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android_system_core/liblog/fake_log_device.c
Mark Salyzyn 2d2e0a5c5e liblog: resolve deadlocks 
Although ever present, an increased regression introduced with
commit b6bee33182 (liblog: logd:
support logd.timestamp = monotonic).

A signal handler can interrupt in locked context, if log is written
in the signal handler, we are in deadlock. To reduce the contention
and chances for this problem separate out timestamp lock from is
loggable lock to reduce contention situations. Provide a best-guess
response if lock would fail in timestamp path.

Use a common lock() inline within each module, with a comment speaking
to the issues surrounding calling a function that has a mutex within
a signal handler.

ToDo: Hold off signals temporarily in mainline, restart when unblock.
      Can not use pthread_sigmask(SIG_BLOCK,,) as it breaks AtCmd.

Signed-off-by: Mark Salyzyn <salyzyn@google.com>
Bug: 25563384
Change-Id: I47e2c87c988c3e359eb9eef129c6a3a08e9eedef
2015-11-19 13:14:16 -08:00

704 lines
19 KiB
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/*
* Copyright (C) 2008-2014 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.
*/
/*
* Intercepts log messages intended for the Android log device.
* When running in the context of the simulator, the messages are
* passed on to the underlying (fake) log device. When not in the
* simulator, messages are printed to stderr.
*/
#include "fake_log_device.h"
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <stdlib.h>
#include <string.h>
#include <log/logd.h>
#if !defined(_WIN32)
#include <pthread.h>
#endif
#ifndef __unused
#define __unused __attribute__((__unused__))
#endif
#define kMaxTagLen 16 /* from the long-dead utils/Log.cpp */
#define kTagSetSize 16 /* arbitrary */
#if 0
#define TRACE(...) printf("fake_log_device: " __VA_ARGS__)
#else
#define TRACE(...) ((void)0)
#endif
/* from the long-dead utils/Log.cpp */
typedef enum {
FORMAT_OFF = 0,
FORMAT_BRIEF,
FORMAT_PROCESS,
FORMAT_TAG,
FORMAT_THREAD,
FORMAT_RAW,
FORMAT_TIME,
FORMAT_THREADTIME,
FORMAT_LONG
} LogFormat;
/*
* Log driver state.
*/
typedef struct LogState {
/* the fake fd that's seen by the user */
int fakeFd;
/* a printable name for this fake device */
char *debugName;
/* nonzero if this is a binary log */
int isBinary;
/* global minimum priority */
int globalMinPriority;
/* output format */
LogFormat outputFormat;
/* tags and priorities */
struct {
char tag[kMaxTagLen];
int minPriority;
} tagSet[kTagSetSize];
} LogState;
#if !defined(_WIN32)
/*
* Locking. Since we're emulating a device, we need to be prepared
* to have multiple callers at the same time. This lock is used
* to both protect the fd list and to prevent LogStates from being
* freed out from under a user.
*/
static pthread_mutex_t fakeLogDeviceLock = PTHREAD_MUTEX_INITIALIZER;
static void lock()
{
/*
* If we trigger a signal handler in the middle of locked activity and the
* signal handler logs a message, we could get into a deadlock state.
*/
pthread_mutex_lock(&fakeLogDeviceLock);
}
static void unlock()
{
pthread_mutex_unlock(&fakeLogDeviceLock);
}
#else // !defined(_WIN32)
#define lock() ((void)0)
#define unlock() ((void)0)
#endif // !defined(_WIN32)
/*
* File descriptor management.
*/
#define FAKE_FD_BASE 10000
#define MAX_OPEN_LOGS 16
static LogState *openLogTable[MAX_OPEN_LOGS];
/*
* Allocate an fd and associate a new LogState with it.
* The fd is available via the fakeFd field of the return value.
*/
static LogState *createLogState()
{
size_t i;
for (i = 0; i < sizeof(openLogTable); i++) {
if (openLogTable[i] == NULL) {
openLogTable[i] = calloc(1, sizeof(LogState));
openLogTable[i]->fakeFd = FAKE_FD_BASE + i;
return openLogTable[i];
}
}
return NULL;
}
/*
* Translate an fd to a LogState.
