/*-*- Mode: C; c-basic-offset: 8; indent-tabs-mode: nil -*-*/ /*** This file is part of systemd. Copyright 2011 Lennart Poettering systemd is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. systemd is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with systemd; If not, see . ***/ #include #include #include #include #include #include #include #include "journal-def.h" #include "journal-file.h" #include "journal-authenticate.h" #include "lookup3.h" #include "compress.h" #include "fsprg.h" #define DEFAULT_DATA_HASH_TABLE_SIZE (2047ULL*sizeof(HashItem)) #define DEFAULT_FIELD_HASH_TABLE_SIZE (333ULL*sizeof(HashItem)) #define COMPRESSION_SIZE_THRESHOLD (512ULL) /* This is the minimum journal file size */ #define JOURNAL_FILE_SIZE_MIN (64ULL*1024ULL) /* 64 KiB */ /* These are the lower and upper bounds if we deduce the max_use value * from the file system size */ #define DEFAULT_MAX_USE_LOWER (1ULL*1024ULL*1024ULL) /* 1 MiB */ #define DEFAULT_MAX_USE_UPPER (4ULL*1024ULL*1024ULL*1024ULL) /* 4 GiB */ /* This is the upper bound if we deduce max_size from max_use */ #define DEFAULT_MAX_SIZE_UPPER (128ULL*1024ULL*1024ULL) /* 128 MiB */ /* This is the upper bound if we deduce the keep_free value from the * file system size */ #define DEFAULT_KEEP_FREE_UPPER (4ULL*1024ULL*1024ULL*1024ULL) /* 4 GiB */ /* This is the keep_free value when we can't determine the system * size */ #define DEFAULT_KEEP_FREE (1024ULL*1024ULL) /* 1 MB */ /* n_data was the first entry we added after the initial file format design */ #define HEADER_SIZE_MIN ALIGN64(offsetof(Header, n_data)) void journal_file_close(JournalFile *f) { assert(f); /* Write the final tag */ if (f->seal && f->writable) journal_file_append_tag(f); /* Sync everything to disk, before we mark the file offline */ if (f->mmap && f->fd >= 0) mmap_cache_close_fd(f->mmap, f->fd); if (f->writable && f->fd >= 0) fdatasync(f->fd); if (f->header) { /* Mark the file offline. Don't override the archived state if it already is set */ if (f->writable && f->header->state == STATE_ONLINE) f->header->state = STATE_OFFLINE; munmap(f->header, PAGE_ALIGN(sizeof(Header))); } if (f->fd >= 0) close_nointr_nofail(f->fd); free(f->path); if (f->mmap) mmap_cache_unref(f->mmap); #ifdef HAVE_XZ free(f->compress_buffer); #endif #ifdef HAVE_GCRYPT if (f->fss_file) munmap(f->fss_file, PAGE_ALIGN(f->fss_file_size)); else if (f->fsprg_state) free(f->fsprg_state); free(f->fsprg_seed); if (f->hmac) gcry_md_close(f->hmac); #endif free(f); } static int journal_file_init_header(JournalFile *f, JournalFile *template) { Header h; ssize_t k; int r; assert(f); zero(h); memcpy(h.signature, HEADER_SIGNATURE, 8); h.header_size = htole64(ALIGN64(sizeof(h))); h.incompatible_flags = htole32(f->compress ? HEADER_INCOMPATIBLE_COMPRESSED : 0); h.compatible_flags = htole32(f->seal ? HEADER_COMPATIBLE_SEALED : 0); r = sd_id128_randomize(&h.file_id); if (r < 0) return r; if (template) { h.seqnum_id = template->header->seqnum_id; h.tail_entry_seqnum = template->header->tail_entry_seqnum; } else h.seqnum_id = h.file_id; k = pwrite(f->fd, &h, sizeof(h), 0); if (k < 0) return -errno; if (k != sizeof(h)) return -EIO; return 0; } static int journal_file_refresh_header(JournalFile *f) { int r; sd_id128_t boot_id; assert(f); r = sd_id128_get_machine(&f->header->machine_id); if (r < 0) return r; r = sd_id128_get_boot(&boot_id); if (r < 0) return r; if (sd_id128_equal(boot_id, f->header->boot_id)) f->tail_entry_monotonic_valid = true; f->header->boot_id = boot_id; f->header->state = STATE_ONLINE; /* Sync the online state to disk */ msync(f->header, PAGE_ALIGN(sizeof(Header)), MS_SYNC); fdatasync(f->fd); return 0; } static int journal_file_verify_header(JournalFile *f) { assert(f); if (memcmp(f->header->signature, HEADER_SIGNATURE, 8)) return -EBADMSG; /* In both read and write mode we refuse to open files with * incompatible flags we don't know */ #ifdef HAVE_XZ if ((le32toh(f->header->incompatible_flags) & ~HEADER_INCOMPATIBLE_COMPRESSED) != 0) return -EPROTONOSUPPORT; #else if (f->header->incompatible_flags != 0) return -EPROTONOSUPPORT; #endif /* When open for writing we refuse to open files with * compatible flags, too */ if (f->writable) { #ifdef HAVE_GCRYPT if ((le32toh(f->header->compatible_flags) & ~HEADER_COMPATIBLE_SEALED) != 0) return -EPROTONOSUPPORT; #else if (f->header->compatible_flags != 0) return -EPROTONOSUPPORT; #endif } if (f->header->state >= _STATE_MAX) return -EBADMSG; /* The first addition was n_data, so check that we are at least this large */ if (le64toh(f->header->header_size) < HEADER_SIZE_MIN) return -EBADMSG; if ((le32toh(f->header->compatible_flags) & HEADER_COMPATIBLE_SEALED) && !JOURNAL_HEADER_CONTAINS(f->header, n_entry_arrays)) return -EBADMSG; if ((le64toh(f->header->header_size) + le64toh(f->header->arena_size)) > (uint64_t) f->last_stat.st_size) return -ENODATA; if (le64toh(f->header->tail_object_offset) > (le64toh(f->header->header_size) + le64toh(f->header->arena_size))) return -ENODATA; if (!VALID64(f->header->data_hash_table_offset) || !VALID64(f->header->field_hash_table_offset) || !VALID64(f->header->tail_object_offset) || !VALID64(f->header->entry_array_offset)) return -ENODATA; if (f->writable) { uint8_t state; sd_id128_t machine_id; int r; r = sd_id128_get_machine(&machine_id); if (r < 0) return r; if (!sd_id128_equal(machine_id, f->header->machine_id)) return -EHOSTDOWN; state = f->header->state; if (state == STATE_ONLINE) { log_debug("Journal file %s is already online. Assuming unclean closing.", f->path); return -EBUSY; } else if (state == STATE_ARCHIVED) return -ESHUTDOWN; else if (state != STATE_OFFLINE) { log_debug("Journal file %s has unknown state %u.", f->path, state); return -EBUSY; } } f->compress = !!(le32toh(f->header->incompatible_flags) & HEADER_INCOMPATIBLE_COMPRESSED); if (f->writable) f->seal = !!