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PIFu-Clothed-Human-Digitization / PIFu /apps /render_data.py

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	#from data.config import raw_dataset, render_dataset, archive_dataset, model_list, zip_path

	from lib.renderer.camera import Camera
	import numpy as np
	from lib.renderer.mesh import load_obj_mesh, compute_tangent, compute_normal, load_obj_mesh_mtl
	from lib.renderer.camera import Camera
	import os
	import cv2
	import time
	import math
	import random
	import pyexr
	import argparse
	from tqdm import tqdm


	def make_rotate(rx, ry, rz):
	sinX = np.sin(rx)
	sinY = np.sin(ry)
	sinZ = np.sin(rz)

	cosX = np.cos(rx)
	cosY = np.cos(ry)
	cosZ = np.cos(rz)

	Rx = np.zeros((3,3))
	Rx[0, 0] = 1.0
	Rx[1, 1] = cosX
	Rx[1, 2] = -sinX
	Rx[2, 1] = sinX
	Rx[2, 2] = cosX

	Ry = np.zeros((3,3))
	Ry[0, 0] = cosY
	Ry[0, 2] = sinY
	Ry[1, 1] = 1.0
	Ry[2, 0] = -sinY
	Ry[2, 2] = cosY

	Rz = np.zeros((3,3))
	Rz[0, 0] = cosZ
	Rz[0, 1] = -sinZ
	Rz[1, 0] = sinZ
	Rz[1, 1] = cosZ
	Rz[2, 2] = 1.0

	R = np.matmul(np.matmul(Rz,Ry),Rx)
	return R

	def rotateSH(SH, R):
	SHn = SH

	# 1st order
	SHn[1] = R[1,1]SH[1] - R[1,2]SH[2] + R[1,0]*SH[3]
	SHn[2] = -R[2,1]SH[1] + R[2,2]SH[2] - R[2,0]*SH[3]
	SHn[3] = R[0,1]SH[1] - R[0,2]SH[2] + R[0,0]*SH[3]

	# 2nd order
	SHn[4:,0] = rotateBand2(SH[4:,0],R)
	SHn[4:,1] = rotateBand2(SH[4:,1],R)
	SHn[4:,2] = rotateBand2(SH[4:,2],R)

	return SHn

	def rotateBand2(x, R):
	s_c3 = 0.94617469575
	s_c4 = -0.31539156525
	s_c5 = 0.54627421529

	s_c_scale = 1.0/0.91529123286551084
	s_c_scale_inv = 0.91529123286551084

	s_rc2 = 1.5853309190550713*s_c_scale
	s_c4_div_c3 = s_c4/s_c3
	s_c4_div_c3_x2 = (s_c4/s_c3)*2.0

	s_scale_dst2 = s_c3 * s_c_scale_inv
	s_scale_dst4 = s_c5 * s_c_scale_inv

	sh0 = x[3] + x[4] + x[4] - x[1]
	sh1 = x[0] + s_rc2*x[2] + x[3] + x[4]
	sh2 = x[0]
	sh3 = -x[3]
	sh4 = -x[1]

	r2x = R[0][0] + R[0][1]
	r2y = R[1][0] + R[1][1]
	r2z = R[2][0] + R[2][1]

	r3x = R[0][0] + R[0][2]
	r3y = R[1][0] + R[1][2]
	r3z = R[2][0] + R[2][2]

	r4x = R[0][1] + R[0][2]
	r4y = R[1][1] + R[1][2]
	r4z = R[2][1] + R[2][2]

	sh0_x = sh0 * R[0][0]
	sh0_y = sh0 * R[1][0]
	d0 = sh0_x * R[1][0]
	d1 = sh0_y * R[2][0]
	d2 = sh0 * (R[2][0] * R[2][0] + s_c4_div_c3)
	d3 = sh0_x * R[2][0]
	d4 = sh0_x * R[0][0] - sh0_y * R[1][0]

	sh1_x = sh1 * R[0][2]
	sh1_y = sh1 * R[1][2]
	d0 += sh1_x * R[1][2]
	d1 += sh1_y * R[2][2]
	d2 += sh1 * (R[2][2] * R[2][2] + s_c4_div_c3)
	d3 += sh1_x * R[2][2]
	d4 += sh1_x * R[0][2] - sh1_y * R[1][2]

