source: vis_dev/vis-2.1/share/vis/help/model_checkCmd.txt @ 11

  model_check - perform fair CTL model checking on a flattened network
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   model_check   [-b]   [-c]   [-d   <dbg_level>]   [-f  <dbg_file>]  [-g
   <hints_file>]   [-h]   [-i]   [-m]   [-r]   [-t  <time_out_period>][-v
   <verbosity_level>] [-D <dc_level>] [-F] [-S <schedule>] [-V] [-B] [-I]
   [-C] <ctl_file>

   Performs  fair  CTL  model  checking  on  a  flattened network. Before
   calling  this  command, the user should have initialized the design by
   calling  the  command  [1]init_verify.  Regardless  of the options, no
   'false  positives'  or  'false  negatives'  will  occur: the result is
   correct for the given circuit.

   Properties  to  be  verified should be provided as CTL formulas in the
   file  ctl_file.  Note  that  the  support of any wire referred to in a
   formula  should consist only of latches. For the precise syntax of CTL
   formulas, see the [2]VIS CTL and LTL syntax manual.

   Properties  of  the form AG f, where f is a formula not involving path
   quantifiers  are referred to as invariants; for such properties it may
   be substantially faster to use the [3]check_invariant command.

   A   fairness   constraint   can   be   specified   by   invoking   the
   [4]read_fairness command; if none is specified, all paths are taken to
   be  fair.  If some initial states do not lie on a fair path, the model
   checker prints a message to this effect.

   A  formula passes iff it is true for all initial states of the system.
   Therefore,  in  the  presence of multiple initial states, if a formula
   fails, the negation of the formula may also fail.

   If  a  formula does not pass, a (potentially partial) proof of failure
   (referred  to  as  a  debug  trace)  is  demonstrated.  Fair paths are
   represented  by  a  finite  sequence of states (the stem) leading to a
   fair  cycle, i.e. a cycle on which there is a state from each fairness
   condition.  The  level  of  detail  of the proof can be specified (see
   option -d).

   Both  backward (future tense CTL formulas) and forward (past tense CTL
   formulas)  model  checking can be performed. Forward model checking is
   based  on  Iwashita's  ICCAD96  paper.  Future  tense CTL formulas are
   automatically  converted  to  past  tense  ones as much as possible in
   forward model checking.

   Command options:

   -b
          Use backward analysis when performing debugging; the default is
          to use forward analysis. This should be tried when the debugger
          spends  a  large  amount of time when creating a path to a fair
          cycle.  This  option  is  not  compatible  with  forward  model
          checking option (-F).

   -c
          Use   the   formula  tree  so  that  there  is  no  sharing  of
          sub-formulae  among the formulae in the input file. This option
          is  useful  in the following scenario - formulae A, B and C are
          being checked in order and there is sub-formula sharing between
          A and C. If the BDDs corresponding to the shared sub-formula is
          huge then computation for B might not be able to finish without
          using this option.

   -d <dbg_level>
          Specify the amount of debugging performed when the system fails
          a  formula  being  checked.  Note  that  it  may  not always be
          possible  to  give  a  simple  counter-example  to  show that a
          formula  is false, since this may require enumerating all paths
          from  a  state.  In  such a case the model checker will print a
          message to this effect. This option is incompatible with -F.

          dbg_level must be one of the following:

          0: No debugging performed. dbg_level=0 is the default.

          1: Debugging with minimal output: generate counter-examples for
          universal  formulas  (formulas  of  the  form  AX|AF|AU|AG) and
          witnesses  for  existential  formulas  (formulas  of  the  form
          EX|EF|EU|EG). States on a path are not further analyzed.

          2:  Same as dbg_level=1, but more verbose. (The subformulas are
          printed, too.)

          3:  Maximal  automatic  debugging:  as for level 1, except that
          states occurring on paths will be recursively analyzed.

          4: Manual debugging: at each state, the user is queried if more
          feedback is desired.

   -f <dbg_file>
          Write   the   debugger  output  to  dbg_file.  This  option  is
          incompatible  with  -F.  Notes:  when  you use -d4 (interactive
          mode), -f is not recommended, since you can't see the output of
          vis on stdout.

   -g <hints_file>
          Use  guided  search.  The  file hints_file contains a series of
          hints.  A  hint is a formula that does not contain any temporal
          operators,  so  hints_file  has  the  same  syntax as a file of
          invariants  used for check_invariant. The hints are used in the
          order  given  to change the transition relation. In the case of
          least  fixpoints (EF, EU), the transition relation is conjoined
          with  the  hint,  whereas for greatest fixpoints the transition
          relation  is  disjoined  with  the negation of the hint. If the
          hints  are  cleverly  chosen, this may speed up the computation
          considerably,  because  a  search  with  the changed transition
          relation  may  be  much  simpler  than  one  with  the original
          transition  relation,  and  results  obtained can be reused, so
          that  we  may  never  have  to do a complicated search with the
          original  relation.  Note: hints in terms of primary inputs are
          not  useful for greatest fixpoints. See also: Ravi and Somenzi,
          Hints to accelerate symbolic traversal. CHARME'99; Bloem, Ravi,
          and  Somenzi,  Efficient Decision Procedures for Model Checking
          of  Linear  Time  Logic  Properties,  CAV'99;  Bloem, Ravi, and
          Somenzi, Symbolic Guided Search for CTL Model Checking, DAC'00.

