Why is ffmpeg biased when converting to 16-bit integer or 32-bit float RGB output?

Question

Consider the following Python invocations, that exercise ffmpeg's ability to convert a 8-bit input into 16-bit integer values or 32-bit float values:

import cv2
import subprocess
import numpy as np

ffmpeg = "ffmpeg -hide_banner -loglevel error -y"
flags = "-sws_flags accurate_rnd+bitexact+full_chroma_int+neighbor -sws_dither none"

for input_color_range in ("tv", "pc"):

    # Generate YUV444 video and encode it losslessly
    subprocess.check_call(rf"{ffmpeg} -y {flags} -color_range {input_color_range} -f lavfi -i yuvtestsrc {flags} -pix_fmt yuv444p -color_range {input_color_range} -x264-params qp=0 -frames 1 -c:v libx264 video_temp.mp4")

    # Extract YUV444 frame, as well as 8-bit int, 16-bit int and 32-bit float frame
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -f rawvideo video_temp_444_frame1.yuv")
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -color_range pc -pix_fmt rgb24 video_temp_444_frame1_8u.png")
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -color_range pc -pix_fmt rgb48be video_temp_444_frame1_16u.png")
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -color_range pc -pix_fmt gbrpf32be -f rawvideo video_temp_444_frame1_32f.gbrpf32be")

    # Reead these frames into (height, width, 3) Numpy arrays containing YUV or RGB data
    data_8u = cv2.imread("video_temp_444_frame1_8u.png", cv2.IMREAD_UNCHANGED)[..., ::-1]
    data_16u = cv2.imread("video_temp_444_frame1_16u.png", cv2.IMREAD_UNCHANGED)[..., ::-1]
    data_yuv = np.rollaxis(np.frombuffer(open("video_temp_444_frame1.yuv", "rb").read()).view(np.uint8).reshape((3, 240, 320)), 0, 3).copy()
    data_32f = np.rollaxis(np.frombuffer(open("video_temp_444_frame1_32f.gbrpf32be", "rb").read()).view(np.dtype(">f4")).reshape((3, 240, 320)), 0, 3).copy()
    data_32f[..., (0, 1, 2)] = data_32f[..., (2, 0, 1)]

    # This pixel in yuvtestsrc corresponds to limited-range YUV=(235, 128,
    # 128)=(100%, 0.0, 0.0), which should correspond to 100% white, i.e.
    # RGB=(100%, 100%, 100%).
    if input_color_range == "tv":
        i, j = 10, 294
    # This pixel in yuvtestsrc corresponds to full-range YUV=(255, 128,
    # 128)=(100%, 0.0, 0.0), which should correspond to 100% white, i.e.
    # RGB=(100%, 100%, 100%).
    elif input_color_range == "pc":
        i, j = 10, 319
    else:
        raise Exception(input_color_range)

    # Print pixel values
    print("")
    print(f"Values for {input_color_range}-range input video at ({i}, {j}):")
    print("- 8-bit YUV input   = %s" % data_yuv[i, j, :])
    print("- 8-bit RGB output  = %s (= %s)" % (data_8u[i, j, :], data_8u[i, j, :] / 255))
    print("- 16-bit RGB output = %s (= %s)" % (data_16u[i, j, :], data_16u[i, j, :] / 65535))
    print("- Float RGB output  = %s" % data_32f[i, j, :])

The script first generates a video frame from ffmpeg's YUV test source, encoded with no chroma subsampling (4:4:4) as losslessly as possible.

That video is then used as a reference source to extract the following frames:

• The input reference YUV data
• A 8-bit RGB conversion
• A 16-bit RGB conversion
• A 32-bit floating-point RGB conversion

One pixel is extracted from each frame, which should contain a 100% white value. The output of the last series of print statements is the following:

Values for tv-range input video at (10, 294):
- 8-bit YUV input   = [235 128 128]
- 8-bit RGB output  = [255 255 255] (= [1. 1. 1.])
- 16-bit RGB output = [65283 65283 65283] (= [0.99615473 0.99615473 0.99615473])
- Float RGB output  = [0.9961547 0.9961547 0.9961547]

Values for pc-range input video at (10, 319):
- 8-bit YUV input   = [255 128 128]
- 8-bit RGB output  = [255 255 255] (= [1. 1. 1.])
- 16-bit RGB output = [65280 65280 65280] (= [0.99610895 0.99610895 0.99610895])
- Float RGB output  = [0.99610895 0.99610895 0.99610895]

While the 8-bit RGB output values are correct, none of the others correctly output a 100% white signal. Why is that?

