# Need help with converting to Chomsky Normal Form?

Convert the grammar below into Chomsky Normal Form. Give all the intermediate steps.

``````S -> AB | aB
A -> aab|lambda
B -> bbA
``````

Ok so the first thing I did was add a new start variable `S0`

so now I have

``````S0 -> S
S -> AB | aB
A -> aab|lambda
B -> bbA
``````

then I removed all of the lambda rules:

``````S0 -> S
S -> AB | aB | B
A -> aab
B -> bbA | bb
``````

Then I checked for `S->S` and `A->B` type rules which did not exist. And that was the answer I came up with, do I need to do anything further or did I do anything wrong?

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The first thing to check is, did you read Wikipedia? –  Nayuki Minase Sep 19 '11 at 0:19
Clarification request: What is lambda? Is it a terminal symbol? –  Nayuki Minase Sep 19 '11 at 0:23
yeah, why? I have no idea what the last rule is saying. Lambda is the Epsilon in wikipedia, it goes to null –  tehman Sep 19 '11 at 0:23
Rule #3 on the Wikipedia page says that only the start symbol is allowed to expand to epsilon. So you will need to deal with your `A -> ... | lambda/epsilon`. –  Nayuki Minase Sep 19 '11 at 0:26
right....didn't I do that? –  tehman Sep 19 '11 at 0:33

Wikipedia says:

In computer science, a context-free grammar is said to be in Chomsky normal form if all of its production rules are of the form:

• A -> BC, or
• A -> α, or
• S -> ε

where A, B, C are nonterminal symbols, α is a terminal symbol, S is the start symbol, and ε is the empty string. Also, neither B nor C may be the start symbol.

``````S0 -> S
S -> AB | aB | B
A -> aab
B -> bbA | bb
``````

Instead of using `|` to denote different choices, split a rule into multiple rules.

``````S0 -> S
S -> AB
S -> aB
S -> B
A -> aab
B -> bbA
B -> bb
``````

Create new rules `Y -> a` and `Z -> b` because we will need them soon.

``````S0 -> S
S -> AB
S -> aB
S -> B
A -> aab
B -> bbA
B -> bb
Y -> a
Z -> b
``````

`S -> aB` is not of the form `S -> BC` because `a` is a terminal. So change `a` into `Y`:

``````S0 -> S
S -> AB
S -> YB
S -> B
A -> aab
B -> bbA
B -> bb
Y -> a
Z -> b
``````

Do the same for the `B -> bb` rule:

``````S0 -> S
S -> AB
S -> YB
S -> B
A -> aab
B -> bbA
B -> ZZ
Y -> a
Z -> b
``````

For `A -> aab`, create `C -> YY`; for `B -> bbA`, create `D -> ZZ`:

``````S0 -> S
S -> AB
S -> YB
S -> B
A -> CZ
C -> YY
B -> DA
D -> ZZ
B -> ZZ
Y -> a
Z -> b
``````

For `S -> B`, duplicate the one rule where `S` occurs on the right hand side and inline the rule:

``````S0 -> B
S0 -> S
S -> AB
S -> YB
A -> CZ
C -> YY
B -> DA
D -> ZZ
B -> ZZ
Y -> a
Z -> b
``````

Deal with the rules `S0 -> B` and `S0 -> S` by joining the right hand side to the left hand sides of other rules. Also, delete the orphaned rules (where the LHS symbol never gets used on RHS):

``````S0 -> DA
S0 -> ZZ
S0 -> AB
S0 -> YB
A -> CZ
C -> YY
B -> DA
D -> ZZ
B -> ZZ
Y -> a
Z -> b
``````

And we're done. Phew!

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then wouldn't I still need to get rid of the epsilon? I think the added rules would just be S -> B and B-> H? –  tehman Sep 19 '11 at 0:32
wow excellent explanation, do you mind expanding a little on what you did for the last two boxes? –  tehman Sep 19 '11 at 1:10

Without getting into too much theory and proofs(you could look at this in Wikipedia), there are a few things you must do when converting a Context Free Grammar to Chomsky Normal Form, you generally have to perform four Normal-Form Transformations. First, you need to identify all the variables that can yield the empty string(lambda/epsilon), directly or indirectly - (Lambda-Free form). Second, you need to remove unit productions - (Unit-Free form). Third, you need to find all the variables that are live/useful (Usefulness). Four, you need to find all the reachable symbols (Reachable). At each step you might or might not have a new grammar. So for your problem this is what I came up with...

Context-Free Grammar

``````G(Variables = { A B S }
Start = S
Alphabet = { a b lamda}

Production Rules = {
S  ->  |  AB  |  aB  |
A  ->  |  aab  |  lamda  |
B  ->  |  bbA  |   } )
``````

Remove lambda/epsilon

``````ERRASABLE(G) = { A }

G(Variables = { A S B }
Start = S
Alphabet = { a b }

Production Rules = {
S  ->  |  AB  |  aB  |  B  |
B  ->  |  bbA  |  bb  |   } )
``````

Remove unit produtions

``````UNIT(A) { A }
UNIT(B) { B }
UNIT(S) { B S }
G (Variables = { A B S }
Start = S
Alphabet = { a b }

Production Rules = {
S  ->  |  AB  |  aB  |  bb  |  bbA  |
A  ->  |  aab  |
B  ->  |  bbA  |  bb  |   })
``````

Determine live symbols

``````LIVE(G) = { b A B S a }

G(Variables = { A B S }
Start = S
Alphabet = { a b }

Production Rules = {
S  ->  |  AB  |  aB  |  bb  |  bbA  |
A  ->  |  aab  |
B  ->  |  bbA  |  bb  |   })
``````

Remove unreachable

``````REACHABLE (G) = { b A B S a }
G(Variables = { A B S }
Start = S
Alphabet = { a b }

Production Rules = {
S  ->  |  AB  |  aB  |  bb  |  bbA  |
A  ->  |  aab  |
B  ->  |  bbA  |  bb  |   })
``````

Replace all mixed strings with solid nonterminals

``````G( Variables = { A S B R I }
Start = S
Alphabet = { a b }

Production Rules = {
S  ->  |  AB  |  RB  |  II  |  IIA  |
A  ->  |  RRI  |
B  ->  |  IIA  |  II  |
R  ->  |  a  |
I  ->  |  b  |   })
``````

Chomsky Normal Form

``````G( Variables = { V A B S R L I Z }
Start = S
Alphabet = { a b }

Production Rules = {
S  ->  |  AB  |  RB  |  II  |  IV  |
A  ->  |  RL  |
B  ->  |  IZ  |  II  |
R  ->  |  a  |
I  ->  |  b  |
L  ->  |  RI  |
Z  ->  |  IA  |
V  ->  |  IA  |   })
``````
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Alternative answer: The grammar can only produce a finite number of strings, namely 6.

``````S -> aabbbaab | aabbb | abbaab | abb | bbaab | bb
``````

You can now condense this back to Chomsky Normal Form by hand.

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