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# Copyright 2023 Zhejiang University Team and The HuggingFace Team. All rights reserved. | |
# | |
# Licensed under the Apache License, Version 2.0 (the "License"); | |
# you may not use this file except in compliance with the License. | |
# You may obtain a copy of the License at | |
# | |
# http://www.apache.org/licenses/LICENSE-2.0 | |
# | |
# Unless required by applicable law or agreed to in writing, software | |
# distributed under the License is distributed on an "AS IS" BASIS, | |
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. | |
# See the License for the specific language governing permissions and | |
# limitations under the License. | |
# DISCLAIMER: This file is strongly influenced by https://github.com/ermongroup/ddim | |
from dataclasses import dataclass | |
from typing import Optional, Tuple, Union | |
import flax | |
import jax | |
import jax.numpy as jnp | |
from ..configuration_utils import ConfigMixin, register_to_config | |
from .scheduling_utils_flax import ( | |
CommonSchedulerState, | |
FlaxKarrasDiffusionSchedulers, | |
FlaxSchedulerMixin, | |
FlaxSchedulerOutput, | |
add_noise_common, | |
) | |
class PNDMSchedulerState: | |
common: CommonSchedulerState | |
final_alpha_cumprod: jnp.ndarray | |
# setable values | |
init_noise_sigma: jnp.ndarray | |
timesteps: jnp.ndarray | |
num_inference_steps: Optional[int] = None | |
prk_timesteps: Optional[jnp.ndarray] = None | |
plms_timesteps: Optional[jnp.ndarray] = None | |
# running values | |
cur_model_output: Optional[jnp.ndarray] = None | |
counter: Optional[jnp.int32] = None | |
cur_sample: Optional[jnp.ndarray] = None | |
ets: Optional[jnp.ndarray] = None | |
def create( | |
cls, | |
common: CommonSchedulerState, | |
final_alpha_cumprod: jnp.ndarray, | |
init_noise_sigma: jnp.ndarray, | |
timesteps: jnp.ndarray, | |
): | |
return cls( | |
common=common, | |
final_alpha_cumprod=final_alpha_cumprod, | |
init_noise_sigma=init_noise_sigma, | |
timesteps=timesteps, | |
) | |
class FlaxPNDMSchedulerOutput(FlaxSchedulerOutput): | |
state: PNDMSchedulerState | |
class FlaxPNDMScheduler(FlaxSchedulerMixin, ConfigMixin): | |
""" | |
Pseudo numerical methods for diffusion models (PNDM) proposes using more advanced ODE integration techniques, | |
namely Runge-Kutta method and a linear multi-step method. | |
[`~ConfigMixin`] takes care of storing all config attributes that are passed in the scheduler's `__init__` | |
function, such as `num_train_timesteps`. They can be accessed via `scheduler.config.num_train_timesteps`. | |
[`SchedulerMixin`] provides general loading and saving functionality via the [`SchedulerMixin.save_pretrained`] and | |
[`~SchedulerMixin.from_pretrained`] functions. | |
For more details, see the original paper: https://arxiv.org/abs/2202.09778 | |
Args: | |
num_train_timesteps (`int`): number of diffusion steps used to train the model. | |
beta_start (`float`): the starting `beta` value of inference. | |
beta_end (`float`): the final `beta` value. | |
beta_schedule (`str`): | |
the beta schedule, a mapping from a beta range to a sequence of betas for stepping the model. Choose from | |
`linear`, `scaled_linear`, or `squaredcos_cap_v2`. | |
trained_betas (`jnp.ndarray`, optional): | |
option to pass an array of betas directly to the constructor to bypass `beta_start`, `beta_end` etc. | |
skip_prk_steps (`bool`): | |
allows the scheduler to skip the Runge-Kutta steps that are defined in the original paper as being required | |
before plms steps; defaults to `False`. | |
set_alpha_to_one (`bool`, default `False`): | |
each diffusion step uses the value of alphas product at that step and at the previous one. For the final | |
step there is no previous alpha. When this option is `True` the previous alpha product is fixed to `1`, | |
otherwise it uses the value of alpha at step 0. | |
