platform_system_core/liblog/logprint.cpp
Tom Cherry 441054aa1e Remove old logger_entry_v* formats
logger_entry and logger_entry_v2 were used for the kernel logger,
which we have long since deprecated.  logger_entry_v3 is the same as
logger_entry_v4 without a uid field, so it is trivially removable,
especially since we're now always providing uids in log messages.

liblog and logd already get updated in sync with each other, so we
have no reason for backwards compatibility with their format.

Test: build, unit tests
Change-Id: I27c90609f28c8d826e5614fdb3fe59bde22b5042
2019-10-24 10:53:14 -07:00

1757 lines
50 KiB
C++

/*
**
** 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.
*/
#ifndef __MINGW32__
#define HAVE_STRSEP
#endif
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <inttypes.h>
#ifndef __MINGW32__
#include <pwd.h>
#endif
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/param.h>
#include <sys/types.h>
#include <wchar.h>
#include <cutils/list.h>
#include <log/log.h>
#include <log/logprint.h>
#include <private/android_logger.h>
#include "log_portability.h"
#define MS_PER_NSEC 1000000
#define US_PER_NSEC 1000
#ifndef MIN
#define MIN(a, b) (((a) < (b)) ? (a) : (b))
#endif
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 nsec_time_output;
bool printable_output;
bool year_output;
bool zone_output;
bool epoch_output;
bool monotonic_output;
bool uid_output;
bool descriptive_output;
};
/*
* API issues prevent us from exposing "descriptive" in AndroidLogFormat_t
* during android_log_processBinaryLogBuffer(), so we break layering.
*/
static bool descriptive_output = false;
/*
* 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) {
/* clang-format off */
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 '?';
/* clang-format on */
}
}
static int colorFromPri(android_LogPriority pri) {
switch (pri) {
/* clang-format off */
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;
/* clang-format on */
}
}
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 = static_cast<AndroidLogFormat*>(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->nsec_time_output = false;
p_ret->printable_output = false;
p_ret->year_output = false;
p_ret->zone_output = false;
p_ret->epoch_output = false;
#ifdef __ANDROID__
p_ret->monotonic_output = android_log_clockid() == CLOCK_MONOTONIC;
#else
p_ret->monotonic_output = false;
#endif
p_ret->uid_output = false;
p_ret->descriptive_output = false;
descriptive_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);
LOG_ALWAYS_FATAL_IF(node == list_head(&convertHead), "corrupted list");
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_TIME_NSEC:
p_format->nsec_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;
case FORMAT_MODIFIER_DESCRIPT:
p_format->descriptive_output = true;
descriptive_output = true;
return 0;
default:
break;
}
p_format->format = format;
return 1;
}
#ifndef __MINGW32__
static const char tz[] = "TZ";
static const char utc[] = "UTC";
#endif
/**
* Returns FORMAT_OFF on invalid string
*/
AndroidLogPrintFormat android_log_formatFromString(const char* formatString) {
static AndroidLogPrintFormat format;
/* clang-format off */
if (!strcmp(formatString, "brief")) format = FORMAT_BRIEF;
else if (!strcmp(formatString, "process")) format = FORMAT_PROCESS;
else if (!strcmp(formatString, "tag")) format = FORMAT_TAG;
else if (!strcmp(formatString, "thread")) format = FORMAT_THREAD;
else if (!strcmp(formatString, "raw")) format = FORMAT_RAW;
else if (!strcmp(formatString, "time")) format = FORMAT_TIME;
else if (!strcmp(formatString, "threadtime")) format = FORMAT_THREADTIME;
else if (!strcmp(formatString, "long")) format = FORMAT_LONG;
else if (!strcmp(formatString, "color")) format = FORMAT_MODIFIER_COLOR;
