latentblending/latent_blending.py

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# Copyright 2022 Lunar Ring. All rights reserved.
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# Written by Johannes Stelzer, email stelzer@lunar-ring.ai twitter @j_stelzer
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#
# 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.
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import os
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import torch
import numpy as np
import warnings
import time
from tqdm.auto import tqdm
from PIL import Image
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from movie_util import MovieSaver
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from typing import List, Optional
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import lpips
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from utils import interpolate_spherical, interpolate_linear, add_frames_linear_interp, yml_load, yml_save
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warnings.filterwarnings('ignore')
torch.backends.cudnn.benchmark = False
torch.set_grad_enabled(False)
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class LatentBlending():
def __init__(
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self,
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dh: None,
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guidance_scale: float = 4,
guidance_scale_mid_damper: float = 0.5,
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mid_compression_scaler: float = 1.2):
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r"""
Initializes the latent blending class.
Args:
guidance_scale: float
Guidance scale as defined in [Classifier-Free Diffusion Guidance](https://arxiv.org/abs/2207.12598).
`guidance_scale` is defined as `w` of equation 2. of [Imagen
Paper](https://arxiv.org/pdf/2205.11487.pdf). Guidance scale is enabled by setting `guidance_scale >
1`. Higher guidance scale encourages to generate images that are closely linked to the text `prompt`,
usually at the expense of lower image quality.
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guidance_scale_mid_damper: float = 0.5
Reduces the guidance scale towards the middle of the transition.
A value of 0.5 would decrease the guidance_scale towards the middle linearly by 0.5.
mid_compression_scaler: float = 2.0
Increases the sampling density in the middle (where most changes happen). Higher value
imply more values in the middle. However the inflection point can occur outside the middle,
thus high values can give rough transitions. Values around 2 should be fine.
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"""
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assert guidance_scale_mid_damper > 0 \
and guidance_scale_mid_damper <= 1.0, \
f"guidance_scale_mid_damper neees to be in interval (0,1], you provided {guidance_scale_mid_damper}"
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self.dh = dh
self.device = self.dh.device
self.set_dimensions()
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self.guidance_scale_mid_damper = guidance_scale_mid_damper
self.mid_compression_scaler = mid_compression_scaler
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self.seed1 = 0
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self.seed2 = 0
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# Initialize vars
self.prompt1 = ""
self.prompt2 = ""
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self.tree_latents = [None, None]
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self.tree_fracts = None
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self.idx_injection = []
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self.tree_status = None
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self.tree_final_imgs = []
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self.list_nmb_branches_prev = []
self.list_injection_idx_prev = []
self.text_embedding1 = None
self.text_embedding2 = None
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self.image1_lowres = None
self.image2_lowres = None
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self.negative_prompt = None
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self.num_inference_steps = self.dh.num_inference_steps
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self.noise_level_upscaling = 20
self.list_injection_idx = None
self.list_nmb_branches = None
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# Mixing parameters
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self.branch1_crossfeed_power = 0.3
self.branch1_crossfeed_range = 0.3
self.branch1_crossfeed_decay = 0.99
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self.parental_crossfeed_power = 0.3
self.parental_crossfeed_range = 0.6
self.parental_crossfeed_power_decay = 0.9
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self.set_guidance_scale(guidance_scale)
self.multi_transition_img_first = None
self.multi_transition_img_last = None
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self.dt_per_diff = 0
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self.spatial_mask = None
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self.lpips = lpips.LPIPS(net='alex').cuda(self.device)
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self.set_prompt1("")
self.set_prompt2("")
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def set_dimensions(self, size_output=None):
r"""
sets the size of the output video.
Args:
size_output: tuple
width x height
Note: the size will get automatically adjusted to be divisable by 32.
"""
self.dh.set_dimensions(size_output)
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def set_guidance_scale(self, guidance_scale):
r"""
sets the guidance scale.
"""
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self.guidance_scale_base = guidance_scale
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self.guidance_scale = guidance_scale
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self.dh.guidance_scale = guidance_scale
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def set_negative_prompt(self, negative_prompt):
r"""Set the negative prompt. Currenty only one negative prompt is supported
"""
self.negative_prompt = negative_prompt
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self.dh.set_negative_prompt(negative_prompt)
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def set_guidance_mid_dampening(self, fract_mixing):
r"""
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Tunes the guidance scale down as a linear function of fract_mixing,
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towards 0.5 the minimum will be reached.
