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Add implementation for signal handling. Use in DDG4 #1336

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47 changes: 47 additions & 0 deletions DDCore/include/DD4hep/SignalHandler.h
Original file line number Diff line number Diff line change
@@ -0,0 +1,47 @@
//==========================================================================
// AIDA Detector description implementation
//--------------------------------------------------------------------------
// Copyright (C) Organisation europeenne pour la Recherche nucleaire (CERN)
// All rights reserved.
//
// For the licensing terms see $DD4hepINSTALL/LICENSE.
// For the list of contributors see $DD4hepINSTALL/doc/CREDITS.
//
// Author : M.Frank
//
//==========================================================================
#ifndef DD4HEP_DDCORE_SIGNALHANDLER_H
#define DD4HEP_DDCORE_SIGNALHANDLER_H

/// System include files
#include <csignal>
#include <memory>

/// Namespace for the AIDA detector description toolkit
namespace dd4hep {

/// Interruptsback interface class with argument
/**
* \author M.Frank
* \version 1.0
* \ingroup DD4HEP_CORE
*/
class SignalHandler {
public:
/// User signal handler definition
typedef bool (*signal_handler_t)(void* user_context, int signal);
/// Internal implementation class
class implementation;

public:
/// Default constructor
SignalHandler();
/// Default destructor
virtual ~SignalHandler();
/// (Re-)apply registered interrupt handlers to override potentially later registrations by other libraries
void applyHandlers();
/// Specialized handler for any signal
bool registerHandler(int sig_num, void* param, signal_handler_t handler);
};
} // End namespace dd4hep
#endif // DD4HEP_DDCORE_SIGNALHANDLER_H
308 changes: 308 additions & 0 deletions DDCore/src/SignalHandler.cpp
Original file line number Diff line number Diff line change
@@ -0,0 +1,308 @@
//==========================================================================
// AIDA Detector description implementation
//--------------------------------------------------------------------------
// Copyright (C) Organisation europeenne pour la Recherche nucleaire (CERN)
// All rights reserved.
//
// For the licensing terms see $DD4hepINSTALL/LICENSE.
// For the list of contributors see $DD4hepINSTALL/doc/CREDITS.
//
// Author : M.Frank
//
//==========================================================================

// Framework include files
#include <DD4hep/Printout.h>
#include <DD4hep/SignalHandler.h>

#include <map>
#include <string>
#include <vector>
#include <iostream>
#include <unistd.h>
#include <execinfo.h>

using namespace dd4hep;

using signal_handler_t = SignalHandler::signal_handler_t;

namespace {
static bool s_exit_handler_print = true;
static bool s_exit_handler_active = false;
static bool s_exit_handler_backtrace = false;
static bool s_exit_handler_sleep_on_fatal = false;

template<class T> union func_cast {
void* ptr;
T fun;
explicit func_cast(T t) { fun = t; }
explicit func_cast(void* t) { ptr = t; }
};
}

/**@class SignalHandler::implementation
*
* Small class to manipulate default signal handling
*
* \author M.Frank
*/
class SignalHandler::implementation {
protected:
struct sig_entry_t {
void* user_context { nullptr };
signal_handler_t user_handler { nullptr };
};
struct sig_handler_t {
std::string name { };
struct sigaction old_action { };
struct sigaction handler_action { };
std::vector<sig_entry_t> user_handlers { };
};

public:
typedef std::map<int, sig_handler_t> SigMap;
SigMap m_map;

public:
/// Default constructor
implementation();
/// Default destructor
~implementation();
/// Singleton accessor
static implementation& instance();
/// Initialize the exit handler. Subscribe to default signals
void init();
/// Install handler for a single signal
void install(int num, const std::string& name, struct sigaction& action);
/// Subscribe to a given signal with a user context and a user handler. The context MUST be unique!
int subscribe(int signum, void* user_context, signal_handler_t handler);
/// Unsubscribe from a given signal with a user context identifier
int unsubscribe(int signum, void* user_context);
/// Create simple backtrace
void back_trace(int /* signum */);
/// Static handler callback for system signal handler
static void handler(int signum, siginfo_t *info,void * );
};