else if (!strcmp(formatString, "colour")) format = FORMAT_MODIFIER_COLOR;
else if (!strcmp(formatString, "usec")) format = FORMAT_MODIFIER_TIME_USEC;
else if (!strcmp(formatString, "nsec")) format = FORMAT_MODIFIER_TIME_NSEC;
else if (!strcmp(formatString, "printable")) format = FORMAT_MODIFIER_PRINTABLE;
else if (!strcmp(formatString, "year")) format = FORMAT_MODIFIER_YEAR;
else if (!strcmp(formatString, "zone")) format = FORMAT_MODIFIER_ZONE;
else if (!strcmp(formatString, "epoch")) format = FORMAT_MODIFIER_EPOCH;
else if (!strcmp(formatString, "monotonic")) format = FORMAT_MODIFIER_MONOTONIC;
else if (!strcmp(formatString, "uid")) format = FORMAT_MODIFIER_UID;
else if (!strcmp(formatString, "descriptive")) format = FORMAT_MODIFIER_DESCRIPT;
/* clang-format on */
#ifndef __MINGW32__
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);
}
#endif
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 strndup, 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;
}
#ifndef HAVE_STRSEP
/* KISS replacement helper for below */
static char* strsep(char** stringp, const char* delim) {
char* token;
char* ret = *stringp;
if (!ret || !*ret) {
return NULL;
}
token = strpbrk(ret, delim);
if (token) {
*token = '\0';
++token;
} else {
token = ret + strlen(ret);
}
*stringp = token;
return ret;
}
#endif
/**
* 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->message = NULL;
entry->messageLen = 0;
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;
if (buf->hdr_size != sizeof(struct logger_entry)) {
fprintf(stderr, "+++ LOG: entry illegal hdr_size\n");
return -1;
}
entry->uid = 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) {
/* +++ LOG: malformed log message, DYB */
for (i = 1; i < buf->len; i++) {
/* odd characters in tag? */
if ((msg[i] <= ' ') || (msg[i] == ':') || (msg[i] >= 0x7f)) {
msg[i] = '\0';
msgStart = i + 1;
break;
}
}
if (msgStart == -1) {
msgStart = buf->len - 1; /* All tag, no message, print truncates */
}
}
if (msgEnd == -1) {
/* incoming message not null-terminated; force it */
msgEnd = buf->len - 1; /* may result in msgEnd < msgStart */
msg[msgEnd] = '\0';
}
entry->priority = static_cast<android_LogPriority>(msg[0]);
entry->tag = msg + 1;
entry->tagLen = msgStart - 1;
entry->message = msg + msgStart;
entry->messageLen = (msgEnd < msgStart) ? 0 : (msgEnd - msgStart);
return 0;
}
static bool findChar(const char** cp, size_t* len, int c) {
while ((*len) && isspace(*(*cp))) {
++(*cp);
--(*len);
}
if (c == INT_MAX) return *len;
if ((*len) && (*(*cp) == c)) {
++(*cp);
--(*len);
return true;
}
return false;
}
/*
* 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.
*/
enum objectType {
TYPE_OBJECTS = '1',
TYPE_BYTES = '2',
TYPE_MILLISECONDS = '3',
TYPE_ALLOCATIONS = '4',
TYPE_ID = '5',
TYPE_PERCENT = '6',
TYPE_MONOTONIC = 's'
};
static int android_log_printBinaryEvent(const unsigned char** pEventData, size_t* pEventDataLen,
char** pOutBuf, size_t* pOutBufLen, const char** fmtStr,
size_t* fmtLen) {
const unsigned char* eventData = *pEventData;
size_t eventDataLen = *pEventDataLen;
char* outBuf = *pOutBuf;
char* outBufSave = outBuf;
size_t outBufLen = *pOutBufLen;
size_t outBufLenSave = outBufLen;
unsigned char type;
size_t outCount = 0;
int result = 0;
const char* cp;
size_t len;
int64_t lval;
if (eventDataLen < 1) return -1;
type = *eventData;
cp = NULL;
len = 0;
if (fmtStr && *fmtStr && fmtLen && *fmtLen && **fmtStr) {
cp = *fmtStr;
len = *fmtLen;
}
/*
* event.logtag format specification:
*
* Optionally, after the tag names can be put a description for the value(s)
* of the tag. Description are in the format
* (<name>|data type[|data unit])
* Multiple values are separated by commas.
