tvl-depot/src/libstore/local-store.cc

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#include "config.h"
#include "local-store.hh"
#include "globals.hh"
#include "archive.hh"
#include "pathlocks.hh"
#include "worker-protocol.hh"
#include "derivations.hh"
#include "nar-info.hh"
#include <iostream>
#include <algorithm>
#include <cstring>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/select.h>
#include <sys/time.h>
#include <unistd.h>
#include <utime.h>
#include <fcntl.h>
#include <errno.h>
#include <stdio.h>
#include <time.h>
#include <grp.h>
#if __linux__
#include <sched.h>
#include <sys/statvfs.h>
#include <sys/mount.h>
#include <sys/ioctl.h>
#endif
#include <sqlite3.h>
namespace nix {
LocalStore::LocalStore(const Params & params)
: LocalFSStore(params)
, linksDir(storeDir + "/.links")
, reservedPath(settings.nixDBPath + "/reserved")
, schemaPath(settings.nixDBPath + "/schema")
, requireSigs(settings.get("signed-binary-caches", std::string("")) != "") // FIXME: rename option
, publicKeys(getDefaultPublicKeys())
{
auto state(_state.lock());
if (settings.readOnlyMode) {
openDB(*state, false);
return;
}
/* Create missing state directories if they don't already exist. */
createDirs(storeDir);
makeStoreWritable();
createDirs(linksDir);
Path profilesDir = settings.nixStateDir + "/profiles";
createDirs(profilesDir);
createDirs(settings.nixStateDir + "/temproots");
createDirs(settings.nixDBPath);
Path gcRootsDir = settings.nixStateDir + "/gcroots";
if (!pathExists(gcRootsDir)) {
createDirs(gcRootsDir);
createSymlink(profilesDir, gcRootsDir + "/profiles");
}
/* Optionally, create directories and set permissions for a
multi-user install. */
if (getuid() == 0 && settings.buildUsersGroup != "") {
Path perUserDir = profilesDir + "/per-user";
createDirs(perUserDir);
if (chmod(perUserDir.c_str(), 01777) == -1)
throw SysError(format("could not set permissions on %1% to 1777") % perUserDir);
mode_t perm = 01775;
struct group * gr = getgrnam(settings.buildUsersGroup.c_str());
if (!gr)
printMsg(lvlError, format("warning: the group %1% specified in build-users-group does not exist")
% settings.buildUsersGroup);
else {
struct stat st;
if (stat(storeDir.c_str(), &st))
throw SysError(format("getting attributes of path %1%") % storeDir);
if (st.st_uid != 0 || st.st_gid != gr->gr_gid || (st.st_mode & ~S_IFMT) != perm) {
if (chown(storeDir.c_str(), 0, gr->gr_gid) == -1)
throw SysError(format("changing ownership of path %1%") % storeDir);
if (chmod(storeDir.c_str(), perm) == -1)
throw SysError(format("changing permissions on path %1%") % storeDir);
}
}
}
/* Ensure that the store and its parents are not symlinks. */
if (getEnv("NIX_IGNORE_SYMLINK_STORE") != "1") {
Path path = storeDir;
struct stat st;
while (path != "/") {
if (lstat(path.c_str(), &st))
throw SysError(format("getting status of %1%") % path);
if (S_ISLNK(st.st_mode))
throw Error(format(
"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 = open(reservedPath.c_str(), O_WRONLY | O_CREAT, 0600);
int res = -1;
#if HAVE_POSIX_FALLOCATE
res = posix_fallocate(fd, 0, settings.reservedSize);
#endif
if (res == -1) {
writeFull(fd, string(settings.reservedSize, 'X'));
ftruncate(fd, settings.reservedSize);
}
}
} catch (SysError & e) { /* don't care about errors */
}
/* Acquire the big fat lock in shared mode to make sure that no
schema upgrade is in progress. */
try {
Path globalLockPath = settings.nixDBPath + "/big-lock";
globalLock = openLockFile(globalLockPath.c_str(), true);
} catch (SysError & e) {
if (e.errNo != EACCES) throw;
settings.readOnlyMode = true;
openDB(*state, false);
return;
}
if (!lockFile(globalLock, ltRead, false)) {
printMsg(lvlError, "waiting for the big Nix store lock...");
lockFile(globalLock, ltRead, true);
}
/* Check the current database schema and if necessary do an
upgrade. */
int curSchema = getSchema();
if (curSchema > nixSchemaVersion)
throw Error(format("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, (format("%1%") % nixSchemaVersion).str());
}
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, ltWrite, false)) {
printMsg(lvlError, "waiting for exclusive access to the Nix store...");
lockFile(globalLock, 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);
