Network RSVPTE4

Package: inet.examples.mpls.testte_tunnel
File: examples/mpls/testte_tunnel/RSVPTE4.ned

Example network to demonstrate RSVP-TE.

See the README file in the model directory for scenario description.

Usage diagram:

The following diagram shows usage relationships between types. Unresolved types are missing from the diagram. Click here to see the full picture.

Inheritance diagram:

The following diagram shows inheritance relationships for this type. Unresolved types are missing from the diagram. Click here to see the full picture.

Properties:

Name	Value	Description
isNetwork

Unassigned submodule parameters:

Name	Type	Default value	Description
nam.logfile	string	""	the name of the logfile ("trace.nam")
nam.prolog	string	""
LSR1.rsvp.traffic	xml		specifies paths to set up
LSR1.rsvp.helloInterval	double
LSR1.rsvp.helloTimeout	double
LSR1.classifier.conf	xml
LSR1.networkLayer.ip.procDelay	double	0s
LSR1.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR1.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR1.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR1.ppp.ppp.mtu	int	4470
LSR1.libTable.conf	xml		table contents to be loaded on startup
LSR2.rsvp.traffic	xml		specifies paths to set up
LSR2.rsvp.helloInterval	double
LSR2.rsvp.helloTimeout	double
LSR2.classifier.conf	xml
LSR2.networkLayer.ip.procDelay	double	0s
LSR2.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR2.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR2.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR2.ppp.ppp.mtu	int	4470
LSR2.libTable.conf	xml		table contents to be loaded on startup
LSR3.rsvp.traffic	xml		specifies paths to set up
LSR3.rsvp.helloInterval	double
LSR3.rsvp.helloTimeout	double
LSR3.classifier.conf	xml
LSR3.networkLayer.ip.procDelay	double	0s
LSR3.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR3.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR3.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR3.ppp.ppp.mtu	int	4470
LSR3.libTable.conf	xml		table contents to be loaded on startup
LSR4.rsvp.traffic	xml		specifies paths to set up
LSR4.rsvp.helloInterval	double
LSR4.rsvp.helloTimeout	double
LSR4.classifier.conf	xml
LSR4.networkLayer.ip.procDelay	double	0s
LSR4.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR4.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR4.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR4.ppp.ppp.mtu	int	4470
LSR4.libTable.conf	xml		table contents to be loaded on startup
LSR5.rsvp.traffic	xml		specifies paths to set up
LSR5.rsvp.helloInterval	double
LSR5.rsvp.helloTimeout	double
LSR5.classifier.conf	xml
LSR5.networkLayer.ip.procDelay	double	0s
LSR5.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR5.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR5.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR5.ppp.ppp.mtu	int	4470
LSR5.libTable.conf	xml		table contents to be loaded on startup
LSR6.rsvp.traffic	xml		specifies paths to set up
LSR6.rsvp.helloInterval	double
LSR6.rsvp.helloTimeout	double
LSR6.classifier.conf	xml
LSR6.networkLayer.ip.procDelay	double	0s
LSR6.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR6.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR6.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR6.ppp.ppp.mtu	int	4470
LSR6.libTable.conf	xml		table contents to be loaded on startup
LSR7.rsvp.traffic	xml		specifies paths to set up
LSR7.rsvp.helloInterval	double
LSR7.rsvp.helloTimeout	double
LSR7.classifier.conf	xml
LSR7.networkLayer.ip.procDelay	double	0s
LSR7.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
LSR7.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
LSR7.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
LSR7.ppp.ppp.mtu	int	4470
LSR7.libTable.conf	xml		table contents to be loaded on startup
