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490 lines
13 KiB
C++
490 lines
13 KiB
C++
/* Copyright 2009-2018 Pierre Ossman for Cendio AB
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*
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* This is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This software 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 General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this software; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307,
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* USA.
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*/
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/*
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* This code implements congestion control in the same way as TCP in
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* order to avoid excessive latency in the transport. This is needed
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* because "buffer bloat" is unfortunately still a very real problem.
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*
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* The basic principle is TCP Congestion Control (RFC 5618), with the
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* addition of using the TCP Vegas algorithm. The reason we use Vegas
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* is that we run on top of a reliable transport so we need a latency
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* based algorithm rather than a loss based one. There is also a lot of
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* interpolation of values. This is because we have rather horrible
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* granularity in our measurements.
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*
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* We use a simplistic form of slow start in order to ramp up quickly
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* from an idle state. We do not have any persistent threshold though
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* as we have too much noise for it to be reliable.
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*/
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#include <assert.h>
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#include <sys/time.h>
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#ifdef __linux__
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#include <sys/ioctl.h>
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#include <sys/socket.h>
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#include <netinet/in.h>
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#include <netinet/tcp.h>
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#include <linux/sockios.h>
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#endif
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#include <rfb/Congestion.h>
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#include <rfb/LogWriter.h>
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#include <rfb/util.h>
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// Debug output on what the congestion control is up to
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#undef CONGESTION_DEBUG
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// Dump socket congestion window debug trace to disk
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#undef CONGESTION_TRACE
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using namespace rfb;
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// This window should get us going fairly fast on a decent bandwidth network.
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// If it's too high, it will rapidly be reduced and stay low.
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static const unsigned INITIAL_WINDOW = 16384;
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// TCP's minimal window is 3*MSS. But since we don't know the MSS, we
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// make a guess at 4 KiB (it's probably a bit higher).
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static const unsigned MINIMUM_WINDOW = 4096;
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// The current default maximum window for Linux (4 MiB). Should be a good
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// limit for now...
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static const unsigned MAXIMUM_WINDOW = 4194304;
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// Compare position even when wrapped around
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static inline bool isAfter(unsigned a, unsigned b) {
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return a != b && a - b <= UINT_MAX / 2;
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}
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static LogWriter vlog("Congestion");
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Congestion::Congestion() :
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lastPosition(0), extraBuffer(0),
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baseRTT(-1), congWindow(INITIAL_WINDOW), inSlowStart(true),
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safeBaseRTT(-1), measurements(0), minRTT(-1), minCongestedRTT(-1)
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{
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gettimeofday(&lastUpdate, NULL);
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gettimeofday(&lastSent, NULL);
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memset(&lastPong, 0, sizeof(lastPong));
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gettimeofday(&lastPongArrival, NULL);
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gettimeofday(&lastAdjustment, NULL);
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}
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Congestion::~Congestion()
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{
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}
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void Congestion::updatePosition(unsigned pos)
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{
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struct timeval now;
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unsigned delta, consumed;
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gettimeofday(&now, NULL);
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delta = pos - lastPosition;
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if ((delta > 0) || (extraBuffer > 0))
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lastSent = now;
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// Idle for too long?
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// We use a very crude RTO calculation in order to keep things simple
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// FIXME: should implement RFC 2861
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if (msBetween(&lastSent, &now) > __rfbmax(baseRTT*2, 100)) {
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#ifdef CONGESTION_DEBUG
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vlog.debug("Connection idle for %d ms, resetting congestion control",
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msBetween(&lastSent, &now));
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#endif
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// Close congestion window and redo wire latency measurement
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congWindow = __rfbmin(INITIAL_WINDOW, congWindow);
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baseRTT = -1;
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measurements = 0;
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gettimeofday(&lastAdjustment, NULL);
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minRTT = minCongestedRTT = -1;
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inSlowStart = true;
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}
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// Commonly we will be in a state of overbuffering. We need to
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// estimate the extra delay that causes so we can separate it from
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// the delay caused by an incorrect congestion window.
