%
-% (c) The University of Glasgow, 2000
+% (c) The University of Glasgow, 2002
+%
+% The Compilation Manager
%
-\section[CompManager]{The Compilation Manager}
-
\begin{code}
-module CompManager ( cmInit, cmLoadModule, cmUnload,
+module CompManager (
+ ModSummary, -- Abstract
+ ModuleGraph, -- All the modules from the home package
+
+ CmState, -- Abstract
+
+ cmInit, -- :: GhciMode -> IO CmState
+
+ cmDepAnal, -- :: CmState -> [FilePath] -> IO ModuleGraph
+ cmTopSort, -- :: Bool -> ModuleGraph -> [SCC ModSummary]
+ cyclicModuleErr, -- :: [ModSummary] -> String -- Used by DriverMkDepend
+
+ cmLoadModules, -- :: CmState -> ModuleGraph
+ -- -> IO (CmState, Bool, [String])
+
+ cmUnload, -- :: CmState -> IO CmState
+
+
#ifdef GHCI
- cmGetExpr, cmRunExpr,
+ cmModuleIsInterpreted, -- :: CmState -> String -> IO Bool
+
+ cmSetContext, -- :: CmState -> [String] -> [String] -> IO CmState
+ cmGetContext, -- :: CmState -> IO ([String],[String])
+
+ cmGetInfo, -- :: CmState -> String -> IO (CmState, [(TyThing,Fixity)])
+ GetInfoResult,
+ cmBrowseModule, -- :: CmState -> IO [TyThing]
+ cmShowModule,
+
+ CmRunResult(..),
+ cmRunStmt, -- :: CmState -> String -> IO (CmState, CmRunResult)
+
+ cmTypeOfExpr, -- :: CmState -> String -> IO (CmState, Maybe String)
+ cmKindOfType, -- :: CmState -> String -> IO (CmState, Maybe String)
+ cmTypeOfName, -- :: CmState -> Name -> IO (Maybe String)
+
+ HValue,
+ cmCompileExpr, -- :: CmState -> String -> IO (CmState, Maybe HValue)
+ cmGetModuleGraph, -- :: CmState -> ModuleGraph
+ cmSetDFlags,
+ cmGetDFlags,
+
+ cmGetBindings, -- :: CmState -> [TyThing]
+ cmGetPrintUnqual, -- :: CmState -> PrintUnqualified
#endif
- CmState, emptyCmState -- abstract
- )
+ )
where
#include "HsVersions.h"
-import CmLink
-import CmTypes
-import HscTypes
-import Module ( Module, ModuleName, moduleName, isHomeModule,
- mkModuleName, moduleNameUserString )
-import CmStaticInfo ( GhciMode(..) )
-import DriverPipeline
-import GetImports
-import HscTypes ( HomeSymbolTable, HomeIfaceTable,
- PersistentCompilerState, ModDetails(..) )
-import HscMain ( initPersistentCompilerState )
-import Finder
-import UniqFM ( emptyUFM, lookupUFM, addToUFM, delListFromUFM,
- UniqFM, listToUFM )
-import Unique ( Uniquable )
-import Digraph ( SCC(..), stronglyConnComp, flattenSCC )
-import DriverFlags ( getDynFlags )
-import DriverPhases
-import DriverUtil ( splitFilename3 )
+import Packages ( isHomePackage )
+import DriverPipeline ( CompResult(..), preprocess, compile, link )
+import HscMain ( newHscEnv )
+import DriverState ( v_Output_file, v_NoHsMain, v_MainModIs )
+import DriverPhases ( HscSource(..), isHsBoot, hscSourceString, isHaskellSrcFilename )
+import Finder ( findModule, findLinkable, addHomeModuleToFinder, flushFinderCache,
+ mkHomeModLocation, FindResult(..), cantFindError )
+import HscTypes ( ModSummary(..), HomeModInfo(..), ModIface(..), msHsFilePath,
+ HscEnv(..), GhciMode(..),
+ InteractiveContext(..), emptyInteractiveContext,
+ HomePackageTable, emptyHomePackageTable, IsBootInterface,
+ Linkable(..), isObjectLinkable )
+import Module ( Module, mkModule, delModuleEnv, delModuleEnvList, mkModuleEnv,
+ lookupModuleEnv, moduleEnvElts, extendModuleEnv, filterModuleEnv,
+ moduleUserString, addBootSuffixLocn,
+ ModLocation(..) )
+import GetImports ( getImports )
+import Digraph ( SCC(..), stronglyConnComp, flattenSCC, flattenSCCs )
import ErrUtils ( showPass )
+import SysTools ( cleanTempFilesExcept )
+import BasicTypes ( SuccessFlag(..), succeeded )
+import StringBuffer ( hGetStringBuffer )
import Util
-import DriverUtil
-import TmpFiles
import Outputable
import Panic
import CmdLineOpts ( DynFlags(..) )
-import IOExts
+import Maybes ( expectJust, orElse, mapCatMaybes )
+import FiniteMap
+
+import DATA_IOREF ( readIORef )
#ifdef GHCI
-import Interpreter ( HValue )
-import HscMain ( hscExpr )
-import Type ( Type )
-import PrelGHC ( unsafeCoerce# )
+import HscMain ( hscGetInfo, GetInfoResult, hscStmt, hscTcExpr, hscKcType )
+import HscTypes ( TyThing(..), icPrintUnqual, showModMsg )
+import TcRnDriver ( mkExportEnv, getModuleContents )
+import IfaceSyn ( IfaceDecl )
+import RdrName ( GlobalRdrEnv, plusGlobalRdrEnv )
+import Name ( Name )
+import NameEnv
+import Id ( idType )
+import Type ( tidyType )
+import VarEnv ( emptyTidyEnv )
+import Linker ( HValue, unload, extendLinkEnv )
+import GHC.Exts ( unsafeCoerce# )
+import Foreign
+import Control.Exception as Exception ( Exception, try )
+import CmdLineOpts ( DynFlag(..), dopt_unset )
#endif
--- lang
-import Exception ( throwDyn )
+import EXCEPTION ( throwDyn )
-- std
-import Time ( ClockTime )
import Directory ( getModificationTime, doesFileExist )
import IO
import Monad
import List ( nub )
-import Maybe ( catMaybes, fromMaybe, isJust, fromJust )
+import Maybe
\end{code}
+%************************************************************************
+%* *
+ The module dependency graph
+ ModSummary, ModGraph, NodeKey, NodeMap
+%* *
+%************************************************************************
+
+The nodes of the module graph are
+ EITHER a regular Haskell source module
+ OR a hi-boot source module
+
+A ModuleGraph contains all the nodes from the home package (only).
+There will be a node for each source module, plus a node for each hi-boot
+module.
+
\begin{code}
-cmInit :: GhciMode -> IO CmState
-cmInit gmode
- = emptyCmState gmode
+type ModuleGraph = [ModSummary] -- The module graph,
+ -- NOT NECESSARILY IN TOPOLOGICAL ORDER
-#ifdef GHCI
-cmGetExpr :: CmState
- -> DynFlags
- -> Bool -- True <=> wrap in 'print' to get an IO-typed result
- -> Module
- -> String
- -> IO (CmState, Maybe (HValue, PrintUnqualified, Type))
-cmGetExpr cmstate dflags wrap_io mod expr
- = do (new_pcs, maybe_stuff) <-
- hscExpr dflags wrap_io hst hit pcs mod expr
- case maybe_stuff of
- Nothing -> return (cmstate{ pcs=new_pcs }, Nothing)
- Just (bcos, print_unqual, ty) -> do
- hValue <- linkExpr pls bcos
- return (cmstate{ pcs=new_pcs },
- Just (hValue, print_unqual, ty))
+emptyMG :: ModuleGraph
+emptyMG = []
- -- ToDo: check that the module we passed in is sane/exists?
- where
- CmState{ hst=hst, hit=hit, pcs=pcs, pls=pls } = cmstate
+--------------------
+ms_allimps :: ModSummary -> [Module]
+ms_allimps ms = ms_srcimps ms ++ ms_imps ms
--- The HValue should represent a value of type IO () (Perhaps IO a?)
-cmRunExpr :: HValue -> IO ()
-cmRunExpr hval
- = do unsafeCoerce# hval :: IO ()
- -- putStrLn "done."
-#endif
+--------------------
+type NodeKey = (Module, HscSource) -- The nodes of the graph are
+type NodeMap a = FiniteMap NodeKey a -- keyed by (mod, src_file_type) pairs
-emptyHIT :: HomeIfaceTable
-emptyHIT = emptyUFM
-emptyHST :: HomeSymbolTable
-emptyHST = emptyUFM
+msKey :: ModSummary -> NodeKey
+msKey (ModSummary { ms_mod = mod, ms_hsc_src = boot }) = (mod,boot)
+
+emptyNodeMap :: NodeMap a
+emptyNodeMap = emptyFM
+
+mkNodeMap :: [ModSummary] -> NodeMap ModSummary
+mkNodeMap summaries = listToFM [ (msKey s, s) | s <- summaries]
+
+nodeMapElts :: NodeMap a -> [a]
+nodeMapElts = eltsFM
+\end{code}
+
+%************************************************************************
+%* *
+ The compilation manager state
+%* *
+%************************************************************************
+
+
+\begin{code}
-- Persistent state for the entire system
data CmState
= CmState {
- hst :: HomeSymbolTable, -- home symbol table
- hit :: HomeIfaceTable, -- home interface table
- ui :: UnlinkedImage, -- the unlinked images
- mg :: ModuleGraph, -- the module graph
- gmode :: GhciMode, -- NEVER CHANGES
-
- pcs :: PersistentCompilerState, -- compile's persistent state
- pls :: PersistentLinkerState -- link's persistent state
+ cm_hsc :: HscEnv, -- Includes the home-package table
+ cm_mg :: ModuleGraph, -- The module graph
+ cm_ic :: InteractiveContext -- Command-line binding info
}
-emptyCmState :: GhciMode -> IO CmState
-emptyCmState gmode
- = do pcs <- initPersistentCompilerState
- pls <- emptyPLS
- return (CmState { hst = emptyHST,
- hit = emptyHIT,
- ui = emptyUI,
- mg = emptyMG,
- gmode = gmode,
- pcs = pcs,
- pls = pls })
-
--- CM internal types
+#ifdef GHCI
+cmGetModuleGraph cmstate = cm_mg cmstate
+cmGetBindings cmstate = nameEnvElts (ic_type_env (cm_ic cmstate))
+cmGetPrintUnqual cmstate = icPrintUnqual (cm_ic cmstate)
+cmHPT cmstate = hsc_HPT (cm_hsc cmstate)
+#endif
+
+cmInit :: GhciMode -> DynFlags -> IO CmState
+cmInit ghci_mode dflags
+ = do { hsc_env <- newHscEnv ghci_mode dflags
+ ; return (CmState { cm_hsc = hsc_env,
+ cm_mg = emptyMG,
+ cm_ic = emptyInteractiveContext })}
+
+discardCMInfo :: CmState -> CmState
+-- Forget the compilation manager's state, including the home package table
+-- but retain the persistent info in HscEnv
+discardCMInfo cm_state
+ = cm_state { cm_mg = emptyMG, cm_ic = emptyInteractiveContext,
+ cm_hsc = (cm_hsc cm_state) { hsc_HPT = emptyHomePackageTable } }
+
+-------------------------------------------------------------------
+-- The unlinked image
+--
+-- The compilation manager keeps a list of compiled, but as-yet unlinked
+-- binaries (byte code or object code). Even when it links bytecode
+-- it keeps the unlinked version so it can re-link it later without
+-- recompiling.
