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forgejo/vendor/github.com/lib/pq/conn.go
6543 d1353e1f7c
Vendor Update (#14496)
* update code.gitea.io/sdk/gitea v0.13.1 -> v0.13.2

* update github.com/go-swagger/go-swagger v0.25.0 -> v0.26.0

* update github.com/google/uuid v1.1.2 -> v1.2.0

* update github.com/klauspost/compress v1.11.3 -> v1.11.7

* update github.com/lib/pq 083382b7e6fc -> v1.9.0

* update github.com/markbates/goth v1.65.0 -> v1.66.1

* update github.com/mattn/go-sqlite3 v1.14.4 -> v1.14.6

* update github.com/mgechev/revive 246eac737dc7 -> v1.0.3

* update github.com/minio/minio-go/v7 v7.0.6 -> v7.0.7

* update github.com/niklasfasching/go-org v1.3.2 -> v1.4.0

* update github.com/olivere/elastic/v7 v7.0.21 -> v7.0.22

* update github.com/pquerna/otp v1.2.0 -> v1.3.0

* update github.com/xanzy/go-gitlab v0.39.0 -> v0.42.0

* update github.com/yuin/goldmark v1.2.1 -> v1.3.1
2021-01-28 17:56:38 +01:00

2033 lines
47 KiB
Go
Vendored

package pq
import (
"bufio"
"context"
"crypto/md5"
"crypto/sha256"
"database/sql"
"database/sql/driver"
"encoding/binary"
"errors"
"fmt"
"io"
"net"
"os"
"os/user"
"path"
"path/filepath"
"strconv"
"strings"
"sync/atomic"
"time"
"unicode"
"github.com/lib/pq/oid"
"github.com/lib/pq/scram"
)
// Common error types
var (
ErrNotSupported = errors.New("pq: Unsupported command")
ErrInFailedTransaction = errors.New("pq: Could not complete operation in a failed transaction")
ErrSSLNotSupported = errors.New("pq: SSL is not enabled on the server")
ErrSSLKeyHasWorldPermissions = errors.New("pq: Private key file has group or world access. Permissions should be u=rw (0600) or less")
ErrCouldNotDetectUsername = errors.New("pq: Could not detect default username. Please provide one explicitly")
errUnexpectedReady = errors.New("unexpected ReadyForQuery")
errNoRowsAffected = errors.New("no RowsAffected available after the empty statement")
errNoLastInsertID = errors.New("no LastInsertId available after the empty statement")
)
// Compile time validation that our types implement the expected interfaces
var (
_ driver.Driver = Driver{}
)
// Driver is the Postgres database driver.
type Driver struct{}
// Open opens a new connection to the database. name is a connection string.
// Most users should only use it through database/sql package from the standard
// library.
func (d Driver) Open(name string) (driver.Conn, error) {
return Open(name)
}
func init() {
sql.Register("postgres", &Driver{})
}
type parameterStatus struct {
// server version in the same format as server_version_num, or 0 if
// unavailable
serverVersion int
// the current location based on the TimeZone value of the session, if
// available
currentLocation *time.Location
}
type transactionStatus byte
const (
txnStatusIdle transactionStatus = 'I'
txnStatusIdleInTransaction transactionStatus = 'T'
txnStatusInFailedTransaction transactionStatus = 'E'
)
func (s transactionStatus) String() string {
switch s {
case txnStatusIdle:
return "idle"
case txnStatusIdleInTransaction:
return "idle in transaction"
case txnStatusInFailedTransaction:
return "in a failed transaction"
default:
errorf("unknown transactionStatus %d", s)
}
panic("not reached")
}
// Dialer is the dialer interface. It can be used to obtain more control over
// how pq creates network connections.
type Dialer interface {
Dial(network, address string) (net.Conn, error)
DialTimeout(network, address string, timeout time.Duration) (net.Conn, error)
}
// DialerContext is the context-aware dialer interface.
type DialerContext interface {
DialContext(ctx context.Context, network, address string) (net.Conn, error)
}
type defaultDialer struct {
d net.Dialer
}
func (d defaultDialer) Dial(network, address string) (net.Conn, error) {
return d.d.Dial(network, address)
}
func (d defaultDialer) DialTimeout(network, address string, timeout time.Duration) (net.Conn, error) {
ctx, cancel := context.WithTimeout(context.Background(), timeout)
defer cancel()
return d.DialContext(ctx, network, address)
}
func (d defaultDialer) DialContext(ctx context.Context, network, address string) (net.Conn, error) {
return d.d.DialContext(ctx, network, address)
}
type conn struct {
c net.Conn
buf *bufio.Reader
namei int
scratch [512]byte
txnStatus transactionStatus
txnFinish func()
// Save connection arguments to use during CancelRequest.
dialer Dialer
opts values
// Cancellation key data for use with CancelRequest messages.
processID int
secretKey int
parameterStatus parameterStatus
saveMessageType byte
saveMessageBuffer []byte
// If true, this connection is bad and all public-facing functions should
// return ErrBadConn.
bad *atomic.Value
// If set, this connection should never use the binary format when
// receiving query results from prepared statements. Only provided for
// debugging.
disablePreparedBinaryResult bool
// Whether to always send []byte parameters over as binary. Enables single
// round-trip mode for non-prepared Query calls.
binaryParameters bool
// If true this connection is in the middle of a COPY
inCopy bool
// If not nil, notices will be synchronously sent here
noticeHandler func(*Error)
// If not nil, notifications will be synchronously sent here
notificationHandler func(*Notification)
// GSSAPI context
gss GSS
}
// Handle driver-side settings in parsed connection string.
func (cn *conn) handleDriverSettings(o values) (err error) {
boolSetting := func(key string, val *bool) error {
if value, ok := o[key]; ok {
if value == "yes" {
*val = true
} else if value == "no" {
*val = false
} else {
return fmt.Errorf("unrecognized value %q for %s", value, key)
}
}
return nil
}
err = boolSetting("disable_prepared_binary_result", &cn.disablePreparedBinaryResult)
if err != nil {
return err
