| <p> | |
| Mr. Fox sure loves his rocks! In fact, when he's not in a hurry, he often looks at the rocks lying around near him to decide where to wander in his forest. | |
| </p> | |
| <p> | |
| Mr. Fox lives in a forest with <strong>N</strong> clearings, numbered from 0 to <strong>N</strong>-1, | |
| with <strong>P</strong> one-way trails initially running amongst them. | |
| The <strong>i</strong>th trail runs from clearing <strong>A<sub>i</sub></strong> | |
| to a different clearing <strong>B<sub>i</sub></strong>, | |
| and is littered with <strong>R<sub>i</sub></strong> rocks. | |
| No two clearings are connected by multiple trails running in the same direction, | |
| though they could be connected by 2 trails running in opposite directions. | |
| Additionally, an interesting property of this forest is that a trail from clearing | |
| <strong>a</strong> to clearing <strong>b</strong> may only exist if | |
| 0 ≤ floor(<strong>b</strong>/4) - floor(<strong>a</strong>/4) ≤ 1. | |
| </p> | |
| <p> | |
| To entertain himself over a period of <strong>D</strong> days, Mr. Fox will cause one event to occur on each day. | |
| The <strong>i</strong>th event may be one of 3 types, determined by the value of <strong>E<sub>i</sub></strong>: | |
| <ol> | |
| <li><p> | |
| Given 3 integers <strong>X<sub>i</sub></strong>, <strong>Y<sub>i</sub></strong>, and <strong>Z<sub>i</sub></strong>, | |
| Mr. Fox will create a new trail from clearing <strong>X<sub>i</sub></strong> to a different clearing | |
| <strong>Y<sub>i</sub></strong>, and drop <strong>Z<sub>i</sub></strong> rocks onto it. | |
| It's guaranteed that no trail from <strong>X<sub>i</sub></strong> to <strong>Y<sub>i</sub></strong> | |
| will exist at the start of the <strong>i</strong>th day, and that | |
| 0 ≤ floor(<strong>Y<sub>i</sub></strong>/4) - floor(<strong>X<sub>i</sub></strong>/4) ≤ 1 will hold. | |
| </p></li> | |
| <li><p> | |
| Given 2 distinct integers <strong>X<sub>i</sub></strong> and <strong>Y<sub>i</sub></strong>, | |
| Mr. Fox will completely destroy the trail from clearing | |
| <strong>X<sub>i</sub></strong> to clearing <strong>Y<sub>i</sub></strong> | |
| (which is guaranteed to exist at the start of the <strong>i</strong>th day). Note that, once such a trail is destroyed, | |
| a new trail from <strong>X<sub>i</sub></strong> to <strong>Y<sub>i</sub></strong> may be created in the future. | |
| </p></li> | |
| <li><p> | |
| Given 2 distinct integers <strong>X<sub>i</sub></strong> and <strong>Y<sub>i</sub></strong>, | |
| Mr. Fox will take a "random stroll" starting at clearing <strong>X<sub>i</sub></strong>, | |
| and would like to determine the probability that he'll visit clearing <strong>Y<sub>i</sub></strong> at least once during it. | |
| </p> | |
| <p> | |
| A "random stroll" consists of repeating the following process potentially infinitely: | |
| If Mr. Fox is currently in some clearing <strong>c</strong>, and there are no outgoing trails from <strong>c</strong>, | |
| then the stroll ends immediately. | |
| Otherwise, he'll consider all of the rocks on all of the outgoing trails from <strong>c</strong>, | |
| choose one of these rocks uniformly at random, follow the trail on which that rock lies to its destination clearing | |
| (without removing any rocks), and repeat the process from his new clearing. | |
| </p></li> | |
| </ol> | |
| <p> | |
| For each event of type 3, output the requested probability. | |
| </p> | |
| <h3>Input</h3> | |
| <p> | |
| Input begins with an integer <strong>T</strong>, the number of test cases. | |
| For each test case, there is first a line containing the space-separated integers | |
| <strong>N</strong>, <strong>P</strong>, and <strong>D</strong>. | |
| </p> | |
| <p> | |
| Then, <strong>P</strong> lines follow, the <strong>i</strong>th of which contains the space-separated integers | |
| <strong>A<sub>i</sub></strong>, <strong>B<sub>i</sub></strong>, and <strong>R<sub>i</sub></strong>. | |
| </p> | |
| <p> | |
| Then, <strong>D</strong> lines follow, the <strong>i</strong>th of which contains the space-separated integers | |
| <strong>E<sub>i</sub></strong>, <strong>X<sub>i</sub></strong>, and <strong>Y<sub>i</sub></strong>. | |
| If <strong>E<sub>i</sub></strong> = 1, this line additionally contains the integer <strong>Z<sub>i</sub></strong>. | |
| </p> | |
| <h3>Output</h3> | |
| <p> | |
| For the <strong>i</strong>th test case, print a line containing "Case #<strong>i</strong>: " | |
| followed by the computed probabilities for each stroll that Mr. Fox takes. | |
| These probabilities should be space-separated, and rounded to 6 decimal places. | |
| </p> | |
| <p> | |
| Absolute errors of up to 2 * 10<sup>-6</sup> will be ignored. | |
| </p> | |
| <h3>Constraints</h3> | |
| <p> | |
| 1 ≤ <strong>T</strong> ≤ 20 <br /> | |
| 1 ≤ <strong>N</strong> ≤ 50,000 <br /> | |
| 0 ≤ <strong>P</strong> ≤ 100,000 <br /> | |
| 1 ≤ <strong>D</strong> ≤ 20,000 <br /> | |
| 0 ≤ <strong>A<sub>i</sub></strong>, <strong>B<sub>i</sub></strong>, | |
| <strong>X<sub>i</sub></strong>, <strong>Y<sub>i</sub></strong> < <strong>N</strong> <br /> | |
| 1 ≤ <strong>E<sub>i</sub></strong> ≤ 3 <br /> | |
| 1 ≤ <strong>R<sub>i</sub></strong>, <strong>Z<sub>i</sub></strong> ≤ 5 <br /> | |
| </p> | |
| <h3>Explanation of Sample</h3> | |
| <p> | |
| In the first test case, Mr. Fox does multiple strolls from clearing 0 while looking out for clearing 3. | |
| His first stroll has probability 1 as he must always end up at clearing 3. | |
| His second stroll has probability 1/2 as there's a 50% chance he gets stuck in clearing 4. | |
| His third stroll has probability 2/3 as he now only goes to clearing 4 1/3 of the time. | |
| His fourth stroll has probability 1/3 as he gets stuck in clearing 4 1/3 of the time, and in clearing 1 1/3 of the time. | |
| </p> | |