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chunk.go
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chunk.go
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// Copyright (c) 2018-2022 Snowflake Computing Inc. All rights reserved.
package gosnowflake
import (
"bytes"
"fmt"
"io"
"unicode"
"unicode/utf16"
"unicode/utf8"
)
const (
defaultChunkBufferSize int64 = 8 << 10 // 8k
defaultStringBufferSize int64 = 512
)
type largeChunkDecoder struct {
r io.Reader
rows int // hint for number of rows
cells int // hint for number of cells/row
rem int // bytes remaining in rbuf
ptr int // position in rbuf
rbuf []byte
sbuf *bytes.Buffer // buffer for decodeString
ioError error
}
func decodeLargeChunk(r io.Reader, rowCount int, cellCount int) ([][]*string, error) {
logger.Info("custom JSON Decoder")
lcd := largeChunkDecoder{
r, rowCount, cellCount,
0, 0,
make([]byte, defaultChunkBufferSize),
bytes.NewBuffer(make([]byte, defaultStringBufferSize)),
nil,
}
rows, err := lcd.decode()
if lcd.ioError != nil && lcd.ioError != io.EOF {
return nil, lcd.ioError
} else if err != nil {
return nil, err
}
return rows, nil
}
func (lcd *largeChunkDecoder) mkError(s string) error {
return fmt.Errorf("corrupt chunk: %s", s)
}
func (lcd *largeChunkDecoder) decode() ([][]*string, error) {
if lcd.nextByteNonWhitespace() != '[' {
return nil, lcd.mkError("expected chunk to begin with '['")
}
rows := make([][]*string, 0, lcd.rows)
if lcd.nextByteNonWhitespace() == ']' {
return rows, nil // special case of an empty chunk
}
lcd.rewind(1)
OuterLoop:
for {
row, err := lcd.decodeRow()
if err != nil {
return nil, err
}
rows = append(rows, row)
switch c := lcd.nextByteNonWhitespace(); {
case c == ',':
continue // more elements in the array
case c == ']':
return rows, nil // we've scanned the whole chunk
default:
break OuterLoop
}
}
return nil, lcd.mkError("invalid row boundary")
}
func (lcd *largeChunkDecoder) decodeRow() ([]*string, error) {
if lcd.nextByteNonWhitespace() != '[' {
return nil, lcd.mkError("expected row to begin with '['")
}
row := make([]*string, 0, lcd.cells)
if lcd.nextByteNonWhitespace() == ']' {
return row, nil // special case of an empty row
}
lcd.rewind(1)
OuterLoop:
for {
cell, err := lcd.decodeCell()
if err != nil {
return nil, err
}
row = append(row, cell)
switch c := lcd.nextByteNonWhitespace(); {
case c == ',':
continue // more elements in the array
case c == ']':
return row, nil // we've scanned the whole row
default:
break OuterLoop
}
}
return nil, lcd.mkError("invalid cell boundary")
}
func (lcd *largeChunkDecoder) decodeCell() (*string, error) {
c := lcd.nextByteNonWhitespace()
if c == '"' {
s, err := lcd.decodeString()
return &s, err
} else if c == 'n' {
if lcd.nextByte() == 'u' &&
lcd.nextByte() == 'l' &&
lcd.nextByte() == 'l' {
return nil, nil
}
}
return nil, lcd.mkError("cell begins with unexpected byte")
}
// TODO we can optimize this further by optimistically searching
// the read buffer for the next string. If it's short enough and
// doesn't contain any escaped characters, we can construct the
// return string directly without writing to the sbuf
func (lcd *largeChunkDecoder) decodeString() (string, error) {
lcd.sbuf.Reset()
for {
// NOTE if you make changes here, ensure this
// variable does not escape to the heap
c := lcd.nextByte()
if c == '"' {
break
} else if c == '\\' {
if err := lcd.decodeEscaped(); err != nil {
return "", err
}
} else if c < ' ' {
return "", lcd.mkError("unexpected control character")
} else if c < utf8.RuneSelf {
lcd.sbuf.WriteByte(c)
} else {
lcd.rewind(1)
lcd.sbuf.WriteRune(lcd.readRune())
}
}
return lcd.sbuf.String(), nil
}
func (lcd *largeChunkDecoder) decodeEscaped() error {
// NOTE if you make changes here, ensure this
// variable does not escape to the heap
c := lcd.nextByte()
switch c {
case '"', '\\', '/', '\'':
lcd.sbuf.WriteByte(c)
case 'b':
lcd.sbuf.WriteByte('\b')
case 'f':
lcd.sbuf.WriteByte('\f')
case 'n':
lcd.sbuf.WriteByte('\n')
case 'r':
lcd.sbuf.WriteByte('\r')
case 't':
lcd.sbuf.WriteByte('\t')
case 'u':
rr := lcd.getu4()
if rr < 0 {
return lcd.mkError("invalid escape sequence")
}
if utf16.IsSurrogate(rr) {
rr1, size := lcd.getu4WithPrefix()
if dec := utf16.DecodeRune(rr, rr1); dec != unicode.ReplacementChar {
// A valid pair; consume.
