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I read the Intel manual and found there is a lock prefix for instructions, which can prevent processors writing to the same memory location at the same time. I am quite excited about it. I guess it could be used as hardware mutex. So I wrote a piece of code to have a shot. The result is quite frustrating. The lock does not support MOV or LEA instructions. The manual says LOCK only supports ADD, ADC, AND, BTC, BTR, BTS, CMPXCHG, CMPXCH8B, DEC, INC, NEG, NOT, OR, SBB, SUB, XOR, XADD, and XCHG. What is more, if the LOCK prefix is used with one of these instructions and the source operand is a memory operand, an undefined opcode exception (#UD) may be generated.

I wonder why so many limitations, so many restrictions make LOCK quit useless. I cannot use it to guarantee a general write operation not have dirty data or other problems caused by parallelism.

E.g. I wrote code ++(*p) in C. p is pointer to a shared memory. The corresponding assembly is like:

movl    28(%esp), %eax
movl    (%eax), %eax
leal    1(%eax), %edx
movl    28(%esp), %eax
movl    %edx, (%eax)

I added "lock" before "movl" and "leal", but the processor complains "Invalid Instruction". :-( I guess the only way to make the write operations serialized is to use software mutex, right?

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A movl to an aligned address is always atomic, so lock would make no difference at all. –  hirschhornsalz Jun 16 '12 at 17:44
    
If these "restrictions" did not exist, the additional uses would all be useless anyway. –  harold Jun 16 '12 at 18:40
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@BrianKnoblauch: They are guaranteed atomic on all processors since 486, to be more specific. I just assumed that we were talking about processors younger than 20 years. See the Intel System Programming Guide Chapter 8.1.1 "The Intel486 processor (and newer processors since) guarantees that the following basic memory operations will always be carried out atomically: • Reading or writing a byte • Reading or writing a word aligned on a 16-bit boundary • Reading or writing a doubleword aligned on a 32-bit boundary" etc. –  hirschhornsalz Jun 18 '12 at 13:47

4 Answers 4

up vote 7 down vote accepted

I certainly would not call lock useless. lock cmpxchg is the standard way to perform compare-and-swap, which is the basic building block of many synchronization algorithms.

Also, see fetch-and-add.

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Thanks. I will check it out. –  Sean Jun 16 '12 at 18:07

The purpose of lock is to make operations atomic, not serialized. In this way the CPU cannot be preempted before the operation takes effect.

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Thanks for your response. I am not very sure about these terminologies. I guess atomic means the operation will be done in a whole, no interruption, otherwise canceled. In this problem, even if "lock add" is done in an atomic manner, if does not mean other processor cannot access that memory location stealthily at the same time. So what "lock" is doing is to prevent parallel access to the same memory location. I guess this is called serialized, making every thread access the memory one by one. –  Sean Jun 16 '12 at 18:06
    
Atomic operations are primitives used for serialization, but they are not serialized themselves; serialization refers to multiple entities performing the same operation one at a time, whereas atomic operations preform an arbitrary operation in one discrete motion, undisturbed by others. –  Ignacio Vazquez-Abrams Jun 16 '12 at 18:24

The x86 processors are known for a hairy design with lots of features, lots of rules, and even more exceptions to all those rules. This is related to the long history to the family.

When compilers or people are using LOCK, they are always using it with all its limitations, often on data specially introduced to perform synchronization between threads, as opposed to application data that the algorithms eventually manipulate. One then adapts the thread synchronization protocols to what LOCK can do for them, rather than vice versa.

The general type of instruction you seem to look for is called memory barriers. Indeed, x86 has several "modern" instructions from this family (MFENCE, LFENCE, SFENCE). They are full fence, load fence, and store fence, respectively. However, their importance in the instruction set is limited to SSE, because Intel guarantees serialization of writes on the traditional part of the instruction set, and that is pretty much the reason why this aged architecture is quite an easy target for multithreaded programming.

See also this answer for more info.

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It is useful when you have two concurrent process on multiprocessor machine using the same data but they can't access to it simultaneously .

When one of the process is using the data he put a lock on it so when the second ask for it he need to wait for the first to finish.

I hope this will help a bit.

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