open-vault/vendor/github.com/jackc/pgx/replication.go

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package pgx
import (
"context"
"encoding/binary"
"fmt"
"strings"
"time"
"github.com/pkg/errors"
"github.com/jackc/pgx/pgio"
"github.com/jackc/pgx/pgproto3"
"github.com/jackc/pgx/pgtype"
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)
const (
copyBothResponse = 'W'
walData = 'w'
senderKeepalive = 'k'
standbyStatusUpdate = 'r'
initialReplicationResponseTimeout = 5 * time.Second
)
var epochNano int64
func init() {
epochNano = time.Date(2000, 1, 1, 0, 0, 0, 0, time.UTC).UnixNano()
}
// Format the given 64bit LSN value into the XXX/XXX format,
// which is the format reported by postgres.
func FormatLSN(lsn uint64) string {
return fmt.Sprintf("%X/%X", uint32(lsn>>32), uint32(lsn))
}
// Parse the given XXX/XXX format LSN as reported by postgres,
// into a 64 bit integer as used internally by the wire procotols
func ParseLSN(lsn string) (outputLsn uint64, err error) {
var upperHalf uint64
var lowerHalf uint64
var nparsed int
nparsed, err = fmt.Sscanf(lsn, "%X/%X", &upperHalf, &lowerHalf)
if err != nil {
return
}
if nparsed != 2 {
err = errors.New(fmt.Sprintf("Failed to parsed LSN: %s", lsn))
return
}
outputLsn = (upperHalf << 32) + lowerHalf
return
}
// The WAL message contains WAL payload entry data
type WalMessage struct {
// The WAL start position of this data. This
// is the WAL position we need to track.
WalStart uint64
// The server wal end and server time are
// documented to track the end position and current
// time of the server, both of which appear to be
// unimplemented in pg 9.5.
ServerWalEnd uint64
ServerTime uint64
// The WAL data is the raw unparsed binary WAL entry.
// The contents of this are determined by the output
// logical encoding plugin.
WalData []byte
}
func (w *WalMessage) Time() time.Time {
return time.Unix(0, (int64(w.ServerTime)*1000)+epochNano)
}
func (w *WalMessage) ByteLag() uint64 {
return (w.ServerWalEnd - w.WalStart)
}
func (w *WalMessage) String() string {
return fmt.Sprintf("Wal: %s Time: %s Lag: %d", FormatLSN(w.WalStart), w.Time(), w.ByteLag())
}
// The server heartbeat is sent periodically from the server,
// including server status, and a reply request field
type ServerHeartbeat struct {
// The current max wal position on the server,
// used for lag tracking
ServerWalEnd uint64
// The server time, in microseconds since jan 1 2000
ServerTime uint64
// If 1, the server is requesting a standby status message
// to be sent immediately.
ReplyRequested byte
}
func (s *ServerHeartbeat) Time() time.Time {
return time.Unix(0, (int64(s.ServerTime)*1000)+epochNano)
}
func (s *ServerHeartbeat) String() string {
return fmt.Sprintf("WalEnd: %s ReplyRequested: %d T: %s", FormatLSN(s.ServerWalEnd), s.ReplyRequested, s.Time())
}
// The replication message wraps all possible messages from the
// server received during replication. At most one of the wal message
// or server heartbeat will be non-nil
type ReplicationMessage struct {
WalMessage *WalMessage
ServerHeartbeat *ServerHeartbeat
}
// The standby status is the client side heartbeat sent to the postgresql
// server to track the client wal positions. For practical purposes,
// all wal positions are typically set to the same value.
type StandbyStatus struct {
// The WAL position that's been locally written
WalWritePosition uint64
// The WAL position that's been locally flushed
WalFlushPosition uint64
// The WAL position that's been locally applied
WalApplyPosition uint64
// The client time in microseconds since jan 1 2000
ClientTime uint64
// If 1, requests the server to immediately send a
// server heartbeat
ReplyRequested byte
}
// Create a standby status struct, which sets all the WAL positions
// to the given wal position, and the client time to the current time.