+
type UnlinkedImage = [Linkable] -- the unlinked images (should be a set, really)
-emptyUI :: UnlinkedImage
-emptyUI = []
-type ModuleGraph = [ModSummary] -- the module graph, topologically sorted
-emptyMG :: ModuleGraph
-emptyMG = []
+findModuleLinkable_maybe :: [Linkable] -> Module -> Maybe Linkable
+findModuleLinkable_maybe lis mod
+ = case [LM time nm us | LM time nm us <- lis, nm == mod] of
+ [] -> Nothing
+ [li] -> Just li
+ many -> pprPanic "findModuleLinkable" (ppr mod)
+delModuleLinkable :: [Linkable] -> Module -> [Linkable]
+delModuleLinkable ls mod = [ l | l@(LM _ nm _) <- ls, nm /= mod ]
\end{code}
-Unload the compilation manager's state: everything it knows about the
-current collection of modules in the Home package.
+
+%************************************************************************
+%* *
+ GHCI stuff
+%* *
+%************************************************************************
\begin{code}
-cmUnload :: CmState -> IO CmState
-cmUnload state
- = do -- Throw away the old home dir cache
- emptyHomeDirCache
- -- Throw away the HIT and the HST
- return state{ hst=new_hst, hit=new_hit, ui=emptyUI }
- where
- CmState{ hst=hst, hit=hit } = state
- (new_hst, new_hit) = retainInTopLevelEnvs [] (hst,hit)
+#ifdef GHCI
+-----------------------------------------------------------------------------
+-- Setting the context doesn't throw away any bindings; the bindings
+-- we've built up in the InteractiveContext simply move to the new
+-- module. They always shadow anything in scope in the current context.
+
+cmSetContext
+ :: CmState
+ -> [String] -- take the top-level scopes of these modules
+ -> [String] -- and the just the exports from these
+ -> IO CmState
+cmSetContext cmstate toplevs exports = do
+ let old_ic = cm_ic cmstate
+ hsc_env = cm_hsc cmstate
+ hpt = hsc_HPT hsc_env
+
+ export_env <- mkExportEnv hsc_env (map mkModule exports)
+ toplev_envs <- mapM (mkTopLevEnv hpt) toplevs
+
+ let all_env = foldr plusGlobalRdrEnv export_env toplev_envs
+ return cmstate{ cm_ic = old_ic { ic_toplev_scope = toplevs,
+ ic_exports = exports,
+ ic_rn_gbl_env = all_env } }
+
+mkTopLevEnv :: HomePackageTable -> String -> IO GlobalRdrEnv
+mkTopLevEnv hpt mod
+ = case lookupModuleEnv hpt (mkModule mod) of
+ Nothing -> throwDyn (ProgramError ("mkTopLevEnv: not a home module " ++ mod))
+ Just details -> case hm_globals details of
+ Nothing -> throwDyn (ProgramError ("mkTopLevEnv: not interpreted " ++ mod))
+ Just env -> return env
+
+cmGetContext :: CmState -> IO ([String],[String])
+cmGetContext CmState{cm_ic=ic} =
+ return (ic_toplev_scope ic, ic_exports ic)
+
+cmModuleIsInterpreted :: CmState -> String -> IO Bool
+cmModuleIsInterpreted cmstate str
+ = case lookupModuleEnv (cmHPT cmstate) (mkModule str) of
+ Just details -> return (isJust (hm_globals details))
+ _not_a_home_module -> return False
+
+-----------------------------------------------------------------------------
+
+cmSetDFlags :: CmState -> DynFlags -> CmState
+cmSetDFlags cm_state dflags
+ = cm_state { cm_hsc = (cm_hsc cm_state) { hsc_dflags = dflags } }
+
+cmGetDFlags :: CmState -> DynFlags
+cmGetDFlags cm_state = hsc_dflags (cm_hsc cm_state)
+
+-----------------------------------------------------------------------------
+-- cmInfoThing: convert a String to a TyThing
+
+-- A string may refer to more than one TyThing (eg. a constructor,
+-- and type constructor), so we return a list of all the possible TyThings.
+
+cmGetInfo :: CmState -> String -> IO [GetInfoResult]
+cmGetInfo cmstate id = hscGetInfo (cm_hsc cmstate) (cm_ic cmstate) id
+
+-- ---------------------------------------------------------------------------
+-- cmBrowseModule: get all the TyThings defined in a module
+
+cmBrowseModule :: CmState -> String -> Bool -> IO [IfaceDecl]
+cmBrowseModule cmstate str exports_only
+ = do { mb_decls <- getModuleContents (cm_hsc cmstate) (cm_ic cmstate)
+ (mkModule str) exports_only
+ ; case mb_decls of
+ Nothing -> return [] -- An error of some kind
+ Just ds -> return ds
+ }
+
+
+-----------------------------------------------------------------------------
+cmShowModule :: CmState -> ModSummary -> String
+cmShowModule cmstate mod_summary
+ = case lookupModuleEnv hpt (ms_mod mod_summary) of
+ Nothing -> panic "missing linkable"
+ Just mod_info -> showModMsg obj_linkable mod_summary
+ where
+ obj_linkable = isObjectLinkable (hm_linkable mod_info)
+ where
+ hpt = hsc_HPT (cm_hsc cmstate)
+
+-----------------------------------------------------------------------------
+-- cmRunStmt: Run a statement/expr.
+
+data CmRunResult
+ = CmRunOk [Name] -- names bound by this evaluation
+ | CmRunFailed
+ | CmRunException Exception -- statement raised an exception
+
+cmRunStmt :: CmState -> String -> IO (CmState, CmRunResult)
+cmRunStmt cmstate@CmState{ cm_hsc=hsc_env, cm_ic=icontext } expr
+ = do
+ -- Turn off -fwarn-unused-bindings when running a statement, to hide
+ -- warnings about the implicit bindings we introduce.
+ let dflags' = dopt_unset (hsc_dflags hsc_env) Opt_WarnUnusedBinds
+ hsc_env' = hsc_env{ hsc_dflags = dflags' }
+
+ maybe_stuff <- hscStmt hsc_env' icontext expr
+
+ case maybe_stuff of
+ Nothing -> return (cmstate, CmRunFailed)
+ Just (new_ic, names, hval) -> do
+
+ let thing_to_run = unsafeCoerce# hval :: IO [HValue]
+ either_hvals <- sandboxIO thing_to_run
+
+ case either_hvals of
+ Left e -> do
+ -- on error, keep the *old* interactive context,
+ -- so that 'it' is not bound to something
+ -- that doesn't exist.
+ return ( cmstate, CmRunException e )
+
+ Right hvals -> do
+ -- Get the newly bound things, and bind them.
+ -- Don't need to delete any shadowed bindings;
+ -- the new ones override the old ones.
+ extendLinkEnv (zip names hvals)
+
+ return (cmstate{ cm_ic=new_ic },
+ CmRunOk names)
+
+
+-- We run the statement in a "sandbox" to protect the rest of the
+-- system from anything the expression might do. For now, this
+-- consists of just wrapping it in an exception handler, but see below
+-- for another version.
+
+sandboxIO :: IO a -> IO (Either Exception a)
+sandboxIO thing = Exception.try thing
+
+{-
+-- This version of sandboxIO runs the expression in a completely new
+-- RTS main thread. It is disabled for now because ^C exceptions
+-- won't be delivered to the new thread, instead they'll be delivered
+-- to the (blocked) GHCi main thread.
+
+-- SLPJ: when re-enabling this, reflect a wrong-stat error as an exception
+
+sandboxIO :: IO a -> IO (Either Int (Either Exception a))
+sandboxIO thing = do
+ st_thing <- newStablePtr (Exception.try thing)
+ alloca $ \ p_st_result -> do
+ stat <- rts_evalStableIO st_thing p_st_result
+ freeStablePtr st_thing
+ if stat == 1
+ then do st_result <- peek p_st_result
+ result <- deRefStablePtr st_result
+ freeStablePtr st_result
+ return (Right result)
+ else do
+ return (Left (fromIntegral stat))
+
+foreign import "rts_evalStableIO" {- safe -}
+ rts_evalStableIO :: StablePtr (IO a) -> Ptr (StablePtr a) -> IO CInt
+ -- more informative than the C type!
