KiCS-0.8.9: src/lib/Curry/Module/FlatCurryGoodies.curry
----------------------------------------------------------------------------
--- This library provides selector functions, test and update operations
--- as well as some useful auxiliary functions for FlatCurry data terms.
--- Most of the provided functions are based on general transformation
--- functions that replace constructors with user-defined
--- functions. For recursive datatypes the transformations are defined
--- inductively over the term structure. This is quite usual for
--- transformations on FlatCurry terms,
--- so the provided functions can be used to implement specific transformations
--- without having to explicitly state the recursion. Essentially, the tedious
--- part of such transformations - descend in fairly complex term structures -
--- is abstracted away, which hopefully makes the code more clear and brief.
---
--- @author Sebastian Fischer
--- @version January 2006
----------------------------------------------------------------------------
module FlatCurryGoodies where
import FlatCurry
type Update a b = (b -> b) -> a -> a
-- Prog ----------------------------------------------------------------------
--- transform program
trProg :: (String -> [String] -> [TypeDecl] -> [FuncDecl] -> [OpDecl] -> a)
-> Prog -> a
trProg prog (Prog name imps types funcs ops) = prog name imps types funcs ops
-- Selectors
--- get name from program
progName :: Prog -> String
progName = trProg (\name _ _ _ _ -> name)
--- get imports from program
progImports :: Prog -> [String]
progImports = trProg (\_ imps _ _ _ -> imps)
--- get type declarations from program
progTypes :: Prog -> [TypeDecl]
progTypes = trProg (\_ _ types _ _ -> types)
--- get functions from program
progFuncs :: Prog -> [FuncDecl]
progFuncs = trProg (\_ _ _ funcs _ -> funcs)
--- get infix operators from program
progOps :: Prog -> [OpDecl]
progOps = trProg (\_ _ _ _ ops -> ops)
-- Update Operations
--- update program
updProg :: (String -> String) ->
([String] -> [String]) ->
([TypeDecl] -> [TypeDecl]) ->
([FuncDecl] -> [FuncDecl]) ->
([OpDecl] -> [OpDecl]) -> Prog -> Prog
updProg fn fi ft ff fo = trProg prog
where
prog name imps types funcs ops
= Prog (fn name) (fi imps) (ft types) (ff funcs) (fo ops)
--- update name of program
updProgName :: Update Prog String
updProgName f = updProg f id id id id
--- update imports of program
updProgImports :: Update Prog [String]
updProgImports f = updProg id f id id id
--- update type declarations of program
updProgTypes :: Update Prog [TypeDecl]
updProgTypes f = updProg id id f id id
--- update functions of program
updProgFuncs :: Update Prog [FuncDecl]
updProgFuncs f = updProg id id id f id
--- update infix operators of program
updProgOps :: Update Prog [OpDecl]
updProgOps = updProg id id id id
-- Auxiliary Functions
--- get all program variables (also from patterns)
allVarsInProg :: Prog -> [VarIndex]
allVarsInProg = concatMap allVarsInFunc . progFuncs
--- lift transformation on expressions to program
updProgExps :: Update Prog Expr
updProgExps = updProgFuncs . map . updFuncBody
--- rename programs variables
rnmAllVarsInProg :: Update Prog VarIndex
rnmAllVarsInProg = updProgFuncs . map . rnmAllVarsInFunc
--- update all qualified names in program
updQNamesInProg :: Update Prog QName
updQNamesInProg f = updProg id id
(map (updQNamesInType f)) (map (updQNamesInFunc f)) (map (updOpName f))
--- rename program (update name of and all qualified names in program)
rnmProg :: String -> Prog -> Prog
rnmProg name p = updProgName (const name) (updQNamesInProg rnm p)
where
rnm (mod,n) | mod==progName p = (name,n)
| otherwise = (mod,n)
-- TypeDecl ------------------------------------------------------------------
-- Selectors
--- transform type declaration
trType :: (QName -> Visibility -> [TVarIndex] -> [ConsDecl] -> a) ->
(QName -> Visibility -> [TVarIndex] -> TypeExpr -> a) -> TypeDecl -> a
trType typ _ (Type name vis params cs) = typ name vis params cs
trType _ typesyn (TypeSyn name vis params syn) = typesyn name vis params syn
--- get name of type declaration
typeName :: TypeDecl -> QName
typeName = trType (\name _ _ _ -> name) (\name _ _ _ -> name)
--- get visibility of type declaration
typeVisibility :: TypeDecl -> Visibility
typeVisibility = trType (\_ vis _ _ -> vis) (\_ vis _ _ -> vis)
--- get type parameters of type declaration
typeParams :: TypeDecl -> [TVarIndex]
typeParams = trType (\_ _ params _ -> params) (\_ _ params _ -> params)
--- get constructor declarations from type declaration
typeConsDecls :: TypeDecl -> [ConsDecl]
typeConsDecls = trType (\_ _ _ cs -> cs) failed
--- get synonym of type declaration
typeSyn :: TypeDecl -> TypeExpr
typeSyn = trType failed (\_ _ _ syn -> syn)
--- is type declaration a type synonym?
