/*------------------------------------------------------------------------- * * numutils.c * utility functions for I/O of built-in numeric types. * * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/utils/adt/numutils.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include #include "common/int.h" #include "port/pg_bitutils.h" #include "utils/builtins.h" /* * A table of all two-digit numbers. This is used to speed up decimal digit * generation by copying pairs of digits into the final output. */ static const char DIGIT_TABLE[200] = "00" "01" "02" "03" "04" "05" "06" "07" "08" "09" "10" "11" "12" "13" "14" "15" "16" "17" "18" "19" "20" "21" "22" "23" "24" "25" "26" "27" "28" "29" "30" "31" "32" "33" "34" "35" "36" "37" "38" "39" "40" "41" "42" "43" "44" "45" "46" "47" "48" "49" "50" "51" "52" "53" "54" "55" "56" "57" "58" "59" "60" "61" "62" "63" "64" "65" "66" "67" "68" "69" "70" "71" "72" "73" "74" "75" "76" "77" "78" "79" "80" "81" "82" "83" "84" "85" "86" "87" "88" "89" "90" "91" "92" "93" "94" "95" "96" "97" "98" "99"; /* * Adapted from http://graphics.stanford.edu/~seander/bithacks.html#IntegerLog10 */ static inline int decimalLength32(const uint32 v) { int t; static const uint32 PowersOfTen[] = { 1, 10, 100, 1000, 10000, 100000, 1000000, 10000000, 100000000, 1000000000 }; /* * Compute base-10 logarithm by dividing the base-2 logarithm by a * good-enough approximation of the base-2 logarithm of 10 */ t = (pg_leftmost_one_pos32(v) + 1) * 1233 / 4096; return t + (v >= PowersOfTen[t]); } static inline int decimalLength64(const uint64 v) { int t; static const uint64 PowersOfTen[] = { UINT64CONST(1), UINT64CONST(10), UINT64CONST(100), UINT64CONST(1000), UINT64CONST(10000), UINT64CONST(100000), UINT64CONST(1000000), UINT64CONST(10000000), UINT64CONST(100000000), UINT64CONST(1000000000), UINT64CONST(10000000000), UINT64CONST(100000000000), UINT64CONST(1000000000000), UINT64CONST(10000000000000), UINT64CONST(100000000000000), UINT64CONST(1000000000000000), UINT64CONST(10000000000000000), UINT64CONST(100000000000000000), UINT64CONST(1000000000000000000), UINT64CONST(10000000000000000000) }; /* * Compute base-10 logarithm by dividing the base-2 logarithm by a * good-enough approximation of the base-2 logarithm of 10 */ t = (pg_leftmost_one_pos64(v) + 1) * 1233 / 4096; return t + (v >= PowersOfTen[t]); } static const int8 hexlookup[128] = { -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, -1, -1, -1, -1, -1, -1, -1, 10, 11, 12, 13, 14, 15, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, 10, 11, 12, 13, 14, 15, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, }; /* * Convert input string to a signed 16 bit integer. Input strings may be * expressed in base-10, hexadecimal, octal, or binary format, all of which * can be prefixed by an optional sign character, either '+' (the default) or * '-' for negative numbers. Hex strings are recognized by the digits being * prefixed by 0x or 0X while octal strings are recognized by the 0o or 0O * prefix. The binary representation is recognized by the 0b or 0B prefix. * * Allows any number of leading or trailing whitespace characters. Digits may * optionally be separated by a single underscore character. These can only * come between digits and not before or after the digits. Underscores have * no effect on the return value and are supported only to assist in improving * the human readability of the input strings. * * pg_strtoint16() will throw ereport() upon bad input format or overflow; * while pg_strtoint16_safe() instead returns such complaints in *escontext, * if it's an ErrorSaveContext. * * NB: Accumulate input as an unsigned number, to deal with two's complement * representation of the most negative number, which can't be represented as a * signed positive number. */ int16 pg_strtoint16(const char *s) { return