/*****************************************************************//** Constructs the last committed version of a clustered index record, which should be seen by a semi-consistent read. @return DB_SUCCESS or DB_MISSING_HISTORY */ UNIV_INTERN ulint row_vers_build_for_semi_consistent_read( /*====================================*/ const rec_t* rec, /*!< in: record in a clustered index; the caller must have a latch on the page; this latch locks the top of the stack of versions of this records */ mtr_t* mtr, /*!< in: mtr holding the latch on rec */ dict_index_t* index, /*!< in: the clustered index */ ulint** offsets,/*!< in/out: offsets returned by rec_get_offsets(rec, index) */ mem_heap_t** offset_heap,/*!< in/out: memory heap from which the offsets are allocated */ mem_heap_t* in_heap,/*!< in: memory heap from which the memory for *old_vers is allocated; memory for possible intermediate versions is allocated and freed locally within the function */ const rec_t** old_vers)/*!< out: rec, old version, or NULL if the record does not exist in the view, that is, it was freshly inserted afterwards */ { const rec_t* version; mem_heap_t* heap = NULL; byte* buf; ulint err; trx_id_t rec_trx_id = ut_dulint_zero; ut_ad(dict_index_is_clust(index)); ut_ad(mtr_memo_contains_page(mtr, rec, MTR_MEMO_PAGE_X_FIX) || mtr_memo_contains_page(mtr, rec, MTR_MEMO_PAGE_S_FIX)); #ifdef UNIV_SYNC_DEBUG ut_ad(!rw_lock_own(&(purge_sys->latch), RW_LOCK_SHARED)); #endif /* UNIV_SYNC_DEBUG */ ut_ad(rec_offs_validate(rec, index, *offsets)); rw_lock_s_lock(&(purge_sys->latch)); /* The S-latch on purge_sys prevents the purge view from changing. Thus, if we have an uncommitted transaction at this point, then purge cannot remove its undo log even if the transaction could commit now. */ version = rec; for (;;) { trx_t* version_trx; mem_heap_t* heap2; rec_t* prev_version; trx_id_t version_trx_id; version_trx_id = row_get_rec_trx_id(version, index, *offsets); if (rec == version) { rec_trx_id = version_trx_id; } mutex_enter(&kernel_mutex); version_trx = trx_get_on_id(version_trx_id); if (version_trx && (version_trx->conc_state == TRX_COMMITTED_IN_MEMORY || version_trx->conc_state == TRX_NOT_STARTED)) { version_trx = NULL; } mutex_exit(&kernel_mutex); if (!version_trx) { /* We found a version that belongs to a committed transaction: return it. */ #if defined UNIV_DEBUG || defined UNIV_BLOB_LIGHT_DEBUG ut_a(!rec_offs_any_null_extern(version, *offsets)); #endif /* UNIV_DEBUG || UNIV_BLOB_LIGHT_DEBUG */ if (rec == version) { *old_vers = rec; err = DB_SUCCESS; break; } /* We assume that a rolled-back transaction stays in TRX_ACTIVE state until all the changes have been rolled back and the transaction is removed from the global list of transactions. */ if (!ut_dulint_cmp(rec_trx_id, version_trx_id)) { /* The transaction was committed while we searched for earlier versions. Return the current version as a semi-consistent read. */ version = rec; *offsets = rec_get_offsets(version, index, *offsets, ULINT_UNDEFINED, offset_heap); } buf = mem_heap_alloc(in_heap, rec_offs_size(*offsets)); *old_vers = rec_copy(buf, version, *offsets); rec_offs_make_valid(*old_vers, index, *offsets); err = DB_SUCCESS; break; } heap2 = heap; heap = mem_heap_create(1024); err = trx_undo_prev_version_build(rec, mtr, version, index, *offsets, heap, &prev_version); if (heap2) { mem_heap_free(heap2); /* free version */ } if (UNIV_UNLIKELY(err != DB_SUCCESS)) { break; } if (prev_version == NULL) { /* It was a freshly inserted version */ *old_vers = NULL; err = DB_SUCCESS; break; } version = prev_version; *offsets = rec_get_offsets(version, index, *offsets, ULINT_UNDEFINED, offset_heap); #if defined UNIV_DEBUG || defined UNIV_BLOB_LIGHT_DEBUG ut_a(!rec_offs_any_null_extern(version, *offsets)); #endif /* UNIV_DEBUG || UNIV_BLOB_LIGHT_DEBUG */ }/* for (;;) */ if (heap) { mem_heap_free(heap); } rw_lock_s_unlock(&(purge_sys->latch)); return(err); }