          For  formulae  that  contain both least and greatest fixpoints,
          the behavior depends on the flag guided_search_hint_type. If it
          is set to local (default) then every subformula is evaluated to
          completion,   using   all  hints  in  order,  before  the  next
          subformula  is started. For pure ACTL or pure ECTL formulae, we
          can  also  set guided_search_hint_type to global, in which case
          the  entire  formula is evaluated for one hint before moving on
          to the next hint, using underapproximations. The description of
          the options for guided search can be found in the help page for
          print_guided_search_options.

          model_check  will  call reachability without any guided search,
          even  if  -g  is used. If you want to perform reachability with
          guided search, call rch directly.

          Incompatible with -F.

   -h
          Print the command usage.

   -i
          Print  input  values  causing transitions between states during
          debugging.  Both  primary  and  pseudo inputs are printed. This
          option is incompatible with -F.

   -m
          Pipe debugger output through the UNIX utility more. This option
          is incompatible with -F.

   -r
          Reduce  the FSM derived from the flattened network with respect
          to  each  formula being checked. By default, the FSM is reduced
          with  respect  to  the conjunction of the formulae in the input
          file. If this option is used and don't cares are being used for
          simplification,  then  subformula  sharing  is disabled (result
          might be incorrect otherwise).

          The  truth  of  a  formula  may  be independent of parts of the
          network   (such   as  when  wires  have  been  abstracted;  see
          [5]flatten_hierarchy). These parts are effectively removed when
          this option is invoked; this may result in more efficient model
          checking.

   -t <timeOutPeriod>
          Specify  the  time  out  period  (in  seconds)  after which the
          command aborts. By default this option is set to infinity.

   -v <verbosity_level>
          Specify  verbosity  level.  This sets the amount of feedback on
          CPU usage and code status.
          verbosity_level must be one of the following:

          0: No feedback provided. This is the default.

          1: Feedback on code location.

          2: Feedback on code location and CPU usage.

   -B
          Check  for  vacuously  passing  formulae using the algorithm of
          Beer  et al. (CAV97). The algorithm applies to a subset of ACTL
          (w-ACTL)  and  replaces  the smallest important subformula of a
          passing  property  with  either  FALSE or TRUE depending on its
          negation   parity.  It  then  applies  model  checking  to  the
          resulting  witness formula. If the witness formula also passes,
          then  the  original formula is deemed to pass vacuously. If the
          witness  formula  fails,  a  counterexample  to  it provides an
          interesting  witness  to  the original passing formula. See the
          CAV97   paper   for   the   definitions  of  w-ACTL,  important
          subformula,  and  interesting  witness.  In  short,  one of the
          operands  of  a  binary  operator in a w-ACTL formula must be a
          propositional formula. See also the -V option.

   -C
          Compute  coverage  of  all  observable  signals in a set of CTL
          formulae   using  the  algorithm  of  Hoskote,  Kam,  Ho,  Zhao
          (DAC'99).  If  the  verbosity  level (-v option) is equal to 0,
          only  the  coverage  stats  are  printed. If verbosity level is
          greater than zero, then detailed information of the computation
          at   each  step  of  the  algorithm  is  also  provided.  Debug
          information  is  provided in the form of states not covered for
          each  observable signal if the dbg_level (-d option) is greater
          than  0.  The  number  of  states  printed  is  set  by the vis
          environment   variable  'nr_uncoveredstates'.  By  default  the
          number  of states printed is 1. The value of nr_uncoveredstates
          can be set using the set command. See also the -I option.

   -D <dc_level>
          Specify  extent  to which don't cares are used to simplify MDDs
          in model checking. Don't cares are minterms on which the values
          taken  by functions do not affect the computation; potentially,
          these minterms can be used to simplify MDDs and reduce the time
          taken  to perform model checking. The -g flag for guided search
          does  not affect the way in which the don't-care conditions are
          computed.
          dc_level must be one of the following:

          0 : No don't cares are used.

          1 : Use unreachable states as don't cares. This is the default.

          2  :  Use  unreachable  states  as  don't  cares  and in the EU
          computation, use 'frontiers' for image computation.

