blob: bd36cddb8d9bf01358db672dc6f51d3df920c83b [file] [log] [blame]
/*
**
** Copyright 2006-2014, 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.
*/
#define _GNU_SOURCE /* for asprintf */
#include <arpa/inet.h>
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <inttypes.h>
#include <sys/param.h>
#include <cutils/list.h>
#include <log/logd.h>
#include <log/logprint.h>
#include <private/android_filesystem_config.h>
#define MS_PER_NSEC 1000000
#define US_PER_NSEC 1000
/* open coded fragment, prevent circular dependencies */
#define WEAK static
typedef struct FilterInfo_t {
char *mTag;
android_LogPriority mPri;
struct FilterInfo_t *p_next;
} FilterInfo;
struct AndroidLogFormat_t {
android_LogPriority global_pri;
FilterInfo *filters;
AndroidLogPrintFormat format;
bool colored_output;
bool usec_time_output;
bool printable_output;
bool year_output;
bool zone_output;
bool epoch_output;
bool monotonic_output;
bool uid_output;
};
/*
* gnome-terminal color tags
* See http://misc.flogisoft.com/bash/tip_colors_and_formatting
* for ideas on how to set the forground color of the text for xterm.
* The color manipulation character stream is defined as:
* ESC [ 3 8 ; 5 ; <color#> m
*/
#define ANDROID_COLOR_BLUE 75
#define ANDROID_COLOR_DEFAULT 231
#define ANDROID_COLOR_GREEN 40
#define ANDROID_COLOR_ORANGE 166
#define ANDROID_COLOR_RED 196
#define ANDROID_COLOR_YELLOW 226
static FilterInfo * filterinfo_new(const char * tag, android_LogPriority pri)
{
FilterInfo *p_ret;
p_ret = (FilterInfo *)calloc(1, sizeof(FilterInfo));
p_ret->mTag = strdup(tag);
p_ret->mPri = pri;
return p_ret;
}
/* balance to above, filterinfo_free left unimplemented */
/*
* Note: also accepts 0-9 priorities
* returns ANDROID_LOG_UNKNOWN if the character is unrecognized
*/
static android_LogPriority filterCharToPri (char c)
{
android_LogPriority pri;
c = tolower(c);
if (c >= '0' && c <= '9') {
if (c >= ('0'+ANDROID_LOG_SILENT)) {
pri = ANDROID_LOG_VERBOSE;
} else {
pri = (android_LogPriority)(c - '0');
}
} else if (c == 'v') {
pri = ANDROID_LOG_VERBOSE;
} else if (c == 'd') {
pri = ANDROID_LOG_DEBUG;
} else if (c == 'i') {
pri = ANDROID_LOG_INFO;
} else if (c == 'w') {
pri = ANDROID_LOG_WARN;
} else if (c == 'e') {
pri = ANDROID_LOG_ERROR;
} else if (c == 'f') {
pri = ANDROID_LOG_FATAL;
} else if (c == 's') {
pri = ANDROID_LOG_SILENT;
} else if (c == '*') {
pri = ANDROID_LOG_DEFAULT;
} else {
pri = ANDROID_LOG_UNKNOWN;
}
return pri;
}
static char filterPriToChar (android_LogPriority pri)
{
switch (pri) {
case ANDROID_LOG_VERBOSE: return 'V';
case ANDROID_LOG_DEBUG: return 'D';
case ANDROID_LOG_INFO: return 'I';
case ANDROID_LOG_WARN: return 'W';
case ANDROID_LOG_ERROR: return 'E';
case ANDROID_LOG_FATAL: return 'F';
case ANDROID_LOG_SILENT: return 'S';
case ANDROID_LOG_DEFAULT:
case ANDROID_LOG_UNKNOWN:
default: return '?';
}
}
static int colorFromPri (android_LogPriority pri)
{
switch (pri) {
case ANDROID_LOG_VERBOSE: return ANDROID_COLOR_DEFAULT;
case ANDROID_LOG_DEBUG: return ANDROID_COLOR_BLUE;
case ANDROID_LOG_INFO: return ANDROID_COLOR_GREEN;
case ANDROID_LOG_WARN: return ANDROID_COLOR_ORANGE;
case ANDROID_LOG_ERROR: return ANDROID_COLOR_RED;
case ANDROID_LOG_FATAL: return ANDROID_COLOR_RED;
case ANDROID_LOG_SILENT: return ANDROID_COLOR_DEFAULT;
case ANDROID_LOG_DEFAULT:
case ANDROID_LOG_UNKNOWN:
default: return ANDROID_COLOR_DEFAULT;
}
}
static android_LogPriority filterPriForTag(
AndroidLogFormat *p_format, const char *tag)
{
FilterInfo *p_curFilter;
for (p_curFilter = p_format->filters
; p_curFilter != NULL
; p_curFilter = p_curFilter->p_next
) {
if (0 == strcmp(tag, p_curFilter->mTag)) {
if (p_curFilter->mPri == ANDROID_LOG_DEFAULT) {
return p_format->global_pri;
} else {
return p_curFilter->mPri;
