# Generating long-run Gray codes

For a communication system, I need a special kind of gray codes. The requirements are:

1. Two successive values differ in only one bit, like all gray codes.
2. Two transitions on the same bit should be at least distant of some arbitrary number of values. this distance is noted mrl for minimum run length.
3. I don't care about the distance form the last code to the first code, there is no constraint on the mrl when the code roll-over.

One example of such Gray code is, for 5 bits and mrl = 4:

``````01111000011110000111100001111000
00111100000011111100001111110000
00011110000111100001111000011110
00001111110000111111000000111100
00000000111111110000000011111111
``````

This paper give the best mrl values for different number of bits. Howerver, those values are found "By use of exhaustive computer searches"

I have python code that work well for small number of bits, up to 6:

``````N = 5 # number of bit
mrl = 4 # minimum run length
first_transition = [0]
first_code = [0]

def Recur(previous_transitions, previous_codes):
if len(previous_codes) == (2**N):
for b in xrange(N):
print ''.join([str((code >> (N-b-1)) & 1) for code in previous_codes])
print
return
new_transition_list = range(N)
for new_transition in new_transition_list:
ok = True
for i in xrange(mrl-1): #look back for transitions that are too close
try:
if new_transition == previous_transitions[-1-i]:
ok = False
break
except: break
if ok:
new_code = previous_codes[-1] ^ 2**new_transition #look back for repeated code
if not (new_code in previous_codes):
Recur(previous_transitions+[new_transition], previous_codes+[new_code])

Recur(first_transition, first_code )
raw_input('[end]')
``````

My problem is that I would like a code of 20 bits, and the complexity of the basic approach seems close to O(n^3). Any suggestions on how to improve this code? Is there a better approach?

• It seems like the balanced gray codes might be useful — if the transitions are distributed evenly among all the bits, you have the best chance of maximizing the minimum transition distance for any given bit. Commented May 29, 2015 at 1:26
• Do you want the gray codes as strings, or integers? Commented May 29, 2015 at 1:48
• @hobbs Long-run gray codes are probably balanced, but I am not sure the opposite is true. The Wikipedia example have an mrl of 2, witch the worst possible result. Do you suggest to generate (or get a table of) balanced Gray codes and check each of them? Commented May 29, 2015 at 2:13
• @CommuSoft Do you mean for output format or you talking about n-ary Gray codes? I need binary Gray codes, any output format. Commented May 29, 2015 at 2:15
• @pserra I'm wondering if math.se or cs.se would be better for this question. Commented May 29, 2015 at 5:49

This is a (poor) python implementation of Method 1 described in Gray Codes with Optimized Run Lengths with special case for `n=10` bits from Binary gray codes with long bit runs

I tried to use same terminology and variable names as in mentioned paper. I believe method 2 from the 1st paper might be able to improve some of the found gaps.

