platform_system_core/logd/LogBuffer.cpp

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/*
* 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.
*/
#include <ctype.h>
#include <errno.h>
#include <stdio.h>
#include <string.h>
#include <sys/cdefs.h>
#include <sys/user.h>
#include <time.h>
#include <unistd.h>
#include <unordered_map>
#include <cutils/properties.h>
#include <private/android_logger.h>
#include "LogBuffer.h"
#include "LogKlog.h"
#include "LogReader.h"
#ifndef __predict_false
#define __predict_false(exp) __builtin_expect((exp) != 0, 0)
#endif
// Default
#define log_buffer_size(id) mMaxSize[id]
void LogBuffer::init() {
log_id_for_each(i) {
mLastSet[i] = false;
mLast[i] = mLogElements.begin();
if (setSize(i, __android_logger_get_buffer_size(i))) {
setSize(i, LOG_BUFFER_MIN_SIZE);
}
}
bool lastMonotonic = monotonic;
monotonic = android_log_clockid() == CLOCK_MONOTONIC;
if (lastMonotonic != monotonic) {
//
// Fixup all timestamps, may not be 100% accurate, but better than
// throwing what we have away when we get 'surprised' by a change.
// In-place element fixup so no need to check reader-lock. Entries
// should already be in timestamp order, but we could end up with a
// few out-of-order entries if new monotonics come in before we
// are notified of the reinit change in status. A Typical example would
// be:
// --------- beginning of system
// 10.494082 184 201 D Cryptfs : Just triggered post_fs_data
// --------- beginning of kernel
// 0.000000 0 0 I : Initializing cgroup subsys
// as the act of mounting /data would trigger persist.logd.timestamp to
// be corrected. 1/30 corner case YMMV.
//
pthread_mutex_lock(&mLogElementsLock);
LogBufferElementCollection::iterator it = mLogElements.begin();
while((it != mLogElements.end())) {
LogBufferElement *e = *it;
if (monotonic) {
if (!android::isMonotonic(e->mRealTime)) {
LogKlog::convertRealToMonotonic(e->mRealTime);
}
} else {
if (android::isMonotonic(e->mRealTime)) {
LogKlog::convertMonotonicToReal(e->mRealTime);
}
}
++it;
}
pthread_mutex_unlock(&mLogElementsLock);
}
// We may have been triggered by a SIGHUP. Release any sleeping reader
// threads to dump their current content.
//
// NB: this is _not_ performed in the context of a SIGHUP, it is
// performed during startup, and in context of reinit administrative thread
LogTimeEntry::lock();
LastLogTimes::iterator times = mTimes.begin();
while(times != mTimes.end()) {
LogTimeEntry *entry = (*times);
if (entry->owned_Locked()) {
entry->triggerReader_Locked();
}
times++;
}
LogTimeEntry::unlock();
}
LogBuffer::LogBuffer(LastLogTimes *times):
monotonic(android_log_clockid() == CLOCK_MONOTONIC),
mTimes(*times) {
pthread_mutex_init(&mLogElementsLock, NULL);
init();
}
int LogBuffer::log(log_id_t log_id, log_time realtime,
uid_t uid, pid_t pid, pid_t tid,
const char *msg, unsigned short len) {
if ((log_id >= LOG_ID_MAX) || (log_id < 0)) {
return -EINVAL;
}
LogBufferElement *elem = new LogBufferElement(log_id, realtime,
uid, pid, tid, msg, len);
if (log_id != LOG_ID_SECURITY) {
int prio = ANDROID_LOG_INFO;
const char *tag = NULL;
liblog: logd: Add android_lookupEventTag_len() Allows us to mitigate the impact of MAP_PRIVATE and copy on write by calling android_lookupEventTag_len instead of android_lookupEventTag, and delaying the copy on write impact to the later. We return a string length in a supplied location along with the string pointer with android_lookupEventTag_len(const EventTagMap* map, size_t* len, int tag). The string is not guaranteed to be nul terminated. Since android_lookupEventTag() called even once can cause the memory impact, we will mark it as deprecated, but we currently have no timeframe for removal since this is a very old interface. Add an API for __android_log_is_loggable_len() that accepts the non null terminated content and fixup callers that would gain because the length is known prior to the call either in the compiler or at runtime. Tackle transition to android_lookupEventTag_len() and fixup callers. On any application that performs logging (eg: com.android.phone) /proc/<pid>/smaps before: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 463 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 0 kB Shared_Dirty: 20 kB Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 0 kB Anonymous: 20 kB AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac /proc/<pid>/smaps after: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 1773 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 20 kB (was 