isTypeSyn :: TypeDecl -> Bool
isTypeSyn = trType (\_ _ _ _ -> False) (\_ _ _ _ -> True)
-- is type declaration declaring a regular type?
isDataTypeDecl :: TypeDecl -> Bool
isDataTypeDecl = trType (\_ _ _ cs -> not (null cs)) (\_ _ _ _ -> False)
-- is type declaration declaring an external type?
isExternalType :: TypeDecl -> Bool
isExternalType = trType (\_ _ _ cs -> null cs) (\_ _ _ _ -> False)
-- Update Operations
--- update type declaration
updType :: (QName -> QName) ->
(Visibility -> Visibility) ->
([TVarIndex] -> [TVarIndex]) ->
([ConsDecl] -> [ConsDecl]) ->
(TypeExpr -> TypeExpr) -> TypeDecl -> TypeDecl
updType fn fv fp fc fs = trType typ typesyn
where
typ name vis params cs = Type (fn name) (fv vis) (fp params) (fc cs)
typesyn name vis params syn = TypeSyn (fn name) (fv vis) (fp params) (fs syn)
--- update name of type declaration
updTypeName :: Update TypeDecl QName
updTypeName f = updType f id id id id
--- update visibility of type declaration
updTypeVisibility :: Update TypeDecl Visibility
updTypeVisibility f = updType id f id id id
--- update type parameters of type declaration
updTypeParams :: Update TypeDecl [TVarIndex]
updTypeParams f = updType id id f id id
--- update constructor declarations of type declaration
updTypeConsDecls :: Update TypeDecl [ConsDecl]
updTypeConsDecls f = updType id id id f id
--- update synonym of type declaration
updTypeSynonym :: Update TypeDecl TypeExpr
updTypeSynonym = updType id id id id
-- Auxiliary Functions
--- update all qualified names in type declaration
updQNamesInType :: Update TypeDecl QName
updQNamesInType f
= updType f id id (map (updQNamesInConsDecl f)) (updQNamesInTypeExpr f)
-- ConsDecl ------------------------------------------------------------------
-- Selectors
--- transform constructor declaration
trCons :: (QName -> Int -> Visibility -> [TypeExpr] -> a) -> ConsDecl -> a
trCons cons (Cons name arity vis args) = cons name arity vis args
--- get name of constructor declaration
consName :: ConsDecl -> QName
consName = trCons (\name _ _ _ -> name)
--- get arity of constructor declaration
consArity :: ConsDecl -> Int
consArity = trCons (\_ arity _ _ -> arity)
--- get visibility of constructor declaration
consVisibility :: ConsDecl -> Visibility
consVisibility = trCons (\_ _ vis _ -> vis)
--- get arguments of constructor declaration
consArgs :: ConsDecl -> [TypeExpr]
consArgs = trCons (\_ _ _ args -> args)
-- Update Operations
--- update constructor declaration
updCons :: (QName -> QName) ->
(Int -> Int) ->
(Visibility -> Visibility) ->
([TypeExpr] -> [TypeExpr]) -> ConsDecl -> ConsDecl
updCons fn fa fv fas = trCons cons
where
cons name arity vis args = Cons (fn name) (fa arity) (fv vis) (fas args)
--- update name of constructor declaration
updConsName :: Update ConsDecl QName
updConsName f = updCons f id id id
--- update arity of constructor declaration
updConsArity :: Update ConsDecl Int
updConsArity f = updCons id f id id
--- update visibility of constructor declaration
updConsVisibility :: Update ConsDecl Visibility
updConsVisibility f = updCons id id f id
--- update arguments of constructor declaration
updConsArgs :: Update ConsDecl [TypeExpr]
updConsArgs = updCons id id id
-- Auxiliary Functions
--- update all qualified names in constructor declaration
updQNamesInConsDecl :: Update ConsDecl QName
updQNamesInConsDecl f = updCons f id id (map (updQNamesInTypeExpr f))
-- TypeExpr ------------------------------------------------------------------
-- Selectors
--- get index from type variable
tVarIndex :: TypeExpr -> TVarIndex
tVarIndex (TVar n) = n
