This is a possibly inane question whose answer I should probably know.

Fifteen years ago or so, a lot of C code I'd look at had tons of integer typedefs in platform-specific #ifdefs. It seemed every program or library I looked at had their own, mutually incompatible typedef soup. I didn't know a whole lot about programming at the time and it seemed like a bizarre bunch of hoops to jump through just to tell the compiler what kind of integer you wanted to use.

I've put together a story in my mind to explain what those typedefs were about, but I don't actually know whether it's true. My guess is basically that when C was first developed and standardized, it wasn't realized how important it was to be able to platform-independently get an integer type of a certain size, and thus all the original C integer types may be of different sizes on different platforms. Thus everyone trying to write portable C code had to do it themselves.

Is this correct? If so, how were programmers expected to use the C integer types? I mean, in a low level language with a lot of bit twiddling, isn't it important to be able to say "this is a 32 bit integer"? And since the language was standardized in 1989, surely there was some thought that people would be trying to write portable code?

  • 20
    It seems that a need of platform-independent types has been realized only 10 years later with C99: stdint.h Apr 14, 2017 at 8:04
  • 2
    10 years? C started in 1972 and "K&R C" was 1978. Apr 14, 2017 at 12:08
  • 4
    another blunder was omitting a true boolean from C89
    – M.M
    Apr 14, 2017 at 12:14
  • 3
    @M.M That was outside the scope of the committee's charge "... to develop a clear, consistent, and unambiguous Standard for the C programming language which codifies the common, existing definition of C ..." [emphasis mine] Apr 14, 2017 at 14:45
  • 4
    This is going to be an unpopular opinion but i think people way overuse [u]intN_t. You really don't need a specific number of bits in most cases, you just think you do.
    – user541686
    Apr 15, 2017 at 0:00

6 Answers 6


When C began computers were less homogenous and a lot less connected than today. It was seen as more important for portability that the int types be the natural size(s) for the computer. Asking for an exactly 32-bit integer type on a 36-bit system is probably going to result in inefficient code.

And then along came pervasive networking where you are working with specific on-the-wire size fields. Now interoperability looks a whole lot different. And the 'octet' becomes the de facto quanta of data types.

Now you need ints of exact multiples of 8-bits, so now you get typedef soup and then eventually the standard catches up and we have standard names for them and the soup is not as needed.

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    I agree, but I feel that today computers are less heterogeneous than in the late 1990s (remember the Unix wars, and the workstations wars: Appollo, HP, IBM, Sun, ....) Apr 14, 2017 at 10:56
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    Spot on, this. The variable-width types are, frankly, antiquated for the majority of targets (though still useful in the low-power world). Overall, unless you know that you have a substantial bottleneck due to them, fixed-width types rule okay. You know what they are and you know what they do and you know how big they are.... on either side of a network or file serialisation layer. Now all you need is to be cautious of endianness and alignment and you're set. Apr 14, 2017 at 16:16
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    “Asking for an exactly 32-bit integer type on a 36-bit system is probably going to result in inefficient code.” if you need exactly 32bit you can’t get around that anyways. If it just has to be at least 32 bit there is int_fast32_t.
    – Michael
    Apr 14, 2017 at 18:22
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    I am of the apparently minority opinion that even today, if you have good reason to be writing C at all, you generally don't actually need, and shouldn't want, a fixed-width integral type: but rather, pick whether you want the smallest or the fastest type that's guaranteed to hold the size you need. The compiler always has the opportunity to know best - tell it how many bits you need, and whether to prefer runtime or runspace efficiency, and let it handle it from there.
    – mtraceur
    Apr 15, 2017 at 9:13
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    @mtraceur In general I agree, but there are times you need a certain size's be behavior for either interoperability or algorythymic correctness - checksums, sequence number wrap around etc - where having the exact expected size greatly simplifies and speeds things along. Apr 15, 2017 at 10:55

C's earlier success was due to it flexibility to adapt to nearly all existing variant architectures @John Hascall with:
1) native integer sizes of 8, 16, 18, 24, 32, 36, etc. bits,
2) variant signed integer models: 2's complement, 1's complement, signed integer and
3) various endian, big, little and others.

