src/lib/dnssd/Resolver.h - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 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.
  */

 #pragma once

 #include <cstdint>
 #include <limits>
 #include <utility>

 #include "lib/support/logging/CHIPLogging.h"
 #include <inet/IPAddress.h>
 #include <inet/InetInterface.h>
 #include <inet/UDPEndPoint.h>
 #include <lib/core/CHIPError.h>
 #include <lib/core/Optional.h>
 #include <lib/core/PeerId.h>
 #include <lib/dnssd/Constants.h>
 #include <lib/support/BytesToHex.h>
 #include <messaging/ReliableMessageProtocolConfig.h>

 namespace chip {
 namespace Dnssd {

 /// Node resolution data common to both operational and commissionable discovery
 struct CommonResolutionData
 {
     // TODO: is this count OK? Sufficient space for IPv6 LL, GUA, ULA (and maybe IPv4 if enabled)
     static constexpr unsigned kMaxIPAddresses = 5;

     Inet::InterfaceId interfaceId;

     size_t numIPs = 0; // number of valid IP addresses
     Inet::IPAddress ipAddress[kMaxIPAddresses];

     uint16_t port                         = 0;
     char hostName[kHostNameMaxLength + 1] = {};
     bool supportsTcp                      = false;
     Optional<System::Clock::Milliseconds32> mrpRetryIntervalIdle;
     Optional<System::Clock::Milliseconds32> mrpRetryIntervalActive;

     CommonResolutionData() { Reset(); }

     bool IsValid() const { return !IsHost("") && (numIPs > 0) && (ipAddress[0] != chip::Inet::IPAddress::Any); }

     ReliableMessageProtocolConfig GetRemoteMRPConfig() const
     {
         const ReliableMessageProtocolConfig defaultConfig = GetDefaultMRPConfig();
         return ReliableMessageProtocolConfig(GetMrpRetryIntervalIdle().ValueOr(defaultConfig.mIdleRetransTimeout),
                                              GetMrpRetryIntervalActive().ValueOr(defaultConfig.mActiveRetransTimeout));
     }
     Optional<System::Clock::Milliseconds32> GetMrpRetryIntervalIdle() const { return mrpRetryIntervalIdle; }
     Optional<System::Clock::Milliseconds32> GetMrpRetryIntervalActive() const { return mrpRetryIntervalActive; }

     bool IsDeviceTreatedAsSleepy(const ReliableMessageProtocolConfig * defaultMRPConfig) const
     {
         // If either sleepy interval (Idle - SII, Active - SAI) has a value and that value is greater
         // than the value passed to this function, then the peer device will be treated as if it is
         // a Sleepy End Device (SED)
         return (mrpRetryIntervalIdle.HasValue() && (mrpRetryIntervalIdle.Value() > defaultMRPConfig->mIdleRetransTimeout)) ||
             (mrpRetryIntervalActive.HasValue() && (mrpRetryIntervalActive.Value() > defaultMRPConfig->mActiveRetransTimeout));
     }

     bool IsHost(const char * host) const { return strcmp(host, hostName) == 0; }

     void Reset()
     {
         memset(hostName, 0, sizeof(hostName));
         mrpRetryIntervalIdle   = NullOptional;
         mrpRetryIntervalActive = NullOptional;
         numIPs                 = 0;
         port                   = 0;
         supportsTcp            = false;
         interfaceId            = Inet::InterfaceId::Null();
         for (auto & addr : ipAddress)
         {
             addr = chip::Inet::IPAddress::Any;
         }
     }

