/* * This file is part of mpv. * * mpv is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * mpv 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 mpv. If not, see . */ #include #include #include #include #include #include #include #include #include "video.h" #include "misc/bstr.h" #include "options/m_config.h" #include "common/global.h" #include "options/options.h" #include "utils.h" #include "hwdec.h" #include "osd.h" #include "ra.h" #include "stream/stream.h" #include "video_shaders.h" #include "user_shaders.h" #include "video/out/filter_kernels.h" #include "video/out/aspect.h" #include "video/out/dither.h" #include "video/out/vo.h" // scale/cscale arguments that map directly to shader filter routines. // Note that the convolution filters are not included in this list. static const char *const fixed_scale_filters[] = { "bilinear", "bicubic_fast", "oversample", NULL }; static const char *const fixed_tscale_filters[] = { "oversample", "linear", NULL }; // must be sorted, and terminated with 0 int filter_sizes[] = {2, 4, 6, 8, 12, 16, 20, 24, 28, 32, 36, 40, 44, 48, 52, 56, 60, 64, 0}; int tscale_sizes[] = {2, 4, 6, 8, 0}; struct vertex_pt { float x, y; }; struct texplane { struct ra_tex *tex; int w, h; bool flipped; }; struct video_image { struct texplane planes[4]; struct mp_image *mpi; // original input image uint64_t id; // unique ID identifying mpi contents bool hwdec_mapped; }; enum plane_type { PLANE_NONE = 0, PLANE_RGB, PLANE_LUMA, PLANE_CHROMA, PLANE_ALPHA, PLANE_XYZ, }; static const char *plane_names[] = { [PLANE_NONE] = "unknown", [PLANE_RGB] = "rgb", [PLANE_LUMA] = "luma", [PLANE_CHROMA] = "chroma", [PLANE_ALPHA] = "alpha", [PLANE_XYZ] = "xyz", }; // A self-contained description of a source image which can be bound to a // texture unit and sampled from. Contains metadata about how it's to be used struct image { enum plane_type type; // must be set to something non-zero int components; // number of relevant coordinates float multiplier; // multiplier to be used when sampling struct ra_tex *tex; int w, h; // logical size (after transformation) struct gl_transform transform; // rendering transformation }; // A named image, for user scripting purposes struct saved_img { const char *name; struct image img; }; // A texture hook. This is some operation that transforms a named texture as // soon as it's generated struct tex_hook { const char *save_tex; const char *hook_tex[SHADER_MAX_HOOKS]; const char *bind_tex[SHADER_MAX_BINDS]; int components; // how many components are relevant (0 = same as input) void *priv; // this gets talloc_freed when the tex_hook is removed void (*hook)(struct gl_video *p, struct image img, // generates GLSL struct gl_transform *trans, void *priv); bool (*cond)(struct gl_video *p, struct image img, void *priv); }; struct surface { struct ra_tex *tex; uint64_t id; double pts; }; #define SURFACES_MAX 10 struct cached_file { char *path; struct bstr body; }; struct pass_info { struct bstr desc; struct mp_pass_perf perf; }; struct dr_buffer { struct ra_buf *buf; // The mpi reference will keep the data from being recycled (or from other // references gaining write access) while the GPU is accessing the buffer. struct mp_image *mpi; }; struct gl_video { struct ra *ra; struct mpv_global *global; struct mp_log *log; struct gl_video_opts opts; struct m_config_cache *opts_cache; struct gl_lcms *cms; int fb_depth; // actual bits available in GL main framebuffer struct m_color clear_color; bool force_clear_color; struct gl_shader_cache *sc; struct osd_state *osd_state; struct mpgl_osd *osd; double osd_pts; struct ra_tex *lut_3d_texture; bool use_lut_3d; int lut_3d_size[3]; struct ra_tex *dither_texture; struct mp_image_params real_image_params; // configured format struct mp_image_params image_params; // texture format (mind hwdec case) struct ra_imgfmt_desc ra_format; // texture format int plane_count; bool is_gray; bool has_alpha; char color_swizzle[5]; bool use_integer_conversion; struct video_image image; struct dr_buffer *dr_buffers; int num_dr_buffers; bool using_dr_path; bool dumb_mode; bool forced_dumb_mode; // Cached vertex array, to avoid re-allocation per frame. For simplicity, // our vertex format is simply a list of `vertex_pt`s, since this greatly // simplifies offset calculation at the cost of (unneeded) flexibility. struct vertex_pt *tmp_vertex; struct ra_renderpass_input *vao; int vao_len; const struct ra_format *fbo_format; struct ra_tex *merge_tex[4]; struct ra_tex *scale_tex[4]; struct ra_tex *integer_tex[4]; struct ra_tex *indirect_tex; struct ra_tex *blend_subs_tex; struct ra_tex *screen_tex; struct ra_tex *output_tex; struct ra_tex *vdpau_deinterleave_tex[2]; struct ra_tex **hook_textures; int num_hook_textures; int idx_hook_textures; struct ra_buf *hdr_peak_ssbo; struct surface surfaces[SURFACES_MAX]; // user pass descriptions and textures struct tex_hook *tex_hooks; int num_tex_hooks; struct gl_user_shader_tex *user_textures; int num_user_textures; int surface_idx; int surface_now; int frames_drawn; bool is_interpolated; bool output_tex_valid; // state for configured scalers struct scaler scaler[SCALER_COUNT]; struct mp_csp_equalizer_state *video_eq; struct mp_rect src_rect; // displayed part of the source video struct mp_rect dst_rect; // video rectangle on output window struct mp_osd_res osd_rect; // OSD size/margins // temporary during rendering struct compute_info pass_compute; // compute shader metadata for this pass struct image *pass_imgs; // bound images for this pass int num_pass_imgs; struct saved_img *saved_imgs; // saved (named) images for this frame int num_saved_imgs; // effective current texture metadata - this will essentially affect the // next render pass target, as well as implicitly tracking what needs to // be done with the image int texture_w, texture_h; struct gl_transform texture_offset; // texture transform without rotation int components; bool use_linear; float user_gamma; // pass info / metrics struct pass_info pass_fresh[VO_PASS_PERF_MAX]; struct pass_info pass_redraw[VO_PASS_PERF_MAX]; struct pass_info *pass; int pass_idx; struct timer_pool *upload_timer; struct timer_pool *blit_timer; struct timer_pool *osd_timer; int frames_uploaded; int frames_rendered; AVLFG lfg; // Cached because computing it can take relatively long int last_dither_matrix_size; float *last_dither_matrix; struct cached_file *files; int num_files; struct ra_hwdec *hwdec; struct ra_hwdec_mapper *hwdec_mapper; bool hwdec_active; bool dsi_warned; bool broken_frame; // temporary error state }; static const struct gl_video_opts gl_video_opts_def = { .dither_algo = DITHER_FRUIT, .dither_depth = -1, .dither_size = 6, .temporal_dither_period = 1, .fbo_format = "auto", .sigmoid_center = 0.75, .sigmoid_slope = 6.5, .scaler = { {{"bilinear", .params={NAN, NAN}}, {.params = {NAN, NAN}}, .cutoff = 0.001}, // scale {{NULL, .params={NAN, NAN}}, {.params = {NAN, NAN}}, .cutoff = 0.001}, // dscale {{"bilinear", .params={NAN, NAN}}, {.params = {NAN, NAN}}, .cutoff = 0.001}, // cscale {{"mitchell", .params={NAN, NAN}}, {.params = {NAN, NAN}}, .clamp = 1, }, // tscale }, .scaler_resizes_only = 1, .scaler_lut_size = 6, .interpolation_threshold = 0.0001, .alpha_mode = ALPHA_BLEND_TILES, .background = {0, 0, 0, 255}, .gamma = 1.0f, .tone_mapping = TONE_MAPPING_MOBIUS, .tone_mapping_param = NAN, .tone_mapping_desat = 1.0, .early_flush = -1, }; static int validate_scaler_opt(struct mp_log *log, const m_option_t *opt, struct bstr name, struct bstr param); static int validate_window_opt(struct mp_log *log, const m_option_t *opt, struct bstr name, struct bstr param); #define OPT_BASE_STRUCT struct gl_video_opts #define SCALER_OPTS(n, i) \ OPT_STRING_VALIDATE(n, scaler[i].kernel.name, 0, validate_scaler_opt), \ OPT_FLOAT(n"-param1", scaler[i].kernel.params[0], 0), \ OPT_FLOAT(n"-param2", scaler[i].kernel.params[1], 0), \ OPT_FLOAT(n"-blur", scaler[i].kernel.blur, 0), \ OPT_FLOATRANGE(n"-cutoff", scaler[i].cutoff, 0, 0.0, 1.0), \ OPT_FLOATRANGE(n"-taper", scaler[i].kernel.taper, 0, 0.0, 1.0), \ OPT_FLOAT(n"-wparam", scaler[i].window.params[0], 0), \ OPT_FLOAT(n"-wblur", scaler[i].window.blur, 0), \ OPT_FLOATRANGE(n"-wtaper", scaler[i].window.taper, 0, 0.0, 1.0), \ OPT_FLOATRANGE(n"-clamp", scaler[i].clamp, 0, 0.0, 1.0), \ OPT_FLOATRANGE(n"-radius", scaler[i].radius, 0, 0.5, 16.0), \ OPT_FLOATRANGE(n"-antiring", scaler[i].antiring, 0, 0.0, 1.0), \ OPT_STRING_VALIDATE(n"-window", scaler[i].window.name, 0, validate_window_opt) const struct m_sub_options gl_video_conf = { .opts = (const m_option_t[]) { OPT_CHOICE("gpu-dumb-mode", dumb_mode, 0, ({"auto", 0}, {"yes", 1}, {"no", -1})), OPT_FLOATRANGE("gamma-factor", gamma, 0, 0.1, 2.0), OPT_FLAG("gamma-auto", gamma_auto, 0), OPT_CHOICE_C("target-prim", target_prim, 0, mp_csp_prim_names), OPT_CHOICE_C("target-trc", target_trc, 0, mp_csp_trc_names), OPT_CHOICE("tone-mapping", tone_mapping, 0, ({"clip", TONE_MAPPING_CLIP}, {"mobius", TONE_MAPPING_MOBIUS}, {"reinhard", TONE_MAPPING_REINHARD}, {"hable", TONE_MAPPING_HABLE}, {"gamma", TONE_MAPPING_GAMMA}, {"linear", TONE_MAPPING_LINEAR})), OPT_FLAG("hdr-compute-peak", compute_hdr_peak, 0), OPT_FLOAT("tone-mapping-param", tone_mapping_param, 0), OPT_FLOAT("tone-mapping-desaturate", tone_mapping_desat, 0), OPT_FLAG("gamut-warning", gamut_warning, 0), OPT_FLAG("opengl-pbo", pbo, 0), SCALER_OPTS("scale", SCALER_SCALE), SCALER_OPTS("dscale", SCALER_DSCALE), SCALER_OPTS("cscale", SCALER_CSCALE), SCALER_OPTS("tscale", SCALER_TSCALE), OPT_INTRANGE("scaler-lut-size", scaler_lut_size, 0, 4, 10), OPT_FLAG("scaler-resizes-only", scaler_resizes_only, 0), OPT_FLAG("linear-scaling", linear_scaling, 0), OPT_FLAG("correct-downscaling", correct_downscaling, 0), OPT_FLAG("sigmoid-upscaling", sigmoid_upscaling, 0), OPT_FLOATRANGE("sigmoid-center", sigmoid_center, 0, 0.0, 1.0), OPT_FLOATRANGE("sigmoid-slope", sigmoid_slope, 0, 1.0, 20.0), OPT_STRING("fbo-format", fbo_format, 0), OPT_CHOICE_OR_INT("dither-depth", dither_depth, 0, -1, 16, ({"no", -1}, {"auto", 0})), OPT_CHOICE("dither", dither_algo, 0, ({"fruit", DITHER_FRUIT}, {"ordered", DITHER_ORDERED}, {"no", DITHER_NONE})), OPT_INTRANGE("dither-size-fruit", dither_size, 0, 2, 8), OPT_FLAG("temporal-dither", temporal_dither, 0), OPT_INTRANGE("temporal-dither-period", temporal_dither_period, 0, 1, 128), OPT_CHOICE("alpha", alpha_mode, 0, ({"no", ALPHA_NO}, {"yes", ALPHA_YES}, {"blend", ALPHA_BLEND}, {"blend-tiles", ALPHA_BLEND_TILES})), OPT_FLAG("opengl-rectangle-textures", use_rectangle, 0), OPT_COLOR("background", background, 0), OPT_FLAG("interpolation", interpolation, 0), OPT_FLOAT("interpolation-threshold", interpolation_threshold, 0), OPT_CHOICE("blend-subtitles", blend_subs, 0, ({"no", BLEND_SUBS_NO}, {"yes", BLEND_SUBS_YES}, {"video", BLEND_SUBS_VIDEO})), OPT_PATHLIST("glsl-shaders", user_shaders, 0), OPT_CLI_ALIAS("glsl-shader", "glsl-shaders-append"), OPT_FLAG("deband", deband, 0), OPT_SUBSTRUCT("deband", deband_opts, deband_conf, 0), OPT_FLOAT("sharpen", unsharp, 0), OPT_INTRANGE("gpu-tex-pad-x", tex_pad_x, 0, 0, 4096), OPT_INTRANGE("gpu-tex-pad-y", tex_pad_y, 0, 0, 4096), OPT_SUBSTRUCT("", icc_opts, mp_icc_conf, 0), OPT_STRING("gpu-shader-cache-dir", shader_cache_dir, 0), OPT_REPLACED("hdr-tone-mapping", "tone-mapping"), OPT_REPLACED("opengl-shaders", "glsl-shaders"), OPT_REPLACED("opengl-shader", "glsl-shader"), OPT_REPLACED("opengl-shader-cache-dir", "gpu-shader-cache-dir"), OPT_REPLACED("opengl-tex-pad-x", "gpu-tex-pad-x"), OPT_REPLACED("opengl-tex-pad-y", "gpu-tex-pad-y"), OPT_REPLACED("opengl-fbo-format", "fbo-format"), OPT_REPLACED("opengl-dumb-mode", "gpu-dumb-mode"), OPT_REPLACED("opengl-gamma", "gamma-factor"), {0} }, .size = sizeof(struct gl_video_opts), .defaults = &gl_video_opts_def, }; static void uninit_rendering(struct gl_video *p); static void uninit_scaler(struct gl_video *p, struct scaler *scaler); static void check_gl_features(struct gl_video *p); static bool pass_upload_image(struct gl_video *p, struct mp_image *mpi, uint64_t id); static const char *handle_scaler_opt(const char *name, bool tscale); static void reinit_from_options(struct gl_video *p); static void get_scale_factors(struct gl_video *p, bool transpose_rot, double xy[2]); static void gl_video_setup_hooks(struct gl_video *p); static void gl_video_update_options(struct gl_video *p); #define GLSL(x) gl_sc_add(p->sc, #x "\n"); #define GLSLF(...) gl_sc_addf(p->sc, __VA_ARGS__) #define GLSLHF(...) gl_sc_haddf(p->sc, __VA_ARGS__) #define PRELUDE(...) gl_sc_paddf(p->sc, __VA_ARGS__) static struct bstr load_cached_file(struct gl_video *p, const char *path) { if (!path || !path[0]) return (struct bstr){0}; for (int n = 0; n < p->num_files; n++) { if (strcmp(p->files[n].path, path) == 0) return p->files[n].body; } // not found -> load it struct bstr s = stream_read_file(path, p, p->global, 1024000); // 1024 kB if (s.len) { struct cached_file new = { .path = talloc_strdup(p, path), .body = s, }; MP_TARRAY_APPEND(p, p->files, p->num_files, new); return new.body; } return (struct bstr){0}; } static void debug_check_gl(struct gl_video *p, const char *msg) { if (p->ra->fns->debug_marker) p->ra->fns->debug_marker(p->ra, msg); } static void gl_video_reset_surfaces(struct gl_video *p) { for (int i = 0; i < SURFACES_MAX; i++) { p->surfaces[i].id = 0; p->surfaces[i].pts = MP_NOPTS_VALUE; } p->surface_idx = 0; p->surface_now = 0; p->frames_drawn = 0; p->output_tex_valid = false; } static void gl_video_reset_hooks(struct gl_video *p) { for (int i = 0; i < p->num_tex_hooks; i++) talloc_free(p->tex_hooks[i].priv); for (int i = 0; i < p->num_user_textures; i++) ra_tex_free(p->ra, &p->user_textures[i].tex); p->num_tex_hooks = 0; p->num_user_textures = 0; } static inline int surface_wrap(int