          3  : First compute an overapproximation of the reachable states
          (ARDC),  and  use  that  as  the cares set. Use `frontiers' for
          image  computation.  For  help on controlling options for ARDC,
          look  up  help  on the command: [6]print_ardc_options. Refer to
          Moon,  Jang,  Somenzi,  Pixley, Yuan, "Approximate Reachability
          Don't  Cares  for  {CTL}  Model  Checking", ICCAD98, and to two
          papers  by Cho et al, IEEE TCAD December 1996: one is for State
          Space  Decomposition  and  the  other  is  for  Approximate FSM
          Traversal.

   -F
          Use  forward  model  checking  based  on  Iwashita's  method in
          ICCAD96.  Future tense CTL formulas are automatically converted
          to  past  tense  ones  as  much  as possible. Converted forward
          formulas  are  printed  when verbosity is greater than 0. Debug
          options  (-b, -d, -f, -i, and -m) are ignored with this option.
          We  have  seen that forward model checking was much faster than
          backward  in  many  cases,  also  forward  was much slower than
          backward in many cases.

   -I
          Compute  coverage  of  all  observable  signals in a set of CTL
          formulae  using  an improved algorithm of Jayakumar, Purandare,
          Somenzi  (DAC'03).  If the verbosity level (-v option) is equal
          to  0,  only the coverage stats are printed. If verbosity level
          is   greater  than  zero,  then  detailed  information  of  the
          computation  at  each  step  of the algorithm is also provided.
          Debug information is provided in the form of states not covered
          for  each  observable  signal  if  the dbg_level (-d option) is
          greater  than 0. The number of states printed is set by the vis
          environment   variable  'nr_uncoveredstates'.  By  default  the
          number  of states printed is 1. The value of nr_uncoveredstates
          can  be  set  using the set command. Compared to the -C option,
          this one produces more accurate results and deals with a larger
          subset of CTL.

   -S <schedule>
          Specify  schedule  for  GSH  algorithm,  which  generalizes the
          Emerson-Lei   algorithm   and   is  used  to  compute  greatest
          fixpoints. The choice of schedule affects the sequence in which
          EX  and  EU  operators  are applied. It makes a difference only
          when fairness constraints are specified.
          <schedule> must be one of the following:

          EL  :  EU  and  EX  operators  strictly  alternate. This is the
          default.

          EL1 : EX is applied once for every application of all EUs.

          EL2  :  EX  is applied repeatedly after each application of all
          EUs.

          budget : a hybrid of EL and EL2.

          random  :  enabled  operators  are  applied  in (pseudo-)random
          order.

          off  :  GSH is disabled, and the old algorithm is used instead.
          The  old  algorithm  uses  the EL schedule, but the termination
          checks are less sophisticated than in GSH.

   -V
          Check  for  vacuously  passing  formulae  with the algorithm of
          Purandare  and  Somenzi (CAV2002). The algorithm applies to all
          of  CTL,  and  to  both passing and failing properties. It says
          whether  a  passing formula may be strengthened and still pass,
          and  whether  a failing formula may be weakened and still fail.
          It  considers  all  leaves  of  a  formula  that  are under one
          negation parity (e.g., not descendants of a XOR or EQ node) for
          replacement by either TRUE or FALSE. See also the -B option.

   -w <node_file> This option invoked the algorithm to generate an error
          trace divided into fated and free segements. Fate represents
          the inevitability and free is asserted when there is no
          inevitability. This can be formulated as a two-player
          concurrent reachability game. The two players are the
          environment and the system. The node_file is given To specify
          the variables the are controlled by the system.

   -W
   This option represents the case that all input variables are
          controlled by system.

   -G
   We proposed two algorithm to generate segemented counter example. They
          are general and restrcited algorithm. Bu default we use
          restricted algorithm. We can invoke general algorithm with -G
          option. For more information, please check the STTT'04 paper of
          Jin et al., "Fate and Free Will in Error Traces"

   <ctl_file>
          File containing CTL formulas to be model checked.

   Related "set" options:

   ctl_change_bracket <yes/no>
          Vl2mv  automatically  converts  "[]"  to  "<>"  in  node names,
          therefore  CTL  parser  does  the  same thing. However, in some
          cases a user does not want to change node names in CTL parsing.
          Then, use this set option by giving "no". Default is "yes".

   guided_search_hint_type
          Switches  between local and global hints (see the -g option, or
          the help page for set).

   See also commands : approximate_model_check,
   incremental_ctl_verification
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   Last updated on 20050519 10h16

References

   1. file://localhost/projects/development/hsv/vis/common/doc/html/init_verifyCmd.html
   2. file://localhost/projects/development/hsv/vis/common/doc/ctl/ctl/ctl.html
   3. file://localhost/projects/development/hsv/vis/common/doc/html/check_invariantCmd.html
   4. file://localhost/projects/development/hsv/vis/common/doc/html/read_fairnessCmd.html
   5. file://localhost/projects/development/hsv/vis/common/doc/html/flatten_hierarchyCmd.html
   6. file://localhost/projects/development/hsv/vis/common/doc/html/print_ardc_optionsCmd.html