path: root/decoder.py

import argparse
import sys
import traceback
import cv2
import numpy as np
from creedsolo import RSCodec
from raptorq import Decoder

parser = argparse.ArgumentParser(formatter_class=argparse.ArgumentDefaultsHelpFormatter)
parser.add_argument("-i", "--input", help="camera device index or input video file", default=0)
parser.add_argument("-o", "--output", help="output file for decoded data")
parser.add_argument("-x", "--height", help="grid height", default=100, type=int)
parser.add_argument("-y", "--width", help="grid width", default=100, type=int)
parser.add_argument("-f", "--fps", help="frame rate", default=30, type=int)
parser.add_argument("-l", "--level", help="error correction level", default=0.1, type=float)
parser.add_argument("-s", "--size", help="number of bytes to decode", default=2**16, type=int)
parser.add_argument("-e", "--erasure", help="detect erasures", action="store_true")
args = parser.parse_args()

cheight = cwidth = max(args.height // 10, args.width // 10)
frame_size = args.height * args.width - 4 * cheight * cwidth
frame_xor = np.arange(frame_size // 2, dtype=np.uint8)
rs_size = frame_size // 2 - (frame_size // 2 + 254) // 255 * int(args.level * 255) - 4

rsc = RSCodec(int(args.level * 255))
decoder = Decoder.with_defaults(args.size, rs_size)


def find_corner(A, f):
    cx, cy = A.shape[:2]
    # Resize so smaller dim is 5
    scale = min(cx // 5, cy // 5)
    B = cv2.resize(A, (cy // scale, cx // scale), interpolation=cv2.INTER_AREA)
    guess = np.array(np.unravel_index(np.argmax(f(B)), B.shape[:2])) * scale + scale // 2
    mask = cv2.floodFill(A, np.empty(0), tuple(reversed(guess)), 1, 10, 10, cv2.FLOODFILL_MASK_ONLY)[2][
        1:-1, 1:-1
    ].astype(bool)
    return np.average(np.where(mask), axis=1), np.average(A[mask], axis=0).astype(np.float64)


if args.input.isdecimal():
    args.input = int(args.input)
cap = cv2.VideoCapture(args.input)
data = None
while data is None:
    try:
        ret, raw_frame = cap.read()
        if not ret:
            print("End of stream")
            break
        cv2.imshow("", raw_frame)
        cv2.waitKey(1)
        # raw_frame is a uint8 BE CAREFUL
        raw_frame = cv2.cvtColor(raw_frame, cv2.COLOR_BGR2RGB)

        X, Y = raw_frame.shape[:2]
        cx, cy = X // 4, Y // 4
        widx, wcol = find_corner(raw_frame[:cx, :cy], lambda B: (np.std(B, axis=2) < 35) * np.sum(B, axis=2))
        ridx, rcol = find_corner(raw_frame[:cx, Y - cy :], lambda B: B[:, :, 0] - B[:, :, 1] - B[:, :, 2])
        ridx[1] += Y - cy
        gidx, gcol = find_corner(raw_frame[X - cx :, :cy], lambda B: B[:, :, 1] - B[:, :, 2] - B[:, :, 0])
        gidx[0] += X - cx
        bidx, bcol = find_corner(raw_frame[X - cx :, Y - cy :], lambda B: B[:, :, 2] - B[:, :, 0] - B[:, :, 1])
        bidx[0] += X - cx
        bidx[1] += Y - cy

        # Find basis of color space
        origin = (rcol + gcol + bcol - wcol) / 2
        rcol -= origin
        gcol -= origin
        bcol -= origin
        F = 255 * np.linalg.inv(np.stack((rcol, gcol, bcol)).T)

        # Dumb perspective transform
        xv = np.linspace(
            -(cheight / 2 - 1) / (args.height - cheight + 1),
            1 + (cheight / 2 - 1) / (args.height - cheight + 1),
            args.height,
        )
        yv = np.linspace(
            -(cwidth / 2 - 1) / (args.width - cwidth + 1),
            1 + (cwidth / 2 - 1) / (args.width - cwidth + 1),
            args.width,
        )
        xp = (
            np.outer(1 - xv, 1 - yv) * widx[0]
            + np.outer(1 - xv, yv) * ridx[0]
            + np.outer(xv, 1 - yv) * gidx[0]
            + np.outer(xv, yv) * bidx[0]
        )
        yp = (
            np.outer(1 - xv, 1 - yv) * widx[1]
            + np.outer(1 - xv, yv) * ridx[1]
            + np.outer(xv, 1 - yv) * gidx[1]
            + np.outer(xv, yv) * bidx[1]
        )

        # plt.scatter(widx[1], widx[0])
        # plt.scatter(ridx[1], ridx[0])
        # plt.scatter(gidx[1], gidx[0])
        # plt.scatter(bidx[1], bidx[0])
        # plt.scatter(yp, xp)
        # plt.imshow(raw_frame.astype(np.uint8))
        # plt.show()

        frame = raw_frame[
            np.clip(np.round(xp).astype(np.int64), 0, X - 1), np.clip(np.round(yp).astype(np.int64), 0, Y - 1), :
        ]
        frame = np.clip(np.squeeze(F @ (frame - origin)[..., np.newaxis]), 0, 255).astype(np.uint8)
        frame = (frame[:, :, 0] >> 7) + (frame[:, :, 1] >> 5 & 0b0110) + (frame[:, :, 2] >> 4 & 0b1000)
        frame = np.concatenate(
            (
                frame[:cheight, cwidth : args.width - cwidth].flatten(),
                frame[cheight : args.height - cheight].flatten(),
                frame[args.height - cheight :, cwidth : args.width - cwidth].flatten(),
            )
        )
        frame = (frame[::2] << 4) + frame[1::2]
        frame = np.pad(frame, (0, (len(frame) + 254) // 255 * 255 - len(frame)))
        frame = np.ravel(frame.reshape(255, len(frame) // 255), "F")[: frame_size // 2]
        erase_pos = list(np.where(frame == 0)[0]) if args.erasure else []
        data = decoder.decode(bytes(rsc.decode(frame ^ frame_xor, erase_pos=erase_pos)[0]))
        print("Decoded frame")
    except KeyboardInterrupt:
        sys.exit()
    except:
        traceback.print_exc()
with open(args.output, "wb") as f:
    f.write(data)
cap.release()