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I'm looking for detailed information regarding the size of basic C++ types.

I know that it depends on the architecture (16 bits, 32 bits, 64 bits) and the compiler.

But are there any standards for C++?

I'm using Visual Studio 2008 on a 32 bit architecture. Here is what I get :

char   : 1 byte
short  : 2 bytes
int    : 4 bytes
long   : 4 bytes
float  : 4 bytes
double : 8 bytes

I tried to find, without much success, reliable information stating the sizes of char, short, int , long, double, float (and other types I didn't think of) under different architectures and compilers.

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6  
Hmm... I did not know that... You think they would standardize something like this, right? –  thyrgle Jun 3 '10 at 3:56
12  
@thyrgle its not by choice... there are so many architectures to support that it needs to be flexible. –  Krakkos Jun 22 '10 at 15:52
5  
See: stackoverflow.com/questions/271076/… –  Loki Astari Aug 25 '10 at 18:39
13  
3 years late, but what about files larger than 4GB? What about packing bitfields? Writing introp code? Reading structures off disk? I'd say you've used these things quite often in the 'past 20 years'. –  James Mar 31 '12 at 5:36
3  
@james Late again, but i dont see any of these actions actually being done THAT often. I can definitely see someone not doing any and still working full time in IT for years and years –  Mr Universe Feb 6 '13 at 4:20

22 Answers 22

The C++ standard does not specify the size of integral types in bytes, but it specifies minimum ranges they must be able to hold. You can infer minimum size in bits from the required range. You can infer minimum size in bytes from that and the value of the CHAR_BIT macro that defines the number of bits in a byte (in all but the most obscure platforms it's 8, and it can't be less than 8).

One additional constraint for char is that its size is always 1 byte, or CHAR_BIT bits (hence the name).

Minimum ranges required by the standard (page 22) are:

and Data Type Ranges on MSDN:

  1. signed char: -127 to 127 (note, not -128 to 127; this accommodates 1's-complement platforms)
  2. unsigned char: 0 to 255
  3. "plain" char: -127 to 127 or 0 to 255 (depends on default char signedness)
  4. signed short: -32767 to 32767
  5. unsigned short: 0 to 65535
  6. signed int: -32767 to 32767
  7. unsigned int: 0 to 65535
  8. signed long: -2147483647 to 2147483647
  9. unsigned long: 0 to 4294967295
  10. signed long long: -9223372036854775807 to 9223372036854775807
  11. unsigned long long: 0 to 18446744073709551615

A C++ (or C) implementation can define the size of a type in bytes sizeof(type) to any value, as long as

  1. the expression sizeof(type) * CHAR_BIT evaluates to the number of bits enough to contain required ranges, and
  2. the ordering of type is still valid (e.g. sizeof(int) <= sizeof(long)).

The actual implementation-specific ranges can be found in <limits.h> header in C, or <climits> in C++ (or even better, templated std::numeric_limits in <limits> header).

For example, this is how you will find maximum range for int:

C:

#include <limits.h>
const int min_int = INT_MIN;
const int max_int = INT_MAX;

C++:

#include <limits>
const int min_int = std::numeric_limits<int>::min();
const int max_int = std::numeric_limits<int>::max();
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10  
Rather, the C++ standard uses the word byte to mean "1 char", and not the usual meaning. –  Ben Voigt May 5 '12 at 1:08
    
It would be nice if this answer was updated with the C++11 ranges, which I think have changed (not sure though). –  gsingh2011 Oct 30 '12 at 2:54
1  
@gsingh2011 I don't think the ranges have changed, though precise types from C99 inttypes.h were added (e.g. int64_t), but it's easy to tell the size of these. –  Alex B Oct 30 '12 at 4:23
1  
@Programmer Read the answer (point 1 note in parentheses), or the actual standard's wording (linked in the answer). C standard accommodates 1's complement architectures, which have different representation from the most widespread 2's complement. Minimum guaranteed ranges will almost always differ from the actual ranges an implementation provides. –  Alex B Feb 4 '13 at 11:48
1  
@user In C++, std::numeric_limits<unsigned long long>::min/max(), in C, ULLONG_MIN/MAX (C99 only). –  Alex B May 22 '13 at 15:55

For 32-bit systems, the 'de facto' standard is ILP32 — that is, int, long and pointer are all 32-bit quantities.

