/*** This file is part of PulseAudio. Copyright 2004-2009 Lennart Poettering Copyright 2006 Pierre Ossman for Cendio AB PulseAudio is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. PulseAudio is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with PulseAudio; if not, see . ***/ #include "config.h" #include #include #include #include #include "conf-parser.h" #include "alsa-mixer.h" #include "alsa-util.h" static int setting_select(pa_alsa_setting *s, snd_mixer_t *m); struct description_map { const char *key; const char *description; }; struct description2_map { const char *key; const char *description; pa_device_port_type_t type; }; char *pa_alsa_mixer_id_to_string(char *dst, size_t dst_len, pa_alsa_mixer_id *id) { if (id->index > 0) { snprintf(dst, dst_len, "'%s',%d", id->name, id->index); } else { snprintf(dst, dst_len, "'%s'", id->name); } return dst; } static int alsa_id_decode(const char *src, char *name, int *index) { char *idx, c; int i; *index = 0; c = src[0]; /* Strip quotes in entries such as 'Speaker',1 or "Speaker",1 */ if (c == '\'' || c == '"') { strcpy(name, src + 1); for (i = 0; name[i] != '\0' && name[i] != c; i++); idx = NULL; if (name[i]) { name[i] = '\0'; idx = strchr(name + i + 1, ','); } } else { strcpy(name, src); idx = strchr(name, ','); } if (idx == NULL) return 0; *idx = '\0'; idx++; if (*idx < '0' || *idx > '9') { pa_log("Element %s: index value is invalid", src); return 1; } *index = atoi(idx); return 0; } pa_alsa_jack *pa_alsa_jack_new(pa_alsa_path *path, const char *mixer_device_name, const char *name, int index) { pa_alsa_jack *jack; pa_assert(name); jack = pa_xnew0(pa_alsa_jack, 1); jack->path = path; jack->mixer_device_name = pa_xstrdup(mixer_device_name); jack->name = pa_xstrdup(name); jack->alsa_id.name = pa_sprintf_malloc("%s Jack", name); jack->alsa_id.index = index; jack->state_unplugged = PA_AVAILABLE_NO; jack->state_plugged = PA_AVAILABLE_YES; jack->ucm_devices = pa_dynarray_new(NULL); jack->ucm_hw_mute_devices = pa_dynarray_new(NULL); return jack; } void pa_alsa_jack_free(pa_alsa_jack *jack) { pa_assert(jack); pa_dynarray_free(jack->ucm_hw_mute_devices); pa_dynarray_free(jack->ucm_devices); pa_xfree(jack->alsa_id.name); pa_xfree(jack->name); pa_xfree(jack->mixer_device_name); pa_xfree(jack); } void pa_alsa_jack_set_has_control(pa_alsa_jack *jack, bool has_control) { pa_alsa_ucm_device *device; unsigned idx; pa_assert(jack); if (has_control == jack->has_control) return; jack->has_control = has_control; PA_DYNARRAY_FOREACH(device, jack->ucm_hw_mute_devices, idx) pa_alsa_ucm_device_update_available(device); PA_DYNARRAY_FOREACH(device, jack->ucm_devices, idx) pa_alsa_ucm_device_update_available(device); } void pa_alsa_jack_set_plugged_in(pa_alsa_jack *jack, bool plugged_in) { pa_alsa_ucm_device *device; unsigned idx; pa_assert(jack); if (plugged_in == jack->plugged_in) return; jack->plugged_in = plugged_in; /* XXX: If this is a headphone jack that mutes speakers when plugged in, * and the headphones get unplugged, then the headphone device must be set * to unavailable and the speaker device must be set to unknown. So far so * good. But there's an ugly detail: we must first set the availability of * the speakers and then the headphones. We shouldn't need to care about * the order, but we have to, because module-switch-on-port-available gets * separate events for the two devices, and the intermediate state between * the two events is such that the second event doesn't trigger the desired * port switch, if the event order is "wrong". * * These are the transitions when the event order is "right": * * speakers: 1) unavailable -> 2) unknown -> 3) unknown * headphones: 1) available -> 2) available -> 3) unavailable * * In the 2 -> 3 transition, headphones become unavailable, and * module-switch-on-port-available sees that speakers can be used, so the * port gets changed as it should. * * These are the transitions when the event order is "wrong": * * speakers: 1) unavailable -> 2) unavailable -> 3) unknown * headphones: 1) available -> 2) unavailable -> 3) unavailable * * In the 1 -> 2 transition, headphones become unavailable, and there are * no available ports to use, so no port change happens. In the 2 -> 3 * transition, speaker availability becomes unknown, but that's not * a strong enough signal for module-switch-on-port-available, so it still * doesn't do the port switch. * * We should somehow merge the two events so that * module-switch-on-port-available would handle both transitions in one go. * If module-switch-on-port-available used a defer event to delay * the port availability processing, that would probably do the trick. */ PA_DYNARRAY_FOREACH(device, jack->ucm_hw_mute_devices, idx) pa_alsa_ucm_device_update_available(device); PA_DYNARRAY_FOREACH(device, jack->ucm_devices, idx) pa_alsa_ucm_device_update_available(device); } void pa_alsa_jack_add_ucm_device(pa_alsa_jack *jack, pa_alsa_ucm_device *device) { pa_alsa_ucm_device *idevice; unsigned idx, prio, iprio; pa_assert(jack); pa_assert(device); /* store the ucm device with the sequence of priority from low to high. this * could guarantee when the jack state is changed, the device with highest * priority will send to the module-switch-on-port-available last */ prio = device->playback_priority ? device->playback_priority : device->capture_priority; PA_DYNARRAY_FOREACH(idevice, jack->ucm_devices, idx) { iprio = idevice->playback_priority ? idevice->playback_priority : idevice->capture_priority; if (iprio > prio) break; } pa_dynarray_insert_by_index(jack->ucm_devices, device, idx); } void pa_alsa_jack_add_ucm_hw_mute_device(pa_alsa_jack *jack, pa_alsa_ucm_device *device) { pa_assert(jack); pa_assert(device); pa_dynarray_append(jack->ucm_hw_mute_devices, device); } static const char *lookup_description(const char *key, const struct description_map dm[], unsigned n) { unsigned i; if (!key) return NULL; for (i = 0; i < n; i++) if (pa_streq(dm[i].key, key)) return _(dm[i].description); return NULL; } static const struct description2_map *lookup_description2(const char *key, const struct description2_map dm[], unsigned n) { unsigned i; if (!key) return NULL; for (i = 0; i < n; i++) if (pa_streq(dm[i].key, key)) return &dm[i]; return NULL; } void pa_alsa_mixer_use_for_poll(pa_hashmap *mixers, snd_mixer_t *mixer_handle) { pa_alsa_mixer *pm; void *state; PA_HASHMAP_FOREACH(pm, mixers, state) { if (pm->mixer_handle == mixer_handle) { pm->used_for_probe_only = false; pm->used_for_poll = true; } } } #if 0 struct pa_alsa_fdlist { unsigned num_fds; struct pollfd *fds; /* This is a temporary buffer used to avoid lots of mallocs */ struct pollfd *work_fds; snd_mixer_t *mixer; snd_hctl_t *hctl; pa_mainloop_api *m; pa_defer_event *defer; pa_io_event **ios; bool polled; void (*cb)(void *userdata); void *userdata; }; static void io_cb(pa_mainloop_api *a, pa_io_event *e, int fd, pa_io_event_flags_t events, void *userdata) { struct pa_alsa_fdlist *fdl = userdata; int err; unsigned i; unsigned short revents; pa_assert(a); pa_assert(fdl); pa_assert(fdl->mixer || fdl->hctl); pa_assert(fdl->fds); pa_assert(fdl->work_fds); if (fdl->polled) return; fdl->polled = true; memcpy(fdl->work_fds, fdl->fds, sizeof(struct pollfd) * fdl->num_fds); for (i = 0; i < fdl->num_fds; i++) { if (e == fdl->ios[i]) { if (events & PA_IO_EVENT_INPUT) fdl->work_fds[i].revents |= POLLIN; if (events & PA_IO_EVENT_OUTPUT) fdl->work_fds[i].revents |= POLLOUT; if (events & PA_IO_EVENT_ERROR) fdl->work_fds[i].revents |= POLLERR; if (events & PA_IO_EVENT_HANGUP) fdl->work_fds[i].revents |= POLLHUP; break; } } pa_assert(i != fdl->num_fds); if (fdl->hctl) err = snd_hctl_poll_descriptors_revents(fdl->hctl, fdl->work_fds, fdl->num_fds, &revents); else err = snd_mixer_poll_descriptors_revents(fdl->mixer, fdl->work_fds, fdl->num_fds, &revents); if (err < 0) { pa_log_error("Unable to get poll revent: %s", pa_alsa_strerror(err)); return; } a->defer_enable(fdl->defer, 1); if (revents) { if (fdl->hctl) snd_hctl_handle_events(fdl->hctl); else snd_mixer_handle_events(fdl->mixer); } } static void defer_cb(pa_mainloop_api *a, pa_defer_event *e, void *userdata) { struct pa_alsa_fdlist *fdl = userdata; unsigned num_fds, i; int err, n; struct pollfd *temp; pa_assert(a); pa_assert(fdl); pa_assert(fdl->mixer || fdl->hctl); a->defer_enable(fdl->defer, 0); if (fdl->hctl) n = snd_hctl_poll_descriptors_count(fdl->hctl); else n = snd_mixer_poll_descriptors_count(fdl->mixer); if (n < 0) { pa_log("snd_mixer_poll_descriptors_count() failed: %s", pa_alsa_strerror(n)); return; } else if (n == 0) { pa_log_warn("Mixer has no poll descriptors. Please control mixer from PulseAudio only."); return; } num_fds = (unsigned) n; if (num_fds != fdl->num_fds) { if (fdl->fds) pa_xfree(fdl->fds); if (fdl->work_fds) pa_xfree(fdl->work_fds); fdl->fds = pa_xnew0(struct pollfd, num_fds); fdl->work_fds = pa_xnew(struct pollfd, num_fds); } memset(fdl->work_fds, 0, sizeof(struct pollfd) * num_fds); if (fdl->hctl) err = snd_hctl_poll_descriptors(fdl->hctl, fdl->work_fds, num_fds); else err = snd_mixer_poll_descriptors(fdl->mixer, fdl->work_fds, num_fds); if (err < 0) { pa_log_error("Unable to get poll descriptors: %s", pa_alsa_strerror(err)); return; } fdl->polled = false; if (memcmp(fdl->fds, fdl->work_fds, sizeof(struct pollfd) * num_fds) == 0) return; if (fdl->ios) { for (i = 0; i < fdl->num_fds; i++) a->io_free(fdl->ios[i]); if (num_fds != fdl->num_fds) { pa_xfree(fdl->ios); fdl->ios = NULL; } } if (!fdl->ios) fdl->ios = pa_xnew(pa_io_event*, num_fds); /* Swap pointers */ temp = fdl->work_fds; fdl->work_fds = fdl->fds; fdl->fds = temp; fdl->num_fds = num_fds; for (i = 0;i < num_fds;i++) fdl->ios[i] = a->io_new(a, fdl->fds[i].fd, ((fdl->fds[i].events & POLLIN) ? PA_IO_EVENT_INPUT : 0) | ((fdl->fds[i].events & POLLOUT) ? PA_IO_EVENT_OUTPUT : 0), io_cb, fdl); } struct pa_alsa_fdlist *pa_alsa_fdlist_new(void) { struct pa_alsa_fdlist *fdl; fdl = pa_xnew0(struct pa_alsa_fdlist, 1); return fdl; } void pa_alsa_fdlist_free(struct pa_alsa_fdlist *fdl) { pa_assert(fdl); if (fdl->defer) { pa_assert(fdl->m); fdl->m->defer_free(fdl->defer); } if (fdl->ios) { unsigned i; pa_assert(fdl->m); for (i = 0; i < fdl->num_fds; i++) fdl->m->io_free(fdl->ios[i]); pa_xfree(fdl->ios); } if (fdl->fds) pa_xfree(fdl->fds); if (fdl->work_fds) pa_xfree(fdl->work_fds); pa_xfree(fdl); } /* We can listen to either a snd_hctl_t or a snd_mixer_t, but not both */ int pa_alsa_fdlist_set_handle(struct pa_alsa_fdlist *fdl, snd_mixer_t *mixer_handle, snd_hctl_t *hctl_handle, pa_mainloop_api *m) { pa_assert(fdl); pa_assert(hctl_handle || mixer_handle); pa_assert(!(hctl_handle && mixer_handle)); pa_assert(m); pa_assert(!fdl->m); fdl->hctl = hctl_handle; fdl->mixer = mixer_handle; fdl->m = m; fdl->defer = m->defer_new(m, defer_cb, fdl); return 0; } struct pa_alsa_mixer_pdata { pa_rtpoll *rtpoll; pa_rtpoll_item *poll_item; snd_mixer_t *mixer; }; struct pa_alsa_mixer_pdata *pa_alsa_mixer_pdata_new(void) { struct pa_alsa_mixer_pdata *pd; pd = pa_xnew0(struct pa_alsa_mixer_pdata, 1); return pd; } void pa_alsa_mixer_pdata_free(struct pa_alsa_mixer_pdata *pd) { pa_assert(pd); if (pd->poll_item) { pa_rtpoll_item_free(pd->poll_item); } pa_xfree(pd); } static int rtpoll_work_cb(pa_rtpoll_item *i) { struct pa_alsa_mixer_pdata *pd; struct pollfd *p; unsigned n_fds; unsigned short revents = 0; int err, ret = 0; pd = pa_rtpoll_item_get_work_userdata(i); pa_assert_fp(pd); pa_assert_fp(i == pd->poll_item); p = pa_rtpoll_item_get_pollfd(i, &n_fds); if ((err = snd_mixer_poll_descriptors_revents(pd->mixer, p, n_fds, &revents)) < 0) { pa_log_error("Unable to get poll revent: %s", pa_alsa_strerror(err)); ret = -1; goto fail; } if (revents) { if (revents & (POLLNVAL | POLLERR)) { pa_log_debug("Device disconnected, stopping poll on mixer"); goto fail; } else if (revents & POLLERR) { /* This shouldn't happen. */ pa_log_error("Got a POLLERR (revents = %04x), stopping poll on mixer", revents); goto fail; } err = snd_mixer_handle_events(pd->mixer); if (PA_LIKELY(err >= 0)) { pa_rtpoll_item_free(i); pa_alsa_set_mixer_rtpoll(pd, pd->mixer, pd->rtpoll); } else { pa_log_error("Error handling mixer event: %s", pa_alsa_strerror(err)); ret = -1; goto fail; } } return ret; fail: pa_rtpoll_item_free(i); pd->poll_item = NULL; pd->rtpoll = NULL; pd->mixer = NULL; return ret; } int pa_alsa_set_mixer_rtpoll(struct pa_alsa_mixer_pdata *pd, snd_mixer_t *mixer, pa_rtpoll *rtp) { pa_rtpoll_item *i; struct pollfd *p; int err, n; pa_assert(pd); pa_assert(mixer); pa_assert(rtp); if ((n = snd_mixer_poll_descriptors_count(mixer)) < 0) { pa_log("snd_mixer_poll_descriptors_count() failed: %s", pa_alsa_strerror(n)); return -1; } else if (n == 0) { pa_log_warn("Mixer has no poll descriptors. Please control mixer from PulseAudio only."); return 0; } i = pa_rtpoll_item_new(rtp, PA_RTPOLL_LATE, (unsigned) n); p = pa_rtpoll_item_get_pollfd(i, NULL); memset(p, 0, sizeof(struct pollfd) * n); if ((err = snd_mixer_poll_descriptors(mixer, p, (unsigned) n)) < 0) { pa_log_error("Unable to get poll descriptors: %s", pa_alsa_strerror(err)); pa_rtpoll_item_free(i); return -1; } pd->rtpoll = rtp; pd->poll_item = i; pd->mixer = mixer; pa_rtpoll_item_set_work_callback(i, rtpoll_work_cb, pd); return 0; } #endif static const snd_mixer_selem_channel_id_t alsa_channel_ids[PA_CHANNEL_POSITION_MAX] = { [PA_CHANNEL_POSITION_MONO] = SND_MIXER_SCHN_MONO, /* The ALSA name is just an alias! */ [PA_CHANNEL_POSITION_FRONT_CENTER] = SND_MIXER_SCHN_FRONT_CENTER, [PA_CHANNEL_POSITION_FRONT_LEFT] = SND_MIXER_SCHN_FRONT_LEFT, [PA_CHANNEL_POSITION_FRONT_RIGHT] = SND_MIXER_SCHN_FRONT_RIGHT, [PA_CHANNEL_POSITION_REAR_CENTER] = SND_MIXER_SCHN_REAR_CENTER, [PA_CHANNEL_POSITION_REAR_LEFT] = SND_MIXER_SCHN_REAR_LEFT, [PA_CHANNEL_POSITION_REAR_RIGHT] = SND_MIXER_SCHN_REAR_RIGHT, [PA_CHANNEL_POSITION_LFE] = SND_MIXER_SCHN_WOOFER, [PA_CHANNEL_POSITION_FRONT_LEFT_OF_CENTER] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_FRONT_RIGHT_OF_CENTER] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_SIDE_LEFT] = SND_MIXER_SCHN_SIDE_LEFT, [PA_CHANNEL_POSITION_SIDE_RIGHT] = SND_MIXER_SCHN_SIDE_RIGHT, [PA_CHANNEL_POSITION_AUX0] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX1] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX2] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX3] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX4] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX5] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX6] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX7] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX8] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX9] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX10] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX11] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX12] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX13] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX14] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX15] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX16] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX17] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX18] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX19] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX20] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX21] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX22] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX23] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX24] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX25] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX26] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX27] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX28] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX29] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX30] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_AUX31] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_CENTER] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_FRONT_CENTER] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_FRONT_LEFT] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_FRONT_RIGHT] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_REAR_CENTER] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_REAR_LEFT] = SND_MIXER_SCHN_UNKNOWN, [PA_CHANNEL_POSITION_TOP_REAR_RIGHT] = SND_MIXER_SCHN_UNKNOWN }; static snd_mixer_selem_channel_id_t alsa_channel_positions[POSITION_MASK_CHANNELS] = { SND_MIXER_SCHN_FRONT_LEFT, SND_MIXER_SCHN_FRONT_RIGHT, SND_MIXER_SCHN_REAR_LEFT, SND_MIXER_SCHN_REAR_RIGHT, SND_MIXER_SCHN_FRONT_CENTER, SND_MIXER_SCHN_WOOFER, SND_MIXER_SCHN_SIDE_LEFT, SND_MIXER_SCHN_SIDE_RIGHT, #if POSITION_MASK_CHANNELS > 8 #error "Extend alsa_channel_positions[] array (9+)" #endif }; static void setting_free(pa_alsa_setting *s) { pa_assert(s); if (s->options) pa_idxset_free(s->options, NULL); pa_xfree(s->name); pa_xfree(s->description); pa_xfree(s); } static void option_free(pa_alsa_option *o) { pa_assert(o); pa_xfree(o->alsa_name); pa_xfree(o->name); pa_xfree(o->description); pa_xfree(o); } static void decibel_fix_free(pa_alsa_decibel_fix *db_fix) { pa_assert(db_fix); pa_xfree(db_fix->name); pa_xfree(db_fix->db_values); pa_xfree(db_fix->key); pa_xfree(db_fix); } static void element_free(pa_alsa_element *e) { pa_alsa_option *o; pa_assert(e); while ((o = e->options)) { PA_LLIST_REMOVE(pa_alsa_option, e->options, o); option_free(o); } if (e->db_fix) decibel_fix_free(e->db_fix); pa_xfree(e->alsa_id.name); pa_xfree(e); } void pa_alsa_path_free(pa_alsa_path *p) { pa_alsa_jack *j; pa_alsa_element *e; pa_alsa_setting *s; pa_assert(p); while ((j = p->jacks)) { PA_LLIST_REMOVE(pa_alsa_jack, p->jacks, j); pa_alsa_jack_free(j); } while ((e = p->elements)) { PA_LLIST_REMOVE(pa_alsa_element, p->elements, e); element_free(e); } while ((s = p->settings)) { PA_LLIST_REMOVE(pa_alsa_setting, p->settings, s); setting_free(s); } pa_proplist_free(p->proplist); pa_xfree(p->availability_group); pa_xfree(p->name); pa_xfree(p->description); pa_xfree(p->description_key); pa_xfree(p); } void pa_alsa_path_set_free(pa_alsa_path_set *ps) { pa_assert(ps); if (ps->paths) pa_hashmap_free(ps->paths); pa_xfree(ps); } int pa_alsa_path_set_is_empty(pa_alsa_path_set *ps) { if (ps && !pa_hashmap_isempty(ps->paths)) return 0; return 1; } static long to_alsa_dB(pa_volume_t v) { return lround(pa_sw_volume_to_dB(v) * 100.0); } static pa_volume_t from_alsa_dB(long v) { return pa_sw_volume_from_dB((double) v / 100.0); } static long to_alsa_volume(pa_volume_t v, long min, long max) { long w; w = (long) round(((double) v * (double) (max - min)) / PA_VOLUME_NORM) + min; return PA_CLAMP_UNLIKELY(w, min, max); } static pa_volume_t from_alsa_volume(long v, long min, long max) { return (pa_volume_t) round(((double) (v - min) * PA_VOLUME_NORM) / (double) (max - min)); } #define SELEM_INIT(sid, aid) \ do { \ snd_mixer_selem_id_alloca(&(sid)); \ snd_mixer_selem_id_set_name((sid), (aid)->name); \ snd_mixer_selem_id_set_index((sid), (aid)->index); \ } while(false) static int element_get_volume(pa_alsa_element *e, snd_mixer_t *m, const pa_channel_map *cm, pa_cvolume *v) { snd_mixer_selem_id_t *sid; snd_mixer_elem_t *me; snd_mixer_selem_channel_id_t c; pa_channel_position_mask_t mask = 0; char buf[64]; unsigned k; pa_assert(m); pa_assert(e); pa_assert(cm); pa_assert(v); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return -1; } pa_cvolume_mute(v, cm->channels); /* We take the highest volume of all channels that match */ for (c = 0; c <= SND_MIXER_SCHN_LAST; c++) { int r; pa_volume_t f; if (e->has_dB) { long value = 0; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { if (snd_mixer_selem_has_playback_channel(me, c)) { if (e->db_fix) { if ((r = snd_mixer_selem_get_playback_volume(me, c, &value)) >= 0) { /* If the channel volume is outside the limits set * by the dB fix, we clamp the hw volume to be * within the limits. */ if (value < e->db_fix->min_step) { value = e->db_fix->min_step; snd_mixer_selem_set_playback_volume(me, c, value); pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_debug("Playback volume for element %s channel %i was below the dB fix limit. " "Volume reset to %0.2f dB.", buf, c, e->db_fix->db_values[value - e->db_fix->min_step] / 100.0); } else if (value > e->db_fix->max_step) { value = e->db_fix->max_step; snd_mixer_selem_set_playback_volume(me, c, value); pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_debug("Playback volume for element %s channel %i was over the dB fix limit. " "Volume reset to %0.2f dB.", buf, c, e->db_fix->db_values[value - e->db_fix->min_step] / 100.0); } /* Volume step -> dB value conversion. */ value = e->db_fix->db_values[value - e->db_fix->min_step]; } } else r = snd_mixer_selem_get_playback_dB(me, c, &value); } else r = -1; } else { if (snd_mixer_selem_has_capture_channel(me, c)) { if (e->db_fix) { if ((r = snd_mixer_selem_get_capture_volume(me, c, &value)) >= 0) { /* If the channel volume is outside the limits set * by the dB fix, we clamp the hw volume to be * within the limits. */ if (value < e->db_fix->min_step) { value = e->db_fix->min_step; snd_mixer_selem_set_capture_volume(me, c, value); pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_debug("Capture volume for element %s channel %i was below the dB fix limit. " "Volume reset to %0.2f dB.", buf, c, e->db_fix->db_values[value - e->db_fix->min_step] / 100.0); } else if (value > e->db_fix->max_step) { value = e->db_fix->max_step; snd_mixer_selem_set_capture_volume(me, c, value); pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_debug("Capture volume for element %s channel %i was over the dB fix limit. " "Volume reset to %0.2f dB.", buf, c, e->db_fix->db_values[value - e->db_fix->min_step] / 100.0); } /* Volume step -> dB value conversion. */ value = e->db_fix->db_values[value - e->db_fix->min_step]; } } else r = snd_mixer_selem_get_capture_dB(me, c, &value); } else r = -1; } if (r < 0) continue; VALGRIND_MAKE_MEM_DEFINED(&value, sizeof(value)); f = from_alsa_dB(value); } else { long value = 0; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { if (snd_mixer_selem_has_playback_channel(me, c)) r = snd_mixer_selem_get_playback_volume(me, c, &value); else r = -1; } else { if (snd_mixer_selem_has_capture_channel(me, c)) r = snd_mixer_selem_get_capture_volume(me, c, &value); else r = -1; } if (r < 0) continue; f = from_alsa_volume(value, e->min_volume, e->max_volume); } for (k = 0; k < cm->channels; k++) if (e->masks[c][e->n_channels-1] & PA_CHANNEL_POSITION_MASK(cm->map[k])) if (v->values[k] < f) v->values[k] = f; mask |= e->masks[c][e->n_channels-1]; } for (k = 0; k < cm->channels; k++) if (!(mask & PA_CHANNEL_POSITION_MASK(cm->map[k]))) v->values[k] = PA_VOLUME_NORM; return 0; } int pa_alsa_path_get_volume(pa_alsa_path *p, snd_mixer_t *m, const pa_channel_map *cm, pa_cvolume *v) { pa_alsa_element *e; pa_assert(m); pa_assert(p); pa_assert(cm); pa_assert(v); if (!p->has_volume) return -1; pa_cvolume_reset(v, cm->channels); PA_LLIST_FOREACH(e, p->elements) { pa_cvolume ev; if (e->volume_use != PA_ALSA_VOLUME_MERGE) continue; pa_assert(!p->has_dB || e->has_dB); if (element_get_volume(e, m, cm, &ev) < 0) return -1; /* If we have no dB information all we can do is take the first element and leave */ if (!p->has_dB) { *v = ev; return 0; } pa_sw_cvolume_multiply(v, v, &ev); } return 0; } static int element_get_switch(pa_alsa_element *e, snd_mixer_t *m, bool *b) { snd_mixer_selem_id_t *sid; snd_mixer_elem_t *me; snd_mixer_selem_channel_id_t c; char buf[64]; pa_assert(m); pa_assert(e); pa_assert(b); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return -1; } /* We return muted if at least one channel is muted */ for (c = 0; c <= SND_MIXER_SCHN_LAST; c++) { int r; int value = 0; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { if (snd_mixer_selem_has_playback_channel(me, c)) r = snd_mixer_selem_get_playback_switch(me, c, &value); else r = -1; } else { if (snd_mixer_selem_has_capture_channel(me, c)) r = snd_mixer_selem_get_capture_switch(me, c, &value); else r = -1; } if (r < 0) continue; if (!value) { *b = false; return 0; } } *b = true; return 0; } int pa_alsa_path_get_mute(pa_alsa_path *p, snd_mixer_t *m, bool *muted) { pa_alsa_element *e; pa_assert(m); pa_assert(p); pa_assert(muted); if (!p->has_mute) return -1; PA_LLIST_FOREACH(e, p->elements) { bool b; if (e->switch_use != PA_ALSA_SWITCH_MUTE) continue; if (element_get_switch(e, m, &b) < 0) return -1; if (!b) { *muted = true; return 0; } } *muted = false; return 0; } /* Finds the closest item in db_fix->db_values and returns the corresponding * step. *db_value is replaced with the value from the db_values table. * Rounding is done based on the rounding parameter: -1 means rounding down and * +1 means rounding up. */ static long decibel_fix_get_step(pa_alsa_decibel_fix *db_fix, long *db_value, int rounding) { unsigned i = 0; unsigned max_i = 0; pa_assert(db_fix); pa_assert(db_value); pa_assert(rounding != 0); max_i = db_fix->max_step - db_fix->min_step; if (rounding > 0) { for (i = 0; i < max_i; i++) { if (db_fix->db_values[i] >= *db_value) break; } } else { for (i = 0; i < max_i; i++) { if (db_fix->db_values[i + 1] > *db_value) break; } } *db_value = db_fix->db_values[i]; return i + db_fix->min_step; } /* Alsa lib documentation says for snd_mixer_selem_set_playback_dB() direction argument, * that "-1 = accurate or first below, 0 = accurate, 1 = accurate or first above". * But even with accurate nearest dB volume step is not selected, so that is why we need * this function. Returns 0 and nearest selectable volume in *value_dB on success or * negative error code if fails. */ static int element_get_nearest_alsa_dB(snd_mixer_elem_t *me, snd_mixer_selem_channel_id_t c, pa_alsa_direction_t d, long *value_dB) { long alsa_val; long value_high; long value_low; int r = -1; pa_assert(me); pa_assert(value_dB); if (d == PA_ALSA_DIRECTION_OUTPUT) { if ((r = snd_mixer_selem_ask_playback_dB_vol(me, *value_dB, +1, &alsa_val)) >= 0) r = snd_mixer_selem_ask_playback_vol_dB(me, alsa_val, &value_high); if (r < 0) return r; if (value_high == *value_dB) return r; if ((r = snd_mixer_selem_ask_playback_dB_vol(me, *value_dB, -1, &alsa_val)) >= 0) r = snd_mixer_selem_ask_playback_vol_dB(me, alsa_val, &value_low); } else { if ((r = snd_mixer_selem_ask_capture_dB_vol(me, *value_dB, +1, &alsa_val)) >= 0) r = snd_mixer_selem_ask_capture_vol_dB(me, alsa_val, &value_high); if (r < 0) return r; if (value_high == *value_dB) return r; if ((r = snd_mixer_selem_ask_capture_dB_vol(me, *value_dB, -1, &alsa_val)) >= 0) r = snd_mixer_selem_ask_capture_vol_dB(me, alsa_val, &value_low); } if (r < 0) return r; if (labs(value_high - *value_dB) < labs(value_low - *value_dB)) *value_dB = value_high; else *value_dB = value_low; return r; } static int element_set_volume(pa_alsa_element *e, snd_mixer_t *m, const pa_channel_map *cm, pa_cvolume *v, bool deferred_volume, bool write_to_hw) { snd_mixer_selem_id_t *sid; pa_cvolume rv; snd_mixer_elem_t *me; snd_mixer_selem_channel_id_t c; pa_channel_position_mask_t mask = 0; char buf[64]; unsigned k; pa_assert(m); pa_assert(e); pa_assert(cm); pa_assert(v); pa_assert(pa_cvolume_compatible_with_channel_map(v, cm)); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return -1; } pa_cvolume_mute(&rv, cm->channels); for (c = 0; c <= SND_MIXER_SCHN_LAST; c++) { int r; pa_volume_t f = PA_VOLUME_MUTED; bool found = false; for (k = 0; k < cm->channels; k++) if (e->masks[c][e->n_channels-1] & PA_CHANNEL_POSITION_MASK(cm->map[k])) { found = true; if (v->values[k] > f) f = v->values[k]; } if (!found) { /* Hmm, so this channel does not exist in the volume * struct, so let's bind it to the overall max of the * volume. */ f = pa_cvolume_max(v); } if (e->has_dB) { long value = to_alsa_dB(f); int rounding; if (e->volume_limit >= 0 && value > (e->max_dB * 100)) value = e->max_dB * 100; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { /* If we call set_playback_volume() without checking first * if the channel is available, ALSA behaves very * strangely and doesn't fail the call */ if (snd_mixer_selem_has_playback_channel(me, c)) { rounding = +1; if (e->db_fix) { if (write_to_hw) r = snd_mixer_selem_set_playback_volume(me, c, decibel_fix_get_step(e->db_fix, &value, rounding)); else { decibel_fix_get_step(e->db_fix, &value, rounding); r = 0; } } else { if (write_to_hw) { if (deferred_volume) { if ((r = element_get_nearest_alsa_dB(me, c, PA_ALSA_DIRECTION_OUTPUT, &value)) >= 0) r = snd_mixer_selem_set_playback_dB(me, c, value, 0); } else { if ((r = snd_mixer_selem_set_playback_dB(me, c, value, rounding)) >= 0) r = snd_mixer_selem_get_playback_dB(me, c, &value); } } else { long alsa_val; if ((r = snd_mixer_selem_ask_playback_dB_vol(me, value, rounding, &alsa_val)) >= 0) r = snd_mixer_selem_ask_playback_vol_dB(me, alsa_val, &value); } } } else r = -1; } else { if (snd_mixer_selem_has_capture_channel(me, c)) { rounding = -1; if (e->db_fix) { if (write_to_hw) r = snd_mixer_selem_set_capture_volume(me, c, decibel_fix_get_step(e->db_fix, &value, rounding)); else { decibel_fix_get_step(e->db_fix, &value, rounding); r = 0; } } else { if (write_to_hw) { if (deferred_volume) { if ((r = element_get_nearest_alsa_dB(me, c, PA_ALSA_DIRECTION_INPUT, &value)) >= 0) r = snd_mixer_selem_set_capture_dB(me, c, value, 0); } else { if ((r = snd_mixer_selem_set_capture_dB(me, c, value, rounding)) >= 0) r = snd_mixer_selem_get_capture_dB(me, c, &value); } } else { long alsa_val; if ((r = snd_mixer_selem_ask_capture_dB_vol(me, value, rounding, &alsa_val)) >= 0) r = snd_mixer_selem_ask_capture_vol_dB(me, alsa_val, &value); } } } else r = -1; } if (r < 0) continue; f = from_alsa_dB(value); } else { long value; value = to_alsa_volume(f, e->min_volume, e->max_volume); if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { if (snd_mixer_selem_has_playback_channel(me, c)) { if ((r = snd_mixer_selem_set_playback_volume(me, c, value)) >= 0) r = snd_mixer_selem_get_playback_volume(me, c, &value); } else r = -1; } else { if (snd_mixer_selem_has_capture_channel(me, c)) { if ((r = snd_mixer_selem_set_capture_volume(me, c, value)) >= 0) r = snd_mixer_selem_get_capture_volume(me, c, &value); } else r = -1; } if (r < 0) continue; f = from_alsa_volume(value, e->min_volume, e->max_volume); } for (k = 0; k < cm->channels; k++) if (e->masks[c][e->n_channels-1] & PA_CHANNEL_POSITION_MASK(cm->map[k])) if (rv.values[k] < f) rv.values[k] = f; mask |= e->masks[c][e->n_channels-1]; } for (k = 0; k < cm->channels; k++) if (!(mask & PA_CHANNEL_POSITION_MASK(cm->map[k]))) rv.values[k] = PA_VOLUME_NORM; *v = rv; return 0; } int pa_alsa_path_set_volume(pa_alsa_path *p, snd_mixer_t *m, const pa_channel_map *cm, pa_cvolume *v, bool deferred_volume, bool write_to_hw) { pa_alsa_element *e; pa_cvolume rv; pa_assert(m); pa_assert(p); pa_assert(cm); pa_assert(v); pa_assert(pa_cvolume_compatible_with_channel_map(v, cm)); if (!p->has_volume) return -1; rv = *v; /* Remaining adjustment */ pa_cvolume_reset(v, cm->channels); /* Adjustment done */ PA_LLIST_FOREACH(e, p->elements) { pa_cvolume ev; if (e->volume_use != PA_ALSA_VOLUME_MERGE) continue; pa_assert(!p->has_dB || e->has_dB); ev = rv; if (element_set_volume(e, m, cm, &ev, deferred_volume, write_to_hw) < 0) return -1; if (!p->has_dB) { *v = ev; return 0; } pa_sw_cvolume_multiply(v, v, &ev); pa_sw_cvolume_divide(&rv, &rv, &ev); } return 0; } static int element_set_switch(pa_alsa_element *e, snd_mixer_t *m, bool b) { snd_mixer_elem_t *me; snd_mixer_selem_id_t *sid; char buf[64]; int r; pa_assert(m); pa_assert(e); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return -1; } if (e->direction == PA_ALSA_DIRECTION_OUTPUT) r = snd_mixer_selem_set_playback_switch_all(me, b); else r = snd_mixer_selem_set_capture_switch_all(me, b); if (r < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to set switch of %s: %s", buf, pa_alsa_strerror(errno)); } return r; } int pa_alsa_path_set_mute(pa_alsa_path *p, snd_mixer_t *m, bool muted) { pa_alsa_element *e; pa_assert(m); pa_assert(p); if (!p->has_mute) return -1; PA_LLIST_FOREACH(e, p->elements) { if (e->switch_use != PA_ALSA_SWITCH_MUTE) continue; if (element_set_switch(e, m, !muted) < 0) return -1; } return 0; } /* Depending on whether e->volume_use is _OFF, _ZERO or _CONSTANT, this * function sets all channels of the volume element to e->min_volume, 0 dB or * e->constant_volume. */ static int element_set_constant_volume(pa_alsa_element *e, snd_mixer_t *m) { snd_mixer_elem_t *me = NULL; snd_mixer_selem_id_t *sid = NULL; int r = 0; long volume = -1; bool volume_set = false; char buf[64]; pa_assert(m); pa_assert(e); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return -1; } switch (e->volume_use) { case PA_ALSA_VOLUME_OFF: volume = e->min_volume; volume_set = true; break; case PA_ALSA_VOLUME_ZERO: if (e->db_fix) { long dB = 0; volume = decibel_fix_get_step(e->db_fix, &dB, (e->direction == PA_ALSA_DIRECTION_OUTPUT ? +1 : -1)); volume_set = true; } break; case PA_ALSA_VOLUME_CONSTANT: volume = e->constant_volume; volume_set = true; break; default: pa_assert_not_reached(); } if (volume_set) { if (e->direction == PA_ALSA_DIRECTION_OUTPUT) r = snd_mixer_selem_set_playback_volume_all(me, volume); else r = snd_mixer_selem_set_capture_volume_all(me, volume); } else { pa_assert(e->volume_use == PA_ALSA_VOLUME_ZERO); pa_assert(!e->db_fix); if (e->direction == PA_ALSA_DIRECTION_OUTPUT) r = snd_mixer_selem_set_playback_dB_all(me, 0, +1); else r = snd_mixer_selem_set_capture_dB_all(me, 0, -1); } if (r < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to set volume of %s: %s", buf, pa_alsa_strerror(errno)); } return r; } int pa_alsa_path_select(pa_alsa_path *p, pa_alsa_setting *s, snd_mixer_t *m, bool device_is_muted) { pa_alsa_element *e; int r = 0; pa_assert(m); pa_assert(p); pa_log_info("Activating path %s", p->name); pa_alsa_path_dump(p); /* First turn on hw mute if available, to avoid noise * when setting the mixer controls. */ if (p->mute_during_activation) { PA_LLIST_FOREACH(e, p->elements) { if (e->switch_use == PA_ALSA_SWITCH_MUTE) /* If the muting fails here, that's not a critical problem for * selecting a path, so we ignore the return value. * element_set_switch() will print a warning anyway, so this * won't be a silent failure either. */ (void) element_set_switch(e, m, false); } } PA_LLIST_FOREACH(e, p->elements) { switch (e->switch_use) { case PA_ALSA_SWITCH_OFF: r = element_set_switch(e, m, false); break; case PA_ALSA_SWITCH_ON: r = element_set_switch(e, m, true); break; case PA_ALSA_SWITCH_MUTE: case PA_ALSA_SWITCH_IGNORE: case PA_ALSA_SWITCH_SELECT: r = 0; break; } if (r < 0) return -1; switch (e->volume_use) { case PA_ALSA_VOLUME_OFF: case PA_ALSA_VOLUME_ZERO: case PA_ALSA_VOLUME_CONSTANT: r = element_set_constant_volume(e, m); break; case PA_ALSA_VOLUME_MERGE: case PA_ALSA_VOLUME_IGNORE: r = 0; break; } if (r < 0) return -1; } if (s) setting_select(s, m); /* Finally restore hw mute to the device mute status. */ if (p->mute_during_activation) { PA_LLIST_FOREACH(e, p->elements) { if (e->switch_use == PA_ALSA_SWITCH_MUTE) { if (element_set_switch(e, m, !device_is_muted) < 0) return -1; } } } return 0; } static int check_required(pa_alsa_element *e, snd_mixer_elem_t *me) { bool has_switch; bool has_enumeration; bool has_volume; pa_assert(e); pa_assert(me); if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { has_switch = snd_mixer_selem_has_playback_switch(me) || (e->direction_try_other && snd_mixer_selem_has_capture_switch(me)); } else { has_switch = snd_mixer_selem_has_capture_switch(me) || (e->direction_try_other && snd_mixer_selem_has_playback_switch(me)); } if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { has_volume = snd_mixer_selem_has_playback_volume(me) || (e->direction_try_other && snd_mixer_selem_has_capture_volume(me)); } else { has_volume = snd_mixer_selem_has_capture_volume(me) || (e->direction_try_other && snd_mixer_selem_has_playback_volume(me)); } has_enumeration = snd_mixer_selem_is_enumerated(me); if ((e->required == PA_ALSA_REQUIRED_SWITCH && !has_switch) || (e->required == PA_ALSA_REQUIRED_VOLUME && !has_volume) || (e->required == PA_ALSA_REQUIRED_ENUMERATION && !has_enumeration)) return -1; if (e->required == PA_ALSA_REQUIRED_ANY && !(has_switch || has_volume || has_enumeration)) return -1; if ((e->required_absent == PA_ALSA_REQUIRED_SWITCH && has_switch) || (e->required_absent == PA_ALSA_REQUIRED_VOLUME && has_volume) || (e->required_absent == PA_ALSA_REQUIRED_ENUMERATION && has_enumeration)) return -1; if (e->required_absent == PA_ALSA_REQUIRED_ANY && (has_switch || has_volume || has_enumeration)) return -1; if (e->required_any != PA_ALSA_REQUIRED_IGNORE) { switch (e->required_any) { case PA_ALSA_REQUIRED_VOLUME: e->path->req_any_present |= (e->volume_use != PA_ALSA_VOLUME_IGNORE); break; case PA_ALSA_REQUIRED_SWITCH: e->path->req_any_present |= (e->switch_use != PA_ALSA_SWITCH_IGNORE); break; case PA_ALSA_REQUIRED_ENUMERATION: e->path->req_any_present |= (e->enumeration_use != PA_ALSA_ENUMERATION_IGNORE); break; case PA_ALSA_REQUIRED_ANY: e->path->req_any_present |= (e->volume_use != PA_ALSA_VOLUME_IGNORE) || (e->switch_use != PA_ALSA_SWITCH_IGNORE) || (e->enumeration_use != PA_ALSA_ENUMERATION_IGNORE); break; default: pa_assert_not_reached(); } } if (e->enumeration_use == PA_ALSA_ENUMERATION_SELECT) { pa_alsa_option *o; PA_LLIST_FOREACH(o, e->options) { e->path->req_any_present |= (o->required_any != PA_ALSA_REQUIRED_IGNORE) && (o->alsa_idx >= 0); if (o->required != PA_ALSA_REQUIRED_IGNORE && o->alsa_idx < 0) return -1; if (o->required_absent != PA_ALSA_REQUIRED_IGNORE && o->alsa_idx >= 0) return -1; } } return 0; } static int element_ask_vol_dB(snd_mixer_elem_t *me, pa_alsa_direction_t dir, long value, long *dBvalue) { if (dir == PA_ALSA_DIRECTION_OUTPUT) return snd_mixer_selem_ask_playback_vol_dB(me, value, dBvalue); else return snd_mixer_selem_ask_capture_vol_dB(me, value, dBvalue); } static bool element_probe_volume(pa_alsa_element *e, snd_mixer_elem_t *me) { long min_dB = 0, max_dB = 0; int r; bool is_mono; pa_channel_position_t p; char buf[64]; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { if (!snd_mixer_selem_has_playback_volume(me)) { if (e->direction_try_other && snd_mixer_selem_has_capture_volume(me)) e->direction = PA_ALSA_DIRECTION_INPUT; else return false; } } else { if (!snd_mixer_selem_has_capture_volume(me)) { if (e->direction_try_other && snd_mixer_selem_has_playback_volume(me)) e->direction = PA_ALSA_DIRECTION_OUTPUT; else return false; } } e->direction_try_other = false; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) r = snd_mixer_selem_get_playback_volume_range(me, &e->min_volume, &e->max_volume); else r = snd_mixer_selem_get_capture_volume_range(me, &e->min_volume, &e->max_volume); if (r < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to get volume range of %s: %s", buf, pa_alsa_strerror(r)); return false; } if (e->min_volume >= e->max_volume) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Your kernel driver is broken for element %s: it reports a volume range from %li to %li which makes no sense.", buf, e->min_volume, e->max_volume); return false; } if (e->volume_use == PA_ALSA_VOLUME_CONSTANT && (e->min_volume > e->constant_volume || e->max_volume < e->constant_volume)) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Constant volume %li configured for element %s, but the available range is from %li to %li.", e->constant_volume, buf, e->min_volume, e->max_volume); return false; } if (e->db_fix && ((e->min_volume > e->db_fix->min_step) || (e->max_volume < e->db_fix->max_step))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("The step range of the decibel fix for element %s (%li-%li) doesn't fit to the " "real hardware range (%li-%li). Disabling the decibel fix.", buf, e->db_fix->min_step, e->db_fix->max_step, e->min_volume, e->max_volume); decibel_fix_free(e->db_fix); e->db_fix = NULL; } if (e->db_fix) { e->has_dB = true; e->min_volume = e->db_fix->min_step; e->max_volume = e->db_fix->max_step; min_dB = e->db_fix->db_values[0]; max_dB = e->db_fix->db_values[e->db_fix->max_step - e->db_fix->min_step]; } else if (e->direction == PA_ALSA_DIRECTION_OUTPUT) e->has_dB = snd_mixer_selem_get_playback_dB_range(me, &min_dB, &max_dB) >= 0; else e->has_dB = snd_mixer_selem_get_capture_dB_range(me, &min_dB, &max_dB) >= 0; /* Assume decibel data to be incorrect if max_dB is negative. */ if (e->has_dB && max_dB < 0 && !e->db_fix) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("The decibel volume range for element %s (%li dB - %li dB) has negative maximum. " "Disabling the decibel range.", buf, min_dB, max_dB); e->has_dB = false; } /* Check that the kernel driver returns consistent limits with * both _get_*_dB_range() and _ask_*_vol_dB(). */ if (e->has_dB && !e->db_fix) { long min_dB_checked = 0; long max_dB_checked = 0; if (element_ask_vol_dB(me, e->direction, e->min_volume, &min_dB_checked) < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to query the dB value for %s at volume level %li", buf, e->min_volume); return false; } if (element_ask_vol_dB(me, e->direction, e->max_volume, &max_dB_checked) < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to query the dB value for %s at volume level %li", buf, e->max_volume); return false; } if (min_dB != min_dB_checked || max_dB != max_dB_checked) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Your kernel driver is broken: the reported dB range for %s (from %0.2f dB to %0.2f dB) " "doesn't match the dB values at minimum and maximum volume levels: %0.2f dB at level %li, " "%0.2f dB at level %li.", buf, min_dB / 100.0, max_dB / 100.0, min_dB_checked / 100.0, e->min_volume, max_dB_checked / 100.0, e->max_volume); return false; } } if (e->has_dB) { e->min_dB = ((double) min_dB) / 100.0; e->max_dB = ((double) max_dB) / 100.0; if (min_dB >= max_dB) { pa_assert(!e->db_fix); pa_log_warn("Your kernel driver is broken: it reports a volume range from %0.2f dB to %0.2f dB which makes no sense.", e->min_dB, e->max_dB); e->has_dB = false; } } if (e->volume_limit >= 0) { if (e->volume_limit <= e->min_volume || e->volume_limit > e->max_volume) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Volume limit for element %s of path %s is invalid: %li isn't within the valid range " "%li-%li. The volume limit is ignored.", buf, e->path->name, e->volume_limit, e->min_volume + 1, e->max_volume); } else { e->max_volume = e->volume_limit; if (e->has_dB) { if (e->db_fix) { e->db_fix->max_step = e->max_volume; e->max_dB = ((double) e->db_fix->db_values[e->db_fix->max_step - e->db_fix->min_step]) / 100.0; } else if (element_ask_vol_dB(me, e->direction, e->max_volume, &max_dB) < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to get dB value of %s: %s", buf, pa_alsa_strerror(r)); e->has_dB = false; } else e->max_dB = ((double) max_dB) / 100.0; } } } if (e->direction == PA_ALSA_DIRECTION_OUTPUT) is_mono = snd_mixer_selem_is_playback_mono(me) > 0; else is_mono = snd_mixer_selem_is_capture_mono(me) > 0; if (is_mono) { e->n_channels = 1; if ((e->override_map & (1 << (e->n_channels-1))) && e->masks[SND_MIXER_SCHN_MONO][e->n_channels-1] == 0) { pa_log_warn("Override map for mono element %s is invalid, ignoring override map", e->path->name); e->override_map &= ~(1 << (e->n_channels-1)); } if (!(e->override_map & (1 << (e->n_channels-1)))) { for (p = PA_CHANNEL_POSITION_FRONT_LEFT; p < PA_CHANNEL_POSITION_MAX; p++) { if (alsa_channel_ids[p] == SND_MIXER_SCHN_UNKNOWN) continue; e->masks[alsa_channel_ids[p]][e->n_channels-1] = 0; } e->masks[SND_MIXER_SCHN_MONO][e->n_channels-1] = PA_CHANNEL_POSITION_MASK_ALL; } e->merged_mask = e->masks[SND_MIXER_SCHN_MONO][e->n_channels-1]; return true; } e->n_channels = 0; for (p = PA_CHANNEL_POSITION_FRONT_LEFT; p < PA_CHANNEL_POSITION_MAX; p++) { if (alsa_channel_ids[p] == SND_MIXER_SCHN_UNKNOWN) continue; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) e->n_channels += snd_mixer_selem_has_playback_channel(me, alsa_channel_ids[p]) > 0; else e->n_channels += snd_mixer_selem_has_capture_channel(me, alsa_channel_ids[p]) > 0; } if (e->n_channels <= 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Volume element %s with no channels?", buf); return false; } else if (e->n_channels > POSITION_MASK_CHANNELS) { /* FIXME: In some places code like this is used: * * e->masks[alsa_channel_ids[p]][e->n_channels-1] * * The definition of e->masks is * * pa_channel_position_mask_t masks[SND_MIXER_SCHN_LAST + 1][POSITION_MASK_CHANNELS]; * * Since the array size is fixed at POSITION_MASK_CHANNELS, we obviously * don't support elements with more than POSITION_MASK_CHANNELS * channels... */ pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Volume element %s has %u channels. That's too much! I can't handle that!", buf, e->n_channels); return false; } retry: if (!(e->override_map & (1 << (e->n_channels-1)))) { for (p = PA_CHANNEL_POSITION_FRONT_LEFT; p < PA_CHANNEL_POSITION_MAX; p++) { bool has_channel; if (alsa_channel_ids[p] == SND_MIXER_SCHN_UNKNOWN) continue; if (e->direction == PA_ALSA_DIRECTION_OUTPUT) has_channel = snd_mixer_selem_has_playback_channel(me, alsa_channel_ids[p]) > 0; else has_channel = snd_mixer_selem_has_capture_channel(me, alsa_channel_ids[p]) > 0; e->masks[alsa_channel_ids[p]][e->n_channels-1] = has_channel ? PA_CHANNEL_POSITION_MASK(p) : 0; } } e->merged_mask = 0; for (p = PA_CHANNEL_POSITION_FRONT_LEFT; p < PA_CHANNEL_POSITION_MAX; p++) { if (alsa_channel_ids[p] == SND_MIXER_SCHN_UNKNOWN) continue; e->merged_mask |= e->masks[alsa_channel_ids[p]][e->n_channels-1]; } if (e->merged_mask == 0) { if (!(e->override_map & (1 << (e->n_channels-1)))) { pa_log_warn("Channel map for element %s is invalid", e->path->name); return false; } pa_log_warn("Override map for element %s has empty result, ignoring override map", e->path->name); e->override_map &= ~(1 << (e->n_channels-1)); goto retry; } return true; } static int element_probe(pa_alsa_element *e, snd_mixer_t *m) { snd_mixer_selem_id_t *sid; snd_mixer_elem_t *me; pa_assert(m); pa_assert(e); pa_assert(e->path); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { if (e->required != PA_ALSA_REQUIRED_IGNORE) return -1; e->switch_use = PA_ALSA_SWITCH_IGNORE; e->volume_use = PA_ALSA_VOLUME_IGNORE; e->enumeration_use = PA_ALSA_ENUMERATION_IGNORE; return 0; } if (e->switch_use != PA_ALSA_SWITCH_IGNORE) { if (e->direction == PA_ALSA_DIRECTION_OUTPUT) { if (!snd_mixer_selem_has_playback_switch(me)) { if (e->direction_try_other && snd_mixer_selem_has_capture_switch(me)) e->direction = PA_ALSA_DIRECTION_INPUT; else e->switch_use = PA_ALSA_SWITCH_IGNORE; } } else { if (!snd_mixer_selem_has_capture_switch(me)) { if (e->direction_try_other && snd_mixer_selem_has_playback_switch(me)) e->direction = PA_ALSA_DIRECTION_OUTPUT; else e->switch_use = PA_ALSA_SWITCH_IGNORE; } } if (e->switch_use != PA_ALSA_SWITCH_IGNORE) e->direction_try_other = false; } if (!element_probe_volume(e, me)) e->volume_use = PA_ALSA_VOLUME_IGNORE; if (e->switch_use == PA_ALSA_SWITCH_SELECT) { pa_alsa_option *o; PA_LLIST_FOREACH(o, e->options) o->alsa_idx = pa_streq(o->alsa_name, "on") ? 1 : 0; } else if (e->enumeration_use == PA_ALSA_ENUMERATION_SELECT) { int n; pa_alsa_option *o; if ((n = snd_mixer_selem_get_enum_items(me)) < 0) { pa_log("snd_mixer_selem_get_enum_items() failed: %s", pa_alsa_strerror(n)); return -1; } PA_LLIST_FOREACH(o, e->options) { int i; for (i = 0; i < n; i++) { char buf[128]; if (snd_mixer_selem_get_enum_item_name(me, i, sizeof(buf), buf) < 0) continue; if (!pa_streq(buf, o->alsa_name)) continue; o->alsa_idx = i; } } } if (check_required(e, me) < 0) return -1; return 0; } static int jack_probe(pa_alsa_jack *j, pa_alsa_mapping *mapping, snd_mixer_t *m) { bool has_control; pa_assert(j); pa_assert(j->path); if (j->append_pcm_to_name) { char *new_name; if (!mapping) { /* This could also be an assertion, because this should never * happen. At the time of writing, mapping can only be NULL when * module-alsa-sink/source synthesizes a path, and those * synthesized paths never have any jacks, so jack_probe() should * never be called with a NULL mapping. */ pa_log("Jack %s: append_pcm_to_name is set, but mapping is NULL. Can't use this jack.", j->name); return -1; } new_name = pa_sprintf_malloc("%s,pcm=%i Jack", j->name, mapping->hw_device_index); pa_xfree(j->alsa_id.name); j->alsa_id.name = new_name; j->append_pcm_to_name = false; } has_control = pa_alsa_mixer_find_card(m, &j->alsa_id, 0) != NULL; pa_alsa_jack_set_has_control(j, has_control); if (j->has_control) { if (j->required_absent != PA_ALSA_REQUIRED_IGNORE) return -1; if (j->required_any != PA_ALSA_REQUIRED_IGNORE) j->path->req_any_present = true; } else { if (j->required != PA_ALSA_REQUIRED_IGNORE) return -1; } return 0; } pa_alsa_element * pa_alsa_element_get(pa_alsa_path *p, const char *section, bool prefixed) { pa_alsa_element *e; char *name; int index; pa_assert(p); pa_assert(section); if (prefixed) { if (!pa_startswith(section, "Element ")) return NULL; section += 8; } /* This is not an element section, but an enum section? */ if (strchr(section, ':')) return NULL; name = alloca(strlen(section) + 1); if (alsa_id_decode(section, name, &index)) return NULL; if (p->last_element && pa_streq(p->last_element->alsa_id.name, name) && p->last_element->alsa_id.index == index) return p->last_element; PA_LLIST_FOREACH(e, p->elements) if (pa_streq(e->alsa_id.name, name) && e->alsa_id.index == index) goto finish; e = pa_xnew0(pa_alsa_element, 1); e->path = p; e->alsa_id.name = pa_xstrdup(name); e->alsa_id.index = index; e->direction = p->direction; e->volume_limit = -1; PA_LLIST_INSERT_AFTER(pa_alsa_element, p->elements, p->last_element, e); finish: p->last_element = e; return e; } static pa_alsa_jack* jack_get(pa_alsa_path *p, const char *section) { pa_alsa_jack *j; char *name; int index; if (!pa_startswith(section, "Jack ")) return NULL; section += 5; name = alloca(strlen(section) + 1); if (alsa_id_decode(section, name, &index)) return NULL; if (p->last_jack && pa_streq(p->last_jack->name, name) && p->last_jack->alsa_id.index == index) return p->last_jack; PA_LLIST_FOREACH(j, p->jacks) if (pa_streq(j->name, name) && j->alsa_id.index == index) goto finish; j = pa_alsa_jack_new(p, NULL, name, index); PA_LLIST_INSERT_AFTER(pa_alsa_jack, p->jacks, p->last_jack, j); finish: p->last_jack = j; return j; } static pa_alsa_option* option_get(pa_alsa_path *p, const char *section) { char *en, *name; const char *on; pa_alsa_option *o; pa_alsa_element *e; size_t len; int index; if (!pa_startswith(section, "Option ")) return NULL; section += 7; /* This is not an enum section, but an element section? */ if (!