zolfa
/
tendermint


								//

								// Written by Maxim Khitrov (November 2012)

								//


								// Package flowrate provides the tools for monitoring and limiting the flow rate

								// of an arbitrary data stream.

								package flowrate


								import (

									"math"

									"sync"

									"time"

								)


								// Monitor monitors and limits the transfer rate of a data stream.

								type Monitor struct {

									mu      sync.Mutex    // Mutex guarding access to all internal fields

									active  bool          // Flag indicating an active transfer

									start   time.Duration // Transfer start time (clock() value)

									bytes   int64         // Total number of bytes transferred

									samples int64         // Total number of samples taken


									rSample float64 // Most recent transfer rate sample (bytes per second)

									rEMA    float64 // Exponential moving average of rSample

									rPeak   float64 // Peak transfer rate (max of all rSamples)

									rWindow float64 // rEMA window (seconds)


									sBytes int64         // Number of bytes transferred since sLast

									sLast  time.Duration // Most recent sample time (stop time when inactive)

									sRate  time.Duration // Sampling rate


									tBytes int64         // Number of bytes expected in the current transfer

									tLast  time.Duration // Time of the most recent transfer of at least 1 byte

								}


								// New creates a new flow control monitor. Instantaneous transfer rate is

								// measured and updated for each sampleRate interval. windowSize determines the

								// weight of each sample in the exponential moving average (EMA) calculation.

								// The exact formulas are:

								//

								// 	sampleTime = currentTime - prevSampleTime

								// 	sampleRate = byteCount / sampleTime

								// 	weight     = 1 - exp(-sampleTime/windowSize)

								// 	newRate    = weight*sampleRate + (1-weight)*oldRate

								//

								// The default values for sampleRate and windowSize (if <= 0) are 100ms and 1s,

								// respectively.

								func New(sampleRate, windowSize time.Duration) *Monitor {

									if sampleRate = clockRound(sampleRate); sampleRate <= 0 {

										sampleRate = 5 * clockRate

									}

									if windowSize <= 0 {

										windowSize = 1 * time.Second

									}

									now := clock()

									return &Monitor{

										active:  true,

										start:   now,

										rWindow: windowSize.Seconds(),

										sLast:   now,

										sRate:   sampleRate,

										tLast:   now,

									}

								}


								// Update records the transfer of n bytes and returns n. It should be called

								// after each Read/Write operation, even if n is 0.

								func (m *Monitor) Update(n int) int {

									m.mu.Lock()

									m.update(n)

									m.mu.Unlock()

									return n

								}


								// Hack to set the current rEMA.

								func (m *Monitor) SetREMA(rEMA float64) {

									m.mu.Lock()

									m.rEMA = rEMA

									m.samples++

									m.mu.Unlock()

								}


								// IO is a convenience method intended to wrap io.Reader and io.Writer method

								// execution. It calls m.Update(n) and then returns (n, err) unmodified.

								func (m *Monitor) IO(n int, err error) (int, error) {

									return m.Update(n), err

								}


								// Done marks the transfer as finished and prevents any further updates or

								// limiting. Instantaneous and current transfer rates drop to 0. Update, IO, and

								// Limit methods become NOOPs. It returns the total number of bytes transferred.

								func (m *Monitor) Done() int64 {

									m.mu.Lock()

									if now := m.update(0); m.sBytes > 0 {

										m.reset(now)

									}

									m.active = false

									m.tLast = 0

									n := m.bytes

									m.mu.Unlock()

									return n

								}


								// timeRemLimit is the maximum Status.TimeRem value.

								const timeRemLimit = 999*time.Hour + 59*time.Minute + 59*time.Second


								// Status represents the current Monitor status. All transfer rates are in bytes

								// per second rounded to the nearest byte.

								type Status struct {

									Start    time.Time     // Transfer start time

									Bytes    int64         // Total number of bytes transferred

									Samples  int64         // Total number of samples taken

									InstRate int64         // Instantaneous transfer rate

									CurRate  int64         // Current transfer rate (EMA of InstRate)

									AvgRate  int64         // Average transfer rate (Bytes / Duration)

									PeakRate int64         // Maximum instantaneous transfer rate

									BytesRem int64         // Number of bytes remaining in the transfer

									Duration time.Duration // Time period covered by the statistics

									Idle     time.Duration // Time since the last transfer of at least 1 byte

									TimeRem  time.Duration // Estimated time to completion

									Progress Percent       // Overall transfer progress

									Active   bool          // Flag indicating an active transfer

								}


								// Status returns current transfer status information. The returned value

								// becomes static after a call to Done.

