#include "local-store.hh" #include "globals.hh" #include "git.hh" #include "archive.hh" #include "pathlocks.hh" #include "worker-protocol.hh" #include "derivations.hh" #include "realisation.hh" #include "nar-info.hh" #include "references.hh" #include "callback.hh" #include "topo-sort.hh" #include "finally.hh" #include "compression.hh" #include "signals.hh" #include "posix-fs-canonicalise.hh" #include "posix-source-accessor.hh" #include "keys.hh" #include "users.hh" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef _WIN32 # include #endif #if __linux__ # include # include # include # include #endif #ifdef __CYGWIN__ # include #endif #include #include "strings.hh" namespace nix { LocalStoreConfig::LocalStoreConfig( std::string_view scheme, std::string_view authority, const Params & params) : StoreConfig(params) , LocalFSStoreConfig(authority, params) { } std::string LocalStoreConfig::doc() { return #include "local-store.md" ; } struct LocalStore::State::Stmts { /* Some precompiled SQLite statements. */ SQLiteStmt RegisterValidPath; SQLiteStmt UpdatePathInfo; SQLiteStmt AddReference; SQLiteStmt QueryPathInfo; SQLiteStmt QueryReferences; SQLiteStmt QueryReferrers; SQLiteStmt InvalidatePath; SQLiteStmt AddDerivationOutput; SQLiteStmt RegisterRealisedOutput; SQLiteStmt UpdateRealisedOutput; SQLiteStmt QueryValidDerivers; SQLiteStmt QueryDerivationOutputs; SQLiteStmt QueryRealisedOutput; SQLiteStmt QueryAllRealisedOutputs; SQLiteStmt QueryPathFromHashPart; SQLiteStmt QueryValidPaths; SQLiteStmt QueryRealisationReferences; SQLiteStmt AddRealisationReference; }; int getSchema(Path schemaPath) { int curSchema = 0; if (pathExists(schemaPath)) { auto s = readFile(schemaPath); auto n = string2Int(s); if (!n) throw Error("'%1%' is corrupt", schemaPath); curSchema = *n; } return curSchema; } void migrateCASchema(SQLite& db, Path schemaPath, AutoCloseFD& lockFd) { const int nixCASchemaVersion = 4; int curCASchema = getSchema(schemaPath); if (curCASchema != nixCASchemaVersion) { if (curCASchema > nixCASchemaVersion) { throw Error("current Nix store ca-schema is version %1%, but I only support %2%", curCASchema, nixCASchemaVersion); } if (!lockFile(lockFd.get(), ltWrite, false)) { printInfo("waiting for exclusive access to the Nix store for ca drvs..."); lockFile(lockFd.get(), ltNone, false); // We have acquired a shared lock; release it to prevent deadlocks lockFile(lockFd.get(), ltWrite, true); } if (curCASchema == 0) { static const char schema[] = #include "ca-specific-schema.sql.gen.hh" ; db.exec(schema); curCASchema = nixCASchemaVersion; } if (curCASchema < 2) { SQLiteTxn txn(db); // Ugly little sql dance to add a new `id` column and make it the primary key db.exec(R"( create table Realisations2 ( id integer primary key autoincrement not null, drvPath text not null, outputName text not null, -- symbolic output id, usually "out" outputPath integer not null, signatures text, -- space-separated list foreign key (outputPath) references ValidPaths(id) on delete cascade ); insert into Realisations2 (drvPath, outputName, outputPath, signatures) select drvPath, outputName, outputPath, signatures from Realisations; drop table Realisations; alter table Realisations2 rename to Realisations; )"); db.exec(R"( create index if not exists IndexRealisations on Realisations(drvPath, outputName); create table if not exists RealisationsRefs ( referrer integer not null, realisationReference integer, foreign key (referrer) references Realisations(id) on delete cascade, foreign key (realisationReference) references Realisations(id) on delete restrict ); )"); txn.commit(); } if (curCASchema < 3) { SQLiteTxn txn(db); // Apply new indices added in this schema update. db.exec(R"( -- used by QueryRealisationReferences create index if not exists IndexRealisationsRefs on RealisationsRefs(referrer); -- used by cascade deletion when ValidPaths is deleted create index if not exists IndexRealisationsRefsOnOutputPath on Realisations(outputPath); )"); txn.commit(); } if (curCASchema < 4) { SQLiteTxn txn(db); db.exec(R"( create trigger if not exists DeleteSelfRefsViaRealisations before delete on ValidPaths begin delete from RealisationsRefs where realisationReference in ( select id from Realisations where outputPath = old.id ); end; -- used by deletion trigger create index if not exists IndexRealisationsRefsRealisationReference on RealisationsRefs(realisationReference); )"); txn.commit(); } writeFile(schemaPath, fmt("%d", nixCASchemaVersion), 0666, true); lockFile(lockFd.get(), ltRead, true); } } LocalStore::LocalStore( std::string_view scheme, PathView path, const Params & params) : StoreConfig(params) , LocalFSStoreConfig(path, params) , LocalStoreConfig(scheme, path, params) , Store(params) , LocalFSStore(params) , dbDir(stateDir + "/db") , linksDir(realStoreDir + "/.links") , reservedPath(dbDir + "/reserved") , schemaPath(dbDir + "/schema") , tempRootsDir(stateDir + "/temproots") , fnTempRoots(fmt("%s/%d", tempRootsDir, getpid())) , locksHeld(tokenizeString(getEnv("NIX_HELD_LOCKS").value_or(""))) { auto state(_state.lock()); state->stmts = std::make_unique(); /* Create missing state directories if they don't already exist. */ createDirs(realStoreDir); if (readOnly) { experimentalFeatureSettings.require(Xp::ReadOnlyLocalStore); } else { makeStoreWritable(); } createDirs(linksDir); Path profilesDir = stateDir + "/profiles"; createDirs(profilesDir); createDirs(tempRootsDir); createDirs(dbDir); Path gcRootsDir = stateDir + "/gcroots"; if (!pathExists(gcRootsDir)) { createDirs(gcRootsDir); createSymlink(profilesDir, gcRootsDir + "/profiles"); } for (auto & perUserDir : {profilesDir + "/per-user", gcRootsDir + "/per-user"}) { createDirs(perUserDir); if (!readOnly) { if (chmod(perUserDir.c_str(), 0755) == -1) throw SysError("could not set permissions on '%s' to 755", perUserDir); } } #ifndef _WIN32 /* Optionally, create directories and set permissions for a multi-user install. */ if (isRootUser() && settings.buildUsersGroup != "") { mode_t perm = 01775; struct group * gr = getgrnam(settings.buildUsersGroup.get().c_str()); if (!gr) printError("warning: the group '%1%' specified in 'build-users-group' does not exist", settings.buildUsersGroup); else if (!readOnly) { struct stat st; if (stat(realStoreDir.get().c_str(), &st)) throw SysError("getting attributes of path '%1%'", realStoreDir); if (st.st_uid != 0 || st.st_gid != gr->gr_gid || (st.st_mode & ~S_IFMT) != perm) { if (chown(realStoreDir.get().c_str(), 0, gr->gr_gid) == -1) throw SysError("changing ownership of path '%1%'", realStoreDir); if (chmod(realStoreDir.get().c_str(), perm) == -1) throw SysError("changing permissions on path '%1%'", realStoreDir); } } } #endif /* Ensure that the store and its parents are not symlinks. */ if (!settings.allowSymlinkedStore) { Path path = realStoreDir; struct stat st; while (path != "/") { st = lstat(path); if (S_ISLNK(st.st_mode)) throw Error( "the path '%1%' is a symlink; " "this is not allowed for the Nix store and its parent directories", path); path = dirOf(path); } } /* We can't open a SQLite database if the disk is full. Since this prevents the garbage collector from running when it's most needed, we reserve some dummy space that we can free just before doing a garbage collection. */ try { struct stat st; if (stat(reservedPath.c_str(), &st) == -1 || st.st_size != settings.reservedSize) { AutoCloseFD fd = toDescriptor(open(reservedPath.c_str(), O_WRONLY | O_CREAT #ifndef _WIN32 | O_CLOEXEC #endif , 0600)); int res = -1; #if HAVE_POSIX_FALLOCATE res = posix_fallocate(fd.get(), 0, settings.reservedSize); #endif if (res == -1) { writeFull(fd.get(), std::string(settings.reservedSize, 'X')); [[gnu::unused]] auto res2 = #ifdef _WIN32 SetEndOfFile(fd.get()) #else ftruncate(fd.get(), settings.reservedSize) #endif ; } } } catch (SystemError & e) { /* don't care about errors */ } /* Acquire the big fat lock in shared mode to make sure that no schema upgrade is in progress. */ if (!readOnly) { Path globalLockPath = dbDir + "/big-lock"; globalLock = openLockFile(globalLockPath.c_str(), true); } if (!readOnly && !lockFile(globalLock.get(), ltRead, false)) { printInfo("waiting for the big Nix store lock..."); lockFile(globalLock.get(), ltRead, true); } /* Check the current database schema and if necessary do an upgrade. */ int curSchema = getSchema(); if (readOnly && curSchema < nixSchemaVersion) { debug("current schema version: %d", curSchema); debug("supported schema version: %d", nixSchemaVersion); throw Error(curSchema == 0 ? "database does not exist, and cannot be created in read-only mode" : "database schema needs migrating, but this cannot be done in read-only mode"); } if (curSchema > nixSchemaVersion) throw Error("current Nix store schema is version %1%, but I only support %2%", curSchema, nixSchemaVersion); else if (curSchema == 0) { /* new store */ curSchema = nixSchemaVersion; openDB(*state, true); writeFile(schemaPath, fmt("%1%", nixSchemaVersion), 0666, true); } else if (curSchema < nixSchemaVersion) { if (curSchema < 5) throw Error( "Your Nix store has a database in Berkeley DB format,\n" "which is no longer supported. To convert to the new format,\n" "please upgrade Nix to version 0.12 first."); if (curSchema < 6) throw Error( "Your Nix store has a database in flat file format,\n" "which is no longer supported. To convert to the new format,\n" "please upgrade Nix to version 1.11 first."); if (!lockFile(globalLock.get(), ltWrite, false)) { printInfo("waiting for exclusive access to the Nix store..."); lockFile(globalLock.get(), ltNone, false); // We have acquired a shared lock; release it to prevent deadlocks lockFile(globalLock.get(), ltWrite, true); } /* Get the schema version again, because another process may have performed the upgrade already. */ curSchema = getSchema(); if (curSchema < 7) { upgradeStore7(); } openDB(*state, false); if (curSchema < 8) { SQLiteTxn txn(state->db); state->db.exec("alter table ValidPaths add column ultimate integer"); state->db.exec("alter table ValidPaths add column sigs text"); txn.commit(); } if (curSchema < 9) { SQLiteTxn txn(state->db); state->db.exec("drop table FailedPaths"); txn.commit(); } if (curSchema < 10) { SQLiteTxn txn(state->db); state->db.exec("alter table ValidPaths add column ca text"); txn.commit(); } writeFile(schemaPath, fmt("%1%", nixSchemaVersion), 0666, true); lockFile(globalLock.get(), ltRead, true); } else openDB(*state, false); if (experimentalFeatureSettings.isEnabled(Xp::CaDerivations)) { if (!readOnly) { migrateCASchema(state->db, dbDir + "/ca-schema", globalLock); } else { throw Error("need to migrate to content-addressed schema, but this cannot be done in read-only mode"); } } /* Prepare SQL statements. */ state->stmts->RegisterValidPath.create(state->db, "insert into ValidPaths (path, hash, registrationTime, deriver, narSize, ultimate, sigs, ca) values (?, ?, ?, ?, ?, ?, ?, ?);"); state->stmts->UpdatePathInfo.create(state->db, "update ValidPaths set narSize = ?, hash = ?, ultimate = ?, sigs = ?, ca = ? where path = ?;"); state->stmts->AddReference.create(state->db, "insert or replace into Refs (referrer, reference) values (?, ?);"); state->stmts->QueryPathInfo.create(state->db, "select id, hash, registrationTime, deriver, narSize, ultimate, sigs, ca from ValidPaths where path = ?;"); state->stmts->QueryReferences.create(state->db, "select path from Refs join ValidPaths on reference = id where referrer = ?;"); state->stmts->QueryReferrers.create(state->db, "select path from Refs join ValidPaths on referrer = id where reference = (select id from ValidPaths where path = ?);"); state->stmts->InvalidatePath.create(state->db, "delete from ValidPaths where path = ?;"); state->stmts->AddDerivationOutput.create(state->db, "insert or replace into DerivationOutputs (drv, id, path) values (?, ?, ?);"); state->stmts->QueryValidDerivers.create(state->db, "select v.id, v.path from DerivationOutputs d join ValidPaths v on d.drv = v.id where d.path = ?;"); state->stmts->QueryDerivationOutputs.create(state->db, "select id, path from DerivationOutputs where drv = ?;"); // Use "path >= ?" with limit 1 rather than "path like '?