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gerrit.openbmc.org / openbmc / pldm / dbbc9ff3b2084c300ce806044858a11d2aae5d2c / . / libpldmresponder / bios.cpp
blob: 47bfc0aae4426f721166502315391a351a003076 [file] [log] [blame]
#include "bios.hpp"
#include "libpldmresponder/utils.hpp"
#include "registration.hpp"
#include "xyz/openbmc_project/Common/error.hpp"
#include <array>
#include <boost/crc.hpp>
#include <chrono>
#include <ctime>
#include <memory>
#include <numeric>
#include <phosphor-logging/elog-errors.hpp>
#include <phosphor-logging/log.hpp>
#include <stdexcept>
#include <string>
#include <variant>
#include <vector>
using namespace pldm::responder::bios;
using namespace bios_parser;
namespace pldm
{
using namespace phosphor::logging;
using namespace sdbusplus::xyz::openbmc_project::Common::Error;
using EpochTimeUS = uint64_t;
using BIOSTableRow = std::vector<uint8_t>;
using BIOSJsonName = std::string;
constexpr auto dbusProperties = "org.freedesktop.DBus.Properties";
constexpr auto padChksumMax = 7;
namespace responder
{
namespace utils
{
void epochToBCDTime(uint64_t timeSec, uint8_t& seconds, uint8_t& minutes,
uint8_t& hours, uint8_t& day, uint8_t& month,
uint16_t& year)
{
auto t = time_t(timeSec);
auto time = localtime(&t);
seconds = decimalToBcd(time->tm_sec);
minutes = decimalToBcd(time->tm_min);
hours = decimalToBcd(time->tm_hour);
day = decimalToBcd(time->tm_mday);
month =
decimalToBcd(time->tm_mon + 1); // The number of months in the range
// 0 to 11.PLDM expects range 1 to 12
year = decimalToBcd(time->tm_year + 1900); // The number of years since 1900
}
size_t getTableTotalsize(size_t sizeWithoutPad)
{
auto padSize = getNumPadBytes(sizeWithoutPad);
return sizeWithoutPad + padSize + sizeof(uint32_t) /* checksum */;
}
void padAndChecksum(Table& table)
{
auto padSize = getNumPadBytes(table.size());
table.insert(table.end(), padSize, 0);
boost::crc_32_type result;
size_t size = table.size();
result.process_bytes(table.data(), size);
uint32_t checkSum = result.checksum();
uint8_t* checkSumPtr = reinterpret_cast<uint8_t*>(&checkSum);
table.insert(table.end(), checkSumPtr, checkSumPtr + sizeof(checkSum));
}
} // namespace utils
Response getDateTime(const pldm_msg* request, size_t /*payloadLength*/)
{
uint8_t seconds = 0;
uint8_t minutes = 0;
uint8_t hours = 0;
uint8_t day = 0;
uint8_t month = 0;
uint16_t year = 0;
constexpr auto timeInterface = "xyz.openbmc_project.Time.EpochTime";
constexpr auto hostTimePath = "/xyz/openbmc_project/time/host";
Response response(sizeof(pldm_msg_hdr) + PLDM_GET_DATE_TIME_RESP_BYTES, 0);
auto responsePtr = reinterpret_cast<pldm_msg*>(response.data());
std::variant<EpochTimeUS> value;
auto bus = sdbusplus::bus::new_default();
try
{
auto service = getService(bus, hostTimePath, timeInterface);
auto method = bus.new_method_call(service.c_str(), hostTimePath,
dbusProperties, "Get");
method.append(timeInterface, "Elapsed");
auto reply = bus.call(method);
reply.read(value);
}
catch (std::exception& e)
{
log<level::ERR>("Error getting time", entry("PATH=%s", hostTimePath),
entry("TIME INTERACE=%s", timeInterface));
encode_get_date_time_resp(request->hdr.instance_id, PLDM_ERROR, seconds,
minutes, hours, day, month, year,
responsePtr);
return response;
}
uint64_t timeUsec = std::get<EpochTimeUS>(value);
uint64_t timeSec = std::chrono::duration_cast<std::chrono::seconds>(
std::chrono::microseconds(timeUsec))
.count();
utils::epochToBCDTime(timeSec, seconds, minutes, hours, day, month, year);
encode_get_date_time_resp(request->hdr.instance_id, PLDM_SUCCESS, seconds,
minutes, hours, day, month, year, responsePtr);