Let me know if useful, I can wrap it in a python package, or make a faster implementation in say rust.

``````import numpy as np

def transition_to_code( transition_sequence ):
code_sequence = [0]

n = np.int( np.log2( len(transition_sequence) ) )

code = 0

for pos in transition_sequence:
code ^= 1 << int(pos)
code_sequence.append(code)

return code_sequence[:-1]

def print_code_from_transition( transition_sequence ):
n = np.int( np.log2( len(transition_sequence) ) )

codes = transition_to_code( transition_sequence )

format_string = "b: {:0"+ str(n) +"b}"

for c in codes:
print( format_string.format( c ) )

def gap( transition_sequence ):
as_array = a = np.array( transition_sequence )
gap = 1

while gap < len(transition_sequence):
if np.any( as_array == np.roll(as_array, gap) ):
return gap
gap += 1

return 0

def valid_circuit( transition_sequence ):
n = np.int( np.log2( len(transition_sequence) ) )

if not len(transition_sequence) == 2**n:
print('Length not valid')
return False

if not np.all(np.array(transition_sequence) < n):
print('Transition codes not valid')
return False

sorted_codes = np.sort( transition_to_code( transition_sequence ) )

if not np.all( sorted_codes == np.arange(0,2**n) ):
print('Not all Unique')
return False

return True

transitions = {
2 : [0, 1, 0, 1],
3 : [0, 1, 0, 2, 0, 1, 0, 2],
4 : [0, 1, 2, 3, 2, 1, 0, 2, 0, 3, 0, 1, 3, 2, 3, 1],
5 : [0, 1, 2, 3, 4, 1, 2, 3, 0, 1, 4, 3, 2, 1, 4, 3, 0, 1, 2, 3, 4, 1, 2, 3, 0, 1, 4, 3, 2, 1, 4, 3],
6 : [0, 1, 2, 3, 4, 5, 0, 2, 4, 1, 3, 2, 0, 5, 4, 2, 3, 1, 4, 0, 2, 5, 3, 4, 2, 1, 0, 4, 3, 5, 2, 4, 0, 1, 2, 3, 4, 5, 0, 2, 4, 1, 3, 2, 0, 5, 4, 2, 3, 1, 4, 0, 2, 5, 3, 4, 2, 1, 0, 4, 3, 5, 2, 4]
}

def interleave(A, B):
n = np.int( np.log2( len(A) ) )
m = np.int( np.log2( len(B) ) )

M = 2**m
N = 2**n

assert N >= M

gap_A = gap(A)
gap_B = gap(B)

assert gap_A >= gap_B

st_pairs = [ (i, M-i) for i in range(M) if i % 2 == 1]

sorted_pairs = sorted(st_pairs, key=lambda p: np.abs(p[1]/p[0] - gap_B/gap_A) )

best_pair = sorted_pairs[0]

s, t = best_pair

ratio = t/s

P = "b"

while len(P) < M:
b_to_a_ratio = P.count('b') / (P.count('a') + 1)

if b_to_a_ratio >= ratio :
P += 'a'
else:
P += 'b'

return P * N

def P_to_transition(P, A, B):
Z = []

pos_a = 0
pos_b = 0

n = np.int( np.log2( len(A) ) )

delta = n

for p in P:
if p == 'a' :
Z.append( A[pos_a % len(A)] )
pos_a += 1
else :
Z.append( B[pos_b % len(B)] + delta )
pos_b += 1

return Z

"""
Code for special case for 10-bits to fabric a gap of 8.

From: Binary gray codes with long bit runs
by: Luis Goddyn∗ & Pavol Gvozdjak

"""

T0 = [0, 1, 2, 3, 0, 1, 2, 3, 0, 1, 2, 3, 0, 1, 2, 3]

def to_4( i, sequence ):

permutations = []

indices = [j for j, x in enumerate(sequence) if x == i]

for pos in indices:
permutation = sequence.copy()
permutation[pos] = 4
permutations.append( permutation )

return permutations

def T_to_group(T):

state = np.array([0,0,0,0,0])

cycle = []

for pos in T:
cycle.append( state.copy() )
state[pos] += 1
state[pos] %= 4

return np.array( cycle )

def T_to_transition(T):

ticker = [False, False, False, False, False]

transitions = []

for t in T:
transistion = 2*t + 1*ticker[t]
ticker[t] = not ticker[t]

transitions.append( transistion )
return transitions

T1 = to_4( 0, T0)[3] * 4
T2 = to_4( 1, T1)[0] * 4
T3 = to_4( 2, T2)[1] * 4

transitions[10] = T_to_transition(T3)

for bits in range(2,21):
if bits in transitions:
print( "gray code for {} bits has gap: {}".format(bits, gap(transitions[bits]) ) )
else:
print( "finding code for {} bits...".format(bits) )

all_partitions = [ (i, bits-i) for i in range(bits) if i > 1]
partitions = [ (n, m) for (n,m) in all_partitions if n >= m and m > 1]
current_gap = 0
for n,m in partitions:
P = interleave( transitions[n], transitions[m])
Z = P_to_transition(P,  transitions[n], transitions[m])
candidate_gap = gap( Z )

if candidate_gap > current_gap:
current_gap = candidate_gap
transitions[bits] = Z
if valid_circuit(transitions[bits]):
print( "gray code for {} bits has gap: {}".format(bits, gap(transitions[bits]) ) )
else:
print( "found in-valid gray code")

