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Added A* algorithm (#1913)
* a* algorithm * changes after build error * intent changes * fix after review * ImportMissmatchError * Build failed fix * doctest changes * doctest changes
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machine_learning/astar.py
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152
machine_learning/astar.py
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import numpy as np
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'''
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The A* algorithm combines features of uniform-cost search and pure
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heuristic search to efficiently compute optimal solutions.
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A* algorithm is a best-first search algorithm in which the cost
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associated with a node is f(n) = g(n) + h(n),
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where g(n) is the cost of the path from the initial state to node n and
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h(n) is the heuristic estimate or the cost or a path
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from node n to a goal.A* algorithm introduces a heuristic into a
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regular graph-searching algorithm,
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essentially planning ahead at each step so a more optimal decision
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is made.A* also known as the algorithm with brains
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'''
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class Cell(object):
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'''
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Class cell represents a cell in the world which have the property
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position : The position of the represented by tupleof x and y
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co-ordinates initially set to (0,0)
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parent : This contains the parent cell object which we visited
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before arrinving this cell
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g,h,f : The parameters for constructing the heuristic function
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which can be any function. for simplicity used line
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distance
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'''
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def __init__(self):
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self.position = (0, 0)
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self.parent = None
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self.g = 0
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self.h = 0
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self.f = 0
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'''
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overrides equals method because otherwise cell assign will give
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wrong results
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'''
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def __eq__(self, cell):
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return self.position == cell.position
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def showcell(self):
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print(self.position)
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class Gridworld(object):
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'''
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Gridworld class represents the external world here a grid M*M
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matrix
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w : create a numpy array with the given world_size default is 5
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'''
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def __init__(self, world_size=(5, 5)):
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self.w = np.zeros(world_size)
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self.world_x_limit = world_size[0]
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self.world_y_limit = world_size[1]
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def show(self):
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print(self.w)
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'''
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get_neighbours
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As the name suggests this function will return the neighbours of
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the a particular cell
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'''
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def get_neigbours(self, cell):
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neughbour_cord = [
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(-1, -1), (-1, 0), (-1, 1), (0, -1),
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(0, 1), (1, -1), (1, 0), (1, 1)]
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current_x = cell.position[0]
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current_y = cell.position[1]
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neighbours = []
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for n in neughbour_cord:
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x = current_x + n[0]
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y = current_y + n[1]
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if (
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(x >= 0 and x < self.world_x_limit) and
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(y >= 0 and y < self.world_y_limit)):
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c = Cell()
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c.position = (x, y)
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c.parent = cell
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neighbours.append(c)
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return neighbours
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'''
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Implementation of a start algorithm
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world : Object of the world object
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start : Object of the cell as start position
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stop : Object of the cell as goal position
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'''
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def astar(world, start, goal):
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'''
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>>> p = Gridworld()
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>>> start = Cell()
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>>> start.position = (0,0)
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>>> goal = Cell()
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>>> goal.position = (4,4)
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>>> astar(p, start, goal)
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[(0, 0), (1, 1), (2, 2), (3, 3), (4, 4)]
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'''
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_open = []
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_closed = []
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_open.append(start)
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while _open:
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min_f = np.argmin([n.f for n in _open])
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current = _open[min_f]
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_closed.append(_open.pop(min_f))
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if current == goal:
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break
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for n in world.get_neigbours(current):
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for c in _closed:
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if c == n:
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continue
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n.g = current.g + 1
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x1, y1 = n.position
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x2, y2 = goal.position
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n.h = (y2 - y1)**2 + (x2 - x1)**2
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n.f = n.h + n.g
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for c in _open:
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if c == n and c.f < n.f:
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continue
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_open.append(n)
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path = []
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while current.parent is not None:
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path.append(current.position)
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current = current.parent
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path.append(current.position)
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path = path[::-1]
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return path
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if __name__ == '__main__':
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'''
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sample run
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'''
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# object for the world
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p = Gridworld()
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# stat position and Goal
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start = Cell()
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start.position = (0, 0)
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goal = Cell()
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goal.position = (4, 4)
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print("path from {} to {} ".format(start.position, goal.position))
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s = astar(p, start, goal)
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# Just for visual Purpose
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for i in s:
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p.w[i] = 1
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print(p.w)
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