steps_offset (`int`, default `0`): | |
an offset added to the inference steps. You can use a combination of `offset=1` and | |
`set_alpha_to_one=False`, to make the last step use step 0 for the previous alpha product, as done in | |
stable diffusion. | |
prediction_type (`str`, default `epsilon`, optional): | |
prediction type of the scheduler function, one of `epsilon` (predicting the noise of the diffusion | |
process), `sample` (directly predicting the noisy sample`) or `v_prediction` (see section 2.4 | |
https://imagen.research.google/video/paper.pdf) | |
dtype (`jnp.dtype`, *optional*, defaults to `jnp.float32`): | |
the `dtype` used for params and computation. | |
""" | |
_compatibles = [e.name for e in FlaxKarrasDiffusionSchedulers] | |
dtype: jnp.dtype | |
pndm_order: int | |
def has_state(self): | |
return True | |
def __init__( | |
self, | |
num_train_timesteps: int = 1000, | |
beta_start: float = 0.0001, | |
beta_end: float = 0.02, | |
beta_schedule: str = "linear", | |
trained_betas: Optional[jnp.ndarray] = None, | |
skip_prk_steps: bool = False, | |
set_alpha_to_one: bool = False, | |
steps_offset: int = 0, | |
prediction_type: str = "epsilon", | |
dtype: jnp.dtype = jnp.float32, | |
): | |
self.dtype = dtype | |
# For now we only support F-PNDM, i.e. the runge-kutta method | |
# For more information on the algorithm please take a look at the paper: https://arxiv.org/pdf/2202.09778.pdf | |
# mainly at formula (9), (12), (13) and the Algorithm 2. | |
self.pndm_order = 4 | |
def create_state(self, common: Optional[CommonSchedulerState] = None) -> PNDMSchedulerState: | |
if common is None: | |
common = CommonSchedulerState.create(self) | |
# At every step in ddim, we are looking into the previous alphas_cumprod | |
# For the final step, there is no previous alphas_cumprod because we are already at 0 | |
# `set_alpha_to_one` decides whether we set this parameter simply to one or | |
# whether we use the final alpha of the "non-previous" one. | |
final_alpha_cumprod = ( | |
jnp.array(1.0, dtype=self.dtype) if self.config.set_alpha_to_one else common.alphas_cumprod[0] | |
) | |
# standard deviation of the initial noise distribution | |
init_noise_sigma = jnp.array(1.0, dtype=self.dtype) | |
timesteps = jnp.arange(0, self.config.num_train_timesteps).round()[::-1] | |
return PNDMSchedulerState.create( | |
common=common, | |
final_alpha_cumprod=final_alpha_cumprod, | |
init_noise_sigma=init_noise_sigma, | |
timesteps=timesteps, | |
) | |
def set_timesteps(self, state: PNDMSchedulerState, num_inference_steps: int, shape: Tuple) -> PNDMSchedulerState: | |
""" | |
Sets the discrete timesteps used for the diffusion chain. Supporting function to be run before inference. | |
Args: | |
state (`PNDMSchedulerState`): | |
the `FlaxPNDMScheduler` state data class instance. | |
num_inference_steps (`int`): | |
the number of diffusion steps used when generating samples with a pre-trained model. | |
shape (`Tuple`): | |
the shape of the samples to be generated. | |
""" | |
step_ratio = self.config.num_train_timesteps // num_inference_steps | |
# creates integer timesteps by multiplying by ratio | |
# rounding to avoid issues when num_inference_step is power of 3 | |
_timesteps = (jnp.arange(0, num_inference_steps) * step_ratio).round() + self.config.steps_offset | |
if self.config.skip_prk_steps: | |
# for some models like stable diffusion the prk steps can/should be skipped to | |
# produce better results. When using PNDM with `self.config.skip_prk_steps` the implementation | |
# is based on crowsonkb's PLMS sampler implementation: https://github.com/CompVis/latent-diffusion/pull/51 | |
prk_timesteps = jnp.array([], dtype=jnp.int32) | |
plms_timesteps = jnp.concatenate([_timesteps[:-1], _timesteps[-2:-1], _timesteps[-1:]])[::-1] | |
else: | |
prk_timesteps = _timesteps[-self.pndm_order :].repeat(2) + jnp.tile( | |
