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session.go
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session.go
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// Copyright 2015 The Cockroach Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
// implied. See the License for the specific language governing
// permissions and limitations under the License.
package sql
import (
"fmt"
"net"
"strings"
"sync/atomic"
"time"
"unicode/utf8"
opentracing "github.com/opentracing/opentracing-go"
"github.com/pkg/errors"
"golang.org/x/net/context"
"golang.org/x/net/trace"
"github.com/cockroachdb/cockroach/pkg/base"
"github.com/cockroachdb/cockroach/pkg/config"
"github.com/cockroachdb/cockroach/pkg/internal/client"
"github.com/cockroachdb/cockroach/pkg/roachpb"
"github.com/cockroachdb/cockroach/pkg/security"
"github.com/cockroachdb/cockroach/pkg/server/serverpb"
"github.com/cockroachdb/cockroach/pkg/settings"
"github.com/cockroachdb/cockroach/pkg/sql/mon"
"github.com/cockroachdb/cockroach/pkg/sql/parser"
"github.com/cockroachdb/cockroach/pkg/sql/sqlbase"
"github.com/cockroachdb/cockroach/pkg/storage/engine/enginepb"
"github.com/cockroachdb/cockroach/pkg/util"
"github.com/cockroachdb/cockroach/pkg/util/duration"
"github.com/cockroachdb/cockroach/pkg/util/envutil"
"github.com/cockroachdb/cockroach/pkg/util/log"
"github.com/cockroachdb/cockroach/pkg/util/retry"
"github.com/cockroachdb/cockroach/pkg/util/syncutil"
"github.com/cockroachdb/cockroach/pkg/util/timeutil"
"github.com/cockroachdb/cockroach/pkg/util/tracing"
"github.com/cockroachdb/cockroach/pkg/util/uint128"
"github.com/cockroachdb/cockroach/pkg/util/uuid"
)
// debugTrace7881Enabled causes all SQL transactions to be traced, in the hope
// that we'll catch #7881 and dump the current trace for debugging.
var debugTrace7881Enabled = envutil.EnvOrDefaultBool("COCKROACH_TRACE_7881", false)
// span baggage key used for marking a span
const keyFor7881Sample = "found#7881"
// traceTxnThreshold can be used to log SQL transactions that take
// longer than duration to complete. For example, traceTxnThreshold=1s
// will log the trace for any transaction that takes 1s or longer. To
// log traces for all transactions use traceTxnThreshold=1ns. Note
// that any positive duration will enable tracing and will slow down
// all execution because traces are gathered for all transactions even
// if they are not output.
var traceTxnThreshold = settings.RegisterDurationSetting(
"sql.trace.txn.enable_threshold",
"duration beyond which all transactions are traced (set to 0 to disable)", 0,
)
// traceSessionEventLogEnabled can be used to enable the event log
// that is normally kept for every SQL connection. The event log has a
// non-trivial performance impact and also reveals SQL statements
// which may be a privacy concern.
var traceSessionEventLogEnabled = settings.RegisterBoolSetting(
"sql.trace.session_eventlog.enabled",
"set to true to enable session tracing", false,
)
// DistSQLClusterExecMode controls the cluster default for when DistSQL is used.
var DistSQLClusterExecMode = settings.RegisterEnumSetting(
"sql.defaults.distsql",
"Default distributed SQL execution mode",
"Auto",
map[int64]string{
int64(DistSQLOff): "Off",
int64(DistSQLAuto): "Auto",
int64(DistSQLOn): "On",
},
)
// DistSQLExecMode controls if and when the Executor uses DistSQL.
type DistSQLExecMode int64
const (
// DistSQLOff means that we never use distSQL.
DistSQLOff DistSQLExecMode = iota
// DistSQLAuto means that we automatically decide on a case-by-case basis if
// we use distSQL.
DistSQLAuto
// DistSQLOn means that we use distSQL for queries that are supported.
DistSQLOn
// DistSQLAlways means that we only use distSQL; unsupported queries fail.