}
}
}
return p_format->global_pri;
}
/**
* returns 1 if this log line should be printed based on its priority
* and tag, and 0 if it should not
*/
int android_log_shouldPrintLine (
AndroidLogFormat *p_format, const char *tag, android_LogPriority pri)
{
return pri >= filterPriForTag(p_format, tag);
}
AndroidLogFormat *android_log_format_new()
{
AndroidLogFormat *p_ret;
p_ret = calloc(1, sizeof(AndroidLogFormat));
p_ret->global_pri = ANDROID_LOG_VERBOSE;
p_ret->format = FORMAT_BRIEF;
p_ret->colored_output = false;
p_ret->usec_time_output = false;
p_ret->printable_output = false;
p_ret->year_output = false;
p_ret->zone_output = false;
p_ret->epoch_output = false;
p_ret->monotonic_output = android_log_clockid() == CLOCK_MONOTONIC;
p_ret->uid_output = false;
return p_ret;
}
static list_declare(convertHead);
void android_log_format_free(AndroidLogFormat *p_format)
{
FilterInfo *p_info, *p_info_old;
p_info = p_format->filters;
while (p_info != NULL) {
p_info_old = p_info;
p_info = p_info->p_next;
free(p_info_old);
}
free(p_format);
/* Free conversion resource, can always be reconstructed */
while (!list_empty(&convertHead)) {
struct listnode *node = list_head(&convertHead);
list_remove(node);
free(node);
}
}
int android_log_setPrintFormat(AndroidLogFormat *p_format,
AndroidLogPrintFormat format)
{
switch (format) {
case FORMAT_MODIFIER_COLOR:
p_format->colored_output = true;
return 0;
case FORMAT_MODIFIER_TIME_USEC:
p_format->usec_time_output = true;
return 0;
case FORMAT_MODIFIER_PRINTABLE:
p_format->printable_output = true;
return 0;
case FORMAT_MODIFIER_YEAR:
p_format->year_output = true;
return 0;
case FORMAT_MODIFIER_ZONE:
p_format->zone_output = !p_format->zone_output;
return 0;
case FORMAT_MODIFIER_EPOCH:
p_format->epoch_output = true;
return 0;
case FORMAT_MODIFIER_MONOTONIC:
p_format->monotonic_output = true;
return 0;
case FORMAT_MODIFIER_UID:
p_format->uid_output = true;
return 0;
default:
break;
}
p_format->format = format;
return 1;
}
static const char tz[] = "TZ";
static const char utc[] = "UTC";
/**
* Returns FORMAT_OFF on invalid string
*/
AndroidLogPrintFormat android_log_formatFromString(const char * formatString)
{
static AndroidLogPrintFormat format;
if (strcmp(formatString, "brief") == 0) format = FORMAT_BRIEF;
else if (strcmp(formatString, "process") == 0) format = FORMAT_PROCESS;
else if (strcmp(formatString, "tag") == 0) format = FORMAT_TAG;
else if (strcmp(formatString, "thread") == 0) format = FORMAT_THREAD;
else if (strcmp(formatString, "raw") == 0) format = FORMAT_RAW;
else if (strcmp(formatString, "time") == 0) format = FORMAT_TIME;
else if (strcmp(formatString, "threadtime") == 0) format = FORMAT_THREADTIME;
else if (strcmp(formatString, "long") == 0) format = FORMAT_LONG;
else if (strcmp(formatString, "color") == 0) format = FORMAT_MODIFIER_COLOR;
else if (strcmp(formatString, "usec") == 0) format = FORMAT_MODIFIER_TIME_USEC;
else if (strcmp(formatString, "printable") == 0) format = FORMAT_MODIFIER_PRINTABLE;
else if (strcmp(formatString, "year") == 0) format = FORMAT_MODIFIER_YEAR;
else if (strcmp(formatString, "zone") == 0) format = FORMAT_MODIFIER_ZONE;
else if (strcmp(formatString, "epoch") == 0) format = FORMAT_MODIFIER_EPOCH;
else if (strcmp(formatString, "monotonic") == 0) format = FORMAT_MODIFIER_MONOTONIC;
else if (strcmp(formatString, "uid") == 0) format = FORMAT_MODIFIER_UID;
else {
extern char *tzname[2];
static const char gmt[] = "GMT";
char *cp = getenv(tz);
if (cp) {
cp = strdup(cp);
}
setenv(tz, formatString, 1);
/*
* Run tzset here to determine if the timezone is legitimate. If the
* zone is GMT, check if that is what was asked for, if not then
* did not match any on the system; report an error to caller.