// The wal positions are, in order:
// WalFlushPosition
// WalApplyPosition
// WalWritePosition
//
// If only one position is provided, it will be used as the value for all 3
// status fields. Note you must provide either 1 wal position, or all 3
// in order to initialize the standby status.
func NewStandbyStatus(walPositions ...uint64) (status *StandbyStatus, err error) {
if len(walPositions) == 1 {
status = new(StandbyStatus)
status.WalFlushPosition = walPositions[0]
status.WalApplyPosition = walPositions[0]
status.WalWritePosition = walPositions[0]
} else if len(walPositions) == 3 {
status = new(StandbyStatus)
status.WalFlushPosition = walPositions[0]
status.WalApplyPosition = walPositions[1]
status.WalWritePosition = walPositions[2]
} else {
err = errors.New(fmt.Sprintf("Invalid number of wal positions provided, need 1 or 3, got %d", len(walPositions)))
return
}
status.ClientTime = uint64((time.Now().UnixNano() - epochNano) / 1000)
return
}
func ReplicationConnect(config ConnConfig) (r *ReplicationConn, err error) {
if config.RuntimeParams == nil {
config.RuntimeParams = make(map[string]string)
}
config.RuntimeParams["replication"] = "database"
config.PreferSimpleProtocol = true
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c, err := Connect(config)
if err != nil {
return
}
return &ReplicationConn{c}, nil
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}
// ReplicationConn is a PostgreSQL connection handle established in the
// replication mode which enables a special set of commands for streaming WAL
// changes from the server.
//
// When in replication mode, only the simple query protocol can be used
// (see PreferSimpleProtocol in ConnConfig). Execution of normal SQL queries on
// the connection is possible but may be limited in available functionality.
// Most notably, prepared statements won't work.
//
// See https://www.postgresql.org/docs/11/protocol-replication.html for
// details.
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type ReplicationConn struct {
*Conn
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}
// Send standby status to the server, which both acts as a keepalive
// message to the server, as well as carries the WAL position of the
// client, which then updates the server's replication slot position.
func (rc *ReplicationConn) SendStandbyStatus(k *StandbyStatus) (err error) {
buf := rc.wbuf
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buf = append(buf, copyData)
sp := len(buf)
buf = pgio.AppendInt32(buf, -1)
buf = append(buf, standbyStatusUpdate)
buf = pgio.AppendInt64(buf, int64(k.WalWritePosition))
buf = pgio.AppendInt64(buf, int64(k.WalFlushPosition))
buf = pgio.AppendInt64(buf, int64(k.WalApplyPosition))
buf = pgio.AppendInt64(buf, int64(k.ClientTime))
buf = append(buf, k.ReplyRequested)
pgio.SetInt32(buf[sp:], int32(len(buf[sp:])))
_, err = rc.conn.Write(buf)
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if err != nil {
rc.die(err)
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}
return
}
func (rc *ReplicationConn) GetConnInfo() *pgtype.ConnInfo {
return rc.ConnInfo
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}
func (rc *ReplicationConn) readReplicationMessage() (r *ReplicationMessage, err error) {
msg, err := rc.rxMsg()
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if err != nil {
return
}
switch msg := msg.(type) {
case *pgproto3.NoticeResponse:
pgError := rc.rxErrorResponse((*pgproto3.ErrorResponse)(msg))
if rc.shouldLog(LogLevelInfo) {
rc.log(LogLevelInfo, pgError.Error(), nil)
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}
case *pgproto3.ErrorResponse:
err = rc.rxErrorResponse(msg)
if rc.shouldLog(LogLevelError) {
rc.log(LogLevelError, err.Error(), nil)
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}
return
case *pgproto3.CopyBothResponse:
// This is the tail end of the replication process start,
// and can be safely ignored
return
case *pgproto3.CopyData:
