/*** This file is part of PulseAudio. Copyright 2011 Colin Guthrie 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 . ***/ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include "module-filter-apply-symdef.h" #define PA_PROP_FILTER_APPLY_MOVING "filter.apply.moving" #define PA_PROP_MDM_AUTO_FILTERED "module-device-manager.auto_filtered" PA_MODULE_AUTHOR("Colin Guthrie"); PA_MODULE_DESCRIPTION("Load filter sinks automatically when needed"); PA_MODULE_VERSION(PACKAGE_VERSION); PA_MODULE_LOAD_ONCE(true); PA_MODULE_USAGE(_("autoclean=")); static const char* const valid_modargs[] = { "autoclean", NULL }; #define DEFAULT_AUTOCLEAN true #define HOUSEKEEPING_INTERVAL (10 * PA_USEC_PER_SEC) struct filter { char *name; uint32_t module_index; pa_sink *sink; pa_sink *sink_master; pa_source *source; pa_source *source_master; }; struct userdata { pa_core *core; pa_hashmap *filters; /* Keep track of streams we're managing PA_PROP_MDM_AUTO_FILTERED on, we're * only maintaining membership, so key and value are just the * pa_sink_input/pa_source_output. */ pa_hashmap *mdm_ignored_inputs, *mdm_ignored_outputs; bool autoclean; pa_time_event *housekeeping_time_event; }; static unsigned filter_hash(const void *p) { const struct filter *f = p; if (f->sink_master && !f->source_master) return (unsigned) (f->sink_master->index + pa_idxset_string_hash_func(f->name)); else if (!f->sink_master && f->source_master) return (unsigned) ((f->source_master->index << 16) + pa_idxset_string_hash_func(f->name)); else return (unsigned) (f->sink_master->index + (f->source_master->index << 16) + pa_idxset_string_hash_func(f->name)); } static int filter_compare(const void *a, const void *b) { const struct filter *fa = a, *fb = b; int r; if (fa->sink_master != fb->sink_master || fa->source_master != fb->source_master) return 1; if ((r = strcmp(fa->name, fb->name))) return r; return 0; } static struct filter *filter_new(const char *name, pa_sink *sink, pa_source *source) { struct filter *f; pa_assert(sink || source); f = pa_xnew(struct filter, 1); f->name = pa_xstrdup(name); f->sink_master = sink; f->source_master = source; f->module_index = PA_INVALID_INDEX; f->sink = NULL; f->source = NULL; return f; } static void filter_free(struct filter *f) { pa_assert(f); pa_xfree(f->name); pa_xfree(f); } static const char* should_filter(pa_object *o, bool is_sink_input) { const char *apply; pa_proplist *pl; if (is_sink_input) pl = PA_SINK_INPUT(o)->proplist; else pl = PA_SOURCE_OUTPUT(o)->proplist; /* If the stream doesn't want any filter, then let it be. */ if ((apply = pa_proplist_gets(pl, PA_PROP_FILTER_APPLY)) && !pa_streq(apply, "")) { const char* suppress = pa_proplist_gets(pl, PA_PROP_FILTER_SUPPRESS); if (!suppress || !pa_streq(suppress, apply)) return apply; } return NULL; } static bool should_group_filter(struct filter *filter) { return pa_streq(filter->name, "echo-cancel"); } static char* get_group(pa_object *o, bool is_sink_input) { pa_proplist *pl; if (is_sink_input) pl = PA_SINK_INPUT(o)->proplist; else pl = PA_SOURCE_OUTPUT(o)->proplist; /* There's a bit of cleverness here -- the second argument ensures that we * only group streams that require the same filter */ return pa_proplist_get_stream_group(pl, pa_proplist_gets(pl, PA_PROP_FILTER_APPLY), NULL); } /* For filters that apply on a source-output/sink-input pair, this finds the * master sink if we know the master source, or vice versa. It does this by * looking up streams that belong to the same stream group as the original * object. The idea is that streams from the sam group are always routed * together. */ static bool find_paired_master(struct userdata *u, struct filter *filter, pa_object *o, bool is_sink_input) { char *group; if ((group = get_group(o, is_sink_input))) { uint32_t idx; char *g; char *module_name = pa_sprintf_malloc("module-%s", filter->name); if (is_sink_input) { pa_source_output *so; PA_IDXSET_FOREACH(so, u->core->source_outputs, idx) { g = get_group(PA_OBJECT(so), false); if (pa_streq(g, group)) { if (pa_streq(module_name, so->source->module->name)) { /* Make sure we're not routing to another instance of * the same filter. */ filter->source_master = so->source->output_from_master->source; } else { filter->source_master = so->source; } pa_xfree(g); break; } pa_xfree (g); } } else { pa_sink_input *si; PA_IDXSET_FOREACH(si, u->core->sink_inputs, idx) { g = get_group(PA_OBJECT(si), true); if (pa_streq(g, group)) { if (pa_streq(module_name, si->sink->module->name)) { /* Make sure we're not routing to another instance of * the same filter. */ filter->sink_master = si->sink->input_to_master->sink; } else { filter->sink_master = si->sink; } pa_xfree(g); break; } pa_xfree(g); } } pa_xfree(group); pa_xfree(module_name); if (!filter->sink_master || !filter->source_master) return false; } return true; } static bool nothing_attached(struct filter *f) { bool no_si = true, no_so = true; if (f->sink) no_si = pa_idxset_isempty(f->sink->inputs); if (f->source) no_so = pa_idxset_isempty(f->source->outputs); return no_si && no_so; } static void housekeeping_time_callback(pa_mainloop_api*a, pa_time_event* e, const struct timeval *t, void *userdata) { struct userdata *u = userdata; struct filter *filter; void *state; pa_assert(a); pa_assert(e); pa_assert(u); pa_assert(e == u->housekeeping_time_event); u->core->mainloop->time_free(u->housekeeping_time_event); u->housekeeping_time_event = NULL; PA_HASHMAP_FOREACH(filter, u->filters, state) { if (nothing_attached(filter)) { uint32_t idx; pa_log_debug("Detected filter %s as no longer used. Unloading.", filter->name); idx = filter->module_index; pa_hashmap_remove(u->filters, filter); filter_free(filter); pa_module_unload_request_by_index(u->core, idx, true); } } pa_log_info("Housekeeping Done."); } static void trigger_housekeeping(struct userdata *u) { pa_assert(u); if (!u->autoclean) return; if (u->housekeeping_time_event) return; u->housekeeping_time_event = pa_core_rttime_new(u->core, pa_rtclock_now() + HOUSEKEEPING_INTERVAL, housekeeping_time_callback, u); } static int do_move(struct userdata *u, pa_object *obj, pa_object *parent, bool is_input) { /* Keep track of objects that we've marked for module-device-manager to ignore */ pa_hashmap_put(is_input ? u->mdm_ignored_inputs : u->mdm_ignored_outputs, obj, obj); if (is_input) { pa_sink_input_set_property(PA_SINK_INPUT(obj), PA_PROP_MDM_AUTO_FILTERED, "1"); return pa_sink_input_move_to(PA_SINK_INPUT(obj), PA_SINK(parent), false); } else { pa_source_output_set_property(PA_SOURCE_OUTPUT(obj), PA_PROP_MDM_AUTO_FILTERED, "1"); return pa_source_output_move_to(PA_SOURCE_OUTPUT(obj), PA_SOURCE(parent), false); } } static void move_object_for_filter(struct userdata *u, pa_object *o, struct filter* filter, bool restore, bool is_sink_input) { pa_object *parent; pa_proplist *pl; const char *name; pa_assert(o); pa_assert(filter); if (is_sink_input) { pl = PA_SINK_INPUT(o)->proplist; parent = PA_OBJECT(restore ? filter->sink_master : filter->sink); if (!parent) return; name = PA_SINK(parent)->name; } else { pl = PA_SOURCE_OUTPUT(o)->proplist; parent = PA_OBJECT(restore ? filter->source_master : filter->source); if (!parent) return; name = PA_SOURCE(parent)->name; } pa_proplist_sets(pl, PA_PROP_FILTER_APPLY_MOVING, "1"); if (do_move(u, o, parent, is_sink_input) < 0) pa_log_info("Failed to move %s for \"%s\" to <%s>.", is_sink_input ? "sink-input" : "source-output", pa_strnull(pa_proplist_gets(pl, PA_PROP_APPLICATION_NAME)), name); else pa_log_info("Successfully moved %s for \"%s\" to <%s>.", is_sink_input ? "sink-input" : "source-output", pa_strnull(pa_proplist_gets(pl, PA_PROP_APPLICATION_NAME)), name); pa_proplist_unset(pl, PA_PROP_FILTER_APPLY_MOVING); } static