// Disable all warnings from gcc/clang:
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpragmas"
#pragma GCC diagnostic ignored "-Wc++98-compat"
#pragma GCC diagnostic ignored "-Wc++98-compat-pedantic"
#pragma GCC diagnostic ignored "-Wexit-time-destructors"
#pragma GCC diagnostic ignored "-Wformat-nonliteral"
#pragma GCC diagnostic ignored "-Wglobal-constructors"
#pragma GCC diagnostic ignored "-Wgnu-zero-variadic-macro-arguments"
#pragma GCC diagnostic ignored "-Wmissing-prototypes"
#pragma GCC diagnostic ignored "-Wpadded"
#pragma GCC diagnostic ignored "-Wsign-compare"
#pragma GCC diagnostic ignored "-Wsign-conversion"
#pragma GCC diagnostic ignored "-Wunknown-pragmas"
#pragma GCC diagnostic ignored "-Wunused-macros"
#pragma GCC diagnostic ignored "-Wzero-as-null-pointer-constant"
#endif // __GNUC__
#if defined(WINAPI_FAMILY) && (WINAPI_FAMILY == WINAPI_FAMILY_APP)
#include <stdlib.h>
// strdup() not available for UWP apps
char* strdup_uwp_workaround_(const char* str_in) {
unsigned int size_inc = 64;
unsigned int size = 32;
unsigned int cnt = 0;
char* str_out = static_cast<char*>(malloc(size));
do {
if (cnt == size) {
size += size_inc;
str_out = static_cast<char*>(realloc(str_out, size));
size_inc = 2*size_inc;
}
str_out[cnt] = str_in[cnt];
} while (str_in[cnt++] != '\0');
return str_out;
}
#define strdup strdup_uwp_workaround_
#endif
#define LOGURU_REPLACE_GLOG 1
#include <ftl/lib/loguru.hpp>
#ifndef LOGURU_HAS_BEEN_IMPLEMENTED
#define LOGURU_HAS_BEEN_IMPLEMENTED
#define LOGURU_PREAMBLE_WIDTH (53 + LOGURU_THREADNAME_WIDTH + LOGURU_FILENAME_WIDTH)
#undef min
#undef max
#include <algorithm>
#include <atomic>
#include <chrono>
#include <cstdarg>
#include <cstdio>
#include <cstdlib>
#include <cstring>
#include <mutex>
#include <regex>
#include <string>
#include <thread>
#include <vector>
#ifdef _WIN32
#include <direct.h>
#define localtime_r(a, b) localtime_s(b, a) // No localtime_r with MSVC, but arguments are swapped for localtime_s
#else
#include <signal.h>
#include <sys/stat.h> // mkdir
#include <unistd.h> // STDERR_FILENO
#endif
#ifdef __linux__
#include <linux/limits.h> // PATH_MAX
#elif !defined(_WIN32)
#include <limits.h> // PATH_MAX
#endif
#ifndef PATH_MAX
#define PATH_MAX 1024
#endif
#ifdef __APPLE__
#include "TargetConditionals.h"
#endif
// TODO: use defined(_POSIX_VERSION) for some of these things?
#if defined(_WIN32) || defined(__CYGWIN__)
#define LOGURU_PTHREADS 0
#define LOGURU_WINTHREADS 1
#ifndef LOGURU_STACKTRACES
#define LOGURU_STACKTRACES 0
#endif
#elif defined(__rtems__)
#define LOGURU_PTHREADS 1
#define LOGURU_WINTHREADS 0
#ifndef LOGURU_STACKTRACES
#define LOGURU_STACKTRACES 0
#endif
#else
#define LOGURU_PTHREADS 1
#define LOGURU_WINTHREADS 0
#ifndef LOGURU_STACKTRACES
#define LOGURU_STACKTRACES 1
#endif
#endif
#if LOGURU_STACKTRACES
#include <cxxabi.h> // for __cxa_demangle
#include <dlfcn.h> // for dladdr
#include <execinfo.h> // for backtrace
#endif // LOGURU_STACKTRACES
#if LOGURU_PTHREADS
#include <pthread.h>
#if defined(__FreeBSD__)
#include <pthread_np.h>
#include <sys/thr.h>
#elif defined(__OpenBSD__)
#include <pthread_np.h>
#endif
#ifdef __linux__
/* On Linux, the default thread name is the same as the name of the binary.
Additionally, all new threads inherit the name of the thread it got forked from.
For this reason, Loguru use the pthread Thread Local Storage
for storing thread names on Linux. */
#define LOGURU_PTLS_NAMES 1
#endif
#endif
#if LOGURU_WINTHREADS
#ifndef _WIN32_WINNT
#define _WIN32_WINNT 0x0502
#endif
#define WIN32_LEAN_AND_MEAN
#define NOMINMAX
#include <windows.h>
#endif
#ifndef LOGURU_PTLS_NAMES
#define LOGURU_PTLS_NAMES 0
#endif
namespace loguru
{
using namespace std::chrono;
#if LOGURU_WITH_FILEABS
struct FileAbs
{
char path[PATH_MAX];
char mode_str[4];
Verbosity verbosity;
struct stat st;
FILE* fp;
bool is_reopening = false; // to prevent recursive call in file_reopen.
decltype(steady_clock::now()) last_check_time = steady_clock::now();
};
#else
typedef FILE* FileAbs;
#endif
struct Callback
{
std::string id;
log_handler_t callback;
void* user_data;
Verbosity verbosity; // Does not change!
