Release 4.14 arch/mips/include/asm/barrier.h
/*
* This file is subject to the terms and conditions of the GNU General Public
* License. See the file "COPYING" in the main directory of this archive
* for more details.
*
* Copyright (C) 2006 by Ralf Baechle (ralf@linux-mips.org)
*/
#ifndef __ASM_BARRIER_H
#define __ASM_BARRIER_H
#include <asm/addrspace.h>
/*
* Sync types defined by the MIPS architecture (document MD00087 table 6.5)
* These values are used with the sync instruction to perform memory barriers.
* Types of ordering guarantees available through the SYNC instruction:
* - Completion Barriers
* - Ordering Barriers
* As compared to the completion barrier, the ordering barrier is a
* lighter-weight operation as it does not require the specified instructions
* before the SYNC to be already completed. Instead it only requires that those
* specified instructions which are subsequent to the SYNC in the instruction
* stream are never re-ordered for processing ahead of the specified
* instructions which are before the SYNC in the instruction stream.
* This potentially reduces how many cycles the barrier instruction must stall
* before it completes.
* Implementations that do not use any of the non-zero values of stype to define
* different barriers, such as ordering barriers, must make those stype values
* act the same as stype zero.
*/
/*
* Completion barriers:
* - Every synchronizable specified memory instruction (loads or stores or both)
* that occurs in the instruction stream before the SYNC instruction must be
* already globally performed before any synchronizable specified memory
* instructions that occur after the SYNC are allowed to be performed, with
* respect to any other processor or coherent I/O module.
*
* - The barrier does not guarantee the order in which instruction fetches are
* performed.
*
* - A stype value of zero will always be defined such that it performs the most
* complete set of synchronization operations that are defined.This means
* stype zero always does a completion barrier that affects both loads and
* stores preceding the SYNC instruction and both loads and stores that are
* subsequent to the SYNC instruction. Non-zero values of stype may be defined
* by the architecture or specific implementations to perform synchronization
* behaviors that are less complete than that of stype zero. If an
* implementation does not use one of these non-zero values to define a
* different synchronization behavior, then that non-zero value of stype must
* act the same as stype zero completion barrier. This allows software written
* for an implementation with a lighter-weight barrier to work on another
* implementation which only implements the stype zero completion barrier.
*
* - A completion barrier is required, potentially in conjunction with SSNOP (in
* Release 1 of the Architecture) or EHB (in Release 2 of the Architecture),
* to guarantee that memory reference results are visible across operating
* mode changes. For example, a completion barrier is required on some
* implementations on entry to and exit from Debug Mode to guarantee that
* memory effects are handled correctly.
*/
/*
* stype 0 - A completion barrier that affects preceding loads and stores and
* subsequent loads and stores.
* Older instructions which must reach the load/store ordering point before the
* SYNC instruction completes: Loads, Stores
* Younger instructions which must reach the load/store ordering point only
* after the SYNC instruction completes: Loads, Stores
* Older instructions which must be globally performed when the SYNC instruction
* completes: Loads, Stores
*/
#define STYPE_SYNC 0x0
/*
* Ordering barriers:
* - Every synchronizable specified memory instruction (loads or stores or both)
* that occurs in the instruction stream before the SYNC instruction must
* reach a stage in the load/store datapath after which no instruction
* re-ordering is possible before any synchronizable specified memory
* instruction which occurs after the SYNC instruction in the instruction
* stream reaches the same stage in the load/store datapath.
*
* - If any memory instruction before the SYNC instruction in program order,
* generates a memory request to the external memory and any memory
* instruction after the SYNC instruction in program order also generates a
* memory request to external memory, the memory request belonging to the
* older instruction must be globally performed before the time the memory
* request belonging to the younger instruction is globally performed.
*
* - The barrier does not guarantee the order in which instruction fetches are
* performed.
*/
/*
* stype 0x10 - An ordering barrier that affects preceding loads and stores and
* subsequent loads and stores.