(on = strchr(section, ':'))) return NULL; len = on - section; en = alloca(len + 1); strncpy(en, section, len); en[len] = '\0'; name = alloca(strlen(en) + 1); if (alsa_id_decode(en, name, &index)) return NULL; on++; if (p->last_option && pa_streq(p->last_option->element->alsa_id.name, name) && p->last_option->element->alsa_id.index == index && pa_streq(p->last_option->alsa_name, on)) { return p->last_option; } pa_assert_se(e = pa_alsa_element_get(p, en, false)); PA_LLIST_FOREACH(o, e->options) if (pa_streq(o->alsa_name, on)) goto finish; o = pa_xnew0(pa_alsa_option, 1); o->element = e; o->alsa_name = pa_xstrdup(on); o->alsa_idx = -1; if (p->last_option && p->last_option->element == e) PA_LLIST_INSERT_AFTER(pa_alsa_option, e->options, p->last_option, o); else PA_LLIST_PREPEND(pa_alsa_option, e->options, o); finish: p->last_option = o; return o; } static int element_parse_switch(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] Switch makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "ignore")) e->switch_use = PA_ALSA_SWITCH_IGNORE; else if (pa_streq(state->rvalue, "mute")) e->switch_use = PA_ALSA_SWITCH_MUTE; else if (pa_streq(state->rvalue, "off")) e->switch_use = PA_ALSA_SWITCH_OFF; else if (pa_streq(state->rvalue, "on")) e->switch_use = PA_ALSA_SWITCH_ON; else if (pa_streq(state->rvalue, "select")) e->switch_use = PA_ALSA_SWITCH_SELECT; else { pa_log("[%s:%u] Switch invalid of '%s'", state->filename, state->lineno, state->section); return -1; } return 0; } static int element_parse_volume(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] Volume makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "ignore")) e->volume_use = PA_ALSA_VOLUME_IGNORE; else if (pa_streq(state->rvalue, "merge")) e->volume_use = PA_ALSA_VOLUME_MERGE; else if (pa_streq(state->rvalue, "off")) e->volume_use = PA_ALSA_VOLUME_OFF; else if (pa_streq(state->rvalue, "zero")) e->volume_use = PA_ALSA_VOLUME_ZERO; else { uint32_t constant; if (pa_atou(state->rvalue, &constant) >= 0) { e->volume_use = PA_ALSA_VOLUME_CONSTANT; e->constant_volume = constant; } else { pa_log("[%s:%u] Volume invalid of '%s'", state->filename, state->lineno, state->section); return -1; } } return 0; } static int element_parse_enumeration(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] Enumeration makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "ignore")) e->enumeration_use = PA_ALSA_ENUMERATION_IGNORE; else if (pa_streq(state->rvalue, "select")) e->enumeration_use = PA_ALSA_ENUMERATION_SELECT; else { pa_log("[%s:%u] Enumeration invalid of '%s'", state->filename, state->lineno, state->section); return -1; } return 0; } static int parse_type(pa_config_parser_state *state) { struct device_port_types { const char *name; pa_device_port_type_t type; } device_port_types[] = { { "unknown", PA_DEVICE_PORT_TYPE_UNKNOWN }, { "aux", PA_DEVICE_PORT_TYPE_AUX }, { "speaker", PA_DEVICE_PORT_TYPE_SPEAKER }, { "headphones", PA_DEVICE_PORT_TYPE_HEADPHONES }, { "line", PA_DEVICE_PORT_TYPE_LINE }, { "mic", PA_DEVICE_PORT_TYPE_MIC }, { "headset", PA_DEVICE_PORT_TYPE_HEADSET }, { "handset", PA_DEVICE_PORT_TYPE_HANDSET }, { "earpiece", PA_DEVICE_PORT_TYPE_EARPIECE }, { "spdif", PA_DEVICE_PORT_TYPE_SPDIF }, { "hdmi", PA_DEVICE_PORT_TYPE_HDMI }, { "tv", PA_DEVICE_PORT_TYPE_TV }, { "radio", PA_DEVICE_PORT_TYPE_RADIO }, { "video", PA_DEVICE_PORT_TYPE_VIDEO }, { "usb", PA_DEVICE_PORT_TYPE_USB }, { "bluetooth", PA_DEVICE_PORT_TYPE_BLUETOOTH }, { "portable", PA_DEVICE_PORT_TYPE_PORTABLE }, { "handsfree", PA_DEVICE_PORT_TYPE_HANDSFREE }, { "car", PA_DEVICE_PORT_TYPE_CAR }, { "hifi", PA_DEVICE_PORT_TYPE_HIFI }, { "phone", PA_DEVICE_PORT_TYPE_PHONE }, { "network", PA_DEVICE_PORT_TYPE_NETWORK }, { "analog", PA_DEVICE_PORT_TYPE_ANALOG }, }; pa_alsa_path *path; unsigned int idx; path = state->userdata; for (idx = 0; idx < PA_ELEMENTSOF(device_port_types); idx++) if (pa_streq(state->rvalue, device_port_types[idx].name)) { path->device_port_type = device_port_types[idx].type; return 0; } pa_log("[%s:%u] Invalid value for option 'type': %s", state->filename, state->lineno, state->rvalue); return -1; } static int parse_eld_device(pa_config_parser_state *state) { pa_alsa_path *path; uint32_t eld_device; path = state->userdata; if (pa_atou(state->rvalue, &eld_device) >= 0) { path->autodetect_eld_device = false; path->eld_device = eld_device; return 0; } if (pa_streq(state->rvalue, "auto")) { path->autodetect_eld_device = true; path->eld_device = -1; return 0; } pa_log("[%s:%u] Invalid value for option 'eld-device': %s", state->filename, state->lineno, state->rvalue); return -1; } static int option_parse_priority(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_option *o; uint32_t prio; pa_assert(state); p = state->userdata; if (!(o = option_get(p, state->section))) { pa_log("[%s:%u] Priority makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_atou(state->rvalue, &prio) < 0) { pa_log("[%s:%u] Priority invalid of '%s'", state->filename, state->lineno, state->section); return -1; } o->priority = prio; return 0; } static int option_parse_name(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_option *o; pa_assert(state); p = state->userdata; if (!(o = option_get(p, state->section))) { pa_log("[%s:%u] Name makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } pa_xfree(o->name); o->name = pa_xstrdup(state->rvalue); return 0; } static int element_parse_required(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; pa_alsa_option *o; pa_alsa_jack *j; pa_alsa_required_t req; pa_assert(state); p = state->userdata; e = pa_alsa_element_get(p, state->section, true); o = option_get(p, state->section); j = jack_get(p, state->section); if (!e && !o && !j) { pa_log("[%s:%u] Required makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "ignore")) req = PA_ALSA_REQUIRED_IGNORE; else if (pa_streq(state->rvalue, "switch") && e) req = PA_ALSA_REQUIRED_SWITCH; else if (pa_streq(state->rvalue, "volume") && e) req = PA_ALSA_REQUIRED_VOLUME; else if (pa_streq(state->rvalue, "enumeration")) req = PA_ALSA_REQUIRED_ENUMERATION; else if (pa_streq(state->rvalue, "any")) req = PA_ALSA_REQUIRED_ANY; else { pa_log("[%s:%u] Required invalid of '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->lvalue, "required-absent")) { if (e) e->required_absent = req; if (o) o->required_absent = req; if (j) j->required_absent = req; } else if (pa_streq(state->lvalue, "required-any")) { if (e) { e->required_any = req; e->path->has_req_any |= (req != PA_ALSA_REQUIRED_IGNORE); } if (o) { o->required_any = req; o->element->path->has_req_any |= (req != PA_ALSA_REQUIRED_IGNORE); } if (j) { j->required_any = req; j->path->has_req_any |= (req != PA_ALSA_REQUIRED_IGNORE); } } else { if (e) e->required = req; if (o) o->required = req; if (j) j->required = req; } return 0; } static int element_parse_direction(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] Direction makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "playback")) e->direction = PA_ALSA_DIRECTION_OUTPUT; else if (pa_streq(state->rvalue, "capture")) e->direction = PA_ALSA_DIRECTION_INPUT; else { pa_log("[%s:%u] Direction invalid of '%s'", state->filename, state->lineno, state->section); return -1; } return 0; } static int element_parse_direction_try_other(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; int yes; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] Direction makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if ((yes = pa_parse_boolean(state->rvalue)) < 0) { pa_log("[%s:%u] Direction invalid of '%s'", state->filename, state->lineno, state->section); return -1; } e->direction_try_other = !!yes; return 0; } static int element_parse_volume_limit(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; long volume_limit; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] volume-limit makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_atol(state->rvalue, &volume_limit) < 0 || volume_limit < 0) { pa_log("[%s:%u] Invalid value for volume-limit", state->filename, state->lineno); return -1; } e->volume_limit = volume_limit; return 0; } static unsigned int parse_channel_position(const char *m) { pa_channel_position_t p; if ((p = pa_channel_position_from_string(m)) == PA_CHANNEL_POSITION_INVALID) return SND_MIXER_SCHN_UNKNOWN; return alsa_channel_ids[p]; } static pa_channel_position_mask_t parse_mask(const char *m) { pa_channel_position_mask_t v; if (pa_streq(m, "all-left")) v = PA_CHANNEL_POSITION_MASK_LEFT; else if (pa_streq(m, "all-right")) v = PA_CHANNEL_POSITION_MASK_RIGHT; else if (pa_streq(m, "all-center")) v = PA_CHANNEL_POSITION_MASK_CENTER; else if (pa_streq(m, "all-front")) v = PA_CHANNEL_POSITION_MASK_FRONT; else if (pa_streq(m, "all-rear")) v = PA_CHANNEL_POSITION_MASK_REAR; else if (pa_streq(m, "all-side")) v = PA_CHANNEL_POSITION_MASK_SIDE_OR_TOP_CENTER; else if (pa_streq(m, "all-top")) v = PA_CHANNEL_POSITION_MASK_TOP; else if (pa_streq(m, "all-no-lfe")) v = PA_CHANNEL_POSITION_MASK_ALL ^ PA_CHANNEL_POSITION_MASK(PA_CHANNEL_POSITION_LFE); else if (pa_streq(m, "all")) v = PA_CHANNEL_POSITION_MASK_ALL; else { pa_channel_position_t p; if ((p = pa_channel_position_from_string(m)) == PA_CHANNEL_POSITION_INVALID) return 0; v = PA_CHANNEL_POSITION_MASK(p); } return v; } static int element_parse_override_map(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_element *e; const char *split_state = NULL; char *s; unsigned i = 0; int channel_count = 0; char *n; pa_assert(state); p = state->userdata; if (!(e = pa_alsa_element_get(p, state->section, true))) { pa_log("[%s:%u] Override map makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } s = strstr(state->lvalue, "."); if (s) { pa_atoi(s + 1, &channel_count); if (channel_count < 1 || channel_count > POSITION_MASK_CHANNELS) { pa_log("[%s:%u] Override map index '%s' invalid in '%s'", state->filename, state->lineno, state->lvalue, state->section); return 0; } } else { pa_log("[%s:%u] Invalid override map syntax '%s' in '%s'", state->filename, state->lineno, state->lvalue, state->section); return -1; } while ((n = pa_split(state->rvalue, ",", &split_state))) { pa_channel_position_mask_t m; snd_mixer_selem_channel_id_t channel_position; if (i >= (unsigned)channel_count) { pa_log("[%s:%u] Invalid override map size (>%d) in '%s'", state->filename, state->lineno, channel_count, state->section); pa_xfree(n); return -1; } channel_position = alsa_channel_positions[i]; if (!*n) m = 0; else { s = strstr(n, ":"); if (s) { *s = '\0'; s++; channel_position = parse_channel_position(n); if (channel_position == SND_MIXER_SCHN_UNKNOWN) { pa_log("[%s:%u] Override map position '%s' invalid in '%s'", state->filename, state->lineno, n, state->section); pa_xfree(n); return -1; } } if ((m = parse_mask(s ? s : n)) == 0) { pa_log("[%s:%u] Override map '%s' invalid in '%s'", state->filename, state->lineno, s ? s : n, state->section); pa_xfree(n); return -1; } } if (e->masks[channel_position][channel_count-1]) { pa_log("[%s:%u] Override map '%s' duplicate position '%s' in '%s'", state->filename, state->lineno, s ? s : n, snd_mixer_selem_channel_name(channel_position), state->section); pa_xfree(n); return -1; } e->override_map |= (1 << (channel_count - 1)); e->masks[channel_position][channel_count-1] = m; pa_xfree(n); i++; } return 0; } static int jack_parse_state(pa_config_parser_state *state) { pa_alsa_path *p; pa_alsa_jack *j; pa_available_t pa; pa_assert(state); p = state->userdata; if (!(j = jack_get(p, state->section))) { pa_log("[%s:%u] state makes no sense in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "yes")) pa = PA_AVAILABLE_YES; else if (pa_streq(state->rvalue, "no")) pa = PA_AVAILABLE_NO; else if (pa_streq(state->rvalue, "unknown")) pa = PA_AVAILABLE_UNKNOWN; else { pa_log("[%s:%u] state must be 'yes', 'no' or 'unknown' in '%s'", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->lvalue, "state.unplugged")) j->state_unplugged = pa; else { j->state_plugged = pa; pa_assert(pa_streq(state->lvalue, "state.plugged")); } return 0; } static int jack_parse_append_pcm_to_name(pa_config_parser_state *state) { pa_alsa_path *path; pa_alsa_jack *jack; int b; pa_assert(state); path = state->userdata; if (!(jack = jack_get(path, state->section))) { pa_log("[%s:%u] Option 'append_pcm_to_name' not expected in section '%s'", state->filename, state->lineno, state->section); return -1; } b = pa_parse_boolean(state->rvalue); if (b < 0) { pa_log("[%s:%u] Invalid value for 'append_pcm_to_name': %s", state->filename, state->lineno, state->rvalue); return -1; } jack->append_pcm_to_name = b; return 0; } static int element_set_option(pa_alsa_element *e, snd_mixer_t *m, int alsa_idx) { snd_mixer_selem_id_t *sid; snd_mixer_elem_t *me; char buf[64]; int r; pa_assert(e); pa_assert(m); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return -1; } if (e->switch_use == PA_ALSA_SWITCH_SELECT) { if (e->direction == PA_ALSA_DIRECTION_OUTPUT) r = snd_mixer_selem_set_playback_switch_all(me, alsa_idx); else r = snd_mixer_selem_set_capture_switch_all(me, alsa_idx); if (r < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to set switch of %s: %s", buf, pa_alsa_strerror(errno)); } } else { pa_assert(e->enumeration_use == PA_ALSA_ENUMERATION_SELECT); if ((r = snd_mixer_selem_set_enum_item(me, 0, alsa_idx)) < 0) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Failed to set enumeration of %s: %s", buf, pa_alsa_strerror(errno)); } } return r; } static int setting_select(pa_alsa_setting *s, snd_mixer_t *m) { pa_alsa_option *o; uint32_t idx; pa_assert(s); pa_assert(m); PA_IDXSET_FOREACH(o, s->options, idx) element_set_option(o->element, m, o->alsa_idx); return 0; } static int option_verify(pa_alsa_option *o) { static const struct description_map well_known_descriptions[] = { { "input", N_("Input") }, { "input-docking", N_("Docking Station Input") }, { "input-docking-microphone", N_("Docking Station Microphone") }, { "input-docking-linein", N_("Docking Station Line In") }, { "input-linein", N_("Line In") }, { "input-microphone", N_("Microphone") }, { "input-microphone-front", N_("Front Microphone") }, { "input-microphone-rear", N_("Rear Microphone") }, { "input-microphone-external", N_("External Microphone") }, { "input-microphone-internal", N_("Internal Microphone") }, { "input-radio", N_("Radio") }, { "input-video", N_("Video") }, { "input-agc-on", N_("Automatic Gain Control") }, { "input-agc-off", N_("No Automatic Gain Control") }, { "input-boost-on", N_("Boost") }, { "input-boost-off", N_("No Boost") }, { "output-amplifier-on", N_("Amplifier") }, { "output-amplifier-off", N_("No Amplifier") }, { "output-bass-boost-on", N_("Bass Boost") }, { "output-bass-boost-off", N_("No Bass Boost") }, { "output-speaker", N_("Speaker") }, { "output-headphones", N_("Headphones") } }; char buf[64]; pa_assert(o); if (!o->name) { pa_log("No name set for option %s", o->alsa_name); return -1; } if (o->element->enumeration_use != PA_ALSA_ENUMERATION_SELECT && o->element->switch_use != PA_ALSA_SWITCH_SELECT) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &o->element->alsa_id); pa_log("Element %s of option %s not set for select.", buf, o->name); return -1; } if (o->element->switch_use == PA_ALSA_SWITCH_SELECT && !pa_streq(o->alsa_name, "on") && !pa_streq(o->alsa_name, "off")) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &o->element->alsa_id); pa_log("Switch %s options need be named off or on ", buf); return -1; } if (!o->description) o->description = pa_xstrdup(lookup_description(o->name, well_known_descriptions, PA_ELEMENTSOF(well_known_descriptions))); if (!o->description) o->description = pa_xstrdup(o->name); return 0; } static int element_verify(pa_alsa_element *e) { pa_alsa_option *o; char buf[64]; pa_assert(e); // pa_log_debug("Element %s, path %s: r=%d, r-any=%d, r-abs=%d", e->alsa_name, e->path->name, e->required, e->required_any, e->required_absent); if ((e->required != PA_ALSA_REQUIRED_IGNORE && e->required == e->required_absent) || (e->required_any != PA_ALSA_REQUIRED_IGNORE && e->required_any == e->required_absent) || (e->required_absent == PA_ALSA_REQUIRED_ANY && e->required_any != PA_ALSA_REQUIRED_IGNORE) || (e->required_absent == PA_ALSA_REQUIRED_ANY && e->required != PA_ALSA_REQUIRED_IGNORE)) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log("Element %s cannot be required and absent at the same time.", buf); return -1; } if (e->switch_use == PA_ALSA_SWITCH_SELECT && e->enumeration_use == PA_ALSA_ENUMERATION_SELECT) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log("Element %s cannot set select for both switch and enumeration.", buf); return -1; } PA_LLIST_FOREACH(o, e->options) if (option_verify(o) < 0) return -1; return 0; } static int path_verify(pa_alsa_path *p) { static const struct description2_map well_known_descriptions[] = { { "analog-input", N_("Analog Input"), PA_DEVICE_PORT_TYPE_ANALOG }, { "analog-input-microphone", N_("Microphone"), PA_DEVICE_PORT_TYPE_MIC }, { "analog-input-microphone-front", N_("Front Microphone"), PA_DEVICE_PORT_TYPE_MIC }, { "analog-input-microphone-rear", N_("Rear Microphone"), PA_DEVICE_PORT_TYPE_MIC }, { "analog-input-microphone-dock", N_("Dock Microphone"), PA_DEVICE_PORT_TYPE_MIC }, { "analog-input-microphone-internal", N_("Internal Microphone"), PA_DEVICE_PORT_TYPE_MIC }, { "analog-input-microphone-headset", N_("Headset Microphone"), PA_DEVICE_PORT_TYPE_HEADSET }, { "analog-input-linein", N_("Line In"), PA_DEVICE_PORT_TYPE_LINE }, { "analog-input-radio", N_("Radio"), PA_DEVICE_PORT_TYPE_RADIO }, { "analog-input-video", N_("Video"), PA_DEVICE_PORT_TYPE_VIDEO }, { "analog-output", N_("Analog Output"), PA_DEVICE_PORT_TYPE_ANALOG }, { "analog-output-headphones", N_("Headphones"), PA_DEVICE_PORT_TYPE_HEADPHONES }, { "analog-output-headphones-2", N_("Headphones 2"), PA_DEVICE_PORT_TYPE_HEADPHONES }, { "analog-output-headphones-mono", N_("Headphones Mono Output"), PA_DEVICE_PORT_TYPE_HEADPHONES }, { "analog-output-lineout", N_("Line Out"), PA_DEVICE_PORT_TYPE_LINE }, { "analog-output-mono", N_("Analog Mono Output"), PA_DEVICE_PORT_TYPE_ANALOG }, { "analog-output-speaker", N_("Speakers"), PA_DEVICE_PORT_TYPE_SPEAKER }, { "hdmi-output", N_("HDMI / DisplayPort"), PA_DEVICE_PORT_TYPE_HDMI }, { "iec958-stereo-output", N_("Digital Output (S/PDIF)"), PA_DEVICE_PORT_TYPE_SPDIF }, { "iec958-stereo-input", N_("Digital Input (S/PDIF)"), PA_DEVICE_PORT_TYPE_SPDIF }, { "multichannel-input", N_("Multichannel Input"), PA_DEVICE_PORT_TYPE_LINE }, { "multichannel-output", N_("Multichannel Output"), PA_DEVICE_PORT_TYPE_LINE }, { "steelseries-arctis-output-game-common", N_("Game Output"), PA_DEVICE_PORT_TYPE_HEADSET }, { "steelseries-arctis-output-chat-common", N_("Chat Output"), PA_DEVICE_PORT_TYPE_HEADSET }, { "analog-chat-output", N_("Chat Output"), PA_DEVICE_PORT_TYPE_HEADSET }, { "analog-chat-input", N_("Chat Input"), PA_DEVICE_PORT_TYPE_HEADSET }, { "virtual-surround-7.1", N_("Virtual Surround 7.1"), PA_DEVICE_PORT_TYPE_HEADPHONES }, }; pa_alsa_element *e; const char *key = p->description_key ? p->description_key : p->name; const struct description2_map *map = lookup_description2(key, well_known_descriptions, PA_ELEMENTSOF(well_known_descriptions)); pa_assert(p); PA_LLIST_FOREACH(e, p->elements) if (element_verify(e) < 0) return -1; if (map) { if (p->device_port_type == PA_DEVICE_PORT_TYPE_UNKNOWN) p->device_port_type = map->type; if (!p->description) p->description = pa_xstrdup(_(map->description)); } if (!p->description) { if (p->description_key) pa_log_warn("Path %s: Unrecognized description key: %s", p->name, p->description_key); p->description = pa_xstrdup(p->name); } return 0; } static const char *get_default_paths_dir(void) { const char *str; #ifdef HAVE_RUNNING_FROM_BUILD_TREE if (pa_run_from_build_tree()) return PA_SRCDIR "mixer/paths"; else #endif if (getenv("ACP_BUILDDIR") != NULL) return "mixer/paths"; if ((str = getenv("ACP_PATHS_DIR")) != NULL) return str; return PA_ALSA_PATHS_DIR; } pa_alsa_path* pa_alsa_path_new(const char *paths_dir, const char *fname, pa_alsa_direction_t direction) { pa_alsa_path *p; char *fn; int r; const char *n; bool mute_during_activation = false; pa_config_item items[] = { /* [General] */ { "priority", pa_config_parse_unsigned, NULL, "General" }, { "description-key", pa_config_parse_string, NULL, "General" }, { "description", pa_config_parse_string, NULL, "General" }, { "mute-during-activation", pa_config_parse_bool, NULL, "General" }, { "type", parse_type, NULL, "General" }, { "eld-device", parse_eld_device, NULL, "General" }, /* [Option ...] */ { "priority", option_parse_priority, NULL, NULL }, { "name", option_parse_name, NULL, NULL }, /* [Jack ...] */ { "state.plugged", jack_parse_state, NULL, NULL }, { "state.unplugged", jack_parse_state, NULL, NULL }, { "append-pcm-to-name", jack_parse_append_pcm_to_name, NULL, NULL }, /* [Element ...] */ { "switch", element_parse_switch, NULL, NULL }, { "volume", element_parse_volume, NULL, NULL }, { "enumeration", element_parse_enumeration, NULL, NULL }, { "override-map.1", element_parse_override_map, NULL, NULL }, { "override-map.2", element_parse_override_map, NULL, NULL }, { "override-map.3", element_parse_override_map, NULL, NULL }, { "override-map.4", element_parse_override_map, NULL, NULL }, { "override-map.5", element_parse_override_map, NULL, NULL }, { "override-map.6", element_parse_override_map, NULL, NULL }, { "override-map.7", element_parse_override_map, NULL, NULL }, { "override-map.8", element_parse_override_map, NULL, NULL }, #if POSITION_MASK_CHANNELS > 8 #error "Add override-map.9+ definitions" #endif /* ... later on we might add override-map.3 and so on here ... */ { "required", element_parse_required, NULL, NULL }, { "required-any", element_parse_required, NULL, NULL }, { "required-absent", element_parse_required, NULL, NULL }, { "direction", element_parse_direction, NULL, NULL }, { "direction-try-other", element_parse_direction_try_other, NULL, NULL }, { "volume-limit", element_parse_volume_limit, NULL, NULL }, { NULL, NULL, NULL, NULL } }; pa_assert(fname); p = pa_xnew0(pa_alsa_path, 1); n = pa_path_get_filename(fname); p->name = pa_xstrndup(n, strcspn(n, ".")); p->proplist = pa_proplist_new(); p->direction = direction; p->eld_device = -1; items[0].data = &p->priority; items[1].data = &p->description_key; items[2].data = &p->description; items[3].data = &mute_during_activation; if (!paths_dir) paths_dir = get_default_paths_dir(); fn = pa_maybe_prefix_path(fname, paths_dir); r = pa_config_parse(fn, NULL, items, p->proplist, false, p); pa_xfree(fn); if (r < 0) goto fail; p->mute_during_activation = mute_during_activation; if (path_verify(p) < 0) goto fail; if (p->description) { char *tmp = p->description; p->description = pa_xstrdup(_(tmp)); free(tmp); } return p; fail: pa_alsa_path_free(p); return NULL; } pa_alsa_path *pa_alsa_path_synthesize(const char *element, pa_alsa_direction_t direction) { pa_alsa_path *p; pa_alsa_element *e; char *name; int index; pa_assert(element); name = alloca(strlen(element) + 1); if (alsa_id_decode(element, name, &index)) return NULL; p = pa_xnew0(pa_alsa_path, 1); p->name = pa_xstrdup(element); p->direction = direction; p->proplist = pa_proplist_new(); e = pa_xnew0(pa_alsa_element, 1); e->path = p; e->alsa_id.name = pa_xstrdup(name); e->alsa_id.index = index; e->direction = direction; e->volume_limit = -1; e->switch_use = PA_ALSA_SWITCH_MUTE; e->volume_use = PA_ALSA_VOLUME_MERGE; PA_LLIST_PREPEND(pa_alsa_element, p->elements, e); p->last_element = e; return p; } static bool element_drop_unsupported(pa_alsa_element *e) { pa_alsa_option *o, *n; pa_assert(e); for (o = e->options; o; o = n) { n = o->next; if (o->alsa_idx < 0) { PA_LLIST_REMOVE(pa_alsa_option, e->options, o); option_free(o); } } return e->switch_use != PA_ALSA_SWITCH_IGNORE || e->volume_use != PA_ALSA_VOLUME_IGNORE || e->enumeration_use != PA_ALSA_ENUMERATION_IGNORE; } static void path_drop_unsupported(pa_alsa_path *p) { pa_alsa_element *e, *n; pa_assert(p); for (e = p->elements; e; e = n) { n = e->next; if (!element_drop_unsupported(e)) { PA_LLIST_REMOVE(pa_alsa_element, p->elements, e); element_free(e); } } } static void path_make_options_unique(pa_alsa_path *p) { pa_alsa_element *e; pa_alsa_option *o, *u; PA_LLIST_FOREACH(e, p->elements) { PA_LLIST_FOREACH(o, e->options) { unsigned i; char *m; for (u = o->next; u; u = u->next) if (pa_streq(u->name, o->name)) break; if (!u) continue; m = pa_xstrdup(o->name); /* OK, this name is not unique, hence let's rename */ for (i = 1, u = o; u; u = u->next) { char *nn, *nd; if (!pa_streq(u->name, m)) continue; nn = pa_sprintf_malloc("%s-%u", m, i); pa_xfree(u->name); u->name = nn; nd = pa_sprintf_malloc("%s %u", u->description, i); pa_xfree(u->description); u->description = nd; i++; } pa_xfree(m); } } } static bool element_create_settings(pa_alsa_element *e, pa_alsa_setting *template) { pa_alsa_option *o; for (; e; e = e->next) if (e->switch_use == PA_ALSA_SWITCH_SELECT || e->enumeration_use == PA_ALSA_ENUMERATION_SELECT) break; if (!e) return false; for (o = e->options; o; o = o->next) { pa_alsa_setting *s; if (template) { s = pa_xnewdup(pa_alsa_setting, template, 1); s->options = pa_idxset_copy(template->options, NULL); s->name = pa_sprintf_malloc("%s+%s", template->name, o->name); s->description = (template->description[0] && o->description[0]) ? pa_sprintf_malloc("%s / %s", template->description, o->description) : (template->description[0] ? pa_xstrdup(template->description) : pa_xstrdup(o->description)); s->priority = PA_MAX(template->priority, o->priority); } else { s = pa_xnew0(pa_alsa_setting, 1); s->options = pa_idxset_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); s->name = pa_xstrdup(o->name); s->description = pa_xstrdup(o->description); s->priority = o->priority; } pa_idxset_put(s->options, o, NULL); if (element_create_settings(e->next, s)) /* This is not a leaf, so let's get rid of it */ setting_free(s); else { /* This is a leaf, so let's add it */ PA_LLIST_INSERT_AFTER(pa_alsa_setting, e->path->settings, e->path->last_setting, s); e->path->last_setting = s; } } return true; } static void path_create_settings(pa_alsa_path *p) { pa_assert(p); element_create_settings(p->elements, NULL); } int pa_alsa_path_probe(pa_alsa_path *p, pa_alsa_mapping *mapping, snd_mixer_t *m, bool ignore_dB) { pa_alsa_element *e; pa_alsa_jack *j; double min_dB[PA_CHANNEL_POSITION_MAX], max_dB[PA_CHANNEL_POSITION_MAX]; pa_channel_position_t t; pa_channel_position_mask_t path_volume_channels = 0; bool min_dB_set, max_dB_set; char buf[64]; pa_assert(p); pa_assert(m); if (p->probed) return p->supported ? 0 : -1; p->probed = true; pa_zero(min_dB); pa_zero(max_dB); pa_log_debug("Probing path '%s'", p->name); PA_LLIST_FOREACH(j, p->jacks) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &j->alsa_id); if (jack_probe(j, mapping, m) < 0) { p->supported = false; pa_log_debug("Probe of jack %s failed.", buf); return -1; } pa_log_debug("Probe of jack %s succeeded (%s)", buf, j->has_control ? "found!" : "not found"); } PA_LLIST_FOREACH(e, p->elements) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); if (element_probe(e, m) < 0) { p->supported = false; pa_log_debug("Probe of element %s failed.", buf); return -1; } pa_log_debug("Probe of element %s succeeded (volume=%d, switch=%d, enumeration=%d, has_dB=%d).", buf, e->volume_use, e->switch_use, e->enumeration_use, e->has_dB); if (ignore_dB) e->has_dB = false; if (e->volume_use == PA_ALSA_VOLUME_MERGE) { if (!p->has_volume) { p->min_volume = e->min_volume; p->max_volume = e->max_volume; } if (e->has_dB) { if (!p->has_volume) { for (t = 0; t < PA_CHANNEL_POSITION_MAX; t++) if (PA_CHANNEL_POSITION_MASK(t) & e->merged_mask) { min_dB[t] = e->min_dB; max_dB[t] = e->max_dB; path_volume_channels |= PA_CHANNEL_POSITION_MASK(t); } p->has_dB = true; } else { if (p->has_dB) { for (t = 0; t < PA_CHANNEL_POSITION_MAX; t++) if (PA_CHANNEL_POSITION_MASK(t) & e->merged_mask) { min_dB[t] += e->min_dB; max_dB[t] += e->max_dB; path_volume_channels |= PA_CHANNEL_POSITION_MASK(t); } } else { /* Hmm, there's another element before us * which cannot do dB volumes, so we we need * to 'neutralize' this slider */ e->volume_use = PA_ALSA_VOLUME_ZERO; pa_log_info("Zeroing volume of %s on path '%s'", buf, p->name); } } } else if (p->has_volume) { /* We can't use this volume, so let's ignore it */ e->volume_use = PA_ALSA_VOLUME_IGNORE; pa_log_info("Ignoring volume of %s on path '%s' (missing dB info)", buf, p->name); } p->has_volume = true; } if (e->switch_use == PA_ALSA_SWITCH_MUTE) p->has_mute = true; } if (p->has_req_any && !p->req_any_present) { p->supported = false; pa_log_debug("Skipping path '%s', none of required-any elements preset.", p->name); return -1; } path_drop_unsupported(p); path_make_options_unique(p); path_create_settings(p); p->supported = true; p->min_dB = INFINITY; min_dB_set = false; p->max_dB = -INFINITY; max_dB_set = false; for (t = 0; t < PA_CHANNEL_POSITION_MAX; t++) { if (path_volume_channels & PA_CHANNEL_POSITION_MASK(t)) { if (p->min_dB > min_dB[t]) { p->min_dB = min_dB[t]; min_dB_set = true; } if (p->max_dB < max_dB[t]) { p->max_dB = max_dB[t]; max_dB_set = true; } } } /* this is probably a wrong prediction, but it should be safe */ if (!min_dB_set) p->min_dB = -INFINITY; if (!max_dB_set) p->max_dB = 0; return 0; } void pa_alsa_setting_dump(pa_alsa_setting *s) { pa_assert(s); pa_log_debug("Setting %s (%s) priority=%u", s->name, pa_strnull(s->description), s->priority); } void pa_alsa_jack_dump(pa_alsa_jack *j) { pa_assert(j); pa_log_debug("Jack %s, alsa_name='%s', index='%d', detection %s", j->name, j->alsa_id.name, j->alsa_id.index, j->has_control ? "possible" : "unavailable"); } void pa_alsa_option_dump(pa_alsa_option *o) { pa_assert(o); pa_log_debug("Option %s (%s/%s) index=%i, priority=%u", o->alsa_name, pa_strnull(o->name), pa_strnull(o->description), o->alsa_idx, o->priority); } void pa_alsa_element_dump(pa_alsa_element *e) { char buf[64]; pa_alsa_option *o; pa_assert(e); pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_debug("Element %s, direction=%i, switch=%i, volume=%i, volume_limit=%li, enumeration=%i, required=%i, required_any=%i, required_absent=%i, mask=0x%llx, n_channels=%u, override_map=%02x", buf, e->direction, e->switch_use, e->volume_use, e->volume_limit, e->enumeration_use, e->required, e->required_any, e->required_absent, (long long unsigned) e->merged_mask, e->n_channels, e->override_map); PA_LLIST_FOREACH(o, e->options) pa_alsa_option_dump(o); } void pa_alsa_path_dump(pa_alsa_path *p) { pa_alsa_element *e; pa_alsa_jack *j; pa_alsa_setting *s; pa_assert(p); pa_log_debug("Path %s (%s), direction=%i, priority=%u, probed=%s, supported=%s, has_mute=%s, has_volume=%s, " "has_dB=%s, min_volume=%li, max_volume=%li, min_dB=%g, max_dB=%g", p->name, pa_strnull(p->description), p->direction, p->priority, pa_yes_no(p->probed), pa_yes_no(p->supported), pa_yes_no(p->has_mute), pa_yes_no(p->has_volume), pa_yes_no(p->has_dB), p->min_volume, p->max_volume, p->min_dB, p->max_dB); PA_LLIST_FOREACH(e, p->elements) pa_alsa_element_dump(e); PA_LLIST_FOREACH(j, p->jacks) pa_alsa_jack_dump(j); PA_LLIST_FOREACH(s, p->settings) pa_alsa_setting_dump(s); } static void element_set_callback(pa_alsa_element *e, snd_mixer_t *m, snd_mixer_elem_callback_t cb, void *userdata) { snd_mixer_selem_id_t *sid; snd_mixer_elem_t *me; char buf[64]; pa_assert(e); pa_assert(m); pa_assert(cb); SELEM_INIT(sid, &e->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &e->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return; } snd_mixer_elem_set_callback(me, cb); snd_mixer_elem_set_callback_private(me, userdata); } void pa_alsa_path_set_callback(pa_alsa_path *p, snd_mixer_t *m, snd_mixer_elem_callback_t cb, void *userdata) { pa_alsa_element *e; pa_assert(p); pa_assert(m); pa_assert(cb); PA_LLIST_FOREACH(e, p->elements) element_set_callback(e, m, cb, userdata); } void pa_alsa_path_set_set_callback(pa_alsa_path_set *ps, snd_mixer_t *m, snd_mixer_elem_callback_t cb, void *userdata) { pa_alsa_path *p; void *state; pa_assert(ps); pa_assert(m); pa_assert(cb); PA_HASHMAP_FOREACH(p, ps->paths, state) pa_alsa_path_set_callback(p, m, cb, userdata); } static pa_alsa_path *profile_set_get_path(pa_alsa_profile_set *ps, const char *path_name) { pa_alsa_path *path; pa_assert(ps); pa_assert(path_name); if ((path = pa_hashmap_get(ps->output_paths, path_name))) return path; return pa_hashmap_get(ps->input_paths, path_name); } static void profile_set_add_path(pa_alsa_profile_set *ps, pa_alsa_path *path) { pa_assert(ps); pa_assert(path); switch (path->direction) { case PA_ALSA_DIRECTION_OUTPUT: pa_assert_se(pa_hashmap_put(ps->output_paths, path->name, path) >= 0); break; case PA_ALSA_DIRECTION_INPUT: pa_assert_se(pa_hashmap_put(ps->input_paths, path->name, path) >= 0); break; default: pa_assert_not_reached(); } } pa_alsa_path_set *pa_alsa_path_set_new(pa_alsa_mapping *m, pa_alsa_direction_t direction, const char *paths_dir) { pa_alsa_path_set *ps; char **pn = NULL, **en = NULL, **ie; pa_alsa_decibel_fix *db_fix; void *state, *state2; char name[64]; int index; pa_assert(m); pa_assert(m->profile_set); pa_assert(m->profile_set->decibel_fixes); pa_assert(direction == PA_ALSA_DIRECTION_OUTPUT || direction == PA_ALSA_DIRECTION_INPUT); if (m->direction != PA_ALSA_DIRECTION_ANY && m->direction != direction) return NULL; ps = pa_xnew0(pa_alsa_path_set, 1); ps->direction = direction; ps->paths = pa_hashmap_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); if (direction == PA_ALSA_DIRECTION_OUTPUT) pn = m->output_path_names; else pn = m->input_path_names; if (pn) { char **in; for (in = pn; *in; in++) { pa_alsa_path *p = NULL; bool duplicate = false; char **kn; for (kn = pn; kn < in; kn++) if (pa_streq(*kn, *in)) { duplicate = true; break; } if (duplicate) continue; p = profile_set_get_path(m->profile_set, *in); if (p && p->direction != direction) { pa_log("Configuration error: Path %s is used both as an input and as an output path.", p->name); goto fail; } if (!p) { char *fn = pa_sprintf_malloc("%s.conf", *in); p = pa_alsa_path_new(paths_dir, fn, direction); pa_xfree(fn); if (p) profile_set_add_path(m->profile_set, p); } if (p) pa_hashmap_put(ps->paths, p, p); } goto finish; } if (direction == PA_ALSA_DIRECTION_OUTPUT) en = m->output_element; else en = m->input_element; if (!en) goto fail; for (ie = en; *ie; ie++) { char **je; pa_alsa_path *p; p = pa_alsa_path_synthesize(*ie, direction); /* Mark all other passed elements for require-absent */ for (je = en; *je; je++) { pa_alsa_element *e; if (je == ie) continue; if (strlen(*je) + 1 >= sizeof(name)) { pa_log("Element identifier %s is too long!", *je); continue; } if (alsa_id_decode(*je, name, &index)) continue; e = pa_xnew0(pa_alsa_element, 1); e->path = p; e->alsa_id.name = pa_xstrdup(name); e->alsa_id.index = index; e->direction = direction; e->required_absent = PA_ALSA_REQUIRED_ANY; e->volume_limit = -1; PA_LLIST_INSERT_AFTER(pa_alsa_element, p->elements, p->last_element, e); p->last_element = e; } pa_hashmap_put(ps->paths, *ie, p); } finish: /* Assign decibel fixes to elements. */ PA_HASHMAP_FOREACH(db_fix, m->profile_set->decibel_fixes, state) { pa_alsa_path *p; PA_HASHMAP_FOREACH(p, ps->paths, state2) { pa_alsa_element *e; PA_LLIST_FOREACH(e, p->elements) { if (e->volume_use != PA_ALSA_VOLUME_IGNORE && pa_streq(db_fix->name, e->alsa_id.name) && db_fix->index == e->alsa_id.index) { /* The profile set that contains the dB fix may be freed * before the element, so we have to copy the dB fix * object. */ e->db_fix = pa_xnewdup(pa_alsa_decibel_fix, db_fix, 1); e->db_fix->profile_set = NULL; e->db_fix->key = pa_xstrdup(db_fix->key); e->db_fix->name = pa_xstrdup(db_fix->name); e->db_fix->db_values = pa_xmemdup(db_fix->db_values, (db_fix->max_step - db_fix->min_step + 1) * sizeof(long)); } } } } return ps; fail: if (ps) pa_alsa_path_set_free(ps); return NULL; } void pa_alsa_path_set_dump(pa_alsa_path_set *ps) { pa_alsa_path *p; void *state; pa_assert(ps); pa_log_debug("Path Set %p, direction=%i", (void*) ps, ps->direction); PA_HASHMAP_FOREACH(p, ps->paths, state) pa_alsa_path_dump(p); } static bool options_have_option(pa_alsa_option *options, const char *alsa_name) { pa_alsa_option *o; pa_assert(options); pa_assert(alsa_name); PA_LLIST_FOREACH(o, options) { if (pa_streq(o->alsa_name, alsa_name)) return true; } return false; } static bool enumeration_is_subset(pa_alsa_option *a_options, pa_alsa_option *b_options) { pa_alsa_option *oa, *ob; if (!a_options) return true; if (!b_options) return false; /* If there is an option A offers that B does not, then A is not a subset of B. */ PA_LLIST_FOREACH(oa, a_options) { bool found = false; PA_LLIST_FOREACH(ob, b_options) { if (pa_streq(oa->alsa_name, ob->alsa_name)) { found = true; break; } } if (!found) return false; } return true; } /** * Compares two elements to see if a is a subset of b */ static bool element_is_subset(pa_alsa_element *a, pa_alsa_element *b, snd_mixer_t *m) { char buf[64]; pa_assert(a); pa_assert(b); pa_assert(m); /* General rules: * Every state is a subset of itself (with caveats for volume_limits and options) * IGNORE is a subset of every other state */ /* Check the volume_use */ if (a->volume_use != PA_ALSA_VOLUME_IGNORE) { /* "Constant" is subset of "Constant" only when their constant values are equal */ if (a->volume_use == PA_ALSA_VOLUME_CONSTANT && b->volume_use == PA_ALSA_VOLUME_CONSTANT && a->constant_volume != b->constant_volume) return false; /* Different volume uses when b is not "Merge" means we are definitely not a subset */ if (a->volume_use != b->volume_use && b->volume_use != PA_ALSA_VOLUME_MERGE) return false; /* "Constant" is a subset of "Merge", if there is not a "volume-limit" in "Merge" below the actual constant. * "Zero" and "Off" are just special cases of "Constant" when comparing to "Merge" * "Merge" with a "volume-limit" is a subset of "Merge" without a "volume-limit" or with a higher "volume-limit" */ if (b->volume_use == PA_ALSA_VOLUME_MERGE && b->volume_limit >= 0) { long a_limit; if (a->volume_use == PA_ALSA_VOLUME_CONSTANT) a_limit = a->constant_volume; else if (a->volume_use == PA_ALSA_VOLUME_ZERO) { long dB = 0; if (a->db_fix) { int rounding = (a->direction == PA_ALSA_DIRECTION_OUTPUT ? +1 : -1); a_limit = decibel_fix_get_step(a->db_fix, &dB, rounding); } else { snd_mixer_selem_id_t *sid; snd_mixer_elem_t *me; SELEM_INIT(sid, &a->alsa_id); if (!(me = snd_mixer_find_selem(m, sid))) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &a->alsa_id); pa_log_warn("Element %s seems to have disappeared.", buf); return false; } if (a->direction == PA_ALSA_DIRECTION_OUTPUT) { if (snd_mixer_selem_ask_playback_dB_vol(me, dB, +1, &a_limit) < 0) return false; } else { if (snd_mixer_selem_ask_capture_dB_vol(me, dB, -1, &a_limit) < 0) return false; } } } else if (a->volume_use == PA_ALSA_VOLUME_OFF) a_limit = a->min_volume; else if (a->volume_use == PA_ALSA_VOLUME_MERGE) a_limit = a->volume_limit; else pa_assert_not_reached(); if (a_limit > b->volume_limit) return false; } if (a->volume_use == PA_ALSA_VOLUME_MERGE) { int s; /* If override-maps are different, they're not subsets */ if (a->n_channels != b->n_channels) return false; for (s = 0; s <= SND_MIXER_SCHN_LAST; s++) if (a->masks[s][a->n_channels-1] != b->masks[s][b->n_channels-1]) { pa_alsa_mixer_id_to_string(buf, sizeof(buf), &a->alsa_id); pa_log_debug("Element %s is not a subset - mask a: 0x%" PRIx64 ", mask b: 0x%" PRIx64 ", at channel %d", buf, a->masks[s][a->n_channels-1], b->masks[s][b->n_channels-1], s); return false; } } } if (a->switch_use != PA_ALSA_SWITCH_IGNORE) { /* "On" is a subset of "Mute". * "Off" is a subset of "Mute". * "On" is a subset of "Select", if there is an "Option:On" in B. * "Off" is a subset of "Select", if there is an "Option:Off" in B. * "Select" is a subset of "Select", if they have the same options (is this always true?). */ if (a->switch_use != b->switch_use) { if (a->switch_use == PA_ALSA_SWITCH_SELECT || a->switch_use == PA_ALSA_SWITCH_MUTE || b->switch_use == PA_ALSA_SWITCH_OFF || b->switch_use == PA_ALSA_SWITCH_ON) return false; if (b->switch_use == PA_ALSA_SWITCH_SELECT) { if (a->switch_use == PA_ALSA_SWITCH_ON) { if (!options_have_option(b->options, "on")) return false; } else if (a->switch_use == PA_ALSA_SWITCH_OFF) { if (!options_have_option(b->options, "off")) return false; } } } else if (a->switch_use == PA_ALSA_SWITCH_SELECT) { if (!enumeration_is_subset(a->options, b->options)) return false; } } if (a->enumeration_use != PA_ALSA_ENUMERATION_IGNORE) { if (b->enumeration_use == PA_ALSA_ENUMERATION_IGNORE) return false; if (!enumeration_is_subset(a->options, b->options)) return false; } return true; } static void path_set_condense(pa_alsa_path_set *ps, snd_mixer_t *m) { pa_alsa_path *p; void *state; pa_assert(ps); pa_assert(m); /* If we only have one path, then don't bother */ if (pa_hashmap_size(ps->paths) < 2) return; PA_HASHMAP_FOREACH(p, ps->paths, state) { pa_alsa_path *p2; void *state2; PA_HASHMAP_FOREACH(p2, ps->paths, state2) { pa_alsa_element *ea, *eb; pa_alsa_jack *ja, *jb; bool is_subset = true; if (p == p2) continue; /* If a has a jack that b does not have, a is not a subset */ PA_LLIST_FOREACH(ja, p->jacks) { bool exists = false; if (!ja->has_control) continue; PA_LLIST_FOREACH(jb, p2->jacks) { if (jb->has_control && pa_streq(ja->alsa_id.name, jb->alsa_id.name) && (ja->alsa_id.index == jb->alsa_id.index) && (ja->state_plugged == jb->state_plugged) && (ja->state_unplugged == jb->state_unplugged)) { exists = true; break; } } if (!exists) { is_subset = false; break; } } /* Compare the elements of each set... */ PA_LLIST_FOREACH(ea, p->elements) { bool found_matching_element = false; if (!is_subset) break; PA_LLIST_FOREACH(eb, p2->elements) { if (pa_streq(ea->alsa_id.name, eb->alsa_id.name) && ea->alsa_id.index == eb->alsa_id.index) { found_matching_element = true; is_subset = element_is_subset(ea, eb, m); break; } } if (!found_matching_element) is_subset = false; } if (is_subset) { pa_log_debug("Removing path '%s' as it is a subset of '%s'.", p->name, p2->name); pa_hashmap_remove(ps->paths, p); break; } } } } static pa_alsa_path* path_set_find_path_by_description(pa_alsa_path_set *ps, const char* description, pa_alsa_path *ignore) { pa_alsa_path* p; void *state; PA_HASHMAP_FOREACH(p, ps->paths, state) if (p != ignore && pa_streq(p->description, description)) return p; return NULL; } static void path_set_make_path_descriptions_unique(pa_alsa_path_set *ps) { pa_alsa_path *p, *q; void *state, *state2; PA_HASHMAP_FOREACH(p, ps->paths, state) { unsigned i; char *old_description; q = path_set_find_path_by_description(ps, p->description, p); if (!q) continue; old_description = pa_xstrdup(p->description); /* OK, this description is not unique, hence let's rename */ i = 1; PA_HASHMAP_FOREACH(q, ps->paths, state2) { char *new_description; if (!pa_streq(q->description, old_description)) continue; new_description = pa_sprintf_malloc("%s %u", q->description, i); pa_xfree(q->description); q->description = new_description; i++; } pa_xfree(old_description); } } void pa_alsa_mapping_free(pa_alsa_mapping *m) { pa_assert(m); pa_xfree(m->name); pa_xfree(m->description); pa_xfree(m->description_key); pa_proplist_free(m->proplist); pa_xstrfreev(m->device_strings); pa_xstrfreev(m->input_path_names); pa_xstrfreev(m->output_path_names); pa_xstrfreev(m->input_element); pa_xstrfreev(m->output_element); if (m->input_path_set) pa_alsa_path_set_free(m->input_path_set); if (m->output_path_set) pa_alsa_path_set_free(m->output_path_set); pa_proplist_free(m->input_proplist); pa_proplist_free(m->output_proplist); pa_assert(!m->input_pcm); pa_assert(!m->output_pcm); pa_alsa_ucm_mapping_context_free(&m->ucm_context); pa_xfree(m); } void pa_alsa_profile_free(pa_alsa_profile *p) { pa_assert(p); pa_xfree(p->name); pa_xfree(p->description); pa_xfree(p->description_key); pa_xfree(p->input_name); pa_xfree(p->output_name); pa_xstrfreev(p->input_mapping_names); pa_xstrfreev(p->output_mapping_names); if (p->input_mappings) pa_idxset_free(p->input_mappings, NULL); if (p->output_mappings) pa_idxset_free(p->output_mappings, NULL); pa_xfree(p); } void pa_alsa_profile_set_free(pa_alsa_profile_set *ps) { pa_assert(ps); if (ps->input_paths) pa_hashmap_free(ps->input_paths); if (ps->output_paths) pa_hashmap_free(ps->output_paths); if (ps->profiles) pa_hashmap_free(ps->profiles); if (ps->mappings) pa_hashmap_free(ps->mappings); if (ps->decibel_fixes) pa_hashmap_free(ps->decibel_fixes); pa_xfree(ps); } pa_alsa_mapping *pa_alsa_mapping_get(pa_alsa_profile_set *ps, const char *name) { pa_alsa_mapping *m; if (!pa_startswith(name, "Mapping ")) return NULL; name += 8; if ((m = pa_hashmap_get(ps->mappings, name))) return m; m = pa_xnew0(pa_alsa_mapping, 1); m->profile_set = ps; m->exact_channels = true; m->name = pa_xstrdup(name); pa_sample_spec_init(&m->sample_spec); pa_channel_map_init(&m->channel_map); m->proplist = pa_proplist_new(); m->hw_device_index = -1; m->input_proplist = pa_proplist_new(); m->output_proplist = pa_proplist_new(); pa_hashmap_put(ps->mappings, m->name, m); return m; } static pa_alsa_profile *profile_get(pa_alsa_profile_set *ps, const char *name) { pa_alsa_profile *p; if (!pa_startswith(name, "Profile ")) return NULL; name += 8; if ((p = pa_hashmap_get(ps->profiles, name))) return p; p = pa_xnew0(pa_alsa_profile, 1); p->profile_set = ps; p->name = pa_xstrdup(name); pa_hashmap_put(ps->profiles, p->name, p); return p; } static pa_alsa_decibel_fix *decibel_fix_get(pa_alsa_profile_set *ps, const char *alsa_id) { pa_alsa_decibel_fix *db_fix; char *name; int index; if (!pa_startswith(alsa_id, "DecibelFix ")) return NULL; alsa_id += 11; if ((db_fix = pa_hashmap_get(ps->decibel_fixes, alsa_id))) return db_fix; name = alloca(strlen(alsa_id) + 1); if (alsa_id_decode(alsa_id, name, &index)) return NULL; db_fix = pa_xnew0(pa_alsa_decibel_fix, 1); db_fix->profile_set = ps; db_fix->name = pa_xstrdup(name); db_fix->index = index; db_fix->key = pa_xstrdup(alsa_id); pa_hashmap_put(ps->decibel_fixes, db_fix->key, db_fix); return db_fix; } static int mapping_parse_device_strings(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } pa_xstrfreev(m->device_strings); if (!(m->device_strings = pa_split_spaces_strv(state->rvalue))) { pa_log("[%s:%u] Device string list empty of '%s'", state->filename, state->lineno, state->section); return -1; } return 0; } static int mapping_parse_channel_map(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if (!(pa_channel_map_parse(&m->channel_map, state->rvalue))) { pa_log("[%s:%u] Channel map invalid of '%s'", state->filename, state->lineno, state->section); return -1; } return 0; } static int mapping_parse_paths(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if (pa_streq(state->lvalue, "paths-input")) { pa_xstrfreev(m->input_path_names); m->input_path_names = pa_split_spaces_strv(state->rvalue); } else { pa_xstrfreev(m->output_path_names); m->output_path_names = pa_split_spaces_strv(state->rvalue); } return 0; } static int mapping_parse_exact_channels(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; int b; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if ((b = pa_parse_boolean(state->rvalue)) < 0) { pa_log("[%s:%u] %s has invalid value '%s'", state->filename, state->lineno, state->lvalue, state->section); return -1; } m->exact_channels = b; return 0; } static int mapping_parse_element(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if (pa_streq(state->lvalue, "element-input")) { pa_xstrfreev(m->input_element); m->input_element = pa_split_spaces_strv(state->rvalue); } else { pa_xstrfreev(m->output_element); m->output_element = pa_split_spaces_strv(state->rvalue); } return 0; } static int mapping_parse_direction(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] Section name %s invalid.", state->filename, state->lineno, state->section); return -1; } if (pa_streq(state->rvalue, "input")) m->direction = PA_ALSA_DIRECTION_INPUT; else if (pa_streq(state->rvalue, "output")) m->direction = PA_ALSA_DIRECTION_OUTPUT; else if (pa_streq(state->rvalue, "any")) m->direction = PA_ALSA_DIRECTION_ANY; else { pa_log("[%s:%u] Direction %s invalid.", state->filename, state->lineno, state->rvalue); return -1; } return 0; } static int mapping_parse_description(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_profile *p; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if ((m = pa_alsa_mapping_get(ps, state->section))) { pa_xfree(m->description); m->description = pa_xstrdup(_(state->rvalue)); } else if ((p = profile_get(ps, state->section))) { pa_xfree(p->description); p->description = pa_xstrdup(_(state->rvalue)); } else { pa_log("[%s:%u] Section name %s invalid.", state->filename, state->lineno, state->section); return -1; } return 0; } static int mapping_parse_description_key(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_profile *p; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if ((m = pa_alsa_mapping_get(ps, state->section))) { pa_xfree(m->description_key); m->description_key = pa_xstrdup(state->rvalue); } else if ((p = profile_get(ps, state->section))) { pa_xfree(p->description_key); p->description_key = pa_xstrdup(state->rvalue); } else { pa_log("[%s:%u] Section name %s invalid.", state->filename, state->lineno, state->section); return -1; } return 0; } static int mapping_parse_priority(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_profile *p; pa_alsa_mapping *m; uint32_t prio; pa_assert(state); ps = state->userdata; if (pa_atou(state->rvalue, &prio) < 0) { pa_log("[%s:%u] Priority invalid of '%s'", state->filename, state->lineno, state->section); return -1; } if ((m = pa_alsa_mapping_get(ps, state->section))) m->priority = prio; else if ((p = profile_get(ps, state->section))) p->priority = prio; else { pa_log("[%s:%u] Section name %s invalid.", state->filename, state->lineno, state->section); return -1; } return 0; } static int mapping_parse_fallback(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_profile *p; pa_alsa_mapping *m; int k; pa_assert(state); ps = state->userdata; if ((k = pa_parse_boolean(state->rvalue)) < 0) { pa_log("[%s:%u] Fallback invalid of '%s'", state->filename, state->lineno, state->section); return -1; } if ((m = pa_alsa_mapping_get(ps, state->section))) m->fallback = k; else if ((p = profile_get(ps, state->section))) p->fallback_input = p->fallback_output = k; else { pa_log("[%s:%u] Section name %s invalid.", state->filename, state->lineno, state->section); return -1; } return 0; } static int mapping_parse_intended_roles(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_mapping *m; pa_assert(state); ps = state->userdata; if (!