Answer 1

I'm going to post the results of my investigation, hoping it will shed some light into what's happening inside ffmpeg for people who come upon this answer.

I added 3 different implementations of the conversion logic from raw Y'UV values (see below):

1. The original ffmpeg pipeline from libswscale\output.c:yuv2gbrpf32_full_X_c. Should yield the exact same values as those extracted using ffmpeg.exe.
2. The original ffmpeg pipeline, implemented using floating-point math instead of integer operations. Should yield the exact same values, up to rounding.
3. A corrected pipeline using correct scaling, implemented using floating-point math.

---

Applying [1] to the same signals as the question above yields the exact same values, which confirms that this is where ffmpeg does the potentially wrong conversions:

>>> print("YUV (limited-range)  : 235 128 128")
... print("RGB48 (ffmpeg int)   : ", *yuv2rgb_ffmpeg_16bit_pipeline(235, 128, 128, False, 8))
... print("RGB24 (ffmpeg int)   : ", *np.floor(np.array(yuv2rgb_ffmpeg_16bit_pipeline(235, 128, 128, False, 8))/256).tolist())
... print("")
... print("YUV (full-range)     : 255 128 128")
... print("RGB48 (ffmpeg int)   : ", *yuv2rgb_ffmpeg_16bit_pipeline(255, 128, 128, True, 8))
... print("RGB24 (ffmpeg int)   : ", *np.floor(np.array(yuv2rgb_ffmpeg_16bit_pipeline(255, 128, 128, True, 8))/256).tolist())
... print("")

YUV (limited range)  :  235 128 128
RGB48 (ffmpeg int)   :  65283.0 65283.0 65283.0
RGB24 (ffmpeg int)   :  255.0 255.0 255.0

YUV (full range)     :  255 128 128
RGB48 (ffmpeg int)   :  65280.0 65280.0 65280.0
RGB24 (ffmpeg int)   :  255.0 255.0 255.0

A subsequent question is : what is causing these 16-bit values to be different from 65535? Are the differences caused by a rounding operation inside of this pipeline, or are the coefficients and scaling factors wrong in the first place?

---

[2] lets us prove the first hypothesis false, since it outputs the same values using only floating-point math, up to rounding:

>>> print("YUV (limited-range)  : 235 128 128")
... print("RGB48 (ffmpeg int)   : ", *yuv2rgb_ffmpeg_float_pipeline(235, 128, 128, False, 8))
... print("RGB24 (ffmpeg int)   : ", *np.floor(np.array(yuv2rgb_ffmpeg_float_pipeline(235, 128, 128, False, 8))/256).tolist())
... print("")
... print("YUV (full-range)     : 255 128 128")
... print("RGB48 (ffmpeg int)   : ", *yuv2rgb_ffmpeg_float_pipeline(255, 128, 128, True, 8))
... print("RGB24 (ffmpeg int)   : ", *np.floor(np.array(yuv2rgb_ffmpeg_float_pipeline(255, 128, 128, True, 8))/256).tolist())

YUV (limited-range)  : 235 128 128
RGB48 (ffmpeg int)   :  65283.0 65283.0 65283.0
RGB24 (ffmpeg int)   :  255.0 255.0 255.0

YUV (full-range)     : 255 128 128
RGB48 (ffmpeg int)   :  65280.5 65280.5 65280.5
RGB24 (ffmpeg int)   :  255.0 255.0 255.0

---

Finally, [3] is a slightly modified version of the float pipeline using the same Y'UV to RGB conversion coefficients, but removing the unneeded bit shifts and replacing the 256/65536 multiplicative factor used to convert from 8-bit to 16-bit values to 255/65535. This indeed yields the correct full-range RGB signal at 65535 for 100% signal.

