/* * This file is part of mpv. * * mpv is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 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 General Public License for more details. * * You should have received a copy of the GNU General Public License along * with mpv; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include #include #include #include #include "mpvcore/mp_common.h" #include "sub/draw_bmp.h" #include "sub/sub.h" #include "sub/img_convert.h" #include "video/mp_image.h" #include "video/sws_utils.h" #include "video/img_format.h" #include "video/csputils.h" const bool mp_draw_sub_formats[SUBBITMAP_COUNT] = { [SUBBITMAP_LIBASS] = true, [SUBBITMAP_RGBA] = true, }; struct sub_cache { struct mp_image *i, *a; }; struct part { int bitmap_pos_id; int imgfmt; enum mp_csp colorspace; enum mp_csp_levels levels; int num_imgs; struct sub_cache *imgs; }; struct mp_draw_sub_cache { struct part *parts[MAX_OSD_PARTS]; struct mp_image *upsample_img; struct mp_image upsample_temp; }; static struct part *get_cache(struct mp_draw_sub_cache *cache, struct sub_bitmaps *sbs, struct mp_image *format); static bool get_sub_area(struct mp_rect bb, struct mp_image *temp, struct sub_bitmap *sb, struct mp_image *out_area, int *out_src_x, int *out_src_y); #define ACCURATE #define CONDITIONAL static void blend_const16_alpha(void *dst, int dst_stride, uint16_t srcp, uint8_t *srca, int srca_stride, uint8_t srcamul, int w, int h) { if (!srcamul) return; for (int y = 0; y < h; y++) { uint16_t *dst_r = (uint16_t *)((uint8_t *)dst + dst_stride * y); uint8_t *srca_r = srca + srca_stride * y; for (int x = 0; x < w; x++) { uint32_t srcap = srca_r[x]; #ifdef CONDITIONAL if (!srcap) continue; #endif srcap *= srcamul; // now 0..65025 dst_r[x] = (srcp * srcap + dst_r[x] * (65025 - srcap) + 32512) / 65025; } } } static void blend_const8_alpha(void *dst, int dst_stride, uint16_t srcp, uint8_t *srca, int srca_stride, uint8_t srcamul, int w, int h) { if (!srcamul) return; for (int y = 0; y < h; y++) { uint8_t *dst_r = (uint8_t *)dst + dst_stride * y; uint8_t *srca_r = srca + srca_stride * y; for (int x = 0; x < w; x++) { uint32_t srcap = srca_r[x]; #ifdef CONDITIONAL if (!srcap) continue; #endif #ifdef ACCURATE srcap *= srcamul; // now 0..65025 dst_r[x] = (srcp * srcap + dst_r[x] * (65025 - srcap) + 32512) / 65025; #else srcap = (srcap * srcamul + 255) >> 8; dst_r[x] = (srcp * srcap + dst_r[x] * (255 - srcap) + 255) >> 8; #endif } } } static void blend_const_alpha(void *dst, int dst_stride, int srcp, uint8_t *srca, int srca_stride, uint8_t srcamul, int w, int h, int bytes) { if (bytes == 2) { blend_const16_alpha(dst, dst_stride, srcp, srca, srca_stride, srcamul, w, h); } else if (bytes == 1) { blend_const8_alpha(dst, dst_stride, srcp, srca, srca_stride, srcamul, w, h); } } static void blend_src16_alpha(void *dst, int dst_stride, void *src, int src_stride, uint8_t *srca, int srca_stride, int w, int h) { for (int y = 0; y < h; y++) { uint16_t *dst_r = (uint16_t *)((uint8_t *)dst + dst_stride * y); uint16_t *src_r = (uint16_t *)((uint8_t *)src + src_stride * y); uint8_t *srca_r = srca + srca_stride * y; for (int x = 0; x < w; x++) { uint32_t srcap = srca_r[x]; #ifdef CONDITIONAL if (!srcap) continue; #endif dst_r[x] = (src_r[x] * srcap + dst_r[x] * (255 - srcap) + 127) / 255; } } } static void blend_src8_alpha(void *dst, int dst_stride, void *src, int src_stride, uint8_t *srca, int srca_stride, int w, int h) { for (int y = 0; y < h; y++) { uint8_t *dst_r = (uint8_t *)dst + dst_stride * y; uint8_t *src_r = (uint8_t *)src + src_stride * y; uint8_t *srca_r = srca + srca_stride * y; for (int x = 0; x < w; x++) { uint16_t srcap = srca_r[x]; #ifdef CONDITIONAL if (!srcap) continue; #endif #ifdef ACCURATE dst_r[x] = (src_r[x] * srcap + dst_r[x] * (255 - srcap) + 127) / 255; #else dst_r[x] = (src_r[x] * srcap + dst_r[x] * (255 - srcap) + 255) >> 8; #endif } } } static void blend_src_alpha(void *dst, int dst_stride, void *src, int src_stride, uint8_t *srca, int srca_stride, int w, int h, int bytes) { if (bytes == 2) { blend_src16_alpha(dst, dst_stride, src, src_stride, srca, srca_stride, w, h); } else if (bytes == 1) { blend_src8_alpha(dst, dst_stride, src, src_stride, srca, srca_stride, w, h); } } static void unpremultiply_and_split_BGR32(struct mp_image *img, struct mp_image *alpha) { for (int y = 0; y < img->h; ++y) { uint32_t *irow = (uint32_t *) &img->planes[0][img->stride[0] * y]; uint8_t *arow = &alpha->planes[0][alpha->stride[0] * y]; for (int x = 0; x < img->w; ++x) { uint32_t pval = irow[x]; uint8_t aval = (pval >> 24); uint8_t rval = (pval >> 16) & 0xFF; uint8_t gval = (pval >> 8) & 0xFF; uint8_t bval = pval & 0xFF; // multiplied = separate * alpha / 255 // separate = rint(multiplied * 255 / alpha) // = floor(multiplied * 255 / alpha + 0.5) // = floor((multiplied * 255 + 0.5 * alpha) / alpha) // = floor((multiplied * 255 + floor(0.5 * alpha)) / alpha) int div = (int) aval; int add = div / 2; if (aval) { rval = FFMIN(255, (rval * 255 + add) / div); gval = FFMIN(255, (gval * 255 + add) / div); bval = FFMIN(255, (bval * 255 + add) / div); irow[x] = bval + (gval << 8) + (rval << 16) + (aval << 24); } arow[x] = aval; } } } // dst_format merely contains the target colorspace/format information static void scale_sb_rgba(struct sub_bitmap *sb, struct mp_image *dst_format, struct mp_image **out_sbi, struct mp_image **out_sba) { struct mp_image sbisrc = {0}; mp_image_setfmt(&sbisrc, IMGFMT_BGR32); mp_image_set_size(&sbisrc, sb->w, sb->h); sbisrc.planes[0] = sb->bitmap; sbisrc.stride[0] = sb->stride; struct mp_image *sbisrc2 = mp_image_alloc(IMGFMT_BGR32, sb->dw, sb->dh); mp_image_swscale(sbisrc2, &sbisrc, SWS_BILINEAR); struct mp_image *sba = mp_image_alloc(IMGFMT_Y8, sb->dw, sb->dh); unpremultiply_and_split_BGR32(sbisrc2, sba); struct mp_image *sbi = mp_image_alloc(dst_format->imgfmt, sb->dw, sb->dh); sbi->colorspace = dst_format->colorspace; sbi->levels = dst_format->levels; mp_image_swscale(sbi, sbisrc2, SWS_BILINEAR); talloc_free(sbisrc2); *out_sbi = sbi; *out_sba = sba; } static void draw_rgba(struct mp_draw_sub_cache *cache, struct mp_rect bb, struct mp_image *temp, int bits, struct sub_bitmaps *sbs) { struct part *part = get_cache(cache, sbs, temp); assert(part); for (int i = 0; i < sbs->num_parts; ++i) { struct sub_bitmap *sb = &sbs->parts[i]; if (sb->w < 1 || sb->h < 1) continue; struct mp_image dst; int src_x, src_y; if (!get_sub_area(bb, temp, sb, &dst, &src_x, &src_y)) continue; struct mp_image *sbi = part->imgs[i].i; struct mp_image *sba = part->imgs[i].a; if (!