# Solving “Welcome to Code Jam” from Google Code Jam 2009

I am trying to solve the following code jam question,ive made some progress but for few cases my code give wrong outputs.. Welcome to Code jam

So i stumbled on a solution by dev "rem" from russia. I've no idea how his/her solution is working correctly.. the code...

``````const string target = "welcome to code jam";

char buf[1<<20];

int main() {
freopen("input.txt", "rt", stdin);
freopen("output.txt", "wt", stdout);

gets(buf);
FOR(test, 1, atoi(buf)) {
gets(buf);
string s(buf);
int n = size(s);
int k = size(target);
vector<vector<int> > dp(n+1, vector<int>(k+1));
dp[0][0] = 1;
const int mod = 10000;
assert(k == 19);
REP(i, n) REP(j, k+1) {// Whats happening here
dp[i+1][j] = (dp[i+1][j]+dp[i][j])%mod;
if (j < k && s[i] == target[j])
dp[i+1][j+1] = (dp[i+1][j+1]+dp[i][j])%mod;
}
printf("Case #%d: %04d\n", test, dp[n][k]);
}

exit(0);
}//credit rem
``````

Can somebody explain whats happening in the two loops?

Thanks.

-
Oh boy, here's a tip: don't try to learn from this code. – R. Martinho Fernandes Mar 17 '12 at 10:54
how about posting the question here – Cheers and hth. - Alf Mar 17 '12 at 10:55
Rest in piece REM. One of the really good coders, that passed away really young. You can see that you still have impact, not forgotten. – Boris Strandjev Mar 17 '12 at 11:01
@R.MartinhoFernandes why? is its approach wrong?? whats wrong about it? – ashishsony Mar 17 '12 at 11:35
@BorisStrandjev did u just joked about REM ? – ashishsony Mar 17 '12 at 11:36

What he is doing: dynamic programming, this far you can see too.

He has 2D array and you need to understand what is its semantics. The fact is that `dp[i][j]` counts the number of ways he can get a subsequence of the first `j` letters of `welcome to code jam` using all the letters in the input string upto the ith index. Both indexes are 1 -based to allow for the case of not taking any letters from the strings.

For example if the input is:

``````welcome to code jjam
``````

The values of `dp` in different situations are going to be:

`````` dp[1][1] = 1; // first letter is w. perfect just the goal
dp[1][2] = 0; // no way to have two letters in just one-letter string
dp[2][2] = 1; // again: perfect
dp[1][2] = 1; // here we ignore the e. We just need the w.
dp[7][2] = 2; // two ways to construct we: [we]lcome and [w]elcom[e].
``````

The loop you are specifically asking about calculates new dynamic values based on the already calculated ones.

-

Whoa, I was practicing this problem few days ago and and stumbled across this question.

I suspect that saying "he's doing dynamic programming" won't not explain too much if you did not study DP.

I can give clearer implementation and easier explanation:

``````string phrase = "welcome to code jam"; // S
string text; getline(cin, text); // T
vector<int> ob(text.size(), 1);
int ans = 0;
for (int p = 0; p < phrase.size(); ++p) {
ans = 0;
for (int i = 0; i < text.size(); ++i) {
if (text[i] == phrase[p]) ans = (ans + ob[i]) % 10000;
ob[i] = ans;
}
}
cout << setfill('0') << setw(4) << ans << endl;
``````

To solve the problem if S had only one character `S[0]` we could just count number of its occurrences.

If it had only two characters `S[0..1]` we see that each occurrence `T[i]==S[1]` increases answer by the number of occurrences of `S[0]` before index `i`.

For three characters `S[0..2]` each occurrence `T[i]==S[2]` similarly increases answer by number of occurrences of `S[0..1]` before index `i`. This number is the same as the answer value at the moment the previous paragraph had processed `T[i]`.

If there were four characters, the answer would be increasing by number of occurrences of the previous three before each index at which fourth character is found, and so on.

As every other step uses values from the previous ones, this can be solved incrementally. On each step `p` we need to know number of occurrences of previous substring `S[0..p-1]` before any index `i`, which can be kept in array of integers `ob` of the same length as T. Then the answer goes up by `ob[i]` whenever we encounter `S[p]` at `i`. And to prepare `ob` for the next step, we also update each `ob[i]` to be the number of occurrences of `S[0..p]` instead — i.e. to the current answer value.

By the end the latest answer value (and the last element of `ob`) contain the number of occurrences of whole `S` in whole `T`, and that is the final answer.

Notice that it starts with `ob` filled with ones. The first step is different from the rest; but counting number of occurrences of `S[0]` means increasing answer by `1` on each occurrence, which is what all other steps do, except that they increase by `ob[i]`. So when every `ob[i]` is initially `1`, the first step will run just like all others, using the same code.

-