}
return boolSetting("binary_parameters", &cn.binaryParameters)
}
func (cn *conn) handlePgpass(o values) {
// if a password was supplied, do not process .pgpass
if _, ok := o["password"]; ok {
return
}
filename := os.Getenv("PGPASSFILE")
if filename == "" {
// XXX this code doesn't work on Windows where the default filename is
// XXX %APPDATA%\postgresql\pgpass.conf
// Prefer $HOME over user.Current due to glibc bug: golang.org/issue/13470
userHome := os.Getenv("HOME")
if userHome == "" {
user, err := user.Current()
if err != nil {
return
}
userHome = user.HomeDir
}
filename = filepath.Join(userHome, ".pgpass")
}
fileinfo, err := os.Stat(filename)
if err != nil {
return
}
mode := fileinfo.Mode()
if mode&(0x77) != 0 {
// XXX should warn about incorrect .pgpass permissions as psql does
return
}
file, err := os.Open(filename)
if err != nil {
return
}
defer file.Close()
scanner := bufio.NewScanner(io.Reader(file))
hostname := o["host"]
ntw, _ := network(o)
port := o["port"]
db := o["dbname"]
username := o["user"]
// From: https://github.com/tg/pgpass/blob/master/reader.go
getFields := func(s string) []string {
fs := make([]string, 0, 5)
f := make([]rune, 0, len(s))
var esc bool
for _, c := range s {
switch {
case esc:
f = append(f, c)
esc = false
case c == '\\':
esc = true
case c == ':':
fs = append(fs, string(f))
f = f[:0]
default:
f = append(f, c)
}
}
return append(fs, string(f))
}
for scanner.Scan() {
line := scanner.Text()
if len(line) == 0 || line[0] == '#' {
continue
}
split := getFields(line)
if len(split) != 5 {
continue
}
if (split[0] == "*" || split[0] == hostname || (split[0] == "localhost" && (hostname == "" || ntw == "unix"))) && (split[1] == "*" || split[1] == port) && (split[2] == "*" || split[2] == db) && (split[3] == "*" || split[3] == username) {
o["password"] = split[4]
return
}
}
}
func (cn *conn) writeBuf(b byte) *writeBuf {
cn.scratch[0] = b
return &writeBuf{
buf: cn.scratch[:5],
pos: 1,
}
}
// Open opens a new connection to the database. dsn is a connection string.
// Most users should only use it through database/sql package from the standard
// library.
func Open(dsn string) (_ driver.Conn, err error) {
return DialOpen(defaultDialer{}, dsn)
}
// DialOpen opens a new connection to the database using a dialer.
func DialOpen(d Dialer, dsn string) (_ driver.Conn, err error) {
c, err := NewConnector(dsn)
if err != nil {
return nil, err
}
c.dialer = d
return c.open(context.Background())
}
func (c *Connector) open(ctx context.Context) (cn *conn, err error) {
// Handle any panics during connection initialization. Note that we
// specifically do *not* want to use errRecover(), as that would turn any
// connection errors into ErrBadConns, hiding the real error message from
// the user.
defer errRecoverNoErrBadConn(&err)
o := c.opts
bad := &atomic.Value{}
bad.Store(false)
cn = &conn{
opts: o,
dialer: c.dialer,
bad: bad,
}
err = cn.handleDriverSettings(o)
if err != nil {
return nil, err
}
cn.handlePgpass(o)
cn.c, err = dial(ctx, c.dialer, o)
if err != nil {
return nil, err
}
err = cn.ssl(o)
if err != nil {
if cn.c != nil {
cn.c.Close()
}
return nil, err
}
// cn.startup panics on error. Make sure we don't leak cn.c.
panicking := true
defer func() {
if panicking {
cn.c.Close()
}
}()
cn.buf = bufio.NewReader(cn.c)
cn.startup(o)
// reset the deadline, in case one was set (see dial)
if timeout, ok := o["connect_timeout"]; ok && timeout != "0" {
err = cn.c.SetDeadline(time.Time{})
}
panicking = false
return cn, err
}
func dial(ctx context.Context, d Dialer, o values) (net.Conn, error) {
network, address := network(o)
// Zero or not specified means wait indefinitely.
if timeout, ok := o["connect_timeout"]; ok && timeout != "0" {
seconds, err := strconv.ParseInt(timeout, 10, 0)
if err != nil {
return nil, fmt.Errorf("invalid value for parameter connect_timeout: %s", err)
}
duration := time.Duration(seconds) * time.Second
// connect_timeout should apply to the entire connection establishment
// procedure, so we both use a timeout for the TCP connection
// establishment and set a deadline for doing the initial handshake.
// The deadline is then reset after startup() is done.
deadline := time.Now().Add(duration)
var conn net.Conn
if dctx, ok := d.(DialerContext); ok {
ctx, cancel := context.WithTimeout(ctx, duration)
defer cancel()
conn, err = dctx.DialContext(ctx, network, address)
} else {
conn, err = d.DialTimeout(network, address, duration)
}
if err != nil {
return nil, err
}
err = conn.SetDeadline(deadline)
return conn, err
}
if dctx, ok := d.(DialerContext); ok {
return dctx.DialContext(ctx, network, address)
}
return d.Dial(network, address)
}
func network(o values) (string, string) {
host := o["host"]
if strings.HasPrefix(host, "/") {
sockPath := path.Join(host, ".s.PGSQL."+o["port"])
return "unix", sockPath
}
return "tcp", net.JoinHostPort(host, o["port"])
}
type values map[string]string
// scanner implements a tokenizer for libpq-style option strings.
type scanner struct {
s []rune
i int
}
// newScanner returns a new scanner initialized with the option string s.
func newScanner(s string) *scanner {
return &scanner{[]rune(s), 0}
}
// Next returns the next rune.
// It returns 0, false if the end of the text has been reached.
func (s *scanner) Next() (rune, bool) {
if s.i >= len(s.s) {
return 0, false
}
r := s.s[s.i]
s.i++
return r, true
}
// SkipSpaces returns the next non-whitespace rune.
// It returns 0, false if the end of the text has been reached.
func (s *scanner) SkipSpaces() (rune, bool) {
r, ok := s.Next()
for unicode.IsSpace(r) && ok {
r, ok = s.Next()
}
return r, ok
}
// parseOpts parses the options from name and adds them to the values.
//
// The parsing code is based on conninfo_parse from libpq's fe-connect.c
