logd/LogBuffer.h - third_party/android/platform/system/core - Git at Google

 /*
  * Copyright (C) 2012-2014 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.
  */

 #ifndef _LOGD_LOG_BUFFER_H__
 #define _LOGD_LOG_BUFFER_H__

 #include <sys/types.h>

 #include <list>
 #include <string>

 #include <android/log.h>
 #include <private/android_filesystem_config.h>
 #include <sysutils/SocketClient.h>

 #include "LogBufferElement.h"
 #include "LogBufferInterface.h"
 #include "LogStatistics.h"
 #include "LogTags.h"
 #include "LogTimes.h"
 #include "LogWhiteBlackList.h"

 //
 // We are either in 1970ish (MONOTONIC) or 2016+ish (REALTIME) so to
 // differentiate without prejudice, we use 1972 to delineate, earlier
 // is likely monotonic, later is real. Otherwise we start using a
 // dividing line between monotonic and realtime if more than a minute
 // difference between them.
 //
 namespace android {

 static bool isMonotonic(const log_time& mono) {
     static const uint32_t EPOCH_PLUS_2_YEARS = 2 * 24 * 60 * 60 * 1461 / 4;
     static const uint32_t EPOCH_PLUS_MINUTE = 60;

     if (mono.tv_sec >= EPOCH_PLUS_2_YEARS) {
         return false;
     }

     log_time now(CLOCK_REALTIME);

     /* Timezone and ntp time setup? */
     if (now.tv_sec >= EPOCH_PLUS_2_YEARS) {
         return true;
     }

     /* no way to differentiate realtime from monotonic time */
     if (now.tv_sec < EPOCH_PLUS_MINUTE) {
         return false;
     }

     log_time cpu(CLOCK_MONOTONIC);
     /* too close to call to differentiate monotonic times from realtime */
     if ((cpu.tv_sec + EPOCH_PLUS_MINUTE) >= now.tv_sec) {
         return false;
     }

     /* dividing line half way between monotonic and realtime */
     return mono.tv_sec < ((cpu.tv_sec + now.tv_sec) / 2);
 }
 }

 typedef std::list<LogBufferElement*> LogBufferElementCollection;

 class LogBuffer : public LogBufferInterface {
     LogBufferElementCollection mLogElements;
     pthread_rwlock_t mLogElementsLock;

     LogStatistics stats;

     PruneList mPrune;
     // watermark for last per log id
     LogBufferElementCollection::iterator mLast[LOG_ID_MAX];
     bool mLastSet[LOG_ID_MAX];
     // watermark of any worst/chatty uid processing
     typedef std::unordered_map<uid_t, LogBufferElementCollection::iterator>
         LogBufferIteratorMap;
     LogBufferIteratorMap mLastWorst[LOG_ID_MAX];
     // watermark of any worst/chatty pid of system processing
     typedef std::unordered_map<pid_t, LogBufferElementCollection::iterator>
         LogBufferPidIteratorMap;
     LogBufferPidIteratorMap mLastWorstPidOfSystem[LOG_ID_MAX];

     unsigned long mMaxSize[LOG_ID_MAX];

     bool monotonic;

     LogTags tags;

     LogBufferElement* lastLoggedElements[LOG_ID_MAX];
     LogBufferElement* droppedElements[LOG_ID_MAX];
     void log(LogBufferElement* elem);

    public:
     LastLogTimes& mTimes;

     explicit LogBuffer(LastLogTimes* times);
     ~LogBuffer() override;
     void init();
     bool isMonotonic() {
         return monotonic;
     }

     int log(log_id_t log_id, log_time realtime, uid_t uid, pid_t pid, pid_t tid,
             const char* msg, unsigned short len) override;
     // lastTid is an optional context to help detect if the last previous
     // valid message was from the same source so we can differentiate chatty
     // filter types (identical or expired)
     log_time flushTo(SocketClient* writer, const log_time& start,
                      pid_t* lastTid,  // &lastTid[LOG_ID_MAX] or nullptr
                      bool privileged, bool security,
                      int (*filter)(const LogBufferElement* element,
                                    void* arg) = nullptr,
                      void* arg = nullptr);

