ipmi_fru_info_area.cpp - openbmc/phosphor-host-ipmid - Gitiles

 #include "ipmi_fru_info_area.hpp"

 #include <algorithm>
 #include <ctime>
 #include <iomanip>
 #include <map>
 #include <numeric>
 #include <phosphor-logging/elog.hpp>
 #include <sstream>

 namespace ipmi
 {
 namespace fru
 {
 using namespace phosphor::logging;

 // Property variables
 static constexpr auto partNumber = "Part Number";
 static constexpr auto serialNumber = "Serial Number";
 static constexpr auto manufacturer = "Manufacturer";
 static constexpr auto buildDate = "Mfg Date";
 static constexpr auto model = "Model";
 static constexpr auto prettyName = "Name";
 static constexpr auto version = "Version";
 static constexpr auto type = "Type";

 // Board info areas
 static constexpr auto board = "Board";
 static constexpr auto chassis = "Chassis";
 static constexpr auto product = "Product";

 static constexpr auto specVersion = 0x1;
 static constexpr auto recordUnitOfMeasurement = 0x8; // size in bytes
 static constexpr auto checksumSize = 0x1;            // size in bytes
 static constexpr auto recordNotPresent = 0x0;
 static constexpr auto englishLanguageCode = 0x0;
 static constexpr auto typeLengthByteNull = 0x0;
 static constexpr auto endOfCustomFields = 0xC1;
 static constexpr auto commonHeaderFormatSize = 0x8; // size in bytes
 static constexpr auto manufacturingDateSize = 0x3;
 static constexpr auto areaSizeOffset = 0x1;
 static constexpr uint8_t typeASCII = 0xC0;
 static constexpr auto maxRecordAttributeValue = 0x1F;

 static constexpr auto secs_from_1970_1996 = 820454400;
 static constexpr auto maxMfgDateValue = 0xFFFFFF; // 3 Byte length
 static constexpr auto secs_per_min = 60;
 static constexpr auto secsToMaxMfgdate =
     secs_from_1970_1996 + secs_per_min * maxMfgDateValue;

 // Minimum size of resulting FRU blob.
 // This is also the theoretical maximum size according to the spec:
 // 8 bytes header + 5 areas at 0xff*8 bytes max each
 // 8 + 5*0xff*8 = 0x27e0
 static constexpr auto fruMinSize = 0x27E0;

 // Value to use for padding.
 // Using 0xff to match the default (blank) value in a physical EEPROM.
 static constexpr auto fruPadValue = 0xff;

 /**
  * @brief Format Beginning of Individual IPMI FRU Data Section
  *
  * @param[in] langCode Language code
  * @param[in/out] data FRU area data
  */
 void preFormatProcessing(bool langCode, FruAreaData& data)
 {
     // Add id for version of FRU Info Storage Spec used
     data.emplace_back(specVersion);

     // Add Data Size - 0 as a placeholder, can edit after the data is finalized
     data.emplace_back(typeLengthByteNull);

     if (langCode)
     {
         data.emplace_back(englishLanguageCode);
     }
 }

 /**
  * @brief Append checksum of the FRU area data
  *
  * @param[in/out] data FRU area data
  */
 void appendDataChecksum(FruAreaData& data)
 {
     uint8_t checksumVal = std::accumulate(data.begin(), data.end(), 0);
     // Push the Zero checksum as the last byte of this data
     // This appears to be a simple summation of all the bytes
     data.emplace_back(-checksumVal);
 }

 /**
  * @brief Append padding bytes for the FRU area data
  *
  * @param[in/out] data FRU area data
  */
 void padData(FruAreaData& data)
 {
     uint8_t pad = (data.size() + checksumSize) % recordUnitOfMeasurement;
     if (pad)
     {
         data.resize((data.size() + recordUnitOfMeasurement - pad));
     }
 }

 /**
  * @brief Format End of Individual IPMI FRU Data Section
  *
  * @param[in/out] fruAreaData FRU area info data
  */
 void postFormatProcessing(FruAreaData& data)
 {
     // This area needs to be padded to a multiple of 8 bytes (after checksum)
     padData(data);

     // Set size of data info area
     data.at(areaSizeOffset) =
         (data.size() + checksumSize) / (recordUnitOfMeasurement);