close_handler_t close;
flush_handler_t flush;
unsigned indentation;
};
using CallbackVec = std::vector<Callback>;
using StringPair = std::pair<std::string, std::string>;
using StringPairList = std::vector<StringPair>;
const auto s_start_time = steady_clock::now();
Verbosity g_stderr_verbosity = Verbosity_0;
bool g_colorlogtostderr = true;
unsigned g_flush_interval_ms = 0;
bool g_preamble = true;
// Preamble details
bool g_preamble_date = true;
bool g_preamble_time = true;
bool g_preamble_uptime = true;
bool g_preamble_thread = true;
bool g_preamble_file = true;
bool g_preamble_verbose = true;
bool g_preamble_pipe = true;
static std::recursive_mutex s_mutex;
static Verbosity s_max_out_verbosity = Verbosity_OFF;
static std::string s_argv0_filename;
static std::string s_arguments;
static char s_current_dir[PATH_MAX];
static CallbackVec s_callbacks;
static fatal_handler_t s_fatal_handler = nullptr;
static verbosity_to_name_t s_verbosity_to_name_callback = nullptr;
static name_to_verbosity_t s_name_to_verbosity_callback = nullptr;
static StringPairList s_user_stack_cleanups;
static bool s_strip_file_path = true;
static std::atomic<unsigned> s_stderr_indentation { 0 };
// For periodic flushing:
static std::thread* s_flush_thread = nullptr;
static bool s_needs_flushing = false;
static const bool s_terminal_has_color = [](){
#ifdef _WIN32
#ifndef ENABLE_VIRTUAL_TERMINAL_PROCESSING
#define ENABLE_VIRTUAL_TERMINAL_PROCESSING 0x0004
#endif
HANDLE hOut = GetStdHandle(STD_OUTPUT_HANDLE);
if (hOut != INVALID_HANDLE_VALUE) {
DWORD dwMode = 0;
GetConsoleMode(hOut, &dwMode);
dwMode |= ENABLE_VIRTUAL_TERMINAL_PROCESSING;
return SetConsoleMode(hOut, dwMode) != 0;
}
return false;
#else
if (const char* term = getenv("TERM")) {
return 0 == strcmp(term, "cygwin")
|| 0 == strcmp(term, "linux")
|| 0 == strcmp(term, "rxvt-unicode-256color")
|| 0 == strcmp(term, "screen")
|| 0 == strcmp(term, "screen-256color")
|| 0 == strcmp(term, "tmux-256color")
|| 0 == strcmp(term, "xterm")
|| 0 == strcmp(term, "xterm-256color")
|| 0 == strcmp(term, "xterm-termite")
|| 0 == strcmp(term, "xterm-color");
} else {
return false;
}
#endif
}();
static void print_preamble_header(char* out_buff, size_t out_buff_size);
#if LOGURU_PTLS_NAMES
static pthread_once_t s_pthread_key_once = PTHREAD_ONCE_INIT;
static pthread_key_t s_pthread_key_name;
void make_pthread_key_name()
{
(void)pthread_key_create(&s_pthread_key_name, free);
}
#endif
// ------------------------------------------------------------------------------
// Colors
bool terminal_has_color() { return s_terminal_has_color; }
// Colors
#ifdef _WIN32
#define VTSEQ(ID) ("\x1b[1;" #ID "m")
#else
#define VTSEQ(ID) ("\x1b[" #ID "m")
#endif
const char* terminal_black() { return s_terminal_has_color ? VTSEQ(30) : ""; }
const char* terminal_red() { return s_terminal_has_color ? VTSEQ(31) : ""; }
const char* terminal_green() { return s_terminal_has_color ? VTSEQ(32) : ""; }
const char* terminal_yellow() { return s_terminal_has_color ? VTSEQ(33) : ""; }
const char* terminal_blue() { return s_terminal_has_color ? VTSEQ(34) : ""; }
const char* terminal_purple() { return s_terminal_has_color ? VTSEQ(35) : ""; }
const char* terminal_cyan() { return s_terminal_has_color ? VTSEQ(36) : ""; }
const char* terminal_light_gray() { return s_terminal_has_color ? VTSEQ(37) : ""; }
const char* terminal_white() { return s_terminal_has_color ? VTSEQ(37) : ""; }
const char* terminal_light_red() { return s_terminal_has_color ? VTSEQ(91) : ""; }
const char* terminal_dim() { return s_terminal_has_color ? VTSEQ(2) : ""; }
// Formating
const char* terminal_bold() { return s_terminal_has_color ? VTSEQ(1) : ""; }
const char* terminal_underline() { return s_terminal_has_color ? VTSEQ(4) : ""; }
// You should end each line with this!
const char* terminal_reset() { return s_terminal_has_color ? VTSEQ(0) : ""; }
// ------------------------------------------------------------------------------
#if LOGURU_WITH_FILEABS
void file_reopen(void* user_data);
inline FILE* to_file(void* user_data) { return reinterpret_cast<FileAbs*>(user_data)->fp; }
#else
inline FILE* to_file(void* user_data) { return reinterpret_cast<FILE*>(user_data); }
#endif
void file_log(void* user_data, const Message& message)
{
#if LOGURU_WITH_FILEABS
FileAbs* file_abs = reinterpret_cast<FileAbs*>(user_data);
if (file_abs->is_reopening) {
return;
}
// It is better checking file change every minute/hour/day,
// instead of doing this every time we log.
// Here check_interval is set to zero to enable checking every time;
const auto check_interval = seconds(0);
if (duration_cast<seconds>(steady_clock::now() - file_abs->last_check_time) > check_interval) {
file_abs->last_check_time = steady_clock::now();
file_reopen(user_data);
}
FILE* file = to_file(user_data);
if (!file) {
return;
}
#else
FILE* file = to_file(user_data);
#endif
fprintf(file, "%s%s%s%s\n",
message.preamble, message.indentation, message.prefix, message.message);
if (g_flush_interval_ms == 0) {
fflush(file);
}
}
void file_close(void* user_data)
{
FILE* file = to_file(user_data);
if (file) {
fclose(file);
}
#if LOGURU_WITH_FILEABS
delete reinterpret_cast<FileAbs*>(user_data);
#endif
}
void file_flush(void* user_data)
{
FILE* file = to_file(user_data);
fflush(file);
}
#if LOGURU_WITH_FILEABS
void file_reopen(void* user_data)
{
FileAbs * file_abs = reinterpret_cast<FileAbs*>(user_data);
struct stat st;
int ret;
if (!file_abs->fp || (ret = stat(file_abs->path, &st)) == -1 || (st.st_ino != file_abs->st.st_ino)) {
file_abs->is_reopening = true;
if (file_abs->fp) {
fclose(file_abs->fp);
}
if (!file_abs->fp) {
LOG_F(INFO, "Reopening file '%s' due to previous error", file_abs->path);
}
else if (ret < 0) {
const auto why = errno_as_text();
LOG_F(INFO, "Reopening file '%s' due to '%s'", file_abs->path, why.c_str());
} else {
LOG_F(INFO, "Reopening file '%s' due to file changed", file_abs->path);
}
// try reopen current file.
if (!create_directories(file_abs->path)) {
LOG_F(ERROR, "Failed to create directories to '%s'", file_abs->path);
}
file_abs->fp = fopen(file_abs->path, file_abs->mode_str);
if (!file_abs->fp) {
LOG_F(ERROR, "Failed to open '%s'", file_abs->path);
} else {
stat(file_abs->path, &file_abs->st);
}
file_abs->is_reopening = false;
}
}
#endif
// ------------------------------------------------------------------------------
// Helpers:
Text::~Text() { free(_str); }
LOGURU_PRINTF_LIKE(1, 0)
static Text vtextprintf(const char* format, va_list vlist)
{
#ifdef _WIN32
int bytes_needed = _vscprintf(format, vlist);
CHECK_F(bytes_needed >= 0, "Bad string format: '%s'", format);
char* buff = (char*)malloc(bytes_needed+1);
vsnprintf(buff, bytes_needed+1, format, vlist);
return Text(buff);
#else
char* buff = nullptr;
int result = vasprintf(&buff, format, vlist);
CHECK_F(result >= 0, "Bad string format: '%s'", format);
return Text(buff);
#endif
}
Text textprintf(const char* format, ...)
{
va_list vlist;
va_start(vlist, format);
auto result = vtextprintf(format, vlist);
va_end(vlist);
return result;
}
// Overloaded for variadic template matching.
