# Binary representation of float in Python (bits not hex)

How to get the string as binary IEEE 754 representation of a 32 bit float?

Example

1.00 -> '00111111100000000000000000000000'

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You can do that with the `struct` package:

``````import struct
def binary(num):
return ''.join(bin(ord(c)).replace('0b', '').rjust(8, '0') for c in struct.pack('!f', num))
``````

That packs it as a network byte-ordered float, and then converts each of the resulting bytes into an 8-bit binary representation and concatenates them out:

``````>>> binary(1)
'00111111100000000000000000000000'
``````

Edit: There was a request to expand the explanation. I'll expand this using intermediate variables to comment each step.

``````def binary(num):
# Struct can provide us with the float packed into bytes. The '!' ensures that
# it's in network byte order (big-endian) and the 'f' says that it should be
# packed as a float. Alternatively, for double-precision, you could use 'd'.
packed = struct.pack('!f', num)
print 'Packed: %s' % repr(packed)

# For each character in the returned string, we'll turn it into its corresponding
# integer code point
#
# [62, 163, 215, 10] = [ord(c) for c in '>\xa3\xd7\n']
integers = [ord(c) for c in packed]
print 'Integers: %s' % integers

# For each integer, we'll convert it to its binary representation.
binaries = [bin(i) for i in integers]
print 'Binaries: %s' % binaries

# Now strip off the '0b' from each of these
stripped_binaries = [s.replace('0b', '') for s in binaries]
print 'Stripped: %s' % stripped_binaries

# Pad each byte's binary representation's with 0's to make sure it has all 8 bits:
#
# ['00111110', '10100011', '11010111', '00001010']
padded = [s.rjust(8, '0') for s in stripped_binaries]

# At this point, we have each of the bytes for the network byte ordered float
# in an array as binary strings. Now we just concatenate them to get the total
# representation of the float:
``````

And the result for a few examples:

``````>>> binary(1)
Packed: '?\x80\x00\x00'
Integers: [63, 128, 0, 0]
Binaries: ['0b111111', '0b10000000', '0b0', '0b0']
Stripped: ['111111', '10000000', '0', '0']
'00111111100000000000000000000000'

>>> binary(0.32)
Packed: '>\xa3\xd7\n'
Integers: [62, 163, 215, 10]
Binaries: ['0b111110', '0b10100011', '0b11010111', '0b1010']
Stripped: ['111110', '10100011', '11010111', '1010']
'00111110101000111101011100001010'
``````
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@MarkRansom -- you might be right, but it seems like there is an awful lot of string manipulation which is going on for each bit that doesn't need to be done ... – mgilson May 8 '13 at 15:59
I agree with @mgilson -- I actually prefer his solution, but with a single final `replace` and `rjust` to 32 (or 64), rather than one for each byte. – Dan Lecocq May 8 '13 at 16:01
@MarkRansom: `bin(struct.unpack('!Q', struct.pack('!d', -1.))[0])[2:].zfill(64)` works for doubles (64-bit floats). – J.F. Sebastian May 8 '13 at 16:46
For Python 3 you must omit the call to ord() since pack() returns a bytes object which yields integers directly when iterated over. – Rob Smallshire Feb 25 '14 at 9:57
@0xAffe, updated with a more in-depth explanation. – Dan Lecocq Nov 13 '14 at 17:45

Here's an ugly one ...

``````>>> import struct
>>> bin(struct.unpack('!i',struct.pack('!f',1.0))[0])
'0b111111100000000000000000000000'
``````

Basically, I just used the struct module to convert the float to an int ...

Here's a slightly better one using `ctypes`:

``````>>> import ctypes
>>> bin(ctypes.c_int.from_buffer(ctypes.c_float(1.0)).value)
'0b111111100000000000000000000000'
``````

Basically, I construct a `float` and use the same memory location, but I tag it as a `c_int`. The `c_int`'s value is a python integer which you can use the builtin `bin` function on.