pg_strtoint16_safe(s, NULL); } int16 pg_strtoint16_safe(const char *s, Node *escontext) { const char *ptr = s; const char *firstdigit; uint16 tmp = 0; bool neg = false; unsigned char digit; int16 result; /* * The majority of cases are likely to be base-10 digits without any * underscore separator characters. We'll first try to parse the string * with the assumption that's the case and only fallback on a slower * implementation which handles hex, octal and binary strings and * underscores if the fastpath version cannot parse the string. */ /* leave it up to the slow path to look for leading spaces */ if (*ptr == '-') { ptr++; neg = true; } /* a leading '+' is uncommon so leave that for the slow path */ /* process the first digit */ digit = (*ptr - '0'); /* * Exploit unsigned arithmetic to save having to check both the upper and * lower bounds of the digit. */ if (likely(digit < 10)) { ptr++; tmp = digit; } else { /* we need at least one digit */ goto slow; } /* process remaining digits */ for (;;) { digit = (*ptr - '0'); if (digit >= 10) break; ptr++; if (unlikely(tmp > -(PG_INT16_MIN / 10))) goto out_of_range; tmp = tmp * 10 + digit; } /* when the string does not end in a digit, let the slow path handle it */ if (unlikely(*ptr != '\0')) goto slow; if (neg) { if (unlikely(pg_neg_u16_overflow(tmp, &result))) goto out_of_range; return result; } if (unlikely(tmp > PG_INT16_MAX)) goto out_of_range; return (int16) tmp; slow: tmp = 0; ptr = s; /* no need to reset neg */ /* skip leading spaces */ while (isspace((unsigned char) *ptr)) ptr++; /* handle sign */ if (*ptr == '-') { ptr++; neg = true; } else if (*ptr == '+') ptr++; /* process digits */ if (ptr[0] == '0' && (ptr[1] == 'x' || ptr[1] == 'X')) { firstdigit = ptr += 2; for (;;) { if (isxdigit((unsigned char) *ptr)) { if (unlikely(tmp > -(PG_INT16_MIN / 16))) goto out_of_range; tmp = tmp * 16 + hexlookup[(unsigned char) *ptr++]; } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || !isxdigit((unsigned char) *ptr)) goto invalid_syntax; } else break; } } else if (ptr[0] == '0' && (ptr[1] == 'o' || ptr[1] == 'O')) { firstdigit = ptr += 2; for (;;) { if (*ptr >= '0' && *ptr <= '7') { if (unlikely(tmp > -(PG_INT16_MIN / 8))) goto out_of_range; tmp = tmp * 8 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || *ptr < '0' || *ptr > '7') goto invalid_syntax; } else break; } } else if (ptr[0] == '0' && (ptr[1] == 'b' || ptr[1] == 'B')) { firstdigit = ptr += 2; for (;;) { if (*ptr >= '0' && *ptr <= '1') { if (unlikely(tmp > -(PG_INT16_MIN / 2))) goto out_of_range; tmp = tmp * 2 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || *ptr < '0' || *ptr > '1') goto invalid_syntax; } else break; } } else { firstdigit = ptr; for (;;) { if (*ptr >= '0' && *ptr <= '9') { if (unlikely(tmp > -(PG_INT16_MIN / 10))) goto out_of_range; tmp = tmp * 10 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore may not be first */ if (unlikely(ptr == firstdigit)) goto invalid_syntax; /* and it must be followed by more digits */ ptr++; if (*ptr == '\0' || !isdigit((unsigned char) *ptr)) goto invalid_syntax; } else break; } } /* require at least one digit */ if (unlikely(ptr == firstdigit)) goto invalid_syntax; /* allow trailing whitespace, but not other trailing chars */ while (isspace((unsigned char) *ptr)) ptr++; if (unlikely(*ptr != '\0')) goto invalid_syntax; if (neg) { if (unlikely(pg_neg_u16_overflow(tmp, &result))) goto out_of_range; return result; } if (tmp > PG_INT16_MAX) goto out_of_range; return (int16) tmp; out_of_range: ereturn(escontext, 0, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("value \"%s\" is out of range for type %s", s, "smallint"))); invalid_syntax: ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", "smallint", s))); } /* * Convert input string to a signed 32 bit integer. Input strings may be * expressed in base-10, hexadecimal, octal, or