/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/*
* Copyright (c) 2005,2006 INRIA
*
* 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
*
* Authors: Mathieu Lacage <mathieu.lacage@sophia.inria.fr>
* Sébastien Deronne <sebastien.deronne@gmail.com>
*/
#ifndef WIFI_PHY_H
#define WIFI_PHY_H
#include <stdint.h>
#include <map>
#include "ns3/callback.h"
#include "ns3/packet.h"
#include "ns3/object.h"
#include "ns3/nstime.h"
#include "ns3/ptr.h"
#include "wifi-mode.h"
#include "wifi-preamble.h"
#include "wifi-phy-standard.h"
#include "ns3/traced-callback.h"
#include "wifi-tx-vector.h"
#include "wifi-phy-standard.h"
namespace ns3 {
class WifiChannel;
class NetDevice;
/**
* This enumeration defines the type of an MPDU.
*/
enum mpduType
{
/** The MPDU is not part of an A-MPDU */
NORMAL_MPDU = 0,
/** The MPDU is part of an A-MPDU, but is not the last aggregate */
MPDU_IN_AGGREGATE,
/** The MPDU is the last aggregate in an A-MPDU */
LAST_MPDU_IN_AGGREGATE
};
struct signalNoiseDbm
{
double signal; //in dBm
double noise; //in dBm
};
struct mpduInfo
{
enum mpduType type;
uint32_t mpduRefNumber;
};
/**
* \brief receive notifications about phy events.
*/
class WifiPhyListener
{
public:
virtual ~WifiPhyListener ();
/**
* \param duration the expected duration of the packet reception.
*
* We have received the first bit of a packet. We decided
* that we could synchronize on this packet. It does not mean
* we will be able to successfully receive completely the
* whole packet. It means that we will report a BUSY status until
* one of the following happens:
* - NotifyRxEndOk
* - NotifyRxEndError
* - NotifyTxStart
*/
virtual void NotifyRxStart (Time duration) = 0;
/**
* We have received the last bit of a packet for which
* NotifyRxStart was invoked first and, the packet has
* been successfully received.
*/
virtual void NotifyRxEndOk (void) = 0;
/**
* We have received the last bit of a packet for which
* NotifyRxStart was invoked first and, the packet has
* _not_ been successfully received.
*/
virtual void NotifyRxEndError (void) = 0;
/**
* \param duration the expected transmission duration.
* \param txPowerDbm the nominal tx power in dBm
*
* We are about to send the first bit of the packet.
* We do not send any event to notify the end of
* transmission. Listeners should assume that the
* channel implicitely reverts to the idle state
* unless they have received a cca busy report.
*/
virtual void NotifyTxStart (Time duration, double txPowerDbm) = 0;
/**
* \param duration the expected busy duration.
*
* This method does not really report a real state
* change as opposed to the other methods in this class.
* It merely reports that, unless the medium is reported
* busy through NotifyTxStart or NotifyRxStart/End,
* it will be busy as defined by the currently selected
* CCA mode.
*
* Typical client code which wants to have a clear picture
* of the CCA state will need to keep track of the time at
* which the last NotifyCcaBusyStart method is called and
* what duration it reported.
*/
virtual void NotifyMaybeCcaBusyStart (Time duration) = 0;
/**
* \param duration the expected channel switching duration.
*
* We do not send any event to notify the end of
* channel switching. Listeners should assume that the
* channel implicitely reverts to the idle or busy states.
*/
virtual void NotifySwitchingStart (Time duration) = 0;
/**
* Notify listeners that we went to sleep
*/
virtual void NotifySleep (void) = 0;
/**
* Notify listeners that we woke up
*/
virtual void NotifyWakeup (void) = 0;
};
/**
* \brief 802.11 PHY layer model
* \ingroup wifi
*
*/
class WifiPhy : public Object
{
public:
/**
* The state of the PHY layer.
*/
enum State
{
/**
* The PHY layer is IDLE.
*/
IDLE,
/**
* The PHY layer has sense the medium busy through the CCA mechanism
*/
CCA_BUSY,
/**
* The PHY layer is sending a packet.
*/
TX,
/**
* The PHY layer is receiving a packet.
*/
RX,
/**
* The PHY layer is switching to other channel.
*/
SWITCHING,
/**
* The PHY layer is sleeping.
*/
SLEEP
};
/**
* arg1: packet received successfully
* arg2: snr of packet
* arg3: TXVECTOR of packet
* arg4: type of preamble used for packet.
*/
typedef Callback<void, Ptr<Packet>, double, WifiTxVector, enum WifiPreamble> RxOkCallback;
/**
* arg1: packet received unsuccessfully
* arg2: snr of packet
*/
typedef Callback<void, Ptr<Packet>, double> RxErrorCallback;
static TypeId GetTypeId (void);
WifiPhy ();
virtual ~WifiPhy ();
/**
* Return the minimum available transmission power level (dBm).
*
* \return the minimum available transmission power level in dBm
*/
virtual double GetTxPowerStart (void) const = 0;
/**
* Return the maximum available transmission power level (dBm).
*
* \return the maximum available transmission power level in dBm
*/
virtual double GetTxPowerEnd (void) const = 0;
/**
* \return the number of tx power levels available for this PHY.
*/
virtual uint32_t GetNTxPower (void) const = 0;
/**
* \param callback the callback to invoke
* upon successful packet reception.
*/
virtual void SetReceiveOkCallback (RxOkCallback callback) = 0;
/**
* \param callback the callback to invoke
* upon erroneous packet reception.
*/
virtual void SetReceiveErrorCallback (RxErrorCallback callback) = 0;
/**
* \param packet the packet to send
* \param txVector the TXVECTOR that has tx parameters such as mode, the transmission mode to use to send
* this packet, and txPowerLevel, a power level to use to send this packet. The real transmission
* power is calculated as txPowerMin + txPowerLevel * (txPowerMax - txPowerMin) / nTxLevels
* \param preamble the type of preamble to use to send this packet.
