The Linux kernel uses lock; addl $0,0(%%esp) as write barrier, while the RE2 library uses xchgl (%0),%0 as write barrier. What's the difference and which is better?

Does x86 also require read barrier instructions? RE2 defines its read barrier function as a no-op on x86 while Linux defines it as either lfence or no-op depending on whether SSE2 is available. When is lfence required?

up vote 9 down vote accepted

The "lock; addl $0,0(%%esp)" is faster in case that we testing the 0 state of lock variable at (%%esp) address. Because we add 0 value to lock variable and the zero flag is set to 1 if the lock value of variable at address (%%esp) is 0.

lfence from Intel datasheet:

Performs a serializing operation on all load-from-memory instructions that were issued prior the LFENCE instruction. This serializing operation guarantees that every load instruction that precedes in program order the LFENCE instruction is globally visible before any load instruction that follows the LFENCE instruction is globally visible.

For instance: memory write instruction like 'mov' are atomic (they don't need lock prefix) if there are properly aligned. But this instruction is normally executed in CPU cache and will not be globally visible at this moment for all other threads, because memory fence must be preformed first.


So the main difference between these two instructions is that xchgl instruction will not have any effect on the conditional flags. Certainly we can test the lock variable state with lock cmpxchg instruction but this is still more complex than with lock add $0 instruction.

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    If I write to shared memory and call lock; addl $0,0(%%esp) or sfence, do I need to call lfence in the other process/thread before reading the memory? Or does the lock/sfence instruction by itself already guarantee that other CPUs see the data? – Hongli Nov 21 '10 at 9:42
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    Yes, lock prefix guarantee that result of instruction is immediately globaly visible. – GJ. Nov 21 '10 at 12:12
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    Suppose the CPU supports SSE but not SSE2. I use sfence but cannot use lfence. Do I need to use lock; add as read barrier, or can I get away with not using a read barrier? – Hongli Nov 21 '10 at 17:41
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    Depend of haw and in which ring your instructions is executed. Instruction lfence is normally used in kernel (ring 0). If CPU don't support lfence instruction than program applications and threads must to use sfence after lock performed with mov, because kernel can interrupt program applications and threads after any CPU instruction and changed data memory and instructions can be still in cache. So you can use "lock add $0,..." in kernel and "mov $1,... sfence" in program applications and threads. – GJ. Nov 21 '10 at 19:05
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    My instructions are executed in userspace. So if I use 'lock; add' as write barrier, then on the reading side I don't have to use any special read barrier instruction, and a simple compiler barrier will suffice, right? – Hongli Nov 24 '10 at 11:03

Quoting from the IA32 manuals (Vol 3A, Chapter 8.2: Memory Ordering):

In a single-processor system for memory regions defined as write-back cacheable, the memory-ordering model respects the following principles [..]

  • Reads are not reordered with other reads
  • Writes are not reordered with older reads
  • Writes to memory are not reordered with other writes, with the exception of
    • writes executed with the CLFLUSH instruction
    • streaming stores (writes) executed with the non-temporal move instructions ([list of instructions here])
    • string operations (see Section
  • Reads may be reordered with older writes to different locations but not with older writes to the same location.
  • Reads or writes cannot be reordered with I/O instructions, locked instructions, or serializing instructions
  • Reads cannot pass LFENCE and MFENCE instructions
  • Writes cannot pass SFENCE and MFENCE instructions

Note: The "In a single-processor system" above is slightly misleading. The same rules hold for each (logical) processor individually; the manual then goes on to describe the additional ordering rules between multiple processors. The only bit about it pertaining to the question is that

  • Locked instructions have a total order.

In short, as long as you're writing to write-back memory (which is all memory you'll ever see as long as you're not a driver or graphics programmer), most x86 instructions are almost sequentially consistent - the only reordering an x86 CPU can perform is reorder later (independent) reads to execute before writes. The main thing about the write barriers is that they have a lock prefix (implicit or explicit), which forbids all reordering and ensures that the operations is seen in the same order by all processors in a multi-processor system.

Also, in write-back memory, reads are never reordered, so there's no need for read barriers. Recent x86 processors have a weaker memory consistency model for streaming stores and write-combined memory (commonly used for mapped graphics memory). That's where the various fence instructions come into play; they're not necessary for any other memory type, but some drivers in the Linux kernel do deal with write-combined memory so they just defined their read-barrier that way. The list of ordering model per memory type is in Section 11.3.1 in Vol. 3A of the IA-32 manuals. Short version: Write-Through, Write-Back and Write-Protected allow speculative reads (following the rules as detailed above), Uncachable and Strong Uncacheable memory has strong ordering guarantees (no processor reordering, reads/writes are immediately executed, used for MMIO) and Write Combined memory has weak ordering (i.e. relaxed ordering rules that need fences).

As an aside to the other answers, the HotSpot devs found that lock; addl $0,0(%%esp) with a zero offset may not be optimal, on some processors it can introduce false data dependencies; related jdk bug.

Touching a stack location with a different offset can improve performance under some circumstances.

The important part of lock; addl and xchgl is the lock prefix. It's implicit for xchgl. There is really no difference between the two. I'd look at how they assemble and choose the one that's shorter (in bytes) since that's usually faster for equivalent operations on x86 (hence tricks like xorl eax,eax)

The presence of SSE2 is probably just a proxy for the real condition which is ultimately a function of cpuid. It probably turns out that SSE2 implies the existence of lfence and the availability of SSE2 was checked/cached at boot. lfence is required when it's available.

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    The instruction lfence is part of the SSE2 instruction set. It's not a proxy. – Pascal Cuoq Nov 20 '10 at 22:48

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