# Prim's algorithm for MST, Adjacency List Implementation in C

I have this question for my programming class which I have been struggling to complete for the past day ... and I have no real idea what to do.

I understand the basic concept of Prim's algorithm:

``````1. Start at an arbitrary node (the first node will do) and

in the MST, to the    Minimum Spanning Tree.
Remove this link from the list.

4. repeat steps 2 & 3 until MST is achieved
(there are no nodes left unconnected).
``````

I have been given this implementation of a Graph (using an Adjacency List) to implement Prim's algorithm on. The problem is I don't really understand the implementation. My understanding of the implementation so far is as follows:

Being an adjacency list, we have all the nodes in array form: Linked to this is a list of links, containing details of the weight, the destination, and a pointer to the rest of the links of the specific node:

Something that looks a bit like this:

``````[0] -> [weight = 1][Destination = 3] -> [weight = 6][Destination = 4][NULL]
[1] -> [weight = 4][Destination = 3][NULL]
and so on...
``````

We also have an "Edge" struct, which I think is supposed to make things simpler for the implementation, but I'm not really seeing it.

Here is the code given:

GRAPH.h interface:

``````typedef struct {
int v;
int w;
int weight;
} Edge;

Edge EDGE (int, int, int);

typedef struct graph *Graph;

Graph GRAPHinit (int);
void GRAPHinsertE (Graph, Edge);
void GRAPHremoveE (Graph, Edge);
int GRAPHedges (Edge [], Graph g);
Graph GRAPHcopy (Graph);
void GRAPHdestroy (Graph);
int GRAPHedgeScan (Edge *);
void GRAPHEdgePrint (Edge);
int GRAPHsearch (Graph, int[]);
Graph GRAPHmst (Graph);
Graph GRAPHmstPrim (Graph);

#define maxV 8
``````