(le32toh(f->header->compatible_flags) & HEADER_COMPATIBLE_SEALED); return 0; } static int journal_file_allocate(JournalFile *f, uint64_t offset, uint64_t size) { uint64_t old_size, new_size; int r; assert(f); /* We assume that this file is not sparse, and we know that * for sure, since we always call posix_fallocate() * ourselves */ old_size = le64toh(f->header->header_size) + le64toh(f->header->arena_size); new_size = PAGE_ALIGN(offset + size); if (new_size < le64toh(f->header->header_size)) new_size = le64toh(f->header->header_size); if (new_size <= old_size) return 0; if (f->metrics.max_size > 0 && new_size > f->metrics.max_size) return -E2BIG; if (new_size > f->metrics.min_size && f->metrics.keep_free > 0) { struct statvfs svfs; if (fstatvfs(f->fd, &svfs) >= 0) { uint64_t available; available = svfs.f_bfree * svfs.f_bsize; if (available >= f->metrics.keep_free) available -= f->metrics.keep_free; else available = 0; if (new_size - old_size > available) return -E2BIG; } } /* Note that the glibc fallocate() fallback is very inefficient, hence we try to minimize the allocation area as we can. */ r = posix_fallocate(f->fd, old_size, new_size - old_size); if (r != 0) return -r; mmap_cache_close_fd_range(f->mmap, f->fd, old_size); if (fstat(f->fd, &f->last_stat) < 0) return -errno; f->header->arena_size = htole64(new_size - le64toh(f->header->header_size)); return 0; } static int journal_file_move_to(JournalFile *f, int context, uint64_t offset, uint64_t size, void **ret) { assert(f); assert(ret); /* Avoid SIGBUS on invalid accesses */ if (offset + size > (uint64_t) f->last_stat.st_size) { /* Hmm, out of range? Let's refresh the fstat() data * first, before we trust that check. */ if (fstat(f->fd, &f->last_stat) < 0 || offset + size > (uint64_t) f->last_stat.st_size) return -EADDRNOTAVAIL; } return mmap_cache_get(f->mmap, f->fd, f->prot, context, offset, size, ret); } static uint64_t minimum_header_size(Object *o) { static uint64_t table[] = { [OBJECT_DATA] = sizeof(DataObject), [OBJECT_FIELD] = sizeof(FieldObject), [OBJECT_ENTRY] = sizeof(EntryObject), [OBJECT_DATA_HASH_TABLE] = sizeof(HashTableObject), [OBJECT_FIELD_HASH_TABLE] = sizeof(HashTableObject), [OBJECT_ENTRY_ARRAY] = sizeof(EntryArrayObject), [OBJECT_TAG] = sizeof(TagObject), }; if (o->object.type >= ELEMENTSOF(table) || table[o->object.type] <= 0) return sizeof(ObjectHeader); return table[o->object.type]; } int journal_file_move_to_object(JournalFile *f, int type, uint64_t offset, Object **ret) { int r; void *t; Object *o; uint64_t s; unsigned context; assert(f); assert(ret); /* Objects may only be located at multiple of 64 bit */ if (!VALID64(offset)) return -EFAULT; /* One context for each type, plus one catch-all for the rest */ context = type > 0 && type < _OBJECT_TYPE_MAX ? type : 0; r = journal_file_move_to(f, context, offset, sizeof(ObjectHeader), &t); if (r < 0) return r; o = (Object*) t; s = le64toh(o->object.size); if (s < sizeof(ObjectHeader)) return -EBADMSG; if (o->object.type <= OBJECT_UNUSED) return -EBADMSG; if (s < minimum_header_size(o)) return -EBADMSG; if (type >= 0 && o->object.type != type) return -EBADMSG; if (s > sizeof(ObjectHeader)) { r = journal_file_move_to(f, o->object.type, offset, s, &t); if (r < 0) return r; o = (Object*) t; } *ret = o; return 0; } static uint64_t journal_file_entry_seqnum(JournalFile *f, uint64_t *seqnum) { uint64_t r; assert(f); r = le64toh(f->header->tail_entry_seqnum) + 1; if (seqnum) { /* If an external seqnum counter was passed, we update * both the local and the external one, and set it to * the maximum of both */ if (*seqnum + 1 > r) r = *seqnum + 1; *seqnum = r; } f->header->tail_entry_seqnum = htole64(r); if (f->header->head_entry_seqnum == 0) f->header->head_entry_seqnum = htole64(r); return r; } int journal_file_append_object(JournalFile *f, int type, uint64_t size, Object **ret, uint64_t *offset) { int r; uint64_t p; Object *tail, *o; void *t; assert(f); assert(type > 0 && type < _OBJECT_TYPE_MAX); assert(size >= sizeof(ObjectHeader)); assert(offset); assert(ret); p = le64toh(f->header->tail_object_offset); if (p == 0) p = le64toh(f->header->header_size); else { r = journal_file_move_to_object(f, -1, p, &tail); if (r < 0) return r; p += ALIGN64(le64toh(tail->object.size)); } r = journal_file_allocate(f, p, size); if (r < 0) return r; r = journal_file_move_to(f, type, p, size, &t); if (r < 0) return r; o = (Object*) t; zero(o->object); o->object.type = type; o->object.size = htole64(size); f->header->tail_object_offset = htole64(p); f->header->n_objects = htole64(le64toh(f->header->n_objects) + 1); *ret = o; *offset = p; return 0; } static int journal_file_setup_data_hash_table(JournalFile *f) { uint64_t s, p; Object *o; int r; assert(f); /* We estimate that we need 1 hash table entry per 768 of journal file and we want to make sure we never get beyond 75% fill level. Calculate the hash table size for the maximum file size based on these metrics. */ s = (f->metrics.max_size * 4 / 768 / 3) * sizeof(HashItem); if (s < DEFAULT_DATA_HASH_TABLE_SIZE) s = DEFAULT_DATA_HASH_TABLE_SIZE; log_info("Reserving %llu entries in hash table.", (unsigned long long) (s / sizeof(HashItem))); r = journal_file_append_object(f, OBJECT_DATA_HASH_TABLE, offsetof(Object, hash_table.items) + s, &o, &p); if (r < 0) return r; memset(o->hash_table.items, 0, s); f->header->data_hash_table_offset = htole64(p + offsetof(Object, hash_table.items)); f->header->data_hash_table_size = htole64(s); return 0; } static int journal_file_setup_field_hash_table(JournalFile *f) { uint64_t s, p; Object *o; int r; assert(f); s = DEFAULT_FIELD_HASH_TABLE_SIZE; r = journal_file_append_object(f, OBJECT_FIELD_HASH_TABLE, offsetof(Object, hash_table.items) + s, &o, &p); if (r < 0) return r; memset(o->hash_table.items, 0, s); f->header->field_hash_table_offset = htole64(p + offsetof(Object, hash_table.items)); f->header->field_hash_table_size = htole64(s); return 0; } static int journal_file_map_data_hash_table(JournalFile *f) { uint64_t s, p; void *t; int r; assert(f); p = le64toh(f->header->data_hash_table_offset); s = le64toh(f->header->data_hash_table_size); r = journal_file_move_to(f, OBJECT_DATA_HASH_TABLE, p, s, &t); if (r < 0) return r; f->data_hash_table = t; return 0; } static int journal_file_map_field_hash_table(JournalFile *f) { uint64_t s, p; void *t; int r; assert(f); p = le64toh(f->header->field_hash_table_offset); s = le64toh(f->header->field_hash_table_size); r = journal_file_move_to(f, OBJECT_FIELD_HASH_TABLE, p, s, &t); if (r < 0) return