StatAnaCSP.hs revision 5cc369fbceee1b13bd0f06e43620c46541d1d4f8
{- |
Module : $Id$
Description : Static analysis of CspCASL
Copyright : (c) Andy Gimblett, Liam O'Reilly Markus Roggenbach,
Swansea University 2008
License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt
Maintainer : a.m.gimblett@swansea.ac.uk
Stability : provisional
Portability : portable
Static analysis of CSP-CASL specifications, following "Tool Support
for CSP-CASL", MPhil thesis by Andy Gimblett, 2008.
-}
module CspCASL.StatAnaCSP where
import qualified Control.Monad as Monad
import qualified Data.Map as Map
import qualified Data.Set as S
import CASL.AS_Basic_CASL (FORMULA(..), OpKind(..), SORT, TERM(..), VAR,
VAR_DECL(..))
import CASL.MixfixParser
import CASL.Overload (minExpFORMULA, oneExpTerm)
import CASL.Sign
import CASL.StaticAna (allConstIds, allOpIds, allPredIds)
import Common.AS_Annotation
import Common.Result
import Common.GlobalAnnotations
import Common.ConvertGlobalAnnos
import qualified Common.Lib.Rel as Rel
import Common.Id (getRange, Id, nullRange, simpleIdToId, tokStr)
import Common.Lib.State
import Common.ExtSign
import CspCASL.AS_CspCASL
import CspCASL.AS_CspCASL_Process
import CspCASL.LocalTop (Obligation(..), unmetObs)
import CspCASL.Print_CspCASL ()
import CspCASL.SignCSP
import CspCASL.Morphism(makeChannelNameSymbol, makeProcNameSymbol)
-- | The first element of the returned pair (CspBasicSpec) is the same
-- as the inputted version just with some very minor optimisations -
-- none in our case, but for CASL - brackets are otimized. This all
-- that happens, the mixfixed terms are still mixed fixed terms in
-- the returned version.
basicAnalysisCspCASL :: (CspBasicSpec, CspCASLSign, GlobalAnnos)
-> Result (CspBasicSpec, ExtSign CspCASLSign Symbol,
[Named CspCASLSen])
basicAnalysisCspCASL (cc, sigma, ga) =
let Result es mga = mergeGlobalAnnos ga $ globAnnos sigma
(_, accSig) = runState (ana_BASIC_CSP cc) $ case mga of
Nothing -> sigma
Just nga -> sigma { globAnnos = nga }
ds = reverse $ envDiags accSig
-- Extract process equations only.
ext = extendedInfo accSig
ccsents = reverse $ ccSentences ext
-- Clean signature here
cleanSig = accSig
{ extendedInfo = ext { ccSentences = []}}
in Result (es ++ ds) $
Just (cc, ExtSign cleanSig $ declaredSymbols accSig, ccsents)
ana_BASIC_CSP :: CspBasicSpec -> State CspCASLSign ()
ana_BASIC_CSP cc = do checkLocalTops
mapM anaChanDecl (channels cc)
mapM anaProcItem (proc_items cc)
return ()
-- Analysis of local top elements
-- | Check a CspCASL signature for local top elements in its subsort
-- relation.
checkLocalTops :: State CspCASLSign ()
checkLocalTops = do
sig <- get
let obs = unmetObs $ Rel.toList $ Rel.transClosure $ sortRel sig
addDiags (map lteError obs)
return ()
-- | Add diagnostic error message for every unmet local top element
-- obligation.
lteError :: Obligation SORT -> Diagnosis
lteError (Obligation x y z) = mkDiag Error msg ()
where msg = ("local top element obligation ("
++ (show x) ++ "<" ++ (show y) ++ "," ++ (show z)
++ ") unfulfilled")
-- Static analysis of channel declarations
-- | Statically analyse a CspCASL channel declaration.
anaChanDecl :: CHANNEL_DECL -> State CspCASLSign ()
anaChanDecl (ChannelDecl chanNames chanSort) = do
checkSorts [chanSort] -- check channel sort is known
sig <- get
let ext = extendedInfo sig
oldChanMap = chans ext
newChanMap <- Monad.foldM (anaChannelName chanSort) oldChanMap chanNames
sig2 <- get
put sig2 { extendedInfo = ext { chans = newChanMap }}
-- | Statically analyse a CspCASL channel name.
anaChannelName :: SORT -> ChanNameMap -> CHANNEL_NAME ->
State CspCASLSign ChanNameMap
anaChannelName s m chanName = do
sig <- get
then do let err = "channel name already in use as a sort name"
addDiags [mkDiag Error err chanName]
return m
else case Map.lookup chanName m of
Nothing ->
-- Add the channel name as a symbol to the list of
-- newly defined symbols - which is stored in the CASL
-- signature
do addSymbol (makeChannelNameSymbol chanName)
return (Map.insert chanName s m) -- insert new.
