# Number of possible paths in android pattern lock

How many paths possible in android pattern lock?

I thought it can be calculated simply by factorial, with formula `(9!)/(9-length)!`

Examples:

For length 9, there are 9*8*7*6*5*4*3*2*1 paths.

For length 8, there are 9*8*7*6*5*4*3*2 paths.

For length 7, there are 9*8*7*6*5*4*3 paths.

etc.

Here is the code for calculating this:

``````def paths_of_length(number_of_staring_points, length_of_path):
print("number_of_staring_points", number_of_staring_points, "length_of_path", length_of_path)
different_paths = 1
for choosing_from in range(number_of_staring_points,
number_of_staring_points - length_of_path,
-1):
different_paths = different_paths * choosing_from

return different_paths

def android_paths():
"""
Returns number of different android lockscreen paths
"""
different_paths = 0
minimum_length = 4
maximum_length = 9
number_of_staring_points = 9
for length in range(minimum_length,maximum_length + 1):
different_paths += paths_of_length(number_of_staring_points,length)

return different_paths

if __name__ == '__main__':
import doctest
doctest.testmod()

print(android_paths())
``````

Is my method, and the code correct? Or am I calculating it wrong?

• I don't know, run some unit tests. – Isaiah Taylor Jan 5 '16 at 5:18
• Can you use a pattern starting `1 -- 9`? On my androids, that is impossible: they insist on `1 -- 5 -- 9` – rici Jan 5 '16 at 6:20
• No but you can use the sequence 5 -- 1 -- 9 (1 -- 9 is valid because 5 has been used). – AChampion Jan 5 '16 at 6:41
• @achampion: Sure, but the fact that `1 -- 9` is not valid (unless a 5 precedes it) reduces the number of permutations. It gets complicated. – rici Jan 5 '16 at 7:12
• Possible duplicate of android lock password combinations – AChampion Jan 5 '16 at 7:41

Update: Found this has been covered in another post android lock password combinations

The allowed moves include adjacent (including diagonals), knights (e.g. 1->6) and pegged moves (e.g. 1->3 if 2 already in the path).

So a quick brute force in python:

``````pegs = {
1: {3:2, 7:4, 9:5},
2: {8:5},
3: {1:2, 7:5, 9:6},
4: {6:5},
5: {},
6: {4:5},
7: {1:4, 3:5, 9:8},
8: {2:5},
9: {1:5, 3:6, 7:8}
}

def next_steps(path):
return (n for n in range(1,10) if (not path or n not in path and
(n not in pegs[path[-1]]
or pegs[path[-1]][n] in path)))

def patterns(path, steps, verbose=False):
if steps == 0:
if verbose: print(path)
return 1
return sum(patterns(path+[n], steps-1, verbose) for n in next_steps(path))

[(steps, patterns([], steps)) for steps in range(1,10)]
``````

Output:

``````[(1, 9),
(2, 56),
(3, 320),
(4, 1624),
(5, 7152),
(6, 26016),
(7, 72912),
(8, 140704),
(9, 140704)]
``````

So the total for android (4-9) is:

``````>>> sum(patterns([], steps) for steps in range(4,10))
389112
``````
• I calculated 3 nodes by hand, it's 304, not 320. Are you sure of these results? – ferit Jan 5 '16 at 9:19
• I'm pretty sure and it agrees with the results in the post referenced. – AChampion Jan 5 '16 at 13:41
• Yeah it agrees but where is the proof? I am going to write down the calculation of 304 and post it. Btw, i cant understand your code, all one liner but not readable. – ferit Jan 5 '16 at 18:59
• Added list of 3 paths... – AChampion Jan 5 '16 at 19:27
• OK, comparing outputs I found whats missing, I understand know what you meant by saying peg : ) – ferit Jan 5 '16 at 20:10

Your calculation is wrong, because not every node has edge to another node, and some nodes have some edges only enabled by some conditions.

For example: To reach from top-left node to top-right node, top-middle node should be visited before.

You can't calculate it simply by multiplying some numbers. You need to use a path finding algorithm.

Good news, I wrote one.

## Code

This is a utility class:

``````import java.util.ArrayList;
import java.util.HashMap;

public class Node
{

private String name;

private HashMap<Node, Node> conditionalNeigbors = new HashMap<>();

private ArrayList<Node> neigbors = new ArrayList<>();
private boolean visited = false;

public Node(String name)
{
this.name = name;
}

{
}

{
conditionalNeigbors.put(condition, n);
}

ArrayList<Node> getNeigbors(ArrayList<Node> path)
{

ArrayList<Node> toReturn = new ArrayList<>();
ArrayList<Node> conditionals = new ArrayList<>();
for (int i = 0; i < path.size(); i++)
{
if(conditionalNeigbors.containsKey(path.get(i)))
{
}
}

}

void setVisited(boolean b)
{
visited = b;
}

boolean getVisited()
{
return visited;
}

public String getName()
{
return name;
}

}
``````

