src/app/util/util.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /**
  *
  *    Copyright (c) 2020-2021 Project CHIP Authors
  *
  *    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 "app/util/common.h"
 #include <app-common/zap-generated/attribute-id.h>
 #include <app-common/zap-generated/attribute-type.h>
 #include <app-common/zap-generated/callback.h>
 #include <app-common/zap-generated/cluster-id.h>
 #include <app-common/zap-generated/command-id.h>
 #include <app-common/zap-generated/print-cluster.h>
 #include <app/util/af-event.h>
 #include <app/util/af.h>
 #include <app/util/ember-compatibility-functions.h>

 // TODO: figure out a clear path for compile-time codegen
 #include <app/PluginApplicationCallbacks.h>

 #ifdef EMBER_AF_PLUGIN_GROUPS_SERVER
 #include <app/clusters/groups-server/groups-server.h>
 #endif // EMBER_AF_PLUGIN_GROUPS_SERVER

 using namespace chip;

 //------------------------------------------------------------------------------
 // Forward Declarations

 //------------------------------------------------------------------------------
 // Globals

 // Storage and functions for turning on and off devices
 bool afDeviceEnabled[MAX_ENDPOINT_COUNT];

 #ifdef EMBER_AF_ENABLE_STATISTICS
 // a variable containing the number of messages send from the utilities
 // since emberAfInit was called.
 uint32_t afNumPktsSent;
 #endif

 const EmberAfClusterName zclClusterNames[] = {
     CLUSTER_IDS_TO_NAMES              // defined in print-cluster.h
     { ZCL_NULL_CLUSTER_ID, nullptr }, // terminator
 };

 // A pointer to the current command being processed
 // This struct is allocated inside ember-compatibility-functions.cpp.
 // The pointer below is set to NULL when not processing a command.
 EmberAfClusterCommand * emAfCurrentCommand;

 // A pointer to the global exchange manager
 chip::Messaging::ExchangeManager * emAfExchangeMgr = nullptr;

 // DEPRECATED.
 uint8_t emberAfIncomingZclSequenceNumber = 0xFF;

 // Sequence used for outgoing messages if they are
 // not responses.
 uint8_t emberAfSequenceNumber = 0xFF;

 static uint8_t /*enum EmberAfRetryOverride*/ emberAfApsRetryOverride                      = EMBER_AF_RETRY_OVERRIDE_NONE;
 static uint8_t /*enum EmberAfDisableDefaultResponse*/ emAfDisableDefaultResponse          = EMBER_AF_DISABLE_DEFAULT_RESPONSE_NONE;
 static uint8_t /*enum EmberAfDisableDefaultResponse*/ emAfSavedDisableDefaultResponseVale = EMBER_AF_DISABLE_DEFAULT_RESPONSE_NONE;

 // Holds the response type
 uint8_t emberAfResponseType = ZCL_UTIL_RESP_NORMAL;

 #ifdef EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_DECLARATIONS
 EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_DECLARATIONS
 #endif

 //------------------------------------------------------------------------------

 // Device enabled/disabled functions

 void emberAfSetDeviceEnabled(EndpointId endpoint, bool enabled)
 {
     uint16_t index = emberAfIndexFromEndpoint(endpoint);
     if (index != 0xFFFF && index < sizeof(afDeviceEnabled))
     {
         afDeviceEnabled[index] = enabled;
     }
 #ifdef ZCL_USING_BASIC_CLUSTER_DEVICE_ENABLED_ATTRIBUTE
     emberAfWriteServerAttribute(endpoint, ZCL_BASIC_CLUSTER_ID, ZCL_DEVICE_ENABLED_ATTRIBUTE_ID, (uint8_t *) &enabled,
                                 ZCL_BOOLEAN_ATTRIBUTE_TYPE);
 #endif
 }

 // Is the device identifying?
 bool emberAfIsDeviceIdentifying(EndpointId endpoint)
 {
 #ifdef ZCL_USING_IDENTIFY_CLUSTER_SERVER
     uint16_t identifyTime;
     EmberAfStatus status = emberAfReadServerAttribute(endpoint, ZCL_IDENTIFY_CLUSTER_ID, ZCL_IDENTIFY_TIME_ATTRIBUTE_ID,
                                                       (uint8_t *) &identifyTime, sizeof(identifyTime));
     return (status == EMBER_ZCL_STATUS_SUCCESS && 0 < identifyTime);
 #else
     return false;
 #endif
 }

 // Calculates difference. See EmberAfDifferenceType for the maximum data size
 // that this function will support.
 EmberAfDifferenceType emberAfGetDifference(uint8_t * pData, EmberAfDifferenceType value, uint8_t dataSize)
 {
     EmberAfDifferenceType value2 = 0, diff;
     uint8_t i;

     // only support data types up to 8 bytes
     if (dataSize > sizeof(EmberAfDifferenceType))
     {
         return 0;
     }

     // get the value
     for (i = 0; i < dataSize; i++)
     {
         value2 = value2 << 8;
 #if (BIGENDIAN_CPU)
         value2 += pData[i];
 #else  // BIGENDIAN
         value2 += pData[dataSize - i - 1];
 #endif // BIGENDIAN
     }

     if (value > value2)
     {
         diff = value - value2;
     }
     else
     {
         diff = value2 - value;
     }

     return diff;
 }

 // ****************************************
 // Initialize Clusters
 // ****************************************
 void emberAfInit(chip::Messaging::ExchangeManager * exchangeMgr)
 {
     uint8_t i;
 #ifdef EMBER_AF_ENABLE_STATISTICS
     afNumPktsSent = 0;
 #endif

     emAfExchangeMgr = exchangeMgr;

     for (i = 0; i < EMBER_SUPPORTED_NETWORKS; i++)
     {
         // FIXME: Do we need to support more than one network?
         // emberAfPushNetworkIndex(i);
         emberAfInitializeAttributes(EMBER_BROADCAST_ENDPOINT);
         // emberAfPopNetworkIndex();
     }

     memset(afDeviceEnabled, true, emberAfEndpointCount());