DistSQLAlways
)
func (m DistSQLExecMode) String() string {
switch m {
case DistSQLOff:
return "off"
case DistSQLAuto:
return "auto"
case DistSQLOn:
return "on"
case DistSQLAlways:
return "always"
default:
return fmt.Sprintf("invalid (%d)", m)
}
}
// DistSQLExecModeFromString converts a string into a DistSQLExecMode
func DistSQLExecModeFromString(val string) DistSQLExecMode {
switch strings.ToUpper(val) {
case "OFF":
return DistSQLOff
case "AUTO":
return DistSQLAuto
case "ON":
return DistSQLOn
case "ALWAYS":
return DistSQLAlways
default:
panic(fmt.Sprintf("unknown DistSQL mode %s", val))
}
}
// queryPhase represents a phase during a query's execution.
type queryPhase int
const (
// The phase before start of execution (includes parsing, building a plan).
preparing queryPhase = 0
// Execution phase.
executing = 1
)
// queryMeta stores metadata about a query. Stored as reference in
// session.mu.ActiveQueries.
type queryMeta struct {
// The timestamp when this query began execution.
start time.Time
// AST of the SQL statement - converted to query string only when necessary.
stmt parser.Statement
// States whether this query is distributed. Note that all queries,
// including those that are distributed, have this field set to false until
// start of execution; only at that point can we can actually determine whether
// this query will be distributed. Use the phase variable below
// to determine whether this query has entered execution yet.
isDistributed bool
// Current phase of execution of query.
phase queryPhase
// Context associated with this query's transaction.
ctx context.Context
// Cancellation function for the context associated with this query's transaction.
// Set to session.txnState.cancel in executor.
ctxCancel context.CancelFunc
// Reference to the Session that contains this query.
session *Session
}
// cancel cancels the query associated with this queryMeta, by closing the associated
// txn context.
func (q *queryMeta) cancel() {
q.ctxCancel()
}
// Session contains the state of a SQL client connection.
// Create instances using NewSession().
type Session struct {
//
// Session parameters, user-configurable.
//
// Database indicates the "current" database for the purpose of
// resolving names. See searchAndQualifyDatabase() for details.
Database string
// DefaultIsolationLevel indicates the default isolation level of
// newly created transactions.
DefaultIsolationLevel enginepb.IsolationType
// DistSQLMode indicates whether to run queries using the distributed
// execution engine.
DistSQLMode DistSQLExecMode
// Location indicates the current time zone.
Location *time.Location
// SearchPath is a list of databases that will be searched for a table name
// before the database. Currently, this is used only for SELECTs.
// Names in the search path must have been normalized already.
SearchPath parser.SearchPath
// User is the name of the user logged into the session.
User string
// SafeUpdates causes errors when the client
// sends syntax that may have unwanted side effects.
SafeUpdates bool
//
// Session parameters, non-user-configurable.
//
// defaults is used to restore default configuration values into
// SET ... TO DEFAULT statements.
defaults sessionDefaults
// ClientAddr is the client's IP address and port.
ClientAddr string
//
// State structures for the logical SQL session.
//
// TxnState carries information about the open transaction (if any),
// including the retry status and the KV client Txn object.
TxnState txnState
// PreparedStatements and PreparedPortals store the statements/portals
// that have been prepared via pgwire.
PreparedStatements PreparedStatements
PreparedPortals PreparedPortals
// virtualSchemas aliases Executor.virtualSchemas.
// It is duplicated in Session to provide easier access to
// the various methods that need this reference.
// TODO(knz): place this in an executionContext parameter-passing
// structure.
virtualSchemas virtualSchemaHolder
// planner is the "default planner" on a session, to save planner allocations
// during serial execution. Since planners are not threadsafe, this is only
// safe to use when a statement is not being parallelized. It must be reset
// before using.
planner planner
//
// Run-time state.
//
// execCfg is the configuration of the Executor that is executing this
// session.
execCfg *ExecutorConfig
// distSQLPlanner is in charge of distSQL physical planning and running
// logic.
distSQLPlanner *distSQLPlanner
// context is the Session's base context, to be used for all
// SQL-related logging. See Ctx().
context context.Context
// eventLog for SQL statements and results.
eventLog trace.EventLog
// cancel is a method to call when the session terminates, to
// release resources associated with the context above.
