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import shlex
import subprocess
import spaces
import torch
import os
import shutil
import glob
import gradio as gr

# install packages for mamba
def install_mamba():
    subprocess.run(shlex.split("pip install https://github.com/state-spaces/mamba/releases/download/v2.2.2/mamba_ssm-2.2.2+cu122torch2.3cxx11abiFALSE-cp310-cp310-linux_x86_64.whl"))

def clone_github():
    subprocess.run([
        "git", "clone",
        f"https://RoyChao19477:{os.environ['GITHUB_TOKEN']}@github.com/RoyChao19477/for_HF_AVSEMamba.git",
    ])
    # move all files except README.md
    for item in glob.glob("for_HF_AVSEMamba/*"):
        if os.path.basename(item) != "README.md":
            if os.path.isdir(item):
                shutil.move(item, ".")
            else:
                shutil.move(item, os.path.join(".", os.path.basename(item)))

    #shutil.rmtree("tmp_repo")
    #subprocess.run(["ls"], check=True)

install_mamba()
clone_github()

ABOUT = """
# SEMamba: Speech Enhancement
A Mamba-based model that denoises real-world audio.
Upload or record a noisy clip and click **Enhance** to hear + see its spectrogram.
"""


import torch
import ffmpeg
import torchaudio
import torchaudio.transforms as T
import yaml
import librosa
import librosa.display
import matplotlib
import numpy as np
import soundfile as sf
import matplotlib.pyplot as plt
from models.stfts    import mag_phase_stft, mag_phase_istft
from models.generator import SEMamba
from models.pcs400   import cal_pcs
from ultralytics import YOLO
import supervision as sv

import gradio as gr
import cv2
import os
import tempfile
from ultralytics import YOLO
from moviepy import ImageSequenceClip
from scipy.io import wavfile
from avse_code import run_avse

# Load face detector
model = YOLO("yolov8n-face.pt").cuda()  # assumes CUDA available


from decord import VideoReader, cpu
from model import AVSEModule
from config import sampling_rate
import spaces

# Load model once globally
#ckpt_path = "ckpts/ep215_0906.oat.ckpt"
#model = AVSEModule.load_from_checkpoint(ckpt_path)
avse_model = AVSEModule()
#avse_state_dict = torch.load("ckpts/ep215_0906.oat.ckpt")
avse_state_dict = torch.load("ckpts/ep220_0908.oat.ckpt")
avse_model.load_state_dict(avse_state_dict, strict=True)
avse_model.to("cuda")
avse_model.eval()

@spaces.GPU
def run_avse_inference(video_path, audio_path):
    estimated = run_avse(video_path, audio_path)
    # Load audio
    #noisy, _ = sf.read(audio_path, dtype='float32')  # (N, )
    #noisy = torch.tensor(noisy).unsqueeze(0)  # (1, N)
    noisy = wavfile.read(audio_path)[1].astype(np.float32) / (2 ** 15)

    # Norm.
    #noisy = noisy * (0.8 / np.max(np.abs(noisy)))

    # Load grayscale video
    vr = VideoReader(video_path, ctx=cpu(0))
    frames = vr.get_batch(list(range(len(vr)))).asnumpy()
    bg_frames = np.array([
        cv2.cvtColor(frames[i], cv2.COLOR_RGB2GRAY) for i in range(len(frames))
    ]).astype(np.float32)
    bg_frames /= 255.0


    # Combine into input dict (match what model.enhance expects)
    data = {
        "noisy_audio": noisy,
        "video_frames": bg_frames[np.newaxis, ...]
    }

    with torch.no_grad():
        estimated = avse_model.enhance(data).reshape(-1)

    # Save result
    tmp_wav = audio_path.replace(".wav", "_enhanced.wav")
    sf.write(tmp_wav, estimated, samplerate=sampling_rate)

    return tmp_wav


def extract_resampled_audio(video_path, target_sr=16000):
    # Step 1: extract audio via torchaudio
    # (moviepy will still extract it to wav temp file)
    tmp_audio_path = tempfile.mktemp(suffix=".wav")
    subprocess.run(["ffmpeg", "-y", "-i", video_path, "-vn", "-acodec", "pcm_s16le", "-ar", "44100", tmp_audio_path])

    # Step 2: Load and resample
    waveform, sr = torchaudio.load(tmp_audio_path)
    if sr != target_sr:
        resampler = T.Resample(orig_freq=sr, new_freq=target_sr)
        waveform = resampler(waveform)