* Older instructions which must reach the load/store ordering point before the
* SYNC instruction completes: Loads, Stores
* Younger instructions which must reach the load/store ordering point only
* after the SYNC instruction completes: Loads, Stores
* Older instructions which must be globally performed when the SYNC instruction
* completes: N/A
*/
#define STYPE_SYNC_MB 0x10
#ifdef CONFIG_CPU_HAS_SYNC
#define __sync() \
__asm__ __volatile__( \
".set push\n\t" \
".set noreorder\n\t" \
".set mips2\n\t" \
"sync\n\t" \
".set pop" \
: /* no output */ \
: /* no input */ \
: "memory")
#else
#define __sync() do { } while(0)
#endif
#define __fast_iob() \
__asm__ __volatile__( \
".set push\n\t" \
".set noreorder\n\t" \
"lw $0,%0\n\t" \
"nop\n\t" \
".set pop" \
: /* no output */ \
: "m" (*(int *)CKSEG1) \
: "memory")
#ifdef CONFIG_CPU_CAVIUM_OCTEON
# define OCTEON_SYNCW_STR ".set push\n.set arch=octeon\nsyncw\nsyncw\n.set pop\n"
# define __syncw() __asm__ __volatile__(OCTEON_SYNCW_STR : : : "memory")
# define fast_wmb() __syncw()
# define fast_rmb() barrier()
# define fast_mb() __sync()
# define fast_iob() do { } while (0)
#else /* ! CONFIG_CPU_CAVIUM_OCTEON */
# define fast_wmb() __sync()
# define fast_rmb() __sync()
# define fast_mb() __sync()
# ifdef CONFIG_SGI_IP28
# define fast_iob() \
__asm__ __volatile__( \
".set push\n\t" \
".set noreorder\n\t" \
"lw $0,%0\n\t" \
"sync\n\t" \
"lw $0,%0\n\t" \
".set pop" \
: /* no output */ \
: "m" (*(int *)CKSEG1ADDR(0x1fa00004)) \
: "memory")
# else
# define fast_iob() \
do { \
__sync(); \
__fast_iob(); \
} while (0)
# endif
#endif /* CONFIG_CPU_CAVIUM_OCTEON */
#ifdef CONFIG_CPU_HAS_WB
#include <asm/wbflush.h>
#define mb() wbflush()
#define iob() wbflush()
#else /* !CONFIG_CPU_HAS_WB */
#define mb() fast_mb()
#define iob() fast_iob()
#endif /* !CONFIG_CPU_HAS_WB */
#define wmb() fast_wmb()
#define rmb() fast_rmb()
#if defined(CONFIG_WEAK_ORDERING)
# ifdef CONFIG_CPU_CAVIUM_OCTEON
# define __smp_mb() __sync()
# define __smp_rmb() barrier()
# define __smp_wmb() __syncw()
# else
# define __smp_mb() __asm__ __volatile__("sync" : : :"memory")
# define __smp_rmb() __asm__ __volatile__("sync" : : :"memory")
# define __smp_wmb() __asm__ __volatile__("sync" : : :"memory")
# endif
#else
#define __smp_mb() barrier()
#define __smp_rmb() barrier()
#define __smp_wmb() barrier()
#endif
#if defined(CONFIG_WEAK_REORDERING_BEYOND_LLSC) && defined(CONFIG_SMP)
#define __WEAK_LLSC_MB " sync \n"
#else
#define __WEAK_LLSC_MB " \n"
#endif
#define smp_llsc_mb() __asm__ __volatile__(__WEAK_LLSC_MB : : :"memory")
#ifdef CONFIG_CPU_CAVIUM_OCTEON
#define smp_mb__before_llsc() smp_wmb()
#define __smp_mb__before_llsc() __smp_wmb()
/* Cause previous writes to become visible on all CPUs as soon as possible */
#define nudge_writes() __asm__ __volatile__(".set push\n\t" \
".set arch=octeon\n\t" \
"syncw\n\t" \
".set pop" : : : "memory")
#else
#define smp_mb__before_llsc() smp_llsc_mb()
#define __smp_mb__before_llsc() smp_llsc_mb()
#define nudge_writes() mb()
#endif
#define __smp_mb__before_atomic() __smp_mb__before_llsc()
#define __smp_mb__after_atomic() smp_llsc_mb()
#include <asm-generic/barrier.h>
#endif /* __ASM_BARRIER_H */
Overall Contributors
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Ralf Bächle | 134 | 42.81% | 3 | 23.08% |
David Daney | 105 | 33.55% | 3 | 23.08% |
Michael S. Tsirkin | 25 | 7.99% | 2 | 15.38% |
Thomas Bogendoerfer | 15 | 4.79% | 1 | 7.69% |
Matt Redfearn | 13 | 4.15% | 1 | 7.69% |
Alexander Duyck | 11 | 3.51% | 1 | 7.69% |
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Total | 313 | 100.00% | 13 | 100.00% |
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