Bug 1170: Formulate best practices for dealing with unused debug variables.
/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/*
* Copyright (c) 2005,2006,2007 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
*
* Author: Mathieu Lacage <mathieu.lacage@sophia.inria.fr>
*/
#include "wifi-remote-station-manager.h"
#include "ns3/simulator.h"
#include "ns3/assert.h"
#include "ns3/log.h"
#include "ns3/tag.h"
#include "ns3/boolean.h"
#include "ns3/double.h"
#include "ns3/uinteger.h"
#include "ns3/wifi-phy.h"
#include "ns3/trace-source-accessor.h"
#include "wifi-mac-header.h"
#include "wifi-mac-trailer.h"
NS_LOG_COMPONENT_DEFINE ("WifiRemoteStationManager");
/***************************************************************
* Packet Mode Tagger
***************************************************************/
namespace ns3 {
class TxModeTag : public Tag
{
public:
TxModeTag ();
TxModeTag (WifiMode rtsMode, WifiMode dataMode);
WifiMode GetRtsMode (void) const;
WifiMode GetDataMode (void) const;
static TypeId GetTypeId (void);
virtual TypeId GetInstanceTypeId (void) const;
virtual uint32_t GetSerializedSize (void) const;
virtual void Serialize (TagBuffer i) const;
virtual void Deserialize (TagBuffer i);
virtual void Print (std::ostream &os) const;
private:
WifiMode m_rtsMode;
WifiMode m_dataMode;
};
TxModeTag::TxModeTag ()
{
}
TxModeTag::TxModeTag (WifiMode rtsMode, WifiMode dataMode)
: m_rtsMode (rtsMode),
m_dataMode (dataMode)
{
}
WifiMode
TxModeTag::GetRtsMode (void) const
{
return m_rtsMode;
}
WifiMode
TxModeTag::GetDataMode (void) const
{
return m_dataMode;
}
TypeId
TxModeTag::GetTypeId (void)
{
static TypeId tid = TypeId ("ns3::TxModeTag")
.SetParent<Tag> ()
.AddConstructor<TxModeTag> ()
.AddAttribute ("RtsTxMode",
"Tx mode of rts to use later",
EmptyAttributeValue (),
MakeWifiModeAccessor (&TxModeTag::GetRtsMode),
MakeWifiModeChecker ())
.AddAttribute ("DataTxMode",
"Tx mode of data to use later",
EmptyAttributeValue (),
MakeWifiModeAccessor (&TxModeTag::GetDataMode),
MakeWifiModeChecker ())
;
return tid;
}
TypeId
TxModeTag::GetInstanceTypeId (void) const
{
return GetTypeId ();
}
uint32_t
TxModeTag::GetSerializedSize (void) const
{
return sizeof (WifiMode) * 2;
}
void
TxModeTag::Serialize (TagBuffer i) const
{
i.Write ((uint8_t *)&m_rtsMode, sizeof (WifiMode));
i.Write ((uint8_t *)&m_dataMode, sizeof (WifiMode));
}
void
TxModeTag::Deserialize (TagBuffer i)
{
i.Read ((uint8_t *)&m_rtsMode, sizeof (WifiMode));
i.Read ((uint8_t *)&m_dataMode, sizeof (WifiMode));
}
void
TxModeTag::Print (std::ostream &os) const
{
os << "Rts=" << m_rtsMode << ", Data=" << m_dataMode;
}
} // namespace ns3
namespace ns3 {
NS_OBJECT_ENSURE_REGISTERED (WifiRemoteStationManager);
TypeId
WifiRemoteStationManager::GetTypeId (void)
{
static TypeId tid = TypeId ("ns3::WifiRemoteStationManager")
.SetParent<Object> ()
.AddAttribute ("IsLowLatency", "If true, we attempt to modelize a so-called low-latency device: a device"
" where decisions about tx parameters can be made on a per-packet basis and feedback about the"
" transmission of each packet is obtained before sending the next. Otherwise, we modelize a "
" high-latency device, that is a device where we cannot update our decision about tx parameters"
" after every packet transmission.",
BooleanValue (true), // this value is ignored because there is no setter
MakeBooleanAccessor (&WifiRemoteStationManager::IsLowLatency),
MakeBooleanChecker ())
.AddAttribute ("MaxSsrc", "The maximum number of retransmission attempts for an RTS. This value"
" will not have any effect on some rate control algorithms.",
UintegerValue (7),
MakeUintegerAccessor (&WifiRemoteStationManager::m_maxSsrc),
MakeUintegerChecker<uint32_t> ())
.AddAttribute ("MaxSlrc", "The maximum number of retransmission attempts for a DATA packet. This value"
" will not have any effect on some rate control algorithms.",
UintegerValue (7),
MakeUintegerAccessor (&WifiRemoteStationManager::m_maxSlrc),
MakeUintegerChecker<uint32_t> ())