/// Default constructor
SignalHandler::implementation::implementation() {
}

/// Default destructor
SignalHandler::implementation::~implementation() {
}

/// Singleton accessor
SignalHandler::implementation& SignalHandler::implementation::instance() {
static std::unique_ptr<implementation> imp;
if ( !imp ) {
imp = std::make_unique<implementation>();
}
return *imp;
}

/// Initialize the exit handler. Subscribe to default signals
void SignalHandler::implementation::init() {
struct sigaction new_action;
sigemptyset(&new_action.sa_mask);
new_action.sa_handler = 0;
new_action.sa_sigaction = handler;
new_action.sa_flags = SA_SIGINFO;

install(SIGILL, "SIGILL", new_action);
install(SIGINT, "SIGINT", new_action);
install(SIGTERM, "SIGTERM", new_action);
install(SIGHUP, "SIGHUP", new_action);

install(SIGQUIT, "SIGQUIT", new_action);
install(SIGBUS, "SIGBUS", new_action);
install(SIGXCPU, "SIGXCPU", new_action);
sigaddset(&new_action.sa_mask,SIGSEGV);
sigaddset(&new_action.sa_mask,SIGABRT);
sigaddset(&new_action.sa_mask,SIGFPE);
install(SIGABRT, "SIGABRT", new_action);
install(SIGFPE, "SIGFPE", new_action);
install(SIGSEGV, "SIGSEGV", new_action);
}

/// Subscribe to a given signal with a user context and a user handler. The context MUST be unique!
int SignalHandler::implementation::subscribe(int signum, void* user_context, signal_handler_t user_handler) {
if ( m_map.empty() ) {
this->init();
}
auto ihandler = m_map.find(signum);
if ( ihandler == m_map.end() ) {
char text[32];
struct sigaction new_action;
sigemptyset(&new_action.sa_mask);
new_action.sa_handler = 0;
new_action.sa_sigaction = SignalHandler::implementation::handler;
new_action.sa_flags = SA_SIGINFO;
::snprintf(text, sizeof(text),"%08X",signum);
install(signum, text, new_action);
ihandler = m_map.find(signum);
}
if ( ihandler != m_map.end() ) { // Should always be true
sig_entry_t entry {user_context, user_handler};
ihandler->second.user_handlers.emplace_back(entry);
return 1;
}
return 0;
}

/// Unsubscribe from a given signal with a user context identifier
int SignalHandler::implementation::unsubscribe(int signum, void* user_context) {
auto ihandler = m_map.find(signum);
if ( ihandler != m_map.end() ) {
auto & handlers = ihandler->second.user_handlers;
for( auto it = handlers.begin(); it != handlers.end(); ++it ) {
if ( it->user_context == user_context ) {
handlers.erase(it);
return 1;
}
}
}
return 0;
}

/// Create simple backtrace
void SignalHandler::implementation::back_trace(int /* signum */) {
if ( s_exit_handler_backtrace ) {
void *bt[256];
char text[512];
int bt_size = ::backtrace(bt, sizeof(bt) / sizeof(void *));
size_t len = ::snprintf(text, sizeof(text), "\n[INFO] (ExitSignalHandler) %s\n",
"---------------------- Backtrace ----------------------\n");
text[sizeof(text)-2] = '\n';
text[sizeof(text)-1] = 0;
::write(STDERR_FILENO, text, len);
len = ::snprintf(text, sizeof(text), "[INFO] Number of elements in backtrace: %d\n", bt_size);
text[sizeof(text)-2] = '\n';
text[sizeof(text)-1] = 0;
::write(STDERR_FILENO, text, len);
::backtrace_symbols_fd(bt, bt_size, STDERR_FILENO);
for (int i = 0; i < bt_size; i++) {
len = ::snprintf(text,sizeof(text),"[INFO] (SignalHandler) %02d --> %p\n", i, bt[i]);
text[sizeof(text)-2] = '\n';
text[sizeof(text)-1] = 0;
::write(STDERR_FILENO, text, len);
}
}
}

/// Install handler for a single signal
void SignalHandler::implementation::install(int num, const std::string& name, struct sigaction& action) {
auto& action_entry = m_map[num];
int res = ::sigaction (num, &action, &action_entry.old_action);
if ( res != 0 ) {
char text[512];
auto len = ::snprintf(text,sizeof(text),"Failed to install exit handler for %s", name.c_str());
text[sizeof(text)-2] = '\n';
text[sizeof(text)-1] = 0;
::write(STDERR_FILENO, text, len);
return;
}
action_entry.handler_action = action;
action_entry.name = name;
}

