use crate::activity::*;
use crate::api::*;
use crate::cdef::*;
use crate::context::*;
use crate::deblock::*;
use crate::ec::*;
use crate::frame::*;
use crate::header::*;
use crate::lrf::*;
use crate::mc::{FilterMode, MotionVector};
use crate::me::*;
use crate::partition::PartitionType::*;
use crate::partition::RefType::*;
use crate::partition::*;
use crate::predict::{
AngleDelta, IntraEdgeFilterParameters, IntraParam, PredictionMode,
};
use crate::quantize::*;
use crate::rate::{
bexp64, q57, QuantizerParameters, FRAME_SUBTYPE_I, FRAME_SUBTYPE_P, QSCALE,
};
use crate::rdo::*;
use crate::segmentation::*;
use crate::serialize::{Deserialize, Serialize};
use crate::stats::EncoderStats;
use crate::tiling::*;
use crate::transform::*;
use crate::util::*;
use crate::wasm_bindgen::*;
use arg_enum_proc_macro::ArgEnum;
use arrayvec::*;
use bitstream_io::{BigEndian, BitWrite, BitWriter};
use std::collections::VecDeque;
use std::io::Write;
use std::mem::MaybeUninit;
use std::sync::Arc;
use std::{fmt, io, mem};
use crate::rayon::iter::*;
use rust_hawktracer::*;
#[allow(dead_code)]
#[derive(Debug, Clone, PartialEq)]
pub enum CDEFSearchMethod {
PickFromQ,
FastSearch,
FullSearch,
}
#[inline(always)]
fn poly2(q: f32, a: f32, b: f32, c: f32, max: i32) -> i32 {
clamp((q * q * a + q * b + c).round() as i32, 0, max)
}
pub static TEMPORAL_DELIMITER: [u8; 2] = [0x12, 0x00];
const MAX_NUM_TEMPORAL_LAYERS: usize = 8;
const MAX_NUM_SPATIAL_LAYERS: usize = 4;
const MAX_NUM_OPERATING_POINTS: usize =
MAX_NUM_TEMPORAL_LAYERS * MAX_NUM_SPATIAL_LAYERS;
pub const IMPORTANCE_BLOCK_SIZE: usize =
1 << (IMPORTANCE_BLOCK_TO_BLOCK_SHIFT + BLOCK_TO_PLANE_SHIFT);
#[derive(Debug, Clone)]
pub struct ReferenceFrame<T: Pixel> {
pub order_hint: u32,
pub width: u32,
pub height: u32,
pub render_width: u32,
pub render_height: u32,
pub frame: Arc<Frame<T>>,
pub input_hres: Arc<Plane<T>>,
pub input_qres: Arc<Plane<T>>,
pub cdfs: CDFContext,
pub frame_me_stats: Arc<[FrameMEStats; REF_FRAMES as usize]>,
pub output_frameno: u64,
pub segmentation: SegmentationState,
}
#[derive(Debug, Clone, Default)]
pub struct ReferenceFramesSet<T: Pixel> {
pub frames: [Option<Arc<ReferenceFrame<T>>>; REF_FRAMES as usize],
pub deblock: [DeblockState; REF_FRAMES as usize],
}
impl<T: Pixel> ReferenceFramesSet<T> {
pub fn new() -> Self {
Self { frames: Default::default(), deblock: Default::default() }
}
}
#[wasm_bindgen]
#[derive(ArgEnum, Copy, Clone, Debug, PartialEq, Serialize, Deserialize)]
#[repr(C)]
pub enum Tune {
Psnr,
Psychovisual,
}
impl Default for Tune {
fn default() -> Self {
Tune::Psychovisual
}
}
const FRAME_ID_LENGTH: u32 = 15;
const DELTA_FRAME_ID_LENGTH: u32 = 14;
#[derive(Copy, Clone, Debug)]
pub struct Sequence {
pub profile: u8,
pub num_bits_width: u32,
pub num_bits_height: u32,
pub bit_depth: usize,
pub chroma_sampling: ChromaSampling,
pub chroma_sample_position: ChromaSamplePosition,
pub pixel_range: PixelRange,
pub color_description: Option<ColorDescription>,
pub mastering_display: Option<MasteringDisplay>,
pub content_light: Option<ContentLight>,
pub max_frame_width: u32,
pub max_frame_height: u32,
pub frame_id_numbers_present_flag: bool,
pub frame_id_length: u32,
pub delta_frame_id_length: u32,
pub use_128x128_superblock: bool,
pub order_hint_bits_minus_1: u32,
pub force_screen_content_tools: u32,
pub force_integer_mv: u32,
pub still_picture: bool,
pub reduced_still_picture_hdr: bool,
pub enable_filter_intra: bool,
pub enable_intra_edge_filter: bool,
pub enable_interintra_compound: bool,
pub enable_masked_compound: bool,
pub enable_dual_filter: bool,
pub enable_order_hint: bool,
pub enable_jnt_comp: bool,
pub enable_ref_frame_mvs: bool,
pub enable_warped_motion: bool,
pub enable_superres: bool,
pub enable_cdef: bool,
pub enable_restoration: bool,
pub enable_large_lru: bool,
pub enable_delayed_loopfilter_rdo: bool,
pub operating_points_cnt_minus_1: usize,
pub operating_point_idc: [u16; MAX_NUM_OPERATING_POINTS],
pub display_model_info_present_flag: bool,
pub decoder_model_info_present_flag: bool,
pub level: [[usize; 2]; MAX_NUM_OPERATING_POINTS],
pub tier: [usize; MAX_NUM_OPERATING_POINTS],
pub film_grain_params_present: bool,
pub timing_info_present: bool,
pub tiling: TilingInfo,
pub time_base: Rational,
}
impl Sequence {
pub fn new(config: &EncoderConfig) -> Sequence {
let width_bits = 32 - (config.width as u32).leading_zeros();
let height_bits = 32 - (config.height as u32).leading_zeros();
assert!(width_bits <= 16);
assert!(height_bits <= 16);
let profile = if config.bit_depth == 12
|| config.chroma_sampling == ChromaSampling::Cs422
{
2
} else if config.chroma_sampling == ChromaSampling::Cs444 {
1
} else {
0
};
let mut operating_point_idc: [u16; MAX_NUM_OPERATING_POINTS] =
[0; MAX_NUM_OPERATING_POINTS];
let mut level: [[usize; 2]; MAX_NUM_OPERATING_POINTS] =
[[1, 2]; MAX_NUM_OPERATING_POINTS];
let mut tier: [usize; MAX_NUM_OPERATING_POINTS] =
[0; MAX_NUM_OPERATING_POINTS];
for i in 0..MAX_NUM_OPERATING_POINTS {
operating_point_idc[i] = 0;
level[i][0] = 1;
level[i][1] = 2;
tier[i] = 0;
}
let enable_restoration_filters = config.width >= 32 && config.height >= 32;
let use_128x128_superblock = false;
let frame_rate = config.frame_rate();
let sb_size_log2 = Self::sb_size_log2(use_128x128_superblock);
let mut tiling = TilingInfo::from_target_tiles(
sb_size_log2,
config.width,
config.height,
frame_rate,
TilingInfo::tile_log2(1, config.tile_cols).unwrap(),
TilingInfo::tile_log2(1, config.tile_rows).unwrap(),
config.chroma_sampling == ChromaSampling::Cs422,
);
if config.tiles > 0 {
let mut tile_rows_log2 = 0;
let mut tile_cols_log2 = 0;
while (tile_rows_log2 < tiling.max_tile_rows_log2)
|| (tile_cols_log2 < tiling.max_tile_cols_log2)
{
tiling = TilingInfo::from_target_tiles(
sb_size_log2,
config.width,
config.height,
frame_rate,
tile_cols_log2,
tile_rows_log2,
config.chroma_sampling == ChromaSampling::Cs422,
);
if tiling.rows * tiling.cols >= config.tiles {
break;
};
if ((tiling.tile_height_sb >= tiling.tile_width_sb)
&& (tiling.tile_rows_log2 < tiling.max_tile_rows_log2))
|| (tile_cols_log2 >= tiling.max_tile_cols_log2)
{
tile_rows_log2 += 1;
} else {
tile_cols_log2 += 1;
}
}
}
Sequence {
tiling,
profile,
num_bits_width: width_bits,
num_bits_height: height_bits,
bit_depth: config.bit_depth,
chroma_sampling: config.chroma_sampling,
chroma_sample_position: config.chroma_sample_position,
pixel_range: config.pixel_range,
color_description: config.color_description,
mastering_display: config.mastering_display,
content_light: config.content_light,
max_frame_width: config.width as u32,
max_frame_height: config.height as u32,
frame_id_numbers_present_flag: false,
frame_id_length: FRAME_ID_LENGTH,
delta_frame_id_length: DELTA_FRAME_ID_LENGTH,
use_128x128_superblock,
order_hint_bits_minus_1: 5,
force_screen_content_tools: if config.still_picture { 2 } else { 0 },
force_integer_mv: 2,
still_picture: config.still_picture,
reduced_still_picture_hdr: config.still_picture,
enable_filter_intra: false,
enable_intra_edge_filter: true,
enable_interintra_compound: false,
enable_masked_compound: false,
enable_dual_filter: false,
enable_order_hint: !config.still_picture,
enable_jnt_comp: false,
enable_ref_frame_mvs: false,
enable_warped_motion: false,
enable_superres: false,
enable_cdef: config.speed_settings.cdef && enable_restoration_filters,
enable_restoration: config.speed_settings.lrf
&& enable_restoration_filters,
enable_large_lru: true,
enable_delayed_loopfilter_rdo: true,
operating_points_cnt_minus_1: 0,
operating_point_idc,
display_model_info_present_flag: false,
decoder_model_info_present_flag: false,
level,
tier,
film_grain_params_present: false,
timing_info_present: config.enable_timing_info,
time_base: config.time_base,
}
}
pub const fn get_relative_dist(&self, a: u32, b: u32) -> i32 {
let diff = a as i32 - b as i32;
let m = 1 << self.order_hint_bits_minus_1;
(diff & (m - 1)) - (diff & m)
}
pub fn get_skip_mode_allowed<T: Pixel>(
&self, fi: &FrameInvariants<T>, inter_cfg: &InterConfig,
reference_select: bool,
) -> bool {
if fi.intra_only || !reference_select || !self.enable_order_hint {
return false;
}
let mut forward_idx: isize = -1;
let mut backward_idx: isize = -1;
let mut forward_hint = 0;
let mut backward_hint = 0;
for i in inter_cfg.allowed_ref_frames().iter().map(|rf| rf.to_index()) {
if let Some(ref rec) = fi.rec_buffer.frames[fi.ref_frames[i] as usize] {
let ref_hint = rec.order_hint;
if self.get_relative_dist(ref_hint, fi.order_hint) < 0 {
if forward_idx < 0
|| self.get_relative_dist(ref_hint, forward_hint) > 0
{
forward_idx = i as isize;
forward_hint = ref_hint;
}
} else if self.get_relative_dist(ref_hint, fi.order_hint) > 0
&& (backward_idx < 0
|| self.get_relative_dist(ref_hint, backward_hint) > 0)
{
backward_idx = i as isize;
backward_hint = ref_hint;
}
}
}
if forward_idx < 0 {
false
} else if backward_idx >= 0 {
true
} else {
let mut second_forward_idx: isize = -1;
let mut second_forward_hint = 0;
for i in inter_cfg.allowed_ref_frames().iter().map(|rf| rf.to_index()) {
if let Some(ref rec) = fi.rec_buffer.frames[fi.ref_frames[i] as usize]
{
let ref_hint = rec.order_hint;
if self.get_relative_dist(ref_hint, forward_hint) < 0
&& (second_forward_idx < 0
|| self.get_relative_dist(ref_hint, second_forward_hint) > 0)
{
second_forward_idx = i as isize;
second_forward_hint = ref_hint;
}
}
}
second_forward_idx >= 0
}
}
#[inline(always)]
const fn sb_size_log2(use_128x128_superblock: bool) -> usize {
6 + (use_128x128_superblock as usize)
}
}
#[derive(Debug, Clone)]
pub struct FrameState<T: Pixel> {
pub sb_size_log2: usize,
pub input: Arc<Frame<T>>,
pub input_hres: Arc<Plane<T>>,
pub input_qres: Arc<Plane<T>>,
pub rec: Arc<Frame<T>>,
pub cdfs: CDFContext,
pub context_update_tile_id: usize,
pub max_tile_size_bytes: u32,
pub deblock: DeblockState,
pub segmentation: SegmentationState,
pub restoration: RestorationState,
pub frame_me_stats: Arc<[FrameMEStats; REF_FRAMES as usize]>,
pub enc_stats: EncoderStats,
}
impl<T: Pixel> FrameState<T> {
pub fn new(fi: &FrameInvariants<T>) -> Self {
FrameState::new_with_frame(
fi,
Arc::new(Frame::new(fi.width, fi.height, fi.sequence.chroma_sampling)),
)
}
pub fn new_with_frame(
fi: &FrameInvariants<T>, frame: Arc<Frame<T>>,
) -> Self {
let rs = RestorationState::new(fi, &frame);
let luma_width = frame.planes[0].cfg.width;
let luma_height = frame.planes[0].cfg.height;