.AddAttribute ("RtsCtsThreshold", "If the size of the data packet + LLC header + MAC header + FCS trailer is bigger than "
"this value, we use an RTS/CTS handshake before sending the data, as per IEEE Std. 802.11-2007, Section 9.2.6. "
"This value will not have any effect on some rate control algorithms.",
UintegerValue (2346),
MakeUintegerAccessor (&WifiRemoteStationManager::m_rtsCtsThreshold),
MakeUintegerChecker<uint32_t> ())
.AddAttribute ("FragmentationThreshold", "If the size of the data packet + LLC header + MAC header + FCS trailer is bigger"
"than this value, we fragment it such that the size of the fragments are equal or smaller "
"than this value, as per IEEE Std. 802.11-2007, Section 9.4. "
"This value will not have any effect on some rate control algorithms.",
UintegerValue (2346),
MakeUintegerAccessor (&WifiRemoteStationManager::m_fragmentationThreshold),
MakeUintegerChecker<uint32_t> ())
.AddAttribute ("NonUnicastMode", "Wifi mode used for non-unicast transmissions.",
WifiModeValue (),
MakeWifiModeAccessor (&WifiRemoteStationManager::m_nonUnicastMode),
MakeWifiModeChecker ())
.AddTraceSource ("MacTxRtsFailed",
"The transmission of a RTS by the MAC layer has failed",
MakeTraceSourceAccessor (&WifiRemoteStationManager::m_macTxRtsFailed))
.AddTraceSource ("MacTxDataFailed",
"The transmission of a data packet by the MAC layer has failed",
MakeTraceSourceAccessor (&WifiRemoteStationManager::m_macTxDataFailed))
.AddTraceSource ("MacTxFinalRtsFailed",
"The transmission of a RTS has exceeded the maximum number of attempts",
MakeTraceSourceAccessor (&WifiRemoteStationManager::m_macTxFinalRtsFailed))
.AddTraceSource ("MacTxFinalDataFailed",
"The transmission of a data packet has exceeded the maximum number of attempts",
MakeTraceSourceAccessor (&WifiRemoteStationManager::m_macTxFinalDataFailed))
;
return tid;
}
WifiRemoteStationManager::WifiRemoteStationManager ()
{
}
WifiRemoteStationManager::~WifiRemoteStationManager ()
{
}
void
WifiRemoteStationManager::DoDispose (void)
{
for (StationStates::const_iterator i = m_states.begin (); i != m_states.end (); i++)
{
delete (*i);
}
m_states.clear ();
for (Stations::const_iterator i = m_stations.begin (); i != m_stations.end (); i++)
{
delete (*i);
}
m_stations.clear ();
}
void
WifiRemoteStationManager::SetupPhy (Ptr<WifiPhy> phy)
{
// We need to track our PHY because it is the object that knows the
// full set of transmit rates that are supported. We need to know
// this in order to find the relevant mandatory rates when chosing a
// transmit rate for automatic control responses like
// acknowledgements.
m_wifiPhy = phy;
m_defaultTxMode = phy->GetMode (0);
Reset ();
}
uint32_t
WifiRemoteStationManager::GetMaxSsrc (void) const
{
return m_maxSsrc;
}
uint32_t
WifiRemoteStationManager::GetMaxSlrc (void) const
{
return m_maxSlrc;
}
uint32_t
WifiRemoteStationManager::GetRtsCtsThreshold (void) const
{
return m_rtsCtsThreshold;
}
uint32_t
WifiRemoteStationManager::GetFragmentationThreshold (void) const
{
return m_fragmentationThreshold;
}
void
WifiRemoteStationManager::SetMaxSsrc (uint32_t maxSsrc)
{
m_maxSsrc = maxSsrc;
}
void
WifiRemoteStationManager::SetMaxSlrc (uint32_t maxSlrc)
{
m_maxSlrc = maxSlrc;
}
void
WifiRemoteStationManager::SetRtsCtsThreshold (uint32_t threshold)
{
m_rtsCtsThreshold = threshold;
}
void
WifiRemoteStationManager::SetFragmentationThreshold (uint32_t threshold)
{
m_fragmentationThreshold = threshold;
}
void
WifiRemoteStationManager::Reset (Mac48Address address)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStationState *state = LookupState (address);
state->m_operationalRateSet.clear ();
AddSupportedMode (address, GetDefaultMode ());
}
void
WifiRemoteStationManager::AddSupportedMode (Mac48Address address, WifiMode mode)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStationState *state = LookupState (address);
for (WifiModeListIterator i = state->m_operationalRateSet.begin (); i != state->m_operationalRateSet.end (); i++)
{
if ((*i) == mode)
{
// already in.