     // Finally add area checksum
     appendDataChecksum(data);
 }

 /**
  * @brief Read chassis type property value from inventory and append to the FRU
  * area data.
  *
  * @param[in] propMap map of property values
  * @param[in,out] data FRU area data to be appended
  */
 void appendChassisType(const PropertyMap& propMap, FruAreaData& data)
 {
     uint8_t chassisType = 0; // Not specified
     auto iter = propMap.find(type);
     if (iter != propMap.end())
     {
         auto value = iter->second;
         try
         {
             chassisType = std::stoi(value);
         }
         catch (std::exception& e)
         {
             log<level::ERR>("Could not parse chassis type",
                             entry("VALUE=%s", value.c_str()),
                             entry("ERROR=%s", e.what()));
             chassisType = 0;
         }
     }
     data.emplace_back(chassisType);
 }

 /**
  * @brief Read property value from inventory and append to the FRU area data
  *
  * @param[in] key key to search for in the property inventory data
  * @param[in] propMap map of property values
  * @param[in,out] data FRU area data to be appended
  */
 void appendData(const Property& key, const PropertyMap& propMap,
                 FruAreaData& data)
 {
     auto iter = propMap.find(key);
     if (iter != propMap.end())
     {
         auto value = iter->second;
         // If starts with 0x or 0X remove them
         // ex: 0x123a just take 123a
         if ((value.compare(0, 2, "0x")) == 0 ||
             (value.compare(0, 2, "0X") == 0))
         {
             value.erase(0, 2);
         }

         // 5 bits for length
         // if length is greater then 31(2^5) bytes then trim the data to 31
         // bytess.
         auto valueLength = (value.length() > maxRecordAttributeValue)
                                ? maxRecordAttributeValue
                                : value.length();
         // 2 bits for type
         // Set the type to ascii
         uint8_t typeLength = valueLength | ipmi::fru::typeASCII;

         data.emplace_back(typeLength);
         std::copy(value.begin(), value.begin() + valueLength,
                   std::back_inserter(data));
     }
     else
     {
         // set 0 size
         data.emplace_back(typeLengthByteNull);
     }
 }

 std::time_t timeStringToRaw(const std::string& input)
 {
     // TODO: For non-US region timestamps, pass in region information for the
     // FRU to avoid the month/day swap.
     // 2017-02-24 - 13:59:00, Tue Nov 20 23:08:00 2018
     static const std::vector<std::string> patterns = {"%Y-%m-%d - %H:%M:%S",
                                                       "%a %b %d %H:%M:%S %Y"};

     std::tm time = {};

     for (const auto& pattern : patterns)
     {
         std::istringstream timeStream(input);
         timeStream >> std::get_time(&time, pattern.c_str());
         if (!timeStream.fail())
         {
             break;
         }
     }

     return std::mktime(&time);
 }

 /**
  * @brief Appends Build Date
  *
  * @param[in] propMap map of property values
  * @param[in/out] data FRU area to add the manfufacture date
  */
 void appendMfgDate(const PropertyMap& propMap, FruAreaData& data)
 {
     // MFG Date/Time
     auto iter = propMap.find(buildDate);
     if ((iter != propMap.end()) && (iter->second.size() > 0))
     {
         std::time_t raw = timeStringToRaw(iter->second);

         // From FRU Spec:
         // "Mfg. Date / Time
         // Number of minutes from 0:00 hrs 1/1/96.
         // LSbyte first (little endian)
         // 00_00_00h = unspecified."
         if ((raw >= secs_from_1970_1996) && (raw <= secsToMaxMfgdate))
         {
             raw -= secs_from_1970_1996;
             raw /= secs_per_min;
             uint8_t fru_raw[3];
             fru_raw[0] = raw & 0xFF;
             fru_raw[1] = (raw >> 8) & 0xFF;
             fru_raw[2] = (raw >> 16) & 0xFF;
             std::copy(fru_raw, fru_raw + 3, std::back_inserter(data));
             return;
         }
         std::fprintf(stderr, "MgfDate invalid date: %u secs since UNIX epoch\n",
                      static_cast<unsigned int>(raw));
     }
     // Blank date
     data.emplace_back(0);
     data.emplace_back(0);
     data.emplace_back(0);
 }

