// getTableID retrieves the table ID for the specified table. It uses the // descriptor cache to perform lookups, falling back to the KV store when // necessary. func (p *planner) getTableID(qname *parser.QualifiedName) (ID, error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return 0, err } // Lookup the database in the cache first, falling back to the KV store if it // isn't present. The cache might cause the usage of a recently renamed // database, but that's a race that could occur anyways. dbDesc, err := p.getCachedDatabaseDesc(qname.Database()) if err != nil { dbDesc, err = p.getDatabaseDesc(qname.Database()) if err != nil { return 0, err } } // Lookup the ID of the table in the cache. The use of the cache might cause // the usage of a recently renamed table, but that's a race that could occur // anyways. nameKey := tableKey{dbDesc.ID, qname.Table()} key := nameKey.Key() if nameVal := p.systemConfig.GetValue(key); nameVal != nil { id, err := nameVal.GetInt() return ID(id), err } gr, err := p.txn.Get(key) if err != nil { return 0, err } if !gr.Exists() { return 0, fmt.Errorf("table %q does not exist", nameKey.Name()) } return ID(gr.ValueInt()), nil }
// getTableID retrieves the table ID for the specified table. It uses the // descriptor cache to perform lookups, falling back to the KV store when // necessary. func (p *planner) getTableID(qname *parser.QualifiedName) (ID, *roachpb.Error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return 0, roachpb.NewError(err) } dbID, pErr := p.getDatabaseID(qname.Database()) if pErr != nil { return 0, pErr } // Lookup the ID of the table in the cache. The use of the cache might cause // the usage of a recently renamed table, but that's a race that could occur // anyways. nameKey := tableKey{dbID, qname.Table()} key := nameKey.Key() if nameVal := p.systemConfig.GetValue(key); nameVal != nil { id, err := nameVal.GetInt() return ID(id), roachpb.NewError(err) } gr, pErr := p.txn.Get(key) if pErr != nil { return 0, pErr } if !gr.Exists() { return 0, roachpb.NewErrorf("table %q does not exist", nameKey.Name()) } return ID(gr.ValueInt()), nil }
func (s *Server) getTableDesc(database string, qname parser.QualifiedName) ( *structured.TableDescriptor, error) { var err error qname, err = s.normalizeTableName(database, qname) if err != nil { return nil, err } dbID, err := s.lookupDatabase(qname.Database()) if err != nil { return nil, err } gr, err := s.db.Get(keys.MakeNameMetadataKey(dbID, qname.Table())) if err != nil { return nil, err } if !gr.Exists() { return nil, fmt.Errorf("table \"%s\" does not exist", qname) } descKey := gr.ValueBytes() desc := structured.TableDescriptor{} if err := s.db.GetProto(descKey, &desc); err != nil { return nil, err } if err := desc.Validate(); err != nil { return nil, err } return &desc, nil }
// getTableID retrieves the table ID for the specified table. It uses the // descriptor cache to perform lookups, falling back to the KV store when // necessary. func (p *planner) getTableID(qname *parser.QualifiedName) (sqlbase.ID, error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return 0, err } dbID, err := p.getDatabaseID(qname.Database()) if err != nil { return 0, err } // Lookup the ID of the table in the cache. The use of the cache might cause // the usage of a recently renamed table, but that's a race that could occur // anyways. // TODO(andrei): remove the used of p.systemConfig as a cache for table names, // replace it with using the leases for resolving names, and do away with any // races due to renames. We'll probably have to rewrite renames to perform // an async schema change. nameKey := tableKey{dbID, qname.Table()} key := nameKey.Key() if nameVal := p.systemConfig.GetValue(key); nameVal != nil { id, err := nameVal.GetInt() return sqlbase.ID(id), err } gr, err := p.txn.Get(key) if err != nil { return 0, err } if !gr.Exists() { return 0, tableDoesNotExistError(qname.String()) } return sqlbase.ID(gr.ValueInt()), nil }
