src/platform/bouffalolab/BL702/DiagnosticDataProviderImpl.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *    Copyright (c) 2022 Project CHIP Authors
  *    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 <platform/ConnectivityManager.h>
 #include <platform/internal/CHIPDeviceLayerInternal.h>

 #include <platform/DiagnosticDataProvider.h>
 #include <platform/bouffalolab/BL702/DiagnosticDataProviderImpl.h>

 #include <lwip/tcpip.h>

 #include "AppConfig.h"
 #include "FreeRTOS.h"

 using namespace ::chip::app::Clusters::GeneralDiagnostics;

 namespace chip {
 namespace DeviceLayer {

 extern "C" size_t get_heap_size(void);
 extern "C" size_t get_heap3_size(void);

 DiagnosticDataProviderImpl & DiagnosticDataProviderImpl::GetDefaultInstance()
 {
     static DiagnosticDataProviderImpl sInstance;
     return sInstance;
 }

 /*
  * The following Heap stats are compiled values done by the FreeRTOS Heap5 implementation.
  * It keeps track of the number of calls to allocate and free memory as well as the
  * number of free bytes remaining, but says nothing about fragmentation.
  */
 CHIP_ERROR DiagnosticDataProviderImpl::GetCurrentHeapFree(uint64_t & currentHeapFree)
 {
     /** for BL706 with PSRAM, just get SRAM heap size which is more critical for firmware execution **/

 #ifdef CFG_USE_PSRAM
     size_t freeHeapSize = xPortGetFreeHeapSize() + xPortGetFreeHeapSizePsram();
 #else
     size_t freeHeapSize              = xPortGetFreeHeapSize();
 #endif
     currentHeapFree = static_cast<uint64_t>(freeHeapSize);
     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetCurrentHeapUsed(uint64_t & currentHeapUsed)
 {
     // Calculate the Heap used based on Total heap - Free heap

 #ifdef CFG_USE_PSRAM
     int64_t heapUsed = (get_heap_size() + get_heap3_size() - xPortGetFreeHeapSize() - xPortGetFreeHeapSizePsram());
 #else
     size_t freeHeapSize              = xPortGetFreeHeapSize();
 #endif

     // Something went wrong, this should not happen
     VerifyOrReturnError(heapUsed >= 0, CHIP_ERROR_INVALID_INTEGER_VALUE);
     currentHeapUsed = static_cast<uint64_t>(heapUsed);
     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetCurrentHeapHighWatermark(uint64_t & currentHeapHighWatermark)
 {
     // FreeRTOS records the lowest amount of available heap during runtime
     // currentHeapHighWatermark wants the highest heap usage point so we calculate it here

 #ifdef CFG_USE_PSRAM
     int64_t HighestHeapUsageRecorded =
         (get_heap_size() + get_heap3_size() - xPortGetMinimumEverFreeHeapSize() - xPortGetMinimumEverFreeHeapSizePsram());
 #else
     size_t freeHeapSize              = xPortGetFreeHeapSize();
     int64_t HighestHeapUsageRecorded = (get_heap_size() - xPortGetMinimumEverFreeHeapSize());
 #endif

     // Something went wrong, this should not happen
     VerifyOrReturnError(HighestHeapUsageRecorded >= 0, CHIP_ERROR_INVALID_INTEGER_VALUE);
     currentHeapHighWatermark = static_cast<uint64_t>(HighestHeapUsageRecorded);

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetThreadMetrics(ThreadMetrics ** threadMetricsOut)
 {
     /* Obtain all available task information */
     TaskStatus_t * taskStatusArray;
     ThreadMetrics * head = nullptr;
     uint32_t arraySize, x, dummy;

     arraySize = uxTaskGetNumberOfTasks();

     taskStatusArray = static_cast<TaskStatus_t *>(chip::Platform::MemoryCalloc(arraySize, sizeof(TaskStatus_t)));

     if (taskStatusArray != NULL)
     {
         /* Generate raw status information about each task. */
         arraySize = uxTaskGetSystemState(taskStatusArray, arraySize, &dummy);
         /* For each populated position in the taskStatusArray array,
            format the raw data as human readable ASCII data. */

         for (x = 0; x < arraySize; x++)
         {
             ThreadMetrics * thread = new ThreadMetrics();
             if (thread)
             {
                 Platform::CopyString(thread->NameBuf, taskStatusArray[x].pcTaskName);
                 thread->name.Emplace(CharSpan::fromCharString(thread->NameBuf));
                 thread->id = taskStatusArray[x].xTaskNumber;
                 thread->stackFreeMinimum.Emplace(taskStatusArray[x].usStackHighWaterMark);

