import os
import shutil
import ffmpeg
from datetime import datetime
from pathlib import Path
import numpy as np
import cv2
import torch
import spaces
# from diffusers import AutoencoderKL, DDIMScheduler
# from einops import repeat
# from omegaconf import OmegaConf
from PIL import Image
from torchvision import transforms
# from transformers import CLIPVisionModelWithProjection

# from src.models.pose_guider import PoseGuider
# from src.models.unet_2d_condition import UNet2DConditionModel
# from src.models.unet_3d import UNet3DConditionModel
# from src.pipelines.pipeline_pose2vid_long import Pose2VideoPipeline
from src.utils.util import get_fps, read_frames, save_videos_grid

# from src.utils.mp_utils  import LMKExtractor
# from src.utils.draw_util import FaceMeshVisualizer
from src.utils.pose_util import project_points_with_trans, matrix_to_euler_and_translation, euler_and_translation_to_matrix
from src.audio2vid import smooth_pose_seq
from src.utils.crop_face_single import crop_face
from src.create_modules import lmk_extractor, vis, pipe

@spaces.GPU
def video2video(ref_img, source_video, size=512, steps=25, length=150, seed=42):
    cfg = 3.5
    
    # config = OmegaConf.load('./configs/prompts/animation_facereenac.yaml')

    # if config.weight_dtype == "fp16":
    #     weight_dtype = torch.float16
    # else:
    #     weight_dtype = torch.float32

    # vae = AutoencoderKL.from_pretrained(
    #     config.pretrained_vae_path,
    # ).to("cuda", dtype=weight_dtype)

    # reference_unet = UNet2DConditionModel.from_pretrained(
    #     config.pretrained_base_model_path,
    #     subfolder="unet",
    # ).to(dtype=weight_dtype, device="cuda")

    # inference_config_path = config.inference_config
    # infer_config = OmegaConf.load(inference_config_path)
    # denoising_unet = UNet3DConditionModel.from_pretrained_2d(
    #     config.pretrained_base_model_path,
    #     config.motion_module_path,
    #     subfolder="unet",
    #     unet_additional_kwargs=infer_config.unet_additional_kwargs,
    # ).to(dtype=weight_dtype, device="cuda")

    # pose_guider = PoseGuider(noise_latent_channels=320, use_ca=True).to(device="cuda", dtype=weight_dtype) # not use cross attention

    # image_enc = CLIPVisionModelWithProjection.from_pretrained(
    #     config.image_encoder_path
    # ).to(dtype=weight_dtype, device="cuda")

    # sched_kwargs = OmegaConf.to_container(infer_config.noise_scheduler_kwargs)
    # scheduler = DDIMScheduler(**sched_kwargs)

    generator = torch.manual_seed(seed)

    width, height = size, size

    # # load pretrained weights
    # denoising_unet.load_state_dict(
    #     torch.load(config.denoising_unet_path, map_location="cpu"),
    #     strict=False,
    # )
    # reference_unet.load_state_dict(
    #     torch.load(config.reference_unet_path, map_location="cpu"),
    # )
    # pose_guider.load_state_dict(
    #     torch.load(config.pose_guider_path, map_location="cpu"),
    # )

    # pipe = Pose2VideoPipeline(
    #     vae=vae,
    #     image_encoder=image_enc,
    #     reference_unet=reference_unet,
    #     denoising_unet=denoising_unet,
    #     pose_guider=pose_guider,
    #     scheduler=scheduler,
    # )
    # pipe = pipe.to("cuda", dtype=weight_dtype)

    date_str = datetime.now().strftime("%Y%m%d")
    time_str = datetime.now().strftime("%H%M")
    save_dir_name = f"{time_str}--seed_{seed}-{size}x{size}"

    save_dir = Path(f"output/{date_str}/{save_dir_name}")
    save_dir.mkdir(exist_ok=True, parents=True)