*/
static LogState *fdToLogState(int fd)
{
if (fd >= FAKE_FD_BASE && fd < FAKE_FD_BASE + MAX_OPEN_LOGS) {
return openLogTable[fd - FAKE_FD_BASE];
}
return NULL;
}
/*
* Unregister the fake fd and free the memory it pointed to.
*/
static void deleteFakeFd(int fd)
{
LogState *ls;
lock();
ls = fdToLogState(fd);
if (ls != NULL) {
openLogTable[fd - FAKE_FD_BASE] = NULL;
free(ls->debugName);
free(ls);
}
unlock();
}
/*
* Configure logging based on ANDROID_LOG_TAGS environment variable. We
* need to parse a string that looks like
*
* *:v jdwp:d dalvikvm:d dalvikvm-gc:i dalvikvmi:i
*
* The tag (or '*' for the global level) comes first, followed by a colon
* and a letter indicating the minimum priority level we're expected to log.
* This can be used to reveal or conceal logs with specific tags.
*
* We also want to check ANDROID_PRINTF_LOG to determine how the output
* will look.
*/
static void configureInitialState(const char* pathName, LogState* logState)
{
static const int kDevLogLen = sizeof("/dev/log/") - 1;
logState->debugName = strdup(pathName);
/* identify binary logs */
if (strcmp(pathName + kDevLogLen, "events") == 0) {
logState->isBinary = 1;
}
/* global min priority defaults to "info" level */
logState->globalMinPriority = ANDROID_LOG_INFO;
/*
* This is based on the the long-dead utils/Log.cpp code.
*/
const char* tags = getenv("ANDROID_LOG_TAGS");
TRACE("Found ANDROID_LOG_TAGS='%s'\n", tags);
if (tags != NULL) {
int entry = 0;
while (*tags != '\0') {
char tagName[kMaxTagLen];
int i, minPrio;
while (isspace(*tags))
tags++;
i = 0;
while (*tags != '\0' && !isspace(*tags) && *tags != ':' &&
i < kMaxTagLen)
{
tagName[i++] = *tags++;
}
if (i == kMaxTagLen) {
TRACE("ERROR: env tag too long (%d chars max)\n", kMaxTagLen-1);
return;
}
tagName[i] = '\0';
/* default priority, if there's no ":" part; also zero out '*' */
minPrio = ANDROID_LOG_VERBOSE;
if (tagName[0] == '*' && tagName[1] == '\0') {
minPrio = ANDROID_LOG_DEBUG;
tagName[0] = '\0';
}
if (*tags == ':') {
tags++;
if (*tags >= '0' && *tags <= '9') {
if (*tags >= ('0' + ANDROID_LOG_SILENT))
minPrio = ANDROID_LOG_VERBOSE;
else
minPrio = *tags - '\0';
} else {
switch (*tags) {
case 'v': minPrio = ANDROID_LOG_VERBOSE; break;
case 'd': minPrio = ANDROID_LOG_DEBUG; break;
case 'i': minPrio = ANDROID_LOG_INFO; break;
case 'w': minPrio = ANDROID_LOG_WARN; break;
case 'e': minPrio = ANDROID_LOG_ERROR; break;
case 'f': minPrio = ANDROID_LOG_FATAL; break;
case 's': minPrio = ANDROID_LOG_SILENT; break;
default: minPrio = ANDROID_LOG_DEFAULT; break;
}
}
tags++;
if (*tags != '\0' && !isspace(*tags)) {
TRACE("ERROR: garbage in tag env; expected whitespace\n");
TRACE(" env='%s'\n", tags);
return;
}
}
if (tagName[0] == 0) {
logState->globalMinPriority = minPrio;
TRACE("+++ global min prio %d\n", logState->globalMinPriority);
} else {
logState->tagSet[entry].minPriority = minPrio;
strcpy(logState->tagSet[entry].tag, tagName);
TRACE("+++ entry %d: %s:%d\n",
entry,
logState->tagSet[entry].tag,
logState->tagSet[entry].minPriority);
entry++;
}
}
}
/*
* Taken from the long-dead utils/Log.cpp
*/
const char* fstr = getenv("ANDROID_PRINTF_LOG");
LogFormat format;
if (fstr == NULL) {
format = FORMAT_BRIEF;
} else {
if (strcmp(fstr, "brief") == 0)
format = FORMAT_BRIEF;
else if (strcmp(fstr, "process") == 0)
format = FORMAT_PROCESS;
else if (strcmp(fstr, "tag") == 0)
format = FORMAT_PROCESS;
else if (strcmp(fstr, "thread") == 0)
format = FORMAT_PROCESS;
else if (strcmp(fstr, "raw") == 0)
format = FORMAT_PROCESS;
else if (strcmp(fstr, "time") == 0)
format = FORMAT_PROCESS;
else if (strcmp(fstr, "long") == 0)
format = FORMAT_PROCESS;
else
format = (LogFormat) atoi(fstr); // really?!
