Is there a built in function in python which will convert a binary string, for example '111111111111', to the two's complement integer 1?

Constraint: should approaches assume the string only contains '1's (and maybe 0's'), no spacing characters like commas, apostrophes, spaces or underscores (which are very commmonly used for digitgroup spacing in long binary/hex strings, not just in Python, but e.g. in languages like Verilog)? And no binary point either?– smciOct 20, 2020 at 23:40

1Also, do you want two's complement to length 32b, 64b, 128b, 16b or whatever arbitrary length the input string is, rounded up to next 32b or nexthighestpowerof2?– smciOct 20, 2020 at 23:48
20 Answers
Two's complement subtracts off (1<<bits)
if the highest bit is 1. Taking 8 bits for example, this gives a range of 127 to 128.
A function for two's complement of an int...
def twos_comp(val, bits):
"""compute the 2's complement of int value val"""
if (val & (1 << (bits  1))) != 0: # if sign bit is set e.g., 8bit: 128255
val = val  (1 << bits) # compute negative value
return val # return positive value as is
Going from a binary string is particularly easy...
binary_string = '1111' # or whatever... no '0b' prefix
out = twos_comp(int(binary_string,2), len(binary_string))
A bit more useful to me is going from hex values (32 bits in this example)...
hex_string = '0xFFFFFFFF' # or whatever... '0x' prefix doesn't matter
out = twos_comp(int(hex_string,16), 32)


@Likak, the answer is ok. See also Subtraction from 2^N for the reasoning behind it. Feb 26, 2017 at 11:06

1
return val & ((2 ** bits)  1)
Without this, you'll just get a negative number in normal python formatting. Presumably when doing 2sc you would want the bits. Oct 12, 2017 at 3:09 
@TechnoSam We want a normal python integer. The 2's compliment means negative (high bit set), it should be negative. That's the whole point.– travcDec 19, 2017 at 0:48

1@Danilo Yep,
!= 0
is not needed, but a good practice to include. That function could even be reduced down to a oneliner, but it wouldn't be as clear ;)– travcMay 2, 2018 at 7:00
Since Python 3.2, there are builtin functions for byte manipulation: https://docs.python.org/3/library/stdtypes.html#int.to_bytes.
By combining to_bytes and from_bytes, you get
def twos(val_str, bytes):
import sys
val = int(val_str, 2)
b = val.to_bytes(bytes, byteorder=sys.byteorder, signed=False)
return int.from_bytes(b, byteorder=sys.byteorder, signed=True)
Check:
twos('11111111', 1) # gives 1
twos('01111111', 1) # gives 127
For older versions of Python, travc's answer is good but it does not work for negative values if one would like to work with integers instead of strings. A twos' complement function for which f(f(val)) == val is true for each val is:
def twos_complement(val, nbits):
"""Compute the 2's complement of int value val"""
if val < 0:
val = (1 << nbits) + val
else:
if (val & (1 << (nbits  1))) != 0:
# If sign bit is set.
# compute negative value.
val = val  (1 << nbits)
return val
It's not built in, but if you want unusual length numbers then you could use the bitstring module.
>>> from bitstring import Bits
>>> a = Bits(bin='111111111111')
>>> a.int
1
The same object can equivalently be created in several ways, including
>>> b = Bits(int=1, length=12)
It just behaves like a string of bits of arbitrary length, and uses properties to get different interpretations:
>>> print a.int, a.uint, a.bin, a.hex, a.oct
1 4095 111111111111 fff 7777

1A comparison between different bithandling tools can be found here Oct 23, 2014 at 13:38

2@erikb85: The answers there (mine included) didn't really get into the simplicity and flexibility of the interface (the OP even started off by complaining that
bitarray
does more than he needs…), so these questions make a nice complement to each other: this one shows how libraries likebitstring
make common operations easier to write, that one shows they don't make them faster, and often make them slower.– abarnertOct 23, 2014 at 17:42
>>> bits_in_word=12
>>> int('111111111111',2)(1<<bits_in_word)
1
This works because:
The two's complement of a binary number is defined as the value obtained by subtracting the number from a large power of two (specifically, from 2^N for an Nbit two's complement). The two's complement of the number then behaves like the negative of the original number in most arithmetic, and it can coexist with positive numbers in a natural way.