                 /* Unsupported metrics */
                 // thread->stackSize
                 // thread->stackFreeCurrent

                 thread->Next = head;
                 head         = thread;
             }
         }

         *threadMetricsOut = head;
         /* The array is no longer needed, free the memory it consumes. */
         chip::Platform::MemoryFree(taskStatusArray);
     }

     return CHIP_NO_ERROR;
 }

 void DiagnosticDataProviderImpl::ReleaseThreadMetrics(ThreadMetrics * threadMetrics)
 {
     while (threadMetrics)
     {
         ThreadMetrics * del = threadMetrics;
         threadMetrics       = threadMetrics->Next;
         delete del;
     }
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetRebootCount(uint16_t & rebootCount)
 {
     uint32_t count = 0;
     CHIP_ERROR err = ConfigurationMgr().GetRebootCount(count);

     if (err == CHIP_NO_ERROR)
     {
         VerifyOrReturnError(count <= UINT16_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE);
         rebootCount = static_cast<uint16_t>(count);
     }

     return err;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetBootReason(BootReasonType & bootReason)
 {
     uint32_t reason = 0;
     CHIP_ERROR err  = ConfigurationMgr().GetBootReason(reason);

     if (err == CHIP_NO_ERROR)
     {
         VerifyOrReturnError(reason <= UINT8_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE);
         bootReason = static_cast<BootReasonType>(reason);
     }

     return err;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetUpTime(uint64_t & upTime)
 {
     System::Clock::Timestamp currentTime = System::SystemClock().GetMonotonicTimestamp();
     System::Clock::Timestamp startTime   = PlatformMgrImpl().GetStartTime();

     if (currentTime >= startTime)
     {
         upTime = std::chrono::duration_cast<System::Clock::Seconds64>(currentTime - startTime).count();
         return CHIP_NO_ERROR;
     }

     return CHIP_ERROR_INVALID_TIME;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetTotalOperationalHours(uint32_t & totalOperationalHours)
 {
     uint64_t upTime = 0;

     if (GetUpTime(upTime) == CHIP_NO_ERROR)
     {
         uint32_t totalHours = 0;
         if (ConfigurationMgr().GetTotalOperationalHours(totalHours) == CHIP_NO_ERROR)
         {
             VerifyOrReturnError(upTime / 3600 <= UINT32_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE);
             totalOperationalHours = totalHours + static_cast<uint32_t>(upTime / 3600);
             return CHIP_NO_ERROR;
         }
     }

     return CHIP_ERROR_INVALID_TIME;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetActiveHardwareFaults(GeneralFaults<kMaxHardwareFaults> & hardwareFaults)
 {
 #if CHIP_CONFIG_TEST
     ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_RADIO));
     ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_SENSOR));
     ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_POWER_SOURCE));
     ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_USER_INTERFACE_FAULT));
 #endif

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetActiveRadioFaults(GeneralFaults<kMaxRadioFaults> & radioFaults)
 {
 #if CHIP_CONFIG_TEST
     ReturnErrorOnFailure(radioFaults.add(EMBER_ZCL_RADIO_FAULT_THREAD_FAULT));
     ReturnErrorOnFailure(radioFaults.add(EMBER_ZCL_RADIO_FAULT_BLE_FAULT));
 #endif