     MATTER_PLUGINS_INIT

     emAfCallInits();
 }

 void emberAfTick(void)
 {
     // Call the AFV2-specific per-endpoint callbacks
     // Anything that defines callbacks as void *TickCallback(void) is called in
     // emAfInit(), which is a generated file
 #ifdef EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_CALLS
     EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_CALLS
 #endif
 }

 // Cluster init functions that don't have a cluster implementation to define
 // them in.
 void MatterBooleanStatePluginServerInitCallback() {}
 void MatterBridgedDeviceBasicPluginServerInitCallback() {}
 void MatterElectricalMeasurementPluginServerInitCallback() {}
 void MatterRelativeHumidityMeasurementPluginServerInitCallback() {}
 void MatterIlluminanceMeasurementPluginServerInitCallback() {}
 void MatterBinaryInputBasicPluginServerInitCallback() {}
 void MatterPressureMeasurementPluginServerInitCallback() {}
 void MatterTemperatureMeasurementPluginServerInitCallback() {}
 void MatterFlowMeasurementPluginServerInitCallback() {}
 void MatterOnOffSwitchConfigurationPluginServerInitCallback() {}
 void MatterThermostatUserInterfaceConfigurationPluginServerInitCallback() {}
 void MatterBridgedDeviceBasicInformationPluginServerInitCallback() {}
 void MatterPowerConfigurationPluginServerInitCallback() {}
 void MatterPowerProfilePluginServerInitCallback() {}
 void MatterPulseWidthModulationPluginServerInitCallback() {}
 void MatterAlarmsPluginServerInitCallback() {}
 void MatterTimePluginServerInitCallback() {}
 void MatterAclPluginServerInitCallback() {}
 void MatterPollControlPluginServerInitCallback() {}
 void MatterUnitLocalizationPluginServerInitCallback() {}
 void MatterTimeSynchronizationPluginServerInitCallback() {}
 void MatterProxyValidPluginServerInitCallback() {}
 void MatterProxyDiscoveryPluginServerInitCallback() {}
 void MatterProxyConfigurationPluginServerInitCallback() {}
 void MatterFanControlPluginServerInitCallback() {}

 // ****************************************
 // This function is called by the application when the stack goes down,
 // such as after a leave network. This allows zcl utils to clear state
 // that should not be kept when changing networks
 // ****************************************
 void emberAfStackDown(void)
 {
     emberAfRegistrationAbortCallback();
 }

 // ****************************************
 // Print out information about each cluster
 // ****************************************

 uint16_t emberAfFindClusterNameIndex(ClusterId cluster)
 {
     static_assert(sizeof(ClusterId) == 4, "May need to adjust our index type or somehow define it in terms of cluster id type");
     uint16_t index = 0;
     while (zclClusterNames[index].id != ZCL_NULL_CLUSTER_ID)
     {
         if (zclClusterNames[index].id == cluster)
         {
             return index;
         }
         index++;
     }
     return 0xFFFF;
 }

 // This function parses into the cluster name table, and tries to find
 // the index in the table that has the right cluster id.
 void emberAfDecodeAndPrintCluster(ClusterId cluster)
 {
     uint16_t index = emberAfFindClusterNameIndex(cluster);
     if (index == 0xFFFF)
     {
         static_assert(sizeof(ClusterId) == 4, "Adjust the print formatting");
         emberAfPrint(emberAfPrintActiveArea, "(Unknown clus. [" ChipLogFormatMEI "])", ChipLogValueMEI(cluster));
     }
     else
     {
         emberAfPrint(emberAfPrintActiveArea, "(%p)", zclClusterNames[index].name);
     }
 }

 // This function makes the assumption that
 // emberAfCurrentCommand will either be NULL
 // when invalid, or will have a valid mfgCode
 // when called.
 // If it is invalid, we just return the
 // EMBER_AF_NULL_MANUFACTURER_CODE, which we tend to use
 // for references to the standard library.
 uint16_t emberAfGetMfgCodeFromCurrentCommand(void)
 {
     if (emberAfCurrentCommand() != nullptr)
     {
         return emberAfCurrentCommand()->mfgCode;
     }

     return EMBER_AF_NULL_MANUFACTURER_CODE;
 }

 // the caller to the library can set a flag to say do not respond to the
 // next ZCL message passed in to the library. Passing true means disable
 // the reply for the next ZCL message. Setting to false re-enables the
 // reply (in the case where the app disables it and then doesnt send a
 // message that gets parsed).
 void emberAfSetNoReplyForNextMessage(bool set)
 {
     if (set)
     {
         emberAfResponseType |= ZCL_UTIL_RESP_NONE;
     }
     else
     {
         emberAfResponseType = static_cast<uint8_t>(emberAfResponseType & ~ZCL_UTIL_RESP_NONE);
     }
 }

 void emberAfSetRetryOverride(EmberAfRetryOverride value)
 {
     emberAfApsRetryOverride = value;
 }

 EmberAfRetryOverride emberAfGetRetryOverride(void)
 {
     return (EmberAfRetryOverride) emberAfApsRetryOverride;
 }

 void emAfApplyRetryOverride(EmberApsOption * options)
 {
     if (options == nullptr)
     {
         return;
     }
     if (emberAfApsRetryOverride == EMBER_AF_RETRY_OVERRIDE_SET)
     {
         *options |= EMBER_APS_OPTION_RETRY;
     }
     else if (emberAfApsRetryOverride == EMBER_AF_RETRY_OVERRIDE_UNSET)
     {
         *options = static_cast<EmberApsOption>(*options & ~EMBER_APS_OPTION_RETRY);
     }
     else
     {
         // MISRA requires ..else if.. to have terminating else.
     }
 }

 void emberAfSetDisableDefaultResponse(EmberAfDisableDefaultResponse value)
 {
     emAfDisableDefaultResponse = value;
     if (value != EMBER_AF_DISABLE_DEFAULT_RESPONSE_ONE_SHOT)
     {
         emAfSavedDisableDefaultResponseVale = value;
     }
 }

