{- |

Module : $Header$

Description : embedding CASL into HasCASL

Copyright : (c) Till Mossakowski, Christian Maeder and Uni Bremen 2003-2005

License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt

Maintainer : Christian.Maeder@dfki.de

Stability : provisional

Portability : non-portable (imports Logic.Logic)

The embedding comorphism from CASL to HasCASL.

-}

module Comorphisms.CASL2HasCASL where

import Logic.Logic

import Logic.Comorphism

import Common.Id

import Common.AS_Annotation

import qualified Data.Map as Map

import qualified Data.Set as Set

-- CASL

import CASL.Logic_CASL

import CASL.Sublogic as CasSub

import qualified CASL.AS_Basic_CASL as Cas

import qualified CASL.Sign as CasS

import qualified CASL.Morphism as CasM

import HasCASL.Logic_HasCASL

import HasCASL.As

import HasCASL.AsUtils

import HasCASL.Le

import HasCASL.Builtin

import HasCASL.Sublogic as HasSub

-- | The identity of the comorphism

data CASL2HasCASL = CASL2HasCASL deriving (Show)

instance Language CASL2HasCASL -- default definition is okay

instance Comorphism CASL2HasCASL

CASL CASL_Sublogics

CASLBasicSpec CASLFORMULA Cas.SYMB_ITEMS Cas.SYMB_MAP_ITEMS

CASLSign

CASLMor

CasS.Symbol CasM.RawSymbol Q_ProofTree

HasCASL Sublogic

BasicSpec Sentence SymbItems SymbMapItems

Env Morphism Symbol RawSymbol () where

sourceLogic CASL2HasCASL = CASL

sourceSublogic CASL2HasCASL = CasSub.top

targetLogic CASL2HasCASL = HasCASL

mapSublogic CASL2HasCASL sl = Just $ sublogicUp $

(if has_cons sl then sublogic_max need_hol else id)

caslLogic

{ HasSub.has_sub = CasSub.has_sub sl

, HasSub.has_part = CasSub.has_part sl

, HasSub.has_eq = CasSub.has_eq sl

, HasSub.has_pred = CasSub.has_pred sl

, HasSub.which_logic = case CasSub.which_logic sl of

CasSub.Atomic -> HasSub.Atomic

CasSub.Horn -> HasSub.Horn

CasSub.GHorn -> HasSub.GHorn

CasSub.FOL -> HasSub.FOL

}

map_morphism CASL2HasCASL = return . mapMor

map_sentence CASL2HasCASL sig = return . toSentence sig

map_symbol CASL2HasCASL = Set.singleton . mapSym

map_theory CASL2HasCASL = return . mapTheory

has_model_expansion CASL2HasCASL = True

is_weakly_amalgamable CASL2HasCASL = True

fromOpType :: CasS.OpType -> Cas.FunKind -> TypeScheme

fromOpType ot ok =

let args = map toType $ CasS.opArgs ot

arg = mkProductType args

res = toType $ CasS.opRes ot

in simpleTypeScheme $

if null args then case ok of

Cas.Total -> res

Cas.Partial -> mkLazyType res

else mkFunArrType arg (case ok of

Cas.Total -> FunArr

Cas.Partial -> PFunArr) res

fromPredType :: CasS.PredType -> TypeScheme

fromPredType pt =

let args = map toType $ CasS.predArgs pt

p = posOf args

arg = mkProductTypeWithRange args p

in simpleTypeScheme $ if null args then unitTypeWithRange p

else predType p arg

mapTheory :: (CasS.Sign f e, [Named (Cas.FORMULA f)])

-> (Env, [Named Sentence])

mapTheory (sig, sents) =

let constr = foldr getConstructors Set.empty sents

env = mapSig constr sig

newSents = map (mapNamed (toSentence sig)) sents

in (env, newSents)

getConstructors :: Named (Cas.FORMULA f) -> Set.Set (Id, CasS.OpType)

