| Mr. Fox always puts aside some time on the weekends to practice his falconry. | |
| Mr. Fox owns **N** hawks, numbered from 1 to **N**. While numbering is | |
| somewhat impersonal, it quickly becomes infeasible to name each hawk | |
| individually when you have as many hawks as Mr. Fox. | |
| Every year, the local falconer club hosts a festival for falconers from across | |
| the nation. Mr. Fox shows off some of his hawks at each festival, and this | |
| year is no different. Selecting a set of hawks to display is not a | |
| straightforward task however. Hawks can be temperamental creatures, and | |
| they'll refuse to perform if they don't like the situation they find | |
| themselves in. Luckily, after careful study, Mr. Fox has been able to capture | |
| the hawks' preferences in a simple boolean expression. | |
| For example, let's say Mr. Fox has 4 hawks. Hawk 1 will only perform if some | |
| other hawk is present. Hawks 2 and 3 will only perform if hawks 1 or 4 are | |
| present. Hawk 4 is much more easy-going and will perform in all situations. We | |
| can express these preferences with the following expression: | |
| ((1 & (2 | 3)) | 4) | |
| Each number is a boolean variable indicating whether or not Mr. Fox brings | |
| that hawk. If the expression is satisfied, then all of the hawks he brings | |
| will perform. If the expression is not satisfied, the hawks will be moody and | |
| that means no blue ribbons for Mr. Fox. | |
| Mr. Fox is keen not to bore his audience, so he always brings a different set | |
| of hawks each year. This is the **K**th annual festival, so he would like to | |
| bring the set of performing hawks with the **K**th lowest value. Mr. Fox | |
| defines the value of a set of hawks as follows: the empty set has a value of | |
| 0, and hawk **i** adds 2**i** to the value of a set. So with 3 hawks, the sets | |
| in increasing order are: | |
| {1} | |
| {2} | |
| {1, 2} | |
| {3} | |
| {1, 3} | |
| {2, 3} | |
| {1, 2, 3} | |
| Note that Mr. Fox always brings a non-empty set of hawks. | |
| ### Input | |
| Input begins with an integer **T**, the number of festivals under | |
| consideration. For each festival, there is first a line containing the space- | |
| separated integers **N** and **K**. The next line contains the boolean | |
| expression encoding the hawks' preferences. | |
| ### Output | |
| For the **i**th festival, print a line containing "Case #**i**: " followed by | |
| value of the set of hawks that Mr. Fox brings modulo 109+7. | |
| ### Constraints | |
| 1 ≤ **T** ≤ 20 | |
| 1 ≤ **N** ≤ 200,000 | |
| 1 ≤ **K** ≤ 1018 | |
| Expressions contain no more than 2,500,000 characters each. | |
| It is guaranteed that there are at least **K** sets of performing hawks. | |
| The boolean expression adheres to the following grammar: | |
| [expression] ::= "(" "~" [expression] ")" | "(" [expression] [binary-operator] [expression] ")" | [variable] | |
| [binary-operator] ::= "|" | "^" | "&" | |
| [variable] ::= [digit] | [digit] [variable] | |
| [digit] ::= "0" | "1" | "2" | "3" | "4" | "5" | "6" | "7" | "8" | "9" | |
| Each hawk appears in the boolean expression exactly once. | |
| Whitespace may appear arbitrarily in the expression (except within variables) | |
| to improve readability. | |
| ### Explanation of Sample | |
| In the first and second cases, the first 4 performing sets, in order, are {1, | |
| 2}, {1, 3}, {1, 2, 3}, and {4}, with values of 6, 10, 14, and 16 respectively. | |