``````

The loop above produces

``````gray code for 2 bits has gap: 2
gray code for 3 bits has gap: 2
gray code for 4 bits has gap: 2
gray code for 5 bits has gap: 4
gray code for 6 bits has gap: 4
finding code for 7 bits...
gray code for 7 bits has gap: 5
finding code for 8 bits...
gray code for 8 bits has gap: 5
finding code for 9 bits...
gray code for 9 bits has gap: 6
gray code for 10 bits has gap: 8
finding code for 11 bits...
gray code for 11 bits has gap: 8
finding code for 12 bits...
gray code for 12 bits has gap: 8
finding code for 13 bits...
gray code for 13 bits has gap: 9
finding code for 14 bits...
gray code for 14 bits has gap: 9
finding code for 15 bits...
gray code for 15 bits has gap: 11
finding code for 16 bits...
gray code for 16 bits has gap: 11
finding code for 17 bits...
gray code for 17 bits has gap: 12
finding code for 18 bits...
gray code for 18 bits has gap: 12
finding code for 19 bits...
gray code for 19 bits has gap: 13
finding code for 20 bits...
gray code for 20 bits has gap: 15
``````

use `transitions[3]` or `print_code_from_transition( transitions[3] )` to display the gray codes (in this example for 3 bits)

• Thank you! I generated these codes and pasted the values for 2-bit through 13-bit into a gist here gist.github.com/kylemcdonald/8c03de4ae1928ab5f3d203245549e802 Commented Jul 5, 2021 at 18:53
• Cool - I want to mention it is possible to improve the result for 19 from 13 to 14. This is quite some extra work but wanted to let the reader to know this in case there is a case. Commented Jul 6, 2021 at 20:40
• Maybe numba would be a good (and easy) choice to further speed this up? Commented Jul 15, 2021 at 3:41

I have exactly the same problem, and has ben unable to find a solution, but there is a good enough one I use.

The book "The Art of Computer Programming, Volume 4, Fascicle 2", by Donald E. Knuth has an image with an 8 bit Long Run Gray Code (no information on how to make it).

Screenshot of Knuth's 8 bit Long Run Gray Code

I extracted the binary sequence, and permutated some rows (it doesn't affects the result, because any row permutation is the same type of code). It is made of the binary representation of the numbers:

``````0, 1, 3, 7, 15, 31, 30, 62, 126, 254, 246, 247, 245, 213, 209, 145, 153, 152, 136, 8, 40, 42, 43, 35, 99, 103, 71, 70, 68, 76, 204, 220, 252, 253, 189, 185, 177, 179, 178, 146, 210, 82, 90, 91, 75, 107, 111, 109, 101, 100, 36, 164, 132, 134, 135, 143, 159, 155, 187, 186, 250, 242, 114, 112, 80, 81, 17, 21, 29, 13, 12, 44, 46, 174, 166, 167, 231, 199, 195, 193, 201, 200, 216, 88, 120, 56, 57, 49, 51, 55, 23, 22, 86, 94, 222, 206, 238, 239, 237, 233, 225, 161, 160, 128, 130, 2, 10, 11, 27, 59, 63, 127, 119, 118, 116, 244, 212, 148, 149, 157, 141, 137, 169, 168, 170, 162, 34, 98, 66, 67, 65, 69, 77, 93, 92, 124, 60, 188, 180, 181, 183, 151, 147, 211, 219, 218, 202, 74, 106, 104, 105, 97, 33, 37, 5, 4, 6, 14, 142, 158, 190, 191, 255, 251, 243, 241, 240, 208, 144, 16, 24, 25, 9, 41, 45, 47, 39, 38, 102, 230, 198, 196, 197, 205, 221, 217, 249, 248, 184, 176, 48, 50, 18, 19, 83, 87, 95, 79, 78, 110, 108, 236, 228, 229, 165, 133, 129, 131, 139, 138, 154, 26, 58, 122, 123, 115, 113, 117, 85, 84, 20, 28, 156, 140, 172, 173, 175, 171, 163, 227, 226, 194, 192, 64, 72, 73, 89, 121, 125, 61, 53, 52, 54, 182, 150, 214, 215, 223, 207, 203, 235, 234, 232, 224, 96, 32
``````

Screenshot

here is the Hamming distance map

Hamming distance

A hack that allows to enlarge it, is to "gray code" this Long Run Gray Code.

To continue the sequence, you reverse the order, and join the binary representation of the second element on the sequence, then reverse the entire sequence again, and join the next

Screenshot, how to extend the code

Is not a perfect solution, but works very well.
It doesn't have the best long runs that could be achieved with more bits (which are in the order of O(log_2(n)), but at least has the long runs of Knuth's 8 bit example.

If you got a solution to your problem, please, inform us. It is really hard to find one.