/* * 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() { 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; }