2023-08-17 22:45:25 +00:00
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from typing import Union
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2023-08-18 14:57:18 +00:00
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2023-07-20 01:52:30 +00:00
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import cv2
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2023-08-18 14:57:18 +00:00
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import numpy as np
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import torch
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from controlnet_aux.util import HWC3
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2023-07-20 01:52:30 +00:00
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from diffusers.utils import PIL_INTERPOLATION
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from einops import rearrange
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2023-08-18 14:57:18 +00:00
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from PIL import Image
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2023-07-20 01:52:30 +00:00
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###################################################################
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# Copy of scripts/lvminthin.py from Mikubill/sd-webui-controlnet
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###################################################################
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# High Quality Edge Thinning using Pure Python
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# Written by Lvmin Zhangu
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# 2023 April
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# Stanford University
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# If you use this, please Cite "High Quality Edge Thinning using Pure Python", Lvmin Zhang, In Mikubill/sd-webui-controlnet.
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lvmin_kernels_raw = [
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np.array([[-1, -1, -1], [0, 1, 0], [1, 1, 1]], dtype=np.int32),
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np.array([[0, -1, -1], [1, 1, -1], [0, 1, 0]], dtype=np.int32),
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]
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lvmin_kernels = []
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lvmin_kernels += [np.rot90(x, k=0, axes=(0, 1)) for x in lvmin_kernels_raw]
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lvmin_kernels += [np.rot90(x, k=1, axes=(0, 1)) for x in lvmin_kernels_raw]
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lvmin_kernels += [np.rot90(x, k=2, axes=(0, 1)) for x in lvmin_kernels_raw]
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lvmin_kernels += [np.rot90(x, k=3, axes=(0, 1)) for x in lvmin_kernels_raw]
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lvmin_prunings_raw = [
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np.array([[-1, -1, -1], [-1, 1, -1], [0, 0, -1]], dtype=np.int32),
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np.array([[-1, -1, -1], [-1, 1, -1], [-1, 0, 0]], dtype=np.int32),
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]
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lvmin_prunings = []
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lvmin_prunings += [np.rot90(x, k=0, axes=(0, 1)) for x in lvmin_prunings_raw]
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lvmin_prunings += [np.rot90(x, k=1, axes=(0, 1)) for x in lvmin_prunings_raw]
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lvmin_prunings += [np.rot90(x, k=2, axes=(0, 1)) for x in lvmin_prunings_raw]
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lvmin_prunings += [np.rot90(x, k=3, axes=(0, 1)) for x in lvmin_prunings_raw]
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def remove_pattern(x, kernel):
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objects = cv2.morphologyEx(x, cv2.MORPH_HITMISS, kernel)
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objects = np.where(objects > 127)
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x[objects] = 0
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return x, objects[0].shape[0] > 0
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def thin_one_time(x, kernels):
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y = x
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is_done = True
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for k in kernels:
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y, has_update = remove_pattern(y, k)
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if has_update:
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is_done = False
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return y, is_done
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def lvmin_thin(x, prunings=True):
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y = x
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for i in range(32):
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y, is_done = thin_one_time(y, lvmin_kernels)
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if is_done:
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break
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if prunings:
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y, _ = thin_one_time(y, lvmin_prunings)
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return y
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def nake_nms(x):
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f1 = np.array([[0, 0, 0], [1, 1, 1], [0, 0, 0]], dtype=np.uint8)
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f2 = np.array([[0, 1, 0], [0, 1, 0], [0, 1, 0]], dtype=np.uint8)
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f3 = np.array([[1, 0, 0], [0, 1, 0], [0, 0, 1]], dtype=np.uint8)
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f4 = np.array([[0, 0, 1], [0, 1, 0], [1, 0, 0]], dtype=np.uint8)
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y = np.zeros_like(x)
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for f in [f1, f2, f3, f4]:
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np.putmask(y, cv2.dilate(x, kernel=f) == x, x)
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return y
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2023-07-20 07:38:20 +00:00
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################################################################################
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# copied from Mikubill/sd-webui-controlnet external_code.py and modified for InvokeAI
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################################################################################
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# FIXME: not using yet, if used in the future will most likely require modification of preprocessors
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def pixel_perfect_resolution(
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image: np.ndarray,
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target_H: int,
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target_W: int,
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resize_mode: str,
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) -> int:
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"""
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Calculate the estimated resolution for resizing an image while preserving aspect ratio.
