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# -*- test-case-name: twisted.test.test_htb -*-
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.
"""
Hierarchical Token Bucket traffic shaping.
Patterned after U{Martin Devera's Hierarchical Token Bucket traffic
shaper for the Linux kernel<http://luxik.cdi.cz/~devik/qos/htb/>}.
@seealso: U{HTB Linux queuing discipline manual - user guide
<http://luxik.cdi.cz/~devik/qos/htb/manual/userg.htm>}
@seealso: U{Token Bucket Filter in Linux Advanced Routing & Traffic Control
HOWTO<http://lartc.org/howto/lartc.qdisc.classless.html#AEN682>}
"""
# TODO: Investigate whether we should be using os.times()[-1] instead of
# time.time. time.time, it has been pointed out, can go backwards. Is
# the same true of os.times?
from time import time
from typing import Optional
from zope.interface import Interface, implementer
from twisted.protocols import pcp
class Bucket:
"""
Implementation of a Token bucket.
A bucket can hold a certain number of tokens and it drains over time.
@cvar maxburst: The maximum number of tokens that the bucket can
hold at any given time. If this is L{None}, the bucket has
an infinite size.
@type maxburst: C{int}
@cvar rate: The rate at which the bucket drains, in number
of tokens per second. If the rate is L{None}, the bucket
drains instantaneously.
@type rate: C{int}
"""
maxburst: Optional[int] = None
rate: Optional[int] = None
_refcount = 0
def __init__(self, parentBucket=None):
"""
Create a L{Bucket} that may have a parent L{Bucket}.
@param parentBucket: If a parent Bucket is specified,
all L{add} and L{drip} operations on this L{Bucket}
will be applied on the parent L{Bucket} as well.
@type parentBucket: L{Bucket}
"""
self.content = 0
self.parentBucket = parentBucket
self.lastDrip = time()
def add(self, amount):
"""
Adds tokens to the L{Bucket} and its C{parentBucket}.
This will add as many of the C{amount} tokens as will fit into both
this L{Bucket} and its C{parentBucket}.
@param amount: The number of tokens to try to add.
@type amount: C{int}
@returns: The number of tokens that actually fit.
@returntype: C{int}
"""
self.drip()
if self.maxburst is None:
allowable = amount
else:
allowable = min(amount, self.maxburst - self.content)
if self.parentBucket is not None:
allowable = self.parentBucket.add(allowable)
self.content += allowable
return allowable
def drip(self):
"""
Let some of the bucket drain.
The L{Bucket} drains at the rate specified by the class
variable C{rate}.
@returns: C{True} if the bucket is empty after this drip.
@returntype: C{bool}
"""
if self.parentBucket is not None:
self.parentBucket.drip()
if self.rate is None:
self.content = 0
else:
now = time()
deltaTime = now - self.lastDrip
deltaTokens = deltaTime * self.rate
self.content = max(0, self.content - deltaTokens)
self.lastDrip = now
return self.content == 0
class IBucketFilter(Interface):
def getBucketFor(*somethings, **some_kw):
"""
Return a L{Bucket} corresponding to the provided parameters.
@returntype: L{Bucket}
"""
@implementer(IBucketFilter)
class HierarchicalBucketFilter:
"""
Filter things into buckets that can be nested.
@cvar bucketFactory: Class of buckets to make.
@type bucketFactory: L{Bucket}
@cvar sweepInterval: Seconds between sweeping out the bucket cache.
@type sweepInterval: C{int}
"""
bucketFactory = Bucket
sweepInterval: Optional[int] = None
def __init__(self, parentFilter=None):
self.buckets = {}
self.parentFilter = parentFilter
self.lastSweep = time()
def getBucketFor(self, *a, **kw):
"""
Find or create a L{Bucket} corresponding to the provided parameters.
Any parameters are passed on to L{getBucketKey}, from them it
decides which bucket you get.
@returntype: L{Bucket}
"""
if (self.sweepInterval is not None) and (
(time() - self.lastSweep) > self.sweepInterval
):
self.sweep()
if self.parentFilter:
parentBucket = self.parentFilter.getBucketFor(self, *a, **kw)
else:
parentBucket = None
key = self.getBucketKey(*a, **kw)
bucket = self.buckets.get(key)
if bucket is None:
bucket = self.bucketFactory(parentBucket)
self.buckets[key] = bucket
return bucket
def getBucketKey(self, *a, **kw):
"""
Construct a key based on the input parameters to choose a L{Bucket}.