2@quqa123 Before applying this method, one must examine whether the value is negative in the first place. If the value is smaller or equal to
(1 << (bits_in_word  1))  1
, it is positive and should not be subject to this method. Nov 7, 2021 at 20:04
This will give you the two's complement efficiently using bitwise logic:
def twos_complement(value, bitWidth):
if value >= 2**bitWidth:
# This catches when someone tries to give a value that is out of range
raise ValueError("Value: {} out of range of {}bit value.".format(value, bitWidth))
return value  int((value << 1) & 2**bitWidth)
How it works:
First, we make sure that the user has passed us a value that is within the range of the supplied bit range (e.g. someone gives us 0xFFFF and specifies 8 bits) Another solution to that problem would be to bitwise AND (&) the value with (2**bitWidth)1
To get the result, the value is shifted by 1 bit to the left. This moves the MSB of the value (the sign bit) into position to be anded with 2**bitWidth
. When the sign bit is '0' the subtrahend becomes 0 and the result is value  0
. When the sign bit is '1' the subtrahend becomes 2**bitWidth
and the result is value  2**bitWidth
Example 1: If the parameters are value=0xFF (255d, b11111111) and bitWidth=8
 0xFF  int((0xFF << 1) & 2**8)
 0xFF  int((0x1FE) & 0x100)
 0xFF  int(0x100)
 255  256
 1
Example 2: If the parameters are value=0x1F (31d, b11111) and bitWidth=6
 0x1F  int((0x1F << 1) & 2**6)
 0x1F  int((0x3E) & 0x40)
 0x1F  int(0x00)
 31  0
 31
Example 3: value = 0x80, bitWidth = 7
ValueError: Value: 128 out of range of 7bit value.
Example 4: value = 0x80, bitWitdh = 8
 0x80  int((0x80 << 1) & 2**8)
 0x80  int((0x100) & 0x100)
 0x80  int(0x100)
 128  256
 128
Now, using what others have already posted, pass your bitstring into int(bitstring, 2)
and pass to the twos_complement
method's value parameter.
A couple of implementations (just an illustration, not intended for use):
def to_int(bin):
x = int(bin, 2)
if bin[0] == '1': # "sign bit", bigendian
x = 2**len(bin)
return x
def to_int(bin): # from definition
n = 0
for i, b in enumerate(reversed(bin)):
if b == '1':
if i != (len(bin)1):
n += 2**i
else: # MSB
n = 2**i
return n

If you're already handling binary as strings, why wouldn't you use this clear and flexible function to create signed integers from them? Apr 23, 2017 at 6:10

@CeesTimmerman perhaps I meant that "01"string is a poor representation for an integer (for arithmetic) and therefore functions that manipulate them directly shouldn't be used.– jfsApr 23, 2017 at 11:07
You can use the bit_length() function to convert numbers to their two's complement:
def twos_complement(j):
return j(1<<(j.bit_length()))
In [1]: twos_complement(0b111111111111)
Out[1]: 1
in case someone needs the inverse direction too:
def num_to_bin(num, wordsize):
if num < 0:
num = 2**wordsize+num
base = bin(num)[2:]
padding_size = wordsize  len(base)
return '0' * padding_size + base
for i in range(7, 9, 1):
print num_to_bin(i, 4)
should output this: 0111 0110 0101 0100 0011 0010 0001 0000 1111 1110 1101 1100 1011 1010 1001 1000

n bits two's complement binary number x is represented as the positive (2 to the power n)+x. example: x=2, n=4, (2 to the power 4) + (2) = 14, bin=1110 Feb 4, 2017 at 11:27

