/* -*- mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- */ // vim: ft=cpp:expandtab:ts=8:sw=4:softtabstop=4: #ident "$Id$" /*====== This file is part of PerconaFT. Copyright (c) 2006, 2015, Percona and/or its affiliates. All rights reserved. PerconaFT is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License, version 2, as published by the Free Software Foundation. PerconaFT 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 General Public License for more details. You should have received a copy of the GNU General Public License along with PerconaFT. If not, see . ---------------------------------------- PerconaFT is free software: you can redistribute it and/or modify it under the terms of the GNU Affero General Public License, version 3, as published by the Free Software Foundation. PerconaFT 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 Affero General Public License for more details. You should have received a copy of the GNU Affero General Public License along with PerconaFT. If not, see . ======= */ #ident "Copyright (c) 2006, 2015, Percona and/or its affiliates. All rights reserved." #include "ft/ft.h" #include "ft/ft-internal.h" #include "ft/msg.h" #include "ft/serialize/block_allocator.h" #include "ft/serialize/block_table.h" #include "ft/serialize/compress.h" #include "ft/serialize/ft-serialize.h" // not version-sensitive because we only serialize a descriptor using the current layout_version uint32_t toku_serialize_descriptor_size(DESCRIPTOR desc) { //Checksum NOT included in this. Checksum only exists in header's version. uint32_t size = 4; // four bytes for size of descriptor size += desc->dbt.size; return size; } static uint32_t deserialize_descriptor_size(DESCRIPTOR desc, int layout_version) { //Checksum NOT included in this. Checksum only exists in header's version. uint32_t size = 4; // four bytes for size of descriptor if (layout_version == FT_LAYOUT_VERSION_13) size += 4; // for version 13, include four bytes of "version" size += desc->dbt.size; return size; } void toku_serialize_descriptor_contents_to_wbuf(struct wbuf *wb, DESCRIPTOR desc) { wbuf_bytes(wb, desc->dbt.data, desc->dbt.size); } //Descriptor is written to disk during toku_ft_handle_open iff we have a new (or changed) //descriptor. //Descriptors are NOT written during the header checkpoint process. void toku_serialize_descriptor_contents_to_fd(int fd, DESCRIPTOR desc, DISKOFF offset) { // make the checksum int64_t size = toku_serialize_descriptor_size(desc)+4; //4 for checksum int64_t size_aligned = roundup_to_multiple(512, size); struct wbuf w; char *XMALLOC_N_ALIGNED(512, size_aligned, aligned_buf); for (int64_t i=size; idbt, data, size); } static int deserialize_descriptor_from(int fd, block_table *bt, DESCRIPTOR desc, int layout_version) { int r = 0; DISKOFF offset; DISKOFF size; unsigned char *dbuf = nullptr; bt->get_descriptor_offset_size(&offset, &size); memset(desc, 0, sizeof(*desc)); if (size > 0) { lazy_assert(size>=4); //4 for checksum { ssize_t size_to_malloc = roundup_to_multiple(512, size); XMALLOC_N_ALIGNED(512, size_to_malloc, dbuf); { ssize_t sz_read = toku_os_pread(fd, dbuf, size_to_malloc, offset); lazy_assert(sz_read==size_to_malloc); } { // check the checksum uint32_t x1764 = toku_x1764_memory(dbuf, size-4); //printf("%s:%d read from %ld (x1764 