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import math | |
import bpy | |
import numpy as np | |
from mGPT.utils.joints import (humanml3d_joints, humanml3d_kinematic_tree, | |
mmm_joints, mmm_kinematic_tree, | |
mmm_to_smplh_scaling_factor) | |
# from .materials import colored_material_diffuse_BSDF as colored_material | |
from .materials import colored_material_relection_BSDF as colored_material | |
sat_factor = 1.1 | |
JOINTS_MATS = [ | |
# colored_material(0.2500, 0.0357, 0.0349, saturation_factor = sat_factor), | |
# # colored_material(0.4500, 0.0357, 0.0349), | |
# colored_material(0.6500, 0.175, 0.0043, saturation_factor = sat_factor), | |
# colored_material(0.0349, 0.3500, 0.0349, saturation_factor = sat_factor), | |
# colored_material(0.018, 0.059, 0.600, saturation_factor = sat_factor), | |
# colored_material(0.032, 0.325, 0.421, saturation_factor = sat_factor), | |
# colored_material(0.3, 0.3, 0.3, saturation_factor = sat_factor), | |
colored_material(0.3500, 0.0357, 0.0349, saturation_factor=sat_factor), | |
# colored_material(0.4500, 0.0357, 0.0349), | |
colored_material(0.6500, 0.175, 0.0043, saturation_factor=sat_factor), | |
colored_material(0.0349, 0.3500, 0.0349, saturation_factor=sat_factor), | |
colored_material(0.018, 0.059, 0.600, saturation_factor=sat_factor), | |
colored_material(0.032, 0.325, 0.421, saturation_factor=sat_factor), | |
colored_material(0.3, 0.3, 0.3, saturation_factor=sat_factor), | |
] | |
class Joints: | |
def __init__(self, | |
data, | |
*, | |
mode, | |
canonicalize, | |
always_on_floor, | |
jointstype="mmm", | |
**kwargs): | |
data = prepare_joints( | |
data, | |
canonicalize=canonicalize, | |
always_on_floor=always_on_floor, | |
jointstype=jointstype, | |
) | |
self.data = data | |
self.mode = mode | |
self.N = len(data) | |
self.N = len(data) | |
self.trajectory = data[:, 0, [0, 1]] | |
if jointstype == "mmm": | |
self.kinematic_tree = mmm_kinematic_tree | |
self.joints = mmm_joints | |
self.joinst.append("") | |
elif jointstype == "humanml3d": | |
self.kinematic_tree = humanml3d_kinematic_tree | |
self.joints = humanml3d_joints | |
self.mat = JOINTS_MATS | |
def get_sequence_mat(self, frac): | |
return self.mat | |
def get_root(self, index): | |
return self.data[index][0] | |
def get_mean_root(self): | |
return self.data[:, 0].mean(0) | |
def load_in_blender(self, index, mats): | |
skeleton = self.data[index] | |
head_mat = mats[0] | |
body_mat = mats[-1] | |
for lst, mat in zip(self.kinematic_tree, mats): | |
for j1, j2 in zip(lst[:-1], lst[1:]): | |
# spine and head | |
if self.joints[j2] in [ | |
"BUN", | |
]: | |
sphere_between(skeleton[j1], skeleton[j2], head_mat) | |
elif self.joints[j2] in [ | |
"LE", | |
"RE", | |
"LW", | |
"RW", | |
]: | |
cylinder_sphere_between(skeleton[j1], skeleton[j2], 0.040, | |
mat) | |
elif self.joints[j2] in [ | |
"LMrot", | |
"RMrot", | |
"RK", | |
"LK", | |
]: | |
cylinder_sphere_between(skeleton[j1], skeleton[j2], 0.040, | |
mat) | |
elif self.joints[j2] in [ | |
"LS", | |
"RS", | |
"LF", | |
"RF", | |
]: | |
cylinder_between(skeleton[j1], skeleton[j2], 0.040, mat) | |
elif self.joints[j2] in ["RK", "LK"]: | |
print(self.joints[j1], self.joints[j2]) | |
# body | |
sphere(0.14, skeleton[self.joints.index("BLN")], body_mat) | |
sphere_between( | |
skeleton[self.joints.index("BLN")], | |
skeleton[self.joints.index("root")], | |
body_mat, | |
factor=0.28, | |
) | |
sphere(0.11, skeleton[self.joints.index("root")], body_mat) | |
