storaged/storaged.cpp - third_party/android/platform/system/core - Git at Google

 /*
  * Copyright (C) 2016 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.
  */

 #define LOG_TAG "storaged"

 #include <stdlib.h>
 #include <time.h>
 #include <unistd.h>

 #include <android-base/logging.h>
 #include <batteryservice/BatteryServiceConstants.h>
 #include <batteryservice/IBatteryPropertiesRegistrar.h>
 #include <binder/IPCThreadState.h>
 #include <binder/IServiceManager.h>
 #include <cutils/properties.h>
 #include <log/log.h>

 #include <storaged.h>
 #include <storaged_utils.h>

 /* disk_stats_publisher */
 void disk_stats_publisher::publish(void) {
     // Logging
     struct disk_perf perf = get_disk_perf(&mAccumulate);
     log_debug_disk_perf(&perf, "regular");
     log_event_disk_stats(&mAccumulate, "regular");
     // Reset global structures
     memset(&mAccumulate, 0, sizeof(struct disk_stats));
 }

 void disk_stats_publisher::update(void) {
     struct disk_stats curr;
     if (parse_disk_stats(DISK_STATS_PATH, &curr)) {
         struct disk_stats inc = get_inc_disk_stats(&mPrevious, &curr);
         add_disk_stats(&inc, &mAccumulate);
 #ifdef DEBUG
 //            log_kernel_disk_stats(&mPrevious, "prev stats");
 //            log_kernel_disk_stats(&curr, "curr stats");
 //            log_kernel_disk_stats(&inc, "inc stats");
 //            log_kernel_disk_stats(&mAccumulate, "accumulated stats");
 #endif
         mPrevious = curr;
     }
 }

 /* disk_stats_monitor */
 void disk_stats_monitor::update_mean() {
     CHECK(mValid);
     mMean.read_perf = (uint32_t)mStats.read_perf.get_mean();
     mMean.read_ios = (uint32_t)mStats.read_ios.get_mean();
     mMean.write_perf = (uint32_t)mStats.write_perf.get_mean();
     mMean.write_ios = (uint32_t)mStats.write_ios.get_mean();
     mMean.queue = (uint32_t)mStats.queue.get_mean();
 }

 void disk_stats_monitor::update_std() {
     CHECK(mValid);
     mStd.read_perf = (uint32_t)mStats.read_perf.get_std();
     mStd.read_ios = (uint32_t)mStats.read_ios.get_std();
     mStd.write_perf = (uint32_t)mStats.write_perf.get_std();
     mStd.write_ios = (uint32_t)mStats.write_ios.get_std();
     mStd.queue = (uint32_t)mStats.queue.get_std();
 }

 void disk_stats_monitor::add(struct disk_perf* perf) {
     mStats.read_perf.add(perf->read_perf);
     mStats.read_ios.add(perf->read_ios);
     mStats.write_perf.add(perf->write_perf);
     mStats.write_ios.add(perf->write_ios);
     mStats.queue.add(perf->queue);
 }

 void disk_stats_monitor::evict(struct disk_perf* perf) {
     mStats.read_perf.evict(perf->read_perf);
     mStats.read_ios.evict(perf->read_ios);
     mStats.write_perf.evict(perf->write_perf);
     mStats.write_ios.evict(perf->write_ios);
     mStats.queue.evict(perf->queue);
 }

 bool disk_stats_monitor::detect(struct disk_perf* perf) {
     return ((double)perf->queue >= (double)mMean.queue + mSigma * (double)mStd.queue) &&
             ((double)perf->read_perf < (double)mMean.read_perf - mSigma * (double)mStd.read_perf) &&
             ((double)perf->write_perf < (double)mMean.write_perf - mSigma * (double)mStd.write_perf);
 }

 void disk_stats_monitor::update(struct disk_stats* stats) {
     struct disk_stats inc = get_inc_disk_stats(&mPrevious, stats);
     struct disk_perf perf = get_disk_perf(&inc);
     // Update internal data structures
     if (LIKELY(mValid)) {
         CHECK_EQ(mBuffer.size(), mWindow);

