[nihav.git] / nihav-duck / src / codecs / truemotion2.rs

use nihav_core::codecs::*;
use nihav_core::io::byteio::*;
use nihav_core::io::bitreader::*;
use nihav_core::io::codebook::*;

#[repr(u8)]
enum TM2StreamType {
    CHigh = 0,
    CLow,
    LHigh,
    LLow,
    Update,
    Motion,
    BlockType,
    Num
}

#[repr(u8)]
#[derive(Debug,Clone,Copy)]
enum TM2BlockType {
    HiRes,
    MedRes,
    LowRes,
    NullRes,
    Update,
    Still,
    Motion
}

const TM2_BLOCK_TYPES: [TM2BlockType; 7] = [
    TM2BlockType::HiRes,  TM2BlockType::MedRes, TM2BlockType::LowRes, TM2BlockType::NullRes,
    TM2BlockType::Update, TM2BlockType::Still,  TM2BlockType::Motion
];

trait ReadLenEsc {
    fn read_len_esc(&mut self) -> DecoderResult<usize>;
}

const TM2_ESCAPE: usize = 0x80000000;

impl<'a> ReadLenEsc for ByteReader<'a> {
    fn read_len_esc(&mut self) -> DecoderResult<usize> {
        let len                                 = self.read_u32le()? as usize;
        if len == TM2_ESCAPE {
            let len2                            = self.read_u32le()? as usize;
            Ok(len2)
        } else {
            Ok(len)
        }
    }
}

struct HuffDef {
    val_bits:   u8,
    max_bits:   u8,
    nelems:     usize,
}

impl HuffDef {
    fn read(&mut self, br: &mut BitReader, codes: &mut Vec<FullCodebookDesc<u8>>, prefix: u32, len: u8) -> DecoderResult<()> {
        validate!(len <= self.max_bits);
        if !br.read_bool()? {
            validate!(codes.len() < self.nelems);
            let sym                             = br.read(self.val_bits)? as u8;
            codes.push(FullCodebookDesc { code: prefix, bits: len, sym });
        } else {
            self.read(br, codes, (prefix << 1) | 0, len + 1)?;
            self.read(br, codes, (prefix << 1) | 1, len + 1)?;
        }
        Ok(())
    }
}

struct HuffTree {
    cb:         Option<Codebook<u8>>,
    sym0:       u8,
}

impl HuffTree {
    fn new() -> Self {
        Self { cb: None, sym0: 0 }
    }
}

const TM2_MAX_DELTAS: usize = 64;

struct TM2Stream {
    tokens:     Vec<u8>,
    deltas:     [i32; TM2_MAX_DELTAS],
    pos:        usize,
}

impl Default for TM2Stream {
    fn default() -> Self {
        Self {
            tokens:     Vec::new(),
            deltas:     [0; TM2_MAX_DELTAS],
            pos:        0,
        }
    }
}

impl TM2Stream {
    fn read_header(&mut self, src: &[u8], br: &mut ByteReader) -> DecoderResult<()> {
        self.tokens.truncate(0);
        self.pos = 0;

        let len                                 = br.read_u32le()? as usize;
        let endpos = br.tell() + (len as u64) * 4;
        if len == 0 {
            return Ok(());
        }
        let ntoks                               = br.read_u32le()? as usize;
        validate!(ntoks < (1 << 24));
        if (ntoks & 1) != 0 {
            let dlen                            = br.read_len_esc()?;
            if (dlen as i32) > 0 {
                let rest_size = (endpos - br.tell()) as usize;
                let skip_size = self.read_deltas(&src[br.tell() as usize..][..rest_size])?;
                validate!(skip_size == dlen * 4);
                                                  br.read_skip(skip_size)?;
            }
        }
        let _len                                = br.read_len_esc()?;
        let _algo                               = br.read_u32le()?;

        let mut htree = HuffTree::new();
        let rest_size = (endpos - br.tell()) as usize;
        let skip_size = self.read_huff_tree(&src[br.tell() as usize..][..rest_size], &mut htree)?;
                                                  br.read_skip(skip_size)?;

        let len                                 = br.read_u32le()? as usize;
        validate!(br.tell() + (len as u64) * 4 <= endpos);
        if len > 0 {
            self.tokens.reserve(ntoks >> 1);
            let rest_size = (endpos - br.tell()) as usize;
            let skip_size = self.read_tokens(&src[br.tell() as usize..][..rest_size], &htree, ntoks >> 1)?;
                                                  br.read_skip(skip_size)?;
        } else {
            self.tokens.resize(ntoks >> 1, htree.sym0);
        }


        let pos = br.tell();
        validate!(pos <= endpos);
        let toskip = endpos - pos;
                                                  br.read_skip(toskip as usize)?;
        
        Ok(())
    }
    fn read_deltas(&mut self, src: &[u8]) -> DecoderResult<usize> {
        let mut br = BitReader::new(src, src.len(), BitReaderMode::LE32MSB);
        let coded_deltas                        = br.read(9)? as usize;
        let bits                                = br.read(5)? as u8;
        validate!((coded_deltas <= TM2_MAX_DELTAS) && (bits > 0));
        let mask = 1 << (bits - 1);
        let bias = 1 << bits;
        self.deltas = [0; TM2_MAX_DELTAS];
        for i in 0..coded_deltas {
            let val                             = br.read(bits)?;
            if (val & mask) != 0 {
                self.deltas[i] = (val as i32) - bias;
            } else {
                self.deltas[i] = val as i32;
            }
        }
        
        Ok(((br.tell() + 31) >> 5) << 2)
    }
    fn read_huff_tree(&mut self, src: &[u8], htree: &mut HuffTree) -> DecoderResult<usize> {
        let mut br = BitReader::new(src, src.len(), BitReaderMode::LE32MSB);

        let val_bits                            = br.read(5)? as u8;
        let max_bits                            = br.read(5)? as u8;
        let min_bits                            = br.read(5)? as u8;
        let nelems                              = br.read(17)? as usize;
        validate!(val_bits > 0 && val_bits <= 6);
        validate!(nelems > 0);
        validate!((max_bits < 25) && (min_bits <= max_bits));

        let mut codes: Vec<FullCodebookDesc<u8>> = Vec::with_capacity(nelems);
        let mut hdef = HuffDef { val_bits, max_bits, nelems };
        hdef.read(&mut br, &mut codes, 0, 0)?;
        htree.sym0 = codes[0].sym;
        if nelems > 1 {
            let mut cr = FullCodebookDescReader::new(codes);
            htree.cb = Some(Codebook::new(&mut cr, CodebookMode::MSB)?);
        }
        
