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------------------------------------------------------------------------------ --- Library for representation of substitutions on first-order terms. --- --- @author Jan-Hendrik Matthes --- @version August 2016 --- @category algorithm ------------------------------------------------------------------------------ module Rewriting.Substitution ( Subst , showSubst, emptySubst, extendSubst, listToSubst, lookupSubst, applySubst , applySubstEq, applySubstEqs, restrictSubst, composeSubst ) where import FiniteMap import Function (both) import List (intercalate) import Maybe (fromMaybe) import Rewriting.Term -- --------------------------------------------------------------------------- -- Representation of substitutions on first-order terms -- --------------------------------------------------------------------------- --- A substitution represented as a finite map from variables to terms and --- parameterized over the kind of function symbols, e.g., strings. type Subst f = FM VarIdx (Term f) -- --------------------------------------------------------------------------- -- Pretty-printing of substitutions on first-order terms -- --------------------------------------------------------------------------- -- \x21a6 = RIGHTWARDS ARROW FROM BAR --- Transforms a substitution into a string representation. showSubst :: (f -> String) -> Subst f -> String showSubst s sub = "{" ++ (intercalate "," (map showMapping (fmToList sub))) ++ "}" where showMapping (v, t) = (showVarIdx v) ++ " \8614 " ++ (showTerm s t) -- --------------------------------------------------------------------------- -- Functions for substitutions on first-order terms -- --------------------------------------------------------------------------- --- The irreflexive order predicate of a substitution. substOrder :: VarIdx -> VarIdx -> Bool substOrder = (<) --- The empty substitution. emptySubst :: Subst _ emptySubst = emptyFM substOrder --- Extends a substitution with a new mapping from the given variable to the --- given term. An already existing mapping with the same variable will be --- thrown away. extendSubst :: Subst f -> VarIdx -> Term f -> Subst f extendSubst = addToFM --- Returns a substitution that contains all the mappings from the given list. --- For multiple mappings with the same variable, the last corresponding --- mapping of the given list is taken. listToSubst :: [(VarIdx, Term f)] -> Subst f listToSubst = listToFM substOrder --- Returns the term mapped to the given variable in a substitution or --- `Nothing` if no such mapping exists. lookupSubst :: Subst f -> VarIdx -> Maybe (Term f) lookupSubst = lookupFM --- Applies a substitution to the given term. applySubst :: Subst f -> Term f -> Term f applySubst sub t@(TermVar v) = fromMaybe t (lookupSubst sub v) applySubst sub (TermCons c ts) = TermCons c (map (applySubst sub) ts) --- Applies a substitution to both sides of the given term equation. applySubstEq :: Subst f -> TermEq f -> TermEq f applySubstEq sub = both (applySubst sub) --- Applies a substitution to every term equation in the given list. applySubstEqs :: Subst f -> TermEqs f -> TermEqs f applySubstEqs sub = map (applySubstEq sub) --- Returns a new substitution with only those mappings from the given --- substitution whose variable is in the given list of variables. restrictSubst :: Subst f -> [VarIdx] -> Subst f restrictSubst sub vs = listToSubst [(v, t) | v <- vs, (Just t) <- [lookupSubst sub v]] --- Composes the first substitution `phi` with the second substitution --- `sigma`. The resulting substitution `sub` fulfills the property --- `sub(t) = phi(sigma(t))` for a term `t`. Mappings in the first --- substitution shadow those in the second. composeSubst :: Subst f -> Subst f -> Subst f composeSubst phi sigma = plusFM phi (mapFM (\_ t -> applySubst phi t) sigma) |