For example :


Can I do x = x/2*2; ? Is there a risk that the compiler will optimize away such expression ?

  • Optimizations aren't allowed to change the results of a well-defined operation. – Barmar Oct 24 '17 at 18:44
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    Strongly suggest using: x >>= 1; x <<= 1; – user3629249 Oct 24 '17 at 22:12
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    @user3629249 Why strongly suggest it? It less clearly expresses the intent than the code already in the question, it compiles to identical machine code so it's not any faster, and there's no analogue if you want to round to the nearest multiple of a different number than 2 (unless that number also happens to be a power of 2). – Arthur Tacca Oct 25 '17 at 7:36
  • because it is faster, no multiply and divide. a MUCH easier way is to simply use: x &= ~(1)' Where the 1` could be a string of 1s of the desired length. For instance: x &= ~(0x07); for three bits, etc – user3629249 Oct 26 '17 at 2:12
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    if both methods are resulting in the same machine instructions, they you must have the optimization set to the max. – user3629249 Oct 26 '17 at 2:13

The compiler is allowed to make any optimisiations it likes so long as it does not introduce any side effects into the program. In your case it can't cancel the '2's as then the expression will have a different value for odd numbers.

x / 2 * 2 is evaluated strictly as (x / 2) * 2, and x / 2 is performed in integer arithmetic if x is an integral type.

This, in fact, is an idiomatic rounding technique.

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    I like the note about this being idiomatic. It's also somewhat more intuitive than a mask IMO. – StoryTeller Oct 18 '17 at 7:54
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    Of course, the compiler is allowed to properly optimize this, e.g. by replacing it with (x>>1)<<1. IIRC, there are compilers which will do this even if optimizations are technically turned off. – MSalters Oct 18 '17 at 8:05
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    @MSalters: Yes it was a silly thing to say. I've amended. – Bathsheba Oct 18 '17 at 8:07
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    @MSalters: Or, in the case of unsigned (x & 0xfffffffe) :) – Matthieu M. Oct 18 '17 at 12:41
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    @Voo: Why? It's an unsigned integer. The behavior is identical by definition. – MSalters Oct 20 '17 at 7:06

Since you specified the integers are unsigned, you can do it with a simple mask:

x & (~1u)

Which will set the LSB to zero, thus producing the immediate even number that is no larger than x. That is, if x has a type that is no wider than an unsigned int.

You can of course force the 1 to be of the same type as a wider x, like this:

x & ~((x & 1u) | 1u)

But at this point, you really ought to look at this approach as an exercise in obfuscation, and accept Bathsheba's answer.

I of course forgot about the standard library. If you include stdint.h (or cstdint, as you should in C++ code). You can let the implementation take care of the details:

uintmax_t const lsb = 1;
x & ~lsb;


x & ~UINTMAX_C(1)
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    Don't you need x & (~static_cast<decltype(x)>(1)) or do I need a coffee? – Bathsheba Oct 18 '17 at 7:54
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    @Bathsheba - It's most definitely I who needs a coffee, than. Mmm... I didn't give it much though about working with any unsigned integer type. – StoryTeller Oct 18 '17 at 7:58
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    @Bathsheba - I would, but that C tag... I kinda want to think about it, and be all cool by producing a solution that works in both C and C++. – StoryTeller Oct 18 '17 at 8:00
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    @Bathsheba - But only up to UINT_MAX, no? Wer'e still in the same boat if x is unsigned long, I think. – StoryTeller Oct 18 '17 at 8:03
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    I'm afraid x & (~1u) does not work if the type of x is larger than unsigned int. Conversely, x & ~1 would behave as expected for all types. This is a counter-intuitive pitfall. If you insist on using an unsigned constant, you must write x & ~(uintmax_t)1 as even x & ~1ULL would fail if x has a larger type than unsigned long long. To make matters worse, many platforms now have larger integer types than uintmax_t, such as __uint128_t. – chqrlie Oct 18 '17 at 9:31

C and C++ generally use the "as if" rule in optimization. The computation result must be as if the compiler didn't optimize your code.

In this case, 9/2*2=8. The compiler may use any method to achieve the result 8. This includes bitmasks, bit shifts, or any CPU-specific hack that produces the same results (x86 has quite a few tricks that rely on the fact that it doesn't differentiate between pointers and integers, unlike C and C++).

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    Case and point. This is what GCC produces with -O1. All the approaches are distilled to the same machine code. – StoryTeller Oct 18 '17 at 8:37
  • And as I suspected, for all 3 variants GCC will use the and RAX, -2 method even on -O0. – MSalters Oct 18 '17 at 8:41
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    GCC is highly unusual in that it applies these sorts of mathematical/bit-twiddling peephole optimizations even when optimizations are disabled. That's kind of an interesting and notable design quirk. Other compilers perform a much more literal translation of the C code into machine instructions with optimization disabled, but once you enable the optimizer, the output is all the same, which is why you should write the code for readability unless you know for sure that your compiler is brain-dead. – Cody Gray Oct 18 '17 at 11:45
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    Transforming a division to a shift is a standard optimization technique known as "strength reduction". Yes, it's very standard, and extremely straightforward, but I disagree that makes it not an optimization. @supercat – Cody Gray Oct 18 '17 at 16:27
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    @supercat: I mostly agree with Cody Gray here. It's not so much the strength reduction; it's the fact that GCC does not generate code for individual expressions. x/2*2 compiles to a single statement. In general, compiling without optimizations is done for debugging purposes, and then you want a 1:N correspondence between source code and assembly. – MSalters Oct 19 '17 at 7:13

You can write x / 2 * 2 and the compiler will produce very efficient code to clear the least significant bit if x has an unsigned type.