For 64-bit systems, the primary Unix 'de facto' standard is LP64 — long and pointer are 64-bit (but int is 32-bit). The Windows 64-bit standard is LLP64 — long long and pointer are 64-bit (but long and int are both 32-bit).

At one time, some Unix systems used an ILP64 organization.

None of these de facto standards is legislated by the C standard (ISO/IEC 9899:1999), but all are permitted by it.

And, by definition, sizeof(char) is 1, notwithstanding the test in the Perl configure script.

Note that there were machines (Crays) where CHAR_BIT was much larger than 8. That meant, IIRC, that sizeof(int) was also 1, because both char and int were 32-bit.

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35  
+1 for stating how things actually are in the cases that matter to most, rather than how things are in theory. If you want 32bit use int, if you want 64bit use long long. If you want native use size_t. Avoid "plain" long because it varies. That should work for most applications. –  Eloff Jan 2 '12 at 2:18
    
+1 Now I know that on Linux64 int is 8 bytes... –  stdcall Jan 9 '13 at 14:53
4  
+1 for the answer. @Eloff: on the contrary... if you want 32 bit use [u]int32_t or similar, if you want 64 bit use [u]int64_t... if you don't have a header for them, download or make one, preferably with either compile time selection of such types or static assertions to verify the size. pubs.opengroup.org/onlinepubs/009695299/basedefs/stdint.h.html If the precise sizes aren't so important and you only care they're at least that big, then your advice holds for common modern PC/server platforms. –  Tony D Nov 19 '13 at 2:29
2  
Note that it's not just old cray machines that have CHAR_BIT > 8. e.g. DSPs often have CHAR_BIT of 16 or 32. (see e.g. these) –  nos Jan 2 at 19:04
1  
@nos: Thank you for the link. It is very helpful to have modern, current systems identified for the oddball cases. Out of curiosity, what is the code set on those machines? If the code set is UTF-16, then 0xFFFF is not a valid character, and if the code set is an ISO 8859-x code set, then again 0xFFFF is not a valid character (character codes from 0x00 to 0xFF are valid). I'm not yet convinced that there's a problem detecting EOF, but there's certainly room for caution, and probably for writing and using a function int get_char(FILE *fp, char *c) which returns EOF or 0 and sets *c. –  Jonathan Leffler Jan 2 at 19:19

In practice there's no such thing. You can expect std::size_t to always represent the unsigned native integer size on current architecture. i.e. 16-bit, 32-bit or 64-bit.

But as far as all the other built-in types go, it really depends on the compiler. Here's two excerpts taken from the current working draft of the latest C++ standard:

There are five standard signed integer types : signed char, short int, int, long int, and long long int. In this list, each type provides at least as much storage as those preceding it in the list.

For each of the standard signed integer types, there exists a corresponding (but different) standard unsigned integer type: unsigned char, unsigned short int, unsigned int, unsigned long int, and unsigned long long int, each of which occupies the same amount of storage and has the same alignment requirements.

If you want to you can statically (compile-time) assert the sizeof these fundamental types. It will alert people to think about porting your code if the sizeof assumptions change.

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6  
good post. another thing that's required is the following least bit-sizes (documented in c89 / c99 together with limits.h and taken over by c++): char >=8, short and int >=16, long >=32 . –  Johannes Schaub - litb Feb 26 '09 at 8:27

There is standard.

C90 standard requires that

sizeof(short) <= sizeof(int) <= sizeof(long)

C99 standard requires that

sizeof(short) <= sizeof(int) <= sizeof(long) < sizeof(long long)

Here is the C99 specifications. Page 22 details sizes of different integral types.

