vendor/jemalloc-sys-0.3.0/jemalloc/include/jemalloc/internal/prng.h - toolchain/rustc - Git at Google

 #ifndef JEMALLOC_INTERNAL_PRNG_H
 #define JEMALLOC_INTERNAL_PRNG_H

 #include "jemalloc/internal/atomic.h"
 #include "jemalloc/internal/bit_util.h"

 /*
  * Simple linear congruential pseudo-random number generator:
  *
  *   prng(y) = (a*x + c) % m
  *
  * where the following constants ensure maximal period:
  *
  *   a == Odd number (relatively prime to 2^n), and (a-1) is a multiple of 4.
  *   c == Odd number (relatively prime to 2^n).
  *   m == 2^32
  *
  * See Knuth's TAOCP 3rd Ed., Vol. 2, pg. 17 for details on these constraints.
  *
  * This choice of m has the disadvantage that the quality of the bits is
  * proportional to bit position.  For example, the lowest bit has a cycle of 2,
  * the next has a cycle of 4, etc.  For this reason, we prefer to use the upper
  * bits.
  */

 /******************************************************************************/
 /* INTERNAL DEFINITIONS -- IGNORE */
 /******************************************************************************/
 #define PRNG_A_32	UINT32_C(1103515241)
 #define PRNG_C_32	UINT32_C(12347)

 #define PRNG_A_64	UINT64_C(6364136223846793005)
 #define PRNG_C_64	UINT64_C(1442695040888963407)

 JEMALLOC_ALWAYS_INLINE uint32_t
 prng_state_next_u32(uint32_t state) {
 	return (state * PRNG_A_32) + PRNG_C_32;
 }

 JEMALLOC_ALWAYS_INLINE uint64_t
 prng_state_next_u64(uint64_t state) {
 	return (state * PRNG_A_64) + PRNG_C_64;
 }

 JEMALLOC_ALWAYS_INLINE size_t
 prng_state_next_zu(size_t state) {
 #if LG_SIZEOF_PTR == 2
 	return (state * PRNG_A_32) + PRNG_C_32;
 #elif LG_SIZEOF_PTR == 3
 	return (state * PRNG_A_64) + PRNG_C_64;
 #else
 #error Unsupported pointer size
 #endif
 }

 /******************************************************************************/
 /* BEGIN PUBLIC API */
 /******************************************************************************/

 /*
  * The prng_lg_range functions give a uniform int in the half-open range [0,
  * 2**lg_range).  If atomic is true, they do so safely from multiple threads.
  * Multithreaded 64-bit prngs aren't supported.
  */

 JEMALLOC_ALWAYS_INLINE uint32_t
 prng_lg_range_u32(atomic_u32_t *state, unsigned lg_range, bool atomic) {
 	uint32_t ret, state0, state1;

 	assert(lg_range > 0);
 	assert(lg_range <= 32);

 	state0 = atomic_load_u32(state, ATOMIC_RELAXED);

 	if (atomic) {
 		do {
 			state1 = prng_state_next_u32(state0);
 		} while (!atomic_compare_exchange_weak_u32(state, &state0,
 		    state1, ATOMIC_RELAXED, ATOMIC_RELAXED));
 	} else {
 		state1 = prng_state_next_u32(state0);
 		atomic_store_u32(state, state1, ATOMIC_RELAXED);
 	}
 	ret = state1 >> (32 - lg_range);

 	return ret;
 }

 JEMALLOC_ALWAYS_INLINE uint64_t
 prng_lg_range_u64(uint64_t *state, unsigned lg_range) {
 	uint64_t ret, state1;

 	assert(lg_range > 0);
 	assert(lg_range <= 64);

 	state1 = prng_state_next_u64(*state);
 	*state = state1;
 	ret = state1 >> (64 - lg_range);

 	return ret;
 }

 JEMALLOC_ALWAYS_INLINE size_t
 prng_lg_range_zu(atomic_zu_t *state, unsigned lg_range, bool atomic) {
 	size_t ret, state0, state1;

 	assert(lg_range > 0);
 	assert(lg_range <= ZU(1) << (3 + LG_SIZEOF_PTR));

 	state0 = atomic_load_zu(state, ATOMIC_RELAXED);

 	if (atomic) {
 		do {
 			state1 = prng_state_next_zu(state0);
 		} while (atomic_compare_exchange_weak_zu(state, &state0,
 		    state1, ATOMIC_RELAXED, ATOMIC_RELAXED));
 	} else {
 		state1 = prng_state_next_zu(state0);
 		atomic_store_zu(state, state1, ATOMIC_RELAXED);
 	}
 	ret = state1 >> ((ZU(1) << (3 + LG_SIZEOF_PTR)) - lg_range);

 	return ret;
 }

 /*
  * The prng_range functions behave like the prng_lg_range, but return a result
  * in [0, range) instead of [0, 2**lg_range).
  */

