InfoCommands.hs revision e9458b1a7a19a63aa4c179f9ab20f4d50681c168
{-# LANGUAGE CPP, RankNTypes #-}
{- |
Module :./CMDL/InfoCommands.hs
Description : CMDL interface commands
Copyright : uni-bremen and DFKI
License : GPLv2 or higher, see LICENSE.txt
Maintainer : r.pascanu@jacobs-university.de
Stability : provisional
Portability : portable
CMDL.InfoCommands contains all commands
that provides information about the state
of the development graph and selected
theories
-}
module CMDL.InfoCommands
( cNodes
, cShowDgGoals
, cShowNodeProvenGoals
, cShowNodeUnprovenGoals
, cRedoHistory
, cCurrentComorphism
, cShowTaxonomy
, cShowTheory
, cShowTheoryGoals
, cUndoHistory
, cEdges
, cShowNodeAxioms
, cInfo
, cComorphismsTo
, cInfoCurrent
, cShowConcept
, cNodeNumber
, cHelp
) where
#ifdef UNI_PACKAGE
import GUI.Taxonomy
#endif
import CMDL.DataTypesUtils
import CMDL.DataTypes
import CMDL.Shell (nodeNames)
import CMDL.Utils
import Static.GTheory
import Static.DevGraph
import Static.PrintDevGraph (showLEdge)
import Common.AS_Annotation (SenAttr (isAxiom))
import Common.DocUtils (showDoc)
import Common.Taxonomy (TaxoGraphKind (..))
import Common.Utils (trim)
import qualified Common.OrderedMap as OMap
import Common.GraphAlgo (yen)
import Proofs.AbstractState (isSubElemG, pathToComorphism)
import Data.Graph.Inductive.Graph (LNode, LEdge, Node)
import Data.List
import Logic.Prover (SenStatus)
import Logic.Comorphism (AnyComorphism)
import Logic.Grothendieck (logicGraph2Graph)
import Comorphisms.LogicGraph (logicGraph)
import Interfaces.Command (cmdNameStr, describeCmd, showCmd)
import Interfaces.DataTypes
import Interfaces.Utils
-- show list of all goals(i.e. prints their name)
cShowDgGoals :: CmdlState -> IO CmdlState
cShowDgGoals state
= case i_state $ intState state of
-- nothing to print
Nothing -> return state
Just dgState -> let
-- list of all nodes
ls = getAllNodes dgState
-- compute list of node goals
nodeGoals = nodeNames $ filter (hasOpenGoals . snd) ls
-- list of all goal edge names
edgeGoals = map fst $ filter (edgeContainsGoals . snd)
$ createEdgeNames ls $ getAllEdges dgState
-- print sorted version of the list
in return $ genMessage [] (unlines $ sort (nodeGoals ++ edgeGoals)) state
{- local function that computes the theory of a node but it
keeps only the goal theory -}
getGoalThS :: CmdlUseTranslation -> Int -> CmdlState -> [String]
getGoalThS useTrans x state
= case getTh useTrans x state of
Nothing -> []
Just th ->
let nwth = case th of
G_theory x1 syn x2 x3 thSens x4 ->
G_theory x1 syn x2 x3
(OMap.filter (\ s -> not (isAxiom s) &&
not (isProvenSenStatus s))
thSens) x4
in [showDoc nwth "\n"]
{- local function that computes the theory of a node
that takes into consideration translated theories in
the selection too and returns the theory as a string -}
getThS :: CmdlUseTranslation -> Int -> CmdlState -> [String]
getThS useTrans x state =
case getTh useTrans x state of
Nothing -> ["Could not find a theory"]
Just th -> [showDoc th "\n"]
getInfoFromNodes :: String -> ([Node] -> [String]) -> CmdlState -> IO CmdlState
getInfoFromNodes input f state =
case i_state $ intState state of
Nothing -> return state
Just dgState -> let (errors, nodes) = getInputNodes input dgState
in return (if null nodes
then genMsgAndCode errors 1 state
else genMessage errors
(intercalate "\n" $ f nodes) state)
cShowFromNode :: (forall a . SenStatus a (AnyComorphism, BasicProof) -> Bool)
-- ^ what sentences to show
-> String -- input string containing node-names
-> CmdlState -- the state
-> IO CmdlState
cShowFromNode f input state =
