\section[CompManager]{The Compilation Manager}
\begin{code}
-module CompManager ( cmInit, cmLoadModule,
+module CompManager ( cmInit, cmLoadModule,
+#ifdef GHCI
cmGetExpr, cmRunExpr,
+#endif
CmState, emptyCmState -- abstract
)
where
#include "HsVersions.h"
-import List ( nub )
-import Maybe ( catMaybes, maybeToList, fromMaybe )
+import CmLink
+import CmTypes
+import HscTypes
+import Module ( ModuleName, moduleName,
+ isModuleInThisPackage, moduleEnvElts,
+ moduleNameUserString )
+import CmStaticInfo ( PackageConfigInfo, GhciMode(..) )
+import DriverPipeline
+import GetImports
+import HscTypes ( HomeSymbolTable, HomeIfaceTable,
+ PersistentCompilerState, ModDetails(..) )
+import Name ( lookupNameEnv )
+import Module
+import PrelNames ( mainName )
+import HscMain ( initPersistentCompilerState )
+import Finder
+import UniqFM ( emptyUFM, lookupUFM, addToUFM, delListFromUFM,
+ UniqFM, listToUFM )
+import Unique ( Uniquable )
+import Digraph ( SCC(..), stronglyConnComp )
+import DriverPhases
+import DriverUtil ( BarfKind(..), splitFilename3 )
+import Util
import Outputable
-import UniqFM ( emptyUFM, lookupUFM, addToUFM, delListFromUFM )
-import Digraph ( SCC(..), stronglyConnComp, flattenSCC, flattenSCCs )
import Panic ( panic )
-import CmLink ( PersistentLinkerState, emptyPLS, Linkable(..),
- link, LinkResult(..),
- filterModuleLinkables, modname_of_linkable,
- is_package_linkable )
+#ifdef GHCI
+import CmdLineOpts ( DynFlags )
import Interpreter ( HValue )
-import CmSummarise ( summarise, ModSummary(..),
- name_of_summary, deps_of_summary,
- mimp_name, ms_get_imports )
-import Module ( ModuleName, moduleName, packageOfModule,
- isModuleInThisPackage, PackageName )
-import CmStaticInfo ( Package(..), PackageConfigInfo )
-import DriverPipeline ( compile, preprocess, CompResult(..) )
-import HscTypes ( HomeSymbolTable, HomeIfaceTable,
- PersistentCompilerState )
-import HscMain ( initPersistentCompilerState )
-import Finder ( findModule, emptyHomeDirCache )
+import HscMain ( hscExpr )
+import RdrName
+import PrelGHC ( unsafeCoerce# )
+#endif
+
+-- lang
+import Exception ( throwDyn )
+
+-- std
+import Time ( ClockTime )
+import Directory ( getModificationTime, doesFileExist )
+import IO
+import List ( nub )
+import Maybe ( catMaybes, fromMaybe, isJust )
\end{code}
-
\begin{code}
-cmInit :: PackageConfigInfo -> IO CmState
-cmInit raw_package_info
- = emptyCmState raw_package_info
+cmInit :: PackageConfigInfo -> GhciMode -> IO CmState
+cmInit raw_package_info gmode
+ = emptyCmState raw_package_info gmode
+#ifdef GHCI
cmGetExpr :: CmState
+ -> DynFlags
-> ModuleName
-> String
- -> IO (CmState, Either [SDoc] HValue)
-cmGetExpr cmstate modhdl expr
- = return (panic "cmGetExpr:unimp")
-
+ -> IO (CmState, Maybe HValue)
+cmGetExpr cmstate dflags modname expr
+ = do (new_pcs, maybe_unlinked_iexpr) <-
+ hscExpr dflags hst hit pcs (mkModuleInThisPackage modname) expr
+ case maybe_unlinked_iexpr of
+ Nothing -> return (cmstate{ pcs=new_pcs }, Nothing)
+ Just uiexpr -> do
+ hValue <- linkExpr pls uiexpr
+ return (cmstate{ pcs=new_pcs }, Just hValue)
+
+ -- ToDo: check that the module we passed in is sane/exists?