 /**
  * @brief Builds a section of the common header
  *
  * @param[in] infoAreaSize size of the FRU area to write
  * @param[in] offset Current offset for data in overall record
  * @param[in/out] data Common Header section data container
  */
 void buildCommonHeaderSection(const uint32_t& infoAreaSize, uint16_t& offset,
                               FruAreaData& data)
 {
     // Check if data for internal use section populated
     if (infoAreaSize == 0)
     {
         // Indicate record not present
         data.emplace_back(recordNotPresent);
     }
     else
     {
         // offset should be multiple of 8.
         auto remainder = offset % recordUnitOfMeasurement;
         // add the padding bytes in the offset so that offset
         // will be multiple of 8 byte.
         offset += (remainder > 0) ? recordUnitOfMeasurement - remainder : 0;
         // Place data to define offset to area data section
         data.emplace_back(offset / recordUnitOfMeasurement);

         offset += infoAreaSize;
     }
 }

 /**
  * @brief Builds the Chassis info area data section
  *
  * @param[in] propMap map of properties for chassis info area
  * @return FruAreaData container with chassis info area
  */
 FruAreaData buildChassisInfoArea(const PropertyMap& propMap)
 {
     FruAreaData fruAreaData;
     if (!propMap.empty())
     {
         // Set formatting data that goes at the beginning of the record
         preFormatProcessing(false, fruAreaData);

         // chassis type
         appendChassisType(propMap, fruAreaData);

         // Chasiss part number, in config.yaml it is configured as model
         appendData(model, propMap, fruAreaData);

         // Board serial number
         appendData(serialNumber, propMap, fruAreaData);

         // Indicate End of Custom Fields
         fruAreaData.emplace_back(endOfCustomFields);

         // Complete record data formatting
         postFormatProcessing(fruAreaData);
     }
     return fruAreaData;
 }

 /**
  * @brief Builds the Board info area data section
  *
  * @param[in] propMap map of properties for board info area
  * @return FruAreaData container with board info area
  */
 FruAreaData buildBoardInfoArea(const PropertyMap& propMap)
 {
     FruAreaData fruAreaData;
     if (!propMap.empty())
     {
         preFormatProcessing(true, fruAreaData);

         // Manufacturing date
         appendMfgDate(propMap, fruAreaData);

         // manufacturer
         appendData(manufacturer, propMap, fruAreaData);

         // Product name/Pretty name
         appendData(prettyName, propMap, fruAreaData);

         // Board serial number
         appendData(serialNumber, propMap, fruAreaData);

         // Board part number
         appendData(partNumber, propMap, fruAreaData);

         // FRU File ID - Empty
         fruAreaData.emplace_back(typeLengthByteNull);

         // Empty FRU File ID bytes
         fruAreaData.emplace_back(recordNotPresent);

         // End of custom fields
         fruAreaData.emplace_back(endOfCustomFields);

         postFormatProcessing(fruAreaData);
     }
     return fruAreaData;
 }

 /**
  * @brief Builds the Product info area data section
  *
  * @param[in] propMap map of FRU properties for Board info area
  * @return FruAreaData container with product info area data
  */
 FruAreaData buildProductInfoArea(const PropertyMap& propMap)
 {
     FruAreaData fruAreaData;
     if (!propMap.empty())
     {
         // Set formatting data that goes at the beginning of the record
         preFormatProcessing(true, fruAreaData);

         // manufacturer
         appendData(manufacturer, propMap, fruAreaData);

         // Product name/Pretty name
         appendData(prettyName, propMap, fruAreaData);

         // Product part/model number
         appendData(model, propMap, fruAreaData);

         // Product version
         appendData(version, propMap, fruAreaData);

         // Serial Number
         appendData(serialNumber, propMap, fruAreaData);

         // Add Asset Tag
         fruAreaData.emplace_back(recordNotPresent);

         // FRU File ID - Empty
         fruAreaData.emplace_back(typeLengthByteNull);

         // Empty FRU File ID bytes
         fruAreaData.emplace_back(recordNotPresent);

         // End of custom fields
         fruAreaData.emplace_back(endOfCustomFields);

         postFormatProcessing(fruAreaData);
     }
     return fruAreaData;
 }

 FruAreaData buildFruAreaData(const FruInventoryData& inventory)
 {
     FruAreaData combFruArea{};
     // Now build common header with data for this FRU Inv Record
     // Use this variable to increment size of header as we go along to determine
     // offset for the subsequent area offsets
     uint16_t curDataOffset = commonHeaderFormatSize;
     // First byte is id for version of FRU Info Storage Spec used
     combFruArea.emplace_back(specVersion);

