Say you want a simple maze on an N by M grid, with one path through, and a good number of dead ends, but that looks "right" (i.e. like someone made it by hand without too many little tiny dead ends and all that). Is there a known way to do this?
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From http://www.astrolog.org/labyrnth/algrithm.htm
They produce only 10% dead ends is an example of a maze generated by that method. 


A pretty straightforward solution could be to assign random weights to the graph edges and apply Kruskal's algorithm to find a minimum spanning tree. Best discussion ever on maze generation algorithms: http://www.jamisbuck.org/presentations/rubyconf2011/index.html (was on HN a couple days ago). 


It turns out there are 12 classic algorithms to generate "perfect" mazes. A maze is perfect if it has one, and only one, solution. Here are some links to each algorithm, in rough order of my preference.
For more info, check out mazelib on GitHub, a Python library implementing all the standard maze generating/solving algorithms. 


Strangely enough, by slightly changing the 'canonical' rules and starting from a random configuration, Conway's Game of Life seems to generate pretty nice mazes! (I don't remember the exact rule, but it's a very simple modification that tends to 'densify' the population of cells...) 


One of the methods to generate a maze is the randomized version of Prim's algorithm. Start with a grid full of walls. Pick a cell, mark it as part of the maze. Add the walls of the cell to the wall list. While there are walls in the list: Pick a random wall from the list. If the cell on the opposite side isn't in the maze yet: (i) Make the wall a passage and mark the cell on the opposite side as part of the maze. (ii) Add the neighboring walls of the cell to the wall list. If the cell on the opposite side already was in the maze, remove the wall from the list. For more understanding click here 


Here's the DFS algorithm written as pseudocode: create a CellStack (LIFO) to hold a list of cell locations while VisitedCells < TotalCells
find all neighbors of CurrentCell with all walls intact 

