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/*
*
* Copyright (c) 2020 Project CHIP Authors
* Copyright (c) 2022 Silabs.
* All rights reserved.
*
* 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 "AppConfig.h"
#include "BaseApplication.h"
#include <MatterConfig.h>
#include <cmsis_os2.h>
#include <mbedtls/platform.h>
#ifdef SL_WIFI
#include <platform/silabs/wifi/WifiInterfaceAbstraction.h>
#endif /* SL_WIFI */
#if PW_RPC_ENABLED
#include "Rpc.h"
#endif
#ifdef ENABLE_CHIP_SHELL
#include "MatterShell.h"
#endif
#ifdef HEAP_MONITORING
#include "MemMonitoring.h"
#endif
#if defined(SLI_SI91X_MCU_INTERFACE) && SLI_SI91X_MCU_INTERFACE == 1
#include <platform/silabs/SiWx917/SiWxPlatformInterface.h>
#include <platform/silabs/wifi/wiseconnect-abstraction/WiseconnectInterfaceAbstraction.h>
#endif // SLI_SI91X_MCU_INTERFACE
#include <crypto/CHIPCryptoPAL.h>
// If building with the EFR32-provided crypto backend, we can use the
// opaque keystore
#if CHIP_CRYPTO_PLATFORM && !(defined(SLI_SI91X_MCU_INTERFACE))
#include <platform/silabs/efr32/Efr32PsaOperationalKeystore.h>
static chip::DeviceLayer::Internal::Efr32PsaOperationalKeystore gOperationalKeystore;
#endif
#include <ProvisionManager.h>
#include <app/InteractionModelEngine.h>
#include <app/TimerDelegates.h>
#include <app/codegen-data-model-provider/Instance.h>
#ifdef SL_MATTER_TEST_EVENT_TRIGGER_ENABLED
#include "SilabsTestEventTriggerDelegate.h" // nogncheck
#endif
#if CHIP_CONFIG_SYNCHRONOUS_REPORTS_ENABLED
#include <app/reporting/SynchronizedReportSchedulerImpl.h>
#else
#include <app/reporting/ReportSchedulerImpl.h>
#endif
#include <lib/support/BytesToHex.h>
#ifdef PERFORMANCE_TEST_ENABLED
#include <performance_test_commands.h>
#endif
#include <AppTask.h>
#include <DeviceInfoProviderImpl.h>
#include <app/server/Server.h>
#include <platform/silabs/platformAbstraction/SilabsPlatform.h>
/**********************************************************
* Defines
*********************************************************/
using namespace ::chip;
using namespace ::chip::Inet;
using namespace ::chip::DeviceLayer;
using namespace ::chip::Credentials;
using namespace chip::DeviceLayer::Silabs;
#if CHIP_ENABLE_OPENTHREAD
#include <inet/EndPointStateOpenThread.h>
#include <openthread/cli.h>
#include <openthread/dataset.h>
#include <openthread/error.h>
#include <openthread/heap.h>
#include <openthread/icmp6.h>
#include <openthread/instance.h>
#include <openthread/link.h>
#include <openthread/platform/openthread-system.h>
#include <openthread/tasklet.h>
#include <openthread/thread.h>
// ================================================================================
// Matter Networking Callbacks
// ================================================================================
void LockOpenThreadTask(void)
{
chip::DeviceLayer::ThreadStackMgr().LockThreadStack();
}
void UnlockOpenThreadTask(void)
{
chip::DeviceLayer::ThreadStackMgr().UnlockThreadStack();
}
// ================================================================================
// SilabsMatterConfig Methods
// ================================================================================
CHIP_ERROR SilabsMatterConfig::InitOpenThread(void)
{
ChipLogProgress(DeviceLayer, "Initializing OpenThread stack");
ReturnErrorOnFailure(ThreadStackMgr().InitThreadStack());
#if CHIP_DEVICE_CONFIG_THREAD_FTD
ReturnErrorOnFailure(ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_Router));
#else // CHIP_DEVICE_CONFIG_THREAD_FTD
#if CHIP_CONFIG_ENABLE_ICD_SERVER
#if CHIP_DEVICE_CONFIG_THREAD_SSED
ReturnErrorOnFailure(ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_SynchronizedSleepyEndDevice));
#else
ReturnErrorOnFailure(ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_SleepyEndDevice));
#endif
#else // CHIP_CONFIG_ENABLE_ICD_SERVER
ReturnErrorOnFailure(ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_MinimalEndDevice));
#endif // CHIP_CONFIG_ENABLE_ICD_SERVER
#endif // CHIP_DEVICE_CONFIG_THREAD_FTD
ChipLogProgress(DeviceLayer, "Starting OpenThread task");
return ThreadStackMgrImpl().StartThreadTask();
}
#endif // CHIP_ENABLE_OPENTHREAD
namespace {
constexpr uint32_t kMainTaskStackSize = (1024 * 5);
// Task is dynamically allocated with max priority. This task gets deleted once the inits are completed.
