xref: /system/connectivity/shill/cellular/cellular_capability_universal.cc

//
// Copyright (C) 2013 The Android Open Source Project
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//      http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//

#include "shill/cellular/cellular_capability_universal.h"

#include <base/bind.h>
#include <base/stl_util.h>
#include <base/strings/string_util.h>
#include <base/strings/stringprintf.h>
#if defined(__ANDROID__)
#include <dbus/service_constants.h>
#else
#include <chromeos/dbus/service_constants.h>
#endif  // __ANDROID__
#include <ModemManager/ModemManager.h>

#include <string>
#include <vector>

#include "shill/adaptor_interfaces.h"
#include "shill/cellular/cellular_bearer.h"
#include "shill/cellular/cellular_service.h"
#include "shill/cellular/mobile_operator_info.h"
#include "shill/control_interface.h"
#include "shill/dbus_properties_proxy_interface.h"
#include "shill/error.h"
#include "shill/logging.h"
#include "shill/pending_activation_store.h"
#include "shill/property_accessor.h"

#ifdef MM_MODEM_CDMA_REGISTRATION_STATE_UNKNOWN
#error "Do not include mm-modem.h"
#endif

using base::Bind;
using base::Closure;
using std::string;
using std::vector;

namespace shill {

namespace Logging {
static auto kModuleLogScope = ScopeLogger::kCellular;
static string ObjectID(CellularCapabilityUniversal* c) {
  return c->cellular()->GetRpcIdentifier();
}
}

// static
const char CellularCapabilityUniversal::kConnectPin[] = "pin";
const char CellularCapabilityUniversal::kConnectOperatorId[] = "operator-id";
const char CellularCapabilityUniversal::kConnectApn[] = "apn";
const char CellularCapabilityUniversal::kConnectIPType[] = "ip-type";
const char CellularCapabilityUniversal::kConnectUser[] = "user";
const char CellularCapabilityUniversal::kConnectPassword[] = "password";
const char CellularCapabilityUniversal::kConnectNumber[] = "number";
const char CellularCapabilityUniversal::kConnectAllowRoaming[] =
    "allow-roaming";
const char CellularCapabilityUniversal::kConnectRMProtocol[] = "rm-protocol";
const int64_t CellularCapabilityUniversal::kEnterPinTimeoutMilliseconds = 20000;
const int64_t
CellularCapabilityUniversal::kRegistrationDroppedUpdateTimeoutMilliseconds =
    15000;
const char CellularCapabilityUniversal::kRootPath[] = "/";
const char CellularCapabilityUniversal::kStatusProperty[] = "status";
const char CellularCapabilityUniversal::kOperatorLongProperty[] =
    "operator-long";
const char CellularCapabilityUniversal::kOperatorShortProperty[] =
    "operator-short";
const char CellularCapabilityUniversal::kOperatorCodeProperty[] =
    "operator-code";
const char CellularCapabilityUniversal::kOperatorAccessTechnologyProperty[] =
    "access-technology";
const char CellularCapabilityUniversal::kAltairLTEMMPlugin[] = "Altair LTE";
const char CellularCapabilityUniversal::kNovatelLTEMMPlugin[] = "Novatel LTE";
const int CellularCapabilityUniversal::kSetPowerStateTimeoutMilliseconds =
    20000;

namespace {

const char kPhoneNumber[] = "*99#";

// This identifier is specified in the serviceproviders.prototxt file.
const char kVzwIdentifier[] = "c83d6597-dc91-4d48-a3a7-d86b80123751";
const size_t kVzwMdnLength = 10;

string AccessTechnologyToString(uint32_t access_technologies) {
  if (access_technologies & MM_MODEM_ACCESS_TECHNOLOGY_LTE)
    return kNetworkTechnologyLte;
  if (access_technologies & (MM_MODEM_ACCESS_TECHNOLOGY_EVDO0 |
                              MM_MODEM_ACCESS_TECHNOLOGY_EVDOA |
                              MM_MODEM_ACCESS_TECHNOLOGY_EVDOB))
    return kNetworkTechnologyEvdo;
  if (access_technologies & MM_MODEM_ACCESS_TECHNOLOGY_1XRTT)
    return kNetworkTechnology1Xrtt;
  if (access_technologies & MM_MODEM_ACCESS_TECHNOLOGY_HSPA_PLUS)
    return kNetworkTechnologyHspaPlus;
  if (access_technologies & (MM_MODEM_ACCESS_TECHNOLOGY_HSPA |
                              MM_MODEM_ACCESS_TECHNOLOGY_HSUPA |
                              MM_MODEM_ACCESS_TECHNOLOGY_HSDPA))
    return kNetworkTechnologyHspa;
  if (access_technologies & MM_MODEM_ACCESS_TECHNOLOGY_UMTS)
    return kNetworkTechnologyUmts;
  if (access_technologies & MM_MODEM_ACCESS_TECHNOLOGY_EDGE)
    return kNetworkTechnologyEdge;
  if (access_technologies & MM_MODEM_ACCESS_TECHNOLOGY_GPRS)
    return kNetworkTechnologyGprs;
  if (access_technologies & (MM_MODEM_ACCESS_TECHNOLOGY_GSM_COMPACT |
                              MM_MODEM_ACCESS_TECHNOLOGY_GSM))
      return kNetworkTechnologyGsm;
  return "";
}

string AccessTechnologyToTechnologyFamily(uint32_t access_technologies) {
  if (access_technologies & (MM_MODEM_ACCESS_TECHNOLOGY_LTE |
                             MM_MODEM_ACCESS_TECHNOLOGY_HSPA_PLUS |
                             MM_MODEM_ACCESS_TECHNOLOGY_HSPA |
                             MM_MODEM_ACCESS_TECHNOLOGY_HSUPA |
                             MM_MODEM_ACCESS_TECHNOLOGY_HSDPA |
                             MM_MODEM_ACCESS_TECHNOLOGY_UMTS |
                             MM_MODEM_ACCESS_TECHNOLOGY_EDGE |
                             MM_MODEM_ACCESS_TECHNOLOGY_GPRS |
                             MM_MODEM_ACCESS_TECHNOLOGY_GSM_COMPACT |
                             MM_MODEM_ACCESS_TECHNOLOGY_GSM))
    return kTechnologyFamilyGsm;
  if (access_technologies & (MM_MODEM_ACCESS_TECHNOLOGY_EVDO0 |
                             MM_MODEM_ACCESS_TECHNOLOGY_EVDOA |
                             MM_MODEM_ACCESS_TECHNOLOGY_EVDOB |
                             MM_MODEM_ACCESS_TECHNOLOGY_1XRTT))
    return kTechnologyFamilyCdma;
  return "";
}

}  // namespace

CellularCapabilityUniversal::CellularCapabilityUniversal(
    Cellular* cellular,
    ControlInterface* control_interface,
    ModemInfo* modem_info)
    : CellularCapability(cellular, control_interface, modem_info),
      mobile_operator_info_(new MobileOperatorInfo(cellular->dispatcher(),
                                                   "ParseScanResult")),
      weak_ptr_factory_(this),
      registration_state_(MM_MODEM_3GPP_REGISTRATION_STATE_UNKNOWN),
      current_capabilities_(MM_MODEM_CAPABILITY_NONE),
      access_technologies_(MM_MODEM_ACCESS_TECHNOLOGY_UNKNOWN),
      resetting_(false),
      subscription_state_(kSubscriptionStateUnknown),
      reset_done_(false),
      registration_dropped_update_timeout_milliseconds_(
          kRegistrationDroppedUpdateTimeoutMilliseconds) {
  SLOG(this, 2) << "Cellular capability constructed: Universal";
  mobile_operator_info_->Init();
  HelpRegisterConstDerivedKeyValueStore(
      kSIMLockStatusProperty,
      &CellularCapabilityUniversal::SimLockStatusToProperty);
}

