In 2D plane, I have a point and a line. How to get the mirror point along this line?

Suppose the equation of the line is The second part is, to find a point on the second line which is equidistant as the first point from the first line. For that, you can find the intersection of the two lines. Calculate the differences in 


When things like that are done in computer programs, one of the issues you might have to deal with is to perform these calculations using integer arithmetic only (or as much as possible), assuming the input is in integers. Doing this in integers as much as possible is a separate issue that I will not cover here. The following is a "mathematical" solution, which if implemented literally will require floatingpoint calculations. I don't know whether this is acceptable in your case. You can optimize it to your taste yourself. (1) Represent your line
equation. Note that vector For example, if the line is defined by two points
(2) Normalize the equation by dividing all coefficients by the length of vector
and then calculate the values
The equation
is still an equivalent equation of your line (3) Take your point
This will give you the signed distance The sign says which side of the line (4) In order to find your mirror point "Across the line" really means that if point This can simply be expressed as moving the point the distance of That means that
gives you your mirror point Alternatively, you can use an approach based on finding the actual closest point (1) Build an equation
for your line (2) Build an equation for the perpendicular line that passes through
The
while
(3) Find the intersection of these two lines by solving the system of two linear equations
Cramer's rule works very well in this case. The formula given in Line intersection article in Wikipedia are nothing else than an application of Cramer's rule to this system. The solution gives you the nearest point (4) Now just calculate
to find your point Note that this approach can be almost entirely implemented in integers. The only step that might lose precision is division inside the Cramer's rule at step 3. Of course, as usual, the price you'll have to pay for "almost integral" solution is the need for largenumber arithmetic. Even coefficients 


The details depend on how your line is represented. If you represent it as an arbitrary point P on the line together with a unit column vector n along the line, then the mirror point Q' to any point Q is given by:
(Here, I is the 2x2 identity matrix, n^{T} is the transpose of n (treating n as a 2x1 matrix), and nn^{T} is the 2x2 matrix formed by standard matrix multiplication of n with n^{T}.) It's not too hard to show that Q' will not change if you move P anywhere on the line. It's not hard to convert other line representations into a point/unit vector representation. 


Compute the closest point on the line to the point in question. Then invert the direction of the vector between those points and add it to the closest point on the line. Voilà, you have found the mirror point. 


I assume you have the location of the point, and an equation for your line, i.e.
First, the obvious case where a=0 (i.e. line parallel to the x axis) yields
For the more general case,
Some steps can be simplified but this is the general idea. I did the algebra while typing, so there could be mistakes. If you find one, please let me know. 


I have done exactly this for another system I have built.. There's a lot more than this in my code; so I hope I have extracted all the necessary bits... The algorithm is based on the idea that the slope of a line perpindicular to any given line is the negative multiplicative reciprocal of the slope of the given line. i.e., if one line has slope m, then the other line has slope 1/m. So all you need to do is form a line through the point with slope equal to 1/m and find the intersection of this line with the original line.