msgType := msg.Data[0]
rp := 1
switch msgType {
case walData:
walStart := binary.BigEndian.Uint64(msg.Data[rp:])
rp += 8
serverWalEnd := binary.BigEndian.Uint64(msg.Data[rp:])
rp += 8
serverTime := binary.BigEndian.Uint64(msg.Data[rp:])
rp += 8
walData := msg.Data[rp:]
walMessage := WalMessage{WalStart: walStart,
ServerWalEnd: serverWalEnd,
ServerTime: serverTime,
WalData: walData,
}
return &ReplicationMessage{WalMessage: &walMessage}, nil
case senderKeepalive:
serverWalEnd := binary.BigEndian.Uint64(msg.Data[rp:])
rp += 8
serverTime := binary.BigEndian.Uint64(msg.Data[rp:])
rp += 8
replyNow := msg.Data[rp]
rp += 1
h := &ServerHeartbeat{ServerWalEnd: serverWalEnd, ServerTime: serverTime, ReplyRequested: replyNow}
return &ReplicationMessage{ServerHeartbeat: h}, nil
default:
if rc.shouldLog(LogLevelError) {
rc.log(LogLevelError, "Unexpected data playload message type", map[string]interface{}{"type": msgType})
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}
}
default:
if rc.shouldLog(LogLevelError) {
rc.log(LogLevelError, "Unexpected replication message type", map[string]interface{}{"type": msg})
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}
}
return
}
// Wait for a single replication message.
//
// Properly using this requires some knowledge of the postgres replication mechanisms,
// as the client can receive both WAL data (the ultimate payload) and server heartbeat
// updates. The caller also must send standby status updates in order to keep the connection
// alive and working.
//
// This returns the context error when there is no replication message before
// the context is canceled.
func (rc *ReplicationConn) WaitForReplicationMessage(ctx context.Context) (*ReplicationMessage, error) {
select {
case <-ctx.Done():
return nil, ctx.Err()
default:
}
go func() {
select {
case <-ctx.Done():
if err := rc.conn.SetDeadline(time.Now()); err != nil {
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rc.Close() // Close connection if unable to set deadline
return
}
rc.closedChan <- ctx.Err()
case <-rc.doneChan:
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}
}()
r, opErr := rc.readReplicationMessage()
var err error
select {
case err = <-rc.closedChan:
if err := rc.conn.SetDeadline(time.Time{}); err != nil {
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rc.Close() // Close connection if unable to disable deadline
return nil, err
}
if opErr == nil {
err = nil
}
case rc.doneChan <- struct{}{}:
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err = opErr
}
return r, err
}
func (rc *ReplicationConn) sendReplicationModeQuery(sql string) (*Rows, error) {
rc.lastActivityTime = time.Now()
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rows := rc.getRows(sql, nil)
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if err := rc.lock(); err != nil {
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rows.fatal(err)
return rows, err
}
rows.unlockConn = true
err := rc.sendSimpleQuery(sql)
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if err != nil {
rows.fatal(err)
}
msg, err := rc.rxMsg()
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if err != nil {
return nil, err
}
switch msg := msg.(type) {
case *pgproto3.RowDescription:
rows.fields = rc.rxRowDescription(msg)
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// We don't have c.PgTypes here because we're a replication
// connection. This means the field descriptions will have
// only OIDs. Not much we can do about this.
default:
if e := rc.processContextFreeMsg(msg); e != nil {
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rows.fatal(e)
return rows, e
}
}
return rows, rows.err
}
// Execute the "IDENTIFY_SYSTEM" command as documented here:
// https://www.postgresql.org/docs/9.5/static/protocol-replication.html
//
// This will return (if successful) a result set that has a single row
// that contains the systemid, current timeline, xlogpos and database
// name.