host1.sctp.numGapReports	int	3	====== SCTP Association Parameters =================================
host1.sctp.rtoInitial	double	3s
host1.sctp.rtoMin	double	1s
host1.sctp.rtoMax	double	60s
host1.sctp.rtoAlpha	double	0.125
host1.sctp.rtoBeta	double	0.250
host1.sctp.maxBurst	int	4
host1.sctp.assocMaxRetrans	int	10
host1.sctp.pathMaxRetrans	int	5
host1.sctp.maxInitRetrans	int	8
host1.sctp.sackPeriod	double	200ms
host1.sctp.sackFrequency	int	2
host1.sctp.reactivatePrimaryPath	bool	false
host1.sctp.sendQueueLimit	int	0
host1.sctp.validCookieLifetime	double	10s	====== Testing =====================================================
host1.sctp.enableHeartbeats	bool	true	====== Heartbeats ==================================================
host1.sctp.hbInterval	double	30s
host1.sctp.nagleEnabled	bool	true	====== Nagle Algorithm =============================================
host1.sctp.naglePoint	int	1468
host1.sctp.fastRecoverySupported	bool	true	====== Congestion Control ==========================================
host1.sctp.sctpAlgorithmClass	string	"SCTPAlg"
host1.sctp.ccModule	int	0	RFC4960=0
host1.sctp.ssModule	int	0	ROUND_ROBIN=0
host1.sctp.arwnd	int	65535
host1.sctp.swsLimit	int	3000	Limit for SWS
host1.sctp.udpEncapsEnabled	bool	false
host1.pingApp.destAddr	string	""	destination IP or IPv6 address
host1.pingApp.srcAddr	string	""	source IP or IPv6 address (useful with multi-homing)
host1.pingApp.packetSize	double	56B	of ping payload, in bytes
host1.pingApp.interval	double	1s	time to wait between pings (can be random)
host1.pingApp.hopLimit	double	32	TTL or hopLimit for IP packets
host1.pingApp.count	double	0	stop after count ping requests, 0 means continuously
host1.pingApp.startTime	double	uniform(0s,this.interval)	send first ping at startTime
host1.pingApp.stopTime	double	0s	send no pings after stopTime, 0 means forever
host1.pingApp.printPing	bool	true	dump on stdout
host1.networkLayer.ip.procDelay	double	0s
host1.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
host1.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
host1.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
host1.ppp.ppp.mtu	int	4470
host1.eth.mac.promiscuous	bool	false	if true, all packets are received, otherwise only the ones with matching destination MAC address
host1.eth.mac.address	string	"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.
host1.eth.mac.txrate	double	100Mbps	maximum data rate supported by this station (bit/s); actually chosen speed may be lower due to auto- configuration. 0 means fully auto-configured.
host1.eth.mac.duplexEnabled	bool	true	whether duplex mode can be enabled or not; whether MAC will actually use duplex mode depends on the result of the auto-configuration process (duplex is only possible with DTE-to-DTE connection).
host1.eth.mac.mtu	int	1500
host1.ext.filterString	string
host1.ext.device	string
host1.ext.mtu	int	1500
host1.tcpdump.dumpFile	string	""
host1.tcpdump.threadEnable	bool	false
host1.tcpdump.snaplen	int	65535
host1.tcpdump.verbosity	int	0
host2.sctp.numGapReports	int	3	====== SCTP Association Parameters =================================
host2.sctp.rtoInitial	double	3s
host2.sctp.rtoMin	double	1s
host2.sctp.rtoMax	double	60s
host2.sctp.rtoAlpha	double	0.125
host2.sctp.rtoBeta	double	0.250
host2.sctp.maxBurst	int	4
host2.sctp.assocMaxRetrans	int	10
host2.sctp.pathMaxRetrans	int	5
host2.sctp.maxInitRetrans	int	8
host2.sctp.sackPeriod	double	200ms
host2.sctp.sackFrequency	int	2
host2.sctp.reactivatePrimaryPath	bool	false
host2.sctp.sendQueueLimit	int	0
host2.sctp.validCookieLifetime	double	10s	====== Testing =====================================================
host2.sctp.enableHeartbeats	bool	true	====== Heartbeats ==================================================
host2.sctp.hbInterval	double	30s
