You can follow the following steps to reduce lambda expressions:

- Fully parenthesize the expression to avoid mistakes and make it more obvious where function application takes place.
- Find a function application, i.e. find an occurrence of the pattern
`(λX. e1) e2`

where `X`

can be any valid identifier and `e1`

and `e2`

can be any valid expressions.
- Apply the function by replacing
`(λx. e1) e2`

with `e1'`

where `e1'`

is the result of replacing each free occurrence of `x`

in `e1`

with `e2`

.
- Repeat 2 and 3 until the pattern no longer occurs. Note that this can lead to an infinite loop for non-normalizing expressions, so you should stop after 1000 iterations or so ;-)

So for your example we start with the expression

```
((λm. (λn. (λa. (λb. (m ((n a) b)) b)))) (λf. (λx. x))) (λf. (λx. (f x)))
```

Here the subexpression `(λm. (λn. (λa. (λb. (m ((n a) b)) b)))) (λf. (λx. x))`

fits our pattern with `X = m`

, `e1 = (λn. (λa. (λb. (m ((n a) b)) b))))`

and `e2 = (λf. (λx. x))`

. So after substitution we get `(λn. (λa. (λb. ((λf. (λx. x)) ((n a) b)) b)))`

, which makes our whole expression:

```
(λn. (λa. (λb. ((λf. (λx. x)) ((n a) b)) b))) (λf. (λx. (f x)))
```

Now we can apply the pattern to the whole expression with `X = n`

, `e1 = (λa. (λb. ((λf. (λx. x)) ((n a) b)) b))`

and `e2 = (λf. (λx. (f x)))`

. So after substituting we get:

```
(λa. (λb. ((λf. (λx. x)) (((λf. (λx. (f x))) a) b)) b))
```

Now `((λf. (λx. (f x))) a)`

fits our pattern and becomes `(λx. (a x))`

, which leads to:

```
(λa. (λb. ((λf. (λx. x)) ((λx. (a x)) b)) b))
```

This time we can apply the pattern to `((λx. (a x)) b)`

, which reduces to `(a b)`

, leading to:

```
(λa. (λb. ((λf. (λx. x)) (a b)) b))
```

Now apply the pattern to `((λf. (λx. x)) (a b))`

, which reduces to `(λx. x)`

and get:

```
(λa. (λb. b))
```

Now we're done.