cellular_capability_gsm.cc - platform/system/connectivity/shill - Gitiles

 // Copyright (c) 2011 The Chromium OS Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "shill/cellular_capability_gsm.h"

 #include <base/logging.h>
 #include <base/stl_util-inl.h>
 #include <base/string_number_conversions.h>
 #include <chromeos/dbus/service_constants.h>
 #include <mm/mm-modem.h>
 #include <mobile_provider.h>

 #include "shill/cellular.h"
 #include "shill/proxy_factory.h"

 using std::string;

 namespace shill {

 const char CellularCapabilityGSM::kNetworkPropertyAccessTechnology[] =
     "access-tech";
 const char CellularCapabilityGSM::kNetworkPropertyID[] = "operator-num";
 const char CellularCapabilityGSM::kNetworkPropertyLongName[] = "operator-long";
 const char CellularCapabilityGSM::kNetworkPropertyShortName[] =
     "operator-short";
 const char CellularCapabilityGSM::kNetworkPropertyStatus[] = "status";

 CellularCapabilityGSM::CellularCapabilityGSM(Cellular *cellular)
     : CellularCapability(cellular),
       task_factory_(this),
       scanning_(false),
       scan_interval_(0) {
   PropertyStore *store = cellular->mutable_store();
   store->RegisterConstStringmaps(flimflam::kFoundNetworksProperty,
                                  &found_networks_);
   store->RegisterConstBool(flimflam::kScanningProperty, &scanning_);
   store->RegisterUint16(flimflam::kScanIntervalProperty, &scan_interval_);
 }

 void CellularCapabilityGSM::InitProxies() {
   VLOG(2) << __func__;
   card_proxy_.reset(
       proxy_factory()->CreateModemGSMCardProxy(this,
                                                cellular()->dbus_path(),
                                                cellular()->dbus_owner()));
   // TODO(petkov): Move GSM-specific proxy ownership from Cellular to this.
   cellular()->set_modem_gsm_network_proxy(
       proxy_factory()->CreateModemGSMNetworkProxy(cellular(),
                                                   cellular()->dbus_path(),
                                                   cellular()->dbus_owner()));
 }

 void CellularCapabilityGSM::GetIdentifiers() {
   VLOG(2) << __func__;
   if (cellular()->imei().empty()) {
     // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
     cellular()->set_imei(card_proxy_->GetIMEI());
     VLOG(2) << "IMEI: " << cellular()->imei();
   }
   if (cellular()->imsi().empty()) {
     // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
     cellular()->set_imsi(card_proxy_->GetIMSI());
     VLOG(2) << "IMSI: " << cellular()->imsi();
   }
   if (cellular()->spn().empty()) {
     // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
     try {
       cellular()->set_spn(card_proxy_->GetSPN());
       VLOG(2) << "SPN: " << cellular()->spn();
     } catch (const DBus::Error e) {
       // Some modems don't support this call so catch the exception explicitly.
       LOG(WARNING) << "Unable to obtain SPN: " << e.what();
     }
   }
   if (cellular()->mdn().empty()) {
     // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
     cellular()->set_mdn(card_proxy_->GetMSISDN());
     VLOG(2) << "MSISDN/MDN: " << cellular()->mdn();
   }
 }

 void CellularCapabilityGSM::GetSignalQuality() {
   VLOG(2) << __func__;
   // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
   uint32 strength = cellular()->modem_gsm_network_proxy()->GetSignalQuality();
   cellular()->HandleNewSignalQuality(strength);
 }

 void CellularCapabilityGSM::RequirePIN(
     const string &pin, bool require, Error */*error*/) {
   VLOG(2) << __func__ << "(" << pin << ", " << require << ")";
   // Defer because we may be in a dbus-c++ callback.
   dispatcher()->PostTask(
       task_factory_.NewRunnableMethod(
           &CellularCapabilityGSM::RequirePINTask, pin, require));
 }