id) { id = id % SURFACES_MAX; return id < 0 ? id + SURFACES_MAX : id; } static void reinit_osd(struct gl_video *p) { mpgl_osd_destroy(p->osd); p->osd = NULL; if (p->osd_state) p->osd = mpgl_osd_init(p->ra, p->log, p->osd_state); } static void uninit_rendering(struct gl_video *p) { for (int n = 0; n < SCALER_COUNT; n++) uninit_scaler(p, &p->scaler[n]); ra_tex_free(p->ra, &p->dither_texture); for (int n = 0; n < 4; n++) { ra_tex_free(p->ra, &p->merge_tex[n]); ra_tex_free(p->ra, &p->scale_tex[n]); ra_tex_free(p->ra, &p->integer_tex[n]); } ra_tex_free(p->ra, &p->indirect_tex); ra_tex_free(p->ra, &p->blend_subs_tex); ra_tex_free(p->ra, &p->screen_tex); ra_tex_free(p->ra, &p->output_tex); for (int n = 0; n < SURFACES_MAX; n++) ra_tex_free(p->ra, &p->surfaces[n].tex); for (int n = 0; n < p->num_hook_textures; n++) ra_tex_free(p->ra, &p->hook_textures[n]); for (int n = 0; n < 2; n++) ra_tex_free(p->ra, &p->vdpau_deinterleave_tex[n]); gl_video_reset_surfaces(p); gl_video_reset_hooks(p); gl_sc_reset_error(p->sc); } bool gl_video_gamma_auto_enabled(struct gl_video *p) { return p->opts.gamma_auto; } struct mp_colorspace gl_video_get_output_colorspace(struct gl_video *p) { return (struct mp_colorspace) { .primaries = p->opts.target_prim, .gamma = p->opts.target_trc, }; } // Warning: profile.start must point to a ta allocation, and the function // takes over ownership. void gl_video_set_icc_profile(struct gl_video *p, bstr icc_data) { if (gl_lcms_set_memory_profile(p->cms, icc_data)) reinit_from_options(p); } bool gl_video_icc_auto_enabled(struct gl_video *p) { return p->opts.icc_opts ? p->opts.icc_opts->profile_auto : false; } static bool gl_video_get_lut3d(struct gl_video *p, enum mp_csp_prim prim, enum mp_csp_trc trc) { if (!p->use_lut_3d) return false; struct AVBufferRef *icc = NULL; if (p->image.mpi) icc = p->image.mpi->icc_profile; if (p->lut_3d_texture && !gl_lcms_has_changed(p->cms, prim, trc, icc)) return true; // GLES3 doesn't provide filtered 16 bit integer textures // GLES2 doesn't even provide 3D textures const struct ra_format *fmt = ra_find_unorm_format(p->ra, 2, 4); if (!fmt || !(p->ra->caps & RA_CAP_TEX_3D)) { p->use_lut_3d = false; MP_WARN(p, "Disabling color management (no RGBA16 3D textures).\n"); return false; } struct lut3d *lut3d = NULL; if (!fmt || !gl_lcms_get_lut3d(p->cms, &lut3d, prim, trc, icc) || !lut3d) { p->use_lut_3d = false; return false; } ra_tex_free(p->ra, &p->lut_3d_texture); struct ra_tex_params params = { .dimensions = 3, .w = lut3d->size[0], .h = lut3d->size[1], .d = lut3d->size[2], .format = fmt, .render_src = true, .src_linear = true, .initial_data = lut3d->data, }; p->lut_3d_texture = ra_tex_create(p->ra, ¶ms); debug_check_gl(p, "after 3d lut creation"); for (int i = 0; i < 3; i++) p->lut_3d_size[i] = lut3d->size[i]; talloc_free(lut3d); return true; } // Fill an image struct from a ra_tex + some metadata static struct image image_wrap(struct ra_tex *tex, enum plane_type type, int components) { assert(type != PLANE_NONE); return (struct image){ .type = type, .tex = tex, .multiplier = 1.0, .w = tex ? tex->params.w : 1, .h = tex ? tex->params.h : 1, .transform = identity_trans, .components = components, }; } // Bind an image to a free texture unit and return its ID. static int pass_bind(struct gl_video *p, struct image img) { int idx = p->num_pass_imgs; MP_TARRAY_APPEND(p, p->pass_imgs, p->num_pass_imgs, img); return idx; } // Rotation by 90° and flipping. // w/h is used for recentering. static void get_transform(float w, float h, int rotate, bool flip, struct gl_transform *out_tr) { int a = rotate % 90 ? 0 : rotate / 90; int sin90[4] = {0, 1, 0, -1}; // just to avoid rounding issues etc. int cos90[4] = {1, 0, -1, 0}; struct gl_transform tr = {{{ cos90[a], sin90[a]}, {-sin90[a], cos90[a]}}}; // basically, recenter to keep the whole image in view float b[2] = {1, 1}; gl_transform_vec(tr, &b[0], &b[1]); tr.t[0] += b[0] < 0 ? w : 0; tr.t[1] += b[1] < 0 ? h : 0; if (flip) { struct gl_transform fliptr = {{{1, 0}, {0, -1}}, {0, h}}; gl_transform_trans(fliptr, &tr); } *out_tr = tr; } // Return the chroma plane upscaled to luma size, but with additional padding // for image sizes not aligned to subsampling. static int chroma_upsize(int size, int pixel) { return (size + pixel - 1) / pixel * pixel; } // If a and b are on the same plane, return what plane type should be used. // If a or b are none, the other type always wins. // Usually: LUMA/RGB/XYZ > CHROMA > ALPHA static enum plane_type merge_plane_types(enum plane_type a, enum plane_type b) { if (a == PLANE_NONE) return b; if (b == PLANE_LUMA || b == PLANE_RGB || b == PLANE_XYZ) return b; if (b != PLANE_NONE && a == PLANE_ALPHA) return b; return a; } // Places a video_image's image textures + associated metadata into img[]. The // number of textures is equal to p->plane_count. Any necessary plane offsets // are stored in off. (e.g. chroma position) static void pass_get_images(struct gl_video *p, struct video_image *vimg, struct image img[4], struct gl_transform off[4]) { assert(vimg->mpi); int w = p->image_params.w; int h = p->image_params.h; // Determine the chroma offset float ls_w = 1.0 / p->ra_format.chroma_w; float ls_h = 1.0 / p->ra_format.chroma_h; struct gl_transform chroma = {{{ls_w, 0.0}, {0.0, ls_h}}}; if (p->image_params.chroma_location != MP_CHROMA_CENTER) { int cx, cy; mp_get_chroma_location(p->image_params.chroma_location, &cx, &cy); // By default texture coordinates are such that chroma is centered with // any chroma subsampling. If a specific direction is given, make it // so that the luma and chroma sample line up exactly. // For 4:4:4, setting chroma location should have no effect at all. // luma sample size (in chroma coord. space) chroma.t[0] = ls_w < 1 ? ls_w * -cx / 2 : 0; chroma.t[1] = ls_h < 1 ? ls_h * -cy / 2 : 0; } int msb_valid_bits = p->ra_format.component_bits + MPMIN(p->ra_format.component_pad, 0); // The existing code assumes we just have a single tex multiplier for // all of the planes. This may change in the future float tex_mul = 1.0 / mp_get_csp_mul(p->image_params.color.space, msb_valid_bits, p->ra_format.component_bits); memset(img, 0, 4 * sizeof(img[0])); for (int n = 0; n < p->plane_count; n++) { struct texplane *t = &vimg->planes[n]; enum plane_type type = PLANE_NONE; for (int i = 0; i < 4; i++) { int c = p->ra_format.components[n][i]; enum plane_type ctype; if (c == 0) { ctype = PLANE_NONE; } else if (c == 4) { ctype = PLANE_ALPHA; } else if (p->image_params.color.space == MP_CSP_RGB) { ctype = PLANE_RGB; } else if (p->image_params.color.space == MP_CSP_XYZ) { ctype = PLANE_XYZ; } else { ctype = c == 1 ? PLANE_LUMA : PLANE_CHROMA; } type = merge_plane_types(type, ctype); } img[n] = (struct image){ .type = type, .tex = t->tex, .multiplier = tex_mul, .w = t->w, .h = t->h, }; for (int i = 0; i < 4; i++) img[n].components += !!p->ra_format.components[n][i]; get_transform(t->w, t->h, p->image_params.rotate, t->flipped, &img[n].transform); if (p->image_params.rotate % 180 == 90) MPSWAP(int, img[n].w, img[n].h); off[n] = identity_trans; if (type == PLANE_CHROMA) { struct gl_transform rot; get_transform(0, 0, p->image_params.rotate, true, &rot); struct gl_transform tr = chroma; gl_transform_vec(rot, &tr.t[0], &tr.t[1]); float dx = (chroma_upsize(w, p->ra_format.chroma_w) - w) * ls_w; float dy = (chroma_upsize(h, p->ra_format.chroma_h) - h) * ls_h; // Adjust the chroma offset if the real chroma size is fractional // due image sizes not aligned to chroma subsampling. struct gl_transform rot2; get_transform(0, 0, p->image_params.rotate, t->flipped, &rot2); if (rot2.m[0][0] < 0) tr.t[0] += dx; if (rot2.m[1][0] < 0) tr.t[0] += dy; if (rot2.m[0][1] < 0) tr.t[1] += dx; if (rot2.m[1][1] < 0) tr.t[1] += dy; off[n] = tr; } } } // Return the index of the given component (assuming all non-padding components // of all planes are concatenated into a linear list). static int find_comp(struct ra_imgfmt_desc *desc, int component) { int cur = 0; for (int n = 0; n < desc->num_planes; n++) { for (int i = 0; i < 4; i++) { if (desc->components[n][i]) { if (desc->components[n][i] == component) return cur; cur++; } } } return -1; } static void init_video(struct gl_video *p) { p->use_integer_conversion = false; if (p->hwdec && ra_hwdec_test_format(p->hwdec, p->image_params.imgfmt)) { if (p->hwdec->driver->overlay_frame) { MP_WARN(p, "Using HW-overlay mode. No GL filtering is performed " "on the video!\n"); } else { p->hwdec_mapper = ra_hwdec_mapper_create(p->hwdec, &p->image_params); if (!p->hwdec_mapper) MP_ERR(p, "Initializing texture for hardware decoding failed.\n"); } if (p->hwdec_mapper) p->image_params = p->hwdec_mapper->dst_params; const char **exts = p->hwdec->glsl_extensions; for (int n = 0; exts && exts[n]; n++) gl_sc_enable_extension(p->sc, (char *)exts[n]); p->hwdec_active = true; } p->ra_format = (struct ra_imgfmt_desc){0}; ra_get_imgfmt_desc(p->ra, p->image_params.imgfmt, &p->ra_format); p->plane_count = p->ra_format.num_planes; p->has_alpha = false; p->is_gray = true; for (int n = 0; n < p->ra_format.num_planes; n++) { for (int i = 0; i < 4; i++) { if (p->ra_format.components[n][i]) { p->has_alpha |= p->ra_format.components[n][i] == 4; p->is_gray &= p->ra_format.components[n][i] == 1 || p->ra_format.components[n][i] == 4; } } } for (int c = 0; c < 4; c++) { int loc = find_comp(&p->ra_format, c + 1); p->color_swizzle[c] = "rgba"[loc >= 0 && loc < 4 ? loc : 0]; } p->color_swizzle[4] = '\0'; // Format-dependent checks. check_gl_features(p); mp_image_params_guess_csp(&p->image_params); av_lfg_init(&p->lfg, 1); debug_check_gl(p, "before video texture creation"); if (!p->hwdec_active) { struct video_image *vimg = &p->image; struct mp_image layout = {0}; mp_image_set_params(&layout, &p->image_params); for (int n = 0; n < p->plane_count; n++) { struct texplane *plane = &vimg->planes[n]; const struct ra_format *format = p->ra_format.planes[n]; plane->w = mp_image_plane_w(&layout, n); plane->h = mp_image_plane_h(&layout, n); struct ra_tex_params params = { .dimensions = 2, .w = plane->w + p->opts.tex_pad_x, .h = plane->h + p->opts.tex_pad_y, .d = 1, .format = format, .render_src = true, .src_linear = format->linear_filter, .non_normalized = p->opts.use_rectangle, .host_mutable = true, }; MP_VERBOSE(p, "Texture for plane %d: %dx%d\n", n, params.w, params.h); plane->tex = ra_tex_create(p->ra, ¶ms); if (!plane->tex) abort(); // shit happens p->use_integer_conversion |= format->ctype == RA_CTYPE_UINT; } } debug_check_gl(p, "after video texture creation"); gl_video_setup_hooks(p); } static struct dr_buffer *gl_find_dr_buffer(struct gl_video *p, uint8_t *ptr) { for (int i = 0; i < p->num_dr_buffers; i++) { struct dr_buffer *buffer = &p->dr_buffers[i]; uint8_t *bufptr = buffer->buf->data; size_t size = buffer->buf->params.size; if (ptr >= bufptr && ptr < bufptr + size) return buffer; } return NULL; } static void gc_pending_dr_fences(struct gl_video *p, bool force) { again:; for (int n = 0; n < p->num_dr_buffers; n++) { struct dr_buffer *buffer = &p->dr_buffers[n]; if (!buffer->mpi) continue; bool res = p->ra->fns->buf_poll(p->ra, buffer->buf); if (res || force) { // Unreferencing the image could cause gl_video_dr_free_buffer() // to be called by the talloc destructor (if it was the last // reference). This will implicitly invalidate the buffer pointer // and change the p->dr_buffers array. To make it worse, it could // free multiple dr_buffers due to weird theoretical corner cases. // This is also why we use the goto to iterate again from the // start, because everything gets fucked up. Hail satan! struct mp_image *ref = buffer->mpi; buffer->mpi = NULL; talloc_free(ref); goto again; } } } static void unref_current_image(struct gl_video *p) { struct video_image *vimg = &p->image; if (vimg->hwdec_mapped) { assert(p->hwdec_active && p->hwdec_mapper); ra_hwdec_mapper_unmap(p->hwdec_mapper); memset(vimg->planes, 0, sizeof(vimg->planes)); vimg->hwdec_mapped = false; } vimg->id = 0; mp_image_unrefp(&vimg->mpi); // While we're at it, also garbage collect pending fences in here to // get it out of the way. gc_pending_dr_fences(p, false); } // If overlay mode is used, make sure to remove the overlay. // Be careful with this. Removing the overlay and adding another one will // lead to flickering artifacts. static void unmap_overlay(struct gl_video *p) { if (p->hwdec_active && p->hwdec->driver->overlay_frame) p->hwdec->driver->overlay_frame(p->hwdec, NULL, NULL, NULL, true); } static void uninit_video(struct gl_video *p) { uninit_rendering(p); struct video_image *vimg = &p->image; unmap_overlay(p); unref_current_image(p); for (int n = 0; n < p->plane_count; n++) { struct texplane *plane = &vimg->planes[n]; ra_tex_free(p->ra, &plane->tex); } *vimg = (struct video_image){0}; // Invalidate image_params to ensure that gl_video_config() will call // init_video() on uninitialized gl_video. p->real_image_params = (struct mp_image_params){0}; p->image_params = p->real_image_params; p->hwdec_active = false; ra_hwdec_mapper_free(&p->hwdec_mapper); } static void pass_record(struct gl_video *p, struct mp_pass_perf perf) { if (!p->pass || p->pass_idx == VO_PASS_PERF_MAX) return; struct pass_info *pass = &p->pass[p->pass_idx]; pass->perf = perf; if (pass->desc.len == 0) bstr_xappend(p, &pass->desc, bstr0("(unknown)")); p->pass_idx++; } PRINTF_ATTRIBUTE(2, 3) static void pass_describe(struct gl_video *p, const char *textf, ...) { if (!p->pass || p->pass_idx == VO_PASS_PERF_MAX) return; struct pass_info *pass = &p->pass[p->pass_idx]; if (pass->desc.len > 0) bstr_xappend(p, &pass->desc, bstr0(" + ")); va_list ap; va_start(ap, textf); bstr_xappend_vasprintf(p, &pass->desc, textf, ap); va_end(ap); } static void pass_info_reset(struct gl_video *p, bool is_redraw) { p->pass = is_redraw ? p->pass_redraw : p->pass_fresh; p->pass_idx = 0; for (int i = 0; i < VO_PASS_PERF_MAX; i++) { p->pass[i].desc.len = 0; p->pass[i].perf = (struct mp_pass_perf){0}; } } static void pass_report_performance(struct gl_video *p) { if (!p->pass) return; for (int i = 0; i < VO_PASS_PERF_MAX; i++) { struct pass_info *pass = &p->pass[i]; if (pass->desc.len) { MP_DBG(p, "pass '%.