        Ok(((br.tell() + 31) >> 5) << 2)
    }
    fn read_tokens(&mut self, src: &[u8], htree: &HuffTree, ntoks: usize) -> DecoderResult<usize> {
        let mut br = BitReader::new(src, src.len(), BitReaderMode::LE32MSB);

        if let Some(ref cb) = htree.cb {
            for _ in 0..ntoks {
                let tok                         = br.read_cb(cb)?;
                self.tokens.push(tok);
            }
        }
        
        Ok(((br.tell() + 31) >> 5) << 2)
    }

    fn get_block_type(&mut self) -> DecoderResult<u8> {
        validate!(self.pos < self.tokens.len());
        let res = self.tokens[self.pos];
        self.pos += 1;
        Ok(res)
    }
    fn get_token(&mut self) -> DecoderResult<i32> {
        validate!(self.pos < self.tokens.len());
        let idx = self.tokens[self.pos] as usize;
        validate!(idx < TM2_MAX_DELTAS);
        self.pos += 1;
        Ok(self.deltas[idx])
    }
}

#[derive(Default)]
struct DeltaState {
    dy: [i32; 4],
    dc: [[i32; 2]; 2],
}

impl DeltaState {
    fn apply_y(&mut self, dst: &mut [u8], mut yoff: usize, ystride: usize, ydeltas: &[i32; 16], last: &mut [i32]) {
        for y in 0..4 {
            let mut d = self.dy[y];
            for x in 0..4 {
                d += ydeltas[x + y * 4];
                last[x] += d;
                dst[yoff + x] = last[x].max(0).min(255) as u8;
            }
            self.dy[y] = d;
            yoff += ystride;
        }
    }
    fn apply_c(&mut self, dst: &mut [i16], mut coff: usize, cstride: usize, cdeltas: &[i32; 4], idx: usize, last: &mut [i32]) {
        for y in 0..2 {
            let mut d = self.dc[idx][y];
            for x in 0..2 {
                d += cdeltas[x + y * 2];
                last[x] += d;
                dst[coff + x] = last[x] as i16;
            }
            self.dc[idx][y] = d;
            coff += cstride;
        }
    }
    fn interpolate_y_low(&mut self, last: &mut [i32]) {
        let dsum = self.dy[0] + self.dy[1] + self.dy[2] + self.dy[3];
        last[1] = (last[0] - dsum + last[2]) >> 1;
        last[3] = (last[2] + last[4]) >> 1;

        let t0 = self.dy[0] + self.dy[1];
        let t1 = self.dy[2] + self.dy[3];
        self.dy[0] = t0 >> 1;
        self.dy[1] = t0 - (t0 >> 1);
        self.dy[2] = t1 >> 1;
        self.dy[3] = t1 - (t1 >> 1);
    }
    fn interpolate_y_null(&mut self, last: &mut [i32]) {
        let dsum = self.dy[0] + self.dy[1] + self.dy[2] + self.dy[3];
        let left = last[0] - dsum;
        let right = last[4];
        let diff = right - left;
        last[1] = left + (diff >> 2);
        last[2] = left + (diff >> 1);
        last[3] = right - (diff >> 2);

        let mut sum = left;
        self.dy[0] = (left + (dsum >> 2)) - sum;
        sum += self.dy[0];
        self.dy[1] = (left + (dsum >> 1)) - sum;
        sum += self.dy[1];
        self.dy[2] = (left + dsum - (dsum >> 2)) - sum;
        sum += self.dy[2];
        self.dy[3] = (left + dsum) - sum;
    }
    fn interpolate_c(&mut self, idx: usize, last: &mut [i32]) {
        let dsum = self.dc[idx][0] + self.dc[idx][1];
        let l = (last[0] + last[2] - dsum) >> 1;
        self.dc[idx][0] = dsum >> 1;
        self.dc[idx][1] = dsum - (dsum >> 1);
        last[1] = l;
    }
    fn recalc_y(&mut self, dst: &[u8], yoff: usize, ystride: usize, last: &mut [i32]) {
        let src = &dst[yoff+3..];
        self.dy[0] = (src[ystride * 0] as i32) - last[3];
        self.dy[1] = (src[ystride * 1] as i32) - (src[ystride * 0] as i32);
        self.dy[2] = (src[ystride * 2] as i32) - (src[ystride * 1] as i32);
        self.dy[3] = (src[ystride * 3] as i32) - (src[ystride * 2] as i32);
        let src = &dst[yoff + 3 * ystride..];
        for x in 0..4 {
            last[x] = src[x] as i32;
        }
    }
    fn recalc_c(&mut self, dst: &[i16], coff: usize, cstride: usize, idx: usize, last: &mut [i32]) {
        self.dc[idx][0] = (dst[coff + 1] as i32) - last[1];
        self.dc[idx][1] = (dst[coff + 1 + cstride] as i32) - (dst[coff + 1] as i32);
        last[0] = dst[coff + cstride + 0] as i32;
        last[1] = dst[coff + cstride + 1] as i32;
    }
}

#[derive(Default)]
struct TM2Frame {
    ydata:      Vec<u8>,
    udata:      Vec<i16>,
    vdata:      Vec<i16>,
    ystride:    usize,
    cstride:    usize,
}

impl TM2Frame {
    fn alloc(width: usize, height: usize) -> Self {
        let ystride = (width + 3) & !3;
        let ysize = ystride * ((height + 3) & !3);
        let mut ydata = Vec::with_capacity(ysize);
        ydata.resize(ysize, 0);
        let cstride = ystride >> 1;
        let csize = cstride * (((height + 3) & !3) >> 1);
        let mut udata = Vec::with_capacity(csize);
        udata.resize(csize, 0);
        let mut vdata = Vec::with_capacity(csize);
        vdata.resize(csize, 0);
        Self { ydata, udata, vdata, ystride, cstride }
    }
}

