go-ethereum/les/flowcontrol/control.go
Felföldi Zsolt 58497f46bd
les, les/flowcontrol: implement LES/3 (#19329)
les, les/flowcontrol: implement LES/3
2019-05-30 20:51:13 +02:00

430 lines
14 KiB
Go

// Copyright 2016 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
// Package flowcontrol implements a client side flow control mechanism
package flowcontrol
import (
"fmt"
"sync"
"time"
"github.com/ethereum/go-ethereum/common/mclock"
"github.com/ethereum/go-ethereum/log"
)
const (
// fcTimeConst is the time constant applied for MinRecharge during linear
// buffer recharge period
fcTimeConst = time.Millisecond
// DecParamDelay is applied at server side when decreasing capacity in order to
// avoid a buffer underrun error due to requests sent by the client before
// receiving the capacity update announcement
DecParamDelay = time.Second * 2
// keepLogs is the duration of keeping logs; logging is not used if zero
keepLogs = 0
)
// ServerParams are the flow control parameters specified by a server for a client
//
// Note: a server can assign different amounts of capacity to each client by giving
// different parameters to them.
type ServerParams struct {
BufLimit, MinRecharge uint64
}
// scheduledUpdate represents a delayed flow control parameter update
type scheduledUpdate struct {
time mclock.AbsTime
params ServerParams
}
// ClientNode is the flow control system's representation of a client
// (used in server mode only)
type ClientNode struct {
params ServerParams
bufValue int64
lastTime mclock.AbsTime
updateSchedule []scheduledUpdate
sumCost uint64 // sum of req costs received from this client
accepted map[uint64]uint64 // value = sumCost after accepting the given req
connected bool
lock sync.Mutex
cm *ClientManager
log *logger
cmNodeFields
}
// NewClientNode returns a new ClientNode
func NewClientNode(cm *ClientManager, params ServerParams) *ClientNode {
node := &ClientNode{
cm: cm,
params: params,
bufValue: int64(params.BufLimit),
lastTime: cm.clock.Now(),
accepted: make(map[uint64]uint64),
connected: true,
}
if keepLogs > 0 {
node.log = newLogger(keepLogs)
}
cm.connect(node)
return node
}
// Disconnect should be called when a client is disconnected
func (node *ClientNode) Disconnect() {
node.lock.Lock()
defer node.lock.Unlock()
node.connected = false
node.cm.disconnect(node)
}
// BufferStatus returns the current buffer value and limit
func (node *ClientNode) BufferStatus() (uint64, uint64) {
node.lock.Lock()
defer node.lock.Unlock()
if !node.connected {
return 0, 0
}
now := node.cm.clock.Now()
node.update(now)
node.cm.updateBuffer(node, 0, now)
bv := node.bufValue
if bv < 0 {
bv = 0
}
return uint64(bv), node.params.BufLimit
}
// OneTimeCost subtracts the given amount from the node's buffer.
//
// Note: this call can take the buffer into the negative region internally.
// In this case zero buffer value is returned by exported calls and no requests
// are accepted.
func (node *ClientNode) OneTimeCost(cost uint64) {
node.lock.Lock()
defer node.lock.Unlock()
now := node.cm.clock.Now()
node.update(now)
node.bufValue -= int64(cost)
node.cm.updateBuffer(node, -int64(cost), now)
}
// Freeze notifies the client manager about a client freeze event in which case
// the total capacity allowance is slightly reduced.