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetActiveNetworkFaults(GeneralFaults<kMaxNetworkFaults> & networkFaults)
 {
 #if CHIP_CONFIG_TEST
     ReturnErrorOnFailure(networkFaults.add(EMBER_ZCL_NETWORK_FAULT_TYPE_HARDWARE_FAILURE));
     ReturnErrorOnFailure(networkFaults.add(EMBER_ZCL_NETWORK_FAULT_TYPE_NETWORK_JAMMED));
     ReturnErrorOnFailure(networkFaults.add(EMBER_ZCL_NETWORK_FAULT_TYPE_CONNECTION_FAILED));
 #endif

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DiagnosticDataProviderImpl::GetNetworkInterfaces(NetworkInterface ** netifpp)
 {
     NetworkInterface * ifp = new NetworkInterface();

 #if CHIP_DEVICE_CONFIG_ENABLE_THREAD

     const char * threadNetworkName = otThreadGetNetworkName(ThreadStackMgrImpl().OTInstance());
     ifp->name                      = Span<const char>(threadNetworkName, strlen(threadNetworkName));
     ifp->isOperational             = true;
     ifp->offPremiseServicesReachableIPv4.SetNull();
     ifp->offPremiseServicesReachableIPv6.SetNull();
     ifp->type = InterfaceType::EMBER_ZCL_INTERFACE_TYPE_THREAD;
     uint8_t macBuffer[ConfigurationManager::kPrimaryMACAddressLength];
     ConfigurationMgr().GetPrimary802154MACAddress(macBuffer);
     ifp->hardwareAddress = ByteSpan(macBuffer, ConfigurationManager::kPrimaryMACAddressLength);

 #else
     /* TODO */
 #endif

     *netifpp = ifp;
     return CHIP_NO_ERROR;
 }

 void DiagnosticDataProviderImpl::ReleaseNetworkInterfaces(NetworkInterface * netifp)
 {
     while (netifp)
     {
         NetworkInterface * del = netifp;
         netifp                 = netifp->Next;
         delete del;
     }
 }

 DiagnosticDataProvider & GetDiagnosticDataProviderImpl()
 {
     return DiagnosticDataProviderImpl::GetDefaultInstance();
 }

 } // namespace DeviceLayer
 } // namespace chip
	/*
	* Copyright (c) 2022 Project CHIP Authors
	* 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 <platform/ConnectivityManager.h>
	#include <platform/internal/CHIPDeviceLayerInternal.h>

	#include <platform/DiagnosticDataProvider.h>
	#include <platform/bouffalolab/BL702/DiagnosticDataProviderImpl.h>

	#include <lwip/tcpip.h>

	#include "AppConfig.h"
	#include "FreeRTOS.h"

	using namespace ::chip::app::Clusters::GeneralDiagnostics;

	namespace chip {
	namespace DeviceLayer {

	extern "C" size_t get_heap_size(void);
	extern "C" size_t get_heap3_size(void);

	DiagnosticDataProviderImpl & DiagnosticDataProviderImpl::GetDefaultInstance()
	{
	static DiagnosticDataProviderImpl sInstance;
	return sInstance;
	}

	/*
	* The following Heap stats are compiled values done by the FreeRTOS Heap5 implementation.
	* It keeps track of the number of calls to allocate and free memory as well as the
	* number of free bytes remaining, but says nothing about fragmentation.
	*/
	CHIP_ERROR DiagnosticDataProviderImpl::GetCurrentHeapFree(uint64_t & currentHeapFree)
	{
	/ for BL706 with PSRAM, just get SRAM heap size which is more critical for firmware execution /

	#ifdef CFG_USE_PSRAM
	size_t freeHeapSize = xPortGetFreeHeapSize() + xPortGetFreeHeapSizePsram();
	#else
	size_t freeHeapSize = xPortGetFreeHeapSize();
	#endif
	currentHeapFree = static_cast<uint64_t>(freeHeapSize);
	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetCurrentHeapUsed(uint64_t & currentHeapUsed)
	{
	// Calculate the Heap used based on Total heap - Free heap

	#ifdef CFG_USE_PSRAM
	int64_t heapUsed = (get_heap_size() + get_heap3_size() - xPortGetFreeHeapSize() - xPortGetFreeHeapSizePsram());
	#else
	size_t freeHeapSize = xPortGetFreeHeapSize();
	#endif