#[derive(Default)]
struct TM2Decoder {
    info:       NACodecInfoRef,
    streams:    [TM2Stream; TM2StreamType::Num as usize],
    width:      usize,
    height:     usize,
    cur_frame:  TM2Frame,
    prev_frame: TM2Frame,
}

impl TM2Decoder {
    fn new() -> Self { Self::default() }
    fn decode_blocks(&mut self) -> DecoderResult<bool> {
        let ydst = &mut self.cur_frame.ydata;
        let udst = &mut self.cur_frame.udata;
        let vdst = &mut self.cur_frame.vdata;
        let ystride = self.cur_frame.ystride;
        let cstride = self.cur_frame.cstride;
        let mut offs: [usize; 2] = [0; 2];
        let mut is_intra = true;

        let bw = self.width >> 2;
        let bh = self.height >> 2;
        validate!(self.streams[TM2StreamType::BlockType as usize].tokens.len() == bw * bh);

        let mut ydeltas: [i32; 16] = [0; 16];
        let mut cdeltas: [[i32; 4]; 2] = [[0; 4]; 2];
        let mut lasty: Vec<i32> = Vec::with_capacity(self.width + 1);
        lasty.resize(self.width + 1, 0);
        let mut lastu: Vec<i32> = Vec::with_capacity(self.width/2 + 1);
        lastu.resize(self.width/2 + 1, 0);
        let mut lastv: Vec<i32> = Vec::with_capacity(self.width/2 + 1);
        lastv.resize(self.width/2 + 1, 0);
        for by in 0..bh {
            let mut dstate = DeltaState::default();
            for bx in 0..bw {
                let bidx = self.streams[TM2StreamType::BlockType as usize].get_block_type()? as usize;
                validate!(bidx < TM2_BLOCK_TYPES.len());
                let btype = TM2_BLOCK_TYPES[bidx];
                match btype {
                    TM2BlockType::HiRes => {
                        for i in 0..4 {
                            cdeltas[0][i] = self.streams[TM2StreamType::CHigh as usize].get_token()?;
                            cdeltas[1][i] = self.streams[TM2StreamType::CHigh as usize].get_token()?;
                        }
                        dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
                        dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
                        for i in 0..4*4 {
                            ydeltas[i] = self.streams[TM2StreamType::LHigh as usize].get_token()?;
                        }
                        dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
                    },
                    TM2BlockType::MedRes => {
                        cdeltas = [[0; 4]; 2];
                        cdeltas[0][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
                        cdeltas[1][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
                        dstate.interpolate_c(0, &mut lastu[bx*2..]);
                        dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
                        dstate.interpolate_c(1, &mut lastv[bx*2..]);
                        dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
                        for i in 0..4*4 {
                            ydeltas[i] = self.streams[TM2StreamType::LHigh as usize].get_token()?;
                        }
                        dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
                    },
                    TM2BlockType::LowRes => {
                        cdeltas = [[0; 4]; 2];
                        cdeltas[0][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
                        cdeltas[1][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
                        dstate.interpolate_c(0, &mut lastu[bx*2..]);
                        dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
                        dstate.interpolate_c(1, &mut lastv[bx*2..]);
                        dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
                        ydeltas = [0; 16];
                        ydeltas[ 0] = self.streams[TM2StreamType::LLow as usize].get_token()?;
                        ydeltas[ 2] = self.streams[TM2StreamType::LLow as usize].get_token()?;
                        ydeltas[ 8] = self.streams[TM2StreamType::LLow as usize].get_token()?;
                        ydeltas[10] = self.streams[TM2StreamType::LLow as usize].get_token()?;
                        dstate.interpolate_y_low(&mut lasty[bx*4..]);
                        dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
                    },
                    TM2BlockType::NullRes => {
                        cdeltas = [[0; 4]; 2];
                        dstate.interpolate_c(0, &mut lastu[bx*2..]);
                        dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
                        dstate.interpolate_c(1, &mut lastv[bx*2..]);
                        dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
                        ydeltas = [0; 16];
                        dstate.interpolate_y_null(&mut lasty[bx*4..]);
                        dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
                    },
                    TM2BlockType::Update => {
                        is_intra = false;

                        let mut coff = offs[1] + bx * 2;
                        let usrc = &self.prev_frame.udata;
                        let vsrc = &self.prev_frame.vdata;
                        for _ in 0..2 {
                            for x in 0..2 {
                                let du = self.streams[TM2StreamType::Update as usize].get_token()?;
                                let dv = self.streams[TM2StreamType::Update as usize].get_token()?;
                                udst[coff + x] = usrc[coff + x] + (du as i16);
                                vdst[coff + x] = vsrc[coff + x] + (dv as i16);
                            }
                            coff += cstride;
                        }
                        dstate.recalc_c(udst, offs[1] + bx * 2, cstride, 0, &mut lastu[bx*2+1..]);
                        dstate.recalc_c(vdst, offs[1] + bx * 2, cstride, 1, &mut lastv[bx*2+1..]);
                        let mut yoff = offs[0] + bx * 4;
                        let ysrc = &self.prev_frame.ydata;
                        for _ in 0..4 {
                            for x in 0..4 {
                                let dy = self.streams[TM2StreamType::Update as usize].get_token()?;
                                ydst[yoff + x] = ((ysrc[yoff + x] as i32) + dy) as u8;
                            }
                            yoff += ystride;
                        }
                        dstate.recalc_y(ydst, offs[0] + bx * 4, ystride, &mut lasty[bx*4+1..]);
                    },
                    TM2BlockType::Still => {
                        is_intra = false;

                        let mut coff = offs[1] + bx * 2;
                        let usrc = &self.prev_frame.udata;
                        let vsrc = &self.prev_frame.vdata;
                        for _ in 0..2 {
                            for x in 0..2 {
                                udst[coff + x] = usrc[coff + x];
                                vdst[coff + x] = vsrc[coff + x];
                            }
                            coff += cstride;
                        }
                        dstate.recalc_c(udst, offs[1] + bx * 2, cstride, 0, &mut lastu[bx*2+1..]);
                        dstate.recalc_c(vdst, offs[1] + bx * 2, cstride, 1, &mut lastv[bx*2+1..]);
                        let mut yoff = offs[0] + bx * 4;
                        let ysrc = &self.prev_frame.ydata;
                        for _ in 0..4 {
                            for x in 0..4 {
                                ydst[yoff + x] = ysrc[yoff + x];
                            }
                            yoff += ystride;
                        }
                        dstate.recalc_y(ydst, offs[0] + bx * 4, ystride, &mut lasty[bx*4+1..]);
                    },
                    TM2BlockType::Motion => {
                        is_intra = false;

