Maude2DG.hs revision ee8fa30911551361cae1eeb9912afe7fb76d0a1d
{- |
Module : $Header$
Description : Maude Development Graphs
Copyright : (c) Adrian Riesco, Facultad de Informatica UCM 2009
License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt
Maintainer : ariesco@fdi.ucm.es
Stability : experimental
Portability : portable
Conversion of Maude to Development Graphs.
-}
module Maude.Maude2DG where
import System.Exit
import System.IO
import System.Process
import Static.GTheory
import Static.DevGraph
import Static.ComputeTheory
import Static.AnalysisStructured
import Logic.Logic
import Logic.Prover
import Logic.ExtSign
import Logic.Grothendieck
import Maude.Sign
import Maude.Symbol
import Maude.AS_Maude
import Maude.Sentence
import Maude.Morphism
import Maude.Language
import Maude.Shellout
import Maude.Logic_Maude
import qualified Maude.Meta.HasName as HasName
import Data.Maybe
import qualified Data.Map as Map
import qualified Data.Set as Set
import Data.Graph.Inductive.Graph
import Common.Consistency
import Common.Id
import Common.Result
import Common.LibName
import Common.AS_Annotation
import Common.Utils
import Driver.Options
-- | Maude importation types: Protecting, Extending and Including
data ImportType = Pr | Ex | Inc
-- | Pair of tokens and parameters contained by the token.
-- For example, (List{X,Y}, [X,Y])
type ParamSort = (Symbol, [Token])
-- | Tuple with information about a module expression:
-- The corresponding node in the development graph.
-- The signature in this node.
-- The sorts not bound yet, defined in theories.
-- The data from parameters: the parameter id, its module expression and
-- the list of sorts imported.
-- The list of sorts "parameterized" (of the form List{X}).
type ProcInfo = (Node, Sign, Symbols, [(Token, Token, Symbols)], [ParamSort])
-- | map from module expression identifiers to ProcInfo
type TokenInfoMap = Map.Map Token ProcInfo
-- | Data structure used to parse module expressions, it keeps:
-- The identifier of the module expression.
-- The map with the information associated with each module expression.
-- The morphism associated to the module expression.
-- The list of sorts parameterized in this module expression.
-- The development graph thus far.
type ModExpProc = (Token, TokenInfoMap, Morphism, [ParamSort], DGraph)
-- | Information related to an importation:
-- The type of importation.
-- The module expression imported.
-- The map with the information associated with each module expression.
-- The morphism associated to the module expression.
-- The list of sorts parameterized in this module expression.
-- The development graph thus far.
type ImportProc = (ImportType, Token, TokenInfoMap, Morphism, [ParamSort], DGraph)
-- | Information related to the parameters:
-- The list of parameters information: (parameter name, theory name, not instantiated sorts)
-- The updated TokenInfoMap map.
-- The list of morphisms associated with each parameter.
-- The updated development graph.
type ParamInfo = ([(Token, Token, Symbols)], TokenInfoMap, [Morphism], DGraph)
-- | Map from view identifiers to tuples containing the target node of the
-- view, the morphism, and a Boolean value indicating if the view instantiates
-- all the values
type ViewMap = Map.Map Token (Node, Token, Morphism, [Renaming], Bool)
-- | Tuple of data structures updated when a specification is introduced into
-- a development graph
type InsSpecRes = (TokenInfoMap, TokenInfoMap, ViewMap, [Token], DGraph)
-- | Tuple of data structures to introduce in the current DG the predefined
-- modules used
type UpdtPredefs = (TokenInfoMap, TokenInfoMap, DGraph)
-- | inserts the list of specifications in the development graph, updating
-- the data structures
insertSpecs :: [Spec] -> DGraph -> TokenInfoMap -> TokenInfoMap -> ViewMap -> [Token] -> DGraph
-> InsSpecRes
insertSpecs [] _ ptim tim vm tks dg = (ptim, tim, vm, tks, dg)
insertSpecs (s : ss) pdg ptim tim vm ths dg = insertSpecs ss pdg ptim' tim' vm' ths' dg'
where (ptim', tim', vm', ths', dg') = insertSpec s pdg ptim tim vm ths dg
-- | inserts the given specification in the development graph, updating
-- the data structures
insertSpec :: Spec -> DGraph -> TokenInfoMap -> TokenInfoMap -> ViewMap -> [Token] -> DGraph
-> InsSpecRes
insertSpec (SpecMod sp_mod) pdg ptim tim vm ths dg = (ptimUp, tim5, vm, ths, dg6)
where ps = getParams sp_mod
(il, _) = getImportsSorts sp_mod
up = incPredImps il pdg (ptim, tim, dg)
(ptimUp, timUp, dgUp) = incPredParams ps pdg up
(pl, tim1, morphs, dg1) = processParameters ps timUp dgUp
top_sg = Maude.Sign.fromSpec sp_mod
paramSorts = getSortsParameterizedBy (paramNames ps) (Set.toList $ sorts top_sg)
ips = processImports tim1 vm dg1 il
(tim2, dg2) = last_da ips (tim1, dg1)
sg = sign_union_morphs morphs $ sign_union top_sg ips
ext_sg = makeExtSign Maude sg
nm_sns = map (makeNamed "") $ Maude.Sentence.fromSpec sp_mod
sens = toThSens nm_sns
gt = G_theory Maude ext_sg startSigId sens startThId
tok = HasName.getName sp_mod
name = makeName tok
(ns, dg3) = insGTheory dg2 name DGBasic gt
tim3 = Map.insert tok (getNode ns, sg, [], pl, paramSorts) tim2
(tim4, dg4) = createEdgesImports tok ips sg tim3 dg3
dg5 = createEdgesParams tok pl morphs sg tim4 dg4
(_, tim5, dg6) = insertFreeNode tok tim4 morphs dg5
insertSpec (SpecTh sp_th) pdg ptim tim vm ths dg = (ptimUp, tim3, vm, tok : ths, dg3)
where (il, ss1) = getImportsSorts sp_th
(ptimUp, timUp, dgUp) = incPredImps il pdg (ptim, tim, dg)
ips = processImports timUp vm dgUp il
ss2 = getThSorts ips
(tim1, dg1) = last_da ips (tim, dg)
sg = sign_union (Maude.Sign.fromSpec sp_th) ips
ext_sg = makeExtSign Maude sg