binary format, all of which * can be prefixed by an optional sign character, either '+' (the default) or * '-' for negative numbers. Hex strings are recognized by the digits being * prefixed by 0x or 0X while octal strings are recognized by the 0o or 0O * prefix. The binary representation is recognized by the 0b or 0B prefix. * * Allows any number of leading or trailing whitespace characters. Digits may * optionally be separated by a single underscore character. These can only * come between digits and not before or after the digits. Underscores have * no effect on the return value and are supported only to assist in improving * the human readability of the input strings. * * pg_strtoint32() will throw ereport() upon bad input format or overflow; * while pg_strtoint32_safe() instead returns such complaints in *escontext, * if it's an ErrorSaveContext. * * NB: Accumulate input as an unsigned number, to deal with two's complement * representation of the most negative number, which can't be represented as a * signed positive number. */ int32 pg_strtoint32(const char *s) { return pg_strtoint32_safe(s, NULL); } int32 pg_strtoint32_safe(const char *s, Node *escontext) { const char *ptr = s; const char *firstdigit; uint32 tmp = 0; bool neg = false; unsigned char digit; int32 result; /* * The majority of cases are likely to be base-10 digits without any * underscore separator characters. We'll first try to parse the string * with the assumption that's the case and only fallback on a slower * implementation which handles hex, octal and binary strings and * underscores if the fastpath version cannot parse the string. */ /* leave it up to the slow path to look for leading spaces */ if (*ptr == '-') { ptr++; neg = true; } /* a leading '+' is uncommon so leave that for the slow path */ /* process the first digit */ digit = (*ptr - '0'); /* * Exploit unsigned arithmetic to save having to check both the upper and * lower bounds of the digit. */ if (likely(digit < 10)) { ptr++; tmp = digit; } else { /* we need at least one digit */ goto slow; } /* process remaining digits */ for (;;) { digit = (*ptr - '0'); if (digit >= 10) break; ptr++; if (unlikely(tmp > -(PG_INT32_MIN / 10))) goto out_of_range; tmp = tmp * 10 + digit; } /* when the string does not end in a digit, let the slow path handle it */ if (unlikely(*ptr != '\0')) goto slow; if (neg) { if (unlikely(pg_neg_u32_overflow(tmp, &result))) goto out_of_range; return result; } if (unlikely(tmp > PG_INT32_MAX)) goto out_of_range; return (int32) tmp; slow: tmp = 0; ptr = s; /* no need to reset neg */ /* skip leading spaces */ while (isspace((unsigned char) *ptr)) ptr++; /* handle sign */ if (*ptr == '-') { ptr++; neg = true; } else if (*ptr == '+') ptr++; /* process digits */ if (ptr[0] == '0' && (ptr[1] == 'x' || ptr[1] == 'X')) { firstdigit = ptr += 2; for (;;) { if (isxdigit((unsigned char) *ptr)) { if (unlikely(tmp > -(PG_INT32_MIN / 16))) goto out_of_range; tmp = tmp * 16 + hexlookup[(unsigned char) *ptr++]; } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || !isxdigit((unsigned char) *ptr)) goto invalid_syntax; } else break; } } else if (ptr[0] == '0' && (ptr[1] == 'o' || ptr[1] == 'O')) { firstdigit = ptr += 2; for (;;) { if (*ptr >= '0' && *ptr <= '7') { if (unlikely(tmp > -(PG_INT32_MIN / 8))) goto out_of_range; tmp = tmp * 8 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || *ptr < '0' || *ptr > '7') goto invalid_syntax; } else break; } } else if (ptr[0] == '0' && (ptr[1] == 'b' || ptr[1] == 'B')) { firstdigit = ptr += 2; for (;;) { if (*ptr >= '0' && *ptr <= '1') { if (unlikely(tmp > -(PG_INT32_MIN / 2))) goto out_of_range; tmp = tmp * 2 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || *ptr < '0' || *ptr > '1') goto invalid_syntax; } else break; } } else { firstdigit = ptr; for (;;) { if (*ptr >= '0' && *ptr <= '9') { if (unlikely(tmp > -(PG_INT32_MIN / 10))) goto out_of_range; tmp = tmp * 10 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore may not be first */ if (unlikely(ptr == firstdigit)) goto invalid_syntax; /* and it must be followed by more digits */ ptr++; if (*ptr == '\0' || !isdigit((unsigned char) *ptr)) goto invalid_syntax; } else break; } } /* require at least one digit */ if (unlikely(ptr == firstdigit)) goto invalid_syntax; /* allow trailing whitespace, but not other trailing chars */ while (isspace((unsigned char) *ptr)) ptr++; if (unlikely(*ptr != '\0')) goto invalid_syntax; if (neg) { if (unlikely(pg_neg_u32_overflow(tmp, &result))) goto out_of_range; return result; } if (tmp > PG_INT32_MAX) goto out_of_range; return (int32) tmp; out_of_range: ereturn(escontext, 0, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("value \"%s\" is out of range for type %s", s, "integer"))); invalid_syntax: ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", "integer", s))); } /* * Convert input string to a signed 64 bit integer. Input strings may be * expressed in base-10, hexadecimal, octal, or binary format, all of which * can be prefixed by an optional sign character, either '+' (the default) or * '-' for negative numbers. Hex strings are recognized by the digits being * prefixed by 0x or 0X while octal strings are recognized by the 0o or 0O * prefix. The binary representation is recognized by the 0b or 0B prefix. * * Allows any number of leading or trailing whitespace characters. Digits may * optionally be separated by a single underscore character. These can only * come between digits and not before or after the digits. Underscores have * no effect on the return value and are supported only to assist in improving * the human readability of the input strings. * * pg_strtoint64() will throw ereport() upon bad input format or overflow; * while pg_strtoint64_safe() instead returns such complaints in *escontext, * if it's an ErrorSaveContext. * * NB: Accumulate input as an unsigned number, to deal with two's complement * representation of the most negative number, which can't be represented as a * signed positive number. */ int64 pg_strtoint64(const char *s) { return pg_strtoint64_safe(s, NULL); } int64 pg_strtoint64_safe(const char *s, Node *escontext) { const char *ptr = s; const char *firstdigit; uint64 tmp = 0; bool neg = false; unsigned char digit; int64 result; /* * The majority of cases are likely to be base-10 digits without any * underscore separator characters. We'll first try to parse the string * with the assumption that's the case and only fallback on a slower * implementation which handles hex, octal and binary strings and * underscores if the fastpath version cannot parse the string. */ /* leave it up to the slow path to look for leading spaces */ if (*ptr == '-') { ptr++; neg = true; } /* a leading '+' is uncommon so leave that for the slow path */ /* process the first digit */ digit = (*ptr - '0'); /* * Exploit unsigned arithmetic to save having to check both the upper and * lower bounds of the digit. */ if (likely(digit < 10)) { ptr++; tmp = digit; } else { /* we need at least one digit */ goto slow; } /* process remaining digits */ for (;;) { digit = (*ptr - '0'); if (digit >= 10) break; ptr++; if (unlikely(tmp > -(PG_INT64_MIN / 10))) goto out_of_range; tmp = tmp * 10 + digit; } /* when the string does not end in a digit, let the slow path handle it */ if (unlikely(*ptr != '\0')) goto slow; if (neg) { if (unlikely(pg_neg_u64_overflow(tmp, &result))) goto out_of_range; return result; } if (unlikely(tmp > PG_INT64_MAX)) goto out_of_range; return (int64) tmp; slow: tmp = 0; ptr = s; /* no need to reset neg */ /* skip leading spaces */ while (isspace((unsigned char) *ptr)) ptr++; /* handle sign */ if (*ptr == '-') { ptr++; neg = true; } else if (*ptr == '+') ptr++; /* process digits */ if (ptr[0] == '0' && (ptr[1] == 'x' || ptr[1] == 'X')) { firstdigit = ptr += 2; for (;;) { if (isxdigit((unsigned char) *ptr)) { if (unlikely(tmp > -(PG_INT64_MIN / 16))) goto out_of_range; tmp = tmp * 16 + hexlookup[(unsigned char) *ptr++]; } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || !isxdigit((unsigned char) *ptr)) goto invalid_syntax; } else break; } } else if (ptr[0] == '0' && (ptr[1] == 'o' || ptr[1] == 'O')) { firstdigit = ptr += 2; for (;;) { if (*ptr >= '0' && *ptr <= '7') { if (unlikely(tmp > -(PG_INT64_MIN / 8))) goto out_of_range; tmp = tmp * 8 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || *ptr < '0' || *ptr > '7') goto invalid_syntax; } else break; } } else if (ptr[0] == '0' && (ptr[1] == 'b' || ptr[1] == 'B')) { firstdigit = ptr += 2; for (;;) { if (*ptr >= '0' && *ptr <= '1') { if (unlikely(tmp > -(PG_INT64_MIN / 2))) goto out_of_range; tmp = tmp * 2 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore must be followed by more digits */ ptr++; if (*ptr == '\0' || *ptr < '0' || *ptr > '1') goto invalid_syntax; } else break; } } else { firstdigit = ptr; for (;;) { if (*ptr >= '0' && *ptr <= '9') { if (unlikely(tmp > -(PG_INT64_MIN / 10))) goto out_of_range; tmp = tmp * 10 + (*ptr++ - '0'); } else if (*ptr == '_') { /* underscore may not be first */ if (unlikely(ptr == firstdigit)) goto invalid_syntax; /* and it must be followed by more digits */ ptr++; if (*ptr == '\0' || !isdigit((unsigned char) *ptr)) goto invalid_syntax; } else break; } } /* require at least one digit */ if (unlikely(ptr == firstdigit)) goto invalid_syntax; /* allow trailing whitespace, but not other trailing chars */ while (isspace((unsigned char) *ptr)) ptr++; if (unlikely(*ptr != '\0')) goto invalid_syntax; if (neg) { if (unlikely(pg_neg_u64_overflow(tmp, &result))) goto out_of_range; return result; } if (tmp > PG_INT64_MAX) goto out_of_range; return (int64) tmp; out_of_range: ereturn(escontext, 0, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("value \"%s\" is out of range for type %s", s, "bigint"))); invalid_syntax: ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", "bigint", s))); } /* * Convert input string to an unsigned 32 bit integer. * * Allows any number of leading or trailing whitespace characters. * * If endloc isn't NULL, store a pointer to the rest of the string there, * so that caller can parse the rest. Otherwise, it's an error if anything * but whitespace follows. * * typname is what is reported in error messages. * * If escontext points to an ErrorSaveContext node, that is filled instead * of throwing an error; the caller must check SOFT_ERROR_OCCURRED() * to detect errors. */ uint32 uint32in_subr(const char *s, char **endloc, const char *typname, Node *escontext) { uint32 result; unsigned long cvt; char *endptr; errno = 0; cvt = strtoul(s, &endptr, 0); /* * strtoul() normally only sets ERANGE. On some systems it may also set * EINVAL, which simply means it couldn't parse the input string. Be sure * to report that the same way as the standard error indication (that * endptr == s). */ if ((errno && errno != ERANGE) || endptr == s) ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", typname, s))); if (errno == ERANGE) ereturn(escontext, 0, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("value \"%s\" is out of range for type %s", s, typname))); if (endloc) { /* caller wants to deal with rest of string */ *endloc = endptr; } else { /* allow only whitespace after number */ while (*endptr && isspace((unsigned char) *endptr)) endptr++; if (*endptr) ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", typname, s))); } result = (uint32) cvt; /* * Cope with possibility that unsigned long is wider than uint32, in which * case strtoul will not raise an error for some values that are out of * the range of uint32. * * For backwards compatibility, we