/* * Clutter. * * An OpenGL based 'interactive canvas' library. * * Authored By Matthew Allum * * Copyright (C) 2006 OpenedHand * * This library 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 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, see . */ /** * SECTION:clutter-stage * @short_description: Top level visual element to which actors are placed. * * #ClutterStage is a top level 'window' on which child actors are placed * and manipulated. * * Backends might provide support for multiple stages. The support for this * feature can be checked at run-time using the clutter_feature_available() * function and the %CLUTTER_FEATURE_STAGE_MULTIPLE flag. If the backend used * supports multiple stages, new #ClutterStage instances can be created * using clutter_stage_new(). These stages must be managed by the developer * using clutter_actor_destroy(), which will take care of destroying all the * actors contained inside them. * * #ClutterStage is a proxy actor, wrapping the backend-specific implementation * (a #StageWindow) of the windowing system. It is possible to subclass * #ClutterStage, as long as every overridden virtual function chains up to the * parent class corresponding function. */ #include "clutter-build-config.h" #include #include #define CLUTTER_DISABLE_DEPRECATION_WARNINGS #define CLUTTER_ENABLE_EXPERIMENTAL_API #include "clutter-stage.h" #include "deprecated/clutter-stage.h" #include "deprecated/clutter-container.h" #include "clutter-actor-private.h" #include "clutter-backend-private.h" #include "clutter-cairo.h" #include "clutter-color.h" #include "clutter-container.h" #include "clutter-debug.h" #include "clutter-enum-types.h" #include "clutter-event-private.h" #include "clutter-id-pool.h" #include "clutter-input-device-private.h" #include "clutter-main.h" #include "clutter-marshal.h" #include "clutter-master-clock.h" #include "clutter-mutter.h" #include "clutter-paint-context-private.h" #include "clutter-paint-volume-private.h" #include "clutter-pick-context-private.h" #include "clutter-private.h" #include "clutter-stage-manager-private.h" #include "clutter-stage-private.h" #include "clutter-stage-view-private.h" #include "clutter-private.h" #include "cogl/cogl.h" struct _ClutterStageQueueRedrawEntry { ClutterActor *actor; gboolean has_clip; ClutterPaintVolume clip; }; typedef struct _PickRecord { graphene_point_t vertex[4]; ClutterActor *actor; int clip_stack_top; } PickRecord; typedef struct _PickClipRecord { int prev; graphene_point_t vertex[4]; } PickClipRecord; struct _ClutterStagePrivate { /* the stage implementation */ ClutterStageWindow *impl; ClutterPerspective perspective; CoglMatrix projection; CoglMatrix inverse_projection; CoglMatrix view; float viewport[4]; gchar *title; ClutterActor *key_focused_actor; GQueue *event_queue; GArray *paint_volume_stack; ClutterPlane current_clip_planes[4]; GHashTable *pending_relayouts; unsigned int pending_relayouts_version; GList *pending_queue_redraws; gint sync_delay; GTimer *fps_timer; gint32 timer_n_frames; GArray *pick_stack; GArray *pick_clip_stack; int pick_clip_stack_top; gboolean pick_stack_frozen; ClutterPickMode cached_pick_mode; #ifdef CLUTTER_ENABLE_DEBUG gulong redraw_count; #endif /* CLUTTER_ENABLE_DEBUG */ ClutterStageState current_state; gpointer paint_data; GDestroyNotify paint_notify; int update_freeze_count; guint redraw_pending : 1; guint is_cursor_visible : 1; guint throttle_motion_events : 1; guint use_alpha : 1; guint min_size_changed : 1; guint accept_focus : 1; guint motion_events_enabled : 1; guint has_custom_perspective : 1; guint stage_was_relayout : 1; }; enum { PROP_0, PROP_COLOR, PROP_CURSOR_VISIBLE, PROP_PERSPECTIVE, PROP_TITLE, PROP_USE_ALPHA, PROP_KEY_FOCUS, PROP_ACCEPT_FOCUS, PROP_LAST }; static GParamSpec *obj_props[PROP_LAST] = { NULL, }; enum { ACTIVATE, DEACTIVATE, DELETE_EVENT, AFTER_PAINT, PAINT_VIEW, PRESENTED, LAST_SIGNAL }; static guint stage_signals[LAST_SIGNAL] = { 0, }; static const ClutterColor default_stage_color = { 255, 255, 255, 255 }; static void clutter_stage_maybe_finish_queue_redraws (ClutterStage *stage); static void free_queue_redraw_entry (ClutterStageQueueRedrawEntry *entry); static void capture_view_into (ClutterStage *stage, gboolean paint, ClutterStageView *view, cairo_rectangle_int_t *rect, uint8_t *data, int stride); static void clutter_stage_update_view_perspective (ClutterStage *stage); static void clutter_container_iface_init (ClutterContainerIface *iface); G_DEFINE_TYPE_WITH_CODE (ClutterStage, clutter_stage, CLUTTER_TYPE_GROUP, G_ADD_PRIVATE (ClutterStage) G_IMPLEMENT_INTERFACE (CLUTTER_TYPE_CONTAINER, clutter_container_iface_init)) static void clutter_stage_real_add (ClutterContainer *container, ClutterActor *child) { clutter_actor_add_child (CLUTTER_ACTOR (container), child); } static void clutter_stage_real_remove (ClutterContainer *container, ClutterActor *child) { clutter_actor_remove_child (CLUTTER_ACTOR (container), child); } static void clutter_stage_real_raise (ClutterContainer *container, ClutterActor *child, ClutterActor *sibling) { clutter_actor_set_child_above_sibling (CLUTTER_ACTOR (container), child, sibling); } static void clutter_stage_real_lower (ClutterContainer *container, ClutterActor *child, ClutterActor *sibling) { clutter_actor_set_child_below_sibling (CLUTTER_ACTOR (container), child, sibling); } static void clutter_stage_real_sort_depth_order (ClutterContainer *container) { } static void clutter_container_iface_init (ClutterContainerIface *iface) { iface->add = clutter_stage_real_add; iface->remove = clutter_stage_real_remove; iface->raise = clutter_stage_real_raise; iface->lower = clutter_stage_real_lower; iface->sort_depth_order = clutter_stage_real_sort_depth_order; } static void clutter_stage_get_preferred_width (ClutterActor *self, gfloat for_height, gfloat *min_width_p, gfloat *natural_width_p) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; cairo_rectangle_int_t geom; if (priv->impl == NULL) return; _clutter_stage_window_get_geometry (priv->impl, &geom); if (min_width_p) *min_width_p = geom.width; if (natural_width_p) *natural_width_p = geom.width; } static void clutter_stage_get_preferred_height (ClutterActor *self, gfloat for_width, gfloat *min_height_p, gfloat *natural_height_p) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; cairo_rectangle_int_t geom; if (priv->impl == NULL) return; _clutter_stage_window_get_geometry (priv->impl, &geom); if (min_height_p) *min_height_p = geom.height; if (natural_height_p) *natural_height_p = geom.height; } static void add_pick_stack_weak_refs (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; int i; if (priv->pick_stack_frozen) return; for (i = 0; i < priv->pick_stack->len; i++) { PickRecord *rec = &g_array_index (priv->pick_stack, PickRecord, i); if (rec->actor) g_object_add_weak_pointer (G_OBJECT (rec->actor), (gpointer) &rec->actor); } priv->pick_stack_frozen = TRUE; } static void remove_pick_stack_weak_refs (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; int i; if (!priv->pick_stack_frozen) return; for (i = 0; i < priv->pick_stack->len; i++) { PickRecord *rec = &g_array_index (priv->pick_stack, PickRecord, i); if (rec->actor) g_object_remove_weak_pointer (G_OBJECT (rec->actor), (gpointer) &rec->actor); } priv->pick_stack_frozen = FALSE; } static void _clutter_stage_clear_pick_stack (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; remove_pick_stack_weak_refs (stage); g_array_set_size (priv->pick_stack, 0); g_array_set_size (priv->pick_clip_stack, 0); priv->pick_clip_stack_top = -1; priv->cached_pick_mode = CLUTTER_PICK_NONE; } void clutter_stage_log_pick (ClutterStage *stage, const graphene_point_t *vertices, ClutterActor *actor) { ClutterStagePrivate *priv; PickRecord rec; g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail (actor != NULL); priv = stage->priv; g_assert (!priv->pick_stack_frozen); memcpy (rec.vertex, vertices, 4 * sizeof (graphene_point_t)); rec.actor = actor; rec.clip_stack_top = priv->pick_clip_stack_top; g_array_append_val (priv->pick_stack, rec); } void clutter_stage_push_pick_clip (ClutterStage *stage, const graphene_point_t *vertices) { ClutterStagePrivate *priv; PickClipRecord clip; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; g_assert (!priv->pick_stack_frozen); clip.prev = priv->pick_clip_stack_top; memcpy (clip.vertex, vertices, 4 * sizeof (graphene_point_t)); g_array_append_val (priv->pick_clip_stack, clip); priv->pick_clip_stack_top = priv->pick_clip_stack->len - 1; } void clutter_stage_pop_pick_clip (ClutterStage *stage) { ClutterStagePrivate *priv; const PickClipRecord *top; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; g_assert (!priv->pick_stack_frozen); g_assert (priv->pick_clip_stack_top >= 0); /* Individual elements of pick_clip_stack are not freed. This is so they * can be shared as part of a tree of different stacks used by different * actors in the pick_stack. The whole pick_clip_stack does however get * freed later in _clutter_stage_clear_pick_stack. */ top = &g_array_index (priv->pick_clip_stack, PickClipRecord, priv->pick_clip_stack_top); priv->pick_clip_stack_top = top->prev; } static gboolean is_quadrilateral_axis_aligned_rectangle (const graphene_point_t *vertices) { int i; for (i = 0; i < 4; i++) { if (!G_APPROX_VALUE (vertices[i].x, vertices[(i + 1) % 4].x, FLT_EPSILON) && !G_APPROX_VALUE (vertices[i].y, vertices[(i + 1) % 4].y, FLT_EPSILON)) return FALSE; } return TRUE; } static gboolean is_inside_axis_aligned_rectangle (const graphene_point_t *point, const graphene_point_t *vertices) { float min_x = FLT_MAX; float max_x = -FLT_MAX; float min_y = FLT_MAX; float max_y = -FLT_MAX; int i; for (i = 0; i < 3; i++) { min_x = MIN (min_x, vertices[i].x); min_y = MIN (min_y, vertices[i].y); max_x = MAX (max_x, vertices[i].x); max_y = MAX (max_y, vertices[i].y); } return (point->x >= min_x && point->y >= min_y && point->x < max_x && point->y < max_y); } static int clutter_point_compare_line (const graphene_point_t *p, const graphene_point_t *a, const graphene_point_t *b) { graphene_vec3_t vec_pa; graphene_vec3_t vec_pb; graphene_vec3_t cross; float cross_z; graphene_vec3_init (&vec_pa, p->x - a->x, p->y - a->y, 0.f); graphene_vec3_init (&vec_pb, p->x - b->x, p->y - b->y, 0.f); graphene_vec3_cross (&vec_pa, &vec_pb, &cross); cross_z = graphene_vec3_get_z (&cross); if (cross_z > 0.f) return 1; else if (cross_z < 0.f) return -1; else return 0; } static gboolean is_inside_unaligned_rectangle (const graphene_point_t *point, const graphene_point_t *vertices) { unsigned int i; int first_side; first_side = 0; for (i = 0; i < 4; i++) { int side; side = clutter_point_compare_line (point, &vertices[i], &vertices[(i + 1) % 4]); if (side) { if (first_side == 0) first_side = side; else if (side != first_side) return FALSE; } } if (first_side == 0) return FALSE; return TRUE; } static gboolean is_inside_input_region (const graphene_point_t *point, const graphene_point_t *vertices) { if (is_quadrilateral_axis_aligned_rectangle (vertices)) return is_inside_axis_aligned_rectangle (point, vertices); else return is_inside_unaligned_rectangle (point, vertices); } static gboolean pick_record_contains_point (ClutterStage *stage, const PickRecord *rec, float x, float y) { const graphene_point_t point = GRAPHENE_POINT_INIT (x, y); ClutterStagePrivate *priv; int clip_index; if (!is_inside_input_region (&point, rec->vertex)) return FALSE; priv = stage->priv; clip_index = rec->clip_stack_top; while (clip_index >= 0) { const PickClipRecord *clip = &g_array_index (priv->pick_clip_stack, PickClipRecord, clip_index); if (!is_inside_input_region (&point, clip->vertex)) return FALSE; clip_index = clip->prev; } return TRUE; } static void clutter_stage_add_redraw_clip (ClutterStage *stage, cairo_rectangle_int_t *clip) { GList *l; for (l = _clutter_stage_peek_stage_views (stage); l; l = l->next) { ClutterStageView *view = l->data; if (!clip) { clutter_stage_view_add_redraw_clip (view, NULL); } else { cairo_rectangle_int_t view_layout; cairo_rectangle_int_t intersection; clutter_stage_view_get_layout (view, &view_layout); if (_clutter_util_rectangle_intersection (&view_layout, clip, &intersection)) clutter_stage_view_add_redraw_clip (view, &intersection); } } } static inline void queue_full_redraw (ClutterStage *stage) { ClutterStageWindow *stage_window; if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return; clutter_actor_queue_redraw (CLUTTER_ACTOR (stage)); /* Just calling clutter_actor_queue_redraw will typically only * redraw the bounding box of the children parented on the stage but * in this case we really need to ensure that the full stage is * redrawn so we add a NULL redraw clip to the stage window. */ stage_window = _clutter_stage_get_window (stage); if (stage_window == NULL) return; clutter_stage_add_redraw_clip (stage, NULL); } static gboolean stage_is_default (ClutterStage *stage) { ClutterStageManager *stage_manager; ClutterStageWindow *impl; stage_manager = clutter_stage_manager_get_default (); if (stage != clutter_stage_manager_get_default_stage (stage_manager)) return FALSE; impl = _clutter_stage_get_window (stage); if (impl != _clutter_stage_get_default_window ()) return FALSE; return TRUE; } static void clutter_stage_allocate (ClutterActor *self, const ClutterActorBox *box, ClutterAllocationFlags flags) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; ClutterActorBox alloc = CLUTTER_ACTOR_BOX_INIT_ZERO; float old_width, old_height; float new_width, new_height; float width, height; cairo_rectangle_int_t window_size; if (priv->impl == NULL) return; /* our old allocation */ clutter_actor_get_allocation_box (self, &alloc); clutter_actor_box_get_size (&alloc, &old_width, &old_height); /* the current allocation */ clutter_actor_box_get_size (box, &width, &height); /* the current Stage implementation size */ _clutter_stage_window_get_geometry (priv->impl, &window_size); /* if the stage is fixed size (for instance, it's using a EGL framebuffer) * then we simply ignore any allocation request and override the * allocation chain - because we cannot forcibly change the size of the * stage window. */ if (!clutter_feature_available (CLUTTER_FEATURE_STAGE_STATIC)) { CLUTTER_NOTE (LAYOUT, "Following allocation to %.2fx%.2f (absolute origin %s)", width, height, (flags & CLUTTER_ABSOLUTE_ORIGIN_CHANGED) ? "changed" : "not changed"); clutter_actor_set_allocation (self, box, flags | CLUTTER_DELEGATE_LAYOUT); /* Ensure the window is sized correctly */ if (priv->min_size_changed) { gfloat min_width, min_height; gboolean min_width_set, min_height_set; g_object_get (G_OBJECT (self), "min-width", &min_width, "min-width-set", &min_width_set, "min-height", &min_height, "min-height-set", &min_height_set, NULL); if (!min_width_set) min_width = 1; if (!min_height_set) min_height = 1; if (width < min_width) width = min_width; if (height < min_height) height = min_height; priv->min_size_changed = FALSE; } if (window_size.width != CLUTTER_NEARBYINT (width) || window_size.height != CLUTTER_NEARBYINT (height)) { _clutter_stage_window_resize (priv->impl, CLUTTER_NEARBYINT (width), CLUTTER_NEARBYINT (height)); } } else { ClutterActorBox override = { 0, }; /* override the passed allocation */ override.x1 = 0; override.y1 = 0; override.x2 = window_size.width; override.y2 = window_size.height; CLUTTER_NOTE (LAYOUT, "Overriding original allocation of %.2fx%.2f " "with %.2fx%.2f (absolute origin %s)", width, height, override.x2, override.y2, (flags & CLUTTER_ABSOLUTE_ORIGIN_CHANGED) ? "changed" : "not changed"); /* and store the overridden allocation */ clutter_actor_set_allocation (self, &override, flags | CLUTTER_DELEGATE_LAYOUT); } /* reset the viewport if the allocation effectively changed */ clutter_actor_get_allocation_box (self, &alloc); clutter_actor_box_get_size (&alloc, &new_width, &new_height); if (CLUTTER_NEARBYINT (old_width) != CLUTTER_NEARBYINT (new_width) || CLUTTER_NEARBYINT (old_height) != CLUTTER_NEARBYINT (new_height)) { int real_width = CLUTTER_NEARBYINT (new_width); int real_height = CLUTTER_NEARBYINT (new_height); _clutter_stage_set_viewport (CLUTTER_STAGE (self), 0, 0, real_width, real_height); /* Note: we don't assume that set_viewport will queue a full redraw * since it may bail-out early if something preemptively set the * viewport before the stage was really allocated its new size. */ queue_full_redraw (CLUTTER_STAGE (self)); } } typedef struct _Vector4 { float x, y, z, w; } Vector4; static void _cogl_util_get_eye_planes_for_screen_poly (float *polygon, int n_vertices, float *viewport, const CoglMatrix *projection, const CoglMatrix *inverse_project, ClutterPlane *planes) { float Wc; Vector4 *tmp_poly; ClutterPlane *plane; int i; Vector4 *poly; graphene_vec3_t b; graphene_vec3_t c; int count; tmp_poly = g_alloca (sizeof (Vector4) * n_vertices * 2); #define DEPTH -50 /* Determine W in clip-space (Wc) for a point (0, 0, DEPTH, 1) * * Note: the depth could be anything except 0. * * We will transform the polygon into clip coordinates using this * depth and then into eye coordinates. Our clip planes will be * defined by triangles that extend between points of the polygon at * DEPTH and corresponding points of the same polygon at DEPTH * 2. * * NB: Wc defines the position of the clip planes in clip * coordinates. Given a screen aligned cross section through the * frustum; coordinates range from [-Wc,Wc] left to right on the * x-axis and [Wc,-Wc] top to bottom on the y-axis. */ Wc = DEPTH * projection->wz + projection->ww; #define CLIP_X(X) ((((float)X - viewport[0]) * (2.0 / viewport[2])) - 1) * Wc #define CLIP_Y(Y) ((((float)Y - viewport[1]) * (2.0 / viewport[3])) - 1) * -Wc for (i = 0; i < n_vertices; i++) { tmp_poly[i].x = CLIP_X (polygon[i * 2]); tmp_poly[i].y = CLIP_Y (polygon[i * 2 + 1]); tmp_poly[i].z = DEPTH; tmp_poly[i].w = Wc; } Wc = DEPTH * 2 * projection->wz + projection->ww; /* FIXME: technically we don't need to project all of the points * twice, it would be enough project every other point since * we can share points in this set to define the plane vectors. */ for (i = 0; i < n_vertices; i++) { tmp_poly[n_vertices + i].x = CLIP_X (polygon[i * 2]); tmp_poly[n_vertices + i].y = CLIP_Y (polygon[i * 2 + 1]); tmp_poly[n_vertices + i].z = DEPTH * 2; tmp_poly[n_vertices + i].w = Wc; } #undef CLIP_X #undef CLIP_Y cogl_matrix_project_points (inverse_project, 4, sizeof (Vector4), tmp_poly, sizeof (Vector4), tmp_poly, n_vertices * 2); /* XXX: It's quite ugly that we end up with these casts between * Vector4 types and CoglVector3s, it might be better if the * cogl_vector APIs just took pointers to floats. */ count = n_vertices - 1; for (i = 0; i < count; i++) { plane = &planes[i]; poly = &tmp_poly[i]; graphene_vec3_init (&plane->v0, poly->x, poly->y, poly->z); poly = &tmp_poly[n_vertices + i]; graphene_vec3_init (&b, poly->x, poly->y, poly->z); poly = &tmp_poly[n_vertices + i + 1]; graphene_vec3_init (&c, poly->x, poly->y, poly->z); graphene_vec3_subtract (&b, &plane->v0, &b); graphene_vec3_subtract (&c, &plane->v0, &c); graphene_vec3_cross (&b, &c, &plane->n); graphene_vec3_normalize (&plane->n, &plane->n); } plane = &planes[n_vertices - 1]; poly = &tmp_poly[0]; graphene_vec3_init (&plane->v0, poly->x, poly->y, poly->z); poly = &tmp_poly[2 * n_vertices - 1]; graphene_vec3_init (&b, poly->x, poly->y, poly->z); poly = &tmp_poly[n_vertices]; graphene_vec3_init (&c, poly->x, poly->y, poly->z); graphene_vec3_subtract (&b, &plane->v0, &b); graphene_vec3_subtract (&c, &plane->v0, &c); graphene_vec3_cross (&b, &c, &plane->n); graphene_vec3_normalize (&plane->n, &plane->n); } /* XXX: Instead of having a toplevel 2D clip region, it might be * better to have a clip volume within the view frustum. This could * allow us to avoid projecting actors into window coordinates to * be able to cull them. */ static void setup_view_for_pick_or_paint (ClutterStage *stage, ClutterStageView *view, const cairo_rectangle_int_t *clip) { ClutterStagePrivate *priv = stage->priv; cairo_rectangle_int_t view_layout; float clip_poly[8]; float viewport[4]; cairo_rectangle_int_t geom; /* Any mode of painting/picking invalidates the pick cache, unless we're * in the middle of building it. So we reset the cached flag but don't * completely clear the pick stack. */ priv->cached_pick_mode = CLUTTER_PICK_NONE; _clutter_stage_window_get_geometry (priv->impl, &geom); viewport[0] = priv->viewport[0]; viewport[1] = priv->viewport[1]; viewport[2] = priv->viewport[2]; viewport[3] = priv->viewport[3]; if (!clip) { clutter_stage_view_get_layout (view, &view_layout); clip = &view_layout; } clip_poly[0] = MAX (clip->x, 0); clip_poly[1] = MAX (clip->y, 0); clip_poly[2] = MIN (clip->x + clip->width, geom.width); clip_poly[3] = clip_poly[1]; clip_poly[4] = clip_poly[2]; clip_poly[5] = MIN (clip->y + clip->height, geom.height); clip_poly[6] = clip_poly[0]; clip_poly[7] = clip_poly[5]; CLUTTER_NOTE (CLIPPING, "Setting stage clip too: " "x=%f, y=%f, width=%f, height=%f", clip_poly[0], clip_poly[1], clip_poly[2] - clip_poly[0], clip_poly[5] - clip_poly[1]); _cogl_util_get_eye_planes_for_screen_poly (clip_poly, 4, viewport, &priv->projection, &priv->inverse_projection, priv->current_clip_planes); _clutter_stage_paint_volume_stack_free_all (stage); } static void clutter_stage_do_paint_view (ClutterStage *stage, ClutterStageView *view, const cairo_region_t *redraw_clip) { ClutterPaintContext *paint_context; cairo_rectangle_int_t clip_rect; paint_context = clutter_paint_context_new_for_view (view, redraw_clip); cairo_region_get_extents (redraw_clip, &clip_rect); setup_view_for_pick_or_paint (stage, view, &clip_rect); clutter_actor_paint (CLUTTER_ACTOR (stage), paint_context); clutter_paint_context_destroy (paint_context); } /* This provides a common point of entry for painting the scenegraph * for picking or painting... */ void clutter_stage_paint_view (ClutterStage *stage, ClutterStageView *view, const cairo_region_t *redraw_clip) { ClutterStagePrivate *priv = stage->priv; if (!priv->impl) return; COGL_TRACE_BEGIN_SCOPED (ClutterStagePaintView, "Paint (view)"); if (g_signal_has_handler_pending (stage, stage_signals[PAINT_VIEW], 0, TRUE)) g_signal_emit (stage, stage_signals[PAINT_VIEW], 0, view, redraw_clip); else CLUTTER_STAGE_GET_CLASS (stage)->paint_view (stage, view, redraw_clip); } void _clutter_stage_emit_after_paint (ClutterStage *stage) { g_signal_emit (stage, stage_signals[AFTER_PAINT], 0); } /* If we don't implement this here, we get the paint function * from the deprecated clutter-group class, which doesn't * respect the Z order as it uses our empty sort_depth_order. */ static void clutter_stage_paint (ClutterActor *self, ClutterPaintContext *paint_context) { ClutterActorIter iter; ClutterActor *child; clutter_actor_iter_init (&iter, self); while (clutter_actor_iter_next (&iter, &child)) clutter_actor_paint (child, paint_context); } static void clutter_stage_pick (ClutterActor *self, ClutterPickContext *pick_context) { ClutterActorIter iter; ClutterActor *child; /* Note: we don't chain up to our parent as we don't want any geometry * emitted for the stage itself. The stage's pick id is effectively handled * by the call to cogl_clear done in clutter-main.c:_clutter_do_pick_async() */ clutter_actor_iter_init (&iter, self); while (clutter_actor_iter_next (&iter, &child)) clutter_actor_pick (child, pick_context); } static gboolean clutter_stage_get_paint_volume (ClutterActor *self, ClutterPaintVolume *volume) { /* Returning False effectively means Clutter has to assume it covers * everything... */ return FALSE; } static void clutter_stage_realize (ClutterActor *self) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; gboolean is_realized; g_assert (priv->impl != NULL); is_realized = _clutter_stage_window_realize (priv->impl); if (!is_realized) CLUTTER_ACTOR_UNSET_FLAGS (self, CLUTTER_ACTOR_REALIZED); } static void clutter_stage_unrealize (ClutterActor *self) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; /* and then unrealize the implementation */ g_assert (priv->impl != NULL); _clutter_stage_window_unrealize (priv->impl); CLUTTER_ACTOR_UNSET_FLAGS (self, CLUTTER_ACTOR_REALIZED); } static void clutter_stage_show_all (ClutterActor *self) { ClutterActorIter iter; ClutterActor *child; /* we don't do a recursive show_all(), to maintain the old * invariants from ClutterGroup */ clutter_actor_iter_init (&iter, self); while (clutter_actor_iter_next (&iter, &child)) clutter_actor_show (child); clutter_actor_show (self); } static void clutter_stage_show (ClutterActor *self) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; CLUTTER_ACTOR_CLASS (clutter_stage_parent_class)->show (self); /* Possibly do an allocation run so that the stage will have the right size before we map it */ _clutter_stage_maybe_relayout (self); g_assert (priv->impl != NULL); _clutter_stage_window_show (priv->impl, TRUE); } static void clutter_stage_hide_all (ClutterActor *self) { ClutterActorIter iter; ClutterActor *child; clutter_actor_hide (self); /* we don't do a recursive hide_all(), to maintain the old invariants * from ClutterGroup */ clutter_actor_iter_init (&iter, self); while (clutter_actor_iter_next (&iter, &child)) clutter_actor_hide (child); } static void clutter_stage_hide (ClutterActor *self) { ClutterStagePrivate *priv = CLUTTER_STAGE (self)->priv; g_assert (priv->impl != NULL); _clutter_stage_window_hide (priv->impl); CLUTTER_ACTOR_CLASS (clutter_stage_parent_class)->hide (self); } static void clutter_stage_emit_key_focus_event (ClutterStage *stage, gboolean focus_in) { ClutterStagePrivate *priv = stage->priv; if (priv->key_focused_actor == NULL) return; _clutter_actor_set_has_key_focus (CLUTTER_ACTOR (stage), focus_in); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_KEY_FOCUS]); } static void clutter_stage_real_activate (ClutterStage *stage) { clutter_stage_emit_key_focus_event (stage, TRUE); } static void clutter_stage_real_deactivate (ClutterStage *stage) { clutter_stage_emit_key_focus_event (stage, FALSE); } void _clutter_stage_queue_event (ClutterStage *stage, ClutterEvent *event, gboolean copy_event) { ClutterStagePrivate *priv; gboolean first_event; ClutterInputDevice *device; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; first_event = priv->event_queue->length == 0; if (copy_event) event = clutter_event_copy (event); /* if needed, update the state of the input device of the event. * we do it here to avoid calling the same code from every backend * event processing function */ device = clutter_event_get_device (event); if (device != NULL && event->type != CLUTTER_PROXIMITY_IN && event->type != CLUTTER_PROXIMITY_OUT) { ClutterModifierType event_state = clutter_event_get_state (event); ClutterEventSequence *sequence = clutter_event_get_event_sequence (event); guint32 event_time = clutter_event_get_time (event); gfloat event_x, event_y; clutter_event_get_coords (event, &event_x, &event_y); _clutter_input_device_set_coords (device, sequence, event_x, event_y, stage); _clutter_input_device_set_state (device, event_state); _clutter_input_device_set_time (device, event_time); } if (first_event) { gboolean compressible = event->type == CLUTTER_MOTION || event->type == CLUTTER_TOUCH_UPDATE; if (!compressible) { _clutter_process_event (event); clutter_event_free (event); return; } } g_queue_push_tail (priv->event_queue, event); if (first_event) { ClutterMasterClock *master_clock = _clutter_master_clock_get_default (); _clutter_master_clock_start_running (master_clock); _clutter_stage_schedule_update (stage); } } gboolean _clutter_stage_has_queued_events (ClutterStage *stage) { ClutterStagePrivate *priv; g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); priv = stage->priv; return priv->event_queue->length > 0; } void _clutter_stage_process_queued_events (ClutterStage *stage) { ClutterStagePrivate *priv; GList *events, *l; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (priv->event_queue->length == 0) return; /* In case the stage gets destroyed during event processing */ g_object_ref (stage); /* Steal events before starting processing to avoid reentrancy * issues */ events = priv->event_queue->head; priv->event_queue->head = NULL; priv->event_queue->tail = NULL; priv->event_queue->length = 0; for (l = events; l != NULL; l = l->next) { ClutterEvent *event; ClutterEvent *next_event; ClutterInputDevice *device; ClutterInputDevice *next_device; ClutterInputDeviceType device_type; gboolean check_device = FALSE; event = l->data; next_event = l->next ? l->next->data : NULL; device = clutter_event_get_device (event); if (next_event != NULL) next_device = clutter_event_get_device (next_event); else next_device = NULL; if (device != NULL && next_device != NULL) check_device = TRUE; device_type = clutter_input_device_get_device_type (device); /* Skip consecutive motion events coming from the same device, * except those of tablet tools, since users of these events * want no precision loss. */ if (priv->throttle_motion_events && next_event != NULL && device_type != CLUTTER_TABLET_DEVICE && device_type != CLUTTER_PEN_DEVICE && device_type != CLUTTER_ERASER_DEVICE) { if (event->type == CLUTTER_MOTION && (next_event->type == CLUTTER_MOTION || next_event->type == CLUTTER_LEAVE) && (!check_device || (device == next_device))) { CLUTTER_NOTE (EVENT, "Omitting motion event at %d, %d", (int) event->motion.x, (int) event->motion.y); if (next_event->type == CLUTTER_MOTION) { ClutterSeat *seat = clutter_input_device_get_seat (device); clutter_seat_compress_motion (seat, next_event, event); } goto next_event; } else if (event->type == CLUTTER_TOUCH_UPDATE && next_event->type == CLUTTER_TOUCH_UPDATE && event->touch.sequence == next_event->touch.sequence && (!check_device || (device == next_device))) { CLUTTER_NOTE (EVENT, "Omitting touch update event at %d, %d", (int) event->touch.x, (int) event->touch.y); goto next_event; } } _clutter_process_event (event); next_event: clutter_event_free (event); } g_list_free (events); g_object_unref (stage); } /** * _clutter_stage_needs_update: * @stage: A #ClutterStage * * Determines if _clutter_stage_do_update() needs to be called. * * Return value: %TRUE if the stage need layout or painting */ gboolean _clutter_stage_needs_update (ClutterStage *stage) { ClutterStagePrivate *priv; g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); priv = stage->priv; return priv->redraw_pending || g_hash_table_size (priv->pending_relayouts) > 0; } void clutter_stage_queue_actor_relayout (ClutterStage *stage, ClutterActor *actor) { ClutterStagePrivate *priv = stage->priv; if (g_hash_table_contains (priv->pending_relayouts, stage)) return; if (g_hash_table_size (priv->pending_relayouts) == 0) _clutter_stage_schedule_update (stage); if (actor == (ClutterActor *) stage) g_hash_table_remove_all (priv->pending_relayouts); g_hash_table_add (priv->pending_relayouts, g_object_ref (actor)); priv->pending_relayouts_version++; } void _clutter_stage_maybe_relayout (ClutterActor *actor) { ClutterStage *stage = CLUTTER_STAGE (actor); ClutterStagePrivate *priv = stage->priv; GHashTableIter iter; gpointer key; int count = 0; /* No work to do? Avoid the extraneous debug log messages too. */ if (g_hash_table_size (priv->pending_relayouts) == 0) return; CLUTTER_NOTE (ACTOR, ">>> Recomputing layout"); g_hash_table_iter_init (&iter, priv->pending_relayouts); while (g_hash_table_iter_next (&iter, &key, NULL)) { g_autoptr (ClutterActor) queued_actor = key; unsigned int old_version; g_hash_table_iter_steal (&iter); priv->pending_relayouts_version++; if (CLUTTER_ACTOR_IN_RELAYOUT (queued_actor)) /* avoid reentrancy */ continue; /* An actor may have been destroyed or hidden between queuing and now */ if (clutter_actor_get_stage (queued_actor) != actor) continue; if (queued_actor == actor) CLUTTER_NOTE (ACTOR, " Deep relayout of stage %s", _clutter_actor_get_debug_name (queued_actor)); else CLUTTER_NOTE (ACTOR, " Shallow relayout of actor %s", _clutter_actor_get_debug_name (queued_actor)); CLUTTER_SET_PRIVATE_FLAGS (queued_actor, CLUTTER_IN_RELAYOUT); old_version = priv->pending_relayouts_version; clutter_actor_allocate_preferred_size (queued_actor, CLUTTER_ALLOCATION_NONE); CLUTTER_UNSET_PRIVATE_FLAGS (queued_actor, CLUTTER_IN_RELAYOUT); count++; /* Prevent using an iterator that's been invalidated */ if (old_version != priv->pending_relayouts_version) g_hash_table_iter_init (&iter, priv->pending_relayouts); } CLUTTER_NOTE (ACTOR, "<<< Completed recomputing layout of %d subtrees", count); if (count) priv->stage_was_relayout = TRUE; } static void clutter_stage_do_redraw (ClutterStage *stage) { ClutterActor *actor = CLUTTER_ACTOR (stage); ClutterStagePrivate *priv = stage->priv; if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return; if (priv->impl == NULL) return; CLUTTER_NOTE (PAINT, "Redraw started for stage '%s'[%p]", _clutter_actor_get_debug_name (actor), stage); if (_clutter_context_get_show_fps ()) { if (priv->fps_timer == NULL) priv->fps_timer = g_timer_new (); } _clutter_stage_window_redraw (priv->impl); if (_clutter_context_get_show_fps ()) { priv->timer_n_frames += 1; if (g_timer_elapsed (priv->fps_timer, NULL) >= 1.0) { g_print ("*** FPS for %s: %i ***\n", _clutter_actor_get_debug_name (actor), priv->timer_n_frames); priv->timer_n_frames = 0; g_timer_start (priv->fps_timer); } } CLUTTER_NOTE (PAINT, "Redraw finished for stage '%s'[%p]", _clutter_actor_get_debug_name (actor), stage); } static GSList * _clutter_stage_check_updated_pointers (ClutterStage *stage) { ClutterBackend *backend; ClutterSeat *seat; GSList *updating = NULL; GList *l, *devices; graphene_point_t point; backend = clutter_get_default_backend (); seat = clutter_backend_get_default_seat (backend); devices = clutter_seat_list_devices (seat); for (l = devices; l; l = l->next) { ClutterInputDevice *dev = l->data; ClutterStageView *view; const cairo_region_t *clip; if (clutter_input_device_get_device_mode (dev) != CLUTTER_INPUT_MODE_MASTER) continue; switch (clutter_input_device_get_device_type (dev)) { case CLUTTER_POINTER_DEVICE: case CLUTTER_TABLET_DEVICE: case CLUTTER_PEN_DEVICE: case CLUTTER_ERASER_DEVICE: case CLUTTER_CURSOR_DEVICE: if (!clutter_input_device_get_coords (dev, NULL, &point)) continue; view = clutter_stage_get_view_at (stage, point.x, point.y); if (!view) continue; clip = clutter_stage_view_peek_redraw_clip (view); if (!clip || cairo_region_contains_point (clip, point.x, point.y)) updating = g_slist_prepend (updating, dev); break; default: /* Any other devices don't need checking, either because they * don't have x/y coordinates, or because they're implicitly * grabbed on an actor by default as it's the case of * touch(screens). */ break; } } g_list_free (devices); return updating; } /** * _clutter_stage_do_update: * @stage: A #ClutterStage * * Handles per-frame layout and repaint for the stage. * * Return value: %TRUE if the stage was updated */ gboolean _clutter_stage_do_update (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; gboolean stage_was_relayout = priv->stage_was_relayout; GSList *pointers = NULL; priv->stage_was_relayout = FALSE; /* if the stage is being destroyed, or if the destruction already * happened and we don't have an StageWindow any more, then we * should bail out */ if (CLUTTER_ACTOR_IN_DESTRUCTION (stage) || priv->impl == NULL) return FALSE; if (!CLUTTER_ACTOR_IS_REALIZED (stage)) return FALSE; COGL_TRACE_BEGIN_SCOPED (ClutterStageDoUpdate, "Update"); /* NB: We need to ensure we have an up to date layout *before* we * check or clear the pending redraws flag since a relayout may * queue a redraw. */ COGL_TRACE_BEGIN (ClutterStageRelayout, "Layout"); _clutter_stage_maybe_relayout (CLUTTER_ACTOR (stage)); COGL_TRACE_END (ClutterStageRelayout); if (!priv->redraw_pending) return FALSE; if (stage_was_relayout) pointers = _clutter_stage_check_updated_pointers (stage); COGL_TRACE_BEGIN (ClutterStagePaint, "Paint"); clutter_stage_maybe_finish_queue_redraws (stage); clutter_stage_do_redraw (stage); COGL_TRACE_END (ClutterStagePaint); /* reset the guard, so that new redraws are possible */ priv->redraw_pending = FALSE; #ifdef CLUTTER_ENABLE_DEBUG if (priv->redraw_count > 0) { CLUTTER_NOTE (SCHEDULER, "Queued %lu redraws during the last cycle", priv->redraw_count); priv->redraw_count = 0; } #endif /* CLUTTER_ENABLE_DEBUG */ COGL_TRACE_BEGIN (ClutterStagePick, "Pick"); while (pointers) { clutter_input_device_update (pointers->data, NULL, TRUE); pointers = g_slist_delete_link (pointers, pointers); } COGL_TRACE_END (ClutterStagePick); return TRUE; } static void clutter_stage_real_queue_relayout (ClutterActor *self) { ClutterStage *stage = CLUTTER_STAGE (self); ClutterActorClass *parent_class; clutter_stage_queue_actor_relayout (stage, self); /* chain up */ parent_class = CLUTTER_ACTOR_CLASS (clutter_stage_parent_class); parent_class->queue_relayout (self); } static gboolean is_full_stage_redraw_queued (ClutterStage *stage) { GList *l; for (l = _clutter_stage_peek_stage_views (stage); l; l = l->next) { ClutterStageView *view = l->data; if (!clutter_stage_view_has_full_redraw_clip (view)) return FALSE; } return TRUE; } static gboolean clutter_stage_real_queue_redraw (ClutterActor *actor, ClutterActor *leaf, ClutterPaintVolume *redraw_clip) { ClutterStage *stage = CLUTTER_STAGE (actor); ClutterStageWindow *stage_window; ClutterActorBox bounding_box; ClutterActorBox intersection_box; cairo_rectangle_int_t geom, stage_clip; if (CLUTTER_ACTOR_IN_DESTRUCTION (actor)) return TRUE; /* If the backend can't do anything with redraw clips (e.g. it already knows * it needs to redraw everything anyway) then don't spend time transforming * any clip volume into stage coordinates... */ stage_window = _clutter_stage_get_window (stage); if (stage_window == NULL) return TRUE; if (is_full_stage_redraw_queued (stage)) return FALSE; if (redraw_clip == NULL) { clutter_stage_add_redraw_clip (stage, NULL); return FALSE; } if (redraw_clip->is_empty) return TRUE; /* Convert the clip volume into stage coordinates and then into an * axis aligned stage coordinates bounding box... */ _clutter_paint_volume_get_stage_paint_box (redraw_clip, stage, &bounding_box); _clutter_stage_window_get_geometry (stage_window, &geom); intersection_box.x1 = MAX (bounding_box.x1, 0); intersection_box.y1 = MAX (bounding_box.y1, 0); intersection_box.x2 = MIN (bounding_box.x2, geom.width); intersection_box.y2 = MIN (bounding_box.y2, geom.height); /* There is no need to track degenerate/empty redraw clips */ if (intersection_box.x2 <= intersection_box.x1 || intersection_box.y2 <= intersection_box.y1) return TRUE; /* when converting to integer coordinates make sure we round the edges of the * clip rectangle outwards... */ stage_clip.x = intersection_box.x1; stage_clip.y = intersection_box.y1; stage_clip.width = intersection_box.x2 - stage_clip.x; stage_clip.height = intersection_box.y2 - stage_clip.y; clutter_stage_add_redraw_clip (stage, &stage_clip); return FALSE; } gboolean _clutter_stage_has_full_redraw_queued (ClutterStage *stage) { if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return FALSE; if (!stage->priv->redraw_pending) return FALSE; return is_full_stage_redraw_queued (stage); } static ClutterActor * _clutter_stage_do_pick_on_view (ClutterStage *stage, float x, float y, ClutterPickMode mode, ClutterStageView *view) { ClutterMainContext *context = _clutter_context_get_default (); ClutterStagePrivate *priv = stage->priv; int i; g_assert (context->pick_mode == CLUTTER_PICK_NONE); if (mode != priv->cached_pick_mode) { ClutterPickContext *pick_context; _clutter_stage_clear_pick_stack (stage); pick_context = clutter_pick_context_new_for_view (view); context->pick_mode = mode; setup_view_for_pick_or_paint (stage, view, NULL); clutter_actor_pick (CLUTTER_ACTOR (stage), pick_context); context->pick_mode = CLUTTER_PICK_NONE; priv->cached_pick_mode = mode; clutter_pick_context_destroy (pick_context); add_pick_stack_weak_refs (stage); } /* Search all "painted" pickable actors from front to back. A linear search * is required, and also performs fine since there is typically only * on the order of dozens of actors in the list (on screen) at a time. */ for (i = priv->pick_stack->len - 1; i >= 0; i--) { const PickRecord *rec = &g_array_index (priv->pick_stack, PickRecord, i); if (rec->actor && pick_record_contains_point (stage, rec, x, y)) return rec->actor; } return CLUTTER_ACTOR (stage); } /** * clutter_stage_get_view_at: (skip) */ ClutterStageView * clutter_stage_get_view_at (ClutterStage *stage, float x, float y) { ClutterStagePrivate *priv = stage->priv; GList *l; for (l = _clutter_stage_window_get_views (priv->impl); l; l = l->next) { ClutterStageView *view = l->data; cairo_rectangle_int_t view_layout; clutter_stage_view_get_layout (view, &view_layout); if (x >= view_layout.x && x < view_layout.x + view_layout.width && y >= view_layout.y && y < view_layout.y + view_layout.height) return view; } return NULL; } ClutterActor * _clutter_stage_do_pick (ClutterStage *stage, float x, float y, ClutterPickMode mode) { ClutterActor *actor = CLUTTER_ACTOR (stage); ClutterStagePrivate *priv = stage->priv; float stage_width, stage_height; ClutterStageView *view = NULL; priv = stage->priv; if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return actor; if (G_UNLIKELY (clutter_pick_debug_flags & CLUTTER_DEBUG_NOP_PICKING)) return actor; if (G_UNLIKELY (priv->impl == NULL)) return actor; clutter_actor_get_size (CLUTTER_ACTOR (stage), &stage_width, &stage_height); if (x < 0 || x >= stage_width || y < 0 || y >= stage_height) return actor; view = clutter_stage_get_view_at (stage, x, y); if (view) return _clutter_stage_do_pick_on_view (stage, x, y, mode, view); return actor; } static gboolean clutter_stage_real_delete_event (ClutterStage *stage, ClutterEvent *event) { if (stage_is_default (stage)) clutter_main_quit (); else clutter_actor_destroy (CLUTTER_ACTOR (stage)); return CLUTTER_EVENT_STOP; } static void clutter_stage_real_apply_transform (ClutterActor *stage, CoglMatrix *matrix) { ClutterStagePrivate *priv = CLUTTER_STAGE (stage)->priv; /* FIXME: we probably shouldn't be explicitly reseting the matrix * here... */ cogl_matrix_init_identity (matrix); cogl_matrix_multiply (matrix, matrix, &priv->view); } static void clutter_stage_constructed (GObject *gobject) { ClutterStage *self = CLUTTER_STAGE (gobject); ClutterStageManager *stage_manager; stage_manager = clutter_stage_manager_get_default (); /* this will take care to sinking the floating reference */ _clutter_stage_manager_add_stage (stage_manager, self); /* if this stage has been created on a backend that does not * support multiple stages then it becomes the default stage * as well; any other attempt at creating a ClutterStage will * fail. */ if (!clutter_feature_available (CLUTTER_FEATURE_STAGE_MULTIPLE)) { if (G_UNLIKELY (clutter_stage_manager_get_default_stage (stage_manager) != NULL)) { g_error ("Unable to create another