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xenadmin/XenOvfApi/Package.cs
Mihaela Stoica bd36a85bff CP-4816: Initial commit to git repo 
Signed-off-by: Mihaela Stoica <mihaela.stoica@citrix.com>
2013-06-24 12:41:48 +01:00

734 lines
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C#
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/* Copyright (c) Citrix Systems Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms,
* with or without modification, are permitted provided
* that the following conditions are met:
*
* * Redistributions of source code must retain the above
* copyright notice, this list of conditions and the
* following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the
* following disclaimer in the documentation and/or other
* materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,
* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
using System;
using System.Collections.Generic;
using System.IO;
using System.Security.Cryptography;
using System.Security.Cryptography.X509Certificates;
using System.Text.RegularExpressions;
using XenCenterLib.Archive;
using XenCenterLib.Compression;
namespace XenOvf
{
// Provides the properties of a digest for a file in the manifest of an OVF appliance.
public class FileDigest
{
// Construct from a line in the manifest.
public FileDigest(string line)
{
var fields = line.Split(new char[] { '(', ')', '=' });
// Expect the first field to be the security algorithm used to compute the hash of the file.
_AlgorithmName = fields[0].Trim();
// Expect the second field to be the name of the file.
Match nameMatch = new Regex(@"[\(](.*)[\)][=]").Match(line);
_Name = nameMatch.Success ? nameMatch.Groups[1].Value.Trim() : fields[1].Trim();
// Expect the last field to be the digest of the file.
_DigestAsString = fields[fields.Length - 1].Trim();
}
// Name of the file with the digest.
public string Name { get { return _Name; } }
private string _Name;
// Name of the algorithm to compute the digest.
// It must be recognized by HashAlgorithm.Create().
public string AlgorithmName { get { return _AlgorithmName; } }
private string _AlgorithmName;
// Algorithm to compute the digest.
public HashAlgorithm Algorithm
{
get
{
var hashAlgorithm = HashAlgorithm.Create(_AlgorithmName);
// Validate the algorithm.
if (hashAlgorithm == null)
throw new ArgumentException(string.Format(Messages.SECURITY_NOT_SUPPORTED, _AlgorithmName));
return hashAlgorithm;
}
}
// Digest as a binary array.
public byte[] Digest { get { return ToArray(_DigestAsString); } }
private string _DigestAsString;
protected string DigestAsString
{
get { return _DigestAsString; }
}
public bool WasVerified { get { return _WasVerified; } }
private bool _WasVerified = false;
// Convert a hex string to a binary array.
public static byte[] ToArray(string HexString)
{
if ((HexString.Length % 2) > 0)
{
// The length is odd.
// Pad the hex string on the left with a space to interpret as a leading zero.
HexString = HexString.PadLeft(HexString.Length + 1);
}
var array = new byte[HexString.Length / 2];
try
{
for (int i = 0; i < HexString.Length; i += 2)
{
array[i / 2] = byte.Parse(HexString.Substring(i, 2), System.Globalization.NumberStyles.HexNumber);
}
}
catch
{
throw new Exception(HexString + " contains an invalid hexadecimal number.");
}
return array;
}
// Verify the digest of the file content accessible from the given stream by comparing it to the stored digest.
public void Verify(Stream stream)
{
var computedDigest = Algorithm.ComputeHash(stream);
if (!System.Linq.Enumerable.SequenceEqual(Digest, computedDigest))
{
throw new Exception(string.Format(Messages.SECURITY_SIGNATURE_FAILED, Name));
}
_WasVerified = true;
}
// Verify the digest, when used as a signature, of the file content accessible from the given stream.
public void Verify(Stream stream, RSACryptoServiceProvider key)
{
var computedDigest = Algorithm.ComputeHash(stream);
if (!key.VerifyHash(computedDigest, CryptoConfig.MapNameToOID(_AlgorithmName), Digest))
{
throw new Exception(string.Format(Messages.SECURITY_SIGNATURE_FAILED, Name));
}
}
}
// OVF Appliance in the form of a folder.
internal class FolderPackage : Package
{
public FolderPackage(string path)
{
PackageSourceFile = path;
_Folder = path;
var extension = Path.GetExtension(path);
if (String.Compare(extension, Properties.Settings.Default.ovfFileExtension, true) == 0)
_Folder = Path.GetDirectoryName(path);
if (_Folder == null)
{
// Handle a package in the root or current folder.