*/
virtual void SendPacket (Ptr<const Packet> packet, WifiTxVector txVector, enum WifiPreamble preamble) = 0;
/**
* \param packet the packet to send
* \param txVector the TXVECTOR that has tx parameters such as mode, the transmission mode to use to send
* this packet, and txPowerLevel, a power level to use to send this packet. The real transmission
* power is calculated as txPowerMin + txPowerLevel * (txPowerMax - txPowerMin) / nTxLevels
* \param preamble the type of preamble to use to send this packet.
* \param mpdutype the type of the MPDU as defined in WifiPhy::mpduType.
*/
virtual void SendPacket (Ptr<const Packet> packet, WifiTxVector txVector, enum WifiPreamble preamble, enum mpduType mpdutype) = 0;
/**
* \param listener the new listener
*
* Add the input listener to the list of objects to be notified of
* PHY-level events.
*/
virtual void RegisterListener (WifiPhyListener *listener) = 0;
/**
* \param listener the listener to be unregistered
*
* Remove the input listener from the list of objects to be notified of
* PHY-level events.
*/
virtual void UnregisterListener (WifiPhyListener *listener) = 0;
/**
* Put in sleep mode.
*/
virtual void SetSleepMode (void) = 0;
/**
* Resume from sleep mode.
*/
virtual void ResumeFromSleep (void) = 0;
/**
* \return true of the current state of the PHY layer is WifiPhy::IDLE, false otherwise.
*/
virtual bool IsStateIdle (void) = 0;
/**
* \return true of the current state of the PHY layer is WifiPhy::CCA_BUSY, false otherwise.
*/
virtual bool IsStateCcaBusy (void) = 0;
/**
* \return true of the current state of the PHY layer is not WifiPhy::IDLE, false otherwise.
*/
virtual bool IsStateBusy (void) = 0;
/**
* \return true of the current state of the PHY layer is WifiPhy::RX, false otherwise.
*/
virtual bool IsStateRx (void) = 0;
/**
* \return true of the current state of the PHY layer is WifiPhy::TX, false otherwise.
*/
virtual bool IsStateTx (void) = 0;
/**
* \return true of the current state of the PHY layer is WifiPhy::SWITCHING, false otherwise.
*/
virtual bool IsStateSwitching (void) = 0;
/**
* \return true if the current state of the PHY layer is WifiPhy::SLEEP, false otherwise.
*/
virtual bool IsStateSleep (void) = 0;
/**
* \return the amount of time since the current state has started.
*/
virtual Time GetStateDuration (void) = 0;
/**
* \return the predicted delay until this PHY can become WifiPhy::IDLE.
*
* The PHY will never become WifiPhy::IDLE _before_ the delay returned by
* this method but it could become really idle later.
*/
virtual Time GetDelayUntilIdle (void) = 0;
/**
* Return the start time of the last received packet.
*
* \return the start time of the last received packet
*/
virtual Time GetLastRxStartTime (void) const = 0;
/**
* \param size the number of bytes in the packet to send
* \param txVector the TXVECTOR used for the transmission of this packet
* \param preamble the type of preamble to use for this packet.
* \param frequency the channel center frequency (MHz)
*
* \return the total amount of time this PHY will stay busy for the transmission of these bytes.
*/
Time CalculateTxDuration (uint32_t size, WifiTxVector txVector, enum WifiPreamble preamble, double frequency);
/**
* \param size the number of bytes in the packet to send
* \param txVector the TXVECTOR used for the transmission of this packet
* \param preamble the type of preamble to use for this packet.
* \param frequency the channel center frequency (MHz)
* \param mpdutype the type of the MPDU as defined in WifiPhy::mpduType.
* \param incFlag this flag is used to indicate that the static variables need to be update or not. This function is called a couple of times for the same packet so static variables should not be increased each time.
*
* \return the total amount of time this PHY will stay busy for the transmission of these bytes.
*/
Time CalculateTxDuration (uint32_t size, WifiTxVector txVector, enum WifiPreamble preamble, double frequency, enum mpduType mpdutype, uint8_t incFlag);
/**
* \param txVector the transmission parameters used for this packet
* \param preamble the type of preamble to use for this packet.
*
* \return the total amount of time this PHY will stay busy for the transmission of the PLCP preamble and PLCP header.
