examples/all-clusters-app/esp32/main/DeviceCallbacks.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2020 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.
  */

 /**
  * @file DeviceCallbacks.cpp
  *
  * Implements all the callbacks to the application from the CHIP Stack
  *
  **/
 #include "DeviceCallbacks.h"

 #include "Globals.h"
 #include "LEDWidget.h"
 #include "WiFiWidget.h"
 #include <app-common/zap-generated/attribute-id.h>
 #include <app-common/zap-generated/attribute-type.h>
 #include <app/CommandHandler.h>
 #include <app/clusters/identify-server/identify-server.h>
 #include <app/util/basic-types.h>
 #include <app/util/util.h>
 #include <common/CHIPDeviceManager.h>
 #include <lib/dnssd/Advertiser.h>

 #if CONFIG_DEVICE_TYPE_ESP32_C3_DEVKITM
 #include <app-common/zap-generated/cluster-id.h>
 #endif

 static const char * TAG = "app-devicecallbacks";

 using namespace ::chip;
 using namespace ::chip::Inet;
 using namespace ::chip::System;
 using namespace chip::app;

 constexpr uint32_t kIdentifyTimerDelayMS = 250;

 void OnIdentifyTriggerEffect(Identify * identify)
 {
     switch (identify->mCurrentEffectIdentifier)
     {
     case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BLINK:
         statusLED1.Blink(kIdentifyTimerDelayMS * 2);
         ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BLINK");
         break;
     case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BREATHE:
         ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BREATHE");
         break;
     case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_OKAY:
         ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_OKAY");
         break;
     case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_CHANNEL_CHANGE:
         ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_CHANNEL_CHANGE");
         break;
     default:
         ChipLogProgress(Zcl, "No identifier effect");
         break;
     }
     return;
 }

 Identify gIdentify0 = {
     chip::EndpointId{ 0 },
     [](Identify *) { ChipLogProgress(Zcl, "onIdentifyStart"); },
     [](Identify *) { ChipLogProgress(Zcl, "onIdentifyStop"); },
     EMBER_ZCL_IDENTIFY_IDENTIFY_TYPE_VISIBLE_LED,
     OnIdentifyTriggerEffect,
 };

 Identify gIdentify1 = {
     chip::EndpointId{ 1 },
     [](Identify *) { ChipLogProgress(Zcl, "onIdentifyStart"); },
     [](Identify *) { ChipLogProgress(Zcl, "onIdentifyStop"); },
     EMBER_ZCL_IDENTIFY_IDENTIFY_TYPE_VISIBLE_LED,
     OnIdentifyTriggerEffect,
 };

 void AppDeviceCallbacks::PostAttributeChangeCallback(EndpointId endpointId, ClusterId clusterId, AttributeId attributeId,
                                                      uint8_t type, uint16_t size, uint8_t * value)
 {
     ESP_LOGI(TAG,
              "PostAttributeChangeCallback - Cluster ID: '0x%04x', EndPoint ID: "
              "'0x%02x', Attribute ID: '0x%04x'",
              clusterId, endpointId, attributeId);

     switch (clusterId)
     {
     case Clusters::OnOff::Id:
         OnOnOffPostAttributeChangeCallback(endpointId, attributeId, value);
         break;

     case Clusters::LevelControl::Id:
         OnLevelControlAttributeChangeCallback(endpointId, attributeId, value);
         break;
 #if CONFIG_DEVICE_TYPE_ESP32_C3_DEVKITM
     case Clusters::ColorControl::Id:
         OnColorControlAttributeChangeCallback(endpointId, attributeId, value);
         break;
 #endif
     case Clusters::Identify::Id:
         OnIdentifyPostAttributeChangeCallback(endpointId, attributeId, size, value);
         break;
     default:
         ESP_LOGI(TAG, "Unhandled cluster ID: %d", clusterId);
         break;
     }

     ESP_LOGI(TAG, "Current free heap: %u\n", static_cast<unsigned int>(heap_caps_get_free_size(MALLOC_CAP_8BIT)));
 }

 void AppDeviceCallbacks::OnOnOffPostAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint8_t * value)
 {
     VerifyOrExit(attributeId == ZCL_ON_OFF_ATTRIBUTE_ID, ESP_LOGI(TAG, "Unhandled Attribute ID: '0x%04x", attributeId));
     VerifyOrExit(endpointId == 1 || endpointId == 2, ESP_LOGE(TAG, "Unexpected EndPoint ID: `0x%02x'", endpointId));