0kB) Shared_Dirty: 0 kB (was 20kB) Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 20 kB (was 0kB) Anonymous: 0 kB (was 20kB) AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac Added liblog-unit-tests --gtest_filter=liblog.event_log_tags to check for Shared_Clean: to not be 0 and Anonymous: to be 0 for all processes referencing event-log-tags. Which can include multiple references to /system/etc/event-log-tags and future possible refs to /data/misc/logd/event-log-tags and /dev/event-log-tags. We want failure messages to help point to errant code using the deprecated interface. This change saves 1/4MB of memory or more on a typical system. Test: gTest liblog-unit-tests Bug: 31456426 Change-Id: I9e08e44d9092bd96fe704b5709242e7195281d33
2016-09-22 18:56:51 +02:00
size_t len = 0;
if (log_id == LOG_ID_EVENTS) {
liblog: logd: Add android_lookupEventTag_len() Allows us to mitigate the impact of MAP_PRIVATE and copy on write by calling android_lookupEventTag_len instead of android_lookupEventTag, and delaying the copy on write impact to the later. We return a string length in a supplied location along with the string pointer with android_lookupEventTag_len(const EventTagMap* map, size_t* len, int tag). The string is not guaranteed to be nul terminated. Since android_lookupEventTag() called even once can cause the memory impact, we will mark it as deprecated, but we currently have no timeframe for removal since this is a very old interface. Add an API for __android_log_is_loggable_len() that accepts the non null terminated content and fixup callers that would gain because the length is known prior to the call either in the compiler or at runtime. Tackle transition to android_lookupEventTag_len() and fixup callers. On any application that performs logging (eg: com.android.phone) /proc/<pid>/smaps before: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 463 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 0 kB Shared_Dirty: 20 kB Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 0 kB Anonymous: 20 kB AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac /proc/<pid>/smaps after: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 1773 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 20 kB (was 0kB) Shared_Dirty: 0 kB (was 20kB) Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 20 kB (was 0kB) Anonymous: 0 kB (was 20kB) AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac Added liblog-unit-tests --gtest_filter=liblog.event_log_tags to check for Shared_Clean: to not be 0 and Anonymous: to be 0 for all processes referencing event-log-tags. Which can include multiple references to /system/etc/event-log-tags and future possible refs to /data/misc/logd/event-log-tags and /dev/event-log-tags. We want failure messages to help point to errant code using the deprecated interface. This change saves 1/4MB of memory or more on a typical system. Test: gTest liblog-unit-tests Bug: 31456426 Change-Id: I9e08e44d9092bd96fe704b5709242e7195281d33
2016-09-22 18:56:51 +02:00
tag = android::tagToName(&len, elem->getTag());
} else {
prio = *msg;
tag = msg + 1;
liblog: logd: Add android_lookupEventTag_len() Allows us to mitigate the impact of MAP_PRIVATE and copy on write by calling android_lookupEventTag_len instead of android_lookupEventTag, and delaying the copy on write impact to the later. We return a string length in a supplied location along with the string pointer with android_lookupEventTag_len(const EventTagMap* map, size_t* len, int tag). The string is not guaranteed to be nul terminated. Since android_lookupEventTag() called even once can cause the memory impact, we will mark it as deprecated, but we currently have no timeframe for removal since this is a very old interface. Add an API for __android_log_is_loggable_len() that accepts the non null terminated content and fixup callers that would gain because the length is known prior to the call either in the compiler or at runtime. Tackle transition to android_lookupEventTag_len() and fixup callers. On any application that performs logging (eg: com.android.phone) /proc/<pid>/smaps before: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 463 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 0 kB Shared_Dirty: 20 kB Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 0 kB Anonymous: 20 kB AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac /proc/<pid>/smaps after: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 1773 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 