 EmberAfDisableDefaultResponse emberAfGetDisableDefaultResponse(void)
 {
     return (EmberAfDisableDefaultResponse) emAfDisableDefaultResponse;
 }

 void emAfApplyDisableDefaultResponse(uint8_t * frame_control)
 {
     if (frame_control == nullptr)
     {
         return;
     }
     if (emAfDisableDefaultResponse == EMBER_AF_DISABLE_DEFAULT_RESPONSE_ONE_SHOT)
     {
         emAfDisableDefaultResponse = emAfSavedDisableDefaultResponseVale;
         *frame_control |= ZCL_DISABLE_DEFAULT_RESPONSE_MASK;
     }
     else if (emAfDisableDefaultResponse == EMBER_AF_DISABLE_DEFAULT_RESPONSE_PERMANENT)
     {
         *frame_control |= ZCL_DISABLE_DEFAULT_RESPONSE_MASK;
     }
     else
     {
         // MISRA requires ..else if.. to have terminating else.
     }
 }

 EmberStatus emberAfSendImmediateDefaultResponse(EmberAfStatus status)
 {
     return emberAfSendDefaultResponse(emberAfCurrentCommand(), status);
 }

 EmberStatus emberAfSendDefaultResponse(const EmberAfClusterCommand * cmd, EmberAfStatus status)
 {
     // Default Response commands are only sent in response to unicast commands.
     if (cmd->type != EMBER_INCOMING_UNICAST && cmd->type != EMBER_INCOMING_UNICAST_REPLY)
     {
         return EMBER_SUCCESS;
     }

     if (!chip::app::Compatibility::IMEmberAfSendDefaultResponseWithCallback(status))
     {
         // Caller is not responding to anything!
         return EMBER_ERR_FATAL;
     }

     return EMBER_SUCCESS;
 }

 void emberAfCopyInt16u(uint8_t * data, uint16_t index, uint16_t x)
 {
     data[index]     = (uint8_t)(((x)) & 0xFF);
     data[index + 1] = (uint8_t)(((x) >> 8) & 0xFF);
 }

 void emberAfCopyInt24u(uint8_t * data, uint16_t index, uint32_t x)
 {
     data[index]     = (uint8_t)(((x)) & 0xFF);
     data[index + 1] = (uint8_t)(((x) >> 8) & 0xFF);
     data[index + 2] = (uint8_t)(((x) >> 16) & 0xFF);
 }

 void emberAfCopyInt32u(uint8_t * data, uint16_t index, uint32_t x)
 {
     data[index]     = (uint8_t)(((x)) & 0xFF);
     data[index + 1] = (uint8_t)(((x) >> 8) & 0xFF);
     data[index + 2] = (uint8_t)(((x) >> 16) & 0xFF);
     data[index + 3] = (uint8_t)(((x) >> 24) & 0xFF);
 }

 void emberAfCopyString(uint8_t * dest, const uint8_t * src, size_t size)
 {
     if (src == nullptr)
     {
         dest[0] = 0; // Zero out the length of string
     }
     else if (src[0] == 0xFF)
     {
         dest[0] = src[0];
     }
     else
     {
         uint8_t length = emberAfStringLength(src);
         if (size < length)
         {
             // Since we have checked that size < length, size must be able to fit into the type of length.
             length = static_cast<decltype(length)>(size);
         }
         memmove(dest + 1, src + 1, length);
         dest[0] = length;
     }
 }

 void emberAfCopyLongString(uint8_t * dest, const uint8_t * src, size_t size)
 {
     if (src == nullptr)
     {
         dest[0] = dest[1] = 0; // Zero out the length of string
     }
     else if ((src[0] == 0xFF) && (src[1] == 0xFF))
     {
         dest[0] = 0xFF;
         dest[1] = 0xFF;
     }
     else
     {
         uint16_t length = emberAfLongStringLength(src);
         if (size < length)
         {
             // Since we have checked that size < length, size must be able to fit into the type of length.
             length = static_cast<decltype(length)>(size);
         }
         memmove(dest + 2, src + 2, length);
         dest[0] = EMBER_LOW_BYTE(length);
         dest[1] = EMBER_HIGH_BYTE(length);
     }
 }

 #if (BIGENDIAN_CPU)
 #define EM_BIG_ENDIAN true
 #else
 #define EM_BIG_ENDIAN false
 #endif

 // You can pass in val1 as NULL, which will assume that it is
 // pointing to an array of all zeroes. This is used so that
 // default value of NULL is treated as all zeroes.
 int8_t emberAfCompareValues(const uint8_t * val1, const uint8_t * val2, uint16_t len, bool signedNumber)
 {
     if (len == 0)
     {
         // no length means nothing to compare.  Shouldn't even happen, since len is sizeof(some-integer-type).
         return 0;
     }

     if (signedNumber)
     { // signed number comparison
         if (len <= 4)
         { // only number with 32-bits or less is supported
             int32_t accum1 = 0x0;
             int32_t accum2 = 0x0;
             int32_t all1s  = -1;

             for (uint16_t i = 0; i < len; i++)
             {
                 uint8_t j = (val1 == nullptr ? 0 : (EM_BIG_ENDIAN ? val1[i] : val1[(len - 1) - i]));
                 accum1 |= j << (8 * (len - 1 - i));

                 uint8_t k = (EM_BIG_ENDIAN ? val2[i] : val2[(len - 1) - i]);
                 accum2 |= k << (8 * (len - 1 - i));
             }

             // sign extending, no need for 32-bits numbers
             if (len < 4)
             {
                 if ((accum1 & (1 << (8 * len - 1))) != 0)
                 { // check sign
                     accum1 |= all1s - ((1 << (len * 8)) - 1);
                 }
                 if ((accum2 & (1 << (8 * len - 1))) != 0)
                 { // check sign
                     accum2 |= all1s - ((1 << (len * 8)) - 1);
                 }
             }

             if (accum1 > accum2)
             {
                 return 1;
             }
             if (accum1 < accum2)
             {
                 return -1;
             }

             return 0;
         }

         // not supported
         return 0;
     }

     // regular unsigned number comparison
     for (uint16_t i = 0; i < len; i++)
     {
         uint8_t j = (val1 == nullptr ? 0 : (EM_BIG_ENDIAN ? val1[i] : val1[(len - 1) - i]));
         uint8_t k = (EM_BIG_ENDIAN ? val2[i] : val2[(len - 1) - i]);

         if (j > k)
         {
             return 1;
         }
         if (k > j)
         {
             return -1;
         }
     }
     return 0;
 }