if (sqlite3_exec(state->db, "alter table ValidPaths add column ultimate integer", 0, 0, 0) != SQLITE_OK)
throwSQLiteError(state->db, "upgrading database schema");
if (sqlite3_exec(state->db, "alter table ValidPaths add column sigs text", 0, 0, 0) != SQLITE_OK)
throwSQLiteError(state->db, "upgrading database schema");
txn.commit();
}
if (curSchema < 9) {
SQLiteTxn txn(state->db);
if (sqlite3_exec(state->db, "drop table FailedPaths", 0, 0, 0) != SQLITE_OK)
throwSQLiteError(state->db, "upgrading database schema");
txn.commit();
}
writeFile(schemaPath, (format("%1%") % nixSchemaVersion).str());
lockFile(globalLock, ltRead, true);
}
else openDB(*state, false);
}
LocalStore::~LocalStore()
{
auto state(_state.lock());
try {
if (state->fdTempRoots != -1) {
state->fdTempRoots.close();
unlink(state->fnTempRoots.c_str());
}
} catch (...) {
ignoreException();
}
}
std::string LocalStore::getUri()
{
return "local";
}
int LocalStore::getSchema()
{
int curSchema = 0;
if (pathExists(schemaPath)) {
string s = readFile(schemaPath);
if (!string2Int(s, curSchema))
throw Error(format("%1% is corrupt") % schemaPath);
}
return curSchema;
}
bool LocalStore::haveWriteAccess()
{
return access(settings.nixDBPath.c_str(), R_OK | W_OK) == 0;
}
void LocalStore::openDB(State & state, bool create)
{
if (!haveWriteAccess())
throw SysError(format("Nix database directory %1% is not writable") % settings.nixDBPath);
/* Open the Nix database. */
string dbPath = settings.nixDBPath + "/db.sqlite";
auto & db(state.db);
if (sqlite3_open_v2(dbPath.c_str(), &db.db,
SQLITE_OPEN_READWRITE | (create ? SQLITE_OPEN_CREATE : 0), 0) != SQLITE_OK)
throw Error(format("cannot open Nix database %1%") % dbPath);
if (sqlite3_busy_timeout(db, 60 * 60 * 1000) != SQLITE_OK)
throwSQLiteError(db, "setting timeout");
if (sqlite3_exec(db, "pragma foreign_keys = 1;", 0, 0, 0) != SQLITE_OK)
throwSQLiteError(db, "enabling foreign keys");
/* !!! 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. */
string syncMode = settings.fsyncMetadata ? "normal" : "off";
if (sqlite3_exec(db, ("pragma synchronous = " + syncMode + ";").c_str(), 0, 0, 0) != SQLITE_OK)
throwSQLiteError(db, "setting synchronous mode");
/* Set the SQLite journal mode. WAL mode is fastest, so it's the
default. */
string mode = settings.useSQLiteWAL ? "wal" : "truncate";
string prevMode;
{
SQLiteStmt stmt;
stmt.create(db, "pragma main.journal_mode;");
if (sqlite3_step(stmt) != SQLITE_ROW)
throwSQLiteError(db, "querying journal mode");
prevMode = 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)
throwSQLiteError(db, "setting journal mode");
/* 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)
throwSQLiteError(db, "setting autocheckpoint interval");
/* Initialise the database schema, if necessary. */
if (create) {
const char * schema =
#include "schema.sql.hh"
;
if (sqlite3_exec(db, (const char *) schema, 0, 0, 0) != SQLITE_OK)
throwSQLiteError(db, "initialising database schema");
}
/* Prepare SQL statements. */
state.stmtRegisterValidPath.create(db,
"insert into ValidPaths (path, hash, registrationTime, deriver, narSize, ultimate, sigs) values (?, ?, ?, ?, ?, ?, ?);");
state.stmtUpdatePathInfo.create(db,
"update ValidPaths set narSize = ?, hash = ?, ultimate = ?, sigs = ? where path = ?;");
state.stmtAddReference.create(db,
"insert or replace into Refs (referrer, reference) values (?, ?);");
state.stmtQueryPathInfo.create(db,
"select id, hash, registrationTime, deriver, narSize, ultimate, sigs from ValidPaths where path = ?;");
state.stmtQueryReferences.create(db,
"select path from Refs join ValidPaths on reference = id where referrer = ?;");
state.stmtQueryReferrers.create(db,
"select path from Refs join ValidPaths on referrer = id where reference = (select id from ValidPaths where path = ?);");
state.stmtInvalidatePath.create(db,
"delete from ValidPaths where path = ?;");
state.stmtAddDerivationOutput.create(db,
"insert or replace into DerivationOutputs (drv, id, path) values (?, ?, ?);");
state.stmtQueryValidDerivers.create(db,
"select v.id, v.path from DerivationOutputs d join ValidPaths v on d.drv = v.id where d.path = ?;");
state.stmtQueryDerivationOutputs.create(db,
"select id, path from DerivationOutputs where drv = ?;");
// Use "path >= ?" with limit 1 rather than "path like '?%'" to
// ensure efficient lookup.