nm_sns = map (makeNamed "") $ Maude.Sentence.fromSpec sp_th
sens = toThSens nm_sns
gt = G_theory Maude ext_sg startSigId sens startThId
tok = HasName.getName sp_th
name = makeName tok
(ns, dg2) = insGTheory dg1 name DGBasic gt
tim2 = Map.insert tok (getNode ns, sg, ss1 ++ ss2, [], []) tim1
(tim3, dg3) = createEdgesImports tok ips sg tim2 dg2
-- (_, tim4, dg4) = insertFreeNode tok tim3 [] dg3
insertSpec (SpecView sp_v) pdg ptim tim vm ths dg = (ptimUp, tim3, vm', ths, dg4)
where View name from to rnms = sp_v
(ptimUp, timUp, dgUp) = incPredView from to pdg (ptim, tim, dg)
inst = isInstantiated ths to
tok_name = HasName.getName name
(tok1, tim1, morph1, _, dg1) = processModExp timUp vm dgUp from
(tok2, tim2, morph2, _, dg2) = processModExp tim1 vm dg1 to
(n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim2
(n2, _, _, _, _) = fromJust $ Map.lookup tok2 tim2
morph = fromSignsRenamings (target morph1) (target morph2) rnms
morph' = fromJust $ maybeResult $ compose morph1 morph
(new_sign, new_sens) = sign4renamings (target morph1) (sortMap morph) rnms
(n3, tim3, dg3) = insertInnerNode n2 tim2 tok2 morph2 new_sign new_sens dg2
vm' = Map.insert (HasName.getName name) (n3, tok2, morph', rnms, inst) vm
dg4 = insertThmEdgeMorphism tok_name n3 n1 morph' dg3
-- | Includes the references used in importations to modules in the maude prelude
-- in the current DG
incPredImps :: [Import] -> DGraph -> UpdtPredefs -> UpdtPredefs
incPredImps [] _ up = up
incPredImps (i : is) pdg up = incPredImps is pdg up'
where up' = incPredImp i pdg up
-- | Includes the references used in parameterizations to modules in the maude prelude
-- in the current DG
incPredParams :: [Parameter] -> DGraph -> UpdtPredefs -> UpdtPredefs
incPredParams [] _ up = up
incPredParams (i : is) pdg up = incPredParams is pdg up'
where up' = incPredParam i pdg up
-- | Includes the references used in views to modules in the maude prelude
-- in the current DG
incPredView :: ModExp -> ModExp -> DGraph -> UpdtPredefs -> UpdtPredefs
incPredView from to pdg up = up''
where up' = incPredImpME from pdg up
up'' = incPredImpME to pdg up'
-- | Includes the references used in a parameter to modules in the maude prelude
-- in the current DG
incPredParam :: Parameter -> DGraph -> UpdtPredefs -> UpdtPredefs
incPredParam (Parameter _ me) up = incPredImpME me up
-- | Includes the references used in an importation to modules in the maude prelude
-- in the current DG
incPredImp :: Import -> DGraph -> UpdtPredefs -> UpdtPredefs
incPredImp i up = up'
where me = getModExp i
up' = incPredImpME me up
-- | Includes the references used in a module expression to modules in the maude prelude
-- in the current DG
incPredImpME :: ModExp -> DGraph -> UpdtPredefs -> UpdtPredefs
incPredImpME (ModExp m_id) pdg (ptim, tim, dg) = up
where ModId q = m_id
q' = mkFreeName q
up = case (Map.member q ptim) of
True -> let (n, sg1, sys1, tts1, ps1) = ptim Map.! q
(n', sg2, sys2, tts2, ps2) = ptim Map.! q'
refInfo = newRefInfo preludeLib n
refInfo' = newRefInfo preludeLib n'
ptim1 = Map.delete q ptim
ptim2 = Map.delete q' ptim1
ext_sg1 = makeExtSign Maude sg1
gt1 = G_theory Maude ext_sg1 startSigId noSens startThId
name1 = makeName q
new = newInfoNodeLab name1 refInfo gt1
newNode = getNewNodeDG dg
refLab = labDG pdg n
nodeCont = new { globalTheory = globalTheory refLab }
-- (ns1, dg1) = insGTheory dg name1 DGBasic gt1
dg1 = addToRefNodesDG newNode refInfo $ insNodeDG (newNode, nodeCont) dg
ext_sg2 = makeExtSign Maude sg2
gt2 = G_theory Maude ext_sg2 startSigId noSens startThId
name2 = makeName q'
new' = newInfoNodeLab name2 refInfo' gt2
newNode' = getNewNodeDG dg1
refLab' = labDG pdg n'
nodeCont' = new' { globalTheory = globalTheory refLab' }
-- (ns2, dg2) = insGTheory dg1 name2 DGBasic gt2
dg2 = addToRefNodesDG newNode' refInfo' $ insNodeDG (newNode', nodeCont') dg1
tim1 = Map.insert q (newNode, sg1, sys1, tts1, ps1) tim
tim2 = Map.insert q' (newNode', sg2, sys2, tts2, ps2) tim1
in (ptim2, tim2, dg2)
False -> (ptim, tim, dg)
incPredImpME (SummationModExp me me') pdg up = up''
where up' = incPredImpME me pdg up
up'' = incPredImpME me' pdg up'
incPredImpME (RenamingModExp me _) pdg up = incPredImpME me pdg up
incPredImpME (InstantiationModExp me _) pdg up = incPredImpME me pdg up
-- | extracts the module expression from an importation statement
getModExp :: Import -> ModExp
getModExp (Including me) = me
getModExp (Extending me) = me
getModExp (Protecting me) = me
-- | computes the union of the signatures obtained from the importation list
sign_union :: Sign -> [ImportProc] -> Sign
sign_union sign = foldr (Maude.Sign.union . get_sign) sign
-- | extracts the target signature from the morphism in an importation tuple
get_sign :: ImportProc -> Sign
get_sign (_, _, _, morph, _, _) = target morph
-- | computes the union of the target signatures of a list of morphisms
sign_union_morphs :: [Morphism] -> Sign -> Sign
sign_union_morphs morphs sg = foldr (Maude.Sign.union . target) sg morphs
-- | extracts the last (newest) data structures from a list of importation
-- tuples, using the second argument as default value if the list is empty
last_da :: [ImportProc] -> (TokenInfoMap, DGraph) -> (TokenInfoMap, DGraph)
last_da [(_, _, tim, _, _, dg)] _ = (tim, dg)
last_da (_ : ips) p = last_da ips p
last_da _ p = p
-- | generates the edges required by a parameter list in a module instantiation
createEdgesParams :: Token -> [(Token, Token, Symbols)] -> [Morphism] -> Sign
-> TokenInfoMap -> DGraph -> DGraph
createEdgesParams tok1 ((_, tok2, _) : toks) (morph : morphs) sg tim dg =
createEdgesParams tok1 toks morphs sg tim dg'
where morph' = setTarget sg morph