func parseOpts(name string, o values) error {
s := newScanner(name)
for {
var (
keyRunes, valRunes []rune
r rune
ok bool
)
if r, ok = s.SkipSpaces(); !ok {
break
}
// Scan the key
for !unicode.IsSpace(r) && r != '=' {
keyRunes = append(keyRunes, r)
if r, ok = s.Next(); !ok {
break
}
}
// Skip any whitespace if we're not at the = yet
if r != '=' {
r, ok = s.SkipSpaces()
}
// The current character should be =
if r != '=' || !ok {
return fmt.Errorf(`missing "=" after %q in connection info string"`, string(keyRunes))
}
// Skip any whitespace after the =
if r, ok = s.SkipSpaces(); !ok {
// If we reach the end here, the last value is just an empty string as per libpq.
o[string(keyRunes)] = ""
break
}
if r != '\'' {
for !unicode.IsSpace(r) {
if r == '\\' {
if r, ok = s.Next(); !ok {
return fmt.Errorf(`missing character after backslash`)
}
}
valRunes = append(valRunes, r)
if r, ok = s.Next(); !ok {
break
}
}
} else {
quote:
for {
if r, ok = s.Next(); !ok {
return fmt.Errorf(`unterminated quoted string literal in connection string`)
}
switch r {
case '\'':
break quote
case '\\':
r, _ = s.Next()
fallthrough
default:
valRunes = append(valRunes, r)
}
}
}
o[string(keyRunes)] = string(valRunes)
}
return nil
}
func (cn *conn) isInTransaction() bool {
return cn.txnStatus == txnStatusIdleInTransaction ||
cn.txnStatus == txnStatusInFailedTransaction
}
func (cn *conn) setBad() {
if cn.bad != nil {
cn.bad.Store(true)
}
}
func (cn *conn) getBad() bool {
if cn.bad != nil {
return cn.bad.Load().(bool)
}
return false
}
func (cn *conn) checkIsInTransaction(intxn bool) {
if cn.isInTransaction() != intxn {
cn.setBad()
errorf("unexpected transaction status %v", cn.txnStatus)
}
}
func (cn *conn) Begin() (_ driver.Tx, err error) {
return cn.begin("")
}
func (cn *conn) begin(mode string) (_ driver.Tx, err error) {
if cn.getBad() {
return nil, driver.ErrBadConn
}
defer cn.errRecover(&err)
cn.checkIsInTransaction(false)
_, commandTag, err := cn.simpleExec("BEGIN" + mode)
if err != nil {
return nil, err
}
if commandTag != "BEGIN" {
cn.setBad()
return nil, fmt.Errorf("unexpected command tag %s", commandTag)
}
if cn.txnStatus != txnStatusIdleInTransaction {
cn.setBad()
return nil, fmt.Errorf("unexpected transaction status %v", cn.txnStatus)
}
return cn, nil
}
func (cn *conn) closeTxn() {
if finish := cn.txnFinish; finish != nil {
finish()
}
}
func (cn *conn) Commit() (err error) {
defer cn.closeTxn()
if cn.getBad() {
return driver.ErrBadConn
}
defer cn.errRecover(&err)
cn.checkIsInTransaction(true)
// We don't want the client to think that everything is okay if it tries
// to commit a failed transaction. However, no matter what we return,
// database/sql will release this connection back into the free connection
// pool so we have to abort the current transaction here. Note that you
// would get the same behaviour if you issued a COMMIT in a failed
// transaction, so it's also the least surprising thing to do here.
if cn.txnStatus == txnStatusInFailedTransaction {
if err := cn.rollback(); err != nil {
return err
}
return ErrInFailedTransaction
}
_, commandTag, err := cn.simpleExec("COMMIT")
if err != nil {
if cn.isInTransaction() {
cn.setBad()
}
return err
}
if commandTag != "COMMIT" {
cn.setBad()
return fmt.Errorf("unexpected command tag %s", commandTag)
}
cn.checkIsInTransaction(false)
return nil
}
func (cn *conn) Rollback() (err error) {
defer cn.closeTxn()
if cn.getBad() {
return driver.ErrBadConn
}
defer cn.errRecover(&err)
return cn.rollback()
}
func (cn *conn) rollback() (err error) {
cn.checkIsInTransaction(true)
_, commandTag, err := cn.simpleExec("ROLLBACK")
if err != nil {
if cn.isInTransaction() {
cn.setBad()
}
return err
}
if commandTag != "ROLLBACK" {
return fmt.Errorf("unexpected command tag %s", commandTag)
}
cn.checkIsInTransaction(false)
return nil
}
func (cn *conn) gname() string {
cn.namei++
return strconv.FormatInt(int64(cn.namei), 10)
}
func (cn *conn) simpleExec(q string) (res driver.Result, commandTag string, err error) {
b := cn.writeBuf('Q')
b.string(q)
cn.send(b)
for {
t, r := cn.recv1()
switch t {
case 'C':
res, commandTag = cn.parseComplete(r.string())
case 'Z':
cn.processReadyForQuery(r)
if res == nil && err == nil {
err = errUnexpectedReady
}
// done
return
case 'E':
err = parseError(r)
case 'I':
res = emptyRows
case 'T', 'D':
// ignore any results
default:
cn.setBad()
errorf("unknown response for simple query: %q", t)
}
}
}
func (cn *conn) simpleQuery(q string) (res *rows, err error) {
defer cn.errRecover(&err)
b := cn.writeBuf('Q')
b.string(q)
cn.send(b)
for {
t, r := cn.recv1()
switch t {
case 'C', 'I':
// We allow queries which don't return any results through Query as
// well as Exec. We still have to give database/sql a rows object
// the user can close, though, to avoid connections from being
// leaked. A "rows" with done=true works fine for that purpose.
if err != nil {
cn.setBad()
errorf("unexpected message %q in simple query execution", t)
}
if res == nil {
res = &rows{
cn: cn,
}
}
// Set the result and tag to the last command complete if there wasn't a
// query already run. Although queries usually return from here and cede
// control to Next, a query with zero results does not.
if t == 'C' {
res.result, res.tag = cn.parseComplete(r.string())
if res.colNames != nil {
return
}
}
res.done = true
case 'Z':
cn.processReadyForQuery(r)
// done
return
case 'E':
res = nil
err = parseError(r)
case 'D':
if res == nil {
cn.setBad()
errorf("unexpected DataRow in simple query execution")
}
// the query didn't fail; kick off to Next
cn.saveMessage(t, r)
return
case 'T':
// res might be non-nil here if we received a previous
// CommandComplete, but that's fine; just overwrite it
res = &rows{cn: cn}
