Come one, come all! The most famous circus troupe in all the land is on tour! Having just arrived in a new location, they're eager to set up their big top and showcase world-class acts of acrobatics and comedy for their audience.

Looking at the tent from the side (as a cross section), it will be set up along a one-dimensional strip of ground. N vertical poles will be placed in the ground, one after another, with the ith pole at a position X_i meters to the right of an arbitrary reference point, and reaching a height of H_i meters. No two poles will be at the same position.

After each pole is placed, the shape of the tent will be updated to fit the current set of poles. In particular, the upper outline of the tent will be a function with the following properties:

1. it's defined over all positions from negative infinity to positive infinity
2. its height is always non-negative
3. it's made up entirely of a series of connected line segments, with each one having a slope with absolute value no greater than 1 (meaning that the function is continuous, and its height may never change from left to right at an angle of more than 45 degrees up/down)
4. it doesn't intersect with any of the poles (meaning that, at each pole's position, the function's height must be no smaller than that of the pole)

The cross-sectional area of the tent is the area under this function. Despite their popularity, the circus troupe doesn't exactly have money to spare on tent materials (with most of their budget allocated to feeding their flying elephant star). As such, they'd like to minimize the cross-sectional area of their tent after placing each of the N poles. They'd like you to calculate the sum of these N minimal areas for them.

In this example, three poles are placed one after another. The first is at X = 20 with height 10. The minimum area of the tent is 100 m². The second pole is placed at X = 30 with a height of 15. The minimum area of the tent is now 268.75 m². The third pole is at X = 24 with a height of 3. This doesn't change the minimum area of the tent, which is still 268.75 m².

You're given X₁, and X_2..N may then be calculated as follows, using given constants A_x, B_x, and C_x (note that it is guaranteed that X_1..N will be distinct):

X_i = ((A_x * X_i-1 + B_x) % C_x) + 1

Similarly, you're given H₁, and H_2..N may then be calculated as follows, using given constants A_h, B_h, and C_h:

H_i = ((A_h * H_i-1 + B_h) % C_h) + 1

Input

Input begins with an integer T, the number of different tents that the circus troupe will set up. For each tent, there is first a line containing the single integer N. Then there is a line containing the four space-separated integers X₁, A_x, B_x, and C_x. Then there is a line containing the four space-separated integers H₁, A_h, B_h, and C_h.

Output

For the ith tent, print a line containing "Case #i: " followed by one real number. This number is the sum of N values, the jth of which is the minimum possible cross-sectional area of the tent after poles 1 through j have been placed.

Answers that have a relative error of up to 10^-6 will be accepted as correct.

Constraints

1 ≤ T ≤ 150
1 ≤ N ≤ 800,000
1 ≤ X₁ ≤ 10,000,000
0 ≤ A_x, B_x ≤ 10,000,000
1 ≤ C_x ≤ 10,000,000
1 ≤ H₁ ≤ 100,000
0 ≤ A_h, B_h ≤ 100,000
1 ≤ C_h ≤ 100,000

Explanation of Sample

In the first case, the cross-sectional areas of the tent after each pole is erected are 1.0, 1.75, 2.5, 3.25, and 4.0 for a total of 12.50.