src/inspur_oem.cpp - openbmc/iei-ipmi-oem - Gitiles

 #include "config.h"

 #include "inspur_oem.hpp"

 #include "sdbus_wrapper.hpp"
 #include "utils.hpp"

 #include <ipmid/api.h>

 #include <phosphor-logging/log.hpp>

 #include <optional>

 namespace
 {
 constexpr auto FIRMWARE_TYPE_OFFSET = 0;
 constexpr auto FIRMWARE_TYPE_SIZE = 1;
 constexpr auto FIRMWARE_VERSION_OFFSET =
     FIRMWARE_TYPE_OFFSET + FIRMWARE_TYPE_SIZE;
 constexpr auto FIRMWARE_VERSION_SIZE = 15;
 constexpr auto FIRMWARE_BUILDTIME_OFFSET =
     FIRMWARE_VERSION_OFFSET + FIRMWARE_VERSION_SIZE;
 constexpr auto FIRMWARE_BUILDTIME_SIZE = 20;
 constexpr auto FIRMWARE_MIN_SIZE = FIRMWARE_BUILDTIME_OFFSET;

 static_assert(FIRMWARE_VERSION_OFFSET == 1);
 static_assert(FIRMWARE_BUILDTIME_OFFSET == 16);
 } // namespace

 namespace ipmi
 {

 #define UNUSED(x) (void)(x)

 using namespace phosphor::logging;
 using namespace inspur;

 static void registerOEMFunctions() __attribute__((constructor));
 static auto& bus = getBus();

 struct ParsedAssetInfo
 {
     uint8_t rwFlag;
     uint8_t deviceType;
     uint8_t infoType;
     uint8_t maskAllPresentLen;
     std::vector<uint8_t> enableStatus;
     std::vector<uint8_t> maskPresent;
     std::vector<uint8_t> maskAllPresent;
     uint8_t allInfoDone;
     uint16_t totalMessageLen;
     std::vector<uint8_t> data;
 };

 void dumpAssetInfo(const ParsedAssetInfo& info)
 {
     fprintf(stderr,
             "AssetInfo: rw %d, deviceType 0x%02x, infoType 0x%02x, "
             "maskAllPresentLen %u\n",
             info.rwFlag, info.deviceType, info.infoType,
             info.maskAllPresentLen);
     fprintf(stderr, "enableStatus ");
     for (const auto& d : info.enableStatus)
     {
         fprintf(stderr, "0x%02x ", d);
     }
     fprintf(stderr, "\nmaskPresent ");
     for (const auto& d : info.maskPresent)
     {
         fprintf(stderr, "0x%02x ", d);
     }
     fprintf(stderr, "\nmaskAllPresent ");
     for (const auto& d : info.maskAllPresent)
     {
         fprintf(stderr, "0x%02x ", d);
     }
     fprintf(stderr, "\nallInfoDone %d, totalMessageLen %u\n", info.allInfoDone,
             info.totalMessageLen);
     fprintf(stderr, "data: ");
     for (const auto& d : info.data)
     {
         fprintf(stderr, "0x%02x ", d);
     }
     fprintf(stderr, "\n");
 }

 std::optional<ParsedAssetInfo> parseAssetInfo(const AssetInfoHeader* h)
 {
     auto len = h->maskAllPresentLen;
     if (len == 0)
     {
         // This is invalid
         return {};
     }

     ParsedAssetInfo info;
     info.rwFlag = h->rwFlag;
     info.deviceType = h->deviceType;
     info.infoType = h->infoType;
     info.maskAllPresentLen = len;
     info.enableStatus.resize(len);
     info.maskPresent.resize(len);
     info.maskAllPresent.resize(len);
     const uint8_t* p = &h->enableStatus;
     memcpy(info.enableStatus.data(), p, len);
     p += len;
     memcpy(info.maskPresent.data(), p, len);
     p += len;
     memcpy(info.maskAllPresent.data(), p, len);
     p += len;
     info.allInfoDone = *p++;
     info.totalMessageLen = *reinterpret_cast<const uint16_t*>(p);
     p += sizeof(uint16_t);
     auto dataLen = info.totalMessageLen - (sizeof(AssetInfoHeader) + 3 * len);
     info.data.resize(dataLen);
     memcpy(info.data.data(), p, dataLen);