Just e ->
if e == s
then do let warn = "channel redeclared with same sort"
addDiags [mkDiag Warning warn chanName]
return m -- already declared with this sort.
else do let err = "channel declared with multiple sorts"
addDiags [mkDiag Error err chanName]
return m
-- Static analysis of process items
-- | Statically analyse a CspCASL process item.
anaProcItem :: PROC_ITEM -> State CspCASLSign ()
anaProcItem procItem =
case procItem of
(Proc_Decl name argSorts alpha) -> anaProcDecl name argSorts alpha
(Proc_Eq parmProcName procTerm) -> anaProcEq parmProcName procTerm
-- Static analysis of process declarations
-- | Statically analyse a CspCASL process declaration.
anaProcDecl :: PROCESS_NAME -> PROC_ARGS -> PROC_ALPHABET
-> State CspCASLSign ()
anaProcDecl name argSorts (ProcAlphabet commTypes _) = do
sig <- get
let ext = extendedInfo sig
oldProcDecls = procSet ext
newProcDecls <-
if name `Map.member` oldProcDecls
then do -- duplicate process declaration
let err = "process name declared more than once"
addDiags [mkDiag Error err name]
return oldProcDecls
else do -- new process declation
checkSorts argSorts -- check argument sorts are known
-- build alphabet: set of CommType values. We do not
-- need the fully qualfied commTypes that are returned
-- (these area used for analysing Event Sets)
(alpha, _ ) <-
Monad.foldM (anaCommType sig) (S.empty, []) commTypes
let profile = (ProcProfile argSorts alpha)
-- Add the process name as a symbol to the list of
-- newly defined symbols - which is stored in the CASL
-- signature
addSymbol (makeProcNameSymbol name)
return (Map.insert name profile oldProcDecls)
sig2 <- get
put sig2 { extendedInfo = ext {procSet = newProcDecls }}
-- Static analysis of process equations
-- | Statically analyse a CspCASL process equation.
anaProcEq :: PARM_PROCNAME -> PROCESS -> State CspCASLSign ()
anaProcEq (ParmProcname pn vs) proc = do
sig <- get
let ext = extendedInfo sig
ccsens = ccSentences ext
procDecls = procSet ext
prof = pn `Map.lookup` procDecls
case prof of
-- Only analyse a process if its name (and thus profile) is known
Just (ProcProfile procArgs procAlpha) ->
do gVars <- anaProcVars pn procArgs vs -- compute global
-- vars Change a procVarList to a FQProcVarList We do
-- not care about the range as we are building fully
-- qualified variables and they have already been
-- checked to be ok.
let mkFQProcVar (v,s) = Qual_var v s nullRange
let fqGVars = map mkFQProcVar gVars
(termAlpha, fqProc) <-
anaProcTerm proc (Map.fromList gVars) Map.empty
checkCommAlphaSub termAlpha procAlpha proc "process equation"
-- Save the diags from the checkCommAlphaSub
vds <- gets envDiags
-- put CspCASL Sentences back in to the state with new sentence
put sig {envDiags = vds, extendedInfo =
ext { ccSentences =
-- BUG - What should the constituent
-- alphabet be for this process?
-- probably the same as the inner one!
(makeNamed ("Proc_" ++ tokStr pn)
(ProcessEq pn fqGVars
procAlpha
fqProc)):ccsens
}
}
return ()
Nothing ->
do addDiags [mkDiag Error
"process equation for unknown process" pn]
return ()
return ()
-- | Statically analyse a CspCASL process equation's global variable
-- names.
anaProcVars :: PROCESS_NAME -> [SORT] -> [VAR] -> State CspCASLSign ProcVarList
anaProcVars pn ss vs =
do vars <-
case (compare (length ss) (length vs)) of
LT -> do addDiags [mkDiag Error "too many process arguments" pn]
return []
GT -> do addDiags [mkDiag Error "not enough process arguments" pn]
return []
EQ -> Monad.foldM anaProcVar [] (zip vs ss)
return $ reverse $ vars
-- | Statically analyse a CspCASL process-global variable name.
anaProcVar :: ProcVarList -> (VAR, SORT) -> State CspCASLSign ProcVarList
anaProcVar old (v, s) = do
if v `elem` (map fst old)
then do addDiags [mkDiag Error
"process argument declared more than once" v]
return old
else return ((v,s) : old)
-- Static analysis of process terms
-- BUG in fucntion below
-- not returing FQProcesses
-- | Statically analyse a CspCASL process term.
