/* * uterm - Linux User-Space Terminal * * Copyright (c) 2011 Ran Benita * Copyright (c) 2011-2012 David Herrmann * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files * (the "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /* * Input Devices */ #include #include #include #include #include #include #include #include #include "eloop.h" #include "shl_dlist.h" #include "shl_hook.h" #include "shl_log.h" #include "shl_misc.h" #include "uterm_input.h" #include "uterm_input_internal.h" #define LOG_SUBSYSTEM "input" /* How many longs are needed to hold \n bits. */ #define NLONGS(n) (((n) + LONG_BIT - 1) / LONG_BIT) static void input_free_dev(struct uterm_input_dev *dev); static void notify_key(struct uterm_input_dev *dev, uint16_t type, uint16_t code, int32_t value) { if (type != EV_KEY) return; uxkb_dev_process(dev, value, code); } static void input_data_dev(struct ev_fd *fd, int mask, void *data) { struct uterm_input_dev *dev = data; struct input_event ev[16]; ssize_t len, n; int i; if (mask & (EV_HUP | EV_ERR)) { log_debug("EOF on %s", dev->node); input_free_dev(dev); return; } len = sizeof(ev); while (len == sizeof(ev)) { len = read(dev->rfd, &ev, sizeof(ev)); if (len < 0) { if (errno == EWOULDBLOCK) break; log_warn("reading from %s failed (%d): %m", dev->node, errno); input_free_dev(dev); } else if (len == 0) { log_debug("EOF on %s", dev->node); input_free_dev(dev); } else if (len % sizeof(*ev)) { log_warn("invalid input_event on %s", dev->node); } else { n = len / sizeof(*ev); for (i = 0; i < n; i++) notify_key(dev, ev[i].type, ev[i].code, ev[i].value); } } } static int input_wake_up_dev(struct uterm_input_dev *dev) { int ret; if (dev->rfd >= 0) return 0; dev->rfd = open(dev->node, O_CLOEXEC | O_NONBLOCK | O_RDWR); if (dev->rfd < 0) { log_warn("cannot open device %s (%d): %m", dev->node, errno); return -EFAULT; } uxkb_dev_wake_up(dev); ret = ev_eloop_new_fd(dev->input->eloop, &dev->fd, dev->rfd, EV_READABLE, input_data_dev, dev); if (ret) { close(dev->rfd); dev->rfd = -1; return ret; } return 0; } static void input_sleep_dev(struct uterm_input_dev *dev) { if (dev->rfd < 0) return; uxkb_dev_sleep(dev); dev->repeating = false; ev_timer_update(dev->repeat_timer, NULL); ev_eloop_rm_fd(dev->fd); dev->fd = NULL; close(dev->rfd); dev->rfd = -1; } static void input_new_dev(struct uterm_input *input, const char *node, unsigned int capabilities) { struct uterm_input_dev *dev; int ret; dev = malloc(sizeof(*dev)); if (!dev) return; memset(dev, 0, sizeof(*dev)); dev->input = input; dev->rfd = -1; dev->capabilities = capabilities; dev->node = strdup(node); if (!dev->node) goto err_free; dev->num_syms = 1; dev->event.keysyms = malloc(sizeof(uint32_t) * dev->num_syms); if (!dev->event.keysyms) goto err_node; dev->event.codepoints = malloc(sizeof(uint32_t) * dev->num_syms); if (!dev->event.codepoints) goto err_syms; dev->repeat_event.keysyms = malloc(sizeof(uint32_t) * dev->num_syms); if (!dev->repeat_event.keysyms) goto err_codepoints; dev->repeat_event.codepoints = malloc(sizeof(uint32_t) * dev->num_syms); if (!dev->repeat_event.codepoints) goto err_rsyms; ret = uxkb_dev_init(dev); if (ret) goto err_rcodepoints; if (input->awake > 0) { ret = input_wake_up_dev(dev); if (ret) goto err_kbd; } log_debug("new device %s", node); shl_dlist_link(&input->devices, &dev->list); return; err_kbd: uxkb_dev_destroy(dev); err_rcodepoints: free(dev->repeat_event.codepoints); err_rsyms: free(dev->repeat_event.keysyms); err_codepoints: free(dev->event.codepoints); err_syms: free(dev->event.keysyms); err_node: free(dev->node); err_free: free(dev); } static void input_free_dev(struct uterm_input_dev *dev) { log_debug("free device %s", dev->node); input_sleep_dev(dev); shl_dlist_unlink(&dev->list); uxkb_dev_destroy(dev); free(dev->repeat_event.codepoints); free(dev->repeat_event.keysyms); free(dev->event.codepoints); free(dev->event.keysyms); free(dev->node); free(dev); } SHL_EXPORT int uterm_input_new(struct uterm_input **out, struct ev_eloop *eloop, const char *model, const char *layout, const char *variant, const char *options, const char *keymap, unsigned int repeat_delay, unsigned int repeat_rate) { struct uterm_input *input; int ret; if (!out || !eloop) return -EINVAL; if (!repeat_delay) repeat_delay = 250; if (repeat_delay >= 1000) repeat_delay = 999; if (!repeat_rate) repeat_rate = 50; if (repeat_rate >= 1000) repeat_rate = 999; input = malloc(sizeof(*input)); if (!input) return -ENOMEM; memset(input, 0, sizeof(*input)); input->ref = 1; input->eloop = eloop; input->repeat_delay = repeat_delay; input->repeat_rate = repeat_rate; shl_dlist_init(&input->devices); ret = shl_hook_new(&input->hook); if (ret) goto err_free; ret = uxkb_desc_init(input, model, layout, variant, options, keymap); if (ret) goto err_hook; log_debug("new object %p", input); ev_eloop_ref(input->eloop); *out = input; return 0; err_hook: shl_hook_free(input->hook); err_free: free(input); return ret; } SHL_EXPORT void uterm_input_ref(struct uterm_input *input) { if (!input || !input->ref) return; ++input->ref; } SHL_EXPORT void uterm_input_unref(struct uterm_input *input) { struct uterm_input_dev *dev; if (!input || !input->ref || --input->ref) return; log_debug("free object %p", input); while (input->devices.next != &input->devices) { dev = shl_dlist_entry(input->devices.next, struct uterm_input_dev, list); input_free_dev(dev); } uxkb_desc_destroy(input); shl_hook_free(input->hook); ev_eloop_unref(input->eloop); free(input); } /* * See if the device has anything useful to offer. * We go over the possible capabilities and return a mask of enum * uterm_input_device_capability's. */ static unsigned int probe_device_capabilities(const char *node) { int i, fd, ret; unsigned int capabilities = 0; unsigned long evbits[NLONGS(EV_CNT)] = { 0 }; unsigned long keybits[NLONGS(KEY_CNT)] = { 0 }; fd = open(node, O_NONBLOCK | O_CLOEXEC | O_RDONLY); if (fd < 0) return 0; /* Which types of input events the device supports. */ ret = ioctl(fd, EVIOCGBIT(0, sizeof(evbits)), evbits); if (ret == -1) goto err_ioctl; /* Device supports keys/buttons. */ if (input_bit_is_set(evbits, EV_KEY)) { ret = ioctl(fd, EVIOCGBIT(EV_KEY, sizeof(keybits)), keybits); if (ret == -1) goto err_ioctl; /* * If the device support any of the normal keyboard keys, we * take it. Even if the keys are not ordinary they can be * mapped to anything by the keyboard backend. */ for (i = KEY_RESERVED; i <= KEY_MIN_INTERESTING; i++) { if (input_bit_is_set(keybits, i)) { capabilities |= UTERM_DEVICE_HAS_KEYS; break; } } } if (input_bit_is_set(evbits, EV_LED)) capabilities |= UTERM_DEVICE_HAS_LEDS; close(fd); return capabilities; err_ioctl: log_warn("cannot probe capabilities of device %s (%d): %m", node, errno); close(fd); return 0; } SHL_EXPORT void uterm_input_add_dev(struct uterm_input *input, const char *node) { unsigned int capabilities; if (!input || !node) return; capabilities = probe_device_capabilities(node); if (!(capabilities & UTERM_DEVICE_HAS_KEYS)) { log_debug("ignoring non-useful device %s", node); return; } input_new_dev(input, node, capabilities); } SHL_EXPORT void uterm_input_remove_dev(struct uterm_input *input, const char *node) { struct shl_dlist *iter; struct uterm_input_dev *dev; if (!input || !node) return; shl_dlist_for_each(iter, &input->devices) { dev = shl_dlist_entry(iter, struct uterm_input_dev, list); if (!strcmp(dev->node, node)) { input_free_dev(dev); break; } } } SHL_EXPORT int uterm_input_register_cb(struct uterm_input *input, uterm_input_cb cb, void *data) { if (!input || !cb) return -EINVAL; return shl_hook_add_cast(input->hook, cb, data, false); } SHL_EXPORT void uterm_input_unregister_cb(struct uterm_input *input, uterm_input_cb cb, void *data) { if (!input || !cb) return; shl_hook_rm_cast(input->hook, cb, data); } SHL_EXPORT void uterm_input_sleep(struct uterm_input *input) { struct shl_dlist *iter; struct uterm_input_dev *dev; if (!input) return; --input->awake; if (input->awake != 0) return; log_debug("going to sleep"); shl_dlist_for_each(iter, &input->devices) { dev = shl_dlist_entry(iter, struct uterm_input_dev, list); input_sleep_dev(dev); } } SHL_EXPORT void uterm_input_wake_up(struct uterm_input *input) { struct shl_dlist *iter, *tmp; struct uterm_input_dev *dev; int ret; if (!input) return; ++input->awake; if (input->awake != 1) return; log_debug("wakeing up"); shl_dlist_for_each_safe(iter, tmp, &input->devices) { dev = shl_dlist_entry(iter, struct uterm_input_dev, list); ret = input_wake_up_dev(dev); if (ret) input_free_dev(dev); } } SHL_EXPORT bool uterm_input_is_awake(struct uterm_input *input) { if (!input) return false; return input->awake > 0; }