*/
tzset();
if (!tzname[0]
|| ((!strcmp(tzname[0], utc)
|| !strcmp(tzname[0], gmt)) /* error? */
&& strcasecmp(formatString, utc)
&& strcasecmp(formatString, gmt))) { /* ok */
if (cp) {
setenv(tz, cp, 1);
} else {
unsetenv(tz);
}
tzset();
format = FORMAT_OFF;
} else {
format = FORMAT_MODIFIER_ZONE;
}
free(cp);
}
return format;
}
/**
* filterExpression: a single filter expression
* eg "AT:d"
*
* returns 0 on success and -1 on invalid expression
*
* Assumes single threaded execution
*/
int android_log_addFilterRule(AndroidLogFormat *p_format,
const char *filterExpression)
{
size_t tagNameLength;
android_LogPriority pri = ANDROID_LOG_DEFAULT;
tagNameLength = strcspn(filterExpression, ":");
if (tagNameLength == 0) {
goto error;
}
if(filterExpression[tagNameLength] == ':') {
pri = filterCharToPri(filterExpression[tagNameLength+1]);
if (pri == ANDROID_LOG_UNKNOWN) {
goto error;
}
}
if(0 == strncmp("*", filterExpression, tagNameLength)) {
/*
* This filter expression refers to the global filter
* The default level for this is DEBUG if the priority
* is unspecified
*/
if (pri == ANDROID_LOG_DEFAULT) {
pri = ANDROID_LOG_DEBUG;
}
p_format->global_pri = pri;
} else {
/*
* for filter expressions that don't refer to the global
* filter, the default is verbose if the priority is unspecified
*/
if (pri == ANDROID_LOG_DEFAULT) {
pri = ANDROID_LOG_VERBOSE;
}
char *tagName;
/*
* Presently HAVE_STRNDUP is never defined, so the second case is always taken
* Darwin doesn't have strnup, everything else does
*/
#ifdef HAVE_STRNDUP
tagName = strndup(filterExpression, tagNameLength);
#else
/* a few extra bytes copied... */
tagName = strdup(filterExpression);
tagName[tagNameLength] = '\0';
#endif /*HAVE_STRNDUP*/
FilterInfo *p_fi = filterinfo_new(tagName, pri);
free(tagName);
p_fi->p_next = p_format->filters;
p_format->filters = p_fi;
}
return 0;
error:
return -1;
}
/**
* filterString: a comma/whitespace-separated set of filter expressions
*
* eg "AT:d *:i"
*
* returns 0 on success and -1 on invalid expression
*
* Assumes single threaded execution
*
*/
int android_log_addFilterString(AndroidLogFormat *p_format,
const char *filterString)
{
char *filterStringCopy = strdup (filterString);
char *p_cur = filterStringCopy;
char *p_ret;
int err;
/* Yes, I'm using strsep */
while (NULL != (p_ret = strsep(&p_cur, " \t,"))) {
/* ignore whitespace-only entries */
if(p_ret[0] != '\0') {
err = android_log_addFilterRule(p_format, p_ret);
if (err < 0) {
goto error;
}
}
}
free (filterStringCopy);
return 0;
error:
free (filterStringCopy);
return -1;
}
/**
* Splits a wire-format buffer into an AndroidLogEntry
* entry allocated by caller. Pointers will point directly into buf
*
* Returns 0 on success and -1 on invalid wire format (entry will be
* in unspecified state)
*/
int android_log_processLogBuffer(struct logger_entry *buf,
AndroidLogEntry *entry)
{
entry->tv_sec = buf->sec;
entry->tv_nsec = buf->nsec;
entry->uid = -1;
entry->pid = buf->pid;
entry->tid = buf->tid;
/*
* format: <priority:1><tag:N>\0<message:N>\0
*
* tag str
* starts at buf->msg+1
* msg
* starts at buf->msg+1+len(tag)+1
*
* The message may have been truncated by the kernel log driver.
* When that happens, we must null-terminate the message ourselves.
*/
if (buf->len < 3) {
/*
* An well-formed entry must consist of at least a priority
* and two null characters
*/
fprintf(stderr, "+++ LOG: entry too small\n");
return -1;
}
int msgStart = -1;
int msgEnd = -1;
int i;
char *msg = buf->msg;
struct logger_entry_v2 *buf2 = (struct logger_entry_v2 *)buf;
if (buf2->hdr_size) {
msg = ((char *)buf2) + buf2->hdr_size;
if (buf2->hdr_size >= sizeof(struct logger_entry_v4)) {
entry->uid = ((struct logger_entry_v4 *)buf)->uid;
}
}
for (i = 1; i < buf->len; i++) {
if (msg[i] == '\0') {
if (msgStart == -1) {
msgStart = i + 1;
} else {
msgEnd = i;
break;
}
}
}
if (msgStart == -1) {
fprintf(stderr, "+++ LOG: malformed log message\n");
return -1;
}
if (msgEnd == -1) {
/* incoming message not null-terminated; force it */
msgEnd = buf->len - 1; /* may result in msgEnd < msgStart */
msg[msgEnd] = '\0';
}
entry->priority = msg[0];
entry->tag = msg + 1;
entry->message = msg + msgStart;
entry->messageLen = (msgEnd < msgStart) ? 0 : (msgEnd - msgStart);
return 0;
}
/*
* Extract a 4-byte value from a byte stream.
*/
static inline uint32_t get4LE(const uint8_t* src)
{
return src[0] | (src[1] << 8) | (src[2] << 16) | (src[3] << 24);
}
/*
* Extract an 8-byte value from a byte stream.
*/
static inline uint64_t get8LE(const uint8_t* src)
{
uint32_t low, high;
low = src[0] | (src[1] << 8) | (src[2] << 16) | (src[3] << 24);
high = src[4] | (src[5] << 8) | (src[6] << 16) | (src[7] << 24);
return ((uint64_t) high << 32) | (uint64_t) low;
}
/*
* Recursively convert binary log data to printable form.
*
* This needs to be recursive because you can have lists of lists.
*
* If we run out of room, we stop processing immediately. It's important
* for us to check for space on every output element to avoid producing
* garbled output.
*
* Returns 0 on success, 1 on buffer full, -1 on failure.