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The function first calculates scaling factors for height and width of the image based on the target
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height and width. Then, based on the chosen resize mode, it either takes the smaller or the larger
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scaling factor to estimate the new resolution.
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If the resize mode is OUTER_FIT, the function uses the smaller scaling factor, ensuring the whole image
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fits within the target dimensions, potentially leaving some empty space.
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If the resize mode is not OUTER_FIT, the function uses the larger scaling factor, ensuring the target
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dimensions are fully filled, potentially cropping the image.
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After calculating the estimated resolution, the function prints some debugging information.
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Args:
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image (np.ndarray): A 3D numpy array representing an image. The dimensions represent [height, width, channels].
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target_H (int): The target height for the image.
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target_W (int): The target width for the image.
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resize_mode (ResizeMode): The mode for resizing.
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Returns:
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int: The estimated resolution after resizing.
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"""
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raw_H, raw_W, _ = image.shape
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k0 = float(target_H) / float(raw_H)
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k1 = float(target_W) / float(raw_W)
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if resize_mode == "fill_resize":
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estimation = min(k0, k1) * float(min(raw_H, raw_W))
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else: # "crop_resize" or "just_resize" (or possibly "just_resize_simple"?)
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estimation = max(k0, k1) * float(min(raw_H, raw_W))
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# print(f"Pixel Perfect Computation:")
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# print(f"resize_mode = {resize_mode}")
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# print(f"raw_H = {raw_H}")
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# print(f"raw_W = {raw_W}")
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# print(f"target_H = {target_H}")
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# print(f"target_W = {target_W}")
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# print(f"estimation = {estimation}")
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return int(np.round(estimation))
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2023-07-20 01:52:30 +00:00
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###########################################################################
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# Copied from detectmap_proc method in scripts/detectmap_proc.py in Mikubill/sd-webui-controlnet
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# modified for InvokeAI
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###########################################################################
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# def detectmap_proc(detected_map, module, resize_mode, h, w):
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def np_img_resize(np_img: np.ndarray, resize_mode: str, h: int, w: int, device: torch.device = torch.device("cpu")):
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# if 'inpaint' in module:
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# np_img = np_img.astype(np.float32)
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# else:
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# np_img = HWC3(np_img)
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np_img = HWC3(np_img)
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def safe_numpy(x):
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# A very safe method to make sure that Apple/Mac works
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y = x
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# below is very boring but do not change these. If you change these Apple or Mac may fail.
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y = y.copy()
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y = np.ascontiguousarray(y)
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y = y.copy()
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return y
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def get_pytorch_control(x):
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# A very safe method to make sure that Apple/Mac works
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y = x
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# below is very boring but do not change these. If you change these Apple or Mac may fail.
