src/setup_payload/tests/TestAdditionalDataPayload.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2021-2022 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.
  */

 /**
  *    @file
  *      This file implements a unit test suite for the additional payload generation
  *      code functionality.
  *
  */

 #include <math.h>
 #include <memory>
 #include <stdio.h>

 #include <gtest/gtest.h>

 #include <lib/support/BytesToHex.h>
 #include <lib/support/CHIPMem.h>
 #include <lib/support/CHIPMemString.h>
 #include <lib/support/CHIPPlatformMemory.h>
 #include <lib/support/verhoeff/Verhoeff.h>
 #include <setup_payload/AdditionalDataPayloadGenerator.h>
 #include <setup_payload/AdditionalDataPayloadParser.h>
 #include <setup_payload/SetupPayload.h>
 #include <system/SystemPacketBuffer.h>

 using namespace chip;

 namespace {

 constexpr char kAdditionalDataPayloadWithoutRotatingDeviceId[]           = "1518";
 constexpr char kAdditionalDataPayloadWithRotatingDeviceId[]              = "153000120A00D00561E77A68A9FD975057375B9283A818";
 constexpr char kAdditionalDataPayloadWithInvalidRotatingDeviceIdLength[] = "153000FF0A001998AB7130E38B7E9A401CFE9F7B79AF18";
 constexpr char kAdditionalDataPayloadWithLongRotatingDeviceId[]          = "153000130A00191998AB7130E38B7E9A401CFE9F7B79AF18";
 constexpr char kAdditionalDataPayloadWithShortRotatingDeviceId[]         = "153000110A001998AB7130E38B7E9A401CFE9F7B7918";
 constexpr char kRotatingDeviceId[]                                       = "0A00D00561E77A68A9FD975057375B9283A8";
 constexpr char kShortRotatingDeviceId[]                                  = "0A001998AB7130E38B7E9A401CFE9F7B79";
 constexpr uint16_t kAdditionalDataPayloadLength                          = 51;
 #if CHIP_ENABLE_ROTATING_DEVICE_ID
 constexpr uint8_t kUniqueId[] = { 0x00, 0x11, 0x22, 0x33, 0x44, 0x55, 0x66, 0x77, 0x88, 0x99, 0xaa, 0xbb, 0xcc, 0xdd, 0xee, 0xff };
 constexpr char kAdditionalDataPayloadWithRotatingDeviceIdAndMaxLifetimeCounter[] = "15300012FFFF8BEA0C775F001981365D6362E1C0665A18";
 constexpr uint16_t kLifetimeCounter                                              = 10;
 constexpr uint16_t kShortRotatingIdLength                                        = 5;
 #endif // CHIP_ENABLE_ROTATING_DEVICE_ID

 CHIP_ERROR GenerateAdditionalDataPayload(AdditionalDataPayloadGeneratorParams & additionalDataPayloadParams,
                                          BitFlags<AdditionalDataFields> additionalDataFields, char * additionalDataPayloadOutput)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     chip::System::PacketBufferHandle bufferHandle;

     err = AdditionalDataPayloadGenerator().generateAdditionalDataPayload(additionalDataPayloadParams, bufferHandle,
                                                                          additionalDataFields);
     if (err == CHIP_NO_ERROR)
     {
         EXPECT_FALSE(bufferHandle.IsNull());
     }
     else
     {
         return err;
     }
     char output[kAdditionalDataPayloadLength];
     err = chip::Encoding::BytesToUppercaseHexString(bufferHandle->Start(), bufferHandle->DataLength(), output, ArraySize(output));

     if (err == CHIP_NO_ERROR)
     {
         memmove(additionalDataPayloadOutput, output, kAdditionalDataPayloadLength);
     }
     return err;
 }

