I have ABC123EFFF.
I want to have 001010101111000001001000111110111111111111 (i.e. binary repr. with, say, 42 digits and leading zeroes).
How?
I have ABC123EFFF.
I want to have 001010101111000001001000111110111111111111 (i.e. binary repr. with, say, 42 digits and leading zeroes).
How?
For solving the left-side trailing zero problem:
my_hexdata = "1a"
scale = 16 ## equals to hexadecimal
num_of_bits = 8
bin(int(my_hexdata, scale))[2:].zfill(num_of_bits)
It will give 00011010 instead of the trimmed version.
import binascii
binary_string = binascii.unhexlify(hex_string)
Read
Return the binary data represented by the hexadecimal string specified as the parameter.
bin(int("abc123efff", 16))[2:]
>>> bin( 0xABC123EFFF )
'0b1010101111000001001000111110111111111111'
Convert hex to binary
I have ABC123EFFF.
I want to have 001010101111000001001000111110111111111111 (i.e. binary repr. with, say, 42 digits and leading zeroes).
The new f-strings in Python 3.6 allow you to do this using very terse syntax:
>>> f'{0xABC123EFFF:0>42b}'
'001010101111000001001000111110111111111111'
or to break that up with the semantics:
>>> number, pad, rjust, size, kind = 0xABC123EFFF, '0', '>', 42, 'b'
>>> f'{number:{pad}{rjust}{size}{kind}}'
'001010101111000001001000111110111111111111'
What you are actually saying is that you have a value in a hexadecimal representation, and you want to represent an equivalent value in binary.
The value of equivalence is an integer. But you may begin with a string, and to view in binary, you must end with a string.
We have several direct ways to accomplish this goal, without hacks using slices.
First, before we can do any binary manipulation at all, convert to int (I presume this is in a string format, not as a literal):
>>> integer = int('ABC123EFFF', 16)
>>> integer
737679765503
alternatively we could use an integer literal as expressed in hexadecimal form:
>>> integer = 0xABC123EFFF
>>> integer
737679765503
Now we need to express our integer in a binary representation.
format
Then pass to format
:
>>> format(integer, '0>42b')
'001010101111000001001000111110111111111111'
This uses the formatting specification's mini-language.
To break that down, here's the grammar form of it:
[[fill]align][sign][#][0][width][,][.precision][type]
To make that into a specification for our needs, we just exclude the things we don't need:
>>> spec = '{fill}{align}{width}{type}'.format(fill='0', align='>', width=42, type='b')
>>> spec
'0>42b'
and just pass that to format
>>> bin_representation = format(integer, spec)
>>> bin_representation
'001010101111000001001000111110111111111111'
>>> print(bin_representation)
001010101111000001001000111110111111111111
str.format
We can use that in a string using str.format
method:
>>> 'here is the binary form: {0:{spec}}'.format(integer, spec=spec)
'here is the binary form: 001010101111000001001000111110111111111111'
Or just put the spec directly in the original string:
>>> 'here is the binary form: {0:0>42b}'.format(integer)
'here is the binary form: 001010101111000001001000111110111111111111'
Let's demonstrate the new f-strings. They use the same mini-language formatting rules:
>>> integer = 0xABC123EFFF
>>> length = 42
>>> f'{integer:0>{length}b}'
'001010101111000001001000111110111111111111'
Now let's put this functionality into a function to encourage reusability:
def bin_format(integer, length):
return f'{integer:0>{length}b}'
And now:
>>> bin_format(0xABC123EFFF, 42)
'001010101111000001001000111110111111111111'
If you actually just wanted to encode the data as a string of bytes in memory or on disk, you can use the int.to_bytes
method, which is only available in Python 3:
>>> help(int.to_bytes)
to_bytes(...)
int.to_bytes(length, byteorder, *, signed=False) -> bytes
...
