blob: cdf1cfd6a09da2fa8d4de51746220a6901a55b34 [file] [log] [blame]
#include <libpldm/platform.h>
#include <libpldm/pldm.h>
#include <libpldm/state_set_oem_ibm.h>
#include <util/dbus.hpp>
#include <util/trace.hpp>
namespace util
{
namespace pldm
{
/** @brief Send PLDM request
*
* @param[in] request - the request data
* @param[in] mcptEid - the mctp endpoint ID
* @param[out] pldmFd - pldm socket file descriptor
*
* @pre a mctp instance must have been
* @return true if send is successful false otherwise
*/
bool sendPldm(const std::vector<uint8_t>& request, uint8_t mctpEid, int& pldmFd)
{
// connect to socket
pldmFd = pldm_open();
if (-1 == pldmFd)
{
trace::err("failed to connect to pldm");
return false;
}
// send PLDM request
auto pldmRc = pldm_send(mctpEid, pldmFd, request.data(), request.size());
trace::inf("sent pldm request");
return pldmRc == PLDM_REQUESTER_SUCCESS ? true : false;
}
/** @brief Prepare a request for SetStateEffecterStates
*
* @param[in] effecterId - the effecter ID
* @param[in] effecterCount - composite effecter count
* @param[in] stateIdPos - position of the state set
* @param[in] stateSetValue - the value to set the state
* @param[in] mcptEid - the MCTP endpoint ID
*
* @return PLDM request message to be sent to host, empty message on error
*/
std::vector<uint8_t> prepareSetEffecterReq(uint16_t effecterId,
uint8_t effecterCount,
uint8_t stateIdPos,
uint8_t stateSetValue,
uint8_t mctpEid)
{
// get mctp instance associated with the endpoint ID
uint8_t mctpInstance;
if (!util::dbus::getMctpInstance(mctpInstance, mctpEid))
{
return std::vector<uint8_t>();
}
// form the request message
std::vector<uint8_t> request(
sizeof(pldm_msg_hdr) + sizeof(effecterId) + sizeof(effecterCount) +
(effecterCount * sizeof(set_effecter_state_field)));
// encode the state data with the change we want to elicit
std::vector<set_effecter_state_field> stateField;
for (uint8_t effecterPos = 0; effecterPos < effecterCount; effecterPos++)
{
if (effecterPos == stateIdPos)
{
stateField.emplace_back(
set_effecter_state_field{PLDM_REQUEST_SET, stateSetValue});
}
else
{
stateField.emplace_back(
set_effecter_state_field{PLDM_NO_CHANGE, 0});
}
}
// encode the message with state data
auto requestMsg = reinterpret_cast<pldm_msg*>(request.data());
auto rc = encode_set_state_effecter_states_req(
mctpInstance, effecterId, effecterCount, stateField.data(), requestMsg);
if (rc != PLDM_SUCCESS)
{
trace::err("encode set effecter states request failed");
request.clear();
}
return request;
}
/** @brief Return map of sensor ID to SBE instance
*
* @param[in] stateSetId - the state set ID of interest
* @param[out] sensorInstanceMap - map of sensor to SBE instance
* @param[out] sensorOffset - position of sensor with state set ID within map
*
* @return true if sensor info is available false otherwise
*/
bool fetchSensorInfo(uint16_t stateSetId,
std::map<uint16_t, unsigned int>& sensorInstanceMap,
uint8_t& sensorOffset)
{
// get state sensor PDRs
std::vector<std::vector<uint8_t>> pdrs{};
if (!util::dbus::getStateSensorPdrs(pdrs, stateSetId))
{
return false;
}
// check for any PDRs available
if (!pdrs.size())
{
trace::err("state sensor PDRs not present");
return false;
}
// find the offset of specified sensor withing PDRs
bool offsetFound = false;
auto stateSensorPDR =
reinterpret_cast<const pldm_state_sensor_pdr*>(pdrs.front().data());