-- The process that is returned is a fully qualified process.
anaProcTerm :: PROCESS -> ProcVarMap -> ProcVarMap ->
State CspCASLSign (CommAlpha, PROCESS)
anaProcTerm proc gVars lVars = case proc of
NamedProcess name args r ->
do addDiags [mkDiag Debug "Named process" proc]
(al, fqArgs) <- anaNamedProc proc name args (lVars `Map.union` gVars)
let fqProc = FQProcess (NamedProcess name fqArgs r) al r
return (al, fqProc)
Skip r ->
do addDiags [mkDiag Debug "Skip" proc]
let fqProc = FQProcess (Skip r) S.empty r
return (S.empty, fqProc)
Stop r ->
do addDiags [mkDiag Debug "Stop" proc]
let fqProc = FQProcess (Stop r) S.empty r
return (S.empty, fqProc)
Div r ->
do addDiags [mkDiag Debug "Div" proc]
let fqProc = FQProcess (Div r) S.empty r
return (S.empty, fqProc)
Run es r ->
do addDiags [mkDiag Debug "Run" proc]
(comms, fqEs) <- anaEventSet es
let fqProc = FQProcess (Run fqEs r) comms r
return (comms, fqProc)
Chaos es r ->
do addDiags [mkDiag Debug "Chaos" proc]
(comms, fqEs) <- anaEventSet es
let fqProc = FQProcess (Chaos fqEs r) comms r
return (comms, fqProc)
PrefixProcess e p r ->
do addDiags [mkDiag Debug "Prefix" proc]
(evComms, rcvMap, fqEvent) <- anaEvent e (lVars `Map.union` gVars)
(comms, pFQTerm) <- anaProcTerm p gVars (rcvMap `Map.union` lVars)
let newAlpha = comms `S.union` evComms
let fqProc = FQProcess (PrefixProcess fqEvent pFQTerm r) newAlpha r
return (newAlpha, fqProc)
Sequential p q r ->
do addDiags [mkDiag Debug "Sequential" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(qComms, qFQTerm) <- anaProcTerm q gVars Map.empty
let newAlpha = pComms `S.union` qComms
let fqProc = FQProcess (Sequential pFQTerm qFQTerm r) newAlpha r
return (newAlpha, fqProc)
InternalChoice p q r ->
do addDiags [mkDiag Debug "InternalChoice" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
let newAlpha = pComms `S.union` qComms
let fqProc = FQProcess (InternalChoice pFQTerm qFQTerm r) newAlpha r
return (newAlpha, fqProc)
ExternalChoice p q r ->
do addDiags [mkDiag Debug "ExternalChoice" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
let newAlpha = pComms `S.union` qComms
let fqProc = FQProcess (ExternalChoice pFQTerm qFQTerm r) newAlpha r
return (newAlpha, fqProc)
Interleaving p q r ->
do addDiags [mkDiag Debug "Interleaving" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
let newAlpha = pComms `S.union` qComms
let fqProc = FQProcess (Interleaving pFQTerm qFQTerm r) newAlpha r
return (newAlpha, fqProc)
SynchronousParallel p q r ->
do addDiags [mkDiag Debug "Synchronous" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
let newAlpha = pComms `S.union` qComms
let fqProc = FQProcess (SynchronousParallel pFQTerm
qFQTerm r) newAlpha r
return (newAlpha, fqProc)
GeneralisedParallel p es q r ->
do addDiags [mkDiag Debug "Generalised parallel" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(synComms, fqEs) <- anaEventSet es
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
let newAlpha = S.unions [pComms, qComms, synComms]
let fqProc = FQProcess (GeneralisedParallel pFQTerm fqEs qFQTerm r)
newAlpha r
return (newAlpha, fqProc)
AlphabetisedParallel p esp esq q r ->
do addDiags [mkDiag Debug "Alphabetised parallel" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(pSynComms, fqEsp) <- anaEventSet esp
checkCommAlphaSub pSynComms pComms proc "alphabetised parallel, left"
(qSynComms, fqEsq) <- anaEventSet esq
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
checkCommAlphaSub qSynComms qComms proc
"alphabetised parallel, right"
let newAlpha = pComms `S.union` qComms
let fqProc = FQProcess (AlphabetisedParallel pFQTerm fqEsp fqEsq