*s': last %dus avg %dus peak %dus\n", BSTR_P(pass->desc), (int)pass->perf.last/1000, (int)pass->perf.avg/1000, (int)pass->perf.peak/1000); } } } static void pass_prepare_src_tex(struct gl_video *p) { struct gl_shader_cache *sc = p->sc; for (int n = 0; n < p->num_pass_imgs; n++) { struct image *s = &p->pass_imgs[n]; if (!s->tex) continue; char *texture_name = mp_tprintf(32, "texture%d", n); char *texture_size = mp_tprintf(32, "texture_size%d", n); char *texture_rot = mp_tprintf(32, "texture_rot%d", n); char *texture_off = mp_tprintf(32, "texture_off%d", n); char *pixel_size = mp_tprintf(32, "pixel_size%d", n); gl_sc_uniform_texture(sc, texture_name, s->tex); float f[2] = {1, 1}; if (!s->tex->params.non_normalized) { f[0] = s->tex->params.w; f[1] = s->tex->params.h; } gl_sc_uniform_vec2(sc, texture_size, f); gl_sc_uniform_mat2(sc, texture_rot, true, (float *)s->transform.m); gl_sc_uniform_vec2(sc, texture_off, (float *)s->transform.t); gl_sc_uniform_vec2(sc, pixel_size, (float[]){1.0f / f[0], 1.0f / f[1]}); } } static void cleanup_binds(struct gl_video *p) { p->num_pass_imgs = 0; } // Sets the appropriate compute shader metadata for an implicit compute pass // bw/bh: block size static void pass_is_compute(struct gl_video *p, int bw, int bh) { p->pass_compute = (struct compute_info){ .active = true, .block_w = bw, .block_h = bh, }; } // w/h: the width/height of the compute shader's operating domain (e.g. the // target target that needs to be written, or the source texture that needs to // be reduced) static void dispatch_compute(struct gl_video *p, int w, int h, struct compute_info info) { PRELUDE("layout (local_size_x = %d, local_size_y = %d) in;\n", info.threads_w > 0 ? info.threads_w : info.block_w, info.threads_h > 0 ? info.threads_h : info.block_h); pass_prepare_src_tex(p); // Since we don't actually have vertices, we pretend for convenience // reasons that we do and calculate the right texture coordinates based on // the output sample ID gl_sc_uniform_vec2(p->sc, "out_scale", (float[2]){ 1.0 / w, 1.0 / h }); PRELUDE("#define outcoord(id) (out_scale * (vec2(id) + vec2(0.5)))\n"); for (int n = 0; n < p->num_pass_imgs; n++) { struct image *s = &p->pass_imgs[n]; if (!s->tex) continue; // We need to rescale the coordinates to the true texture size char *tex_scale = mp_tprintf(32, "tex_scale%d", n); gl_sc_uniform_vec2(p->sc, tex_scale, (float[2]){ (float)s->w / s->tex->params.w, (float)s->h / s->tex->params.h, }); PRELUDE("#define texmap%d_raw(id) (tex_scale%d * outcoord(id))\n", n, n); PRELUDE("#define texmap%d(id) (texture_rot%d * texmap%d_raw(id) + " "pixel_size%d * texture_off%d)\n", n, n, n, n, n); PRELUDE("#define texcoord%d texmap%d(gl_GlobalInvocationID)\n", n, n); } // always round up when dividing to make sure we don't leave off a part of // the image int num_x = info.block_w > 0 ? (w + info.block_w - 1) / info.block_w : 1, num_y = info.block_h > 0 ? (h + info.block_h - 1) / info.block_h : 1; pass_record(p, gl_sc_dispatch_compute(p->sc, num_x, num_y, 1)); cleanup_binds(p); } static struct mp_pass_perf render_pass_quad(struct gl_video *p, struct ra_fbo fbo, const struct mp_rect *dst) { // The first element is reserved for `vec2 position` int num_vertex_attribs = 1 + p->num_pass_imgs; size_t vertex_stride = num_vertex_attribs * sizeof(struct vertex_pt); // Expand the VAO if necessary while (p->vao_len < num_vertex_attribs) { MP_TARRAY_APPEND(p, p->vao, p->vao_len, (struct ra_renderpass_input) { .name = talloc_asprintf(p, "texcoord%d", p->vao_len - 1), .type = RA_VARTYPE_FLOAT, .dim_v = 2, .dim_m = 1, .offset = p->vao_len * sizeof(struct vertex_pt), }); } int num_vertices = 6; // quad as triangle list int num_attribs_total = num_vertices * num_vertex_attribs; MP_TARRAY_GROW(p, p->tmp_vertex, num_attribs_total); struct gl_transform t; gl_transform_ortho_fbo(&t, fbo); float x[2] = {dst->x0, dst->x1}; float y[2] = {dst->y0, dst->y1}; gl_transform_vec(t, &x[0], &y[0]); gl_transform_vec(t, &x[1], &y[1]); for (int n = 0; n < 4; n++) { struct vertex_pt *vs = &p->tmp_vertex[num_vertex_attribs * n]; // vec2 position in idx 0 vs[0].x = x[n / 2]; vs[0].y = y[n % 2]; for (int i = 0; i < p->num_pass_imgs; i++) { struct image *s = &p->pass_imgs[i]; if (!s->tex) continue; struct gl_transform tr = s->transform; float tx = (n / 2) * s->w; float ty = (n % 2) * s->h; gl_transform_vec(tr, &tx, &ty); bool rect = s->tex->params.non_normalized; // vec2 texcoordN in idx N+1 vs[i + 1].x = tx / (rect ? 1 : s->tex->params.w); vs[i + 1].y = ty / (rect ? 1 : s->tex->params.h); } } memmove(&p->tmp_vertex[num_vertex_attribs * 4], &p->tmp_vertex[num_vertex_attribs * 2], vertex_stride); memmove(&p->tmp_vertex[num_vertex_attribs * 5], &p->tmp_vertex[num_vertex_attribs * 1], vertex_stride); return gl_sc_dispatch_draw(p->sc, fbo.tex, p->vao, num_vertex_attribs, vertex_stride, p->tmp_vertex, num_vertices); } static void finish_pass_fbo(struct gl_video *p, struct ra_fbo fbo, const struct mp_rect *dst) { pass_prepare_src_tex(p); pass_record(p, render_pass_quad(p, fbo, dst)); debug_check_gl(p, "after rendering"); cleanup_binds(p); } // dst_fbo: this will be used for rendering; possibly reallocating the whole // FBO, if the required parameters have changed // w, h: required FBO target dimension, and also defines the target rectangle // used for rasterization static void finish_pass_tex(struct gl_video *p, struct ra_tex **dst_tex, int w, int h) { if (!ra_tex_resize(p->ra, p->log, dst_tex, w, h, p->fbo_format)) { cleanup_binds(p); gl_sc_reset(p->sc); return; } if (p->pass_compute.active) { gl_sc_uniform_image2D_wo(p->sc, "out_image", *dst_tex); if (!p->pass_compute.directly_writes) GLSL(imageStore(out_image, ivec2(gl_GlobalInvocationID), color);) dispatch_compute(p, w, h, p->pass_compute); p->pass_compute = (struct compute_info){0}; debug_check_gl(p, "after dispatching compute shader"); } else { struct ra_fbo fbo = { .tex = *dst_tex, }; finish_pass_fbo(p, fbo, &(struct mp_rect){0, 0, w, h}); } } static const char *get_tex_swizzle(struct image *img) { if (!img->tex) return "rgba"; return img->tex->params.format->luminance_alpha ? "raaa" : "rgba"; } // Copy a texture to the vec4 color, while increasing offset. Also applies // the texture multiplier to the sampled color static void copy_image(struct gl_video *p, int *offset, struct image img) { int count = img.components; assert(*offset + count <= 4); int id = pass_bind(p, img); char src[5] = {0}; char dst[5] = {0}; const char *tex_fmt = get_tex_swizzle(&img); const char *dst_fmt = "rgba"; for (int i = 0; i < count; i++) { src[i] = tex_fmt[i]; dst[i] = dst_fmt[*offset + i]; } if (img.tex && img.tex->params.format->ctype == RA_CTYPE_UINT) { uint64_t tex_max = 1ull << p->ra_format.component_bits; img.multiplier *= 1.0 / (tex_max - 1); } GLSLF("color.%s = %f * vec4(texture(texture%d, texcoord%d)).%s;\n", dst, img.multiplier, id, id, src); *offset += count; } static void skip_unused(struct gl_video *p, int num_components) { for (int i = num_components; i < 4; i++) GLSLF("color.%c = %f;\n", "rgba"[i], i < 3 ? 0.0 : 1.0); } static void uninit_scaler(struct gl_video *p, struct scaler *scaler) { ra_tex_free(p->ra, &scaler->sep_fbo); ra_tex_free(p->ra, &scaler->lut); scaler->kernel = NULL; scaler->initialized = false; } static void hook_prelude(struct gl_video *p, const char *name, int id, struct image img) { GLSLHF("#define %s_raw texture%d\n", name, id); GLSLHF("#define %s_pos texcoord%d\n", name, id); GLSLHF("#define %s_size texture_size%d\n", name, id); GLSLHF("#define %s_rot texture_rot%d\n", name, id); GLSLHF("#define %s_pt pixel_size%d\n", name, id); GLSLHF("#define %s_map texmap%d\n", name, id); GLSLHF("#define %s_mul %f\n", name, img.multiplier); // Set up the sampling functions GLSLHF("#define %s_tex(pos) (%s_mul * vec4(texture(%s_raw, pos)).%s)\n", name, name, name, get_tex_swizzle(&img)); // Since the extra matrix multiplication impacts performance, // skip it unless the texture was actually rotated if (gl_transform_eq(img.transform, identity_trans)) { GLSLHF("#define %s_texOff(off) %s_tex(%s_pos + %s_pt * vec2(off))\n", name, name, name, name); } else { GLSLHF("#define %s_texOff(off) " "%s_tex(%s_pos + %s_rot * vec2(off)/%s_size)\n", name, name, name, name, name); } } static bool saved_img_find(struct gl_video *p, const char *name, struct image *out) { if (!name || !out) return false; for (int i = 0; i < p->num_saved_imgs; i++) { if (strcmp(p->saved_imgs[i].name, name) == 0) { *out = p->saved_imgs[i].img; return true; } } return false; } static void saved_img_store(struct gl_video *p, const char *name, struct image img) { assert(name); for (int i = 0; i < p->num_saved_imgs; i++) { if (strcmp(p->saved_imgs[i].name, name) == 0) { p->saved_imgs[i].img = img; return; } } MP_TARRAY_APPEND(p, p->saved_imgs, p->num_saved_imgs, (struct saved_img) { .name = name, .img = img }); } static bool pass_hook_setup_binds(struct gl_video *p, const char *name, struct image img, struct tex_hook *hook) { for (int t = 0; t < SHADER_MAX_BINDS; t++) { char *bind_name = (char *)hook->bind_tex[t]; if (!bind_name) continue; // This is a special name that means "currently hooked texture" if (strcmp(bind_name, "HOOKED") == 0) { int id = pass_bind(p, img); hook_prelude(p, "HOOKED", id, img); hook_prelude(p, name, id, img); continue; } // BIND can also be used to load user-defined textures, in which // case we will directly load them as a uniform instead of // generating the hook_prelude boilerplate for (int u = 0; u < p->num_user_textures; u++) { struct gl_user_shader_tex *utex = &p->user_textures[u]; if (bstr_equals0(utex->name, bind_name)) { gl_sc_uniform_texture(p->sc, bind_name, utex->tex); goto next_bind; } } struct image bind_img; if (!saved_img_find(p, bind_name, &bind_img)) { // Clean up texture bindings and move on to the next hook MP_DBG(p, "Skipping hook on %s due to no texture named %s.\n", name, bind_name); p->num_pass_imgs -= t; return false; } hook_prelude(p, bind_name, pass_bind(p, bind_img), bind_img); next_bind: ; } return true; } static struct ra_tex **next_hook_tex(struct gl_video *p) { if (p->idx_hook_textures == p->num_hook_textures) MP_TARRAY_APPEND(p, p->hook_textures, p->num_hook_textures, NULL); return &p->hook_textures[p->idx_hook_textures++]; } // Process hooks for a plane, saving the result and returning a new image // If 'trans' is NULL, the shader is forbidden from transforming img static struct image pass_hook(struct gl_video *p, const char *name, struct image img, struct gl_transform *trans) { if (!name) return img; saved_img_store(p, name, img); MP_DBG(p, "Running hooks for %s\n", name); for (int i = 0; i < p->num_tex_hooks; i++) { struct tex_hook *hook = &p->tex_hooks[i]; // Figure out if this pass hooks this texture for (int h = 0; h < SHADER_MAX_HOOKS; h++) { if (hook->hook_tex[h] && strcmp(hook->hook_tex[h], name) == 0) goto found; } continue; found: // Check the hook's condition if (hook->cond && !hook->cond(p, img, hook->priv)) { MP_DBG(p, "Skipping hook on %s due to condition.\n", name); continue; } if (!pass_hook_setup_binds(p, name, img, hook)) continue; // Run the actual hook. This generates a series of GLSL shader // instructions sufficient for drawing the hook's output struct gl_transform hook_off = identity_trans; hook->hook(p, img, &hook_off, hook->priv); int comps = hook->components ? hook->components : img.components; skip_unused(p, comps); // Compute the updated FBO dimensions and store the result struct mp_rect_f sz = {0, 0, img.w, img.h}; gl_transform_rect(hook_off, &sz); int w = lroundf(fabs(sz.x1 - sz.x0)); int h = lroundf(fabs(sz.y1 - sz.y0)); struct ra_tex **tex = next_hook_tex(p); finish_pass_tex(p, tex, w, h); const char *store_name = hook->save_tex ? hook->save_tex : name; struct image saved_img = image_wrap(*tex, img.type, comps); // If the texture we're saving overwrites the "current" texture, also // update the tex parameter so that the future loop cycles will use the // updated values, and export the offset if (strcmp(store_name, name) == 0) { if (!trans && !gl_transform_eq(hook_off, identity_trans)) { MP_ERR(p, "Hook tried changing size of unscalable texture %s!