示例#1
0
            void AES_CTR_Cipher_BCrypt::IncrementCounter(CryptoBuffer& buffer)
            {
                assert(buffer.GetLength() == BlockSizeBytes);

                int32_t ctr = 0;
                for (size_t i = BlockSizeBytes - 5; i < BlockSizeBytes; ++i)
                {
                    ctr <<= 8;
                    ctr |= buffer[i];
                }

                ctr += 1;

                for (size_t i = BlockSizeBytes - 1; i > BlockSizeBytes - 5; --i)
                {
                    buffer[i] = ctr & 0x000000FF;
                    ctr >>= 8;
                }
            }
示例#2
0
static nsresult
AssembleClientData(const nsAString& aOrigin, const nsAString& aTyp,
                   const nsAString& aChallenge, CryptoBuffer& aClientData)
{
  ClientData clientDataObject;
  clientDataObject.mTyp.Construct(aTyp); // "Typ" from the U2F specification
  clientDataObject.mChallenge.Construct(aChallenge);
  clientDataObject.mOrigin.Construct(aOrigin);

  nsAutoString json;
  if (NS_WARN_IF(!clientDataObject.ToJSON(json))) {
    return NS_ERROR_FAILURE;
  }

  if (NS_WARN_IF(!aClientData.Assign(NS_ConvertUTF16toUTF8(json)))) {
    return NS_ERROR_FAILURE;
  }

  return NS_OK;
}
示例#3
0
UniqueSECKEYPublicKey
CryptoKey::PublicECKeyFromRaw(CryptoBuffer& aKeyData,
                              const nsString& aNamedCurve,
                              const nsNSSShutDownPreventionLock& /*proofOfLock*/)
{
  UniquePLArenaPool arena(PORT_NewArena(DER_DEFAULT_CHUNKSIZE));
  if (!arena) {
    return nullptr;
  }

  SECItem rawItem = { siBuffer, nullptr, 0 };
  if (!aKeyData.ToSECItem(arena.get(), &rawItem)) {
    return nullptr;
  }

  uint32_t flen;
  if (aNamedCurve.EqualsLiteral(WEBCRYPTO_NAMED_CURVE_P256)) {
    flen = 32; // bytes
  } else if (aNamedCurve.EqualsLiteral(WEBCRYPTO_NAMED_CURVE_P384)) {
    flen = 48; // bytes
  } else if (aNamedCurve.EqualsLiteral(WEBCRYPTO_NAMED_CURVE_P521)) {
    flen = 66; // bytes
  } else {
    return nullptr;
  }

  // Check length of uncompressed point coordinates. There are 2 field elements
  // and a leading point form octet (which must EC_POINT_FORM_UNCOMPRESSED).
  if (rawItem.len != (2 * flen + 1)) {
    return nullptr;
  }

  // No support for compressed points.
  if (rawItem.data[0] != EC_POINT_FORM_UNCOMPRESSED) {
    return nullptr;
  }

  return CreateECPublicKey(&rawItem, aNamedCurve);
}
示例#4
0
NS_IMETHODIMP
U2FSignTask::Run()
{
  nsNSSShutDownPreventionLock locker;
  if (isAlreadyShutDown()) {
    ReturnError(ErrorCode::OTHER_ERROR);
    return NS_ERROR_FAILURE;
  }

  // Search the requests for one a token can fulfill
  for (size_t i = 0; i < mRegisteredKeys.Length(); i += 1) {
    RegisteredKey request(mRegisteredKeys[i]);

    // Check for required attributes
    if (!(request.mVersion.WasPassed() &&
          request.mKeyHandle.WasPassed())) {
      continue;
    }

    // Do not permit an individual RegisteredKey to assert a different AppID
    if (request.mAppId.WasPassed() && mAppId != request.mAppId.Value()) {
      continue;
    }

    // Assemble a clientData object
    CryptoBuffer clientData;
    nsresult rv = AssembleClientData(mOrigin, kGetAssertion, mChallenge,
                                     clientData);
    if (NS_WARN_IF(NS_FAILED(rv))) {
      ReturnError(ErrorCode::OTHER_ERROR);
      return NS_ERROR_FAILURE;
    }

    // Hash the AppID and the ClientData into the AppParam and ChallengeParam
    SECStatus srv;
    nsCString cAppId = NS_ConvertUTF16toUTF8(mAppId);
    CryptoBuffer appParam;
    CryptoBuffer challengeParam;
    if (!appParam.SetLength(SHA256_LENGTH, fallible) ||
        !challengeParam.SetLength(SHA256_LENGTH, fallible)) {
      ReturnError(ErrorCode::OTHER_ERROR);
      return NS_ERROR_FAILURE;
    }

    srv = PK11_HashBuf(SEC_OID_SHA256, appParam.Elements(),
                       reinterpret_cast<const uint8_t*>(cAppId.BeginReading()),
                       cAppId.Length());
    if (srv != SECSuccess) {
      ReturnError(ErrorCode::OTHER_ERROR);
      return NS_ERROR_FAILURE;
    }

    srv = PK11_HashBuf(SEC_OID_SHA256, challengeParam.Elements(),
                       clientData.Elements(), clientData.Length());
    if (srv != SECSuccess) {
      ReturnError(ErrorCode::OTHER_ERROR);
      return NS_ERROR_FAILURE;
    }

    // Decode the key handle
    CryptoBuffer keyHandle;
    rv = keyHandle.FromJwkBase64(request.mKeyHandle.Value());
    if (NS_WARN_IF(NS_FAILED(rv))) {
      ReturnError(ErrorCode::OTHER_ERROR);
      return NS_ERROR_FAILURE;
    }

    // Get the signature from the token
    CryptoBuffer signatureData;
    bool signSuccess = false;

