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The C standard is quite unclear about the uint_fast*_t family of types. On a gcc-4.4.4 linux x86_64 system, the types uint_fast16_t and uint_fast32_t are both 8 bytes in size. However, multiplication of 8-byte numbers seems to be fairly slower than multiplication of 4-byte numbers. The following piece of code demonstrates that:

#include <stdio.h>
#include <stdint.h>
#include <inttypes.h>

main ()
  uint_least16_t p, x;
  int count;

  p = 1;
  for (count = 100000; count != 0; --count)
    for (x = 1; x != 50000; ++x)
      p*= x;

  printf("%"PRIuLEAST16, p);
  return 0;

Running the time command on the program, I get

real 0m7.606s
user 0m7.557s
sys  0m0.019s

If I change the type to uint_fast16_t (and the printf modifier), the timing becomes

real 0m12.609s
user 0m12.593s
sys  0m0.009s

So, would it not be much better if the stdint.h header defined uint_fast16_t (and also uint_fast32_t) to be a 4-byte type?

share|improve this question
Just a tiny tip: You don't need to include both, stdint.h and inttypes.h; according to ISO C standard, inttypes.h must always include stdint.h, so including it first is just a waste of time (not that it is forbidden or incorrect, just unnecessary). – Mecki Aug 28 '12 at 10:42

I think that such a design decision is not simple to take. It depends on many factors. For the moment I don't take your experiment as conclusive, see below.

First of all there is no such thing like one single concept of what fast should mean. Here you emphasized on multiplication in place, which is just one particular point of view.

Then x86_64 is an architecture and not a processor. So outcomes might be quite different for different processors in that family. I don't think that it would be sane that gcc would have the type decision depend on particular commandline switches that optimize for a given processor.

Now to come back to your example. I guess you have also looked at the assembler code? Did it e.g use SSE instructions to realize your code? Did you switch processor specific options on, something like -march=native?

Edit: I experimented a bit with your test program and if I leave it exactly as it is I can basically reproduce your measurements. But modifying and playing around with it I am even less convinced that it is conclusive.

E.g if I change the inner loop also to go downward, the assembler looks almost the same as before (but using decrement and a test against 0) but the execution takes about 50% more. So I guess the timing depends very much on the environment of the instruction that you want to benchmark, pipeline stalls, whatever. You'd have to bench codes of very different nature where the instructions are issued in different contexts, alignment problems and vectorization come to play, to make a decision what the appropriate types for the fast typedefs are.

share|improve this answer
"I don't think that it would be sane that gcc would have the type decision depend on particular commandline switches that optimize for a given processor." As R. says, that's an ABI question. If the compiler says that the ABI is independent of those switches, and the ABI specifies the sizes of those typedefs, then of course it can't vary. Whether it's sane to use the fast types in a library interface is also questionable, I think ;-) – Steve Jessop Nov 7 '10 at 11:03
@Steve, I completely agree. My point was just that for a given ABI that applies eventually to a whole family of processors, you can't deduce much for the validity of a particular choice by doing just one test, with one type of instruction, on one particular processor and with one particular compiler. – Jens Gustedt Nov 7 '10 at 11:24
@Jens: yes, I didn't intend to disagree, just add that varying those types by compiler options isn't just "insane" or user-unfriendly in a vague sense, there's a specific issue with call compatibility. – Steve Jessop Nov 7 '10 at 11:44
@Steve, right, I see. – Jens Gustedt Nov 7 '10 at 12:32
@Jens: On x86_64, 32-bit arithmetic should never be slower than 64-bit arithmetic, period. Even if they're the same speed, the smallest of the 2 types that can hold the value should be chosen. [u]intfast*_t are just wrong. – R.. Nov 7 '10 at 13:15

AFAIK compilers only define their own versions of (u)int_(fast/least)XX_t types if these are not already defined by the system. That is because it is very important that these types are equally defined across all libraries/binaries on a single system. Otherwise, if different compilers would define those types differently, a library built with CompilerA may have a different uint_fast32_t type than a binary built with CompilerB, yet this binary may still link against the library; there is no formal standard requirement that all executable code of a system has to be built by the same compiler (actually on some systems, e.g. Windows, it is rather common that code has been compiled by all kind of different compilers). If now this binary calls a function of the library, things will break!

So the question is: Is it really GCC defining uint_fast16_t here, or is it actually Linux (I mean the kernel here) or maybe even the Standard C Lib (glibc in most cases), that defines those types? Since if Linux or glibc defines these, GCC built on that system has no choice other than to adopt whatever conventions these have established. Same is true for all other variable width types, too: char, short, int, long, long long; all these types have only a minimum guaranteed bit width in the C Standard (and for int it is actually 16 bit, so on platforms where int is 32 bit, it is already much bigger than would be required by the standard).