(m = pa_alsa_mapping_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } pa_proplist_sets(m->proplist, PA_PROP_DEVICE_INTENDED_ROLES, state->rvalue); return 0; } static int profile_parse_mappings(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_profile *p; pa_assert(state); ps = state->userdata; if (!(p = profile_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if (pa_streq(state->lvalue, "input-mappings")) { pa_xstrfreev(p->input_mapping_names); p->input_mapping_names = pa_split_spaces_strv(state->rvalue); } else { pa_xstrfreev(p->output_mapping_names); p->output_mapping_names = pa_split_spaces_strv(state->rvalue); } return 0; } static int profile_parse_skip_probe(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_profile *p; int b; pa_assert(state); ps = state->userdata; if (!(p = profile_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if ((b = pa_parse_boolean(state->rvalue)) < 0) { pa_log("[%s:%u] Skip probe invalid of '%s'", state->filename, state->lineno, state->section); return -1; } p->supported = b; return 0; } static int decibel_fix_parse_db_values(pa_config_parser_state *state) { pa_alsa_profile_set *ps; pa_alsa_decibel_fix *db_fix; char **items; char *item; long *db_values; unsigned n = 8; /* Current size of the db_values table. */ unsigned min_step = 0; unsigned max_step = 0; unsigned i = 0; /* Index to the items table. */ unsigned prev_step = 0; double prev_db = 0; pa_assert(state); ps = state->userdata; if (!(db_fix = decibel_fix_get(ps, state->section))) { pa_log("[%s:%u] %s invalid in section %s", state->filename, state->lineno, state->lvalue, state->section); return -1; } if (!(items = pa_split_spaces_strv(state->rvalue))) { pa_log("[%s:%u] Value missing", state->filename, state->lineno); return -1; } db_values = pa_xnew(long, n); while ((item = items[i++])) { char *s = item; /* Step value string. */ char *d = item; /* dB value string. */ uint32_t step; double db; /* Move d forward until it points to a colon or to the end of the item. */ for (; *d && *d != ':'; ++d); if (d == s) { /* item started with colon. */ pa_log("[%s:%u] No step value found in %s", state->filename, state->lineno, item); goto fail; } if (!*d || !*(d + 1)) { /* No colon found, or it was the last character in item. */ pa_log("[%s:%u] No dB value found in %s", state->filename, state->lineno, item); goto fail; } /* pa_atou() needs a null-terminating string. Let's replace the colon * with a zero byte. */ *d++ = '\0'; if (pa_atou(s, &step) < 0) { pa_log("[%s:%u] Invalid step value: %s", state->filename, state->lineno, s); goto fail; } if (pa_atod(d, &db) < 0) { pa_log("[%s:%u] Invalid dB value: %s", state->filename, state->lineno, d); goto fail; } if (step <= prev_step && i != 1) { pa_log("[%s:%u] Step value %u not greater than the previous value %u", state->filename, state->lineno, step, prev_step); goto fail; } if (db < prev_db && i != 1) { pa_log("[%s:%u] Decibel value %0.2f less than the previous value %0.2f", state->filename, state->lineno, db, prev_db); goto fail; } if (i == 1) { min_step = step; db_values[0] = (long) (db * 100.0); prev_step = step; prev_db = db; } else { /* Interpolate linearly. */ double db_increment = (db - prev_db) / (step - prev_step); for (; prev_step < step; ++prev_step, prev_db += db_increment) { /* Reallocate the db_values table if it's about to overflow. */ if (prev_step + 1 - min_step == n) { n *= 2; db_values = pa_xrenew(long, db_values, n); } db_values[prev_step + 1 - min_step] = (long) ((prev_db + db_increment) * 100.0); } } max_step = step; } db_fix->min_step = min_step; db_fix->max_step = max_step; pa_xfree(db_fix->db_values); db_fix->db_values = db_values; pa_xstrfreev(items); return 0; fail: pa_xstrfreev(items); pa_xfree(db_values); return -1; } /* the logic is simple: if we see the jack in multiple paths */ /* assign all those paths to one availability_group */ static void profile_set_set_availability_groups(pa_alsa_profile_set *ps) { pa_dynarray *paths; pa_alsa_path *p; void *state; unsigned idx1; uint32_t num = 1; /* Merge ps->input_paths and ps->output_paths into one dynarray. */ paths = pa_dynarray_new(NULL); PA_HASHMAP_FOREACH(p, ps->input_paths, state) pa_dynarray_append(paths, p); PA_HASHMAP_FOREACH(p, ps->output_paths, state) pa_dynarray_append(paths, p); PA_DYNARRAY_FOREACH(p, paths, idx1) { pa_alsa_jack *j; const char *found = NULL; bool has_control = false; PA_LLIST_FOREACH(j, p->jacks) { pa_alsa_path *p2; unsigned idx2; if (!j->has_control || j->state_plugged == PA_AVAILABLE_NO) continue; has_control = true; PA_DYNARRAY_FOREACH(p2, paths, idx2) { pa_alsa_jack *j2; if (p2 == p) break; PA_LLIST_FOREACH(j2, p2->jacks) { if (!j2->has_control || j2->state_plugged == PA_AVAILABLE_NO) continue; if (pa_streq(j->alsa_id.name, j2->alsa_id.name) && j->alsa_id.index == j2->alsa_id.index) { j->state_plugged = PA_AVAILABLE_UNKNOWN; j2->state_plugged = PA_AVAILABLE_UNKNOWN; found = p2->availability_group; break; } } } if (found) break; } if (!has_control) continue; if (!found) { p->availability_group = pa_sprintf_malloc("Legacy %d", num); } else { p->availability_group = pa_xstrdup(found); } if (!found) num++; } pa_dynarray_free(paths); } static void mapping_paths_probe(pa_alsa_mapping *m, pa_alsa_profile *profile, pa_alsa_direction_t direction, pa_hashmap *used_paths, pa_hashmap *mixers) { pa_alsa_path *p; void *state; snd_pcm_t *pcm_handle; pa_alsa_path_set *ps; snd_mixer_t *mixer_handle; if (direction == PA_ALSA_DIRECTION_OUTPUT) { if (m->output_path_set) return; /* Already probed */ m->output_path_set = ps = pa_alsa_path_set_new(m, direction, NULL); /* FIXME: Handle paths_dir */ pcm_handle = m->output_pcm; } else { if (m->input_path_set) return; /* Already probed */ m->input_path_set = ps = pa_alsa_path_set_new(m, direction, NULL); /* FIXME: Handle paths_dir */ pcm_handle = m->input_pcm; } if (!ps) return; /* No paths */ pa_assert(pcm_handle); mixer_handle = pa_alsa_open_mixer_for_pcm(mixers, pcm_handle, true); if (!mixer_handle) { /* Cannot open mixer, remove all entries */ pa_hashmap_remove_all(ps->paths); return; } PA_HASHMAP_FOREACH(p, ps->paths, state) { if (p->autodetect_eld_device) p->eld_device = m->hw_device_index; if (pa_alsa_path_probe(p, m, mixer_handle, m->profile_set->ignore_dB) < 0) pa_hashmap_remove(ps->paths, p); } path_set_condense(ps, mixer_handle); path_set_make_path_descriptions_unique(ps); PA_HASHMAP_FOREACH(p, ps->paths, state) pa_hashmap_put(used_paths, p, p); pa_log_debug("Available mixer paths (after tidying):"); pa_alsa_path_set_dump(ps); } static int mapping_verify(pa_alsa_mapping *m, const pa_channel_map *bonus) { static const struct description_map well_known_descriptions[] = { { "analog-mono", N_("Analog Mono") }, { "analog-mono-left", N_("Analog Mono (Left)") }, { "analog-mono-right", N_("Analog Mono (Right)") }, { "analog-stereo", N_("Analog Stereo") }, { "mono-fallback", N_("Mono") }, { "stereo-fallback", N_("Stereo") }, /* Note: Not translated to "Analog Stereo Input", because the source * name gets "Input" appended to it automatically, so adding "Input" * here would lead to the source name to become "Analog Stereo Input * Input". The same logic applies to analog-stereo-output, * multichannel-input and multichannel-output. */ { "analog-stereo-input", N_("Analog Stereo") }, { "analog-stereo-output", N_("Analog Stereo") }, { "analog-stereo-headset", N_("Headset") }, { "analog-stereo-speakerphone", N_("Speakerphone") }, { "multichannel-input", N_("Multichannel") }, { "multichannel-output", N_("Multichannel") }, { "analog-surround-21", N_("Analog Surround 2.1") }, { "analog-surround-30", N_("Analog Surround 3.0") }, { "analog-surround-31", N_("Analog Surround 3.1") }, { "analog-surround-40", N_("Analog Surround 4.0") }, { "analog-surround-41", N_("Analog Surround 4.1") }, { "analog-surround-50", N_("Analog Surround 5.0") }, { "analog-surround-51", N_("Analog Surround 5.1") }, { "analog-surround-61", N_("Analog Surround 6.0") }, { "analog-surround-61", N_("Analog Surround 6.1") }, { "analog-surround-70", N_("Analog Surround 7.0") }, { "analog-surround-71", N_("Analog Surround 7.1") }, { "iec958-stereo", N_("Digital Stereo (IEC958)") }, { "iec958-ac3-surround-40", N_("Digital Surround 4.0 (IEC958/AC3)") }, { "iec958-ac3-surround-51", N_("Digital Surround 5.1 (IEC958/AC3)") }, { "iec958-dts-surround-51", N_("Digital Surround 5.1 (IEC958/DTS)") }, { "hdmi-stereo", N_("Digital Stereo (HDMI)") }, { "hdmi-surround-51", N_("Digital Surround 5.1 (HDMI)") }, { "gaming-headset-chat", N_("Chat") }, { "gaming-headset-game", N_("Game") }, }; const char *description_key = m->description_key ? m->description_key : m->name; pa_assert(m); if (!pa_channel_map_valid(&m->channel_map)) { pa_log("Mapping %s is missing channel map.", m->name); return -1; } if (!m->device_strings) { pa_log("Mapping %s is missing device strings.", m->name); return -1; } if ((m->input_path_names && m->input_element) || (m->output_path_names && m->output_element)) { pa_log("Mapping %s must have either mixer path or mixer element, not both.", m->name); return -1; } if (!m->description) m->description = pa_xstrdup(lookup_description(description_key, well_known_descriptions, PA_ELEMENTSOF(well_known_descriptions))); if (!m->description) m->description = pa_xstrdup(m->name); if (bonus) { if (pa_channel_map_equal(&m->channel_map, bonus)) m->priority += 50; else if (m->channel_map.channels == bonus->channels) m->priority += 30; } return 0; } void pa_alsa_mapping_dump(pa_alsa_mapping *m) { char cm[PA_CHANNEL_MAP_SNPRINT_MAX]; pa_assert(m); pa_log_debug("Mapping %s (%s), priority=%u, channel_map=%s, supported=%s, direction=%i", m->name, pa_strnull(m->description), m->priority, pa_channel_map_snprint(cm, sizeof(cm), &m->channel_map), pa_yes_no(m->supported), m->direction); } static void profile_set_add_auto_pair( pa_alsa_profile_set *ps, pa_alsa_mapping *m, /* output */ pa_alsa_mapping *n /* input */) { char *name; pa_alsa_profile *p; pa_assert(ps); pa_assert(m || n); if (m && m->direction == PA_ALSA_DIRECTION_INPUT) return; if (n && n->direction == PA_ALSA_DIRECTION_OUTPUT) return; if (m && n) name = pa_sprintf_malloc("output:%s+input:%s", m->name, n->name); else if (m) name = pa_sprintf_malloc("output:%s", m->name); else name = pa_sprintf_malloc("input:%s", n->name); if (pa_hashmap_get(ps->profiles, name)) { pa_xfree(name); return; } p = pa_xnew0(pa_alsa_profile, 1); p->profile_set = ps; p->name = name; if (m) { p->output_name = pa_xstrdup(m->name); p->output_mappings = pa_idxset_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); pa_idxset_put(p->output_mappings, m, NULL); p->priority += m->priority * 100; p->fallback_output = m->fallback; } if (n) { p->input_name = pa_xstrdup(n->name); p->input_mappings = pa_idxset_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); pa_idxset_put(p->input_mappings, n, NULL); p->priority += n->priority; p->fallback_input = n->fallback; } pa_hashmap_put(ps->profiles, p->name, p); } static void profile_set_add_auto(pa_alsa_profile_set *ps) { pa_alsa_mapping *m, *n; void *m_state, *n_state; pa_assert(ps); /* The order is important here: 1) try single inputs and outputs before trying their combination, because if the half-duplex test failed, we don't have to try full duplex. 2) try the output right before the input combinations with that output, because then the output_pcm is not closed between tests. */ PA_HASHMAP_FOREACH(n, ps->mappings, n_state) profile_set_add_auto_pair(ps, NULL, n); PA_HASHMAP_FOREACH(m, ps->mappings, m_state) { profile_set_add_auto_pair(ps, m, NULL); PA_HASHMAP_FOREACH(n, ps->mappings, n_state) profile_set_add_auto_pair(ps, m, n); } } static int profile_verify(pa_alsa_profile *p) { static const struct description_map well_known_descriptions[] = { { "output:analog-mono+input:analog-mono", N_("Analog Mono Duplex") }, { "output:analog-stereo+input:analog-stereo", N_("Analog Stereo Duplex") }, { "output:analog-stereo-headset+input:analog-stereo-headset", N_("Headset") }, { "output:analog-stereo-speakerphone+input:analog-stereo-speakerphone", N_("Speakerphone") }, { "output:iec958-stereo+input:iec958-stereo", N_("Digital Stereo Duplex (IEC958)") }, { "output:multichannel-output+input:multichannel-input", N_("Multichannel Duplex") }, { "output:unknown-stereo+input:unknown-stereo", N_("Stereo Duplex") }, { "output:analog-output-surround71+output:analog-output-chat+input:analog-input", N_("Mono Chat + 7.1 Surround") }, { "off", N_("Off") } }; const char *description_key = p->description_key ? p->description_key : p->name; pa_assert(p); /* Replace the output mapping names by the actual mappings */ if (p->output_mapping_names) { char **name; pa_assert(!p->output_mappings); p->output_mappings = pa_idxset_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); for (name = p->output_mapping_names; *name; name++) { pa_alsa_mapping *m; char **in; bool duplicate = false; for (in = name + 1; *in; in++) if (pa_streq(*name, *in)) { duplicate = true; break; } if (duplicate) continue; if (!(m = pa_hashmap_get(p->profile_set->mappings, *name)) || m->direction == PA_ALSA_DIRECTION_INPUT) { pa_log("Profile '%s' refers to nonexistent mapping '%s'.", p->name, *name); return -1; } pa_idxset_put(p->output_mappings, m, NULL); if (p->supported) m->supported++; } pa_xstrfreev(p->output_mapping_names); p->output_mapping_names = NULL; } /* Replace the input mapping names by the actual mappings */ if (p->input_mapping_names) { char **name; pa_assert(!p->input_mappings); p->input_mappings = pa_idxset_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); for (name = p->input_mapping_names; *name; name++) { pa_alsa_mapping *m; char **in; bool duplicate = false; for (in = name + 1; *in; in++) if (pa_streq(*name, *in)) { duplicate = true; break; } if (duplicate) continue; if (!