+-}
+
+-----------------------------------------------------------------------------
+-- cmTypeOfExpr: returns a string representing the type of an expression
+
+cmTypeOfExpr :: CmState -> String -> IO (Maybe String)
+cmTypeOfExpr cmstate expr
+ = do maybe_stuff <- hscTcExpr (cm_hsc cmstate) (cm_ic cmstate) expr
+
+ case maybe_stuff of
+ Nothing -> return Nothing
+ Just ty -> return (Just res_str)
+ where
+ res_str = showSDocForUser unqual (text expr <+> dcolon <+> ppr tidy_ty)
+ unqual = icPrintUnqual (cm_ic cmstate)
+ tidy_ty = tidyType emptyTidyEnv ty
+
+
+-----------------------------------------------------------------------------
+-- cmKindOfType: returns a string representing the kind of a type
+
+cmKindOfType :: CmState -> String -> IO (Maybe String)
+cmKindOfType cmstate str
+ = do maybe_stuff <- hscKcType (cm_hsc cmstate) (cm_ic cmstate) str
+ case maybe_stuff of
+ Nothing -> return Nothing
+ Just kind -> return (Just res_str)
+ where
+ res_str = showSDocForUser unqual (text str <+> dcolon <+> ppr kind)
+ unqual = icPrintUnqual (cm_ic cmstate)
+
+-----------------------------------------------------------------------------
+-- cmTypeOfName: returns a string representing the type of a name.
+
+cmTypeOfName :: CmState -> Name -> IO (Maybe String)
+cmTypeOfName CmState{ cm_ic=ic } name
+ = do
+ hPutStrLn stderr ("cmTypeOfName: " ++ showSDoc (ppr name))
+ case lookupNameEnv (ic_type_env ic) name of
+ Nothing -> return Nothing
+ Just (AnId id) -> return (Just str)
+ where
+ unqual = icPrintUnqual ic
+ ty = tidyType emptyTidyEnv (idType id)
+ str = showSDocForUser unqual (ppr ty)
+
+ _ -> panic "cmTypeOfName"
+
+-----------------------------------------------------------------------------
+-- cmCompileExpr: compile an expression and deliver an HValue
+
+cmCompileExpr :: CmState -> String -> IO (Maybe HValue)
+cmCompileExpr cmstate expr
+ = do
+ maybe_stuff
+ <- hscStmt (cm_hsc cmstate) (cm_ic cmstate)
+ ("let __cmCompileExpr = "++expr)
+
+ case maybe_stuff of
+ Nothing -> return Nothing
+ Just (new_ic, names, hval) -> do
+
+ -- Run it!
+ hvals <- (unsafeCoerce# hval) :: IO [HValue]
+
+ case (names,hvals) of
+ ([n],[hv]) -> return (Just hv)
+ _ -> panic "cmCompileExpr"
+
+#endif /* GHCI */
\end{code}
-The real business of the compilation manager: given a system state and
-a module name, try and bring the module up to date, probably changing
-the system state at the same time.
+
+%************************************************************************
+%* *
+ Loading and unloading
+%* *
+%************************************************************************
\begin{code}
-cmLoadModule :: CmState
- -> FilePath
- -> IO (CmState, -- new state
- Bool, -- was successful
- [Module]) -- list of modules loaded
+-----------------------------------------------------------------------------
+-- Unload the compilation manager's state: everything it knows about the
+-- current collection of modules in the Home package.
-cmLoadModule cmstate1 rootname
- = do -- version 1's are the original, before downsweep
- let pls1 = pls cmstate1
- let pcs1 = pcs cmstate1
- let hst1 = hst cmstate1
- let hit1 = hit cmstate1
- -- similarly, ui1 is the (complete) set of linkables from
- -- the previous pass, if any.
- let ui1 = ui cmstate1
- let mg1 = mg cmstate1
+cmUnload :: CmState -> IO CmState
+cmUnload state@CmState{ cm_hsc = hsc_env }
+ = do -- Throw away the old home dir cache
+ flushFinderCache
- let ghci_mode = gmode cmstate1 -- this never changes
+ -- Unload everything the linker knows about
+ cm_unload hsc_env []
- -- Do the downsweep to reestablish the module graph
- -- then generate version 2's by retaining in HIT,HST,UI a
- -- stable set S of modules, as defined below.
+ -- Start with a fresh CmState, but keep the PersistentCompilerState
+ return (discardCMInfo state)
+
+cm_unload hsc_env stable_linkables -- Unload everthing *except* 'stable_linkables'
+ = case hsc_mode hsc_env of
+ Batch -> return ()
+#ifdef GHCI
+ Interactive -> Linker.unload (hsc_dflags hsc_env) stable_linkables
+#else
+ Interactive -> panic "cm_unload: no interpreter"
+#endif
+ other -> panic "cm_unload: strange mode"
+
+
+-----------------------------------------------------------------------------
+-- Trace dependency graph
+
+-- This is a seperate pass so that the caller can back off and keep
+-- the current state if the downsweep fails. Typically the caller
+-- might go cmDepAnal
+-- cmUnload
+-- cmLoadModules
+-- He wants to do the dependency analysis before the unload, so that
+-- if the former fails he can use the later
+
+cmDepAnal :: CmState -> [FilePath] -> IO ModuleGraph
+cmDepAnal cmstate rootnames
+ = do showPass dflags "Chasing dependencies"
+ when (verbosity dflags >= 1 && gmode == Batch) $
+ hPutStrLn stderr (showSDoc (hcat [
+ text "Chasing modules from: ",
+ hcat (punctuate comma (map text rootnames))]))
+ downsweep dflags rootnames (cm_mg cmstate)
+ where
+ hsc_env = cm_hsc cmstate
+ dflags = hsc_dflags hsc_env
+ gmode = hsc_mode hsc_env
+
+-----------------------------------------------------------------------------
+-- The real business of the compilation manager: given a system state and
+-- a module name, try and bring the module up to date, probably changing
+-- the system state at the same time.
+
+cmLoadModules :: CmState -- The HPT may not be as up to date
+ -> ModuleGraph -- Bang up to date; but may contain hi-boot no
+ -> IO (CmState, -- new state
+ SuccessFlag, -- was successful
+ [String]) -- list of modules loaded
+
+cmLoadModules cmstate1 mg2unsorted
+ = do -- version 1's are the original, before downsweep
+ let hsc_env = cm_hsc cmstate1
+ let hpt1 = hsc_HPT hsc_env
+ let ghci_mode = hsc_mode hsc_env -- this never changes
+ let dflags = hsc_dflags hsc_env -- this never changes
- dflags <- getDynFlags
+ -- Do the downsweep to reestablish the module graph
let verb = verbosity dflags
- showPass dflags "Chasing dependencies"
- when (verb >= 1 && ghci_mode == Batch) $
- hPutStrLn stderr (progName ++ ": chasing modules from: " ++ rootname)
+ -- Find out if we have a Main module
+ mb_main_mod <- readIORef v_MainModIs
+ let
+ main_mod = mb_main_mod `orElse` "Main"
+ a_root_is_Main
+ = any ((==main_mod).moduleUserString.ms_mod)
+ mg2unsorted
- (mg2unsorted, a_root_is_Main) <- downsweep [rootname] mg1
- let mg2unsorted_names = map name_of_summary mg2unsorted
+ let mg2unsorted_names = map ms_mod mg2unsorted
- -- reachable_from follows source as well as normal imports
- let reachable_from :: ModuleName -> [ModuleName]
- reachable_from = downwards_closure_of_module mg2unsorted
-
- -- should be cycle free; ignores 'import source's
- let mg2 = topological_sort False mg2unsorted
- -- ... whereas this takes them into account. Used for
+ -- mg2 should be cycle free; but it includes hi-boot ModSummary nodes
+ let mg2 :: [SCC ModSummary]
+ mg2 = cmTopSort False mg2unsorted
+
+ -- mg2_with_srcimps drops the hi-boot nodes, returning a
+ -- graph with cycles. Among other things, it is used for
-- backing out partially complete cycles following a failed
- -- upsweep, and for removing from hst/hit all the modules
+ -- upsweep, and for removing from hpt all the modules
-- not in strict downwards closure, during calls to compile.
- let mg2_with_srcimps = topological_sort True mg2unsorted
+ let mg2_with_srcimps :: [SCC ModSummary]
+ mg2_with_srcimps = cmTopSort True mg2unsorted
-- Sort out which linkables we wish to keep in the unlinked image.
-- See getValidLinkables below for details.
- valid_linkables <- getValidLinkables ui1 mg2unsorted_names
- mg2_with_srcimps
+ (valid_old_linkables, new_linkables)
+ <- getValidLinkables ghci_mode (hptLinkables hpt1)
+ mg2unsorted_names mg2_with_srcimps
+
+ -- putStrLn (showSDoc (vcat [ppr valid_old_linkables, ppr new_linkables]))
+
+ -- The new_linkables are .o files we found on the disk, presumably
+ -- as a result of a GHC run "on the side". So we'd better forget
+ -- everything we know abouut those modules!
+ let old_hpt = delModuleEnvList hpt1 (map linkableModule new_linkables)
+
+ -- When (verb >= 2) $
+ -- putStrLn (showSDoc (text "Valid linkables:"
+ -- <+> ppr valid_linkables))
-- Figure out a stable set of modules which can be retained
-- the top level envs, to avoid upsweeping them. Goes to a
-- Travel upwards, over the sccified graph. For each scc
-- of modules ms, add ms to S only if:
-- 1. All home imports of ms are either in ms or S
- -- 2. A valid linkable exists for each module in ms
+ -- 2. A valid old linkable exists for each module in ms
- stable_mods
- <- preUpsweep valid_linkables ui1 mg2unsorted_names
- [] mg2_with_srcimps
+ -- mg2_with_srcimps has no hi-boot nodes,
+ -- and hence neither does stable_mods
+ stable_summaries <- preUpsweep valid_old_linkables
+ mg2unsorted_names [] mg2_with_srcimps
+ let stable_mods = map ms_mod stable_summaries
+ stable_linkables = filter (\m -> linkableModule m `elem` stable_mods)
+ valid_old_linkables
- let stable_summaries
- = concatMap (findInSummaries mg2unsorted) stable_mods
+ stable_hpt = filterModuleEnv is_stable_hm hpt1
+ is_stable_hm hm_info = mi_module (hm_iface hm_info) `elem` stable_mods
- stable_linkables
- = filter (\m -> linkableModName m `elem` stable_mods)
- valid_linkables
+ upsweep_these
+ = filter (\scc -> any (`notElem` stable_mods)
+ (map ms_mod (flattenSCC scc)))
+ mg2
when (verb >= 2) $
- putStrLn (showSDoc (text "STABLE MODULES:"
- <+> sep (map (text.moduleNameUserString) stable_mods)))
+ hPutStrLn stderr (showSDoc (text "Stable modules:"
+ <+> sep (map (text.moduleUserString) stable_mods)))
+
+ -- Unload any modules which are going to be re-linked this time around.
