Can someone explain in simple terms to me what a Directed acyclic graph is? I have looked on Wikipedia but it doesn't really make me see its use in programming.
graph = structure consisting of nodes, that are connected to each other with edges
directed = the connections between the nodes (edges) have a direction: A -> B is not the same as B -> A
acyclic = "non-circular" = moving from node to node by following the edges, you will never encounter the same node for the second time.
Basically a directed acyclic graph is a tree.
Example uses of a directed acyclic graph in programming include more or less anything that represents connectivity and causality.
For example, suppose you have a computation pipeline that is configurable at runtime. As one example of this, suppose computations A,B,C,D,E,F, and G depend on each other: A depends on C, C depends on E and F, B depends on D and E, and D depends on F. This can be represented as a DAG. Once you have the DAG in memory, you can write algorithms to:
among many other things.
Outside the realm of application programming, any decent automated build tool (make, ant, scons, etc.) will use DAGs to ensure proper build order of the components of a program.
Directed Acyclic Graphs (DAG) have the following properties which distinguish them from other graphs:
Well, I can think of one use right now - DAG (known as Wait-For-Graphs - more technical details) are handy in detecting deadlocks as they illustrate the dependencies amongst a set of processes and resources (both are nodes in the DAG). Deadlock would happen when a cycle is detected.
I hope this helps.
Several answers have given examples of the use of graphs (e.g. network modeling) and you've asked "what does this have to do with programming?".
The answer to that sub-question is that it doesn't have much of anything to do with programming. It has to do with problem solving.
Just like linked-lists are data structures used for certain classes of problems, graphs are useful for representing certain relationships. Linked lists, trees, graphs, and other abstract structures only have a connection to programming in that you can implement them in code. They exist at a higher level of abstraction. It's not about programming, it's about applying data structures in the solution of problems.
I assume you already know basic graph terminology; otherwise you should start from the article on graph theory.
Directed refers to the fact that the edges (connections) have directions. In the diagram, these directions are shown by the arrows. The opposite is an undirected graph, whose edges don't specify directions.
Acyclic means that, if you start from a random node X and walk through all possible edges (following the edge directions), you will not return to X. Naturally, this is only possible in a directed graph (otherwise you could go from node X to some node Y, then back to X).
Graphs, of all sorts, are used in programming to model various different real-world relationships. For example, a social network is often represented by a graph (cyclic in this case). Likewise, network topologies, family trees, airline routes, ...
From a source code or even three address(TAC) code perspective you can visualize the problem really easily at this page...
If you go to the expression tree section, and then page down a bit it shows the "topological sorting" of the tree, and the algorithm for how to evaluate the expression.
So in that case you can use the DAG to evaluate expressions, which is handy since evaluation is normally interpreted and using such a DAG evaluator will make simple intrepreters faster in principal because it is not pushing and popping to a stack and also because it is eliminating common sub-expressions.
The basic algorithm to compute the DAG in non ancient egyptian(ie English) is this:
1) Make your DAG object like so
You need a live list and this list holds all the current live DAG nodes and DAG sub-expressions. A DAG sub expression is a DAG Node, or you can also call it an internal node. What I mean by live DAG Node is that if you assign to a variable X then it becomes live. A common sub-expression that then uses X uses that instance. If X is assigned to again then a NEW DAG NODE is created and added to the live list and the old X is removed so the next sub-expression that uses X will refer to the new instance and thus will not conflict with sub-expressions that merely use the same variable name.
Once you assign to a variable X, then co-incidentally all the DAG sub-expression nodes that are live at the point of assignment become not-live, since the new assignment invalidates the meaning of sub expressions using the old value.
So what you do is walk through your tree in your own code, such as a tree of expressions in source code for example. Call the existing nodes XNodes for example.
So for each XNode you need to decide how to add it into the DAG, and there is the possibility that it is already in the DAG.
This is very simple pseudo code. Not intended for compilation.
So that is one way of looking at it. A basic walk of the tree and just adding in and referring to the Dag nodes as it goes. The root of the dag is whatever DagNode the root of the tree returns for example.
Obviously the example procedure can be broken up into smaller parts or made as sub-classes with virtual functions.
As for sorting the Dag, you go through each DagNode from left to right. In other words follow the DagNodes left hand edge, and then the right hand side edge. The numbers are assigned in reverse. In other words when you reach a DagNode with no children, assign that Node the current sorting number and increment the sorting number, so as the recursion unwinds the numbers get assigned in increasing order.
This example only handles trees with nodes that have zero or two children. Obviously some trees have nodes with more than two children so the logic is still the same. Instead of computing left and right, compute from left to right etc...
A directed acyclic graph is useful when you want to represent...a directed acyclic graph! The canonical example is a family tree or genealogy.