offset=%ld) size=%ld\n", __FILE__, __LINE__, block_translation_address_on_disk, offset, block_translation_size_on_disk); uint32_t stored_x1764 = toku_dtoh32(*(int*)(dbuf + size-4)); if (x1764 != stored_x1764) { fprintf(stderr, "Descriptor checksum failure: calc=0x%08x read=0x%08x\n", x1764, stored_x1764); r = TOKUDB_BAD_CHECKSUM; toku_free(dbuf); goto exit; } } struct rbuf rb = { .buf = dbuf, .size = (unsigned int) size, .ndone = 0 }; deserialize_descriptor_from_rbuf(&rb, desc, layout_version); lazy_assert(deserialize_descriptor_size(desc, layout_version) + 4 == size); toku_free(dbuf); } } exit: return r; } int deserialize_ft_versioned(int fd, struct rbuf *rb, FT *ftp, uint32_t version) // Effect: Deserialize the ft header. // We deserialize ft_header only once and then share everything with all the FTs. { int r; FT ft = NULL; paranoid_invariant(version >= FT_LAYOUT_MIN_SUPPORTED_VERSION); paranoid_invariant(version <= FT_LAYOUT_VERSION); // We already know: // we have an rbuf representing the header. // The checksum has been validated //Verification of initial elements. //Check magic number const void *magic; rbuf_literal_bytes(rb, &magic, 8); lazy_assert(memcmp(magic,"tokudata",8)==0); XCALLOC(ft); ft->checkpoint_header = NULL; toku_list_init(&ft->live_ft_handles); //version MUST be in network order on disk regardless of disk order ft->layout_version_read_from_disk = rbuf_network_int(rb); invariant(ft->layout_version_read_from_disk >= FT_LAYOUT_MIN_SUPPORTED_VERSION); invariant(ft->layout_version_read_from_disk <= FT_LAYOUT_VERSION); //build_id MUST be in network order on disk regardless of disk order uint32_t build_id; build_id = rbuf_network_int(rb); //Size MUST be in network order regardless of disk order. uint32_t size; size = rbuf_network_int(rb); lazy_assert(size == rb->size); const void *tmp_byte_order_check; lazy_assert((sizeof tmp_byte_order_check) >= 8); rbuf_literal_bytes(rb, &tmp_byte_order_check, 8); //Must not translate byte order int64_t byte_order_stored; byte_order_stored = *(int64_t*)tmp_byte_order_check; lazy_assert(byte_order_stored == toku_byte_order_host); uint64_t checkpoint_count; checkpoint_count = rbuf_ulonglong(rb); LSN checkpoint_lsn; checkpoint_lsn = rbuf_LSN(rb); unsigned nodesize; nodesize = rbuf_int(rb); DISKOFF translation_address_on_disk; translation_address_on_disk = rbuf_DISKOFF(rb); DISKOFF translation_size_on_disk; translation_size_on_disk = rbuf_DISKOFF(rb); lazy_assert(translation_address_on_disk > 0); lazy_assert(translation_size_on_disk > 0); // initialize the tree lock toku_ft_init_reflock(ft); //Load translation table { size_t size_to_read = roundup_to_multiple(512, translation_size_on_disk); unsigned char *XMALLOC_N_ALIGNED(512, size_to_read, tbuf); { // This cast is messed up in 32-bits if the block translation // table is ever more than 4GB. But in that case, the // translation table itself won't fit in main memory. ssize_t readsz = toku_os_pread(fd, tbuf, size_to_read, translation_address_on_disk); invariant(readsz >= translation_size_on_disk); invariant(readsz <= (ssize_t)size_to_read); } // Create table and read in data. r = ft->blocktable.create_from_buffer(fd, translation_address_on_disk, translation_size_on_disk, tbuf); toku_free(tbuf); if (r != 0) { goto exit; } } BLOCKNUM root_blocknum; root_blocknum = rbuf_blocknum(rb); unsigned flags; flags = rbuf_int(rb); if (ft->layout_version_read_from_disk <= FT_LAYOUT_VERSION_13) { // deprecate 'TOKU_DB_VALCMP_BUILTIN'. just remove the flag flags &= ~TOKU_DB_VALCMP_BUILTIN_13; } int layout_version_original; layout_version_original = rbuf_int(rb); uint32_t build_id_original; build_id_original = rbuf_int(rb); uint64_t time_of_creation; time_of_creation = rbuf_ulonglong(rb); uint64_t time_of_last_modification; time_of_last_modification = rbuf_ulonglong(rb); if (ft->layout_version_read_from_disk <= FT_LAYOUT_VERSION_18) { // 17 was the last version with these fields, we no longer store // them, so read and discard them (void) rbuf_ulonglong(rb); // num_blocks_to_upgrade_13 if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_15) { (void) rbuf_ulonglong(rb); // num_blocks_to_upgrade_14 } } // fake creation during the last checkpoint TXNID root_xid_that_created; root_xid_that_created = checkpoint_lsn.lsn; if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_14) { rbuf_TXNID(rb, &root_xid_that_created); } // TODO(leif): get this to default to what's specified, not the // hard-coded default unsigned basementnodesize; basementnodesize = FT_DEFAULT_BASEMENT_NODE_SIZE; uint64_t time_of_last_verification; time_of_last_verification = 0; if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_15) { basementnodesize = rbuf_int(rb); time_of_last_verification = rbuf_ulonglong(rb); } STAT64INFO_S on_disk_stats; on_disk_stats = ZEROSTATS; uint64_t time_of_last_optimize_begin; time_of_last_optimize_begin = 0; uint64_t time_of_last_optimize_end; time_of_last_optimize_end = 0; uint32_t count_of_optimize_in_progress; count_of_optimize_in_progress = 0; MSN msn_at_start_of_last_completed_optimize; msn_at_start_of_last_completed_optimize = ZERO_MSN; if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_18) { on_disk_stats.numrows = rbuf_ulonglong(rb); on_disk_stats.numbytes = rbuf_ulonglong(rb); ft->in_memory_stats = on_disk_stats; time_of_last_optimize_begin = rbuf_ulonglong(rb); time_of_last_optimize_end = rbuf_ulonglong(rb); count_of_optimize_in_progress = rbuf_int(rb); msn_at_start_of_last_completed_optimize = rbuf_MSN(rb); } enum toku_compression_method compression_method; MSN highest_unused_msn_for_upgrade; highest_unused_msn_for_upgrade.msn = (MIN_MSN.msn - 1); if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_19) { unsigned char method = rbuf_char(rb); compression_method = (enum toku_compression_method) method; highest_unused_msn_for_upgrade = rbuf_MSN(rb); } else { // we hard coded zlib until 5.2, then quicklz in 5.2 if (ft->layout_version_read_from_disk < FT_LAYOUT_VERSION_18) { compression_method = TOKU_ZLIB_METHOD; } else { compression_method = TOKU_QUICKLZ_METHOD; } } MSN max_msn_in_ft; max_msn_in_ft = ZERO_MSN; // We'll upgrade it from the root node later if necessary if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_21) { max_msn_in_ft = rbuf_MSN(rb); } unsigned fanout; fanout = FT_DEFAULT_FANOUT; if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_28) { fanout = rbuf_int(rb); } uint64_t on_disk_logical_rows; on_disk_logical_rows = (uint64_t)-1; if (ft->layout_version_read_from_disk >= FT_LAYOUT_VERSION_29) { on_disk_logical_rows = rbuf_ulonglong(rb); } ft->in_memory_logical_rows = on_disk_logical_rows; (void) rbuf_int(rb); //Read in checksum and ignore (already verified). if (rb->ndone != rb->size) { fprintf(stderr, "Header size did not match contents.