GRAPH.c implementation:

``````    #include <stdlib.h>
#include <stdio.h>
#include "GRAPH.h"

#define exch(A, B) { Edge t = A; A = B; B = t; }
#define max(A,B)(A>B?A:B)
#define min(A,B)(A<B?A:B)

struct node {
int v;
int weight;
};

struct graph {
int V;
int E;
};

static void sortEdges (Edge *edges, int noOfEdges);
static void updateConnectedComponent (Graph g, int from, int to, int newVal, int *connectedComponent);

Edge EDGE (int v, int w, int weight) {
Edge e = {v, w, weight};
return e;
}

link x = malloc (sizeof *x);

x->v = v;
x->next = next;
x->weight = weight;
return x;
}

Graph GRAPHinit (int V) {
int v;
Graph G = malloc (sizeof *G);

// Set the size of the graph, = number of verticies
G->V = V;
G->E = 0;

for (v = 0; v < V; v++){
}
return G;
}

void GRAPHdestroy (Graph g) {
// not implemented yet
}

void GRAPHinsertE(Graph G, Edge e){
int v = e.v;
int w = e.w;
int weight = e.weight;

G->E++;
}

void GRAPHremoveE(Graph G, Edge e){
int v = e.v;
int w = e.w;

while (*curr != NULL){
if ((*curr)->v == v) {
(*curr) = (*curr)->next;
G->E--;
break;
}
curr= &((*curr)->next);
}
while (*curr != NULL){
if ((*curr)->v == w) {
(*curr) = (*curr)->next;
break;
}
curr= &((*curr)->next);

}
}

int GRAPHedges (Edge edges[], Graph g) {
int v, E = 0;

for (v = 0; v < g->V; v++) {
for (t = g->adj[v]; t != NULL; t = t->next) {
if (v < t->v) {
edges[E++] = EDGE(v, t->v, t->weight);
}
}
}
return E;
}

void GRAPHEdgePrint (Edge edge) {
printf ("%d -- (%d) -- %d", edge.v, edge.weight, edge.w);
}

int GRAPHedgeScan (Edge *edge) {
if (edge == NULL) {
printf ("GRAPHedgeScan: called with NULL \n");
abort();
}

if ((scanf ("%d", &(edge->v)) == 1) &&
(scanf ("%d", &(edge->w)) == 1) &&
(scanf ("%d", &(edge->weight)) == 1)) {
return 1;
} else {
return 0;
}
}

// Update the CC label for all the nodes in the MST reachable through the edge from-to
// Assumes graph is a tree, will not terminate otherwise.
void updateConnectedComponent (Graph g, int from, int to, int newVal, int *connectedComponent) {
connectedComponent[to] = newVal;

updateConnectedComponent (g, to, currLink->v, newVal, connectedComponent);
}
}
}

// insertion sort, replace with O(n * lon n) alg to get
// optimal work complexity for Kruskal
void sortEdges (Edge *edges, int noOfEdges) {
int i;
int l = 0;
int r = noOfEdges-1;

for (i = r-1; i >= l; i--) {
int j = i;
while ((j < r) && (edges[j].weight > edges[j+1].weight)) {
exch (edges[j], edges[j+1]);
j++;
}
}

}

Graph GRAPHmst (Graph g) {
Edge *edgesSorted;
int i;
int *connectedComponent = malloc (sizeof (int) * g->V);
int *sizeOfCC = malloc (sizeof (int) * g->V);
Graph mst = GRAPHinit (g->V);

edgesSorted = malloc (sizeof (*edgesSorted) * g->E);
GRAPHedges (edgesSorted, g);
sortEdges (edgesSorted, g->E);

// keep track of the connected component each vertex belongs to
// in the current MST. Initially, MST is empty, so no vertex is
// in an MST CC, therefore all are set to -1.
// We also keep track of the size of each CC, so that we're able
// to identify the CC with fewer vertices when merging two CCs
for (i = 0; i < g->V; i++) {
connectedComponent[i] = -1;
sizeOfCC[i] = 0;
}

int currentEdge = 0; // the shortest edge not yet in the mst
int mstCnt = 0;      // no of edges currently in the mst
int v, w;

// The MST can have at most min (g->E, g->V-1) edges
while ((currentEdge < g->E) && (mstCnt < g->V)) {
v = edgesSorted[currentEdge].v;
w = edgesSorted[currentEdge].w;
printf ("Looking at Edge ");
GRAPHEdgePrint (edgesSorted[currentEdge]);
if ((connectedComponent[v] == -1) ||
(connectedComponent[w] == -1)) {
GRAPHinsertE (mst, edgesSorted[currentEdge]);
mstCnt++;
if (connectedComponent[v] == connectedComponent[w]) {
connectedComponent[v] = mstCnt;
connectedComponent[w] = mstCnt;
sizeOfCC[mstCnt] = 2;  // initialise a new CC
} else {
connectedComponent[v] = max (connectedComponent[w],  connectedComponent[v]);
connectedComponent[w] = max (connectedComponent[w],  connectedComponent[v]);
sizeOfCC[connectedComponent[w]]++;
}
printf ("  is in MST\n");
} else if (connectedComponent[v] == connectedComponent[w]) {
printf ("  is not in MST\n");
} else {
printf ("  is in MST, connecting two msts\n");
GRAPHinsertE (mst, edgesSorted[currentEdge]);
mstCnt++;
// update the CC label of all the vertices in the smaller CC
// (size is only important for performance, not correctness)
if (sizeOfCC[connectedComponent[w]] > sizeOfCC[connectedComponent[v]]) {
updateConnectedComponent (mst, v, v, connectedComponent[w], connectedComponent);
sizeOfCC[connectedComponent[w]] += sizeOfCC[connectedComponent[v]];
} else {
updateConnectedComponent (mst, w, w, connectedComponent[v], connectedComponent);
sizeOfCC[connectedComponent[v]] += sizeOfCC[connectedComponent[w]];
}
}
currentEdge++;
}
free (edgesSorted);
free (connectedComponent);
free (sizeOfCC);
return mst;
}

// my code so far
Graph GRAPHmstPrim (Graph g) {

// Initializations
Graph mst = GRAPHinit (g->V); // graph to hold the MST
int i = 0;

int nodeIsConnected[g->V];
// initially all nodes are not connected, initialize as 0;
for(i = 0; i < g->V; i++) {
nodeIsConnected[i] = 0;
}

// extract the first vertex from the graph
nodeIsConnected[0] = 1;

// push all of the links from the first node onto a temporary list

while(vertex != NULL) {
tempList = prepend(tempList, vertex);
vertex = vertex->next;
}

// find the smallest link from the node;

}

// some helper functions I've been writing
return NULL;
}

list = malloc(sizeof(list));
list->v = node->v;
list->weigth = node->weight;
list->next = temp;

return list;
}

while(list != NULL){
if((list->weight < smallest->weight)&&(nodeIsConnected[list->v] == 0)) {
smallest = list;
}
list = list->next;
}

if(nodeIsConnected[smallest->v] != 0) {
return NULL;
} else {
return smallest;
}
}
``````

