{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE ImplicitParams #-}
{-# LANGUAGE RecordWildCards #-}
module Cryptol.ModuleSystem.Base where
import Cryptol.ModuleSystem.Env (DynamicEnv(..))
import Cryptol.ModuleSystem.Fingerprint
import Cryptol.ModuleSystem.Interface
import Cryptol.ModuleSystem.Monad
import Cryptol.ModuleSystem.Name (Name,liftSupply,PrimMap)
import Cryptol.ModuleSystem.Env (lookupModule
, LoadedModule(..)
, meCoreLint, CoreLint(..)
, ModContext(..)
, ModulePath(..), modulePathLabel)
import qualified Cryptol.Eval as E
import qualified Cryptol.Eval.Concrete as Concrete
import Cryptol.Eval.Concrete (Concrete(..))
import qualified Cryptol.ModuleSystem.NamingEnv as R
import qualified Cryptol.ModuleSystem.Renamer as R
import qualified Cryptol.Parser as P
import qualified Cryptol.Parser.Unlit as P
import Cryptol.Parser.AST as P
import Cryptol.Parser.NoPat (RemovePatterns(removePatterns))
import Cryptol.Parser.NoInclude (removeIncludesModule)
import Cryptol.Parser.Position (HasLoc(..), Range, emptyRange)
import qualified Cryptol.TypeCheck as T
import qualified Cryptol.TypeCheck.AST as T
import qualified Cryptol.TypeCheck.PP as T
import qualified Cryptol.TypeCheck.Sanity as TcSanity
import Cryptol.Transform.AddModParams (addModParams)
import Cryptol.Utils.Ident (preludeName, floatName, arrayName, interactiveName
, modNameChunks, notParamInstModName
, isParamInstModName )
import Cryptol.Utils.PP (pretty)
import Cryptol.Utils.Panic (panic)
import Cryptol.Utils.Logger(logPutStrLn, logPrint)
import Cryptol.Prelude (preludeContents, floatContents, arrayContents)
import Cryptol.Transform.MonoValues (rewModule)
import qualified Control.Exception as X
import Control.Monad (unless,when)
import Data.Maybe (fromMaybe)
import Data.Monoid ((<>))
import Data.Text.Encoding (decodeUtf8')
import System.Directory (doesFileExist, canonicalizePath)
import System.FilePath ( addExtension
, isAbsolute
, joinPath
, (</>)
, normalise
, takeDirectory
, takeFileName
)
import qualified System.IO.Error as IOE
import qualified Data.Map as Map
import Prelude ()
import Prelude.Compat hiding ( (<>) )
rename :: ModName -> R.NamingEnv -> R.RenameM a -> ModuleM a
rename modName env m = do
(res,ws) <- liftSupply $ \ supply ->
case R.runRenamer supply modName env m of
(Right (a,supply'),ws) -> ((Right a,ws),supply')
(Left errs,ws) -> ((Left errs,ws),supply)
renamerWarnings ws
case res of
Right r -> return r
Left errs -> renamerErrors errs
renameModule :: P.Module PName
-> ModuleM (IfaceDecls,R.NamingEnv,P.Module Name)
renameModule m = do
(decls,menv) <- importIfaces (map thing (P.mImports m))
(declsEnv,rm) <- rename (thing (mName m)) menv (R.renameModule m)
return (decls,declsEnv,rm)
noPat :: RemovePatterns a => a -> ModuleM a
noPat a = do
let (a',errs) = removePatterns a
unless (null errs) (noPatErrors errs)
return a'
parseModule :: ModulePath -> ModuleM (Fingerprint, P.Module PName)
parseModule path = do
getBytes <- getByteReader
bytesRes <- case path of
InFile p -> io (X.try (getBytes p))
InMem _ bs -> pure (Right bs)
bytes <- case bytesRes of
Right bytes -> return bytes
Left exn ->
case path of
InFile p
| IOE.isDoesNotExistError exn -> cantFindFile p
| otherwise -> otherIOError p exn
InMem p _ -> panic "parseModule"
[ "IOError for in-memory contetns???"
