8

Question

  • Is there a way to create a arbitrary size integer using c/c++?

For example:

int main(void) {
  Int i = Int(3); //3-bit integer
  i = 1; //Represented as: 001
}

Bonus

  • Is there a way to do the same with floating values?
8
  • 1
    You can write a class that does this.
    – user253751
    Feb 23, 2015 at 23:49
  • 2
    Not individually, but as part of a struct or class: bit field Feb 23, 2015 at 23:52
  • 1
    You'd have a stack overflow if you tried to do 1/3 in an arbitrary-sized floating point class !
    – MSalters
    Feb 24, 2015 at 0:09
  • 1
    Take a look here for small arbitrary size integers: stackoverflow.com/questions/11815894/… , that is if you are interested in saving memory (bit packing comes at a small performance penalty). For bigger than the standard types you'd probably be better off using some library.
    – dtech
    Feb 24, 2015 at 0:26
  • 2
    FYI, there is a C23 proposal (open-std.org/jtc1/sc22/wg14/www/docs/n2709.pdf "Adding a Fundamental Type for N-bit integers") for adding them via _BitInt(3). If it's approved, this may be an additional future answer. Dec 21, 2021 at 12:15

5 Answers 5

9

You can't create integers of size less than char (that is, each object has a size in bytes that's a multiple of sizeof(char), which is 1). But that's not a problem since you can pack numbers inside a larger number.

const unsigned size_in_bits = 3;
unsigned a = 1; // 001
unsigned b = 5; // 101
unsigned packed = (b << size_in_bits*1) | (a << size_in_bits*0); // 101001
unsigned unpacked_a = (packed >> size_in_bits*0) & ((1 << size_in_bits)-1);
unsigned unpacked_b = (packed >> size_in_bits*1) & ((1 << size_in_bits)-1);

or use bitfields (the syntax is nicer, but the binary layout is implementation-defined)

struct Date
{
    unsigned day : 5;
    unsigned month : 4;
    unsigned year : 21; 
};

Date d;
d.day = 5; d.month = 11; d.year = 2014;
2
  • could you please elaborate on "binary layout is implementation-defined"? Feb 24, 2015 at 0:47
  • @SimonOroño - there is no guarantee different compilers will produce the same layout. The standard leaves that "unstandardized" for compatibility with exotic platforms long gone. If you want portability, you better write your own "manual bitfields" as described in the question I linked in the comments above.
    – dtech
    Feb 24, 2015 at 0:51
5

You could try the GNU Multiple Precision Arithmetic Library library, which supports both integers, fractions, and real numbers.

5
  • 1
    Can I create a fixed size integer with gmp? For what I'm reading this creates python-like integers that grow as long as they have the memory required. Feb 24, 2015 at 0:09
  • @SimonOroño: At least for the floating-point support, it looks like you specify the number of bits to use: mpfr.org/sample.html
    – Ben Voigt
    Feb 24, 2015 at 0:14
  • 1
    The answer is missing the "smaller than a byte" aspect. Feb 24, 2015 at 0:20
  • @SimonOroño Aha; I didn't realize that sub-byte sizes was important to you. Feb 24, 2015 at 0:24
  • @SimonOroño if you want fixed width integer/floating-point types then you should use ttmath or boost::multiprecision
    – phuclv
    Feb 24, 2015 at 0:30
2

You could write a wrapper class around std::bitset or std::vector<bool>. These are bit containers.

Your class would contain one of the containers and add functionality for conversion to and from integral numbers; as well as other arithmetic operations.

This will allow you to have unusual bit sized integers, such as 3, 5 and 13.

Most implementations will round up to the nearest multiple of 8 or the processor's word size. A container of 3 bits would use a uint8_t with 5 unused bits, primary because its easier for the processor to manipulate. A 13-bit integer would reside in a 16-bit package.

Edit 1: Floating Point Number
Unless you conform to the standard floating point formats, you will have to write your own wrapper class. This would allow you to have 3 bits of mantissa, 5 bits of exponent and one bit for sign -- 9bits. Again, think about all the methods you would need to write. Most applications will use either double or float because there is no need to write separate wrappers which takes coding time and testing time.

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  • Wrapping around bitset or vector<bool> will be needlessly slow and complicated. Bitsets don't even support dynamic size, it has to be known at compile time.
    – dtech
    Feb 24, 2015 at 1:00
  • Custom bit sized variables will be needlessly slow and complicated because of the bit set, clear, extraction and packing. The bitset or vector<bool> are convenient containers. Feb 24, 2015 at 1:30
  • Depending on the requirements, you could get away with using a tremendously more efficient container than single bit based.
    – dtech
    Feb 24, 2015 at 1:33
  • Why is a bit container slower? what would be more efficient? @ddriver Feb 24, 2015 at 11:53
  • 1
    And ironically, on modern hardware operations on 64bit integer operations usually take a single clock cycle, whereas bit access requires 2-3 cycles for the access alone and you still have the actual operation to go. Computers can address a byte at least, so going below byte always has overhead of the bitwise operations needed to extract the value.
    – dtech
    Feb 24, 2015 at 12:07
1

Explanation:


You could always try to use integer and float manipulation using arrays. If the number is too big for array initialization, you could use the malloc(); function.

Please Note: This method is not very fast, because we will be allocating memory in the heap. You will also have to write your own mathematical operation functions, because I am not quite sure on how to implement it efficiently. SEE MORE BELOW


How to implement (sort of):


#include <stdio.h>
#include <stdlib.h>

#define MAX_DIGIT_COUNT 1000

int main()
{
    int* big_num = (int*)malloc(sizeof(int) * MAX_DIGIT_COUNT); //allocate memory
    for(int x; x<MAX_DIGIT_COUNT; x++)
    {
        /*
        *Iterating through number - iterating works, because we are basing out max number lenght 
        *off of the maximum digits, and therefore, we can have a maximum of 2^64 digits
        */
        big_num[x] = rand()%5; //fill up memory block with psuedo-random numbers
    }
    /*Printing begins here...*/
    for(int i; i<MAX_DIGIT_COUNT; i++)
    {
        int iterated;
        iterated = big_num[i];
        printf("%d", iterated);
    }
    printf("\n");
    /*Printing ends here*/
    return 0;
}

Please note: This is just a crude way of implementing arbitrary-sized number support in pure C.

1
  • By the way, you could use char arrays to improve memory efficiency...
    – user9111069
    Feb 8, 2018 at 5:13
-2

No, size of every primitive element (int,short,long...) depends of hardware architecture.

For bigger sizes, you should use one Big Integer library (they represent numbers with strings).

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  • Could you elaborate on what you mean by "strings"?
    – Neil Kirk
    Feb 23, 2015 at 23:57
  • Example: "94314". Strings can have one arbitrary size, so you can have bigger numbers.
    – amchacon
    Feb 24, 2015 at 0:00
  • 1
    The problem is redefine arithmethics operations. @NeilKirk
    – amchacon
    Feb 24, 2015 at 0:00
  • Why not represent an arbitrary integer with an array of ints of certain size? That will be much faster than a text string.
    – Neil Kirk
    Feb 24, 2015 at 0:13
  • 1
    "No, size of every primitive element (int,short,long...) depends of hardware architecture." Hmmm - With the same hardware platform, I can use various compilers and option settings and have control on the range of char (sign or unsigned), int (16 or 32), long (32 or 64 bit). I'd say the compiler has ultimate control. and not the hardware. Feb 24, 2015 at 1:01

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