     // At this point we can assume that value points to a bool value.
     mEndpointOnOffState[endpointId - 1] = *value;
     endpointId == 1 ? statusLED1.Set(*value) : statusLED2.Set(*value);

 exit:
     return;
 }

 void AppDeviceCallbacks::OnLevelControlAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint8_t * value)
 {
     bool onOffState    = mEndpointOnOffState[endpointId - 1];
     uint8_t brightness = onOffState ? *value : 0;

     VerifyOrExit(attributeId == ZCL_CURRENT_LEVEL_ATTRIBUTE_ID, ESP_LOGI(TAG, "Unhandled Attribute ID: '0x%04x", attributeId));
     VerifyOrExit(endpointId == 1 || endpointId == 2, ESP_LOGE(TAG, "Unexpected EndPoint ID: `0x%02x'", endpointId));

     // At this point we can assume that value points to a bool value.
     endpointId == 1 ? statusLED1.SetBrightness(brightness) : statusLED2.SetBrightness(brightness);

 exit:
     return;
 }

 // Currently we only support ColorControl cluster for ESP32C3_DEVKITM which has
 // an on-board RGB-LED
 #if CONFIG_DEVICE_TYPE_ESP32_C3_DEVKITM
 void AppDeviceCallbacks::OnColorControlAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint8_t * value)
 {
     VerifyOrExit(attributeId == ZCL_COLOR_CONTROL_CURRENT_HUE_ATTRIBUTE_ID ||
                      attributeId == ZCL_COLOR_CONTROL_CURRENT_SATURATION_ATTRIBUTE_ID,
                  ESP_LOGI(TAG, "Unhandled AttributeId ID: '0x%04x", attributeId));
     VerifyOrExit(endpointId == 1 || endpointId == 2, ESP_LOGE(TAG, "Unexpected EndPoint ID: `0x%02x'", endpointId));
     if (endpointId == 1)
     {
         uint8_t hue, saturation;
         if (attributeId == ZCL_COLOR_CONTROL_CURRENT_HUE_ATTRIBUTE_ID)
         {
             hue = *value;
             emberAfReadServerAttribute(endpointId, ZCL_COLOR_CONTROL_CLUSTER_ID, ZCL_COLOR_CONTROL_CURRENT_SATURATION_ATTRIBUTE_ID,
                                        &saturation, sizeof(uint8_t));
         }
         else
         {
             saturation = *value;
             emberAfReadServerAttribute(endpointId, ZCL_COLOR_CONTROL_CLUSTER_ID, ZCL_COLOR_CONTROL_CURRENT_HUE_ATTRIBUTE_ID, &hue,
                                        sizeof(uint8_t));
         }
         statusLED1.SetColor(hue, saturation);
     }
 exit:
     return;
 }
 #endif

 void AppDeviceCallbacks::OnIdentifyPostAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint16_t size,
                                                                uint8_t * value)
 {
     if (attributeId == Clusters::Identify::Attributes::IdentifyTime::Id && size == 2)
     {
         uint16_t identifyTime;
         memcpy(&identifyTime, value, size);
         if (identifyTime)
         {
             // Currently we have no separate indicator LEDs on each endpoints.
             // We are using LED1 for endpoint 0,1 and LED2 for endpoint 2
             endpointId == 2 ? statusLED2.Blink(kIdentifyTimerDelayMS * 2) : statusLED1.Blink(kIdentifyTimerDelayMS * 2);
         }
         else
         {
             bool onOffState;
             endpointId == 0 ? onOffState = mEndpointOnOffState[0] : onOffState = mEndpointOnOffState[endpointId - 1];
             endpointId == 2 ? statusLED2.Set(onOffState) : statusLED1.Set(onOffState);
         }
     }
 }

 bool emberAfBasicClusterMfgSpecificPingCallback(chip::app::CommandHandler * commandObj)
 {
     emberAfSendDefaultResponse(emberAfCurrentCommand(), EMBER_ZCL_STATUS_SUCCESS);
     return true;
 }

 void AppDeviceCallbacksDelegate::OnIPv4ConnectivityEstablished()
 {
     wifiLED.Set(true);
 }
 void AppDeviceCallbacksDelegate::OnIPv4ConnectivityLost()
 {
     wifiLED.Set(false);
 }
	/*
	*
	* Copyright (c) 2020 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.
	*/