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y = torch.from_numpy(y)
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y = y.float() / 255.0
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y = rearrange(y, "h w c -> 1 c h w")
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y = y.clone()
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# y = y.to(devices.get_device_for("controlnet"))
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y = y.to(device)
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y = y.clone()
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return y
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def high_quality_resize(x: np.ndarray, size):
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# Written by lvmin
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# Super high-quality control map up-scaling, considering binary, seg, and one-pixel edges
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inpaint_mask = None
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if x.ndim == 3 and x.shape[2] == 4:
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inpaint_mask = x[:, :, 3]
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x = x[:, :, 0:3]
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new_size_is_smaller = (size[0] * size[1]) < (x.shape[0] * x.shape[1])
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new_size_is_bigger = (size[0] * size[1]) > (x.shape[0] * x.shape[1])
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unique_color_count = np.unique(x.reshape(-1, x.shape[2]), axis=0).shape[0]
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is_one_pixel_edge = False
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is_binary = False
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if unique_color_count == 2:
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is_binary = np.min(x) < 16 and np.max(x) > 240
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if is_binary:
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xc = x
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xc = cv2.erode(xc, np.ones(shape=(3, 3), dtype=np.uint8), iterations=1)
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xc = cv2.dilate(xc, np.ones(shape=(3, 3), dtype=np.uint8), iterations=1)
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one_pixel_edge_count = np.where(xc < x)[0].shape[0]
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all_edge_count = np.where(x > 127)[0].shape[0]
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is_one_pixel_edge = one_pixel_edge_count * 2 > all_edge_count
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if 2 < unique_color_count < 200:
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interpolation = cv2.INTER_NEAREST
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elif new_size_is_smaller:
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interpolation = cv2.INTER_AREA
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else:
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interpolation = cv2.INTER_CUBIC # Must be CUBIC because we now use nms. NEVER CHANGE THIS
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y = cv2.resize(x, size, interpolation=interpolation)
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if inpaint_mask is not None:
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inpaint_mask = cv2.resize(inpaint_mask, size, interpolation=interpolation)
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if is_binary:
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y = np.mean(y.astype(np.float32), axis=2).clip(0, 255).astype(np.uint8)
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if is_one_pixel_edge:
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y = nake_nms(y)
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_, y = cv2.threshold(y, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU)
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y = lvmin_thin(y, prunings=new_size_is_bigger)
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else:
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_, y = cv2.threshold(y, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU)
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y = np.stack([y] * 3, axis=2)
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if inpaint_mask is not None:
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inpaint_mask = (inpaint_mask > 127).astype(np.float32) * 255.0
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inpaint_mask = inpaint_mask[:, :, None].clip(0, 255).astype(np.uint8)
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y = np.concatenate([y, inpaint_mask], axis=2)
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return y
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# if resize_mode == external_code.ResizeMode.RESIZE:
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if resize_mode == "just_resize": # RESIZE
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np_img = high_quality_resize(np_img, (w, h))
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np_img = safe_numpy(np_img)
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return get_pytorch_control(np_img), np_img
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old_h, old_w, _ = np_img.shape
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old_w = float(old_w)
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old_h = float(old_h)
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k0 = float(h) / old_h
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k1 = float(w) / old_w
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2023-08-17 22:45:25 +00:00
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def safeint(x: Union[int, float]) -> int:
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return int(np.round(x))
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2023-07-20 01:52:30 +00:00
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# if resize_mode == external_code.ResizeMode.OUTER_FIT:
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if resize_mode == "fill_resize": # OUTER_FIT
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k = min(k0, k1)
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borders = np.concatenate([np_img[0, :, :], np_img[-1, :, :], np_img[:, 0, :], np_img[:, -1, :]], axis=0)
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high_quality_border_color = np.median(borders, axis=0).astype(np_img.dtype)
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if len(high_quality_border_color) == 4:
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# Inpaint hijack
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high_quality_border_color[3] = 255
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high_quality_background = np.tile(high_quality_border_color[None, None], [h, w, 1])
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np_img = high_quality_resize(np_img, (safeint(old_w * k), safeint(old_h * k)))
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new_h, new_w, _ = np_img.shape
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pad_h = max(0, (h - new_h) // 2)
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pad_w = max(0, (w - new_w) // 2)
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high_quality_background[pad_h : pad_h + new_h, pad_w : pad_w + new_w] = np_img
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np_img = high_quality_background
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np_img = safe_numpy(np_img)
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return get_pytorch_control(np_img), np_img
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else: # resize_mode == "crop_resize" (INNER_FIT)
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k = max(k0, k1)
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np_img = high_quality_resize(np_img, (safeint(old_w * k), safeint(old_h * k)))
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new_h, new_w, _ = np_img.shape
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pad_h = max(0, (new_h - h) // 2)
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pad_w = max(0, (new_w - w) // 2)
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np_img = np_img[pad_h : pad_h + h, pad_w : pad_w + w]
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np_img = safe_numpy(np_img)
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return get_pytorch_control(np_img), np_img
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2023-07-20 02:01:14 +00:00
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2023-07-27 14:54:01 +00:00
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2023-07-20 02:01:14 +00:00
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def prepare_control_image(
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image: Image,
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2023-10-05 05:29:16 +00:00
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width: int,
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height: int,
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num_channels: int = 3,
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2023-07-20 02:01:14 +00:00
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device="cuda",
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dtype=torch.float16,
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do_classifier_free_guidance=True,
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control_mode="balanced",
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resize_mode="just_resize_simple",
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):
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2023-10-05 05:29:16 +00:00
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"""Pre-process images for ControlNets or T2I-Adapters.
