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/*
* Copyright (c) 2014 Nicira, Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* This header implements atomic operation primitives on x86_64 with GCC. */
#ifndef IN_OVS_ATOMIC_H
#error "This header should only be included indirectly via ovs-atomic.h."
#endif
#define OVS_ATOMIC_X86_64_IMPL 1
/*
* x86_64 Memory model (http://www.intel.com/content/www/us/en/architecture-and-technology/64-ia-32-architectures-software-developer-vol-3a-part-1-manual.html):
*
* - 1, 2, 4, and 8 byte loads and stores are atomic on aligned memory.
* - Loads are not reordered with other loads.
* - Stores are not reordered with OLDER loads.
* - Loads may be reordered with OLDER stores to a different memory location,
* but not with OLDER stores to the same memory location.
* - Stores are not reordered with other stores, except for special
* instructions (CLFLUSH, streaming stores, fast string operations).
* Most of these are not emitted by compilers, and as long as the
* atomic stores are not combined with any other stores, even the allowed
* reordering of the stores by a single fast string operation (e.g., "stos")
* is not a problem.
* - Neither loads nor stores are reordered with locked instructions.
* - Loads cannot pass earlier LFENCE or MFENCE instructions.
* - Stores cannot pass earlier LFENCE, SFENCE, or MFENCE instructions.
* - LFENCE instruction cannot pass earlier loads.
* - SFENCE instruction cannot pass earlier stores.
* - MFENCE instruction cannot pass earlier loads or stores.
* - Stores by a single processor are observed in the same order by all
* processors.
* - (Unlocked) Stores from different processors are NOT ordered.
* - Memory ordering obeys causality (memory ordering respects transitive
* visibility).
* - Any two stores are seen in a consistent order by processors other than
* the those performing the stores.
* - Locked instructions have total order.
*
* These rules imply that:
*
* - Locked instructions are not needed for aligned loads or stores to make
* them atomic.
* - All stores have release semantics; none of the preceding stores or loads
* can be reordered with following stores. Following loads could still be
* reordered to happen before the store, but that is not a violation of the
* release semantics.
* - All loads from a given memory location have acquire semantics with
* respect to the stores on the same memory location; none of the following
* loads or stores can be reordered with the load. Preceding stores to a
* different memory location MAY be reordered with the load, but that is not
* a violation of the acquire semantics (i.e., the loads and stores of two
* critical sections guarded by a different memory location can overlap).
* - Locked instructions serve as CPU memory barriers by themselves.
* - Locked stores implement the sequential consistency memory order. Using
* locked instructions when seq_cst memory order is requested allows normal
* loads to observe the stores in the same (total) order without using CPU
* memory barrier after the loads.
*
* NOTE: Some older AMD Opteron processors have a bug that violates the
* acquire semantics described above. The bug manifests as an unlocked
* read-modify-write operation following a "semaphore operation" operating
* on data that existed before entering the critical section; i.e., the
* preceding "semaphore operation" fails to function as an acquire barrier.
* The affected CPUs are AMD family 15, models 32 to 63.
*
* Ref. http://support.amd.com/TechDocs/25759.pdf errata #147.
*/
/* Barriers. */
#define compiler_barrier() asm volatile(" " : : : "memory")
#define cpu_barrier() asm volatile("mfence;" : : : "memory")
/*
* The 'volatile' keyword prevents the compiler from keeping the atomic
* value in a register, and generates a new memory access for each atomic
* operation. This allows the implementations of memory_order_relaxed and
* memory_order_consume to avoid issuing a compiler memory barrier, allowing
* full optimization of all surrounding non-atomic variables.
*
* The placement of the 'volatile' keyword after the 'TYPE' below is highly
* significant when the TYPE is a pointer type. In that case we want the
* pointer to be declared volatile, not the data type that is being pointed
* at!
*/
#define ATOMIC(TYPE) TYPE volatile
/* Memory ordering. Must be passed in as a constant. */
typedef enum {
memory_order_relaxed,
memory_order_consume,
memory_order_acquire,
memory_order_release,
memory_order_acq_rel,
memory_order_seq_cst
} memory_order;
�
#define ATOMIC_BOOL_LOCK_FREE 2
#define ATOMIC_CHAR_LOCK_FREE 2
#define ATOMIC_SHORT_LOCK_FREE 2
#define ATOMIC_INT_LOCK_FREE 2
#define ATOMIC_LONG_LOCK_FREE 2
#define ATOMIC_LLONG_LOCK_FREE 2
#define ATOMIC_POINTER_LOCK_FREE 2
#define IS_LOCKLESS_ATOMIC(OBJECT) \
(sizeof(OBJECT) <= 8 && IS_POW2(sizeof(OBJECT)))
�
#define atomic_init(OBJECT, VALUE) (*(OBJECT) = (VALUE), (void) 0)
/*
* The memory_model_relaxed does not need a compiler barrier, if the
* atomic operation can otherwise be guaranteed to not be moved with
* respect to other atomic operations on the same memory location. Using
* the 'volatile' keyword in the definition of the atomic types
* accomplishes this, as memory accesses to volatile data may not be
* optimized away, or be reordered with other volatile accesses.