res.rowsHeader = parsePortalRowDescribe(r)
// To work around a bug in QueryRow in Go 1.2 and earlier, wait
// until the first DataRow has been received.
default:
cn.setBad()
errorf("unknown response for simple query: %q", t)
}
}
}
type noRows struct{}
var emptyRows noRows
var _ driver.Result = noRows{}
func (noRows) LastInsertId() (int64, error) {
return 0, errNoLastInsertID
}
func (noRows) RowsAffected() (int64, error) {
return 0, errNoRowsAffected
}
// Decides which column formats to use for a prepared statement. The input is
// an array of type oids, one element per result column.
func decideColumnFormats(colTyps []fieldDesc, forceText bool) (colFmts []format, colFmtData []byte) {
if len(colTyps) == 0 {
return nil, colFmtDataAllText
}
colFmts = make([]format, len(colTyps))
if forceText {
return colFmts, colFmtDataAllText
}
allBinary := true
allText := true
for i, t := range colTyps {
switch t.OID {
// This is the list of types to use binary mode for when receiving them
// through a prepared statement. If a type appears in this list, it
// must also be implemented in binaryDecode in encode.go.
case oid.T_bytea:
fallthrough
case oid.T_int8:
fallthrough
case oid.T_int4:
fallthrough
case oid.T_int2:
fallthrough
case oid.T_uuid:
colFmts[i] = formatBinary
allText = false
default:
allBinary = false
}
}
if allBinary {
return colFmts, colFmtDataAllBinary
} else if allText {
return colFmts, colFmtDataAllText
} else {
colFmtData = make([]byte, 2+len(colFmts)*2)
binary.BigEndian.PutUint16(colFmtData, uint16(len(colFmts)))
for i, v := range colFmts {
binary.BigEndian.PutUint16(colFmtData[2+i*2:], uint16(v))
}
return colFmts, colFmtData
}
}
func (cn *conn) prepareTo(q, stmtName string) *stmt {
st := &stmt{cn: cn, name: stmtName}
b := cn.writeBuf('P')
b.string(st.name)
b.string(q)
b.int16(0)
b.next('D')
b.byte('S')
b.string(st.name)
b.next('S')
cn.send(b)
cn.readParseResponse()
st.paramTyps, st.colNames, st.colTyps = cn.readStatementDescribeResponse()
st.colFmts, st.colFmtData = decideColumnFormats(st.colTyps, cn.disablePreparedBinaryResult)
cn.readReadyForQuery()
return st
}
func (cn *conn) Prepare(q string) (_ driver.Stmt, err error) {
if cn.getBad() {
return nil, driver.ErrBadConn
}
defer cn.errRecover(&err)
if len(q) >= 4 && strings.EqualFold(q[:4], "COPY") {
s, err := cn.prepareCopyIn(q)
if err == nil {
cn.inCopy = true
}
return s, err
}
return cn.prepareTo(q, cn.gname()), nil
}
func (cn *conn) Close() (err error) {
// Skip cn.bad return here because we always want to close a connection.
defer cn.errRecover(&err)
// Ensure that cn.c.Close is always run. Since error handling is done with
// panics and cn.errRecover, the Close must be in a defer.
defer func() {
cerr := cn.c.Close()
if err == nil {
err = cerr
}
}()
// Don't go through send(); ListenerConn relies on us not scribbling on the
// scratch buffer of this connection.
return cn.sendSimpleMessage('X')
}
// Implement the "Queryer" interface
func (cn *conn) Query(query string, args []driver.Value) (driver.Rows, error) {
return cn.query(query, args)
}
func (cn *conn) query(query string, args []driver.Value) (_ *rows, err error) {
if cn.getBad() {
return nil, driver.ErrBadConn
}
if cn.inCopy {
return nil, errCopyInProgress
}
defer cn.errRecover(&err)
// Check to see if we can use the "simpleQuery" interface, which is
// *much* faster than going through prepare/exec
if len(args) == 0 {
return cn.simpleQuery(query)
}
if cn.binaryParameters {
cn.sendBinaryModeQuery(query, args)
cn.readParseResponse()
cn.readBindResponse()
rows := &rows{cn: cn}
rows.rowsHeader = cn.readPortalDescribeResponse()
cn.postExecuteWorkaround()
return rows, nil
}
st := cn.prepareTo(query, "")
st.exec(args)
return &rows{
cn: cn,
rowsHeader: st.rowsHeader,
}, nil
}
// Implement the optional "Execer" interface for one-shot queries
func (cn *conn) Exec(query string, args []driver.Value) (res driver.Result, err error) {
if cn.getBad() {
return nil, driver.ErrBadConn
}
defer cn.errRecover(&err)
// Check to see if we can use the "simpleExec" interface, which is
// *much* faster than going through prepare/exec
if len(args) == 0 {
// ignore commandTag, our caller doesn't care
r, _, err := cn.simpleExec(query)
return r, err
}
if cn.binaryParameters {
cn.sendBinaryModeQuery(query, args)
cn.readParseResponse()
cn.readBindResponse()
cn.readPortalDescribeResponse()
cn.postExecuteWorkaround()
res, _, err = cn.readExecuteResponse("Execute")
return res, err
}
// Use the unnamed statement to defer planning until bind
// time, or else value-based selectivity estimates cannot be
// used.
st := cn.prepareTo(query, "")
r, err := st.Exec(args)
if err != nil {
panic(err)
}
return r, err
}
type safeRetryError struct {
Err error
}
func (se *safeRetryError) Error() string {
return se.Err.Error()
}
func (cn *conn) send(m *writeBuf) {
n, err := cn.c.Write(m.wrap())
if err != nil {
if n == 0 {
err = &safeRetryError{Err: err}
}
panic(err)
}
}
func (cn *conn) sendStartupPacket(m *writeBuf) error {
_, err := cn.c.Write((m.wrap())[1:])
return err
}
// Send a message of type typ to the server on the other end of cn. The
// message should have no payload. This method does not use the scratch
// buffer.
func (cn *conn) sendSimpleMessage(typ byte) (err error) {
_, err = cn.c.Write([]byte{typ, '\x00', '\x00', '\x00', '\x04'})
return err
}
// saveMessage memorizes a message and its buffer in the conn struct.
// recvMessage will then return these values on the next call to it. This
// method is useful in cases where you have to see what the next message is
// going to be (e.g. to see whether it's an error or not) but you can't handle
// the message yourself.
func (cn *conn) saveMessage(typ byte, buf *readBuf) {
if cn.saveMessageType != 0 {