, "Label: " ++ show p
, "Exception: " ++ show exn ]
txt <- case decodeUtf8' bytes of
Right txt -> return txt
Left e -> badUtf8 path e
let cfg = P.defaultConfig
{ P.cfgSource = case path of
InFile p -> p
InMem l _ -> l
, P.cfgPreProc = P.guessPreProc (modulePathLabel path)
}
case P.parseModule cfg txt of
Right pm -> let fp = fingerprint bytes
in fp `seq` return (fp, pm)
Left err -> moduleParseError path err
loadModuleByPath :: FilePath -> ModuleM T.Module
loadModuleByPath path = withPrependedSearchPath [ takeDirectory path ] $ do
let fileName = takeFileName path
foundPath <- findFile fileName
(fp, pm) <- parseModule (InFile foundPath)
let n = thing (P.mName pm)
env <- getModuleEnv
path' <- io (canonicalizePath foundPath)
case lookupModule n env of
Nothing -> doLoadModule (FromModule n) (InFile foundPath) fp pm
Just lm
| path' == loaded -> return (lmModule lm)
| otherwise -> duplicateModuleName n path' loaded
where loaded = lmModuleId lm
loadModuleFrom :: ImportSource -> ModuleM (ModulePath,T.Module)
loadModuleFrom isrc =
do let n = importedModule isrc
mb <- getLoadedMaybe n
case mb of
Just m -> return (lmFilePath m, lmModule m)
Nothing ->
do path <- findModule n
errorInFile path $
do (fp, pm) <- parseModule path
m <- doLoadModule isrc path fp pm
return (path,m)
doLoadModule ::
ImportSource ->
ModulePath ->
Fingerprint ->
P.Module PName ->
ModuleM T.Module
doLoadModule isrc path fp pm0 =
loading isrc $
do let pm = addPrelude pm0
loadDeps pm
withLogger logPutStrLn
("Loading module " ++ pretty (P.thing (P.mName pm)))
tcm <- optionalInstantiate =<< checkModule isrc path pm
let ?evalPrim = Concrete.evalPrim
unless (T.isParametrizedModule tcm) $ modifyEvalEnv (E.moduleEnv Concrete tcm)
loadedModule path fp tcm
return tcm
where
optionalInstantiate tcm
| isParamInstModName (importedModule isrc) =
if T.isParametrizedModule tcm then
case addModParams tcm of
Right tcm1 -> return tcm1
Left xs -> failedToParameterizeModDefs (T.mName tcm) xs
else notAParameterizedModule (T.mName tcm)
| otherwise = return tcm
fullyQualified :: P.Import -> P.Import
fullyQualified i = i { iAs = Just (iModule i) }
importIface :: P.Import -> ModuleM (IfaceDecls,R.NamingEnv)
importIface imp =
do Iface { .. } <- getIface (T.iModule imp)
return (ifPublic, R.interpImport imp ifPublic)
importIfaces :: [P.Import] -> ModuleM (IfaceDecls,R.NamingEnv)
importIfaces is = mconcat `fmap` mapM importIface is
moduleFile :: ModName -> String -> FilePath
moduleFile n = addExtension (joinPath (modNameChunks n))
findModule :: ModName -> ModuleM ModulePath
findModule n = do
paths <- getSearchPath
loop (possibleFiles paths)
where
loop paths = case paths of
path:rest -> do
b <- io (doesFileExist path)
if b then return (InFile path) else loop rest
[] -> handleNotFound
handleNotFound =
case n of
m | m == preludeName -> pure (InMem "Cryptol" preludeContents)
| m == floatName -> pure (InMem "Float" floatContents)
| m == arrayName -> pure (InMem "Array" arrayContents)
_ -> moduleNotFound n =<< getSearchPath
possibleFiles paths = do
path <- paths
ext <- P.knownExts
return (path </> moduleFile n ext)
findFile :: FilePath -> ModuleM FilePath
findFile path | isAbsolute path = do