                        let mx = self.streams[TM2StreamType::Motion as usize].get_token()?;
                        let my = self.streams[TM2StreamType::Motion as usize].get_token()?;
                        let xpos = (((bx as i32) * 4) + mx).max(0).min((self.width  - 4) as i32) as usize;
                        let ypos = (((by as i32) * 4) + my).max(0).min((self.height - 4) as i32) as usize;
                        let mut coff = offs[1] + bx * 2;
                        let mut csoff = (xpos >> 1) + (ypos >> 1) * cstride;
                        let usrc = &self.prev_frame.udata;
                        let vsrc = &self.prev_frame.vdata;
                        for _ in 0..2 {
                            for x in 0..2 {
                                udst[coff + x] = usrc[csoff + x];
                                vdst[coff + x] = vsrc[csoff + x];
                            }
                            coff  += cstride;
                            csoff += cstride;
                        }
                        dstate.recalc_c(udst, offs[1] + bx * 2, cstride, 0, &mut lastu[bx*2+1..]);
                        dstate.recalc_c(vdst, offs[1] + bx * 2, cstride, 1, &mut lastv[bx*2+1..]);
                        let mut yoff = offs[0] + bx * 4;
                        let mut ysoff = xpos + ypos * ystride;
                        let ysrc = &self.prev_frame.ydata;
                        for _ in 0..4 {
                            for x in 0..4 {
                                ydst[yoff + x] = ysrc[ysoff + x];
                            }
                            yoff  += ystride;
                            ysoff += ystride;
                        }
                        dstate.recalc_y(ydst, offs[0] + bx * 4, ystride, &mut lasty[bx*4+1..]);
                    },
                };
            }
            offs[0] += ystride * 4;
            offs[1] += cstride * 2;
        }

        Ok(is_intra)
    }
    fn output_frame(&mut self, buf: &mut NAVideoBuffer<u8>) {
        let fmt = buf.get_info().get_format();
        let offs = [fmt.get_chromaton(0).unwrap().get_offset() as usize,
                    fmt.get_chromaton(1).unwrap().get_offset() as usize,
                    fmt.get_chromaton(2).unwrap().get_offset() as usize];
        let stride = buf.get_stride(0);
        let data = buf.get_data_mut().unwrap();
        let dst = data.as_mut_slice();

        let mut off = 0;
        let mut ysrc = 0;
        let mut csrc = 0;
        for y in 0..self.height {
            let out = &mut dst[off..];
            for (x, pic) in out.chunks_exact_mut(3).take(self.width).enumerate() {
                let y = self.cur_frame.ydata[ysrc + x] as i16;
                let u = self.cur_frame.udata[csrc + (x >> 1)];
                let v = self.cur_frame.vdata[csrc + (x >> 1)];
                pic[offs[0]] = (y + u).max(0).min(255) as u8;
                pic[offs[1]] = y.max(0).min(255) as u8;
                pic[offs[2]] = (y + v).max(0).min(255) as u8;
            }
            off += stride;
            ysrc += self.cur_frame.ystride;
            if (y & 1) != 0 {
                csrc += self.cur_frame.cstride;
            }
        }
    }
}

impl NADecoder for TM2Decoder {
    fn init(&mut self, info: NACodecInfoRef) -> DecoderResult<()> {
        if let NACodecTypeInfo::Video(vinfo) = info.get_properties() {
            let myinfo = NACodecTypeInfo::Video(NAVideoInfo::new(vinfo.get_width(), vinfo.get_height(), false, YUV410_FORMAT));
            self.width  = vinfo.get_width();
            self.height = vinfo.get_height();
            self.cur_frame  = TM2Frame::alloc(self.width, self.height);
            self.prev_frame = TM2Frame::alloc(self.width, self.height);
            self.info = NACodecInfo::new_ref(info.get_name(), myinfo, info.get_extradata()).into_ref();
            Ok(())
        } else {
            Err(DecoderError::InvalidData)
        }
    }
    fn decode(&mut self, pkt: &NAPacket) -> DecoderResult<NAFrameRef> {
        let src = pkt.get_buffer();
        validate!(src.len() >= 40 + (TM2StreamType::Num as usize) * 4 + 4);
        let mut mr = MemoryReader::new_read(&src);
        let mut br = ByteReader::new(&mut mr);

        let magic                               = br.read_u32be()?;
        validate!(magic == 0x100 || magic == 0x101);
                                                  br.read_skip(36)?;
        for str in self.streams.iter_mut() {
            str.read_header(&src, &mut br)?;
        }

        let myinfo = NAVideoInfo::new(self.width, self.height, false, RGB24_FORMAT);
        let bufret = alloc_video_buffer(myinfo, 2);
        if let Err(_) = bufret { return Err(DecoderError::InvalidData); }
        let bufinfo = bufret.unwrap();
        let mut buf = bufinfo.get_vbuf().unwrap();

        let is_intra = self.decode_blocks()?;
        self.output_frame(&mut buf);
        std::mem::swap(&mut self.cur_frame, &mut self.prev_frame);

        let mut frm = NAFrame::new_from_pkt(pkt, self.info.clone(), bufinfo);
        frm.set_keyframe(is_intra);
        frm.set_frame_type(if is_intra { FrameType::I } else { FrameType::P });
        Ok(Rc::new(RefCell::new(frm)))
    }
}

pub fn get_decoder() -> Box<NADecoder> {
    Box::new(TM2Decoder::new())
}

#[cfg(test)]
mod test {
    use nihav_core::codecs::RegisteredDecoders;
    use nihav_core::demuxers::RegisteredDemuxers;
    use nihav_core::test::dec_video::*;
    use crate::codecs::duck_register_all_codecs;
    use nihav_commonfmt::demuxers::generic_register_all_demuxers;
    #[test]
    fn test_tm2() {
        let mut dmx_reg = RegisteredDemuxers::new();
        generic_register_all_demuxers(&mut dmx_reg);
        let mut dec_reg = RegisteredDecoders::new();
        duck_register_all_codecs(&mut dec_reg);

