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hackercup

	You're about to put on an exciting show at your local circus — a parkour
	demonstration! N platforms with adjustable heights have been set up in a
	row, and are numbered from 1 to N in order from left to right. The initial
	height of platform _i_ is Hi metres.

	When the show starts, M parkourists will take the stage. The _i_th
	parkourist will start at platform Ai, with the goal of reaching a
	different platform Bi. If Bi > Ai, they'll repeatedly jump to the
	next platform to their right until they reach Bi. If Bi < Ai,
	they'll instead repeatedly jump to the next platform to their left until they
	reach Bi. All of the parkourists will complete their routes simultaneously
	(but don't worry, they've been trained well to not impede one another).

	Not all parkourists are equally talented, and there are limits on how far up
	or down they can jump between successive platforms. The _i_th parkourist's
	maximum upwards and downwards jump heights are Ui and Di,
	respectively. This means that they're only able to move directly from platform
	_x_ to some adjacent platform _y_ if Hx \- Di ≤ Hy ≤ Hx \+
	Ui, where Hx and Hy are the current heights of platforms _x_ and
	_y_, respectively.

	With the show about to begin, a disastrous flaw has just occurred to you — it
	may not be possible for all of the parkourists to actually complete their
	routes with the existing arrangement of platforms! If so, you will need to
	quickly adjust some of the platforms' heights first. The height of each
	platform may be adjusted upwards or downwards at a rate of 1 metre per second,
	to any non-negative real-valued height of your choice, and multiple platforms
	may be adjusted simultaneously. As such, if the initial height of platform _i_
	is Hi and its final height is Pi, then the total time required to make
	your chosen height adjustments will be `max{`\|Hi \- Pi\|`}` over
	_i_=1..N.

	Determine the minimum amount of time required to set up the platforms such
	that all M parkourists will then be able to complete their required
	routes. Note that you may not perform further height adjustments once the show
	starts. The platform heights must all remain constant while all M
	parkourists complete their routes.

	In order to reduce the size of the input data, you're given H1 and H2.
	H3..N may then be generated as follows using given constants W, X,
	Y, and Z (please watch out for integer overflow during this process):

	Hi = (W * Hi-2 \+ X * Hi-1 \+ Y) % Z (for _i_=3..N)

	### Input

	Input begins with an integer T, the number of shows. For each show, there
	is first a line containing the space-separated integers N and M. The
	next line contains the space-separated integers H1, H2, W, X,
	Y, and Z. Then, M lines follow. The _i_th of these lines contains
	the space-separated integers Ai, Bi, Ui, and Di.

	### Output

	For the _i_th show, print a line containing "Case #_i_: " followed by 1 real
	number, the minimum amount of time required to set up the platforms (in
	seconds). Absolute and relative errors of up to 10-6 will be ignored.

	### Constraints

	1 ≤ T ≤ 85
	2 ≤ N ≤ 200,000
	1 ≤ M ≤ 20
	0 ≤ Hi < Z
	0 ≤ W, X, Y < Z
	1 ≤ Z ≤ 1,000,000
	1 ≤ Ai, Bi ≤ N
	0 ≤ Ui, Di ≤ 1,000,000
	Ai, ≠ Bi

	### Explanation of Sample

	In the first case, H = [0, 10]. You can increase the first platform's
	height by 3.5 and decrease the second's by 3.5 in 3.5 seconds, yielding P
	= [3.5, 6.5]. The single parkourist will then be able to successfully complete
	their route from platform 1 to platform 2 by jumping upwards by a height of at
	most 3.

	In the second case, H = [50, 59, 55, 51, 47]. One optimal possibility is
	P = [54.0, 54.5, 53.5, 52.5, 51.5].

	In the third case, H = [46, 38, 38, 22, 8].

	In the fourth case, H = [53, 25, 24, 81, 77, 40, 29, 21].

	You're about to put on an exciting show at your local circus — a parkour
	demonstration! N platforms with adjustable heights have been set up in a
	row, and are numbered from 1 to N in order from left to right. The initial
	height of platform _i_ is Hi metres.

	When the show starts, M parkourists will take the stage. The _i_th
	parkourist will start at platform Ai, with the goal of reaching a
	different platform Bi. If Bi > Ai, they'll repeatedly jump to the
	next platform to their right until they reach Bi. If Bi < Ai,
	they'll instead repeatedly jump to the next platform to their left until they
	reach Bi. All of the parkourists will complete their routes simultaneously
	(but don't worry, they've been trained well to not impede one another).

	Not all parkourists are equally talented, and there are limits on how far up
	or down they can jump between successive platforms. The _i_th parkourist's
	maximum upwards and downwards jump heights are Ui and Di,
	respectively. This means that they're only able to move directly from platform
	_x_ to some adjacent platform _y_ if Hx \- Di ≤ Hy ≤ Hx \+
	Ui, where Hx and Hy are the current heights of platforms _x_ and
	_y_, respectively.

	With the show about to begin, a disastrous flaw has just occurred to you — it
	may not be possible for all of the parkourists to actually complete their
	routes with the existing arrangement of platforms! If so, you will need to
	quickly adjust some of the platforms' heights first. The height of each
	platform may be adjusted upwards or downwards at a rate of 1 metre per second,
	to any non-negative real-valued height of your choice, and multiple platforms
	may be adjusted simultaneously. As such, if the initial height of platform _i_
	is Hi and its final height is Pi, then the total time required to make
	your chosen height adjustments will be `max{`\|Hi \- Pi\|`}` over
	_i_=1..N.

	Determine the minimum amount of time required to set up the platforms such
	that all M parkourists will then be able to complete their required
	routes. Note that you may not perform further height adjustments once the show
	starts. The platform heights must all remain constant while all M
	parkourists complete their routes.

	In order to reduce the size of the input data, you're given H1 and H2.
	H3..N may then be generated as follows using given constants W, X,
	Y, and Z (please watch out for integer overflow during this process):

	Hi = (W * Hi-2 \+ X * Hi-1 \+ Y) % Z (for _i_=3..N)

	### Input

	Input begins with an integer T, the number of shows. For each show, there
	is first a line containing the space-separated integers N and M. The
	next line contains the space-separated integers H1, H2, W, X,
	Y, and Z. Then, M lines follow. The _i_th of these lines contains
	the space-separated integers Ai, Bi, Ui, and Di.

	### Output

	For the _i_th show, print a line containing "Case #_i_: " followed by 1 real
	number, the minimum amount of time required to set up the platforms (in
	seconds). Absolute and relative errors of up to 10-6 will be ignored.

	### Constraints

	1 ≤ T ≤ 85
	2 ≤ N ≤ 200,000
	1 ≤ M ≤ 20
	0 ≤ Hi < Z
	0 ≤ W, X, Y < Z
	1 ≤ Z ≤ 1,000,000
	1 ≤ Ai, Bi ≤ N
	0 ≤ Ui, Di ≤ 1,000,000
	Ai, ≠ Bi

	### Explanation of Sample

	In the first case, H = [0, 10]. You can increase the first platform's
	height by 3.5 and decrease the second's by 3.5 in 3.5 seconds, yielding P
	= [3.5, 6.5]. The single parkourist will then be able to successfully complete
	their route from platform 1 to platform 2 by jumping upwards by a height of at
	most 3.

	In the second case, H = [50, 59, 55, 51, 47]. One optimal possibility is
	P = [54.0, 54.5, 53.5, 52.5, 51.5].

	In the third case, H = [46, 38, 38, 22, 8].

	In the fourth case, H = [53, 25, 24, 81, 77, 40, 29, 21].