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I have two tasks for an assignment, one return the number of bits in type int on any machine. I thought I would write my function like so:

int CountIntBitsF() {
    int x = sizeof(int) / 8;
    return x;

Does that look right?

The second part is to return the number of any bits of any data type with a macro, and the macro can be taken from limits.h. I looked up limits.h on my machine, and also http://www.opengroup.org/onlinepubs/007908799/xsh/limits.h.html, but I don't think I really understand how any of those would return the number of bits in any data type. Any thoughts? Thanks.

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6 Answers 6

up vote 6 down vote accepted

It's *, not /.

As for the second part, see the "Numerical Limits" section.

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The fundamental unit of storage is a char. It is not always 8 bits wide. CHAR_BIT is defined in limits.h and has the number of bits in a char.

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In limits.h, UINT_MAX is the maximum value for an object of type unsigned int. Which means it is an int with all bits set to 1. So, counting the number of bits in an int:

#include <limits.h>

int intBits () {
    int x = INT_MAX;
    int count = 2; /* start from 1 + 1 because we assume
                    * that sign uses a single bit, which
                    * is a fairly reasonable assumption

    /* Keep shifting bits to the right until none is left.
     * We use divide instead of >> here since I personally
     * know some compilers which does not shift in zero as
     * the topmost bit
    while (x = x/2) count++;

    return count;
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Such compilers are violating the standard, fwiw. –  Roger Pate Jan 19 '10 at 3:19
@slebetman: you might be thinking about shifting signed values. For unsigned types, shifting is well-defined. –  Alok Singhal Jan 19 '10 at 3:28
One must remember that source code is turned into machine language by compilers, rather than by the documents specifying them. –  Crashworks Jan 19 '10 at 7:27
@slebetman: technically that's not an extension to the standard, it's just a violation, and the compiler in that mode is therefore not a C compiler, it's a compiler of some other language very similar to C. Otherwise, Java is an "extension" of the C standard, by adding and removing rules from C until you end up with Java ;-). An extension to the C standard is when you take something which would not be legal C, and define what it does in your implementation. It doesn't affect legal C. –  Steve Jessop Jan 19 '10 at 19:44
@slebetman: "Signed int and unsigned int have the same number of bits". I can't find that in the standard, do you know where it's stated? What rule do I break if in my implementation sizeof(unsigned int) == 4, UINT_MAX == 0xFFFFFFFF, sizeof(int) == 4, INT_MAX == 0x3FFFFFFF, and int has a padding bit for no good reason that I can think of other than lulz? –  Steve Jessop Jan 19 '10 at 19:48

If you want the number of bits used to store an int in memory, use Justin's answer, sizeof(int)*CHAR_BIT. If you want to know the number of bits used in the value, use slebetman's answer.

Although to get the bits in an INT, you should probably use INT_MAX rather than UINT_MAX. I can't remember whether C99 actually guarantees that int and unsigned int are the same width, or just that they're the same storage size. I suspect only the latter, since in we have "if there are M value bits in the signed type and N in the unsigned type, then M <= N", not "M = N or M = N-1".

In practice, integral types don't have padding bits in any implementation I've used, so you most likely get the same answer for all, +/- 1 for the sign bit.

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Another quote from C99 draft ( For each of the signed integer types, there is a corresponding (but different) unsigned integer type (designated with the keyword unsigned) that uses the same amount of storage (including sign information) and has the same alignment requirements. –  Alok Singhal Jan 19 '10 at 3:33
Thanks. And note "same amount of storage", not saying "same number of non-padding bits". –  Steve Jessop Jan 19 '10 at 3:44
Why do we need to know the difference between an int in memory vs the bits used in the value. Is the bits used in the value more important if you were doing some sort of hardware programming where you needed to know the number of bits used to represent certain register values or something along those lines? –  Crystal Jan 19 '10 at 4:52
Yes, there are many important reasons to care about the bitwidth of an int. For one thing, it determines how large a value may be stored (ie, a signed 16 bit int can store -32768..32767 while an unsigned 16bit int can store 0..65535 and so on). It's also significant if you need to serialize your data, ie for saving to a file or transmitting across the network. –  Crashworks Jan 19 '10 at 6:49

With g++ -O2 this function evaluates to an inline constant:

#include <climits>
#include <stddef.h>
#include <stdint.h>
#include <cstdio>

template <typename T>
size_t num_bits()
    return sizeof (T) * (CHAR_BIT);

int main()
    printf("uint8_t : %d\n", num_bits<uint8_t>());
    printf("size_t : %d\n", num_bits<size_t>());
    printf("long long : %d\n", num_bits<long long>());
    printf("void* : %d\n", num_bits<void*>());
    printf("bool : %d\n", num_bits<bool>());
    printf("float : %d\n", num_bits<float>());
    printf("double : %d\n", num_bits<double>());
    printf("long double : %d\n", num_bits<long double>());

    return 0;


uint8_t : 8
size_t : 32
long long : 64
void* : 32
bool : 8
float : 32
double : 64
long double : 96

Generated X86 32-bit assember:


movl    $32, 8(%esp)      <--- const $32
movl    $.LC1, 4(%esp)
movl    $1, (%esp)
call    __printf_chk
movl    $64, 8(%esp)      <--- const $64
movl    $.LC2, 4(%esp)
movl    $1, (%esp)
call    __printf_chk


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Are you sure you want number of bits, not number of bytes? In C, for a given type T, you can find the number of bytes it takes by using the sizeof operator. The number of bits in a byte is CHAR_BIT, which usually is 8, but can be different.

So, given a type T, the number of bits in an object of type T is:

#include <limits.h>
size_t nbits = sizeof(T) * CHAR_BIT

Note that, except for unsigned char type, all possible combinations of nbits bits above may not represent a valid value of type T.

For the second part, note that you can apply sizeof operator to an object as well as a type. In other words, given a type T and an object x of such type:

T x;

You can find the size of T by sizeof(T), and the size of x by sizeof x. The parentheses are optional if sizeof is used for an object.

Given the information above, you should be able to answer your second question. Ask again if you still have issues.

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