src/platform/tests/TestConfigurationMgr.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2020-2022 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 Configuration Manager
  *      code functionality.
  *
  */

 #include <inttypes.h>
 #include <stdarg.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>

 #include <gtest/gtest.h>
 #include <lib/support/CHIPMem.h>
 #include <lib/support/CodeUtils.h>

 #include <platform/BuildTime.h>
 #include <platform/CHIPDeviceLayer.h>
 #include <platform/DeviceInstanceInfoProvider.h>

 using namespace chip;
 using namespace chip::Logging;
 using namespace chip::Inet;
 using namespace chip::DeviceLayer;

 namespace {

 // =================================
 //      Unit tests
 // =================================

 struct TestConfigurationMgr : ::testing::Test
 {
     static void SetUpTestSuite()
     {
         // ConfigurationManager is initialized from PlatformManager indirectly
         CHIP_ERROR err = chip::Platform::MemoryInit();
         EXPECT_EQ(err, CHIP_NO_ERROR);
         err = PlatformMgr().InitChipStack();
         EXPECT_EQ(err, CHIP_NO_ERROR);
     }

     static void TearDownTestSuite()
     {
         PlatformMgr().Shutdown();
         chip::Platform::MemoryShutdown();
     }
 };

 TEST_F(TestConfigurationMgr, RunUnitTest)
 {
 #if CHIP_DEVICE_LAYER_TARGET_OPEN_IOT_SDK
     // TODO: Fix RunUnitTests() for Open IOT SDK.
     // Previously, TestPlatformMgr_RunUnitTest was only run if !NDEBUG while the Open IOT SDK
     // test runner was built with NDEBUG set.
     return;
 #endif

     ConfigurationMgr().RunUnitTests();
 }

 TEST_F(TestConfigurationMgr, SerialNumber)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;

     char buf[64];
     const char * serialNumber = "89051AAZZ236";

     err = ConfigurationMgr().StoreSerialNumber(serialNumber, strlen(serialNumber));
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = GetDeviceInstanceInfoProvider()->GetSerialNumber(buf, 64);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(strlen(buf), 12u);
     EXPECT_STREQ(buf, serialNumber);

     err = ConfigurationMgr().StoreSerialNumber(serialNumber, 5);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = GetDeviceInstanceInfoProvider()->GetSerialNumber(buf, 64);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(strlen(buf), 5u);
     EXPECT_STREQ(buf, "89051");
 }

 TEST_F(TestConfigurationMgr, UniqueId)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;

     char buf[64];
     const char * uniqueId = "67MXAZ012RT8UE";

     err = ConfigurationMgr().StoreUniqueId(uniqueId, strlen(uniqueId));
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = ConfigurationMgr().GetUniqueId(buf, 64);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(strlen(buf), 14u);
     EXPECT_STREQ(buf, uniqueId);

     err = ConfigurationMgr().StoreUniqueId(uniqueId, 7);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = ConfigurationMgr().GetUniqueId(buf, 64);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(strlen(buf), 7u);
     EXPECT_STREQ(buf, "67MXAZ0");
 }

 TEST_F(TestConfigurationMgr, ManufacturingDate)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;

     const char * mfgDate = "2008/09/20";
     uint16_t year;
     uint8_t month;
     uint8_t dayOfMonth;

     err = ConfigurationMgr().StoreManufacturingDate(mfgDate, strlen(mfgDate));
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = GetDeviceInstanceInfoProvider()->GetManufacturingDate(year, month, dayOfMonth);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(year, 2008);
     EXPECT_EQ(month, 9);
     EXPECT_EQ(dayOfMonth, 20);
 }