>>> print("YUV (limited-range)  : 235 128 128")
... print("RGB48 (ffmpeg int)   : ", *yuv2rgb_ffmpeg_full_float_pipeline_correct(235, 128, 128, False, 8))
... print("RGB24 (ffmpeg int)   : ", *np.floor(np.array(yuv2rgb_ffmpeg_full_float_pipeline_correct(235, 128, 128, False, 8))/256).tolist())
... print("")
... print("YUV (full-range)     : 255 128 128")
... print("RGB48 (ffmpeg int)   : ", *yuv2rgb_ffmpeg_full_float_pipeline_correct(255, 128, 128, True, 8))
... print("RGB24 (ffmpeg int)   : ", *np.floor(np.array(yuv2rgb_ffmpeg_full_float_pipeline_correct(255, 128, 128, True, 8))/256).tolist())

YUV (limited-range)  : 235 128 128
RGB48 (ffmpeg int)   :  65535.0 65535.0 65535.0
RGB24 (ffmpeg int)   :  255.0 255.0 255.0

YUV (full-range)     : 255 128 128
RGB48 (ffmpeg int)   :  65535.0 65535.0 65535.0
RGB24 (ffmpeg int)   :  255.0 255.0 255.0

---

Additionally, here is the working version with zscale:

import cv2
import subprocess
import numpy as np

ffmpeg = "ffmpeg -hide_banner -loglevel error -y"
flags = "-sws_flags accurate_rnd+bitexact+full_chroma_int+neighbor -sws_dither none"

for input_color_range in ("tv", "pc"):

    # Generate YUV444 video and encode it losslessly
    subprocess.check_call(rf"{ffmpeg} -y {flags} -color_range {input_color_range} -f lavfi -i yuvtestsrc {flags} -pix_fmt yuv444p -color_range {input_color_range} -colorspace bt2020nc -x264-params qp=0 -frames 1 -c:v libx264 video_temp.mp4", shell=True)

    # Extract YUV444 frame, as well as 8-bit int, 16-bit int and 32-bit float frame
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -f rawvideo video_temp_444_frame1.yuv", shell=True)
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -vf zscale,format=gbrp16le -color_range pc -pix_fmt rgb24 video_temp_444_frame1_8u.png", shell=True)
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -vf zscale,format=gbrp16le -color_range pc -pix_fmt rgb48be video_temp_444_frame1_16u.png", shell=True)
    subprocess.check_call(rf"{ffmpeg} -y {flags} -i video_temp.mp4 {flags} -vf zscale,format=gbrp16le -color_range pc -pix_fmt gbrpf32be -f rawvideo video_temp_444_frame1_32f.gbrpf32be", shell=True)

    # Reead these frames into (height, width, 3) Numpy arrays containing YUV or RGB data
    data_8u = cv2.imread("video_temp_444_frame1_8u.png", cv2.IMREAD_UNCHANGED)[..., ::-1]
    data_16u = cv2.imread("video_temp_444_frame1_16u.png", cv2.IMREAD_UNCHANGED)[..., ::-1]
    data_yuv = np.rollaxis(np.frombuffer(open("video_temp_444_frame1.yuv", "rb").read()).view(np.uint8).reshape((3, 240, 320)), 0, 3).copy()
    data_32f = np.rollaxis(np.frombuffer(open("video_temp_444_frame1_32f.gbrpf32be", "rb").read()).view(np.dtype(">f4")).reshape((3, 240, 320)), 0, 3).copy()
    data_32f[..., (0, 1, 2)] = data_32f[..., (2, 0, 1)]

    # This pixel in yuvtestsrc corresponds to limited-range YUV=(235, 128,
    # 128)=(100%, 0.0, 0.0), which should correspond to 100% white, i.e.
    # RGB=(100%, 100%, 100%).
    if input_color_range == "tv":
        i, j = 10, 294
    # This pixel in yuvtestsrc corresponds to full-range YUV=(255, 128,
    # 128)=(100%, 0.0, 0.0), which should correspond to 100% white, i.e.
    # RGB=(100%, 100%, 100%).
    elif input_color_range == "pc":
        i, j = 10, 319
    else:
        raise Exception(input_color_range)

