#include #include // Safe execvpe() __attribute__((noreturn)) void safe_execvpe(const char *const argv[], const char *const envp[]) { int ret = execvpe(argv[0], (char *const *) argv, (char *const *) envp); if (ret == -1) { ERR("Unable To Execute Program: %s: %s", argv[0], strerror(errno)); } else { IMPOSSIBLE(); } } // Chop Off Last Component void chop_last_component(char **str) { size_t length = strlen(*str); for (size_t i = 0; i < length; i++) { size_t j = length - i - 1; if ((*str)[j] == '/') { (*str)[j] = '\0'; break; } } } // Get Binary Directory (Remember To Free) char *get_binary_directory() { // Get Path To Current Executable char *exe = realpath("/proc/self/exe", NULL); ALLOC_CHECK(exe); // Chop Off Last Component chop_last_component(&exe); // Return return exe; } // Safe execvpe() Relative To Binary __attribute__((noreturn)) void safe_execvpe_relative_to_binary(const char *const argv[], const char *const envp[]) { // Get Binary Directory char *binary_directory = get_binary_directory(); // Create Full Path char *full_path = NULL; safe_asprintf(&full_path, "%s/%s", binary_directory, argv[0]); // Free Binary Directory free(binary_directory); // Build New argv int argc; for (argc = 0; argv[argc] != NULL; argc++); const char *new_argv[argc + 1]; for (int i = 1; i < argc; i++) { new_argv[i] = argv[i]; } new_argv[0] = full_path; new_argv[argc] = NULL; // Run safe_execvpe(new_argv, envp); } // Run Command And Get Output char *run_command(const char *const command[], int *exit_status) { // Store Output int output_pipe[2]; safe_pipe2(output_pipe, 0); // Run pid_t ret = fork(); if (ret == -1) { ERR("Unable To Run Command: %s", strerror(errno)); } else if (ret == 0) { // Child Process // Pipe stdout dup2(output_pipe[1], STDOUT_FILENO); close(output_pipe[0]); close(output_pipe[1]); // Run safe_execvpe(command, (const char *const *) environ); } else { // Parent Process track_child(ret); // Read stdout close(output_pipe[1]); char *output = NULL; #define BUFFER_SIZE 1024 char buf[BUFFER_SIZE]; ssize_t bytes_read = 0; while ((bytes_read = read(output_pipe[0], (void *) buf, BUFFER_SIZE - 1 /* Account For NULL-Terminator */)) > 0) { buf[bytes_read] = '\0'; string_append(&output, "%s", buf); } close(output_pipe[0]); // Get Return Code int status; waitpid(ret, &status, 0); untrack_child(ret); if (exit_status != NULL) { *exit_status = status; } // Return return output; } } // Get Exit Status String void get_exit_status_string(int status, char **out) { if (out != NULL) { *out =NULL; if (WIFEXITED(status)) { safe_asprintf(out, ": Exit Code: %i", WEXITSTATUS(status)); } else if (WIFSIGNALED(status)) { safe_asprintf(out, ": Signal: %i%s", WTERMSIG(status), WCOREDUMP(status) ? " (Core Dumped)" : ""); } else { safe_asprintf(out, ": Terminated"); } } } // Track Children #define MAX_CHILDREN 128 static pid_t children[MAX_CHILDREN] = { 0 }; static pthread_mutex_t children_lock = PTHREAD_MUTEX_INITIALIZER; void track_child(pid_t pid) { pthread_mutex_lock(&children_lock); for (int i = 0; i < MAX_CHILDREN; i++) { if (children[i] == 0) { children[i] = pid; break; } } pthread_mutex_unlock(&children_lock); } void untrack_child(pid_t pid) { pthread_mutex_lock(&children_lock); for (int i = 0; i < MAX_CHILDREN; i++) { if (children[i] == pid) { children[i] = 0; } } pthread_mutex_unlock(&children_lock); } void murder_children() { pthread_mutex_lock(&children_lock); for (int i = 0; i < MAX_CHILDREN; i++) { if (children[i] != 0) { kill(children[i], SIGTERM); } } pthread_mutex_unlock(&children_lock); }