 void CellularCapabilityGSM::RequirePINTask(const string &pin, bool require) {
   VLOG(2) << __func__ << "(" << pin << ", " << require << ")";
   // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
   card_proxy_->EnablePIN(pin, require);
 }

 void CellularCapabilityGSM::EnterPIN(const string &pin, Error */*error*/) {
   VLOG(2) << __func__ << "(" << pin << ")";
   // Defer because we may be in a dbus-c++ callback.
   dispatcher()->PostTask(
       task_factory_.NewRunnableMethod(
           &CellularCapabilityGSM::EnterPINTask, pin));
 }

 void CellularCapabilityGSM::EnterPINTask(const string &pin) {
   VLOG(2) << __func__ << "(" << pin << ")";
   // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
   card_proxy_->SendPIN(pin);
 }

 void CellularCapabilityGSM::UnblockPIN(
     const string &unblock_code, const string &pin, Error */*error*/) {
   VLOG(2) << __func__ << "(" << unblock_code << ", " << pin << ")";
   // Defer because we may be in a dbus-c++ callback.
   dispatcher()->PostTask(
       task_factory_.NewRunnableMethod(
           &CellularCapabilityGSM::UnblockPINTask, unblock_code, pin));
 }

 void CellularCapabilityGSM::UnblockPINTask(
     const string &unblock_code, const string &pin) {
   VLOG(2) << __func__ << "(" << unblock_code << ", " << pin << ")";
   // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
   card_proxy_->SendPUK(unblock_code, pin);
 }

 void CellularCapabilityGSM::ChangePIN(
     const string &old_pin, const string &new_pin, Error */*error*/) {
   VLOG(2) << __func__ << "(" << old_pin << ", " << new_pin << ")";
   // Defer because we may be in a dbus-c++ callback.
   dispatcher()->PostTask(
       task_factory_.NewRunnableMethod(
           &CellularCapabilityGSM::ChangePINTask, old_pin, new_pin));
 }

 void CellularCapabilityGSM::ChangePINTask(
     const string &old_pin, const string &new_pin) {
   VLOG(2) << __func__ << "(" << old_pin << ", " << new_pin << ")";
   // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
   card_proxy_->ChangePIN(old_pin, new_pin);
 }

 void CellularCapabilityGSM::Scan(Error */*error*/) {
   VLOG(2) << __func__;
   // Defer because we may be in a dbus-c++ callback.
   dispatcher()->PostTask(
       task_factory_.NewRunnableMethod(&CellularCapabilityGSM::ScanTask));
 }

 void CellularCapabilityGSM::ScanTask() {
   VLOG(2) << __func__;
   // TODO(petkov): Defer scan requests if a scan is in progress already.
   //
   // TODO(petkov): Switch to asynchronous calls (crosbug.com/17583). This is a
   // must for this call which is basically a stub at this point.
   ModemGSMNetworkProxyInterface::ScanResults results =
       cellular()->modem_gsm_network_proxy()->Scan();
   found_networks_.clear();
   for (ModemGSMNetworkProxyInterface::ScanResults::const_iterator it =
            results.begin(); it != results.end(); ++it) {
     found_networks_.push_back(ParseScanResult(*it));
   }
 }

