public override void Parse(TreeBuilder tree)
{
S2K = new S2K();
Version = tree.ReadByte("Version");
S2K.SymAlgo = tree.ReadByte("Symmetric Algorithm", SymmetricAlgorithmTypes.Get);
byte S2KSpecifier = tree.ReadByte("S2K Specifier", S2KTypes.Get);
if (S2KSpecifier != S2KTypes.Salted && S2KSpecifier != S2KTypes.Simple && S2KSpecifier != S2KTypes.IteratedAndSalted)
{
throw new InvalidDataException("Invalid S2K Specifier");
}
S2K.HashAlgorithm = tree.ReadByte("Hash Algorithm", HashAlgorithmTypes.Get);
if (S2KSpecifier == S2KTypes.Salted || S2KSpecifier == S2KTypes.IteratedAndSalted)
{
S2K.Salt = tree.ReadBytes("Salt", 8);
if (S2KSpecifier == S2KTypes.IteratedAndSalted)
{
byte CodedCount = tree.ReadByte("Coded Iteration");
S2K.ByteCount = (16 + (CodedCount & 15)) << ((CodedCount >> 4) + 6);
}
}
if (tree.IsMoreData())
{
EncryptedSessionKey = tree.ReadBytes("Encrypted Session Key");
}
else
{
EncryptedSessionKey = null;
}
}
public override void Parse(TreeBuilder tree)
{
tree.ReadByte("Compression Algorithm", CompressionAlgorithmTypes.Get);
tree.SkipBytes("Compressed Data");
ThisBlock = tree.CurrentBlock;
ThisBlock.ProcessBlock += ExtractData;
}
public override void LoadPublicKey(TreeBuilder tree)
{
tree.AddNode("RSA Public Key");
tree.PushByteBlock();
ModN = tree.ReadMPIBytes("Mod n");
Exp = tree.ReadMPIBytes("Exp");
tree.PopByteBlock();
}
public override void Parse(TreeBuilder tree)
{
Version = tree.ReadByte("Version");
var block = tree.SkipBytes("Encrypted Data");
block.ProcessBlock += ExtractData;
ThisBlock = block;
}
public override void LoadPublicKey(TreeBuilder tree)
{
tree.AddNode("Elgamal Public Key");
tree.PushByteBlock();
P = tree.ReadMPIBytes("Elgamal Prime p");
G = tree.ReadMPIBytes("Elgamal group generator g");
Y = tree.ReadMPIBytes("Elgamal public key value y");
tree.PopByteBlock();
}
public override void LoadPublicKey(TreeBuilder tree)
{
tree.AddNode("DSA Public Key");
tree.PushByteBlock();
P = tree.ReadMPIBytes("DSA Prime p");
Q = tree.ReadMPIBytes("DSA group order q");
G = tree.ReadMPIBytes("DSA group generator g");
Y = tree.ReadMPIBytes("DSA public key value y");
tree.PopByteBlock();
}
public override ITransformedData LoadPublicKeyTransformedData(TreeBuilder tree)
{
var Data = new PublicKeyTransformedRSAData();
tree.AddNode("RSA Encrypted Data");
tree.PushByteBlock();
Data.M_E_ModN = tree.ReadMPIBytes("m ^ e Mod n");
tree.PopByteBlock();
return(Data);
}
public override void Parse(TreeBuilder tree)
{
tree.SetBookMark();
Version = tree.ReadByte("Version");
tree.ReadFormatted("Creation Time", BlockFormat.UnixTime);
if (Version == 2 || Version == 3 || Version == 4)
{
if (Version != 4)
{
tree.ReadNumber("Days Valid", 2);
}
}
else
{
throw new NotImplementedException("Unknown Public Key Packet Version Code: " + Version.ToString());
}
byte AlgoCode = tree.ReadByte("Public Key Algorithm", PKAlgorithmTypes.Get);
PublicKeyAlgorithm = PKAlgorithm.CreatePKAlgorithm(AlgoCode);
if (PublicKeyAlgorithm == null)
{
tree.ReadBytes("Unknown Public Key Algorithm");
return;
}
PublicKeyAlgorithm.LoadPublicKey(tree);
PacketDataPublicKey = tree.ReadBytesFromBookMark();
if (Version < 4)
{
// Only RSA is supported
var ModN = ((RSA)PublicKeyAlgorithm).ModN;
//KeyId = BitConverter.ToString(ModN, ModN.Length - 8);
KeyId = ModN.SubArray(ModN.Length - 8, 8);
}
else
{
int l = PacketDataPublicKey.Length;
SHA1 shaM = new SHA1Managed();
byte[] HashContext = new byte[l + 3];
HashContext[0] = 0x99;
HashContext[1] = (byte)((l & 0xFF00) >> 8);
HashContext[2] = (byte)(l & 0x00FF);
Array.Copy(PacketDataPublicKey, 0, HashContext, 3, l);
byte[] result = shaM.ComputeHash(HashContext);
//KeyId = BitConverter.ToString(result, result.Length - 8);
KeyId = result.SubArray(result.Length - 8, 8);
}
tree.AddCalculated("Key Id", BitConverter.ToString(KeyId), KeyId);
}
// Signature Value
// ???