     bool clear(log_id_t id, uid_t uid = AID_ROOT);
     unsigned long getSize(log_id_t id);
     int setSize(log_id_t id, unsigned long size);
     unsigned long getSizeUsed(log_id_t id);

     std::string formatStatistics(uid_t uid, pid_t pid, unsigned int logMask);

     void enableStatistics() {
         stats.enableStatistics();
     }

     int initPrune(const char* cp) {
         return mPrune.init(cp);
     }
     std::string formatPrune() {
         return mPrune.format();
     }

     std::string formatGetEventTag(uid_t uid, const char* name,
                                   const char* format) {
         return tags.formatGetEventTag(uid, name, format);
     }
     std::string formatEntry(uint32_t tag, uid_t uid) {
         return tags.formatEntry(tag, uid);
     }
     const char* tagToName(uint32_t tag) {
         return tags.tagToName(tag);
     }

     // helper must be protected directly or implicitly by wrlock()/unlock()
     const char* pidToName(pid_t pid) {
         return stats.pidToName(pid);
     }
     virtual uid_t pidToUid(pid_t pid) override {
         return stats.pidToUid(pid);
     }
     virtual pid_t tidToPid(pid_t tid) override {
         return stats.tidToPid(tid);
     }
     const char* uidToName(uid_t uid) {
         return stats.uidToName(uid);
     }
     void wrlock() {
         pthread_rwlock_wrlock(&mLogElementsLock);
     }
     void rdlock() {
         pthread_rwlock_rdlock(&mLogElementsLock);
     }
     void unlock() {
         pthread_rwlock_unlock(&mLogElementsLock);
     }

    private:
     static constexpr size_t minPrune = 4;
     static constexpr size_t maxPrune = 256;
     static const log_time pruneMargin;

     void maybePrune(log_id_t id);
     bool isBusy(log_time watermark);
     void kickMe(LogTimeEntry* me, log_id_t id, unsigned long pruneRows);

     bool prune(log_id_t id, unsigned long pruneRows, uid_t uid = AID_ROOT);
     LogBufferElementCollection::iterator erase(
         LogBufferElementCollection::iterator it, bool coalesce = false);
 };

 #endif  // _LOGD_LOG_BUFFER_H__
	/*
	* Copyright (C) 2012-2014 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.
	*/

	#ifndef _LOGD_LOG_BUFFER_H__
	#define _LOGD_LOG_BUFFER_H__

	#include <sys/types.h>

	#include <list>
	#include <string>

	#include <android/log.h>
	#include <private/android_filesystem_config.h>
	#include <sysutils/SocketClient.h>

	#include "LogBufferElement.h"
	#include "LogBufferInterface.h"
	#include "LogStatistics.h"
	#include "LogTags.h"
	#include "LogTimes.h"
	#include "LogWhiteBlackList.h"

	//
	// We are either in 1970ish (MONOTONIC) or 2016+ish (REALTIME) so to
	// differentiate without prejudice, we use 1972 to delineate, earlier
	// is likely monotonic, later is real. Otherwise we start using a
	// dividing line between monotonic and realtime if more than a minute
	// difference between them.
	//
	namespace android {

	static bool isMonotonic(const log_time& mono) {
	static const uint32_t EPOCH_PLUS_2_YEARS = 2 * 24 * 60 * 60 * 1461 / 4;
	static const uint32_t EPOCH_PLUS_MINUTE = 60;

	if (mono.tv_sec >= EPOCH_PLUS_2_YEARS) {
	return false;
	}

	log_time now(CLOCK_REALTIME);

	/* Timezone and ntp time setup? */
	if (now.tv_sec >= EPOCH_PLUS_2_YEARS) {
	return true;
	}

	/* no way to differentiate realtime from monotonic time */
	if (now.tv_sec < EPOCH_PLUS_MINUTE) {
	return false;
	}

	log_time cpu(CLOCK_MONOTONIC);
	/* too close to call to differentiate monotonic times from realtime */
	if ((cpu.tv_sec + EPOCH_PLUS_MINUTE) >= now.tv_sec) {
	return false;
	}