\n", name); return img; } img = saved_img; if (trans) gl_transform_trans(hook_off, trans); } saved_img_store(p, store_name, saved_img); } return img; } // This can be used at any time in the middle of rendering to specify an // optional hook point, which if triggered will render out to a new FBO and // load the result back into vec4 color. Offsets applied by the hooks are // accumulated in tex_trans, and the FBO is dimensioned according // to p->texture_w/h static void pass_opt_hook_point(struct gl_video *p, const char *name, struct gl_transform *tex_trans) { if (!name) return; for (int i = 0; i < p->num_tex_hooks; i++) { struct tex_hook *hook = &p->tex_hooks[i]; for (int h = 0; h < SHADER_MAX_HOOKS; h++) { if (hook->hook_tex[h] && strcmp(hook->hook_tex[h], name) == 0) goto found; } for (int b = 0; b < SHADER_MAX_BINDS; b++) { if (hook->bind_tex[b] && strcmp(hook->bind_tex[b], name) == 0) goto found; } } // Nothing uses this texture, don't bother storing it return; found: ; struct ra_tex **tex = next_hook_tex(p); finish_pass_tex(p, tex, p->texture_w, p->texture_h); struct image img = image_wrap(*tex, PLANE_RGB, p->components); img = pass_hook(p, name, img, tex_trans); copy_image(p, &(int){0}, img); p->texture_w = img.w; p->texture_h = img.h; p->components = img.components; pass_describe(p, "(remainder pass)"); } static void load_shader(struct gl_video *p, struct bstr body) { gl_sc_hadd_bstr(p->sc, body); gl_sc_uniform_dynamic(p->sc); gl_sc_uniform_f(p->sc, "random", (double)av_lfg_get(&p->lfg) / UINT32_MAX); gl_sc_uniform_dynamic(p->sc); gl_sc_uniform_i(p->sc, "frame", p->frames_uploaded); gl_sc_uniform_vec2(p->sc, "input_size", (float[]){(p->src_rect.x1 - p->src_rect.x0) * p->texture_offset.m[0][0], (p->src_rect.y1 - p->src_rect.y0) * p->texture_offset.m[1][1]}); gl_sc_uniform_vec2(p->sc, "target_size", (float[]){p->dst_rect.x1 - p->dst_rect.x0, p->dst_rect.y1 - p->dst_rect.y0}); gl_sc_uniform_vec2(p->sc, "tex_offset", (float[]){p->src_rect.x0 * p->texture_offset.m[0][0] + p->texture_offset.t[0], p->src_rect.y0 * p->texture_offset.m[1][1] + p->texture_offset.t[1]}); } // Semantic equality static bool double_seq(double a, double b) { return (isnan(a) && isnan(b)) || a == b; } static bool scaler_fun_eq(struct scaler_fun a, struct scaler_fun b) { if ((a.name && !b.name) || (b.name && !a.name)) return false; return ((!a.name && !b.name) || strcmp(a.name, b.name) == 0) && double_seq(a.params[0], b.params[0]) && double_seq(a.params[1], b.params[1]) && a.blur == b.blur && a.taper == b.taper; } static bool scaler_conf_eq(struct scaler_config a, struct scaler_config b) { // Note: antiring isn't compared because it doesn't affect LUT // generation return scaler_fun_eq(a.kernel, b.kernel) && scaler_fun_eq(a.window, b.window) && a.radius == b.radius && a.clamp == b.clamp; } static void reinit_scaler(struct gl_video *p, struct scaler *scaler, const struct scaler_config *conf, double scale_factor, int sizes[]) { if (scaler_conf_eq(scaler->conf, *conf) && scaler->scale_factor == scale_factor && scaler->initialized) return; uninit_scaler(p, scaler); scaler->conf = *conf; bool is_tscale = scaler->index == SCALER_TSCALE; scaler->conf.kernel.name = (char *)handle_scaler_opt(conf->kernel.name, is_tscale); scaler->conf.window.name = (char *)handle_scaler_opt(conf->window.name, is_tscale); scaler->scale_factor = scale_factor; scaler->insufficient = false; scaler->initialized = true; const struct filter_kernel *t_kernel = mp_find_filter_kernel(conf->kernel.name); if (!t_kernel) return; scaler->kernel_storage = *t_kernel; scaler->kernel = &scaler->kernel_storage; const char *win = conf->window.name; if (!win || !win[0]) win = t_kernel->window; // fall back to the scaler's default window const struct filter_window *t_window = mp_find_filter_window(win); if (t_window) scaler->kernel->w = *t_window; for (int n = 0; n < 2; n++) { if (!isnan(conf->kernel.params[n])) scaler->kernel->f.params[n] = conf->kernel.params[n]; if (!isnan(conf->window.params[n])) scaler->kernel->w.params[n] = conf->window.params[n]; } if (conf->kernel.blur > 0.0) scaler->kernel->f.blur = conf->kernel.blur; if (conf->window.blur > 0.0) scaler->kernel->w.blur = conf->window.blur; if (conf->kernel.taper > 0.0) scaler->kernel->f.taper = conf->kernel.taper; if (conf->window.taper > 0.0) scaler->kernel->w.taper = conf->window.taper; if (scaler->kernel->f.resizable && conf->radius > 0.0) scaler->kernel->f.radius = conf->radius; scaler->kernel->clamp = conf->clamp; scaler->kernel->value_cutoff = conf->cutoff; scaler->insufficient = !mp_init_filter(scaler->kernel, sizes, scale_factor); int size = scaler->kernel->size; int num_components = size > 2 ? 4 : size; const struct ra_format *fmt = ra_find_float16_format(p->ra, num_components); assert(fmt); int width = (size + num_components - 1) / num_components; // round up int stride = width * num_components; assert(size <= stride); scaler->lut_size = 1 << p->opts.scaler_lut_size; float *weights = talloc_array(NULL, float, scaler->lut_size * stride); mp_compute_lut(scaler->kernel, scaler->lut_size, stride, weights); bool use_1d = scaler->kernel->polar && (p->ra->caps & RA_CAP_TEX_1D); struct ra_tex_params lut_params = { .dimensions = use_1d ? 1 : 2, .w = use_1d ? scaler->lut_size : width, .h = use_1d ? 1 : scaler->lut_size, .d = 1, .format = fmt, .render_src = true, .src_linear = true, .initial_data = weights, }; scaler->lut = ra_tex_create(p->ra, &lut_params); talloc_free(weights); debug_check_gl(p, "after initializing scaler"); } // Special helper for sampling from two separated stages static void pass_sample_separated(struct gl_video *p, struct image src, struct scaler *scaler, int w, int h) { // Separate the transformation into x and y components, per pass struct gl_transform t_x = { .m = {{src.transform.m[0][0], 0.0}, {src.transform.m[1][0], 1.0}}, .t = {src.transform.t[0], 0.0}, }; struct gl_transform t_y = { .m = {{1.0, src.transform.m[0][1]}, {0.0, src.transform.m[1][1]}}, .t = {0.0, src.transform.t[1]}, }; // First pass (scale only in the y dir) src.transform = t_y; sampler_prelude(p->sc, pass_bind(p, src)); GLSLF("// first pass\n"); pass_sample_separated_gen(p->sc, scaler, 0, 1); GLSLF("color *= %f;\n", src.multiplier); finish_pass_tex(p, &scaler->sep_fbo, src.w, h); // Second pass (scale only in the x dir) src = image_wrap(scaler->sep_fbo, src.type, src.components); src.transform = t_x; pass_describe(p, "%s second pass", scaler->conf.kernel.name); sampler_prelude(p->sc, pass_bind(p, src)); pass_sample_separated_gen(p->sc, scaler, 1, 0); } // Picks either the compute shader version or the regular sampler version // depending on hardware support static void pass_dispatch_sample_polar(struct gl_video *p, struct scaler *scaler, struct image img, int w, int h) { uint64_t reqs = RA_CAP_COMPUTE; if ((p->ra->caps & reqs) != reqs) goto fallback; int bound = ceil(scaler->kernel->radius_cutoff); int offset = bound - 1; // padding top/left int padding = offset + bound; // total padding float ratiox = (float)w / img.w, ratioy = (float)h / img.h; // For performance we want to load at least as many pixels // horizontally as there are threads in a warp (32 for nvidia), as // well as enough to take advantage of shmem parallelism const int warp_size = 32, threads = 256; int bw = warp_size; int bh = threads / bw; // We need to sample everything from base_min to base_max, so make sure // we have enough room in shmem int iw = (int)ceil(bw / ratiox) + padding + 1, ih = (int)ceil(bh / ratioy) + padding + 1; int shmem_req = iw * ih * img.components * sizeof(float); if (shmem_req > p->ra->max_shmem) goto fallback; pass_is_compute(p, bw, bh); pass_compute_polar(p->sc, scaler, img.components, bw, bh, iw, ih); return; fallback: // Fall back to regular polar shader when compute shaders are unsupported // or the kernel is too big for shmem pass_sample_polar(p->sc, scaler, img.components, p->ra->caps & RA_CAP_GATHER); } // Sample from image, with the src rectangle given by it. // The dst rectangle is implicit by what the caller will do next, but w and h // must still be what is going to be used (to dimension FBOs correctly). // This will write the scaled contents to the vec4 "color". // The scaler unit is initialized by this function; in order to avoid cache // thrashing, the scaler unit should usually use the same parameters. static void pass_sample(struct gl_video *p, struct image img, struct scaler *scaler, const struct scaler_config *conf, double scale_factor, int w, int h) { reinit_scaler(p, scaler, conf, scale_factor, filter_sizes); // Describe scaler const char *scaler_opt[] = { [SCALER_SCALE] = "scale", [SCALER_DSCALE] = "dscale", [SCALER_CSCALE] = "cscale", [SCALER_TSCALE] = "tscale", }; pass_describe(p, "%s=%s (%s)", scaler_opt[scaler->index], scaler->conf.kernel.name, plane_names[img.type]); bool is_separated = scaler->kernel && !scaler->kernel->polar; // Set up the transformation+prelude and bind the texture, for everything // other than separated scaling (which does this in the subfunction) if (!is_separated) sampler_prelude(p->sc, pass_bind(p, img)); // Dispatch the scaler. They're all wildly different. const char *name = scaler->conf.kernel.name; if (strcmp(name, "bilinear") == 0) { GLSL(color = texture(tex, pos);) } else if (strcmp(name, "bicubic_fast") == 0) { pass_sample_bicubic_fast(p->sc); } else if (strcmp(name, "oversample") == 0) { pass_sample_oversample(p->sc, scaler, w, h); } else if (scaler->kernel && scaler->kernel->polar) { pass_dispatch_sample_polar(p, scaler, img, w, h); } else if (scaler->kernel) { pass_sample_separated(p, img, scaler, w, h); } else { // Should never happen abort(); } // Apply any required multipliers. Separated scaling already does this in // its first stage if (!is_separated) GLSLF("color *= %f;\n", img.multiplier); // Micro-optimization: Avoid scaling unneeded channels skip_unused(p, img.components); } // Returns true if two images are semantically equivalent (same metadata) static bool image_equiv(struct image a, struct image b) { return a.type == b.type && a.components == b.components && a.multiplier == b.multiplier && a.tex->params.format == b.tex->params.format && a.tex->params.w == b.tex->params.w && a.tex->params.h == b.tex->params.h && a.w == b.w && a.h == b.h && gl_transform_eq(a.transform, b.transform); } static void deband_hook(struct gl_video *p, struct image img, struct gl_transform *trans, void *priv) { pass_describe(p, "debanding (%s)", plane_names[img.type]); pass_sample_deband(p->sc, p->opts.deband_opts, &p->lfg, p->image_params.color.gamma); } static void unsharp_hook(struct gl_video *p, struct image img, struct gl_transform *trans, void *priv) { pass_describe(p, "unsharp masking"); pass_sample_unsharp(p->sc, p->opts.unsharp); } struct szexp_ctx { struct gl_video *p; struct image img; }; static bool szexp_lookup(void *priv, struct bstr var, float size[2]) { struct szexp_ctx *ctx = priv; struct gl_video *p = ctx->p; if (bstr_equals0(var, "NATIVE_CROPPED")) { size[0] = (p->src_rect.x1 - p->src_rect.x0) * p->texture_offset.m[0][0]; size[1] = (p->src_rect.y1 - p->src_rect.y0) * p->texture_offset.m[1][1]; return true; } // The size of OUTPUT is determined. It could be useful for certain // user shaders to skip passes. if (bstr_equals0(var, "OUTPUT")) { size[0] = p->dst_rect.x1 - p->dst_rect.x0; size[1] = p->dst_rect.y1 - p->dst_rect.y0; return true; } // HOOKED is a special case if (bstr_equals0(var, "HOOKED")) { size[0] = ctx->img.w; size[1] = ctx->img.h; return true; } for (int o = 0; o < p->num_saved_imgs; o++) { if (bstr_equals0(var, p->saved_imgs[o].name)) { size[0] = p->saved_imgs[o].img.w; size[1] = p->saved_imgs[o].img.h; return true; } } return false; } static bool user_hook_cond(struct gl_video *p, struct image img, void *priv) { struct gl_user_shader_hook *shader = priv; assert(shader); float res = false; struct szexp_ctx ctx = {p, img}; eval_szexpr(p->log, &ctx, szexp_lookup, shader->cond, &res); return res; } static void user_hook(struct gl_video *p, struct image img, struct gl_transform *trans, void *priv) { struct gl_user_shader_hook *shader = priv; assert(shader); load_shader(p, shader->pass_body); pass_describe(p, "user shader: %.*s (%s)", BSTR_P(shader->pass_desc), plane_names[img.type]); if (shader->compute.active) { p->pass_compute = shader->compute; GLSLF("hook();\n"); } else { GLSLF("color = hook();\n"); } // Make sure we at least create a legal FBO on failure, since it's better // to do this and display an error message than just crash OpenGL float w = 1.0, h = 1.0; eval_szexpr(p->log, &(struct szexp_ctx){p, img}, szexp_lookup, shader->width, &w); eval_szexpr(p->log, &(struct szexp_ctx){p, img}, szexp_lookup, shader->height, &h); *trans = (struct gl_transform){{{w / img.w, 0}, {0, h / img.h}}}; gl_transform_trans(shader->offset, trans); } static bool add_user_hook(void *priv, struct gl_user_shader_hook hook) { struct gl_video *p = priv; struct gl_user_shader_hook *copy = talloc_ptrtype(p, copy); *copy = hook; struct tex_hook texhook = { .save_tex = bstrdup0(copy, hook.save_tex), .components = hook.components, .hook = user_hook, .cond = user_hook_cond, .priv = copy, }; for (int h = 0; h < SHADER_MAX_HOOKS; h++) texhook.hook_tex[h] = bstrdup0(copy, hook.hook_tex[h]); for (int h = 0; h < SHADER_MAX_BINDS; h++) texhook.bind_tex[h] = bstrdup0(copy, hook.bind_tex[h]); MP_TARRAY_APPEND(p, p->tex_hooks, p->num_tex_hooks, texhook); return true; } static bool add_user_tex(void *priv, struct gl_user_shader_tex tex) { struct gl_video *p = priv; tex.tex = ra_tex_create(p->ra, &tex.params); TA_FREEP(&tex.params.initial_data); if (!tex.tex) return false; MP_TARRAY_APPEND(p, p->user_textures, p->num_user_textures, tex); return true; } static void load_user_shaders(struct gl_video *p, char **shaders) { if (!shaders) return; for (int n = 0; shaders[n] != NULL; n++) { struct bstr file = load_cached_file(p, shaders[n]); parse_user_shader(p->log, p->ra, file, p, add_user_hook, add_user_tex); } } static void gl_video_setup_hooks(struct gl_video *p) { gl_video_reset_hooks(p); if (p->opts.deband) { MP_TARRAY_APPEND(p, p->tex_hooks, p->num_tex_hooks, (struct tex_hook) { .hook_tex = {"LUMA", "CHROMA", "RGB", "XYZ"}, .bind_tex = {"HOOKED"}, .hook = deband_hook, }); } if (p->opts.unsharp != 0.0) { MP_TARRAY_APPEND(p, p->tex_hooks, p->num_tex_hooks, (struct tex_hook) { .hook_tex = {"MAIN"}, .bind_tex = {"HOOKED"}, .hook = unsharp_hook, }); } load_user_shaders(p, p->opts.user_shaders); } // sample from video textures, set "color" variable to yuv value static void pass_read_video(struct gl_video *p) { struct image img[4]; struct gl_transform offsets[4]; pass_get_images(p, &p->image, img, offsets); // To keep the code as simple as possibly, we currently run all shader // stages even if they would be unnecessary (e.g. no hooks for a texture). // In the future, deferred image should optimize this away. // Merge semantically identical textures. This loop is done from back // to front so that merged textures end up in the right order while // simultaneously allowing us to skip unnecessary merges for (int n = 3; n >= 0; n--) { if (img[n].type == PLANE_NONE) continue; int first = n; int num = 0; for (int i = 0; i < n; i++) { if (image_equiv(img[n], img[i]) && gl_transform_eq(offsets[n], offsets[i])) { GLSLF("// merging plane %d ...