%'" to // ensure efficient lookup. state->stmts->QueryPathFromHashPart.create(state->db, "select path from ValidPaths where path >= ? limit 1;"); state->stmts->QueryValidPaths.create(state->db, "select path from ValidPaths"); if (experimentalFeatureSettings.isEnabled(Xp::CaDerivations)) { state->stmts->RegisterRealisedOutput.create(state->db, R"( insert into Realisations (drvPath, outputName, outputPath, signatures) values (?, ?, (select id from ValidPaths where path = ?), ?) ; )"); state->stmts->UpdateRealisedOutput.create(state->db, R"( update Realisations set signatures = ? where drvPath = ? and outputName = ? ; )"); state->stmts->QueryRealisedOutput.create(state->db, R"( select Realisations.id, Output.path, Realisations.signatures from Realisations inner join ValidPaths as Output on Output.id = Realisations.outputPath where drvPath = ? and outputName = ? ; )"); state->stmts->QueryAllRealisedOutputs.create(state->db, R"( select outputName, Output.path from Realisations inner join ValidPaths as Output on Output.id = Realisations.outputPath where drvPath = ? ; )"); state->stmts->QueryRealisationReferences.create(state->db, R"( select drvPath, outputName from Realisations join RealisationsRefs on realisationReference = Realisations.id where referrer = ?; )"); state->stmts->AddRealisationReference.create(state->db, R"( insert or replace into RealisationsRefs (referrer, realisationReference) values ( (select id from Realisations where drvPath = ? and outputName = ?), (select id from Realisations where drvPath = ? and outputName = ?)); )"); } } LocalStore::LocalStore(const Params & params) : LocalStore("local", "", params) { } AutoCloseFD LocalStore::openGCLock() { Path fnGCLock = stateDir + "/gc.lock"; auto fdGCLock = open(fnGCLock.c_str(), O_RDWR | O_CREAT #ifndef _WIN32 | O_CLOEXEC #endif , 0600); if (!fdGCLock) throw SysError("opening global GC lock '%1%'", fnGCLock); return toDescriptor(fdGCLock); } void LocalStore::deleteStorePath(const Path & path, uint64_t & bytesFreed) { deletePath(path, bytesFreed); } LocalStore::~LocalStore() { std::shared_future future; { auto state(_state.lock()); if (state->gcRunning) future = state->gcFuture; } if (future.valid()) { printInfo("waiting for auto-GC to finish on exit..."); future.get(); } try { auto fdTempRoots(_fdTempRoots.lock()); if (*fdTempRoots) { fdTempRoots->close(); unlink(fnTempRoots.c_str()); } } catch (...) { ignoreException(); } } std::string LocalStore::getUri() { return "local"; } int LocalStore::getSchema() { return nix::getSchema(schemaPath); } void LocalStore::openDB(State & state, bool create) { if (create && readOnly) { throw Error("cannot create database while in read-only mode"); } if (access(dbDir.c_str(), R_OK | (readOnly ? 0 : W_OK))) throw SysError("Nix database directory '%1%' is not writable", dbDir); /* Open the Nix database. */ std::string dbPath = dbDir + "/db.sqlite"; auto & db(state.db); auto openMode = readOnly ? SQLiteOpenMode::Immutable : create ? SQLiteOpenMode::Normal : SQLiteOpenMode::NoCreate; state.db = SQLite(dbPath, openMode); #ifdef __CYGWIN__ /* The cygwin version of sqlite3 has a patch which calls SetDllDirectory("/usr/bin") on init. It was intended to fix extension loading, which we don't use, and the effect of SetDllDirectory is inherited by child processes, and causes libraries to be loaded from /usr/bin instead of $PATH. This breaks quite a few things (e.g. checkPhase on openssh), so we set it back to default behaviour. */ SetDllDirectoryW(L""); #endif /* !!! check whether sqlite has been built with foreign key support */ /* Whether SQLite should fsync(). "Normal" synchronous mode should be safe enough. If the user asks for it, don't sync at all. This can cause database corruption if the system crashes. */ std::string syncMode = settings.fsyncMetadata ? "normal" : "off"; db.exec("pragma synchronous = " + syncMode); /* Set the SQLite journal mode. WAL mode is fastest, so it's the default. */ std::string mode = settings.useSQLiteWAL ? "wal" : "truncate"; std::string prevMode; { SQLiteStmt stmt; stmt.create(db, "pragma main.journal_mode;"); if (sqlite3_step(stmt) != SQLITE_ROW) SQLiteError::throw_(db, "querying journal mode"); prevMode = std::string((const char *) sqlite3_column_text(stmt, 0)); } if (prevMode != mode && sqlite3_exec(db, ("pragma main.journal_mode = " + mode + ";").c_str(), 0, 0, 0) != SQLITE_OK) SQLiteError::throw_(db, "setting journal mode"); if (mode == "wal") { /* persist the WAL files when the db connection is closed. This allows for read-only connections without write permissions on the containing directory to succeed on a closed db. Setting the journal_size_limit to 2^40 bytes results in the WAL files getting truncated to 0 on exit and limits the on disk size of the WAL files to 2^40 bytes following a checkpoint */ if (sqlite3_exec(db, "pragma main.journal_size_limit = 1099511627776;", 0, 0, 0) == SQLITE_OK) { int enable = 1; sqlite3_file_control(db, NULL, SQLITE_FCNTL_PERSIST_WAL, &enable); } } /* Increase the auto-checkpoint interval to 40000 pages. This seems enough to ensure that instantiating the NixOS system derivation is done in a single fsync(). */ if (mode == "wal" && sqlite3_exec(db, "pragma wal_autocheckpoint = 40000;", 0, 0, 0) != SQLITE_OK) SQLiteError::throw_(db, "setting autocheckpoint interval"); /* Initialise the database schema, if necessary. */ if (create) { static const char schema[] = #include "schema.sql.gen.hh" ; db.exec(schema); } } /* To improve purity, users may want to make the Nix store a read-only bind mount. So make the Nix store writable for this process. */ void LocalStore::makeStoreWritable() { #if __linux__ if (!isRootUser()) return; /* Check if /nix/store is on a read-only mount. */ struct statvfs stat; if (statvfs(realStoreDir.get().c_str(), &stat) != 0) throw SysError("getting