let hres = frame.planes[0].downsampled(fi.width, fi.height);
let qres = hres.downsampled(fi.width, fi.height);
Self {
sb_size_log2: fi.sb_size_log2(),
input: frame,
input_hres: Arc::new(hres),
input_qres: Arc::new(qres),
rec: Arc::new(Frame::new(
luma_width,
luma_height,
fi.sequence.chroma_sampling,
)),
cdfs: CDFContext::new(0),
context_update_tile_id: 0,
max_tile_size_bytes: 0,
deblock: Default::default(),
segmentation: Default::default(),
restoration: rs,
frame_me_stats: FrameMEStats::new_arc_array(fi.w_in_b, fi.h_in_b),
enc_stats: Default::default(),
}
}
#[inline(always)]
pub fn as_tile_state_mut(&mut self) -> TileStateMut<'_, T> {
let PlaneConfig { width, height, .. } = self.rec.planes[0].cfg;
let sbo_0 = PlaneSuperBlockOffset(SuperBlockOffset { x: 0, y: 0 });
TileStateMut::new(self, sbo_0, self.sb_size_log2, width, height)
}
}
#[derive(Copy, Clone, Debug)]
pub struct DeblockState {
pub levels: [u8; MAX_PLANES + 1],
pub sharpness: u8,
pub deltas_enabled: bool,
pub delta_updates_enabled: bool,
pub ref_deltas: [i8; REF_FRAMES],
pub mode_deltas: [i8; 2],
pub block_deltas_enabled: bool,
pub block_delta_shift: u8,
pub block_delta_multi: bool,
}
impl Default for DeblockState {
fn default() -> Self {
DeblockState {
levels: [8, 8, 4, 4],
sharpness: 0,
deltas_enabled: false,
delta_updates_enabled: false,
ref_deltas: [1, 0, 0, 0, 0, -1, -1, -1],
mode_deltas: [0, 0],
block_deltas_enabled: false,
block_delta_shift: 0,
block_delta_multi: false,
}
}
}
#[derive(Copy, Clone, Debug)]
pub struct SegmentationState {
pub enabled: bool,
pub update_data: bool,
pub update_map: bool,
pub preskip: bool,
pub last_active_segid: u8,
pub features: [[bool; SegLvl::SEG_LVL_MAX as usize]; 8],
pub data: [[i16; SegLvl::SEG_LVL_MAX as usize]; 8],
}
impl Default for SegmentationState {
fn default() -> Self {
SegmentationState {
enabled: false,
update_data: false,
update_map: false,
preskip: false,
last_active_segid: 0,
features: [[false; SegLvl::SEG_LVL_MAX as usize]; 8],
data: [[0; SegLvl::SEG_LVL_MAX as usize]; 8],
}
}
}
#[allow(dead_code)]
#[derive(Debug, Clone)]
pub struct FrameInvariants<T: Pixel> {
pub sequence: Arc<Sequence>,
pub config: Arc<EncoderConfig>,
pub width: usize,
pub height: usize,
pub render_width: u32,
pub render_height: u32,
pub frame_size_override_flag: bool,
pub render_and_frame_size_different: bool,
pub sb_width: usize,
pub sb_height: usize,
pub w_in_b: usize,
pub h_in_b: usize,
pub input_frameno: u64,
pub order_hint: u32,
pub show_frame: bool,
pub showable_frame: bool,
pub error_resilient: bool,
pub intra_only: bool,
pub allow_high_precision_mv: bool,
pub frame_type: FrameType,
pub show_existing_frame: bool,
pub frame_to_show_map_idx: u32,
pub use_reduced_tx_set: bool,
pub reference_mode: ReferenceMode,
pub use_prev_frame_mvs: bool,
pub partition_range: PartitionRange,
pub globalmv_transformation_type: [GlobalMVMode; INTER_REFS_PER_FRAME],
pub num_tg: usize,
pub large_scale_tile: bool,
pub disable_cdf_update: bool,
pub allow_screen_content_tools: u32,
pub force_integer_mv: u32,
pub primary_ref_frame: u32,
pub refresh_frame_flags: u32,
pub allow_intrabc: bool,
pub use_ref_frame_mvs: bool,
pub is_filter_switchable: bool,
pub is_motion_mode_switchable: bool,
pub disable_frame_end_update_cdf: bool,
pub allow_warped_motion: bool,
pub cdef_search_method: CDEFSearchMethod,
pub cdef_damping: u8,
pub cdef_bits: u8,
pub cdef_y_strengths: [u8; 8],
pub cdef_uv_strengths: [u8; 8],
pub delta_q_present: bool,
pub ref_frames: [u8; INTER_REFS_PER_FRAME],
pub ref_frame_sign_bias: [bool; INTER_REFS_PER_FRAME],
pub rec_buffer: ReferenceFramesSet<T>,
pub base_q_idx: u8,
pub dc_delta_q: [i8; 3],
pub ac_delta_q: [i8; 3],
pub lambda: f64,
pub me_lambda: f64,
pub dist_scale: [f64; 3],
pub me_range_scale: u8,
pub use_tx_domain_distortion: bool,
pub use_tx_domain_rate: bool,
pub idx_in_group_output: u64,
pub pyramid_level: u64,
pub enable_early_exit: bool,
pub tx_mode_select: bool,
pub enable_inter_txfm_split: bool,
pub default_filter: FilterMode,
pub invalid: bool,
pub lookahead_me_stats: Arc<[FrameMEStats; REF_FRAMES as usize]>,
pub lookahead_rec_buffer: ReferenceFramesSet<T>,
pub w_in_imp_b: usize,
pub h_in_imp_b: usize,
pub lookahead_intra_costs: Box<[u32]>,
pub block_importances: Box<[f32]>,
pub distortion_scales: Box<[DistortionScale]>,
pub cpu_feature_level: crate::cpu_features::CpuFeatureLevel,
pub activity_mask: ActivityMask,
pub enable_segmentation: bool,
}
pub(crate) const fn pos_to_lvl(pos: u64, pyramid_depth: u64) -> u64 {
pyramid_depth - (pos | (1 << pyramid_depth)).trailing_zeros() as u64
}
impl<T: Pixel> FrameInvariants<T> {
#[allow(clippy::erasing_op, clippy::identity_op)]
pub fn new(config: Arc<EncoderConfig>, sequence: Arc<Sequence>) -> Self {
assert!(
sequence.bit_depth <= mem::size_of::<T>() * 8,
"bit depth cannot fit into u8"
);
let (width, height) = (config.width, config.height);
let frame_size_override_flag = width as u32 != sequence.max_frame_width
|| height as u32 != sequence.max_frame_height;
let (render_width, render_height) = config.render_size();
let render_and_frame_size_different =
render_width != width || render_height != height;
let use_reduced_tx_set = config.speed_settings.reduced_tx_set;
let use_tx_domain_distortion =
config.tune == Tune::Psnr && config.speed_settings.tx_domain_distortion;
let use_tx_domain_rate = config.speed_settings.tx_domain_rate;
let w_in_b = 2 * config.width.align_power_of_two_and_shift(3);
let h_in_b = 2 * config.height.align_power_of_two_and_shift(3);
let w_in_imp_b = w_in_b / 2;
let h_in_imp_b = h_in_b / 2;
Self {
width,
height,
render_width: render_width as u32,
render_height: render_height as u32,
frame_size_override_flag,
render_and_frame_size_different,
sb_width: width.align_power_of_two_and_shift(6),
sb_height: height.align_power_of_two_and_shift(6),
w_in_b,
h_in_b,
input_frameno: 0,
order_hint: 0,
show_frame: true,
showable_frame: !sequence.reduced_still_picture_hdr,
error_resilient: false,
intra_only: true,
allow_high_precision_mv: false,
frame_type: FrameType::KEY,
show_existing_frame: false,
frame_to_show_map_idx: 0,
use_reduced_tx_set,
reference_mode: ReferenceMode::SINGLE,
use_prev_frame_mvs: false,
partition_range: config.speed_settings.partition_range,
globalmv_transformation_type: [GlobalMVMode::IDENTITY;
INTER_REFS_PER_FRAME],
num_tg: 1,
large_scale_tile: false,
disable_cdf_update: false,
allow_screen_content_tools: sequence.force_screen_content_tools,
force_integer_mv: 1,
primary_ref_frame: PRIMARY_REF_NONE,
refresh_frame_flags: ALL_REF_FRAMES_MASK,
allow_intrabc: false,
use_ref_frame_mvs: false,
is_filter_switchable: false,
is_motion_mode_switchable: false,
disable_frame_end_update_cdf: sequence.reduced_still_picture_hdr,
allow_warped_motion: false,
cdef_search_method: CDEFSearchMethod::PickFromQ,
cdef_damping: 3,
cdef_bits: 0,
cdef_y_strengths: [
0 * 4 + 0,
1 * 4 + 0,
2 * 4 + 1,
3 * 4 + 1,
5 * 4 + 2,
7 * 4 + 3,
10 * 4 + 3,
13 * 4 + 3,
],
cdef_uv_strengths: [
0 * 4 + 0,
1 * 4 + 0,
2 * 4 + 1,
3 * 4 + 1,
5 * 4 + 2,
7 * 4 + 3,
10 * 4 + 3,
13 * 4 + 3,
],
delta_q_present: false,
ref_frames: [0; INTER_REFS_PER_FRAME],
ref_frame_sign_bias: [false; INTER_REFS_PER_FRAME],
rec_buffer: ReferenceFramesSet::new(),
base_q_idx: config.quantizer as u8,
dc_delta_q: [0; 3],
ac_delta_q: [0; 3],
lambda: 0.0,
dist_scale: [1.0; 3],
me_lambda: 0.0,
me_range_scale: 1,
use_tx_domain_distortion,
use_tx_domain_rate,
idx_in_group_output: 0,
pyramid_level: 0,
enable_early_exit: true,
tx_mode_select: false,
default_filter: FilterMode::REGULAR,
invalid: false,
lookahead_me_stats: FrameMEStats::new_arc_array(w_in_b, h_in_b),
lookahead_rec_buffer: ReferenceFramesSet::new(),
w_in_imp_b,
h_in_imp_b,
lookahead_intra_costs: Box::new([]),
block_importances: vec![0.; w_in_imp_b * h_in_imp_b].into_boxed_slice(),
distortion_scales: vec![
DistortionScale::default();
w_in_imp_b * h_in_imp_b
]
.into_boxed_slice(),
cpu_feature_level: Default::default(),
activity_mask: Default::default(),
enable_segmentation: config.speed_settings.enable_segmentation,
enable_inter_txfm_split: config.speed_settings.enable_inter_tx_split,
sequence,
config,
}
}
pub fn new_key_frame(
config: Arc<EncoderConfig>, sequence: Arc<Sequence>,
gop_input_frameno_start: u64,
) -> Self {
let tx_mode_select = config.speed_settings.rdo_tx_decision;
let mut fi = Self::new(config, sequence);
fi.input_frameno = gop_input_frameno_start;
fi.tx_mode_select = tx_mode_select;
fi
}
pub(crate) fn new_inter_frame(
previous_fi: &Self, inter_cfg: &InterConfig, gop_input_frameno_start: u64,
output_frameno_in_gop: u64, next_keyframe_input_frameno: u64,
error_resilient: bool,
) -> Self {
let mut fi = previous_fi.clone();
fi.intra_only = false;
fi.force_integer_mv = 0;
fi.idx_in_group_output =
inter_cfg.get_idx_in_group_output(output_frameno_in_gop);
fi.tx_mode_select = fi.enable_inter_txfm_split;
fi.order_hint =
inter_cfg.get_order_hint(output_frameno_in_gop, fi.idx_in_group_output);
let input_frameno = inter_cfg
.get_input_frameno(output_frameno_in_gop, gop_input_frameno_start);
if input_frameno >= next_keyframe_input_frameno {
fi.frame_type = FrameType::INTER;
fi.show_existing_frame = false;
fi.show_frame = false;
fi.invalid = true;
return fi;
} else {
fi.invalid = false;
}
fi.pyramid_level = inter_cfg.get_level(fi.idx_in_group_output);
fi.frame_type = if (inter_cfg.switch_frame_interval > 0)
&& (output_frameno_in_gop % inter_cfg.switch_frame_interval == 0)
&& (fi.pyramid_level == 0)
{
FrameType::SWITCH
} else {
FrameType::INTER
};
fi.error_resilient =
if fi.frame_type == FrameType::SWITCH { true } else { error_resilient };
fi.frame_size_override_flag = if fi.frame_type == FrameType::SWITCH {
true
} else if fi.sequence.reduced_still_picture_hdr {
false
} else if fi.frame_type == FrameType::INTER
&& !fi.error_resilient
&& fi.render_and_frame_size_different
{
true
} else {
fi.width as u32 != fi.sequence.max_frame_width
|| fi.height as u32 != fi.sequence.max_frame_height
};
let slot_idx = inter_cfg.get_slot_idx(fi.pyramid_level, fi.order_hint);
fi.show_frame = inter_cfg.get_show_frame(fi.idx_in_group_output);
fi.show_existing_frame =
inter_cfg.get_show_existing_frame(fi.idx_in_group_output);
fi.frame_to_show_map_idx = slot_idx;
fi.refresh_frame_flags = if fi.frame_type == FrameType::SWITCH {
ALL_REF_FRAMES_MASK
} else if fi.show_existing_frame {
0
} else {
1 << slot_idx
};
let second_ref_frame =