     // 2nd byte is offset to internal use data
     combFruArea.emplace_back(recordNotPresent);

     // 3rd byte is offset to chassis data
     FruAreaData chassisArea;
     auto chassisIt = inventory.find(chassis);
     if (chassisIt != inventory.end())
     {
         chassisArea = std::move(buildChassisInfoArea(chassisIt->second));
     }
     // update the offset to chassis data.
     buildCommonHeaderSection(chassisArea.size(), curDataOffset, combFruArea);

     // 4th byte is offset to board data
     FruAreaData boardArea;
     auto boardIt = inventory.find(board);
     if (boardIt != inventory.end())
     {
         boardArea = std::move(buildBoardInfoArea(boardIt->second));
     }
     // update the offset to the board data.
     buildCommonHeaderSection(boardArea.size(), curDataOffset, combFruArea);

     // 5th byte is offset to product data
     FruAreaData prodArea;
     auto prodIt = inventory.find(product);
     if (prodIt != inventory.end())
     {
         prodArea = std::move(buildProductInfoArea(prodIt->second));
     }
     // update the offset to the product data.
     buildCommonHeaderSection(prodArea.size(), curDataOffset, combFruArea);

     // 6th byte is offset to multirecord data
     combFruArea.emplace_back(recordNotPresent);

     // 7th byte is PAD
     combFruArea.emplace_back(recordNotPresent);

     // 8th (Final byte of Header Format) is the checksum
     appendDataChecksum(combFruArea);

     // Combine everything into one full IPMI FRU specification Record
     // add chassis use area data
     combFruArea.insert(combFruArea.end(), chassisArea.begin(),
                        chassisArea.end());

     // add board area data
     combFruArea.insert(combFruArea.end(), boardArea.begin(), boardArea.end());

     // add product use area data
     combFruArea.insert(combFruArea.end(), prodArea.begin(), prodArea.end());

     // If area is smaller than the minimum size, pad it. This enables ipmitool
     // to update the FRU blob with values longer than the original payload.
     if (combFruArea.size() < fruMinSize)
     {
         combFruArea.resize(fruMinSize, fruPadValue);
     }

     return combFruArea;
 }

 } // namespace fru
 } // namespace ipmi
	#include "ipmi_fru_info_area.hpp"

	#include <algorithm>
	#include <ctime>
	#include <iomanip>
	#include <map>
	#include <numeric>
	#include <phosphor-logging/elog.hpp>
	#include <sstream>

	namespace ipmi
	{
	namespace fru
	{
	using namespace phosphor::logging;

	// Property variables
	static constexpr auto partNumber = "Part Number";
	static constexpr auto serialNumber = "Serial Number";
	static constexpr auto manufacturer = "Manufacturer";
	static constexpr auto buildDate = "Mfg Date";
	static constexpr auto model = "Model";
	static constexpr auto prettyName = "Name";
	static constexpr auto version = "Version";
	static constexpr auto type = "Type";

	// Board info areas
	static constexpr auto board = "Board";
	static constexpr auto chassis = "Chassis";
	static constexpr auto product = "Product";

	static constexpr auto specVersion = 0x1;
	static constexpr auto recordUnitOfMeasurement = 0x8; // size in bytes
	static constexpr auto checksumSize = 0x1; // size in bytes
	static constexpr auto recordNotPresent = 0x0;
	static constexpr auto englishLanguageCode = 0x0;
	static constexpr auto typeLengthByteNull = 0x0;
	static constexpr auto endOfCustomFields = 0xC1;
	static constexpr auto commonHeaderFormatSize = 0x8; // size in bytes
	static constexpr auto manufacturingDateSize = 0x3;
	static constexpr auto areaSizeOffset = 0x1;
	static constexpr uint8_t typeASCII = 0xC0;
	static constexpr auto maxRecordAttributeValue = 0x1F;

	static constexpr auto secs_from_1970_1996 = 820454400;
	static constexpr auto maxMfgDateValue = 0xFFFFFF; // 3 Byte length
	static constexpr auto secs_per_min = 60;
	static constexpr auto secsToMaxMfgdate =
	secs_from_1970_1996 + secs_per_min * maxMfgDateValue;

	// Minimum size of resulting FRU blob.
	// This is also the theoretical maximum size according to the spec:
	// 8 bytes header + 5 areas at 0xff*8 bytes max each
	// 8 + 50xff8 = 0x27e0
	static constexpr auto fruMinSize = 0x27E0;

