glance/app/Translate.hs

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{-# LANGUAGE NoMonomorphismRestriction, FlexibleContexts, TypeFamilies #-}
module Translate(
translateStringToSyntaxGraph,
translateStringToCollapsedGraphAndDecl,
translateModuleToCollapsedGraphs
) where
import Diagrams.Prelude((<>))
import Data.Maybe(catMaybes)
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import Control.Monad(replicateM)
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import Control.Monad.State(State, evalState)
import Data.Either(partitionEithers)
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import Data.List(unzip5, unzip4, partition, intercalate)
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import qualified Language.Haskell.Exts as Exts
import Language.Haskell.Exts(Decl(..), parseDecl, Name(..), Pat(..), Rhs(..),
Exp(..), QName(..), fromParseResult, Match(..), QOp(..), GuardedRhs(..),
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Stmt(..), Binds(..), Alt(..), Module(..), SpecialCon(..), prettyPrint)
import qualified Data.Graph.Inductive.PatriciaTree as FGR
--import Data.Maybe(catMaybes)
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import GraphAlgorithms(collapseNodes)
import TranslateCore(Reference, SyntaxGraph(..), EvalContext, GraphAndRef, Sink,
syntaxGraphFromNodes, syntaxGraphFromNodesEdges, getUniqueName, combineExpressions,
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edgesForRefPortList, makeApplyGraph,
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namesInPattern, lookupReference, deleteBindings, makeEdges,
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makeBox, nTupleString, nListString,
syntaxGraphToFglGraph, getUniqueString)
import Types(NameAndPort(..), IDState,
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initialIdState, Edge, SyntaxNode(..), IngSyntaxGraph, NodeName, Port(..), SgNamedNode,
LikeApplyFlavor(..))
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import Util(makeSimpleEdge, nameAndPort, justName)
-- OVERVIEW --
-- The core functions and data types used in this module are in TranslateCore.
-- The TranslateCore also contains most/all of the translation functions that
-- do not use Language.Haskell.Exts.
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-- HELPER FUNCTIONS --
makeVarExp :: String -> Exp
makeVarExp = Var . UnQual . Ident
makeQVarOp :: String -> QOp
makeQVarOp = QVarOp . UnQual . Ident
-- END HELPER FUNCTIONS --
nameToString :: Language.Haskell.Exts.Name -> String
nameToString (Ident s) = s
nameToString (Symbol s) = s
qNameToString :: QName -> String
qNameToString (Qual (Exts.ModuleName modName) name) = modName ++ "." ++ nameToString name
qNameToString (UnQual name) = nameToString name
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qNameToString (Special UnitCon) = "()"
qNameToString (Special ListCon) = "[]"
qNameToString (Special FunCon) = "(->)"
qNameToString (Special (TupleCon _ n)) = nTupleString n
qNameToString (Special Cons) = "(:)"
-- unboxed singleton tuple constructor
qNameToString (Special UnboxedSingleCon) = "(# #)"
evalPApp :: QName -> [Pat] -> State IDState (SyntaxGraph, NameAndPort)
evalPApp name patterns = case patterns of
[] -> makeBox constructorName
_ -> do
patName <- getUniqueName "pat"
evaledPatterns <- mapM evalPattern patterns
pure $ makePatternGraph patName constructorName evaledPatterns (length evaledPatterns)
where
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constructorName = qNameToString name
evalPLit :: Exts.Sign -> Exts.Literal -> State IDState (SyntaxGraph, NameAndPort)
evalPLit Exts.Signless l = evalLit l
evalPLit Exts.Negative l = makeBox ('-' : showLiteral l)
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evalPAsPat :: Name -> Pat -> State IDState GraphAndRef
evalPAsPat n p = do
(evaledPatGraph, evaledPatRef) <- evalPattern p
let
newBind = [(nameToString n, evaledPatRef)]
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newGraph = SyntaxGraph mempty mempty mempty newBind mempty
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pure (newGraph <> evaledPatGraph, evaledPatRef)
evalPattern :: Pat -> State IDState GraphAndRef
evalPattern p = case p of
PVar n -> pure (mempty, Left $ nameToString n)
PLit s l -> fmap Right <$> evalPLit s l
PInfixApp p1 qName p2 -> evalPattern (PApp qName [p1, p2])
PApp name patterns -> fmap Right <$> evalPApp name patterns
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-- TODO special tuple handling.