if fi.idx_in_group_output == 0 { LAST2_FRAME } else { ALTREF_FRAME };
let ref_in_previous_group = LAST3_FRAME;
fi.primary_ref_frame = if fi.error_resilient || (fi.pyramid_level > 2) {
PRIMARY_REF_NONE
} else {
(ref_in_previous_group.to_index()) as u32
};
if fi.pyramid_level == 0 {
fi.ref_frames = [
(slot_idx + 4 - 1) as u8 % 4
; INTER_REFS_PER_FRAME];
if inter_cfg.multiref {
fi.ref_frames[second_ref_frame.to_index()] =
(slot_idx + 4 - 2) as u8 % 4;
}
} else {
debug_assert!(inter_cfg.multiref);
fi.ref_frames = [{
let oh = fi.order_hint
- (inter_cfg.group_input_len as u32 >> fi.pyramid_level);
let lvl1 = pos_to_lvl(oh as u64, inter_cfg.pyramid_depth);
if lvl1 == 0 {
((oh >> inter_cfg.pyramid_depth) % 4) as u8
} else {
3 + lvl1 as u8
}
}; INTER_REFS_PER_FRAME];
fi.ref_frames[second_ref_frame.to_index()] = {
let oh = fi.order_hint
+ (inter_cfg.group_input_len as u32 >> fi.pyramid_level);
let lvl2 = pos_to_lvl(oh as u64, inter_cfg.pyramid_depth);
if lvl2 == 0 {
((oh >> inter_cfg.pyramid_depth) % 4) as u8
} else {
3 + lvl2 as u8
}
};
fi.ref_frames[ref_in_previous_group.to_index()] = slot_idx as u8;
}
fi.set_ref_frame_sign_bias();
fi.reference_mode = if inter_cfg.multiref && fi.idx_in_group_output != 0 {
ReferenceMode::SELECT
} else {
ReferenceMode::SINGLE
};
fi.input_frameno = input_frameno;
fi.me_range_scale = (inter_cfg.group_input_len >> fi.pyramid_level) as u8;
fi
}
pub fn set_ref_frame_sign_bias(&mut self) {
for i in 0..INTER_REFS_PER_FRAME {
self.ref_frame_sign_bias[i] = if !self.sequence.enable_order_hint {
false
} else if let Some(ref rec) =
self.rec_buffer.frames[self.ref_frames[i] as usize]
{
let hint = rec.order_hint;
self.sequence.get_relative_dist(hint, self.order_hint) > 0
} else {
false
};
}
}
pub fn get_frame_subtype(&self) -> usize {
if self.frame_type == FrameType::KEY {
FRAME_SUBTYPE_I
} else {
FRAME_SUBTYPE_P + (self.pyramid_level as usize)
}
}
fn pick_strength_from_q(&mut self, qps: &QuantizerParameters) {
self.cdef_damping = 3 + (self.base_q_idx >> 6);
let q = bexp64(qps.log_target_q as i64 + q57(QSCALE)) as f32;
let (y_f1, y_f2, uv_f1, uv_f2) = if !self.intra_only {
(
poly2(q, -0.0000023593946_f32, 0.0068615186_f32, 0.02709886_f32, 15),
poly2(q, -0.00000057629734_f32, 0.0013993345_f32, 0.03831067_f32, 3),
poly2(q, -0.0000007095069_f32, 0.0034628846_f32, 0.00887099_f32, 15),
poly2(q, 0.00000023874085_f32, 0.00028223585_f32, 0.05576307_f32, 3),
)
} else {
(
poly2(q, 0.0000033731974_f32, 0.008070594_f32, 0.0187634_f32, 15),
poly2(q, 0.0000029167343_f32, 0.0027798624_f32, 0.0079405_f32, 3),
poly2(q, -0.0000130790995_f32, 0.012892405_f32, -0.00748388_f32, 15),
poly2(q, 0.0000032651783_f32, 0.00035520183_f32, 0.00228092_f32, 3),
)
};
self.cdef_y_strengths[0] = (y_f1 * CDEF_SEC_STRENGTHS as i32 + y_f2) as u8;
self.cdef_uv_strengths[0] =
(uv_f1 * CDEF_SEC_STRENGTHS as i32 + uv_f2) as u8;
}
pub fn set_quantizers(&mut self, qps: &QuantizerParameters) {
self.base_q_idx = qps.ac_qi[0];
let base_q_idx = self.base_q_idx as i32;
for pi in 0..3 {
self.dc_delta_q[pi] = (qps.dc_qi[pi] as i32 - base_q_idx) as i8;
self.ac_delta_q[pi] = (qps.ac_qi[pi] as i32 - base_q_idx) as i8;
}
self.lambda =
qps.lambda * ((1 << (2 * (self.sequence.bit_depth - 8))) as f64);
self.me_lambda = self.lambda.sqrt();
self.dist_scale = qps.dist_scale;
match self.cdef_search_method {
CDEFSearchMethod::PickFromQ => {
self.pick_strength_from_q(qps);
}
_ => unreachable!(),
}
}
#[inline(always)]
pub fn sb_size_log2(&self) -> usize {
self.sequence.tiling.sb_size_log2
}
}
impl<T: Pixel> fmt::Display for FrameInvariants<T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "Input Frame {} - {}", self.input_frameno, self.frame_type)
}
}
pub fn write_temporal_delimiter(packet: &mut dyn io::Write) -> io::Result<()> {
packet.write_all(&TEMPORAL_DELIMITER)?;
Ok(())
}
fn write_key_frame_obus<T: Pixel>(
packet: &mut dyn io::Write, fi: &FrameInvariants<T>, obu_extension: u32,
) -> io::Result<()> {
let mut buf1 = Vec::new();
let mut buf2 = Vec::new();
{
let mut bw2 = BitWriter::endian(&mut buf2, BigEndian);
bw2.write_sequence_header_obu(fi)?;
bw2.write_bit(true)?;
bw2.byte_align()?;
}
{
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_obu_header(ObuType::OBU_SEQUENCE_HEADER, obu_extension)?;
}
packet.write_all(&buf1).unwrap();
buf1.clear();
{
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_uleb128(buf2.len() as u64)?;
}
packet.write_all(&buf1).unwrap();
buf1.clear();
packet.write_all(&buf2).unwrap();
buf2.clear();
if fi.sequence.content_light.is_some() {
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_metadata_obu(ObuMetaType::OBU_META_HDR_CLL, &fi.sequence)?;
packet.write_all(&buf1).unwrap();
buf1.clear();
}
if fi.sequence.mastering_display.is_some() {
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_metadata_obu(ObuMetaType::OBU_META_HDR_MDCV, &fi.sequence)?;
packet.write_all(&buf1).unwrap();
buf1.clear();
}
Ok(())
}
fn diff<T: Pixel>(
dst: &mut [i16], src1: &PlaneRegion<'_, T>, src2: &PlaneRegion<'_, T>,
width: usize, height: usize,
) {
for ((l, s1), s2) in dst
.chunks_mut(width)
.take(height)
.zip(src1.rows_iter())
.zip(src2.rows_iter())
{
for ((r, v1), v2) in l.iter_mut().zip(s1).zip(s2) {
*r = i16::cast_from(*v1) - i16::cast_from(*v2);
}
}
}
fn get_qidx<T: Pixel>(
fi: &FrameInvariants<T>, ts: &TileStateMut<'_, T>, cw: &ContextWriter,
tile_bo: TileBlockOffset,
) -> u8 {
let mut qidx = fi.base_q_idx;
let sidx = cw.bc.blocks[tile_bo].segmentation_idx as usize;
if ts.segmentation.features[sidx][SegLvl::SEG_LVL_ALT_Q as usize] {
let delta = ts.segmentation.data[sidx][SegLvl::SEG_LVL_ALT_Q as usize];
qidx = clamp((qidx as i16) + delta, 0, 255) as u8;
}
qidx
}
pub fn encode_tx_block<T: Pixel>(
fi: &FrameInvariants<T>,
ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter,
w: &mut dyn Writer,
p: usize,
tile_partition_bo: TileBlockOffset,
bx: usize,
by: usize,
tx_bo: TileBlockOffset,
mode: PredictionMode,
tx_size: TxSize,
tx_type: TxType,
bsize: BlockSize,
po: PlaneOffset,
skip: bool,
qidx: u8,
ac: &[i16],
pred_intra_param: IntraParam,
rdo_type: RDOType,
need_recon_pixel: bool,
) -> (bool, ScaledDistortion) {
let PlaneConfig { xdec, ydec, .. } = ts.input.planes[p].cfg;
let tile_rect = ts.tile_rect().decimated(xdec, ydec);
let area = Area::BlockStartingAt { bo: tx_bo.0 };
if tx_bo.0.x >= ts.mi_width || tx_bo.0.y >= ts.mi_height {
return (false, ScaledDistortion::zero());
}
debug_assert!(tx_bo.0.x < ts.mi_width);
debug_assert!(tx_bo.0.y < ts.mi_height);
debug_assert!(
tx_size.sqr() <= TxSize::TX_32X32 || tx_type == TxType::DCT_DCT
);
let plane_bsize = bsize.subsampled_size(xdec, ydec);
debug_assert!(p != 0 || !mode.is_intra() || tx_size.block_size() == plane_bsize || need_recon_pixel,
"mode.is_intra()={:#?}, plane={:#?}, tx_size.block_size()={:#?}, plane_bsize={:#?}, need_recon_pixel={:#?}",
mode.is_intra(), p, tx_size.block_size(), plane_bsize, need_recon_pixel);
let ief_params = if mode.is_directional()
&& fi.sequence.enable_intra_edge_filter
{
let (plane_xdec, plane_ydec) = if p == 0 { (0, 0) } else { (xdec, ydec) };
let above_block_info =
ts.above_block_info(tile_partition_bo, plane_xdec, plane_ydec);
let left_block_info =
ts.left_block_info(tile_partition_bo, plane_xdec, plane_ydec);
Some(IntraEdgeFilterParameters::new(p, above_block_info, left_block_info))
} else {
None
};
let frame_bo = ts.to_frame_block_offset(tx_bo);
let rec = &mut ts.rec.planes[p];
if mode.is_intra() {
let bit_depth = fi.sequence.bit_depth;
let edge_buf = get_intra_edges(
&rec.as_const(),
tile_partition_bo,
bx,
by,
bsize,
po,
tx_size,
bit_depth,
Some(mode),
fi.sequence.enable_intra_edge_filter,
pred_intra_param,
);
mode.predict_intra(
tile_rect,
&mut rec.subregion_mut(area),
tx_size,
bit_depth,
ac,
pred_intra_param,
ief_params,
&edge_buf,
fi.cpu_feature_level,
);
}
if skip {
return (false, ScaledDistortion::zero());
}
let coded_tx_area = av1_get_coded_tx_size(tx_size).area();
let mut residual_storage: Aligned<[i16; 64 * 64]> = Aligned::uninitialized();
let mut coeffs_storage: Aligned<[T::Coeff; 64 * 64]> =
Aligned::uninitialized();
let mut qcoeffs_storage: Aligned<[MaybeUninit<T::Coeff>; 32 * 32]> =
Aligned::uninitialized();
let mut rcoeffs_storage: Aligned<[T::Coeff; 32 * 32]> =
Aligned::uninitialized();
let residual = &mut residual_storage.data[..tx_size.area()];
let coeffs = &mut coeffs_storage.data[..tx_size.area()];
let qcoeffs = init_slice_repeat_mut(
&mut qcoeffs_storage.data[..coded_tx_area],
T::Coeff::cast_from(0),
);
let rcoeffs = &mut rcoeffs_storage.data[..coded_tx_area];
let (visible_tx_w, visible_tx_h) = clip_visible_bsize(
fi.width >> xdec,
fi.height >> ydec,
tx_size.block_size(),
(frame_bo.0.x << MI_SIZE_LOG2) >> xdec,
(frame_bo.0.y << MI_SIZE_LOG2) >> ydec,
);
if visible_tx_w != 0 && visible_tx_h != 0 {
diff(
residual,
&ts.input_tile.planes[p].subregion(area),
&rec.subregion(area),
visible_tx_w,
visible_tx_h,
);
}
let visible_area = visible_tx_w * visible_tx_h;
for a in residual[visible_area..].iter_mut() {
*a = 0;
}
forward_transform(
residual,
coeffs,
tx_size.width(),
tx_size,
tx_type,
fi.sequence.bit_depth,
fi.cpu_feature_level,
);
let eob = ts.qc.quantize(coeffs, qcoeffs, tx_size, tx_type);
let has_coeff = if need_recon_pixel || rdo_type.needs_coeff_rate() {
debug_assert!((((fi.w_in_b - frame_bo.0.x) << MI_SIZE_LOG2) >> xdec) >= 4);
debug_assert!((((fi.h_in_b - frame_bo.0.y) << MI_SIZE_LOG2) >> ydec) >= 4);
let frame_clipped_txw: usize =
(((fi.w_in_b - frame_bo.0.x) << MI_SIZE_LOG2) >> xdec)
.min(tx_size.width());
let frame_clipped_txh: usize =
(((fi.h_in_b - frame_bo.0.y) << MI_SIZE_LOG2) >> ydec)
.min(tx_size.height());
cw.write_coeffs_lv_map(
w,
p,
tx_bo,
qcoeffs,
eob,
mode,
tx_size,
tx_type,
plane_bsize,
xdec,
ydec,
fi.use_reduced_tx_set,
frame_clipped_txw,
frame_clipped_txh,
)
} else {
true
};
dequantize(
qidx,
qcoeffs,
eob,
rcoeffs,
tx_size,
fi.sequence.bit_depth,
fi.dc_delta_q[p],
fi.ac_delta_q[p],
fi.cpu_feature_level,
);
if !fi.use_tx_domain_distortion || need_recon_pixel {
inverse_transform_add(
rcoeffs,
&mut rec.subregion_mut(area),
eob,
tx_size,
tx_type,
fi.sequence.bit_depth,
fi.cpu_feature_level,
);
}
let tx_dist =
if rdo_type.needs_tx_dist() && visible_tx_w != 0 && visible_tx_h != 0 {
let mut raw_tx_dist = coeffs
.iter()
.zip(rcoeffs.iter())
.map(|(&a, &b)| {
let c = i32::cast_from(a) - i32::cast_from(b);
(c * c) as u64
})
.sum::<u64>()
+ coeffs[rcoeffs.len()..]