+ where
+ CmState{ pcs=pcs, pcms=pcms, pls=pls } = cmstate
+ PersistentCMState{ hst=hst, hit=hit } = pcms
+
+-- The HValue should represent a value of type IO () (Perhaps IO a?)
cmRunExpr :: HValue -> IO ()
cmRunExpr hval
- = return (panic "cmRunExpr:unimp")
-
+ = do unsafeCoerce# hval :: IO ()
+ -- putStrLn "done."
+#endif
-- Persistent state just for CM, excluding link & compile subsystems
data PersistentCMState
= PersistentCMState {
- hst :: HomeSymbolTable, -- home symbol table
- hit :: HomeIfaceTable, -- home interface table
- ui :: UnlinkedImage, -- the unlinked images
- mg :: ModuleGraph, -- the module graph
- pci :: PackageConfigInfo -- NEVER CHANGES
+ hst :: HomeSymbolTable, -- home symbol table
+ hit :: HomeIfaceTable, -- home interface table
+ ui :: UnlinkedImage, -- the unlinked images
+ mg :: ModuleGraph, -- the module graph
+ pci :: PackageConfigInfo, -- NEVER CHANGES
+ gmode :: GhciMode -- NEVER CHANGES
}
-emptyPCMS :: PackageConfigInfo -> PersistentCMState
-emptyPCMS pci
+emptyPCMS :: PackageConfigInfo -> GhciMode -> PersistentCMState
+emptyPCMS pci gmode
= PersistentCMState { hst = emptyHST, hit = emptyHIT,
- ui = emptyUI, mg = emptyMG, pci = pci }
+ ui = emptyUI, mg = emptyMG,
+ pci = pci, gmode = gmode }
emptyHIT :: HomeIfaceTable
emptyHIT = emptyUFM
pls :: PersistentLinkerState -- link's persistent state
}
-emptyCmState :: PackageConfigInfo -> IO CmState
-emptyCmState pci
- = do let pcms = emptyPCMS pci
+emptyCmState :: PackageConfigInfo -> GhciMode -> IO CmState
+emptyCmState pci gmode
+ = do let pcms = emptyPCMS pci gmode
pcs <- initPersistentCompilerState
pls <- emptyPLS
return (CmState { pcms = pcms,
emptyUI :: UnlinkedImage
emptyUI = []
-type ModuleGraph = [SCC ModSummary] -- the module graph, topologically sorted
+type ModuleGraph = [ModSummary] -- the module graph, topologically sorted
emptyMG :: ModuleGraph
emptyMG = []
\begin{code}
cmLoadModule :: CmState
- -> ModuleName
- -> IO (CmState, Maybe ModuleName)
+ -> FilePath
+ -> IO (CmState, -- new state
+ Bool, -- was successful
+ [ModuleName]) -- list of modules loaded
-cmLoadModule cmstate1 modname
+cmLoadModule cmstate1 rootname
= do -- version 1's are the original, before downsweep
- let pcms1 = pcms cmstate1
- let pls1 = pls cmstate1
- let pcs1 = pcs cmstate1
- let mg1 = mg pcms1
- let hst1 = hst pcms1
- let hit1 = hit pcms1
- let ui1 = ui pcms1
+ let pcms1 = pcms cmstate1
+ let pls1 = pls cmstate1
+ let pcs1 = pcs cmstate1
+ let mg1 = mg pcms1
+ let hst1 = hst pcms1
+ let hit1 = hit pcms1
+ let ui1 = ui pcms1
- let pcii = pci pcms1 -- this never changes
+ let pcii = pci pcms1 -- this never changes
+ let ghci_mode = gmode pcms1 -- ToDo: fix!
- -- do the downsweep to reestablish the module graph
+ -- Do the downsweep to reestablish the module graph
-- then generate version 2's by removing from HIT,HST,UI any
-- modules in the old MG which are not in the new one.
