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# How can I convert a binary to a float number

I want to convert a binary number into a float number. Here's an example of a possibility:

``````>>> float(-0b1110)
``````

gives me the correct output:

``````-14.0
``````

Unfortunately, I am working with binary strings, i.e., I need something like float('-0b1110'). However, this doesn't work:

``````>>> float('-0b1110')
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ValueError: invalid literal for float(): -0b1110
``````

I tried to use *binascii.a2b_qp(string[, header])* which converts a block of quoted-printable data back to binary and returns the binary data. But eventually, I get the same error:

``````>>> float(binascii.a2b_qp('-0b1110'))
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ValueError: invalid literal for float(): -0b1110
``````

I understand the cases where the output number is an integer but what if I want to obtain the number 12.546? How should the function call for the binary string look like then?

-
What would the binary representation of `12.546` look like -- is it IEEE 754 binary32 or binary64? If not, how is the binary point represented or where is its assumed position in the string? – martineau Jan 6 '12 at 3:10
The binary representation of the float 12.546 is IEEE 754 binary64. – deedee Jan 6 '12 at 14:10
OK, but `'0b10110011000000'` is the IEEE 754 binary64 representation of `-14.0`, not '-0b1110'. – martineau Jan 7 '12 at 3:43
Actually, the IEEE 754 binary64 representation of `-14.0` is `'1100000000101100000000000000000000000000000000000000000000000000'` (in my previous comment the number shown was the little-endian interpretation, but the point made remains the same). – martineau Jan 7 '12 at 18:33

``````float(int('-0b1110',0))
``````

That works for me.

If you have a 64-bit string that represents a floating point number rather than an integer, you can do a three-step conversion - the first step turns the string into an integer, the second converts it into an 8-byte string, and the third re-interprets those bits as a float.

``````>>> import struct
>>> s = '0b0100000000101001000101111000110101001111110111110011101101100100'
>>> q = int(s, 0)
>>> b8 = struct.pack('Q', q)
>>> struct.unpack('d', b8)[0]
12.546
``````

Of course you can combine all those steps into a single line.

``````>>> s2 = '0b1100000000101100000000000000000000000000000000000000000000000000'
>>> struct.unpack('d', struct.pack('Q', int(s2, 0)))[0]
-14.0
``````
-
according to wikipedia 0 10000000 10010010000111111011011 this is the value of pi rounded for 24 bits of precision. >>> float(int('0b01000000010010010000111111011011',0)) 1078530011.0 – user173973 Jan 6 '12 at 0:07
huh???????????? – wim Jan 6 '12 at 0:23
@wim en.wikipedia.org/wiki/… otherwise what's the point in converting to float if in can only get the integer part. – user173973 Jan 6 '12 at 0:27
But Python doesn't support binary floats anyway, so none of these solutions (including `ast.literal_eval`) will work. – kindall Jan 6 '12 at 0:41
@nvm, the question uses an integer binary constant as an example. This is completely at odds with the requirement for floating point binary, as the representation of -14.0 is not -0b1110. – Mark Ransom Jan 6 '12 at 1:03

Another option is to do

``````from ast import literal_eval

float_str = "-0b101010101"
result = float(literal_eval(float_str))
``````

Unlike the built-in "eval", literal_eval is safe to be run even on user inputs, as it can only parse Python literals - and will not execute expressions, which means it will not call functions as well.

-

In one of your comments you indicated that the binary number represents a float in 8 byte long IEEE 754 binary64 format. However this is inconsistent with the `-0b1110` value you showed as an example, so I've ignored that and and attempted to provide my own properly formatted example input data to test the answer shown below.

Essentially what is done is first the binary string in converted into an integer value, then next into a string of raw bytes, and lastly is passed to`struct.unpack()`for conversion to a floating point value. The `bin_to_float()` function shown below drives the process. Although not illustrated, the binary input string argument can be prefixed with`'0b'`.

``````import struct

def bin_to_float(b):
""" convert binary string to float """
bf = int_to_bytes(int(b, 2), 8)  # 8 bytes needed for IEEE 754 binary64
return struct.unpack('>d', bf)[0]

def int_to_bytes(n, minlen=0):  # helper function
""" int/long to byte string """
nbits = n.bit_length() + (1 if n < 0 else 0)  # plus one for any sign bit
nbytes = (nbits+7)/8  # number of whole bytes
bytes = []
for i in range(nbytes):
bytes.append(chr(n & 0xff))
n >>= 8
if minlen > 0 and len(bytes) < minlen:
bytes.extend((minlen-len(bytes)) * '0')
bytes.reverse()  # put high bytes at beginning
return ''.join(bytes)

# tests

def float_to_bin(f):
""" convert float to binary string """
ba = struct.pack('>d', f)
s = ''.join('{:08b}'.format(ord(b)) for b in ba)
for i in range(len(s)):
if s[i] != '0':
break
else:  # all zeros
s = '0'
i = 0
return s[i:]

import math

floats = [0.0, 1.0, -14.0, 12.546, math.pi]

for f in floats:
binary = float_to_bin(f)
print 'float_to_bin(%f): %r' % (f, binary)
float = bin_to_float(binary)
print 'bin_to_float(%r): %f' % (binary, float)
print
``````

Test output:

``````float_to_bin(0.000000): '0'
bin_to_float('0'): 0.000000

float_to_bin(1.000000): '11111111110000000000000000000000000000000000000000000000000000'
bin_to_float('11111111110000000000000000000000000000000000000000000000000000'): 1.000000

float_to_bin(-14.000000): '1100000000101100000000000000000000000000000000000000000000000000'
bin_to_float('1100000000101100000000000000000000000000000000000000000000000000'): -14.000000

float_to_bin(12.546000): '100000000101001000101111000110101001111110111110011101101100100'
bin_to_float('100000000101001000101111000110101001111110111110011101101100100'): 12.546000

float_to_bin(3.141593): '100000000001001001000011111101101010100010001000010110100011000'
bin_to_float('100000000001001001000011111101101010100010001000010110100011000'): 3.141593
``````
-
This is great. Exactly what I was looking for, thank you! – Savara Aug 14 '15 at 11:25

You could use eval('') and then cast it as a float if needed. Example:

``````>> eval('-0b1110')
-14
>> float(eval('-0b1110'))
-14.0
``````
-
Good one, but see the ast.literal_eval on my answer - it is an interesting trick to have under the belt. – jsbueno Jan 6 '12 at 0:06
yeah, eval is evil – wim Jan 6 '12 at 0:07

You can convert a binary number in string form to an int by setting the base to 2 in the built-in `int([x[, base]])` function, however you need to get rid of the `0b` first. You can then pass the result into `float()` to get your final result:

``````>>> s = '-0b1110'
>>> float(int(s.replace('0b', ''), 2))
-14.0
``````

edit: Apparently getting rid of the `0b` is only necessary on Python 2.5 and below, Mark's answer works fine for me on Python 2.6 but here is what I see on Python 2.5:

``````>>> int('-0b1110', 2)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ValueError: invalid literal for int() with base 2: '-0b1110'
``````
-

This works for me. Tested with Python3.4:

``````def float_to_bin(num):
return bin(struct.unpack('!I', struct.pack('!f', num))[0])[2:].zfill(32)

def bin_to_float(binary):
return struct.unpack('!f',struct.pack('!I', int(binary, 2)))[0]

float_to_bin(bin_to_float(float_to_bin(123.123))) == float_to_bin(123.123)
>>> True
``````
-