// 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): // - pax extensions import ( "bytes" "errors" "io" "io/ioutil" "math" "os" "strconv" "strings" "time" ) var ( ErrHeader = errors.New("archive/tar: invalid tar header") ) const maxNanoSecondIntSize = 9 // A Reader provides sequential access to the contents of a tar archive. // A tar archive consists of a sequence of files. // The Next method advances to the next file in the archive (including the first), // and then it can be treated as an io.Reader to access the file's data. type Reader struct { r io.Reader err error pad int64 // amount of padding (ignored) after current file entry curr numBytesReader // reader for current file entry hdrBuff [blockSize]byte // buffer to use in readHeader RawAccounting bool // Whether to enable the access needed to reassemble the tar from raw bytes. Some performance/memory hit for this. rawBytes *bytes.Buffer // last raw bits } // RawBytes accesses the raw bytes of the archive, apart from the file payload itself. // This includes the header and padding. // // This call resets the current rawbytes buffer // // Only when RawAccounting is enabled, otherwise this returns nil func (tr *Reader) RawBytes() []byte { if !tr.RawAccounting { return nil } if tr.rawBytes == nil { tr.rawBytes = bytes.NewBuffer(nil) } // if we've read them, then flush them. defer tr.rawBytes.Reset() return tr.rawBytes.Bytes() } // A numBytesReader is an io.Reader with a numBytes method, returning the number // of bytes remaining in the underlying encoded data. type numBytesReader interface { io.Reader numBytes() int64 } // A regFileReader is a numBytesReader for reading file data from a tar archive. type regFileReader struct { r io.Reader // underlying reader nb int64 // number of unread bytes for current file entry } // A sparseFileReader is a numBytesReader for reading sparse file data from a // tar archive. type sparseFileReader struct { rfr numBytesReader // Reads the sparse-encoded file data sp []sparseEntry // The sparse map for the file pos int64 // Keeps track of file position total int64 // Total size of the file } // A sparseEntry holds a single entry in a sparse file's sparse map. // // Sparse files are represented using a series of sparseEntrys. // Despite the name, a sparseEntry represents an actual data fragment that // references data found in the underlying archive stream. All regions not // covered by a sparseEntry are logically filled with zeros. // // For example, if the underlying raw file contains the 10-byte data: // var compactData = "abcdefgh" // // And the sparse map has the following entries: // var sp = []sparseEntry{ // {offset: 2, numBytes: 5} // Data fragment for [2..7] // {offset: 18, numBytes: 3} // Data fragment for [18..21] // } // // Then the content of the resulting sparse file with a "real" size of 25 is: // var sparseData = "\x00"*2 + "abcde" + "\x00"*11 + "fgh" + "\x00"*4 type sparseEntry struct { offset int64 // Starting position of the fragment numBytes int64 // Length of the fragment } // Keywords for GNU sparse files in a PAX extended header const ( paxGNUSparseNumBlocks = "GNU.sparse.numblocks" paxGNUSparseOffset = "GNU.sparse.offset" paxGNUSparseNumBytes = "GNU.sparse.numbytes" paxGNUSparseMap = "GNU.sparse.map" paxGNUSparseName = "GNU.sparse.name" paxGNUSparseMajor = "GNU.sparse.major" paxGNUSparseMinor = "GNU.sparse.minor" paxGNUSparseSize = "GNU.sparse.size" paxGNUSparseRealSize = "GNU.sparse.realsize" ) // Keywords for old GNU sparse headers const ( oldGNUSparseMainHeaderOffset = 386 oldGNUSparseMainHeaderIsExtendedOffset = 482 oldGNUSparseMainHeaderNumEntries = 4 oldGNUSparseExtendedHeaderIsExtendedOffset = 504 oldGNUSparseExtendedHeaderNumEntries = 21 oldGNUSparseOffsetSize = 12 oldGNUSparseNumBytesSize = 12 ) // NewReader creates a new Reader reading from r. func NewReader(r io.Reader) *Reader { return &Reader{r: r} } // Next advances to the next entry in the tar archive. // // io.EOF is returned at the end of the input. func (tr *Reader) Next() (*Header, error) { var hdr *Header if tr.RawAccounting { if tr.rawBytes == nil { tr.rawBytes = bytes.NewBuffer(nil) } else { tr.rawBytes.Reset() } } if tr.err == nil { tr.skipUnread() } if tr.err != nil { return hdr, tr.err } hdr = tr.readHeader() if hdr == nil { return hdr, tr.err } // Check for PAX/GNU header. switch hdr.Typeflag { case TypeXHeader: // PAX extended header headers, err := parsePAX(tr) if err != nil { return nil, err } // We actually read the whole file, // but this skips alignment padding tr.skipUnread() if tr.err != nil { return nil, tr.err } hdr = tr.readHeader() if hdr == nil { return nil, tr.err } mergePAX(hdr, headers) // Check for a PAX format sparse file sp, err := tr.checkForGNUSparsePAXHeaders(hdr, headers) if err != nil { tr.err = err return nil, err } if sp != nil { // Sparse files do not make sense when applied to the special header // types that never have a data section. if isHeaderOnlyType(hdr.Typeflag) { tr.err = ErrHeader return nil, tr.err } // Current file is a PAX format GNU sparse file. // Set the current file reader to a sparse file reader. tr.curr, tr.err = newSparseFileReader(tr.curr, sp, hdr.Size) if tr.err != nil { return nil, tr.err } } return hdr, nil case TypeGNULongName: // We have a GNU long name header. Its contents are the real file name. realname, err := ioutil.ReadAll(tr) if err != nil { return nil, err } var buf []byte if tr.RawAccounting { if _, err = tr.rawBytes.Write(realname); err != nil { return nil, err } buf = make([]byte, tr.rawBytes.Len()) copy(buf[:], tr.RawBytes()) } hdr, err := tr.Next() // since the above call to Next() resets the buffer, we need to throw the bytes over if tr.RawAccounting { buf = append(buf, tr.RawBytes()...) if _, err = tr.rawBytes.Write(buf); err != nil { return nil, err } } hdr.Name = cString(realname) return hdr, err case TypeGNULongLink: // We have a GNU long link header. realname, err := ioutil.ReadAll(tr) if err != nil { return nil, err } var buf []byte if tr.RawAccounting { if _, err = tr.rawBytes.Write(realname); err != nil { return nil, err } buf = make([]byte, tr.rawBytes.Len()) copy(buf[:], tr.RawBytes()) } hdr, err := tr.Next() // since the above call to Next() resets the buffer, we need to throw the bytes over if tr.RawAccounting { buf = append(buf, tr.RawBytes()...) if _, err = tr.rawBytes.Write(buf); err != nil { return nil, err } } hdr.Linkname = cString(realname) return hdr, err } return hdr, tr.err } // checkForGNUSparsePAXHeaders checks the PAX headers for GNU sparse headers. If they are found, then // this function reads the sparse map and returns it. Unknown sparse formats are ignored, causing the file to // be treated as a regular file. func (tr *Reader) checkForGNUSparsePAXHeaders(hdr *Header, headers map[string]string) ([]sparseEntry, error) { var sparseFormat string // Check for sparse format indicators major, majorOk := headers[paxGNUSparseMajor] minor, minorOk := headers[paxGNUSparseMinor] sparseName, sparseNameOk := headers[paxGNUSparseName] _, sparseMapOk := headers[paxGNUSparseMap] sparseSize, sparseSizeOk := headers[paxGNUSparseSize] sparseRealSize, sparseRealSizeOk := headers[paxGNUSparseRealSize] // Identify which, if any, sparse format applies from which PAX headers are set if majorOk && minorOk { sparseFormat = major + "." + minor } else if sparseNameOk && sparseMapOk { sparseFormat = "0.1" } else if sparseSizeOk { sparseFormat = "0.0" } else { // Not a PAX format GNU sparse file. return nil, nil } // Check for unknown sparse format if sparseFormat != "0.0" && sparseFormat != "0.1" && sparseFormat != "1.0" { return nil, nil } // Update hdr from GNU sparse PAX headers if sparseNameOk { hdr.Name = sparseName } if sparseSizeOk { realSize, err := strconv.ParseInt(sparseSize, 10, 0) if err != nil { return nil, ErrHeader } hdr.Size = realSize } else if sparseRealSizeOk { realSize, err := strconv.ParseInt(sparseRealSize, 10, 0) if err != nil { return nil, ErrHeader } hdr.Size = realSize } // Set