/_idea

## _idea
simulate roads created by people trying to get from point A to point B

rules:

  - each turn, everybody is assigned a position to go if they don't have already somewhere to go
  - each time they go over a "block", it becomes easier for others to use it

## dijkstra.py
# Dijkstra's algorithm for shortest paths
# David Eppstein, UC Irvine, 4 April 2002

# http://aspn.activestate.com/ASPN/Cookbook/Python/Recipe/117228
class priorityDictionary(dict):
    def __init__(self):
        '''Initialize priorityDictionary by creating binary heap
of pairs (value,key).  Note that changing or removing a dict entry will
not remove the old pair from the heap until it is found by smallest() or
until the heap is rebuilt.'''
        self.__heap = []
        dict.__init__(self)

    def smallest(self):
        '''Find smallest item after removing deleted items from heap.'''
        if len(self) == 0:
            raise IndexError("smallest of empty priorityDictionary")
        heap = self.__heap
        while heap[0][1] not in self or self[heap[0][1]] != heap[0][0]:
            lastItem = heap.pop()
            insertionPoint = 0
            while 1:
                smallChild = 2*insertionPoint+1
                if smallChild+1 < len(heap) and \
                        heap[smallChild] > heap[smallChild+1]:
                    smallChild += 1
                if smallChild >= len(heap) or lastItem <= heap[smallChild]:
                    heap[insertionPoint] = lastItem
                    break
                heap[insertionPoint] = heap[smallChild]
                insertionPoint = smallChild
        return heap[0][1]

    def __iter__(self):
        '''Create destructive sorted iterator of priorityDictionary.'''
        def iterfn():
            while len(self) > 0:
                x = self.smallest()
                yield x
                del self[x]
        return iterfn()

    def __setitem__(self,key,val):
        '''Change value stored in dictionary and add corresponding
pair to heap.  Rebuilds the heap if the number of deleted items grows
too large, to avoid memory leakage.'''
        dict.__setitem__(self,key,val)
        heap = self.__heap
        if len(heap) > 2 * len(self):
            self.__heap = [(v,k) for k,v in self.items()]
            self.__heap.sort()  # builtin sort likely faster than O(n) heapify
        else:
            newPair = (val,key)
            insertionPoint = len(heap)
            heap.append(None)
            while insertionPoint > 0 and \
                    newPair < heap[(insertionPoint-1)//2]:
                heap[insertionPoint] = heap[(insertionPoint-1)//2]
                insertionPoint = (insertionPoint-1)//2
            heap[insertionPoint] = newPair

    def setdefault(self,key,val):
        '''Reimplement setdefault to call our customized __setitem__.'''
        if key not in self:
            self[key] = val
        return self[key]

def Dijkstra(G,start,end=None):
    """
    Find shortest paths from the  start vertex to all vertices nearer than or equal to the end.

    The input graph G is assumed to have the following representation:
    A vertex can be any object that can be used as an index into a dictionary.
    G is a dictionary, indexed by vertices.  For any vertex v, G[v] is itself a dictionary,
    indexed by the neighbors of v.  For any edge v->w, G[v][w] is the length of the edge.
    This is related to the representation in <http://www.python.org/doc/essays/graphs.html>
    where Guido van Rossum suggests representing graphs as dictionaries mapping vertices
    to lists of outgoing edges, however dictionaries of edges have many advantages over lists:
    they can store extra information (here, the lengths), they support fast existence tests,
    and they allow easy modification of the graph structure by edge insertion and removal.
    Such modifications are not needed here but are important in many other graph algorithms.
    Since dictionaries obey iterator protocol, a graph represented as described here could
    be handed without modification to an algorithm expecting Guido's graph representation.

    Of course, G and G[v] need not be actual Python dict objects, they can be any other
    type of object that obeys dict protocol, for instance one could use a wrapper in which vertices
    are URLs of web pages and a call to G[v] loads the web page and finds its outgoing links.

    The output is a pair (D,P) where D[v] is the distance from start to v and P[v] is the
    predecessor of v along the shortest path from s to v.