-- Throw away the old home dir cache
emptyHomeDirCache
- putStr "cmLoadModule: downsweep begins\n"
- mg2unsorted <- downsweep modname
- putStrLn (showSDoc (vcat (map ppr mg2unsorted)))
+ hPutStr stderr "cmLoadModule: downsweep begins\n"
+ mg2unsorted <- downsweep [rootname]
- let modnames1 = map name_of_summary (flattenSCCs mg1)
+ let modnames1 = map name_of_summary mg1
let modnames2 = map name_of_summary mg2unsorted
let mods_to_zap = filter (`notElem` modnames2) modnames1
let (hst2, hit2, ui2)
= removeFromTopLevelEnvs mods_to_zap (hst1, hit1, ui1)
-
- let mg2 = topological_sort mg2unsorted
-
- putStrLn "after tsort:\n"
- putStrLn (showSDoc (vcat (map ppr (flattenSCCs mg2))))
+ -- should be cycle free; ignores 'import source's
+ let mg2 = topological_sort False mg2unsorted
+ -- ... whereas this takes them into account. Used for
+ -- backing out partially complete cycles following a failed
+ -- upsweep, and for removing from hst/hit all the modules
+ -- not in strict downwards closure, during calls to compile.
+ let mg2_with_srcimps = topological_sort True mg2unsorted
+
+ let reachable_from :: ModuleName -> [ModuleName]
+ reachable_from = downwards_closure_of_module mg2unsorted
+
+ hPutStrLn stderr "after tsort:\n"
+ hPutStrLn stderr (showSDoc (vcat (map ppr mg2)))
+
+ -- Because we don't take into account source imports when doing
+ -- the topological sort, there shouldn't be any cycles in mg2.
+ -- If there is, we complain and give up -- the user needs to
+ -- break the cycle using a boot file.
-- Now do the upsweep, calling compile for each module in
-- turn. Final result is version 3 of everything.
- let threaded2 = ModThreaded pcs1 hst2 hit2
+ let threaded2 = CmThreaded pcs1 hst2 hit2
- (upsweepOK, threaded3, sccOKs, newLis)
- <- upsweep_sccs threaded2 [] [] mg2
+ (upsweep_complete_success, threaded3, modsDone, newLis)
+ <- upsweep_mods ghci_mode ui2 reachable_from threaded2 mg2
let ui3 = add_to_ui ui2 newLis
- let (ModThreaded pcs3 hst3 hit3) = threaded3
+ let (CmThreaded pcs3 hst3 hit3) = threaded3
+
+ -- At this point, modsDone and newLis should have the same
+ -- length, so there is one new (or old) linkable for each
+ -- mod which was processed (passed to compile).
-- Try and do linking in some form, depending on whether the
-- upsweep was completely or only partially successful.
- if upsweepOK
+ if upsweep_complete_success
then
- do let mods_to_relink = upwards_closure mg2
- (map modname_of_linkable newLis)
- pkg_linkables <- find_pkg_linkables_for pcii
- mg2 mods_to_relink
- putStrLn ("needed package modules =\n"
- ++ showSDoc (vcat (map ppr pkg_linkables)))
- let sccs_to_relink = group_uis ui3 mg2 mods_to_relink
- let all_to_relink = map AcyclicSCC pkg_linkables
- ++ sccs_to_relink
- linkresult <- link pcii all_to_relink pls1
+ -- Easy; just relink it all.
+ do hPutStrLn stderr "UPSWEEP COMPLETELY SUCCESSFUL"
+ linkresult
+ <- link ghci_mode (any exports_main (moduleEnvElts hst3))
+ newLis pls1
case linkresult of
LinkErrs _ _
-> panic "cmLoadModule: link failed (1)"
LinkOK pls3
-> do let pcms3 = PersistentCMState { hst=hst3, hit=hit3,
- ui=ui3, mg=mg2, pci=pcii }
+ ui=ui3, mg=modsDone,
+ pci=pcii, gmode=ghci_mode }
let cmstate3
= CmState { pcms=pcms3, pcs=pcs3, pls=pls3 }
- return (cmstate3, Just modname)
+ return (cmstate3, True, map name_of_summary modsDone)
else
- do let mods_to_relink = downwards_closure mg2
- (map name_of_summary (flattenSCCs sccOKs))
- pkg_linkables <- find_pkg_linkables_for pcii
- mg2 mods_to_relink
- let sccs_to_relink = group_uis ui3 mg2 mods_to_relink
- let all_to_relink = map AcyclicSCC pkg_linkables
- ++ sccs_to_relink
- linkresult <- link pcii all_to_relink pls1
+ -- Tricky. We need to back out the effects of compiling any
+ -- half-done cycles, both so as to clean up the top level envs
+ -- and to avoid telling the interactive linker to link them.
