c2003ed63b
This change - implements concurrent LES request serving even for a single peer. - replaces the request cost estimation method with a cost table based on benchmarks which gives much more consistent results. Until now the allowed number of light peers was just a guess which probably contributed a lot to the fluctuating quality of available service. Everything related to request cost is implemented in a single object, the 'cost tracker'. It uses a fixed cost table with a global 'correction factor'. Benchmark code is included and can be run at any time to adapt costs to low-level implementation changes. - reimplements flowcontrol.ClientManager in a cleaner and more efficient way, with added capabilities: There is now control over bandwidth, which allows using the flow control parameters for client prioritization. Target utilization over 100 percent is now supported to model concurrent request processing. Total serving bandwidth is reduced during block processing to prevent database contention. - implements an RPC API for the LES servers allowing server operators to assign priority bandwidth to certain clients and change prioritized status even while the client is connected. The new API is meant for cases where server operators charge for LES using an off-protocol mechanism. - adds a unit test for the new client manager. - adds an end-to-end test using the network simulator that tests bandwidth control functions through the new API.
357 lines
12 KiB
Go
357 lines
12 KiB
Go
// Copyright 2016 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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// Package flowcontrol implements a client side flow control mechanism
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package flowcontrol
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import (
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"fmt"
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"sync"
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"time"
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"github.com/ethereum/go-ethereum/common/mclock"
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"github.com/ethereum/go-ethereum/log"
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)
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const (
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// fcTimeConst is the time constant applied for MinRecharge during linear
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// buffer recharge period
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fcTimeConst = time.Millisecond
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// DecParamDelay is applied at server side when decreasing capacity in order to
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// avoid a buffer underrun error due to requests sent by the client before
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// receiving the capacity update announcement
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DecParamDelay = time.Second * 2
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// keepLogs is the duration of keeping logs; logging is not used if zero
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keepLogs = 0
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)
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// ServerParams are the flow control parameters specified by a server for a client
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//
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// Note: a server can assign different amounts of capacity to each client by giving
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// different parameters to them.
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type ServerParams struct {
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BufLimit, MinRecharge uint64
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}
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// scheduledUpdate represents a delayed flow control parameter update
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type scheduledUpdate struct {
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time mclock.AbsTime
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params ServerParams
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}
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// ClientNode is the flow control system's representation of a client
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// (used in server mode only)
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type ClientNode struct {
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params ServerParams
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bufValue uint64
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lastTime mclock.AbsTime
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updateSchedule []scheduledUpdate
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sumCost uint64 // sum of req costs received from this client
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accepted map[uint64]uint64 // value = sumCost after accepting the given req
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lock sync.Mutex
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cm *ClientManager
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log *logger
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cmNodeFields
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}
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// NewClientNode returns a new ClientNode
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func NewClientNode(cm *ClientManager, params ServerParams) *ClientNode {
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node := &ClientNode{
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cm: cm,
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params: params,
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bufValue: params.BufLimit,
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lastTime: cm.clock.Now(),
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accepted: make(map[uint64]uint64),
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}
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if keepLogs > 0 {
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node.log = newLogger(keepLogs)
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}
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cm.connect(node)
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return node
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}
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// Disconnect should be called when a client is disconnected
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func (node *ClientNode) Disconnect() {
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node.cm.disconnect(node)
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}
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// update recalculates the buffer value at a specified time while also performing
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// scheduled flow control parameter updates if necessary
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func (node *ClientNode) update(now mclock.AbsTime) {
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for len(node.updateSchedule) > 0 && node.updateSchedule[0].time <= now {
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node.recalcBV(node.updateSchedule[0].time)
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node.updateParams(node.updateSchedule[0].params, now)
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node.updateSchedule = node.updateSchedule[1:]
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}
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node.recalcBV(now)
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}
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// recalcBV recalculates the buffer value at a specified time
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func (node *ClientNode) recalcBV(now mclock.AbsTime) {
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dt := uint64(now - node.lastTime)
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if now < node.lastTime {
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dt = 0
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}
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node.bufValue += node.params.MinRecharge * dt / uint64(fcTimeConst)
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if node.bufValue > node.params.BufLimit {
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node.bufValue = node.params.BufLimit
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}
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("updated bv=%d MRR=%d BufLimit=%d", node.bufValue, node.params.MinRecharge, node.params.BufLimit))
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}
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node.lastTime = now
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}
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// UpdateParams updates the flow control parameters of a client node
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func (node *ClientNode) UpdateParams(params ServerParams) {
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node.lock.Lock()
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defer node.lock.Unlock()
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now := node.cm.clock.Now()
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node.update(now)
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if params.MinRecharge >= node.params.MinRecharge {
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node.updateSchedule = nil
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node.updateParams(params, now)
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} else {
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for i, s := range node.updateSchedule {
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if params.MinRecharge >= s.params.MinRecharge {