\n", i); copy_image(p, &num, img[i]); first = MPMIN(first, i); img[i] = (struct image){0}; } } if (num > 0) { GLSLF("// merging plane %d ... into %d\n", n, first); copy_image(p, &num, img[n]); pass_describe(p, "merging planes"); finish_pass_tex(p, &p->merge_tex[n], img[n].w, img[n].h); img[first] = image_wrap(p->merge_tex[n], img[n].type, num); img[n] = (struct image){0}; } } // If any textures are still in integer format by this point, we need // to introduce an explicit conversion pass to avoid breaking hooks/scaling for (int n = 0; n < 4; n++) { if (img[n].tex && img[n].tex->params.format->ctype == RA_CTYPE_UINT) { GLSLF("// use_integer fix for plane %d\n", n); copy_image(p, &(int){0}, img[n]); pass_describe(p, "use_integer fix"); finish_pass_tex(p, &p->integer_tex[n], img[n].w, img[n].h); img[n] = image_wrap(p->integer_tex[n], img[n].type, img[n].components); } } // Dispatch the hooks for all of these textures, saving and perhaps // modifying them in the process for (int n = 0; n < 4; n++) { const char *name; switch (img[n].type) { case PLANE_RGB: name = "RGB"; break; case PLANE_LUMA: name = "LUMA"; break; case PLANE_CHROMA: name = "CHROMA"; break; case PLANE_ALPHA: name = "ALPHA"; break; case PLANE_XYZ: name = "XYZ"; break; default: continue; } img[n] = pass_hook(p, name, img[n], &offsets[n]); } // At this point all planes are finalized but they may not be at the // required size yet. Furthermore, they may have texture offsets that // require realignment. For lack of something better to do, we assume // the rgb/luma texture is the "reference" and scale everything else // to match. for (int n = 0; n < 4; n++) { switch (img[n].type) { case PLANE_RGB: case PLANE_XYZ: case PLANE_LUMA: break; default: continue; } p->texture_w = img[n].w; p->texture_h = img[n].h; p->texture_offset = offsets[n]; break; } // Compute the reference rect struct mp_rect_f src = {0.0, 0.0, p->image_params.w, p->image_params.h}; struct mp_rect_f ref = src; gl_transform_rect(p->texture_offset, &ref); MP_DBG(p, "ref rect: {%f %f} {%f %f}\n", ref.x0, ref.y0, ref.x1, ref.y1); // Explicitly scale all of the textures that don't match for (int n = 0; n < 4; n++) { if (img[n].type == PLANE_NONE) continue; // If the planes are aligned identically, we will end up with the // exact same source rectangle. struct mp_rect_f rect = src; gl_transform_rect(offsets[n], &rect); MP_DBG(p, "rect[%d]: {%f %f} {%f %f}\n", n, rect.x0, rect.y0, rect.x1, rect.y1); if (mp_rect_f_seq(ref, rect)) continue; // If the rectangles differ, then our planes have a different // alignment and/or size. First of all, we have to compute the // corrections required to meet the target rectangle struct gl_transform fix = { .m = {{(ref.x1 - ref.x0) / (rect.x1 - rect.x0), 0.0}, {0.0, (ref.y1 - ref.y0) / (rect.y1 - rect.y0)}}, .t = {ref.x0, ref.y0}, }; MP_DBG(p, "-> fix[%d] = {%f %f} + off {%f %f}\n", n, fix.m[0][0], fix.m[1][1], fix.t[0], fix.t[1]); // Since the scale in texture space is different from the scale in // absolute terms, we have to scale the coefficients down to be // relative to the texture's physical dimensions and local offset struct gl_transform scale = { .m = {{(float)img[n].w / p->texture_w, 0.0}, {0.0, (float)img[n].h / p->texture_h}}, .t = {-rect.x0, -rect.y0}, }; if (p->image_params.rotate % 180 == 90) MPSWAP(double, scale.m[0][0], scale.m[1][1]); gl_transform_trans(scale, &fix); MP_DBG(p, "-> scaled[%d] = {%f %f} + off {%f %f}\n", n, fix.m[0][0], fix.m[1][1], fix.t[0], fix.t[1]); // Since the texture transform is a function of the texture coordinates // to texture space, rather than the other way around, we have to // actually apply the *inverse* of this. Fortunately, calculating // the inverse is relatively easy here. fix.m[0][0] = 1.0 / fix.m[0][0]; fix.m[1][1] = 1.0 / fix.m[1][1]; fix.t[0] = fix.m[0][0] * -fix.t[0]; fix.t[1] = fix.m[1][1] * -fix.t[1]; gl_transform_trans(fix, &img[n].transform); int scaler_id = -1; const char *name = NULL; switch (img[n].type) { case PLANE_RGB: case PLANE_LUMA: case PLANE_XYZ: scaler_id = SCALER_SCALE; // these aren't worth hooking, fringe hypothetical cases only break; case PLANE_CHROMA: scaler_id = SCALER_CSCALE; name = "CHROMA_SCALED"; break; case PLANE_ALPHA: // alpha always uses bilinear name = "ALPHA_SCALED"; } if (scaler_id < 0) continue; const struct scaler_config *conf = &p->opts.scaler[scaler_id]; struct scaler *scaler = &p->scaler[scaler_id]; // bilinear scaling is a free no-op thanks to GPU sampling if (strcmp(conf->kernel.name, "bilinear") != 0) { GLSLF("// upscaling plane %d\n", n); pass_sample(p, img[n], scaler, conf, 1.0, p->texture_w, p->texture_h); finish_pass_tex(p, &p->scale_tex[n], p->texture_w, p->texture_h); img[n] = image_wrap(p->scale_tex[n], img[n].type, img[n].components); } // Run any post-scaling hooks img[n] = pass_hook(p, name, img[n], NULL); } // All planes are of the same size and properly aligned at this point pass_describe(p, "combining planes"); int coord = 0; for (int i = 0; i < 4; i++) { if (img[i].type != PLANE_NONE) copy_image(p, &coord, img[i]); } p->components = coord; } // Utility function that simply binds a texture and reads from it, without any // transformations. static void pass_read_tex(struct gl_video *p, struct ra_tex *tex) { struct image img = image_wrap(tex, PLANE_RGB, p->components); copy_image(p, &(int){0}, img); } // yuv conversion, and any other conversions before main up/down-scaling static void pass_convert_yuv(struct gl_video *p) { struct gl_shader_cache *sc = p->sc; struct mp_csp_params cparams = MP_CSP_PARAMS_DEFAULTS; cparams.gray = p->is_gray; mp_csp_set_image_params(&cparams, &p->image_params); mp_csp_equalizer_state_get(p->video_eq, &cparams); p->user_gamma = 1.0 / (cparams.gamma * p->opts.gamma); pass_describe(p, "color conversion"); if (p->color_swizzle[0]) GLSLF("color = color.%s;\n", p->color_swizzle); // Pre-colormatrix input gamma correction if (cparams.color.space == MP_CSP_XYZ) GLSL(color.rgb = pow(color.rgb, vec3(2.6));) // linear light // We always explicitly normalize the range in pass_read_video cparams.input_bits = cparams.texture_bits = 0; // Conversion to RGB. For RGB itself, this still applies e.g. brightness // and contrast controls, or expansion of e.g. LSB-packed 10 bit data. struct mp_cmat m = {{{0}}}; mp_get_csp_matrix(&cparams, &m); gl_sc_uniform_mat3(sc, "colormatrix", true, &m.m[0][0]); gl_sc_uniform_vec3(sc, "colormatrix_c", m.c); GLSL(color.rgb = mat3(colormatrix) * color.rgb + colormatrix_c;) if (p->image_params.color.space == MP_CSP_BT_2020_C) { // Conversion for C'rcY'cC'bc via the BT.2020 CL system: // C'bc = (B'-Y'c) / 1.9404 | C'bc <= 0 // = (B'-Y'c) / 1.5816 | C'bc > 0 // // C'rc = (R'-Y'c) / 1.7184 | C'rc <= 0 // = (R'-Y'c) / 0.9936 | C'rc > 0 // // as per the BT.2020 specification, table 4. This is a non-linear // transformation because (constant) luminance receives non-equal // contributions from the three different channels. GLSLF("// constant luminance conversion\n"); GLSL(color.br = color.br * mix(vec2(1.5816, 0.9936), vec2(1.9404, 1.7184), lessThanEqual(color.br, vec2(0))) + color.gg;) // Expand channels to camera-linear light. This shader currently just // assumes everything uses the BT.2020 12-bit gamma function, since the // difference between 10 and 12-bit is negligible for anything other // than 12-bit content. GLSL(color.rgb = mix(color.rgb * vec3(1.0/4.5), pow((color.rgb + vec3(0.0993))*vec3(1.0/1.0993), vec3(1.0/0.45)), lessThanEqual(vec3(0.08145), color.rgb));) // Calculate the green channel from the expanded RYcB // The BT.2020 specification says Yc = 0.2627*R + 0.6780*G + 0.0593*B GLSL(color.g = (color.g - 0.2627*color.r - 0.0593*color.b)*1.0/0.6780;) // Recompress to receive the R'G'B' result, same as other systems GLSL(color.rgb = mix(color.rgb * vec3(4.5), vec3(1.0993) * pow(color.rgb, vec3(0.45)) - vec3(0.0993), lessThanEqual(vec3(0.0181), color.rgb));) } p->components = 3; if (!p->has_alpha || p->opts.alpha_mode == ALPHA_NO) { GLSL(color.a = 1.0;) } else { // alpha present in image p->components = 4; GLSL(color = vec4(color.rgb * color.a, color.a);) } } static void get_scale_factors(struct gl_video *p, bool transpose_rot, double xy[2]) { double target_w = p->src_rect.x1 - p->src_rect.x0; double target_h = p->src_rect.y1 - p->src_rect.y0; if (transpose_rot && p->image_params.rotate % 180 == 90) MPSWAP(double, target_w, target_h); xy[0] = (p->dst_rect.x1 - p->dst_rect.x0) / target_w; xy[1] = (p->dst_rect.y1 - p->dst_rect.y0) / target_h; } // Cropping. static void compute_src_transform(struct gl_video *p, struct gl_transform *tr) { float sx = (p->src_rect.x1 - p->src_rect.x0) / (float)p->texture_w, sy = (p->src_rect.y1 - p->src_rect.y0) / (float)p->texture_h, ox = p->src_rect.x0, oy = p->src_rect.y0; struct gl_transform transform = {{{sx, 0}, {0, sy}}, {ox, oy}}; gl_transform_trans(p->texture_offset, &transform); *tr = transform; } // Takes care of the main scaling and pre/post-conversions static void pass_scale_main(struct gl_video *p) { // Figure out the main scaler. double xy[2]; get_scale_factors(p, true, xy); // actual scale factor should be divided by the scale factor of prescaling. xy[0] /= p->texture_offset.m[0][0]; xy[1] /= p->texture_offset.m[1][1]; bool downscaling = xy[0] < 1.0 || xy[1] < 1.0; bool upscaling = !downscaling && (xy[0] > 1.0 || xy[1] > 1.0); double scale_factor = 1.0; struct scaler *scaler = &p->scaler[SCALER_SCALE]; struct scaler_config scaler_conf = p->opts.scaler[SCALER_SCALE]; if (p->opts.scaler_resizes_only && !downscaling && !upscaling) { scaler_conf.kernel.name = "bilinear"; // For scaler-resizes-only, we round the texture offset to // the nearest round value in order to prevent ugly blurriness // (in exchange for slightly shifting the image by up to half a // subpixel) p->texture_offset.t[0] = roundf(p->texture_offset.t[0]); p->texture_offset.t[1] = roundf(p->texture_offset.t[1]); } if (downscaling && p->opts.scaler[SCALER_DSCALE].kernel.name) { scaler_conf = p->opts.scaler[SCALER_DSCALE]; scaler = &p->scaler[SCALER_DSCALE]; } // When requesting correct-downscaling and the clip is anamorphic, and // because only a single scale factor is used for both axes, enable it only // when both axes are downscaled, and use the milder of the factors to not // end up with too much blur on one axis (even if we end up with sub-optimal // scale factor on the other axis). This is better than not respecting // correct scaling at all for anamorphic clips. double f = MPMAX(xy[0], xy[1]); if (p->opts.correct_downscaling && f < 1.0) scale_factor = 1.0 / f; // Pre-conversion, like linear light/sigmoidization GLSLF("// scaler pre-conversion\n"); bool use_linear = p->opts.linear_scaling || p->opts.sigmoid_upscaling; // Linear light downscaling results in nasty artifacts for HDR curves due // to the potentially extreme brightness differences severely compounding // any ringing. So just scale in gamma light instead. if (mp_trc_is_hdr(p->image_params.color.gamma) && downscaling) use_linear = false; if (use_linear) { p->use_linear = true; pass_linearize(p->sc, p->image_params.color.gamma); pass_opt_hook_point(p, "LINEAR", NULL); } bool use_sigmoid = use_linear && p->opts.sigmoid_upscaling && upscaling; float sig_center, sig_slope, sig_offset, sig_scale; if (use_sigmoid) { // Coefficients for the sigmoidal transform are taken from the // formula here: http://www.imagemagick.org/Usage/color_mods/#sigmoidal sig_center = p->opts.sigmoid_center; sig_slope = p->opts.sigmoid_slope; // This function needs to go through (0,0) and (1,1) so we compute the // values at 1 and 0, and then scale/shift them, respectively. sig_offset = 1.0/(1+expf(sig_slope * sig_center)); sig_scale = 1.0/(1+expf(sig_slope * (sig_center-1))) - sig_offset; GLSLF("color.rgb = %f - log(1.0/(color.rgb * %f + %f) - 1.0) * 1.0/%f;\n", sig_center, sig_scale, sig_offset, sig_slope); pass_opt_hook_point(p, "SIGMOID", NULL); } pass_opt_hook_point(p, "PREKERNEL", NULL); int vp_w = p->dst_rect.x1 - p->dst_rect.x0; int vp_h = p->dst_rect.y1 - p->dst_rect.y0; struct gl_transform transform; compute_src_transform(p, &transform); GLSLF("// main scaling\n"); finish_pass_tex(p, &p->indirect_tex, p->texture_w, p->texture_h); struct image src = image_wrap(p->indirect_tex, PLANE_RGB, p->components); gl_transform_trans(transform, &src.transform); pass_sample(p, src, scaler, &scaler_conf, scale_factor, vp_w, vp_h); // Changes the texture size to display size after main scaler. p->texture_w = vp_w; p->texture_h = vp_h; pass_opt_hook_point(p, "POSTKERNEL", NULL); GLSLF("// scaler post-conversion\n"); if (use_sigmoid) { // Inverse of the transformation above GLSLF("color.rgb = (1.0/(1.0 + exp(%f * (%f - color.rgb))) - %f) * 1.0/%f;\n", sig_slope, sig_center, sig_offset, sig_scale); } } // Adapts the colors to the right output color space. (Final pass during // rendering) // If OSD is true, ignore any changes that may have been made to the video // by previous passes (i.e. linear scaling) static void pass_colormanage(struct gl_video *p, struct mp_colorspace src, bool osd) { struct ra *ra = p->ra; // Figure out the target color space from the options, or auto-guess if // none were set struct mp_colorspace dst = { .gamma = p->opts.target_trc, .primaries = p->opts.target_prim, .light = MP_CSP_LIGHT_DISPLAY, }; if (p->use_lut_3d) { // The 3DLUT is always generated against the video's original source // space, *not* the reference space. (To avoid having to regenerate // the 3DLUT for the OSD on every frame) enum mp_csp_prim prim_orig = p->image_params.color.primaries; enum mp_csp_trc trc_orig = p->image_params.color.gamma; // One exception: HDR is not implemented by LittleCMS for technical // limitation reasons, so we use a gamma 2.2 input curve here instead. // We could pick any value we want here, the difference is just coding // efficiency. if (mp_trc_is_hdr(trc_orig)) trc_orig = MP_CSP_TRC_GAMMA22; if (gl_video_get_lut3d(p, prim_orig, trc_orig)) { dst.primaries = prim_orig; dst.gamma = trc_orig; } } if (dst.primaries == MP_CSP_PRIM_AUTO) { // The vast majority of people are on sRGB or BT.709 displays, so pick // this as the default output color space. dst.primaries = MP_CSP_PRIM_BT_709; if (src.primaries == MP_CSP_PRIM_BT_601_525 || src.primaries == MP_CSP_PRIM_BT_601_625) { // Since we auto-pick BT.601 and BT.709 based on the dimensions, // combined with the fact that they're very similar to begin with, // and to avoid confusing the average user, just don't adapt BT.601 // content automatically at all. dst.primaries = src.primaries; } } if (dst.gamma == MP_CSP_TRC_AUTO) { // Most people seem to complain when the image is darker or brighter // than what they're "used to", so just avoid changing the gamma // altogether by default. The only exceptions to this rule apply to // very unusual TRCs, which even hardcode technoluddites would probably // not enjoy viewing unaltered. dst.gamma = src.gamma; // Avoid outputting linear light or HDR content "by default". For these // just pick gamma 2.2 as a default, since it's a good estimate for // the response of typical displays if (dst.gamma == MP_CSP_TRC_LINEAR || mp_trc_is_hdr(dst.gamma)) dst.gamma = MP_CSP_TRC_GAMMA22; } bool detect_peak = p->opts.compute_hdr_peak && mp_trc_is_hdr(src.gamma); if (detect_peak && !p->hdr_peak_ssbo) { struct { unsigned int sig_peak_raw; unsigned int index; unsigned int frame_max[PEAK_DETECT_FRAMES+1]; } peak_ssbo = {0}; // Prefill with safe values int safe = MP_REF_WHITE * mp_trc_nom_peak(p->image_params.color.gamma); peak_ssbo.sig_peak_raw = PEAK_DETECT_FRAMES * safe; for (int i = 0; i < PEAK_DETECT_FRAMES+1; i++) peak_ssbo.frame_max[i] = safe; struct ra_buf_params params = { .type = RA_BUF_TYPE_SHADER_STORAGE, .size = sizeof(peak_ssbo), .initial_data = &peak_ssbo, }; p->hdr_peak_ssbo = ra_buf_create(ra, ¶ms); if (!p->hdr_peak_ssbo) { MP_WARN(p, "Failed to create HDR peak detection SSBO, disabling.\n"); detect_peak = (p->opts.compute_hdr_peak = false); } } if (detect_peak) { pass_describe(p, "detect HDR peak"); pass_is_compute(p, 8, 8); // 8x8 is good for performance gl_sc_ssbo(p->sc, "PeakDetect", p->hdr_peak_ssbo, "uint sig_peak_raw;" "uint index;" "uint frame_max[%d];", PEAK_DETECT_FRAMES + 1 ); } // Adapt from src to dst as necessary pass_color_map(p->sc, src, dst, p->opts.tone_mapping, p->opts.tone_mapping_param, p->opts.tone_mapping_desat, detect_peak, p->opts.gamut_warning, p->use_linear && !osd); if (p->use_lut_3d) { gl_sc_uniform_texture(p->sc, "lut_3d", p->lut_3d_texture); GLSL(vec3 cpos;) for (int i = 0; i < 3; i++) GLSLF("cpos[%d] = LUT_POS(color[%d], %d.0);\n", i, i, p->lut_3d_size[i]); GLSL(color.rgb = tex3D(lut_3d, cpos).rgb;) } } void gl_video_set_fb_depth(struct gl_video *p, int fb_depth) { p->fb_depth = fb_depth; } static void pass_dither(struct gl_video *p) { // Assume 8 bits per component if unknown. int dst_depth = p->fb_depth > 0 ? p->fb_depth : 8; if (p->opts.dither_depth > 0) dst_depth = p->opts.dither_depth; if (p->opts.dither_depth < 0 || p->opts.dither_algo == DITHER_NONE) return; if (!p->dither_texture) { MP_VERBOSE(p, "Dither to %d.\n", dst_depth); int tex_size = 0; void *tex_data = NULL; const struct ra_format *fmt = NULL; void *temp = NULL; if (p->opts.dither_algo == DITHER_FRUIT) { int sizeb = p->opts.dither_size; int size = 1 << sizeb; if (p->last_dither_matrix_size != size) { p->last_dither_matrix = talloc_realloc(p, p->last_dither_matrix, float, size * size); mp_make_fruit_dither_matrix(p->last_dither_matrix, sizeb); p->last_dither_matrix_size = size; } // Prefer R16 texture since they provide higher precision. fmt = ra_find_unorm_format(p->ra, 2, 1); if (!fmt) fmt = ra_find_float16_format(p->ra, 1); if (fmt) { tex_size = size; tex_data = p->last_dither_matrix; if (fmt->ctype == RA_CTYPE_UNORM) { uint16_t *t = temp = talloc_array(NULL, uint16_t, size * size); for (int n = 0; n < size * size; n++) t[n] = p->last_dither_matrix[n] * UINT16_MAX; tex_data = t; } } else { MP_VERBOSE(p, "GL too old. Falling back to ordered dither.\n"); p->opts.dither_algo = DITHER_ORDERED; } } if (p->opts.dither_algo == DITHER_ORDERED) { temp = talloc_array(NULL, char, 8 * 8); mp_make_ordered_dither_matrix(temp, 8); fmt = ra_find_unorm_format(p->ra, 1, 1); tex_size = 8; tex_data = temp; } struct ra_tex_params params = { .dimensions = 2, .w = tex_size, .h = tex_size, .d = 1, .format = fmt, .render_src = true, .src_repeat = true, .initial_data = tex_data, }; p->dither_texture = ra_tex_create(p->ra, ¶ms); debug_check_gl(p, "dither setup"); talloc_free(temp); } GLSLF("// dithering\n"); // This defines how many bits are considered significant for output on // screen. The superfluous bits will be used for rounding according to the // dither matrix. The precision of the source implicitly decides how many // dither patterns can be visible. int dither_quantization = (1 << dst_depth) - 1; int dither_size = p->dither_texture->params.w; gl_sc_uniform_texture(p->sc, "dither", p->dither_texture); GLSLF("vec2 dither_pos = gl_FragCoord.xy * 1.0/%d.0;\n", dither_size); if (p->opts.temporal_dither) { int phase = (p->frames_rendered / p->opts.temporal_dither_period) % 8u; float r = phase * (M_PI / 2); // rotate float m = phase < 4 ? 1 : -1; // mirror float matrix[2][2] = {{cos(r), -sin(r) }, {sin(r) * m, cos(r) * m}}; gl_sc_uniform_dynamic(p->sc); gl_sc_uniform_mat2(p->sc, "dither_trafo", true, &matrix[0][0]); GLSL(dither_pos = dither_trafo * dither_pos;) } GLSL(float dither_value = texture(dither, dither_pos).r;) GLSLF("color = floor(color * %d.0 + dither_value + 0.5 / %d.0) * 1.0/%d.0;\n", dither_quantization, dither_size * dither_size, dither_quantization); } // Draws the OSD, in scene-referred colors.. If cms is true, subtitles are // instead adapted to the display's gamut. static void pass_draw_osd(struct gl_video *p, int draw_flags, double pts, struct mp_osd_res rect, struct ra_fbo fbo, bool cms) { mpgl_osd_generate(p->osd, rect, pts, p->image_params.stereo_out, draw_flags); timer_pool_start(p->osd_timer); for (int n = 0; n < MAX_OSD_PARTS; n++) { // (This returns false if this part is empty with nothing to draw.) if (!mpgl_osd_draw_prepare(p->osd, n, p->sc)) continue; // When subtitles need to be color managed, assume they're in sRGB // (for lack of anything saner to do) if (cms) { static const struct mp_colorspace csp_srgb = { .primaries = MP_CSP_PRIM_BT_709, .gamma = MP_CSP_TRC_SRGB, .light = MP_CSP_LIGHT_DISPLAY, }; pass_colormanage(p, csp_srgb, true); } mpgl_osd_draw_finish(p->osd, n, p->sc, fbo); } timer_pool_stop(p->osd_timer); pass_describe(p, "drawing osd"); pass_record(p, timer_pool_measure(p->osd_timer)); } static float chroma_realign(int size, int pixel) { return size / (float)chroma_upsize(size, pixel); } // Minimal rendering code path, for GLES or OpenGL 2.1 without proper FBOs. static void pass_render_frame_dumb(struct gl_video *p) { struct image img[4]; struct gl_transform off[4]; pass_get_images(p, &p->image, img, off); struct gl_transform transform; compute_src_transform(p, &transform); int index = 0; for (int i = 0; i < p->plane_count; i++) { int cw = img[i].type == PLANE_CHROMA ? p->ra_format.chroma_w : 1; int ch = img[i].type == PLANE_CHROMA ? p->ra_format.chroma_h : 1; if (p->image_params.rotate % 180 == 90) MPSWAP(int, cw, ch); struct gl_transform t = transform; t.m[0][0] *= chroma_realign(p->texture_w, cw); t.m[1][1] *= chroma_realign(p->texture_h, ch); t.t[0] /= cw; t.t[1] /= ch; t.t[0] += off[i].t[0]; t.t[1] += off[i].t[1]; gl_transform_trans(img[i].transform, &t); img[i].transform = t; copy_image(p, &index, img[i]); } pass_convert_yuv(p); } // The main rendering function, takes care of everything up to and including // upscaling. p->image is rendered. static bool pass_render_frame(struct gl_video *p, struct mp_image *mpi, uint64_t id) { // initialize the texture parameters and temporary variables p->texture_w = p->image_params.w; p->texture_h = p->image_params.h; p->texture_offset = identity_trans; p->components = 0; p->num_saved_imgs = 0; p->idx_hook_textures = 0; p->use_linear = false; // try uploading the frame if (!pass_upload_image(p, mpi, id)) return false; if (p->image_params.rotate % 180 == 90) MPSWAP(int, p->texture_w, p->texture_h); if (p->dumb_mode) return true; pass_read_video(p); pass_opt_hook_point(p, "NATIVE", &p->texture_offset); pass_convert_yuv(p); pass_opt_hook_point(p, "MAINPRESUB", &p->texture_offset); // For subtitles double vpts = p->image.mpi->pts; if (vpts == MP_NOPTS_VALUE) vpts = p->osd_pts; if (p->osd && p->opts.blend_subs == BLEND_SUBS_VIDEO) { double scale[2]; get_scale_factors(p, false, scale); struct mp_osd_res rect = { .w = p->texture_w, .h = p->texture_h, .display_par = scale[1] / scale[0], // counter compensate scaling }; finish_pass_tex(p, &p->blend_subs_tex, rect.w, rect.h); struct ra_fbo fbo = { p->blend_subs_tex }; pass_draw_osd(p, OSD_DRAW_SUB_ONLY, vpts, rect, fbo, false); pass_read_tex(p, p->blend_subs_tex); pass_describe(p, "blend subs video"); } pass_opt_hook_point(p, "MAIN", &p->texture_offset); pass_scale_main(p); int vp_w = p->dst_rect.x1 - p->dst_rect.x0, vp_h = p->dst_rect.y1 - p->dst_rect.y0; if (p->osd && p->opts.blend_subs == BLEND_SUBS_YES) { // Recreate the real video size from the src/dst rects struct mp_osd_res rect = { .w = vp_w, .h = vp_h, .ml = -p->src_rect.x0, .mr = p->src_rect.x1 - p->image_params.w, .mt = -p->src_rect.y0, .mb = p->src_rect.y1 - p->image_params.h, .display_par = 1.0, }; // Adjust margins for scale double scale[2]; get_scale_factors(p, true, scale); rect.ml *= scale[0]; rect.mr *= scale[0]; rect.mt *= scale[1]; rect.mb *= scale[1]; // We should always blend subtitles in non-linear light if (p->use_linear) { pass_delinearize(p->sc, p->image_params.color.gamma); p->use_linear = false; } finish_pass_tex(p, &p->blend_subs_tex, p->texture_w, p->texture_h); struct ra_fbo fbo = { p->blend_subs_tex }; pass_draw_osd(p, OSD_DRAW_SUB_ONLY, vpts, rect, fbo, false); pass_read_tex(p, p->blend_subs_tex); pass_describe(p, "blend subs"); } pass_opt_hook_point(p, "SCALED", NULL); return true; } static void pass_draw_to_screen(struct gl_video *p, struct ra_fbo fbo) { if (p->dumb_mode) pass_render_frame_dumb(p); // Adjust the overall gamma before drawing to screen if (p->user_gamma != 1) { gl_sc_uniform_f(p->sc, "user_gamma", p->user_gamma); GLSL(color.rgb = clamp(color.rgb, 0.0, 1.0);) GLSL(color.rgb = pow(color.rgb, vec3(user_gamma));) } pass_colormanage(p, p->image_params.color, false); // Since finish_pass_fbo doesn't work with compute shaders, and neither // does the checkerboard/dither code, we may need an indirection via // p->screen_tex here. if (p->pass_compute.active) { int o_w = p->dst_rect.x1 - p->dst_rect.x0, o_h = p->dst_rect.y1 - p->dst_rect.y0; finish_pass_tex(p, &p->screen_tex, o_w, o_h); struct image tmp = image_wrap(p->screen_tex, PLANE_RGB, p->components); copy_image(p, &(int){0}, tmp); } if (p->has_alpha){ if (p->opts.alpha_mode == ALPHA_BLEND_TILES) { // Draw checkerboard pattern to indicate transparency GLSLF("// transparency checkerboard\n"); GLSL(bvec2 tile = lessThan(fract(gl_FragCoord.xy * 1.0/32.0), vec2(0.5));) GLSL(vec3 background = vec3(tile.x == tile.y ? 