 JEMALLOC_ALWAYS_INLINE uint32_t
 prng_range_u32(atomic_u32_t *state, uint32_t range, bool atomic) {
 	uint32_t ret;
 	unsigned lg_range;

 	assert(range > 1);

 	/* Compute the ceiling of lg(range). */
 	lg_range = ffs_u32(pow2_ceil_u32(range)) - 1;

 	/* Generate a result in [0..range) via repeated trial. */
 	do {
 		ret = prng_lg_range_u32(state, lg_range, atomic);
 	} while (ret >= range);

 	return ret;
 }

 JEMALLOC_ALWAYS_INLINE uint64_t
 prng_range_u64(uint64_t *state, uint64_t range) {
 	uint64_t ret;
 	unsigned lg_range;

 	assert(range > 1);

 	/* Compute the ceiling of lg(range). */
 	lg_range = ffs_u64(pow2_ceil_u64(range)) - 1;

 	/* Generate a result in [0..range) via repeated trial. */
 	do {
 		ret = prng_lg_range_u64(state, lg_range);
 	} while (ret >= range);

 	return ret;
 }

 JEMALLOC_ALWAYS_INLINE size_t
 prng_range_zu(atomic_zu_t *state, size_t range, bool atomic) {
 	size_t ret;
 	unsigned lg_range;

 	assert(range > 1);

 	/* Compute the ceiling of lg(range). */
 	lg_range = ffs_u64(pow2_ceil_u64(range)) - 1;

 	/* Generate a result in [0..range) via repeated trial. */
 	do {
 		ret = prng_lg_range_zu(state, lg_range, atomic);
 	} while (ret >= range);

 	return ret;
 }

 #endif /* JEMALLOC_INTERNAL_PRNG_H */
	#ifndef JEMALLOC_INTERNAL_PRNG_H
	#define JEMALLOC_INTERNAL_PRNG_H

	#include "jemalloc/internal/atomic.h"
	#include "jemalloc/internal/bit_util.h"

	/*
	* Simple linear congruential pseudo-random number generator:
	*
	* prng(y) = (a*x + c) % m
	*
	* where the following constants ensure maximal period:
	*
	* a == Odd number (relatively prime to 2^n), and (a-1) is a multiple of 4.
	* c == Odd number (relatively prime to 2^n).
	* m == 2^32
	*
	* See Knuth's TAOCP 3rd Ed., Vol. 2, pg. 17 for details on these constraints.
	*
	* This choice of m has the disadvantage that the quality of the bits is
	* proportional to bit position. For example, the lowest bit has a cycle of 2,
	* the next has a cycle of 4, etc. For this reason, we prefer to use the upper
	* bits.
	*/

	/******************************************************************************/
	/* INTERNAL DEFINITIONS -- IGNORE */
	/******************************************************************************/
	#define PRNG_A_32 UINT32_C(1103515241)
	#define PRNG_C_32 UINT32_C(12347)

	#define PRNG_A_64 UINT64_C(6364136223846793005)
	#define PRNG_C_64 UINT64_C(1442695040888963407)

	JEMALLOC_ALWAYS_INLINE uint32_t
	prng_state_next_u32(uint32_t state) {
	return (state * PRNG_A_32) + PRNG_C_32;
	}

	JEMALLOC_ALWAYS_INLINE uint64_t
	prng_state_next_u64(uint64_t state) {
	return (state * PRNG_A_64) + PRNG_C_64;
	}

	JEMALLOC_ALWAYS_INLINE size_t
	prng_state_next_zu(size_t state) {
	#if LG_SIZEOF_PTR == 2
	return (state * PRNG_A_32) + PRNG_C_32;
	#elif LG_SIZEOF_PTR == 3
	return (state * PRNG_A_64) + PRNG_C_64;
	#else
	#error Unsupported pointer size
	#endif
	}