.iter()
.map(|&a| {
let c = i32::cast_from(a);
(c * c) as u64
})
.sum::<u64>();
let tx_dist_scale_bits = 2 * (3 - get_log_tx_scale(tx_size));
let tx_dist_scale_rounding_offset = 1 << (tx_dist_scale_bits - 1);
raw_tx_dist =
(raw_tx_dist + tx_dist_scale_rounding_offset) >> tx_dist_scale_bits;
if rdo_type == RDOType::TxDistEstRate {
let estimated_rate =
estimate_rate(fi.base_q_idx, tx_size, raw_tx_dist);
w.add_bits_frac(estimated_rate as u32);
}
let bias = distortion_scale(fi, ts.to_frame_block_offset(tx_bo), bsize);
RawDistortion::new(raw_tx_dist) * bias * fi.dist_scale[p]
} else {
ScaledDistortion::zero()
};
(has_coeff, tx_dist)
}
pub fn motion_compensate<T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, luma_mode: PredictionMode, ref_frames: [RefType; 2],
mvs: [MotionVector; 2], bsize: BlockSize, tile_bo: TileBlockOffset,
luma_only: bool,
) {
debug_assert!(!luma_mode.is_intra());
let PlaneConfig { xdec: u_xdec, ydec: u_ydec, .. } = ts.input.planes[1].cfg;
let num_planes = 1
+ if !luma_only
&& has_chroma(
tile_bo,
bsize,
u_xdec,
u_ydec,
fi.sequence.chroma_sampling,
) {
2
} else {
0
};
let luma_tile_rect = ts.tile_rect();
let compound_buffer = &mut ts.inter_compound_buffers;
for p in 0..num_planes {
let plane_bsize =
if p == 0 { bsize } else { bsize.subsampled_size(u_xdec, u_ydec) };
let rec = &mut ts.rec.planes[p];
let po = tile_bo.plane_offset(rec.plane_cfg);
let &PlaneConfig { xdec, ydec, .. } = rec.plane_cfg;
let tile_rect = luma_tile_rect.decimated(xdec, ydec);
let area = Area::BlockStartingAt { bo: tile_bo.0 };
if p > 0 && bsize < BlockSize::BLOCK_8X8 {
let mut some_use_intra = false;
if bsize == BlockSize::BLOCK_4X4 || bsize == BlockSize::BLOCK_4X8 {
some_use_intra |=
cw.bc.blocks[tile_bo.with_offset(-1, 0)].mode.is_intra();
};
if !some_use_intra && bsize == BlockSize::BLOCK_4X4
|| bsize == BlockSize::BLOCK_8X4
{
some_use_intra |=
cw.bc.blocks[tile_bo.with_offset(0, -1)].mode.is_intra();
};
if !some_use_intra && bsize == BlockSize::BLOCK_4X4 {
some_use_intra |=
cw.bc.blocks[tile_bo.with_offset(-1, -1)].mode.is_intra();
};
if some_use_intra {
luma_mode.predict_inter(
fi,
tile_rect,
p,
po,
&mut rec.subregion_mut(area),
plane_bsize.width(),
plane_bsize.height(),
ref_frames,
mvs,
compound_buffer,
);
} else {
assert!(u_xdec == 1 && u_ydec == 1);
if bsize == BlockSize::BLOCK_4X4 {
let mv0 = cw.bc.blocks[tile_bo.with_offset(-1, -1)].mv;
let rf0 = cw.bc.blocks[tile_bo.with_offset(-1, -1)].ref_frames;
let mv1 = cw.bc.blocks[tile_bo.with_offset(0, -1)].mv;
let rf1 = cw.bc.blocks[tile_bo.with_offset(0, -1)].ref_frames;
let po1 = PlaneOffset { x: po.x + 2, y: po.y };
let area1 = Area::StartingAt { x: po1.x, y: po1.y };
let mv2 = cw.bc.blocks[tile_bo.with_offset(-1, 0)].mv;
let rf2 = cw.bc.blocks[tile_bo.with_offset(-1, 0)].ref_frames;
let po2 = PlaneOffset { x: po.x, y: po.y + 2 };
let area2 = Area::StartingAt { x: po2.x, y: po2.y };
let po3 = PlaneOffset { x: po.x + 2, y: po.y + 2 };
let area3 = Area::StartingAt { x: po3.x, y: po3.y };
luma_mode.predict_inter(
fi,
tile_rect,
p,
po,
&mut rec.subregion_mut(area),
2,
2,
rf0,
mv0,
compound_buffer,
);
luma_mode.predict_inter(
fi,
tile_rect,
p,
po1,
&mut rec.subregion_mut(area1),
2,
2,
rf1,
mv1,
compound_buffer,
);
luma_mode.predict_inter(
fi,
tile_rect,
p,
po2,
&mut rec.subregion_mut(area2),
2,
2,
rf2,
mv2,
compound_buffer,
);
luma_mode.predict_inter(
fi,
tile_rect,
p,
po3,
&mut rec.subregion_mut(area3),
2,
2,
ref_frames,
mvs,
compound_buffer,
);
}
if bsize == BlockSize::BLOCK_8X4 {
let mv1 = cw.bc.blocks[tile_bo.with_offset(0, -1)].mv;
let rf1 = cw.bc.blocks[tile_bo.with_offset(0, -1)].ref_frames;
luma_mode.predict_inter(
fi,
tile_rect,
p,
po,
&mut rec.subregion_mut(area),
4,
2,
rf1,
mv1,
compound_buffer,
);
let po3 = PlaneOffset { x: po.x, y: po.y + 2 };
let area3 = Area::StartingAt { x: po3.x, y: po3.y };
luma_mode.predict_inter(
fi,
tile_rect,
p,
po3,
&mut rec.subregion_mut(area3),
4,
2,
ref_frames,
mvs,
compound_buffer,
);
}
if bsize == BlockSize::BLOCK_4X8 {
let mv2 = cw.bc.blocks[tile_bo.with_offset(-1, 0)].mv;
let rf2 = cw.bc.blocks[tile_bo.with_offset(-1, 0)].ref_frames;
luma_mode.predict_inter(
fi,
tile_rect,
p,
po,
&mut rec.subregion_mut(area),
2,
4,
rf2,
mv2,
compound_buffer,
);
let po3 = PlaneOffset { x: po.x + 2, y: po.y };
let area3 = Area::StartingAt { x: po3.x, y: po3.y };
luma_mode.predict_inter(
fi,
tile_rect,
p,
po3,
&mut rec.subregion_mut(area3),
2,
4,
ref_frames,
mvs,
compound_buffer,
);
}
}
} else {
luma_mode.predict_inter(
fi,
tile_rect,
p,
po,
&mut rec.subregion_mut(area),
plane_bsize.width(),
plane_bsize.height(),
ref_frames,
mvs,
compound_buffer,
);
}
}
}
pub fn save_block_motion<T: Pixel>(
ts: &mut TileStateMut<'_, T>, bsize: BlockSize, tile_bo: TileBlockOffset,
ref_frame: usize, mv: MotionVector,
) {
let tile_me_stats = &mut ts.me_stats[ref_frame];
let tile_bo_x_end = (tile_bo.0.x + bsize.width_mi()).min(ts.mi_width);
let tile_bo_y_end = (tile_bo.0.y + bsize.height_mi()).min(ts.mi_height);
for mi_y in tile_bo.0.y..tile_bo_y_end {
for mi_x in tile_bo.0.x..tile_bo_x_end {
tile_me_stats[mi_y][mi_x].mv = mv;
}
}
}
pub fn encode_block_pre_cdef<T: Pixel>(
seq: &Sequence, ts: &TileStateMut<'_, T>, cw: &mut ContextWriter,
w: &mut dyn Writer, bsize: BlockSize, tile_bo: TileBlockOffset, skip: bool,
) -> bool {
cw.bc.blocks.set_skip(tile_bo, bsize, skip);
if ts.segmentation.enabled
&& ts.segmentation.update_map
&& ts.segmentation.preskip
{
cw.write_segmentation(
w,
tile_bo,
bsize,
false,
ts.segmentation.last_active_segid,
);
}
cw.write_skip(w, tile_bo, skip);
if ts.segmentation.enabled
&& ts.segmentation.update_map
&& !ts.segmentation.preskip
{
cw.write_segmentation(
w,
tile_bo,
bsize,
skip,
ts.segmentation.last_active_segid,
);
}
if !skip && seq.enable_cdef {
cw.bc.cdef_coded = true;
}
cw.bc.cdef_coded
}
pub fn encode_block_post_cdef<T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w: &mut dyn Writer, luma_mode: PredictionMode,
chroma_mode: PredictionMode, angle_delta: AngleDelta,
ref_frames: [RefType; 2], mvs: [MotionVector; 2], bsize: BlockSize,
tile_bo: TileBlockOffset, skip: bool, cfl: CFLParams, tx_size: TxSize,
tx_type: TxType, mode_context: usize, mv_stack: &[CandidateMV],
rdo_type: RDOType, need_recon_pixel: bool, record_stats: bool,
) -> (bool, ScaledDistortion) {
let planes =
if fi.sequence.chroma_sampling == ChromaSampling::Cs400 { 1 } else { 3 };
let is_inter = !luma_mode.is_intra();
if is_inter {
assert!(luma_mode == chroma_mode);
};
let sb_size = if fi.sequence.use_128x128_superblock {
BlockSize::BLOCK_128X128
} else {
BlockSize::BLOCK_64X64
};
let PlaneConfig { xdec, ydec, .. } = ts.input.planes[1].cfg;
if skip {
cw.bc.reset_skip_context(
tile_bo,
bsize,
xdec,
ydec,
fi.sequence.chroma_sampling,
);
}
cw.bc.blocks.set_block_size(tile_bo, bsize);
cw.bc.blocks.set_mode(tile_bo, bsize, luma_mode);
cw.bc.blocks.set_tx_size(tile_bo, bsize, tx_size);
cw.bc.blocks.set_ref_frames(tile_bo, bsize, ref_frames);
cw.bc.blocks.set_motion_vectors(tile_bo, bsize, mvs);
if cw.bc.code_deltas
&& ts.deblock.block_deltas_enabled
&& (bsize < sb_size || !skip)
{
cw.write_block_deblock_deltas(
w,
tile_bo,
ts.deblock.block_delta_multi,
planes,
);
}
cw.bc.code_deltas = false;
if fi.frame_type.has_inter() {
cw.write_is_inter(w, tile_bo, is_inter);
if is_inter {
cw.fill_neighbours_ref_counts(tile_bo);
cw.write_ref_frames(w, fi, tile_bo);
if luma_mode.is_compound() {
cw.write_compound_mode(w, luma_mode, mode_context);
} else {
cw.write_inter_mode(w, luma_mode, mode_context);
}
let ref_mv_idx = 0;
let num_mv_found = mv_stack.len();
if luma_mode == PredictionMode::NEWMV
|| luma_mode == PredictionMode::NEW_NEWMV
{
if luma_mode == PredictionMode::NEW_NEWMV {
assert!(num_mv_found >= 2);
}
for idx in 0..2 {
if num_mv_found > idx + 1 {
let drl_mode = ref_mv_idx > idx;
let ctx: usize = (mv_stack[idx].weight < REF_CAT_LEVEL) as usize
+ (mv_stack[idx + 1].weight < REF_CAT_LEVEL) as usize;
cw.write_drl_mode(w, drl_mode, ctx);
if !drl_mode {
break;
}
}
}
}
let ref_mvs = if num_mv_found > 0 {
[mv_stack[ref_mv_idx].this_mv, mv_stack[ref_mv_idx].comp_mv]
} else {
[MotionVector::default(); 2]
};
let mv_precision = if fi.force_integer_mv != 0 {
MvSubpelPrecision::MV_SUBPEL_NONE
} else if fi.allow_high_precision_mv {
MvSubpelPrecision::MV_SUBPEL_HIGH_PRECISION
} else {
MvSubpelPrecision::MV_SUBPEL_LOW_PRECISION
};
if luma_mode == PredictionMode::NEWMV
|| luma_mode == PredictionMode::NEW_NEWMV
|| luma_mode == PredictionMode::NEW_NEARESTMV
{
cw.write_mv(w, mvs[0], ref_mvs[0], mv_precision);
}
if luma_mode == PredictionMode::NEW_NEWMV
|| luma_mode == PredictionMode::NEAREST_NEWMV
{
cw.write_mv(w, mvs[1], ref_mvs[1], mv_precision);
}
if luma_mode.has_nearmv() {
let ref_mv_idx = luma_mode.ref_mv_idx();
if luma_mode != PredictionMode::NEAR0MV {
assert!(num_mv_found > ref_mv_idx);
}
for idx in 1..3 {
if num_mv_found > idx + 1 {
let drl_mode = ref_mv_idx > idx;
let ctx: usize = (mv_stack[idx].weight < REF_CAT_LEVEL) as usize
+ (mv_stack[idx + 1].weight < REF_CAT_LEVEL) as usize;
cw.write_drl_mode(w, drl_mode, ctx);
if !drl_mode {
break;
}
}
}
if mv_stack.len() > 1 {
assert!(mv_stack[ref_mv_idx].this_mv.row == mvs[0].row);
assert!(mv_stack[ref_mv_idx].this_mv.col == mvs[0].col);
} else {
assert!(0 == mvs[0].row);
assert!(0 == mvs[0].col);
}
} else if luma_mode == PredictionMode::NEARESTMV {
if mv_stack.is_empty() {
assert_eq!(mvs[0].row, 0);
assert_eq!(mvs[0].col, 0);
} else {
assert_eq!(mvs[0].row, mv_stack[0].this_mv.row);
assert_eq!(mvs[0].col, mv_stack[0].this_mv.col);