void move_objects_for_filter(struct userdata *u, pa_object *o, struct filter* filter, bool restore, bool is_sink_input) { if (!should_group_filter(filter)) move_object_for_filter(u, o, filter, restore, is_sink_input); else { pa_source_output *so; pa_sink_input *si; char *g, *group; uint32_t idx; group = get_group(o, is_sink_input); PA_IDXSET_FOREACH(so, u->core->source_outputs, idx) { g = get_group(PA_OBJECT(so), false); if (pa_streq(g, group)) move_object_for_filter(u, PA_OBJECT(so), filter, restore, false); pa_xfree(g); } PA_IDXSET_FOREACH(si, u->core->sink_inputs, idx) { g = get_group(PA_OBJECT(si), true); if (pa_streq(g, group)) move_object_for_filter(u, PA_OBJECT(si), filter, restore, true); pa_xfree(g); } pa_xfree(group); } } /* Note that we assume a filter will provide at most one sink and at most one * source (and at least one of either). */ static void find_filters_for_module(struct userdata *u, pa_module *m, const char *name) { uint32_t idx; pa_sink *sink; pa_source *source; struct filter *fltr = NULL; PA_IDXSET_FOREACH(sink, u->core->sinks, idx) { if (sink->module == m) { pa_assert(pa_sink_is_filter(sink)); fltr = filter_new(name, sink->input_to_master->sink, NULL); fltr->module_index = m->index; fltr->sink = sink; break; } } PA_IDXSET_FOREACH(source, u->core->sources, idx) { if (source->module == m && !source->monitor_of) { pa_assert(pa_source_is_filter(source)); if (!fltr) { fltr = filter_new(name, NULL, source->output_from_master->source); fltr->module_index = m->index; fltr->source = source; } else { fltr->source = source; fltr->source_master = source->output_from_master->source; } break; } } pa_hashmap_put(u->filters, fltr, fltr); } static bool can_unload_module(struct userdata *u, uint32_t idx) { void *state; struct filter *filter; /* Check if any other struct filters point to the same module */ PA_HASHMAP_FOREACH(filter, u->filters, state) { if (filter->module_index == idx && !nothing_attached(filter)) return false; } return true; } static pa_hook_result_t process(struct userdata *u, pa_object *o, bool is_sink_input) { const char *want; bool done_something = false; pa_sink *sink = NULL; pa_source *source = NULL; pa_module *module = NULL; char *module_name = NULL; struct filter *fltr = NULL, *filter = NULL; if (is_sink_input) { sink = PA_SINK_INPUT(o)->sink; if (sink) module = sink->module; } else { source = PA_SOURCE_OUTPUT(o)->source; if (source) module = source->module; } /* If there is no sink/source yet, we can't do much */ if ((is_sink_input && !sink) || (!is_sink_input && !source)) goto done; /* If the stream doesn't what any filter, then let it be. */ if ((want = should_filter(o, is_sink_input))) { /* We need to ensure the SI is playing on a sink of this type * attached to the sink it's "officially" playing on */ if (!module) goto done; module_name = pa_sprintf_malloc("module-%s", want); if (pa_streq(module->name, module_name)) { pa_log_debug("Stream appears to be playing on an appropriate sink already. Ignoring."); goto done; } fltr = filter_new(want, sink, source); if (should_group_filter(fltr) && !find_paired_master(u, fltr, o, is_sink_input)) { pa_log_debug("Want group filtering but don't have enough streams."); goto done; } if (!(filter = pa_hashmap_get(u->filters, fltr))) { char *args; pa_module *m; args = pa_sprintf_malloc("autoloaded=1 %s%s %s%s", fltr->sink_master ? "sink_master=" : "", fltr->sink_master ? fltr->sink_master->name : "", fltr->source_master ? "source_master=" : "", fltr->source_master ? fltr->source_master->name : ""); pa_log_debug("Loading %s with arguments '%s'", module_name, args); if ((m = pa_module_load(u->core, module_name, args))) { find_filters_for_module(u, m, want); filter = pa_hashmap_get(u->filters, fltr); done_something = true; } pa_xfree(args); } if (!filter) { pa_log("Unable to load %s", module_name); goto done; } /* We