0.93 : 0.87);) GLSL(color.rgb += background.rgb * (1.0 - color.a);) GLSL(color.a = 1.0;) } else if (p->opts.alpha_mode == ALPHA_BLEND) { // Blend into background color (usually black) struct m_color c = p->opts.background; GLSLF("vec4 background = vec4(%f, %f, %f, %f);\n", c.r / 255.0, c.g / 255.0, c.b / 255.0, c.a / 255.0); GLSL(color.rgb += background.rgb * (1.0 - color.a);) GLSL(color.a = background.a;) } } pass_opt_hook_point(p, "OUTPUT", NULL); pass_dither(p); pass_describe(p, "output to screen"); finish_pass_fbo(p, fbo, &p->dst_rect); } static bool update_surface(struct gl_video *p, struct mp_image *mpi, uint64_t id, struct surface *surf) { int vp_w = p->dst_rect.x1 - p->dst_rect.x0, vp_h = p->dst_rect.y1 - p->dst_rect.y0; pass_info_reset(p, false); if (!pass_render_frame(p, mpi, id)) return false; // Frame blending should always be done in linear light to preserve the // overall brightness, otherwise this will result in flashing dark frames // because mixing in compressed light artificially darkens the results if (!p->use_linear) { p->use_linear = true; pass_linearize(p->sc, p->image_params.color.gamma); } finish_pass_tex(p, &surf->tex, vp_w, vp_h); surf->id = id; surf->pts = mpi->pts; return true; } // Draws an interpolate frame to fbo, based on the frame timing in t static void gl_video_interpolate_frame(struct gl_video *p, struct vo_frame *t, struct ra_fbo fbo) { bool is_new = false; // Reset the queue completely if this is a still image, to avoid any // interpolation artifacts from surrounding frames when unpausing or // framestepping if (t->still) gl_video_reset_surfaces(p); // First of all, figure out if we have a frame available at all, and draw // it manually + reset the queue if not if (p->surfaces[p->surface_now].id == 0) { struct surface *now = &p->surfaces[p->surface_now]; if (!update_surface(p, t->current, t->frame_id, now)) return; p->surface_idx = p->surface_now; is_new = true; } // Find the right frame for this instant if (t->current) { int next = surface_wrap(p->surface_now + 1); while (p->surfaces[next].id && p->surfaces[next].id > p->surfaces[p->surface_now].id && p->surfaces[p->surface_now].id < t->frame_id) { p->surface_now = next; next = surface_wrap(next + 1); } } // Figure out the queue size. For illustration, a filter radius of 2 would // look like this: _ A [B] C D _ // A is surface_bse, B is surface_now, C is surface_now+1 and D is // surface_end. struct scaler *tscale = &p->scaler[SCALER_TSCALE]; reinit_scaler(p, tscale, &p->opts.scaler[SCALER_TSCALE], 1, tscale_sizes); bool oversample = strcmp(tscale->conf.kernel.name, "oversample") == 0; bool linear = strcmp(tscale->conf.kernel.name, "linear") == 0; int size; if (oversample || linear) { size = 2; } else { assert(tscale->kernel && !tscale->kernel->polar); size = ceil(tscale->kernel->size); } int radius = size/2; int surface_now = p->surface_now; int surface_bse = surface_wrap(surface_now - (radius-1)); int surface_end = surface_wrap(surface_now + radius); assert(surface_wrap(surface_bse + size-1) == surface_end); // Render new frames while there's room in the queue. Note that technically, // this should be done before the step where we find the right frame, but // it only barely matters at the very beginning of playback, and this way // makes the code much more linear. int surface_dst = surface_wrap(p->surface_idx + 1); for (int i = 0; i < t->num_frames; i++) { // Avoid overwriting data we might still need if (surface_dst == surface_bse - 1) break; struct mp_image *f = t->frames[i]; uint64_t f_id = t->frame_id + i; if (!mp_image_params_equal(&f->params, &p->real_image_params)) continue; if (f_id > p->surfaces[p->surface_idx].id) { struct surface *dst = &p->surfaces[surface_dst]; if (!update_surface(p, f, f_id, dst)) return; p->surface_idx = surface_dst; surface_dst = surface_wrap(surface_dst + 1); is_new = true; } } // Figure out whether the queue is "valid". A queue is invalid if the // frames' PTS is not monotonically increasing. Anything else is invalid, // so avoid blending incorrect data and just draw the latest frame as-is. // Possible causes for failure of this condition include seeks, pausing, // end of playback or start of playback. bool valid = true; for (int i = surface_bse, ii; valid && i != surface_end; i = ii) { ii = surface_wrap(i + 1); if (p->surfaces[i].id == 0 || p->surfaces[ii].id == 0) { valid = false; } else if (p->surfaces[ii].id < p->surfaces[i].id) { valid = false; MP_DBG(p, "interpolation queue underrun\n"); } } // Update OSD PTS to synchronize subtitles with the displayed frame p->osd_pts = p->surfaces[surface_now].pts; // Finally, draw the right mix of frames to the screen. if (!is_new) pass_info_reset(p, true); pass_describe(p, "interpolation"); if (!valid || t->still) { // surface_now is guaranteed to be valid, so we can safely use it. pass_read_tex(p, p->surfaces[surface_now].tex); p->is_interpolated = false; } else { double mix = t->vsync_offset / t->ideal_frame_duration; // The scaler code always wants the fcoord to be between 0 and 1, // so we try to adjust by using the previous set of N frames instead // (which requires some extra checking to make sure it's valid) if (mix < 0.0) { int prev = surface_wrap(surface_bse - 1); if (p->surfaces[prev].id != 0 && p->surfaces[prev].id < p->surfaces[surface_bse].id) { mix += 1.0; surface_bse = prev; } else { mix = 0.0; // at least don't blow up, this should only // ever happen at the start of playback } } if (oversample) { // Oversample uses the frame area as mix ratio, not the the vsync // position itself double vsync_dist = t->vsync_interval / t->ideal_frame_duration, threshold = tscale->conf.kernel.params[0]; threshold = isnan(threshold) ? 0.0 : threshold; mix = (1 - mix) / vsync_dist; mix = mix <= 0 + threshold ? 0 : mix; mix = mix >= 1 - threshold ? 1 : mix; mix = 1 - mix; } // Blend the frames together if (oversample || linear) { gl_sc_uniform_dynamic(p->sc); gl_sc_uniform_f(p->sc, "inter_coeff", mix); GLSL(color = mix(texture(texture0, texcoord0), texture(texture1, texcoord1), inter_coeff);) } else { gl_sc_uniform_dynamic(p->sc); gl_sc_uniform_f(p->sc, "fcoord", mix); pass_sample_separated_gen(p->sc, tscale, 0, 0); } // Load all the required frames for (int i = 0; i < size; i++) { struct image img = image_wrap(p->surfaces[surface_wrap(surface_bse+i)].tex, PLANE_RGB, p->components); // Since the code in pass_sample_separated currently assumes // the textures are bound in-order and starting at 0, we just // assert to make sure this is the case (which it should always be) int id = pass_bind(p, img); assert(id == i); } MP_DBG(p, "inter frame dur: %f vsync: %f, mix: %f\n", t->ideal_frame_duration, t->vsync_interval, mix); p->is_interpolated = true; } pass_draw_to_screen(p, fbo); p->frames_drawn += 1; } void gl_video_render_frame(struct gl_video *p, struct vo_frame *frame, struct ra_fbo fbo) { gl_video_update_options(p); struct mp_rect target_rc = {0, 0, fbo.tex->params.w, fbo.tex->params.h}; p->broken_frame = false; bool has_frame = !!frame->current; if (!has_frame || !mp_rect_equals(&p->dst_rect, &target_rc)) { struct m_color c = p->clear_color; float color[4] = {c.r / 255.0, c.g / 255.0, c.b / 255.0, c.a / 255.0}; p->ra->fns->clear(p->ra, fbo.tex, color, &target_rc); } if (p->hwdec_active && p->hwdec->driver->overlay_frame) { if (has_frame) { float *color = p->hwdec->overlay_colorkey; p->ra->fns->clear(p->ra, fbo.tex, color, &p->dst_rect); } p->hwdec->driver->overlay_frame(p->hwdec, frame->current, &p->src_rect, &p->dst_rect, frame->frame_id != p->image.id); if (frame->current) p->osd_pts = frame->current->pts; // Disable GL rendering has_frame = false; } if (has_frame) { bool interpolate = p->opts.interpolation && frame->display_synced && (p->frames_drawn || !frame->still); if (interpolate) { double ratio = frame->ideal_frame_duration / frame->vsync_interval; if (fabs(ratio - 1.0) < p->opts.interpolation_threshold) interpolate = false; } if (interpolate) { gl_video_interpolate_frame(p, frame, fbo); } else { bool is_new = frame->frame_id != p->image.id; // Redrawing a frame might update subtitles. if (frame->still && p->opts.blend_subs) is_new = true; if (is_new || !p->output_tex_valid) { p->output_tex_valid = false; pass_info_reset(p, !is_new); if (!pass_render_frame(p, frame->current, frame->frame_id)) goto done; // For the non-interpolation case, we draw to a single "cache" // texture to speed up subsequent re-draws (if any exist) struct ra_fbo dest_fbo = fbo; if (frame->num_vsyncs > 1 && frame->display_synced && !p->dumb_mode && (p->ra->caps & RA_CAP_BLIT)) { bool r = ra_tex_resize(p->ra, p->log, &p->output_tex, fbo.tex->params.w, fbo.tex->params.h, p->fbo_format); if (r) { dest_fbo = (struct ra_fbo) { p->output_tex }; p->output_tex_valid = true; } } pass_draw_to_screen(p, dest_fbo); } // "output tex valid" and "output tex needed" are equivalent if (p->output_tex_valid) { pass_info_reset(p, true); pass_describe(p, "redraw cached frame"); struct mp_rect src = p->dst_rect; struct mp_rect dst = src; if (fbo.flip) { dst.y0 = fbo.tex->params.h - src.y0; dst.y1 = fbo.tex->params.h - src.y1; } timer_pool_start(p->blit_timer); p->ra->fns->blit(p->ra, fbo.tex, p->output_tex, &dst, &src); timer_pool_stop(p->blit_timer); pass_record(p, timer_pool_measure(p->blit_timer)); } } } done: debug_check_gl(p, "after video rendering"); if (p->osd) { // If we haven't actually drawn anything so far, then we technically // need to consider this the start of a new pass. Let's call it a // redraw just because, since it's basically a blank frame anyway if (!has_frame) pass_info_reset(p, true); pass_draw_osd(p, p->opts.blend_subs ? OSD_DRAW_OSD_ONLY : 0, p->osd_pts, p->osd_rect, fbo, true); debug_check_gl(p, "after OSD rendering"); } if (gl_sc_error_state(p->sc) || p->broken_frame) { // Make the screen solid blue to make it visually clear that an // error has occurred float color[4] = {0.0, 0.05, 0.5, 1.0}; p->ra->fns->clear(p->ra, fbo.tex, color, &target_rc); } p->frames_rendered++; pass_report_performance(p); } // Use this color instead of the global option. void gl_video_set_clear_color(struct gl_video *p, struct m_color c) { p->force_clear_color = true; p->clear_color = c; } void gl_video_set_osd_pts(struct gl_video *p, double pts) { p->osd_pts = pts; } bool gl_video_check_osd_change(struct gl_video *p, struct mp_osd_res *res, double pts) { return p->osd ? mpgl_osd_check_change(p->osd, res, pts) : false; } void gl_video_resize(struct gl_video *p, struct mp_rect *src, struct mp_rect *dst, struct mp_osd_res *osd) { if (mp_rect_equals(&p->src_rect, src) && mp_rect_equals(&p->dst_rect, dst) && osd_res_equals(p->osd_rect, *osd)) return; p->src_rect = *src; p->dst_rect = *dst; p->osd_rect = *osd; gl_video_reset_surfaces(p); if (p->osd) mpgl_osd_resize(p->osd, p->osd_rect, p->image_params.stereo_out); } static void frame_perf_data(struct pass_info pass[], struct mp_frame_perf *out) { for (int i = 0; i < VO_PASS_PERF_MAX; i++) { if (!pass[i].desc.len) break; out->perf[out->count] = pass[i].perf; out->desc[out->count] = pass[i].desc.start; out->count++; } } void gl_video_perfdata(struct gl_video *p, struct voctrl_performance_data *out) { *out = (struct voctrl_performance_data){0}; frame_perf_data(p->pass_fresh, &out->fresh); frame_perf_data(p->pass_redraw, &out->redraw); } // This assumes nv12, with textures set to GL_NEAREST filtering. static void reinterleave_vdpau(struct gl_video *p, struct ra_tex *input[4], struct ra_tex *output[2]) { for (int n = 0; n < 2; n++) { struct ra_tex **tex = &p->vdpau_deinterleave_tex[n]; // This is an array of the 2 to-merge planes. struct ra_tex **src = &input[n * 2]; int w = src[0]->params.w; int h = src[0]->params.h; int ids[2]; for (int t = 0; t < 2; t++) { ids[t] = pass_bind(p, (struct image){ .tex = src[t], .multiplier = 1.0, .transform = identity_trans, .w = w, .h = h, }); } pass_describe(p, "vdpau reinterleaving"); GLSLF("color = fract(gl_FragCoord.y * 0.5) < 0.5\n"); GLSLF(" ? texture(texture%d, texcoord%d)\n", ids[0], ids[0]); GLSLF(" : texture(texture%d, texcoord%d);", ids[1], ids[1]); int comps = n == 0 ? 1 : 2; const struct ra_format *fmt = ra_find_unorm_format(p->ra, 1, comps); ra_tex_resize(p->ra, p->log, tex, w, h * 2, fmt); struct ra_fbo fbo = { *tex }; finish_pass_fbo(p, fbo, &(struct mp_rect){0, 0, w, h * 2}); output[n] = *tex; } } // Returns false on failure. static bool pass_upload_image(struct gl_video *p, struct mp_image *mpi, uint64_t id) { struct video_image *vimg = &p->image; if (vimg->id == id) return true; unref_current_image(p); mpi = mp_image_new_ref(mpi); if (!mpi) goto error; vimg->mpi = mpi; vimg->id = id; p->osd_pts = mpi->pts; p->frames_uploaded++; if (p->hwdec_active) { // Hardware decoding if (!p->hwdec_mapper) goto error; pass_describe(p, "map frame (hwdec)"); timer_pool_start(p->upload_timer); bool ok = ra_hwdec_mapper_map(p->hwdec_mapper, vimg->mpi) >= 0; timer_pool_stop(p->upload_timer); pass_record(p, timer_pool_measure(p->upload_timer)); vimg->hwdec_mapped = true; if (ok) { struct mp_image layout = {0}; mp_image_set_params(&layout, &p->image_params); struct ra_tex **tex = p->hwdec_mapper->tex; struct ra_tex *tmp[4] = {0}; if (p->hwdec_mapper->vdpau_fields) { reinterleave_vdpau(p, tex, tmp); tex = tmp; } for (int n = 0; n < p->plane_count; n++) { vimg->planes[n] = (struct texplane){ .w = mp_image_plane_w(&layout, n), .h = mp_image_plane_h(&layout, n), .tex = tex[n], }; } } else { MP_FATAL(p, "Mapping hardware decoded surface failed.\n"); goto error; } return true; } // Software decoding assert(mpi->num_planes == p->plane_count); timer_pool_start(p->upload_timer); for (int n = 0; n < p->plane_count; n++) { struct texplane *plane = &vimg->planes[n]; plane->flipped = mpi->stride[0] < 0; struct ra_tex_upload_params params = { .tex = plane->tex, .src = mpi->planes[n], .invalidate = true, .stride = mpi->stride[n], }; struct dr_buffer *mapped = gl_find_dr_buffer(p, mpi->planes[n]); if (mapped) { params.buf = mapped->buf; params.buf_offset = (uintptr_t)params.src - (uintptr_t)mapped->buf->data; params.src = NULL; } if (p->using_dr_path != !!mapped) { p->using_dr_path = !!mapped; MP_VERBOSE(p, "DR enabled: %s\n", p->using_dr_path ? "yes" : "no"); } if (!p->ra->fns->tex_upload(p->ra, ¶ms)) { timer_pool_stop(p->upload_timer); goto error; } if (mapped && !mapped->mpi) mapped->mpi = mp_image_new_ref(mpi); } timer_pool_stop(p->upload_timer); bool using_pbo = p->ra->use_pbo || !(p->ra->caps & RA_CAP_DIRECT_UPLOAD); const char *mode = p->using_dr_path ? "DR" : using_pbo ? "PBO" : "naive"; pass_describe(p, "upload frame (%s)", mode); pass_record(p, timer_pool_measure(p->upload_timer)); return true; error: unref_current_image(p); p->broken_frame = true; return false; } static bool test_fbo(struct gl_video *p, const struct ra_format *fmt) { MP_VERBOSE(p, "Testing FBO format %s\n", fmt->name); struct ra_tex *tex = NULL; bool success = ra_tex_resize(p->ra, p->log, &tex, 16, 16, fmt); ra_tex_free(p->ra, &tex); return success; } // Return whether dumb-mode can be used without disabling any features. // Essentially, vo_opengl with mostly default settings will return true. static bool check_dumb_mode(struct gl_video *p) { struct gl_video_opts *o = &p->opts; if (p->use_integer_conversion) return false; if (o->dumb_mode > 0) // requested by user return true; if (o->dumb_mode < 0) // disabled by user return false; // otherwise, use auto-detection if (o->target_prim || o->target_trc || o->linear_scaling || o->correct_downscaling || o->sigmoid_upscaling || o->interpolation || o->blend_subs || o->deband || o->unsharp) return false; // check remaining scalers (tscale is already implicitly excluded above) for (int i = 0; i < SCALER_COUNT; i++) { if (i != SCALER_TSCALE) { const char *name = o->scaler[i].kernel.name; if (name && strcmp(name, "bilinear") != 0) return false; } } if (o->user_shaders && o->user_shaders[0]) return false; if (p->use_lut_3d) return false; return true; } // Disable features that are not supported with the current OpenGL version. static void check_gl_features(struct gl_video *p) { struct ra *ra = p->ra; bool have_float_tex = !!ra_find_float16_format(ra, 1); bool have_mglsl = ra->glsl_version >= 130; // modern GLSL const struct ra_format *rg_tex = ra_find_unorm_format(p->ra, 1, 2); bool have_texrg = rg_tex && !rg_tex->luminance_alpha; bool have_compute = ra->caps & RA_CAP_COMPUTE; bool have_ssbo = ra->caps & RA_CAP_BUF_RW; const char *auto_fbo_fmts[] = {"rgba16", "rgba16f", "rgba16hf", "rgb10_a2", "rgba8", 0}; const char *user_fbo_fmts[] = {p->opts.fbo_format, 0}; const char **fbo_fmts = user_fbo_fmts[0] && strcmp(user_fbo_fmts[0], "auto") ? user_fbo_fmts : auto_fbo_fmts; bool have_fbo = false; p->fbo_format = NULL; for (int n = 0; fbo_fmts[n]; n++) { const char *fmt = fbo_fmts[n]; const struct ra_format *f = ra_find_named_format(p->ra, fmt); if (!f && fbo_fmts == user_fbo_fmts) MP_WARN(p, "FBO format '%s' not found!