info about the Nix store mount point"); if (stat.f_flag & ST_RDONLY) { if (mount(0, realStoreDir.get().c_str(), "none", MS_REMOUNT | MS_BIND, 0) == -1) throw SysError("remounting %1% writable", realStoreDir); } #endif } void LocalStore::registerDrvOutput(const Realisation & info, CheckSigsFlag checkSigs) { experimentalFeatureSettings.require(Xp::CaDerivations); if (checkSigs == NoCheckSigs || !realisationIsUntrusted(info)) registerDrvOutput(info); else throw Error("cannot register realisation '%s' because it lacks a signature by a trusted key", info.outPath.to_string()); } void LocalStore::registerDrvOutput(const Realisation & info) { experimentalFeatureSettings.require(Xp::CaDerivations); retrySQLite([&]() { auto state(_state.lock()); if (auto oldR = queryRealisation_(*state, info.id)) { if (info.isCompatibleWith(*oldR)) { auto combinedSignatures = oldR->signatures; combinedSignatures.insert(info.signatures.begin(), info.signatures.end()); state->stmts->UpdateRealisedOutput.use() (concatStringsSep(" ", combinedSignatures)) (info.id.strHash()) (info.id.outputName) .exec(); } else { throw Error("Trying to register a realisation of '%s', but we already " "have another one locally.\n" "Local: %s\n" "Remote: %s", info.id.to_string(), printStorePath(oldR->outPath), printStorePath(info.outPath) ); } } else { state->stmts->RegisterRealisedOutput.use() (info.id.strHash()) (info.id.outputName) (printStorePath(info.outPath)) (concatStringsSep(" ", info.signatures)) .exec(); } for (auto & [outputId, depPath] : info.dependentRealisations) { auto localRealisation = queryRealisationCore_(*state, outputId); if (!localRealisation) throw Error("unable to register the derivation '%s' as it " "depends on the non existent '%s'", info.id.to_string(), outputId.to_string()); if (localRealisation->second.outPath != depPath) throw Error("unable to register the derivation '%s' as it " "depends on a realisation of '%s' that doesn’t" "match what we have locally", info.id.to_string(), outputId.to_string()); state->stmts->AddRealisationReference.use() (info.id.strHash()) (info.id.outputName) (outputId.strHash()) (outputId.outputName) .exec(); } }); } void LocalStore::cacheDrvOutputMapping( State & state, const uint64_t deriver, const std::string & outputName, const StorePath & output) { retrySQLite([&]() { state.stmts->AddDerivationOutput.use() (deriver) (outputName) (printStorePath(output)) .exec(); }); } uint64_t LocalStore::addValidPath(State & state, const ValidPathInfo & info, bool checkOutputs) { if (info.ca.has_value() && !info.isContentAddressed(*this)) throw Error("cannot add path '%s' to the Nix store because it claims to be content-addressed but isn't", printStorePath(info.path)); state.stmts->RegisterValidPath.use() (printStorePath(info.path)) (info.narHash.to_string(HashFormat::Base16, true)) (info.registrationTime == 0 ? time(0) : info.registrationTime) (info.deriver ? printStorePath(*info.deriver) : "", (bool) info.deriver) (info.narSize, info.narSize != 0) (info.ultimate ? 1 : 0, info.ultimate) (concatStringsSep(" ", info.sigs), !info.sigs.empty()) (renderContentAddress(info.ca), (bool) info.ca) .exec(); uint64_t id = state.db.getLastInsertedRowId(); /* If this is a derivation, then store the derivation outputs in the database. This is useful for the garbage collector: it can efficiently query whether a path is an output of some derivation. */ if (info.path.isDerivation()) { auto drv = readInvalidDerivation(info.path); /* Verify that the output paths in the derivation are correct (i.e., follow the scheme for computing output paths from derivations). Note that if this throws an error, then the DB transaction is rolled back, so the path validity registration above is undone. */ if (checkOutputs) drv.checkInvariants(*this, info.path); for (auto & i : drv.outputsAndOptPaths(*this)) { /* Floating CA derivations have indeterminate output paths until they are built, so don't register anything in that case */ if (i.second.second) cacheDrvOutputMapping(state, id, i.first, *i.second.second); } } { auto state_(Store::state.lock()); state_->pathInfoCache.upsert(std::string(info.path.to_string()), PathInfoCacheValue{ .value = std::make_shared(info) }); } return id; } void LocalStore::queryPathInfoUncached(const StorePath & path, Callback> callback) noexcept { try { callback(retrySQLite>([&]() { auto state(_state.lock()); return queryPathInfoInternal(*state, path); })); } catch (...) { callback.rethrow(); } } std::shared_ptr LocalStore::queryPathInfoInternal(State & state, const StorePath & path) { /* Get the path info. */ auto useQueryPathInfo(state.stmts->QueryPathInfo.use()(printStorePath(path))); if (!useQueryPathInfo.next()) return std::shared_ptr(); auto id = useQueryPathInfo.getInt(0); auto narHash = Hash::dummy; try { narHash = Hash::parseAnyPrefixed(useQueryPathInfo.getStr(1)); } catch (BadHash & e) { throw Error("invalid-path entry for '%s': %s", printStorePath(path), e.what()); } auto info = std::make_shared(path, narHash); info->id = id; info->registrationTime = useQueryPathInfo.getInt(2); auto s = (const char *) sqlite3_column_text(state.stmts->QueryPathInfo, 3); if (s) info->deriver = parseStorePath(s); /* Note that narSize = NULL yields 0. */ info->narSize = useQueryPathInfo.getInt(4); info->ultimate = useQueryPathInfo.getInt(5) == 1; s = (const char *) sqlite3_column_text(state.stmts->QueryPathInfo, 6); if (s) info->sigs = tokenizeString(s, " "); s = (const char *) sqlite3_column_text(state.stmts->QueryPathInfo, 7); if (s) info->ca = ContentAddress::parseOpt(s); /* Get the references. */ auto useQueryReferences(state.stmts->QueryReferences.use()(info->id)); while (useQueryReferences.next()) info->references.insert(parseStorePath(useQueryReferences.getStr(0))); return info; } /* Update path info in the database. */ void LocalStore::updatePathInfo(State & state, const ValidPathInfo & info) { state.stmts->UpdatePathInfo.use() (info.narSize, info.narSize != 0) (info.narHash.to_string(HashFormat::Base16, true)) (info.ultimate ? 