*
* The data type is a number from the following values:
* 1: int
* 2: long
* 3: string
* 4: list
* 5: float
*
* The data unit is a number taken from the following list:
* 1: Number of objects
* 2: Number of bytes
* 3: Number of milliseconds
* 4: Number of allocations
* 5: Id
* 6: Percent
* s: Number of seconds (monotonic time)
* Default value for data of type int/long is 2 (bytes).
*/
if (!cp || !findChar(&cp, &len, '(')) {
len = 0;
} else {
char* outBufLastSpace = NULL;
findChar(&cp, &len, INT_MAX);
while (len && *cp && (*cp != '|') && (*cp != ')')) {
if (outBufLen <= 0) {
/* halt output */
goto no_room;
}
outBufLastSpace = isspace(*cp) ? outBuf : NULL;
*outBuf = *cp;
++outBuf;
++cp;
--outBufLen;
--len;
}
if (outBufLastSpace) {
outBufLen += outBuf - outBufLastSpace;
outBuf = outBufLastSpace;
}
if (outBufLen <= 0) {
/* halt output */
goto no_room;
}
if (outBufSave != outBuf) {
*outBuf = '=';
++outBuf;
--outBufLen;
}
if (findChar(&cp, &len, '|') && findChar(&cp, &len, INT_MAX)) {
static const unsigned char typeTable[] = {EVENT_TYPE_INT, EVENT_TYPE_LONG, EVENT_TYPE_STRING,
EVENT_TYPE_LIST, EVENT_TYPE_FLOAT};
if ((*cp >= '1') && (*cp < (char)('1' + (sizeof(typeTable) / sizeof(typeTable[0])))) &&
(type != typeTable[(size_t)(*cp - '1')]))
len = 0;
if (len) {
++cp;
--len;
} else {
/* reset the format */
outBuf = outBufSave;
outBufLen = outBufLenSave;
}
}
}
outCount = 0;
lval = 0;
switch (type) {
case EVENT_TYPE_INT:
/* 32-bit signed int */
{
if (eventDataLen < sizeof(android_event_int_t)) return -1;
auto* event_int = reinterpret_cast<const android_event_int_t*>(eventData);
lval = event_int->data;
eventData += sizeof(android_event_int_t);
eventDataLen -= sizeof(android_event_int_t);
}
goto pr_lval;
case EVENT_TYPE_LONG:
/* 64-bit signed long */
if (eventDataLen < sizeof(android_event_long_t)) {
return -1;
}
{
auto* event_long = reinterpret_cast<const android_event_long_t*>(eventData);
lval = event_long->data;
}
eventData += sizeof(android_event_long_t);
eventDataLen -= sizeof(android_event_long_t);
pr_lval:
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 */
{
if (eventDataLen < sizeof(android_event_float_t)) return -1;
auto* event_float = reinterpret_cast<const android_event_float_t*>(eventData);
float fval = event_float->data;
eventData += sizeof(android_event_int_t);
eventDataLen -= sizeof(android_event_int_t);
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 */
{
if (eventDataLen < sizeof(android_event_string_t)) return -1;
auto* event_string = reinterpret_cast<const android_event_string_t*>(eventData);
unsigned int strLen = event_string->length;
eventData += sizeof(android_event_string_t);
eventDataLen -= sizeof(android_event_string_t);
if (eventDataLen < strLen) {
result = -1; /* mark truncated */
strLen = eventDataLen;
}
if (cp && (strLen == 0)) {
/* reset the format if no content */
outBuf = outBufSave;
outBufLen = outBufLenSave;
}
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;
}
if (!result) result = 1; /* if not truncated, return no room */
}
eventData += strLen;
eventDataLen -= strLen;
if (result != 0) goto bail;