}
logState->outputFormat = format;
}
/*
* Return a human-readable string for the priority level. Always returns
* a valid string.
*/
static const char* getPriorityString(int priority)
{
/* the first character of each string should be unique */
static const char* priorityStrings[] = {
"Verbose", "Debug", "Info", "Warn", "Error", "Assert"
};
int idx;
idx = (int) priority - (int) ANDROID_LOG_VERBOSE;
if (idx < 0 ||
idx >= (int) (sizeof(priorityStrings) / sizeof(priorityStrings[0])))
return "?unknown?";
return priorityStrings[idx];
}
#if defined(_WIN32)
/*
* WIN32 does not have writev().
* Make up something to replace it.
*/
static ssize_t fake_writev(int fd, const struct iovec *iov, int iovcnt) {
ssize_t result = 0;
const struct iovec* end = iov + iovcnt;
for (; iov < end; iov++) {
ssize_t w = write(fd, iov->iov_base, iov->iov_len);
if (w != (ssize_t) iov->iov_len) {
if (w < 0)
return w;
return result + w;
}
result += w;
}
return result;
}
#define writev fake_writev
#endif
/*
* Write a filtered log message to stderr.
*
* Log format parsing taken from the long-dead utils/Log.cpp.
*/
static void showLog(LogState *state,
int logPrio, const char* tag, const char* msg)
{
#if !defined(_WIN32)
struct tm tmBuf;
#endif
struct tm* ptm;
char timeBuf[32];
char prefixBuf[128], suffixBuf[128];
char priChar;
time_t when;
pid_t pid, tid;
TRACE("LOG %d: %s %s", logPrio, tag, msg);
priChar = getPriorityString(logPrio)[0];
when = time(NULL);
pid = tid = getpid(); // find gettid()?
/*
* Get the current date/time in pretty form
*
* It's often useful when examining a log with "less" to jump to
* a specific point in the file by searching for the date/time stamp.
* For this reason it's very annoying to have regexp meta characters
* in the time stamp. Don't use forward slashes, parenthesis,
* brackets, asterisks, or other special chars here.
*/
#if !defined(_WIN32)
ptm = localtime_r(&when, &tmBuf);
#else
ptm = localtime(&when);
#endif
//strftime(timeBuf, sizeof(timeBuf), "%Y-%m-%d %H:%M:%S", ptm);
strftime(timeBuf, sizeof(timeBuf), "%m-%d %H:%M:%S", ptm);
/*
* Construct a buffer containing the log header and log message.