         if (UNLIKELY(detect(&perf))) {
             mStall = true;
             add_disk_stats(&inc, &mAccumulate);
             log_debug_disk_perf(&mMean, "stalled_mean");
             log_debug_disk_perf(&mStd, "stalled_std");
         } else {
             if (mStall) {
                 struct disk_perf acc_perf = get_disk_perf(&mAccumulate);
                 log_debug_disk_perf(&acc_perf, "stalled");
                 log_event_disk_stats(&mAccumulate, "stalled");
                 mStall = false;
                 memset(&mAccumulate, 0, sizeof(mAccumulate));
             }
         }

         evict(&mBuffer.front());
         mBuffer.pop();
         add(&perf);
         mBuffer.push(perf);

         update_mean();
         update_std();

     } else { /* mValid == false */
         CHECK_LT(mBuffer.size(), mWindow);
         add(&perf);
         mBuffer.push(perf);
         if (mBuffer.size() == mWindow) {
             mValid = true;
             update_mean();
             update_std();
         }
     }

     mPrevious = *stats;
 }

 void disk_stats_monitor::update(void) {
     struct disk_stats curr;
     if (LIKELY(parse_disk_stats(DISK_STATS_PATH, &curr))) {
         update(&curr);
     }
 }

 static sp<IBatteryPropertiesRegistrar> get_battery_properties_service() {
     sp<IServiceManager> sm = defaultServiceManager();
     if (sm == NULL) return NULL;

     sp<IBinder> binder = sm->getService(String16("batteryproperties"));
     if (binder == NULL) return NULL;

     sp<IBatteryPropertiesRegistrar> battery_properties =
         interface_cast<IBatteryPropertiesRegistrar>(binder);

     return battery_properties;
 }

 static inline charger_stat_t is_charger_on(int64_t prop) {
     return (prop == BATTERY_STATUS_CHARGING || prop == BATTERY_STATUS_FULL) ?
         CHARGER_ON : CHARGER_OFF;
 }

 void storaged_t::batteryPropertiesChanged(struct BatteryProperties props) {
     mUidm.set_charger_state(is_charger_on(props.batteryStatus));
 }

 void storaged_t::init_battery_service() {
     if (!mConfig.proc_uid_io_available)
         return;

     battery_properties = get_battery_properties_service();
     if (battery_properties == NULL) {
         LOG_TO(SYSTEM, WARNING) << "failed to find batteryproperties service";
         return;
     }

     struct BatteryProperty val;
     battery_properties->getProperty(BATTERY_PROP_BATTERY_STATUS, &val);
     mUidm.init(is_charger_on(val.valueInt64));

     // register listener after init uid_monitor
     battery_properties->registerListener(this);
     IInterface::asBinder(battery_properties)->linkToDeath(this);
 }

 void storaged_t::binderDied(const wp<IBinder>& who) {
     if (battery_properties != NULL &&
         IInterface::asBinder(battery_properties) == who) {
         LOG_TO(SYSTEM, ERROR) << "batteryproperties service died, exiting";
         IPCThreadState::self()->stopProcess();
         exit(1);
     } else {
         LOG_TO(SYSTEM, ERROR) << "unknown service died";
     }
 }

 void storaged_t::report_storage_info() {
     storage_info->report();
 }

 /* storaged_t */
 storaged_t::storaged_t(void) {
     if (access(MMC_DISK_STATS_PATH, R_OK) < 0 && access(SDA_DISK_STATS_PATH, R_OK) < 0) {
         mConfig.diskstats_available = false;
     } else {
         mConfig.diskstats_available = true;
     }

     mConfig.proc_uid_io_available = (access(UID_IO_STATS_PATH, R_OK) == 0);

     mConfig.periodic_chores_interval_unit =
         property_get_int32("ro.storaged.event.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_UNIT);

     mConfig.event_time_check_usec =
         property_get_int32("ro.storaged.event.perf_check", 0);

     mConfig.periodic_chores_interval_disk_stats_publish =
         property_get_int32("ro.storaged.disk_stats_pub", DEFAULT_PERIODIC_CHORES_INTERVAL_DISK_STATS_PUBLISH);