*
* On x86 also memory_order_consume is automatic, and data dependency on a
* volatile atomic variable means that the compiler optimizations should not
* cause problems. That is, the compiler should not speculate the value of
* the atomic_read, as it is going to read it from the memory anyway.
* This allows omiting the compiler memory barrier on atomic_reads with
* memory_order_consume. This matches the definition of
* smp_read_barrier_depends() in Linux kernel as a nop for x86, and its usage
* in rcu_dereference().
*
* We use this same logic below to choose inline assembly statements with or
* without a compiler memory barrier.
*/
static inline void
atomic_compiler_barrier(memory_order order)
{
if (order > memory_order_consume) {
compiler_barrier();
}
}
static inline void
atomic_thread_fence(memory_order order)
{
if (order == memory_order_seq_cst) {
cpu_barrier();
} else {
atomic_compiler_barrier(order);
}
}
static inline void
atomic_signal_fence(memory_order order)
{
atomic_compiler_barrier(order);
}
#define atomic_is_lock_free(OBJ) \
((void) *(OBJ), \
IS_LOCKLESS_ATOMIC(*(OBJ)) ? 2 : 0)
#define atomic_exchange__(DST, SRC, ORDER) \
({ \
typeof(DST) dst___ = (DST); \
typeof(*(DST)) src___ = (SRC); \
\
if ((ORDER) > memory_order_consume) { \
asm volatile("xchg %1,%0 ; " \
"# atomic_exchange__" \
: "+r" (src___), /* 0 */ \
"+m" (*dst___) /* 1 */ \
:: "memory"); \
} else { \
asm volatile("xchg %1,%0 ; " \
"# atomic_exchange__" \
: "+r" (src___), /* 0 */ \
"+m" (*dst___)); /* 1 */ \
} \
src___; \
})
/* Atomic store: Valid memory models are:
*
* memory_order_relaxed, memory_order_release, and
* memory_order_seq_cst. */
#define atomic_store_explicit(DST, SRC, ORDER) \
({ \
typeof(DST) dst__ = (DST); \
typeof(*(DST)) src__ = (SRC); \
\
if ((ORDER) != memory_order_seq_cst) { \
atomic_compiler_barrier(ORDER); \
*dst__ = src__; \
} else { \
atomic_exchange__(dst__, src__, ORDER); \
} \
(void) 0; \
})
#define atomic_store(DST, SRC) \
atomic_store_explicit(DST, SRC, memory_order_seq_cst)
/* Atomic read: Valid memory models are:
*
* memory_order_relaxed, memory_order_consume, memory_model_acquire,
* and memory_order_seq_cst. */
#define atomic_read_explicit(SRC, DST, ORDER) \
({ \
typeof(DST) dst__ = (DST); \
typeof(SRC) src__ = (SRC); \
\
*dst__ = *src__; \
atomic_compiler_barrier(ORDER); \
(void) 0; \
})
#define atomic_read(SRC, DST) \
atomic_read_explicit(SRC, DST, memory_order_seq_cst)
#define atomic_compare_exchange__(DST, EXP, SRC, RES, CLOB) \
asm volatile("lock; cmpxchg %3,%1 ; " \
" sete %0 " \
"# atomic_compare_exchange__" \
: "=q" (RES), /* 0 */ \
"+m" (*DST), /* 1 */ \
"+a" (EXP) /* 2 */ \
: "r" (SRC) /* 3 */ \
: CLOB, "cc")
/* All memory models are valid for read-modify-write operations.
*
* Valid memory models for the read operation of the current value in
* the failure case are the same as for atomic read, but can not be
* stronger than the success memory model.