20 kB (was 0kB) Shared_Dirty: 0 kB (was 20kB) Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 20 kB (was 0kB) Anonymous: 0 kB (was 20kB) AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac Added liblog-unit-tests --gtest_filter=liblog.event_log_tags to check for Shared_Clean: to not be 0 and Anonymous: to be 0 for all processes referencing event-log-tags. Which can include multiple references to /system/etc/event-log-tags and future possible refs to /data/misc/logd/event-log-tags and /dev/event-log-tags. We want failure messages to help point to errant code using the deprecated interface. This change saves 1/4MB of memory or more on a typical system. Test: gTest liblog-unit-tests Bug: 31456426 Change-Id: I9e08e44d9092bd96fe704b5709242e7195281d33
2016-09-22 18:56:51 +02:00
len = strlen(tag);
}
liblog: logd: Add android_lookupEventTag_len() Allows us to mitigate the impact of MAP_PRIVATE and copy on write by calling android_lookupEventTag_len instead of android_lookupEventTag, and delaying the copy on write impact to the later. We return a string length in a supplied location along with the string pointer with android_lookupEventTag_len(const EventTagMap* map, size_t* len, int tag). The string is not guaranteed to be nul terminated. Since android_lookupEventTag() called even once can cause the memory impact, we will mark it as deprecated, but we currently have no timeframe for removal since this is a very old interface. Add an API for __android_log_is_loggable_len() that accepts the non null terminated content and fixup callers that would gain because the length is known prior to the call either in the compiler or at runtime. Tackle transition to android_lookupEventTag_len() and fixup callers. On any application that performs logging (eg: com.android.phone) /proc/<pid>/smaps before: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 463 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 0 kB Shared_Dirty: 20 kB Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 0 kB Anonymous: 20 kB AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac /proc/<pid>/smaps after: xxxxxxxxxx-xxxxxxxxxx rw-p 00000000 fd:00 1773 /system/etc/event-log-tags Size: 20 kB Rss: 20 kB Pss: 1 kB Shared_Clean: 20 kB (was 0kB) Shared_Dirty: 0 kB (was 20kB) Private_Clean: 0 kB Private_Dirty: 0 kB Referenced: 20 kB (was 0kB) Anonymous: 0 kB (was 20kB) AnonHugePages: 0 kB Swap: 0 kB SwapPss: 0 kB KernelPageSize: 4 kB MMUPageSize: 4 kB Locked: 0 kB VmFlags: rd wr mr mw me ac Added liblog-unit-tests --gtest_filter=liblog.event_log_tags to check for Shared_Clean: to not be 0 and Anonymous: to be 0 for all processes referencing event-log-tags. Which can include multiple references to /system/etc/event-log-tags and future possible refs to /data/misc/logd/event-log-tags and /dev/event-log-tags. We want failure messages to help point to errant code using the deprecated interface. This change saves 1/4MB of memory or more on a typical system. Test: gTest liblog-unit-tests Bug: 31456426 Change-Id: I9e08e44d9092bd96fe704b5709242e7195281d33
2016-09-22 18:56:51 +02:00
if (!__android_log_is_loggable_len(prio, tag, len, ANDROID_LOG_VERBOSE)) {
// Log traffic received to total
pthread_mutex_lock(&mLogElementsLock);
stats.add(elem);
stats.subtract(elem);
pthread_mutex_unlock(&mLogElementsLock);
delete elem;
return -EACCES;
}
}
pthread_mutex_lock(&mLogElementsLock);
// Insert elements in time sorted order if possible
// NB: if end is region locked, place element at end of list
LogBufferElementCollection::iterator it = mLogElements.end();
LogBufferElementCollection::iterator last = it;
while (last != mLogElements.begin()) {
--it;
if ((*it)->getRealTime() <= realtime) {
break;
}
last = it;
}
if (last == mLogElements.end()) {
mLogElements.push_back(elem);
} else {
uint64_t end = 1;
bool end_set = false;
bool end_always = false;
LogTimeEntry::lock();
LastLogTimes::iterator times = mTimes.begin();
while(times != mTimes.end()) {
LogTimeEntry *entry = (*times);
if (entry->owned_Locked()) {
if (!entry->mNonBlock) {
end_always = true;
break;
}
if (!end_set || (end <= entry->mEnd)) {
end = entry->mEnd;
end_set = true;
}
}
times++;
}
if (end_always
|| (end_set && (end >= (*last)->getSequence()))) {
mLogElements.push_back(elem);
} else {
mLogElements.insert(last,elem);
}
LogTimeEntry::unlock();
}
stats.add(elem);
maybePrune(log_id);
pthread_mutex_unlock(&mLogElementsLock);
return len;
}
// Prune at most 10% of the log entries or maxPrune, whichever is less.