*/
Time CalculatePlcpPreambleAndHeaderDuration (WifiTxVector txVector, enum WifiPreamble preamble);
/**
* \param preamble the type of preamble
* \param txVector the transmission parameters used for this packet
*
* \return the training symbol duration
*/
static Time GetPlcpHtTrainingSymbolDuration (WifiPreamble preamble, WifiTxVector txVector);
/**
* \param payloadMode the WifiMode use for the transmission of the payload
*
* \return the WifiMode used for the transmission of the HT-SIG and the HT training fields
* in Mixed Format and greenfield format PLCP header
*/
static WifiMode GetHtPlcpHeaderMode (WifiMode payloadMode);
/**
* \param payloadMode the WifiMode use for the transmission of the payload
*
* \return the WifiMode used for the transmission of the VHT-STF, VHT-LTF and VHT-SIG-B fields
*/
static WifiMode GetVhtPlcpHeaderMode (WifiMode payloadMode);
/**
* \param preamble the type of preamble
*
* \return the duration of the HT-SIG in Mixed Format and greenfield format PLCP header
*/
static Time GetPlcpHtSigHeaderDuration (WifiPreamble preamble);
/**
* \param preamble the type of preamble
*
* \return the duration of the VHT-SIG-A1 in PLCP header
*/
static Time GetPlcpVhtSigA1Duration (WifiPreamble preamble);
/**
* \param preamble the type of preamble
*
* \return the duration of the VHT-SIG-A2 in PLCP header
*/
static Time GetPlcpVhtSigA2Duration (WifiPreamble preamble);
/**
* \param preamble the type of preamble
*
* \return the duration of the VHT-SIG-B in PLCP header
*/
static Time GetPlcpVhtSigBDuration (WifiPreamble preamble);
/**
* \param payloadMode the WifiMode use for the transmission of the payload
* \param preamble the type of preamble
* \param txVector the transmission parameters used for this packet
*
* \return the WifiMode used for the transmission of the PLCP header
*/
static WifiMode GetPlcpHeaderMode (WifiMode payloadMode, WifiPreamble preamble, WifiTxVector txVector);
/**
* \param txVector the transmission parameters used for this packet
* \param preamble the type of preamble
*
* \return the duration of the PLCP header
*/
static Time GetPlcpHeaderDuration (WifiTxVector txVector, WifiPreamble preamble);
/**
* \param txVector the transmission parameters used for this packet
* \param preamble the type of preamble
*
* \return the duration of the PLCP preamble
*/
static Time GetPlcpPreambleDuration (WifiTxVector txVector, WifiPreamble preamble);
/**
* \param size the number of bytes in the packet to send
* \param txVector the TXVECTOR used for the transmission of this packet
* \param preamble the type of preamble to use for this packet
* \param frequency the channel center frequency (MHz)
*
* \return the duration of the payload
*/
Time GetPayloadDuration (uint32_t size, WifiTxVector txVector, WifiPreamble preamble, double frequency);
/**
* \param size the number of bytes in the packet to send
* \param txVector the TXVECTOR used for the transmission of this packet
* \param preamble the type of preamble to use for this packet
* \param frequency the channel center frequency (MHz)
* \param mpdutype the type of the MPDU as defined in WifiPhy::mpduType.
* \param incFlag this flag is used to indicate that the static variables need to be update or not. This function is called a couple of times for the same packet so static variables should not be increased each time
*
* \return the duration of the payload
*/
Time GetPayloadDuration (uint32_t size, WifiTxVector txVector, WifiPreamble preamble, double frequency, enum mpduType mpdutype, uint8_t incFlag);
/**
* The WifiPhy::GetNModes() and WifiPhy::GetMode() methods are used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception modes that this WifiPhy(-derived class)
* can support - a set of WifiMode objects which we call the
* DeviceRateSet, and which is stored as WifiPhy::m_deviceRateSet.
*
* It is important to note that the DeviceRateSet is a superset (not
* necessarily proper) of the OperationalRateSet (which is
* logically, if not actually, a property of the associated
* WifiRemoteStationManager), which itself is a superset (again, not
* necessarily proper) of the BSSBasicRateSet.
*
* \return the number of transmission modes supported by this PHY.
*
* \sa WifiPhy::GetMode()
*/
virtual uint32_t GetNModes (void) const = 0;
/**
* The WifiPhy::GetNModes() and WifiPhy::GetMode() methods are used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception modes that this WifiPhy(-derived class)
* can support - a set of WifiMode objects which we call the
* DeviceRateSet, and which is stored as WifiPhy::m_deviceRateSet.
*
* It is important to note that the DeviceRateSet is a superset (not
* necessarily proper) of the OperationalRateSet (which is
* logically, if not actually, a property of the associated
* WifiRemoteStationManager), which itself is a superset (again, not
* necessarily proper) of the BSSBasicRateSet.
*
* \param mode index in array of supported modes
*
* \return the mode whose index is specified.
*
* \sa WifiPhy::GetNModes()
*/
virtual WifiMode GetMode (uint32_t mode) const = 0;
/**
* Check if the given WifiMode is supported by the PHY.
*
* \param mode the wifi mode to check
*
* \return true if the given mode is supported,
* false otherwise
*/
virtual bool IsModeSupported (WifiMode mode) const = 0;
/**
* \param txVector the transmission vector
* \param ber the probability of bit error rate
*
* \return the minimum snr which is required to achieve
* the requested ber for the specified transmission vector. (W/W)
*/
virtual double CalculateSnr (WifiTxVector txVector, double ber) const = 0;
/**
* The WifiPhy::NBssMembershipSelectors() method is used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception modes that this WifiPhy(-derived class)
* can support - a set of WifiMode objects which we call the
* BssMembershipSelectorSet, and which is stored as WifiPhy::m_bssMembershipSelectorSet.
*
* \return the memebership selector whose index is specified.
*/
virtual uint32_t GetNBssMembershipSelectors (void) const = 0;
/**
* The WifiPhy::BssMembershipSelector() method is used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception modes that this WifiPhy(-derived class)
* can support - a set of WifiMode objects which we call the
* BssMembershipSelectorSet, and which is stored as WifiPhy::m_bssMembershipSelectorSet.
*
* \param selector index in array of supported memberships
*
* \return the memebership selector whose index is specified.
*/
virtual uint32_t GetBssMembershipSelector (uint32_t selector) const = 0;
/**
* The WifiPhy::GetMembershipSelectorModes() method is used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception modes that this WifiPhy(-derived class)
* can support - a set of WifiMode objects which we call the
* BssMembershipSelectorSet, and which is stored as WifiPhy::m_bssMembershipSelectorSet.
*
* \param selector index in array of supported memberships
*
* \return a WifiModeList that contains the WifiModes associrated with the selected index.
*
* \sa WifiPhy::GetMembershipSelectorModes()
*/
virtual WifiModeList GetMembershipSelectorModes (uint32_t selector) = 0;
/**
* The WifiPhy::GetNMcs() method is used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception MCS indexes that this WifiPhy(-derived class)
* can support - a set of MCS indexes which we call the
* DeviceMcsSet, and which is stored as WifiPhy::m_deviceMcsSet.
*
* \return the MCS index whose index is specified.
