// IPv4: PTA model with digitial clocks
// multi-objective model of the host
// gxn/dxp 28/09/09

mdp

//-------------------------------------------------------------
// VARIABLES
const int N=20; // number of abstract hosts
const int K; // number of probes to send

// PROBABILITIES
const double old = N/65024; // probability pick an ip address being used
//const double old = 0.5; // probability pick an ip address being used
const double new = (1-old); // probability pick a new ip address

// TIMING CONSTANTS
const int CONSEC = 2;  // time interval between sending consecutive probles 
const int TRANSTIME = 1; // upper bound on transmission time delay
const int LONGWAIT = 60; // minimum time delay after a high number of address collisions
const int DEFEND = 10;

const int TIME_MAX_X = 60; // max value of clock x
const int TIME_MAX_Y = 10; // max value of clock y
const int TIME_MAX_Z = 1;  // max value of clock z

// OTHER CONSTANTS
const int MAXCOLL = 10;  // maximum number of collisions before long wait


//-------------------------------------------------------------
// CONCRETE HOST
module host0
	
	x : [0..TIME_MAX_X]; // first clock of the host
	y : [0..TIME_MAX_Y]; // second clock of the host
	
	coll : [0..MAXCOLL]; // number of address collisions
	probes : [0..K]; // counter (number of probes sent)
	mess : [0..1]; // need to send a message or not
	defend : [0..1]; // defend (if =1, try to defend IP address)
	
	ip : [1..2]; // ip address (1 - in use & 2 - fresh)
	
	l : [0..4] init 1; // location
	// 0 : RECONFIGURE 
	// 1 : RANDOM
	// 2 : WAITSP
	// 3 : WAITSG 
	// 4 : USE
	
	// RECONFIGURE
	[reset] l=0 -> (l'=1);
	
	// RANDOM (choose IP address)
	[rec0] (l=1) -> true; // get message (ignore since have no ip address)
	[rec1] (l=1) -> true; // get message (ignore since have no ip address)
	// small number of collisions (choose straight away)
	[] l=1 & coll<MAXCOLL -> 1/3*old : (l'=2) & (ip'=1) & (x'=0) 
		                     + 1/3*old : (l'=2) & (ip'=1) & (x'=1) 
		                     + 1/3*old : (l'=2) & (ip'=1) & (x'=2) 
		                     + 1/3*new : (l'=2) & (ip'=2) & (x'=0) 
		                     + 1/3*new : (l'=2) & (ip'=2) & (x'=1) 
		                     + 1/3*new : (l'=2) & (ip'=2) & (x'=2); 
	// large number of collisions: (wait for LONGWAIT)
	[time] l=1 & coll=MAXCOLL & x<LONGWAIT -> (x'=min(x+1,TIME_MAX_X));
	[]     l=1 & coll=MAXCOLL & x=LONGWAIT -> 1/3*old : (l'=2) & (ip'=1) & (x'=0) 
			                                   + 1/3*old : (l'=2) & (ip'=1) & (x'=1) 
			                                   + 1/3*old : (l'=2) & (ip'=1) & (x'=2) 
			                                   + 1/3*new : (l'=2) & (ip'=2) & (x'=0) 
			                                   + 1/3*new : (l'=2) & (ip'=2) & (x'=1) 
			                                   + 1/3*new : (l'=2) & (ip'=2) & (x'=2);
	
	// WAITSP 
	// let time pass
	[time]  l=2 & x<2 -> (x'=min(x+1,2));
	// send probe
	[send1] l=2 & ip=1 & x=2  & probes<K -> (x'=0) & (probes'=probes+1);
	[send2] l=2 & ip=2 & x=2  & probes<K -> (x'=0) & (probes'=probes+1);
	// sent K probes and waited 2 seconds
	[] l=2 & x=2 & probes=K -> (l'=3) & (probes'=0) & (coll'=0) & (x'=0);
	// get message and ip does not match: ignore
	[rec0] l=2 & ip!=0 -> (l'=l);
	[rec1] l=2 & ip!=1 -> (l'=l);
	// get a message with matching ip: reconfigure
	[rec1] l=2 & ip=1 -> (l'=0) & (coll'=min(coll+1,MAXCOLL)) & (x'=0) & (probes'=0);
	
	// WAITSG (sends two gratuitious arp probes)
	// time passage
	[time] l=3 & mess=0 & defend=0 & x<CONSEC -> (x'=min(x+1,TIME_MAX_X)); 
	[time] l=3 & mess=0 & defend=1 & x<CONSEC -> (x'=min(x+1,TIME_MAX_X)) & (y'=min(y+1,DEFEND));
	