+ cm_unload hsc_env stable_linkables
- -- unload any modules which aren't going to be re-linked this
- -- time around.
- pls2 <- unload ghci_mode dflags stable_linkables pls1
+ -- We can now glom together our linkable sets
+ let valid_linkables = valid_old_linkables ++ new_linkables
-- We could at this point detect cycles which aren't broken by
-- a source-import, and complain immediately, but it seems better
-- to let upsweep_mods do this, so at least some useful work gets
-- done before the upsweep is abandoned.
- let upsweep_these
- = filter (\scc -> any (`notElem` stable_mods)
- (map name_of_summary (flattenSCC scc)))
- mg2
-
--hPutStrLn stderr "after tsort:\n"
--hPutStrLn stderr (showSDoc (vcat (map ppr mg2)))
-- Now do the upsweep, calling compile for each module in
-- turn. Final result is version 3 of everything.
- let threaded2 = CmThreaded pcs1 hst1 hit1
-
- (upsweep_complete_success, threaded3, modsUpswept, newLis)
- <- upsweep_mods ghci_mode dflags valid_linkables reachable_from
- threaded2 upsweep_these
+ -- clean up between compilations
+ let cleanup = cleanTempFilesExcept dflags
+ (ppFilesFromSummaries (flattenSCCs mg2))
- let ui3 = add_to_ui valid_linkables newLis
- let (CmThreaded pcs3 hst3 hit3) = threaded3
+ (upsweep_ok, hsc_env3, modsUpswept)
+ <- upsweep_mods (hsc_env { hsc_HPT = stable_hpt })
+ (old_hpt, valid_linkables)
+ cleanup upsweep_these
-- At this point, modsUpswept and newLis should have the same
-- length, so there is one new (or old) linkable for each
-- mod which was processed (passed to compile).
-- Make modsDone be the summaries for each home module now
- -- available; this should equal the domains of hst3 and hit3.
+ -- available; this should equal the domain of hpt3.
-- (NOT STRICTLY TRUE if an interactive session was started
-- with some object on disk ???)
-- Get in in a roughly top .. bottom order (hence reverse).
-- Try and do linking in some form, depending on whether the
-- upsweep was completely or only partially successful.
- if upsweep_complete_success
+ if succeeded upsweep_ok
then
-- Easy; just relink it all.
hPutStrLn stderr "Upsweep completely successful."
-- clean up after ourselves
- cleanTempFilesExcept verb (ppFilesFromSummaries modsDone)
-
- linkresult
- <- link ghci_mode dflags a_root_is_Main ui3 pls2
- case linkresult of
- LinkErrs _ _
- -> panic "cmLoadModule: link failed (1)"
- LinkOK pls3
- -> do let cmstate3
- = CmState { hst=hst3, hit=hit3,
- ui=ui3, mg=modsDone,
- gmode=ghci_mode,
- pcs=pcs3, pls=pls3 }
- return (cmstate3, True,
- map ms_mod modsDone)
+ cleanTempFilesExcept dflags (ppFilesFromSummaries modsDone)
+
+ ofile <- readIORef v_Output_file
+ no_hs_main <- readIORef v_NoHsMain
+
+ -- Issue a warning for the confusing case where the user
+ -- said '-o foo' but we're not going to do any linking.
+ -- We attempt linking if either (a) one of the modules is
+ -- called Main, or (b) the user said -no-hs-main, indicating
+ -- that main() is going to come from somewhere else.
+ --
+ let do_linking = a_root_is_Main || no_hs_main
+ when (ghci_mode == Batch && isJust ofile && not do_linking
+ && verb > 0) $
+ hPutStrLn stderr ("Warning: output was redirected with -o, but no output will be generated\nbecause there is no " ++ main_mod ++ " module.")
+
+ -- link everything together
+ linkresult <- link ghci_mode dflags do_linking (hsc_HPT hsc_env3)
+
+ let cmstate3 = cmstate1 { cm_mg = modsDone, cm_hsc = hsc_env3 }
+ cmLoadFinish Succeeded linkresult cmstate3
else
-- Tricky. We need to back out the effects of compiling any
hPutStrLn stderr "Upsweep partially successful."
let modsDone_names
- = map name_of_summary modsDone
+ = map ms_mod modsDone
let mods_to_zap_names
- = findPartiallyCompletedCycles modsDone_names mg2_with_srcimps
- let (hst4, hit4, ui4)
- = removeFromTopLevelEnvs mods_to_zap_names (hst3,hit3,ui3)
+ = findPartiallyCompletedCycles modsDone_names
+ mg2_with_srcimps
let mods_to_keep
- = filter ((`notElem` mods_to_zap_names).name_of_summary) modsDone
- let mods_to_keep_names
- = map name_of_summary mods_to_keep
- -- we could get the relevant linkables by filtering newLis, but
- -- it seems easier to drag them out of the updated, cleaned-up UI
- let linkables_to_link
- = map (unJust "linkables_to_link" . findModuleLinkable_maybe ui4)
- mods_to_keep_names
+ = filter ((`notElem` mods_to_zap_names).ms_mod)
+ modsDone
+
+ let hpt4 = retainInTopLevelEnvs (map ms_mod mods_to_keep)
+ (hsc_HPT hsc_env3)
+
+ -- Clean up after ourselves
+ cleanTempFilesExcept dflags (ppFilesFromSummaries mods_to_keep)
+
+ -- Link everything together
+ linkresult <- link ghci_mode dflags False hpt4
+
+ let cmstate3 = cmstate1 { cm_mg = mods_to_keep,
+ cm_hsc = hsc_env3 { hsc_HPT = hpt4 } }
+ cmLoadFinish Failed linkresult cmstate3
- -- clean up after ourselves
- cleanTempFilesExcept verb (ppFilesFromSummaries mods_to_keep)
- linkresult <- link ghci_mode dflags False linkables_to_link pls2
- case linkresult of
- LinkErrs _ _
- -> panic "cmLoadModule: link failed (2)"
- LinkOK pls3
- -> do let cmstate4
- = CmState { hst=hst4, hit=hit4,
- ui=ui4, mg=mods_to_keep,
- gmode=ghci_mode, pcs=pcs3, pls=pls3 }
- return (cmstate4, False,
- map ms_mod mods_to_keep)
+-- Finish up after a cmLoad.
+-- If the link failed, unload everything and return.
+cmLoadFinish ok Failed cmstate
+ = do cm_unload (cm_hsc cmstate) []
+ return (discardCMInfo cmstate, Failed, [])
-ppFilesFromSummaries summaries
- = [ fn | Just fn <- map (ml_hspp_file . ms_location) summaries ]
+-- Empty the interactive context and set the module context to the topmost
+-- newly loaded module, or the Prelude if none were loaded.
+cmLoadFinish ok Succeeded cmstate
+ = do let new_cmstate = cmstate { cm_ic = emptyInteractiveContext }
+ mods_loaded = map (moduleUserString.ms_mod)
+ (cm_mg cmstate)
+
+ return (new_cmstate, ok, mods_loaded)
+
+-- used to fish out the preprocess output files for the purposes of
+-- cleaning up. The preprocessed file *might* be the same as the
+-- source file, but that doesn't do any harm.
+ppFilesFromSummaries summaries = [ fn | Just fn <- map ms_hspp_file summaries ]
-----------------------------------------------------------------------------
-- getValidLinkables
-- For each module (or SCC of modules), we take:
--
--- - the old in-core linkable, if available
--- - an on-disk linkable, if available
+-- - an on-disk linkable, if this is the first time around and one
+-- is available.
+--
+-- - the old linkable, otherwise (and if one is available).
--
--- and we take the youngest of these, provided it is younger than the
--- source file. We ignore the on-disk linkables unless all of the
--- dependents of this SCC also have on-disk linkables.
+-- and we throw away the linkable if it is older than the source file.
+-- In interactive mode, we also ignore the on-disk linkables unless
+-- all of the dependents of this SCC also have on-disk linkables (we
+-- can't have dynamically loaded objects that depend on interpreted
+-- modules in GHCi).
--
-- If a module has a valid linkable, then it may be STABLE (see below),
-- and it is classified as SOURCE UNCHANGED for the purposes of calling
-- ToDo: this pass could be merged with the preUpsweep.
getValidLinkables
- :: [Linkable] -- old linkables
- -> [ModuleName] -- all home modules
+ :: GhciMode
+ -> [Linkable] -- old linkables
+ -> [Module] -- all home modules
-> [SCC ModSummary] -- all modules in the program, dependency order
- -> IO [Linkable] -- still-valid linkables
-
-getValidLinkables old_linkables all_home_mods module_graph
- = foldM (getValidLinkablesSCC old_linkables all_home_mods) [] module_graph
-
-getValidLinkablesSCC old_linkables all_home_mods new_linkables scc0
+ -> IO ( [Linkable], -- still-valid linkables
+ [Linkable] -- new linkables we just found on the disk
+ -- presumably generated by separate run of ghc
+ )
+
+getValidLinkables mode old_linkables all_home_mods module_graph
+ = do { -- Process the SCCs in bottom-to-top order
+ -- (foldM works left-to-right)
+ ls <- foldM (getValidLinkablesSCC mode old_linkables all_home_mods)
+ [] module_graph
+ ; return (partition_it ls [] []) }
+ where
+ partition_it [] valid new = (valid,new)
+ partition_it ((l,b):ls) valid new
+ | b = partition_it ls valid (l:new)
+ | otherwise = partition_it ls (l:valid) new
+
+
+getValidLinkablesSCC
+ :: GhciMode
+ -> [Linkable] -- old linkables
+ -> [Module] -- all home modules
+ -> [(Linkable,Bool)]
+ -> SCC ModSummary
+ -> IO [(Linkable,Bool)]
+
+getValidLinkablesSCC mode old_linkables all_home_mods new_linkables scc0
= let
scc = flattenSCC scc0
- scc_names = map name_of_summary scc
+ scc_names = map ms_mod scc
home_module m = m `elem` all_home_mods && m `notElem` scc_names
- scc_allhomeimps = nub (filter home_module (concatMap ms_allimps scc))
+ scc_allhomeimps = nub (filter home_module (concatMap ms_imps scc))
+ -- NB. ms_imps, not ms_allimps above. We don't want to
+ -- force a module's SOURCE imports to be already compiled for
+ -- its object linkable to be valid.
