# Bresenham's line algorithm. Does exist ncurses output for file?

I have homework, ASCII line plot drawer. I must print graph into to file. All algoritms of Bresenham's line algoritm have function SetPixel ( x, y ); in loops. This function must print pixel by x and y. NCurses library is idealy solution for print on windows console, but I must print into file.txt. I think that Ncurses only print on window console. My question: How to implement SetPixel function for print into file in this code? :

``````void Line( const float x1, const float y1, const float x2, const float y2, const Color& color )
{
// Bresenham's line algorithm
const bool steep = (fabs(y2 - y1) > fabs(x2 - x1));
if(steep)
{
std::swap(x1, y1);
std::swap(x2, y2);
}

if(x1 > x2)
{
std::swap(x1, x2);
std::swap(y1, y2);
}

const float dx = x2 - x1;
const float dy = fabs(y2 - y1);

float error = dx / 2.0f;
const int ystep = (y1 < y2) ? 1 : -1;
int y = (int)y1;

const int maxX = (int)x2;

for(int x=(int)x1; x<maxX; x++)
{
if(steep)
{
SetPixel(y,x, color);
}
else
{
SetPixel(x,y, color);
}

error -= dy;
if(error < 0)
{
y += ystep;
error += dx;
}
}
}
``````

## 3 Answers

To save this to a file, you will need to do some initial calculations before writing data to a file. I suggest that you create a data structure (perhaps an array) to keep track of each "pixel". For example, you can declare

``````char graph;
``````

Each element of `graph` is either a space or a `'X'`. Use Bresenham's line algoritm to calculate the elements in `graph` which should be set to `'X'` and then write the array to a file.

First make an instance of a dynamic structure, preferably `std::vector`. I suggest to separate x and y for ease, e.g `std::vector<int> x_points, y_points`. Then, from your `for loop` body, record all coordinates i.e that (x,y). Then create a function that writes all the data from your vector into a file.

• +1, no a priori limitations – chux Jun 14 '13 at 3:04

You don't need NCurses to save ASCII, just create a plain text file and save the output of the Bresenham's algorithm in there. I suggest you use a different implementation of the algorithm aswell.