 Stringmap CellularCapabilityGSM::ParseScanResult(
     const ModemGSMNetworkProxyInterface::ScanResult &result) {
   Stringmap parsed;
   for (ModemGSMNetworkProxyInterface::ScanResult::const_iterator it =
            result.begin(); it != result.end(); ++it) {
     // TODO(petkov): Define these in system_api/service_constants.h. The
     // numerical values are taken from 3GPP TS 27.007 Section 7.3.
     static const char * const kStatusString[] = {
       "unknown",
       "available",
       "current",
       "forbidden",
     };
     static const char * const kTechnologyString[] = {
       flimflam::kNetworkTechnologyGsm,
       "GSM Compact",
       flimflam::kNetworkTechnologyUmts,
       flimflam::kNetworkTechnologyEdge,
       "HSDPA",
       "HSUPA",
       flimflam::kNetworkTechnologyHspa,
     };
     VLOG(2) << "Network property: " << it->first << " = " << it->second;
     if (it->first == kNetworkPropertyStatus) {
       int status = 0;
       if (base::StringToInt(it->second, &status) &&
           status >= 0 &&
           status < static_cast<int>(arraysize(kStatusString))) {
         parsed[flimflam::kStatusProperty] = kStatusString[status];
       } else {
         LOG(ERROR) << "Unexpected status value: " << it->second;
       }
     } else if (it->first == kNetworkPropertyID) {
       parsed[flimflam::kNetworkIdProperty] = it->second;
     } else if (it->first == kNetworkPropertyLongName) {
       parsed[flimflam::kLongNameProperty] = it->second;
     } else if (it->first == kNetworkPropertyShortName) {
       parsed[flimflam::kShortNameProperty] = it->second;
     } else if (it->first == kNetworkPropertyAccessTechnology) {
       int tech = 0;
       if (base::StringToInt(it->second, &tech) &&
           tech >= 0 &&
           tech < static_cast<int>(arraysize(kTechnologyString))) {
         parsed[flimflam::kTechnologyProperty] = kTechnologyString[tech];
       } else {
         LOG(ERROR) << "Unexpected technology value: " << it->second;
       }
     } else {
       LOG(WARNING) << "Unknown network property ignored: " << it->first;
     }
   }
   // 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, flimflam::kLongNameProperty) ||
        parsed[flimflam::kLongNameProperty].empty()) &&
       ContainsKey(parsed, flimflam::kNetworkIdProperty)) {
     mobile_provider *provider =
         mobile_provider_lookup_by_network(
             cellular()->provider_db(),
             parsed[flimflam::kNetworkIdProperty].c_str());
     if (provider) {
       const char *long_name = mobile_provider_get_name(provider);
       if (long_name && *long_name) {
         parsed[flimflam::kLongNameProperty] = long_name;
       }
     }
   }
   return parsed;
 }

 string CellularCapabilityGSM::GetNetworkTechnologyString() const {
   if (cellular()->gsm_registration_state() ==
       MM_MODEM_GSM_NETWORK_REG_STATUS_HOME ||
       cellular()->gsm_registration_state() ==
       MM_MODEM_GSM_NETWORK_REG_STATUS_ROAMING) {
     switch (cellular()->gsm_access_technology()) {
       case MM_MODEM_GSM_ACCESS_TECH_GSM:
       case MM_MODEM_GSM_ACCESS_TECH_GSM_COMPACT:
         return flimflam::kNetworkTechnologyGsm;
       case MM_MODEM_GSM_ACCESS_TECH_GPRS:
         return flimflam::kNetworkTechnologyGprs;
       case MM_MODEM_GSM_ACCESS_TECH_EDGE:
         return flimflam::kNetworkTechnologyEdge;
       case MM_MODEM_GSM_ACCESS_TECH_UMTS:
         return flimflam::kNetworkTechnologyUmts;
       case MM_MODEM_GSM_ACCESS_TECH_HSDPA:
       case MM_MODEM_GSM_ACCESS_TECH_HSUPA:
       case MM_MODEM_GSM_ACCESS_TECH_HSPA:
         return flimflam::kNetworkTechnologyHspa;
       case MM_MODEM_GSM_ACCESS_TECH_HSPA_PLUS:
         return flimflam::kNetworkTechnologyHspaPlus;
       default:
         NOTREACHED();
     }
   }
   return "";
 }

 string CellularCapabilityGSM::GetRoamingStateString() const {
   switch (cellular()->gsm_registration_state()) {
     case MM_MODEM_GSM_NETWORK_REG_STATUS_HOME:
       return flimflam::kRoamingStateHome;
     case MM_MODEM_GSM_NETWORK_REG_STATUS_ROAMING:
       return flimflam::kRoamingStateRoaming;
     default:
       break;
   }
   return flimflam::kRoamingStateUnknown;
 }