PTuple _ patterns ->
fmap Right <$> evalPApp (Exts.UnQual . Ident . nTupleString . length $ patterns) patterns
PList patterns ->
fmap Right <$> evalPApp (Exts.UnQual . Ident . nListString . length $ patterns) patterns
PParen pat -> evalPattern pat
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PAsPat n subPat -> evalPAsPat n subPat
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PWildCard -> fmap Right <$> makeBox "_"
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_ -> error $ "evalPattern: No pattern in case for " ++ show p
-- TODO: Other cases
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-- strToGraphRef is not in TranslateCore, since it is only used by evalQName.
strToGraphRef :: EvalContext -> String -> State IDState (SyntaxGraph, Reference)
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strToGraphRef c str = fmap mapper (makeBox str) where
mapper gr = if str `elem` c
then (mempty, Left str)
else fmap Right gr
evalQName :: QName -> EvalContext -> State IDState (SyntaxGraph, Reference)
evalQName qName c = case qName of
UnQual _ -> graphRef
Qual _ _ -> graphRef
_ -> fmap Right <$> makeBox qNameString
where
qNameString = qNameToString qName
graphRef = strToGraphRef c qNameString
-- evalQOp :: QOp -> EvalContext -> State IDState (SyntaxGraph, Reference)
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-- evalQOp (QVarOp n) = evalQName n
-- evalQOp (QConOp n) = evalQName n
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-- qOpToString :: QOp -> String
-- qOpToString (QVarOp n) = qNameToString n
-- qOpToString (QConOp n) = qNameToString n
--findReferencedIcon :: Reference -> [(NodeName, Icon)] -> Maybe (Name, Icon)
-- findReferencedIcon :: Either t NameAndPort -> [(NodeName, t1)] -> Maybe (NodeName, t1)
-- findReferencedIcon (Left str) _ = Nothing
-- findReferencedIcon (Right (NameAndPort name _)) nameIconMap = (\x -> (name, x)) <$> lookup name nameIconMap
-- TODO Refactor decideIfNested and makePatternGraph
decideIfNested :: ((SyntaxGraph, t1), t) ->
(Maybe ((SyntaxGraph, t1), t), Maybe SgNamedNode, [Sink], [(String, Reference)], [(NodeName, NodeName)])
decideIfNested ((SyntaxGraph [nameAndIcon] [] sinks bindings eMap, _), _) = (Nothing, Just nameAndIcon, sinks, bindings, eMap)
decideIfNested valAndPort = (Just valAndPort, Nothing, [], [], [])
-- TODO Consider removing the Int numArgs parameter.
makePatternGraph :: NodeName -> String -> [(SyntaxGraph, Reference)] -> Int -> (SyntaxGraph, NameAndPort)
makePatternGraph applyIconName funStr argVals _ = nestedApplyResult
where
argumentPorts = map (nameAndPort applyIconName . Port) [2,3..]
(unnestedArgsAndPort, nestedArgs, nestedSinks, nestedBindings, nestedEMaps) = unzip5 $ fmap decideIfNested (zip argVals argumentPorts)
allSinks = mconcat nestedSinks
allBinds = mconcat nestedBindings
originalPortExpPairs = catMaybes unnestedArgsAndPort
portExpressionPairs = originalPortExpPairs
combinedGraph = combineExpressions True portExpressionPairs
icons = [(applyIconName, NestedPatternApplyNode funStr nestedArgs)]
newEMap = ((\(n, _) -> (n, applyIconName)) <$> catMaybes nestedArgs) <> mconcat nestedEMaps
newGraph = SyntaxGraph icons [] allSinks allBinds newEMap
nestedApplyResult = (newGraph <> combinedGraph, nameAndPort applyIconName (Port 1))
makePatternGraph' :: NodeName -> String -> [(SyntaxGraph, Reference)] -> Int -> (SyntaxGraph, NameAndPort)
makePatternGraph' applyIconName funStr argVals numArgs = (newGraph <> combinedGraph, nameAndPort applyIconName (Port 1))
where
argumentPorts = map (nameAndPort applyIconName . Port) [2,3..]