    // We ignore mTransports, as it is intended to be used for sorting the
    // available devices by preference, but is not an exclusion factor.

    for (size_t a = 0; a < mAuthenticators.Length() && !signSuccess; ++a) {
      Authenticator token(mAuthenticators[a]);
      bool isCompatible = false;
      bool isRegistered = false;

      rv = token->IsCompatibleVersion(request.mVersion.Value(), &isCompatible);
      if (NS_FAILED(rv)) {
        ReturnError(ErrorCode::OTHER_ERROR);
        return NS_ERROR_FAILURE;
      }
      if (!isCompatible) {
        continue;
      }

      rv = token->IsRegistered(keyHandle.Elements(), keyHandle.Length(),
                               &isRegistered);
      if (NS_FAILED(rv)) {
        ReturnError(ErrorCode::OTHER_ERROR);
        return NS_ERROR_FAILURE;
      }

      if (isCompatible && isRegistered) {
        uint8_t* buffer;
        uint32_t bufferlen;
        nsresult rv = token->Sign(appParam.Elements(), appParam.Length(),
                                  challengeParam.Elements(), challengeParam.Length(),
                                  keyHandle.Elements(), keyHandle.Length(),
                                  &buffer, &bufferlen);
        if (NS_FAILED(rv)) {
          ReturnError(ErrorCode::OTHER_ERROR);
          return NS_ERROR_FAILURE;
        }

        MOZ_ASSERT(buffer);
        signatureData.Assign(buffer, bufferlen);
        free(buffer);
        signSuccess = true;
      }
    }

    if (!signSuccess) {
      // Try another request
      continue;
    }

    // Assemble a response object to return
    nsString clientDataBase64, signatureDataBase64;
    nsresult rvClientData =
      clientData.ToJwkBase64(clientDataBase64);
    nsresult rvSignatureData =
      signatureData.ToJwkBase64(signatureDataBase64);
    if (NS_WARN_IF(NS_FAILED(rvClientData)) ||
        NS_WARN_IF(NS_FAILED(rvSignatureData))) {
      ReturnError(ErrorCode::OTHER_ERROR);
      return NS_ERROR_FAILURE;
    }
    SignResponse response;
    response.mKeyHandle.Construct(request.mKeyHandle.Value());
    response.mClientData.Construct(clientDataBase64);
    response.mSignatureData.Construct(signatureDataBase64);
    response.mErrorCode.Construct(static_cast<uint32_t>(ErrorCode::OK));

    ErrorResult result;
    mCallback->Call(response, result);
    NS_WARN_IF(result.Failed());
    // Useful exceptions already got reported.
    result.SuppressException();
    return NS_OK;
  }

  // Nothing could satisfy
  ReturnError(ErrorCode::DEVICE_INELIGIBLE);
  return NS_ERROR_FAILURE;
}
示例#5
0
nsresult
CryptoKey::PublicKeyToSpki(SECKEYPublicKey* aPubKey,
                           CryptoBuffer& aRetVal,
                           const nsNSSShutDownPreventionLock& /*proofOfLock*/)
{
  ScopedCERTSubjectPublicKeyInfo spki;

  // NSS doesn't support exporting DH public keys.
  if (aPubKey->keyType == dhKey) {
    // Mimic the behavior of SECKEY_CreateSubjectPublicKeyInfo() and create
    // a new arena for the SPKI object.
    ScopedPLArenaPool arena(PORT_NewArena(DER_DEFAULT_CHUNKSIZE));
    if (!arena) {
      return NS_ERROR_DOM_OPERATION_ERR;
    }

    spki = PORT_ArenaZNew(arena, CERTSubjectPublicKeyInfo);
    if (!spki) {
      return NS_ERROR_DOM_OPERATION_ERR;
    }

    // Assign |arena| to |spki| and null the variable afterwards so that the
    // arena created above that holds the SPKI object is free'd when |spki|
    // goes out of scope, not when |arena| does.
    spki->arena = arena.forget();

    nsresult rv = PublicDhKeyToSpki(aPubKey, spki);
    NS_ENSURE_SUCCESS(rv, rv);
  } else {
    spki = SECKEY_CreateSubjectPublicKeyInfo(aPubKey);
    if (!spki) {
      return NS_ERROR_DOM_OPERATION_ERR;
    }
  }

  // Per WebCrypto spec we must export ECDH SPKIs with the algorithm OID
  // id-ecDH (1.3.132.112) and DH SPKIs with OID dhKeyAgreement
  // (1.2.840.113549.1.3.1). NSS doesn't know about these OIDs and there is
  // no way to specify the algorithm to use when exporting a public key.
  if (aPubKey->keyType == ecKey || aPubKey->keyType == dhKey) {
    const SECItem* oidData = nullptr;
    if (aPubKey->keyType == ecKey) {
      oidData = &SEC_OID_DATA_EC_DH;
    } else if (aPubKey->keyType == dhKey) {
      oidData = &SEC_OID_DATA_DH_KEY_AGREEMENT;
    } else {
      MOZ_ASSERT(false);
    }

    SECStatus rv = SECITEM_CopyItem(spki->arena, &spki->algorithm.algorithm,
                                    oidData);
    if (rv != SECSuccess) {
      return NS_ERROR_DOM_OPERATION_ERR;
    }
  }

  const SEC_ASN1Template* tpl = SEC_ASN1_GET(CERT_SubjectPublicKeyInfoTemplate);
  ScopedSECItem spkiItem(SEC_ASN1EncodeItem(nullptr, nullptr, spki, tpl));

  aRetVal.Assign(spkiItem.get());
  return NS_OK;
}
示例#6
0
            /**
            * Windows doesn't expose CTR mode. We can however, build it manually from ECB. Here, split each
            * buffer into 16 byte chunks, for each complete buffer encrypt the counter and xor it against the unencrypted
            * text. Save anything left over for the next run.
            */
            CryptoBuffer AES_CTR_Cipher_BCrypt::EncryptWithCtr(const CryptoBuffer& buffer)
            {
                size_t bytesWritten = 0;
                Aws::Vector<ByteBuffer*> finalBufferSet(0);

