private static bool ReadHeader(ZipEntry ze, System.Text.Encoding defaultEncoding) { int bytesRead = 0; // change for workitem 8098 ze._RelativeOffsetOfLocalHeader = ze.ArchiveStream.Position; int signature = Crisis.Ionic.Zip.SharedUtilities.ReadEntrySignature(ze.ArchiveStream); bytesRead += 4; // Return false if this is not a local file header signature. if (ZipEntry.IsNotValidSig(signature)) { // Getting "not a ZipEntry signature" is not always wrong or an error. // This will happen after the last entry in a zipfile. In that case, we // expect to read : // a ZipDirEntry signature (if a non-empty zip file) or // a ZipConstants.EndOfCentralDirectorySignature. // // Anything else is a surprise. ze.ArchiveStream.Seek(-4, SeekOrigin.Current); // unread the signature // workitem 10178 Crisis.Ionic.Zip.SharedUtilities.Workaround_Ladybug318918(ze.ArchiveStream); if (ZipEntry.IsNotValidZipDirEntrySig(signature) && (signature != ZipConstants.EndOfCentralDirectorySignature)) { throw new BadReadException(String.Format(" Bad signature (0x{0:X8}) at position 0x{1:X8}", signature, ze.ArchiveStream.Position)); } return(false); } byte[] block = new byte[26]; int n = ze.ArchiveStream.Read(block, 0, block.Length); if (n != block.Length) { return(false); } bytesRead += n; int i = 0; ze._VersionNeeded = (Int16)(block[i++] + block[i++] * 256); ze._BitField = (Int16)(block[i++] + block[i++] * 256); ze._CompressionMethod_FromZipFile = ze._CompressionMethod = (Int16)(block[i++] + block[i++] * 256); ze._TimeBlob = block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256; // transform the time data into something usable (a DateTime) ze._LastModified = Crisis.Ionic.Zip.SharedUtilities.PackedToDateTime(ze._TimeBlob); ze._timestamp |= ZipEntryTimestamp.DOS; if ((ze._BitField & 0x01) == 0x01) { ze._Encryption_FromZipFile = ze._Encryption = EncryptionAlgorithm.PkzipWeak; // this *may* change after processing the Extra field ze._sourceIsEncrypted = true; } // NB: if ((ze._BitField & 0x0008) != 0x0008), then the Compressed, uncompressed and // CRC values are not true values; the true values will follow the entry data. // But, regardless of the status of bit 3 in the bitfield, the slots for // the three amigos may contain marker values for ZIP64. So we must read them. { ze._Crc32 = (Int32)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); ze._CompressedSize = (uint)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); ze._UncompressedSize = (uint)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); if ((uint)ze._CompressedSize == 0xFFFFFFFF || (uint)ze._UncompressedSize == 0xFFFFFFFF) { ze._InputUsesZip64 = true; } } Int16 filenameLength = (short)(block[i++] + block[i++] * 256); Int16 extraFieldLength = (short)(block[i++] + block[i++] * 256); block = new byte[filenameLength]; n = ze.ArchiveStream.Read(block, 0, block.Length); bytesRead += n; // if the UTF8 bit is set for this entry, override the // encoding the application requested. if ((ze._BitField & 0x0800) == 0x0800) { // workitem 12744 ze.AlternateEncoding = System.Text.Encoding.UTF8; ze.AlternateEncodingUsage = ZipOption.Always; } // need to use this form of GetString() for .NET CF ze._FileNameInArchive = ze.AlternateEncoding.GetString(block, 0, block.Length); // workitem 6898 if (ze._FileNameInArchive.EndsWith("/")) { ze.MarkAsDirectory(); } bytesRead += ze.ProcessExtraField(ze.ArchiveStream, extraFieldLength); ze._LengthOfTrailer = 0; // workitem 6607 - don't read for directories // actually get the compressed size and CRC if necessary if (!ze._FileNameInArchive.EndsWith("/") && (ze._BitField & 0x0008) == 0x0008) { // This descriptor exists only if bit 3 of the general // purpose bit flag is set (see below). It is byte aligned // and immediately follows the last byte of compressed data, // as well as any encryption