r; f->field_hash_table = t; return 0; } static int journal_file_link_data(JournalFile *f, Object *o, uint64_t offset, uint64_t hash) { uint64_t p, h; int r; assert(f); assert(o); assert(offset > 0); assert(o->object.type == OBJECT_DATA); /* This might alter the window we are looking at */ o->data.next_hash_offset = o->data.next_field_offset = 0; o->data.entry_offset = o->data.entry_array_offset = 0; o->data.n_entries = 0; h = hash % (le64toh(f->header->data_hash_table_size) / sizeof(HashItem)); p = le64toh(f->data_hash_table[h].tail_hash_offset); if (p == 0) { /* Only entry in the hash table is easy */ f->data_hash_table[h].head_hash_offset = htole64(offset); } else { /* Move back to the previous data object, to patch in * pointer */ r = journal_file_move_to_object(f, OBJECT_DATA, p, &o); if (r < 0) return r; o->data.next_hash_offset = htole64(offset); } f->data_hash_table[h].tail_hash_offset = htole64(offset); if (JOURNAL_HEADER_CONTAINS(f->header, n_data)) f->header->n_data = htole64(le64toh(f->header->n_data) + 1); return 0; } int journal_file_find_data_object_with_hash( JournalFile *f, const void *data, uint64_t size, uint64_t hash, Object **ret, uint64_t *offset) { uint64_t p, osize, h; int r; assert(f); assert(data || size == 0); osize = offsetof(Object, data.payload) + size; if (f->header->data_hash_table_size == 0) return -EBADMSG; h = hash % (le64toh(f->header->data_hash_table_size) / sizeof(HashItem)); p = le64toh(f->data_hash_table[h].head_hash_offset); while (p > 0) { Object *o; r = journal_file_move_to_object(f, OBJECT_DATA, p, &o); if (r < 0) return r; if (le64toh(o->data.hash) != hash) goto next; if (o->object.flags & OBJECT_COMPRESSED) { #ifdef HAVE_XZ uint64_t l, rsize; l = le64toh(o->object.size); if (l <= offsetof(Object, data.payload)) return -EBADMSG; l -= offsetof(Object, data.payload); if (!uncompress_blob(o->data.payload, l, &f->compress_buffer, &f->compress_buffer_size, &rsize)) return -EBADMSG; if (rsize == size && memcmp(f->compress_buffer, data, size) == 0) { if (ret) *ret = o; if (offset) *offset = p; return 1; } #else return -EPROTONOSUPPORT; #endif } else if (le64toh(o->object.size) == osize && memcmp(o->data.payload, data, size) == 0) { if (ret) *ret = o; if (offset) *offset = p; return 1; } next: p = le64toh(o->data.next_hash_offset); } return 0; } int journal_file_find_data_object( JournalFile *f, const void *data, uint64_t size, Object **ret, uint64_t *offset) { uint64_t hash; assert(f); assert(data || size == 0); hash = hash64(data, size); return journal_file_find_data_object_with_hash(f, data, size, hash, ret, offset); } static int journal_file_append_data( JournalFile *f, const void *data, uint64_t size, Object **ret, uint64_t *offset) { uint64_t hash, p; uint64_t osize; Object *o; int r; bool compressed = false; assert(f); assert(data || size == 0); hash = hash64(data, size); r = journal_file_find_data_object_with_hash(f, data, size, hash, &o, &p); if (r < 0) return r; else if (r > 0) { if (ret) *ret = o; if (offset) *offset = p; return 0; } osize = offsetof(Object, data.payload) + size; r = journal_file_append_object(f, OBJECT_DATA, osize, &o, &p); if (r < 0) return r; o->data.hash = htole64(hash); #ifdef HAVE_XZ if (f->compress && size >= COMPRESSION_SIZE_THRESHOLD) { uint64_t rsize; compressed = compress_blob(data, size, o->data.payload, &rsize); if (compressed) { o->object.size = htole64(offsetof(Object, data.payload) + rsize); o->object.flags |= OBJECT_COMPRESSED; log_debug("Compressed data object %lu -> %lu", (unsigned long) size, (unsigned long) rsize); } } #endif if (!compressed && size > 0) memcpy(o->data.payload, data, size); r = journal_file_link_data(f, o, p, hash); if (r < 0) return r; r = journal_file_hmac_put_object(f, OBJECT_DATA, p); if (r < 0) return r; /* The linking might have altered the window, so let's * refresh our pointer */ r = journal_file_move_to_object(f, OBJECT_DATA, p, &o); if (r < 0) return r; if (ret) *ret = o; if (offset) *offset = p; return 0; } uint64_t journal_file_entry_n_items(Object *o) { assert(o); assert(o->object.type == OBJECT_ENTRY); return (le64toh(o->object.size) - offsetof(Object, entry.items)) / sizeof(EntryItem); } uint64_t journal_file_entry_array_n_items(Object *o) { assert(o); assert(o->object.type == OBJECT_ENTRY_ARRAY); return (le64toh(o->object.size) - offsetof(Object, entry_array.items)) / sizeof(uint64_t); } uint64_t journal_file_hash_table_n_items(Object *o) { assert(o); assert(o->object.type == OBJECT_DATA_HASH_TABLE || o->object.type == OBJECT_FIELD_HASH_TABLE); return (le64toh(o->object.size) - offsetof(Object, hash_table.items)) / sizeof(HashItem); } static int link_entry_into_array(JournalFile *f, le64_t *first, le64_t *idx, uint64_t p) { int r; uint64_t n = 0, ap = 0, q, i, a, hidx; Object *o; assert(f); assert(first); assert(idx); assert(p > 0); a = le64toh(*first); i = hidx = le64toh(*idx); while (a > 0) { r = journal_file_move_to_object(f, OBJECT_ENTRY_ARRAY, a, &o); if (r < 0) return r; n = journal_file_entry_array_n_items(o); if (i < n) { o->entry_array.items[i] = htole64(p); *idx = htole64(hidx + 1); return 0; } i -= n; ap = a; a = le64toh(o->entry_array.next_entry_array_offset); } if (hidx > n) n = (hidx+1) * 2; else n = n * 2; if (n < 4) n = 4; r = journal_file_append_object(f, OBJECT_ENTRY_ARRAY, offsetof(Object, entry_array.items) + n * sizeof(uint64_t), &o, &q); if (r < 0) return r; r = journal_file_hmac_put_object(f, OBJECT_ENTRY_ARRAY, q); if (r < 0) return r; o->entry_array.items[i] = htole64(p); if (ap == 0) *first = htole64(q); else { r = journal_file_move_to_object(f, OBJECT_ENTRY_ARRAY, ap, &o); if (r < 0) return r; o->entry_array.next_entry_array_offset = htole64(q); } if (JOURNAL_HEADER_CONTAINS(f->header, n_entry_arrays)) f->header->n_entry_arrays = htole64(le64toh(f->header->n_entry_arrays) + 1); *idx = htole64(hidx + 1); return 0; } static int link_entry_into_array_plus_one(JournalFile *f, le64_t *extra, le64_t *first, le64_t *idx, uint64_t p) { int r; assert(f); assert(extra); assert(first); assert(idx); assert(p > 0); if (*idx == 0) *extra = htole64(p); else { le64_t i; i = htole64(le64toh(*idx) - 1); r = link_entry_into_array(f, first, &i, p); if (r < 0) return r; } *idx = htole64(le64toh(*idx) + 1); return 0; } static int journal_file_link_entry_item(JournalFile *f, Object *o, uint64_t offset, uint64_t i) { uint64_t p; int r; assert(f); assert(o); assert(offset > 0); p = le64toh(o->entry.items[i].object_offset); if (p == 0) return -EINVAL; r = journal_file_move_to_object(f, OBJECT_DATA, p, &o); if (r < 0) return r; return link_entry_into_array_plus_one(f, &o->data.entry_offset, &o->data.entry_array_offset, &o->data.n_entries, offset); } static int journal_file_link_entry(JournalFile *f, Object *o, uint64_t offset) { uint64_t n, i; int r; assert(f); assert(o); assert(offset > 0); assert(o->object.type == OBJECT_ENTRY); __sync_synchronize(); /* Link up the entry itself */ r = link_entry_into_array(f, &f->header->entry_array_offset, &f->header->n_entries, offset); if (r < 0) return r; /* log_debug("=> %s seqnr=%lu n_entries=%lu", f->path, (unsigned long) o->entry.seqnum, (unsigned long) f->header->n_entries); */ if (f->header->head_entry_realtime == 0) f->header->head_entry_realtime = o->entry.realtime; f->header->tail_entry_realtime = o->entry.realtime; f->header->tail_entry_monotonic = o->entry.monotonic; f->tail_entry_monotonic_valid = true; /* Link up the items */ n = journal_file_entry_n_items(o); for (i = 0; i < n; i++) { r = journal_file_link_entry_item(f, o, offset, i); if (r < 0) return r; } return 0; } static int journal_file_append_entry_internal( JournalFile *f, const dual_timestamp *ts, uint64_t xor_hash, const EntryItem items[], unsigned n_items, uint64_t *seqnum, Object **ret, uint64_t *offset) { uint64_t np; uint64_t osize; Object *o; int r; assert(f); assert(items || n_items == 0); assert(ts); osize = offsetof(Object, entry.items) + (n_items * sizeof(EntryItem)); r = journal_file_append_object(f, OBJECT_ENTRY, osize, &o, &np); if (r < 0) return r; o->entry.seqnum = htole64(journal_file_entry_seqnum(f, seqnum)); memcpy(o->entry.items, items, n_items * sizeof(EntryItem)); o->entry.realtime = htole64(ts->realtime); o->entry.monotonic = htole64(ts->monotonic); o->entry.xor_hash = htole64(xor_hash); o->entry.boot_id = f->header->boot_id; r = journal_file_hmac_put_object(f, OBJECT_ENTRY, np); if (r < 0) return r; r = journal_file_link_entry(f, o, np); if (r < 0) return r; if (ret) *ret = o; if (offset) *offset = np; return 0; } void journal_file_post_change(JournalFile *f) { assert(f); /* inotify() does not receive IN_MODIFY events from file * accesses done via mmap(). After each access we hence * trigger IN_MODIFY by truncating the journal file to its * current size which triggers IN_MODIFY. */ __sync_synchronize(); if (ftruncate(f->fd, f->last_stat.st_size) < 0) log_error("Failed to to truncate file to its own size: %m"); } int journal_file_append_entry(JournalFile *f, const dual_timestamp *ts, const struct iovec iovec[], unsigned n_iovec, uint64_t *seqnum, Object **ret, uint64_t *offset) { unsigned i; EntryItem *items; int r; uint64_t xor_hash = 0; struct dual_timestamp _ts; assert(f); assert(iovec || n_iovec == 0); if (!f->writable) return -EPERM; if (!ts) { dual_timestamp_get(&_ts); ts = &_ts; } if (f->tail_entry_monotonic_valid && ts->monotonic < le64toh(f->header->tail_entry_monotonic)) return -EINVAL; r = journal_file_maybe_append_tag(f, ts->realtime); if (r < 0) return r; /* alloca() can't take 0, hence let's allocate at least one */ items = alloca(sizeof(EntryItem) * MAX(1, n_iovec)); for (i = 0; i < n_iovec; i++) { uint64_t p; Object *o; r = journal_file_append_data(f, iovec[i].iov_base, iovec[i].iov_len, &o, &p); if (r < 0) return r; xor_hash ^= le64toh(o->data.hash); items[i].object_offset = htole64(p); items[i].hash = o->data.hash; } r = journal_file_append_entry_internal(f, ts, xor_hash, items, n_iovec, seqnum, ret, offset); journal_file_post_change(f); return r; } static int generic_array_get(JournalFile *f, uint64_t first, uint64_t i, Object **ret, uint64_t *offset) { Object *o; uint64_t p = 0, a; int r; assert(f); a = first; while (a > 0) { uint64_t n; r = journal_file_move_to_object(f, OBJECT_ENTRY_ARRAY, a, &o); if (r < 0) return r; n = journal_file_entry_array_n_items(o); if (i < n) { p = le64toh(o->entry_array.items[i]); break; } i -= n; a = le64toh(o->entry_array.next_entry_array_offset); } if (a <= 0 || p <= 0) return 0; r = journal_file_move_to_object(f, OBJECT_ENTRY, p, &o); if (r < 0) return r; if (ret) *ret = o; if (offset) *offset = p; return 1; } static int generic_array_get_plus_one(JournalFile *f, uint64_t extra, uint64_t first, uint64_t i, Object **ret, uint64_t *offset) { Object *o; assert(f); if (i == 0) { int r; r = journal_file_move_to_object(f, OBJECT_ENTRY, extra, &o); if (r < 0) return r; if (ret) *ret = o; if (offset) *offset = extra; return 1; } return generic_array_get(f, first, i-1, ret, offset); } enum { TEST_FOUND, TEST_LEFT, TEST_RIGHT }; static int generic_array_bisect(JournalFile *f, uint64_t first, uint64_t n, uint64_t needle, int (*test_object)(JournalFile *f, uint64_t p, uint64_t needle), direction_t direction, Object **ret, uint64_t *offset, uint64_t *idx) { uint64_t a, p, t = 0, i = 0, last_p = 0; bool subtract_one = false; Object *o, *array = NULL; int r; assert(f); assert(test_object); a = first; while (a > 0) { uint64_t left, right, k, lp; r = journal_file_move_to_object(f, OBJECT_ENTRY_ARRAY, a, &array); if (r < 0) return r; k = journal_file_entry_array_n_items(array); right = MIN(k, n); if (right <= 0) return 0; i = right - 1; lp = p = le64toh(array->entry_array.items[i]); if (p <= 0) return -EBADMSG; r = test_object(f, p, needle); if (r < 0) return r; if (r == TEST_FOUND) r = direction == DIRECTION_DOWN ? TEST_RIGHT : TEST_LEFT; if (r == TEST_RIGHT) { left = 0; right -= 1; for (;;) { if (left == right) { if (direction == DIRECTION_UP) subtract_one = true; i = left; goto found; } assert(left < right); i = (left + right) / 2; p = le64toh(array->entry_array.items[i]); if (p <= 0) return -EBADMSG; r = test_object(f, p, needle); if (r < 0) return r; if (r == TEST_FOUND) r = direction == DIRECTION_DOWN ? TEST_RIGHT : TEST_LEFT; if (r == TEST_RIGHT) right = i; else left = i + 1; } } if (k > n) { if (direction == DIRECTION_UP) { i = n; subtract_one = true; goto found; } return 0; } last_p = lp; n -= k; t += k; a = le64toh(array->entry_array.next_entry_array_offset); } return 0; found: if (subtract_one && t == 0 && i == 0) return 0; if (subtract_one && i == 0) p = last_p; else if (subtract_one) p = le64toh(array->entry_array.items[i-1]); else p = le64toh(array->entry_array.items[i]); r = journal_file_move_to_object(f, OBJECT_ENTRY, p, &o); if (r < 0) return r; if (ret) *ret = o; if (offset) *offset = p; if (idx) *idx = t + i + (subtract_one ? -1 : 0); return 1; } static int generic_array_bisect_plus_one(JournalFile *f, uint64_t extra, uint64_t first, uint64_t n, uint64_t needle, int (*test_object)(JournalFile *f, uint64_t p, uint64_t needle), direction_t direction, Object **ret, uint64_t *offset, uint64_t *idx) { int r; bool step_back = false; Object *o; assert(f); assert(test_object); if (n <= 0) return 0; /* This bisects the array in object 'first', but first checks * an extra */ r = test_object(f, extra, needle); if (r < 0) return r; if (r == TEST_FOUND) r = direction == DIRECTION_DOWN ? TEST_RIGHT : TEST_LEFT; /* if we are looking with DIRECTION_UP then we need to first see if in the actual array there is a matching entry, and return the last one of that. But if there isn't any we need to return this one. Hence remember this, and return it below. */ if (r == TEST_LEFT) step_back = direction == DIRECTION_UP; if (r == TEST_RIGHT) { if (direction == DIRECTION_DOWN) goto found; else return 0; } r = generic_array_bisect(f, first, n-1, needle, test_object, direction, ret, offset, idx); if (r == 0 && step_back) goto found; if (r > 0 && idx) (*idx) ++; return r; found: r = journal_file_move_to_object(f, OBJECT_ENTRY, extra, &o); if (r < 0) return r; if (ret) *ret = o; if (offset) *offset = extra; if (idx) *idx = 0; return 1; } static int test_object_offset(JournalFile *f, uint64_t p, uint64_t needle) { assert(f); assert(p > 0); if (p == needle) return TEST_FOUND; else if (p < needle) return TEST_LEFT; else return TEST_RIGHT; } int journal_file_move_to_entry_by_offset( JournalFile *f, uint64_t p, direction_t direction, Object **ret, uint64_t *offset) { return generic_array_bisect(f, le64toh(f->header->entry_array_offset), le64toh(f->header->n_entries), p, test_object_offset, direction, ret, offset, NULL); } static int test_object_seqnum(JournalFile *f, uint64_t p, uint64_t needle) { Object *o; int r; assert(f); assert(p > 0); r = journal_file_move_to_object(f, OBJECT_ENTRY, p, &o); if (r < 0) return r; if (le64toh(o->entry.seqnum) == needle) return TEST_FOUND; else if (le64toh(o->entry.seqnum) < needle) return TEST_LEFT; else return TEST_RIGHT; } int journal_file_move_to_entry_by_seqnum( JournalFile *f, uint64_t seqnum, direction_t direction, Object **ret, uint64_t *offset) { return generic_array_bisect(f, le64toh(f->header->entry_array_offset), le64toh(f->header->n_entries), seqnum, test_object_seqnum, direction, ret, offset, NULL); } static int test_object_realtime(JournalFile *f, uint64_t p, uint64_t needle) { Object *o; int r; assert(f); assert(p > 0); r = journal_file_move_to_object(f, OBJECT_ENTRY, p, &o); if (r < 0) return r; if (le64toh(o->entry.realtime) == needle) return TEST_FOUND; else if (le64toh(o->entry.realtime) < needle) return TEST_LEFT; else return TEST_RIGHT; } int journal_file_move_to_entry_by_realtime( JournalFile *f, uint64_t realtime, direction_t direction, Object **ret, uint64_t *offset) { return generic_array_bisect(f, le64toh(f->header->entry_array_offset), le64toh(f->header->n_entries), realtime, test_object_realtime, direction, ret, offset, NULL); } static int test_object_monotonic(JournalFile *f, uint64_t p, uint64_t needle) { Object *o; int r; assert(f); assert(p > 0); r = journal_file_move_to_object(f, OBJECT_ENTRY, p, &o); if (r < 0) return r; if (le64toh(o->entry.monotonic) == needle) return TEST_FOUND; else if (le64toh(o->entry.monotonic) < needle) return TEST_LEFT; else return TEST_RIGHT; } int journal_file_move_to_entry_by_monotonic( JournalFile *f, sd_id128_t boot_id, uint64_t monotonic, direction_t direction, Object **ret, uint64_t *offset) { char t[9+32+1] = "_BOOT_ID="; Object *o; int r; assert(f); sd_id128_to_string(boot_id, t + 9); r = journal_file_find_data_object(f, t, strlen(t), &o, NULL); if (r < 0) return r; if (r == 0) return -ENOENT; return generic_array_bisect_plus_one(f, le64toh(o->data.entry_offset), le64toh(o->data.entry_array_offset), le64toh(o->data.n_entries), monotonic, test_object_monotonic, direction, ret, offset, NULL); } int journal_file_next_entry( JournalFile *f, Object *o, uint64_t p, direction_t direction, Object **ret, uint64_t *offset) { uint64_t i, n; int r; assert(f); assert(p > 0 || !o); n = le64toh(f->header->n_entries); if (n <= 0) return 0; if (!o) i = direction == DIRECTION_DOWN ? 0 : n - 1; else { if (o->object.type != OBJECT_ENTRY) return -EINVAL; r = generic_array_bisect(f, le64toh(f->header->entry_array_offset), le64toh(f->header->n_entries), p, test_object_offset, DIRECTION_DOWN, NULL, NULL, &i); if (r <= 0) return r; if (direction == DIRECTION_DOWN) { if (i >= n - 1) return 0; i++; } else { if (i <= 0) return 0; i--; } } /* And jump to it */ return generic_array_get(f, le64toh(f->header->entry_array_offset), i, ret, offset); } int journal_file_skip_entry( JournalFile *f, Object *o, uint64_t p, int64_t skip, Object **ret, uint64_t *offset) { uint64_t i, n; int r; assert(f); assert(o); assert(p > 0); if (o->object.type != OBJECT_ENTRY) return -EINVAL; r = generic_array_bisect(f, le64toh(f->header->entry_array_offset), le64toh(f->header->n_entries), p, test_object_offset, DIRECTION_DOWN, NULL, NULL, &i); if (r <= 0) return r; /* Calculate new index */ if (skip < 0) { if ((uint64_t) -skip >= i) i = 0; else i = i - (uint64_t) -skip; } else i += (uint64_t) skip; n = le64toh(f->header->n_entries); if (n <= 0) return -EBADMSG; if (i >= n) i = n-1; return generic_array_get(f, le64toh(f->header->entry_array_offset), i, ret, offset); } int journal_file_next_entry_for_data( JournalFile *f, Object *o, uint64_t p, uint64_t data_offset, direction_t direction, Object **ret, uint64_t *offset) { uint64_t n, i; int r; Object *d; assert(f); assert(p > 0 || !o); r = journal_file_move_to_object(f, OBJECT_DATA, data_offset, &d); if (r < 0) return r; n = le64toh(d->data.n_entries); if (n <= 0) return n; if (!o) i = direction == DIRECTION_DOWN ? 