NED File src/inet/linklayer/ethernet/EtherMAC.ned
| Name | Type | Description |
|---|---|---|
| EtherMAC | simple module |
Ethernet MAC layer. MAC performs transmission and reception of frames. See the IEtherMAC for the Ethernet MAC layer general informations. Doesn't do encapsulation/decapsulation; see EtherLLC and EtherEncap for that. |
Source code
// // Copyright (C) 2003 Andras Varga; CTIE, Monash University, Australia // Copyright (C) 2010 Zoltan Bojthe // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public License // as published by the Free Software Foundation; either version 2 // of the License, or (at your option) any later version. // // 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 Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with this program; if not, see <http://www.gnu.org/licenses/>. // package inet.linklayer.ethernet; import inet.linklayer.contract.IEtherMAC; // // Ethernet MAC layer. MAC performs transmission and reception of frames. // See the ~IEtherMAC for the Ethernet MAC layer general informations. // Doesn't do encapsulation/decapsulation; see ~EtherLLC and ~EtherEncap for // that. // // Supported variations: // - 10Mb Ethernet (duplex and half-duplex, coaxial cable or twisted pair) // - 100Mb Ethernet (duplex and half-duplex) // - 1Gb Ethernet (duplex and half-duplex) // - 10Gb Ethernet // - 40Gb Ethernet // - 100Gb Ethernet // // Supports all three Ethernet frame types. (It handles ~EtherFrame message class; // specific frame classes (Ethernet-II, IEEE 802.3) are subclassed from that one.) // RAW mode (only used by the IPX protocol) is not supported. // // Expected environment: // - phys$i and phys$o should be connected to the "network" // - upperLayerIn and upperLayerOut are usually connected to ~EtherLLC (in hosts) // or ~MACRelayUnit (in a switch) // // <b>Operation</b> // // Processing of frames received from higher layers: // - if src address in the frame is empty, fill it out // - frames get queued up until transmission // - transmit according to the CSMA/CD protocol // - can send PAUSE message if requested by higher layers (PAUSE protocol, // used in switches). // // Processing of frames incoming from the network: // - receive according to the CSMA/CD protocol // - CRC checking (frames with the error bit set are discarded). // - respond to PAUSE frames // - in promiscuous mode, pass up all received frames; // otherwise, only frames with matching MAC addresses and // broadcast frames are passed up. // // The module does not perform encapsulation or decapsulation of frames -- // this is done by higher layers (~EtherLLC or ~EtherEncap). // // When a frame is received from the higher layers, it must be an ~EtherFrame, // and with all protocol fields filled out // (including the destination MAC address). The source address, if left empty, // will be filled in. Then frame is queued and transmitted according // to the CSMA/CD protocol. // // Data frames received from the network are EtherFrames. They are passed to // the higher layers without modification. // Also, the module properly responds to PAUSE frames, but never sends them // by itself -- however, it transmits PAUSE frames received from upper layers. // See <a href="ether-pause.html">PAUSE handling</a> for more info. // // For more info see <a href="ether-overview.html">Ethernet Model Overview</a>. // // <b>Disabling and disconnecting</b> // // If the MAC is not connected to the network ("cable unplugged"), it will // start up in "disabled" mode. A disabled MAC simply discards any messages // it receives. It is currently not supported to dynamically connect/disconnect // a MAC. // // // <b>Queueing</b> // // In routers, MAC relies on an external queue module (see ~IOutputQueue) // to model finite buffer, implement QoS and/or RED, and requests packets // from this external queue one-by-one. // // In hosts, no such queue is used, so MAC contains an internal // queue named txQueue to queue up packets waiting for transmission. // Conceptually, txQueue is of infinite size, but for better diagnostics // one can specify a hard limit in the txQueueLimit parameter -- if this is // exceeded, the simulation stops with an error. // // // <b>Physical layer messaging</b> // // Please see <a href="physical.html">Messaging on the physical layer</a>. // // @see ~EtherMACFullDuplex, ~EthernetInterface, ~IOutputQueue, ~EtherEncap, ~EtherLLC // @see ~EtherFrame, ~EthernetIIFrame, ~EtherFrameWithLLC, ~Ieee802Ctrl // simple EtherMAC like IEtherMAC { parameters: string interfaceTableModule; // The path to the InterfaceTable module bool promiscuous = default(false); // if true, all packets are received, otherwise only the // ones with matching destination MAC address string address @mutable = default("auto"); // MAC address as hex string (12 hex digits), or // "auto". "auto" values will be replaced by // a generated MAC address in init stage 0. bool duplexMode = default(true); // selects full-duplex (true) or half-duplex (false) operation int txQueueLimit = default(1000); // maximum number of frames queued up for transmission in the internal queue (only used if queueModule==""); additional frames cause a runtime error string queueModule = default(""); // name of optional external queue module bool frameBursting = default(true); // enable/disable frame bursting mode in Gigabit Ethernet int mtu @unit("B") = default(1500B); @display("i=block/rxtx"); @signal[txPk](type=inet::EtherFrame); @signal[rxPkOk](type=inet::EtherFrame); @signal[txPausePkUnits](type=inet::long); @signal[rxPausePkUnits](type=inet::long); @signal[rxPkFromHL](type=inet::EtherFrame); @signal[dropPkNotForUs](type=inet::EtherFrame); @signal[dropPkBitError](type=inet::EtherFrame); @signal[dropPkFromHLIfaceDown](type=inet::EtherFrame); @signal[dropPkIfaceDown](type=inet::EtherFrame); // emitted at begin of receiving @signal[packetSentToLower](type=inet::EtherFrame); @signal[packetReceivedFromLower](type=inet::EtherFrame); @signal[packetSentToUpper](type=inet::EtherFrame); @signal[packetReceivedFromUpper](type=inet::EtherFrame); @signal[collision](type=long); @signal[backoff](type=long); @signal[transmitState](type=long); // enum=MACTransmitState @signal[receiveState](type=long); // enum=MACReceiveState @statistic[txPk](title="packets transmitted"; source=txPk; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[rxPkOk](title="packets received OK"; source=rxPkOk; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[passedUpPk](title="packets passed to higher layer"; source=packetSentToUpper; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[txPausePkUnits](title="pause units sent"; record=count,sum,vector; interpolationmode=none); @statistic[rxPausePkUnits](title="pause units received"; record=count,sum,vector; interpolationmode=none); @statistic[rxPkFromHL](title="packet bytes from higher layer"; source=rxPkFromHL; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[droppedPkIfaceDown](title="packets dropped/interface down"; source=dropPkIfaceDown; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[droppedPkBitError](title="packets dropped/bit error"; source=dropPkBitError; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[droppedPkNotForUs](title="packets dropped/not for us"; source=dropPkNotForUs; record=count,"sum(packetBytes)","vector(packetBytes)"; interpolationmode=none); @statistic[collision](title="collision"; record=count,vector; interpolationmode=none); @statistic[backoff](title="backoff"; record=count,vector; interpolationmode=none); gates: input upperLayerIn @labels(EtherFrame); // to ~EtherLLC or ~EtherEncap or ~IMACRelayUnit output upperLayerOut @labels(EtherFrame); // to ~EtherLLC or ~EtherEncap or ~IMACRelayUnit inout phys @labels(EtherFrame); // to physical layer or the network }
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