// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package tar // TODO(dsymonds): // - catch more errors (no first header, etc.) import ( "bytes" "errors" "fmt" "io" "path" "sort" "strconv" "strings" "time" ) var ( ErrWriteTooLong = errors.New("archive/tar: write too long") ErrFieldTooLong = errors.New("archive/tar: header field too long") ErrWriteAfterClose = errors.New("archive/tar: write after close") errInvalidHeader = errors.New("archive/tar: header field too long or contains invalid values") ) // A Writer provides sequential writing of a tar archive in POSIX.1 format. // A tar archive consists of a sequence of files. // Call WriteHeader to begin a new file, and then call Write to supply that file's data, // writing at most hdr.Size bytes in total. type Writer struct { w io.Writer err error nb int64 // number of unwritten bytes for current file entry pad int64 // amount of padding to write after current file entry closed bool usedBinary bool // whether the binary numeric field extension was used preferPax bool // use pax header instead of binary numeric header hdrBuff [blockSize]byte // buffer to use in writeHeader when writing a regular header paxHdrBuff [blockSize]byte // buffer to use in writeHeader when writing a pax header } type formatter struct { err error // Last error seen } // NewWriter creates a new Writer writing to w. func NewWriter(w io.Writer) *Writer { return &Writer{w: w} } // Flush finishes writing the current file (optional). func (tw *Writer) Flush() error { if tw.nb > 0 { tw.err = fmt.Errorf("archive/tar: missed writing %d bytes", tw.nb) return tw.err } n := tw.nb + tw.pad for n > 0 && tw.err == nil { nr := n if nr > blockSize { nr = blockSize } var nw int nw, tw.err = tw.w.Write(zeroBlock[0:nr]) n -= int64(nw) } tw.nb = 0 tw.pad = 0 return tw.err } // Write s into b, terminating it with a NUL if there is room. func (f *formatter) formatString(b []byte, s string) { if len(s) > len(b) { f.err = ErrFieldTooLong return } ascii := toASCII(s) copy(b, ascii) if len(ascii) < len(b) { b[len(ascii)] = 0 } } // Encode x as an octal ASCII string and write it into b with leading zeros. func (f *formatter) formatOctal(b []byte, x int64) { s := strconv.FormatInt(x, 8) // leading zeros, but leave room for a NUL. for len(s)+1 < len(b) { s = "0" + s } f.formatString(b, s) } // fitsInBase256 reports whether x can be encoded into n bytes using base-256 // encoding. Unlike octal encoding, base-256 encoding does not require that the // string ends with a NUL character. Thus, all n bytes are available for output. // // If operating in binary mode, this assumes strict GNU binary mode; which means // that the first byte can only be either 0x80 or 0xff. Thus, the first byte is // equivalent to the sign bit in two's complement form. func fitsInBase256(n int, x int64) bool { var binBits = uint(n-1) * 8 return n >= 9 || (x >= -1<= 0; i-- { b[i] = byte(x) x >>= 8 } b[0] |= 0x80 // Highest bit indicates binary format return } f.formatOctal(b, 0) // Last resort, just write zero f.err = ErrFieldTooLong } var ( minTime = time.Unix(0, 0) // There is room for 11 octal digits (33 bits) of mtime. maxTime = minTime.Add((1<<33 - 1) * time.Second) ) // WriteHeader writes hdr and prepares to accept the file's contents. // WriteHeader calls Flush if it is not the first header. // Calling after a Close will return ErrWriteAfterClose. func (tw *Writer) WriteHeader(hdr *Header) error { return tw.writeHeader(hdr, true) } // WriteHeader writes hdr and prepares to accept the file's contents. // WriteHeader calls Flush if it is not the first header. // Calling after a Close will return ErrWriteAfterClose. // As this method is called internally by writePax header to allow it to // suppress writing