Text textprintf()
{
return Text(static_cast<char*>(calloc(1, 1)));
}
static const char* indentation(unsigned depth)
{
static const char buff[] =
". . . . . . . . . . " ". . . . . . . . . . "
". . . . . . . . . . " ". . . . . . . . . . "
". . . . . . . . . . " ". . . . . . . . . . "
". . . . . . . . . . " ". . . . . . . . . . "
". . . . . . . . . . " ". . . . . . . . . . ";
static const size_t INDENTATION_WIDTH = 4;
static const size_t NUM_INDENTATIONS = (sizeof(buff) - 1) / INDENTATION_WIDTH;
depth = std::min<unsigned>(depth, NUM_INDENTATIONS);
return buff + INDENTATION_WIDTH * (NUM_INDENTATIONS - depth);
}
static void parse_args(int& argc, char* argv[], const char* verbosity_flag)
{
int arg_dest = 1;
int out_argc = argc;
for (int arg_it = 1; arg_it < argc; ++arg_it) {
auto cmd = argv[arg_it];
auto arg_len = strlen(verbosity_flag);
if (strncmp(cmd, verbosity_flag, arg_len) == 0 && !std::isalpha(cmd[arg_len], std::locale(""))) {
out_argc -= 1;
auto value_str = cmd + arg_len;
if (value_str[0] == '\0') {
// Value in separate argument
arg_it += 1;
CHECK_LT_F(arg_it, argc, "Missing verbosiy level after %s", verbosity_flag);
value_str = argv[arg_it];
out_argc -= 1;
}
if (*value_str == '=') { value_str += 1; }
auto req_verbosity = get_verbosity_from_name(value_str);
if (req_verbosity != Verbosity_INVALID) {
g_stderr_verbosity = req_verbosity;
} else {
char* end = 0;
g_stderr_verbosity = static_cast<int>(strtol(value_str, &end, 10));
CHECK_F(end && *end == '\0',
"Invalid verbosity. Expected integer, INFO, WARNING, ERROR or OFF, got '%s'", value_str);
}
} else {
argv[arg_dest++] = argv[arg_it];
}
}
argc = out_argc;
argv[argc] = nullptr;
}
static long long now_ns()
{
return duration_cast<nanoseconds>(high_resolution_clock::now().time_since_epoch()).count();
}
// Returns the part of the path after the last / or \ (if any).
const char* filename(const char* path)
{
for (auto ptr = path; *ptr; ++ptr) {
if (*ptr == '/' || *ptr == '\\') {
path = ptr + 1;
}
}
return path;
}
// ------------------------------------------------------------------------------
static void on_atexit()
{
LOG_F(INFO, "atexit");
flush();
}
static void install_signal_handlers();
static void write_hex_digit(std::string& out, unsigned num)
{
DCHECK_LT_F(num, 16u);
if (num < 10u) { out.push_back(char('0' + num)); }
else { out.push_back(char('A' + num - 10)); }
}
static void write_hex_byte(std::string& out, uint8_t n)
{
write_hex_digit(out, n >> 4u);
write_hex_digit(out, n & 0x0f);
}
static void escape(std::string& out, const std::string& str)
{
for (char c : str) {
/**/ if (c == '\a') { out += "\\a"; }
else if (c == '\b') { out += "\\b"; }
else if (c == '\f') { out += "\\f"; }
else if (c == '\n') { out += "\\n"; }
else if (c == '\r') { out += "\\r"; }
else if (c == '\t') { out += "\\t"; }
else if (c == '\v') { out += "\\v"; }
else if (c == '\\') { out += "\\\\"; }
else if (c == '\'') { out += "\\\'"; }
else if (c == '\"') { out += "\\\""; }
else if (c == ' ') { out += "\\ "; }
else if (0 <= c && c < 0x20) { // ASCI control character:
// else if (c < 0x20 || c != (c & 127)) { // ASCII control character or UTF-8:
out += "\\x";
write_hex_byte(out, static_cast<uint8_t>(c));
} else { out += c; }
}
}
Text errno_as_text()
{
// cppcheck-suppress unusedVariable
char buff[256];
#if defined(__GLIBC__) && defined(_GNU_SOURCE)
// GNU Version
return Text(strdup(strerror_r(errno, buff, sizeof(buff))));
#elif defined(__APPLE__) || _POSIX_C_SOURCE >= 200112L
// XSI Version
strerror_r(errno, buff, sizeof(buff));
return Text(strdup(buff));
#elif defined(_WIN32)
strerror_s(buff, sizeof(buff), errno);
return Text(strdup(buff));
#else
// Not thread-safe.
return Text(strdup(strerror(errno)));
#endif
}
void init(int& argc, char* argv[], const char* verbosity_flag)
{
CHECK_GT_F(argc, 0, "Expected proper argc/argv");
CHECK_EQ_F(argv[argc], nullptr, "Expected proper argc/argv");
// Nick: Added to allow for multiple calls to init during tests
if (s_argv0_filename.size() > 0) return;
s_argv0_filename = filename(argv[0]);
#ifdef _WIN32
#define getcwd _getcwd
#endif
if (!getcwd(s_current_dir, sizeof(s_current_dir)))
{
const auto error_text = errno_as_text();
LOG_F(WARNING, "Failed to get current working directory: %s", error_text.c_str());
}
s_arguments = "";
for (int i = 0; i < argc; ++i) {
escape(s_arguments, argv[i]);
if (i + 1 < argc) {
s_arguments += " ";
}
}
if (verbosity_flag) {
parse_args(argc, argv, verbosity_flag);
}
#if LOGURU_PTLS_NAMES || LOGURU_WINTHREADS
set_thread_name("main thread");
#elif LOGURU_PTHREADS
char old_thread_name[16] = {0};
auto this_thread = pthread_self();
#if defined(__APPLE__) || defined(__linux__)
pthread_getname_np(this_thread, old_thread_name, sizeof(old_thread_name));
#endif
if (old_thread_name[0] == 0) {
#ifdef __APPLE__
pthread_setname_np("main thread");
#elif defined(__FreeBSD__) || defined(__OpenBSD__)
pthread_set_name_np(this_thread, "main thread");
#elif defined(__linux__)
pthread_setname_np(this_thread, "main thread");
#endif
}
#endif // LOGURU_PTHREADS
if (g_stderr_verbosity >= Verbosity_INFO) {
if (g_preamble) {
char preamble_explain[LOGURU_PREAMBLE_WIDTH];
print_preamble_header(preamble_explain, sizeof(preamble_explain));
if (g_colorlogtostderr && s_terminal_has_color) {
fprintf(stderr, "%s%s%s\n", terminal_reset(), terminal_dim(), preamble_explain);
} else {
fprintf(stderr, "%s\n", preamble_explain);
}
}
fflush(stderr);
}
LOG_F(INFO, "arguments: %s", s_arguments.c_str());
if (strlen(s_current_dir) != 0)
{
LOG_F(INFO, "Current dir: %s", s_current_dir);
}
LOG_F(INFO, "stderr verbosity: %d", g_stderr_verbosity);
LOG_F(INFO, "-----------------------------------");
install_signal_handlers();
atexit(on_atexit);
}
void shutdown()
{
LOG_F(INFO, "loguru::shutdown()");
remove_all_callbacks();
set_fatal_handler(nullptr);
set_verbosity_to_name_callback(nullptr);
