I'm trying to make a simple maze game using various random maze generation techniques. The user will have to find the best path from the start to exit and their score will be measured against the amount of steps they took, their time and how many undoes they used.

For my first generation, I used depth-first. I used this technique to generate a bitmap. However, now I would like to have an overlay on-top of the maze to see where the user has clicked (Not on the walls). The only way I can think about how to do it would be to use buttons. However, this is what I need help with. I think I should change it from a bitmap to using system.drawing lines? However, I don't know the most effective way of doing it.

I also would like to know how I could improve the code below to make it most effective as this is the first time I've done maze generation.

If possible, can you please keep your explanation simple so I can understand!

Here is my current code:

```
using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Drawing;
namespace FunTech
{
//Home mission example class
public class Maze
{
static List<Bitmap> _bitmap = new List<Bitmap>();
Node[,] Grid;
int width;
int height;
/// <summary>
/// Bengin to create a maze, setting its size. Important: The maze must be generated before it can be used!
/// </summary>
/// <param name="width">The width of your maze</param>
/// <param name="height">The height of your maze</param>
public Maze(int width, int height)
{
Grid = new Node[width, height];
this.width = width;
this.height = height;
Node.r = new Random();
for (int x = 0; x < width; x++)
{
for (int y = 0; y < height; y++)
{
Grid[x, y] = new Node(x, y);
Grid[x, y].walls = new bool[]
{ true, true, true, true };
Grid[x, y].edges = new bool[4];
if (x == 0) //Left edge
Grid[x, y].edges[3] = true;
if (x == width - 1) //Right edge
Grid[x, y].edges[1] = true;
if (y == 0) //Top edge
Grid[x, y].edges[0] = true;
if (y == height - 1) //Bottom edge
Grid[x, y].edges[2] = true;
}
}
}
/// <summary>
/// Generates a maze starting from the position of your choice
/// </summary>
/// <param name="x">The starting X co-ordinate</param>
/// <param name="y">The starting Y co-ordinate</param>
public void Generate(int x, int y)
{
Grid[x, y].Explore(this);
}
/// <summary>
/// Generates a maze starting from (1, 1) and returns an image of each step (WARNING: Slow!)
/// </summary>
/// <returns>Returns a list of Bitmap images, generated at each step of the maze's creation</returns>
public List<Bitmap> Generate()
{
Grid[1, 1].Explore(this);
return Maze._bitmap;
}
/// <summary>
/// Generates a Bitmap image to represent your maze
/// </summary>
/// <param name="wallsize">The thickness of the walls</param>
/// <param name="cellsize">The size of the inside of each cell</param>
/// <returns>The final image</returns>
public Bitmap bitmap(int wallsize, int cellsize)
{
int totalcellsize = (2 * wallsize) + cellsize;
Bitmap bmp = new Bitmap((width) * totalcellsize, (height) * totalcellsize);
for (int x = 0; x < width; x++)
{
for (int y = 0; y < height; y++)
{
if (Grid[x, y].walls[0]
&& Grid[x, y].walls[1]
&& Grid[x, y].walls[2]
&& Grid[x, y].walls[3]
)
{
for (int xw = 0; xw < totalcellsize; xw++)
{
for (int yw = 0; yw < totalcellsize; yw++)
{
bmp.SetPixel((x * totalcellsize) + xw,(y * totalcellsize) + yw, Color.Black);
}
}
}
else
{
//Set BG white
for (int xw = 0; xw < totalcellsize; xw++)
for (int yw = 0; yw < totalcellsize; yw++)
bmp.SetPixel((x * totalcellsize) + xw,
(y * totalcellsize) + yw, Color.White);
for (int xw = 0; xw < totalcellsize; xw++)
{ //Top wall
if (Grid[x, y].walls[0])
for (int yw = 0; yw < wallsize; yw++)
bmp.SetPixel((x * totalcellsize) + xw,
(y * totalcellsize) + yw, Color.Black);
//Bottom wall
if (Grid[x, y].walls[2])
for (int yw = (totalcellsize - wallsize) - 1; yw < totalcellsize; yw++)
bmp.SetPixel((x * totalcellsize) + xw,
(y * totalcellsize) + yw, Color.Black);
}
for (int yw = 0; yw < totalcellsize; yw++)
{
//Left wall
if (Grid[x, y].walls[3])
for (int xw = 0; xw < wallsize; xw++)
bmp.SetPixel((x * totalcellsize) + xw,
(y * totalcellsize) + yw, Color.Black);
//Right wall
if (Grid[x, y].walls[1])
for (int xw = (totalcellsize - wallsize) - 1; xw < totalcellsize; xw++)
bmp.SetPixel((x * totalcellsize) + xw,
(y * totalcellsize) + yw, Color.Black);
}
}
}
}
return bmp;
}
internal class Node
{
private int x;
private int y;
private int visited = 0;
//N, E, S, W
internal bool[] walls = new bool[4];
internal bool[] edges = new bool[4];
internal static Random r;
internal Node(int x, int y)
{
this.x = x;
this.y = y;
}
internal void Explore(Maze m)
{
Node[,] Grid;
Grid = m.Grid;
Maze._bitmap.Add(m.bitmap(1, 10));
visited++;
List<Node> neighbours = new List<Node>();
if (!edges[0]) neighbours.Add(Grid[x, y - 1]); //N neighbour
if (!edges[1]) neighbours.Add(Grid[x + 1, y]); //E neighbour
if (!edges[2]) neighbours.Add(Grid[x, y + 1]); //S neighbour
if (!edges[3]) neighbours.Add(Grid[x - 1, y]); //W neighbour
if (neighbours.Count == 0) return;
for (int i = neighbours.Count - 1; i >= 0; i--)
if (neighbours[i].visited > 0)
neighbours.RemoveAt(i);
while (neighbours.Count > 0)
{
Node next = neighbours[r.Next(0, neighbours.Count)];
if (next.y < this.y) { walls[0] = false; next.walls[2] = false; }
else if (next.y > this.y) { walls[2] = false; next.walls[0] = false; }
else if (next.x > this.x) { walls[1] = false; next.walls[3] = false; }
else if (next.x < this.x) { walls[3] = false; next.walls[1] = false; }
next.Explore(m);
for (int i = neighbours.Count - 1; i >= 0; i--)
if (neighbours[i].visited > 0)
neighbours.RemoveAt(i);
}
}
}
}
```

}