For the sake of being specific, suppose your original triangle has vertices A, B, and C. The line segment has end points D and E. Furthermore, you want DE to correspond to AB. The problem is then to find a point F such that triangle DEF is similar to triangle ABC. I hope that's what you're trying to solve, because that's what I'm going to give you as a solution. Explaining the solution is going to be a lot longer than coding it. :)

I think you can do all this with vector arithmetic, without using angles and trig functions. Let all points be represented by their x and y coordinates in some shared coordinate system. (If you don't know vector arithmetic, see the appendix below.)

First, we'll imagine a local coordinate system u-v with A as the origin and AB parallel to the u axis; the v axis is perpendicular to u; we'll nail down which direction is positive in a second. Now, even though AB is the side of the triangle, from now on we'll think of it as a vector from A to B. It can be computed in the x-y system as `AB = (B[x] - A[x], B[y] - A[y])`

. The same goes for all other point pairs. Individual points will also be vectors in the x-y system. A unit vector in the x-y system along the u axis is given by:

```
u = (u_x, u_y) = AB / ‖AB‖
```

A unit vector along the v axis is just:

```
v = (-u_y, u_x)
```

(We could also have used `(u_y, -u_x)`

.) We will now compute the vector components of AC in the u-v system:

```
AC_u = (AC_x * u_x, AC_y * u_y) // = (AC ∙ u)
AC_v = ‖AC - AC_u * u‖
```

Now we imagine another local coordinate system, r-s, with origin at D and r axis along DE. The unit vectors along r and s in the x-y system are:

```
r = (r_x, r_y) = DE / ‖DE‖
s = (-r_y, r_x)
```

We can scale the u-v components of AC by the ratio `‖DE‖ / ‖AB‖`

to get r-s components of DF:

```
DF_r = AC_u * ‖DE‖ / ‖AB‖
DF_s = AC_v * ‖DE‖ / ‖AB‖
```

Finally, we just need to add everything together:

```
F = D + DF_r * r + DF_s * s
```

(Recall that `D`

, `r`

, and `s`

are vectors.) That's it. Although the post is long, there are only a dozen or so lines of code (each vector calculation step takes one lines for each component) plus another handful for a function to compute the norm of a vector.

APPENDIX: Vector arithmetic

Vectors in an x-y coordinate system are ordered pairs of numbers: (x, y). Two vectors A and B can be added or subtracted by adding or subtracting their components: `A ± B = (A_x ± B_x, A_y ± B_y)`

. A vector can be multiplied by a number (also called a *scalar*) by multiplying each vector component by the scalar: `q*A = (q*A_x, q*A_y)`

. Division by a scalar is just multiplication by the inverse of the scalar. The *norm* of a vector A (also called its length) is written ‖A‖; it can be computed using the Pythagorean theorem: `‖A‖ = sqrt(A_x * A_x + A_y * A_y)`

. A *unit vector* is a vector with norm = 1. The *dot product* of two vectors is the sum (a simple number) of the products of corresponding components: `A ∙ B = A_x*B_x + A_y*B_y`

. Note that the dot product of a vector with itself is the square of its norm. An important identity about the dot product is: `A ∙ B = ‖A‖ * ‖B‖ * cos(α)`

where `α`

is the angle between A and B. A corollary is that the dot product of two non-zero vectors is zero exactly when the vectors are perpendicular to one another.