     void LogDetail() const
     {
         if (!IsHost(""))
         {
             ChipLogDetail(Discovery, "\tHostname: %s", hostName);
         }
 #if CHIP_DETAIL_LOGGING
         for (unsigned j = 0; j < numIPs; j++)
         {
             char buf[Inet::IPAddress::kMaxStringLength];
             char * ipAddressOut = ipAddress[j].ToString(buf);
             ChipLogDetail(Discovery, "\tIP Address #%d: %s", j + 1, ipAddressOut);
         }
 #endif // CHIP_DETAIL_LOGGING
         if (port > 0)
         {
             ChipLogDetail(Discovery, "\tPort: %u", port);
         }
         if (mrpRetryIntervalIdle.HasValue())
         {
             ChipLogDetail(Discovery, "\tMrp Interval idle: %" PRIu32 " ms", mrpRetryIntervalIdle.Value().count());
         }
         else
         {
             ChipLogDetail(Discovery, "\tMrp Interval idle: not present");
         }
         if (mrpRetryIntervalActive.HasValue())
         {
             ChipLogDetail(Discovery, "\tMrp Interval active: %" PRIu32 " ms", mrpRetryIntervalActive.Value().count());
         }
         else
         {
             ChipLogDetail(Discovery, "\tMrp Interval active: not present");
         }
         ChipLogDetail(Discovery, "\tTCP Supported: %d", supportsTcp);
     }
 };

 /// Data that is specific to Operational Discovery of nodes
 struct OperationalNodeData
 {
     PeerId peerId;

     void Reset() { peerId = PeerId(); }
 };

 constexpr size_t kMaxDeviceNameLen         = 32;
 constexpr size_t kMaxRotatingIdLen         = 50;
 constexpr size_t kMaxPairingInstructionLen = 128;

 /// Data that is specific to commisionable/commissioning node discovery
 struct CommissionNodeData
 {
     char instanceName[Commission::kInstanceNameMaxLength + 1] = {};
     uint16_t longDiscriminator                                = 0;
     uint16_t vendorId                                         = 0;
     uint16_t productId                                        = 0;
     uint8_t commissioningMode                                 = 0;
     // TODO: possibly 32-bit - see spec issue #3226
     uint16_t deviceType                                    = 0;
     char deviceName[kMaxDeviceNameLen + 1]                 = {};
     uint8_t rotatingId[kMaxRotatingIdLen]                  = {};
     size_t rotatingIdLen                                   = 0;
     uint16_t pairingHint                                   = 0;
     char pairingInstruction[kMaxPairingInstructionLen + 1] = {};

     CommissionNodeData() {}

     void Reset()
     {
         // Let constructor clear things as default
         this->~CommissionNodeData();
         new (this) CommissionNodeData();
     }

     bool IsInstanceName(const char * instance) const { return strcmp(instance, instanceName) == 0; }

     void LogDetail() const
     {
         if (rotatingIdLen > 0)
         {
             char rotatingIdString[chip::Dnssd::kMaxRotatingIdLen * 2 + 1] = "";
             Encoding::BytesToUppercaseHexString(rotatingId, rotatingIdLen, rotatingIdString, sizeof(rotatingIdString));
             ChipLogDetail(Discovery, "\tRotating ID: %s", rotatingIdString);
         }
         if (strlen(deviceName) != 0)
         {
             ChipLogDetail(Discovery, "\tDevice Name: %s", deviceName);
         }
         if (vendorId > 0)
         {
             ChipLogDetail(Discovery, "\tVendor ID: %u", vendorId);
         }
         if (productId > 0)
         {
             ChipLogDetail(Discovery, "\tProduct ID: %u", productId);
         }
         if (deviceType > 0)
         {
             ChipLogDetail(Discovery, "\tDevice Type: %u", deviceType);
         }
         if (longDiscriminator > 0)
         {
             ChipLogDetail(Discovery, "\tLong Discriminator: %u", longDiscriminator);
         }
         if (strlen(pairingInstruction) != 0)
         {
             ChipLogDetail(Discovery, "\tPairing Instruction: %s", pairingInstruction);
         }
         if (pairingHint > 0)
         {
             ChipLogDetail(Discovery, "\tPairing Hint: %u", pairingHint);
         }
         if (!IsInstanceName(""))
         {
             ChipLogDetail(Discovery, "\tInstance Name: %s", instanceName);
         }
         ChipLogDetail(Discovery, "\tCommissioning Mode: %u", commissioningMode);
     }
 };

 struct ResolvedNodeData
 {
     CommonResolutionData resolutionData;
     OperationalNodeData operationalData;