 TEST_F(TestConfigurationMgr, HardwareVersion)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     uint16_t hardwareVer;

     err = ConfigurationMgr().StoreHardwareVersion(1234);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = GetDeviceInstanceInfoProvider()->GetHardwareVersion(hardwareVer);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(hardwareVer, 1234);
 }

 static int SnprintfBuildDate(char * s, size_t n, uint16_t year, uint8_t month, uint8_t day)
 {
     // Print the calendar date to a human readable string as would
     // given from the __DATE__ macro.
     const char * monthString = nullptr;
     switch (month)
     {
     case 1:
         monthString = "Jan";
         break;
     case 2:
         monthString = "Feb";
         break;
     case 3:
         monthString = "Mar";
         break;
     case 4:
         monthString = "Apr";
         break;
     case 5:
         monthString = "May";
         break;
     case 6:
         monthString = "Jun";
         break;
     case 7:
         monthString = "Jul";
         break;
     case 8:
         monthString = "Aug";
         break;
     case 9:
         monthString = "Sep";
         break;
     case 10:
         monthString = "Oct";
         break;
     case 11:
         monthString = "Nov";
         break;
     case 12:
         monthString = "Dec";
         break;
     }
     if (monthString == nullptr)
     {
         return -1;
     }
     return snprintf(s, n, "%s %2u %u", monthString, day, year);
 }

 static int SnprintfBuildDate(char * s, size_t n, System::Clock::Seconds32 chipEpochBuildTime)
 {
     // Convert to a calendar date-time.
     uint16_t year;
     uint8_t month;
     uint8_t day;
     uint8_t hour;
     uint8_t minute;
     uint8_t second;
     ChipEpochToCalendarTime(chipEpochBuildTime.count(), year, month, day, hour, minute, second);
     return SnprintfBuildDate(s, n, year, month, day);
 }

 static int SnprintfBuildTimeOfDay(char * s, size_t n, uint8_t hour, uint8_t minute, uint8_t second)
 {
     // Print the time of day to a human readable string as would
     // given from the __TIME__ macro.
     return snprintf(s, n, "%02u:%02u:%02u", hour, minute, second);
 }

 static int SnprintfBuildTimeOfDay(char * s, size_t n, System::Clock::Seconds32 chipEpochBuildTime)
 {
     // Convert to a calendar date-time.
     uint16_t year;
     uint8_t month;
     uint8_t day;
     uint8_t hour;
     uint8_t minute;
     uint8_t second;
     ChipEpochToCalendarTime(chipEpochBuildTime.count(), year, month, day, hour, minute, second);
     return SnprintfBuildTimeOfDay(s, n, hour, minute, second);
 }

 TEST_F(TestConfigurationMgr, FirmwareBuildTime)
 {
     // Read the firmware build time from the configuration manager.
     // This is referenced to the CHIP epoch.
     System::Clock::Seconds32 chipEpochTime;
     EXPECT_EQ(ConfigurationMgr().GetFirmwareBuildChipEpochTime(chipEpochTime), CHIP_NO_ERROR);

     // Override the hard-coded build time with the setter and verify operation.
     System::Clock::Seconds32 overrideValue = System::Clock::Seconds32(rand());
     EXPECT_EQ(ConfigurationMgr().SetFirmwareBuildChipEpochTime(overrideValue), CHIP_NO_ERROR);
     EXPECT_EQ(ConfigurationMgr().GetFirmwareBuildChipEpochTime(chipEpochTime), CHIP_NO_ERROR);
     EXPECT_EQ(overrideValue, chipEpochTime);

     // Verify that the BuildTime.h parser can parse current CHIP_DEVICE_CONFIG_FIRMWARE_BUILD_DATE / TIME.
     do
     {
         const char * date      = CHIP_DEVICE_CONFIG_FIRMWARE_BUILD_DATE;
         const char * timeOfDay = CHIP_DEVICE_CONFIG_FIRMWARE_BUILD_TIME;

         // Check that strings look good.
         EXPECT_FALSE(BUILD_DATE_IS_BAD(date));
         EXPECT_FALSE(BUILD_TIME_IS_BAD(timeOfDay));
         if (BUILD_DATE_IS_BAD(date) || BUILD_TIME_IS_BAD(timeOfDay))
         {
             break;
         }