}
}
} else {
cw.write_intra_mode(w, bsize, luma_mode);
}
} else {
cw.write_intra_mode_kf(w, tile_bo, luma_mode);
}
if !is_inter {
if luma_mode.is_directional() && bsize >= BlockSize::BLOCK_8X8 {
cw.write_angle_delta(w, angle_delta.y, luma_mode);
}
if has_chroma(tile_bo, bsize, xdec, ydec, fi.sequence.chroma_sampling) {
cw.write_intra_uv_mode(w, chroma_mode, luma_mode, bsize);
if chroma_mode.is_cfl() {
assert!(bsize.cfl_allowed());
cw.write_cfl_alphas(w, cfl);
}
if chroma_mode.is_directional() && bsize >= BlockSize::BLOCK_8X8 {
cw.write_angle_delta(w, angle_delta.uv, chroma_mode);
}
}
if fi.allow_screen_content_tools > 0
&& bsize >= BlockSize::BLOCK_8X8
&& bsize.width() <= 64
&& bsize.height() <= 64
{
cw.write_use_palette_mode(
w,
false,
bsize,
tile_bo,
luma_mode,
chroma_mode,
xdec,
ydec,
fi.sequence.chroma_sampling,
);
}
if fi.sequence.enable_filter_intra
&& luma_mode == PredictionMode::DC_PRED
&& bsize.width() <= 32
&& bsize.height() <= 32
{
cw.write_use_filter_intra(w, false, bsize);
}
}
if fi.tx_mode_select {
if bsize > BlockSize::BLOCK_4X4 && (!is_inter || !skip) {
if !is_inter {
cw.write_tx_size_intra(w, tile_bo, bsize, tx_size);
cw.bc.update_tx_size_context(tile_bo, bsize, tx_size, false);
} else {
debug_assert!(fi.tx_mode_select);
debug_assert!(bsize > BlockSize::BLOCK_4X4);
debug_assert!(is_inter);
debug_assert!(!skip);
let max_tx_size = max_txsize_rect_lookup[bsize as usize];
debug_assert!(max_tx_size.block_size() <= BlockSize::BLOCK_64X64);
let txfm_split =
fi.enable_inter_txfm_split && tx_size.block_size() < bsize;
cw.write_tx_size_inter(
w,
tile_bo,
bsize,
max_tx_size,
txfm_split,
0,
0,
0,
);
}
} else {
debug_assert!(bsize == BlockSize::BLOCK_4X4 || (is_inter && skip));
cw.bc.update_tx_size_context(tile_bo, bsize, tx_size, is_inter && skip);
}
}
if record_stats {
let pixels = tx_size.area();
ts.enc_stats.block_size_counts[bsize as usize] += pixels;
ts.enc_stats.tx_type_counts[tx_type as usize] += pixels;
ts.enc_stats.luma_pred_mode_counts[luma_mode as usize] += pixels;
ts.enc_stats.chroma_pred_mode_counts[chroma_mode as usize] += pixels;
if skip {
ts.enc_stats.skip_block_count += pixels;
}
}
if fi.sequence.enable_intra_edge_filter {
for y in 0..bsize.height_mi() {
if tile_bo.0.y + y >= ts.mi_height {
continue;
}
for x in 0..bsize.width_mi() {
if tile_bo.0.x + x >= ts.mi_width {
continue;
}
let bi = &mut ts.coded_block_info[tile_bo.0.y + y][tile_bo.0.x + x];
bi.luma_mode = luma_mode;
bi.chroma_mode = chroma_mode;
bi.reference_types = ref_frames;
}
}
}
if is_inter {
motion_compensate(
fi, ts, cw, luma_mode, ref_frames, mvs, bsize, tile_bo, false,
);
write_tx_tree(
fi,
ts,
cw,
w,
luma_mode,
angle_delta.y,
tile_bo,
bsize,
tx_size,
tx_type,
skip,
false,
rdo_type,
need_recon_pixel,
)
} else {
write_tx_blocks(
fi,
ts,
cw,
w,
luma_mode,
chroma_mode,
angle_delta,
tile_bo,
bsize,
tx_size,
tx_type,
skip,
cfl,
false,
rdo_type,
need_recon_pixel,
)
}
}
pub fn luma_ac<T: Pixel>(
ac: &mut [i16], ts: &mut TileStateMut<'_, T>, tile_bo: TileBlockOffset,
bsize: BlockSize, tx_size: TxSize, fi: &FrameInvariants<T>,
) {
let PlaneConfig { xdec, ydec, .. } = ts.input.planes[1].cfg;
let plane_bsize = bsize.subsampled_size(xdec, ydec);
let bo = if bsize.is_sub8x8(xdec, ydec) {
let offset = bsize.sub8x8_offset(xdec, ydec);
tile_bo.with_offset(offset.0, offset.1)
} else {
tile_bo
};
let rec = &ts.rec.planes[0];
let luma = &rec.subregion(Area::BlockStartingAt { bo: bo.0 });
let frame_bo = ts.to_frame_block_offset(bo);
let frame_clipped_bw: usize =
((fi.w_in_b - frame_bo.0.x) << MI_SIZE_LOG2).min(bsize.width());
let frame_clipped_bh: usize =
((fi.h_in_b - frame_bo.0.y) << MI_SIZE_LOG2).min(bsize.height());
let max_luma_w: usize;
let max_luma_h: usize;
if bsize.width() > BlockSize::BLOCK_8X8.width() {
let txw_log2 = tx_size.width_log2();
max_luma_w =
((frame_clipped_bw + (1 << txw_log2) - 1) >> txw_log2) << txw_log2;
} else {
max_luma_w = bsize.width();
}
if bsize.height() > BlockSize::BLOCK_8X8.height() {
let txh_log2 = tx_size.height_log2();
max_luma_h =
((frame_clipped_bh + (1 << txh_log2) - 1) >> txh_log2) << txh_log2;
} else {
max_luma_h = bsize.height();
}
let max_luma_x: usize = max_luma_w.max(8) - (1 << xdec);
let max_luma_y: usize = max_luma_h.max(8) - (1 << ydec);
let mut sum: i32 = 0;
for sub_y in 0..plane_bsize.height() {
for sub_x in 0..plane_bsize.width() {
let luma_y = sub_y << ydec;
let luma_x = sub_x << xdec;
let y = luma_y.min(max_luma_y);
let x = luma_x.min(max_luma_x);
let mut sample: i16 = i16::cast_from(luma[y][x]);
if xdec != 0 {
sample += i16::cast_from(luma[y][x + 1]);
}
if ydec != 0 {
debug_assert!(xdec != 0);
sample +=
i16::cast_from(luma[y + 1][x]) + i16::cast_from(luma[y + 1][x + 1]);
}
sample <<= 3 - xdec - ydec;
ac[sub_y * plane_bsize.width() + sub_x] = sample;
sum += sample as i32;
}
}
let shift = plane_bsize.width_log2() + plane_bsize.height_log2();
let average = ((sum + (1 << (shift - 1))) >> shift) as i16;
for sub_y in 0..plane_bsize.height() {
for sub_x in 0..plane_bsize.width() {
ac[sub_y * plane_bsize.width() + sub_x] -= average;
}
}
}
pub fn write_tx_blocks<T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w: &mut dyn Writer, luma_mode: PredictionMode,
chroma_mode: PredictionMode, angle_delta: AngleDelta,
tile_bo: TileBlockOffset, bsize: BlockSize, tx_size: TxSize,
tx_type: TxType, skip: bool, cfl: CFLParams, luma_only: bool,
rdo_type: RDOType, need_recon_pixel: bool,
) -> (bool, ScaledDistortion) {
let bw = bsize.width_mi() / tx_size.width_mi();
let bh = bsize.height_mi() / tx_size.height_mi();
let qidx = get_qidx(fi, ts, cw, tile_bo);
assert_ne!(qidx, 0);
let PlaneConfig { xdec, ydec, .. } = ts.input.planes[1].cfg;
let mut ac: Aligned<[i16; 32 * 32]> = Aligned::uninitialized();
let mut partition_has_coeff: bool = false;
let mut tx_dist = ScaledDistortion::zero();
let do_chroma =
has_chroma(tile_bo, bsize, xdec, ydec, fi.sequence.chroma_sampling);
ts.qc.update(
qidx,
tx_size,
luma_mode.is_intra(),
fi.sequence.bit_depth,
fi.dc_delta_q[0],
0,
);
for by in 0..bh {
for bx in 0..bw {
let tx_bo = TileBlockOffset(BlockOffset {
x: tile_bo.0.x + bx * tx_size.width_mi(),
y: tile_bo.0.y + by * tx_size.height_mi(),
});
if tx_bo.0.x >= ts.mi_width || tx_bo.0.y >= ts.mi_height {
continue;
}
let po = tx_bo.plane_offset(&ts.input.planes[0].cfg);
let (has_coeff, dist) = encode_tx_block(
fi,
ts,
cw,
w,
0,
tile_bo,
bx,
by,
tx_bo,
luma_mode,
tx_size,
tx_type,
bsize,
po,
skip,
qidx,
&ac.data,
IntraParam::AngleDelta(angle_delta.y),
rdo_type,
need_recon_pixel,
);
partition_has_coeff |= has_coeff;
tx_dist += dist;
}
}
if !do_chroma
|| luma_only
|| fi.sequence.chroma_sampling == ChromaSampling::Cs400
{
return (partition_has_coeff, tx_dist);
};
debug_assert!(has_chroma(
tile_bo,
bsize,
xdec,
ydec,
fi.sequence.chroma_sampling
));
let uv_tx_size = bsize.largest_chroma_tx_size(xdec, ydec);
let mut bw_uv = (bw * tx_size.width_mi()) >> xdec;
let mut bh_uv = (bh * tx_size.height_mi()) >> ydec;
if bw_uv == 0 || bh_uv == 0 {
bw_uv = 1;
bh_uv = 1;
}
bw_uv /= uv_tx_size.width_mi();
bh_uv /= uv_tx_size.height_mi();
if chroma_mode.is_cfl() {
luma_ac(&mut ac.data, ts, tile_bo, bsize, tx_size, fi);
}
let uv_tx_type = if uv_tx_size.width() >= 32 || uv_tx_size.height() >= 32 {
TxType::DCT_DCT
} else {
uv_intra_mode_to_tx_type_context(chroma_mode)
};
for p in 1..3 {
ts.qc.update(
qidx,
uv_tx_size,
true,
fi.sequence.bit_depth,
fi.dc_delta_q[p],
fi.ac_delta_q[p],
);
let alpha = cfl.alpha(p - 1);
for by in 0..bh_uv {
for bx in 0..bw_uv {
let tx_bo = TileBlockOffset(BlockOffset {
x: tile_bo.0.x + ((bx * uv_tx_size.width_mi()) << xdec)
- ((bw * tx_size.width_mi() == 1) as usize) * xdec,
y: tile_bo.0.y + ((by * uv_tx_size.height_mi()) << ydec)
- ((bh * tx_size.height_mi() == 1) as usize) * ydec,
});
let mut po = tile_bo.plane_offset(&ts.input.planes[p].cfg);
po.x += (bx * uv_tx_size.width()) as isize;
po.y += (by * uv_tx_size.height()) as isize;
let (has_coeff, dist) = encode_tx_block(
fi,
ts,
cw,
w,
p,
tile_bo,
bx,
by,
tx_bo,
chroma_mode,
uv_tx_size,
uv_tx_type,
bsize,
po,
skip,
qidx,
&ac.data,
if chroma_mode.is_cfl() {
IntraParam::Alpha(alpha)
} else {
IntraParam::AngleDelta(angle_delta.uv)
},
rdo_type,
need_recon_pixel,
);
partition_has_coeff |= has_coeff;
tx_dist += dist;
}
}
}
(partition_has_coeff, tx_dist)
}
pub fn write_tx_tree<T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w: &mut dyn Writer, luma_mode: PredictionMode,
angle_delta_y: i8, tile_bo: TileBlockOffset, bsize: BlockSize,
tx_size: TxSize, tx_type: TxType, skip: bool, luma_only: bool,
rdo_type: RDOType, need_recon_pixel: bool,
) -> (bool, ScaledDistortion) {
if skip {
return (false, ScaledDistortion::zero());
}
let bw = bsize.width_mi() / tx_size.width_mi();
let bh = bsize.height_mi() / tx_size.height_mi();
let qidx = get_qidx(fi, ts, cw, tile_bo);
let PlaneConfig { xdec, ydec, .. } = ts.input.planes[1].cfg;
let ac = &[0i16; 0];
let mut partition_has_coeff: bool = false;
let mut tx_dist = ScaledDistortion::zero();
ts.qc.update(
qidx,
tx_size,
luma_mode.is_intra(),
fi.sequence.bit_depth,
fi.dc_delta_q[0],
0,
);
for by in 0..bh {
for bx in 0..bw {
let tx_bo = TileBlockOffset(BlockOffset {
x: tile_bo.0.x + bx * tx_size.width_mi(),
y: tile_bo.0.y + by * tx_size.height_mi(),
});
if tx_bo.0.x >= ts.mi_width || tx_bo.0.y >= ts.mi_height {
continue;
}
let po = tx_bo.plane_offset(&ts.input.planes[0].cfg);
let (has_coeff, dist) = encode_tx_block(
fi,
ts,
cw,
w,
0,
tile_bo,
0,
0,
tx_bo,
luma_mode,
tx_size,
tx_type,
bsize,
po,
skip,