*/
virtual uint8_t GetNMcs (void) const = 0;
/**
* The WifiPhy::GetMcs() method is used
* (e.g., by a WifiRemoteStationManager) to determine the set of
* transmission/reception MCS indexes that this WifiPhy(-derived class)
* can support - a set of MCS indexes which we call the
* DeviceMcsSet, and which is stored as WifiPhy::m_deviceMcsSet.
*
* \param mcs index in array of supported MCS
*
* \return the MCS index whose index is specified.
*/
virtual WifiMode GetMcs (uint8_t mcs) const = 0;
/**
* \brief Set channel number.
*
* Channel center frequency = Channel starting frequency + 5 MHz * (nch - 1)
*
* where Starting channel frequency is standard-dependent, see SetStandard()
* as defined in (Section 18.3.8.4.2 "Channel numbering"; IEEE Std 802.11-2012).
* This method may fail to take action if the Phy model determines that
* the channel number cannot be switched for some reason (e.g. sleep state)
*
* \param id the channel number
*/
virtual void SetChannelNumber (uint16_t id);
/**
* Return current channel number.
*
* \return the current channel number
*/
virtual uint16_t GetChannelNumber (void) const;
/**
* \return the required time for channel switch operation of this WifiPhy
*/
virtual Time GetChannelSwitchDelay (void) const = 0;
/**
* Configure the PHY-level parameters for different Wi-Fi standard.
*
* \param standard the Wi-Fi standard
*/
virtual void ConfigureStandard (enum WifiPhyStandard standard);
/**
* Get the configured Wi-Fi standard
*
* \return the Wi-Fi standard that has been configured
*/
virtual enum WifiPhyStandard GetStandard (void) const;
/**
* Add a channel definition to the WifiPhy. The pair (channelNumber,
* WifiPhyStandard) may then be used to lookup a pair (frequency,
* channelWidth).
*
* If the channel is not already defined for the standard, the method
* should return true; otherwise false.
*
* \param channelNumber the channel number to define
* \param standard the applicable WifiPhyStandard
* \param frequency the frequency (MHz)
* \param channelWidth the channel width (MHz)
*
* \return true if the channel definition succeeded
*/
bool DefineChannelNumber (uint16_t channelNumber, enum WifiPhyStandard standard, uint32_t frequency, uint32_t channelWidth);
/**
* A pair of a ChannelNumber and WifiPhyStandard
*/
typedef std::pair<uint16_t, enum WifiPhyStandard> ChannelNumberStandardPair;
/**
* A pair of a center Frequency and a ChannelWidth
*/
typedef std::pair<uint32_t, uint32_t> FrequencyWidthPair;
/**
* Return the WifiChannel this WifiPhy is connected to.
*
* \return the WifiChannel this WifiPhy is connected to
*/
virtual Ptr<WifiChannel> GetChannel (void) const = 0;
/**
* Return a WifiMode for DSSS at 1Mbps.
*
* \return a WifiMode for DSSS at 1Mbps
*/
static WifiMode GetDsssRate1Mbps ();
/**
* Return a WifiMode for DSSS at 2Mbps.
*
* \return a WifiMode for DSSS at 2Mbps
*/
static WifiMode GetDsssRate2Mbps ();
/**
* Return a WifiMode for DSSS at 5.5Mbps.
*
* \return a WifiMode for DSSS at 5.5Mbps
*/
static WifiMode GetDsssRate5_5Mbps ();
/**
* Return a WifiMode for DSSS at 11Mbps.
*
* \return a WifiMode for DSSS at 11Mbps
*/
static WifiMode GetDsssRate11Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 6Mbps.
*
* \return a WifiMode for ERP-OFDM at 6Mbps
*/
static WifiMode GetErpOfdmRate6Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 9Mbps.
*
* \return a WifiMode for ERP-OFDM at 9Mbps
*/
static WifiMode GetErpOfdmRate9Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 12Mbps.
*
* \return a WifiMode for ERP-OFDM at 12Mbps
*/
static WifiMode GetErpOfdmRate12Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 18Mbps.
*
* \return a WifiMode for ERP-OFDM at 18Mbps
*/
static WifiMode GetErpOfdmRate18Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 24Mbps.
*
* \return a WifiMode for ERP-OFDM at 24Mbps
*/
static WifiMode GetErpOfdmRate24Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 36Mbps.
*
* \return a WifiMode for ERP-OFDM at 36Mbps
*/
static WifiMode GetErpOfdmRate36Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 48Mbps.
*
* \return a WifiMode for ERP-OFDM at 48Mbps
*/
static WifiMode GetErpOfdmRate48Mbps ();
/**
* Return a WifiMode for ERP-OFDM at 54Mbps.
*
* \return a WifiMode for ERP-OFDM at 54Mbps
*/
static WifiMode GetErpOfdmRate54Mbps ();
/**
* Return a WifiMode for OFDM at 6Mbps.
*
* \return a WifiMode for OFDM at 6Mbps
*/
static WifiMode GetOfdmRate6Mbps ();
/**
* Return a WifiMode for OFDM at 9Mbps.
*
* \return a WifiMode for OFDM at 9Mbps
*/
static WifiMode GetOfdmRate9Mbps ();
/**
* Return a WifiMode for OFDM at 12Mbps.
*
* \return a WifiMode for OFDM at 12Mbps
*/
static WifiMode GetOfdmRate12Mbps ();
/**
* Return a WifiMode for OFDM at 18Mbps.
*
* \return a WifiMode for OFDM at 18Mbps
*/
static WifiMode GetOfdmRate18Mbps ();
/**
* Return a WifiMode for OFDM at 24Mbps.
*
* \return a WifiMode for OFDM at 24Mbps
*/
static WifiMode GetOfdmRate24Mbps ();
/**
* Return a WifiMode for OFDM at 36Mbps.
*
* \return a WifiMode for OFDM at 36Mbps
*/
static WifiMode GetOfdmRate36Mbps ();
/**
* Return a WifiMode for OFDM at 48Mbps.