up the sparse map, according to the particular sparse format in use var sp []sparseEntry var err error switch sparseFormat { case "0.0", "0.1": sp, err = readGNUSparseMap0x1(headers) case "1.0": sp, err = readGNUSparseMap1x0(tr.curr) } return sp, err } // mergePAX merges well known headers according to PAX standard. // In general headers with the same name as those found // in the header struct overwrite those found in the header // struct with higher precision or longer values. Esp. useful // for name and linkname fields. func mergePAX(hdr *Header, headers map[string]string) error { for k, v := range headers { switch k { case paxPath: hdr.Name = v case paxLinkpath: hdr.Linkname = v case paxGname: hdr.Gname = v case paxUname: hdr.Uname = v case paxUid: uid, err := strconv.ParseInt(v, 10, 0) if err != nil { return err } hdr.Uid = int(uid) case paxGid: gid, err := strconv.ParseInt(v, 10, 0) if err != nil { return err } hdr.Gid = int(gid) case paxAtime: t, err := parsePAXTime(v) if err != nil { return err } hdr.AccessTime = t case paxMtime: t, err := parsePAXTime(v) if err != nil { return err } hdr.ModTime = t case paxCtime: t, err := parsePAXTime(v) if err != nil { return err } hdr.ChangeTime = t case paxSize: size, err := strconv.ParseInt(v, 10, 0) if err != nil { return err } hdr.Size = int64(size) default: if strings.HasPrefix(k, paxXattr) { if hdr.Xattrs == nil { hdr.Xattrs = make(map[string]string) } hdr.Xattrs[k[len(paxXattr):]] = v } } } return nil } // parsePAXTime takes a string of the form %d.%d as described in // the PAX specification. func parsePAXTime(t string) (time.Time, error) { buf := []byte(t) pos := bytes.IndexByte(buf, '.') var seconds, nanoseconds int64 var err error if pos == -1 { seconds, err = strconv.ParseInt(t, 10, 0) if err != nil { return time.Time{}, err } } else { seconds, err = strconv.ParseInt(string(buf[:pos]), 10, 0) if err != nil { return time.Time{}, err } nano_buf := string(buf[pos+1:]) // Pad as needed before converting to a decimal. // For example .030 -> .030000000 -> 30000000 nanoseconds if len(nano_buf) < maxNanoSecondIntSize { // Right pad nano_buf += strings.Repeat("0", maxNanoSecondIntSize-len(nano_buf)) } else if len(nano_buf) > maxNanoSecondIntSize { // Right truncate nano_buf = nano_buf[:maxNanoSecondIntSize] } nanoseconds, err = strconv.ParseInt(string(nano_buf), 10, 0) if err != nil { return time.Time{}, err } } ts := time.Unix(seconds, nanoseconds) return ts, nil } // parsePAX parses PAX headers. // If an extended header (type 'x') is invalid, ErrHeader is returned func parsePAX(r io.Reader) (map[string]string, error) { buf, err := ioutil.ReadAll(r) if err != nil { return nil, err } // leaving this function for io.Reader makes it more testable if tr, ok := r.(*Reader); ok && tr.RawAccounting { if _, err = tr.rawBytes.Write(buf); err != nil { return nil, err } } // For GNU PAX sparse format 0.0 support. // This function transforms the sparse format 0.0 headers into sparse format 0.1 headers. var sparseMap bytes.Buffer headers := make(map[string]string) // Each record is constructed as // "%d %s=%s\n", length, keyword, value for len(buf) > 0 { // or the header was empty to start with. var sp int // The size field ends at the first space. sp = bytes.IndexByte(buf, ' ') if sp == -1 { return nil, ErrHeader } // Parse the first token as a decimal integer. n, err := strconv.ParseInt(string(buf[:sp]), 10, 0) if err != nil || n < 5 || int64(len(buf)) < n { return nil, ErrHeader } // Extract everything between the decimal and the n -1 on the // beginning to eat the ' ', -1 on the end to skip the newline. var record []byte record, buf = buf[sp+1:n-1], buf[n:] // The first equals is guaranteed to mark the end of the key. // Everything else is value. eq := bytes.IndexByte(record, '=') if eq == -1 { return nil, ErrHeader } key, value := record[:eq], record[eq+1:] keyStr := string(key) if keyStr == paxGNUSparseOffset || keyStr == paxGNUSparseNumBytes { // GNU sparse format 0.0 special key. Write to