# Critical Path Method Algorithm

Where can I find a Java implementation of the Critical Path Method Algorithm? I am sure there's some implementation in the cloud. I have already searched on google obviously, but haven't found any implementation that works well. That's why I am asking.

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You can find this and more at Google. – samoz Jun 6 '10 at 18:32
This sort of comment doesn't seem very constructive, especially since when I googled this question, this link was the top hit. – Joshua Davies Apr 17 '12 at 22:31

Here is an implementation of the algorithm based on the explanation provided on this page There is a wrapper class to hold the task, cost, and critical path cost. It starts by calculating the critical cost as the maximum critical cost of all dependencies plus its own cost. Then once the critical costs are available it uses a comparator to sort the tasks based on the critical cost with dependency as a tie breaker (choosing randomly if there is no dependency). Note that an exception will be thrown if there is a cycle and it will fail if any of the costs are negative.

Here is the implementation:

``````public class CriticalPath {

public static void main(String[] args) {
//The example dependency graph from
//http://www.ctl.ua.edu/math103/scheduling/scheduling_algorithms.htm
}

//A wrapper class to hold the tasks during the calculation
//the actual cost of the task
public int cost;
//the cost of the task along the critical path
public int criticalCost;
//a name for the task for printing
public String name;
this.name = name;
this.cost = cost;
}
}
@Override
public String toString() {
return name+": "+criticalCost;
}
//is t a direct dependency?
if(dependencies.contains(t)){
return true;
}
//is t an indirect dependency
if(dep.isDependent(t)){
return true;
}
}
return false;
}
}

//tasks whose critical cost has been calculated
//tasks whose ciritcal cost needs to be calculated

//Backflow algorithm
//while there are tasks whose critical cost isn't calculated.
while(!remaining.isEmpty()){
boolean progress = false;

//find a new task to calculate
//all dependencies calculated, critical cost is max dependency
//critical cost, plus our cost
int critical = 0;
if(t.criticalCost > critical){
critical = t.criticalCost;
}
}
//set task as calculated an remove
it.remove();
//note we are making progress
progress = true;
}
}
//If we haven't made any progress then a cycle must exist in
//the graph and we wont be able to calculate the critical path
if(!progress) throw new RuntimeException("Cyclic dependency, algorithm stopped!");
}

//create a priority list

@Override
//sort by cost
int i= o2.criticalCost-o1.criticalCost;
if(i != 0)return i;

//using dependency as a tie breaker
//note if a is dependent on b then
//critical cost a must be >= critical cost of b
if(o1.isDependent(o2))return -1;
if(o2.isDependent(o1))return 1;
return 0;
}
});

return ret;
}
}
``````
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There's a Java applet at `cut-the-knot.org`. There's also an online calculator at sporkforge.com.

### References

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Here is the another version of Jessup's code. I simply add some other functions and now the code calculates earliest/latest start and finish times, slack and whether the node is on the critical path or not. (I simply added the functions and get the result, I haven't put much effort on algorithm and coding)

``````public class CriticalPath {
public static int maxCost;
public static String format = "%1\$-10s %2\$-5s %3\$-5s %4\$-5s %5\$-5s %6\$-5s %7\$-10s\n";

public static void main(String[] args) {
// The example dependency graph
print(result);
// System.out.println("Critical Path: " + Arrays.toString(result));
}

// A wrapper class to hold the tasks during the calculation
// the actual cost of the task
public int cost;
// the cost of the task along the critical path
public int criticalCost;
// a name for the task for printing
public String name;
// the earliest start
public int earlyStart;
// the earliest finish
public int earlyFinish;
// the latest start
public int latestStart;
// the latest finish
public int latestFinish;

this.name = name;
this.cost = cost;
for (Task t : dependencies) {
}
this.earlyFinish = -1;
}

public void setLatest() {
latestStart = maxCost - criticalCost;
latestFinish = latestStart + cost;
}

public String[] toStringArray() {
String criticalCond = earlyStart == latestStart ? "Yes" : "No";
String[] toString = { name, earlyStart + "", earlyFinish + "", latestStart + "", latestFinish + "",
latestStart - earlyStart + "", criticalCond };
}

// is t a direct dependency?
if (dependencies.contains(t)) {
return true;
}
// is t an indirect dependency
for (Task dep : dependencies) {
if (dep.isDependent(t)) {
return true;
}
}
return false;
}
}

// tasks whose critical cost has been calculated
// tasks whose critical cost needs to be calculated

// Backflow algorithm
// while there are tasks whose critical cost isn't calculated.
while (!remaining.isEmpty()) {
boolean progress = false;

// find a new task to calculate
for (Iterator<Task> it = remaining.iterator(); it.hasNext();) {
// all dependencies calculated, critical cost is max
// dependency
// critical cost, plus our cost
int critical = 0;
if (t.criticalCost > critical) {
critical = t.criticalCost;
}
}
// set task as calculated an remove
it.remove();
// note we are making progress
progress = true;
}
}
// If we haven't made any progress then a cycle must exist in
// the graph and we wont be able to calculate the critical path
if (!progress)
throw new RuntimeException("Cyclic dependency, algorithm stopped!");
}

// get the cost
calculateEarly(initialNodes);

// create a priority list

@Override
return o1.name.compareTo(o2.name);
}
});

return ret;
}

public static void calculateEarly(HashSet<Task> initials) {
for (Task initial : initials) {
initial.earlyStart = 0;
initial.earlyFinish = initial.cost;
setEarly(initial);
}
}

public static void setEarly(Task initial) {
int completionTime = initial.earlyFinish;
for (Task t : initial.dependencies) {
if (completionTime >= t.earlyStart) {
t.earlyStart = completionTime;
t.earlyFinish = completionTime + t.cost;
}
setEarly(t);
}
}

for (Task td : t.dependencies) {
remaining.remove(td);
}
}

System.out.print("Initial nodes: ");
System.out.print(t.name + " ");
System.out.print("\n\n");
return remaining;
}

int max = -1;
if (t.criticalCost > max)
max = t.criticalCost;
}
maxCost = max;
System.out.println("Critical path length (cost): " + maxCost);
t.setLatest();
}
}

System.out.format(format, "Task", "ES", "EF", "LS", "LF", "Slack", "Critical?");
System.out.format(format, (Object[]) t.toStringArray());
}
}
``````
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