    Dijkstra's algorithm is only guaranteed to work correctly when all edge lengths are positive.
    This code does not verify this property for all edges (only the edges examined until the end
    vertex is reached), but will correctly compute shortest paths even for some graphs with negative
    edges, and will raise an exception if it discovers that a negative edge has caused it to make a mistake.
    """

    D = {}  # dictionary of final distances
    P = {}  # dictionary of predecessors
    Q = priorityDictionary()    # estimated distances of non-final vertices
    Q[start] = 0

    for v in Q:
        D[v] = Q[v]
        if v == end: break

        for w in G[v]:
            vwLength = D[v] + G[v][w]
            if w in D:
                if vwLength < D[w]:
                    raise ValueError("Dijkstra: found better path to already-final vertex")
            elif w not in Q or vwLength < Q[w]:
                Q[w] = vwLength
                P[w] = v

    return (D,P)

def shortestPath(G,start,end):
    """
    Find a single shortest path from the given start vertex to the given end vertex.
    The input has the same conventions as Dijkstra().
    The output is a list of the vertices in order along the shortest path.
    """

    D,P = Dijkstra(G,start,end)
    Path = []
    while 1:
        Path.append(end)
        if end == start: break
        end = P[end]
    Path.reverse()
    return Path

class Point:
    def __init__(self, x, y):
        self.x = x
        self.y = y

    def __add__(self, other):
        if not isinstance(other, Point):
            return NotImplemented
        return Point(self.x + other.x, self.y + other.y)

    def __eq__(self, other):
        if not isinstance(other, Point):
            return NotImplemented
        return self.x == other.x and self.y == other.y

    def __hash__(self):
        return self.x*1000000 + self.y

    def __str__(self):
        return '{},{}'.format(self.x, self.y)

def shortestPath(G,start,end):
    """
    Find a single shortest path from the given start vertex to the given end vertex.
    The input has the same conventions as Dijkstra().
    The output is a list of the vertices in order along the shortest path.
    """

    D,P = Dijkstra(G,start,end)
    Path = []
    while 1:
        Path.append(end)
        if end == start: break
        end = P[end]
    Path.reverse()
    return Path

def to_graph(grid):
    G = dict()
    for y, row in enumerate(grid):
        for x, block in enumerate(row):
            edges = {}
            for offx, offy in (-1, 0), (1, 0), (0, -1), (0, 1): #, (-1, -1), (1, 1), (-1, 1), (1, -1):
                p = Point(x + offx, y + offy)
                if p.x < 0 or p.y < 0 or p.x >= len(row) or p.y >= len(grid):
                    continue
                try:
                    # w = 1000 - grid[y][x][0]
                    w = 1 / (grid[y][x][0] + 10)
                    edges[str(p)] = w
                except IndexError:
                    pass
            G[str(Point(x, y))] = edges
    return G

def faster_path(G, x, y, dest_x, dest_y):
    path = shortestPath(G, str(Point(x, y)),
                str(Point(dest_x, dest_y)))
    if len(path) < 2:
        return 0, 0
    start, end = path[:2]
    sx, sy = [int(x) for x in start.split(',')]
    ex, ey = [int(x) for x in end.split(',')]
    return ex - sx, ey - sy

if __name__ == '__main__':
    from pprint import pprint as pp

    # example, CLR p.528
    G = {'s': {'u':10, 'x':5},
        'u': {'v':1, 'x':2},
        'v': {'y':4},
        'x':{'u':3,'v':9,'y':2},
        'y':{'s':7,'v':6}}

    grid = [
        [(0,), (4,), (0,)],
        [(0,), (4,), (4,)],
        [(0,), (0,), (0,)],
    ]

    G = to_graph(grid)

    pp(G)

    print(Dijkstra(G, str(Point(0, 0))))
    print(shortestPath(G, str(Point(0, 0)), str(Point(2, 2))))


## grid.py
# two things to show: people positions + block resistance
# one easy thing: each block is
# - (block_smoothness, peoples)
# and people are just (goal_x, goal_y)

