def simulate(self, limit, hz):
# reset and restart
time = 0
self.evtQue = MinBinaryHeap(key=lambda x: x.time)
self.evtQue.push(Event(time, None, None))
map(lambda x: self.predict(x, time, limit), self.particles)
# main loop
while len(self.evtQue) > 0:
# get the nearest event
evt = self.evtQue.pop()
if not evt.isValid():
continue
# update all particles
for pa in self.particles:
pa.move(evt.time - self.time)
self.time = evt.time
# handle collision and predict the future
if evt.pa != None and evt.pb != None:
evt.pa.bounceOff(evt.pb)
self.predict(evt.pa, time, limit)
self.predict(evt.pb, time, limit)
elif evt.pa != None and evt.pb == None:
evt.pa.bounceoffVerticalWall()
self.predict(evt.pa, time, limit)
elif evt.pa == None and evt.pb != None:
evt.pb.bounceOffHorizontalWall()
self.predict(evt.pb, time, limit)
else:
self.redraw(hz)
class Collision():
def __init__(self, particles):
assert (all(isinstance(x, Particle) for x in particles))
self.particles = particles[:]
self.evtQue = None
def predict(self, pa, time, limit):
assert (pa != None and isinstance(pa, Particle))
for pb in self.particles:
if pb != pa:
dt = pa.timeToHit(pb)
if dt != None and time + dt <= limit:
self.evtQue.push(Event(time + dt, pa, pb))
dt = pa.timeToHitVerticalWall()
if time + dt <= limit:
self.evtQue.push(Event(time + dt, pa, None))
dt = pa.timeToHitHorizontalWall()
if time + dt <= limit:
self.evtQue.push(Event(time + dt, None, pa))
def simulate(self, limit, hz):
# reset and restart
time = 0
self.evtQue = MinBinaryHeap(key=lambda x: x.time)
self.evtQue.push(Event(time, None, None))
map(lambda x: self.predict(x, time, limit), self.particles)
# main loop
while len(self.evtQue) > 0:
# get the nearest event
evt = self.evtQue.pop()
if not evt.isValid():
continue
# update all particles
for pa in self.particles:
pa.move(evt.time - self.time)
self.time = evt.time
# handle collision and predict the future
if evt.pa != None and evt.pb != None:
evt.pa.bounceOff(evt.pb)
self.predict(evt.pa, time, limit)
self.predict(evt.pb, time, limit)
elif evt.pa != None and evt.pb == None:
evt.pa.bounceoffVerticalWall()
self.predict(evt.pa, time, limit)
elif evt.pa == None and evt.pb != None:
evt.pb.bounceOffHorizontalWall()
self.predict(evt.pb, time, limit)
else:
self.redraw(hz)
def redraw(self, hz):
pass
def main_Prim_2(self, grp, src=0):
# 1) initialize
vtx = [0 if i != src else 1 for i in range(len(grp))]
dis = [None if i != src else 0 for i in range(len(grp))]
pre = [None] * len(grp)
hp = MinBinaryHeap(key=lambda x: x[1])
for i, w in grp[src]:
dis[i] = w
pre[i] = src
hp.push((i, dis[i]))
# 2) build MST by greedily selecting vertexes from heap
mst = []
while len(hp) > 0:
i, w = hp.pop()
assert (dis[i] is not None and w >= dis[i])
if w > dis[i] or vtx[i] != 0:
continue
mst.append(((i, pre[i]), dis[i]))
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] is None or dis[j] > v):
dis[j] = v
pre[j] = i
hp.push((j, dis[j]))
assert (len(mst) == len(grp) - 1)
assert (sum(vtx) == len(vtx))
return mst
def main_2(grp, src):
vtx = [0] * len(grp)
dis = [None] * len(grp)
hp = MinBinaryHeap(key=lambda x: x[1])
dis[src] = 0
vtx[src] = 1
for i, w in grp[src]:
dis[i] = w
hp.push((i, dis[i]))
while len(hp) > 0:
i, w = hp.pop()
if vtx[i] == 1 or dis[i] < w:
continue
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] == None or dis[j] > v):
dis[j] = v
hp.push((j, dis[j]))
return sum(dis)
def f4(grp, src):
vtx = [0] * len(grp)
vtx[src] = 1
dis = [None] * len(grp)
dis[src] = 0
hp = MinBinaryHeap(key=lambda x: x[1])
for i, w in grp[src]:
dis[i] = w
hp.push((i, dis[i]))
ret = []
while len(hp) > 0:
i, w = hp.pop()
if vtx[i] == 1 or w > dis[i]:
continue
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] is None or dis[j] > dis[i] + v):
dis[j] = dis[i] + v
hp.push((j, dis[j]))
ret.append(w)
return sum(ret)
def main_2(grp, src):
vtx = [0] * len(grp)
dis = [None] * len(grp)
hp = MinBinaryHeap(key=lambda x: x[1])
dis[src] = 0
vtx[src] = 1
for i, w in grp[src]:
dis[i] = w
hp.push((i, dis[i]))
while len(hp) > 0:
i, w = hp.pop()
if vtx[i] == 1 or dis[i] < w:
continue
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] == None or dis[j] > v):
dis[j] = v
hp.push((j, dis[j]))
return sum(dis)
def main_Dijkstra_2(self, grp, src):
# 1) initialize
vtx = [0 if i != src else 1 for i in range(len(grp))]
dis = [None if i != src else 0 for i in range(len(grp))]
pre = [None] * len(grp)
hp = MinBinaryHeap(key=lambda x: x[1])
for i, w in grp[src]:
dis[i] = w
pre[i] = src
hp.push((i, dis[i]))
# 2) calculate by greedily selecting vertexes from heap
while len(hp) > 0:
i, w = hp.pop()
assert (dis[i] is not None and w >= dis[i])
if w > dis[i] or vtx[i] != 0:
continue
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] is None or dis[j] > dis[i] + v):
dis[j] = dis[i] + v
pre[j] = i
hp.push((j, dis[j]))
# 3) build shortest-path tree
return dis, pre
def f4(grp, src):
vtx = [0] * len(grp)
vtx[src] = 1
dis = [None] * len(grp)
dis[src] = 0
hp = MinBinaryHeap(key=lambda x: x[1])
for i, w in grp[src]:
dis[i] = w
hp.push((i, dis[i]))
ret = []
while len(hp) > 0:
i, w = hp.pop()
if vtx[i] == 1 or w > dis[i]:
continue
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] is None or dis[j] > dis[i] + v):
dis[j] = dis[i] + v
hp.push((j, dis[j]))
ret.append(w)
return sum(ret)
def main(self, chst):
assert (isinstance(chst, dict) and len(chst) > 2) # makes sense
# build Huffman tree
hp = MinBinaryHeap(map(lambda (c, f): self.__class__.Node(f, c), chst.items()), lambda x: x.key)
while len(hp) > 1:
left = hp.pop()
right = hp.pop()
node = self.__class__.Node(left.key + right.key, None, left, right)
hp.push(node)
# check tree and prepare for code generation
assert (len(hp) == 1)
node = hp.pop()
assert (node.key == sum(map(lambda x: x[1], chst.items())) and node.value is None)
node.key = None
# generate Huffman code by traversing Huffman tree
que = Queue()
que.push(node)
while len(que) > 0:
node = que.pop()
if node.value is not None:
assert (isinstance(node.key, str) and isinstance(node.value, str))
chst[node.value] = node.key
assert (node.left is None and node.right is None)
elif node.key is None: # node is root
if node.left:
node.left.key = '0'
que.push(node.left)
if node.right:
node.right.key = '1'
que.push(node.right)
else:
assert (isinstance(node.key, str))
if node.left:
node.left.key = node.key + '0'
que.push(node.left)
if node.right:
node.right.key = node.key + '1'
que.push(node.right)
return chst
def main_Dijkstra_2(self, grp, src):
# 1) initialize
vtx = [0 if i != src else 1 for i in range(len(grp))]
dis = [None if i != src else 0 for i in range(len(grp))]
pre = [None] * len(grp)
hp = MinBinaryHeap(key=lambda x: x[1])
for i, w in grp[src]:
dis[i] = w
pre[i] = src
hp.push((i, dis[i]))
# 2) calculate by greedily selecting vertexes from heap
while len(hp) > 0:
i, w = hp.pop()
assert dis[i] is not None and w >= dis[i]
if w > dis[i] or vtx[i] != 0:
continue
vtx[i] = 1
for j, v in grp[i]:
if vtx[j] == 0 and (dis[j] is None or dis[j] > dis[i] + v):
dis[j] = dis[i] + v
pre[j] = i
hp.push((j, dis[j]))
# 3) build shortest-path tree
return dis, pre
