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public static Create ( |
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| symDef | ||
| keyData | byte | |
| iv | byte | |
| return | ||
/// <summary>
/// Creates a *software* root key. The key will be random (not created from a seed). The key can be used
/// as the root of a software hierarchy that can be translated into a duplication blob ready for import into
/// a TPM. Depending on the type of key, the software root key can be a parent for other root keys that can
/// comprise a migration group. The caller should specify necessary key parameters in Public.
/// </summary>
/// <returns></returns>
public static TssObject CreateStorageParent(TpmPublic keyParameters, AuthValue authVal)
{
var newKey = new TssObject();
// Create a new asymmetric key from the supplied parameters
IPublicIdUnion publicId;
ISensitiveCompositeUnion sensitiveData = CreateSensitiveComposite(keyParameters, out publicId);
// fill in the public data
newKey.publicPart = keyParameters.Copy();
newKey.publicPart.unique = publicId;
// Create the associated symmetric key -
SymDefObject symDef = GetSymDef(keyParameters);
byte[] symmKey;
if (symDef.Algorithm != TpmAlgId.Null)
{
using (var symmCipher = SymmCipher.Create(symDef))
{
symmKey = symmCipher.KeyData;
}
}
else
{
symmKey = new byte[0];
}
// Fill in the fields for the symmetric private-part of the asymmetric key
var sens = new Sensitive(authVal.AuthVal, symmKey, sensitiveData);
newKey.sensitivePart = sens;
// And return the new key
return(newKey);
}
/// <summary>
/// Create activation blobs that can be passed to ActivateCredential. Two blobs are returned -
/// (a) - encryptedSecret - is the symmetric key cfb-symmetrically encrypted with an enveloping key
/// (b) credentialBlob (the return value of this function) - is the enveloping key OEAP (RSA) encrypted
/// by the public part of this key.
/// </summary>
/// <param name="secret"></param>
/// <param name="nameAlgId"></param>
/// <param name="nameOfKeyToBeActivated"></param>
/// <param name="encryptedSecret"></param>
/// <returns>CredentialBlob (</returns>
public byte[] CreateActivationCredentials(
byte[] secret,
TpmAlgId nameAlgId,
byte[] nameOfKeyToBeActivated,
out byte[] encryptedSecret)
{
byte[] seed, encSecret;
switch (type)
{
case TpmAlgId.Rsa:
// The seed should be the same size as the symmKey
seed = Globs.GetRandomBytes((CryptoLib.DigestSize(nameAlg) + 7) / 8);
encSecret = EncryptOaep(seed, ActivateEncodingParms);
break;
case TpmAlgId.Ecc:
EccPoint pubEphem;
seed = EcdhGetKeyExchangeKey(ActivateEncodingParms, nameAlg, out pubEphem);
encSecret = Marshaller.GetTpmRepresentation(pubEphem);
break;
default:
Globs.Throw <NotImplementedException>("CreateActivationCredentials: Unsupported algorithm");
encryptedSecret = new byte[0];
return(new byte[0]);
}
var cvx = new Tpm2bDigest(secret);
byte[] cvTpm2B = Marshaller.GetTpmRepresentation(cvx);
SymDefObject symDef = TssObject.GetSymDef(this);
byte[] symKey = KDF.KDFa(nameAlg, seed, "STORAGE", nameOfKeyToBeActivated, new byte[0], symDef.KeyBits);
byte[] encIdentity;
using (SymmCipher symm2 = SymmCipher.Create(symDef, symKey))
{
encIdentity = symm2.Encrypt(cvTpm2B);
}
var hmacKeyBits = CryptoLib.DigestSize(nameAlg);
byte[] hmacKey = KDF.KDFa(nameAlg, seed, "INTEGRITY", new byte[0], new byte[0], hmacKeyBits * 8);
byte[] outerHmac = CryptoLib.HmacData(nameAlg,
hmacKey,
Globs.Concatenate(encIdentity, nameOfKeyToBeActivated));
byte[] activationBlob = Globs.Concatenate(
Marshaller.ToTpm2B(outerHmac),
encIdentity);
encryptedSecret = encSecret;
return(activationBlob);
}
internal byte[] ParmEncrypt(byte[] parm, Direction inOrOut)
{
if (Symmetric == null)
{
Globs.Throw("parameter encryption cipher not defined");
return(parm);
}
if (Symmetric.Algorithm == TpmAlgId.Null)
{
return(parm);
}
byte[] nonceNewer, nonceOlder;
if (inOrOut == Direction.Command)
{
nonceNewer = NonceCaller;
nonceOlder = NonceTpm;
}
else
{
nonceNewer = NonceTpm;
nonceOlder = NonceCaller;
}
byte[] encKey = (AuthHandle != null && AuthHandle.Auth != null)
? SessionKey.Concat(Globs.TrimTrailingZeros(AuthHandle.Auth)).ToArray()
: SessionKey;
if (Symmetric.Algorithm == TpmAlgId.Xor)
{
return(CryptoLib.KdfThenXor(AuthHash, encKey, nonceNewer, nonceOlder, parm));
}
int keySize = (Symmetric.KeyBits + 7) / 8,
blockSize = SymmCipher.GetBlockSize(Symmetric),
bytesRequired = keySize + blockSize;
byte[] keyInfo = KDF.KDFa(AuthHash, encKey, "CFB", nonceNewer, nonceOlder, bytesRequired * 8);
var key = new byte[keySize];
Array.Copy(keyInfo, 0, key, 0, keySize);
var iv = new byte[blockSize];
Array.Copy(keyInfo, keySize, iv, 0, blockSize);
// Make a new SymmCipher from the key and IV and do the encryption.