	// Value to use for padding.
	// Using 0xff to match the default (blank) value in a physical EEPROM.
	static constexpr auto fruPadValue = 0xff;

	/**
	* @brief Format Beginning of Individual IPMI FRU Data Section
	*
	* @param[in] langCode Language code
	* @param[in/out] data FRU area data
	*/
	void preFormatProcessing(bool langCode, FruAreaData& data)
	{
	// Add id for version of FRU Info Storage Spec used
	data.emplace_back(specVersion);

	// Add Data Size - 0 as a placeholder, can edit after the data is finalized
	data.emplace_back(typeLengthByteNull);

	if (langCode)
	{
	data.emplace_back(englishLanguageCode);
	}
	}

	/**
	* @brief Append checksum of the FRU area data
	*
	* @param[in/out] data FRU area data
	*/
	void appendDataChecksum(FruAreaData& data)
	{
	uint8_t checksumVal = std::accumulate(data.begin(), data.end(), 0);
	// Push the Zero checksum as the last byte of this data
	// This appears to be a simple summation of all the bytes
	data.emplace_back(-checksumVal);
	}

	/**
	* @brief Append padding bytes for the FRU area data
	*
	* @param[in/out] data FRU area data
	*/
	void padData(FruAreaData& data)
	{
	uint8_t pad = (data.size() + checksumSize) % recordUnitOfMeasurement;
	if (pad)
	{
	data.resize((data.size() + recordUnitOfMeasurement - pad));
	}
	}

	/**
	* @brief Format End of Individual IPMI FRU Data Section
	*
	* @param[in/out] fruAreaData FRU area info data
	*/
	void postFormatProcessing(FruAreaData& data)
	{
	// This area needs to be padded to a multiple of 8 bytes (after checksum)
	padData(data);

	// Set size of data info area
	data.at(areaSizeOffset) =
	(data.size() + checksumSize) / (recordUnitOfMeasurement);

	// Finally add area checksum
	appendDataChecksum(data);
	}

	/**
	* @brief Read chassis type property value from inventory and append to the FRU
	* area data.
	*
	* @param[in] propMap map of property values
	* @param[in,out] data FRU area data to be appended
	*/
	void appendChassisType(const PropertyMap& propMap, FruAreaData& data)
	{
	uint8_t chassisType = 0; // Not specified
	auto iter = propMap.find(type);
	if (iter != propMap.end())
	{
	auto value = iter->second;
	try
	{
	chassisType = std::stoi(value);
	}
	catch (std::exception& e)
	{
	log<level::ERR>("Could not parse chassis type",
	entry("VALUE=%s", value.c_str()),
	entry("ERROR=%s", e.what()));
	chassisType = 0;
	}
	}
	data.emplace_back(chassisType);
	}

	/**
	* @brief Read property value from inventory and append to the FRU area data
	*
	* @param[in] key key to search for in the property inventory data
	* @param[in] propMap map of property values
	* @param[in,out] data FRU area data to be appended
	*/
	void appendData(const Property& key, const PropertyMap& propMap,
	FruAreaData& data)
	{
	auto iter = propMap.find(key);
	if (iter != propMap.end())
	{
	auto value = iter->second;
	// If starts with 0x or 0X remove them
	// ex: 0x123a just take 123a
	if ((value.compare(0, 2, "0x")) == 0 \|\|
	(value.compare(0, 2, "0X") == 0))
	{
	value.erase(0, 2);
	}

	// 5 bits for length
	// if length is greater then 31(2^5) bytes then trim the data to 31
	// bytess.
	auto valueLength = (value.length() > maxRecordAttributeValue)
	? maxRecordAttributeValue
	: value.length();
	// 2 bits for type
	// Set the type to ascii
	uint8_t typeLength = valueLength \| ipmi::fru::typeASCII;

	data.emplace_back(typeLength);
	std::copy(value.begin(), value.begin() + valueLength,
	std::back_inserter(data));
	}
	else
	{
	// set 0 size
	data.emplace_back(typeLengthByteNull);
	}
	}

	std::time_t timeStringToRaw(const std::string& input)
	{
	// TODO: For non-US region timestamps, pass in region information for the
	// FRU to avoid the month/day swap.
	// 2017-02-24 - 13:59:00, Tue Nov 20 23:08:00 2018
	static const std::vector<std::string> patterns = {"%Y-%m-%d - %H:%M:%S",
	"%a %b %d %H:%M:%S %Y"};