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Args:
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image (Image): The PIL image to pre-process.
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width (int): The target width in pixels.
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height (int): The target height in pixels.
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num_channels (int, optional): The target number of image channels. This is achieved by converting the input
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image to RGB, then naively taking the first `num_channels` channels. The primary use case is converting a
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RGB image to a single-channel grayscale image. Raises if `num_channels` cannot be achieved. Defaults to 3.
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device (str, optional): The target device for the output image. Defaults to "cuda".
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dtype (_type_, optional): The dtype for the output image. Defaults to torch.float16.
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do_classifier_free_guidance (bool, optional): If True, repeat the output image along the batch dimension.
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Defaults to True.
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control_mode (str, optional): Defaults to "balanced".
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resize_mode (str, optional): Defaults to "just_resize_simple".
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Raises:
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NotImplementedError: If resize_mode == "crop_resize_simple".
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NotImplementedError: If resize_mode == "fill_resize_simple".
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ValueError: If `resize_mode` is not recognized.
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ValueError: If `num_channels` is out of range.
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Returns:
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torch.Tensor: The pre-processed input tensor.
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"""
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2023-07-20 02:01:14 +00:00
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if (
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resize_mode == "just_resize_simple"
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or resize_mode == "crop_resize_simple"
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or resize_mode == "fill_resize_simple"
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):
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image = image.convert("RGB")
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if resize_mode == "just_resize_simple":
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image = image.resize((width, height), resample=PIL_INTERPOLATION["lanczos"])
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2023-10-05 05:29:16 +00:00
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elif resize_mode == "crop_resize_simple":
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raise NotImplementedError(f"prepare_control_image is not implemented for resize_mode='{resize_mode}'.")
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elif resize_mode == "fill_resize_simple":
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raise NotImplementedError(f"prepare_control_image is not implemented for resize_mode='{resize_mode}'.")
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2023-07-20 02:01:14 +00:00
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nimage = np.array(image)
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nimage = nimage[None, :]
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nimage = np.concatenate([nimage], axis=0)
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# normalizing RGB values to [0,1] range (in PIL.Image they are [0-255])
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nimage = np.array(nimage).astype(np.float32) / 255.0
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nimage = nimage.transpose(0, 3, 1, 2)
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timage = torch.from_numpy(nimage)
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# use fancy lvmin controlnet resizing
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elif resize_mode == "just_resize" or resize_mode == "crop_resize" or resize_mode == "fill_resize":
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nimage = np.array(image)
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timage, nimage = np_img_resize(
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np_img=nimage,
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resize_mode=resize_mode,
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h=height,
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w=width,
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# device=torch.device('cpu')
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device=device,
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)
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else:
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2023-10-05 05:29:16 +00:00
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raise ValueError(f"Unsupported resize_mode: '{resize_mode}'.")
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if timage.shape[1] < num_channels or num_channels <= 0:
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raise ValueError(f"Cannot achieve the target of num_channels={num_channels}.")
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timage = timage[:, :num_channels, :, :]
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2023-07-20 02:01:14 +00:00
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timage = timage.to(device=device, dtype=dtype)
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cfg_injection = control_mode == "more_control" or control_mode == "unbalanced"
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if do_classifier_free_guidance and not cfg_injection:
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timage = torch.cat([timage] * 2)
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return timage
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