//
// NOTE: Because this is a replication mode connection, we don't have
// type names, so the field descriptions in the result will have only
// OIDs and no DataTypeName values
func (rc *ReplicationConn) IdentifySystem() (r *Rows, err error) {
return rc.sendReplicationModeQuery("IDENTIFY_SYSTEM")
}
// Execute the "TIMELINE_HISTORY" command as documented here:
// https://www.postgresql.org/docs/9.5/static/protocol-replication.html
//
// This will return (if successful) a result set that has a single row
// that contains the filename of the history file and the content
// of the history file. If called for timeline 1, typically this will
// generate an error that the timeline history file does not exist.
//
// NOTE: Because this is a replication mode connection, we don't have
// type names, so the field descriptions in the result will have only
// OIDs and no DataTypeName values
func (rc *ReplicationConn) TimelineHistory(timeline int) (r *Rows, err error) {
return rc.sendReplicationModeQuery(fmt.Sprintf("TIMELINE_HISTORY %d", timeline))
}
// Start a replication connection, sending WAL data to the given replication
// receiver. This function wraps a START_REPLICATION command as documented
// here:
// https://www.postgresql.org/docs/9.5/static/protocol-replication.html
//
// Once started, the client needs to invoke WaitForReplicationMessage() in order
// to fetch the WAL and standby status. Also, it is the responsibility of the caller
// to periodically send StandbyStatus messages to update the replication slot position.
//
// This function assumes that slotName has already been created. In order to omit the timeline argument
// pass a -1 for the timeline to get the server default behavior.
func (rc *ReplicationConn) StartReplication(slotName string, startLsn uint64, timeline int64, pluginArguments ...string) (err error) {
queryString := fmt.Sprintf("START_REPLICATION SLOT %s LOGICAL %s", slotName, FormatLSN(startLsn))
if timeline >= 0 {
timelineOption := fmt.Sprintf("TIMELINE %d", timeline)
pluginArguments = append(pluginArguments, timelineOption)
}
if len(pluginArguments) > 0 {
queryString += fmt.Sprintf(" ( %s )", strings.Join(pluginArguments, ", "))
}
if err = rc.sendQuery(queryString); err != nil {
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return
}
ctx, cancelFn := context.WithTimeout(context.Background(), initialReplicationResponseTimeout)
defer cancelFn()
// The first replication message that comes back here will be (in a success case)
// a empty CopyBoth that is (apparently) sent as the confirmation that the replication has
// started. This call will either return nil, nil or if it returns an error
// that indicates the start replication command failed
var r *ReplicationMessage
r, err = rc.WaitForReplicationMessage(ctx)
if err != nil && r != nil {
if rc.shouldLog(LogLevelError) {
rc.log(LogLevelError, "Unexpected replication message", map[string]interface{}{"msg": r, "err": err})
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}
}
return
}
// Create the replication slot, using the given name and output plugin.
func (rc *ReplicationConn) CreateReplicationSlot(slotName, outputPlugin string) (err error) {
_, err = rc.Exec(fmt.Sprintf("CREATE_REPLICATION_SLOT %s LOGICAL %s NOEXPORT_SNAPSHOT", slotName, outputPlugin))
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return
}
// Create the replication slot, using the given name and output plugin, and return the consistent_point and snapshot_name values.
func (rc *ReplicationConn) CreateReplicationSlotEx(slotName, outputPlugin string) (consistentPoint string, snapshotName string, err error) {
var dummy string
var rows *Rows
rows, err = rc.sendReplicationModeQuery(fmt.Sprintf("CREATE_REPLICATION_SLOT %s LOGICAL %s", slotName, outputPlugin))
defer rows.Close()
for rows.Next() {
rows.Scan(&dummy, &consistentPoint, &snapshotName, &dummy)
}
return
}
// Drop the replication slot for the given name
func (rc *ReplicationConn) DropReplicationSlot(slotName string) (err error) {
_, err = rc.Exec(fmt.Sprintf("DROP_REPLICATION_SLOT %s", slotName))
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return
}