qFQTerm r) newAlpha r
return (newAlpha, fqProc)
Hiding p es r ->
do addDiags [mkDiag Debug "Hiding" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(hidComms, fqEs) <- anaEventSet es
return (pComms `S.union` hidComms, FQProcess (Hiding pFQTerm fqEs r)
(pComms `S.union` hidComms) r)
RenamingProcess p renaming r ->
do addDiags [mkDiag Debug "Renaming" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(renAlpha, fqRenaming) <- anaRenaming renaming
let newAlpha = pComms `S.union` renAlpha
let fqProc = FQProcess (RenamingProcess pFQTerm fqRenaming r)
(pComms `S.union` renAlpha) r
return (newAlpha, fqProc)
ConditionalProcess f p q r ->
do addDiags [mkDiag Debug "Conditional" proc]
(pComms, pFQTerm) <- anaProcTerm p gVars lVars
(qComms, qFQTerm) <- anaProcTerm q gVars lVars
-- mfs is the fully qualified formula version of f
mfs <- anaFormulaCspCASL (gVars `Map.union` lVars) f
let fFQ = case mfs of
Nothing -> f -- use old formula as the fully
-- qualified version - there is a
-- error in the spec anyway as the
-- formula could not be fully
-- qualified.
Just fs -> fs -- use the real fully qualified formula
let fComms = case mfs of
Nothing -> S.empty
Just fs -> formulaComms fs
let newAlpha = S.unions [pComms, qComms, fComms]
let fqProc = FQProcess (ConditionalProcess
(fFQ) pFQTerm qFQTerm r)
newAlpha r
return (newAlpha, fqProc)
FQProcess _ _ _ ->
error "CspCASL.StatAnaCSP.anaProcTerm: Unexpected FQProcess"
-- | Statically analyse a CspCASL "named process" term. Return the
-- permitted alphabet of the process and also a list of the fully qualified
-- version of the inputted terms.
anaNamedProc :: PROCESS -> PROCESS_NAME -> [TERM ()] -> ProcVarMap ->
State CspCASLSign (CommAlpha, [TERM ()])
anaNamedProc proc pn terms procVars = do
sig <- get
let ext = extendedInfo sig
procDecls = procSet ext
prof = pn `Map.lookup` procDecls
case prof of
Just (ProcProfile varSorts permAlpha) ->
if (length terms) == (length varSorts)
then do fqTerms <-
mapM (anaNamedProcTerm procVars) (zip terms varSorts)
-- Return the permitted alphabet of the process and
-- the fully qualifed terms
return (permAlpha, fqTerms)
else do let err = "wrong number of arguments in named process"
addDiags [mkDiag Error err proc]
-- Return the empty alphabet and the original
-- terms. There is an error in the spec.
return (S.empty, terms)
Nothing ->
do addDiags [mkDiag Error "unknown process name" proc]
-- Return the empty alphabet and the original
-- terms. There is an error in the spec.
return (S.empty, terms)
-- | Statically analysis a CASL term occurring in a CspCASL "named
-- process" term.
anaNamedProcTerm :: ProcVarMap -> ((TERM ()), SORT) ->
State CspCASLSign (TERM ())
anaNamedProcTerm pm (t, expSort) = do
mt <- anaTermCspCASL pm t
case mt of
Nothing -> return t -- CASL term analysis failed. Use old term
-- as the fully qualified term, there is a
-- error in the spec anyway.
(Just at) -> do at' <- ccTermCast at expSort -- attempt cast;
case at' of
Nothing -> -- Use old term as the fully
-- qualified term, there is a error
-- in the spec anyway.
return t
(Just at'') -> return at'' -- Use the fully
-- qualified
-- (possibly cast)
-- term
-- Static analysis of event sets and communication types
-- | Statically analyse a CspCASL event set. Returns the alphabet of
-- the event set and a fully qualified version of the event set.
anaEventSet :: EVENT_SET -> State CspCASLSign (CommAlpha, EVENT_SET)
anaEventSet eventSet =
case eventSet of
EventSet es r ->
do sig <- get
-- fqEsElems is built the reversed order for efficiency.