For clarity, file to obtain test data from file:

``````#include <stdlib.h>
#include <stdio.h>
#include "GRAPH.h"

// call with graph_e1.txt as input, for example.
//
int main (int argc, char *argv[]) {

Edge e, *edges;
Graph g, mst;
int graphSize, i, noOfEdges;

if (argc < 2) {
printf ("No size provided - setting max. no of vertices to %d\n", maxV);
graphSize = maxV;
} else  {
graphSize = atoi (argv[1]);
}
g =   GRAPHinit (graphSize);

printf ("Reading graph edges (format: v w weight) from stdin\n");
while (GRAPHedgeScan (&e)) {
GRAPHinsertE (g, e);
}

edges = malloc (sizeof (*edges) * graphSize * graphSize);
noOfEdges = GRAPHedges (edges, g);
printf ("Edges of the graph:\n");
for (i = 0; i < noOfEdges; i++) {
GRAPHEdgePrint (edges[i]);
printf ("\n");
}

mst = GRAPHmstPrim (g);
noOfEdges = GRAPHedges (edges, mst);

printf ("\n MST \n");
for (i = 0; i < noOfEdges; i++) {
GRAPHEdgePrint (edges[i]);
printf ("\n");
}

GRAPHdestroy (g);
GRAPHdestroy (mst);
free (edges);
return EXIT_SUCCESS;
}
``````