constexpr osThreadAttr_t kMainTaskAttr = { .name = "main",
.attr_bits = osThreadDetached,
.cb_mem = NULL,
.cb_size = 0U,
.stack_mem = NULL,
.stack_size = kMainTaskStackSize,
.priority = osPriorityRealtime7 };
osThreadId_t sMainTaskHandle;
static chip::DeviceLayer::DeviceInfoProviderImpl gExampleDeviceInfoProvider;
void ApplicationStart(void * unused)
{
CHIP_ERROR err = SilabsMatterConfig::InitMatter(BLE_DEV_NAME);
if (err != CHIP_NO_ERROR)
appError(err);
gExampleDeviceInfoProvider.SetStorageDelegate(&chip::Server::GetInstance().GetPersistentStorage());
chip::DeviceLayer::SetDeviceInfoProvider(&gExampleDeviceInfoProvider);
chip::DeviceLayer::PlatformMgr().LockChipStack();
// Initialize device attestation config
SetDeviceAttestationCredentialsProvider(&Provision::Manager::GetInstance().GetStorage());
chip::DeviceLayer::PlatformMgr().UnlockChipStack();
ChipLogProgress(DeviceLayer, "Starting App Task");
err = AppTask::GetAppTask().StartAppTask();
if (err != CHIP_NO_ERROR)
appError(err);
VerifyOrDie(osThreadTerminate(sMainTaskHandle) == osOK); // Deleting the main task should never fail.
sMainTaskHandle = nullptr;
}
} // namespace
void SilabsMatterConfig::AppInit()
{
GetPlatform().Init();
sMainTaskHandle = osThreadNew(ApplicationStart, nullptr, &kMainTaskAttr);
ChipLogProgress(DeviceLayer, "Starting scheduler");
VerifyOrDie(sMainTaskHandle); // We can't proceed if the Main Task creation failed.
GetPlatform().StartScheduler();
// Should never get here.
chip::Platform::MemoryShutdown();
ChipLogProgress(DeviceLayer, "Start Scheduler Failed");
appError(CHIP_ERROR_INTERNAL);
}
CHIP_ERROR SilabsMatterConfig::InitMatter(const char * appName)
{
CHIP_ERROR err;
#ifdef SL_WIFI
// Because OpenThread needs to use memory allocation during its Key operations, we initialize the memory management for thread
// and set the allocation functions inside sl_ot_create_instance, which is called by sl_system_init in the OpenThread stack
// initialization.
mbedtls_platform_set_calloc_free(CHIPPlatformMemoryCalloc, CHIPPlatformMemoryFree);
#endif
ChipLogProgress(DeviceLayer, "==================================================");
ChipLogProgress(DeviceLayer, "%s starting", appName);
ChipLogProgress(DeviceLayer, "==================================================");
#if PW_RPC_ENABLED
chip::rpc::Init();
#endif
#ifdef HEAP_MONITORING
MemMonitoring::StartMonitor();
#endif
//==============================================
// Init Matter Stack
//==============================================
ChipLogProgress(DeviceLayer, "Init CHIP Stack");
#ifdef SL_WIFI
// Init Chip memory management before the stack
// See comment above about OpenThread memory allocation as to why this is WIFI only here.