 CHIP_ERROR ParseAdditionalDataPayload(const char * additionalDataPayload, size_t additionalDataPayloadLength,
                                       chip::SetupPayloadData::AdditionalDataPayload & outPayload)
 {
     if (additionalDataPayloadLength % 2 != 0)
     {
         return CHIP_ERROR_INVALID_STRING_LENGTH;
     }
     size_t additionalDataPayloadBytesLength = additionalDataPayloadLength / 2;
     std::unique_ptr<uint8_t[]> additionalDataPayloadBytes(new uint8_t[additionalDataPayloadBytesLength]);
     size_t bufferSize = chip::Encoding::HexToBytes(additionalDataPayload, additionalDataPayloadLength,
                                                    additionalDataPayloadBytes.get(), additionalDataPayloadBytesLength);
     return AdditionalDataPayloadParser(additionalDataPayloadBytes.get(), bufferSize).populatePayload(outPayload);
 }

 class TestAdditionalDataPayload : public ::testing::Test
 {
 public:
     static void SetUpTestSuite() { ASSERT_EQ(chip::Platform::MemoryInit(), CHIP_NO_ERROR); }
     static void TearDownTestSuite() { chip::Platform::MemoryShutdown(); }
 };

 TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithoutRotatingDeviceId)
 {
     BitFlags<AdditionalDataFields> additionalDataFields;
     char output[kAdditionalDataPayloadLength];
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;

     EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output), CHIP_NO_ERROR);
     EXPECT_STREQ(output, kAdditionalDataPayloadWithoutRotatingDeviceId);
 }

 #if CHIP_ENABLE_ROTATING_DEVICE_ID
 TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithRotatingDeviceId)
 {
     BitFlags<AdditionalDataFields> additionalDataFields;
     additionalDataFields.Set(AdditionalDataFields::RotatingDeviceId);
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
     additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = kLifetimeCounter;
     additionalDataPayloadParams.rotatingDeviceIdUniqueId        = ByteSpan(kUniqueId);

     char output[kAdditionalDataPayloadLength];
     EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output), CHIP_NO_ERROR);
     EXPECT_STREQ(output, kAdditionalDataPayloadWithRotatingDeviceId);
 }

 TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithRotatingDeviceIdAndMaxLifetimeCounter)
 {
     BitFlags<AdditionalDataFields> additionalDataFields;
     additionalDataFields.Set(AdditionalDataFields::RotatingDeviceId);
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
     additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = std::numeric_limits<uint16_t>::max();
     additionalDataPayloadParams.rotatingDeviceIdUniqueId        = ByteSpan(kUniqueId);

     char output[kAdditionalDataPayloadLength];
     EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output), CHIP_NO_ERROR);
     EXPECT_STREQ(output, kAdditionalDataPayloadWithRotatingDeviceIdAndMaxLifetimeCounter);
 }

 TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithRotatingDeviceIdWithNullInputs)
 {
     BitFlags<AdditionalDataFields> additionalDataFields;
     additionalDataFields.Set(AdditionalDataFields::RotatingDeviceId);
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;

     char output[kAdditionalDataPayloadLength];
     EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output),
               CHIP_ERROR_INVALID_ARGUMENT);
 }

 TEST_F(TestAdditionalDataPayload, TestGeneratingRotatingDeviceIdAsString)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     char rotatingDeviceIdHexBuffer[RotatingDeviceId::kHexMaxLength];
     size_t rotatingDeviceIdValueOutputSize = 0;
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
     additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = kLifetimeCounter;
     additionalDataPayloadParams.rotatingDeviceIdUniqueId        = ByteSpan(kUniqueId);
     err = AdditionalDataPayloadGenerator().generateRotatingDeviceIdAsHexString(
         additionalDataPayloadParams, rotatingDeviceIdHexBuffer, ArraySize(rotatingDeviceIdHexBuffer),
         rotatingDeviceIdValueOutputSize);
     EXPECT_EQ(err, CHIP_NO_ERROR);
     EXPECT_STREQ(rotatingDeviceIdHexBuffer, kRotatingDeviceId);
     // Parsing out the lifetime counter value
     long lifetimeCounter;
     char lifetimeCounterStr[3];
     Platform::CopyString(lifetimeCounterStr, rotatingDeviceIdHexBuffer);

     char * parseEnd;
     lifetimeCounter = strtol(lifetimeCounterStr, &parseEnd, 16);
     EXPECT_EQ(lifetimeCounter, kLifetimeCounter);
 }