	std::tm time = {};

	for (const auto& pattern : patterns)
	{
	std::istringstream timeStream(input);
	timeStream >> std::get_time(&time, pattern.c_str());
	if (!timeStream.fail())
	{
	break;
	}
	}

	return std::mktime(&time);
	}

	/**
	* @brief Appends Build Date
	*
	* @param[in] propMap map of property values
	* @param[in/out] data FRU area to add the manfufacture date
	*/
	void appendMfgDate(const PropertyMap& propMap, FruAreaData& data)
	{
	// MFG Date/Time
	auto iter = propMap.find(buildDate);
	if ((iter != propMap.end()) && (iter->second.size() > 0))
	{
	std::time_t raw = timeStringToRaw(iter->second);

	// From FRU Spec:
	// "Mfg. Date / Time
	// Number of minutes from 0:00 hrs 1/1/96.
	// LSbyte first (little endian)
	// 00_00_00h = unspecified."
	if ((raw >= secs_from_1970_1996) && (raw <= secsToMaxMfgdate))
	{
	raw -= secs_from_1970_1996;
	raw /= secs_per_min;
	uint8_t fru_raw[3];
	fru_raw[0] = raw & 0xFF;
	fru_raw[1] = (raw >> 8) & 0xFF;
	fru_raw[2] = (raw >> 16) & 0xFF;
	std::copy(fru_raw, fru_raw + 3, std::back_inserter(data));
	return;
	}
	std::fprintf(stderr, "MgfDate invalid date: %u secs since UNIX epoch\n",
	static_cast<unsigned int>(raw));
	}
	// Blank date
	data.emplace_back(0);
	data.emplace_back(0);
	data.emplace_back(0);
	}

	/**
	* @brief Builds a section of the common header
	*
	* @param[in] infoAreaSize size of the FRU area to write
	* @param[in] offset Current offset for data in overall record
	* @param[in/out] data Common Header section data container
	*/
	void buildCommonHeaderSection(const uint32_t& infoAreaSize, uint16_t& offset,
	FruAreaData& data)
	{
	// Check if data for internal use section populated
	if (infoAreaSize == 0)
	{
	// Indicate record not present
	data.emplace_back(recordNotPresent);
	}
	else
	{
	// offset should be multiple of 8.
	auto remainder = offset % recordUnitOfMeasurement;
	// add the padding bytes in the offset so that offset
	// will be multiple of 8 byte.
	offset += (remainder > 0) ? recordUnitOfMeasurement - remainder : 0;
	// Place data to define offset to area data section
	data.emplace_back(offset / recordUnitOfMeasurement);

	offset += infoAreaSize;
	}
	}

	/**
	* @brief Builds the Chassis info area data section
	*
	* @param[in] propMap map of properties for chassis info area
	* @return FruAreaData container with chassis info area
	*/
	FruAreaData buildChassisInfoArea(const PropertyMap& propMap)
	{
	FruAreaData fruAreaData;
	if (!propMap.empty())
	{
	// Set formatting data that goes at the beginning of the record
	preFormatProcessing(false, fruAreaData);

	// chassis type
	appendChassisType(propMap, fruAreaData);

	// Chasiss part number, in config.yaml it is configured as model
	appendData(model, propMap, fruAreaData);

	// Board serial number
	appendData(serialNumber, propMap, fruAreaData);

	// Indicate End of Custom Fields
	fruAreaData.emplace_back(endOfCustomFields);

	// Complete record data formatting
	postFormatProcessing(fruAreaData);
	}
	return fruAreaData;
	}

	/**
	* @brief Builds the Board info area data section
	*
	* @param[in] propMap map of properties for board info area
	* @return FruAreaData container with board info area
	*/
	FruAreaData buildBoardInfoArea(const PropertyMap& propMap)
	{
	FruAreaData fruAreaData;
	if (!propMap.empty())
	{
	preFormatProcessing(true, fruAreaData);

	// Manufacturing date
	appendMfgDate(propMap, fruAreaData);

	// manufacturer
	appendData(manufacturer, propMap, fruAreaData);

	// Product name/Pretty name
	appendData(prettyName, propMap, fruAreaData);

