module Agda.TypeChecking.Pretty where
import Prelude hiding (null)
import Control.Applicative hiding (empty)
import Control.Monad
import qualified Data.Map as Map
import Data.Maybe
import Agda.Syntax.Position
import Agda.Syntax.Common
import Agda.Syntax.Internal
import Agda.Syntax.Literal
import Agda.Syntax.Translation.InternalToAbstract
import Agda.Syntax.Translation.ReflectedToAbstract
import Agda.Syntax.Translation.AbstractToConcrete
import qualified Agda.Syntax.Translation.ReflectedToAbstract as R
import qualified Agda.Syntax.Reflected as R
import qualified Agda.Syntax.Abstract as A
import qualified Agda.Syntax.Concrete as C
import qualified Agda.Syntax.Reflected as R
import qualified Agda.Syntax.Abstract.Pretty as AP
import Agda.Syntax.Concrete.Pretty (bracesAndSemicolons)
import qualified Agda.Syntax.Concrete.Pretty as CP
import qualified Agda.Syntax.Info as A
import Agda.TypeChecking.Monad
import Agda.TypeChecking.Monad.Builtin (equalityUnview)
import Agda.TypeChecking.Positivity.Occurrence
import Agda.TypeChecking.Substitute
import Agda.Utils.Graph.AdjacencyMap.Unidirectional (Graph)
import qualified Agda.Utils.Graph.AdjacencyMap.Unidirectional as Graph
import Agda.Utils.Maybe
import Agda.Utils.Null
import Agda.Utils.Permutation (Permutation)
import qualified Agda.Utils.Pretty as P
#include "undefined.h"
import Agda.Utils.Impossible
type Doc = P.Doc
comma, colon, equals :: TCM Doc
comma = return P.comma
colon = return P.colon
equals = return P.equals
pretty :: P.Pretty a => a -> TCM Doc
pretty x = return $ P.pretty x
prettyA :: (P.Pretty c, ToConcrete a c) => a -> TCM Doc
prettyA x = AP.prettyA x
prettyAs :: (P.Pretty c, ToConcrete a [c]) => a -> TCM Doc
prettyAs x = AP.prettyAs x
text :: String -> TCM Doc
text s = return $ P.text s
pwords :: String -> [TCM Doc]
pwords s = map return $ P.pwords s
fwords :: String -> TCM Doc
fwords s = return $ P.fwords s
sep, fsep, hsep, hcat, vcat :: [TCM Doc] -> TCM Doc
sep ds = P.sep <$> sequence ds
fsep ds = P.fsep <$> sequence ds
hsep ds = P.hsep <$> sequence ds
hcat ds = P.hcat <$> sequence ds
vcat ds = P.vcat <$> sequence ds
($$), ($+$), (<>), (<+>) :: TCM Doc -> TCM Doc -> TCM Doc
d1 $$ d2 = (P.$$) <$> d1 <*> d2
d1 $+$ d2 = (P.$+$) <$> d1 <*> d2
d1 <> d2 = (P.<>) <$> d1 <*> d2
d1 <+> d2 = (P.<+>) <$> d1 <*> d2
nest :: Int -> TCM Doc -> TCM Doc
nest n d = P.nest n <$> d
braces, dbraces, brackets, parens :: TCM Doc -> TCM Doc
braces d = P.braces <$> d
dbraces d = CP.dbraces <$> d
brackets d = P.brackets <$> d
parens d = P.parens <$> d
prettyList :: [TCM Doc] -> TCM Doc
prettyList ds = brackets $ fsep $ punctuate comma ds
prettyList_ :: [TCM Doc] -> TCM Doc
prettyList_ ds = fsep $ punctuate comma ds
punctuate :: TCM Doc -> [TCM Doc] -> [TCM Doc]
punctuate _ [] = []
punctuate d ds = zipWith (<>) ds (replicate n d ++ [empty])
where
n = length ds 1
class PrettyTCM a where
prettyTCM :: a -> TCM Doc
instance PrettyTCM Bool where prettyTCM = pretty
instance PrettyTCM C.Name where prettyTCM = pretty
instance PrettyTCM C.QName where prettyTCM = pretty
instance PrettyTCM Comparison where prettyTCM = pretty
instance PrettyTCM Literal where prettyTCM = pretty