	// Something went wrong, this should not happen
	VerifyOrReturnError(heapUsed >= 0, CHIP_ERROR_INVALID_INTEGER_VALUE);
	currentHeapUsed = static_cast<uint64_t>(heapUsed);
	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetCurrentHeapHighWatermark(uint64_t & currentHeapHighWatermark)
	{
	// FreeRTOS records the lowest amount of available heap during runtime
	// currentHeapHighWatermark wants the highest heap usage point so we calculate it here

	#ifdef CFG_USE_PSRAM
	int64_t HighestHeapUsageRecorded =
	(get_heap_size() + get_heap3_size() - xPortGetMinimumEverFreeHeapSize() - xPortGetMinimumEverFreeHeapSizePsram());
	#else
	size_t freeHeapSize = xPortGetFreeHeapSize();
	int64_t HighestHeapUsageRecorded = (get_heap_size() - xPortGetMinimumEverFreeHeapSize());
	#endif

	// Something went wrong, this should not happen
	VerifyOrReturnError(HighestHeapUsageRecorded >= 0, CHIP_ERROR_INVALID_INTEGER_VALUE);
	currentHeapHighWatermark = static_cast<uint64_t>(HighestHeapUsageRecorded);

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetThreadMetrics(ThreadMetrics ** threadMetricsOut)
	{
	/* Obtain all available task information */
	TaskStatus_t * taskStatusArray;
	ThreadMetrics * head = nullptr;
	uint32_t arraySize, x, dummy;

	arraySize = uxTaskGetNumberOfTasks();

	taskStatusArray = static_cast<TaskStatus_t *>(chip::Platform::MemoryCalloc(arraySize, sizeof(TaskStatus_t)));

	if (taskStatusArray != NULL)
	{
	/* Generate raw status information about each task. */
	arraySize = uxTaskGetSystemState(taskStatusArray, arraySize, &dummy);
	/* For each populated position in the taskStatusArray array,
	format the raw data as human readable ASCII data. */

	for (x = 0; x < arraySize; x++)
	{
	ThreadMetrics * thread = new ThreadMetrics();
	if (thread)
	{
	Platform::CopyString(thread->NameBuf, taskStatusArray[x].pcTaskName);
	thread->name.Emplace(CharSpan::fromCharString(thread->NameBuf));
	thread->id = taskStatusArray[x].xTaskNumber;
	thread->stackFreeMinimum.Emplace(taskStatusArray[x].usStackHighWaterMark);

	/* Unsupported metrics */
	// thread->stackSize
	// thread->stackFreeCurrent

	thread->Next = head;
	head = thread;
	}
	}

	*threadMetricsOut = head;
	/* The array is no longer needed, free the memory it consumes. */
	chip::Platform::MemoryFree(taskStatusArray);
	}

	return CHIP_NO_ERROR;
	}

	void DiagnosticDataProviderImpl::ReleaseThreadMetrics(ThreadMetrics * threadMetrics)
	{
	while (threadMetrics)
	{
	ThreadMetrics * del = threadMetrics;
	threadMetrics = threadMetrics->Next;
	delete del;
	}
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetRebootCount(uint16_t & rebootCount)
	{
	uint32_t count = 0;
	CHIP_ERROR err = ConfigurationMgr().GetRebootCount(count);

	if (err == CHIP_NO_ERROR)
	{
	VerifyOrReturnError(count <= UINT16_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE);
	rebootCount = static_cast<uint16_t>(count);
	}

	return err;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetBootReason(BootReasonType & bootReason)
	{
	uint32_t reason = 0;
	CHIP_ERROR err = ConfigurationMgr().GetBootReason(reason);

	if (err == CHIP_NO_ERROR)
	{
	VerifyOrReturnError(reason <= UINT8_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE);
	bootReason = static_cast<BootReasonType>(reason);
	}

	return err;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetUpTime(uint64_t & upTime)
	{
	System::Clock::Timestamp currentTime = System::SystemClock().GetMonotonicTimestamp();
	System::Clock::Timestamp startTime = PlatformMgrImpl().GetStartTime();