                CryptoBuffer bufferToEncrypt;

                if (m_blockOverflow.GetLength() > 0 && &m_blockOverflow != &buffer)
                {
                    bufferToEncrypt = CryptoBuffer({ (ByteBuffer*)&m_blockOverflow, (ByteBuffer*)&buffer });
                    m_blockOverflow = CryptoBuffer();
                }
                else
                {
                    bufferToEncrypt = buffer;
                }

                Aws::Utils::Array<CryptoBuffer> slicedBuffers;

                if (bufferToEncrypt.GetLength() > BlockSizeBytes)
                {
                    slicedBuffers = bufferToEncrypt.Slice(BlockSizeBytes);
                }
                else
                {
                    slicedBuffers = Aws::Utils::Array<CryptoBuffer>(1u);
                    slicedBuffers[0] = bufferToEncrypt;
                }

                finalBufferSet = Aws::Vector<ByteBuffer*>(slicedBuffers.GetLength());
                InitBuffersToNull(finalBufferSet);

                for (size_t i = 0; i < slicedBuffers.GetLength(); ++i)
                {
                    if (slicedBuffers[i].GetLength() == BlockSizeBytes || (m_blockOverflow.GetLength() > 0 && slicedBuffers.GetLength() == 1))
                    {
                        ULONG lengthWritten = static_cast<ULONG>(BlockSizeBytes);
                        CryptoBuffer encryptedText(BlockSizeBytes);

                        NTSTATUS status = BCryptEncrypt(m_keyHandle, m_workingIv.GetUnderlyingData(), (ULONG)m_workingIv.GetLength(),
                            nullptr, nullptr, 0, encryptedText.GetUnderlyingData(), (ULONG)encryptedText.GetLength(), &lengthWritten, m_flags);

                        if (!NT_SUCCESS(status))
                        {
                            m_failure = true;
                            AWS_LOGSTREAM_ERROR(CTR_LOG_TAG, "Failed to compute encrypted output with error code " << status);
                            CleanupBuffers(finalBufferSet);
                            return CryptoBuffer();
                        }

                        CryptoBuffer* newBuffer = Aws::New<CryptoBuffer>(CTR_LOG_TAG, BlockSizeBytes);
                        *newBuffer = slicedBuffers[i] ^ encryptedText;
                        finalBufferSet[i] = newBuffer;
                        IncrementCounter(m_workingIv);
                        bytesWritten += static_cast<size_t>(lengthWritten);
                    }
                    else
                    {
                        m_blockOverflow = slicedBuffers[i];
                        CryptoBuffer* newBuffer = Aws::New<CryptoBuffer>(CTR_LOG_TAG, 0);
                        finalBufferSet[i] = newBuffer;
                    }
                }

                CryptoBuffer returnBuffer(std::move(finalBufferSet));
                CleanupBuffers(finalBufferSet);

                return returnBuffer;
            }
示例#7
0
already_AddRefed<Promise>
WebAuthentication::GetAssertion(const ArrayBufferViewOrArrayBuffer& aChallenge,
                                const AssertionOptions& aOptions)
{
  MOZ_ASSERT(mParent);
  nsCOMPtr<nsIGlobalObject> global = do_QueryInterface(GetParentObject());
  if (!global) {
    return nullptr;
  }

  // 4.1.2.1 If timeoutSeconds was specified, check if its value lies within a
  // reasonable range as defined by the platform and if not, correct it to the
  // closest value lying within that range.

  double adjustedTimeout = 30.0;
  if (aOptions.mTimeoutSeconds.WasPassed()) {
    adjustedTimeout = aOptions.mTimeoutSeconds.Value();
    adjustedTimeout = std::max(15.0, adjustedTimeout);
    adjustedTimeout = std::min(120.0, adjustedTimeout);
  }

  // 4.1.2.2 Let promise be a new Promise. Return promise and start a timer for
  // adjustedTimeout seconds.

  RefPtr<AssertionRequest> requestMonitor = new AssertionRequest();
  requestMonitor->SetDeadline(TimeDuration::FromSeconds(adjustedTimeout));

  ErrorResult rv;
  RefPtr<Promise> promise = Promise::Create(global, rv);

  nsresult initRv = InitLazily();
  if (NS_FAILED(initRv)) {
    promise->MaybeReject(initRv);
    return promise.forget();
  }

  if (mOrigin.EqualsLiteral("null")) {
    // 4.1.2.3 If callerOrigin is an opaque origin, reject promise with a
    // DOMException whose name is "NotAllowedError", and terminate this algorithm
    promise->MaybeReject(NS_ERROR_DOM_NOT_ALLOWED_ERR);
    return promise.forget();
  }

  nsCString rpId;
  if (!aOptions.mRpId.WasPassed()) {
    // 4.1.2.3.a If rpId is not specified, then set rpId to callerOrigin, and
    // rpIdHash to the SHA-256 hash of rpId.
    rpId.Assign(NS_ConvertUTF16toUTF8(mOrigin));
  } else {
    // 4.1.2.3.b If rpId is specified, then invoke the procedure used for
    // relaxing the same-origin restriction by setting the document.domain
    // attribute, using rpId as the given value but without changing the current
    // document’s domain. If no errors are thrown, set rpId to the value of host
    // as computed by this procedure, and rpIdHash to the SHA-256 hash of rpId.
    // Otherwise, reject promise with a DOMException whose name is
    // "SecurityError", and terminate this algorithm.