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// (we cannot do this until we have a RTT measurement though)
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if (baseRTT != (unsigned)-1) {
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extraBuffer += delta;
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consumed = msBetween(&lastUpdate, &now) * congWindow / baseRTT;
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if (extraBuffer < consumed)
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extraBuffer = 0;
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else
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extraBuffer -= consumed;
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}
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lastPosition = pos;
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lastUpdate = now;
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}
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void Congestion::sentPing()
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{
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struct RTTInfo rttInfo;
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memset(&rttInfo, 0, sizeof(struct RTTInfo));
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gettimeofday(&rttInfo.tv, NULL);
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rttInfo.pos = lastPosition;
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rttInfo.extra = getExtraBuffer();
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rttInfo.congested = isCongested();
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pings.push_back(rttInfo);
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}
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void Congestion::gotPong()
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{
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struct timeval now;
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struct RTTInfo rttInfo;
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unsigned rtt, delay;
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if (pings.empty())
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return;
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gettimeofday(&now, NULL);
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rttInfo = pings.front();
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pings.pop_front();
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lastPong = rttInfo;
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lastPongArrival = now;
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rtt = msBetween(&rttInfo.tv, &now);
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if (rtt < 1)
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rtt = 1;
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// Try to estimate wire latency by tracking lowest seen latency
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if (rtt < baseRTT)
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safeBaseRTT = baseRTT = rtt;
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// Pings sent before the last adjustment aren't interesting as they
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// aren't a measurement of the current congestion window
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if (isBefore(&rttInfo.tv, &lastAdjustment))
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return;
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// Estimate added delay because of overtaxed buffers (see above)
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delay = rttInfo.extra * baseRTT / congWindow;
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if (delay < rtt)
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rtt -= delay;
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else
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rtt = 1;
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// A latency less than the wire latency means that we've
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// understimated the congestion window. We can't really determine
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// how much, so pretend that we got no buffer latency at all.
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if (rtt < baseRTT)
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rtt = baseRTT;
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// Record the minimum seen delay (hopefully ignores jitter) and let
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// the congestion control do its thing.
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//
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// Note: We are delay based rather than loss based, which means we
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// need to look at pongs even if they weren't limited by the
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// current window ("congested"). Otherwise we will fail to
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// detect increasing congestion until the application exceeds
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// the congestion window.
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if (rtt < minRTT)
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minRTT = rtt;
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if (rttInfo.congested) {
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if (rtt < minCongestedRTT)
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minCongestedRTT = rtt;
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}
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measurements++;
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updateCongestion();
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}
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bool Congestion::isCongested()
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{
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if (getInFlight() < congWindow)
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return false;
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return true;
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}
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int Congestion::getUncongestedETA()
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{
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unsigned targetAcked;
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const struct RTTInfo* prevPing;
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unsigned eta, elapsed;
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unsigned etaNext, delay;
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std::list<struct RTTInfo>::const_iterator iter;
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targetAcked = lastPosition - congWindow;
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// Simple case?
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if (isAfter(lastPong.pos, targetAcked))
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return 0;
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// No measurements yet?
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if (baseRTT == (unsigned)-1)
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return -1;
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prevPing = &lastPong;
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eta = 0;
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elapsed = msSince(&lastPongArrival);
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// Walk the ping queue and figure out which one we are waiting for to
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// get to an uncongested state
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for (iter = pings.begin(); ;++iter) {
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struct RTTInfo curPing;
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// If we aren't waiting for a pong that will clear the congested
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// state then we have to estimate the final bit by pretending that
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// we had a ping just after the last position update.
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if (iter == pings.end()) {
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curPing.tv = lastUpdate;
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curPing.pos = lastPosition;
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curPing.extra = extraBuffer;
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} else {
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curPing = *iter;
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}
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etaNext = msBetween(&prevPing->tv, &curPing.tv);
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// Compensate for buffering delays
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delay = curPing.extra * baseRTT / congWindow;
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etaNext += delay;
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delay = prevPing->extra * baseRTT / congWindow;
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if (delay >= etaNext)
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etaNext = 0;
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else
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etaNext -= delay;
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// Found it?
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if (isAfter(curPing.pos, targetAcked)) {
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eta += etaNext * (curPing.pos - targetAcked) / (curPing.pos - prevPing->pos);
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if (elapsed > eta)
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return 0;
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else
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return eta - elapsed;
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}
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assert(iter != pings.end());
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eta += etaNext;
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prevPing = &*iter;
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}
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}
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size_t Congestion::getBandwidth()
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{
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// No measurements yet? Guess RTT of 60 ms
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if (safeBaseRTT == (unsigned)-1)
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return congWindow * 1000 / 60;
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return congWindow * 1000 / safeBaseRTT;
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}
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unsigned Congestion::getPingTime() const
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{
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return safeBaseRTT;
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}
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void Congestion::debugTrace(const char* filename, int fd)
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{
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#ifdef CONGESTION_TRACE
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#ifdef __linux__
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FILE *f;
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f = fopen(filename, "ab");
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if (f != NULL) {
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struct tcp_info info;
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int buffered;
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socklen_t len;
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len = sizeof(info);
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if ((getsockopt(fd, IPPROTO_TCP,
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TCP_INFO, &info, &len) == 0) &&
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(ioctl(fd, SIOCOUTQ, &buffered) == 0)) {
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struct timeval now;
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gettimeofday(&now, NULL);
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fprintf(f, "%u.%06u,%u,%u,%u,%u\n",
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(unsigned)now.tv_sec, (unsigned)now.tv_usec,
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congWindow, info.tcpi_snd_cwnd * info.tcpi_snd_mss,
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getInFlight(), buffered);
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}
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fclose(f);
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}
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#endif
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#endif
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}
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unsigned Congestion::getExtraBuffer()
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{
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unsigned elapsed;
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unsigned consumed;
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if (baseRTT == (unsigned)-1)
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return 0;
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elapsed = msSince(&lastUpdate);
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consumed = elapsed * congWindow / baseRTT;
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if (consumed >= extraBuffer)
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return 0;
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else
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return extraBuffer - consumed;
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}
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unsigned Congestion::getInFlight()
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{
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struct RTTInfo nextPong;
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unsigned etaNext, delay, elapsed, acked;
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// Simple case?
