I'm assuming this is theoretical since it's homework, and not something you actually need to code at this point. (Kendrick's answer covers the code approach)

The basic idea is to start with your BNF start variable and try to figure out how to expand it, applying rules one at a time, to see if you can come up with your input sequence.

For a ruleset like the following:

```
(1) start: expression
(2) expression: expression '+' term
(3) | expression '-' term
(4) | term
(5) term: 'a'
(6) | 'b'
```

Given the expression `a + b - a`

, you would go something like this:

a. `start`

(given)

b. `expression`

(1)

c. `expression '-' term`

(3)

d. `expression '-' 'a'`

(5)

e. `expression '+' term '-' 'a'`

(2)

f. `term '+' term '-' 'a'`

(4)

g. `'a' '+' term '-' 'a'`

(5)

h. `'a' '+' 'b' '-' 'a'`

(6)

So that's how you do it one step at a time... Now the trick is, you need to trace out all your rule invocations. So your real tree would look something like this:

```
start
| (b)
expression
/ | \ (c)
expression '-' term
/ | \ (e) | (d)
expression '+' term 'a'
| (f) | (h)
term 'b'
| (g)
'a'
```

It's a little complicated at first, but once you actually see how it's done it's not too hard to pick up.

**Note:** Some people find it easier to work backwards, starting with your input and then applying rules in reverse to try to find your start expression. When you write a parser, you will inevitably need to follow this route on some level.

**EDIT:** I listed all the expression steps using lowercase letters above, and then showed that each set of branches from the tree actually corresponds with one of the rule applications. May or may not help.

treenode out of a recursive rule like`<syntax> ::= <rule> | <rule> <syntax>`

, unless one used identifiers to indicate the recursion. Can you find any examples in your textbook? – Joey Adams Dec 7 '10 at 18:25