/* SPDX-License-Identifier: LGPL-2.1+ */ /* * Copyright 2016 Tom aan de Wiel * Copyright 2018 Cisco Systems, Inc. and/or its affiliates. All rights reserved. */ #ifndef CODEC_FWHT_H #define CODEC_FWHT_H #include #include #include /* * The compressed format consists of a fwht_cframe_hdr struct followed by the * compressed frame data. The header contains the size of that data. * Each Y, Cb and Cr plane is compressed separately. If the compressed * size of each plane becomes larger than the uncompressed size, then * that plane is stored uncompressed and the corresponding bit is set * in the flags field of the header. * * Each compressed plane consists of macroblocks and each macroblock * is run-length-encoded. Each macroblock starts with a 16 bit value. * Bit 15 indicates if this is a P-coded macroblock (1) or not (0). * P-coded macroblocks contain a delta against the previous frame. * * Bits 1-12 contain a number. If non-zero, then this same macroblock * repeats that number of times. This results in a high degree of * compression for generated images like colorbars. * * Following this macroblock header the MB coefficients are run-length * encoded: the top 12 bits contain the coefficient, the bottom 4 bits * tell how many times this coefficient occurs. The value 0xf indicates * that the remainder of the macroblock should be filled with zeroes. * * All 16 and 32 bit values are stored in big-endian (network) order. * * Each fwht_cframe_hdr starts with an 8 byte magic header that is * guaranteed not to occur in the compressed frame data. This header * can be used to sync to the next frame. * * This codec uses the Fast Walsh Hadamard Transform. Tom aan de Wiel * developed this as part of a university project, specifically for use * with this driver. His project report can be found here: * * https://hverkuil.home.xs4all.nl/fwht.pdf */ /* * This is a sequence of 8 bytes with the low 4 bits set to 0xf. * * This sequence cannot occur in the encoded data * * Note that these two magic values are symmetrical so endian issues here. */ #define FWHT_MAGIC1 0x4f4f4f4f #define FWHT_MAGIC2 0xffffffff #define FWHT_VERSION 2 /* Set if this is an interlaced format */ #define FWHT_FL_IS_INTERLACED BIT(0) /* Set if this is a bottom-first (NTSC) interlaced format */ #define FWHT_FL_IS_BOTTOM_FIRST BIT(1) /* Set if each 'frame' contains just one field */ #define FWHT_FL_IS_ALTERNATE BIT(2) /* * If FWHT_FL_IS_ALTERNATE was set, then this is set if this * 'frame' is the bottom field, else it is the top field. */ #define FWHT_FL_IS_BOTTOM_FIELD BIT(3) /* Set if this frame is uncompressed */ #define FWHT_FL_LUMA_IS_UNCOMPRESSED BIT(4) #define FWHT_FL_CB_IS_UNCOMPRESSED BIT(5) #define FWHT_FL_CR_IS_UNCOMPRESSED BIT(6) #define FWHT_FL_CHROMA_FULL_HEIGHT BIT(7) #define FWHT_FL_CHROMA_FULL_WIDTH BIT(8) #define FWHT_FL_ALPHA_IS_UNCOMPRESSED BIT(9) /* A 4-values flag - the number of components - 1 */ #define FWHT_FL_COMPONENTS_NUM_MSK GENMASK(17, 16) #define FWHT_FL_COMPONENTS_NUM_OFFSET 16 struct fwht_cframe_hdr { u32 magic1; u32 magic2; __be32 version; __be32 width, height; __be32 flags; __be32 colorspace; __be32 xfer_func; __be32 ycbcr_enc; __be32 quantization; __be32 size; }; struct fwht_cframe { unsigned int width, height; u16 i_frame_qp; u16 p_frame_qp; __be16 *rlc_data; s16 coeffs[8 * 8]; s16 de_coeffs[8 * 8]; s16 de_fwht[8 * 8]; u32 size; }; struct fwht_raw_frame { unsigned int width, height; unsigned int width_div; unsigned int height_div; unsigned int luma_alpha_step; unsigned int chroma_step; unsigned int components_num; u8 *luma, *cb, *cr, *alpha; }; #define FWHT_FRAME_PCODED BIT(0) #define FWHT_FRAME_UNENCODED BIT(1) #define FWHT_LUMA_UNENCODED BIT(2) #define FWHT_CB_UNENCODED BIT(3) #define FWHT_CR_UNENCODED BIT(4) #define FWHT_ALPHA_UNENCODED BIT(5) u32 fwht_encode_frame(struct fwht_raw_frame *frm, struct fwht_raw_frame *ref_frm, struct fwht_cframe *cf, bool is_intra, bool next_is_intra); void fwht_decode_frame(struct fwht_cframe *cf, struct fwht_raw_frame *ref, u32 hdr_flags, unsigned int components_num); #endif