return response;
}
/** @brief Construct the BIOS string table
*
* @param[in] BIOSStringTable - the string table
* @param[in] transferHandle - transfer handle to identify part of transfer
* @param[in] transferOpFlag - flag to indicate which part of data being
* transferred
* @param[in] instanceID - instance ID to identify the command
*/
Response getBIOSStringTable(BIOSTable& BIOSStringTable,
uint32_t /*transferHandle*/,
uint8_t /*transferOpFlag*/, uint8_t instanceID)
{
Response response(sizeof(pldm_msg_hdr) + PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES,
0);
auto responsePtr = reinterpret_cast<pldm_msg*>(response.data());
if (!BIOSStringTable.isEmpty())
{
encode_get_bios_table_resp(instanceID, PLDM_SUCCESS,
0, /* next transfer handle */
PLDM_START_AND_END, nullptr, response.size(),
responsePtr); // filling up the header here
BIOSStringTable.load(response);
return response;
}
auto biosStrings = bios_parser::getStrings();
std::sort(biosStrings.begin(), biosStrings.end());
// remove all duplicate strings received from bios json
biosStrings.erase(std::unique(biosStrings.begin(), biosStrings.end()),
biosStrings.end());
size_t sizeWithoutPad = std::accumulate(
biosStrings.begin(), biosStrings.end(), 0,
[](size_t sum, const std::string& elem) {
return sum +
pldm_bios_table_string_entry_encode_length(elem.length());
});
Table stringTable;
stringTable.reserve(utils::getTableTotalsize(sizeWithoutPad));
stringTable.resize(sizeWithoutPad);
auto tablePtr = stringTable.data();
for (const auto& elem : biosStrings)
{
auto entry_length =
pldm_bios_table_string_entry_encode_length(elem.length());
pldm_bios_table_string_entry_encode(tablePtr, sizeWithoutPad,
elem.c_str(), elem.length());
tablePtr += entry_length;
sizeWithoutPad -= entry_length;
}
utils::padAndChecksum(stringTable);
BIOSStringTable.store(stringTable);
response.resize(sizeof(pldm_msg_hdr) + PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES +
stringTable.size(),
0);
responsePtr = reinterpret_cast<pldm_msg*>(response.data());
encode_get_bios_table_resp(
instanceID, PLDM_SUCCESS, 0 /* nxtTransferHandle */, PLDM_START_AND_END,
stringTable.data(), response.size(), responsePtr);
return response;
}
/** @brief Find the string handle from the BIOS string table given the name
*
* @param[in] name - name of the BIOS string
* @param[in] BIOSStringTable - the string table
* @return - uint16_t - handle of the string
*/
StringHandle findStringHandle(const std::string& name,
const BIOSTable& BIOSStringTable)
{
Table table;
BIOSStringTable.load(table);
auto stringEntry = pldm_bios_table_string_find_by_string(
table.data(), table.size(), name.c_str());
if (stringEntry == nullptr)
{
log<level::ERR>("Reached end of BIOS string table,did not find the "
"handle for the string",
entry("STRING=%s", name.c_str()));
elog<InternalFailure>();
}
return pldm_bios_table_string_entry_decode_handle(stringEntry);
}
/** @brief Find the string name from the BIOS string table for a string handle
*
* @param[in] stringHdl - string handle
* @param[in] BIOSStringTable - the string table
*
* @return - std::string - name of the corresponding BIOS string
*/
std::string findStringName(StringHandle stringHdl,
const BIOSTable& BIOSStringTable)
{
Table table;
BIOSStringTable.load(table);
auto stringEntry = pldm_bios_table_string_find_by_handle(
table.data(), table.size(), stringHdl);
std::string name;
if (stringEntry == nullptr)
{
log<level::ERR>("Reached end of BIOS string table,did not find "
"string name for handle",
entry("STRING_HANDLE=%d", stringHdl));
}
auto strLength =
pldm_bios_table_string_entry_decode_string_length(stringEntry);
