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I'm curious as to why we are not allowed to use registers as offsets in MIPS. I know that you can't use registers as offsets like this: lw $t3, $t1($t4); I'm just curious as to why that is the case.

Is it a hardware restriction? Or simply just part of the ISA?

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    That's the way they designed it. You'll have to ask the designers why they decided against it. – Raymond Chen Oct 22 '17 at 20:57
  • I think later MIPS does have indexed loads (as well as PC-relative). tkt.cs.tut.fi/kurssit/3200/S05/Luennot/Lec_notes05/…. Probably supporting PC-relative meant they needed a 2-register adder in the AGU, so might as well also allow 2 arbitrary registers instead of just PC + register. First-gen MIPS I had only one addressing mode: base + displacement (which could be zero, of course). So obviously that makes decoding and address-generation simpler. – Peter Cordes Oct 22 '17 at 21:23
  • Wikipedia says MIPS IV added indexed addressing modes. Hmm, but they only mention it for FP loads/stores. A current MIPS instruction-set quick ref only lists the off(Rs) modes for integer loads/stores, including unaligned and LL/SC. – Peter Cordes Oct 22 '17 at 21:28
  • lwpc is new in MIPS release 6, and uses the usual sign_extend( offset << 2 ) encoding, but with PC instead of a GPR. That same doc does document the indexed FP loads (like lwxc1, which uses GPR[base] + GPR[index]). So yes, the MIPS ISA still doesn't include indexed integer loads. You have to do the address math yourself. At least there's a shift-and-add instruction (lsa) for scaled-index address generation (e.g. for int[]). – Peter Cordes Oct 22 '17 at 21:50
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    I'd guess the motivation was part of the whole RISC philosophy. MIPS was one of the very first RISC designs. – Peter Cordes Oct 22 '17 at 21:54
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I'm curious as to why we are not allowed to use registers as offsets in MIPS.

I'm not sure if you mean "why does MIPS assembly not permit you to write it this form" or "why does the underlying ISA not offer this form".

If it's the former, then the answer is that the base ISA doesn't have any machine instructions that offers that functionality, and apparently the designers didn't decide to offer any pseudo-instruction that would implement that behind the scenes.2

If you're asking why the ISA doesn't offer it in the first place, it's just a design choice. By offering fewer or simpler addressing modes, you get the following advantages:

  • Less room is needed to encode a more limited set of possibilities, so you save encoding space for more opcodes, shorter instructions, etc.
  • The hardware can be simpler, or faster. For example, allowing two registers in address calculation may result in:
  • The need for an additional read port in the register file1.
  • Additional connections between the register file and the AGU to get both registers values there.
  • The need to do a full width (32 or 64 bit) addition rather than a simpler address-side + 16 bit-addition for the offset.
  • The need to have a three-input ALU if you want to still want to support immediate offsets with the 2-register addresses (and they are less useful if you don't).
  • Additional complexity in instruction decoding and address-generation since you may need to support two quite different paths for address generation.

Of course, all of those trade-offs may very well pay off in some contexts that could make good use of 2-reg addressing with smaller or faster code, but the original design which was heavily inspired by the RISC philosophy didn't include it. As Peter points out in the comments, new addressing modes have been subsequently added for some cases, although apparently not a general 2-reg addressing mode for load or store.

Is it a hardware restriction? Or simply just part of the ISA?

There's a bit of a false dichotomy there. Certainly it's not a hardware restriction in the sense that hardware could certainly support this, even when MIPS was designed. It sort of seems to imply that some existing hardware had that restriction and so the MIPS ISA somehow inherited it. I would suspect it was much the other way around: the ISA was defined this way, based on analysis of how likely hardware would be implemented, and then it became a hardware simplification since MIPS hardware doesn't need to support anything outside of what's in the MIPS ISA.


1 E.g., to support store instructions which would need to read from 3 registers.

2 It's certainly worth asking whether such a pseudo-instruction is a good idea or not: it would probably expand to an add of the two registers to a temporary register and then a lw with the result. There is always a danger that this hides "too much" work. Since this partly glosses over the difference between a true load that maps 1:1 to a hardware load, and the version that is doing extra arithmetic behind the covers, it is easy to imagine it might lead to sup-optimal decisions.

Take the classic example of linearly accessing two arrays of equal element size in a loop. With 2-reg addressing, it is natural to write this loop as two 2-reg accesses (each with a different base register and a common offset register). The only "overhead" for the offset maintenance is the single offset increment. This hides the fact that internally there are two hidden adds required to support the addressing mode: it would have simply been better to increment each base directly and not use the offset. Furthermore, once the overhead is clear, you can see that unrolling the loop and using immediate offsets can further reduce the overhead.

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    li with small constants is only one instructions, same for lw with small offsets. lw is the regular load-word machine instruction. I think some MIPS assemblers have a no-pseudo mode which you could use if you want to make sure you didn't unintentionally use multiple instructions. – Peter Cordes Oct 23 '17 at 1:04
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    But anyway, I was thinking about the register-read port argument as a good explanation for why MIPS still doesn't have indexed integer load/store. There's plenty of coding space left, and MIPS Release 6 re-assigned some opcodes to make room for new instructions (e.g. branches without a branch-delay slot)! So it's not at all like x86 as far as coding-space and backwards-compat Flipping through the instruction-set reference manual (searching for index) was interesting. (And ports explains why it has indexed FP load/store, because that's the other register file.) – Peter Cordes Oct 23 '17 at 1:09
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    @PeterCordes - yes, good point about today's reasons. A lot of the other costs reduce with time, but the cost of adding an extra read-port is still potentially prohibitive, since it can be a large part of the area of simple chips, it is inherently part of most of the important critical paths and can limit the cycle time, and can have effects on things like the renamer (if a chip is fancy enough to use one). I added a way-too-long footnote about whether a pseudo-instruction would have been a good idea. – BeeOnRope Oct 23 '17 at 1:24
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    ... the logic of which isn't really consistent with some existing pseudo-instructions like div and rem which definitely hide stuff that might waste effort (e.g., if you needed both of those you are much better writing it yourself and saving a div). Actually div answers a question I had above: they apparently did have pseudo-instructions with the same mnemonic that were either "pseudo" or "real" depending on, for example, the number of args. Interesting. Too sneaky for my liking though. – BeeOnRope Oct 23 '17 at 1:30
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    I'm not a fan of MIPS pseudo-instructions. If you have an architectural register "intended" for use as a hidden temporary, you may have too many registers... (Although honestly it's an interesting design to have a couple architectural registers that the kernel is allowed to asynchronously clobber for fast interrupts handlers, including TLB-miss handlers. It means that interrupt handling can be architecturally simpler; IDK how it works, but maybe it puts the old PC in one of those registers.) – Peter Cordes Oct 23 '17 at 1:37

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