forked from cerc-io/plugeth
2c5648d891
* Fix some typos * Fix some mistakes * Revert 4byte.json * Fix an incorrect fix * Change files to fails
462 lines
16 KiB
Go
462 lines
16 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
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import (
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"fmt"
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"math"
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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/common/prque"
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)
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// cmNodeFields are ClientNode fields used by the client manager
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// Note: these fields are locked by the client manager's mutex
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type cmNodeFields struct {
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corrBufValue int64 // buffer value adjusted with the extra recharge amount
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rcLastIntValue int64 // past recharge integrator value when corrBufValue was last updated
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rcFullIntValue int64 // future recharge integrator value when corrBufValue will reach maximum
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queueIndex int // position in the recharge queue (-1 if not queued)
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}
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// FixedPointMultiplier is applied to the recharge integrator and the recharge curve.
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//
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// Note: fixed point arithmetic is required for the integrator because it is a
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// constantly increasing value that can wrap around int64 limits (which behavior is
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// also supported by the priority queue). A floating point value would gradually lose
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// precision in this application.
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// The recharge curve and all recharge values are encoded as fixed point because
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// sumRecharge is frequently updated by adding or subtracting individual recharge
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// values and perfect precision is required.
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const FixedPointMultiplier = 1000000
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var (
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capacityDropFactor = 0.1
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capacityRaiseTC = 1 / (3 * float64(time.Hour)) // time constant for raising the capacity factor
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capacityRaiseThresholdRatio = 1.125 // total/connected capacity ratio threshold for raising the capacity factor
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)
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// ClientManager controls the capacity assigned to the clients of a server.
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// Since ServerParams guarantee a safe lower estimate for processable requests
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// even in case of all clients being active, ClientManager calculates a
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// corrugated buffer value and usually allows a higher remaining buffer value
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// to be returned with each reply.
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type ClientManager struct {
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clock mclock.Clock
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lock sync.Mutex
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stop chan chan struct{}
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curve PieceWiseLinear
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sumRecharge, totalRecharge, totalConnected uint64
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logTotalCap, totalCapacity float64
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logTotalCapRaiseLimit float64
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minLogTotalCap, maxLogTotalCap float64
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capacityRaiseThreshold uint64
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capLastUpdate mclock.AbsTime
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totalCapacityCh chan uint64
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// recharge integrator is increasing in each moment with a rate of
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// (totalRecharge / sumRecharge)*FixedPointMultiplier or 0 if sumRecharge==0
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rcLastUpdate mclock.AbsTime // last time the recharge integrator was updated
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rcLastIntValue int64 // last updated value of the recharge integrator
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// recharge queue is a priority queue with currently recharging client nodes
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// as elements. The priority value is rcFullIntValue which allows to quickly
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// determine which client will first finish recharge.
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rcQueue *prque.Prque
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}
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// NewClientManager returns a new client manager.
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// Client manager enhances flow control performance by allowing client buffers
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// to recharge quicker than the minimum guaranteed recharge rate if possible.
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// The sum of all minimum recharge rates (sumRecharge) is updated each time
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// a clients starts or finishes buffer recharging. Then an adjusted total
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// recharge rate is calculated using a piecewise linear recharge curve:
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//
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// totalRecharge = curve(sumRecharge)
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// (totalRecharge >= sumRecharge is enforced)
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//
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// Then the "bonus" buffer recharge is distributed between currently recharging
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// clients proportionally to their minimum recharge rates.
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//
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// Note: total recharge is proportional to the average number of parallel running
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// serving threads. A recharge value of 1000000 corresponds to one thread in average.
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// The maximum number of allowed serving threads should always be considerably
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// higher than the targeted average number.
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//
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// Note 2: although it is possible to specify a curve allowing the total target
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// recharge starting from zero sumRecharge, it makes sense to add a linear ramp
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// starting from zero in order to not let a single low-priority client use up
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// the entire server capacity and thus ensure quick availability for others at
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// any moment.
