I am working with Python3.2. I need to take a hex stream as an input and parse it at bit-level. So I used


to convert the string to actual bytes. Now how do I convert these bytes to bits?

  • 2
    Bytes are bits, just 8 at a time ;) - The answer depends on what you want to do, please be more specific Also bit-manipulation is mostly done on byte level... Jan 11, 2012 at 7:27
  • 1
    I want to represent the bytes in the form a bit string so that I can do something like: field1 = bit_string[0:1] field2 = bit_string[1:16] and so on
    – user904832
    Jan 11, 2012 at 7:31
  • 1
    Confusing title. Hexadecimals are nothing to do with bytes. Title should be: "Convert hexadecimals to bits in python"
    – illuminato
    Feb 13, 2022 at 16:30

14 Answers 14


Another way to do this is by using the bitstring module:

>>> from bitstring import BitArray
>>> input_str = '0xff'
>>> c = BitArray(hex=input_str)
>>> c.bin

And if you need to strip the leading 0b:

>>> c.bin[2:]

The bitstring module isn't a requirement, as jcollado's answer shows, but it has lots of performant methods for turning input into bits and manipulating them. You might find this handy (or not), for example:

>>> c.uint
>>> c.invert()
>>> c.bin[2:]


  • 5
    +1. And for the latest version of bitstring (3.0) you don't need to strip the leading 0b. Jan 11, 2012 at 9:00
  • I have found that, for most cases, bitstring has far worse performance than python builtins like struct.pack/unpack
    – JeremyKun
    Dec 11, 2022 at 19:58
  • It will likely help others who come to this question for you to show examples of how those builtins work. If you have time to post an answer, please do. Dec 12, 2022 at 17:56
  • In your example, the currnet version of the library won't return a number like '0b1111111' instead it will return without the prefix, so I have been looking into how to pad the number if it representation is less than 8 bit , do you know if it is possible using the bitstring library?
    – mhanuel
    Feb 1 at 14:08

What about something like this?

>>> bin(int('ff', base=16))

This will convert the hexadecimal string you have to an integer and that integer to a string in which each byte is set to 0/1 depending on the bit-value of the integer.

As pointed out by a comment, if you need to get rid of the 0b prefix, you can do it this way:

>>> bin(int('ff', base=16))[2:]

... or, if you are using Python 3.9 or newer:

>>> bin(int('ff', base=16)).removepreffix('0b')

Note: using lstrip("0b") here will lead to 0 integer being converted to an empty string. This is almost always not what you want to do.

  • lstrip('-0b') # remove leading zeros and minus sign
    – ahoffer
    Jan 11, 2012 at 7:35
  • @ahoffer Thanks for your comment. I've updated my answer to let the OP know how to remove the 0b prefix.
    – jcollado
    Jan 11, 2012 at 7:39
  • 11
    Note that lstrip('0b') will also remove, say, 00bb since the argument to lstrip is a set of characters to remove. It'll work fine in this case, but I prefer the [2:] solution since it's more explicit. Jan 11, 2012 at 7:45
  • @MartinGeisler Yes, bin leading zeros are already removed when converting to an integer, but it's worth to note that lstrip removes a set of characters, not a prefix.
    – jcollado
    Jan 11, 2012 at 7:50
  • 1
    Do not use lstrip for this! It will remove ALL leading zeroes, so this will convert 0 integer to an empty string! The only valid way of doing this without indexing would be using str.removeprefix(). Dec 22, 2022 at 2:53

Operations are much faster when you work at the integer level. In particular, converting to a string as suggested here is really slow.

If you want bit 7 and 8 only, use e.g.

val = (byte >> 6) & 3

(this is: shift the byte 6 bits to the right - dropping them. Then keep only the last two bits 3 is the number with the first two bits set...)

