#include #include #include #include #include #include #include #ifdef __linux__ #include #ifndef PR_SET_PTRACER #define PR_SET_PTRACER 0x59616d61 #endif #elif defined (__APPLE__) || defined (BSD) #include #endif static const char crash_switch[] = "--cc-handle-crash"; static const char fatal_err[] = "\n\n*** Fatal Error ***\n"; static const char pipe_err[] = "!!! Failed to create pipe\n"; static const char fork_err[] = "!!! Failed to fork debug process\n"; static const char exec_err[] = "!!! Failed to exec debug process\n"; static char argv0[PATH_MAX]; static char altstack[SIGSTKSZ]; static struct { int signum; pid_t pid; int has_siginfo; siginfo_t siginfo; char buf[4096]; } crash_info; static const struct { const char *name; int signum; } signals[] = { { "Segmentation fault", SIGSEGV }, { "Illegal instruction", SIGILL }, { "FPU exception", SIGFPE }, { "System BUS error", SIGBUS }, { NULL, 0 } }; static const struct { int code; const char *name; } sigill_codes[] = { #ifndef __FreeBSD__ { ILL_ILLOPC, "Illegal opcode" }, { ILL_ILLOPN, "Illegal operand" }, { ILL_ILLADR, "Illegal addressing mode" }, { ILL_ILLTRP, "Illegal trap" }, { ILL_PRVOPC, "Privileged opcode" }, { ILL_PRVREG, "Privileged register" }, { ILL_COPROC, "Coprocessor error" }, { ILL_BADSTK, "Internal stack error" }, #endif { 0, NULL } }; static const struct { int code; const char *name; } sigfpe_codes[] = { { FPE_INTDIV, "Integer divide by zero" }, { FPE_INTOVF, "Integer overflow" }, { FPE_FLTDIV, "Floating point divide by zero" }, { FPE_FLTOVF, "Floating point overflow" }, { FPE_FLTUND, "Floating point underflow" }, { FPE_FLTRES, "Floating point inexact result" }, { FPE_FLTINV, "Floating point invalid operation" }, { FPE_FLTSUB, "Subscript out of range" }, { 0, NULL } }; static const struct { int code; const char *name; } sigsegv_codes[] = { #ifndef __FreeBSD__ { SEGV_MAPERR, "Address not mapped to object" }, { SEGV_ACCERR, "Invalid permissions for mapped object" }, #endif { 0, NULL } }; static const struct { int code; const char *name; } sigbus_codes[] = { #ifndef __FreeBSD__ { BUS_ADRALN, "Invalid address alignment" }, { BUS_ADRERR, "Non-existent physical address" }, { BUS_OBJERR, "Object specific hardware error" }, #endif { 0, NULL } }; static int (*cc_user_info)(char*, char*); static void gdb_info(pid_t pid) { char respfile[64]; char cmd_buf[128]; FILE *f; int fd; /* Create a temp file to put gdb commands into */ strcpy(respfile, "gdb-respfile-XXXXXX"); if((fd=mkstemp(respfile)) >= 0 && (f=fdopen(fd, "w")) != NULL) { fprintf(f, "attach %d\n" "shell echo \"\"\n" "shell echo \"* Loaded Libraries\"\n" "info sharedlibrary\n" "shell echo \"\"\n" "shell echo \"* Threads\"\n" "info threads\n" "shell echo \"\"\n" "shell echo \"* FPU Status\"\n" "info float\n" "shell echo \"\"\n" "shell echo \"* Registers\"\n" "info registers\n" "shell echo \"\"\n" "shell echo \"* Backtrace\"\n" "thread apply all backtrace full\n" "detach\n" "quit\n", pid); fclose(f); /* Run gdb and print process info. */ snprintf(cmd_buf, sizeof(cmd_buf), "gdb --quiet --batch --command=%s", respfile); printf("Executing: %s\n", cmd_buf); fflush(stdout); system(cmd_buf); /* Clean up */ remove(respfile); } else { /* Error creating temp file */ if(fd >= 0) { close(fd); remove(respfile); } printf("!!! Could not create gdb command file\n"); } fflush(stdout); } static void sys_info(void) { #ifdef __unix__ system("echo \"System: `uname -a`\""); putchar('\n'); fflush(stdout); #endif } static size_t safe_write(int fd, const void *buf, size_t len) { size_t ret = 0; while(ret < len) { ssize_t rem; if((rem=write(fd, (const char*)buf+ret, len-ret)) == -1) { if(errno == EINTR) continue; break; } ret += rem; } return ret; } static void crash_catcher(int signum, siginfo_t *siginfo, void *context) { //ucontext_t *ucontext = (ucontext_t*)context; pid_t dbg_pid; int fd[2]; /* Make sure the effective uid is the real uid */ if(getuid() != geteuid()) { raise(signum); return; } safe_write(STDERR_FILENO, fatal_err, sizeof(fatal_err)-1); if(pipe(fd) == -1) { safe_write(STDERR_FILENO, pipe_err, sizeof(pipe_err)-1); raise(signum); return; } crash_info.signum = signum; crash_info.pid = getpid(); crash_info.has_siginfo = !!siginfo; if(siginfo) crash_info.siginfo = *siginfo; if(cc_user_info) cc_user_info(crash_info.buf, crash_info.buf+sizeof(crash_info.buf)); /* Fork