Here is the int type sizes (bits) for Windows platforms:

Type           C99 Minimum     Windows 32bit
char           8               8
short          16              16
int            16              32
long           32              32
long long      64              64

If you are concerned with portability, or you want the name of the type reflects the size, you can look at the header <inttypes.h>, where the following macros are available:

int8_t
int16_t
int32_t
int64_t

int8_t is guaranteed to be 8 bits, and int16_t is guaranteed to be 16 bits, etc.

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+1 for the specific int#_t types. That's what I use when I need a guaranteed size. –  Abhi Beckert Jan 8 '12 at 10:06
4  
Minor nitpick: where does the standard say sizeof(long) < sizeof(long long) as opposed to the symmetric sizeof(long) <= sizeof(long long)? –  Jonathan Leffler Jul 23 '13 at 22:31
    
@JonathonLeffler - see C99 5.2.4.2.1 - Sizes of integer types. minsizeof(int)==16-bits, minsizeof(long)==32-bits, minsizeof(long long)==64-bits. So I think you are right on the <= as no maxsizeof(type) is specified. –  Jesse Chisholm Jun 8 at 16:26
    
Similarly sizeof(float) <= sizeof(double) <= sizeof(long double). According to C99 7.12 paragraph 2. –  Jesse Chisholm Jun 8 at 16:47

If you need fixed size types use types like uint32_t (unsigned integer 32bits) defined in stdint.h, they are specified in c99.

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3  
They are specified but not required. –  dreamlax Jun 3 '10 at 3:58

Updated: C++11 brought the types from TR1 officially into the standard:

  • long long int
  • unsigned long long int

And the "sized" types from <cstdint>

  • int8_t
  • int16_t
  • int32_t
  • int64_t
  • (and the unsigned counterparts).

Plus you get:

  • int_least8_t
  • int_least16_t
  • int_least32_t
  • int_least64_t
  • Plus the unsigned counterparts.

These types represent the smallest integer types with at least the specified number of bits. Likewise there are the "fastest" integer types with at least the specified number of bits:

  • int_fast8_t
  • int_fast16_t
  • int_fast32_t
  • int_fast64_t
  • Plus the unsigned versions.

What "fast" means, if anything, is up to the implementation. It need not be the fastest for all purposes either.

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This is part of the C++11 standard now. –  Jaan Jan 27 at 18:09
    
"fast" just means tailored to the hardware architecture. If the registers are 16-bit, then int_fast8_t is a 16-bit value. If registers are 32-bit, then int_fast8_t and int_fast16_t are both 32-bit values. etc. See C99 section 7.18.1.3 paragraph 2. –  Jesse Chisholm Jun 8 at 16:34
    
As @Jaan pointed out, int32_t etc are in C++11 standard. I'd like to add that it can be accessed by #include <cstdint>. –  Peter Lamberg Sep 17 at 19:03
    
@PeterLamberg and Jaan: I have edited my answer now that these types are in the standard. Thanks for the reminder. –  Brian Neal Sep 18 at 3:06
    
@BrianNeal thanks for updating your answer. I had forgotten to upvote it, but that is now fixed too :) –  Peter Lamberg Sep 18 at 13:53

Nope, there is no standard for type sizes. Standard only requires that:

sizeof(short int) <= sizeof(int) <= sizeof(long int)

The best thing you can do if you want variables of a fixed sizes is to use macros like this:

#ifdef SYSTEM_X
  #define WORD int
#else
  #define WORD long int
#endif

Then you can use WORD to define your variables. It's not that I like this but it's the most portable way.