(n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim
(n2, _, _, _, _) = fromJust $ Map.lookup tok2 tim
dg' = insertDefEdgeMorphism n1 n2 morph' dg
createEdgesParams _ _ _ _ _ dg = dg
-- | generates the edges required by the importations
createEdgesImports :: Token -> [ImportProc] -> Sign -> TokenInfoMap -> DGraph
-> (TokenInfoMap, DGraph)
createEdgesImports _ [] _ tim dg = (tim, dg)
createEdgesImports tok (ip : ips) sg tim dg = createEdgesImports tok ips sg tim' dg'
where (tim', dg') = createEdgeImport tok ip sg tim dg
-- | generates the edge for a concrete importation
createEdgeImport :: Token -> ImportProc -> Sign -> TokenInfoMap -> DGraph
-> (TokenInfoMap, DGraph)
createEdgeImport tok1 (Pr, tok2, _, morph, _, _) sg tim dg = (tim', dg'')
where morph' = setTarget sg morph
(tok2', tim', dg') = insertFreeNode tok2 tim [] dg
(n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim'
(n2, _, _, _, _) = fromJust $ Map.lookup tok2' tim'
dg'' = insertDefEdgeMorphism n1 n2 morph' dg'
createEdgeImport tok1 (Ex, tok2, _, morph, _, _) sg tim dg = (tim, dg')
where morph' = setTarget sg morph
(n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim
(n2, _, _, _, _) = fromJust $ Map.lookup tok2 tim
dg' = insertConsEdgeMorphism n1 n2 morph' dg
createEdgeImport tok1 (Inc, tok2, _, morph, _, _) sg tim dg = (tim, dg')
where morph' = setTarget sg morph
(n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim
(n2, _, _, _, _) = fromJust $ Map.lookup tok2 tim
dg' = insertDefEdgeMorphism n1 n2 morph' dg
-- | extracts the sorts provided by the theories
getThSorts :: [ImportProc] -> Symbols
getThSorts [] = []
getThSorts (ip : ips) = getThSortsAux ip ++ getThSorts ips
-- | extracts the not-bounded-yet sorts related to the given identifier
getThSortsAux :: ImportProc -> Symbols
getThSortsAux (_, tok, tim, _, _, _) = srts
where (_, _, srts, _, _) = fromJust $ Map.lookup tok tim
-- | generates the extra signature needed when using term to term renaming in views
sign4renamings :: Sign -> SymbolMap -> [Renaming] -> (Sign, [Sentence])
sign4renamings sg sm ((TermMap t1 t2) : rnms) = (new_sg, (Equation eq) : sens)
where (op_top, ss) = getOpSorts t1
sg' = newOp sg op_top ss sm
(sg'', sens) = sign4renamings sg sm rnms
eq = Eq (applyRenamingTerm sm t1) t2 [] []
new_sg = Maude.Sign.union sg' sg''
sign4renamings sg sm (_ : rnms) = sign4renamings sg sm rnms
sign4renamings sg _ [] = (sg, [])
-- | given the identifier of an operator in the given signature, the function
-- generates a new signature with this operator and a renamed profile computed
-- from the renaming given in the mapping
newOp :: Sign -> Token -> Symbols -> SymbolMap -> Sign
newOp sg op ss sm = Maude.Sign.empty {ops = Map.singleton op ods'}
where om = ops sg
ods = fromJust $ Map.lookup op om
ods' = getOpDeclSet ods ss sm
-- | renames the profile with the given map
getOpDeclSet :: OpDeclSet -> Symbols -> SymbolMap -> OpDeclSet
getOpDeclSet ods ss sm = Set.singleton (op_sym', ats)
where f = \ (Operator _ x _) b -> x == ss || b
g = \ (x, _) -> Set.fold f False x
(ods', ats) = head $ Set.toList $ Set.filter g ods
h = \ (Operator _ y _) -> y == ss
ods'' = Set.filter h ods'
op_sym = head $ Set.toList ods''
op_sym' = applyRenamingOpSymbol op_sym sm
-- | applies the renaming in the map to the operator declaration
applyRenamingOpSymbol :: Symbol -> SymbolMap -> SymbolSet
applyRenamingOpSymbol (Operator q ar co) sm = Set.singleton $ Operator q ar' co'
where f = \ x -> if Map.member x sm
then fromJust $ Map.lookup co sm
else x
ar' = map f ar
co' = f co
applyRenamingOpSymbol _ _ = Set.empty
-- | renames the sorts in a term
applyRenamingTerm :: SymbolMap -> Term -> Term
applyRenamingTerm sm (Apply q ts ty) = Apply q (map (applyRenamingTerm sm) ts)
(applyRenamingType sm ty)
applyRenamingTerm sm (Const q s) = Const q s'
where s' = applyRenamingType sm s
applyRenamingTerm sm (Var q s) = Var q s'
where s' = applyRenamingType sm s
-- | renames a type
applyRenamingType :: SymbolMap -> Type -> Type
applyRenamingType sm (TypeSort s) = TypeSort $ SortId $ HasName.getName q'
where SortId q = s
q' = if Map.member (Sort q) sm
then fromJust $ Map.lookup (Sort q) sm
else (Sort q)
applyRenamingType sm (TypeKind k) = TypeKind $ KindId $ HasName.getName q'
where KindId q = k
q' = if Map.member (Kind q) sm
then fromJust $ Map.lookup (Kind q) sm
else (Kind q)
-- | extracts the top operator of a term and the names of its sorts
-- if it is applicated to some arguments
getOpSorts :: Term -> (Token, Symbols)
getOpSorts (Const q _) = (q, [])
getOpSorts (Var q _) = (q, [])
getOpSorts (Apply q ls _) = (q, getTypes ls)
-- | extracts the types of the terms while they are variables
getTypes :: [Term] -> Symbols
getTypes ((Var _ (TypeSort s)) : ts) = Sort (HasName.getName s) : getTypes ts
getTypes ((Var _ (TypeKind s)) : ts) = Kind (HasName.getName s) : getTypes ts
getTypes _ = []
-- | process the information of the given list of imports
processImports :: TokenInfoMap -> ViewMap -> DGraph -> [Import] -> [ImportProc]
processImports _ _ _ [] = []
processImports tim vm dg (i : il) = ip : processImports tim' vm dg' il
where ip@(_, _, tim', _, _, dg') = processImport tim vm dg i
-- | process the module expression and then adds the information about
-- the type of import
processImport :: TokenInfoMap -> ViewMap -> DGraph -> Import -> ImportProc
processImport tim vm dg (Protecting modExp) = (Pr, tok, tim', morph, ps, dg')
where (tok, tim', morph, ps, dg') = processModExp tim vm dg modExp
processImport tim vm dg (Extending modExp) = (Ex, tok, tim', morph, ps, dg')
where (tok, tim', morph, ps, dg') = processModExp tim vm dg modExp