auto possibleStatesPtr = stateSensorPDR->possible_states;
for (auto offset = 0; offset < stateSensorPDR->composite_sensor_count;
offset++)
{
auto possibleStates =
reinterpret_cast<const state_sensor_possible_states*>(
possibleStatesPtr);
if (possibleStates->state_set_id == stateSetId)
{
sensorOffset = offset;
offsetFound = true;
break;
}
possibleStatesPtr += sizeof(possibleStates->state_set_id) +
sizeof(possibleStates->possible_states_size) +
possibleStates->possible_states_size;
}
if (!offsetFound)
{
trace::err("state sensor not found");
return false;
}
// map sensor ID to equivelent 16 bit value
std::map<uint32_t, uint16_t> entityInstMap{};
for (auto& pdr : pdrs)
{
auto pdrPtr =
reinterpret_cast<const pldm_state_sensor_pdr*>(pdr.data());
uint32_t key = pdrPtr->sensor_id;
entityInstMap.emplace(key, static_cast<uint16_t>(pdrPtr->sensor_id));
}
// map sensor ID to zero based SBE instance
unsigned int position = 0;
for (auto const& pair : entityInstMap)
{
sensorInstanceMap.emplace(pair.second, position);
position++;
}
return true;
}
/** @brief Return map of SBE instance to effecter ID
*
* @param[in] stateSetId - the state set ID of interest
* @param[out] instanceToEffecterMap - map of sbe instance to effecter ID
* @param[out] effecterCount - composite effecter count
* @param[out] stateIdPos - position of effecter with state set ID within map
*
* @return true if effector info is available false otherwise
*/
bool fetchEffecterInfo(uint16_t stateSetId,
std::map<unsigned int, uint16_t>& instanceToEffecterMap,
uint8_t& effecterCount, uint8_t& stateIdPos)
{
// get state effecter PDRs
std::vector<std::vector<uint8_t>> pdrs{};
if (!util::dbus::getStateEffecterPdrs(pdrs, stateSetId))
{
return false;
}
// check for any PDRs available
if (!pdrs.size())
{
trace::err("state effecter PDRs not present");
return false;
}
// find the offset of specified effector within PDRs
bool offsetFound = false;
auto stateEffecterPDR =
reinterpret_cast<const pldm_state_effecter_pdr*>(pdrs.front().data());
auto possibleStatesPtr = stateEffecterPDR->possible_states;
for (auto offset = 0; offset < stateEffecterPDR->composite_effecter_count;
offset++)
{
auto possibleStates =
reinterpret_cast<const state_effecter_possible_states*>(
possibleStatesPtr);
if (possibleStates->state_set_id == stateSetId)
{
stateIdPos = offset;
effecterCount = stateEffecterPDR->composite_effecter_count;
offsetFound = true;
break;
}
possibleStatesPtr += sizeof(possibleStates->state_set_id) +
sizeof(possibleStates->possible_states_size) +
possibleStates->possible_states_size;
}
if (!offsetFound)
{
trace::err("state set effecter not found");
return false;
}
// map effecter ID to equivelent 16 bit value
std::map<uint32_t, uint16_t> entityInstMap{};
for (auto& pdr : pdrs)
{
auto pdrPtr =
reinterpret_cast<const pldm_state_effecter_pdr*>(pdr.data());
uint32_t key = pdrPtr->effecter_id;
entityInstMap.emplace(key, static_cast<uint16_t>(pdrPtr->effecter_id));
}
// map zero based SBE instance to effecter ID
unsigned int position = 0;
for (auto const& pair : entityInstMap)
{
instanceToEffecterMap.emplace(position, pair.second);
position++;
}
return true;
}
/** @brief Reset SBE using HBRT PLDM interface */
bool hresetSbe(unsigned int sbeInstance)
{
trace::inf("requesting sbe hreset");
// get effecter info