 #if 0
 // Moving to time-util.c
 int8_t emberAfCompareDates(EmberAfDate* date1, EmberAfDate* date2)
 {
   uint32_t val1 = emberAfEncodeDate(date1);
   uint32_t val2 = emberAfEncodeDate(date2);
   return (val1 == val2) ? 0 : ((val1 < val2) ? -1 : 1);
 }
 #endif

 // Zigbee spec says types between signed 8 bit and signed 64 bit
 bool emberAfIsTypeSigned(EmberAfAttributeType dataType)
 {
     return (dataType >= ZCL_INT8S_ATTRIBUTE_TYPE && dataType <= ZCL_INT64S_ATTRIBUTE_TYPE);
 }

 uint8_t emberAfAppendCharacters(uint8_t * zclString, uint8_t zclStringMaxLen, const uint8_t * appendingChars,
                                 uint8_t appendingCharsLen)
 {
     uint8_t freeChars;
     uint8_t curLen;
     uint8_t charsToWrite;

     if ((zclString == nullptr) || (zclStringMaxLen == 0) || (appendingChars == nullptr) || (appendingCharsLen == 0))
     {
         return 0;
     }

     curLen = emberAfStringLength(zclString);

     if ((zclString[0] == 0xFF) || (curLen >= zclStringMaxLen))
     {
         return 0;
     }

     freeChars    = static_cast<uint8_t>(zclStringMaxLen - curLen);
     charsToWrite = (freeChars > appendingCharsLen) ? appendingCharsLen : freeChars;

     memcpy(&zclString[1 + curLen], // 1 is to account for zcl's length byte
            appendingChars, charsToWrite);
     // Cast is safe, because the sum can't be bigger than zclStringMaxLen.
     zclString[0] = static_cast<uint8_t>(curLen + charsToWrite);
     return charsToWrite;
 }

 /*
    On each page, first channel maps to channel number zero and so on.
    Example:
    page    Band      Rage of 90 channels    Per page channel mapping
    28     863 MHz        0-26                    0-26
    29     863 MHz        27-34,62                0-8 (Here 7th channel maps to 34 and 8th to 62)
    30     863 MHz        35 - 61                 0-26
    31     915            0-26                    0-26

  */
 EmberStatus emAfValidateChannelPages(uint8_t page, uint8_t channel)
 {
     switch (page)
     {
     case 0:
         if (!((channel <= EMBER_MAX_802_15_4_CHANNEL_NUMBER) &&
               ((EMBER_MIN_802_15_4_CHANNEL_NUMBER == 0) || (channel >= EMBER_MIN_802_15_4_CHANNEL_NUMBER))))
         {
             return EMBER_PHY_INVALID_CHANNEL;
         }
         break;
     case 28:
     case 30:
     case 31:
         if (channel > EMBER_MAX_SUBGHZ_CHANNEL_NUMBER_ON_PAGES_28_30_31)
         {
             return EMBER_PHY_INVALID_CHANNEL;
         }
         break;
     case 29:
         if (channel > EMBER_MAX_SUBGHZ_CHANNEL_NUMBER_ON_PAGE_29)
         {
             return EMBER_PHY_INVALID_CHANNEL;
         }
         break;
     default:
         return EMBER_PHY_INVALID_CHANNEL;
         break;
     }
     return EMBER_SUCCESS;
 }

 void slabAssert(const char * file, int line)
 {
     (void) file; // Unused parameter
     (void) line; // Unused parameter
     // Wait forever until the watchdog fires
     while (true)
     {
     }
 }

 #define ENCODED_8BIT_CHANPG_PAGE_MASK 0xE0         // top 3 bits
 #define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_0 0x00  // 0b000xxxxx
 #define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_28 0x80 // 0b100xxxxx
 #define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_29 0xA0 // 0b101xxxxx
 #define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_30 0xC0 // 0b110xxxxx
 #define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_31 0xE0 // 0b111xxxxx

 #define ENCODED_8BIT_CHANPG_CHANNEL_MASK 0x1F // bottom 5 bits

 uint8_t emberAfGetPageFrom8bitEncodedChanPg(uint8_t chanPg)
 {
     switch (chanPg & ENCODED_8BIT_CHANPG_PAGE_MASK)
     {
     case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_0:
         return 0;
     case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_28:
         return 28;
     case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_29:
         return 29;
     case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_30:
         return 30;
     case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_31:
         return 31;
     default:
         return 0xFF;
     }
 }

 uint8_t emberAfGetChannelFrom8bitEncodedChanPg(uint8_t chanPg)
 {
     return chanPg & ENCODED_8BIT_CHANPG_CHANNEL_MASK;
 }

 uint8_t emberAfMake8bitEncodedChanPg(uint8_t page, uint8_t channel)
 {
     if (emAfValidateChannelPages(page, channel) != EMBER_SUCCESS)
     {
         return 0xFF;
     }

     switch (page)
     {
     case 28:
         return channel | ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_28;
     case 29:
         return channel | ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_29;
     case 30:
         return channel | ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_30;
     case 31:
         return channel | ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_31;
     default:
         // Strictly speaking, we only need case 0 here, but MISRA in its infinite
         // wisdom requires a default case. Since we have validated the arguments
         // already, and 0 is the only remaining case, we simply treat the default
         // as case 0 to make MISRA happy.
         return channel | ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_0;
     }
 }

 bool emberAfContainsAttribute(chip::EndpointId endpoint, chip::ClusterId clusterId, chip::AttributeId attributeId)
 {
     return (emberAfGetServerAttributeIndexByAttributeId(endpoint, clusterId, attributeId) != UINT16_MAX);
 }

 bool emberAfIsKnownVolatileAttribute(chip::EndpointId endpoint, chip::ClusterId clusterId, chip::AttributeId attributeId)
 {
     const EmberAfAttributeMetadata * metadata = emberAfLocateAttributeMetadata(endpoint, clusterId, attributeId);

     if (metadata == nullptr)
     {
         return false;
     }

     return !metadata->IsAutomaticallyPersisted() && !metadata->IsExternal();
 }

 chip::Messaging::ExchangeManager * chip::ExchangeManager()
 {
     return emAfExchangeMgr;
 }
	/**
	*
	* Copyright (c) 2020-2021 Project CHIP Authors
	*
	* 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 "app/util/common.h"
	#include <app-common/zap-generated/attribute-id.h>
	#include <app-common/zap-generated/attribute-type.h>
	#include <app-common/zap-generated/callback.h>
	#include <app-common/zap-generated/cluster-id.h>
	#include <app-common/zap-generated/command-id.h>
	#include <app-common/zap-generated/print-cluster.h>
	#include <app/util/af-event.h>
	#include <app/util/af.h>
	#include <app/util/ember-compatibility-functions.h>