host2.sctp.nagleEnabled	bool	true	====== Nagle Algorithm =============================================
host2.sctp.naglePoint	int	1468
host2.sctp.fastRecoverySupported	bool	true	====== Congestion Control ==========================================
host2.sctp.sctpAlgorithmClass	string	"SCTPAlg"
host2.sctp.ccModule	int	0	RFC4960=0
host2.sctp.ssModule	int	0	ROUND_ROBIN=0
host2.sctp.arwnd	int	65535
host2.sctp.swsLimit	int	3000	Limit for SWS
host2.sctp.udpEncapsEnabled	bool	false
host2.pingApp.destAddr	string	""	destination IP or IPv6 address
host2.pingApp.srcAddr	string	""	source IP or IPv6 address (useful with multi-homing)
host2.pingApp.packetSize	double	56B	of ping payload, in bytes
host2.pingApp.interval	double	1s	time to wait between pings (can be random)
host2.pingApp.hopLimit	double	32	TTL or hopLimit for IP packets
host2.pingApp.count	double	0	stop after count ping requests, 0 means continuously
host2.pingApp.startTime	double	uniform(0s,this.interval)	send first ping at startTime
host2.pingApp.stopTime	double	0s	send no pings after stopTime, 0 means forever
host2.pingApp.printPing	bool	true	dump on stdout
host2.networkLayer.ip.procDelay	double	0s
host2.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
host2.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
host2.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
host2.ppp.ppp.mtu	int	4470
host2.eth.mac.promiscuous	bool	false	if true, all packets are received, otherwise only the ones with matching destination MAC address
host2.eth.mac.address	string	"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.
host2.eth.mac.txrate	double	100Mbps	maximum data rate supported by this station (bit/s); actually chosen speed may be lower due to auto- configuration. 0 means fully auto-configured.
host2.eth.mac.duplexEnabled	bool	true	whether duplex mode can be enabled or not; whether MAC will actually use duplex mode depends on the result of the auto-configuration process (duplex is only possible with DTE-to-DTE connection).
host2.eth.mac.mtu	int	1500
host2.ext.filterString	string
host2.ext.device	string
host2.ext.mtu	int	1500
host2.tcpdump.dumpFile	string	""
host2.tcpdump.threadEnable	bool	false
host2.tcpdump.snaplen	int	65535
host2.tcpdump.verbosity	int	0
host3.sctp.numGapReports	int	3	====== SCTP Association Parameters =================================
host3.sctp.rtoInitial	double	3s
host3.sctp.rtoMin	double	1s
host3.sctp.rtoMax	double	60s
host3.sctp.rtoAlpha	double	0.125
host3.sctp.rtoBeta	double	0.250
host3.sctp.maxBurst	int	4
host3.sctp.assocMaxRetrans	int	10
host3.sctp.pathMaxRetrans	int	5
host3.sctp.maxInitRetrans	int	8
host3.sctp.sackPeriod	double	200ms
host3.sctp.sackFrequency	int	2
host3.sctp.reactivatePrimaryPath	bool	false
host3.sctp.sendQueueLimit	int	0
host3.sctp.validCookieLifetime	double	10s	====== Testing =====================================================
host3.sctp.enableHeartbeats	bool	true	====== Heartbeats ==================================================
host3.sctp.hbInterval	double	30s
host3.sctp.nagleEnabled	bool	true	====== Nagle Algorithm =============================================
host3.sctp.naglePoint	int	1468
host3.sctp.fastRecoverySupported	bool	true	====== Congestion Control ==========================================
host3.sctp.sctpAlgorithmClass	string	"SCTPAlg"
host3.sctp.ccModule	int	0	RFC4960=0
host3.sctp.ssModule	int	0	ROUND_ROBIN=0
host3.sctp.arwnd	int	65535
host3.sctp.swsLimit	int	3000	Limit for SWS
host3.sctp.udpEncapsEnabled	bool	false
host3.pingApp.destAddr	string	""	destination IP or IPv6 address
host3.pingApp.srcAddr	string	""	source IP or IPv6 address (useful with multi-homing)
host3.pingApp.packetSize	double	56B	of ping payload, in bytes
host3.pingApp.interval	double	1s	time to wait between pings (can be random)
host3.pingApp.hopLimit	double	32	TTL or hopLimit for IP packets
