InvokeAI/invokeai/backend/generator/txt2img2img.py
2023-02-28 08:32:11 -05:00

164 lines
7.1 KiB
Python

'''
invokeai.backend.generator.txt2img inherits from invokeai.backend.generator
'''
import math
from typing import Callable, Optional
import torch
from diffusers.utils.logging import get_verbosity, set_verbosity, set_verbosity_error
from .base import Generator
from .diffusers_pipeline import trim_to_multiple_of, StableDiffusionGeneratorPipeline, \
ConditioningData
from ..models import PostprocessingSettings
class Txt2Img2Img(Generator):
def __init__(self, model, precision):
super().__init__(model, precision)
self.init_latent = None # for get_noise()
def get_make_image(self, prompt:str, sampler, steps:int, cfg_scale:float, ddim_eta,
conditioning, width:int, height:int, strength:float,
step_callback:Optional[Callable]=None, threshold=0.0, warmup=0.2, perlin=0.0,
h_symmetry_time_pct=None, v_symmetry_time_pct=None, attention_maps_callback=None, **kwargs):
"""
Returns a function returning an image derived from the prompt and the initial image
Return value depends on the seed at the time you call it
kwargs are 'width' and 'height'
"""
self.perlin = perlin
# noinspection PyTypeChecker
pipeline: StableDiffusionGeneratorPipeline = self.model
pipeline.scheduler = sampler
uc, c, extra_conditioning_info = conditioning
conditioning_data = (
ConditioningData(
uc, c, cfg_scale, extra_conditioning_info,
postprocessing_settings = PostprocessingSettings(
threshold=threshold,
warmup=0.2,
h_symmetry_time_pct=h_symmetry_time_pct,
v_symmetry_time_pct=v_symmetry_time_pct
)
).add_scheduler_args_if_applicable(pipeline.scheduler, eta=ddim_eta))
def make_image(x_T):
first_pass_latent_output, _ = pipeline.latents_from_embeddings(
latents=torch.zeros_like(x_T),
num_inference_steps=steps,
conditioning_data=conditioning_data,
noise=x_T,
callback=step_callback,
)
# Get our initial generation width and height directly from the latent output so
# the message below is accurate.
init_width = first_pass_latent_output.size()[3] * self.downsampling_factor
init_height = first_pass_latent_output.size()[2] * self.downsampling_factor
print(
f"\n>> Interpolating from {init_width}x{init_height} to {width}x{height} using DDIM sampling"
)
# resizing
resized_latents = torch.nn.functional.interpolate(
first_pass_latent_output,
size=(height // self.downsampling_factor, width // self.downsampling_factor),
mode="bilinear"
)
# Free up memory from the last generation.
clear_cuda_cache = kwargs['clear_cuda_cache'] or None
if clear_cuda_cache is not None:
clear_cuda_cache()
second_pass_noise = self.get_noise_like(resized_latents, override_perlin=True)
# Clear symmetry for the second pass
from dataclasses import replace
new_postprocessing_settings = replace(conditioning_data.postprocessing_settings, h_symmetry_time_pct=None)
new_postprocessing_settings = replace(new_postprocessing_settings, v_symmetry_time_pct=None)
new_conditioning_data = replace(conditioning_data, postprocessing_settings=new_postprocessing_settings)
verbosity = get_verbosity()
set_verbosity_error()
pipeline_output = pipeline.img2img_from_latents_and_embeddings(
resized_latents,
num_inference_steps=steps,
conditioning_data=new_conditioning_data,
strength=strength,
noise=second_pass_noise,
callback=step_callback)
set_verbosity(verbosity)
if pipeline_output.attention_map_saver is not None and attention_maps_callback is not None:
attention_maps_callback(pipeline_output.attention_map_saver)
return pipeline.numpy_to_pil(pipeline_output.images)[0]
# FIXME: do we really need something entirely different for the inpainting model?
# in the case of the inpainting model being loaded, the trick of
# providing an interpolated latent doesn't work, so we transiently
# create a 512x512 PIL image, upscale it, and run the inpainting
# over it in img2img mode. Because the inpaing model is so conservative
# it doesn't change the image (much)
return make_image
def get_noise_like(self, like: torch.Tensor, override_perlin: bool=False):
device = like.device
if device.type == 'mps':
x = torch.randn_like(like, device='cpu', dtype=self.torch_dtype()).to(device)
else:
x = torch.randn_like(like, device=device, dtype=self.torch_dtype())
if self.perlin > 0.0 and override_perlin == False:
shape = like.shape
x = (1-self.perlin)*x + self.perlin*self.get_perlin_noise(shape[3], shape[2])
return x
# returns a tensor filled with random numbers from a normal distribution
def get_noise(self,width,height,scale = True):
# print(f"Get noise: {width}x{height}")
if scale:
# Scale the input width and height for the initial generation
# Make their area equivalent to the model's resolution area (e.g. 512*512 = 262144),
# while keeping the minimum dimension at least 0.5 * resolution (e.g. 512*0.5 = 256)
aspect = width / height
dimension = self.model.unet.config.sample_size * self.model.vae_scale_factor
min_dimension = math.floor(dimension * 0.5)
model_area = dimension * dimension # hardcoded for now since all models are trained on square images
if aspect > 1.0:
init_height = max(min_dimension, math.sqrt(model_area / aspect))
init_width = init_height * aspect
else:
init_width = max(min_dimension, math.sqrt(model_area * aspect))
init_height = init_width / aspect
scaled_width, scaled_height = trim_to_multiple_of(math.floor(init_width), math.floor(init_height))
else:
scaled_width = width
scaled_height = height
device = self.model.device
channels = self.latent_channels
if channels == 9:
channels = 4 # we don't really want noise for all the mask channels
shape = (1, channels,
scaled_height // self.downsampling_factor, scaled_width // self.downsampling_factor)
if self.use_mps_noise or device.type == 'mps':
tensor = torch.empty(size=shape, device='cpu')
tensor = self.get_noise_like(like=tensor).to(device)
else:
tensor = torch.empty(size=shape, device=device)
tensor = self.get_noise_like(like=tensor)
return tensor