SO,

**The problem**

I have a question about algorithm of determining if two points are connected on 2D-plane. I have:

- Array of 2D-lines. Each line is limited with its start end end 2D-point. Each point is simple array of two elements
`[x,y]`

- i.e. each line looks like`['start'=>[X0, Y0], 'end'=>[X1, Y1]]`

Let this lines set be named as`L`

. Lines can belongs one to another (i.e. one could be part of another), they can be intersected by only one point e.t.c. - i.e. there are*no restrictions*for them on 2D plane. But line can not be a point - i.e. start of line can not be equal to end of line. - Two points
`S`

and`E`

, i.e. arrays`[Xs, Ys]`

and`[Xe, Ye]`

Now, all lines from `L`

are drawn on the plane. Then, `S`

and `E`

are also drawn and I need to answer the question - *can E be reached from S without intersection of any lines in L*? And, to be more specific - which algorithm will be optimal? By 'could be reached' I mean that there is a way on the plane from `S`

to `E`

without intersection any line from `L`

- and, of cause, this way could be anything, not just line.

*Sample*

-as you see, in sample `S`

and `E`

are not connected. Also in the sample there is a case when one line fully belongs to another (gray and purple lines) - and a case when one line has a start/end on another line (green and rose lines).

**My approach**

Currently, I have non-deterministic polynomial (NP) algorithm to do that. It's steps are:

- Find all intersections for each pairs of lines.
- Create new set of lines from points of first step. If two lines has one intersection, then there will be 4 new lines with intersection point at the start of each new line - or it can be 3 new lines if first line has it's start/end on second line - or it can be 2 new lines if first line has it's start/end exactly match with second's line start/end. I.e:

so 1-st case will result in 4 new lines, 2-4 cases in 3 new lines and 5 case in 2 new lines. (lines are `[A, B]`

and `[C, D]`

)

- Next, in lines step from 2-nd step I'm searching all polygons. Polygon is a closed line set (i.e. it holds closed part of area)
- I'm determining for
`S`

subset of such polygons that contain`S`

. To do this, I'm using simple algorithm - counting number of intersections with polygon's edges and some line from`S`

to outer plane (if it's odd, then`S`

is inside polygon and if it's even - then outside). This is a ray-casting algorithm. Then I do that for`E`

- Now, when I have polygons set for both
`S`

and`E`

I'm simply comparing both sets. If they are equal, then`E`

could be reached from`S`

and could not be - otherwise.

*Why is this NP?*

The answer is simple: on 3-rd step I'm performing search of **all** loops in 2D-graph. Since a problem of finding maximum/minimum loop length if NP, then mine is too (because I can get maximum/minimum loop length simply with sorting resulted loops set). Good information about this is located here.

**The question**

Since my current solution is NP, I want to know - may be my solution for the problem is an overkill? I.e. may be there are simpler solution which will result in polynomial time?