	/******************************************************************************/
	/* BEGIN PUBLIC API */
	/******************************************************************************/

	/*
	* The prng_lg_range functions give a uniform int in the half-open range [0,
	* 2**lg_range). If atomic is true, they do so safely from multiple threads.
	* Multithreaded 64-bit prngs aren't supported.
	*/

	JEMALLOC_ALWAYS_INLINE uint32_t
	prng_lg_range_u32(atomic_u32_t *state, unsigned lg_range, bool atomic) {
	uint32_t ret, state0, state1;

	assert(lg_range > 0);
	assert(lg_range <= 32);

	state0 = atomic_load_u32(state, ATOMIC_RELAXED);

	if (atomic) {
	do {
	state1 = prng_state_next_u32(state0);
	} while (!atomic_compare_exchange_weak_u32(state, &state0,
	state1, ATOMIC_RELAXED, ATOMIC_RELAXED));
	} else {
	state1 = prng_state_next_u32(state0);
	atomic_store_u32(state, state1, ATOMIC_RELAXED);
	}
	ret = state1 >> (32 - lg_range);

	return ret;
	}

	JEMALLOC_ALWAYS_INLINE uint64_t
	prng_lg_range_u64(uint64_t *state, unsigned lg_range) {
	uint64_t ret, state1;

	assert(lg_range > 0);
	assert(lg_range <= 64);

	state1 = prng_state_next_u64(*state);
	*state = state1;
	ret = state1 >> (64 - lg_range);

	return ret;
	}

	JEMALLOC_ALWAYS_INLINE size_t
	prng_lg_range_zu(atomic_zu_t *state, unsigned lg_range, bool atomic) {
	size_t ret, state0, state1;

	assert(lg_range > 0);
	assert(lg_range <= ZU(1) << (3 + LG_SIZEOF_PTR));

	state0 = atomic_load_zu(state, ATOMIC_RELAXED);

	if (atomic) {
	do {
	state1 = prng_state_next_zu(state0);
	} while (atomic_compare_exchange_weak_zu(state, &state0,
	state1, ATOMIC_RELAXED, ATOMIC_RELAXED));
	} else {
	state1 = prng_state_next_zu(state0);
	atomic_store_zu(state, state1, ATOMIC_RELAXED);
	}
	ret = state1 >> ((ZU(1) << (3 + LG_SIZEOF_PTR)) - lg_range);

	return ret;
	}

	/*
	* The prng_range functions behave like the prng_lg_range, but return a result
	* in [0, range) instead of [0, 2**lg_range).
	*/

	JEMALLOC_ALWAYS_INLINE uint32_t
	prng_range_u32(atomic_u32_t *state, uint32_t range, bool atomic) {
	uint32_t ret;
	unsigned lg_range;

	assert(range > 1);

	/* Compute the ceiling of lg(range). */
	lg_range = ffs_u32(pow2_ceil_u32(range)) - 1;

	/* Generate a result in [0..range) via repeated trial. */
	do {
	ret = prng_lg_range_u32(state, lg_range, atomic);
	} while (ret >= range);

	return ret;
	}

	JEMALLOC_ALWAYS_INLINE uint64_t
	prng_range_u64(uint64_t *state, uint64_t range) {
	uint64_t ret;
	unsigned lg_range;

	assert(range > 1);

	/* Compute the ceiling of lg(range). */
	lg_range = ffs_u64(pow2_ceil_u64(range)) - 1;

	/* Generate a result in [0..range) via repeated trial. */
	do {
	ret = prng_lg_range_u64(state, lg_range);
	} while (ret >= range);

	return ret;
	}

	JEMALLOC_ALWAYS_INLINE size_t
	prng_range_zu(atomic_zu_t *state, size_t range, bool atomic) {
	size_t ret;
	unsigned lg_range;

	assert(range > 1);

	/* Compute the ceiling of lg(range). */
	lg_range = ffs_u64(pow2_ceil_u64(range)) - 1;

	/* Generate a result in [0..range) via repeated trial. */
	do {
	ret = prng_lg_range_zu(state, lg_range, atomic);
	} while (ret >= range);

	return ret;
	}

	#endif /* JEMALLOC_INTERNAL_PRNG_H */