erikerlandson/ray_pi.py

## ray_pi.py
def ray_pi(n = 1000, k = 10):
    c = SimpleRDD(range(n*k), k=k) \
        .map(lambda _: (random.uniform(-1,1), random.uniform(-1,1))) \
        .filter(lambda p: p[0]*p[0] + p[1]*p[1] <= 1) \
        .count()
    return 4 * c / (n*k)

## ray_simple_rdd.py
@ray.remote
def simple_rdd_part(data):
    return data

@ray.remote
def simple_rdd_map(f, data):
    return [f(x) for x in data]

@ray.remote
def simple_rdd_filter(f, data):
    return [x for x in data if f(x)]

@ray.remote
def simple_rdd_pmap(f, data):
    # expected to return another list
    # should be type checked, etc
    return f(data)

@ray.remote
def simple_rdd_reduce(z, f, data):
    s = z
    for x in data:
        s = f(s, x)
    return s

@ray.remote
def simple_rdd_reduce_2(f, x1, x2):
    return f(x1, x2)

@ray.remote
def simple_rdd_reduce_z(z):
    return z

class SimpleRDD:
    def __init__(self, data, k=2, partitions=None):
        if partitions is not None:
            self.nparts = len(partitions)
            self.parts = partitions
        else:
            n = len(data)
            k = max(1, min(k, n // 10))
            self.nparts = k
            s = n // k
            b = 0
            parts = []
            while b < n:
                parts.append(data[b:b+s])
                b += s
            self.parts = [simple_rdd_part.remote(p) for p in parts]

    def map(self, f):
        parts = [simple_rdd_map.remote(f, p) for p in self.parts]
        return SimpleRDD(None, partitions=parts)

    def pmap(self, f):
        parts = [simple_rdd_pmap.remote(f, p) for p in self.parts]
        return SimpleRDD(None, partitions=parts)

    def filter(self, f):
        parts = [simple_rdd_filter.remote(f, p) for p in self.parts]
        return SimpleRDD(None, partitions = parts)

    def collect(self):
        parts = ray.get(self.parts)
        data = []
        for p in parts:
            data.extend(p)
        return data

    def reduce(self, z, f):
        rparts = [simple_rdd_reduce.remote(z, f, p) for p in self.parts]
        r = simple_rdd_reduce_z.remote(z)
        for p in rparts:
            r = simple_rdd_reduce_2.remote(f, r, p)
        return ray.get(r)

    def count(self):
        return self.pmap(lambda x: [len(x)]).reduce(0, lambda x,y: x + y)
	def ray_pi(n = 1000, k = 10):
	c = SimpleRDD(range(n*k), k=k) \
	.map(lambda _: (random.uniform(-1,1), random.uniform(-1,1))) \
	.filter(lambda p: p[0]p[0] + p[1]p[1] <= 1) \
	.count()
	return 4 * c / (n*k)
	@ray.remote
	def simple_rdd_part(data):
	return data

	@ray.remote
	def simple_rdd_map(f, data):
	return [f(x) for x in data]

	@ray.remote
	def simple_rdd_filter(f, data):
	return [x for x in data if f(x)]

	@ray.remote
	def simple_rdd_pmap(f, data):
	# expected to return another list
	# should be type checked, etc
	return f(data)

	@ray.remote
	def simple_rdd_reduce(z, f, data):
	s = z
	for x in data:
	s = f(s, x)
	return s

	@ray.remote
	def simple_rdd_reduce_2(f, x1, x2):
	return f(x1, x2)

	@ray.remote
	def simple_rdd_reduce_z(z):
	return z

	class SimpleRDD:
	def __init__(self, data, k=2, partitions=None):
	if partitions is not None:
	self.nparts = len(partitions)
	self.parts = partitions
	else:
	n = len(data)
	k = max(1, min(k, n // 10))
	self.nparts = k
	s = n // k
	b = 0
	parts = []
	while b < n:
	parts.append(data[b:b+s])
	b += s
	self.parts = [simple_rdd_part.remote(p) for p in parts]

	def map(self, f):
	parts = [simple_rdd_map.remote(f, p) for p in self.parts]
	return SimpleRDD(None, partitions=parts)

	def pmap(self, f):
	parts = [simple_rdd_pmap.remote(f, p) for p in self.parts]
	return SimpleRDD(None, partitions=parts)

	def filter(self, f):
	parts = [simple_rdd_filter.remote(f, p) for p in self.parts]
	return SimpleRDD(None, partitions = parts)

	def collect(self):
	parts = ray.get(self.parts)
	data = []
	for p in parts:
	data.extend(p)
	return data

	def reduce(self, z, f):
	rparts = [simple_rdd_reduce.remote(z, f, p) for p in self.parts]
	r = simple_rdd_reduce_z.remote(z)
	for p in rparts:
	r = simple_rdd_reduce_2.remote(f, r, p)
	return ray.get(r)

	def count(self):
	return self.pmap(lambda x: [len(x)]).reduce(0, lambda x,y: x + y)