instance PrettyTCM Nat where prettyTCM = pretty
instance PrettyTCM ProblemId where prettyTCM = pretty
instance PrettyTCM Range where prettyTCM = pretty
instance PrettyTCM a => PrettyTCM (Closure a) where
prettyTCM cl = enterClosure cl prettyTCM
instance PrettyTCM a => PrettyTCM [a] where
prettyTCM = prettyList . map prettyTCM
instance (PrettyTCM a, PrettyTCM b) => PrettyTCM (a,b) where
prettyTCM (a, b) = parens $ prettyTCM a <> comma <> prettyTCM b
instance (PrettyTCM a, PrettyTCM b, PrettyTCM c) => PrettyTCM (a,b,c) where
prettyTCM (a, b, c) = parens $
prettyTCM a <> comma <> prettyTCM b <> comma <> prettyTCM c
instance PrettyTCM Term where prettyTCM = prettyA <=< reify
instance PrettyTCM Type where prettyTCM = prettyA <=< reify
instance PrettyTCM Sort where prettyTCM = prettyA <=< reify
instance PrettyTCM DisplayTerm where prettyTCM = prettyA <=< reify
instance PrettyTCM NamedClause where prettyTCM = prettyA <=< reify
instance PrettyTCM Level where prettyTCM = prettyA <=< reify . Level
instance PrettyTCM Permutation where prettyTCM = text . show
instance PrettyTCM Polarity where prettyTCM = text . show
instance PrettyTCM R.Term where prettyTCM = prettyA <=< toAbstractWithoutImplicit
instance (Show a, PrettyTCM a, Subst a a) => PrettyTCM (Substitution' a) where
prettyTCM IdS = text "idS"
prettyTCM (Wk m IdS) = text "wkS" <+> pretty m
prettyTCM EmptyS = text "emptyS"
prettyTCM rho = prettyTCM u <+> comma <+> prettyTCM rho1
where
(rho1, rho2) = splitS 1 rho
u = lookupS rho2 0
instance PrettyTCM Clause where
prettyTCM cl = do
x <- qualify_ <$> freshName_ "<unnamedclause>"
prettyTCM (QNamed x cl)
instance PrettyTCM ClauseBody where
prettyTCM b = do
(binds, body) <- walk b
sep [ brackets (fsep binds), return body ]
where
walk NoBody = return ([], P.text "()")
walk (Body v) = ([],) <$> prettyTCM v
walk (Bind b) = do
(bs, v) <- underAbstraction_ b walk
return (text (argNameToString $ absName b) : bs, v)
instance PrettyTCM a => PrettyTCM (Judgement a) where
prettyTCM (HasType a t) = prettyTCM a <+> text ":" <+> prettyTCM t
prettyTCM (IsSort a t) = text "Sort" <+> prettyTCM a <+> text ":" <+> prettyTCM t
instance PrettyTCM MetaId where
prettyTCM x = do
mn <- getMetaNameSuggestion x
pretty $ NamedMeta mn x
instance PrettyTCM a => PrettyTCM (Blocked a) where
prettyTCM (Blocked x a) = text "[" <+> prettyTCM a <+> text "]" <> text (show x)
prettyTCM (NotBlocked _ x) = prettyTCM x
instance (Reify a e, ToConcrete e c, P.Pretty c) => PrettyTCM (Named_ a) where
prettyTCM x = prettyA =<< reify x
instance (Reify a e, ToConcrete e c, P.Pretty c) => PrettyTCM (Arg a) where
prettyTCM x = prettyA =<< reify x
instance (Reify a e, ToConcrete e c, P.Pretty c) => PrettyTCM (Dom a) where
prettyTCM x = prettyA =<< reify x
instance PrettyTCM Elim where
prettyTCM (Apply v) = text "$" <+> prettyTCM v
prettyTCM (Proj f) = text "." <> prettyTCM f
instance PrettyTCM a => PrettyTCM (MaybeReduced a) where
prettyTCM = prettyTCM . ignoreReduced
instance PrettyTCM EqualityView where
prettyTCM v = prettyTCM $ equalityUnview v
instance PrettyTCM A.Expr where
prettyTCM = prettyA
instance PrettyTCM Relevance where
prettyTCM Irrelevant = text "."
prettyTCM NonStrict = text ".."