These can easily be translated into simple CPU operations that are super fast.


using python format string syntax

>>> mybyte = bytes.fromhex("1F") # mybyte = b'\x1f'
>>> myhex = mybyte.hex() # myhex = '1f'
>>> myint = int(myhex, 16) # myint = 31
>>> binary_string = "{:08b}".format(myint) # binary_string = '00011111'
>>> print(binary_string)

Byte objects (b'\x1f') have a .hex() method, which returns a normal string made up of characters '0' to 'F'. Using this plain string, we then convert it to an int, using the int() function that takes a string as input, and also that it's a base 16 string (because hex is base 16).

So then we have a normal int, that we want to represent as binary. The next step is we make a new string, using the python string formatting mini-language to apply formatting to that integer so it looks like a binary string.

The "{:08b}".format(myint) line is where the magic happens. The {:08b} uses the Format Specification Mini-Language format_spec. Specifically it's using the width and the type parts of the format_spec syntax. The 8 sets width to 8, and the 0 before the 8 tells it to pad with zeros (this is how we get the nice 000 padding), and the b sets the type to binary.

I prefer this method over the bin() built-in function because using a format string gives a lot more flexibility. This fact is even mentioned in the official python docs as part of the bin() docs. The docs suggest to use a format string if you want more flexibility.

  • but this method doesn't let you take a variable number of bytes as input, right? you need to hard-code how long the final binary string needs to be. Aug 26, 2020 at 11:49

I think simplest would be use numpy here. For example you can read a file as bytes and then expand it to bits easily like this:

Bytes = numpy.fromfile(filename, dtype = "uint8")
Bits = numpy.unpackbits(Bytes)
input_str = "ABC"
[bin(byte) for byte in bytes(input_str, "utf-8")]

Will give:

['0b1000001', '0b1000010', '0b1000011']

Here how to do it using format()

print "bin_signedDate : ", ''.join(format(x, '08b') for x in bytevector)

It is important the 08b . That means it will be a maximum of 8 leading zeros be appended to complete a byte. If you don't specify this then the format will just have a variable bit length for each converted byte.


To binary:

  • 9
    You can't convert a byte using bin. Jan 20, 2015 at 14:49

Use ord when reading reading bytes:

byte_binary = bin(ord(f.read(1))) # Add [2:] to remove the "0b" prefix


Using str.format():


The other answers here provide the bits in big-endian order ('\x01' becomes '00000001')

In case you're interested in little-endian order of bits, which is useful in many cases, like common representations of bignums etc - here's a snippet for that:

def bits_little_endian_from_bytes(s):
    return ''.join(bin(ord(x))[2:].rjust(8,'0')[::-1] for x in s)

And for the other direction:

def bytes_from_bits_little_endian(s):
    return ''.join(chr(int(s[i:i+8][::-1], 2)) for i in range(0, len(s), 8))

Q: How convert bytes to bits / string of bits?


b = ''.join(f'{z:08b}' for z in x)

Replace ''.join(.) with [.] for the bit representations. This answers preserves the size so each byte takes 8 bits and the output is 8 * nbytes long.


print(''.join(f'{z:08b}' for z in b'DECADE'))
# output: 010001000100010101000011010000010100010001000101
# len(output) is 48 == len('DECADE') * 8

One line function to convert bytes (not string) to bit list. There is no endnians issue when source is from a byte reader/writer to another byte reader/writer, only if source and target are bit reader and bit writers.

def byte2bin(b):
    return [int(X) for X in "".join(["{:0>8}".format(bin(X)[2:])for X in b])]

I came across this answer when looking for a way to convert an integer into a list of bit positions where the bitstring is equal to one. This becomes very similar to this question if you first convert your hex string to an integer like int('0x453', 16).

Now, given an integer - a representation already well-encoded in the hardware, I was very surprised to find out that the string variants of the above solutions using things like bin turn out to be faster than numpy based solutions for a single number, and I thought I'd quickly write up the results.