host3.pingApp.count	double	0	stop after count ping requests, 0 means continuously
host3.pingApp.startTime	double	uniform(0s,this.interval)	send first ping at startTime
host3.pingApp.stopTime	double	0s	send no pings after stopTime, 0 means forever
host3.pingApp.printPing	bool	true	dump on stdout
host3.networkLayer.ip.procDelay	double	0s
host3.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
host3.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
host3.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
host3.ppp.ppp.mtu	int	4470
host3.eth.mac.promiscuous	bool	false	if true, all packets are received, otherwise only the ones with matching destination MAC address
host3.eth.mac.address	string	"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.
host3.eth.mac.txrate	double	100Mbps	maximum data rate supported by this station (bit/s); actually chosen speed may be lower due to auto- configuration. 0 means fully auto-configured.
host3.eth.mac.duplexEnabled	bool	true	whether duplex mode can be enabled or not; whether MAC will actually use duplex mode depends on the result of the auto-configuration process (duplex is only possible with DTE-to-DTE connection).
host3.eth.mac.mtu	int	1500
host3.ext.filterString	string
host3.ext.device	string
host3.ext.mtu	int	1500
host3.tcpdump.dumpFile	string	""
host3.tcpdump.threadEnable	bool	false
host3.tcpdump.snaplen	int	65535
host3.tcpdump.verbosity	int	0
host4.sctp.numGapReports	int	3	====== SCTP Association Parameters =================================
host4.sctp.rtoInitial	double	3s
host4.sctp.rtoMin	double	1s
host4.sctp.rtoMax	double	60s
host4.sctp.rtoAlpha	double	0.125
host4.sctp.rtoBeta	double	0.250
host4.sctp.maxBurst	int	4
host4.sctp.assocMaxRetrans	int	10
host4.sctp.pathMaxRetrans	int	5
host4.sctp.maxInitRetrans	int	8
host4.sctp.sackPeriod	double	200ms
host4.sctp.sackFrequency	int	2
host4.sctp.reactivatePrimaryPath	bool	false
host4.sctp.sendQueueLimit	int	0
host4.sctp.validCookieLifetime	double	10s	====== Testing =====================================================
host4.sctp.enableHeartbeats	bool	true	====== Heartbeats ==================================================
host4.sctp.hbInterval	double	30s
host4.sctp.nagleEnabled	bool	true	====== Nagle Algorithm =============================================
host4.sctp.naglePoint	int	1468
host4.sctp.fastRecoverySupported	bool	true	====== Congestion Control ==========================================
host4.sctp.sctpAlgorithmClass	string	"SCTPAlg"
host4.sctp.ccModule	int	0	RFC4960=0
host4.sctp.ssModule	int	0	ROUND_ROBIN=0
host4.sctp.arwnd	int	65535
host4.sctp.swsLimit	int	3000	Limit for SWS
host4.sctp.udpEncapsEnabled	bool	false
host4.pingApp.destAddr	string	""	destination IP or IPv6 address
host4.pingApp.srcAddr	string	""	source IP or IPv6 address (useful with multi-homing)
host4.pingApp.packetSize	double	56B	of ping payload, in bytes
host4.pingApp.interval	double	1s	time to wait between pings (can be random)
host4.pingApp.hopLimit	double	32	TTL or hopLimit for IP packets
host4.pingApp.count	double	0	stop after count ping requests, 0 means continuously
host4.pingApp.startTime	double	uniform(0s,this.interval)	send first ping at startTime
host4.pingApp.stopTime	double	0s	send no pings after stopTime, 0 means forever
host4.pingApp.printPing	bool	true	dump on stdout
host4.networkLayer.ip.procDelay	double	0s
host4.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
host4.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
host4.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
host4.ppp.ppp.mtu	int	4470
host4.eth.mac.promiscuous	bool	false	if true, all packets are received, otherwise only the ones with matching destination MAC address
host4.eth.mac.address	string	"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.