combinedGraph = combineExpressions True $ zip argVals argumentPorts
icons = [(applyIconName, PatternApplyNode funStr numArgs)]
newGraph = syntaxGraphFromNodes icons
removeCompose :: Exp -> Exp -> Exp
removeCompose f x = case removeParen f of
(InfixApp f1 (QVarOp (UnQual (Symbol "."))) f2) -> App f1 $ removeCompose f2 x
_ -> App f x
-- TODO Refactor this and all sub-expressions
evaluateAppExpression :: EvalContext -> Exp -> Exp -> State IDState (SyntaxGraph, NameAndPort)
evaluateAppExpression c f e = if appScore <= compScore
then evalApp c ApplyNodeFlavor (simplifyApp noComposeExp)
else evalApp c ComposeNodeFlavor (simplifyComposeApply noComposeExp)
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where
noComposeExp = removeCompose f e
(appScore, compScore) = applyComposeScore noComposeExp
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evalApp :: EvalContext -> LikeApplyFlavor -> (Exp, [Exp]) -> State IDState (SyntaxGraph, NameAndPort)
evalApp c flavor (funExp, argExps) = do
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funVal <- evalExp c funExp
argVals <- mapM (evalExp c) argExps
applyIconName <- getUniqueName "app0"
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pure $ makeApplyGraph flavor False applyIconName funVal argVals (length argExps)
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qOpToExp :: QOp -> Exp
qOpToExp (QVarOp n) = Var n
qOpToExp (QConOp n) = Con n
evalCompose :: EvalContext -> [Exp] -> State IDState (SyntaxGraph, NameAndPort)
evalCompose c functions = do
let reversedFunctios = reverse functions
evaluatedFunctions <- mapM (evalExp c) reversedFunctios
neverUsedPort <- Left <$> getUniqueString "unusedArgument"
applyIconName <- getUniqueName "compose"
pure $ makeApplyGraph ComposeNodeFlavor False applyIconName
(mempty, neverUsedPort) evaluatedFunctions (length evaluatedFunctions)
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simplifyCompose :: Exp -> [Exp]
simplifyCompose e = case removeParen e of
(InfixApp exp1 (QVarOp (UnQual (Symbol "."))) exp2) -> exp1 : simplifyCompose exp2
x -> [x]
evalInfixApp :: EvalContext -> Exp -> QOp -> Exp -> State IDState (SyntaxGraph, Reference)
evalInfixApp c e1 op e2 = case op of
QVarOp (UnQual (Symbol sym)) -> case sym of
"$" -> evalExp c (App e1 e2)
"." -> fmap Right <$> evalCompose c (e1 : simplifyCompose e2)
_ -> defaultCase
_ -> defaultCase
where
defaultCase = evalExp c $ App (App (qOpToExp op) e1) e2
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scoreExpressions :: Exp -> Exp -> (Int, Int)
scoreExpressions exp1 exp2 = (appScore, compScore) where
(e1App, e1Comp) = applyComposeScore exp1
(e2App, e2Comp) = applyComposeScore exp2
leftApp = min e1App (1 + e1Comp)
rightApp = 1 + min e2App e2Comp
appScore = max leftApp rightApp
leftComp = 1 + min e1App e1Comp
rightComp = min (1 + e2App) e2Comp
compScore = max leftComp rightComp
removeParen :: Exp -> Exp
removeParen e = case e of
Paren x -> removeParen x
x -> x
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simplifyExp :: Exp -> Exp
simplifyExp e = case removeParen e of
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InfixApp exp1 (QVarOp (UnQual (Symbol "$"))) exp2 -> App exp1 exp2
-- Don't convert compose to apply
InfixApp _ (QVarOp (UnQual (Symbol "."))) _ -> e
App (Var (UnQual (Symbol "<$>"))) arg -> App (makeVarExp "fmap") arg
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InfixApp exp1 op exp2 -> App (App (qOpToExp op) exp1) exp2
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LeftSection exp1 op -> App (qOpToExp op) exp1
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x -> x
-- TODO Consider putting this logic in a separate "simplifyExpression" function.