// getTableLease implements the SchemaAccessor interface. func (p *planner) getTableLease(qname *parser.QualifiedName) (*sqlbase.TableDescriptor, error) { if log.V(2) { log.Infof("planner acquiring lease on table %q", qname) } if err := qname.NormalizeTableName(p.session.Database); err != nil { return nil, err } if qname.Database() == sqlbase.SystemDB.Name || testDisableTableLeases { // We don't go through the normal lease mechanism for system tables. The // system.lease and system.descriptor table, in particular, are problematic // because they are used for acquiring leases itself, creating a // chicken&egg problem. return p.mustGetTableDesc(qname) } dbID, err := p.getDatabaseID(qname.Database()) if err != nil { return nil, err } // First, look to see if we already have a lease for this table. // This ensures that, once a SQL transaction resolved name N to id X, it will // continue to use N to refer to X even if N is renamed during the // transaction. var lease *LeaseState for _, l := range p.leases { if sqlbase.NormalizeName(l.Name) == sqlbase.NormalizeName(qname.Table()) && l.ParentID == dbID { lease = l if log.V(2) { log.Infof("found lease in planner cache for table %q", qname) } break } } // If we didn't find a lease or the lease is about to expire, acquire one. if lease == nil || p.removeLeaseIfExpiring(lease) { var err error lease, err = p.leaseMgr.AcquireByName(p.txn, dbID, qname.Table()) if err != nil { if err == errDescriptorNotFound { // Transform the descriptor error into an error that references the // table's name. return nil, sqlbase.NewUndefinedTableError(qname.String()) } return nil, err } p.leases = append(p.leases, lease) // If the lease we just acquired expires before the txn's deadline, reduce // the deadline. p.txn.UpdateDeadlineMaybe(hlc.Timestamp{WallTime: lease.Expiration().UnixNano()}) } return &lease.TableDescriptor, nil }
func (p *planner) getTableDesc(qname *parser.QualifiedName) (*TableDescriptor, error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return nil, err } dbDesc, err := p.getDatabaseDesc(qname.Database()) if err != nil { return nil, err } desc := TableDescriptor{} if err := p.getDescriptor(tableKey{dbDesc.ID, qname.Table()}, &desc); err != nil { return nil, err } return &desc, nil }
func (p *planner) getTableDesc(qname *parser.QualifiedName) (TableDescriptor, *roachpb.Error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return TableDescriptor{}, roachpb.NewError(err) } dbDesc, pErr := p.getDatabaseDesc(qname.Database()) if pErr != nil { return TableDescriptor{}, pErr } desc := TableDescriptor{} if pErr := p.getDescriptor(tableKey{dbDesc.ID, qname.Table()}, &desc); pErr != nil { return TableDescriptor{}, pErr } return desc, nil }
func (p *planner) getTableDesc(qname *parser.QualifiedName) ( *structured.TableDescriptor, error) { if err := p.normalizeTableName(qname); err != nil { return nil, err } dbDesc, err := p.getDatabaseDesc(qname.Database()) if err != nil { return nil, err } nameKey := keys.MakeNameMetadataKey(dbDesc.ID, qname.Table()) desc := structured.TableDescriptor{} if err := p.getDescriptor(nameKey, &desc); err != nil { return nil, err } return &desc, nil }
// getTableID retrieves the table ID for the specified table. func getTableID(p *planner, qname *parser.QualifiedName) (sqlbase.ID, error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return 0, err } dbID, err := p.getDatabaseID(qname.Database()) if err != nil { return 0, err } nameKey := tableKey{dbID, qname.Table()} key := nameKey.Key() gr, err := p.txn.Get(key) if err != nil { return 0, err } if !gr.Exists() { return 0, sqlbase.NewUndefinedTableError(qname.String()) } return sqlbase.ID(gr.ValueInt()), nil }
// getTableDesc implements the SchemaAccessor interface. func (p *planner) getTableDesc(qname *parser.QualifiedName) (*sqlbase.TableDescriptor, error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return nil, err } dbDesc, err := p.getDatabaseDesc(qname.Database()) if err != nil { return nil, err } if dbDesc == nil { return nil, sqlbase.NewUndefinedDatabaseError(qname.Database()) } desc := sqlbase.TableDescriptor{} found, err := p.getDescriptor(tableKey{parentID: dbDesc.ID, name: qname.Table()}, &desc) if err != nil { return nil, err } if !found { return nil, nil } return &desc, nil }
// getCachedTableDesc looks for a table descriptor in the descriptor cache. // Looks up the database descriptor, followed by the table descriptor. // // Returns: the table descriptor, whether it comes from the cache, and an error. func (p *planner) getCachedTableDesc(qname *parser.QualifiedName) (*TableDescriptor, bool, error) { if err := qname.NormalizeTableName(p.session.Database); err != nil { return nil, false, err } dbDesc, cached, err := p.getCachedDatabaseDesc(qname.Database()) if err != nil { return nil, false, err } desc := &TableDescriptor{} // Only attempt cached lookup if the database descriptor was found in the cache. if cached { if err := p.getCachedDescriptor(tableKey{dbDesc.ID, qname.Table()}, desc); err == nil { return desc, true, nil } // Problem, or not found in the cache: fall back on KV lookup. } if err := p.getDescriptor(tableKey{dbDesc.ID, qname.Table()}, desc); err != nil { return nil, false, err } return desc, false, nil }