name.resize(strLength);
pldm_bios_table_string_entry_decode_string(stringEntry, name.data(),
name.size());
return name;
}
namespace bios_type_enum
{
using namespace bios_parser::bios_enum;
/** @brief Find the indices into the array of the possible values of string
* handles for the current values.This is used in attribute value table
*
* @param[in] possiVals - vector of string handles comprising all the possible
* values for an attribute
* @param[in] currVals - vector of strings comprising all current values
* for an attribute
* @param[in] BIOSStringTable - the string table
*
* @return - std::vector<uint8_t> - indices into the array of the possible
* values of string handles
*/
std::vector<uint8_t> findStrIndices(PossibleValuesByHandle possiVals,
CurrentValues currVals,
const BIOSTable& BIOSStringTable)
{
std::vector<uint8_t> stringIndices;
for (const auto& currVal : currVals)
{
StringHandle curHdl;
try
{
curHdl = findStringHandle(currVal, BIOSStringTable);
}
catch (InternalFailure& e)
{
log<level::ERR>("Exception fetching handle for the string",
entry("STRING=%s", currVal.c_str()));
continue;
}
uint8_t i = 0;
for (auto possiHdl : possiVals)
{
if (possiHdl == curHdl)
{
stringIndices.push_back(i);
break;
}
i++;
}
}
return stringIndices;
}
/** @brief Find the indices into the array of the possible values of string
* handles for the default values. This is used in attribute table
*
* @param[in] possiVals - vector of strings comprising all the possible values
* for an attribute
* @param[in] defVals - vector of strings comprising all the default values
* for an attribute
* @return - std::vector<uint8_t> - indices into the array of the possible
* values of string
*/
std::vector<uint8_t> findDefaultValHandle(const PossibleValues& possiVals,
const DefaultValues& defVals)
{
std::vector<uint8_t> defHdls;
for (const auto& defs : defVals)
{
auto index = std::lower_bound(possiVals.begin(), possiVals.end(), defs);
if (index != possiVals.end())
{
defHdls.push_back(index - possiVals.begin());
}
}
return defHdls;
}
/** @brief Construct the attibute table for BIOS type Enumeration and
* Enumeration ReadOnly
* @param[in] BIOSStringTable - the string table
* @param[in] biosJsonDir - path where the BIOS json files are present
* @param[in,out] attributeTable - the attribute table
*
*/
void constructAttrTable(const BIOSTable& BIOSStringTable, Table& attributeTable)
{
const auto& attributeMap = getValues();
StringHandle strHandle;
for (const auto& [key, value] : attributeMap)
{
try
{
strHandle = findStringHandle(key, BIOSStringTable);
}
catch (InternalFailure& e)
{
log<level::ERR>("Could not find handle for BIOS string",
entry("ATTRIBUTE=%s", key.c_str()));
continue;
}
bool readOnly = (std::get<0>(value));
PossibleValues possiVals = std::get<1>(value);
DefaultValues defVals = std::get<2>(value);
// both the possible and default values are stored in sorted manner to
// ease in fetching back/comparison
std::sort(possiVals.begin(), possiVals.end());
std::sort(defVals.begin(), defVals.end());
std::vector<StringHandle> possiValsByHdl;
for (const auto& elem : possiVals)
{
try
{
auto hdl = findStringHandle(elem, BIOSStringTable);
possiValsByHdl.push_back(std::move(hdl));
}
catch (InternalFailure& e)
{
log<level::ERR>("Could not find handle for BIOS string",
entry("STRING=%s", elem.c_str()));
continue;
}
}
auto defValsByHdl = findDefaultValHandle(possiVals, defVals);
auto entryLength = pldm_bios_table_attr_entry_enum_encode_length(
possiValsByHdl.size(), defValsByHdl.size());
auto attrTableSize = attributeTable.size();
attributeTable.resize(attrTableSize + entryLength, 0);
