/* GStreamer Video Overlay Composition * Copyright (C) 2011 Intel Corporation * Copyright (C) 2011 Collabora Ltd. * Copyright (C) 2011 Tim-Philipp Müller * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, * Boston, MA 02110-1301, USA. */ /** * SECTION:gstvideooverlaycomposition * @title: GstVideoOverlayRectangle * @short_description: Video Buffer Overlay Compositions (Subtitles, Logos) * * Functions to create and handle overlay compositions on video buffers. * * An overlay composition describes one or more overlay rectangles to be * blended on top of a video buffer. * * This API serves two main purposes: * * * it can be used to attach overlay information (subtitles or logos) * to non-raw video buffers such as GL/VAAPI/VDPAU surfaces. The actual * blending of the overlay can then be done by e.g. the video sink that * processes these non-raw buffers. * * * it can also be used to blend overlay rectangles on top of raw video * buffers, thus consolidating blending functionality for raw video in * one place. * * Together, this allows existing overlay elements to easily handle raw * and non-raw video as input in without major changes (once the overlays * have been put into a #GstOverlayComposition object anyway) - for raw * video the overlay can just use the blending function to blend the data * on top of the video, and for surface buffers it can just attach them to * the buffer and let the sink render the overlays. * */ /* TODO: * - provide accessors for seq_num and other fields (as needed) * - allow overlay to set/get original pango markup string on/from rectangle */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "video-overlay-composition.h" #include "video-blend.h" #include "gstvideometa.h" #include struct _GstVideoOverlayComposition { GstMiniObject parent; guint num_rectangles; GstVideoOverlayRectangle **rectangles; /* lowest rectangle sequence number still used by the upstream * overlay element. This way a renderer maintaining some kind of * rectangles <-> surface cache can know when to free cached * surfaces/rectangles. */ guint min_seq_num_used; /* sequence number for the composition (same series as rectangles) */ guint seq_num; }; struct _GstVideoOverlayRectangle { GstMiniObject parent; /* Position on video frame and dimension of output rectangle in * output frame terms (already adjusted for the PAR of the output * frame). x/y can be negative (overlay will be clipped then) */ gint x, y; guint render_width, render_height; /* Info on overlay pixels (format, width, height) */ GstVideoInfo info; /* The flags associated to this rectangle */ GstVideoOverlayFormatFlags flags; /* Refcounted blob of memory, no caps or timestamps */ GstBuffer *pixels; /* FIXME: how to express source like text or pango markup? * (just add source type enum + source buffer with data) * * FOR 0.10: always send pixel blobs, but attach source data in * addition (reason: if downstream changes, we can't renegotiate * that properly, if we just do a query of supported formats from * the start). Sink will just ignore pixels and use pango markup * from source data if it supports that. * * FOR 0.11: overlay should query formats (pango markup, pixels) * supported by downstream and then only send that. We can * renegotiate via the reconfigure event. */ /* sequence number: useful for backends/renderers/sinks that want * to maintain a cache of rectangles <-> surfaces. The value of * the min_seq_num_used in the composition tells the renderer which * rectangles have expired. */ guint seq_num; /* global alpha: global alpha value of the rectangle. Each each per-pixel * alpha value of image-data will be multiplied with the global alpha value * during blending. * Can be used for efficient fading in/out of overlay rectangles. * GstElements that render OverlayCompositions and don't support global alpha * should simply ignore it.*/ gfloat global_alpha; /* track alpha-values already applied: */ gfloat applied_global_alpha; /* store initial per-pixel alpha values: */ guint8 *initial_alpha; /* FIXME: we may also need a (private) way to cache converted/scaled * pixel blobs */ GMutex lock; GList *scaled_rectangles; }; #define GST_RECTANGLE_LOCK(rect) g_mutex_lock(&rect->lock) #define GST_RECTANGLE_UNLOCK(rect) g_mutex_unlock(&rect->lock) /* --------------------------- utility functions --------------------------- */ #ifndef GST_DISABLE_GST_DEBUG #define GST_CAT_DEFAULT ensure_debug_category() static GstDebugCategory * ensure_debug_category (void) { static gsize cat_gonce = 0; if (g_once_init_enter (&cat_gonce)) { gsize cat_done; cat_done = (gsize) _gst_debug_category_new ("video-composition", 0, "video overlay composition"); g_once_init_leave (&cat_gonce, cat_done); } return (GstDebugCategory *) cat_gonce; } #else #define ensure_debug_category() /* NOOP */ #endif /* GST_DISABLE_GST_DEBUG */ static guint gst_video_overlay_get_seqnum (void) { static gint seqnum; /* 0 */ return (guint) g_atomic_int_add (&seqnum, 1); } static gboolean gst_video_overlay_composition_meta_init (GstMeta * meta, gpointer params, GstBuffer * buf) { GstVideoOverlayCompositionMeta *ometa; ometa = (GstVideoOverlayCompositionMeta *) meta; ometa->overlay = NULL; return TRUE; } static void gst_video_overlay_composition_meta_free (GstMeta * meta, GstBuffer * buf) { GstVideoOverlayCompositionMeta *ometa; ometa = (GstVideoOverlayCompositionMeta *) meta; if (ometa->overlay) gst_video_overlay_composition_unref (ometa->overlay); } static gboolean gst_video_overlay_composition_meta_transform (GstBuffer * dest, GstMeta * meta, GstBuffer * buffer, GQuark type, gpointer data) { GstVideoOverlayCompositionMeta *dmeta, *smeta; smeta = (GstVideoOverlayCompositionMeta *) meta; if (GST_META_TRANSFORM_IS_COPY (type)) { GstMetaTransformCopy *copy = data; if (!copy->region) { GST_DEBUG ("copy video overlay composition metadata"); /* only copy if the complete data is copied as well */ dmeta = (GstVideoOverlayCompositionMeta *) gst_buffer_add_meta (dest, GST_VIDEO_OVERLAY_COMPOSITION_META_INFO, NULL); if (!dmeta) return FALSE; dmeta->overlay = gst_video_overlay_composition_ref (smeta->overlay); } } else { /* return FALSE, if transform type is not supported */ return FALSE; } return TRUE; } GType