state.stmtQueryPathFromHashPart.create(db,
"select path from ValidPaths where path >= ? limit 1;");
state.stmtQueryValidPaths.create(db, "select path from ValidPaths");
}
/* 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 (getuid() != 0) return;
/* Check if /nix/store is on a read-only mount. */
struct statvfs stat;
if (statvfs(storeDir.c_str(), &stat) != 0)
throw SysError("getting info about the Nix store mount point");
if (stat.f_flag & ST_RDONLY) {
if (unshare(CLONE_NEWNS) == -1)
throw SysError("setting up a private mount namespace");
if (mount(0, storeDir.c_str(), "none", MS_REMOUNT | MS_BIND, 0) == -1)
throw SysError(format("remounting %1% writable") % storeDir);
}
#endif
}
const time_t mtimeStore = 1; /* 1 second into the epoch */
static void canonicaliseTimestampAndPermissions(const Path & path, const struct stat & st)
{
if (!S_ISLNK(st.st_mode)) {
/* Mask out all type related bits. */
mode_t mode = st.st_mode & ~S_IFMT;
if (mode != 0444 && mode != 0555) {
mode = (st.st_mode & S_IFMT)
| 0444
| (st.st_mode & S_IXUSR ? 0111 : 0);
if (chmod(path.c_str(), mode) == -1)
throw SysError(format("changing mode of %1% to %2$o") % path % mode);
}
}
if (st.st_mtime != mtimeStore) {
struct timeval times[2];
times[0].tv_sec = st.st_atime;
times[0].tv_usec = 0;
times[1].tv_sec = mtimeStore;
times[1].tv_usec = 0;
#if HAVE_LUTIMES
if (lutimes(path.c_str(), times) == -1)
if (errno != ENOSYS ||
(!S_ISLNK(st.st_mode) && utimes(path.c_str(), times) == -1))
#else
if (!S_ISLNK(st.st_mode) && utimes(path.c_str(), times) == -1)
#endif
throw SysError(format("changing modification time of %1%") % path);
}
}
void canonicaliseTimestampAndPermissions(const Path & path)
{
struct stat st;
if (lstat(path.c_str(), &st))
throw SysError(format("getting attributes of path %1%") % path);
canonicaliseTimestampAndPermissions(path, st);
}
static void canonicalisePathMetaData_(const Path & path, uid_t fromUid, InodesSeen & inodesSeen)
{
checkInterrupt();
struct stat st;
if (lstat(path.c_str(), &st))
throw SysError(format("getting attributes of path %1%") % path);
/* Really make sure that the path is of a supported type. */
if (!(S_ISREG(st.st_mode) || S_ISDIR(st.st_mode) || S_ISLNK(st.st_mode)))
throw Error(format("file %1% has an unsupported type") % path);
/* Fail if the file is not owned by the build user. This prevents
us from messing up the ownership/permissions of files
hard-linked into the output (e.g. "ln /etc/shadow $out/foo").
