utils/ndn-rtt-mean-deviation.cc - ndnSIM - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
 //
 // Copyright (c) 2006 Georgia Tech Research Corporation
 //           (c) 2013 University of Arizona
 //           (c) 2013 University of California, Los Angeles
 //
 // This program is free software; you can redistribute it and/or modify
 // it under the terms of the GNU General Public License version 2 as
 // published by the Free Software Foundation;
 //
 // This program is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU General Public License for more details.
 //
 // You should have received a copy of the GNU General Public License
 // along with this program; if not, write to the Free Software
 // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 //
 // Author: Rajib Bhattacharjea<raj.b@gatech.edu>
 //         Cheng Yi <yic@email.arizona.edu>
 //         Alexander Afanasyev <alexander.afanasyev@ucla.edu>
 //

 // Georgia Tech Network Simulator - Round Trip Time Estimation Class
 // George F. Riley.  Georgia Tech, Spring 2002

 #include "ndn-rtt-mean-deviation.h"
 #include "ns3/simulator.h"
 #include "ns3/double.h"
 #include "ns3/integer.h"
 #include "ns3/uinteger.h"
 #include "ns3/log.h"

 NS_LOG_COMPONENT_DEFINE ("ndn.RttMeanDeviation");

 namespace ns3 {
 namespace ndn {

 //---------------------------------------------------------------------------------
 // A modified version of Mean-Deviation Estimator optimized for NDN packet delivery

 NS_OBJECT_ENSURE_REGISTERED (RttMeanDeviation);

 TypeId
 RttMeanDeviation::GetTypeId (void)
 {
   static TypeId tid = TypeId ("ns3::ndn::RttMeanDeviation")
     .SetParent<RttEstimator> ()
     .AddConstructor<RttMeanDeviation> ()
     .AddAttribute ("Gain",
                    "Gain used in estimating the RTT (smoothed RTT), must be 0 < Gain < 1",
                    DoubleValue (0.125),
                    MakeDoubleAccessor (&RttMeanDeviation::m_gain),
                    MakeDoubleChecker<double> ())
     .AddAttribute ("Gain2",
                    "Gain2 used in estimating the RTT (variance), must be 0 < Gain2 < 1",
                    DoubleValue (0.25),
                    MakeDoubleAccessor (&RttMeanDeviation::m_gain2),
                    MakeDoubleChecker<double> ())
   ;
   return tid;
 }

 RttMeanDeviation::RttMeanDeviation() :
   m_variance (0)
 {
   NS_LOG_FUNCTION (this);
 }

 RttMeanDeviation::RttMeanDeviation (const RttMeanDeviation& c)
   : RttEstimator (c), m_gain (c.m_gain), m_gain2 (c.m_gain2), m_variance (c.m_variance)
 {
   NS_LOG_FUNCTION (this);
 }

 TypeId
 RttMeanDeviation::GetInstanceTypeId (void) const
 {
   return GetTypeId ();
 }

 void RttMeanDeviation::Measurement (Time m)
 {
   NS_LOG_FUNCTION (this << m);
   if (m_nSamples)
     { // Not first
       Time err (m - m_currentEstimatedRtt);
       double gErr = err.ToDouble (Time::S) * m_gain;
       m_currentEstimatedRtt += Time::FromDouble (gErr, Time::S);
       Time difference = Abs (err) - m_variance;
       NS_LOG_DEBUG ("m_variance += " << Time::FromDouble (difference.ToDouble (Time::S) * m_gain2, Time::S));
       m_variance += Time::FromDouble (difference.ToDouble (Time::S) * m_gain2, Time::S);
     }
   else
     { // First sample
       m_currentEstimatedRtt = m;             // Set estimate to current
       //variance = sample / 2;               // And variance to current / 2
       // m_variance = m; // try this  why????
       m_variance = Seconds (m.ToDouble (Time::S) / 2);
       NS_LOG_DEBUG ("(first sample) m_variance += " << m);
     }
   m_nSamples++;
 }

 Time RttMeanDeviation::RetransmitTimeout ()
 {
   NS_LOG_FUNCTION (this);

   double retval = std::min (m_maxRto.ToDouble (Time::S),
                             std::max (m_multiplier*m_minRto.ToDouble (Time::S),
                                       m_multiplier*(m_currentEstimatedRtt.ToDouble (Time::S) + 4 * m_variance.ToDouble (Time::S))));