* ORD_FAIL is ignored, as atomic_compare_exchange__ already implements
* at least as strong a barrier as allowed for ORD_FAIL in all cases. */
#define atomic_compare_exchange_strong_explicit(DST, EXP, SRC, ORDER, ORD_FAIL) \
({ \
typeof(DST) dst__ = (DST); \
typeof(DST) expp__ = (EXP); \
typeof(*(DST)) src__ = (SRC); \
typeof(*(DST)) exp__ = *expp__; \
uint8_t res__; \
(void)ORD_FAIL; \
\
if ((ORDER) > memory_order_consume) { \
atomic_compare_exchange__(dst__, exp__, src__, res__, \
"memory"); \
} else { \
atomic_compare_exchange__(dst__, exp__, src__, res__, \
"cc"); \
} \
if (!res__) { \
*expp__ = exp__; \
} \
(bool)res__; \
})
#define atomic_compare_exchange_strong(DST, EXP, SRC) \
atomic_compare_exchange_strong_explicit(DST, EXP, SRC, \
memory_order_seq_cst, \
memory_order_seq_cst)
#define atomic_compare_exchange_weak \
atomic_compare_exchange_strong
#define atomic_compare_exchange_weak_explicit \
atomic_compare_exchange_strong_explicit
#define atomic_exchange_explicit(RMW, ARG, ORDER) \
atomic_exchange__(RMW, ARG, ORDER)
#define atomic_exchange(RMW, ARG) \
atomic_exchange_explicit(RMW, ARG, memory_order_seq_cst)
#define atomic_add__(RMW, ARG, CLOB) \
asm volatile("lock; xadd %0,%1 ; " \
"# atomic_add__ " \
: "+r" (ARG), /* 0 */ \
"+m" (*RMW) /* 1 */ \
:: CLOB, "cc")
#define atomic_add_explicit(RMW, ARG, ORIG, ORDER) \
({ \
typeof(RMW) rmw__ = (RMW); \
typeof(*(RMW)) arg__ = (ARG); \
\
if ((ORDER) > memory_order_consume) { \
atomic_add__(rmw__, arg__, "memory"); \
} else { \
atomic_add__(rmw__, arg__, "cc"); \
} \
*(ORIG) = arg__; \
})
#define atomic_add(RMW, ARG, ORIG) \
atomic_add_explicit(RMW, ARG, ORIG, memory_order_seq_cst)
#define atomic_sub_explicit(RMW, ARG, ORIG, ORDER) \
atomic_add_explicit(RMW, -(ARG), ORIG, ORDER)
#define atomic_sub(RMW, ARG, ORIG) \
atomic_sub_explicit(RMW, ARG, ORIG, memory_order_seq_cst)
/* We could use simple locked instructions if the original value was not
* needed. */
#define atomic_op__(RMW, OP, ARG, ORIG, ORDER) \
({ \
typeof(RMW) rmw__ = (RMW); \
typeof(ARG) arg__ = (ARG); \
\
typeof(*(RMW)) val__; \
\
atomic_read_explicit(rmw__, &val__, memory_order_relaxed); \
do { \
} while (!atomic_compare_exchange_weak_explicit(rmw__, &val__, \
val__ OP arg__, \
ORDER, \
memory_order_relaxed)); \
*(ORIG) = val__; \
})
#define atomic_or_explicit(RMW, ARG, ORIG, ORDER) \
atomic_op__(RMW, |, ARG, ORIG, ORDER)
#define atomic_or(RMW, ARG, ORIG) \
atomic_or_explicit(RMW, ARG, ORIG, memory_order_seq_cst)
#define atomic_xor_explicit(RMW, ARG, ORIG, ORDER) \
atomic_op__(RMW, ^, ARG, ORIG, ORDER)
#define atomic_xor(RMW, ARG, ORIG) \
atomic_xor_explicit(RMW, ARG, ORIG, memory_order_seq_cst)
#define atomic_and_explicit(RMW, ARG, ORIG, ORDER) \
atomic_op__(RMW, &, ARG, ORIG, ORDER)
#define atomic_and(RMW, ARG, ORIG) \
atomic_and_explicit(RMW, ARG, ORIG, memory_order_seq_cst)
�
/* atomic_flag */
typedef ATOMIC(int) atomic_flag;
#define ATOMIC_FLAG_INIT { false }
#define atomic_flag_test_and_set_explicit(FLAG, ORDER) \
((bool)atomic_exchange__(FLAG, 1, ORDER))
#define atomic_flag_test_and_set(FLAG) \
atomic_flag_test_and_set_explicit(FLAG, memory_order_seq_cst)
#define atomic_flag_clear_explicit(FLAG, ORDER) \
atomic_store_explicit(FLAG, 0, ORDER)
#define atomic_flag_clear(FLAG) \
atomic_flag_clear_explicit(FLAG, memory_order_seq_cst)
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