One important stumbling issue here is that "being able to pump" does not imply context free, rather "not being able to pump" shows it is not context free. *Similarly, being grey ***does not** imply you're an elephant, but being an elephant **does** imply you're grey...

```
Grammar context free => Pumping Lemma is definitely satisfied
Grammar not context free => Pumping Lemma *may* be satisfied
Pumping Lemma satisfied => Grammar *may* be context free
Pumping Lemma not satisfied => Grammar definitely not context free
# (we can write exactly the same for Ogden's Lemma)
# Here "=>" should be read as implies
```

That is to say, in order to demonstrate that a language is **not** context free we must show it **fails**(!) to satisfy one of these lemmata. *(Even if it satisfies both we haven't proved it is context free.)*

Below is a sketch proof that `L = { a^i b^j c^k d^l where i = 0 or j = k = l}`

is not context free *(although it satisfies The Pumping Lemma, it doesn't satisfy Ogden's Lemma)*:

If a language `L`

is context-free, then there exists some integer `p ≥ 1`

such that any string `s`

in `L`

with `|s| ≥ p`

(where `p`

is a pumping length) can be written as
`s = uvxyz`

with substrings `u, v, x, y and z`

, such that:

1. `|vxy| ≤ p`

,

2. `|vy| ≥ 1`

, and

3. `u v^n x y^n z`

is in `L`

for every natural number `n`

.

### In our example:

For any `s`

in `L`

(with `|s|>=p)`

:

- If
`s`

contains `a`

s then choose `v=a, x=epsilon, y=epsilon`

*(and we have ***no contradiction** to the language being context-free).
- If
`s`

contains no `a`

s (`w=b^j c^k d^l`

and one of `j`

, `k`

or `l`

is non-zero, since `|s|>=1`

) then choose `v=b`

(if `j>0`

, `v=c`

elif `k>0`

, else `v=c`

), `x=epsilon`

, `y=epsilon`

*(and we have ***no contradiction** to the language being context-free).

*(So unfortunately: ***using the Pumping Lemma we are unable to prove anything about **`L`

!

Note: the above was essentially the argument you gave in the question.)

If a language `L`

is context-free, then there exists some number `p > 0`

(where `p`

may or may not be a pumping length) such that for any string `w`

of length at least `p`

in `L`

and every way of "marking" `p`

or more of the positions in `w`

, `w`

can be written as
`w = uxyzv`

with strings `u, x, y, z,`

and `v`

such that:

1. `xz`

has at least one marked position,

2. `xyz`

has at most `p`

marked positions, and

3. `u x^n y z^n v`

is in `L`

for every `n ≥ 0`

.

*Note: this marking is the key part of Ogden's Lemma, it says: "not only can every element be "pumped", but it can be pumped using any *`p`

marked positions".

### In our example:

Let `w = a b^p c^p d^p`

and mark the positions of the `b`

s (of which there are `p`

, so `w`

satisfies the requirements of Ogden's Lemma), and let `u,x,y,z,v`

be a decomposition satisfying the conditions from Ogden's lemma (`z=uxyzv`

).

- If
`x`

or `z`

contain multiple symbols, then `u x^2 y z^2 w`

is not in `L`

, because there will be symbols in the wrong order (consider `(bc)^2 = bcbc`

).
- Either
`x`

or `z`

must contain a `b`

(by Lemma condition 1.)

This leaves us with five cases to check (for `i,j>0`

):

`x=epsilon, z=b^i`

`x=a, z=b^i`

`x=b^i, z=c^j`

`x=b^i, z=d^j`

`x=b^i, z=epsilon`

in every case (by comparing the number of `b`

s, `c`

s and `d`

s) we can see that `u x^2 v y^2 z`

is not in `L`

*(and we have ***a contradiction** (!) to the language being context-free, that is, **we've proved that **`L`

is not context free).

.

To summarise, `L`

is not context-free, but this **cannot be demonstrated using The Pumping Lemma** (but *can* by Ogden's Lemma) and thus we can say that:

Ogden's lemma is a second, **stronger** pumping lemma for context-free languages.