return;
}
}
state->m_operationalRateSet.push_back (mode);
}
bool
WifiRemoteStationManager::IsBrandNew (Mac48Address address) const
{
if (address.IsGroup ())
{
return false;
}
return LookupState (address)->m_state == WifiRemoteStationState::BRAND_NEW;
}
bool
WifiRemoteStationManager::IsAssociated (Mac48Address address) const
{
if (address.IsGroup ())
{
return true;
}
return LookupState (address)->m_state == WifiRemoteStationState::GOT_ASSOC_TX_OK;
}
bool
WifiRemoteStationManager::IsWaitAssocTxOk (Mac48Address address) const
{
if (address.IsGroup ())
{
return false;
}
return LookupState (address)->m_state == WifiRemoteStationState::WAIT_ASSOC_TX_OK;
}
void
WifiRemoteStationManager::RecordWaitAssocTxOk (Mac48Address address)
{
NS_ASSERT (!address.IsGroup ());
LookupState (address)->m_state = WifiRemoteStationState::WAIT_ASSOC_TX_OK;
}
void
WifiRemoteStationManager::RecordGotAssocTxOk (Mac48Address address)
{
NS_ASSERT (!address.IsGroup ());
LookupState (address)->m_state = WifiRemoteStationState::GOT_ASSOC_TX_OK;
}
void
WifiRemoteStationManager::RecordGotAssocTxFailed (Mac48Address address)
{
NS_ASSERT (!address.IsGroup ());
LookupState (address)->m_state = WifiRemoteStationState::DISASSOC;
}
void
WifiRemoteStationManager::RecordDisassociated (Mac48Address address)
{
NS_ASSERT (!address.IsGroup ());
LookupState (address)->m_state = WifiRemoteStationState::DISASSOC;
}
void
WifiRemoteStationManager::PrepareForQueue (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet, uint32_t fullPacketSize)
{
if (IsLowLatency () || address.IsGroup ())
{
return;
}
WifiRemoteStation *station = Lookup (address, header);
WifiMode rts = DoGetRtsMode (station);
WifiMode data = DoGetDataMode (station, fullPacketSize);
TxModeTag tag;
// first, make sure that the tag is not here anymore.
ConstCast<Packet> (packet)->RemovePacketTag (tag);
tag = TxModeTag (rts, data);
// and then, add it back
packet->AddPacketTag (tag);
}
WifiMode
WifiRemoteStationManager::GetDataMode (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet, uint32_t fullPacketSize)
{
if (address.IsGroup ())
{
return GetNonUnicastMode ();
}
if (!IsLowLatency ())
{
TxModeTag tag;
bool found;
found = ConstCast<Packet> (packet)->PeekPacketTag (tag);
NS_ASSERT (found);
return tag.GetDataMode ();
}
return DoGetDataMode (Lookup (address, header), fullPacketSize);
}
WifiMode
WifiRemoteStationManager::GetRtsMode (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet)
{
NS_ASSERT (!address.IsGroup ());
if (!IsLowLatency ())
{
TxModeTag tag;
bool found;
found = ConstCast<Packet> (packet)->PeekPacketTag (tag);
NS_ASSERT (found);
return tag.GetRtsMode ();
}
return DoGetRtsMode (Lookup (address, header));
}
void
WifiRemoteStationManager::ReportRtsFailed (Mac48Address address, const WifiMacHeader *header)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
station->m_ssrc++;
m_macTxRtsFailed (address);
DoReportRtsFailed (station);
}
void
WifiRemoteStationManager::ReportDataFailed (Mac48Address address, const WifiMacHeader *header)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
station->m_slrc++;
m_macTxDataFailed (address);
DoReportDataFailed (station);
}
void
WifiRemoteStationManager::ReportRtsOk (Mac48Address address, const WifiMacHeader *header,
double ctsSnr, WifiMode ctsMode, double rtsSnr)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
station->m_state->m_info.NotifyTxSuccess (station->m_ssrc);
station->m_ssrc = 0;
DoReportRtsOk (station, ctsSnr, ctsMode, rtsSnr);
}
void
WifiRemoteStationManager::ReportDataOk (Mac48Address address, const WifiMacHeader *header,
double ackSnr, WifiMode ackMode, double dataSnr)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
station->m_state->m_info.NotifyTxSuccess (station->m_slrc);
station->m_slrc = 0;
DoReportDataOk (station, ackSnr, ackMode, dataSnr);
}
void
WifiRemoteStationManager::ReportFinalRtsFailed (Mac48Address address, const WifiMacHeader *header)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