(comms, fqEsElems) <- Monad.foldM (anaCommType sig)
(S.empty, []) es
vds <- gets envDiags
put sig { envDiags = vds }
-- reverse the list inside the event set
return (comms, FQEventSet (reverse fqEsElems) r)
FQEventSet _ _ ->
error "CspCASL.StatAnaCSP.anaEventSet: Unexpected FQEventSet"
-- | Statically analyse a CspCASL communication type. Returns the
-- extended alphabet and the extended list of fully qualified event
-- set elements - [CommType].
anaCommType :: CspCASLSign -> (CommAlpha, [CommType]) -> COMM_TYPE ->
State CspCASLSign (CommAlpha, [CommType])
anaCommType sig (alpha, fqEsElems) ct =
if ctSort `S.member` (sortSet sig)
then -- ct is a sort name; insert sort into alpha and add a sort
-- to the fully qualified event set elements.
do let newAlpha = S.insert (CommTypeSort ctSort) alpha
let newFqEsElems = (CommTypeSort ctSort) : fqEsElems
return (newAlpha, newFqEsElems)
else -- ct not a sort name, so should be a channel name
case Map.lookup ct (chans $ extendedInfo sig) of
Just s -> -- ct is a channel name; insert typed chan name
-- into alpha and add typed channel to the fully
-- qualified event set elemenets.
let newAlpha = S.insert (mkTypedChan ct s) alpha
newFqEsElems = (mkTypedChan ct s) : fqEsElems
in return (newAlpha, newFqEsElems)
Nothing -> do let err = "not a sort or channel name"
addDiags [mkDiag Error err ct]
-- failed, thus error in spec, return the
-- unmodified alphabet and the unmodifled
-- fully qualified event set elements.
return (alpha, fqEsElems)
where ctSort = simpleIdToId ct
mkTypedChan c s = CommTypeChan $ TypedChanName c s
-- Static analysis of events
-- | Statically analyse a CspCASL event. Returns a constituent
-- communication alphabet of the event, mapping for any new
-- locally bound variables and a fully qualified version of the event.
anaEvent :: EVENT -> ProcVarMap ->
State CspCASLSign (CommAlpha, ProcVarMap, EVENT)
anaEvent e vars =
case e of
TermEvent t range ->
do addDiags [mkDiag Debug "Term event" e]
(alpha, newVars, fqTerm) <- anaTermEvent t vars
let fqEvent = FQEvent e Nothing fqTerm range
return (alpha, newVars, fqEvent)
InternalPrefixChoice v s range ->
do addDiags [mkDiag Debug "Internal prefix event" e]
(alpha, newVars, fqVar) <- anaPrefixChoice v s
let fqEvent = FQEvent e Nothing fqVar range
return (alpha, newVars, fqEvent)
ExternalPrefixChoice v s range ->
do addDiags [mkDiag Debug "External prefix event" e]
(alpha, newVars, fqVar) <- anaPrefixChoice v s
let fqEvent = FQEvent e Nothing fqVar range
return (alpha, newVars, fqEvent)
ChanSend c t range ->
do addDiags [mkDiag Debug "Channel send event" e]
-- mfqChan is a maybe fully qualified
-- channel. It will be Nothing if
-- annChanSend failed - i.e. we forget
-- about the channel.
(alpha, newVars, mfqChan, fqTerm) <- anaChanSend c t vars
let fqEvent = FQEvent e mfqChan fqTerm range
return (alpha, newVars, fqEvent)
ChanNonDetSend c v s range ->
do addDiags [mkDiag Debug "Channel nondeterministic send event" e]
-- mfqChan is the same as in chanSend case.
-- fqVar is the fully qualfied version of the variable.
(alpha, newVars, mfqChan, fqVar) <- anaChanBinding c v s
let fqEvent = FQEvent e mfqChan fqVar range
return (alpha, newVars, fqEvent)
ChanRecv c v s range ->
do addDiags [mkDiag Debug "Channel receive event" e]
-- mfqChan is the same as in chanSend case.
-- fqVar is the fully qualfied version of the variable.