 }  // namespace shill
	// Copyright (c) 2011 The Chromium OS Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "shill/cellular_capability_gsm.h"

	#include <base/logging.h>
	#include <base/stl_util-inl.h>
	#include <base/string_number_conversions.h>
	#include <chromeos/dbus/service_constants.h>
	#include <mm/mm-modem.h>
	#include <mobile_provider.h>

	#include "shill/cellular.h"
	#include "shill/proxy_factory.h"

	using std::string;

	namespace shill {

	const char CellularCapabilityGSM::kNetworkPropertyAccessTechnology[] =
	"access-tech";
	const char CellularCapabilityGSM::kNetworkPropertyID[] = "operator-num";
	const char CellularCapabilityGSM::kNetworkPropertyLongName[] = "operator-long";
	const char CellularCapabilityGSM::kNetworkPropertyShortName[] =
	"operator-short";
	const char CellularCapabilityGSM::kNetworkPropertyStatus[] = "status";

	CellularCapabilityGSM::CellularCapabilityGSM(Cellular *cellular)
	: CellularCapability(cellular),
	task_factory_(this),
	scanning_(false),
	scan_interval_(0) {
	PropertyStore *store = cellular->mutable_store();
	store->RegisterConstStringmaps(flimflam::kFoundNetworksProperty,
	&found_networks_);
	store->RegisterConstBool(flimflam::kScanningProperty, &scanning_);
	store->RegisterUint16(flimflam::kScanIntervalProperty, &scan_interval_);
	}

	void CellularCapabilityGSM::InitProxies() {
	VLOG(2) << __func__;
	card_proxy_.reset(
	proxy_factory()->CreateModemGSMCardProxy(this,
	cellular()->dbus_path(),
	cellular()->dbus_owner()));
	// TODO(petkov): Move GSM-specific proxy ownership from Cellular to this.
	cellular()->set_modem_gsm_network_proxy(
	proxy_factory()->CreateModemGSMNetworkProxy(cellular(),
	cellular()->dbus_path(),
	cellular()->dbus_owner()));
	}

	void CellularCapabilityGSM::GetIdentifiers() {
	VLOG(2) << __func__;
	if (cellular()->imei().empty()) {
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	cellular()->set_imei(card_proxy_->GetIMEI());
	VLOG(2) << "IMEI: " << cellular()->imei();
	}
	if (cellular()->imsi().empty()) {
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	cellular()->set_imsi(card_proxy_->GetIMSI());
	VLOG(2) << "IMSI: " << cellular()->imsi();
	}
	if (cellular()->spn().empty()) {
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	try {
	cellular()->set_spn(card_proxy_->GetSPN());
	VLOG(2) << "SPN: " << cellular()->spn();
	} catch (const DBus::Error e) {
	// Some modems don't support this call so catch the exception explicitly.
	LOG(WARNING) << "Unable to obtain SPN: " << e.what();
	}
	}
	if (cellular()->mdn().empty()) {
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	cellular()->set_mdn(card_proxy_->GetMSISDN());
	VLOG(2) << "MSISDN/MDN: " << cellular()->mdn();
	}
	}

	void CellularCapabilityGSM::GetSignalQuality() {
	VLOG(2) << __func__;
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	uint32 strength = cellular()->modem_gsm_network_proxy()->GetSignalQuality();
	cellular()->HandleNewSignalQuality(strength);
	}

	void CellularCapabilityGSM::RequirePIN(
	const string &pin, bool require, Error /error*/) {
	VLOG(2) << __func__ << "(" << pin << ", " << require << ")";
	// Defer because we may be in a dbus-c++ callback.
	dispatcher()->PostTask(
	task_factory_.NewRunnableMethod(
	&CellularCapabilityGSM::RequirePINTask, pin, require));
	}

	void CellularCapabilityGSM::RequirePINTask(const string &pin, bool require) {
	VLOG(2) << __func__ << "(" << pin << ", " << require << ")";
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	card_proxy_->EnablePIN(pin, require);
	}