0 : n - 1; else { if (o->object.type != OBJECT_ENTRY) return -EINVAL; r = generic_array_bisect_plus_one(f, le64toh(d->data.entry_offset), le64toh(d->data.entry_array_offset), le64toh(d->data.n_entries), p, test_object_offset, DIRECTION_DOWN, NULL, NULL, &i); if (r <= 0) return r; if (direction == DIRECTION_DOWN) { if (i >= n - 1) return 0; i++; } else { if (i <= 0) return 0; i--; } } return generic_array_get_plus_one(f, le64toh(d->data.entry_offset), le64toh(d->data.entry_array_offset), i, ret, offset); } int journal_file_move_to_entry_by_offset_for_data( JournalFile *f, uint64_t data_offset, uint64_t p, direction_t direction, Object **ret, uint64_t *offset) { int r; Object *d; assert(f); r = journal_file_move_to_object(f, OBJECT_DATA, data_offset, &d); if (r < 0) return r; return generic_array_bisect_plus_one(f, le64toh(d->data.entry_offset), le64toh(d->data.entry_array_offset), le64toh(d->data.n_entries), p, test_object_offset, direction, ret, offset, NULL); } int journal_file_move_to_entry_by_monotonic_for_data( JournalFile *f, uint64_t data_offset, sd_id128_t boot_id, uint64_t monotonic, direction_t direction, Object **ret, uint64_t *offset) { char t[9+32+1] = "_BOOT_ID="; Object *o, *d; int r; uint64_t b, z; assert(f); /* First, seek by time */ sd_id128_to_string(boot_id, t + 9); r = journal_file_find_data_object(f, t, strlen(t), &o, &b); if (r < 0) return r; if (r == 0) return -ENOENT; r = generic_array_bisect_plus_one(f, le64toh(o->data.entry_offset), le64toh(o->data.entry_array_offset), le64toh(o->data.n_entries), monotonic, test_object_monotonic, direction, NULL, &z, NULL); if (r <= 0) return r; /* And now, continue seeking until we find an entry that * exists in both bisection arrays */ for (;;) { Object *qo; uint64_t p, q; r = journal_file_move_to_object(f, OBJECT_DATA, data_offset, &d); if (r < 0) return r; r = generic_array_bisect_plus_one(f, le64toh(d->data.entry_offset), le64toh(d->data.entry_array_offset), le64toh(d->data.n_entries), z, test_object_offset, direction, NULL, &p, NULL); if (r <= 0) return r; r = journal_file_move_to_object(f, OBJECT_DATA, b, &o); if (r < 0) return r; r = generic_array_bisect_plus_one(f, le64toh(o->data.entry_offset), le64toh(o->data.entry_array_offset), le64toh(o->data.n_entries), p, test_object_offset, direction, &qo, &q, NULL); if (r <= 0) return r; if (p == q) { if (ret) *ret = qo; if (offset) *offset = q; return 1; } z = q; } return 0; } int journal_file_move_to_entry_by_seqnum_for_data( JournalFile *f, uint64_t data_offset, uint64_t seqnum, direction_t direction, Object **ret, uint64_t *offset) { Object *d; int r; assert(f); r = journal_file_move_to_object(f, OBJECT_DATA, data_offset, &d); if (r < 0) return r; return generic_array_bisect_plus_one(f, le64toh(d->data.entry_offset), le64toh(d->data.entry_array_offset), le64toh(d->data.n_entries), seqnum, test_object_seqnum, direction, ret, offset, NULL); } int journal_file_move_to_entry_by_realtime_for_data( JournalFile *f, uint64_t data_offset, uint64_t realtime, direction_t direction, Object **ret, uint64_t *offset) { Object *d; int r; assert(f); r = journal_file_move_to_object(f, OBJECT_DATA, data_offset, &d); if (r < 0) return r; return generic_array_bisect_plus_one(f, le64toh(d->data.entry_offset), le64toh(d->data.entry_array_offset), le64toh(d->data.n_entries), realtime, test_object_realtime, direction, ret, offset, NULL); } void journal_file_dump(JournalFile *f) { Object *o; int r; uint64_t p; assert(f); journal_file_print_header(f); p = le64toh(f->header->header_size); while (p != 0) { r = journal_file_move_to_object(f, -1, p, &o); if (r < 0) goto fail; switch (o->object.type) { case OBJECT_UNUSED: printf("Type: OBJECT_UNUSED\n"); break; case OBJECT_DATA: printf("Type: OBJECT_DATA\n"); break; case OBJECT_ENTRY: printf("Type: OBJECT_ENTRY %llu %llu %llu\n", (unsigned long long) le64toh(o->entry.seqnum), (unsigned long long) le64toh(o->entry.monotonic), (unsigned long long) le64toh(o->entry.realtime)); break; case OBJECT_FIELD_HASH_TABLE: printf("Type: OBJECT_FIELD_HASH_TABLE\n"); break; case OBJECT_DATA_HASH_TABLE: printf("Type: OBJECT_DATA_HASH_TABLE\n"); break; case OBJECT_ENTRY_ARRAY: printf("Type: OBJECT_ENTRY_ARRAY\n"); break; case OBJECT_TAG: printf("Type: OBJECT_TAG %llu\n", (unsigned long long) le64toh(o->tag.seqnum)); break; } if (o->object.flags & OBJECT_COMPRESSED) printf("Flags: COMPRESSED\n"); if (p == le64toh(f->header->tail_object_offset)) p = 0; else p = p + ALIGN64(le64toh(o->object.size)); } return; fail: log_error("File corrupt"); } void journal_file_print_header(JournalFile *f) { char a[33], b[33], c[33]; char x[FORMAT_TIMESTAMP_MAX], y[FORMAT_TIMESTAMP_MAX]; assert(f); printf("File Path: %s\n" "File ID: %s\n" "Machine ID: %s\n" "Boot ID: %s\n" "Sequential Number ID: %s\n" "State: %s\n" "Compatible Flags:%s%s\n" "Incompatible Flags:%s%s\n" "Header size: %llu\n" "Arena size: %llu\n" "Data Hash Table Size: %llu\n" "Field Hash Table Size: %llu\n" "Rotate Suggested: %s\n" "Head Sequential Number: %llu\n" "Tail Sequential Number: %llu\n" "Head Realtime Timestamp: %s\n" "Tail Realtime Timestamp: %s\n" "Objects: %llu\n" "Entry Objects: %llu\n", f->path, sd_id128_to_string(f->header->file_id, a), sd_id128_to_string(f->header->machine_id, b), sd_id128_to_string(f->header->boot_id, c), sd_id128_to_string(f->header->seqnum_id, c), f->header->state == STATE_OFFLINE ? "OFFLINE" : f->header->state == STATE_ONLINE ? "ONLINE" : f->header->state == STATE_ARCHIVED ? "ARCHIVED" : "UNKNOWN", (f->header->compatible_flags & HEADER_COMPATIBLE_SEALED) ? " SEALED" : "", (f->header->compatible_flags & ~HEADER_COMPATIBLE_SEALED) ? " ???" : "", (f->header->incompatible_flags & HEADER_INCOMPATIBLE_COMPRESSED) ? " COMPRESSED" : "", (f->header->incompatible_flags & ~HEADER_INCOMPATIBLE_COMPRESSED) ? " ???" : "", (unsigned long long) le64toh(f->header->header_size), (unsigned long long) le64toh(f->header->arena_size), (unsigned long long) le64toh(f->header->data_hash_table_size) / sizeof(HashItem), (unsigned long long) le64toh(f->header->field_hash_table_size) / sizeof(HashItem), yes_no(journal_file_rotate_suggested(f)), (unsigned