// TODO(andrei): We need to either get rid of this cancel field, or
// it needs to move to the TxnState and become a per-txn
// cancel. Right now, we're cancelling all the txns that have ever
// run on this session when the session is closed, as opposed to
// cancelling the individual transactions as soon as they
// COMMIT/ROLLBACK.
cancel context.CancelFunc
// parallelizeQueue is a queue managing all parallelized SQL statements
// running in this session.
parallelizeQueue ParallelizeQueue
// mon tracks memory usage for SQL activity within this session. It
// is not directly used, but rather indirectly used via sessionMon
// and TxnState.mon. sessionMon tracks session-bound objects like prepared
// statements and result sets.
//
// The reason why TxnState.mon and mon are split is to enable
// separate reporting of statistics per transaction and per
// session. This is because the "interesting" behavior w.r.t memory
// is typically caused by transactions, not sessions. The reason why
// sessionMon and mon are split is to enable separate reporting of
// statistics for result sets (which escape transactions).
mon mon.BytesMonitor
sessionMon mon.BytesMonitor
// emergencyShutdown is set to true by EmergencyClose() to
// indicate to Finish() that the session is already closed.
emergencyShutdown bool
// ResultsWriter is where query results are written to. It's set to a
// pgwire.v3conn for sessions opened for SQL client connections and a
// bufferedResultWriter for internal uses.
ResultsWriter ResultsWriter
Tracing SessionTracing
tables TableCollection
// If set, contains the in progress COPY FROM columns.
copyFrom *copyNode
// ActiveSyncQueries contains query IDs of all synchronous (i.e. non-parallel)
// queries in flight. All ActiveSyncQueries must also be in mu.ActiveQueries.
ActiveSyncQueries []uint128.Uint128
// mu contains of all elements of the struct that can be changed
// after initialization, and may be accessed from another thread.
mu struct {
syncutil.RWMutex
//
// Session parameters, user-configurable.
//
// ApplicationName is the name of the application running the
// current session. This can be used for logging and per-application
// statistics. Change via resetApplicationName().
ApplicationName string
//
// State structures for the logical SQL session.
//
// ActiveQueries contains all queries in flight.
ActiveQueries map[uint128.Uint128]*queryMeta
// LastActiveQuery contains a reference to the AST of the last
// query that ran on this session.
LastActiveQuery parser.Statement
}
//
// Testing state.
//
// If set, called after the Session is done executing the current SQL statement.
// It can be used to verify assumptions about how metadata will be asynchronously
// updated. Note that this can overwrite a previous callback that was waiting to be
// verified, which is not ideal.
testingVerifyMetadataFn func(config.SystemConfig) error
verifyFnCheckedOnce bool
//
// Per-session statistics.
//
// memMetrics track memory usage by SQL execution.
memMetrics *MemoryMetrics
// sqlStats tracks per-application statistics for all
// applications on each node.
sqlStats *sqlStats
// appStats track per-application SQL usage statistics.
appStats *appStats
// phaseTimes tracks session-level phase times. It is copied-by-value
// to each planner in session.newPlanner.
phaseTimes phaseTimes
// noCopy is placed here to guarantee that Session objects are not
// copied.
noCopy util.NoCopy
}
// sessionDefaults mirrors fields in Session, for restoring default
// configuration values in SET ... TO DEFAULT statements.
type sessionDefaults struct {
applicationName string
database string
}
// SessionArgs contains arguments for creating a new Session with NewSession().
type SessionArgs struct {
Database string
User string
ApplicationName string
}
// SessionRegistry stores a set of all sessions on this node.
// Use register() and deregister() to modify this registry.
type SessionRegistry struct {
syncutil.Mutex
store map[*Session]struct{}
}
// MakeSessionRegistry creates a new SessionRegistry with an empty set
// of sessions.
func MakeSessionRegistry() *SessionRegistry {
return &SessionRegistry{store: make(map[*Session]struct{})}
}
func (r *SessionRegistry) register(s *Session) {
r.Lock()
r.store[s] = struct{}{}
r.Unlock()
}
func (r *SessionRegistry) deregister(s *Session) {
r.Lock()
delete(r.store, s)
r.Unlock()
}
// CancelQuery looks up the associated query in the session registry and cancels it.