ReturnErrorOnFailure(chip::Platform::MemoryInit());
ReturnErrorOnFailure(InitWiFi());
#endif
ReturnErrorOnFailure(PlatformMgr().InitChipStack());
chip::DeviceLayer::ConnectivityMgr().SetBLEDeviceName(appName);
// Provision Manager
Silabs::Provision::Manager & provision = Silabs::Provision::Manager::GetInstance();
ReturnErrorOnFailure(provision.Init());
SetDeviceInstanceInfoProvider(&provision.GetStorage());
SetCommissionableDataProvider(&provision.GetStorage());
ChipLogProgress(DeviceLayer, "Provision mode %s", provision.IsProvisionRequired() ? "ENABLED" : "disabled");
#if CHIP_ENABLE_OPENTHREAD
ReturnErrorOnFailure(InitOpenThread());
#endif
// Stop Matter event handling while setting up resources
chip::DeviceLayer::PlatformMgr().LockChipStack();
// Create initParams with SDK example defaults here
// TODO: replace with our own init param to avoid double allocation in examples
static chip::CommonCaseDeviceServerInitParams initParams;
// Report scheduler and timer delegate instance
static chip::app::DefaultTimerDelegate sTimerDelegate;
#if CHIP_CONFIG_SYNCHRONOUS_REPORTS_ENABLED
static chip::app::reporting::SynchronizedReportSchedulerImpl sReportScheduler(&sTimerDelegate);
#else
static chip::app::reporting::ReportSchedulerImpl sReportScheduler(&sTimerDelegate);
#endif
initParams.reportScheduler = &sReportScheduler;
#ifdef SL_MATTER_TEST_EVENT_TRIGGER_ENABLED
static SilabsTestEventTriggerDelegate sTestEventTriggerDelegate;
initParams.testEventTriggerDelegate = &sTestEventTriggerDelegate;
#endif // SL_MATTER_TEST_EVENT_TRIGGER_ENABLED
#if CHIP_CRYPTO_PLATFORM && !(defined(SLI_SI91X_MCU_INTERFACE))
// When building with EFR32 crypto, use the opaque key store
// instead of the default (insecure) one.
gOperationalKeystore.Init();
initParams.operationalKeystore = &gOperationalKeystore;
#endif
// Initialize the remaining (not overridden) providers to the SDK example defaults
(void) initParams.InitializeStaticResourcesBeforeServerInit();
initParams.dataModelProvider = app::CodegenDataModelProviderInstance();
#if CHIP_ENABLE_OPENTHREAD
// Set up OpenThread configuration when OpenThread is included
chip::Inet::EndPointStateOpenThread::OpenThreadEndpointInitParam nativeParams;
nativeParams.lockCb = LockOpenThreadTask;
nativeParams.unlockCb = UnlockOpenThreadTask;
nativeParams.openThreadInstancePtr = chip::DeviceLayer::ThreadStackMgrImpl().OTInstance();
initParams.endpointNativeParams = static_cast<void *>(&nativeParams);
#endif
initParams.appDelegate = &BaseApplication::sAppDelegate;
// Init Matter Server and Start Event Loop
err = chip::Server::GetInstance().Init(initParams);
chip::DeviceLayer::PlatformMgr().UnlockChipStack();
ReturnErrorOnFailure(err);
SILABS_LOG("Starting Platform Manager Event Loop");
ReturnErrorOnFailure(PlatformMgr().StartEventLoopTask());
#ifdef ENABLE_CHIP_SHELL
chip::startShellTask();
#endif
return CHIP_NO_ERROR;
}
#ifdef SL_WIFI
CHIP_ERROR SilabsMatterConfig::InitWiFi(void)
{
#ifdef WF200_WIFI
// Start wfx bus communication task.
wfx_bus_start();
#ifdef SL_WFX_USE_SECURE_LINK
// start securelink key renegotiation task
wfx_securelink_task_start();
#endif // SL_WFX_USE_SECURE_LINK
#endif // WF200_WIFI
#if defined(SLI_SI91X_MCU_INTERFACE) && SLI_SI91X_MCU_INTERFACE == 1
VerifyOrReturnError(sl_matter_wifi_platform_init() == SL_STATUS_OK, CHIP_ERROR_INTERNAL);
#endif // SLI_SI91X_MCU_INTERFACE
return CHIP_NO_ERROR;
}
#endif // SL_WIFI
// ================================================================================
// FreeRTOS Callbacks
// ================================================================================
extern "C" void vApplicationIdleHook(void)
{
#if (SLI_SI91X_MCU_INTERFACE && CHIP_CONFIG_ENABLE_ICD_SERVER)
SiWxPlatformInterface::sl_si91x_btn_event_handler();
SiWxPlatformInterface::sl_si91x_uart_power_requirement_handler();
#endif
}