*/
static int android_log_printBinaryEvent(const unsigned char** pEventData,
size_t* pEventDataLen, char** pOutBuf, size_t* pOutBufLen)
{
const unsigned char* eventData = *pEventData;
size_t eventDataLen = *pEventDataLen;
char* outBuf = *pOutBuf;
size_t outBufLen = *pOutBufLen;
unsigned char type;
size_t outCount;
int result = 0;
if (eventDataLen < 1)
return -1;
type = *eventData++;
eventDataLen--;
switch (type) {
case EVENT_TYPE_INT:
/* 32-bit signed int */
{
int ival;
if (eventDataLen < 4)
return -1;
ival = get4LE(eventData);
eventData += 4;
eventDataLen -= 4;
outCount = snprintf(outBuf, outBufLen, "%d", ival);
if (outCount < outBufLen) {
outBuf += outCount;
outBufLen -= outCount;
} else {
/* halt output */
goto no_room;
}
}
break;
case EVENT_TYPE_LONG:
/* 64-bit signed long */
{
uint64_t lval;
if (eventDataLen < 8)
return -1;
lval = get8LE(eventData);
eventData += 8;
eventDataLen -= 8;
outCount = snprintf(outBuf, outBufLen, "%" PRId64, lval);
if (outCount < outBufLen) {
outBuf += outCount;
outBufLen -= outCount;
} else {
/* halt output */
goto no_room;
}
}
break;
case EVENT_TYPE_FLOAT:
/* float */
{
uint32_t ival;
float fval;
if (eventDataLen < 4)
return -1;
ival = get4LE(eventData);
fval = *(float*)&ival;
eventData += 4;
eventDataLen -= 4;
outCount = snprintf(outBuf, outBufLen, "%f", fval);
if (outCount < outBufLen) {
outBuf += outCount;
outBufLen -= outCount;
} else {
/* halt output */
goto no_room;
}
}
break;
case EVENT_TYPE_STRING:
/* UTF-8 chars, not NULL-terminated */
{
unsigned int strLen;
if (eventDataLen < 4)
return -1;
strLen = get4LE(eventData);
eventData += 4;
eventDataLen -= 4;
if (eventDataLen < strLen)
return -1;
if (strLen < outBufLen) {
memcpy(outBuf, eventData, strLen);
outBuf += strLen;
outBufLen -= strLen;
} else if (outBufLen > 0) {
/* copy what we can */
memcpy(outBuf, eventData, outBufLen);
outBuf += outBufLen;
outBufLen -= outBufLen;
goto no_room;
}
eventData += strLen;
eventDataLen -= strLen;
break;
}
case EVENT_TYPE_LIST:
/* N items, all different types */
{
unsigned char count;
int i;
if (eventDataLen < 1)
return -1;
count = *eventData++;
eventDataLen--;
if (outBufLen > 0) {
*outBuf++ = '[';
outBufLen--;
} else {
goto no_room;
}
for (i = 0; i < count; i++) {
result = android_log_printBinaryEvent(&eventData, &eventDataLen,
&outBuf, &outBufLen);
if (result != 0)
goto bail;
if (i < count-1) {
if (outBufLen > 0) {
*outBuf++ = ',';
outBufLen--;
} else {
goto no_room;
}
}
}
if (outBufLen > 0) {
*outBuf++ = ']';
outBufLen--;
} else {
goto no_room;
}
}
break;
default:
fprintf(stderr, "Unknown binary event type %d\n", type);
return -1;
}
bail:
*pEventData = eventData;
*pEventDataLen = eventDataLen;
*pOutBuf = outBuf;
*pOutBufLen = outBufLen;
return result;
no_room:
result = 1;
goto bail;
}
/**
* Convert a binary log entry to ASCII form.
*
* For convenience we mimic the processLogBuffer API. There is no
* pre-defined output length for the binary data, since we're free to format
* it however we choose, which means we can't really use a fixed-size buffer
* here.
*/
int android_log_processBinaryLogBuffer(struct logger_entry *buf,
AndroidLogEntry *entry, const EventTagMap* map, char* messageBuf,
int messageBufLen)
{
size_t inCount;
unsigned int tagIndex;
const unsigned char* eventData;
entry->tv_sec = buf->sec;
entry->tv_nsec = buf->nsec;
entry->priority = ANDROID_LOG_INFO;
entry->uid = -1;
entry->pid = buf->pid;
entry->tid = buf->tid;
/*
* Pull the tag out, fill in some additional details based on incoming
* buffer version (v3 adds lid, v4 adds uid).
*/
eventData = (const unsigned char*) buf->msg;
struct logger_entry_v2 *buf2 = (struct logger_entry_v2 *)buf;
if (buf2->hdr_size) {
eventData = ((unsigned char *)buf2) + buf2->hdr_size;
if ((buf2->hdr_size >= sizeof(struct logger_entry_v3)) &&
(((struct logger_entry_v3 *)buf)->lid == LOG_ID_SECURITY)) {
entry->priority = ANDROID_LOG_WARN;
}
if (buf2->hdr_size >= sizeof(struct logger_entry_v4)) {
entry->uid = ((struct logger_entry_v4 *)buf)->uid;
}
}
inCount = buf->len;
if (inCount < 4)
return -1;
tagIndex = get4LE(eventData);
eventData += 4;
inCount -= 4;
if (map != NULL) {
entry->tag = android_lookupEventTag(map, tagIndex);
} else {
entry->tag = NULL;
}
/*
* If we don't have a map, or didn't find the tag number in the map,
* stuff a generated tag value into the start of the output buffer and
* shift the buffer pointers down.
*/
if (entry->tag == NULL) {
int tagLen;
tagLen = snprintf(messageBuf, messageBufLen, "[%d]", tagIndex);
entry->tag = messageBuf;
messageBuf += tagLen+1;
messageBufLen -= tagLen+1;
}
/*
* Format the event log data into the buffer.