1 : 0, info.ultimate) (concatStringsSep(" ", info.sigs), !info.sigs.empty()) (renderContentAddress(info.ca), (bool) info.ca) (printStorePath(info.path)) .exec(); } uint64_t LocalStore::queryValidPathId(State & state, const StorePath & path) { auto use(state.stmts->QueryPathInfo.use()(printStorePath(path))); if (!use.next()) throw InvalidPath("path '%s' is not valid", printStorePath(path)); return use.getInt(0); } bool LocalStore::isValidPath_(State & state, const StorePath & path) { return state.stmts->QueryPathInfo.use()(printStorePath(path)).next(); } bool LocalStore::isValidPathUncached(const StorePath & path) { return retrySQLite([&]() { auto state(_state.lock()); return isValidPath_(*state, path); }); } StorePathSet LocalStore::queryValidPaths(const StorePathSet & paths, SubstituteFlag maybeSubstitute) { StorePathSet res; for (auto & i : paths) if (isValidPath(i)) res.insert(i); return res; } StorePathSet LocalStore::queryAllValidPaths() { return retrySQLite([&]() { auto state(_state.lock()); auto use(state->stmts->QueryValidPaths.use()); StorePathSet res; while (use.next()) res.insert(parseStorePath(use.getStr(0))); return res; }); } void LocalStore::queryReferrers(State & state, const StorePath & path, StorePathSet & referrers) { auto useQueryReferrers(state.stmts->QueryReferrers.use()(printStorePath(path))); while (useQueryReferrers.next()) referrers.insert(parseStorePath(useQueryReferrers.getStr(0))); } void LocalStore::queryReferrers(const StorePath & path, StorePathSet & referrers) { return retrySQLite([&]() { auto state(_state.lock()); queryReferrers(*state, path, referrers); }); } StorePathSet LocalStore::queryValidDerivers(const StorePath & path) { return retrySQLite([&]() { auto state(_state.lock()); auto useQueryValidDerivers(state->stmts->QueryValidDerivers.use()(printStorePath(path))); StorePathSet derivers; while (useQueryValidDerivers.next()) derivers.insert(parseStorePath(useQueryValidDerivers.getStr(1))); return derivers; }); } std::map> LocalStore::queryStaticPartialDerivationOutputMap(const StorePath & path) { return retrySQLite>>([&]() { auto state(_state.lock()); std::map> outputs; uint64_t drvId; drvId = queryValidPathId(*state, path); auto use(state->stmts->QueryDerivationOutputs.use()(drvId)); while (use.next()) outputs.insert_or_assign( use.getStr(0), parseStorePath(use.getStr(1))); return outputs; }); } std::optional LocalStore::queryPathFromHashPart(const std::string & hashPart) { if (hashPart.size() != StorePath::HashLen) throw Error("invalid hash part"); Path prefix = storeDir + "/" + hashPart; return retrySQLite>([&]() -> std::optional { auto state(_state.lock()); auto useQueryPathFromHashPart(state->stmts->QueryPathFromHashPart.use()(prefix)); if (!useQueryPathFromHashPart.next()) return {}; const char * s = (const char *) sqlite3_column_text(state->stmts->QueryPathFromHashPart, 0); if (s && prefix.compare(0, prefix.size(), s, prefix.size()) == 0) return parseStorePath(s); return {}; }); } StorePathSet LocalStore::querySubstitutablePaths(const StorePathSet & paths) { if (!settings.useSubstitutes) return StorePathSet(); StorePathSet remaining; for (auto & i : paths) remaining.insert(i); StorePathSet res; for (auto & sub : getDefaultSubstituters()) { if (remaining.empty()) break; if (sub->storeDir != storeDir) continue; if (!sub->wantMassQuery) continue; auto valid = sub->queryValidPaths(remaining); StorePathSet remaining2; for (auto & path : remaining) if (valid.count(path)) res.insert(path); else remaining2.insert(path); std::swap(remaining, remaining2); } return res; } void LocalStore::registerValidPath(const ValidPathInfo & info) { registerValidPaths({{info.path, info}}); } void LocalStore::registerValidPaths(const ValidPathInfos & infos) { #ifndef _WIN32 /* SQLite will fsync by default, but the new valid paths may not be fsync-ed. So some may want to fsync them before registering the validity, at the expense of some speed of the path registering operation. */ if (settings.syncBeforeRegistering) sync(); #endif return retrySQLite([&]() { auto state(_state.lock()); SQLiteTxn txn(state->db); StorePathSet paths; for (auto & [_, i] : infos) { assert(i.narHash.algo == HashAlgorithm::SHA256); if (isValidPath_(*state, i.path)) updatePathInfo(*state, i); else addValidPath(*state, i, false); paths.insert(i.path); } for (auto & [_, i] : infos) { auto referrer = queryValidPathId(*state, i.path); for (auto & j : i.references) state->stmts->AddReference.use()(referrer)(queryValidPathId(*state, j)).exec(); } /* Check that the derivation outputs are correct. We can't do this in addValidPath() above, because the references might not be valid yet. */ for (auto & [_, i] : infos) if (i.path.isDerivation()) { // FIXME: inefficient; we already loaded the derivation in addValidPath(). readInvalidDerivation(i.path).checkInvariants(*this, i.path); } /* Do a topological sort of the paths. This will throw an error if a cycle is detected and roll back the transaction. Cycles can only occur when a derivation has multiple outputs. */ topoSort(paths, {[&](const StorePath & path) { auto i = infos.find(path); return i == infos.end() ? StorePathSet() : i->second.references; }}, {[&](const StorePath & path, const StorePath & parent) { return BuildError( "cycle detected in the references of '%s' from '%s'", printStorePath(path), printStorePath(parent)); }}); txn.commit(); }); } /* Invalidate a path. The caller is responsible for checking that there are no referrers. */ void LocalStore::invalidatePath(State & state, const StorePath & path) { debug("invalidating path '%s'", printStorePath(path)); state.stmts->InvalidatePath.use()(printStorePath(path)).exec(); /* Note that the foreign key constraints on the Refs table take care of deleting the references entries for `path'. */ { auto state_(Store::state.lock()); state_->pathInfoCache.erase(std::string(path.to_string())); } } const PublicKeys & LocalStore::getPublicKeys() { auto state(_state.lock()); if (!state->publicKeys) state->publicKeys = std::make_unique(getDefaultPublicKeys()); return *state->publicKeys; } bool LocalStore::pathInfoIsUntrusted(const ValidPathInfo & info) { return requireSigs && !info.checkSignatures(*this, getPublicKeys()); } bool LocalStore::realisationIsUntrusted(const Realisation & realisation) { return requireSigs && !realisation.checkSignatures(getPublicKeys()); } void LocalStore::addToStore(const ValidPathInfo & info, Source & source, RepairFlag repair, CheckSigsFlag checkSigs) { if (checkSigs && pathInfoIsUntrusted(info)) throw Error("cannot add path '%s' because it lacks a signature by a trusted key", printStorePath(info.path)); /* In case we are not interested in reading the NAR: discard it. */ bool narRead = false; Finally cleanup = [&]() { if (!narRead) { NullFileSystemObjectSink sink; try { parseDump(sink, source); } catch (...) { ignoreException(); } } }; addTempRoot(info.path); if (repair || !isValidPath(info.path)) { PathLocks outputLock; auto realPath = Store::toRealPath(info.path); /* Lock the output path. But don't lock if we're being called from a build hook (whose parent process already acquired a lock on this path). */ if (!locksHeld.count(printStorePath(info.path))) outputLock.lockPaths({realPath}); if (repair || !isValidPath(info.path)) { deletePath(realPath); /* While restoring the path from the NAR, compute the hash of the NAR. */ HashSink hashSink(HashAlgorithm::SHA256); TeeSource wrapperSource { source, hashSink }; narRead = true; restorePath(realPath, wrapperSource); auto hashResult = hashSink.finish(); if (hashResult.first != info.narHash) throw Error("hash mismatch importing path '%s';\n specified: %s\n got: %s", printStorePath(info.path), info.narHash.to_string(HashFormat::Nix32, true), hashResult.first.to_string(HashFormat::Nix32, true)); if (hashResult.second != info.narSize) throw Error("size mismatch importing path '%s';\n specified: %s\n got: %s", printStorePath(info.path), info.narSize, hashResult.second); if (info.ca) { auto & specified = *info.ca; auto actualHash = ({ auto accessor = getFSAccessor(false); CanonPath path { printStorePath(info.path) }; Hash h { HashAlgorithm::SHA256 }; // throwaway def to appease C++ auto fim = specified.method.getFileIngestionMethod(); switch (fim) { case FileIngestionMethod::Flat: case FileIngestionMethod::NixArchive: { HashModuloSink caSink { specified.hash.algo, std::string { info.path.hashPart() }, }; dumpPath({accessor, path}, caSink, (FileSerialisationMethod) fim); h = caSink.finish().first; break; } case FileIngestionMethod::Git: h = git::dumpHash(specified.hash.algo, {accessor, path}).hash; break; } ContentAddress { .method = specified.method, .hash = std::move(h), }; }); if (specified.hash != actualHash.hash) { throw Error("ca hash mismatch importing path '%s';\n specified: %s\n got: %s", printStorePath(info.path), specified.hash.to_string(HashFormat::Nix32, true), actualHash.hash.to_string(HashFormat::Nix32, true)); } } autoGC(); canonicalisePathMetaData(realPath); optimisePath(realPath, repair); // FIXME: combine with hashPath() registerValidPath(info); } outputLock.setDeletion(true); } } StorePath LocalStore::addToStoreFromDump( Source & source0, std::string_view name, FileSerialisationMethod dumpMethod, ContentAddressMethod hashMethod, HashAlgorithm hashAlgo, const StorePathSet & references, RepairFlag repair) { /* For computing the store path. */ auto hashSink = std::make_unique(hashAlgo); TeeSource source { source0, *hashSink }; /* Read the source path into memory, but only if it's up to narBufferSize bytes. If it's larger, write it to a temporary location in the Nix store. If the subsequently computed destination store path is already valid, we just delete the temporary path. Otherwise, we move it to the destination store path. */ bool inMemory = false; struct Free { void operator()(void* v) { free(v); } }; std::unique_ptr dumpBuffer(nullptr); std::string_view dump; /* Fill out buffer, and decide whether we are working strictly in memory based on whether we break out because the buffer is full or the original source is empty */ while (dump.size() < settings.narBufferSize) { auto oldSize = dump.size(); constexpr size_t chunkSize = 65536; auto want = std::min(chunkSize, settings.narBufferSize - oldSize); if (auto tmp = realloc(dumpBuffer.get(), oldSize + want)) { dumpBuffer.release(); dumpBuffer.reset((char*) tmp); } else { throw std::bad_alloc(); } auto got = 0; Finally cleanup([&]() { dump = {dumpBuffer.get(), dump.size() + got}; }); try { got = source.read(dumpBuffer.get() + oldSize, want); } catch (EndOfFile &) { inMemory = true; break; } } std::unique_ptr delTempDir; std::filesystem::path tempPath; std::filesystem::path tempDir; AutoCloseFD tempDirFd; bool methodsMatch = static_cast(dumpMethod) == hashMethod.getFileIngestionMethod(); /* If the methods don't match, our streaming hash of the dump is the wrong sort, and we need to rehash. */ bool inMemoryAndDontNeedRestore = inMemory && methodsMatch; if (!inMemoryAndDontNeedRestore) { /* Drain what we pulled so far, and then keep on pulling */ StringSource dumpSource { dump }; ChainSource bothSource { dumpSource, source }; std::tie(tempDir, tempDirFd) = createTempDirInStore(); delTempDir = std::make_unique(tempDir); tempPath = tempDir / "x"; restorePath(tempPath.string(), bothSource, dumpMethod); dumpBuffer.reset(); dump = {}; } auto [dumpHash, size] = hashSink->finish(); auto desc = ContentAddressWithReferences::fromParts( hashMethod, methodsMatch ? dumpHash : hashPath( PosixSourceAccessor::createAtRoot(tempPath), hashMethod.getFileIngestionMethod(), hashAlgo).first, { .others = references, // caller is not capable of creating a self-reference, because this is content-addressed without modulus .self = false, }); auto dstPath = makeFixedOutputPathFromCA(name, desc); addTempRoot(dstPath); if (repair || !isValidPath(dstPath)) { /* The first check above is an optimisation to prevent unnecessary lock acquisition. */ auto realPath = Store::toRealPath(dstPath); PathLocks outputLock({realPath}); if (repair || !isValidPath(dstPath)) { deletePath(realPath); autoGC(); if (inMemoryAndDontNeedRestore) { StringSource dumpSource { dump }; /* Restore from the buffer in memory. */ auto fim = hashMethod.getFileIngestionMethod(); switch (fim) { case FileIngestionMethod::Flat: case FileIngestionMethod::NixArchive: restorePath(realPath, dumpSource, (FileSerialisationMethod) fim); break; case FileIngestionMethod::Git: // doesn't correspond to serialization method, so // this should be unreachable assert(false); } } else { /* Move the temporary path we restored above. */ moveFile(tempPath.string(), realPath); } /* For computing the nar hash. In recursive SHA-256 mode, this is the same as the store hash, so no need to do it again. */ auto narHash = std::pair { dumpHash, size }; if (dumpMethod != FileSerialisationMethod::NixArchive || hashAlgo != HashAlgorithm::SHA256) { HashSink narSink { HashAlgorithm::SHA256 }; dumpPath(realPath, narSink); narHash = narSink.finish(); } canonicalisePathMetaData(realPath); // FIXME: merge into restorePath optimisePath(realPath, repair); ValidPathInfo info { *this, name, std::move(desc), narHash.first }; info.narSize = narHash.second; registerValidPath(info); } outputLock.setDeletion(true); } return dstPath; } /* Create a temporary directory in the store that won't be garbage-collected until the returned FD is closed. */ std::pair LocalStore::createTempDirInStore() { std::filesystem::path tmpDirFn; AutoCloseFD tmpDirFd; bool lockedByUs = false; do { /* There is a slight possibility that `tmpDir' gets deleted by the GC between createTempDir() and when we acquire a lock on it. We'll repeat until 'tmpDir' exists and we've locked it. */ tmpDirFn = createTempDir(realStoreDir, "tmp"); tmpDirFd = openDirectory(tmpDirFn); if (!tmpDirFd) { continue; } lockedByUs = lockFile(tmpDirFd.get(), ltWrite, true); } while (!pathExists(tmpDirFn.string()) || !lockedByUs); return {tmpDirFn, std::move(tmpDirFd)}; } void LocalStore::invalidatePathChecked(const StorePath & path) { retrySQLite([&]() { auto state(_state.lock()); SQLiteTxn txn(state->db); if (isValidPath_(*state, path)) { StorePathSet referrers; queryReferrers(*state, path, referrers); referrers.erase(path); /* ignore self-references */ if (!referrers.empty()) throw PathInUse("cannot delete path '%s' because it is in use by %s", printStorePath(path), showPaths(referrers)); invalidatePath(*state, path); } txn.commit(); }); } bool LocalStore::verifyStore(bool checkContents, RepairFlag repair) { printInfo("reading the Nix store..."); /* Acquire the global GC lock to get a consistent snapshot of existing and valid paths. */ auto fdGCLock = openGCLock(); FdLock gcLock(fdGCLock.get(), ltRead, true, "waiting for the big garbage collector lock..."); auto [errors, validPaths] = verifyAllValidPaths(repair); /* Optionally, check the content hashes (slow). */ if (checkContents) { printInfo("checking link hashes..."); for (auto & link : std::filesystem::directory_iterator{linksDir}) { checkInterrupt(); auto name = link.path().filename(); printMsg(lvlTalkative, "checking contents of '%s'", name); PosixSourceAccessor accessor; std::string hash = hashPath( PosixSourceAccessor::createAtRoot(link.path()), FileIngestionMethod::NixArchive, HashAlgorithm::SHA256).first.to_string(HashFormat::Nix32, false); if (hash != name.string()) { printError("link '%s' was modified! expected hash '%s', got '%s'", link.path(), name, hash); if (repair) { std::filesystem::remove(link.path()); printInfo("removed link '%s'", link.path()); } else { errors = true; } } } printInfo("checking store hashes..."); Hash nullHash(HashAlgorithm::SHA256); for (auto & i : validPaths) { try { auto info = std::const_pointer_cast(std::shared_ptr(queryPathInfo(i))); /* Check the content hash (optionally - slow). */ printMsg(lvlTalkative, "checking contents of '%s'", printStorePath(i)); auto hashSink = HashSink(info->narHash.algo); dumpPath(Store::toRealPath(i), hashSink); auto current = hashSink.finish(); if (info->narHash != nullHash && info->narHash != current.first) { printError("path '%s' was modified! expected hash '%s', got '%s'", printStorePath(i), info->narHash.to_string(HashFormat::Nix32, true), current.first.to_string(HashFormat::Nix32, true)); if (repair) repairPath(i); else errors = true; } else { bool update = false; /* Fill in missing hashes. */ if (info->narHash == nullHash) { printInfo("fixing missing hash on '%s'", printStorePath(i)); info->narHash = current.first; update = true; } /* Fill in missing narSize fields (from old stores). */ if (info->narSize == 0) { printInfo("updating size field on '%s' to %s", printStorePath(i), current.second); info->narSize = current.second; update = true; } if (update) { auto state(_state.lock()); updatePathInfo(*state, *info); } } } catch (Error & e) { /* It's possible that the path got GC'ed, so ignore errors on invalid paths. */ if (isValidPath(i)) logError(e.info()); else warn(e.msg()); errors = true; } } } return errors; } LocalStore::VerificationResult LocalStore::verifyAllValidPaths(RepairFlag repair) { StorePathSet storePathsInStoreDir; /* Why aren't we using `queryAllValidPaths`? Because that would tell us about all the paths than the database knows about. Here we want to know about all the store paths in the store directory, regardless of what the database thinks. We will end up cross-referencing these two sources of truth (the database and the filesystem) in the loop below, in order to catch invalid states. */ for (auto & i : std::filesystem::directory_iterator{realStoreDir.to_string()}) { checkInterrupt(); try { storePathsInStoreDir.insert({i.path().filename().string()}); } catch (BadStorePath &) { } } /* Check whether all valid paths actually exist. */ printInfo("checking path existence..."); StorePathSet done; auto existsInStoreDir = [&](const StorePath & storePath) { return storePathsInStoreDir.count(storePath); }; bool errors = false; StorePathSet