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2  
The problem is that WORD gets spread around the program into areas that are not truly dependent on a fixed size (look at some windows code). As I found out when moving from a 16 bit to 32 bit system you end up with the same problem that WORD was meant to solve. –  lilburne Feb 26 '09 at 9:46
    
@liburne Of course you should use WORD only when you need a fixed size variable, like when you are reading/writing from/to a file. If a piece of code is not really dependent from a fixed size, then you should use normal "int" variables. –  Emiliano Feb 26 '09 at 10:24
1  
Also, 1 = sizeof(char) <= sizeof(short int) <= ... –  Drew Hall Feb 27 '09 at 3:20
1  
The best thing you can do to get portable sizes should be #include <boost/cstdint.hpp> –  kizzx2 Apr 26 '11 at 8:55

The C++ Standard says it like this :

3.9.1, §2 :

There are five signed integer types : "signed char", "short int", "int", "long int", and "long 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 (44); the other signed integer types are provided to meet special needs.

(44) that is, large enough to contain any value in the range of INT_MIN and INT_MAX, as defined in the header <climits>.

The conclusion : it depends on which architecture you're working on. Any other assumption is false.

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We are allowed to define a synonym for the type so we can create our own "standard".

On a machine in which sizeof(int) == 4, we can define:

typedef int int32;

int32 i;
int32 j;
...

So when we transfer the code to a different machine where actually the size of long int is 4, we can just redefine the single occurrence of int.

typedef long int int32;

int32 i;
int32 j;
...

I know that this doesn't answer the question directly, but I hope that it can be useful to someone.

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There is a standard and it is specified in the various standards documents (ISO, ANSI and whatnot).

Wikipedia has a great page explaining the various types and the max they may store: Integer in Computer Science.

However even with a standard C++ compiler you can find out relatively easily using the following code snippet:

#include <iostream>
#include <limits>


int main() {
    // Change the template parameter to the various different types.
    std::cout << std::numeric_limits<int>::max() << std::endl;
}

Documentation for std::numeric_limits can be found at Roguewave. It includes a plethora of other commands you can call to find out the various limits. This can be used with any arbitrary type that conveys size, for example std::streamsize.

John's answer contains the best description, as those are guaranteed to hold. No matter what platform you are on, there is another good page that goes into more detail as to how many bits each type MUST contain: int types, which are defined in the standard.

I hope this helps!

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For floating point numbers there is a standard (IEEE754): floats are 32 bit and doubles are 64. This is a hardware standard, not a C++ standard, so compilers could theoretically define float and double to some other size, but in practice I've never seen an architecture that used anything different.

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2  
However, compliance with IEEE 754 (aka IEC 559) is optional within C++ (probably C too, but I'm not sure). See std::numeric_limits::is_iec559. –  Drew Hall Feb 27 '09 at 3:26
    
Then you haven't seen TI's compiler for TMS320C28xx DSPs, where double has the same size as float (and int the same as char, both are 16 bit). But they have a 64 bit long double. –  starblue Sep 21 '12 at 14:53

You can use:

cout << "size of datatype = " << sizeof(datatype) << endl;

datatype = int, long int etc. You will be able to see the size for whichever datatype you type.

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1) Table N1 in article "The forgotten problems of 64-bit programs development"

2) "Data model"

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When it comes to built in types for different architectures and different compilers just run the following code on your architecture with your compiler to see what it outputs. Below shows my ubuntu 13.04 64bit g++4.7.3 output. Also please note what was answered below which is why the output is ordered as such:

"There are five standard signed integer types : signed char, short int, int, long int, and long long int. In this list, each type provides at least as much storage as those preceding it in the list."

#include <iostream>

int main ( int argc, char * argv[] )
{
  std::cout<< "size of char: " << sizeof (char) << std::endl;
  std::cout<< "size of short: " << sizeof (short) << std::endl;
  std::cout<< "size of int: " << sizeof (int) << std::endl;
  std::cout<< "size of long: " << sizeof (long) << std::endl;
  std::cout<< "size of long long: " << sizeof (long long) << std::endl;

  std::cout<< "size of float: " << sizeof (float) << std::endl;
  std::cout<< "size of double: " << sizeof (double) << std::endl;

  std::cout<< "size of pointer: " << sizeof (int *) << std::endl;


}


size of char: 1
size of short: 2
size of int: 4
size of long: 8
size of long long: 8
size of float: 4
size of double: 8
size of pointer: 8
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As you mentioned - it largely depends upon the compiler and the platform

check herefor the ANSI standard http://home.att.net/~jackklein/c/inttypes.html

Here is the one for microsoft compiler http://msdn.microsoft.com/en-us/library/s3f49ktz(vs.71).aspx

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In addition to Brian Neal's answer, see also my answer to the stackoverflow question: What is the difference between an int and a long in C++?