break;
}
case EVENT_TYPE_LIST:
/* N items, all different types */
{
if (eventDataLen < sizeof(android_event_list_t)) return -1;
auto* event_list = reinterpret_cast<const android_event_list_t*>(eventData);
int8_t count = event_list->element_count;
eventData += sizeof(android_event_list_t);
eventDataLen -= sizeof(android_event_list_t);
if (outBufLen <= 0) goto no_room;
*outBuf++ = '[';
outBufLen--;
for (int i = 0; i < count; i++) {
result = android_log_printBinaryEvent(&eventData, &eventDataLen, &outBuf, &outBufLen,
fmtStr, fmtLen);
if (result != 0) goto bail;
if (i < (count - 1)) {
if (outBufLen <= 0) goto no_room;
*outBuf++ = ',';
outBufLen--;
}
}
if (outBufLen <= 0) goto no_room;
*outBuf++ = ']';
outBufLen--;
}
break;
default:
fprintf(stderr, "Unknown binary event type %d\n", type);
return -1;
}
if (cp && len) {
if (findChar(&cp, &len, '|') && findChar(&cp, &len, INT_MAX)) {
switch (*cp) {
case TYPE_OBJECTS:
outCount = 0;
/* outCount = snprintf(outBuf, outBufLen, " objects"); */
break;
case TYPE_BYTES:
if ((lval != 0) && ((lval % 1024) == 0)) {
/* repaint with multiplier */
static const char suffixTable[] = {'K', 'M', 'G', 'T'};
size_t idx = 0;
outBuf -= outCount;
outBufLen += outCount;
do {
lval /= 1024;
if ((lval % 1024) != 0) break;
} while (++idx < ((sizeof(suffixTable) / sizeof(suffixTable[0])) - 1));
outCount = snprintf(outBuf, outBufLen, "%" PRId64 "%cB", lval, suffixTable[idx]);
} else {
outCount = snprintf(outBuf, outBufLen, "B");
}
break;
case TYPE_MILLISECONDS:
if (((lval <= -1000) || (1000 <= lval)) && (outBufLen || (outBuf[-1] == '0'))) {
/* repaint as (fractional) seconds, possibly saving space */
if (outBufLen) outBuf[0] = outBuf[-1];
outBuf[-1] = outBuf[-2];
outBuf[-2] = outBuf[-3];
outBuf[-3] = '.';
while ((outBufLen == 0) || (*outBuf == '0')) {
--outBuf;
++outBufLen;
}
if (*outBuf != '.') {
++outBuf;
--outBufLen;
}
outCount = snprintf(outBuf, outBufLen, "s");
} else {
outCount = snprintf(outBuf, outBufLen, "ms");
}
break;
case TYPE_MONOTONIC: {
static const uint64_t minute = 60;
static const uint64_t hour = 60 * minute;
static const uint64_t day = 24 * hour;
/* Repaint as unsigned seconds, minutes, hours ... */
outBuf -= outCount;
outBufLen += outCount;
uint64_t val = lval;
if (val >= day) {
outCount = snprintf(outBuf, outBufLen, "%" PRIu64 "d ", val / day);
if (outCount >= outBufLen) break;
outBuf += outCount;
outBufLen -= outCount;
val = (val % day) + day;
}
if (val >= minute) {
if (val >= hour) {
outCount = snprintf(outBuf, outBufLen, "%" PRIu64 ":", (val / hour) % (day / hour));
if (outCount >= outBufLen) break;
outBuf += outCount;
outBufLen -= outCount;
}
outCount =
snprintf(outBuf, outBufLen, (val >= hour) ? "%02" PRIu64 ":" : "%" PRIu64 ":",
(val / minute) % (hour / minute));
if (outCount >= outBufLen) break;
outBuf += outCount;
outBufLen -= outCount;
}
outCount = snprintf(outBuf, outBufLen, (val >= minute) ? "%02" PRIu64 : "%" PRIu64 "s",
val % minute);
} break;
case TYPE_ALLOCATIONS:
outCount = 0;
/* outCount = snprintf(outBuf, outBufLen, " allocations"); */
break;
case TYPE_ID:
outCount = 0;
break;
