I'm having a heck of a time trying to come up with a constant time rotate that does not violate the C/C++ standards.

The problem is the edge/corner cases, where operations are called out in algorithms and those algorithms cannot be changed. For example, the following is from Crypto++ and executes the test harness under GCC ubsan (i.e., g++ fsanitize=undefined):

$ ./cryptest.exe v | grep runtime
misc.h:637:22: runtime error: shift exponent 32 is too large for 32-bit type 'unsigned int'
misc.h:643:22: runtime error: shift exponent 32 is too large for 32-bit type 'unsigned int'
misc.h:625:22: runtime error: shift exponent 32 is too large for 32-bit type 'unsigned int'
misc.h:637:22: runtime error: shift exponent 32 is too large for 32-bit type 'unsigned int'
misc.h:643:22: runtime error: shift exponent 32 is too large for 32-bit type 'unsigned int'
misc.h:637:22: runtime error: shift exponent 32 is too large for 32-bit type 'unsigned int'

And the code at misc.h:637:

template <class T> inline T rotlMod(T x, unsigned int y)
    y %= sizeof(T)*8;
    return T((x<<y) | (x>>(sizeof(T)*8-y)));

Intel's ICC was particularly ruthless, and it removed the entire function call with out the y %= sizeof(T)*8. We fixed that a few years back, but left the other errata in-place due to lack of a constant time solution.

There's one pain point remaining. When y = 0, I get a condition where 32 - y = 32, and it sets up the undefined behavior. If I add a check for if(y == 0) ..., then the code fails to meet the constant time requirement.

I've looked at a number of other implementations, from the Linux kernel to other cryptographic libraries. They all contain the same undefined behavior, so it appears to be a dead end.

How can I perform the rotate in nearly constant time with a minimum number of instructions?

EDIT: by near constant time, I mean avoid the branch so the same instructions are always executed. I'm not worried about CPU microcode timings. While branch prediction may be great on x86/x64, it may not perform as well on other platforms, like embedded.

None of these tricks would be required if GCC or Clang provided an intrinsic to perform the rotate in near constant time. I'd even settle for "perform the rotate" since they don't even have that.

  • 3
    Check your processor's assembly language. Most processors have rotate and shift operations that perform in constant time. Worst case, use these in inline assembly. Jul 13, 2015 at 15:50
  • 1
    @Thomas - that's exactly where I have arrived. The one pain point there is, GCC does not have a pseudo instruction that says, "Give me a register of your [GCC] choosing" so I minimally disrupt the optimizer. And I also like to think folks smarter than me have a solution.
    – jww
    Jul 13, 2015 at 15:59
  • Check the assembly language listing generated by the compiler. If the compiler is smart enough to recognize the pattern, it will use the assembly language rotate instruction. If you really need the speed, use assembly language. Jul 13, 2015 at 16:01
  • 1
    Mightn't hurt to define "constant time rotate". You have substantially failed to "put yourself in our shoes" while writing this question. Jul 13, 2015 at 16:04
  • 2
    For the record, GCC does have a way of specifying "give me a register of your choosing" by using the r constraint for the value and then referring to the value by %0 or similar. Jul 13, 2015 at 16:46

4 Answers 4


I've linked to this answer for the full details from several other "rotate" questions, including this community wiki question, which should be kept up to date with best-practices.

I found a blog post about this issue, and it looks like it's finally a solved problem (with new-enough compiler versions).

John Regehr at the University of Utah recommends version "c" of his attempts at making a rotate function. I replaced his assert with a bitwise AND, and found that it still compiles to a single rotate insn.

typedef uint32_t rotwidth_t;  // parameterize for comparing compiler output with various sizes

rotwidth_t rotl (rotwidth_t x, unsigned int n)
  const unsigned int mask = (CHAR_BIT*sizeof(x)-1);  // e.g. 31

  assert ( (n<=mask)  &&"rotate by type width or more");
  n &= mask;  // avoid undef behaviour with NDEBUG.  0 overhead for most types / compilers
  return (x<<n) | (x>>( (-n)&mask ));

rotwidth_t rot_const(rotwidth_t x)
  return rotl(x, 7);

This could be templated on x's type, but it probably makes more sense for real use, to have the width in the function name (like rotl32). Usually when you're rotating, you know what width you want, and that matters more than what size variable you're currently storing the value in.