        test_file_decoding("avi", "assets/Duck/tm20.avi", Some(16), true, false, None/*Some("tm2")*/, &dmx_reg, &dec_reg);
    }
}
Commit	Line	Data
8bde0eae KS	1	use nihav_core::codecs::*;
	2	use nihav_core::io::byteio::*;
	3	use nihav_core::io::bitreader::*;
	4	use nihav_core::io::codebook::*;
	5
	6	#[repr(u8)]
	7	enum TM2StreamType {
	8	CHigh = 0,
	9	CLow,
	10	LHigh,
	11	LLow,
	12	Update,
	13	Motion,
	14	BlockType,
	15	Num
	16	}
	17
	18	#[repr(u8)]
	19	#[derive(Debug,Clone,Copy)]
	20	enum TM2BlockType {
	21	HiRes,
	22	MedRes,
	23	LowRes,
	24	NullRes,
	25	Update,
	26	Still,
	27	Motion
	28	}
	29
	30	const TM2_BLOCK_TYPES: [TM2BlockType; 7] = [
	31	TM2BlockType::HiRes, TM2BlockType::MedRes, TM2BlockType::LowRes, TM2BlockType::NullRes,
	32	TM2BlockType::Update, TM2BlockType::Still, TM2BlockType::Motion
	33	];
	34
	35	trait ReadLenEsc {
	36	fn read_len_esc(&mut self) -> DecoderResult<usize>;
	37	}
	38
	39	const TM2_ESCAPE: usize = 0x80000000;
	40
	41	impl<'a> ReadLenEsc for ByteReader<'a> {
	42	fn read_len_esc(&mut self) -> DecoderResult<usize> {
	43	let len = self.read_u32le()? as usize;
	44	if len == TM2_ESCAPE {
	45	let len2 = self.read_u32le()? as usize;
	46	Ok(len2)
	47	} else {
	48	Ok(len)
	49	}
	50	}
	51	}
	52
	53	struct HuffDef {
	54	val_bits: u8,
	55	max_bits: u8,
	56	nelems: usize,
	57	}
	58
	59	impl HuffDef {
	60	fn read(&mut self, br: &mut BitReader, codes: &mut Vec<FullCodebookDesc<u8>>, prefix: u32, len: u8) -> DecoderResult<()> {
	61	validate!(len <= self.max_bits);
	62	if !br.read_bool()? {
	63	validate!(codes.len() < self.nelems);
	64	let sym = br.read(self.val_bits)? as u8;
65	codes.push(FullCodebookDesc { code: prefix, bits: len, sym });
66	} else {
67	self.read(br, codes, (prefix << 1) \| 0, len + 1)?;
68	self.read(br, codes, (prefix << 1) \| 1, len + 1)?;
69	}
70	Ok(())
71	}
72	}
73
74	struct HuffTree {
75	cb: Option<Codebook<u8>>,
76	sym0: u8,
77	}
78
79	impl HuffTree {
80	fn new() -> Self {
81	Self { cb: None, sym0: 0 }
82	}
83	}
84
85	const TM2_MAX_DELTAS: usize = 64;
86
87	struct TM2Stream {
88	tokens: Vec<u8>,
89	deltas: [i32; TM2_MAX_DELTAS],
90	pos: usize,
91	}
92
93	impl Default for TM2Stream {
94	fn default() -> Self {
95	Self {
96	tokens: Vec::new(),
97	deltas: [0; TM2_MAX_DELTAS],
98	pos: 0,
99	}
100	}
101	}
102
103	impl TM2Stream {
104	fn read_header(&mut self, src: &[u8], br: &mut ByteReader) -> DecoderResult<()> {
105	self.tokens.truncate(0);
106	self.pos = 0;
107
108	let len = br.read_u32le()? as usize;
109	let endpos = br.tell() + (len as u64) * 4;
110	if len == 0 {
111	return Ok(());
112	}
113	let ntoks = br.read_u32le()? as usize;
114	validate!(ntoks < (1 << 24));
115	if (ntoks & 1) != 0 {
116	let dlen = br.read_len_esc()?;
117	if (dlen as i32) > 0 {
118	let rest_size = (endpos - br.tell()) as usize;
119	let skip_size = self.read_deltas(&src[br.tell() as usize..][..rest_size])?;
120	validate!(skip_size == dlen * 4);
121	br.read_skip(skip_size)?;
122	}
123	}
124	let _len = br.read_len_esc()?;
125	let _algo = br.read_u32le()?;
126
127	let mut htree = HuffTree::new();
128	let rest_size = (endpos - br.tell()) as usize;
129	let skip_size = self.read_huff_tree(&src[br.tell() as usize..][..rest_size], &mut htree)?;
130	br.read_skip(skip_size)?;
131
132	let len = br.read_u32le()? as usize;
133	validate!(br.tell() + (len as u64) * 4 <= endpos);
134	if len > 0 {
135	self.tokens.reserve(ntoks >> 1);
136	let rest_size = (endpos - br.tell()) as usize;
137	let skip_size = self.read_tokens(&src[br.tell() as usize..][..rest_size], &htree, ntoks >> 1)?;
138	br.read_skip(skip_size)?;
139	} else {
140	self.tokens.resize(ntoks >> 1, htree.sym0);
141	}
142
143
144	let pos = br.tell();
145	validate!(pos <= endpos);
146	let toskip = endpos - pos;
147	br.read_skip(toskip as usize)?;
148
149	Ok(())
150	}
151	fn read_deltas(&mut self, src: &[u8]) -> DecoderResult<usize> {
152	let mut br = BitReader::new(src, src.len(), BitReaderMode::LE32MSB);
153	let coded_deltas = br.read(9)? as usize;
154	let bits = br.read(5)? as u8;
155	validate!((coded_deltas <= TM2_MAX_DELTAS) && (bits > 0));
156	let mask = 1 << (bits - 1);
157	let bias = 1 << bits;
158	self.deltas = [0; TM2_MAX_DELTAS];
159	for i in 0..coded_deltas {
160	let val = br.read(bits)?;
161	if (val & mask) != 0 {
162	self.deltas[i] = (val as i32) - bias;
163	} else {
164	self.deltas[i] = val as i32;
165	}
166	}
167
168	Ok(((br.tell() + 31) >> 5) << 2)
169	}
170	fn read_huff_tree(&mut self, src: &[u8], htree: &mut HuffTree) -> DecoderResult<usize> {
171	let mut br = BitReader::new(src, src.len(), BitReaderMode::LE32MSB);
172
173	let val_bits = br.read(5)? as u8;
174	let max_bits = br.read(5)? as u8;
175	let min_bits = br.read(5)? as u8;
176	let nelems = br.read(17)? as usize;
177	validate!(val_bits > 0 && val_bits <= 6);
178	validate!(nelems > 0);
179	validate!((max_bits < 25) && (min_bits <= max_bits));
180
181	let mut codes: Vec<FullCodebookDesc<u8>> = Vec::with_capacity(nelems);
182	let mut hdef = HuffDef { val_bits, max_bits, nelems };
183	hdef.read(&mut br, &mut codes, 0, 0)?;
184	htree.sym0 = codes[0].sym;
185	if nelems > 1 {
