Contributors: 17
Author Tokens Token Proportion Commits Commit Proportion
Peter Zijlstra 188 32.70% 8 26.67%
Michael S. Tsirkin 110 19.13% 3 10.00%
Arnd Bergmann 83 14.43% 1 3.33%
Marco Elver 44 7.65% 2 6.67%
David Howells 33 5.74% 1 3.33%
Alexander Duyck 24 4.17% 1 3.33%
Vineet Gupta 24 4.17% 1 3.33%
Kefeng Wang 16 2.78% 1 3.33%
Will Deacon 12 2.09% 3 10.00%
Xiongfeng Wang 11 1.91% 2 6.67%
Mathieu Desnoyers 11 1.91% 1 3.33%
Aneesh Kumar K.V 7 1.22% 1 3.33%
Linus Torvalds 3 0.52% 1 3.33%
Arvind Sankar 3 0.52% 1 3.33%
Thomas Gleixner 2 0.35% 1 3.33%
Christoph Lameter 2 0.35% 1 3.33%
Baokun Li 2 0.35% 1 3.33%
Total 575 30 


/* SPDX-License-Identifier: GPL-2.0-or-later */
/*
 * Generic barrier definitions.
 *
 * It should be possible to use these on really simple architectures,
 * but it serves more as a starting point for new ports.
 *
 * Copyright (C) 2007 Red Hat, Inc. All Rights Reserved.
 * Written by David Howells (dhowells@redhat.com)
 */
#ifndef __ASM_GENERIC_BARRIER_H
#define __ASM_GENERIC_BARRIER_H

#ifndef __ASSEMBLY__

#include <linux/compiler.h>
#include <linux/kcsan-checks.h>
#include <asm/rwonce.h>

#ifndef nop
#define nop()	asm volatile ("nop")
#endif

/*
 * Architectures that want generic instrumentation can define __ prefixed
 * variants of all barriers.
 */

#ifdef __mb
#define mb()	do { kcsan_mb(); __mb(); } while (0)
#endif

#ifdef __rmb
#define rmb()	do { kcsan_rmb(); __rmb(); } while (0)
#endif

#ifdef __wmb
#define wmb()	do { kcsan_wmb(); __wmb(); } while (0)
#endif

#ifdef __dma_mb
#define dma_mb()	do { kcsan_mb(); __dma_mb(); } while (0)
#endif

#ifdef __dma_rmb
#define dma_rmb()	do { kcsan_rmb(); __dma_rmb(); } while (0)
#endif

#ifdef __dma_wmb
#define dma_wmb()	do { kcsan_wmb(); __dma_wmb(); } while (0)
#endif

/*
 * Force strict CPU ordering. And yes, this is required on UP too when we're
 * talking to devices.
 *
 * Fall back to compiler barriers if nothing better is provided.
 */

#ifndef mb
#define mb()	barrier()
#endif

#ifndef rmb
#define rmb()	mb()
#endif

#ifndef wmb
#define wmb()	mb()
#endif

#ifndef dma_mb
#define dma_mb()	mb()
#endif

#ifndef dma_rmb
#define dma_rmb()	rmb()
#endif

#ifndef dma_wmb
#define dma_wmb()	wmb()
#endif

#ifndef __smp_mb
#define __smp_mb()	mb()
#endif

#ifndef __smp_rmb
#define __smp_rmb()	rmb()
#endif

#ifndef __smp_wmb
#define __smp_wmb()	wmb()
#endif

#ifdef CONFIG_SMP

#ifndef smp_mb
#define smp_mb()	do { kcsan_mb(); __smp_mb(); } while (0)
#endif

#ifndef smp_rmb
#define smp_rmb()	do { kcsan_rmb(); __smp_rmb(); } while (0)
#endif

#ifndef smp_wmb
#define smp_wmb()	do { kcsan_wmb(); __smp_wmb(); } while (0)
#endif

#else	/* !CONFIG_SMP */

#ifndef smp_mb
#define smp_mb()	barrier()
#endif

#ifndef smp_rmb
#define smp_rmb()	barrier()
#endif

#ifndef smp_wmb
#define smp_wmb()	barrier()
#endif

#endif	/* CONFIG_SMP */

#ifndef __smp_store_mb
#define __smp_store_mb(var, value)  do { WRITE_ONCE(var, value); __smp_mb(); } while (0)
#endif

#ifndef __smp_mb__before_atomic
#define __smp_mb__before_atomic()	__smp_mb()
#endif

#ifndef __smp_mb__after_atomic
#define __smp_mb__after_atomic()	__smp_mb()
#endif

#ifndef __smp_store_release
#define __smp_store_release(p, v)					\
do {									\
	compiletime_assert_atomic_type(*p);				\
	__smp_mb();							\
	WRITE_ONCE(*p, v);						\
} while (0)
#endif

#ifndef __smp_load_acquire
#define __smp_load_acquire(p)						\
({									\
	__unqual_scalar_typeof(*p) ___p1 = READ_ONCE(*p);		\
	compiletime_assert_atomic_type(*p);				\
	__smp_mb();							\
	(typeof(*p))___p1;						\
})
#endif

#ifdef CONFIG_SMP

#ifndef smp_store_mb
#define smp_store_mb(var, value)  do { kcsan_mb(); __smp_store_mb(var, value); } while (0)
#endif