processImport tim vm dg (Including modExp) = (Inc, tok, tim', morph, ps, dg')
where (tok, tim', morph, ps, dg') = processModExp tim vm dg modExp
-- | traverses the list of parameters and generates the required data structures
processParameters :: [Parameter] -> TokenInfoMap -> DGraph -> ParamInfo
processParameters ps tim dg = foldr processParameter ([], tim, [], dg) ps
-- | given a parameter, the function processes the module expression associated
-- to it, qualifies the not-bound-yet sorts and creates the morphism
processParameter :: Parameter -> ParamInfo -> ParamInfo
processParameter (Parameter sort modExp) (toks, tim, morphs, dg) =
(toks', tim', morphs', dg')
where (tok, tim', morph, _, dg') = processModExp tim Map.empty dg modExp
(_, _, fs, _, _) = fromJust $ Map.lookup tok tim'
fs' = translateSorts morph fs
morph' = qualifySorts morph (HasName.getName sort) fs'
toks' = (HasName.getName sort, tok, fs') : toks
morphs' = morph' : morphs
-- | distinguishes between the different module expressions to compute
-- the morphisms and update the development graph
processModExp :: TokenInfoMap -> ViewMap -> DGraph -> ModExp -> ModExpProc
processModExp tim _ dg (ModExp modId) = (tok, tim, morph, ps, dg)
where tok = HasName.getName modId
(_, sg, _, _, ps) = fromJust $ Map.lookup tok tim
morph = Maude.Morphism.inclusion sg sg
processModExp tim vm dg (SummationModExp modExp1 modExp2) = (tok, tim3, morph, ps', dg5)
where (tok1, tim1, morph1, ps1, dg1) = processModExp tim vm dg modExp1
(tok2, tim2, morph2, ps2, dg2) = processModExp tim1 vm dg1 modExp2
ps' = deleteRepeated $ ps1 ++ ps2
tok = mkSimpleId $ concat ["{", show tok1, " + ", show tok2, "}"]
(n1, _, ss1, _, _) = fromJust $ Map.lookup tok1 tim2
(n2, _, ss2, _, _) = fromJust $ Map.lookup tok2 tim2
ss1' = translateSorts morph1 ss1
ss2' = translateSorts morph1 ss2
sg1 = target morph1
sg2 = target morph2
sg = Maude.Sign.union sg1 sg2
morph = Maude.Morphism.inclusion sg sg
morph1' = setTarget sg morph1
morph2' = setTarget sg morph2
(tim3, dg3) = insertNode tok sg tim2 (ss1' ++ ss2') [] dg2
(n3, _, _, _, _) = fromJust $ Map.lookup tok tim3
dg4 = insertDefEdgeMorphism n3 n1 morph1' dg3
dg5 = insertDefEdgeMorphism n3 n2 morph2' dg4
processModExp tim vm dg (RenamingModExp modExp rnms) = (tok, tim', comp_morph, ps', dg')
where (tok, tim', morph, ps, dg') = processModExp tim vm dg modExp
morph' = fromSignRenamings (target morph) rnms
ps' = applyRenamingParamSorts (sortMap morph') ps
comp_morph = fromJust $ maybeResult $ compose morph morph'
processModExp tim vm dg (InstantiationModExp modExp views) = (tok'', tim'', final_morph, new_param_sorts, dg'')
where (tok, tim', morph, paramSorts, dg') = processModExp tim vm dg modExp
(_, _, _, ps, _) = fromJust $ Map.lookup tok tim'
param_names = map fstTpl ps
view_names = map HasName.getName views
(new_param_sorts, ps_morph) = instantiateSorts param_names view_names vm morph paramSorts
(tok', morph1, ns, deps) = processViews views (mkSimpleId "") tim' vm ps (ps_morph, [], [])
tok'' = mkSimpleId $ concat [show tok, "{", show tok', "}"]
sg2 = target morph1
final_morph = Maude.Morphism.inclusion sg2 sg2
(tim'', dg'') = if Map.member tok'' tim
then (tim', dg')
else updateGraphViews tok tok'' sg2 morph1 ns tim' deps dg'
-- | generates a edge between the source and the target of a view, inserting
-- a new node if the view contained a term to term renaming, and thus updating
-- the map from module expression to its info and the development graph
updateGraphViews :: Token -> Token -> Sign -> Morphism -> [(Node, Morphism)] -> TokenInfoMap
-> [(Token, Token, Symbols)] -> DGraph -> (TokenInfoMap, DGraph)
updateGraphViews tok1 tok2 sg morph views tim deps dg = (tim', dg''')
where (n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim
morph' = setTarget sg morph
(tim', dg') = insertNode tok2 sg tim [] deps dg
(n2, _, _, _, _) = fromJust $ Map.lookup tok2 tim'
dg'' = insertDefEdgeMorphism n2 n1 morph' dg'
dg''' = insertDefEdgesMorphism n2 views sg dg''
-- | traverses a list of views obtained in an instantiation module expression
-- and return a tuple with:
-- The accumulated identifier of the module expression.
-- The accumulated morphism thus far.
-- A list of nodes and morphisms to create the appropriate edges in the
-- development graph.
-- The not-bound-yet sorts.
processViews :: [ViewId] -> Token -> TokenInfoMap -> ViewMap -> [(Token, Token, Symbols)]
-> (Morphism, [(Node, Morphism)], [(Token, Token, Symbols)])
-> (Token, Morphism, [(Node, Morphism)], [(Token, Token, Symbols)])
processViews (vi : vis) tok tim vm (p : ps) (morph, lp, dep) =
processViews vis tok'' tim vm ps (morph', lp ++ [(n, vmorph)], dep ++ new_dep)
where (tok', morph', vmorph, n, new_dep) = processView vi tim vm p morph
tok'' = mkSimpleId $ show tok ++ "," ++ show tok'
processViews _ tok _ _ _ (morph, nds, deps) = (tok', morph, nds, deps)
where tok' = mkSimpleId $ drop 1 $ show tok
-- | this function distinguishes whether the view is an instantiation (and thus)
-- the view is in the map of views and the function morphismView is used
-- or it is just a parameter binding and paramBinding is used
processView :: ViewId -> TokenInfoMap -> ViewMap -> (Token, Token, Symbols) ->
Morphism -> (Token, Morphism, Morphism, Node, [(Token, Token, Symbols)])
processView vi tim vm (p, theory, ss) morph =
if Map.member name vm
then morphismView name p ss (fromJust $ Map.lookup name vm) morph
else paramBinding theory name p ss morph tim
where name = HasName.getName vi
-- | the function distinguishes if the instantiation is from a module, and thus
-- all the symbols are instantiated, or it is a theory and the symbols are not
-- completely instantiated.
