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Dahlia is taking a roadtrip across all of Canada! Along the way, she's
spending a night in one of the country's hallmark cities, Toronto.
Toronto's nighttime skyline can be represented as a 2D plane, with the ground
forming a horizontal line with y-coordinate 0. There are **W** building
windows, with the _i_th one at coordinates (**XWi**, **YWi**). There are also
**S** visible stars, with the _i_th one at coordinates (**XSi**, **YSi**).
It's guaranteed that all **W** \+ **S** of these points are distinct, and that
no star is directly below a window (having the same x-coordinate but a smaller
y-coordinate).
At night, it's impossible to see any given window unless there's light coming
from it. On any given night, each window is independently either lit up or not
with equal probability. As such, there are 2**W** equally-likely subsets of
windows which might be visible. Dahlia finds herself looking at Toronto's
skyline on one such random night.
Dahlia knows that Toronto consists of 0 or more buildings, each of which
covers a rectangular portion of the sky with some bottom-left corner (**x1**,
0) and some top-right corner (**x2**, **h**), for some real values of **x1**,
**x2**, and **h** (such that **x1** < **x2** and **h** > 0). The buildings
might overlap with one another. Based on Dahlia's view of the stars and lit-up
windows, she can infer some things about the set of buildings present. In
particular, for each lit-up window _i_, Dahlia realizes that there must be at
least one building whose rectangle inclusively covers the point (**XWi**,
**YWi**). Furthermore, for each star _i_, Dahlia realizes that there must be
no buildings whose rectangles inclusively cover the point (**XSi**, **YSi**).
Dahlia is going to assume that Toronto consists of as few buildings as
possible which are consistent with her observations on that night. What's the
expected number of buildings which she'll assume exist? In order to avoid
floating-point arithmetic and large integers, output this expected number
multiplied by 2**W** (which is guaranteed to result in an integer) and then
taken modulo 1,000,000,007.
### Input
Input begins with an integer **T**, the number of skylines. For each skyline,
there is first a line containing the space-separated integers **W** and **S**.
Then, **W** lines follow, the _i_th of which contains the space-separated
integers **XWi** and **YWi**. Then, **S** lines follow, the _i_th of which
contains the space-separated integers **XSi** and **YSi**.
### Output
For the _i_th universe, output a line containing "Case #_i_: " the expected
number of buildings which Dahlia will assume exist, multiplied by 2**W** and
then taken modulo 1,000,000,007.
### Constraints
1 ≤ **T** ≤ 150
1 ≤ **W** ≤ 80
1 ≤ **S** ≤ 50
1 ≤ **XWi**, **YWi**, **XSi**, **YSi** ≤ 1,000,000,000
### Explanation of Sample
In the first case, there's a 50% chance that the single window will be
visible, in which case Dahlia will assume that Toronto has 1 building. There's
also a 50% chance that it won't be visible, in which case she'll assume that
there are 0 buildings. As such, the expected number of buildings which she'll
assume exist is (1 + 0) / 2 = 1/2. This should then be multiplied by 21 and
taken modulo 1,000,000,007 to produce a final answer of 1.
In the second case, however many windows are visible, Dahlia will assume
Toronto has that many buildings. For example, if both windows are visible,
then there must be at least 2 buildings, as a single building can't account
for both windows without also covering the single visible star. This results
in a final answer of ((0 + 1 + 1 + 2) / 4 * 22) modulo 1,000,000,007 = 4.
In the third case, the final answer is ((0 + 1 + 1 + 1 + 1 + 1 + 2 + 2) / 8 *
23) modulo 1,000,000,007 = 9.
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