--- get domain from functional type
domain :: TypeExpr -> TypeExpr
domain (FuncType dom _) = dom
--- get range from functional type
range :: TypeExpr -> TypeExpr
range (FuncType _ ran) = ran
--- get name from constructed type
tConsName :: TypeExpr -> QName
tConsName (TCons name _) = name
--- get arguments from constructed type
tConsArgs :: TypeExpr -> [TypeExpr]
tConsArgs (TCons _ args) = args
--- transform type expression
trTypeExpr :: (TVarIndex -> a) ->
(QName -> [a] -> a) ->
(a -> a -> a) -> TypeExpr -> a
trTypeExpr tvar _ _ (TVar n) = tvar n
trTypeExpr tvar tcons functype (TCons name args)
= tcons name (map (trTypeExpr tvar tcons functype) args)
trTypeExpr tvar tcons functype (FuncType from to) = functype (f from) (f to)
where
f = trTypeExpr tvar tcons functype
-- Test Operations
--- is type expression a type variable?
isTVar :: TypeExpr -> Bool
isTVar = trTypeExpr (\_ -> True) (\_ _ -> False) (\_ _ -> False)
--- is type declaration a constructed type?
isTCons :: TypeExpr -> Bool
isTCons = trTypeExpr (\_ -> False) (\_ _ -> True) (\_ _ -> False)
--- is type declaration a functional type?
isFuncType :: TypeExpr -> Bool
isFuncType = trTypeExpr (\_ -> False) (\_ _ -> False) (\_ _ -> True)
-- Update Operations
--- update all type variables
updTVars :: (TVarIndex -> TypeExpr) -> TypeExpr -> TypeExpr
updTVars tvar = trTypeExpr tvar TCons FuncType
--- update all type constructors
updTCons :: (QName -> [TypeExpr] -> TypeExpr) -> TypeExpr -> TypeExpr
updTCons tcons = trTypeExpr TVar tcons FuncType
--- update all functional types
updFuncTypes :: (TypeExpr -> TypeExpr -> TypeExpr) -> TypeExpr -> TypeExpr
updFuncTypes = trTypeExpr TVar TCons
-- Auxiliary Functions
--- get argument types from functional type
argTypes :: TypeExpr -> [TypeExpr]
argTypes (TVar _) = []
argTypes (TCons _ _) = []
argTypes (FuncType dom ran) = dom : argTypes ran
--- get result type from (nested) functional type
resultType :: TypeExpr -> TypeExpr
resultType (TVar n) = TVar n
resultType (TCons name args) = TCons name args
resultType (FuncType _ ran) = resultType ran
--- get indexes of all type variables
allVarsInTypeExpr :: TypeExpr -> [TVarIndex]
allVarsInTypeExpr = trTypeExpr (:[]) (const concat) (++)
--- rename variables in type expression
rnmAllVarsInTypeExpr :: (TVarIndex -> TVarIndex) -> TypeExpr -> TypeExpr
rnmAllVarsInTypeExpr f = updTVars (TVar . f)
--- update all qualified names in type expression
updQNamesInTypeExpr :: (QName -> QName) -> TypeExpr -> TypeExpr
updQNamesInTypeExpr f = updTCons (\name args -> TCons (f name) args)
-- OpDecl --------------------------------------------------------------------
--- transform operator declaration
trOp :: (QName -> Fixity -> Int -> a) -> OpDecl -> a
trOp op (Op name fix prec) = op name fix prec
-- Selectors
--- get name from operator declaration
opName :: OpDecl -> QName
opName = trOp (\name _ _ -> name)
--- get fixity of operator declaration
opFixity :: OpDecl -> Fixity
opFixity = trOp (\_ fix _ -> fix)
--- get precedence of operator declaration
opPrecedence :: OpDecl -> Int
opPrecedence = trOp (\_ _ prec -> prec)
-- Update Operations
--- update operator declaration
updOp :: (QName -> QName) ->
(Fixity -> Fixity) ->
(Int -> Int) -> OpDecl -> OpDecl
updOp fn ff fp = trOp op
where
op name fix prec = Op (fn name) (ff fix) (fp prec)
--- update name of operator declaration
updOpName :: Update OpDecl QName
updOpName f = updOp f id id
--- update fixity of operator declaration
updOpFixity :: Update OpDecl Fixity
updOpFixity f = updOp id f id
--- update precedence of operator declaration
updOpPrecedence :: Update OpDecl Int