Other than that, I actually wonder what is wrong with your CPU/compiler/system. On my system 64 bit multiplication is equally fast to 32 bit multiplication. I modified your code to test 16, 32, and 64 bit:

#include <time.h>
#include <stdio.h>
#include <inttypes.h>

#define RUNS 100000

#define TEST(type)                                  \
    static type test ## type ()                     \
    {                                               \
        int count;                                  \
        type p, x;                                  \
        p = 1;                                      \
        for (count = RUNS; count != 0; count--) {   \
            for (x = 1; x != 50000; x++) {          \
                p *= x;                             \
            }                                       \
        }                                           \
        return p;                                   \


#define CLOCK_TO_SEC(clock) ((double)clockTime / CLOCKS_PER_SEC)

#define RUN_TEST(type)                             \
    {                                              \
        clock_t clockTime;                         \
        unsigned long long result;                 \
        clockTime = clock();                       \
        result = test ## type ();                  \
        clockTime = clock() - clockTime;           \
        printf("Test %s took %2.4f s. (%llu)\n",   \
            #type, CLOCK_TO_SEC(clockTime), result \
        );                                         \

int main ()
    return 0;

Using unoptimized code (-O0), I get:

Test uint16_t took 13.6286 s. (0)
Test uint32_t took 12.5881 s. (0)
Test uint64_t took 12.6006 s. (0)

Using optimized code (-O3), I get:

Test uint16_t took 13.6385 s. (0)
Test uint32_t took 4.5455 s. (0)
Test uint64_t took 4.5382 s. (0)

The second output is quite interesting. @R.. wrote in a comment above:

On x86_64, 32-bit arithmetic should never be slower than 64-bit arithmetic, period.

The second output shows that the same thing cannot be said for 32/16 bit arithmetic. 16 bit arithmetic can be significantly slower on a 32/64 bit CPU, even though my x86 CPU can natively perform 16 bit arithmetic; unlike some other CPUs, like a PPC, for example, that can only perform 32 bit arithmetic. However, this only seems to apply to multiplication on my CPU, when changing the code to do addition/subtraction/division, there is no significant difference between 16 and 32 bit any longer.

The results above are from an Intel Core i7 (2.66 GHz), yet if anyone is interested, I can run this benchmark also on an Intel Core 2 Duo (one CPU generation older) and on an Motorola PowerPC G4.

share|improve this answer

Actual performance at runtime is a very very complicated topic. With many factors ranging from Ram memory, hard-disks, OS'es; And the many processor specific quirks. But this will give you a rough run down for you:


  • Optimal size to calculate most (addition and subtraction) operations efficiently for the processor. This is hardware specific, in which 32bit variables is native and faster (and hence used) over 16bit variables. (for example)
  • As it does not benefit as well as N_leastX in terms of cacheline hits, this should be used mainly when only a single variable is needed as fast as possible. While not being in a large array (how large is it optimally to switch between both is sadly platform dependent)
  • Note that fast vs least has several quirks case, mainly multiplication and divisions. That is platform specific. However if most operations are additions / subtrations / or / and. It is generally safe to assume fast is faster. (once again note the CPU cache and other quirk)


  • The smallest variable the hardware will allow, that is at least of the X size. (some platform is unable to assign variables below 4 bytes for example. In fact most of your BOOL variables take up at least a byte, and not a bit)
  • May be calculated via CPU costly software emulation if hardware support does not exists.
  • May have performance penalty due to partial hardware support (as compared to fast) in a single operations basis.
  • HOWEVER : as it takes less variable space, it may hit the cache lines alot more frequently. This is much more prominent in arrays. And as such will be faster (memory cost > CPU cost) See for more details.

The Multiplication problem?

Also to answer why the larger fastX variable would be slower in multiplication. Is cause due to the very nature of multiplication. (being similar to what you were thought in school)

//Assuming 4bit int
   0011 (3 in decimal)
 x 0101 (5 in decimal)
   0011 ("0011 x 0001")
  0000- ("0011 x 0000")
 0011-- ("0011 x 0001")
0000--- ("0011 x 0000")
   1111 (15 in decimal)

However it is important to know that a computer is a "logical idiot". While its obvious to us humans to skip the trailing zeros step. The computer will still work it out (its cheaper then checking conditionally then working it out anyway). Hence this creates a quirk for a larger size variable of the same value

   //Assuming 8bit int
      0000 0011 (3 in decimal)
    x 0000 0101 (5 in decimal)
      0000 0011 ("0011 x 0001")
    0 0000 000- ("0011 x 0000")
   00 0000 11-- ("0011 x 0001")
  000 0000 0--- ("0011 x 0000")
 0000 0000 ---- (And the remainders of zeros)
 -------------- (Will all be worked out)
      0000 1111 (15 in decimal)

While i did not spam out the remainder 0x0 additions in the multiplication process. It is important to note that the computer will "get them done". And hence it is natural that a larger variable multiplication will take longer time then its smaller counterpart. (Hence its always good to avoid multiplication and divisions whenever possible).

However here comes the 2nd quirk. It may not apply to all processors. It is important to note that all CPU operations are counted in CPU cycles. In which in each cycle dozens (or more) of such small additions operations is performed as seen above. As a result, a 8bit addition may take the same amount of time as an 8bit multiplication, and etc. Due to the various optimizations and CPU specific quirks.