trailer, as with AES. // This descriptor is used only when it was not possible to // seek in the output .ZIP file, e.g., when the output .ZIP file // was standard output or a non-seekable device. For ZIP64(tm) format // archives, the compressed and uncompressed sizes are 8 bytes each. // workitem 8098: ok (restore) long posn = ze.ArchiveStream.Position; // Here, we're going to loop until we find a ZipEntryDataDescriptorSignature and // a consistent data record after that. To be consistent, the data record must // indicate the length of the entry data. bool wantMore = true; long SizeOfDataRead = 0; int tries = 0; while (wantMore) { tries++; // We call the FindSignature shared routine to find the specified signature // in the already-opened zip archive, starting from the current cursor // position in that filestream. If we cannot find the signature, then the // routine returns -1, and the ReadHeader() method returns false, // indicating we cannot read a legal entry header. If we have found it, // then the FindSignature() method returns the number of bytes in the // stream we had to seek forward, to find the sig. We need this to // determine if the zip entry is valid, later. if (ze._container.ZipFile != null) { ze._container.ZipFile.OnReadBytes(ze); } long d = Crisis.Ionic.Zip.SharedUtilities.FindSignature(ze.ArchiveStream, ZipConstants.ZipEntryDataDescriptorSignature); if (d == -1) { return(false); } // total size of data read (through all loops of this). SizeOfDataRead += d; if (ze._InputUsesZip64) { // read 1x 4-byte (CRC) and 2x 8-bytes (Compressed Size, Uncompressed Size) block = new byte[20]; n = ze.ArchiveStream.Read(block, 0, block.Length); if (n != 20) { return(false); } // do not increment bytesRead - it is for entry header only. // the data we have just read is a footer (falls after the file data) //bytesRead += n; i = 0; ze._Crc32 = (Int32)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); ze._CompressedSize = BitConverter.ToInt64(block, i); i += 8; ze._UncompressedSize = BitConverter.ToInt64(block, i); i += 8; ze._LengthOfTrailer += 24; // bytes including sig, CRC, Comp and Uncomp sizes } else { // read 3x 4-byte fields (CRC, Compressed Size, Uncompressed Size) block = new byte[12]; n = ze.ArchiveStream.Read(block, 0, block.Length); if (n != 12) { return(false); } // do not increment bytesRead - it is for entry header only. // the data we have just read is a footer (falls after the file data) //bytesRead += n; i = 0; ze._Crc32 = (Int32)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); ze._CompressedSize = (uint)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); ze._UncompressedSize = (uint)(block[i++] + block[i++] * 256 + block[i++] * 256 * 256 + block[i++] * 256 * 256 * 256); ze._LengthOfTrailer += 16; // bytes including sig, CRC, Comp and Uncomp sizes } wantMore = (SizeOfDataRead != ze._CompressedSize); if (wantMore) { // Seek back to un-read the last 12 bytes - maybe THEY contain // the ZipEntryDataDescriptorSignature. // (12 bytes for the CRC, Comp and Uncomp size.) ze.ArchiveStream.Seek(-12, SeekOrigin.Current); // workitem 10178 Crisis.Ionic.Zip.SharedUtilities.Workaround_Ladybug318918(ze.ArchiveStream); // Adjust the size to account for the false signature read in // FindSignature(). SizeOfDataRead += 4; } } // seek back to previous position, to prepare to read file data // workitem 8098: ok (restore) ze.ArchiveStream.Seek(posn, SeekOrigin.Begin); // workitem 10178 Crisis.Ionic.Zip.SharedUtilities.Workaround_Ladybug318918(ze.ArchiveStream); } ze._CompressedFileDataSize = ze._CompressedSize; // bit 0 set indicates that some kind of encryption is in use if ((ze._BitField & 0x01) == 0x01) { #if AESCRYPTO if (ze.Encryption == EncryptionAlgorithm.WinZipAes128 || ze.Encryption == EncryptionAlgorithm.WinZipAes256) { int bits = ZipEntry.GetKeyStrengthInBits(ze._Encryption_FromZipFile); // read in the WinZip AES metadata: salt + PV. 18 bytes for AES256. 