/* * Copyright (C) 2012 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* * A service that exchanges time synchronization information between * a master that defines a timeline and clients that follow the timeline. */ #define LOG_TAG "common_time" #include <utils/Log.h> #include <binder/IServiceManager.h> #include <binder/IPCThreadState.h> #include "common_time_server.h" namespace android { // // Clock API // uint64_t CommonTimeServer::getTimelineID() { AutoMutex _lock(&mLock); return mTimelineID; } ICommonClock::State CommonTimeServer::getState() { AutoMutex _lock(&mLock); return mState; } status_t CommonTimeServer::getMasterAddr(struct sockaddr_storage* addr) { AutoMutex _lock(&mLock); if (mMasterEPValid) { memcpy(addr, &mMasterEP, sizeof(*addr)); return OK; } return UNKNOWN_ERROR; } int32_t CommonTimeServer::getEstimatedError() { AutoMutex _lock(&mLock); if (ICommonClock::STATE_MASTER == mState) return 0; if (!mClockSynced) return ICommonClock::kErrorEstimateUnknown; return mClockRecovery.getLastErrorEstimate(); } status_t CommonTimeServer::isCommonTimeValid(bool* valid, uint32_t* timelineID) { AutoMutex _lock(&mLock); *valid = mCommonClock.isValid(); *timelineID = mTimelineID; return OK; } // // Config API // status_t CommonTimeServer::getMasterElectionPriority(uint8_t *priority) { AutoMutex _lock(&mLock); *priority = mMasterPriority; return OK; } status_t CommonTimeServer::setMasterElectionPriority(uint8_t priority) { AutoMutex _lock(&mLock); if (priority > 0x7F) return BAD_VALUE; mMasterPriority = priority; return OK; } status_t CommonTimeServer::getMasterElectionEndpoint( struct sockaddr_storage *addr) { AutoMutex _lock(&mLock); memcpy(addr, &mMasterElectionEP, sizeof(*addr)); return OK; } status_t CommonTimeServer::setMasterElectionEndpoint( const struct sockaddr_storage *addr) { AutoMutex _lock(&mLock); if (!addr) return BAD_VALUE; // TODO: add proper support for IPv6 if (addr->ss_family != AF_INET) return BAD_VALUE; // Only multicast and broadcast endpoints with explicit ports are allowed. uint16_t ipv4Port = ntohs( reinterpret_cast<const struct sockaddr_in*>(addr)->sin_port); if (!ipv4Port) return BAD_VALUE; uint32_t ipv4Addr = ntohl( reinterpret_cast<const struct sockaddr_in*>(addr)->sin_addr.s_addr); if ((ipv4Addr != 0xFFFFFFFF) && (0xE0000000 != (ipv4Addr & 0xF0000000))) return BAD_VALUE; memcpy(&mMasterElectionEP, addr, sizeof(mMasterElectionEP)); // Force a rebind in order to change election enpoints. mBindIfaceDirty = true; wakeupThread_l(); return OK; } status_t CommonTimeServer::getMasterElectionGroupId(uint64_t *id) { AutoMutex _lock(&mLock); *id = mSyncGroupID; return OK; } status_t CommonTimeServer::setMasterElectionGroupId(uint64_t id) { AutoMutex _lock(&mLock); mSyncGroupID = id; return OK; } status_t CommonTimeServer::getInterfaceBinding(String8& ifaceName) { AutoMutex _lock(&mLock); if (!mBindIfaceValid) return INVALID_OPERATION; ifaceName = mBindIface; return OK; } status_t CommonTimeServer::setInterfaceBinding(const String8& ifaceName) { AutoMutex _lock(&mLock); mBindIfaceDirty = true; if (ifaceName.size()) { mBindIfaceValid = true; mBindIface = ifaceName; } else { mBindIfaceValid = false; mBindIface.clear(); } wakeupThread_l(); return OK; } status_t CommonTimeServer::getMasterAnnounceInterval(int *interval) { AutoMutex _lock(&mLock); *interval = mMasterAnnounceIntervalMs; return OK; } status_t CommonTimeServer::setMasterAnnounceInterval(int interval) { AutoMutex _lock(&mLock); if (interval > (6 *3600000)) // Max interval is once every 6 hrs return BAD_VALUE; if (interval < 500) // Min interval is once per 0.5 seconds return BAD_VALUE; mMasterAnnounceIntervalMs = interval; if (ICommonClock::STATE_MASTER == mState) { int pendingTimeout = mCurTimeout.msecTillTimeout(); if ((kInfiniteTimeout == pendingTimeout) || (pendingTimeout > interval)) { mCurTimeout.setTimeout(mMasterAnnounceIntervalMs); wakeupThread_l(); } } return OK; } status_t CommonTimeServer::getClientSyncInterval(int *interval) { AutoMutex _lock(&mLock); *interval = mSyncRequestIntervalMs; return OK; } status_t CommonTimeServer::setClientSyncInterval(int interval) { AutoMutex _lock(&mLock); if (interval > (3600000)) // Max interval is once every 60 min return BAD_VALUE; if (interval < 250) // Min interval is once per 0.25 seconds return BAD_VALUE; mSyncRequestIntervalMs = interval; if (ICommonClock::STATE_CLIENT == mState) { int pendingTimeout = mCurTimeout.msecTillTimeout(); if ((kInfiniteTimeout == pendingTimeout) || (pendingTimeout > interval)) { mCurTimeout.setTimeout(mSyncRequestIntervalMs); wakeupThread_l(); } } return OK; } status_t CommonTimeServer::getPanicThreshold(int *threshold) { AutoMutex _lock(&mLock); *threshold = mPanicThresholdUsec; return OK; } status_t CommonTimeServer::setPanicThreshold(int threshold) { AutoMutex _lock(&mLock); if (threshold < 1000) // Min threshold is 1mSec return BAD_VALUE; mPanicThresholdUsec = threshold; return OK; } status_t CommonTimeServer::getAutoDisable(bool *autoDisable) { AutoMutex _lock(&mLock); *autoDisable = mAutoDisable; return OK; } status_t CommonTimeServer::setAutoDisable(bool autoDisable) { AutoMutex _lock(&mLock); mAutoDisable = autoDisable; wakeupThread_l(); return OK; } status_t CommonTimeServer::forceNetworklessMasterMode() { AutoMutex _lock(&mLock); // Can't force networkless master mode if we are currently bound to a // network. if (mSocket >= 0) return INVALID_OPERATION; becomeMaster("force networkless"); return OK; } void CommonTimeServer::reevaluateAutoDisableState(bool commonClockHasClients) { AutoMutex _lock(&mLock); bool needWakeup = (mAutoDisable && mMasterEPValid && (commonClockHasClients != mCommonClockHasClients)); mCommonClockHasClients = commonClockHasClients; if (needWakeup) { ALOGI("Waking up service, auto-disable is engaged and service now has%s" " clients", mCommonClockHasClients ? "" : " no"); wakeupThread_l(); } } #define dump_printf(a, b...) do { \ int res; \ res = snprintf(buffer, sizeof(buffer), a, b); \ buffer[sizeof(buffer) - 1] = 0; \ if (res > 0) \ write(fd, buffer, res); \ } while (0) #define checked_percentage(a, b) ((0 == b) ? 0.0f : ((100.0f * a) / b)) status_t CommonTimeServer::dumpClockInterface(int fd, const Vector<String16>& args, size_t activeClients) { AutoMutex _lock(&mLock); const size_t SIZE = 256; char buffer[SIZE]; if (checkCallingPermission(String16("android.permission.DUMP")) == false) { snprintf(buffer, SIZE, "Permission Denial: " "can't dump CommonClockService from pid=%d, uid=%d\n", IPCThreadState::self()->getCallingPid(), IPCThreadState::self()->getCallingUid()); write(fd, buffer, strlen(buffer)); } else { int64_t commonTime; int64_t localTime; bool synced; char maStr[64]; localTime = mLocalClock.getLocalTime(); synced = (OK == mCommonClock.localToCommon(localTime, &commonTime)); sockaddrToString(mMasterEP, mMasterEPValid, maStr, sizeof(maStr)); dump_printf("Common Clock Service Status\nLocal time : %lld\n", localTime); if (synced) dump_printf("Common time : %lld\n", commonTime); else dump_printf("Common time : %s\n", "not synced"); dump_printf("Timeline ID : %016llx\n", mTimelineID); dump_printf("State : %s\n", stateToString(mState)); dump_printf("Master Addr : %s\n", maStr); if (synced) { int32_t est = (ICommonClock::STATE_MASTER != mState) ? mClockRecovery.getLastErrorEstimate() : 0; dump_printf("Error Est. : %.3f msec\n", static_cast<float>(est) / 1000.0); } else { dump_printf("Error Est. : %s\n", "unknown"); } dump_printf("Syncs TXes : %u\n", mClient_SyncsSentToCurMaster); dump_printf("Syncs RXes : %u (%.2f%%)\n", mClient_SyncRespsRXedFromCurMaster, checked_percentage( mClient_SyncRespsRXedFromCurMaster, mClient_SyncsSentToCurMaster)); dump_printf("RXs Expired : %u (%.2f%%)\n", mClient_ExpiredSyncRespsRXedFromCurMaster, checked_percentage( mClient_ExpiredSyncRespsRXedFromCurMaster, mClient_SyncsSentToCurMaster)); if (!mClient_LastGoodSyncRX) { dump_printf("Last Good RX : %s\n", "unknown"); } else { int64_t localDelta, usecDelta; localDelta = localTime - mClient_LastGoodSyncRX; usecDelta = mCommonClock.localDurationToCommonDuration(localDelta); dump_printf("Last Good RX : %lld uSec ago\n", usecDelta); } dump_printf("Active Clients : %u\n", activeClients); mClient_PacketRTTLog.dumpLog(fd, mCommonClock); } return NO_ERROR; } status_t CommonTimeServer::dumpConfigInterface(int fd, const Vector<String16>& args) { AutoMutex _lock(&mLock); const size_t SIZE = 256; char buffer[SIZE]; if (checkCallingPermission(String16("android.permission.DUMP")) == false) { snprintf(buffer, SIZE, "Permission Denial: " "can't dump CommonTimeConfigService from pid=%d, uid=%d\n", IPCThreadState::self()->getCallingPid(), IPCThreadState::self()->getCallingUid()); write(fd, buffer, strlen(buffer)); } else { char meStr[64]; sockaddrToString(mMasterElectionEP, true, meStr, sizeof(meStr)); dump_printf("Common Time Config Service Status\n" "Bound Interface : %s\n", mBindIfaceValid ? mBindIface.string() : "<unbound>"); dump_printf("Master Election Endpoint : %s\n", meStr); dump_printf("Master Election Group ID : %016llx\n", mSyncGroupID); dump_printf("Master Announce Interval : %d mSec\n", mMasterAnnounceIntervalMs); dump_printf("Client Sync Interval : %d mSec\n", mSyncRequestIntervalMs); dump_printf("Panic Threshold : %d uSec\n", mPanicThresholdUsec); dump_printf("Base ME Prio : 0x%02x\n", static_cast<uint32_t>(mMasterPriority)); dump_printf("Effective ME Prio : 0x%02x\n", static_cast<uint32_t>(effectivePriority())); dump_printf("Auto Disable Allowed : %s\n", mAutoDisable ? "yes" : "no"); dump_printf("Auto Disable Engaged : %s\n", shouldAutoDisable() ? "yes" : "no"); } return NO_ERROR; } void CommonTimeServer::PacketRTTLog::dumpLog(int fd, const CommonClock& cclk) { const size_t SIZE = 256; char buffer[SIZE]; uint32_t avail = !logFull ? wrPtr : RTT_LOG_SIZE; if (!avail) return; dump_printf("\nPacket Log (%d entries)\n", avail); uint32_t ndx = 0; uint32_t i = logFull ? wrPtr : 0; do { if (rxTimes[i]) { int64_t delta = rxTimes[i] - txTimes[i]; int64_t deltaUsec = cclk.localDurationToCommonDuration(delta); dump_printf("pkt[%2d] : localTX %12lld localRX %12lld " "(%.3f msec RTT)\n", ndx, txTimes[i], rxTimes[i], static_cast<float>(deltaUsec) / 1000.0); } else { dump_printf("pkt[%2d] : localTX %12lld localRX never\n", ndx, txTimes[i]); } i = (i + 1) % RTT_LOG_SIZE; ndx++; } while (i != wrPtr); } #undef dump_printf #undef checked_percentage } // namespace android