celery/streaming/gpu_output.py

"""
Zero-copy GPU video encoding output.

Uses PyNvVideoCodec for direct GPU-to-GPU encoding without CPU transfers.
Frames stay on GPU throughout: CuPy → NV12 conversion → NVENC encoding.
"""

import numpy as np
import subprocess
import sys
from pathlib import Path
from typing import Tuple, Optional, Union
import time

# Try to import GPU libraries
try:
    import cupy as cp
    CUPY_AVAILABLE = True
except ImportError:
    cp = None
    CUPY_AVAILABLE = False

try:
    import PyNvVideoCodec as nvc
    PYNVCODEC_AVAILABLE = True
except ImportError:
    nvc = None
    PYNVCODEC_AVAILABLE = False


def check_gpu_encode_available() -> bool:
    """Check if zero-copy GPU encoding is available."""
    return CUPY_AVAILABLE and PYNVCODEC_AVAILABLE


# RGB to NV12 CUDA kernel
_RGB_TO_NV12_KERNEL = None

def _get_rgb_to_nv12_kernel():
    """Get or create the RGB to NV12 conversion kernel."""
    global _RGB_TO_NV12_KERNEL
    if _RGB_TO_NV12_KERNEL is None and CUPY_AVAILABLE:
        _RGB_TO_NV12_KERNEL = cp.RawKernel(r'''
extern "C" __global__
void rgb_to_nv12(
    const unsigned char* rgb,
    unsigned char* y_plane,
    unsigned char* uv_plane,
    int width, int height
) {
    int x = blockIdx.x * blockDim.x + threadIdx.x;
    int y = blockIdx.y * blockDim.y + threadIdx.y;

    if (x >= width || y >= height) return;

    int rgb_idx = (y * width + x) * 3;
    unsigned char r = rgb[rgb_idx];
    unsigned char g = rgb[rgb_idx + 1];
    unsigned char b = rgb[rgb_idx + 2];

    // RGB to Y (BT.601)
    int y_val = ((66 * r + 129 * g + 25 * b + 128) >> 8) + 16;
    y_plane[y * width + x] = (unsigned char)(y_val > 255 ? 255 : (y_val < 0 ? 0 : y_val));

    // UV (subsample 2x2) - only process even pixels
    if ((x & 1) == 0 && (y & 1) == 0) {
        int u_val = ((-38 * r - 74 * g + 112 * b + 128) >> 8) + 128;
        int v_val = ((112 * r - 94 * g - 18 * b + 128) >> 8) + 128;

        int uv_idx = (y / 2) * width + x;
        uv_plane[uv_idx] = (unsigned char)(u_val > 255 ? 255 : (u_val < 0 ? 0 : u_val));
        uv_plane[uv_idx + 1] = (unsigned char)(v_val > 255 ? 255 : (v_val < 0 ? 0 : v_val));
    }
}
''', 'rgb_to_nv12')
    return _RGB_TO_NV12_KERNEL


class GPUEncoder:
    """
    Zero-copy GPU video encoder using PyNvVideoCodec.

    Frames are converted from RGB to NV12 on GPU and encoded directly
    without any CPU memory transfers.
    """

    def __init__(self, width: int, height: int, fps: float = 30, crf: int = 23):
        if not check_gpu_encode_available():
            raise RuntimeError("GPU encoding not available (need CuPy and PyNvVideoCodec)")

        self.width = width
        self.height = height
        self.fps = fps
        self.crf = crf

        # Create dummy video to get frame buffer template
        self._init_frame_buffer()

        # Create encoder
        self.encoder = nvc.CreateEncoder(width, height, "NV12", usecpuinputbuffer=False)

        # CUDA kernel grid/block config
        self._block = (16, 16)
        self._grid = ((width + 15) // 16, (height + 15) // 16)

        self._frame_count = 0
        self._encoded_data = []

        print(f"[GPUEncoder] Initialized {width}x{height} @ {fps}fps, zero-copy GPU encoding", file=sys.stderr)

    def _init_frame_buffer(self):
        """Initialize frame buffer from dummy decode."""
        # Create minimal dummy video
        dummy_path = Path("/tmp/gpu_encoder_dummy.mp4")
        subprocess.run([
            "ffmpeg", "-y", "-f", "lavfi",
            "-i", f"color=black:size={self.width}x{self.height}:duration=0.1:rate=30",
            "-c:v", "h264", "-pix_fmt", "yuv420p",
            str(dummy_path)
        ], capture_output=True)