qidx,
ac,
IntraParam::AngleDelta(angle_delta_y),
rdo_type,
need_recon_pixel,
);
partition_has_coeff |= has_coeff;
tx_dist += dist;
}
}
if !has_chroma(tile_bo, bsize, xdec, ydec, fi.sequence.chroma_sampling)
|| luma_only
|| fi.sequence.chroma_sampling == ChromaSampling::Cs400
{
return (partition_has_coeff, tx_dist);
};
debug_assert!(has_chroma(
tile_bo,
bsize,
xdec,
ydec,
fi.sequence.chroma_sampling
));
let max_tx_size = max_txsize_rect_lookup[bsize as usize];
debug_assert!(max_tx_size.block_size() <= BlockSize::BLOCK_64X64);
let uv_tx_size = bsize.largest_chroma_tx_size(xdec, ydec);
let mut bw_uv = max_tx_size.width_mi() >> xdec;
let mut bh_uv = max_tx_size.height_mi() >> ydec;
if bw_uv == 0 || bh_uv == 0 {
bw_uv = 1;
bh_uv = 1;
}
bw_uv /= uv_tx_size.width_mi();
bh_uv /= uv_tx_size.height_mi();
let uv_tx_type = if partition_has_coeff {
tx_type.uv_inter(uv_tx_size)
} else {
TxType::DCT_DCT
};
for p in 1..3 {
ts.qc.update(
qidx,
uv_tx_size,
false,
fi.sequence.bit_depth,
fi.dc_delta_q[p],
fi.ac_delta_q[p],
);
for by in 0..bh_uv {
for bx in 0..bw_uv {
let tx_bo = TileBlockOffset(BlockOffset {
x: tile_bo.0.x + ((bx * uv_tx_size.width_mi()) << xdec)
- (max_tx_size.width_mi() == 1) as usize * xdec,
y: tile_bo.0.y + ((by * uv_tx_size.height_mi()) << ydec)
- (max_tx_size.height_mi() == 1) as usize * ydec,
});
let mut po = tile_bo.plane_offset(&ts.input.planes[p].cfg);
po.x += (bx * uv_tx_size.width()) as isize;
po.y += (by * uv_tx_size.height()) as isize;
let (has_coeff, dist) = encode_tx_block(
fi,
ts,
cw,
w,
p,
tile_bo,
bx,
by,
tx_bo,
luma_mode,
uv_tx_size,
uv_tx_type,
bsize,
po,
skip,
qidx,
ac,
IntraParam::AngleDelta(angle_delta_y),
rdo_type,
need_recon_pixel,
);
partition_has_coeff |= has_coeff;
tx_dist += dist;
}
}
}
(partition_has_coeff, tx_dist)
}
pub fn encode_block_with_modes<T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w_pre_cdef: &mut dyn Writer,
w_post_cdef: &mut dyn Writer, bsize: BlockSize, tile_bo: TileBlockOffset,
mode_decision: &PartitionParameters, rdo_type: RDOType, record_stats: bool,
) {
let (mode_luma, mode_chroma) =
(mode_decision.pred_mode_luma, mode_decision.pred_mode_chroma);
let cfl = mode_decision.pred_cfl_params;
let ref_frames = mode_decision.ref_frames;
let mvs = mode_decision.mvs;
let mut skip = mode_decision.skip;
let mut cdef_coded = cw.bc.cdef_coded;
cw.bc.blocks.set_segmentation_idx(tile_bo, bsize, mode_decision.sidx);
let mut mv_stack = ArrayVec::<[CandidateMV; 9]>::new();
let is_compound = ref_frames[1] != NONE_FRAME;
let mode_context =
cw.find_mvrefs(tile_bo, ref_frames, &mut mv_stack, bsize, fi, is_compound);
let (tx_size, tx_type) = if !mode_decision.skip && !mode_decision.has_coeff {
skip = true;
rdo_tx_size_type(
fi, ts, cw, bsize, tile_bo, mode_luma, ref_frames, mvs, skip,
)
} else {
(mode_decision.tx_size, mode_decision.tx_type)
};
cdef_coded = encode_block_pre_cdef(
&fi.sequence,
ts,
cw,
if cdef_coded { w_post_cdef } else { w_pre_cdef },
bsize,
tile_bo,
skip,
);
encode_block_post_cdef(
fi,
ts,
cw,
if cdef_coded { w_post_cdef } else { w_pre_cdef },
mode_luma,
mode_chroma,
mode_decision.angle_delta,
ref_frames,
mvs,
bsize,
tile_bo,
skip,
cfl,
tx_size,
tx_type,
mode_context,
&mv_stack,
rdo_type,
true,
record_stats,
);
}
fn encode_partition_bottomup<T: Pixel, W: Writer>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w_pre_cdef: &mut W, w_post_cdef: &mut W,
bsize: BlockSize, tile_bo: TileBlockOffset, ref_rd_cost: f64,
inter_cfg: &InterConfig,
) -> PartitionGroupParameters {
let rdo_type = RDOType::PixelDistRealRate;
let mut rd_cost = std::f64::MAX;
let mut best_rd = std::f64::MAX;
let mut rdo_output = PartitionGroupParameters {
rd_cost,
part_type: PartitionType::PARTITION_INVALID,
part_modes: ArrayVec::new(),
};
if tile_bo.0.x >= ts.mi_width || tile_bo.0.y >= ts.mi_height {
return rdo_output;
}
let is_square = bsize.is_sqr();
let hbs = bsize.width_mi() >> 1;
let has_cols = tile_bo.0.x + hbs < ts.mi_width;
let has_rows = tile_bo.0.y + hbs < ts.mi_height;
let is_straddle_x = tile_bo.0.x + bsize.width_mi() > ts.mi_width;
let is_straddle_y = tile_bo.0.y + bsize.height_mi() > ts.mi_height;
assert!(fi.partition_range.max <= BlockSize::BLOCK_64X64);
let must_split =
is_square && (bsize > fi.partition_range.max || !has_cols || !has_rows);
let can_split =
if fi.frame_type.has_inter() &&
fi.sequence.chroma_sampling != ChromaSampling::Cs420 &&
bsize <= BlockSize::BLOCK_8X8 {
false
} else {
(bsize > fi.partition_range.min && is_square) || must_split
};
assert!(bsize >= BlockSize::BLOCK_8X8 || !can_split);
let mut best_partition = PartitionType::PARTITION_INVALID;
let cw_checkpoint = cw.checkpoint();
let w_pre_checkpoint = w_pre_cdef.checkpoint();
let w_post_checkpoint = w_post_cdef.checkpoint();
if !must_split {
let cost = if bsize >= BlockSize::BLOCK_8X8 && is_square {
let w: &mut W = if cw.bc.cdef_coded { w_post_cdef } else { w_pre_cdef };
let tell = w.tell_frac();
cw.write_partition(w, tile_bo, PartitionType::PARTITION_NONE, bsize);
compute_rd_cost(fi, w.tell_frac() - tell, ScaledDistortion::zero())
} else {
0.0
};
let mode_decision =
rdo_mode_decision(fi, ts, cw, bsize, tile_bo, inter_cfg);
if !mode_decision.pred_mode_luma.is_intra() {
save_block_motion(
ts,
mode_decision.bsize,
mode_decision.bo,
mode_decision.ref_frames[0].to_index(),
mode_decision.mvs[0],
);
}
rd_cost = mode_decision.rd_cost + cost;
best_partition = PartitionType::PARTITION_NONE;
best_rd = rd_cost;
rdo_output.part_modes.push(mode_decision.clone());
if !can_split {
encode_block_with_modes(
fi,
ts,
cw,
w_pre_cdef,
w_post_cdef,
bsize,
tile_bo,
&mode_decision,
rdo_type,
true,
);
}
}
let mut early_exit = false;
if can_split {
debug_assert!(is_square);
let mut partition_types = ArrayVec::<[PartitionType; 3]>::new();
if fi.config.speed_settings.non_square_partition
|| is_straddle_x
|| is_straddle_y
{
if has_cols {
partition_types.push(PartitionType::PARTITION_HORZ);
}
if !(fi.sequence.chroma_sampling == ChromaSampling::Cs422) && has_rows {
partition_types.push(PartitionType::PARTITION_VERT);
}
}
partition_types.push(PartitionType::PARTITION_SPLIT);
for partition in partition_types {
debug_assert!((has_rows && has_cols) || must_split);
debug_assert!(
has_rows || !has_cols || (partition != PartitionType::PARTITION_VERT)
);
debug_assert!(
!has_rows || has_cols || (partition != PartitionType::PARTITION_HORZ)
);
debug_assert!(
has_rows || has_cols || (partition == PartitionType::PARTITION_SPLIT)
);
cw.rollback(&cw_checkpoint);
w_pre_cdef.rollback(&w_pre_checkpoint);
w_post_cdef.rollback(&w_post_checkpoint);
let subsize = bsize.subsize(partition);
let hbsw = subsize.width_mi();
let hbsh = subsize.height_mi();
let mut child_modes = ArrayVec::<[PartitionParameters; 4]>::new();
rd_cost = 0.0;
if bsize >= BlockSize::BLOCK_8X8 {
let w: &mut W =
if cw.bc.cdef_coded { w_post_cdef } else { w_pre_cdef };
let tell = w.tell_frac();
cw.write_partition(w, tile_bo, partition, bsize);
rd_cost =
compute_rd_cost(fi, w.tell_frac() - tell, ScaledDistortion::zero());
}
let four_partitions = [
tile_bo,
TileBlockOffset(BlockOffset {
x: tile_bo.0.x + hbsw as usize,
y: tile_bo.0.y,
}),
TileBlockOffset(BlockOffset {
x: tile_bo.0.x,
y: tile_bo.0.y + hbsh as usize,
}),
TileBlockOffset(BlockOffset {
x: tile_bo.0.x + hbsw as usize,
y: tile_bo.0.y + hbsh as usize,
}),
];
let partitions = get_sub_partitions(&four_partitions, partition);
early_exit = false;
for offset in partitions {
if offset.0.x >= ts.mi_width || offset.0.y >= ts.mi_height {
continue;
}
let child_rdo_output = encode_partition_bottomup(
fi,
ts,
cw,
w_pre_cdef,
w_post_cdef,
subsize,
offset,
best_rd,
inter_cfg,
);
let cost = child_rdo_output.rd_cost;
assert!(cost >= 0.0);
if cost != std::f64::MAX {
rd_cost += cost;
if !must_split
&& fi.enable_early_exit
&& (rd_cost >= best_rd || rd_cost >= ref_rd_cost)
{
assert!(cost != std::f64::MAX);
early_exit = true;
break;
} else if partition != PartitionType::PARTITION_SPLIT {
child_modes.push(child_rdo_output.part_modes[0].clone());
}
}
}
if !early_exit && rd_cost < best_rd {
best_rd = rd_cost;
best_partition = partition;
if partition != PartitionType::PARTITION_SPLIT {
assert!(!child_modes.is_empty());
rdo_output.part_modes = child_modes;
}
}
}
debug_assert!(
early_exit || best_partition != PartitionType::PARTITION_INVALID
);
if best_partition != PartitionType::PARTITION_SPLIT {
assert!(!rdo_output.part_modes.is_empty());
cw.rollback(&cw_checkpoint);
w_pre_cdef.rollback(&w_pre_checkpoint);
w_post_cdef.rollback(&w_post_checkpoint);
assert!(best_partition != PartitionType::PARTITION_NONE || !must_split);
let subsize = bsize.subsize(best_partition);
if bsize >= BlockSize::BLOCK_8X8 {
let w: &mut W =
if cw.bc.cdef_coded { w_post_cdef } else { w_pre_cdef };
cw.write_partition(w, tile_bo, best_partition, bsize);
}
for mode in rdo_output.part_modes.clone() {
assert!(subsize == mode.bsize);
if !mode.pred_mode_luma.is_intra() {
save_block_motion(
ts,
mode.bsize,
mode.bo,
mode.ref_frames[0].to_index(),
mode.mvs[0],
);
}
encode_block_with_modes(
fi,
ts,
cw,
w_pre_cdef,
w_post_cdef,
mode.bsize,
mode.bo,
&mode,
rdo_type,
true,
);
}
}
}
assert!(best_partition != PartitionType::PARTITION_INVALID);
if is_square
&& bsize >= BlockSize::BLOCK_8X8
&& (bsize == BlockSize::BLOCK_8X8
|| best_partition != PartitionType::PARTITION_SPLIT)
{
cw.bc.update_partition_context(
tile_bo,
bsize.subsize(best_partition),
bsize,
);
}
rdo_output.rd_cost = best_rd;
rdo_output.part_type = best_partition;
if best_partition != PartitionType::PARTITION_NONE {