10 bytes for AES128. ze._aesCrypto_forExtract = WinZipAesCrypto.ReadFromStream(null, bits, ze.ArchiveStream); bytesRead += ze._aesCrypto_forExtract.SizeOfEncryptionMetadata - 10; // MAC (follows crypto bytes) // according to WinZip, the CompressedSize includes the AES Crypto framing data. ze._CompressedFileDataSize -= ze._aesCrypto_forExtract.SizeOfEncryptionMetadata; ze._LengthOfTrailer += 10; // MAC } else #endif { // read in the header data for "weak" encryption ze._WeakEncryptionHeader = new byte[12]; bytesRead += ZipEntry.ReadWeakEncryptionHeader(ze._archiveStream, ze._WeakEncryptionHeader); // decrease the filedata size by 12 bytes ze._CompressedFileDataSize -= 12; } } // Remember the size of the blob for this entry. // We also have the starting position in the stream for this entry. ze._LengthOfHeader = bytesRead; ze._TotalEntrySize = ze._LengthOfHeader + ze._CompressedFileDataSize + ze._LengthOfTrailer; // We've read in the regular entry header, the extra field, and any // encryption header. The pointer in the file is now at the start of the // filedata, which is potentially compressed and encrypted. Just ahead in // the file, there are _CompressedFileDataSize bytes of data, followed by // potentially a non-zero length trailer, consisting of optionally, some // encryption stuff (10 byte MAC for AES), and the bit-3 trailer (16 or 24 // bytes). return(true); }
public static ZipCrypto ForRead(string password, ZipEntry e) { System.IO.Stream s = e._archiveStream; e._WeakEncryptionHeader = new byte[12]; byte[] eh = e._WeakEncryptionHeader; ZipCrypto z = new ZipCrypto(); if (password == null) { throw new BadPasswordException("This entry requires a password."); } z.InitCipher(password); ZipEntry.ReadWeakEncryptionHeader(s, eh); // Decrypt the header. This has a side effect of "further initializing the // encryption keys" in the traditional zip encryption. byte[] DecryptedHeader = z.DecryptMessage(eh, eh.Length); // CRC check // According to the pkzip spec, the final byte in the decrypted header // is the highest-order byte in the CRC. We check it here. if (DecryptedHeader[11] != (byte)((e._Crc32 >> 24) & 0xff)) { // In the case that bit 3 of the general purpose bit flag is set to // indicate the presence of an 'Extended File Header' or a 'data // descriptor' (signature 0x08074b50), the last byte of the decrypted // header is sometimes compared with the high-order byte of the // lastmodified time, rather than the high-order byte of the CRC, to // verify the password. // // This is not documented in the PKWare Appnote.txt. It was // discovered this by analysis of the Crypt.c source file in the // InfoZip library http://www.info-zip.org/pub/infozip/ // // The reason for this is that the CRC for a file cannot be known // until the entire contents of the file have been streamed. This // means a tool would have to read the file content TWICE in its // entirety in order to perform PKZIP encryption - once to compute // the CRC, and again to actually encrypt. // // This is so important for performance that using the timeblob as // the verification should be the standard practice for DotNetZip // when using PKZIP encryption. This implies that bit 3 must be // set. The downside is that some tools still cannot cope with ZIP // files that use bit 3. Therefore, DotNetZip DOES NOT force bit 3 // when PKZIP encryption is in use, and instead, reads the stream // twice. // if ((e._BitField & 0x0008) != 0x0008) { throw new BadPasswordException("The password did not match."); } else if (DecryptedHeader[11] != (byte)((e._TimeBlob >> 8) & 0xff)) { throw new BadPasswordException("The password did not match."); } // We have a good password. } else { // A-OK } return(z); }