# let's do something minimal, create a grid with nobody
# let's add people

# grid[y // row][x // column]
import random, time, os

import dijkstra

WIDTH = 200
HEIGHT = 60

def maybe_add_somebody():
    if random.random() > 0.9995:
        return [(random.randint(0, WIDTH - 1), random.randint(0, HEIGHT - 1))]
    return []


def grid_print(grid):
    for row in grid:
        for block in row:
            # color it to make it fun !
            # limit precision too !
            l = block[0]
            c = ' '
            if l == 2:
                c = '\''
            elif l == 3:
                c = '"'
            elif l > 3:
                if l > 11: l = 11
                c = l - 2
            if len(block[1]) > 0:
                c = '|'
            print(c, end='')
        print()

def direct_path(grid, x, y, dest_x, dest_y):
    # compute movement to do to get to the target
    # without taking into account block resistance
    offx = 0
    if x != dest_x:
        if x > dest_x:
            offx = -1
        else:
            offx = 1

    offy = 0
    if y != dest_y:
        if y > dest_y:
            offy = -1
        else:
            offy = 1
    return offx, offy

def move_people(grid):
    G = dijkstra.to_graph(grid)
    new_peoples = []
    for y, row in enumerate(grid):
        for x, block in enumerate(row):
            for (dest_x, dest_y) in block[1]:
                # offx, offy = direct_path(grid, x, y, dest_x, dest_y)
                offx, offy = dijkstra.faster_path(G, x, y, dest_x, dest_y)

                ### if we are on the target, set new goal
                if offx == 0 and offy == 0:
                    dest_x = random.randint(0, WIDTH - 1)
                    dest_y = random.randint(0, HEIGHT - 1)

                ### detect bad directions
                new_x = x + offx
                if new_x < 0 or new_x >= WIDTH:
                    print('error: new_x=', new_x)
                    new_x = x
                new_y = y + offy
                if new_y < 0 or new_y >= HEIGHT:
                    print('error: new_y=', new_y)
                    new_y = y

                new_peoples.append((new_x, new_y, (dest_x, dest_y)))
            block[1] = []
    for x, y, dest in new_peoples:
        try:
            grid[y][x][0] += 1
            grid[y][x][1].append(dest)
        except IndexError:
            print('error: y=', y, ' x=', x)
            import pudb;pudb.set_trace()

grid = [ [ [
        1, maybe_add_somebody()
    ] for _ in range(WIDTH)
 ] for _ in range(HEIGHT)]

step = 0
while True:
    os.system('clear')
    print(step)
    grid_print(grid)
    move_people(grid)
    time.sleep(0.1)
    step += 1
	simulate roads created by people trying to get from point A to point B

	rules:

	- each turn, everybody is assigned a position to go if they don't have already somewhere to go
	- each time they go over a "block", it becomes easier for others to use it
	# Dijkstra's algorithm for shortest paths
	# David Eppstein, UC Irvine, 4 April 2002

	# http://aspn.activestate.com/ASPN/Cookbook/Python/Recipe/117228
	class priorityDictionary(dict):
	def __init__(self):
	'''Initialize priorityDictionary by creating binary heap
	of pairs (value,key). Note that changing or removing a dict entry will
	not remove the old pair from the heap until it is found by smallest() or
	until the heap is rebuilt.'''
	self.__heap = []
	dict.__init__(self)

	def smallest(self):
	'''Find smallest item after removing deleted items from heap.'''
	if len(self) == 0:
	raise IndexError("smallest of empty priorityDictionary")
	heap = self.__heap
	while heap[0][1] not in self or self[heap[0][1]] != heap[0][0]:
	lastItem = heap.pop()
	insertionPoint = 0
	while 1:
	smallChild = 2*insertionPoint+1
	if smallChild+1 < len(heap) and \
	heap[smallChild] > heap[smallChild+1]:
	smallChild += 1
	if smallChild >= len(heap) or lastItem <= heap[smallChild]:
	heap[insertionPoint] = lastItem
	break
	heap[insertionPoint] = heap[smallChild]
	insertionPoint = smallChild
	return heap[0][1]

	def __iter__(self):
	'''Create destructive sorted iterator of priorityDictionary.'''
	def iterfn():
	while len(self) > 0:
	x = self.smallest()
	yield x
	del self[x]
	return iterfn()

	def __setitem__(self,key,val):
	'''Change value stored in dictionary and add corresponding
	pair to heap. Rebuilds the heap if the number of deleted items grows
	too large, to avoid memory leakage.'''
	dict.__setitem__(self,key,val)
	heap = self.__heap
	if len(heap) > 2 * len(self):
	self.__heap = [(v,k) for k,v in self.items()]
	self.__heap.sort() # builtin sort likely faster than O(n) heapify
	else:
	newPair = (val,key)
	insertionPoint = len(heap)
	heap.append(None)
	while insertionPoint > 0 and \
	newPair < heap[(insertionPoint-1)//2]:
	heap[insertionPoint] = heap[(insertionPoint-1)//2]
	insertionPoint = (insertionPoint-1)//2
	heap[insertionPoint] = newPair