*/
char* outBuf = messageBuf;
size_t outRemaining = messageBufLen-1; /* leave one for nul byte */
int result;
result = android_log_printBinaryEvent(&eventData, &inCount, &outBuf,
&outRemaining);
if (result < 0) {
fprintf(stderr, "Binary log entry conversion failed\n");
return -1;
} else if (result == 1) {
if (outBuf > messageBuf) {
/* leave an indicator */
*(outBuf-1) = '!';
} else {
/* no room to output anything at all */
*outBuf++ = '!';
outRemaining--;
}
/* pretend we ate all the data */
inCount = 0;
}
/* eat the silly terminating '\n' */
if (inCount == 1 && *eventData == '\n') {
eventData++;
inCount--;
}
if (inCount != 0) {
fprintf(stderr,
"Warning: leftover binary log data (%zu bytes)\n", inCount);
}
/*
* Terminate the buffer. The NUL byte does not count as part of
* entry->messageLen.
*/
*outBuf = '\0';
entry->messageLen = outBuf - messageBuf;
assert(entry->messageLen == (messageBufLen-1) - outRemaining);
entry->message = messageBuf;
return 0;
}
/*
* One utf8 character at a time
*
* Returns the length of the utf8 character in the buffer,
* or -1 if illegal or truncated
*
* Open coded from libutils/Unicode.cpp, borrowed from utf8_length(),
* can not remove from here because of library circular dependencies.
* Expect one-day utf8_character_length with the same signature could
* _also_ be part of libutils/Unicode.cpp if its usefullness needs to
* propagate globally.
*/
WEAK ssize_t utf8_character_length(const char *src, size_t len)
{
const char *cur = src;
const char first_char = *cur++;
static const uint32_t kUnicodeMaxCodepoint = 0x0010FFFF;
int32_t mask, to_ignore_mask;
size_t num_to_read;
uint32_t utf32;
if ((first_char & 0x80) == 0) { /* ASCII */
return first_char ? 1 : -1;
}
/*
* (UTF-8's character must not be like 10xxxxxx,
* but 110xxxxx, 1110xxxx, ... or 1111110x)
*/
if ((first_char & 0x40) == 0) {
return -1;
}
for (utf32 = 1, num_to_read = 1, mask = 0x40, to_ignore_mask = 0x80;
num_to_read < 5 && (first_char & mask);
num_to_read++, to_ignore_mask |= mask, mask >>= 1) {
if (num_to_read > len) {
return -1;
}
if ((*cur & 0xC0) != 0x80) { /* can not be 10xxxxxx? */
return -1;
}
utf32 = (utf32 << 6) + (*cur++ & 0b00111111);
}
/* "first_char" must be (110xxxxx - 11110xxx) */
if (num_to_read >= 5) {
return -1;
}
to_ignore_mask |= mask;
utf32 |= ((~to_ignore_mask) & first_char) << (6 * (num_to_read - 1));
if (utf32 > kUnicodeMaxCodepoint) {
return -1;
}
return num_to_read;
}
/*
* Convert to printable from message to p buffer, return string length. If p is
* NULL, do not copy, but still return the expected string length.
*/
static size_t convertPrintable(char *p, const char *message, size_t messageLen)
{
char *begin = p;
bool print = p != NULL;
while (messageLen) {
char buf[6];
ssize_t len = sizeof(buf) - 1;
if ((size_t)len > messageLen) {
len = messageLen;
}
len = utf8_character_length(message, len);
if (len < 0) {
snprintf(buf, sizeof(buf),
((messageLen > 1) && isdigit(message[1]))
? "\\%03o"
: "\\%o",
*message & 0377);
len = 1;
} else {
buf[0] = '\0';
if (len == 1) {
if (*message == '\a') {
strcpy(buf, "\\a");
} else if (*message == '\b') {
strcpy(buf, "\\b");
} else if (*message == '\t') {
strcpy(buf, "\t"); // Do not escape tabs
} else if (*message == '\v') {
strcpy(buf, "\\v");
} else if (*message == '\f') {
strcpy(buf, "\\f");
} else if (*message == '\r') {
strcpy(buf, "\\r");
} else if (*message == '\\') {
strcpy(buf, "\\\\");
} else if ((*message < ' ') || (*message & 0x80)) {
snprintf(buf, sizeof(buf), "\\%o", *message & 0377);
}
}
if (!buf[0]) {
strncpy(buf, message, len);
buf[len] = '\0';
}
}
if (print) {
strcpy(p, buf);
}
p += strlen(buf);
message += len;
messageLen -= len;
}
return p - begin;
}
char *readSeconds(char *e, struct timespec *t)
{
unsigned long multiplier;
char *p;
t->tv_sec = strtoul(e, &p, 10);
if (*p != '.') {
return NULL;
}
t->tv_nsec = 0;
multiplier = NS_PER_SEC;
while (isdigit(*++p) && (multiplier /= 10)) {
t->tv_nsec += (*p - '0') * multiplier;
}
return p;
}
static struct timespec *sumTimespec(struct timespec *left,
struct timespec *right)
{
left->tv_nsec += right->tv_nsec;
left->tv_sec += right->tv_sec;
if (left->tv_nsec >= (long)NS_PER_SEC) {
left->tv_nsec -= NS_PER_SEC;
left->tv_sec += 1;
}
return left;
}
static struct timespec *subTimespec(struct timespec *result,
struct timespec *left,
struct timespec *right)
{
result->tv_nsec = left->tv_nsec - right->tv_nsec;
result->tv_sec = left->tv_sec - right->tv_sec;
if (result->tv_nsec < 0) {
result->tv_nsec += NS_PER_SEC;
result->tv_sec -= 1;
}
return result;
}
static long long nsecTimespec(struct timespec *now)
{
return (long long)now->tv_sec * NS_PER_SEC + now->tv_nsec;
}
static void convertMonotonic(struct timespec *result,
const AndroidLogEntry *entry)
{
struct listnode *node;
struct conversionList {
struct listnode node; /* first */
struct timespec time;
struct timespec convert;
} *list, *next;
struct timespec time, convert;
/* If we do not have a conversion list, build one up */
if (list_empty(&convertHead)) {
bool suspended_pending = false;
struct timespec suspended_monotonic = { 0, 0 };
struct timespec suspended_diff = { 0, 0 };
/*
* Read dmesg for _some_ synchronization markers and insert
* Anything in the Android Logger before the dmesg logging span will
* be highly suspect regarding the monotonic time calculations.