     void LogNodeIdResolved() const
     {
 #if CHIP_PROGRESS_LOGGING
         // Would be nice to log the interface id, but sorting out how to do so
         // across our different InterfaceId implementations is a pain.
         ChipLogProgress(Discovery, "Node ID resolved for " ChipLogFormatX64 ":" ChipLogFormatX64,
                         ChipLogValueX64(operationalData.peerId.GetCompressedFabricId()),
                         ChipLogValueX64(operationalData.peerId.GetNodeId()));
         resolutionData.LogDetail();
 #endif // CHIP_PROGRESS_LOGGING
     }
 };

 struct DiscoveredNodeData
 {
     CommonResolutionData resolutionData;
     CommissionNodeData commissionData;

     void Reset()
     {
         resolutionData.Reset();
         commissionData.Reset();
     }
     DiscoveredNodeData() { Reset(); }

     void LogDetail() const
     {
         ChipLogDetail(Discovery, "Discovered node:");
         resolutionData.LogDetail();
         commissionData.LogDetail();
     }
 };

 enum class DiscoveryFilterType : uint8_t
 {
     kNone,
     kShortDiscriminator,
     kLongDiscriminator,
     kVendorId,
     kDeviceType,
     kCommissioningMode,
     kInstanceName,
     kCommissioner,
     kCompressedFabricId,
 };
 struct DiscoveryFilter
 {
     DiscoveryFilterType type;
     uint64_t code             = 0;
     const char * instanceName = nullptr;
     DiscoveryFilter() : type(DiscoveryFilterType::kNone), code(0) {}
     DiscoveryFilter(const DiscoveryFilterType newType) : type(newType) {}
     DiscoveryFilter(const DiscoveryFilterType newType, uint64_t newCode) : type(newType), code(newCode) {}
     DiscoveryFilter(const DiscoveryFilterType newType, const char * newInstanceName) : type(newType), instanceName(newInstanceName)
     {}
     bool operator==(const DiscoveryFilter & other) const
     {
         if (type != other.type)
         {
             return false;
         }
         if (type == DiscoveryFilterType::kInstanceName)
         {
             return (instanceName != nullptr) && (other.instanceName != nullptr) && (strcmp(instanceName, other.instanceName) == 0);
         }

         return code == other.code;
     }
 };
 enum class DiscoveryType
 {
     kUnknown,
     kOperational,
     kCommissionableNode,
     kCommissionerNode
 };

 /// Callbacks for resolving operational node resolution
 class OperationalResolveDelegate
 {
 public:
     virtual ~OperationalResolveDelegate() = default;

     /// Called within the CHIP event loop after a successful node resolution.
     ///
     /// May be called multiple times: implementations may call this once per
     /// received packet and MDNS packets may arrive over different interfaces
     /// which will make nodeData have different content.
     virtual void OnOperationalNodeResolved(const ResolvedNodeData & nodeData) = 0;

     /// Notify a final failure for a node operational resolution.
     ///
     /// Called within the chip event loop if node resolution could not be performed.
     /// This may be due to internal errors or timeouts.
     ///
     /// This will be called only if 'OnOperationalNodeResolved' is never called.
     virtual void OnOperationalNodeResolutionFailed(const PeerId & peerId, CHIP_ERROR error) = 0;
 };

 /// Callbacks for discovering nodes advertising non-operational status:
 ///   - Commissioners
 ///   - Nodes in commissioning modes over IP (e.g. ethernet devices, devices already
 ///     connected to thread/wifi or devices with a commissioning window open)
 class CommissioningResolveDelegate
 {
 public:
     virtual ~CommissioningResolveDelegate() = default;

     /// Called within the CHIP event loop once a node is discovered.
     ///
     /// May be called multiple times as more nodes send their answer to a
     /// multicast discovery query
     virtual void OnNodeDiscovered(const DiscoveredNodeData & nodeData) = 0;
 };

 /**
  * Interface for resolving CHIP DNS-SD services
  */
 class Resolver
 {
 public:
     virtual ~Resolver() {}

     /**
      * Initializes the resolver.
      *
      * The method must be called before other methods of this class.
      * If the resolver has already been initialized, the method exits immediately with no error.
      */
     virtual CHIP_ERROR Init(chip::Inet::EndPointManager<Inet::UDPEndPoint> * endPointManager) = 0;

     /**
      * Shuts down the resolver if it has been initialized before.
      */
     virtual void Shutdown() = 0;

