I assume you're talking about this link.
If so, read it very carefully hundreds of times ;-) It's "additive" given that you're only considering alignments where the split is fixed at a specific (i, j)
pair.
In your supposed counterexample, you started by breaking the initial G
off of GTC
and the initial GTA
off of GTAA
. Then G--
is the shortest way to change GTC
into G
. Fine. Continuing with the same split, you still needed to align the remaining right-hand parts: TC
with A
. Also fine.
This is no claim that this is the best possible split. There's only the claim that it's the best possible alignment given that you're only considering that specific split.
It's one small step in the dynamic programming approach, which is the part you're missing. It remains to compute the best alignments across all possible splits.
Dynamic programming is tricky at first. You shouldn't expect to learn it from staring at telegraphic slides. Read a real textbook, or search the web for tutorials.
Speeding a recursive version
The comments indicate that the code for this "must" be recursive. Oh well ;-)
Caution: I just threw this together to illustrate a general procedure for speeding suitable recursive functions. It's barely been tested at all.
First an utterly naive recursive version:
def lev(a, b):
if not a:
return len(b)
if not b:
return len(a)
return min(lev(a[:-1], b[:-1]) + (a[-1] != b[-1]),
lev(a[:-1], b) + 1,
lev(a, b[:-1]) + 1)
I'll be using "absd31-km"
and "ldk3-1fjm"
as arguments in all runs discussed here.
On my box, using Python 3, that simple function returns 7 after about 1.6 seconds. It's horribly slow.
The most obvious problem is the endlessly repeated string slicing. Each :
in an index takes time proportional to the current length of the string being sliced. So the first refinement is to pass string indices instead. Since the code always slices off a prefix of a string, we only need to pass the "end of string" indices:
def lev2(a, b):
def inner(j1, j2):
if j1 < 0:
return j2 + 1
if j2 < 0:
return j1 + 1
return min(inner(j1-1, j2-1) + (a[j1] != b[j2]),
inner(j1-1, j2) + 1,
inner(j1, j2-1) + 1)
return inner(len(a)-1, len(b)-1)
Much better! This version returns 7 in "only" about 1.44 seconds. Still horridly slow, but better than the original. It's advantage would increase on longer strings, but who cares ;-)
We're almost done! The important thing to notice now is that the function passes the same arguments many times over the course of a run. We capture those in "a memo" to avoid all the redundant computation:
def lev3(a, b):
memo = {}
def inner(j1, j2):
if j1 < 0:
return j2 + 1
if j2 < 0:
return j1 + 1
args = j1, j2
if args in memo:
return memo[args]
result = min(inner(j1-1, j2-1) + (a[j1] != b[j2]),
inner(j1-1, j2) + 1,
inner(j1, j2-1) + 1)
memo[args] = result
return result
return inner(len(a)-1, len(b)-1)
That version returns 7 in about 0.00026 seconds, over 5000 times faster than lev2
did it.
Now if you've studied the matrix-based algorithms, and squint a little, you'll see that lev3()
effectively builds a 2-dimensional matrix mapping index pairs to results in its memo
dictionary. They're really the same thing, except that the recursive version builds the matrix in a more convoluted way. On the other hand, the recursive version may be easier to understand and to reason about. Note that the slides you found called the memoization aporoach "top down" and the nested-loop matrix approach "bottom up". Those are nicely descriptive.
You haven't said anything about how your recursive function works, but if it suffers any similar kinds of recursive excess, you should be able to get similar speedups using similar techniques :-)