The simplest (and very generalizable) way to solve this is to say that

```
L1 + x*(L2 - L1) = (P1 + y*(P2 - P1)) + (P1 + z*(P3 - P1))
```

which gives you 3 equations in 3 variables. Solve for x, y and z, and then substitute back into either of the original equations to get your answer. This can be generalized to do complex things like find the point that is the intersection of two planes in 4 dimensions.

For an alternate approach, the cross product `N`

of `(P2-P1)`

and `(P3-P1)`

is a vector that is at right angles to the plane. This means that the plane can be defined as the set of points `P`

such that the dot product of `P`

and `N`

is the dot product of `P1`

and `N`

. Solving for `x`

such that `(L1 + x*(L2 - L1)) dot N`

is this constant gives you one equation in one variable that is easy to solve. If you're going to be intersecting a lot of lines with this plane, this approach is definitely worthwhile.

Written out explicitly this gives:

```
N = cross(P2-P1, P3 - P1)
Answer = L1 + (dot(N, P1 - L1) / dot(N, L2 - L1)) * (L2 - L1)
```

where

```
cross([x, y, z], [u, v, w]) = x*u + y*w + z*u - x*w - y*u - z*v
dot([x, y, z], [u, v, w]) = x*u + y*v + z*w
```

Note that that cross product trick **only** works in 3 dimensions, and only for your specific problem of a plane and a line.