	// TODO: figure out a clear path for compile-time codegen
	#include <app/PluginApplicationCallbacks.h>

	#ifdef EMBER_AF_PLUGIN_GROUPS_SERVER
	#include <app/clusters/groups-server/groups-server.h>
	#endif // EMBER_AF_PLUGIN_GROUPS_SERVER

	using namespace chip;

	//------------------------------------------------------------------------------
	// Forward Declarations

	//------------------------------------------------------------------------------
	// Globals

	// Storage and functions for turning on and off devices
	bool afDeviceEnabled[MAX_ENDPOINT_COUNT];

	#ifdef EMBER_AF_ENABLE_STATISTICS
	// a variable containing the number of messages send from the utilities
	// since emberAfInit was called.
	uint32_t afNumPktsSent;
	#endif

	const EmberAfClusterName zclClusterNames[] = {
	CLUSTER_IDS_TO_NAMES // defined in print-cluster.h
	{ ZCL_NULL_CLUSTER_ID, nullptr }, // terminator
	};

	// A pointer to the current command being processed
	// This struct is allocated inside ember-compatibility-functions.cpp.
	// The pointer below is set to NULL when not processing a command.
	EmberAfClusterCommand * emAfCurrentCommand;

	// A pointer to the global exchange manager
	chip::Messaging::ExchangeManager * emAfExchangeMgr = nullptr;

	// DEPRECATED.
	uint8_t emberAfIncomingZclSequenceNumber = 0xFF;

	// Sequence used for outgoing messages if they are
	// not responses.
	uint8_t emberAfSequenceNumber = 0xFF;

	static uint8_t /enum EmberAfRetryOverride/ emberAfApsRetryOverride = EMBER_AF_RETRY_OVERRIDE_NONE;
	static uint8_t /enum EmberAfDisableDefaultResponse/ emAfDisableDefaultResponse = EMBER_AF_DISABLE_DEFAULT_RESPONSE_NONE;
	static uint8_t /enum EmberAfDisableDefaultResponse/ emAfSavedDisableDefaultResponseVale = EMBER_AF_DISABLE_DEFAULT_RESPONSE_NONE;

	// Holds the response type
	uint8_t emberAfResponseType = ZCL_UTIL_RESP_NORMAL;

	#ifdef EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_DECLARATIONS
	EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_DECLARATIONS
	#endif

	//------------------------------------------------------------------------------

	// Device enabled/disabled functions

	void emberAfSetDeviceEnabled(EndpointId endpoint, bool enabled)
	{
	uint16_t index = emberAfIndexFromEndpoint(endpoint);
	if (index != 0xFFFF && index < sizeof(afDeviceEnabled))
	{
	afDeviceEnabled[index] = enabled;
	}
	#ifdef ZCL_USING_BASIC_CLUSTER_DEVICE_ENABLED_ATTRIBUTE
	emberAfWriteServerAttribute(endpoint, ZCL_BASIC_CLUSTER_ID, ZCL_DEVICE_ENABLED_ATTRIBUTE_ID, (uint8_t *) &enabled,
	ZCL_BOOLEAN_ATTRIBUTE_TYPE);
	#endif
	}

	// Is the device identifying?
	bool emberAfIsDeviceIdentifying(EndpointId endpoint)
	{
	#ifdef ZCL_USING_IDENTIFY_CLUSTER_SERVER
	uint16_t identifyTime;
	EmberAfStatus status = emberAfReadServerAttribute(endpoint, ZCL_IDENTIFY_CLUSTER_ID, ZCL_IDENTIFY_TIME_ATTRIBUTE_ID,
	(uint8_t *) &identifyTime, sizeof(identifyTime));
	return (status == EMBER_ZCL_STATUS_SUCCESS && 0 < identifyTime);
	#else
	return false;
	#endif
	}

	// Calculates difference. See EmberAfDifferenceType for the maximum data size
	// that this function will support.
	EmberAfDifferenceType emberAfGetDifference(uint8_t * pData, EmberAfDifferenceType value, uint8_t dataSize)
	{
	EmberAfDifferenceType value2 = 0, diff;
	uint8_t i;

	// only support data types up to 8 bytes
	if (dataSize > sizeof(EmberAfDifferenceType))
	{
	return 0;
	}

	// get the value
	for (i = 0; i < dataSize; i++)
	{
	value2 = value2 << 8;
	#if (BIGENDIAN_CPU)
	value2 += pData[i];
	#else // BIGENDIAN
	value2 += pData[dataSize - i - 1];
	#endif // BIGENDIAN
	}

	if (value > value2)
	{
	diff = value - value2;
	}
	else
	{
	diff = value2 - value;
	}

	return diff;
	}

	// ****************************************
	// Initialize Clusters
	// ****************************************
	void emberAfInit(chip::Messaging::ExchangeManager * exchangeMgr)
	{
	uint8_t i;
	#ifdef EMBER_AF_ENABLE_STATISTICS
	afNumPktsSent = 0;
	#endif

	emAfExchangeMgr = exchangeMgr;

	for (i = 0; i < EMBER_SUPPORTED_NETWORKS; i++)
	{
	// FIXME: Do we need to support more than one network?
	// emberAfPushNetworkIndex(i);
	emberAfInitializeAttributes(EMBER_BROADCAST_ENDPOINT);
	// emberAfPopNetworkIndex();
	}

	memset(afDeviceEnabled, true, emberAfEndpointCount());

	MATTER_PLUGINS_INIT

	emAfCallInits();
	}

	void emberAfTick(void)
	{
	// Call the AFV2-specific per-endpoint callbacks
	// Anything that defines callbacks as void *TickCallback(void) is called in
	// emAfInit(), which is a generated file
	#ifdef EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_CALLS
	EMBER_AF_GENERATED_PLUGIN_TICK_FUNCTION_CALLS
	#endif
	}