/****************************************************************//** Creates trx objects for transactions and initializes the trx list of trx_sys at database start. Rollback segment and undo log lists must already exist when this function is called, because the lists of transactions to be rolled back or cleaned up are built based on the undo log lists. */ UNIV_INTERN void trx_lists_init_at_db_start(void) /*============================*/ { trx_rseg_t* rseg; trx_undo_t* undo; trx_t* trx; ut_ad(mutex_own(&kernel_mutex)); UT_LIST_INIT(trx_sys->trx_list); /* Look from the rollback segments if there exist undo logs for transactions */ rseg = UT_LIST_GET_FIRST(trx_sys->rseg_list); while (rseg != NULL) { undo = UT_LIST_GET_FIRST(rseg->insert_undo_list); while (undo != NULL) { trx = trx_create(trx_dummy_sess); trx->is_recovered = TRUE; trx->id = undo->trx_id; trx->xid = undo->xid; trx->insert_undo = undo; trx->rseg = rseg; if (undo->state != TRX_UNDO_ACTIVE) { /* Prepared transactions are left in the prepared state waiting for a commit or abort decision from MySQL */ if (undo->state == TRX_UNDO_PREPARED) { fprintf(stderr, "InnoDB: Transaction " TRX_ID_FMT " was in the" " XA prepared state.\n", TRX_ID_PREP_PRINTF(trx->id)); if (srv_force_recovery == 0) { trx->conc_state = TRX_PREPARED; } else { fprintf(stderr, "InnoDB: Since" " innodb_force_recovery" " > 0, we will" " rollback it" " anyway.\n"); trx->conc_state = TRX_ACTIVE; } } else { trx->conc_state = TRX_COMMITTED_IN_MEMORY; } /* We give a dummy value for the trx no; this should have no relevance since purge is not interested in committed transaction numbers, unless they are in the history list, in which case it looks the number from the disk based undo log structure */ trx->no = trx->id; } else { trx->conc_state = TRX_ACTIVE; /* A running transaction always has the number field inited to ut_dulint_max */ trx->no = ut_dulint_max; } if (undo->dict_operation) { trx_set_dict_operation( trx, TRX_DICT_OP_TABLE); trx->table_id = undo->table_id; } if (!undo->empty) { trx->undo_no = ut_dulint_add(undo->top_undo_no, 1); } trx_list_insert_ordered(trx); undo = UT_LIST_GET_NEXT(undo_list, undo); } undo = UT_LIST_GET_FIRST(rseg->update_undo_list); while (undo != NULL) { trx = trx_get_on_id(undo->trx_id); if (NULL == trx) { trx = trx_create(trx_dummy_sess); trx->is_recovered = TRUE; trx->id = undo->trx_id; trx->xid = undo->xid; if (undo->state != TRX_UNDO_ACTIVE) { /* Prepared transactions are left in the prepared state waiting for a commit or abort decision from MySQL */ if (undo->state == TRX_UNDO_PREPARED) { fprintf(stderr, "InnoDB: Transaction " TRX_ID_FMT " was in the" " XA prepared state.\n", TRX_ID_PREP_PRINTF( trx->id)); if (srv_force_recovery == 0) { trx->conc_state = TRX_PREPARED; } else { fprintf(stderr, "InnoDB: Since" " innodb_force_recovery" " > 0, we will" " rollback it" " anyway.\n"); trx->conc_state = TRX_ACTIVE; } } else { trx->conc_state = TRX_COMMITTED_IN_MEMORY; } /* We give a dummy value for the trx number */ trx->no = trx->id; } else { trx->conc_state = TRX_ACTIVE; /* A running transaction always has the number field inited to ut_dulint_max */ trx->no = ut_dulint_max; } trx->rseg = rseg; trx_list_insert_ordered(trx); if (undo->dict_operation) { trx_set_dict_operation( trx, TRX_DICT_OP_TABLE); trx->table_id = undo->table_id; } } trx->update_undo = undo; if ((!undo->empty) && (ut_dulint_cmp(undo->top_undo_no, trx->undo_no) >= 0)) { trx->undo_no = ut_dulint_add(undo->top_undo_no, 1); } undo = UT_LIST_GET_NEXT(undo_list, undo); } rseg = UT_LIST_GET_NEXT(rseg_list, rseg); } }