-- | Returns the amount of nesting if the App is converted to (applyNode, composeNode)
applyComposeScore :: Exp -> (Int, Int)
applyComposeScore e = case simplifyExp e of
App exp1 exp2 -> scoreExpressions exp1 exp2
_ -> (0, 0)
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-- Todo add test for this function
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simplifyApp :: Exp -> (Exp, [Exp])
simplifyApp e = case simplifyExp e of
App exp1 exp2 -> (funExp, args <> [exp2])
where
(funExp, args) = simplifyApp exp1
x -> (x, [])
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simplifyComposeApply :: Exp -> (Exp, [Exp])
simplifyComposeApply e = case simplifyExp e of
App exp1 exp2 -> (argExp, funcs <> [exp1])
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where
(argExp, funcs) = simplifyComposeApply exp2
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simpleExp -> (simpleExp, [])
evalIf :: EvalContext -> Exp -> Exp -> Exp -> State IDState (SyntaxGraph, NameAndPort)
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evalIf c e1 e2 e3 = do
e1Val <- evalExp c e1
e2Val <- evalExp c e2
e3Val <- evalExp c e3
guardName <- getUniqueName "if"
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let
icons = [(guardName, GuardNode 2)]
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combinedGraph =
combineExpressions False $ zip [e1Val, e2Val, e3Val] (map (nameAndPort guardName . Port) [3, 2, 4])
newGraph = syntaxGraphFromNodes icons <> combinedGraph
pure (newGraph, nameAndPort guardName (Port 0))
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evalStmt :: EvalContext -> Stmt -> State IDState GraphAndRef
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evalStmt c (Qualifier e) = evalExp c e
evalStmts :: EvalContext -> [Stmt] -> State IDState GraphAndRef
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evalStmts c [stmt] = evalStmt c stmt
evalGuaredRhs :: EvalContext -> GuardedRhs -> State IDState (GraphAndRef, GraphAndRef)
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evalGuaredRhs c (GuardedRhs _ stmts e) = do
expVal <- evalExp c e
stmtsVal <- evalStmts c stmts
pure (stmtsVal, expVal)
evalGuardedRhss :: EvalContext -> [GuardedRhs] -> State IDState (SyntaxGraph, NameAndPort)
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evalGuardedRhss c rhss = do
guardName <- getUniqueName "guard"
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evaledRhss <- mapM (evalGuaredRhs c) rhss
let
(bools, exps) = unzip evaledRhss
expsWithPorts = zip exps $ map (nameAndPort guardName . Port) [2,4..]
boolsWithPorts = zip bools $ map (nameAndPort guardName . Port) [3,5..]
combindedGraph = combineExpressions False $ expsWithPorts <> boolsWithPorts
icons = [(guardName, GuardNode (length rhss))]
newGraph = syntaxGraphFromNodes icons <> combindedGraph
pure (newGraph, nameAndPort guardName (Port 1))
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-- This is in Translate and not Translate core since currently it is only used by evalLit.
makeLiteral :: (Show x) => x -> State IDState (SyntaxGraph, NameAndPort)
makeLiteral = makeBox. show
evalLit :: Exts.Literal -> State IDState (SyntaxGraph, NameAndPort)
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evalLit (Exts.Int x) = makeLiteral x
evalLit (Exts.Char x) = makeLiteral x
evalLit (Exts.String x) = makeLiteral x
-- TODO: Print the Rational as a floating point.
evalLit (Exts.Frac x) = makeLiteral x
-- TODO: Test the unboxed literals
evalLit (Exts.PrimInt x) = makeLiteral x
evalLit (Exts.PrimWord x) = makeLiteral x
evalLit (Exts.PrimFloat x) = makeLiteral x
evalLit (Exts.PrimDouble x) = makeLiteral x
evalLit (Exts.PrimChar x) = makeLiteral x
evalLit (Exts.PrimString x) = makeLiteral x
showLiteral :: Exts.Literal -> String
showLiteral (Exts.Int x) = show x
showLiteral (Exts.Char x) = show x
showLiteral (Exts.String x) = show x
-- TODO: Print the Rational as a floating point.
showLiteral (Exts.Frac x) = show x
-- TODO: Test the unboxed literals
showLiteral (Exts.PrimInt x) = show x
showLiteral (Exts.PrimWord x) = show x
showLiteral (Exts.PrimFloat x) = show x
showLiteral (Exts.PrimDouble x) = show x
showLiteral (Exts.PrimChar x) = show x
showLiteral (Exts.PrimString x) = show x
getBoundVarName :: Decl -> [String]
-- TODO Should evalState be used here?
getBoundVarName (PatBind _ pat _ _) = namesInPattern $ evalState (evalPattern pat) initialIdState
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getBoundVarName (FunBind (Match _ name _ _ _ _:_)) = [nameToString name]
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-- TODO: Other cases
getBoundVarName (TypeSig _ _ _) = []
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getBoundVarName decl = error $ "getBoundVarName: No pattern in case for " ++ show decl
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--TODO: Should this call makeEdges?