- has_object m = case findModuleLinkable_maybe new_linkables m of
+ -- The new_linkables is only the *valid* linkables below here
+ has_object m = case findModuleLinkable_maybe (map fst new_linkables) m of
Nothing -> False
Just l -> isObjectLinkable l
- objects_allowed = all has_object scc_allhomeimps
+ objects_allowed = mode == Batch || all has_object scc_allhomeimps
in do
- these_linkables
+ new_linkables'
<- foldM (getValidLinkable old_linkables objects_allowed) [] scc
-- since an scc can contain only all objects or no objects at all,
-- we have to check whether we got all objects or not, and re-do
-- the linkable check if not.
- adjusted_linkables
- <- if objects_allowed && not (all isObjectLinkable these_linkables)
- then foldM (getValidLinkable old_linkables False) [] scc
- else return these_linkables
+ new_linkables' <-
+ if objects_allowed
+ && not (all isObjectLinkable (map fst new_linkables'))
+ then foldM (getValidLinkable old_linkables False) [] scc
+ else return new_linkables'
- return (adjusted_linkables ++ new_linkables)
+ return (new_linkables ++ new_linkables')
-getValidLinkable :: [Linkable] -> Bool -> [Linkable] -> ModSummary
- -> IO [Linkable]
+getValidLinkable :: [Linkable] -> Bool -> [(Linkable,Bool)] -> ModSummary
+ -> IO [(Linkable,Bool)]
+ -- True <=> linkable is new; i.e. freshly discovered on the disk
+ -- presumably generated 'on the side'
+ -- by a separate GHC run
getValidLinkable old_linkables objects_allowed new_linkables summary
- = do
- let mod_name = name_of_summary summary
+ -- 'objects_allowed' says whether we permit this module to
+ -- have a .o-file linkable. We only permit it if all the
+ -- modules it depends on also have .o files; a .o file can't
+ -- link to a bytecode module
+ = do let mod_name = ms_mod summary
maybe_disk_linkable
- <- if (not objects_allowed)
+ <- if (not objects_allowed)
then return Nothing
- else case ml_obj_file (ms_location summary) of
- Just obj_fn -> maybe_getFileLinkable mod_name obj_fn
- Nothing -> return Nothing
-
- -- find an old in-core linkable if we have one. (forget about
- -- on-disk linkables for now, we'll check again whether there's
- -- one here below, just in case a new one has popped up recently).
- let old_linkable = findModuleLinkable_maybe old_linkables mod_name
- maybe_old_linkable =
- case old_linkable of
- Just (LM _ _ ls) | all isInterpretable ls -> old_linkable
- _ -> Nothing
-
- -- The most recent of the old UI linkable or whatever we could
- -- find on disk is returned as the linkable if compile
- -- doesn't think we need to recompile.
- let linkable_list
- = case (maybe_old_linkable, maybe_disk_linkable) of
- (Nothing, Nothing) -> []
- (Nothing, Just di) -> [di]
- (Just ui, Nothing) -> [ui]
- (Just ui, Just di)
- | linkableTime ui >= linkableTime di -> [ui]
- | otherwise -> [di]
-
- -- only linkables newer than the source code are valid
- let maybe_src_date = ms_hs_date summary
-
- valid_linkable_list
- = case maybe_src_date of
- Nothing -> panic "valid_linkable_list"
- Just src_date
- -> filter (\li -> linkableTime li > src_date) linkable_list
-
- return (valid_linkable_list ++ new_linkables)
-
-
-maybe_getFileLinkable :: ModuleName -> FilePath -> IO (Maybe Linkable)
-maybe_getFileLinkable mod_name obj_fn
- = do obj_exist <- doesFileExist obj_fn
- if not obj_exist
- then return Nothing
- else
- do let stub_fn = case splitFilename3 obj_fn of
- (dir, base, ext) -> dir ++ "/" ++ base ++ ".stub_o"
- stub_exist <- doesFileExist stub_fn
- obj_time <- getModificationTime obj_fn
- if stub_exist
- then return (Just (LM obj_time mod_name [DotO obj_fn, DotO stub_fn]))
- else return (Just (LM obj_time mod_name [DotO obj_fn]))
+
+ else findLinkable mod_name (ms_location summary)
+
+ let old_linkable = findModuleLinkable_maybe old_linkables mod_name
+
+ new_linkables' =
+ case (old_linkable, maybe_disk_linkable) of
+ (Nothing, Nothing) -> []
+
+ -- new object linkable just appeared
+ (Nothing, Just l) -> up_to_date l True
+
+ (Just l, Nothing)
+ | isObjectLinkable l -> []
+ -- object linkable disappeared! In case we need to
+ -- relink the module, disregard the old linkable and
+ -- just interpret the module from now on.
+ | otherwise -> up_to_date l False
+ -- old byte code linkable
+
+ (Just l, Just l')
+ | not (isObjectLinkable l) -> up_to_date l False
+ -- if the previous linkable was interpreted, then we
+ -- ignore a newly compiled version, because the version
+ -- numbers in the interface file will be out-of-sync with
+ -- our internal ones.
+ | linkableTime l' > linkableTime l -> up_to_date l' True
+ | linkableTime l' == linkableTime l -> up_to_date l False
+ | otherwise -> []
+ -- on-disk linkable has been replaced by an older one!
+ -- again, disregard the previous one.
+
+ up_to_date l b
+ | linkableTime l < ms_hs_date summary = []
+ | otherwise = [(l,b)]
+ -- why '<' rather than '<=' above? If the filesystem stores
+ -- times to the nearset second, we may occasionally find that
+ -- the object & source have the same modification time,
+ -- especially if the source was automatically generated
+ -- and compiled. Using >= is slightly unsafe, but it matches
+ -- make's behaviour.
+
+ return (new_linkables' ++ new_linkables)
+
+
+hptLinkables :: HomePackageTable -> [Linkable]
+-- Get all the linkables from the home package table, one for each module
+-- Once the HPT is up to date, these are the ones we should link
+hptLinkables hpt = map hm_linkable (moduleEnvElts hpt)
-----------------------------------------------------------------------------
-- Do a pre-upsweep without use of "compile", to establish a
-- (downward-closed) set of stable modules for which we won't call compile.
+-- a stable module:
+-- * has a valid linkable (see getValidLinkables above)
+-- * depends only on stable modules
+-- * has an interface in the HPT (interactive mode only)
+
preUpsweep :: [Linkable] -- new valid linkables
- -> [Linkable] -- old linkables
- -> [ModuleName] -- names of all mods encountered in downsweep
- -> [ModuleName] -- accumulating stable modules
+ -> [Module] -- names of all mods encountered in downsweep
+ -> [ModSummary] -- accumulating stable modules
-> [SCC ModSummary] -- scc-ified mod graph, including src imps
- -> IO [ModuleName] -- stable modules
+ -> IO [ModSummary] -- stable modules
-preUpsweep valid_lis old_lis all_home_mods stable []
- = return stable
-preUpsweep valid_lis old_lis all_home_mods stable (scc0:sccs)
+preUpsweep valid_lis all_home_mods stable [] = return stable
+preUpsweep valid_lis all_home_mods stable (scc0:sccs)
= do let scc = flattenSCC scc0
- scc_allhomeimps :: [ModuleName]
+ scc_allhomeimps :: [Module]
scc_allhomeimps
= nub (filter (`elem` all_home_mods) (concatMap ms_allimps scc))
all_imports_in_scc_or_stable
= all in_stable_or_scc scc_allhomeimps
- scc_names
- = map name_of_summary scc
- in_stable_or_scc m
- = m `elem` scc_names || m `elem` stable
+ scc_mods = map ms_mod scc
+ stable_names = scc_mods ++ map ms_mod stable
+ in_stable_or_scc m = m `elem` stable_names
-- now we check for valid linkables: each module in the SCC must
- -- have a valid linkable (see getValidLinkables above), and the
- -- newest linkable must be the same as the previous linkable for
- -- this module (if one exists).
- has_valid_linkable new_summary
- = case findModuleLinkable_maybe valid_lis modname of
- Nothing -> False
- Just l -> case findModuleLinkable_maybe old_lis modname of
- Nothing -> True
- Just m -> linkableTime l == linkableTime m
- where modname = name_of_summary new_summary
+ -- have a valid linkable (see getValidLinkables above).
+ has_valid_linkable scc_mod
+ = isJust (findModuleLinkable_maybe valid_lis scc_mod)
scc_is_stable = all_imports_in_scc_or_stable
- && all has_valid_linkable scc
+ && all has_valid_linkable scc_mods
if scc_is_stable
- then preUpsweep valid_lis old_lis all_home_mods
- (scc_names++stable) sccs
- else preUpsweep valid_lis old_lis all_home_mods
- stable sccs
-
- where
-
+ then preUpsweep valid_lis all_home_mods (scc ++ stable) sccs
+ else preUpsweep valid_lis all_home_mods stable sccs
--- Helper for preUpsweep. Assuming that new_summary's imports are all
--- stable (in the sense of preUpsweep), determine if new_summary is itself
--- stable, and, if so, in batch mode, return its linkable.
-findInSummaries :: [ModSummary] -> ModuleName -> [ModSummary]
-findInSummaries old_summaries mod_name
- = [s | s <- old_summaries, name_of_summary s == mod_name]
-
-findModInSummaries :: [ModSummary] -> Module -> Maybe ModSummary
-findModInSummaries old_summaries mod
- = case [s | s <- old_summaries, ms_mod s == mod] of
- [] -> Nothing
- (s:_) -> Just s
-- Return (names of) all those in modsDone who are part of a cycle
-- as defined by theGraph.