//
// mLogElementsLock must be held when this function is called.
void LogBuffer::maybePrune(log_id_t id) {
size_t sizes = stats.sizes(id);
unsigned long maxSize = log_buffer_size(id);
if (sizes > maxSize) {
size_t sizeOver = sizes - ((maxSize * 9) / 10);
size_t elements = stats.realElements(id);
size_t minElements = elements / 100;
if (minElements < minPrune) {
minElements = minPrune;
}
unsigned long pruneRows = elements * sizeOver / sizes;
if (pruneRows < minElements) {
pruneRows = minElements;
}
if (pruneRows > maxPrune) {
pruneRows = maxPrune;
}
prune(id, pruneRows);
}
}
LogBufferElementCollection::iterator LogBuffer::erase(
LogBufferElementCollection::iterator it, bool coalesce) {
LogBufferElement *element = *it;
log_id_t id = element->getLogId();
// Remove iterator references in the various lists that will become stale
// after the element is erased from the main logging list.
{ // start of scope for found iterator
int key = ((id == LOG_ID_EVENTS) || (id == LOG_ID_SECURITY)) ?
element->getTag() : element->getUid();
LogBufferIteratorMap::iterator found = mLastWorst[id].find(key);
if ((found != mLastWorst[id].end()) && (it == found->second)) {
mLastWorst[id].erase(found);
}
}
{ // start of scope for pid found iterator
// element->getUid() may not be AID_SYSTEM for next-best-watermark.
// will not assume id != LOG_ID_EVENTS or LOG_ID_SECURITY for KISS and
// long term code stability, find() check should be fast for those ids.
LogBufferPidIteratorMap::iterator found =
mLastWorstPidOfSystem[id].find(element->getPid());
if ((found != mLastWorstPidOfSystem[id].end())
&& (it == found->second)) {
mLastWorstPidOfSystem[id].erase(found);
}
}
bool setLast[LOG_ID_MAX];
bool doSetLast = false;
log_id_for_each(i) {
doSetLast |= setLast[i] = mLastSet[i] && (it == mLast[i]);
}
it = mLogElements.erase(it);
if (doSetLast) {
log_id_for_each(i) {
if (setLast[i]) {
if (__predict_false(it == mLogElements.end())) { // impossible
mLastSet[i] = false;
mLast[i] = mLogElements.begin();
} else {
mLast[i] = it; // push down the road as next-best-watermark
}
}
}
}
if (coalesce) {
stats.erase(element);
} else {
stats.subtract(element);
}
delete element;
return it;
}
// Define a temporary mechanism to report the last LogBufferElement pointer
// for the specified uid, pid and tid. Used below to help merge-sort when
// pruning for worst UID.
class LogBufferElementKey {
const union {
struct {
uint16_t uid;
uint16_t pid;
uint16_t tid;
uint16_t padding;
} __packed;
uint64_t value;
} __packed;
public:
LogBufferElementKey(uid_t uid, pid_t pid, pid_t tid):
uid(uid),
pid(pid),
tid(tid),
padding(0) {
}
explicit LogBufferElementKey(uint64_t key):value(key) { }
uint64_t getKey() { return value; }
};
class LogBufferElementLast {
typedef std::unordered_map<uint64_t, LogBufferElement *> LogBufferElementMap;
LogBufferElementMap map;
public:
bool coalesce(LogBufferElement *element, unsigned short dropped) {
LogBufferElementKey key(element->getUid(),
element->getPid(),
element->getTid());
LogBufferElementMap::iterator it = map.find(key.getKey());
if (it != map.end()) {
LogBufferElement *found = it->second;
unsigned short moreDropped = found->getDropped();
if ((dropped + moreDropped) > USHRT_MAX) {
map.erase(it);
} else {
found->setDropped(dropped + moreDropped);
return true;
}
}
return false;
}
void add(LogBufferElement *element) {
LogBufferElementKey key(element->getUid(),
element->getPid(),
element->getTid());
map[key.getKey()] = element;
}
inline void clear() {
map.clear();
}
void clear(LogBufferElement *element) {
uint64_t current = element->getRealTime().nsec()
- (EXPIRE_RATELIMIT * NS_PER_SEC);
for(LogBufferElementMap::iterator it = map.begin(); it != map.end();) {
LogBufferElement *mapElement = it->second;
if ((mapElement->getDropped() >= EXPIRE_THRESHOLD)
&& (current > mapElement->getRealTime().nsec())) {
it = map.erase(it);
} else {
++it;
}
}
}
};
// prune "pruneRows" of type "id" from the buffer.
