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258 lines
11 KiB
258 lines
11 KiB
// IPv4: PTA model with digitial clocks
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// one concrete host attempting to choose an ip address
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// when a number of (abstract) hosts have already got ip addresses
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// gxn/dxp/jzs 02/05/03
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// model is an mdp
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mdp
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// reset or noreset model
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const bool reset=false;
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//-------------------------------------------------------------
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// we suppose that
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// - the abstract hosts have already picked their addresses
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// and always defend their addresses
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// - the concrete host never picks the same ip address twice
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// (this can happen only with a verys small probability)
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// under these assumptions we do not need message types because:
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// 1) since messages to the concrete host will never be a probe,
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// this host will react to all messages in the same way
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// 2) since the abstract hosts always defend their addresses,
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// all messages from the host will get an arp reply if the ip matches
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// following from the above assumptions we require only three abstract IP addresses
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// (0,1 and 2) which correspond to the following sets of IP addresses:
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// 0 - the IP addresses of the abstract hosts which the concrete host
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// previously tried to configure
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// 1 - an IP address of an abstract host which the concrete host is
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// currently trying to configure
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// 2 - a fresh IP address which the concrete host is currently trying to configure
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// if the host picks an address that is being used it may end up picking another ip address
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// in which case there may still be messages corresponding to the old ip address
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// to be sent both from and to the host which the host should now disregard
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// (since it will never pick the same ip address)
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// to deal with this situation: when a host picks a new ip address we reconfigure the
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// messages that are still be be sent or are being sent by changing the ip address to 0
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// (an old ip address of the host)
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// all the messages from the abstract hosts for the 'old' address (in fact the
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// set of old addresses since it may have started again more than once)
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// can arrive in any order since they are equivalent to the host - it ignores then all
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// also the messages for the old and new address will come from different hosts
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// (the ones with that ip address) which we model by allowing them to arrive in any order
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// i.e. not neccessarily in the order they where sent
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//-------------------------------------------------------------
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//-------------------------------------------------------------
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// VARIABLES
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//const int N; // number of abstract hosts
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const int K=6; // number of probes to send
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const double loss; // probability of message loss
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// PROBABILITIES
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const double old; //=N/65024; // probability pick an ip address being used
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const double new = (1-old); // probability pick a new ip address
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// TIMING CONSTANTS
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const int CONSEC = 2; // time interval between sending consecutive probles
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const int TRANSTIME = 1; // upper bound on transmission time delay
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const int LONGWAIT = 60; // minimum time delay after a high number of address collisions
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const int DEFEND = 10;
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const int TIME_MAX_X = 60; // max value of clock x
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const int TIME_MAX_Y = 10; // max value of clock y
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const int TIME_MAX_Z = 1; // max value of clock z
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// OTHER CONSTANTS
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const int MAXCOLL = 10; // maximum number of collisions before long wait
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// size of buffers for other hosts
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const int B0 = 20; // buffer size for one abstract host
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const int B1 = 8; // buffer sizes for all abstract hosts
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//-------------------------------------------------------------
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// ENVIRONMENT - models: medium, output buffer of concrete host and all other hosts
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module environment
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// buffer of concrete host
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b_ip7 : [0..2]; // ip address of message in buffer position 8
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b_ip6 : [0..2]; // ip address of message in buffer position 7
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b_ip5 : [0..2]; // ip address of message in buffer position 6
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b_ip4 : [0..2]; // ip address of message in buffer position 5
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b_ip3 : [0..2]; // ip address of message in buffer position 4
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b_ip2 : [0..2]; // ip address of message in buffer position 3
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b_ip1 : [0..2]; // ip address of message in buffer position 2
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b_ip0 : [0..2]; // ip address of message in buffer position 1
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n : [0..8]; // number of places in the buffer used (from host)
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// messages to be sent from abstract hosts to concrete host
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n0 : [0..B0]; // number of messages which do not have the host's current ip address
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n1 : [0..B1]; // number of messages which have the host's current ip address
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b : [0..2]; // local state
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// 0 - idle
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// 1 - sending message from concrete host
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// 2 - sending message from abstract host
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z : [0..1]; // clock of environment (needed for the time to send a message)
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ip_mess : [0..2]; // ip in the current message being sent
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// 0 - different from concrete host
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// 1 - same as the concrete host and in use
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// 2 - same as the concrete host and not in use
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// RESET/RECONFIG: when host is about to choose new ip address
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// suppose that the host cannot choose the same ip address
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// (since happens with very small probability).