"""
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mid_factor = 1 - np.abs(fract_mixing - 0.5) / 0.5
max_guidance_reduction = self.guidance_scale_base * (1 - self.guidance_scale_mid_damper) - 1
guidance_scale_effective = self.guidance_scale_base - max_guidance_reduction * mid_factor
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self.guidance_scale = guidance_scale_effective
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self.dh.guidance_scale = guidance_scale_effective
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def set_branch1_crossfeed(self, crossfeed_power, crossfeed_range, crossfeed_decay):
r"""
Sets the crossfeed parameters for the first branch to the last branch.
Args:
crossfeed_power: float [0,1]
Controls the level of cross-feeding between the first and last image branch.
crossfeed_range: float [0,1]
Sets the duration of active crossfeed during development.
crossfeed_decay: float [0,1]
Sets decay for branch1_crossfeed_power. Lower values make the decay stronger across the range.
"""
self.branch1_crossfeed_power = np.clip(crossfeed_power, 0, 1)
self.branch1_crossfeed_range = np.clip(crossfeed_range, 0, 1)
self.branch1_crossfeed_decay = np.clip(crossfeed_decay, 0, 1)
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def set_parental_crossfeed(self, crossfeed_power, crossfeed_range, crossfeed_decay):
r"""
Sets the crossfeed parameters for all transition images (within the first and last branch).
Args:
crossfeed_power: float [0,1]
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Controls the level of cross-feeding from the parental branches
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crossfeed_range: float [0,1]
Sets the duration of active crossfeed during development.
crossfeed_decay: float [0,1]
Sets decay for branch1_crossfeed_power. Lower values make the decay stronger across the range.
"""
self.parental_crossfeed_power = np.clip(crossfeed_power, 0, 1)
self.parental_crossfeed_range = np.clip(crossfeed_range, 0, 1)
self.parental_crossfeed_power_decay = np.clip(crossfeed_decay, 0, 1)
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def set_prompt1(self, prompt: str):
r"""
Sets the first prompt (for the first keyframe) including text embeddings.
Args:
prompt: str
ABC trending on artstation painted by Greg Rutkowski
"""
prompt = prompt.replace("_", " ")
self.prompt1 = prompt
self.text_embedding1 = self.get_text_embeddings(self.prompt1)
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def set_prompt2(self, prompt: str):
r"""
Sets the second prompt (for the second keyframe) including text embeddings.
Args:
prompt: str
XYZ trending on artstation painted by Greg Rutkowski
"""
prompt = prompt.replace("_", " ")
self.prompt2 = prompt
self.text_embedding2 = self.get_text_embeddings(self.prompt2)
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def set_image1(self, image: Image):
r"""
Sets the first image (keyframe), relevant for the upscaling model transitions.
Args:
image: Image
"""
self.image1_lowres = image
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def set_image2(self, image: Image):
r"""
Sets the second image (keyframe), relevant for the upscaling model transitions.
Args:
image: Image
"""
self.image2_lowres = image
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def run_transition(
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self,
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recycle_img1: Optional[bool] = False,
recycle_img2: Optional[bool] = False,
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num_inference_steps: Optional[int] = 30,
depth_strength: Optional[float] = 0.3,
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t_compute_max_allowed: Optional[float] = None,
nmb_max_branches: Optional[int] = None,
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fixed_seeds: Optional[List[int]] = None):
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r"""
Function for computing transitions.
Returns a list of transition images using spherical latent blending.
Args:
recycle_img1: Optional[bool]:
Don't recompute the latents for the first keyframe (purely prompt1). Saves compute.
recycle_img2: Optional[bool]:
Don't recompute the latents for the second keyframe (purely prompt2). Saves compute.
num_inference_steps:
Number of diffusion steps. Higher values will take more compute time.
depth_strength:
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Determines how deep the first injection will happen.
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Deeper injections will cause (unwanted) formation of new structures,
more shallow values will go into alpha-blendy land.
t_compute_max_allowed:
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Either provide t_compute_max_allowed or nmb_max_branches.
The maximum time allowed for computation. Higher values give better results but take longer.
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nmb_max_branches: int
Either provide t_compute_max_allowed or nmb_max_branches. The maximum number of branches to be computed. Higher values give better
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results. Use this if you want to have controllable results independent
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of your computer.
fixed_seeds: Optional[List[int)]:
You can supply two seeds that are used for the first and second keyframe (prompt1 and prompt2).