*
* \return a WifiMode for OFDM at 48Mbps
*/
static WifiMode GetOfdmRate48Mbps ();
/**
* Return a WifiMode for OFDM at 54Mbps.
*
* \return a WifiMode for OFDM at 54Mbps
*/
static WifiMode GetOfdmRate54Mbps ();
/**
* Return a WifiMode for OFDM at 3Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 3Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate3MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 4.5Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 4.5Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate4_5MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 6Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 6Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate6MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 9Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 9Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate9MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 12Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 12Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate12MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 18Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 18Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate18MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 24Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 24Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate24MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 27Mbps with 10MHz channel spacing.
*
* \return a WifiMode for OFDM at 27Mbps with 10MHz channel spacing
*/
static WifiMode GetOfdmRate27MbpsBW10MHz ();
/**
* Return a WifiMode for OFDM at 1.5Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 1.5Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate1_5MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 2.25Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 2.25Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate2_25MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 3Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 3Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate3MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 4.5Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 4.5Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate4_5MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 6Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 6Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate6MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 9Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 9Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate9MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 12Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 12Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate12MbpsBW5MHz ();
/**
* Return a WifiMode for OFDM at 13.5Mbps with 5MHz channel spacing.
*
* \return a WifiMode for OFDM at 13.5Mbps with 5MHz channel spacing
*/
static WifiMode GetOfdmRate13_5MbpsBW5MHz ();
/**
* Return MCS 0 from HT MCS values.
*
* \return MCS 0 from HT MCS values
*/
static WifiMode GetHtMcs0 ();
/**
* Return MCS 1 from HT MCS values.
*
* \return MCS 1 from HT MCS values
*/
static WifiMode GetHtMcs1 ();
/**
* Return MCS 2 from HT MCS values.
*
* \return MCS 2 from HT MCS values
*/
static WifiMode GetHtMcs2 ();
/**
* Return MCS 3 from HT MCS values.
*
* \return MCS 3 from HT MCS values
*/
static WifiMode GetHtMcs3 ();
/**
* Return MCS 4 from HT MCS values.
*
* \return MCS 4 from HT MCS values
*/
static WifiMode GetHtMcs4 ();
/**
* Return MCS 5 from HT MCS values.
*
* \return MCS 5 from HT MCS values
*/
static WifiMode GetHtMcs5 ();
/**
* Return MCS 6 from HT MCS values.
*
* \return MCS 6 from HT MCS values
*/
static WifiMode GetHtMcs6 ();
/**
* Return MCS 7 from HT MCS values.
*
* \return MCS 7 from HT MCS values
*/
static WifiMode GetHtMcs7 ();
/**
* Return MCS 8 from HT MCS values.
*
* \return MCS 8 from HT MCS values
*/
static WifiMode GetHtMcs8 ();
/**
* Return MCS 9 from HT MCS values.
*
* \return MCS 9 from HT MCS values
*/
static WifiMode GetHtMcs9 ();
/**
* Return MCS 10 from HT MCS values.
*
* \return MCS 10 from HT MCS values
*/
static WifiMode GetHtMcs10 ();
/**
* Return MCS 11 from HT MCS values.
*
* \return MCS 11 from HT MCS values
*/
static WifiMode GetHtMcs11 ();
/**
* Return MCS 12 from HT MCS values.
*
* \return MCS 12 from HT MCS values
*/
static WifiMode GetHtMcs12 ();
/**
* Return MCS 13 from HT MCS values.
*
* \return MCS 13 from HT MCS values
*/
static WifiMode GetHtMcs13 ();
/**
* Return MCS 14 from HT MCS values.
*
* \return MCS 14 from HT MCS values
*/
static WifiMode GetHtMcs14 ();
/**
* Return MCS 15 from HT MCS values.
*
* \return MCS 15 from HT MCS values
*/
static WifiMode GetHtMcs15 ();
/**
* Return MCS 16 from HT MCS values.
*
* \return MCS 16 from HT MCS values
*/
static WifiMode GetHtMcs16 ();
/**
* Return MCS 17 from HT MCS values.
*
* \return MCS 17 from HT MCS values
*/
static WifiMode GetHtMcs17 ();
/**
* Return MCS 18 from HT MCS values.
*
* \return MCS 18 from HT MCS values
*/
static WifiMode GetHtMcs18 ();
/**
* Return MCS 19 from HT MCS values.
*
* \return MCS 19 from HT MCS values
*/
static WifiMode GetHtMcs19 ();
/**
* Return MCS 20 from HT MCS values.
*
* \return MCS 20 from HT MCS values
*/
static WifiMode GetHtMcs20 ();
/**
* Return MCS 21 from HT MCS values.
*
* \return MCS 21 from HT MCS values
*/
static WifiMode GetHtMcs21 ();
/**
* Return MCS 22 from HT MCS values.
*
* \return MCS 22 from HT MCS values
*/
static WifiMode GetHtMcs22 ();
/**
* Return MCS 23 from HT MCS values.
*
* \return MCS 23 from HT MCS values
*/
static WifiMode GetHtMcs23 ();
/**
* Return MCS 24 from HT MCS values.
*
* \return MCS 24 from HT MCS values
*/
static WifiMode GetHtMcs24 ();
/**
* Return MCS 25 from HT MCS values.
*
* \return MCS 25 from HT MCS values
*/
static WifiMode GetHtMcs25 ();
/**
* Return MCS 26 from HT MCS values.
*
* \return MCS 26 from HT MCS values
*/
static WifiMode GetHtMcs26 ();
/**
* Return MCS 27 from HT MCS values.
*
* \return MCS 27 from HT MCS values
*/
static WifiMode GetHtMcs27 ();
/**
* Return MCS 28 from HT MCS values.
*
* \return MCS 28 from HT MCS values
*/
static WifiMode GetHtMcs28 ();
/**
* Return MCS 29 from HT MCS values.