+ do hPutStrLn stderr "UPSWEEP PARTIALLY SUCCESSFUL"
+
+ let modsDone_names
+ = map name_of_summary modsDone
+ let mods_to_zap_names
+ = findPartiallyCompletedCycles modsDone_names mg2_with_srcimps
let (hst4, hit4, ui4)
- = removeFromTopLevelEnvs mods_to_relink (hst3,hit3,ui3)
+ = removeFromTopLevelEnvs mods_to_zap_names (hst3,hit3,ui3)
+ 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
+
+ linkresult <- link ghci_mode False linkables_to_link pls1
case linkresult of
LinkErrs _ _
-> panic "cmLoadModule: link failed (2)"
LinkOK pls4
-> do let pcms4 = PersistentCMState { hst=hst4, hit=hit4,
- ui=ui4, mg=mg2, pci=pcii }
+ ui=ui4, mg=mods_to_keep,
+ pci=pcii, gmode=ghci_mode }
let cmstate4
= CmState { pcms=pcms4, pcs=pcs3, pls=pls4 }
- return (cmstate4, Just modname)
-
-
--- Given a (home) module graph and a bunch of names of (home) modules
--- within that graph, return the names of any packages needed by the
--- named modules. Do this by looking at their imports. Assumes, and
--- checks, that all of "mods" are mentioned in "mg".
---
--- Then, having found the packages directly needed by "mods",
--- (1) round up, by looking in "pci", all packages they directly or
--- indirectly depend on, and (2) put these packages in topological
--- order, since that's important for some linkers. Since cycles in
--- the package dependency graph aren't allowed, we can just return
--- the list of (package) linkables, rather than a list of SCCs.
-find_pkg_linkables_for :: PackageConfigInfo -> [SCC ModSummary] -> [ModuleName]
- -> IO [Linkable]
-find_pkg_linkables_for pcii mg mods
- = let mg_summaries = flattenSCCs mg
- mg_names = map name_of_summary mg_summaries
- in
- -- Assert that the modules for which we seek the required packages
- -- are all in the module graph, i.e. are all home modules.
- if not (all (`elem` mg_names) mods)
- then panic "find_pkg_linkables_for"
- else
- do let all_imports
- = concat
- [deps_of_summary summ
- | summ <- mg_summaries, name_of_summary summ `elem` mods]
- let imports_not_in_home -- imports which must be from packages
- = nub (filter (`notElem` mg_names) all_imports)
-
- -- Figure out the packages directly imported by the home modules
- maybe_locs_n_mods <- mapM findModule imports_not_in_home
- let home_pkgs_needed
- = nub (concatMap get_pkg maybe_locs_n_mods)
- where get_pkg Nothing = []
- get_pkg (Just (mod, loc))
- = case packageOfModule mod of
- Just p -> [p]; _ -> []
-
- -- Discover the package dependency graph, and use it to find the
- -- transitive closure of all the needed packages
- let pkg_depend_graph :: [(PackageName,[PackageName])]
- pkg_depend_graph = map (\pkg -> (_PK_ (name pkg), map _PK_ (package_deps pkg))) pcii
-
- let all_pkgs_needed = simple_transitive_closure
- pkg_depend_graph home_pkgs_needed
-
- -- Make a graph, in the style which Digraph.stronglyConnComp expects,
- -- containing entries only for the needed packages.
- let needed_graph
- = concat
- [if srcP `elem` all_pkgs_needed
- then [(srcP, srcP, dstsP)]
- else []
- | (srcP, dstsP) <- pkg_depend_graph]
- tsorted = flattenSCCs (stronglyConnComp needed_graph)
-
- return (map LP tsorted)
+ return (cmstate4, False, mods_to_keep_names)
-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
-
-
--- For each module in mods_to_group, extract the relevant linkable
--- out of "ui", and arrange these linkables in SCCs as defined by modGraph.