Also make sure to only use this with unsigned types. Right-shift of signed types does an arithmetic shift, shifting in sign-bits. (It's technically implementation-dependent behaviour, but everything uses 2's complement now.)

Pabigot independently came up with the same idea before I did, and posted it at gibhub. His version has C++ static_assert checking to make it a compile-time error to use a rotate count outside the range for the type.

I tested mine with gcc.godbolt.org, with NDEBUG defined, for variable and compile-time-const rotate counts:

  • gcc: optimal code with gcc >= 4.9.0, non-branching neg+shifts+or with earlier.
    (compile-time const count: gcc 4.4.7 is fine)
  • clang: optimal code with clang >= 3.5.0, non-branching neg+shifts+or with earlier.
    (compile-time const rotate count: clang 3.0 is fine)
  • icc 13: optimal code.
    (compile-time const count with -march=native: generates slower shld $7, %edi, %edi. Fine without -march=native)

Even newer compiler versions can handle the commonly-given code from wikipedia (included in the godbolt sample) without generating a branch or cmov. John Regehr's version has the advantage of avoiding undefined behaviour when the rotate count is 0.

There are some caveats with 8 and 16 bit rotates, but compilers seem fine with 32 or 64, when n is uint32_t. See the comments in the code on the godbolt link for some notes from my testing various widths of uint*_t. Hopefully this idiom will be better-recognized by all compilers for more combinations of type widths in the future. Sometimes gcc will uselessly emit an AND insn on the rotate count, even though the x86 ISA defines the rotate insns with that exact AND as the first step.

"optimal" means as efficient as:

# gcc 4.9.2 rotl(unsigned int, unsigned int):
    movl    %edi, %eax
    movl    %esi, %ecx
    roll    %cl, %eax
# rot_const(unsigned int):
    movl    %edi, %eax
    roll    $7, %eax

When inlined, the compiler should be able to arrange for values to be in the right registers in the first place, resulting in just a single rotate.

With older compilers, you'll still get ideal code when the rotate count is a compile-time constant. Godbolt lets you test with ARM as a target, and it used a rotate there, too. With variable counts on older compilers, you get a bit of code bloat, but no branches or major performance problems, so this idiom should be safe to use in general.

BTW, I modified John Regehr's original to use CHAR_BIT*sizeof(x), and gcc / clang / icc emit optimal code for uint64_t as well. However, I did notice that changing x to uint64_t while the function return type is still uint32_t makes gcc compile it to shifts/or. So be careful to cast the result to 32bits in a separate sequence point, if you want the low 32b of a 64b rotate. i.e. Assign the result to a 64bit variable, then cast/return it. icc still generates a rotate insn, but gcc and clang don't, for

// generates slow code: cast separately.
uint32_t r = (uint32_t)( (x<<n) | (x>>( -n&(CHAR_BIT*sizeof(x)-1) )) );

If anyone can test this with MSVC, it would be useful to know what happens there.