	sh2_x = sh2 * r2x
	sh2_y = sh2 * r2y
	d0 += sh2_x * r2y
	d1 += sh2_y * r2z
	d2 += sh2 * (r2z * r2z + s_c4_div_c3_x2)
	d3 += sh2_x * r2z
	d4 += sh2_x * r2x - sh2_y * r2y

	sh3_x = sh3 * r3x
	sh3_y = sh3 * r3y
	d0 += sh3_x * r3y
	d1 += sh3_y * r3z
	d2 += sh3 * (r3z * r3z + s_c4_div_c3_x2)
	d3 += sh3_x * r3z
	d4 += sh3_x * r3x - sh3_y * r3y

	sh4_x = sh4 * r4x
	sh4_y = sh4 * r4y
	d0 += sh4_x * r4y
	d1 += sh4_y * r4z
	d2 += sh4 * (r4z * r4z + s_c4_div_c3_x2)
	d3 += sh4_x * r4z
	d4 += sh4_x * r4x - sh4_y * r4y

	dst = x
	dst[0] = d0
	dst[1] = -d1
	dst[2] = d2 * s_scale_dst2
	dst[3] = -d3
	dst[4] = d4 * s_scale_dst4

	return dst

	def render_prt_ortho(out_path, folder_name, subject_name, shs, rndr, rndr_uv, im_size, angl_step=4, n_light=1, pitch=[0]):
	cam = Camera(width=im_size, height=im_size)
	cam.ortho_ratio = 0.4 * (512 / im_size)
	cam.near = -100
	cam.far = 100
	cam.sanity_check()

	# set path for obj, prt
	mesh_file = os.path.join(folder_name, subject_name + '_100k.obj')
	if not os.path.exists(mesh_file):
	print('ERROR: obj file does not exist!!', mesh_file)
	return
	prt_file = os.path.join(folder_name, 'bounce', 'bounce0.txt')
	if not os.path.exists(prt_file):
	print('ERROR: prt file does not exist!!!', prt_file)
	return
	face_prt_file = os.path.join(folder_name, 'bounce', 'face.npy')
	if not os.path.exists(face_prt_file):
	print('ERROR: face prt file does not exist!!!', prt_file)
	return
	text_file = os.path.join(folder_name, 'tex', subject_name + '_dif_2k.jpg')
	if not os.path.exists(text_file):
	print('ERROR: dif file does not exist!!', text_file)
	return

	texture_image = cv2.imread(text_file)
	texture_image = cv2.cvtColor(texture_image, cv2.COLOR_BGR2RGB)

	vertices, faces, normals, faces_normals, textures, face_textures = load_obj_mesh(mesh_file, with_normal=True, with_texture=True)
	vmin = vertices.min(0)
	vmax = vertices.max(0)
	up_axis = 1 if (vmax-vmin).argmax() == 1 else 2

	vmed = np.median(vertices, 0)
	vmed[up_axis] = 0.5*(vmax[up_axis]+vmin[up_axis])
	y_scale = 180/(vmax[up_axis] - vmin[up_axis])

	rndr.set_norm_mat(y_scale, vmed)
	rndr_uv.set_norm_mat(y_scale, vmed)

	tan, bitan = compute_tangent(vertices, faces, normals, textures, face_textures)
	prt = np.loadtxt(prt_file)
	face_prt = np.load(face_prt_file)
	rndr.set_mesh(vertices, faces, normals, faces_normals, textures, face_textures, prt, face_prt, tan, bitan)
	rndr.set_albedo(texture_image)

	rndr_uv.set_mesh(vertices, faces, normals, faces_normals, textures, face_textures, prt, face_prt, tan, bitan)
	rndr_uv.set_albedo(texture_image)

	os.makedirs(os.path.join(out_path, 'GEO', 'OBJ', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'PARAM', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'RENDER', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'MASK', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'UV_RENDER', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'UV_MASK', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'UV_POS', subject_name),exist_ok=True)
	os.makedirs(os.path.join(out_path, 'UV_NORMAL', subject_name),exist_ok=True)

	if not os.path.exists(os.path.join(out_path, 'val.txt')):
	f = open(os.path.join(out_path, 'val.txt'), 'w')
	f.close()