struct pldm_bios_table_attr_entry_enum_info info = {
strHandle,
readOnly,
(uint8_t)possiValsByHdl.size(),
possiValsByHdl.data(),
(uint8_t)defValsByHdl.size(),
defValsByHdl.data(),
};
pldm_bios_table_attr_entry_enum_encode(
attributeTable.data() + attrTableSize, entryLength, &info);
}
}
void constructAttrValueEntry(
const struct pldm_bios_attr_table_entry* attrTableEntry,
const std::string& attrName, const BIOSTable& BIOSStringTable,
Table& attrValueTable)
{
CurrentValues currVals;
try
{
currVals = getAttrValue(attrName);
}
catch (const std::exception& e)
{
log<level::ERR>("getAttrValue returned error for attribute",
entry("NAME=%s", attrName.c_str()),
entry("ERROR=%s", e.what()));
return;
}
uint8_t pv_num =
pldm_bios_table_attr_entry_enum_decode_pv_num(attrTableEntry);
PossibleValuesByHandle pvHdls(pv_num, 0);
pldm_bios_table_attr_entry_enum_decode_pv_hdls(attrTableEntry,
pvHdls.data(), pv_num);
std::sort(currVals.begin(), currVals.end());
auto currValStrIndices = findStrIndices(pvHdls, currVals, BIOSStringTable);
auto entryLength = pldm_bios_table_attr_value_entry_encode_enum_length(
currValStrIndices.size());
auto tableSize = attrValueTable.size();
attrValueTable.resize(tableSize + entryLength);
pldm_bios_table_attr_value_entry_encode_enum(
attrValueTable.data() + tableSize, entryLength,
attrTableEntry->attr_handle, attrTableEntry->attr_type,
currValStrIndices.size(), currValStrIndices.data());
}
} // end namespace bios_type_enum
namespace bios_type_string
{
using namespace bios_parser::bios_string;
/** @brief Construct the attibute table for BIOS type String and
* String ReadOnly
* @param[in] BIOSStringTable - the string table
* @param[in] biosJsonDir - path where the BIOS json files are present
* @param[in,out] attributeTable - the attribute table
*
*/
void constructAttrTable(const BIOSTable& BIOSStringTable, Table& attributeTable)
{
const auto& attributeMap = getValues();
StringHandle strHandle;
for (const auto& [key, value] : attributeMap)
{
try
{
strHandle = findStringHandle(key, BIOSStringTable);
}
catch (InternalFailure& e)
{
log<level::ERR>("Could not find handle for BIOS string",
entry("ATTRIBUTE=%s", key.c_str()));
continue;
}
const auto& [readOnly, strType, minStrLen, maxStrLen, defaultStrLen,
defaultStr] = value;
auto entryLength =
pldm_bios_table_attr_entry_string_encode_length(defaultStrLen);
struct pldm_bios_table_attr_entry_string_info info = {
strHandle, readOnly, strType, minStrLen,
maxStrLen, defaultStrLen, defaultStr.data(),
};
auto attrTableSize = attributeTable.size();
attributeTable.resize(attrTableSize + entryLength, 0);
pldm_bios_table_attr_entry_string_encode(
attributeTable.data() + attrTableSize, entryLength, &info);
}
}
void constructAttrValueEntry(const pldm_bios_attr_table_entry* attrTableEntry,
const std::string& attrName,
const BIOSTable& BIOSStringTable,
Table& attrValueTable)
{
std::ignore = BIOSStringTable;
std::string currStr;
uint16_t currStrLen = 0;
try
{
currStr = getAttrValue(attrName);
currStrLen = currStr.size();
}
catch (const std::exception& e)
{
log<level::ERR>("getAttrValue returned error for attribute",
entry("NAME=%s", attrName.c_str()),
entry("ERROR=%s", e.what()));
return;
}
auto entryLength =
pldm_bios_table_attr_value_entry_encode_string_length(currStrLen);
auto tableSize = attrValueTable.size();
attrValueTable.resize(tableSize + entryLength);
pldm_bios_table_attr_value_entry_encode_string(
attrValueTable.data() + tableSize, entryLength,
attrTableEntry->attr_handle, attrTableEntry->attr_type, currStrLen,
currStr.c_str());
}
} // end namespace bios_type_string
namespace bios_type_integer
{
using namespace bios_parser::bios_integer;