         // Parse.
         uint16_t year  = COMPUTE_BUILD_YEAR(date);
         uint8_t month  = COMPUTE_BUILD_MONTH(date);
         uint8_t day    = COMPUTE_BUILD_DAY(date);
         uint8_t hour   = COMPUTE_BUILD_HOUR(timeOfDay);
         uint8_t minute = COMPUTE_BUILD_MIN(timeOfDay);
         uint8_t second = COMPUTE_BUILD_SEC(timeOfDay);

         // Print the date to a string as would be given by the __DATE__ macro.
         char parsedDate[14] = { 0 }; // strlen("Jan 000 00000") == 13
         {
             int printed;
             printed = SnprintfBuildDate(parsedDate, sizeof(parsedDate), year, month, day);
             EXPECT_GT(printed, 0);
             EXPECT_LT(printed, static_cast<int>(sizeof(parsedDate)));
         }

         // Print the time of day to a straing as would be given by the __TIME__ macro.
         char parsedTimeOfDay[12] = { 0 }; // strlen("000:000:000") == 11
         {
             int printed;
             printed = SnprintfBuildTimeOfDay(parsedTimeOfDay, sizeof(parsedTimeOfDay), hour, minute, second);
             EXPECT_GT(printed, 0);
             EXPECT_LT(printed, static_cast<int>(sizeof(parsedTimeOfDay)));
         }

         // Verify match.
         EXPECT_STREQ(date, parsedDate);
         EXPECT_STREQ(timeOfDay, parsedTimeOfDay);
     } while (false);

     // Generate random chip epoch times and verify that our BuildTime.h parser
     // macros also work for these.
     for (int i = 0; i < 10000; ++i)
     {
         char date[14]      = { 0 }; // strlen("Jan 000 00000") == 13
         char timeOfDay[12] = { 0 }; // strlen("000:000:000") == 11

         chipEpochTime = System::Clock::Seconds32(rand());

         // rand() will only give us [0, 0x7FFFFFFF].  Give us coverage for
         // times in the upper half of the chip epoch time range as well.
         chipEpochTime = i % 2 ? chipEpochTime : System::Clock::Seconds32(chipEpochTime.count() | 0x80000000);

         // Print the date to a string as would be given by the __DATE__ macro.
         {
             int printed;
             printed = SnprintfBuildDate(date, sizeof(date), chipEpochTime);
             EXPECT_GT(printed, 0);
             EXPECT_LT(printed, static_cast<int>(sizeof(date)));
         }

         // Print the time of day to a straing as would be given by the __TIME__ macro.
         {
             int printed;
             printed = SnprintfBuildTimeOfDay(timeOfDay, sizeof(timeOfDay), chipEpochTime);
             EXPECT_GT(printed, 0);
             EXPECT_LT(printed, static_cast<int>(sizeof(timeOfDay)));
         }

         // Check that strings look good.
         EXPECT_FALSE(BUILD_DATE_IS_BAD(date));
         EXPECT_FALSE(BUILD_TIME_IS_BAD(timeOfDay));
         if (BUILD_DATE_IS_BAD(date) || BUILD_TIME_IS_BAD(timeOfDay))
         {
             continue;
         }

         // Convert from chip epoch seconds to calendar time.
         uint16_t year;
         uint8_t month;
         uint8_t day;
         uint8_t hour;
         uint8_t minute;
         uint8_t second;
         ChipEpochToCalendarTime(chipEpochTime.count(), year, month, day, hour, minute, second);

         // Verify that our BuildTime.h macros can correctly parse the date / time strings.
         EXPECT_EQ(year, COMPUTE_BUILD_YEAR(date));
         EXPECT_EQ(month, COMPUTE_BUILD_MONTH(date));
         EXPECT_EQ(day, COMPUTE_BUILD_DAY(date));
         EXPECT_EQ(hour, COMPUTE_BUILD_HOUR(timeOfDay));
         EXPECT_EQ(minute, COMPUTE_BUILD_MIN(timeOfDay));
         EXPECT_EQ(second, COMPUTE_BUILD_SEC(timeOfDay));
     }
 }