However, ignore files that we chown'ed ourselves previously to
ensure that we don't fail on hard links within the same build
(i.e. "touch $out/foo; ln $out/foo $out/bar"). */
if (fromUid != (uid_t) -1 && st.st_uid != fromUid) {
assert(!S_ISDIR(st.st_mode));
if (inodesSeen.find(Inode(st.st_dev, st.st_ino)) == inodesSeen.end())
throw BuildError(format("invalid ownership on file %1%") % path);
mode_t mode = st.st_mode & ~S_IFMT;
assert(S_ISLNK(st.st_mode) || (st.st_uid == geteuid() && (mode == 0444 || mode == 0555) && st.st_mtime == mtimeStore));
return;
}
inodesSeen.insert(Inode(st.st_dev, st.st_ino));
canonicaliseTimestampAndPermissions(path, st);
/* Change ownership to the current uid. If it's a symlink, use
lchown if available, otherwise don't bother. Wrong ownership
of a symlink doesn't matter, since the owning user can't change
the symlink and can't delete it because the directory is not
writable. The only exception is top-level paths in the Nix
store (since that directory is group-writable for the Nix build
users group); we check for this case below. */
if (st.st_uid != geteuid()) {
#if HAVE_LCHOWN
if (lchown(path.c_str(), geteuid(), getegid()) == -1)
#else
if (!S_ISLNK(st.st_mode) &&
chown(path.c_str(), geteuid(), getegid()) == -1)
#endif
throw SysError(format("changing owner of %1% to %2%")
% path % geteuid());
}
if (S_ISDIR(st.st_mode)) {
DirEntries entries = readDirectory(path);
for (auto & i : entries)
canonicalisePathMetaData_(path + "/" + i.name, fromUid, inodesSeen);
}
}
void canonicalisePathMetaData(const Path & path, uid_t fromUid, InodesSeen & inodesSeen)
{
canonicalisePathMetaData_(path, fromUid, inodesSeen);
/* On platforms that don't have lchown(), the top-level path can't
be a symlink, since we can't change its ownership. */
struct stat st;
if (lstat(path.c_str(), &st))
throw SysError(format("getting attributes of path %1%") % path);
if (st.st_uid != geteuid()) {
assert(S_ISLNK(st.st_mode));
throw Error(format("wrong ownership of top-level store path %1%") % path);
}
}
void canonicalisePathMetaData(const Path & path, uid_t fromUid)
{
InodesSeen inodesSeen;
canonicalisePathMetaData(path, fromUid, inodesSeen);
}
void LocalStore::checkDerivationOutputs(const Path & drvPath, const Derivation & drv)
{
string drvName = storePathToName(drvPath);
assert(isDerivation(drvName));
drvName = string(drvName, 0, drvName.size() - drvExtension.size());
if (drv.isFixedOutput()) {
DerivationOutputs::const_iterator out = drv.outputs.find("out");
if (out == drv.outputs.end())
throw Error(format("derivation %1% does not have an output named out") % drvPath);
bool recursive; HashType ht; Hash h;
out->second.parseHashInfo(recursive, ht, h);
Path outPath = makeFixedOutputPath(recursive, ht, h, drvName);
StringPairs::const_iterator j = drv.env.find("out");
if (out->second.path != outPath || j == drv.env.end() || j->second != outPath)
throw Error(format("derivation %1% has incorrect output %2%, should be %3%")
% drvPath % out->second.path % outPath);
}
else {
Derivation drvCopy(drv);
for (auto & i : drvCopy.outputs) {
i.second.path = "";
drvCopy.env[i.first] = "";
}
Hash h = hashDerivationModulo(*this, drvCopy);
for (auto & i : drv.outputs) {
Path outPath = makeOutputPath(i.first, h, drvName);
StringPairs::const_iterator j = drv.env.find(i.first);
if (i.second.path != outPath || j == drv.env.end() || j->second != outPath)
throw Error(format("derivation %1% has incorrect output %2%, should be %3%")
% drvPath % i.second.path % outPath);
}
}
}
uint64_t LocalStore::addValidPath(State & state,
const ValidPathInfo & info, bool checkOutputs)
{
state.stmtRegisterValidPath.use()
(info.path)
("sha256:" + printHash(info.narHash))
(info.registrationTime == 0 ? time(0) : info.registrationTime)
(info.deriver, info.deriver != "")
(info.narSize, info.narSize != 0)
(info.ultimate ? 1 : 0, info.ultimate)
(concatStringsSep(" ", info.sigs), !info.sigs.empty())
.exec();
uint64_t id = sqlite3_last_insert_rowid(state.db);
/* 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 (isDerivation(info.path)) {
