void processFdbEntriesForAging()
{
    SWSS_LOG_ENTER();

    if (!g_recursive_mutex.try_lock())
    {
        return;
    }

    SWSS_LOG_INFO("fdb infos to process: %zu", g_fdb_info_set.size());

    uint32_t current = (uint32_t)time(NULL);

    // find aged fdb entries

    for (auto it = g_fdb_info_set.begin(); it != g_fdb_info_set.end();)
    {
        sai_attribute_t attr;

        attr.id = SAI_SWITCH_ATTR_FDB_AGING_TIME;

        sai_status_t status = vs_generic_get(SAI_OBJECT_TYPE_SWITCH, it->fdb_entry.switch_id, 1, &attr);

        if (status != SAI_STATUS_SUCCESS)
        {
            SWSS_LOG_WARN("failed to get FDB aging time for switch %s",
                    sai_serialize_object_id(it->fdb_entry.switch_id).c_str());

            ++it;
            continue;
        }

        uint32_t aging_time = attr.value.u32;

        if (aging_time == 0)
        {
            // aging is disabled
            ++it;
            continue;
        }

        if ((current - it->timestamp) >= aging_time)
        {
            fdb_info_t fi = *it;

            processFdbInfo(fi, SAI_FDB_EVENT_AGED);

            it = g_fdb_info_set.erase(it);
        }
        else
        {
            ++it;
        }
    }

    g_recursive_mutex.unlock();
}
Exemple #2
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// Read the Wiimote once
void Update(int _WiimoteNumber)
{
	// Try to get a lock and return without doing anything if we fail
	// This avoids deadlocks when adding a Wiimote during continuous scan
	if(!g_refresh_lock.try_lock())
		return;

	if (g_wiimotes[_WiimoteNumber])
		g_wiimotes[_WiimoteNumber]->Update();

	// Wiimote::Update() may remove the Wiimote if it was disconnected.
	if (!g_wiimotes[_WiimoteNumber])
	{
		Host_ConnectWiimote(_WiimoteNumber, false);
	}
	g_refresh_lock.unlock();
}