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Chapter 16 : KRONOS (Model Checking of Real-time Systems). JIHO YANG. What is KRONOS?. KRONOS allows analyzing timed automata. KRONOS is a model checker for the TCTL(Timed CTL) logic. KRONOS checks whether a timed automaton satisfies a TCTL. KRONOS’ Essentials .
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Chapter 16 : KRONOS (Model Checking of Real-time Systems) JIHO YANG
What is KRONOS? • KRONOS allows analyzing timed automata. • KRONOS is a model checker for the TCTL(Timed CTL) logic. • KRONOS checks whether a timed automaton satisfies a TCTL.
KRONOS’ Essentials • KRONOS is one of the tools, which implements a model checking algorithm for a timed temporal logic (TCTL). • KRONOS contains no graphical, no simulation modes. • KRONOS is a timed model checker. • http://www-verimag.imag.fr/TEMPORISE/kronos
Railroad crossing example(Two train, a gate, a controller, a counter)
Cont. KRONOS Code (Tr1.tg) /* train1 */ #locs 3 /* number of states*/ #trans 3 /* number of transitions */ #clocks x1 /* clock */ #sync app1 exit1 /* synchronization labels */ loc: 0 prop: far inv: TRUE trans: TRUE => app1; x1:=0 ; goto 1 loc: 1 prop: near inv: x1 < 30 trans: x1 > 20 and x1 < 30 => enter; ; goto 2 loc: 2 prop: on inv: x1 < 50 trans: x1 > 20 and x1 < 50 => exit1; ; goto 0 (trans: x1 > 30 and x1 < 50 => exit1; ; goto 0)
Synchronized Product • In order for several components of a system to communicate, KRONOS introduce a synchronization function. • KRONOS, a synchronization label is simply obtained by the union of the label sets of the components. • A set of transitions are synchronized if and only if each label occurring in one of the transition sets also belongs to one set of another transition.
Cont. (example) • A1 containts the single transition {a,b} t1 : q1 ------- r1 • A2 contains the single transition {b,c} t2 : q2 ------- r2
Cont. (example) • If b is a synchronization label, then the product of automata A1 and A2 contains transition of {a,b,c} q1,q2 ---------- r1,r2.
Kronos code (Example) • Extension “.tg” : “timed graph” • Make the product of A1 and A2: A(12) Kronos -out A12.tg A1.tg A2.tg
Cont.(Example) • Compose the result A(12) with A3: (we can express kronos code like) Kronos -out A12A3.tg A12.tg A3.tg
Cont. • The automaton A(12)3 – the product of A1 and A2, and then compose the result A(12) with A3 • The automaton A1(23) – the product of A2 and A3, and then compose the result A(23) with A1 • It is not easy to use a modular approach.
Cont. • There is two ways to overcome. • The first one consists in building in a single operation the product of all components of a given system. • Kronos code: Kronos –out S.tg Tr1.tg Tr2.tg Gate.tg Contr.tg Ct.tg
Cont. • The second way: use a special option “-sd” • Kronos –sd –out A12.tg A1.tg A2.tg
Model checking • The properties to be checked must be expressed by TCTL. • Each being in a separate file with extension “.tctl”
Safety property • Safety property : Under certain conditions, an event never occur. ……??? • “when a train is inside the crossing, the gate is closed.” • Safe.tctl : Init impl AB(on impl closed) • AB correspond A and G of CTL • Impl : Boolean combinator
Cont. • Verifying safety property KRONOS command: • Kronos –back S.tgsafe.tctl • (backward analysis) • Kronos –forw S.tgsafe.tctl • (forwards analysis) • Safe.eval contains the result
Liveness property • Liveness property: under certain condition, some event will ultimately occur. • “from the moment where no train arrives anymore, the gate will be open after d time units.” • Express TCTL
Cont. • Init => AG (┐near ^ ┐on => ┐E(┐near ^ ┐on ^ ┐open) U (>d) true)) • Write KRONOS when d = 20; Init impl AB((not near and not on) impl not((not near and not on and not open) EU{>20} TRUE))