--- All this is so that we can pass SCCified Linkable groups to the
--- linker. A constraint that should be recorded somewhere is that
--- all sccs should either be all-interpreted or all-object, not a mixture.
-group_uis :: UnlinkedImage -> [SCC ModSummary] -> [ModuleName] -> [SCC Linkable]
-group_uis ui modGraph mods_to_group
- = map extract (cleanup (fishOut modGraph mods_to_group))
+-- Return (names of) all those in modsDone who are part of a cycle
+-- as defined by theGraph.
+findPartiallyCompletedCycles :: [ModuleName] -> [SCC ModSummary] -> [ModuleName]
+findPartiallyCompletedCycles modsDone theGraph
+ = chew theGraph
where
- fishOut :: [SCC ModSummary] -> [ModuleName] -> [(Bool,[ModuleName])]
- fishOut [] unused
- | null unused = []
- | otherwise = panic "group_uis: modnames not in modgraph"
- fishOut ((AcyclicSCC ms):sccs) unused
- = case split (== (name_of_summary ms)) unused of
- (eq, not_eq) -> (False, eq) : fishOut sccs not_eq
- fishOut ((CyclicSCC mss):sccs) unused
- = case split (`elem` (map name_of_summary mss)) unused of
- (eq, not_eq) -> (True, eq) : fishOut sccs not_eq
-
- cleanup :: [(Bool,[ModuleName])] -> [SCC ModuleName]
- cleanup [] = []
- cleanup ((isRec,names):rest)
- | null names = cleanup rest
- | isRec = CyclicSCC names : cleanup rest
- | not isRec = case names of [name] -> AcyclicSCC name : cleanup rest
- other -> panic "group_uis(cleanup)"
-
- extract :: SCC ModuleName -> SCC Linkable
- extract (AcyclicSCC nm) = AcyclicSCC (getLi nm)
- extract (CyclicSCC nms) = CyclicSCC (map getLi nms)
-
- getLi nm = case [li | li <- ui, not (is_package_linkable li),
- nm == modname_of_linkable li] of
- [li] -> li
- other -> panic "group_uis:getLi"
-
- split f xs = (filter f xs, filter (not.f) xs)
+ 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)
+ 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)
+ && length mods_in_this_cycle < length names_in_this_cycle
+ then mods_in_this_cycle ++ chewed_rest
+ else chewed_rest
+
+
+-- Does this ModDetails export Main.main?
+exports_main :: ModDetails -> Bool
+exports_main md
+ = isJust (lookupNameEnv (md_types md) mainName)
-- Add the given (LM-form) Linkables to the UI, overwriting previous
&& modname_of_linkable li1 == modname_of_linkable li2
--- Compute upwards and downwards closures in the (home-) module graph.
-downwards_closure,
- upwards_closure :: [SCC ModSummary] -> [ModuleName] -> [ModuleName]
-
-upwards_closure = up_down_closure True
-downwards_closure = up_down_closure False
-
-up_down_closure :: Bool -> [SCC ModSummary] -> [ModuleName] -> [ModuleName]
-up_down_closure up modGraph roots
- = let mgFlat = flattenSCCs modGraph
- nodes = map name_of_summary mgFlat
-
- fwdEdges, backEdges :: [(ModuleName, [ModuleName])]
- -- have an entry for each mod in mgFlat, and do not
- -- mention edges leading out of the home package
- fwdEdges
- = map mkEdge mgFlat
- backEdges -- Only calculated if needed, which is just as well!