     /**
      * If nullptr is passed, the previously registered delegate is unregistered.
      */
     virtual void SetOperationalDelegate(OperationalResolveDelegate * delegate) = 0;

     /**
      * If nullptr is passed, the previously registered delegate is unregistered.
      */
     virtual void SetCommissioningDelegate(CommissioningResolveDelegate * delegate) = 0;

     /**
      * Requests resolution of the given operational node service.
      *
      * This will trigger a DNSSD query.
      *
      * When the operation succeeds or fails, and a resolver delegate has been registered,
      * the result of the operation is passed to the delegate's `OnNodeIdResolved` or
      * `OnNodeIdResolutionFailed` method, respectively.
      */
     virtual CHIP_ERROR ResolveNodeId(const PeerId & peerId, Inet::IPAddressType type) = 0;

     /**
      * Finds all commissionable nodes matching the given filter.
      *
      * Whenever a new matching node is found and a resolver delegate has been registered,
      * the node information is passed to the delegate's `OnNodeDiscoveryComplete` method.
      */
     virtual CHIP_ERROR DiscoverCommissionableNodes(DiscoveryFilter filter = DiscoveryFilter()) = 0;

     /**
      * Finds all commissioner nodes matching the given filter.
      *
      * Whenever a new matching node is found and a resolver delegate has been registered,
      * the node information is passed to the delegate's `OnNodeDiscoveryComplete` method.
      */
     virtual CHIP_ERROR DiscoverCommissioners(DiscoveryFilter filter = DiscoveryFilter()) = 0;

     /**
      * Stop discovery (of commissionable or commissioner nodes).
      *
      * Some back ends may not support stopping discovery, so consumers should
      * not assume they will stop getting callbacks after calling this.
      */
     virtual CHIP_ERROR StopDiscovery() = 0;

     /**
      * Verify the validity of an address that appears to be out of date (for example
      * because establishing a connection to it has failed).
      */
     virtual CHIP_ERROR ReconfirmRecord(const char * hostname, Inet::IPAddress address, Inet::InterfaceId interfaceId) = 0;

     /**
      * Provides the system-wide implementation of the service resolver
      */
     static Resolver & Instance();
 };

 } // namespace Dnssd
 } // namespace chip
	/*
	*
	* Copyright (c) 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.
	*/

	#pragma once

	#include <cstdint>
	#include <limits>
	#include <utility>

	#include "lib/support/logging/CHIPLogging.h"
	#include <inet/IPAddress.h>
	#include <inet/InetInterface.h>
	#include <inet/UDPEndPoint.h>
	#include <lib/core/CHIPError.h>
	#include <lib/core/Optional.h>
	#include <lib/core/PeerId.h>
	#include <lib/dnssd/Constants.h>
	#include <lib/support/BytesToHex.h>
	#include <messaging/ReliableMessageProtocolConfig.h>

	namespace chip {
	namespace Dnssd {

	/// Node resolution data common to both operational and commissionable discovery
	struct CommonResolutionData
	{
	// TODO: is this count OK? Sufficient space for IPv6 LL, GUA, ULA (and maybe IPv4 if enabled)
	static constexpr unsigned kMaxIPAddresses = 5;

	Inet::InterfaceId interfaceId;

	size_t numIPs = 0; // number of valid IP addresses
	Inet::IPAddress ipAddress[kMaxIPAddresses];

	uint16_t port = 0;
	char hostName[kHostNameMaxLength + 1] = {};
	bool supportsTcp = false;
	Optional<System::Clock::Milliseconds32> mrpRetryIntervalIdle;
	Optional<System::Clock::Milliseconds32> mrpRetryIntervalActive;

	CommonResolutionData() { Reset(); }

	bool IsValid() const { return !IsHost("") && (numIPs > 0) && (ipAddress[0] != chip::Inet::IPAddress::Any); }

