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8d2a90529e
Without any synchronization here, the "first packet" callback can be delayed indefinitely, while other work continues. Since the callback starts the benchmark timer, this could skew results. Worse, if the benchmark manages to complete before the benchmark timer begins, it'll cause a data race with the benchmark shutdown performed by package testing. That is what is reported in #1881. This is a bit unfortunate, in that it means that users of TrafficGen have to be careful to keep this callback speedy and lightweight and to avoid deadlocks. Fixes #1881 Signed-off-by: Josh Bleecher Snyder <josh@tailscale.com>
261 lines
6.6 KiB
Go
261 lines
6.6 KiB
Go
// Copyright (c) 2021 Tailscale Inc & AUTHORS All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package main
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import (
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"encoding/binary"
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"fmt"
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"log"
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"sync"
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"time"
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"inet.af/netaddr"
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"tailscale.com/net/packet"
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"tailscale.com/types/ipproto"
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)
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type Snapshot struct {
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WhenNsec int64 // current time
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timeAcc int64 // accumulated time (+NSecPerTx per transmit)
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LastSeqTx int64 // last sequence number sent
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LastSeqRx int64 // last sequence number received
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TotalLost int64 // packets out-of-order or lost so far
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TotalOOO int64 // packets out-of-order so far
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TotalBytesRx int64 // total bytes received so far
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}
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type Delta struct {
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DurationNsec int64
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TxPackets int64
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RxPackets int64
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LostPackets int64
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OOOPackets int64
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Bytes int64
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}
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func (b Snapshot) Sub(a Snapshot) Delta {
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return Delta{
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DurationNsec: b.WhenNsec - a.WhenNsec,
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TxPackets: b.LastSeqTx - a.LastSeqTx,
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RxPackets: (b.LastSeqRx - a.LastSeqRx) -
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(b.TotalLost - a.TotalLost) +
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(b.TotalOOO - a.TotalOOO),
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LostPackets: b.TotalLost - a.TotalLost,
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OOOPackets: b.TotalOOO - a.TotalOOO,
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Bytes: b.TotalBytesRx - a.TotalBytesRx,
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}
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}
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func (d Delta) String() string {
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return fmt.Sprintf("tx=%-6d rx=%-4d (%6d = %.1f%% loss) (%d OOO) (%4.1f Mbit/s)",
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d.TxPackets, d.RxPackets, d.LostPackets,
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float64(d.LostPackets)*100/float64(d.TxPackets),
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d.OOOPackets,
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float64(d.Bytes)*8*1e9/float64(d.DurationNsec)/1e6)
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}
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type TrafficGen struct {
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mu sync.Mutex
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cur, prev Snapshot // snapshots used for rate control
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buf []byte // pre-generated packet buffer
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done bool // true if the test has completed
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onFirstPacket func() // function to call on first received packet
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// maxPackets is the max packets to receive (not send) before
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// ending the test. If it's zero, the test runs forever.
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maxPackets int64
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// nsPerPacket is the target average nanoseconds between packets.
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// It's initially zero, which means transmit as fast as the
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// caller wants to go.
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nsPerPacket int64
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// ppsHistory is the observed packets-per-second from recent
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// samples.
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ppsHistory [5]int64
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}
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// NewTrafficGen creates a new, initially locked, TrafficGen.
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// Until Start() is called, Generate() will block forever.
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func NewTrafficGen(onFirstPacket func()) *TrafficGen {
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t := TrafficGen{
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onFirstPacket: onFirstPacket,
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}
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// initially locked, until first Start()
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t.mu.Lock()
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return &t
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}
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// Start starts the traffic generator. It assumes mu is already locked,
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// and unlocks it.
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func (t *TrafficGen) Start(src, dst netaddr.IP, bytesPerPacket int, maxPackets int64) {
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h12 := packet.ICMP4Header{
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IP4Header: packet.IP4Header{
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IPProto: ipproto.ICMPv4,
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IPID: 0,
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Src: src,
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Dst: dst,
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},
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Type: packet.ICMP4EchoRequest,
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Code: packet.ICMP4NoCode,
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}
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// ensure there's room for ICMP header plus sequence number
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if bytesPerPacket < ICMPMinSize+8 {
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log.Fatalf("bytesPerPacket must be > 24+8")
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}
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t.maxPackets = maxPackets
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payload := make([]byte, bytesPerPacket-ICMPMinSize)
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t.buf = packet.Generate(h12, payload)
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t.mu.Unlock()
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}
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func (t *TrafficGen) Snap() Snapshot {
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t.mu.Lock()
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defer t.mu.Unlock()
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t.cur.WhenNsec = time.Now().UnixNano()
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return t.cur
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}
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func (t *TrafficGen) Running() bool {
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t.mu.Lock()
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defer t.mu.Unlock()
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return !t.done
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}
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// Generate produces the next packet in the sequence. It sleeps if
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// it's too soon for the next packet to be sent.