(alpha, newVars, mfqChan, fqVar) <- anaChanBinding c v s
let fqEvent = FQEvent e mfqChan fqVar range
return (alpha, newVars, fqEvent)
FQEvent _ _ _ _ ->
error "CspCASL.StatAnaCSP.anaEvent: Unexpected FQEvent"
-- | Statically analyse a CspCASL term event. Returns a constituent
-- communication alphabet of the event and a mapping for any new
-- locally bound variables and the fully qualified version of the
-- term.
anaTermEvent :: (TERM ()) -> ProcVarMap ->
State CspCASLSign (CommAlpha, ProcVarMap, TERM ())
anaTermEvent t vars = do
mt <- anaTermCspCASL vars t
let (alpha, t') = case mt of
-- return the alphabet and the fully qualified term
Just at -> ([(CommTypeSort (sortOfTerm at))], at)
-- return the empty alphabet and the original term
Nothing -> ([], t)
return (S.fromList alpha, Map.empty, t')
-- | Statically analyse a CspCASL internal or external prefix choice
-- event. Returns a constituent communication alphabet of the event
-- and a mapping for any new locally bound variables and the fully
-- qualified version of the variable.
anaPrefixChoice :: VAR -> SORT ->
State CspCASLSign (CommAlpha, ProcVarMap, TERM ())
anaPrefixChoice v s = do
checkSorts [s] -- check sort is known
let alpha = S.singleton $ CommTypeSort s
let binding = Map.singleton v s
let fqVar = Qual_var v s nullRange
return (alpha, binding, fqVar)
-- | Statically analyse a CspCASL channel send event. Returns a
-- constituent communication alphabet of the event, a mapping for
-- any new locally bound variables, a fully qualified channel (if
-- possible) and the fully qualified version of the term.
anaChanSend :: CHANNEL_NAME -> (TERM ()) -> ProcVarMap ->
State CspCASLSign (CommAlpha, ProcVarMap,
(Maybe (CHANNEL_NAME, SORT)), TERM ())
anaChanSend c t vars = do
sig <- get
let ext = extendedInfo sig
case c `Map.lookup` (chans ext) of
Nothing -> do
addDiags [mkDiag Error "unknown channel" c]
-- Use old term as the fully qualified term and forget about the
-- channel, there is an error in the spec
Just chanSort -> do
mt <- anaTermCspCASL vars t
case mt of
Nothing -> -- CASL analysis failed. Use old term as the fully
-- qualified term and forget about the channel,
-- there is an error in the spec.
(Just at) ->
do mc <- ccTermCast at chanSort
case mc of
Nothing -> -- cast failed. Use old term as the fully
-- qualified term, and forget about the
-- channel there is an error in the spec.
(Just ct) ->
do let castSort = sortOfTerm ct
alpha = [CommTypeSort castSort
,CommTypeChan $ TypedChanName c castSort
]
-- Use the real fully qualified term. We do
-- not want to use a cast term here. A cast
-- must be possible, but we do not want to
-- force it!
return (S.fromList alpha, Map.empty,
Just (c, chanSort), at)
-- | Statically analyse a CspCASL "binding" channel event (which is
-- either a channel nondeterministic send event or a channel receive
-- event). Returns a constituent communication alphabet of the event,
-- a mapping for any new locally bound variables, a fully qualified
-- channel (if possible) and the fully qualified version of the
-- variable.
anaChanBinding :: CHANNEL_NAME -> VAR -> SORT ->
State CspCASLSign( CommAlpha,
ProcVarMap,
(Maybe (CHANNEL_NAME, SORT)), TERM ()
)
anaChanBinding c v s = do
checkSorts [s] -- check sort is known
sig <- get
let ext = extendedInfo sig
case c `Map.lookup` (chans ext) of
Nothing -> do
addDiags [mkDiag Error "unknown channel" c]
-- No fully qualified channel, use Nothing - there is a error in
-- the spec anyway. Use the real fully qualified variable
-- version with a nullRange.
Just chanSort -> do
then do let alpha = [CommTypeSort s
,CommTypeChan (TypedChanName c s)]
let binding = [(v, s)]
-- Return the alphabet, var mapping, the fully
-- qualfied channel and fully qualfied
-- variable. Notice that the fully qualified
-- channel's sort should be the lowest sort we can
-- communicate in i.e. the sort of the variable.
return (S.fromList alpha, Map.fromList binding,
(Just (c,s)), (Qual_var v s nullRange))
else do let err = "sort not a subsort of channel's sort"
addDiags [mkDiag Error err s]
-- There is a error in the spec, but return
-- the alphabet, var mapping, the fully
-- qualfied channel and fully qualfied
-- variable - as we can.
