The compiler decides how large the basic types are, and what the layout of structures is. If a library declares any types, it will decide how those are defined and therefore what size they are.
However, it is often the case that compatibility with an existing standard, and the need to link to existing libraries produced by other compilers, forces a given implementation to make certain choices. For example, the language standard says that a
wchar_t has to be wider than 16 bits, and on Linux, it is 32 bits wide, but it’s always been 16 bits on Windows, so compilers for Windows all choose to be compatible with the Windows API instead of the language standard. A lot of legacy code for both Linux and Windows assumes that a
long is exactly 32 bits wide, while other code assumed it was wide enough to hold a timestamp in seconds or an IPv4 address or a file offset or the bits of a pointer, and (after one compiler defined
int as 64 bits wide and
long as 32 bits wide) the language standard made a new rule that
int cannot be wider than
As a result, mainstream compilers from this century choose to define
int as 32 bits wide, but historically some have defined it as 16 bits, 18 bits, 32 bits, 64 bits and other sizes. Some compilers let you choose whether
long will be exactly 32 bits wide, as some legacy code assumes, or as wide as a pointer, as other legacy code assumes.
This demonstrates how assumptions you make today, like some type always being 32 bits wide, might come back to bite you in the future. This has already happened to C codebases twice, in the transitions to 32-bit and 64-bit code.
But what should you actually use?
int type is rarely useful these days. There’s usually some other type you can use that makes a stronger guarantee of what you’ll get. (It does have one advantage: types that aren’t as wide as an
int could get automatically widened to
int, which could cause a few really weird bugs when you mix signed and unsigned types, and
int is the smallest type guaranteed not to be shorter than
If you’re using a particular API, you’ll generally want to use the same type it does. There are numerous types in the standard library for specific purposes, such as
clock_t for clock ticks and
time_t for time in seconds.
If you want the fastest type that’s at least 16 bits wide, that’s
int_fast16_t, and there are other similar types. (Unless otherwise specified, all these types are defined in
<stdint.h>.) If you want the smallest type that’s at least 32 bits wide, to pack the most data into your arrays, that’s
int_least32_t. If you want the widest possible type, that’s
intmax_t. If you know you want exactly 32 bits, and your compiler has a type like that, it’s
int32_t If you want something that’s 32 bits wide on a 32-bit machine and 64 bits wide on a 64-bit machine, and always the right size to store a pointer, that’s
intptr_t. If you want a good type for doing array indexing and pointer math, that’s
<stddef.h>. (This one’s in a different header because it’s from C89, not C99.)
Use the type you really mean!