Otherwise random seeds will be taken.
"""
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# Sanity checks first
assert self.text_embedding1 is not None, 'Set the first text embedding with .set_prompt1(...) before'
assert self.text_embedding2 is not None, 'Set the second text embedding with .set_prompt2(...) before'
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# Random seeds
if fixed_seeds is not None:
if fixed_seeds == 'randomize':
fixed_seeds = list(np.random.randint(0, 1000000, 2).astype(np.int32))
else:
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assert len(fixed_seeds) == 2, "Supply a list with len = 2"
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self.seed1 = fixed_seeds[0]
self.seed2 = fixed_seeds[1]
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# Ensure correct num_inference_steps in holder
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self.num_inference_steps = num_inference_steps
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self.dh.set_num_inference_steps(num_inference_steps)
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# Compute / Recycle first image
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if not recycle_img1 or len(self.tree_latents[0]) != self.num_inference_steps:
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list_latents1 = self.compute_latents1()
else:
list_latents1 = self.tree_latents[0]
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# Compute / Recycle first image
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if not recycle_img2 or len(self.tree_latents[-1]) != self.num_inference_steps:
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list_latents2 = self.compute_latents2()
else:
list_latents2 = self.tree_latents[-1]
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# Reset the tree, injecting the edge latents1/2 we just generated/recycled
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self.tree_latents = [list_latents1, list_latents2]
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self.tree_fracts = [0.0, 1.0]
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self.tree_final_imgs = [self.dh.latent2image((self.tree_latents[0][-1])), self.dh.latent2image((self.tree_latents[-1][-1]))]
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self.tree_idx_injection = [0, 0]
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# Hard-fix. Apply spatial mask only for list_latents2 but not for transition. WIP...
self.spatial_mask = None
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# Set up branching scheme (dependent on provided compute time)
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list_idx_injection, list_nmb_stems = self.get_time_based_branching(depth_strength, t_compute_max_allowed, nmb_max_branches)
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# Run iteratively, starting with the longest trajectory.
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# Always inserting new branches where they are needed most according to image similarity
for s_idx in tqdm(range(len(list_idx_injection))):
nmb_stems = list_nmb_stems[s_idx]
idx_injection = list_idx_injection[s_idx]
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for i in range(nmb_stems):
fract_mixing, b_parent1, b_parent2 = self.get_mixing_parameters(idx_injection)
self.set_guidance_mid_dampening(fract_mixing)
list_latents = self.compute_latents_mix(fract_mixing, b_parent1, b_parent2, idx_injection)
self.insert_into_tree(fract_mixing, idx_injection, list_latents)
# print(f"fract_mixing: {fract_mixing} idx_injection {idx_injection}")
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return self.tree_final_imgs
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def compute_latents1(self, return_image=False):
r"""
Runs a diffusion trajectory for the first image
Args:
return_image: bool
whether to return an image or the list of latents
"""
print("starting compute_latents1")
list_conditionings = self.get_mixed_conditioning(0)
t0 = time.time()
latents_start = self.get_noise(self.seed1)
list_latents1 = self.run_diffusion(
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list_conditionings,
latents_start=latents_start,
idx_start=0)
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t1 = time.time()
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self.dt_per_diff = (t1 - t0) / self.num_inference_steps
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self.tree_latents[0] = list_latents1
if return_image:
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return self.dh.latent2image(list_latents1[-1])
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else:
return list_latents1
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def compute_latents2(self, return_image=False):
r"""
Runs a diffusion trajectory for the last image, which may be affected by the first image's trajectory.
