Assuming that the lines can't be diagonal, here's one simple way. It's based on BFS and will also find the shortest line connecting the points:

Just create a graph, containing one vertex for each point (x, y) and for each point the edges:

```
((x,y),(x+1,y)) ((x,y),(x-1,y)) ((x,y),(x,y+1)) ((x,y),(x,y-1))
```

But each of this edges must be present only if it doesn't overlap a box.

Now just do a plain BFS from point (x1,y1) to (x2,y2)

It's really easy to obtain also diagonal lines the same way but you will need 8 edges for each vertex, that are, in addition to the previouses 4:

```
((x,y),(x-1,y+1)) ((x,y),(x-1,y-1)) ((x,y),(x+1,y-1)) ((x,y),(x+1,y+1))
```

Still, each edge must be present only if it doesn't overlap a box.

EDIT

If you can't consider space divided into a grid, here's another possibility, it won't give you the very shortest path, though.

Create a graph, in which each box is a vertex and has an edge to any other box that can be reached without the line to overlap a third box. Now find the shortet path using dijkstra between box1 and box2 containing the two points.

Now consider each box to have a small countour that doesn't overlap any other box. This way you can link the entering and the exiting point of each box in the path found through dijistra, passing through the countour.