# Floating Point to Binary Value(C++)

I want to take a floating point number in C++, like 2.25125, and a int array filled with the binary value that is used to store the float in memory (IEEE 754).

So I could take a number, and end up with a int num[16] array with the binary value of the float: num[0] would be 1 num[1] would be 1 num[2] would be 0 num[3] would be 1 and so on...

Putting an int into an array isn't difficult, just the process of getting the binary value of a float is where I'm stuck. Can you just read the binary in the memory that the float variable? If not, how could I go about doing this in C++?

EDIT: The reason for doing the comparison this way is that I am wanting to learn to do bitwise operations in C++.

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Out of curiosity - why do you need one integer per bit? –  Arkadiy Jan 23 '09 at 19:30

Use union and bitset:

#include <iostream>
#include <bitset>

int main()
{
union
{
float input;   // assumes sizeof(float) == sizeof(int)
int   output;
}    data;

data.input = 2.25125;

std::bitset<sizeof(float) * CHAR_BIT>   bits(data.output);

std::cout << bits << std::endl;

// or

std::cout << "BIT 4: " << bits[4] << std::endl;
std::cout << "BIT 7: " << bits[7] << std::endl;
}

It may not be an array but you can access bits with [] operator as if you were using an array.

Output

\$ ./bits
01000000000100000001010001111011
BIT 4: 1
BIT 7: 0
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This looks really promising. After I get home I will test it out. Thanks! –  user58389 Jan 23 '09 at 22:25
Yep! This is exactly what I was looking for. Thank you Seattle! –  user58389 Jan 23 '09 at 23:37
ieee754 floats are always 32 bits, c++ is spec'ed to use ieee754 for it floating point types. Long is also spec'ed to be 32 bits. Change the union to use long instead of int, and you'll have truly portable code. –  deft_code Feb 11 '09 at 17:50
@deft_code: C++ is NOT spec'ed to use ieee754 (it can be). Long is NOT spec'ed as 32 bits (it must be at least 32). This will never be portable as assigning to one field in a union and reading from another is unspecified behavior. If I am incorrect about either of the above please let me know the clause in the C++ standards where it is defined because a simple search showed both statements as wrong. –  Loki Astari May 4 '13 at 0:22

other approach, using stl

#include <iostream>
#include <bitset>

using namespace std;
int main()
{
float f=4.5f;
cout<<bitset<sizeof f*8>(*(long unsigned int*)(&f))<<endl;
return 0;
}
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Well I don't believe C++ has any real safe way to store floats without some sort of issue. When it comes to moving between machines and is both efficient and easily stored without using a large storage capacity.

It's very accurate, but it won't support really insane values. You will be able to have up to 7 digits in any location, but you can't exceed 7 digits on either side. For the left you'll receive inaccurate results. On the right you'll get an error during read time. To resolve the error you can throw an error during the write or perform "buffer[idx++] & 0x7" on the read to prevent it from going outside 0 and 7 bounds. Keep in mind "& 0x7" only works because it's a power of 2 minus one. Which is 2^3 - 1. You can only do that with those values E.g. 0, 1, 3, 7, 15, 31, 63, 127, 255, 511, 1023, etc...

So it's up to you if you want to use this or not. I felt it was a safe way to get most values you'll ever need. The example below shows how it's converted into a 4 byte array, but for C++ this would be a char*. If you don't want to perform division you can convert the POWERS_OF_TEN array into a secondary array with decimals and multiple instead.

{
1.0F, 10.0F, 100.0F, 1000.0F, 10000.0F, 100000.0F, 1000000.0F, 10000000.0F
};

{
if (flags & 0x1)
value = -value;
return value / POWERS_OF_TEN[(flags >> 1) & 0x7];
}

{
}

{
}

{
int exponent = -1;
float ceiling = 0.0F;

for ( ; ++exponent < 8; )
{
ceiling = (POWERS_OF_TEN[exponent] * data);
if (ceiling == (int)ceiling)
break;
}

exponent = exponent << 0x1;
int ceil = (int)ceiling;
if (ceil < 0)
{
exponent |= 0x1;
ceil = -ceil;
}
buffer[writer_position++] = (signed __int16)(exponent);
buffer[writer_position++] = (signed __int16)(ceil >> 16);
buffer[writer_position++] = (signed __int16)(ceil >> 8);
buffer[writer_position++] = (signed __int16)(ceil);
}
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Easiest way:

float myfloat;
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int fl = *(int*)&floatVar; //assuming sizeof(int) = sizeof(float)

int binaryRepresentation[sizeof(float) * 8];

for (int i = 0; i < sizeof(float) * 8; ++i)
binaryRepresentation[i] = ((1 << i) & fl) != 0 ? 1 : 0;

## Explanation

(1 << i) shifts the value 1, i bits to the left. The & operator computes the bitwise and of the operands.