# sphere_between( | |
# skeleton[self.joints.index("BLN")], | |
# skeleton[self.joints.index("BT")], | |
# mats[0], | |
# ) | |
# hip | |
# sphere_between( | |
# skeleton[self.joints.index("LH")], | |
# skeleton[self.joints.index("RH")], | |
# mats[0], | |
# factor=0.6, | |
# ) | |
# | |
# sphere(skeleton[self.joints.index("BLN")], 0.05, mats[0]) | |
# sphere_between(skeleton[13], skeleton[14], mat) | |
# node | |
# print(self.joints.index("BUN")) | |
# print(len(lst)) | |
# sphere(lst[self.joints.index("BUN")], 0.2, mat) # head | |
return ["Cylinder", "Sphere"] | |
def __len__(self): | |
return self.N | |
def softmax(x, softness=1.0, dim=None): | |
maxi, mini = x.max(dim), x.min(dim) | |
return maxi + np.log(softness + np.exp(mini - maxi)) | |
def softmin(x, softness=1.0, dim=0): | |
return -softmax(-x, softness=softness, dim=dim) | |
def get_forward_direction(poses, jointstype="mmm"): | |
if jointstype == "mmm" or jointstype == "mmmns": | |
joints = mmm_joints | |
elif jointstype == "humanml3d": | |
joints = humanml3d_joints | |
else: | |
raise TypeError("Only supports mmm, mmmns and humanl3d jointstype") | |
# Shoulders | |
LS, RS = joints.index("LS"), joints.index("RS") | |
# Hips | |
LH, RH = mmm_joints.index("LH"), mmm_joints.index("RH") | |
across = (poses[..., RH, :] - poses[..., LH, :] + poses[..., RS, :] - | |
poses[..., LS, :]) | |
forward = np.stack((-across[..., 2], across[..., 0]), axis=-1) | |
forward = forward / np.linalg.norm(forward, axis=-1) | |
return forward | |
def cylinder_between(t1, t2, r, mat): | |
x1, y1, z1 = t1 | |
x2, y2, z2 = t2 | |
dx = x2 - x1 | |
dy = y2 - y1 | |
dz = z2 - z1 | |
dist = math.sqrt(dx**2 + dy**2 + dz**2) | |
bpy.ops.mesh.primitive_cylinder_add(radius=r, | |
depth=dist, | |
location=(dx / 2 + x1, dy / 2 + y1, | |
dz / 2 + z1)) | |
phi = math.atan2(dy, dx) | |
theta = math.acos(dz / dist) | |
bpy.context.object.rotation_euler[1] = theta | |
bpy.context.object.rotation_euler[2] = phi | |
# bpy.context.object.shade_smooth() | |
bpy.context.object.active_material = mat | |
bpy.ops.mesh.primitive_uv_sphere_add(radius=r, location=(x1, y1, z1)) | |
bpy.context.object.active_material = mat | |
bpy.ops.mesh.primitive_uv_sphere_add(radius=r, location=(x2, y2, z2)) | |
bpy.context.object.active_material = mat | |
def cylinder_sphere_between(t1, t2, r, mat): | |
x1, y1, z1 = t1 | |
x2, y2, z2 = t2 | |
dx = x2 - x1 | |
dy = y2 - y1 | |
dz = z2 - z1 | |
dist = math.sqrt(dx**2 + dy**2 + dz**2) | |
phi = math.atan2(dy, dx) | |
theta = math.acos(dz / dist) | |
dist = dist - 0.2 * r | |
# sphere node | |
sphere(r * 0.9, t1, mat) | |
sphere(r * 0.9, t2, mat) | |
# leveled cylinder | |
bpy.ops.mesh.primitive_cylinder_add( | |
radius=r, | |
depth=dist, | |
location=(dx / 2 + x1, dy / 2 + y1, dz / 2 + z1), | |
enter_editmode=True, | |
) | |
bpy.ops.mesh.select_mode(type="EDGE") | |
bpy.ops.mesh.select_all(action="DESELECT") | |
bpy.ops.mesh.select_face_by_sides(number=32, extend=False) | |
bpy.ops.mesh.bevel(offset=r, segments=8) | |
bpy.ops.object.editmode_toggle(False) | |
# bpy.ops.object.shade_smooth() | |
bpy.context.object.rotation_euler[1] = theta | |
bpy.context.object.rotation_euler[2] = phi | |
bpy.context.object.active_material = mat | |
def sphere(r, t, mat): | |
bpy.ops.mesh.primitive_uv_sphere_add(segments=50, | |
ring_count=50, | |
radius=r, | |
location=t) | |
# bpy.ops.mesh.primitive_uv_sphere_add(radius=r, location=t) | |
# bpy.context.object.shade_smooth() | |
bpy.context.object.active_material = mat | |
def sphere_between(t1, t2, mat, factor=1): | |
x1, y1, z1 = t1 | |
x2, y2, z2 = t2 | |
dx = x2 - x1 | |
dy = y2 - y1 | |
dz = z2 - z1 | |
dist = math.sqrt(dx**2 + dy**2 + dz**2) * factor | |
