-------------------------------------------------------------------------------- -- See end of this file for licence information. -------------------------------------------------------------------------------- -- | -- Module : Proof -- Copyright : (c) 2003, Graham Klyne, 2009 Vasili I Galchin, 2011 Douglas Burke -- License : GPL V2 -- -- Maintainer : Douglas Burke -- Stability : experimental -- Portability : H98 -- -- This module defines a framework for constructing proofs -- over some expression form. It is intended to be used -- with RDF graphs, but the structures aim to be quite -- generic with respect to the expression forms allowed. -- -- It does not define any proof-finding strategy. -- -------------------------------------------------------------------------------- module Swish.Proof ( Proof(..), Step(..) , checkProof, explainProof, checkStep, showProof, showsProof, showsFormula ) where import Swish.Rule (Expression(..), Formula(..), Rule(..)) import Swish.Rule (showsFormula, showsFormulae) import Swish.Ruleset (Ruleset(..)) import Swish.Utils.ListHelpers (subset) import Data.List (union, intersect, intercalate, foldl') import Data.Maybe (catMaybes, isNothing) import Data.String.ShowLines (ShowLines(..)) ------------------------------------------------------------ -- Proof framework ------------------------------------------------------------ -- |Step in proof chain -- -- The display name for a proof step comes from the display name of its -- consequence formula. data Step ex = Step { stepRule :: Rule ex -- ^ Inference rule used , stepAnt :: [Formula ex] -- ^ Antecedents of inference rule , stepCon :: Formula ex -- ^ Named consequence of inference rule } deriving Show -- |Proof is a structure that presents a chain of rule applications -- that yield a result expression from a given expression data Proof ex = Proof { proofContext :: [Ruleset ex] -- ^ Proof context: list of rulesets, -- each of which provides a number of -- axioms and rules. , proofInput :: Formula ex -- ^ Given expression , proofResult :: Formula ex -- ^ Result expression , proofChain :: [Step ex] -- ^ Chain of inference rule applications -- progressing from input to result } -- |Return a list of axioms from all the rulesets in a proof proofAxioms :: Proof a -> [Formula a] proofAxioms = concatMap rsAxioms . proofContext -- |Return a list of rules from all the rulesets in a proof proofRules :: Proof a -> [Rule a] proofRules = concatMap rsRules . proofContext -- |Return list of axioms actually referenced by a proof proofAxiomsUsed :: Proof ex -> [Formula ex] proofAxiomsUsed proof = foldl' union [] $ map stepAxioms (proofChain proof) where stepAxioms st = stepAnt st `intersect` proofAxioms proof -- |Check consistency of given proof. -- The supplied rules and axioms are assumed to be correct. checkProof :: (Expression ex) => Proof ex -> Bool checkProof pr = checkProof1 (proofRules pr) initExpr (proofChain pr) goalExpr where initExpr = formExpr (proofInput pr) : map formExpr (proofAxioms pr) goalExpr = formExpr $ proofResult pr checkProof1 :: (Expression ex) => [Rule ex] -> [ex] -> [Step ex] -> ex -> Bool checkProof1 _ prev [] res = res `elem` prev checkProof1 rules prev (st:steps) res = checkStep rules prev st && checkProof1 rules (formExpr (stepCon st):prev) steps res -- | A proof step is valid if rule is in list of rules -- and the antecedents are sufficient to obtain the conclusion -- and the antecedents are in the list of formulae already proven. -- -- Note: this function depends on the ruleName of any rule being -- unique among all rules. In particular the name of the step rule -- being in correspondence with the name of one of the indicated -- valid rules of inference. checkStep :: (Expression ex) => [Rule ex] -- ^ rules -> [ex] -- ^ antecedants -> Step ex -- ^ the step to validate -> Bool -- ^ @True@ if the step is valid checkStep rules prev step = isNothing $ explainStep rules prev step {- Is the following an optimisation of the above? checkStep rules prev step = -- Rule name is one of supplied rules, and (ruleName srul `elem` map ruleName rules) && -- Antecedent expressions are all previously accepted expressions (sant `subset` prev) && -- Inference rule yields concequence from antecendents checkInference srul sant scon where -- Rule from proof step: srul = stepRule step -- Antecedent expressions from proof step: sant = map formExpr $ stepAnt step -- Consequentent expression from proof step: scon = formExpr $ stepCon step -} {- (formExpr (stepCon step) `elem` sfwd) -- (or $ map (`subset` sant) sbwd) where -- Rule from proof step: srul = stepRule step -- Antecedent expressions from proof step: sant = map formExpr $ stepAnt step -- Forward chaining from antecedents of proof step scon = map formExpr $ stepCon step -- Forward chaining from antecedents of proof step sfwd = fwdApply srul sant -- Backward chaining from consequent of proof step -- (Does not work because of introduction of