/** @brief Construct the attibute table for BIOS type Integer and
* Integer ReadOnly
* @param[in] BIOSStringTable - the string table
* @param[in,out] attributeTable - the attribute table
*
*/
void constructAttrTable(const BIOSTable& BIOSStringTable, Table& attributeTable)
{
const auto& attributeMap = getValues();
StringHandle strHandle;
for (const auto& [key, value] : attributeMap)
{
try
{
strHandle = findStringHandle(key, BIOSStringTable);
}
catch (InternalFailure& e)
{
log<level::ERR>("Could not find handle for BIOS string",
entry("ATTRIBUTE=%s", key.c_str()));
continue;
}
const auto& [readOnly, lowerBound, upperBound, scalarIncrement,
defaultValue] = value;
auto entryLength = pldm_bios_table_attr_entry_integer_encode_length();
struct pldm_bios_table_attr_entry_integer_info info = {
strHandle, readOnly, lowerBound,
upperBound, scalarIncrement, defaultValue,
};
auto attrTableSize = attributeTable.size();
attributeTable.resize(attrTableSize + entryLength, 0);
pldm_bios_table_attr_entry_integer_encode(
attributeTable.data() + attrTableSize, entryLength, &info);
}
}
void constructAttrValueEntry(const pldm_bios_attr_table_entry* attrTableEntry,
const std::string& attrName,
const BIOSTable& BIOSStringTable,
Table& attrValueTable)
{
std::ignore = BIOSStringTable;
uint64_t currentValue;
try
{
currentValue = getAttrValue(attrName);
}
catch (const std::exception& e)
{
log<level::ERR>("Failed to get attribute value",
entry("NAME=%s", attrName.c_str()),
entry("ERROR=%s", e.what()));
return;
}
auto entryLength = pldm_bios_table_attr_value_entry_encode_integer_length();
auto tableSize = attrValueTable.size();
attrValueTable.resize(tableSize + entryLength);
pldm_bios_table_attr_value_entry_encode_integer(
attrValueTable.data() + tableSize, entryLength,
attrTableEntry->attr_handle, attrTableEntry->attr_type, currentValue);
}
} // namespace bios_type_integer
void traverseBIOSAttrTable(const Table& biosAttrTable,
AttrTableEntryHandler handler)
{
std::unique_ptr<pldm_bios_table_iter, decltype(&pldm_bios_table_iter_free)>
iter(pldm_bios_table_iter_create(biosAttrTable.data(),
biosAttrTable.size(),
PLDM_BIOS_ATTR_TABLE),
pldm_bios_table_iter_free);
while (!pldm_bios_table_iter_is_end(iter.get()))
{
auto table_entry = pldm_bios_table_iter_attr_entry_value(iter.get());
try
{
handler(table_entry);
}
catch (const std::exception& e)
{
log<level::ERR>("handler fails when traversing BIOSAttrTable",
entry("ERROR=%s", e.what()));
}
pldm_bios_table_iter_next(iter.get());
}
}
using typeHandler = std::function<void(const BIOSTable& BIOSStringTable,
Table& attributeTable)>;
std::map<BIOSJsonName, typeHandler> attrTypeHandlers{
{bios_parser::bIOSEnumJson, bios_type_enum::constructAttrTable},
{bios_parser::bIOSStrJson, bios_type_string::constructAttrTable},
{bios_parser::bIOSIntegerJson, bios_type_integer::constructAttrTable},
};
/** @brief Construct the BIOS attribute table
*
* @param[in] BIOSAttributeTable - the attribute table
* @param[in] BIOSStringTable - the string table
* @param[in] transferHandle - transfer handle to identify part of transfer
* @param[in] transferOpFlag - flag to indicate which part of data being
* transferred
* @param[in] instanceID - instance ID to identify the command
* @param[in] biosJsonDir - path where the BIOS json files are present
*/
Response getBIOSAttributeTable(BIOSTable& BIOSAttributeTable,
const BIOSTable& BIOSStringTable,
uint32_t /*transferHandle*/,
uint8_t /*transferOpFlag*/, uint8_t instanceID,
const char* biosJsonDir)
{
Response response(sizeof(pldm_msg_hdr) + PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES,
0);