station->m_state->m_info.NotifyTxFailed ();
station->m_ssrc = 0;
m_macTxFinalRtsFailed (address);
DoReportFinalRtsFailed (station);
}
void
WifiRemoteStationManager::ReportFinalDataFailed (Mac48Address address, const WifiMacHeader *header)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
station->m_state->m_info.NotifyTxFailed ();
station->m_slrc = 0;
m_macTxFinalDataFailed (address);
DoReportFinalDataFailed (station);
}
void
WifiRemoteStationManager::ReportRxOk (Mac48Address address, const WifiMacHeader *header,
double rxSnr, WifiMode txMode)
{
if (address.IsGroup ())
{
return;
}
WifiRemoteStation *station = Lookup (address, header);
DoReportRxOk (station, rxSnr, txMode);
}
bool
WifiRemoteStationManager::NeedRts (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet)
{
if (address.IsGroup ())
{
return false;
}
bool normally = (packet->GetSize () + header->GetSize () + WIFI_MAC_FCS_LENGTH) > GetRtsCtsThreshold ();
return DoNeedRts (Lookup (address, header), packet, normally);
}
bool
WifiRemoteStationManager::NeedRtsRetransmission (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
bool normally = station->m_ssrc < GetMaxSsrc ();
return DoNeedRtsRetransmission (station, packet, normally);
}
bool
WifiRemoteStationManager::NeedDataRetransmission (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet)
{
NS_ASSERT (!address.IsGroup ());
WifiRemoteStation *station = Lookup (address, header);
bool normally = station->m_slrc < GetMaxSlrc ();
return DoNeedDataRetransmission (station, packet, normally);
}
bool
WifiRemoteStationManager::NeedFragmentation (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet)
{
if (address.IsGroup ())
{
return false;
}
WifiRemoteStation *station = Lookup (address, header);
bool normally = (packet->GetSize () + header->GetSize () + WIFI_MAC_FCS_LENGTH) > GetFragmentationThreshold ();
return DoNeedFragmentation (station, packet, normally);
}
uint32_t
WifiRemoteStationManager::GetNFragments (Ptr<const Packet> packet)
{
uint32_t nFragments = packet->GetSize () / GetFragmentationThreshold () + 1;
return nFragments;
}
uint32_t
WifiRemoteStationManager::GetFragmentSize (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet, uint32_t fragmentNumber)
{
NS_ASSERT (!address.IsGroup ());
uint32_t nFragment = GetNFragments (packet);
if (fragmentNumber >= nFragment)
{
return 0;
}
if (fragmentNumber == nFragment - 1)
{
uint32_t lastFragmentSize = packet->GetSize () % GetFragmentationThreshold ();
return lastFragmentSize;
}
else
{
return GetFragmentationThreshold ();
}
}
uint32_t
WifiRemoteStationManager::GetFragmentOffset (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet, uint32_t fragmentNumber)
{
NS_ASSERT (!address.IsGroup ());
NS_ASSERT (fragmentNumber < GetNFragments (packet));
uint32_t fragmentOffset = fragmentNumber * GetFragmentationThreshold ();
return fragmentOffset;
}
bool
WifiRemoteStationManager::IsLastFragment (Mac48Address address, const WifiMacHeader *header,
Ptr<const Packet> packet, uint32_t fragmentNumber)
{
NS_ASSERT (!address.IsGroup ());
bool isLast = fragmentNumber == (GetNFragments (packet) - 1);
return isLast;
}
WifiMode
WifiRemoteStationManager::GetControlAnswerMode (Mac48Address address, WifiMode reqMode)
{
/**
* The standard has relatively unambiguous rules for selecting a
* control response rate (the below is quoted from IEEE 802.11-2007,
* Section 9.6):
*
* To allow the transmitting STA to calculate the contents of the
* Duration/ID field, a STA responding to a received frame shall
* transmit its Control Response frame (either CTS or ACK), other
* than the BlockAck control frame, at the highest rate in the
* BSSBasicRateSet parameter that is less than or equal to the
* rate of the immediately previous frame in the frame exchange
* sequence (as defined in 9.12) and that is of the same
* modulation class (see 9.6.1) as the received frame...