\n"); r = EINVAL; goto exit; } { struct ft_header h = { .type = FT_CURRENT, .dirty_ = 0, .checkpoint_count = checkpoint_count, .checkpoint_lsn = checkpoint_lsn, .layout_version = FT_LAYOUT_VERSION, .layout_version_original = layout_version_original, .build_id = build_id, .build_id_original = build_id_original, .time_of_creation = time_of_creation, .root_xid_that_created = root_xid_that_created, .time_of_last_modification = time_of_last_modification, .time_of_last_verification = time_of_last_verification, .root_blocknum = root_blocknum, .flags = flags, .nodesize = nodesize, .basementnodesize = basementnodesize, .compression_method = compression_method, .fanout = fanout, .highest_unused_msn_for_upgrade = highest_unused_msn_for_upgrade, .max_msn_in_ft = max_msn_in_ft, .time_of_last_optimize_begin = time_of_last_optimize_begin, .time_of_last_optimize_end = time_of_last_optimize_end, .count_of_optimize_in_progress = count_of_optimize_in_progress, .count_of_optimize_in_progress_read_from_disk = count_of_optimize_in_progress, .msn_at_start_of_last_completed_optimize = msn_at_start_of_last_completed_optimize, .on_disk_stats = on_disk_stats, .on_disk_logical_rows = on_disk_logical_rows }; XMEMDUP(ft->h, &h); } if (ft->layout_version_read_from_disk < FT_LAYOUT_VERSION_18) { // This needs ft->h to be non-null, so we have to do it after we // read everything else. r = toku_upgrade_subtree_estimates_to_stat64info(fd, ft); if (r != 0) { goto exit; } } if (ft->layout_version_read_from_disk < FT_LAYOUT_VERSION_21) { r = toku_upgrade_msn_from_root_to_header(fd, ft); if (r != 0) { goto exit; } } invariant((uint32_t) ft->layout_version_read_from_disk == version); r = deserialize_descriptor_from(fd, &ft->blocktable, &ft->descriptor, version); if (r != 0) { goto exit; } // initialize for svn #4541 toku_clone_dbt(&ft->cmp_descriptor.dbt, ft->descriptor.dbt); // Version 13 descriptors had an extra 4 bytes that we don't read // anymore. Since the header is going to think it's the current // version if it gets written out, we need to write the descriptor in // the new format (without those bytes) before that happens. if (version <= FT_LAYOUT_VERSION_13) { toku_ft_update_descriptor_with_fd(ft, &ft->cmp_descriptor, fd); } r = 0; exit: if (r != 0 && ft != NULL) { toku_free(ft); ft = NULL; } *ftp = ft; return r; } static size_t serialize_ft_min_size(uint32_t version) { size_t size = 0; switch (version) { case FT_LAYOUT_VERSION_29: size += sizeof(uint64_t); // logrows in ft // fallthrough case FT_LAYOUT_VERSION_28: size += sizeof(uint32_t); // fanout in ft // fallthrough case FT_LAYOUT_VERSION_27: case FT_LAYOUT_VERSION_26: case FT_LAYOUT_VERSION_25: case FT_LAYOUT_VERSION_24: case FT_LAYOUT_VERSION_23: case FT_LAYOUT_VERSION_22: case FT_LAYOUT_VERSION_21: size += sizeof(MSN); // max_msn_in_ft // fallthrough case FT_LAYOUT_VERSION_20: case FT_LAYOUT_VERSION_19: size += 1; // compression method size += sizeof(MSN); // highest_unused_msn_for_upgrade // fallthrough case FT_LAYOUT_VERSION_18: size += sizeof(uint64_t); // time_of_last_optimize_begin size += sizeof(uint64_t); // time_of_last_optimize_end size += sizeof(uint32_t); // count_of_optimize_in_progress size += sizeof(MSN); // msn_at_start_of_last_completed_optimize