auto responsePtr = reinterpret_cast<pldm_msg*>(response.data());
uint32_t nxtTransferHandle = 0;
uint8_t transferFlag = PLDM_START_AND_END;
if (BIOSAttributeTable.isEmpty())
{ // no persisted table, constructing fresh table and response
Table attributeTable;
fs::path dir(biosJsonDir);
for (auto it = attrTypeHandlers.begin(); it != attrTypeHandlers.end();
it++)
{
fs::path file = dir / it->first;
if (fs::exists(file))
{
it->second(BIOSStringTable, attributeTable);
}
}
if (attributeTable.empty())
{ // no available json file is found
encode_get_bios_table_resp(instanceID, PLDM_BIOS_TABLE_UNAVAILABLE,
nxtTransferHandle, transferFlag, nullptr,
response.size(), responsePtr);
return response;
}
utils::padAndChecksum(attributeTable);
BIOSAttributeTable.store(attributeTable);
response.resize(sizeof(pldm_msg_hdr) +
PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES +
attributeTable.size());
responsePtr = reinterpret_cast<pldm_msg*>(response.data());
encode_get_bios_table_resp(instanceID, PLDM_SUCCESS, nxtTransferHandle,
transferFlag, attributeTable.data(),
response.size(), responsePtr);
}
else
{ // persisted table present, constructing response
encode_get_bios_table_resp(instanceID, PLDM_SUCCESS, nxtTransferHandle,
transferFlag, nullptr, response.size(),
responsePtr); // filling up the header here
BIOSAttributeTable.load(response);
}
return response;
}
using AttrValTableEntryConstructHandler =
std::function<void(const struct pldm_bios_attr_table_entry* tableEntry,
const std::string& attrName,
const BIOSTable& BIOSStringTable, Table& table)>;
using AttrType = uint8_t;
const std::map<AttrType, AttrValTableEntryConstructHandler>
AttrValTableConstructMap{
{PLDM_BIOS_STRING, bios_type_string::constructAttrValueEntry},
{PLDM_BIOS_STRING_READ_ONLY, bios_type_string::constructAttrValueEntry},
{PLDM_BIOS_ENUMERATION, bios_type_enum::constructAttrValueEntry},
{PLDM_BIOS_ENUMERATION_READ_ONLY,
bios_type_enum::constructAttrValueEntry},
{PLDM_BIOS_INTEGER, bios_type_integer::constructAttrValueEntry},
{PLDM_BIOS_INTEGER_READ_ONLY,
bios_type_integer::constructAttrValueEntry},
};
void constructAttrValueTableEntry(
const struct pldm_bios_attr_table_entry* attrEntry,
const BIOSTable& BIOSStringTable, Table& attributeValueTable)
{
auto attrName = findStringName(attrEntry->string_handle, BIOSStringTable);
if (attrName.empty())
{
log<level::ERR>("invalid string handle",
entry("STRING_HANDLE=%d", attrEntry->string_handle));
return;
}
AttrValTableConstructMap.at(attrEntry->attr_type)(
attrEntry, attrName, BIOSStringTable, attributeValueTable);
}
/** @brief Construct the BIOS attribute value table
*
* @param[in] BIOSAttributeValueTable - the attribute value table
* @param[in] BIOSAttributeTable - the attribute table
* @param[in] BIOSStringTable - the string table
* @param[in] transferHandle - transfer handle to identify part of transfer
* @param[in] transferOpFlag - flag to indicate which part of data being
* transferred
* @param[in] instanceID - instance ID to identify the command
*/
Response getBIOSAttributeValueTable(BIOSTable& BIOSAttributeValueTable,
const BIOSTable& BIOSAttributeTable,
const BIOSTable& BIOSStringTable,
uint32_t& /*transferHandle*/,
uint8_t& /*transferOpFlag*/,
uint8_t instanceID)
{
Response response(sizeof(pldm_msg_hdr) + PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES,
0);
auto responsePtr = reinterpret_cast<pldm_msg*>(response.data());
uint32_t nxtTransferHandle = 0;
uint8_t transferFlag = PLDM_START_AND_END;
if (!BIOSAttributeValueTable.isEmpty())
{
encode_get_bios_table_resp(instanceID, PLDM_SUCCESS, nxtTransferHandle,
transferFlag, nullptr, response.size(),
