So you've got a big set of strings of length
N bits (where
N is approximately 100), and you want a simple logic expression that matches those strings and none others?
You could try to make a program that builds the Kernaugh map for you. It would be an interesting exercise. I don't remember much about Kernaugh maps, but I think the labels on rows and columns arranged using a Gray code.
Or you could just try to make the problem more tractable for hand-made Kernaugh maps. For each of the strings, find the bits that are common to all of them. Then print a list of the remaining bit positions for the human to build a map of.
A bit of Python code:
str_len = 5
strs = [
for i in range(str_len):
if all([x[i] for x in strs]):
print 'Bit %d is 1' % i
elif not any([x[i] for x in strs]):
print 'Bit %d is 0' % i
print 'Bit %d is contingent' % i
At that point you could try to think of ways to encode the
B remaining contingent bits. In this example, it so happens that all cases are covered (and you could detect that as a special case -- e.g.
N = 2^B).
A brute force algorithm for finding a formula for the contingent bits would be:
- Pick the next contingent bit
- Divide S into S0 (the subset where bit
i = 0) and S1 (the subset where bit
i = 1).
- Recursively find the formulas f0 and f1 for S0 and S1 respectively.
- The formula for S is
(~b[i] & f0) | (b[i] & f1).
There are some optimisations. The easy one is where S0 or S1 is empty -- then just omit that branch of the resulting formula. Another one is where all possible combinations are in a set (similar to the example above); the formula doesn't need to refer to the bits in that case. The hardest one is finding a good order to iterative over the bits in. Doing it naively in order may result in a less-than-optimal formula.
You could in fact skip the first suggestion above and run this over all bits. Bits which are always 1 or 0 would simply yield trivial cases where S0 or S1 is empty.
This rather messy Python code performs the algorithm with a few optimisations. N.B. It's not tested much and doesn't necessarily produce optimal output!
def get_formula(S, i=0):
# Special case where it's an empty set -- return a tautology
if len(S) == 0:
remaining_bits = len(S) - i
# Special case where no bits are left
if remaining_bits <= 0:
# Partition the set
S0 = filter(lambda x: x[i] == 0, S)
S1 = filter(lambda x: x[i] == 1, S)
f0 = get_formula(S0, i+1)
f1 = get_formula(S1, i+1)
# Special cases where one subset is empty
# Also special case for subformula being tautology
if len(S1) == 0:
if f0 == '1':
return '~b[%d]' % i
return '~b[%d] & (%s)' % (i, f0)
if len(S0) == 0:
if f1 == '1':
return 'b[%d]' % i
return 'b[%d] & (%s)' % (i, f1)
# Special cases where one or both subformulas was a tautology
if f0 == '1' and f1 == '1':
if f0 == '1':
return '~b[%d] | b[%d] & (%s)' % (i, i, f1)
if f1 == '1':
return '~b[%d] & (%s) | b[%d]' % (i, f0, 1)
# General case
return '~b[%d] & (%s) | b[%d] & (%s)' % (i, f0, i, f1)
strs = [
Finally, I think one way to make this code find more optimal formulas would be to scan ahead in
S for bits that are always 0 or always 1, and process them early. The remaining continginent bits in each subset will get pushed into the deeply-nested subformulas where they will form less redundant formulas than when they are processed too early. I think this will in effect simulate a Kernaugh-map style construction: at each step, the set of always 0 or always 1 bits defines a rectangle on the map. Find that set, process them all at once (e.g. as a compact formula
~b & ~b & ~b) then recurse on the remaining bits. You need to keep track of which bit positions have already been processed, rather than doing them in order using
(Actually, now that I think about it, for optimal formulas you also need to partition smartly by selecting a bunch of correlated bits at a time. An interesting problem...)