lcd.sbuf.WriteRune(dec)
break
}
// Invalid surrogate; fall back to replacement rune.
lcd.rewind(size)
rr = unicode.ReplacementChar
}
lcd.sbuf.WriteRune(rr)
default:
return lcd.mkError("invalid escape sequence: " + string(c))
}
return nil
}
func (lcd *largeChunkDecoder) readRune() rune {
lcd.ensureBytes(4)
r, size := utf8.DecodeRune(lcd.rbuf[lcd.ptr:])
lcd.ptr += size
lcd.rem -= size
return r
}
func (lcd *largeChunkDecoder) getu4WithPrefix() (rune, int) {
lcd.ensureBytes(6)
// NOTE take a snapshot of the cursor state. If this
// is not a valid rune, then we need to roll back to
// where we were before we began consuming bytes
ptr := lcd.ptr
if lcd.nextByte() != '\\' {
return -1, lcd.ptr - ptr
}
if lcd.nextByte() != 'u' {
return -1, lcd.ptr - ptr
}
r := lcd.getu4()
return r, lcd.ptr - ptr
}
func (lcd *largeChunkDecoder) getu4() rune {
var r rune
for i := 0; i < 4; i++ {
c := lcd.nextByte()
switch {
case '0' <= c && c <= '9':
c = c - '0'
case 'a' <= c && c <= 'f':
c = c - 'a' + 10
case 'A' <= c && c <= 'F':
c = c - 'A' + 10
default:
return -1
}
r = r*16 + rune(c)
}
return r
}
func (lcd *largeChunkDecoder) nextByteNonWhitespace() byte {
for {
c := lcd.nextByte()
switch c {
case ' ', '\t', '\n', '\r':
continue
default:
return c
}
}
}
func (lcd *largeChunkDecoder) rewind(n int) {
lcd.ptr -= n
lcd.rem += n
}
func (lcd *largeChunkDecoder) nextByte() byte {
if lcd.rem == 0 {
if lcd.ioError != nil {
return 0
}
lcd.ptr = 0
lcd.rem = lcd.fillBuffer(lcd.rbuf)
if lcd.rem == 0 {
return 0
}
}
b := lcd.rbuf[lcd.ptr]
lcd.ptr++
lcd.rem--
return b
}
func (lcd *largeChunkDecoder) ensureBytes(n int) {
if lcd.rem <= n {
rbuf := make([]byte, defaultChunkBufferSize)
// NOTE when the buffer reads from the stream, there's no
// guarantee that it will actually be filled. As such we
// must use (ptr+rem) to compute the end of the slice.
off := copy(rbuf, lcd.rbuf[lcd.ptr:lcd.ptr+lcd.rem])
add := lcd.fillBuffer(rbuf[off:])
lcd.ptr = 0
lcd.rem += add
lcd.rbuf = rbuf
}
}
func (lcd *largeChunkDecoder) fillBuffer(b []byte) int {
n, err := lcd.r.Read(b)
if err != nil && err != io.EOF {
lcd.ioError = err
return 0
} else if n <= 0 {
lcd.ioError = io.EOF
return 0
}
return n
}