# How to handle arrays minimizing a transition graph

Im trying to write a program that minimizes a Transition Graph (its basically combining states with similar numbers). Basically, the algorithm is to first find states with the same 'a' and 'b' inputs, combine them, remove them from the 'leftovers' list, then find states that have either 'a' or 'b' and combine them.

Here is an example:

``````Initial TG:
final state is state 1
State  Input a  Input b
[0]    [3]      [1]
[1]    [1]      [4]
[2]    [3]      [1]
[3]    [6]      [3]
[4]    [2]      [7]
[5]    [1]      [3]
[6]    [2]      [5]
[7]    [1]      [3]

final state     leftover
[ 1 ]           [ 0 2 3 4 5 6 7 ]

final state    same a,b   leftover
[ 1 ]          [ 0 2 ]    [ 3 4 5 6 7 ]

final state    same a,b   same a,b    leftover
[ 1 ]          [ 0 2 ]    [5 7 ]      [ 3 4 6 ]

final state    same a,b   same a,b    same a     leftover
[ 1 ]          [ 0 2 ]    [ 5 7 ]     [ 4 6 ]    [ 3 ]

The Final Minimized TG is now:
State  Input a  Input b
[0,2]  [3]      [1]
[1]    [1]      [4,6]
[3]    [4,6]    [3]
[4,6]  [0,2]    [5,7]
[5,7]  [1]      [3]
``````

The problem Im facing is knowing how/what to do with the arrays since there could be any number of combinations depending on the amount of states in a given Transition Graph. Any ideas on how to code this or any advice on how to handle everything?

Cheers

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## migrated from cs.stackexchange.comNov 26 '12 at 23:26

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There are established algorithms for minimising finite automata, readily found on Wikipedia or in any introductory automata textbook. Is there a particular reason for not using those? – Raphael Nov 24 '12 at 15:25
To be more specific, I'm not sure how to mark items as read or unreachable and how to program it. Following the algorithms on paper is no problem I just need help with how to code it. – Noah Jones Nov 26 '12 at 23:12
@NoahJones Are you still waiting for answer – Grijesh Chauhan Dec 21 '12 at 8:12