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	# Author(s): Jiaqi Xu
	# Created on: 2020-11

	"""
	PSM wrapper
	Refer to:
	https://github.com/jhu-dvrk/dvrk-ros/blob/master/dvrk_python/src/dvrk/ecm.py
	https://github.com/jhu-dvrk/dvrk-ros/blob/7b3d48ca164755ccfc88028e15baa9fbf7aa1360/dvrk_python/src/dvrk/ecm.py
	https://github.com/jhu-dvrk/sawIntuitiveResearchKit/blob/master/share/kinematic/ecm.json
	https://github.com/jhu-dvrk/sawIntuitiveResearchKit/blob/4a8b4817ee7404b3183dfba269c0efe5885b41c2/share/arm/ecm-straight.json
	"""
	import os
	import numpy as np
	import pybullet as p

	from surrol.robots.arm import Arm
	from surrol.const import ASSET_DIR_PATH
	from surrol.utils.pybullet_utils import (
	get_joint_positions,
	get_link_pose,
	render_image
	)

	# Rendering width and height
	RENDER_HEIGHT = 256
	RENDER_WIDTH = 256
	FoV = 60

	LINKS = (
	'ecm_base_link', 'ecm_yaw_link', 'ecm_pitch_end_link', # -1, 0, 1
	'ecm_main_insertion_link', 'ecm_tool_link', # 2, 3
	'ecm_end_link', # 4
	'ecm_tip_link', # 5
	'ecm_pitch_front_link', # 6
	'ecm_pitch_bottom_link', 'ecm_pitch_top_link', # 7, 8
	'ecm_pitch_back_link', # 9
	'ecm_remote_center_link', # 10
	)

	# tooltip-offset; refer to .json
	tool_T_tip = np.array([[0.0, 1.0, 0.0, 0.0],
	[-1.0, 0.0, 0.0, 0.0],
	[0.0, 0.0, 1.0, 0.0],
	[0.0, 0.0, 0.0, 1.0]])

	# Joint limits. No limits in the .json. TODO: dVRK config modified
	TOOL_JOINT_LIMIT = {
	'lower': np.deg2rad([-90.0, -45.0, 0.0, -np.inf]), # not sure about the last joint
	'upper': np.deg2rad([ 90.0, 66.4, 254.0, np.inf]),
	}
	TOOL_JOINT_LIMIT['lower'][2] = -0.01 # allow small tolerance
	TOOL_JOINT_LIMIT['upper'][2] = 0.254 # prismatic joint (m); not sure, from ambf
	# [-1.57079633, -0.78539816, 0. , -1.57079633]
	# [ 1.57079633, 1.15889862, 0.254, 1.57079633]


	class Ecm(Arm):
	NAME = 'ECM'
	URDF_PATH = os.path.join(ASSET_DIR_PATH, 'ecm/ecm.urdf')
	DoF = 4 # 4-dof arm
	JOINT_TYPES = ('R', 'R', 'P', 'R')
	EEF_LINK_INDEX = 4 # EEF link index, one redundant joint for inverse kinematics
	TIP_LINK_INDEX = 5 # redundant joint for easier camera matrix computation
	RCM_LINK_INDEX = 10 # RCM link index
	# D-H parameters
	A = np.array([0.0, 0.0, 0.0, 0.0])
	ALPHA = np.array([np.pi / 2, -np.pi / 2, np.pi / 2, 0.0])
	D = np.array([0.0, 0.0, -0.3822, 0.3829])
	THETA = np.array([np.pi / 2, -np.pi / 2, 0.0, 0.0])

	def __init__(self, pos=(0., 0., 1.), orn=(0., 0., 0., 1.),
	scaling=1.):
	super(Ecm, self).__init__(self.URDF_PATH, pos, orn,
	TOOL_JOINT_LIMIT, tool_T_tip, scaling)

	# camera control related parameters
	self.view_matrix = None
	self.proj_matrix = None
	self._homo_delta = np.zeros((2, 1))
	self._wz = 0

