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Unique3D / scripts /normal_to_height_map.py

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37aeb5b about 1 month ago

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	# code modified from https://github.com/YertleTurtleGit/depth-from-normals
	import numpy as np
	import cv2 as cv
	from multiprocessing.pool import ThreadPool as Pool
	from multiprocessing import cpu_count
	from typing import Tuple, List, Union
	import numba


	def calculate_gradients(
	normals: np.ndarray, mask: np.ndarray
	) -> Tuple[np.ndarray, np.ndarray]:
	horizontal_angle_map = np.arccos(np.clip(normals[:, :, 0], -1, 1))
	left_gradients = np.zeros(normals.shape[:2])
	left_gradients[mask != 0] = (1 - np.sin(horizontal_angle_map[mask != 0])) * np.sign(
	horizontal_angle_map[mask != 0] - np.pi / 2
	)

	vertical_angle_map = np.arccos(np.clip(normals[:, :, 1], -1, 1))
	top_gradients = np.zeros(normals.shape[:2])
	top_gradients[mask != 0] = -(1 - np.sin(vertical_angle_map[mask != 0])) * np.sign(
	vertical_angle_map[mask != 0] - np.pi / 2
	)

	return left_gradients, top_gradients


	@numba.jit(nopython=True)
	def integrate_gradient_field(
	gradient_field: np.ndarray, axis: int, mask: np.ndarray
	) -> np.ndarray:
	heights = np.zeros(gradient_field.shape)

	for d1 in numba.prange(heights.shape[1 - axis]):
	sum_value = 0
	for d2 in range(heights.shape[axis]):
	coordinates = (d1, d2) if axis == 1 else (d2, d1)

	if mask[coordinates] != 0:
	sum_value = sum_value + gradient_field[coordinates]
	heights[coordinates] = sum_value
	else:
	sum_value = 0

	return heights


	def calculate_heights(
	left_gradients: np.ndarray, top_gradients, mask: np.ndarray
	) -> Tuple[np.ndarray, np.ndarray, np.ndarray, np.ndarray]:
	left_heights = integrate_gradient_field(left_gradients, 1, mask)
	right_heights = np.fliplr(
	integrate_gradient_field(np.fliplr(-left_gradients), 1, np.fliplr(mask))
	)
	top_heights = integrate_gradient_field(top_gradients, 0, mask)
	bottom_heights = np.flipud(
	integrate_gradient_field(np.flipud(-top_gradients), 0, np.flipud(mask))
	)
	return left_heights, right_heights, top_heights, bottom_heights


	def combine_heights(*heights: np.ndarray) -> np.ndarray:
	return np.mean(np.stack(heights, axis=0), axis=0)


	def rotate(matrix: np.ndarray, angle: float) -> np.ndarray:
	h, w = matrix.shape[:2]
	center = (w / 2, h / 2)

	rotation_matrix = cv.getRotationMatrix2D(center, angle, 1.0)
	corners = cv.transform(
	np.array([[[0, 0], [w, 0], [w, h], [0, h]]]), rotation_matrix
	)[0]

	_, _, w, h = cv.boundingRect(corners)

	rotation_matrix[0, 2] += w / 2 - center[0]
	rotation_matrix[1, 2] += h / 2 - center[1]
	result = cv.warpAffine(matrix, rotation_matrix, (w, h), flags=cv.INTER_LINEAR)

	return result


	def rotate_vector_field_normals(normals: np.ndarray, angle: float) -> np.ndarray:
	angle = np.radians(angle)
	cos_angle = np.cos(angle)
	sin_angle = np.sin(angle)

	rotated_normals = np.empty_like(normals)
	rotated_normals[:, :, 0] = (
	normals[:, :, 0] * cos_angle - normals[:, :, 1] * sin_angle
	)
	rotated_normals[:, :, 1] = (
	normals[:, :, 0] * sin_angle + normals[:, :, 1] * cos_angle
	)

	return rotated_normals


	def centered_crop(image: np.ndarray, target_resolution: Tuple[int, int]) -> np.ndarray:
	return image[
	(image.shape[0] - target_resolution[0])
	// 2 : (image.shape[0] - target_resolution[0])
	// 2
	+ target_resolution[0],
	(image.shape[1] - target_resolution[1])
	// 2 : (image.shape[1] - target_resolution[1])
	// 2
	+ target_resolution[1],
	]


	def integrate_vector_field(
	vector_field: np.ndarray,
	mask: np.ndarray,
	target_iteration_count: int,
	thread_count: int,
	) -> np.ndarray:
	shape = vector_field.shape[:2]
	angles = np.linspace(0, 90, target_iteration_count, endpoint=False)

	def integrate_vector_field_angles(angles: List[float]) -> np.ndarray:
	all_combined_heights = np.zeros(shape)

	for angle in angles:
	rotated_vector_field = rotate_vector_field_normals(
	rotate(vector_field, angle), angle
	)
	rotated_mask = rotate(mask, angle)

	left_gradients, top_gradients = calculate_gradients(
	rotated_vector_field, rotated_mask
	)
	(
	left_heights,
	right_heights,
	top_heights,
	bottom_heights,
	) = calculate_heights(left_gradients, top_gradients, rotated_mask)

	combined_heights = combine_heights(
	left_heights, right_heights, top_heights, bottom_heights
	)
	combined_heights = centered_crop(rotate(combined_heights, -angle), shape)
	all_combined_heights += combined_heights / len(angles)

	return all_combined_heights

	with Pool(processes=thread_count) as pool:
	heights = pool.map(
	integrate_vector_field_angles,
	np.array(
	np.array_split(angles, thread_count),
	dtype=object,
	),
	)
	pool.close()
	pool.join()

	isotropic_height = np.zeros(shape)
	for height in heights:
	isotropic_height += height / thread_count

	return isotropic_height


	def estimate_height_map(
	normal_map: np.ndarray,
	mask: Union[np.ndarray, None] = None,
	height_divisor: float = 1,
	target_iteration_count: int = 250,
	thread_count: int = cpu_count(),
	raw_values: bool = False,
	) -> np.ndarray:
	if mask is None:
	if normal_map.shape[-1] == 4:
	mask = normal_map[:, :, 3] / 255
	mask[mask < 0.5] = 0
	mask[mask >= 0.5] = 1
	else:
	mask = np.ones(normal_map.shape[:2], dtype=np.uint8)

	normals = ((normal_map[:, :, :3].astype(np.float64) / 255) - 0.5) * 2
	heights = integrate_vector_field(
	normals, mask, target_iteration_count, thread_count
	)

	if raw_values:
	return heights

	heights /= height_divisor
	heights[mask > 0] += 1 / 2
	heights[mask == 0] = 1 / 2

	heights = 2*16 - 1

	if np.min(heights) < 0 or np.max(heights) > 2**16 - 1:
	raise OverflowError("Height values are clipping.")

	heights = np.clip(heights, 0, 2**16 - 1)
	heights = heights.astype(np.uint16)

	return heights