Derivation drv = readDerivation(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) checkDerivationOutputs(info.path, drv);
for (auto & i : drv.outputs) {
state.stmtAddDerivationOutput.use()
(id)
(i.first)
(i.second.path)
.exec();
}
}
{
auto state_(Store::state.lock());
state_->pathInfoCache.upsert(storePathToHash(info.path), std::make_shared<ValidPathInfo>(info));
}
return id;
}
Hash parseHashField(const Path & path, const string & s)
{
string::size_type colon = s.find(':');
if (colon == string::npos)
throw Error(format("corrupt hash %1% in valid-path entry for %2%")
% s % path);
HashType ht = parseHashType(string(s, 0, colon));
if (ht == htUnknown)
throw Error(format("unknown hash type %1% in valid-path entry for %2%")
% string(s, 0, colon) % path);
return parseHash(ht, string(s, colon + 1));
}
std::shared_ptr<ValidPathInfo> LocalStore::queryPathInfoUncached(const Path & path)
{
auto info = std::make_shared<ValidPathInfo>();
info->path = path;
assertStorePath(path);
return retrySQLite<std::shared_ptr<ValidPathInfo>>([&]() {
auto state(_state.lock());
/* Get the path info. */
auto useQueryPathInfo(state->stmtQueryPathInfo.use()(path));
if (!useQueryPathInfo.next())
return std::shared_ptr<ValidPathInfo>();
info->id = useQueryPathInfo.getInt(0);
info->narHash = parseHashField(path, useQueryPathInfo.getStr(1));
info->registrationTime = useQueryPathInfo.getInt(2);
auto s = (const char *) sqlite3_column_text(state->stmtQueryPathInfo, 3);
if (s) info->deriver = 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->stmtQueryPathInfo, 6);
if (s) info->sigs = tokenizeString<StringSet>(s, " ");
/* Get the references. */
auto useQueryReferences(state->stmtQueryReferences.use()(info->id));
while (useQueryReferences.next())
info->references.insert(useQueryReferences.getStr(0));
return info;
});
}
/* Update path info in the database. */
void LocalStore::updatePathInfo(State & state, const ValidPathInfo & info)
{
state.stmtUpdatePathInfo.use()
(info.narSize, info.narSize != 0)
("sha256:" + printHash(info.narHash))
(info.ultimate ? 1 : 0, info.ultimate)
(concatStringsSep(" ", info.sigs), !info.sigs.empty())
(info.path)
.exec();
}
uint64_t LocalStore::queryValidPathId(State & state, const Path & path)
{
auto use(state.stmtQueryPathInfo.use()(path));
if (!use.next())
throw Error(format("path %1% is not valid") % path);
return use.getInt(0);
}
bool LocalStore::isValidPath_(State & state, const Path & path)
{
return state.stmtQueryPathInfo.use()(path).next();
}
bool LocalStore::isValidPathUncached(const Path & path)
{
return retrySQLite<bool>([&]() {
auto state(_state.lock());
return isValidPath_(*state, path);
});
}
PathSet LocalStore::queryValidPaths(const PathSet & paths)
{
PathSet res;
for (auto & i : paths)
if (isValidPath(i)) res.insert(i);
return res;
}
PathSet LocalStore::queryAllValidPaths()
{
return retrySQLite<PathSet>([&]() {
auto state(_state.lock());
auto use(state->stmtQueryValidPaths.use());
PathSet res;
while (use.next()) res.insert(use.getStr(0));
return res;
});
}
void LocalStore::queryReferrers(State & state, const Path & path, PathSet & referrers)
{
auto useQueryReferrers(state.stmtQueryReferrers.use()(path));
while (useQueryReferrers.next())
referrers.insert(useQueryReferrers.getStr(0));
}
void LocalStore::queryReferrers(const Path & path, PathSet & referrers)
{
assertStorePath(path);
return retrySQLite<void>([&]() {
auto state(_state.lock());
queryReferrers(*state, path, referrers);
});
}
PathSet LocalStore::queryValidDerivers(const Path & path)
{
assertStorePath(path);
return retrySQLite<PathSet>([&]() {
auto state(_state.lock());
auto useQueryValidDerivers(state->stmtQueryValidDerivers.use()(path));
PathSet derivers;
while (useQueryValidDerivers.next())
derivers.insert(useQueryValidDerivers.getStr(1));
return derivers;
});
}
PathSet LocalStore::queryDerivationOutputs(const Path & path)
{
return retrySQLite<PathSet>([&]() {
auto state(_state.lock());
auto useQueryDerivationOutputs(state->stmtQueryDerivationOutputs.use()
(queryValidPathId(*state, path)));
PathSet outputs;
while (useQueryDerivationOutputs.next())