 TEST_F(TestAdditionalDataPayload, TestGeneratingRotatingDeviceIdAsStringWithNullInputs)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     char rotatingDeviceIdHexBuffer[RotatingDeviceId::kHexMaxLength];
     size_t rotatingDeviceIdValueOutputSize = 0;
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
     additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = 0;
     additionalDataPayloadParams.rotatingDeviceIdUniqueId        = ByteSpan();
     err = AdditionalDataPayloadGenerator().generateRotatingDeviceIdAsHexString(
         additionalDataPayloadParams, rotatingDeviceIdHexBuffer, ArraySize(rotatingDeviceIdHexBuffer),
         rotatingDeviceIdValueOutputSize);
     EXPECT_EQ(err, CHIP_ERROR_INVALID_ARGUMENT);
 }

 TEST_F(TestAdditionalDataPayload, TestGeneratingRotatingDeviceIdWithSmallBuffer)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     char rotatingDeviceIdHexBuffer[kShortRotatingIdLength];
     size_t rotatingDeviceIdValueOutputSize = 0;
     AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
     additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = kLifetimeCounter;
     additionalDataPayloadParams.rotatingDeviceIdUniqueId        = ByteSpan(kUniqueId);
     err = AdditionalDataPayloadGenerator().generateRotatingDeviceIdAsHexString(
         additionalDataPayloadParams, rotatingDeviceIdHexBuffer, ArraySize(rotatingDeviceIdHexBuffer),
         rotatingDeviceIdValueOutputSize);
     EXPECT_EQ(err, CHIP_ERROR_BUFFER_TOO_SMALL);
 }
 #endif // CHIP_ENABLE_ROTATING_DEVICE_ID

 TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithRotatingDeviceId)
 {
     chip::SetupPayloadData::AdditionalDataPayload resultPayload;
     EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithRotatingDeviceId,
                                          strlen(kAdditionalDataPayloadWithRotatingDeviceId), resultPayload),
               CHIP_NO_ERROR);
     EXPECT_STREQ(resultPayload.rotatingDeviceId.c_str(), kRotatingDeviceId);
 }

 TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithoutRotatingDeviceId)
 {
     chip::SetupPayloadData::AdditionalDataPayload resultPayload;
     EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithoutRotatingDeviceId,
                                          strlen(kAdditionalDataPayloadWithoutRotatingDeviceId), resultPayload),
               CHIP_NO_ERROR);
     EXPECT_STREQ(resultPayload.rotatingDeviceId.c_str(), "");
 }

 TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithInvalidRotatingDeviceIdLength)
 {
     chip::SetupPayloadData::AdditionalDataPayload resultPayload;
     EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithInvalidRotatingDeviceIdLength,
                                          strlen(kAdditionalDataPayloadWithInvalidRotatingDeviceIdLength), resultPayload),
               CHIP_ERROR_TLV_UNDERRUN);
 }

 TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithLongRotatingDeviceId)
 {
     chip::SetupPayloadData::AdditionalDataPayload resultPayload;
     EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithLongRotatingDeviceId,
                                          strlen(kAdditionalDataPayloadWithLongRotatingDeviceId), resultPayload),
               CHIP_ERROR_INVALID_STRING_LENGTH);
 }

 TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithShortRotatingDeviceId)
 {
     chip::SetupPayloadData::AdditionalDataPayload resultPayload;
     EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithShortRotatingDeviceId,
                                          strlen(kAdditionalDataPayloadWithShortRotatingDeviceId), resultPayload),
               CHIP_NO_ERROR);
     EXPECT_STREQ(resultPayload.rotatingDeviceId.c_str(), kShortRotatingDeviceId);
 }

 } // namespace
	/*
	*
	* Copyright (c) 2021-2022 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.
	*/

	/**
	* @file
	* This file implements a unit test suite for the additional payload generation
	* code functionality.
	*
	*/