/// Static handler callback for system signal handler
void SignalHandler::implementation::handler(int signum, siginfo_t *info, void *ptr) {
SigMap& m = instance().m_map;
SigMap::iterator iter_handler = m.find(signum);
s_exit_handler_active = true;
if ( iter_handler != m.end() ) {
__sighandler_t hdlr = iter_handler->second.old_action.sa_handler;
func_cast<void (*)(int)> dsc0(hdlr);
func_cast<void (*)(int,siginfo_t*, void*)> dsc(dsc0.ptr);

if ( s_exit_handler_print ) {{
char text[512];
size_t len = ::snprintf(text,sizeof(text),
"[FATAL] (SignalHandler) Handle signal: %d [%s] Old action:%p Mem:%p Code:%08X\n",
signum,iter_handler->second.name.c_str(),dsc.ptr,info->si_addr,info->si_code);
text[sizeof(text)-2] = '\n';
text[sizeof(text)-1] = 0;
::write(STDERR_FILENO,text,len);
// Debugging hack, if enabled (default: NO)
if ( s_exit_handler_sleep_on_fatal ) {
bool _s_sleep = true;
len = ::snprintf(text,sizeof(text),
"[FATAL] (SignalHandler) Sleeping for debugging.... %s\n",
_s_sleep ? "YES" : "NO");
text[sizeof(text)-2] = '\n';
text[sizeof(text)-1] = 0;
::write(STDERR_FILENO,text,len);
while ( _s_sleep ) ::usleep(100000);
}
}
if ( !iter_handler->second.user_handlers.empty() ) {
auto& handlers = iter_handler->second.user_handlers;
for( auto ih = handlers.rbegin(); ih != handlers.rend(); ++ih ) {
if ( ih->user_handler ) {
bool ret = (*(ih->user_handler))(ih->user_context, signum);
if ( ret ) {
return;
}
// Otherwise continue signal processing and eventually call default handlers
}
// No handler fired: call previously registered signal handler
auto& entry = iter_handler->second.old_action;
if ( entry.sa_handler )
(*entry.sa_handler)(signum);
else if ( entry.sa_sigaction )
(*entry.sa_sigaction)(signum, info, ptr);
}
}
if ( signum == SIGSEGV || signum == SIGBUS || signum == SIGILL || signum == SIGABRT ) {
instance().back_trace(signum);
}
else if ( info->si_signo == SIGSEGV || info->si_signo == SIGBUS || info->si_signo == SIGILL || info->si_signo == SIGABRT ) {
instance().back_trace(info->si_signo);
}
}
if ( signum == SIGINT || signum == SIGHUP || signum == SIGFPE || signum == SIGPIPE ) {
if ( dsc.fun && (dsc0.fun != SIG_IGN) )
dsc.fun(signum, info, ptr);
else if ( signum == SIGHUP )
::_exit(signum);
}
else if ( signum == SIGSEGV && hdlr && hdlr != SIG_IGN && hdlr != SIG_DFL ) {
::_exit(0);
}
else if ( hdlr && hdlr != SIG_IGN && dsc.fun ) {
dsc.fun(signum, info, ptr);
}
else if ( hdlr == SIG_DFL ) {
::_exit(0);
}
}
s_exit_handler_active = false;
}

/// Default constructor
SignalHandler::SignalHandler()
{
}

/// Default destructor
SignalHandler::~SignalHandler() {
}

/// (Re-)apply registered interrupt handlers to override potentially later registrations by other libraries
void SignalHandler::applyHandlers() {
auto& imp = implementation::instance();
struct sigaction old_action { };
printout(INFO, "SignalHandler", "++ Re-apply signal handlers");
for( const auto& e : imp.m_map ) {
::sigaction (e.first, &e.second.handler_action, &old_action);
printout(DEBUG, "SignalHandler",
"++ Re-apply signal handler for %-10s [%3ld entries]",
e.second.name.c_str(), e.second.user_handlers.size());
}
}

/// Install handler for any signal
bool SignalHandler::registerHandler(int sig_num, void* param, signal_handler_t handler) {
return implementation::instance().subscribe(sig_num, param, handler) == 1;
}
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