I recently debugged an OCR decoder. It is a newly implemented decoder with many fast pruning techniques and supporting to new features. It runs smoothly, but the decoded outputs are all junks. I was scared at the first glance, because this code is very long but very few comments. I wish my colleague who wrote this code is still in the company to debug this code himself, but it seems that I have no excuse to not do this, because I am the only guy worked on similar decoders before.
It is not easy to determine where is the problem. It could be these newly implemented pruning techniques, which I didnot know at all; it could be the score computations of each possible candidate; and it could be something else. I tried to first eliminate the two possible problems. I firstly turn-off all pruning and see what happens. But best candidates were close to those produced by applying the new pruning techniques. This meant the pruning stage did not accidentally discard good candidates.
So I go to the second reason and to see whether the likelihood scores of each candidate is incorrect. It turns out the computation process of these scores are correct, but I really have no clue whether these scores as expected. Because they were computed from a number of models and input features. It does not make any sense for a human to see these raw feature files and model parameters. So the only option I have is to print out all intermediate feature files and the used model parameters, and manually check these results with those produced by our previous decoder.
I saw these two sets of results showed similar tendencies, but I was not sure whether any error in this stage become larger and larger during propagation and eventually cause the problem. I then used the old decoder to decode the intermediate results from the new decoder, and this time output results were quite reasonable. However, when I used the new decoder to decode the results from the old decoder, the output results are still junks. I say to myself at least the new decoder is correct before computing scores.
I then checked the score computing stage of the new decoder line by line, but I failed to find anything suspicious. I copied this part of code to the old decoder, but the old decoder stopped working. I copied the corresponding old decoder code to the new decoder, but the new decoder still produced junks. I was completely puzzled, because I expected at least one of the above copy attempts should work.
In the next day, I decided to compare these two parts of coder in parallel, and finally noticed one difference: the new coder used a log-function of base e, but the old one used a log-function of base 10 to compute log-likelihood scores. However, this difference should be OK, because all what we need is to select candidates with the highest scores. As long as all candidates are represented in the same base, it should be OK.
Other than this difference, I really cannot find anything essentially different. I was on this code for more than three days, and I was really frustrated. Just before I gave up, I suddenly noticed that all input transition probabilities were already in a log form, and these probabilities are fed by our old trainer, whose log is also of base 10. Aha, this is the problem. The computation stage is incorrect simply because the log likelihood it computes from theoretical models and actual observed from features are of different bases. After I replace all log_e with log_10 in the new decoder, it runs normally.