	void CellularCapabilityGSM::EnterPIN(const string &pin, Error /error*/) {
	VLOG(2) << __func__ << "(" << pin << ")";
	// Defer because we may be in a dbus-c++ callback.
	dispatcher()->PostTask(
	task_factory_.NewRunnableMethod(
	&CellularCapabilityGSM::EnterPINTask, pin));
	}

	void CellularCapabilityGSM::EnterPINTask(const string &pin) {
	VLOG(2) << __func__ << "(" << pin << ")";
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	card_proxy_->SendPIN(pin);
	}

	void CellularCapabilityGSM::UnblockPIN(
	const string &unblock_code, const string &pin, Error /error*/) {
	VLOG(2) << __func__ << "(" << unblock_code << ", " << pin << ")";
	// Defer because we may be in a dbus-c++ callback.
	dispatcher()->PostTask(
	task_factory_.NewRunnableMethod(
	&CellularCapabilityGSM::UnblockPINTask, unblock_code, pin));
	}

	void CellularCapabilityGSM::UnblockPINTask(
	const string &unblock_code, const string &pin) {
	VLOG(2) << __func__ << "(" << unblock_code << ", " << pin << ")";
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	card_proxy_->SendPUK(unblock_code, pin);
	}

	void CellularCapabilityGSM::ChangePIN(
	const string &old_pin, const string &new_pin, Error /error*/) {
	VLOG(2) << __func__ << "(" << old_pin << ", " << new_pin << ")";
	// Defer because we may be in a dbus-c++ callback.
	dispatcher()->PostTask(
	task_factory_.NewRunnableMethod(
	&CellularCapabilityGSM::ChangePINTask, old_pin, new_pin));
	}

	void CellularCapabilityGSM::ChangePINTask(
	const string &old_pin, const string &new_pin) {
	VLOG(2) << __func__ << "(" << old_pin << ", " << new_pin << ")";
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583).
	card_proxy_->ChangePIN(old_pin, new_pin);
	}

	void CellularCapabilityGSM::Scan(Error /error*/) {
	VLOG(2) << __func__;
	// Defer because we may be in a dbus-c++ callback.
	dispatcher()->PostTask(
	task_factory_.NewRunnableMethod(&CellularCapabilityGSM::ScanTask));
	}

	void CellularCapabilityGSM::ScanTask() {
	VLOG(2) << __func__;
	// TODO(petkov): Defer scan requests if a scan is in progress already.
	//
	// TODO(petkov): Switch to asynchronous calls (crosbug.com/17583). This is a
	// must for this call which is basically a stub at this point.
	ModemGSMNetworkProxyInterface::ScanResults results =
	cellular()->modem_gsm_network_proxy()->Scan();
	found_networks_.clear();
	for (ModemGSMNetworkProxyInterface::ScanResults::const_iterator it =
	results.begin(); it != results.end(); ++it) {
	found_networks_.push_back(ParseScanResult(*it));
	}
	}