	def setdefault(self,key,val):
	'''Reimplement setdefault to call our customized __setitem__.'''
	if key not in self:
	self[key] = val
	return self[key]

	def Dijkstra(G,start,end=None):
	"""
	Find shortest paths from the start vertex to all vertices nearer than or equal to the end.

	The input graph G is assumed to have the following representation:
	A vertex can be any object that can be used as an index into a dictionary.
	G is a dictionary, indexed by vertices. For any vertex v, G[v] is itself a dictionary,
	indexed by the neighbors of v. For any edge v->w, G[v][w] is the length of the edge.
	This is related to the representation in <http://www.python.org/doc/essays/graphs.html>
	where Guido van Rossum suggests representing graphs as dictionaries mapping vertices
	to lists of outgoing edges, however dictionaries of edges have many advantages over lists:
	they can store extra information (here, the lengths), they support fast existence tests,
	and they allow easy modification of the graph structure by edge insertion and removal.
	Such modifications are not needed here but are important in many other graph algorithms.
	Since dictionaries obey iterator protocol, a graph represented as described here could
	be handed without modification to an algorithm expecting Guido's graph representation.

	Of course, G and G[v] need not be actual Python dict objects, they can be any other
	type of object that obeys dict protocol, for instance one could use a wrapper in which vertices
	are URLs of web pages and a call to G[v] loads the web page and finds its outgoing links.

	The output is a pair (D,P) where D[v] is the distance from start to v and P[v] is the
	predecessor of v along the shortest path from s to v.

	Dijkstra's algorithm is only guaranteed to work correctly when all edge lengths are positive.
	This code does not verify this property for all edges (only the edges examined until the end
	vertex is reached), but will correctly compute shortest paths even for some graphs with negative
	edges, and will raise an exception if it discovers that a negative edge has caused it to make a mistake.
	"""

	D = {} # dictionary of final distances
	P = {} # dictionary of predecessors
	Q = priorityDictionary() # estimated distances of non-final vertices
	Q[start] = 0

	for v in Q:
	D[v] = Q[v]
	if v == end: break

	for w in G[v]:
	vwLength = D[v] + G[v][w]
	if w in D:
	if vwLength < D[w]:
	raise ValueError("Dijkstra: found better path to already-final vertex")
	elif w not in Q or vwLength < Q[w]:
	Q[w] = vwLength
	P[w] = v

	return (D,P)

	def shortestPath(G,start,end):
	"""
	Find a single shortest path from the given start vertex to the given end vertex.
	The input has the same conventions as Dijkstra().
	The output is a list of the vertices in order along the shortest path.
	"""

	D,P = Dijkstra(G,start,end)
	Path = []
	while 1:
	Path.append(end)
	if end == start: break
	end = P[end]
	Path.reverse()
	return Path

	class Point:
	def __init__(self, x, y):
	self.x = x
	self.y = y

	def __add__(self, other):
	if not isinstance(other, Point):
	return NotImplemented
	return Point(self.x + other.x, self.y + other.y)

	def __eq__(self, other):
	if not isinstance(other, Point):
	return NotImplemented
	return self.x == other.x and self.y == other.y

	def __hash__(self):
	return self.x*1000000 + self.y

	def __str__(self):
	return '{},{}'.format(self.x, self.y)

	def shortestPath(G,start,end):
	"""
	Find a single shortest path from the given start vertex to the given end vertex.
	The input has the same conventions as Dijkstra().
	The output is a list of the vertices in order along the shortest path.
	"""