	// receive message and same ip: defend
	[rec1] l=3 & mess=0 & ip=1 & (defend=0 | y>=DEFEND) -> (defend'=1) & (mess'=1) & (y'=0);
	// receive message and same ip: defer
	[rec1] l=3 & mess=0 & ip=1 & (defend=0 | y<DEFEND) -> (l'=0) & (probes'=0) & (defend'=0) & (x'=0) & (y'=0);
	// receive message and different ip
	[rec0] l=3 & mess=0 & ip!=0 -> (l'=l);
	[rec1] l=3 & mess=0 & ip!=1 -> (l'=l);
	
		
	// send probe reply or message for defence
	[send1] l=3 & ip=1 & mess=1 -> (mess'=0);
	[send2] l=3 & ip=2 & mess=1 -> (mess'=0);
	// send first gratuitous arp message
	[send1] l=3 & ip=1 & mess=0 & x=CONSEC & probes<1 -> (x'=0) & (probes'=probes+1);
	[send2] l=3 & ip=2 & mess=0 & x=CONSEC & probes<1 -> (x'=0) & (probes'=probes+1);
	// send second gratuitous arp message (move to use)
	[send1] l=3 & ip=1 & mess=0 & x=CONSEC & probes=1 -> (l'=4) & (x'=0) & (y'=0) & (probes'=0);
	[send2] l=3 & ip=2 & mess=0 & x=CONSEC & probes=1 -> (l'=4) & (x'=0) & (y'=0) & (probes'=0);
	
	// USE (only interested in reaching this state so do not need to add anything here)
	[] l=4 -> true;
	
endmodule

//-------------------------------------------------------------
// error automaton for the environment assumption
// do not get a reply when K probes are sent
const int M; // time between sending and receiving a message

module env_error8

	env : [0..1]; // 0 active and 1 done
	k : [0..8]; // counts the number of messages sent
	c1 : [0..M+1]; // time since first message
	c2 : [0..M+1]; // time since second message
	c3 : [0..M+1]; // time since third message
	c4 : [0..M+1]; // time since fourth message
	c5 : [0..M+1]; // time since fifth message
	c6 : [0..M+1]; // time since sixth message
	c7 : [0..M+1]; // time since seventh message
	c8 : [0..M+1]; // time since eighth message
	error : [0..1];

	// message with new ip address arrives so done
	[send2] error=0 & env=0 -> (env'=1);
	// message with old ip address arrives so count
	[send1] error=0 & env=0 -> (k'=min(k+1,K));
	// time passgae so update relevant clocks
	[time] error=0 & env=0 & k=0 -> true;
	[time] error=0 & env=0 & k=1 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1));
	[time] error=0 & env=0 & k=2 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1));
	[time] error=0 & env=0 & k=3 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1)) & (c3'=min(c3+1,M+1));
	[time] error=0 & env=0 & k=4 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1)) & (c3'=min(c3+1,M+1)) & (c4'=min(c4+1,M+1));
	[time] error=0 & env=0 & k=5 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1)) & (c3'=min(c3+1,M+1)) & (c4'=min(c4+1,M+1)) & (c5'=min(c5+1,M+1));
	[time] error=0 & env=0 & k=6 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1)) & (c3'=min(c3+1,M+1)) & (c4'=min(c4+1,M+1)) & (c5'=min(c5+1,M+1)) & (c6'=min(c6+1,M+1));
	[time] error=0 & env=0 & k=7 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1)) & (c3'=min(c3+1,M+1)) & (c4'=min(c4+1,M+1)) & (c5'=min(c5+1,M+1)) & (c6'=min(c6+1,M+1)) & (c7'=min(c7+1,M+1));
	[time] error=0 & env=0 & k=8 & min(c1,c2,c3,c4,c5,c6,c7,c8)<M -> (c1'=min(c1+1,M+1)) & (c2'=min(c2+1,M+1)) & (c3'=min(c3+1,M+1)) & (c4'=min(c4+1,M+1)) & (c5'=min(c5+1,M+1)) & (c6'=min(c6+1,M+1)) & (c7'=min(c7+1,M+1)) & (c8'=min(c8+1,M+1));
	// all clocks reached their bound so an error
	[time] error=0 & env=0 & min(c1,c2,c3,c4,c5,c6,c7,c8)=M -> (error'=1); 
	// send a reply (then done)
	[rec1] error=0 & env=0 & k>0 & min(c1,c2,c3,c4,c5,c6,c7,c8)<=M -> (env'=1);
	// finished so any action can be performed
	[time]  error=1 | env=1 -> true;
	[send1]  error=1 | env=1 -> true;
	[send2]  error=1 | env=1 -> true;
	[rec1]  error=1 | env=1 -> true;

endmodule