InvokeAI/ldm/invoke/generator/base.py
Jonathan cab41f0538
Fix perlin noise generator for diffusers tensors (#2678)
Tensors with diffusers no longer have to be multiples of 8. This broke Perlin noise generation. We now generate noise for the next largest multiple of 8 and return a cropped result. Fixes #2674.
2023-02-15 19:37:42 +01:00

381 lines
16 KiB
Python

'''
Base class for ldm.invoke.generator.*
including img2img, txt2img, and inpaint
'''
from __future__ import annotations
import os
import os.path as osp
import random
import traceback
from contextlib import nullcontext
import cv2
import numpy as np
import torch
from PIL import Image, ImageFilter, ImageChops
from diffusers import DiffusionPipeline
from einops import rearrange
from pathlib import Path
from pytorch_lightning import seed_everything
from tqdm import trange
import invokeai.assets.web as web_assets
from ldm.models.diffusion.ddpm import DiffusionWrapper
from ldm.util import rand_perlin_2d
downsampling = 8
CAUTION_IMG = 'caution.png'
class Generator:
downsampling_factor: int
latent_channels: int
precision: str
model: DiffusionWrapper | DiffusionPipeline
def __init__(self, model: DiffusionWrapper | DiffusionPipeline, precision: str):
self.model = model
self.precision = precision
self.seed = None
self.latent_channels = model.channels
self.downsampling_factor = downsampling # BUG: should come from model or config
self.safety_checker = None
self.perlin = 0.0
self.threshold = 0
self.variation_amount = 0
self.with_variations = []
self.use_mps_noise = False
self.free_gpu_mem = None
self.caution_img = None
# this is going to be overridden in img2img.py, txt2img.py and inpaint.py
def get_make_image(self,prompt,**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
"""
raise NotImplementedError("image_iterator() must be implemented in a descendent class")
def set_variation(self, seed, variation_amount, with_variations):
self.seed = seed
self.variation_amount = variation_amount
self.with_variations = with_variations
def generate(self,prompt,init_image,width,height,sampler, iterations=1,seed=None,
image_callback=None, step_callback=None, threshold=0.0, perlin=0.0,
safety_checker:dict=None,
free_gpu_mem: bool=False,
**kwargs):
scope = nullcontext
self.safety_checker = safety_checker
self.free_gpu_mem = free_gpu_mem
attention_maps_images = []
attention_maps_callback = lambda saver: attention_maps_images.append(saver.get_stacked_maps_image())
make_image = self.get_make_image(
prompt,
sampler = sampler,
init_image = init_image,
width = width,
height = height,
step_callback = step_callback,
threshold = threshold,
perlin = perlin,
attention_maps_callback = attention_maps_callback,
**kwargs
)
results = []
seed = seed if seed is not None and seed >= 0 else self.new_seed()
first_seed = seed
seed, initial_noise = self.generate_initial_noise(seed, width, height)
# There used to be an additional self.model.ema_scope() here, but it breaks
# the inpaint-1.5 model. Not sure what it did.... ?
with scope(self.model.device.type):
for n in trange(iterations, desc='Generating'):
x_T = None
if self.variation_amount > 0:
seed_everything(seed)
target_noise = self.get_noise(width,height)
x_T = self.slerp(self.variation_amount, initial_noise, target_noise)
elif initial_noise is not None:
# i.e. we specified particular variations
x_T = initial_noise
else:
seed_everything(seed)
try:
x_T = self.get_noise(width,height)
except:
print('** An error occurred while getting initial noise **')
print(traceback.format_exc())
image = make_image(x_T)
if self.safety_checker is not None:
image = self.safety_check(image)
results.append([image, seed])
if image_callback is not None:
attention_maps_image = None if len(attention_maps_images)==0 else attention_maps_images[-1]
image_callback(image, seed, first_seed=first_seed, attention_maps_image=attention_maps_image)
seed = self.new_seed()
# 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()
return results
def sample_to_image(self,samples)->Image.Image:
"""
Given samples returned from a sampler, converts
it into a PIL Image
"""
x_samples = self.model.decode_first_stage(samples)
x_samples = torch.clamp((x_samples + 1.0) / 2.0, min=0.0, max=1.0)
if len(x_samples) != 1:
raise Exception(
f'>> expected to get a single image, but got {len(x_samples)}')
x_sample = 255.0 * rearrange(
x_samples[0].cpu().numpy(), 'c h w -> h w c'
)
return Image.fromarray(x_sample.astype(np.uint8))
# write an approximate RGB image from latent samples for a single step to PNG
def repaste_and_color_correct(self, result: Image.Image, init_image: Image.Image, init_mask: Image.Image, mask_blur_radius: int = 8) -> Image.Image:
if init_image is None or init_mask is None:
return result
# Get the original alpha channel of the mask if there is one.
# Otherwise it is some other black/white image format ('1', 'L' or 'RGB')
pil_init_mask = init_mask.getchannel('A') if init_mask.mode == 'RGBA' else init_mask.convert('L')
pil_init_image = init_image.convert('RGBA') # Add an alpha channel if one doesn't exist
# Build an image with only visible pixels from source to use as reference for color-matching.
init_rgb_pixels = np.asarray(init_image.convert('RGB'), dtype=np.uint8)
init_a_pixels = np.asarray(pil_init_image.getchannel('A'), dtype=np.uint8)
init_mask_pixels = np.asarray(pil_init_mask, dtype=np.uint8)
# Get numpy version of result
np_image = np.asarray(result, dtype=np.uint8)
# Mask and calculate mean and standard deviation
mask_pixels = init_a_pixels * init_mask_pixels > 0
np_init_rgb_pixels_masked = init_rgb_pixels[mask_pixels, :]
np_image_masked = np_image[mask_pixels, :]
if np_init_rgb_pixels_masked.size > 0:
init_means = np_init_rgb_pixels_masked.mean(axis=0)
init_std = np_init_rgb_pixels_masked.std(axis=0)
gen_means = np_image_masked.mean(axis=0)
gen_std = np_image_masked.std(axis=0)
# Color correct
np_matched_result = np_image.copy()
np_matched_result[:,:,:] = (((np_matched_result[:,:,:].astype(np.float32) - gen_means[None,None,:]) / gen_std[None,None,:]) * init_std[None,None,:] + init_means[None,None,:]).clip(0, 255).astype(np.uint8)
matched_result = Image.fromarray(np_matched_result, mode='RGB')
else:
matched_result = Image.fromarray(np_image, mode='RGB')
# Blur the mask out (into init image) by specified amount
if mask_blur_radius > 0:
nm = np.asarray(pil_init_mask, dtype=np.uint8)
nmd = cv2.erode(nm, kernel=np.ones((3,3), dtype=np.uint8), iterations=int(mask_blur_radius / 2))
pmd = Image.fromarray(nmd, mode='L')
blurred_init_mask = pmd.filter(ImageFilter.BoxBlur(mask_blur_radius))
else:
blurred_init_mask = pil_init_mask
multiplied_blurred_init_mask = ImageChops.multiply(blurred_init_mask, self.pil_image.split()[-1])
# Paste original on color-corrected generation (using blurred mask)
matched_result.paste(init_image, (0,0), mask = multiplied_blurred_init_mask)
return matched_result
def sample_to_lowres_estimated_image(self,samples):
# origingally adapted from code by @erucipe and @keturn here:
# https://discuss.huggingface.co/t/decoding-latents-to-rgb-without-upscaling/23204/7
# these updated numbers for v1.5 are from @torridgristle
v1_5_latent_rgb_factors = torch.tensor([
# R G B
[ 0.3444, 0.1385, 0.0670], # L1
[ 0.1247, 0.4027, 0.1494], # L2
[-0.3192, 0.2513, 0.2103], # L3
[-0.1307, -0.1874, -0.7445] # L4
], dtype=samples.dtype, device=samples.device)
latent_image = samples[0].permute(1, 2, 0) @ v1_5_latent_rgb_factors
latents_ubyte = (((latent_image + 1) / 2)
.clamp(0, 1) # change scale from -1..1 to 0..1
.mul(0xFF) # to 0..255
.byte()).cpu()
return Image.fromarray(latents_ubyte.numpy())
def generate_initial_noise(self, seed, width, height):
initial_noise = None
if self.variation_amount > 0 or len(self.with_variations) > 0:
# use fixed initial noise plus random noise per iteration
seed_everything(seed)
initial_noise = self.get_noise(width,height)
for v_seed, v_weight in self.with_variations:
seed = v_seed
seed_everything(seed)
next_noise = self.get_noise(width,height)
initial_noise = self.slerp(v_weight, initial_noise, next_noise)
if self.variation_amount > 0:
random.seed() # reset RNG to an actually random state, so we can get a random seed for variations
seed = random.randrange(0,np.iinfo(np.uint32).max)
return (seed, initial_noise)
else:
return (seed, None)
# returns a tensor filled with random numbers from a normal distribution
def get_noise(self,width,height):
"""
Returns a tensor filled with random numbers, either form a normal distribution
(txt2img) or from the latent image (img2img, inpaint)
"""
raise NotImplementedError("get_noise() must be implemented in a descendent class")
def get_perlin_noise(self,width,height):
fixdevice = 'cpu' if (self.model.device.type == 'mps') else self.model.device
# limit noise to only the diffusion image channels, not the mask channels
input_channels = min(self.latent_channels, 4)
# round up to the nearest block of 8
temp_width = int((width + 7) / 8) * 8
temp_height = int((height + 7) / 8) * 8
noise = torch.stack([
rand_perlin_2d((temp_height, temp_width),
(8, 8),
device = self.model.device).to(fixdevice) for _ in range(input_channels)], dim=0).to(self.model.device)
return noise[0:4, 0:height, 0:width]
def new_seed(self):
self.seed = random.randrange(0, np.iinfo(np.uint32).max)
return self.seed
def slerp(self, t, v0, v1, DOT_THRESHOLD=0.9995):
'''
Spherical linear interpolation
Args:
t (float/np.ndarray): Float value between 0.0 and 1.0
v0 (np.ndarray): Starting vector
v1 (np.ndarray): Final vector
DOT_THRESHOLD (float): Threshold for considering the two vectors as
colineal. Not recommended to alter this.