*/
FILE *p = popen("/system/bin/dmesg", "r");
if (p) {
char *line = NULL;
size_t len = 0;
while (getline(&line, &len, p) > 0) {
static const char suspend[] = "PM: suspend entry ";
static const char resume[] = "PM: suspend exit ";
static const char healthd[] = "healthd";
static const char battery[] = ": battery ";
static const char suspended[] = "Suspended for ";
struct timespec monotonic;
struct tm tm;
char *cp, *e = line;
bool add_entry = true;
if (*e == '<') {
while (*e && (*e != '>')) {
++e;
}
if (*e != '>') {
continue;
}
}
if (*e != '[') {
continue;
}
while (*++e == ' ') {
;
}
e = readSeconds(e, &monotonic);
if (!e || (*e != ']')) {
continue;
}
if ((e = strstr(e, suspend))) {
e += sizeof(suspend) - 1;
} else if ((e = strstr(line, resume))) {
e += sizeof(resume) - 1;
} else if (((e = strstr(line, healthd)))
&& ((e = strstr(e + sizeof(healthd) - 1, battery)))) {
/* NB: healthd is roughly 150us late, worth the price to
* deal with ntp-induced or hardware clock drift. */
e += sizeof(battery) - 1;
} else if ((e = strstr(line, suspended))) {
e += sizeof(suspended) - 1;
e = readSeconds(e, &time);
if (!e) {
continue;
}
add_entry = false;
suspended_pending = true;
suspended_monotonic = monotonic;
suspended_diff = time;
} else {
continue;
}
if (add_entry) {
/* look for "????-??-?? ??:??:??.????????? UTC" */
cp = strstr(e, " UTC");
if (!cp || ((cp - e) < 29) || (cp[-10] != '.')) {
continue;
}
e = cp - 29;
cp = readSeconds(cp - 10, &time);
if (!cp) {
continue;
}
cp = strptime(e, "%Y-%m-%d %H:%M:%S.", &tm);
if (!cp) {
continue;
}
cp = getenv(tz);
if (cp) {
cp = strdup(cp);
}
setenv(tz, utc, 1);
time.tv_sec = mktime(&tm);
if (cp) {
setenv(tz, cp, 1);
free(cp);
} else {
unsetenv(tz);
}
list = calloc(1, sizeof(struct conversionList));
list_init(&list->node);
list->time = time;
subTimespec(&list->convert, &time, &monotonic);
list_add_tail(&convertHead, &list->node);
}
if (suspended_pending && !list_empty(&convertHead)) {
list = node_to_item(list_tail(&convertHead),
struct conversionList, node);
if (subTimespec(&time,
subTimespec(&time,
&list->time,
&list->convert),
&suspended_monotonic)->tv_sec > 0) {
/* resume, what is convert factor before? */
subTimespec(&convert, &list->convert, &suspended_diff);
} else {
/* suspend */
convert = list->convert;
}
time = suspended_monotonic;
sumTimespec(&time, &convert);
/* breakpoint just before sleep */
list = calloc(1, sizeof(struct conversionList));
list_init(&list->node);
list->time = time;
list->convert = convert;
list_add_tail(&convertHead, &list->node);
/* breakpoint just after sleep */
list = calloc(1, sizeof(struct conversionList));
list_init(&list->node);
list->time = time;
sumTimespec(&list->time, &suspended_diff);
list->convert = convert;
sumTimespec(&list->convert, &suspended_diff);
list_add_tail(&convertHead, &list->node);
suspended_pending = false;
}
}
pclose(p);
}
/* last entry is our current time conversion */
list = calloc(1, sizeof(struct conversionList));
list_init(&list->node);
clock_gettime(CLOCK_REALTIME, &list->time);
clock_gettime(CLOCK_MONOTONIC, &convert);
clock_gettime(CLOCK_MONOTONIC, &time);
/* Correct for instant clock_gettime latency (syscall or ~30ns) */
subTimespec(&time, &convert, subTimespec(&time, &time, &convert));
/* Calculate conversion factor */
subTimespec(&list->convert, &list->time, &time);
list_add_tail(&convertHead, &list->node);
if (suspended_pending) {
/* manufacture a suspend @ point before */
subTimespec(&convert, &list->convert, &suspended_diff);
time = suspended_monotonic;
sumTimespec(&time, &convert);
/* breakpoint just after sleep */
list = calloc(1, sizeof(struct conversionList));
list_init(&list->node);
list->time = time;