  • Thank you very much. I know John from his (and Peng Li's) Integer Overflow Checker (long before Clang had sanitizers). I used to use it extensively when self test would fail after compiling with Intel's ICC. ICC was ruthless about removing this sort of undefined behavior.
    – jww
    Jul 18, 2015 at 23:15
  • Although x86 presently defines their shift operators as masking the size, that was a behavioral change in the 80386 [IMHO not a good one]. On earlier processors, shifting was done mod 256 (since the shift amount was specified using a byte register); on processors like the ARM where shifts of 32-255 bits are equivalent to (but faster than) a series of one-bit shifts, such semantics can be useful in graphics programming (e.g. row1 |= dat >> y; row2 |= dat >> (y-32). In any case, on a vintage 8086 or 80286, the behavior of shift instructions uses the whole value of CL.
    – supercat
    Jul 20, 2015 at 15:49
  • So you'd get zero from a shift count higher than register width? Intel's vector shifts do work this way. Masking (rather than saturating) the count makes sense for a rotate, but it does seem silly for shifts. Jul 20, 2015 at 16:05
  • @PeterCordes: On the 8086, the shift count is specified in an 8-bit register. Consequently, even if Intel had included the hardware to saturate shifts of length (regsize) up to 255, shifts that are slightly larger than multiples of 256 would have their lengths masked. That having been said, there would have been considerable value in having shifts with lengths up to 255 behave in saturating fashion; the value of extending that to longer shifts would be much less. BTW, the rotate-through-carry instructions were much slower on the 80836 than the other shifts (extra cycles proportional to N)...
    – supercat
    Jul 23, 2015 at 16:20
  • ...and I suspect Intel wanted to avoid having an instruction take too long if N was 255. On the other hand, the behavior of shifting a 32-bit register right through carry by 32 or 33 bits would be different from shifting right by any smaller amount (including zero or one), and so masking yields totally wrong semantics. Interestingly, the ARM allows shift-by-N and 32-bit rotate-by-N, but only allows 32+1-bit rotate through carry to be done one bit at a time.
    – supercat
    Jul 23, 2015 at 16:28

You can add one additional modulo operation to prevent the shifting by 32 bits, but I'm not convinced this is faster than using an if check in conjunction with branch predictors.

template <class T> inline T rotlMod(T x, unsigned int y)
    y %= sizeof(T)*8;
    return T((x<<y) | (x>>((sizeof(T)*8-y) % (sizeof(T)*8))));
  • 4
    This is where I believe a simple inline assembly instruction would be easier to read. :-) Jul 13, 2015 at 16:03
  • 2
    Yeah but portability! Jul 13, 2015 at 16:05
  • I'm not 100% sure if it's well-defined, but I think you can simplify that to -y % (sizeof(T)*8). It seems to be better optimized by clang++ and g++
    – dyp
    Jul 13, 2015 at 16:18
  • "... in conjunction with branch predictors..." - I think that assumes the branch predictors work as {expected|desired}. That may not be the case on low end processors and boards. Plus, the guys advancing these attacks are very clever, so I want to avoid giving them a toehold.
    – jww
    Jul 13, 2015 at 16:25
  • 2
    Just for readability I'd store sizeof(T)*8 in a local variable.
    – MikeMB
    Jul 13, 2015 at 16:25

Writing the expression as T((x<<y) | ((x>>(sizeof(T)*CHAR_BITS-y-1)>>1)) should yield defined behavior for all values of y below the bit size, assuming that T is an unsigned type with no padding. Unless the compiler has a good optimizer, the resulting code may not be as good as what would have been produced by your original expression. Having to put up with clunky hard to read code which will yield slower execution on many compilers is part of the price of progress, however, since a hyper-modern compiler which is given

if (y) do_something();
return T((x<<y) | (x>>(sizeof(T)*8-y)));

might improve the "efficiency" of the code by making the call to do_something unconditional.

PS: I wonder if there are any real-world platforms where changing the definition of shift-right so that x >> y when y is precisely equal to the bit size of x, would be required to yield either 0 or x, but could make the choice in an arbitrary (unspecified) fashion, would require the platform to generate extra code or would preclude genuinely useful optimizations in non-contrived scenarios?


An alternative to the extra modulo is to multiply by 0 or 1 (thanks to !!):

template <class T> T rotlMod(T x, unsigned int y)
    y %= sizeof(T) * 8;
    return T((x << y) | (x >> ((!!y) * (sizeof(T) * 8 - y)));
  • 1
    Are you sure that the !! doesn't force the compiler to generate a branch?
    – Mark B
    Jul 20, 2015 at 15:55
  • @MarkB: You're right, this unfortunately generates terrible asm even on gcc 5.2 and clang 3.7. goo.gl/wJBthc (godbolt). Also, templating a rotate function seems like a terrible idea unless you just use it as a building block for named wrappers, like rotl32. If you want 32bit rotate, you don't want to accidentally do a 64bit rotate because of the size of your temporary. Aug 17, 2015 at 20:40

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