	if (currentTime >= startTime)
	{
	upTime = std::chrono::duration_cast<System::Clock::Seconds64>(currentTime - startTime).count();
	return CHIP_NO_ERROR;
	}

	return CHIP_ERROR_INVALID_TIME;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetTotalOperationalHours(uint32_t & totalOperationalHours)
	{
	uint64_t upTime = 0;

	if (GetUpTime(upTime) == CHIP_NO_ERROR)
	{
	uint32_t totalHours = 0;
	if (ConfigurationMgr().GetTotalOperationalHours(totalHours) == CHIP_NO_ERROR)
	{
	VerifyOrReturnError(upTime / 3600 <= UINT32_MAX, CHIP_ERROR_INVALID_INTEGER_VALUE);
	totalOperationalHours = totalHours + static_cast<uint32_t>(upTime / 3600);
	return CHIP_NO_ERROR;
	}
	}

	return CHIP_ERROR_INVALID_TIME;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetActiveHardwareFaults(GeneralFaults<kMaxHardwareFaults> & hardwareFaults)
	{
	#if CHIP_CONFIG_TEST
	ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_RADIO));
	ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_SENSOR));
	ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_POWER_SOURCE));
	ReturnErrorOnFailure(hardwareFaults.add(EMBER_ZCL_HARDWARE_FAULT_USER_INTERFACE_FAULT));
	#endif

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetActiveRadioFaults(GeneralFaults<kMaxRadioFaults> & radioFaults)
	{
	#if CHIP_CONFIG_TEST
	ReturnErrorOnFailure(radioFaults.add(EMBER_ZCL_RADIO_FAULT_THREAD_FAULT));
	ReturnErrorOnFailure(radioFaults.add(EMBER_ZCL_RADIO_FAULT_BLE_FAULT));
	#endif

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetActiveNetworkFaults(GeneralFaults<kMaxNetworkFaults> & networkFaults)
	{
	#if CHIP_CONFIG_TEST
	ReturnErrorOnFailure(networkFaults.add(EMBER_ZCL_NETWORK_FAULT_TYPE_HARDWARE_FAILURE));
	ReturnErrorOnFailure(networkFaults.add(EMBER_ZCL_NETWORK_FAULT_TYPE_NETWORK_JAMMED));
	ReturnErrorOnFailure(networkFaults.add(EMBER_ZCL_NETWORK_FAULT_TYPE_CONNECTION_FAILED));
	#endif

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DiagnosticDataProviderImpl::GetNetworkInterfaces(NetworkInterface ** netifpp)
	{
	NetworkInterface * ifp = new NetworkInterface();

	#if CHIP_DEVICE_CONFIG_ENABLE_THREAD

	const char * threadNetworkName = otThreadGetNetworkName(ThreadStackMgrImpl().OTInstance());
	ifp->name = Span<const char>(threadNetworkName, strlen(threadNetworkName));
	ifp->isOperational = true;
	ifp->offPremiseServicesReachableIPv4.SetNull();
	ifp->offPremiseServicesReachableIPv6.SetNull();
	ifp->type = InterfaceType::EMBER_ZCL_INTERFACE_TYPE_THREAD;
	uint8_t macBuffer[ConfigurationManager::kPrimaryMACAddressLength];
	ConfigurationMgr().GetPrimary802154MACAddress(macBuffer);
	ifp->hardwareAddress = ByteSpan(macBuffer, ConfigurationManager::kPrimaryMACAddressLength);

	#else
	/* TODO */
	#endif

	*netifpp = ifp;
	return CHIP_NO_ERROR;
	}

	void DiagnosticDataProviderImpl::ReleaseNetworkInterfaces(NetworkInterface * netifp)
	{
	while (netifp)
	{
	NetworkInterface * del = netifp;
	netifp = netifp->Next;
	delete del;
	}
	}

	DiagnosticDataProvider & GetDiagnosticDataProviderImpl()
	{
	return DiagnosticDataProviderImpl::GetDefaultInstance();
	}

	} // namespace DeviceLayer
	} // namespace chip