# Dead or Alive turtle jumping Algorithm

River is divided into n segments breadth wise, with either stone or water [ 1,0,0,1,1,0,1,1,0,1... ].A turtle is present on one side of the bank and he can make a move with speed of x, x speed means he can cross x segments of the river at a single time. After making a cross with x speed, he can acquire, either of these three speeds, x,x+1,x-1. He can move in both directions.

Now 1 represents stone and 0 represents water. If the turtle jumps into water he dies, but if he makes a jump on stone, then he can acquire new speed according to the given rule.

Given no. of segments (n), distribution of segment(array[n]), and the initial speed(x). Find is there any possibility of the turtle making it to the other side of the bank ?

I've solved this problem recursively, but not able to do using non-recursive method.

Turtle on one side||1,0,1,1,0,0,0,1,1,0,1,....||Other side of the river

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what is your recursive solution? –  Voles Sep 12 '13 at 9:23
Its sort of a brute force approach, 1)I'm constantly checking for cases when turtle will be dead, that can be case when all three speeds will hit water. 2) It can always make a valid exit, if at any point of time distance between bank and current position is less than x. Based on this cases and few more I made a recursive approach, allowing every current position to recurse in possible positions ahead. –  Anathema.Imbued Sep 12 '13 at 9:31

Basically it's a simple search problem, where your states are tuples of the current position of the turtle and it's speed. It can be implemented without recursion using a stack (depth first) or a queue (breadth first search). Here's an implementation using a queue, i.e., breadth-first, in Python:

``````from collections import deque

def cross_river(river, position=0, speed=1):
queue = deque([(position, speed, [])])
visited = set()
while queue:
position, speed, path = queue.popleft()

# if  last stone of river, return sequence of jumps to get there
if position == len(river) - 1:
return path

# check whether we've been here before
if (position, abs(speed)) in visited:
continue

# for all possible jumps, add the new state to the queue
for i in [-1, 0, +1]:    # change in speed
for k in [-1, +1]:   # change in direction
new_spd = (speed + i) * k
new_pos = position + new_spd
if 0 <= new_pos < len(river) and river[new_pos] == 1:
queue.append((new_pos, new_spd, path + [new_spd]))

print cross_river([1,0,1,1,0,0,0,1,1,0,1])  # Result: [2, -2, 3, 4, 3]
``````

(In fact, this algorithm is a bit stricter than what's described in your question, as the turtle has to to land exactly on the last stone, instead of anywhere on the other side, but this should be easy to change.)

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