186	let mut cr = FullCodebookDescReader::new(codes);
187	htree.cb = Some(Codebook::new(&mut cr, CodebookMode::MSB)?);
188	}
189
190	Ok(((br.tell() + 31) >> 5) << 2)
191	}
192	fn read_tokens(&mut self, src: &[u8], htree: &HuffTree, ntoks: usize) -> DecoderResult<usize> {
193	let mut br = BitReader::new(src, src.len(), BitReaderMode::LE32MSB);
194
195	if let Some(ref cb) = htree.cb {
196	for _ in 0..ntoks {
197	let tok = br.read_cb(cb)?;
198	self.tokens.push(tok);
199	}
200	}
201
202	Ok(((br.tell() + 31) >> 5) << 2)
203	}
204
205	fn get_block_type(&mut self) -> DecoderResult<u8> {
206	validate!(self.pos < self.tokens.len());
207	let res = self.tokens[self.pos];
208	self.pos += 1;
209	Ok(res)
210	}
211	fn get_token(&mut self) -> DecoderResult<i32> {
212	validate!(self.pos < self.tokens.len());
213	let idx = self.tokens[self.pos] as usize;
214	validate!(idx < TM2_MAX_DELTAS);
215	self.pos += 1;
216	Ok(self.deltas[idx])
217	}
218	}
219
220	#[derive(Default)]
221	struct DeltaState {
222	dy: [i32; 4],
223	dc: [[i32; 2]; 2],
224	}
225
226	impl DeltaState {
227	fn apply_y(&mut self, dst: &mut [u8], mut yoff: usize, ystride: usize, ydeltas: &[i32; 16], last: &mut [i32]) {
228	for y in 0..4 {
229	let mut d = self.dy[y];
230	for x in 0..4 {
231	d += ydeltas[x + y * 4];
232	last[x] += d;
233	dst[yoff + x] = last[x].max(0).min(255) as u8;
234	}
235	self.dy[y] = d;
236	yoff += ystride;
237	}
238	}
239	fn apply_c(&mut self, dst: &mut [i16], mut coff: usize, cstride: usize, cdeltas: &[i32; 4], idx: usize, last: &mut [i32]) {
240	for y in 0..2 {
241	let mut d = self.dc[idx][y];
242	for x in 0..2 {
243	d += cdeltas[x + y * 2];
244	last[x] += d;
245	dst[coff + x] = last[x] as i16;
246	}
247	self.dc[idx][y] = d;
248	coff += cstride;
249	}
250	}
251	fn interpolate_y_low(&mut self, last: &mut [i32]) {
252	let dsum = self.dy[0] + self.dy[1] + self.dy[2] + self.dy[3];
253	last[1] = (last[0] - dsum + last[2]) >> 1;
254	last[3] = (last[2] + last[4]) >> 1;
255
256	let t0 = self.dy[0] + self.dy[1];
257	let t1 = self.dy[2] + self.dy[3];
258	self.dy[0] = t0 >> 1;
259	self.dy[1] = t0 - (t0 >> 1);
260	self.dy[2] = t1 >> 1;
261	self.dy[3] = t1 - (t1 >> 1);
262	}
263	fn interpolate_y_null(&mut self, last: &mut [i32]) {
264	let dsum = self.dy[0] + self.dy[1] + self.dy[2] + self.dy[3];
265	let left = last[0] - dsum;
266	let right = last[4];
267	let diff = right - left;
268	last[1] = left + (diff >> 2);
269	last[2] = left + (diff >> 1);
270	last[3] = right - (diff >> 2);
271
272	let mut sum = left;
273	self.dy[0] = (left + (dsum >> 2)) - sum;
274	sum += self.dy[0];
275	self.dy[1] = (left + (dsum >> 1)) - sum;
276	sum += self.dy[1];
277	self.dy[2] = (left + dsum - (dsum >> 2)) - sum;
278	sum += self.dy[2];
279	self.dy[3] = (left + dsum) - sum;
280	}
281	fn interpolate_c(&mut self, idx: usize, last: &mut [i32]) {
282	let dsum = self.dc[idx][0] + self.dc[idx][1];
283	let l = (last[0] + last[2] - dsum) >> 1;
284	self.dc[idx][0] = dsum >> 1;
285	self.dc[idx][1] = dsum - (dsum >> 1);
286	last[1] = l;
287	}
288	fn recalc_y(&mut self, dst: &[u8], yoff: usize, ystride: usize, last: &mut [i32]) {
289	let src = &dst[yoff+3..];
290	self.dy[0] = (src[ystride * 0] as i32) - last[3];
291	self.dy[1] = (src[ystride * 1] as i32) - (src[ystride * 0] as i32);
292	self.dy[2] = (src[ystride * 2] as i32) - (src[ystride * 1] as i32);
293	self.dy[3] = (src[ystride * 3] as i32) - (src[ystride * 2] as i32);
294	let src = &dst[yoff + 3 * ystride..];
295	for x in 0..4 {
296	last[x] = src[x] as i32;
297	}
298	}
299	fn recalc_c(&mut self, dst: &[i16], coff: usize, cstride: usize, idx: usize, last: &mut [i32]) {
300	self.dc[idx][0] = (dst[coff + 1] as i32) - last[1];
301	self.dc[idx][1] = (dst[coff + 1 + cstride] as i32) - (dst[coff + 1] as i32);
302	last[0] = dst[coff + cstride + 0] as i32;
303	last[1] = dst[coff + cstride + 1] as i32;
304	}
305	}
306
307	#[derive(Default)]
308	struct TM2Frame {
309	ydata: Vec<u8>,
310	udata: Vec<i16>,
311	vdata: Vec<i16>,
312	ystride: usize,
313	cstride: usize,
314	}
315
316	impl TM2Frame {
317	fn alloc(width: usize, height: usize) -> Self {
318	let ystride = (width + 3) & !3;
319	let ysize = ystride * ((height + 3) & !3);
320	let mut ydata = Vec::with_capacity(ysize);
321	ydata.resize(ysize, 0);
322	let cstride = ystride >> 1;
323	let csize = cstride * (((height + 3) & !3) >> 1);
324	let mut udata = Vec::with_capacity(csize);
325	udata.resize(csize, 0);
326	let mut vdata = Vec::with_capacity(csize);
327	vdata.resize(csize, 0);
328	Self { ydata, udata, vdata, ystride, cstride }
329	}
330	}
331
332	#[derive(Default)]
333	struct TM2Decoder {
2422d969	334	info: NACodecInfoRef,
8bde0eae KS	335	streams: [TM2Stream; TM2StreamType::Num as usize],
	336	width: usize,
	337	height: usize,
	338	cur_frame: TM2Frame,
	339	prev_frame: TM2Frame,
	340	}
	341
	342	impl TM2Decoder {
	343	fn new() -> Self { Self::default() }
	344	fn decode_blocks(&mut self) -> DecoderResult<bool> {
	345	let ydst = &mut self.cur_frame.ydata;
	346	let udst = &mut self.cur_frame.udata;
	347	let vdst = &mut self.cur_frame.vdata;
	348	let ystride = self.cur_frame.ystride;
	349	let cstride = self.cur_frame.cstride;