    if (NS_FAILED(RelaxSameOrigin(aOptions.mRpId.Value(), rpId))) {
      promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
      return promise.forget();
    }
  }

  CryptoBuffer rpIdHash;
  if (!rpIdHash.SetLength(SHA256_LENGTH, fallible)) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  nsresult srv;
  nsCOMPtr<nsICryptoHash> hashService =
    do_CreateInstance(NS_CRYPTO_HASH_CONTRACTID, &srv);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  srv = HashCString(hashService, rpId, rpIdHash);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  // 4.1.2.4 If extensions was specified, process any extensions supported by
  // this client platform, to produce the extension data that needs to be sent
  // to the authenticator. If an error is encountered while processing an
  // extension, skip that extension and do not produce any extension data for
  // it. Call the result of this processing clientExtensions.

  // TODO

  // 4.1.2.5 Use assertionChallenge, callerOrigin and rpId, along with the token
  // binding key associated with callerOrigin (if any), to create a ClientData
  // structure representing this request. Choose a hash algorithm for hashAlg
  // and compute the clientDataJSON and clientDataHash.
  CryptoBuffer challenge;
  if (!challenge.Assign(aChallenge)) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  nsAutoCString clientDataJSON;
  srv = AssembleClientData(mOrigin, challenge, clientDataJSON);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  CryptoBuffer clientDataHash;
  if (!clientDataHash.SetLength(SHA256_LENGTH, fallible)) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  srv = HashCString(hashService, clientDataJSON, clientDataHash);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  // Note: we only support U2F-style authentication for now, so we effectively
  // require an AllowList.
  if (!aOptions.mAllowList.WasPassed()) {
    promise->MaybeReject(NS_ERROR_DOM_NOT_ALLOWED_ERR);
    return promise.forget();
  }

  const Sequence<ScopedCredentialDescriptor>& allowList =
    aOptions.mAllowList.Value();

  // 4.1.2.6 Initialize issuedRequests to an empty list.
  RefPtr<AssertionPromise> monitorPromise = requestMonitor->Ensure();

  // 4.1.2.7 For each authenticator currently available on this platform,
  // perform the following steps:
  for(Authenticator u2ftoken : mAuthenticators) {
    // 4.1.2.7.a If allowList is undefined or empty, let credentialList be an
    // empty list. Otherwise, execute a platform-specific procedure to determine
    // which, if any, credentials listed in allowList might be present on this
    // authenticator, and set credentialList to this filtered list. If no such
    // filtering is possible, set credentialList to an empty list.

    nsTArray<CryptoBuffer> credentialList;

    for (const ScopedCredentialDescriptor& scd : allowList) {
      CryptoBuffer buf;
      if (NS_WARN_IF(!buf.Assign(scd.mId))) {
        continue;
      }

      // 4.1.2.7.b For each credential C within the credentialList that has a
      // non- empty transports list, optionally use only the specified
      // transports to get assertions using credential C.

      // TODO: Filter using Transport
      if (!credentialList.AppendElement(buf, mozilla::fallible)) {
        requestMonitor->CancelNow();
        promise->MaybeReject(NS_ERROR_OUT_OF_MEMORY);
        return promise.forget();
      }
    }

    // 4.1.2.7.c If the above filtering process concludes that none of the
    // credentials on allowList can possibly be on this authenticator, do not
    // perform any of the following steps for this authenticator, and proceed to
    // the next authenticator (if any).
    if (credentialList.IsEmpty()) {
      continue;
    }

    // 4.1.2.7.d Asynchronously invoke the authenticatorGetAssertion operation
    // on this authenticator with rpIdHash, clientDataHash, credentialList, and
    // clientExtensions as parameters.
    U2FAuthGetAssertion(requestMonitor, u2ftoken, rpIdHash, clientDataJSON,
                        clientDataHash, credentialList, aOptions.mExtensions);
  }

  requestMonitor->CompleteTask();

  monitorPromise->Then(AbstractThread::MainThread(), __func__,
    [promise] (AssertionPtr aAssertion) {
      promise->MaybeResolve(aAssertion);
    },
    [promise] (nsresult aErrorCode) {
      promise->MaybeReject(aErrorCode);
  });

  return promise.forget();
}
示例#8
0
already_AddRefed<Promise>
WebAuthentication::MakeCredential(JSContext* aCx, const Account& aAccount,
                  const Sequence<ScopedCredentialParameters>& aCryptoParameters,
                  const ArrayBufferViewOrArrayBuffer& aChallenge,
                  const ScopedCredentialOptions& aOptions)
{
  MOZ_ASSERT(mParent);
  nsCOMPtr<nsIGlobalObject> global = do_QueryInterface(GetParentObject());
  if (!global) {
    return nullptr;
  }

  ErrorResult rv;
  RefPtr<Promise> promise = Promise::Create(global, rv);

  nsresult initRv = InitLazily();
  if (NS_FAILED(initRv)) {
    promise->MaybeReject(initRv);
    return promise.forget();
  }

  // 4.1.1.1 If timeoutSeconds was specified, check if its value lies within a
  // reasonable range as defined by the platform and if not, correct it to the
  // closest value lying within that range.

  double adjustedTimeout = 30.0;
  if (aOptions.mTimeoutSeconds.WasPassed()) {
    adjustedTimeout = aOptions.mTimeoutSeconds.Value();
    adjustedTimeout = std::max(15.0, adjustedTimeout);
    adjustedTimeout = std::min(120.0, adjustedTimeout);
  }

  // 4.1.1.2 Let promise be a new Promise. Return promise and start a timer for
  // adjustedTimeout seconds.

