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I already know that stdint is used to when you need specific variable sizes for portability between platforms, I don't really have such issue for now, but what are the cons and pros of using it besides de already shown fact above?

Looking for it on stackoverflow and others sites, I found 2 links that treats about the theme:

  • 1 - this one talks about the portability of the stdint.

  • 2 - this one is more specific about uint8_t.

Theses two links are great specially about to know more about the main reason of this header that is portability, but for me, what I like most about it that I think uint8_t is cleaner than unsigned char (for storing an RBG channel value for example), int32_t looks more meaningfull than simply int, etc.

So, my question is, exactly what is the cons, and specially the pros of using stdint besides the portability, and should I use it just in some specifics parts of my code, or everywhere? if everywhere, how can I user functions like atoi, strtok, etc with it?

Thanks!

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4 Answers 4

up vote 13 down vote accepted

Pros

Using well-defined types makes the code far easier and safer to port, as you won't get any surprises when for example one machine interprets int as 16-bit and another as 32-bit. With stdint.h, what you type is what you get.

Using int etc also makes it hard to detect dangerous type promotions.

Another advantage is that by using int8_t instead of char, you know that you always get a signed 8 bit variable. char can be signed or unsigned, it is implementation-defined behavior and varies between compilers. Therefore, the default char is plain dangerous to use in code that should be portable.

If you want to give the compiler hints of that a variable should be optimized, you can use the uint_fastx_t which tells the compiler to use the fastest possible integer type, at least as large as 'x'. Most of the time this doesn't matter, the compiler is smart enough to make optimizations on type sizes no matter what you have typed in. Between sequence points, the compiler can implicitly change the type to another one than specified, as long as it doesn't affect the result.

Cons

None.


Reference: MISRA-C:2004 rule 6.3."typedefs that indicate size and signedness shall be used in place of the basic types".

EDIT : Removed incorrect example.

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Obvious Cons as wallyk stated is the performance impact. Forcing to count in uint32_t integers on a 12bit machine is tedious –  hroptatyr Mar 23 '12 at 10:40
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uint32_t cannot exist on a 12bit machine. –  R.. Mar 23 '12 at 12:02
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@hroptatyr If you read my answer again, you will find that I addressed that very issue. If it needs to be uint32_t, declare it as that. If it doesn't need that high resolution, but only 16 bit, then declare it as uint_fast16_t, which will be compiled as a 32 bit on a CPU where 32 bit alignment is faster. –  Lundin Mar 23 '12 at 12:24
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According to 6.3.1.3 (1), "When a value with integer type is converted to another integer type other than _Bool, if the value can be represented by the new type, it is unchanged.", your example should print out "x > y" also on a 16-bit system. The integer conversion rank of long is greater than that of (unsigned) int, ~x is UINT_MAX, with 16-bit unsigned ints, 65535, that is representable as a long. So the comparison is 65535L > 0L. The point is valid, but you picked a wrong example. –  Daniel Fischer Apr 27 '12 at 22:03
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Sorry to be a nuisance, but I'd really like you to either change the example, so I can upvote, or point out a flaw in my reasoning, so I can upvote. –  Daniel Fischer May 20 '12 at 1:12

The only reason to use uint8_t rather than unsigned char (aside from aesthetic preference) is if you want to document that your program requires char to be exactly 8 bits. uint8_t exists if and only if CHAR_BIT==8, per the requirements of the C standard.

The rest of the intX_t and uintX_t types are useful in the following situations:

  • reading/writing disk/network (but then you also have to use endian conversion functions)
  • when you want unsigned wraparound behavior at an exact cutoff (but this can be done more portably with the & operator).
  • when you're controlling the exact layout of a struct because you need to ensure no padding exists (e.g. for memcmp or hashing purposes).

On the other hand, the uint_least8_t, etc. types are useful anywhere that you want to avoid using wastefully large or slow types but need to ensure that you can store values of a certain magnitude. For example, while long long is at least 64 bits, it might be 128-bit on some machines, and using it when what you need is just a type that can store 64 bit numbers would be very wasteful on such machines. int_least64_t solves the problem.

I would avoid using the [u]int_fastX_t types entirely since they've sometimes changed on a given machine (breaking the ABI) and since the definitions are usually wrong. For instance, on x86_64, the 64-bit integer type is considered the "fast" one for 16-, 32-, and 64-bit values, but while addition, subtraction, and multiplication are exactly the same speed whether you use 32-bit or 64-bit values, division is almost surely slower with larger-than-necessary types, and even if they were the same speed, you're using twice the memory for no benefit.

Finally, note that the arguments some answers have made about the inefficiency of using int32_t for a counter when it's not the native integer size are technically mostly correct, but it's irrelevant to correct code. Unless you're counting some small number of things where the maximum count is under your control, or some external (not in your program's memory) thing where the count might be astronomical, the correct type for a count is almost always size_t. This is why all the standard C functions use size_t for counts. Don't consider using anything else unless you have a very good reason.

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The issue with int_fastx_t sounds like a compiler bug, rather than something the programmer should need to concern themselves with. And I agree that counter variables (for loop int interators etc) should be be size_t in most cases. –  Lundin Mar 23 '12 at 12:31
    
"reading/writing disk/network" is the PC answer. You also definitely need stdint types in any form of embedded system, where you are dealing with hardware registers, direct memory access, memory handling routines, data protocol mappings, interrupt vector setup, bootloaders... and so on. –  Lundin Mar 23 '12 at 12:35
    
@Lundin: The fact that it's a widespread "bug", along with the lack of a specification for the definitions of these types in the psABI, is a very good reason for the programmer to be concerned. It means that if the bug is ever fixed, any external interfaces using these types will break ABI compatibility. Worse yet, the "version" of your interfaces is determined not by your library version but by your compiler version. –  R.. Mar 24 '12 at 0:10

cons

The primary reason the C language does not specify the size of int or long, etc. is for computational efficiency. Each architecture has a natural, most-efficient size, and the designers specifically empowered and intended the compiler implementor to use the natural native data size data for speed and code size efficiency.

In years past, communication with other machines was not a primary concern—most programs were local to the machine—so the predictability of each data type's size was of little concern.

Insisting that a particular architecture use a particular size int to count with is a really bad idea, even though it would seem to make other things easier.

In a way, thanks to XML and its brethren, data type size again is no longer much of a concern. Shipping machine-specific binary structures from machine to machine is again the exception rather than the rule.

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-1, you don't know the standard. stdint.h contains not only uintx_t, but also uintx_least_t and uintx_fast_t. Also, when porting code you don't want any surprises with sudden type size changes. If portability is important, the code should use types that will work well on any machine. I use the basic stdint types, not the fast ones, and often port wildly between tiny 8-bit MCU and cumbersome 64-bit PC, without any problems. Not having to rewrite the code when I do so, actually seems like a really good idea to me. –  Lundin Mar 23 '12 at 7:52

I use stdint types for one reason only, when the data I hold in memory shall go on disk/network/descriptor in binary form. You only have to fight the little-endian/big-endian issue but that's relatively easy to overcome.

The obvious reason not to use stdint is when the code is size-independent, in maths terms everything that works over the rational integers. It would produce ugly code duplicates if you provided a uint*_t version of, say, qsort() for every expansion of *.

I use my own types in that case, derived from size_t when I'm lazy or the largest supported unsigned integer on the platform when I'm not.

Edit, because I ran into this issue earlier:
I think it's noteworthy that at least uint8_t, uint32_t and uint64_t are broken in Solaris 2.5.1. So for maximum portability I still suggest avoiding stdint.h (at least for the next few years).

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