# Tag Info

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This a famous problem called minimum path cover, it's a pity that wiki says nothing about it, you can search it in google. As methioned, the minimum path cover problem is NP-hard in normal graph. But in DAG, it can be solved with Matching. Method: Dividing each vertex u into two different vertex u1 and u2. For every edge (u->v) in orginal graph, adding ...

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I think this problem is NP-hard via a reduction from the Steiner tree problem. Given a graph G and a set of nodes S that need to be spanned, set the weight of all of the nodes in S to one and all the other nodes to 0. A subgraph with node weight at least |S| with minimum total edge cost must be a tree (if there are any cycles, deleting an edge from the cycle ...

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Note: The actual links in the original network are all present in this distance matrix unless there is a shorter path between those two nodes via another node. And if there is a shorter path then this longer distance link can be ignored for the purpose of solving this problem. So ... I would start with the shortest distance. This must represent an actual ...

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counter-example: a1 a2 a3 a4 a5 p1 x x p2 x x x x p3 x x x x p4 x p5 x x x a5 is selected first. Randomly select pilot which MAY be p5. If it is, p4 doesn't have a plane.

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All of these effects follow from the usual Iterator invalidation rules Why does adding an edge invalidate the edge and adjacency iterators; why isn't every column of the add_edge() row "OK"? Wouldn't the in/out edge lists simply be appended? Yes they would be appended. And, seeing that they might reallocate doing so, they invalidate iterators. ...

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Represent trees like so (untested Haskell). > data Tree a = Node a > | Cons (Tree a) (Tree a) The tree 1 /|\ 2 3 4 | 5 is (Cons (Node 2) (Cons (Cons (Node 5) (Node 3)) (Cons (Node 4) (Node 1)))) :: Tree Int . Here's a bottom-up verification function. > type ZeroOneOrTwo = Int > data Result = Failure ...

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The simplest graph where both BFS and DFS would visit the nodes in the same order would be a linked list. Since a linked list is just a graph with just one node at each depth, both algorithms will visit nodes in the same order, assuming you start at one of the end points of the linked list for undirected graphs, or you start at the node with indegree=0 for ...

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Finding Euclidean shortest paths based on a 2D grid discretization of the traversable space can be performed with the Theta* algorithm. The other (more commonly employed) approach is based on a standard 4-way or 8-way pathfind (the picture on the left), followed by a "string pulling" optimization. The most common algorithm for this is known as the "Funnel ...

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This can be solved via dynamical-programming-like algorithm. As you have only just a few hundreds of nodes and X is round 10. You can assign each node v an array Fv with size X, and Fv[i] represents the maximum cost from the source to the node v with length i. Let s be the source. Set Fs[0] = 0, and all other Fs[i] = -infinity. All other arrays are ...

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The greedy approach will not work on bipartite matching. The problem as you could have guessed is with "selecting any node on the left". Here is an example - nodes on the left are A, B, C and D and on the right are x, y, z, t. Connect each of A, B, C with each of x, y, z(so 9 edges here) then connect D with t and A with t. As a result you have 3 nodes on ...

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