	ReliableMessageProtocolConfig GetRemoteMRPConfig() const
	{
	const ReliableMessageProtocolConfig defaultConfig = GetDefaultMRPConfig();
	return ReliableMessageProtocolConfig(GetMrpRetryIntervalIdle().ValueOr(defaultConfig.mIdleRetransTimeout),
	GetMrpRetryIntervalActive().ValueOr(defaultConfig.mActiveRetransTimeout));
	}
	Optional<System::Clock::Milliseconds32> GetMrpRetryIntervalIdle() const { return mrpRetryIntervalIdle; }
	Optional<System::Clock::Milliseconds32> GetMrpRetryIntervalActive() const { return mrpRetryIntervalActive; }

	bool IsDeviceTreatedAsSleepy(const ReliableMessageProtocolConfig * defaultMRPConfig) const
	{
	// If either sleepy interval (Idle - SII, Active - SAI) has a value and that value is greater
	// than the value passed to this function, then the peer device will be treated as if it is
	// a Sleepy End Device (SED)
	return (mrpRetryIntervalIdle.HasValue() && (mrpRetryIntervalIdle.Value() > defaultMRPConfig->mIdleRetransTimeout)) \|\|
	(mrpRetryIntervalActive.HasValue() && (mrpRetryIntervalActive.Value() > defaultMRPConfig->mActiveRetransTimeout));
	}

	bool IsHost(const char * host) const { return strcmp(host, hostName) == 0; }

	void Reset()
	{
	memset(hostName, 0, sizeof(hostName));
	mrpRetryIntervalIdle = NullOptional;
	mrpRetryIntervalActive = NullOptional;
	numIPs = 0;
	port = 0;
	supportsTcp = false;
	interfaceId = Inet::InterfaceId::Null();
	for (auto & addr : ipAddress)
	{
	addr = chip::Inet::IPAddress::Any;
	}
	}

	void LogDetail() const
	{
	if (!IsHost(""))
	{
	ChipLogDetail(Discovery, "\tHostname: %s", hostName);
	}
	#if CHIP_DETAIL_LOGGING
	for (unsigned j = 0; j < numIPs; j++)
	{
	char buf[Inet::IPAddress::kMaxStringLength];
	char * ipAddressOut = ipAddress[j].ToString(buf);
	ChipLogDetail(Discovery, "\tIP Address #%d: %s", j + 1, ipAddressOut);
	}
	#endif // CHIP_DETAIL_LOGGING
	if (port > 0)
	{
	ChipLogDetail(Discovery, "\tPort: %u", port);
	}
	if (mrpRetryIntervalIdle.HasValue())
	{
	ChipLogDetail(Discovery, "\tMrp Interval idle: %" PRIu32 " ms", mrpRetryIntervalIdle.Value().count());
	}
	else
	{
	ChipLogDetail(Discovery, "\tMrp Interval idle: not present");
	}
	if (mrpRetryIntervalActive.HasValue())
	{
	ChipLogDetail(Discovery, "\tMrp Interval active: %" PRIu32 " ms", mrpRetryIntervalActive.Value().count());
	}
	else
	{
	ChipLogDetail(Discovery, "\tMrp Interval active: not present");
	}
	ChipLogDetail(Discovery, "\tTCP Supported: %d", supportsTcp);
	}
	};

	/// Data that is specific to Operational Discovery of nodes
	struct OperationalNodeData
	{
	PeerId peerId;

	void Reset() { peerId = PeerId(); }
	};

	constexpr size_t kMaxDeviceNameLen = 32;
	constexpr size_t kMaxRotatingIdLen = 50;
	constexpr size_t kMaxPairingInstructionLen = 128;

	/// Data that is specific to commisionable/commissioning node discovery
	struct CommissionNodeData
	{
	char instanceName[Commission::kInstanceNameMaxLength + 1] = {};
	uint16_t longDiscriminator = 0;
	uint16_t vendorId = 0;
	uint16_t productId = 0;
	uint8_t commissioningMode = 0;
	// TODO: possibly 32-bit - see spec issue #3226
	uint16_t deviceType = 0;
	char deviceName[kMaxDeviceNameLen + 1] = {};
	uint8_t rotatingId[kMaxRotatingIdLen] = {};
	size_t rotatingIdLen = 0;
	uint16_t pairingHint = 0;
	char pairingInstruction[kMaxPairingInstructionLen + 1] = {};