updOpPrecedence = updOp id id
-- FuncDecl ------------------------------------------------------------------
--- transform function
trFunc :: (QName -> Int -> Visibility -> TypeExpr -> Rule -> a) -> FuncDecl -> a
trFunc func (Func name arity vis t rule) = func name arity vis t rule
-- Selectors
--- get name of function
funcName :: FuncDecl -> QName
funcName = trFunc (\name _ _ _ _ -> name)
--- get arity of function
funcArity :: FuncDecl -> Int
funcArity = trFunc (\_ arity _ _ _ -> arity)
--- get visibility of function
funcVisibility :: FuncDecl -> Visibility
funcVisibility = trFunc (\_ _ vis _ _ -> vis)
--- get type of function
funcType :: FuncDecl -> TypeExpr
funcType = trFunc (\_ _ _ t _ -> t)
--- get rule of function
funcRule :: FuncDecl -> Rule
funcRule = trFunc (\_ _ _ _ rule -> rule)
-- Update Operations
--- update function
updFunc :: (QName -> QName) ->
(Int -> Int) ->
(Visibility -> Visibility) ->
(TypeExpr -> TypeExpr) ->
(Rule -> Rule) -> FuncDecl -> FuncDecl
updFunc fn fa fv ft fr = trFunc func
where
func name arity vis t rule
= Func (fn name) (fa arity) (fv vis) (ft t) (fr rule)
--- update name of function
updFuncName :: Update FuncDecl QName
updFuncName f = updFunc f id id id id
--- update arity of function
updFuncArity :: Update FuncDecl Int
updFuncArity f = updFunc id f id id id
--- update visibility of function
updFuncVisibility :: Update FuncDecl Visibility
updFuncVisibility f = updFunc id id f id id
--- update type of function
updFuncType :: Update FuncDecl TypeExpr
updFuncType f = updFunc id id id f id
--- update rule of function
updFuncRule :: Update FuncDecl Rule
updFuncRule = updFunc id id id id
-- Auxiliary Functions
--- is function externally defined?
isExternal :: FuncDecl -> Bool
isExternal = isRuleExternal . funcRule
--- get variable names in a function declaration
allVarsInFunc :: FuncDecl -> [VarIndex]
allVarsInFunc = allVarsInRule . funcRule
--- get arguments of function, if not externally defined
funcArgs :: FuncDecl -> [VarIndex]
funcArgs = ruleArgs . funcRule
--- get body of function, if not externally defined
funcBody :: FuncDecl -> Expr
funcBody = ruleBody . funcRule
funcRHS :: FuncDecl -> [Expr]
funcRHS f | not (isExternal f) = orCase (funcBody f)
| otherwise = []
where
orCase e
| isOr e = concatMap orCase (orExps e)
| isCase e = concatMap orCase (map branchExpr (caseBranches e))
| otherwise = [e]
--- rename all variables in function
rnmAllVarsInFunc :: Update FuncDecl VarIndex
rnmAllVarsInFunc = updFunc id id id id . rnmAllVarsInRule
--- update all qualified names in function
updQNamesInFunc :: Update FuncDecl QName
updQNamesInFunc f = updFunc f id id (updQNamesInTypeExpr f) (updQNamesInRule f)
--- update arguments of function, if not externally defined
updFuncArgs :: Update FuncDecl [VarIndex]
updFuncArgs = updFuncRule . updRuleArgs
--- update body of function, if not externally defined
updFuncBody :: Update FuncDecl Expr
updFuncBody = updFuncRule . updRuleBody
-- Rule ----------------------------------------------------------------------
--- transform rule
trRule :: ([VarIndex] -> Expr -> a) -> (String -> a) -> Rule -> a
trRule rule _ (Rule args exp) = rule args exp
trRule _ ext (External s) = ext s
-- Selectors
--- get rules arguments if it's not external
ruleArgs :: Rule -> [VarIndex]
ruleArgs = trRule (\args _ -> args) failed
--- get rules body if it's not external
ruleBody :: Rule -> Expr
ruleBody = trRule (\_ exp -> exp) failed
--- get rules external declaration
ruleExtDecl :: Rule -> String
ruleExtDecl = trRule failed id
-- Test Operations
--- is rule external?