    # Print pixel values
    print("")
    print(f"Values for {input_color_range}-range input video at ({i}, {j}):")
    print("- 8-bit YUV input   = %s" % data_yuv[i, j, :])
    print("- 8-bit RGB output  = %s (= %s)" % (data_8u[i, j, :], data_8u[i, j, :] / 255))
    print("- 16-bit RGB output = %s (= %s)" % (data_16u[i, j, :], data_16u[i, j, :] / 65535))
    print("- Float RGB output  = %s" % data_32f[i, j, :])

The values are indeed correct:

Values for tv-range input video at (10, 294):
- 8-bit YUV input   = [235 128 128]
- 8-bit RGB output  = [255 255 255] (= [1. 1. 1.])
- 16-bit RGB output = [65535 65535 65535] (= [1. 1. 1.])
- Float RGB output  = [0.99998474 1.         1.        ]

Values for pc-range input video at (10, 319):
- 8-bit YUV input   = [255 128 128]
- 8-bit RGB output  = [255 255 255] (= [1. 1. 1.])
- 16-bit RGB output = [65535 65535 65535] (= [1. 1. 1.])
- Float RGB output  = [0.99998474 1.         1.        ]

---

[1] Original pipeline used in ffmpeg gbrpf32 conversion routine:

def yuv2rgb_ffmpeg_16bit_pipeline(pY, pU, pV, fullRange, depth):

    # Coefficients for ITU-R BT.2020 NCL
    # libswscale\yuv2rgb.c:ff_yuv2rgb_coeffs:58 (ffmpeg 5.1.2)
    crv, cbu, cgu, cgv = 110013, 140363, 12277, 42626

    # libswscale\yuv2rgb.c:roundToInt16:762 (ffmpeg 5.1.2)
    def roundToInt16(f: np.int64) -> np.int16:
        r = (f + (np.int64(1) << 15)) >> 16
        if r < -0x7FFF:
            return np.int16(0x8000)
        elif r > 0x7FFF:
            return np.int16(0x7FFF)
        return np.int16(r)

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:813 (ffmpeg 5.1.2)
    cy = np.int64(1) << 16
    oy = np.int64(0)

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:817 (ffmpeg 5.1.2)
    if not fullRange:
        cy = (cy * 255) // 219
        oy = np.int64(16) << 16
    else:
        crv = (crv * 224) // 255
        cbu = (cbu * 224) // 255
        cgu = (cgu * 224) // 255
        cgv = (cgv * 224) // 255

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:811 (ffmpeg 5.1.2)
    cgu = -cgu
    cgv = -cgv

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:836 (ffmpeg 5.1.2)
    yuv2rgb_y_coeff = roundToInt16(cy * (np.int64(1) << 13))
    yuv2rgb_y_offset = roundToInt16(oy * (np.int64(1) <<  9))
    yuv2rgb_v2r_coeff = roundToInt16(crv * (np.int64(1) << 13))
    yuv2rgb_v2g_coeff = roundToInt16(cgv * (np.int64(1) << 13))
    yuv2rgb_u2g_coeff = roundToInt16(cgu * (np.int64(1) << 13))
    yuv2rgb_u2b_coeff = roundToInt16(cbu * (np.int64(1) << 13))

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2389 (ffmpeg 5.1.2)
    Y = -np.int64(0x40000000)
    U = -(np.int64(128) << 23)
    V = -(np.int64(128) << 23)

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2394 (ffmpeg 5.1.2)
    # NOTE: Ffmpeg refers to a filter with multiple pixels, here we only add one.
    Y += np.int64(pY) << (31-depth)
    U += np.int64(pU) << (31-depth)
    V += np.int64(pV) << (31-depth)

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2402 (ffmpeg 5.1.2)
    Y >>= 14
    Y += 0x10000
    U >>= 14
    V >>= 14