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// Therefore all messages will have a different ip address,
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// i.e. all n1 messages become n0 ones.
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// Note this include any message currently being sent (ip is set to zero 0)
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[reset] true -> (n1'=0) & (n0'=min(B0,n0+n1)) // abstract buffers
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& (ip_mess'=0) // message being set
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& (n'=(reset)?0:n) // concrete buffer (remove this update to get NO_RESET model)
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& (b_ip7'=0)
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& (b_ip6'=0)
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& (b_ip5'=0)
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& (b_ip4'=0)
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& (b_ip3'=0)
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& (b_ip2'=0)
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& (b_ip1'=0)
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& (b_ip0'=0);
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// note: prevent anything else from happening when reconfiguration needs to take place
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// time passage (only if no messages to send or sending a message)
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[time] l>0 & b=0 & n=0 & n0=0 & n1=0 -> (b'=b); // cannot send a message
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[time] l>0 & b>0 & z<1 -> (z'=min(z+1,TIME_MAX_Z)); // sending a message
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// get messages to be sent (so message has same ip address as host)
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[send] l>0 & n=0 -> (b_ip0'=ip) & (n'=n+1);
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[send] l>0 & n=1 -> (b_ip1'=ip) & (n'=n+1);
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[send] l>0 & n=2 -> (b_ip2'=ip) & (n'=n+1);
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[send] l>0 & n=3 -> (b_ip3'=ip) & (n'=n+1);
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[send] l>0 & n=4 -> (b_ip4'=ip) & (n'=n+1);
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[send] l>0 & n=5 -> (b_ip5'=ip) & (n'=n+1);
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[send] l>0 & n=6 -> (b_ip6'=ip) & (n'=n+1);
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[send] l>0 & n=7 -> (b_ip7'=ip) & (n'=n+1);
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[send] l>0 & n=8 -> (n'=n); // buffer full so lose message
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// start sending message from host
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[] l>0 & b=0 & n>0 -> (1-loss) : (b'=1) & (ip_mess'=b_ip0)
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& (n'=n-1)
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& (b_ip7'=0)
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& (b_ip6'=b_ip7)
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& (b_ip5'=b_ip6)
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& (b_ip4'=b_ip5)
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& (b_ip3'=b_ip4)
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& (b_ip2'=b_ip3)
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& (b_ip1'=b_ip2)
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& (b_ip0'=b_ip1) // send message
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+ loss : (n'=n-1)
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& (b_ip7'=0)
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& (b_ip6'=b_ip7)
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& (b_ip5'=b_ip6)
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& (b_ip4'=b_ip5)
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& (b_ip3'=b_ip4)
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& (b_ip2'=b_ip3)
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& (b_ip1'=b_ip2)
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& (b_ip0'=b_ip1); // lose message
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// start sending message to host
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[] l>0 & b=0 & n0>0 -> (1-loss) : (b'=2) & (ip_mess'=0) & (n0'=n0-1) + loss : (n0'=n0-1); // different ip
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[] l>0 & b=0 & n1>0 -> (1-loss) : (b'=2) & (ip_mess'=1) & (n1'=n1-1) + loss : (n1'=n1-1); // same ip
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// finish sending message from host
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[] l>0 & b=1 & ip_mess=0 -> (b'=0) & (z'=0) & (n0'=min(n0+1,B0)) & (ip_mess'=0);
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[] l>0 & b=1 & ip_mess=1 -> (b'=0) & (z'=0) & (n1'=min(n1+1,B1)) & (ip_mess'=0);
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[] l>0 & b=1 & ip_mess=2 -> (b'=0) & (z'=0) & (ip_mess'=0);
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// finish sending message to host
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[rec] l>0 & b=2 -> (b'=0) & (z'=0) & (ip_mess'=0);
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endmodule
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//-------------------------------------------------------------
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// CONCRETE HOST
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module host0
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x : [0..TIME_MAX_X]; // first clock of the host
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y : [0..TIME_MAX_Y]; // second clock of the host
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coll : [0..MAXCOLL]; // number of address collisions