	CommissionNodeData() {}

	void Reset()
	{
	// Let constructor clear things as default
	this->~CommissionNodeData();
	new (this) CommissionNodeData();
	}

	bool IsInstanceName(const char * instance) const { return strcmp(instance, instanceName) == 0; }

	void LogDetail() const
	{
	if (rotatingIdLen > 0)
	{
	char rotatingIdString[chip::Dnssd::kMaxRotatingIdLen * 2 + 1] = "";
	Encoding::BytesToUppercaseHexString(rotatingId, rotatingIdLen, rotatingIdString, sizeof(rotatingIdString));
	ChipLogDetail(Discovery, "\tRotating ID: %s", rotatingIdString);
	}
	if (strlen(deviceName) != 0)
	{
	ChipLogDetail(Discovery, "\tDevice Name: %s", deviceName);
	}
	if (vendorId > 0)
	{
	ChipLogDetail(Discovery, "\tVendor ID: %u", vendorId);
	}
	if (productId > 0)
	{
	ChipLogDetail(Discovery, "\tProduct ID: %u", productId);
	}
	if (deviceType > 0)
	{
	ChipLogDetail(Discovery, "\tDevice Type: %u", deviceType);
	}
	if (longDiscriminator > 0)
	{
	ChipLogDetail(Discovery, "\tLong Discriminator: %u", longDiscriminator);
	}
	if (strlen(pairingInstruction) != 0)
	{
	ChipLogDetail(Discovery, "\tPairing Instruction: %s", pairingInstruction);
	}
	if (pairingHint > 0)
	{
	ChipLogDetail(Discovery, "\tPairing Hint: %u", pairingHint);
	}
	if (!IsInstanceName(""))
	{
	ChipLogDetail(Discovery, "\tInstance Name: %s", instanceName);
	}
	ChipLogDetail(Discovery, "\tCommissioning Mode: %u", commissioningMode);
	}
	};

	struct ResolvedNodeData
	{
	CommonResolutionData resolutionData;
	OperationalNodeData operationalData;

	void LogNodeIdResolved() const
	{
	#if CHIP_PROGRESS_LOGGING
	// Would be nice to log the interface id, but sorting out how to do so
	// across our different InterfaceId implementations is a pain.
	ChipLogProgress(Discovery, "Node ID resolved for " ChipLogFormatX64 ":" ChipLogFormatX64,
	ChipLogValueX64(operationalData.peerId.GetCompressedFabricId()),
	ChipLogValueX64(operationalData.peerId.GetNodeId()));
	resolutionData.LogDetail();
	#endif // CHIP_PROGRESS_LOGGING
	}
	};

	struct DiscoveredNodeData
	{
	CommonResolutionData resolutionData;
	CommissionNodeData commissionData;

	void Reset()
	{
	resolutionData.Reset();
	commissionData.Reset();
	}
	DiscoveredNodeData() { Reset(); }

	void LogDetail() const
	{
	ChipLogDetail(Discovery, "Discovered node:");
	resolutionData.LogDetail();
	commissionData.LogDetail();
	}
	};

	enum class DiscoveryFilterType : uint8_t
	{
	kNone,
	kShortDiscriminator,
	kLongDiscriminator,
	kVendorId,
	kDeviceType,
	kCommissioningMode,
	kInstanceName,
	kCommissioner,
	kCompressedFabricId,
	};
	struct DiscoveryFilter
	{
	DiscoveryFilterType type;
	uint64_t code = 0;
	const char * instanceName = nullptr;
	DiscoveryFilter() : type(DiscoveryFilterType::kNone), code(0) {}
	DiscoveryFilter(const DiscoveryFilterType newType) : type(newType) {}
	DiscoveryFilter(const DiscoveryFilterType newType, uint64_t newCode) : type(newType), code(newCode) {}
	DiscoveryFilter(const DiscoveryFilterType newType, const char * newInstanceName) : type(newType), instanceName(newInstanceName)
	{}
	bool operator==(const DiscoveryFilter & other) const
	{
	if (type != other.type)
	{
	return false;
	}
	if (type == DiscoveryFilterType::kInstanceName)
	{
	return (instanceName != nullptr) && (other.instanceName != nullptr) && (strcmp(instanceName, other.instanceName) == 0);
	}

	return code == other.code;
	}
	};
	enum class DiscoveryType
	{
	kUnknown,
	kOperational,
	kCommissionableNode,
	kCommissionerNode
	};