prettyTCM Relevant = empty
prettyTCM Forced{} = empty
prettyTCM UnusedArg = empty
instance PrettyTCM ProblemConstraint where
prettyTCM (PConstr pid c) = prettyList (map prettyTCM pid) <+> prettyTCM c
instance PrettyTCM Constraint where
prettyTCM c = case c of
ValueCmp cmp ty s t ->
sep [ sep [ prettyTCM s
, prettyTCM cmp <+> prettyTCM t
]
, nest 2 $ text ":" <+> prettyTCM ty
]
ElimCmp cmps t v us vs ->
sep [ sep [ prettyTCM us
, nest 2 $ text "~~" <+> prettyTCM vs
]
, text ":" <+> prettyTCM t ]
LevelCmp cmp a b ->
sep [ prettyTCM a
, prettyTCM cmp <+> prettyTCM b
]
TypeCmp cmp a b ->
sep [ prettyTCM a
, prettyTCM cmp <+> prettyTCM b
]
TelCmp a b cmp tela telb ->
sep [ prettyTCM tela
, prettyTCM cmp <+> prettyTCM telb
]
SortCmp cmp s1 s2 ->
sep [ prettyTCM s1
, prettyTCM cmp <+> prettyTCM s2
]
Guarded c pid ->
sep [ prettyTCM c
, nest 2 $ brackets $ text "blocked on problem" <+> prettyTCM pid
]
UnBlock m -> do
mi <- mvInstantiation <$> lookupMeta m
case mi of
BlockedConst t ->
sep [ pretty m <+> text ":="
, nest 2 $ prettyTCM t
]
PostponedTypeCheckingProblem cl _ -> enterClosure cl $ \p ->
sep [ pretty m <+> text ":="
, nest 2 $ prettyTCM p ]
Open{} -> __IMPOSSIBLE__
OpenIFS{} -> __IMPOSSIBLE__
InstS{} -> __IMPOSSIBLE__
InstV{} -> __IMPOSSIBLE__
FindInScope m mb Nothing -> do
t <- getMetaType m
sep [ text "Find in scope" <+> pretty m
<+> maybe (text ":") (\ b -> text "blocked on" <+> pretty b <+> text ":") mb
, prettyTCM t
, text " (no candidate for now)"
]
FindInScope m mb (Just cands) -> do
t <- getMetaType m
sep [ text "Find in scope" <+> pretty m
<+> maybe (text ":") (\ b -> text "blocked on" <+> pretty b <+> text ":") mb
, nest 2 $ prettyTCM t
, sep $ flip map cands $ \cand ->
prettyTCM (candidateTerm cand) <+> text ": " <+> prettyTCM (candidateType cand)
]
IsEmpty r t ->
sep [ text "Is empty:", nest 2 $ prettyTCM t ]
CheckSizeLtSat t ->
sep [ text "Is not empty type of sizes:", nest 2 $ prettyTCM t ]
instance PrettyTCM TypeCheckingProblem where
prettyTCM (CheckExpr e a) =
sep [ prettyA e <+> text ":?", prettyTCM a ]
prettyTCM (CheckArgs _ _ es t0 t1 _) =
sep [ parens $ text "_ :" <+> prettyTCM t0
, nest 2 $ prettyList $ map prettyA es
, nest 2 $ text ":?" <+> prettyTCM t1 ]
prettyTCM (CheckLambda (Arg ai (xs, mt)) e t) =
sep [ return CP.lambda <+>
(CP.prettyRelevance ai .
CP.prettyHiding ai (if isNothing mt && length xs == 1 then id
else P.parens) <$> do
fsep $
map prettyTCM xs ++
caseMaybe mt [] (\ a -> [text ":", prettyTCM a])) <+>
return CP.arrow <+>
prettyTCM e <+>
text ":?"
, prettyTCM t
]
prettyTCM (UnquoteTactic v _ _) = do
e <- reify v
let noInfo = A.exprNoRange
prettyTCM (A.App noInfo (A.Unquote noInfo) (defaultNamedArg e))
instance PrettyTCM a => PrettyTCM (WithHiding a) where
prettyTCM (WithHiding h a) = CP.prettyHiding h id <$> prettyTCM a
instance PrettyTCM Name where
prettyTCM x = P.pretty <$> abstractToConcrete_ x
instance PrettyTCM QName where
prettyTCM x = P.pretty <$> abstractToConcrete_ x
instance PrettyTCM ModuleName where
prettyTCM x = P.pretty <$> abstractToConcrete_ x
instance PrettyTCM ConHead where
prettyTCM = prettyTCM . conName
instance PrettyTCM Telescope where
prettyTCM tel = P.fsep . map P.pretty <$> (do
tel <- reify tel
runAbsToCon $ bindToConcrete tel (return . concat)
)
newtype PrettyContext = PrettyContext Context
instance PrettyTCM PrettyContext where
prettyTCM (PrettyContext ctx) = P.fsep . reverse <$> pr (map ctxEntry ctx)
where
pr :: [Dom (Name, Type)] -> TCM [P.Doc]