_Folder = "";
}
}
private string _Folder;
public override string DescriptorFileName
{
get
{
return Path.GetFileName(PackageSourceFile);
}
}
public override bool HasFile(string fileName)
{
try
{
using (var stream = File.OpenRead(Path.Combine(_Folder, fileName)))
{
return true;
}
}
catch
{
return false;
}
}
protected override byte[] ReadAllBytes(string fileName)
{
return File.ReadAllBytes(Path.Combine(_Folder, fileName));
}
protected override string ReadAllText(string fileName)
{
return File.ReadAllText(Path.Combine(_Folder, fileName));
}
public override void VerifyManifest()
{
// Verify the presence of a manifest.
var manifest = Manifest;
// For a folder package, it is efficient to iterate by the order of files in the manifest.
foreach (FileDigest fileDigest in manifest)
{
using (var stream = File.OpenRead(Path.Combine(_Folder, fileDigest.Name)))
{
// Verify each manifest item.
fileDigest.Verify(stream);
}
}
}
}
// Exposes a stream of entries within a tar for TarPackage.
internal class TarFileStream : IDisposable /*: Stream */
{
// Open a file within the tar.
public TarFileStream(string tarPath)
{
_tarStream = File.OpenRead(tarPath);
var extension = Path.GetExtension(tarPath);
// Check for a compressed archive.
if (String.Compare(extension, ".gz", true) == 0)
{
_compressionStream = CompressionFactory.Reader(CompressionFactory.Type.Gz, _tarStream);
_tarInputStream = ArchiveFactory.Reader(ArchiveFactory.Type.Tar, _compressionStream);
}
else if (String.Compare(extension, ".bz2", true) == 0)
{
_compressionStream = CompressionFactory.Reader(CompressionFactory.Type.Bz2, _tarStream);
_tarInputStream = ArchiveFactory.Reader(ArchiveFactory.Type.Tar, _compressionStream);
}
else
{
_tarInputStream = ArchiveFactory.Reader(ArchiveFactory.Type.Tar, _tarStream);
}
}
// An improvement would be to construct an enumerator for use with foreach.
public bool FindNextFile(string filePath)
{
// Emulate the simple pattern matching of Directory.GetFiles(string path, string pattern)
var regexPattern = new System.Text.StringBuilder(filePath);
// Escape any directory separators first.
regexPattern = regexPattern.Replace("\\", "\\\\");
// Escape any extension separator second.
regexPattern = regexPattern.Replace(".", "\\.");
// Translate any wildcards to their RegEx equivalents.
regexPattern = regexPattern.Replace("*", ".*");
regexPattern = regexPattern.Replace("?", ".?");
var regexPatternAsString = regexPattern.ToString();
while (MoveNext())
{
if (System.Text.RegularExpressions.Regex.IsMatch(Current, regexPatternAsString, System.Text.RegularExpressions.RegexOptions.IgnoreCase))
return true;
}
return false;
}
public byte[] ReadAllBytes()
{
MemoryStream ms = new MemoryStream();
_tarInputStream.ExtractCurrentFile(ms);
if( ms.Length < 1 )
return null;
return ms.ToArray();
}
// Name of current file in the archive.
public string Current
{
get
{
return _tarInputStream.CurrentFileName();
}
}
public bool MoveNext()
{
return _tarInputStream.HasNext();
}
protected void Dispose(Boolean disposing)
{
if (disposing)
{
// TarInputStream does not implement Dispose(boolean).