b <- io (doesFileExist path)
if b then return path else cantFindFile path
findFile path = do
paths <- getSearchPath
loop (possibleFiles paths)
where
loop paths = case paths of
path':rest -> do
b <- io (doesFileExist path')
if b then return (normalise path') else loop rest
[] -> cantFindFile path
possibleFiles paths = map (</> path) paths
addPrelude :: P.Module PName -> P.Module PName
addPrelude m
| preludeName == P.thing (P.mName m) = m
| preludeName `elem` importedMods = m
| otherwise = m { mImports = importPrelude : mImports m }
where
importedMods = map (P.iModule . P.thing) (P.mImports m)
importPrelude = P.Located
{ P.srcRange = emptyRange
, P.thing = P.Import
{ iModule = preludeName
, iAs = Nothing
, iSpec = Nothing
}
}
loadDeps :: P.Module name -> ModuleM ()
loadDeps m =
do mapM_ loadI (P.mImports m)
mapM_ loadF (P.mInstance m)
where
loadI i = do (_,m1) <- loadModuleFrom (FromImport i)
when (T.isParametrizedModule m1) $ importParamModule $ T.mName m1
loadF f = do _ <- loadModuleFrom (FromModuleInstance f)
return ()
checkExpr :: P.Expr PName -> ModuleM (P.Expr Name,T.Expr,T.Schema)
checkExpr e = do
fe <- getFocusedEnv
let params = mctxParams fe
decls = mctxDecls fe
names = mctxNames fe
npe <- noPat e
re <- rename interactiveName names (R.rename npe)
prims <- getPrimMap
let act = TCAction { tcAction = T.tcExpr, tcLinter = exprLinter
, tcPrims = prims }
(te,s) <- typecheck act re params decls
return (re,te,s)
checkDecls :: [P.TopDecl PName] -> ModuleM (R.NamingEnv,[T.DeclGroup])
checkDecls ds = do
fe <- getFocusedEnv
let params = mctxParams fe
decls = mctxDecls fe
names = mctxNames fe
declsEnv <- liftSupply (R.namingEnv' (map (R.InModule interactiveName) ds))
rds <- rename interactiveName (declsEnv `R.shadowing` names)
(traverse R.rename ds)
prims <- getPrimMap
let act = TCAction { tcAction = T.tcDecls, tcLinter = declsLinter
, tcPrims = prims }
ds' <- typecheck act rds params decls
return (declsEnv,ds')
getPrimMap :: ModuleM PrimMap
getPrimMap =
do env <- getModuleEnv
let mkPrims = ifacePrimMap . lmInterface
mp `alsoPrimFrom` m =
case lookupModule m env of
Nothing -> mp
Just lm -> mkPrims lm <> mp
case lookupModule preludeName env of
Just prel -> return $ mkPrims prel
`alsoPrimFrom` floatName
Nothing -> panic "Cryptol.ModuleSystem.Base.getPrimMap"
[ "Unable to find the prelude" ]
checkModule :: ImportSource -> ModulePath -> P.Module PName -> ModuleM T.Module
checkModule isrc path m =
case P.mInstance m of
Nothing -> checkSingleModule T.tcModule isrc path m
Just fmName -> do tf <- getLoaded (thing fmName)
checkSingleModule (T.tcModuleInst tf) isrc path m
checkSingleModule ::
Act (P.Module Name) T.Module ->
ImportSource ->
ModulePath ->
P.Module PName ->
ModuleM T.Module
checkSingleModule how isrc path m = do
let nm = importedModule isrc
unless (notParamInstModName nm == thing (P.mName m))
(moduleNameMismatch nm (mName m))
e <- case path of
InFile p -> do
r <- getByteReader
io (removeIncludesModule r p m)
InMem {} -> pure (Right m)
nim <- case e of
Right nim -> return nim
Left ierrs -> noIncludeErrors ierrs
npm <- noPat nim
(tcEnv,declsEnv,scm) <- renameModule npm
prims <- if thing (mName m) == preludeName