evalBinds :: EvalContext -> Binds -> State IDState (SyntaxGraph, EvalContext)
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evalBinds c (BDecls decls) = do
let
boundNames = concatMap getBoundVarName decls
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augmentedContext = boundNames <> c
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evaledDecl <- mconcat <$> mapM (evalDecl augmentedContext) decls
pure (evaledDecl, augmentedContext)
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evalGeneralLet :: (EvalContext -> State IDState (SyntaxGraph, Reference)) -> EvalContext -> Binds -> State IDState (SyntaxGraph, Reference)
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evalGeneralLet expOrRhsEvaler c bs = do
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(bindGraph, bindContext) <- evalBinds c bs
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expVal <- expOrRhsEvaler bindContext
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let
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(expGraph, expResult) = expVal
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newGraph = deleteBindings . makeEdges $ expGraph <> bindGraph
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bindings = sgSources bindGraph
pure (newGraph, lookupReference bindings expResult)
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evalLet :: EvalContext -> Binds -> Exp -> State IDState (SyntaxGraph, Reference)
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evalLet context binds e = evalGeneralLet (`evalExp` e) context binds
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-- TODO: Refactor this with evalPatBind
evalPatAndRhs :: EvalContext -> Pat -> Rhs -> Maybe Binds -> State IDState (Bool, SyntaxGraph, Reference, Reference)
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evalPatAndRhs c pat rhs maybeWhereBinds = do
patternNames <- namesInPattern <$> evalPattern pat
let rhsContext = patternNames <> c
(rhsGraph, rhsRef) <- rhsWithBinds maybeWhereBinds rhs rhsContext
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(patGraph, patRef) <- evalPattern pat
let
grWithEdges = makeEdges (rhsGraph <> patGraph)
lookedUpRhsRef = lookupReference (sgSources grWithEdges) rhsRef
-- The pattern and rhs are conneted if makeEdges added extra edges, or if the rhsRef refers to a source
-- in the pattern
patRhsAreConnected = (rhsRef /= lookedUpRhsRef) ||
length (sgEdges grWithEdges) > (length (sgEdges rhsGraph) + length (sgEdges patGraph))
pure (patRhsAreConnected, deleteBindings grWithEdges, patRef, lookedUpRhsRef)
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-- returns (combined graph, pattern reference, rhs reference)
evalAlt :: EvalContext -> Exts.Alt -> State IDState (Bool, SyntaxGraph, Reference, Reference)
evalAlt c (Exts.Alt _ pat rhs maybeBinds) = evalPatAndRhs c pat rhs maybeBinds
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evalCase :: EvalContext -> Exp -> [Alt] -> State IDState (SyntaxGraph, NameAndPort)
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evalCase c e alts = do
evaledAlts <- mapM (evalAlt c) alts
(expGraph, expRef) <- evalExp c e
caseIconName <- getUniqueName "case"
let
(patRhsConnected, altGraphs, patRefs, rhsRefs) = unzip4 evaledAlts
combindedAltGraph = mconcat altGraphs
numAlts = length alts
icons = [(caseIconName, CaseNode numAlts)]
caseGraph = syntaxGraphFromNodes icons
expEdge = (expRef, nameAndPort caseIconName (Port 0))
patEdges = zip patRefs $ map (nameAndPort caseIconName . Port) [2,4..]
rhsEdges = zip patRhsConnected $ zip rhsRefs $ map (nameAndPort caseIconName . Port) [3,5..]