	350	let mut offs: [usize; 2] = [0; 2];
	351	let mut is_intra = true;
	352
	353	let bw = self.width >> 2;
	354	let bh = self.height >> 2;
	355	validate!(self.streams[TM2StreamType::BlockType as usize].tokens.len() == bw * bh);
	356
	357	let mut ydeltas: [i32; 16] = [0; 16];
	358	let mut cdeltas: [[i32; 4]; 2] = [[0; 4]; 2];
	359	let mut lasty: Vec<i32> = Vec::with_capacity(self.width + 1);
	360	lasty.resize(self.width + 1, 0);
	361	let mut lastu: Vec<i32> = Vec::with_capacity(self.width/2 + 1);
	362	lastu.resize(self.width/2 + 1, 0);
	363	let mut lastv: Vec<i32> = Vec::with_capacity(self.width/2 + 1);
	364	lastv.resize(self.width/2 + 1, 0);
	365	for by in 0..bh {
	366	let mut dstate = DeltaState::default();
	367	for bx in 0..bw {
	368	let bidx = self.streams[TM2StreamType::BlockType as usize].get_block_type()? as usize;
	369	validate!(bidx < TM2_BLOCK_TYPES.len());
	370	let btype = TM2_BLOCK_TYPES[bidx];
	371	match btype {
	372	TM2BlockType::HiRes => {
	373	for i in 0..4 {
	374	cdeltas[0][i] = self.streams[TM2StreamType::CHigh as usize].get_token()?;
	375	cdeltas[1][i] = self.streams[TM2StreamType::CHigh as usize].get_token()?;
	376	}
	377	dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
	378	dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
	379	for i in 0..4*4 {
	380	ydeltas[i] = self.streams[TM2StreamType::LHigh as usize].get_token()?;
	381	}
	382	dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
	383	},
	384	TM2BlockType::MedRes => {
	385	cdeltas = [[0; 4]; 2];
	386	cdeltas[0][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
	387	cdeltas[1][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
	388	dstate.interpolate_c(0, &mut lastu[bx*2..]);
	389	dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
	390	dstate.interpolate_c(1, &mut lastv[bx*2..]);
	391	dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
	392	for i in 0..4*4 {
	393	ydeltas[i] = self.streams[TM2StreamType::LHigh as usize].get_token()?;
	394	}
	395	dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
	396	},
	397	TM2BlockType::LowRes => {
	398	cdeltas = [[0; 4]; 2];
399	cdeltas[0][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
400	cdeltas[1][0] = self.streams[TM2StreamType::CLow as usize].get_token()?;
401	dstate.interpolate_c(0, &mut lastu[bx*2..]);
402	dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
403	dstate.interpolate_c(1, &mut lastv[bx*2..]);
404	dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
405	ydeltas = [0; 16];
406	ydeltas[ 0] = self.streams[TM2StreamType::LLow as usize].get_token()?;
407	ydeltas[ 2] = self.streams[TM2StreamType::LLow as usize].get_token()?;
408	ydeltas[ 8] = self.streams[TM2StreamType::LLow as usize].get_token()?;
409	ydeltas[10] = self.streams[TM2StreamType::LLow as usize].get_token()?;
410	dstate.interpolate_y_low(&mut lasty[bx*4..]);
411	dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
412	},
413	TM2BlockType::NullRes => {
414	cdeltas = [[0; 4]; 2];
415	dstate.interpolate_c(0, &mut lastu[bx*2..]);
416	dstate.apply_c(udst, offs[1] + bx * 2, cstride, &cdeltas[0], 0, &mut lastu[bx*2+1..]);
417	dstate.interpolate_c(1, &mut lastv[bx*2..]);
418	dstate.apply_c(vdst, offs[1] + bx * 2, cstride, &cdeltas[1], 1, &mut lastv[bx*2+1..]);
419	ydeltas = [0; 16];
420	dstate.interpolate_y_null(&mut lasty[bx*4..]);
421	dstate.apply_y(ydst, offs[0] + bx * 4, ystride, &ydeltas, &mut lasty[bx*4+1..]);
422	},
423	TM2BlockType::Update => {
424	is_intra = false;
425
426	let mut coff = offs[1] + bx * 2;
427	let usrc = &self.prev_frame.udata;
428	let vsrc = &self.prev_frame.vdata;
429	for _ in 0..2 {
430	for x in 0..2 {
431	let du = self.streams[TM2StreamType::Update as usize].get_token()?;
432	let dv = self.streams[TM2StreamType::Update as usize].get_token()?;
433	udst[coff + x] = usrc[coff + x] + (du as i16);
434	vdst[coff + x] = vsrc[coff + x] + (dv as i16);
435	}
436	coff += cstride;
437	}
438	dstate.recalc_c(udst, offs[1] + bx * 2, cstride, 0, &mut lastu[bx*2+1..]);
439	dstate.recalc_c(vdst, offs[1] + bx * 2, cstride, 1, &mut lastv[bx*2+1..]);
440	let mut yoff = offs[0] + bx * 4;
441	let ysrc = &self.prev_frame.ydata;
442	for _ in 0..4 {
443	for x in 0..4 {
444	let dy = self.streams[TM2StreamType::Update as usize].get_token()?;
445	ydst[yoff + x] = ((ysrc[yoff + x] as i32) + dy) as u8;
446	}
447	yoff += ystride;
448	}
449	dstate.recalc_y(ydst, offs[0] + bx * 4, ystride, &mut lasty[bx*4+1..]);
450	},
451	TM2BlockType::Still => {
452	is_intra = false;
453
454	let mut coff = offs[1] + bx * 2;
455	let usrc = &self.prev_frame.udata;
456	let vsrc = &self.prev_frame.vdata;
457	for _ in 0..2 {
458	for x in 0..2 {
459	udst[coff + x] = usrc[coff + x];
460	vdst[coff + x] = vsrc[coff + x];
461	}
462	coff += cstride;
463	}
464	dstate.recalc_c(udst, offs[1] + bx * 2, cstride, 0, &mut lastu[bx*2+1..]);
465	dstate.recalc_c(vdst, offs[1] + bx * 2, cstride, 1, &mut lastv[bx*2+1..]);
466	let mut yoff = offs[0] + bx * 4;
467	let ysrc = &self.prev_frame.ydata;
468	for _ in 0..4 {
469	for x in 0..4 {
470	ydst[yoff + x] = ysrc[yoff + x];
471	}
472	yoff += ystride;
473	}
