As I've learned recently, a long in C/C++ is the same length as an int. To put it simply, why? It seems almost pointless to even include the datatype in the language. Does it have any uses specific to it that an int doesn't have? I know we can declare a 64-bit int like so:

long long x = 0;

But why does the language choose to do it this way, rather than just making a long well...longer than an int? Other languages such as C# do this, so why not C/C++?

  • 13
    The reaon we use types like u8, s16, s32, u64, etc. Commented Sep 17, 2011 at 18:25
  • 22
    "a long in C/C++ is the same length as an int." Not always. The C++ standard specifies that an int be the "natural" size for the processor, which may not always be as big as a long. The standard also guarantees that a long is at least as long as an int, so the fact that they are equal sizes are not always guaranteed.
    – In silico
    Commented Sep 17, 2011 at 18:27
  • 7
    Historical and architectural baggage. Believe me, it can hurt making assumptions like you make about int and long always being the same size; I am currently fixing a ton of portability issues in one of our C++ static libraries as we transition to a 64-bit architecture Commented Sep 17, 2011 at 18:28
  • 4
    Practically speaking, sizeof(long) == sizeof(int) only on 32-bit architectures or 64-bit Windows, where it comes as a shock to programmers who are used to sizeof(long) == sizeof(void *). Commented Sep 17, 2011 at 18:32
  • 6
    Just for kicks I'll throw this out there: on 8-bit Arduino microcontroller development boards at least (using Atmel's ATmega328 microcontroller, for example), char is 8-bits, short is 16-bits, int is 16-bits, and long is 32-bits. So in this case short and int are identical, while long truly is longer. Commented Jul 27, 2017 at 21:34

5 Answers 5


When writing in C or C++, every datatype is architecture and compiler specific. On one system int is 32, but you can find ones where it is 16 or 64; it's not defined, so it's up to compiler.

As for long and int, it comes from times, where standard integer was 16bit, where long was 32 bit integer - and it indeed was longer than int.

  • 14
    @MGZero: You're sort of right, but you didn't read the answer fully. There was a time in the long past when int and short were the same size on many platforms. If int were still 16 bits, then that would be a 'legacy' thing. int is basically meant to represent a very efficient size for integers on whatever platform you happen to be on. Commented Sep 17, 2011 at 18:31
  • 2
    +1 - also prob good to mention that this is why c99 defined the uintNN_t etc types to clear things up. Commented Sep 17, 2011 at 18:31
  • 4
    @MGZero, Not at all, this continues to vary by platform, and there are many platforms still define int and long of different size. Commented Sep 17, 2011 at 18:40
  • 8
    @Griwes, you imply that this is a thing of the past, when in fact, the present has plenty of platforms where long and int are different sizes, and the future shows no signs of not having such platforms. You don't describe the actual rules governing the sizes of types in C at all. Commented Sep 17, 2011 at 19:36
  • 3
    @Mike: As I read it, he explains the rationale for the current situation, a rationale which by necessity must be found in the past.
    – MSalters
    Commented Sep 17, 2011 at 23:05

The specific guarantees are as follows:

  • char is at least 8 bits (1 byte by definition, however many bits it is)
  • short is at least 16 bits
  • int is at least 16 bits
  • long is at least 32 bits
  • long long (in versions of the language that support it) is at least 64 bits
  • Each type in the above list is at least as wide as the previous type (but may well be the same).

Thus it makes sense to use long if you need a type that's at least 32 bits, int if you need a type that's reasonably fast and at least 16 bits.

Actually, at least in C, these lower bounds are expressed in terms of ranges, not sizes. For example, the language requires that INT_MIN <= -32767, and INT_MAX >= +32767. The 16-bit requirements follows from this and from the requirement that integers are represented in binary.

C99 adds <stdint.h> and <inttypes.h>, which define types such as uint32_t, int_least32_t, and int_fast16_t; these are typedefs, usually defined as aliases for the predefined types.

(There isn't necessarily a direct relationship between size and range. An implementation could make int 32 bits, but with a range of only, say, -2**23 .. +2^23-1, with the other 8 bits (called padding bits) not contributing to the value. It's theoretically possible (but practically highly unlikely) that int could be larger than long, as long as long has at least as wide a range as int. In practice, few modern systems use padding bits, or even representations other than 2's-complement, but the standard still permits such oddities. You're more likely to encounter exotic features in embedded systems.)