func (r *SessionRegistry) CancelQuery(queryIDStr string, username string) (bool, error) {
queryID, err := uint128.FromString(queryIDStr)
if err != nil {
return false, fmt.Errorf("query ID %s malformed: %s", queryID, err)
}
r.Lock()
defer r.Unlock()
for session := range r.store {
if !(username == security.RootUser || username == session.User) {
// Skip this session.
continue
}
session.mu.Lock()
if queryMeta, exists := session.mu.ActiveQueries[queryID]; exists {
queryMeta.cancel()
session.mu.Unlock()
return true, nil
}
session.mu.Unlock()
}
return false, fmt.Errorf("query ID %s not found", queryID)
}
// SerializeAll returns a slice of all sessions in the registry, converted to serverpb.Sessions.
func (r *SessionRegistry) SerializeAll() []serverpb.Session {
r.Lock()
defer r.Unlock()
response := make([]serverpb.Session, 0, len(r.store))
for s := range r.store {
response = append(response, s.serialize())
}
return response
}
// NewSession creates and initializes a new Session object.
// remote can be nil.
func NewSession(
ctx context.Context, args SessionArgs, e *Executor, remote net.Addr, memMetrics *MemoryMetrics,
) *Session {
ctx = e.AnnotateCtx(ctx)
distSQLMode := DistSQLExecMode(DistSQLClusterExecMode.Get(&e.cfg.Settings.SV))
s := &Session{
Database: args.Database,
DistSQLMode: distSQLMode,
SearchPath: sqlbase.DefaultSearchPath,
Location: time.UTC,
User: args.User,
virtualSchemas: e.virtualSchemas,
execCfg: &e.cfg,
distSQLPlanner: e.distSQLPlanner,
parallelizeQueue: MakeParallelizeQueue(NewSpanBasedDependencyAnalyzer()),
memMetrics: memMetrics,
sqlStats: &e.sqlStats,
defaults: sessionDefaults{
applicationName: args.ApplicationName,
database: args.Database,
},
tables: TableCollection{
leaseMgr: e.cfg.LeaseManager,
databaseCache: e.getDatabaseCache(),
},
}
s.phaseTimes[sessionInit] = timeutil.Now()
s.resetApplicationName(args.ApplicationName)
s.PreparedStatements = makePreparedStatements(s)
s.PreparedPortals = makePreparedPortals(s)
s.Tracing.session = s
s.mu.ActiveQueries = make(map[uint128.Uint128]*queryMeta)
s.ActiveSyncQueries = make([]uint128.Uint128, 0)
remoteStr := "<admin>"
if remote != nil {
remoteStr = remote.String()
}
s.ClientAddr = remoteStr
if traceSessionEventLogEnabled.Get(&e.cfg.Settings.SV) {
s.eventLog = trace.NewEventLog(fmt.Sprintf("sql [%s]", args.User), remoteStr)
}
s.context, s.cancel = context.WithCancel(ctx)
e.cfg.SessionRegistry.register(s)
return s
}
// Finish releases resources held by the Session. It is called by the Session's
// main goroutine, so no synchronous queries will be in-flight during the
// method's execution. However, it could be called when asynchronous queries are
// operating in the background in the case of parallelized statements, which
// is why we make sure to drain background statements.
func (s *Session) Finish(e *Executor) {
log.VEvent(s.context, 2, "finishing session")
if s.emergencyShutdown {
// closed by EmergencyClose() already.
return
}
if s.mon == (mon.BytesMonitor{}) {
// This check won't catch the cases where Finish is never called, but it's
// proven to be easier to remember to call Finish than it is to call
// StartMonitor.
panic("session.Finish: session monitors were never initialized. Missing call " +
"to session.StartMonitor?")
}
// Make sure that no statements remain in the ParallelizeQueue. If no statements
// are in the queue, this will be a no-op. If there are statements in the
// queue, they would have eventually drained on their own, but if we don't
// wait here, we risk alarming the MemoryMonitor. We ignore the error because
// it will only ever be non-nil if there are statements in the queue, meaning
// that the Session was abandoned in the middle of a transaction, in which
// case the error doesn't matter.
//
// TODO(nvanbenschoten): Once we have better support for cancelling ongoing
// statement execution by the infrastructure added to support CancelRequest,
// we should try to actively drain this queue instead of passively waiting
// for it to drain. (andrei, 2017/09) - We now have support for statement
// cancellation. Now what?
