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- package pq
-
- import (
- "bytes"
- "database/sql/driver"
- "encoding/binary"
- "encoding/hex"
- "errors"
- "fmt"
- "math"
- "strconv"
- "strings"
- "sync"
- "time"
-
- "github.com/lib/pq/oid"
- )
-
- func binaryEncode(parameterStatus *parameterStatus, x interface{}) []byte {
- switch v := x.(type) {
- case []byte:
- return v
- default:
- return encode(parameterStatus, x, oid.T_unknown)
- }
- }
-
- func encode(parameterStatus *parameterStatus, x interface{}, pgtypOid oid.Oid) []byte {
- switch v := x.(type) {
- case int64:
- return strconv.AppendInt(nil, v, 10)
- case float64:
- return strconv.AppendFloat(nil, v, 'f', -1, 64)
- case []byte:
- if pgtypOid == oid.T_bytea {
- return encodeBytea(parameterStatus.serverVersion, v)
- }
-
- return v
- case string:
- if pgtypOid == oid.T_bytea {
- return encodeBytea(parameterStatus.serverVersion, []byte(v))
- }
-
- return []byte(v)
- case bool:
- return strconv.AppendBool(nil, v)
- case time.Time:
- return formatTs(v)
-
- default:
- errorf("encode: unknown type for %T", v)
- }
-
- panic("not reached")
- }
-
- func decode(parameterStatus *parameterStatus, s []byte, typ oid.Oid, f format) interface{} {
- switch f {
- case formatBinary:
- return binaryDecode(parameterStatus, s, typ)
- case formatText:
- return textDecode(parameterStatus, s, typ)
- default:
- panic("not reached")
- }
- }
-
- func binaryDecode(parameterStatus *parameterStatus, s []byte, typ oid.Oid) interface{} {
- switch typ {
- case oid.T_bytea:
- return s
- case oid.T_int8:
- return int64(binary.BigEndian.Uint64(s))
- case oid.T_int4:
- return int64(int32(binary.BigEndian.Uint32(s)))
- case oid.T_int2:
- return int64(int16(binary.BigEndian.Uint16(s)))
- case oid.T_uuid:
- b, err := decodeUUIDBinary(s)
- if err != nil {
- panic(err)
- }
- return b
-
- default:
- errorf("don't know how to decode binary parameter of type %d", uint32(typ))
- }
-
- panic("not reached")
- }
-
- func textDecode(parameterStatus *parameterStatus, s []byte, typ oid.Oid) interface{} {
- switch typ {
- case oid.T_char, oid.T_varchar, oid.T_text:
- return string(s)
- case oid.T_bytea:
- b, err := parseBytea(s)
- if err != nil {
- errorf("%s", err)
- }
- return b
- case oid.T_timestamptz:
- return parseTs(parameterStatus.currentLocation, string(s))
- case oid.T_timestamp, oid.T_date:
- return parseTs(nil, string(s))
- case oid.T_time:
- return mustParse("15:04:05", typ, s)
- case oid.T_timetz:
- return mustParse("15:04:05-07", typ, s)
- case oid.T_bool:
- return s[0] == 't'
- case oid.T_int8, oid.T_int4, oid.T_int2:
- i, err := strconv.ParseInt(string(s), 10, 64)
- if err != nil {
- errorf("%s", err)
- }
- return i
- case oid.T_float4, oid.T_float8:
- // We always use 64 bit parsing, regardless of whether the input text is for
- // a float4 or float8, because clients expect float64s for all float datatypes
- // and returning a 32-bit parsed float64 produces lossy results.
- f, err := strconv.ParseFloat(string(s), 64)
- if err != nil {
- errorf("%s", err)
- }
- return f
- }
-
- return s
- }
-
- // appendEncodedText encodes item in text format as required by COPY
- // and appends to buf
- func appendEncodedText(parameterStatus *parameterStatus, buf []byte, x interface{}) []byte {
- switch v := x.(type) {
- case int64:
- return strconv.AppendInt(buf, v, 10)
- case float64:
- return strconv.AppendFloat(buf, v, 'f', -1, 64)
- case []byte:
- encodedBytea := encodeBytea(parameterStatus.serverVersion, v)
- return appendEscapedText(buf, string(encodedBytea))
- case string:
- return appendEscapedText(buf, v)
- case bool:
- return strconv.AppendBool(buf, v)
- case time.Time:
- return append(buf, formatTs(v)...)
- case nil:
- return append(buf, "\\N"...)