	D,P = Dijkstra(G,start,end)
	Path = []
	while 1:
	Path.append(end)
	if end == start: break
	end = P[end]
	Path.reverse()
	return Path

	def to_graph(grid):
	G = dict()
	for y, row in enumerate(grid):
	for x, block in enumerate(row):
	edges = {}
	for offx, offy in (-1, 0), (1, 0), (0, -1), (0, 1): #, (-1, -1), (1, 1), (-1, 1), (1, -1):
	p = Point(x + offx, y + offy)
	if p.x < 0 or p.y < 0 or p.x >= len(row) or p.y >= len(grid):
	continue
	try:
	# w = 1000 - grid[y][x][0]
	w = 1 / (grid[y][x][0] + 10)
	edges[str(p)] = w
	except IndexError:
	pass
	G[str(Point(x, y))] = edges
	return G

	def faster_path(G, x, y, dest_x, dest_y):
	path = shortestPath(G, str(Point(x, y)),
	str(Point(dest_x, dest_y)))
	if len(path) < 2:
	return 0, 0
	start, end = path[:2]
	sx, sy = [int(x) for x in start.split(',')]
	ex, ey = [int(x) for x in end.split(',')]
	return ex - sx, ey - sy

	if __name__ == '__main__':
	from pprint import pprint as pp

	# example, CLR p.528
	G = {'s': {'u':10, 'x':5},
	'u': {'v':1, 'x':2},
	'v': {'y':4},
	'x':{'u':3,'v':9,'y':2},
	'y':{'s':7,'v':6}}

	grid = [
	[(0,), (4,), (0,)],
	[(0,), (4,), (4,)],
	[(0,), (0,), (0,)],
	]

	G = to_graph(grid)

	pp(G)

	print(Dijkstra(G, str(Point(0, 0))))
	print(shortestPath(G, str(Point(0, 0)), str(Point(2, 2))))
	# two things to show: people positions + block resistance
	# one easy thing: each block is
	# - (block_smoothness, peoples)
	# and people are just (goal_x, goal_y)

	# let's do something minimal, create a grid with nobody
	# let's add people

	# grid[y // row][x // column]
	import random, time, os

	import dijkstra

	WIDTH = 200
	HEIGHT = 60

	def maybe_add_somebody():
	if random.random() > 0.9995:
	return [(random.randint(0, WIDTH - 1), random.randint(0, HEIGHT - 1))]
	return []


	def grid_print(grid):
	for row in grid:
	for block in row:
	# color it to make it fun !
	# limit precision too !
	l = block[0]
	c = ' '
	if l == 2:
	c = '\''
	elif l == 3:
	c = '"'
	elif l > 3:
	if l > 11: l = 11
	c = l - 2
	if len(block[1]) > 0:
	c = '\|'
	print(c, end='')
	print()

	def direct_path(grid, x, y, dest_x, dest_y):
	# compute movement to do to get to the target
	# without taking into account block resistance
	offx = 0
	if x != dest_x:
	if x > dest_x:
	offx = -1
	else:
	offx = 1

	offy = 0
	if y != dest_y:
	if y > dest_y:
	offy = -1
	else:
	offy = 1
	return offx, offy

	def move_people(grid):
	G = dijkstra.to_graph(grid)
	new_peoples = []
	for y, row in enumerate(grid):
	for x, block in enumerate(row):
	for (dest_x, dest_y) in block[1]:
	# offx, offy = direct_path(grid, x, y, dest_x, dest_y)
	offx, offy = dijkstra.faster_path(G, x, y, dest_x, dest_y)

	### if we are on the target, set new goal
	if offx == 0 and offy == 0:
	dest_x = random.randint(0, WIDTH - 1)
	dest_y = random.randint(0, HEIGHT - 1)

	### detect bad directions
	new_x = x + offx
	if new_x < 0 or new_x >= WIDTH:
	print('error: new_x=', new_x)
	new_x = x
	new_y = y + offy
	if new_y < 0 or new_y >= HEIGHT:
	print('error: new_y=', new_y)
	new_y = y

	new_peoples.append((new_x, new_y, (dest_x, dest_y)))
	block[1] = []
	for x, y, dest in new_peoples:
	try:
	grid[y][x][0] += 1
	grid[y][x][1].append(dest)
	except IndexError:
	print('error: y=', y, ' x=', x)
	import pudb;pudb.set_trace()

	grid = [ [ [
	1, maybe_add_somebody()
	] for _ in range(WIDTH)
	] for _ in range(HEIGHT)]

	step = 0
	while True:
	os.system('clear')
	print(step)
	grid_print(grid)
	move_people(grid)
	time.sleep(0.1)
	step += 1