/*****************************************************************//** Finds out if an active transaction has inserted or modified a secondary index record. NOTE: the kernel mutex is temporarily released in this function! @return NULL if committed, else the active transaction */ UNIV_INTERN trx_t* row_vers_impl_x_locked_off_kernel( /*==============================*/ const rec_t* rec, /*!< in: record in a secondary index */ dict_index_t* index, /*!< in: the secondary index */ const ulint* offsets)/*!< in: rec_get_offsets(rec, index) */ { dict_index_t* clust_index; rec_t* clust_rec; ulint* clust_offsets; rec_t* version; trx_id_t trx_id; mem_heap_t* heap; mem_heap_t* heap2; dtuple_t* row; dtuple_t* entry = NULL; /* assignment to eliminate compiler warning */ trx_t* trx; ulint rec_del; #ifdef UNIV_DEBUG ulint err; #endif /* UNIV_DEBUG */ mtr_t mtr; ulint comp; ut_ad(mutex_own(&kernel_mutex)); #ifdef UNIV_SYNC_DEBUG ut_ad(!rw_lock_own(&(purge_sys->latch), RW_LOCK_SHARED)); #endif /* UNIV_SYNC_DEBUG */ mutex_exit(&kernel_mutex); mtr_start(&mtr); /* Search for the clustered index record: this is a time-consuming operation: therefore we release the kernel mutex; also, the release is required by the latching order convention. The latch on the clustered index locks the top of the stack of versions. We also reserve purge_latch to lock the bottom of the version stack. */ clust_rec = row_get_clust_rec(BTR_SEARCH_LEAF, rec, index, &clust_index, &mtr); if (!clust_rec) { /* In a rare case it is possible that no clust rec is found for a secondary index record: if in row0umod.c row_undo_mod_remove_clust_low() we have already removed the clust rec, while purge is still cleaning and removing secondary index records associated with earlier versions of the clustered index record. In that case there cannot be any implicit lock on the secondary index record, because an active transaction which has modified the secondary index record has also modified the clustered index record. And in a rollback we always undo the modifications to secondary index records before the clustered index record. */ mutex_enter(&kernel_mutex); mtr_commit(&mtr); return(NULL); } heap = mem_heap_create(1024); clust_offsets = rec_get_offsets(clust_rec, clust_index, NULL, ULINT_UNDEFINED, &heap); trx_id = row_get_rec_trx_id(clust_rec, clust_index, clust_offsets); mtr_s_lock(&(purge_sys->latch), &mtr); mutex_enter(&kernel_mutex); trx = NULL; if (!trx_is_active(trx_id)) { /* The transaction that modified or inserted clust_rec is no longer active: no implicit lock on rec */ goto exit_func; } if (!lock_check_trx_id_sanity(trx_id, clust_rec, clust_index, clust_offsets, TRUE)) { /* Corruption noticed: try to avoid a crash by returning */ goto exit_func; } comp = page_rec_is_comp(rec); ut_ad(index->table == clust_index->table); ut_ad(!!comp == dict_table_is_comp(index->table)); ut_ad(!comp == !page_rec_is_comp(clust_rec)); /* We look up if some earlier version, which was modified by the trx_id transaction, of the clustered index record would require rec to be in a different state (delete marked or unmarked, or have different field values, or not existing). If there is such a version, then rec was modified by the trx_id transaction, and it has an implicit x-lock on rec. Note that if