Assuming that you have a simple directed acyclic graph (DAG), the following approach will work for counting:

`(A^n)_ij`

gives you the number of paths of length `n`

between nodes `i`

and `j`

. Therefore you need to compute `A + A^2 + ... + A^n + ...`

to get the total number of paths between any two nodes. It is essential that you work with a DAG, as this guarantees that for large enough `n`

, `A^n = 0`

. Then the result can be written as `A . (I - A)^(-1)`

where `I`

is the identity matrix.

**EDIT:**

I don't really know R so I can only give you some pseudocode or explanations.

First, **let's find the set of nodes reachable from node **`i`

. Let's define vector `v`

to contain only zeros except at the `i`

th position where it contains 1. E.g. for the 1st node you'll have

```
v = (1,0,0, ..., 0)
```

Now let `v_(n+1) = sign(v_n + A . v_n)`

, where the purpose of the `sign()`

function is to replace nonzero elements by 1 and keep zeros 0. Do this iteration until you reach the fixed point, and you'll have a vector `v`

with nonzero elements at the positions corresponding to the nodes reachable from node `i`

.

If instead of the vector `v`

you start with the identity matrix (of the same size as `A`

), you'll get the reachable nodes for each other node in one go.

Now you have the set of reachable nodes for any starting node. Similarly you can get the list of nodes from which any target node is reachable (just reverse the directed edges, i.e. transpose `A`

)

Next, **let's traverse the graph and find all paths you need**.

This recursive function should do it (pseudocode):

```
traverse( path-so-far, target ):
let S = the last element of path-so-far
if S == target:
output path-so-far
return
let N = the set of nodes reachable from S in one step
remove all nodes from N from which the target is not reachable
for each K in N:
traverse( append(path-so-far, K), target )
```

`path-so-far`

is the list of nodes already visited; `target`

is the target node.

For a given pair of start and target nodes, just do `traverse( {start}, target )`

.

Note that the step where we remove all nodes from which the target is not reachable is only there to speed up the traversal, and don't enter "blind alleys"