     mConfig.periodic_chores_interval_uid_io =
         property_get_int32("ro.storaged.uid_io.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_UID_IO);

     storage_info.reset(storage_info_t::get_storage_info());

     mStarttime = time(NULL);
 }

 void storaged_t::event(void) {
     if (mConfig.diskstats_available) {
         mDiskStats.update();
         mDsm.update();
         storage_info->refresh();
         if (mTimer && (mTimer % mConfig.periodic_chores_interval_disk_stats_publish) == 0) {
             mDiskStats.publish();
         }
     }

     if (mConfig.proc_uid_io_available && mTimer &&
             (mTimer % mConfig.periodic_chores_interval_uid_io) == 0) {
          mUidm.report();
     }

     mTimer += mConfig.periodic_chores_interval_unit;
 }

 void storaged_t::event_checked(void) {
     struct timespec start_ts, end_ts;
     bool check_time = true;

     if (mConfig.event_time_check_usec &&
         clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &start_ts) < 0) {
         check_time = false;
         static time_t state_a;
         IF_ALOG_RATELIMIT_LOCAL(300, &state_a) {
             PLOG_TO(SYSTEM, ERROR) << "clock_gettime() failed";
         }
     }

     event();

     if (mConfig.event_time_check_usec && check_time) {
         if (clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &end_ts) < 0) {
             static time_t state_b;
             IF_ALOG_RATELIMIT_LOCAL(300, &state_b) {
                 PLOG_TO(SYSTEM, ERROR) << "clock_gettime() failed";
             }
             return;
         }
         int64_t cost = (end_ts.tv_sec - start_ts.tv_sec) * SEC_TO_USEC +
                        (end_ts.tv_nsec - start_ts.tv_nsec) / USEC_TO_NSEC;
         if (cost > mConfig.event_time_check_usec) {
             LOG_TO(SYSTEM, ERROR)
                 << "event loop spent " << cost << " usec, threshold "
                 << mConfig.event_time_check_usec << " usec";
         }
     }
 }
	/*
	* Copyright (C) 2016 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.
	*/

	#define LOG_TAG "storaged"

	#include <stdlib.h>
	#include <time.h>
	#include <unistd.h>

	#include <android-base/logging.h>
	#include <batteryservice/BatteryServiceConstants.h>
	#include <batteryservice/IBatteryPropertiesRegistrar.h>
	#include <binder/IPCThreadState.h>
	#include <binder/IServiceManager.h>
	#include <cutils/properties.h>
	#include <log/log.h>

	#include <storaged.h>
	#include <storaged_utils.h>

	/* disk_stats_publisher */
	void disk_stats_publisher::publish(void) {
	// Logging
	struct disk_perf perf = get_disk_perf(&mAccumulate);
	log_debug_disk_perf(&perf, "regular");
	log_event_disk_stats(&mAccumulate, "regular");
	// Reset global structures
	memset(&mAccumulate, 0, sizeof(struct disk_stats));
	}

	void disk_stats_publisher::update(void) {
	struct disk_stats curr;
	if (parse_disk_stats(DISK_STATS_PATH, &curr)) {
	struct disk_stats inc = get_inc_disk_stats(&mPrevious, &curr);
	add_disk_stats(&inc, &mAccumulate);
	#ifdef DEBUG
	// log_kernel_disk_stats(&mPrevious, "prev stats");
	// log_kernel_disk_stats(&curr, "curr stats");
	// log_kernel_disk_stats(&inc, "inc stats");
	// log_kernel_disk_stats(&mAccumulate, "accumulated stats");
	#endif
	mPrevious = curr;
	}
	}