*
* \return MCS 29 from HT MCS values
*/
static WifiMode GetHtMcs29 ();
/**
* Return MCS 30 from HT MCS values.
*
* \return MCS 30 from HT MCS values
*/
static WifiMode GetHtMcs30 ();
/**
* Return MCS 31 from HT MCS values.
*
* \return MCS 31 from HT MCS values
*/
static WifiMode GetHtMcs31 ();
/**
* Return MCS 0 from VHT MCS values.
*
* \return MCS 0 from VHT MCS values
*/
static WifiMode GetVhtMcs0 ();
/**
* Return MCS 1 from VHT MCS values.
*
* \return MCS 1 from VHT MCS values
*/
static WifiMode GetVhtMcs1 ();
/**
* Return MCS 2 from VHT MCS values.
*
* \return MCS 2 from VHT MCS values
*/
static WifiMode GetVhtMcs2 ();
/**
* Return MCS 3 from VHT MCS values.
*
* \return MCS 3 from VHT MCS values
*/
static WifiMode GetVhtMcs3 ();
/**
* Return MCS 4 from VHT MCS values.
*
* \return MCS 4 from VHT MCS values
*/
static WifiMode GetVhtMcs4 ();
/**
* Return MCS 5 from VHT MCS values.
*
* \return MCS 5 from VHT MCS values
*/
static WifiMode GetVhtMcs5 ();
/**
* Return MCS 6 from VHT MCS values.
*
* \return MCS 6 from VHT MCS values
*/
static WifiMode GetVhtMcs6 ();
/**
* Return MCS 7 from VHT MCS values.
*
* \return MCS 7 from VHT MCS values
*/
static WifiMode GetVhtMcs7 ();
/**
* Return MCS 8 from VHT MCS values.
*
* \return MCS 8 from VHT MCS values
*/
static WifiMode GetVhtMcs8 ();
/**
* Return MCS 9 from VHT MCS values.
*
* \return MCS 9 from VHT MCS values
*/
static WifiMode GetVhtMcs9 ();
/**
* The standard disallows certain combinations of WifiMode, number of
* spatial streams, and channel widths. This method can be used to
* check whether this WifiTxVector contains an invalid combination.
*
* \param txVector the WifiTxVector to inspect
* \return true if the WifiTxVector parameters are allowed by the standard
*/
static bool IsValidTxVector (WifiTxVector txVector);
/**
* Public method used to fire a PhyTxBegin trace.
* Implemented for encapsulation purposes.
*
* \param packet the packet being transmitted
*/
void NotifyTxBegin (Ptr<const Packet> packet);
/**
* Public method used to fire a PhyTxEnd trace.
* Implemented for encapsulation purposes.
*
* \param packet the packet that was transmitted
*/
void NotifyTxEnd (Ptr<const Packet> packet);
/**
* Public method used to fire a PhyTxDrop trace.
* Implemented for encapsulation purposes.
*
* \param packet the packet that was failed to transmitted
*/
void NotifyTxDrop (Ptr<const Packet> packet);
/**
* Public method used to fire a PhyRxBegin trace.
* Implemented for encapsulation purposes.
*
* \param packet the packet being received
*/
void NotifyRxBegin (Ptr<const Packet> packet);
/**
* Public method used to fire a PhyRxEnd trace.
* Implemented for encapsulation purposes.
*
* \param packet the packet received
*/
void NotifyRxEnd (Ptr<const Packet> packet);
/**
* Public method used to fire a PhyRxDrop trace.
* Implemented for encapsulation purposes.
*
* \param packet the packet that was not successfully received
*/
void NotifyRxDrop (Ptr<const Packet> packet);
/**
* Public method used to fire a MonitorSniffer trace for a wifi packet being received.
* Implemented for encapsulation purposes.
*
* \param packet the packet being received
* \param channelFreqMhz the frequency in MHz at which the packet is
* received. Note that in real devices this is normally the
* frequency to which the receiver is tuned, and this can be
* different than the frequency at which the packet was originally
* transmitted. This is because it is possible to have the receiver
* tuned on a given channel and still to be able to receive packets
* on a nearby channel.
* \param channelNumber the channel on which the packet is received
* \param rate the PHY data rate in units of 500kbps (i.e., the same
* units used both for the radiotap and for the prism header)
* \param preamble the preamble of the packet
* \param txVector the TXVECTOR that holds rx parameters
* \param aMpdu the type of the packet (0 is not A-MPDU, 1 is a MPDU that is part of an A-MPDU and 2 is the last MPDU in an A-MPDU)
* and the A-MPDU reference number (must be a different value for each A-MPDU but the same for each subframe within one A-MPDU)
* \param signalNoise signal power and noise power in dBm
*/
void NotifyMonitorSniffRx (Ptr<const Packet> packet, uint16_t channelFreqMhz,
uint16_t channelNumber, uint32_t rate, WifiPreamble preamble,
WifiTxVector txVector, struct mpduInfo aMpdu, struct signalNoiseDbm signalNoise);
/**
* TracedCallback signature for monitor mode receive events.
*
*
* \param packet the packet being received
* \param channelFreqMhz the frequency in MHz at which the packet is
* received. Note that in real devices this is normally the
* frequency to which the receiver is tuned, and this can be
* different than the frequency at which the packet was originally
* transmitted. This is because it is possible to have the receiver
* tuned on a given channel and still to be able to receive packets
* on a nearby channel.
* \param channelNumber the channel on which the packet is received
* \param rate the PHY data rate in units of 500kbps (i.e., the same
* units used both for the radiotap and for the prism header)
* \param preamble the preamble of the packet
* \param txVector the TXVECTOR that holds rx parameters
* \param aMpdu the type of the packet (0 is not A-MPDU, 1 is a MPDU that is part of an A-MPDU and 2 is the last MPDU in an A-MPDU)
* and the A-MPDU reference number (must be a different value for each A-MPDU but the same for each subframe within one A-MPDU)
* \param signalNoise signal power and noise power in dBm
* \todo WifiTxVector should be passed by const reference because
* of its size.