  • Then there is a problem. Because almost everyone assumes that int will store 32 bit number. So they usually put million into the int variable. Nowadays everyone assumes it's 32bits I think. If we are going to be politically correct, everyone should start to use long as their default data type.
    – offchan
    Commented Dec 5, 2020 at 11:25
  • 2
    @off99555 There is no "default data type". You can safely assume that int is at least 32 bits if you're on an implementation that makes that guarantee; all POSIX-conforming systems do so. If you make that assumption, your code won't be portable to systems with 16-bit int. That may or may not be a good tradeoff. (And being "politically correct" is irrelevant.) Commented Dec 5, 2020 at 21:39

long is not the same length as an int. According to the specification, long is at least as large as int. For example, on Linux x86_64 with GCC, sizeof(long) = 8, and sizeof(int) = 4.


long is not the same size as int, it is at least the same size as int. To quote the C++03 standard (3.9.1-2):

There are four signed integer types: “signed char”, “short int”, “int”, and “long int.” In this list, each type provides at least as much storage as those preceding it in the list. Plain ints have the natural size suggested by the architecture of the execution environment); the other signed integer types are provided to meet special needs.

My interpretation of this is "just use int, but if for some reason that doesn't fit your needs and you are lucky to find another integral type that's better suited, be our guest and use that one instead". One way that long might be better is if you 're on an architecture where it is... longer.

  • 1
    "One way that long might be better is if you 're on an architecture where it is... longer." Not really. long might be better if you write portable code and you need integer of at least 32-bits. long is guaranteed to be not less than 32-bits by C standard. int is not guaranteed (it may be 16-bits). Commented Sep 17, 2011 at 23:34
  • @SergeDundich: Very true. No excuses for not addressing the question in C for me.
    – Jon
    Commented Sep 17, 2011 at 23:44

looking for something completely unrelated and stumbled across this and needed to answer. Yeah, this is old, so for people who surf on in later...

Frankly, I think all the answers on here are incomplete.

The size of a long is the size of the number of bits your processor can operate on at one time. It's also called a "word". A "half-word" is a short. A "doubleword" is a long long and is twice as large as a long (and originally was only implemented by vendors and not standard), and even bigger than a long long is a "quadword" which is twice the size of a long long but it had no formal name (and not really standard).

Now, where does the int come in? In part registers on your processor, and in part your OS. Your registers define the native sizes the CPU handles which in turn define the size of things like the short and long. Processors are also designed with a data size that is the most efficient size for it to operate on. That should be an int.

On todays 64bit machines you'd assume, since a long is a word and a word on a 64bit machine is 64bits, that a long would be 64bits and an int whatever the processor is designed to handle, but it might not be. Why? Your OS has chosen a data model and defined these data sizes for you (pretty much by how it's built). Ultimately, if you're on Windows (and using Win64) it's 32bits for both a long and int. Solaris and Linux use different definitions (the long is 64bits). These definitions are called things like ILP64, LP64, and LLP64. Windows uses LLP64 and Solaris and Linux use LP64:

Model      ILP64   LP64   LLP64
int        64      32     32
long       64      64     32
pointer    64      64     64
long long  64      64     64

Where, e.g., ILP means int-long-pointer, and LLP means long-long-pointer

To get around this most compilers seem to support setting the size of an integer directly with types like int32 or int64.

  • 3
    "The size of a long is the size of the number of bits your processor can operate on at one time." -- The standard doesn't say or imply that, and it's not always true. On a system with 16-bit words that needs multiple instructions to operate on a 32-bit quantity, long is still required to be at least 32 bits. There is no requirement that short is half the width of long, or that long long is twice the width of long -- and neither is true on the system I'm using (16-bit short, 64-bit long, 64-bit long long). Commented Sep 21, 2017 at 18:29
  • Finally, all conforming C and C++ compilers define int32_t and int64_t in <stdint.h> (introduced in C in 1999 and later adopted by C++). That's assuming the implementation has types that support the requirements; not all do. Commented Sep 21, 2017 at 18:30
  • Since you didn't tag me in your comment, I didn't see it until just now. I did in fact read the entire answer. What about my comments makes you think I didn't? Commented Mar 21, 2021 at 21:34
  • this is a bad answer. it is confidently inaccurate, and even internally contradictory Commented Jan 24, 2023 at 8:40

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.