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(connectedRhss, unConnectedRhss) = partition fst rhsEdges
resultIconNames <- replicateM numAlts (getUniqueName "caseResult")
let
makeCaseResult :: NodeName -> Reference -> SyntaxGraph
makeCaseResult resultIconName rhsRef = case rhsRef of
Left _ -> mempty
Right rhsPort -> syntaxGraphFromNodesEdges rhsNewIcons rhsNewEdges
where
rhsNewIcons = [(resultIconName, CaseResultNode)]
rhsNewEdges = [makeSimpleEdge (rhsPort, justName resultIconName)]
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caseResultGraphs = mconcat $ zipWith makeCaseResult resultIconNames (fmap (fst . snd) connectedRhss)
filteredRhsEdges = fmap snd unConnectedRhss
patternEdgesGraph = edgesForRefPortList True patEdges
caseEdgeGraph = edgesForRefPortList False (expEdge : filteredRhsEdges)
finalGraph = mconcat [patternEdgesGraph, caseResultGraphs, expGraph, caseEdgeGraph, caseGraph, combindedAltGraph]
pure (finalGraph, nameAndPort caseIconName (Port 1))
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evalTuple :: EvalContext -> [Exp] -> State IDState (SyntaxGraph, NameAndPort)
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evalTuple c exps = do
argVals <- mapM (evalExp c) exps
funVal <- makeBox $ nTupleString (length exps)
applyIconName <- getUniqueName "tupleApp"
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pure $ makeApplyGraph ApplyNodeFlavor False applyIconName (fmap Right funVal) argVals (length exps)
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evalListExp :: EvalContext -> [Exp] -> State IDState (SyntaxGraph, NameAndPort)
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evalListExp _ [] = makeBox "[]"
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evalListExp c exps = evalApp c ApplyNodeFlavor (makeVarExp . nListString . length $ exps, exps)
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evalLeftSection :: EvalContext -> Exp -> QOp -> State IDState (SyntaxGraph, Reference)
evalLeftSection c e op = evalExp c $ App (qOpToExp op) e
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evalRightSection :: EvalContext -> QOp -> Exp -> State IDState (SyntaxGraph, NameAndPort)
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evalRightSection c op e = do
expVal <- evalExp c e
funVal <- evalExp c (qOpToExp op)
applyIconName <- getUniqueName "tupleApp"
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-- TODO: A better option would be for makeApplyGraph to take the list of expressions as Maybes.
neverUsedPort <- Left <$> getUniqueString "unusedArgument"
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pure $ makeApplyGraph ApplyNodeFlavor False applyIconName funVal [(mempty, neverUsedPort), expVal] 2
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-- evalEnums is only used by evalExp
evalEnums :: EvalContext -> String -> [Exp] -> State IDState (SyntaxGraph, Reference)
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evalEnums c s exps = fmap Right <$> evalApp c ApplyNodeFlavor (makeVarExp s, exps)
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desugarDo :: [Stmt] -> Exp
desugarDo [Qualifier e] = e
desugarDo (Qualifier e : stmts) = InfixApp e thenOp (desugarDo stmts)
where thenOp = makeQVarOp ">>"
desugarDo (Generator srcLoc pat e : stmts) =
InfixApp e (makeQVarOp ">>=") (Lambda srcLoc [pat] (desugarDo stmts))
desugarDo (LetStmt binds : stmts) = Let binds (desugarDo stmts)
-- TODO: Finish evalRecConstr
evalRecConstr :: EvalContext -> QName -> [Exts.FieldUpdate] -> State IDState (SyntaxGraph, Reference)
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evalRecConstr c qName _ = evalQName qName c
evalExp :: EvalContext -> Exp -> State IDState (SyntaxGraph, Reference)
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evalExp c x = case x of
Var n -> evalQName n c
Con n -> evalQName n c
Lit l -> fmap Right <$> evalLit l
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InfixApp e1 op e2 -> evalInfixApp c e1 op e2
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App f arg -> fmap Right <$> evaluateAppExpression c f arg
NegApp e -> evalExp c (App (makeVarExp "negate") e)
Lambda _ patterns e -> fmap Right <$> evalLambda c patterns e
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Let bs e -> evalLet c bs e
If e1 e2 e3 -> fmap Right <$> evalIf c e1 e2 e3
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Case e alts -> fmap Right <$> evalCase c e alts
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Do stmts -> evalExp c (desugarDo stmts)
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-- TODO special tuple symbol
Tuple _ exps -> fmap Right <$> evalTuple c exps
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List exps -> fmap Right <$> evalListExp c exps
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Paren e -> evalExp c e
LeftSection e op -> evalLeftSection c e op
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RightSection op e -> fmap Right <$> evalRightSection c op e
RecConstr n updates -> evalRecConstr c n updates
-- TODO: Do RecUpdate correcly
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RecUpdate e _ -> evalExp c e
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EnumFrom e -> evalEnums c "enumFrom" [e]
EnumFromTo e1 e2 -> evalEnums c "enumFromTo" [e1, e2]
EnumFromThen e1 e2 -> evalEnums c "enumFromThen" [e1, e2]
EnumFromThenTo e1 e2 e3 -> evalEnums c "enumFromThenTo" [e1, e2, e3]
-- TODO: Add the type signiture to ExpTypeSig.