host4.eth.mac.txrate	double	100Mbps	maximum data rate supported by this station (bit/s); actually chosen speed may be lower due to auto- configuration. 0 means fully auto-configured.
host4.eth.mac.duplexEnabled	bool	true	whether duplex mode can be enabled or not; whether MAC will actually use duplex mode depends on the result of the auto-configuration process (duplex is only possible with DTE-to-DTE connection).
host4.eth.mac.mtu	int	1500
host4.ext.filterString	string
host4.ext.device	string
host4.ext.mtu	int	1500
host4.tcpdump.dumpFile	string	""
host4.tcpdump.threadEnable	bool	false
host4.tcpdump.snaplen	int	65535
host4.tcpdump.verbosity	int	0
host5.sctp.numGapReports	int	3	====== SCTP Association Parameters =================================
host5.sctp.rtoInitial	double	3s
host5.sctp.rtoMin	double	1s
host5.sctp.rtoMax	double	60s
host5.sctp.rtoAlpha	double	0.125
host5.sctp.rtoBeta	double	0.250
host5.sctp.maxBurst	int	4
host5.sctp.assocMaxRetrans	int	10
host5.sctp.pathMaxRetrans	int	5
host5.sctp.maxInitRetrans	int	8
host5.sctp.sackPeriod	double	200ms
host5.sctp.sackFrequency	int	2
host5.sctp.reactivatePrimaryPath	bool	false
host5.sctp.sendQueueLimit	int	0
host5.sctp.validCookieLifetime	double	10s	====== Testing =====================================================
host5.sctp.enableHeartbeats	bool	true	====== Heartbeats ==================================================
host5.sctp.hbInterval	double	30s
host5.sctp.nagleEnabled	bool	true	====== Nagle Algorithm =============================================
host5.sctp.naglePoint	int	1468
host5.sctp.fastRecoverySupported	bool	true	====== Congestion Control ==========================================
host5.sctp.sctpAlgorithmClass	string	"SCTPAlg"
host5.sctp.ccModule	int	0	RFC4960=0
host5.sctp.ssModule	int	0	ROUND_ROBIN=0
host5.sctp.arwnd	int	65535
host5.sctp.swsLimit	int	3000	Limit for SWS
host5.sctp.udpEncapsEnabled	bool	false
host5.pingApp.destAddr	string	""	destination IP or IPv6 address
host5.pingApp.srcAddr	string	""	source IP or IPv6 address (useful with multi-homing)
host5.pingApp.packetSize	double	56B	of ping payload, in bytes
host5.pingApp.interval	double	1s	time to wait between pings (can be random)
host5.pingApp.hopLimit	double	32	TTL or hopLimit for IP packets
host5.pingApp.count	double	0	stop after count ping requests, 0 means continuously
host5.pingApp.startTime	double	uniform(0s,this.interval)	send first ping at startTime
host5.pingApp.stopTime	double	0s	send no pings after stopTime, 0 means forever
host5.pingApp.printPing	bool	true	dump on stdout
host5.networkLayer.ip.procDelay	double	0s
host5.networkLayer.arp.retryTimeout	double	1s	number seconds ARP waits between retries to resolve an IP address
host5.networkLayer.arp.retryCount	int	3	number of times ARP will attempt to resolve an IP address
host5.networkLayer.arp.cacheTimeout	double	120s	number seconds unused entries in the cache will time out
host5.ppp.ppp.mtu	int	4470
host5.eth.mac.promiscuous	bool	false	if true, all packets are received, otherwise only the ones with matching destination MAC address
host5.eth.mac.address	string	"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.
host5.eth.mac.txrate	double	100Mbps	maximum data rate supported by this station (bit/s); actually chosen speed may be lower due to auto- configuration. 0 means fully auto-configured.
host5.eth.mac.duplexEnabled	bool	true	whether duplex mode can be enabled or not; whether MAC will actually use duplex mode depends on the result of the auto-configuration process (duplex is only possible with DTE-to-DTE connection).
host5.eth.mac.mtu	int	1500
host5.ext.filterString	string
host5.ext.device	string
host5.ext.mtu	int	1500
host5.tcpdump.dumpFile	string	""
host5.tcpdump.threadEnable	bool	false
host5.tcpdump.snaplen	int	65535
host5.tcpdump.verbosity	int	0
scenarioManager.script	xml