 TEST_F(TestConfigurationMgr, CountryCode)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;

     char buf[8];
     size_t countryCodeLen    = 0;
     const char * countryCode = "US";

     err = ConfigurationMgr().StoreCountryCode(countryCode, strlen(countryCode));
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = ConfigurationMgr().GetCountryCode(buf, 8, countryCodeLen);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     EXPECT_EQ(countryCodeLen, strlen(countryCode));
     EXPECT_STREQ(buf, countryCode);
 }

 TEST_F(TestConfigurationMgr, GetPrimaryMACAddress)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     uint8_t macBuffer8Bytes[8];
     uint8_t macBuffer6Bytes[6];
     MutableByteSpan mac8Bytes(macBuffer8Bytes);
     MutableByteSpan mac6Bytes(macBuffer6Bytes);

     err = ConfigurationMgr().GetPrimaryMACAddress(mac8Bytes);
     if (mac8Bytes.size() != ConfigurationManager::kPrimaryMACAddressLength)
     {
         EXPECT_EQ(err, CHIP_ERROR_INVALID_ARGUMENT);
     }

     err = ConfigurationMgr().GetPrimaryMACAddress(mac6Bytes);
     if (mac6Bytes.size() != ConfigurationManager::kPrimaryMACAddressLength)
     {
         EXPECT_EQ(err, CHIP_ERROR_INVALID_ARGUMENT);
     }

     // NOTICE for above:
     //   no validation for CHIP_NO_ERROR:
     //    - there is no guarantee in CI that a valid IP address exists,
     //      expecially if running in emulators (zephyr and qemu)
 }

 TEST_F(TestConfigurationMgr, GetFailSafeArmed)
 {
     CHIP_ERROR err     = CHIP_NO_ERROR;
     bool failSafeArmed = false;

     err = ConfigurationMgr().SetFailSafeArmed(true);
     EXPECT_EQ(err, CHIP_NO_ERROR);

     err = ConfigurationMgr().GetFailSafeArmed(failSafeArmed);
     EXPECT_EQ(err, CHIP_NO_ERROR);
     EXPECT_EQ(failSafeArmed, true);

     err = ConfigurationMgr().SetFailSafeArmed(false);
     EXPECT_EQ(err, CHIP_NO_ERROR);
 }

 TEST_F(TestConfigurationMgr, GetVendorName)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     char buf[64];

     err = GetDeviceInstanceInfoProvider()->GetVendorName(buf, 64);
     EXPECT_EQ(err, CHIP_NO_ERROR);
     EXPECT_GT(strlen(buf), 0u);
     EXPECT_LE(strlen(buf), ConfigurationManager::kMaxVendorNameLength);
 }

 TEST_F(TestConfigurationMgr, GetVendorId)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     uint16_t vendorId;

     err = GetDeviceInstanceInfoProvider()->GetVendorId(vendorId);
     EXPECT_EQ(err, CHIP_NO_ERROR);
     EXPECT_GE(vendorId, 0u);
     EXPECT_LE(vendorId, 0xfff4);
 }

 TEST_F(TestConfigurationMgr, GetProductName)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     char buf[64];

     err = GetDeviceInstanceInfoProvider()->GetProductName(buf, 64);
     EXPECT_EQ(err, CHIP_NO_ERROR);
     EXPECT_GT(strlen(buf), 0u);
     EXPECT_LE(strlen(buf), ConfigurationManager::kMaxProductNameLength);
 }

 TEST_F(TestConfigurationMgr, GetProductId)
 {
     CHIP_ERROR err = CHIP_NO_ERROR;
     uint16_t productId;

     err = GetDeviceInstanceInfoProvider()->GetProductId(productId);
     EXPECT_EQ(err, CHIP_NO_ERROR);
     EXPECT_GE(productId, 1u);
     EXPECT_LE(productId, 0xffff);
 }

