As Henning says, they most likely won't intersect. The co-dimension of a $2$-d plane in $\mathbb{R}^d$ is $d-2$ and the co-dimension of a $1$-d line is $d-1$. The typical intersection adds the co-dimensions, so the intersection has co-dimension $2d-3$. In $\mathbb{R}^3$, the typical intersection (without everything lying in a lower dimension subspace) would have co-dimension $3$, that is a point.
Consider two $2$-d planes in $\mathbb{R}^4$. Both have co-dimension $2$ and so their typical intersection would have co-dimension $4$, that is a point. If two planes intersect in a point, it is easy to believe that a plane and a line usually don't intersect.
To check if the plane and the line happen to lie in the same $3$ dimensional subspace, take one of the $5$ points, $P$, and subtract it from the other $4$ to get $4$ vectors. Create a $4{\times}\mathrm{d}$ matrix, $R_4$, with these vectors as rows and compute the determinant of the $4{\times}4$ matrix $R_4R_4^T$. If that determinant is not $0$, the line and triangle do not lie in the same $3$-d subspace and so they don't intersect. If the determinant is $0$, then take $3$ of the $4$ vectors and create a $3{\times}\mathrm{d}$ matrix, $R_3$, with these vectors as rows. If $\det(R_3R_3^T)=0$, pick another $3$. If all choices give a $0$ determinant, then all $5$ points live in a $2$-dimensional subspace and that can be handled in a similar fashion. To find a point of intersection,
- map all points to $\mathbb{R}^3$ with $x\mapsto R(x-P)$
- find the intersection as usual in $\mathbb{R}^3$
- map the intersection back to $\mathbb{R}^d$ with $x\mapsto R^T(RR^T)^{-1}x+P$