want to accept inputs that are given * with a minus sign, so allow the input value if it matches after either * signed or unsigned extension to long. * * To ensure consistent results on 32-bit and 64-bit platforms, make sure * the error message is the same as if strtoul() had returned ERANGE. */ #if PG_UINT32_MAX != ULONG_MAX if (cvt != (unsigned long) result && cvt != (unsigned long) ((int) result)) ereturn(escontext, 0, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("value \"%s\" is out of range for type %s", s, typname))); #endif return result; } /* * Convert input string to an unsigned 64 bit integer. * * Allows any number of leading or trailing whitespace characters. * * If endloc isn't NULL, store a pointer to the rest of the string there, * so that caller can parse the rest. Otherwise, it's an error if anything * but whitespace follows. * * typname is what is reported in error messages. * * If escontext points to an ErrorSaveContext node, that is filled instead * of throwing an error; the caller must check SOFT_ERROR_OCCURRED() * to detect errors. */ uint64 uint64in_subr(const char *s, char **endloc, const char *typname, Node *escontext) { uint64 result; char *endptr; errno = 0; result = strtou64(s, &endptr, 0); /* * strtoul[l] normally only sets ERANGE. On some systems it may also set * EINVAL, which simply means it couldn't parse the input string. Be sure * to report that the same way as the standard error indication (that * endptr == s). */ if ((errno && errno != ERANGE) || endptr == s) ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", typname, s))); if (errno == ERANGE) ereturn(escontext, 0, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("value \"%s\" is out of range for type %s", s, typname))); if (endloc) { /* caller wants to deal with rest of string */ *endloc = endptr; } else { /* allow only whitespace after number */ while (*endptr && isspace((unsigned char) *endptr)) endptr++; if (*endptr) ereturn(escontext, 0, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s: \"%s\"", typname, s))); } return result; } /* * pg_itoa: converts a signed 16-bit integer to its string representation * and returns strlen(a). * * Caller must ensure that 'a' points to enough memory to hold the result * (at least 7 bytes, counting a leading sign and trailing NUL). * * It doesn't seem worth implementing this separately. */ int pg_itoa(int16 i, char *a) { return pg_ltoa((int32) i, a); } /* * pg_ultoa_n: converts an unsigned 32-bit integer to its string representation, * not NUL-terminated, and returns the length of that string representation * * Caller must ensure that 'a' points to enough memory to hold the result (at * least 10 bytes) */ int pg_ultoa_n(uint32 value, char *a) { int olength, i = 0; /* Degenerate case */ if (value == 0) { *a = '0'; return 1; } olength = decimalLength32(value); /* Compute the result string. */ while (value >= 10000) { const uint32 c = value - 10000 * (value / 10000); const uint32 c0 = (c % 100) << 1; const uint32 c1 = (c / 100) << 1; char *pos = a + olength - i; value /= 10000; memcpy(pos - 2, DIGIT_TABLE + c0, 2); memcpy(pos - 4, DIGIT_TABLE + c1, 2); i += 4; } if (value >= 100) { const uint32 c = (value % 100) << 1; char *pos = a + olength - i; value /= 100; memcpy(pos - 2, DIGIT_TABLE + c, 2); i += 2; } if (value >= 10) { const uint32 c = value << 1; char *pos = a + olength - i; memcpy(pos - 2, DIGIT_TABLE + c, 2); } else { *a = (char) ('0' + value); } return olength; } /* * pg_ltoa: converts a signed 32-bit integer to its string representation and * returns strlen(a). * * It is the caller's responsibility to ensure that a is at least 12 bytes long, * which is enough room to hold a minus sign, a maximally long int32, and the * above terminating NUL. */ int pg_ltoa(int32 value, char *a) { uint32 uvalue = (uint32) value; int len = 0; if (value < 