*/
WifiMode mode = GetDefaultMode ();
bool found = false;
// First, search the BSS Basic Rate set
for (WifiModeListIterator i = m_bssBasicRateSet.begin ();
i != m_bssBasicRateSet.end (); i++)
{
if ((!found || i->GetPhyRate () > mode.GetPhyRate ())
&& i->GetPhyRate () <= reqMode.GetPhyRate ()
&& i->GetModulationClass () == reqMode.GetModulationClass ())
{
mode = *i;
// We've found a potentially-suitable transmit rate, but we
// need to continue and consider all the basic rates before
// we can be sure we've got the right one.
found = true;
}
}
// If we found a suitable rate in the BSSBasicRateSet, then we are
// done and can return that mode.
if (found)
{
return mode;
}
/**
* If no suitable basic rate was found, we search the mandatory
* rates. The standard (IEEE 802.11-2007, Section 9.6) says:
*
* ...If no rate contained in the BSSBasicRateSet parameter meets
* these conditions, then the control frame sent in response to a
* received frame shall be transmitted at the highest mandatory
* rate of the PHY that is less than or equal to the rate of the
* received frame, and that is of the same modulation class as the
* received frame. In addition, the Control Response frame shall
* be sent using the same PHY options as the received frame,
* unless they conflict with the requirement to use the
* BSSBasicRateSet parameter.
*
* TODO: Note that we're ignoring the last sentence for now, because
* there is not yet any manipulation here of PHY options.
*/
for (uint32_t idx = 0; idx < m_wifiPhy->GetNModes (); idx++)
{
WifiMode thismode = m_wifiPhy->GetMode (idx);
/* If the rate:
*
* - is a mandatory rate for the PHY, and
* - is equal to or faster than our current best choice, and
* - is less than or equal to the rate of the received frame, and
* - is of the same modulation class as the received frame
*
* ...then it's our best choice so far.
*/
if (thismode.IsMandatory ()
&& (!found || thismode.GetPhyRate () > mode.GetPhyRate ())
&& thismode.GetPhyRate () <= reqMode.GetPhyRate ()
&& thismode.GetModulationClass () == reqMode.GetModulationClass ())
{
mode = thismode;
// As above; we've found a potentially-suitable transmit
// rate, but we need to continue and consider all the
// mandatory rates before we can be sure we've got the right
// one.
found = true;
}
}
/**
* If we still haven't found a suitable rate for the response then
* someone has messed up the simulation config. This probably means
* that the WifiPhyStandard is not set correctly, or that a rate that
* is not supported by the PHY has been explicitly requested in a
* WifiRemoteStationManager (or descendant) configuration.
*
* Either way, it is serious - we can either disobey the standard or
* fail, and I have chosen to do the latter...
*/
if (!found)
{
NS_FATAL_ERROR ("Can't find response rate for " << reqMode
<< ". Check standard and selected rates match.");
}
return mode;
}
WifiMode
WifiRemoteStationManager::GetCtsMode (Mac48Address address, WifiMode rtsMode)
{
NS_ASSERT (!address.IsGroup ());
return GetControlAnswerMode (address, rtsMode);
}
WifiMode
WifiRemoteStationManager::GetAckMode (Mac48Address address, WifiMode dataMode)
{
NS_ASSERT (!address.IsGroup ());
return GetControlAnswerMode (address, dataMode);
}
WifiRemoteStationInfo
WifiRemoteStationManager::GetInfo (Mac48Address address)
{
WifiRemoteStationState *state = LookupState (address);
return state->m_info;
}
WifiRemoteStationState *
WifiRemoteStationManager::LookupState (Mac48Address address) const
{
for (StationStates::const_iterator i = m_states.begin (); i != m_states.end (); i++)
{
if ((*i)->m_address == address)
{
return (*i);
}
}
WifiRemoteStationState *state = new WifiRemoteStationState ();
state->m_state = WifiRemoteStationState::BRAND_NEW;
state->m_address = address;