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func NewClientManager(curve PieceWiseLinear, clock mclock.Clock) *ClientManager {
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cm := &ClientManager{
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clock: clock,
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rcQueue: prque.NewWrapAround(func(a interface{}, i int) { a.(*ClientNode).queueIndex = i }),
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capLastUpdate: clock.Now(),
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stop: make(chan chan struct{}),
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}
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if curve != nil {
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cm.SetRechargeCurve(curve)
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}
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go func() {
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// regularly recalculate and update total capacity
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for {
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select {
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case <-time.After(time.Minute):
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cm.lock.Lock()
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cm.updateTotalCapacity(cm.clock.Now(), true)
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cm.lock.Unlock()
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case stop := <-cm.stop:
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close(stop)
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return
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}
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}
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}()
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return cm
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}
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// Stop stops the client manager
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func (cm *ClientManager) Stop() {
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stop := make(chan struct{})
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cm.stop <- stop
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<-stop
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}
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// SetRechargeCurve updates the recharge curve
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func (cm *ClientManager) SetRechargeCurve(curve PieceWiseLinear) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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now := cm.clock.Now()
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cm.updateRecharge(now)
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cm.curve = curve
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if len(curve) > 0 {
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cm.totalRecharge = curve[len(curve)-1].Y
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} else {
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cm.totalRecharge = 0
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}
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}
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// SetCapacityRaiseThreshold sets a threshold value used for raising capFactor.
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// Either if the difference between total allowed and connected capacity is less
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// than this threshold or if their ratio is less than capacityRaiseThresholdRatio
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// then capFactor is allowed to slowly raise.
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func (cm *ClientManager) SetCapacityLimits(min, max, raiseThreshold uint64) {
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if min < 1 {
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min = 1
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}
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cm.minLogTotalCap = math.Log(float64(min))
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if max < 1 {
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max = 1
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}
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cm.maxLogTotalCap = math.Log(float64(max))
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cm.logTotalCap = cm.maxLogTotalCap
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cm.capacityRaiseThreshold = raiseThreshold
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cm.refreshCapacity()
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}
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// connect should be called when a client is connected, before passing it to any
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// other ClientManager function
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func (cm *ClientManager) connect(node *ClientNode) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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now := cm.clock.Now()
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cm.updateRecharge(now)
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node.corrBufValue = int64(node.params.BufLimit)
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node.rcLastIntValue = cm.rcLastIntValue
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node.queueIndex = -1
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cm.updateTotalCapacity(now, true)
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cm.totalConnected += node.params.MinRecharge
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cm.updateRaiseLimit()
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}
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// disconnect should be called when a client is disconnected
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func (cm *ClientManager) disconnect(node *ClientNode) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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now := cm.clock.Now()
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cm.updateRecharge(cm.clock.Now())
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cm.updateTotalCapacity(now, true)
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cm.totalConnected -= node.params.MinRecharge
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cm.updateRaiseLimit()
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}
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// accepted is called when a request with given maximum cost is accepted.
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// It returns a priority indicator for the request which is used to determine placement
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// in the serving queue. Older requests have higher priority by default. If the client
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// is almost out of buffer, request priority is reduced.
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func (cm *ClientManager) accepted(node *ClientNode, maxCost uint64, now mclock.AbsTime) (priority int64) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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cm.updateNodeRc(node, -int64(maxCost), &node.params, now)
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rcTime := (node.params.BufLimit - uint64(node.corrBufValue)) * FixedPointMultiplier / node.params.MinRecharge
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return -int64(now) - int64(rcTime)
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}
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// processed updates the client buffer according to actual request cost after
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// serving has been finished.