jnp.array([0, self.config.num_train_timesteps // num_inference_steps // 2], dtype=jnp.int32), | |
self.pndm_order, | |
) | |
prk_timesteps = (prk_timesteps[:-1].repeat(2)[1:-1])[::-1] | |
plms_timesteps = _timesteps[:-3][::-1] | |
timesteps = jnp.concatenate([prk_timesteps, plms_timesteps]) | |
# initial running values | |
cur_model_output = jnp.zeros(shape, dtype=self.dtype) | |
counter = jnp.int32(0) | |
cur_sample = jnp.zeros(shape, dtype=self.dtype) | |
ets = jnp.zeros((4,) + shape, dtype=self.dtype) | |
return state.replace( | |
timesteps=timesteps, | |
num_inference_steps=num_inference_steps, | |
prk_timesteps=prk_timesteps, | |
plms_timesteps=plms_timesteps, | |
cur_model_output=cur_model_output, | |
counter=counter, | |
cur_sample=cur_sample, | |
ets=ets, | |
) | |
def scale_model_input( | |
self, state: PNDMSchedulerState, sample: jnp.ndarray, timestep: Optional[int] = None | |
) -> jnp.ndarray: | |
""" | |
Ensures interchangeability with schedulers that need to scale the denoising model input depending on the | |
current timestep. | |
Args: | |
state (`PNDMSchedulerState`): the `FlaxPNDMScheduler` state data class instance. | |
sample (`jnp.ndarray`): input sample | |
timestep (`int`, optional): current timestep | |
Returns: | |
`jnp.ndarray`: scaled input sample | |
""" | |
return sample | |
def step( | |
self, | |
state: PNDMSchedulerState, | |
model_output: jnp.ndarray, | |
timestep: int, | |
sample: jnp.ndarray, | |
return_dict: bool = True, | |
) -> Union[FlaxPNDMSchedulerOutput, Tuple]: | |
""" | |
Predict the sample at the previous timestep by reversing the SDE. Core function to propagate the diffusion | |
process from the learned model outputs (most often the predicted noise). | |
This function calls `step_prk()` or `step_plms()` depending on the internal variable `counter`. | |
Args: | |
state (`PNDMSchedulerState`): the `FlaxPNDMScheduler` state data class instance. | |
model_output (`jnp.ndarray`): direct output from learned diffusion model. | |
timestep (`int`): current discrete timestep in the diffusion chain. | |
sample (`jnp.ndarray`): | |
current instance of sample being created by diffusion process. | |
return_dict (`bool`): option for returning tuple rather than FlaxPNDMSchedulerOutput class | |
Returns: | |
[`FlaxPNDMSchedulerOutput`] or `tuple`: [`FlaxPNDMSchedulerOutput`] if `return_dict` is True, otherwise a | |
`tuple`. When returning a tuple, the first element is the sample tensor. | |
""" | |
if state.num_inference_steps is None: | |
raise ValueError( | |
"Number of inference steps is 'None', you need to run 'set_timesteps' after creating the scheduler" | |
) | |
if self.config.skip_prk_steps: | |
prev_sample, state = self.step_plms(state, model_output, timestep, sample) | |
else: | |
prk_prev_sample, prk_state = self.step_prk(state, model_output, timestep, sample) | |
plms_prev_sample, plms_state = self.step_plms(state, model_output, timestep, sample) | |
cond = state.counter < len(state.prk_timesteps) | |
prev_sample = jax.lax.select(cond, prk_prev_sample, plms_prev_sample) | |
state = state.replace( | |
cur_model_output=jax.lax.select(cond, prk_state.cur_model_output, plms_state.cur_model_output), | |
ets=jax.lax.select(cond, prk_state.ets, plms_state.ets), | |
cur_sample=jax.lax.select(cond, prk_state.cur_sample, plms_state.cur_sample), | |
counter=jax.lax.select(cond, prk_state.counter, plms_state.counter), | |
) | |
if not return_dict: | |
return (prev_sample, state) | |
return FlaxPNDMSchedulerOutput(prev_sample=prev_sample, state=state) | |
def step_prk( | |
self, | |
state: PNDMSchedulerState, | |
model_output: jnp.ndarray, | |
timestep: int, | |
sample: jnp.ndarray, | |
) -> Union[FlaxPNDMSchedulerOutput, Tuple]: | |
""" | |
Step function propagating the sample with the Runge-Kutta method. RK takes 4 forward passes to approximate the | |
solution to the differential equation. | |