CellularCapabilityUniversal::~CellularCapabilityUniversal() {}

KeyValueStore CellularCapabilityUniversal::SimLockStatusToProperty(
    Error* /*error*/) {
  KeyValueStore status;
  string lock_type;
  switch (sim_lock_status_.lock_type) {
    case MM_MODEM_LOCK_SIM_PIN:
      lock_type = "sim-pin";
      break;
    case MM_MODEM_LOCK_SIM_PUK:
      lock_type = "sim-puk";
      break;
    default:
      lock_type = "";
      break;
  }
  status.SetBool(kSIMLockEnabledProperty, sim_lock_status_.enabled);
  status.SetString(kSIMLockTypeProperty, lock_type);
  status.SetUint(kSIMLockRetriesLeftProperty, sim_lock_status_.retries_left);
  return status;
}

void CellularCapabilityUniversal::HelpRegisterConstDerivedKeyValueStore(
    const string& name,
    KeyValueStore(CellularCapabilityUniversal::*get)(Error* error)) {
  cellular()->mutable_store()->RegisterDerivedKeyValueStore(
      name,
      KeyValueStoreAccessor(
          new CustomAccessor<CellularCapabilityUniversal, KeyValueStore>(
              this, get, nullptr)));
}

void CellularCapabilityUniversal::InitProxies() {
  modem_3gpp_proxy_.reset(
      control_interface()->CreateMM1ModemModem3gppProxy(
          cellular()->dbus_path(), cellular()->dbus_service()));
  modem_proxy_.reset(
      control_interface()->CreateMM1ModemProxy(cellular()->dbus_path(),
                                               cellular()->dbus_service()));
  modem_simple_proxy_.reset(
      control_interface()->CreateMM1ModemSimpleProxy(
          cellular()->dbus_path(), cellular()->dbus_service()));

  modem_proxy_->set_state_changed_callback(
      Bind(&CellularCapabilityUniversal::OnModemStateChangedSignal,
           weak_ptr_factory_.GetWeakPtr()));
  // Do not create a SIM proxy until the device is enabled because we
  // do not yet know the object path of the sim object.
  // TODO(jglasgow): register callbacks
}

void CellularCapabilityUniversal::StartModem(Error* error,
                                             const ResultCallback& callback) {
  SLOG(this, 3) << __func__;
  InitProxies();
  deferred_enable_modem_callback_.Reset();
  EnableModem(true, error, callback);
}

void CellularCapabilityUniversal::EnableModem(bool deferrable,
                                              Error* error,
                                              const ResultCallback& callback) {
  SLOG(this, 3) << __func__ << "(deferrable=" << deferrable << ")";
  CHECK(!callback.is_null());
  Error local_error(Error::kOperationInitiated);
  modem_info()->metrics()->NotifyDeviceEnableStarted(
      cellular()->interface_index());
  modem_proxy_->Enable(
      true,
      &local_error,
      Bind(&CellularCapabilityUniversal::EnableModemCompleted,
           weak_ptr_factory_.GetWeakPtr(), deferrable, callback),
      kTimeoutEnable);
  if (local_error.IsFailure()) {
    SLOG(this, 2) << __func__ << "Call to modem_proxy_->Enable() failed";
  }
  if (error) {
    error->CopyFrom(local_error);
  }
}

void CellularCapabilityUniversal::EnableModemCompleted(
    bool deferrable, const ResultCallback& callback, const Error& error) {
  SLOG(this, 3) << __func__ << "(deferrable=" << deferrable
                            << ", error=" << error << ")";

  // If the enable operation failed with Error::kWrongState, the modem is not
  // in the expected state (i.e. disabled). If |deferrable| indicates that the
  // enable operation can be deferred, we defer the operation until the modem
  // goes into the expected state (see OnModemStateChangedSignal).
  //
  // Note that when the SIM is locked, the enable operation also fails with
  // Error::kWrongState. The enable operation is deferred until the modem goes
  // into the disabled state after the SIM is unlocked. We may choose not to
  // defer the enable operation when the SIM is locked, but the UI needs to
  // trigger the enable operation after the SIM is unlocked, which is currently
  // not the case.
  if (error.IsFailure()) {
    if (!deferrable || error.type() != Error::kWrongState) {
      callback.Run(error);
      return;
    }

    if (deferred_enable_modem_callback_.is_null()) {
      SLOG(this, 2) << "Defer enable operation.";
      // The Enable operation to be deferred should not be further deferrable.
      deferred_enable_modem_callback_ =
          Bind(&CellularCapabilityUniversal::EnableModem,
               weak_ptr_factory_.GetWeakPtr(),
               false,  // non-deferrable
               nullptr,
               callback);
    }
    return;
  }

  // After modem is enabled, it should be possible to get properties
  // TODO(jglasgow): handle errors from GetProperties
  GetProperties();
  // We expect the modem to start scanning after it has been enabled.
  // Change this if this behavior is no longer the case in the future.
  modem_info()->metrics()->NotifyDeviceEnableFinished(
      cellular()->interface_index());
  modem_info()->metrics()->NotifyDeviceScanStarted(
      cellular()->interface_index());
  callback.Run(error);
}

void CellularCapabilityUniversal::StopModem(Error* error,
                                            const ResultCallback& callback) {
  CHECK(!callback.is_null());
  CHECK(error);
  // If there is an outstanding registration change, simply ignore it since
  // the service will be destroyed anyway.
  if (!registration_dropped_update_callback_.IsCancelled()) {
    registration_dropped_update_callback_.Cancel();
    SLOG(this, 2) << __func__ << " Cancelled delayed deregister.";
  }

  // Some modems will implicitly disconnect the bearer when transitioning to
  // low power state. For such modems, it's faster to let the modem disconnect
  // the bearer. To do that, we just remove the bearer from the list so
  // ModemManager doesn't try to disconnect it during disable.
  Closure task;
  if (cellular()->mm_plugin() == kAltairLTEMMPlugin) {
    task = Bind(&CellularCapabilityUniversal::Stop_DeleteActiveBearer,
                weak_ptr_factory_.GetWeakPtr(),
                callback);
  } else {
    task = Bind(&CellularCapabilityUniversal::Stop_Disable,
                weak_ptr_factory_.GetWeakPtr(),
                callback);
  }
  cellular()->dispatcher()->PostTask(task);
  deferred_enable_modem_callback_.Reset();
}

void CellularCapabilityUniversal::Stop_DeleteActiveBearer(
    const ResultCallback& callback) {
  SLOG(this, 3) << __func__;

  if (!active_bearer_) {
    Stop_Disable(callback);
    return;
  }

  Error error;
  modem_proxy_->DeleteBearer(
      active_bearer_->dbus_path(), &error,
      Bind(&CellularCapabilityUniversal::Stop_DeleteActiveBearerCompleted,
           weak_ptr_factory_.GetWeakPtr(), callback),
      kTimeoutDefault);
  if (error.IsFailure())
    callback.Run(error);
}

void CellularCapabilityUniversal::Stop_DeleteActiveBearerCompleted(
    const ResultCallback& callback, const Error& error) {
  SLOG(this, 3) << __func__;
  // Disregard the error from the bearer deletion since the disable will clean
  // up any remaining bearers.
  Stop_Disable(callback);
}

void CellularCapabilityUniversal::Stop_Disable(const ResultCallback& callback) {
  SLOG(this, 3) << __func__;
  Error error;
  modem_info()->metrics()->NotifyDeviceDisableStarted(
      cellular()->interface_index());
  modem_proxy_->Enable(
      false, &error,
      Bind(&CellularCapabilityUniversal::Stop_DisableCompleted,
           weak_ptr_factory_.GetWeakPtr(), callback),
      kTimeoutEnable);
  if (error.IsFailure())
    callback.Run(error);
}

void CellularCapabilityUniversal::Stop_DisableCompleted(
    const ResultCallback& callback, const Error& error) {
  SLOG(this, 3) << __func__;

  if (error.IsSuccess()) {
    // The modem has been successfully disabled, but we still need to power it
    // down.
    Stop_PowerDown(callback);
  } else {
    // An error occurred; terminate the disable sequence.
    callback.Run(error);
  }
}

void CellularCapabilityUniversal::Stop_PowerDown(
    const ResultCallback& callback) {
  SLOG(this, 3) << __func__;
  Error error;
  modem_proxy_->SetPowerState(
      MM_MODEM_POWER_STATE_LOW,
      &error,
      Bind(&CellularCapabilityUniversal::Stop_PowerDownCompleted,
           weak_ptr_factory_.GetWeakPtr(), callback),
      kSetPowerStateTimeoutMilliseconds);

  if (error.IsFailure())
    // This really shouldn't happen, but if it does, report success,
    // because a stop initiated power down is only called if the
    // modem was successfully disabled, but the failure of this
    // operation should still be propagated up as a successful disable.
    Stop_PowerDownCompleted(callback, error);
}

// Note: if we were in the middle of powering down the modem when the
// system suspended, we might not get this event from
// ModemManager. And we might not even get a timeout from dbus-c++,
// because StartModem re-initializes proxies.
void CellularCapabilityUniversal::Stop_PowerDownCompleted(
    const ResultCallback& callback,
    const Error& error) {
  SLOG(this, 3) << __func__;

  if (error.IsFailure())
    SLOG(this, 2) << "Ignoring error returned by SetPowerState: " << error;