validPaths; for (auto & i : queryAllValidPaths()) verifyPath(i, existsInStoreDir, done, validPaths, repair, errors); return { .errors = errors, .validPaths = validPaths, }; } void LocalStore::verifyPath(const StorePath & path, std::function existsInStoreDir, StorePathSet & done, StorePathSet & validPaths, RepairFlag repair, bool & errors) { checkInterrupt(); if (!done.insert(path).second) return; if (!existsInStoreDir(path)) { /* Check any referrers first. If we can invalidate them first, then we can invalidate this path as well. */ bool canInvalidate = true; StorePathSet referrers; queryReferrers(path, referrers); for (auto & i : referrers) if (i != path) { verifyPath(i, existsInStoreDir, done, validPaths, repair, errors); if (validPaths.count(i)) canInvalidate = false; } auto pathS = printStorePath(path); if (canInvalidate) { printInfo("path '%s' disappeared, removing from database...", pathS); auto state(_state.lock()); invalidatePath(*state, path); } else { printError("path '%s' disappeared, but it still has valid referrers!", pathS); if (repair) try { repairPath(path); } catch (Error & e) { logWarning(e.info()); errors = true; } else errors = true; } return; } validPaths.insert(std::move(path)); } unsigned int LocalStore::getProtocol() { return PROTOCOL_VERSION; } std::optional LocalStore::isTrustedClient() { return Trusted; } #if defined(FS_IOC_SETFLAGS) && defined(FS_IOC_GETFLAGS) && defined(FS_IMMUTABLE_FL) static void makeMutable(const Path & path) { checkInterrupt(); auto st = lstat(path); if (!S_ISDIR(st.st_mode) && !S_ISREG(st.st_mode)) return; if (S_ISDIR(st.st_mode)) { for (auto & i : readDirectory(path)) makeMutable(path + "/" + i.name); } /* The O_NOFOLLOW is important to prevent us from changing the mutable bit on the target of a symlink (which would be a security hole). */ AutoCloseFD fd = open(path.c_str(), O_RDONLY | O_NOFOLLOW #ifndef _WIN32 | O_CLOEXEC #endif ); if (fd == INVALID_DESCRIPTOR) { if (errno == ELOOP) return; // it's a symlink throw SysError("opening file '%1%'", path); } unsigned int flags = 0, old; /* Silently ignore errors getting/setting the immutable flag so that we work correctly on filesystems that don't support it. */ if (ioctl(fd, FS_IOC_GETFLAGS, &flags)) return; old = flags; flags &= ~FS_IMMUTABLE_FL; if (old == flags) return; if (ioctl(fd, FS_IOC_SETFLAGS, &flags)) return; } /* Upgrade from schema 6 (Nix 0.15) to schema 7 (Nix >= 1.3). */ void LocalStore::upgradeStore7() { if (!isRootUser()) return; printInfo("removing immutable bits from the Nix store (this may take a while)..."); makeMutable(realStoreDir); } #else void LocalStore::upgradeStore7() { } #endif void LocalStore::vacuumDB() { auto state(_state.lock()); state->db.exec("vacuum"); } void LocalStore::addSignatures(const StorePath & storePath, const StringSet & sigs) { retrySQLite([&]() { auto state(_state.lock()); SQLiteTxn txn(state->db); auto info = std::const_pointer_cast(queryPathInfoInternal(*state, storePath)); info->sigs.insert(sigs.begin(), sigs.end()); updatePathInfo(*state, *info); txn.commit(); }); } void LocalStore::signRealisation(Realisation & realisation) { // FIXME: keep secret keys in memory. auto secretKeyFiles = settings.secretKeyFiles; for (auto & secretKeyFile : secretKeyFiles.get()) { SecretKey secretKey(readFile(secretKeyFile)); LocalSigner signer(std::move(secretKey)); realisation.sign(signer); } } void LocalStore::signPathInfo(ValidPathInfo & info) { // FIXME: keep secret keys in memory. auto secretKeyFiles = settings.secretKeyFiles; for (auto & secretKeyFile : secretKeyFiles.get()) { SecretKey secretKey(readFile(secretKeyFile)); LocalSigner signer(std::move(secretKey)); info.sign(*this, signer); } } std::optional> LocalStore::queryRealisationCore_( LocalStore::State & state, const DrvOutput & id) { auto useQueryRealisedOutput( state.stmts->QueryRealisedOutput.use() (id.strHash()) (id.outputName)); if (!useQueryRealisedOutput.next()) return std::nullopt; auto realisationDbId = useQueryRealisedOutput.getInt(0); auto outputPath = parseStorePath(useQueryRealisedOutput.getStr(1)); auto signatures = tokenizeString(useQueryRealisedOutput.getStr(2)); return {{ realisationDbId, Realisation{ .id = id, .outPath = outputPath, .signatures = signatures, } }}; } std::optional LocalStore::queryRealisation_( LocalStore::State & state, const DrvOutput & id) { auto maybeCore = queryRealisationCore_(state, id); if (!maybeCore) return std::nullopt; auto [realisationDbId, res] = *maybeCore; std::map dependentRealisations; auto useRealisationRefs( state.stmts->QueryRealisationReferences.use() (realisationDbId)); while (useRealisationRefs.next()) { auto depId = DrvOutput { Hash::parseAnyPrefixed(useRealisationRefs.getStr(0)), useRealisationRefs.getStr(1), }; auto dependentRealisation = queryRealisationCore_(state, depId); assert(dependentRealisation); // Enforced by the db schema auto outputPath = dependentRealisation->second.outPath; dependentRealisations.insert({depId, outputPath}); } res.dependentRealisations = dependentRealisations; return { res }; } void LocalStore::queryRealisationUncached(const DrvOutput & id, Callback> callback) noexcept { try { auto maybeRealisation = retrySQLite>([&]() { auto state(_state.lock()); return queryRealisation_(*state, id); }); if (maybeRealisation) callback( std::make_shared(maybeRealisation.value())); else callback(nullptr); } catch (...) { callback.rethrow(); } } void LocalStore::addBuildLog(const StorePath & drvPath, std::string_view log) { assert(drvPath.isDerivation()); auto baseName = drvPath.to_string(); auto logPath = fmt("%s/%s/%s/%s.bz2", logDir, drvsLogDir, baseName.substr(0, 2), baseName.substr(2)); if (pathExists(logPath)) return; createDirs(dirOf(logPath)); auto tmpFile = fmt("%s.tmp.%d", logPath, getpid()); writeFile(tmpFile, compress("bzip2", log)); std::filesystem::rename(tmpFile, logPath); } std::optional LocalStore::getVersion() { return nixVersion; } static RegisterStoreImplementation regLocalStore; } // namespace nix