,LDBL}_{MIN,MAX} */ #include /* LONG_{MIN,MAX} */ #include /* localeconv() */ #include /* NAN */ #include #include /* sprintf() */ #include /* strdup() */ #if HAVE_NL_LANGINFO # include #endif #include "c-ctype.h" #undef MIN #undef MAX #ifdef USE_LONG_DOUBLE # define STRTOD strtold # define LDEXP ldexpl # if defined __hpux && defined __hppa /* We cannot call strtold on HP-UX/hppa, because its return type is a struct, not a 'long double'. */ # define HAVE_UNDERLYING_STRTOD 0 # elif STRTOLD_HAS_UNDERFLOW_BUG /* strtold would not set errno=ERANGE upon underflow. */ # define HAVE_UNDERLYING_STRTOD 0 # else # define HAVE_UNDERLYING_STRTOD HAVE_STRTOLD # endif # define DOUBLE long double # define MIN LDBL_MIN # define MAX LDBL_MAX # define L_(literal) literal##L #else # define STRTOD strtod # define LDEXP ldexp # define HAVE_UNDERLYING_STRTOD 1 # define DOUBLE double # define MIN DBL_MIN # define MAX DBL_MAX # define L_(literal) literal #endif #if (defined USE_LONG_DOUBLE ? HAVE_LDEXPM_IN_LIBC : HAVE_LDEXP_IN_LIBC) # define USE_LDEXP 1 #else # define USE_LDEXP 0 #endif /* Return true if C is a space in the current locale, avoiding problems with signed char and isspace. */ static bool locale_isspace (char c) { unsigned char uc = c; return isspace (uc) != 0; } /* Determine the decimal-point character according to the current locale. */ static char decimal_point_char (void) { const char *point; /* Determine it in a multithread-safe way. We know nl_langinfo is multithread-safe on glibc systems and Mac OS X systems, but is not required to be multithread-safe by POSIX. sprintf(), however, is multithread-safe. localeconv() is rarely multithread-safe. */ #if HAVE_NL_LANGINFO && (__GLIBC__ || defined __UCLIBC__ || (defined __APPLE__ && defined __MACH__)) point = nl_langinfo (RADIXCHAR); #elif 1 char pointbuf[5]; sprintf (pointbuf, "%#.0f", 1.0); point = &pointbuf[1]; #else point = localeconv () -> decimal_point; #endif /* The decimal point is always a single byte: either '.' or ','. */ return (point[0] != '\0' ? point[0] : '.'); } #if !USE_LDEXP #undef LDEXP #define LDEXP dummy_ldexp /* A dummy definition that will never be invoked. */ static DOUBLE LDEXP (DOUBLE x _GL_UNUSED, int exponent _GL_UNUSED) { abort (); return L_(0.0); } #endif /* Return X * BASE**EXPONENT. Return an extreme value and set errno to ERANGE if underflow or overflow occurs. */ static DOUBLE scale_radix_exp (DOUBLE x, int radix, long int exponent) { /* If RADIX == 10, this code is neither precise nor fast; it is merely a straightforward and relatively portable approximation. If N == 2, this code is precise on a radix-2 implementation, albeit perhaps not fast if ldexp is not in libc. */ long int e = exponent; if (USE_LDEXP && radix == 2) return LDEXP (x, e < INT_MIN ? INT_MIN : INT_MAX < e ? INT_MAX : e); else { DOUBLE r = x; if (r != 0) { if (e < 0) { while (e++ != 0) { r /= radix; if (r == 0 && x != 0) { errno = ERANGE; break; } } } else { while (e-- != 0) { if (r < -MAX / radix) { errno = ERANGE; return -HUGE_VAL; } else if (MAX / radix < r) { errno = ERANGE; return HUGE_VAL; } else r *= radix; } } } return r; } } /* Parse a number at NPTR; this is a bit like strtol (NPTR, ENDPTR) except there are no leading spaces or signs or "0x", and ENDPTR is nonnull. The number uses a base BASE (either 10 or 16) fraction, a radix RADIX (either 10 or 2) exponent, and exponent character EXPCHAR. BASE is RADIX**RADIX_MULTIPLIER. */ static DOUBLE parse_number (const char *nptr, int base, int radix, int radix_multiplier, char radixchar, char expchar, char **endptr) { const char *s = nptr; const char *digits_start; const char *digits_end; const char *radixchar_ptr; long int exponent; DOUBLE num; /* First, determine the start and end of the digit sequence. */ digits_start = s; radixchar_ptr = NULL; for (;; ++s) { if (base == 16 ? c_isxdigit (*s) : c_isdigit (*s)) ; else if (radixchar_ptr == NULL && *s == radixchar) { /* Record that we have found the decimal point. */ radixchar_ptr = s; } else /* Any other character terminates the digit sequence. */ break; } digits_end = s; /* Now radixchar_ptr == NULL or digits_start <= radixchar_ptr < digits_end. */ if (false) { /* Unoptimized. */ exponent = (radixchar_ptr != NULL ? - (long int) (digits_end - radixchar_ptr - 1) : 0); } else { /* Remove trailing zero digits. This reduces rounding errors for inputs such as 1.0000000000 or 10000000000e-10. */ while (digits_end > digits_start) { if (digits_end - 1 == radixchar_ptr || *(digits_end - 1) == '0') digits_end--; else break; } exponent = (radixchar_ptr != NULL ? (digits_end > radixchar_ptr ? - (long int) (digits_end - radixchar_ptr - 1) : (long int) (radixchar_ptr - digits_end)) : (long int) (s - digits_end)); } /* Then, convert the digit sequence to a number. */ { const char *dp; num = 0; for (dp = digits_start; dp < digits_end; dp++) if (dp != radixchar_ptr) { int digit; /* Make sure that multiplication by BASE will not overflow. */ if (!(num <= MAX / base)) { /* The value of the digit and all subsequent digits don't matter, since we have already gotten as many digits as can be represented in a 'DOUBLE'. This doesn't necessarily mean that the result will overflow: The exponent may reduce it to within range. */ exponent += (digits_end - dp) - (radixchar_ptr >= dp && radixchar_ptr < digits_end ? 1 : 0); break; } /* Eat the next digit. */ if (c_isdigit (*dp)) digit = *dp - '0'; else if (base == 16 && c_isxdigit (*dp)) digit = c_tolower (*dp) - ('a' - 10); else abort (); num = num * base + digit; } } exponent = exponent * radix_multiplier; /* Finally, parse the exponent. */ if (c_tolower (*s) == expchar && ! locale_isspace (s[1])) { /* Add any given exponent to the implicit one. */ int saved_errno = errno; char *end; long int value = strtol (s + 1, &end, 10); errno = saved_errno; if (s + 1 != end) { /* Skip past the exponent, and add in the implicit exponent, resulting in an extreme value on overflow. */ s = end; exponent = (exponent < 0 ? (value < LONG_MIN - exponent ? LONG_MIN : exponent + value) : (LONG_MAX - exponent < value ? LONG_MAX : exponent + value)); } } *endptr = (char *) s; return scale_radix_exp (num, radix, exponent); } /* HP cc on HP-UX 10.20 has a bug with the constant expression -0.0. ICC 10.0 has a bug when optimizing the expression -zero. The expression -MIN * MIN does not work when cross-compiling to PowerPC on Mac OS X 10.5. */ static DOUBLE minus_zero (void) { #if defined __hpux || defined __sgi || defined __ICC return -MIN * MIN; #else return -0.0; #endif } /* Convert NPTR to a DOUBLE. If ENDPTR is not NULL, a pointer to the character after the last one used in the number is put in *ENDPTR. */ DOUBLE STRTOD (const char *nptr, char **endptr) #if HAVE_UNDERLYING_STRTOD # ifdef USE_LONG_DOUBLE # undef strtold # else # undef strtod # endif #else # undef STRTOD # define