  // Since the disable succeeded, if power down fails, we currently fail
  // silently, i.e. we need to report the disable operation as having
  // succeeded.
  modem_info()->metrics()->NotifyDeviceDisableFinished(
      cellular()->interface_index());
  ReleaseProxies();
  callback.Run(Error());
}

void CellularCapabilityUniversal::Connect(const KeyValueStore& properties,
                                          Error* error,
                                          const ResultCallback& callback) {
  SLOG(this, 3) << __func__;
  RpcIdentifierCallback cb = Bind(&CellularCapabilityUniversal::OnConnectReply,
                                  weak_ptr_factory_.GetWeakPtr(),
                                  callback);
  modem_simple_proxy_->Connect(properties, error, cb, kTimeoutConnect);
}

void CellularCapabilityUniversal::Disconnect(Error* error,
                                             const ResultCallback& callback) {
  SLOG(this, 3) << __func__;
  if (modem_simple_proxy_.get()) {
    SLOG(this, 2) << "Disconnect all bearers.";
    // If "/" is passed as the bearer path, ModemManager will disconnect all
    // bearers.
    modem_simple_proxy_->Disconnect(kRootPath,
                                    error,
                                    callback,
                                    kTimeoutDisconnect);
  }
}

void CellularCapabilityUniversal::CompleteActivation(Error* error) {
  SLOG(this, 3) << __func__;

  // Persist the ICCID as "Pending Activation".
  // We're assuming that when this function gets called,
  // |cellular()->sim_identifier()| will be non-empty. We still check here that
  // is non-empty, though something is wrong if it is empty.
  const string& sim_identifier = cellular()->sim_identifier();
  if (sim_identifier.empty()) {
    SLOG(this, 2) << "SIM identifier not available. Nothing to do.";
    return;
  }

  modem_info()->pending_activation_store()->SetActivationState(
      PendingActivationStore::kIdentifierICCID,
      sim_identifier,
      PendingActivationStore::kStatePending);
  UpdatePendingActivationState();

  SLOG(this, 2) << "Resetting modem for activation.";
  ResetAfterActivation();
}

void CellularCapabilityUniversal::ResetAfterActivation() {
  SLOG(this, 3) << __func__;

  // Here the initial call to Reset might fail in rare cases. Simply ignore.
  Error error;
  ResultCallback callback = Bind(
      &CellularCapabilityUniversal::OnResetAfterActivationReply,
      weak_ptr_factory_.GetWeakPtr());
  Reset(&error, callback);
  if (error.IsFailure())
    SLOG(this, 2) << "Failed to reset after activation.";
}

void CellularCapabilityUniversal::OnResetAfterActivationReply(
    const Error& error) {
  SLOG(this, 3) << __func__;
  if (error.IsFailure()) {
    SLOG(this, 2) << "Failed to reset after activation. Try again later.";
    // TODO(armansito): Maybe post a delayed reset task?
    return;
  }
  reset_done_ = true;
  UpdatePendingActivationState();
}

void CellularCapabilityUniversal::UpdatePendingActivationState() {
  SLOG(this, 3) << __func__;

  const string& sim_identifier = cellular()->sim_identifier();
  bool registered =
      registration_state_ == MM_MODEM_3GPP_REGISTRATION_STATE_HOME;

  // We know a service is activated if |subscription_state_| is
  // kSubscriptionStateProvisioned / kSubscriptionStateOutOfData
  // In the case that |subscription_state_| is kSubscriptionStateUnknown, we
  // fallback on checking for a valid MDN.
  bool activated =
    ((subscription_state_ == kSubscriptionStateProvisioned) ||
     (subscription_state_ == kSubscriptionStateOutOfData)) ||
    ((subscription_state_ == kSubscriptionStateUnknown) && IsMdnValid());

  if (activated && !sim_identifier.empty())
      modem_info()->pending_activation_store()->RemoveEntry(
          PendingActivationStore::kIdentifierICCID,
          sim_identifier);

  CellularServiceRefPtr service = cellular()->service();

  if (!service.get())
    return;

  if (service->activation_state() == kActivationStateActivated)
      // Either no service or already activated. Nothing to do.
      return;

  // If the ICCID is not available, the following logic can be delayed until it
  // becomes available.
  if (sim_identifier.empty())
    return;

  PendingActivationStore::State state =
      modem_info()->pending_activation_store()->GetActivationState(
          PendingActivationStore::kIdentifierICCID,
          sim_identifier);
  switch (state) {
    case PendingActivationStore::kStatePending:
      // Always mark the service as activating here, as the ICCID could have
      // been unavailable earlier.
      service->SetActivationState(kActivationStateActivating);
      if (reset_done_) {
        SLOG(this, 2) << "Post-payment activation reset complete.";
        modem_info()->pending_activation_store()->SetActivationState(
            PendingActivationStore::kIdentifierICCID,
            sim_identifier,
            PendingActivationStore::kStateActivated);
      }
      break;
    case PendingActivationStore::kStateActivated:
      if (registered) {
        // Trigger auto connect here.
        SLOG(this, 2) << "Modem has been reset at least once, try to "
                      << "autoconnect to force MDN to update.";
        service->AutoConnect();
      }
      break;
    case PendingActivationStore::kStateUnknown:
      // No entry exists for this ICCID. Nothing to do.
      break;
    default:
      NOTREACHED();
  }
}

string CellularCapabilityUniversal::GetMdnForOLP(
    const MobileOperatorInfo* operator_info) const {
  // TODO(benchan): This is ugly. Remove carrier specific code once we move
  // mobile activation logic to carrier-specifc extensions (crbug.com/260073).
  const string& mdn = cellular()->mdn();
  if (!operator_info->IsMobileNetworkOperatorKnown()) {
    // Can't make any carrier specific modifications.
    return mdn;
  }

  if (operator_info->uuid() == kVzwIdentifier) {
    // subscription_state_ is the definitive indicator of whether we need
    // activation. The OLP expects an all zero MDN in that case.
    if (subscription_state_ == kSubscriptionStateUnprovisioned || mdn.empty()) {
      return string(kVzwMdnLength, '0');
    }
    if (mdn.length() > kVzwMdnLength) {
      return mdn.substr(mdn.length() - kVzwMdnLength);
    }
  }
  return mdn;
}

void CellularCapabilityUniversal::ReleaseProxies() {
  SLOG(this, 3) << __func__;
  modem_3gpp_proxy_.reset();
  modem_proxy_.reset();
  modem_simple_proxy_.reset();
  sim_proxy_.reset();
}

bool CellularCapabilityUniversal::AreProxiesInitialized() const {
  return (modem_3gpp_proxy_.get() && modem_proxy_.get() &&
          modem_simple_proxy_.get() && sim_proxy_.get());
}

void CellularCapabilityUniversal::UpdateServiceActivationState() {
  if (!cellular()->service().get())
    return;

  const string& sim_identifier = cellular()->sim_identifier();
  string activation_state;
  PendingActivationStore::State state =
      modem_info()->pending_activation_store()->GetActivationState(
          PendingActivationStore::kIdentifierICCID,
          sim_identifier);
  if ((subscription_state_ == kSubscriptionStateUnknown ||
       subscription_state_ == kSubscriptionStateUnprovisioned) &&
      !sim_identifier.empty() &&
      state == PendingActivationStore::kStatePending) {
    activation_state = kActivationStateActivating;
  } else if (IsServiceActivationRequired()) {
    activation_state = kActivationStateNotActivated;
  } else {
    activation_state = kActivationStateActivated;

    // Mark an activated service for auto-connect by default. Since data from
    // the user profile will be loaded after the call to OnServiceCreated, this
    // property will be corrected based on the user data at that time.
    // NOTE: This function can be called outside the service initialization
    // path so make sure we don't overwrite the auto-connect setting.
    if (cellular()->service()->activation_state() != activation_state)
      cellular()->service()->SetAutoConnect(true);
  }
  cellular()->service()->SetActivationState(activation_state);
}

void CellularCapabilityUniversal::OnServiceCreated() {
  cellular()->service()->SetActivationType(CellularService::kActivationTypeOTA);
  UpdateServiceActivationState();

  // WORKAROUND:
  // E362 modems on Verizon network does not properly redirect when a SIM
  // runs out of credits, we need to enforce out-of-credits detection.
  //
  // The out-of-credits detection is also needed on ALT3100 modems until the PCO
  // support is ready (crosbug.com/p/20461).
  cellular()->service()->InitOutOfCreditsDetection(
      GetOutOfCreditsDetectionType());

  // Make sure that the network technology is set when the service gets
  // created, just in case.
  cellular()->service()->SetNetworkTechnology(GetNetworkTechnologyString());
}

// Create the list of APNs to try, in the following order:
// - last APN that resulted in a successful connection attempt on the
//   current network (if any)
// - the APN, if any, that was set by the user
// - the list of APNs found in the mobile broadband provider DB for the
//   home provider associated with the current SIM
// - as a last resort, attempt to connect with no APN
void CellularCapabilityUniversal::SetupApnTryList() {
  apn_try_list_.clear();