 } // namespace
	/*
	*
	* Copyright (c) 2020-2022 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 Configuration Manager
	* code functionality.
	*
	*/

	#include <inttypes.h>
	#include <stdarg.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>

	#include <gtest/gtest.h>
	#include <lib/support/CHIPMem.h>
	#include <lib/support/CodeUtils.h>

	#include <platform/BuildTime.h>
	#include <platform/CHIPDeviceLayer.h>
	#include <platform/DeviceInstanceInfoProvider.h>

	using namespace chip;
	using namespace chip::Logging;
	using namespace chip::Inet;
	using namespace chip::DeviceLayer;

	namespace {

	// =================================
	// Unit tests
	// =================================

	struct TestConfigurationMgr : ::testing::Test
	{
	static void SetUpTestSuite()
	{
	// ConfigurationManager is initialized from PlatformManager indirectly
	CHIP_ERROR err = chip::Platform::MemoryInit();
	EXPECT_EQ(err, CHIP_NO_ERROR);
	err = PlatformMgr().InitChipStack();
	EXPECT_EQ(err, CHIP_NO_ERROR);
	}

	static void TearDownTestSuite()
	{
	PlatformMgr().Shutdown();
	chip::Platform::MemoryShutdown();
	}
	};

	TEST_F(TestConfigurationMgr, RunUnitTest)
	{
	#if CHIP_DEVICE_LAYER_TARGET_OPEN_IOT_SDK
	// TODO: Fix RunUnitTests() for Open IOT SDK.
	// Previously, TestPlatformMgr_RunUnitTest was only run if !NDEBUG while the Open IOT SDK
	// test runner was built with NDEBUG set.
	return;
	#endif

	ConfigurationMgr().RunUnitTests();
	}

	TEST_F(TestConfigurationMgr, SerialNumber)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;

	char buf[64];
	const char * serialNumber = "89051AAZZ236";

	err = ConfigurationMgr().StoreSerialNumber(serialNumber, strlen(serialNumber));
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = GetDeviceInstanceInfoProvider()->GetSerialNumber(buf, 64);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(strlen(buf), 12u);
	EXPECT_STREQ(buf, serialNumber);

	err = ConfigurationMgr().StoreSerialNumber(serialNumber, 5);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = GetDeviceInstanceInfoProvider()->GetSerialNumber(buf, 64);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(strlen(buf), 5u);
	EXPECT_STREQ(buf, "89051");
	}

	TEST_F(TestConfigurationMgr, UniqueId)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;

	char buf[64];
	const char * uniqueId = "67MXAZ012RT8UE";

	err = ConfigurationMgr().StoreUniqueId(uniqueId, strlen(uniqueId));
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = ConfigurationMgr().GetUniqueId(buf, 64);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(strlen(buf), 14u);
	EXPECT_STREQ(buf, uniqueId);

	err = ConfigurationMgr().StoreUniqueId(uniqueId, 7);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = ConfigurationMgr().GetUniqueId(buf, 64);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(strlen(buf), 7u);
	EXPECT_STREQ(buf, "67MXAZ0");
	}

	TEST_F(TestConfigurationMgr, ManufacturingDate)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;

	const char * mfgDate = "2008/09/20";
	uint16_t year;
	uint8_t month;
	uint8_t dayOfMonth;

	err = ConfigurationMgr().StoreManufacturingDate(mfgDate, strlen(mfgDate));
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = GetDeviceInstanceInfoProvider()->GetManufacturingDate(year, month, dayOfMonth);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(year, 2008);
	EXPECT_EQ(month, 9);
	EXPECT_EQ(dayOfMonth, 20);
	}