0) { uvalue = (uint32) 0 - uvalue; a[len++] = '-'; } len += pg_ultoa_n(uvalue, a + len); a[len] = '\0'; return len; } /* * Get the decimal representation, not NUL-terminated, and return the length of * same. Caller must ensure that a points to at least MAXINT8LEN bytes. */ int pg_ulltoa_n(uint64 value, char *a) { int olength, i = 0; uint32 value2; /* Degenerate case */ if (value == 0) { *a = '0'; return 1; } olength = decimalLength64(value); /* Compute the result string. */ while (value >= 100000000) { const uint64 q = value / 100000000; uint32 value3 = (uint32) (value - 100000000 * q); const uint32 c = value3 % 10000; const uint32 d = value3 / 10000; const uint32 c0 = (c % 100) << 1; const uint32 c1 = (c / 100) << 1; const uint32 d0 = (d % 100) << 1; const uint32 d1 = (d / 100) << 1; char *pos = a + olength - i; value = q; memcpy(pos - 2, DIGIT_TABLE + c0, 2); memcpy(pos - 4, DIGIT_TABLE + c1, 2); memcpy(pos - 6, DIGIT_TABLE + d0, 2); memcpy(pos - 8, DIGIT_TABLE + d1, 2); i += 8; } /* Switch to 32-bit for speed */ value2 = (uint32) value; if (value2 >= 10000) { const uint32 c = value2 - 10000 * (value2 / 10000); const uint32 c0 = (c % 100) << 1; const uint32 c1 = (c / 100) << 1; char *pos = a + olength - i; value2 /= 10000; memcpy(pos - 2, DIGIT_TABLE + c0, 2); memcpy(pos - 4, DIGIT_TABLE + c1, 2); i += 4; } if (value2 >= 100) { const uint32 c = (value2 % 100) << 1; char *pos = a + olength - i; value2 /= 100; memcpy(pos - 2, DIGIT_TABLE + c, 2); i += 2; } if (value2 >= 10) { const uint32 c = value2 << 1; char *pos = a + olength - i; memcpy(pos - 2, DIGIT_TABLE + c, 2); } else *a = (char) ('0' + value2); return olength; } /* * pg_lltoa: converts a signed 64-bit integer to its string representation and * returns strlen(a). * * Caller must ensure that 'a' points to enough memory to hold the result * (at least MAXINT8LEN + 1 bytes, counting a leading sign and trailing NUL). */ int pg_lltoa(int64 value, char *a) { uint64 uvalue = value; int len = 0; if (value < 0) { uvalue = (uint64) 0 - uvalue; a[len++] = '-'; } len += pg_ulltoa_n(uvalue, a + len); a[len] = '\0'; return len; } /* * pg_ultostr_zeropad * Converts 'value' into a decimal string representation stored at 'str'. * 'minwidth' specifies the minimum width of the result; any extra space * is filled up by prefixing the number with zeros. * * Returns the ending address of the string result (the last character written * plus 1). Note that no NUL terminator is written. * * The intended use-case for this function is to build strings that contain * multiple individual numbers, for example: * * str = pg_ultostr_zeropad(str, hours, 2); * *str++ = ':'; * str = pg_ultostr_zeropad(str, mins, 2); * *str++ = ':'; * str = pg_ultostr_zeropad(str, secs, 2); * *str = '\0'; * * Note: Caller must ensure that 'str' points to enough memory to hold the * result. */ char * pg_ultostr_zeropad(char *str, uint32 value, int32 minwidth) { int len; Assert(minwidth > 0); if (value < 100 && minwidth == 2) /* Short cut for common case */ { memcpy(str, DIGIT_TABLE + value * 2, 2); return str + 2; } len = pg_ultoa_n(value, str); if (len >= minwidth) return str + len; memmove(str + minwidth - len, str, len); memset(str, '0', minwidth - len); return str + minwidth; } /* * pg_ultostr * Converts 'value' into a decimal string representation stored at 'str'. * * Returns the ending address of the string result (the last character written * plus 1). Note that no NUL terminator is written. * * The intended use-case for this function is to build strings that contain * multiple individual numbers, for example: * * str = pg_ultostr(str, a); * *str++ = ' '; * str = pg_ultostr(str, b); * *str = '\0'; * * Note: Caller must ensure that 'str' points to enough memory to hold the * result. */ char * pg_ultostr(char *str, uint32 value) { int len = pg_ultoa_n(value, str); return str + len; }