blob: 44c04a82d0b7d4ef0a983ce97dbbae9fbe8db271 [file] [log] [blame]
/* SPDX-License-Identifier: GPL-2.0-only */
#ifndef __MIPS_ASM_SYNC_H__
#define __MIPS_ASM_SYNC_H__
/*
* sync types are defined by the MIPS64 Instruction Set documentation in Volume
* II-A of the MIPS Architecture Reference Manual, which can be found here:
*
* https://www.mips.com/?do-download=the-mips64-instruction-set-v6-06
*
* Two types of barrier are provided:
*
* 1) Completion barriers, which ensure that a memory operation has actually
* completed & often involve stalling the CPU pipeline to do so.
*
* 2) Ordering barriers, which only ensure that affected memory operations
* won't be reordered in the CPU pipeline in a manner that violates the
* restrictions imposed by the barrier.
*
* Ordering barriers can be more efficient than completion barriers, since:
*
* a) Ordering barriers only require memory access instructions which precede
* them in program order (older instructions) to reach a point in the
* load/store datapath beyond which reordering is not possible before
* allowing memory access instructions which follow them (younger
* instructions) to be performed. That is, older instructions don't
* actually need to complete - they just need to get far enough that all
* other coherent CPUs will observe their completion before they observe
* the effects of younger instructions.
*
* b) Multiple variants of ordering barrier are provided which allow the
* effects to be restricted to different combinations of older or younger
* loads or stores. By way of example, if we only care that stores older
* than a barrier are observed prior to stores that are younger than a
* barrier & don't care about the ordering of loads then the 'wmb'
* ordering barrier can be used. Limiting the barrier's effects to stores
* allows loads to continue unaffected & potentially allows the CPU to
* make progress faster than if younger loads had to wait for older stores
* to complete.
*/
/*
* No sync instruction at all; used to allow code to nullify the effect of the
* __SYNC() macro without needing lots of #ifdefery.
*/
#define __SYNC_none -1
/*
* A full completion barrier; all memory accesses appearing prior to this sync
* instruction in program order must complete before any memory accesses
* appearing after this sync instruction in program order.
*/
#define __SYNC_full 0x00
/*
* For now we use a full completion barrier to implement all sync types, until
* we're satisfied that lightweight ordering barriers defined by MIPSr6 are
* sufficient to uphold our desired memory model.
*/
#define __SYNC_aq __SYNC_full
#define __SYNC_rl __SYNC_full
#define __SYNC_mb __SYNC_full
/*
* ...except on Cavium Octeon CPUs, which have been using the 'wmb' ordering
* barrier since 2010 & omit 'rmb' barriers because the CPUs don't perform
* speculative reads.
*/
#ifdef CONFIG_CPU_CAVIUM_OCTEON
# define __SYNC_rmb __SYNC_none
# define __SYNC_wmb 0x04
#else
# define __SYNC_rmb __SYNC_full
# define __SYNC_wmb __SYNC_full
#endif
/*
* A GINV sync is a little different; it doesn't relate directly to loads or
* stores, but instead causes synchronization of an icache or TLB global
* invalidation operation triggered by the ginvi or ginvt instructions
* respectively. In cases where we need to know that a ginvi or ginvt operation
* has been performed by all coherent CPUs, we must issue a sync instruction of
* this type. Once this instruction graduates all coherent CPUs will have
* observed the invalidation.
*/
#define __SYNC_ginv 0x14
/* Trivial; indicate that we always need this sync instruction. */
#define __SYNC_always (1 << 0)
/*
* Indicate that we need this sync instruction only on systems with weakly
* ordered memory access. In general this is most MIPS systems, but there are
* exceptions which provide strongly ordered memory.
*/
#ifdef CONFIG_WEAK_ORDERING
# define __SYNC_weak_ordering (1 << 1)
#else
# define __SYNC_weak_ordering 0
#endif
/*
* Indicate that we need this sync instruction only on systems where LL/SC
* don't implicitly provide a memory barrier. In general this is most MIPS
* systems.