outputs.insert(useQueryDerivationOutputs.getStr(1));
return outputs;
});
}
StringSet LocalStore::queryDerivationOutputNames(const Path & path)
{
return retrySQLite<StringSet>([&]() {
auto state(_state.lock());
auto useQueryDerivationOutputs(state->stmtQueryDerivationOutputs.use()
(queryValidPathId(*state, path)));
StringSet outputNames;
while (useQueryDerivationOutputs.next())
outputNames.insert(useQueryDerivationOutputs.getStr(0));
return outputNames;
});
}
Path LocalStore::queryPathFromHashPart(const string & hashPart)
{
if (hashPart.size() != storePathHashLen) throw Error("invalid hash part");
Path prefix = storeDir + "/" + hashPart;
return retrySQLite<Path>([&]() {
auto state(_state.lock());
auto useQueryPathFromHashPart(state->stmtQueryPathFromHashPart.use()(prefix));
if (!useQueryPathFromHashPart.next()) return "";
const char * s = (const char *) sqlite3_column_text(state->stmtQueryPathFromHashPart, 0);
return s && prefix.compare(0, prefix.size(), s, prefix.size()) == 0 ? s : "";
});
}
PathSet LocalStore::querySubstitutablePaths(const PathSet & paths)
{
PathSet res;
for (auto & sub : getDefaultSubstituters()) {
if (sub->storeDir != storeDir) continue;
if (!sub->wantMassQuery()) continue;
for (auto & path : paths) {
if (res.count(path)) continue;
debug(format("checking substituter %s for path %s")
% sub->getUri() % path);
if (sub->isValidPath(path))
res.insert(path);
}
}
return res;
}
void LocalStore::querySubstitutablePathInfos(const PathSet & paths,
SubstitutablePathInfos & infos)
{
for (auto & sub : getDefaultSubstituters()) {
if (sub->storeDir != storeDir) continue;
for (auto & path : paths) {
if (infos.count(path)) continue;
debug(format("checking substituter %s for path %s")
% sub->getUri() % path);
try {
auto info = sub->queryPathInfo(path);
auto narInfo = std::dynamic_pointer_cast<const NarInfo>(
std::shared_ptr<const ValidPathInfo>(info));
infos[path] = SubstitutablePathInfo{
info->deriver,
info->references,
narInfo ? narInfo->fileSize : 0,
info->narSize};
} catch (InvalidPath) {
}
}
}
}
void LocalStore::registerValidPath(const ValidPathInfo & info)
{
ValidPathInfos infos;
infos.push_back(info);
registerValidPaths(infos);
}
void LocalStore::registerValidPaths(const ValidPathInfos & infos)
{
/* 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();
return retrySQLite<void>([&]() {
auto state(_state.lock());
SQLiteTxn txn(state->db);
PathSet paths;
for (auto & i : infos) {
assert(i.narHash.type == htSHA256);
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->stmtAddReference.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 (isDerivation(i.path)) {
// FIXME: inefficient; we already loaded the
// derivation in addValidPath().
Derivation drv = readDerivation(i.path);
checkDerivationOutputs(i.path, drv);
}
/* 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. */
topoSortPaths(paths);
txn.commit();
});
}
/* Invalidate a path. The caller is responsible for checking that
there are no referrers. */
void LocalStore::invalidatePath(State & state, const Path & path)
{
debug(format("invalidating path %1%") % path);
state.stmtInvalidatePath.use()(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(storePathToHash(path));
}
}
void LocalStore::addToStore(const ValidPathInfo & info, const std::string & nar,
bool repair, bool dontCheckSigs)
{
Hash h = hashString(htSHA256, nar);
if (h != info.narHash)
throw Error(format("hash mismatch importing path %s; expected hash %s, got %s") %
info.path % info.narHash.to_string() % h.to_string());
if (requireSigs && !dontCheckSigs && !info.checkSignatures(publicKeys))
throw Error(format("cannot import path %s because it lacks a valid signature") % info.path);
addTempRoot(info.path);
if (repair || !isValidPath(info.path)) {
PathLocks outputLock;
/* 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). */
Strings locksHeld = tokenizeString<Strings>(getEnv("NIX_HELD_LOCKS"));
if (find(locksHeld.begin(), locksHeld.end(), info.path) == locksHeld.end())
outputLock.lockPaths({info.path});
if (repair || !isValidPath(info.path)) {
deletePath(info.path);
StringSource source(nar);