	/* disk_stats_monitor */
	void disk_stats_monitor::update_mean() {
	CHECK(mValid);
	mMean.read_perf = (uint32_t)mStats.read_perf.get_mean();
	mMean.read_ios = (uint32_t)mStats.read_ios.get_mean();
	mMean.write_perf = (uint32_t)mStats.write_perf.get_mean();
	mMean.write_ios = (uint32_t)mStats.write_ios.get_mean();
	mMean.queue = (uint32_t)mStats.queue.get_mean();
	}

	void disk_stats_monitor::update_std() {
	CHECK(mValid);
	mStd.read_perf = (uint32_t)mStats.read_perf.get_std();
	mStd.read_ios = (uint32_t)mStats.read_ios.get_std();
	mStd.write_perf = (uint32_t)mStats.write_perf.get_std();
	mStd.write_ios = (uint32_t)mStats.write_ios.get_std();
	mStd.queue = (uint32_t)mStats.queue.get_std();
	}

	void disk_stats_monitor::add(struct disk_perf* perf) {
	mStats.read_perf.add(perf->read_perf);
	mStats.read_ios.add(perf->read_ios);
	mStats.write_perf.add(perf->write_perf);
	mStats.write_ios.add(perf->write_ios);
	mStats.queue.add(perf->queue);
	}

	void disk_stats_monitor::evict(struct disk_perf* perf) {
	mStats.read_perf.evict(perf->read_perf);
	mStats.read_ios.evict(perf->read_ios);
	mStats.write_perf.evict(perf->write_perf);
	mStats.write_ios.evict(perf->write_ios);
	mStats.queue.evict(perf->queue);
	}

	bool disk_stats_monitor::detect(struct disk_perf* perf) {
	return ((double)perf->queue >= (double)mMean.queue + mSigma * (double)mStd.queue) &&
	((double)perf->read_perf < (double)mMean.read_perf - mSigma * (double)mStd.read_perf) &&
	((double)perf->write_perf < (double)mMean.write_perf - mSigma * (double)mStd.write_perf);
	}

	void disk_stats_monitor::update(struct disk_stats* stats) {
	struct disk_stats inc = get_inc_disk_stats(&mPrevious, stats);
	struct disk_perf perf = get_disk_perf(&inc);
	// Update internal data structures
	if (LIKELY(mValid)) {
	CHECK_EQ(mBuffer.size(), mWindow);

	if (UNLIKELY(detect(&perf))) {
	mStall = true;
	add_disk_stats(&inc, &mAccumulate);
	log_debug_disk_perf(&mMean, "stalled_mean");
	log_debug_disk_perf(&mStd, "stalled_std");
	} else {
	if (mStall) {
	struct disk_perf acc_perf = get_disk_perf(&mAccumulate);
	log_debug_disk_perf(&acc_perf, "stalled");
	log_event_disk_stats(&mAccumulate, "stalled");
	mStall = false;
	memset(&mAccumulate, 0, sizeof(mAccumulate));
	}
	}

	evict(&mBuffer.front());
	mBuffer.pop();
	add(&perf);
	mBuffer.push(perf);

	update_mean();
	update_std();

	} else { /* mValid == false */
	CHECK_LT(mBuffer.size(), mWindow);
	add(&perf);
	mBuffer.push(perf);
	if (mBuffer.size() == mWindow) {
	mValid = true;
	update_mean();
	update_std();
	}
	}

	mPrevious = *stats;
	}

	void disk_stats_monitor::update(void) {
	struct disk_stats curr;
	if (LIKELY(parse_disk_stats(DISK_STATS_PATH, &curr))) {
	update(&curr);
	}
	}

	static sp<IBatteryPropertiesRegistrar> get_battery_properties_service() {
	sp<IServiceManager> sm = defaultServiceManager();
	if (sm == NULL) return NULL;

	sp<IBinder> binder = sm->getService(String16("batteryproperties"));
	if (binder == NULL) return NULL;

	sp<IBatteryPropertiesRegistrar> battery_properties =
	interface_cast<IBatteryPropertiesRegistrar>(binder);

	return battery_properties;
	}

	static inline charger_stat_t is_charger_on(int64_t prop) {
	return (prop == BATTERY_STATUS_CHARGING \|\| prop == BATTERY_STATUS_FULL) ?
	CHARGER_ON : CHARGER_OFF;
	}

	void storaged_t::batteryPropertiesChanged(struct BatteryProperties props) {
	mUidm.set_charger_state(is_charger_on(props.batteryStatus));
	}

	void storaged_t::init_battery_service() {
	if (!mConfig.proc_uid_io_available)
	return;

	battery_properties = get_battery_properties_service();
	if (battery_properties == NULL) {
	LOG_TO(SYSTEM, WARNING) << "failed to find batteryproperties service";
	return;
	}

	struct BatteryProperty val;
	battery_properties->getProperty(BATTERY_PROP_BATTERY_STATUS, &val);
	mUidm.init(is_charger_on(val.valueInt64));