- = [(n, [m | (m, m_imports) <- fwdEdges, n `elem` m_imports])
- | (n, n_imports) <- fwdEdges]
-
- mkEdge summ
- = (name_of_summary summ,
- -- ignore imports not from the home package
- filter (`elem` nodes) (deps_of_summary summ))
- in
- simple_transitive_closure
- (if up then backEdges else fwdEdges) (nub roots)
-
+data CmThreaded -- stuff threaded through individual module compilations
+ = CmThreaded PersistentCompilerState HomeSymbolTable HomeIfaceTable
-data ModThreaded -- stuff threaded through individual module compilations
- = ModThreaded PersistentCompilerState HomeSymbolTable HomeIfaceTable
-
--- Compile multiple SCCs, stopping as soon as an error appears
-upsweep_sccs :: ModThreaded -- PCS & HST & HIT
- -> [SCC ModSummary] -- accum: SCCs which succeeded
- -> [Linkable] -- accum: new Linkables
- -> [SCC ModSummary] -- SCCs to do (the worklist)
+-- 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
+ -> UnlinkedImage -- old linkables
+ -> (ModuleName -> [ModuleName]) -- to construct downward closures
+ -> CmThreaded -- PCS & HST & HIT
+ -> [SCC ModSummary] -- mods to do (the worklist)
-- ...... RETURNING ......
- -> IO (Bool{-success?-},
- ModThreaded,
- [SCC ModSummary], -- SCCs which succeeded
+ -> IO (Bool{-complete success?-},
+ CmThreaded,
+ [ModSummary], -- mods which succeeded
[Linkable]) -- new linkables
-upsweep_sccs threaded sccOKs newLis []
- = -- No more SCCs to do.
- return (True, threaded, sccOKs, newLis)
-
-upsweep_sccs threaded sccOKs newLis (scc:sccs)
- = -- Start work on a new SCC.
- do (sccOK, threaded2, lisSCC)
- <- upsweep_scc threaded (flattenSCC scc)
- if sccOK
- then -- all the modules in the scc were ok
- -- move on to the next SCC
- upsweep_sccs threaded2
- (scc:sccOKs) (lisSCC++newLis) sccs
- else -- we got a compilation error; give up now
- return
- (False, threaded2, sccOKs, lisSCC++newLis)
-
-
--- Compile multiple modules (one SCC), stopping as soon as an error appears
-upsweep_scc :: ModThreaded
- -> [ModSummary]
- -> IO (Bool{-success?-}, ModThreaded, [Linkable])
-upsweep_scc threaded []
- = return (True, threaded, [])
-upsweep_scc threaded (mod:mods)
- = do (moduleOK, threaded1, maybe_linkable)
- <- upsweep_mod threaded mod
- if moduleOK
- then -- No errors; get contribs from the rest
- do (restOK, threaded2, linkables)
- <- upsweep_scc threaded1 mods
- return
- (restOK, threaded2, maybeToList maybe_linkable ++ linkables)
- else -- Errors; give up _now_
- return (False, threaded1, [])
-
--- Compile a single module.
-upsweep_mod :: ModThreaded
+upsweep_mods ghci_mode oldUI reachable_from threaded
+ []
+ = return (True, threaded, [], [])
+
+upsweep_mods ghci_mode oldUI reachable_from threaded
+ ((CyclicSCC ms):_)
+ = do hPutStrLn stderr ("ghc: module imports form a cycle for modules:\n\t" ++
+ unwords (map (moduleNameUserString.name_of_summary) ms))
+ return (False, threaded, [], [])
+
+upsweep_mods ghci_mode oldUI reachable_from threaded
+ ((AcyclicSCC mod):mods)
+ = do (threaded1, maybe_linkable)
+ <- upsweep_mod ghci_mode 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 oldUI reachable_from
+ threaded1 mods
+ return (restOK, threaded2, mod:modOKs, linkable:linkables)
+ Nothing -- we got a compilation error; give up now
+ -> return (False, threaded1, [], [])
+
+
+-- Compile a single module. Always produce a Linkable for it if
+-- successful. If no compilation happened, return the old Linkable.