_ = s.synchronizeParallelStmts(s.context)
// If we're inside a txn, roll it back.
if s.TxnState.State().kvTxnIsOpen() {
_ = s.TxnState.updateStateAndCleanupOnErr(fmt.Errorf("session closing"), e)
}
if s.TxnState.State() != NoTxn {
s.TxnState.finishSQLTxn(s)
}
// We might have unreleased tables if we're finishing the
// session abruptly in the middle of a transaction, or, until #7648 is
// addressed, there might be leases accumulated by preparing statements.
s.tables.releaseTables(s.context)
s.ClearStatementsAndPortals(s.context)
s.sessionMon.Stop(s.context)
s.mon.Stop(s.context)
if s.eventLog != nil {
s.eventLog.Finish()
s.eventLog = nil
}
if s.Tracing.Enabled() {
if err := s.Tracing.StopTracing(); err != nil {
log.Infof(s.context, "error stopping tracing: %s", err)
}
}
// Clear this session from the sessions registry.
e.cfg.SessionRegistry.deregister(s)
// This will stop the heartbeating of the of the txn record.
// TODO(andrei): This shouldn't have any effect, since, if there was a
// transaction, we just explicitly rolled it back above, so the heartbeat loop
// in the TxnCoordSender should not be waiting on this channel any more.
// Consider getting rid of this cancel field all-together.
s.cancel()
}
// EmergencyClose is a simplified replacement for Finish() which is
// less picky about the current state of the Session. In particular
// this can be used to tidy up after a session even in the middle of a
// transaction, where there may still be memory activity registered to
// a monitor and not cleanly released.
func (s *Session) EmergencyClose() {
// Ensure that all in-flight statements are done, so that monitor
// traffic is stopped.
_ = s.synchronizeParallelStmts(s.context)
// Release the leases - to ensure other sessions don't get stuck.
s.tables.releaseTables(s.context)
// The KV txn may be unusable - just leave it dead. Simply
// shut down its memory monitor.
s.TxnState.mon.EmergencyStop(s.context)
// Shut the remaining monitors down.
s.sessionMon.EmergencyStop(s.context)
s.mon.EmergencyStop(s.context)
// Finalize the event log.
if s.eventLog != nil {
s.eventLog.Finish()
s.eventLog = nil
}
// Stop the heartbeating.
s.cancel()
// Mark the session as already closed, so that Finish() doesn't get confused.
s.emergencyShutdown = true
}
// Ctx returns the current context for the session: if there is an active SQL
// transaction it returns the transaction context, otherwise it returns the
// session context.
// Note that in some cases we may want the session context even if there is an
// active transaction (an example is when we want to log an event to the session
// event log); in that case s.context should be used directly.
func (s *Session) Ctx() context.Context {
if s.TxnState.State() != NoTxn {
return s.TxnState.Ctx
}
return s.context
}
func (s *Session) resetPlanner(p *planner, e *Executor, txn *client.Txn) {
p.session = s
// phaseTimes is an array, not a slice, so this performs a copy-by-value.
p.phaseTimes = s.phaseTimes
p.stmt = nil
p.cancelChecker = sqlbase.NewCancelChecker(s.Ctx())
p.semaCtx = parser.MakeSemaContext(s.User == security.RootUser)
p.semaCtx.Location = &s.Location
p.semaCtx.SearchPath = s.SearchPath
p.evalCtx = s.evalCtx()
p.evalCtx.Planner = p
if e != nil {
p.evalCtx.ClusterID = e.cfg.ClusterID()
p.evalCtx.NodeID = e.cfg.NodeID.Get()
p.evalCtx.ReCache = e.reCache
}
p.setTxn(txn)
}
// FinishPlan releases the resources that were consumed by the currently active
// default planner. It does not check to see whether any other resources are
// still pointing to the planner, so it should only be called when a connection
// is entirely finished executing a statement and all results have been sent.
func (s *Session) FinishPlan() {
if len(s.ActiveSyncQueries) > 0 {
s.mu.Lock()
// Store the last sync query as the last active query.