  RefPtr<CredentialRequest> requestMonitor = new CredentialRequest();
  requestMonitor->SetDeadline(TimeDuration::FromSeconds(adjustedTimeout));

  if (mOrigin.EqualsLiteral("null")) {
    // 4.1.1.3 If callerOrigin is an opaque origin, reject promise with a
    // DOMException whose name is "NotAllowedError", and terminate this
    // algorithm
    MOZ_LOG(gWebauthLog, LogLevel::Debug, ("Rejecting due to opaque origin"));
    promise->MaybeReject(NS_ERROR_DOM_NOT_ALLOWED_ERR);
    return promise.forget();
  }

  nsCString rpId;
  if (!aOptions.mRpId.WasPassed()) {
    // 4.1.1.3.a If rpId is not specified, then set rpId to callerOrigin, and
    // rpIdHash to the SHA-256 hash of rpId.
    rpId.Assign(NS_ConvertUTF16toUTF8(mOrigin));
  } else {
    // 4.1.1.3.b If rpId is specified, then invoke the procedure used for
    // relaxing the same-origin restriction by setting the document.domain
    // attribute, using rpId as the given value but without changing the current
    // document’s domain. If no errors are thrown, set rpId to the value of host
    // as computed by this procedure, and rpIdHash to the SHA-256 hash of rpId.
    // Otherwise, reject promise with a DOMException whose name is
    // "SecurityError", and terminate this algorithm.

    if (NS_FAILED(RelaxSameOrigin(aOptions.mRpId.Value(), rpId))) {
      promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
      return promise.forget();
    }
  }

  CryptoBuffer rpIdHash;
  if (!rpIdHash.SetLength(SHA256_LENGTH, fallible)) {
    promise->MaybeReject(NS_ERROR_OUT_OF_MEMORY);
    return promise.forget();
  }

  nsresult srv;
  nsCOMPtr<nsICryptoHash> hashService =
    do_CreateInstance(NS_CRYPTO_HASH_CONTRACTID, &srv);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  srv = HashCString(hashService, rpId, rpIdHash);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  // 4.1.1.4 Process each element of cryptoParameters using the following steps,
  // to produce a new sequence normalizedParameters.
  nsTArray<ScopedCredentialParameters> normalizedParams;
  for (size_t a = 0; a < aCryptoParameters.Length(); ++a) {
    // 4.1.1.4.a Let current be the currently selected element of
    // cryptoParameters.

    // 4.1.1.4.b If current.type does not contain a ScopedCredentialType
    // supported by this implementation, then stop processing current and move
    // on to the next element in cryptoParameters.
    if (aCryptoParameters[a].mType != ScopedCredentialType::ScopedCred) {
      continue;
    }

    // 4.1.1.4.c Let normalizedAlgorithm be the result of normalizing an
    // algorithm using the procedure defined in [WebCryptoAPI], with alg set to
    // current.algorithm and op set to 'generateKey'. If an error occurs during
    // this procedure, then stop processing current and move on to the next
    // element in cryptoParameters.

    nsString algName;
    if (NS_FAILED(GetAlgorithmName(aCx, aCryptoParameters[a].mAlgorithm,
                                   algName))) {
      continue;
    }

    // 4.1.1.4.d Add a new object of type ScopedCredentialParameters to
    // normalizedParameters, with type set to current.type and algorithm set to
    // normalizedAlgorithm.
    ScopedCredentialParameters normalizedObj;
    normalizedObj.mType = aCryptoParameters[a].mType;
    normalizedObj.mAlgorithm.SetAsString().Assign(algName);

    if (!normalizedParams.AppendElement(normalizedObj, mozilla::fallible)){
      promise->MaybeReject(NS_ERROR_OUT_OF_MEMORY);
      return promise.forget();
    }
  }

  // 4.1.1.5 If normalizedAlgorithm is empty and cryptoParameters was not empty,
  // cancel the timer started in step 2, reject promise with a DOMException
  // whose name is "NotSupportedError", and terminate this algorithm.
  if (normalizedParams.IsEmpty() && !aCryptoParameters.IsEmpty()) {
    promise->MaybeReject(NS_ERROR_DOM_NOT_SUPPORTED_ERR);
    return promise.forget();
  }

  // 4.1.1.6 If excludeList is undefined, set it to the empty list.

  // 4.1.1.7 If extensions was specified, process any extensions supported by
  // this client platform, to produce the extension data that needs to be sent
  // to the authenticator. If an error is encountered while processing an
  // extension, skip that extension and do not produce any extension data for
  // it. Call the result of this processing clientExtensions.

  // Currently no extensions are supported

  // 4.1.1.8 Use attestationChallenge, callerOrigin and rpId, along with the
  // token binding key associated with callerOrigin (if any), to create a
  // ClientData structure representing this request. Choose a hash algorithm for
  // hashAlg and compute the clientDataJSON and clientDataHash.

  CryptoBuffer challenge;
  if (!challenge.Assign(aChallenge)) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  nsAutoCString clientDataJSON;
  srv = AssembleClientData(mOrigin, challenge, clientDataJSON);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  CryptoBuffer clientDataHash;
  if (!clientDataHash.SetLength(SHA256_LENGTH, fallible)) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  srv = HashCString(hashService, clientDataJSON, clientDataHash);
  if (NS_WARN_IF(NS_FAILED(srv))) {
    promise->MaybeReject(NS_ERROR_DOM_SECURITY_ERR);
    return promise.forget();
  }

  // 4.1.1.9 Initialize issuedRequests to an empty list.
  RefPtr<CredentialPromise> monitorPromise = requestMonitor->Ensure();