morphismView :: Token -> Token -> Symbols -> (Node, Token, Morphism, [Renaming], Bool)
-> Morphism -> (Token, Morphism, Morphism, Node, [(Token, Token, Symbols)])
morphismView name p _ (n, _, vmorph, rnms, True) morph = (name, morph'', vmorph', n, [])
where rnms' = qualifyRenamings p rnms
morph' = applyRenamings morph rnms'
tgt = target vmorph
vmorph' = Maude.Morphism.inclusion tgt tgt
ctgt = target morph'
usg = Maude.Sign.union ctgt tgt
morph'' = setTarget usg morph'
morphismView name p ss (n, th, morph, rnms, False) morph1 =
(name, morph4, vmorph', n, [(p, th, translateSorts morph ss)])
where rnms' = qualifyRenamings2 p rnms
morph2 = applyRenamings morph1 rnms'
rnms'' = createQualificationTh2Mod p ss
morph3 = applyRenamings morph2 rnms''
tgt = target morph
vmorph = Maude.Morphism.inclusion tgt tgt
vmorph' = applyRenamings vmorph rnms''
vtgt = target vmorph'
ctgt = target morph3
usg = Maude.Sign.union vtgt ctgt
morph4 = setTarget usg morph3
-- this function is applied when two parameters are linked, it updates the qualifications
-- of the sorts. The parameters are:
-- theory -> parameter instantiated -> parameter binding -> sorts bound -> current morph
-- map token info
paramBinding :: Token -> Token -> Token -> Symbols -> Morphism -> TokenInfoMap
-> (Token, Morphism, Morphism, Node, [(Token, Token, Symbols)])
paramBinding th view p ss morph tim = (view, morph', vmorph', n, [])
where rnms = createQualifiedSortRenaming p view ss
morph' = applyRenamings morph rnms
(n, sg, _, _, _) = fromJust $ Map.lookup th tim
vmorph = Maude.Morphism.inclusion sg sg
rnms' = createQualificationTh2Mod p ss
vmorph' = applyRenamings vmorph rnms'
-- | inserts the node into the development graph if it does not already exist
insertNode :: Token -> Sign -> TokenInfoMap -> Symbols -> [(Token, Token, Symbols)]
-> DGraph -> (TokenInfoMap, DGraph)
insertNode tok sg tim ss deps dg = if Map.member tok tim
then (tim, dg)
else let
ext_sg = makeExtSign Maude sg
gt = G_theory Maude ext_sg startSigId noSens startThId
name = makeName tok
(ns, dg') = insGTheory dg name DGBasic gt
tim' = Map.insert tok (getNode ns, sg, ss, deps, []) tim
in (tim', dg')
-- | inserts an inner node. This function is used when a view defines a map
-- between terms, so it is neccesary to extend the signature of the target
-- module in order to have the appropriate map.
insertInnerNode :: Node -> TokenInfoMap -> Token -> Morphism -> Sign -> [Sentence]
-> DGraph -> (Node, TokenInfoMap, DGraph)
insertInnerNode nod tim tok morph sg sens dg =
if (isIdentity morph) && null sens
then let
(fn, tim', dg') = insertFreeNode tok tim [] dg
(n2, _, _, _, _) = fromJust $ Map.lookup fn tim'
in (n2, tim', dg')
else let
nm = makeName tok
th_sens = toThSens $ map (makeNamed "") sens
sg' = Maude.Sign.union sg $ target morph
ext_sg = makeExtSign Maude sg'
gt = G_theory Maude ext_sg startSigId th_sens startThId
nm' = inc nm
(ns, dg1) = insGTheory dg nm' DGBasic gt
nod2 = getNode ns
morph' = setTarget sg' morph
dg2 = insertDefEdgeMorphism nod2 nod morph' dg1
-- inserting the free node
gt2 = G_theory Maude ext_sg startSigId noSens startThId
(ns2, dg3) = insGTheory dg2 (inc nm') DGBasic gt2
nod3 = getNode ns2
-- inserting the free link
inc_sg = Maude.Morphism.inclusion Maude.Sign.empty sg'
mor = G_morphism Maude inc_sg startMorId
dgt = FreeOrCofreeDefLink NPFree $ EmptyNode (Logic Maude)
edg = defDGLink (gEmbed mor) dgt SeeTarget
dg4 = snd $ insLEdgeDG (nod2, nod3, edg) dg3
in (nod3, tim, dg4)
-- | inserts the list of definition edges, building for each node the inclusion morphism
-- between the signatures
insertDefEdgesMorphism :: Node -> [(Node, Morphism)] -> Sign -> DGraph -> DGraph
insertDefEdgesMorphism _ [] _ dg = dg
insertDefEdgesMorphism n1 ((n2, morph) : views) sg2 dg = insertDefEdgesMorphism n1 views sg2 dg'
where morph' = setTarget sg2 morph
dg' = insertDefEdgeMorphism n1 n2 morph' dg
-- | inserts a definition link between the nodes with the given morphism
insertDefEdgeMorphism :: Node -> Node -> Morphism -> DGraph -> DGraph
insertDefEdgeMorphism n1 n2 morph dg = snd $ insLEdgeDG (n2, n1, edg) dg
where mor = G_morphism Maude morph startMorId
edg = globDefLink (gEmbed mor) SeeTarget
-- | inserts a theorem link, labeled with the name of the view, between the nodes
-- with the given morphism in the development graph
insertThmEdgeMorphism :: Token -> Node -> Node -> Morphism -> DGraph -> DGraph
insertThmEdgeMorphism name n1 n2 morph dg = snd $ insLEdgeDG (n2, n1, edg) dg
where mor = G_morphism Maude morph startMorId
edg = defDGLink (gEmbed mor) globalThm
(DGLinkView name $ Fitted [])
-- | inserts a PCons link between the nodes with the given morphism
insertConsEdgeMorphism :: Node -> Node -> Morphism -> DGraph -> DGraph
insertConsEdgeMorphism n1 n2 morph dg = snd $ insLEdgeDG (n2, n1, edg) dg
where mor = G_morphism Maude morph startMorId
edg = defDGLink (gEmbed mor) (globalConsThm PCons) SeeTarget
-- | inserts a free definition link between the nodes with the given name
insertFreeEdge :: Token -> Token -> TokenInfoMap -> DGraph -> DGraph
insertFreeEdge tok1 tok2 tim dg = snd $ insLEdgeDG (n2, n1, edg) dg
-- currently, the empty sign is used in the inclusion instead of sg1
where (n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim
(n2, sg2, _, _, _) = fromJust $ Map.lookup tok2 tim
mor = G_morphism Maude (Maude.Morphism.inclusion Maude.Sign.empty sg2) startMorId
dgt = FreeOrCofreeDefLink NPFree $ EmptyNode (Logic Maude)
edg = defDGLink (gEmbed mor) dgt SeeTarget
-- | inserts a free definition link between the nodes with the given name. This function is used
-- to create free links when a module is parameterized, so the morphism is more complicated:
-- It also receives a morphism, obtained from the parameters.
