{-# LANGUAGE CPP #-} {-# LANGUAGE TupleSections #-} module DsUsage ( -- * Dependency/fingerprinting code (used by MkIface) mkUsageInfo, mkUsedNames, mkDependencies ) where #include "HsVersions.h" import GhcPrelude import DynFlags import HscTypes import TcRnTypes import Name import NameSet import Module import Outputable import Util import UniqSet import UniqFM import Fingerprint import Maybes import Packages import Finder import Control.Monad (filterM) import Data.List import Data.IORef import Data.Map (Map) import qualified Data.Map as Map import qualified Data.Set as Set import System.Directory import System.FilePath {- Note [Module self-dependency] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ RnNames.calculateAvails asserts the invariant that a module must not occur in its own dep_orphs or dep_finsts. However, if we aren't careful this can occur in the presence of hs-boot files: Consider that we have two modules, A and B, both with hs-boot files, A.hs contains a SOURCE import of B B.hs-boot contains a SOURCE import of A A.hs-boot declares an orphan instance A.hs defines the orphan instance In this case, B's dep_orphs will contain A due to its SOURCE import of A. Consequently, A will contain itself in its imp_orphs due to its import of B. This fact would end up being recorded in A's interface file. This would then break the invariant asserted by calculateAvails that a module does not itself in its dep_orphs. This was the cause of Trac #14128. -} -- | Extract information from the rename and typecheck phases to produce -- a dependencies information for the module being compiled. -- -- The first argument is additional dependencies from plugins mkDependencies :: InstalledUnitId -> [Module] -> TcGblEnv -> IO Dependencies mkDependencies iuid pluginModules (TcGblEnv{ tcg_mod = mod, tcg_imports = imports, tcg_th_used = th_var }) = do -- Template Haskell used? let (dep_plgins, ms) = unzip [ (moduleName mn, mn) | mn <- pluginModules ] plugin_dep_pkgs = filter (/= iuid) (map (toInstalledUnitId . moduleUnitId) ms) th_used <- readIORef th_var let dep_mods = modDepsElts (delFromUFM (imp_dep_mods imports) (moduleName mod)) -- M.hi-boot can be in the imp_dep_mods, but we must remove -- it before recording the modules on which this one depends! -- (We want to retain M.hi-boot in imp_dep_mods so that -- loadHiBootInterface can see if M's direct imports depend -- on M.hi-boot, and hence that we should do the hi-boot consistency -- check.) dep_orphs = filter (/= mod) (imp_orphs imports) -- We must also remove self-references from imp_orphs. See -- Note [Module self-dependency] raw_pkgs = foldr Set.insert (imp_dep_pkgs imports) plugin_dep_pkgs pkgs | th_used = Set.insert (toInstalledUnitId thUnitId) raw_pkgs | otherwise = raw_pkgs -- Set the packages required to be Safe according to Safe Haskell. -- See Note [RnNames . Tracking Trust Transitively] sorted_pkgs = sort (Set.toList pkgs) trust_pkgs = imp_trust_pkgs imports dep_pkgs' = map (\x -> (x, x `Set.member` trust_pkgs)) sorted_pkgs return Deps { dep_mods = dep_mods, dep_pkgs = dep_pkgs', dep_orphs = dep_orphs, dep_plgins = dep_plgins, dep_finsts = sortBy stableModuleCmp (imp_finsts imports) } -- sort to get into canonical order -- NB. remember to use lexicographic ordering mkUsedNames :: TcGblEnv -> NameSet mkUsedNames TcGblEnv{ tcg_dus = dus } = allUses dus mkUsageInfo :: HscEnv -> Module -> ImportedMods -> NameSet -> [FilePath] -> [(Module, Fingerprint)] -> [ModIface] -> IO [Usage] mkUsageInfo hsc_env this_mod dir_imp_mods used_names dependent_files merged pluginModules = do eps <- hscEPS hsc_env hashes <- mapM getFileHash dependent_files plugin_usages <- mapM (mkPluginUsage hsc_env) pluginModules let mod_usages = mk_mod_usage_info (eps_PIT eps) hsc_env this_mod dir_imp_mods used_names usages = mod_usages ++ [ UsageFile { usg_file_path = f , usg_file_hash = hash } | (f, hash) <- zip dependent_files hashes ] ++ [ UsageMergedRequirement { usg_mod = mod, usg_mod_hash = hash } | (mod, hash) <- merged ] ++ concat plugin_usages usages `seqList` return usages -- seq the list of Usages returned: occasionally these -- don't get evaluated for a while and we can end up hanging on to -- the entire collection of Ifaces. {- Note [Plugin dependencies] Modules for which