USACO 2020 December Contest, Gold
Problem 2. Bovine Genetics
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Farmer John starts with a single genome and edits it by performing the following steps:
- Split the genome between every two consecutive equal characters.
- Reverse each of the resulting substrings.
- Concatenate the reversed substrings together in the same order.
For example, if FJ started with the genome AGGCTTT then he would perform the following steps:
- Split between the consecutive Gs and Ts to get AG | GCT | T | T.
- Reverse each substring to get GA | TCG | T | T.
- Concatenate the substrings together to get GATCGTT.
Unfortunately, after editing the genome, Farmer John's computer crashed and he lost the sequence of the genome he originally started with. Furthermore, some parts of the edited genome have been damaged, meaning that they have been replaced by question marks.
Given the sequence of the edited genome, help FJ determine the number of possibilities for the original genome, modulo $10^9+7$.
INPUT FORMAT (input arrives from the terminal / stdin):
A non-empty string where each character is one of A, G, C, T, or ?.OUTPUT FORMAT (print output to the terminal / stdout):
The number of possible original genomes modulo $10^9+7$.SAMPLE INPUT:
?
SAMPLE OUTPUT:
4
The question mark can be any of A, G, C, or T.
SAMPLE INPUT:
GAT?GTT
SAMPLE OUTPUT:
3
There are two possible original genomes aside from AGGCTTT, which was described above.
AGGATTT -> AG | GAT | T | T -> GA | TAG | T | T -> GATAGTT TAGGTTT -> TAG | GT | T | T -> GAT | TG | T | T -> GATTGTT
SCORING:
- In test cases 1-4, the genome has length at most $10$.
- In test cases 5-11, the genome has length at most $10^2$.
- In test cases 12-20, there are no additional constraints.
Problem credits: Benjamin Qi