the pax header. func (tw *Writer) writeHeader(hdr *Header, allowPax bool) error { if tw.closed { return ErrWriteAfterClose } if tw.err == nil { tw.Flush() } if tw.err != nil { return tw.err } // a map to hold pax header records, if any are needed paxHeaders := make(map[string]string) // TODO(shanemhansen): we might want to use PAX headers for // subsecond time resolution, but for now let's just capture // too long fields or non ascii characters var f formatter var header []byte // We need to select which scratch buffer to use carefully, // since this method is called recursively to write PAX headers. // If allowPax is true, this is the non-recursive call, and we will use hdrBuff. // If allowPax is false, we are being called by writePAXHeader, and hdrBuff is // already being used by the non-recursive call, so we must use paxHdrBuff. header = tw.hdrBuff[:] if !allowPax { header = tw.paxHdrBuff[:] } copy(header, zeroBlock) s := slicer(header) // Wrappers around formatter that automatically sets paxHeaders if the // argument extends beyond the capacity of the input byte slice. var formatString = func(b []byte, s string, paxKeyword string) { needsPaxHeader := paxKeyword != paxNone && len(s) > len(b) || !isASCII(s) if needsPaxHeader { paxHeaders[paxKeyword] = s return } f.formatString(b, s) } var formatNumeric = func(b []byte, x int64, paxKeyword string) { // Try octal first. s := strconv.FormatInt(x, 8) if len(s) < len(b) { f.formatOctal(b, x) return } // If it is too long for octal, and PAX is preferred, use a PAX header. if paxKeyword != paxNone && tw.preferPax { f.formatOctal(b, 0) s := strconv.FormatInt(x, 10) paxHeaders[paxKeyword] = s return } tw.usedBinary = true f.formatNumeric(b, x) } // keep a reference to the filename to allow to overwrite it later if we detect that we can use ustar longnames instead of pax pathHeaderBytes := s.next(fileNameSize) formatString(pathHeaderBytes, hdr.Name, paxPath) // Handle out of range ModTime carefully. var modTime int64 if !hdr.ModTime.Before(minTime) && !hdr.ModTime.After(maxTime) { modTime = hdr.ModTime.Unix() } f.formatOctal(s.next(8), hdr.Mode) // 100:108 formatNumeric(s.next(8), int64(hdr.Uid), paxUid) // 108:116 formatNumeric(s.next(8), int64(hdr.Gid), paxGid) // 116:124 formatNumeric(s.next(12), hdr.Size, paxSize) // 124:136 formatNumeric(s.next(12), modTime, paxNone) // 136:148 --- consider using pax for finer granularity s.next(8) // chksum (148:156) s.next(1)[0] = hdr.Typeflag // 156:157 formatString(s.next(100), hdr.Linkname, paxLinkpath) copy(s.next(8), []byte("ustar\x0000")) // 257:265 formatString(s.next(32), hdr.Uname, paxUname) // 265:297 formatString(s.next(32), hdr.Gname, paxGname) // 297:329 formatNumeric(s.next(8), hdr.Devmajor, paxNone) // 329:337 formatNumeric(s.next(8), hdr.Devminor, paxNone) // 337:345 // keep a reference to the prefix to allow to overwrite it later if we detect that we can use ustar longnames instead of pax prefixHeaderBytes := s.next(155) formatString(prefixHeaderBytes, "", paxNone) // 345:500 prefix // Use the GNU magic instead of POSIX magic if we used any GNU extensions. if tw.usedBinary { copy(header[257:265], []byte("ustar \x00")) } _, paxPathUsed := paxHeaders[paxPath] // try to use a ustar header when only the name is too long if !tw.preferPax && len(paxHeaders) == 1 && paxPathUsed { prefix, suffix, ok := splitUSTARPath(hdr.Name) if ok { // Since we can encode in USTAR format, disable PAX header. delete(paxHeaders, paxPath) // Update the path fields formatString(pathHeaderBytes, suffix, paxNone) formatString(prefixHeaderBytes, prefix, paxNone) } } // The chksum field is terminated by a NUL and a space. // This is different from the other octal fields. chksum, _ := checksum(header) f.formatOctal(header[148:155], chksum) // Never fails header[155] = ' ' // Check if there were any formatting errors. if f.err != nil { tw.err = f.err return tw.err } if allowPax { for k, v := range hdr.Xattrs { paxHeaders[paxXattr+k] = v } } if len(paxHeaders) > 0 { if !allowPax { return errInvalidHeader } if err := tw.writePAXHeader(hdr, paxHeaders); err != nil { return err } } tw.nb = hdr.Size tw.pad = (blockSize - (tw.nb % blockSize)) % blockSize _, tw.err = tw.w.Write(header) return tw.err } // splitUSTARPath splits a path according to USTAR prefix and suffix rules. // If the path is not splittable, then it will return ("", "", false). func splitUSTARPath(name string) (prefix, suffix string, ok bool) { length := len(name) if length <= fileNameSize || !isASCII(name) { return "", "", false } else if length > fileNamePrefixSize+1 { length = fileNamePrefixSize + 1 } else if name[length-1] == '/' { length-- } i := strings.LastIndex(name[:length], "/") nlen := len(name) - i - 1 // nlen is length of suffix plen := i // plen is length of prefix if i <= 0 || nlen > fileNameSize || nlen == 0 || plen > fileNamePrefixSize { return "", "", false } return name[:i], name[i+1:], true } // writePaxHeader writes an extended pax header to the // archive. func (tw *Writer) writePAXHeader(hdr *Header, paxHeaders map[string]string) error { // Prepare extended header ext := new(Header) ext.Typeflag = TypeXHeader // Setting ModTime is required for reader parsing to // succeed, and seems harmless enough. ext.ModTime = hdr.ModTime // The spec asks that we namespace our pseudo files // with the current pid. However, this results in differing outputs // for identical inputs. As such, the constant 0 is now used instead. // golang.org/issue/12358 dir, file := path.Split(hdr.Name) fullName := path.Join(dir, "PaxHeaders.0", file) ascii := toASCII(fullName) if len(ascii) > 100 { ascii = ascii[:100] } ext.Name = ascii // Construct the body var buf bytes.Buffer // Keys are sorted before writing to body to allow deterministic output. var keys []string for k := range paxHeaders { keys = append(keys, k) } sort.Strings(keys) for _, k := range keys { fmt.Fprint(&buf, formatPAXRecord(k, paxHeaders[k])) } ext.Size = int64(len(buf.Bytes())) if err := tw.writeHeader(ext, false); err != nil { return err } if _, err := tw.Write(buf.Bytes()); err != nil { return err } if err := tw.Flush(); err != nil { return err } return nil } // formatPAXRecord formats a single PAX record, prefixing it with the // appropriate length. func formatPAXRecord(k, v string) string { const padding = 3 // Extra padding for ' ', '=', and '\n' size := len(k) + len(v) + padding size += len(strconv.Itoa(size)) record := fmt.Sprintf("%d %s=%s\n", size, k, v) // Final adjustment if adding size field increased the record size. if len(record) != size { size = len(record) record = fmt.Sprintf("%d %s=%s\n", size, k, v) } return record } // Write writes to the current entry in the tar archive. // Write returns the error ErrWriteTooLong if more than // hdr.Size bytes are written after WriteHeader. func (tw *Writer) Write(b []byte) (n int, err error) { if tw.closed { err = ErrWriteAfterClose return } overwrite := false if int64(len(b)) > tw.nb { b = b[0:tw.nb] overwrite = true } n, err = tw.w.Write(b) tw.nb -= int64(n) if err == nil && overwrite { err = ErrWriteTooLong return } tw.err = err return } // Close closes the tar archive, flushing any unwritten // data to the underlying writer. func (tw *Writer) Close() error { if tw.err != nil || tw.closed { return tw.err } tw.Flush() tw.closed = true if tw.err != nil { return tw.err } // trailer: two zero blocks for i := 0; i < 2; i++ { _, tw.err = tw.w.Write(zeroBlock) if tw.err != nil { break } } return tw.err }