set_name_to_verbosity_callback(nullptr);
}
void write_date_time(char* buff, size_t buff_size)
{
auto now = system_clock::now();
long long ms_since_epoch = duration_cast<milliseconds>(now.time_since_epoch()).count();
time_t sec_since_epoch = time_t(ms_since_epoch / 1000);
tm time_info;
localtime_r(&sec_since_epoch, &time_info);
snprintf(buff, buff_size, "%04d%02d%02d_%02d%02d%02d.%03lld",
1900 + time_info.tm_year, 1 + time_info.tm_mon, time_info.tm_mday,
time_info.tm_hour, time_info.tm_min, time_info.tm_sec, ms_since_epoch % 1000);
}
const char* argv0_filename()
{
return s_argv0_filename.c_str();
}
const char* arguments()
{
return s_arguments.c_str();
}
const char* current_dir()
{
return s_current_dir;
}
const char* home_dir()
{
#ifdef _WIN32
auto user_profile = getenv("USERPROFILE");
CHECK_F(user_profile != nullptr, "Missing USERPROFILE");
return user_profile;
#else // _WIN32
auto home = getenv("HOME");
CHECK_F(home != nullptr, "Missing HOME");
return home;
#endif // _WIN32
}
void suggest_log_path(const char* prefix, char* buff, unsigned buff_size)
{
if (prefix[0] == '~') {
snprintf(buff, buff_size - 1, "%s%s", home_dir(), prefix + 1);
} else {
snprintf(buff, buff_size - 1, "%s", prefix);
}
// Check for terminating /
size_t n = strlen(buff);
if (n != 0) {
if (buff[n - 1] != '/') {
CHECK_F(n + 2 < buff_size, "Filename buffer too small");
buff[n] = '/';
buff[n + 1] = '\0';
}
}
strncat(buff, s_argv0_filename.c_str(), buff_size - strlen(buff) - 1);
strncat(buff, "/", buff_size - strlen(buff) - 1);
write_date_time(buff + strlen(buff), buff_size - strlen(buff));
strncat(buff, ".log", buff_size - strlen(buff) - 1);
}
bool create_directories(const char* file_path_const)
{
CHECK_F(file_path_const && *file_path_const);
char* file_path = strdup(file_path_const);
for (char* p = strchr(file_path + 1, '/'); p; p = strchr(p + 1, '/')) {
*p = '\0';
#ifdef _WIN32
if (_mkdir(file_path) == -1) {
#else
if (mkdir(file_path, 0755) == -1) {
#endif
if (errno != EEXIST) {
LOG_F(ERROR, "Failed to create directory '%s'", file_path);
LOG_IF_F(ERROR, errno == EACCES, "EACCES");
LOG_IF_F(ERROR, errno == ENAMETOOLONG, "ENAMETOOLONG");
LOG_IF_F(ERROR, errno == ENOENT, "ENOENT");
LOG_IF_F(ERROR, errno == ENOTDIR, "ENOTDIR");
LOG_IF_F(ERROR, errno == ELOOP, "ELOOP");
*p = '/';
free(file_path);
return false;
}
}
*p = '/';
}
free(file_path);
return true;
}
bool add_file(const char* path_in, FileMode mode, Verbosity verbosity)
{
char path[PATH_MAX];
if (path_in[0] == '~') {
snprintf(path, sizeof(path) - 1, "%s%s", home_dir(), path_in + 1);
} else {
snprintf(path, sizeof(path) - 1, "%s", path_in);
}
if (!create_directories(path)) {
LOG_F(ERROR, "Failed to create directories to '%s'", path);
}
const char* mode_str = (mode == FileMode::Truncate ? "w" : "a");
auto file = fopen(path, mode_str);
if (!file) {
LOG_F(ERROR, "Failed to open '%s'", path);
return false;
}
#if LOGURU_WITH_FILEABS
FileAbs* file_abs = new FileAbs(); // this is deleted in file_close;
snprintf(file_abs->path, sizeof(file_abs->path) - 1, "%s", path);
snprintf(file_abs->mode_str, sizeof(file_abs->mode_str) - 1, "%s", mode_str);
stat(file_abs->path, &file_abs->st);
file_abs->fp = file;
file_abs->verbosity = verbosity;
add_callback(path_in, file_log, file_abs, verbosity, file_close, file_flush);
#else
add_callback(path_in, file_log, file, verbosity, file_close, file_flush);
#endif
if (mode == FileMode::Append) {
fprintf(file, "\n\n\n\n\n");
}
if (!s_arguments.empty()) {
fprintf(file, "arguments: %s\n", s_arguments.c_str());
}
if (strlen(s_current_dir) != 0) {
fprintf(file, "Current dir: %s\n", s_current_dir);
}
fprintf(file, "File verbosity level: %d\n", verbosity);
if (g_preamble) {
char preamble_explain[LOGURU_PREAMBLE_WIDTH];
print_preamble_header(preamble_explain, sizeof(preamble_explain));
fprintf(file, "%s\n", preamble_explain);
}
fflush(file);
LOG_F(INFO, "Logging to '%s', mode: '%s', verbosity: %d", path, mode_str, verbosity);
return true;
}
// Will be called right before abort().
void set_fatal_handler(fatal_handler_t handler)
{
s_fatal_handler = handler;
}
fatal_handler_t get_fatal_handler()
{
return s_fatal_handler;
}
void set_verbosity_to_name_callback(verbosity_to_name_t callback)
{
s_verbosity_to_name_callback = callback;
}
void set_name_to_verbosity_callback(name_to_verbosity_t callback)
{
s_name_to_verbosity_callback = callback;
}
void add_stack_cleanup(const char* find_this, const char* replace_with_this)
{
if (strlen(find_this) <= strlen(replace_with_this)) {
LOG_F(WARNING, "add_stack_cleanup: the replacement should be shorter than the pattern!");
return;
}
s_user_stack_cleanups.push_back(StringPair(find_this, replace_with_this));
}
static void on_callback_change()
{
s_max_out_verbosity = Verbosity_OFF;
for (const auto& callback : s_callbacks) {
s_max_out_verbosity = std::max(s_max_out_verbosity, callback.verbosity);
}
}
void add_callback(
const char* id,
log_handler_t callback,
void* user_data,
Verbosity verbosity,
close_handler_t on_close,
flush_handler_t on_flush)
{
std::lock_guard<std::recursive_mutex> lock(s_mutex);
s_callbacks.push_back(Callback{id, callback, user_data, verbosity, on_close, on_flush, 0});
on_callback_change();
}
// Returns a custom verbosity name if one is available, or nullptr.
// See also set_verbosity_to_name_callback.
const char* get_verbosity_name(Verbosity verbosity)
{
auto name = s_verbosity_to_name_callback
? (*s_verbosity_to_name_callback)(verbosity)
: nullptr;
// Use standard replacements if callback fails:
if (!name)
{
if (verbosity <= Verbosity_FATAL) {
name = "FATL";
} else if (verbosity == Verbosity_ERROR) {
name = "ERR";
} else if (verbosity == Verbosity_WARNING) {
name = "WARN";
} else if (verbosity == Verbosity_INFO) {
name = "INFO";
}
}
return name;
}
// Returns Verbosity_INVALID if the name is not found.
// See also set_name_to_verbosity_callback.
