What is the fastest way of clearing a register (=0) in MIPS assembly?
xor $t0, $t0, $t0 and $t0, $t0, $0 move $t0, $0 li $t0, 0 add $t0, $0, $0
Which is the most efficient?
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In many MIPS implementations, these ops will both compile to the same instruction, because typically 'mov $a, $b' is an idiom for
or $a, $b, $0 and
li $r, x is shorthand for
ori $r, $0, x:
move $t0, $0 li $t0, 0
and these will both take place on the same pipeline, being architecturally equivalent:
xor $t0, $t0, $t0 and $t0, $t0, $0
and in every RISC implementation I've ever worked with, add is on the same pipe as xor/and/nor/etc.
Basically, this is all particular to the implementation of a particular chip, but they all ought to be single clock. If the chip is out of order,
and x, $0, $0 might be fastest because they minimize false dependencies on other registers.
Given that all of those instructions take a single pipeline cycle, there shouldn't be much difference between them.
If any, I'd expect the
xor $t0, $t0, $t0 to be best for speed because it doesn't use any other registers, thus keeping them free for other values and potentially reducing register file contention.
The xor method is also treated as a specific idiom on some processors, which allow it to use even less resources (e.g. not needing to do the XOR ALU operation.
On most implementations of the MIPS architecture, all of these should offer the same performance. However, one can envision a superscalar system which could execute several instructions simultaneously, as long as they use distinct internal units. I have no actual example of a MIPS system which works like that, but that is how it happens on PowerPC systems. A
xor $t0, $t0, $t0 opcode would be executed on the "integer computations" unit (because it is a
move $t0, $0 would not use that unit; conceptually, the latter could be executed in parallel with another opcode which perform integer computations.
In brief, if you find a system where all the ways you list are not equally efficient, then I would expect the
move $t0, $0 method to be the most efficient.
It probably depends on what other instructions will be in the pipeline at the same time: when the register was last used, when it will next be used and which internal units are currently in use.
I'm not familiar with the pipeline structure of any particular MIPS processor, but your compiler should be and I would expect it to choose whichever would be the fastest in a given code sequence.