existentials) sbwd = bwdApply srul (formExpr $ stepCon step) -} -- |Check proof. If there is an error then return information -- about the failing step. explainProof :: (Expression ex) => Proof ex -> Maybe String explainProof pr = explainProof1 (proofRules pr) initExpr (proofChain pr) goalExpr where initExpr = formExpr (proofInput pr) : map formExpr (proofAxioms pr) goalExpr = formExpr $ proofResult pr explainProof1 :: (Expression ex) => [Rule ex] -> [ex] -> [Step ex] -> ex -> Maybe String explainProof1 _ prev [] res = if res `elem` prev then Nothing else Just "Result not demonstrated" explainProof1 rules prev (st:steps) res = case explainStep rules prev st of Nothing -> explainProof1 rules (formExpr (stepCon st):prev) steps res Just ex -> Just ("Invalid step: "++show (formName $ stepCon st)++": "++ex) -- | A proof step is valid if rule is in list of rules -- and the antecedents are sufficient to obtain the conclusion -- and the antecedents are in the list of formulae already proven. -- -- Note: this function depends on the ruleName of any rule being -- unique among all rules. In particular the name of the step rule -- being in correspondence with the name of one of the indicated -- valid rules of inference. -- explainStep :: (Expression ex) => [Rule ex] -- ^ rules -> [ex] -- ^ previous -> Step ex -- ^ step -> Maybe String -- ^ @Nothing@ if step is okay, otherwise a string indicating the error explainStep rules prev step = if null errors then Nothing else Just $ intercalate ", " errors where -- Rule from proof step: srul = stepRule step -- Antecedent expressions from proof step: sant = map formExpr $ stepAnt step -- Consequentent expression from proof step: scon = formExpr $ stepCon step -- Tests for step to be valid errors = catMaybes -- Rule name is one of supplied rules, and [ require (ruleName srul `elem` map ruleName rules) ("rule "++show (ruleName srul)++" not present") -- Antecedent expressions are all previously accepted expressions , require (sant `subset` prev) "antecedent not axiom or previous result" -- Inference rule yields consequence from antecedents , require (checkInference srul sant scon) "rule does not deduce consequence from antecedents" ] require b s = if b then Nothing else Just s -- |Create a displayable form of a proof, returned as a `ShowS` value. -- -- This function is intended to allow the calling function some control -- of multiline displays by providing: -- -- (1) the first line of the proof is not preceded by any text, so -- it may be appended to some preceding text on the same line, -- -- (2) the supplied newline string is used to separate lines of the -- formatted text, and may include any desired indentation, and -- -- (3) no newline is output following the final line of text. showsProof :: (ShowLines ex) => String -- ^ newline string -> Proof ex -> ShowS showsProof newline proof = if null axioms then shProof else shAxioms . shProof where axioms = proofAxiomsUsed proof shAxioms = showString ("Axioms:" ++ newline) . showsFormulae newline (proofAxiomsUsed proof) newline shProof = showString ("Input:" ++ newline) . showsFormula newline (proofInput proof) . showString (newline ++ "Proof:" ++ newline) . showsSteps newline (proofChain proof) -- |Returns a simple string representation of a proof. showProof :: (ShowLines ex) => String -- ^ newline string -> Proof ex -> String showProof newline proof = showsProof newline proof "" -- |Create a displayable form of a list of labelled proof steps showsSteps :: (ShowLines ex) => String -> [Step ex] -> ShowS showsSteps _ [] = id showsSteps newline [s] = showsStep newline s showsSteps newline (s:ss) = showsStep newline s . showString newline . showsSteps newline ss -- |Create a displayable form of a labelled proof step. showsStep :: (ShowLines ex) => String -> Step ex -> ShowS showsStep newline s = showsFormula newline (stepCon s) . showString newline . showString (" (by ["++rulename++"] from "++antnames++")") where rulename = show . ruleName $ stepRule s antnames = showNames $ map (show . formName) (stepAnt s) -- |Return a string containing a list of names. showNames :: [String] -> String showNames [] = "<nothing>" showNames [n] = showName n showNames [n1,n2] = showName n1 ++ " and " ++ showName n2 showNames (n1:ns) = showName n1 ++ ", " ++ showNames ns -- |Return a string representing a single name. showName :: String -> String showName n = "["++n++"]" -------------------------------------------------------------------------------- -- -- Copyright (c) 2003, Graham Klyne, 2009 Vasili I Galchin, 2011 Douglas Burke -- All rights reserved. -- -- This file is part of Swish. -- -- Swish is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- Swish is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with Swish; if not, write to: -- The Free Software Foundation, Inc., -- 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA -- --------------------------------------------------------------------------------