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if (lastPosition == lastPong.pos)
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return 0;
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// No measurements yet?
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if (baseRTT == (unsigned)-1) {
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if (!pings.empty())
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return lastPosition - pings.front().pos;
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return 0;
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}
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// If we aren't waiting for any pong then we have to estimate things
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// by pretending that we had a ping just after the last position
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// update.
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if (pings.empty()) {
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nextPong.tv = lastUpdate;
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nextPong.pos = lastPosition;
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nextPong.extra = extraBuffer;
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} else {
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nextPong = pings.front();
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}
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// First we need to estimate how many bytes have made it through
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// completely. Look at the next ping that should arrive and figure
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// out how far behind it should be and interpolate the positions.
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etaNext = msBetween(&lastPong.tv, &nextPong.tv);
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// Compensate for buffering delays
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delay = nextPong.extra * baseRTT / congWindow;
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etaNext += delay;
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delay = lastPong.extra * baseRTT / congWindow;
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if (delay >= etaNext)
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etaNext = 0;
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else
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etaNext -= delay;
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elapsed = msSince(&lastPongArrival);
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// The pong should be here any second. Be optimistic and assume
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// we can already use its value.
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if (etaNext <= elapsed)
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acked = nextPong.pos;
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else {
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acked = lastPong.pos;
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acked += (nextPong.pos - lastPong.pos) * elapsed / etaNext;
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}
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return lastPosition - acked;
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}
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void Congestion::updateCongestion()
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{
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unsigned diff;
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// We want at least three measurements to avoid noise
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if (measurements < 3)
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return;
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assert(minRTT >= baseRTT);
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assert(minCongestedRTT >= baseRTT);
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// The goal is to have a slightly too large congestion window since
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// a "perfect" one cannot be distinguished from a too small one. This
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// translates to a goal of a few extra milliseconds of delay.
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diff = minRTT - baseRTT;
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if (diff > __rfbmax(100, baseRTT/2)) {
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// We have no way of detecting loss, so assume massive latency
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// spike means packet loss. Adjust the window and go directly
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// to congestion avoidance.
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#ifdef CONGESTION_DEBUG
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vlog.debug("Latency spike! Backing off...");
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#endif
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congWindow = congWindow * baseRTT / minRTT;
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inSlowStart = false;
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}
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if (inSlowStart) {
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// Slow start. Aggressive growth until we see congestion.
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if (diff > 25) {
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// If we see an increased latency then we assume we've hit the
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// limit and it's time to leave slow start and switch to
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// congestion avoidance
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congWindow = congWindow * baseRTT / minRTT;
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inSlowStart = false;
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} else {
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// It's not safe to increase unless we actually used the entire
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// congestion window, hence we look at minCongestedRTT and not
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// minRTT
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diff = minCongestedRTT - baseRTT;
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if (diff < 25)
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congWindow *= 2;
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}
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} else {
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// Congestion avoidance (VEGAS)
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if (diff > 50) {
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// Slightly too fast
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congWindow -= 4096;
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} else {
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// Only the "congested" pongs are checked to see if the
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// window is too small.
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diff = minCongestedRTT - baseRTT;
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if (diff < 5) {
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// Way too slow
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congWindow += 8192;
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} else if (diff < 25) {
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// Too slow
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congWindow += 4096;
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}
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}
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}
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if (congWindow < MINIMUM_WINDOW)
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congWindow = MINIMUM_WINDOW;
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if (congWindow > MAXIMUM_WINDOW)
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congWindow = MAXIMUM_WINDOW;
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#ifdef CONGESTION_DEBUG
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vlog.debug("RTT: %d/%d ms (%d ms), Window: %d KiB, Bandwidth: %g Mbps%s",
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minRTT, minCongestedRTT, baseRTT, congWindow / 1024,
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congWindow * 8.0 / baseRTT / 1000.0,
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inSlowStart ? " (slow start)" : "");
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#endif
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measurements = 0;
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gettimeofday(&lastAdjustment, NULL);
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minRTT = minCongestedRTT = -1;
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}
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