public override ITransformedData LoadPublicKeyTransformedData(TreeBuilder tree)
{
var Data = new PublicKeyTransformedElgamalData();
tree.AddNode("Elgamal Encrypted Data");
tree.PushByteBlock();
Data.G_K_ModP = tree.ReadMPIBytes("g ^ k Mod p");
Data.M_Y_K_ModP = tree.ReadMPIBytes("m * y ^ k Mod p");
tree.PopByteBlock();
return(Data);
}
public override ITransformedData LoadSecretKeyTransformedData(TreeBuilder tree)
{
var Data = new SecretKeyTransformedRSAData();
tree.AddNode("RSA Signed Data");
tree.PushByteBlock();
Data.M_D_ModN = tree.ReadMPIBytes("m ^ d Mod n");
tree.PopByteBlock();
return(Data);
}
public override ITransformedData LoadSecretKeyTransformedData(TreeBuilder tree)
{
var Data = new SecretKeyTransformedDSAData();
tree.AddNode("DSA Signed Data");
tree.PushByteBlock();
Data.R = tree.ReadMPIBytes("r");
Data.S = tree.ReadMPIBytes("r");
tree.PopByteBlock();
return(Data);
}
public override void Parse(TreeBuilder tree)
{
tree.ReadByte("Data Format", true);
byte FileNameLength = tree.ReadByte();
byte[] FileNameBytes = tree.ReadBytes("File Name", FileNameLength, true);
ExtractFileName = System.Text.Encoding.UTF8.GetString(FileNameBytes);
tree.ReadFormatted("Date/Time", BlockFormat.UnixTime);
tree.RemainingBytes("Literal Data");
ThisBlock = tree.CurrentBlock;
ThisBlock.ProcessBlock += ExtractData;
}
private void ReadByteTags(TreeBuilder tree, string Label, int DataLength, Func <byte, string> DescFunc)
{
tree.AddNode(Label);
tree.PushByteBlock();
//tree.AddChildLevel = true;
while (DataLength-- > 0)
{
tree.SetBookMark();
byte ByteCode = tree.ReadByte();
tree.GoToBookMark();
//tree.Seek(-1);
tree.ReadByte(DescFunc(ByteCode));
}
tree.PopByteBlock();
}
//public HashAlgorithm HashAlgo { private set; get; }
public override void Parse(TreeBuilder tree)
{
Version = tree.ReadByte("Version");
SignatureType = tree.ReadByte("Signature Type", SignatureTypes.Get);
HashAlgorithm = tree.ReadByte("Hash Algorithm", HashAlgorithmTypes.Get);
//try
//{
// HashAlgo = null;
// HashAlgo = HashAlgorithmTypes.GetHashAlgoManaged(HashAlgorithm);
//}
//catch { }
PKAlgorithm = tree.ReadByte("Primary Key Algorithm", PKAlgorithmTypes.Get);
tree.ReadBytes("Key ID", 8);
Flag = tree.ReadByte("Flag");
}
public override void Parse(TreeBuilder tree)
{
Version = tree.ReadByte("Version");
KeyId = tree.ReadBytes("Key Id", 8);
PKAlgoCode = tree.ReadByte("PK Algorithm", PKAlgorithmTypes.Get);
var PublicKeyAlgorithm = PKAlgorithm.CreatePKAlgorithm(PKAlgoCode);
PublicKeyTransformedData = null;
if (PublicKeyAlgorithm == null)
{
tree.ReadBytes("Unknowon Encrypted Session Key");
}
else
{
PublicKeyTransformedData = PublicKeyAlgorithm.LoadPublicKeyTransformedData(tree);
}
}
public override void Parse(TreeBuilder tree)