getInfoFromNodes input (concatMap (\ n ->
case getTh Dont_translate n state of
Nothing -> []
Just th -> case th of
G_theory _ _ _ _ sens _ -> OMap.keys $
OMap.filter f sens)) state
cShowNodeProvenGoals :: String -> CmdlState -> IO CmdlState
cShowNodeProvenGoals =
cShowFromNode (\ s -> not (isAxiom s) && isProvenSenStatus s)
cShowNodeUnprovenGoals :: String -> CmdlState -> IO CmdlState
cShowNodeUnprovenGoals =
cShowFromNode (\ s -> not (isAxiom s) && not (isProvenSenStatus s))
cShowNodeAxioms :: String -> CmdlState -> IO CmdlState
cShowNodeAxioms = cShowFromNode isAxiom
-- show theory of input nodes
cShowTheory :: CmdlUseTranslation -> String -> CmdlState -> IO CmdlState
cShowTheory useTrans input state =
getInfoFromNodes input (concatMap (\ n -> getThS useTrans n state)) state
-- show theory of all goals
cShowTheoryGoals :: String -> CmdlState -> IO CmdlState
cShowTheoryGoals input st =
getInfoFromNodes input (concatMap (\ n -> getGoalThS Do_translate n st)) st
showNodeInfo :: LNode DGNodeLab -> String
showNodeInfo (i, l) =
(if isDGRef l
then ("reference " ++)
else if isInternalNode l then ("internal " ++) else id)
"node " ++ getDGNodeName l ++ " " ++ show i ++ "\n" ++ showDoc l ""
showEdgeInfo :: LEdge DGLinkLab -> String
showEdgeInfo e@(_, _, l) = showLEdge e ++ "\n" ++ showDoc l ""
-- show all information of selection
cInfoCurrent :: CmdlState -> IO CmdlState
cInfoCurrent state =
case i_state $ intState state of
-- nothing selected
Nothing -> return state
Just ps -> let (errors, nodes) = getSelectedDGNodes ps
in if null nodes
then return $ genMsgAndCode errors 1 state
else cInfo (unwords $ nodeNames nodes) state
cComorphismsTo :: String -> CmdlState -> IO CmdlState
cComorphismsTo input state =
case i_state $ intState state of
-- nothing selected
Nothing -> return state
Just ps -> case getCurrentSublogic ps of
Just start -> case parseSublogics input of
Just end ->
let cmors = yen 10 (start, Nothing)
(\ (l, _) -> isSubElemG l end)
(logicGraph2Graph logicGraph)
cmor = map (show . pathToComorphism) cmors
in return $ genMessage ""
(unlines cmor) state
Nothing -> return $ genMsgAndCode
("Invalid logic " ++ input) 1 state
Nothing -> return $ genMsgAndCode
"No node(s) selected!" 1 state
-- show all information of input
cInfo :: String -> CmdlState -> IO CmdlState
cInfo input state =
case i_state $ intState state of
-- error message
Nothing -> return $ genMsgAndCode "No library loaded" 1 state
Just dgS ->
let (nds, edg, nbEdg, errs) = decomposeIntoGoals input
tmpErrs = prettyPrintErrList errs
in case (nds, edg, nbEdg) of
([], [], []) -> return $ genMsgAndCode ("Nothing from the input "
++ "could be processed") 1 state
(_, _, _) ->
let lsNodes = getAllNodes dgS
lsEdges = getAllEdges dgS
(errs'', listEdges) = obtainEdgeList edg nbEdg lsNodes lsEdges
(errs', listNodes) = obtainNodeList nds lsNodes
strsNode = map showNodeInfo listNodes
strsEdge = map showEdgeInfo listEdges
tmpErrs' = tmpErrs ++ prettyPrintErrList errs'
tmpErrs'' = tmpErrs' ++ prettyPrintErrList errs''
in return $ genMessage tmpErrs''
(intercalate "\n\n" (strsNode ++ strsEdge)) state
taxoShowGeneric :: TaxoGraphKind -> CmdlState -> [LNode DGNodeLab] -> IO ()
#ifdef UNI_PACKAGE
taxoShowGeneric kind state ls =
case ls of
(nb, nlab) : ll ->
case i_state $ intState state of
Nothing -> return ()
Just _ ->
case getTh Do_translate nb state of
-- the theory was computed
Just th ->
do
-- display graph
displayGraph kind
(getDGNodeName nlab) th
taxoShowGeneric kind state ll
-- theory couldn't be computed so just go next