bpy.ops.mesh.primitive_uv_sphere_add( | |
segments=50, | |
ring_count=50, | |
# bpy.ops.mesh.primitive_uv_sphere_add( | |
radius=dist, | |
location=(dx / 2 + x1, dy / 2 + y1, dz / 2 + z1)) | |
# bpy.context.object.shade_smooth() | |
bpy.context.object.active_material = mat | |
def matrix_of_angles(cos, sin, inv=False): | |
sin = -sin if inv else sin | |
return np.stack((np.stack( | |
(cos, -sin), axis=-1), np.stack((sin, cos), axis=-1)), | |
axis=-2) | |
def get_floor(poses, jointstype="mmm"): | |
if jointstype == "mmm" or jointstype == "mmmns": | |
joints = mmm_joints | |
elif jointstype == "humanml3d": | |
joints = humanml3d_joints | |
else: | |
raise TypeError("Only supports mmm, mmmns and humanl3d jointstype") | |
# Feet | |
LM, RM = joints.index("LMrot"), joints.index("RMrot") | |
LF, RF = joints.index("LF"), joints.index("RF") | |
ndim = len(poses.shape) | |
foot_heights = poses[..., (LM, LF, RM, RF), 1].min(-1) | |
floor_height = softmin(foot_heights, softness=0.5, dim=-1) | |
return floor_height[tuple((ndim - 2) * [None])].T | |
def canonicalize_joints(joints, jointstype="mmm"): | |
poses = joints.copy() | |
translation = joints[..., 0, :].copy() | |
# Let the root have the Y translation | |
translation[..., 1] = 0 | |
# Trajectory => Translation without gravity axis (Y) | |
trajectory = translation[..., [0, 2]] | |
# Remove the floor | |
poses[..., 1] -= get_floor(poses, jointstype) | |
# Remove the trajectory of the joints | |
poses[..., [0, 2]] -= trajectory[..., None, :] | |
# Let the first pose be in the center | |
trajectory = trajectory - trajectory[..., 0, :] | |
# Compute the forward direction of the first frame | |
forward = get_forward_direction(poses[..., 0, :, :], jointstype) | |
# Construct the inverse rotation matrix | |
sin, cos = forward[..., 0], forward[..., 1] | |
rotations_inv = matrix_of_angles(cos, sin, inv=True) | |
# Rotate the trajectory | |
trajectory_rotated = np.einsum("...j,...jk->...k", trajectory, | |
rotations_inv) | |
# Rotate the poses | |
poses_rotated = np.einsum("...lj,...jk->...lk", poses[..., [0, 2]], | |
rotations_inv) | |
poses_rotated = np.stack( | |
(poses_rotated[..., 0], poses[..., 1], poses_rotated[..., 1]), axis=-1) | |
# Re-merge the pose and translation | |
poses_rotated[..., (0, 2)] += trajectory_rotated[..., None, :] | |
return poses_rotated | |
def prepare_joints(joints, | |
canonicalize=True, | |
always_on_floor=False, | |
jointstype="mmm"): | |
# All face the same direction for the first frame | |
if canonicalize: | |
data = canonicalize_joints(joints, jointstype) | |
else: | |
data = joints | |
# Rescaling, shift axis and swap left/right | |
if jointstype == "humanml3d": | |
data = data * mmm_to_smplh_scaling_factor | |
data[..., 1] = - data[..., 1] | |
# Swap axis (gravity=Z instead of Y) | |
data = data[..., [2, 0, 1]] | |
if jointstype == "mmm": | |
# Make left/right correct | |
data[..., [1]] = -data[..., [1]] | |
# Center the first root to the first frame | |
data -= data[[0], [0], :] | |
# Remove the floor | |
data[..., 2] -= data[..., 2].min() | |
# Put all the body on the floor | |
if always_on_floor: | |
data[..., 2] -= data[..., 2].min(1)[:, None] | |
return data | |
def NormalInDirection(normal, direction, limit=0.5): | |
return direction.dot(normal) > limit | |
def GoingUp(normal, limit=0.5): | |
return NormalInDirection(normal, (0, 0, 1), limit) | |
def GoingDown(normal, limit=0.5): | |
return NormalInDirection(normal, (0, 0, -1), limit) | |
def GoingSide(normal, limit=0.5): | |
return GoingUp(normal, limit) == False and GoingDown(normal, | |
limit) == False | |