//
// This garbage collection task is used to expire log entries. It is called to
// remove all logs (clear), all UID logs (unprivileged clear), or every
// 256 or 10% of the total logs (whichever is less) to prune the logs.
//
// First there is a prep phase where we discover the reader region lock that
// acts as a backstop to any pruning activity to stop there and go no further.
//
// There are three major pruning loops that follow. All expire from the oldest
// entries. Since there are multiple log buffers, the Android logging facility
// will appear to drop entries 'in the middle' when looking at multiple log
// sources and buffers. This effect is slightly more prominent when we prune
// the worst offender by logging source. Thus the logs slowly loose content
// and value as you move back in time. This is preferred since chatty sources
// invariably move the logs value down faster as less chatty sources would be
// expired in the noise.
//
// The first loop performs blacklisting and worst offender pruning. Falling
// through when there are no notable worst offenders and have not hit the
// region lock preventing further worst offender pruning. This loop also looks
// after managing the chatty log entries and merging to help provide
// statistical basis for blame. The chatty entries are not a notification of
// how much logs you may have, but instead represent how much logs you would
// have had in a virtual log buffer that is extended to cover all the in-memory
// logs without loss. They last much longer than the represented pruned logs
// since they get multiplied by the gains in the non-chatty log sources.
//
// The second loop get complicated because an algorithm of watermarks and
// history is maintained to reduce the order and keep processing time
// down to a minimum at scale. These algorithms can be costly in the face
// of larger log buffers, or severly limited processing time granted to a
// background task at lowest priority.
//
// This second loop does straight-up expiration from the end of the logs
// (again, remember for the specified log buffer id) but does some whitelist
// preservation. Thus whitelist is a Hail Mary low priority, blacklists and
// spam filtration all take priority. This second loop also checks if a region
// lock is causing us to buffer too much in the logs to help the reader(s),
// and will tell the slowest reader thread to skip log entries, and if
// persistent and hits a further threshold, kill the reader thread.
//
// The third thread is optional, and only gets hit if there was a whitelist
// and more needs to be pruned against the backstop of the region lock.
//
// mLogElementsLock must be held when this function is called.
//
bool LogBuffer::prune(log_id_t id, unsigned long pruneRows, uid_t caller_uid) {
LogTimeEntry *oldest = NULL;
bool busy = false;
bool clearAll = pruneRows == ULONG_MAX;
LogTimeEntry::lock();
// Region locked?
LastLogTimes::iterator times = mTimes.begin();
while(times != mTimes.end()) {
LogTimeEntry *entry = (*times);
if (entry->owned_Locked() && entry->isWatching(id)
&& (!oldest ||
(oldest->mStart > entry->mStart) ||
((oldest->mStart == entry->mStart) &&
(entry->mTimeout.tv_sec || entry->mTimeout.tv_nsec)))) {
oldest = entry;
}
times++;
}
LogBufferElementCollection::iterator it;
if (__predict_false(caller_uid != AID_ROOT)) { // unlikely
// Only here if clear all request from non system source, so chatty
// filter logistics is not required.