Returns:
v2 (np.ndarray): Interpolation vector between v0 and v1
'''
inputs_are_torch = False
if not isinstance(v0, np.ndarray):
inputs_are_torch = True
v0 = v0.detach().cpu().numpy()
if not isinstance(v1, np.ndarray):
inputs_are_torch = True
v1 = v1.detach().cpu().numpy()
dot = np.sum(v0 * v1 / (np.linalg.norm(v0) * np.linalg.norm(v1)))
if np.abs(dot) > DOT_THRESHOLD:
v2 = (1 - t) * v0 + t * v1
else:
theta_0 = np.arccos(dot)
sin_theta_0 = np.sin(theta_0)
theta_t = theta_0 * t
sin_theta_t = np.sin(theta_t)
s0 = np.sin(theta_0 - theta_t) / sin_theta_0
s1 = sin_theta_t / sin_theta_0
v2 = s0 * v0 + s1 * v1
if inputs_are_torch:
v2 = torch.from_numpy(v2).to(self.model.device)
return v2
def safety_check(self,image:Image.Image):
'''
If the CompViz safety checker flags an NSFW image, we
blur it out.
'''
import diffusers
checker = self.safety_checker['checker']
extractor = self.safety_checker['extractor']
features = extractor([image], return_tensors="pt")
features.to(self.model.device)
# unfortunately checker requires the numpy version, so we have to convert back
x_image = np.array(image).astype(np.float32) / 255.0
x_image = x_image[None].transpose(0, 3, 1, 2)
diffusers.logging.set_verbosity_error()
checked_image, has_nsfw_concept = checker(images=x_image, clip_input=features.pixel_values)
if has_nsfw_concept[0]:
print('** An image with potential non-safe content has been detected. A blurred image will be returned. **')
return self.blur(image)
else:
return image
def blur(self,input):
blurry = input.filter(filter=ImageFilter.GaussianBlur(radius=32))
try:
caution = self.get_caution_img()
if caution:
blurry.paste(caution,(0,0),caution)
except FileNotFoundError:
pass
return blurry
def get_caution_img(self):
path = None
if self.caution_img:
return self.caution_img
path = Path(web_assets.__path__[0]) / CAUTION_IMG
print(f'DEBUG: path to caution = {path}')
caution = Image.open(path)
self.caution_img = caution.resize((caution.width // 2, caution.height //2))
return self.caution_img
# this is a handy routine for debugging use. Given a generated sample,
# convert it into a PNG image and store it at the indicated path
def save_sample(self, sample, filepath):
image = self.sample_to_image(sample)
dirname = os.path.dirname(filepath) or '.'
if not os.path.exists(dirname):
print(f'** creating directory {dirname}')
os.makedirs(dirname, exist_ok=True)
image.save(filepath,'PNG')
def torch_dtype(self)->torch.dtype:
return torch.float16 if self.precision == 'float16' else torch.float32
# returns a tensor filled with random numbers from a normal distribution
def get_noise(self,width,height):
device = self.model.device
# limit noise to only the diffusion image channels, not the mask channels
input_channels = min(self.latent_channels, 4)
if self.use_mps_noise or device.type == 'mps':
x = torch.randn([1,
input_channels,
height // self.downsampling_factor,
width // self.downsampling_factor],
dtype=self.torch_dtype(),
device='cpu').to(device)
else:
x = torch.randn([1,
input_channels,
height // self.downsampling_factor,
width // self.downsampling_factor],
dtype=self.torch_dtype(),
device=device)
if self.perlin > 0.0:
perlin_noise = self.get_perlin_noise(width // self.downsampling_factor, height // self.downsampling_factor)
x = (1-self.perlin)*x + self.perlin*perlin_noise
return x