As coding developed, algorithms and interchange of data pushed for greater uniformity and so the need for types that met 1 & 2 above across platforms. Coders rolled their own like typedef int int32 inside a #if .... The many variations of that created the soup as noted by OP.

C99 introduced (u)int_leastN_t, (u)int_fastN_t, (u)intmax_t to make portable yet somewhat of minimum bit-width-ness types. These types are required for N = 8,16,32,64.

Also introduced are semi-optional types (see below **) like (u)intN_t which has the additional attributes of they must be 2's complement and no padding. It is these popular types that are so widely desired and used to thin out the integer soup.

how were programmers expected to use the C integer types?

By writing flexible code that did not strongly rely on bit width. Is is fairly easy to code strtol() using only LONG_MIN, LONG_MAX without regard to bit-width/endian/integer encoding.

Yet many coding tasks oblige precise width types and 2's complement for easy high performance coding. It is better in that case to forego portability to 36-bit machines and 32-bit sign-magnitudes ones and stick with 2N wide (2's complement for signed) integers. Various CRC & crypto algorithms and file formats come to mind. Thus the need for fixed-width types and a specified (C99) way to do it.

Today there are still gotchas that still need to be managed. Example: The usual promotions int/unsigned lose some control as those types may be 16, 32 or 64.


These types are optional. However, if an implementation provides integer types with widths of 8, 16, 32, or 64 bits, no padding bits, and (for the signed types) that have a two’s complement representation, it shall define the corresponding typedef names. C11 Exact-width integer types 3


I remember that period and I'm guilty of doing the same!

One issue was the size of int, it could be the same as short, or long or in between. For example, if you were working with binary file formats, it was imperative that everything align. Byte ordering complicated things as well. Many developer went the lazy route and just did fwrite of whatever, instead of picking numbers apart byte-by-byte. When the machines upgraded to longer word lengths, all hell broke loose. So typedef was an easy hack to fix that.

If performance was an issue, as it often was back then, int was guaranteed to be the machine's fastest natural size, but if you needed 32 bits, and int was shorter than that, you were in danger of rollover.

In the C language, sizeof() is not supposed to be resolved at the preprocessor stage, which made things complicated because you couldn't do #if sizeof(int) == 4 for example.

Personally, some of the rationale was also just working from an assembler language mindset and not being willing to abstract out the notion of what short, int and long are for. Back then, assembler was used in C quite frequently.

Nowadays, there are plenty of non-binary file formats, JSON, XML, etc. where it doesn't matter what the binary representation is. As well, many popular platforms have settled on a 32-bit int or longer, which is usually enough for most purposes, so there's less of an issue with rollover.

  • I thought one could assert at compile time using the diagnostic for an attempt to declare a negatively sized array: extern const char int_is_4_bytes[sizeof(int) == 4 ? 1 : -1]; Or was this not widely known? Apr 14, 2017 at 15:29
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    @DamianYerrick that only lets you error out when the typedefs are incorrect and then requires manual correction. It won't let you select a correct typedef a priori #if sizeof(long) == 8 \ #define int64 long \ #elif sizeof(long long) == 8 \ #define int64 long long \ #endif Apr 14, 2017 at 16:14
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    "most platforms have settled on a 32-bit int or larger" --> Hmmm, at least 100s of millions of embedded process each year (2016) use 16-bit int. C is very popular there. Apr 14, 2017 at 16:29
  • "you couldn't do #if sizeof(int) == 4 for example" -> while this has never been standard, several compilers did (and still do) actually support this. Presumably exactly to address the difficulty in handling it any other way before stdint.h came along. Apr 14, 2017 at 21:00
  • From what I remember of the time, portability could be improved by avoiding the use of "int" for things other than simple automatic, or maybe static, variables. For anything else, use either short or long. Compilers for platforms where int was 16 bits would recognize that int* and short* could alias, and those where int was 32 bits would recognize that int* and long* could alias. Adding int32_t but not specifying that it would be alias-compatible with other integer types using the same size and representation was not an improvement, IMHO.
    – supercat
    Apr 15, 2017 at 18:49

C is a product of the early 1970s, when the computing ecosystem was very different. Instead of millions of computers all talking to each other over an extended network, you had maybe a hundred thousand systems worldwide, each running a few monolithic apps, with almost no communication between systems. You couldn't assume that any two architectures had the same word sizes, or represented signed integers in the same way. The market was still small enough that there wasn't any percieved need to standardize, computers didn't talk to each other (much), and nobody though much about portability.