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//
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// The generated packet is placed into buf at offset ofs, for compatibility
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// with the wireguard-go conventions.
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//
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// The return value is the number of bytes generated in the packet, or 0
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// if the test has finished running.
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func (t *TrafficGen) Generate(b []byte, ofs int) int {
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t.mu.Lock()
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now := time.Now().UnixNano()
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if t.nsPerPacket == 0 || t.cur.timeAcc == 0 {
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t.cur.timeAcc = now - 1
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}
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if t.cur.timeAcc >= now {
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// too soon
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t.mu.Unlock()
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time.Sleep(time.Duration(t.cur.timeAcc-now) * time.Nanosecond)
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t.mu.Lock()
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now = t.cur.timeAcc
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}
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if t.done {
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t.mu.Unlock()
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return 0
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}
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t.cur.timeAcc += t.nsPerPacket
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t.cur.LastSeqTx += 1
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t.cur.WhenNsec = now
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seq := t.cur.LastSeqTx
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t.mu.Unlock()
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copy(b[ofs:], t.buf)
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binary.BigEndian.PutUint64(
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b[ofs+ICMPMinSize:ofs+ICMPMinSize+8],
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uint64(seq))
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return len(t.buf)
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}
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// GotPacket processes a packet that came back on the receive side.
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func (t *TrafficGen) GotPacket(b []byte, ofs int) {
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t.mu.Lock()
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defer t.mu.Unlock()
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s := &t.cur
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seq := int64(binary.BigEndian.Uint64(
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b[ofs+ICMPMinSize : ofs+ICMPMinSize+8]))
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if seq > s.LastSeqRx {
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if s.LastSeqRx > 0 {
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// only count lost packets after the very first
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// successful one.
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s.TotalLost += seq - s.LastSeqRx - 1
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}
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s.LastSeqRx = seq
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} else {
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s.TotalOOO += 1
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}
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// +1 packet since we only start counting after the first one
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if t.maxPackets > 0 && s.LastSeqRx >= t.maxPackets+1 {
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t.done = true
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}
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s.TotalBytesRx += int64(len(b) - ofs)
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f := t.onFirstPacket
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t.onFirstPacket = nil
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if f != nil {
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f()
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}
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}
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// Adjust tunes the transmit rate based on the received packets.
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// The goal is to converge on the fastest transmit rate that still has
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// minimal packet loss. Returns the new target rate in packets/sec.
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//
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// We need to play this guessing game in order to balance out tx and rx
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// rates when there's a lossy network between them. Otherwise we can end
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// up using 99% of the CPU to blast out transmitted packets and leaving only
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// 1% to receive them, leading to a misleading throughput calculation.
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//
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// Call this function multiple times per second.
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func (t *TrafficGen) Adjust() (pps int64) {
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t.mu.Lock()
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defer t.mu.Unlock()
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d := t.cur.Sub(t.prev)
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// don't adjust rate until the first full period *after* receiving
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// the first packet. This skips any handshake time in the underlying
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// transport.
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if t.prev.LastSeqRx == 0 || d.DurationNsec == 0 {
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t.prev = t.cur
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return 0 // no estimate yet, continue at max speed
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}
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pps = int64(d.RxPackets) * 1e9 / int64(d.DurationNsec)
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// We use a rate selection algorithm based loosely on TCP BBR.
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// Basically, we set the transmit rate to be a bit higher than
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// the best observed transmit rate in the last several time
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// periods. This guarantees some packet loss, but should converge
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// quickly on a rate near the sustainable maximum.
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bestPPS := pps
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for _, p := range t.ppsHistory {
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if p > bestPPS {
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bestPPS = p
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}
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}
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if pps > 0 && t.prev.WhenNsec > 0 {
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copy(t.ppsHistory[1:], t.ppsHistory[0:len(t.ppsHistory)-1])
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t.ppsHistory[0] = pps
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}
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if bestPPS > 0 {
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pps = bestPPS * 103 / 100
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t.nsPerPacket = int64(1e9 / pps)
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}
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t.prev = t.cur
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return pps
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}
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