	// Board serial number
	appendData(serialNumber, propMap, fruAreaData);

	// Board part number
	appendData(partNumber, propMap, fruAreaData);

	// FRU File ID - Empty
	fruAreaData.emplace_back(typeLengthByteNull);

	// Empty FRU File ID bytes
	fruAreaData.emplace_back(recordNotPresent);

	// End of custom fields
	fruAreaData.emplace_back(endOfCustomFields);

	postFormatProcessing(fruAreaData);
	}
	return fruAreaData;
	}

	/**
	* @brief Builds the Product info area data section
	*
	* @param[in] propMap map of FRU properties for Board info area
	* @return FruAreaData container with product info area data
	*/
	FruAreaData buildProductInfoArea(const PropertyMap& propMap)
	{
	FruAreaData fruAreaData;
	if (!propMap.empty())
	{
	// Set formatting data that goes at the beginning of the record
	preFormatProcessing(true, fruAreaData);

	// manufacturer
	appendData(manufacturer, propMap, fruAreaData);

	// Product name/Pretty name
	appendData(prettyName, propMap, fruAreaData);

	// Product part/model number
	appendData(model, propMap, fruAreaData);

	// Product version
	appendData(version, propMap, fruAreaData);

	// Serial Number
	appendData(serialNumber, propMap, fruAreaData);

	// Add Asset Tag
	fruAreaData.emplace_back(recordNotPresent);

	// FRU File ID - Empty
	fruAreaData.emplace_back(typeLengthByteNull);

	// Empty FRU File ID bytes
	fruAreaData.emplace_back(recordNotPresent);

	// End of custom fields
	fruAreaData.emplace_back(endOfCustomFields);

	postFormatProcessing(fruAreaData);
	}
	return fruAreaData;
	}

	FruAreaData buildFruAreaData(const FruInventoryData& inventory)
	{
	FruAreaData combFruArea{};
	// Now build common header with data for this FRU Inv Record
	// Use this variable to increment size of header as we go along to determine
	// offset for the subsequent area offsets
	uint16_t curDataOffset = commonHeaderFormatSize;
	// First byte is id for version of FRU Info Storage Spec used
	combFruArea.emplace_back(specVersion);

	// 2nd byte is offset to internal use data
	combFruArea.emplace_back(recordNotPresent);

	// 3rd byte is offset to chassis data
	FruAreaData chassisArea;
	auto chassisIt = inventory.find(chassis);
	if (chassisIt != inventory.end())
	{
	chassisArea = std::move(buildChassisInfoArea(chassisIt->second));
	}
	// update the offset to chassis data.
	buildCommonHeaderSection(chassisArea.size(), curDataOffset, combFruArea);

	// 4th byte is offset to board data
	FruAreaData boardArea;
	auto boardIt = inventory.find(board);
	if (boardIt != inventory.end())
	{
	boardArea = std::move(buildBoardInfoArea(boardIt->second));
	}
	// update the offset to the board data.
	buildCommonHeaderSection(boardArea.size(), curDataOffset, combFruArea);

	// 5th byte is offset to product data
	FruAreaData prodArea;
	auto prodIt = inventory.find(product);
	if (prodIt != inventory.end())
	{
	prodArea = std::move(buildProductInfoArea(prodIt->second));
	}
	// update the offset to the product data.
	buildCommonHeaderSection(prodArea.size(), curDataOffset, combFruArea);

	// 6th byte is offset to multirecord data
	combFruArea.emplace_back(recordNotPresent);

	// 7th byte is PAD
	combFruArea.emplace_back(recordNotPresent);

	// 8th (Final byte of Header Format) is the checksum
	appendDataChecksum(combFruArea);

	// Combine everything into one full IPMI FRU specification Record
	// add chassis use area data
	combFruArea.insert(combFruArea.end(), chassisArea.begin(),
	chassisArea.end());

	// add board area data
	combFruArea.insert(combFruArea.end(), boardArea.begin(), boardArea.end());

	// add product use area data
	combFruArea.insert(combFruArea.end(), prodArea.begin(), prodArea.end());

	// If area is smaller than the minimum size, pad it. This enables ipmitool
	// to update the FRU blob with values longer than the original payload.
	if (combFruArea.size() < fruMinSize)
	{
	combFruArea.resize(fruMinSize, fruPadValue);
	}

	return combFruArea;
	}

	} // namespace fru
	} // namespace ipmi