And since 42 bits divided by 8 bits per byte equals 6 bytes:
>>> integer.to_bytes(6, 'big')
b'\x00\xab\xc1#\xef\xff'
"{0:020b}".format(int('ABC123EFFF', 16))
Here's a fairly raw way to do it using bit fiddling to generate the binary strings.
The key bit to understand is:
(n & (1 << i)) and 1
Which will generate either a 0 or 1 if the i'th bit of n is set.
import binascii
def byte_to_binary(n):
return ''.join(str((n & (1 << i)) and 1) for i in reversed(range(8)))
def hex_to_binary(h):
return ''.join(byte_to_binary(ord(b)) for b in binascii.unhexlify(h))
print hex_to_binary('abc123efff')
>>> 1010101111000001001000111110111111111111
Edit: using the "new" ternary operator this:
(n & (1 << i)) and 1
Would become:
1 if n & (1 << i) or 0
(Which TBH I'm not sure how readable that is)
01111001
11111110
.
– tymac
Mar 29 '18 at 2:53
This is a slight touch up to Glen Maynard's solution, which I think is the right way to do it. It just adds the padding element.
def hextobin(self, hexval):
'''
Takes a string representation of hex data with
arbitrary length and converts to string representation
of binary. Includes padding 0s
'''
thelen = len(hexval)*4
binval = bin(int(hexval, 16))[2:]
while ((len(binval)) < thelen):
binval = '0' + binval
return binval
Pulled it out of a class. Just take out self,
if you're working in a stand-alone script.
bin(int("abc123efff", 16))[2:]
'1010101111000001001000111110111111111111'
`bin(int("abc123efff", 16))[2:].zfill(50)`
'00000000001010101111000001001000111110111111111111'
(The number 50
will tell zfill
that you want to complete the string with zeros until the string length is 50
. )
Replace each hex digit with the corresponding 4 binary digits:
1 - 0001
2 - 0010
...
a - 1010
b - 1011
...
f - 1111
hex --> decimal then decimal --> binary
#decimal to binary
def d2b(n):
bStr = ''
if n < 0: raise ValueError, "must be a positive integer"
if n == 0: return '0'
while n > 0:
bStr = str(n % 2) + bStr
n = n >> 1
return bStr
#hex to binary
def h2b(hex):
return d2b(int(hex,16))
Another way:
import math
def hextobinary(hex_string):
s = int(hex_string, 16)
num_digits = int(math.ceil(math.log(s) / math.log(2)))
digit_lst = ['0'] * num_digits
idx = num_digits
while s > 0:
idx -= 1
if s % 2 == 1: digit_lst[idx] = '1'
s = s / 2
return ''.join(digit_lst)
print hextobinary('abc123efff')
I added the calculation for the number of bits to fill to Onedinkenedi's solution. Here is the resulting function:
def hextobin(h):
return bin(int(h, 16))[2:].zfill(len(h) * 4)
Where 16 is the base you're converting from (hexadecimal), and 4 is how many bits you need to represent each digit, or log base 2 of the scale.
def conversion():
e=raw_input("enter hexadecimal no.:")
e1=("a","b","c","d","e","f")
e2=(10,11,12,13,14,15)
e3=1
e4=len(e)
e5=()
while e3<=e4:
e5=e5+(e[e3-1],)
e3=e3+1
print e5
e6=1
e8=()
while e6<=e4:
e7=e5[e6-1]
if e7=="A":
e7=10
if e7=="B":
e7=11
if e7=="C":
e7=12
if e7=="D":
e7=13
if e7=="E":
e7=14
if e7=="F":
e7=15
else:
e7=int(e7)
e8=e8+(e7,)
e6=e6+1
print e8
e9=1
e10=len(e8)
e11=()
while e9<=e10:
e12=e8[e9-1]
a1=e12
a2=()
a3=1
while a3<=1:
a4=a1%2
a2=a2+(a4,)
a1=a1/2
if a1<2:
if a1==1:
a2=a2+(1,)
if a1==0:
a2=a2+(0,)
a3=a3+1
a5=len(a2)
a6=1
a7=""
a56=a5
while a6<=a5:
a7=a7+str(a2[a56-1])
a6=a6+1
a56=a56-1
if a5<=3:
if a5==1:
a8="000"
a7=a8+a7
if a5==2:
a8="00"
a7=a8+a7
if a5==3:
a8="0"
a7=a8+a7
else:
a7=a7
print a7,
e9=e9+1
i have a short snipped hope that helps :-)
input = 'ABC123EFFF'
for index, value in enumerate(input):
print(value)
print(bin(int(value,16)+16)[3:])
string = ''.join([bin(int(x,16)+16)[3:] for y,x in enumerate(input)])
print(string)
first i use your input and enumerate it to get each symbol. then i convert it to binary and trim from 3th position to the end. The trick to get the 0 is to add the max value of the input -> in this case always 16 :-)
the short form ist the join method. Enjoy.