1Since you're doing bit manipulations you should use
1 << wordsize
rather than2 ** wordsize
; besides, bit shifting is significantly faster than exponentiation.– PM 2RingApr 22, 2017 at 7:17
No, there is no builtin function that converts two's complement binary strings into decimals.
A simple user defined function that does this:
def two2dec(s):
if s[0] == '1':
return 1 * (int(''.join('1' if x == '0' else '0' for x in s), 2) + 1)
else:
return int(s, 2)
Note that this function doesn't take the bit width as parameter, instead positive input values have to be specified with one or more leading zero bits.
Examples:
In [2]: two2dec('1111')
Out[2]: 1
In [3]: two2dec('111111111111')
Out[3]: 1
In [4]: two2dec('0101')
Out[4]: 5
In [5]: two2dec('10000000')
Out[5]: 128
In [6]: two2dec('11111110')
Out[6]: 2
In [7]: two2dec('01111111')
Out[7]: 127
you could convert the integer to bytes and then use struct.unpack
to convert:
from struct import unpack
x = unpack("b", 0b11111111.to_bytes(length=1, byteorder="little"))
print(x) # (1,)
Since erikb85 brought up performance, here's travc's answer against Scott Griffiths':
In [534]: a = [0b111111111111, 0b100000000000, 0b1, 0] * 1000
In [535]: %timeit [twos_comp(x, 12) for x in a]
100 loops, best of 3: 8.8 ms per loop
In [536]: %timeit [bitstring.Bits(uint=x, length=12).int for x in a]
10 loops, best of 3: 55.9 ms per loop
So, bitstring
is, as found in the other question, almost an order of magnitude slower than int
. But on the other hand, it's hard to beat the simplicity—I'm converting a uint
to a bitstring then to an int
; you'd have to work hard not to understand this, or to find anywhere to introduce a bug. And as Scott Griffiths' answer implies, there's a lot more flexibility to the class which might be useful to the same app. But on the third hand, travc's answer makes it clear what's actually happening—even a novice should be able to understand what conversion from an unsigned int to a 2s complement signed int means just from reading 2 lines of code.
Anyway, unlike the other question, which was about directly manipulating bits, this one is all about doing arithmetic on fixedlength ints, just oddlysized ones. So I'm guessing if you need performance, it's probably because you have a whole bunch of these things, so you probably want it to be vectorized. Adapting travc's answer to numpy:
def twos_comp_np(vals, bits):
"""compute the 2's compliment of array of int values vals"""
vals[vals & (1<<(bits1)) != 0] = (1<<bits)
return vals
Now:
In [543]: a = np.array(a)
In [544]: %timeit twos_comp_np(a.copy(), 12)
10000 loops, best of 3: 63.5 µs per loop
You could probably beat that with custom C code, but you probably don't have to.
Unfortunately there is no builtin function to cast an unsigned integer to a two's complement signed value, but we can define a function to do so using bitwise operations:
def s12(value):
return (value & 0b100000000000)  (value & 0b011111111111)
The first bitwiseand operation is used to signextend negative numbers (most significant bit is set), while the second is used to grab the remaining 11 bits. This works since integers in Python are treated as arbitrary precision two's complement values.
You can then combine this with the int
function to convert a string of binary digits into the unsigned integer form, then interpret it as a 12bit signed value.
>>> s12(int('111111111111', 2))
1
>>> s12(int('011111111111', 2))
2047
>>> s12(int('100000000000', 2))
2048
One nice property of this function is that it's idempotent, thus the value of an already signed value will not change.
>>> s12(1)
1