cn.setBad()
errorf("unexpected saveMessageType %d", cn.saveMessageType)
}
cn.saveMessageType = typ
cn.saveMessageBuffer = *buf
}
// recvMessage receives any message from the backend, or returns an error if
// a problem occurred while reading the message.
func (cn *conn) recvMessage(r *readBuf) (byte, error) {
// workaround for a QueryRow bug, see exec
if cn.saveMessageType != 0 {
t := cn.saveMessageType
*r = cn.saveMessageBuffer
cn.saveMessageType = 0
cn.saveMessageBuffer = nil
return t, nil
}
x := cn.scratch[:5]
_, err := io.ReadFull(cn.buf, x)
if err != nil {
return 0, err
}
// read the type and length of the message that follows
t := x[0]
n := int(binary.BigEndian.Uint32(x[1:])) - 4
var y []byte
if n <= len(cn.scratch) {
y = cn.scratch[:n]
} else {
y = make([]byte, n)
}
_, err = io.ReadFull(cn.buf, y)
if err != nil {
return 0, err
}
*r = y
return t, nil
}
// recv receives a message from the backend, but if an error happened while
// reading the message or the received message was an ErrorResponse, it panics.
// NoticeResponses are ignored. This function should generally be used only
// during the startup sequence.
func (cn *conn) recv() (t byte, r *readBuf) {
for {
var err error
r = &readBuf{}
t, err = cn.recvMessage(r)
if err != nil {
panic(err)
}
switch t {
case 'E':
panic(parseError(r))
case 'N':
if n := cn.noticeHandler; n != nil {
n(parseError(r))
}
case 'A':
if n := cn.notificationHandler; n != nil {
n(recvNotification(r))
}
default:
return
}
}
}
// recv1Buf is exactly equivalent to recv1, except it uses a buffer supplied by
// the caller to avoid an allocation.
func (cn *conn) recv1Buf(r *readBuf) byte {
for {
t, err := cn.recvMessage(r)
if err != nil {
panic(err)
}
switch t {
case 'A':
if n := cn.notificationHandler; n != nil {
n(recvNotification(r))
}
case 'N':
if n := cn.noticeHandler; n != nil {
n(parseError(r))
}
case 'S':
cn.processParameterStatus(r)
default:
return t
}
}
}
// recv1 receives a message from the backend, panicking if an error occurs
// while attempting to read it. All asynchronous messages are ignored, with
// the exception of ErrorResponse.
func (cn *conn) recv1() (t byte, r *readBuf) {
r = &readBuf{}
t = cn.recv1Buf(r)
return t, r
}
func (cn *conn) ssl(o values) error {
upgrade, err := ssl(o)
if err != nil {
return err
}
if upgrade == nil {
// Nothing to do
return nil
}
w := cn.writeBuf(0)
w.int32(80877103)
if err = cn.sendStartupPacket(w); err != nil {
return err
}
b := cn.scratch[:1]
_, err = io.ReadFull(cn.c, b)
if err != nil {
return err
}
if b[0] != 'S' {
return ErrSSLNotSupported
}
cn.c, err = upgrade(cn.c)
return err
}
// isDriverSetting returns true iff a setting is purely for configuring the
// driver's options and should not be sent to the server in the connection
// startup packet.
func isDriverSetting(key string) bool {
switch key {
case "host", "port":
return true
case "password":
return true
case "sslmode", "sslcert", "sslkey", "sslrootcert":
return true
case "fallback_application_name":
return true
case "connect_timeout":
return true
case "disable_prepared_binary_result":
return true
case "binary_parameters":
return true
case "krbsrvname":
return true
case "krbspn":
return true
default:
return false
}
}
func (cn *conn) startup(o values) {
w := cn.writeBuf(0)
w.int32(196608)
// Send the backend the name of the database we want to connect to, and the
// user we want to connect as. Additionally, we send over any run-time
// parameters potentially included in the connection string. If the server
// doesn't recognize any of them, it will reply with an error.
for k, v := range o {
if isDriverSetting(k) {
// skip options which can't be run-time parameters
continue
}
// The protocol requires us to supply the database name as "database"
// instead of "dbname".
if k == "dbname" {
k = "database"
}
w.string(k)
w.string(v)
}
w.string("")
if err := cn.sendStartupPacket(w); err != nil {
panic(err)
}
for {
t, r := cn.recv()
switch t {
case 'K':
cn.processBackendKeyData(r)
case 'S':
cn.processParameterStatus(r)
case 'R':
cn.auth(r, o)
case 'Z':
cn.processReadyForQuery(r)
return
default:
errorf("unknown response for startup: %q", t)
}
}
}
func (cn *conn) auth(r *readBuf, o values) {
switch code := r.int32(); code {
case 0:
// OK
case 3:
w := cn.writeBuf('p')
w.string(o["password"])
cn.send(w)
t, r := cn.recv()
if t != 'R' {
errorf("unexpected password response: %q", t)
}
if r.int32() != 0 {
errorf("unexpected authentication response: %q", t)
}
case 5:
s := string(r.next(4))
w := cn.writeBuf('p')
w.string("md5" + md5s(md5s(o["password"]+o["user"])+s))
cn.send(w)
t, r := cn.recv()
if t != 'R' {
errorf("unexpected password response: %q", t)
}
if r.int32() != 0 {
errorf("unexpected authentication response: %q", t)
}
case 7: // GSSAPI, startup
if newGss == nil {
errorf("kerberos error: no GSSAPI provider registered (import github.com/lib/pq/auth/kerberos if you need Kerberos support)")
}
cli, err := newGss()
if err != nil {
errorf("kerberos error: %s", err.Error())
}
var token []byte
if spn, ok := o["krbspn"]; ok {
// Use the supplied SPN if provided..
token, err = cli.GetInitTokenFromSpn(spn)
} else {
// Allow the kerberos service name to be overridden
service := "postgres"
if val, ok := o["krbsrvname"]; ok {
service = val
}
token, err = cli.GetInitToken(o["host"], service)
}
if err != nil {
errorf("failed to get Kerberos ticket: %q", err)
}
w := cn.writeBuf('p')
w.bytes(token)
cn.send(w)
// Store for GSSAPI continue message
cn.gss = cli
case 8: // GSSAPI continue
if cn.gss == nil {
errorf("GSSAPI protocol error")
}
b := []byte(*r)
done, tokOut, err := cn.gss.Continue(b)
if err == nil && !done {
w := cn.writeBuf('p')
w.bytes(tokOut)
cn.send(w)
}
// Errors fall through and read the more detailed message