  // 4.1.1.10 For each authenticator currently available on this platform:
  // asynchronously invoke the authenticatorMakeCredential operation on that
  // authenticator with rpIdHash, clientDataHash, accountInformation,
  // normalizedParameters, excludeList and clientExtensions as parameters. Add a
  // corresponding entry to issuedRequests.
  for (Authenticator u2ftoken : mAuthenticators) {
    // 4.1.1.10.a For each credential C in excludeList that has a non-empty
    // transports list, optionally use only the specified transports to test for
    // the existence of C.
    U2FAuthMakeCredential(requestMonitor, u2ftoken, rpIdHash, clientDataJSON,
                          clientDataHash, aAccount, normalizedParams,
                          aOptions.mExcludeList, aOptions.mExtensions);
  }

  requestMonitor->CompleteTask();

  monitorPromise->Then(AbstractThread::MainThread(), __func__,
    [promise] (CredentialPtr aInfo) {
      promise->MaybeResolve(aInfo);
    },
    [promise] (nsresult aErrorCode) {
      promise->MaybeReject(aErrorCode);
  });

  return promise.forget();
}
示例#9
0
// NOTE: This method represents a theoretical way to use a U2F-compliant token
// to produce the result of the WebAuthn GetAssertion method. The exact mapping
// of U2F data fields to WebAuthn data fields is still a matter of ongoing
// discussion, and this should not be taken as anything but a point-in- time
// possibility.
void
WebAuthentication::U2FAuthGetAssertion(const RefPtr<AssertionRequest>& aRequest,
                    const Authenticator& aToken, CryptoBuffer& aRpIdHash,
                    const nsACString& aClientData, CryptoBuffer& aClientDataHash,
                    nsTArray<CryptoBuffer>& aAllowList,
                    const WebAuthnExtensions& aExtensions)
{
  MOZ_LOG(gWebauthLog, LogLevel::Debug, ("U2FAuthGetAssertion"));

  // 4.1.2.7.e Add an entry to issuedRequests, corresponding to this request.
  aRequest->AddActiveToken(__func__);

  // 4.1.2.8 While issuedRequests is not empty, perform the following actions
  // depending upon the adjustedTimeout timer and responses from the
  // authenticators:

  // 4.1.2.8.a If the timer for adjustedTimeout expires, then for each entry
  // in issuedRequests invoke the authenticatorCancel operation on that
  // authenticator and remove its entry from the list.

  for (CryptoBuffer& allowedCredential : aAllowList) {
    bool isRegistered = false;
    nsresult rv = aToken->IsRegistered(allowedCredential.Elements(),
                                       allowedCredential.Length(),
                                       &isRegistered);

    // 4.1.2.8.b If any authenticator returns a status indicating that the user
    // cancelled the operation, delete that authenticator’s entry from
    // issuedRequests. For each remaining entry in issuedRequests invoke the
    // authenticatorCancel operation on that authenticator, and remove its entry
    // from the list.

    // 4.1.2.8.c If any authenticator returns an error status, delete the
    // corresponding entry from issuedRequests.
    if (NS_WARN_IF(NS_FAILED(rv))) {
      aRequest->SetFailure(rv);
      return;
    }

    if (!isRegistered) {
      continue;
    }

    // Sign
    uint8_t* buffer;
    uint32_t bufferlen;
    rv = aToken->Sign(aRpIdHash.Elements(), aRpIdHash.Length(),
                      aClientDataHash.Elements(), aClientDataHash.Length(),
                      allowedCredential.Elements(), allowedCredential.Length(),
                      &buffer, &bufferlen);
    if (NS_WARN_IF(NS_FAILED(rv))) {
      aRequest->SetFailure(rv);
      return;
    }

    MOZ_ASSERT(buffer);
    CryptoBuffer signatureData;
    if (NS_WARN_IF(!signatureData.Assign(buffer, bufferlen))) {
      free(buffer);
      aRequest->SetFailure(NS_ERROR_OUT_OF_MEMORY);
      return;
    }
    free(buffer);

    // 4.1.2.8.d If any authenticator returns success:

    // 4.1.2.8.d.1 Remove this authenticator’s entry from issuedRequests.

    // 4.1.2.8.d.2 Create a new WebAuthnAssertion object named value and
    // populate its fields with the values returned from the authenticator as
    // well as the clientDataJSON computed earlier.

    CryptoBuffer clientDataBuf;
    if (!clientDataBuf.Assign(aClientData)) {
      aRequest->SetFailure(NS_ERROR_OUT_OF_MEMORY);
      return;
    }

    CryptoBuffer authenticatorDataBuf;
    rv = U2FAssembleAuthenticatorData(authenticatorDataBuf, aRpIdHash,
                                      signatureData);
    if (NS_WARN_IF(NS_FAILED(rv))) {
      aRequest->SetFailure(rv);
      return;
    }

    RefPtr<ScopedCredential> credential = new ScopedCredential(this);
    credential->SetType(ScopedCredentialType::ScopedCred);
    credential->SetId(allowedCredential);

    AssertionPtr assertion = new WebAuthnAssertion(this);
    assertion->SetCredential(credential);
    assertion->SetClientData(clientDataBuf);
    assertion->SetAuthenticatorData(authenticatorDataBuf);
    assertion->SetSignature(signatureData);

    // 4.1.2.8.d.3 For each remaining entry in issuedRequests invoke the
    // authenticatorCancel operation on that authenticator and remove its entry
    // from the list.