-> Set.Set (Id, CasS.OpType)

getConstructors f s = case sentence f of

Cas.Sort_gen_ax cs _ -> let

(_, ops, _) = Cas.recover_Sort_gen_ax cs

in foldr ( \ (Cas.Qual_op_name i t _) ->

Set.insert (i, (CasS.toOpType t) { CasS.opKind = Cas.Partial }))

s ops

_ -> s

mapSig :: Set.Set (Id, CasS.OpType) -> CasS.Sign f e -> Env

mapSig constr sign =

let f1 = concatMap ( \ (i, s) ->

map ( \ ty -> (i, fromOpType ty $ CasS.opKind ty,

if Set.member (i, ty { CasS.opKind = Cas.Partial })

constr then ConstructData $ CasS.opRes ty

else NoOpDefn Op))

$ Set.toList s) $ Map.toList $ CasS.opMap sign

f2 = concatMap ( \ (i, s) ->

map ( \ ty -> (i, fromPredType ty, NoOpDefn Pred))

$ Set.toList s) $ Map.toList $ CasS.predMap sign

insF (i, ty, defn) m =

let os = Map.findWithDefault Set.empty i m

in Map.insert i (Set.insert (OpInfo ty Set.empty defn) os) m

in initialEnv

{ classMap = Map.empty,

typeMap = Map.fromList $ map

( \ s -> (s, starTypeInfo

{ superTypes = Set.delete s $

CasS.supersortsOf s sign

})) $ Set.toList $ CasS.sortSet sign,

assumps = foldr insF Map.empty (f1 ++ f2)}

mapMor :: CasM.Morphism f e m -> Morphism

mapMor m = let tm = CasM.sort_map m

f1 = map ( \ ((i, ot), (j, t)) ->

((i, fromOpType ot (CasS.opKind ot)),

(j, mapTypeOfScheme (mapType tm)

$ fromOpType ot t)))

$ Map.toList $ CasM.fun_map m

f2 = map ( \ ((i, pt), j) ->

let sc = fromPredType pt

in ((i, sc), (j, mapTypeOfScheme (mapType tm) sc)))

$ Map.toList $ CasM.pred_map m

in (mkMorphism (mapSig Set.empty $ CasM.msource m)

(mapSig Set.empty $ CasM.mtarget m))

{ typeIdMap = tm , funMap = Map.fromList $ f2 ++ f1 }

mapSym :: CasS.Symbol -> Symbol

mapSym s = let i = CasS.symName s in

case CasS.symbType s of

CasS.OpAsItemType ot ->

idToOpSymbol initialEnv i $ fromOpType ot $ CasS.opKind ot

CasS.PredAsItemType pt -> idToOpSymbol initialEnv i $ fromPredType pt

CasS.SortAsItemType -> idToTypeSymbol initialEnv i rStar

toQuant :: Cas.QUANTIFIER -> Quantifier

toQuant Cas.Universal = Universal

toQuant Cas.Existential = Existential

toQuant Cas.Unique_existential = Unique

toVarDecl :: Cas.VAR_DECL -> [GenVarDecl]

toVarDecl (Cas.Var_decl vs s ps) =

map ( \ i -> GenVarDecl $

VarDecl (simpleIdToId i) (toType s) Other ps) vs

toSentence :: CasS.Sign f e -> Cas.FORMULA f -> Sentence

toSentence sig f = case f of

Cas.Sort_gen_ax cs b -> let

(sorts, ops, smap) = Cas.recover_Sort_gen_ax cs

genKind = if b then Free else Generated

mapPart :: Cas.FunKind -> Partiality

mapPart cp = case cp of

Cas.Total -> HasCASL.As.Total

Cas.Partial -> HasCASL.As.Partial

in DatatypeSen $ map ( \ s ->

DataEntry (Map.fromList smap) s genKind [] rStar

$ Set.fromList $ map ( \ (i, t) ->

let args = map toType $ CasS.opArgs t in

Construct (if isInjName i then Nothing else Just i)

(if null args then [] else [mkProductType args])

(mapPart $ CasS.opKind t)

$ if null args then [] else

[map (\ a -> Select Nothing a HasCASL.As.Total) args])

$ filter ( \ (_, t) -> CasS.opRes t == s)

$ map ( \ (Cas.Qual_op_name i t _) ->

(i, CasS.toOpType t)) ops) sorts

_ -> Formula $ toTerm sig f

toTerm :: CasS.Sign f e -> Cas.FORMULA f -> Term

toTerm s f = case f of

Cas.Quantification q vs frm ps ->

QuantifiedTerm (toQuant q)