Luke

files in full: http://www.cse.unsw.edu.au/~cs1927/12s2/labs/13/MST.html

UPDATE: I have had another attempt at this question. Here is the updated code (One edit above to change the graph_client.c to use "GRAPHmstPrim" function that I have written.

``````#include <stdlib.h>
#include <stdio.h>
#include "GRAPH.h"

#define exch(A, B) { Edge t = A; A = B; B = t; }
#define max(A,B)(A>B?A:B)
#define min(A,B)(A<B?A:B)

struct _node {
int v;
int weight;
}node;

struct graph {
int V;
int E;
};

struct _edgeNode {
int v;
int w;
int weight;
}edgeNode;

static void sortEdges (Edge *edges, int noOfEdges);
static void updateConnectedComponent (Graph g, int from, int to, int newVal, int *connectedComponent);

Edge EDGE (int v, int w, int weight) {
Edge e = {v, w, weight};
return e;
}

link x = malloc (sizeof *x);

x->v = v;
x->next = next;
x->weight = weight;
return x;
}

Graph GRAPHinit (int V) {
int v;
Graph G = malloc (sizeof *G);

G->V = V;
G->E = 0;

for (v = 0; v < V; v++){
}
return G;
}

void GRAPHdestroy (Graph g) {
// not implemented yet
}

void GRAPHinsertE(Graph G, Edge e){
int v = e.v;
int w = e.w;
int weight = e.weight;

G->E++;
}

void GRAPHremoveE(Graph G, Edge e){
int v = e.v;
int w = e.w;

while (*curr != NULL){
if ((*curr)->v == v) {
(*curr) = (*curr)->next;
G->E--;
break;
}
curr= &((*curr)->next);
}
while (*curr != NULL){
if ((*curr)->v == w) {
(*curr) = (*curr)->next;
break;
}
curr= &((*curr)->next);

}
}

int GRAPHedges (Edge edges[], Graph g) {
int v, E = 0;

for (v = 0; v < g->V; v++) {
for (t = g->adj[v]; t != NULL; t = t->next) {
if (v < t->v) {
edges[E++] = EDGE(v, t->v, t->weight);
}
}
}
return E;
}

void GRAPHEdgePrint (Edge edge) {
printf ("%d -- (%d) -- %d", edge.v, edge.weight, edge.w);
}

int GRAPHedgeScan (Edge *edge) {
if (edge == NULL) {
printf ("GRAPHedgeScan: called with NULL \n");
abort();
}

if ((scanf ("%d", &(edge->v)) == 1) &&
(scanf ("%d", &(edge->w)) == 1) &&
(scanf ("%d", &(edge->weight)) == 1)) {
return 1;
} else {
return 0;
}
}

// Update the CC label for all the nodes in the MST reachable through the edge from-to
// Assumes graph is a tree, will not terminate otherwise.
void updateConnectedComponent (Graph g, int from, int to, int newVal, int *connectedComponent) {
connectedComponent[to] = newVal;

updateConnectedComponent (g, to, currLink->v, newVal, connectedComponent);
}
}
}

// insertion sort, replace with O(n * lon n) alg to get
// optimal work complexity for Kruskal
void sortEdges (Edge *edges, int noOfEdges) {
int i;
int l = 0;
int r = noOfEdges-1;

for (i = r-1; i >= l; i--) {
int j = i;
while ((j < r) && (edges[j].weight > edges[j+1].weight)) {
exch (edges[j], edges[j+1]);
j++;
}
}

}

Graph GRAPHmst (Graph g) {
Edge *edgesSorted;
int i;
int *connectedComponent = malloc (sizeof (int) * g->V);
int *sizeOfCC = malloc (sizeof (int) * g->V);
Graph mst = GRAPHinit (g->V);

edgesSorted = malloc (sizeof (*edgesSorted) * g->E);
GRAPHedges (edgesSorted, g);
sortEdges (edgesSorted, g->E);

// keep track of the connected component each vertex belongs to
// in the current MST. Initially, MST is empty, so no vertex is
// in an MST CC, therefore all are set to -1.
// We also keep track of the size of each CC, so that we're able
// to identify the CC with fewer vertices when merging two CCs
for (i = 0; i < g->V; i++) {
connectedComponent[i] = -1;
sizeOfCC[i] = 0;
}

int currentEdge = 0; // the shortest edge not yet in the mst
int mstCnt = 0;      // no of edges currently in the mst
int v, w;

// The MST can have at most min (g->E, g->V-1) edges
while ((currentEdge < g->E) && (mstCnt < g->V)) {
v = edgesSorted[currentEdge].v;
w = edgesSorted[currentEdge].w;
printf ("Looking at Edge ");
GRAPHEdgePrint (edgesSorted[currentEdge]);
if ((connectedComponent[v] == -1) ||
(connectedComponent[w] == -1)) {
GRAPHinsertE (mst, edgesSorted[currentEdge]);
mstCnt++;
if (connectedComponent[v] == connectedComponent[w]) {
connectedComponent[v] = mstCnt;
connectedComponent[w] = mstCnt;
sizeOfCC[mstCnt] = 2;  // initialise a new CC
} else {
connectedComponent[v] = max (connectedComponent[w],  connectedComponent[v]);
connectedComponent[w] = max (connectedComponent[w],  connectedComponent[v]);
sizeOfCC[connectedComponent[w]]++;
}
printf ("  is in MST\n");
} else if (connectedComponent[v] == connectedComponent[w]) {
printf ("  is not in MST\n");
} else {
printf ("  is in MST, connecting two msts\n");
GRAPHinsertE (mst, edgesSorted[currentEdge]);
mstCnt++;
// update the CC label of all the vertices in the smaller CC
// (size is only important for performance, not correctness)
if (sizeOfCC[connectedComponent[w]] > sizeOfCC[connectedComponent[v]]) {
updateConnectedComponent (mst, v, v, connectedComponent[w], connectedComponent);
sizeOfCC[connectedComponent[w]] += sizeOfCC[connectedComponent[v]];
} else {
updateConnectedComponent (mst, w, w, connectedComponent[v], connectedComponent);
sizeOfCC[connectedComponent[v]] += sizeOfCC[connectedComponent[w]];
}
}
currentEdge++;
}
free (edgesSorted);
free (connectedComponent);
free (sizeOfCC);
return mst;
}

return NULL;
}

printf("EdgeListStart");
list = malloc(sizeof(edgeNode));
list->w = node;
list->v = edge->v;
list->weight = edge->weight;
list->next = temp;
printf("EdgeListEnd");
return list;
}

printf("SmallestSTart");
int small = 99999;

while(waitList != NULL) {
if((waitList->weight < small)&&(nodeIsConnected[waitList->v] == 0)) {
smallest = waitList;
small = smallest->weight;
} else {
printf("\n\n smallest already used %d", waitList->v);
}

waitList = waitList->next;
}
printf("SmallestEnd");
if(nodeIsConnected[smallest->v] == 0){
return smallest;

} else {
printf("Returning NULL");
return NULL;
}
}

printf(":istsatt");
list = malloc(sizeof(node));
list->v = v;
list->weight = smallest->weight;
list->next = temp;
printf("Listend");
return list;
}

Graph GRAPHmstPrim (Graph g) {

Graph mst = GRAPHinit (g->V); // graph to hold the MST

int i = 0;
int v = 0;
int w = 0;
int nodeIsConnected[g->V]; // array to hold whether a vertex has been added to MST

int loopStarted = 0;

// initially all nodes are not in the MST
for(i = 0; i < g->V; i++) {
nodeIsConnected[i] = 0;
}

while((smallest != NULL)||(loopStarted == 0)) {
printf("v is : %d", v);
// add the very first node to the MST
nodeIsConnected[v] = 1;
loopStarted = 1;

// push all of its links onto the list

while(vertex != NULL) {
vertex = vertex->next;
}

// find the smallest edge from the list
// which doesn't duplicate a connection
smallest = findSmallest(waitList, nodeIsConnected);

// no nodes don't duplicate a connection
// return the current MST
if(smallest == NULL){
return mst;
}

// otherwise add the attributes to the MST graph
w = smallest->w;
v = smallest->v;

}

return mst;

}
``````

Summary of changes: - Added edgeList to hold the edges that may be entered into the MST - Array nodeIsConnected[] to track whether a node is in the MST - Function to select the smallest node. If there is no node which doesn't duplicate a link this returns NULL

-

Each time you start your loop, you do `edgeLink waitList = NewEdgeList();`. This erases all of the previous encountered links, while you should just add the new links to the old waitlist. With your current code, after you process node 2, your waitinglist only contains 1 link and you already have that so it exits. Your list should also contain all previous encountered links. –  Origin Oct 22 '12 at 10:00