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You can use variables provided by libraries such as OpenGL, Qt etc.

For example, Qt provides qint8 (guaranteed to be 8-bit on all platforms supported by Qt), qint16, qint32, qint64, quint8, quint16, quint32, quint64, etc.

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If you are interested in a pure C++ solution, I made use of templates and only C++ standard code to define types at compile time based on their bit size. This make the solution portable across compilers.

The idea behind is very simple: Create a list containing types char, int, short, long, long long (signed and unsigned versions) and the scan the list and by the use of numeric_limits template select the type with given size.

Including this header you got 8 type stdtype::int8, stdtype::int16, stdtype::int32, stdtype::int64, stdtype::uint8, stdtype::uint16, stdtype::uint32, stdtype::uint64.

If some type cannot be represented it will be evaluated to stdtype::null_type also declared in that header.

THE CODE BELOW IS GIVEN WITHOUT WARRANTY, PLEASE DOUBLE CHECK IT.
I'M NEW AT METAPROGRAMMING TOO, FEEL FREE TO EDIT AND CORRECT THIS CODE.
Tested with DevC++ (so a gcc version around 3.5)

#include <limits>

namespace stdtype
{
    using namespace std;


    /*
     * THIS IS THE CLASS USED TO SEMANTICALLY SPECIFY A NULL TYPE.
     * YOU CAN USE WHATEVER YOU WANT AND EVEN DRIVE A COMPILE ERROR IF IT IS 
     * DECLARED/USED.
     *
     * PLEASE NOTE that C++ std define sizeof of an empty class to be 1.
     */
    class null_type{};

    /*
     *  Template for creating lists of types
     *
     *  T is type to hold
     *  S is the next type_list<T,S> type
     *
     *  Example:
     *   Creating a list with type int and char: 
     *      typedef type_list<int, type_list<char> > test;
     *      test::value         //int
     *      test::next::value   //char
     */
    template <typename T, typename S> struct type_list
    {
        typedef T value;
        typedef S next;         

    };




    /*
     * Declaration of template struct for selecting a type from the list
     */
    template <typename list, int b, int ctl> struct select_type;


    /*
     * Find a type with specified "b" bit in list "list"
     *
     * 
     */
    template <typename list, int b> struct find_type
    {   
        private:
            //Handy name for the type at the head of the list
            typedef typename list::value cur_type;

            //Number of bits of the type at the head
            //CHANGE THIS (compile time) exp TO USE ANOTHER TYPE LEN COMPUTING
            enum {cur_type_bits = numeric_limits<cur_type>::digits};

        public:
            //Select the type at the head if b == cur_type_bits else
            //select_type call find_type with list::next
            typedef  typename select_type<list, b, cur_type_bits>::type type;
    };

    /*
     * This is the specialization for empty list, return the null_type
     * OVVERRIDE this struct to ADD CUSTOM BEHAVIOR for the TYPE NOT FOUND case
     * (ie search for type with 17 bits on common archs)
     */
    template <int b> struct find_type<null_type, b>
    {   
        typedef null_type type;

    };


    /*
     * Primary template for selecting the type at the head of the list if
     * it matches the requested bits (b == ctl)
     *
     * If b == ctl the partial specified templated is evaluated so here we have
     * b != ctl. We call find_type on the next element of the list
     */
    template <typename list, int b, int ctl> struct select_type
    {   
            typedef  typename find_type<typename list::next, b>::type type; 
    };

    /*
     * This partial specified templated is used to select top type of a list
     * it is called by find_type with the list of value (consumed at each call)
     * the bits requested (b) and the current type (top type) length in bits
     *
     * We specialice the b == ctl case
     */
    template <typename list, int b> struct select_type<list, b, b>
    {
            typedef typename list::value type;
    };