restorePath(info.path, source);
canonicalisePathMetaData(info.path, -1);
optimisePath(info.path); // FIXME: combine with hashPath()
registerValidPath(info);
}
outputLock.setDeletion(true);
}
}
Path LocalStore::addToStoreFromDump(const string & dump, const string & name,
bool recursive, HashType hashAlgo, bool repair)
{
Hash h = hashString(hashAlgo, dump);
Path dstPath = makeFixedOutputPath(recursive, hashAlgo, h, name);
addTempRoot(dstPath);
if (repair || !isValidPath(dstPath)) {
/* The first check above is an optimisation to prevent
unnecessary lock acquisition. */
PathLocks outputLock({dstPath});
if (repair || !isValidPath(dstPath)) {
deletePath(dstPath);
if (recursive) {
StringSource source(dump);
restorePath(dstPath, source);
} else
writeFile(dstPath, dump);
canonicalisePathMetaData(dstPath, -1);
/* Register the SHA-256 hash of the NAR serialisation of
the path in the database. We may just have computed it
above (if called with recursive == true and hashAlgo ==
sha256); otherwise, compute it here. */
HashResult hash;
if (recursive) {
hash.first = hashAlgo == htSHA256 ? h : hashString(htSHA256, dump);
hash.second = dump.size();
} else
hash = hashPath(htSHA256, dstPath);
optimisePath(dstPath); // FIXME: combine with hashPath()
ValidPathInfo info;
info.path = dstPath;
info.narHash = hash.first;
info.narSize = hash.second;
info.ultimate = true;
registerValidPath(info);
}
outputLock.setDeletion(true);
}
return dstPath;
}
Path LocalStore::addToStore(const string & name, const Path & _srcPath,
bool recursive, HashType hashAlgo, PathFilter & filter, bool repair)
{
Path srcPath(absPath(_srcPath));
/* Read the whole path into memory. This is not a very scalable
method for very large paths, but `copyPath' is mainly used for
small files. */
StringSink sink;
if (recursive)
dumpPath(srcPath, sink, filter);
else
sink.s = make_ref<std::string>(readFile(srcPath));
return addToStoreFromDump(*sink.s, name, recursive, hashAlgo, repair);
}
Path LocalStore::addTextToStore(const string & name, const string & s,
const PathSet & references, bool repair)
{
Path dstPath = computeStorePathForText(name, s, references);
addTempRoot(dstPath);
if (repair || !isValidPath(dstPath)) {
PathLocks outputLock({dstPath});
if (repair || !isValidPath(dstPath)) {
deletePath(dstPath);
writeFile(dstPath, s);
canonicalisePathMetaData(dstPath, -1);
StringSink sink;
dumpString(s, sink);
auto hash = hashString(htSHA256, *sink.s);
optimisePath(dstPath);
ValidPathInfo info;
info.path = dstPath;
info.narHash = hash;
info.narSize = sink.s->size();
info.references = references;
info.ultimate = true;
registerValidPath(info);
}
outputLock.setDeletion(true);
}
return dstPath;
}
/* Create a temporary directory in the store that won't be
garbage-collected. */
Path LocalStore::createTempDirInStore()
{
Path tmpDir;
do {
/* There is a slight possibility that `tmpDir' gets deleted by
the GC between createTempDir() and addTempRoot(), so repeat
until `tmpDir' exists. */
tmpDir = createTempDir(storeDir);
addTempRoot(tmpDir);
} while (!pathExists(tmpDir));
return tmpDir;
}
void LocalStore::invalidatePathChecked(const Path & path)
{
assertStorePath(path);
retrySQLite<void>([&]() {
auto state(_state.lock());
SQLiteTxn txn(state->db);
if (isValidPath_(*state, path)) {
PathSet referrers; queryReferrers(*state, path, referrers);
referrers.erase(path); /* ignore self-references */
if (!referrers.empty())
throw PathInUse(format("cannot delete path %1% because it is in use by %2%")
% path % showPaths(referrers));
invalidatePath(*state, path);
}
txn.commit();
});
}
bool LocalStore::verifyStore(bool checkContents, bool repair)
{
printMsg(lvlError, format("reading the Nix store..."));
bool errors = false;
/* Acquire the global GC lock to prevent a garbage collection. */
AutoCloseFD fdGCLock = openGCLock(ltWrite);
PathSet store;
for (auto & i : readDirectory(storeDir)) store.insert(i.name);
/* Check whether all valid paths actually exist. */
printMsg(lvlInfo, "checking path existence...");
PathSet validPaths2 = queryAllValidPaths(), validPaths, done;
for (auto & i : validPaths2)