Args:
return_image: bool
whether to return an image or the list of latents
"""
print("starting compute_latents2")
list_conditionings = self.get_mixed_conditioning(1)
latents_start = self.get_noise(self.seed2)
# Influence from branch1
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if self.branch1_crossfeed_power > 0.0:
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# Set up the mixing_coeffs
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idx_mixing_stop = int(round(self.num_inference_steps * self.branch1_crossfeed_range))
mixing_coeffs = list(np.linspace(self.branch1_crossfeed_power, self.branch1_crossfeed_power * self.branch1_crossfeed_decay, idx_mixing_stop))
mixing_coeffs.extend((self.num_inference_steps - idx_mixing_stop) * [0])
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list_latents_mixing = self.tree_latents[0]
list_latents2 = self.run_diffusion(
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list_conditionings,
latents_start=latents_start,
idx_start=0,
list_latents_mixing=list_latents_mixing,
mixing_coeffs=mixing_coeffs)
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else:
list_latents2 = self.run_diffusion(list_conditionings, latents_start)
self.tree_latents[-1] = list_latents2
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if return_image:
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return self.dh.latent2image(list_latents2[-1])
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else:
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return list_latents2
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def compute_latents_mix(self, fract_mixing, b_parent1, b_parent2, idx_injection):
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r"""
Runs a diffusion trajectory, using the latents from the respective parents
Args:
fract_mixing: float
the fraction along the transition axis [0, 1]
b_parent1: int
index of parent1 to be used
b_parent2: int
index of parent2 to be used
idx_injection: int
the index in terms of diffusion steps, where the next insertion will start.
"""
list_conditionings = self.get_mixed_conditioning(fract_mixing)
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fract_mixing_parental = (fract_mixing - self.tree_fracts[b_parent1]) / (self.tree_fracts[b_parent2] - self.tree_fracts[b_parent1])
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# idx_reversed = self.num_inference_steps - idx_injection
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list_latents_parental_mix = []
for i in range(self.num_inference_steps):
latents_p1 = self.tree_latents[b_parent1][i]
latents_p2 = self.tree_latents[b_parent2][i]
if latents_p1 is None or latents_p2 is None:
latents_parental = None
else:
latents_parental = interpolate_spherical(latents_p1, latents_p2, fract_mixing_parental)
list_latents_parental_mix.append(latents_parental)
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idx_mixing_stop = int(round(self.num_inference_steps * self.parental_crossfeed_range))
mixing_coeffs = idx_injection * [self.parental_crossfeed_power]
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nmb_mixing = idx_mixing_stop - idx_injection
if nmb_mixing > 0:
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mixing_coeffs.extend(list(np.linspace(self.parental_crossfeed_power, self.parental_crossfeed_power * self.parental_crossfeed_power_decay, nmb_mixing)))
mixing_coeffs.extend((self.num_inference_steps - len(mixing_coeffs)) * [0])
latents_start = list_latents_parental_mix[idx_injection - 1]
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list_latents = self.run_diffusion(
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list_conditionings,
latents_start=latents_start,
idx_start=idx_injection,
list_latents_mixing=list_latents_parental_mix,
mixing_coeffs=mixing_coeffs)
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return list_latents
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def get_time_based_branching(self, depth_strength, t_compute_max_allowed=None, nmb_max_branches=None):
r"""
Sets up the branching scheme dependent on the time that is granted for compute.
The scheme uses an estimation derived from the first image's computation speed.
Either provide t_compute_max_allowed or nmb_max_branches
Args:
depth_strength:
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Determines how deep the first injection will happen.
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Deeper injections will cause (unwanted) formation of new structures,
more shallow values will go into alpha-blendy land.
t_compute_max_allowed: float
The maximum time allowed for computation. Higher values give better results
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but take longer. Use this if you want to fix your waiting time for the results.
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nmb_max_branches: int
The maximum number of branches to be computed. Higher values give better
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results. Use this if you want to have controllable results independent
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of your computer.
"""
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idx_injection_base = int(round(self.num_inference_steps * depth_strength))
list_idx_injection = np.arange(idx_injection_base, self.num_inference_steps - 1, 3)
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list_nmb_stems = np.ones(len(list_idx_injection), dtype=np.int32)
t_compute = 0
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if nmb_max_branches is None:
assert t_compute_max_allowed is not None, "Either specify t_compute_max_allowed or nmb_max_branches"
stop_criterion = "t_compute_max_allowed"
elif t_compute_max_allowed is None:
assert nmb_max_branches is not None, "Either specify t_compute_max_allowed or nmb_max_branches"
stop_criterion = "nmb_max_branches"
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nmb_max_branches -= 2 # Discounting the outer frames
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else:
raise ValueError("Either specify t_compute_max_allowed or nmb_max_branches")
stop_criterion_reached = False
is_first_iteration = True
while not stop_criterion_reached:
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list_compute_steps = self.num_inference_steps - list_idx_injection
list_compute_steps *= list_nmb_stems
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t_compute = np.sum(list_compute_steps) * self.dt_per_diff + 0.15 * np.sum(list_nmb_stems)
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t_compute += 2 * self.num_inference_steps * self.dt_per_diff # outer branches
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increase_done = False
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for s_idx in range(len(list_nmb_stems) - 1):
if list_nmb_stems[s_idx + 1] / list_nmb_stems[s_idx] >= 2:
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list_nmb_stems[s_idx] += 1
increase_done = True
break
if not increase_done:
list_nmb_stems[-1] += 1
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if stop_criterion == "t_compute_max_allowed" and t_compute > t_compute_max_allowed:
stop_criterion_reached = True
elif stop_criterion == "nmb_max_branches" and np.sum(list_nmb_stems) >= nmb_max_branches:
stop_criterion_reached = True
if is_first_iteration:
# Need to undersample.
list_idx_injection = np.linspace(list_idx_injection[0], list_idx_injection[-1], nmb_max_branches).astype(np.int32)
list_nmb_stems = np.ones(len(list_idx_injection), dtype=np.int32)
else:
is_first_iteration = False
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# print(f"t_compute {t_compute} list_nmb_stems {list_nmb_stems}")
return list_idx_injection, list_nmb_stems
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def get_mixing_parameters(self, idx_injection):
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r"""
Computes which parental latents should be mixed together to achieve a smooth blend.
As metric, we are using lpips image similarity. The insertion takes place
where the metric is maximal.
Args:
idx_injection: int
the index in terms of diffusion steps, where the next insertion will start.
"""
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# get_lpips_similarity
similarities = []
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for i in range(len(self.tree_final_imgs) - 1):
similarities.append(self.get_lpips_similarity(self.tree_final_imgs[i], self.tree_final_imgs[i + 1]))
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b_closest1 = np.argmax(similarities)
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b_closest2 = b_closest1 + 1
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fract_closest1 = self.tree_fracts[b_closest1]
fract_closest2 = self.tree_fracts[b_closest2]
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# Ensure that the parents are indeed older!
b_parent1 = b_closest1
while True:
if self.tree_idx_injection[b_parent1] < idx_injection:
break
else:
b_parent1 -= 1
b_parent2 = b_closest2
while True:
if self.tree_idx_injection[b_parent2] < idx_injection:
break
else:
b_parent2 += 1
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fract_mixing = (fract_closest1 + fract_closest2) / 2
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return fract_mixing, b_parent1, b_parent2
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def insert_into_tree(self, fract_mixing, idx_injection, list_latents):
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r"""
Inserts all necessary parameters into the trajectory tree.
Args:
fract_mixing: float
the fraction along the transition axis [0, 1]
idx_injection: int
the index in terms of diffusion steps, where the next insertion will start.
list_latents: list
list of the latents to be inserted
"""
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b_parent1, b_parent2 = self.get_closest_idx(fract_mixing)
self.tree_latents.insert(b_parent1 + 1, list_latents)
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self.tree_final_imgs.insert(b_parent1 + 1, self.dh.latent2image(list_latents[-1]))
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self.tree_fracts.insert(b_parent1 + 1, fract_mixing)
self.tree_idx_injection.insert(b_parent1 + 1, idx_injection)
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def get_noise(self, seed):
r"""
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Helper function to get noise given seed.
Args:
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seed: int
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"""
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return self.dh.get_noise(seed)
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@torch.no_grad()
def run_diffusion(
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self,
list_conditionings,
latents_start: torch.FloatTensor = None,
idx_start: int = 0,
list_latents_mixing=None,
mixing_coeffs=0.0,
return_image: Optional[bool] = False):
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r"""
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Wrapper function for diffusion runners.
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Depending on the mode, the correct one will be executed.
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Args:
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list_conditionings: list
List of all conditionings for the diffusion model.
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latents_start: torch.FloatTensor
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Latents that are used for injection
idx_start: int
Index of the diffusion process start and where the latents_for_injection are injected
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list_latents_mixing: torch.FloatTensor
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List of latents (latent trajectories) that are used for mixing
mixing_coeffs: float or list
Coefficients, how strong each element of list_latents_mixing will be mixed in.