func (node *ClientNode) Freeze() {
node.lock.Lock()
frozenCap := node.params.MinRecharge
node.lock.Unlock()
node.cm.reduceTotalCapacity(frozenCap)
}
// update recalculates the buffer value at a specified time while also performing
// scheduled flow control parameter updates if necessary
func (node *ClientNode) update(now mclock.AbsTime) {
for len(node.updateSchedule) > 0 && node.updateSchedule[0].time <= now {
node.recalcBV(node.updateSchedule[0].time)
node.updateParams(node.updateSchedule[0].params, now)
node.updateSchedule = node.updateSchedule[1:]
}
node.recalcBV(now)
}
// recalcBV recalculates the buffer value at a specified time
func (node *ClientNode) recalcBV(now mclock.AbsTime) {
dt := uint64(now - node.lastTime)
if now < node.lastTime {
dt = 0
}
node.bufValue += int64(node.params.MinRecharge * dt / uint64(fcTimeConst))
if node.bufValue > int64(node.params.BufLimit) {
node.bufValue = int64(node.params.BufLimit)
}
if node.log != nil {
node.log.add(now, fmt.Sprintf("updated bv=%d MRR=%d BufLimit=%d", node.bufValue, node.params.MinRecharge, node.params.BufLimit))
}
node.lastTime = now
}
// UpdateParams updates the flow control parameters of a client node
func (node *ClientNode) UpdateParams(params ServerParams) {
node.lock.Lock()
defer node.lock.Unlock()
now := node.cm.clock.Now()
node.update(now)
if params.MinRecharge >= node.params.MinRecharge {
node.updateSchedule = nil
node.updateParams(params, now)
} else {
for i, s := range node.updateSchedule {
if params.MinRecharge >= s.params.MinRecharge {
s.params = params
node.updateSchedule = node.updateSchedule[:i+1]
return
}
}
node.updateSchedule = append(node.updateSchedule, scheduledUpdate{time: now + mclock.AbsTime(DecParamDelay), params: params})
}
}
// updateParams updates the flow control parameters of the node
func (node *ClientNode) updateParams(params ServerParams, now mclock.AbsTime) {
diff := int64(params.BufLimit - node.params.BufLimit)
if diff > 0 {
node.bufValue += diff
} else if node.bufValue > int64(params.BufLimit) {
node.bufValue = int64(params.BufLimit)
}
node.cm.updateParams(node, params, now)
}
// AcceptRequest returns whether a new request can be accepted and the missing
// buffer amount if it was rejected due to a buffer underrun. If accepted, maxCost
// is deducted from the flow control buffer.
func (node *ClientNode) AcceptRequest(reqID, index, maxCost uint64) (accepted bool, bufShort uint64, priority int64) {
node.lock.Lock()
defer node.lock.Unlock()
now := node.cm.clock.Now()
node.update(now)
if int64(maxCost) > node.bufValue {
if node.log != nil {
node.log.add(now, fmt.Sprintf("rejected reqID=%d bv=%d maxCost=%d", reqID, node.bufValue, maxCost))
node.log.dump(now)
}
return false, maxCost - uint64(node.bufValue), 0
}
node.bufValue -= int64(maxCost)
node.sumCost += maxCost
if node.log != nil {
node.log.add(now, fmt.Sprintf("accepted reqID=%d bv=%d maxCost=%d sumCost=%d", reqID, node.bufValue, maxCost, node.sumCost))
}
node.accepted[index] = node.sumCost
return true, 0, node.cm.accepted(node, maxCost, now)
}
// RequestProcessed should be called when the request has been processed
func (node *ClientNode) RequestProcessed(reqID, index, maxCost, realCost uint64) uint64 {
node.lock.Lock()
defer node.lock.Unlock()
now := node.cm.clock.Now()
node.update(now)
node.cm.processed(node, maxCost, realCost, now)
bv := node.bufValue + int64(node.sumCost-node.accepted[index])
if node.log != nil {
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))
}
delete(node.accepted, index)
if bv < 0 {
return 0
}
return uint64(bv)
}
// ServerNode is the flow control system's representation of a server
// (used in client mode only)
type ServerNode struct {
clock mclock.Clock
bufEstimate uint64
bufRecharge bool
lastTime mclock.AbsTime
params ServerParams
sumCost uint64 // sum of req costs sent to this server
pending map[uint64]uint64 // value = sumCost after sending the given req
log *logger
lock sync.RWMutex
}
// NewServerNode returns a new ServerNode
func NewServerNode(params ServerParams, clock mclock.Clock) *ServerNode {
node := &ServerNode{
clock: clock,
bufEstimate: params.BufLimit,
bufRecharge: false,
lastTime: clock.Now(),
params: params,
pending: make(map[uint64]uint64),
}
if keepLogs > 0 {
node.log = newLogger(keepLogs)
}
return node
}
// UpdateParams updates the flow control parameters of the node
func (node *ServerNode) UpdateParams(params ServerParams) {
node.lock.Lock()
defer node.lock.Unlock()
node.recalcBLE(mclock.Now())
if params.BufLimit > node.params.BufLimit {
node.bufEstimate += params.BufLimit - node.params.BufLimit
} else {
if node.bufEstimate > params.BufLimit {
node.bufEstimate = params.BufLimit
}
}
node.params = params
}
// recalcBLE recalculates the lowest estimate for the client's buffer value at
// the given server at the specified time
func (node *ServerNode) recalcBLE(now mclock.AbsTime) {
if now < node.lastTime {
return
}
if node.bufRecharge {
dt := uint64(now - node.lastTime)
node.bufEstimate += node.params.MinRecharge * dt / uint64(fcTimeConst)
if node.bufEstimate >= node.params.BufLimit {
node.bufEstimate = node.params.BufLimit
node.bufRecharge = false
}
}
node.lastTime = now
if node.log != nil {
node.log.add(now, fmt.Sprintf("updated bufEst=%d MRR=%d BufLimit=%d", node.bufEstimate, node.params.MinRecharge, node.params.BufLimit))
}
}
// safetyMargin is added to the flow control waiting time when estimated buffer value is low
const safetyMargin = time.Millisecond
// CanSend returns the minimum waiting time required before sending a request
// with the given maximum estimated cost. Second return value is the relative
// estimated buffer level after sending the request (divided by BufLimit).