     //    dumpAssetInfo(info);
     return info;
 }

 void parseBIOSInfo(const std::vector<uint8_t>& data)
 {
     if (data.size() < FIRMWARE_MIN_SIZE)
     {
         return;
     }
     bios_version_devname dev = static_cast<bios_version_devname>(data[0]);
     std::string version{data.data() + FIRMWARE_VERSION_OFFSET,
                         data.data() + FIRMWARE_VERSION_SIZE};
     std::string buildTime;
     if (dev == bios_version_devname::BIOS)
     {
         buildTime.assign(reinterpret_cast<const char*>(
                              data.data() + FIRMWARE_BUILDTIME_OFFSET),
                          FIRMWARE_BUILDTIME_SIZE);

         // Set BIOS version
         auto service = utils::getService(bus, BIOS_OBJPATH, VERSION_IFACE);
         utils::setProperty(bus, service.c_str(), BIOS_OBJPATH, VERSION_IFACE,
                            VERSION, version);
     }

     printf("Dev %s, version %s, build time %s\n",
            bios_devname[static_cast<int>(dev)].data(), version.c_str(),
            buildTime.c_str());
 }

 ipmi_ret_t ipmiOemInspurAssetInfo(ipmi_netfn_t /* netfn */,
                                   ipmi_cmd_t /* cmd */, ipmi_request_t request,
                                   ipmi_response_t response,
                                   ipmi_data_len_t /* data_len */,
                                   ipmi_context_t /* context */)
 {
     auto header = reinterpret_cast<AssetInfoHeader*>(request);
     uint8_t* res = reinterpret_cast<uint8_t*>(response);
     UNUSED(res);

     auto info = parseAssetInfo(header);
     auto deviceType = info->deviceType;
     if (deviceType != 0x05)
     {
         log<level::WARNING>("Device type not supported yet");
         return IPMI_CC_UNSPECIFIED_ERROR;
     }

     // For now we only support BIOS type
     parseBIOSInfo(info->data);

     return IPMI_CC_OK;
 }

 void registerOEMFunctions(void)
 {
     ipmi_register_callback(NETFN_OEM_INSPUR, CMD_OEM_ASSET_INFO, nullptr,
                            ipmiOemInspurAssetInfo, SYSTEM_INTERFACE);
 }

 } // namespace ipmi
	#include "config.h"

	#include "inspur_oem.hpp"

	#include "sdbus_wrapper.hpp"
	#include "utils.hpp"

	#include <ipmid/api.h>

	#include <phosphor-logging/log.hpp>

	#include <optional>

	namespace
	{
	constexpr auto FIRMWARE_TYPE_OFFSET = 0;
	constexpr auto FIRMWARE_TYPE_SIZE = 1;
	constexpr auto FIRMWARE_VERSION_OFFSET =
	FIRMWARE_TYPE_OFFSET + FIRMWARE_TYPE_SIZE;
	constexpr auto FIRMWARE_VERSION_SIZE = 15;
	constexpr auto FIRMWARE_BUILDTIME_OFFSET =
	FIRMWARE_VERSION_OFFSET + FIRMWARE_VERSION_SIZE;
	constexpr auto FIRMWARE_BUILDTIME_SIZE = 20;
	constexpr auto FIRMWARE_MIN_SIZE = FIRMWARE_BUILDTIME_OFFSET;

	static_assert(FIRMWARE_VERSION_OFFSET == 1);
	static_assert(FIRMWARE_BUILDTIME_OFFSET == 16);
	} // namespace

	namespace ipmi
	{

	#define UNUSED(x) (void)(x)

	using namespace phosphor::logging;
	using namespace inspur;

	static void registerOEMFunctions() __attribute__((constructor));
	static auto& bus = getBus();

	struct ParsedAssetInfo
	{
	uint8_t rwFlag;
	uint8_t deviceType;
	uint8_t infoType;
	uint8_t maskAllPresentLen;
	std::vector<uint8_t> enableStatus;
	std::vector<uint8_t> maskPresent;
	std::vector<uint8_t> maskAllPresent;
	uint8_t allInfoDone;
	uint16_t totalMessageLen;
	std::vector<uint8_t> data;
	};