	#include <math.h>
	#include <memory>
	#include <stdio.h>

	#include <gtest/gtest.h>

	#include <lib/support/BytesToHex.h>
	#include <lib/support/CHIPMem.h>
	#include <lib/support/CHIPMemString.h>
	#include <lib/support/CHIPPlatformMemory.h>
	#include <lib/support/verhoeff/Verhoeff.h>
	#include <setup_payload/AdditionalDataPayloadGenerator.h>
	#include <setup_payload/AdditionalDataPayloadParser.h>
	#include <setup_payload/SetupPayload.h>
	#include <system/SystemPacketBuffer.h>

	using namespace chip;

	namespace {

	constexpr char kAdditionalDataPayloadWithoutRotatingDeviceId[] = "1518";
	constexpr char kAdditionalDataPayloadWithRotatingDeviceId[] = "153000120A00D00561E77A68A9FD975057375B9283A818";
	constexpr char kAdditionalDataPayloadWithInvalidRotatingDeviceIdLength[] = "153000FF0A001998AB7130E38B7E9A401CFE9F7B79AF18";
	constexpr char kAdditionalDataPayloadWithLongRotatingDeviceId[] = "153000130A00191998AB7130E38B7E9A401CFE9F7B79AF18";
	constexpr char kAdditionalDataPayloadWithShortRotatingDeviceId[] = "153000110A001998AB7130E38B7E9A401CFE9F7B7918";
	constexpr char kRotatingDeviceId[] = "0A00D00561E77A68A9FD975057375B9283A8";
	constexpr char kShortRotatingDeviceId[] = "0A001998AB7130E38B7E9A401CFE9F7B79";
	constexpr uint16_t kAdditionalDataPayloadLength = 51;
	#if CHIP_ENABLE_ROTATING_DEVICE_ID
	constexpr uint8_t kUniqueId[] = { 0x00, 0x11, 0x22, 0x33, 0x44, 0x55, 0x66, 0x77, 0x88, 0x99, 0xaa, 0xbb, 0xcc, 0xdd, 0xee, 0xff };
	constexpr char kAdditionalDataPayloadWithRotatingDeviceIdAndMaxLifetimeCounter[] = "15300012FFFF8BEA0C775F001981365D6362E1C0665A18";
	constexpr uint16_t kLifetimeCounter = 10;
	constexpr uint16_t kShortRotatingIdLength = 5;
	#endif // CHIP_ENABLE_ROTATING_DEVICE_ID

	CHIP_ERROR GenerateAdditionalDataPayload(AdditionalDataPayloadGeneratorParams & additionalDataPayloadParams,
	BitFlags<AdditionalDataFields> additionalDataFields, char * additionalDataPayloadOutput)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	chip::System::PacketBufferHandle bufferHandle;

	err = AdditionalDataPayloadGenerator().generateAdditionalDataPayload(additionalDataPayloadParams, bufferHandle,
	additionalDataFields);
	if (err == CHIP_NO_ERROR)
	{
	EXPECT_FALSE(bufferHandle.IsNull());
	}
	else
	{
	return err;
	}
	char output[kAdditionalDataPayloadLength];
	err = chip::Encoding::BytesToUppercaseHexString(bufferHandle->Start(), bufferHandle->DataLength(), output, ArraySize(output));

	if (err == CHIP_NO_ERROR)
	{
	memmove(additionalDataPayloadOutput, output, kAdditionalDataPayloadLength);
	}
	return err;
	}

