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"""

Utilities for changing sampling schedules of a trained model.



Simplified from: https://github.com/openai/guided-diffusion/blob/main/guided_diffusion/respace.py

"""

import numpy as np
import torch as th

from .gaussian_diffusion import GaussianDiffusion


def space_timesteps(num_timesteps, section_counts):
    """

    Create a list of timesteps to use from an original diffusion process,

    given the number of timesteps we want to take from equally-sized portions

    of the original process.



    For example, if there's 300 timesteps and the section counts are [10,15,20]

    then the first 100 timesteps are strided to be 10 timesteps, the second 100

    are strided to be 15 timesteps, and the final 100 are strided to be 20.



    :param num_timesteps: the number of diffusion steps in the original

                          process to divide up.

    :param section_counts: either a list of numbers, or a string containing

                           comma-separated numbers, indicating the step count

                           per section. As a special case, use "ddimN" where N

                           is a number of steps to use the striding from the

                           DDIM paper.

    :return: a set of diffusion steps from the original process to use.

    """
    if isinstance(section_counts, str):
        if section_counts.startswith("ddim"):
            desired_count = int(section_counts[len("ddim") :])
            for i in range(1, num_timesteps):
                if len(range(0, num_timesteps, i)) == desired_count:
                    return set(range(0, num_timesteps, i))
            raise ValueError(f"cannot create exactly {num_timesteps} steps with an integer stride")
        elif section_counts == "fast27":
            steps = space_timesteps(num_timesteps, "10,10,3,2,2")
            # Help reduce DDIM artifacts from noisiest timesteps.
            steps.remove(num_timesteps - 1)
            steps.add(num_timesteps - 3)
            return steps
        section_counts = [int(x) for x in section_counts.split(",")]
    size_per = num_timesteps // len(section_counts)
    extra = num_timesteps % len(section_counts)
    start_idx = 0
    all_steps = []
    for i, section_count in enumerate(section_counts):
        size = size_per + (1 if i < extra else 0)
        if size < section_count:
            raise ValueError(f"cannot divide section of {size} steps into {section_count}")
        if section_count <= 1:
            frac_stride = 1
        else:
            frac_stride = (size - 1) / (section_count - 1)
        cur_idx = 0.0
        taken_steps = []
        for _ in range(section_count):
            taken_steps.append(start_idx + round(cur_idx))
            cur_idx += frac_stride
        all_steps += taken_steps
        start_idx += size
    return set(all_steps)


class SpacedDiffusion(GaussianDiffusion):
    """

    A diffusion process which can skip steps in a base diffusion process.



    :param use_timesteps: a collection (sequence or set) of timesteps from the

                          original diffusion process to retain.

    :param kwargs: the kwargs to create the base diffusion process.

    """

    def __init__(self, use_timesteps, **kwargs):
        self.use_timesteps = set(use_timesteps)
        self.timestep_map = []
        self.original_num_steps = len(kwargs["betas"])

        base_diffusion = GaussianDiffusion(**kwargs)  # pylint: disable=missing-kwoa
        last_alpha_cumprod = 1.0
        new_betas = []
        for i, alpha_cumprod in enumerate(base_diffusion.alphas_cumprod):
            if i in self.use_timesteps:
                new_betas.append(1 - alpha_cumprod / last_alpha_cumprod)
                last_alpha_cumprod = alpha_cumprod
                self.timestep_map.append(i)
        kwargs["betas"] = np.array(new_betas)
        super().__init__(**kwargs)

    def p_mean_variance(self, model, *args, **kwargs):
        return super().p_mean_variance(self._wrap_model(model), *args, **kwargs)

    def condition_mean(self, cond_fn, *args, **kwargs):
        return super().condition_mean(self._wrap_model(cond_fn), *args, **kwargs)

    def condition_score(self, cond_fn, *args, **kwargs):
        return super().condition_score(self._wrap_model(cond_fn), *args, **kwargs)

    def _wrap_model(self, model):
        if isinstance(model, _WrappedModel):
            return model
        return _WrappedModel(model, self.timestep_map, self.original_num_steps)


class _WrappedModel:
    def __init__(self, model, timestep_map, original_num_steps):
        self.model = model
        self.timestep_map = timestep_map
        self.original_num_steps = original_num_steps

    def __call__(self, x, ts, **kwargs):
        map_tensor = th.tensor(self.timestep_map, device=ts.device, dtype=ts.dtype)
        new_ts = map_tensor[ts]
        return self.model(x, new_ts, **kwargs)