# Python Program - Convert Hexadecimal to Binary
hexdec = input("Enter Hexadecimal string: ")
print(hexdec," in Binary = ", end="") # end is by default "\n" which prints a new line
for _hex in hexdec:
dec = int(_hex, 16) # 16 means base-16 wich is hexadecimal
print(bin(dec)[2:].rjust(4,"0"), end="") # the [2:] skips 0b, and the
Use Built-in format() function and int() function It's simple and easy to understand. It's little bit simplified version of Aaron answer
int()
int(string, base)
format()
format(integer, # of bits)
Example
# w/o 0b prefix
>> format(int("ABC123EFFF", 16), "040b")
1010101111000001001000111110111111111111
# with 0b prefix
>> format(int("ABC123EFFF", 16), "#042b")
0b1010101111000001001000111110111111111111
# w/o 0b prefix + 64bit
>> format(int("ABC123EFFF", 16), "064b")
0000000000000000000000001010101111000001001000111110111111111111
See also this answer
The binary version of ABC123EFFF is actually 1010101111000001001000111110111111111111
For almost all applications you want the binary version to have a length that is a multiple of 4 with leading padding of 0s.
To get this in Python:
def hex_to_binary( hex_code ):
bin_code = bin( hex_code )[2:]
padding = (4-len(bin_code)%4)%4
return '0'*padding + bin_code
Example 1:
>>> hex_to_binary( 0xABC123EFFF )
'1010101111000001001000111110111111111111'
Example 2:
>>> hex_to_binary( 0x7123 )
'0111000100100011'
Note that this also works in Micropython :)
a = raw_input('hex number\n')
length = len(a)
ab = bin(int(a, 16))[2:]
while len(ab)<(length * 4):
ab = '0' + ab
print ab
import binascii
hexa_input = input('Enter hex String to convert to Binary: ')
pad_bits=len(hexa_input)*4
Integer_output=int(hexa_input,16)
Binary_output= bin(Integer_output)[2:]. zfill(pad_bits)
print(Binary_output)
"""zfill(x) i.e. x no of 0 s to be padded left - Integers will overwrite 0 s
starting from right side but remaining 0 s will display till quantity x
[y:] where y is no of output chars which need to destroy starting from left"""
no=raw_input("Enter your number in hexa decimal :")
def convert(a):
if a=="0":
c="0000"
elif a=="1":
c="0001"
elif a=="2":
c="0010"
elif a=="3":
c="0011"
elif a=="4":
c="0100"
elif a=="5":
c="0101"
elif a=="6":
c="0110"
elif a=="7":
c="0111"
elif a=="8":
c="1000"
elif a=="9":
c="1001"
elif a=="A":
c="1010"
elif a=="B":
c="1011"
elif a=="C":
c="1100"
elif a=="D":
c="1101"
elif a=="E":
c="1110"
elif a=="F":
c="1111"
else:
c="invalid"
return c
a=len(no)
b=0
l=""
while b<a:
l=l+convert(no[b])
b+=1
print l