	TEST_F(TestConfigurationMgr, HardwareVersion)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	uint16_t hardwareVer;

	err = ConfigurationMgr().StoreHardwareVersion(1234);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = GetDeviceInstanceInfoProvider()->GetHardwareVersion(hardwareVer);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(hardwareVer, 1234);
	}

	static int SnprintfBuildDate(char * s, size_t n, uint16_t year, uint8_t month, uint8_t day)
	{
	// Print the calendar date to a human readable string as would
	// given from the __DATE__ macro.
	const char * monthString = nullptr;
	switch (month)
	{
	case 1:
	monthString = "Jan";
	break;
	case 2:
	monthString = "Feb";
	break;
	case 3:
	monthString = "Mar";
	break;
	case 4:
	monthString = "Apr";
	break;
	case 5:
	monthString = "May";
	break;
	case 6:
	monthString = "Jun";
	break;
	case 7:
	monthString = "Jul";
	break;
	case 8:
	monthString = "Aug";
	break;
	case 9:
	monthString = "Sep";
	break;
	case 10:
	monthString = "Oct";
	break;
	case 11:
	monthString = "Nov";
	break;
	case 12:
	monthString = "Dec";
	break;
	}
	if (monthString == nullptr)
	{
	return -1;
	}
	return snprintf(s, n, "%s %2u %u", monthString, day, year);
	}

	static int SnprintfBuildDate(char * s, size_t n, System::Clock::Seconds32 chipEpochBuildTime)
	{
	// Convert to a calendar date-time.
	uint16_t year;
	uint8_t month;
	uint8_t day;
	uint8_t hour;
	uint8_t minute;
	uint8_t second;
	ChipEpochToCalendarTime(chipEpochBuildTime.count(), year, month, day, hour, minute, second);
	return SnprintfBuildDate(s, n, year, month, day);
	}

	static int SnprintfBuildTimeOfDay(char * s, size_t n, uint8_t hour, uint8_t minute, uint8_t second)
	{
	// Print the time of day to a human readable string as would
	// given from the __TIME__ macro.
	return snprintf(s, n, "%02u:%02u:%02u", hour, minute, second);
	}

	static int SnprintfBuildTimeOfDay(char * s, size_t n, System::Clock::Seconds32 chipEpochBuildTime)
	{
	// Convert to a calendar date-time.
	uint16_t year;
	uint8_t month;
	uint8_t day;
	uint8_t hour;
	uint8_t minute;
	uint8_t second;
	ChipEpochToCalendarTime(chipEpochBuildTime.count(), year, month, day, hour, minute, second);
	return SnprintfBuildTimeOfDay(s, n, hour, minute, second);
	}

	TEST_F(TestConfigurationMgr, FirmwareBuildTime)
	{
	// Read the firmware build time from the configuration manager.
	// This is referenced to the CHIP epoch.
	System::Clock::Seconds32 chipEpochTime;
	EXPECT_EQ(ConfigurationMgr().GetFirmwareBuildChipEpochTime(chipEpochTime), CHIP_NO_ERROR);

	// Override the hard-coded build time with the setter and verify operation.
	System::Clock::Seconds32 overrideValue = System::Clock::Seconds32(rand());
	EXPECT_EQ(ConfigurationMgr().SetFirmwareBuildChipEpochTime(overrideValue), CHIP_NO_ERROR);
	EXPECT_EQ(ConfigurationMgr().GetFirmwareBuildChipEpochTime(chipEpochTime), CHIP_NO_ERROR);
	EXPECT_EQ(overrideValue, chipEpochTime);

	// Verify that the BuildTime.h parser can parse current CHIP_DEVICE_CONFIG_FIRMWARE_BUILD_DATE / TIME.
	do
	{
	const char * date = CHIP_DEVICE_CONFIG_FIRMWARE_BUILD_DATE;
	const char * timeOfDay = CHIP_DEVICE_CONFIG_FIRMWARE_BUILD_TIME;

