/* * FFv1 codec * * Copyright (c) 2024 Lynne * * This file is part of FFmpeg. * * FFmpeg 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. * * FFmpeg 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 FFmpeg; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #ifndef VULKAN_FFV1_COMMON_H #define VULKAN_FFV1_COMMON_H #ifdef GOLOMB #include "ffv1_vlc.glsl" #endif #define MAX_QUANT_TABLES 8 #define MAX_CONTEXT_INPUTS 5 #define MAX_QUANT_TABLE_SIZE 256 #define MAX_QUANT_TABLE_MASK (MAX_QUANT_TABLE_SIZE - 1) layout (constant_id = 0) const int rgb_linecache = 2; layout (constant_id = 1) const bool has_crc = false; layout (constant_id = 2) const int version = 0; layout (constant_id = 3) const int quant_table_count = 0; layout (constant_id = 4) const bool has_extend_lookup = false; layout (constant_id = 5) const int rct_offset = 0; layout (constant_id = 6) const int colorspace = 0; layout (constant_id = 7) const bool transparency = false; layout (constant_id = 8) const bool planar_rgb = false; layout (constant_id = 9) const int codec_planes = 0; layout (constant_id = 10) const int color_planes = 0; layout (constant_id = 11) const int planes = 0; layout (constant_id = 12) const int bits = 0; layout (constant_id = 13) const int chroma_shift_x = 0; layout (constant_id = 14) const int chroma_shift_y = 0; const ivec2 chroma_shift = ivec2(chroma_shift_x, chroma_shift_y); /* Encoder-only */ layout (constant_id = 15) const bool force_pcm = false; layout (constant_id = 16) const bool rct_search = false; layout (constant_id = 17) const uint context_model = 0; layout (push_constant, scalar) uniform pushConstants { u8buf slice_data; bool extend_lookup[MAX_QUANT_TABLES]; uint16_t context_count[MAX_QUANT_TABLES]; ivec4 fmt_lut; u16vec2 img_size; uint plane_state_size; bool key_frame; uint32_t crcref; int micro_version; /* Encoder-only */ ivec2 sar; int pic_mode; uint slice_size_max; }; #include "rangecoder.glsl" #if !defined(RGB) #define TYPE int16_t #define VTYPE2 i16vec2 #define VTYPE3 i16vec3 #else #define TYPE int32_t #define VTYPE2 i32vec2 #define VTYPE3 i32vec3 #endif struct SliceContext { RangeCoder c; ivec2 slice_dim; ivec2 slice_pos; ivec2 slice_rct_coef; u8vec3 quant_table_idx; uint slice_coding_mode; bool slice_reset_contexts; }; #if !defined(SB_QUALI) #if (defined(ENCODE) || defined(DECODE)) #define SB_QUALI readonly #else #define SB_QUALI #endif #endif layout (set = 1, binding = 0, scalar) SB_QUALI buffer slice_ctx_buf { SliceContext slice_ctx[]; }; uint slice_coord(uint width, uint sx, uint num_h_slices, uint chroma_shift) { uint mpw = 1 << chroma_shift; uint awidth = align(width, mpw); if ((version < 4) || ((version == 4) && (micro_version < 3))) return width * sx / num_h_slices; sx = (2 * awidth * sx + num_h_slices * mpw) / (2 * num_h_slices * mpw) * mpw; if (sx == awidth) sx = width; return sx; } #if defined(ENCODE) || defined(DECODE) layout (set = 0, binding = 1, scalar) readonly uniform quant_buf { int16_t quant_table[MAX_QUANT_TABLES] [MAX_CONTEXT_INPUTS] [MAX_QUANT_TABLE_SIZE]; }; /* -1, { -1, 0 } */ int predict(int L, ivec2 top) { return mid_pred(L, L + top[1] - top[0], top[1]); } const uint32_t log2_run[41] = { 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, }; shared VTYPE2 linecache; #ifdef RGB #define RGB_LBUF (rgb_linecache - 1) #define LADDR(p) (ivec2((p).x, ((p).y & RGB_LBUF))) ivec2 get_pred(readonly uimage2D pred, ivec2 sp, ivec2 off, uint comp, int sw, uint8_t quant_table_idx, bool extend_lookup) { ivec2 yoff_border1 = expectEXT(off.x == 0, false) ? off + ivec2(1, -1) : off; /* Thanks to the same coincidence as below, we can skip checking if off == 0, 1 */ VTYPE3 top = VTYPE3(TYPE(imageLoad(pred, sp + LADDR(yoff_border1 + ivec2(-1, -1)))[comp]), TYPE(imageLoad(pred, sp + LADDR(off + ivec2(0, -1)))[comp]), TYPE(imageLoad(pred, sp + LADDR(off + ivec2(min(1, sw - off.x - 1), -1)))[comp])); /* Normally, we'd need to check if off != ivec2(0, 0) here, since otherwise, we must * return zero. However, ivec2(-1, 0) + ivec2(1, -1) == ivec2(0, -1), e.g. previous * row, 0 offset, same slice, which is zero since we zero out the buffer for RGB */ TYPE cur = linecache[1]; int base = quant_table[quant_table_idx][0][(cur - top[0]) & MAX_QUANT_TABLE_MASK] + quant_table[quant_table_idx][1][(top[0] - top[1]) & MAX_QUANT_TABLE_MASK] + quant_table[quant_table_idx][2][(top[1] - top[2]) & MAX_QUANT_TABLE_MASK]; if (has_extend_lookup && extend_lookup) { TYPE cur2 = linecache[0]; base += quant_table[quant_table_idx][3][(cur2 - cur) & MAX_QUANT_TABLE_MASK]; /* top-2 became current upon swap when rgb_linecache == 2 */ ivec2 top2_off = off; if (rgb_linecache != 2) top2_off += ivec2(0, -2); TYPE top2 = TYPE(imageLoad(pred, sp + LADDR(top2_off))[comp]); base += quant_table[quant_table_idx][4][(top2 - top[1]) & MAX_QUANT_TABLE_MASK]; } /* context, prediction */ return ivec2(base, predict(cur, VTYPE2(top))); } #else #define LADDR(p) (p) ivec2 get_pred(readonly uimage2D pred, ivec2 sp, ivec2 off, uint comp, int sw, uint8_t quant_table_idx, bool extend_lookup) { ivec2 yoff_border1 = off.x == 0 ? ivec2(1, -1) : ivec2(0, 0); sp += off; VTYPE3 top = VTYPE3(TYPE(0), TYPE(0), TYPE(0)); if (off.y > 0 && off != ivec2(0, 1)) top[0] = TYPE(imageLoad(pred, sp + ivec2(-1, -1) + yoff_border1)[comp]); if (off.y > 0) { top[1] = TYPE(imageLoad(pred, sp + ivec2(0, -1))[comp]); top[2] = TYPE(imageLoad(pred, sp + ivec2(min(1, sw - off.x - 1), -1))[comp]); } TYPE cur = linecache[1]; int base = quant_table[quant_table_idx][0][(cur - top[0]) & MAX_QUANT_TABLE_MASK] + quant_table[quant_table_idx][1][(top[0] - top[1]) & MAX_QUANT_TABLE_MASK] + quant_table[quant_table_idx][2][(top[1] - top[2]) & MAX_QUANT_TABLE_MASK]; if (has_extend_lookup && extend_lookup) { TYPE cur2 = linecache[0]; base += quant_table[quant_table_idx][3][(cur2 - cur) & MAX_QUANT_TABLE_MASK]; TYPE top2 = TYPE(0); if (off.y > 1) top2 = TYPE(imageLoad(pred, sp + ivec2(0, -2))[comp]); base += quant_table[quant_table_idx][4][(top2 - top[1]) & MAX_QUANT_TABLE_MASK]; } /* context, prediction */ return ivec2(base, predict(cur, VTYPE2(top))); } #endif /* RGB */ void linecache_load(readonly uimage2D src, ivec2 sp, int y, uint comp) { if (gl_LocalInvocationID.x == 0) { linecache[0] = TYPE(0); } else if (gl_LocalInvocationID.x == 1) { TYPE c = TYPE(0); if (y > 0) c = TYPE(imageLoad(src, sp + LADDR(ivec2(0, y - 1)))[comp]); linecache[1] = c; } barrier(); } void linecache_next(TYPE cur) { linecache[0] = linecache[1]; linecache[1] = cur; } #endif /* ENCODE || DECODE */ #endif /* VULKAN_FFV1_COMMON_H */