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s.params = params
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node.updateSchedule = node.updateSchedule[:i+1]
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return
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}
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}
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node.updateSchedule = append(node.updateSchedule, scheduledUpdate{time: now + mclock.AbsTime(DecParamDelay), params: params})
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}
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}
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// updateParams updates the flow control parameters of the node
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func (node *ClientNode) updateParams(params ServerParams, now mclock.AbsTime) {
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diff := params.BufLimit - node.params.BufLimit
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if int64(diff) > 0 {
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node.bufValue += diff
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} else if node.bufValue > params.BufLimit {
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node.bufValue = params.BufLimit
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}
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node.cm.updateParams(node, params, now)
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}
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// AcceptRequest returns whether a new request can be accepted and the missing
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// buffer amount if it was rejected due to a buffer underrun. If accepted, maxCost
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// is deducted from the flow control buffer.
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func (node *ClientNode) AcceptRequest(reqID, index, maxCost uint64) (accepted bool, bufShort uint64, priority int64) {
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node.lock.Lock()
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defer node.lock.Unlock()
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now := node.cm.clock.Now()
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node.update(now)
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if maxCost > node.bufValue {
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("rejected reqID=%d bv=%d maxCost=%d", reqID, node.bufValue, maxCost))
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node.log.dump(now)
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}
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return false, maxCost - node.bufValue, 0
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}
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node.bufValue -= maxCost
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node.sumCost += maxCost
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("accepted reqID=%d bv=%d maxCost=%d sumCost=%d", reqID, node.bufValue, maxCost, node.sumCost))
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}
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node.accepted[index] = node.sumCost
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return true, 0, node.cm.accepted(node, maxCost, now)
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}
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// RequestProcessed should be called when the request has been processed
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func (node *ClientNode) RequestProcessed(reqID, index, maxCost, realCost uint64) (bv uint64) {
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node.lock.Lock()
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defer node.lock.Unlock()
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now := node.cm.clock.Now()
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node.update(now)
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node.cm.processed(node, maxCost, realCost, now)
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bv = node.bufValue + node.sumCost - node.accepted[index]
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("processed reqID=%d bv=%d maxCost=%d realCost=%d sumCost=%d oldSumCost=%d reportedBV=%d", reqID, node.bufValue, maxCost, realCost, node.sumCost, node.accepted[index], bv))
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}
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delete(node.accepted, index)
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return
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}
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// ServerNode is the flow control system's representation of a server
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// (used in client mode only)
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type ServerNode struct {
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clock mclock.Clock
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bufEstimate uint64
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bufRecharge bool
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lastTime mclock.AbsTime
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params ServerParams
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sumCost uint64 // sum of req costs sent to this server
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pending map[uint64]uint64 // value = sumCost after sending the given req
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log *logger
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lock sync.RWMutex
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}
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// NewServerNode returns a new ServerNode
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func NewServerNode(params ServerParams, clock mclock.Clock) *ServerNode {
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node := &ServerNode{
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clock: clock,
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bufEstimate: params.BufLimit,
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bufRecharge: false,
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lastTime: clock.Now(),
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params: params,
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pending: make(map[uint64]uint64),
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}
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if keepLogs > 0 {
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node.log = newLogger(keepLogs)
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}
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return node
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}
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// UpdateParams updates the flow control parameters of the node
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func (node *ServerNode) UpdateParams(params ServerParams) {
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node.lock.Lock()
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defer node.lock.Unlock()
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node.recalcBLE(mclock.Now())
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if params.BufLimit > node.params.BufLimit {
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node.bufEstimate += params.BufLimit - node.params.BufLimit
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} else {
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if node.bufEstimate > params.BufLimit {
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node.bufEstimate = params.BufLimit
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}
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}
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node.params = params
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}
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// recalcBLE recalculates the lowest estimate for the client's buffer value at
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// the given server at the specified time
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func (node *ServerNode) recalcBLE(now mclock.AbsTime) {
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if now < node.lastTime {
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return
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}
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if node.bufRecharge {
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dt := uint64(now - node.lastTime)
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node.bufEstimate += node.params.MinRecharge * dt / uint64(fcTimeConst)
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if node.bufEstimate >= node.params.BufLimit {
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node.bufEstimate = node.params.BufLimit
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node.bufRecharge = false
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}
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}
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node.lastTime = now
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("updated bufEst=%d MRR=%d BufLimit=%d", node.bufEstimate, node.params.MinRecharge, node.params.BufLimit))
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}
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}
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// safetyMargin is added to the flow control waiting time when estimated buffer value is low
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const safetyMargin = time.Millisecond
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// CanSend returns the minimum waiting time required before sending a request
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// with the given maximum estimated cost. Second return value is the relative
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// estimated buffer level after sending the request (divided by BufLimit).
