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The C99 standard introduces the following datatypes. The documentation can be found here for the AVR stdint library.

  • uint8_t means it's an 8-bit unsigned type.
  • uint_fast8_t means it's the fastest unsigned int with at least 8 bits.
  • uint_least8_t means it's an unsigned int with at least 8 bits.

I understand uint8_t and what is uint_fast8_t( I don't know how it's implemented in register level).

1.Can you explain what is the meaning of "it's an unsigned int with at least 8 bits"?

2.How uint_fast8_t and uint_least8_t help increase efficiency/code space compared to the uint8_t?

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For your 1st question I can imagine that whereas uint8_t is guaranteed to be 8 bits, uint_fast8_t is guaranteed to be >= 8 bits, much like an unsigned char. – jacob Jan 28 at 7:24
    
One consideration is that uint8_t doesn't exist on systems that don't have a native 8-bit type. The other two will be there. – Pete Becker Jan 28 at 14:04
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You've gotten answers that refer to "obscure" and "exotic" architectures. Those terms are a bit biased. Sure, if your only experience is with desktop systems, these architectures are outside your range of experience. But "I haven't seen this before" is not the same as "this is obscure or exotic". For people who work with embedded systems or DSPs these things are quite common. – Pete Becker Jan 28 at 14:08
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Possible duplicate of The difference of int8_t, int_least8_t and int_fast8_t? – dan04 Jan 28 at 23:24
up vote 49 down vote accepted

uint_least8_t is the smallest type that has at least 8 bits. uint_fast8_t is the fastest type that has at least 8 bits.

You can see the differences by imagining exotic architectures. Imagine a 20-bit architecture. Its unsigned int has 20 bits (one register), and its unsigned char has 10 bits. So sizeof(int) == 2, but using char types requires extra instructions to cut the registers in half. Then:

  • uint8_t: is undefined (no 8 bit type).
  • uint_least8_t: is unsigned char, the smallest type that is at least 8 bits.
  • uint_fast8_t: is unsigned int, because in my imaginary architecture, a half-register variable is slower than a full-register one.
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I love how you have to imagine exotic architectures to find a use case for this. Have they found any usefulness in practice? – Mehrdad Jan 28 at 7:28
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@Mehrdad In ARM for example, if your int_fast8_t is 32-bit variable, you don't need to do sign extension before arithmetric operations. – user694733 Jan 28 at 7:30
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@Mehrdad: I admit that I've never seen the uint_leastX_t or uint_fastX_t used in real world applications. uintX_t yes, they are heavily used. It looks like people are not very interesting in portability to exotic architectures. Which is expected, even if you get your unsigneds right, your program will fail at a thousand different things. – rodrigo Jan 28 at 8:36
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@Mehrdad: ...and if you are programming for an exotic architecture, then you know your types, you are unlikely to write code useful for another computer, so you don't care about portability. – rodrigo Jan 28 at 8:41
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@skyking: I'm not saying they should not be used, just that they are not used very much in practice. If you can find a real-world application or library that uses them sensibly, then post a link, because I couldn't find any. – rodrigo Jan 28 at 8:46

uint8_t means: give me an unsigned int of exactly 8 bits.

uint_least8_t means: give me the smallest type of unsigned int which has at least 8 bits. Optimize for memory consumption.

uint_fast8_t means: give me an unsigned int of at least 8 bits. Pick a larger type if it will make my program faster, because of alignment considerations. Optimize for speed.

Also, unlike the plain int types, the signed version of the above stdint.h types are guaranteed to be 2's complement format.

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Thanks. Good to know that the signed types in stdint.h are guaranteed to be two's complement. Wonder where it will help when writing portable code. – legends2k Jan 28 at 7:46
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Note that only the exact width variants are required to use 2's complement format. Also note that these are not required to exist. Consequently a platform is not required to support 2's complement format. – skyking Jan 28 at 7:52
    
@legends2k: The types in stdint.h are rather less helpful than one might like if one is trying to write portable code, since while they are required to use two's-complement storage format, that does not imply that they will exhibit two's-complement wrapping behavior. Note also that even on platforms where int is 32 bits, writing a value using an int32_t* and reading using an int*, or vice versa, is not guaranteed to work. – supercat Jan 29 at 17:29
    
@supercat Every compiler I have seen use an internal typedef for the stdint.h types, to make them synonymous with one of the basic "keyword" integer types. So if you worry about pointer aliasing I don't think that's going to be an issue in practice, only in theory. – Lundin Feb 1 at 7:19
    
@Lundin: Some compilers use "long" as the typedef for int32_t, and some use "int". Even when "int" and "long" have the same representation they may be (and sometimes are) considered distinct for purposes of C's aliasing rules. – supercat Feb 1 at 14:43

The theory goes something like:

uint8_t is required to be exactly 8 bits but it's not required to exist. So you should use it where you are relying on the modulo-256 arithmetic behaviour of an 8 bit integer and where you would prefer a compile failure to misbehaviour on obscure architectures.

uint_least8_t is required to be the smallest available unsigned integer type that can store at least 8 bits. You would use it when you want to minimise the memory use of things like large arrays.

uint_fast8_t is supposed to be the "fastest" unsigned type that can store at least 8 bits; however, it's not actually guaranteed to be the fastest for any given operation on any given processor. You would use it in processing code that performs lots of operations on the value.