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probes : [0..K]; // counter (number of probes sent)
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mess : [0..1]; // need to send a message or not
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defend : [0..1]; // defend (if =1, try to defend IP address)
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ip : [1..2]; // ip address (1 - in use & 2 - fresh)
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l : [0..4] init 1; // location
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// 0 : RECONFIGURE
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// 1 : RANDOM
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// 2 : WAITSP
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// 3 : WAITSG
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// 4 : USE
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// RECONFIGURE
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[reset] l=0 -> (l'=1);
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// RANDOM (choose IP address)
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[rec] (l=1) -> 1: true; // get message (ignore since have no ip address)
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// small number of collisions (choose straight away)
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[] l=1 & coll<MAXCOLL -> 1/3*old : (l'=2) & (ip'=1) & (x'=0)
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+ 1/3*old : (l'=2) & (ip'=1) & (x'=1)
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+ 1/3*old : (l'=2) & (ip'=1) & (x'=2)
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+ 1/3*new : (l'=2) & (ip'=2) & (x'=0)
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+ 1/3*new : (l'=2) & (ip'=2) & (x'=1)
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+ 1/3*new : (l'=2) & (ip'=2) & (x'=2);
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// large number of collisions: (wait for LONGWAIT)
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[time] l=1 & coll=MAXCOLL & x<LONGWAIT -> (x'=min(x+1,TIME_MAX_X));
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[] l=1 & coll=MAXCOLL & x=LONGWAIT -> 1/3*old : (l'=2) & (ip'=1) & (x'=0)
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+ 1/3*old : (l'=2) & (ip'=1) & (x'=1)
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+ 1/3*old : (l'=2) & (ip'=1) & (x'=2)
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+ 1/3*new : (l'=2) & (ip'=2) & (x'=0)
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+ 1/3*new : (l'=2) & (ip'=2) & (x'=1)
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+ 1/3*new : (l'=2) & (ip'=2) & (x'=2);
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// WAITSP
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// let time pass
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[time] l=2 & x<2 -> (x'=min(x+1,2));
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// send probe
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[send] l=2 & x=2 & probes<K -> (x'=0) & (probes'=probes+1);
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// sent K probes and waited 2 seconds
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[] l=2 & x=2 & probes=K -> (l'=3) & (probes'=0) & (coll'=0) & (x'=0);
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// get message and ip does not match: ignore
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[rec] l=2 & ip_mess!=ip -> (l'=l);
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// get a message with matching ip: reconfigure
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[rec] l=2 & ip_mess=ip -> (l'=0) & (coll'=min(coll+1,MAXCOLL)) & (x'=0) & (probes'=0);
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// WAITSG (sends two gratuitious arp probes)
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// time passage
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[time] l=3 & mess=0 & defend=0 & x<CONSEC -> (x'=min(x+1,TIME_MAX_X));
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[time] l=3 & mess=0 & defend=1 & x<CONSEC -> (x'=min(x+1,TIME_MAX_X)) & (y'=min(y+1,DEFEND));
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// receive message and same ip: defend
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[rec] l=3 & mess=0 & ip_mess=ip & (defend=0 | y>=DEFEND) -> (defend'=1) & (mess'=1) & (y'=0);
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// receive message and same ip: defer
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[rec] l=3 & mess=0 & ip_mess=ip & (defend=0 | y<DEFEND) -> (l'=0) & (probes'=0) & (defend'=0) & (x'=0) & (y'=0);
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// receive message and different ip
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[rec] l=3 & mess=0 & ip_mess!=ip -> (l'=l);
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// send probe reply or message for defence
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[send] l=3 & mess=1 -> (mess'=0);
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// send first gratuitous arp message
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[send] l=3 & mess=0 & x=CONSEC & probes<1 -> (x'=0) & (probes'=probes+1);
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// send second gratuitous arp message (move to use)
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[send] l=3 & mess=0 & x=CONSEC & probes=1 -> (l'=4) & (x'=0) & (y'=0) & (probes'=0);
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// USE (only interested in reaching this state so do not need to add anything here)
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[] l=4 -> 1 : true;
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endmodule
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