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//
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// Note: processed should always be called for all accepted requests
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func (cm *ClientManager) processed(node *ClientNode, maxCost, realCost uint64, now mclock.AbsTime) {
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if realCost > maxCost {
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realCost = maxCost
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}
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cm.updateBuffer(node, int64(maxCost-realCost), now)
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}
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// updateBuffer recalulates the corrected buffer value, adds the given value to it
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// and updates the node's actual buffer value if possible
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func (cm *ClientManager) updateBuffer(node *ClientNode, add int64, now mclock.AbsTime) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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cm.updateNodeRc(node, add, &node.params, now)
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if node.corrBufValue > node.bufValue {
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if node.log != nil {
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node.log.add(now, fmt.Sprintf("corrected bv=%d oldBv=%d", node.corrBufValue, node.bufValue))
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}
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node.bufValue = node.corrBufValue
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}
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}
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// updateParams updates the flow control parameters of a client node
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func (cm *ClientManager) updateParams(node *ClientNode, params ServerParams, now mclock.AbsTime) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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cm.updateRecharge(now)
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cm.updateTotalCapacity(now, true)
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cm.totalConnected += params.MinRecharge - node.params.MinRecharge
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cm.updateRaiseLimit()
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cm.updateNodeRc(node, 0, ¶ms, now)
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}
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// updateRaiseLimit recalculates the limiting value until which logTotalCap
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// can be raised when no client freeze events occur
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func (cm *ClientManager) updateRaiseLimit() {
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if cm.capacityRaiseThreshold == 0 {
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cm.logTotalCapRaiseLimit = 0
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return
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}
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limit := float64(cm.totalConnected + cm.capacityRaiseThreshold)
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limit2 := float64(cm.totalConnected) * capacityRaiseThresholdRatio
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if limit2 > limit {
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limit = limit2
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}
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if limit < 1 {
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limit = 1
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}
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cm.logTotalCapRaiseLimit = math.Log(limit)
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}
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// updateRecharge updates the recharge integrator and checks the recharge queue
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// for nodes with recently filled buffers
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func (cm *ClientManager) updateRecharge(now mclock.AbsTime) {
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lastUpdate := cm.rcLastUpdate
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cm.rcLastUpdate = now
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// updating is done in multiple steps if node buffers are filled and sumRecharge
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// is decreased before the given target time
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for cm.sumRecharge > 0 {
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sumRecharge := cm.sumRecharge
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if sumRecharge > cm.totalRecharge {
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sumRecharge = cm.totalRecharge
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}
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bonusRatio := float64(1)
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v := cm.curve.ValueAt(sumRecharge)
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s := float64(sumRecharge)
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if v > s && s > 0 {
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bonusRatio = v / s
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}
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dt := now - lastUpdate
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// fetch the client that finishes first
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rcqNode := cm.rcQueue.PopItem().(*ClientNode) // if sumRecharge > 0 then the queue cannot be empty
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// check whether it has already finished
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dtNext := mclock.AbsTime(float64(rcqNode.rcFullIntValue-cm.rcLastIntValue) / bonusRatio)
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if dt < dtNext {
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// not finished yet, put it back, update integrator according
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// to current bonusRatio and return
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cm.rcQueue.Push(rcqNode, -rcqNode.rcFullIntValue)
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cm.rcLastIntValue += int64(bonusRatio * float64(dt))
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return
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}
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lastUpdate += dtNext
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// finished recharging, update corrBufValue and sumRecharge if necessary and do next step
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if rcqNode.corrBufValue < int64(rcqNode.params.BufLimit) {
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rcqNode.corrBufValue = int64(rcqNode.params.BufLimit)
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cm.sumRecharge -= rcqNode.params.MinRecharge
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}
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cm.rcLastIntValue = rcqNode.rcFullIntValue
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}
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}
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// updateNodeRc updates a node's corrBufValue and adds an external correction value.
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// It also adds or removes the rcQueue entry and updates ServerParams and sumRecharge if necessary.
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func (cm *ClientManager) updateNodeRc(node *ClientNode, bvc int64, params *ServerParams, now mclock.AbsTime) {
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cm.updateRecharge(now)
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wasFull := true
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if node.corrBufValue != int64(node.params.BufLimit) {
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wasFull = false
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node.corrBufValue += (cm.rcLastIntValue - node.rcLastIntValue) * int64(node.params.MinRecharge) / FixedPointMultiplier
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if node.corrBufValue > int64(node.params.BufLimit) {
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node.corrBufValue = int64(node.params.BufLimit)
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}
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node.rcLastIntValue = cm.rcLastIntValue
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}
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node.corrBufValue += bvc
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diff := int64(params.BufLimit - node.params.BufLimit)
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if diff > 0 {
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node.corrBufValue += diff
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}
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isFull := false
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if node.corrBufValue >= int64(params.BufLimit) {
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node.corrBufValue = int64(params.BufLimit)
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isFull = true
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}
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if !wasFull {
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cm.sumRecharge -= node.params.MinRecharge
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}
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if params != &node.params {
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node.params = *params
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}
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if !isFull {
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cm.sumRecharge += node.params.MinRecharge
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if node.queueIndex != -1 {
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cm.rcQueue.Remove(node.queueIndex)
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}
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node.rcLastIntValue = cm.rcLastIntValue
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node.rcFullIntValue = cm.rcLastIntValue + (int64(node.params.BufLimit)-node.corrBufValue)*FixedPointMultiplier/int64(node.params.MinRecharge)
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cm.rcQueue.Push(node, -node.rcFullIntValue)
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}
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}
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// reduceTotalCapacity reduces the total capacity allowance in case of a client freeze event
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func (cm *ClientManager) reduceTotalCapacity(frozenCap uint64) {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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ratio := float64(1)
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if frozenCap < cm.totalConnected {
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ratio = float64(frozenCap) / float64(cm.totalConnected)
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}
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now := cm.clock.Now()
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cm.updateTotalCapacity(now, false)
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cm.logTotalCap -= capacityDropFactor * ratio
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if cm.logTotalCap < cm.minLogTotalCap {
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cm.logTotalCap = cm.minLogTotalCap
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}
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cm.updateTotalCapacity(now, true)
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}
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// updateTotalCapacity updates the total capacity factor. The capacity factor allows
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// the total capacity of the system to go over the allowed total recharge value
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// if clients go to frozen state sufficiently rarely.