	// Cluster init functions that don't have a cluster implementation to define
	// them in.
	void MatterBooleanStatePluginServerInitCallback() {}
	void MatterBridgedDeviceBasicPluginServerInitCallback() {}
	void MatterElectricalMeasurementPluginServerInitCallback() {}
	void MatterRelativeHumidityMeasurementPluginServerInitCallback() {}
	void MatterIlluminanceMeasurementPluginServerInitCallback() {}
	void MatterBinaryInputBasicPluginServerInitCallback() {}
	void MatterPressureMeasurementPluginServerInitCallback() {}
	void MatterTemperatureMeasurementPluginServerInitCallback() {}
	void MatterFlowMeasurementPluginServerInitCallback() {}
	void MatterOnOffSwitchConfigurationPluginServerInitCallback() {}
	void MatterThermostatUserInterfaceConfigurationPluginServerInitCallback() {}
	void MatterBridgedDeviceBasicInformationPluginServerInitCallback() {}
	void MatterPowerConfigurationPluginServerInitCallback() {}
	void MatterPowerProfilePluginServerInitCallback() {}
	void MatterPulseWidthModulationPluginServerInitCallback() {}
	void MatterAlarmsPluginServerInitCallback() {}
	void MatterTimePluginServerInitCallback() {}
	void MatterAclPluginServerInitCallback() {}
	void MatterPollControlPluginServerInitCallback() {}
	void MatterUnitLocalizationPluginServerInitCallback() {}
	void MatterTimeSynchronizationPluginServerInitCallback() {}
	void MatterProxyValidPluginServerInitCallback() {}
	void MatterProxyDiscoveryPluginServerInitCallback() {}
	void MatterProxyConfigurationPluginServerInitCallback() {}
	void MatterFanControlPluginServerInitCallback() {}

	// ****************************************
	// This function is called by the application when the stack goes down,
	// such as after a leave network. This allows zcl utils to clear state
	// that should not be kept when changing networks
	// ****************************************
	void emberAfStackDown(void)
	{
	emberAfRegistrationAbortCallback();
	}

	// ****************************************
	// Print out information about each cluster
	// ****************************************

	uint16_t emberAfFindClusterNameIndex(ClusterId cluster)
	{
	static_assert(sizeof(ClusterId) == 4, "May need to adjust our index type or somehow define it in terms of cluster id type");
	uint16_t index = 0;
	while (zclClusterNames[index].id != ZCL_NULL_CLUSTER_ID)
	{
	if (zclClusterNames[index].id == cluster)
	{
	return index;
	}
	index++;
	}
	return 0xFFFF;
	}

	// This function parses into the cluster name table, and tries to find
	// the index in the table that has the right cluster id.
	void emberAfDecodeAndPrintCluster(ClusterId cluster)
	{
	uint16_t index = emberAfFindClusterNameIndex(cluster);
	if (index == 0xFFFF)
	{
	static_assert(sizeof(ClusterId) == 4, "Adjust the print formatting");
	emberAfPrint(emberAfPrintActiveArea, "(Unknown clus. [" ChipLogFormatMEI "])", ChipLogValueMEI(cluster));
	}
	else
	{
	emberAfPrint(emberAfPrintActiveArea, "(%p)", zclClusterNames[index].name);
	}
	}

	// This function makes the assumption that
	// emberAfCurrentCommand will either be NULL
	// when invalid, or will have a valid mfgCode
	// when called.
	// If it is invalid, we just return the
	// EMBER_AF_NULL_MANUFACTURER_CODE, which we tend to use
	// for references to the standard library.
	uint16_t emberAfGetMfgCodeFromCurrentCommand(void)
	{
	if (emberAfCurrentCommand() != nullptr)
	{
	return emberAfCurrentCommand()->mfgCode;
	}

	return EMBER_AF_NULL_MANUFACTURER_CODE;
	}

	// the caller to the library can set a flag to say do not respond to the
	// next ZCL message passed in to the library. Passing true means disable
	// the reply for the next ZCL message. Setting to false re-enables the
	// reply (in the case where the app disables it and then doesnt send a
	// message that gets parsed).
	void emberAfSetNoReplyForNextMessage(bool set)
	{
	if (set)
	{
	emberAfResponseType \|= ZCL_UTIL_RESP_NONE;
	}
	else
	{
	emberAfResponseType = static_cast<uint8_t>(emberAfResponseType & ~ZCL_UTIL_RESP_NONE);
	}
	}

	void emberAfSetRetryOverride(EmberAfRetryOverride value)
	{
	emberAfApsRetryOverride = value;
	}

	EmberAfRetryOverride emberAfGetRetryOverride(void)
	{
	return (EmberAfRetryOverride) emberAfApsRetryOverride;
	}

	void emAfApplyRetryOverride(EmberApsOption * options)
	{
	if (options == nullptr)
	{
	return;
	}
	if (emberAfApsRetryOverride == EMBER_AF_RETRY_OVERRIDE_SET)
	{
	*options \|= EMBER_APS_OPTION_RETRY;
	}
	else if (emberAfApsRetryOverride == EMBER_AF_RETRY_OVERRIDE_UNSET)
	{
	options = static_cast<EmberApsOption>(options & ~EMBER_APS_OPTION_RETRY);
	}
	else
	{
	// MISRA requires ..else if.. to have terminating else.
	}
	}

	void emberAfSetDisableDefaultResponse(EmberAfDisableDefaultResponse value)
	{
	emAfDisableDefaultResponse = value;
	if (value != EMBER_AF_DISABLE_DEFAULT_RESPONSE_ONE_SHOT)
	{
	emAfSavedDisableDefaultResponseVale = value;
	}
	}