std::map<unsigned int, uint16_t> sbeInstanceToEffecter;
uint8_t SBEEffecterCount = 0;
uint8_t sbeMaintenanceStatePosition = 0;
if (!fetchEffecterInfo(PLDM_OEM_IBM_SBE_MAINTENANCE_STATE,
sbeInstanceToEffecter, SBEEffecterCount,
sbeMaintenanceStatePosition))
{
return false;
}
// find the state effecter ID for the given SBE instance
auto effecterEntry = sbeInstanceToEffecter.find(sbeInstance);
if (effecterEntry == sbeInstanceToEffecter.end())
{
trace::err("failed to find effecter for SBE");
return false;
}
// create request to HRESET the SBE
constexpr uint8_t hbrtMctpEid = 10; // HBRT MCTP EID
auto request = prepareSetEffecterReq(
effecterEntry->second, SBEEffecterCount, sbeMaintenanceStatePosition,
SBE_RETRY_REQUIRED, hbrtMctpEid);
if (request.empty())
{
trace::err("HRESET effecter request empty");
return false;
}
// get sensor info for validating sensor change
std::map<uint16_t, unsigned int> sensorToSbeInstance;
uint8_t sbeSensorOffset = 0;
if (!fetchSensorInfo(PLDM_OEM_IBM_SBE_HRESET_STATE, sensorToSbeInstance,
sbeSensorOffset))
{
return false;
}
// register signal change listener
std::string hresetStatus = "requested";
constexpr auto interface = "xyz.openbmc_project.PLDM.Event";
constexpr auto path = "/xyz/openbmc_project/pldm";
constexpr auto member = "StateSensorEvent";
auto bus = sdbusplus::bus::new_default();
std::unique_ptr<sdbusplus::bus::match_t> match =
std::make_unique<sdbusplus::bus::match_t>(
bus,
sdbusplus::bus::match::rules::type::signal() +
sdbusplus::bus::match::rules::member(member) +
sdbusplus::bus::match::rules::path(path) +
sdbusplus::bus::match::rules::interface(interface),
[&](auto& msg) {
uint8_t sensorTid{};
uint16_t sensorId{};
uint8_t msgSensorOffset{};
uint8_t eventState{};
uint8_t previousEventState{};
// get sensor event details
msg.read(sensorTid, sensorId, msgSensorOffset, eventState,
previousEventState);
// does sensor offset match?
if (sbeSensorOffset == msgSensorOffset)
{
// does sensor ID match?
auto sensorEntry = sensorToSbeInstance.find(sensorId);
if (sensorEntry != sensorToSbeInstance.end())
{
const uint8_t instance = sensorEntry->second;
// if instances matche check status
if (instance == sbeInstance)
{
if (eventState ==
static_cast<uint8_t>(SBE_HRESET_READY))
{
hresetStatus = "success";
}
else if (eventState ==
static_cast<uint8_t>(SBE_HRESET_FAILED))
{
hresetStatus = "fail";
}
}
}
}
});
// send request to issue hreset of sbe
int pldmFd = -1; // mctp socket file descriptor
if (!sendPldm(request, hbrtMctpEid, pldmFd))
{
trace::err("send pldm request failed");
if (-1 != pldmFd)
{
close(pldmFd);
}
return false;
}
// keep track of elapsed time
uint64_t timeRemaining = 60000000; // microseconds, 1 minute
std::chrono::steady_clock::time_point begin =
std::chrono::steady_clock::now();
// wait for status update or timeout
trace::inf("waiting on sbe hreset");
while ("requested" == hresetStatus && 0 != timeRemaining)
{
bus.wait(timeRemaining);
uint64_t timeElapsed =
std::chrono::duration_cast<std::chrono::microseconds>(
std::chrono::steady_clock::now() - begin)
.count();
timeRemaining =
timeElapsed > timeRemaining ? 0 : timeRemaining - timeElapsed;
bus.process_discard();
}
if (0 == timeRemaining)
{
trace::err("hreset timed out");
}
close(pldmFd); // close pldm socket
return hresetStatus == "success" ? true : false;
}
} // namespace pldm
} // namespace util