\n", fmt); if (f && f->renderable && f->linear_filter && test_fbo(p, f)) { MP_VERBOSE(p, "Using FBO format %s.\n", f->name); have_fbo = true; p->fbo_format = f; break; } } p->forced_dumb_mode = p->opts.dumb_mode > 0 || !have_fbo || !have_texrg; bool voluntarily_dumb = check_dumb_mode(p); if (p->forced_dumb_mode || voluntarily_dumb) { if (voluntarily_dumb) { MP_VERBOSE(p, "No advanced processing required. Enabling dumb mode.\n"); } else if (p->opts.dumb_mode <= 0) { MP_WARN(p, "High bit depth FBOs unsupported. Enabling dumb mode.\n" "Most extended features will be disabled.\n"); } p->dumb_mode = true; // Most things don't work, so whitelist all options that still work. p->opts = (struct gl_video_opts){ .gamma = p->opts.gamma, .gamma_auto = p->opts.gamma_auto, .pbo = p->opts.pbo, .fbo_format = p->opts.fbo_format, .alpha_mode = p->opts.alpha_mode, .use_rectangle = p->opts.use_rectangle, .background = p->opts.background, .dither_algo = p->opts.dither_algo, .dither_depth = p->opts.dither_depth, .dither_size = p->opts.dither_size, .temporal_dither = p->opts.temporal_dither, .temporal_dither_period = p->opts.temporal_dither_period, .tex_pad_x = p->opts.tex_pad_x, .tex_pad_y = p->opts.tex_pad_y, .tone_mapping = p->opts.tone_mapping, .tone_mapping_param = p->opts.tone_mapping_param, .tone_mapping_desat = p->opts.tone_mapping_desat, .early_flush = p->opts.early_flush, .icc_opts = p->opts.icc_opts, }; for (int n = 0; n < SCALER_COUNT; n++) p->opts.scaler[n] = gl_video_opts_def.scaler[n]; if (!have_fbo) p->use_lut_3d = false; return; } p->dumb_mode = false; // Normally, we want to disable them by default if FBOs are unavailable, // because they will be slow (not critically slow, but still slower). // Without FP textures, we must always disable them. // I don't know if luminance alpha float textures exist, so disregard them. for (int n = 0; n < SCALER_COUNT; n++) { const struct filter_kernel *kernel = mp_find_filter_kernel(p->opts.scaler[n].kernel.name); if (kernel) { char *reason = NULL; if (!have_float_tex) reason = "(float tex. missing)"; if (!have_mglsl) reason = "(GLSL version too old)"; if (reason) { MP_WARN(p, "Disabling scaler #%d %s %s.\n", n, p->opts.scaler[n].kernel.name, reason); // p->opts is a copy => we can just mess with it. p->opts.scaler[n].kernel.name = "bilinear"; if (n == SCALER_TSCALE) p->opts.interpolation = 0; } } } int use_cms = p->opts.target_prim != MP_CSP_PRIM_AUTO || p->opts.target_trc != MP_CSP_TRC_AUTO || p->use_lut_3d; // mix() is needed for some gamma functions if (!have_mglsl && (p->opts.linear_scaling || p->opts.sigmoid_upscaling)) { p->opts.linear_scaling = false; p->opts.sigmoid_upscaling = false; MP_WARN(p, "Disabling linear/sigmoid scaling (GLSL version too old).\n"); } if (!have_mglsl && use_cms) { p->opts.target_prim = MP_CSP_PRIM_AUTO; p->opts.target_trc = MP_CSP_TRC_AUTO; p->use_lut_3d = false; MP_WARN(p, "Disabling color management (GLSL version too old).\n"); } if (!have_mglsl && p->opts.deband) { p->opts.deband = 0; MP_WARN(p, "Disabling debanding (GLSL version too old).\n"); } if ((!have_compute || !have_ssbo) && p->opts.compute_hdr_peak) { p->opts.compute_hdr_peak = 0; MP_WARN(p, "Disabling HDR peak computation (no compute shaders).\n"); } if (!(ra->caps & RA_CAP_FRAGCOORD) && p->opts.dither_depth >= 0 && p->opts.dither_algo != DITHER_NONE) { p->opts.dither_algo = DITHER_NONE; MP_WARN(p, "Disabling dithering (no gl_FragCoord).\n"); } if (!(ra->caps & RA_CAP_FRAGCOORD) && p->opts.alpha_mode == ALPHA_BLEND_TILES) { p->opts.alpha_mode = ALPHA_BLEND; // Verbose, since this is the default setting MP_VERBOSE(p, "Disabling alpha checkerboard (no gl_FragCoord).\n"); } } static void init_gl(struct gl_video *p) { debug_check_gl(p, "before init_gl"); p->upload_timer = timer_pool_create(p->ra); p->blit_timer = timer_pool_create(p->ra); p->osd_timer = timer_pool_create(p->ra); debug_check_gl(p, "after init_gl"); ra_dump_tex_formats(p->ra, MSGL_DEBUG); ra_dump_img_formats(p->ra, MSGL_DEBUG); } void gl_video_uninit(struct gl_video *p) { if (!p) return; uninit_video(p); gl_sc_destroy(p->sc); ra_tex_free(p->ra, &p->lut_3d_texture); ra_buf_free(p->ra, &p->hdr_peak_ssbo); timer_pool_destroy(p->upload_timer); timer_pool_destroy(p->blit_timer); timer_pool_destroy(p->osd_timer); for (int i = 0; i < VO_PASS_PERF_MAX; i++) { talloc_free(p->pass_fresh[i].desc.start); talloc_free(p->pass_redraw[i].desc.start); } mpgl_osd_destroy(p->osd); // Forcibly destroy possibly remaining image references. This should also // cause gl_video_dr_free_buffer() to be called for the remaining buffers. gc_pending_dr_fences(p, true); // Should all have been unreffed already. assert(!p->num_dr_buffers); talloc_free(p); } void gl_video_reset(struct gl_video *p) { gl_video_reset_surfaces(p); } bool gl_video_showing_interpolated_frame(struct gl_video *p) { return p->is_interpolated; } static bool is_imgfmt_desc_supported(struct gl_video *p, const struct ra_imgfmt_desc *desc) { if (!desc->num_planes) return false; if (desc->planes[0]->ctype == RA_CTYPE_UINT && p->forced_dumb_mode) return false; return true; } bool gl_video_check_format(struct gl_video *p, int mp_format) { struct ra_imgfmt_desc desc; if (ra_get_imgfmt_desc(p->ra, mp_format, &desc) && is_imgfmt_desc_supported(p, &desc)) return true; if (p->hwdec && ra_hwdec_test_format(p->hwdec, mp_format)) return true; return false; } void gl_video_config(struct gl_video *p, struct mp_image_params *params) { unmap_overlay(p); unref_current_image(p); if (!mp_image_params_equal(&p->real_image_params, params)) { uninit_video(p); p->real_image_params = *params; p->image_params = *params; if (params->imgfmt) init_video(p); } gl_video_reset_surfaces(p); } void gl_video_set_osd_source(struct gl_video *p, struct osd_state *osd) { mpgl_osd_destroy(p->osd); p->osd = NULL; p->osd_state = osd; reinit_osd(p); } struct gl_video *gl_video_init(struct ra *ra, struct mp_log *log, struct mpv_global *g) { struct gl_video *p = talloc_ptrtype(NULL, p); *p = (struct gl_video) { .ra = ra, .global = g, .log = log, .sc = gl_sc_create(ra, g, log), .video_eq = mp_csp_equalizer_create(p, g), .opts_cache = m_config_cache_alloc(p, g, &gl_video_conf), }; // make sure this variable is initialized to *something* p->pass = p->pass_fresh; struct gl_video_opts *opts = p->opts_cache->opts; p->cms = gl_lcms_init(p, log, g, opts->icc_opts), p->opts = *opts; for (int n = 0; n < SCALER_COUNT; n++) p->scaler[n] = (struct scaler){.index = n}; // our VAO always has the vec2 position as the first element MP_TARRAY_APPEND(p, p->vao, p->vao_len, (struct ra_renderpass_input) { .name = "position", .type = RA_VARTYPE_FLOAT, .dim_v = 2, .dim_m = 1, .offset = 0, }); init_gl(p); reinit_from_options(p); return p; } // Get static string for scaler shader. If "tscale" is set to true, the // scaler must be a separable convolution filter. static const char *handle_scaler_opt(const char *name, bool tscale) { if (name && name[0]) { const struct filter_kernel *kernel = mp_find_filter_kernel(name); if (kernel && (!tscale || !kernel->polar)) return kernel->f.name; for (const char *const *filter = tscale ? fixed_tscale_filters : fixed_scale_filters; *filter; filter++) { if (strcmp(*filter, name) == 0) return *filter; } } return NULL; } static void gl_video_update_options(struct gl_video *p) { if (m_config_cache_update(p->opts_cache)) { gl_lcms_update_options(p->cms); reinit_from_options(p); } if (mp_csp_equalizer_state_changed(p->video_eq)) p->output_tex_valid = false; } static void reinit_from_options(struct gl_video *p) { p->use_lut_3d = gl_lcms_has_profile(p->cms); // Copy the option fields, so that check_gl_features() can mutate them. // This works only for the fields themselves of course, not for any memory // referenced by them. p->opts = *(struct gl_video_opts *)p->opts_cache->opts; if (!p->force_clear_color) p->clear_color = p->opts.background; check_gl_features(p); uninit_rendering(p); gl_sc_set_cache_dir(p->sc, p->opts.shader_cache_dir); p->ra->use_pbo = p->opts.pbo; gl_video_setup_hooks(p); reinit_osd(p); if (p->opts.interpolation && !p->global->opts->video_sync && !p->dsi_warned) { MP_WARN(p, "Interpolation now requires enabling display-sync mode.\n" "E.g.: --video-sync=display-resample\n"); p->dsi_warned = true; } } void gl_video_configure_queue(struct gl_video *p, struct vo *vo) { gl_video_update_options(p); int queue_size = 1; // Figure out an adequate size for the interpolation queue. The larger // the radius, the earlier we need to queue frames. if (p->opts.interpolation) { const struct filter_kernel *kernel = mp_find_filter_kernel(p->opts.scaler[SCALER_TSCALE].kernel.name); if (kernel) { // filter_scale wouldn't be correctly initialized were we to use it here. // This is fine since we're always upsampling, but beware if downsampling // is added! double radius = kernel->f.radius; radius = radius > 0 ? radius : p->opts.scaler[SCALER_TSCALE].radius; queue_size += 1 + ceil(radius); } else { // Oversample/linear case queue_size += 2; } } vo_set_queue_params(vo, 0, queue_size); } static int validate_scaler_opt(struct mp_log *log, const m_option_t *opt, struct bstr name, struct bstr param) { char s[20] = {0}; int r = 1; bool tscale = bstr_equals0(name, "tscale"); if (bstr_equals0(param, "help")) { r = M_OPT_EXIT; } else { snprintf(s, sizeof(s), "%.*s", BSTR_P(param)); if (!handle_scaler_opt(s, tscale)) r = M_OPT_INVALID; } if (r < 1) { mp_info(log, "Available scalers:\n"); for (const char *const *filter = tscale ? fixed_tscale_filters : fixed_scale_filters; *filter; filter++) { mp_info(log, " %s\n", *filter); } for (int n = 0; mp_filter_kernels[n].f.name; n++) { if (!tscale || !mp_filter_kernels[n].polar) mp_info(log, " %s\n", mp_filter_kernels[n].f.name); } if (s[0]) mp_fatal(log, "No scaler named '%s' found!\n", s); } return r; } static int validate_window_opt(struct mp_log *log, const m_option_t *opt, struct bstr name, struct bstr param) { char s[20] = {0}; int r = 1; if (bstr_equals0(param, "help")) { r = M_OPT_EXIT; } else { snprintf(s, sizeof(s), "%.*s", BSTR_P(param)); const struct filter_window *window = mp_find_filter_window(s); if (!window) r = M_OPT_INVALID; } if (r < 1) { mp_info(log, "Available windows:\n"); for (int n = 0; mp_filter_windows[n].name; n++) mp_info(log, " %s\n", mp_filter_windows[n].name); if (s[0]) mp_fatal(log, "No window named '%s' found!\n", s); } return r; } float gl_video_scale_ambient_lux(float lmin, float lmax, float rmin, float rmax, float lux) { assert(lmax > lmin); float num = (rmax - rmin) * (log10(lux) - log10(lmin)); float den = log10(lmax) - log10(lmin); float result = num / den + rmin; // clamp the result float max = MPMAX(rmax, rmin); float min = MPMIN(rmax, rmin); return MPMAX(MPMIN(result, max), min); } void gl_video_set_ambient_lux(struct gl_video *p, int lux) { if (p->opts.gamma_auto) { p->opts.gamma = gl_video_scale_ambient_lux(16.0, 256.0, 1.0, 1.2, lux); MP_VERBOSE(p, "ambient light changed: %d lux (gamma: %f)\n", lux, p->opts.gamma); } } void gl_video_set_hwdec(struct gl_video *p, struct ra_hwdec *hwdec) { unref_current_image(p); ra_hwdec_mapper_free(&p->hwdec_mapper); p->hwdec = hwdec; } static void *gl_video_dr_alloc_buffer(struct gl_video *p, size_t size) { struct ra_buf_params params = { .type = RA_BUF_TYPE_TEX_UPLOAD, .host_mapped = true, .size = size, }; struct ra_buf *buf = ra_buf_create(p->ra, ¶ms); if (!buf) return NULL; MP_TARRAY_GROW(p, p->dr_buffers, p->num_dr_buffers); p->dr_buffers[p->num_dr_buffers++] = (struct dr_buffer){ .buf = buf }; return buf->data; }; static void gl_video_dr_free_buffer(void *opaque, uint8_t *data) { struct gl_video *p = opaque; for (int n = 0; n < p->num_dr_buffers; n++) { struct dr_buffer *buffer = &p->dr_buffers[n]; if (buffer->buf->data == data) { assert(!buffer->mpi); // can't be freed while it has a ref ra_buf_free(p->ra, &buffer->buf); MP_TARRAY_REMOVE_AT(p->dr_buffers, p->num_dr_buffers, n); return; } } // not found - must not happen assert(0); } struct mp_image *gl_video_get_image(struct gl_video *p, int imgfmt, int w, int h, int stride_align) { int size = mp_image_get_alloc_size(imgfmt, w, h, stride_align); if (size < 0) return NULL; int alloc_size = size + stride_align; void *ptr = gl_video_dr_alloc_buffer(p, alloc_size); if (!ptr) return NULL; // (we expect vo.c to proxy the free callback, so it happens in the same // thread it was allocated in, removing the need for synchronization) struct mp_image *res = mp_image_from_buffer(imgfmt, w, h, stride_align, ptr, alloc_size, p, gl_video_dr_free_buffer); if (!res) gl_video_dr_free_buffer(p, ptr); return res; }