it = mLastSet[id] ? mLast[id] : mLogElements.begin();
while (it != mLogElements.end()) {
LogBufferElement *element = *it;
if ((element->getLogId() != id) || (element->getUid() != caller_uid)) {
++it;
continue;
}
if (!mLastSet[id] || ((*mLast[id])->getLogId() != id)) {
mLast[id] = it;
mLastSet[id] = true;
}
if (oldest && (oldest->mStart <= element->getSequence())) {
busy = true;
if (oldest->mTimeout.tv_sec || oldest->mTimeout.tv_nsec) {
oldest->triggerReader_Locked();
} else {
oldest->triggerSkip_Locked(id, pruneRows);
}
break;
}
it = erase(it);
if (--pruneRows == 0) {
break;
}
}
LogTimeEntry::unlock();
return busy;
}
// prune by worst offenders; by blacklist, UID, and by PID of system UID
bool hasBlacklist = (id != LOG_ID_SECURITY) && mPrune.naughty();
while (!clearAll && (pruneRows > 0)) {
// recalculate the worst offender on every batched pass
int worst = -1; // not valid for getUid() or getKey()
size_t worst_sizes = 0;
size_t second_worst_sizes = 0;
pid_t worstPid = 0; // POSIX guarantees PID != 0
if (worstUidEnabledForLogid(id) && mPrune.worstUidEnabled()) {
// Calculate threshold as 12.5% of available storage
size_t threshold = log_buffer_size(id) / 8;
if ((id == LOG_ID_EVENTS) || (id == LOG_ID_SECURITY)) {
stats.sortTags(AID_ROOT, (pid_t)0, 2, id).findWorst(
worst, worst_sizes, second_worst_sizes, threshold);
// per-pid filter for AID_SYSTEM sources is too complex
} else {
stats.sort(AID_ROOT, (pid_t)0, 2, id).findWorst(
worst, worst_sizes, second_worst_sizes, threshold);
if ((worst == AID_SYSTEM) && mPrune.worstPidOfSystemEnabled()) {
stats.sortPids(worst, (pid_t)0, 2, id).findWorst(
worstPid, worst_sizes, second_worst_sizes);
}
}
}
// skip if we have neither worst nor naughty filters
if ((worst == -1) && !hasBlacklist) {
break;
}
bool kick = false;
bool leading = true;
it = mLastSet[id] ? mLast[id] : mLogElements.begin();
// Perform at least one mandatory garbage collection cycle in following
// - clear leading chatty tags
// - coalesce chatty tags
// - check age-out of preserved logs
bool gc = pruneRows <= 1;
if (!gc && (worst != -1)) {
{ // begin scope for worst found iterator
LogBufferIteratorMap::iterator found = mLastWorst[id].find(worst);
if ((found != mLastWorst[id].end())
&& (found->second != mLogElements.end())) {
leading = false;
it = found->second;
}
}
if (worstPid) { // begin scope for pid worst found iterator
// FYI: worstPid only set if !LOG_ID_EVENTS and
// !LOG_ID_SECURITY, not going to make that assumption ...
LogBufferPidIteratorMap::iterator found
= mLastWorstPidOfSystem[id].find(worstPid);
if ((found != mLastWorstPidOfSystem[id].end())
&& (found->second != mLogElements.end())) {
leading = false;
it = found->second;
}
}
}
static const timespec too_old = {
EXPIRE_HOUR_THRESHOLD * 60 * 60, 0
};
LogBufferElementCollection::iterator lastt;
lastt = mLogElements.end();
--lastt;
LogBufferElementLast last;
while (it != mLogElements.end()) {
LogBufferElement *element = *it;
if (oldest && (oldest->mStart <= element->getSequence())) {
busy = true;
if (oldest->mTimeout.tv_sec || oldest->mTimeout.tv_nsec) {
oldest->triggerReader_Locked();
}
break;
}
if (element->getLogId() != id) {
++it;
continue;
}
// below this point element->getLogId() == id
if (leading && (!mLastSet[id] || ((*mLast[id])->getLogId() != id))) {
mLast[id] = it;
mLastSet[id] = true;
}
unsigned short dropped = element->getDropped();
// remove any leading drops
if (leading && dropped) {
it = erase(it);
continue;
}
if (dropped && last.coalesce(element, dropped)) {
it = erase(it, true);
continue;
}
int key = ((id == LOG_ID_EVENTS) || (id == LOG_ID_SECURITY)) ?
element->getTag() :
element->getUid();
if (hasBlacklist && mPrune.naughty(element)) {
last.clear(element);
it = erase(it);
if (dropped) {
continue;
}
pruneRows--;
if (pruneRows == 0) {
break;
}
if (key == worst) {
kick = true;
if (worst_sizes < second_worst_sizes) {
break;
}
worst_sizes -= element->getMsgLen();
}
continue;
}
if ((element->getRealTime() < ((*lastt)->getRealTime() - too_old))
|| (element->getRealTime() > (*lastt)->getRealTime())) {
break;
}
if (dropped) {
last.add(element);
if (worstPid
&& ((!gc && (element->getPid() == worstPid))
|| (mLastWorstPidOfSystem[id].find(element->getPid())
== mLastWorstPidOfSystem[id].end()))) {
// element->getUid() may not be AID_SYSTEM, next best
// watermark if current one empty. id is not LOG_ID_EVENTS
// or LOG_ID_SECURITY because of worstPid check.