The default implementation returns the same key for all
arguments. Override this method to provide L{Bucket} selection.
@returns: Something to be used as a key in the bucket cache.
"""
return None
def sweep(self):
"""
Remove empty buckets.
"""
for key, bucket in self.buckets.items():
bucket_is_empty = bucket.drip()
if (bucket._refcount == 0) and bucket_is_empty:
del self.buckets[key]
self.lastSweep = time()
class FilterByHost(HierarchicalBucketFilter):
"""
A Hierarchical Bucket filter with a L{Bucket} for each host.
"""
sweepInterval = 60 * 20
def getBucketKey(self, transport):
return transport.getPeer()[1]
class FilterByServer(HierarchicalBucketFilter):
"""
A Hierarchical Bucket filter with a L{Bucket} for each service.
"""
sweepInterval = None
def getBucketKey(self, transport):
return transport.getHost()[2]
class ShapedConsumer(pcp.ProducerConsumerProxy):
"""
Wraps a C{Consumer} and shapes the rate at which it receives data.
"""
# Providing a Pull interface means I don't have to try to schedule
# traffic with callLaters.
iAmStreaming = False
def __init__(self, consumer, bucket):
pcp.ProducerConsumerProxy.__init__(self, consumer)
self.bucket = bucket
self.bucket._refcount += 1
def _writeSomeData(self, data):
# In practice, this actually results in obscene amounts of
# overhead, as a result of generating lots and lots of packets
# with twelve-byte payloads. We may need to do a version of
# this with scheduled writes after all.
amount = self.bucket.add(len(data))
return pcp.ProducerConsumerProxy._writeSomeData(self, data[:amount])
def stopProducing(self):
pcp.ProducerConsumerProxy.stopProducing(self)
self.bucket._refcount -= 1
class ShapedTransport(ShapedConsumer):
"""
Wraps a C{Transport} and shapes the rate at which it receives data.
This is a L{ShapedConsumer} with a little bit of magic to provide for
the case where the consumer it wraps is also a C{Transport} and people
will be attempting to access attributes this does not proxy as a
C{Consumer} (e.g. C{loseConnection}).
"""
# Ugh. We only wanted to filter IConsumer, not ITransport.
iAmStreaming = False
def __getattr__(self, name):
# Because people will be doing things like .getPeer and
# .loseConnection on me.
return getattr(self.consumer, name)
class ShapedProtocolFactory:
"""
Dispense C{Protocols} with traffic shaping on their transports.
Usage::
myserver = SomeFactory()
myserver.protocol = ShapedProtocolFactory(myserver.protocol,
bucketFilter)
Where C{SomeServerFactory} is a L{twisted.internet.protocol.Factory}, and
C{bucketFilter} is an instance of L{HierarchicalBucketFilter}.
"""
def __init__(self, protoClass, bucketFilter):
"""
Tell me what to wrap and where to get buckets.
@param protoClass: The class of C{Protocol} this will generate
wrapped instances of.
@type protoClass: L{Protocol<twisted.internet.interfaces.IProtocol>}
class
@param bucketFilter: The filter which will determine how
traffic is shaped.
@type bucketFilter: L{HierarchicalBucketFilter}.
"""
# More precisely, protoClass can be any callable that will return
# instances of something that implements IProtocol.
self.protocol = protoClass
self.bucketFilter = bucketFilter
def __call__(self, *a, **kw):
"""
Make a C{Protocol} instance with a shaped transport.
Any parameters will be passed on to the protocol's initializer.
@returns: A C{Protocol} instance with a L{ShapedTransport}.
"""
proto = self.protocol(*a, **kw)
origMakeConnection = proto.makeConnection
def makeConnection(transport):
bucket = self.bucketFilter.getBucketFor(transport)
shapedTransport = ShapedTransport(transport, bucket)
return origMakeConnection(shapedTransport)
proto.makeConnection = makeConnection
return proto
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