verifyPath(i, store, done, validPaths, repair, errors);
/* Release the GC lock so that checking content hashes (which can
take ages) doesn't block the GC or builds. */
fdGCLock.close();
/* Optionally, check the content hashes (slow). */
if (checkContents) {
printMsg(lvlInfo, "checking hashes...");
Hash nullHash(htSHA256);
for (auto & i : validPaths) {
try {
auto info = std::const_pointer_cast<ValidPathInfo>(std::shared_ptr<const ValidPathInfo>(queryPathInfo(i)));
/* Check the content hash (optionally - slow). */
printMsg(lvlTalkative, format("checking contents of %1%") % i);
HashResult current = hashPath(info->narHash.type, i);
if (info->narHash != nullHash && info->narHash != current.first) {
printMsg(lvlError, format("path %1% was modified! "
"expected hash %2%, got %3%")
% i % printHash(info->narHash) % printHash(current.first));
if (repair) repairPath(i); else errors = true;
} else {
bool update = false;
/* Fill in missing hashes. */
if (info->narHash == nullHash) {
printMsg(lvlError, format("fixing missing hash on %1%") % i);
info->narHash = current.first;
update = true;
}
/* Fill in missing narSize fields (from old stores). */
if (info->narSize == 0) {
printMsg(lvlError, format("updating size field on %1% to %2%") % 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))
printMsg(lvlError, format("error: %1%") % e.msg());
else
printMsg(lvlError, format("warning: %1%") % e.msg());
errors = true;
}
}
}
return errors;
}
void LocalStore::verifyPath(const Path & path, const PathSet & store,
PathSet & done, PathSet & validPaths, bool repair, bool & errors)
{
checkInterrupt();
if (done.find(path) != done.end()) return;
done.insert(path);
if (!isStorePath(path)) {
printMsg(lvlError, format("path %1% is not in the Nix store") % path);
auto state(_state.lock());
invalidatePath(*state, path);
return;
}
if (store.find(baseNameOf(path)) == store.end()) {
/* Check any referrers first. If we can invalidate them
first, then we can invalidate this path as well. */
bool canInvalidate = true;
PathSet referrers; queryReferrers(path, referrers);
for (auto & i : referrers)
if (i != path) {
verifyPath(i, store, done, validPaths, repair, errors);
if (validPaths.find(i) != validPaths.end())
canInvalidate = false;
}
if (canInvalidate) {
printMsg(lvlError, format("path %1% disappeared, removing from database...") % path);
auto state(_state.lock());
invalidatePath(*state, path);
} else {
printMsg(lvlError, format("path %1% disappeared, but it still has valid referrers!") % path);
if (repair)
try {
repairPath(path);
} catch (Error & e) {
printMsg(lvlError, format("warning: %1%") % e.msg());
errors = true;
}
else errors = true;
}
return;
}
validPaths.insert(path);
}
#if defined(FS_IOC_SETFLAGS) && defined(FS_IOC_GETFLAGS) && defined(FS_IMMUTABLE_FL)
static void makeMutable(const Path & path)
{
checkInterrupt();
struct stat 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);
if (fd == -1) {
if (errno == ELOOP) return; // it's a symlink
throw SysError(format("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 (getuid() != 0) return;
printMsg(lvlError, "removing immutable bits from the Nix store (this may take a while)...");
makeMutable(storeDir);
}
#else
void LocalStore::upgradeStore7()
{
}
#endif
void LocalStore::vacuumDB()
{
auto state(_state.lock());
if (sqlite3_exec(state->db, "vacuum;", 0, 0, 0) != SQLITE_OK)
throwSQLiteError(state->db, "vacuuming SQLite database");
}
void LocalStore::addSignatures(const Path & storePath, const StringSet & sigs)
{
retrySQLite<void>([&]() {
auto state(_state.lock());
SQLiteTxn txn(state->db);
auto info = std::const_pointer_cast<ValidPathInfo>(std::shared_ptr<const ValidPathInfo>(queryPathInfo(storePath)));
info->sigs.insert(sigs.begin(), sigs.end());
updatePathInfo(*state, *info);
txn.commit();
});
}
void LocalStore::signPathInfo(ValidPathInfo & info)
{
// FIXME: keep secret keys in memory.
auto secretKeyFiles = settings.get("secret-key-files", Strings());
for (auto & secretKeyFile : secretKeyFiles) {
SecretKey secretKey(readFile(secretKeyFile));
info.sign(secretKey);
}
}
}