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2417 (ffmpeg 5.1.2)
    Y -= yuv2rgb_y_offset
    Y *= yuv2rgb_y_coeff
    Y += 1 << 13

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2420 (ffmpeg 5.1.2)
    R = Y + V * yuv2rgb_v2r_coeff
    G = Y + V * yuv2rgb_v2g_coeff + U * yuv2rgb_u2g_coeff
    B = Y +                         U * yuv2rgb_u2b_coeff

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2424 (ffmpeg 5.1.2)
    pR = np.round(np.clip(float(R >> 14), 0, 65535), 1)
    pG = np.round(np.clip(float(G >> 14), 0, 65535), 1)
    pB = np.round(np.clip(float(B >> 14), 0, 65535), 1)

    return pR, pG, pB

---

[2] Same as the original pipeline, but computed using floating-point math instead of integers:

def yuv2rgb_ffmpeg_float_pipeline(pY, pU, pV, fullRange, depth):

    # Color space conversion coefficients for YCbCr -> RGB mapping.
    #
    #   Comment from libswscale\yuv2rgb.c:
    #
    #   Entries are {crv, cbu, cgu, cgv}
    #
    #     crv = (255 / 224) * 65536 * (1 - cr) / 0.5
    #     cbu = (255 / 224) * 65536 * (1 - cb) / 0.5
    #     cgu = (255 / 224) * 65536 * (cb / cg) * (1 - cb) / 0.5
    #     cgv = (255 / 224) * 65536 * (cr / cg) * (1 - cr) / 0.5
    #
    #   where Y = cr * R + cg * G + cb * B and cr + cg + cb = 1.
    #
    # Compute the crv, cbu, cgu and cgv coefficients in float, with the same
    # scaling as ffmpeg.
    cr, cb = 0.2627, 0.0593
    cg = 1.0 - cr - cb
    fcrv = (255 / 224) * 65536 * (1 - cr) / 0.5
    fcbu = (255 / 224) * 65536 * (1 - cb) / 0.5
    fcgu = (255 / 224) * 65536 * (cb / cg) * (1 - cb) / 0.5
    fcgv = (255 / 224) * 65536 * (cr / cg) * (1 - cr) / 0.5

    # libswscale\yuv2rgb.c:roundToInt16:762 (ffmpeg 5.1.2)
    def froundToInt16(f):
        r = np.round(float(f) / 65536.0)
        if r < -0x7FFF:
            return float(0x8000)
        elif r > 0x7FFF:
            return float(0x7FFF)
        return float(r)

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:813 (ffmpeg 5.1.2)
    fcy = float(1 << 16)
    foy = 0.0

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:817 (ffmpeg 5.1.2)
    if not fullRange:
        fcy = (fcy * 255) / 219
        foy = float(16 << 16)
    else:
        fcrv = (fcrv * 224) / 255
        fcbu = (fcbu * 224) / 255
        fcgu = (fcgu * 224) / 255
        fcgv = (fcgv * 224) / 255

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:811 (ffmpeg 5.1.2)
    fcgu = -fcgu
    fcgv = -fcgv

    # libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:836 (ffmpeg 5.1.2)
    fyuv2rgb_y_coeff = froundToInt16(fcy * float(np.int64(1) << 13))
    fyuv2rgb_y_offset = froundToInt16(foy * float(np.int64(1) <<  9))
    fyuv2rgb_v2r_coeff = froundToInt16(fcrv * float(np.int64(1) << 13))
    fyuv2rgb_v2g_coeff = froundToInt16(fcgv * float(np.int64(1) << 13))
    fyuv2rgb_u2g_coeff = froundToInt16(fcgu * float(np.int64(1) << 13))
    fyuv2rgb_u2b_coeff = froundToInt16(fcbu * float(np.int64(1) << 13))

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2389 (ffmpeg 5.1.2)
    fY = -float(np.int64(128) << (31 - 8))
    fU = -float(np.int64(128) << (31 - 8))
    fV = -float(np.int64(128) << (31 - 8))