using (SymmCipher s = SymmCipher.Create(Symmetric, key, iv))
{
return(inOrOut == Direction.Command ? s.Encrypt(parm) : s.Decrypt(parm));
}
}
/// <summary>
/// Creates a duplication blob for the current key that can be Imported as a child
/// of newParent. Three forms are possible. GetPlaintextDuplicationBlob() allows
/// plaintext-import. This function enables duplication with and without an
/// inner wrapper (depending on whether innerWrapper is null)
/// </summary>
/// <param name="newParent"></param>
/// <param name="innerWrapper"></param>
/// <param name="encryptedWrappingKey"></param>
/// <returns></returns>
public TpmPrivate GetDuplicationBlob(
TpmPublic newParent,
SymmCipher innerWrapper,
out byte[] encryptedWrappingKey)
{
byte[] encSensitive;
if (innerWrapper == null)
{
// No inner wrapper
encSensitive = Marshaller.ToTpm2B(sensitivePart.GetTpmRepresentation());
}
else
{
byte[] sens = Marshaller.ToTpm2B(sensitivePart.GetTpmRepresentation());
byte[] toHash = Globs.Concatenate(sens, GetName());
byte[] innerIntegrity = Marshaller.ToTpm2B(CryptoLib.HashData(publicPart.nameAlg, toHash));
byte[] innerData = Globs.Concatenate(innerIntegrity, sens);
encSensitive = innerWrapper.Encrypt(innerData);
}
byte[] seed, encSecret;
SymDefObject symDef = GetSymDef(newParent);
using (AsymCryptoSystem newParentPubKey = AsymCryptoSystem.CreateFrom(newParent))
{
switch (newParent.type)
{
case TpmAlgId.Rsa:
// The seed should be the same size as the symmKey
seed = Globs.GetRandomBytes((symDef.KeyBits + 7) / 8);
encSecret = newParentPubKey.EncryptOaep(seed, DuplicateEncodingParms);
break;
case TpmAlgId.Ecc:
EccPoint pubEphem;
seed = newParentPubKey.EcdhGetKeyExchangeKey(DuplicateEncodingParms,
newParent.nameAlg,
out pubEphem);
encSecret = Marshaller.GetTpmRepresentation(pubEphem);
break;
default:
Globs.Throw <NotImplementedException>("GetDuplicationBlob: Unsupported algorithm");
encryptedWrappingKey = new byte[0];
return(new TpmPrivate());
}
}
encryptedWrappingKey = encSecret;
byte[] symKey = KDF.KDFa(newParent.nameAlg, seed, "STORAGE", publicPart.GetName(), new byte[0], symDef.KeyBits);
byte[] dupSensitive;
using (SymmCipher enc2 = SymmCipher.Create(symDef, symKey))
{
dupSensitive = enc2.Encrypt(encSensitive);
}
var npNameNumBits = CryptoLib.DigestSize(newParent.nameAlg) * 8;
byte[] hmacKey = KDF.KDFa(newParent.nameAlg, seed, "INTEGRITY", new byte[0], new byte[0], npNameNumBits);
byte[] outerDataToHmac = Globs.Concatenate(dupSensitive, publicPart.GetName());
byte[] outerHmac = Marshaller.ToTpm2B(CryptoLib.HmacData(newParent.nameAlg, hmacKey, outerDataToHmac));
byte[] dupBlob = Globs.Concatenate(outerHmac, dupSensitive);
return(new TpmPrivate(dupBlob));
}