	# copy obj file
	cmd = 'cp %s %s' % (mesh_file, os.path.join(out_path, 'GEO', 'OBJ', subject_name))
	print(cmd)
	os.system(cmd)

	for p in pitch:
	for y in tqdm(range(0, 360, angl_step)):
	R = np.matmul(make_rotate(math.radians(p), 0, 0), make_rotate(0, math.radians(y), 0))
	if up_axis == 2:
	R = np.matmul(R, make_rotate(math.radians(90),0,0))

	rndr.rot_matrix = R
	rndr_uv.rot_matrix = R
	rndr.set_camera(cam)
	rndr_uv.set_camera(cam)

	for j in range(n_light):
	sh_id = random.randint(0,shs.shape[0]-1)
	sh = shs[sh_id]
	sh_angle = 0.2np.pi(random.random()-0.5)
	sh = rotateSH(sh, make_rotate(0, sh_angle, 0).T)

	dic = {'sh': sh, 'ortho_ratio': cam.ortho_ratio, 'scale': y_scale, 'center': vmed, 'R': R}

	rndr.set_sh(sh)
	rndr.analytic = False
	rndr.use_inverse_depth = False
	rndr.display()

	out_all_f = rndr.get_color(0)
	out_mask = out_all_f[:,:,3]
	out_all_f = cv2.cvtColor(out_all_f, cv2.COLOR_RGBA2BGR)

	np.save(os.path.join(out_path, 'PARAM', subject_name, '%d_%d_%02d.npy'%(y,p,j)),dic)
	cv2.imwrite(os.path.join(out_path, 'RENDER', subject_name, '%d_%d_%02d.jpg'%(y,p,j)),255.0*out_all_f)
	cv2.imwrite(os.path.join(out_path, 'MASK', subject_name, '%d_%d_%02d.png'%(y,p,j)),255.0*out_mask)

	rndr_uv.set_sh(sh)
	rndr_uv.analytic = False
	rndr_uv.use_inverse_depth = False
	rndr_uv.display()

	uv_color = rndr_uv.get_color(0)
	uv_color = cv2.cvtColor(uv_color, cv2.COLOR_RGBA2BGR)
	cv2.imwrite(os.path.join(out_path, 'UV_RENDER', subject_name, '%d_%d_%02d.jpg'%(y,p,j)),255.0*uv_color)

	if y == 0 and j == 0 and p == pitch[0]:
	uv_pos = rndr_uv.get_color(1)
	uv_mask = uv_pos[:,:,3]
	cv2.imwrite(os.path.join(out_path, 'UV_MASK', subject_name, '00.png'),255.0*uv_mask)

	data = {'default': uv_pos[:,:,:3]} # default is a reserved name
	pyexr.write(os.path.join(out_path, 'UV_POS', subject_name, '00.exr'), data)

	uv_nml = rndr_uv.get_color(2)
	uv_nml = cv2.cvtColor(uv_nml, cv2.COLOR_RGBA2BGR)
	cv2.imwrite(os.path.join(out_path, 'UV_NORMAL', subject_name, '00.png'),255.0*uv_nml)


	if __name__ == '__main__':
	shs = np.load('./env_sh.npy')

	parser = argparse.ArgumentParser()
	parser.add_argument('-i', '--input', type=str, default='/home/shunsuke/Downloads/rp_dennis_posed_004_OBJ')
	parser.add_argument('-o', '--out_dir', type=str, default='/home/shunsuke/Documents/hf_human')
	parser.add_argument('-m', '--ms_rate', type=int, default=1, help='higher ms rate results in less aliased output. MESA renderer only supports ms_rate=1.')
	parser.add_argument('-e', '--egl', action='store_true', help='egl rendering option. use this when rendering with headless server with NVIDIA GPU')
	parser.add_argument('-s', '--size', type=int, default=512, help='rendering image size')
	args = parser.parse_args()

	# NOTE: GL context has to be created before any other OpenGL function loads.
	from lib.renderer.gl.init_gl import initialize_GL_context
	initialize_GL_context(width=args.size, height=args.size, egl=args.egl)

	from lib.renderer.gl.prt_render import PRTRender
	rndr = PRTRender(width=args.size, height=args.size, ms_rate=args.ms_rate, egl=args.egl)
	rndr_uv = PRTRender(width=args.size, height=args.size, uv_mode=True, egl=args.egl)

	if args.input[-1] == '/':
	args.input = args.input[:-1]
	subject_name = args.input.split('/')[-1][:-4]
	render_prt_ortho(args.out_dir, args.input, subject_name, shs, rndr, rndr_uv, args.size, 1, 1, pitch=[0])