ExpTypeSig _ e _ -> evalExp c e
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-- TODO: Add other cases
_ -> error $ "evalExp: No pattern in case for " ++ show x
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-- | First argument is the right hand side.
-- The second arugement is a list of strings that are bound in the environment.
evalRhs :: EvalContext -> Rhs -> State IDState (SyntaxGraph, Reference)
evalRhs c (UnGuardedRhs e) = evalExp c e
evalRhs c (GuardedRhss rhss) = fmap Right <$> evalGuardedRhss c rhss
rhsWithBinds :: Maybe Binds -> Rhs -> EvalContext -> State IDState (SyntaxGraph, Reference)
rhsWithBinds maybeWhereBinds rhs rhsContext = case maybeWhereBinds of
Nothing -> evalRhs rhsContext rhs
Just b -> evalGeneralLet (`evalRhs` rhs) rhsContext b
evalPatBind :: EvalContext -> Decl -> State IDState SyntaxGraph
evalPatBind c (PatBind _ pat rhs maybeWhereBinds) = do
patternNames <- namesInPattern <$> evalPattern pat
let rhsContext = patternNames <> c
(rhsGraph, rhsRef) <- rhsWithBinds maybeWhereBinds rhs rhsContext
(patGraph, patRef) <- evalPattern pat
let
(newEdges, newSinks, bindings) = case patRef of
(Left s) -> (mempty, mempty, [(s, rhsRef)])
(Right patPort) -> case rhsRef of
-- TODO This edge/sink should have a special arrow head to indicate an input to a pattern.
(Left rhsStr) -> (mempty, [(rhsStr, patPort)], mempty)
(Right rhsPort) -> ([makeSimpleEdge (rhsPort, patPort)], mempty, mempty)
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gr = SyntaxGraph mempty newEdges newSinks bindings mempty
pure . makeEdges $ (gr <> rhsGraph <> patGraph)
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generalEvalLambda :: EvalContext -> [Pat] -> (EvalContext -> State IDState GraphAndRef) -> State IDState (SyntaxGraph, NameAndPort)
generalEvalLambda context patterns rhsEvalFun = do
lambdaName <- getUniqueName "lam"
patternVals <- mapM evalPattern patterns
let
patternStrings = concatMap namesInPattern patternVals
rhsContext = patternStrings <> context
lambdaPorts = map (nameAndPort lambdaName . Port) [2,3..]
patternGraph = mconcat $ map fst patternVals
(patternEdges, newBinds) =
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partitionEithers $ zipWith makePatternEdges patternVals lambdaPorts
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(rhsRawGraph, rhsRef) <- rhsEvalFun rhsContext
let
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icons = [(lambdaName, FunctionDefNode (length patterns))]
returnPort = nameAndPort lambdaName (Port 0)
(newEdges, newSinks) = case rhsRef of
Left s -> (patternEdges, [(s, returnPort)])
Right rhsPort -> (makeSimpleEdge (rhsPort, returnPort) : patternEdges, mempty)
finalGraph = SyntaxGraph icons newEdges newSinks newBinds mempty
pure (deleteBindings . makeEdges $ (rhsRawGraph <> patternGraph <> finalGraph), nameAndPort lambdaName (Port 1))
where
-- TODO Like evalPatBind, this edge should have an indicator that it is the input to a pattern.
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-- makePatternEdges creates the edges between the patterns and the parameter ports.