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func (node *ServerNode) CanSend(maxCost uint64) (time.Duration, float64) {
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node.lock.RLock()
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defer node.lock.RUnlock()
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now := node.clock.Now()
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node.recalcBLE(now)
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maxCost += uint64(safetyMargin) * node.params.MinRecharge / uint64(fcTimeConst)
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if maxCost > node.params.BufLimit {
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maxCost = node.params.BufLimit
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}
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if node.bufEstimate >= maxCost {
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relBuf := float64(node.bufEstimate-maxCost) / float64(node.params.BufLimit)
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("canSend bufEst=%d maxCost=%d true relBuf=%f", node.bufEstimate, maxCost, relBuf))
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}
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return 0, relBuf
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}
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timeLeft := time.Duration((maxCost - node.bufEstimate) * uint64(fcTimeConst) / node.params.MinRecharge)
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("canSend bufEst=%d maxCost=%d false timeLeft=%v", node.bufEstimate, maxCost, timeLeft))
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}
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return timeLeft, 0
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}
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// QueuedRequest should be called when the request has been assigned to the given
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// server node, before putting it in the send queue. It is mandatory that requests
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// are sent in the same order as the QueuedRequest calls are made.
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func (node *ServerNode) QueuedRequest(reqID, maxCost uint64) {
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node.lock.Lock()
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defer node.lock.Unlock()
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now := node.clock.Now()
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node.recalcBLE(now)
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// Note: we do not know when requests actually arrive to the server so bufRecharge
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// is not turned on here if buffer was full; in this case it is going to be turned
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// on by the first reply's bufValue feedback
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if node.bufEstimate >= maxCost {
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node.bufEstimate -= maxCost
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} else {
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log.Error("Queued request with insufficient buffer estimate")
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node.bufEstimate = 0
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}
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node.sumCost += maxCost
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node.pending[reqID] = node.sumCost
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("queued reqID=%d bufEst=%d maxCost=%d sumCost=%d", reqID, node.bufEstimate, maxCost, node.sumCost))
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}
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}
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// ReceivedReply adjusts estimated buffer value according to the value included in
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// the latest request reply.
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func (node *ServerNode) ReceivedReply(reqID, bv uint64) {
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node.lock.Lock()
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defer node.lock.Unlock()
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now := node.clock.Now()
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node.recalcBLE(now)
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if bv > node.params.BufLimit {
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bv = node.params.BufLimit
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}
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sc, ok := node.pending[reqID]
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if !ok {
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return
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}
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delete(node.pending, reqID)
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cc := node.sumCost - sc
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newEstimate := uint64(0)
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if bv > cc {
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newEstimate = bv - cc
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}
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if newEstimate > node.bufEstimate {
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// Note: we never reduce the buffer estimate based on the reported value because
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// this can only happen because of the delayed delivery of the latest reply.
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// The lowest estimate based on the previous reply can still be considered valid.
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node.bufEstimate = newEstimate
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}
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node.bufRecharge = node.bufEstimate < node.params.BufLimit
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node.lastTime = now
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("received reqID=%d bufEst=%d reportedBv=%d sumCost=%d oldSumCost=%d", reqID, node.bufEstimate, bv, node.sumCost, sc))
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}
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}
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// DumpLogs dumps the event log if logging is used
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func (node *ServerNode) DumpLogs() {
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node.lock.Lock()
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defer node.lock.Unlock()
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if node.log != nil {
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node.log.dump(node.clock.Now())
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}
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}
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