rdo_output.part_modes.clear();
}
rdo_output
}
fn encode_partition_topdown<T: Pixel, W: Writer>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w_pre_cdef: &mut W, w_post_cdef: &mut W,
bsize: BlockSize, tile_bo: TileBlockOffset,
block_output: &Option<PartitionGroupParameters>, inter_cfg: &InterConfig,
) {
if tile_bo.0.x >= ts.mi_width || tile_bo.0.y >= ts.mi_height {
return;
}
let is_square = bsize.is_sqr();
let rdo_type = RDOType::PixelDistRealRate;
let hbs = bsize.width_mi() >> 1;
let has_cols = tile_bo.0.x + hbs < ts.mi_width;
let has_rows = tile_bo.0.y + hbs < ts.mi_height;
assert!(fi.partition_range.max <= BlockSize::BLOCK_64X64);
let must_split =
is_square && (bsize > fi.partition_range.max || !has_cols || !has_rows);
let can_split =
if fi.frame_type.has_inter() &&
fi.sequence.chroma_sampling != ChromaSampling::Cs420 &&
bsize <= BlockSize::BLOCK_8X8 {
false
} else {
(bsize > fi.partition_range.min && is_square) || must_split
};
let mut rdo_output =
block_output.clone().unwrap_or(PartitionGroupParameters {
part_type: PartitionType::PARTITION_INVALID,
rd_cost: std::f64::MAX,
part_modes: ArrayVec::new(),
});
let partition: PartitionType;
if must_split {
partition = PartitionType::PARTITION_SPLIT;
} else if can_split {
debug_assert!(bsize.is_sqr());
let mut partition_types = ArrayVec::<[PartitionType; 3]>::new();
partition_types.push(PartitionType::PARTITION_SPLIT);
if !must_split {
partition_types.push(PartitionType::PARTITION_NONE);
}
rdo_output = rdo_partition_decision(
fi,
ts,
cw,
w_pre_cdef,
w_post_cdef,
bsize,
tile_bo,
&rdo_output,
&partition_types,
rdo_type,
inter_cfg,
);
partition = rdo_output.part_type;
} else {
partition = PartitionType::PARTITION_NONE;
}
assert!(
PartitionType::PARTITION_NONE <= partition
&& partition < PartitionType::PARTITION_INVALID
);
let subsize = bsize.subsize(partition);
debug_assert!(subsize != BlockSize::BLOCK_INVALID);
if bsize >= BlockSize::BLOCK_8X8 && is_square {
let w: &mut W = if cw.bc.cdef_coded { w_post_cdef } else { w_pre_cdef };
cw.write_partition(w, tile_bo, partition, bsize);
}
match partition {
PartitionType::PARTITION_NONE => {
let part_decision = if !rdo_output.part_modes.is_empty() {
rdo_output.part_modes[0].clone()
} else {
rdo_mode_decision(fi, ts, cw, bsize, tile_bo, inter_cfg)
};
let mut mode_luma = part_decision.pred_mode_luma;
let mut mode_chroma = part_decision.pred_mode_chroma;
let cfl = part_decision.pred_cfl_params;
let skip = part_decision.skip;
let ref_frames = part_decision.ref_frames;
let mvs = part_decision.mvs;
let mut cdef_coded = cw.bc.cdef_coded;
cw.bc.blocks.set_segmentation_idx(tile_bo, bsize, part_decision.sidx);
let (tx_size, tx_type) = rdo_tx_size_type(
fi, ts, cw, bsize, tile_bo, mode_luma, ref_frames, mvs, skip,
);
let mut mv_stack = ArrayVec::<[CandidateMV; 9]>::new();
let is_compound = ref_frames[1] != NONE_FRAME;
let mode_context = cw.find_mvrefs(
tile_bo,
ref_frames,
&mut mv_stack,
bsize,
fi,
is_compound,
);
if !mode_luma.is_intra() {
if is_compound && mode_luma != PredictionMode::GLOBAL_GLOBALMV {
let match0 = mv_stack[0].this_mv.row == mvs[0].row
&& mv_stack[0].this_mv.col == mvs[0].col;
let match1 = mv_stack[0].comp_mv.row == mvs[1].row
&& mv_stack[0].comp_mv.col == mvs[1].col;
let match2 = mv_stack[1].this_mv.row == mvs[0].row
&& mv_stack[1].this_mv.col == mvs[0].col;
let match3 = mv_stack[1].comp_mv.row == mvs[1].row
&& mv_stack[1].comp_mv.col == mvs[1].col;
let match4 = mv_stack.len() > 2 && mv_stack[2].this_mv == mvs[0];
let match5 = mv_stack.len() > 2 && mv_stack[2].comp_mv == mvs[1];
let match6 = mv_stack.len() > 3 && mv_stack[3].this_mv == mvs[0];
let match7 = mv_stack.len() > 3 && mv_stack[3].comp_mv == mvs[1];
mode_luma = if match0 && match1 {
PredictionMode::NEAREST_NEARESTMV
} else if match2 && match3 {
PredictionMode::NEAR_NEAR0MV
} else if match4 && match5 {
PredictionMode::NEAR_NEAR1MV
} else if match6 && match7 {
PredictionMode::NEAR_NEAR2MV
} else if match0 {
PredictionMode::NEAREST_NEWMV
} else if match1 {
PredictionMode::NEW_NEARESTMV
} else {
PredictionMode::NEW_NEWMV
};
if mode_luma != PredictionMode::NEAREST_NEARESTMV
&& mvs[0].row == 0
&& mvs[0].col == 0
&& mvs[1].row == 0
&& mvs[1].col == 0
{
mode_luma = PredictionMode::GLOBAL_GLOBALMV;
}
mode_chroma = mode_luma;
} else if !is_compound && mode_luma != PredictionMode::GLOBALMV {
mode_luma = PredictionMode::NEWMV;
for (c, m) in mv_stack.iter().take(4).zip(
[
PredictionMode::NEARESTMV,
PredictionMode::NEAR0MV,
PredictionMode::NEAR1MV,
PredictionMode::NEAR2MV,
]
.iter(),
) {
if c.this_mv.row == mvs[0].row && c.this_mv.col == mvs[0].col {
mode_luma = *m;
}
}
if mode_luma == PredictionMode::NEWMV
&& mvs[0].row == 0
&& mvs[0].col == 0
{
mode_luma = if mv_stack.is_empty() {
PredictionMode::NEARESTMV
} else if mv_stack.len() == 1 {
PredictionMode::NEAR0MV
} else {
PredictionMode::GLOBALMV
};
}
mode_chroma = mode_luma;
}
save_block_motion(
ts,
part_decision.bsize,
part_decision.bo,
part_decision.ref_frames[0].to_index(),
part_decision.mvs[0],
);
}
cdef_coded = encode_block_pre_cdef(
&fi.sequence,
ts,
cw,
if cdef_coded { w_post_cdef } else { w_pre_cdef },
bsize,
tile_bo,
skip,
);
encode_block_post_cdef(
fi,
ts,
cw,
if cdef_coded { w_post_cdef } else { w_pre_cdef },
mode_luma,
mode_chroma,
part_decision.angle_delta,
ref_frames,
mvs,
bsize,
tile_bo,
skip,
cfl,
tx_size,
tx_type,
mode_context,
&mv_stack,
RDOType::PixelDistRealRate,
true,
true,
);
}
PARTITION_SPLIT | PARTITION_HORZ | PARTITION_VERT => {
if !rdo_output.part_modes.is_empty() {
debug_assert!(can_split && !must_split);
assert!(subsize != BlockSize::BLOCK_INVALID);
for mode in rdo_output.part_modes {
use std::iter::once;
encode_partition_topdown(
fi,
ts,
cw,
w_pre_cdef,
w_post_cdef,
subsize,
mode.bo,
&Some(PartitionGroupParameters {
rd_cost: mode.rd_cost,
part_type: PartitionType::PARTITION_NONE,
part_modes: once(mode).collect(),
}),
inter_cfg,
);
}
} else {
debug_assert!(must_split);
let hbsw = subsize.width_mi();
let hbsh = subsize.height_mi();
let four_partitions = [
tile_bo,
TileBlockOffset(BlockOffset {
x: tile_bo.0.x + hbsw as usize,
y: tile_bo.0.y,
}),
TileBlockOffset(BlockOffset {
x: tile_bo.0.x,
y: tile_bo.0.y + hbsh as usize,
}),
TileBlockOffset(BlockOffset {
x: tile_bo.0.x + hbsw as usize,
y: tile_bo.0.y + hbsh as usize,
}),
];
let partitions = get_sub_partitions(&four_partitions, partition);
partitions.iter().for_each(|&offset| {
encode_partition_topdown(
fi,
ts,
cw,
w_pre_cdef,
w_post_cdef,
subsize,
offset,
&None,
inter_cfg,
);
});
}
}
_ => unreachable!(),
}
if is_square
&& bsize >= BlockSize::BLOCK_8X8
&& (bsize == BlockSize::BLOCK_8X8
|| partition != PartitionType::PARTITION_SPLIT)
{
cw.bc.update_partition_context(tile_bo, subsize, bsize);
}
}
fn get_initial_cdfcontext<T: Pixel>(fi: &FrameInvariants<T>) -> CDFContext {
let cdf = if fi.primary_ref_frame == PRIMARY_REF_NONE {
None
} else {
let ref_frame_idx = fi.ref_frames[fi.primary_ref_frame as usize] as usize;
let ref_frame = fi.rec_buffer.frames[ref_frame_idx].as_ref();
ref_frame.map(|rec| rec.cdfs)
};
cdf.unwrap_or_else(|| CDFContext::new(fi.base_q_idx))
}
#[hawktracer(encode_tile_group)]
fn encode_tile_group<T: Pixel>(
fi: &FrameInvariants<T>, fs: &mut FrameState<T>, inter_cfg: &InterConfig,
) -> Vec<u8> {
let planes =
if fi.sequence.chroma_sampling == ChromaSampling::Cs400 { 1 } else { 3 };
let mut blocks = FrameBlocks::new(fi.w_in_b, fi.h_in_b);
let ti = &fi.sequence.tiling;
let initial_cdf = get_initial_cdfcontext(fi);
let mut cdfs = vec![initial_cdf; ti.tile_count()];
let (raw_tiles, tile_states): (Vec<_>, Vec<_>) = ti
.tile_iter_mut(fs, &mut blocks)
.zip(cdfs.iter_mut())
.collect::<Vec<_>>()
.into_par_iter()
.map(|(mut ctx, cdf)| {
let raw = encode_tile(fi, &mut ctx.ts, cdf, &mut ctx.tb, inter_cfg);
(raw, ctx.ts)
})
.unzip();
let stats =
tile_states.into_iter().map(|ts| ts.enc_stats).collect::<Vec<_>>();
for tile_stats in stats {
fs.enc_stats += &tile_stats;
}
let levels;
{
let ts = &mut fs.as_tile_state_mut();
let rec = &mut ts.rec;
levels = deblock_filter_optimize(
fi,
&rec.as_const(),
&ts.input.as_tile(),
&blocks.as_tile_blocks(),
fi.width,
fi.height,
);
}
fs.deblock.levels = levels;
if fs.deblock.levels[0] != 0 || fs.deblock.levels[1] != 0 {
let ts = &mut fs.as_tile_state_mut();
let rec = &mut ts.rec;
deblock_filter_frame(
ts.deblock,
rec,
&blocks.as_tile_blocks(),
fi.width,
fi.height,
fi.sequence.bit_depth,
planes,
);
}
if fi.sequence.enable_restoration {
let deblocked_frame = fs.rec.clone();
if fi.sequence.enable_cdef {
let ts = &mut fs.as_tile_state_mut();
let rec = &mut ts.rec;
cdef_filter_tile(fi, &deblocked_frame, &blocks.as_tile_blocks(), rec);
}
fs.restoration.lrf_filter_frame(
Arc::make_mut(&mut fs.rec),
&deblocked_frame,
fi,
);
} else {
if fi.sequence.enable_cdef {
let deblocked_frame = fs.rec.clone();
let ts = &mut fs.as_tile_state_mut();
let rec = &mut ts.rec;
cdef_filter_tile(fi, &deblocked_frame, &blocks.as_tile_blocks(), rec);
}
}
let (idx_max, max_len) = raw_tiles
.iter()
.map(Vec::len)
.enumerate()
.max_by_key(|&(_, len)| len)
.unwrap();
if !fi.disable_frame_end_update_cdf {
fs.context_update_tile_id = idx_max;
fs.cdfs = cdfs[idx_max];
fs.cdfs.reset_counts();
}
let max_tile_size_bytes = ((max_len.ilog() + 7) / 8) as u32;
debug_assert!(max_tile_size_bytes > 0 && max_tile_size_bytes <= 4);
fs.max_tile_size_bytes = max_tile_size_bytes;
build_raw_tile_group(ti, &raw_tiles, max_tile_size_bytes)
}
fn build_raw_tile_group(
ti: &TilingInfo, raw_tiles: &[Vec<u8>], max_tile_size_bytes: u32,