STRTOD(NPTR,ENDPTR) \ parse_number (NPTR, 10, 10, 1, radixchar, 'e', ENDPTR) #endif /* From here on, STRTOD refers to the underlying implementation. It needs to handle only finite unsigned decimal numbers with non-null ENDPTR. */ { char radixchar; bool negative = false; /* The number so far. */ DOUBLE num; const char *s = nptr; const char *end; char *endbuf; int saved_errno = errno; radixchar = decimal_point_char (); /* Eat whitespace. */ while (locale_isspace (*s)) ++s; /* Get the sign. */ negative = *s == '-'; if (*s == '-' || *s == '+') ++s; num = STRTOD (s, &endbuf); end = endbuf; if (c_isdigit (s[*s == radixchar])) { /* If a hex float was converted incorrectly, do it ourselves. If the string starts with "0x" but does not contain digits, consume the "0" ourselves. If a hex float is followed by a 'p' but no exponent, then adjust the end pointer. */ if (*s == '0' && c_tolower (s[1]) == 'x') { if (! c_isxdigit (s[2 + (s[2] == radixchar)])) { end = s + 1; /* strtod() on z/OS returns ERANGE for "0x". */ errno = saved_errno; } else if (end <= s + 2) { num = parse_number (s + 2, 16, 2, 4, radixchar, 'p', &endbuf); end = endbuf; } else { const char *p = s + 2; while (p < end && c_tolower (*p) != 'p') p++; if (p < end && ! c_isdigit (p[1 + (p[1] == '-' || p[1] == '+')])) { char *dup = strdup (s); errno = saved_errno; if (!dup) { /* Not really our day, is it. Rounding errors are better than outright failure. */ num = parse_number (s + 2, 16, 2, 4, radixchar, 'p', &endbuf); } else { dup[p - s] = '\0'; num = STRTOD (dup, &endbuf); saved_errno = errno; free (dup); errno = saved_errno; } end = p; } } } else { /* If "1e 1" was misparsed as 10.0 instead of 1.0, re-do the underlying STRTOD on a copy of the original string truncated to avoid the bug. */ const char *e = s + 1; while (e < end && c_tolower (*e) != 'e') e++; if (e < end && ! c_isdigit (e[1 + (e[1] == '-' || e[1] == '+')])) { char *dup = strdup (s); errno = saved_errno; if (!dup) { /* Not really our day, is it. Rounding errors are better than outright failure. */ num = parse_number (s, 10, 10, 1, radixchar, 'e', &endbuf); } else { dup[e - s] = '\0'; num = STRTOD (dup, &endbuf); saved_errno = errno; free (dup); errno = saved_errno; } end = e; } } s = end; } /* Check for infinities and NaNs. */ else if (c_tolower (*s) == 'i' && c_tolower (s[1]) == 'n' && c_tolower (s[2]) == 'f') { s += 3; if (c_tolower (*s) == 'i' && c_tolower (s[1]) == 'n' && c_tolower (s[2]) == 'i' && c_tolower (s[3]) == 't' && c_tolower (s[4]) == 'y') s += 5; num = HUGE_VAL; errno = saved_errno; } else if (c_tolower (*s) == 'n' && c_tolower (s[1]) == 'a' && c_tolower (s[2]) == 'n') { s += 3; if (*s == '(') { const char *p = s + 1; while (c_isalnum (*p)) p++; if (*p == ')') s = p + 1; } /* If the underlying implementation misparsed the NaN, assume its result is incorrect, and return a NaN. Normally it's better to use the underlying implementation's result, since a nice implementation populates the bits of the NaN according to interpreting n-char-sequence as a hexadecimal number. */ if (s != end || num == num) num = NAN; errno = saved_errno; } else { /* No conversion could be performed. */ errno = EINVAL; s = nptr; } if (endptr != NULL) *endptr = (char *) s; /* Special case -0.0, since at least ICC miscompiles negation. We can't use copysign(), as that drags in -lm on some platforms. */ if (!num && negative) return minus_zero (); return negative ? -num : num; }