size -= 8; // removed num_blocks_to_upgrade_14 size -= 8; // removed num_blocks_to_upgrade_13 // fallthrough case FT_LAYOUT_VERSION_17: size += 16; invariant(sizeof(STAT64INFO_S) == 16); // fallthrough case FT_LAYOUT_VERSION_16: case FT_LAYOUT_VERSION_15: size += 4; // basement node size size += 8; // num_blocks_to_upgrade_14 (previously // num_blocks_to_upgrade, now one int each for upgrade // from 13, 14 size += 8; // time of last verification // fallthrough case FT_LAYOUT_VERSION_14: size += 8; // TXNID that created // fallthrough case FT_LAYOUT_VERSION_13: size += (4 // build_id + 4 // build_id_original + 8 // time_of_creation + 8 // time_of_last_modification ); // fallthrough case FT_LAYOUT_VERSION_12: size += (+8 // "tokudata" + 4 // version + 4 // original_version + 4 // size + 8 // byte order verification + 8 // checkpoint_count + 8 // checkpoint_lsn + 4 // tree's nodesize + 8 // translation_size_on_disk + 8 // translation_address_on_disk + 4 // checksum + 8 // Number of blocks in old version. + 8 // diskoff + 4 // flags ); break; default: abort(); } lazy_assert(size <= BlockAllocator::BLOCK_ALLOCATOR_HEADER_RESERVE); return size; } int deserialize_ft_from_fd_into_rbuf(int fd, toku_off_t offset_of_header, struct rbuf *rb, uint64_t *checkpoint_count, LSN *checkpoint_lsn, uint32_t *version_p) // Effect: Read and parse the header of a fractalal tree // // Simply reading the raw bytes of the header into an rbuf is insensitive // to disk format version. If that ever changes, then modify this. // // TOKUDB_DICTIONARY_NO_HEADER means we can overwrite everything in the // file AND the header is useless { int r = 0; const int64_t prefix_size = 8 + // magic ("tokudata") 4 + // version 4 + // build_id 4; // size const int64_t read_size = roundup_to_multiple(512, prefix_size); unsigned char *XMALLOC_N_ALIGNED(512, read_size, prefix); rb->buf = NULL; int64_t n = toku_os_pread(fd, prefix, read_size, offset_of_header); if (n != read_size) { if (n == 0) { r = TOKUDB_DICTIONARY_NO_HEADER; } else if (n < 0) { r = get_error_errno(); } else { r = EINVAL; } toku_free(prefix); goto exit; } rbuf_init(rb, prefix, prefix_size); // Check magic number const void *magic; rbuf_literal_bytes(rb, &magic, 8); if (memcmp(magic, "tokudata", 8) != 0) { if ((*(uint64_t *)magic) == 0) { r = TOKUDB_DICTIONARY_NO_HEADER; } else { r = EINVAL; // Not a tokudb file! Do not use. } goto exit; } // Version MUST be in network order regardless of disk order. uint32_t version; version = rbuf_network_int(rb); *version_p = version; if (version < FT_LAYOUT_MIN_SUPPORTED_VERSION) { r = TOKUDB_DICTIONARY_TOO_OLD; // Cannot use goto exit; } else if (version > FT_LAYOUT_VERSION) { r = TOKUDB_DICTIONARY_TOO_NEW; // Cannot use goto exit; } // build_id MUST be in network order regardless of disk order. uint32_t build_id __attribute__((__unused__)); build_id = rbuf_network_int(rb); int64_t min_header_size; min_header_size = serialize_ft_min_size(version); // Size MUST be in network order regardless of disk order. uint32_t size; size = rbuf_network_int(rb); // If too big, it is corrupt. We would probably notice during checksum // but may have to do a multi-gigabyte malloc+read to find out. // If its too small reading rbuf would crash, so verify. if (size > BlockAllocator::BLOCK_ALLOCATOR_HEADER_RESERVE || size < min_header_size) { r = TOKUDB_DICTIONARY_NO_HEADER; goto exit; } lazy_assert(rb->ndone == prefix_size); rb->size = size; { toku_free(rb->buf); uint32_t size_to_read = roundup_to_multiple(512, size); XMALLOC_N_ALIGNED(512, size_to_read, rb->buf); invariant(offset_of_header % 512 == 0); n = toku_os_pread(fd, rb->buf, size_to_read, offset_of_header); if (n != size_to_read) { if (n < 0) { r = get_error_errno(); } else { r = EINVAL; // Header might be useless (wrong size) or could be // a disk read error. } goto exit; } } // It's version 14 or later. Magic looks OK. // We have an rbuf that represents the header. // Size is within acceptable bounds. // Verify checksum (FT_LAYOUT_VERSION_13 or later, when checksum function // changed) uint32_t calculated_x1764; calculated_x1764 = toku_x1764_memory(rb->buf, rb->size - 4); uint32_t stored_x1764; stored_x1764 = toku_dtoh32(*(int *)(rb->buf + rb->size - 4)); if (calculated_x1764 != stored_x1764) { r = TOKUDB_BAD_CHECKSUM; // Header useless fprintf(stderr, "Header checksum failure: calc=0x%08x read=0x%08x\n", calculated_x1764, stored_x1764); goto exit; } // Verify byte order const void *tmp_byte_order_check; lazy_assert((sizeof toku_byte_order_host) == 8); rbuf_literal_bytes( rb, &tmp_byte_order_check, 8); // Must not translate byte order int64_t byte_order_stored; byte_order_stored = *(int64_t *)tmp_byte_order_check; if (byte_order_stored != toku_byte_order_host) { r = TOKUDB_DICTIONARY_NO_HEADER; // Cannot use dictionary goto exit; } // Load checkpoint count *checkpoint_count = rbuf_ulonglong(rb); *checkpoint_lsn = rbuf_LSN(rb); // Restart at beginning during regular deserialization rb->ndone = 0; exit: if (r != 0 && rb->buf != NULL) { toku_free(rb->buf); rb->buf = NULL; } return r; } // Read ft from file into struct. Read both headers and use one. // We want the latest acceptable header whose checkpoint_lsn is no later // than max_acceptable_lsn. #define dump_state_of_toku_deserialize_ft_from() \ fprintf(stderr, \ "%s:%d toku_deserialize_ft_from: " \ "filename[%s] " \ "r[%d] max_acceptable_lsn[%llu]" \ "r0[%d] checkpoint_lsn_0[%llu] checkpoint_count_0[%llu] " \ "r1[%d] checkpoint_lsn_1[%llu] checkpoint_count_1[%llu]\n", \ __FILE__, \ __LINE__, \ fn, \ r, \ (ulonglong)max_acceptable_lsn.lsn, \ r0, \ (ulonglong)checkpoint_lsn_0.lsn, \ (ulonglong)checkpoint_count_0, \ r1, \ (ulonglong)checkpoint_lsn_1.lsn, \ (ulonglong)checkpoint_count_1); int toku_deserialize_ft_from(int fd, const char *fn, LSN max_acceptable_lsn, FT *ft) { struct rbuf rb_0; struct rbuf rb_1; uint64_t checkpoint_count_0 = 0; uint64_t checkpoint_count_1 = 0; LSN checkpoint_lsn_0; LSN checkpoint_lsn_1; uint32_t version_0 = 0, version_1 = 0, version = 0; bool h0_acceptable = false; bool h1_acceptable = false; struct rbuf *rb = NULL; int r0, r1, r = 0; toku_off_t header_0_off = 0; r0 = deserialize_ft_from_fd_into_rbuf(fd, header_0_off, &rb_0, &checkpoint_count_0, &checkpoint_lsn_0, &version_0); if (r0 == 0 && checkpoint_lsn_0.lsn <= max_acceptable_lsn.lsn) { h0_acceptable = true; } toku_off_t header_1_off = BlockAllocator::BLOCK_ALLOCATOR_HEADER_RESERVE; r1 = deserialize_ft_from_fd_into_rbuf(fd, header_1_off, &rb_1, &checkpoint_count_1, &checkpoint_lsn_1, &version_1); if (r1 == 0 && checkpoint_lsn_1.lsn <= max_acceptable_lsn.lsn) { h1_acceptable = true; } // if either header is too new, the dictionary is unreadable if (r0 == TOKUDB_DICTIONARY_TOO_NEW || r1 == TOKUDB_DICTIONARY_TOO_NEW || !