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return_image: Optional[bool]
Optionally return image directly
"""
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# Ensure correct num_inference_steps in Holder
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self.dh.set_num_inference_steps(self.num_inference_steps)
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assert type(list_conditionings) is list, "list_conditionings need to be a list"
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if self.dh.use_sd_xl:
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text_embeddings = list_conditionings[0]
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return self.dh.run_diffusion_sd_xl(
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text_embeddings=text_embeddings,
latents_start=latents_start,
idx_start=idx_start,
list_latents_mixing=list_latents_mixing,
mixing_coeffs=mixing_coeffs,
return_image=return_image)
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else:
text_embeddings = list_conditionings[0]
return self.dh.run_diffusion_standard(
text_embeddings=text_embeddings,
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latents_start=latents_start,
idx_start=idx_start,
list_latents_mixing=list_latents_mixing,
mixing_coeffs=mixing_coeffs,
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return_image=return_image)
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def run_upscaling(
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self,
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dp_img: str,
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depth_strength: float = 0.65,
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num_inference_steps: int = 100,
nmb_max_branches_highres: int = 5,
nmb_max_branches_lowres: int = 6,
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duration_single_segment=3,
fps=24,
fixed_seeds: Optional[List[int]] = None):
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r"""
Runs upscaling with the x4 model. Requires that you run a transition before with a low-res model and save the results using write_imgs_transition.
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Args:
dp_img: str
Path to the low-res transition path (as saved in write_imgs_transition)
depth_strength:
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Determines how deep the first injection will happen.
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Deeper injections will cause (unwanted) formation of new structures,
more shallow values will go into alpha-blendy land.
num_inference_steps:
Number of diffusion steps. Higher values will take more compute time.
nmb_max_branches_highres: int
Number of final branches of the upscaling transition pass. Note this is the number
of branches between each pair of low-res images.
nmb_max_branches_lowres: int
Number of input low-res images, subsampling all transition images written in the low-res pass.
Setting this number lower (e.g. 6) will decrease the compute time but not affect the results too much.
duration_single_segment: float
The duration of each high-res movie segment. You will have nmb_max_branches_lowres-1 segments in total.
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fps: float
frames per second of movie
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fixed_seeds: Optional[List[int)]:
You can supply two seeds that are used for the first and second keyframe (prompt1 and prompt2).
Otherwise random seeds will be taken.
"""
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fp_yml = os.path.join(dp_img, "lowres.yaml")
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fp_movie = os.path.join(dp_img, "movie_highres.mp4")
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ms = MovieSaver(fp_movie, fps=fps)
assert os.path.isfile(fp_yml), "lowres.yaml does not exist. did you forget run_upscaling_step1?"
dict_stuff = yml_load(fp_yml)
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# load lowres images
nmb_images_lowres = dict_stuff['nmb_images']
prompt1 = dict_stuff['prompt1']
prompt2 = dict_stuff['prompt2']
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idx_img_lowres = np.round(np.linspace(0, nmb_images_lowres - 1, nmb_max_branches_lowres)).astype(np.int32)
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imgs_lowres = []
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for i in idx_img_lowres:
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fp_img_lowres = os.path.join(dp_img, f"lowres_img_{str(i).zfill(4)}.jpg")
assert os.path.isfile(fp_img_lowres), f"{fp_img_lowres} does not exist. did you forget run_upscaling_step1?"
imgs_lowres.append(Image.open(fp_img_lowres))
# set up upscaling
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text_embeddingA = self.dh.get_text_embedding(prompt1)
text_embeddingB = self.dh.get_text_embedding(prompt2)
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list_fract_mixing = np.linspace(0, 1, nmb_max_branches_lowres - 1)
for i in range(nmb_max_branches_lowres - 1):
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print(f"Starting movie segment {i+1}/{nmb_max_branches_lowres-1}")
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self.text_embedding1 = interpolate_linear(text_embeddingA, text_embeddingB, list_fract_mixing[i])
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self.text_embedding2 = interpolate_linear(text_embeddingA, text_embeddingB, 1 - list_fract_mixing[i])
if i == 0:
recycle_img1 = False
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else:
self.swap_forward()
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recycle_img1 = True
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self.set_image1(imgs_lowres[i])
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self.set_image2(imgs_lowres[i + 1])
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list_imgs = self.run_transition(
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recycle_img1=recycle_img1,
recycle_img2=False,
num_inference_steps=num_inference_steps,
depth_strength=depth_strength,
nmb_max_branches=nmb_max_branches_highres)
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list_imgs_interp = add_frames_linear_interp(list_imgs, fps, duration_single_segment)
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# Save movie frame
for img in list_imgs_interp:
ms.write_frame(img)
ms.finalize()
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@torch.no_grad()
def get_mixed_conditioning(self, fract_mixing):
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if self.dh.use_sd_xl:
text_embeddings_mix = []
for i in range(len(self.text_embedding1)):
text_embeddings_mix.append(interpolate_linear(self.text_embedding1[i], self.text_embedding2[i], fract_mixing))
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list_conditionings = [text_embeddings_mix]
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else:
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text_embeddings_mix = interpolate_linear(self.text_embedding1, self.text_embedding2, fract_mixing)
list_conditionings = [text_embeddings_mix]
return list_conditionings
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@torch.no_grad()
def get_text_embeddings(
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self,
prompt: str):
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r"""
Computes the text embeddings provided a string with a prompts.
