/*===-- atomic.c - Implement support functions for atomic operations.------===
*
* The LLVM Compiler Infrastructure
*
* This file is dual licensed under the MIT and the University of Illinois Open
* Source Licenses. See LICENSE.TXT for details.
*
*===----------------------------------------------------------------------===
*
* atomic.c defines a set of functions for performing atomic accesses on
* arbitrary-sized memory locations. This design uses locks that should
* be fast in the uncontended case, for two reasons:
*
* 1) This code must work with C programs that do not link to anything
* (including pthreads) and so it should not depend on any pthread
* functions.
* 2) Atomic operations, rather than explicit mutexes, are most commonly used
* on code where contended operations are rate.
*
* To avoid needing a per-object lock, this code allocates an array of
* locks and hashes the object pointers to find the one that it should use.
* For operations that must be atomic on two locations, the lower lock is
* always acquired first, to avoid deadlock.
*
*===----------------------------------------------------------------------===
*/
#include <stdint.h>
#include <string.h>
// Clang objects if you redefine a builtin. This little hack allows us to
// define a function with the same name as an intrinsic.
#pragma redefine_extname __atomic_load_n __atomic_load
#pragma redefine_extname __atomic_store_n __atomic_store
#pragma redefine_extname __atomic_exchange_n __atomic_exchange
#pragma redefine_extname __atomic_compare_exchange_n __atomic_compare_exchange
/// Number of locks. This allocates one page on 32-bit platforms, two on
/// 64-bit. This can be specified externally if a different trade between
/// memory usage and contention probability is required for a given platform.
#ifndef SPINLOCK_COUNT
#define SPINLOCK_COUNT (1<<10)
#endif
static const long SPINLOCK_MASK = SPINLOCK_COUNT - 1;
////////////////////////////////////////////////////////////////////////////////
// Platform-specific lock implementation. Falls back to spinlocks if none is
// defined. Each platform should define the Lock type, and corresponding
// lock() and unlock() functions.
////////////////////////////////////////////////////////////////////////////////
#ifdef __FreeBSD__
#include <errno.h>
#include <sys/types.h>
#include <machine/atomic.h>
#include <sys/umtx.h>
typedef struct _usem Lock;
inline static void unlock(Lock *l) {
__atomic_store((_Atomic(uint32_t)*)&l->_count, 1, __ATOMIC_RELEASE);
__atomic_thread_fence(__ATOMIC_SEQ_CST);
if (l->_has_waiters)
_umtx_op(l, UMTX_OP_SEM_WAKE, 1, 0, 0);
}
inline static void lock(Lock *l) {
uint32_t old = 1;
while (!__atomic_compare_exchange_weak((_Atomic(uint32_t)*)&l->_count, &old,
0, __ATOMIC_ACQUIRE, __ATOMIC_RELAXED)) {
_umtx_op(l, UMTX_OP_SEM_WAIT, 0, 0, 0);
old = 1;
}
}
/// locks for atomic operations
static Lock locks[SPINLOCK_COUNT] = { [0 ... SPINLOCK_COUNT-1] = {0,1,0} };
#else
typedef _Atomic(uintptr_t) Lock;
/// Unlock a lock. This is a release operation.
inline static void unlock(Lock *l) {
__atomic_store(l, 0, __ATOMIC_RELEASE);
}
/// Locks a lock. In the current implementation, this is potentially
/// unbounded in the contended case.
inline static void lock(Lock *l) {
uintptr_t old = 0;
while (!__atomic_compare_exchange_weak(l, &old, 1, __ATOMIC_ACQUIRE,
__ATOMIC_RELAXED))
old = 0;
}
/// locks for atomic operations
static Lock locks[SPINLOCK_COUNT];
#endif
/// Returns a lock to use for a given pointer.
static inline Lock *lock_for_pointer(void *ptr) {
intptr_t hash = (intptr_t)ptr;
// Disregard the lowest 4 bits. We want all values that may be part of the
// same memory operation to hash to the same value and therefore use the same
// lock.
hash >>= 4;
// Use the next bits as the basis for the hash
intptr_t low = hash & SPINLOCK_MASK;
// Now use the high(er) set of bits to perturb the hash, so that we don't
// get collisions from atomic fields in a single object
hash >>= 16;
hash ^= low;
// Return a pointer to the word to use
return locks + (hash & SPINLOCK_MASK);
}
/// Macros for determining whether a size is lock free. Clang can not yet
/// codegen __atomic_is_lock_free(16), so for now we assume 16-byte values are
/// not lock free.
#define IS_LOCK_FREE_1 __atomic_is_lock_free(1)
#define IS_LOCK_FREE_2 __atomic_is_lock_free(2)
#define IS_LOCK_FREE_4 __atomic_is_lock_free(4)
#define IS_LOCK_FREE_8 __atomic_is_lock_free(8)
#define IS_LOCK_FREE_16 0
/// Macro that calls the compiler-generated lock-free versions of functions
/// when they exist.
#define LOCK_FREE_CASES() \
do {\
switch (size) {\
case 2:\
if (IS_LOCK_FREE_2) {\
LOCK_FREE_ACTION(uint16_t);\
}\
case 4:\
if (IS_LOCK_FREE_4) {\
LOCK_FREE_ACTION(uint32_t);\
}\
case 8:\
if (IS_LOCK_FREE_8) {\
LOCK_FREE_ACTION(uint64_t);\
}\
case 16:\
if (IS_LOCK_FREE_16) {\
/* FIXME: __uint128_t isn't available on 32 bit platforms.
