Is there is a standard or recommendation for how the addi instruction (and others) should be interpreted in assembly, when hexadecimal immediate values are used?


addi $t0, $zero, 0xffff

I was expecting this to mean the same as addi $t0, $zero, -1 where 0xffff would be sign extended to 0xffffffff, as is done by the processor, but was surprised by the fact that the assembler of the Mars simulator interprets hexadecimals as 32bit unsigned numbers and tries to do addi $t0, $zero, 0x0000ffff as a pseudo-instruction (if pseudo-instructions are enabled).

To be clear, MARS's assembler assembles that addi $t0, $zero, 0xffff pseudo-instruction to multiple machine instructions which create that constant (65535 = 0xffff) in a register and then add it, if pseudo-instructions are enabled. MARS's simulator simulates instructions like 0x2008ffff (addi $t0, $zero, -1) correctly.

The SPIM assembler just aborts with an error.

What I would like to know is if assemblers always interpret this way, and if there is someplace where this is written or explained as I could not find anything.

  • 1
    Assemblers usually interpret hexadecimal immediates as unsigned constants.
    – gusbro
    May 11, 2016 at 13:58
  • This is why there is a subi instruction.
    – markgz
    May 11, 2016 at 16:55
  • @markgz There is no subi instruction in MIPS.
    – Miguel
    May 11, 2016 at 23:55
  • Whoops! My memory failed on that one.
    – markgz
    May 12, 2016 at 21:34
  • 2
    @ChrisDodd: That's not a bug. 0xffff is not representable as a 16-bit sign-extended integer, and asm source normally uses full 32-bit constants like -1, not just the bit-pattern for the immediate. What's surprising to me is that clang -target mips assembles it to 0x2008ffff (i.e. addi $t0, $zero, -1) without even a warning about the value not fitting in an immediate, like NASM does for add rcx, 0xffffffff, the equivalent situation for x86-64 with 64-bit add of a 32-bit immediate. : warning: signed dword value exceeds bounds [-w+number-overflow] Aug 1, 2019 at 2:28


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