- default:
- errorf("encode: unknown type for %T", v)
- }
-
- panic("not reached")
- }
-
- func appendEscapedText(buf []byte, text string) []byte {
- escapeNeeded := false
- startPos := 0
- var c byte
-
- // check if we need to escape
- for i := 0; i < len(text); i++ {
- c = text[i]
- if c == '\\' || c == '\n' || c == '\r' || c == '\t' {
- escapeNeeded = true
- startPos = i
- break
- }
- }
- if !escapeNeeded {
- return append(buf, text...)
- }
-
- // copy till first char to escape, iterate the rest
- result := append(buf, text[:startPos]...)
- for i := startPos; i < len(text); i++ {
- c = text[i]
- switch c {
- case '\\':
- result = append(result, '\\', '\\')
- case '\n':
- result = append(result, '\\', 'n')
- case '\r':
- result = append(result, '\\', 'r')
- case '\t':
- result = append(result, '\\', 't')
- default:
- result = append(result, c)
- }
- }
- return result
- }
-
- func mustParse(f string, typ oid.Oid, s []byte) time.Time {
- str := string(s)
-
- // check for a 30-minute-offset timezone
- if (typ == oid.T_timestamptz || typ == oid.T_timetz) &&
- str[len(str)-3] == ':' {
- f += ":00"
- }
- t, err := time.Parse(f, str)
- if err != nil {
- errorf("decode: %s", err)
- }
- return t
- }
-
- var errInvalidTimestamp = errors.New("invalid timestamp")
-
- type timestampParser struct {
- err error
- }
-
- func (p *timestampParser) expect(str string, char byte, pos int) {
- if p.err != nil {
- return
- }
- if pos+1 > len(str) {
- p.err = errInvalidTimestamp
- return
- }
- if c := str[pos]; c != char && p.err == nil {
- p.err = fmt.Errorf("expected '%v' at position %v; got '%v'", char, pos, c)
- }
- }
-
- func (p *timestampParser) mustAtoi(str string, begin int, end int) int {
- if p.err != nil {
- return 0
- }
- if begin < 0 || end < 0 || begin > end || end > len(str) {
- p.err = errInvalidTimestamp
- return 0
- }
- result, err := strconv.Atoi(str[begin:end])
- if err != nil {
- if p.err == nil {
- p.err = fmt.Errorf("expected number; got '%v'", str)
- }
- return 0
- }
- return result
- }
-
- // The location cache caches the time zones typically used by the client.
- type locationCache struct {
- cache map[int]*time.Location
- lock sync.Mutex
- }
-
- // All connections share the same list of timezones. Benchmarking shows that
- // about 5% speed could be gained by putting the cache in the connection and
- // losing the mutex, at the cost of a small amount of memory and a somewhat
- // significant increase in code complexity.
- var globalLocationCache = newLocationCache()
-
- func newLocationCache() *locationCache {
- return &locationCache{cache: make(map[int]*time.Location)}
- }
-
- // Returns the cached timezone for the specified offset, creating and caching
- // it if necessary.
- func (c *locationCache) getLocation(offset int) *time.Location {
- c.lock.Lock()
- defer c.lock.Unlock()
-
- location, ok := c.cache[offset]
- if !ok {
- location = time.FixedZone("", offset)
- c.cache[offset] = location
- }
-
- return location
- }
-
- var infinityTsEnabled = false
- var infinityTsNegative time.Time
- var infinityTsPositive time.Time
-
- const (
- infinityTsEnabledAlready = "pq: infinity timestamp enabled already"
- infinityTsNegativeMustBeSmaller = "pq: infinity timestamp: negative value must be smaller (before) than positive"
- )
-
- // EnableInfinityTs controls the handling of Postgres' "-infinity" and
- // "infinity" "timestamp"s.
- //
- // If EnableInfinityTs is not called, "-infinity" and "infinity" will return
- // []byte("-infinity") and []byte("infinity") respectively, and potentially
- // cause error "sql: Scan error on column index 0: unsupported driver -> Scan
- // pair: []uint8 -> *time.Time", when scanning into a time.Time value.
- //
- // Once EnableInfinityTs has been called, all connections created using this
- // driver will decode Postgres' "-infinity" and "infinity" for "timestamp",
- // "timestamp with time zone" and "date" types to the predefined minimum and
- // maximum times, respectively. When encoding time.Time values, any time which
- // equals or precedes the predefined minimum time will be encoded to
- // "-infinity". Any values at or past the maximum time will similarly be
- // encoded to "infinity".
- //
- // If EnableInfinityTs is called with negative >= positive, it will panic.
- // Calling EnableInfinityTs after a connection has been established results in
- // undefined behavior. If EnableInfinityTs is called more than once, it will
- // panic.
