#pragma once #include enum { // This controls bheavior with different bit widths per component (like // RGB565). If ROUND_DOWN is specified, the planar format will use the min. // bit width of all components, otherwise the transformation is lossless. REPACK_CREATE_ROUND_DOWN = (1 << 0), // Expand some (not all) low bit depth fringe formats to 8 bit on unpack. REPACK_CREATE_EXPAND_8BIT = (1 << 1), // For mp_repack_create_planar(). If specified, the planar format uses a // float 32 bit sample format. No range expansion is done. REPACK_CREATE_PLANAR_F32 = (1 << 2), }; struct mp_repack; struct mp_image; // Create a repacker between any format (imgfmt parameter) and an equivalent // planar format (that is native endian). If pack==true, imgfmt is the output, // otherwise it is the input. The respective other input/output is the planar // format. The planar format can be queried with mp_repack_get_format_*(). // Note that some formats may change the "implied" colorspace (for example, // packed xyz unpacks as rgb). // If imgfmt is already planar, a passthrough repacker may be created. // imgfmt: src or dst format (usually packed, non-planar, etc.) // pack: true if imgfmt is dst, false if imgfmt is src // flags: any of REPACK_CREATE_* flags // returns: NULL on failure, otherwise free with talloc_free(). struct mp_repack *mp_repack_create_planar(int imgfmt, bool pack, int flags); // Return input and output formats for which rp was created. int mp_repack_get_format_src(struct mp_repack *rp); int mp_repack_get_format_dst(struct mp_repack *rp); // Return pixel alignment. For x, this is a lowest pixel count at which there is // a byte boundary and a full chroma pixel (horizontal subsampling) on src/dst. // For y, this is the pixel height of the vertical subsampling. // Always returns a power of 2. int mp_repack_get_align_x(struct mp_repack *rp); int mp_repack_get_align_y(struct mp_repack *rp); // Repack a single line from dst to src, as set in repack_config_buffers(). // For subsampled chroma formats, this copies as many luma/alpha rows as needed // for a complete line (e.g. 2 luma lines, 1 chroma line for 4:2:0). // dst_x, src_x, y must be aligned to the pixel alignment. w may be unaligned // if at the right crop-border of the image, but must be always aligned to // horiz. sub-sampling. y is subject to hslice. void repack_line(struct mp_repack *rp, int dst_x, int dst_y, int src_x, int src_y, int w); // Configure with a source and target buffer. The rp instance will keep the // mp_image pointers and access them on repack_line() calls. Refcounting is // not respected - the caller needs to make sure dst is always writable. // The images can have different sizes (as repack_line() lets you use different // target coordinates for dst/src). // This also allocaters potentially required temporary buffers. // dst_flags: REPACK_BUF_* flags for dst // dst: where repack_line() writes to // src_flags: REPACK_BUF_* flags for src // src: where repack_line() reads from // enable_passthrough: if non-NULL, an bool array of size MP_MAX_PLANES indexed // by plane; a true entry requests disabling copying the // plane data to the dst plane. The function will write to // this array whether the plane can really be passed through // (i.e. will set array entries from true to false if pass- // through is not possible). It writes to all MP_MAX_PLANES // entries. If NULL, all entries are implicitly false. // returns: success (fails on OOM) bool repack_config_buffers(struct mp_repack *rp, int dst_flags, struct mp_image *dst, int src_flags, struct mp_image *src, bool *enable_passthrough);