    # Step 3: Save resampled audio
    resampled_audio_path = tempfile.mktemp(suffix="_16k.wav")
    torchaudio.save(resampled_audio_path, waveform, sample_rate=target_sr)
    return resampled_audio_path

@spaces.GPU
def extract_faces(video_file):
    cap = cv2.VideoCapture(video_file)
    fps = cap.get(cv2.CAP_PROP_FPS)
    frames = []

    while True:
        ret, frame = cap.read()
        if not ret:
            break

        # Inference
        results = model(frame, verbose=False)[0]
        for box in results.boxes:
            # version 1
            # x1, y1, x2, y2 = map(int, box.xyxy[0])

            # version 2
            h, w, _ = frame.shape
            x1, y1, x2, y2 = box.xyxy[0].cpu().numpy()
            pad_ratio = 0.5  # 30% padding

            dx = (x2 - x1) * pad_ratio
            dy = (y2 - y1) * pad_ratio

            x1 = int(max(0, x1 - dx))
            y1 = int(max(0, y1 - dy))
            x2 = int(min(w, x2 + dx))
            y2 = int(min(h, y2 + dy))
            # Added for v3
            shift_down = int(0.1 * (y2 - y1))
            y1 = int(min(max(0, y1 + shift_down), h))
            y2 = int(min(max(0, y2 + shift_down), h))
            face_crop = frame[y1:y2, x1:x2]
            if face_crop.size != 0:
                resized = cv2.resize(face_crop, (224, 224))
                frames.append(resized)

                #h_crop, w_crop = face_crop.shape[:2]
                #side = min(h_crop, w_crop)
                #start_y = (h_crop - side) // 2
                #start_x = (w_crop - side) // 2
                #square_crop = face_crop[start_y:start_y+side, start_x:start_x+side]
                #resized = cv2.resize(square_crop, (224, 224))
                #frames.append(resized)

                break  # only one face per frame

    cap.release()

    # Save as video
    tmpdir = tempfile.mkdtemp()
    output_path = os.path.join(tmpdir, "face_only_video.mp4")
    #clip = ImageSequenceClip([cv2.cvtColor(f, cv2.COLOR_BGR2RGB) for f in frames], fps=25)
    #clip = ImageSequenceClip([cv2.cvtColor(f, cv2.COLOR_BGR2RGB) for f in frames], fps=fps)
    clip = ImageSequenceClip(
        [cv2.cvtColor(cv2.resize(f, (224, 224)), cv2.COLOR_BGR2RGB) for f in frames],
        fps=fps
    )
    clip.write_videofile(output_path, codec="libx264", audio=False, fps=25)

    # Save audio from original, resampled to 16kHz
    audio_path = os.path.join(tmpdir, "audio_16k.wav")

    # Extract audio using ffmpeg-python (more robust than moviepy)
    ffmpeg.input(video_file).output(
        audio_path,
        ar=16000,  # resample to 16k
        ac=1,      # mono
        format='wav',
        vn=None    # no video
    ).run(overwrite_output=True)




    # ------------------------------- #
    # AVSE models

    enhanced_audio_path = run_avse_inference(output_path, audio_path)


    return output_path, enhanced_audio_path
    #return output_path, audio_path

iface = gr.Interface(
    fn=extract_faces,
    inputs=gr.Video(label="Upload or record your video"),
    outputs=[
        gr.Video(label="Detected Face Only Video"),
        #gr.Audio(label="Extracted Audio (16kHz)", type="filepath"),
        gr.Audio(label="Enhanced Audio", type="filepath")
    ],
    title="Face Detector",
    description="Upload or record a video. We'll crop face regions and return a face-only video and its 16kHz audio."
)

iface.launch()



ckpt = "ckpts/SEMamba_advanced.pth"
cfg_f = "recipes/SEMamba_advanced.yaml"

# load config
with open(cfg_f, 'r') as f:
    cfg = yaml.safe_load(f)


# device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
device = "cuda"
model  = SEMamba(cfg).to(device)
#sdict  = torch.load(ckpt, map_location=device)
#model.load_state_dict(sdict["generator"])
#model.eval()

