1

This is the Photo i'm trying to implement as a graph

What I'm trying to do is to implement a depth search algorithm on a graph to reach a goal state but i keeping getting a KeyError. It seemed to be working fine with smaller more simplier graphs but this one isn't working.

    #The Graph to Search   
         graph = {
                    'state1' : set(['state2','state3','state4']),
                    'state2' : set(['state5']),
                    'state5' : set(['state10','state11']),
                    'state10' : set(['state20']),
                    'state20' : set(['state34','state35']),
                    'state11' : set(['state21','state22','state23']),
                    'state21' : set(['state36','state37']),
                    'state22' : set(['state38','state39']),
                    'state23' : set(['state40','state41']),
                    'state3' : set(['state6','state7','state8']),
                    'state6' : set(['state12','state13']),
                    'state12' : set(['state24']),
                    'state24' : set(['state42','state43']),
                    'state13' : set(['state25']),
                    'state25' : set(['state44','state45']),
                    'state7' : set(['state14','state15']),
                    'state14' : set(['state26']),
                    'state26' : set(['state46']), #GOALSTATE
                    'state15' : set(['state27']),
                    'state8' : set(['state16','state17']),
                    'state16' : set(['state28']),
                    'state17' : set(['state29']),
                    'state4' : set(['state9']),
                    'state9' : set(['state18','state19']),
                    'state18' : set(['state30','state31','state32']),
                    'state19' : set(['state33'])
                    }


            #Depth First Algorithm
            def dfs_paths(graph, start, goal):
                stack = [(start, [start])]
                while stack:
                    (vertex, path) = stack.pop()
                    for next in graph[vertex] - set(path) :
                        if next == goal:
                            yield path + [next]
                        else:[enter image description here][1]
                            stack.append((next, path + [next]))

            #Method Call
            list(dfs_paths(graph, 'state1', 'state46'))   
2
  • Some of your states, for instance state30, are not in the graph.
    – k_ssb
    Sep 30 '18 at 10:32
  • I don't believe hardcoding every state of that graph is a good idea. It would be much wiser to implement a SlidingWindowGame class which keeps record of a 3x3 board and has a possible_moves method which returns a set a future boards.
    – timgeb
    Sep 30 '18 at 10:32
2

As timgeb mentions, there are better ways to do this. But as pkpnd mentions, the reason your code sometimes fails is that some of the path states do not have corresponding keys, so they need to be skipped.

I've made a few other minor changes, like using more modern set syntax, and not using next as a variable name because that's a built-in function. I also use the set.difference method rather than the - operand form so I don't need to convert the path list to a set.

graph = {
    'state1': {'state3', 'state2', 'state4'},
    'state2': {'state5'},
    'state5': {'state11', 'state10'},
    'state10': {'state20'},
    'state20': {'state34', 'state35'},
    'state11': {'state22', 'state21', 'state23'},
    'state21': {'state37', 'state36'},
    'state22': {'state39', 'state38'},
    'state23': {'state40', 'state41'},
    'state3': {'state8', 'state7', 'state6'},
    'state6': {'state13', 'state12'},
    'state12': {'state24'},
    'state24': {'state43', 'state42'},
    'state13': {'state25'},
    'state25': {'state45', 'state44'},
    'state7': {'state14', 'state15'},
    'state14': {'state26'},
    'state26': {'state46'},
    'state15': {'state27'},
    'state8': {'state17', 'state16'},
    'state16': {'state28'},
    'state17': {'state29'},
    'state4': {'state9'},
    'state9': {'state19', 'state18'},
    'state18': {'state30', 'state32', 'state31'},
    'state19': {'state33'},
}

#Depth First Algorithm
def dfs_paths(graph, start, goal):
    stack = [(start, [start])]
    while stack:
        vertex, path = stack.pop()
        if vertex not in graph:
            continue
        for nxt in graph[vertex].difference(path):
            if nxt == goal:
                yield path + [nxt]
            else:
                stack.append((nxt, path + [nxt]))

for a in dfs_paths(graph, 'state1', 'state46'):
    print(a)

output

['state1', 'state3', 'state7', 'state14', 'state26', 'state46']
2
  • As chance has it, I implemented this a few years ago ... Board, Search Algorithms.
    – timgeb
    Sep 30 '18 at 11:08
  • 1
    @timgeb Cool! FWIW, I've written a few sliding block programs over the years, including a 3x3x3 one back in the 8 bit era. I don't think I ever got around to writing a solver, but I might have. :)
    – PM 2Ring
    Sep 30 '18 at 11:12

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