insertFreeEdgeMor :: Token -> Token -> TokenInfoMap -> Morphism -> DGraph -> DGraph
insertFreeEdgeMor tok1 tok2 tim mor dg = snd $ insLEdgeDG (n2, n1, edg) dg
where (n1, _, _, _, _) = fromJust $ Map.lookup tok1 tim
(n2, _, _, _, _) = fromJust $ Map.lookup tok2 tim
mor' = G_morphism Maude mor startMorId
dgt = FreeOrCofreeDefLink NPFree $ EmptyNode (Logic Maude)
edg = defDGLink (gEmbed mor') dgt SeeTarget
-- | the importation mode "protecting M" generates a new node M' and a free link
-- between M and M'. This function is in charge of creating such M' if it does not
-- exist
insertFreeNode :: Token -> TokenInfoMap -> [Morphism] -> DGraph -> (Token, TokenInfoMap, DGraph)
insertFreeNode t tim [] dg = (t', tim', dg'')
where t' = mkFreeName t
b = Map.member t' tim
(tim', dg') = if b
then (tim, dg)
else insertFreeNode2 t' tim (fromJust $ Map.lookup t tim) dg
dg'' = if b
then dg'
else insertFreeEdge t' t tim' dg'
insertFreeNode t tim morphs@(_:_) dg = (t', tim', dg'')
where t' = mkFreeName t
b = Map.member t' tim
(tim', dg') = if b
then (tim, dg)
else insertFreeNode2 t' tim (fromJust $ Map.lookup t tim) dg
morph = morphismUnion morphs
dg'' = if b
then dg'
else insertFreeEdgeMor t' t tim' morph dg'
morphismUnion :: [Morphism] -> Morphism
morphismUnion = foldr Maude.Morphism.union Maude.Morphism.empty
-- | auxiliary function in charge of creating M' when it does not exist
insertFreeNode2 :: Token -> TokenInfoMap -> ProcInfo -> DGraph -> (TokenInfoMap, DGraph)
insertFreeNode2 t tim (_, sg, _, _, _) dg = (tim', dg')
where ext_sg = makeExtSign Maude sg
gt = G_theory Maude ext_sg startSigId noSens startThId
name = makeName t
(ns, dg') = insGTheory dg name DGBasic gt
tim' = Map.insert t (getNode ns, sg, [], [], []) tim
-- | Given the identifier of a module, generates the identifier for the module
-- with the ``freeness'' constraint
mkFreeName :: Token -> Token
mkFreeName = mkSimpleId . (\ x -> x ++ "'") . show
-- | extracts the parameters of a Maude module
getParams :: Module -> [Parameter]
getParams (Module _ params _) = params
-- | extracts the importation statements and the sorts from a module definition
getImportsSorts :: Module -> ([Import], Symbols)
getImportsSorts (Module _ _ stmts) = getImportsSortsStmnts stmts ([],[])
-- | traverses the statements accumulating the importations and the sorts
getImportsSortsStmnts :: [Statement] -> ([Import], Symbols) -> ([Import], Symbols)
getImportsSortsStmnts [] p = p
getImportsSortsStmnts ((ImportStmnt imp) : stmts) (is, ss) =
getImportsSortsStmnts stmts (imp : is, ss)
getImportsSortsStmnts ((SortStmnt s) : stmts) (is, ss) =
getImportsSortsStmnts stmts (is, (Sort $ HasName.getName s) : ss)
getImportsSortsStmnts (_ : stmts) p = getImportsSortsStmnts stmts p
-- | builds the development graph of the specified Maude file
directMaudeParsing :: FilePath -> IO (DGraph, DGraph)
directMaudeParsing fp = do
ml <- getEnvDef "MAUDE_LIB" ""
if null ml then error "environment variable MAUDE_LIB is not set" else do
ns <- parse fp
let ns' = either (const []) id ns
(hIn, hOut, hErr, procH) <- runMaude
exitCode <- getProcessExitCode procH
case exitCode of
Nothing -> do
hPutStrLn hIn $ "load " ++ fp
hFlush hIn
hPutStrLn hIn "."
hFlush hIn
ms <- traverseNames hIn hOut ns'
hPutStrLn hIn "in Maude/hets.prj"
psps <- predefinedSpecs hIn hOut
sps <- traverseSpecs hIn hOut ms
(ok, errs) <- getErrors hErr
if ok
then do
hClose hIn
hClose hOut
hClose hErr
return $ maude2DG psps sps
else do
hClose hIn
hClose hOut
hClose hErr
error errs
Just ExitSuccess -> error "maude terminated immediately"
Just (ExitFailure i) ->
error $ "calling maude failed with exitCode: " ++ show i
maude2DG :: [Spec] -> [Spec] -> (DGraph, DGraph)
maude2DG psps sps = (dg1, dg2)
(_,_, _, _, dg2) = insertSpecs sps dg1 tim Map.empty vm tks emptyDG
-- | given input and output handlers and a list of strings, this method
-- traverses the list transforming each string into a Maude specification
traverseSpecs :: Handle -> Handle -> [String] -> IO [Spec]
traverseSpecs _ _ [] = return []
traverseSpecs hIn hOut (m : ms) = do
hPutStrLn hIn m
hFlush hIn
sOutput <- getAllSpec hOut "" False
ss <- traverseSpecs hIn hOut ms
let stringSpec = findSpec sOutput
let spec = read stringSpec :: Spec
return $ spec : ss
-- | given a list of names of views and specifications, a list of
-- string with the real specifications is extracted.
traverseNames :: Handle -> Handle -> [NamedSpec] -> IO [String]
traverseNames _ _ [] = return []
traverseNames hIn hOut (ModName q : ns) = do
hPutStrLn hIn $ concat ["show module ", q, " ."]
hFlush hIn
sOutput <- getAllOutput hOut "" False
rs <- traverseNames hIn hOut ns
return $ sOutput : rs
traverseNames hIn hOut (ViewName q : ns) = do
hPutStrLn hIn $ concat ["show view ", q, " ."]