If so, how were programmers expected to use the C integer types?

If you wanted to write maximally portable code, then you didn't assume anything beyond what the Standard guaranteed. In the case of int, that meant you didn't assume that it could represent anything outside of the range [-32767,32767], nor did you assume that it would be represented in 2's complement, nor did you assume that it was a specific width (it could be wider than 16 bits, yet still only represent a 16 bit range if it contained any padding bits).

If you didn't care about portability, or you were doing things that were inherently non-portable (which bit twiddling usually is), then you used whatever type(s) met your requirements.

I did mostly high-level applications programming, so I was less worried about representation than I was about range. Even so, I occasionally needed to dip down into binary representations, and it always bit me in the ass. I remember writing some code in the early '90s that had to run on classic MacOS, Windows 3.1, and Solaris. I created a bunch of enumeration constants for 32-bit masks, which worked fine on the Mac and Unix boxes, but failed to compile on the Windows box because on Windows an int was only 16 bits wide.

  • Microcomputer C compilers almost without exception used 8/16/32 bits for char/short/long and used two's-complement signed representations. The only things that varied in the general-purpose-microcomputer world were whether "int" was 16 or 32 bits, and whether they were big-endian or little-endian. Things were different with machines other than general-purpose microcomputers, but a lot of programs would not have been useful on such machines anyway.
    – supercat
    Apr 14, 2017 at 21:35

C was designed as a language that could be ported to as wide a range of machines as possible, rather than as a language that would allow most kinds of programs to be run without modification on such a range of machines. For most practical purposes, C's types were:

  • An 8-bit type if one is available, or else the smallest type that's at least 8 bits.

  • A 16-bit type, if one is available, or else the smallest type that's at least 16 bits.

  • A 32-bit type, if one is available, or else some type that's at least 32 bits.

  • A type which will be 32 bits if systems can handle such things as efficiently as 16-bit types, or 16 bits otherwise.

If code needed 8, 16, or 32-bit types and would be unlikely to be usable on machines which did not support them, there wasn't any particular problem with such code regarding char, short, and long as 8, 16, and 32 bits, respectively. The only systems that didn't map those names to those types would be those which couldn't support those types and wouldn't be able to usefully handle code that required them. Such systems would be limited to writing code which had been written to be compatible with the types that they use.

I think C could perhaps best be viewed as a recipe for converting system specifications into language dialects. A system which uses 36-bit memory won't really be able to efficiently process the same language dialect as a system that use octet-based memory, but a programmer who learns one dialect would be able to learn another merely by learning what integer representations the latter one uses. It's much more useful to tell a programmer who needs to write code for a 36-bit system, "This machine is just like the other machines except char is 9 bits, short is 18 bits, and long is 36 bits", than to say "You have to use assembly language because other languages would all require integer types this system can't process efficiently".