  DCHECK(cellular()->service().get());
  const Stringmap* apn_info = cellular()->service()->GetLastGoodApn();
  if (apn_info)
    apn_try_list_.push_back(*apn_info);

  apn_info = cellular()->service()->GetUserSpecifiedApn();
  if (apn_info)
    apn_try_list_.push_back(*apn_info);

  apn_try_list_.insert(apn_try_list_.end(),
                       cellular()->apn_list().begin(),
                       cellular()->apn_list().end());
}

void CellularCapabilityUniversal::SetupConnectProperties(
    KeyValueStore* properties) {
  SetupApnTryList();
  FillConnectPropertyMap(properties);
}

void CellularCapabilityUniversal::FillConnectPropertyMap(
    KeyValueStore* properties) {

  // TODO(jglasgow): Is this really needed anymore?
  properties->SetString(kConnectNumber, kPhoneNumber);

  properties->SetBool(kConnectAllowRoaming, AllowRoaming());

  if (!apn_try_list_.empty()) {
    // Leave the APN at the front of the list, so that it can be recorded
    // if the connect attempt succeeds.
    Stringmap apn_info = apn_try_list_.front();
    SLOG(this, 2) << __func__ << ": Using APN " << apn_info[kApnProperty];
    properties->SetString(kConnectApn, apn_info[kApnProperty]);
    if (ContainsKey(apn_info, kApnUsernameProperty))
      properties->SetString(kConnectUser, apn_info[kApnUsernameProperty]);
    if (ContainsKey(apn_info, kApnPasswordProperty))
      properties->SetString(kConnectPassword, apn_info[kApnPasswordProperty]);
  }
}

void CellularCapabilityUniversal::OnConnectReply(const ResultCallback& callback,
                                                 const string& path,
                                                 const Error& error) {
  SLOG(this, 3) << __func__ << "(" << error << ")";

  CellularServiceRefPtr service = cellular()->service();
  if (!service) {
    // The service could have been deleted before our Connect() request
    // completes if the modem was enabled and then quickly disabled.
    apn_try_list_.clear();
  } else if (error.IsFailure()) {
    service->ClearLastGoodApn();
    // The APN that was just tried (and failed) is still at the
    // front of the list, about to be removed. If the list is empty
    // after that, try one last time without an APN. This may succeed
    // with some modems in some cases.
    if (RetriableConnectError(error) && !apn_try_list_.empty()) {
      apn_try_list_.pop_front();
      SLOG(this, 2) << "Connect failed with invalid APN, "
                    << apn_try_list_.size() << " remaining APNs to try";
      KeyValueStore props;
      FillConnectPropertyMap(&props);
      Error error;
      Connect(props, &error, callback);
      return;
    }
  } else {
    if (!apn_try_list_.empty()) {
      service->SetLastGoodApn(apn_try_list_.front());
      apn_try_list_.clear();
    }
    SLOG(this, 2) << "Connected bearer " << path;
  }

  if (!callback.is_null())
    callback.Run(error);

  UpdatePendingActivationState();
}

bool CellularCapabilityUniversal::AllowRoaming() {
  return cellular()->provider_requires_roaming() || allow_roaming_property();
}

void CellularCapabilityUniversal::GetProperties() {
  SLOG(this, 3) << __func__;

  std::unique_ptr<DBusPropertiesProxyInterface> properties_proxy(
      control_interface()->CreateDBusPropertiesProxy(
          cellular()->dbus_path(), cellular()->dbus_service()));

  KeyValueStore properties(
      properties_proxy->GetAll(MM_DBUS_INTERFACE_MODEM));
  OnModemPropertiesChanged(properties, vector<string>());

  properties = properties_proxy->GetAll(MM_DBUS_INTERFACE_MODEM_MODEM3GPP);
  OnModem3GPPPropertiesChanged(properties, vector<string>());
}

void CellularCapabilityUniversal::UpdateServiceOLP() {
  SLOG(this, 3) << __func__;

  // OLP is based off of the Home Provider.
  if (!cellular()->home_provider_info()->IsMobileNetworkOperatorKnown()) {
    return;
  }

  const vector<MobileOperatorInfo::OnlinePortal>& olp_list =
      cellular()->home_provider_info()->olp_list();
  if (olp_list.empty()) {
    return;
  }

  if (olp_list.size() > 1) {
    SLOG(this, 1) << "Found multiple online portals. Choosing the first.";
  }
  string post_data = olp_list[0].post_data;
  base::ReplaceSubstringsAfterOffset(
      &post_data, 0, "${iccid}", cellular()->sim_identifier());
  base::ReplaceSubstringsAfterOffset(
      &post_data, 0, "${imei}", cellular()->imei());
  base::ReplaceSubstringsAfterOffset(
      &post_data, 0, "${imsi}", cellular()->imsi());
  base::ReplaceSubstringsAfterOffset(
      &post_data, 0, "${mdn}", GetMdnForOLP(cellular()->home_provider_info()));
  base::ReplaceSubstringsAfterOffset(
      &post_data, 0, "${min}", cellular()->min());
  cellular()->service()->SetOLP(olp_list[0].url, olp_list[0].method, post_data);
}

void CellularCapabilityUniversal::UpdateActiveBearer() {
  SLOG(this, 3) << __func__;

  // Look for the first active bearer and use its path as the connected
  // one. Right now, we don't allow more than one active bearer.
  active_bearer_.reset();
  for (const auto& path : bearer_paths_) {
    std::unique_ptr<CellularBearer> bearer(
        new CellularBearer(control_interface(),
                           path,
                           cellular()->dbus_service()));
    // The bearer object may have vanished before ModemManager updates the
    // 'Bearers' property.
    if (!bearer->Init())
      continue;

    if (!bearer->connected())
      continue;

    SLOG(this, 2) << "Found active bearer \"" << path << "\".";
    CHECK(!active_bearer_) << "Found more than one active bearer.";
    active_bearer_ = std::move(bearer);
  }

  if (!active_bearer_)
    SLOG(this, 2) << "No active bearer found.";
}

bool CellularCapabilityUniversal::IsServiceActivationRequired() const {
  const string& sim_identifier = cellular()->sim_identifier();
  // subscription_state_ is the definitive answer. If that does not work,
  // fallback on MDN based logic.
  if (subscription_state_ == kSubscriptionStateProvisioned ||
      subscription_state_ == kSubscriptionStateOutOfData)
    return false;

  // We are in the process of activating, ignore all other clues from the
  // network and use our own knowledge about the activation state.
  if (!sim_identifier.empty() &&
      modem_info()->pending_activation_store()->GetActivationState(
          PendingActivationStore::kIdentifierICCID,
          sim_identifier) != PendingActivationStore::kStateUnknown)
    return false;

  // Network notification that the service needs to be activated.
  if (subscription_state_ == kSubscriptionStateUnprovisioned)
    return true;

  // If there is no online payment portal information, it's safer to assume
  // the service does not require activation.
  if (!cellular()->home_provider_info()->IsMobileNetworkOperatorKnown() ||
      cellular()->home_provider_info()->olp_list().empty()) {
    return false;
  }

  // If the MDN is invalid (i.e. empty or contains only zeros), the service
  // requires activation.
  return !IsMdnValid();
}

bool CellularCapabilityUniversal::IsMdnValid() const {
  const string& mdn = cellular()->mdn();
  // Note that |mdn| is normalized to contain only digits in OnMdnChanged().
  for (size_t i = 0; i < mdn.size(); ++i) {
    if (mdn[i] != '0')
      return true;
  }
  return false;
}