plugins were used in the compilation process, should be recompiled whenever one of those plugins changes. But how do we know if a plugin changed from the previous time a module was compiled? We could try storing the fingerprints of the interface files of plugins in the interface file of the module. And see if there are changes between compilation runs. However, this is pretty much a non-option because interface fingerprints of plugin modules are fairly stable, unless you compile plugins with optimisations turned on, and give basically all binders an INLINE pragma. So instead: * For plugins that were built locally: we store the filepath and hash of the object files of the module with the `plugin` binder, and the object files of modules that are dependencies of the plugin module and belong to the same `UnitId` as the plugin * For plugins in an external package: we store the filepath and hash of the dynamic library containing the plugin module. During recompilation we then compare the hashes of those files again to see if anything has changed. One issue with this approach is that object files are currently (GHC 8.6.1) not created fully deterministicly, which could sometimes induce accidental recompilation of a module for which plugins were used in the compile process. One way to improve this is to either: * Have deterministic object file creation * Create and store implementation hashes, which would be based on the Core of the module and the implementation hashes of its dependencies, and then compare implementation hashes for recompilation. Creation of implementation hashes is however potentially expensive. -} mkPluginUsage :: HscEnv -> ModIface -> IO [Usage] mkPluginUsage hsc_env pluginModule = case lookupPluginModuleWithSuggestions dflags pNm Nothing of LookupFound _ pkg -> do -- The plugin is from an external package: -- search for the library files containing the plugin. let searchPaths = collectLibraryPaths dflags [pkg] useDyn = WayDyn `elem` ways dflags suffix = if useDyn then soExt platform else "a" libLocs = [ searchPath </> "lib" ++ libLoc <.> suffix | searchPath <- searchPaths , libLoc <- packageHsLibs dflags pkg ] -- we also try to find plugin library files by adding WayDyn way, -- if it isn't already present (see trac #15492) paths = if useDyn then libLocs else let dflags' = updateWays (addWay' WayDyn dflags) dlibLocs = [ searchPath </> mkHsSOName platform dlibLoc | searchPath <- searchPaths , dlibLoc <- packageHsLibs dflags' pkg ] in libLocs ++ dlibLocs files <- filterM doesFileExist paths case files of [] -> pprPanic ( "mkPluginUsage: missing plugin library, tried:\n" ++ unlines paths ) (ppr pNm) _ -> mapM hashFile (nub files) _ -> do foundM <- findPluginModule hsc_env pNm case foundM of -- The plugin was built locally: look up the object file containing -- the `plugin` binder, and all object files belong to modules that are -- transitive dependencies of the plugin that belong to the same package. Found ml _ -> do pluginObject <- hashFile (ml_obj_file ml) depObjects <- catMaybes <$> mapM lookupObjectFile deps return (nub (pluginObject : depObjects)) _ -> pprPanic "mkPluginUsage: no object file found" (ppr pNm) where dflags = hsc_dflags hsc_env platform = targetPlatform dflags pNm = moduleName (mi_module pluginModule) pPkg = moduleUnitId (mi_module pluginModule) deps = map fst (dep_mods (mi_deps pluginModule)) -- Lookup object file for a plugin dependency, -- from the same package as the plugin. lookupObjectFile nm = do foundM <- findImportedModule hsc_env nm Nothing case foundM of Found ml m | moduleUnitId m == pPkg -> Just <$> hashFile (ml_obj_file ml) | otherwise -> return Nothing _ -> pprPanic "mkPluginUsage: no object for dependency" (ppr pNm <+> ppr nm) hashFile f = do fExist <- doesFileExist f if fExist then do h <- getFileHash f return (UsageFile f h) else pprPanic "mkPluginUsage: file not found" (ppr pNm <+> text f) mk_mod_usage_info :: PackageIfaceTable -> HscEnv -> Module -> ImportedMods -> NameSet -> [Usage] mk_mod_usage_info pit hsc_env this_mod direct_imports used_names = mapMaybe mkUsage usage_mods where hpt = hsc_HPT hsc_env dflags = hsc_dflags hsc_env this_pkg = thisPackage dflags used_mods = moduleEnvKeys ent_map dir_imp_mods = moduleEnvKeys direct_imports all_mods = used_mods ++ filter (`notElem` used_mods) dir_imp_mods usage_mods = sortBy stableModuleCmp all_mods -- canonical order is imported, to avoid interface-file -- wobblage. -- ent_map groups together all the things imported and used -- from a particular module ent_map :: ModuleEnv [OccName] ent_map = nonDetFoldUniqSet add_mv emptyModuleEnv used_names -- nonDetFoldUFM is OK here. If you follow the logic, we sort by OccName -- in ent_hashs where add_mv name mv_map | isWiredInName name = mv_map -- ignore wired-in names | otherwise = case nameModule_maybe name of Nothing -> ASSERT2( isSystemName name, ppr name ) mv_map -- See Note [Internal used_names] Just mod -> -- See Note [Identity versus semantic module] let mod' = if isHoleModule mod then mkModule this_pkg (moduleName mod) else mod -- This lambda function is really just a -- specialised (++); originally came about to -- avoid quadratic behaviour (trac #2680) in extendModuleEnvWith (\_ xs -> occ:xs) mv_map mod' [occ] where occ = nameOccName name -- We want to create a Usage for a home module if -- a) we used something from it; has something in used_names -- b) we imported it, even if we used nothing from it -- (need to recompile if its export list changes: export_fprint) mkUsage :: Module -> Maybe Usage mkUsage mod | isNothing maybe_iface -- We can't depend on it if we didn't -- load its interface. || mod == this_mod -- We don't care about usages of -- things in *this* module = Nothing | moduleUnitId mod /= this_pkg = Just UsagePackageModule{ usg_mod = mod, usg_mod_hash = mod_hash, usg_safe = imp_safe } -- for package modules, we record the module hash only | (null used_occs && isNothing export_hash && not is_direct_import && not finsts_mod) = Nothing -- Record no usage info -- for directly-imported modules, we always want to record a usage -- on the orphan hash. This is what triggers a recompilation if -- an orphan is added or removed somewhere below us in the future. | otherwise = Just UsageHomeModule { usg_mod_name = moduleName mod, usg_mod_hash = mod_hash, usg_exports = export_hash, usg_entities = Map.toList ent_hashs, usg_safe = imp_safe } where maybe_iface = lookupIfaceByModule dflags hpt pit mod -- In one-shot mode, the interfaces for home-package -- modules accumulate in the PIT not HPT. Sigh. Just iface = maybe_iface finsts_mod = mi_finsts iface hash_env = mi_hash_fn iface mod_hash = mi_mod_hash iface export_hash | depend_on_exports = Just (mi_exp_hash iface) | otherwise = Nothing by_is_safe (ImportedByUser imv) = imv_is_safe imv by_is_safe _ = False (is_direct_import, imp_safe) = case lookupModuleEnv direct_imports mod of -- ezyang: I'm not sure if any is the correct -- metric here. If safety was guaranteed to be uniform -- across all imports, why did the old code only look -- at the first import? Just bys -> (True, any by_is_safe bys) Nothing -> (False, safeImplicitImpsReq dflags) -- Nothing case is for references to entities which were -- not directly imported (NB: the "implicit" Prelude import -- counts as directly imported! An entity is not directly -- imported if, e.g., we got a reference to it from a -- reexport of another module.) used_occs = lookupModuleEnv ent_map mod `orElse` [] -- Making a Map here ensures that (a) we remove duplicates -- when we have usages on several subordinates of a single parent, -- and (b) that the usages emerge in a canonical order, which -- is why we use Map rather than OccEnv: Map works -- using Ord on the OccNames, which is a lexicographic ordering. ent_hashs :: Map OccName Fingerprint ent_hashs = Map.fromList (map lookup_occ used_occs) lookup_occ occ = case hash_env occ of Nothing -> pprPanic "mkUsage" (ppr mod <+> ppr occ <+> ppr used_names) Just r -> r depend_on_exports = is_direct_import {- True Even if we used 'import M ()', we have to register a usage on the export list because we are sensitive to changes in orphan instances/rules. False In GHC 6.8.x we always returned true, and in fact it recorded a dependency on *all* the modules underneath in the dependency tree. This happens to make orphans work right, but is too expensive: it'll read too many interface files. The 'isNothing maybe_iface' check above saved us from generating many of these usages (at least in one-shot mode), but that's even more bogus! -}