lastQueryID := s.ActiveSyncQueries[len(s.ActiveSyncQueries)-1]
s.mu.LastActiveQuery = s.mu.ActiveQueries[lastQueryID].stmt
// All results have been sent to the client; so deregister all synchronous
// active queries from this session. Cannot deregister asynchronous ones
// because those might still be executing in the parallelizeQueue.
for _, queryID := range s.ActiveSyncQueries {
delete(s.mu.ActiveQueries, queryID)
}
s.mu.Unlock()
s.ActiveSyncQueries = make([]uint128.Uint128, 0)
}
s.planner = emptyPlanner
}
// newPlanner creates a planner inside the scope of the given Session. The
// statement executed by the planner will be executed in txn. The planner
// should only be used to execute one statement.
func (s *Session) newPlanner(e *Executor, txn *client.Txn) *planner {
p := &planner{}
s.resetPlanner(p, e, txn)
return p
}
// evalCtx creates a parser.EvalContext from the Session's current configuration.
func (s *Session) evalCtx() parser.EvalContext {
return parser.EvalContext{
Location: &s.Location,
Database: s.Database,
User: s.User,
SearchPath: s.SearchPath,
Ctx: s.Ctx,
Mon: &s.TxnState.mon,
}
}
// resetForBatch prepares the Session for executing a new batch of statements.
func (s *Session) resetForBatch(e *Executor) {
// Update the database cache to a more recent copy, so that we can use tables
// that we created in previous batches of the same transaction.
s.tables.databaseCache = e.getDatabaseCache()
}
// setTestingVerifyMetadata sets a callback to be called after the Session
// is done executing the current SQL statement. It can be used to verify
// assumptions about how metadata will be asynchronously updated.
// Note that this can overwrite a previous callback that was waiting to be
// verified, which is not ideal.
func (s *Session) setTestingVerifyMetadata(fn func(config.SystemConfig) error) {
s.testingVerifyMetadataFn = fn
s.verifyFnCheckedOnce = false
}
// addActiveQuery adds a running query to the session's internal store of active
// queries, as well as to the executor's query registry. Called from executor
// before start of execution.
func (s *Session) addActiveQuery(queryID uint128.Uint128, queryMeta *queryMeta) {
s.mu.Lock()
s.mu.ActiveQueries[queryID] = queryMeta
queryMeta.session = s
s.mu.Unlock()
// addActiveQuery is called from the main goroutine of the session;
// and at this stage, this query is a synchronous query for our purposes.
// setQueryExecutionMode will remove this element if this query enters the
// parallelizeQueue.
s.ActiveSyncQueries = append(s.ActiveSyncQueries, queryID)
}
// removeActiveQuery removes a query from a session's internal store of active
// queries, as well as from the executor's query registry.
// Called when a query finishes execution.
func (s *Session) removeActiveQuery(queryID uint128.Uint128) {
s.mu.Lock()
queryMeta, ok := s.mu.ActiveQueries[queryID]
if ok {
delete(s.mu.ActiveQueries, queryID)
s.mu.LastActiveQuery = queryMeta.stmt
}
s.mu.Unlock()
}
// setQueryExecutionMode is called upon start of execution of a query, and sets
// the query's metadata to indicate whether it's distributed or not.
func (s *Session) setQueryExecutionMode(
queryID uint128.Uint128, isDistributed bool, isParallel bool,
) {
s.mu.Lock()
defer s.mu.Unlock()
queryMeta, ok := s.mu.ActiveQueries[queryID]
if !ok {
// Could be a statement that implements HiddenFromShowQueries.
// These statements have a query ID but do not have an entry
// in session.mu.ActiveQueries.
return
}
queryMeta.phase = executing
queryMeta.isDistributed = isDistributed
if isParallel {
// We default to putting queries in ActiveSyncQueries. Since
// this query is not synchronous anymore, remove it from
// ActiveSyncQueries. We expect the last element in
// ActiveSyncQueries to be this query; because all execution
// up to this call of setQueryExecutionMode is synchronous.
lenSyncQueries := len(s.ActiveSyncQueries)
s.ActiveSyncQueries = s.ActiveSyncQueries[:lenSyncQueries-1]
}
}
// synchronizeParallelStmts waits for all statements in the parallelizeQueue to
// finish. If errors are seen in the parallel batch, we attempt to turn these
// errors into a single error we can send to the client. We do this by prioritizing
// non-retryable errors over retryable errors.