// always called from an async context
void CellularCapabilityUniversal::Register(const ResultCallback& callback) {
  SLOG(this, 3) << __func__ << " \"" << cellular()->selected_network()
                            << "\"";
  CHECK(!callback.is_null());
  Error error;
  ResultCallback cb = Bind(&CellularCapabilityUniversal::OnRegisterReply,
                                weak_ptr_factory_.GetWeakPtr(), callback);
  modem_3gpp_proxy_->Register(cellular()->selected_network(), &error, cb,
                              kTimeoutRegister);
  if (error.IsFailure())
    callback.Run(error);
}

void CellularCapabilityUniversal::RegisterOnNetwork(
    const string& network_id,
    Error* error,
    const ResultCallback& callback) {
  SLOG(this, 3) << __func__ << "(" << network_id << ")";
  CHECK(error);
  desired_network_ = network_id;
  ResultCallback cb = Bind(&CellularCapabilityUniversal::OnRegisterReply,
                                weak_ptr_factory_.GetWeakPtr(), callback);
  modem_3gpp_proxy_->Register(network_id, error, cb, kTimeoutRegister);
}

void CellularCapabilityUniversal::OnRegisterReply(
    const ResultCallback& callback,
    const Error& error) {
  SLOG(this, 3) << __func__ << "(" << error << ")";

  if (error.IsSuccess()) {
    cellular()->set_selected_network(desired_network_);
    desired_network_.clear();
    callback.Run(error);
    return;
  }
  // If registration on the desired network failed,
  // try to register on the home network.
  if (!desired_network_.empty()) {
    desired_network_.clear();
    cellular()->set_selected_network("");
    LOG(INFO) << "Couldn't register on selected network, trying home network";
    Register(callback);
    return;
  }
  callback.Run(error);
}

bool CellularCapabilityUniversal::IsRegistered() const {
  return IsRegisteredState(registration_state_);
}

bool CellularCapabilityUniversal::IsRegisteredState(
    MMModem3gppRegistrationState state) {
  return (state == MM_MODEM_3GPP_REGISTRATION_STATE_HOME ||
          state == MM_MODEM_3GPP_REGISTRATION_STATE_ROAMING);
}

void CellularCapabilityUniversal::SetUnregistered(bool searching) {
  // If we're already in some non-registered state, don't override that
  if (registration_state_ == MM_MODEM_3GPP_REGISTRATION_STATE_HOME ||
          registration_state_ == MM_MODEM_3GPP_REGISTRATION_STATE_ROAMING) {
    registration_state_ =
        (searching ? MM_MODEM_3GPP_REGISTRATION_STATE_SEARCHING :
                     MM_MODEM_3GPP_REGISTRATION_STATE_IDLE);
  }
}

void CellularCapabilityUniversal::RequirePIN(
    const string& pin, bool require,
    Error* error, const ResultCallback& callback) {
  CHECK(error);
  sim_proxy_->EnablePin(pin, require, error, callback, kTimeoutDefault);
}

void CellularCapabilityUniversal::EnterPIN(const string& pin,
                                           Error* error,
                                           const ResultCallback& callback) {
  CHECK(error);
  SLOG(this, 3) << __func__;
  sim_proxy_->SendPin(pin, error, callback, kEnterPinTimeoutMilliseconds);
}

void CellularCapabilityUniversal::UnblockPIN(const string& unblock_code,
                                             const string& pin,
                                             Error* error,
                                             const ResultCallback& callback) {
  CHECK(error);
  sim_proxy_->SendPuk(unblock_code, pin, error, callback, kTimeoutDefault);
}

void CellularCapabilityUniversal::ChangePIN(
    const string& old_pin, const string& new_pin,
    Error* error, const ResultCallback& callback) {
  CHECK(error);
  sim_proxy_->ChangePin(old_pin, new_pin, error, callback, kTimeoutDefault);
}

void CellularCapabilityUniversal::Reset(Error* error,
                                        const ResultCallback& callback) {
  SLOG(this, 3) << __func__;
  CHECK(error);
  if (resetting_) {
    Error::PopulateAndLog(FROM_HERE, error, Error::kInProgress,
                          "Already resetting");
    return;
  }
  ResultCallback cb = Bind(&CellularCapabilityUniversal::OnResetReply,
                           weak_ptr_factory_.GetWeakPtr(), callback);
  modem_proxy_->Reset(error, cb, kTimeoutReset);
  if (!error->IsFailure()) {
    resetting_ = true;
  }
}

void CellularCapabilityUniversal::OnResetReply(const ResultCallback& callback,
                                               const Error& error) {
  SLOG(this, 3) << __func__;
  resetting_ = false;
  if (!callback.is_null())
    callback.Run(error);
}

void CellularCapabilityUniversal::Scan(
    Error* error,
    const ResultStringmapsCallback& callback) {
  KeyValueStoresCallback cb = Bind(&CellularCapabilityUniversal::OnScanReply,
                                   weak_ptr_factory_.GetWeakPtr(), callback);
  modem_3gpp_proxy_->Scan(error, cb, kTimeoutScan);
}

void CellularCapabilityUniversal::OnScanReply(
    const ResultStringmapsCallback& callback,
    const ScanResults& results,
    const Error& error) {
  Stringmaps found_networks;
  for (const auto& result : results)
    found_networks.push_back(ParseScanResult(result));
  callback.Run(found_networks, error);
}

Stringmap CellularCapabilityUniversal::ParseScanResult(
    const ScanResult& result) {

  /* ScanResults contain the following keys:

     "status"
     A MMModem3gppNetworkAvailability value representing network
     availability status, given as an unsigned integer (signature "u").
     This key will always be present.

     "operator-long"
     Long-format name of operator, given as a string value (signature
     "s"). If the name is unknown, this field should not be present.

     "operator-short"
     Short-format name of operator, given as a string value
     (signature "s"). If the name is unknown, this field should not
     be present.

     "operator-code"
     Mobile code of the operator, given as a string value (signature
     "s"). Returned in the format "MCCMNC", where MCC is the
     three-digit ITU E.212 Mobile Country Code and MNC is the two- or
     three-digit GSM Mobile Network Code. e.g. "31026" or "310260".

     "access-technology"
     A MMModemAccessTechnology value representing the generic access
     technology used by this mobile network, given as an unsigned
     integer (signature "u").
  */
  Stringmap parsed;

  if (result.ContainsUint(kStatusProperty)) {
    uint32_t status = result.GetUint(kStatusProperty);
    // numerical values are taken from 3GPP TS 27.007 Section 7.3.
    static const char* const kStatusString[] = {
      "unknown",    // MM_MODEM_3GPP_NETWORK_AVAILABILITY_UNKNOWN
      "available",  // MM_MODEM_3GPP_NETWORK_AVAILABILITY_AVAILABLE
      "current",    // MM_MODEM_3GPP_NETWORK_AVAILABILITY_CURRENT
      "forbidden",  // MM_MODEM_3GPP_NETWORK_AVAILABILITY_FORBIDDEN
    };
    parsed[kStatusProperty] = kStatusString[status];
  }

  // MMModemAccessTechnology
  if (result.ContainsUint(kOperatorAccessTechnologyProperty)) {
    parsed[kTechnologyProperty] =
        AccessTechnologyToString(
            result.GetUint(kOperatorAccessTechnologyProperty));
  }

  string operator_long, operator_short, operator_code;
  if (result.ContainsString(kOperatorLongProperty))
    parsed[kLongNameProperty] = result.GetString(kOperatorLongProperty);
  if (result.ContainsString(kOperatorShortProperty))
    parsed[kShortNameProperty] = result.GetString(kOperatorShortProperty);
  if (result.ContainsString(kOperatorCodeProperty))
    parsed[kNetworkIdProperty] = result.GetString(kOperatorCodeProperty);

  // If the long name is not available but the network ID is, look up the long
  // name in the mobile provider database.
  if ((!ContainsKey(parsed, kLongNameProperty) ||
       parsed[kLongNameProperty].empty()) &&
      ContainsKey(parsed, kNetworkIdProperty)) {
    mobile_operator_info_->Reset();
    mobile_operator_info_->UpdateMCCMNC(parsed[kNetworkIdProperty]);
    if (mobile_operator_info_->IsMobileNetworkOperatorKnown() &&
        !mobile_operator_info_->operator_name().empty()) {
      parsed[kLongNameProperty] = mobile_operator_info_->operator_name();
    }
  }
  return parsed;
}

CellularBearer* CellularCapabilityUniversal::GetActiveBearer() const {
  return active_bearer_.get();
}

string CellularCapabilityUniversal::GetNetworkTechnologyString() const {
  // If we know that the modem is an E362 modem supported by the Novatel LTE
  // plugin, return LTE here to make sure that Chrome sees LTE as the network
  // technology even if the actual technology is unknown.
  //
  // This hack will cause the UI to display LTE even if the modem doesn't
  // support it at a given time. This might be problematic if we ever want to
  // support switching between access technologies (e.g. falling back to 3G
  // when LTE is not available).
  if (cellular()->mm_plugin() == kNovatelLTEMMPlugin)
    return kNetworkTechnologyLte;

  // Order is important.  Return the highest speed technology
  // TODO(jglasgow): change shill interfaces to a capability model
  return AccessTechnologyToString(access_technologies_);
}

string CellularCapabilityUniversal::GetRoamingStateString() const {
  switch (registration_state_) {
    case MM_MODEM_3GPP_REGISTRATION_STATE_HOME:
      return kRoamingStateHome;
    case MM_MODEM_3GPP_REGISTRATION_STATE_ROAMING:
      return kRoamingStateRoaming;
    default:
      break;
  }
  return kRoamingStateUnknown;
}

