src/util.cpp - openbmc/estoraged - Gitiles

 #include "util.hpp"

 #include "getConfig.hpp"

 #include <linux/fs.h>

 #include <phosphor-logging/lg2.hpp>
 #include <stdplus/fd/create.hpp>
 #include <stdplus/fd/managed.hpp>
 #include <stdplus/handle/managed.hpp>
 #include <xyz/openbmc_project/Common/error.hpp>

 #include <filesystem>
 #include <fstream>
 #include <iostream>
 #include <string>

 namespace estoraged
 {
 namespace util
 {
 using ::sdbusplus::xyz::openbmc_project::Common::Error::InternalFailure;
 using ::stdplus::fd::ManagedFd;

 uint64_t findSizeOfBlockDevice(const std::string& devPath)
 {
     ManagedFd fd;
     uint64_t bytes = 0;
     try
     {
         // open block dev
         fd = stdplus::fd::open(devPath, stdplus::fd::OpenAccess::ReadOnly);
         // get block size
         fd.ioctl(BLKGETSIZE64, &bytes);
     }
     catch (...)
     {
         lg2::error("erase unable to open blockdev", "REDFISH_MESSAGE_ID",
                    std::string("OpenBMC.0.1.DriveEraseFailure"),
                    "REDFISH_MESSAGE_ARGS", std::to_string(fd.get()));
         throw InternalFailure();
     }
     return bytes;
 }

 uint8_t findPredictedMediaLifeLeftPercent(const std::string& sysfsPath)
 {
     // The eMMC spec defines two estimates for the life span of the device
     // in the extended CSD field 269 and 268, named estimate A and estimate B.
     // Linux exposes the values in the /life_time node.
     // estimate A is for A type memory
     // estimate B is for B type memory
     //
     // the estimate are encoded as such
     // 0x01 <=>  0% - 10% device life time used
     // 0x02 <=>  10% -20% device life time used
     // ...
     // 0x0A <=>  90% - 100% device life time used
     // 0x0B <=> Exceeded its maximum estimated device life time

     uint16_t estA = 0, estB = 0;
     std::ifstream lifeTimeFile;
     try
     {
         lifeTimeFile.open(sysfsPath + "/life_time", std::ios_base::in);
         lifeTimeFile >> std::hex >> estA;
         lifeTimeFile >> std::hex >> estB;
         if ((estA == 0) || (estA > 11) || (estB == 0) || (estB > 11))
         {
             throw InternalFailure();
         }
     }
     catch (...)
     {
         lg2::error("Unable to read sysfs", "REDFISH_MESSAGE_ID",
                    std::string("OpenBMC.0.1.DriveEraseFailure"));
         lifeTimeFile.close();
         return 255;
     }
     lifeTimeFile.close();
     // we are returning lowest LifeLeftPercent
     uint8_t maxLifeUsed = 0;
     if (estA > estB)
     {
         maxLifeUsed = estA;
     }
     else
     {
         maxLifeUsed = estB;
     }

     return static_cast<uint8_t>(11 - maxLifeUsed) * 10;
 }

 bool findDevice(const StorageData& data, const std::filesystem::path& searchDir,
                 std::filesystem::path& deviceFile,
                 std::filesystem::path& sysfsDir, std::string& luksName)
 {
     /* Check what type of storage device this is. */
     estoraged::BasicVariantType typeVariant;
     try
     {
         /* The EntityManager config should have this property set. */
         typeVariant = data.at("Type");
     }
     catch (const boost::container::out_of_range& e)
     {
         lg2::error("Could not read device type", "REDFISH_MESSAGE_ID",
                    std::string("OpenBMC.0.1.FindDeviceFail"));
         return false;
     }

     /*
      * Currently, we only support eMMC, so report an error for any other device
      * types.
      */
     std::string type = std::get<std::string>(typeVariant);
     if (type.compare("EmmcDevice") != 0)
     {
         lg2::error("Unsupported device type {TYPE}", "TYPE", type,
                    "REDFISH_MESSAGE_ID",
                    std::string("OpenBMC.0.1.FindDeviceFail"));
         return false;
     }

     /* Look for the eMMC in the specified searchDir directory. */
     for (auto const& dirEntry : std::filesystem::directory_iterator{searchDir})
     {
         /*
          * We will look at the 'type' file to determine if this is an MMC
          * device.
          */
         std::filesystem::path curPath(dirEntry.path());
         curPath /= "device/type";
         if (!std::filesystem::exists(curPath))
         {
             /* The 'type' file doesn't exist. This must not be an eMMC. */
             continue;
         }

         try
         {
             std::ifstream typeFile(curPath, std::ios_base::in);
             std::string devType;
             typeFile >> devType;
             if (devType.compare("MMC") == 0)
             {
                 /* Found it. Get the sysfs directory and device file. */
                 std::filesystem::path deviceName(dirEntry.path().filename());

                 sysfsDir = dirEntry.path();
                 sysfsDir /= "device";

                 deviceFile = "/dev";
                 deviceFile /= deviceName;

                 luksName = "luks-" + deviceName.string();
                 return true;
             }
         }
         catch (...)
         {
             lg2::error("Failed to read device type for {PATH}", "PATH", curPath,
                        "REDFISH_MESSAGE_ID",
                        std::string("OpenBMC.0.1.FindDeviceFail"));
             /*
              * We will still continue searching, though. Maybe this wasn't the
              * device we were looking for, anyway.
              */
         }
     }