	// Check that strings look good.
	EXPECT_FALSE(BUILD_DATE_IS_BAD(date));
	EXPECT_FALSE(BUILD_TIME_IS_BAD(timeOfDay));
	if (BUILD_DATE_IS_BAD(date) \|\| BUILD_TIME_IS_BAD(timeOfDay))
	{
	break;
	}

	// Parse.
	uint16_t year = COMPUTE_BUILD_YEAR(date);
	uint8_t month = COMPUTE_BUILD_MONTH(date);
	uint8_t day = COMPUTE_BUILD_DAY(date);
	uint8_t hour = COMPUTE_BUILD_HOUR(timeOfDay);
	uint8_t minute = COMPUTE_BUILD_MIN(timeOfDay);
	uint8_t second = COMPUTE_BUILD_SEC(timeOfDay);

	// Print the date to a string as would be given by the __DATE__ macro.
	char parsedDate[14] = { 0 }; // strlen("Jan 000 00000") == 13
	{
	int printed;
	printed = SnprintfBuildDate(parsedDate, sizeof(parsedDate), year, month, day);
	EXPECT_GT(printed, 0);
	EXPECT_LT(printed, static_cast<int>(sizeof(parsedDate)));
	}

	// Print the time of day to a straing as would be given by the __TIME__ macro.
	char parsedTimeOfDay[12] = { 0 }; // strlen("000:000:000") == 11
	{
	int printed;
	printed = SnprintfBuildTimeOfDay(parsedTimeOfDay, sizeof(parsedTimeOfDay), hour, minute, second);
	EXPECT_GT(printed, 0);
	EXPECT_LT(printed, static_cast<int>(sizeof(parsedTimeOfDay)));
	}

	// Verify match.
	EXPECT_STREQ(date, parsedDate);
	EXPECT_STREQ(timeOfDay, parsedTimeOfDay);
	} while (false);

	// Generate random chip epoch times and verify that our BuildTime.h parser
	// macros also work for these.
	for (int i = 0; i < 10000; ++i)
	{
	char date[14] = { 0 }; // strlen("Jan 000 00000") == 13
	char timeOfDay[12] = { 0 }; // strlen("000:000:000") == 11

	chipEpochTime = System::Clock::Seconds32(rand());

	// rand() will only give us [0, 0x7FFFFFFF]. Give us coverage for
	// times in the upper half of the chip epoch time range as well.
	chipEpochTime = i % 2 ? chipEpochTime : System::Clock::Seconds32(chipEpochTime.count() \| 0x80000000);

	// Print the date to a string as would be given by the __DATE__ macro.
	{
	int printed;
	printed = SnprintfBuildDate(date, sizeof(date), chipEpochTime);
	EXPECT_GT(printed, 0);
	EXPECT_LT(printed, static_cast<int>(sizeof(date)));
	}

	// Print the time of day to a straing as would be given by the __TIME__ macro.
	{
	int printed;
	printed = SnprintfBuildTimeOfDay(timeOfDay, sizeof(timeOfDay), chipEpochTime);
	EXPECT_GT(printed, 0);
	EXPECT_LT(printed, static_cast<int>(sizeof(timeOfDay)));
	}

	// Check that strings look good.
	EXPECT_FALSE(BUILD_DATE_IS_BAD(date));
	EXPECT_FALSE(BUILD_TIME_IS_BAD(timeOfDay));
	if (BUILD_DATE_IS_BAD(date) \|\| BUILD_TIME_IS_BAD(timeOfDay))
	{
	continue;
	}

	// Convert from chip epoch seconds to calendar time.
	uint16_t year;
	uint8_t month;
	uint8_t day;
	uint8_t hour;
	uint8_t minute;
	uint8_t second;
	ChipEpochToCalendarTime(chipEpochTime.count(), year, month, day, hour, minute, second);