   NS_LOG_DEBUG ("RetransmitTimeout:  return " << retval);

   return Seconds (retval);
 }

 Ptr<RttEstimator> RttMeanDeviation::Copy () const
 {
   NS_LOG_FUNCTION (this);
   return CopyObject<RttMeanDeviation> (this);
 }

 void RttMeanDeviation::Reset ()
 {
   NS_LOG_FUNCTION (this);
   // Reset to initial state
   m_variance = Seconds (0);
   RttEstimator::Reset ();
 }

 void RttMeanDeviation::Gain (double g)
 {
   NS_LOG_FUNCTION (this);
   NS_ASSERT_MSG( (g > 0) && (g < 1), "RttMeanDeviation: Gain must be less than 1 and greater than 0" );
   m_gain = g;
 }

 void RttMeanDeviation::SentSeq (SequenceNumber32 seq, uint32_t size)
 {
   NS_LOG_FUNCTION (this << seq << size);

   RttHistory_t::iterator i;
   for (i = m_history.begin (); i != m_history.end (); ++i)
   {
       if (seq == i->seq)
       { // Found it
           i->retx = true;
           break;
       }
   }

   // Note that a particular sequence has been sent
   if (i == m_history.end())
       m_history.push_back (RttHistory (seq, size, Simulator::Now () ));
 }

 Time RttMeanDeviation::AckSeq (SequenceNumber32 ackSeq)
 {
   NS_LOG_FUNCTION (this << ackSeq);
   // An ack has been received, calculate rtt and log this measurement
   // Note we use a linear search (O(n)) for this since for the common
   // case the ack'ed packet will be at the head of the list
   Time m = Seconds (0.0);
   if (m_history.size () == 0) return (m);    // No pending history, just exit

   for (RttHistory_t::iterator i = m_history.begin (); i != m_history.end (); ++i)
   {
       if (ackSeq == i->seq)
       { // Found it
           if (!i->retx) {
               m = Simulator::Now () - i->time;// Elapsed time
               Measurement (m);                // Log the measurement
               ResetMultiplier ();             // Reset multiplier on valid measurement
           }
           m_history.erase(i);
           break;
       }
   }

   return m;
 }

 } // namespace ndn
 } // namespace ns3
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -- */
	//
	// Copyright (c) 2006 Georgia Tech Research Corporation
	// (c) 2013 University of Arizona
	// (c) 2013 University of California, Los Angeles
	//
	// This program is free software; you can redistribute it and/or modify
	// it under the terms of the GNU General Public License version 2 as
	// published by the Free Software Foundation;
	//
	// This program is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.
	//
	// You should have received a copy of the GNU General Public License
	// along with this program; if not, write to the Free Software
	// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
	//
	// Author: Rajib Bhattacharjea<raj.b@gatech.edu>
	// Cheng Yi <yic@email.arizona.edu>
	// Alexander Afanasyev <alexander.afanasyev@ucla.edu>
	//

	// Georgia Tech Network Simulator - Round Trip Time Estimation Class
	// George F. Riley. Georgia Tech, Spring 2002

	#include "ndn-rtt-mean-deviation.h"
	#include "ns3/simulator.h"
	#include "ns3/double.h"
	#include "ns3/integer.h"
	#include "ns3/uinteger.h"
	#include "ns3/log.h"

	NS_LOG_COMPONENT_DEFINE ("ndn.RttMeanDeviation");

	namespace ns3 {
	namespace ndn {

	//---------------------------------------------------------------------------------
	// A modified version of Mean-Deviation Estimator optimized for NDN packet delivery

	NS_OBJECT_ENSURE_REGISTERED (RttMeanDeviation);

	TypeId
	RttMeanDeviation::GetTypeId (void)
	{
	static TypeId tid = TypeId ("ns3::ndn::RttMeanDeviation")
	.SetParent<RttEstimator> ()
	.AddConstructor<RttMeanDeviation> ()
	.AddAttribute ("Gain",
	"Gain used in estimating the RTT (smoothed RTT), must be 0 < Gain < 1",
	DoubleValue (0.125),
	MakeDoubleAccessor (&RttMeanDeviation::m_gain),
	MakeDoubleChecker<double> ())
	.AddAttribute ("Gain2",
	"Gain2 used in estimating the RTT (variance), must be 0 < Gain2 < 1",
	DoubleValue (0.25),
	MakeDoubleAccessor (&RttMeanDeviation::m_gain2),
	MakeDoubleChecker<double> ())
	;
	return tid;
	}