#ifndef smp_mb__before_atomic
#define smp_mb__before_atomic()	do { kcsan_mb(); __smp_mb__before_atomic(); } while (0)
#endif

#ifndef smp_mb__after_atomic
#define smp_mb__after_atomic()	do { kcsan_mb(); __smp_mb__after_atomic(); } while (0)
#endif

#ifndef smp_store_release
#define smp_store_release(p, v) do { kcsan_release(); __smp_store_release(p, v); } while (0)
#endif

#ifndef smp_load_acquire
#define smp_load_acquire(p) __smp_load_acquire(p)
#endif

#else	/* !CONFIG_SMP */

#ifndef smp_store_mb
#define smp_store_mb(var, value)  do { WRITE_ONCE(var, value); barrier(); } while (0)
#endif

#ifndef smp_mb__before_atomic
#define smp_mb__before_atomic()	barrier()
#endif

#ifndef smp_mb__after_atomic
#define smp_mb__after_atomic()	barrier()
#endif

#ifndef smp_store_release
#define smp_store_release(p, v)						\
do {									\
	barrier();							\
	WRITE_ONCE(*p, v);						\
} while (0)
#endif

#ifndef smp_load_acquire
#define smp_load_acquire(p)						\
({									\
	__unqual_scalar_typeof(*p) ___p1 = READ_ONCE(*p);		\
	barrier();							\
	(typeof(*p))___p1;						\
})
#endif

#endif	/* CONFIG_SMP */

/* Barriers for virtual machine guests when talking to an SMP host */
#define virt_mb() do { kcsan_mb(); __smp_mb(); } while (0)
#define virt_rmb() do { kcsan_rmb(); __smp_rmb(); } while (0)
#define virt_wmb() do { kcsan_wmb(); __smp_wmb(); } while (0)
#define virt_store_mb(var, value) do { kcsan_mb(); __smp_store_mb(var, value); } while (0)
#define virt_mb__before_atomic() do { kcsan_mb(); __smp_mb__before_atomic(); } while (0)
#define virt_mb__after_atomic()	do { kcsan_mb(); __smp_mb__after_atomic(); } while (0)
#define virt_store_release(p, v) do { kcsan_release(); __smp_store_release(p, v); } while (0)
#define virt_load_acquire(p) __smp_load_acquire(p)

/**
 * smp_acquire__after_ctrl_dep() - Provide ACQUIRE ordering after a control dependency
 *
 * A control dependency provides a LOAD->STORE order, the additional RMB
 * provides LOAD->LOAD order, together they provide LOAD->{LOAD,STORE} order,
 * aka. (load)-ACQUIRE.
 *
 * Architectures that do not do load speculation can have this be barrier().
 */
#ifndef smp_acquire__after_ctrl_dep
#define smp_acquire__after_ctrl_dep()		smp_rmb()
#endif

/**
 * smp_cond_load_relaxed() - (Spin) wait for cond with no ordering guarantees
 * @ptr: pointer to the variable to wait on
 * @cond: boolean expression to wait for
 *
 * Equivalent to using READ_ONCE() on the condition variable.
 *
 * Due to C lacking lambda expressions we load the value of *ptr into a
 * pre-named variable @VAL to be used in @cond.
 */
#ifndef smp_cond_load_relaxed
#define smp_cond_load_relaxed(ptr, cond_expr) ({		\
	typeof(ptr) __PTR = (ptr);				\
	__unqual_scalar_typeof(*ptr) VAL;			\
	for (;;) {						\
		VAL = READ_ONCE(*__PTR);			\
		if (cond_expr)					\
			break;					\
		cpu_relax();					\
	}							\
	(typeof(*ptr))VAL;					\
})
#endif

/**
 * smp_cond_load_acquire() - (Spin) wait for cond with ACQUIRE ordering
 * @ptr: pointer to the variable to wait on
 * @cond: boolean expression to wait for
 *
 * Equivalent to using smp_load_acquire() on the condition variable but employs
 * the control dependency of the wait to reduce the barrier on many platforms.
 */
#ifndef smp_cond_load_acquire
#define smp_cond_load_acquire(ptr, cond_expr) ({		\
	__unqual_scalar_typeof(*ptr) _val;			\
	_val = smp_cond_load_relaxed(ptr, cond_expr);		\
	smp_acquire__after_ctrl_dep();				\
	(typeof(*ptr))_val;					\
})
#endif

/*
 * pmem_wmb() ensures that all stores for which the modification
 * are written to persistent storage by preceding instructions have
 * updated persistent storage before any data  access or data transfer
 * caused by subsequent instructions is initiated.
 */
#ifndef pmem_wmb
#define pmem_wmb()	wmb()
#endif

/*
 * ioremap_wc() maps I/O memory as memory with write-combining attributes. For
 * this kind of memory accesses, the CPU may wait for prior accesses to be
 * merged with subsequent ones. In some situation, such wait is bad for the
 * performance. io_stop_wc() can be used to prevent the merging of
 * write-combining memory accesses before this macro with those after it.
 */
#ifndef io_stop_wc
#define io_stop_wc() do { } while (0)
#endif

/*
 * Architectures that guarantee an implicit smp_mb() in switch_mm()
 * can override smp_mb__after_switch_mm.
 */
#ifndef smp_mb__after_switch_mm
# define smp_mb__after_switch_mm()	smp_mb()
#endif

#endif /* !__ASSEMBLY__ */
#endif /* __ASM_GENERIC_BARRIER_H */