# Generating gray codes.

I tried generating gray codes in Python. This code works correctly. The issue is that I am initialising the base case (`n=1,[0,1]`) in the `main` function and passing it to `gray_code` function to compute the rest. I want to generate all the gray codes inside the function itself including the base case. How do I do that?

``````def gray_code(g,n):
k=len(g)
if n<=0:
return

else:
for i in range (k-1,-1,-1):
char='1'+g[i]
g.append(char)
for i in range (k-1,-1,-1):
g[i]='0'+g[i]

gray_code(g,n-1)

def main():
n=int(raw_input())
g=['0','1']
gray_code(g,n-1)
if n>=1:
for i in range (len(g)):
print g[i],

main()
``````

Is the recurrence relation of this algorithm `T(n)=T(n-1)+n` ?

``````def gray_code(n):
def gray_code_recurse (g,n):
k=len(g)
if n<=0:
return

else:
for i in range (k-1,-1,-1):
char='1'+g[i]
g.append(char)
for i in range (k-1,-1,-1):
g[i]='0'+g[i]

gray_code_recurse (g,n-1)

g=['0','1']
gray_code_recurse(g,n-1)
return g

def main():
n=int(raw_input())
g = gray_code (n)

if n>=1:
for i in range (len(g)):
print g[i],

main()
``````
• Wow, amazed to see such an elegant code. Thanks. Time complexity is `n^2` right? – sagar_jeevan Aug 3 '16 at 9:33
• It's just a matter of thinking step by step. Since your main was already doing what you needed, but you wanted it INSIDE your gray_code function, I just turned your main into gray_code function and renamed your original function to gray_code_recurse. Since it wasn't needed anywhere else, I made it local. As for time complexity: the number of 'digits' is proportional to n. The number of 'numbers' is proportional to 2 ^ n. So I would expect time order to be n * (2 ^ n), or equivalently, since it's only order: n * exp (n). But I may be overlooking something, so don't trust me here... – Jacques de Hooge Aug 3 '16 at 9:41
• Instead of this `for i in range (len(g)): print g[i],` you could have iterated through the object directly, e.g. `for elem in g: print(elem)`. – jermenkoo Aug 3 '16 at 10:42

Generating Gray codes is easier than you think. The secret is that the Nth gray code is in the bits of N^(N>>1)

So:

``````def main():
n=int(raw_input())
for i in range(0, 1<<n):
gray=i^(i>>1)
print "{0:0{1}b}".format(gray,n),

main()
``````
• Isn't that the Nth gray code is in the bits of (N-1)^((N-1)>>1) ? – sagar_jeevan Aug 3 '16 at 14:03
• I coded this which generates codes till specified n only to realise that its inefficient. A bit lengthy. ideone.com/KuVeCw – sagar_jeevan Aug 3 '16 at 14:08
• I didn't quite understand the print statement in your code `print "{0:0{1}b}".format(gray,n)`. What's happening here? – sagar_jeevan Aug 3 '16 at 14:25
• it prints the binary representation of `gray`, padded on the left with zeros until it's `n` digits long – Matt Timmermans Aug 3 '16 at 14:27
• Great. Thanks for solutions and explanations. – sagar_jeevan Aug 3 '16 at 14:32

It's relatively easy to do if you implement the function iteratively (even if it's defined recursively). This will often execute more quickly as it generally requires fewer function calls.

``````def gray_code(n):
if n < 1:
g = []
else:
g = ['0', '1']
n -= 1
while n > 0:
k = len(g)
for i in range(k-1, -1, -1):
char = '1' + g[i]
g.append(char)
for i in range(k-1, -1, -1):
g[i] = '0' + g[i]
n -= 1
return g

def main():
n = int(raw_input())
g = gray_code(n)
print ' '.join(g)

main()
``````

``````#! /usr/bin/python3

def hipow(n):
''' Return the highest power of 2 within n. '''
exp = 0
while 2**exp <= n:
exp += 1
return 2**(exp-1)

def code(n):
''' Return nth gray code. '''
if n>0:
return hipow(n) + code(2*hipow(n) - n - 1)
return 0

# main:
for n in range(30):
print(bin(code(n)))
``````
• Beautiful and simple, and all set for Python3. This gets my vote. – CENTURION Aug 16 '18 at 20:14