	RttMeanDeviation::RttMeanDeviation() :
	m_variance (0)
	{
	NS_LOG_FUNCTION (this);
	}

	RttMeanDeviation::RttMeanDeviation (const RttMeanDeviation& c)
	: RttEstimator (c), m_gain (c.m_gain), m_gain2 (c.m_gain2), m_variance (c.m_variance)
	{
	NS_LOG_FUNCTION (this);
	}

	TypeId
	RttMeanDeviation::GetInstanceTypeId (void) const
	{
	return GetTypeId ();
	}

	void RttMeanDeviation::Measurement (Time m)
	{
	NS_LOG_FUNCTION (this << m);
	if (m_nSamples)
	{ // Not first
	Time err (m - m_currentEstimatedRtt);
	double gErr = err.ToDouble (Time::S) * m_gain;
	m_currentEstimatedRtt += Time::FromDouble (gErr, Time::S);
	Time difference = Abs (err) - m_variance;
	NS_LOG_DEBUG ("m_variance += " << Time::FromDouble (difference.ToDouble (Time::S) * m_gain2, Time::S));
	m_variance += Time::FromDouble (difference.ToDouble (Time::S) * m_gain2, Time::S);
	}
	else
	{ // First sample
	m_currentEstimatedRtt = m; // Set estimate to current
	//variance = sample / 2; // And variance to current / 2
	// m_variance = m; // try this why????
	m_variance = Seconds (m.ToDouble (Time::S) / 2);
	NS_LOG_DEBUG ("(first sample) m_variance += " << m);
	}
	m_nSamples++;
	}

	Time RttMeanDeviation::RetransmitTimeout ()
	{
	NS_LOG_FUNCTION (this);

	double retval = std::min (m_maxRto.ToDouble (Time::S),
	std::max (m_multiplier*m_minRto.ToDouble (Time::S),
	m_multiplier(m_currentEstimatedRtt.ToDouble (Time::S) + 4 m_variance.ToDouble (Time::S))));

	NS_LOG_DEBUG ("RetransmitTimeout: return " << retval);

	return Seconds (retval);
	}

	Ptr<RttEstimator> RttMeanDeviation::Copy () const
	{
	NS_LOG_FUNCTION (this);
	return CopyObject<RttMeanDeviation> (this);
	}

	void RttMeanDeviation::Reset ()
	{
	NS_LOG_FUNCTION (this);
	// Reset to initial state
	m_variance = Seconds (0);
	RttEstimator::Reset ();
	}

	void RttMeanDeviation::Gain (double g)
	{
	NS_LOG_FUNCTION (this);
	NS_ASSERT_MSG( (g > 0) && (g < 1), "RttMeanDeviation: Gain must be less than 1 and greater than 0" );
	m_gain = g;
	}

	void RttMeanDeviation::SentSeq (SequenceNumber32 seq, uint32_t size)
	{
	NS_LOG_FUNCTION (this << seq << size);

	RttHistory_t::iterator i;
	for (i = m_history.begin (); i != m_history.end (); ++i)
	{
	if (seq == i->seq)
	{ // Found it
	i->retx = true;
	break;
	}
	}

	// Note that a particular sequence has been sent
	if (i == m_history.end())
	m_history.push_back (RttHistory (seq, size, Simulator::Now () ));
	}

	Time RttMeanDeviation::AckSeq (SequenceNumber32 ackSeq)
	{
	NS_LOG_FUNCTION (this << ackSeq);
	// An ack has been received, calculate rtt and log this measurement
	// Note we use a linear search (O(n)) for this since for the common
	// case the ack'ed packet will be at the head of the list
	Time m = Seconds (0.0);
	if (m_history.size () == 0) return (m); // No pending history, just exit

	for (RttHistory_t::iterator i = m_history.begin (); i != m_history.end (); ++i)
	{
	if (ackSeq == i->seq)
	{ // Found it
	if (!i->retx) {
	m = Simulator::Now () - i->time;// Elapsed time
	Measurement (m); // Log the measurement
	ResetMultiplier (); // Reset multiplier on valid measurement
	}
	m_history.erase(i);
	break;
	}
	}

	return m;
	}

	} // namespace ndn
	} // namespace ns3