- func EnableInfinityTs(negative time.Time, positive time.Time) {
- if infinityTsEnabled {
- panic(infinityTsEnabledAlready)
- }
- if !negative.Before(positive) {
- panic(infinityTsNegativeMustBeSmaller)
- }
- infinityTsEnabled = true
- infinityTsNegative = negative
- infinityTsPositive = positive
- }
-
- /*
- * Testing might want to toggle infinityTsEnabled
- */
- func disableInfinityTs() {
- infinityTsEnabled = false
- }
-
- // This is a time function specific to the Postgres default DateStyle
- // setting ("ISO, MDY"), the only one we currently support. This
- // accounts for the discrepancies between the parsing available with
- // time.Parse and the Postgres date formatting quirks.
- func parseTs(currentLocation *time.Location, str string) interface{} {
- switch str {
- case "-infinity":
- if infinityTsEnabled {
- return infinityTsNegative
- }
- return []byte(str)
- case "infinity":
- if infinityTsEnabled {
- return infinityTsPositive
- }
- return []byte(str)
- }
- t, err := ParseTimestamp(currentLocation, str)
- if err != nil {
- panic(err)
- }
- return t
- }
-
- // ParseTimestamp parses Postgres' text format. It returns a time.Time in
- // currentLocation iff that time's offset agrees with the offset sent from the
- // Postgres server. Otherwise, ParseTimestamp returns a time.Time with the
- // fixed offset offset provided by the Postgres server.
- func ParseTimestamp(currentLocation *time.Location, str string) (time.Time, error) {
- p := timestampParser{}
-
- monSep := strings.IndexRune(str, '-')
- // this is Gregorian year, not ISO Year
- // In Gregorian system, the year 1 BC is followed by AD 1
- year := p.mustAtoi(str, 0, monSep)
- daySep := monSep + 3
- month := p.mustAtoi(str, monSep+1, daySep)
- p.expect(str, '-', daySep)
- timeSep := daySep + 3
- day := p.mustAtoi(str, daySep+1, timeSep)
-
- minLen := monSep + len("01-01") + 1
-
- isBC := strings.HasSuffix(str, " BC")
- if isBC {
- minLen += 3
- }
-
- var hour, minute, second int
- if len(str) > minLen {
- p.expect(str, ' ', timeSep)
- minSep := timeSep + 3
- p.expect(str, ':', minSep)
- hour = p.mustAtoi(str, timeSep+1, minSep)
- secSep := minSep + 3
- p.expect(str, ':', secSep)
- minute = p.mustAtoi(str, minSep+1, secSep)
- secEnd := secSep + 3
- second = p.mustAtoi(str, secSep+1, secEnd)
- }
- remainderIdx := monSep + len("01-01 00:00:00") + 1
- // Three optional (but ordered) sections follow: the
- // fractional seconds, the time zone offset, and the BC
- // designation. We set them up here and adjust the other
- // offsets if the preceding sections exist.
-
- nanoSec := 0
- tzOff := 0
-
- if remainderIdx < len(str) && str[remainderIdx] == '.' {
- fracStart := remainderIdx + 1
- fracOff := strings.IndexAny(str[fracStart:], "-+ ")
- if fracOff < 0 {
- fracOff = len(str) - fracStart
- }
- fracSec := p.mustAtoi(str, fracStart, fracStart+fracOff)
- nanoSec = fracSec * (1000000000 / int(math.Pow(10, float64(fracOff))))
-
- remainderIdx += fracOff + 1
- }
- if tzStart := remainderIdx; tzStart < len(str) && (str[tzStart] == '-' || str[tzStart] == '+') {
- // time zone separator is always '-' or '+' (UTC is +00)
- var tzSign int
- switch c := str[tzStart]; c {
- case '-':
- tzSign = -1
- case '+':
- tzSign = +1
- default:
- return time.Time{}, fmt.Errorf("expected '-' or '+' at position %v; got %v", tzStart, c)
- }
- tzHours := p.mustAtoi(str, tzStart+1, tzStart+3)
- remainderIdx += 3
- var tzMin, tzSec int
- if remainderIdx < len(str) && str[remainderIdx] == ':' {
- tzMin = p.mustAtoi(str, remainderIdx+1, remainderIdx+3)
- remainderIdx += 3
- }
- if remainderIdx < len(str) && str[remainderIdx] == ':' {
- tzSec = p.mustAtoi(str, remainderIdx+1, remainderIdx+3)
- remainderIdx += 3
- }
- tzOff = tzSign * ((tzHours * 60 * 60) + (tzMin * 60) + tzSec)
- }
- var isoYear int
-
- if isBC {
- isoYear = 1 - year
- remainderIdx += 3
- } else {
- isoYear = year
- }
- if remainderIdx < len(str) {
- return time.Time{}, fmt.Errorf("expected end of input, got %v", str[remainderIdx:])
- }
- t := time.Date(isoYear, time.Month(month), day,
- hour, minute, second, nanoSec,
- globalLocationCache.getLocation(tzOff))
-
- if currentLocation != nil {
- // Set the location of the returned Time based on the session's
- // TimeZone value, but only if the local time zone database agrees with
- // the remote database on the offset.