  • "C was not designed as a language that could be ported to as wide a range of machines as possible". I'm not sure what you mean by this. Wasn't C born into the UNIX environment for the sole purpose of eliminating inconsistent interfaces for files and so on?
    – autistic
    May 2, 2017 at 5:38
  • @Seb: Mea culpa. I started by saying it wasn't designed to facilitate portable programs, but rather to be a language that was portable, but then I reversed the order and accidentally left an extra "not". Better now?
    – supercat
    May 2, 2017 at 14:22
  • Fantastic! It's a shame there aren't any types which guarantee the portable ranges of signed char, short, int, long and long long (and their unsigned equivalents), without going above and beyond those ranges, even at the expense of meaningless padding... or better yet, the ability for the programmer to specify the ranges he/she cares about; this would virtually eliminate misunderstandings regarding portability of ranges of types such as int and long that exist nowadays, and provide useful internal documentation within the code to facilitate maintenance. Again, nice answer!
    – autistic
    May 3, 2017 at 4:56
  • @Seb: I would really like to see C include a way of specifying exactly what one needs: "32 bits non-promoting unsigned, stored as four possibly-padded 8-bit chunks, big-endian, accessible at 32-bit boundaries, and alias-compatible with all similar types." A compiler whose "uint32_t" has those characteristics could simply use "uint32_t", but code could using such types could also work on systems where uint32_t doesn't have those characteristics if they support types that do.
    – supercat
    May 3, 2017 at 14:42

Not all machines have the same native word size. While you might be tempted to think a smaller variable size will be more efficient, it just ain't so. In fact, using a variable that is the same size as the native word size of the CPU is much, much faster for arithmetic, logical and bit manipulation operations.

But what, exactly, is the "native word size"? Almost always, this means the register size of the CPU, which is the same as the Arithmetic Logic Unit (ALU) can work with.

In embedded environments, there are still such things as 8 and 16 bit CPUs (are there still 4-bit PIC controllers?). There are mountains of 32-bit processors out there still. So the concept of "native word size" is alive and well for C developers.

With 64-bit processors, there is often good support for 32-bit operands. In practice, using 32-bit integers and floating point values can often be faster than the full word size.

Also, there are trade-offs between native word alignment and overall memory consumption when laying out C structures.

But the two common usage patterns remain: size agnostic code for improved speed (int, short, long), or fixed size (int32_t, int16_t, int64_t) for correctness or interoperability where needed.

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    int/short/long are not size-agnostic. They have specified sizes on any given platform. Performance is application- and algorithm-dependant, and blindly using arbitrarily sized types thinking "the compiler will sort it out for me" isn't a good way to write fast code. In theory clever use of the u?int_fast\d*_t types can help here, but in practice you're still better-off just benchmarking for the specific platforms you want.
    – Veedrac
    Apr 15, 2017 at 13:59
  • @Veedrac: Performance could be enhanced if there were types that were allowed to hold values outside their "normal" range at the compiler's convenience without a requirement that they behave consistently. On some systems, using 16-bit types for variables kept in registers may require that a compiler add otherwise-unneeded code to truncate values to 16 bits, but using 16-bit types for variables kept in arrays would improve cache performance. A type that would allow 16-bit variables in memory but not promise truncation might offer optimal performance, but C defines no such thing.
    – supercat
    Apr 15, 2017 at 18:59
  • @supercat The compiler is always allowed to do that if you tell it that it's UB! That's what the "as-if" rule is about. Unfortunately C does poorly thought-out things like making whether wraparound is defined a property of the signedness type (WTF?) rather than the operation, which means it's often challenging to tell the compiler that the transformations are valid. This isn't any more or less a problem with short/int/long than it is with the fixed-width types, though; it's just a problem with C.
    – Veedrac
    Apr 15, 2017 at 20:27
  • @Veedrac: A conforming 32-bit implementation, given int16_t foo; and asked to executing foo++; when foo is 32767, will be required by the Standard as either set foo to "an implementation-defined value" (typically -32768) or raise an implementation-defined signal. While a programmer could add extra code to induce UB if foo was 32767 (and hope the compiler doesn't generate any machine code for that) I find backward the notion that programmers should be expected to write useless code in the hope that optimizers will eliminate it.
    – supercat
    Apr 15, 2017 at 20:35
  • @Veedrac: On a system with 32-bit int, incrementing an int32_t or a 32-bit int_least16_t beyond its range would invoke UB. Incrementing an int16_t` or a 16-bit int_least16_t beyond its range, however, would be required to either yield a value within the range of int16_t or else raise an implementation-defined signal. On some systems, both options would have costs which wouldn't apply if an implementation could treat int_least16_t as sometimes being able to hold numbers larger than 32767.
    – supercat
    Apr 15, 2017 at 20:56

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