(Qual_var v s nullRange))
where subsorts = Rel.predecessors (sortRel sig)
-- Static analysis of renaming and renaming items
-- | Statically analyse a CspCASL renaming. Returns the alphabet and
-- | the fully qualified renaming.
anaRenaming :: RENAMING -> State CspCASLSign (CommAlpha, RENAMING)
anaRenaming renaming = case renaming of
Renaming r -> do
(al, fqRenamingTermsMaybes) <- Monad.foldM anaRenamingItem (S.empty, []) r
return (al, FQRenaming fqRenamingTermsMaybes)
FQRenaming _ ->
error "CspCASL.StatAnaCSP.anaRenaming: Unexpected FQRenaming"
-- | Statically analyse a CspCASL renaming item. Return the alphabet
-- | and the fully qualified list of renaming functions and predicates.
anaRenamingItem :: (CommAlpha, [TERM ()]) -> Id ->
State CspCASLSign (CommAlpha, [TERM ()])
anaRenamingItem (inAl, fqRenamingTerms) ri = do
-- BUG -- too many nothings - should only be one
totOps <- getUnaryOpsById ri Total
if (not $ S.null totOps)
then return (inAl `S.union` totOps, fqRenamingTerms)
else do
parOps <- getUnaryOpsById ri Partial
if not (S.null parOps)
then return (inAl `S.union` parOps, fqRenamingTerms)
else do
preds <- getBinPredsById ri
if not (S.null preds)
then return (inAl `S.union` preds, fqRenamingTerms)
else do
let err = "renaming item not a binary "
++ "operation or predicate name"
addDiags [mkDiag Error err ri]
-- return the original alphabet and the original fully
-- qualified terms (renamings) with out any modification
-- as there is an error in the spec.
return (inAl, fqRenamingTerms)
-- | Given a CASL identifier and a `function kind' (total or partial),
-- find all unary operations of that kind with that name in the CASL
-- signature, and return a set of corresponding communication types
-- for those operations.
getUnaryOpsById :: Id -> OpKind -> State CspCASLSign (S.Set CommType)
getUnaryOpsById ri kind = do
sig <- get
let opsWithId = Map.findWithDefault S.empty ri (opMap sig)
binOpsKind = S.filter (isBin kind) opsWithId
return cts
where isBin k ot = (k == opKind ot) && (1 == (length (opArgs ot)))
opSorts o inS = inS `S.union` (S.fromList ((opArgs o) ++ [opRes o]))
-- | Given a CASL identifier find all binary predicates with that name
-- in the CASL signature, and return a set of corresponding
-- communication types for those predicates.
getBinPredsById :: Id -> State CspCASLSign (S.Set CommType)
getBinPredsById ri = do
sig <- get
let predsWithId = Map.findWithDefault S.empty ri (predMap sig)
binPreds = S.filter isBin predsWithId
return cts
where isBin ot = (2 == (length (predArgs ot)))
predSorts p inS = inS `S.union` (S.fromList (predArgs p))
-- | Given two CspCASL communication alphabets, check that the first's
-- subsort closure is a subset of the second's subsort closure.
checkCommAlphaSub :: CommAlpha -> CommAlpha -> PROCESS -> String ->
State CspCASLSign ()
checkCommAlphaSub sub super proc context = do
sig <- get
let extras = ((closeCspCommAlpha sig sub) `S.difference`
(closeCspCommAlpha sig super))
if S.null extras
then do return ()
else do let err = ("Communication alphabet subset violations (" ++
context ++ "): " ++ (show $ S.toList extras))
addDiags [mkDiag Error err proc]
return ()
-- Static analysis of CASL terms occurring in CspCASL process terms.