state->m_operationalRateSet.push_back (GetDefaultMode ());
const_cast<WifiRemoteStationManager *> (this)->m_states.push_back (state);
return state;
}
WifiRemoteStation *
WifiRemoteStationManager::Lookup (Mac48Address address, const WifiMacHeader *header) const
{
uint8_t tid;
if (header->IsQosData ())
{
tid = header->GetQosTid ();
}
else
{
tid = 0;
}
return Lookup (address, tid);
}
WifiRemoteStation *
WifiRemoteStationManager::Lookup (Mac48Address address, uint8_t tid) const
{
for (Stations::const_iterator i = m_stations.begin (); i != m_stations.end (); i++)
{
if ((*i)->m_tid == tid
&& (*i)->m_state->m_address == address)
{
return (*i);
}
}
WifiRemoteStationState *state = LookupState (address);
WifiRemoteStation *station = DoCreateStation ();
station->m_state = state;
station->m_tid = tid;
station->m_ssrc = 0;
station->m_slrc = 0;
// XXX
const_cast<WifiRemoteStationManager *> (this)->m_stations.push_back (station);
return station;
}
WifiMode
WifiRemoteStationManager::GetDefaultMode (void) const
{
return m_defaultTxMode;
}
void
WifiRemoteStationManager::Reset (void)
{
for (Stations::const_iterator i = m_stations.begin (); i != m_stations.end (); i++)
{
delete (*i);
}
m_stations.clear ();
m_bssBasicRateSet.clear ();
m_bssBasicRateSet.push_back (m_defaultTxMode);
NS_ASSERT (m_defaultTxMode.IsMandatory ());
}
void
WifiRemoteStationManager::AddBasicMode (WifiMode mode)
{
for (uint32_t i = 0; i < GetNBasicModes (); i++)
{
if (GetBasicMode (i) == mode)
{
return;
}
}
m_bssBasicRateSet.push_back (mode);
}
uint32_t
WifiRemoteStationManager::GetNBasicModes (void) const
{
return m_bssBasicRateSet.size ();
}
WifiMode
WifiRemoteStationManager::GetBasicMode (uint32_t i) const
{
NS_ASSERT (i < m_bssBasicRateSet.size ());
return m_bssBasicRateSet[i];
}
WifiMode
WifiRemoteStationManager::GetNonUnicastMode (void) const
{
if (m_nonUnicastMode == WifiMode ())
{
return GetBasicMode (0);
}
else
{
return m_nonUnicastMode;
}
}
bool
WifiRemoteStationManager::DoNeedRts (WifiRemoteStation *station,
Ptr<const Packet> packet, bool normally)
{
return normally;
}
bool
WifiRemoteStationManager::DoNeedRtsRetransmission (WifiRemoteStation *station,
Ptr<const Packet> packet, bool normally)
{
return normally;
}
bool
WifiRemoteStationManager::DoNeedDataRetransmission (WifiRemoteStation *station,
Ptr<const Packet> packet, bool normally)
{
return normally;
}
bool
WifiRemoteStationManager::DoNeedFragmentation (WifiRemoteStation *station,
Ptr<const Packet> packet, bool normally)
{
return normally;
}
WifiMode
WifiRemoteStationManager::GetSupported (const WifiRemoteStation *station, uint32_t i) const
{
NS_ASSERT (i < GetNSupported (station));
return station->m_state->m_operationalRateSet[i];
}
uint32_t
WifiRemoteStationManager::GetNSupported (const WifiRemoteStation *station) const
{
return station->m_state->m_operationalRateSet.size ();
}
//WifiRemoteStationInfo constructor
WifiRemoteStationInfo::WifiRemoteStationInfo ()
: m_memoryTime (Seconds (1.0)),
m_lastUpdate (Seconds (0.0)),
m_failAvg (0.0)
{
}
double
WifiRemoteStationInfo::CalculateAveragingCoefficient ()
{
double retval = exp ((double)(m_lastUpdate.GetMicroSeconds () - Simulator::Now ().GetMicroSeconds ())
/ (double)m_memoryTime.GetMicroSeconds ());
m_lastUpdate = Simulator::Now ();
return retval;
}
void
WifiRemoteStationInfo::NotifyTxSuccess (uint32_t retryCounter)
{
double coefficient = CalculateAveragingCoefficient ();
m_failAvg = (double)retryCounter / (1 + (double) retryCounter) * (1.0 - coefficient) + coefficient * m_failAvg;
}
void
WifiRemoteStationInfo::NotifyTxFailed ()
{
double coefficient = CalculateAveragingCoefficient ();
m_failAvg = (1.0 - coefficient) + coefficient * m_failAvg;
}
double
WifiRemoteStationInfo::GetFrameErrorRate () const
{
return m_failAvg;
}
} // namespace ns3