sparseMap instead of using the headers map. sparseMap.Write(value) sparseMap.Write([]byte{','}) } else { // Normal key. Set the value in the headers map. headers[keyStr] = string(value) } } if sparseMap.Len() != 0 { // Add sparse info to headers, chopping off the extra comma sparseMap.Truncate(sparseMap.Len() - 1) headers[paxGNUSparseMap] = sparseMap.String() } return headers, nil } // cString parses bytes as a NUL-terminated C-style string. // If a NUL byte is not found then the whole slice is returned as a string. func cString(b []byte) string { n := 0 for n < len(b) && b[n] != 0 { n++ } return string(b[0:n]) } func (tr *Reader) octal(b []byte) int64 { // Check for binary format first. if len(b) > 0 && b[0]&0x80 != 0 { var x int64 for i, c := range b { if i == 0 { c &= 0x7f // ignore signal bit in first byte } x = x<<8 | int64(c) } return x } // Because unused fields are filled with NULs, we need // to skip leading NULs. Fields may also be padded with // spaces or NULs. // So we remove leading and trailing NULs and spaces to // be sure. b = bytes.Trim(b, " \x00") if len(b) == 0 { return 0 } x, err := strconv.ParseUint(cString(b), 8, 64) if err != nil { tr.err = err } return int64(x) } // skipUnread skips any unread bytes in the existing file entry, as well as any // alignment padding. It returns io.ErrUnexpectedEOF if any io.EOF is // encountered in the data portion; it is okay to hit io.EOF in the padding. // // Note that this function still works properly even when sparse files are being // used since numBytes returns the bytes remaining in the underlying io.Reader. func (tr *Reader) skipUnread() error { dataSkip := tr.numBytes() // Number of data bytes to skip totalSkip := dataSkip + tr.pad // Total number of bytes to skip tr.curr, tr.pad = nil, 0 if tr.RawAccounting { _, tr.err = io.CopyN(tr.rawBytes, tr.r, totalSkip) return tr.err } // If possible, Seek to the last byte before the end of the data section. // Do this because Seek is often lazy about reporting errors; this will mask // the fact that the tar stream may be truncated. We can rely on the // io.CopyN done shortly afterwards to trigger any IO errors. var seekSkipped int64 // Number of bytes skipped via Seek if sr, ok := tr.r.(io.Seeker); ok && dataSkip > 1 { // Not all io.Seeker can actually Seek. For example, os.Stdin implements // io.Seeker, but calling Seek always returns an error and performs // no action. Thus, we try an innocent seek to the current position // to see if Seek is really supported. pos1, err := sr.Seek(0, os.SEEK_CUR) if err == nil { // Seek seems supported, so perform the real Seek. pos2, err := sr.Seek(dataSkip-1, os.SEEK_CUR) if err != nil { tr.err = err return tr.err } seekSkipped = pos2 - pos1 } } var copySkipped int64 // Number of bytes skipped via CopyN copySkipped, tr.err = io.CopyN(ioutil.Discard, tr.r, totalSkip-seekSkipped) if tr.err == io.EOF && seekSkipped+copySkipped < dataSkip { tr.err = io.ErrUnexpectedEOF } return tr.err } func (tr *Reader) verifyChecksum(header []byte) bool { if tr.err != nil { return false } given := tr.octal(header[148:156]) unsigned, signed := checksum(header) return given == unsigned || given == signed } // readHeader reads the next block header and assumes that the underlying reader // is already aligned to a block boundary. // // The err will be set to io.EOF only when one of the following occurs: // * Exactly 0 bytes are read and EOF is hit. // * Exactly 1 block of zeros is read and EOF is hit. // * At least 2 blocks of zeros are read. func (tr *Reader) readHeader() *Header { header := tr.hdrBuff[:] copy(header, zeroBlock) if _, tr.err = io.ReadFull(tr.r, header); tr.err != nil { // because it could read some of the block, but reach EOF first if tr.err == io.EOF && tr.RawAccounting { if _, tr.err = tr.rawBytes.Write(header); tr.err != nil { return nil } } return nil // io.EOF is okay here } if tr.RawAccounting { if _, tr.err = tr.rawBytes.Write(header); tr.err != nil { return nil } } // Two blocks of zero