If it concerns you that much. Go refer to Intel :

Additional mention about CPU vs RAM

As CPU have advance to moore's law to be several times faster then your DDR3 RAM.

This can result to situations where more time is spent looking up the variable from the ram then to CPU "compute" it. This is most prominent in long pointer chains.

So while a CPU cache exists on most processor to reduce "RAM look-up" time. Its uses is limited to specific cases (where cache line benefits the most). And for cases when it does not fit. Note that the RAM look-up time > CPU processing time (excluding multiplication/divisions/some quirks)

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Just because I was curious about the fast integer types I benchmarked a real-life parser which, in its semantic part, used an integer type for indexing arrays and C++-containers. It performed a mix of operations rather than a simple loop and most of the program did not depend on the integer type chosen. Actually, for my particular data, any integer type would have been fine. So all versions produced the same output.

At assembly level there are 8 cases: four for the sizes and 2 for the signedness. The 24 ISO C type names must be mapped to the eight basic types. As Jens already stated a "good" mapping must consider the particular processor and the particular code. Therefore, in practice, we should not expect perfect results even though the compiler writers should know the generated code.

Many runs of the example were averaged so that the fluctuation range of the run time is just about 2 of the least given digit. For this particular setup the results were:

  • No runtime difference between int16_t / uint16_t and int64_t / uint64_t respectively.
  • Unsigned versions are much faster for int8_t / uint8_t and int32_t / uint32_t respectively.
  • Unsigned versions are always smaller (text and data segment) than signed versions.

Compiler: g++ 4.9.1, Options: -O3 mtune=generic -march=x86-64

CPU: Intel™ Core™ 2 Duo E8400 @ 3.00GHz

The mapping

|    |Integer|                                                                     |
|Sign|Size   | Types                                                               |
|    |[bits] |                                                                     |
| u  |   8   | uint8_t  uint_fast8_t   uint_least8_t                               |
| s  |   8   | int8_t   int_fast8_t    int_least8_t                                |
| u  |  16   | uint16_t uint_least16_t                                             |
| s  |  16   | int16_t  int_least16_t                                              |
| u  |  32   | uint32_t uint_least32_t                                             |
| s  |  32   | int32_t  int_least32_t                                              |
| u  |  64   | uint64_t uint_fast16_t  uint_fast32_t  uint_fast64_t uint_least64_t |
| s  |  64   | int64_t  int_fast16_t   int_fast32_t   int_fast64_t  int_least64_t  |

Sizes and Timings

|      | Integer |         |       |       |         |
| Sign | Size    |  text   |  data |  bss  | Time    |
|      | [bits]  | [bytes] |[bytes]|[bytes]| [ms]    |
|:----:|--------:|--------:| -----:|------:|--------:|
|  u   |    8    | 1285801 |  3024 |  5704 | 407.61  |
|  s   |    8    | 1285929 |  3032 |  5704 | 412.39  |
|  u   |   16    | 1285833 |  3024 |  5704 | 408.81  |
|  s   |   16    | 1286105 |  3040 |  5704 | 408.80  |
|  u   |   32    | 1285609 |  3024 |  5704 | 406.78  |
|  s   |   32    | 1285921 |  3032 |  5704 | 413.30  |
|  u   |   64    | 1285557 |  3032 |  5704 | 410.12  |
|  s   |   64    | 1285824 |  3048 |  5704 | 410.13  |
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Yes, I think this is simply a mistake. Unfortunately you can't just go fixing mistakes like this without breaking the ABI, but it may not matter since virtually nobody (and certainly no library functions I know of) actually uses the *int_fast*_t types.

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If I am not wrong the vorbis library does. Also, everytime gcc upgrades from gcc-x.y.z to gcc-x.y+1.w the ABI may break, so we could make that change at that time. – Luís Fernando Schultz Xavier Nov 7 '10 at 4:17
Does vorbis use these types in the public interface, or just internally? I would hope just the latter. Regardless of gcc policy, there's also an issue of library maintainers' policy. If gcc broke their ABIs, they would be pretty damn pissed, and probably institute workarounds to lock in the old type rather than changing with gcc. – R.. Nov 7 '10 at 5:28
@R. Just out of interest, does the linux x86_64 ABI include the fast types (or for that matter anything from stdint)?. It's a slight worry to me that ABI documents often ignore them and hence (one might argue) it is not safe to pass them as parameters unless you static link. – Steve Jessop Nov 7 '10 at 11:08
@Steve: I think we're working with slightly different meanings of the word ABI. Your question seems to be about published documentation, which I'm not sure about, while my idea of ABI is "any implementation details which affect the ability to link object files produced by different tools (or versions of the same tool) for the same machine architecture, OS, and API". Of course depending on your view of what constitutes API, one might say that this is really already an issue at the API level before you even get to ABI, but I usually consider implementation of types to be an ABI issue. – R.. Nov 7 '10 at 12:11
@Steve Jessop: Linux uses the SYS V x86-64 ABI, and it does not specify those types. – caf Nov 7 '10 at 13:03

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