    # lmk_extractor = LMKExtractor()
    # vis = FaceMeshVisualizer(forehead_edge=False)
    


    ref_image_np = cv2.cvtColor(ref_img, cv2.COLOR_RGB2BGR)
    ref_image_np = crop_face(ref_image_np, lmk_extractor)
    if ref_image_np is None:
        return None, Image.fromarray(ref_img)
    
    ref_image_np = cv2.resize(ref_image_np, (size, size))
    ref_image_pil = Image.fromarray(cv2.cvtColor(ref_image_np, cv2.COLOR_BGR2RGB))
    
    face_result = lmk_extractor(ref_image_np)
    if face_result is None: 
        return None, ref_image_pil
    
    lmks = face_result['lmks'].astype(np.float32)
    ref_pose = vis.draw_landmarks((ref_image_np.shape[1], ref_image_np.shape[0]), lmks, normed=True)

    source_images = read_frames(source_video)
    src_fps = get_fps(source_video)
    pose_transform = transforms.Compose(
        [transforms.Resize((height, width)), transforms.ToTensor()]
    )
    
    step = 1
    if src_fps == 60:
        src_fps = 30
        step = 2
    
    pose_trans_list = []
    verts_list = []
    bs_list = []
    src_tensor_list = []
    args_L = len(source_images) if length==0 or length*step > len(source_images) else length*step
    args_L = min(args_L, 300*step)
    for src_image_pil in source_images[: args_L: step]:
        src_tensor_list.append(pose_transform(src_image_pil))
        src_img_np = cv2.cvtColor(np.array(src_image_pil), cv2.COLOR_RGB2BGR)
        frame_height, frame_width, _ = src_img_np.shape
        src_img_result = lmk_extractor(src_img_np)
        if src_img_result is None:
            break
        pose_trans_list.append(src_img_result['trans_mat'])
        verts_list.append(src_img_result['lmks3d'])
        bs_list.append(src_img_result['bs'])

    
    # pose_arr = np.array(pose_trans_list)
    trans_mat_arr = np.array(pose_trans_list)
    verts_arr = np.array(verts_list)
    bs_arr = np.array(bs_list)
    min_bs_idx = np.argmin(bs_arr.sum(1))
    
    # compute delta pose
    pose_arr = np.zeros([trans_mat_arr.shape[0], 6])

    for i in range(pose_arr.shape[0]):
        euler_angles, translation_vector = matrix_to_euler_and_translation(trans_mat_arr[i]) # real pose of source
        pose_arr[i, :3] =  euler_angles
        pose_arr[i, 3:6] =  translation_vector
    
    init_tran_vec = face_result['trans_mat'][:3, 3] # init translation of tgt
    pose_arr[:, 3:6] = pose_arr[:, 3:6] - pose_arr[0, 3:6] + init_tran_vec # (relative translation of source) + (init translation of tgt)

    pose_arr_smooth = smooth_pose_seq(pose_arr, window_size=3)
    pose_mat_smooth = [euler_and_translation_to_matrix(pose_arr_smooth[i][:3], pose_arr_smooth[i][3:6]) for i in range(pose_arr_smooth.shape[0])]    
    pose_mat_smooth = np.array(pose_mat_smooth)   

    # face retarget
    verts_arr = verts_arr - verts_arr[min_bs_idx] + face_result['lmks3d']
    # project 3D mesh to 2D landmark
    projected_vertices = project_points_with_trans(verts_arr, pose_mat_smooth, [frame_height, frame_width])
    
    pose_list = []
    for i, verts in enumerate(projected_vertices):
        lmk_img = vis.draw_landmarks((frame_width, frame_height), verts, normed=False)
        pose_image_np = cv2.resize(lmk_img,  (width, height))
        pose_list.append(pose_image_np)
    
    pose_list = np.array(pose_list)
    
    video_length = len(pose_list)

    video = pipe(
        ref_image_pil,
        pose_list,
        ref_pose,
        width,
        height,
        video_length,
        steps,
        cfg,
        generator=generator,
    ).videos

    save_path = f"{save_dir}/{size}x{size}_{time_str}_noaudio.mp4"
    save_videos_grid(
        video,
        save_path,
        n_rows=1,
        fps=src_fps,
    )
    
    audio_output = f'{save_dir}/audio_from_video.aac'
    # extract audio
    try:
        ffmpeg.input(source_video).output(audio_output, acodec='copy').run()
        # merge audio and video
        stream = ffmpeg.input(save_path)
        audio = ffmpeg.input(audio_output)
        ffmpeg.output(stream.video, audio.audio, save_path.replace('_noaudio.mp4', '.mp4'), vcodec='copy', acodec='aac', shortest=None).run()
    
        os.remove(save_path)
        os.remove(audio_output)
    except:
        shutil.move(
            save_path,
            save_path.replace('_noaudio.mp4', '.mp4')
        )
    
    return save_path.replace('_noaudio.mp4', '.mp4'), ref_image_pil