For this question, it was assumed the author was asking how to interpret 12 binary digits as a 12bit two's complement signed integer (since 1 is always represented by N 1bits in an Nbit two's complement representation). The first bit is used for the sign, while the remaining (11) bits determine the magnitude.– dcolesApr 25, 2017 at 1:21
Use ~
, ^
, and a mask (mask determines the total number of bits)
# Given negative value, obtain its two's complement form in 16 bits
>>> mask = (1 << 16)  1
>>> a = 6
>>> bin(~(a ^ mask))
'0b1111111111111010'
# Given 16bit signed binary string, return the integer value
>>> mask = (1 << 16)  1
>>> b = '1111111111110101'
>>> ~(int(b, 2) ^ mask)
11
I'm using Python 3.4.0
In Python 3 we have some problems with data types transformation.
So... here I'll tell a tip for those (like me) that works a lot with hex strings.
I'll take an hex data and make an complement it:
a = b'acad0109'
compl = int(a,16)pow(2,32)
result=hex(compl)
print(result)
print(int(result,16))
print(bin(int(result,16)))
result = 1397948151 or 0x5352fef7 or '0b1010011010100101111111011110111'
This works for 3 bytes. Live code is here
def twos_compliment(byte_arr):
a = byte_arr[0]; b = byte_arr[1]; c = byte_arr[2]
out = ((a<<16)&0xff0000)  ((b<<8)&0xff00)  (c&0xff)
neg = (a & (1<<7) != 0) # first bit of a is the "signed bit." if it's a 1, then the value is negative
if neg: out = (1 << 24)
print(hex(a), hex(b), hex(c), neg, out)
return out
twos_compliment([0x00, 0x00, 0x01])
>>> 1
twos_compliment([0xff,0xff,0xff])
>>> 1
twos_compliment([0b00010010, 0b11010110, 0b10000111])
>>> 1234567
twos_compliment([0b11101101, 0b00101001, 0b01111001])
>>> 1234567
twos_compliment([0b01110100, 0b11001011, 0b10110001])
>>> 7654321
twos_compliment([0b10001011, 0b00110100, 0b01001111])
>>> 7654321
Ok i had this issue with uLaw compression algorithm with PCM wav file type. And what i've found out is that two's complement is kinda making a negative value of some binary number as can be seen here.And after consulting with wikipedia i deemed it true.
The guy explained it as finding least significant bit
and flipping all after it. I must say that all these solutions above didn't help me much. When i tried on 0x67ff
it gave me some off result instead of 26623
. Now solutions may have worked if someone knew the least significant bit
is scanning list of data but i didn't knew since data in PCM varies. So here is my answer:
max_data = b'\xff\x67' #maximum value i've got from uLaw data chunk to test
def twos_compliment(short_byte): # 2 bytes
short_byte = signedShort(short_byte) # converting binary string to integer from struct.unpack i've just shortened it.
valid_nibble = min([ x*4 for x in range(4) if (short_byte>>(x*4))&0xf ])
bit_shift = valid_nibble + min( [ x for x in [1,2,4,8] if ( ( short_byte>>valid_nibble )&0xf )&x ] )
return (~short_byte)^( 2**bit_shift1 )
data = 0x67ff
bit4 = '{0:04b}'.format
bit16 = lambda x: ' '.join( map( bit4, reversed([ x&0xf, (x>>4)&0xf, (x>>8)&0xf, (x>>12)&0xf ]) ) )
# print( bit16(0x67ff) , ' : ', bit16( twos_compliment( b'\xff\x67' ) ) )
# print( bit16(0x67f0) , ' : ', bit16( twos_compliment( b'\xf0\x67' ) ) )
# print( bit16(0x6700) , ' : ', bit16( twos_compliment( b'\x00\x67' ) ) )
# print( bit16(0x6000) , ' : ', bit16( twos_compliment( b'\x00\x60' ) ) )
print( data, twos_compliment(max_data) )
Now since code is unreadable i will walk you through the idea.
## example data, for testing... in general unknown
data = 0x67ff # 26623 or 0110 0111 1111 1111
This is just any hexadecimal value, i needed test to be sure but in general it could be anything in range of int. So not to loop over whole bunch of 65535 values short integer
can have i decided to split it by nibbles ( 4 bits ). It could be done like this if you haven't used bitwise operators
before.
nibble_mask = 0xf # 1111
valid_nibble = []
for x in range(4): #0,1,2,3 aka places of bit value
# for individual bits you could go 1<<x as you will see later
# x*4 is because we are shifting bit places , so 0xFA>>4 = 0xF
# so 0x67ff>>0*4 = 0x67ff
# so 0x67ff>>1*4 = 0x67f
# so 0x67ff>>2*4 = 0x67
# so 0x67ff>>3*4 = 0x6
# and nibble mask just makes it confided to 1 nibble so 0xFA&0xF=0xA
if (data>>(x*4))&nibble_mask: valid_nibble.append(x*4) # to avoid multiplying it with 4 later
So we are searching for least significant bit
so here the min(valid_nibble )
will suffice. Here we've gotten the place where first active (with setted bit) nibble is. Now we just need is to find where in desired nibble is our first setted bit.
bit_shift = min(valid_nibble)
for x in range(4):
# in my example above [1,2,4,8] i did this to spare python calculating
ver_data = data>>min(bit_shift ) # shifting from 0xFABA to lets say 0xFA
ver_data &= nibble_mask # from 0xFA to 0xA
if ver_data&(1<<x):
bit_shift += (1<<x)
break
Now here i need to clarify somethings since seeing ~
and ^
can confuse people who aren't used to this:
XOR
: ^
: 2 numbers are necesery
This operation is kinda illogical, for each 2 bits it scans if both are either 1 or 0 it will be 0, for everything else 1.
0b10110
^0b11100

0b01010
And another example:
0b10110
^0b11111

0b01001
1's complement
: ~
 doesn't need any other number
This operation flips every bit in a number. It is very similar to what we are after but it doesn't leave the least significant bit.
0b10110
~
0b01001
And as we can see here 1's compliment is same as number XOR full set bits.
Now that we've understood each other, we will getting two's complement
by restoring all bites to least significant bit in one's complement.
data = ~data # one's complement of data
This unfortunately flipped all bits in our number, so we just need to find a way to flip back the numbers we want. We can do that with bit_shift
since it is bit position of our bit we need to keep. So when calculating number of data some number of bits can hold we can do that with 2**n
and for nibble we get 16 since we are calculating 0 in values of bits.
2**4 = 16 # in binary 1 0000
But we need the bytes after the 1
so we can use that to diminish the value by 1 and we can get.
2**4 1 = 15 # in binary 0 1111
So lets see the logic in concrete example:
0b110110
lsb = 2 # binary 10
~0b110110