then return (R.toPrimMap declsEnv)
else getPrimMap
let act = TCAction { tcAction = how
, tcLinter = moduleLinter (P.thing (P.mName m))
, tcPrims = prims }
tcm0 <- typecheck act scm noIfaceParams tcEnv
let tcm = tcm0
liftSupply (`rewModule` tcm)
data TCLinter o = TCLinter
{ lintCheck ::
o -> T.InferInput -> Either TcSanity.Error [TcSanity.ProofObligation]
, lintModule :: Maybe P.ModName
}
exprLinter :: TCLinter (T.Expr, T.Schema)
exprLinter = TCLinter
{ lintCheck = \(e',s) i ->
case TcSanity.tcExpr i e' of
Left err -> Left err
Right (s1,os)
| TcSanity.same s s1 -> Right os
| otherwise -> Left (TcSanity.TypeMismatch "exprLinter" s s1)
, lintModule = Nothing
}
declsLinter :: TCLinter [ T.DeclGroup ]
declsLinter = TCLinter
{ lintCheck = \ds' i -> case TcSanity.tcDecls i ds' of
Left err -> Left err
Right os -> Right os
, lintModule = Nothing
}
moduleLinter :: P.ModName -> TCLinter T.Module
moduleLinter m = TCLinter
{ lintCheck = \m' i -> case TcSanity.tcModule i m' of
Left err -> Left err
Right os -> Right os
, lintModule = Just m
}
type Act i o = i -> T.InferInput -> IO (T.InferOutput o)
data TCAction i o = TCAction
{ tcAction :: Act i o
, tcLinter :: TCLinter o
, tcPrims :: PrimMap
}
typecheck ::
(Show i, Show o, HasLoc i) => TCAction i o -> i ->
IfaceParams -> IfaceDecls -> ModuleM o
typecheck act i params env = do
let range = fromMaybe emptyRange (getLoc i)
input <- genInferInput range (tcPrims act) params env
out <- io (tcAction act i input)
case out of
T.InferOK warns seeds supply' o ->
do setNameSeeds seeds
setSupply supply'
typeCheckWarnings warns
menv <- getModuleEnv
case meCoreLint menv of
NoCoreLint -> return ()
CoreLint -> case lintCheck (tcLinter act) o input of
Right as ->
let ppIt l = mapM_ (logPrint l . T.pp)
in withLogger ppIt as
Left err -> panic "Core lint failed:" [show err]
return o
T.InferFailed warns errs ->
do typeCheckWarnings warns
typeCheckingFailed errs
genInferInput :: Range -> PrimMap ->
IfaceParams -> IfaceDecls -> ModuleM T.InferInput
genInferInput r prims params env = do
seeds <- getNameSeeds
monoBinds <- getMonoBinds
cfg <- getSolverConfig
supply <- getSupply
searchPath <- getSearchPath
return T.InferInput
{ T.inpRange = r
, T.inpVars = Map.map ifDeclSig (ifDecls env)
, T.inpTSyns = ifTySyns env
, T.inpNewtypes = ifNewtypes env
, T.inpAbstractTypes = ifAbstractTypes env
, T.inpNameSeeds = seeds
, T.inpMonoBinds = monoBinds
, T.inpSolverConfig = cfg
, T.inpSearchPath = searchPath
, T.inpSupply = supply
, T.inpPrimNames = prims
, T.inpParamTypes = ifParamTypes params
, T.inpParamConstraints = ifParamConstraints params
, T.inpParamFuns = ifParamFuns params
}
evalExpr :: T.Expr -> ModuleM Concrete.Value
evalExpr e = do
env <- getEvalEnv
denv <- getDynEnv
evopts <- getEvalOpts
let ?evalPrim = Concrete.evalPrim
io $ E.runEval evopts $ (E.evalExpr Concrete (env <> deEnv denv) e)
evalDecls :: [T.DeclGroup] -> ModuleM ()
evalDecls dgs = do
env <- getEvalEnv
denv <- getDynEnv
evOpts <- getEvalOpts
let env' = env <> deEnv denv
let ?evalPrim = Concrete.evalPrim
deEnv' <- io $ E.runEval evOpts $ E.evalDecls Concrete dgs env'
let denv' = denv { deDecls = deDecls denv ++ dgs
, deEnv = deEnv'
}
setDynEnv denv'