It seems like part what you're really asking is:
Why isn't the lock prefix implicit for cmpxchg with a memory operand, like it is for xchg (since 386)?
The simple answer (that others have given) is simply that Intel designed it this way. But this leads to the question:
Why did Intel do that? Is there a use-case for cmpxchg without lock?
On a single-CPU system, cmpxchg is atomic with respect to other threads, or any other code running on the same CPU core. (But not to "system" observers like a memory-mapped I/O device, or a device doing DMA reads of normal memory, so lock cmpxchg was relevant even on uniprocessor CPU designs).
Context switches can only happen on interrupts, and interrupts happen before or after an instruction, not in the middle. Any code running on the same CPU will see the cmpxchg as either fully executed or not at all.
For example, the Linux kernel is normally compiled with SMP support, so it uses lock cmpxchg for atomic CAS. But when booted on a single-processor system, it will patch the lock prefix to a nop everywhere that code was inlined, since nop cmpxchg runs much faster than lock cmpxchg. For more info, see this LWN article about Linux's "SMP alternatives" system. It can even patch back to lock prefixes before hot-plugging a second CPU.
Read more about atomicity of single instructions on uniprocessor systems in this answer, and in @supercat's answer + comments on Can num++ be atomic for int num. See my answer there for lots of details about how atomicity really works / is implemented for read-modify-write instructions like lock cmpxchg.
(This same reasoning also applies to cmpxchg8b / cmpxchg16b, and xadd, which are usually only used for synchonization / atomic ops, not to make single-threaded code run faster. Of course memory-destination instructions like add [mem], reg are useful outside of the lock add [mem], reg case.)
与恶龙缠斗过久,自身亦成为恶龙;凝视深渊过久,深渊将回以凝视…