-findPartiallyCompletedCycles :: [ModuleName] -> [SCC ModSummary] -> [ModuleName]
+findPartiallyCompletedCycles :: [Module] -> [SCC ModSummary] -> [Module]
findPartiallyCompletedCycles modsDone theGraph
= chew theGraph
where
chew [] = []
chew ((AcyclicSCC v):rest) = chew rest -- acyclic? not interesting.
chew ((CyclicSCC vs):rest)
- = let names_in_this_cycle = nub (map name_of_summary vs)
+ = let names_in_this_cycle = nub (map ms_mod vs)
mods_in_this_cycle
= nub ([done | done <- modsDone,
done `elem` names_in_this_cycle])
chewed_rest = chew rest
in
- if not (null mods_in_this_cycle)
+ if notNull mods_in_this_cycle
&& length mods_in_this_cycle < length names_in_this_cycle
then mods_in_this_cycle ++ chewed_rest
else chewed_rest
--- Add the given (LM-form) Linkables to the UI, overwriting previous
--- versions if they exist.
-add_to_ui :: UnlinkedImage -> [Linkable] -> UnlinkedImage
-add_to_ui ui lis
- = filter (not_in lis) ui ++ lis
- where
- not_in :: [Linkable] -> Linkable -> Bool
- not_in lis li
- = all (\l -> linkableModName l /= mod) lis
- where mod = linkableModName li
-
-
-data CmThreaded -- stuff threaded through individual module compilations
- = CmThreaded PersistentCompilerState HomeSymbolTable HomeIfaceTable
-
-
-- Compile multiple modules, stopping as soon as an error appears.
-- There better had not be any cyclic groups here -- we check for them.
-upsweep_mods :: GhciMode
- -> DynFlags
- -> UnlinkedImage -- valid linkables
- -> (ModuleName -> [ModuleName]) -- to construct downward closures
- -> CmThreaded -- PCS & HST & HIT
- -> [SCC ModSummary] -- mods to do (the worklist)
- -- ...... RETURNING ......
- -> IO (Bool{-complete success?-},
- CmThreaded,
- [ModSummary], -- mods which succeeded
- [Linkable]) -- new linkables
-
-upsweep_mods ghci_mode dflags oldUI reachable_from threaded
+upsweep_mods :: HscEnv -- Includes initially-empty HPT
+ -> (HomePackageTable, [Linkable]) -- HPT and valid linkables from last time round
+ -> IO () -- How to clean up unwanted tmp files
+ -> [SCC ModSummary] -- Mods to do (the worklist)
+ -> IO (SuccessFlag,
+ HscEnv, -- With an updated HPT
+ [ModSummary]) -- Mods which succeeded
+
+upsweep_mods hsc_env oldUI cleanup
[]
- = return (True, threaded, [], [])
-
-upsweep_mods ghci_mode dflags oldUI reachable_from threaded
- ((CyclicSCC ms):_)
- = do hPutStrLn stderr ("Module imports form a cycle for modules:\n\t" ++
- unwords (map (moduleNameUserString.name_of_summary) ms))
- return (False, threaded, [], [])
-
-upsweep_mods ghci_mode dflags oldUI reachable_from threaded
- ((AcyclicSCC mod):mods)
- = do --case threaded of
- -- CmThreaded pcsz hstz hitz
- -- -> putStrLn ("UPSWEEP_MOD: hit = " ++ show (map (moduleNameUserString.moduleName.mi_module) (eltsUFM hitz)))
-
- (threaded1, maybe_linkable)
- <- upsweep_mod ghci_mode dflags oldUI threaded mod
- (reachable_from (name_of_summary mod))
- case maybe_linkable of
- Just linkable
- -> -- No errors; do the rest
- do (restOK, threaded2, modOKs, linkables)
- <- upsweep_mods ghci_mode dflags oldUI reachable_from
- threaded1 mods
- return (restOK, threaded2, mod:modOKs, linkable:linkables)
- Nothing -- we got a compilation error; give up now
- -> return (False, threaded1, [], [])
+ = return (Succeeded, hsc_env, [])
+
+upsweep_mods hsc_env oldUI cleanup
+ (CyclicSCC ms:_)
+ = do hPutStrLn stderr (showSDoc (cyclicModuleErr ms))
+ return (Failed, hsc_env, [])
+
+upsweep_mods hsc_env oldUI@(old_hpt, old_linkables) cleanup
+ (AcyclicSCC mod:mods)
+ = do -- putStrLn ("UPSWEEP_MOD: hpt = " ++
+ -- show (map (moduleUserString.moduleName.mi_module.hm_iface)
+ -- (moduleEnvElts (hsc_HPT hsc_env)))
+
+ mb_mod_info <- upsweep_mod hsc_env oldUI mod
+
+ cleanup -- Remove unwanted tmp files between compilations
+
+ case mb_mod_info of
+ Nothing -> return (Failed, hsc_env, [])
+ Just mod_info -> do
+ { let this_mod = ms_mod mod
+
+ -- Add new info to hsc_env
+ hpt1 = extendModuleEnv (hsc_HPT hsc_env) this_mod mod_info
+ hsc_env1 = hsc_env { hsc_HPT = hpt1 }
+
+ -- Space-saving: delete the old HPT entry and linkable for mod
+ -- BUT if mod is a hs-boot node, don't delete it
+ -- For the linkable this is dead right: the linkable relates only
+ -- to the main Haskell source file.
+ -- For the interface, the HPT entry is probaby for the main Haskell
+ -- source file. Deleting it would force
+ oldUI1 | isHsBoot (ms_hsc_src mod) = oldUI
+ | otherwise
+ = (delModuleEnv old_hpt this_mod,
+ delModuleLinkable old_linkables this_mod)
+
+ ; (restOK, hsc_env2, modOKs) <- upsweep_mods hsc_env1 oldUI1 cleanup mods
+ ; return (restOK, hsc_env2, mod:modOKs) }
-- Compile a single module. Always produce a Linkable for it if
-- successful. If no compilation happened, return the old Linkable.
-upsweep_mod :: GhciMode
- -> DynFlags
- -> UnlinkedImage
- -> CmThreaded
+upsweep_mod :: HscEnv
+ -> (HomePackageTable, UnlinkedImage)
-> ModSummary
- -> [ModuleName]
- -> IO (CmThreaded, Maybe Linkable)
+ -> IO (Maybe HomeModInfo) -- Nothing => Failed
-upsweep_mod ghci_mode dflags oldUI threaded1 summary1 reachable_from_here
+upsweep_mod hsc_env (old_hpt, old_linkables) summary
= do
- let mod_name = name_of_summary summary1
- let verb = verbosity dflags
+ let this_mod = ms_mod summary
+
+ -- The old interface is ok if it's in the old HPT
+ -- a) we're compiling a source file, and the old HPT entry is for a source file
+ -- b) we're compiling a hs-boot file
+ -- Case (b) allows an hs-boot file to get the interface of its real source file
+ -- on the second iteration of the compilation manager, but that does no harm.
+ -- Otherwise the hs-boot file will always be recompiled
+ mb_old_iface
+ = case lookupModuleEnv old_hpt this_mod of
+ Nothing -> Nothing
+ Just hm_info | isHsBoot (ms_hsc_src summary) -> Just iface
+ | not (mi_boot iface) -> Just iface
+ | otherwise -> Nothing
+ where
+ iface = hm_iface hm_info
+
+ maybe_old_linkable = findModuleLinkable_maybe old_linkables this_mod
+ source_unchanged = isJust maybe_old_linkable
+
+ old_linkable = expectJust "upsweep_mod:old_linkable" maybe_old_linkable
+
+ have_object
+ | Just l <- maybe_old_linkable, isObjectLinkable l = True
+ | otherwise = False
+
+ compresult <- compile hsc_env summary source_unchanged have_object mb_old_iface
- when (verb == 1) $
- if (ghci_mode == Batch)
- then hPutStr stderr (progName ++ ": module "
- ++ moduleNameUserString mod_name
- ++ ": ")
- else hPutStr stderr ("Compiling "
- ++ moduleNameUserString mod_name
- ++ " ... ")
+ case compresult of
- let (CmThreaded pcs1 hst1 hit1) = threaded1
- let old_iface = lookupUFM hit1 mod_name
+ -- Compilation "succeeded", and may or may not have returned a new
+ -- linkable (depending on whether compilation was actually performed
+ -- or not).
+ CompOK new_details new_globals new_iface maybe_new_linkable
+ -> do let
+ new_linkable = maybe_new_linkable `orElse` old_linkable
+ new_info = HomeModInfo { hm_iface = new_iface,
+ hm_globals = new_globals,
+ hm_details = new_details,
+ hm_linkable = new_linkable }
+ return (Just new_info)
+
+ -- Compilation failed. Compile may still have updated the PCS, tho.
+ CompErrs -> return Nothing
+
+-- Filter modules in the HPT
+retainInTopLevelEnvs :: [Module] -> HomePackageTable -> HomePackageTable
+retainInTopLevelEnvs keep_these hpt
+ = mkModuleEnv [ (mod, fromJust mb_mod_info)
+ | mod <- keep_these
+ , let mb_mod_info = lookupModuleEnv hpt mod
+ , isJust mb_mod_info ]
- let maybe_old_linkable = findModuleLinkable_maybe oldUI mod_name
+-----------------------------------------------------------------------------
+cmTopSort :: Bool -- Drop hi-boot nodes? (see below)
+ -> [ModSummary]
+ -> [SCC ModSummary]
+-- Calculate SCCs of the module graph, possibly dropping the hi-boot nodes
+--
+-- Drop hi-boot nodes (first boolean arg)?
+--
+-- False: treat the hi-boot summaries as nodes of the graph,
+-- so the graph must be acyclic
+--
+-- True: eliminate the hi-boot nodes, and instead pretend
+-- the a source-import of Foo is an import of Foo
+-- The resulting graph has no hi-boot nodes, but can by cyclic
- source_unchanged = isJust maybe_old_linkable
+cmTopSort drop_hs_boot_nodes summaries
+ = stronglyConnComp nodes
+ where
+ -- Drop hs-boot nodes by using HsSrcFile as the key
+ hs_boot_key | drop_hs_boot_nodes = HsSrcFile
+ | otherwise = HsBootFile
- (hst1_strictDC, hit1_strictDC)
- = retainInTopLevelEnvs
- (filter (/= (name_of_summary summary1)) reachable_from_here)
- (hst1,hit1)
+ -- We use integers as the keys for the SCC algorithm
+ nodes :: [(ModSummary, Int, [Int])]
+ nodes = [(s, fromJust (lookup_key (ms_hsc_src s) (ms_mod s)),
+ out_edge_keys hs_boot_key (ms_srcimps s) ++
+ out_edge_keys HsSrcFile (ms_imps s) )
+ | s <- summaries
+ , not (ms_hsc_src s == HsBootFile && drop_hs_boot_nodes) ]
+ -- Drop the hi-boot ones if told to do so
- old_linkable
- = unJust "upsweep_mod:old_linkable" maybe_old_linkable
+ key_map :: NodeMap Int
+ key_map = listToFM ([(ms_mod s, ms_hsc_src s) | s <- summaries]
+ `zip` [1..])