@spaces.GPU
def enhance(filepath, model_name):
    # Load model based on selection
    ckpt_path = {
        "VCTK-Demand": "ckpts/SEMamba_advanced.pth",
        "VCTK+DNS": "ckpts/vd.pth"
    }[model_name]

    print("Loading:", ckpt_path)
    model.load_state_dict(torch.load(ckpt_path, map_location=device)["generator"])
    model.eval()
    with torch.no_grad():
        # load & resample
        wav, orig_sr = librosa.load(filepath, sr=None)
        noisy_wav = wav.copy()
        if orig_sr != 16000:
            wav = librosa.resample(wav, orig_sr=orig_sr, target_sr=16000)
        x = torch.from_numpy(wav).float().to(device)
        norm = torch.sqrt(len(x)/torch.sum(x**2))
        #x = (x * norm).unsqueeze(0)
        x = (x * norm)

        # split into 4s segments (64000 samples)
        segment_len = 4 * 16000
        chunks = x.split(segment_len)
        enhanced_chunks = []

        for chunk in chunks:
            if len(chunk) < segment_len:
                #pad = torch.zeros(segment_len - len(chunk), device=chunk.device)
                pad = (torch.randn(segment_len - len(chunk), device=chunk.device) * 1e-4)
                chunk = torch.cat([chunk, pad])
            chunk = chunk.unsqueeze(0)

            amp, pha, _ = mag_phase_stft(chunk, 400, 100, 400, 0.3)
            amp2, pha2, _ = model(amp, pha)
            out = mag_phase_istft(amp2, pha2, 400, 100, 400, 0.3)
            out = (out / norm).squeeze(0)
            enhanced_chunks.append(out)

        out = torch.cat(enhanced_chunks)[:len(x)].cpu().numpy()  # trim padding

        # back to original rate
        if orig_sr != 16000:
            out = librosa.resample(out, orig_sr=16000, target_sr=orig_sr)

        # Normalize
        peak = np.max(np.abs(out))
        if peak > 0.05:
            out = out / peak * 0.85

        # write file
        sf.write("enhanced.wav", out, orig_sr)

        # spectrograms
        fig, axs = plt.subplots(1, 2, figsize=(16, 4))

        # noisy
        D_noisy = librosa.stft(noisy_wav, n_fft=512, hop_length=256)
        S_noisy = librosa.amplitude_to_db(np.abs(D_noisy), ref=np.max)
        librosa.display.specshow(S_noisy, sr=orig_sr, hop_length=256, x_axis="time", y_axis="hz", ax=axs[0], vmax=0)
        axs[0].set_title("Noisy Spectrogram")

        # enhanced
        D_clean = librosa.stft(out, n_fft=512, hop_length=256)
        S_clean = librosa.amplitude_to_db(np.abs(D_clean), ref=np.max)
        librosa.display.specshow(S_clean, sr=orig_sr, hop_length=256, x_axis="time", y_axis="hz", ax=axs[1], vmax=0)
        #librosa.display.specshow(S_clean, sr=16000, hop_length=512, x_axis="time", y_axis="hz", ax=axs[1], vmax=0)
        axs[1].set_title("Enhanced Spectrogram")

        plt.tight_layout()

    return "enhanced.wav", fig

#with gr.Blocks() as demo:
#    gr.Markdown(ABOUT)
#    input_audio = gr.Audio(label="Input Audio", type="filepath", interactive=True)
#    enhance_btn = gr.Button("Enhance")
#    output_audio = gr.Audio(label="Enhanced Audio", type="filepath")
#    plot_output = gr.Plot(label="Spectrograms")
#
#    enhance_btn.click(fn=enhance, inputs=input_audio, outputs=[output_audio, plot_output])
#
#demo.queue().launch()

with gr.Blocks() as demo:
    gr.Markdown(ABOUT)
    input_audio = gr.Audio(label="Input Audio", type="filepath", interactive=True)
    model_choice = gr.Radio(
        label="Choose Model (The use of VCTK+DNS is recommended)",
        choices=["VCTK-Demand", "VCTK+DNS"],
        value="VCTK-Demand"
    )
    enhance_btn = gr.Button("Enhance")
    output_audio = gr.Audio(label="Enhanced Audio", type="filepath")
    plot_output = gr.Plot(label="Spectrograms")

    enhance_btn.click(
        fn=enhance,
        inputs=[input_audio, model_choice],
        outputs=[output_audio, plot_output]
    )
    gr.Markdown("**Note**: The current models are trained on 16kHz audio. Therefore, any input audio not sampled at 16kHz will be automatically resampled before enhancement.")

demo.queue().launch()