_tarInputStream.Dispose();
if (_compressionStream != null)
_compressionStream.Dispose();
_tarStream.Dispose();
}
}
private Stream _tarStream;
private Stream _compressionStream;
private ArchiveIterator _tarInputStream;
public void Close()
{
Dispose(true);
}
public void Dispose()
{
Close();
}
}
// OVF Appliance in the form of a tape archive (tar).
internal class TarPackage : Package
{
public TarPackage(string path)
{
PackageSourceFile = path;
_DirectoryCache = new Dictionary<string, byte[]>();
}
private Dictionary<string, byte[]> _DirectoryCache;
public override string DescriptorFileName
{
get
{
if (_DescriptorFileName != null)
return _DescriptorFileName;
Load();
if (_DescriptorFileName != null)
{
return _DescriptorFileName;
}
// Last resort is to search the whole archive.
var ovfFilePattern = "*" + Properties.Settings.Default.ovfFileExtension;
using (var stream = OpenRead(ovfFilePattern))
{
_DescriptorFileName = stream.Current;
}
return _DescriptorFileName;
}
}
private string _DescriptorFileName;
// Open a file within the tar.
protected TarFileStream OpenRead(string fileName)
{
var stream = new TarFileStream(PackageSourceFile);
if (!stream.FindNextFile(fileName))
{
stream.Close();
throw new FileNotFoundException(fileName);
}
return stream;
}
public override bool HasFile(string fileName)
{
try
{
if (_DirectoryCache.ContainsKey(fileName))
return true;
using (var stream = OpenRead(fileName))
{
return true;
}
}
catch
{
return false;
}
}
// Wrap calls to TarFileStream.MoveNext() to cache file names for HasFile().
private bool MoveNext(TarFileStream stream)
{
var haveFile = stream.MoveNext();
if (haveFile)
_DirectoryCache[stream.Current] = null;
return haveFile;
}
protected override byte[] ReadAllBytes(string fileName)
{
byte[] buffer;
if ((_DirectoryCache.TryGetValue(fileName, out buffer)) && (buffer != null))
{
return buffer;
}
using (var stream = OpenRead(fileName))
{
return (_DirectoryCache[stream.Current] = stream.ReadAllBytes());
}
}
protected override string ReadAllText(string fileName)
{
var buffer = ReadAllBytes(fileName);
using (var stream = new MemoryStream(buffer))
using (var reader = new StreamReader(stream))
{
return reader.ReadToEnd();
}
}
private void Load()
{
using (var stream = new TarFileStream(PackageSourceFile))
{
while (MoveNext(stream))
{
var extension = Path.GetExtension(stream.Current);
if ((_DescriptorFileName == null) && (String.Compare(extension, Properties.Settings.Default.ovfFileExtension, true) == 0))
{
// Use the first file name with an ovf extension.
_DescriptorFileName = stream.Current;
}
else if (String.Compare(extension, Properties.Settings.Default.manifestFileExtension, true) == 0)
{
// Skip a manifest file that does not have the base name as the descriptor.
if ((_DescriptorFileName != null) && (String.Compare(stream.Current, ManifestFileName, true) != 0))
continue;
}
else if (String.Compare(extension, Properties.Settings.Default.certificateFileExtension, true) == 0)
{
// Skip a certificate file that does not have the base name as the descriptor.
if ((_DescriptorFileName != null) && (String.Compare(stream.Current, CertificateFileName, true) != 0))
continue;
}
else
{
// Stop loading because descriptor, manifest, and certificate files must precede all other files.
break;
}
// Load this file.
_DirectoryCache[stream.Current] = stream.ReadAllBytes();
}
}
}
public override void VerifyManifest()
{
// Verify the presence of a manifest.
var manifest = Manifest;
int verifiedCount = 0;
using (var stream = new TarFileStream(PackageSourceFile))
{
// For a tar package, it is more efficient to iterate the files in the order within the archive.
while (MoveNext(stream))
{
// Find the manifest entry for the current tar entry.
FileDigest fileDigest = manifest.Find(
delegate(FileDigest aFileDigest)
{
return (String.Compare(aFileDigest.Name, stream.Current, true) == 0);
});
if (fileDigest == null)
continue;
// The manifest entry was found.
// Verify its digest.
fileDigest.Verify(new MemoryStream(stream.ReadAllBytes()));
verifiedCount++;
}
foreach (var fileDigest in manifest)
{
if (!fileDigest.WasVerified)
{
// A manifest entry was missing.