_ -> taxoShowGeneric kind state ll
_ -> return ()
#else
taxoShowGeneric _ _ _ = return ()
#endif
cShowTaxoGraph :: TaxoGraphKind -> String -> CmdlState -> IO CmdlState
cShowTaxoGraph kind input state =
case i_state $ intState state of
Nothing -> return state
Just dgState ->
do
let (errors, nodes) = getInputDGNodes input dgState
taxoShowGeneric kind state nodes
return $ genMessage errors [] state
cShowTaxonomy :: String -> CmdlState -> IO CmdlState
cShowTaxonomy = cShowTaxoGraph KSubsort
cShowConcept :: String -> CmdlState -> IO CmdlState
cShowConcept = cShowTaxoGraph KConcept
-- show node number of input
cNodeNumber :: String -> CmdlState -> IO CmdlState
cNodeNumber input state =
case i_state $ intState state of
Nothing -> return state
Just dgState ->
let (errors, nodes) = getInputDGNodes input dgState
ls = map (\ (i, n) -> getDGNodeName n ++ " is node number " ++
show i) nodes
in return $ genMessage errors (intercalate "\n" ls) state
-- print the name of all edges
cEdges :: CmdlState -> IO CmdlState
cEdges state
= case i_state $ intState state of
Nothing -> return state
Just dgState ->
do
-- list of all nodes
let lsNodes = getAllNodes dgState
-- compute all edges names
lsEdg = getAllEdges dgState
lsEdges = map fst $ createEdgeNames lsNodes lsEdg
-- print edge list in a sorted fashion
return $ genMessage [] (intercalate "\n" $ sort lsEdges) state
cUndoHistory :: CmdlState -> IO CmdlState
cUndoHistory = return . cHistory True
cRedoHistory :: CmdlState -> IO CmdlState
cRedoHistory = return . cHistory False
cCurrentComorphism :: CmdlState -> IO CmdlState
cCurrentComorphism st =
case i_state $ intState st of
Nothing -> return $ genMessage "" "No comorphism!" st
Just ist -> case cComorphism ist of
Just cmor -> return $ genMessage "" (show cmor) st
Nothing -> return $ genMessage "" "No comorphism!" st
cHistory :: Bool -> CmdlState -> CmdlState
cHistory isUndo state = genMessage []
(unlines $ ((if isUndo then "Un" else "Re") ++ "do history :")
: map (showCmd . command)
((if isUndo then undoList else redoList) $ i_hist $ intState state)
) state
-- print the name of all nodes
cNodes :: CmdlState -> IO CmdlState
cNodes state
= case i_state $ intState state of
-- no library loaded, so nothing to print
Nothing -> return state
Just dgState ->
do
-- compute the list of node names
let ls = nodeNames $ getAllNodes dgState
-- print a sorted version of it
return $ genMessage [] (intercalate "\n" $ sort ls) state
cHelp :: [CmdlCmdDescription] -> CmdlState -> IO CmdlState
cHelp allcmds state = do
putStrLn $ formatLine ("Command", "Parameter", "Description")
putStrLn $ replicate maxLineWidth '-'
mapM_ (\ cm -> do
let cmd = cmdDescription cm
name = cmdNameStr cmd
req = formatRequirement $ cmdReq cm
descL = formatDesc $ describeCmd cmd
desc = head descL ++
concatMap (('\n' : replicate descStart ' ') ++)
(tail descL)
putStrLn $ formatLine (name, req, desc)) allcmds
return state
where
maxLineWidth = 80
maxNameLen = maximum $ map (length . cmdNameStr . cmdDescription) allcmds
maxParamLen = maximum $ map (length . formatRequirement . cmdReq ) allcmds
descStart = maxNameLen + 1 + maxParamLen + 1
descWidth = maxLineWidth - descStart
formatDesc :: String -> [String]
formatDesc = reverse . filter (not . null) . map trim .
foldl (\ l w -> if length (head l) + length w > descWidth
then (w ++ " ") : l
else (head l ++ w ++ " ") : tail l)
[""] . words
formatLine :: (String, String, String) -> String
formatLine (c1, c2, c3) =
c1 ++ replicate (maxNameLen - length c1 + 1) ' ' ++
c2 ++ replicate (maxParamLen - length c2 + 1) ' ' ++ c3