-- | Statically analyse a CASL term appearing in a CspCASL process;
-- any in-scope process variables are added to the signature before
-- performing the analysis.
anaTermCspCASL :: ProcVarMap -> (TERM ()) ->
State CspCASLSign (Maybe (TERM ()))
anaTermCspCASL pm t = do
sig <- get
let newVars = Map.union pm (varMap sig)
sigext = sig { varMap = newVars }
Result ds mt = anaTermCspCASL' sigext t
addDiags ds
return mt
idSetOfSig :: CspCASLSign -> IdSets
idSetOfSig sig =
unite [mkIdSets (allConstIds sig) (allOpIds sig) $ allPredIds sig]
-- | Statically analyse a CASL term in the context of a CspCASL
-- signature. If successful, returns a fully-qualified term.
anaTermCspCASL' :: CspCASLSign -> TERM () -> Result (TERM ())
anaTermCspCASL' sig trm = do
let ga = globAnnos sig
mix = extendMix (Map.keysSet $ varMap sig)
emptyMix { mixRules = makeRules ga $ idSetOfSig sig }
resT <- resolveMixfix (putParen mix) (mixResolve mix)
ga (mixRules mix) trm
oneExpTerm (const return) sig resT
-- | Attempt to cast a CASL term to a particular CASL sort.
ccTermCast :: (TERM ()) -> SORT -> State CspCASLSign (Maybe (TERM ()))
ccTermCast t cSort =
if termSort == (cSort)
then return (Just t)
else do sig <- get
if Rel.member termSort cSort (sortRel sig)
then do let err = "upcast term to " ++ (show cSort)
addDiags [mkDiag Debug err t]
return (Just (Sorted_term t cSort (getRange t)))
else if Rel.member cSort termSort (sortRel sig)
then do let err = "downcast term to " ++ (show cSort)
addDiags [mkDiag Debug err t]
return (Just (Cast t cSort (getRange t)))
else do let err = "can't cast term to sort " ++
(show cSort)
addDiags [mkDiag Error err t]
return Nothing
where termSort = (sortOfTerm t)
-- Static analysis of CASL formulae occurring in CspCASL process
-- terms.
-- | Statically analyse a CASL formula appearing in a CspCASL process;
-- any in-scope process variables are added to the signature before
-- performing the analysis.
anaFormulaCspCASL :: ProcVarMap -> (FORMULA ()) ->
State CspCASLSign (Maybe (FORMULA ()))
anaFormulaCspCASL pm f = do
addDiags [mkDiag Debug "anaFormulaCspCASL" f]
sig <- get
let newVars = Map.union pm (varMap sig)
sigext = sig { varMap = newVars }
Result ds mt = anaFormulaCspCASL' sigext f
addDiags ds
return mt
-- | Statically analyse a CASL formula in the context of a CspCASL
-- signature. If successful, returns a fully-qualified formula.
anaFormulaCspCASL' :: CspCASLSign -> FORMULA () -> Result (FORMULA ())
anaFormulaCspCASL' sig frm = do
let ga = globAnnos sig
mix = extendMix (Map.keysSet $ varMap sig)
emptyMix { mixRules = makeRules ga $ idSetOfSig sig }
resF <- resolveFormula (putParen mix) (mixResolve mix) ga (mixRules mix) frm
minExpFORMULA (const return) sig resF
-- | Compute the communication alphabet arising from a formula
-- occurring in a CspCASL process term.
formulaComms :: (FORMULA ()) -> CommAlpha
formulaComms f = case f of
Quantification _ varDecls f' _ ->
(formulaComms f') `S.union` S.fromList vdSorts
where vdSorts = (map (CommTypeSort . vdSort) varDecls)
vdSort (Var_decl _ s _) = s
Conjunction fs _ -> S.unions (map formulaComms fs)
Disjunction fs _ -> S.unions (map formulaComms fs)
Implication f1 f2 _ _ -> (formulaComms f1) `S.union` (formulaComms f2)
Equivalence f1 f2 _ -> (formulaComms f1) `S.union` (formulaComms f2)
Negation f' _ -> formulaComms f'
Definedness t _ -> S.singleton (CommTypeSort (sortOfTerm t))
Existl_equation t1 t2 _ -> S.fromList [CommTypeSort (sortOfTerm t1),
CommTypeSort (sortOfTerm t2)]
Strong_equation t1 t2 _ -> S.fromList [CommTypeSort (sortOfTerm t1),
CommTypeSort (sortOfTerm t2)]
Membership t s _ -> S.fromList [CommTypeSort (sortOfTerm t),
CommTypeSort s]
Mixfix_formula t -> S.singleton (CommTypeSort (sortOfTerm t))
_ -> S.empty