// TODO(armansito): Remove this method once cromo is deprecated.
void CellularCapabilityUniversal::GetSignalQuality() {
  // ModemManager always returns the cached value, so there is no need to
  // trigger an update here. The true value is updated through a property
  // change signal.
}

string CellularCapabilityUniversal::GetTypeString() const {
  return AccessTechnologyToTechnologyFamily(access_technologies_);
}

void CellularCapabilityUniversal::OnModemPropertiesChanged(
    const KeyValueStore& properties,
    const vector<string>& /* invalidated_properties */) {

  // Update the bearers property before the modem state property as
  // OnModemStateChanged may call UpdateActiveBearer, which reads the bearers
  // property.
  if (properties.ContainsRpcIdentifiers(MM_MODEM_PROPERTY_BEARERS)) {
    RpcIdentifiers bearers =
        properties.GetRpcIdentifiers(MM_MODEM_PROPERTY_BEARERS);
    OnBearersChanged(bearers);
  }

  // This solves a bootstrapping problem: If the modem is not yet
  // enabled, there are no proxy objects associated with the capability
  // object, so modem signals like StateChanged aren't seen. By monitoring
  // changes to the State property via the ModemManager, we're able to
  // get the initialization process started, which will result in the
  // creation of the proxy objects.
  //
  // The first time we see the change to State (when the modem state
  // is Unknown), we simply update the state, and rely on the Manager to
  // enable the device when it is registered with the Manager. On subsequent
  // changes to State, we need to explicitly enable the device ourselves.
  if (properties.ContainsInt(MM_MODEM_PROPERTY_STATE)) {
    int32_t istate = properties.GetInt(MM_MODEM_PROPERTY_STATE);
    Cellular::ModemState state = static_cast<Cellular::ModemState>(istate);
    OnModemStateChanged(state);
  }
  if (properties.ContainsRpcIdentifier(MM_MODEM_PROPERTY_SIM))
    OnSimPathChanged(properties.GetRpcIdentifier(MM_MODEM_PROPERTY_SIM));

  if (properties.ContainsUint32s(MM_MODEM_PROPERTY_SUPPORTEDCAPABILITIES)) {
    OnSupportedCapabilitesChanged(
        properties.GetUint32s(MM_MODEM_PROPERTY_SUPPORTEDCAPABILITIES));
  }

  if (properties.ContainsUint(MM_MODEM_PROPERTY_CURRENTCAPABILITIES)) {
    OnModemCurrentCapabilitiesChanged(
        properties.GetUint(MM_MODEM_PROPERTY_CURRENTCAPABILITIES));
  }
  // not needed: MM_MODEM_PROPERTY_MAXBEARERS
  // not needed: MM_MODEM_PROPERTY_MAXACTIVEBEARERS
  if (properties.ContainsString(MM_MODEM_PROPERTY_MANUFACTURER)) {
    cellular()->set_manufacturer(
        properties.GetString(MM_MODEM_PROPERTY_MANUFACTURER));
  }
  if (properties.ContainsString(MM_MODEM_PROPERTY_MODEL)) {
    cellular()->set_model_id(properties.GetString(MM_MODEM_PROPERTY_MODEL));
  }
  if (properties.ContainsString(MM_MODEM_PROPERTY_PLUGIN)) {
    cellular()->set_mm_plugin(properties.GetString(MM_MODEM_PROPERTY_PLUGIN));
  }
  if (properties.ContainsString(MM_MODEM_PROPERTY_REVISION)) {
    OnModemRevisionChanged(properties.GetString(MM_MODEM_PROPERTY_REVISION));
  }
  // not needed: MM_MODEM_PROPERTY_DEVICEIDENTIFIER
  // not needed: MM_MODEM_PROPERTY_DEVICE
  // not needed: MM_MODEM_PROPERTY_DRIVER
  // not needed: MM_MODEM_PROPERTY_PLUGIN
  // not needed: MM_MODEM_PROPERTY_EQUIPMENTIDENTIFIER

  // Unlock required and SimLock
  bool lock_status_changed = false;
  if (properties.ContainsUint(MM_MODEM_PROPERTY_UNLOCKREQUIRED)) {
    uint32_t unlock_required =
        properties.GetUint(MM_MODEM_PROPERTY_UNLOCKREQUIRED);
    OnLockTypeChanged(static_cast<MMModemLock>(unlock_required));
    lock_status_changed = true;
  }

  // Unlock retries
  if (properties.Contains(MM_MODEM_PROPERTY_UNLOCKRETRIES)) {
    OnLockRetriesChanged(
        properties.Get(MM_MODEM_PROPERTY_UNLOCKRETRIES).Get<LockRetryData>());
    lock_status_changed = true;
  }

  if (lock_status_changed)
    OnSimLockStatusChanged();

  if (properties.ContainsUint(MM_MODEM_PROPERTY_ACCESSTECHNOLOGIES)) {
    OnAccessTechnologiesChanged(
        properties.GetUint(MM_MODEM_PROPERTY_ACCESSTECHNOLOGIES));
  }

  if (properties.Contains(MM_MODEM_PROPERTY_SIGNALQUALITY)) {
    SignalQuality quality =
        properties.Get(MM_MODEM_PROPERTY_SIGNALQUALITY).Get<SignalQuality>();
    OnSignalQualityChanged(std::get<0>(quality));
  }

  if (properties.ContainsStrings(MM_MODEM_PROPERTY_OWNNUMBERS)) {
    vector<string> numbers =
        properties.GetStrings(MM_MODEM_PROPERTY_OWNNUMBERS);
    string mdn;
    if (numbers.size() > 0)
      mdn = numbers[0];
    OnMdnChanged(mdn);
  }

  if (properties.Contains(MM_MODEM_PROPERTY_SUPPORTEDMODES)) {
    SupportedModes mm_supported_modes =
        properties.Get(MM_MODEM_PROPERTY_SUPPORTEDMODES).Get<SupportedModes>();
    vector<ModemModes> supported_modes;
    for (const auto& modes : mm_supported_modes) {
      supported_modes.push_back(
          ModemModes(std::get<0>(modes),
                     static_cast<MMModemMode>(std::get<1>(modes))));
    }
    OnSupportedModesChanged(supported_modes);
  }

  if (properties.Contains(MM_MODEM_PROPERTY_CURRENTMODES)) {
    ModesData current_modes =
        properties.Get(MM_MODEM_PROPERTY_CURRENTMODES).Get<ModesData>();
    OnCurrentModesChanged(
        ModemModes(std::get<0>(current_modes),
                   static_cast<MMModemMode>(std::get<1>(current_modes))));
  }

  // au: MM_MODEM_PROPERTY_SUPPORTEDBANDS,
  // au: MM_MODEM_PROPERTY_BANDS
}

void CellularCapabilityUniversal::OnPropertiesChanged(
    const string& interface,
    const KeyValueStore& changed_properties,
    const vector<string>& invalidated_properties) {
  SLOG(this, 3) << __func__ << "(" << interface << ")";
  if (interface == MM_DBUS_INTERFACE_MODEM) {
    OnModemPropertiesChanged(changed_properties, invalidated_properties);
  }
  if (interface == MM_DBUS_INTERFACE_MODEM_MODEM3GPP) {
    OnModem3GPPPropertiesChanged(changed_properties, invalidated_properties);
  }
  if (interface == MM_DBUS_INTERFACE_SIM) {
    OnSimPropertiesChanged(changed_properties, invalidated_properties);
  }
}

bool CellularCapabilityUniversal::RetriableConnectError(
    const Error& error) const {
  if (error.type() == Error::kInvalidApn)
    return true;