pr [] = return []
pr (Dom info (x,t) : ctx) = escapeContext 1 $ do
d <- CP.prettyRelevance info . CP.prettyHiding info P.parens <$> do
prettyTCM x <+> text ":" <+> prettyTCM t
(d :) <$> pr ctx
instance PrettyTCM Context where
prettyTCM = prettyTCM . PrettyContext
instance PrettyTCM CtxId where
prettyTCM (CtxId x) = prettyTCM x
instance PrettyTCM Pattern where
prettyTCM = showPat' (text . patVarNameToString)
instance PrettyTCM DeBruijnPattern where
prettyTCM = showPat' $ \ (i, x) -> prettyTCM $ var i
showPat' :: (a -> TCM Doc) -> Pattern' a -> TCM Doc
showPat' showVar = showPat
where
showPat (VarP x) = showVar x
showPat (DotP t) = text ".(" <> prettyTCM t <> text ")"
showPat (ConP c i ps) = (if b then braces else parens) $ prTy $
prettyTCM c <+> fsep (map (showPat . namedArg) ps)
where
b = maybe False (/= ConPCon) $ conPRecord i
showRec :: TCM Doc
showRec = sep
[ text "record"
, bracesAndSemicolons <$> zipWithM showField (conFields c) ps
]
showField x p =
sep [ prettyTCM (A.qnameName x) <+> text "=" , nest 2 $ showPat $ namedArg p ]
showCon = parens $ prTy $ prettyTCM c <+> fsep (map (showPat . namedArg) ps)
prTy d = d
showPat (LitP l) = text (show l)
showPat (ProjP q) = text (show q)
instance PrettyTCM (Elim' DisplayTerm) where
prettyTCM (Apply v) = text "$" <+> prettyTCM (unArg v)
prettyTCM (Proj f) = text "." <> prettyTCM f
raisePatVars :: Int -> NLPat -> NLPat
raisePatVars k (PVar id x) = PVar id (k+x)
raisePatVars k (PWild) = PWild
raisePatVars k (PDef f es) = PDef f $ (fmap . fmap) (raisePatVars k) es
raisePatVars k (PLam i u) = PLam i $ fmap (raisePatVars k) u
raisePatVars k (PPi a b) = PPi ((fmap . fmap) (raisePatVars k) a) ((fmap . fmap) (raisePatVars k) b)
raisePatVars k (PBoundVar i es) = PBoundVar i $ (fmap . fmap) (raisePatVars k) es
raisePatVars k (PTerm t) = PTerm t
instance PrettyTCM NLPat where
prettyTCM (PVar id x) = prettyTCM (var x)
prettyTCM (PWild) = text $ "_"
prettyTCM (PDef f es) = parens $
prettyTCM f <+> fsep (map prettyTCM es)
prettyTCM (PLam i u) = text ("λ " ++ absName u ++ " →") <+>
(addContext (absName u) $ prettyTCM (raisePatVars 1 $ absBody u))
prettyTCM (PPi a b) = text "Π" <+> prettyTCM (unDom a) <+>
(addContext (absName b) $ prettyTCM (fmap (raisePatVars 1) $ unAbs b))
prettyTCM (PBoundVar i es) = parens $ prettyTCM (var i) <+> fsep (map prettyTCM es)
prettyTCM (PTerm t) = text "." <> parens (prettyTCM t)
instance PrettyTCM (Elim' NLPat) where
prettyTCM (Apply v) = text "$" <+> prettyTCM (unArg v)
prettyTCM (Proj f) = text "." <> prettyTCM f
instance PrettyTCM (Type' NLPat) where
prettyTCM = prettyTCM . unEl
instance PrettyTCM RewriteRule where
prettyTCM (RewriteRule q gamma lhs rhs b) = sep
[ prettyTCM q <+> text " rule "
, prettyTCM gamma <+> text " |- "
, addContext gamma $ hsep
[ prettyTCM lhs
, text " --> "
, prettyTCM rhs
, text " : "
, prettyTCM b
]
]
instance PrettyTCM Occurrence where
prettyTCM GuardPos = text "-[g+]->"
prettyTCM StrictPos = text "-[++]->"
prettyTCM JustPos = text "-[+]->"
prettyTCM JustNeg = text "-[-]->"
prettyTCM Mixed = text "-[*]->"
prettyTCM Unused = text "-[ ]->"
data WithNode n a = WithNode n a
instance PrettyTCM n => PrettyTCM (WithNode n Occurrence) where
prettyTCM (WithNode n o) = prettyTCM o <+> prettyTCM n
instance (PrettyTCM n, PrettyTCM (WithNode n e)) => PrettyTCM (Graph n n e) where
prettyTCM g = vcat $ map pr $ Map.assocs $ Graph.graph g
where
pr (n, es) = sep
[ prettyTCM n
, nest 2 $ vcat $ map (prettyTCM . uncurry WithNode) $ Map.assocs es
]