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2394 (ffmpeg 5.1.2)
    # NOTE: Ffmpeg refers to a filter with multiple pixels, here we only add one.
    fY += float(np.int64(pY) << (31-depth))
    fU += float(np.int64(pU) << (31-depth))
    fV += float(np.int64(pV) << (31-depth))

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2402 (ffmpeg 5.1.2)
    fY /= 2**14
    fY += 0x10000
    fU /= 2**14
    fV /= 2**14

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2417 (ffmpeg 5.1.2)
    fY -= fyuv2rgb_y_offset
    fY *= fyuv2rgb_y_coeff
    fY += 1 << 13

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2420 (ffmpeg 5.1.2)
    fR = fY + fV * fyuv2rgb_v2r_coeff
    fG = fY + fV * fyuv2rgb_v2g_coeff + fU * fyuv2rgb_u2g_coeff
    fB = fY +                           fU * fyuv2rgb_u2b_coeff

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2424 (ffmpeg 5.1.2)
    fR = np.round(np.clip((fR / (2**14)), 0, 65535), 1)
    fG = np.round(np.clip((fG / (2**14)), 0, 65535), 1)
    fB = np.round(np.clip((fB / (2**14)), 0, 65535), 1)

    return fR, fG, fB

---

[3] Correct pipeline, using the same conversion coefficients:

def yuv2rgb_ffmpeg_full_float_pipeline_correct(pY, pU, pV, fullRange, depth):

    # Coefficients for ITU-R BT.2020 NCL
    # libswscale\yuv2rgb.c:ff_yuv2rgb_coeffs:58 (ffmpeg 5.1.2)
    crv, cbu, cgu, cgv = 110013, 140363, 12277, 42626
    fcrv = crv / 65536
    fcbu = cbu / 65536
    fcgu = cgu / 65536
    fcgv = cgv / 65536

    # Equivalent to libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:813 (ffmpeg 5.1.2)
    fcy = 1.0
    foy = 0.0

    # Equivalent to libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:817 (ffmpeg 5.1.2)
    if not fullRange:
        fcy = (fcy * 255) / 219
        foy = 16.0 * 65535 / 255.0
    else:
        fcrv = (fcrv * 224) / 255
        fcbu = (fcbu * 224) / 255
        fcgu = (fcgu * 224) / 255
        fcgv = (fcgv * 224) / 255

    # Equivalent to libswscale\yuv2rgb.c:ff_yuv2rgb_c_init_tables:811 (ffmpeg 5.1.2)
    fcgu = -fcgu
    fcgv = -fcgv

    # Equivalent to libswscale\output.c:yuv2gbrpf32_full_X_c:2389 (ffmpeg 5.1.2)
    fY = float(-128) * 65535 / 255
    fU = float(-128) * 65535 / 255
    fV = float(-128) * 65535 / 255

    # Equivalent to libswscale\output.c:yuv2gbrpf32_full_X_c:2394 (ffmpeg 5.1.2)
    fY += pY * 65535 / (2**depth-1)
    fU += pU * 65535 / (2**depth-1)
    fV += pV * 65535 / (2**depth-1)

    # Equivalent to libswscale\output.c:yuv2gbrpf32_full_X_c:2402 (ffmpeg 5.1.2)
    fY += float(128) * 65535 / 255

    # Equivalent to libswscale\output.c:yuv2gbrpf32_full_X_c:2417 (ffmpeg 5.1.2)
    fY -= foy
    fY *= fcy

    # Equivalent to libswscale\output.c:yuv2gbrpf32_full_X_c:2420 (ffmpeg 5.1.2)
    fR = fY + fV*fcrv
    fG = fY + fV*fcgv + fU*fcgu
    fB = fY +           fU*fcbu

    # libswscale\output.c:yuv2gbrpf32_full_X_c:2424 (ffmpeg 5.1.2)
    fR = np.round(np.clip(fR, 0, 65535), 1)
    fG = np.round(np.clip(fG, 0, 65535), 1)
    fB = np.round(np.clip(fB, 0, 65535), 1)

    return fR, fG, fB