	/* dividing line half way between monotonic and realtime */
	return mono.tv_sec < ((cpu.tv_sec + now.tv_sec) / 2);
	}
	}

	typedef std::list<LogBufferElement*> LogBufferElementCollection;

	class LogBuffer : public LogBufferInterface {
	LogBufferElementCollection mLogElements;
	pthread_rwlock_t mLogElementsLock;

	LogStatistics stats;

	PruneList mPrune;
	// watermark for last per log id
	LogBufferElementCollection::iterator mLast[LOG_ID_MAX];
	bool mLastSet[LOG_ID_MAX];
	// watermark of any worst/chatty uid processing
	typedef std::unordered_map<uid_t, LogBufferElementCollection::iterator>
	LogBufferIteratorMap;
	LogBufferIteratorMap mLastWorst[LOG_ID_MAX];
	// watermark of any worst/chatty pid of system processing
	typedef std::unordered_map<pid_t, LogBufferElementCollection::iterator>
	LogBufferPidIteratorMap;
	LogBufferPidIteratorMap mLastWorstPidOfSystem[LOG_ID_MAX];

	unsigned long mMaxSize[LOG_ID_MAX];

	bool monotonic;

	LogTags tags;

	LogBufferElement* lastLoggedElements[LOG_ID_MAX];
	LogBufferElement* droppedElements[LOG_ID_MAX];
	void log(LogBufferElement* elem);

	public:
	LastLogTimes& mTimes;

	explicit LogBuffer(LastLogTimes* times);
	~LogBuffer() override;
	void init();
	bool isMonotonic() {
	return monotonic;
	}

	int log(log_id_t log_id, log_time realtime, uid_t uid, pid_t pid, pid_t tid,
	const char* msg, unsigned short len) override;
	// lastTid is an optional context to help detect if the last previous
	// valid message was from the same source so we can differentiate chatty
	// filter types (identical or expired)
	log_time flushTo(SocketClient* writer, const log_time& start,
	pid_t* lastTid, // &lastTid[LOG_ID_MAX] or nullptr
	bool privileged, bool security,
	int (filter)(const LogBufferElement element,
	void* arg) = nullptr,
	void* arg = nullptr);

	bool clear(log_id_t id, uid_t uid = AID_ROOT);
	unsigned long getSize(log_id_t id);
	int setSize(log_id_t id, unsigned long size);
	unsigned long getSizeUsed(log_id_t id);

	std::string formatStatistics(uid_t uid, pid_t pid, unsigned int logMask);

	void enableStatistics() {
	stats.enableStatistics();
	}

	int initPrune(const char* cp) {
	return mPrune.init(cp);
	}
	std::string formatPrune() {
	return mPrune.format();
	}

	std::string formatGetEventTag(uid_t uid, const char* name,
	const char* format) {
	return tags.formatGetEventTag(uid, name, format);
	}
	std::string formatEntry(uint32_t tag, uid_t uid) {
	return tags.formatEntry(tag, uid);
	}
	const char* tagToName(uint32_t tag) {
	return tags.tagToName(tag);
	}

	// helper must be protected directly or implicitly by wrlock()/unlock()
	const char* pidToName(pid_t pid) {
	return stats.pidToName(pid);
	}
	virtual uid_t pidToUid(pid_t pid) override {
	return stats.pidToUid(pid);
	}
	virtual pid_t tidToPid(pid_t tid) override {
	return stats.tidToPid(tid);
	}
	const char* uidToName(uid_t uid) {
	return stats.uidToName(uid);
	}
	void wrlock() {
	pthread_rwlock_wrlock(&mLogElementsLock);
	}
	void rdlock() {
	pthread_rwlock_rdlock(&mLogElementsLock);
	}
	void unlock() {
	pthread_rwlock_unlock(&mLogElementsLock);
	}

	private:
	static constexpr size_t minPrune = 4;
	static constexpr size_t maxPrune = 256;
	static const log_time pruneMargin;

	void maybePrune(log_id_t id);
	bool isBusy(log_time watermark);
	void kickMe(LogTimeEntry* me, log_id_t id, unsigned long pruneRows);

	bool prune(log_id_t id, unsigned long pruneRows, uid_t uid = AID_ROOT);
	LogBufferElementCollection::iterator erase(
	LogBufferElementCollection::iterator it, bool coalesce = false);
	};

	#endif // _LOGD_LOG_BUFFER_H__