I'm learning the difference between the lemmata in the question. Every reference I can find uses the example:
{(a^i)(b^j)(c^k)(d^l) : i = 0 or j = k = l}
to show the difference between the two. I can find an example using the regular lemma to "disprove" it.
Select w = uvxyz, s.t. |vy| > 0, |vxy| <= p. Suppose w contains an equal number of b's, c's, d's.
I selected:
u,v,x = ε
y = (the string of a's)
z = (the rest of the string w)
Pumping y will just add to the number of a's, and if |b|=|c|=|d| at first, it still will now.
(Similar argument for if w has no a's. Then just pump whatever you want.)
My question is, how does Ogden's lemma change this strategy? What does "marking" do?
Thanks!
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 integerp ≥ 1
such that any strings
inL
with|s| ≥ p
(wherep
is a pumping length) can be written ass = uvxyz
with substringsu, v, x, y and z
, such that:
1.|vxy| ≤ p
,
2.|vy| ≥ 1
, and
3.u v^n x y^n z
is inL
for every natural numbern
.
For any s
in L
(with |s|>=p)
:
s
contains a
s then choose v=a, x=epsilon, y=epsilon
(and we have no contradiction to the language being context-free).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 numberp > 0
(wherep
may or may not be a pumping length) such that for any stringw
of length at leastp
inL
and every way of "marking"p
or more of the positions inw
,w
can be written asw = uxyzv
with stringsu, x, y, z,
andv
such that:
1.xz
has at least one marked position,
2.xyz
has at mostp
marked positions, and
3.u x^n y z^n v
is inL
for everyn ≥ 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".
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
).
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
).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.
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