/* File descriptors managment and switching */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include /* FreeBSD FD_ZERO() macro calls bzero() */ #ifdef HAVE_SYS_SIGNAL_H #include #endif #include #ifdef HAVE_SYS_WAIT_H #include #endif #ifdef HAVE_UNISTD_H #include #endif /* This must be here, thanks to BSD. */ #ifdef HAVE_INTTYPES_H #include /* OMG */ #endif #ifdef HAVE_SYS_SELECT_H #include #endif #include "elinks.h" #include "intl/gettext/libintl.h" #include "main/main.h" #include "main/select.h" #include "main/timer.h" #include "osdep/signals.h" #include "terminal/terminal.h" #include "util/error.h" #include "util/memory.h" #include "util/time.h" #ifndef FD_SETSIZE #define FD_SETSIZE 1024 #endif struct thread { select_handler_T read_func; select_handler_T write_func; select_handler_T error_func; void *data; }; static struct thread threads[FD_SETSIZE]; static fd_set w_read; static fd_set w_write; static fd_set w_error; static fd_set x_read; static fd_set x_write; static fd_set x_error; static int w_max; int get_file_handles_count(void) { int i = 0, j; for (j = 0; j < FD_SETSIZE; j++) if (threads[j].read_func || threads[j].write_func || threads[j].error_func) i++; return i; } struct bottom_half { LIST_HEAD(struct bottom_half); select_handler_T fn; void *data; }; static INIT_LIST_HEAD(bottom_halves); int register_bottom_half_do(select_handler_T fn, void *data) { struct bottom_half *bh; foreach (bh, bottom_halves) if (bh->fn == fn && bh->data == data) return 0; bh = mem_alloc(sizeof(*bh)); if (!bh) return -1; bh->fn = fn; bh->data = data; add_to_list(bottom_halves, bh); return 0; } void check_bottom_halves(void) { while (!list_empty(bottom_halves)) { struct bottom_half *bh = bottom_halves.prev; select_handler_T fn = bh->fn; void *data = bh->data; del_from_list(bh); mem_free(bh); fn(data); } } select_handler_T get_handler(int fd, enum select_handler_type tp) { #ifndef CONFIG_OS_WIN32 assertm(fd >= 0 && fd < FD_SETSIZE, "get_handler: handle %d >= FD_SETSIZE %d", fd, FD_SETSIZE); if_assert_failed return NULL; #endif switch (tp) { case SELECT_HANDLER_READ: return threads[fd].read_func; case SELECT_HANDLER_WRITE: return threads[fd].write_func; case SELECT_HANDLER_ERROR: return threads[fd].error_func; case SELECT_HANDLER_DATA: return threads[fd].data; } INTERNAL("get_handler: bad type %d", tp); return NULL; } void set_handlers(int fd, select_handler_T read_func, select_handler_T write_func, select_handler_T error_func, void *data) { #ifndef CONFIG_OS_WIN32 assertm(fd >= 0 && fd < FD_SETSIZE, "set_handlers: handle %d >= FD_SETSIZE %d", fd, FD_SETSIZE); if_assert_failed return; #endif threads[fd].read_func = read_func; threads[fd].write_func = write_func; threads[fd].error_func = error_func; threads[fd].data = data; if (read_func) { FD_SET(fd, &w_read); } else { FD_CLR(fd, &w_read); FD_CLR(fd, &x_read); } if (write_func) { FD_SET(fd, &w_write); } else { FD_CLR(fd, &w_write); FD_CLR(fd, &x_write); } if (error_func) { FD_SET(fd, &w_error); } else { FD_CLR(fd, &w_error); FD_CLR(fd, &x_error); } if (read_func || write_func || error_func) { if (fd >= w_max) w_max = fd + 1; } else if (fd == w_max - 1) { int i; for (i = fd - 1; i >= 0; i--) if (FD_ISSET(i, &w_read) || FD_ISSET(i, &w_write) || FD_ISSET(i, &w_error)) break; w_max = i + 1; } } void select_loop(void (*init)(void)) { timeval_T last_time; int select_errors = 0; clear_signal_mask_and_handlers(); FD_ZERO(&w_read); FD_ZERO(&w_write); FD_ZERO(&w_error); w_max = 0; timeval_now(&last_time); #ifdef SIGPIPE signal(SIGPIPE, SIG_IGN); #endif init(); check_bottom_halves(); while (!program.terminate) { struct timeval *timeout = NULL; int n, i, has_timer; timeval_T t; check_signals(); check_timers(&last_time); redraw_all_terminals(); memcpy(&x_read, &w_read, sizeof(fd_set)); memcpy(&x_write, &w_write, sizeof(fd_set)); memcpy(&x_error, &w_error, sizeof(fd_set)); if (program.terminate) break; has_timer = get_next_timer_time(&t); if (!w_max && !has_timer) break; critical_section = 1; if (check_signals()) { critical_section = 0; continue; } #if 0 { int i; printf("\nR:"); for (i = 0; i < 256; i++) if (FD_ISSET(i, &x_read)) printf("%d,", i); printf("\nW:"); for (i = 0; i < 256; i++) if (FD_ISSET(i, &x_write)) printf("%d,", i); printf("\nE:"); for (i = 0; i < 256; i++) if (FD_ISSET(i, &x_error)) printf("%d,", i); fflush(stdout); } #endif if (has_timer) { /* Be sure timeout is not negative. */ timeval_limit_to_zero_or_one(&t); timeout = (struct timeval *) &t; } n = select(w_max, &x_read, &x_write, &x_error, timeout); if (n < 0) { /* The following calls (especially gettext) * might change errno. */ const int errno_from_select = errno; critical_section = 0; uninstall_alarm(); if (errno_from_select != EINTR) { ERROR(gettext("The call to %s failed: %d (%s)"), "select()", errno_from_select, (unsigned char *) strerror(errno_from_select)); if (++select_errors > 10) /* Infinite loop prevention. */ INTERNAL(gettext("%d select() failures."), select_errors); } continue; } select_errors = 0; critical_section = 0; uninstall_alarm(); check_signals(); /*printf("sel: %d\n", n);*/ check_timers(&last_time); i = -1; while (n > 0 && ++i < w_max) { int k = 0; #if 0 printf("C %d : %d,%d,%d\n", i, FD_ISSET(i, &w_read), FD_ISSET(i, &w_write), FD_ISSET(i, &w_error)); printf("A %d : %d,%d,%d\n", i, FD_ISSET(i, &x_read), FD_ISSET(i, &x_write), FD_ISSET(i, &x_error)); #endif if (FD_ISSET(i, &x_read)) { if (threads[i].read_func) { threads[i].read_func(threads[i].data); check_bottom_halves(); } k = 1; } if (FD_ISSET(i, &x_write)) { if (threads[i].write_func) { threads[i].write_func(threads[i].data); check_bottom_halves(); } k = 1; } if (FD_ISSET(i, &x_error)) { if (threads[i].error_func) { threads[i].error_func(threads[i].data); check_bottom_halves(); } k = 1; } n -= k; } } } static int can_read_or_write(int fd, int write) { struct timeval tv = {0, 0}; fd_set fds; fd_set *rfds = NULL; fd_set *wfds = NULL; FD_ZERO(&fds); FD_SET(fd, &fds); if (write) wfds = &fds; else rfds = &fds; return select(fd + 1, rfds, wfds, NULL, &tv); } int can_read(int fd) { return can_read_or_write(fd, 0); } int can_write(int fd) { return can_read_or_write(fd, 1); }