  // ModemManager does not ever return kInvalidApn for an E362 modem (with
  // firmware version 1.41) supported by the Novatel LTE plugin.
  if ((cellular()->mm_plugin() == kNovatelLTEMMPlugin) &&
      (error.type() == Error::kOperationFailed)) {
    return true;
  }
  return false;
}

void CellularCapabilityUniversal::OnNetworkModeSignal(uint32_t /*mode*/) {
  // TODO(petkov): Implement this.
  NOTIMPLEMENTED();
}

bool CellularCapabilityUniversal::IsValidSimPath(const string& sim_path) const {
  return !sim_path.empty() && sim_path != kRootPath;
}

string CellularCapabilityUniversal::NormalizeMdn(const string& mdn) const {
  string normalized_mdn;
  for (size_t i = 0; i < mdn.size(); ++i) {
    if (base::IsAsciiDigit(mdn[i]))
      normalized_mdn += mdn[i];
  }
  return normalized_mdn;
}

void CellularCapabilityUniversal::OnSimPathChanged(
    const string& sim_path) {
  if (sim_path == sim_path_)
    return;

  mm1::SimProxyInterface* proxy = nullptr;
  if (IsValidSimPath(sim_path))
    proxy = control_interface()->CreateSimProxy(sim_path,
                                                cellular()->dbus_service());
  sim_path_ = sim_path;
  sim_proxy_.reset(proxy);

  if (!IsValidSimPath(sim_path)) {
    // Clear all data about the sim
    cellular()->set_imsi("");
    spn_ = "";
    cellular()->set_sim_present(false);
    OnSimIdentifierChanged("");
    OnOperatorIdChanged("");
    cellular()->home_provider_info()->Reset();
  } else {
    cellular()->set_sim_present(true);
    std::unique_ptr<DBusPropertiesProxyInterface> properties_proxy(
        control_interface()->CreateDBusPropertiesProxy(
            sim_path, cellular()->dbus_service()));
    // TODO(jglasgow): convert to async interface
    KeyValueStore properties(properties_proxy->GetAll(MM_DBUS_INTERFACE_SIM));
    OnSimPropertiesChanged(properties, vector<string>());
  }
}

void CellularCapabilityUniversal::OnSupportedCapabilitesChanged(
    const vector<uint32_t>& supported_capabilities) {
  supported_capabilities_ = supported_capabilities;
}

void CellularCapabilityUniversal::OnModemCurrentCapabilitiesChanged(
    uint32_t current_capabilities) {
  current_capabilities_ = current_capabilities;

  // Only allow network scan when the modem's current capabilities support
  // GSM/UMTS.
  //
  // TODO(benchan): We should consider having the modem plugins in ModemManager
  // reporting whether network scan is supported.
  cellular()->set_scanning_supported(
      (current_capabilities & MM_MODEM_CAPABILITY_GSM_UMTS) != 0);
}

void CellularCapabilityUniversal::OnMdnChanged(
    const string& mdn) {
  cellular()->set_mdn(NormalizeMdn(mdn));
  UpdatePendingActivationState();
}

void CellularCapabilityUniversal::OnModemRevisionChanged(
    const string& revision) {
  cellular()->set_firmware_revision(revision);
}

void CellularCapabilityUniversal::OnModemStateChanged(
    Cellular::ModemState state) {
  SLOG(this, 3) << __func__ << ": " << Cellular::GetModemStateString(state);

  if (state == Cellular::kModemStateConnected) {
    // This assumes that ModemManager updates the Bearers list and the Bearer
    // properties before changing Modem state to Connected.
    SLOG(this, 2) << "Update active bearer.";
    UpdateActiveBearer();
  }

  cellular()->OnModemStateChanged(state);
  // TODO(armansito): Move the deferred enable logic to Cellular
  // (See crbug.com/279499).
  if (!deferred_enable_modem_callback_.is_null() &&
      state == Cellular::kModemStateDisabled) {
    SLOG(this, 2) << "Enabling modem after deferring.";
    deferred_enable_modem_callback_.Run();
    deferred_enable_modem_callback_.Reset();
  }
}

void CellularCapabilityUniversal::OnAccessTechnologiesChanged(
    uint32_t access_technologies) {
  if (access_technologies_ != access_technologies) {
    const string old_type_string(GetTypeString());
    access_technologies_ = access_technologies;
    const string new_type_string(GetTypeString());
    if (new_type_string != old_type_string) {
      // TODO(jglasgow): address layering violation of emitting change
      // signal here for a property owned by Cellular.
      cellular()->adaptor()->EmitStringChanged(
          kTechnologyFamilyProperty, new_type_string);
    }
    if (cellular()->service().get()) {
      cellular()->service()->SetNetworkTechnology(GetNetworkTechnologyString());
    }
  }
}

void CellularCapabilityUniversal::OnSupportedModesChanged(
    const vector<ModemModes>& supported_modes) {
  supported_modes_ = supported_modes;
}

void CellularCapabilityUniversal::OnCurrentModesChanged(
    const ModemModes& current_modes) {
  current_modes_ = current_modes;
}

void CellularCapabilityUniversal::OnBearersChanged(
    const RpcIdentifiers& bearers) {
  bearer_paths_ = bearers;
}

void CellularCapabilityUniversal::OnLockRetriesChanged(
    const LockRetryData& lock_retries) {
  SLOG(this, 3) << __func__;

  // Look for the retries left for the current lock. Try the obtain the count
  // that matches the current count. If no count for the current lock is
  // available, report the first one in the dictionary.
  LockRetryData::const_iterator it =
      lock_retries.find(sim_lock_status_.lock_type);
  if (it == lock_retries.end())
      it = lock_retries.begin();
  if (it != lock_retries.end())
    sim_lock_status_.retries_left = it->second;
  else
    // Unknown, use 999
    sim_lock_status_.retries_left = 999;
}

void CellularCapabilityUniversal::OnLockTypeChanged(
    MMModemLock lock_type) {
  SLOG(this, 3) << __func__ << ": " << lock_type;
  sim_lock_status_.lock_type = lock_type;

  // If the SIM is in a locked state |sim_lock_status_.enabled| might be false.
  // This is because the corresponding property 'EnabledFacilityLocks' is on
  // the 3GPP interface and the 3GPP interface is not available while the Modem
  // is in the 'LOCKED' state.
  if (lock_type != MM_MODEM_LOCK_NONE &&
      lock_type != MM_MODEM_LOCK_UNKNOWN &&
      !sim_lock_status_.enabled)
    sim_lock_status_.enabled = true;
}

void CellularCapabilityUniversal::OnSimLockStatusChanged() {
  SLOG(this, 3) << __func__;
  cellular()->adaptor()->EmitKeyValueStoreChanged(
      kSIMLockStatusProperty, SimLockStatusToProperty(nullptr));

  // If the SIM is currently unlocked, assume that we need to refresh
  // carrier information, since a locked SIM prevents shill from obtaining
  // the necessary data to establish a connection later (e.g. IMSI).
  if (IsValidSimPath(sim_path_) &&
      (sim_lock_status_.lock_type == MM_MODEM_LOCK_NONE ||
       sim_lock_status_.lock_type == MM_MODEM_LOCK_UNKNOWN)) {
    std::unique_ptr<DBusPropertiesProxyInterface> properties_proxy(
        control_interface()->CreateDBusPropertiesProxy(
            sim_path_, cellular()->dbus_service()));
    KeyValueStore properties(
        properties_proxy->GetAll(MM_DBUS_INTERFACE_SIM));
    OnSimPropertiesChanged(properties, vector<string>());
  }
}

void CellularCapabilityUniversal::OnModem3GPPPropertiesChanged(
    const KeyValueStore& properties,
    const vector<string>& /* invalidated_properties */) {
  SLOG(this, 3) << __func__;
  if (properties.ContainsString(MM_MODEM_MODEM3GPP_PROPERTY_IMEI))
    cellular()->set_imei(
        properties.GetString(MM_MODEM_MODEM3GPP_PROPERTY_IMEI));

  // Handle registration state changes as a single change
  Stringmap::const_iterator it;
  string operator_code;
  string operator_name;
  it = serving_operator_.find(kOperatorCodeKey);
  if (it != serving_operator_.end())
    operator_code = it->second;
  it = serving_operator_.find(kOperatorNameKey);
  if (it != serving_operator_.end())
    operator_name = it->second;

  MMModem3gppRegistrationState state = registration_state_;
  bool registration_changed = false;
  if (properties.ContainsUint(MM_MODEM_MODEM3GPP_PROPERTY_REGISTRATIONSTATE)) {
    state = static_cast<MMModem3gppRegistrationState>(
        properties.GetUint(MM_MODEM_MODEM3GPP_PROPERTY_REGISTRATIONSTATE));
    registration_changed = true;
  }
  if (properties.ContainsString(MM_MODEM_MODEM3GPP_PROPERTY_OPERATORCODE)) {
    operator_code =
        properties.GetString(MM_MODEM_MODEM3GPP_PROPERTY_OPERATORCODE);
    registration_changed = true;
  }
  if (properties.ContainsString(MM_MODEM_MODEM3GPP_PROPERTY_OPERATORNAME)) {
    operator_name =
        properties.GetString(MM_MODEM_MODEM3GPP_PROPERTY_OPERATORNAME);
    registration_changed = true;
  }
  if (registration_changed)
    On3GPPRegistrationChanged(state, operator_code, operator_name);
  if (properties.ContainsUint(MM_MODEM_MODEM3GPP_PROPERTY_SUBSCRIPTIONSTATE))
    On3GPPSubscriptionStateChanged(
        static_cast<MMModem3gppSubscriptionState>(
            properties.GetUint(MM_MODEM_MODEM3GPP_PROPERTY_SUBSCRIPTIONSTATE)));