- compresult <- compile ghci_mode summary1 source_unchanged
- old_iface hst1_strictDC hit1_strictDC pcs1
+ lookup_key :: HscSource -> Module -> Maybe Int
+ lookup_key hs_src mod = lookupFM key_map (mod, hs_src)
- case compresult of
+ out_edge_keys :: HscSource -> [Module] -> [Int]
+ out_edge_keys hi_boot ms = mapCatMaybes (lookup_key hi_boot) ms
+ -- If we want keep_hi_boot_nodes, then we do lookup_key with
+ -- the IsBootInterface parameter True; else False
- -- Compilation "succeeded", but didn't return a new
- -- linkable, meaning that compilation wasn't needed, and the
- -- new details were manufactured from the old iface.
- CompOK pcs2 new_details new_iface Nothing
- -> do let hst2 = addToUFM hst1 mod_name new_details
- hit2 = addToUFM hit1 mod_name new_iface
- threaded2 = CmThreaded pcs2 hst2 hit2
-
- if ghci_mode == Interactive && verb >= 1 then
- -- if we're using an object file, tell the user
- case old_linkable of
- (LM _ _ objs@(DotO _:_))
- -> do hPutStrLn stderr (showSDoc (space <>
- parens (hsep (text "using":
- punctuate comma
- [ text o | DotO o <- objs ]))))
- _ -> return ()
- else
- return ()
-
- return (threaded2, Just old_linkable)
-
- -- Compilation really did happen, and succeeded. A new
- -- details, iface and linkable are returned.
- CompOK pcs2 new_details new_iface (Just new_linkable)
- -> do let hst2 = addToUFM hst1 mod_name new_details
- hit2 = addToUFM hit1 mod_name new_iface
- threaded2 = CmThreaded pcs2 hst2 hit2
-
- return (threaded2, Just new_linkable)
-
- -- Compilation failed. compile may still have updated
- -- the PCS, tho.
- CompErrs pcs2
- -> do let threaded2 = CmThreaded pcs2 hst1 hit1
- return (threaded2, Nothing)
-
--- Remove unwanted modules from the top level envs (HST, HIT, UI).
-removeFromTopLevelEnvs :: [ModuleName]
- -> (HomeSymbolTable, HomeIfaceTable, UnlinkedImage)
- -> (HomeSymbolTable, HomeIfaceTable, UnlinkedImage)
-removeFromTopLevelEnvs zap_these (hst, hit, ui)
- = (delListFromUFM hst zap_these,
- delListFromUFM hit zap_these,
- filterModuleLinkables (`notElem` zap_these) ui
- )
-
-retainInTopLevelEnvs :: [ModuleName]
- -> (HomeSymbolTable, HomeIfaceTable)
- -> (HomeSymbolTable, HomeIfaceTable)
-retainInTopLevelEnvs keep_these (hst, hit)
- = (retainInUFM hst keep_these,
- retainInUFM hit keep_these
- )
- where
- retainInUFM :: Uniquable key => UniqFM elt -> [key] -> UniqFM elt
- retainInUFM ufm keys_to_keep
- = listToUFM (concatMap (maybeLookupUFM ufm) keys_to_keep)
- maybeLookupUFM ufm u
- = case lookupUFM ufm u of Nothing -> []; Just val -> [(u, val)]
-
--- Needed to clean up HIT and HST so that we don't get duplicates in inst env
-downwards_closure_of_module :: [ModSummary] -> ModuleName -> [ModuleName]
-downwards_closure_of_module summaries root
- = let toEdge :: ModSummary -> (ModuleName,[ModuleName])
- toEdge summ = (name_of_summary summ, ms_allimps summ)
- res = simple_transitive_closure (map toEdge summaries) [root]
- in
- --trace (showSDoc (text "DC of mod" <+> ppr root
- -- <+> text "=" <+> ppr res)) (
- res
- --)
-
--- Calculate transitive closures from a set of roots given an adjacency list
-simple_transitive_closure :: Eq a => [(a,[a])] -> [a] -> [a]
-simple_transitive_closure graph set
- = let set2 = nub (concatMap dsts set ++ set)
- dsts node = fromMaybe [] (lookup node graph)
- in
- if length set == length set2
- then set
- else simple_transitive_closure graph set2
-
-
--- Calculate SCCs of the module graph, with or without taking into
--- account source imports.
-topological_sort :: Bool -> [ModSummary] -> [SCC ModSummary]
-topological_sort include_source_imports summaries
- = let
- toEdge :: ModSummary -> (ModSummary,ModuleName,[ModuleName])
- toEdge summ
- = (summ, name_of_summary summ,
- (if include_source_imports
- then ms_srcimps summ else []) ++ ms_imps summ)
-
- mash_edge :: (ModSummary,ModuleName,[ModuleName]) -> (ModSummary,Int,[Int])
- mash_edge (summ, m, m_imports)
- = case lookup m key_map of
- Nothing -> panic "reverse_topological_sort"
- Just mk -> (summ, mk,
- -- ignore imports not from the home package
- catMaybes (map (flip lookup key_map) m_imports))
-
- edges = map toEdge summaries
- key_map = zip [nm | (s,nm,imps) <- edges] [1 ..] :: [(ModuleName,Int)]
- scc_input = map mash_edge edges
- sccs = stronglyConnComp scc_input
- in
- sccs
+-----------------------------------------------------------------------------
+-- Downsweep (dependency analysis)
-- Chase downwards from the specified root set, returning summaries
-- for all home modules encountered. Only follow source-import
--- links. Also returns a Bool to indicate whether any of the roots
--- are module Main.
-downsweep :: [FilePath] -> [ModSummary] -> IO ([ModSummary], Bool)
-downsweep rootNm old_summaries
- = do rootSummaries <- mapM getRootSummary rootNm
- let a_root_is_Main
- = any ((=="Main").moduleNameUserString.name_of_summary)
- rootSummaries
- all_summaries
- <- loop (concat (map ms_imps rootSummaries))
- (filter (isHomeModule.ms_mod) rootSummaries)
- return (all_summaries, a_root_is_Main)
+-- links.
+
+-- We pass in the previous collection of summaries, which is used as a
+-- cache to avoid recalculating a module summary if the source is
+-- unchanged.
+
+downsweep :: DynFlags -> [FilePath] -> [ModSummary] -> IO [ModSummary]
+downsweep dflags roots old_summaries
+ = do rootSummaries <- mapM getRootSummary roots
+ checkDuplicates rootSummaries
+ loop (concatMap msImports rootSummaries)
+ (mkNodeMap rootSummaries)
where
+ old_summary_map :: NodeMap ModSummary
+ old_summary_map = mkNodeMap old_summaries
+
getRootSummary :: FilePath -> IO ModSummary
getRootSummary file
- | haskellish_file file
+ | isHaskellSrcFilename file
= do exists <- doesFileExist file
- if exists then summariseFile file else do
- throwDyn (OtherError ("can't find file `" ++ file ++ "'"))
+ if exists then summariseFile dflags file else do
+ throwDyn (CmdLineError ("can't find file `" ++ file ++ "'"))
| otherwise
= do exists <- doesFileExist hs_file
- if exists then summariseFile hs_file else do
+ if exists then summariseFile dflags hs_file else do
exists <- doesFileExist lhs_file
- if exists then summariseFile lhs_file else do
- getSummary (mkModuleName file)
+ if exists then summariseFile dflags lhs_file else do
+ let mod_name = mkModule file
+ maybe_summary <- summarise dflags emptyNodeMap Nothing False mod_name
+ case maybe_summary of
+ Nothing -> packageModErr mod_name
+ Just s -> return s
where
hs_file = file ++ ".hs"
lhs_file = file ++ ".lhs"
- getSummary :: ModuleName -> IO ModSummary
- getSummary nm
- = do found <- findModule nm
- case found of
- Just (mod, location) -> do
- let old_summary = findModInSummaries old_summaries mod
- new_summary <- summarise mod location old_summary
- case new_summary of
- Nothing -> return (fromJust old_summary)
- Just s -> return s
-
- Nothing -> throwDyn (OtherError
- ("can't find module `"
- ++ showSDoc (ppr nm) ++ "'"))
-
- -- loop invariant: home_summaries doesn't contain package modules
- loop :: [ModuleName] -> [ModSummary] -> IO [ModSummary]
- loop [] home_summaries = return home_summaries
- loop imps home_summaries
- = do -- all modules currently in homeSummaries
- let all_home = map (moduleName.ms_mod) home_summaries
-
- -- imports for modules we don't already have
- let needed_imps = nub (filter (`notElem` all_home) imps)
-
- -- summarise them
- needed_summaries <- mapM getSummary needed_imps
-
- -- get just the "home" modules
- let new_home_summaries
- = filter (isHomeModule.ms_mod) needed_summaries
-
- -- loop, checking the new imports
- let new_imps = concat (map ms_imps new_home_summaries)
- loop new_imps (new_home_summaries ++ home_summaries)
+ -- In a root module, the filename is allowed to diverge from the module
+ -- name, so we have to check that there aren't multiple root files
+ -- defining the same module (otherwise the duplicates will be silently
+ -- ignored, leading to confusing behaviour).