	// register listener after init uid_monitor
	battery_properties->registerListener(this);
	IInterface::asBinder(battery_properties)->linkToDeath(this);
	}

	void storaged_t::binderDied(const wp<IBinder>& who) {
	if (battery_properties != NULL &&
	IInterface::asBinder(battery_properties) == who) {
	LOG_TO(SYSTEM, ERROR) << "batteryproperties service died, exiting";
	IPCThreadState::self()->stopProcess();
	exit(1);
	} else {
	LOG_TO(SYSTEM, ERROR) << "unknown service died";
	}
	}

	void storaged_t::report_storage_info() {
	storage_info->report();
	}

	/* storaged_t */
	storaged_t::storaged_t(void) {
	if (access(MMC_DISK_STATS_PATH, R_OK) < 0 && access(SDA_DISK_STATS_PATH, R_OK) < 0) {
	mConfig.diskstats_available = false;
	} else {
	mConfig.diskstats_available = true;
	}

	mConfig.proc_uid_io_available = (access(UID_IO_STATS_PATH, R_OK) == 0);

	mConfig.periodic_chores_interval_unit =
	property_get_int32("ro.storaged.event.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_UNIT);

	mConfig.event_time_check_usec =
	property_get_int32("ro.storaged.event.perf_check", 0);

	mConfig.periodic_chores_interval_disk_stats_publish =
	property_get_int32("ro.storaged.disk_stats_pub", DEFAULT_PERIODIC_CHORES_INTERVAL_DISK_STATS_PUBLISH);

	mConfig.periodic_chores_interval_uid_io =
	property_get_int32("ro.storaged.uid_io.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_UID_IO);

	storage_info.reset(storage_info_t::get_storage_info());

	mStarttime = time(NULL);
	}

	void storaged_t::event(void) {
	if (mConfig.diskstats_available) {
	mDiskStats.update();
	mDsm.update();
	storage_info->refresh();
	if (mTimer && (mTimer % mConfig.periodic_chores_interval_disk_stats_publish) == 0) {
	mDiskStats.publish();
	}
	}

	if (mConfig.proc_uid_io_available && mTimer &&
	(mTimer % mConfig.periodic_chores_interval_uid_io) == 0) {
	mUidm.report();
	}

	mTimer += mConfig.periodic_chores_interval_unit;
	}

	void storaged_t::event_checked(void) {
	struct timespec start_ts, end_ts;
	bool check_time = true;

	if (mConfig.event_time_check_usec &&
	clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &start_ts) < 0) {
	check_time = false;
	static time_t state_a;
	IF_ALOG_RATELIMIT_LOCAL(300, &state_a) {
	PLOG_TO(SYSTEM, ERROR) << "clock_gettime() failed";
	}
	}

	event();

	if (mConfig.event_time_check_usec && check_time) {
	if (clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &end_ts) < 0) {
	static time_t state_b;
	IF_ALOG_RATELIMIT_LOCAL(300, &state_b) {
	PLOG_TO(SYSTEM, ERROR) << "clock_gettime() failed";
	}
	return;
	}
	int64_t cost = (end_ts.tv_sec - start_ts.tv_sec) * SEC_TO_USEC +
	(end_ts.tv_nsec - start_ts.tv_nsec) / USEC_TO_NSEC;
	if (cost > mConfig.event_time_check_usec) {
	LOG_TO(SYSTEM, ERROR)
	<< "event loop spent " << cost << " usec, threshold "
	<< mConfig.event_time_check_usec << " usec";
	}
	}
	}