I wrote three variants of the function. First using numpy:

import math
import numpy as np
def bit_positions_numpy(val):
    Given an integer value, return the positions of the on bits.
    bit_length = val.bit_length() + 1
    length = math.ceil(bit_length / 8.0)  # bytelength
    bytestr = val.to_bytes(length, byteorder='big', signed=True)
    arr = np.frombuffer(bytestr, dtype=np.uint8, count=length)
    bit_arr = np.unpackbits(arr, bitorder='big')
    bit_positions = np.where(bit_arr[::-1])[0].tolist()
    return bit_positions

Then using string logic:

def bit_positions_str(val):
    is_negative = val < 0
    if is_negative:
        bit_length = val.bit_length() + 1
        length = math.ceil(bit_length / 8.0)  # bytelength
        neg_position = (length * 8) - 1
        # special logic for negatives to get twos compliment repr
        max_val = 1 << neg_position
        val_ = max_val + val
        val_ = val
    binary_string = '{:b}'.format(val_)[::-1]
    bit_positions = [pos for pos, char in enumerate(binary_string)
                     if char == '1']
    if is_negative:
    return bit_positions

And finally, I added a third method where I precomputed a lookuptable of the positions for a single byte and expanded that given larger itemsizes.

pos_masks = [(s, (1 << s)) for s in range(0, 8)]
for i in range(0, 256):
    positions = [pos  for pos, mask in pos_masks if (mask & i)]

def bit_positions_lut(val):
    bit_length = val.bit_length() + 1
    length = math.ceil(bit_length / 8.0)  # bytelength
    bytestr = val.to_bytes(length, byteorder='big', signed=True)
    bit_positions = []
    for offset, b in enumerate(bytestr[::-1]):
        pos = BYTE_TO_POSITIONS[b]
        if offset == 0:
            pos_offset = (8 * offset)
            bit_positions.extend([p + pos_offset for p in pos])
    return bit_positions

The benchmark code is as follows:

def benchmark_bit_conversions():
    # for val in [-0, -1, -3, -4, -9999]:

    test_values = [
        # -1, -2, -3, -4, -8, -32, -290, -9999,
        # 0, 1, 2, 3, 4, 8, 32, 290, 9999,
        4324, 1028, 1024, 3000, -100000,
        2 ** 32,
        2 ** 64,
        2 ** 128,
        2 ** 128,

    for val in test_values:
        r1 = bit_positions_str(val)
        r2 = bit_positions_numpy(val)
        r3 = bit_positions_lut(val)
        assert r1 == r2

    import xdev

    import timerit
    ti = timerit.Timerit(10000, bestof=10, verbose=2)
    for timer in ti.reset('str'):
        for val in test_values:

    for timer in ti.reset('numpy'):
        for val in test_values:

    for timer in ti.reset('lut'):
        for val in test_values:

    for timer in ti.reset('raw_bin'):
        for val in test_values:

    for timer in ti.reset('raw_bytes'):
        for val in test_values:
            val.to_bytes(val.bit_length(), 'big', signed=True)

And it clearly shows the str and lookup table implementations are ahead of numpy. I tested this on CPython 3.10 and 3.11.

Timed str for: 10000 loops, best of 10
    time per loop: best=20.488 µs, mean=21.438 ± 0.4 µs
Timed numpy for: 10000 loops, best of 10
    time per loop: best=25.754 µs, mean=28.509 ± 5.2 µs
Timed lut for: 10000 loops, best of 10
    time per loop: best=19.420 µs, mean=21.305 ± 3.8 µs

For Python 3.6+ or newer, you can first convert the hex string to integer using int(input_str, 16). Then use f-strings format to convert the integer to bit string.

>>> input_str = b'1a'
>>> f'{int(input_str, 16):b}'

The width specifier can be used to set the length of the output bit string if the length of the output is less than the specified width:

>>> f'{int(input_str, 16):08b}'


>>> len_in_bits = 8
>>> f'{int(input_str, 16):0{len_in_bits}b}'

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