								func (m *Monitor) Status() Status {

									m.mu.Lock()

									now := m.update(0)

									s := Status{

										Active:   m.active,

										Start:    clockToTime(m.start),

										Duration: m.sLast - m.start,

										Idle:     now - m.tLast,

										Bytes:    m.bytes,

										Samples:  m.samples,

										PeakRate: round(m.rPeak),

										BytesRem: m.tBytes - m.bytes,

										Progress: percentOf(float64(m.bytes), float64(m.tBytes)),

									}

									if s.BytesRem < 0 {

										s.BytesRem = 0

									}

									if s.Duration > 0 {

										rAvg := float64(s.Bytes) / s.Duration.Seconds()

										s.AvgRate = round(rAvg)

										if s.Active {

											s.InstRate = round(m.rSample)

											s.CurRate = round(m.rEMA)

											if s.BytesRem > 0 {

												if tRate := 0.8*m.rEMA + 0.2*rAvg; tRate > 0 {

													ns := float64(s.BytesRem) / tRate * 1e9

													if ns > float64(timeRemLimit) {

														ns = float64(timeRemLimit)

													}

													s.TimeRem = clockRound(time.Duration(ns))

												}

											}

										}

									}

									m.mu.Unlock()

									return s

								}


								// Limit restricts the instantaneous (per-sample) data flow to rate bytes per

								// second. It returns the maximum number of bytes (0 <= n <= want) that may be

								// transferred immediately without exceeding the limit. If block == true, the

								// call blocks until n > 0. want is returned unmodified if want < 1, rate < 1,

								// or the transfer is inactive (after a call to Done).

								//

								// At least one byte is always allowed to be transferred in any given sampling

								// period. Thus, if the sampling rate is 100ms, the lowest achievable flow rate

								// is 10 bytes per second.

								//

								// For usage examples, see the implementation of Reader and Writer in io.go.

								func (m *Monitor) Limit(want int, rate int64, block bool) (n int) {

									if want < 1 || rate < 1 {

										return want

									}

									m.mu.Lock()


									// Determine the maximum number of bytes that can be sent in one sample

									limit := round(float64(rate) * m.sRate.Seconds())

									if limit <= 0 {

										limit = 1

									}


									// If block == true, wait until m.sBytes < limit

									if now := m.update(0); block {

										for m.sBytes >= limit && m.active {

											now = m.waitNextSample(now)

										}

									}


									// Make limit <= want (unlimited if the transfer is no longer active)

									if limit -= m.sBytes; limit > int64(want) || !m.active {

										limit = int64(want)

									}

									m.mu.Unlock()


									if limit < 0 {

										limit = 0

									}

									return int(limit)

								}


								// SetTransferSize specifies the total size of the data transfer, which allows

								// the Monitor to calculate the overall progress and time to completion.

								func (m *Monitor) SetTransferSize(bytes int64) {

									if bytes < 0 {

										bytes = 0

									}

									m.mu.Lock()

									m.tBytes = bytes

									m.mu.Unlock()

								}


								// update accumulates the transferred byte count for the current sample until

								// clock() - m.sLast >= m.sRate. The monitor status is updated once the current

								// sample is done.

								func (m *Monitor) update(n int) (now time.Duration) {

									if !m.active {

										return

									}

									if now = clock(); n > 0 {

										m.tLast = now

									}

									m.sBytes += int64(n)

									if sTime := now - m.sLast; sTime >= m.sRate {

										t := sTime.Seconds()

										if m.rSample = float64(m.sBytes) / t; m.rSample > m.rPeak {

											m.rPeak = m.rSample

										}


										// Exponential moving average using a method similar to *nix load

										// average calculation. Longer sampling periods carry greater weight.

										if m.samples > 0 {

											w := math.Exp(-t / m.rWindow)

											m.rEMA = m.rSample + w*(m.rEMA-m.rSample)

										} else {

											m.rEMA = m.rSample

										}

										m.reset(now)

									}

									return

								}


								// reset clears the current sample state in preparation for the next sample.

								func (m *Monitor) reset(sampleTime time.Duration) {

									m.bytes += m.sBytes

									m.samples++

									m.sBytes = 0

									m.sLast = sampleTime

								}


								// waitNextSample sleeps for the remainder of the current sample. The lock is

								// released and reacquired during the actual sleep period, so it's possible for

								// the transfer to be inactive when this method returns.

								func (m *Monitor) waitNextSample(now time.Duration) time.Duration {

									const minWait = 5 * time.Millisecond

									current := m.sLast


									// sleep until the last sample time changes (ideally, just one iteration)

									for m.sLast == current && m.active {

										d := current + m.sRate - now

										m.mu.Unlock()

										if d < minWait {

											d = minWait

										}

										time.Sleep(d)

										m.mu.Lock()

										now = m.update(0)

									}

									return now

								}