stage: the backend of " "type '%s' does not support multiple stages. Use " "clutter_stage_manager_get_default_stage() instead " "to access the stage singleton.", G_OBJECT_TYPE_NAME (clutter_get_default_backend ())); } _clutter_stage_manager_set_default_stage (stage_manager, self); } G_OBJECT_CLASS (clutter_stage_parent_class)->constructed (gobject); } static void clutter_stage_set_property (GObject *object, guint prop_id, const GValue *value, GParamSpec *pspec) { ClutterStage *stage = CLUTTER_STAGE (object); switch (prop_id) { case PROP_COLOR: clutter_actor_set_background_color (CLUTTER_ACTOR (stage), clutter_value_get_color (value)); break; case PROP_CURSOR_VISIBLE: if (g_value_get_boolean (value)) clutter_stage_show_cursor (stage); else clutter_stage_hide_cursor (stage); break; case PROP_PERSPECTIVE: clutter_stage_set_perspective (stage, g_value_get_boxed (value)); break; case PROP_TITLE: clutter_stage_set_title (stage, g_value_get_string (value)); break; case PROP_USE_ALPHA: clutter_stage_set_use_alpha (stage, g_value_get_boolean (value)); break; case PROP_KEY_FOCUS: clutter_stage_set_key_focus (stage, g_value_get_object (value)); break; case PROP_ACCEPT_FOCUS: clutter_stage_set_accept_focus (stage, g_value_get_boolean (value)); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (object, prop_id, pspec); break; } } static void clutter_stage_get_property (GObject *gobject, guint prop_id, GValue *value, GParamSpec *pspec) { ClutterStagePrivate *priv = CLUTTER_STAGE (gobject)->priv; switch (prop_id) { case PROP_COLOR: { ClutterColor bg_color; clutter_actor_get_background_color (CLUTTER_ACTOR (gobject), &bg_color); clutter_value_set_color (value, &bg_color); } break; case PROP_CURSOR_VISIBLE: g_value_set_boolean (value, priv->is_cursor_visible); break; case PROP_PERSPECTIVE: g_value_set_boxed (value, &priv->perspective); break; case PROP_TITLE: g_value_set_string (value, priv->title); break; case PROP_USE_ALPHA: g_value_set_boolean (value, priv->use_alpha); break; case PROP_KEY_FOCUS: g_value_set_object (value, priv->key_focused_actor); break; case PROP_ACCEPT_FOCUS: g_value_set_boolean (value, priv->accept_focus); break; default: G_OBJECT_WARN_INVALID_PROPERTY_ID (gobject, prop_id, pspec); break; } } static void clutter_stage_dispose (GObject *object) { ClutterStage *stage = CLUTTER_STAGE (object); ClutterStagePrivate *priv = stage->priv; ClutterStageManager *stage_manager; clutter_actor_hide (CLUTTER_ACTOR (object)); _clutter_clear_events_queue_for_stage (stage); if (priv->impl != NULL) { CLUTTER_NOTE (BACKEND, "Disposing of the stage implementation"); if (CLUTTER_ACTOR_IS_REALIZED (object)) _clutter_stage_window_unrealize (priv->impl); g_object_unref (priv->impl); priv->impl = NULL; } clutter_actor_destroy_all_children (CLUTTER_ACTOR (object)); g_list_free_full (priv->pending_queue_redraws, (GDestroyNotify) free_queue_redraw_entry); priv->pending_queue_redraws = NULL; g_clear_pointer (&priv->pending_relayouts, g_hash_table_destroy); /* this will release the reference on the stage */ stage_manager = clutter_stage_manager_get_default (); _clutter_stage_manager_remove_stage (stage_manager, stage); G_OBJECT_CLASS (clutter_stage_parent_class)->dispose (object); } static void clutter_stage_finalize (GObject *object) { ClutterStage *stage = CLUTTER_STAGE (object); ClutterStagePrivate *priv = stage->priv; g_queue_foreach (priv->event_queue, (GFunc) clutter_event_free, NULL); g_queue_free (priv->event_queue); g_free (priv->title); g_array_free (priv->paint_volume_stack, TRUE); _clutter_stage_clear_pick_stack (stage); g_array_free (priv->pick_clip_stack, TRUE); g_array_free (priv->pick_stack, TRUE); if (priv->fps_timer != NULL) g_timer_destroy (priv->fps_timer); if (priv->paint_notify != NULL) priv->paint_notify (priv->paint_data); G_OBJECT_CLASS (clutter_stage_parent_class)->finalize (object); } static void clutter_stage_real_paint_view (ClutterStage *stage, ClutterStageView *view, const cairo_region_t *redraw_clip) { clutter_stage_do_paint_view (stage, view, redraw_clip); } static void clutter_stage_class_init (ClutterStageClass *klass) { GObjectClass *gobject_class = G_OBJECT_CLASS (klass); ClutterActorClass *actor_class = CLUTTER_ACTOR_CLASS (klass); gobject_class->constructed = clutter_stage_constructed; gobject_class->set_property = clutter_stage_set_property; gobject_class->get_property = clutter_stage_get_property; gobject_class->dispose = clutter_stage_dispose; gobject_class->finalize = clutter_stage_finalize; actor_class->allocate = clutter_stage_allocate; actor_class->get_preferred_width = clutter_stage_get_preferred_width; actor_class->get_preferred_height = clutter_stage_get_preferred_height; actor_class->paint = clutter_stage_paint; actor_class->pick = clutter_stage_pick; actor_class->get_paint_volume = clutter_stage_get_paint_volume; actor_class->realize = clutter_stage_realize; actor_class->unrealize = clutter_stage_unrealize; actor_class->show = clutter_stage_show; actor_class->show_all = clutter_stage_show_all; actor_class->hide = clutter_stage_hide; actor_class->hide_all = clutter_stage_hide_all; actor_class->queue_relayout = clutter_stage_real_queue_relayout; actor_class->queue_redraw = clutter_stage_real_queue_redraw; actor_class->apply_transform = clutter_stage_real_apply_transform; klass->paint_view = clutter_stage_real_paint_view; /** * ClutterStage:cursor-visible: * * Whether the mouse pointer should be visible */ obj_props[PROP_CURSOR_VISIBLE] = g_param_spec_boolean ("cursor-visible", P_("Cursor Visible"), P_("Whether the mouse pointer is visible on the main stage"), TRUE, CLUTTER_PARAM_READWRITE); /** * ClutterStage:color: * * The background color of the main stage. * * Deprecated: 1.10: Use the #ClutterActor:background-color property of * #ClutterActor instead. */ obj_props[PROP_COLOR] = clutter_param_spec_color ("color", P_("Color"), P_("The color of the stage"), &default_stage_color, CLUTTER_PARAM_READWRITE | G_PARAM_DEPRECATED); /** * ClutterStage:perspective: * * The parameters used for the perspective projection from 3D * coordinates to 2D * * Since: 0.8 */ obj_props[PROP_PERSPECTIVE] = g_param_spec_boxed ("perspective", P_("Perspective"), P_("Perspective projection parameters"), CLUTTER_TYPE_PERSPECTIVE, CLUTTER_PARAM_READWRITE); /** * ClutterStage:title: * * The stage's title - usually displayed in stage windows title decorations. * * Since: 0.4 */ obj_props[PROP_TITLE] = g_param_spec_string ("title", P_("Title"), P_("Stage Title"), NULL, CLUTTER_PARAM_READWRITE); /** * ClutterStage:use-alpha: * * Whether the #ClutterStage should honour the alpha component of the * #ClutterStage:color property when painting. If Clutter is run under * a compositing manager this will result in the stage being blended * with the underlying window(s) * * Since: 1.2 */ obj_props[PROP_USE_ALPHA] = g_param_spec_boolean ("use-alpha", P_("Use Alpha"), P_("Whether to honour the alpha component of the stage color"), FALSE, CLUTTER_PARAM_READWRITE); /** * ClutterStage:key-focus: * * The #ClutterActor that will receive key events from the underlying * windowing system. * * If %NULL, the #ClutterStage will receive the events. * * Since: 1.2 */ obj_props[PROP_KEY_FOCUS] = g_param_spec_object ("key-focus", P_("Key Focus"), P_("The currently key focused actor"), CLUTTER_TYPE_ACTOR, CLUTTER_PARAM_READWRITE); /** * ClutterStage:accept-focus: * * Whether the #ClutterStage should accept key focus when shown. * * Since: 1.6 */ obj_props[PROP_ACCEPT_FOCUS] = g_param_spec_boolean ("accept-focus", P_("Accept Focus"), P_("Whether the stage should accept focus on show"), TRUE, CLUTTER_PARAM_READWRITE); g_object_class_install_properties (gobject_class, PROP_LAST, obj_props); /** * ClutterStage::activate: * @stage: the stage which was activated * * The ::activate signal is emitted when the stage receives key focus * from the underlying window system. * * Since: 0.6 */ stage_signals[ACTIVATE] = g_signal_new (I_("activate"), G_TYPE_FROM_CLASS (gobject_class), G_SIGNAL_RUN_LAST, G_STRUCT_OFFSET (ClutterStageClass, activate), NULL, NULL, NULL, G_TYPE_NONE, 0); /** * ClutterStage::deactivate: * @stage: the stage which was deactivated * * The ::deactivate signal is emitted when the stage loses key focus * from the underlying window system. * * Since: 0.6 */ stage_signals[DEACTIVATE] = g_signal_new (I_("deactivate"), G_TYPE_FROM_CLASS (gobject_class), G_SIGNAL_RUN_LAST, G_STRUCT_OFFSET (ClutterStageClass, deactivate), NULL, NULL, NULL, G_TYPE_NONE, 0); /** * ClutterStage::delete-event: * @stage: the stage that received the event * @event: a #ClutterEvent of type %CLUTTER_DELETE * * The ::delete-event signal is emitted when the user closes a * #ClutterStage window using the window controls. * * Clutter by default will call clutter_main_quit() if @stage is * the default stage, and clutter_actor_destroy() for any other * stage. * * It is possible to override the default behaviour by connecting * a new handler and returning %TRUE there. * * This signal is emitted only on Clutter backends that * embed #ClutterStage in native windows. It is not emitted for * backends that use a static frame buffer. * * Since: 1.2 */ stage_signals[DELETE_EVENT] = g_signal_new (I_("delete-event"), G_TYPE_FROM_CLASS (gobject_class), G_SIGNAL_RUN_LAST, G_STRUCT_OFFSET (ClutterStageClass, delete_event), _clutter_boolean_handled_accumulator, NULL, _clutter_marshal_BOOLEAN__BOXED, G_TYPE_BOOLEAN, 1, CLUTTER_TYPE_EVENT | G_SIGNAL_TYPE_STATIC_SCOPE); /** * ClutterStage::after-paint: * @stage: the stage that received the event * @paint_Context: the paint context * * The ::after-paint signal is emitted after the stage is painted, * but before the results are displayed on the screen. * * Since: 1.20 */ stage_signals[AFTER_PAINT] = g_signal_new (I_("after-paint"), G_TYPE_FROM_CLASS (gobject_class), G_SIGNAL_RUN_LAST, 0, /* no corresponding vfunc */ NULL, NULL, NULL, G_TYPE_NONE, 0); /** * ClutterStage::paint-view: * @stage: the stage that received the event * @view: a #ClutterStageView * @redraw_clip: a #cairo_region_t with the redraw clip * * The ::paint-view signal is emitted before a #ClutterStageView is being * painted. * * The view is painted in the default handler. Hence, if you want to perform * some action after the view is painted, like reading the contents of the * framebuffer, use g_signal_connect_after() or pass %G_CONNECT_AFTER. */ stage_signals[PAINT_VIEW] = g_signal_new (I_("paint-view"), G_TYPE_FROM_CLASS (gobject_class), G_SIGNAL_RUN_LAST, G_STRUCT_OFFSET (ClutterStageClass, paint_view), NULL, NULL, NULL, G_TYPE_NONE, 2, CLUTTER_TYPE_STAGE_VIEW, G_TYPE_POINTER); /** * ClutterStage::presented: (skip) * @stage: the stage that received the event * @frame_event: a #CoglFrameEvent * @frame_info: a #ClutterFrameInfo * * Signals that the #ClutterStage was presented on the screen to the user. */ stage_signals[PRESENTED] = g_signal_new (I_("presented"), G_TYPE_FROM_CLASS (gobject_class), G_SIGNAL_RUN_LAST, 0, NULL, NULL, _clutter_marshal_VOID__INT_POINTER, G_TYPE_NONE, 2, G_TYPE_INT, G_TYPE_POINTER); klass->activate = clutter_stage_real_activate; klass->deactivate = clutter_stage_real_deactivate; klass->delete_event = clutter_stage_real_delete_event; } static void clutter_stage_notify_min_size (ClutterStage *self) { self->priv->min_size_changed = TRUE; } static void clutter_stage_init (ClutterStage *self) { cairo_rectangle_int_t geom = { 0, }; ClutterStagePrivate *priv; ClutterStageWindow *impl; ClutterBackend *backend; GError *error; /* a stage is a top-level object */ CLUTTER_SET_PRIVATE_FLAGS (self, CLUTTER_IS_TOPLEVEL); self->priv = priv = clutter_stage_get_instance_private (self); CLUTTER_NOTE (BACKEND, "Creating stage from the default backend"); backend = clutter_get_default_backend (); error = NULL; impl = _clutter_backend_create_stage (backend, self, &error); if (G_LIKELY (impl != NULL)) { _clutter_stage_set_window (self, impl); _clutter_stage_window_get_geometry (priv->impl, &geom); } else { if (error != NULL) { g_critical ("Unable to create a new stage implementation: %s", error->message); g_error_free (error); } else g_critical ("Unable to create a new stage implementation."); } priv->event_queue = g_queue_new (); priv->is_cursor_visible = TRUE; priv->throttle_motion_events = TRUE; priv->min_size_changed = FALSE; priv->sync_delay = -1; priv->motion_events_enabled = TRUE; clutter_actor_set_background_color (CLUTTER_ACTOR (self), &default_stage_color); priv->pending_relayouts = g_hash_table_new_full (NULL, NULL, g_object_unref, NULL); clutter_stage_queue_actor_relayout (self, CLUTTER_ACTOR (self)); clutter_actor_set_reactive (CLUTTER_ACTOR (self), TRUE); clutter_stage_set_title (self, g_get_prgname ()); clutter_stage_set_key_focus (self, NULL); g_signal_connect (self, "notify::min-width", G_CALLBACK (clutter_stage_notify_min_size), NULL); g_signal_connect (self, "notify::min-height", G_CALLBACK (clutter_stage_notify_min_size), NULL); _clutter_stage_set_viewport (self, 0, 0, geom.width, geom.height); priv->paint_volume_stack = g_array_new (FALSE, FALSE, sizeof (ClutterPaintVolume)); priv->pick_stack = g_array_new (FALSE, FALSE, sizeof (PickRecord)); priv->pick_clip_stack = g_array_new (FALSE, FALSE, sizeof (PickClipRecord)); priv->pick_clip_stack_top = -1; priv->cached_pick_mode = CLUTTER_PICK_NONE; } /** * clutter_stage_get_default: * * Retrieves a #ClutterStage singleton. * * This function is not as useful as it sounds, and will most likely * by deprecated in the future. Application code should only create * a #ClutterStage instance using clutter_stage_new(), and manage the * lifetime of the stage manually. * * The default stage singleton has a platform-specific behaviour: on * platforms without the %CLUTTER_FEATURE_STAGE_MULTIPLE feature flag * set, the first #ClutterStage instance will also be set to be the * default stage instance, and this function will always return a * pointer to it. * * On platforms with the %CLUTTER_FEATURE_STAGE_MULTIPLE feature flag * set, the default stage will be created by the first call to this * function, and every following call will return the same pointer to * it. * * Return value: (transfer none) (type Clutter.Stage): the main * #ClutterStage. You should never destroy or unref the returned * actor. * * Deprecated: 1.10: Use clutter_stage_new() instead. */ ClutterActor * clutter_stage_get_default (void) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); ClutterStage *stage; stage = clutter_stage_manager_get_default_stage (stage_manager); if (G_UNLIKELY (stage == NULL)) { /* This will take care of automatically adding the stage to the * stage manager and setting it as the default. Its floating * reference will be claimed by the stage manager. */ stage = g_object_new (CLUTTER_TYPE_STAGE, NULL); _clutter_stage_manager_set_default_stage (stage_manager, stage); /* the default stage is realized by default */ clutter_actor_realize (CLUTTER_ACTOR (stage)); } return CLUTTER_ACTOR (stage); } /** * clutter_stage_set_color: * @stage: A #ClutterStage * @color: A #ClutterColor * * Sets the stage color. * * Deprecated: 1.10: Use clutter_actor_set_background_color() instead. */ void clutter_stage_set_color (ClutterStage *stage, const ClutterColor *color) { clutter_actor_set_background_color (CLUTTER_ACTOR (stage), color); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_COLOR]); } /** * clutter_stage_get_color: * @stage: A #ClutterStage * @color: (out caller-allocates): return location for a #ClutterColor * * Retrieves the stage color. * * Deprecated: 1.10: Use clutter_actor_get_background_color() instead. */ void clutter_stage_get_color (ClutterStage *stage, ClutterColor *color) { clutter_actor_get_background_color (CLUTTER_ACTOR (stage), color); } static void clutter_stage_set_perspective_internal (ClutterStage *stage, ClutterPerspective *perspective) { ClutterStagePrivate *priv = stage->priv; if (priv->perspective.fovy == perspective->fovy && priv->perspective.aspect == perspective->aspect && priv->perspective.z_near == perspective->z_near && priv->perspective.z_far == perspective->z_far) return; priv->perspective = *perspective; cogl_matrix_init_identity (&priv->projection); cogl_matrix_perspective (&priv->projection, priv->perspective.fovy, priv->perspective.aspect, priv->perspective.z_near, priv->perspective.z_far); cogl_matrix_get_inverse (&priv->projection, &priv->inverse_projection); _clutter_stage_dirty_projection (stage); clutter_actor_queue_redraw (CLUTTER_ACTOR (stage)); } /** * clutter_stage_set_perspective: * @stage: A #ClutterStage * @perspective: A #ClutterPerspective * * Sets the stage perspective. Using this function is not recommended * because it will disable Clutter's attempts to generate an * appropriate perspective based on the size of the stage. */ void clutter_stage_set_perspective (ClutterStage *stage, ClutterPerspective *perspective) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail (perspective != NULL); g_return_if_fail (perspective->z_far - perspective->z_near != 0); priv = stage->priv; /* If the application ever calls this function then we'll stop automatically updating the perspective when the stage changes size */ priv->has_custom_perspective = TRUE; clutter_stage_set_perspective_internal (stage, perspective); clutter_stage_update_view_perspective (stage); } /** * clutter_stage_get_perspective: * @stage: A #ClutterStage * @perspective: (out caller-allocates) (allow-none): return location for a * #ClutterPerspective * * Retrieves the stage perspective. */ void clutter_stage_get_perspective (ClutterStage *stage, ClutterPerspective *perspective) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail (perspective != NULL); *perspective = stage->priv->perspective; } /* * clutter_stage_get_projection_matrix: * @stage: A #ClutterStage * @projection: return location for a #CoglMatrix representing the * perspective projection applied to actors on the given * @stage. * * Retrieves the @stage's projection matrix. This is derived from the * current perspective set using clutter_stage_set_perspective(). * * Since: 1.6 */ void _clutter_stage_get_projection_matrix (ClutterStage *stage, CoglMatrix *projection) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail (projection != NULL); *projection = stage->priv->projection; } /* This simply provides a simple mechanism for us to ensure that * the projection matrix gets re-asserted before painting. * * This is used when switching between multiple stages */ void _clutter_stage_dirty_projection (ClutterStage *stage) { ClutterStagePrivate *priv; GList *l; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; for (l = _clutter_stage_window_get_views (priv->impl); l; l = l->next) { ClutterStageView *view = l->data; clutter_stage_view_set_dirty_projection (view, TRUE); } } /* * clutter_stage_set_viewport: * @stage: A #ClutterStage * @x: The X postition to render the stage at, in window coordinates * @y: The Y position to render the stage at, in window coordinates * @width: The width to render the stage at, in window coordinates * @height: The height to render the stage at, in window coordinates * * Sets the stage viewport. The viewport defines a final scale and * translation of your rendered stage and actors. This lets you render * your stage into a subregion of the stage window or you could use it to * pan a subregion of the stage if your stage window is smaller then * the stage. (XXX: currently this isn't possible) * * Unlike a scale and translation done using the modelview matrix this * is done after everything has had perspective projection applied, so * for example if you were to pan across a subregion of the stage using * the viewport then you would not see a change in perspective for the * actors on the stage. * * Normally the stage viewport will automatically track the size of the * stage window with no offset so the stage will fill your window. This * behaviour can be changed with the "viewport-mimics-window" property * which will automatically be set to FALSE if you use this API. If * you want to revert to the original behaviour then you should set * this property back to %TRUE using * clutter_stage_set_viewport_mimics_window(). * (XXX: If we were to make this API public then we might want to do * add that property.) * * Note: currently this interface only support integer precision * offsets and sizes for viewports but the interface takes floats because * OpenGL 4.0 has introduced floating point viewports which we might * want to expose via this API eventually. * * Since: 1.6 */ void _clutter_stage_set_viewport (ClutterStage *stage, float x, float y, float width, float height) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (x == priv->viewport[0] && y == priv->viewport[1] && width == priv->viewport[2] && height == priv->viewport[3]) return; priv->viewport[0] = x; priv->viewport[1] = y; priv->viewport[2] = width; priv->viewport[3] = height; clutter_stage_update_view_perspective (stage); _clutter_stage_dirty_viewport (stage); queue_full_redraw (stage); } /* This simply provides a simple mechanism for us to ensure that * the viewport gets re-asserted before next painting. * * This is used when switching between multiple stages */ void _clutter_stage_dirty_viewport (ClutterStage *stage) { ClutterStagePrivate *priv; GList *l; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; for (l = _clutter_stage_window_get_views (priv->impl); l; l = l->next) { ClutterStageView *view = l->data; clutter_stage_view_set_dirty_viewport (view, TRUE); } } /* * clutter_stage_get_viewport: * @stage: A #ClutterStage * @x: A location for the X position where the stage is rendered, * in window coordinates. * @y: A location for the Y position where the stage is rendered, * in window coordinates. * @width: A location for the width the stage is rendered at, * in window coordinates. * @height: A location for the height the stage is rendered at, * in window coordinates. * * Returns the viewport offset and size set using * clutter_stage_set_viewport() or if the "viewport-mimics-window" property * is TRUE then @x and @y will be set to 0 and @width and @height will equal * the width if the stage window. * * Since: 1.6 */ void _clutter_stage_get_viewport (ClutterStage *stage, float *x, float *y, float *width, float *height) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; *x = priv->viewport[0]; *y = priv->viewport[1]; *width = priv->viewport[2]; *height = priv->viewport[3]; } /** * clutter_stage_show_cursor: * @stage: a #ClutterStage * * Shows the cursor on the stage window */ void clutter_stage_show_cursor (ClutterStage *stage) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (!priv->is_cursor_visible) { ClutterStageWindow *impl = CLUTTER_STAGE_WINDOW (priv->impl); ClutterStageWindowInterface *iface; iface = CLUTTER_STAGE_WINDOW_GET_IFACE (impl); if (iface->set_cursor_visible) { priv->is_cursor_visible = TRUE; iface->set_cursor_visible (impl, TRUE); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_CURSOR_VISIBLE]); } } } /** * clutter_stage_hide_cursor: * @stage: a #ClutterStage * * Makes the cursor invisible on the stage window * * Since: 0.4 */ void clutter_stage_hide_cursor (ClutterStage *stage) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (priv->is_cursor_visible) { ClutterStageWindow *impl = CLUTTER_STAGE_WINDOW (priv->impl); ClutterStageWindowInterface *iface; iface = CLUTTER_STAGE_WINDOW_GET_IFACE (impl); if (iface->set_cursor_visible) { priv->is_cursor_visible = FALSE; iface->set_cursor_visible (impl, FALSE); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_CURSOR_VISIBLE]); } } } /** * clutter_stage_read_pixels: * @stage: A #ClutterStage * @x: x coordinate of the first pixel that is read from stage * @y: y coordinate of the first pixel that is read from stage * @width: Width dimention of pixels to be read, or -1 for the * entire stage width * @height: Height dimention of pixels to be read, or -1 for the * entire stage height * * Makes a screenshot of the stage in RGBA 8bit data, returns a * linear buffer with @width * 4 as rowstride. * * The alpha data contained in the returned buffer is driver-dependent, * and not guaranteed to hold any sensible value. * * Return value: (transfer full) (array): a pointer to newly allocated memory with the buffer * or %NULL if the read failed. Use g_free() on the returned data * to release the resources it has allocated. */ guchar * clutter_stage_read_pixels (ClutterStage *stage, gint x, gint y, gint width, gint height) { ClutterStagePrivate *priv; ClutterActorBox box; GList *l; ClutterStageView *view; cairo_region_t *clip; cairo_rectangle_int_t clip_rect; CoglFramebuffer *framebuffer; float view_scale; float pixel_width; float pixel_height; uint8_t *pixels; COGL_TRACE_BEGIN_SCOPED (ClutterStageReadPixels, "Read Pixels"); g_return_val_if_fail (CLUTTER_IS_STAGE (stage), NULL); priv = stage->priv; clutter_actor_get_allocation_box (CLUTTER_ACTOR (stage), &box); if (width < 0) width = ceilf (box.x2 - box.x1); if (height < 0) height = ceilf (box.y2 - box.y1); l = _clutter_stage_window_get_views (priv->impl); if (!l) return NULL; /* XXX: We only read the first view. Needs different API for multi view screen * capture. */ view = l->data; clutter_stage_view_get_layout (view, &clip_rect); clip = cairo_region_create_rectangle (&clip_rect); cairo_region_intersect_rectangle (clip, &(cairo_rectangle_int_t) { .x = x, .y = y, .width = width, .height = height, }); cairo_region_get_extents (clip, &clip_rect); if (clip_rect.width == 0 || clip_rect.height == 0) { cairo_region_destroy (clip); return NULL; } framebuffer = clutter_stage_view_get_framebuffer (view); clutter_stage_do_paint_view (stage, view, clip); cairo_region_destroy (clip); view_scale = clutter_stage_view_get_scale (view); pixel_width = roundf (clip_rect.width * view_scale); pixel_height = roundf (clip_rect.height * view_scale); pixels = g_malloc0 (pixel_width * pixel_height * 4); cogl_framebuffer_read_pixels (framebuffer, clip_rect.x * view_scale, clip_rect.y * view_scale, pixel_width, pixel_height, COGL_PIXEL_FORMAT_RGBA_8888, pixels); return pixels; } /** * clutter_stage_get_actor_at_pos: * @stage: a #ClutterStage * @pick_mode: how the scene graph should be painted * @x: X coordinate to check * @y: Y coordinate to check * * Checks the scene at the coordinates @x and @y and returns a pointer * to the #ClutterActor at those coordinates. The result is the actor which * would be at the specified location on the next redraw, and is not * necessarily that which was there on the previous redraw. This allows the * function to perform chronologically correctly after any queued changes to * the scene, and even if nothing has been drawn. * * By using @pick_mode it is possible to control which actors will be * painted and thus available. * * Return value: (transfer none): the actor at the specified coordinates, * if any */ ClutterActor * clutter_stage_get_actor_at_pos (ClutterStage *stage, ClutterPickMode pick_mode, float x, float y) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), NULL); return _clutter_stage_do_pick (stage, x, y, pick_mode); } /** * clutter_stage_event: * @stage: a #ClutterStage * @event: a #ClutterEvent * * This function is used to emit an event on the main stage. * * You should rarely need to use this function, except for * synthetised events. * * Return value: the return value from the signal emission * * Since: 0.4 */ gboolean clutter_stage_event (ClutterStage *stage, ClutterEvent *event) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); g_return_val_if_fail (event != NULL, FALSE); if (event->type == CLUTTER_DELETE) { gboolean retval = FALSE; g_signal_emit_by_name (stage, "event", event, &retval); if (!retval) g_signal_emit_by_name (stage, "delete-event", event, &retval); return retval; } if (event->type != CLUTTER_STAGE_STATE) return FALSE; /* emit raw event */ if (clutter_actor_event (CLUTTER_ACTOR (stage), event, FALSE)) return TRUE; if (event->stage_state.changed_mask & CLUTTER_STAGE_STATE_ACTIVATED) { if (event->stage_state.new_state & CLUTTER_STAGE_STATE_ACTIVATED) g_signal_emit (stage, stage_signals[ACTIVATE], 0); else g_signal_emit (stage, stage_signals[DEACTIVATE], 0); } return TRUE; } /** * clutter_stage_set_title: * @stage: A #ClutterStage * @title: A utf8 string for the stage windows title. * * Sets the stage title. * * Since: 0.4 **/ void clutter_stage_set_title (ClutterStage *stage, const gchar *title) { ClutterStagePrivate *priv; ClutterStageWindow *impl; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; g_free (priv->title); priv->title = g_strdup (title); impl = CLUTTER_STAGE_WINDOW (priv->impl); if (CLUTTER_STAGE_WINDOW_GET_IFACE(impl)->set_title != NULL) CLUTTER_STAGE_WINDOW_GET_IFACE (impl)->set_title (impl, priv->title); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_TITLE]); } /** * clutter_stage_get_title: * @stage: A #ClutterStage * * Gets the stage title. * * Return value: pointer to the title string for the stage. The * returned string is owned by the actor and should not * be modified or freed. * * Since: 0.4 **/ const gchar * clutter_stage_get_title (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), NULL); return stage->priv->title; } /** * clutter_stage_set_key_focus: * @stage: the #ClutterStage * @actor: (allow-none): the actor to set key focus to, or %NULL * * Sets the key focus on @actor. An actor with key focus will receive * all the key events. If @actor is %NULL, the stage will receive * focus. * * Since: 0.6 */ void clutter_stage_set_key_focus (ClutterStage *stage, ClutterActor *actor) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail (actor == NULL || CLUTTER_IS_ACTOR (actor)); priv = stage->priv; /* normalize the key focus. NULL == stage */ if (actor == CLUTTER_ACTOR (stage)) actor = NULL; /* avoid emitting signals and notifications if we're setting the same * actor as the key focus */ if (priv->key_focused_actor == actor) return; if (priv->key_focused_actor != NULL) { ClutterActor *old_focused_actor; old_focused_actor = priv->key_focused_actor; /* set key_focused_actor to NULL before emitting the signal or someone * might hide the previously focused actor in the signal handler */ priv->key_focused_actor = NULL; _clutter_actor_set_has_key_focus (old_focused_actor, FALSE); } else _clutter_actor_set_has_key_focus (CLUTTER_ACTOR (stage), FALSE); /* Note, if someone changes key focus in focus-out signal handler we'd be * overriding the latter call below moving the focus where it was originally * intended. The order of events would be: * 1st focus-out, 2nd focus-out (on stage), 2nd focus-in, 1st focus-in */ if (actor != NULL) { priv->key_focused_actor = actor; _clutter_actor_set_has_key_focus (actor, TRUE); } else _clutter_actor_set_has_key_focus (CLUTTER_ACTOR (stage), TRUE); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_KEY_FOCUS]); } /** * clutter_stage_get_key_focus: * @stage: the #ClutterStage * * Retrieves the actor that is currently under key focus. * * Return value: (transfer none): the actor with key focus, or the stage * * Since: 0.6 */ ClutterActor * clutter_stage_get_key_focus (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), NULL); if (stage->priv->key_focused_actor) return stage->priv->key_focused_actor; return CLUTTER_ACTOR (stage); } /*** Perspective boxed type ******/ static gpointer clutter_perspective_copy (gpointer data) { if (G_LIKELY (data)) return g_slice_dup (ClutterPerspective, data); return NULL; } static void clutter_perspective_free (gpointer data) { if (G_LIKELY (data)) g_slice_free (ClutterPerspective, data); } G_DEFINE_BOXED_TYPE (ClutterPerspective, clutter_perspective, clutter_perspective_copy, clutter_perspective_free); /** * clutter_stage_new: * * Creates a new, non-default stage. A non-default stage is a new * top-level actor which can be used as another container. It works * exactly like the default stage, but while clutter_stage_get_default() * will always return the same instance, you will have to keep a pointer * to any #ClutterStage returned by clutter_stage_new(). * * The ability to support multiple stages depends on the current * backend. Use clutter_feature_available() and * %CLUTTER_FEATURE_STAGE_MULTIPLE to check at runtime whether a * backend supports multiple stages. * * Return value: a new stage, or %NULL if the default backend does * not support multiple stages. Use clutter_actor_destroy() to * programmatically close the returned stage. * * Since: 0.8 */ ClutterActor * clutter_stage_new (void) { return g_object_new (CLUTTER_TYPE_STAGE, NULL); } /** * clutter_stage_ensure_current: * @stage: the #ClutterStage * * This function essentially makes sure the right GL context is * current for the passed stage. It is not intended to * be used by applications. * * Since: 0.8 * Deprecated: mutter: This function does not do anything. */ void clutter_stage_ensure_current (ClutterStage *stage) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); } /** * clutter_stage_ensure_viewport: * @stage: a #ClutterStage * * Ensures that the GL viewport is updated with the current * stage window size. * * This function will queue a redraw of @stage. * * This function should not be called by applications; it is used * when embedding a #ClutterStage into a toolkit with another * windowing system, like GTK+. * * Since: 1.0 */ void clutter_stage_ensure_viewport (ClutterStage *stage) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); _clutter_stage_dirty_viewport (stage); clutter_actor_queue_redraw (CLUTTER_ACTOR (stage)); } # define _DEG_TO_RAD(d) ((d) * ((float) G_PI / 180.0f)) /* This calculates a distance into the view frustum to position the * stage so there is a decent amount of space to position geometry * between the stage and the near clipping plane. * * Some awkward issues with this problem are: * - It's not possible to have a gap as large as the stage size with * a fov > 53° which is basically always the case since the default * fov is 60°. * - This can be deduced if you consider that this requires a * triangle as wide as it is deep to fit in the frustum in front * of the z_near plane. That triangle will always have an angle * of 53.13° at the point sitting on the z_near plane, but if the * frustum has a wider fov angle the left/right clipping planes * can never converge with the two corners of our triangle no * matter what size the triangle has. * - With a fov > 53° there is a trade off between maximizing the gap * size relative to the stage size but not loosing depth precision. * - Perhaps ideally we wouldn't just consider the fov on the y-axis * that is usually used to define a perspective, we would consider * the fov of the axis with the largest stage size so the gap would * accommodate that size best. * * After going around in circles a few times with how to handle these * issues, we decided in the end to go for the simplest solution to * start with instead of an elaborate function that handles arbitrary * fov angles that we currently have no use-case for. * * The solution assumes a fovy of 60° and for that case gives a gap * that's 85% of the stage height. We can consider more elaborate * functions if necessary later. * * One guide we had to steer the gap size we support is the * interactive test, test-texture-quality which expects to animate an * actor to +400 on the z axis with a stage size of 640x480. A gap * that's 85% of the stage height gives a gap of 408 in that case. */ static float calculate_z_translation (float z_near) { /* This solution uses fairly basic trigonometry, but is seems worth * clarifying the particular geometry we are looking at in-case * anyone wants to develop this further later. Not sure how well an * ascii diagram is going to work :-) * * |--- stage_height ---| * | stage line | * ╲━━━━━━━━━━━━━━━━━━━━━╱------------ * ╲. (2) │ .╱ | | * C ╲ . │ . ╱ gap| | * =0.5°╲ . a │ . ╱ | | * b╲(1). D│ . ╱ | | * ╲ B.│. ╱near plane | | * A= ╲━━━━━━━━━╱------------- | * 120° ╲ c │ ╱ | z_2d * ╲ │ ╱ z_near | * left ╲ │ ╱ | | * clip 60°fovy | | * plane ╳---------------------- * | * | * origin line * * The area of interest is the triangle labeled (1) at the top left * marked with the ... line (a) from where the origin line crosses * the near plane to the top left where the stage line cross the * left clip plane. * * The sides of the triangle are a, b and c and the corresponding * angles opposite those sides are A, B and C. * * The angle of C is what trades off the gap size we have relative * to the stage size vs the depth precision we have. * * As mentioned above we arove at the angle for C is by working * backwards from how much space we want for test-texture-quality. * With a stage_height of 480 we want a gap > 400, ideally we also * wanted a somewhat round number as a percentage of the height for * documentation purposes. ~87% or a gap of ~416 is the limit * because that's where we approach a C angle of 0° and effectively * loose all depth precision. * * So for our test app with a stage_height of 480 if we aim for a * gap of 408 (85% of 480) we can get the angle D as * atan (stage_height/2/408) = 30.5°. * * That gives us the angle for B as 90° - 30.5° = 59.5° * * We can already determine that A has an angle of (fovy/2 + 90°) = * 120° * * Therefore C = 180 - A - B = 0.5° * * The length of c = z_near * tan (30°) * * Now we can use the rule a/SinA = c/SinC to calculate the * length of a. After some rearranging that gives us: * * a c * ---------- = ---------- * sin (120°) sin (0.5°) * * c * sin (120°) * a = -------------- * sin (0.5°) * * And with that we can determine z_2d = cos (D) * a = * cos (30.5°) * a + z_near: * * c * sin (120°) * cos (30.5°) * z_2d = --------------------------- + z_near * sin (0.5°) */ /* We expect the compiler should boil this down to z_near * CONSTANT * already, but just in case we use precomputed constants */ #if 0 # define A tanf (_DEG_TO_RAD (30.f)) # define B sinf (_DEG_TO_RAD (120.f)) # define C cosf (_DEG_TO_RAD (30.5f)) # define D sinf (_DEG_TO_RAD (.5f)) #else # define A 0.57735025882720947265625f # define B 0.866025388240814208984375f # define C 0.86162912845611572265625f # define D 0.00872653536498546600341796875f #endif return z_near * A * B * C / D + z_near; } static void clutter_stage_update_view_perspective (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; ClutterPerspective perspective; float z_2d; perspective = priv->perspective; /* Ideally we want to regenerate the perspective matrix whenever * the size changes but if the user has provided a custom matrix * then we don't want to override it */ if (!priv->has_custom_perspective) { perspective.fovy = 60.0; /* 60 Degrees */ perspective.z_near = 0.1; perspective.aspect = priv->viewport[2] / priv->viewport[3]; z_2d = calculate_z_translation (perspective.z_near); /* NB: z_2d is only enough room for 85% of the stage_height between * the stage and the z_near plane. For behind the stage plane we * want a more consistent gap of 10 times the stage_height before * hitting the far plane so we calculate that relative to the final * height of the stage plane at the z_2d_distance we got... */ perspective.z_far = z_2d + tanf (_DEG_TO_RAD (perspective.fovy / 2.0f)) * z_2d * 20.0f; clutter_stage_set_perspective_internal (stage, &perspective); } else { z_2d = calculate_z_translation (perspective.z_near); } cogl_matrix_init_identity (&priv->view); cogl_matrix_view_2d_in_perspective (&priv->view, perspective.fovy, perspective.aspect, perspective.z_near, z_2d, priv->viewport[2], priv->viewport[3]); } void _clutter_stage_maybe_setup_viewport (ClutterStage *stage, ClutterStageView *view) { ClutterStagePrivate *priv = stage->priv; CoglFramebuffer *fb = clutter_stage_view_get_framebuffer (view); if (clutter_stage_view_is_dirty_viewport (view)) { cairo_rectangle_int_t view_layout; float fb_scale; float viewport_offset_x; float viewport_offset_y; float viewport_x; float viewport_y; float viewport_width; float viewport_height; CLUTTER_NOTE (PAINT, "Setting up the viewport { w:%f, h:%f }", priv->viewport[2], priv->viewport[3]); fb_scale = clutter_stage_view_get_scale (view); clutter_stage_view_get_layout (view, &view_layout); viewport_offset_x = view_layout.x * fb_scale; viewport_offset_y = view_layout.y * fb_scale; viewport_x = roundf (priv->viewport[0] * fb_scale - viewport_offset_x); viewport_y = roundf (priv->viewport[1] * fb_scale - viewport_offset_y); viewport_width = roundf (priv->viewport[2] * fb_scale); viewport_height = roundf (priv->viewport[3] * fb_scale); cogl_framebuffer_set_viewport (fb, viewport_x, viewport_y, viewport_width, viewport_height); clutter_stage_view_set_dirty_viewport (view, FALSE); } if (clutter_stage_view_is_dirty_projection (view)) { cogl_framebuffer_set_projection_matrix (fb, &priv->projection); clutter_stage_view_set_dirty_projection (view, FALSE); } } #undef _DEG_TO_RAD /** * clutter_stage_ensure_redraw: * @stage: a #ClutterStage * * Ensures that @stage is redrawn * * This function should not be called by applications: it is * used when embedding a #ClutterStage into a toolkit with * another windowing system, like GTK+. * * Since: 1.0 */ void clutter_stage_ensure_redraw (ClutterStage *stage) { ClutterMasterClock *master_clock; ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (!_clutter_stage_needs_update (stage)) _clutter_stage_schedule_update (stage); priv->redraw_pending = TRUE; master_clock = _clutter_master_clock_get_default (); _clutter_master_clock_start_running (master_clock); } /** * clutter_stage_is_redraw_queued: (skip) */ gboolean clutter_stage_is_redraw_queued (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; return priv->redraw_pending; } /** * clutter_stage_queue_redraw: * @stage: the #ClutterStage * * Queues a redraw for the passed stage. * * Applications should call clutter_actor_queue_redraw() and not * this function. * * Since: 0.8 * * Deprecated: 1.10: Use clutter_actor_queue_redraw() instead. */ void clutter_stage_queue_redraw (ClutterStage *stage) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); clutter_actor_queue_redraw (CLUTTER_ACTOR (stage)); } /** * clutter_stage_is_default: * @stage: a #ClutterStage * * Checks if @stage is the default stage, or an instance created using * clutter_stage_new() but internally using the same implementation. * * Return value: %TRUE if the passed stage is the default one * * Since: 0.8 * * Deprecated: 1.10: Track the stage pointer inside your application * code, or use clutter_actor_get_stage() to retrieve the stage for * a given actor. */ gboolean clutter_stage_is_default (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); return stage_is_default (stage); } void _clutter_stage_set_window (ClutterStage *stage, ClutterStageWindow *stage_window) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail (CLUTTER_IS_STAGE_WINDOW (stage_window)); if (stage->priv->impl != NULL) g_object_unref (stage->priv->impl); stage->priv->impl = stage_window; } ClutterStageWindow * _clutter_stage_get_window (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), NULL); return CLUTTER_STAGE_WINDOW (stage->priv->impl); } ClutterStageWindow * _clutter_stage_get_default_window (void) { ClutterStageManager *manager = clutter_stage_manager_get_default (); ClutterStage *stage; stage = clutter_stage_manager_get_default_stage (manager); if (stage == NULL) return NULL; return _clutter_stage_get_window (stage); } /** * clutter_stage_set_throttle_motion_events: * @stage: a #ClutterStage * @throttle: %TRUE to throttle motion events * * Sets whether motion events received between redraws should * be throttled or not. If motion events are throttled, those * events received by the windowing system between redraws will * be compressed so that only the last event will be propagated * to the @stage and its actors. * * This function should only be used if you want to have all * the motion events delivered to your application code. * * Since: 1.0 */ void clutter_stage_set_throttle_motion_events (ClutterStage *stage, gboolean throttle) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (priv->throttle_motion_events != throttle) priv->throttle_motion_events = throttle; } /** * clutter_stage_get_throttle_motion_events: * @stage: a #ClutterStage * * Retrieves the value set with clutter_stage_set_throttle_motion_events() * * Return value: %TRUE if the motion events are being throttled, * and %FALSE otherwise * * Since: 1.0 */ gboolean clutter_stage_get_throttle_motion_events (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); return stage->priv->throttle_motion_events; } /** * clutter_stage_set_use_alpha: * @stage: a #ClutterStage * @use_alpha: whether the stage should honour the opacity or the * alpha channel of the stage color * * Sets whether the @stage should honour the #ClutterActor:opacity and * the alpha channel of the #ClutterStage:color * * Since: 1.2 */ void clutter_stage_set_use_alpha (ClutterStage *stage, gboolean use_alpha) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; if (priv->use_alpha != use_alpha) { priv->use_alpha = use_alpha; clutter_actor_queue_redraw (CLUTTER_ACTOR (stage)); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_USE_ALPHA]); } } /** * clutter_stage_get_use_alpha: * @stage: a #ClutterStage * * Retrieves the value set using clutter_stage_set_use_alpha() * * Return value: %TRUE if the stage should honour the opacity and the * alpha channel of the stage color * * Since: 1.2 */ gboolean clutter_stage_get_use_alpha (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); return stage->priv->use_alpha; } /** * clutter_stage_set_minimum_size: * @stage: a #ClutterStage * @width: width, in pixels * @height: height, in pixels * * Sets the minimum size for a stage window, if the default backend * uses #ClutterStage inside a window * * This is a convenience function, and it is equivalent to setting the * #ClutterActor:min-width and #ClutterActor:min-height on @stage * * If the current size of @stage is smaller than the minimum size, the * @stage will be resized to the new @width and @height * * Since: 1.2 */ void clutter_stage_set_minimum_size (ClutterStage *stage, guint width, guint height) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_return_if_fail ((width > 0) && (height > 0)); g_object_set (G_OBJECT (stage), "min-width", (gfloat) width, "min-height", (gfloat )height, NULL); } /** * clutter_stage_get_minimum_size: * @stage: a #ClutterStage * @width: (out): return location for the minimum width, in pixels, * or %NULL * @height: (out): return location for the minimum height, in pixels, * or %NULL * * Retrieves the minimum size for a stage window as set using * clutter_stage_set_minimum_size(). * * The returned size may not correspond to the actual minimum size and * it is specific to the #ClutterStage implementation inside the * Clutter backend * * Since: 1.2 */ void clutter_stage_get_minimum_size (ClutterStage *stage, guint *width_p, guint *height_p) { gfloat width, height; gboolean width_set, height_set; g_return_if_fail (CLUTTER_IS_STAGE (stage)); g_object_get (G_OBJECT (stage), "min-width", &width, "min-width-set", &width_set, "min-height", &height, "min-height-set", &height_set, NULL); /* if not width or height have been set, then the Stage * minimum size is defined to be 1x1 */ if (!width_set) width = 1; if (!height_set) height = 1; if (width_p) *width_p = (guint) width; if (height_p) *height_p = (guint) height; } /** * _clutter_stage_schedule_update: * @window: a #ClutterStage actor * * Schedules a redraw of the #ClutterStage at the next optimal timestamp. */ void _clutter_stage_schedule_update (ClutterStage *stage) { ClutterStageWindow *stage_window; if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return; stage_window = _clutter_stage_get_window (stage); if (stage_window == NULL) return; return _clutter_stage_window_schedule_update (stage_window, stage->priv->sync_delay); } /** * _clutter_stage_get_update_time: * @stage: a #ClutterStage actor * * Returns the earliest time in which the stage is ready to update. The update * time is set when _clutter_stage_schedule_update() is called. This can then * be used by e.g. the #ClutterMasterClock to know when the stage needs to be * redrawn. * * Returns: -1 if no redraw is needed; 0 if the backend doesn't know, or the * timestamp (in microseconds) otherwise. */ gint64 _clutter_stage_get_update_time (ClutterStage *stage) { ClutterStageWindow *stage_window; if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return 0; stage_window = _clutter_stage_get_window (stage); if (stage_window == NULL) return 0; return _clutter_stage_window_get_update_time (stage_window); } /** * _clutter_stage_clear_update_time: * @stage: a #ClutterStage actor * * Resets the update time. Call this after a redraw, so that the update time * can again be updated. */ void _clutter_stage_clear_update_time (ClutterStage *stage) { ClutterStageWindow *stage_window; stage_window = _clutter_stage_get_window (stage); if (stage_window) _clutter_stage_window_clear_update_time (stage_window); } int64_t _clutter_stage_get_next_presentation_time (ClutterStage *stage) { ClutterStageWindow *stage_window; if (CLUTTER_ACTOR_IN_DESTRUCTION (stage)) return 0; stage_window = _clutter_stage_get_window (stage); if (stage_window == NULL) return 0; return _clutter_stage_window_get_next_presentation_time (stage_window); } ClutterPaintVolume * _clutter_stage_paint_volume_stack_allocate (ClutterStage *stage) { GArray *paint_volume_stack = stage->priv->paint_volume_stack; g_array_set_size (paint_volume_stack, paint_volume_stack->len+1); return &g_array_index (paint_volume_stack, ClutterPaintVolume, paint_volume_stack->len - 1); } void _clutter_stage_paint_volume_stack_free_all (ClutterStage *stage) { GArray *paint_volume_stack = stage->priv->paint_volume_stack; int i; for (i = 0; i < paint_volume_stack->len; i++) { ClutterPaintVolume *pv = &g_array_index (paint_volume_stack, ClutterPaintVolume, i); clutter_paint_volume_free (pv); } g_array_set_size (paint_volume_stack, 0); } /* The is an out-of-band paramater available while painting that * can be used to cull actors. */ const ClutterPlane * _clutter_stage_get_clip (ClutterStage *stage) { return stage->priv->current_clip_planes; } /* When an actor queues a redraw we add it to a list on the stage that * gets processed once all updates to the stage have been finished. * * This deferred approach to processing queue_redraw requests means * that we can avoid redundant transformations of clip volumes if * something later triggers a full stage redraw anyway. It also means * we can be more sure that all the referenced actors will have valid * allocations improving the chance that we can determine the actors * paint volume so we can clip the redraw request even if the user * didn't explicitly do so. */ ClutterStageQueueRedrawEntry * _clutter_stage_queue_actor_redraw (ClutterStage *stage, ClutterStageQueueRedrawEntry *entry, ClutterActor *actor, const ClutterPaintVolume *clip) { ClutterStagePrivate *priv = stage->priv; CLUTTER_NOTE (CLIPPING, "stage_queue_actor_redraw (actor=%s, clip=%p): ", _clutter_actor_get_debug_name (actor), clip); /* Queuing a redraw or clip change invalidates the pick cache, unless we're * in the middle of building it. So we reset the cached flag but don't * completely clear the pick stack... */ priv->cached_pick_mode = CLUTTER_PICK_NONE; if (!priv->redraw_pending) { ClutterMasterClock *master_clock; CLUTTER_NOTE (PAINT, "First redraw request"); _clutter_stage_schedule_update (stage); priv->redraw_pending = TRUE; master_clock = _clutter_master_clock_get_default (); _clutter_master_clock_start_running (master_clock); } #ifdef CLUTTER_ENABLE_DEBUG else { CLUTTER_NOTE (PAINT, "Redraw request number %lu", priv->redraw_count + 1); priv->redraw_count += 1; } #endif /* CLUTTER_ENABLE_DEBUG */ if (entry) { /* Ignore all requests to queue a redraw for an actor if a full * (non-clipped) redraw of the actor has already been queued. */ if (!entry->has_clip) { CLUTTER_NOTE (CLIPPING, "Bail from stage_queue_actor_redraw (%s): " "Unclipped redraw of actor already queued", _clutter_actor_get_debug_name (actor)); return entry; } /* If queuing a clipped redraw and a clipped redraw has * previously been queued for this actor then combine the latest * clip together with the existing clip */ if (clip) clutter_paint_volume_union (&entry->clip, clip); else { clutter_paint_volume_free (&entry->clip); entry->has_clip = FALSE; } return entry; } else { entry = g_slice_new (ClutterStageQueueRedrawEntry); entry->actor = g_object_ref (actor); if (clip) { entry->has_clip = TRUE; _clutter_paint_volume_init_static (&entry->clip, actor); _clutter_paint_volume_set_from_volume (&entry->clip, clip); } else entry->has_clip = FALSE; stage->priv->pending_queue_redraws = g_list_prepend (stage->priv->pending_queue_redraws, entry); return entry; } } static void free_queue_redraw_entry (ClutterStageQueueRedrawEntry *entry) { if (entry->actor) g_object_unref (entry->actor); if (entry->has_clip) clutter_paint_volume_free (&entry->clip); g_slice_free (ClutterStageQueueRedrawEntry, entry); } void _clutter_stage_queue_redraw_entry_invalidate (ClutterStageQueueRedrawEntry *entry) { if (entry == NULL) return; if (entry->actor != NULL) { g_object_unref (entry->actor); entry->actor = NULL; } if (entry->has_clip) { clutter_paint_volume_free (&entry->clip); entry->has_clip = FALSE; } } static void clutter_stage_maybe_finish_queue_redraws (ClutterStage *stage) { /* Note: we have to repeat until the pending_queue_redraws list is * empty because actors are allowed to queue redraws in response to * the queue-redraw signal. For example Clone actors or * texture_new_from_actor actors will have to queue a redraw if * their source queues a redraw. */ while (stage->priv->pending_queue_redraws) { GList *l; /* XXX: we need to allow stage->priv->pending_queue_redraws to * be updated while we process the current entries in the list * so we steal the list pointer and then reset it to an empty * list before processing... */ GList *stolen_list = stage->priv->pending_queue_redraws; stage->priv->pending_queue_redraws = NULL; for (l = stolen_list; l; l = l->next) { ClutterStageQueueRedrawEntry *entry = l->data; ClutterPaintVolume *clip; /* NB: Entries may be invalidated if the actor gets destroyed */ if (G_LIKELY (entry->actor != NULL)) { clip = entry->has_clip ? &entry->clip : NULL; _clutter_actor_finish_queue_redraw (entry->actor, clip); } free_queue_redraw_entry (entry); } g_list_free (stolen_list); } } /** * clutter_stage_set_accept_focus: * @stage: a #ClutterStage * @accept_focus: %TRUE to accept focus on show * * Sets whether the @stage should accept the key focus when shown. * * This function should be called before showing @stage using * clutter_actor_show(). * * Since: 1.6 */ void clutter_stage_set_accept_focus (ClutterStage *stage, gboolean accept_focus) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); accept_focus = !!accept_focus; priv = stage->priv; if (priv->accept_focus != accept_focus) { _clutter_stage_window_set_accept_focus (priv->impl, accept_focus); g_object_notify_by_pspec (G_OBJECT (stage), obj_props[PROP_ACCEPT_FOCUS]); } } /** * clutter_stage_get_accept_focus: * @stage: a #ClutterStage * * Retrieves the value set with clutter_stage_set_accept_focus(). * * Return value: %TRUE if the #ClutterStage should accept focus, and %FALSE * otherwise * * Since: 1.6 */ gboolean clutter_stage_get_accept_focus (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), TRUE); return stage->priv->accept_focus; } /** * clutter_stage_set_motion_events_enabled: * @stage: a #ClutterStage * @enabled: %TRUE to enable the motion events delivery, and %FALSE * otherwise * * Sets whether per-actor motion events (and relative crossing * events) should be disabled or not. * * The default is %TRUE. * * If @enable is %FALSE the following signals will not be emitted * by the actors children of @stage: * * - #ClutterActor::motion-event * - #ClutterActor::enter-event * - #ClutterActor::leave-event * * The events will still be delivered to the #ClutterStage. * * The main side effect of this function is that disabling the motion * events will disable picking to detect the #ClutterActor underneath * the pointer for each motion event. This is useful, for instance, * when dragging a #ClutterActor across the @stage: the actor underneath * the pointer is not going to change, so it's meaningless to perform * a pick. * * Since: 1.8 */ void clutter_stage_set_motion_events_enabled (ClutterStage *stage, gboolean enabled) { ClutterStagePrivate *priv; g_return_if_fail (CLUTTER_IS_STAGE (stage)); priv = stage->priv; enabled = !!enabled; if (priv->motion_events_enabled != enabled) priv->motion_events_enabled = enabled; } /** * clutter_stage_get_motion_events_enabled: * @stage: a #ClutterStage * * Retrieves the value set using clutter_stage_set_motion_events_enabled(). * * Return value: %TRUE if the per-actor motion event delivery is enabled * and %FALSE otherwise * * Since: 1.8 */ gboolean clutter_stage_get_motion_events_enabled (ClutterStage *stage) { g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); return stage->priv->motion_events_enabled; } void _clutter_stage_add_pointer_drag_actor (ClutterStage *stage, ClutterInputDevice *device, ClutterActor *actor) { GHashTable *drag_actors; drag_actors = g_object_get_data (G_OBJECT (stage), "__clutter_stage_pointer_drag_actors"); if (drag_actors == NULL) { drag_actors = g_hash_table_new (NULL, NULL); g_object_set_data_full (G_OBJECT (stage), "__clutter_stage_pointer_drag_actors", drag_actors, (GDestroyNotify) g_hash_table_destroy); } g_hash_table_replace (drag_actors, device, actor); } ClutterActor * _clutter_stage_get_pointer_drag_actor (ClutterStage *stage, ClutterInputDevice *device) { GHashTable *drag_actors; drag_actors = g_object_get_data (G_OBJECT (stage), "__clutter_stage_pointer_drag_actors"); if (drag_actors == NULL) return NULL; return g_hash_table_lookup (drag_actors, device); } void _clutter_stage_remove_pointer_drag_actor (ClutterStage *stage, ClutterInputDevice *device) { GHashTable *drag_actors; drag_actors = g_object_get_data (G_OBJECT (stage), "__clutter_stage_pointer_drag_actors"); if (drag_actors == NULL) return; g_hash_table_remove (drag_actors, device); if (g_hash_table_size (drag_actors) == 0) g_object_set_data (G_OBJECT (stage), "__clutter_stage_pointer_drag_actors", NULL); } void _clutter_stage_add_touch_drag_actor (ClutterStage *stage, ClutterEventSequence *sequence, ClutterActor *actor) { GHashTable *drag_actors; drag_actors = g_object_get_data (G_OBJECT (stage), "__clutter_stage_touch_drag_actors"); if (drag_actors == NULL) { drag_actors = g_hash_table_new (NULL, NULL); g_object_set_data_full (G_OBJECT (stage), "__clutter_stage_touch_drag_actors", drag_actors, (GDestroyNotify) g_hash_table_destroy); } g_hash_table_replace (drag_actors, sequence, actor); } ClutterActor * _clutter_stage_get_touch_drag_actor (ClutterStage *stage, ClutterEventSequence *sequence) { GHashTable *drag_actors; drag_actors = g_object_get_data (G_OBJECT (stage), "__clutter_stage_touch_drag_actors"); if (drag_actors == NULL) return NULL; return g_hash_table_lookup (drag_actors, sequence); } void _clutter_stage_remove_touch_drag_actor (ClutterStage *stage, ClutterEventSequence *sequence) { GHashTable *drag_actors; drag_actors = g_object_get_data (G_OBJECT (stage), "__clutter_stage_touch_drag_actors"); if (drag_actors == NULL) return; g_hash_table_remove (drag_actors, sequence); if (g_hash_table_size (drag_actors) == 0) g_object_set_data (G_OBJECT (stage), "__clutter_stage_touch_drag_actors", NULL); } /*< private > * _clutter_stage_get_state: * @stage: a #ClutterStage * * Retrieves the current #ClutterStageState flags associated to the @stage. * * Return value: a bitwise OR of #ClutterStageState flags */ ClutterStageState _clutter_stage_get_state (ClutterStage *stage) { return stage->priv->current_state; } /*< private > * _clutter_stage_is_activated: * @stage: a #ClutterStage * * Checks whether the @stage state includes %CLUTTER_STAGE_STATE_ACTIVATED. * * Return value: %TRUE if the @stage is active */ gboolean _clutter_stage_is_activated (ClutterStage *stage) { return (stage->priv->current_state & CLUTTER_STAGE_STATE_ACTIVATED) != 0; } /*< private > * _clutter_stage_update_state: * @stage: a #ClutterStage * @unset_flags: flags to unset * @set_flags: flags to set * * Updates the state of @stage, by unsetting the @unset_flags and setting * the @set_flags. * * If the stage state has been changed, this function will queue a * #ClutterEvent of type %CLUTTER_STAGE_STATE. * * Return value: %TRUE if the state was updated, and %FALSE otherwise */ gboolean _clutter_stage_update_state (ClutterStage *stage, ClutterStageState unset_flags, ClutterStageState set_flags) { ClutterStageState new_state; ClutterEvent event; new_state = stage->priv->current_state; new_state |= set_flags; new_state &= ~unset_flags; if (new_state == stage->priv->current_state) return FALSE; memset (&event, 0, sizeof (event)); event.type = CLUTTER_STAGE_STATE; clutter_event_set_stage (&event, stage); event.stage_state.new_state = new_state; event.stage_state.changed_mask = new_state ^ stage->priv->current_state; stage->priv->current_state = new_state; clutter_stage_event (stage, &event); return TRUE; } /** * clutter_stage_set_sync_delay: * @stage: a #ClutterStage * @sync_delay: number of milliseconds after frame presentation to wait * before painting the next frame. If less than zero, restores the * default behavior where redraw is throttled to the refresh rate but * not synchronized to it. * * This function enables an alternate behavior where Clutter draws at * a fixed point in time after the frame presentation time (also known * as the VBlank time). This is most useful when the application * wants to show incoming data with predictable latency. (The primary * example of this would be a window system compositor.) By synchronizing * to provide new data before Clutter redraws, an external source of * updates (in the compositor, an application) can get a reliable latency. * * The appropriate value of @sync_delay depends on the complexity of * drawing the stage's scene graph - in general a value of between 0 * and 8 ms (up to one-half of a typical 60hz frame rate) is appropriate. * using a larger value will reduce latency but risks skipping a frame if * drawing the stage takes too long. * * Since: 1.14 * Stability: unstable */ void clutter_stage_set_sync_delay (ClutterStage *stage, gint sync_delay) { g_return_if_fail (CLUTTER_IS_STAGE (stage)); stage->priv->sync_delay = sync_delay; } /** * clutter_stage_skip_sync_delay: * @stage: a #ClutterStage * * Causes the next frame for the stage to be drawn as quickly as * possible, ignoring any delay that clutter_stage_set_sync_delay() * would normally cause. * * Since: 1.14 * Stability: unstable */ void clutter_stage_skip_sync_delay (ClutterStage *stage) { ClutterStageWindow *stage_window; stage_window = _clutter_stage_get_window (stage); if (stage_window) _clutter_stage_window_schedule_update (stage_window, -1); } int64_t clutter_stage_get_frame_counter (ClutterStage *stage) { ClutterStageWindow *stage_window; stage_window = _clutter_stage_get_window (stage); return _clutter_stage_window_get_frame_counter (stage_window); } void _clutter_stage_presented (ClutterStage *stage, CoglFrameEvent frame_event, ClutterFrameInfo *frame_info) { g_signal_emit (stage, stage_signals[PRESENTED], 0, (int) frame_event, frame_info); } static void capture_view (ClutterStage *stage, gboolean paint, ClutterStageView *view, ClutterCapture *capture) { cairo_surface_t *image; uint8_t *data; int stride; cairo_rectangle_int_t *rect; float view_scale; float texture_width; float texture_height; rect = &capture->rect; view_scale = clutter_stage_view_get_scale (view); texture_width = roundf (rect->width * view_scale); texture_height = roundf (rect->height * view_scale); image = cairo_image_surface_create (CAIRO_FORMAT_ARGB32, texture_width, texture_height); cairo_surface_set_device_scale (image, view_scale, view_scale); data = cairo_image_surface_get_data (image); stride = cairo_image_surface_get_stride (image); capture_view_into (stage, paint, view, rect, data, stride); capture->image = image; cairo_surface_mark_dirty (capture->image); } /** * clutter_stage_capture: * @stage: a #ClutterStage * @paint: whether to pain the frame * @rect: a #cairo_rectangle_int_t in stage coordinates * @out_captures: (out) (array length=out_n_captures): an array of * #ClutterCapture * @out_n_captures: (out): the number of captures in @out_captures * * Captures the stage pixels of @rect into @captures. @rect is in stage * coordinates. * * Returns: %TRUE if a #ClutterCapture has been created, %FALSE otherwise */ gboolean clutter_stage_capture (ClutterStage *stage, gboolean paint, cairo_rectangle_int_t *rect, ClutterCapture **out_captures, int *out_n_captures) { ClutterStagePrivate *priv = stage->priv; GList *views = _clutter_stage_window_get_views (priv->impl); GList *l; ClutterCapture *captures; int n_captures; g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); captures = g_new0 (ClutterCapture, g_list_length (views)); n_captures = 0; for (l = views; l; l = l->next) { ClutterStageView *view = l->data; ClutterCapture *capture; cairo_rectangle_int_t view_layout; cairo_region_t *region; clutter_stage_view_get_layout (view, &view_layout); region = cairo_region_create_rectangle (&view_layout); cairo_region_intersect_rectangle (region, rect); capture = &captures[n_captures]; cairo_region_get_extents (region, &capture->rect); cairo_region_destroy (region); if (capture->rect.width == 0 || capture->rect.height == 0) continue; capture_view (stage, paint, view, capture); n_captures++; } if (n_captures == 0) g_clear_pointer (&captures, g_free); *out_captures = captures; *out_n_captures = n_captures; return n_captures > 0; } gboolean clutter_stage_get_capture_final_size (ClutterStage *stage, cairo_rectangle_int_t *rect, int *out_width, int *out_height, float *out_scale) { float max_scale; g_return_val_if_fail (CLUTTER_IS_STAGE (stage), FALSE); if (rect) { graphene_rect_t capture_rect; _clutter_util_rect_from_rectangle (rect, &capture_rect); if (!_clutter_stage_get_max_view_scale_factor_for_rect (stage, &capture_rect, &max_scale)) return FALSE; if (out_width) *out_width = (gint) roundf (rect->width * max_scale); if (out_height) *out_height = (gint) roundf (rect->height * max_scale); } else { ClutterActorBox alloc; float stage_width, stage_height; clutter_actor_get_allocation_box (CLUTTER_ACTOR (stage), &alloc); clutter_actor_box_get_size (&alloc, &stage_width, &stage_height); if (!_clutter_actor_get_real_resource_scale (CLUTTER_ACTOR (stage), &max_scale)) return FALSE; if (out_width) *out_width = (gint) roundf (stage_width * max_scale); if (out_height) *out_height = (gint) roundf (stage_height * max_scale); } if (out_scale) *out_scale = max_scale; return TRUE; } static void capture_view_into (ClutterStage *stage, gboolean paint, ClutterStageView *view, cairo_rectangle_int_t *rect, uint8_t *data, int stride) { CoglFramebuffer *framebuffer; ClutterBackend *backend; CoglContext *context; CoglBitmap *bitmap; cairo_rectangle_int_t view_layout; float view_scale; float texture_width; float texture_height; g_return_if_fail (CLUTTER_IS_STAGE (stage)); framebuffer = clutter_stage_view_get_framebuffer (view); if (paint) { cairo_region_t *region; _clutter_stage_maybe_setup_viewport (stage, view); region = cairo_region_create_rectangle (rect); clutter_stage_do_paint_view (stage, view, region); cairo_region_destroy (region); } view_scale = clutter_stage_view_get_scale (view); texture_width = roundf (rect->width * view_scale); texture_height = roundf (rect->height * view_scale); backend = clutter_get_default_backend (); context = clutter_backend_get_cogl_context (backend); bitmap = cogl_bitmap_new_for_data (context, texture_width, texture_height, CLUTTER_CAIRO_FORMAT_ARGB32, stride, data); clutter_stage_view_get_layout (view, &view_layout); cogl_framebuffer_read_pixels_into_bitmap (framebuffer, roundf ((rect->x - view_layout.x) * view_scale), roundf ((rect->y - view_layout.y) * view_scale), COGL_READ_PIXELS_COLOR_BUFFER, bitmap); cogl_object_unref (bitmap); } void clutter_stage_capture_into (ClutterStage *stage, gboolean paint, cairo_rectangle_int_t *rect, uint8_t *data) { ClutterStagePrivate *priv = stage->priv; GList *l; int bpp = 4; int stride; stride = rect->width * 4; for (l = _clutter_stage_window_get_views (priv->impl); l; l = l->next) { ClutterStageView *view = l->data; cairo_rectangle_int_t view_layout; cairo_region_t *region; cairo_rectangle_int_t capture_rect; int x_offset, y_offset; clutter_stage_view_get_layout (view, &view_layout); region = cairo_region_create_rectangle (&view_layout); cairo_region_intersect_rectangle (region, rect); cairo_region_get_extents (region, &capture_rect); cairo_region_destroy (region); x_offset = capture_rect.x - rect->x; y_offset = capture_rect.y - rect->y; capture_view_into (stage, paint, view, &capture_rect, data + (x_offset * bpp) + (y_offset * stride), stride); } } /** * clutter_stage_freeze_updates: * * Freezing updates makes Clutter stop processing events, * redrawing, and advancing timelines, by pausing the master clock. This is * necessary when implementing a display server, to ensure that Clutter doesn't * keep trying to page flip when DRM master has been dropped, e.g. when VT * switched away. * * The master clock starts out running, so if you are VT switched away on * startup, you need to call this immediately. * * To thaw updates, use clutter_stage_thaw_updates(). */ void clutter_stage_freeze_updates (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; priv->update_freeze_count++; if (priv->update_freeze_count == 1) { ClutterMasterClock *master_clock; master_clock = _clutter_master_clock_get_default (); _clutter_master_clock_set_paused (master_clock, TRUE); } } /** * clutter_stage_thaw_updates: * * Resumes a master clock that has previously been frozen with * clutter_stage_freeze_updates(), and start pumping the master clock * again at the next iteration. Note that if you're switching back to your * own VT, you should probably also queue a stage redraw with * clutter_stage_ensure_redraw(). */ void clutter_stage_thaw_updates (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; g_assert (priv->update_freeze_count > 0); priv->update_freeze_count--; if (priv->update_freeze_count == 0) { ClutterMasterClock *master_clock; master_clock = _clutter_master_clock_get_default (); _clutter_master_clock_set_paused (master_clock, FALSE); } } GList * _clutter_stage_peek_stage_views (ClutterStage *stage) { ClutterStagePrivate *priv = stage->priv; return _clutter_stage_window_get_views (priv->impl); } void clutter_stage_update_resource_scales (ClutterStage *stage) { _clutter_actor_queue_update_resource_scale_recursive (CLUTTER_ACTOR (stage)); } gboolean _clutter_stage_get_max_view_scale_factor_for_rect (ClutterStage *stage, graphene_rect_t *rect, float *view_scale) { ClutterStagePrivate *priv = stage->priv; float scale = 0.0f; GList *l; for (l = _clutter_stage_window_get_views (priv->impl); l; l = l->next) { ClutterStageView *view = l->data; cairo_rectangle_int_t view_layout; graphene_rect_t view_rect; clutter_stage_view_get_layout (view, &view_layout); _clutter_util_rect_from_rectangle (&view_layout, &view_rect); if (graphene_rect_intersection (&view_rect, rect, NULL)) scale = MAX (clutter_stage_view_get_scale (view), scale); } if (scale == 0.0) return FALSE; *view_scale = scale; return TRUE; }