And the main class:

``````import java.util.ArrayList;

public class Pathfinder
{

static boolean debug = false;

/**
* A B C
*
* D E F
*
* G H J
*/
public static void main(String[] args)
{

Node a = new Node("A");
Node b = new Node("B");
Node c = new Node("C");
Node d = new Node("D");
Node e = new Node("E");
Node f = new Node("F");
Node g = new Node("G");
Node h = new Node("H");
Node j = new Node("J");

ArrayList<Node> graph = new ArrayList<>();

int sum = 0;

System.out.println(countPaths(b, 3, new ArrayList<>()));

for (int k = 1; k < 10; k++)
{
for (int i = 0; i < graph.size(); i++)
{
sum += countPaths(graph.get(i), k, new ArrayList<>());
}

System.out.println("Number of all paths with length of " + k + ": " + sum);
sum = 0;
}
}

/*
Finds number of all possible paths of given length, starting from given node
*/
static int countPaths(Node start, int length, ArrayList<Node> path)
{

start.setVisited(true);

ArrayList<Node> neigbors = start.getNeigbors(path);
int neigborCount = neigbors.size();
ArrayList<Node> unvisitedNeighbors = new ArrayList<>();

for (int i = 0; i < neigborCount; i++)
{
Node temp = neigbors.get(i);

if (temp.getVisited() == false)
{
}
}

int unvisitedNeighborCount = unvisitedNeighbors.size();

if (length == 1) // Base case, no more moves, a path found, return 1
{
if (debug)
{
for (int i = 0; i < path.size(); i++)
{
System.out.print(path.get(i).getName());
}
System.out.println("");
}

start.setVisited(false); // Backtrack
path.remove(path.size() - 1);

return 1;
} else // There are still moves
{
int sum = 0;
for (int i = 0; i < unvisitedNeighborCount; i++)
{
sum += countPaths(unvisitedNeighbors.get(i), length - 1, path);
}

start.setVisited(false); // Backtrack
path.remove(path.size() - 1);

return sum;
}
}

}
``````

No, you don't have to run this. I have calculated all for you:

``````Number of all paths with length of 1: 9
Number of all paths with length of 2: 56
Number of all paths with length of 3: 320
Number of all paths with length of 4: 1624
Number of all paths with length of 5: 7152
Number of all paths with length of 6: 26016
Number of all paths with length of 7: 72912
Number of all paths with length of 8: 140704
Number of all paths with length of 9: 140704
``````

## Explanation

I turned the problem into a undirected cyclic graph search problem.

``````A  B  C
D  E  F
G  H  J
``````
• Points are represented as `Node`s
• Legal moves are represented as `Edge`s
• Every `Node` has a `visited` property
• There are two types of edges: Always available ones, and conditional ones. An example to conditional move: A-C possible only when B is visited.
• Search starts from a given node for given length of paths, with empty path. In each iteration, algorithm obtains possible edges(taking account of conditional edges) and recursively calls a sub-search starting from next nodes.

Example

This is an example call trace, for searching paths length of 3, starting from node B.

``````_\ countPaths(B, 3, null)
_\ countPaths(A, 2, B)
_\ countPaths(C, 1, BA)
_\ countPaths(D, 1, BA)
_\ countPaths(E, 1, BA)
_\ countPaths(F, 1, BA)
_\ countPaths(H, 1, BA)
_\ countPaths(C, 2, B)
_\ countPaths(A, 1, BC)
_\ countPaths(D, 1, BC)
_\ countPaths(H, 1, BC)
_\ countPaths(E, 1, BC)
_\ countPaths(F, 1, BC)
_\ countPaths(D, 2, B)
_\ countPaths(A, 1, BD)
_\ countPaths(E, 1, BD)
_\ countPaths(G, 1, BD)
_\ countPaths(H, 1, BD)
_\ countPaths(C, 1, BD)
_\ countPaths(J, 1, BD)
_\ countPaths(E, 2, B)
_\ countPaths(A, 1, BE)
_\ countPaths(C, 1, BE)
_\ countPaths(D, 1, BE)
_\ countPaths(F, 1, BE)
_\ countPaths(G, 1, BE)
_\ countPaths(H, 1, BE)
_\ countPaths(J, 1, BE)
_\ countPaths(F, 2, B)
_\ countPaths(C, 1, BF)
_\ countPaths(E, 1, BF)
_\ countPaths(H, 1, BF)
_\ countPaths(J, 1, BF)
_\ countPaths(A, 1, BF)
_\ countPaths(G, 1, BF)
_\ countPaths(G, 2, B)
_\ countPaths(D, 1, BG)
_\ countPaths(E, 1, BG)
_\ countPaths(H, 1, BG)
_\ countPaths(F, 1, BG)
_\ countPaths(J, 2, B)
_\ countPaths(F, 1, BJ)
_\ countPaths(E, 1, BJ)
_\ countPaths(H, 1, BJ)
_\ countPaths(D, 1, BJ)
``````

So it simply divides problems into smaller sub-problems, until it gets a problem with length of 1 where solution is 1(base case).

So after finding all path from a given node, all we need to do is to enumerate this operation for all 9 nodes, which is done by a simple for loop in `main()` method, simply by calling `countPaths()` methods.

• I don't believe this correct either. You can make knight moves, e.g. 1->8 and you can make peg moves, e.g. 1->3 if 2 has already been used. – AChampion Jan 5 '16 at 6:41
• Yes, I found a mistake too, I'm debugging it now. But the approach is correct. – ferit Jan 5 '16 at 6:46
• I'll explain in more detail after debugging. – ferit Jan 5 '16 at 6:46
• I reworked the code, including knight and peg moves. Now it's working fine. – ferit Jan 7 '16 at 17:53