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it relies on `sizeof(int) == sizeof(float)` (use `'!'` to force `4` bytes for `i` format). `ctypes.sizeof(ctypes.c_int)` might depend on platform. There is `int.from_bytes()` on Python 3.2+ – J.F. Sebastian May 8 '13 at 16:11
@J.F.Sebastian -- I suppose I'm also assuming that `bin` returns the IEEE standard representation... – mgilson May 8 '13 at 16:19
no. I don't understand what you're talking about. – J.F. Sebastian May 8 '13 at 16:25
I suppose I don't either. The `bin` function doesn't guarantee much about the output -- Only that it is an object that python can handle. If the `sizeof(int) != sizeof(float)` then it's not using IEEE 754 (is it?). In that case, the bit pattern returned by `bin` could be anything as well -- e.g. the bits could be reported backward or something due to different endianness. The sign bit could be some place else, etc. etc. – mgilson May 8 '13 at 16:29
`sizeof(int) != sizeof(float)` issue is unrelated to `bin()` (that works on Python integers that are unlimited). To support negative floats, use `!I` format. – J.F. Sebastian May 8 '13 at 16:41

This problem is more cleanly handled by breaking it into two parts.

The first is to convert the float into an int with the equivalent bit pattern:

``````def float32_bit_pattern(value):
return sum(ord(b) << 8*i for i,b in enumerate(struct.pack('f', value)))
``````

Next convert the int to a string:

``````def int_to_binary(value, bits):
return bin(value).replace('0b', '').rjust(bits, '0')
``````

Now combine them:

``````>>> int_to_binary(float32_bit_pattern(1.0), 32)
'00111111100000000000000000000000'
``````
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`float32_bit_pattern` can be defined as `lambda x: int.from_bytes(struct.pack("f", x), byteorder="little")` on Python 3.2+ – Janus Troelsen Sep 30 '14 at 16:25

Found another solution using the bitstring module.

``````import bitstring
f1 = bitstring.BitArray(float=1.0, length=32)
``````

Output:

``````00111111100000000000000000000000
``````
-

After browsing through lots of similar questions I've written something which hopefully does what I wanted.

``````f = 1.00
negative = False
if f < 0:
f = f*-1
negative = True

s = struct.pack('>f', f)
p = struct.unpack('>l', s)[0]
hex_data =  hex(p)

scale = 16
num_of_bits = 32
binrep = bin(int(hex_data, scale))[2:].zfill(num_of_bits)
if negative:
binrep = '1' + binrep[1:]
``````

`binrep` is the result. Each part will be explained.

``````f = 1.00
negative = False
if f < 0:
f = f*-1
negative = True
``````

Converts the number to a positive if negative, and sets the variable negative to false. The reason for this is that the difference between positive and negative binary representations is just in the first bit, and this was the simpler way than to figure out what goes wrong when doing the whole process with negative numbers.

``````s = struct.pack('>f', f)                          #'?\x80\x00\x00'
p = struct.unpack('>l', s)[0]                     #1065353216
hex_data =  hex(p)                                #'0x3f800000'
``````

`s` is a hex representation of the binary `f`. it is however not in the pretty form i need. Thats where p comes in. It is the int representation of the hex s. And then another conversion to get a pretty hex.

``````scale = 16
num_of_bits = 32
binrep = bin(int(hex_data, scale))[2:].zfill(num_of_bits)
if negative:
binrep = '1' + binrep[1:]
``````

`scale` is the base 16 for the hex. `num_of_bits` is 32, as float is 32 bits, it is used later to fill the additional places with 0 to get to 32. Got the code for `binrep` from this question. If the number was negative, just change the first bit.

I know this is ugly, but i didn't find a nice way and I needed it fast. Comments are welcome.

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`bin(struct.unpack('!I', struct.pack('!f', -1.))[0])[2:].zfill(32)` supports positive/negative floats. To improve performance you could modify `b2a_bin(struct.pack('!f', -1.))` to accept floats directly. – J.F. Sebastian May 8 '13 at 16:34

You can use the .format for the easiest representation of bits in my opinion:

my code would look something like:

``````def fto32b(flt):
# is given a 32 bit float value and converts it to a binary string
if isinstance(flt,float):
# THE FOLLOWING IS AN EXPANDED REPRESENTATION OF THE ONE LINE RETURN
#   packed = struct.pack('!f',flt) <- get the hex representation in (!)Big Endian format of a (f) Float
#   integers = []
#   for c in packed:
#       integers.append(ord(c))    <- change each entry into an int
#   binaries = []
#   for i in integers:
#       binaries.append("{0:08b}".format(i)) <- get the 8bit binary representation of each int (00100101)
#   binarystring = ''.join(binaries) <- join all the bytes together
#   return binarystring
return ''.join(["{0:08b}".format(i) for i in [ord(c) for c in struct.pack('!f',flt)]])
return None
``````

Output:

``````>>> a = 5.0
'01000000101000000000000000000000'
>>> b = 1.0
'00111111100000000000000000000000'
``````
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