LOCK_FREE_ACTION(__uint128_t);*/\
}\
}\
} while (0)
/// An atomic load operation. This is atomic with respect to the source
/// pointer only.
void __atomic_load_n(int size, void *src, void *dest, int model) {
#define LOCK_FREE_ACTION(type) \
*((type*)dest) = __atomic_load((_Atomic(type)*)src, model);\
return;
LOCK_FREE_CASES();
#undef LOCK_FREE_ACTION
Lock *l = lock_for_pointer(src);
lock(l);
memcpy(dest, src, size);
unlock(l);
}
/// An atomic store operation. This is atomic with respect to the destination
/// pointer only.
void __atomic_store_n(int size, void *dest, void *src, int model) {
#define LOCK_FREE_ACTION(type) \
__atomic_store((_Atomic(type)*)dest, *(type*)dest, model);\
return;
LOCK_FREE_CASES();
#undef LOCK_FREE_ACTION
Lock *l = lock_for_pointer(dest);
lock(l);
memcpy(dest, src, size);
unlock(l);
}
/// Atomic compare and exchange operation. If the value at *ptr is identical
/// to the value at *expected, then this copies value at *desired to *ptr. If
/// they are not, then this stores the current value from *ptr in *expected.
///
/// This function returns 1 if the exchange takes place or 0 if it fails.
int __atomic_compare_exchange_n(int size, void *ptr, void *expected,
void *desired, int success, int failure) {
#define LOCK_FREE_ACTION(type) \
return __atomic_compare_exchange_strong((_Atomic(type)*)ptr, (type*)expected,\
*(type*)desired, success, failure)
LOCK_FREE_CASES();
#undef LOCK_FREE_ACTION
Lock *l = lock_for_pointer(ptr);
lock(l);
if (memcmp(ptr, expected, size) == 0) {
memcpy(ptr, desired, size);
unlock(l);
return 1;
}
memcpy(expected, ptr, size);
unlock(l);
return 0;
}
/// Performs an atomic exchange operation between two pointers. This is atomic
/// with respect to the target address.
void __atomic_exchange_n(int size, void *ptr, void *val, void *old, int model) {
#define LOCK_FREE_ACTION(type) \
*(type*)old = __atomic_exchange((_Atomic(type)*)ptr, *(type*)val,\
model);\
return;
LOCK_FREE_CASES();
#undef LOCK_FREE_ACTION
Lock *l = lock_for_pointer(ptr);
lock(l);
memcpy(old, ptr, size);
memcpy(ptr, val, size);
unlock(l);
}
////////////////////////////////////////////////////////////////////////////////
// Where the size is known at compile time, the compiler may emit calls to
// specialised versions of the above functions.
////////////////////////////////////////////////////////////////////////////////
#define OPTIMISED_CASES\
OPTIMISED_CASE(1, IS_LOCK_FREE_1, uint8_t)\
OPTIMISED_CASE(2, IS_LOCK_FREE_2, uint16_t)\
OPTIMISED_CASE(4, IS_LOCK_FREE_4, uint32_t)\
OPTIMISED_CASE(8, IS_LOCK_FREE_8, uint64_t)\
/* FIXME: __uint128_t isn't available on 32 bit platforms.
OPTIMISED_CASE(16, IS_LOCK_FREE_16, __uint128_t)*/\
#define OPTIMISED_CASE(n, lockfree, type)\
type __atomic_load_##n(type *src, int model) {\
if (lockfree)\
return __atomic_load((_Atomic(type)*)src, model);\
Lock *l = lock_for_pointer(src);\
lock(l);\
type val = *src;\
unlock(l);\
return val;\
}
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type)\
void __atomic_store_##n(type *dest, type val, int model) {\
if (lockfree) {\
__atomic_store((_Atomic(type)*)dest, val, model);\
return;\
}\
Lock *l = lock_for_pointer(dest);\
lock(l);\
*dest = val;\
unlock(l);\
return;\
}
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type)\
type __atomic_exchange_##n(type *dest, type val, int model) {\
if (lockfree)\
return __atomic_exchange((_Atomic(type)*)dest, val, model);\
Lock *l = lock_for_pointer(dest);\
lock(l);\
type tmp = *dest;\
*dest = val;\
unlock(l);\
return tmp;\
}
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type)\
int __atomic_compare_exchange_##n(type *ptr, type *expected, type desired,\
int success, int failure) {\
if (lockfree)\
return __atomic_compare_exchange_strong((_Atomic(type)*)ptr, expected, desired,\
success, failure);\
Lock *l = lock_for_pointer(ptr);\
lock(l);\
if (*ptr == *expected) {\
*ptr = desired;\
unlock(l);\
return 1;\
}\
*expected = *ptr;\
unlock(l);\
return 0;\
}
OPTIMISED_CASES
#undef OPTIMISED_CASE
////////////////////////////////////////////////////////////////////////////////
// Atomic read-modify-write operations for integers of various sizes.
////////////////////////////////////////////////////////////////////////////////
#define ATOMIC_RMW(n, lockfree, type, opname, op) \
type __atomic_fetch_##opname##_##n(type *ptr, type val, int model) {\
if (lockfree) \
return __atomic_fetch_##opname((_Atomic(type)*)ptr, val, model);\
Lock *l = lock_for_pointer(ptr);\
lock(l);\
type tmp = *ptr;\
*ptr = tmp op val;\
unlock(l);\
return tmp;\
}
#define OPTIMISED_CASE(n, lockfree, type) ATOMIC_RMW(n, lockfree, type, add, +)
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type) ATOMIC_RMW(n, lockfree, type, sub, -)
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type) ATOMIC_RMW(n, lockfree, type, and, &)
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type) ATOMIC_RMW(n, lockfree, type, or, |)
OPTIMISED_CASES
#undef OPTIMISED_CASE
#define OPTIMISED_CASE(n, lockfree, type) ATOMIC_RMW(n, lockfree, type, xor, ^)
OPTIMISED_CASES
#undef OPTIMISED_CASE