XenOvf.Utilities.Log.Error(string.Format(Messages.FILE_MISSING, fileDigest.Name));
}
}
if (verifiedCount != manifest.Count)
{
// A manifest entry was missing.
throw new Exception(Messages.SECURITY_FILE_MISSING);
}
}
}
}
// Abstract class to access any time of package.
public abstract class Package
{
// Package factory.
public static Package Create(string path)
{
var extension = Path.GetExtension(path);
if (String.Compare(extension, Properties.Settings.Default.ovfFileExtension, true) == 0)
{
return new FolderPackage(path);
}
// Assume it is an archive.
return new TarPackage(path);
}
// Hide the constructor because only the factory can create a package.
protected Package() { }
#region Properties
// DescriptorFileName is a special property.
// Access to the rest of the package depends on it.
// Abstract because the most efficient method to get it depends on the package type.
public abstract string DescriptorFileName { get; }
// According to the OVF specification, name of the *package* is base name of the descriptor file.
public string Name
{
get
{
return Path.GetFileNameWithoutExtension(DescriptorFileName);
}
}
// According to the OVF specification, base name of the manifest file must be the same as the descriptor file.
public string ManifestFileName
{
get
{
return (Name + Properties.Settings.Default.manifestFileExtension);
}
}
// According to the OVF specification, base name of the certificate file must be the same as the descriptor file.
public string CertificateFileName { get { return (Name + Properties.Settings.Default.certificateFileExtension); } }
// Contents of the OVF file.
public virtual string Descriptor
{
get
{
if (_Descriptor != null)
return _Descriptor;
return (_Descriptor = ReadAllText(DescriptorFileName));
}
}
// Cache this property because it is expensive to get.
private string _Descriptor;
public List<FileDigest> Manifest
{
get
{
var manifest = new List<FileDigest>();
using (var stream = new MemoryStream(RawManifest))
using (StreamReader reader = new StreamReader(stream))
{
while (!reader.EndOfStream)
{
manifest.Add(new FileDigest(reader.ReadLine()));
}
}
return manifest;
}
}
protected byte[] RawManifest
{
get
{
if (_RawManifest != null)
return _RawManifest;
return (_RawManifest = ReadAllBytes(ManifestFileName));
}
}
private byte[] _RawManifest;
public X509Certificate2 Certificate
{
get
{
return (new X509Certificate2(RawCertificate));
}
}
protected byte[] RawCertificate
{
get
{
if (_RawCertificate != null)
return _RawCertificate;
return (_RawCertificate = ReadAllBytes(CertificateFileName));
}
}
private byte[] _RawCertificate;
public string PackageSourceFile { get; protected set; }
#endregion
public virtual bool HasManifest()
{
return ((_RawManifest != null) || (HasFile(ManifestFileName)));
}
public virtual bool HasSignature()
{
return ((_RawCertificate != null) || (HasFile(CertificateFileName)));
}
public virtual void VerifySignature()
{
// Verify the certificate used to sign the package.
var certificate = Certificate;
if (!certificate.Verify())
{
throw new Exception(Messages.CERTIFICATE_IS_INVALID);
}
// Get the package signature from the certificate file.
FileDigest fileDigest = null;
using (Stream stream = new MemoryStream(RawCertificate))
using (StreamReader reader = new StreamReader(stream))
{
// The package signature is the digest of the file identified on the first line in the certificate file.
fileDigest = new FileDigest(reader.ReadLine());
}
// Compare the stored signature to the computed signature.
// Do this independently to minimize the number of files opened concurrently.
using (Stream stream = new MemoryStream(RawManifest))
{
// Verify the signature using the public key.
fileDigest.Verify(stream, (RSACryptoServiceProvider)certificate.PublicKey.Key);
}
}
#region Package methods to specialize
public abstract bool HasFile(string name);
protected abstract byte[] ReadAllBytes(string fileName);
protected abstract string ReadAllText(string fileName);
// Abstract because the file enumerator method varies by package type.
public abstract void VerifyManifest();
#endregion
}
}
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