        # Decode to get frame buffer
        demuxer = nvc.CreateDemuxer(str(dummy_path))
        decoder = nvc.CreateDecoder(gpuid=0, usedevicememory=True)

        self._template_frame = None
        for _ in range(30):
            packet = demuxer.Demux()
            if not packet:
                break
            frames = decoder.Decode(packet)
            if frames:
                self._template_frame = frames[0]
                break

        if not self._template_frame:
            raise RuntimeError("Failed to initialize GPU frame buffer")

        # Wrap frame planes with CuPy for zero-copy access
        y_ptr = self._template_frame.GetPtrToPlane(0)
        uv_ptr = self._template_frame.GetPtrToPlane(1)

        y_mem = cp.cuda.UnownedMemory(y_ptr, self.height * self.width, None)
        self._y_plane = cp.ndarray(
            (self.height, self.width), dtype=cp.uint8,
            memptr=cp.cuda.MemoryPointer(y_mem, 0)
        )

        uv_mem = cp.cuda.UnownedMemory(uv_ptr, (self.height // 2) * self.width, None)
        self._uv_plane = cp.ndarray(
            (self.height // 2, self.width), dtype=cp.uint8,
            memptr=cp.cuda.MemoryPointer(uv_mem, 0)
        )

        # Keep references to prevent GC
        self._decoder = decoder
        self._demuxer = demuxer

        # Cleanup dummy file
        dummy_path.unlink(missing_ok=True)

    def encode_frame(self, frame: Union[np.ndarray, 'cp.ndarray']) -> bytes:
        """
        Encode a frame (RGB format) to H.264.

        Args:
            frame: RGB frame as numpy or CuPy array, shape (H, W, 3)

        Returns:
            Encoded bytes (may be empty if frame is buffered)
        """
        # Ensure frame is on GPU
        if isinstance(frame, np.ndarray):
            frame_gpu = cp.asarray(frame)
        else:
            frame_gpu = frame

        # Ensure uint8
        if frame_gpu.dtype != cp.uint8:
            frame_gpu = cp.clip(frame_gpu, 0, 255).astype(cp.uint8)

        # Ensure contiguous
        if not frame_gpu.flags['C_CONTIGUOUS']:
            frame_gpu = cp.ascontiguousarray(frame_gpu)

        # Convert RGB to NV12 on GPU
        kernel = _get_rgb_to_nv12_kernel()
        kernel(self._grid, self._block, (frame_gpu, self._y_plane, self._uv_plane, self.width, self.height))

        # Encode (GPU to GPU)
        result = self.encoder.Encode(self._template_frame)
        self._frame_count += 1

        return result if result else b''

    def flush(self) -> bytes:
        """Flush encoder and return remaining data."""
        return self.encoder.EndEncode()

    def close(self):
        """Close encoder and cleanup."""
        pass


class GPUHLSOutput:
    """
    GPU-accelerated HLS output with IPFS upload.

    Uses zero-copy GPU encoding and writes HLS segments.
    """

    def __init__(
        self,
        output_dir: str,
        size: Tuple[int, int],
        fps: float = 30,
        segment_duration: float = 4.0,
        crf: int = 23,
        audio_source: str = None,
        ipfs_gateway: str = "https://ipfs.io/ipfs",
        on_playlist_update: callable = None,
    ):
        self.output_dir = Path(output_dir)
        self.output_dir.mkdir(parents=True, exist_ok=True)
        self.size = size
        self.fps = fps
        self.segment_duration = segment_duration
        self.ipfs_gateway = ipfs_gateway.rstrip("/")
        self._on_playlist_update = on_playlist_update
        self._is_open = True

        # GPU encoder
        self._gpu_encoder = GPUEncoder(size[0], size[1], fps, crf)

        # Segment management
        self._current_segment = 0
        self._frames_in_segment = 0
        self._frames_per_segment = int(fps * segment_duration)
        self._segment_data = []

        # Track segment CIDs for IPFS
        self.segment_cids = {}
        self._playlist_cid = None

        # Import IPFS client
        from ipfs_client import add_file, add_bytes
        self._ipfs_add_file = add_file
        self._ipfs_add_bytes = add_bytes