Args: | |
state (`PNDMSchedulerState`): the `FlaxPNDMScheduler` state data class instance. | |
model_output (`jnp.ndarray`): direct output from learned diffusion model. | |
timestep (`int`): current discrete timestep in the diffusion chain. | |
sample (`jnp.ndarray`): | |
current instance of sample being created by diffusion process. | |
return_dict (`bool`): option for returning tuple rather than FlaxPNDMSchedulerOutput class | |
Returns: | |
[`FlaxPNDMSchedulerOutput`] or `tuple`: [`FlaxPNDMSchedulerOutput`] if `return_dict` is True, otherwise a | |
`tuple`. When returning a tuple, the first element is the sample tensor. | |
""" | |
if state.num_inference_steps is None: | |
raise ValueError( | |
"Number of inference steps is 'None', you need to run 'set_timesteps' after creating the scheduler" | |
) | |
diff_to_prev = jnp.where( | |
state.counter % 2, 0, self.config.num_train_timesteps // state.num_inference_steps // 2 | |
) | |
prev_timestep = timestep - diff_to_prev | |
timestep = state.prk_timesteps[state.counter // 4 * 4] | |
model_output = jax.lax.select( | |
(state.counter % 4) != 3, | |
model_output, # remainder 0, 1, 2 | |
state.cur_model_output + 1 / 6 * model_output, # remainder 3 | |
) | |
state = state.replace( | |
cur_model_output=jax.lax.select_n( | |
state.counter % 4, | |
state.cur_model_output + 1 / 6 * model_output, # remainder 0 | |
state.cur_model_output + 1 / 3 * model_output, # remainder 1 | |
state.cur_model_output + 1 / 3 * model_output, # remainder 2 | |
jnp.zeros_like(state.cur_model_output), # remainder 3 | |
), | |
ets=jax.lax.select( | |
(state.counter % 4) == 0, | |
state.ets.at[0:3].set(state.ets[1:4]).at[3].set(model_output), # remainder 0 | |
state.ets, # remainder 1, 2, 3 | |
), | |
cur_sample=jax.lax.select( | |
(state.counter % 4) == 0, | |
sample, # remainder 0 | |
state.cur_sample, # remainder 1, 2, 3 | |
), | |
) | |
cur_sample = state.cur_sample | |
prev_sample = self._get_prev_sample(state, cur_sample, timestep, prev_timestep, model_output) | |
state = state.replace(counter=state.counter + 1) | |
return (prev_sample, state) | |
def step_plms( | |
self, | |
state: PNDMSchedulerState, | |
model_output: jnp.ndarray, | |
timestep: int, | |
sample: jnp.ndarray, | |
) -> Union[FlaxPNDMSchedulerOutput, Tuple]: | |
""" | |
Step function propagating the sample with the linear multi-step method. This has one forward pass with multiple | |
times to approximate the solution. | |
Args: | |
state (`PNDMSchedulerState`): the `FlaxPNDMScheduler` state data class instance. | |
model_output (`jnp.ndarray`): direct output from learned diffusion model. | |
timestep (`int`): current discrete timestep in the diffusion chain. | |
sample (`jnp.ndarray`): | |
current instance of sample being created by diffusion process. | |
return_dict (`bool`): option for returning tuple rather than FlaxPNDMSchedulerOutput class | |
Returns: | |
[`FlaxPNDMSchedulerOutput`] or `tuple`: [`FlaxPNDMSchedulerOutput`] if `return_dict` is True, otherwise a | |
`tuple`. When returning a tuple, the first element is the sample tensor. | |
""" | |
if state.num_inference_steps is None: | |
raise ValueError( | |
"Number of inference steps is 'None', you need to run 'set_timesteps' after creating the scheduler" | |
) | |
# NOTE: There is no way to check in the jitted runtime if the prk mode was ran before | |
prev_timestep = timestep - self.config.num_train_timesteps // state.num_inference_steps | |
prev_timestep = jnp.where(prev_timestep > 0, prev_timestep, 0) | |
# Reference: | |
# if state.counter != 1: | |
# state.ets.append(model_output) | |
# else: | |
# prev_timestep = timestep | |
# timestep = timestep + self.config.num_train_timesteps // state.num_inference_steps | |
prev_timestep = jnp.where(state.counter == 1, timestep, prev_timestep) | |
timestep = jnp.where( | |
