# Pointers enable efficient composite data structures

You have something like this (using pseudocode C++):

```
class Node
bool visited
double key
Node* pi
vector<pair<Node*, double>> adjacent //adjacent nodes and edge weights
//and extra fields needed for PriorityQueue data structure
// - a clean way to do this is to use CRTP for defining the base
// PriorityQueue node class, then inherit your graph node from that
class Graph
vector<Node*> vertices
```

CRTP: http://en.wikipedia.org/wiki/Curiously_recurring_template_pattern

**The priority queue **`Q`

in the algorithm contains items of type `Node*`

, where `ExtractMin`

gets you the `Node*`

with minimum `key`

.

The reason **you don't have to do any linear search** is because, when you get `u = ExtractMin(Q)`

, you have a `Node*`

. So `u->adjacent`

gets you both the `v`

's in `G.Adj[u]`

and the `w(u,v)`

's in **const time per adjacent node**. Since you have a pointer `v`

to the priority queue node (which *is* `v`

), you can update it's position in the priority queue in **logarithmic time per adjacent node** (with most implementations of a priority queue).

*To name some specific data structures, the *`DecreaseKey(Q, v)`

function used below has logarithmic complexity for Fibonnaci heaps and pairing heaps (amortized).

# More-concrete pseudocode for the algorithm

```
MstPrim(Graph* G)
for each u in G->vertices
u->visited = false
u->key = infinity
u->pi = NULL
Q = PriorityQueue(G->vertices)
while Q not empty
u = ExtractMin(Q)
u->visited = true
for each (v, w) in u->adjacent
if not v->visited and w < v->key
v->pi = u
v->key = w
DecreasedKey(Q, v) //O(log n)
```