func (s *Session) synchronizeParallelStmts(ctx context.Context) error {
if errs := s.parallelizeQueue.Wait(); len(errs) > 0 {
s.TxnState.mu.Lock()
defer s.TxnState.mu.Unlock()
// Check that all errors are retryable. If any are not, return the
// first non-retryable error.
var retryErr *roachpb.HandledRetryableTxnError
for _, err := range errs {
switch t := err.(type) {
case *roachpb.HandledRetryableTxnError:
// Ignore retryable errors to previous incarnations of this transaction.
curTxn := s.TxnState.mu.txn.Proto()
errTxn := t.Transaction
if errTxn.ID == curTxn.ID && errTxn.Epoch == curTxn.Epoch {
retryErr = t
}
case *roachpb.UntrackedTxnError:
// Symptom of concurrent retry, ignore.
case *roachpb.TxnPrevAttemptError:
// Symptom of concurrent retry, ignore.
default:
return err
}
}
if retryErr == nil {
log.Fatalf(ctx, "found symptoms of a concurrent retry, but did "+
"not find the final retry error: %v", errs)
}
// If all errors are retryable, we return the one meant for the current
// incarnation of this transaction. Before doing so though, we need to bump
// the transaction epoch to invalidate any writes performed by any workers
// after the retry updated the txn's proto but before we synchronized (some
// of these writes might have been performed at the wrong epoch). Note
// that we don't need to lock the client.Txn because we're synchronized.
// See #17197.
s.TxnState.mu.txn.Proto().BumpEpoch()
return retryErr
}
return nil
}
// MaxSQLBytes is the maximum length in bytes of SQL statements serialized
// into a serverpb.Session. Exported for testing.
const MaxSQLBytes = 1000
// serialize serializes a Session into a serverpb.Session
// that can be served over RPC.
func (s *Session) serialize() serverpb.Session {
s.mu.RLock()
defer s.mu.RUnlock()
s.TxnState.mu.RLock()
defer s.TxnState.mu.RUnlock()
var kvTxnID *uuid.UUID
txn := s.TxnState.mu.txn
if txn != nil {
id := txn.ID()
kvTxnID = &id
}
activeQueries := make([]serverpb.ActiveQuery, 0, len(s.mu.ActiveQueries))
truncateSQL := func(sql string) string {
if len(sql) > MaxSQLBytes {
sql = sql[:MaxSQLBytes-utf8.RuneLen('…')]
// Ensure the resulting string is valid utf8.
for {
if r, _ := utf8.DecodeLastRuneInString(sql); r != utf8.RuneError {
break
}
sql = sql[:len(sql)-1]
}
sql += "…"
}
return sql
}
for id, query := range s.mu.ActiveQueries {
sql := truncateSQL(query.stmt.String())
activeQueries = append(activeQueries, serverpb.ActiveQuery{
ID: id.String(),
Start: query.start.UTC(),
Sql: sql,
IsDistributed: query.isDistributed,
Phase: (serverpb.ActiveQuery_Phase)(query.phase),
})
}
lastActiveQuery := ""
if s.mu.LastActiveQuery != nil {
lastActiveQuery = truncateSQL(s.mu.LastActiveQuery.String())
}
return serverpb.Session{
Username: s.User,
ClientAddress: s.ClientAddr,
ApplicationName: s.mu.ApplicationName,
Start: s.phaseTimes[sessionInit].UTC(),
ActiveQueries: activeQueries,
KvTxnID: kvTxnID,
LastActiveQuery: lastActiveQuery,
}
}
// TxnStateEnum represents the state of a SQL txn.
type TxnStateEnum int64
//go:generate stringer -type=TxnStateEnum
const (
// No txn is in scope. Either there never was one, or it got committed/rolled
// back. Note that this state will not be experienced outside of the Session
// and Executor (i.e. it will not be observed by a running query) because the
// Executor opens implicit transactions before executing non-transactional
// queries.
NoTxn TxnStateEnum = iota
// Like Open, a txn is in scope. The difference is that, while in the
// AutoRetry state, a retriable error will be handled by an automatic
// transaction retry, whereas we can't do that in Open. There's a caveat -
// even if we're in AutoRetry, we can't do automatic retries if any
// results for statements in the current transaction have already been
// delivered to the client.