	CHIP_ERROR ParseAdditionalDataPayload(const char * additionalDataPayload, size_t additionalDataPayloadLength,
	chip::SetupPayloadData::AdditionalDataPayload & outPayload)
	{
	if (additionalDataPayloadLength % 2 != 0)
	{
	return CHIP_ERROR_INVALID_STRING_LENGTH;
	}
	size_t additionalDataPayloadBytesLength = additionalDataPayloadLength / 2;
	std::unique_ptr<uint8_t[]> additionalDataPayloadBytes(new uint8_t[additionalDataPayloadBytesLength]);
	size_t bufferSize = chip::Encoding::HexToBytes(additionalDataPayload, additionalDataPayloadLength,
	additionalDataPayloadBytes.get(), additionalDataPayloadBytesLength);
	return AdditionalDataPayloadParser(additionalDataPayloadBytes.get(), bufferSize).populatePayload(outPayload);
	}

	class TestAdditionalDataPayload : public ::testing::Test
	{
	public:
	static void SetUpTestSuite() { ASSERT_EQ(chip::Platform::MemoryInit(), CHIP_NO_ERROR); }
	static void TearDownTestSuite() { chip::Platform::MemoryShutdown(); }
	};

	TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithoutRotatingDeviceId)
	{
	BitFlags<AdditionalDataFields> additionalDataFields;
	char output[kAdditionalDataPayloadLength];
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;

	EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output), CHIP_NO_ERROR);
	EXPECT_STREQ(output, kAdditionalDataPayloadWithoutRotatingDeviceId);
	}

	#if CHIP_ENABLE_ROTATING_DEVICE_ID
	TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithRotatingDeviceId)
	{
	BitFlags<AdditionalDataFields> additionalDataFields;
	additionalDataFields.Set(AdditionalDataFields::RotatingDeviceId);
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
	additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = kLifetimeCounter;
	additionalDataPayloadParams.rotatingDeviceIdUniqueId = ByteSpan(kUniqueId);

	char output[kAdditionalDataPayloadLength];
	EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output), CHIP_NO_ERROR);
	EXPECT_STREQ(output, kAdditionalDataPayloadWithRotatingDeviceId);
	}

	TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithRotatingDeviceIdAndMaxLifetimeCounter)
	{
	BitFlags<AdditionalDataFields> additionalDataFields;
	additionalDataFields.Set(AdditionalDataFields::RotatingDeviceId);
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
	additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = std::numeric_limits<uint16_t>::max();
	additionalDataPayloadParams.rotatingDeviceIdUniqueId = ByteSpan(kUniqueId);

	char output[kAdditionalDataPayloadLength];
	EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output), CHIP_NO_ERROR);
	EXPECT_STREQ(output, kAdditionalDataPayloadWithRotatingDeviceIdAndMaxLifetimeCounter);
	}

	TEST_F(TestAdditionalDataPayload, TestGeneratingAdditionalDataPayloadWithRotatingDeviceIdWithNullInputs)
	{
	BitFlags<AdditionalDataFields> additionalDataFields;
	additionalDataFields.Set(AdditionalDataFields::RotatingDeviceId);
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;

	char output[kAdditionalDataPayloadLength];
	EXPECT_EQ(GenerateAdditionalDataPayload(additionalDataPayloadParams, additionalDataFields, output),
	CHIP_ERROR_INVALID_ARGUMENT);
	}

	TEST_F(TestAdditionalDataPayload, TestGeneratingRotatingDeviceIdAsString)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	char rotatingDeviceIdHexBuffer[RotatingDeviceId::kHexMaxLength];
	size_t rotatingDeviceIdValueOutputSize = 0;
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
	additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = kLifetimeCounter;
	additionalDataPayloadParams.rotatingDeviceIdUniqueId = ByteSpan(kUniqueId);
	err = AdditionalDataPayloadGenerator().generateRotatingDeviceIdAsHexString(
	additionalDataPayloadParams, rotatingDeviceIdHexBuffer, ArraySize(rotatingDeviceIdHexBuffer),
	rotatingDeviceIdValueOutputSize);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	EXPECT_STREQ(rotatingDeviceIdHexBuffer, kRotatingDeviceId);
	// Parsing out the lifetime counter value
	long lifetimeCounter;
	char lifetimeCounterStr[3];
	Platform::CopyString(lifetimeCounterStr, rotatingDeviceIdHexBuffer);

	char * parseEnd;
	lifetimeCounter = strtol(lifetimeCounterStr, &parseEnd, 16);
	EXPECT_EQ(lifetimeCounter, kLifetimeCounter);
	}