func (node *ServerNode) CanSend(maxCost uint64) (time.Duration, float64) {
node.lock.RLock()
defer node.lock.RUnlock()
now := node.clock.Now()
node.recalcBLE(now)
maxCost += uint64(safetyMargin) * node.params.MinRecharge / uint64(fcTimeConst)
if maxCost > node.params.BufLimit {
maxCost = node.params.BufLimit
}
if node.bufEstimate >= maxCost {
relBuf := float64(node.bufEstimate-maxCost) / float64(node.params.BufLimit)
if node.log != nil {
node.log.add(now, fmt.Sprintf("canSend bufEst=%d maxCost=%d true relBuf=%f", node.bufEstimate, maxCost, relBuf))
}
return 0, relBuf
}
timeLeft := time.Duration((maxCost - node.bufEstimate) * uint64(fcTimeConst) / node.params.MinRecharge)
if node.log != nil {
node.log.add(now, fmt.Sprintf("canSend bufEst=%d maxCost=%d false timeLeft=%v", node.bufEstimate, maxCost, timeLeft))
}
return timeLeft, 0
}
// QueuedRequest should be called when the request has been assigned to the given
// server node, before putting it in the send queue. It is mandatory that requests
// are sent in the same order as the QueuedRequest calls are made.
func (node *ServerNode) QueuedRequest(reqID, maxCost uint64) {
node.lock.Lock()
defer node.lock.Unlock()
now := node.clock.Now()
node.recalcBLE(now)
// Note: we do not know when requests actually arrive to the server so bufRecharge
// is not turned on here if buffer was full; in this case it is going to be turned
// on by the first reply's bufValue feedback
if node.bufEstimate >= maxCost {
node.bufEstimate -= maxCost
} else {
log.Error("Queued request with insufficient buffer estimate")
node.bufEstimate = 0
}
node.sumCost += maxCost
node.pending[reqID] = node.sumCost
if node.log != nil {
node.log.add(now, fmt.Sprintf("queued reqID=%d bufEst=%d maxCost=%d sumCost=%d", reqID, node.bufEstimate, maxCost, node.sumCost))
}
}
// ReceivedReply adjusts estimated buffer value according to the value included in
// the latest request reply.
func (node *ServerNode) ReceivedReply(reqID, bv uint64) {
node.lock.Lock()
defer node.lock.Unlock()
now := node.clock.Now()
node.recalcBLE(now)
if bv > node.params.BufLimit {
bv = node.params.BufLimit
}
sc, ok := node.pending[reqID]
if !ok {
return
}
delete(node.pending, reqID)
cc := node.sumCost - sc
newEstimate := uint64(0)
if bv > cc {
newEstimate = bv - cc
}
if newEstimate > node.bufEstimate {
// Note: we never reduce the buffer estimate based on the reported value because
// this can only happen because of the delayed delivery of the latest reply.
// The lowest estimate based on the previous reply can still be considered valid.
node.bufEstimate = newEstimate
}
node.bufRecharge = node.bufEstimate < node.params.BufLimit
node.lastTime = now
if node.log != nil {
node.log.add(now, fmt.Sprintf("received reqID=%d bufEst=%d reportedBv=%d sumCost=%d oldSumCost=%d", reqID, node.bufEstimate, bv, node.sumCost, sc))
}
}
// ResumeFreeze cleans all pending requests and sets the buffer estimate to the
// reported value after resuming from a frozen state
func (node *ServerNode) ResumeFreeze(bv uint64) {
node.lock.Lock()
defer node.lock.Unlock()
for reqID := range node.pending {
delete(node.pending, reqID)
}
now := node.clock.Now()
node.recalcBLE(now)
if bv > node.params.BufLimit {
bv = node.params.BufLimit
}
node.bufEstimate = bv
node.bufRecharge = node.bufEstimate < node.params.BufLimit
node.lastTime = now
if node.log != nil {
node.log.add(now, fmt.Sprintf("unfreeze bv=%d sumCost=%d", bv, node.sumCost))
}
}
// DumpLogs dumps the event log if logging is used
func (node *ServerNode) DumpLogs() {
node.lock.Lock()
defer node.lock.Unlock()
if node.log != nil {
node.log.dump(node.clock.Now())
}
}