// In principle, we can do automatic retries for the first batch of statements
// in a transaction. There is an extension to the rule, though: for
// example, is we get a batch with "BEGIN; SET TRANSACTION ISOLATION LEVEL
// foo; SAVEPOINT cockroach_restart;" followed by a 2nd batch, we can
// automatically retry the 2nd batch even though the statements in the first
// batch will not be executed again and their results have already been sent
// to the clients. We can do this because some statements are special in that
// their execution always generates exactly the same results to the consumer
// (i.e. the SQL client).
//
// TODO(andrei): This state shouldn't exist; the decision about whether we can
// retry automatically or not should be entirely dynamic, based on which
// results we've delivered to the client already. It should have nothing to do
// with the client's batching of statements. For example, the client can send
// 100 batches but, if we haven't sent it any results yet, we should still be
// able to retry them all). Currently the splitting into batches is relevant
// because we don't keep track of statements from previous batches, so we
// would not be capable of retrying them even if we knew that no results have
// been delivered.
AutoRetry
// A txn is in scope.
Open
// The txn has encountered a (non-retriable) error.
// Statements will be rejected until a COMMIT/ROLLBACK is seen.
Aborted
// The txn has encountered a retriable error.
// Statements will be rejected until a RESTART_TRANSACTION is seen.
RestartWait
// The KV txn has been committed successfully through a RELEASE.
// Statements are rejected until a COMMIT is seen.
CommitWait
)
// Some states mean that a client.Txn is open, others don't.
func (s TxnStateEnum) kvTxnIsOpen() bool {
return s == Open || s == AutoRetry || s == RestartWait
}
// txnState contains state associated with an ongoing SQL txn.
// There may or may not be an open KV txn associated with the SQL txn.
// For interactive transactions (open across batches of SQL commands sent by a
// user), txnState is intended to be stored as part of a user Session.
type txnState struct {
// state is read and written to atomically because it can be updated
// concurrently with the execution of statements in the parallelizeQueue.
// Access with State() / SetState().
//
// NOTE: Only state updates that are inconsequential to statement execution
// are allowed concurrently with the execution of the parallizeQueue (e.g.
// Open->AutoRetry).
state TxnStateEnum
// Mutable fields accessed from goroutines not synchronized by this txn's session,
// such as when a SHOW SESSIONS statement is executed on another session.
// Note that reads of mu.txn from the session's main goroutine
// do not require acquiring a read lock - since only that
// goroutine will ever write to mu.txn.
mu struct {
syncutil.RWMutex
txn *client.Txn
}
// If we're in a SQL txn, txnResults is the ResultsGroup that statements in
// this transaction should write results to.
txnResults ResultsGroup
// Ctx is the context for everything running in this SQL txn.
Ctx context.Context
// cancel is the cancellation function for the above context. Called upon
// COMMIT/ROLLBACK of the transaction to release resources associated with
// the context. nil when no txn is in progress.
cancel context.CancelFunc
// implicitTxn if set if the transaction was automatically created for a
// single statement.
implicitTxn bool
// If set, the user declared the intention to retry the txn in case of retriable
// errors. The txn will enter a RestartWait state in case of such errors.
retryIntent bool
// A COMMIT statement has been processed. Useful for allowing the txn to
// survive retriable errors if it will be auto-retried (BEGIN; ... COMMIT; in
// the same batch), but not if the error needs to be reported to the user.
commitSeen bool
// The schema change closures to run when this txn is done.
schemaChangers schemaChangerCollection
sp opentracing.Span
// The timestamp to report for current_timestamp(), now() etc.
// This must be constant for the lifetime of a SQL transaction.
sqlTimestamp time.Time
// The transaction's isolation level.
isolation enginepb.IsolationType
// The transaction's priority.
priority roachpb.UserPriority
// mon tracks txn-bound objects like the running state of
// planNode in the midst of performing a computation. We
// host this here instead of TxnState because TxnState is
// fully reset upon each call to resetForNewSQLTxn().
mon mon.BytesMonitor
}
// State returns the current state of the session.
func (ts *txnState) State() TxnStateEnum {