mLastWorstPidOfSystem[id][element->getPid()] = it;
}
if ((!gc && !worstPid && (key == worst))
|| (mLastWorst[id].find(key) == mLastWorst[id].end())) {
mLastWorst[id][key] = it;
}
++it;
continue;
}
if ((key != worst)
|| (worstPid && (element->getPid() != worstPid))) {
leading = false;
last.clear(element);
++it;
continue;
}
// key == worst below here
// If worstPid set, then element->getPid() == worstPid below here
pruneRows--;
if (pruneRows == 0) {
break;
}
kick = true;
unsigned short len = element->getMsgLen();
// do not create any leading drops
if (leading) {
it = erase(it);
} else {
stats.drop(element);
element->setDropped(1);
if (last.coalesce(element, 1)) {
it = erase(it, true);
} else {
last.add(element);
if (worstPid && (!gc
|| (mLastWorstPidOfSystem[id].find(worstPid)
== mLastWorstPidOfSystem[id].end()))) {
// element->getUid() may not be AID_SYSTEM, next best
// watermark if current one empty. id is not
// LOG_ID_EVENTS or LOG_ID_SECURITY because of worstPid.
mLastWorstPidOfSystem[id][worstPid] = it;
}
if ((!gc && !worstPid) ||
(mLastWorst[id].find(worst) == mLastWorst[id].end())) {
mLastWorst[id][worst] = it;
}
++it;
}
}
if (worst_sizes < second_worst_sizes) {
break;
}
worst_sizes -= len;
}
last.clear();
if (!kick || !mPrune.worstUidEnabled()) {
break; // the following loop will ask bad clients to skip/drop
}
}
bool whitelist = false;
bool hasWhitelist = (id != LOG_ID_SECURITY) && mPrune.nice() && !clearAll;
it = mLastSet[id] ? mLast[id] : mLogElements.begin();
while((pruneRows > 0) && (it != mLogElements.end())) {
LogBufferElement *element = *it;
if (element->getLogId() != id) {
it++;
continue;
}
if (!mLastSet[id] || ((*mLast[id])->getLogId() != id)) {
mLast[id] = it;
mLastSet[id] = true;
}
if (oldest && (oldest->mStart <= element->getSequence())) {
busy = true;
if (whitelist) {
break;
}
if (stats.sizes(id) > (2 * log_buffer_size(id))) {
// kick a misbehaving log reader client off the island
oldest->release_Locked();
} else if (oldest->mTimeout.tv_sec || oldest->mTimeout.tv_nsec) {
oldest->triggerReader_Locked();
} else {
oldest->triggerSkip_Locked(id, pruneRows);
}
break;
}
if (hasWhitelist && !element->getDropped() && mPrune.nice(element)) {
// WhiteListed
whitelist = true;
it++;
continue;
}
it = erase(it);
pruneRows--;
}
// Do not save the whitelist if we are reader range limited
if (whitelist && (pruneRows > 0)) {
it = mLastSet[id] ? mLast[id] : mLogElements.begin();
while((it != mLogElements.end()) && (pruneRows > 0)) {
LogBufferElement *element = *it;
if (element->getLogId() != id) {
++it;
continue;
}
if (!mLastSet[id] || ((*mLast[id])->getLogId() != id)) {
mLast[id] = it;
mLastSet[id] = true;
}
if (oldest && (oldest->mStart <= element->getSequence())) {
busy = true;
if (stats.sizes(id) > (2 * log_buffer_size(id))) {
// kick a misbehaving log reader client off the island
oldest->release_Locked();
} else if (oldest->mTimeout.tv_sec || oldest->mTimeout.tv_nsec) {
oldest->triggerReader_Locked();
} else {
oldest->triggerSkip_Locked(id, pruneRows);
}
break;
}
it = erase(it);
pruneRows--;
}
}
LogTimeEntry::unlock();
return (pruneRows > 0) && busy;
}
// clear all rows of type "id" from the buffer.