	/**
	* @file DeviceCallbacks.cpp
	*
	* Implements all the callbacks to the application from the CHIP Stack
	*
	**/
	#include "DeviceCallbacks.h"

	#include "Globals.h"
	#include "LEDWidget.h"
	#include "WiFiWidget.h"
	#include <app-common/zap-generated/attribute-id.h>
	#include <app-common/zap-generated/attribute-type.h>
	#include <app/CommandHandler.h>
	#include <app/clusters/identify-server/identify-server.h>
	#include <app/util/basic-types.h>
	#include <app/util/util.h>
	#include <common/CHIPDeviceManager.h>
	#include <lib/dnssd/Advertiser.h>

	#if CONFIG_DEVICE_TYPE_ESP32_C3_DEVKITM
	#include <app-common/zap-generated/cluster-id.h>
	#endif

	static const char * TAG = "app-devicecallbacks";

	using namespace ::chip;
	using namespace ::chip::Inet;
	using namespace ::chip::System;
	using namespace chip::app;

	constexpr uint32_t kIdentifyTimerDelayMS = 250;

	void OnIdentifyTriggerEffect(Identify * identify)
	{
	switch (identify->mCurrentEffectIdentifier)
	{
	case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BLINK:
	statusLED1.Blink(kIdentifyTimerDelayMS * 2);
	ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BLINK");
	break;
	case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BREATHE:
	ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_BREATHE");
	break;
	case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_OKAY:
	ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_OKAY");
	break;
	case EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_CHANNEL_CHANGE:
	ChipLogProgress(Zcl, "EMBER_ZCL_IDENTIFY_EFFECT_IDENTIFIER_CHANNEL_CHANGE");
	break;
	default:
	ChipLogProgress(Zcl, "No identifier effect");
	break;
	}
	return;
	}

	Identify gIdentify0 = {
	chip::EndpointId{ 0 },
	[](Identify *) { ChipLogProgress(Zcl, "onIdentifyStart"); },
	[](Identify *) { ChipLogProgress(Zcl, "onIdentifyStop"); },
	EMBER_ZCL_IDENTIFY_IDENTIFY_TYPE_VISIBLE_LED,
	OnIdentifyTriggerEffect,
	};

	Identify gIdentify1 = {
	chip::EndpointId{ 1 },
	[](Identify *) { ChipLogProgress(Zcl, "onIdentifyStart"); },
	[](Identify *) { ChipLogProgress(Zcl, "onIdentifyStop"); },
	EMBER_ZCL_IDENTIFY_IDENTIFY_TYPE_VISIBLE_LED,
	OnIdentifyTriggerEffect,
	};

	void AppDeviceCallbacks::PostAttributeChangeCallback(EndpointId endpointId, ClusterId clusterId, AttributeId attributeId,
	uint8_t type, uint16_t size, uint8_t * value)
	{
	ESP_LOGI(TAG,
	"PostAttributeChangeCallback - Cluster ID: '0x%04x', EndPoint ID: "
	"'0x%02x', Attribute ID: '0x%04x'",
	clusterId, endpointId, attributeId);

	switch (clusterId)
	{
	case Clusters::OnOff::Id:
	OnOnOffPostAttributeChangeCallback(endpointId, attributeId, value);
	break;

	case Clusters::LevelControl::Id:
	OnLevelControlAttributeChangeCallback(endpointId, attributeId, value);
	break;
	#if CONFIG_DEVICE_TYPE_ESP32_C3_DEVKITM
	case Clusters::ColorControl::Id:
	OnColorControlAttributeChangeCallback(endpointId, attributeId, value);
	break;
	#endif
	case Clusters::Identify::Id:
	OnIdentifyPostAttributeChangeCallback(endpointId, attributeId, size, value);
	break;
	default:
	ESP_LOGI(TAG, "Unhandled cluster ID: %d", clusterId);
	break;
	}

	ESP_LOGI(TAG, "Current free heap: %u\n", static_cast<unsigned int>(heap_caps_get_free_size(MALLOC_CAP_8BIT)));
	}

	void AppDeviceCallbacks::OnOnOffPostAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint8_t * value)
	{
	VerifyOrExit(attributeId == ZCL_ON_OFF_ATTRIBUTE_ID, ESP_LOGI(TAG, "Unhandled Attribute ID: '0x%04x", attributeId));
	VerifyOrExit(endpointId == 1 \|\| endpointId == 2, ESP_LOGE(TAG, "Unexpected EndPoint ID: `0x%02x'", endpointId));

