This answer is similar to some others but I think explains the maths more and should allow you to incorporate it into a program more easily.
You can find the gradient of the "known" line by doing
Ay is the y co-ordinate of
A, etc.). Lets just call this
M since it is entirely calculable.
If the two lines are parallel then you can work out the gradient of the other line in the same way:
(Cy-Dy)/(Cx-Dx) = M
Which rearranges to
(Cy-Dy) = M*(Cx-Dx)
We also know that
C->D is a given length (lets call it L). So we can say
(Cy-Dy)^2+(Cx-Dx)^2 = L^2
Using our gradient equation we can substitute to get:
(M^2+1)(Cx-Dx)^2 = L^2
Given we know what M, L and Dx are we can easily solve this:
Cx = ((L^2)/(M^2+1))^0.5 + Dx
then we can use this value of
Cx along with either equation (Gradient is probably easiest) to get
Of note is that the last equation has a square root which can be positive or negative so you will get two possible values of
Cx and thus two possible values of
Cy. This is the equivalent of moving in the two opposite directions on the parallel line from
As noted in comments this will fail if the line is vertical (ie
Ax-Bx = 0). You would need to special case this but in this case the answer becomes a trivial case of just adding or subtracting your length from the value of Cy.