It's not about shortening the names, but about portability. Different platforms will need to typedef those things differently.
long may be 32 or 64 bits, depending on your compiler/target, so it can't be safely assumed to be a certain size. A library author will thus typedef his own type, guaranteeing a certain size, with the knowledge of the target platform.
typedef __int64 INT64; // long will not be 64 bit on Windows/VC.
typedef long INT64; // gcc typically uses 64 bit longs.
#elif // ... other platforms ...
And if compilers change type properties in future versions, the types can be edited in one place.
In the past you also had a typical case where
int might be 16 or 32 bits in size, so you couldn't simply use the raw
int type in code where you needed a
Hence why you have things like
It's also used as a form of abstraction. Which is why you see typedefs like
typedef int Handle;
Because while it's an
int now, the library author reserves the ability to change it later down the track to anything else, say a
void *, or any other type they deem necessary.
But the client code doesn't need to know it's an
int specifically, since that's just what it currently happens to be. All the client needs to know is to pass it along to functions accepting a
Typedefs also allow configuration at compile time. E.g. some libraries may have a
Real type for real numbers. It could be defined in a way such as
typedef double Real;
typedef float Real;
And the user of the library can optionally set
/DUSE_DOUBLE_PREC when compiling to get double precision float support, but the important thing is that no library code needs to change for this to work, since it's been abstracted.