{
base.Parse(tree);
bool IsEncrypted = true;
tree.SetBookMark();
var S2K = new S2K
{
S2KUsage = tree.ReadByte()
};
if (S2K.S2KUsage == 254 || S2K.S2KUsage == 255)
{
S2K.SymAlgo = tree.ReadByte("Symmetric Algorithm", SymmetricAlgorithmTypes.Get);
byte S2KSpecifier = tree.ReadByte("S2K Specifier", S2KTypes.Get);
if (S2KSpecifier != S2KTypes.Salted && S2KSpecifier != S2KTypes.Simple && S2KSpecifier != S2KTypes.IteratedAndSalted)
{
//tree.AddCalculated("Invalid S2K", S2KSpecifier.ToString());
tree.AddCalculated("Unable to Process", S2KSpecifier.ToString(), ByteBlockType.CalculatedError);
return;
}
S2K.HashAlgorithm = tree.ReadByte("Hash Algorithm", HashAlgorithmTypes.Get);
if (S2KSpecifier == S2KTypes.Salted || S2KSpecifier == S2KTypes.IteratedAndSalted)
{
S2K.Salt = tree.ReadBytes("Salt", 8);
if (S2KSpecifier == S2KTypes.IteratedAndSalted)
{
byte CodedCount = tree.ReadByte("Coded Iteration");
S2K.ByteCount = (16 + (CodedCount & 15)) << ((CodedCount >> 4) + 6);
}
}
int BlockSizeBytes = SymmetricAlgorithmTypes.GetBlockSize(S2K.SymAlgo) / 8;
S2K.IV = tree.ReadBytes("IV", BlockSizeBytes);
}
else
{
byte SymAlgo = S2K.S2KUsage;
S2K.SymAlgo = SymAlgo;
if (SymAlgo != 0)
{
tree.GoToBookMark();
tree.ReadByte("Symmetric Algorithm", SymmetricAlgorithmTypes.Get);
int BlockSize = SymmetricAlgorithmTypes.GetBlockSize(SymAlgo) / 8;
S2K.IV = tree.ReadBytes("IV", BlockSize);
}
else
{
IsEncrypted = false;
}
}
PublicKeyAlgorithm.S2K = S2K;
if (IsEncrypted)
{
byte[] Encrypted = tree.ReadBytes("Encrypted Secret Key");
PublicKeyAlgorithm.EncryptedPrivateKey = Encrypted;
tree.CurrentBlock.ProcessBlock += ExtractPrivateKey;
SecretKeyNode = tree.CurrentBlock;
}
else
{
byte[] ClearBytes = tree.ReadBytes("Unencrypted Secret Key");
var SecBlockClear = PublicKeyAlgorithm.SetPrivate(ClearBytes);
tree.AddChild(PublicKeyAlgorithm.GetPrivateByteBlocks());
}
}
public override ITransformedData LoadSecretKeyTransformedData(TreeBuilder tree)
{
throw new NotImplementedException();
}
public abstract ITransformedData LoadSecretKeyTransformedData(TreeBuilder tree);
public abstract void Parse(TreeBuilder tree);
public override void Parse(TreeBuilder tree)
{
tree.ReadBytes("SHA-1", 20);
}
public override void Parse(TreeBuilder tree)
{
UserIDBytes = tree.ReadBytes("User Id", true);
}
public override void Parse(TreeBuilder tree)
{
}
public void Parse(TreeBuilder tree, int SubPacketsLength)
{
long SubPacketsEnd = tree.BaseReader.Position + SubPacketsLength;
tree.PushByteBlock();
//if (tree.Position < SubPacketsEnd)
// tree.AddChildLevel = true;
while (tree.BaseReader.Position < SubPacketsEnd)
{
byte LengthFinder = tree.ReadByte();
uint SubPacketLength = 0;
if (LengthFinder < 192)
{