	void dumpAssetInfo(const ParsedAssetInfo& info)
	{
	fprintf(stderr,
	"AssetInfo: rw %d, deviceType 0x%02x, infoType 0x%02x, "
	"maskAllPresentLen %u\n",
	info.rwFlag, info.deviceType, info.infoType,
	info.maskAllPresentLen);
	fprintf(stderr, "enableStatus ");
	for (const auto& d : info.enableStatus)
	{
	fprintf(stderr, "0x%02x ", d);
	}
	fprintf(stderr, "\nmaskPresent ");
	for (const auto& d : info.maskPresent)
	{
	fprintf(stderr, "0x%02x ", d);
	}
	fprintf(stderr, "\nmaskAllPresent ");
	for (const auto& d : info.maskAllPresent)
	{
	fprintf(stderr, "0x%02x ", d);
	}
	fprintf(stderr, "\nallInfoDone %d, totalMessageLen %u\n", info.allInfoDone,
	info.totalMessageLen);
	fprintf(stderr, "data: ");
	for (const auto& d : info.data)
	{
	fprintf(stderr, "0x%02x ", d);
	}
	fprintf(stderr, "\n");
	}

	std::optional<ParsedAssetInfo> parseAssetInfo(const AssetInfoHeader* h)
	{
	auto len = h->maskAllPresentLen;
	if (len == 0)
	{
	// This is invalid
	return {};
	}

	ParsedAssetInfo info;
	info.rwFlag = h->rwFlag;
	info.deviceType = h->deviceType;
	info.infoType = h->infoType;
	info.maskAllPresentLen = len;
	info.enableStatus.resize(len);
	info.maskPresent.resize(len);
	info.maskAllPresent.resize(len);
	const uint8_t* p = &h->enableStatus;
	memcpy(info.enableStatus.data(), p, len);
	p += len;
	memcpy(info.maskPresent.data(), p, len);
	p += len;
	memcpy(info.maskAllPresent.data(), p, len);
	p += len;
	info.allInfoDone = *p++;
	info.totalMessageLen = reinterpret_cast<const uint16_t>(p);
	p += sizeof(uint16_t);
	auto dataLen = info.totalMessageLen - (sizeof(AssetInfoHeader) + 3 * len);
	info.data.resize(dataLen);
	memcpy(info.data.data(), p, dataLen);

	// dumpAssetInfo(info);
	return info;
	}

	void parseBIOSInfo(const std::vector<uint8_t>& data)
	{
	if (data.size() < FIRMWARE_MIN_SIZE)
	{
	return;
	}
	bios_version_devname dev = static_cast<bios_version_devname>(data[0]);
	std::string version{data.data() + FIRMWARE_VERSION_OFFSET,
	data.data() + FIRMWARE_VERSION_SIZE};
	std::string buildTime;
	if (dev == bios_version_devname::BIOS)
	{
	buildTime.assign(reinterpret_cast<const char*>(
	data.data() + FIRMWARE_BUILDTIME_OFFSET),
	FIRMWARE_BUILDTIME_SIZE);

	// Set BIOS version
	auto service = utils::getService(bus, BIOS_OBJPATH, VERSION_IFACE);
	utils::setProperty(bus, service.c_str(), BIOS_OBJPATH, VERSION_IFACE,
	VERSION, version);
	}

	printf("Dev %s, version %s, build time %s\n",
	bios_devname[static_cast<int>(dev)].data(), version.c_str(),
	buildTime.c_str());
	}

	ipmi_ret_t ipmiOemInspurAssetInfo(ipmi_netfn_t /* netfn */,
	ipmi_cmd_t /* cmd */, ipmi_request_t request,
	ipmi_response_t response,
	ipmi_data_len_t /* data_len */,
	ipmi_context_t /* context */)
	{
	auto header = reinterpret_cast<AssetInfoHeader*>(request);
	uint8_t* res = reinterpret_cast<uint8_t*>(response);
	UNUSED(res);

	auto info = parseAssetInfo(header);
	auto deviceType = info->deviceType;
	if (deviceType != 0x05)
	{
	log<level::WARNING>("Device type not supported yet");
	return IPMI_CC_UNSPECIFIED_ERROR;
	}

	// For now we only support BIOS type
	parseBIOSInfo(info->data);

	return IPMI_CC_OK;
	}

	void registerOEMFunctions(void)
	{
	ipmi_register_callback(NETFN_OEM_INSPUR, CMD_OEM_ASSET_INFO, nullptr,
	ipmiOemInspurAssetInfo, SYSTEM_INTERFACE);
	}

	} // namespace ipmi