        # Setup ffmpeg for muxing (takes raw H.264, outputs .ts segments)
        self._setup_muxer()

        print(f"[GPUHLSOutput] Initialized {size[0]}x{size[1]} @ {fps}fps, GPU encoding", file=sys.stderr)

    def _setup_muxer(self):
        """Setup ffmpeg for muxing H.264 to MPEG-TS segments."""
        self.local_playlist_path = self.output_dir / "stream.m3u8"

        cmd = [
            "ffmpeg", "-y",
            "-f", "h264",  # Input is raw H.264
            "-i", "-",
            "-c:v", "copy",  # Just copy, no re-encoding
            "-f", "hls",
            "-hls_time", str(self.segment_duration),
            "-hls_list_size", "0",
            "-hls_flags", "independent_segments+append_list+split_by_time",
            "-hls_segment_type", "mpegts",
            "-hls_segment_filename", str(self.output_dir / "segment_%05d.ts"),
            str(self.local_playlist_path),
        ]

        self._muxer = subprocess.Popen(
            cmd,
            stdin=subprocess.PIPE,
            stderr=subprocess.DEVNULL,
        )

    def write(self, frame: Union[np.ndarray, 'cp.ndarray'], t: float = 0):
        """Write a frame using GPU encoding."""
        if not self._is_open:
            return

        # GPU encode
        encoded = self._gpu_encoder.encode_frame(frame)

        # Send to muxer
        if encoded:
            try:
                self._muxer.stdin.write(encoded)
            except BrokenPipeError:
                self._is_open = False
                return

        self._frames_in_segment += 1

        # Check for segment completion
        if self._frames_in_segment >= self._frames_per_segment:
            self._frames_in_segment = 0
            self._check_upload_segments()

    def _check_upload_segments(self):
        """Check for and upload new segments to IPFS."""
        segments = sorted(self.output_dir.glob("segment_*.ts"))

        for seg_path in segments:
            seg_num = int(seg_path.stem.split("_")[1])

            if seg_num in self.segment_cids:
                continue

            # Check if segment is complete
            try:
                size1 = seg_path.stat().st_size
                if size1 == 0:
                    continue
                time.sleep(0.05)
                size2 = seg_path.stat().st_size
                if size1 != size2:
                    continue
            except FileNotFoundError:
                continue

            # Upload to IPFS
            cid = self._ipfs_add_file(seg_path, pin=True)
            if cid:
                self.segment_cids[seg_num] = cid
                print(f"Added to IPFS: {seg_path.name} -> {cid}", file=sys.stderr)
                self._update_playlist()

    def _update_playlist(self):
        """Generate and upload IPFS-aware playlist."""
        if not self.segment_cids:
            return

        lines = [
            "#EXTM3U",
            "#EXT-X-VERSION:3",
            f"#EXT-X-TARGETDURATION:{int(self.segment_duration) + 1}",
            "#EXT-X-MEDIA-SEQUENCE:0",
        ]

        for seg_num in sorted(self.segment_cids.keys()):
            cid = self.segment_cids[seg_num]
            lines.append(f"#EXTINF:{self.segment_duration:.3f},")
            lines.append(f"{self.ipfs_gateway}/{cid}")

        playlist_content = "\n".join(lines) + "\n"

        # Upload playlist
        self._playlist_cid = self._ipfs_add_bytes(playlist_content.encode(), pin=True)
        if self._playlist_cid and self._on_playlist_update:
            self._on_playlist_update(self._playlist_cid)

    def close(self):
        """Close output and flush remaining data."""
        if not self._is_open:
            return

        self._is_open = False

        # Flush GPU encoder
        final_data = self._gpu_encoder.flush()
        if final_data:
            try:
                self._muxer.stdin.write(final_data)
            except:
                pass

        # Close muxer
        try:
            self._muxer.stdin.close()
            self._muxer.wait(timeout=10)
        except:
            self._muxer.kill()

        # Final segment upload
        self._check_upload_segments()

        self._gpu_encoder.close()

    @property
    def is_open(self) -> bool:
        return self._is_open

    @property
    def playlist_cid(self) -> Optional[str]:
        return self._playlist_cid

    @property
    def playlist_url(self) -> Optional[str]:
        """Get the full IPFS URL for the playlist."""
        if self._playlist_cid:
            return f"{self.ipfs_gateway}/{self._playlist_cid}"
        return None