Source code:

//
// Example network to demonstrate \RSVP-TE.
//
// See the README file in the model directory for scenario description.
//
network RSVPTE4
{
    submodules:
        nam: NAMTrace {
            parameters:
                @display("p=152,280");

        }
        LSR1: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp1";
                @display("p=160,167");
            gates:
                pppg[5];
        }
        LSR2: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp1 ppp2";
                @display("p=254,255");
            gates:
                pppg[3];
        }
        LSR3: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp1 ppp2";
                @display("p=253,78");
            gates:
                pppg[3];
        }
        LSR4: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp1 ppp2";
                @display("p=358,167");
            gates:
                pppg[3];
        }
        LSR5: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp3 ppp4";
                @display("p=460,167");
            gates:
                pppg[5];
        }
        LSR6: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp1";
                @display("p=400,300");
            gates:
                pppg[2];
        }
        LSR7: RSVP_LSR {
            parameters:
                peers = "ppp0 ppp1";
                @display("p=400,50");
            gates:
                pppg[2];
        }
        host1: StandardHost { // client
            parameters:
                @display("p=71,80;i=device/pc2");
        }
        host2: StandardHost { // client
            parameters:
                @display("p=72,153;i=device/pc2");
        }
        host3: StandardHost { // server
            parameters:
                @display("p=570,88;i=device/server");
        }
        host4: StandardHost { // server
            parameters:
                @display("p=562,256;i=device/server");
        }
        host5: StandardHost { // client
            parameters:
                @display("p=73,233;i=device/pc2");
        }
        scenarioManager: ScenarioManager {
            parameters:
                @display("p=150,50");
        }
        failureManager: FailureManager {
            parameters:
                @display("p=500,50");
        }
    connections:
        LSR1.pppg[0] <--> {  delay = 15ms; datarate = 600Kbps; } <--> LSR2.pppg[0];
        LSR1.pppg[1] <--> {  delay = 5ms; datarate = 600Kbps; } <--> LSR3.pppg[0];
        host2.pppg++ <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR1.pppg[2];
        host1.pppg++ <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR1.pppg[3];
        LSR2.pppg[1] <--> {  delay = 5ms; datarate = 600Kbps; } <--> LSR4.pppg[0];
        LSR3.pppg[1] <--> {  delay = 5ms; datarate = 600Kbps; } <--> LSR4.pppg[2];
        LSR4.pppg[1] <--> {  delay = 5ms; datarate = 600Kbps; } <--> LSR5.pppg[0];
        LSR5.pppg[1] <--> {  delay = 10ms; datarate = 600Kbps; } <--> host3.pppg++;
        LSR5.pppg[2] <--> {  delay = 10ms; datarate = 600Kbps; } <--> host4.pppg++;
        LSR2.pppg[2] <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR6.pppg[0];
        LSR5.pppg[3] <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR6.pppg[1];
        LSR3.pppg[2] <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR7.pppg[0];
        LSR5.pppg[4] <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR7.pppg[1];
        host5.pppg++ <--> {  delay = 10ms; datarate = 600Kbps; } <--> LSR1.pppg[4];
}