SubPacketLength = LengthFinder;
}
else if (LengthFinder < 255)
{
byte b = tree.ReadByte();
SubPacketLength = (uint)((LengthFinder - 192) << 8) + b + 192;
}
else
{
byte[] b = new byte[4];
b[0] = tree.ReadByte();
b[1] = tree.ReadByte();
b[2] = tree.ReadByte();
b[3] = tree.ReadByte();
SubPacketLength = Program.GetBigEndian(b, 0, 4);
}
byte SubPacketType = tree.ReadByte();
string Label = SignatureSubPacketTypes.Get(SubPacketType);
int DataLength = (int)SubPacketLength - 1;
if (SubPacketType == SignatureSubPacketTypes.SignatureCreationTime)
{
tree.ReadFormatted(Label, BlockFormat.UnixTime);
}
else if (SubPacketType == SignatureSubPacketTypes.Issuer)
{
Issuer = tree.ReadBytes(Label, 8);
}
else if (SubPacketType == SignatureSubPacketTypes.KeyExpirationTime)
{
tree.ReadFormatted(Label, BlockFormat.Days);
}
else if (SubPacketType == SignatureSubPacketTypes.PreferredSymmetricAlgorithm)
{
ReadByteTags(tree, Label, DataLength, SymmetricAlgorithmTypes.Get);
}
else if (SubPacketType == SignatureSubPacketTypes.PreferredHashAlgorithm)
{
ReadByteTags(tree, Label, DataLength, HashAlgorithmTypes.Get);
}
else if (SubPacketType == SignatureSubPacketTypes.PreferredCompressionAlgorithm)
{
ReadByteTags(tree, Label, DataLength, CompressionAlgorithmTypes.Get);
}
else if (SubPacketType == SignatureSubPacketTypes.KeyFlags)
{
ReadByteTags(tree, Label, DataLength, KeyFlagsTypes.Get);
}
else if (SubPacketType == SignatureSubPacketTypes.PrimaryUserId)
{
tree.ReadBytes(Label, DataLength);
}
else if (SubPacketType == SignatureSubPacketTypes.ReasonForRevocation)
{
tree.AddNode(Label);
tree.PushByteBlock();
tree.ReadByte("Reason", RevocationReasonTypes.Get);
tree.ReadBytes("Message", DataLength - 1);
tree.PopByteBlock();
}
else
{
tree.ReadBytes(Label, DataLength);
}
}
tree.PopByteBlock();
}
public abstract void LoadPublicKey(TreeBuilder tree);
public static ByteBlock Process(string PGPFile)
{
var Root = new ByteBlock();
PGPPacket pgp;
PublicKeyPacket PrimaryKeyPacket = null;
PublicKeyPacket SubKeyPacket = null;
UserIDPacket UIDPacket = null;
Stack <OnePassSignaturePacket> OPSigPacketStack = new Stack <OnePassSignaturePacket>();
HashAlgorithm[] HashAlgorithms = null;
using (var PacketReader = new PGPReader(PGPFile))
{
PacketReader.DoIndexUpdate += IndexUpdate;
while ((pgp = PacketReader.ReadNextPacket()) != null)
{
TreeBuilder Tree = new TreeBuilder(PacketReader);
pgp.Parse(Tree);
if (pgp is LiteralDataPacket litPgp)
{
if (HashAlgorithms == null)
{
HashAlgorithms = GetHashAlgorithms(OPSigPacketStack);
}
litPgp.ProgressUpdate += StatusUpdate;
litPgp.DoHash(PacketReader, HashAlgorithms);
}
else
{
if (pgp is OnePassSignaturePacket OPSig)
{
OPSigPacketStack.Push(OPSig);
}
else if (pgp.PacketTag == 6 || pgp.PacketTag == 5)
