blob: c3c142f06bc16f6ce67c0f146c7d69b222278ced [file] [log] [blame]
#include "manager.hpp"
#include <phosphor-logging/log.hpp>
#include <sdbusplus/exception.hpp>
#include <xyz/openbmc_project/Led/Physical/server.hpp>
#include <algorithm>
#include <iostream>
#include <string>
namespace phosphor
{
namespace led
{
using namespace phosphor::logging;
// Assert -or- De-assert
bool Manager::setGroupState(const std::string& path, bool assert,
group& ledsAssert, group& ledsDeAssert)
{
if (assert)
{
assertedGroups.insert(&ledMap.at(path));
}
else
{
auto search = assertedGroups.find(&ledMap.at(path));
if (search != assertedGroups.end())
{
assertedGroups.erase(&ledMap.at(path));
}
}
// This will contain the union of what's already in the asserted group
group desiredState{};
for (const auto& grp : assertedGroups)
{
desiredState.insert(grp->cbegin(), grp->cend());
}
// Find difference between Combined and Desired to identify
// which LEDs are getting altered
group transient{};
std::set_difference(combinedState.begin(), combinedState.end(),
desiredState.begin(), desiredState.end(),
std::inserter(transient, transient.begin()), ledComp);
if (transient.size())
{
// Find common LEDs between transient and Desired to know if some LEDs
// are changing state and not really getting DeAsserted
group ledsTransient{};
std::set_intersection(
transient.begin(), transient.end(), desiredState.begin(),
desiredState.end(),
std::inserter(ledsTransient, ledsTransient.begin()), ledLess);
// Find difference between above 2 to identify those LEDs which are
// really getting DeAsserted
std::set_difference(transient.begin(), transient.end(),
ledsTransient.begin(), ledsTransient.end(),
std::inserter(ledsDeAssert, ledsDeAssert.begin()),
ledLess);
// Remove the elements from Current that are being DeAsserted.
if (ledsDeAssert.size())
{
// Power off LEDs that are to be really DeAsserted
for (auto& it : ledsDeAssert)
{
// Update LEDs in "physically asserted" set by removing those
// LEDs which are De-Asserted
auto found = currentState.find(it);
if (found != currentState.end())
{
currentState.erase(found);
}
}
}
}
// Now LEDs that are to be Asserted. These could either be fresh asserts
// -or- change between [On]<-->[Blink]
group temp{};
std::unique_copy(desiredState.begin(), desiredState.end(),
std::inserter(temp, temp.begin()), ledEqual);
if (temp.size())
{
// Find difference between [desired to be Asserted] and those LEDs
// that are physically asserted currently.
std::set_difference(
temp.begin(), temp.end(), currentState.begin(), currentState.end(),
std::inserter(ledsAssert, ledsAssert.begin()), ledComp);
}
// Update the current actual and desired(the virtual actual)
currentState = std::move(temp);
combinedState = std::move(desiredState);
// If we survive, then set the state accordingly.
return assert;
}
/** @brief Run through the map and apply action on the LEDs */
void Manager::driveLEDs(group& ledsAssert, group& ledsDeAssert)
{
// This order of LED operation is important.
if (ledsDeAssert.size())
{
for (const auto& it : ledsDeAssert)
{
std::string objPath = std::string(PHY_LED_PATH) + it.name;
log<level::DEBUG>("De-Asserting LED",
entry("NAME=%s", it.name.c_str()));
drivePhysicalLED(objPath, Layout::Action::Off, it.dutyOn,
it.period);
}
}
if (ledsAssert.size())
{
for (const auto& it : ledsAssert)
{
std::string objPath = std::string(PHY_LED_PATH) + it.name;
log<level::DEBUG>("Asserting LED",
entry("NAME=%s", it.name.c_str()));
drivePhysicalLED(objPath, it.action, it.dutyOn, it.period);
}
}
return;
}
// Calls into driving physical LED post choosing the action
void Manager::drivePhysicalLED(const std::string& objPath,
Layout::Action action, uint8_t dutyOn,
const uint16_t period)
{
try
{
// If Blink, set its property
if (action == Layout::Action::Blink)
{
PropertyValue dutyOnValue{dutyOn};
PropertyValue periodValue{period};
dBusHandler.setProperty(objPath, PHY_LED_IFACE, "DutyOn",
dutyOnValue);
dBusHandler.setProperty(objPath, PHY_LED_IFACE, "Period",
periodValue);
}
PropertyValue actionValue{getPhysicalAction(action)};
dBusHandler.setProperty(objPath, PHY_LED_IFACE, "State", actionValue);
}
catch (const std::exception& e)
{
log<level::ERR>("Error setting property for physical LED",
entry("ERROR=%s", e.what()),
entry("OBJECT_PATH=%s", objPath.c_str()));
}
return;
}
/** @brief Returns action string based on enum */
std::string Manager::getPhysicalAction(Layout::Action action)
{
namespace server = sdbusplus::xyz::openbmc_project::Led::server;
// TODO: openbmc/phosphor-led-manager#5
// Somehow need to use the generated Action enum than giving one
// in ledlayout.
if (action == Layout::Action::On)
{
return server::convertForMessage(server::Physical::Action::On);
}
else if (action == Layout::Action::Blink)
{
return server::convertForMessage(server::Physical::Action::Blink);
}
else
{
return server::convertForMessage(server::Physical::Action::Off);
}
}
// Set OperationalStatus functional according to the asserted state of the group
void Manager::setOperationalStatus(const std::string& path, bool value) const
{
using namespace phosphor::logging;
// Get endpoints from the rType
std::string fru = path + "/fru_fault";
// endpoint contains the vector of strings, where each string is a Inventory
// D-Bus object that this, associated with this LED Group D-Bus object
// pointed to by fru_fault
PropertyValue endpoint{};
try
{
endpoint = dBusHandler.getProperty(
fru, "xyz.openbmc_project.Association", "endpoints");
}
catch (const sdbusplus::exception::SdBusError& e)
{
log<level::ERR>("Failed to get endpoints property",
entry("ERROR=%s", e.what()),
entry("PATH=%s", fru.c_str()));
return;
}
auto& endpoints = std::get<std::vector<std::string>>(endpoint);
if (endpoints.empty())
{
return;
}
for (const auto& fruInstancePath : endpoints)
{
// Set OperationalStatus by fru instance path
try
{
PropertyValue functionalValue{value};
dBusHandler.setProperty(
fruInstancePath,
"xyz.openbmc_project.State.Decorator.OperationalStatus",
"Functional", functionalValue);
}
catch (const sdbusplus::exception::SdBusError& e)
{
log<level::ERR>("Failed to set Functional property",
entry("ERROR=%s", e.what()),
entry("PATH=%s", fruInstancePath.c_str()));
}
}
}
} // namespace led
} // namespace phosphor