sumTimespec(&list->time, &suspended_diff);
list->convert = convert;
sumTimespec(&list->convert, &suspended_diff);
list_add_head(&convertHead, &list->node);
/* breakpoint just before sleep */
list = calloc(1, sizeof(struct conversionList));
list_init(&list->node);
list->time = time;
list->convert = convert;
list_add_head(&convertHead, &list->node);
}
}
/* Find the breakpoint in the conversion list */
list = node_to_item(list_head(&convertHead), struct conversionList, node);
next = NULL;
list_for_each(node, &convertHead) {
next = node_to_item(node, struct conversionList, node);
if (entry->tv_sec < next->time.tv_sec) {
break;
} else if (entry->tv_sec == next->time.tv_sec) {
if (entry->tv_nsec < next->time.tv_nsec) {
break;
}
}
list = next;
}
/* blend time from one breakpoint to the next */
convert = list->convert;
if (next) {
unsigned long long total, run;
total = nsecTimespec(subTimespec(&time, &next->time, &list->time));
time.tv_sec = entry->tv_sec;
time.tv_nsec = entry->tv_nsec;
run = nsecTimespec(subTimespec(&time, &time, &list->time));
if (run < total) {
long long crun;
float f = nsecTimespec(subTimespec(&time, &next->convert, &convert));
f *= run;
f /= total;
crun = f;
convert.tv_sec += crun / (long long)NS_PER_SEC;
if (crun < 0) {
convert.tv_nsec -= (-crun) % NS_PER_SEC;
if (convert.tv_nsec < 0) {
convert.tv_nsec += NS_PER_SEC;
convert.tv_sec -= 1;
}
} else {
convert.tv_nsec += crun % NS_PER_SEC;
if (convert.tv_nsec >= (long)NS_PER_SEC) {
convert.tv_nsec -= NS_PER_SEC;
convert.tv_sec += 1;
}
}
}
}
/* Apply the correction factor */
result->tv_sec = entry->tv_sec;
result->tv_nsec = entry->tv_nsec;
subTimespec(result, result, &convert);
}
/**
* Formats a log message into a buffer
*
* Uses defaultBuffer if it can, otherwise malloc()'s a new buffer
* If return value != defaultBuffer, caller must call free()
* Returns NULL on malloc error
*/
char *android_log_formatLogLine (
AndroidLogFormat *p_format,
char *defaultBuffer,
size_t defaultBufferSize,
const AndroidLogEntry *entry,
size_t *p_outLength)
{
#if !defined(_WIN32)
struct tm tmBuf;
#endif
struct tm* ptm;
char timeBuf[64]; /* good margin, 23+nul for msec, 26+nul for usec */
char prefixBuf[128], suffixBuf[128];
char priChar;
int prefixSuffixIsHeaderFooter = 0;
char *ret;
time_t now;
unsigned long nsec;
priChar = filterPriToChar(entry->priority);
size_t prefixLen = 0, suffixLen = 0;
size_t len;
/*
* 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.
*
* The caller may have affected the timezone environment, this is
* expected to be sensitive to that.
*/
now = entry->tv_sec;
nsec = entry->tv_nsec;
if (p_format->monotonic_output) {
// prevent convertMonotonic from being called if logd is monotonic
if (android_log_clockid() != CLOCK_MONOTONIC) {
struct timespec time;
convertMonotonic(&time, entry);
now = time.tv_sec;
nsec = time.tv_nsec;
}
}
if (now < 0) {
nsec = NS_PER_SEC - nsec;
}
if (p_format->epoch_output || p_format->monotonic_output) {
ptm = NULL;
snprintf(timeBuf, sizeof(timeBuf),
p_format->monotonic_output ? "%6lld" : "%19lld",
(long long)now);
} else {
#if !defined(_WIN32)
ptm = localtime_r(&now, &tmBuf);
#else
ptm = localtime(&now);
#endif
strftime(timeBuf, sizeof(timeBuf),
&"%Y-%m-%d %H:%M:%S"[p_format->year_output ? 0 : 3],
ptm);
}
len = strlen(timeBuf);
if (p_format->usec_time_output) {
len += snprintf(timeBuf + len, sizeof(timeBuf) - len,
".%06ld", nsec / US_PER_NSEC);
} else {
len += snprintf(timeBuf + len, sizeof(timeBuf) - len,
".%03ld", nsec / MS_PER_NSEC);
}
if (p_format->zone_output && ptm) {
strftime(timeBuf + len, sizeof(timeBuf) - len, " %z", ptm);
}
/*
* Construct a buffer containing the log header and log message.