+ checkDuplicates :: [ModSummary] -> IO ()
+ checkDuplicates summaries = mapM_ check summaries
+ where check summ =
+ case dups of
+ [] -> return ()
+ [_one] -> return ()
+ many -> multiRootsErr modl many
+ where modl = ms_mod summ
+ dups =
+ [ fromJust (ml_hs_file (ms_location summ'))
+ | summ' <- summaries, ms_mod summ' == modl ]
+
+ loop :: [(FilePath,Module,IsBootInterface)] -- Work list: process these modules
+ -> NodeMap ModSummary -- Visited set
+ -> IO [ModSummary] -- The result includes the worklist, except
+ -- for those mentioned in the visited set
+ loop [] done = return (nodeMapElts done)
+ loop ((cur_path, wanted_mod, is_boot) : ss) done
+ | key `elemFM` done = loop ss done
+ | otherwise = do { mb_s <- summarise dflags old_summary_map
+ (Just cur_path) is_boot wanted_mod
+ ; case mb_s of
+ Nothing -> loop ss done
+ Just s -> loop (msImports s ++ ss)
+ (addToFM done key s) }
+ where
+ key = (wanted_mod, if is_boot then HsBootFile else HsSrcFile)
+
+msImports :: ModSummary -> [(FilePath, -- Importing module
+ Module, -- Imported module
+ IsBootInterface)] -- {-# SOURCE #-} import or not
+msImports s = [(f, m,True) | m <- ms_srcimps s]
+ ++ [(f, m,False) | m <- ms_imps s]
+ where
+ f = msHsFilePath s -- Keep the importing module for error reporting
+
-----------------------------------------------------------------------------
-- Summarising modules
-- We have two types of summarisation:
--
--- * Summarise a file. This is used for the root module passed to
--- cmLoadModule. The file is read, and used to determine the root
+-- * Summarise a file. This is used for the root module(s) passed to
+-- cmLoadModules. The file is read, and used to determine the root
-- module name. The module name may differ from the filename.
--
-- * Summarise a module. We are given a module name, and must provide
-- a summary. The finder is used to locate the file in which the module
-- resides.
-summariseFile :: FilePath -> IO ModSummary
-summariseFile file
- = do hspp_fn <- preprocess file
- modsrc <- readFile hspp_fn
-
- let (srcimps,imps,mod_name) = getImports modsrc
- (path, basename, ext) = splitFilename3 file
-
- Just (mod, location)
- <- mkHomeModuleLocn mod_name (path ++ '/':basename) file
-
- maybe_src_timestamp
+summariseFile :: DynFlags -> FilePath -> IO ModSummary
+-- Used for Haskell source only, I think
+-- We know the file name, and we know it exists,
+-- but we don't necessarily know the module name (might differ)
+summariseFile dflags file
+ = do (dflags', hspp_fn) <- preprocess dflags file
+ -- The dflags' contains the OPTIONS pragmas
+
+ -- Read the file into a buffer. We're going to cache
+ -- this buffer in the ModLocation (ml_hspp_buf) so that it
+ -- doesn't have to be slurped again when hscMain parses the
+ -- file later.
+ buf <- hGetStringBuffer hspp_fn
+ (srcimps,the_imps,mod) <- getImports dflags' buf hspp_fn
+
+ -- Make a ModLocation for this file
+ location <- mkHomeModLocation mod file
+
+ -- Tell the Finder cache where it is, so that subsequent calls
+ -- to findModule will find it, even if it's not on any search path
+ addHomeModuleToFinder mod location
+
+ src_timestamp
<- case ml_hs_file location of
- Nothing -> return Nothing
- Just src_fn -> maybe_getModificationTime src_fn
+ Nothing -> noHsFileErr Nothing mod
+ Just src_fn -> getModificationTime src_fn
- return (ModSummary mod
- location{ml_hspp_file=Just hspp_fn}
- srcimps imps
- maybe_src_timestamp)
+ return (ModSummary { ms_mod = mod, ms_hsc_src = HsSrcFile,
+ ms_location = location,
+ ms_hspp_file = Just hspp_fn,
+ ms_hspp_buf = Just buf,
+ ms_srcimps = srcimps, ms_imps = the_imps,
+ ms_hs_date = src_timestamp })
-- Summarise a module, and pick up source and timestamp.
-summarise :: Module -> ModuleLocation -> Maybe ModSummary
- -> IO (Maybe ModSummary)
-summarise mod location old_summary
- | isHomeModule mod
- = do let hs_fn = unJust "summarise" (ml_hs_file location)
-
- maybe_src_timestamp
- <- case ml_hs_file location of
- Nothing -> return Nothing
- Just src_fn -> maybe_getModificationTime src_fn
+summarise :: DynFlags
+ -> NodeMap ModSummary -- Map of old summaries
+ -> Maybe FilePath -- Importing module (for error messages)
+ -> IsBootInterface -- True <=> a {-# SOURCE #-} import
+ -> Module -- Imported module to be summarised
+ -> IO (Maybe ModSummary) -- Its new summary
+
+summarise dflags old_summary_map cur_mod is_boot wanted_mod
+ = do { found <- findModule dflags wanted_mod True {-explicit-}
+ ; case found of
+ Found location pkg
+ | isHomePackage pkg
+ -> do { summary <- do_summary location
+ ; return (Just summary) }
+ | otherwise
+ -> return Nothing -- Drop an external-package modules
+
+ err -> noModError dflags cur_mod wanted_mod err
+ }
+ where
+ hsc_src = if is_boot then HsBootFile else HsSrcFile
+
+ do_summary location
+ = do { -- Adjust location to point to the hs-boot source file,
+ -- hi file, object file, when is_boot says so
+ let location' | is_boot = addBootSuffixLocn location
+ | otherwise = location
+
+ -- Find the source file to summarise
+ ; src_fn <- case ml_hs_file location' of
+ Nothing -> noHsFileErr cur_mod wanted_mod
+ Just src_fn -> return src_fn
+
+ -- In the case of hs-boot files, check that it exists
+ -- The Finder was dealing only with the main source file
+ ; if is_boot then do
+ { exists <- doesFileExist src_fn
+ ; if exists then return ()
+ else noHsBootFileErr cur_mod src_fn }
+ else return ()
+
+ -- Find its timestamp
+ ; src_timestamp <- getModificationTime src_fn
+
+ -- return the cached summary if the source didn't change
+ ; case lookupFM old_summary_map (wanted_mod, hsc_src) of {
+ Just s | ms_hs_date s == src_timestamp -> return s;
+ _ -> do
+
+ -- Preprocess the source file
+ { (dflags', hspp_fn) <- preprocess dflags src_fn
+ -- The dflags' contains the OPTIONS pragmas
+
+ ; buf <- hGetStringBuffer hspp_fn
+ ; (srcimps, the_imps, mod_name) <- getImports dflags' buf hspp_fn
+
+ ; when (mod_name /= wanted_mod) $
+ throwDyn (ProgramError
+ (showSDoc (text src_fn
+ <> text ": file name does not match module name"
+ <+> quotes (ppr mod_name))))
+
+ ; return (ModSummary { ms_mod = wanted_mod,
+ ms_hsc_src = hsc_src,
+ ms_location = location',
+ ms_hspp_file = Just hspp_fn,
+ ms_hspp_buf = Just buf,
+ ms_srcimps = srcimps,
+ ms_imps = the_imps,
+ ms_hs_date = src_timestamp })
+ }}}
- -- return the cached summary if the source didn't change
- case old_summary of {
- Just s | ms_hs_date s == maybe_src_timestamp -> return Nothing;
- _ -> do
- hspp_fn <- preprocess hs_fn
- modsrc <- readFile hspp_fn
- let (srcimps,imps,mod_name) = getImports modsrc
+-----------------------------------------------------------------------------
+-- Error messages
+-----------------------------------------------------------------------------
- maybe_src_timestamp
- <- case ml_hs_file location of
- Nothing -> return Nothing
- Just src_fn -> maybe_getModificationTime src_fn
-
- when (mod_name /= moduleName mod) $
- throwDyn (OtherError
- (showSDoc (text "file name does not match module name: "
- <+> ppr (moduleName mod) <+> text "vs"
- <+> ppr mod_name)))
-
- return (Just (ModSummary mod location{ml_hspp_file=Just hspp_fn}
- srcimps imps
- maybe_src_timestamp))
- }
-
- | otherwise
- = return (Just (ModSummary mod location [] [] Nothing))
-
-maybe_getModificationTime :: FilePath -> IO (Maybe ClockTime)
-maybe_getModificationTime fn
- = (do time <- getModificationTime fn
- return (Just time))
- `catch`
- (\err -> return Nothing)
+noModError :: DynFlags -> Maybe FilePath -> Module -> FindResult -> IO ab
+-- ToDo: we don't have a proper line number for this error
+noModError dflags cur_mod wanted_mod err
+ = throwDyn $ ProgramError $ showSDoc $
+ vcat [cantFindError dflags wanted_mod err,
+ nest 2 (parens (pp_where cur_mod))]
+
+noHsFileErr :: Maybe FilePath -> Module -> IO a
+-- Complain about not being able to find an imported module
+noHsFileErr cur_mod mod
+ = throwDyn $ CmdLineError $ showSDoc $
+ vcat [text "No source file for module" <+> quotes (ppr mod),
+ nest 2 (parens (pp_where cur_mod))]
+
+noHsBootFileErr cur_mod path
+ = throwDyn $ CmdLineError $ showSDoc $
+ vcat [text "Can't find" <+> text path,
+ nest 2 (parens (pp_where cur_mod))]
+
+pp_where Nothing = text "one of the roots of the dependency analysis"
+pp_where (Just p) = text "imported from" <+> text p
+
+packageModErr mod
+ = throwDyn (CmdLineError (showSDoc (text "module" <+>
+ quotes (ppr mod) <+>
+ text "is a package module")))
+
+multiRootsErr mod files
+ = throwDyn (ProgramError (showSDoc (
+ text "module" <+> quotes (ppr mod) <+>
+ text "is defined in multiple files:" <+>
+ sep (map text files))))
+
+cyclicModuleErr :: [ModSummary] -> SDoc
+cyclicModuleErr ms
+ = hang (ptext SLIT("Module imports form a cycle for modules:"))
+ 2 (vcat (map show_one ms))
+ where
+ show_one ms = vcat [show_mod (ms_hsc_src ms) (ms_mod ms),
+ ptext SLIT("Imports:") <+>
+ (pp_imps HsBootFile (ms_srcimps ms)
+ $$ pp_imps HsSrcFile (ms_imps ms))]
+ show_mod hsc_src mod = ppr mod <> text (hscSourceString hsc_src)
+ pp_imps src mods = fsep (map (show_mod src) mods)
\end{code}
+