  CellularServiceRefPtr service = cellular()->service();
  if (service.get() &&
      properties.ContainsUint(MM_MODEM_MODEM3GPP_PROPERTY_SUBSCRIPTIONSTATE)) {
    uint32_t subscription_state =
        properties.GetUint(MM_MODEM_MODEM3GPP_PROPERTY_SUBSCRIPTIONSTATE);
    SLOG(this, 3) << __func__ << ": Subscription state = "
                              << subscription_state;
    service->out_of_credits_detector()->NotifySubscriptionStateChanged(
        subscription_state);
  }

  if (properties.ContainsUint(MM_MODEM_MODEM3GPP_PROPERTY_ENABLEDFACILITYLOCKS))
    OnFacilityLocksChanged(
        properties.GetUint(MM_MODEM_MODEM3GPP_PROPERTY_ENABLEDFACILITYLOCKS));
}

void CellularCapabilityUniversal::On3GPPRegistrationChanged(
    MMModem3gppRegistrationState state,
    const string& operator_code,
    const string& operator_name) {
  SLOG(this, 3) << __func__ << ": regstate=" << state
                            << ", opercode=" << operator_code
                            << ", opername=" << operator_name;

  // While the modem is connected, if the state changed from a registered state
  // to a non registered state, defer the state change by 15 seconds.
  if (cellular()->modem_state() == Cellular::kModemStateConnected &&
      IsRegistered() && !IsRegisteredState(state)) {
    if (!registration_dropped_update_callback_.IsCancelled()) {
      LOG(WARNING) << "Modem reported consecutive 3GPP registration drops. "
                   << "Ignoring earlier notifications.";
      registration_dropped_update_callback_.Cancel();
    } else {
      // This is not a repeated post. So, count this instance of delayed drop
      // posted.
      modem_info()->metrics()->Notify3GPPRegistrationDelayedDropPosted();
    }
    SLOG(this, 2) << "Posted deferred registration state update";
    registration_dropped_update_callback_.Reset(
        Bind(&CellularCapabilityUniversal::Handle3GPPRegistrationChange,
             weak_ptr_factory_.GetWeakPtr(),
             state,
             operator_code,
             operator_name));
    cellular()->dispatcher()->PostDelayedTask(
        registration_dropped_update_callback_.callback(),
        registration_dropped_update_timeout_milliseconds_);
  } else {
    if (!registration_dropped_update_callback_.IsCancelled()) {
      SLOG(this, 2) << "Cancelled a deferred registration state update";
      registration_dropped_update_callback_.Cancel();
      // If we cancelled the callback here, it means we had flaky network for a
      // small duration.
      modem_info()->metrics()->Notify3GPPRegistrationDelayedDropCanceled();
    }
    Handle3GPPRegistrationChange(state, operator_code, operator_name);
  }
}

void CellularCapabilityUniversal::Handle3GPPRegistrationChange(
    MMModem3gppRegistrationState updated_state,
    string updated_operator_code,
    string updated_operator_name) {
  // A finished callback does not qualify as a canceled callback.
  // We test for a canceled callback to check for outstanding callbacks.
  // So, explicitly cancel the callback here.
  registration_dropped_update_callback_.Cancel();

  SLOG(this, 3) << __func__ << ": regstate=" << updated_state
                            << ", opercode=" << updated_operator_code
                            << ", opername=" << updated_operator_name;

  registration_state_ = updated_state;
  serving_operator_[kOperatorCodeKey] = updated_operator_code;
  serving_operator_[kOperatorNameKey] = updated_operator_name;
  cellular()->serving_operator_info()->UpdateMCCMNC(updated_operator_code);
  cellular()->serving_operator_info()->UpdateOperatorName(
      updated_operator_name);

  cellular()->HandleNewRegistrationState();

  // If the modem registered with the network and the current ICCID is pending
  // activation, then reset the modem.
  UpdatePendingActivationState();
}

void CellularCapabilityUniversal::On3GPPSubscriptionStateChanged(
    MMModem3gppSubscriptionState updated_state) {
  SLOG(this, 3) << __func__ << ": Updated subscription state = "
                            << updated_state;

  // A one-to-one enum mapping.
  SubscriptionState new_subscription_state;
  switch (updated_state) {
    case MM_MODEM_3GPP_SUBSCRIPTION_STATE_UNKNOWN:
      new_subscription_state = kSubscriptionStateUnknown;
      break;
    case MM_MODEM_3GPP_SUBSCRIPTION_STATE_PROVISIONED:
      new_subscription_state = kSubscriptionStateProvisioned;
      break;
    case MM_MODEM_3GPP_SUBSCRIPTION_STATE_UNPROVISIONED:
      new_subscription_state = kSubscriptionStateUnprovisioned;
      break;
    case MM_MODEM_3GPP_SUBSCRIPTION_STATE_OUT_OF_DATA:
      new_subscription_state = kSubscriptionStateOutOfData;
      break;
    default:
      LOG(ERROR) << "Unrecognized MMModem3gppSubscriptionState: "
                 << updated_state;
      new_subscription_state = kSubscriptionStateUnknown;
      return;
  }
  if (new_subscription_state == subscription_state_)
    return;

  subscription_state_ = new_subscription_state;

  UpdateServiceActivationState();
  UpdatePendingActivationState();
}

void CellularCapabilityUniversal::OnModemStateChangedSignal(
    int32_t old_state, int32_t new_state, uint32_t reason) {
  Cellular::ModemState old_modem_state =
      static_cast<Cellular::ModemState>(old_state);
  Cellular::ModemState new_modem_state =
      static_cast<Cellular::ModemState>(new_state);
  SLOG(this, 3) << __func__ << "("
                            << Cellular::GetModemStateString(old_modem_state)
                            << ", "
                            << Cellular::GetModemStateString(new_modem_state)
                            << ", "
                            << reason << ")";
}

void CellularCapabilityUniversal::OnSignalQualityChanged(uint32_t quality) {
  cellular()->HandleNewSignalQuality(quality);
}

void CellularCapabilityUniversal::OnFacilityLocksChanged(uint32_t locks) {
  bool sim_enabled = !!(locks & MM_MODEM_3GPP_FACILITY_SIM);
  if (sim_lock_status_.enabled != sim_enabled) {
    sim_lock_status_.enabled = sim_enabled;
    OnSimLockStatusChanged();
  }
}

void CellularCapabilityUniversal::OnSimPropertiesChanged(
    const KeyValueStore& props,
    const vector<string>& /* invalidated_properties */) {
  SLOG(this, 3) << __func__;
  if (props.ContainsString(MM_SIM_PROPERTY_SIMIDENTIFIER))
    OnSimIdentifierChanged(props.GetString(MM_SIM_PROPERTY_SIMIDENTIFIER));
  if (props.ContainsString(MM_SIM_PROPERTY_OPERATORIDENTIFIER))
    OnOperatorIdChanged(props.GetString(MM_SIM_PROPERTY_OPERATORIDENTIFIER));
  if (props.ContainsString(MM_SIM_PROPERTY_OPERATORNAME))
    OnSpnChanged(props.GetString(MM_SIM_PROPERTY_OPERATORNAME));
  if (props.ContainsString(MM_SIM_PROPERTY_IMSI)) {
    string imsi = props.GetString(MM_SIM_PROPERTY_IMSI);
    cellular()->set_imsi(imsi);
    cellular()->home_provider_info()->UpdateIMSI(imsi);
    // We do not obtain IMSI OTA right now. Provide the value from the SIM to
    // serving operator as well, to aid in MVNO identification.
    cellular()->serving_operator_info()->UpdateIMSI(imsi);
  }
}

void CellularCapabilityUniversal::OnSpnChanged(const std::string& spn) {
  spn_ = spn;
  cellular()->home_provider_info()->UpdateOperatorName(spn);
}

void CellularCapabilityUniversal::OnSimIdentifierChanged(const string& id) {
  cellular()->set_sim_identifier(id);
  cellular()->home_provider_info()->UpdateICCID(id);
  // Provide ICCID to serving operator as well to aid in MVNO identification.
  cellular()->serving_operator_info()->UpdateICCID(id);
  UpdatePendingActivationState();
}

void CellularCapabilityUniversal::OnOperatorIdChanged(
    const string& operator_id) {
  SLOG(this, 2) << "Operator ID = '" << operator_id << "'";
  cellular()->home_provider_info()->UpdateMCCMNC(operator_id);
}

OutOfCreditsDetector::OOCType
CellularCapabilityUniversal::GetOutOfCreditsDetectionType() const {
  if (cellular()->mm_plugin() == kAltairLTEMMPlugin) {
    return OutOfCreditsDetector::OOCTypeSubscriptionState;
  } else {
    return OutOfCreditsDetector::OOCTypeNone;
  }
}

}  // namespace shill