off to start a crash handler */ switch((dbg_pid=fork())) { /* Error */ case -1: safe_write(STDERR_FILENO, fork_err, sizeof(fork_err)-1); raise(signum); return; case 0: dup2(fd[0], STDIN_FILENO); close(fd[0]); close(fd[1]); execl(argv0, argv0, crash_switch, NULL); safe_write(STDERR_FILENO, exec_err, sizeof(exec_err)-1); _exit(1); default: #ifdef __linux__ prctl(PR_SET_PTRACER, dbg_pid, 0, 0, 0); #endif safe_write(fd[1], &crash_info, sizeof(crash_info)); close(fd[0]); close(fd[1]); /* Wait; we'll be killed when gdb is done */ do { int status; if(waitpid(dbg_pid, &status, 0) == dbg_pid && (WIFEXITED(status) || WIFSIGNALED(status))) { /* The debug process died before it could kill us */ raise(signum); break; } } while(1); } } static void crash_handler(const char *logfile) { const char *sigdesc = ""; int i; if(fread(&crash_info, sizeof(crash_info), 1, stdin) != 1) { fprintf(stderr, "!!! Failed to retrieve info from crashed process\n"); exit(1); } /* Get the signal description */ for(i = 0;signals[i].name;++i) { if(signals[i].signum == crash_info.signum) { sigdesc = signals[i].name; break; } } if(crash_info.has_siginfo) { switch(crash_info.signum) { case SIGSEGV: for(i = 0;sigsegv_codes[i].name;++i) { if(sigsegv_codes[i].code == crash_info.siginfo.si_code) { sigdesc = sigsegv_codes[i].name; break; } } break; case SIGFPE: for(i = 0;sigfpe_codes[i].name;++i) { if(sigfpe_codes[i].code == crash_info.siginfo.si_code) { sigdesc = sigfpe_codes[i].name; break; } } break; case SIGILL: for(i = 0;sigill_codes[i].name;++i) { if(sigill_codes[i].code == crash_info.siginfo.si_code) { sigdesc = sigill_codes[i].name; break; } } break; case SIGBUS: for(i = 0;sigbus_codes[i].name;++i) { if(sigbus_codes[i].code == crash_info.siginfo.si_code) { sigdesc = sigbus_codes[i].name; break; } } break; } } fprintf(stderr, "%s (signal %i)\n", sigdesc, crash_info.signum); if(crash_info.has_siginfo) fprintf(stderr, "Address: %p\n", crash_info.siginfo.si_addr); fputc('\n', stderr); if(logfile) { /* Create crash log file and redirect shell output to it */ if(freopen(logfile, "wa", stdout) != stdout) { fprintf(stderr, "!!! Could not create %s following signal\n", logfile); exit(1); } fprintf(stderr, "Generating %s and killing process %d, please wait... ", logfile, crash_info.pid); printf("*** Fatal Error ***\n" "%s (signal %i)\n", sigdesc, crash_info.signum); if(crash_info.has_siginfo) printf("Address: %p\n", crash_info.siginfo.si_addr); fputc('\n', stdout); fflush(stdout); } sys_info(); crash_info.buf[sizeof(crash_info.buf)-1] = '\0'; printf("%s\n", crash_info.buf); fflush(stdout); if(crash_info.pid > 0) { gdb_info(crash_info.pid); kill(crash_info.pid, SIGKILL); } if(logfile) { const char *str; char buf[512]; if((str=getenv("KDE_FULL_SESSION")) && strcmp(str, "true") == 0) snprintf(buf, sizeof(buf), "kdialog --title \"Very Fatal Error\" --textbox \"%s\" 800 600", logfile); else if((str=getenv("GNOME_DESKTOP_SESSION_ID")) && str[0] != '\0') snprintf(buf, sizeof(buf), "gxmessage -buttons \"Okay:0\" -geometry 800x600 -title \"Very Fatal Error\" -center -file \"%s\"", logfile); else snprintf(buf, sizeof(buf), "xmessage -buttons \"Okay:0\" -center -file \"%s\"", logfile); system(buf); } exit(0); } int cc_install_handlers(int argc, char **argv, int num_signals, int *signals, const char *logfile, int (*user_info)(char*, char*)) { struct sigaction sa; stack_t altss; int retval; if(argc == 2 && strcmp(argv[1], crash_switch) == 0) crash_handler(logfile); cc_user_info = user_info; if(argv[0][0] == '/') snprintf(argv0, sizeof(argv0), "%s", argv[0]); else { getcwd(argv0, sizeof(argv0)); retval = strlen(argv0); snprintf(argv0+retval, sizeof(argv0)-retval, "/%s", argv[0]); } /* Set an alternate signal stack so SIGSEGVs caused by stack overflows * still run */ altss.ss_sp = altstack; altss.ss_flags = 0; altss.ss_size = sizeof(altstack); sigaltstack(&altss, NULL); memset(&sa, 0, sizeof(sa)); sa.sa_sigaction = crash_catcher; sa.sa_flags = SA_RESETHAND | SA_NODEFER | SA_SIGINFO | SA_ONSTACK; sigemptyset(&sa.sa_mask); retval = 0; while(num_signals--) { if((*signals != SIGSEGV && *signals != SIGILL && *signals != SIGFPE && *signals != SIGBUS) || sigaction(*signals, &sa, NULL) == -1) { *signals = 0; retval = -1; } ++signals; } return retval; }