// from the server..
case 10:
sc := scram.NewClient(sha256.New, o["user"], o["password"])
sc.Step(nil)
if sc.Err() != nil {
errorf("SCRAM-SHA-256 error: %s", sc.Err().Error())
}
scOut := sc.Out()
w := cn.writeBuf('p')
w.string("SCRAM-SHA-256")
w.int32(len(scOut))
w.bytes(scOut)
cn.send(w)
t, r := cn.recv()
if t != 'R' {
errorf("unexpected password response: %q", t)
}
if r.int32() != 11 {
errorf("unexpected authentication response: %q", t)
}
nextStep := r.next(len(*r))
sc.Step(nextStep)
if sc.Err() != nil {
errorf("SCRAM-SHA-256 error: %s", sc.Err().Error())
}
scOut = sc.Out()
w = cn.writeBuf('p')
w.bytes(scOut)
cn.send(w)
t, r = cn.recv()
if t != 'R' {
errorf("unexpected password response: %q", t)
}
if r.int32() != 12 {
errorf("unexpected authentication response: %q", t)
}
nextStep = r.next(len(*r))
sc.Step(nextStep)
if sc.Err() != nil {
errorf("SCRAM-SHA-256 error: %s", sc.Err().Error())
}
default:
errorf("unknown authentication response: %d", code)
}
}
type format int
const formatText format = 0
const formatBinary format = 1
// One result-column format code with the value 1 (i.e. all binary).
var colFmtDataAllBinary = []byte{0, 1, 0, 1}
// No result-column format codes (i.e. all text).
var colFmtDataAllText = []byte{0, 0}
type stmt struct {
cn *conn
name string
rowsHeader
colFmtData []byte
paramTyps []oid.Oid
closed bool
}
func (st *stmt) Close() (err error) {
if st.closed {
return nil
}
if st.cn.getBad() {
return driver.ErrBadConn
}
defer st.cn.errRecover(&err)
w := st.cn.writeBuf('C')
w.byte('S')
w.string(st.name)
st.cn.send(w)
st.cn.send(st.cn.writeBuf('S'))
t, _ := st.cn.recv1()
if t != '3' {
st.cn.setBad()
errorf("unexpected close response: %q", t)
}
st.closed = true
t, r := st.cn.recv1()
if t != 'Z' {
st.cn.setBad()
errorf("expected ready for query, but got: %q", t)
}
st.cn.processReadyForQuery(r)
return nil
}
func (st *stmt) Query(v []driver.Value) (r driver.Rows, err error) {
if st.cn.getBad() {
return nil, driver.ErrBadConn
}
defer st.cn.errRecover(&err)
st.exec(v)
return &rows{
cn: st.cn,
rowsHeader: st.rowsHeader,
}, nil
}
func (st *stmt) Exec(v []driver.Value) (res driver.Result, err error) {
if st.cn.getBad() {
return nil, driver.ErrBadConn
}
defer st.cn.errRecover(&err)
st.exec(v)
res, _, err = st.cn.readExecuteResponse("simple query")
return res, err
}
func (st *stmt) exec(v []driver.Value) {
if len(v) >= 65536 {
errorf("got %d parameters but PostgreSQL only supports 65535 parameters", len(v))
}
if len(v) != len(st.paramTyps) {
errorf("got %d parameters but the statement requires %d", len(v), len(st.paramTyps))
}
cn := st.cn
w := cn.writeBuf('B')
w.byte(0) // unnamed portal
w.string(st.name)
if cn.binaryParameters {
cn.sendBinaryParameters(w, v)
} else {
w.int16(0)
w.int16(len(v))
for i, x := range v {
if x == nil {
w.int32(-1)
} else {
b := encode(&cn.parameterStatus, x, st.paramTyps[i])
w.int32(len(b))
w.bytes(b)
}
}
}
w.bytes(st.colFmtData)
w.next('E')
w.byte(0)
w.int32(0)
w.next('S')
cn.send(w)
cn.readBindResponse()
cn.postExecuteWorkaround()
}
func (st *stmt) NumInput() int {
return len(st.paramTyps)
}
// parseComplete parses the "command tag" from a CommandComplete message, and
// returns the number of rows affected (if applicable) and a string
// identifying only the command that was executed, e.g. "ALTER TABLE". If the
// command tag could not be parsed, parseComplete panics.
func (cn *conn) parseComplete(commandTag string) (driver.Result, string) {
commandsWithAffectedRows := []string{
"SELECT ",
// INSERT is handled below
"UPDATE ",
"DELETE ",
"FETCH ",
"MOVE ",
"COPY ",
}
var affectedRows *string
for _, tag := range commandsWithAffectedRows {
if strings.HasPrefix(commandTag, tag) {
t := commandTag[len(tag):]
affectedRows = &t
commandTag = tag[:len(tag)-1]
break
}
}
// INSERT also includes the oid of the inserted row in its command tag.
// Oids in user tables are deprecated, and the oid is only returned when
// exactly one row is inserted, so it's unlikely to be of value to any
// real-world application and we can ignore it.
if affectedRows == nil && strings.HasPrefix(commandTag, "INSERT ") {
parts := strings.Split(commandTag, " ")
if len(parts) != 3 {
cn.setBad()
errorf("unexpected INSERT command tag %s", commandTag)
}
affectedRows = &parts[len(parts)-1]
commandTag = "INSERT"
}
// There should be no affected rows attached to the tag, just return it
if affectedRows == nil {
return driver.RowsAffected(0), commandTag
}
n, err := strconv.ParseInt(*affectedRows, 10, 64)
if err != nil {
cn.setBad()
errorf("could not parse commandTag: %s", err)
}
return driver.RowsAffected(n), commandTag
}
type rowsHeader struct {
colNames []string
colTyps []fieldDesc
colFmts []format
}
type rows struct {
cn *conn
finish func()
rowsHeader
done bool
rb readBuf
result driver.Result
tag string
next *rowsHeader
}
func (rs *rows) Close() error {
if finish := rs.finish; finish != nil {
defer finish()
}
// no need to look at cn.bad as Next() will
for {
err := rs.Next(nil)
switch err {
case nil:
case io.EOF:
// rs.Next can return io.EOF on both 'Z' (ready for query) and 'T' (row
// description, used with HasNextResultSet). We need to fetch messages until
// we hit a 'Z', which is done by waiting for done to be set.
if rs.done {
return nil
}
default:
return err
}
}
}
func (rs *rows) Columns() []string {
return rs.colNames
}
func (rs *rows) Result() driver.Result {
if rs.result == nil {
return emptyRows
}
return rs.result
}
func (rs *rows) Tag() string {
return rs.tag
}
func (rs *rows) Next(dest []driver.Value) (err error) {
if rs.done {
return io.EOF
}
conn := rs.cn
if conn.getBad() {
return driver.ErrBadConn
}
defer conn.errRecover(&err)
for {
t := conn.recv1Buf(&rs.rb)
switch t {
case 'E':