hFlush hIn
sOutput <- getAllOutput hOut "" False
rs <- traverseNames hIn hOut ns
return $ sOutput : rs
-- | list of names of the predefined modules
predefined :: [NamedSpec]
predefined = [ModName "TRUTH-VALUE", ModName "TRUTH", ModName "BOOL", ModName "EXT-BOOL",
ModName "NAT",
ModName "INT", ModName "RAT", ModName "FLOAT", ModName "STRING", ModName "CONVERSION",
ModName "RANDOM", ModName "QID", ModName "TRIV", ViewName "TRIV", ViewName "Bool",
ViewName "Nat", ViewName "Int", ViewName "Rat", ViewName "Float", ViewName "String",
ViewName "Qid", ModName "STRICT-WEAK-ORDER", ViewName "STRICT-WEAK-ORDER",
ModName "STRICT-TOTAL-ORDER", ViewName "STRICT-TOTAL-ORDER", ViewName "Nat<",
ViewName "Int<", ViewName "Rat<", ViewName "Float<", ViewName "String<",
ModName "TOTAL-PREORDER", ViewName "TOTAL-PREORDER", ModName "TOTAL-ORDER",
ViewName "TOTAL-ORDER", ViewName "Nat<=", ViewName "Int<=", ViewName "Rat<=",
ViewName "Float<=", ViewName "String<=", ModName "DEFAULT", ViewName "DEFAULT",
ViewName "Nat0", ViewName "Int0", ViewName "Rat0", ViewName "Float0",
ViewName "String0", ViewName "Qid0", ModName "LIST", ModName "WEAKLY-SORTABLE-LIST",
ModName "SORTABLE-LIST", ModName "WEAKLY-SORTABLE-LIST'",
ModName "SORTABLE-LIST'", ModName "SET", ModName "LIST-AND-SET",
ModName "SORTABLE-LIST-AND-SET", ModName "SORTABLE-LIST-AND-SET'",
ModName "LIST*", ModName "SET*", ModName "MAP", ModName "ARRAY",
ModName "NAT-LIST", ModName "QID-LIST", ModName "QID-SET", ModName "META-TERM",
ModName "META-MODULE", ModName "META-LEVEL", ModName "COUNTER", ModName "LOOP-MODE",
ModName "CONFIGURATION"]
-- | returns the specifications of the predefined modules by passing as
-- parameter the list of names
predefinedSpecs :: Handle -> Handle -> IO [Spec]
predefinedSpecs hIn hOut = traversePredefined hIn hOut predefined
-- | returns the specifications of the predefined modules
traversePredefined :: Handle -> Handle -> [NamedSpec] -> IO [Spec]
traversePredefined _ _ [] = return []
traversePredefined hIn hOut (ModName n : ns) = do
hPutStrLn hIn $ concat ["(hets ", n, " .)"]
hFlush hIn
sOutput <- getAllSpec hOut "" False
ss <- traversePredefined hIn hOut ns
let stringSpec = findSpec sOutput
let spec = read stringSpec :: Spec
return $ spec : ss
traversePredefined hIn hOut (ViewName n : ns) = do
hPutStrLn hIn $ concat ["(hetsView ", n, " .)"]
hFlush hIn
sOutput <- getAllSpec hOut "" False
ss <- traversePredefined hIn hOut ns
let stringSpec = findSpec sOutput
let spec = read stringSpec :: Spec
return $ spec : ss
-- | returns the parameter names
paramNames :: [Parameter] -> [Token]
paramNames = map f
where f = \ (Parameter s _) -> HasName.getName s
-- | returns the sorts (second argument of the pair) that contain any of the parameters
-- given as first argument
getSortsParameterizedBy :: [Token] -> Symbols -> [ParamSort]
getSortsParameterizedBy ps = filter f . map (g ps)
where f = \ (_, l) -> l /= []
g = \ pss x -> let
params = getSortParams $ HasName.getName x
in (x, intersec params pss)
-- | computes the intersection of the two list (considers them as sorts)
intersec :: [Token] -> [Token] -> [Token]
intersec [] _ = []
intersec (e : es) l = case elem e l of
False -> intersec es l
True -> e : intersec es l
-- | extracts the parameters of the given sort
-- For example, getSortParams List{X} = [X]
-- List{X}{Y, Y} = [Y,Z]
getSortParams :: Token -> [Token]
getSortParams t = getSortParamsString $ show t
-- | traverses a String looking for the last curly braces
getSortParamsString :: String -> [Token]
getSortParamsString [] = []
getSortParamsString ('{' : cs) = if null sps
then getSortParamsStringAux cs ""
else sps
where sps = getSortParamsString cs
getSortParamsString (_ : cs) = getSortParamsString cs
-- | traverses a String keeping the token separated by commas
getSortParamsStringAux :: String -> String -> [Token]
getSortParamsStringAux ('`' : ',' : cs) st = mkSimpleId st : getSortParamsStringAux cs ""
getSortParamsStringAux ('`' : '}' : []) st = [mkSimpleId st]
getSortParamsStringAux (' ' : cs) st = getSortParamsStringAux cs st
getSortParamsStringAux (c : cs) st = getSortParamsStringAux cs (st ++ [c])
getSortParamsStringAux [] st = [mkSimpleId st]
-- | checks if the target of the view is completely instantiated (to modules)
isInstantiated :: [Token] -> ModExp -> Bool
isInstantiated ths (ModExp modExp) = notElem (HasName.getName modExp) ths
isInstantiated ths (SummationModExp me1 me2) = isInstantiated ths me1 &&
isInstantiated ths me2
isInstantiated ths (RenamingModExp modExp _) = isInstantiated ths modExp
isInstantiated _ (InstantiationModExp _ _) = True
-- | rename the parameterized sorts and computes if they are still parameterized
applyRenamingParamSorts :: SymbolMap -> [ParamSort] -> [ParamSort]
applyRenamingParamSorts sm = foldr (applyRenamingParamSort sm) []
applyRenamingParamSort :: SymbolMap -> ParamSort -> [ParamSort]
-> [ParamSort]
applyRenamingParamSort sm (tok, params) acc = case Map.member tok sm of
False -> (tok, params) : acc
True -> let
tok' = fromJust $ Map.lookup tok sm
ps = getSortsParameterizedBy params [tok']
in ps ++ acc
-- | removes the repetitions from a list
deleteRepeated :: [ParamSort] -> [ParamSort]
deleteRepeated [] = []
deleteRepeated (p : ps) = if elem p ps
then deleteRepeated ps
else p : deleteRepeated ps
-- | returns the first element from the triple
fstTpl :: (a, b, c) -> a
fstTpl (a, _, _) = a
-- | instantiate the parametric sorts
-- ParamNames -> ViewName -> Map of views -> Parametricsorts
instantiateSorts :: [Token] -> [Token] -> ViewMap -> Morphism -> [ParamSort]
-> ([ParamSort], Morphism)
instantiateSorts _ _ _ morph [] = ([], morph)
instantiateSorts params views vm morph (ps : pss) = (nps'' ++ res_ps, res_morph)
where np4s = newParamers4sorts params views vm
nps = instantiateSort ps params views
nps' = addNewParams2sort nps np4s
nps'' = if null (snd nps') then [] else [nps']
morph' = extendWithSortRenaming (fst ps) (fst nps') morph