Adapted from stable diffusion repo
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Args:
prompt: str
ABC trending on artstation painted by Old Greg.
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"""
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return self.dh.get_text_embedding(prompt)
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def write_imgs_transition(self, dp_img):
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r"""
Writes the transition images into the folder dp_img.
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Requires run_transition to be completed.
Args:
dp_img: str
Directory, into which the transition images, yaml file and latents are written.
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"""
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imgs_transition = self.tree_final_imgs
os.makedirs(dp_img, exist_ok=True)
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for i, img in enumerate(imgs_transition):
img_leaf = Image.fromarray(img)
img_leaf.save(os.path.join(dp_img, f"lowres_img_{str(i).zfill(4)}.jpg"))
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fp_yml = os.path.join(dp_img, "lowres.yaml")
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self.save_statedict(fp_yml)
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def write_movie_transition(self, fp_movie, duration_transition, fps=30):
r"""
Writes the transition movie to fp_movie, using the given duration and fps..
The missing frames are linearly interpolated.
Args:
fp_movie: str
file pointer to the final movie.
duration_transition: float
duration of the movie in seonds
fps: int
fps of the movie
"""
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# Let's get more cheap frames via linear interpolation (duration_transition*fps frames)
imgs_transition_ext = add_frames_linear_interp(self.tree_final_imgs, duration_transition, fps)
# Save as MP4
if os.path.isfile(fp_movie):
os.remove(fp_movie)
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ms = MovieSaver(fp_movie, fps=fps, shape_hw=[self.dh.height_img, self.dh.width_img])
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for img in tqdm(imgs_transition_ext):
ms.write_frame(img)
ms.finalize()
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def save_statedict(self, fp_yml):
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# Dump everything relevant into yaml
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imgs_transition = self.tree_final_imgs
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state_dict = self.get_state_dict()
state_dict['nmb_images'] = len(imgs_transition)
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yml_save(fp_yml, state_dict)
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def get_state_dict(self):
state_dict = {}
grab_vars = ['prompt1', 'prompt2', 'seed1', 'seed2', 'height', 'width',
'num_inference_steps', 'depth_strength', 'guidance_scale',
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'guidance_scale_mid_damper', 'mid_compression_scaler', 'negative_prompt',
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'branch1_crossfeed_power', 'branch1_crossfeed_range', 'branch1_crossfeed_decay'
'parental_crossfeed_power', 'parental_crossfeed_range', 'parental_crossfeed_power_decay']
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for v in grab_vars:
if hasattr(self, v):
if v == 'seed1' or v == 'seed2':
state_dict[v] = int(getattr(self, v))
elif v == 'guidance_scale':
state_dict[v] = float(getattr(self, v))
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else:
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try:
state_dict[v] = getattr(self, v)
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except Exception:
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pass
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return state_dict
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def randomize_seed(self):
r"""
Set a random seed for a fresh start.
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"""
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seed = np.random.randint(999999999)
self.set_seed(seed)
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def set_seed(self, seed: int):
r"""
Set a the seed for a fresh start.
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"""
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self.seed = seed
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self.dh.seed = seed
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def set_width(self, width):
r"""
Set the width of the resulting image.
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"""
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assert np.mod(width, 64) == 0, "set_width: value needs to be divisible by 64"
self.width = width
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self.dh.width = width
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def set_height(self, height):
r"""
Set the height of the resulting image.