case TYPE_PERCENT:
outCount = snprintf(outBuf, outBufLen, "%%");
break;
default: /* ? */
outCount = 0;
break;
}
++cp;
--len;
if (outCount < outBufLen) {
outBuf += outCount;
outBufLen -= outCount;
} else if (outCount) {
/* halt output */
goto no_room;
}
}
if (!findChar(&cp, &len, ')')) len = 0;
if (!findChar(&cp, &len, ',')) len = 0;
}
bail:
*pEventData = eventData;
*pEventDataLen = eventDataLen;
*pOutBuf = outBuf;
*pOutBufLen = outBufLen;
if (cp) {
*fmtStr = cp;
*fmtLen = len;
}
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,
[[maybe_unused]] const EventTagMap* map, /* only on !__ANDROID__ */
char* messageBuf, int messageBufLen) {
size_t inCount;
uint32_t tagIndex;
const unsigned char* eventData;
entry->message = NULL;
entry->messageLen = 0;
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;
eventData = (const unsigned char*)buf->msg;
if (buf->hdr_size != sizeof(struct logger_entry)) {
fprintf(stderr, "+++ LOG: entry illegal hdr_size\n");
return -1;
}
if (buf->lid == LOG_ID_SECURITY) {
entry->priority = ANDROID_LOG_WARN;
}
entry->uid = buf->uid;
inCount = buf->len;
if (inCount < sizeof(android_event_header_t)) return -1;
auto* event_header = reinterpret_cast<const android_event_header_t*>(eventData);
tagIndex = event_header->tag;
eventData += sizeof(android_event_header_t);
inCount -= sizeof(android_event_header_t);
entry->tagLen = 0;
entry->tag = NULL;
#ifdef __ANDROID__
if (map != NULL) {
entry->tag = android_lookupEventTag_len(map, &entry->tagLen, tagIndex);
}
#endif
/*
* 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) {
size_t tagLen;
tagLen = snprintf(messageBuf, messageBufLen, "[%" PRIu32 "]", tagIndex);
if (tagLen >= (size_t)messageBufLen) {
tagLen = messageBufLen - 1;
}
entry->tag = messageBuf;
entry->tagLen = tagLen;
messageBuf += tagLen + 1;
messageBufLen -= tagLen + 1;
}
/*
* Format the event log data into the buffer.
*/
const char* fmtStr = NULL;
size_t fmtLen = 0;
#ifdef __ANDROID__
if (descriptive_output && map) {
fmtStr = android_lookupEventFormat_len(map, &fmtLen, tagIndex);
}
#endif
char* outBuf = messageBuf;
size_t outRemaining = messageBufLen - 1; /* leave one for nul byte */
int result = 0;
if ((inCount > 0) || fmtLen) {
result = android_log_printBinaryEvent(&eventData, &inCount, &outBuf, &outRemaining, &fmtStr,
&fmtLen);
}
if ((result == 1) && fmtStr) {
/* We overflowed :-(, let's repaint the line w/o format dressings */
eventData = (const unsigned char*)buf->msg;
eventData += 4;
outBuf = messageBuf;
outRemaining = messageBufLen - 1;
result = android_log_printBinaryEvent(&eventData, &inCount, &outBuf, &outRemaining, NULL, NULL);
}
if (result < 0) {
fprintf(stderr, "Binary log entry conversion failed\n");
}
if (result) {
if (!outRemaining) {
/* make space to leave an indicator */
--outBuf;
++outRemaining;
}
*outBuf++ = (result < 0) ? '!' : '^'; /* Error or Truncation? */
outRemaining--;
/* pretend we ate all the data to prevent log stutter */
inCount = 0;
if (result > 0) result = 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 result;
}
/*
* 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.