0b001001 # here is that 01 we don't like
0b001001
^0b000011 # 2**2 = 4 ; 41 = 3 in binary 0b11

0b001010
I hope this help'd you or any newbie that had this same problem and researched their a** off finding the solution. Have in mind this code i wrote is frankenstein code , that i why i had to explain it. It could be done more prettier, if anyone wants to make my code pretty please be my guest.
Here's a version to convert each value in a hex string to it's two's complement version.
In [5159]: twoscomplement('f0079debdd9abe0fdb8adca9dbc89a807b707f')
Out[5159]: '10097325337652013586346735487680959091'
def twoscomplement(hm):
twoscomplement=''
for x in range(0,len(hm)):
value = int(hm[x],16)
if value % 2 == 1:
twoscomplement+=hex(value ^ 14)[2:]
else:
twoscomplement+=hex(((value1)^15)&0xf)[2:]
return twoscomplement
Still a very relevant question, but none of the answers worked in my scenario  which is surprising.
Here's a very simple function to calculate nbit 2's complement integer values from an integer value.
This function especially ensures that the returned value is NOT seen as a negative value by python, as it breaks the very nature of 2's complement numbers.
2's complement numbers were originally created to work with both positive and negative values on architectures that do not natively support them. It's a conversion and is all about using the bits available to represent and calculate with both positive and negative numbers.
Therefore the number of bits can be specified, defaults to 16, and can by setting it to 0, be set to the required number of bits for the given value.
def twos_comp(val, bits=16):
"""compute the 2's complement of int value """
if bits == 0: # Use as many bits needed for the value.
bits = val.bit_length()
return ((val & (2 ** bits)  1)  (2 ** bits)) * 1
Test code:
value = 6752
print(f'{value:05d} = 0x{value:04x} = 0b{value:016b}')
value = twos_comp(value)
print(f'{value:05d} = 0x{value:04x} = 0b{value:016b}')
value = twos_comp(value)
print(f'{value:05d} = 0x{value:04x} = 0b{value:016b}')
Test code output:
06752 = 0x1a60 = 0b0001101001100000
01440 = 0x05a0 = 0b0000010110100000
06752 = 0x1a60 = 0b0001101001100000
Subtract 2^nbits from negative values:
In [75]: (lambda x: int(x,2)  2**len(x)*int(x[0]))('10000000')
Out[75]: 128
In [76]: (lambda x: int(x,2)  2**len(x)*int(x[0]))('01111111')
Out[76]: 127
In [77]: (lambda x: int(x,2)  2**len(x)*int(x[0]))('0111')
Out[77]: 7
In [78]: (lambda x: int(x,2)  2**len(x)*int(x[0]))('1111001')
Out[78]: 7
 works for any length input
 handles positive and negative values correctly
 NOTE: positive values must have leading zeros
It's much easier than all that...
for X on N bits: Comp = (X) & (2**N  1)
def twoComplement(number, nBits):
return (number) & (2**nBits  1)

This doesn't work for '1111'. The result of
twoComplement(int('1111', 2), 4)
is1
when using your function. But the correct result is1
. See also the other answers that get this right. Feb 26, 2017 at 11:51 
Last time I checked, the 2 complement of 1111 on four bits is 0001.– FrancoisFeb 27, 2017 at 13:48

I think you might be confusing calculating the 2 complement of a number with the value of a number (as a negative) in a 2 complement domain.– FrancoisFeb 27, 2017 at 13:49

Don't be silly  the term "Two's complement" commonly denotes a decimal interpretation of a bit pattern  cf. e.g. the first 2 tables in en.wikipedia.org/wiki/Two's_complement . Also, the OP specifically asked about this and gave as example
'111111111111' > 1
. That means that you don't answer the question. Thus, your statement "It's much easier than all that ..." doesn't apply. Feb 28, 2017 at 8:38 
ahahah, I guess you're right. I must have jumped in the middle of the thread and missed the original question !– FrancoisFeb 28, 2017 at 15:56