*/
if (p_format->colored_output) {
prefixLen = snprintf(prefixBuf, sizeof(prefixBuf), "\x1B[38;5;%dm",
colorFromPri(entry->priority));
prefixLen = MIN(prefixLen, sizeof(prefixBuf));
suffixLen = snprintf(suffixBuf, sizeof(suffixBuf), "\x1B[0m");
suffixLen = MIN(suffixLen, sizeof(suffixBuf));
}
char uid[16];
uid[0] = '\0';
if (p_format->uid_output) {
if (entry->uid >= 0) {
const struct android_id_info *info = android_ids;
size_t i;
for (i = 0; i < android_id_count; ++i) {
if (info->aid == (unsigned int)entry->uid) {
break;
}
++info;
}
if ((i < android_id_count) && (strlen(info->name) <= 5)) {
snprintf(uid, sizeof(uid), "%5s:", info->name);
} else {
// Not worth parsing package list, names all longer than 5
snprintf(uid, sizeof(uid), "%5d:", entry->uid);
}
} else {
snprintf(uid, sizeof(uid), " ");
}
}
switch (p_format->format) {
case FORMAT_TAG:
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%c/%-8s: ", priChar, entry->tag);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_PROCESS:
len = snprintf(suffixBuf + suffixLen, sizeof(suffixBuf) - suffixLen,
" (%s)\n", entry->tag);
suffixLen += MIN(len, sizeof(suffixBuf) - suffixLen);
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%c(%s%5d) ", priChar, uid, entry->pid);
break;
case FORMAT_THREAD:
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%c(%s%5d:%5d) ", priChar, uid, entry->pid, entry->tid);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_RAW:
prefixBuf[prefixLen] = 0;
len = 0;
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_TIME:
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%s %c/%-8s(%s%5d): ", timeBuf, priChar, entry->tag,
uid, entry->pid);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_THREADTIME:
ret = strchr(uid, ':');
if (ret) {
*ret = ' ';
}
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%s %s%5d %5d %c %-8s: ", timeBuf,
uid, entry->pid, entry->tid, priChar, entry->tag);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_LONG:
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"[ %s %s%5d:%5d %c/%-8s ]\n",
timeBuf, uid, entry->pid, entry->tid, priChar, entry->tag);
strcpy(suffixBuf + suffixLen, "\n\n");
suffixLen += 2;
prefixSuffixIsHeaderFooter = 1;
break;
case FORMAT_BRIEF:
default:
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%c/%-8s(%s%5d): ", priChar, entry->tag, uid, entry->pid);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
}
/* snprintf has a weird return value. It returns what would have been
* written given a large enough buffer. In the case that the prefix is
* longer then our buffer(128), it messes up the calculations below
* possibly causing heap corruption. To avoid this we double check and
* set the length at the maximum (size minus null byte)
*/
prefixLen += MIN(len, sizeof(prefixBuf) - prefixLen);
suffixLen = MIN(suffixLen, sizeof(suffixBuf));
/* the following code is tragically unreadable */
size_t numLines;
char *p;
size_t bufferSize;
const char *pm;
if (prefixSuffixIsHeaderFooter) {
/* we're just wrapping message with a header/footer */
numLines = 1;
} else {
pm = entry->message;
numLines = 0;
/*
* The line-end finding here must match the line-end finding
* in for ( ... numLines...) loop below
*/
while (pm < (entry->message + entry->messageLen)) {
if (*pm++ == '\n') numLines++;
}
/* plus one line for anything not newline-terminated at the end */
if (pm > entry->message && *(pm-1) != '\n') numLines++;
}
/*
* this is an upper bound--newlines in message may be counted
* extraneously
*/
bufferSize = (numLines * (prefixLen + suffixLen)) + 1;
if (p_format->printable_output) {
/* Calculate extra length to convert non-printable to printable */
bufferSize += convertPrintable(NULL, entry->message, entry->messageLen);
} else {
bufferSize += entry->messageLen;
}
if (defaultBufferSize >= bufferSize) {
ret = defaultBuffer;
} else {
ret = (char *)malloc(bufferSize);
if (ret == NULL) {
return ret;
}
}
ret[0] = '\0'; /* to start strcat off */
p = ret;
pm = entry->message;
if (prefixSuffixIsHeaderFooter) {
strcat(p, prefixBuf);
p += prefixLen;
if (p_format->printable_output) {
p += convertPrintable(p, entry->message, entry->messageLen);
} else {
strncat(p, entry->message, entry->messageLen);
p += entry->messageLen;
}
strcat(p, suffixBuf);
p += suffixLen;
} else {
while(pm < (entry->message + entry->messageLen)) {
const char *lineStart;
size_t lineLen;
lineStart = pm;
/* Find the next end-of-line in message */
while (pm < (entry->message + entry->messageLen)
&& *pm != '\n') pm++;
lineLen = pm - lineStart;
strcat(p, prefixBuf);
p += prefixLen;
if (p_format->printable_output) {
p += convertPrintable(p, lineStart, lineLen);
} else {
strncat(p, lineStart, lineLen);
p += lineLen;
}
strcat(p, suffixBuf);
p += suffixLen;
if (*pm == '\n') pm++;
}
}
if (p_outLength != NULL) {
*p_outLength = p - ret;
}
return ret;
}
/**
* Either print or do not print log line, based on filter
*
* Returns count bytes written
*/
int android_log_printLogLine(
AndroidLogFormat *p_format,
int fd,
const AndroidLogEntry *entry)
{
int ret;
char defaultBuffer[512];
char *outBuffer = NULL;
size_t totalLen;
outBuffer = android_log_formatLogLine(p_format, defaultBuffer,
sizeof(defaultBuffer), entry, &totalLen);
if (!outBuffer)
return -1;
do {
ret = write(fd, outBuffer, totalLen);
} while (ret < 0 && errno == EINTR);
if (ret < 0) {
fprintf(stderr, "+++ LOG: write failed (errno=%d)\n", errno);
ret = 0;
goto done;
}
if (((size_t)ret) < totalLen) {
fprintf(stderr, "+++ LOG: write partial (%d of %d)\n", ret,
(int)totalLen);
goto done;
}
done:
if (outBuffer != defaultBuffer) {
free(outBuffer);
}
return ret;
}