(res_ps, res_morph) = instantiateSorts params views vm morph' pss
-- | computes the theories that have to be further instantiated
newParamers4sorts :: [Token] -> [Token] -> ViewMap -> [Token]
newParamers4sorts (param : ps) (view : vs) vm = case Map.member view vm of
False -> newParamers4sorts ps vs vm
True -> let
(_, _, _, _, inst) = fromJust $ Map.lookup view vm
param' = if inst
then []
else [param]
in param' ++ newParamers4sorts ps vs vm
newParamers4sorts _ _ _ = []
-- | creates a new parameterized sort
addNewParams2sort :: ParamSort -> [Token] -> ParamSort
addNewParams2sort (Sort tok, _) lps@(_:_) = (Sort tok', lps)
where tok' = mkSimpleId $ concat [show tok, "`{", printNewParams4sort lps, "`}"]
addNewParams2sort (Kind tok, _) lps@(_:_) = (Kind tok', lps)
where tok' = mkSimpleId $ concat [show tok, "`{", printNewParams4sort lps, "`}"]
addNewParams2sort (ps, _) _ = (ps, [])
-- | introduces commas between the tokens
printNewParams4sort :: [Token] -> String
printNewParams4sort [] = ""
printNewParams4sort [p] = show p
printNewParams4sort (p : ps) = concat [show p, "`,", printNewParams4sort ps]
-- | instantiate a sort
-- Params: Parameterized sort -> Parameter to be replaced -> New name of the parameter
instantiateSort :: ParamSort -> [Token] -> [Token] -> ParamSort
instantiateSort sp@(Sort tok, tok_params) (p : ps) (v : vs) = case elem p tok_params of
False -> instantiateSort sp ps vs
True -> let
tok' = mkSimpleId $ instantiateSortString (show tok) (show p) (show v)
in instantiateSort (Sort tok', tok_params) ps vs
instantiateSort sp@(Kind tok, tok_params) (p : ps) (v : vs) = case elem p tok_params of
False -> instantiateSort sp ps vs
True -> let
tok' = mkSimpleId $ instantiateSortString (show tok) (show p) (show v)
in instantiateSort (Kind tok', tok_params) ps vs
instantiateSort ps _ _ = ps
-- | replaces one param by one view in a sort identifier
-- sort id -> param id -> view id
instantiateSortString :: String -> String -> String -> String
instantiateSortString ('{' : cs) param view = case elem '{' cs of
False -> '{' : instantiateSortStringAux cs param view ""
True -> '{' : instantiateSortString cs param view
instantiateSortString (c : cs) param view = c : instantiateSortString cs param view
instantiateSortString [] _ _ = ""
-- | replaces one param by one view in the list of parameters
-- parameters list -> param id -> view id
instantiateSortStringAux :: String -> String -> String -> String -> String
instantiateSortStringAux ('`' : ',' : ps) param view acc = value ++ "`," ++
instantiateSortStringAux ps param view ""
where value = if acc == param
then view
else acc
instantiateSortStringAux ('`' : '}' : _) param view acc = value ++ "`}"
where value = if acc == param
then view
else acc
instantiateSortStringAux (p : ps) param view acc =
instantiateSortStringAux ps param view (acc ++ [p])
instantiateSortStringAux _ _ _ acc = acc
-- | qualifies the source sorts in the renamigs
qualifyRenamings :: Token -> [Renaming] -> [Renaming]
qualifyRenamings t = map (qualifyRenaming t)
-- | qualifies the source sort in the renaming. Sorts only appear in operator mappings
-- with profile and sort mappings
qualifyRenaming :: Token -> Renaming -> Renaming
qualifyRenaming p rnm = case rnm of
OpRenaming2 from ar co to -> OpRenaming2 from (map (qualifyType p) ar)
((qualifyType p) co) to
SortRenaming from to -> SortRenaming ((qualifySort p) from) to
_ -> rnm
-- | qualifies both the source and target sorts in the renamings
qualifyRenamings2 :: Token -> [Renaming] -> [Renaming]
qualifyRenamings2 t = map (qualifyRenaming2 t)
-- | qualifies both the source and target sorts in the renaming.
-- Sorts only appear in operator mappings with profile and sort mappings
qualifyRenaming2 :: Token -> Renaming -> Renaming
qualifyRenaming2 p rnm = case rnm of
OpRenaming2 from ar co to -> OpRenaming2 from (map (qualifyType p) ar)
((qualifyType p) co) to
SortRenaming from to -> SortRenaming ((qualifySort p) from) ((qualifySort p) to)
_ -> rnm
-- | creates a renaming to substitute the sorts qualified by a parameter name
-- with a new parameter name due to a parameter binding
createQualifiedSortRenaming :: Token -> Token -> Symbols -> [Renaming]
createQualifiedSortRenaming _ _ [] = []
createQualifiedSortRenaming old new (s : ss) = case old == new of
True -> []
False -> rnm : createQualifiedSortRenaming old new ss
where rnm = SortRenaming (qualifiedSort old' s')
(qualifiedSort new' s')
where old' = HasName.getName old
new' = HasName.getName new
s' = HasName.getName s
-- | qualifies with the given parameter the token
qualifiedSort :: Token -> Token -> Sort
qualifiedSort param sort = SortId $ mkSimpleId $ concat [show param, "$", show sort]
-- | qualifies with the given parameter the sort
qualifySort :: Token -> Sort -> Sort
qualifySort p (SortId s) = qualifiedSort p s
-- | qualifies with the given parameter the type
qualifyType :: Token -> Type -> Type
qualifyType p (TypeSort (SortId s)) = TypeSort $ qualifiedSort p s
qualifyType _ ty = ty
-- | qualifies the symbols in the theory imported with the parameter name
-- given as first parameter
createQualificationTh2Mod :: Token -> Symbols -> [Renaming]
createQualificationTh2Mod _ [] = []
createQualificationTh2Mod par (s : ss) =
rnm : createQualificationTh2Mod par ss
where par' = HasName.getName par
s' = HasName.getName s
rnm = SortRenaming (SortId s') (qualifiedSort par' s')
-- | Library name for Maude prelude
preludeLib :: LibName
preludeLib = emptyLibName "Maude_Prelude"
-- | generates the library and the development graph from the path of the
-- maude file
anaMaudeFile :: HetcatsOpts -> FilePath -> IO (Maybe (LibName, LibEnv))
anaMaudeFile _ file = do
(dg1, dg2) <- directMaudeParsing file
let ln = emptyLibName file
lib1 = Map.singleton preludeLib $
markHiding Map.empty dg1
lib2 = Map.insert ln
(computeDGraphTheories lib1 $ markFree lib1 $
markHiding lib1 dg2) lib1
return $ Just (ln, lib2)