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"""
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assert np.mod(height, 64) == 0, "set_height: value needs to be divisible by 64"
self.height = height
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self.dh.height = height
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def swap_forward(self):
r"""
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Moves over keyframe two -> keyframe one. Useful for making a sequence of transitions
as in run_multi_transition()
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"""
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# Move over all latents
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self.tree_latents[0] = self.tree_latents[-1]
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# Move over prompts and text embeddings
self.prompt1 = self.prompt2
self.text_embedding1 = self.text_embedding2
# Final cleanup for extra sanity
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self.tree_final_imgs = []
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def get_lpips_similarity(self, imgA, imgB):
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r"""
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Computes the image similarity between two images imgA and imgB.
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Used to determine the optimal point of insertion to create smooth transitions.
High values indicate low similarity.
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"""
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tensorA = torch.from_numpy(np.asarray(imgA)).float().cuda(self.device)
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tensorA = 2 * tensorA / 255.0 - 1
tensorA = tensorA.permute([2, 0, 1]).unsqueeze(0)
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tensorB = torch.from_numpy(np.asarray(imgB)).float().cuda(self.device)
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tensorB = 2 * tensorB / 255.0 - 1
tensorB = tensorB.permute([2, 0, 1]).unsqueeze(0)
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lploss = self.lpips(tensorA, tensorB)
lploss = float(lploss[0][0][0][0])
return lploss
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# Auxiliary functions
def get_closest_idx(
self,
fract_mixing: float):
r"""
Helper function to retrieve the parents for any given mixing.
Example: fract_mixing = 0.4 and self.tree_fracts = [0, 0.3, 0.6, 1.0]
Will return the two closest values here, i.e. [1, 2]
"""
pdist = fract_mixing - np.asarray(self.tree_fracts)
pdist_pos = pdist.copy()
pdist_pos[pdist_pos < 0] = np.inf
b_parent1 = np.argmin(pdist_pos)
pdist_neg = -pdist.copy()
pdist_neg[pdist_neg <= 0] = np.inf
b_parent2 = np.argmin(pdist_neg)
if b_parent1 > b_parent2:
tmp = b_parent2
b_parent2 = b_parent1
b_parent1 = tmp
return b_parent1, b_parent2
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if __name__ == "__main__":
# %% First let us spawn a stable diffusion holder. Uncomment your version of choice.
from diffusers_holder import DiffusersHolder
from diffusers import DiffusionPipeline
from diffusers import AutoencoderTiny
pipe = DiffusionPipeline.from_pretrained("stabilityai/sdxl-turbo", torch_dtype=torch.float16, variant="fp16")
pipe.to("cuda")
# pipe.vae = AutoencoderTiny.from_pretrained('madebyollin/taesdxl', torch_device='cuda', torch_dtype=torch.float16)
# pipe.vae = pipe.vae.cuda()
dh = DiffusersHolder(pipe)
# %% Next let's set up all parameters
depth_strength = 0.5 # Specifies how deep (in terms of diffusion iterations the first branching happens)
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t_compute_max_allowed = 5 # Determines the quality of the transition in terms of compute time you grant it
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num_inference_steps = 4
size_output = (512, 512)
prompt1 = "underwater landscape, fish, und the sea, incredible detail, high resolution"
prompt2 = "rendering of an alien planet, strange plants, strange creatures, surreal"
negative_prompt = "blurry, ugly, pale" # Optional
fp_movie = 'movie_example1.mp4'
duration_transition = 12 # In seconds
# Spawn latent blending
lb = LatentBlending(dh)
lb.set_prompt1(prompt1)
lb.set_prompt2(prompt2)
lb.set_dimensions(size_output)
lb.set_negative_prompt(negative_prompt)
lb.set_guidance_scale(0)
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lb.branch1_crossfeed_power = 0.0
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lb.branch1_crossfeed_range = 0.6
lb.branch1_crossfeed_decay = 0.99
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lb.parental_crossfeed_power = 1.0
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lb.parental_crossfeed_power_decay = 1.0
lb.parental_crossfeed_range = 1.0
# Run latent blending
lb.run_transition(
depth_strength=depth_strength,
num_inference_steps=num_inference_steps,
t_compute_max_allowed=t_compute_max_allowed)
# Save movie
lb.write_movie_transition(fp_movie, duration_transition)
#%%
"""
checkout sizes
checkout good tree for num inference steps
checkout that good nmb inference step given
"""