	// Verify that our BuildTime.h macros can correctly parse the date / time strings.
	EXPECT_EQ(year, COMPUTE_BUILD_YEAR(date));
	EXPECT_EQ(month, COMPUTE_BUILD_MONTH(date));
	EXPECT_EQ(day, COMPUTE_BUILD_DAY(date));
	EXPECT_EQ(hour, COMPUTE_BUILD_HOUR(timeOfDay));
	EXPECT_EQ(minute, COMPUTE_BUILD_MIN(timeOfDay));
	EXPECT_EQ(second, COMPUTE_BUILD_SEC(timeOfDay));
	}
	}

	TEST_F(TestConfigurationMgr, CountryCode)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;

	char buf[8];
	size_t countryCodeLen = 0;
	const char * countryCode = "US";

	err = ConfigurationMgr().StoreCountryCode(countryCode, strlen(countryCode));
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = ConfigurationMgr().GetCountryCode(buf, 8, countryCodeLen);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	EXPECT_EQ(countryCodeLen, strlen(countryCode));
	EXPECT_STREQ(buf, countryCode);
	}

	TEST_F(TestConfigurationMgr, GetPrimaryMACAddress)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	uint8_t macBuffer8Bytes[8];
	uint8_t macBuffer6Bytes[6];
	MutableByteSpan mac8Bytes(macBuffer8Bytes);
	MutableByteSpan mac6Bytes(macBuffer6Bytes);

	err = ConfigurationMgr().GetPrimaryMACAddress(mac8Bytes);
	if (mac8Bytes.size() != ConfigurationManager::kPrimaryMACAddressLength)
	{
	EXPECT_EQ(err, CHIP_ERROR_INVALID_ARGUMENT);
	}

	err = ConfigurationMgr().GetPrimaryMACAddress(mac6Bytes);
	if (mac6Bytes.size() != ConfigurationManager::kPrimaryMACAddressLength)
	{
	EXPECT_EQ(err, CHIP_ERROR_INVALID_ARGUMENT);
	}

	// NOTICE for above:
	// no validation for CHIP_NO_ERROR:
	// - there is no guarantee in CI that a valid IP address exists,
	// expecially if running in emulators (zephyr and qemu)
	}

	TEST_F(TestConfigurationMgr, GetFailSafeArmed)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	bool failSafeArmed = false;

	err = ConfigurationMgr().SetFailSafeArmed(true);
	EXPECT_EQ(err, CHIP_NO_ERROR);

	err = ConfigurationMgr().GetFailSafeArmed(failSafeArmed);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	EXPECT_EQ(failSafeArmed, true);

	err = ConfigurationMgr().SetFailSafeArmed(false);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	}

	TEST_F(TestConfigurationMgr, GetVendorName)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	char buf[64];

	err = GetDeviceInstanceInfoProvider()->GetVendorName(buf, 64);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	EXPECT_GT(strlen(buf), 0u);
	EXPECT_LE(strlen(buf), ConfigurationManager::kMaxVendorNameLength);
	}

	TEST_F(TestConfigurationMgr, GetVendorId)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	uint16_t vendorId;

	err = GetDeviceInstanceInfoProvider()->GetVendorId(vendorId);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	EXPECT_GE(vendorId, 0u);
	EXPECT_LE(vendorId, 0xfff4);
	}

	TEST_F(TestConfigurationMgr, GetProductName)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	char buf[64];

	err = GetDeviceInstanceInfoProvider()->GetProductName(buf, 64);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	EXPECT_GT(strlen(buf), 0u);
	EXPECT_LE(strlen(buf), ConfigurationManager::kMaxProductNameLength);
	}

	TEST_F(TestConfigurationMgr, GetProductId)
	{
	CHIP_ERROR err = CHIP_NO_ERROR;
	uint16_t productId;

	err = GetDeviceInstanceInfoProvider()->GetProductId(productId);
	EXPECT_EQ(err, CHIP_NO_ERROR);
	EXPECT_GE(productId, 1u);
	EXPECT_LE(productId, 0xffff);
	}

	} // namespace