+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]))
+
+
+upsweep_mod :: GhciMode
+ -> UnlinkedImage
+ -> CmThreaded
-> ModSummary
- -> IO (Bool{-success?-}, ModThreaded, Maybe Linkable)
+ -> [ModuleName]
+ -> IO (CmThreaded, Maybe Linkable)
-upsweep_mod threaded1 summary1
+upsweep_mod ghci_mode oldUI threaded1 summary1 reachable_from_here
= do let mod_name = name_of_summary summary1
- let (ModThreaded pcs1 hst1 hit1) = threaded1
+ let (CmThreaded pcs1 hst1 hit1) = threaded1
let old_iface = lookupUFM hit1 (name_of_summary summary1)
- compresult <- compile summary1 old_iface hst1 hit1 pcs1
+
+ -- We *have* to compile it if we're in batch mode and we can't see
+ -- a previous linkable for it on disk.
+ compilation_mandatory
+ <- if ghci_mode /= Batch then return False
+ else case ml_obj_file (ms_location summary1) of
+ Nothing -> do --putStrLn "cmcm: object?!"
+ return True
+ Just obj_fn -> do --putStrLn ("cmcm: old obj " ++ obj_fn)
+ b <- doesFileExist obj_fn
+ return (not b)
+
+ let maybe_oldUI_linkable = findModuleLinkable_maybe oldUI mod_name
+ maybe_oldDisk_linkable
+ <- case ml_obj_file (ms_location summary1) of
+ Nothing -> return Nothing
+ Just obj_fn -> maybe_getFileLinkable mod_name obj_fn
+
+ -- 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 maybe_old_linkable
+ = case (maybe_oldUI_linkable, maybe_oldDisk_linkable) of
+ (Nothing, Nothing) -> Nothing
+ (Nothing, Just di) -> Just di
+ (Just ui, Nothing) -> Just ui
+ (Just ui, Just di)
+ | linkableTime ui >= linkableTime di -> Just ui
+ | otherwise -> Just di
+
+ let compilation_mandatory
+ = case maybe_old_linkable of
+ Nothing -> True
+ Just li -> case ms_hs_date summary1 of
+ Nothing -> panic "compilation_mandatory:no src date"
+ Just src_date -> src_date >= linkableTime li
+ source_unchanged
+ = not compilation_mandatory
+
+ (hst1_strictDC, hit1_strictDC)
+ = retainInTopLevelEnvs reachable_from_here (hst1,hit1)
+
+ old_linkable
+ = unJust "upsweep_mod:old_linkable" maybe_old_linkable
+
+ compresult <- compile ghci_mode summary1 source_unchanged
+ old_iface hst1_strictDC hit1_strictDC pcs1
case compresult of
-- linkable, meaning that compilation wasn't needed, and the
-- new details were manufactured from the old iface.
CompOK details Nothing pcs2
- -> let hst2 = addToUFM hst1 mod_name details
- hit2 = hit1
- threaded2 = ModThreaded pcs2 hst2 hit2
- in return (True, threaded2, Nothing)
+ -> let hst2 = addToUFM hst1 mod_name details
+ hit2 = hit1
+ threaded2 = CmThreaded pcs2 hst2 hit2
+ in return (threaded2, Just old_linkable)
-- Compilation really did happen, and succeeded. A new
-- details, iface and linkable are returned.
CompOK details (Just (new_iface, new_linkable)) pcs2
-> let hst2 = addToUFM hst1 mod_name details
hit2 = addToUFM hit1 mod_name new_iface
- threaded2 = ModThreaded pcs2 hst2 hit2
- in return (True, threaded2, Just new_linkable)
+ threaded2 = CmThreaded pcs2 hst2 hit2
+ in return (threaded2, Just new_linkable)
-- Compilation failed. compile may still have updated
-- the PCS, tho.
CompErrs pcs2
- -> let threaded2 = ModThreaded pcs2 hst1 hit1
- in return (False, threaded2, Nothing)
+ -> let threaded2 = CmThreaded pcs2 hst1 hit1
+ in return (threaded2, Nothing)
+-- Remove unwanted modules from the top level envs (HST, HIT, UI).
removeFromTopLevelEnvs :: [ModuleName]
-> (HomeSymbolTable, HomeIfaceTable, UnlinkedImage)
-> (HomeSymbolTable, HomeIfaceTable, UnlinkedImage)
filterModuleLinkables (`notElem` zap_these) ui
)
-topological_sort :: [ModSummary] -> [SCC ModSummary]
-topological_sort summaries
+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_srcimps summ ++ ms_imps 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, deps_of_summary 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
in
sccs
-downsweep :: ModuleName -- module to chase from
- -> IO [ModSummary]
+
+-- Chase downwards from the specified root set, returning summaries
+-- for all home modules encountered. Only follow source-import
+-- links.