	TEST_F(TestAdditionalDataPayload, TestGeneratingRotatingDeviceIdAsStringWithNullInputs)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	char rotatingDeviceIdHexBuffer[RotatingDeviceId::kHexMaxLength];
	size_t rotatingDeviceIdValueOutputSize = 0;
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
	additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = 0;
	additionalDataPayloadParams.rotatingDeviceIdUniqueId = ByteSpan();
	err = AdditionalDataPayloadGenerator().generateRotatingDeviceIdAsHexString(
	additionalDataPayloadParams, rotatingDeviceIdHexBuffer, ArraySize(rotatingDeviceIdHexBuffer),
	rotatingDeviceIdValueOutputSize);
	EXPECT_EQ(err, CHIP_ERROR_INVALID_ARGUMENT);
	}

	TEST_F(TestAdditionalDataPayload, TestGeneratingRotatingDeviceIdWithSmallBuffer)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	char rotatingDeviceIdHexBuffer[kShortRotatingIdLength];
	size_t rotatingDeviceIdValueOutputSize = 0;
	AdditionalDataPayloadGeneratorParams additionalDataPayloadParams;
	additionalDataPayloadParams.rotatingDeviceIdLifetimeCounter = kLifetimeCounter;
	additionalDataPayloadParams.rotatingDeviceIdUniqueId = ByteSpan(kUniqueId);
	err = AdditionalDataPayloadGenerator().generateRotatingDeviceIdAsHexString(
	additionalDataPayloadParams, rotatingDeviceIdHexBuffer, ArraySize(rotatingDeviceIdHexBuffer),
	rotatingDeviceIdValueOutputSize);
	EXPECT_EQ(err, CHIP_ERROR_BUFFER_TOO_SMALL);
	}
	#endif // CHIP_ENABLE_ROTATING_DEVICE_ID

	TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithRotatingDeviceId)
	{
	chip::SetupPayloadData::AdditionalDataPayload resultPayload;
	EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithRotatingDeviceId,
	strlen(kAdditionalDataPayloadWithRotatingDeviceId), resultPayload),
	CHIP_NO_ERROR);
	EXPECT_STREQ(resultPayload.rotatingDeviceId.c_str(), kRotatingDeviceId);
	}

	TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithoutRotatingDeviceId)
	{
	chip::SetupPayloadData::AdditionalDataPayload resultPayload;
	EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithoutRotatingDeviceId,
	strlen(kAdditionalDataPayloadWithoutRotatingDeviceId), resultPayload),
	CHIP_NO_ERROR);
	EXPECT_STREQ(resultPayload.rotatingDeviceId.c_str(), "");
	}

	TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithInvalidRotatingDeviceIdLength)
	{
	chip::SetupPayloadData::AdditionalDataPayload resultPayload;
	EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithInvalidRotatingDeviceIdLength,
	strlen(kAdditionalDataPayloadWithInvalidRotatingDeviceIdLength), resultPayload),
	CHIP_ERROR_TLV_UNDERRUN);
	}

	TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithLongRotatingDeviceId)
	{
	chip::SetupPayloadData::AdditionalDataPayload resultPayload;
	EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithLongRotatingDeviceId,
	strlen(kAdditionalDataPayloadWithLongRotatingDeviceId), resultPayload),
	CHIP_ERROR_INVALID_STRING_LENGTH);
	}

	TEST_F(TestAdditionalDataPayload, TestParsingAdditionalDataPayloadWithShortRotatingDeviceId)
	{
	chip::SetupPayloadData::AdditionalDataPayload resultPayload;
	EXPECT_EQ(ParseAdditionalDataPayload(kAdditionalDataPayloadWithShortRotatingDeviceId,
	strlen(kAdditionalDataPayloadWithShortRotatingDeviceId), resultPayload),
	CHIP_NO_ERROR);
	EXPECT_STREQ(resultPayload.rotatingDeviceId.c_str(), kShortRotatingDeviceId);
	}

	} // namespace