	// At this point we can assume that value points to a bool value.
	mEndpointOnOffState[endpointId - 1] = *value;
	endpointId == 1 ? statusLED1.Set(value) : statusLED2.Set(value);

	exit:
	return;
	}

	void AppDeviceCallbacks::OnLevelControlAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint8_t * value)
	{
	bool onOffState = mEndpointOnOffState[endpointId - 1];
	uint8_t brightness = onOffState ? *value : 0;

	VerifyOrExit(attributeId == ZCL_CURRENT_LEVEL_ATTRIBUTE_ID, ESP_LOGI(TAG, "Unhandled Attribute ID: '0x%04x", attributeId));
	VerifyOrExit(endpointId == 1 \|\| endpointId == 2, ESP_LOGE(TAG, "Unexpected EndPoint ID: `0x%02x'", endpointId));

	// At this point we can assume that value points to a bool value.
	endpointId == 1 ? statusLED1.SetBrightness(brightness) : statusLED2.SetBrightness(brightness);

	exit:
	return;
	}

	// Currently we only support ColorControl cluster for ESP32C3_DEVKITM which has
	// an on-board RGB-LED
	#if CONFIG_DEVICE_TYPE_ESP32_C3_DEVKITM
	void AppDeviceCallbacks::OnColorControlAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint8_t * value)
	{
	VerifyOrExit(attributeId == ZCL_COLOR_CONTROL_CURRENT_HUE_ATTRIBUTE_ID \|\|
	attributeId == ZCL_COLOR_CONTROL_CURRENT_SATURATION_ATTRIBUTE_ID,
	ESP_LOGI(TAG, "Unhandled AttributeId ID: '0x%04x", attributeId));
	VerifyOrExit(endpointId == 1 \|\| endpointId == 2, ESP_LOGE(TAG, "Unexpected EndPoint ID: `0x%02x'", endpointId));
	if (endpointId == 1)
	{
	uint8_t hue, saturation;
	if (attributeId == ZCL_COLOR_CONTROL_CURRENT_HUE_ATTRIBUTE_ID)
	{
	hue = *value;
	emberAfReadServerAttribute(endpointId, ZCL_COLOR_CONTROL_CLUSTER_ID, ZCL_COLOR_CONTROL_CURRENT_SATURATION_ATTRIBUTE_ID,
	&saturation, sizeof(uint8_t));
	}
	else
	{
	saturation = *value;
	emberAfReadServerAttribute(endpointId, ZCL_COLOR_CONTROL_CLUSTER_ID, ZCL_COLOR_CONTROL_CURRENT_HUE_ATTRIBUTE_ID, &hue,
	sizeof(uint8_t));
	}
	statusLED1.SetColor(hue, saturation);
	}
	exit:
	return;
	}
	#endif

	void AppDeviceCallbacks::OnIdentifyPostAttributeChangeCallback(EndpointId endpointId, AttributeId attributeId, uint16_t size,
	uint8_t * value)
	{
	if (attributeId == Clusters::Identify::Attributes::IdentifyTime::Id && size == 2)
	{
	uint16_t identifyTime;
	memcpy(&identifyTime, value, size);
	if (identifyTime)
	{
	// Currently we have no separate indicator LEDs on each endpoints.
	// We are using LED1 for endpoint 0,1 and LED2 for endpoint 2
	endpointId == 2 ? statusLED2.Blink(kIdentifyTimerDelayMS * 2) : statusLED1.Blink(kIdentifyTimerDelayMS * 2);
	}
	else
	{
	bool onOffState;
	endpointId == 0 ? onOffState = mEndpointOnOffState[0] : onOffState = mEndpointOnOffState[endpointId - 1];
	endpointId == 2 ? statusLED2.Set(onOffState) : statusLED1.Set(onOffState);
	}
	}
	}

	bool emberAfBasicClusterMfgSpecificPingCallback(chip::app::CommandHandler * commandObj)
	{
	emberAfSendDefaultResponse(emberAfCurrentCommand(), EMBER_ZCL_STATUS_SUCCESS);
	return true;
	}

	void AppDeviceCallbacksDelegate::OnIPv4ConnectivityEstablished()
	{
	wifiLED.Set(true);
	}
	void AppDeviceCallbacksDelegate::OnIPv4ConnectivityLost()
	{
	wifiLED.Set(false);
	}