long long) le64toh(f->header->head_entry_seqnum), (unsigned long long) le64toh(f->header->tail_entry_seqnum), format_timestamp(x, sizeof(x), le64toh(f->header->head_entry_realtime)), format_timestamp(y, sizeof(y), le64toh(f->header->tail_entry_realtime)), (unsigned long long) le64toh(f->header->n_objects), (unsigned long long) le64toh(f->header->n_entries)); if (JOURNAL_HEADER_CONTAINS(f->header, n_data)) printf("Data Objects: %llu\n" "Data Hash Table Fill: %.1f%%\n", (unsigned long long) le64toh(f->header->n_data), 100.0 * (double) le64toh(f->header->n_data) / ((double) (le64toh(f->header->data_hash_table_size) / sizeof(HashItem)))); if (JOURNAL_HEADER_CONTAINS(f->header, n_fields)) printf("Field Objects: %llu\n" "Field Hash Table Fill: %.1f%%\n", (unsigned long long) le64toh(f->header->n_fields), 100.0 * (double) le64toh(f->header->n_fields) / ((double) (le64toh(f->header->field_hash_table_size) / sizeof(HashItem)))); if (JOURNAL_HEADER_CONTAINS(f->header, n_tags)) printf("Tag Objects: %llu\n", (unsigned long long) le64toh(f->header->n_tags)); if (JOURNAL_HEADER_CONTAINS(f->header, n_entry_arrays)) printf("Entry Array Objects: %llu\n", (unsigned long long) le64toh(f->header->n_entry_arrays)); } int journal_file_open( const char *fname, int flags, mode_t mode, bool compress, bool seal, JournalMetrics *metrics, MMapCache *mmap_cache, JournalFile *template, JournalFile **ret) { JournalFile *f; int r; bool newly_created = false; assert(fname); if ((flags & O_ACCMODE) != O_RDONLY && (flags & O_ACCMODE) != O_RDWR) return -EINVAL; if (!endswith(fname, ".journal") && !endswith(fname, ".journal~")) return -EINVAL; f = new0(JournalFile, 1); if (!f) return -ENOMEM; f->fd = -1; f->mode = mode; f->flags = flags; f->prot = prot_from_flags(flags); f->writable = (flags & O_ACCMODE) != O_RDONLY; f->compress = compress; f->seal = seal; if (mmap_cache) f->mmap = mmap_cache_ref(mmap_cache); else { f->mmap = mmap_cache_new(); if (!f->mmap) { r = -ENOMEM; goto fail; } } f->path = strdup(fname); if (!f->path) { r = -ENOMEM; goto fail; } f->fd = open(f->path, f->flags|O_CLOEXEC, f->mode); if (f->fd < 0) { r = -errno; goto fail; } if (fstat(f->fd, &f->last_stat) < 0) { r = -errno; goto fail; } if (f->last_stat.st_size == 0 && f->writable) { newly_created = true; /* Try to load the FSPRG state, and if we can't, then * just don't do sealing */ r = journal_file_fss_load(f); if (r < 0) f->seal = false; r = journal_file_init_header(f, template); if (r < 0) goto fail; if (fstat(f->fd, &f->last_stat) < 0) { r = -errno; goto fail; } } if (f->last_stat.st_size < (off_t) HEADER_SIZE_MIN) { r = -EIO; goto fail; } f->header = mmap(NULL, PAGE_ALIGN(sizeof(Header)), prot_from_flags(flags), MAP_SHARED, f->fd, 0); if (f->header == MAP_FAILED) { f->header = NULL; r = -errno; goto fail; } if (!newly_created) { r = journal_file_verify_header(f); if (r < 0) goto fail; } if (!newly_created && f->writable) { r = journal_file_fss_load(f); if (r < 0) goto fail; } if (f->writable) { if (metrics) { journal_default_metrics(metrics, f->fd); f->metrics = *metrics; } else if (template) f->metrics = template->metrics; r = journal_file_refresh_header(f); if (r < 0) goto fail; } r = journal_file_hmac_setup(f); if (r < 0) goto fail; if (newly_created) { r = journal_file_setup_field_hash_table(f); if (r < 0) goto fail; r = journal_file_setup_data_hash_table(f); if (r < 0) goto fail; r = journal_file_append_first_tag(f); if (r < 0) goto fail; } r = journal_file_map_field_hash_table(f); if (r < 0) goto fail; r = journal_file_map_data_hash_table(f); if (r < 0) goto fail; if (ret) *ret = f; return 0; fail: journal_file_close(f); return r; } int journal_file_rotate(JournalFile **f, bool compress, bool seal) { char *p; size_t l; JournalFile *old_file, *new_file = NULL; int r; assert(f); assert(*f); old_file = *f; if (!old_file->writable) return -EINVAL; if (!endswith(old_file->path, ".journal")) return -EINVAL; l = strlen(old_file->path); p = new(char, l + 1 + 32 + 1 + 16 + 1 + 16 + 1); if (!p) return -ENOMEM; memcpy(p, old_file->path, l - 8); p[l-8] = '@'; sd_id128_to_string(old_file->header->seqnum_id, p + l - 8 + 1); snprintf(p + l - 8 + 1 + 32, 1 + 16 + 1 + 16 + 8 + 1, "-%016llx-%016llx.journal", (unsigned long long) le64toh((*f)->header->tail_entry_seqnum), (unsigned long long) le64toh((*f)->header->tail_entry_realtime)); r = rename(old_file->path, p); free(p); if (r < 0) return -errno; old_file->header->state = STATE_ARCHIVED; r = journal_file_open(old_file->path, old_file->flags, old_file->mode, compress, seal, NULL, old_file->mmap, old_file, &new_file); journal_file_close(old_file); *f = new_file; return r; } int journal_file_open_reliably( const char *fname, int flags, mode_t mode, bool compress, bool seal, JournalMetrics *metrics, MMapCache *mmap_cache, JournalFile *template, JournalFile **ret) { int r; size_t l; char *p; r = journal_file_open(fname, flags, mode, compress, seal, metrics, mmap_cache, template, ret); if (r != -EBADMSG && /* corrupted */ r != -ENODATA && /* truncated */ r != -EHOSTDOWN && /* other machine */ r != -EPROTONOSUPPORT && /* incompatible feature */ r != -EBUSY && /* unclean shutdown */ r != -ESHUTDOWN /* already archived */) return r; if ((flags & O_ACCMODE) == O_RDONLY) return r; if (!(flags & O_CREAT)) return r; if (!endswith(fname, ".journal")) return r; /* The file is corrupted. Rotate it away and try it again (but only once) */ l = strlen(fname); if (asprintf(&p, "%.