     /* Device wasn't found. */
     return false;
 }

 } // namespace util

 } // namespace estoraged
	#include "util.hpp"

	#include "getConfig.hpp"

	#include <linux/fs.h>

	#include <phosphor-logging/lg2.hpp>
	#include <stdplus/fd/create.hpp>
	#include <stdplus/fd/managed.hpp>
	#include <stdplus/handle/managed.hpp>
	#include <xyz/openbmc_project/Common/error.hpp>

	#include <filesystem>
	#include <fstream>
	#include <iostream>
	#include <string>

	namespace estoraged
	{
	namespace util
	{
	using ::sdbusplus::xyz::openbmc_project::Common::Error::InternalFailure;
	using ::stdplus::fd::ManagedFd;

	uint64_t findSizeOfBlockDevice(const std::string& devPath)
	{
	ManagedFd fd;
	uint64_t bytes = 0;
	try
	{
	// open block dev
	fd = stdplus::fd::open(devPath, stdplus::fd::OpenAccess::ReadOnly);
	// get block size
	fd.ioctl(BLKGETSIZE64, &bytes);
	}
	catch (...)
	{
	lg2::error("erase unable to open blockdev", "REDFISH_MESSAGE_ID",
	std::string("OpenBMC.0.1.DriveEraseFailure"),
	"REDFISH_MESSAGE_ARGS", std::to_string(fd.get()));
	throw InternalFailure();
	}
	return bytes;
	}

	uint8_t findPredictedMediaLifeLeftPercent(const std::string& sysfsPath)
	{
	// The eMMC spec defines two estimates for the life span of the device
	// in the extended CSD field 269 and 268, named estimate A and estimate B.
	// Linux exposes the values in the /life_time node.
	// estimate A is for A type memory
	// estimate B is for B type memory
	//
	// the estimate are encoded as such
	// 0x01 <=> 0% - 10% device life time used
	// 0x02 <=> 10% -20% device life time used
	// ...
	// 0x0A <=> 90% - 100% device life time used
	// 0x0B <=> Exceeded its maximum estimated device life time

	uint16_t estA = 0, estB = 0;
	std::ifstream lifeTimeFile;
	try
	{
	lifeTimeFile.open(sysfsPath + "/life_time", std::ios_base::in);
	lifeTimeFile >> std::hex >> estA;
	lifeTimeFile >> std::hex >> estB;
	if ((estA == 0) \|\| (estA > 11) \|\| (estB == 0) \|\| (estB > 11))
	{
	throw InternalFailure();
	}
	}
	catch (...)
	{
	lg2::error("Unable to read sysfs", "REDFISH_MESSAGE_ID",
	std::string("OpenBMC.0.1.DriveEraseFailure"));
	lifeTimeFile.close();
	return 255;
	}
	lifeTimeFile.close();
	// we are returning lowest LifeLeftPercent
	uint8_t maxLifeUsed = 0;
	if (estA > estB)
	{
	maxLifeUsed = estA;
	}
	else
	{
	maxLifeUsed = estB;
	}

	return static_cast<uint8_t>(11 - maxLifeUsed) * 10;
	}

	bool findDevice(const StorageData& data, const std::filesystem::path& searchDir,
	std::filesystem::path& deviceFile,
	std::filesystem::path& sysfsDir, std::string& luksName)
	{
	/* Check what type of storage device this is. */
	estoraged::BasicVariantType typeVariant;
	try
	{
	/* The EntityManager config should have this property set. */
	typeVariant = data.at("Type");
	}
	catch (const boost::container::out_of_range& e)
	{
	lg2::error("Could not read device type", "REDFISH_MESSAGE_ID",
	std::string("OpenBMC.0.1.FindDeviceFail"));
	return false;
	}

	/*
	* Currently, we only support eMMC, so report an error for any other device
	* types.
	*/
	std::string type = std::get<std::string>(typeVariant);
	if (type.compare("EmmcDevice") != 0)
	{
	lg2::error("Unsupported device type {TYPE}", "TYPE", type,
	"REDFISH_MESSAGE_ID",
	std::string("OpenBMC.0.1.FindDeviceFail"));
	return false;
	}

	/* Look for the eMMC in the specified searchDir directory. */
	for (auto const& dirEntry : std::filesystem::directory_iterator{searchDir})
	{
	/*
	* We will look at the 'type' file to determine if this is an MMC
	* device.
	*/
	std::filesystem::path curPath(dirEntry.path());
	curPath /= "device/type";
	if (!std::filesystem::exists(curPath))
	{
	/* The 'type' file doesn't exist. This must not be an eMMC. */
	continue;
	}

	try
	{
	std::ifstream typeFile(curPath, std::ios_base::in);
	std::string devType;
	typeFile >> devType;
	if (devType.compare("MMC") == 0)
	{
	/* Found it. Get the sysfs directory and device file. */
	std::filesystem::path deviceName(dirEntry.path().filename());

	sysfsDir = dirEntry.path();
	sysfsDir /= "device";

	deviceFile = "/dev";
	deviceFile /= deviceName;

	luksName = "luks-" + deviceName.string();
	return true;
	}
	}
	catch (...)
	{
	lg2::error("Failed to read device type for {PATH}", "PATH", curPath,
	"REDFISH_MESSAGE_ID",
	std::string("OpenBMC.0.1.FindDeviceFail"));
	/*
	* We will still continue searching, though. Maybe this wasn't the
	* device we were looking for, anyway.
	*/
	}
	}

	/* Device wasn't found. */
	return false;
	}

	} // namespace util

	} // namespace estoraged