(h0_acceptable || h1_acceptable)) { // We were unable to read either header or at least one is too // new. Certain errors are higher priority than others. Order of // these if/else if is important. if (r0 == TOKUDB_DICTIONARY_TOO_NEW || r1 == TOKUDB_DICTIONARY_TOO_NEW) { r = TOKUDB_DICTIONARY_TOO_NEW; } else if (r0 == TOKUDB_DICTIONARY_TOO_OLD || r1 == TOKUDB_DICTIONARY_TOO_OLD) { r = TOKUDB_DICTIONARY_TOO_OLD; } else if (r0 == TOKUDB_BAD_CHECKSUM && r1 == TOKUDB_BAD_CHECKSUM) { fprintf(stderr, "Both header checksums failed.\n"); r = TOKUDB_BAD_CHECKSUM; } else if (r0 == TOKUDB_DICTIONARY_NO_HEADER || r1 == TOKUDB_DICTIONARY_NO_HEADER) { r = TOKUDB_DICTIONARY_NO_HEADER; } else { r = r0 ? r0 : r1; // Arbitrarily report the error from the // first header, unless it's readable } if (r != TOKUDB_DICTIONARY_NO_HEADER) { dump_state_of_toku_deserialize_ft_from(); } // it should not be possible for both headers to be later than the // max_acceptable_lsn invariant( !((r0 == 0 && checkpoint_lsn_0.lsn > max_acceptable_lsn.lsn) && (r1 == 0 && checkpoint_lsn_1.lsn > max_acceptable_lsn.lsn))); invariant(r != 0); goto exit; } if (h0_acceptable && h1_acceptable) { if (checkpoint_count_0 > checkpoint_count_1) { if (!(checkpoint_count_0 == checkpoint_count_1 + 1) || !(version_0 >= version_1)) { dump_state_of_toku_deserialize_ft_from(); } invariant(checkpoint_count_0 == checkpoint_count_1 + 1); invariant(version_0 >= version_1); rb = &rb_0; version = version_0; } else { if (!(checkpoint_count_1 == checkpoint_count_0 + 1) || !(version_1 >= version_0)) { dump_state_of_toku_deserialize_ft_from(); } invariant(checkpoint_count_1 == checkpoint_count_0 + 1); invariant(version_1 >= version_0); rb = &rb_1; version = version_1; } } else if (h0_acceptable) { if (r1 == TOKUDB_BAD_CHECKSUM) { // print something reassuring fprintf( stderr, "Header 2 checksum failed, but header 1 ok. Proceeding.\n"); dump_state_of_toku_deserialize_ft_from(); } rb = &rb_0; version = version_0; } else if (h1_acceptable) { if (r0 == TOKUDB_BAD_CHECKSUM) { // print something reassuring fprintf( stderr, "Header 1 checksum failed, but header 2 ok. Proceeding.\n"); dump_state_of_toku_deserialize_ft_from(); } rb = &rb_1; version = version_1; } if (!rb) { dump_state_of_toku_deserialize_ft_from(); } paranoid_invariant(rb); r = deserialize_ft_versioned(fd, rb, ft, version); exit: if (rb_0.buf) { toku_free(rb_0.buf); } if (rb_1.buf) { toku_free(rb_1.buf); } return r; } size_t toku_serialize_ft_size(FT_HEADER h) { size_t size = serialize_ft_min_size(h->layout_version); // There is no dynamic data. lazy_assert(size <= BlockAllocator::BLOCK_ALLOCATOR_HEADER_RESERVE); return size; } void toku_serialize_ft_to_wbuf ( struct wbuf *wbuf, FT_HEADER h, DISKOFF translation_location_on_disk, DISKOFF translation_size_on_disk ) { wbuf_literal_bytes(wbuf, "tokudata", 8); wbuf_network_int (wbuf, h->layout_version); //MUST be in network order regardless of disk order wbuf_network_int (wbuf, BUILD_ID); //MUST be in network order regardless of disk order wbuf_network_int (wbuf, wbuf->size); //MUST be in network order regardless of disk order wbuf_literal_bytes(wbuf, &toku_byte_order_host, 8); //Must not translate byte order wbuf_ulonglong(wbuf, h->checkpoint_count); wbuf_LSN (wbuf, h->checkpoint_lsn); wbuf_int (wbuf, h->nodesize); wbuf_DISKOFF(wbuf, translation_location_on_disk); wbuf_DISKOFF(wbuf, translation_size_on_disk); wbuf_BLOCKNUM(wbuf, h->root_blocknum); wbuf_int(wbuf, h->flags); wbuf_int(wbuf, h->layout_version_original); wbuf_int(wbuf, h->build_id_original); wbuf_ulonglong(wbuf, h->time_of_creation); wbuf_ulonglong(wbuf, h->time_of_last_modification); wbuf_TXNID(wbuf, h->root_xid_that_created); wbuf_int(wbuf, h->basementnodesize); wbuf_ulonglong(wbuf, h->time_of_last_verification); wbuf_ulonglong(wbuf, h->on_disk_stats.numrows); wbuf_ulonglong(wbuf, h->on_disk_stats.numbytes); wbuf_ulonglong(wbuf, h->time_of_last_optimize_begin); wbuf_ulonglong(wbuf, h->time_of_last_optimize_end); wbuf_int(wbuf, h->count_of_optimize_in_progress); wbuf_MSN(wbuf, h->msn_at_start_of_last_completed_optimize); wbuf_char(wbuf, (unsigned char) h->compression_method); wbuf_MSN(wbuf, h->highest_unused_msn_for_upgrade); wbuf_MSN(wbuf, h->max_msn_in_ft); wbuf_int(wbuf, h->fanout); wbuf_ulonglong(wbuf, h->on_disk_logical_rows); uint32_t checksum = toku_x1764_finish(&wbuf->checksum); wbuf_int(wbuf, checksum); lazy_assert(wbuf->ndone == wbuf->size); } void toku_serialize_ft_to(int fd, FT_HEADER h, block_table *bt, CACHEFILE cf) { lazy_assert(h->type == FT_CHECKPOINT_INPROGRESS); struct wbuf w_translation; int64_t size_translation; int64_t address_translation; // Must serialize translation first, to get address,size for header. bt->serialize_translation_to_wbuf( fd, &w_translation, &address_translation, &size_translation); invariant(size_translation == w_translation.ndone); // the number of bytes available in the buffer is 0 mod 512, and those last // bytes are all initialized. invariant(w_translation.size % 512 == 0); struct wbuf w_main; size_t size_main = toku_serialize_ft_size(h); size_t size_main_aligned = roundup_to_multiple(512, size_main); invariant(size_main_aligned < BlockAllocator::BLOCK_ALLOCATOR_HEADER_RESERVE); char *XMALLOC_N_ALIGNED(512, size_main_aligned, mainbuf); for (size_t i = size_main; i < size_main_aligned; i++) mainbuf[i] = 0; // initialize the end of the buffer with zeros wbuf_init(&w_main, mainbuf, size_main); toku_serialize_ft_to_wbuf( &w_main, h, address_translation, size_translation); lazy_assert(w_main.ndone == size_main); // Actually write translation table // This write is guaranteed to read good data at the end of the buffer, // since the // w_translation.buf is padded with zeros to a 512-byte boundary. toku_os_full_pwrite(fd, w_translation.buf, roundup_to_multiple(512, size_translation), address_translation); // Everything but the header MUST be on disk before header starts. // Otherwise we will think the header is good and some blocks might not // yet be on disk. // If the header has a cachefile we need to do cachefile fsync (to // prevent crash if we redirected to dev null) // If there is no cachefile we still need to do an fsync. if (cf) { toku_cachefile_fsync(cf); } else { toku_file_fsync(fd); } // Alternate writing header to two locations: // Beginning (0) or BLOCK_ALLOCATOR_HEADER_RESERVE toku_off_t main_offset; main_offset = (h->checkpoint_count & 0x1) ? 0 : BlockAllocator::BLOCK_ALLOCATOR_HEADER_RESERVE; toku_os_full_pwrite(fd, w_main.buf, size_main_aligned, main_offset); toku_free(w_main.buf); toku_free(w_translation.buf); }