*/
typedef void (* MonitorSnifferRxCallback)(Ptr<const Packet> packet, uint16_t channelFreqMhz,
uint16_t channelNumber, uint32_t rate, WifiPreamble preamble,
WifiTxVector txVector, struct mpduInfo aMpdu, struct signalNoiseDbm signalNoise);
/**
* Public method used to fire a MonitorSniffer trace for a wifi packet being transmitted.
* Implemented for encapsulation purposes.
*
* \param packet the packet being transmitted
* \param channelFreqMhz the frequency in MHz at which the packet is
* transmitted.
* \param channelNumber the channel on which the packet is transmitted
* \param rate the PHY data rate in units of 500kbps (i.e., the same
* units used both for the radiotap and for the prism header)
* \param preamble the preamble of the packet
* \param txVector the TXVECTOR that holds tx parameters
* \param aMpdu the type of the packet (0 is not A-MPDU, 1 is a MPDU that is part of an A-MPDU and 2 is the last MPDU in an A-MPDU)
* and the A-MPDU reference number (must be a different value for each A-MPDU but the same for each subframe within one A-MPDU)
*/
void NotifyMonitorSniffTx (Ptr<const Packet> packet, uint16_t channelFreqMhz,
uint16_t channelNumber, uint32_t rate, WifiPreamble preamble,
WifiTxVector txVector, struct mpduInfo aMpdu);
/**
* TracedCallback signature for monitor mode transmit events.
*
* \param packet the packet being transmitted
* \param channelFreqMhz the frequency in MHz at which the packet is
* transmitted.
* \param channelNumber the channel on which the packet is transmitted
* \param rate the PHY data rate in units of 500kbps (i.e., the same
* units used both for the radiotap and for the prism header)
* \param preamble the preamble of the packet
* \param txVector the TXVECTOR that holds tx parameters
* \param aMpdu the type of the packet (0 is not A-MPDU, 1 is a MPDU that is part of an A-MPDU and 2 is the last MPDU in an A-MPDU)
* and the A-MPDU reference number (must be a different value for each A-MPDU but the same for each subframe within one A-MPDU)
* \todo WifiTxVector should be passed by const reference because
* of its size.
*/
typedef void (* MonitorSnifferTxCallback)(const Ptr<const Packet> packet, uint16_t channelFreqMhz,
uint16_t channelNumber, uint32_t rate, WifiPreamble preamble,
WifiTxVector txVector, struct mpduInfo aMpdu);
/**
* Assign a fixed random variable stream number to the random variables
* used by this model. Return the number of streams (possibly zero) that
* have been assigned.
*
* \param stream first stream index to use
* \return the number of stream indices assigned by this model
*/
virtual int64_t AssignStreams (int64_t stream) = 0;
/**
* \param freq the operating center frequency (MHz) on this node.
*/
virtual void SetFrequency (uint32_t freq);
/**
* \return the operating center frequency (MHz)
*/
virtual uint32_t GetFrequency (void) const;
/**
* \param tx the number of transmitters on this node.
*/
virtual void SetNumberOfTransmitAntennas (uint32_t tx) = 0;
/**
* \return the number of transmit antenna on this device
*/
virtual uint32_t GetNumberOfTransmitAntennas (void) const = 0;
/**
* \param rx the number of receivers on this node.
*/
virtual void SetNumberOfReceiveAntennas (uint32_t rx) = 0;
/**
* \return the number of receivers on this node.
*/
virtual uint32_t GetNumberOfReceiveAntennas (void) const = 0;
/**
* \param guardInterval Enable or disable short guard interval
*/
virtual void SetGuardInterval (bool guardInterval) = 0;
/**
* \return true if short guard interval is supported, false otherwise
*/
virtual bool GetGuardInterval (void) const = 0;
/**
* \param ldpc Enable or disable LDPC
*/
virtual void SetLdpc (bool ldpc) = 0;
/**
* \return true if LDPC is supported, false otherwise
*/
virtual bool GetLdpc (void) const = 0;
/**
* \param stbc Enable or disable STBC is supported
*/
virtual void SetStbc (bool stbc) = 0;
/**
* \return true if STBC is supported, false otherwise
*/
virtual bool GetStbc (void) const = 0;
/**
* \param greenfield Enable or disable GreenField
*/
virtual void SetGreenfield (bool greenfield) = 0;
/**
* \return true if Greenfield is supported, false otherwise
*/
virtual bool GetGreenfield (void) const = 0;
/**
* \param preamble sets whether short PLCP preamble is supported or not
*/
virtual void SetShortPlcpPreambleSupported (bool preamble) = 0;
/**
* \return true if short PLCP preamble is supported, false otherwise
*/
virtual bool GetShortPlcpPreambleSupported (void) const = 0;
/**
* \return the channel width
*/
virtual uint32_t GetChannelWidth (void) const;
/**
* \param channelwidth channel width
*/
virtual void SetChannelWidth (uint32_t channelwidth);
/**
* \param channelwidth channel width (in MHz) to support
*/
virtual void AddSupportedChannelWidth (uint32_t channelwidth);
/**
* \return a vector containing the supported channel widths, values in MHz
*/
virtual std::vector<uint32_t> GetSupportedChannelWidthSet (void) const;
/**
* \return the maximum number of supported Rx spatial streams
*/
virtual uint8_t GetSupportedRxSpatialStreams (void) const = 0;
/**
* \return the maximum number of supported Tx spatial streams
*/
virtual uint8_t GetSupportedTxSpatialStreams (void) const = 0;
/**
* Convert from dBm to Watts.
*
* \param dbm the power in dBm
*
* \return the equivalent Watts for the given dBm
*/
double DbmToW (double dbm) const;
/**
* Convert from dB to ratio.