*s@%016llx-%016llx.journal~", (int) (l-8), fname, (unsigned long long) now(CLOCK_REALTIME), random_ull()) < 0) return -ENOMEM; r = rename(fname, p); free(p); if (r < 0) return -errno; log_warning("File %s corrupted or uncleanly shut down, renaming and replacing.", fname); return journal_file_open(fname, flags, mode, compress, seal, metrics, mmap_cache, template, ret); } int journal_file_copy_entry(JournalFile *from, JournalFile *to, Object *o, uint64_t p, uint64_t *seqnum, Object **ret, uint64_t *offset) { uint64_t i, n; uint64_t q, xor_hash = 0; int r; EntryItem *items; dual_timestamp ts; assert(from); assert(to); assert(o); assert(p); if (!to->writable) return -EPERM; ts.monotonic = le64toh(o->entry.monotonic); ts.realtime = le64toh(o->entry.realtime); if (to->tail_entry_monotonic_valid && ts.monotonic < le64toh(to->header->tail_entry_monotonic)) return -EINVAL; n = journal_file_entry_n_items(o); items = alloca(sizeof(EntryItem) * n); for (i = 0; i < n; i++) { uint64_t l, h; le64_t le_hash; size_t t; void *data; Object *u; q = le64toh(o->entry.items[i].object_offset); le_hash = o->entry.items[i].hash; r = journal_file_move_to_object(from, OBJECT_DATA, q, &o); if (r < 0) return r; if (le_hash != o->data.hash) return -EBADMSG; l = le64toh(o->object.size) - offsetof(Object, data.payload); t = (size_t) l; /* We hit the limit on 32bit machines */ if ((uint64_t) t != l) return -E2BIG; if (o->object.flags & OBJECT_COMPRESSED) { #ifdef HAVE_XZ uint64_t rsize; if (!uncompress_blob(o->data.payload, l, &from->compress_buffer, &from->compress_buffer_size, &rsize)) return -EBADMSG; data = from->compress_buffer; l = rsize; #else return -EPROTONOSUPPORT; #endif } else data = o->data.payload; r = journal_file_append_data(to, data, l, &u, &h); if (r < 0) return r; xor_hash ^= le64toh(u->data.hash); items[i].object_offset = htole64(h); items[i].hash = u->data.hash; r = journal_file_move_to_object(from, OBJECT_ENTRY, p, &o); if (r < 0) return r; } return journal_file_append_entry_internal(to, &ts, xor_hash, items, n, seqnum, ret, offset); } void journal_default_metrics(JournalMetrics *m, int fd) { uint64_t fs_size = 0; struct statvfs ss; char a[FORMAT_BYTES_MAX], b[FORMAT_BYTES_MAX], c[FORMAT_BYTES_MAX], d[FORMAT_BYTES_MAX]; assert(m); assert(fd >= 0); if (fstatvfs(fd, &ss) >= 0) fs_size = ss.f_frsize * ss.f_blocks; if (m->max_use == (uint64_t) -1) { if (fs_size > 0) { m->max_use = PAGE_ALIGN(fs_size / 10); /* 10% of file system size */ if (m->max_use > DEFAULT_MAX_USE_UPPER) m->max_use = DEFAULT_MAX_USE_UPPER; if (m->max_use < DEFAULT_MAX_USE_LOWER) m->max_use = DEFAULT_MAX_USE_LOWER; } else m->max_use = DEFAULT_MAX_USE_LOWER; } else { m->max_use = PAGE_ALIGN(m->max_use); if (m->max_use < JOURNAL_FILE_SIZE_MIN*2) m->max_use = JOURNAL_FILE_SIZE_MIN*2; } if (m->max_size == (uint64_t) -1) { m->max_size = PAGE_ALIGN(m->max_use / 8); /* 8 chunks */ if (m->max_size > DEFAULT_MAX_SIZE_UPPER) m->max_size = DEFAULT_MAX_SIZE_UPPER; } else m->max_size = PAGE_ALIGN(m->max_size); if (m->max_size < JOURNAL_FILE_SIZE_MIN) m->max_size = JOURNAL_FILE_SIZE_MIN; if (m->max_size*2 > m->max_use) m->max_use = m->max_size*2; if (m->min_size == (uint64_t) -1) m->min_size = JOURNAL_FILE_SIZE_MIN; else { m->min_size = PAGE_ALIGN(m->min_size); if (m->min_size < JOURNAL_FILE_SIZE_MIN) m->min_size = JOURNAL_FILE_SIZE_MIN; if (m->min_size > m->max_size) m->max_size = m->min_size; } if (m->keep_free == (uint64_t) -1) { if (fs_size > 0) { m->keep_free = PAGE_ALIGN(fs_size / 20); /* 5% of file system size */ if (m->keep_free > DEFAULT_KEEP_FREE_UPPER) m->keep_free = DEFAULT_KEEP_FREE_UPPER; } else m->keep_free = DEFAULT_KEEP_FREE; } log_info("Fixed max_use=%s max_size=%s min_size=%s keep_free=%s", format_bytes(a, sizeof(a), m->max_use), format_bytes(b, sizeof(b), m->max_size), format_bytes(c, sizeof(c), m->min_size), format_bytes(d, sizeof(d), m->keep_free)); } int journal_file_get_cutoff_realtime_usec(JournalFile *f, usec_t *from, usec_t *to) { assert(f); assert(from || to); if (from) { if (f->header->head_entry_realtime == 0) return -ENOENT; *from = le64toh(f->header->head_entry_realtime); } if (to) { if (f->header->tail_entry_realtime == 0) return -ENOENT; *to = le64toh(f->header->tail_entry_realtime); } return 1; } int journal_file_get_cutoff_monotonic_usec(JournalFile *f, sd_id128_t boot_id, usec_t *from, usec_t *to) { char t[9+32+1] = "_BOOT_ID="; Object *o; uint64_t p; int r; assert(f); assert(from || to); sd_id128_to_string(boot_id, t + 9); r = journal_file_find_data_object(f, t, strlen(t), &o, &p); if (r <= 0) return r; if (le64toh(o->data.n_entries) <= 0) return 0; if (from) { r = journal_file_move_to_object(f, OBJECT_ENTRY, le64toh(o->data.entry_offset), &o); if (r < 0) return r; *from = le64toh(o->entry.monotonic); } if (to) { r = journal_file_move_to_object(f, OBJECT_DATA, p, &o); if (r < 0) return r; r = generic_array_get_plus_one(f, le64toh(o->data.entry_offset), le64toh(o->data.entry_array_offset), le64toh(o->data.n_entries)-1, &o, NULL); if (r <= 0) return r; *to = le64toh(o->entry.monotonic); } return 1; } bool journal_file_rotate_suggested(JournalFile *f) { assert(f); /* If we gained new header fields we gained new features, * hence suggest a rotation */ if (le64toh(f->header->header_size) < sizeof(Header)) { log_debug("%s uses an outdated header, suggesting rotation.", f->path); return true; } /* Let's check if the hash tables grew over a certain fill * level (75%, borrowing this value from Java's hash table * implementation), and if so suggest a rotation. To calculate * the fill level we need the n_data field, which only exists * in newer versions. */ if (JOURNAL_HEADER_CONTAINS(f->header, n_data)) if (le64toh(f->header->n_data) * 4ULL > (le64toh(f->header->data_hash_table_size) / sizeof(HashItem)) * 3ULL) { log_debug("Data hash table of %s has a fill level at %.1f (%llu of %llu items, %llu file size, %llu bytes per hash table item), suggesting rotation.", f->path, 100.0 * (double) le64toh(f->header->n_data) / ((double) (le64toh(f->header->data_hash_table_size) / sizeof(HashItem))), (unsigned long long) le64toh(f->header->n_data), (unsigned long long) (le64toh(f->header->data_hash_table_size) / sizeof(HashItem)), (unsigned long long) (f->last_stat.st_size), (unsigned long long) (f->last_stat.st_size / le64toh(f->header->n_data))); return true; } if (JOURNAL_HEADER_CONTAINS(f->header, n_fields)) if (le64toh(f->header->n_fields) * 4ULL > (le64toh(f->header->field_hash_table_size) / sizeof(HashItem)) * 3ULL) { log_debug("Field hash table of %s has a fill level at %.1f (%llu of %llu items), suggesting rotation.", f->path, 100.0 * (double) le64toh(f->header->n_fields) / ((double) (le64toh(f->header->field_hash_table_size) / sizeof(HashItem))), (unsigned long long) le64toh(f->header->n_fields), (unsigned long long) (le64toh(f->header->field_hash_table_size) / sizeof(HashItem))); return true; } return false; }