The practice is that the "fast" and "least" types aren't used much.

The "least" types are only really useful if you care about portability to obscure architectures with CHAR_BIT != 8 which most people don't.

The problem with the "fast" types is that "fastest" is hard to pin down. A smaller type may mean less load on the memory/cache system but using a type that is smaller than native may require extra instructions. Furthermore which is best may change between architecture versions but implementers often want to avoid breaking ABI in such cases.

From looking at some popular implementations it seems that the definitions of uint_fastn_t are fairly arbitrary. glibc seems to define them as being at least the "native word size" of the system in question taking no account of the fact that many modern processors (especially 64-bit ones) have specific support for fast operations on items smaller than their native word size. IOS apparently defines them as equivalent to the fixed-size types. Other platforms may vary.

All in all if performance of tight code with tiny integers is your goal you should be bench-marking your code on the platforms you care about with different sized types to see what works best.

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glibc's definitions were chosen at a time when those optimizations didn't exist, and they are now baked into the ABI and cannot be changed. This is one of the several reasons why the _least and _fast types are not actually useful in practice. – zwol Jan 28 at 17:19
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@zwol: I wish the language would add types types that were defined in terms of layout and semantic requirements, e.g. "I need something whose lower bits will alias other 16-bit types, and which can hold values 0-65535, but I don't need it to peg larger values to that range". Aliasing, layout, range, and out-of-range behavior should be four separate aspects of a type, but C only allows certain combinations which aren't consistent among different platforms. – supercat Jan 28 at 23:45

1.Can you explain what is the meaning of "it's an unsigned int with at least 8 bits"?

That ought to be obvious. It means that it's an unsigned integer type, and that it's width is at least 8 bits. In effect this means that it can at least hold the numbers 0 through 255, and it can definitely not hold negative numbers, but it may be able to hold numbers higher than 255.

Obviously you should not use any of these types if you plan to store any number outside the range 0 through 255 (and you want it to be portable).

2.How uint_fast8_t and uint_least8_t help increase efficiency/code space compared to the uint8_t?

uint_fast8_t is required to be faster so you should use that if your requirement is that the code be fast. uint_least8_t on the other hand requires that there is no candidate of lesser size - so you would use that if size is the concern.


And of course you use only uint8_t when you absolutely require it to be exactly 8 bits. Using uint8_t may make the code non-portable as uint8_t is not required to exist (because such small integer type does not exist on certain platforms).

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The "fast" integer types are defined to be the fastest integer available with at least the amount of bits required (in your case 8).

A platform can define uint_fast8_t as uint8_t then there will be absolutely no difference in speed.

The reason is that there are platforms that are slower when not using their native word length.

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Some processors cannot operate as efficiently on smaller data types as on large ones. For example, given:

uint32_t foo(uint32_t x, uint8_t y)
{
  x+=y;
  y+=2;
  x+=y;
  y+=4;
  x+=y;
  y+=6;
  x+=y;
  return x;
}

if y were uint32_t a compiler for the ARM Cortex-M3 could simply generate

add r0,r0,r1,asl #2   ; x+=(y<<2)
add r0,r0,#12         ; x+=12
bx  lr                ; return x

but since y is uint8_t the compiler would have to instead generate:

add r0,r0,r1          ; x+=y
add r1,r1,#2          ; Compute y+2
and r1,r1,#255        ; y=(y+2) & 255
add r0,r0,r1          ; x+=y
add r1,r1,#4          ; Compute y+4
and r1,r1,#255        ; y=(y+4) & 255
add r0,r0,r1          ; x+=y
add r1,r1,#6          ; Compute y+6
and r1,r1,#255        ; y=(y+6) & 255
add r0,r0,r1          ; x+=y
bx  lr                ; return x

The intended purpose of the "fast" types was to allow compilers to replace smaller types which couldn't be processed efficiently with faster ones. Unfortunately, the semantics of "fast" types are rather poorly specified, which in turn leaves murky questions of whether expressions will be evaluated using signed or unsigned math.

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