+downsweep :: [FilePath] -> IO [ModSummary]
downsweep rootNm
- = do rootLoc <- getSummary rootNm
- loop [rootLoc]
+ = do rootSummaries <- mapM getRootSummary rootNm
+ loop (filter (isModuleInThisPackage.ms_mod) rootSummaries)
where
+ getRootSummary :: FilePath -> IO ModSummary
+ getRootSummary file
+ | haskellish_file file
+ = do exists <- doesFileExist file
+ if exists then summariseFile file
+ else getSummary (mkModuleName file)
+ -- ToDo: should check import paths
+ | otherwise
+ = getSummary (mkModuleName file)
+
getSummary :: ModuleName -> IO ModSummary
getSummary nm
| trace ("getSummary: "++ showSDoc (ppr nm)) True
= do found <- findModule nm
case found of
- Just (mod, location) -> summarise preprocess mod location
- Nothing -> panic ("CompManager: can't find module `" ++
- showSDoc (ppr nm) ++ "'")
-
+ -- Be sure not to use the mod and location passed in to
+ -- summarise for any other purpose -- summarise may change
+ -- the module names in them if name of module /= name of file,
+ -- and put the changed versions in the returned summary.
+ -- These will then conflict with the passed-in versions.
+ Just (mod, location) -> summarise mod location
+ Nothing -> throwDyn (OtherError
+ ("no signs of life for module `"
+ ++ showSDoc (ppr nm) ++ "'"))
+
-- loop invariant: homeSummaries doesn't contain package modules
loop :: [ModSummary] -> IO [ModSummary]
loop homeSummaries
= do let allImps :: [ModuleName]
- allImps -- all imports
- = (nub . map mimp_name . concat . map ms_get_imports)
- homeSummaries
+ allImps = (nub . concatMap ms_imps) homeSummaries
let allHome -- all modules currently in homeSummaries
= map (moduleName.ms_mod) homeSummaries
let neededImps
if null newHomeSummaries
then return homeSummaries
else loop (newHomeSummaries ++ homeSummaries)
+
+
+-----------------------------------------------------------------------------
+-- 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
+-- 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
+ <- case ml_hs_file location of
+ Nothing -> return Nothing
+ Just src_fn -> maybe_getModificationTime src_fn
+
+ return (ModSummary mod
+ location{ml_hspp_file=Just hspp_fn}
+ srcimps imps
+ maybe_src_timestamp)
+
+-- Summarise a module, and pick up source and interface timestamps.
+summarise :: Module -> ModuleLocation -> IO ModSummary
+summarise mod location
+ | isModuleInThisPackage mod
+ = do let hs_fn = unJust "summarise" (ml_hs_file location)
+ hspp_fn <- preprocess hs_fn
+ modsrc <- readFile hspp_fn
+ let (srcimps,imps,mod_name) = getImports modsrc
+
+ maybe_src_timestamp
+ <- case ml_hs_file location of
+ Nothing -> return Nothing
+ Just src_fn -> maybe_getModificationTime src_fn
+
+ if mod_name == moduleName mod
+ then return ()
+ else throwDyn (OtherError
+ (showSDoc (text "file name does not match module name: "
+ <+> ppr (moduleName mod) <+> text "vs"
+ <+> ppr mod_name)))
+
+ return (ModSummary mod location{ml_hspp_file=Just hspp_fn}
+ srcimps imps
+ maybe_src_timestamp)
+
+ | otherwise
+ = return (ModSummary mod location [] [] Nothing)
+
+maybe_getModificationTime :: FilePath -> IO (Maybe ClockTime)
+maybe_getModificationTime fn
+ = (do time <- getModificationTime fn
+ return (Just time))
+ `catch`
+ (\err -> return Nothing)
\end{code}