gst_video_overlay_composition_meta_api_get_type (void) { static volatile GType type = 0; static const gchar *tags[] = { NULL }; if (g_once_init_enter (&type)) { GType _type = gst_meta_api_type_register ("GstVideoOverlayCompositionMetaAPI", tags); g_once_init_leave (&type, _type); } return type; } /* video overlay composition metadata */ const GstMetaInfo * gst_video_overlay_composition_meta_get_info (void) { static const GstMetaInfo *video_overlay_composition_meta_info = NULL; if (g_once_init_enter ((GstMetaInfo **) & video_overlay_composition_meta_info)) { const GstMetaInfo *meta = gst_meta_register (GST_VIDEO_OVERLAY_COMPOSITION_META_API_TYPE, "GstVideoOverlayCompositionMeta", sizeof (GstVideoOverlayCompositionMeta), (GstMetaInitFunction) gst_video_overlay_composition_meta_init, (GstMetaFreeFunction) gst_video_overlay_composition_meta_free, (GstMetaTransformFunction) gst_video_overlay_composition_meta_transform); g_once_init_leave ((GstMetaInfo **) & video_overlay_composition_meta_info, (GstMetaInfo *) meta); } return video_overlay_composition_meta_info; } /** * gst_buffer_add_video_overlay_composition_meta: * @buf: a #GstBuffer * @comp: (allow-none): a #GstVideoOverlayComposition * * Sets an overlay composition on a buffer. The buffer will obtain its own * reference to the composition, meaning this function does not take ownership * of @comp. * * Returns: (transfer none): a #GstVideoOverlayCompositionMeta */ GstVideoOverlayCompositionMeta * gst_buffer_add_video_overlay_composition_meta (GstBuffer * buf, GstVideoOverlayComposition * comp) { GstVideoOverlayCompositionMeta *ometa; g_return_val_if_fail (gst_buffer_is_writable (buf), NULL); ometa = (GstVideoOverlayCompositionMeta *) gst_buffer_add_meta (buf, GST_VIDEO_OVERLAY_COMPOSITION_META_INFO, NULL); ometa->overlay = gst_video_overlay_composition_ref (comp); return ometa; } /* ------------------------------ composition ------------------------------ */ #define RECTANGLE_ARRAY_STEP 4 /* premature optimization */ GST_DEFINE_MINI_OBJECT_TYPE (GstVideoOverlayComposition, gst_video_overlay_composition); static void gst_video_overlay_composition_free (GstMiniObject * mini_obj) { GstVideoOverlayComposition *comp = (GstVideoOverlayComposition *) mini_obj; guint num; num = comp->num_rectangles; while (num > 0) { gst_video_overlay_rectangle_unref (comp->rectangles[num - 1]); --num; } g_free (comp->rectangles); comp->rectangles = NULL; comp->num_rectangles = 0; g_slice_free (GstVideoOverlayComposition, comp); } /** * gst_video_overlay_composition_new: * @rectangle: (transfer none): a #GstVideoOverlayRectangle to add to the * composition * * Creates a new video overlay composition object to hold one or more * overlay rectangles. * * Returns: (transfer full): a new #GstVideoOverlayComposition. Unref with * gst_video_overlay_composition_unref() when no longer needed. */ GstVideoOverlayComposition * gst_video_overlay_composition_new (GstVideoOverlayRectangle * rectangle) { GstVideoOverlayComposition *comp; /* FIXME: should we allow empty compositions? Could also be expressed as * buffer without a composition on it. Maybe there are cases where doing * an empty new + _add() in a loop is easier? */ g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), NULL); comp = g_slice_new0 (GstVideoOverlayComposition); gst_mini_object_init (GST_MINI_OBJECT_CAST (comp), 0, GST_TYPE_VIDEO_OVERLAY_COMPOSITION, (GstMiniObjectCopyFunction) gst_video_overlay_composition_copy, NULL, (GstMiniObjectFreeFunction) gst_video_overlay_composition_free); comp->rectangles = g_new0 (GstVideoOverlayRectangle *, RECTANGLE_ARRAY_STEP); comp->rectangles[0] = gst_video_overlay_rectangle_ref (rectangle); comp->num_rectangles = 1; comp->seq_num = gst_video_overlay_get_seqnum (); /* since the rectangle was created earlier, its seqnum is smaller than ours */ comp->min_seq_num_used = rectangle->seq_num; GST_LOG ("new composition %p: seq_num %u with rectangle %p", comp, comp->seq_num, rectangle); return comp; } /** * gst_video_overlay_composition_add_rectangle: * @comp: a #GstVideoOverlayComposition * @rectangle: (transfer none): a #GstVideoOverlayRectangle to add to the * composition * * Adds an overlay rectangle to an existing overlay composition object. This * must be done right after creating the overlay composition. */ void gst_video_overlay_composition_add_rectangle (GstVideoOverlayComposition * comp, GstVideoOverlayRectangle * rectangle) { g_return_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp)); g_return_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle)); g_return_if_fail (GST_MINI_OBJECT_REFCOUNT_VALUE (comp) == 1); if (comp->num_rectangles % RECTANGLE_ARRAY_STEP == 0) { comp->rectangles = g_renew (GstVideoOverlayRectangle *, comp->rectangles, comp->num_rectangles + RECTANGLE_ARRAY_STEP); } comp->rectangles[comp->num_rectangles] = gst_video_overlay_rectangle_ref (rectangle); comp->num_rectangles += 1; comp->min_seq_num_used = MIN (comp->min_seq_num_used, rectangle->seq_num); GST_LOG ("composition %p: added rectangle %p", comp, rectangle); } /** * gst_video_overlay_composition_n_rectangles: * @comp: a #GstVideoOverlayComposition * * Returns the number of #GstVideoOverlayRectangles contained in @comp. * * Returns: the number of rectangles */ guint gst_video_overlay_composition_n_rectangles (GstVideoOverlayComposition * comp) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp), 0); return comp->num_rectangles; } /** * gst_video_overlay_composition_get_rectangle: * @comp: a #GstVideoOverlayComposition * @n: number of the rectangle to get * * Returns the @n-th #GstVideoOverlayRectangle contained in @comp. * * Returns: (transfer none): the @n-th rectangle, or NULL if @n is out of * bounds. Will not return a new reference, the caller will need to * obtain her own reference using gst_video_overlay_rectangle_ref() * if needed. */ GstVideoOverlayRectangle * gst_video_overlay_composition_get_rectangle (GstVideoOverlayComposition * comp, guint n) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp), NULL); if (n >= comp->num_rectangles) return NULL; return comp->rectangles[n]; } static gboolean gst_video_overlay_rectangle_needs_scaling (GstVideoOverlayRectangle * r) { return (GST_VIDEO_INFO_WIDTH (&r->info) != r->render_width || GST_VIDEO_INFO_HEIGHT (&r->info) != r->render_height); } /** * gst_video_overlay_composition_blend: * @comp: a #GstVideoOverlayComposition * @video_buf: a #GstVideoFrame containing raw video data in a * supported format. It should be mapped using GST_MAP_READWRITE * * Blends the overlay rectangles in @comp on top of the raw video data * contained in @video_buf. The data in @video_buf must be writable and * mapped appropriately. * * Since @video_buf data is read and will be modified, it ought be * mapped with flag GST_MAP_READWRITE. */ /* FIXME: formats with more than 8 bit per component which get unpacked into * ARGB64 or AYUV64 (such as v210, v216, UYVP, GRAY16_LE and GRAY16_BE) * are not supported yet by the code in video-blend.c. */ gboolean gst_video_overlay_composition_blend (GstVideoOverlayComposition * comp, GstVideoFrame * video_buf) { GstVideoInfo scaled_info; GstVideoInfo *vinfo; GstVideoFrame rectangle_frame; GstVideoFormat fmt; GstBuffer *pixels = NULL; gboolean ret = TRUE; guint n, num; int w, h; g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp), FALSE); g_return_val_if_fail (video_buf != NULL, FALSE); w = GST_VIDEO_FRAME_WIDTH (video_buf); h = GST_VIDEO_FRAME_HEIGHT (video_buf); fmt = GST_VIDEO_FRAME_FORMAT (video_buf); num = comp->num_rectangles; GST_LOG ("Blending composition %p with %u rectangles onto video buffer %p " "(%ux%u, format %u)", comp, num, video_buf, w, h, fmt); for (n = 0; n < num; ++n) { GstVideoOverlayRectangle *rect; gboolean needs_scaling; rect = comp->rectangles[n]; GST_LOG (" rectangle %u %p: %ux%u, format %u", n, rect, GST_VIDEO_INFO_WIDTH (&rect->info), GST_VIDEO_INFO_HEIGHT (&rect->info), GST_VIDEO_INFO_FORMAT (&rect->info)); needs_scaling = gst_video_overlay_rectangle_needs_scaling (rect); if (needs_scaling) { gst_video_blend_scale_linear_RGBA (&rect->info, rect->pixels, rect->render_height, rect->render_width, &scaled_info, &pixels); vinfo = &scaled_info; } else { pixels = gst_buffer_ref (rect->pixels); vinfo = &rect->info; } gst_video_frame_map (&rectangle_frame, vinfo, pixels, GST_MAP_READ); ret = gst_video_blend (video_buf, &rectangle_frame, rect->x, rect->y, rect->global_alpha); gst_video_frame_unmap (&rectangle_frame); if (!ret) { GST_WARNING ("Could not blend overlay rectangle onto video buffer"); } /* FIXME: should cache scaled pixels in the rectangle struct */ gst_buffer_unref (pixels); } return ret; } /** * gst_video_overlay_composition_copy: * @comp: (transfer none): a #GstVideoOverlayComposition to copy * * Makes a copy of @comp and all contained rectangles, so that it is possible * to modify the composition and contained rectangles (e.g. add additional * rectangles or change the render co-ordinates or render dimension). The * actual overlay pixel data buffers contained in the rectangles are not * copied. * * Returns: (transfer full): a new #GstVideoOverlayComposition equivalent * to @comp. */ GstVideoOverlayComposition * gst_video_overlay_composition_copy (GstVideoOverlayComposition * comp) { GstVideoOverlayComposition *copy; GstVideoOverlayRectangle *rect; guint n; g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp), NULL); if (G_LIKELY (comp->num_rectangles == 0)) return gst_video_overlay_composition_new (NULL); rect = gst_video_overlay_rectangle_copy (comp->rectangles[0]); copy = gst_video_overlay_composition_new (rect); gst_video_overlay_rectangle_unref (rect); for (n = 1; n < comp->num_rectangles; ++n) { rect = gst_video_overlay_rectangle_copy (comp->rectangles[n]); gst_video_overlay_composition_add_rectangle (copy, rect); gst_video_overlay_rectangle_unref (rect); } return copy; } /** * gst_video_overlay_composition_make_writable: * @comp: (transfer full): a #GstVideoOverlayComposition to copy * * Takes ownership of @comp and returns a version of @comp that is writable * (i.e. can be modified). Will either return @comp right away, or create a * new writable copy of @comp and unref @comp itself. All the contained * rectangles will also be copied, but the actual overlay pixel data buffers * contained in the rectangles are not copied. * * Returns: (transfer full): a writable #GstVideoOverlayComposition * equivalent to @comp. */ GstVideoOverlayComposition * gst_video_overlay_composition_make_writable (GstVideoOverlayComposition * comp) { GstVideoOverlayComposition *writable_comp; g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp), NULL); if (GST_MINI_OBJECT_REFCOUNT_VALUE (comp) == 1) { guint n; for (n = 0; n < comp->num_rectangles; ++n) { if (GST_MINI_OBJECT_REFCOUNT_VALUE (comp->rectangles[n]) != 1) goto copy; } return comp; } copy: writable_comp = gst_video_overlay_composition_copy (comp); gst_video_overlay_composition_unref (comp); return writable_comp; } /** * gst_video_overlay_composition_get_seqnum: * @comp: a #GstVideoOverlayComposition * * Returns the sequence number of this composition. Sequence numbers are * monotonically increasing and unique for overlay compositions and rectangles * (meaning there will never be a rectangle with the same sequence number as * a composition). * * Returns: the sequence number of @comp */ guint gst_video_overlay_composition_get_seqnum (GstVideoOverlayComposition * comp) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_COMPOSITION (comp), 0); return comp->seq_num; } /* ------------------------------ rectangles ------------------------------ -*/ GST_DEFINE_MINI_OBJECT_TYPE (GstVideoOverlayRectangle, gst_video_overlay_rectangle); static void gst_video_overlay_rectangle_free (GstMiniObject * mini_obj) { GstVideoOverlayRectangle *rect = (GstVideoOverlayRectangle *) mini_obj; gst_buffer_replace (&rect->pixels, NULL); while (rect->scaled_rectangles != NULL) { GstVideoOverlayRectangle *scaled_rect = rect->scaled_rectangles->data; gst_video_overlay_rectangle_unref (scaled_rect); rect->scaled_rectangles = g_list_delete_link (rect->scaled_rectangles, rect->scaled_rectangles); } g_free (rect->initial_alpha); g_mutex_clear (&rect->lock); g_slice_free (GstVideoOverlayRectangle, rect); } static inline gboolean gst_video_overlay_rectangle_check_flags (GstVideoOverlayFormatFlags flags) { /* Check flags only contains flags we know about */ return (flags & ~(GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA | GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA)) == 0; } static gboolean gst_video_overlay_rectangle_is_same_alpha_type (GstVideoOverlayFormatFlags flags1, GstVideoOverlayFormatFlags flags2) { return ((flags1 ^ flags2) & GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA) == 0; } /** * gst_video_overlay_rectangle_new_raw: * @pixels: (transfer none): a #GstBuffer pointing to the pixel memory * @render_x: the X co-ordinate on the video where the top-left corner of this * overlay rectangle should be rendered to * @render_y: the Y co-ordinate on the video where the top-left corner of this * overlay rectangle should be rendered to * @render_width: the render width of this rectangle on the video * @render_height: the render height of this rectangle on the video * @flags: flags * * Creates a new video overlay rectangle with ARGB or AYUV pixel data. * The layout in case of ARGB of the components in memory is B-G-R-A * on little-endian platforms * (corresponding to #GST_VIDEO_FORMAT_BGRA) and A-R-G-B on big-endian * platforms (corresponding to #GST_VIDEO_FORMAT_ARGB). In other words, * pixels are treated as 32-bit words and the lowest 8 bits then contain * the blue component value and the highest 8 bits contain the alpha * component value. Unless specified in the flags, the RGB values are * non-premultiplied. This is the format that is used by most hardware, * and also many rendering libraries such as Cairo, for example. * The pixel data buffer must have #GstVideoMeta set. * * Returns: (transfer full): a new #GstVideoOverlayRectangle. Unref with * gst_video_overlay_rectangle_unref() when no longer needed. */ GstVideoOverlayRectangle * gst_video_overlay_rectangle_new_raw (GstBuffer * pixels, gint render_x, gint render_y, guint render_width, guint render_height, GstVideoOverlayFormatFlags flags) { GstVideoOverlayRectangle *rect; GstVideoMeta *vmeta; GstVideoFormat format; guint width, height; g_return_val_if_fail (GST_IS_BUFFER (pixels), NULL); g_return_val_if_fail (render_height > 0 && render_width > 0, NULL); g_return_val_if_fail (gst_video_overlay_rectangle_check_flags (flags), NULL); /* buffer must have video meta with some expected settings */ vmeta = gst_buffer_get_video_meta (pixels); g_return_val_if_fail (vmeta, NULL); g_return_val_if_fail (vmeta->format == GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_RGB || vmeta->format == GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_YUV, NULL); g_return_val_if_fail (vmeta->flags == GST_VIDEO_FRAME_FLAG_NONE, NULL); format = vmeta->format; width = vmeta->width; height = vmeta->height; /* technically ((height-1)*stride)+width might be okay too */ g_return_val_if_fail (gst_buffer_get_size (pixels) >= height * width * 4, NULL); g_return_val_if_fail (height > 0 && width > 0, NULL); rect = g_slice_new0 (GstVideoOverlayRectangle); gst_mini_object_init (GST_MINI_OBJECT_CAST (rect), 0, GST_TYPE_VIDEO_OVERLAY_RECTANGLE, (GstMiniObjectCopyFunction) gst_video_overlay_rectangle_copy, NULL, (GstMiniObjectFreeFunction) gst_video_overlay_rectangle_free); g_mutex_init (&rect->lock); rect->pixels = gst_buffer_ref (pixels); rect->scaled_rectangles = NULL; gst_video_info_init (&rect->info); if (!gst_video_info_set_format (&rect->info, format, width, height)) { gst_mini_object_unref (GST_MINI_OBJECT_CAST (rect)); return NULL; } if (flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA) rect->info.flags |= GST_VIDEO_FLAG_PREMULTIPLIED_ALPHA; rect->x = render_x; rect->y = render_y; rect->render_width = render_width; rect->render_height = render_height; rect->global_alpha = 1.0; rect->applied_global_alpha = 1.0; rect->initial_alpha = NULL; rect->flags = flags; rect->seq_num = gst_video_overlay_get_seqnum (); GST_LOG ("new rectangle %p: %ux%u => %ux%u @ %u,%u, seq_num %u, format %u, " "flags %x, pixels %p, global_alpha=%f", rect, width, height, render_width, render_height, render_x, render_y, rect->seq_num, format, rect->flags, pixels, rect->global_alpha); return rect; } /** * gst_video_overlay_rectangle_get_render_rectangle: * @rectangle: a #GstVideoOverlayRectangle * @render_x: (out) (allow-none): address where to store the X render offset * @render_y: (out) (allow-none): address where to store the Y render offset * @render_width: (out) (allow-none): address where to store the render width * @render_height: (out) (allow-none): address where to store the render height * * Retrieves the render position and render dimension of the overlay * rectangle on the video. * * Returns: TRUE if valid render dimensions were retrieved. */ gboolean gst_video_overlay_rectangle_get_render_rectangle (GstVideoOverlayRectangle * rectangle, gint * render_x, gint * render_y, guint * render_width, guint * render_height) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), FALSE); if (render_x) *render_x = rectangle->x; if (render_y) *render_y = rectangle->y; if (render_width) *render_width = rectangle->render_width; if (render_height) *render_height = rectangle->render_height; return TRUE; } /** * gst_video_overlay_rectangle_set_render_rectangle: * @rectangle: a #GstVideoOverlayRectangle * @render_x: render X position of rectangle on video * @render_y: render Y position of rectangle on video * @render_width: render width of rectangle * @render_height: render height of rectangle * * Sets the render position and dimensions of the rectangle on the video. * This function is mainly for elements that modify the size of the video * in some way (e.g. through scaling or cropping) and need to adjust the * details of any overlays to match the operation that changed the size. * * @rectangle must be writable, meaning its refcount must be 1. You can * make the rectangles inside a #GstVideoOverlayComposition writable using * gst_video_overlay_composition_make_writable() or * gst_video_overlay_composition_copy(). */ void gst_video_overlay_rectangle_set_render_rectangle (GstVideoOverlayRectangle * rectangle, gint render_x, gint render_y, guint render_width, guint render_height) { g_return_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle)); g_return_if_fail (GST_MINI_OBJECT_REFCOUNT_VALUE (rectangle) == 1); rectangle->x = render_x; rectangle->y = render_y; rectangle->render_width = render_width; rectangle->render_height = render_height; } /* FIXME: orc-ify */ static void gst_video_overlay_rectangle_premultiply_0 (GstVideoFrame * frame) { int i, j; for (j = 0; j < GST_VIDEO_FRAME_HEIGHT (frame); ++j) { guint8 *line; line = GST_VIDEO_FRAME_PLANE_DATA (frame, 0); line += GST_VIDEO_FRAME_PLANE_STRIDE (frame, 0) * j; for (i = 0; i < GST_VIDEO_FRAME_WIDTH (frame); ++i) { int a = line[0]; line[1] = line[1] * a / 255; line[2] = line[2] * a / 255; line[3] = line[3] * a / 255; line += 4; } } } static void gst_video_overlay_rectangle_premultiply_3 (GstVideoFrame * frame) { int i, j; for (j = 0; j < GST_VIDEO_FRAME_HEIGHT (frame); ++j) { guint8 *line; line = GST_VIDEO_FRAME_PLANE_DATA (frame, 0); line += GST_VIDEO_FRAME_PLANE_STRIDE (frame, 0) * j; for (i = 0; i < GST_VIDEO_FRAME_WIDTH (frame); ++i) { int a = line[3]; line[0] = line[0] * a / 255; line[1] = line[1] * a / 255; line[2] = line[2] * a / 255; line += 4; } } } static void gst_video_overlay_rectangle_premultiply (GstVideoFrame * frame) { gint alpha_offset; alpha_offset = GST_VIDEO_FRAME_COMP_POFFSET (frame, 3); switch (alpha_offset) { case 0: gst_video_overlay_rectangle_premultiply_0 (frame); break; case 3: gst_video_overlay_rectangle_premultiply_3 (frame); break; default: g_assert_not_reached (); break; } } /* FIXME: orc-ify */ static void gst_video_overlay_rectangle_unpremultiply_0 (GstVideoFrame * frame) { int i, j; for (j = 0; j < GST_VIDEO_FRAME_HEIGHT (frame); ++j) { guint8 *line; line = GST_VIDEO_FRAME_PLANE_DATA (frame, 0); line += GST_VIDEO_FRAME_PLANE_STRIDE (frame, 0) * j; for (i = 0; i < GST_VIDEO_FRAME_WIDTH (frame); ++i) { int a = line[0]; if (a) { line[1] = MIN ((line[1] * 255 + a / 2) / a, 255); line[2] = MIN ((line[2] * 255 + a / 2) / a, 255); line[3] = MIN ((line[3] * 255 + a / 2) / a, 255); } line += 4; } } } static void gst_video_overlay_rectangle_unpremultiply_3 (GstVideoFrame * frame) { int i, j; for (j = 0; j < GST_VIDEO_FRAME_HEIGHT (frame); ++j) { guint8 *line; line = GST_VIDEO_FRAME_PLANE_DATA (frame, 0); line += GST_VIDEO_FRAME_PLANE_STRIDE (frame, 0) * j; for (i = 0; i < GST_VIDEO_FRAME_WIDTH (frame); ++i) { int a = line[3]; if (a) { line[0] = MIN ((line[0] * 255 + a / 2) / a, 255); line[1] = MIN ((line[1] * 255 + a / 2) / a, 255); line[2] = MIN ((line[2] * 255 + a / 2) / a, 255); } line += 4; } } } static void gst_video_overlay_rectangle_unpremultiply (GstVideoFrame * frame) { gint alpha_offset; alpha_offset = GST_VIDEO_FRAME_COMP_POFFSET (frame, 3); switch (alpha_offset) { case 0: gst_video_overlay_rectangle_unpremultiply_0 (frame); break; case 3: gst_video_overlay_rectangle_unpremultiply_3 (frame); break; default: g_assert_not_reached (); break; } } static void gst_video_overlay_rectangle_extract_alpha (GstVideoOverlayRectangle * rect) { guint8 *src, *dst; GstVideoFrame frame; gint i, j, w, h, stride, alpha_offset; alpha_offset = GST_VIDEO_INFO_COMP_POFFSET (&rect->info, 3); g_return_if_fail (alpha_offset == 0 || alpha_offset == 3); gst_video_frame_map (&frame, &rect->info, rect->pixels, GST_MAP_READ); src = GST_VIDEO_FRAME_PLANE_DATA (&frame, 0); w = GST_VIDEO_INFO_WIDTH (&rect->info); h = GST_VIDEO_INFO_HEIGHT (&rect->info); stride = GST_VIDEO_INFO_PLANE_STRIDE (&rect->info, 0); g_free (rect->initial_alpha); rect->initial_alpha = g_malloc (w * h); dst = rect->initial_alpha; for (i = 0; i < h; i++) { for (j = 0; j < w; j++) { *dst = src[alpha_offset]; dst++; src += 4; } src += stride - 4 * w; } gst_video_frame_unmap (&frame); } static void gst_video_overlay_rectangle_apply_global_alpha (GstVideoOverlayRectangle * rect, float global_alpha) { guint8 *src, *dst; GstVideoFrame frame; gint i, j, w, h, stride; gint argb_a, argb_r, argb_g, argb_b; gint alpha_offset; g_assert (!(rect->applied_global_alpha != 1.0 && rect->initial_alpha == NULL)); alpha_offset = GST_VIDEO_INFO_COMP_POFFSET (&rect->info, 3); g_return_if_fail (alpha_offset == 0 || alpha_offset == 3); if (global_alpha == rect->applied_global_alpha) return; if (rect->initial_alpha == NULL) gst_video_overlay_rectangle_extract_alpha (rect); src = rect->initial_alpha; rect->pixels = gst_buffer_make_writable (rect->pixels); gst_video_frame_map (&frame, &rect->info, rect->pixels, GST_MAP_READ); dst = GST_VIDEO_FRAME_PLANE_DATA (&frame, 0); w = GST_VIDEO_INFO_WIDTH (&rect->info); h = GST_VIDEO_INFO_HEIGHT (&rect->info); stride = GST_VIDEO_INFO_PLANE_STRIDE (&rect->info, 0); argb_a = GST_VIDEO_INFO_COMP_POFFSET (&rect->info, 3); argb_r = (argb_a + 1) % 4; argb_g = (argb_a + 2) % 4; argb_b = (argb_a + 3) % 4; for (i = 0; i < h; i++) { for (j = 0; j < w; j++) { guint8 na = (guint8) (*src * global_alpha); if (! !(rect->flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA)) { dst[argb_r] = (guint8) ((double) (dst[argb_r] * 255) / (double) dst[argb_a]) * na / 255; dst[argb_g] = (guint8) ((double) (dst[argb_g] * 255) / (double) dst[argb_a]) * na / 255; dst[argb_b] = (guint8) ((double) (dst[argb_b] * 255) / (double) dst[argb_a]) * na / 255; } dst[argb_a] = na; src++; dst += 4; } dst += stride - 4 * w; } gst_video_frame_unmap (&frame); rect->applied_global_alpha = global_alpha; } static void gst_video_overlay_rectangle_convert (GstVideoInfo * src, GstBuffer * src_buffer, GstVideoFormat dest_format, GstVideoInfo * dest, GstBuffer ** dest_buffer) { gint width, height, stride; GstVideoFrame src_frame, dest_frame; GstVideoFormat format; gint k, l; guint8 *sdata, *ddata; format = GST_VIDEO_INFO_FORMAT (src); width = GST_VIDEO_INFO_WIDTH (src); height = GST_VIDEO_INFO_HEIGHT (src); gst_video_info_init (dest); if (!gst_video_info_set_format (dest, dest_format, width, height)) { g_warn_if_reached (); return; } *dest_buffer = gst_buffer_new_and_alloc (GST_VIDEO_INFO_SIZE (dest)); gst_video_frame_map (&src_frame, src, src_buffer, GST_MAP_READ); gst_video_frame_map (&dest_frame, dest, *dest_buffer, GST_MAP_WRITE); sdata = GST_VIDEO_FRAME_PLANE_DATA (&src_frame, 0); ddata = GST_VIDEO_FRAME_PLANE_DATA (&dest_frame, 0); stride = GST_VIDEO_FRAME_PLANE_STRIDE (&src_frame, 0); if (format == GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_YUV && dest_format == GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_RGB) { gint ayuv; gint a, y, u, v, r, g, b; for (k = 0; k < height; k++) { for (l = 0; l < width; l++) { ayuv = GST_READ_UINT32_BE (sdata); a = ayuv >> 24; y = (ayuv >> 16) & 0xff; u = (ayuv >> 8) & 0xff; v = (ayuv & 0xff); r = (298 * y + 459 * v - 63514) >> 8; g = (298 * y - 55 * u - 136 * v + 19681) >> 8; b = (298 * y + 541 * u - 73988) >> 8; r = CLAMP (r, 0, 255); g = CLAMP (g, 0, 255); b = CLAMP (b, 0, 255); /* native endian ARGB */ *(guint32 *) ddata = ((a << 24) | (r << 16) | (g << 8) | b); sdata += 4; ddata += 4; } sdata += stride - 4 * width; } } else if (format == GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_RGB && dest_format == GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_YUV) { gint argb; gint a, y, u, v, r, g, b; for (k = 0; k < height; k++) { for (l = 0; l < width; l++) { /* native endian ARGB */ argb = *(guint32 *) sdata; a = argb >> 24; r = (argb >> 16) & 0xff; g = (argb >> 8) & 0xff; b = (argb & 0xff); y = (47 * r + 157 * g + 16 * b + 4096) >> 8; u = (-26 * r - 87 * g + 112 * b + 32768) >> 8; v = (112 * r - 102 * g - 10 * b + 32768) >> 8; y = CLAMP (y, 0, 255); u = CLAMP (u, 0, 255); v = CLAMP (v, 0, 255); GST_WRITE_UINT32_BE (ddata, ((a << 24) | (y << 16) | (u << 8) | v)); sdata += 4; ddata += 4; } sdata += stride - 4 * width; } } else { GST_ERROR ("unsupported conversion"); g_assert_not_reached (); } gst_video_frame_unmap (&src_frame); gst_video_frame_unmap (&dest_frame); } static GstBuffer * gst_video_overlay_rectangle_get_pixels_raw_internal (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags, gboolean unscaled, GstVideoFormat wanted_format) { GstVideoOverlayFormatFlags new_flags; GstVideoOverlayRectangle *scaled_rect = NULL, *conv_rect = NULL; GstVideoInfo info; GstVideoFrame frame; GstBuffer *buf; GList *l; guint width, height; guint wanted_width; guint wanted_height; gboolean apply_global_alpha; gboolean revert_global_alpha; GstVideoFormat format; g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), NULL); g_return_val_if_fail (gst_video_overlay_rectangle_check_flags (flags), NULL); width = GST_VIDEO_INFO_WIDTH (&rectangle->info); height = GST_VIDEO_INFO_HEIGHT (&rectangle->info); wanted_width = unscaled ? width : rectangle->render_width; wanted_height = unscaled ? height : rectangle->render_height; format = GST_VIDEO_INFO_FORMAT (&rectangle->info); apply_global_alpha = (! !(rectangle->flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA) && !(flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA)); revert_global_alpha = (! !(rectangle->flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA) && ! !(flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA)); /* This assumes we don't need to adjust the format */ if (wanted_width == width && wanted_height == height && wanted_format == format && gst_video_overlay_rectangle_is_same_alpha_type (rectangle->flags, flags)) { /* don't need to apply/revert global-alpha either: */ if ((!apply_global_alpha || rectangle->applied_global_alpha == rectangle->global_alpha) && (!revert_global_alpha || rectangle->applied_global_alpha == 1.0)) { return rectangle->pixels; } else { /* only apply/revert global-alpha */ scaled_rect = rectangle; goto done; } } /* see if we've got one cached already */ GST_RECTANGLE_LOCK (rectangle); for (l = rectangle->scaled_rectangles; l != NULL; l = l->next) { GstVideoOverlayRectangle *r = l->data; if (GST_VIDEO_INFO_WIDTH (&r->info) == wanted_width && GST_VIDEO_INFO_HEIGHT (&r->info) == wanted_height && GST_VIDEO_INFO_FORMAT (&r->info) == wanted_format && gst_video_overlay_rectangle_is_same_alpha_type (r->flags, flags)) { /* we'll keep these rectangles around until finalize, so it's ok not * to take our own ref here */ scaled_rect = r; break; } } GST_RECTANGLE_UNLOCK (rectangle); if (scaled_rect != NULL) goto done; /* maybe have one in the right format though */ if (format != wanted_format) { GST_RECTANGLE_LOCK (rectangle); for (l = rectangle->scaled_rectangles; l != NULL; l = l->next) { GstVideoOverlayRectangle *r = l->data; if (GST_VIDEO_INFO_FORMAT (&r->info) == wanted_format && gst_video_overlay_rectangle_is_same_alpha_type (r->flags, flags)) { /* we'll keep these rectangles around until finalize, so it's ok not * to take our own ref here */ conv_rect = r; break; } } GST_RECTANGLE_UNLOCK (rectangle); } else { conv_rect = rectangle; } if (conv_rect == NULL) { GstVideoInfo conv_info; gst_video_overlay_rectangle_convert (&rectangle->info, rectangle->pixels, wanted_format, &conv_info, &buf); gst_buffer_add_video_meta (buf, GST_VIDEO_FRAME_FLAG_NONE, GST_VIDEO_INFO_FORMAT (&conv_info), width, height); conv_rect = gst_video_overlay_rectangle_new_raw (buf, 0, 0, width, height, rectangle->flags); if (rectangle->global_alpha != 1.0) gst_video_overlay_rectangle_set_global_alpha (scaled_rect, rectangle->global_alpha); gst_buffer_unref (buf); /* keep this converted one around as well in any case */ GST_RECTANGLE_LOCK (rectangle); rectangle->scaled_rectangles = g_list_prepend (rectangle->scaled_rectangles, conv_rect); GST_RECTANGLE_UNLOCK (rectangle); } /* now we continue from conv_rect */ width = GST_VIDEO_INFO_WIDTH (&conv_rect->info); height = GST_VIDEO_INFO_HEIGHT (&conv_rect->info); format = GST_VIDEO_INFO_FORMAT (&conv_rect->info); /* not cached yet, do the preprocessing and put the result into our cache */ if (wanted_width != width || wanted_height != height) { GstVideoInfo scaled_info; /* we could check the cache for a scaled rect with global_alpha == 1 here */ gst_video_blend_scale_linear_RGBA (&conv_rect->info, conv_rect->pixels, wanted_height, wanted_width, &scaled_info, &buf); info = scaled_info; gst_buffer_add_video_meta (buf, GST_VIDEO_FRAME_FLAG_NONE, GST_VIDEO_INFO_FORMAT (&conv_rect->info), wanted_width, wanted_height); } else if (!gst_video_overlay_rectangle_is_same_alpha_type (conv_rect->flags, flags)) { /* if we don't have to scale, we have to modify the alpha values, so we * need to make a copy of the pixel memory (and we take ownership below) */ buf = gst_buffer_copy (conv_rect->pixels); info = conv_rect->info; } else { /* do not need to scale or modify alpha values, almost done then */ scaled_rect = conv_rect; goto done; } new_flags = conv_rect->flags; gst_video_frame_map (&frame, &info, buf, GST_MAP_READWRITE); if (!gst_video_overlay_rectangle_is_same_alpha_type (conv_rect->flags, flags)) { if (rectangle->flags & GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA) { gst_video_overlay_rectangle_unpremultiply (&frame); new_flags &= ~GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA; } else { gst_video_overlay_rectangle_premultiply (&frame); new_flags |= GST_VIDEO_OVERLAY_FORMAT_FLAG_PREMULTIPLIED_ALPHA; } } gst_video_frame_unmap (&frame); scaled_rect = gst_video_overlay_rectangle_new_raw (buf, 0, 0, wanted_width, wanted_height, new_flags); if (conv_rect->global_alpha != 1.0) gst_video_overlay_rectangle_set_global_alpha (scaled_rect, conv_rect->global_alpha); gst_buffer_unref (buf); GST_RECTANGLE_LOCK (rectangle); rectangle->scaled_rectangles = g_list_prepend (rectangle->scaled_rectangles, scaled_rect); GST_RECTANGLE_UNLOCK (rectangle); done: GST_RECTANGLE_LOCK (rectangle); if (apply_global_alpha && scaled_rect->applied_global_alpha != rectangle->global_alpha) { gst_video_overlay_rectangle_apply_global_alpha (scaled_rect, rectangle->global_alpha); gst_video_overlay_rectangle_set_global_alpha (scaled_rect, rectangle->global_alpha); } else if (revert_global_alpha && scaled_rect->applied_global_alpha != 1.0) { gst_video_overlay_rectangle_apply_global_alpha (scaled_rect, 1.0); } GST_RECTANGLE_UNLOCK (rectangle); return scaled_rect->pixels; } /** * gst_video_overlay_rectangle_get_pixels_raw: * @rectangle: a #GstVideoOverlayRectangle * @flags: flags * If a global_alpha value != 1 is set for the rectangle, the caller * should set the #GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA flag * if he wants to apply global-alpha himself. If the flag is not set * global_alpha is applied internally before returning the pixel-data. * * Returns: (transfer none): a #GstBuffer holding the pixel data with * format as originally provided and specified in video meta with * width and height of the render dimensions as per * gst_video_overlay_rectangle_get_render_rectangle(). This function does * not return a reference, the caller should obtain a reference of her own * with gst_buffer_ref() if needed. */ GstBuffer * gst_video_overlay_rectangle_get_pixels_raw (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags) { return gst_video_overlay_rectangle_get_pixels_raw_internal (rectangle, flags, FALSE, GST_VIDEO_INFO_FORMAT (&rectangle->info)); } /** * gst_video_overlay_rectangle_get_pixels_argb: * @rectangle: a #GstVideoOverlayRectangle * @flags: flags * If a global_alpha value != 1 is set for the rectangle, the caller * should set the #GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA flag * if he wants to apply global-alpha himself. If the flag is not set * global_alpha is applied internally before returning the pixel-data. * * Returns: (transfer none): a #GstBuffer holding the ARGB pixel data with * width and height of the render dimensions as per * gst_video_overlay_rectangle_get_render_rectangle(). This function does * not return a reference, the caller should obtain a reference of her own * with gst_buffer_ref() if needed. */ GstBuffer * gst_video_overlay_rectangle_get_pixels_argb (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags) { return gst_video_overlay_rectangle_get_pixels_raw_internal (rectangle, flags, FALSE, GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_RGB); } /** * gst_video_overlay_rectangle_get_pixels_ayuv: * @rectangle: a #GstVideoOverlayRectangle * @flags: flags * If a global_alpha value != 1 is set for the rectangle, the caller * should set the #GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA flag * if he wants to apply global-alpha himself. If the flag is not set * global_alpha is applied internally before returning the pixel-data. * * Returns: (transfer none): a #GstBuffer holding the AYUV pixel data with * width and height of the render dimensions as per * gst_video_overlay_rectangle_get_render_rectangle(). This function does * not return a reference, the caller should obtain a reference of her own * with gst_buffer_ref() if needed. */ GstBuffer * gst_video_overlay_rectangle_get_pixels_ayuv (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags) { return gst_video_overlay_rectangle_get_pixels_raw_internal (rectangle, flags, FALSE, GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_YUV); } /** * gst_video_overlay_rectangle_get_pixels_unscaled_raw: * @rectangle: a #GstVideoOverlayRectangle * @flags: flags. * If a global_alpha value != 1 is set for the rectangle, the caller * should set the #GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA flag * if he wants to apply global-alpha himself. If the flag is not set * global_alpha is applied internally before returning the pixel-data. * * Retrieves the pixel data as it is. This is useful if the caller can * do the scaling itself when handling the overlaying. The rectangle will * need to be scaled to the render dimensions, which can be retrieved using * gst_video_overlay_rectangle_get_render_rectangle(). * * Returns: (transfer none): a #GstBuffer holding the pixel data with * #GstVideoMeta set. This function does not return a reference, the caller * should obtain a reference of her own with gst_buffer_ref() if needed. */ GstBuffer * gst_video_overlay_rectangle_get_pixels_unscaled_raw (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), NULL); return gst_video_overlay_rectangle_get_pixels_raw_internal (rectangle, flags, TRUE, GST_VIDEO_INFO_FORMAT (&rectangle->info)); } /** * gst_video_overlay_rectangle_get_pixels_unscaled_argb: * @rectangle: a #GstVideoOverlayRectangle * @flags: flags. * If a global_alpha value != 1 is set for the rectangle, the caller * should set the #GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA flag * if he wants to apply global-alpha himself. If the flag is not set * global_alpha is applied internally before returning the pixel-data. * * Retrieves the pixel data as it is. This is useful if the caller can * do the scaling itself when handling the overlaying. The rectangle will * need to be scaled to the render dimensions, which can be retrieved using * gst_video_overlay_rectangle_get_render_rectangle(). * * Returns: (transfer none): a #GstBuffer holding the ARGB pixel data with * #GstVideoMeta set. This function does not return a reference, the caller * should obtain a reference of her own with gst_buffer_ref() if needed. */ GstBuffer * gst_video_overlay_rectangle_get_pixels_unscaled_argb (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), NULL); return gst_video_overlay_rectangle_get_pixels_raw_internal (rectangle, flags, TRUE, GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_RGB); } /** * gst_video_overlay_rectangle_get_pixels_unscaled_ayuv: * @rectangle: a #GstVideoOverlayRectangle * @flags: flags. * If a global_alpha value != 1 is set for the rectangle, the caller * should set the #GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA flag * if he wants to apply global-alpha himself. If the flag is not set * global_alpha is applied internally before returning the pixel-data. * * Retrieves the pixel data as it is. This is useful if the caller can * do the scaling itself when handling the overlaying. The rectangle will * need to be scaled to the render dimensions, which can be retrieved using * gst_video_overlay_rectangle_get_render_rectangle(). * * Returns: (transfer none): a #GstBuffer holding the AYUV pixel data with * #GstVideoMeta set. This function does not return a reference, the caller * should obtain a reference of her own with gst_buffer_ref() if needed. */ GstBuffer * gst_video_overlay_rectangle_get_pixels_unscaled_ayuv (GstVideoOverlayRectangle * rectangle, GstVideoOverlayFormatFlags flags) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), NULL); return gst_video_overlay_rectangle_get_pixels_raw_internal (rectangle, flags, TRUE, GST_VIDEO_OVERLAY_COMPOSITION_FORMAT_YUV); } /** * gst_video_overlay_rectangle_get_flags: * @rectangle: a #GstVideoOverlayRectangle * * Retrieves the flags associated with a #GstVideoOverlayRectangle. * This is useful if the caller can handle both premultiplied alpha and * non premultiplied alpha, for example. By knowing whether the rectangle * uses premultiplied or not, it can request the pixel data in the format * it is stored in, to avoid unnecessary conversion. * * Returns: the #GstVideoOverlayFormatFlags associated with the rectangle. */ GstVideoOverlayFormatFlags gst_video_overlay_rectangle_get_flags (GstVideoOverlayRectangle * rectangle) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), GST_VIDEO_OVERLAY_FORMAT_FLAG_NONE); return rectangle->flags; } /** * gst_video_overlay_rectangle_get_global_alpha: * @rectangle: a #GstVideoOverlayRectangle * * Retrieves the global-alpha value associated with a #GstVideoOverlayRectangle. * * Returns: the global-alpha value associated with the rectangle. */ gfloat gst_video_overlay_rectangle_get_global_alpha (GstVideoOverlayRectangle * rectangle) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), -1); return rectangle->global_alpha; } /** * gst_video_overlay_rectangle_set_global_alpha: * @rectangle: a #GstVideoOverlayRectangle * @global_alpha: Global alpha value (0 to 1.0) * * Sets the global alpha value associated with a #GstVideoOverlayRectangle. Per- * pixel alpha values are multiplied with this value. Valid * values: 0 <= global_alpha <= 1; 1 to deactivate. * * @rectangle must be writable, meaning its refcount must be 1. You can * make the rectangles inside a #GstVideoOverlayComposition writable using * gst_video_overlay_composition_make_writable() or * gst_video_overlay_composition_copy(). */ void gst_video_overlay_rectangle_set_global_alpha (GstVideoOverlayRectangle * rectangle, gfloat global_alpha) { g_return_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle)); g_return_if_fail (global_alpha >= 0 && global_alpha <= 1); if (rectangle->global_alpha != global_alpha) { rectangle->global_alpha = global_alpha; if (global_alpha != 1) rectangle->flags |= GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA; else rectangle->flags &= ~GST_VIDEO_OVERLAY_FORMAT_FLAG_GLOBAL_ALPHA; /* update seq_num automatically to signal the consumer, that data has changed * note, that this might mislead renderers, that can handle global-alpha * themselves, because what they want to know is whether the actual pixel data * has changed. */ rectangle->seq_num = gst_video_overlay_get_seqnum (); } } /** * gst_video_overlay_rectangle_copy: * @rectangle: (transfer none): a #GstVideoOverlayRectangle to copy * * Makes a copy of @rectangle, so that it is possible to modify it * (e.g. to change the render co-ordinates or render dimension). The * actual overlay pixel data buffers contained in the rectangle are not * copied. * * Returns: (transfer full): a new #GstVideoOverlayRectangle equivalent * to @rectangle. */ GstVideoOverlayRectangle * gst_video_overlay_rectangle_copy (GstVideoOverlayRectangle * rectangle) { GstVideoOverlayRectangle *copy; g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), NULL); copy = gst_video_overlay_rectangle_new_raw (rectangle->pixels, rectangle->x, rectangle->y, rectangle->render_width, rectangle->render_height, rectangle->flags); if (rectangle->global_alpha != 1) gst_video_overlay_rectangle_set_global_alpha (copy, rectangle->global_alpha); return copy; } /** * gst_video_overlay_rectangle_get_seqnum: * @rectangle: a #GstVideoOverlayRectangle * * Returns the sequence number of this rectangle. Sequence numbers are * monotonically increasing and unique for overlay compositions and rectangles * (meaning there will never be a rectangle with the same sequence number as * a composition). * * Using the sequence number of a rectangle as an indicator for changed * pixel-data of a rectangle is dangereous. Some API calls, like e.g. * gst_video_overlay_rectangle_set_global_alpha(), automatically update * the per rectangle sequence number, which is misleading for renderers/ * consumers, that handle global-alpha themselves. For them the * pixel-data returned by gst_video_overlay_rectangle_get_pixels_*() * wont be different for different global-alpha values. In this case a * renderer could also use the GstBuffer pointers as a hint for changed * pixel-data. * * Returns: the sequence number of @rectangle */ guint gst_video_overlay_rectangle_get_seqnum (GstVideoOverlayRectangle * rectangle) { g_return_val_if_fail (GST_IS_VIDEO_OVERLAY_RECTANGLE (rectangle), 0); return rectangle->seq_num; }