) -> Vec<u8> {
let mut raw = Vec::new();
let mut bw = BitWriter::endian(&mut raw, BigEndian);
if ti.cols * ti.rows > 1 {
bw.write_bit(false).unwrap();
}
bw.byte_align().unwrap();
for (i, raw_tile) in raw_tiles.iter().enumerate() {
let last = raw_tiles.len() - 1;
if i != last {
let tile_size_minus_1 = raw_tile.len() - 1;
bw.write_le(max_tile_size_bytes, tile_size_minus_1 as u64).unwrap();
}
bw.write_bytes(raw_tile).unwrap();
}
raw
}
pub struct SBSQueueEntry {
pub sbo: TileSuperBlockOffset,
pub lru_index: [i32; MAX_PLANES],
pub cdef_coded: bool,
pub w_pre_cdef: WriterBase<WriterRecorder>,
pub w_post_cdef: WriterBase<WriterRecorder>,
}
fn check_lf_queue<T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
cw: &mut ContextWriter, w: &mut WriterBase<WriterEncoder>,
sbs_q: &mut VecDeque<SBSQueueEntry>, last_lru_ready: &mut [i32; 3],
last_lru_rdoed: &mut [i32; 3], last_lru_coded: &mut [i32; 3],
deblock_p: bool,
) {
let mut check_queue = true;
let planes = if fi.sequence.chroma_sampling == ChromaSampling::Cs400 {
1
} else {
MAX_PLANES
};
while check_queue {
if let Some(qe) = sbs_q.front_mut() {
for pli in 0..planes {
if qe.lru_index[pli] > last_lru_ready[pli] {
check_queue = false;
break;
}
}
if check_queue {
if qe.cdef_coded || fi.sequence.enable_restoration {
let mut already_rdoed = false;
for pli in 0..planes {
if qe.lru_index[pli] != -1
&& qe.lru_index[pli] <= last_lru_rdoed[pli]
{
already_rdoed = true;
break;
}
}
if !already_rdoed {
rdo_loop_decision(qe.sbo, fi, ts, cw, w, deblock_p);
for pli in 0..planes {
if qe.lru_index[pli] != -1
&& last_lru_rdoed[pli] < qe.lru_index[pli]
{
last_lru_rdoed[pli] = qe.lru_index[pli];
}
}
}
}
if fi.sequence.enable_restoration {
for pli in 0..planes {
if qe.lru_index[pli] != -1
&& last_lru_coded[pli] < qe.lru_index[pli]
{
last_lru_coded[pli] = qe.lru_index[pli];
cw.write_lrf(w, fi, &mut ts.restoration, qe.sbo, pli);
}
}
}
qe.w_pre_cdef.replay(w);
if qe.cdef_coded {
let cdef_index = cw.bc.blocks.get_cdef(qe.sbo);
cw.write_cdef(w, cdef_index, fi.cdef_bits);
qe.w_post_cdef.replay(w);
}
sbs_q.pop_front();
}
} else {
check_queue = false;
}
}
}
#[hawktracer(encode_tile)]
fn encode_tile<'a, T: Pixel>(
fi: &FrameInvariants<T>, ts: &mut TileStateMut<'_, T>,
fc: &'a mut CDFContext, blocks: &'a mut TileBlocksMut<'a>,
inter_cfg: &InterConfig,
) -> Vec<u8> {
let mut w = WriterEncoder::new();
let planes =
if fi.sequence.chroma_sampling == ChromaSampling::Cs400 { 1 } else { 3 };
let bc = BlockContext::new(blocks);
let mut cw = ContextWriter::new(fc, bc);
let mut sbs_q: VecDeque<SBSQueueEntry> = VecDeque::new();
let mut last_lru_ready = [-1; 3];
let mut last_lru_rdoed = [-1; 3];
let mut last_lru_coded = [-1; 3];
for sby in 0..ts.sb_height {
cw.bc.reset_left_contexts(planes);
for sbx in 0..ts.sb_width {
let tile_sbo = TileSuperBlockOffset(SuperBlockOffset { x: sbx, y: sby });
let mut sbs_qe = SBSQueueEntry {
sbo: tile_sbo,
lru_index: [-1; MAX_PLANES],
cdef_coded: false,
w_pre_cdef: WriterRecorder::new(),
w_post_cdef: WriterRecorder::new(),
};
let tile_bo = tile_sbo.block_offset(0, 0);
cw.bc.cdef_coded = false;
cw.bc.code_deltas = fi.delta_q_present;
let is_straddle_sbx =
tile_bo.0.x + BlockSize::BLOCK_64X64.width_mi() > ts.mi_width;
let is_straddle_sby =
tile_bo.0.y + BlockSize::BLOCK_64X64.height_mi() > ts.mi_height;
if fi.config.speed_settings.encode_bottomup
|| is_straddle_sbx
|| is_straddle_sby
{
encode_partition_bottomup(
fi,
ts,
&mut cw,
&mut sbs_qe.w_pre_cdef,
&mut sbs_qe.w_post_cdef,
BlockSize::BLOCK_64X64,
tile_bo,
std::f64::MAX,
inter_cfg,
);
} else {
encode_partition_topdown(
fi,
ts,
&mut cw,
&mut sbs_qe.w_pre_cdef,
&mut sbs_qe.w_post_cdef,
BlockSize::BLOCK_64X64,
tile_bo,
&None,
inter_cfg,
);
}
{
let mut check_queue = false;
sbs_qe.cdef_coded = cw.bc.cdef_coded;
for pli in 0..planes {
if let Some((lru_x, lru_y)) =
ts.restoration.planes[pli].restoration_unit_index(tile_sbo, false)
{
let lru_index = ts.restoration.planes[pli]
.restoration_unit_countable(lru_x, lru_y)
as i32;
sbs_qe.lru_index[pli] = lru_index;
if ts.restoration.planes[pli]
.restoration_unit_last_sb_for_rdo(fi, ts.sbo, tile_sbo)
{
last_lru_ready[pli] = lru_index;
check_queue = true;
}
} else {
sbs_qe.lru_index[pli] = -1;
check_queue = true;
}
}
sbs_q.push_back(sbs_qe);
if check_queue && !fi.sequence.enable_delayed_loopfilter_rdo {
check_lf_queue(
fi,
ts,
&mut cw,
&mut w,
&mut sbs_q,
&mut last_lru_ready,
&mut last_lru_rdoed,
&mut last_lru_coded,
true,
);
}
}
}
}
if fi.sequence.enable_delayed_loopfilter_rdo {
let deblock_levels = deblock_filter_optimize(
fi,
&ts.rec.as_const(),
&ts.input_tile,
&cw.bc.blocks.as_const(),
fi.width,
fi.height,
);
if deblock_levels[0] != 0 || deblock_levels[1] != 0 {
let rec_copy = if planes == 3 {
vec![
ts.rec.planes[0].scratch_copy(),
ts.rec.planes[1].scratch_copy(),
ts.rec.planes[2].scratch_copy(),
]
} else {
vec![ts.rec.planes[0].scratch_copy()]
};
let mut deblock_copy = *ts.deblock;
deblock_copy.levels = deblock_levels;
deblock_filter_frame(
&deblock_copy,
&mut ts.rec,
&cw.bc.blocks.as_const(),
fi.width,
fi.height,
fi.sequence.bit_depth,
planes,
);
check_lf_queue(
fi,
ts,
&mut cw,
&mut w,
&mut sbs_q,
&mut last_lru_ready,
&mut last_lru_rdoed,
&mut last_lru_coded,
false,
);
for pli in 0..planes {
let dst = &mut ts.rec.planes[pli];
let src = &rec_copy[pli];
for (dst_row, src_row) in dst.rows_iter_mut().zip(src.rows_iter()) {
for (out, input) in dst_row.iter_mut().zip(src_row) {
*out = *input;
}
}
}
} else {
check_lf_queue(
fi,
ts,
&mut cw,
&mut w,
&mut sbs_q,
&mut last_lru_ready,
&mut last_lru_rdoed,
&mut last_lru_coded,
false,
);
}
}
assert!(
sbs_q.is_empty(),
"Superblock queue not empty in tile at offset {}:{}",
ts.sbo.0.x,
ts.sbo.0.y
);
w.done()
}
#[allow(unused)]
fn write_tile_group_header(tile_start_and_end_present_flag: bool) -> Vec<u8> {
let mut buf = Vec::new();
{
let mut bw = BitWriter::endian(&mut buf, BigEndian);
bw.write_bit(tile_start_and_end_present_flag).unwrap();
bw.byte_align().unwrap();
}
buf
}
pub fn encode_show_existing_frame<T: Pixel>(
fi: &FrameInvariants<T>, fs: &mut FrameState<T>, inter_cfg: &InterConfig,
) -> Vec<u8> {
debug_assert!(fi.show_existing_frame);
let obu_extension = 0;
let mut packet = Vec::new();
if fi.frame_type == FrameType::KEY {
write_key_frame_obus(&mut packet, fi, obu_extension).unwrap();
}
let mut buf1 = Vec::new();
let mut buf2 = Vec::new();
{
let mut bw2 = BitWriter::endian(&mut buf2, BigEndian);
bw2.write_frame_header_obu(fi, fs, inter_cfg).unwrap();
}
{
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_obu_header(ObuType::OBU_FRAME_HEADER, obu_extension).unwrap();
}
packet.write_all(&buf1).unwrap();
buf1.clear();
{
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_uleb128(buf2.len() as u64).unwrap();
}
packet.write_all(&buf1).unwrap();
buf1.clear();
packet.write_all(&buf2).unwrap();
buf2.clear();
let map_idx = fi.frame_to_show_map_idx as usize;
if let Some(ref rec) = fi.rec_buffer.frames[map_idx] {
let fs_rec = Arc::make_mut(&mut fs.rec);
let planes =
if fi.sequence.chroma_sampling == ChromaSampling::Cs400 { 1 } else { 3 };
for p in 0..planes {
fs_rec.planes[p].data.copy_from_slice(&rec.frame.planes[p].data);
}
}
packet
}
fn get_initial_segmentation<T: Pixel>(
fi: &FrameInvariants<T>,
) -> SegmentationState {
let segmentation = if fi.primary_ref_frame == PRIMARY_REF_NONE {
None
} else {
let ref_frame_idx = fi.ref_frames[fi.primary_ref_frame as usize] as usize;
let ref_frame = fi.rec_buffer.frames[ref_frame_idx].as_ref();
ref_frame.map(|rec| rec.segmentation)
};
segmentation.unwrap_or_default()
}
pub fn encode_frame<T: Pixel>(
fi: &FrameInvariants<T>, fs: &mut FrameState<T>, inter_cfg: &InterConfig,
) -> Vec<u8> {
debug_assert!(!fi.show_existing_frame);
debug_assert!(!fi.invalid);
let obu_extension = 0;
let mut packet = Vec::new();
if fi.enable_segmentation {
fs.segmentation = get_initial_segmentation(fi);
segmentation_optimize(fi, fs);
}
let tile_group = encode_tile_group(fi, fs, inter_cfg);
if fi.frame_type == FrameType::KEY {
write_key_frame_obus(&mut packet, fi, obu_extension).unwrap();
}
let mut buf1 = Vec::new();
let mut buf2 = Vec::new();
{
let mut bw2 = BitWriter::endian(&mut buf2, BigEndian);
bw2.write_frame_header_obu(fi, fs, inter_cfg).unwrap();
}
{
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_obu_header(ObuType::OBU_FRAME, obu_extension).unwrap();
}
packet.write_all(&buf1).unwrap();
buf1.clear();
{
let mut bw1 = BitWriter::endian(&mut buf1, BigEndian);
bw1.write_uleb128((buf2.len() + tile_group.len()) as u64).unwrap();
}
packet.write_all(&buf1).unwrap();
buf1.clear();
packet.write_all(&buf2).unwrap();
buf2.clear();
packet.write_all(&tile_group).unwrap();
packet
}
pub fn update_rec_buffer<T: Pixel>(
output_frameno: u64, fi: &mut FrameInvariants<T>, fs: &FrameState<T>,
) {
let rfs = Arc::new(ReferenceFrame {
order_hint: fi.order_hint,
width: fi.width as u32,
height: fi.height as u32,
render_width: fi.render_width,
render_height: fi.render_height,
frame: fs.rec.clone(),
input_hres: fs.input_hres.clone(),
input_qres: fs.input_qres.clone(),
cdfs: fs.cdfs,
frame_me_stats: fs.frame_me_stats.clone(),
output_frameno,
segmentation: fs.segmentation,
});
for i in 0..(REF_FRAMES as usize) {
if (fi.refresh_frame_flags & (1 << i)) != 0 {
fi.rec_buffer.frames[i] = Some(Arc::clone(&rfs));
fi.rec_buffer.deblock[i] = fs.deblock;
}
}
}
#[cfg(test)]
mod test {
use super::*;
#[test]
fn check_partition_types_order() {
assert_eq!(
RAV1E_PARTITION_TYPES[RAV1E_PARTITION_TYPES.len() - 1],
PartitionType::PARTITION_SPLIT
);
}
}