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import math
import os
from dataclasses import dataclass, field
from typing import List, Union

import numpy as np
import PIL.Image
import torch
import torch.nn.functional as F
import trimesh
from einops import rearrange
from huggingface_hub import hf_hub_download
from omegaconf import OmegaConf
from PIL import Image
import sys
script_dir = os.path.dirname(os.path.abspath(__file__))
imgto3d_path = os.path.join(script_dir, '.')
print(imgto3d_path)
sys.path.append(imgto3d_path)

from .models.isosurface import MarchingCubeHelper
from tsr_utils import (
    BaseModule,
    ImagePreprocessor,
    find_class,
    get_spherical_cameras,
    scale_tensor,
)


class TSR(BaseModule):
    @dataclass
    class Config(BaseModule.Config):
        cond_image_size: int

        image_tokenizer_cls: str
        image_tokenizer: dict

        tokenizer_cls: str
        tokenizer: dict

        backbone_cls: str
        backbone: dict

        post_processor_cls: str
        post_processor: dict

        decoder_cls: str
        decoder: dict

        renderer_cls: str
        renderer: dict

    cfg: Config

    @classmethod
    def from_pretrained(

        cls, config_path: str, weight_path: str

    ):
        cfg = OmegaConf.load(config_path)
        OmegaConf.resolve(cfg)
        model = cls(cfg)
        ckpt = torch.load(weight_path, map_location="cpu")
        model.load_state_dict(ckpt)
        return model

    def configure(self):
        self.image_tokenizer = find_class(self.cfg.image_tokenizer_cls)(
            self.cfg.image_tokenizer
        )
        self.tokenizer = find_class(self.cfg.tokenizer_cls)(self.cfg.tokenizer)
        self.backbone = find_class(self.cfg.backbone_cls)(self.cfg.backbone)
        self.post_processor = find_class(self.cfg.post_processor_cls)(
            self.cfg.post_processor
        )
        self.decoder = find_class(self.cfg.decoder_cls)(self.cfg.decoder)
        self.renderer = find_class(self.cfg.renderer_cls)(self.cfg.renderer)
        self.image_processor = ImagePreprocessor()
        self.isosurface_helper = None

    def forward(

        self,

        image: Union[

            PIL.Image.Image,

            np.ndarray,

            torch.FloatTensor,

            List[PIL.Image.Image],

            List[np.ndarray],

            List[torch.FloatTensor],

        ],

        device: str,

    ) -> torch.FloatTensor:
        rgb_cond = self.image_processor(image, self.cfg.cond_image_size)[:, None].to(
            device
        )
        batch_size = rgb_cond.shape[0]

        input_image_tokens: torch.Tensor = self.image_tokenizer(
            rearrange(rgb_cond, "B Nv H W C -> B Nv C H W", Nv=1),
        )

        input_image_tokens = rearrange(
            input_image_tokens, "B Nv C Nt -> B (Nv Nt) C", Nv=1
        )

        tokens: torch.Tensor = self.tokenizer(batch_size)

        tokens = self.backbone(
            tokens,
            encoder_hidden_states=input_image_tokens,
        )

        scene_codes = self.post_processor(self.tokenizer.detokenize(tokens))
        return scene_codes

    def render(

        self,

        scene_codes,

        n_views: int,

        elevation_deg: float = 0.0,

        camera_distance: float = 1.9,

        fovy_deg: float = 40.0,

        height: int = 256,

        width: int = 256,

        return_type: str = "pil",

    ):
        rays_o, rays_d = get_spherical_cameras(
            n_views, elevation_deg, camera_distance, fovy_deg, height, width
        )
        rays_o, rays_d = rays_o.to(scene_codes.device), rays_d.to(scene_codes.device)

        def process_output(image: torch.FloatTensor):
            if return_type == "pt":
                return image
            elif return_type == "np":
                return image.detach().cpu().numpy()
            elif return_type == "pil":
                return Image.fromarray(
                    (image.detach().cpu().numpy() * 255.0).astype(np.uint8)
                )
            else:
                raise NotImplementedError

        images = []
        for scene_code in scene_codes:
            images_ = []
            for i in range(n_views):
                with torch.no_grad():
                    image = self.renderer(
                        self.decoder, scene_code, rays_o[i], rays_d[i]
                    )
                images_.append(process_output(image))
            images.append(images_)

        return images

    def set_marching_cubes_resolution(self, resolution: int):
        if (
            self.isosurface_helper is not None
            and self.isosurface_helper.resolution == resolution
        ):
            return
        self.isosurface_helper = MarchingCubeHelper(resolution)

    def extract_mesh(self, scene_codes, resolution: int = 256, threshold: float = 25.0):
        self.set_marching_cubes_resolution(resolution)
        meshes = []
        for scene_code in scene_codes:
            with torch.no_grad():
                density = self.renderer.query_triplane(
                    self.decoder,
                    scale_tensor(
                        self.isosurface_helper.grid_vertices.to(scene_codes.device),
                        self.isosurface_helper.points_range,
                        (-self.renderer.cfg.radius, self.renderer.cfg.radius),
                    ),
                    scene_code,
                )["density_act"]
            v_pos, t_pos_idx = self.isosurface_helper(-(density - threshold))
            v_pos = scale_tensor(
                v_pos,
                self.isosurface_helper.points_range,
                (-self.renderer.cfg.radius, self.renderer.cfg.radius),
            )
            with torch.no_grad():
                color = self.renderer.query_triplane(
                    self.decoder,
                    v_pos,
                    scene_code,
                )["color"]
            mesh = trimesh.Trimesh(
                vertices=v_pos.cpu().numpy(),
                faces=t_pos_idx.cpu().numpy(),
                vertex_colors=color.cpu().numpy(),
            )
            meshes.append(mesh)
        return meshes