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// The capacity factor is dropped instantly by a small amount if a clients is frozen.
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// It is raised slowly (with a large time constant) if the total connected capacity
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// is close to the total allowed amount and no clients are frozen.
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func (cm *ClientManager) updateTotalCapacity(now mclock.AbsTime, refresh bool) {
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dt := now - cm.capLastUpdate
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cm.capLastUpdate = now
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if cm.logTotalCap < cm.logTotalCapRaiseLimit {
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cm.logTotalCap += capacityRaiseTC * float64(dt)
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if cm.logTotalCap > cm.logTotalCapRaiseLimit {
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cm.logTotalCap = cm.logTotalCapRaiseLimit
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}
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}
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if cm.logTotalCap > cm.maxLogTotalCap {
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cm.logTotalCap = cm.maxLogTotalCap
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}
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if refresh {
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cm.refreshCapacity()
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}
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}
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// refreshCapacity recalculates the total capacity value and sends an update to the subscription
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// channel if the relative change of the value since the last update is more than 0.1 percent
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func (cm *ClientManager) refreshCapacity() {
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totalCapacity := math.Exp(cm.logTotalCap)
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if totalCapacity >= cm.totalCapacity*0.999 && totalCapacity <= cm.totalCapacity*1.001 {
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return
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}
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cm.totalCapacity = totalCapacity
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if cm.totalCapacityCh != nil {
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select {
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case cm.totalCapacityCh <- uint64(cm.totalCapacity):
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default:
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}
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}
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}
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// SubscribeTotalCapacity returns all future updates to the total capacity value
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// through a channel and also returns the current value
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func (cm *ClientManager) SubscribeTotalCapacity(ch chan uint64) uint64 {
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cm.lock.Lock()
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defer cm.lock.Unlock()
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cm.totalCapacityCh = ch
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return uint64(cm.totalCapacity)
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}
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// PieceWiseLinear is used to describe recharge curves
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type PieceWiseLinear []struct{ X, Y uint64 }
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// ValueAt returns the curve's value at a given point
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func (pwl PieceWiseLinear) ValueAt(x uint64) float64 {
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l := 0
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h := len(pwl)
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if h == 0 {
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return 0
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}
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for h != l {
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m := (l + h) / 2
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if x > pwl[m].X {
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l = m + 1
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} else {
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h = m
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}
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}
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if l == 0 {
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return float64(pwl[0].Y)
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}
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l--
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if h == len(pwl) {
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return float64(pwl[l].Y)
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}
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dx := pwl[h].X - pwl[l].X
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if dx < 1 {
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return float64(pwl[l].Y)
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}
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return float64(pwl[l].Y) + float64(pwl[h].Y-pwl[l].Y)*float64(x-pwl[l].X)/float64(dx)
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}
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// Valid returns true if the X coordinates of the curve points are non-strictly monotonic
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func (pwl PieceWiseLinear) Valid() bool {
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var lastX uint64
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for _, i := range pwl {
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if i.X < lastX {
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return false
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}
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lastX = i.X
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}
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return true
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}
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