*/
size_t prefixLen, suffixLen;
switch (state->outputFormat) {
case FORMAT_TAG:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"%c/%-8s: ", priChar, tag);
strcpy(suffixBuf, "\n"); suffixLen = 1;
break;
case FORMAT_PROCESS:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"%c(%5d) ", priChar, pid);
suffixLen = snprintf(suffixBuf, sizeof(suffixBuf),
" (%s)\n", tag);
break;
case FORMAT_THREAD:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"%c(%5d:%5d) ", priChar, pid, tid);
strcpy(suffixBuf, "\n"); suffixLen = 1;
break;
case FORMAT_RAW:
prefixBuf[0] = 0; prefixLen = 0;
strcpy(suffixBuf, "\n"); suffixLen = 1;
break;
case FORMAT_TIME:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"%s %-8s\n\t", timeBuf, tag);
strcpy(suffixBuf, "\n"); suffixLen = 1;
break;
case FORMAT_THREADTIME:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"%s %5d %5d %c %-8s \n\t", timeBuf, pid, tid, priChar, tag);
strcpy(suffixBuf, "\n"); suffixLen = 1;
break;
case FORMAT_LONG:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"[ %s %5d:%5d %c/%-8s ]\n",
timeBuf, pid, tid, priChar, tag);
strcpy(suffixBuf, "\n\n"); suffixLen = 2;
break;
default:
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf),
"%c/%-8s(%5d): ", priChar, tag, pid);
strcpy(suffixBuf, "\n"); suffixLen = 1;
break;
}
/*
* Figure out how many lines there will be.
*/
const char* end = msg + strlen(msg);
size_t numLines = 0;
const char* p = msg;
while (p < end) {
if (*p++ == '\n') numLines++;
}
if (p > msg && *(p-1) != '\n') numLines++;
/*
* Create an array of iovecs large enough to write all of
* the lines with a prefix and a suffix.
*/
const size_t INLINE_VECS = 6;
const size_t MAX_LINES = ((size_t)~0)/(3*sizeof(struct iovec*));
struct iovec stackVec[INLINE_VECS];
struct iovec* vec = stackVec;
size_t numVecs;
if (numLines > MAX_LINES)
numLines = MAX_LINES;
numVecs = numLines*3; // 3 iovecs per line.
if (numVecs > INLINE_VECS) {
vec = (struct iovec*)malloc(sizeof(struct iovec)*numVecs);
if (vec == NULL) {
msg = "LOG: write failed, no memory";
numVecs = 3;
numLines = 1;
vec = stackVec;
}
}
/*
* Fill in the iovec pointers.
*/
p = msg;
struct iovec* v = vec;
int totalLen = 0;
while (numLines > 0 && p < end) {
if (prefixLen > 0) {
v->iov_base = prefixBuf;
v->iov_len = prefixLen;
totalLen += prefixLen;
v++;
}
const char* start = p;
while (p < end && *p != '\n') p++;
if ((p-start) > 0) {
v->iov_base = (void*)start;
v->iov_len = p-start;
totalLen += p-start;
v++;
}
if (*p == '\n') p++;
if (suffixLen > 0) {
v->iov_base = suffixBuf;
v->iov_len = suffixLen;
totalLen += suffixLen;
v++;
}
numLines -= 1;
}
/*
* Write the entire message to the log file with a single writev() call.
* We need to use this rather than a collection of printf()s on a FILE*
* because of multi-threading and multi-process issues.
*
* If the file was not opened with O_APPEND, this will produce interleaved
* output when called on the same file from multiple processes.
*
* If the file descriptor is actually a network socket, the writev()
* call may return with a partial write. Putting the writev() call in
* a loop can result in interleaved data. This can be alleviated
* somewhat by wrapping the writev call in the Mutex.
*/
for(;;) {
int cc = writev(fileno(stderr), vec, v-vec);
if (cc == totalLen) break;
if (cc < 0) {
if(errno == EINTR) continue;
/* can't really log the failure; for now, throw out a stderr */
fprintf(stderr, "+++ LOG: write failed (errno=%d)\n", errno);
break;
} else {
/* shouldn't happen when writing to file or tty */
fprintf(stderr, "+++ LOG: write partial (%d of %d)\n", cc, totalLen);
break;
}
}
/* if we allocated storage for the iovecs, free it */
if (vec != stackVec)
free(vec);
}
/*
* Receive a log message. We happen to know that "vector" has three parts:
*
* priority (1 byte)
* tag (N bytes -- null-terminated ASCII string)
* message (N bytes -- null-terminated ASCII string)
*/
static ssize_t logWritev(int fd, const struct iovec* vector, int count)
{
LogState* state;
/* Make sure that no-one frees the LogState while we're using it.