(m = pa_hashmap_get(p->profile_set->mappings, *name)) || m->direction == PA_ALSA_DIRECTION_OUTPUT) { pa_log("Profile '%s' refers to nonexistent mapping '%s'.", p->name, *name); return -1; } pa_idxset_put(p->input_mappings, m, NULL); if (p->supported) m->supported++; } pa_xstrfreev(p->input_mapping_names); p->input_mapping_names = NULL; } if (!p->input_mappings && !p->output_mappings) { pa_log("Profile '%s' lacks mappings.", p->name); return -1; } if (!p->description) p->description = pa_xstrdup(lookup_description(description_key, well_known_descriptions, PA_ELEMENTSOF(well_known_descriptions))); if (!p->description) { uint32_t idx; pa_alsa_mapping *m; char *ptr; size_t size; FILE *f; int count = 0; f = open_memstream(&ptr, &size); if (f == NULL) { pa_log("failed to open memstream: %m"); return -1; } if (p->output_mappings) PA_IDXSET_FOREACH(m, p->output_mappings, idx) { if (count++ > 0) fprintf(f, " + "); fprintf(f, _("%s Output"), m->description); } if (p->input_mappings) PA_IDXSET_FOREACH(m, p->input_mappings, idx) { if (count++ > 0) fprintf(f, " + "); fprintf(f, _("%s Input"), m->description); } fclose(f); p->description = ptr; } return 0; } void pa_alsa_profile_dump(pa_alsa_profile *p) { uint32_t idx; pa_alsa_mapping *m; pa_assert(p); pa_log_debug("Profile %s (%s), input=%s, output=%s priority=%u, supported=%s n_input_mappings=%u, n_output_mappings=%u", p->name, pa_strnull(p->description), pa_strnull(p->input_name), pa_strnull(p->output_name), p->priority, pa_yes_no(p->supported), p->input_mappings ? pa_idxset_size(p->input_mappings) : 0, p->output_mappings ? pa_idxset_size(p->output_mappings) : 0); if (p->input_mappings) PA_IDXSET_FOREACH(m, p->input_mappings, idx) pa_log_debug("Input %s", m->name); if (p->output_mappings) PA_IDXSET_FOREACH(m, p->output_mappings, idx) pa_log_debug("Output %s", m->name); } static int decibel_fix_verify(pa_alsa_decibel_fix *db_fix) { pa_assert(db_fix); /* Check that the dB mapping has been configured. Since "db-values" is * currently the only option in the DecibelFix section, and decibel fix * objects don't get created if a DecibelFix section is empty, this is * actually a redundant check. Having this may prevent future bugs, * however. */ if (!db_fix->db_values) { pa_log("Decibel fix for element %s lacks the dB values.", db_fix->name); return -1; } return 0; } void pa_alsa_decibel_fix_dump(pa_alsa_decibel_fix *db_fix) { char *db_values = NULL; pa_assert(db_fix); if (db_fix->db_values) { unsigned long i, nsteps; FILE *f; char *ptr; size_t size; f = open_memstream(&ptr, &size); if (f == NULL) return; pa_assert(db_fix->min_step <= db_fix->max_step); nsteps = db_fix->max_step - db_fix->min_step + 1; for (i = 0; i < nsteps; ++i) fprintf(f, "[%li]:%0.2f ", i + db_fix->min_step, db_fix->db_values[i] / 100.0); fclose(f); db_values = ptr; } pa_log_debug("Decibel fix %s, min_step=%li, max_step=%li, db_values=%s", db_fix->name, db_fix->min_step, db_fix->max_step, pa_strnull(db_values)); pa_xfree(db_values); } static const char *get_default_profile_dir(void) { const char *str; #ifdef HAVE_RUNNING_FROM_BUILD_TREE if (pa_run_from_build_tree()) return PA_SRCDIR "mixer/profile-sets"; else #endif if (getenv("ACP_BUILDDIR") != NULL) return "mixer/profile-sets"; if ((str = getenv("ACP_PROFILES_DIR")) != NULL) return str; return PA_ALSA_PROFILE_SETS_DIR; } pa_alsa_profile_set* pa_alsa_profile_set_new(const char *fname, const pa_channel_map *bonus) { pa_alsa_profile_set *ps; pa_alsa_profile *p; pa_alsa_mapping *m; pa_alsa_decibel_fix *db_fix; char *fn; int r; void *state; static pa_config_item items[] = { /* [General] */ { "auto-profiles", pa_config_parse_bool, NULL, "General" }, /* [Mapping ...] */ { "device-strings", mapping_parse_device_strings, NULL, NULL }, { "channel-map", mapping_parse_channel_map, NULL, NULL }, { "paths-input", mapping_parse_paths, NULL, NULL }, { "paths-output", mapping_parse_paths, NULL, NULL }, { "element-input", mapping_parse_element, NULL, NULL }, { "element-output", mapping_parse_element, NULL, NULL }, { "direction", mapping_parse_direction, NULL, NULL }, { "exact-channels", mapping_parse_exact_channels, NULL, NULL }, { "intended-roles", mapping_parse_intended_roles, NULL, NULL }, /* Shared by [Mapping ...] and [Profile ...] */ { "description", mapping_parse_description, NULL, NULL }, { "description-key", mapping_parse_description_key,NULL, NULL }, { "priority", mapping_parse_priority, NULL, NULL }, { "fallback", mapping_parse_fallback, NULL, NULL }, /* [Profile ...] */ { "input-mappings", profile_parse_mappings, NULL, NULL }, { "output-mappings", profile_parse_mappings, NULL, NULL }, { "skip-probe", profile_parse_skip_probe, NULL, NULL }, /* [DecibelFix ...] */ { "db-values", decibel_fix_parse_db_values, NULL, NULL }, { NULL, NULL, NULL, NULL } }; ps = pa_xnew0(pa_alsa_profile_set, 1); ps->mappings = pa_hashmap_new_full(pa_idxset_string_hash_func, pa_idxset_string_compare_func, NULL, (pa_free_cb_t) pa_alsa_mapping_free); ps->profiles = pa_hashmap_new_full(pa_idxset_string_hash_func, pa_idxset_string_compare_func, NULL, (pa_free_cb_t) pa_alsa_profile_free); ps->decibel_fixes = pa_hashmap_new_full(pa_idxset_string_hash_func, pa_idxset_string_compare_func, NULL, (pa_free_cb_t) decibel_fix_free); ps->input_paths = pa_hashmap_new_full(pa_idxset_string_hash_func, pa_idxset_string_compare_func, NULL, (pa_free_cb_t) pa_alsa_path_free); ps->output_paths = pa_hashmap_new_full(pa_idxset_string_hash_func, pa_idxset_string_compare_func, NULL, (pa_free_cb_t) pa_alsa_path_free); items[0].data = &ps->auto_profiles; fn = pa_maybe_prefix_path(fname ? fname : "default.conf", get_default_profile_dir()); if ((r = access(fn, R_OK)) != 0) { if (fname != NULL) { pa_log_warn("profile-set '%s' can't be accessed: %m", fn); fn = pa_maybe_prefix_path("default.conf", get_default_profile_dir()); r = access(fn, R_OK); } if (r != 0) { pa_log_warn("profile-set '%s' can't be accessed: %m", fn); } } r = pa_config_parse(fn, NULL, items, NULL, false, ps); pa_xfree(fn); if (r < 0) goto fail; PA_HASHMAP_FOREACH(m, ps->mappings, state) if (mapping_verify(m, bonus) < 0) goto fail; if (ps->auto_profiles) profile_set_add_auto(ps); PA_HASHMAP_FOREACH(p, ps->profiles, state) if (profile_verify(p) < 0) goto fail; PA_HASHMAP_FOREACH(db_fix, ps->decibel_fixes, state) if (decibel_fix_verify(db_fix) < 0) goto fail; return ps; fail: pa_alsa_profile_set_free(ps); return NULL; } static void profile_finalize_probing(pa_alsa_profile *to_be_finalized, pa_alsa_profile *next) { pa_alsa_mapping *m; uint32_t idx; if (!to_be_finalized) return; if (to_be_finalized->output_mappings) PA_IDXSET_FOREACH(m, to_be_finalized->output_mappings, idx) { if (!m->output_pcm) continue; if (to_be_finalized->supported) m->supported++; /* If this mapping is also in the next profile, we won't close the * pcm handle here, because it would get immediately reopened * anyway. */ if (next && next->output_mappings && pa_idxset_get_by_data(next->output_mappings, m, NULL)) continue; pa_alsa_init_proplist_pcm(NULL, m->output_proplist, m->output_pcm); pa_alsa_close(&m->output_pcm); } if (to_be_finalized->input_mappings) PA_IDXSET_FOREACH(m, to_be_finalized->input_mappings, idx) { if (!m->input_pcm) continue; if (to_be_finalized->supported) m->supported++; /* If this mapping is also in the next profile, we won't close the * pcm handle here, because it would get immediately reopened * anyway. */ if (next && next->input_mappings && pa_idxset_get_by_data(next->input_mappings, m, NULL)) continue; pa_alsa_init_proplist_pcm(NULL, m->input_proplist, m->input_pcm); pa_alsa_close(&m->input_pcm); } } static snd_pcm_t* mapping_open_pcm(pa_alsa_mapping *m, const pa_sample_spec *ss, const char *dev_id, bool exact_channels, int mode, unsigned default_n_fragments, unsigned default_fragment_size_msec) { snd_pcm_t* handle; pa_sample_spec try_ss = *ss; pa_channel_map try_map = m->channel_map; snd_pcm_uframes_t try_period_size, try_buffer_size; try_ss.channels = try_map.channels; try_period_size = pa_usec_to_bytes(default_fragment_size_msec * PA_USEC_PER_MSEC, &try_ss) / pa_frame_size(&try_ss); try_buffer_size = default_n_fragments * try_period_size; handle = pa_alsa_open_by_template( m->device_strings, dev_id, NULL, &try_ss, &try_map, mode, &try_period_size, &try_buffer_size, 0, NULL, NULL, exact_channels); if (handle && !exact_channels && m->channel_map.channels != try_map.channels) { char buf[PA_CHANNEL_MAP_SNPRINT_MAX]; pa_log_debug("Channel map for mapping '%s' permanently changed to '%s'", m->name, pa_channel_map_snprint(buf, sizeof(buf), &try_map)); m->channel_map = try_map; } return handle; } static void paths_drop_unused(pa_hashmap* h, pa_hashmap *keep) { void* state = NULL; const void* key; pa_alsa_path* p; pa_assert(h); pa_assert(keep); p = pa_hashmap_iterate(h, &state, &key); while (p) { if (pa_hashmap_get(keep, p) == NULL) pa_hashmap_remove_and_free(h, key); p = pa_hashmap_iterate(h, &state, &key); } } static int add_profiles_to_probe( pa_alsa_profile **list, pa_hashmap *profiles, bool fallback_output, bool fallback_input) { int i = 0; void *state; pa_alsa_profile *p; PA_HASHMAP_FOREACH(p, profiles, state) if (p->fallback_input == fallback_input && p->fallback_output == fallback_output) { *list = p; list++; i++; } return i; } static void mapping_query_hw_device(pa_alsa_mapping *mapping, snd_pcm_t *pcm) { int r; snd_pcm_info_t* pcm_info; snd_pcm_info_alloca(&pcm_info); r = snd_pcm_info(pcm, pcm_info); if (r < 0) { pa_log("Mapping %s: snd_pcm_info() failed %s: ", mapping->name, pa_alsa_strerror(r)); return; } /* XXX: It's not clear what snd_pcm_info_get_device() does if the device is * not backed by a hw device or if it's backed by multiple hw devices. We * only use hw_device_index for HDMI devices, however, and for those the * return value is expected to be always valid, so this shouldn't be a * significant problem. */ mapping->hw_device_index = snd_pcm_info_get_device(pcm_info); } void pa_alsa_profile_set_probe( pa_alsa_profile_set *ps, pa_hashmap *mixers, const char *dev_id, const pa_sample_spec *ss, unsigned default_n_fragments, unsigned default_fragment_size_msec) { bool found_output = false, found_input = false; pa_alsa_profile *p, *last = NULL; pa_alsa_profile **pp, **probe_order; pa_alsa_mapping *m; pa_hashmap *broken_inputs, *broken_outputs, *used_paths; pa_alsa_mapping *selected_fallback_input = NULL, *selected_fallback_output = NULL; pa_assert(ps); pa_assert(dev_id); pa_assert(ss); if (ps->probed) return; broken_inputs = pa_hashmap_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); broken_outputs = pa_hashmap_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); used_paths = pa_hashmap_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func); pp = probe_order = pa_xnew0(pa_alsa_profile *, pa_hashmap_size(ps->profiles) + 1); pp += add_profiles_to_probe(pp, ps->profiles, false, false); pp += add_profiles_to_probe(pp, ps->profiles, false, true); pp += add_profiles_to_probe(pp, ps->profiles, true, false); pp += add_profiles_to_probe(pp, ps->profiles, true, true); for (pp = probe_order; *pp; pp++) { uint32_t idx; p = *pp; /* Skip if fallback and already found something, but still probe already selected fallbacks. * If UCM is used then both fallback_input and fallback_output flags are false. * If UCM is not used then there will be only a single entry in mappings. */ if (found_input && p->fallback_input) if (selected_fallback_input == NULL || pa_idxset_get_by_index(p->input_mappings, 0) != selected_fallback_input) continue; if (found_output && p->fallback_output) if (selected_fallback_output == NULL || pa_idxset_get_by_index(p->output_mappings, 0) != selected_fallback_output) continue; /* Skip if this is already marked that it is supported (i.e. from the config file) */ if (!p->supported) { profile_finalize_probing(last, p); p->supported = true; if (p->output_mappings) { PA_IDXSET_FOREACH(m, p->output_mappings, idx) { if (pa_hashmap_get(broken_outputs, m) == m) { pa_log_debug("Skipping profile %s - will not be able to open output:%s", p->name, m->name); p->supported = false; break; } } } if (p->input_mappings && p->supported) { PA_IDXSET_FOREACH(m, p->input_mappings, idx) { if (pa_hashmap_get(broken_inputs, m) == m) { pa_log_debug("Skipping profile %s - will not be able to open input:%s", p->name, m->name); p->supported = false; break; } } } if (p->supported) pa_log_debug("Looking at profile %s", p->name); /* Check if we can open all new ones */ if (p->output_mappings && p->supported) PA_IDXSET_FOREACH(m, p->output_mappings, idx) { if (m->output_pcm) continue; pa_log_debug("Checking for playback on %s (%s)", m->description, m->name); if (!(m->output_pcm = mapping_open_pcm(m, ss, dev_id, m->exact_channels, SND_PCM_STREAM_PLAYBACK, default_n_fragments, default_fragment_size_msec))) { p->supported = false; if (pa_idxset_size(p->output_mappings) == 1 && ((!p->input_mappings) || pa_idxset_size(p->input_mappings) == 0)) { pa_log_debug("Caching failure to open output:%s", m->name); pa_hashmap_put(broken_outputs, m, m); } break; } if (m->hw_device_index < 0) mapping_query_hw_device(m, m->output_pcm); } if (p->input_mappings && p->supported) PA_IDXSET_FOREACH(m, p->input_mappings, idx) { if (m->input_pcm) continue; pa_log_debug("Checking for recording on %s (%s)", m->description, m->name); if (!(m->input_pcm = mapping_open_pcm(m, ss, dev_id, m->exact_channels, SND_PCM_STREAM_CAPTURE, default_n_fragments, default_fragment_size_msec))) { p->supported = false; if (pa_idxset_size(p->input_mappings) == 1 && ((!p->output_mappings) || pa_idxset_size(p->output_mappings) == 0)) { pa_log_debug("Caching failure to open input:%s", m->name); pa_hashmap_put(broken_inputs, m, m); } break; } if (m->hw_device_index < 0) mapping_query_hw_device(m, m->input_pcm); } last = p; if (!p->supported) continue; } pa_log_debug("Profile %s supported.", p->name); if (p->output_mappings) PA_IDXSET_FOREACH(m, p->output_mappings, idx) if (m->output_pcm) { found_output = true; if (p->fallback_output && selected_fallback_output == NULL) { selected_fallback_output = m; } mapping_paths_probe(m, p, PA_ALSA_DIRECTION_OUTPUT, used_paths, mixers); } if (p->input_mappings) PA_IDXSET_FOREACH(m, p->input_mappings, idx) if (m->input_pcm) { found_input = true; if (p->fallback_input && selected_fallback_input == NULL) { selected_fallback_input = m; } mapping_paths_probe(m, p, PA_ALSA_DIRECTION_INPUT, used_paths, mixers); } } /* Clean up */ profile_finalize_probing(last, NULL); pa_alsa_profile_set_drop_unsupported(ps); paths_drop_unused(ps->input_paths, used_paths); paths_drop_unused(ps->output_paths, used_paths); pa_hashmap_free(broken_inputs); pa_hashmap_free(broken_outputs); pa_hashmap_free(used_paths); pa_xfree(probe_order); profile_set_set_availability_groups(ps); ps->probed = true; } void pa_alsa_profile_set_dump(pa_alsa_profile_set *ps) { pa_alsa_profile *p; pa_alsa_mapping *m; pa_alsa_decibel_fix *db_fix; void *state; pa_assert(ps); pa_log_debug("Profile set %p, auto_profiles=%s, probed=%s, n_mappings=%u, n_profiles=%u, n_decibel_fixes=%u", (void*) ps, pa_yes_no(ps->auto_profiles), pa_yes_no(ps->probed), pa_hashmap_size(ps->mappings), pa_hashmap_size(ps->profiles), pa_hashmap_size(ps->decibel_fixes)); PA_HASHMAP_FOREACH(m, ps->mappings, state) pa_alsa_mapping_dump(m); PA_HASHMAP_FOREACH(p, ps->profiles, state) pa_alsa_profile_dump(p); PA_HASHMAP_FOREACH(db_fix, ps->decibel_fixes, state) pa_alsa_decibel_fix_dump(db_fix); } void pa_alsa_profile_set_drop_unsupported(pa_alsa_profile_set *ps) { pa_alsa_profile *p; pa_alsa_mapping *m; void *state; PA_HASHMAP_FOREACH(p, ps->profiles, state) { if (!p->supported) pa_hashmap_remove_and_free(ps->profiles, p->name); } PA_HASHMAP_FOREACH(m, ps->mappings, state) { if (m->supported <= 0) pa_hashmap_remove_and_free(ps->mappings, m->name); } } static pa_device_port* device_port_alsa_init(pa_hashmap *ports, /* card ports */ const char* name, const char* description, pa_alsa_path *path, pa_alsa_setting *setting, pa_card_profile *cp, pa_hashmap *extra, /* sink/source ports */ pa_core *core) { pa_device_port *p; pa_assert(path); p = pa_hashmap_get(ports, name); if (!p) { pa_alsa_port_data *data; pa_device_port_new_data port_data; pa_device_port_new_data_init(&port_data); pa_device_port_new_data_set_name(&port_data, name); pa_device_port_new_data_set_description(&port_data, description); pa_device_port_new_data_set_direction(&port_data, path->direction == PA_ALSA_DIRECTION_OUTPUT ? PA_DIRECTION_OUTPUT : PA_DIRECTION_INPUT); pa_device_port_new_data_set_type(&port_data, path->device_port_type); pa_device_port_new_data_set_availability_group(&port_data, path->availability_group); p = pa_device_port_new(core, &port_data, sizeof(pa_alsa_port_data)); pa_device_port_new_data_done(&port_data); pa_assert(p); pa_hashmap_put(ports, p->name, p); pa_proplist_update(p->proplist, PA_UPDATE_REPLACE, path->proplist); data = PA_DEVICE_PORT_DATA(p); /* Ownership of the path and setting is not transferred to the port data, so we don't deal with freeing them */ data->path = path; data->setting = setting; path->port = p; } if (cp) pa_hashmap_put(p->profiles, cp->name, cp); if (extra) { pa_hashmap_put(extra, p->name, p); } return p; } void pa_alsa_path_set_add_ports( pa_alsa_path_set *ps, pa_card_profile *cp, pa_hashmap *ports, /* card ports */ pa_hashmap *extra, /* sink/source ports */ pa_core *core) { pa_alsa_path *path; void *state; pa_assert(ports); if (!ps) return; PA_HASHMAP_FOREACH(path, ps->paths, state) { if (!path->settings || !path->settings->next) { /* If there is no or just one setting we only need a * single entry */ pa_device_port *port = device_port_alsa_init(ports, path->name, path->description, path, path->settings, cp, extra, core); port->priority = path->priority * 100; } else { pa_alsa_setting *s; PA_LLIST_FOREACH(s, path->settings) { pa_device_port *port; char *n, *d; n = pa_sprintf_malloc("%s;%s", path->name, s->name); if (s->description[0]) d = pa_sprintf_malloc("%s / %s", path->description, s->description); else d = pa_xstrdup(path->description); port = device_port_alsa_init(ports, n, d, path, s, cp, extra, core); port->priority = path->priority * 100 + s->priority; pa_xfree(n); pa_xfree(d); } } } } void pa_alsa_add_ports(pa_hashmap *ports, pa_alsa_path_set *ps, pa_card *card) { pa_assert(ps); if (ps->paths && pa_hashmap_size(ps->paths) > 0) { pa_assert(card); pa_alsa_path_set_add_ports(ps, NULL, card->ports, ports, card->core); } pa_log_debug("Added %u ports", pa_hashmap_size(ports)); }