	Stringmap CellularCapabilityGSM::ParseScanResult(
	const ModemGSMNetworkProxyInterface::ScanResult &result) {
	Stringmap parsed;
	for (ModemGSMNetworkProxyInterface::ScanResult::const_iterator it =
	result.begin(); it != result.end(); ++it) {
	// TODO(petkov): Define these in system_api/service_constants.h. The
	// numerical values are taken from 3GPP TS 27.007 Section 7.3.
	static const char * const kStatusString[] = {
	"unknown",
	"available",
	"current",
	"forbidden",
	};
	static const char * const kTechnologyString[] = {
	flimflam::kNetworkTechnologyGsm,
	"GSM Compact",
	flimflam::kNetworkTechnologyUmts,
	flimflam::kNetworkTechnologyEdge,
	"HSDPA",
	"HSUPA",
	flimflam::kNetworkTechnologyHspa,
	};
	VLOG(2) << "Network property: " << it->first << " = " << it->second;
	if (it->first == kNetworkPropertyStatus) {
	int status = 0;
	if (base::StringToInt(it->second, &status) &&
	status >= 0 &&
	status < static_cast<int>(arraysize(kStatusString))) {
	parsed[flimflam::kStatusProperty] = kStatusString[status];
	} else {
	LOG(ERROR) << "Unexpected status value: " << it->second;
	}
	} else if (it->first == kNetworkPropertyID) {
	parsed[flimflam::kNetworkIdProperty] = it->second;
	} else if (it->first == kNetworkPropertyLongName) {
	parsed[flimflam::kLongNameProperty] = it->second;
	} else if (it->first == kNetworkPropertyShortName) {
	parsed[flimflam::kShortNameProperty] = it->second;
	} else if (it->first == kNetworkPropertyAccessTechnology) {
	int tech = 0;
	if (base::StringToInt(it->second, &tech) &&
	tech >= 0 &&
	tech < static_cast<int>(arraysize(kTechnologyString))) {
	parsed[flimflam::kTechnologyProperty] = kTechnologyString[tech];
	} else {
	LOG(ERROR) << "Unexpected technology value: " << it->second;
	}
	} else {
	LOG(WARNING) << "Unknown network property ignored: " << it->first;
	}
	}
	// 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, flimflam::kLongNameProperty) \|\|
	parsed[flimflam::kLongNameProperty].empty()) &&
	ContainsKey(parsed, flimflam::kNetworkIdProperty)) {
	mobile_provider *provider =
	mobile_provider_lookup_by_network(
	cellular()->provider_db(),
	parsed[flimflam::kNetworkIdProperty].c_str());
	if (provider) {
	const char *long_name = mobile_provider_get_name(provider);
	if (long_name && *long_name) {
	parsed[flimflam::kLongNameProperty] = long_name;
	}
	}
	}
	return parsed;
	}

	string CellularCapabilityGSM::GetNetworkTechnologyString() const {
	if (cellular()->gsm_registration_state() ==
	MM_MODEM_GSM_NETWORK_REG_STATUS_HOME \|\|
	cellular()->gsm_registration_state() ==
	MM_MODEM_GSM_NETWORK_REG_STATUS_ROAMING) {
	switch (cellular()->gsm_access_technology()) {
	case MM_MODEM_GSM_ACCESS_TECH_GSM:
	case MM_MODEM_GSM_ACCESS_TECH_GSM_COMPACT:
	return flimflam::kNetworkTechnologyGsm;
	case MM_MODEM_GSM_ACCESS_TECH_GPRS:
	return flimflam::kNetworkTechnologyGprs;
	case MM_MODEM_GSM_ACCESS_TECH_EDGE:
	return flimflam::kNetworkTechnologyEdge;
	case MM_MODEM_GSM_ACCESS_TECH_UMTS:
	return flimflam::kNetworkTechnologyUmts;
	case MM_MODEM_GSM_ACCESS_TECH_HSDPA:
	case MM_MODEM_GSM_ACCESS_TECH_HSUPA:
	case MM_MODEM_GSM_ACCESS_TECH_HSPA:
	return flimflam::kNetworkTechnologyHspa;
	case MM_MODEM_GSM_ACCESS_TECH_HSPA_PLUS:
	return flimflam::kNetworkTechnologyHspaPlus;
	default:
	NOTREACHED();
	}
	}
	return "";
	}

	string CellularCapabilityGSM::GetRoamingStateString() const {
	switch (cellular()->gsm_registration_state()) {
	case MM_MODEM_GSM_NETWORK_REG_STATUS_HOME:
	return flimflam::kRoamingStateHome;
	case MM_MODEM_GSM_NETWORK_REG_STATUS_ROAMING:
	return flimflam::kRoamingStateRoaming;
	default:
	break;
	}
	return flimflam::kRoamingStateUnknown;
	}

	} // namespace shill