* Also guarantees that only one thread is in showLog() at a given
* time (if it matters).
*/
lock();
state = fdToLogState(fd);
if (state == NULL) {
errno = EBADF;
goto error;
}
if (state->isBinary) {
TRACE("%s: ignoring binary log\n", state->debugName);
goto bail;
}
if (count != 3) {
TRACE("%s: writevLog with count=%d not expected\n",
state->debugName, count);
goto error;
}
/* pull out the three fields */
int logPrio = *(const char*)vector[0].iov_base;
const char* tag = (const char*) vector[1].iov_base;
const char* msg = (const char*) vector[2].iov_base;
/* see if this log tag is configured */
int i;
int minPrio = state->globalMinPriority;
for (i = 0; i < kTagSetSize; i++) {
if (state->tagSet[i].minPriority == ANDROID_LOG_UNKNOWN)
break; /* reached end of configured values */
if (strcmp(state->tagSet[i].tag, tag) == 0) {
//TRACE("MATCH tag '%s'\n", tag);
minPrio = state->tagSet[i].minPriority;
break;
}
}
if (logPrio >= minPrio) {
showLog(state, logPrio, tag, msg);
} else {
//TRACE("+++ NOLOG(%d): %s %s", logPrio, tag, msg);
}
bail:
unlock();
return vector[0].iov_len + vector[1].iov_len + vector[2].iov_len;
error:
unlock();
return -1;
}
/*
* Free up our state and close the fake descriptor.
*/
static int logClose(int fd)
{
deleteFakeFd(fd);
return 0;
}
/*
* Open a log output device and return a fake fd.
*/
static int logOpen(const char* pathName, int flags __unused)
{
LogState *logState;
int fd = -1;
lock();
logState = createLogState();
if (logState != NULL) {
configureInitialState(pathName, logState);
fd = logState->fakeFd;
} else {
errno = ENFILE;
}
unlock();
return fd;
}
/*
* Runtime redirection. If this binary is running in the simulator,
* just pass log messages to the emulated device. If it's running
* outside of the simulator, write the log messages to stderr.
*/
static int (*redirectOpen)(const char *pathName, int flags) = NULL;
static int (*redirectClose)(int fd) = NULL;
static ssize_t (*redirectWritev)(int fd, const struct iovec* vector, int count)
= NULL;
static void setRedirects()
{
const char *ws;
/* Wrapsim sets this environment variable on children that it's
* created using its LD_PRELOAD wrapper.
*/
ws = getenv("ANDROID_WRAPSIM");
if (ws != NULL && strcmp(ws, "1") == 0) {
/* We're running inside wrapsim, so we can just write to the device. */
redirectOpen = (int (*)(const char *pathName, int flags))open;
redirectClose = close;
redirectWritev = writev;
} else {
/* There's no device to delegate to; handle the logging ourselves. */
redirectOpen = logOpen;
redirectClose = logClose;
redirectWritev = logWritev;
}
}
int fakeLogOpen(const char *pathName, int flags)
{
if (redirectOpen == NULL) {
setRedirects();
}
return redirectOpen(pathName, flags);
}
int fakeLogClose(int fd)
{
/* Assume that open() was called first. */
return redirectClose(fd);
}
ssize_t fakeLogWritev(int fd, const struct iovec* vector, int count)
{
/* Assume that open() was called first. */
return redirectWritev(fd, vector, count);
}
int __android_log_is_loggable(int prio, const char *tag __unused, int def)
{
int logLevel = def;
return logLevel >= 0 && prio >= logLevel;
}
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