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Consider this simple function which adds a constant:

unsigned char f(unsigned char x) {
    return x + 5;
}

This generates the following assembly (with -O3 on gcc 4.7.2):

leal    5(%rdi), %eax
ret

Now since unsigned overflow is well-defined behavior in C, one would assume that adding a modulo operation should be essentially a nop:

unsigned char f(unsigned char x) {
    return (x + 5) % 256; // assume char is 8-bits, which is typical
}

But the assembly generated has an extra instruction:

leal    5(%rdi), %eax
movzbl  %al, %eax
ret

Can someone enlighten me why this is so? I'm not very familiar with assembly though.

(Note: This is just a toy problem that I made to understand how GCC optimizes code.)

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ICC does it too, Clang has the movzbl in either case. –  harold Jul 1 '13 at 16:40

1 Answer 1

up vote 4 down vote accepted

For a definite answer to 'why the generated code is different', you probably need an engineer with intimate knowledge of the details of this gcc compiler. You may want to experiment more with a couple more examples as below:

unsigned char f1(unsigned char x) { return x + 5; }
unsigned char f2(unsigned char x) { return (x + 5) % 256; }
unsigned char f3(unsigned char x) { return (x + 5) % 256U; }
unsigned char f4(unsigned char x) { return (x + 5) & 0xFFU; }

With gcc version 4.1.2 suitable for 64 bit systems, I get the same code for all these functions both for 64 bit as 32 bit code. Which actually all include the movzbl. Which might be a bug in gcc compiling f1 (and likely corrected at the caller side). It really depends on the calling conventions: whether an 8 bit value in a 64 bit register should be zero/sign extended or not. I couldn't find a conclusive answer to this in the Draft Version 0.96 of the System V Application Binary Interface, AMD64 Architecture Processor Supplement of June 14, 2005. The gcc compiler 4.1.2 seems to adopt the philosophy of 'better safe than sorry' as the movzbl also occurs on the caller side. In my experience one normally requires such values to be zero/sign extended unless one has operations operating on parts of a register, which is quite unusual.

Interestingly my home compiler gcc version 4.3.2 does make a small difference in that f2 is implemented through an and operation. All the others just add 5, strongly suggesting that it is the callers responsibility to perform zero/sign extension, which it indeed does. But this is 32 bit code.

If I find a conclusive answer on the zero/sign extension of values in oversized registers in any of the architecture specifications, then I'll let you know. I happen to need to know this professionally too.

In defense of your gcc compiler. You are looking at small beer optimizations. Normal code does not contain such a modulo and it is nice if the compiler somewhere down the line will reduce such a special modulo to an and. In case of the %256 (vs %256U) some value range analysis is required to determine that an and suffices, because the modulo is done in 'signed' arithmetic. Clearly my compiler does conclude at some point that the and suffices, but apparently too late to determine that it then is subsumed by the typing of the result, which it did determine in the other cases. This is what we compiler engineers call the 'phase ordering problem'.

Update on zero/sign extension of values in registers.

I've abandoned the quest for now and will have to continue with some colleagues as I've not found a conclusive statement if parameters/functions results are expected to be zero/sign extended.

I did find the following relating to this in the above mentioned ABI specification.

Booleans, when stored in a memory object, are stored as single byte objects the value of which is always 0 (false) or 1 (true). When stored in integer registers or passed as arguments on the stack, all 8 bytes of the register are significant; any nonzero value is considered true.

So boolean types have to be zero extended.

For calls that may call functions that use varargs or stdargs (prototype-less calls or calls to functions containing ellipsis (. . . ) in the declaration) %al (Note 14) is used as hidden argument to specify the number of SSE registers used. The contents of %al do not need to match exactly the number of registers, but must be an upper bound on the number of SSE registers used and is in the range 0–8 inclusive.

Note 14: Note that the rest of %rax is undefined, only the contents of %al is defined.

So for this special use of %al it need not be extended.

Considering that booleans have to be zero extended one may conclude that the spirit of the ABI is that other sub-word types should also be extended. Taking a more formal stance one can argue that the absence of any statement should be interpreted as no zero/sign extension is required. All in all, not satisfactory.

Update 2 on zero/sign extension of values in registers.

I've discussed the issue with a colleague. The newest version of the ABI from 2012 version 0.99 has been changed exactly on the parameter passing of booleans in that these are only zero extended to 8 bits. That suggest that this has been modified to be in line with passing other sub-word types as all being not zero/sign extended. The AMD64 architecture also supports sub-word registers for half of the 64 bit registers and can do operations on these sub-word registers. That is probably the motivation not to pass parameters in a zero/sign extended fashion.

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It's worthwhile to note that C11 no longer allows intvar = intval % 256; to be optimized using a simple "AND" instruction but instead requires that compilers favor the almost-never-useful identity (-n) % 256 == -(n % 256) rather than (n+256) % 256 == n % 256. If one wants optimized behavior, one must cast to unsigned first. –  supercat Jul 1 '13 at 17:51
    
@Bryan: Since my post got downvoted, I've taken it down - so you may want to edit your post in reflection to that... I thought my answer was pretty decent, but as there wasn't a comment to say why, I don't know what was wrong with it. –  Mats Petersson Jul 1 '13 at 18:10
    
@supercat Probably due to a lack of mathematical education in computer science. As far as I know this has however been standing practice for a long time in C. –  Bryan Olivier Jul 1 '13 at 18:10
    
@MatsPetersson Will do. A totally unjust downvote if you'd ask me. –  Bryan Olivier Jul 1 '13 at 18:12
2  
@PascalCuoq: Having integers divide toward negative infinity would facilitate some types of code, and most processors' divide instructions are so horribly slow that cleanup code wouldn't affect things much. Further, a lot of embedded devices have some hardware to facilitate unsigned division, but not necessarily signed division. –  supercat Jul 1 '13 at 22:23

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