474	dstate.recalc_y(ydst, offs[0] + bx * 4, ystride, &mut lasty[bx*4+1..]);
475	},
476	TM2BlockType::Motion => {
477	is_intra = false;
478
479	let mx = self.streams[TM2StreamType::Motion as usize].get_token()?;
480	let my = self.streams[TM2StreamType::Motion as usize].get_token()?;
481	let xpos = (((bx as i32) * 4) + mx).max(0).min((self.width - 4) as i32) as usize;
482	let ypos = (((by as i32) * 4) + my).max(0).min((self.height - 4) as i32) as usize;
483	let mut coff = offs[1] + bx * 2;
484	let mut csoff = (xpos >> 1) + (ypos >> 1) * cstride;
485	let usrc = &self.prev_frame.udata;
486	let vsrc = &self.prev_frame.vdata;
487	for _ in 0..2 {
488	for x in 0..2 {
489	udst[coff + x] = usrc[csoff + x];
490	vdst[coff + x] = vsrc[csoff + x];
491	}
492	coff += cstride;
493	csoff += cstride;
494	}
495	dstate.recalc_c(udst, offs[1] + bx * 2, cstride, 0, &mut lastu[bx*2+1..]);
496	dstate.recalc_c(vdst, offs[1] + bx * 2, cstride, 1, &mut lastv[bx*2+1..]);
497	let mut yoff = offs[0] + bx * 4;
498	let mut ysoff = xpos + ypos * ystride;
499	let ysrc = &self.prev_frame.ydata;
500	for _ in 0..4 {
501	for x in 0..4 {
502	ydst[yoff + x] = ysrc[ysoff + x];
503	}
504	yoff += ystride;
505	ysoff += ystride;
506	}
507	dstate.recalc_y(ydst, offs[0] + bx * 4, ystride, &mut lasty[bx*4+1..]);
508	},
509	};
510	}
511	offs[0] += ystride * 4;
512	offs[1] += cstride * 2;
513	}
514
515	Ok(is_intra)
516	}
517	fn output_frame(&mut self, buf: &mut NAVideoBuffer<u8>) {
518	let fmt = buf.get_info().get_format();
519	let offs = [fmt.get_chromaton(0).unwrap().get_offset() as usize,
520	fmt.get_chromaton(1).unwrap().get_offset() as usize,
521	fmt.get_chromaton(2).unwrap().get_offset() as usize];
522	let stride = buf.get_stride(0);
1a967e6b	523	let data = buf.get_data_mut().unwrap();
8bde0eae KS	524	let dst = data.as_mut_slice();
	525
	526	let mut off = 0;
	527	let mut ysrc = 0;
	528	let mut csrc = 0;
	529	for y in 0..self.height {
	530	let out = &mut dst[off..];
	531	for (x, pic) in out.chunks_exact_mut(3).take(self.width).enumerate() {
	532	let y = self.cur_frame.ydata[ysrc + x] as i16;
	533	let u = self.cur_frame.udata[csrc + (x >> 1)];
	534	let v = self.cur_frame.vdata[csrc + (x >> 1)];
	535	pic[offs[0]] = (y + u).max(0).min(255) as u8;
	536	pic[offs[1]] = y.max(0).min(255) as u8;
	537	pic[offs[2]] = (y + v).max(0).min(255) as u8;
	538	}
	539	off += stride;
	540	ysrc += self.cur_frame.ystride;
	541	if (y & 1) != 0 {
	542	csrc += self.cur_frame.cstride;
	543	}
	544	}
	545	}
	546	}
	547
	548	impl NADecoder for TM2Decoder {
2422d969	549	fn init(&mut self, info: NACodecInfoRef) -> DecoderResult<()> {
8bde0eae KS	550	if let NACodecTypeInfo::Video(vinfo) = info.get_properties() {
	551	let myinfo = NACodecTypeInfo::Video(NAVideoInfo::new(vinfo.get_width(), vinfo.get_height(), false, YUV410_FORMAT));
	552	self.width = vinfo.get_width();
	553	self.height = vinfo.get_height();
	554	self.cur_frame = TM2Frame::alloc(self.width, self.height);
	555	self.prev_frame = TM2Frame::alloc(self.width, self.height);
2422d969	556	self.info = NACodecInfo::new_ref(info.get_name(), myinfo, info.get_extradata()).into_ref();
8bde0eae KS	557	Ok(())
	558	} else {
	559	Err(DecoderError::InvalidData)
	560	}
	561	}
	562	fn decode(&mut self, pkt: &NAPacket) -> DecoderResult<NAFrameRef> {
	563	let src = pkt.get_buffer();
	564	validate!(src.len() >= 40 + (TM2StreamType::Num as usize) * 4 + 4);
	565	let mut mr = MemoryReader::new_read(&src);
	566	let mut br = ByteReader::new(&mut mr);
	567
	568	let magic = br.read_u32be()?;
	569	validate!(magic == 0x100 \|\| magic == 0x101);
	570	br.read_skip(36)?;
	571	for str in self.streams.iter_mut() {
	572	str.read_header(&src, &mut br)?;
	573	}
	574
	575	let myinfo = NAVideoInfo::new(self.width, self.height, false, RGB24_FORMAT);
	576	let bufret = alloc_video_buffer(myinfo, 2);
	577	if let Err(_) = bufret { return Err(DecoderError::InvalidData); }
b70cc006	578	let bufinfo = bufret.unwrap();
8bde0eae KS	579	let mut buf = bufinfo.get_vbuf().unwrap();
	580
	581	let is_intra = self.decode_blocks()?;
	582	self.output_frame(&mut buf);
	583	std::mem::swap(&mut self.cur_frame, &mut self.prev_frame);
	584
	585	let mut frm = NAFrame::new_from_pkt(pkt, self.info.clone(), bufinfo);
	586	frm.set_keyframe(is_intra);
	587	frm.set_frame_type(if is_intra { FrameType::I } else { FrameType::P });
	588	Ok(Rc::new(RefCell::new(frm)))
	589	}
	590	}
	591
	592	pub fn get_decoder() -> Box<NADecoder> {
	593	Box::new(TM2Decoder::new())
	594	}
	595
	596	#[cfg(test)]
	597	mod test {
	598	use nihav_core::codecs::RegisteredDecoders;
	599	use nihav_core::demuxers::RegisteredDemuxers;
	600	use nihav_core::test::dec_video::*;
	601	use crate::codecs::duck_register_all_codecs;
	602	use nihav_commonfmt::demuxers::generic_register_all_demuxers;
	603	#[test]
	604	fn test_tm2() {
	605	let mut dmx_reg = RegisteredDemuxers::new();
	606	generic_register_all_demuxers(&mut dmx_reg);
	607	let mut dec_reg = RegisteredDecoders::new();
	608	duck_register_all_codecs(&mut dec_reg);
	609
	610	test_file_decoding("avi", "assets/Duck/tm20.avi", Some(16), true, false, None/Some("tm2")/, &dmx_reg, &dec_reg);
	611	}
	612	}