isRuleExternal :: Rule -> Bool
isRuleExternal = trRule (\_ _ -> False) (\_ -> True)
-- Update Operations
--- update rule
updRule :: ([VarIndex] -> [VarIndex]) ->
(Expr -> Expr) ->
(String -> String) -> Rule -> Rule
updRule fa fe fs = trRule rule ext
where
rule args exp = Rule (fa args) (fe exp)
ext s = External (fs s)
--- update rules arguments
updRuleArgs :: Update Rule [VarIndex]
updRuleArgs f = updRule f id id
--- update rules body
updRuleBody :: Update Rule Expr
updRuleBody f = updRule id f id
--- update rules external declaration
updRuleExtDecl :: Update Rule String
updRuleExtDecl f = updRule id id f
-- Auxiliary Functions
--- get variable names in a functions rule
allVarsInRule :: Rule -> [VarIndex]
allVarsInRule = trRule (\args body -> args ++ allVars body) (\_ -> [])
--- rename all variables in rule
rnmAllVarsInRule :: Update Rule VarIndex
rnmAllVarsInRule f = updRule (map f) (rnmAllVars f) id
--- update all qualified names in rule
updQNamesInRule :: Update Rule QName
updQNamesInRule = updRuleBody . updQNames
-- CombType ------------------------------------------------------------------
--- transform combination type
trCombType :: a -> (Int -> a) -> a -> (Int -> a) -> CombType -> a
trCombType fc _ _ _ FuncCall = fc
trCombType _ fpc _ _ (FuncPartCall n) = fpc n
trCombType _ _ cc _ ConsCall = cc
trCombType _ _ _ cpc (ConsPartCall n) = cpc n
-- Test Operations
--- is type of combination FuncCall?
isCombTypeFuncCall :: CombType -> Bool
isCombTypeFuncCall = trCombType True (\_ -> False) False (\_ -> False)
--- is type of combination FuncPartCall?
isCombTypeFuncPartCall :: CombType -> Bool
isCombTypeFuncPartCall = trCombType False (\_ -> True) False (\_ -> False)
--- is type of combination ConsCall?
isCombTypeConsCall :: CombType -> Bool
isCombTypeConsCall = trCombType False (\_ -> False) True (\_ -> False)
--- is type of combination ConsPartCall?
isCombTypeConsPartCall :: CombType -> Bool
isCombTypeConsPartCall = trCombType False (\_ -> False) False (\_ -> True)
-- Auxiliary Functions
missingArgs :: CombType -> Int
missingArgs = trCombType 0 id 0 id
-- Expr ----------------------------------------------------------------------
-- Selectors
--- get internal number of variable
varNr :: Expr -> VarIndex
varNr (Var n) = n
--- get literal if expression is literal expression
literal :: Expr -> Literal
literal (Lit l) = l
--- get combination type of a combined expression
combType :: Expr -> CombType
combType (Comb ct _ _) = ct
--- get name of a combined expression
combName :: Expr -> QName
combName (Comb _ name _) = name
--- get arguments of a combined expression
combArgs :: Expr -> [Expr]
combArgs (Comb _ _ args) = args
--- get number of missing arguments if expression is combined
missingCombArgs :: Expr -> Int
missingCombArgs = missingArgs . combType
--- get indices of varoables in let declaration
letBinds :: Expr -> [(VarIndex,Expr)]
letBinds (Let vs _) = vs
--- get body of let declaration
letBody :: Expr -> Expr
letBody (Let _ e) = e
--- get variable indices from declaration of free variables
freeVars :: Expr -> [VarIndex]
freeVars (Free vs _) = vs
--- get expression from declaration of free variables
freeExpr :: Expr -> Expr
freeExpr (Free _ e) = e
--- get expressions from or-expression
orExps :: Expr -> [Expr]
orExps (FlatCurry.Or e1 e2) = [e1,e2]
--- get case-type of case expression
caseType :: Expr -> CaseType
caseType (Case ct _ _) = ct
--- get scrutinee of case expression
caseExpr :: Expr -> Expr
caseExpr (Case _ e _) = e
--- get branch expressions from case expression
caseBranches :: Expr -> [BranchExpr]
caseBranches (Case _ _ bs) = bs
-- Test Operations
--- is expression a variable?