	/// Callbacks for resolving operational node resolution
	class OperationalResolveDelegate
	{
	public:
	virtual ~OperationalResolveDelegate() = default;

	/// Called within the CHIP event loop after a successful node resolution.
	///
	/// May be called multiple times: implementations may call this once per
	/// received packet and MDNS packets may arrive over different interfaces
	/// which will make nodeData have different content.
	virtual void OnOperationalNodeResolved(const ResolvedNodeData & nodeData) = 0;

	/// Notify a final failure for a node operational resolution.
	///
	/// Called within the chip event loop if node resolution could not be performed.
	/// This may be due to internal errors or timeouts.
	///
	/// This will be called only if 'OnOperationalNodeResolved' is never called.
	virtual void OnOperationalNodeResolutionFailed(const PeerId & peerId, CHIP_ERROR error) = 0;
	};

	/// Callbacks for discovering nodes advertising non-operational status:
	/// - Commissioners
	/// - Nodes in commissioning modes over IP (e.g. ethernet devices, devices already
	/// connected to thread/wifi or devices with a commissioning window open)
	class CommissioningResolveDelegate
	{
	public:
	virtual ~CommissioningResolveDelegate() = default;

	/// Called within the CHIP event loop once a node is discovered.
	///
	/// May be called multiple times as more nodes send their answer to a
	/// multicast discovery query
	virtual void OnNodeDiscovered(const DiscoveredNodeData & nodeData) = 0;
	};

	/**
	* Interface for resolving CHIP DNS-SD services
	*/
	class Resolver
	{
	public:
	virtual ~Resolver() {}

	/**
	* Initializes the resolver.
	*
	* The method must be called before other methods of this class.
	* If the resolver has already been initialized, the method exits immediately with no error.
	*/
	virtual CHIP_ERROR Init(chip::Inet::EndPointManager<Inet::UDPEndPoint> * endPointManager) = 0;

	/**
	* Shuts down the resolver if it has been initialized before.
	*/
	virtual void Shutdown() = 0;

	/**
	* If nullptr is passed, the previously registered delegate is unregistered.
	*/
	virtual void SetOperationalDelegate(OperationalResolveDelegate * delegate) = 0;

	/**
	* If nullptr is passed, the previously registered delegate is unregistered.
	*/
	virtual void SetCommissioningDelegate(CommissioningResolveDelegate * delegate) = 0;

	/**
	* Requests resolution of the given operational node service.
	*
	* This will trigger a DNSSD query.
	*
	* When the operation succeeds or fails, and a resolver delegate has been registered,
	* the result of the operation is passed to the delegate's `OnNodeIdResolved` or
	* `OnNodeIdResolutionFailed` method, respectively.
	*/
	virtual CHIP_ERROR ResolveNodeId(const PeerId & peerId, Inet::IPAddressType type) = 0;

	/**
	* Finds all commissionable nodes matching the given filter.
	*
	* Whenever a new matching node is found and a resolver delegate has been registered,
	* the node information is passed to the delegate's `OnNodeDiscoveryComplete` method.
	*/
	virtual CHIP_ERROR DiscoverCommissionableNodes(DiscoveryFilter filter = DiscoveryFilter()) = 0;

	/**
	* Finds all commissioner nodes matching the given filter.
	*
	* Whenever a new matching node is found and a resolver delegate has been registered,
	* the node information is passed to the delegate's `OnNodeDiscoveryComplete` method.
	*/
	virtual CHIP_ERROR DiscoverCommissioners(DiscoveryFilter filter = DiscoveryFilter()) = 0;

	/**
	* Stop discovery (of commissionable or commissioner nodes).
	*
	* Some back ends may not support stopping discovery, so consumers should
	* not assume they will stop getting callbacks after calling this.
	*/
	virtual CHIP_ERROR StopDiscovery() = 0;

	/**
	* Verify the validity of an address that appears to be out of date (for example
	* because establishing a connection to it has failed).
	*/
	virtual CHIP_ERROR ReconfirmRecord(const char * hostname, Inet::IPAddress address, Inet::InterfaceId interfaceId) = 0;

	/**
	* Provides the system-wide implementation of the service resolver
	*/
	static Resolver & Instance();
	};

	} // namespace Dnssd
	} // namespace chip