/*------------------------------------------------------------------------- * * int.h * Routines to perform integer math, while checking for overflows. * * The routines in this file are intended to be well defined C, without * relying on compiler flags like -fwrapv. * * To reduce the overhead of these routines try to use compiler intrinsics * where available. That's not that important for the 16, 32 bit cases, but * the 64 bit cases can be considerably faster with intrinsics. In case no * intrinsics are available 128 bit math is used where available. * * Copyright (c) 2017-2021, PostgreSQL Global Development Group * * src/include/common/int.h * *------------------------------------------------------------------------- */ #ifndef COMMON_INT_H #define COMMON_INT_H /*--------- * The following guidelines apply to all the routines: * - If a + b overflows, return true, otherwise store the result of a + b * into *result. The content of *result is implementation defined in case of * overflow. * - If a - b overflows, return true, otherwise store the result of a - b * into *result. The content of *result is implementation defined in case of * overflow. * - If a * b overflows, return true, otherwise store the result of a * b * into *result. The content of *result is implementation defined in case of * overflow. *--------- */ /*------------------------------------------------------------------------ * Overflow routines for signed integers *------------------------------------------------------------------------ */ /* * INT16 */ static inline bool pg_add_s16_overflow(int16 a, int16 b, int16 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_add_overflow(a, b, result); #else int32 res = (int32) a + (int32) b; if (res > PG_INT16_MAX || res < PG_INT16_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int16) res; return false; #endif } static inline bool pg_sub_s16_overflow(int16 a, int16 b, int16 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_sub_overflow(a, b, result); #else int32 res = (int32) a - (int32) b; if (res > PG_INT16_MAX || res < PG_INT16_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int16) res; return false; #endif } static inline bool pg_mul_s16_overflow(int16 a, int16 b, int16 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_mul_overflow(a, b, result); #else int32 res = (int32) a * (int32) b; if (res > PG_INT16_MAX || res < PG_INT16_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int16) res; return false; #endif } /* * INT32 */ static inline bool pg_add_s32_overflow(int32 a, int32 b, int32 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_add_overflow(a, b, result); #else int64 res = (int64) a + (int64) b; if (res > PG_INT32_MAX || res < PG_INT32_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int32) res; return false; #endif } static inline bool pg_sub_s32_overflow(int32 a, int32 b, int32 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_sub_overflow(a, b, result); #else int64 res = (int64) a - (int64) b; if (res > PG_INT32_MAX || res < PG_INT32_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int32) res; return false; #endif } static inline bool pg_mul_s32_overflow(int32 a, int32 b, int32 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_mul_overflow(a, b, result); #else int64 res = (int64) a * (int64) b; if (res > PG_INT32_MAX || res < PG_INT32_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int32) res; return false; #endif } /* * INT64 */ static inline bool pg_add_s64_overflow(int64 a, int64 b, int64 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_add_overflow(a, b, result); #elif defined(HAVE_INT128) int128 res = (int128) a + (int128) b; if (res > PG_INT64_MAX || res < PG_INT64_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int64) res; return false; #else if ((a > 0 && b > 0 && a > PG_INT64_MAX - b) || (a < 0 && b < 0 && a < PG_INT64_MIN - b)) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = a + b; return false; #endif } static inline bool pg_sub_s64_overflow(int64 a, int64 b, int64 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_sub_overflow(a, b, result); #elif defined(HAVE_INT128) int128 res = (int128) a - (int128) b; if (res > PG_INT64_MAX || res < PG_INT64_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int64) res; return false; #else if ((a < 0 && b > 0 && a < PG_INT64_MIN + b) || (a > 0 && b < 0 && a > PG_INT64_MAX + b)) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = a - b; return false; #endif } static inline bool pg_mul_s64_overflow(int64 a, int64 b, int64 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_mul_overflow(a, b, result); #elif defined(HAVE_INT128) int128 res = (int128) a * (int128) b; if (res > PG_INT64_MAX || res < PG_INT64_MIN) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (int64) res; return false; #else /* * Overflow can only happen if at least one value is outside the range * sqrt(min)..sqrt(max) so check that first as the division can be quite a * bit more expensive than the multiplication. * * Multiplying by 0 or 1 can't overflow of course and checking for 0 * separately avoids any risk of dividing by 0. Be careful about dividing * INT_MIN by -1 also, note reversing the a and b to ensure we're always * dividing it by a positive value. * */ if ((a > PG_INT32_MAX || a < PG_INT32_MIN || b > PG_INT32_MAX || b < PG_INT32_MIN) && a != 0 && a != 1 && b != 0 && b != 1 && ((a > 0 && b > 0 && a > PG_INT64_MAX / b) || (a > 0 && b < 0 && b < PG_INT64_MIN / a) || (a < 0 && b > 0 && a < PG_INT64_MIN / b) || (a < 0 && b < 0 && a < PG_INT64_MAX / b))) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = a * b; return false; #endif } /*------------------------------------------------------------------------ * Overflow routines for unsigned integers *------------------------------------------------------------------------ */ /* * UINT16 */ static inline bool pg_add_u16_overflow(uint16 a, uint16 b, uint16 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_add_overflow(a, b, result); #else uint16 res = a + b; if (res < a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = res; return false; #endif } static inline bool pg_sub_u16_overflow(uint16 a, uint16 b, uint16 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_sub_overflow(a, b, result); #else if (b > a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = a - b; return false; #endif } static inline bool pg_mul_u16_overflow(uint16 a, uint16 b, uint16 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_mul_overflow(a, b, result); #else uint32 res = (uint32) a * (uint32) b; if (res > PG_UINT16_MAX) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (uint16) res; return false; #endif } /* * INT32 */ static inline bool pg_add_u32_overflow(uint32 a, uint32 b, uint32 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_add_overflow(a, b, result); #else uint32 res = a + b; if (res < a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = res; return false; #endif } static inline bool pg_sub_u32_overflow(uint32 a, uint32 b, uint32 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_sub_overflow(a, b, result); #else if (b > a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = a - b; return false; #endif } static inline bool pg_mul_u32_overflow(uint32 a, uint32 b, uint32 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_mul_overflow(a, b, result); #else uint64 res = (uint64) a * (uint64) b; if (res > PG_UINT32_MAX) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (uint32) res; return false; #endif } /* * UINT64 */ static inline bool pg_add_u64_overflow(uint64 a, uint64 b, uint64 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_add_overflow(a, b, result); #else uint64 res = a + b; if (res < a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = res; return false; #endif } static inline bool pg_sub_u64_overflow(uint64 a, uint64 b, uint64 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_sub_overflow(a, b, result); #else if (b > a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = a - b; return false; #endif } static inline bool pg_mul_u64_overflow(uint64 a, uint64 b, uint64 *result) { #if defined(HAVE__BUILTIN_OP_OVERFLOW) return __builtin_mul_overflow(a, b, result); #elif defined(HAVE_INT128) uint128 res = (uint128) a * (uint128) b; if (res > PG_UINT64_MAX) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = (uint64) res; return false; #else uint64 res = a * b; if (a != 0 && b != res / a) { *result = 0x5EED; /* to avoid spurious warnings */ return true; } *result = res; return false; #endif } #endif /* COMMON_INT_H */