/*------------------------------------------------------------------------- * * erand48.c * * This file supplies pg_erand48() and related functions, which except * for the names are just like the POSIX-standard erand48() family. * (We don't supply the full set though, only the ones we have found use * for in Postgres. In particular, we do *not* implement lcong48(), so * that there is no need for the multiplier and addend to be variable.) * * We used to test for an operating system version rather than * unconditionally using our own, but (1) some versions of Cygwin have a * buggy erand48() that always returns zero and (2) as of 2011, glibc's * erand48() is strangely coded to be almost-but-not-quite thread-safe, * which doesn't matter for the backend but is important for pgbench. * * Portions Copyright (c) 1996-2019, PostgreSQL Global Development Group * * Portions Copyright (c) 1993 Martin Birgmeier * All rights reserved. * * You may redistribute unmodified or modified versions of this source * code provided that the above copyright notice and this and the * following conditions are retained. * * This software is provided ``as is'', and comes with no warranties * of any kind. I shall in no event be liable for anything that happens * to anyone/anything when using this software. * * IDENTIFICATION * src/port/erand48.c * *------------------------------------------------------------------------- */ #include "c.h" #include /* These values are specified by POSIX */ #define RAND48_MULT UINT64CONST(0x0005deece66d) #define RAND48_ADD UINT64CONST(0x000b) /* POSIX specifies 0x330e's use in srand48, but the other bits are arbitrary */ #define RAND48_SEED_0 (0x330e) #define RAND48_SEED_1 (0xabcd) #define RAND48_SEED_2 (0x1234) static unsigned short _rand48_seed[3] = { RAND48_SEED_0, RAND48_SEED_1, RAND48_SEED_2 }; /* * Advance the 48-bit value stored in xseed[] to the next "random" number. * * Also returns the value of that number --- without masking it to 48 bits. * If caller uses the result, it must mask off the bits it wants. */ static uint64 _dorand48(unsigned short xseed[3]) { /* * We do the arithmetic in uint64; any type wider than 48 bits would work. */ uint64 in; uint64 out; in = (uint64) xseed[2] << 32 | (uint64) xseed[1] << 16 | (uint64) xseed[0]; out = in * RAND48_MULT + RAND48_ADD; xseed[0] = out & 0xFFFF; xseed[1] = (out >> 16) & 0xFFFF; xseed[2] = (out >> 32) & 0xFFFF; return out; } /* * Generate a random floating-point value using caller-supplied state. * Values are uniformly distributed over the interval [0.0, 1.0). */ double pg_erand48(unsigned short xseed[3]) { uint64 x = _dorand48(xseed); return ldexp((double) (x & UINT64CONST(0xFFFFFFFFFFFF)), -48); } /* * Generate a random non-negative integral value using internal state. * Values are uniformly distributed over the interval [0, 2^31). */ long pg_lrand48(void) { uint64 x = _dorand48(_rand48_seed); return (x >> 17) & UINT64CONST(0x7FFFFFFF); } /* * Generate a random signed integral value using caller-supplied state. * Values are uniformly distributed over the interval [-2^31, 2^31). */ long pg_jrand48(unsigned short xseed[3]) { uint64 x = _dorand48(xseed); return (int32) ((x >> 16) & UINT64CONST(0xFFFFFFFF)); } /* * Initialize the internal state using the given seed. * * Per POSIX, this uses only 32 bits from "seed" even if "long" is wider. * Hence, the set of possible seed values is smaller than it could be. * Better practice is to use caller-supplied state and initialize it with * random bits obtained from a high-quality source of random bits. * * Note: POSIX specifies a function seed48() that allows all 48 bits * of the internal state to be set, but we don't currently support that. */ void pg_srand48(long seed) { _rand48_seed[0] = RAND48_SEED_0; _rand48_seed[1] = (unsigned short) seed; _rand48_seed[2] = (unsigned short) (seed >> 16); }