isVar :: Expr -> Bool
isVar e = case e of
Var _ -> True
_ -> False
--- is expression a literal expression?
isLit :: Expr -> Bool
isLit e = case e of
Lit _ -> True
_ -> False
--- is expression combined?
isComb :: Expr -> Bool
isComb e = case e of
Comb _ _ _ -> True
_ -> False
--- is expression a let expression?
isLet :: Expr -> Bool
isLet e = case e of
Let _ _ -> True
_ -> False
--- is expression a declaration of free variables?
isFree :: Expr -> Bool
isFree e = case e of
Free _ _ -> True
_ -> False
--- is expression an or-expression?
isOr :: Expr -> Bool
isOr e = case e of
FlatCurry.Or _ _ -> True
_ -> False
--- is expression a case expression?
isCase :: Expr -> Bool
isCase e = case e of
Case _ _ _ -> True
_ -> False
--- transform expression
trExpr :: (VarIndex -> a) ->
(Literal -> a) ->
(CombType -> QName -> [a] -> a) ->
([(VarIndex,a)] -> a -> a) ->
([VarIndex] -> a -> a) ->
(a -> a -> a) ->
(CaseType -> a -> [b] -> a) ->
(Pattern -> a -> b) -> Expr -> a
trExpr var _ _ _ _ _ _ _ (Var n) = var n
trExpr _ lit _ _ _ _ _ _ (Lit l) = lit l
trExpr var lit comb lt fr or cas branch (Comb ct name args)
= comb ct name (map (trExpr var lit comb lt fr or cas branch) args)
trExpr var lit comb lt fr or cas branch (Let bs e)
= lt (map (\ (n,exp) -> (n,f exp)) bs) (f e)
where
f = trExpr var lit comb lt fr or cas branch
trExpr var lit comb lt fr or cas branch (Free vs e)
= fr vs (trExpr var lit comb lt fr or cas branch e)
trExpr var lit comb lt fr or cas branch (FlatCurry.Or e1 e2) = or (f e1) (f e2)
where
f = trExpr var lit comb lt fr or cas branch
trExpr var lit comb lt fr or cas branch (Case ct e bs)
= cas ct (f e) (map (\ (Branch pat exp) -> branch pat (f exp)) bs)
where
f = trExpr var lit comb lt fr or cas branch
-- Update Operations
--- update all variables in given expression
updVars :: (VarIndex -> Expr) -> Expr -> Expr
updVars var = trExpr var Lit Comb Let Free FlatCurry.Or Case Branch
--- update all literals in given expression
updLiterals :: (Literal -> Expr) -> Expr -> Expr
updLiterals lit = trExpr Var lit Comb Let Free FlatCurry.Or Case Branch
--- update all combined expressions in given expression
updCombs :: (CombType -> QName -> [Expr] -> Expr) -> Expr -> Expr
updCombs comb = trExpr Var Lit comb Let Free FlatCurry.Or Case Branch
--- update all let expressions in given expression
updLets :: ([(VarIndex,Expr)] -> Expr -> Expr) -> Expr -> Expr
updLets lt = trExpr Var Lit Comb lt Free FlatCurry.Or Case Branch
--- update all free declarations in given expression
updFrees :: ([VarIndex] -> Expr -> Expr) -> Expr -> Expr
updFrees fr = trExpr Var Lit Comb Let fr FlatCurry.Or Case Branch
--- update all or expressions in given expression
updOrs :: (Expr -> Expr -> Expr) -> Expr -> Expr
updOrs or = trExpr Var Lit Comb Let Free or Case Branch
--- update all case expressions in given expression
updCases :: (CaseType -> Expr -> [BranchExpr] -> Expr) -> Expr -> Expr
updCases cas = trExpr Var Lit Comb Let Free FlatCurry.Or cas Branch
--- update all case branches in given expression
updBranches :: (Pattern -> Expr -> BranchExpr) -> Expr -> Expr
updBranches branch = trExpr Var Lit Comb Let Free FlatCurry.Or Case branch
-- Auxiliary Functions
--- is expression a call of a function where all arguments are provided?
isFuncCall :: Expr -> Bool
isFuncCall e = isComb e && isCombTypeFuncCall (combType e)
--- is expression a partial function call?
isFuncPartCall :: Expr -> Bool
isFuncPartCall e = isComb e && isCombTypeFuncPartCall (combType e)
--- is expression a call of a constructor?