Conversely, you could write:

x = x & ~1;

Or probably less readably:

x = x & -2;

Or even

x = (x >> 1) << 1;

Or this too:

x = x - (x & 1);

Or this last one, suggested by supercat, that works for positive values of all integer types and representations:

x = (x | 1) ^ 1;

All of the above proposals work correctly for all unsigned integer types on 2's complement architectures. Whether the compiler will produce optimal code is a question of configuration and quality of implementation.

Note however that x & (~1u) does not work if the type of x is larger than unsigned int. This is a counter-intuitive pitfall. If you insist on using an unsigned constant, you must write x & ~(uintmax_t)1 as even x & ~1ULL would fail if x has a larger type than unsigned long long. To make matters worse, many platforms now have integer types larger than uintmax_t, such as __uint128_t.

Here is a little benchmark:

typedef unsigned int T;

T test1(T x) {
    return x / 2 * 2;

T test2(T x) {
    return x & ~1;

T test3(T x) {
    return x & -2;

T test4(T x) {
    return (x >> 1) << 1;

T test5(T x) {
    return x - (x & 1);

T test6(T x) {  // suggested by supercat
    return (x | 1) ^ 1;

T test7(T x) {  // suggested by Mehrdad
    return ~(~x | 1);

T test1u(T x) {
    return x & ~1u;

As suggested by Ruslan, testing on Godbolt's Compiler Explorer shows that for all the above alternatives gcc -O1 produces the same exact code for unsigned int, but changing the type T to unsigned long long shows differing code for test1u.

  • Here's an example of what GCC does with x/2*2 for unsigned x: – Ruslan Oct 18 '17 at 12:49
  • @Ruslan: Thanks for your comment, gcc indeed produces the same code for all proposed alternatives. – chqrlie Oct 18 '17 at 14:05
  • x = (x | 1) ^ 1 doesn't work for one's complement – M.M Oct 18 '17 at 20:20
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    @M.M: How so? 1 is positive, and always is represented as 00...01. |1 sets the LSB. ^1 toggles that same bit. One's complement affects the value of the MSB c.q. the value of INT_MIN but we're not touching the MSB. IOW, number representations start to matter when you mix arithmetic and numerical operations, and we don't do that. (But the question leaves open how to round negative numbers, round down or round to zero) – MSalters Oct 19 '17 at 7:18
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    What good is a puzzle of bit manipulation without everyone's favorite, modulo! x = x - (x%2)? This has the advantage of scaling to any n where roundToMultiple(int x, int n) { return x - (x % n); } – corsiKa Oct 20 '17 at 3:44

If your values are of any unsigned type as you say, the easiest is

x & -2;

The wonders of unsigned arithmetic make it that -2 is converted to the type of x, and has a bit pattern that has all ones, but for the least significant bit which is 0.

In contrary to some of the other proposed solutions, this should work with any unsigned integer type that is at least as wide as unsigned. (And you shouldn't do arithmetic with narrower types, anyhow.)

Extra bonus, as remarked by supercat, this only uses conversion of a signed type to an unsigned type. This is well-defined by the standard as being modulo arithmetic. So the result is always UTYPE_MAX-1 for UTYPE the unsigned type of x. In particular, it is independent of the sign representation of the platform for signed types.

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    It may be worth noting, just to preempt any confusion, that converting -2 to "unsigned" will yield the "unsigned value" which, when added to 2, will yield 0, regardless of whether a system uses two's-complement signed math. By contrast, if one had a ones`-complement system, ~1 would equal -1, which when converted to unsigned would yield a value with all bits set. – supercat Oct 18 '17 at 16:15
  • @supercat, thanks, yes exactly. I tried to integrate these ideas in my answer. – Jens Gustedt Oct 19 '17 at 8:28
  • To make this safe for unsigned types smaller than unsigned int you can use (1u * x) & -2 – plugwash Oct 19 '17 at 17:37

One option that I'm surprised hasn't been mentioned so far is to use the modulo operator. I would argue this represents your intent at least as well as your original snippet, and perhaps even better.

x = x - x % 2

As others have said, the compiler's optimiser will deal with any reasonable expression equivalently, so worry about what's clearer rather than what you think is fastest. All the bit-tweaking answers are interesting, but you should definitely not use any of them in place of arithmetic operators (assuming the motivation is arithmetic rather than bit tweaking).

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    Yes, compiler's optimizers are smart enough: – Bob__ Oct 19 '17 at 13:04
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    While the OP did specify unsigned, it should be noted that the above produces possibly surprising results when you feed it a signed integer. – Yakk - Adam Nevraumont Oct 19 '17 at 13:51
  • @Yakk In C, modulo is defined to be x % d = x - x / d * d, so my snippet is guaranteed to give identical results to the x = x/2*2 mentioned in the question. Assuming it's x you're worried about being negative (rather than a negative replacement for 2), this gives what OP probably wants: if x=-7 then x/2*2 == x - x%2 == -6. – Arthur Tacca Oct 19 '17 at 14:44
  • But the fact that you had that worry, and I wasn't sure until I checked it, does throw out my argument about it being easier to read (in the case of negative numbers). – Arthur Tacca Oct 19 '17 at 14:45
  • @ArthurTacca I'd argue even the OP's x/2*2 is also surprising with negative integers. So not sure how to avoid having code that behaves surprising to someone with negative integers! – Yakk - Adam Nevraumont Oct 19 '17 at 14:56

just use following:

template<class T>
inline T f(T v)
    return v & (~static_cast<T>(1));

Do not afraid that this is function, compiler should finally optimize this into just v & (~1) with appropriate type of 1.

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