    // 4.1.2.8.d.4 Resolve promise with value and terminate this algorithm.
    aRequest->SetSuccess(assertion);
    return;
  }

  // 4.1.2.9 Reject promise with a DOMException whose name is "NotAllowedError",
  // and terminate this algorithm.
  aRequest->SetFailure(NS_ERROR_DOM_NOT_ALLOWED_ERR);
}
示例#10
0
// NOTE: This method represents a theoretical way to use a U2F-compliant token
// to produce the result of the WebAuthn MakeCredential method. The exact
// mapping of U2F data fields to WebAuthn data fields is still a matter of
// ongoing discussion, and this should not be taken as anything but a point-in-
// time possibility.
void
WebAuthentication::U2FAuthMakeCredential(
             const RefPtr<CredentialRequest>& aRequest,
             const Authenticator& aToken, CryptoBuffer& aRpIdHash,
             const nsACString& aClientData, CryptoBuffer& aClientDataHash,
             const Account& aAccount,
             const nsTArray<ScopedCredentialParameters>& aNormalizedParams,
             const Optional<Sequence<ScopedCredentialDescriptor>>& aExcludeList,
             const WebAuthnExtensions& aExtensions)
{
  MOZ_LOG(gWebauthLog, LogLevel::Debug, ("U2FAuthMakeCredential"));
  aRequest->AddActiveToken(__func__);

  // 5.1.1 When this operation is invoked, the authenticator must perform the
  // following procedure:

  // 5.1.1.a Check if all the supplied parameters are syntactically well-
  // formed and of the correct length. If not, return an error code equivalent
  // to UnknownError and terminate the operation.

  if ((aRpIdHash.Length() != SHA256_LENGTH) ||
      (aClientDataHash.Length() != SHA256_LENGTH)) {
    aRequest->SetFailure(NS_ERROR_DOM_UNKNOWN_ERR);
    return;
  }

  // 5.1.1.b Check if at least one of the specified combinations of
  // ScopedCredentialType and cryptographic parameters is supported. If not,
  // return an error code equivalent to NotSupportedError and terminate the
  // operation.

  bool isValidCombination = false;

  for (size_t a = 0; a < aNormalizedParams.Length(); ++a) {
    if (aNormalizedParams[a].mType == ScopedCredentialType::ScopedCred &&
        aNormalizedParams[a].mAlgorithm.IsString() &&
        aNormalizedParams[a].mAlgorithm.GetAsString().EqualsLiteral(
          WEBCRYPTO_NAMED_CURVE_P256)) {
      isValidCombination = true;
      break;
    }
  }
  if (!isValidCombination) {
    aRequest->SetFailure(NS_ERROR_DOM_NOT_SUPPORTED_ERR);
    return;
  }

  // 5.1.1.c Check if a credential matching any of the supplied
  // ScopedCredential identifiers is present on this authenticator. If so,
  // return an error code equivalent to NotAllowedError and terminate the
  // operation.

  if (aExcludeList.WasPassed()) {
    const Sequence<ScopedCredentialDescriptor>& list = aExcludeList.Value();

    for (const ScopedCredentialDescriptor& scd : list) {
      bool isRegistered = false;

      uint8_t *data;
      uint32_t len;

      // data is owned by the Descriptor, do don't free it here.
      if (NS_FAILED(ScopedCredentialGetData(scd, &data, &len))) {
        aRequest->SetFailure(NS_ERROR_DOM_UNKNOWN_ERR);
        return;
      }

      nsresult rv = aToken->IsRegistered(data, len, &isRegistered);
      if (NS_WARN_IF(NS_FAILED(rv))) {
        aRequest->SetFailure(rv);
        return;
      }

      if (isRegistered) {
        aRequest->SetFailure(NS_ERROR_DOM_NOT_ALLOWED_ERR);
        return;
      }
    }
  }

  // 5.1.1.d Prompt the user for consent to create a new credential. The
  // prompt for obtaining this consent is shown by the authenticator if it has
  // its own output capability, or by the user agent otherwise. If the user
  // denies consent, return an error code equivalent to NotAllowedError and
  // terminate the operation.

  // 5.1.1.d Once user consent has been obtained, generate a new credential
  // object

  // 5.1.1.e If any error occurred while creating the new credential object,
  // return an error code equivalent to UnknownError and terminate the
  // operation.

  // 5.1.1.f Process all the supported extensions requested by the client, and
  // generate an attestation statement. If no authority key is available to
  // sign such an attestation statement, then the authenticator performs self
  // attestation of the credential with its own private key. For more details
  // on attestation, see §5.3 Credential Attestation Statements.

  // No extensions are supported

  // 4.1.1.11 While issuedRequests is not empty, perform the following actions
  // depending upon the adjustedTimeout timer and responses from the
  // authenticators:

  // 4.1.1.11.a If the adjustedTimeout timer expires, then for each entry in
  // issuedRequests invoke the authenticatorCancel operation on that
  // authenticator and remove its entry from the list.

  uint8_t* buffer;
  uint32_t bufferlen;

  nsresult rv = aToken->Register(aRpIdHash.Elements(), aRpIdHash.Length(),
                                 aClientDataHash.Elements(),
                                 aClientDataHash.Length(), &buffer, &bufferlen);

  // 4.1.1.11.b If any authenticator returns a status indicating that the user
  // cancelled the operation, delete that authenticator’s entry from
  // issuedRequests. For each remaining entry in issuedRequests invoke the
  // authenticatorCancel operation on that authenticator and remove its entry
  // from the list.