Verbosity get_verbosity_from_name(const char* name)
{
auto verbosity = s_name_to_verbosity_callback
? (*s_name_to_verbosity_callback)(name)
: Verbosity_INVALID;
// Use standard replacements if callback fails:
if (verbosity == Verbosity_INVALID) {
if (strcmp(name, "OFF") == 0) {
verbosity = Verbosity_OFF;
} else if (strcmp(name, "INFO") == 0) {
verbosity = Verbosity_INFO;
} else if (strcmp(name, "WARNING") == 0) {
verbosity = Verbosity_WARNING;
} else if (strcmp(name, "ERROR") == 0) {
verbosity = Verbosity_ERROR;
} else if (strcmp(name, "FATAL") == 0) {
verbosity = Verbosity_FATAL;
}
}
return verbosity;
}
bool remove_callback(const char* id)
{
std::lock_guard<std::recursive_mutex> lock(s_mutex);
auto it = std::find_if(begin(s_callbacks), end(s_callbacks), [&](const Callback& c) { return c.id == id; });
if (it != s_callbacks.end()) {
if (it->close) { it->close(it->user_data); }
s_callbacks.erase(it);
on_callback_change();
return true;
} else {
LOG_F(ERROR, "Failed to locate callback with id '%s'", id);
return false;
}
}
void remove_all_callbacks()
{
std::lock_guard<std::recursive_mutex> lock(s_mutex);
for (auto& callback : s_callbacks) {
if (callback.close) {
callback.close(callback.user_data);
}
}
s_callbacks.clear();
on_callback_change();
}
// Returns the maximum of g_stderr_verbosity and all file/custom outputs.
Verbosity current_verbosity_cutoff()
{
return g_stderr_verbosity > s_max_out_verbosity ?
g_stderr_verbosity : s_max_out_verbosity;
}
#if LOGURU_WINTHREADS
char* get_thread_name_win32()
{
__declspec( thread ) static char thread_name[LOGURU_THREADNAME_WIDTH + 1] = {0};
return &thread_name[0];
}
#endif // LOGURU_WINTHREADS
void set_thread_name(const char* name)
{
#if LOGURU_PTLS_NAMES
(void)pthread_once(&s_pthread_key_once, make_pthread_key_name);
(void)pthread_setspecific(s_pthread_key_name, strdup(name));
#elif LOGURU_PTHREADS
#ifdef __APPLE__
pthread_setname_np(name);
#elif defined(__FreeBSD__) || defined(__OpenBSD__)
pthread_set_name_np(pthread_self(), name);
#elif defined(__linux__)
pthread_setname_np(pthread_self(), name);
#endif
#elif LOGURU_WINTHREADS
strncpy_s(get_thread_name_win32(), LOGURU_THREADNAME_WIDTH + 1, name, _TRUNCATE);
#else // LOGURU_PTHREADS
(void)name;
#endif // LOGURU_PTHREADS
}
#if LOGURU_PTLS_NAMES
const char* get_thread_name_ptls()
{
(void)pthread_once(&s_pthread_key_once, make_pthread_key_name);
return static_cast<const char*>(pthread_getspecific(s_pthread_key_name));
}
#endif // LOGURU_PTLS_NAMES
void get_thread_name(char* buffer, unsigned long long length, bool right_align_hext_id)
{
CHECK_NE_F(length, 0u, "Zero length buffer in get_thread_name");
CHECK_NOTNULL_F(buffer, "nullptr in get_thread_name");
#if LOGURU_PTHREADS
auto thread = pthread_self();
#if LOGURU_PTLS_NAMES
if (const char* name = get_thread_name_ptls()) {
snprintf(buffer, length, "%s", name);
} else {
buffer[0] = 0;
}
#elif defined(__APPLE__) || defined(__linux__)
pthread_getname_np(thread, buffer, length);
#else
buffer[0] = 0;
#endif
if (buffer[0] == 0) {
#ifdef __APPLE__
uint64_t thread_id;
pthread_threadid_np(thread, &thread_id);
#elif defined(__FreeBSD__)
long thread_id;
(void)thr_self(&thread_id);
#elif defined(__OpenBSD__)
unsigned thread_id = -1;
#else
uint64_t thread_id = thread;
#endif
if (right_align_hext_id) {
snprintf(buffer, length, "%*X", static_cast<int>(length - 1), static_cast<unsigned>(thread_id));
} else {
snprintf(buffer, length, "%X", static_cast<unsigned>(thread_id));
}
}
#elif LOGURU_WINTHREADS
if (const char* name = get_thread_name_win32()) {
snprintf(buffer, (size_t)length, "%s", name);
} else {
buffer[0] = 0;
}
#else // !LOGURU_WINTHREADS && !LOGURU_WINTHREADS
buffer[0] = 0;
#endif
}
// ------------------------------------------------------------------------
// Stack traces
#if LOGURU_STACKTRACES
Text demangle(const char* name)
{
int status = -1;
char* demangled = abi::__cxa_demangle(name, 0, 0, &status);
Text result{status == 0 ? demangled : strdup(name)};
return result;
}
#if LOGURU_RTTI
template <class T>
std::string type_name()
{
auto demangled = demangle(typeid(T).name());
return demangled.c_str();
}
#endif // LOGURU_RTTI
static const StringPairList REPLACE_LIST = {
#if LOGURU_RTTI
{ type_name<std::string>(), "std::string" },
{ type_name<std::wstring>(), "std::wstring" },
{ type_name<std::u16string>(), "std::u16string" },
{ type_name<std::u32string>(), "std::u32string" },
#endif // LOGURU_RTTI
{ "std::__1::", "std::" },
{ "__thiscall ", "" },
{ "__cdecl ", "" },
};
void do_replacements(const StringPairList& replacements, std::string& str)
{
for (auto&& p : replacements) {
if (p.first.size() <= p.second.size()) {
// On gcc, "type_name<std::string>()" is "std::string"
continue;
}
size_t it;
while ((it=str.find(p.first)) != std::string::npos) {
str.replace(it, p.first.size(), p.second);
}
}
}
std::string prettify_stacktrace(const std::string& input)
{
std::string output = input;
do_replacements(s_user_stack_cleanups, output);
do_replacements(REPLACE_LIST, output);
try {
std::regex std_allocator_re(R"(,\s*std::allocator<[^<>]+>)");
output = std::regex_replace(output, std_allocator_re, std::string(""));
std::regex template_spaces_re(R"(<\s*([^<> ]+)\s*>)");
output = std::regex_replace(output, template_spaces_re, std::string("<$1>"));
} catch (std::regex_error&) {
// Probably old GCC.
