Showing binary representation of floating point types in C++ [closed]

Question

Consider the following code for integral types:

template <class T>
std::string as_binary_string( T value ) {
    return std::bitset<sizeof( T ) * 8>( value ).to_string();
}

int main() {
    unsigned char a(2);
    char          b(4);

    unsigned short c(2);
    short          d(4);

    unsigned int   e(2);
    int            f(4);

    unsigned long long g(2);
    long long h(4);

    std::cout << "a = " << +a << " " << as_binary_string( a ) << std::endl;
    std::cout << "b = " << +b << " " << as_binary_string( b ) << std::endl;
    std::cout << "c = " << c << " " << as_binary_string( c ) << std::endl;
    std::cout << "d = " << c << " " << as_binary_string( d ) << std::endl;
    std::cout << "e = " << e << " " << as_binary_string( e ) << std::endl;
    std::cout << "f = " << f << " " << as_binary_string( f ) << std::endl;
    std::cout << "g = " << g << " " << as_binary_string( g ) << std::endl;
    std::cout << "h = " << h << " " << as_binary_string( h ) << std::endl;

    std::cout << "\nPress any key and enter to quit.\n";
    char q;
    std::cin >> q;

    return 0;
}

Pretty straight forward, works well and is quite simple.

---

EDIT

How would one go about writing a function to extract the binary or bit pattern of arbitrary floating point types at compile time?

---

When it comes to floats I have not found anything similar in any existing libraries of my own knowledge. I've searched google for days looking for one, so then I resorted into trying to write my own function without any success. I no longer have the attempted code available since I've originally asked this question so I can not exactly show you all of the different attempts of implementations along with their compiler - build errors. I was interested in trying to generate the bit pattern for floats in a generic way during compile time and wanted to integrate that into my existing class that seamlessly does the same for any integral type. As for the floating types themselves, I have taken into consideration the different formats as well as architecture endian. For my general purposes the standard IEEE versions of the floating point types is all that I should need to be concerned with.

iBug had suggested for me to write my own function when I originally asked this question, while I was in the attempt of trying to do so. I understand binary numbers, memory sizes, and the mathematics, but when trying to put it all together with how floating point types are stored in memory with their different parts {sign bit, base & exp } is where I was having the most trouble.

Since then with the suggestions those who have given a great answer - example I was able to write a function that would fit nicely into my already existing class template and now it works for my intended purposes.

Answer 1

What about writing one by yourself?

static_assert(sizeof(float) == sizeof(uint32_t));
static_assert(sizeof(double) == sizeof(uint64_t));

std::string as_binary_string( float value ) {
    std::uint32_t t;
    std::memcpy(&t, &value, sizeof(value));
    return std::bitset<sizeof(float) * 8>(t).to_string();
}

std::string as_binary_string( double value ) {
    std::uint64_t t;
    std::memcpy(&t, &value, sizeof(value));
    return std::bitset<sizeof(double) * 8>(t).to_string();
}

You may need to change the helper variable t in case the sizes for the floating point numbers are different.

You can alternatively copy them bit-by-bit. This is slower but serves for arbitrarily any type.

template <typename T>
std::string as_binary_string( T value )
{
    const std::size_t nbytes = sizeof(T), nbits = nbytes * CHAR_BIT;
    std::bitset<nbits> b;
    std::uint8_t buf[nbytes];
    std::memcpy(buf, &value, nbytes);

    for(int i = 0; i < nbytes; ++i)
    {
        std::uint8_t cur = buf[i];
        int offset = i * CHAR_BIT;

        for(int bit = 0; bit < CHAR_BIT; ++bit)
        {
            b[offset] = cur & 1;
            ++offset;   // Move to next bit in b
            cur >>= 1;  // Move to next bit in array
        }
    }

    return b.to_string();
}

Answer 2

You said it doesn't need to be standard. So, here is what works in clang on my computer:

#include <iostream>
#include <algorithm>

using namespace std;

int main()
{
  char *result;
  result=new char[33];
  fill(result,result+32,'0');
  float input;
  cin >>input;
  asm(
"mov %0,%%eax\n"
"mov %1,%%rbx\n"
".intel_syntax\n"
"mov rcx,20h\n"
"loop_begin:\n"
"shr eax\n"
"jnc loop_end\n"
"inc byte ptr [rbx+rcx-1]\n"
"loop_end:\n"
"loop loop_begin\n"
".att_syntax\n"
      :
      : "m" (input), "m" (result)
      );
  cout <<result <<endl;
  delete[] result;
  return 0;
}

This code makes a bunch of assumptions about the computer architecture and I am not sure on how many computers it would work.

EDIT:
My computer is a 64-bit Mac-Air. This program basically works by allocating a 33-byte string and filling the first 32 bytes with '0' (the 33rd byte will automatically be '\0').
Then it uses inline assembly to store the float into a 32-bit register and then it repeatedly shifts it to the right by one bit.
If the last bit in the register was 1 before the shift, it gets stored into the carry flag.
The assembly code then checks the carry flag and, if it contains 1, it increases the corresponding byte in the string by 1.
Since it was previously initialized to '0', it will turn to '1'.

So, effectively, when the loop in the assembly is finished, the binary representation of a float is stored into a string.

This code only works for x64 (it uses 64-bit registers "rbx" and "rcx" to store the pointer and the counter for the loop), but I think it's easy to tweak it to work on other processors.

Answer 3

An IEEE floating point number looks like the following

sign  exponent   mantissa
1 bit  11 bits    52 bits 

Note that there's a hidden 1 before the mantissa, and the exponent is biased so 1023 = 0, not two's complement. By memcpy()ing to a 64 bit unsigned integer you can then apply AND and OR masks to get the bit pattern. The arrangement could be big endian or little endian. You can easily work out which arrangement you have by passing easy numbers such as 1 or 2.

Answer 4

Generally people either use std::hexfloat or cast a pointer to the floating-point value to a pointer to an unsigned integer of the same size and print the indirected value in hex format. Both methods facilitate bit-level analysis of floating-point in a productive fashion.

Answer 5

You could roll your by casting the address of the float/double to a char and iterating it that way:

#include <memory>
#include <iostream>
#include <limits>
#include <iomanip>

template <typename T>
std::string getBits(T t) {
    std::string returnString{""};
    char *base{reinterpret_cast<char *>(std::addressof(t))};
    char *tail{base + sizeof(t) - 1};
    do {
        for (int bits = std::numeric_limits<unsigned char>::digits - 1; bits >= 0; bits--) {
            returnString += ( ((*tail) & (1 << bits)) ? '1' : '0');
        }
    } while (--tail >= base);
    return returnString;
}

int main() {
    float f{10.0};
    double d{100.0};
    double nd{-100.0};
    std::cout << std::setprecision(1);
    std::cout << getBits(f) << std::endl;
    std::cout << getBits(d) << std::endl;
    std::cout << getBits(nd) << std::endl;
}

Output on my machine (note the sign flip in the third output):

01000001001000000000000000000000
0100000001011001000000000000000000000000000000000000000000000000
1100000001011001000000000000000000000000000000000000000000000000