state.counter == 1, timestep + self.config.num_train_timesteps // state.num_inference_steps, timestep | |
) | |
# Reference: | |
# if len(state.ets) == 1 and state.counter == 0: | |
# model_output = model_output | |
# state.cur_sample = sample | |
# elif len(state.ets) == 1 and state.counter == 1: | |
# model_output = (model_output + state.ets[-1]) / 2 | |
# sample = state.cur_sample | |
# state.cur_sample = None | |
# elif len(state.ets) == 2: | |
# model_output = (3 * state.ets[-1] - state.ets[-2]) / 2 | |
# elif len(state.ets) == 3: | |
# model_output = (23 * state.ets[-1] - 16 * state.ets[-2] + 5 * state.ets[-3]) / 12 | |
# else: | |
# model_output = (1 / 24) * (55 * state.ets[-1] - 59 * state.ets[-2] + 37 * state.ets[-3] - 9 * state.ets[-4]) | |
state = state.replace( | |
ets=jax.lax.select( | |
state.counter != 1, | |
state.ets.at[0:3].set(state.ets[1:4]).at[3].set(model_output), # counter != 1 | |
state.ets, # counter 1 | |
), | |
cur_sample=jax.lax.select( | |
state.counter != 1, | |
sample, # counter != 1 | |
state.cur_sample, # counter 1 | |
), | |
) | |
state = state.replace( | |
cur_model_output=jax.lax.select_n( | |
jnp.clip(state.counter, 0, 4), | |
model_output, # counter 0 | |
(model_output + state.ets[-1]) / 2, # counter 1 | |
(3 * state.ets[-1] - state.ets[-2]) / 2, # counter 2 | |
(23 * state.ets[-1] - 16 * state.ets[-2] + 5 * state.ets[-3]) / 12, # counter 3 | |
(1 / 24) | |
* (55 * state.ets[-1] - 59 * state.ets[-2] + 37 * state.ets[-3] - 9 * state.ets[-4]), # counter >= 4 | |
), | |
) | |
sample = state.cur_sample | |
model_output = state.cur_model_output | |
prev_sample = self._get_prev_sample(state, sample, timestep, prev_timestep, model_output) | |
state = state.replace(counter=state.counter + 1) | |
return (prev_sample, state) | |
def _get_prev_sample(self, state: PNDMSchedulerState, sample, timestep, prev_timestep, model_output): | |
# See formula (9) of PNDM paper https://arxiv.org/pdf/2202.09778.pdf | |
# this function computes x_(t−δ) using the formula of (9) | |
# Note that x_t needs to be added to both sides of the equation | |
# Notation (<variable name> -> <name in paper> | |
# alpha_prod_t -> α_t | |
# alpha_prod_t_prev -> α_(t−δ) | |
# beta_prod_t -> (1 - α_t) | |
# beta_prod_t_prev -> (1 - α_(t−δ)) | |
# sample -> x_t | |
# model_output -> e_θ(x_t, t) | |
# prev_sample -> x_(t−δ) | |
alpha_prod_t = state.common.alphas_cumprod[timestep] | |
alpha_prod_t_prev = jnp.where( | |
prev_timestep >= 0, state.common.alphas_cumprod[prev_timestep], state.final_alpha_cumprod | |
) | |
beta_prod_t = 1 - alpha_prod_t | |
beta_prod_t_prev = 1 - alpha_prod_t_prev | |
if self.config.prediction_type == "v_prediction": | |
model_output = (alpha_prod_t**0.5) * model_output + (beta_prod_t**0.5) * sample | |
elif self.config.prediction_type != "epsilon": | |
raise ValueError( | |
f"prediction_type given as {self.config.prediction_type} must be one of `epsilon` or `v_prediction`" | |
) | |
# corresponds to (α_(t−δ) - α_t) divided by | |
# denominator of x_t in formula (9) and plus 1 | |
# Note: (α_(t−δ) - α_t) / (sqrt(α_t) * (sqrt(α_(t−δ)) + sqr(α_t))) = | |
# sqrt(α_(t−δ)) / sqrt(α_t)) | |
sample_coeff = (alpha_prod_t_prev / alpha_prod_t) ** (0.5) | |
# corresponds to denominator of e_θ(x_t, t) in formula (9) | |
model_output_denom_coeff = alpha_prod_t * beta_prod_t_prev ** (0.5) + ( | |
alpha_prod_t * beta_prod_t * alpha_prod_t_prev | |
) ** (0.5) | |
# full formula (9) | |
prev_sample = ( | |
sample_coeff * sample - (alpha_prod_t_prev - alpha_prod_t) * model_output / model_output_denom_coeff | |
) | |
return prev_sample | |
def add_noise( | |
self, | |
state: PNDMSchedulerState, | |
original_samples: jnp.ndarray, | |
noise: jnp.ndarray, | |
timesteps: jnp.ndarray, | |
) -> jnp.ndarray: | |
return add_noise_common(state.common, original_samples, noise, timesteps) | |
def __len__(self): | |
return self.config.num_train_timesteps | |