}
return output;
}
std::string stacktrace_as_stdstring(int skip)
{
// From https://gist.github.com/fmela/591333
void* callstack[128];
const auto max_frames = sizeof(callstack) / sizeof(callstack[0]);
int num_frames = backtrace(callstack, max_frames);
char** symbols = backtrace_symbols(callstack, num_frames);
std::string result;
// Print stack traces so the most relevant ones are written last
// Rationale: http://yellerapp.com/posts/2015-01-22-upside-down-stacktraces.html
for (int i = num_frames - 1; i >= skip; --i) {
char buf[1024];
Dl_info info;
if (dladdr(callstack[i], &info) && info.dli_sname) {
char* demangled = NULL;
int status = -1;
if (info.dli_sname[0] == '_') {
demangled = abi::__cxa_demangle(info.dli_sname, 0, 0, &status);
}
snprintf(buf, sizeof(buf), "%-3d %*p %s + %zd\n",
i - skip, int(2 + sizeof(void*) * 2), callstack[i],
status == 0 ? demangled :
info.dli_sname == 0 ? symbols[i] : info.dli_sname,
(ssize_t)(static_cast<char*>(callstack[i]) - static_cast<char*>(info.dli_saddr)));
free(demangled);
} else {
snprintf(buf, sizeof(buf), "%-3d %*p %s\n",
i - skip, int(2 + sizeof(void*) * 2), callstack[i], symbols[i]);
}
result += buf;
}
free(symbols);
if (num_frames == max_frames) {
result = "[truncated]\n" + result;
}
if (!result.empty() && result[result.size() - 1] == '\n') {
result.resize(result.size() - 1);
}
return prettify_stacktrace(result);
}
#else // LOGURU_STACKTRACES
Text demangle(const char* name)
{
return Text(strdup(name));
}
std::string stacktrace_as_stdstring(int)
{
// No stacktraces available on this platform"
return "";
}
#endif // LOGURU_STACKTRACES
Text stacktrace(int skip)
{
auto str = stacktrace_as_stdstring(skip + 1);
return Text(strdup(str.c_str()));
}
// ------------------------------------------------------------------------
static void print_preamble_header(char* out_buff, size_t out_buff_size)
{
if (out_buff_size == 0) { return; }
out_buff[0] = '\0';
long pos = 0;
if (g_preamble_date && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "date ");
}
if (g_preamble_time && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "time ");
}
if (g_preamble_uptime && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "( uptime ) ");
}
if (g_preamble_thread && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "[%-*s]", LOGURU_THREADNAME_WIDTH, " thread name/id");
}
if (g_preamble_file && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "%*s:line ", LOGURU_FILENAME_WIDTH, "file");
}
if (g_preamble_verbose && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, " v");
}
if (g_preamble_pipe && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "| ");
}
}
static void print_preamble(char* out_buff, size_t out_buff_size, Verbosity verbosity, const char* file, unsigned line)
{
if (out_buff_size == 0) { return; }
out_buff[0] = '\0';
if (!g_preamble) { return; }
long long ms_since_epoch = duration_cast<milliseconds>(system_clock::now().time_since_epoch()).count();
time_t sec_since_epoch = time_t(ms_since_epoch / 1000);
tm time_info;
localtime_r(&sec_since_epoch, &time_info);
auto uptime_ms = duration_cast<milliseconds>(steady_clock::now() - s_start_time).count();
auto uptime_sec = uptime_ms / 1000.0;
char thread_name[LOGURU_THREADNAME_WIDTH + 1] = {0};
get_thread_name(thread_name, LOGURU_THREADNAME_WIDTH + 1, true);
if (s_strip_file_path) {
file = filename(file);
}
char level_buff[6];
const char* custom_level_name = get_verbosity_name(verbosity);
if (custom_level_name) {
snprintf(level_buff, sizeof(level_buff) - 1, "%s", custom_level_name);
} else {
snprintf(level_buff, sizeof(level_buff) - 1, "% 4d", verbosity);
}
long pos = 0;
if (g_preamble_date && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "%04d-%02d-%02d ",
1900 + time_info.tm_year, 1 + time_info.tm_mon, time_info.tm_mday);
}
if (g_preamble_time && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "%02d:%02d:%02d.%03lld ",
time_info.tm_hour, time_info.tm_min, time_info.tm_sec, ms_since_epoch % 1000);
}
if (g_preamble_uptime && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "(%8.3fs) ",
uptime_sec);
}
if (g_preamble_thread && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "[%-*s]",
LOGURU_THREADNAME_WIDTH, thread_name);
}
if (g_preamble_file && pos < out_buff_size) {
char shortened_filename[LOGURU_FILENAME_WIDTH + 1];
snprintf(shortened_filename, LOGURU_FILENAME_WIDTH + 1, "%s", file);
pos += snprintf(out_buff + pos, out_buff_size - pos, "%*s:%-5u ",
LOGURU_FILENAME_WIDTH, shortened_filename, line);
}
if (g_preamble_verbose && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "%4s",
level_buff);
}
if (g_preamble_pipe && pos < out_buff_size) {
pos += snprintf(out_buff + pos, out_buff_size - pos, "| ");
}
}
// stack_trace_skip is just if verbosity == FATAL.
static void log_message(int stack_trace_skip, Message& message, bool with_indentation, bool abort_if_fatal)
{
const auto verbosity = message.verbosity;
std::lock_guard<std::recursive_mutex> lock(s_mutex);
if (message.verbosity == Verbosity_FATAL) {
auto st = loguru::stacktrace(stack_trace_skip + 2);
if (!st.empty()) {
RAW_LOG_F(ERROR, "Stack trace:\n%s", st.c_str());
}
auto ec = loguru::get_error_context();
if (!ec.empty()) {
RAW_LOG_F(ERROR, "%s", ec.c_str());
}
}
if (with_indentation) {
message.indentation = indentation(s_stderr_indentation);
}
if (verbosity <= g_stderr_verbosity) {
if (g_colorlogtostderr && s_terminal_has_color) {
if (verbosity > Verbosity_WARNING) {
fprintf(stderr, "%s%s%s%s%s%s%s%s\n",
terminal_reset(),
terminal_dim(),
message.preamble,
message.indentation,
verbosity == Verbosity_INFO ? terminal_reset() : "", // un-dim for info
message.prefix,
message.message,
terminal_reset());
} else {
fprintf(stderr, "%s%s%s%s%s%s%s\n",
terminal_reset(),
verbosity == Verbosity_WARNING ? terminal_yellow() : terminal_red(),
message.preamble,
message.indentation,
message.prefix,
message.message,
terminal_reset());
}
} else {
fprintf(stderr, "%s%s%s%s\n",
message.preamble, message.indentation, message.prefix, message.message);
}
if (g_flush_interval_ms == 0) {
fflush(stderr);
} else {
s_needs_flushing = true;
}
}
for (auto& p : s_callbacks) {
if (verbosity <= p.verbosity) {
if (with_indentation) {
message.indentation = indentation(p.indentation);
}
p.callback(p.user_data, message);
if (g_flush_interval_ms == 0) {
if (p.flush) { p.flush(p.user_data); }
} else {
s_needs_flushing = true;
}
}
}
if (g_flush_interval_ms > 0 && !s_flush_thread) {
s_flush_thread = new std::thread([](){
for (;;) {
if (s_needs_flushing) {
flush();
}
std::this_thread::sleep_for(std::chrono::milliseconds(g_flush_interval_ms));
}
});
}
if (message.verbosity == Verbosity_FATAL) {
flush();
if (s_fatal_handler) {
s_fatal_handler(message);
flush();
}
if (abort_if_fatal) {
#if LOGURU_CATCH_SIGABRT && !defined(_WIN32)
// Make sure we don't catch our own abort:
signal(SIGABRT, SIG_DFL);
#endif
abort();
}
}
}
// stack_trace_skip is just if verbosity == FATAL.
void log_to_everywhere(int stack_trace_skip, Verbosity verbosity,
const char* file, unsigned line,
const char* prefix, const char* buff)
{
char preamble_buff[LOGURU_PREAMBLE_WIDTH];
print_preamble(preamble_buff, sizeof(preamble_buff), verbosity, file, line);
auto message = Message{verbosity, file, line, preamble_buff, "", prefix, buff};
log_message(stack_trace_skip + 1, message, true, true);
}
#if LOGURU_USE_FMTLIB
void log(Verbosity verbosity, const char* file, unsigned line, const char* format, fmt::ArgList args)
{
auto formatted = fmt::format(format, args);
log_to_everywhere(1, verbosity, file, line, "", formatted.c_str());
}
void raw_log(Verbosity verbosity, const char* file, unsigned line, const char* format, fmt::ArgList args)
{
auto formatted = fmt::format(format, args);
auto message = Message{verbosity, file, line, "", "", "", formatted.c_str()};
log_message(1, message, false, true);
}
#else
void log(Verbosity verbosity, const char* file, unsigned line, const char* format, ...)