The for loop runs once for each of the 32 bits in the float. Each time, i will be the number of the bit we want to extract the value from. We compute the bitwise and of the number and 1 << i:

Assume the number is: 1001011, and i = 2

1<<i will be equal to 0000100

10001011
& 00000100
==========
00000000

if i = 3 then:

10001011
& 00001000
==========
00001000

Basically, the result will be a number with ith bit set to the ith bit of the original number and all other bits are zero. The result will be either zero, which means the ith bit in the original number was zero or nonzero, which means the actual number had the ith bit equal to 1.

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That's not what he wants: The binary representation must be an array of size sizeof(float) * CHAR_BIT (-1) –  Christoph Jan 23 '09 at 19:03
@Christoph: I doubt so. Look at the question. He says he wants a binary representation of the float in an int array. –  Mehrdad Afshari Jan 23 '09 at 19:16
continued: To quote from the question: "So I could take a number, and end up with a int num[16] array with the binary value of the float: num[0] would be 1 num[1] would be 1 num[2] would be 0 num[3] would be 1 and so on..." –  Mehrdad Afshari Jan 23 '09 at 19:17
He wants the int array to contain the bit pattern, ie one int for each bit - therefore, its size must be the number of bits in a float variable, ie 32 (he incorrectly assumed that a float value takes 16 bits...) –  Christoph Jan 23 '09 at 19:23
Oops, my fault. Thanks for the point. –  Mehrdad Afshari Jan 23 '09 at 19:32

Looking at the comments in this answer (http://stackoverflow.com/questions/474007/floating-point-to-binary-valuec#474014) the reason to do this is to perform a bitwise comparison of two values.

#include <iostream>

int main()
{
union Flip
{
float input;   // assumes sizeof(float) == sizeof(int)
int   output;
};

Flip    data1;
Flip    data2;
Flip    data3;

data1.input = 2.25125;
data2.input = 2.25126;
data3.input = 2.25125;

bool    test12  = data1.output ^ data2.output;
bool    test13  = data1.output ^ data3.output;
bool    test23  = data2.output ^ data3.output;

std::cout << "T1(" << test12 << ") T2(" << test13 << ") T3(" << test23 << ")\n";

}
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You can use an unsigned char to read the float byte by byte into the integer array:

unsigned int bits[sizeof (float) * CHAR_BIT];
unsigned char const *c = static_cast<unsigned char const*>(
static_cast<void const*>(&my_float)
);

for(size_t i = 0; i < sizeof(float) * CHAR_BIT; i++) {
int bitnr = i % CHAR_BIT;
bits[i] = (*c >> bitnr) & 1;
if(bitnr == CHAR_BIT-1)
c++;
}

// the bits are now stored in "bits". one bit in one integer.

By the way, if you just want to compare the bits (as you comment on another answer) use memcmp:

memcmp(&float1, &float2, sizeof (float));
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Create a union of float and and unsigned long. set the value of the float member and iterate over the bits of the unsigned long value as already described in other answers.

This will eliminate the cast operators.

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Can you just read the binary in the memory that the float variable?

Yes. Static cast a pointer to it to an int pointer and read the bits from the result. An IEEE 754 float is 32 bits.

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If you need a particular floating point representation, you'll have to build that up semantically from the float itself, not by bit-copying.

c0x standard: http://c0x.coding-guidelines.com/5.2.4.2.2.html doesn't define the format of floating point numbers.

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Cast the int pointer to a float pointer, and you're done.

(Though I wouldn't declare it as an int array. I'd use void* to make it clear the the memory is being used as a dumping ground for other values.)

Incidentally, why don't you just use an array of floats?

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