Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I used to work with MATLAB, and for the question I raised I can use p = polyfit(x,y,1) to estimate the best fit line for the scatter data in a plate. I was wondering which resources I can rely on to implement the line fitting algorithm with C++. I understand there are a lot of algorithms for this subject, and for me I expect the algorithm should be fast and meantime it can obtain the comparable accuracy of polyfit function in MATLAB.

share|improve this question
up vote 5 down vote accepted

I would suggest coding it from scratch. It is a very simple implementation in C++. You can code up both the intercept and gradient for least-squares fit (the same method as polyfit) from your data directly from the formulas here

These are closed form formulas that you can easily evaluate yourself using loops. If you were using higher degree fits then I would suggest a matrix library or more sophisticated algorithms but for simple linear regression as you describe above this is all you need. Matrices and linear algebra routines would be overkill for such a problem (in my opinion).

share|improve this answer
Thanks, and this is a good starting point. – feelfree Jul 12 '12 at 10:19
Hmm, how does Simple Linear regression deal with data that's (almost) exactly parallel to the vertical (y) axis. It seems that non-injective functions will give issues in case of simple linear regression. In case of arbitrary scattered 2D linear data, this can, however, be possible. – Ben Aug 4 '15 at 12:19

You can also use or go over this implementation there is also documentation here.

share|improve this answer

Fitting a Line can be acomplished in different ways. Least Square means minimizing the sum of the squared distance. But you could take another cost function as example the (not squared) distance. But normaly you use the squred distance (Least Square). There is also a possibility to define the distance in different ways. Normaly you just use the "y"-axis for the distance. But you could also use the total/orthogonal distance. There the distance is calculated in x- and y-direction. This can be a better fit if you have also errors in x direction (let it be the time of measurment) and you didn't start the measurment on the exact time you saved in the data. For Least Square and Total Least Square Line fit exist algorithms in closed form. So if you fitted with one of those you will get the line with the minimal sum of the squared distance to the datapoints. You can't fit a better line in the sence of your defenition. You could just change the definition as examples taking another cost function or defining distance in another way.

There is a lot of stuff about fitting models into data you could think of, but normaly they all use the "Least Square Line Fit" and you should be fine most times. But if you have a special case it can be necessary to think about what your doing. Taking Least Square done in maybe a few minutes. Thinking about what Method fits you best to the problem envolves understanding the math, which can take indefinit time :-).

share|improve this answer

This page describes the algorithm easier than Wikipedia, without extra steps to calculate the means etc. : . Almost quoted from there, in C++ it's:

#include <vector>
#include <cmath>

struct Point {
  double _x, _y;
struct Line {
  double _slope, _yInt;
  double getYforX(double x) {
    return _slope*x + _yInt;
  // Construct line from points
  bool fitPoints(const std::vector<Point> &pts) {
    int nPoints = pts.size();
    if( nPoints < 2 ) {
      // Fail: infinitely many lines passing through this single point
      return false;
    double sumX=0, sumY=0, sumXY=0, sumX2=0;
    for(int i=0; i<nPoints; i++) {
      sumX += pts[i]._x;
      sumY += pts[i]._y;
      sumXY += pts[i]._x * pts[i]._y;
      sumX2 += pts[i]._x * pts[i]._x;
    double xMean = sumX / nPoints;
    double yMean = sumY / nPoints;
    double denominator = sumX2 - sumX * xMean;
    // You can tune the eps (1e-7) below for your specific task
    if( std::fabs(denominator) < 1e-7 ) {
      // Fail: it seems a vertical line
      return false;
    _slope = (sumXY - sumX * yMean) / denominator;
    _yInt = yMean - _slope * xMean;
    return true;

Please, be aware that both this algorithm and the algorithm from Wikipedia ( ) fail in case the "best" description of points is a vertical line. They fail because they use

y = k*x + b 

line equation which intrinsically is not capable to describe vertical lines. If you want to cover also the cases when data points are "best" described by vertical lines, you need a line fitting algorithm which uses

A*x + B*y + C = 0

line equation.

share|improve this answer
When x=[0..n], sumX is ( 0.5 * n + 0.5 ) * n and sumX2 is ( ( 1/3.0 * n + 1/2.0 ) * n + 1/6.0 ) * n. – Khouri Giordano Jan 16 at 3:49
@KhouriGiordano , could you elaborate on the utility of those observations? – Serge Rogatch Jan 16 at 10:49
For data that is regularly spaced in the X dimension beginning with X = 0, rather than summing X and X squared, they can be directly calculated. E.g. pixel values have x = location and y = intensity. – Khouri Giordano Jan 20 at 23:38

to fit a line y=param[0]x+param[1] simply do this: loop over data: {
sum_x += x[i]; sum_y += y[i]; sum_xy += x[i] * y[i]; sum_x2 += x[i] * x[i]; }

// means
double mean_x = sum_x / ninliers;
double mean_y = sum_y / ninliers;

float varx = sum_x2 - sum_x * mean_x;
float cov = sum_xy - sum_x * mean_y;

// check for zero varx

param[0] = cov / varx;
param[1] = mean_y - param[0] * mean_x;

More on the topic (formulas are the same, they just multiplied and divided by N, a sample sz.). If you want to fit plane to 3D data use a similar approach -

Disclaimer: all quadratic fits are linear and optimal in a sense that they reduce the noise in parameters. However, you might interested in the reducing noise in the data instead. You might also want to ignore outliers since they can bia s your solutions greatly. Both problems can be solved with RANSAC. See my post at:

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.