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makePatternEdges :: GraphAndRef -> NameAndPort -> Either Edge (String, Reference)
makePatternEdges (_, Right patPort) lamPort =
Left $ makeSimpleEdge (lamPort, patPort)
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makePatternEdges (_, Left str) lamPort = Right (str, Right lamPort)
evalLambda :: EvalContext -> [Pat] -> Exp -> State IDState (SyntaxGraph, NameAndPort)
evalLambda c patterns e = generalEvalLambda c patterns (`evalExp` e)
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evalMatch :: EvalContext -> Match -> State IDState SyntaxGraph
evalMatch c (Match _ name patterns _ rhs maybeWhereBinds) = do
let
matchFunNameString = nameToString name
newContext = matchFunNameString : c
(lambdaGraph, lambdaPort) <-
generalEvalLambda newContext patterns (rhsWithBinds maybeWhereBinds rhs)
let
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newBinding = SyntaxGraph mempty mempty mempty [(matchFunNameString, Right lambdaPort)] mempty
pure $ makeEdges (newBinding <> lambdaGraph)
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-- Only used by matchesToCase
matchToAlt :: Match -> Alt
matchToAlt (Match srcLocation _ mtaPats _ rhs binds) = Alt srcLocation altPattern rhs binds where
altPattern = case mtaPats of
[onePat] -> onePat
_ -> PTuple Exts.Boxed mtaPats
matchesToCase :: Match -> [Match] -> State IDState Match
matchesToCase match [] = pure match
matchesToCase firstMatch@(Match srcLoc funName pats mType _ _) restOfMatches = do
tempStrings <- replicateM (length pats) (getUniqueString "_tempvar")
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let
tempPats = fmap (PVar . Ident) tempStrings
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tempVars = fmap makeVarExp tempStrings
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tuple = Tuple Exts.Boxed tempVars
caseExp = case tempVars of
[oneTempVar] -> Case oneTempVar alts
_ -> Case tuple alts
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rhs = UnGuardedRhs caseExp
match = Match srcLoc funName tempPats mType rhs Nothing
pure match
where
allMatches = firstMatch:restOfMatches
alts = fmap matchToAlt allMatches
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evalMatches :: EvalContext -> [Match] -> State IDState SyntaxGraph
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evalMatches _ [] = pure mempty
evalMatches c (firstMatch:restOfMatches) = matchesToCase firstMatch restOfMatches >>= evalMatch c
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-- Pretty printing the entire type sig results in extra whitespace in the middle
-- TODO May want to trim whitespace from (prettyPrint typeForNames)
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evalTypeSig :: Decl -> State IDState (SyntaxGraph, NameAndPort)
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evalTypeSig (TypeSig _ names typeForNames) = makeBox
(intercalate "," (fmap prettyPrint names)
++ " :: "
++ prettyPrint typeForNames)
evalDecl :: EvalContext -> Decl -> State IDState SyntaxGraph
evalDecl c d = case d of
PatBind _ _ _ _ -> evalPatBind c d
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FunBind matches -> evalMatches c matches
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TypeSig _ _ _ -> fst <$> evalTypeSig d
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--TODO: Add other cases here
_ -> pure mempty
showTopLevelBinds :: SyntaxGraph -> State IDState SyntaxGraph
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showTopLevelBinds gr = do
let
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binds = sgSources gr
addBind (_, Left _) = pure mempty
addBind (patName, Right port) = do
uniquePatName <- getUniqueName patName
let
icons = [(uniquePatName, BindNameNode patName)]
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edges = [makeSimpleEdge (port, justName uniquePatName)]
edgeGraph = syntaxGraphFromNodesEdges icons edges
pure edgeGraph
newGraph <- mconcat <$> mapM addBind binds
pure $ newGraph <> gr
translateDeclToSyntaxGraph :: Decl -> SyntaxGraph
translateDeclToSyntaxGraph d = graph where
evaluatedDecl = evalDecl mempty d >>= showTopLevelBinds
graph = evalState evaluatedDecl initialIdState
-- | Convert a single function declaration into a SyntaxGraph
translateStringToSyntaxGraph :: String -> SyntaxGraph
translateStringToSyntaxGraph = translateDeclToSyntaxGraph . fromParseResult . parseDecl
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syntaxGraphToCollapsedGraph :: SyntaxGraph -> IngSyntaxGraph FGR.Gr
syntaxGraphToCollapsedGraph = collapseNodes . syntaxGraphToFglGraph
translateDeclToCollapsedGraph :: Decl -> IngSyntaxGraph FGR.Gr
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translateDeclToCollapsedGraph = syntaxGraphToCollapsedGraph . translateDeclToSyntaxGraph
-- Profiling: about 1.5% of total time.
translateStringToCollapsedGraphAndDecl :: String -> (IngSyntaxGraph FGR.Gr, Decl)
translateStringToCollapsedGraphAndDecl s = (drawing, decl) where
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decl = fromParseResult (parseDecl s) -- :: ParseResult Module
drawing = translateDeclToCollapsedGraph decl
-- TODO Put the type declarations in a box below the image.
translateModuleToCollapsedGraphs :: Module -> [IngSyntaxGraph FGR.Gr]
translateModuleToCollapsedGraphs (Module _ _ _ _ _ _ decls) = fmap translateDeclToCollapsedGraph decls