(concatMap toVarDecl vs) (toTerm s frm) ps

Cas.Conjunction fs ps ->

case map (toTerm s) fs of

[] -> unitTerm trueId ps

ts -> toBinJunctor andId ts ps

Cas.Disjunction fs ps ->

case map (toTerm s) fs of

[] -> unitTerm falseId ps

ts -> toBinJunctor orId ts ps

Cas.Implication f1 f2 b ps ->

let t1 = toTerm s f1

t2 = toTerm s f2

in if b then mkLogTerm implId ps t1 t2

else mkLogTerm infixIf ps t2 t1

Cas.Equivalence f1 f2 ps ->

mkLogTerm eqvId ps (toTerm s f1) $ toTerm s f2

Cas.Negation frm ps -> mkTerm notId notType [] ps $ toTerm s frm

Cas.True_atom ps -> unitTerm trueId ps

Cas.False_atom ps -> unitTerm falseId ps

Cas.Existl_equation t1 t2 ps ->

mkEqTerm exEq (typeOfTerm t1) ps (fromTERM s t1) $ fromTERM s t2

Cas.Strong_equation t1 t2 ps ->

mkEqTerm eqId (typeOfTerm t1) ps (fromTERM s t1) $ fromTERM s t2

Cas.Predication (Cas.Qual_pred_name i (Cas.Pred_type ts _) ps) args qs ->

let sc = simpleTypeScheme $ if null ts then unitTypeWithRange ps

else predType ps $ mkProductTypeWithRange (map toType ts) ps

p = QualOp Pred (PolyId i [] ps) sc [] Infer ps

in if null args then p else TypedTerm

(ApplTerm p (mkTupleTerm (zipWith

(\ tr ty -> TypedTerm (fromTERM s tr) Inferred (toType ty) ps)

args ts) qs) qs)

Inferred unitType ps

Cas.Definedness t ps ->

mkTerm defId defType [typeOfTerm t] ps $ fromTERM s t

Cas.Membership t ty ps -> TypedTerm (fromTERM s t) InType (toType ty) ps

_ -> error "fromTERM"

fromOP_TYPE :: Cas.OP_TYPE -> TypeScheme

fromOP_TYPE ot =

let (args, res, total, arr) = case ot of

Cas.Op_type Cas.Total ars rs _ ->

(ars, rs, True, FunArr)

Cas.Op_type Cas.Partial ars rs _ ->

(ars, rs, False, PFunArr)

resType = toType res

in simpleTypeScheme $ if null args then

if total then resType else mkLazyType resType

else mkFunArrType (mkProductType $ map toType args) arr resType

fromTERM :: CasS.Sign f e -> Cas.TERM f -> Term

fromTERM s t = case t of

Cas.Qual_var v ty ps ->

QualVar $ VarDecl (simpleIdToId v) (toType ty) Other ps

Cas.Application (Cas.Qual_op_name i ot ps) args qs ->

let o = QualOp Op (PolyId i [] ps) (fromOP_TYPE ot) [] Infer ps

at = CasS.toOpType ot

in if null args then o else TypedTerm

(ApplTerm o (mkTupleTerm (zipWith

(\ tr ty -> TypedTerm (fromTERM s tr) Inferred (toType ty) ps)

args $ CasS.opArgs at) qs) qs)

Inferred (toType $ CasS.opRes at) ps

Cas.Sorted_term trm ty ps ->

TypedTerm (fromTERM s trm) OfType (toType ty) ps

Cas.Cast trm ty ps -> TypedTerm (fromTERM s trm) AsType (toType ty) ps

Cas.Conditional t1 f t2 ps -> mkTerm whenElse whenType [typeOfTerm t1] ps $

TupleTerm [fromTERM s t1, toTerm s f, fromTERM s t2] ps

_ -> error "fromTERM"

sortOfTerm :: Cas.TERM f -> Id

sortOfTerm t = case t of

Cas.Qual_var _ ty _ -> ty

Cas.Application (Cas.Qual_op_name _ ot _) _ _ ->

CasS.opRes $ CasS.toOpType ot

Cas.Sorted_term _ ty _ -> ty

Cas.Cast _ ty _ -> ty

Cas.Conditional t1 _ _ _ -> sortOfTerm t1

_ -> error "sortOfTerm"

typeOfTerm :: Cas.TERM f -> Type

typeOfTerm = toType . sortOfTerm