can move the stream now as we know the destination. If this * isn't true, we will do it later when the sink appears. */ if ((is_sink_input && filter->sink) || (!is_sink_input && filter->source)) { move_objects_for_filter(u, o, filter, false, is_sink_input); done_something = true; } } else { void *state; /* We do not want to filter... but are we already filtered? * This can happen if an input's proplist changes */ PA_HASHMAP_FOREACH(filter, u->filters, state) { if ((is_sink_input && sink == filter->sink) || (!is_sink_input && source == filter->source)) { move_objects_for_filter(u, o, filter, true, is_sink_input); done_something = true; break; } } } if (done_something) trigger_housekeeping(u); done: pa_xfree(module_name); pa_xfree(fltr); return PA_HOOK_OK; } static pa_hook_result_t sink_input_put_cb(pa_core *core, pa_sink_input *i, struct userdata *u) { pa_core_assert_ref(core); pa_sink_input_assert_ref(i); return process(u, PA_OBJECT(i), true); } static pa_hook_result_t sink_input_move_finish_cb(pa_core *core, pa_sink_input *i, struct userdata *u) { pa_core_assert_ref(core); pa_sink_input_assert_ref(i); if (pa_proplist_gets(i->proplist, PA_PROP_FILTER_APPLY_MOVING)) return PA_HOOK_OK; /* If we're managing m-d-m.auto_filtered on this, remove and re-add if we're continuing to manage it */ pa_hashmap_remove(u->mdm_ignored_inputs, i); return process(u, PA_OBJECT(i), true); } static pa_hook_result_t sink_input_proplist_cb(pa_core *core, pa_sink_input *i, struct userdata *u) { pa_core_assert_ref(core); pa_sink_input_assert_ref(i); return process(u, PA_OBJECT(i), true); } static pa_hook_result_t sink_input_unlink_cb(pa_core *core, pa_sink_input *i, struct userdata *u) { pa_core_assert_ref(core); pa_sink_input_assert_ref(i); pa_assert(u); if (pa_hashmap_size(u->filters) > 0) trigger_housekeeping(u); pa_hashmap_remove(u->mdm_ignored_inputs, i); return PA_HOOK_OK; } static pa_hook_result_t sink_unlink_cb(pa_core *core, pa_sink *sink, struct userdata *u) { void *state; struct filter *filter = NULL; pa_core_assert_ref(core); pa_sink_assert_ref(sink); pa_assert(u); /* If either the parent or the sink we've loaded disappears, * we should remove it from our hashmap */ PA_HASHMAP_FOREACH(filter, u->filters, state) { if (filter->sink_master == sink || filter->sink == sink) { uint32_t idx; /* Attempt to rescue any streams to the parent sink as this is likely * the best course of action (as opposed to a generic rescue via * module-rescue-streams */ if (filter->sink == sink) { pa_sink_input *i; PA_IDXSET_FOREACH(i, sink->inputs, idx) move_objects_for_filter(u, PA_OBJECT(i), filter, true, true); } idx = filter->module_index; pa_hashmap_remove(u->filters, filter); filter_free(filter); if (can_unload_module(u, idx)) pa_module_unload_request_by_index(u->core, idx, true); } } return PA_HOOK_OK; } static pa_hook_result_t source_output_put_cb(pa_core *core, pa_source_output *o, struct userdata *u) { pa_core_assert_ref(core); pa_source_output_assert_ref(o); return process(u, PA_OBJECT(o), false); } static pa_hook_result_t source_output_move_finish_cb(pa_core *core, pa_source_output *o, struct userdata *u) { pa_core_assert_ref(core); pa_source_output_assert_ref(o); if (pa_proplist_gets(o->proplist, PA_PROP_FILTER_APPLY_MOVING)) return PA_HOOK_OK; /* If we're managing m-d-m.auto_filtered on this, remove and re-add if we're continuing to manage it */ pa_hashmap_remove(u->mdm_ignored_outputs, o); return process(u, PA_OBJECT(o), false); } static pa_hook_result_t source_output_proplist_cb(pa_core *core, pa_source_output *o, struct userdata *u) { pa_core_assert_ref(core); pa_source_output_assert_ref(o); return process(u, PA_OBJECT(o), false); } static pa_hook_result_t source_output_unlink_cb(pa_core *core, pa_source_output *o, struct userdata *u) { pa_core_assert_ref(core); pa_source_output_assert_ref(o); pa_assert(u); if (pa_hashmap_size(u->filters) > 0) trigger_housekeeping(u); pa_hashmap_remove(u->mdm_ignored_outputs, o); return PA_HOOK_OK; } static pa_hook_result_t source_unlink_cb(pa_core *core, pa_source *source, struct userdata *u) { void *state; struct filter *filter = NULL; pa_core_assert_ref(core); pa_source_assert_ref(source); pa_assert(u); /* If either the parent or the source we've loaded disappears, * we should remove it from our hashmap */ PA_HASHMAP_FOREACH(filter, u->filters, state) { if (filter->source_master == source || filter->source == source) { uint32_t idx; /* Attempt to rescue any streams to the parent source as this is likely * the best course of action (as opposed to a generic rescue via * module-rescue-streams */ if (filter->source == source) { pa_source_output *o; PA_IDXSET_FOREACH(o, source->outputs, idx) move_objects_for_filter(u, PA_OBJECT(o), filter, true, false); } idx = filter->module_index; pa_hashmap_remove(u->filters, filter); filter_free(filter); if (can_unload_module(u, idx)) pa_module_unload_request_by_index(u->core, idx, true); } } return PA_HOOK_OK; } static void unset_mdm_ignore_input(pa_sink_input *i) { pa_sink_input_set_property(i, PA_PROP_MDM_AUTO_FILTERED, NULL); } static void unset_mdm_ignore_output(pa_source_output *o) { pa_source_output_set_property(o, PA_PROP_MDM_AUTO_FILTERED, NULL); } int pa__init(pa_module *m) { pa_modargs *ma = NULL; struct userdata *u; pa_assert(m); if (!(ma = pa_modargs_new(m->argument, valid_modargs))) { pa_log("Failed to parse module arguments"); goto fail; } m->userdata = u = pa_xnew0(struct userdata, 1); u->core = m->core; u->autoclean = DEFAULT_AUTOCLEAN; if (pa_modargs_get_value_boolean(ma, "autoclean", &u->autoclean) < 0) { pa_log("Failed to parse autoclean value"); goto fail; } u->filters = pa_hashmap_new(filter_hash, filter_compare); u->mdm_ignored_inputs = pa_hashmap_new_full(NULL, NULL, (pa_free_cb_t) unset_mdm_ignore_input, NULL); u->mdm_ignored_outputs = pa_hashmap_new_full(NULL, NULL, (pa_free_cb_t) unset_mdm_ignore_output, NULL); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_PUT], PA_HOOK_LATE, (pa_hook_cb_t) sink_input_put_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_MOVE_FINISH], PA_HOOK_LATE, (pa_hook_cb_t) sink_input_move_finish_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_PROPLIST_CHANGED], PA_HOOK_LATE, (pa_hook_cb_t) sink_input_proplist_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_INPUT_UNLINK], PA_HOOK_LATE, (pa_hook_cb_t) sink_input_unlink_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SINK_UNLINK], PA_HOOK_LATE-1, (pa_hook_cb_t) sink_unlink_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_PUT], PA_HOOK_LATE, (pa_hook_cb_t) source_output_put_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_MOVE_FINISH], PA_HOOK_LATE, (pa_hook_cb_t) source_output_move_finish_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_PROPLIST_CHANGED], PA_HOOK_LATE, (pa_hook_cb_t) source_output_proplist_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_OUTPUT_UNLINK], PA_HOOK_LATE, (pa_hook_cb_t) source_output_unlink_cb, u); pa_module_hook_connect(m, &m->core->hooks[PA_CORE_HOOK_SOURCE_UNLINK], PA_HOOK_LATE-1, (pa_hook_cb_t) source_unlink_cb, u); pa_modargs_free(ma); return 0; fail: pa__done(m); if (ma) pa_modargs_free(ma); return -1; } void pa__done(pa_module *m) { struct userdata* u; pa_assert(m); if (!(u = m->userdata)) return; if (u->housekeeping_time_event) u->core->mainloop->time_free(u->housekeeping_time_event); if (u->filters) { struct filter *f; while ((f = pa_hashmap_steal_first(u->filters))) { pa_module_unload_request_by_index(u->core, f->module_index, true); filter_free(f); } pa_hashmap_free(u->filters); } if (u->mdm_ignored_inputs) pa_hashmap_free(u->mdm_ignored_inputs); if (u->mdm_ignored_outputs) pa_hashmap_free(u->mdm_ignored_outputs); pa_xfree(u); }