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Maze Solving using graph

Hey i was in a local programming competition and they asked me this question which i could not do so please help me on this one.

Write a program that loads from a file the size of a maze and then the maze itself. To model the maze we use the character "S" that specifies the start cell, "." that specifies free cell, "#" is a wall and "F" is the final cell. Write a program that will find a path from the start cell to the final cell. You can think that in the maze there is a robot that obeys commands, so for the following maze the robot should receive the following commands: up, up, right, right, down, down.

maze 1 text file

``````5 5
#####
#...#
#.#.#
#S#T#
#####
``````

maze 2 text file

``````4 5
#.#.#
#.#.#
#S#T#
#####
``````

Write your program in general (the maze maximum input can be at most 200x200).

Help would be much appreciated. I am just a rising sophmore so if you could provide me the code then i could understand it and they do it again bymyself.

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@rwilliams: This isn't homework. – Cam Nov 14 '10 at 4:48
Are multiple paths possible from S to T ? – bjskishore123 Nov 14 '10 at 5:10
you just have to find one path to solve the problem, i think thats what the questions says.. – catvsrat Nov 15 '10 at 1:47

One way to find a path:

1. Have a queue of cells to check, and a count of steps for each cell from there to the destination.
2. Set the ending cell's count to 0, and add it to the queue.
3. While the queue is not empty:
1. Get a cell from the queue.
2. For each free neighbor cell, compare the current cell's count + 1 to the neighbor cell's count. If it's less, of if the neighbor cell doesn't have a count yet, set the neighbor cell's count to the current cell's count + 1, then add the neighbor cell to the queue.

Once the queue's empty, every free cell in the maze (that can be reached from the destination) will have the number of steps in the shortest path to the destination. If a cell doesn't have a count, there's no path from it to the destination.

If the start cell has a count,

1. Get the start cell's count.
2. Check each neighbor cell for a count of (count - 1). There will be one, and that's the next step in the path. Record the direction to that cell, and then get that cell, and if it's not the destination, repeat step 2 with that cell.

I'll leave it up to you to figure out how to load the maze. That's the easy part of all this.

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Also known as Flood Filling if I am not mistaken. Probably the easiest way to solve this I implemented, back in high school (after the follow the left-wall variants, which can be trapped). – Matthieu M. Nov 14 '10 at 11:15
thanks for the reply – catvsrat Nov 15 '10 at 1:49

In case you don't know what to search for: http://en.wikipedia.org/wiki/Pathfinding#Sample_algorithm and this contains a LOT more info: http://www.astrolog.org/labyrnth/algrithm.htm

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thanks for the link – catvsrat Nov 15 '10 at 1:49

The code is too much to write here, but the most common way of solving mazes is to set off in one direction, and at every right turn you can make, turn right.

This is guaranteed to work so long as the start and exit are in one of the four surrounding walls. For mazes that don't have their start and exit along the walls, it's an exercise in recursion.

See what you can come up with code-wise based off that as a starting point!

HTH, James

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That also assumes there are no holes in the outside walls besides the start and exit, of course. – Jefromi Nov 14 '10 at 4:49
In terms of graphs, this algorithm works perfectly for `connected, acyclic graphs` and for no other types. – SingleNegationElimination Nov 14 '10 at 5:03
Jefromi> True! TokenMackGuy> What would an example of a maze that isn't a connected, acyclic graph? (My graph theory is weak) – James King Nov 14 '10 at 5:19
@James: Say one of the endpoints is in the middle of the maze, and is surrounded by a sub-maze of sorts that's not connected to the outside wall at all. It'd be possible to walk all the way around the inner maze, ending up right back where you started. (Read: the maze is no longer acyclic.) And if you don't switch sides from time to time, you'll never make your way from the outer maze to the inner one. – cHao Nov 14 '10 at 18:53
thanks eveyone for your help – catvsrat Nov 15 '10 at 1:51