{
PrimaryKeyPacket = (PublicKeyPacket)pgp;
}
else if (pgp is UserIDPacket)
{
UIDPacket = (UserIDPacket)pgp;
}
else if (pgp.PacketTag == 14 || pgp.PacketTag == 7)
{
SubKeyPacket = (PublicKeyPacket)pgp;
}
else if (pgp is SignaturePacket Sig)
{
if ((Sig.SignatureType == 0x18 || Sig.SignatureType == 0x19) && PrimaryKeyPacket != null && SubKeyPacket != null && SubKeyPacket.PacketDataPublicKey != null)
{
Sig.GenerateSubKeyBindingHash(PrimaryKeyPacket, SubKeyPacket);
}
if (Sig.SignatureType >= 0x10 && Sig.SignatureType <= 0x13 && PrimaryKeyPacket != null && UIDPacket != null)
{
Sig.GenerateCertifyHash(PrimaryKeyPacket, UIDPacket);
}
// Signature of a Binary Document
if (Sig.SignatureType == 0x00)
{
// Are we generating hash for One Pass Signature Packet
if (OPSigPacketStack.Count() > 0)
{
var OnePassSignaturePacket = OPSigPacketStack.Pop();
if (OnePassSignaturePacket.HashAlgorithm == Sig.HashAlgorithm)
{
Sig.GenerateBinaryHash(HashAlgorithmTypes.GetHashAlgoManaged(Sig.HashAlgorithm, HashAlgorithms));
}
}
}
}
}
PacketBlock pb = new PacketBlock(pgp);
pb.AddChildBlock(Tree.StartBlock);
Root.AddChildBlock(pb);
_PacketNodes.Add(pb);
}
}
return(Root.ChildBlock);
}
public override void Parse(TreeBuilder tree)
{
Version = tree.ReadByte("Version");
SignatureType = tree.ReadByte("Signature Type", SignatureTypes.Get);
PKAlgo = tree.ReadByte("Public Key Algorithm", PKAlgorithmTypes.Get);
if (Version == 4)
{
uint SubPacketLength;
HashAlgorithm = tree.ReadByte("Hash Algorithm", HashAlgorithmTypes.Get);
SubPacketLength = tree.ReadNumber(2);
tree.SetBookMark();
HashedSubPacketBytes = tree.ReadBytes("Hashed Sub Packet", (int)SubPacketLength);
//tree.Seek(-SubPacketLength);
tree.GoToBookMark();
var HashedSubPackets = new SignatureSubPackets();
HashedSubPackets.Parse(tree, (int)SubPacketLength);
SubPacketLength = tree.ReadNumber(2);
tree.SetBookMark();
UnHashedSubPacketBytes = tree.ReadBytes("Unhashed Sub Packet", (int)SubPacketLength);
//tree.Seek(-SubPacketLength);
tree.GoToBookMark();
var UnHashedSubPackets = new SignatureSubPackets();
UnHashedSubPackets.Parse(tree, (int)SubPacketLength);
Issuer = UnHashedSubPackets.Issuer;
tree.ReadBytes("Left 16 Bit Hash", 2);
var PublicKeyAlgorithm = PKAlgorithm.CreatePKAlgorithm(PKAlgo);
SecretKeyTransformedData = null;
if (PublicKeyAlgorithm == null)
{
tree.ReadBytes("Unknowon Signature");
}
else
{
SecretKeyTransformedData = PublicKeyAlgorithm.LoadSecretKeyTransformedData(tree);
}
//if (PublicKeySignature != null)
//{
// tree.AddNode("Signature");
// tree.AddChild(PublicKeySignature.LoadSignatureValue(tree.ReadMPIBytes));
//}
//else
// tree.ReadBytes("Signature");
}
else
{
throw new NotImplementedException("Not Implemented");
}
}