    /*
     * These are the types list, to avoid possible ambiguity (some weird archs)
     * we kept signed and unsigned separated
     */

    #define UNSIGNED_TYPES type_list<unsigned char,         \
        type_list<unsigned short,                           \
        type_list<unsigned int,                             \
        type_list<unsigned long,                            \
        type_list<unsigned long long, null_type> > > > >

    #define SIGNED_TYPES type_list<signed char,         \
        type_list<signed short,                         \
        type_list<signed int,                           \
        type_list<signed long,                          \
        type_list<signed long long, null_type> > > > >



    /*
     * These are acutally typedef used in programs.
     * 
     * Nomenclature is [u]intN where u if present means unsigned, N is the 
     * number of bits in the integer
     *
     * find_type is used simply by giving first a type_list then the number of 
     * bits to search for.
     *
     * NB. Each type in the type list must had specified the template 
     * numeric_limits as it is used to compute the type len in (binary) digit.
     */
    typedef find_type<UNSIGNED_TYPES, 8>::type  uint8;
    typedef find_type<UNSIGNED_TYPES, 16>::type uint16;
    typedef find_type<UNSIGNED_TYPES, 32>::type uint32;
    typedef find_type<UNSIGNED_TYPES, 64>::type uint64;

    typedef find_type<SIGNED_TYPES, 7>::type    int8;
    typedef find_type<SIGNED_TYPES, 15>::type   int16;
    typedef find_type<SIGNED_TYPES, 31>::type   int32;
    typedef find_type<SIGNED_TYPES, 63>::type   int64;

}
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As others have answered, the "standards" all leave most of the details as "implementation defined" and only state that type "char" is at leat "char_bis" wide, and that "char <= short <= int <= long <= long long" (float and double are pretty much consistent with the IEEE floating point standards, and long double is typically same as double--but may be larger on more current implementations).

Part of the reasons for not having very specific and exact values is because languages like C/C++ were designed to be portable to a large number of hardware platforms--Including computer systems in which the "char" word-size may be 4-bits or 7-bits, or even some value other than the "8-/16-/32-/64-bit" computers the average home computer user is exposed to. (Word-size here meaning how many bits wide the system normally operates on--Again, it's not always 8-bits as home computer users may expect.)

If you really need a object (in the sense of a series of bits representing an integral value) of a specific number of bits, most compilers have some method of specifying that; But it's generally not portable, even between compilers made by the ame company but for different platforms. Some standards and practices (especially limits.h and the like) are common enough that most compilers will have support for determining at the best-fit type for a specific range of values, but not the number of bits used. (That is, if you know you need to hold values between 0 and 127, you can determine that your compiler supports an "int8" type of 8-bits which will be large enought to hold the full range desired, but not something like an "int7" type which would be an exact match for 7-bits.)

Note: Many Un*x source packages used "./configure" script which will probe the compiler/system's capabilities and output a suitable Makefile and config.h. You might examine some of these scripts to see how they work and how they probe the comiler/system capabilities, and follow their lead.

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As mentioned the size should reflect the current architecture. You could take a peak around in limits.h if you want to see how your current compiler is handling things.

share|improve this answer
    
Thanks, but I would like to know the sizes for achitectures I don't have myselft (like 64bits). This tutorial only talk about 32bits achitectures... –  Jérôme Feb 26 '09 at 8:05
unsigned char bits = sizeof(X) << 3;

where X is a char,int,long etc.. will give you size of X in bits.

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there are 4 types of integer based on size. short integer : 2 byte long integer : 4 byte long long integer : 8 byte integer : depends upon the compiler(16 bit,32 bit,64 bit)

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8  
False, they all depend from the architecture, with the minimum ranges described in one of the other answers. Nothing stops an implementation to have short, int and long all 32 bit integers. –  Matteo Italia Sep 15 '11 at 23:24

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