err = parseError(&rs.rb)
case 'C', 'I':
if t == 'C' {
rs.result, rs.tag = conn.parseComplete(rs.rb.string())
}
continue
case 'Z':
conn.processReadyForQuery(&rs.rb)
rs.done = true
if err != nil {
return err
}
return io.EOF
case 'D':
n := rs.rb.int16()
if err != nil {
conn.setBad()
errorf("unexpected DataRow after error %s", err)
}
if n < len(dest) {
dest = dest[:n]
}
for i := range dest {
l := rs.rb.int32()
if l == -1 {
dest[i] = nil
continue
}
dest[i] = decode(&conn.parameterStatus, rs.rb.next(l), rs.colTyps[i].OID, rs.colFmts[i])
}
return
case 'T':
next := parsePortalRowDescribe(&rs.rb)
rs.next = &next
return io.EOF
default:
errorf("unexpected message after execute: %q", t)
}
}
}
func (rs *rows) HasNextResultSet() bool {
hasNext := rs.next != nil && !rs.done
return hasNext
}
func (rs *rows) NextResultSet() error {
if rs.next == nil {
return io.EOF
}
rs.rowsHeader = *rs.next
rs.next = nil
return nil
}
// QuoteIdentifier quotes an "identifier" (e.g. a table or a column name) to be
// used as part of an SQL statement. For example:
//
// tblname := "my_table"
// data := "my_data"
// quoted := pq.QuoteIdentifier(tblname)
// err := db.Exec(fmt.Sprintf("INSERT INTO %s VALUES ($1)", quoted), data)
//
// Any double quotes in name will be escaped. The quoted identifier will be
// case sensitive when used in a query. If the input string contains a zero
// byte, the result will be truncated immediately before it.
func QuoteIdentifier(name string) string {
end := strings.IndexRune(name, 0)
if end > -1 {
name = name[:end]
}
return `"` + strings.Replace(name, `"`, `""`, -1) + `"`
}
// QuoteLiteral quotes a 'literal' (e.g. a parameter, often used to pass literal
// to DDL and other statements that do not accept parameters) to be used as part
// of an SQL statement. For example:
//
// exp_date := pq.QuoteLiteral("2023-01-05 15:00:00Z")
// err := db.Exec(fmt.Sprintf("CREATE ROLE my_user VALID UNTIL %s", exp_date))
//
// Any single quotes in name will be escaped. Any backslashes (i.e. "\") will be
// replaced by two backslashes (i.e. "\\") and the C-style escape identifier
// that PostgreSQL provides ('E') will be prepended to the string.
func QuoteLiteral(literal string) string {
// This follows the PostgreSQL internal algorithm for handling quoted literals
// from libpq, which can be found in the "PQEscapeStringInternal" function,
// which is found in the libpq/fe-exec.c source file:
// https://git.postgresql.org/gitweb/?p=postgresql.git;a=blob;f=src/interfaces/libpq/fe-exec.c
//
// substitute any single-quotes (') with two single-quotes ('')
literal = strings.Replace(literal, `'`, `''`, -1)
// determine if the string has any backslashes (\) in it.
// if it does, replace any backslashes (\) with two backslashes (\\)
// then, we need to wrap the entire string with a PostgreSQL
// C-style escape. Per how "PQEscapeStringInternal" handles this case, we
// also add a space before the "E"
if strings.Contains(literal, `\`) {
literal = strings.Replace(literal, `\`, `\\`, -1)
literal = ` E'` + literal + `'`
} else {
// otherwise, we can just wrap the literal with a pair of single quotes
literal = `'` + literal + `'`
}
return literal
}
func md5s(s string) string {
h := md5.New()
h.Write([]byte(s))
return fmt.Sprintf("%x", h.Sum(nil))
}
func (cn *conn) sendBinaryParameters(b *writeBuf, args []driver.Value) {
// Do one pass over the parameters to see if we're going to send any of
// them over in binary. If we are, create a paramFormats array at the
// same time.
var paramFormats []int
for i, x := range args {
_, ok := x.([]byte)
if ok {
if paramFormats == nil {
paramFormats = make([]int, len(args))
}
paramFormats[i] = 1
}
}
if paramFormats == nil {
b.int16(0)
} else {
b.int16(len(paramFormats))
for _, x := range paramFormats {
b.int16(x)
}
}
b.int16(len(args))
for _, x := range args {
if x == nil {
b.int32(-1)
} else {
datum := binaryEncode(&cn.parameterStatus, x)
b.int32(len(datum))
b.bytes(datum)
}
}
}
func (cn *conn) sendBinaryModeQuery(query string, args []driver.Value) {
if len(args) >= 65536 {
errorf("got %d parameters but PostgreSQL only supports 65535 parameters", len(args))
}
b := cn.writeBuf('P')
b.byte(0) // unnamed statement
b.string(query)
b.int16(0)
b.next('B')
b.int16(0) // unnamed portal and statement
cn.sendBinaryParameters(b, args)
b.bytes(colFmtDataAllText)
b.next('D')
b.byte('P')
b.byte(0) // unnamed portal
b.next('E')
b.byte(0)
b.int32(0)
b.next('S')
cn.send(b)
}
func (cn *conn) processParameterStatus(r *readBuf) {
var err error
param := r.string()
switch param {
case "server_version":
var major1 int
var major2 int
var minor int
_, err = fmt.Sscanf(r.string(), "%d.%d.%d", &major1, &major2, &minor)
if err == nil {
cn.parameterStatus.serverVersion = major1*10000 + major2*100 + minor
}
case "TimeZone":
cn.parameterStatus.currentLocation, err = time.LoadLocation(r.string())
if err != nil {
cn.parameterStatus.currentLocation = nil
}
default:
// ignore
}
}
func (cn *conn) processReadyForQuery(r *readBuf) {
cn.txnStatus = transactionStatus(r.byte())
}
func (cn *conn) readReadyForQuery() {
t, r := cn.recv1()
switch t {
case 'Z':
cn.processReadyForQuery(r)
return
default:
cn.setBad()
errorf("unexpected message %q; expected ReadyForQuery", t)
}
}
func (cn *conn) processBackendKeyData(r *readBuf) {
cn.processID = r.int32()
cn.secretKey = r.int32()
}
func (cn *conn) readParseResponse() {
t, r := cn.recv1()
switch t {
case '1':
return
case 'E':
err := parseError(r)
cn.readReadyForQuery()
panic(err)
default:
cn.setBad()
errorf("unexpected Parse response %q", t)
}
}
func (cn *conn) readStatementDescribeResponse() (paramTyps []oid.Oid, colNames []string, colTyps []fieldDesc) {
for {
t, r := cn.recv1()
switch t {
case 't':