*/
size_t convertPrintable(char* p, const char* message, size_t messageLen) {
char* begin = p;
bool print = p != NULL;
mbstate_t mb_state = {};
while (messageLen) {
char buf[6];
ssize_t len = sizeof(buf) - 1;
if ((size_t)len > messageLen) {
len = messageLen;
}
len = mbrtowc(nullptr, message, len, &mb_state);
if (len < 0) {
snprintf(buf, sizeof(buf), "\\x%02X", static_cast<unsigned char>(*message));
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), "\\x%02X", static_cast<unsigned char>(*message));
}
}
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;
}
#ifdef __ANDROID__
static 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", "re");
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 = static_cast<conversionList*>(calloc(1, sizeof(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 = static_cast<conversionList*>(calloc(1, sizeof(conversionList)));
list_init(&list->node);
list->time = time;
list->convert = convert;
list_add_tail(&convertHead, &list->node);
/* breakpoint just after sleep */
list = static_cast<conversionList*>(calloc(1, sizeof(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 = static_cast<conversionList*>(calloc(1, sizeof(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 = static_cast<conversionList*>(calloc(1, sizeof(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 = static_cast<conversionList*>(calloc(1, sizeof(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);
}
#endif
/**
* 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;
/* good margin, 23+nul for msec, 26+nul for usec, 29+nul to nsec */
char timeBuf[64];
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 __ANDROID__
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;
}
}
#endif
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->nsec_time_output) {
len += snprintf(timeBuf + len, sizeof(timeBuf) - len, ".%09ld", nsec);
} else 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));
const char suffixContents[] = "\x1B[0m";
strcpy(suffixBuf, suffixContents);
suffixLen = strlen(suffixContents);
}
char uid[16];
uid[0] = '\0';
if (p_format->uid_output) {
if (entry->uid >= 0) {
/*
* This code is Android specific, bionic guarantees that
* calls to non-reentrant getpwuid() are thread safe.
*/
#if !defined(__MINGW32__)
#if (FAKE_LOG_DEVICE == 0)
#ifndef __BIONIC__
#warning "This code assumes that getpwuid is thread safe, only true with Bionic!"
#endif
#endif
struct passwd* pwd = getpwuid(entry->uid);
if (pwd && (strlen(pwd->pw_name) <= 5)) {
snprintf(uid, sizeof(uid), "%5s:", pwd->pw_name);
} else
#endif
{
/* 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/%-8.*s: ", priChar,
(int)entry->tagLen, entry->tag);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_PROCESS:
len = snprintf(suffixBuf + suffixLen, sizeof(suffixBuf) - suffixLen, " (%.*s)\n",
(int)entry->tagLen, 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/%-8.*s(%s%5d): ", timeBuf, priChar, (int)entry->tagLen, 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 %-8.*s: ", timeBuf, uid, entry->pid, entry->tid, priChar,
(int)entry->tagLen, entry->tag);
strcpy(suffixBuf + suffixLen, "\n");
++suffixLen;
break;
case FORMAT_LONG:
len = snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"[ %s %s%5d:%5d %c/%-8.*s ]\n", timeBuf, uid, entry->pid, entry->tid, priChar,
(int)entry->tagLen, entry->tag);
strcpy(suffixBuf + suffixLen, "\n\n");
suffixLen += 2;
prefixSuffixIsHeaderFooter = 1;
break;
case FORMAT_BRIEF:
default:
len =
snprintf(prefixBuf + prefixLen, sizeof(prefixBuf) - prefixLen,
"%c/%-8.*s(%s%5d): ", priChar, (int)entry->tagLen, 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 += len;
if (prefixLen >= sizeof(prefixBuf)) {
prefixLen = sizeof(prefixBuf) - 1;
prefixBuf[sizeof(prefixBuf) - 1] = '\0';
}
if (suffixLen >= sizeof(suffixBuf)) {
suffixLen = sizeof(suffixBuf) - 1;
suffixBuf[sizeof(suffixBuf) - 2] = '\n';
suffixBuf[sizeof(suffixBuf) - 1] = '\0';
}
/* 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 {
do {
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++;
} while (pm < (entry->message + entry->messageLen));
}
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;
}