{
va_list vlist;
va_start(vlist, format);
auto buff = vtextprintf(format, vlist);
log_to_everywhere(1, verbosity, file, line, "", buff.c_str());
va_end(vlist);
}
void raw_log(Verbosity verbosity, const char* file, unsigned line, const char* format, ...)
{
va_list vlist;
va_start(vlist, format);
auto buff = vtextprintf(format, vlist);
auto message = Message{verbosity, file, line, "", "", "", buff.c_str()};
log_message(1, message, false, true);
va_end(vlist);
}
#endif
void flush()
{
std::lock_guard<std::recursive_mutex> lock(s_mutex);
fflush(stderr);
for (const auto& callback : s_callbacks)
{
if (callback.flush) {
callback.flush(callback.user_data);
}
}
s_needs_flushing = false;
}
LogScopeRAII::LogScopeRAII(Verbosity verbosity, const char* file, unsigned line, const char* format, ...)
: _verbosity(verbosity), _file(file), _line(line)
{
if (verbosity <= current_verbosity_cutoff()) {
std::lock_guard<std::recursive_mutex> lock(s_mutex);
_indent_stderr = (verbosity <= g_stderr_verbosity);
_start_time_ns = now_ns();
va_list vlist;
va_start(vlist, format);
vsnprintf(_name, sizeof(_name), format, vlist);
log_to_everywhere(1, _verbosity, file, line, "{ ", _name);
va_end(vlist);
if (_indent_stderr) {
++s_stderr_indentation;
}
for (auto& p : s_callbacks) {
if (verbosity <= p.verbosity) {
++p.indentation;
}
}
} else {
_file = nullptr;
}
}
LogScopeRAII::~LogScopeRAII()
{
if (_file) {
std::lock_guard<std::recursive_mutex> lock(s_mutex);
if (_indent_stderr && s_stderr_indentation > 0) {
--s_stderr_indentation;
}
for (auto& p : s_callbacks) {
// Note: Callback indentation cannot change!
if (_verbosity <= p.verbosity) {
// in unlikely case this callback is new
if (p.indentation > 0) {
--p.indentation;
}
}
}
#if LOGURU_VERBOSE_SCOPE_ENDINGS
auto duration_sec = (now_ns() - _start_time_ns) / 1e9;
auto buff = textprintf("%.*f s: %s", LOGURU_SCOPE_TIME_PRECISION, duration_sec, _name);
log_to_everywhere(1, _verbosity, _file, _line, "} ", buff.c_str());
#else
log_to_everywhere(1, _verbosity, _file, _line, "}", "");
#endif
}
}
void log_and_abort(int stack_trace_skip, const char* expr, const char* file, unsigned line, const char* format, ...)
{
va_list vlist;
va_start(vlist, format);
auto buff = vtextprintf(format, vlist);
log_to_everywhere(stack_trace_skip + 1, Verbosity_FATAL, file, line, expr, buff.c_str());
va_end(vlist);
abort(); // log_to_everywhere already does this, but this makes the analyzer happy.
}
void log_and_abort(int stack_trace_skip, const char* expr, const char* file, unsigned line)
{
log_and_abort(stack_trace_skip + 1, expr, file, line, " ");
}
// ----------------------------------------------------------------------------
// Streams:
std::string vstrprintf(const char* format, va_list vlist)
{
auto text = vtextprintf(format, vlist);
std::string result = text.c_str();
return result;
}
std::string strprintf(const char* format, ...)
{
va_list vlist;
va_start(vlist, format);
auto result = vstrprintf(format, vlist);
va_end(vlist);
return result;
}
#if LOGURU_WITH_STREAMS
StreamLogger::~StreamLogger() noexcept(false)
{
auto message = _ss.str();
log(_verbosity, _file, _line, "%s", message.c_str());
}
AbortLogger::~AbortLogger() noexcept(false)
{
auto message = _ss.str();
loguru::log_and_abort(1, _expr, _file, _line, "%s", message.c_str());
}
#endif // LOGURU_WITH_STREAMS
// ----------------------------------------------------------------------------
// 888888 88""Yb 88""Yb dP"Yb 88""Yb dP""b8 dP"Yb 88b 88 888888 888888 Yb dP 888888
// 88__ 88__dP 88__dP dP Yb 88__dP dP `" dP Yb 88Yb88 88 88__ YbdP 88
// 88"" 88"Yb 88"Yb Yb dP 88"Yb Yb Yb dP 88 Y88 88 88"" dPYb 88
// 888888 88 Yb 88 Yb YbodP 88 Yb YboodP YbodP 88 Y8 88 888888 dP Yb 88
// ----------------------------------------------------------------------------
struct StringStream
{
std::string str;
};
// Use this in your EcPrinter implementations.
void stream_print(StringStream& out_string_stream, const char* text)
{
out_string_stream.str += text;
}
// ----------------------------------------------------------------------------
using ECPtr = EcEntryBase*;
#if defined(_WIN32) || (defined(__APPLE__) && !TARGET_OS_IPHONE)
#ifdef __APPLE__
#define LOGURU_THREAD_LOCAL __thread
#else
#define LOGURU_THREAD_LOCAL thread_local
#endif
static LOGURU_THREAD_LOCAL ECPtr thread_ec_ptr = nullptr;
ECPtr& get_thread_ec_head_ref()
{
return thread_ec_ptr;
}
#else // !thread_local
static pthread_once_t s_ec_pthread_once = PTHREAD_ONCE_INIT;
static pthread_key_t s_ec_pthread_key;
void free_ec_head_ref(void* io_error_context)
{
delete reinterpret_cast<ECPtr*>(io_error_context);
}
void ec_make_pthread_key()
{
(void)pthread_key_create(&s_ec_pthread_key, free_ec_head_ref);
}
ECPtr& get_thread_ec_head_ref()
{
(void)pthread_once(&s_ec_pthread_once, ec_make_pthread_key);
auto ec = reinterpret_cast<ECPtr*>(pthread_getspecific(s_ec_pthread_key));
if (ec == nullptr) {
ec = new ECPtr(nullptr);
(void)pthread_setspecific(s_ec_pthread_key, ec);
}
return *ec;
}
#endif // !thread_local
// ----------------------------------------------------------------------------
EcHandle get_thread_ec_handle()
{
return get_thread_ec_head_ref();
}
Text get_error_context()
{
return get_error_context_for(get_thread_ec_head_ref());
}
Text get_error_context_for(const EcEntryBase* ec_head)
{
std::vector<const EcEntryBase*> stack;
while (ec_head) {
stack.push_back(ec_head);
ec_head = ec_head->_previous;
}
std::reverse(stack.begin(), stack.end());
StringStream result;
if (!stack.empty()) {
result.str += "------------------------------------------------\n";
for (auto entry : stack) {
const auto description = std::string(entry->_descr) + ":";
auto prefix = textprintf("[ErrorContext] %*s:%-5u %-20s ",
LOGURU_FILENAME_WIDTH, filename(entry->_file), entry->_line, description.c_str());
result.str += prefix.c_str();
entry->print_value(result);
result.str += "\n";
}
result.str += "------------------------------------------------";
}
return Text(strdup(result.str.c_str()));
}
EcEntryBase::EcEntryBase(const char* file, unsigned line, const char* descr)
: _file(file), _line(line), _descr(descr)
{
EcEntryBase*& ec_head = get_thread_ec_head_ref();
_previous = ec_head;
ec_head = this;
}
EcEntryBase::~EcEntryBase()
{
get_thread_ec_head_ref() = _previous;
}
// ------------------------------------------------------------------------
Text ec_to_text(const char* value)
{
// Add quotes around the string to make it obvious where it begin and ends.