nparams := r.int16()
paramTyps = make([]oid.Oid, nparams)
for i := range paramTyps {
paramTyps[i] = r.oid()
}
case 'n':
return paramTyps, nil, nil
case 'T':
colNames, colTyps = parseStatementRowDescribe(r)
return paramTyps, colNames, colTyps
case 'E':
err := parseError(r)
cn.readReadyForQuery()
panic(err)
default:
cn.setBad()
errorf("unexpected Describe statement response %q", t)
}
}
}
func (cn *conn) readPortalDescribeResponse() rowsHeader {
t, r := cn.recv1()
switch t {
case 'T':
return parsePortalRowDescribe(r)
case 'n':
return rowsHeader{}
case 'E':
err := parseError(r)
cn.readReadyForQuery()
panic(err)
default:
cn.setBad()
errorf("unexpected Describe response %q", t)
}
panic("not reached")
}
func (cn *conn) readBindResponse() {
t, r := cn.recv1()
switch t {
case '2':
return
case 'E':
err := parseError(r)
cn.readReadyForQuery()
panic(err)
default:
cn.setBad()
errorf("unexpected Bind response %q", t)
}
}
func (cn *conn) postExecuteWorkaround() {
// Work around a bug in sql.DB.QueryRow: in Go 1.2 and earlier it ignores
// any errors from rows.Next, which masks errors that happened during the
// execution of the query. To avoid the problem in common cases, we wait
// here for one more message from the database. If it's not an error the
// query will likely succeed (or perhaps has already, if it's a
// CommandComplete), so we push the message into the conn struct; recv1
// will return it as the next message for rows.Next or rows.Close.
// However, if it's an error, we wait until ReadyForQuery and then return
// the error to our caller.
for {
t, r := cn.recv1()
switch t {
case 'E':
err := parseError(r)
cn.readReadyForQuery()
panic(err)
case 'C', 'D', 'I':
// the query didn't fail, but we can't process this message
cn.saveMessage(t, r)
return
default:
cn.setBad()
errorf("unexpected message during extended query execution: %q", t)
}
}
}
// Only for Exec(), since we ignore the returned data
func (cn *conn) readExecuteResponse(protocolState string) (res driver.Result, commandTag string, err error) {
for {
t, r := cn.recv1()
switch t {
case 'C':
if err != nil {
cn.setBad()
errorf("unexpected CommandComplete after error %s", err)
}
res, commandTag = cn.parseComplete(r.string())
case 'Z':
cn.processReadyForQuery(r)
if res == nil && err == nil {
err = errUnexpectedReady
}
return res, commandTag, err
case 'E':
err = parseError(r)
case 'T', 'D', 'I':
if err != nil {
cn.setBad()
errorf("unexpected %q after error %s", t, err)
}
if t == 'I' {
res = emptyRows
}
// ignore any results
default:
cn.setBad()
errorf("unknown %s response: %q", protocolState, t)
}
}
}
func parseStatementRowDescribe(r *readBuf) (colNames []string, colTyps []fieldDesc) {
n := r.int16()
colNames = make([]string, n)
colTyps = make([]fieldDesc, n)
for i := range colNames {
colNames[i] = r.string()
r.next(6)
colTyps[i].OID = r.oid()
colTyps[i].Len = r.int16()
colTyps[i].Mod = r.int32()
// format code not known when describing a statement; always 0
r.next(2)
}
return
}
func parsePortalRowDescribe(r *readBuf) rowsHeader {
n := r.int16()
colNames := make([]string, n)
colFmts := make([]format, n)
colTyps := make([]fieldDesc, n)
for i := range colNames {
colNames[i] = r.string()
r.next(6)
colTyps[i].OID = r.oid()
colTyps[i].Len = r.int16()
colTyps[i].Mod = r.int32()
colFmts[i] = format(r.int16())
}
return rowsHeader{
colNames: colNames,
colFmts: colFmts,
colTyps: colTyps,
}
}
// parseEnviron tries to mimic some of libpq's environment handling
//
// To ease testing, it does not directly reference os.Environ, but is
// designed to accept its output.
//
// Environment-set connection information is intended to have a higher
// precedence than a library default but lower than any explicitly
// passed information (such as in the URL or connection string).
func parseEnviron(env []string) (out map[string]string) {
out = make(map[string]string)
for _, v := range env {
parts := strings.SplitN(v, "=", 2)
accrue := func(keyname string) {
out[keyname] = parts[1]
}
unsupported := func() {
panic(fmt.Sprintf("setting %v not supported", parts[0]))
}
// The order of these is the same as is seen in the
// PostgreSQL 9.1 manual. Unsupported but well-defined
// keys cause a panic; these should be unset prior to
// execution. Options which pq expects to be set to a
// certain value are allowed, but must be set to that
// value if present (they can, of course, be absent).
switch parts[0] {
case "PGHOST":
accrue("host")
case "PGHOSTADDR":
unsupported()
case "PGPORT":
accrue("port")
case "PGDATABASE":
accrue("dbname")
case "PGUSER":
accrue("user")
case "PGPASSWORD":
accrue("password")
case "PGSERVICE", "PGSERVICEFILE", "PGREALM":
unsupported()
case "PGOPTIONS":
accrue("options")
case "PGAPPNAME":
accrue("application_name")
case "PGSSLMODE":
accrue("sslmode")
case "PGSSLCERT":
accrue("sslcert")
case "PGSSLKEY":
accrue("sslkey")
case "PGSSLROOTCERT":
accrue("sslrootcert")
case "PGREQUIRESSL", "PGSSLCRL":
unsupported()
case "PGREQUIREPEER":
unsupported()
case "PGKRBSRVNAME", "PGGSSLIB":
unsupported()
case "PGCONNECT_TIMEOUT":
accrue("connect_timeout")
case "PGCLIENTENCODING":
accrue("client_encoding")
case "PGDATESTYLE":
accrue("datestyle")
case "PGTZ":
accrue("timezone")
case "PGGEQO":
accrue("geqo")
case "PGSYSCONFDIR", "PGLOCALEDIR":
unsupported()
}
}
return out
}
// isUTF8 returns whether name is a fuzzy variation of the string "UTF-8".
func isUTF8(name string) bool {
// Recognize all sorts of silly things as "UTF-8", like Postgres does
s := strings.Map(alnumLowerASCII, name)
return s == "utf8" || s == "unicode"
}
func alnumLowerASCII(ch rune) rune {
if 'A' <= ch && ch <= 'Z' {
return ch + ('a' - 'A')
}
if 'a' <= ch && ch <= 'z' || '0' <= ch && ch <= '9' {
return ch
}
return -1 // discard
}