clust_rec itself would require rec to be in a different state, then the trx_id transaction has not yet had time to modify rec, and does not necessarily have an implicit x-lock on rec. */ rec_del = rec_get_deleted_flag(rec, comp); trx = NULL; version = clust_rec; for (;;) { rec_t* prev_version; ulint vers_del; row_ext_t* ext; trx_id_t prev_trx_id; mutex_exit(&kernel_mutex); /* While we retrieve an earlier version of clust_rec, we release the kernel mutex, because it may take time to access the disk. After the release, we have to check if the trx_id transaction is still active. We keep the semaphore in mtr on the clust_rec page, so that no other transaction can update it and get an implicit x-lock on rec. */ heap2 = heap; heap = mem_heap_create(1024); #ifdef UNIV_DEBUG err = #endif /* UNIV_DEBUG */ trx_undo_prev_version_build(clust_rec, &mtr, version, clust_index, clust_offsets, heap, &prev_version); mem_heap_free(heap2); /* free version and clust_offsets */ if (prev_version == NULL) { mutex_enter(&kernel_mutex); if (!trx_is_active(trx_id)) { /* Transaction no longer active: no implicit x-lock */ break; } /* If the transaction is still active, clust_rec must be a fresh insert, because no previous version was found. */ ut_ad(err == DB_SUCCESS); /* It was a freshly inserted version: there is an implicit x-lock on rec */ trx = trx_get_on_id(trx_id); break; } clust_offsets = rec_get_offsets(prev_version, clust_index, NULL, ULINT_UNDEFINED, &heap); vers_del = rec_get_deleted_flag(prev_version, comp); prev_trx_id = row_get_rec_trx_id(prev_version, clust_index, clust_offsets); /* The stack of versions is locked by mtr. Thus, it is safe to fetch the prefixes for externally stored columns. */ row = row_build(ROW_COPY_POINTERS, clust_index, prev_version, clust_offsets, NULL, &ext, heap); entry = row_build_index_entry(row, ext, index, heap); /* entry may be NULL if a record was inserted in place of a deleted record, and the BLOB pointers of the new record were not initialized yet. But in that case, prev_version should be NULL. */ ut_a(entry); mutex_enter(&kernel_mutex); if (!trx_is_active(trx_id)) { /* Transaction no longer active: no implicit x-lock */ break; } /* If we get here, we know that the trx_id transaction is still active and it has modified prev_version. Let us check if prev_version would require rec to be in a different state. */ /* The previous version of clust_rec must be accessible, because the transaction is still active and clust_rec was not a fresh insert. */ ut_ad(err == DB_SUCCESS); /* We check if entry and rec are identified in the alphabetical ordering */ if (0 == cmp_dtuple_rec(entry, rec, offsets)) { /* The delete marks of rec and prev_version should be equal for rec to be in the state required by prev_version */ if (rec_del != vers_del) { trx = trx_get_on_id(trx_id); break; } /* It is possible that the row was updated so that the secondary index record remained the same in alphabetical ordering, but the field values changed still. For example, 'abc' -> 'ABC'. Check also that. */ dtuple_set_types_binary(entry, dtuple_get_n_fields(entry)); if (0 != cmp_dtuple_rec(entry, rec, offsets)) { trx = trx_get_on_id(trx_id); break; } } else if (!rec_del) { /* The delete mark should be set in rec for it to be in the state required by prev_version */ trx = trx_get_on_id(trx_id); break; } if (0 != ut_dulint_cmp(trx_id, prev_trx_id)) { /* The versions modified by the trx_id transaction end to prev_version: no implicit x-lock */ break; } version = prev_version; }/* for (;;) */ exit_func: mtr_commit(&mtr); mem_heap_free(heap); return(trx); }