*/
#ifdef CONFIG_WEAK_REORDERING_BEYOND_LLSC
# define __SYNC_weak_llsc (1 << 2)
#else
# define __SYNC_weak_llsc 0
#endif
/*
* Some Loongson 3 CPUs have a bug wherein execution of a memory access (load,
* store or prefetch) in between an LL & SC can cause the SC instruction to
* erroneously succeed, breaking atomicity. Whilst it's unusual to write code
* containing such sequences, this bug bites harder than we might otherwise
* expect due to reordering & speculation:
*
* 1) A memory access appearing prior to the LL in program order may actually
* be executed after the LL - this is the reordering case.
*
* In order to avoid this we need to place a memory barrier (ie. a SYNC
* instruction) prior to every LL instruction, in between it and any earlier
* memory access instructions.
*
* This reordering case is fixed by 3A R2 CPUs, ie. 3A2000 models and later.
*
* 2) If a conditional branch exists between an LL & SC with a target outside
* of the LL-SC loop, for example an exit upon value mismatch in cmpxchg()
* or similar, then misprediction of the branch may allow speculative
* execution of memory accesses from outside of the LL-SC loop.
*
* In order to avoid this we need a memory barrier (ie. a SYNC instruction)
* at each affected branch target.
*
* This case affects all current Loongson 3 CPUs.
*
* The above described cases cause an error in the cache coherence protocol;
* such that the Invalidate of a competing LL-SC goes 'missing' and SC
* erroneously observes its core still has Exclusive state and lets the SC
* proceed.
*
* Therefore the error only occurs on SMP systems.
*/
#ifdef CONFIG_CPU_LOONGSON3_WORKAROUNDS
# define __SYNC_loongson3_war (1 << 31)
#else
# define __SYNC_loongson3_war 0
#endif
/*
* Some Cavium Octeon CPUs suffer from a bug that causes a single wmb ordering
* barrier to be ineffective, requiring the use of 2 in sequence to provide an
* effective barrier as noted by commit 6b07d38aaa52 ("MIPS: Octeon: Use
* optimized memory barrier primitives."). Here we specify that the affected
* sync instructions should be emitted twice.
* Note that this expression is evaluated by the assembler (not the compiler),
* and that the assembler evaluates '==' as 0 or -1, not 0 or 1.
*/
#ifdef CONFIG_CPU_CAVIUM_OCTEON
# define __SYNC_rpt(type) (1 - (type == __SYNC_wmb))
#else
# define __SYNC_rpt(type) 1
#endif
/*
* The main event. Here we actually emit a sync instruction of a given type, if
* reason is non-zero.
*
* In future we have the option of emitting entries in a fixups-style table
* here that would allow us to opportunistically remove some sync instructions
* when we detect at runtime that we're running on a CPU that doesn't need
* them.
*/
#ifdef CONFIG_CPU_HAS_SYNC
# define ____SYNC(_type, _reason, _else) \
.if (( _type ) != -1) && ( _reason ); \
.set push; \
.set MIPS_ISA_LEVEL_RAW; \
.rept __SYNC_rpt(_type); \
sync _type; \
.endr; \
.set pop; \
.else; \
_else; \
.endif
#else
# define ____SYNC(_type, _reason, _else)
#endif
/*
* Preprocessor magic to expand macros used as arguments before we insert them
* into assembly code.
*/
#ifdef __ASSEMBLY__
# define ___SYNC(type, reason, else) \
____SYNC(type, reason, else)
#else
# define ___SYNC(type, reason, else) \
__stringify(____SYNC(type, reason, else))
#endif
#define __SYNC(type, reason) \
___SYNC(__SYNC_##type, __SYNC_##reason, )
#define __SYNC_ELSE(type, reason, else) \
___SYNC(__SYNC_##type, __SYNC_##reason, else)
#endif /* __MIPS_ASM_SYNC_H__ */