*
* \param db
*
* \return ratio
*/
double DbToRatio (double db) const;
/**
* Convert from Watts to dBm.
*
* \param w the power in Watts
*
* \return the equivalent dBm for the given Watts
*/
double WToDbm (double w) const;
/**
* Convert from ratio to dB.
*
* \param ratio
*
* \return dB
*/
double RatioToDb (double ratio) const;
protected:
// Inherited
virtual void DoInitialize (void);
/**
* The default implementation does nothing and returns true. This method
* is typically called internally by SetChannelNumber ().
*
* \brief Perform any actions necessary when user changes channel number
* \param id channel number to try to switch to
* \return true if WifiPhy can actually change the number; false if not
* \see SetChannelNumber
*/
virtual bool DoChannelSwitch (uint16_t id);
/**
* The default implementation does nothing and returns true. This method
* is typically called internally by SetFrequency ().
*
* \brief Perform any actions necessary when user changes frequency
* \param frequency frequency to try to switch to
* \return true if WifiPhy can actually change the frequency; false if not
* \see SetFrequency
*/
virtual bool DoFrequencySwitch (uint32_t frequency);
private:
/**
* Configure the PHY-level parameters for different Wi-Fi standard.
* This method is called when defaults for each standard must be
* selected.
*
* \param standard the Wi-Fi standard
*/
virtual void ConfigureDefaultsForStandard (enum WifiPhyStandard standard);
/**
* Configure the PHY-level parameters for different Wi-Fi standard.
* This method is called when the Frequency or ChannelNumber attributes
* are set by the user. If the Frequency or ChannelNumber are valid for
* the standard, they are used instead.
*
* \param standard the Wi-Fi standard
*/
virtual void ConfigureChannelForStandard (enum WifiPhyStandard standard);
/**
* Look for channel number matching the frequency and width
* \param frequency The center frequency to use
* \param width The channel width to use
* \return the channel number if found, zero if not
*/
uint16_t FindChannelNumberForFrequencyWidth (uint32_t frequency, uint32_t width) const;
/**
* Lookup frequency/width pair for channelNumber/standard pair
* \param channelNumber The channel number to check
* \param standard The WifiPhyStandard to check
* \return the FrequencyWidthPair found
*/
FrequencyWidthPair GetFrequencyWidthForChannelNumberStandard (uint16_t channelNumber, enum WifiPhyStandard standard) const;
/**
* The trace source fired when a packet begins the transmission process on
* the medium.
*
* \see class CallBackTraceSource
*/
TracedCallback<Ptr<const Packet> > m_phyTxBeginTrace;
/**
* The trace source fired when a packet ends the transmission process on
* the medium.
*
* \see class CallBackTraceSource
*/
TracedCallback<Ptr<const Packet> > m_phyTxEndTrace;
/**
* The trace source fired when the phy layer drops a packet as it tries
* to transmit it.
*
* \see class CallBackTraceSource
*/
TracedCallback<Ptr<const Packet> > m_phyTxDropTrace;
/**
* The trace source fired when a packet begins the reception process from
* the medium.
*
* \see class CallBackTraceSource
*/
TracedCallback<Ptr<const Packet> > m_phyRxBeginTrace;
/**
* The trace source fired when a packet ends the reception process from
* the medium.
*
* \see class CallBackTraceSource
*/
TracedCallback<Ptr<const Packet> > m_phyRxEndTrace;
/**
* The trace source fired when the phy layer drops a packet it has received.
*
* \see class CallBackTraceSource
*/
TracedCallback<Ptr<const Packet> > m_phyRxDropTrace;
/**
* A trace source that emulates a wifi device in monitor mode
* sniffing a packet being received.
*
* As a reference with the real world, firing this trace
* corresponds in the madwifi driver to calling the function
* ieee80211_input_monitor()
*
* \see class CallBackTraceSource
* \todo WifiTxVector and signalNoiseDbm should be be passed as
* const references because of their sizes.
*/
TracedCallback<Ptr<const Packet>, uint16_t, uint16_t, uint32_t,
WifiPreamble, WifiTxVector, struct mpduInfo, struct signalNoiseDbm> m_phyMonitorSniffRxTrace;
/**
* A trace source that emulates a wifi device in monitor mode
* sniffing a packet being transmitted.
*
* As a reference with the real world, firing this trace
* corresponds in the madwifi driver to calling the function
* ieee80211_input_monitor()
*
* \see class CallBackTraceSource
* \todo WifiTxVector should be passed by const reference because
* of its size.
*/
TracedCallback<Ptr<const Packet>, uint16_t, uint16_t, uint32_t,
WifiPreamble, WifiTxVector, struct mpduInfo> m_phyMonitorSniffTxTrace;
enum WifiPhyStandard m_standard; //!< WifiPhyStandard
uint32_t m_channelCenterFrequency; //!< Center frequency in MHz
uint32_t m_channelWidth; //!< Channel width
typedef std::map<ChannelNumberStandardPair,FrequencyWidthPair> ChannelToFrequencyWidthMap;
static ChannelToFrequencyWidthMap m_channelToFrequencyWidth;
std::vector<uint32_t> m_supportedChannelWidthSet; //!< Supported channel width
uint16_t m_channelNumber; //!< Operating channel number
double m_totalAmpduNumSymbols; //!< Number of symbols previously transmitted for the MPDUs in an A-MPDU, used for the computation of the number of symbols needed for the last MPDU in the A-MPDU
uint32_t m_totalAmpduSize; //!< Total size of the previously transmitted MPDUs in an A-MPDU, used for the computation of the number of symbols needed for the last MPDU in the A-MPDU
};
/**
* \param os output stream
* \param state wifi state to stringify
* \return output stream
*/
std::ostream& operator<< (std::ostream& os, enum WifiPhy::State state);
} //namespace ns3
#endif /* WIFI_PHY_H */