// This is great for detecting erroneous leading or trailing spaces in e.g. an identifier.
auto str = "\"" + std::string(value) + "\"";
return Text{strdup(str.c_str())};
}
Text ec_to_text(char c)
{
// Add quotes around the character to make it obvious where it begin and ends.
std::string str = "'";
auto write_hex_digit = [&](unsigned num)
{
if (num < 10u) { str += char('0' + num); }
else { str += char('a' + num - 10); }
};
auto write_hex_16 = [&](uint16_t n)
{
write_hex_digit((n >> 12u) & 0x0f);
write_hex_digit((n >> 8u) & 0x0f);
write_hex_digit((n >> 4u) & 0x0f);
write_hex_digit((n >> 0u) & 0x0f);
};
if (c == '\\') { str += "\\\\"; }
else if (c == '\"') { str += "\\\""; }
else if (c == '\'') { str += "\\\'"; }
else if (c == '\0') { str += "\\0"; }
else if (c == '\b') { str += "\\b"; }
else if (c == '\f') { str += "\\f"; }
else if (c == '\n') { str += "\\n"; }
else if (c == '\r') { str += "\\r"; }
else if (c == '\t') { str += "\\t"; }
else if (0 <= c && c < 0x20) {
str += "\\u";
write_hex_16(static_cast<uint16_t>(c));
} else { str += c; }
str += "'";
return Text{strdup(str.c_str())};
}
#define DEFINE_EC(Type) \
Text ec_to_text(Type value) \
{ \
auto str = std::to_string(value); \
return Text{strdup(str.c_str())}; \
}
DEFINE_EC(int)
DEFINE_EC(unsigned int)
DEFINE_EC(long)
DEFINE_EC(unsigned long)
DEFINE_EC(long long)
DEFINE_EC(unsigned long long)
DEFINE_EC(float)
DEFINE_EC(double)
DEFINE_EC(long double)
#undef DEFINE_EC
Text ec_to_text(EcHandle ec_handle)
{
Text parent_ec = get_error_context_for(ec_handle);
char* with_newline = reinterpret_cast<char*>(malloc(strlen(parent_ec.c_str()) + 2));
with_newline[0] = '\n';
strcpy(with_newline + 1, parent_ec.c_str());
return Text(with_newline);
}
// ----------------------------------------------------------------------------
} // namespace loguru
// ----------------------------------------------------------------------------
// .dP"Y8 88 dP""b8 88b 88 db 88 .dP"Y8
// `Ybo." 88 dP `" 88Yb88 dPYb 88 `Ybo."
// o.`Y8b 88 Yb "88 88 Y88 dP__Yb 88 .o o.`Y8b
// 8bodP' 88 YboodP 88 Y8 dP""""Yb 88ood8 8bodP'
// ----------------------------------------------------------------------------
#ifdef _WIN32
namespace loguru {
void install_signal_handlers()
{
#if defined(_MSC_VER)
#pragma message ( "No signal handlers on Win32" )
#else
#warning "No signal handlers on Win32"
#endif
}
} // namespace loguru
#else // _WIN32
namespace loguru
{
struct Signal
{
int number;
const char* name;
};
const Signal ALL_SIGNALS[] = {
#if LOGURU_CATCH_SIGABRT
{ SIGABRT, "SIGABRT" },
#endif
{ SIGBUS, "SIGBUS" },
{ SIGFPE, "SIGFPE" },
{ SIGILL, "SIGILL" },
{ SIGINT, "SIGINT" },
{ SIGSEGV, "SIGSEGV" },
{ SIGTERM, "SIGTERM" },
};
void write_to_stderr(const char* data, size_t size)
{
auto result = write(STDERR_FILENO, data, size);
(void)result; // Ignore errors.
}
void write_to_stderr(const char* data)
{
write_to_stderr(data, strlen(data));
}
void call_default_signal_handler(int signal_number)
{
struct sigaction sig_action;
memset(&sig_action, 0, sizeof(sig_action));
sigemptyset(&sig_action.sa_mask);
sig_action.sa_handler = SIG_DFL;
sigaction(signal_number, &sig_action, NULL);
kill(getpid(), signal_number);
}
void signal_handler(int signal_number, siginfo_t*, void*)
{
const char* signal_name = "UNKNOWN SIGNAL";
for (const auto& s : ALL_SIGNALS) {
if (s.number == signal_number) {
signal_name = s.name;
break;
}
}
// --------------------------------------------------------------------
/* There are few things that are safe to do in a signal handler,
but writing to stderr is one of them.
So we first print out what happened to stderr so we're sure that gets out,
then we do the unsafe things, like logging the stack trace.
*/
if (g_colorlogtostderr && s_terminal_has_color) {
write_to_stderr(terminal_reset());
write_to_stderr(terminal_bold());
write_to_stderr(terminal_light_red());
}
write_to_stderr("\n");
write_to_stderr("Loguru caught a signal: ");
write_to_stderr(signal_name);
write_to_stderr("\n");
if (g_colorlogtostderr && s_terminal_has_color) {
write_to_stderr(terminal_reset());
}
// --------------------------------------------------------------------
#if LOGURU_UNSAFE_SIGNAL_HANDLER
// --------------------------------------------------------------------
/* Now we do unsafe things. This can for example lead to deadlocks if
the signal was triggered from the system's memory management functions
and the code below tries to do allocations.
*/
flush();
char preamble_buff[LOGURU_PREAMBLE_WIDTH];
print_preamble(preamble_buff, sizeof(preamble_buff), Verbosity_FATAL, "", 0);
auto message = Message{Verbosity_FATAL, "", 0, preamble_buff, "", "Signal: ", signal_name};
try {
log_message(1, message, false, false);
} catch (...) {
// This can happed due to s_fatal_handler.
write_to_stderr("Exception caught and ignored by Loguru signal handler.\n");
}
flush();
// --------------------------------------------------------------------
#endif // LOGURU_UNSAFE_SIGNAL_HANDLER
call_default_signal_handler(signal_number);
}
void install_signal_handlers()
{
struct sigaction sig_action;
memset(&sig_action, 0, sizeof(sig_action));
sigemptyset(&sig_action.sa_mask);
sig_action.sa_flags |= SA_SIGINFO;
sig_action.sa_sigaction = &signal_handler;
for (const auto& s : ALL_SIGNALS) {
CHECK_F(sigaction(s.number, &sig_action, NULL) != -1,
"Failed to install handler for %s", s.name);
}
}
} // namespace loguru
#endif // _WIN32
#endif // LOGURU_IMPLEMENTATION