isConsCall :: Expr -> Bool
isConsCall e = isComb e && isCombTypeConsCall (combType e)
--- is expression a partial constructor call?
isConsPartCall :: Expr -> Bool
isConsPartCall e = isComb e && isCombTypeConsPartCall (combType e)
--- is expression fully evaluated?
isGround :: Expr -> Bool
isGround exp
= case exp of
Comb ConsCall _ args -> all isGround args
_ -> isLit exp
--- get all variables (also pattern variables) in expression
allVars :: Expr -> [VarIndex]
allVars e = trExpr (:) (const id) comb lt fr (.) cas branch e []
where
comb _ _ = foldr (.) id
lt bs exp = exp . foldr (.) id (map (\ (n,ns) -> (n:) . ns) bs)
fr vs exp = (vs++) . exp
cas _ exp bs = exp . foldr (.) id bs
branch pat exp = ((args pat)++) . exp
args pat | isConsPattern pat = patArgs pat
| otherwise = []
--- rename all variables (also in patterns) in expression
rnmAllVars :: Update Expr VarIndex
rnmAllVars f = trExpr (Var . f) Lit Comb lt (Free . map f) FlatCurry.Or Case branch
where
lt = Let . map (\ (n,exp) -> (f n,exp))
branch = Branch . updPatArgs (map f)
--- update all qualified names in expression
updQNames :: Update Expr QName
updQNames f = trExpr Var Lit comb Let Free FlatCurry.Or Case (Branch . updPatCons f)
where
comb ct name args = Comb ct (f name) args
-- BranchExpr ----------------------------------------------------------------
--- transform branch expression
trBranch :: (Pattern -> Expr -> a) -> BranchExpr -> a
trBranch branch (Branch pat exp) = branch pat exp
-- Selectors
--- get pattern from branch expression
branchPattern :: BranchExpr -> Pattern
branchPattern = trBranch (\pat _ -> pat)
--- get expression from branch expression
branchExpr :: BranchExpr -> Expr
branchExpr = trBranch (\_ e -> e)
-- Update Operations
--- update branch expression
updBranch :: (Pattern -> Pattern) -> (Expr -> Expr) -> BranchExpr -> BranchExpr
updBranch fp fe = trBranch branch
where
branch pat exp = Branch (fp pat) (fe exp)
--- update pattern of branch expression
updBranchPattern :: Update BranchExpr Pattern
updBranchPattern f = updBranch f id
--- update expression of branch expression
updBranchExpr :: Update BranchExpr Expr
updBranchExpr = updBranch id
-- Pattern -------------------------------------------------------------------
--- transform pattern
trPattern :: (QName -> [VarIndex] -> a) -> (Literal -> a) -> Pattern -> a
trPattern pattern _ (Pattern name args) = pattern name args
trPattern _ lpattern (LPattern l) = lpattern l
-- Selectors
--- get name from constructor pattern
patCons :: Pattern -> QName
patCons = trPattern (\name _ -> name) failed
--- get arguments from constructor pattern
patArgs :: Pattern -> [VarIndex]
patArgs = trPattern (\_ args -> args) failed
--- get literal from literal pattern
patLiteral :: Pattern -> Literal
patLiteral = trPattern failed id
-- Test Operations
--- is pattern a constructor pattern?
isConsPattern :: Pattern -> Bool
isConsPattern = trPattern (\_ _ -> True) (\_ -> False)
-- Update Operations
--- update pattern
updPattern :: (QName -> QName) ->
([VarIndex] -> [VarIndex]) ->
(Literal -> Literal) -> Pattern -> Pattern
updPattern fn fa fl = trPattern pattern lpattern
where
pattern name args = Pattern (fn name) (fa args)
lpattern l = LPattern (fl l)
--- update constructors name of pattern
updPatCons :: (QName -> QName) -> Pattern -> Pattern
updPatCons f = updPattern f id id
--- update arguments of constructor pattern
updPatArgs :: ([VarIndex] -> [VarIndex]) -> Pattern -> Pattern
updPatArgs f = updPattern id f id
--- update literal of pattern
updPatLiteral :: (Literal -> Literal) -> Pattern -> Pattern
updPatLiteral f = updPattern id id f
-- Auxiliary Functions
--- build expression from pattern
patExpr :: Pattern -> Expr
patExpr = trPattern (\ name -> Comb ConsCall name . map Var) Lit