bytes marks the end of the archive. if bytes.Equal(header, zeroBlock[0:blockSize]) { if _, tr.err = io.ReadFull(tr.r, header); tr.err != nil { // because it could read some of the block, but reach EOF first if tr.err == io.EOF && tr.RawAccounting { if _, tr.err = tr.rawBytes.Write(header); tr.err != nil { return nil } } return nil // io.EOF is okay here } if tr.RawAccounting { if _, tr.err = tr.rawBytes.Write(header); tr.err != nil { return nil } } if bytes.Equal(header, zeroBlock[0:blockSize]) { tr.err = io.EOF } else { tr.err = ErrHeader // zero block and then non-zero block } return nil } if !tr.verifyChecksum(header) { tr.err = ErrHeader return nil } // Unpack hdr := new(Header) s := slicer(header) hdr.Name = cString(s.next(100)) hdr.Mode = tr.octal(s.next(8)) hdr.Uid = int(tr.octal(s.next(8))) hdr.Gid = int(tr.octal(s.next(8))) hdr.Size = tr.octal(s.next(12)) hdr.ModTime = time.Unix(tr.octal(s.next(12)), 0) s.next(8) // chksum hdr.Typeflag = s.next(1)[0] hdr.Linkname = cString(s.next(100)) // The remainder of the header depends on the value of magic. // The original (v7) version of tar had no explicit magic field, // so its magic bytes, like the rest of the block, are NULs. magic := string(s.next(8)) // contains version field as well. var format string switch { case magic[:6] == "ustar\x00": // POSIX tar (1003.1-1988) if string(header[508:512]) == "tar\x00" { format = "star" } else { format = "posix" } case magic == "ustar \x00": // old GNU tar format = "gnu" } switch format { case "posix", "gnu", "star": hdr.Uname = cString(s.next(32)) hdr.Gname = cString(s.next(32)) devmajor := s.next(8) devminor := s.next(8) if hdr.Typeflag == TypeChar || hdr.Typeflag == TypeBlock { hdr.Devmajor = tr.octal(devmajor) hdr.Devminor = tr.octal(devminor) } var prefix string switch format { case "posix", "gnu": prefix = cString(s.next(155)) case "star": prefix = cString(s.next(131)) hdr.AccessTime = time.Unix(tr.octal(s.next(12)), 0) hdr.ChangeTime = time.Unix(tr.octal(s.next(12)), 0) } if len(prefix) > 0 { hdr.Name = prefix + "/" + hdr.Name } } if tr.err != nil { tr.err = ErrHeader return nil } nb := hdr.Size if isHeaderOnlyType(hdr.Typeflag) { nb = 0 } if nb < 0 { tr.err = ErrHeader return nil } // Set the current file reader. tr.pad = -nb & (blockSize - 1) // blockSize is a power of two tr.curr = ®FileReader{r: tr.r, nb: nb} // Check for old GNU sparse format entry. if hdr.Typeflag == TypeGNUSparse { // Get the real size of the file. hdr.Size = tr.octal(header[483:495]) // Read the sparse map. sp := tr.readOldGNUSparseMap(header) if tr.err != nil { return nil } // Current file is a GNU sparse file. Update the current file reader. tr.curr, tr.err = newSparseFileReader(tr.curr, sp, hdr.Size) if tr.err != nil { return nil } } return hdr } // readOldGNUSparseMap reads the sparse map as stored in the old GNU sparse format. // The sparse map is stored in the tar header if it's small enough. If it's larger than four entries, // then one or more extension headers are used to store the rest of the sparse map. func (tr *Reader) readOldGNUSparseMap(header []byte) []sparseEntry { isExtended := header[oldGNUSparseMainHeaderIsExtendedOffset] != 0 spCap := oldGNUSparseMainHeaderNumEntries if isExtended { spCap += oldGNUSparseExtendedHeaderNumEntries } sp := make([]sparseEntry, 0, spCap) s := slicer(header[oldGNUSparseMainHeaderOffset:]) // Read the four entries from the main tar header for i := 0; i < oldGNUSparseMainHeaderNumEntries; i++ { offset := tr.octal(s.next(oldGNUSparseOffsetSize)) numBytes := tr.octal(s.next(oldGNUSparseNumBytesSize)) if tr.err != nil { tr.err = ErrHeader return nil } if offset == 0 && numBytes == 0 { break } sp = append(sp, sparseEntry{offset: offset, numBytes: numBytes}) } for isExtended { // There are more entries. Read an extension header and parse its entries. sparseHeader := make([]byte, blockSize) if _, tr.err = io.ReadFull(tr.r, sparseHeader); tr.err != nil { return nil } if tr.RawAccounting { if _, tr.err = tr.rawBytes.Write(sparseHeader); tr.err != nil { return nil } } isExtended = sparseHeader[oldGNUSparseExtendedHeaderIsExtendedOffset] != 0 s = slicer(sparseHeader) for i := 0; i < oldGNUSparseExtendedHeaderNumEntries; i++ { offset := tr.octal(s.next(oldGNUSparseOffsetSize)) numBytes := tr.octal(s.next(oldGNUSparseNumBytesSize)) if tr.err != nil { tr.err = ErrHeader return nil } if offset == 0 && numBytes == 0 { break } sp = append(sp, sparseEntry{offset: offset, numBytes: numBytes}) } } return sp } // readGNUSparseMap1x0 reads the sparse map as stored in GNU's PAX sparse format version 1.0. // The sparse map is stored just before the file data and padded out to the nearest block boundary. func readGNUSparseMap1x0(r io.Reader) ([]sparseEntry, error) { buf := make([]byte, 2*blockSize) sparseHeader := buf[:blockSize] // readDecimal is a helper function to read a decimal integer from the sparse map // while making sure to read from the file in blocks of size blockSize readDecimal := func() (int64, error) { // Look for newline nl := bytes.IndexByte(sparseHeader, '\n') if nl == -1 { if len(sparseHeader) >= blockSize { // This is an error return 0, ErrHeader } oldLen := len(sparseHeader) newLen := oldLen + blockSize if cap(sparseHeader) < newLen { // There's more header, but we need to make room for the next block copy(buf, sparseHeader) sparseHeader = buf[:newLen] } else { // There's more header, and we can just reslice sparseHeader = sparseHeader[:newLen] } // Now that sparseHeader is large enough, read next block if _, err := io.ReadFull(r, sparseHeader[oldLen:newLen]); err != nil { return 0, err } // leaving this function for io.Reader makes it more testable if tr, ok := r.(*Reader); ok && tr.RawAccounting { if _, err := tr.rawBytes.Write(sparseHeader[oldLen:newLen]); err != nil { return 0, err } } // Look for a newline in the new data nl = bytes.IndexByte(sparseHeader[oldLen:newLen], '\n') if nl == -1 { // This is an error return 0, ErrHeader } nl += oldLen // We want the position from the beginning } // Now that we've found a newline, read a number n, err := strconv.ParseInt(string(sparseHeader[:nl]), 10, 0) if err != nil { return 0, ErrHeader } // Update sparseHeader to consume this number sparseHeader = sparseHeader[nl+1:] return n, nil } // Read the first block if _, err := io.ReadFull(r, sparseHeader); err != nil { return nil, err } // leaving this function for io.Reader makes it more testable if tr, ok := r.(*Reader); ok && tr.RawAccounting { if _, err := tr.rawBytes.Write(sparseHeader); err != nil { return nil, err } } // The first line contains the number of entries numEntries, err := readDecimal() if err != nil { return nil, err } // Read all the entries sp := make([]sparseEntry, 0, numEntries) for i := int64(0); i < numEntries; i++ { // Read the offset offset, err := readDecimal() if err != nil { return nil, err } // Read numBytes numBytes, err := readDecimal() if err != nil { return nil, err } sp = append(sp, sparseEntry{offset: offset, numBytes: numBytes}) } return sp, nil } // readGNUSparseMap0x1 reads the sparse map as stored in GNU's PAX sparse format // version 0.1. The sparse map is stored in the PAX headers. func readGNUSparseMap0x1(extHdrs map[string]string) ([]sparseEntry, error) { // Get number of entries. // Use integer overflow resistant math to check this. numEntriesStr := extHdrs[paxGNUSparseNumBlocks] numEntries, err := strconv.ParseInt(numEntriesStr, 10, 0) // Intentionally parse as native int if err != nil || numEntries < 0 || int(2*numEntries) < int(numEntries) { return nil, ErrHeader } // There should be two numbers in sparseMap for each entry. sparseMap := strings.Split(extHdrs[paxGNUSparseMap], ",") if int64(len(sparseMap)) != 2*numEntries { return nil, ErrHeader } // Loop through the entries in the sparse map. // numEntries is trusted now. sp := make([]sparseEntry, 0, numEntries) for i := int64(0); i < numEntries; i++ { offset, err := strconv.ParseInt(sparseMap[2*i], 10, 64) if err != nil { return nil, ErrHeader } numBytes, err := strconv.ParseInt(sparseMap[2*i+1], 10, 64) if err != nil { return nil, ErrHeader } sp = append(sp, sparseEntry{offset: offset, numBytes: numBytes}) } return sp, nil } // numBytes returns the number of bytes left to read in the current file's entry // in the tar archive, or 0 if there is no current file. func (tr *Reader) numBytes() int64 { if tr.curr == nil { // No current file, so no bytes return 0 } return tr.curr.numBytes() } // Read reads from the current entry in the tar archive. // It returns 0, io.EOF when it reaches the end of that entry, // until Next is called to advance to the next entry. func (tr *Reader) Read(b []byte) (n int, err error) { if tr.err != nil { return 0, tr.err } if tr.curr == nil { return 0, io.EOF } n, err = tr.curr.Read(b) if err != nil && err != io.EOF { tr.err = err } return } func (rfr *regFileReader) Read(b []byte) (n int, err error) { if rfr.nb == 0 { // file consumed return 0, io.EOF } if int64(len(b)) > rfr.nb { b = b[0:rfr.nb] } n, err = rfr.r.Read(b) rfr.nb -= int64(n) if err == io.EOF && rfr.nb > 0 { err = io.ErrUnexpectedEOF } return } // numBytes returns the number of bytes left to read in the file's data in the tar archive. func (rfr *regFileReader) numBytes() int64 { return rfr.nb } // newSparseFileReader creates a new sparseFileReader, but validates all of the // sparse entries before doing so. func newSparseFileReader(rfr numBytesReader, sp []sparseEntry, total int64) (*sparseFileReader, error) { if total < 0 { return nil, ErrHeader // Total size cannot be negative } // Validate all sparse entries. These are the same checks as performed by // the BSD tar utility. for i, s := range sp { switch { case s.offset < 0 || s.numBytes < 0: return nil, ErrHeader // Negative values are never okay case s.offset > math.MaxInt64-s.numBytes: return nil, ErrHeader // Integer overflow with large length case s.offset+s.numBytes > total: return nil, ErrHeader // Region extends beyond the "real" size case i > 0 && sp[i-1].offset+sp[i-1].numBytes > s.offset: return nil, ErrHeader // Regions can't overlap and must be in order } } return &sparseFileReader{rfr: rfr, sp: sp, total: total}, nil } // readHole reads a sparse hole ending at endOffset. func (sfr *sparseFileReader) readHole(b []byte, endOffset int64) int { n64 := endOffset - sfr.pos if n64 > int64(len(b)) { n64 = int64(len(b)) } n := int(n64) for i := 0; i < n; i++ { b[i] = 0 } sfr.pos += n64 return n } // Read reads the sparse file data in expanded form. func (sfr *sparseFileReader) Read(b []byte) (n int, err error) { // Skip past all empty fragments. for len(sfr.sp) > 0 && sfr.sp[0].numBytes == 0 { sfr.sp = sfr.sp[1:] } // If there are no more fragments, then it is possible that there // is one last sparse hole. if len(sfr.sp) == 0 { // This behavior matches the BSD tar utility. // However, GNU tar stops returning data even if sfr.total is unmet. if sfr.pos < sfr.total { return sfr.readHole(b, sfr.total), nil } return 0, io.EOF } // In front of a data fragment, so read a hole. if sfr.pos < sfr.sp[0].offset { return sfr.readHole(b, sfr.sp[0].offset), nil } // In a data fragment, so read from it. // This math is overflow free since we verify that offset and numBytes can // be safely added when creating the sparseFileReader. endPos := sfr.sp[0].offset + sfr.sp[0].numBytes // End offset of fragment bytesLeft := endPos - sfr.pos // Bytes left in fragment if int64(len(b)) > bytesLeft { b = b[:bytesLeft] } n, err = sfr.rfr.Read(b) sfr.pos += int64(n) if err == io.EOF { if sfr.pos < endPos { err = io.ErrUnexpectedEOF // There was supposed to be more data } else if sfr.pos < sfr.total { err = nil // There is still an implicit sparse hole at the end } } if sfr.pos == endPos { sfr.sp = sfr.sp[1:] // We are done with this fragment, so pop it } return n, err } // numBytes returns the number of bytes left to read in the sparse file's // sparse-encoded data in the tar archive. func (sfr *sparseFileReader) numBytes() int64 { return sfr.rfr.numBytes() }