  // 4.1.1.11.c If any authenticator returns an error status, delete the
  // corresponding entry from issuedRequests.
  if (NS_WARN_IF(NS_FAILED(rv))) {
    aRequest->SetFailure(NS_ERROR_DOM_UNKNOWN_ERR);
    return;
  }

  MOZ_ASSERT(buffer);
  CryptoBuffer regData;
  if (NS_WARN_IF(!regData.Assign(buffer, bufferlen))) {
    free(buffer);
    aRequest->SetFailure(NS_ERROR_OUT_OF_MEMORY);
    return;
  }
  free(buffer);

  // Decompose the U2F registration packet
  CryptoBuffer pubKeyBuf;
  CryptoBuffer keyHandleBuf;
  CryptoBuffer attestationCertBuf;
  CryptoBuffer signatureBuf;

  rv = U2FDecomposeRegistrationResponse(regData, pubKeyBuf, keyHandleBuf,
                                        attestationCertBuf, signatureBuf);
  if (NS_WARN_IF(NS_FAILED(rv))) {
    aRequest->SetFailure(rv);
    return;
  }

  // Sign the aClientDataHash explicitly to get the format needed for
  // the AuthenticatorData parameter of WebAuthnAttestation. This might
  // be temporary while the spec settles down how to incorporate U2F.
  rv = aToken->Sign(aRpIdHash.Elements(), aRpIdHash.Length(),
                    aClientDataHash.Elements(), aClientDataHash.Length(),
                    keyHandleBuf.Elements(), keyHandleBuf.Length(), &buffer,
                    &bufferlen);
  if (NS_WARN_IF(NS_FAILED(rv))) {
    aRequest->SetFailure(rv);
    return;
  }

  MOZ_ASSERT(buffer);
  CryptoBuffer signatureData;
  if (NS_WARN_IF(!signatureData.Assign(buffer, bufferlen))) {
    free(buffer);
    aRequest->SetFailure(NS_ERROR_OUT_OF_MEMORY);
    return;
  }
  free(buffer);

  CryptoBuffer clientDataBuf;
  if (!clientDataBuf.Assign(aClientData)) {
    aRequest->SetFailure(NS_ERROR_OUT_OF_MEMORY);
    return;
  }

  CryptoBuffer authenticatorDataBuf;
  rv = U2FAssembleAuthenticatorData(authenticatorDataBuf, aRpIdHash,
                                    signatureData);
  if (NS_WARN_IF(NS_FAILED(rv))) {
    aRequest->SetFailure(rv);
    return;
  }

  // 4.1.1.11.d If any authenticator indicates success:

  // 4.1.1.11.d.1 Remove this authenticator’s entry from issuedRequests.

  // 4.1.1.11.d.2 Create a new ScopedCredentialInfo object named value and
  // populate its fields with the values returned from the authenticator as well
  // as the clientDataJSON computed earlier.

  RefPtr<ScopedCredential> credential = new ScopedCredential(this);
  credential->SetType(ScopedCredentialType::ScopedCred);
  credential->SetId(keyHandleBuf);

  RefPtr<WebAuthnAttestation> attestation = new WebAuthnAttestation(this);
  attestation->SetFormat(NS_LITERAL_STRING("u2f"));
  attestation->SetClientData(clientDataBuf);
  attestation->SetAuthenticatorData(authenticatorDataBuf);
  attestation->SetAttestation(regData);

  CredentialPtr info = new ScopedCredentialInfo(this);
  info->SetCredential(credential);
  info->SetAttestation(attestation);

  // 4.1.1.11.d.3 For each remaining entry in issuedRequests invoke the
  // authenticatorCancel operation on that authenticator and remove its entry
  // from the list.

  // 4.1.1.11.d.4 Resolve promise with value and terminate this algorithm.
  aRequest->SetSuccess(info);
}
示例#11
0
static nsresult
U2FDecomposeRegistrationResponse(const CryptoBuffer& aResponse,
                                 /* out */ CryptoBuffer& aPubKeyBuf,
                                 /* out */ CryptoBuffer& aKeyHandleBuf,
                                 /* out */ CryptoBuffer& aAttestationCertBuf,
                                 /* out */ CryptoBuffer& aSignatureBuf)
{
  // U2F v1.1 Format via
  // http://fidoalliance.org/specs/fido-u2f-v1.1-id-20160915/fido-u2f-raw-message-formats-v1.1-id-20160915.html
  //
  // Bytes  Value
  // 1      0x05
  // 65     public key
  // 1      key handle length
  // *      key handle
  // ASN.1  attestation certificate
  // *      attestation signature

  pkix::Input u2fResponse;
  u2fResponse.Init(aResponse.Elements(), aResponse.Length());

  pkix::Reader input(u2fResponse);

  uint8_t b;
  if (input.Read(b) != pkix::Success) {
    return NS_ERROR_DOM_UNKNOWN_ERR;
  }
  if (b != 0x05) {
    return NS_ERROR_DOM_UNKNOWN_ERR;
  }

  nsresult rv = ReadToCryptoBuffer(input, aPubKeyBuf, 65);
  if (NS_FAILED(rv)) {
    return rv;
  }

  uint8_t handleLen;
  if (input.Read(handleLen) != pkix::Success) {
    return NS_ERROR_DOM_UNKNOWN_ERR;
  }

  rv = ReadToCryptoBuffer(input, aKeyHandleBuf, handleLen);
  if (NS_FAILED(rv)) {
    return rv;
  }

  // We have to parse the ASN.1 SEQUENCE on the outside to determine the cert's
  // length.
  pkix::Input cert;
  if (pkix::der::ExpectTagAndGetValue(input, pkix::der::SEQUENCE, cert)
        != pkix::Success) {
    return NS_ERROR_DOM_UNKNOWN_ERR;
  }

  pkix::Reader certInput(cert);
  rv = ReadToCryptoBuffer(certInput, aAttestationCertBuf, cert.GetLength());
  if (NS_FAILED(rv)) {
    return rv;
  }

  // The remainder of u2fResponse is the signature
  pkix::Input u2fSig;
  input.SkipToEnd(u2fSig);
  pkix::Reader sigInput(u2fSig);
  rv = ReadToCryptoBuffer(sigInput, aSignatureBuf, u2fSig.GetLength());
  if (NS_FAILED(rv)) {
    return rv;
  }

  return NS_OK;
}