/* * A tiny random number generator used for Math.random() and other internals. * * Default algorithm is xoroshiro128+: http://xoroshiro.di.unimi.it/xoroshiro128plus.c * with SplitMix64 seed preparation: http://xorshift.di.unimi.it/splitmix64.c. * * Low memory targets and targets without 64-bit types use a slightly smaller * (but slower) algorithm by Adi Shamir: * http://www.woodmann.com/forum/archive/index.php/t-3100.html. * */ #include "third_party/duktape/duk_internal.h" #if !defined(DUK_USE_GET_RANDOM_DOUBLE) #if defined(DUK_USE_PREFER_SIZE) || !defined(DUK_USE_64BIT_OPS) #define DUK__RANDOM_SHAMIR3OP #else #define DUK__RANDOM_XOROSHIRO128PLUS #endif #if defined(DUK__RANDOM_SHAMIR3OP) #define DUK__UPDATE_RND(rnd) do { \ (rnd) += ((rnd) * (rnd)) | 0x05UL; \ (rnd) = ((rnd) & 0xffffffffUL); /* if duk_uint32_t is exactly 32 bits, this is a NOP */ \ } while (0) #define DUK__RND_BIT(rnd) ((rnd) >> 31) /* only use the highest bit */ DUK_INTERNAL void duk_util_tinyrandom_prepare_seed(duk_hthread *thr) { DUK_UNREF(thr); /* Nothing now. */ } DUK_INTERNAL duk_double_t duk_util_tinyrandom_get_double(duk_hthread *thr) { duk_double_t t; duk_small_int_t n; duk_uint32_t rnd; rnd = thr->heap->rnd_state; n = 53; /* enough to cover the whole mantissa */ t = 0.0; do { DUK__UPDATE_RND(rnd); t += DUK__RND_BIT(rnd); t /= 2.0; } while (--n); thr->heap->rnd_state = rnd; DUK_ASSERT(t >= (duk_double_t) 0.0); DUK_ASSERT(t < (duk_double_t) 1.0); return t; } #endif /* DUK__RANDOM_SHAMIR3OP */ #if defined(DUK__RANDOM_XOROSHIRO128PLUS) DUK_LOCAL DUK_ALWAYS_INLINE duk_uint64_t duk__rnd_splitmix64(duk_uint64_t *x) { duk_uint64_t z; z = (*x += DUK_U64_CONSTANT(0x9E3779B97F4A7C15)); z = (z ^ (z >> 30U)) * DUK_U64_CONSTANT(0xBF58476D1CE4E5B9); z = (z ^ (z >> 27U)) * DUK_U64_CONSTANT(0x94D049BB133111EB); return z ^ (z >> 31U); } DUK_LOCAL DUK_ALWAYS_INLINE duk_uint64_t duk__rnd_rotl(const duk_uint64_t x, duk_small_uint_t k) { return (x << k) | (x >> (64U - k)); } DUK_LOCAL DUK_ALWAYS_INLINE duk_uint64_t duk__xoroshiro128plus(duk_uint64_t *s) { duk_uint64_t s0; duk_uint64_t s1; duk_uint64_t res; s0 = s[0]; s1 = s[1]; res = s0 + s1; s1 ^= s0; s[0] = duk__rnd_rotl(s0, 55) ^ s1 ^ (s1 << 14U); s[1] = duk__rnd_rotl(s1, 36); return res; } DUK_INTERNAL void duk_util_tinyrandom_prepare_seed(duk_hthread *thr) { duk_small_uint_t i; duk_uint64_t x; /* Mix both halves of the initial seed with SplitMix64. The intent * is to ensure that very similar raw seeds (which is usually the case * because current seed is Date.now()) result in different xoroshiro128+ * seeds. */ x = thr->heap->rnd_state[0]; /* Only [0] is used as input here. */ for (i = 0; i < 64; i++) { thr->heap->rnd_state[i & 0x01] = duk__rnd_splitmix64(&x); /* Keep last 2 values. */ } } DUK_INTERNAL duk_double_t duk_util_tinyrandom_get_double(duk_hthread *thr) { duk_uint64_t v; duk_double_union du; /* For big and little endian the integer and IEEE double byte order * is the same so a direct assignment works. For mixed endian the * 32-bit parts must be swapped. */ v = (DUK_U64_CONSTANT(0x3ff) << 52U) | (duk__xoroshiro128plus((duk_uint64_t *) thr->heap->rnd_state) >> 12U); du.ull[0] = v; #if defined(DUK_USE_DOUBLE_ME) do { duk_uint32_t tmp; tmp = du.ui[0]; du.ui[0] = du.ui[1]; du.ui[1] = tmp; } while (0); #endif return du.d - 1.0; } #endif /* DUK__RANDOM_XOROSHIRO128PLUS */ #endif /* !DUK_USE_GET_RANDOM_DOUBLE */