responsePtr); // filling up the header here
BIOSAttributeValueTable.load(response);
return response;
}
Table attributeValueTable;
Table attributeTable;
BIOSAttributeTable.load(attributeTable);
traverseBIOSAttrTable(
attributeTable,
[&BIOSStringTable, &attributeValueTable](
const struct pldm_bios_attr_table_entry* tableEntry) {
constructAttrValueTableEntry(tableEntry, BIOSStringTable,
attributeValueTable);
});
if (attributeValueTable.empty())
{
encode_get_bios_table_resp(instanceID, PLDM_BIOS_TABLE_UNAVAILABLE,
nxtTransferHandle, transferFlag, nullptr,
response.size(), responsePtr);
return response;
}
utils::padAndChecksum(attributeValueTable);
BIOSAttributeValueTable.store(attributeValueTable);
response.resize(sizeof(pldm_msg_hdr) + PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES +
attributeValueTable.size());
responsePtr = reinterpret_cast<pldm_msg*>(response.data());
encode_get_bios_table_resp(instanceID, PLDM_SUCCESS, nxtTransferHandle,
transferFlag, attributeValueTable.data(),
response.size(), responsePtr);
return response;
}
Response getBIOSTable(const pldm_msg* request, size_t payloadLength)
{
fs::create_directory(BIOS_TABLES_DIR);
auto response = internal::buildBIOSTables(request, payloadLength,
BIOS_JSONS_DIR, BIOS_TABLES_DIR);
return response;
}
namespace bios
{
void registerHandlers()
{
registerHandler(PLDM_BIOS, PLDM_GET_DATE_TIME, std::move(getDateTime));
registerHandler(PLDM_BIOS, PLDM_GET_BIOS_TABLE, std::move(getBIOSTable));
}
namespace internal
{
Response buildBIOSTables(const pldm_msg* request, size_t payloadLength,
const char* biosJsonDir, const char* biosTablePath)
{
Response response(sizeof(pldm_msg_hdr) + PLDM_GET_BIOS_TABLE_MIN_RESP_BYTES,
0);
auto responsePtr = reinterpret_cast<pldm_msg*>(response.data());
if (setupConfig(biosJsonDir) != 0)
{
encode_get_bios_table_resp(
request->hdr.instance_id, PLDM_BIOS_TABLE_UNAVAILABLE,
0 /* nxtTransferHandle */, PLDM_START_AND_END, nullptr,
response.size(), responsePtr);
return response;
}
uint32_t transferHandle{};
uint8_t transferOpFlag{};
uint8_t tableType{};
auto rc = decode_get_bios_table_req(request, payloadLength, &transferHandle,
&transferOpFlag, &tableType);
if (rc == PLDM_SUCCESS)
{
BIOSTable BIOSStringTable(
((std::string(biosTablePath) + "/stringTable")).c_str());
BIOSTable BIOSAttributeTable(
((std::string(biosTablePath) + "/attributeTable")).c_str());
BIOSTable BIOSAttributeValueTable(
((std::string(biosTablePath) + "/attributeValueTable")).c_str());
switch (tableType)
{
case PLDM_BIOS_STRING_TABLE:
response = getBIOSStringTable(BIOSStringTable, transferHandle,
transferOpFlag,
request->hdr.instance_id);
break;
case PLDM_BIOS_ATTR_TABLE:
if (BIOSStringTable.isEmpty())
{
rc = PLDM_BIOS_TABLE_UNAVAILABLE;
}
else
{
response = getBIOSAttributeTable(
BIOSAttributeTable, BIOSStringTable, transferHandle,
transferOpFlag, request->hdr.instance_id, biosJsonDir);
}
break;
case PLDM_BIOS_ATTR_VAL_TABLE:
if (BIOSAttributeTable.isEmpty() || BIOSStringTable.isEmpty())
{
rc = PLDM_BIOS_TABLE_UNAVAILABLE;
}
else
{
response = getBIOSAttributeValueTable(
BIOSAttributeValueTable, BIOSAttributeTable,
BIOSStringTable, transferHandle, transferOpFlag,
request->hdr.instance_id);
}
break;
default:
rc = PLDM_INVALID_BIOS_TABLE_TYPE;
break;
}
}
if (rc != PLDM_SUCCESS)
{
uint32_t nxtTransferHandle{};
uint8_t transferFlag{};
size_t respPayloadLength{};
encode_get_bios_table_resp(request->hdr.instance_id, rc,
nxtTransferHandle, transferFlag, nullptr,
respPayloadLength, responsePtr);
}
return response;
}
} // end namespace internal
} // namespace bios
} // namespace responder
} // namespace pldm