	EmberAfDisableDefaultResponse emberAfGetDisableDefaultResponse(void)
	{
	return (EmberAfDisableDefaultResponse) emAfDisableDefaultResponse;
	}

	void emAfApplyDisableDefaultResponse(uint8_t * frame_control)
	{
	if (frame_control == nullptr)
	{
	return;
	}
	if (emAfDisableDefaultResponse == EMBER_AF_DISABLE_DEFAULT_RESPONSE_ONE_SHOT)
	{
	emAfDisableDefaultResponse = emAfSavedDisableDefaultResponseVale;
	*frame_control \|= ZCL_DISABLE_DEFAULT_RESPONSE_MASK;
	}
	else if (emAfDisableDefaultResponse == EMBER_AF_DISABLE_DEFAULT_RESPONSE_PERMANENT)
	{
	*frame_control \|= ZCL_DISABLE_DEFAULT_RESPONSE_MASK;
	}
	else
	{
	// MISRA requires ..else if.. to have terminating else.
	}
	}

	EmberStatus emberAfSendImmediateDefaultResponse(EmberAfStatus status)
	{
	return emberAfSendDefaultResponse(emberAfCurrentCommand(), status);
	}

	EmberStatus emberAfSendDefaultResponse(const EmberAfClusterCommand * cmd, EmberAfStatus status)
	{
	// Default Response commands are only sent in response to unicast commands.
	if (cmd->type != EMBER_INCOMING_UNICAST && cmd->type != EMBER_INCOMING_UNICAST_REPLY)
	{
	return EMBER_SUCCESS;
	}

	if (!chip::app::Compatibility::IMEmberAfSendDefaultResponseWithCallback(status))
	{
	// Caller is not responding to anything!
	return EMBER_ERR_FATAL;
	}

	return EMBER_SUCCESS;
	}

	void emberAfCopyInt16u(uint8_t * data, uint16_t index, uint16_t x)
	{
	data[index] = (uint8_t)(((x)) & 0xFF);
	data[index + 1] = (uint8_t)(((x) >> 8) & 0xFF);
	}

	void emberAfCopyInt24u(uint8_t * data, uint16_t index, uint32_t x)
	{
	data[index] = (uint8_t)(((x)) & 0xFF);
	data[index + 1] = (uint8_t)(((x) >> 8) & 0xFF);
	data[index + 2] = (uint8_t)(((x) >> 16) & 0xFF);
	}

	void emberAfCopyInt32u(uint8_t * data, uint16_t index, uint32_t x)
	{
	data[index] = (uint8_t)(((x)) & 0xFF);
	data[index + 1] = (uint8_t)(((x) >> 8) & 0xFF);
	data[index + 2] = (uint8_t)(((x) >> 16) & 0xFF);
	data[index + 3] = (uint8_t)(((x) >> 24) & 0xFF);
	}

	void emberAfCopyString(uint8_t * dest, const uint8_t * src, size_t size)
	{
	if (src == nullptr)
	{
	dest[0] = 0; // Zero out the length of string
	}
	else if (src[0] == 0xFF)
	{
	dest[0] = src[0];
	}
	else
	{
	uint8_t length = emberAfStringLength(src);
	if (size < length)
	{
	// Since we have checked that size < length, size must be able to fit into the type of length.
	length = static_cast<decltype(length)>(size);
	}
	memmove(dest + 1, src + 1, length);
	dest[0] = length;
	}
	}

	void emberAfCopyLongString(uint8_t * dest, const uint8_t * src, size_t size)
	{
	if (src == nullptr)
	{
	dest[0] = dest[1] = 0; // Zero out the length of string
	}
	else if ((src[0] == 0xFF) && (src[1] == 0xFF))
	{
	dest[0] = 0xFF;
	dest[1] = 0xFF;
	}
	else
	{
	uint16_t length = emberAfLongStringLength(src);
	if (size < length)
	{
	// Since we have checked that size < length, size must be able to fit into the type of length.
	length = static_cast<decltype(length)>(size);
	}
	memmove(dest + 2, src + 2, length);
	dest[0] = EMBER_LOW_BYTE(length);
	dest[1] = EMBER_HIGH_BYTE(length);
	}
	}

	#if (BIGENDIAN_CPU)
	#define EM_BIG_ENDIAN true
	#else
	#define EM_BIG_ENDIAN false
	#endif

	// You can pass in val1 as NULL, which will assume that it is
	// pointing to an array of all zeroes. This is used so that
	// default value of NULL is treated as all zeroes.
	int8_t emberAfCompareValues(const uint8_t * val1, const uint8_t * val2, uint16_t len, bool signedNumber)
	{
	if (len == 0)
	{
	// no length means nothing to compare. Shouldn't even happen, since len is sizeof(some-integer-type).
	return 0;
	}

	if (signedNumber)
	{ // signed number comparison
	if (len <= 4)
	{ // only number with 32-bits or less is supported
	int32_t accum1 = 0x0;
	int32_t accum2 = 0x0;
	int32_t all1s = -1;

	for (uint16_t i = 0; i < len; i++)
	{
	uint8_t j = (val1 == nullptr ? 0 : (EM_BIG_ENDIAN ? val1[i] : val1[(len - 1) - i]));
	accum1 \|= j << (8 * (len - 1 - i));

	uint8_t k = (EM_BIG_ENDIAN ? val2[i] : val2[(len - 1) - i]);
	accum2 \|= k << (8 * (len - 1 - i));
	}

	// sign extending, no need for 32-bits numbers
	if (len < 4)
	{
	if ((accum1 & (1 << (8 * len - 1))) != 0)
	{ // check sign
	accum1 \|= all1s - ((1 << (len * 8)) - 1);
	}
	if ((accum2 & (1 << (8 * len - 1))) != 0)
	{ // check sign
	accum2 \|= all1s - ((1 << (len * 8)) - 1);
	}
	}

	if (accum1 > accum2)
	{
	return 1;
	}
	if (accum1 < accum2)
	{
	return -1;
	}

	return 0;
	}

	// not supported
	return 0;
	}

	// regular unsigned number comparison
	for (uint16_t i = 0; i < len; i++)
	{
	uint8_t j = (val1 == nullptr ? 0 : (EM_BIG_ENDIAN ? val1[i] : val1[(len - 1) - i]));
	uint8_t k = (EM_BIG_ENDIAN ? val2[i] : val2[(len - 1) - i]);

	if (j > k)
	{
	return 1;
	}
	if (k > j)
	{
	return -1;
	}
	}
	return 0;
	}

	#if 0
	// Moving to time-util.c
	int8_t emberAfCompareDates(EmberAfDate* date1, EmberAfDate* date2)
	{
	uint32_t val1 = emberAfEncodeDate(date1);
	uint32_t val2 = emberAfEncodeDate(date2);
	return (val1 == val2) ? 0 : ((val1 < val2) ? -1 : 1);
	}
	#endif