bool LogBuffer::clear(log_id_t id, uid_t uid) {
bool busy = true;
// If it takes more than 4 tries (seconds) to clear, then kill reader(s)
for (int retry = 4;;) {
if (retry == 1) { // last pass
// Check if it is still busy after the sleep, we say prune
// one entry, not another clear run, so we are looking for
// the quick side effect of the return value to tell us if
// we have a _blocked_ reader.
pthread_mutex_lock(&mLogElementsLock);
busy = prune(id, 1, uid);
pthread_mutex_unlock(&mLogElementsLock);
// It is still busy, blocked reader(s), lets kill them all!
// otherwise, lets be a good citizen and preserve the slow
// readers and let the clear run (below) deal with determining
// if we are still blocked and return an error code to caller.
if (busy) {
LogTimeEntry::lock();
LastLogTimes::iterator times = mTimes.begin();
while (times != mTimes.end()) {
LogTimeEntry *entry = (*times);
// Killer punch
if (entry->owned_Locked() && entry->isWatching(id)) {
entry->release_Locked();
}
times++;
}
LogTimeEntry::unlock();
}
}
pthread_mutex_lock(&mLogElementsLock);
busy = prune(id, ULONG_MAX, uid);
pthread_mutex_unlock(&mLogElementsLock);
if (!busy || !--retry) {
break;
}
sleep (1); // Let reader(s) catch up after notification
}
return busy;
}
// get the used space associated with "id".
unsigned long LogBuffer::getSizeUsed(log_id_t id) {
pthread_mutex_lock(&mLogElementsLock);
size_t retval = stats.sizes(id);
pthread_mutex_unlock(&mLogElementsLock);
return retval;
}
// set the total space allocated to "id"
int LogBuffer::setSize(log_id_t id, unsigned long size) {
// Reasonable limits ...
if (!__android_logger_valid_buffer_size(size)) {
return -1;
}
pthread_mutex_lock(&mLogElementsLock);
log_buffer_size(id) = size;
pthread_mutex_unlock(&mLogElementsLock);
return 0;
}
// get the total space allocated to "id"
unsigned long LogBuffer::getSize(log_id_t id) {
pthread_mutex_lock(&mLogElementsLock);
size_t retval = log_buffer_size(id);
pthread_mutex_unlock(&mLogElementsLock);
return retval;
}
uint64_t LogBuffer::flushTo(
SocketClient *reader, const uint64_t start,
bool privileged, bool security,
int (*filter)(const LogBufferElement *element, void *arg), void *arg) {
LogBufferElementCollection::iterator it;
uint64_t max = start;
uid_t uid = reader->getUid();
pthread_mutex_lock(&mLogElementsLock);
if (start <= 1) {
// client wants to start from the beginning
it = mLogElements.begin();
} else {
// Client wants to start from some specified time. Chances are
// we are better off starting from the end of the time sorted list.
for (it = mLogElements.end(); it != mLogElements.begin(); /* do nothing */) {
--it;
LogBufferElement *element = *it;
if (element->getSequence() <= start) {
it++;
break;
}
}
}
for (; it != mLogElements.end(); ++it) {
LogBufferElement *element = *it;
if (!privileged && (element->getUid() != uid)) {
continue;
}
if (!security && (element->getLogId() == LOG_ID_SECURITY)) {
continue;
}
if (element->getSequence() <= start) {
continue;
}
// NB: calling out to another object with mLogElementsLock held (safe)
if (filter) {
int ret = (*filter)(element, arg);
if (ret == false) {
continue;
}
if (ret != true) {
break;
}
}
pthread_mutex_unlock(&mLogElementsLock);
// range locking in LastLogTimes looks after us
max = element->flushTo(reader, this, privileged);
if (max == element->FLUSH_ERROR) {
return max;
}
pthread_mutex_lock(&mLogElementsLock);
}
pthread_mutex_unlock(&mLogElementsLock);
return max;
}
std::string LogBuffer::formatStatistics(uid_t uid, pid_t pid,
unsigned int logMask) {
pthread_mutex_lock(&mLogElementsLock);
std::string ret = stats.format(uid, pid, logMask);
pthread_mutex_unlock(&mLogElementsLock);
return ret;
}