(sbi && sba)) scale_sb_rgba(sb, temp, &sbi, &sba); int bytes = (bits + 7) / 8; uint8_t *alpha_p = sba->planes[0] + src_y * sba->stride[0] + src_x; for (int p = 0; p < (temp->num_planes > 2 ? 3 : 1); p++) { void *src = sbi->planes[p] + src_y * sbi->stride[p] + src_x * bytes; blend_src_alpha(dst.planes[p], dst.stride[p], src, sbi->stride[p], alpha_p, sba->stride[0], dst.w, dst.h, bytes); } part->imgs[i].i = talloc_steal(part, sbi); part->imgs[i].a = talloc_steal(part, sba); } } static void draw_ass(struct mp_draw_sub_cache *cache, struct mp_rect bb, struct mp_image *temp, int bits, struct sub_bitmaps *sbs) { struct mp_csp_params cspar = MP_CSP_PARAMS_DEFAULTS; cspar.colorspace.format = temp->colorspace; cspar.colorspace.levels_in = temp->levels; cspar.colorspace.levels_out = MP_CSP_LEVELS_PC; // RGB (libass.color) cspar.int_bits_in = bits; cspar.int_bits_out = 8; float yuv2rgb[3][4], rgb2yuv[3][4]; if (temp->flags & MP_IMGFLAG_YUV) { mp_get_yuv2rgb_coeffs(&cspar, yuv2rgb); mp_invert_yuv2rgb(rgb2yuv, yuv2rgb); } for (int i = 0; i < sbs->num_parts; ++i) { struct sub_bitmap *sb = &sbs->parts[i]; struct mp_image dst; int src_x, src_y; if (!get_sub_area(bb, temp, sb, &dst, &src_x, &src_y)) continue; int r = (sb->libass.color >> 24) & 0xFF; int g = (sb->libass.color >> 16) & 0xFF; int b = (sb->libass.color >> 8) & 0xFF; int a = 255 - (sb->libass.color & 0xFF); int color_yuv[3] = {r, g, b}; if (dst.flags & MP_IMGFLAG_YUV) { mp_map_int_color(rgb2yuv, bits, color_yuv); } else { assert(dst.imgfmt == IMGFMT_GBRP); color_yuv[0] = g; color_yuv[1] = b; color_yuv[2] = r; } int bytes = (bits + 7) / 8; uint8_t *alpha_p = (uint8_t *)sb->bitmap + src_y * sb->stride + src_x; for (int p = 0; p < (temp->num_planes > 2 ? 3 : 1); p++) { blend_const_alpha(dst.planes[p], dst.stride[p], color_yuv[p], alpha_p, sb->stride, a, dst.w, dst.h, bytes); } } } static void get_swscale_alignment(const struct mp_image *img, int *out_xstep, int *out_ystep) { int sx = (1 << img->chroma_x_shift); int sy = (1 << img->chroma_y_shift); for (int p = 0; p < img->num_planes; ++p) { int bits = img->fmt.bpp[p]; // the * 2 fixes problems with writing past the destination width while (((sx >> img->chroma_x_shift) * bits) % (SWS_MIN_BYTE_ALIGN * 8 * 2)) sx *= 2; } *out_xstep = sx; *out_ystep = sy; } static void align_bbox(int xstep, int ystep, struct mp_rect *rc) { rc->x0 = rc->x0 & ~(xstep - 1); rc->y0 = rc->y0 & ~(ystep - 1); rc->x1 = FFALIGN(rc->x1, xstep); rc->y1 = FFALIGN(rc->y1, ystep); } // Post condition, if true returned: rc is inside img static bool align_bbox_for_swscale(struct mp_image *img, struct mp_rect *rc) { struct mp_rect img_rect = {0, 0, img->w, img->h}; // Get rid of negative coordinates if (!mp_rect_intersection(rc, &img_rect)) return false; int xstep, ystep; get_swscale_alignment(img, &xstep, &ystep); align_bbox(xstep, ystep, rc); return mp_rect_intersection(rc, &img_rect); } // Try to find best/closest YUV 444 format (or similar) for imgfmt static void get_closest_y444_format(int imgfmt, int *out_format, int *out_bits) { struct mp_imgfmt_desc desc = mp_imgfmt_get_desc(imgfmt); if (desc.flags & MP_IMGFLAG_RGB) { *out_format = IMGFMT_GBRP; *out_bits = 8; return; } else if (desc.flags & MP_IMGFLAG_YUV_P) { *out_format = mp_imgfmt_find_yuv_planar(0, 0, desc.num_planes, desc.plane_bits); if (*out_format && mp_sws_supported_format(*out_format)) { *out_bits = mp_imgfmt_get_desc(*out_format).plane_bits; return; } } // fallback *out_format = IMGFMT_444P; *out_bits = 8; } static struct part *get_cache(struct mp_draw_sub_cache *cache, struct sub_bitmaps *sbs, struct mp_image *format) { struct part *part = NULL; bool use_cache = sbs->format == SUBBITMAP_RGBA; if (use_cache) { part = cache->parts[sbs->render_index]; if (part) { if (part->bitmap_pos_id != sbs->bitmap_pos_id || part->imgfmt != format->imgfmt || part->colorspace != format->colorspace || part->levels != format->levels) { talloc_free(part); part = NULL; } } if (!part) { part = talloc(cache, struct part); *part = (struct part) { .bitmap_pos_id = sbs->bitmap_pos_id, .num_imgs = sbs->num_parts, .imgfmt = format->imgfmt, .levels = format->levels, .colorspace = format->colorspace, }; part->imgs = talloc_zero_array(part, struct sub_cache, part->num_imgs); } assert(part->num_imgs == sbs->num_parts); cache->parts[sbs->render_index] = part; } return part; } // Return area of intersection between target and sub-bitmap as cropped image static bool get_sub_area(struct mp_rect bb, struct mp_image *temp, struct sub_bitmap *sb, struct mp_image *out_area, int *out_src_x, int *out_src_y) { // coordinates are relative to the bbox struct mp_rect dst = {sb->x - bb.x0, sb->y - bb.y0}; dst.x1 = dst.x0 + sb->dw; dst.y1 = dst.y0 + sb->dh; if (!mp_rect_intersection(&dst, &(struct mp_rect){0, 0, temp->w, temp->h})) return false; *out_src_x = (dst.x0 - sb->x) + bb.x0; *out_src_y = (dst.y0 - sb->y) + bb.y0; *out_area = *temp; mp_image_crop_rc(out_area, dst); return true; } // Convert the src image to imgfmt (which should be a 444 format) static struct mp_image *chroma_up(struct mp_draw_sub_cache *cache, int imgfmt, struct mp_image *src) { if (src->imgfmt == imgfmt) return src; if (!cache->upsample_img || cache->upsample_img->imgfmt != imgfmt || cache->upsample_img->w < src->w || cache->upsample_img->h < src->h) { talloc_free(cache->upsample_img); cache->upsample_img = mp_image_alloc(imgfmt, src->w, src->h); talloc_steal(cache, cache->upsample_img); } cache->upsample_temp = *cache->upsample_img; struct mp_image *temp = &cache->upsample_temp; mp_image_set_size(temp, src->w, src->h); // The temp image is always YUV, but src not necessarily. // Reduce amount of conversions in YUV case (upsampling/shifting only) if (src->flags & MP_IMGFLAG_YUV) { temp->colorspace = src->colorspace; temp->levels = src->levels; } if (src->imgfmt == IMGFMT_420P) { assert(imgfmt == IMGFMT_444P); // Faster upsampling: keep Y plane, upsample chroma planes only // The whole point is not having swscale copy the Y plane struct mp_image t_dst = *temp; mp_image_setfmt(&t_dst, IMGFMT_Y8); mp_image_set_size(&t_dst, temp->chroma_width, temp->chroma_height); struct mp_image t_src = t_dst; mp_image_set_size(&t_src, src->chroma_width, src->chroma_height); for (int c = 0; c < 2; c++) { t_dst.planes[0] = temp->planes[1 + c]; t_dst.stride[0] = temp->stride[1 + c]; t_src.planes[0] = src->planes[1 + c]; t_src.stride[0] = src->stride[1 + c]; mp_image_swscale(&t_dst, &t_src, SWS_POINT); } temp->planes[0] = src->planes[0]; temp->stride[0] = src->stride[0]; } else { mp_image_swscale(temp, src, SWS_POINT); } return temp; } // Undo chroma_up() (copy temp to old_src if needed) static void chroma_down(struct mp_image *old_src, struct mp_image *temp) { assert(old_src->w == temp->w && old_src->h == temp->h); if (temp != old_src) { if (old_src->imgfmt == IMGFMT_420P) { // Downsampling, skipping the Y plane (see chroma_up()) assert(temp->imgfmt == IMGFMT_444P); assert(temp->planes[0] == old_src->planes[0]); struct mp_image t_dst = *temp; mp_image_setfmt(&t_dst, IMGFMT_Y8); mp_image_set_size(&t_dst, old_src->chroma_width, old_src->chroma_height); struct mp_image t_src = t_dst; mp_image_set_size(&t_src, temp->chroma_width, temp->chroma_height); for (int c = 0; c < 2; c++) { t_dst.planes[0] = old_src->planes[1 + c]; t_dst.stride[0] = old_src->stride[1 + c]; t_src.planes[0] = temp->planes[1 + c]; t_src.stride[0] = temp->stride[1 + c]; mp_image_swscale(&t_dst, &t_src, SWS_AREA); } } else { mp_image_swscale(old_src, temp, SWS_AREA); // chroma down } } } // cache: if not NULL, the function will set *cache to a talloc-allocated cache // containing scaled versions of sbs contents - free the cache with // talloc_free() void mp_draw_sub_bitmaps(struct mp_draw_sub_cache **cache, struct mp_image *dst, struct sub_bitmaps *sbs) { assert(mp_draw_sub_formats[sbs->format]); if (!mp_sws_supported_format(dst->imgfmt)) return; struct mp_draw_sub_cache *cache_ = cache ? *cache : NULL; if (!cache_) cache_ = talloc_zero(NULL, struct mp_draw_sub_cache); int format, bits; get_closest_y444_format(dst->imgfmt, &format, &bits); struct mp_rect rc_list[MP_SUB_BB_LIST_MAX]; int num_rc = mp_get_sub_bb_list(sbs, rc_list, MP_SUB_BB_LIST_MAX); for (int r = 0; r < num_rc; r++) { struct mp_rect bb = rc_list[r]; if (!align_bbox_for_swscale(dst, &bb)) return; struct mp_image dst_region = *dst; mp_image_crop_rc(&dst_region, bb); struct mp_image *temp = chroma_up(cache_, format, &dst_region); if (sbs->format == SUBBITMAP_RGBA) { draw_rgba(cache_, bb, temp, bits, sbs); } else if (sbs->format == SUBBITMAP_LIBASS) { draw_ass(cache_, bb, temp, bits, sbs); } chroma_down(&dst_region, temp); } if (cache) { *cache = cache_; } else { talloc_free(cache_); } } // vim: ts=4 sw=4 et tw=80