- lt := t.In(currentLocation)
- _, newOff := lt.Zone()
- if newOff == tzOff {
- t = lt
- }
- }
-
- return t, p.err
- }
-
- // formatTs formats t into a format postgres understands.
- func formatTs(t time.Time) []byte {
- if infinityTsEnabled {
- // t <= -infinity : ! (t > -infinity)
- if !t.After(infinityTsNegative) {
- return []byte("-infinity")
- }
- // t >= infinity : ! (!t < infinity)
- if !t.Before(infinityTsPositive) {
- return []byte("infinity")
- }
- }
- return FormatTimestamp(t)
- }
-
- // FormatTimestamp formats t into Postgres' text format for timestamps.
- func FormatTimestamp(t time.Time) []byte {
- // Need to send dates before 0001 A.D. with " BC" suffix, instead of the
- // minus sign preferred by Go.
- // Beware, "0000" in ISO is "1 BC", "-0001" is "2 BC" and so on
- bc := false
- if t.Year() <= 0 {
- // flip year sign, and add 1, e.g: "0" will be "1", and "-10" will be "11"
- t = t.AddDate((-t.Year())*2+1, 0, 0)
- bc = true
- }
- b := []byte(t.Format("2006-01-02 15:04:05.999999999Z07:00"))
-
- _, offset := t.Zone()
- offset = offset % 60
- if offset != 0 {
- // RFC3339Nano already printed the minus sign
- if offset < 0 {
- offset = -offset
- }
-
- b = append(b, ':')
- if offset < 10 {
- b = append(b, '0')
- }
- b = strconv.AppendInt(b, int64(offset), 10)
- }
-
- if bc {
- b = append(b, " BC"...)
- }
- return b
- }
-
- // Parse a bytea value received from the server. Both "hex" and the legacy
- // "escape" format are supported.
- func parseBytea(s []byte) (result []byte, err error) {
- if len(s) >= 2 && bytes.Equal(s[:2], []byte("\\x")) {
- // bytea_output = hex
- s = s[2:] // trim off leading "\\x"
- result = make([]byte, hex.DecodedLen(len(s)))
- _, err := hex.Decode(result, s)
- if err != nil {
- return nil, err
- }
- } else {
- // bytea_output = escape
- for len(s) > 0 {
- if s[0] == '\\' {
- // escaped '\\'
- if len(s) >= 2 && s[1] == '\\' {
- result = append(result, '\\')
- s = s[2:]
- continue
- }
-
- // '\\' followed by an octal number
- if len(s) < 4 {
- return nil, fmt.Errorf("invalid bytea sequence %v", s)
- }
- r, err := strconv.ParseInt(string(s[1:4]), 8, 9)
- if err != nil {
- return nil, fmt.Errorf("could not parse bytea value: %s", err.Error())
- }
- result = append(result, byte(r))
- s = s[4:]
- } else {
- // We hit an unescaped, raw byte. Try to read in as many as
- // possible in one go.
- i := bytes.IndexByte(s, '\\')
- if i == -1 {
- result = append(result, s...)
- break
- }
- result = append(result, s[:i]...)
- s = s[i:]
- }
- }
- }
-
- return result, nil
- }
-
- func encodeBytea(serverVersion int, v []byte) (result []byte) {
- if serverVersion >= 90000 {
- // Use the hex format if we know that the server supports it
- result = make([]byte, 2+hex.EncodedLen(len(v)))
- result[0] = '\\'
- result[1] = 'x'
- hex.Encode(result[2:], v)
- } else {
- // .. or resort to "escape"
- for _, b := range v {
- if b == '\\' {
- result = append(result, '\\', '\\')
- } else if b < 0x20 || b > 0x7e {
- result = append(result, []byte(fmt.Sprintf("\\%03o", b))...)
- } else {
- result = append(result, b)
- }
- }
- }
-
- return result
- }
-
- // NullTime represents a time.Time that may be null. NullTime implements the
- // sql.Scanner interface so it can be used as a scan destination, similar to
- // sql.NullString.
- type NullTime struct {
- Time time.Time
- Valid bool // Valid is true if Time is not NULL
- }
-
- // Scan implements the Scanner interface.
- func (nt *NullTime) Scan(value interface{}) error {
- nt.Time, nt.Valid = value.(time.Time)
- return nil
- }
-
- // Value implements the driver Valuer interface.
- func (nt NullTime) Value() (driver.Value, error) {
- if !nt.Valid {
- return nil, nil
- }
- return nt.Time, nil
- }
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