	// Zigbee spec says types between signed 8 bit and signed 64 bit
	bool emberAfIsTypeSigned(EmberAfAttributeType dataType)
	{
	return (dataType >= ZCL_INT8S_ATTRIBUTE_TYPE && dataType <= ZCL_INT64S_ATTRIBUTE_TYPE);
	}

	uint8_t emberAfAppendCharacters(uint8_t * zclString, uint8_t zclStringMaxLen, const uint8_t * appendingChars,
	uint8_t appendingCharsLen)
	{
	uint8_t freeChars;
	uint8_t curLen;
	uint8_t charsToWrite;

	if ((zclString == nullptr) \|\| (zclStringMaxLen == 0) \|\| (appendingChars == nullptr) \|\| (appendingCharsLen == 0))
	{
	return 0;
	}

	curLen = emberAfStringLength(zclString);

	if ((zclString[0] == 0xFF) \|\| (curLen >= zclStringMaxLen))
	{
	return 0;
	}

	freeChars = static_cast<uint8_t>(zclStringMaxLen - curLen);
	charsToWrite = (freeChars > appendingCharsLen) ? appendingCharsLen : freeChars;

	memcpy(&zclString[1 + curLen], // 1 is to account for zcl's length byte
	appendingChars, charsToWrite);
	// Cast is safe, because the sum can't be bigger than zclStringMaxLen.
	zclString[0] = static_cast<uint8_t>(curLen + charsToWrite);
	return charsToWrite;
	}

	/*
	On each page, first channel maps to channel number zero and so on.
	Example:
	page Band Rage of 90 channels Per page channel mapping
	28 863 MHz 0-26 0-26
	29 863 MHz 27-34,62 0-8 (Here 7th channel maps to 34 and 8th to 62)
	30 863 MHz 35 - 61 0-26
	31 915 0-26 0-26

	*/
	EmberStatus emAfValidateChannelPages(uint8_t page, uint8_t channel)
	{
	switch (page)
	{
	case 0:
	if (!((channel <= EMBER_MAX_802_15_4_CHANNEL_NUMBER) &&
	((EMBER_MIN_802_15_4_CHANNEL_NUMBER == 0) \|\| (channel >= EMBER_MIN_802_15_4_CHANNEL_NUMBER))))
	{
	return EMBER_PHY_INVALID_CHANNEL;
	}
	break;
	case 28:
	case 30:
	case 31:
	if (channel > EMBER_MAX_SUBGHZ_CHANNEL_NUMBER_ON_PAGES_28_30_31)
	{
	return EMBER_PHY_INVALID_CHANNEL;
	}
	break;
	case 29:
	if (channel > EMBER_MAX_SUBGHZ_CHANNEL_NUMBER_ON_PAGE_29)
	{
	return EMBER_PHY_INVALID_CHANNEL;
	}
	break;
	default:
	return EMBER_PHY_INVALID_CHANNEL;
	break;
	}
	return EMBER_SUCCESS;
	}

	void slabAssert(const char * file, int line)
	{
	(void) file; // Unused parameter
	(void) line; // Unused parameter
	// Wait forever until the watchdog fires
	while (true)
	{
	}
	}

	#define ENCODED_8BIT_CHANPG_PAGE_MASK 0xE0 // top 3 bits
	#define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_0 0x00 // 0b000xxxxx
	#define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_28 0x80 // 0b100xxxxx
	#define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_29 0xA0 // 0b101xxxxx
	#define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_30 0xC0 // 0b110xxxxx
	#define ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_31 0xE0 // 0b111xxxxx

	#define ENCODED_8BIT_CHANPG_CHANNEL_MASK 0x1F // bottom 5 bits

	uint8_t emberAfGetPageFrom8bitEncodedChanPg(uint8_t chanPg)
	{
	switch (chanPg & ENCODED_8BIT_CHANPG_PAGE_MASK)
	{
	case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_0:
	return 0;
	case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_28:
	return 28;
	case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_29:
	return 29;
	case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_30:
	return 30;
	case ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_31:
	return 31;
	default:
	return 0xFF;
	}
	}

	uint8_t emberAfGetChannelFrom8bitEncodedChanPg(uint8_t chanPg)
	{
	return chanPg & ENCODED_8BIT_CHANPG_CHANNEL_MASK;
	}

	uint8_t emberAfMake8bitEncodedChanPg(uint8_t page, uint8_t channel)
	{
	if (emAfValidateChannelPages(page, channel) != EMBER_SUCCESS)
	{
	return 0xFF;
	}

	switch (page)
	{
	case 28:
	return channel \| ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_28;
	case 29:
	return channel \| ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_29;
	case 30:
	return channel \| ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_30;
	case 31:
	return channel \| ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_31;
	default:
	// Strictly speaking, we only need case 0 here, but MISRA in its infinite
	// wisdom requires a default case. Since we have validated the arguments
	// already, and 0 is the only remaining case, we simply treat the default
	// as case 0 to make MISRA happy.
	return channel \| ENCODED_8BIT_CHANPG_PAGE_MASK_PAGE_0;
	}
	}

	bool emberAfContainsAttribute(chip::EndpointId endpoint, chip::ClusterId clusterId, chip::AttributeId attributeId)
	{
	return (emberAfGetServerAttributeIndexByAttributeId(endpoint, clusterId, attributeId) != UINT16_MAX);
	}

	bool emberAfIsKnownVolatileAttribute(chip::EndpointId endpoint, chip::ClusterId clusterId, chip::AttributeId attributeId)
	{
	const EmberAfAttributeMetadata * metadata = emberAfLocateAttributeMetadata(endpoint, clusterId, attributeId);

	if (metadata == nullptr)
	{
	return false;
	}

	return !metadata->IsAutomaticallyPersisted() && !metadata->IsExternal();
	}

	chip::Messaging::ExchangeManager * chip::ExchangeManager()
	{
	return emAfExchangeMgr;
	}