	# b: rcm, e: eef, c: camera
	pos_eef, orn_eef = get_link_pose(self.body, self.EEF_LINK_INDEX)
	pos_cam, orn_cam = get_link_pose(self.body, self.TIP_LINK_INDEX)
	self._tip_offset = np.linalg.norm(np.array(pos_eef) - np.array(pos_cam)) # TODO
	wRe = np.array(p.getMatrixFromQuaternion(orn_eef)).reshape((3, 3))
	wRc = np.array(p.getMatrixFromQuaternion(orn_cam)).reshape((3, 3))
	self._wRc0 = wRc.copy() # initial rotation matrix
	self._eRc = np.matmul(wRe.T, wRc)

	def _get_joint_positions_all(self, abs_input):
	""" With the consideration of parallel mechanism constraints and other redundant joints.
	"""
	positions = get_joint_positions(self.body, self.joints)
	joint_positions = [
	abs_input[0], abs_input[1], # 0, 1
	abs_input[2] * self.scaling, abs_input[3], # 2, 3
	positions[4], positions[5], # 4 (0.0), 5 (0.0)
	abs_input[1], # 6
	-abs_input[1], -abs_input[1], # 7, 8
	abs_input[1], # 9
	positions[10], # 10 (0.0)
	]
	return joint_positions

	def cVc_to_dq(self, cVc: np.ndarray) -> np.ndarray:
	"""
	convert the camera velocity in its own frame (cVc) into the joint velocity q_dot
	"""
	cVc = cVc.reshape((3, 1))

	# restrict the step size, need tune
	if np.abs(cVc).max() > 0.01:
	cVc = cVc / np.abs(cVc).max() * 0.01

	# Forward kinematics
	q = self.get_current_joint_position()
	bRe = self.robot.fkine(q).R # use rtb instead of PyBullet, no tool_tip_offset
	_, orn_cam = get_link_pose(self.body, self.TIP_LINK_INDEX)
	wRc = np.array(p.getMatrixFromQuaternion(orn_cam)).reshape((3, 3))

	# Rotation
	R1, R2 = self._wRc0, wRc
	x = R1[0, 0] * R2[1, 0] - R1[1, 0] * R2[0, 0] + R1[0, 1] * R2[1, 1] - R1[1, 1] * R2[0, 1]
	y = R1[0, 0] * R2[1, 1] - R1[1, 0] * R2[0, 1] - R1[0, 1] * R2[1, 0] + R1[1, 1] * R2[0, 0]
	dz = np.arctan(x / y)
	k1, k2 = 25.0, 0.1
	self._wz = k1 * dz * np.exp(-k2 * np.linalg.norm(self._homo_delta))
	# print(' -> x: {:.4f}, y: {:.4f}, dz: {:.4f}, wz: {:.4f}'.format(x, y, dz, self._wz))

	# Pseudo Solution
	d = self._tip_offset
	Jd = np.matmul(self._eRc,
	np.array([[0, 0, d, 0],
	[0, -d, 0, 0],
	[1, 0, 0, 0]]))
	Je = np.matmul(self._eRc,
	np.array([[0, 1, 0, 0],
	[0, 0, 1, 0],
	[0, 0, 0, 1]]))

	eVe4 = np.dot(np.linalg.pinv(Jd), cVc) \
	+ np.dot(np.dot((np.eye(4) - np.dot(np.linalg.pinv(Jd), Jd)), np.linalg.pinv(Je)),
	np.array([[0], [0], [self._wz]]))
	eVe = np.zeros((6, 1))
	eVe[2: 6] = eVe4[0: 4]
	Q = np.zeros((6, 6))
	Q[0: 3, 0: 3] = - bRe
	Q[3: 6, 3: 6] = - bRe
	bVe = np.dot(Q, eVe)

	# Compute the Jacobian matrix
	bJe = self.get_jacobian_spatial()
	dq = np.dot(np.linalg.pinv(bJe), bVe)
	# print(" -> cVc: {}, q: {}, dq: {}".format(list(np.round(cVc.flatten(), 4)), q, list(dq.flatten())))
	return dq.flatten()

	def render_image(self, width=RENDER_WIDTH, height=RENDER_HEIGHT):
	pos_eef, orn_eef = get_link_pose(self.body, self.EEF_LINK_INDEX)
	pos_tip = get_link_pose(self.body, self.TIP_LINK_INDEX)[0]
	mat_eef = np.array(p.getMatrixFromQuaternion(orn_eef)).reshape((3, 3))

	# TODO: need to check the up vector
	self.view_matrix = p.computeViewMatrix(cameraEyePosition=pos_eef,
	cameraTargetPosition=pos_tip,
	cameraUpVector=mat_eef[:, 0])
	self.proj_matrix = p.computeProjectionMatrixFOV(fov=FoV,
	aspect=float(width) / height,
	nearVal=0.01,
	farVal=10.0)

	rgb_array, mask, depth = render_image(width, height,
	self.view_matrix, self.proj_matrix)
	return rgb_array, mask, depth

	def get_centroid_proj(self, pos) -> np.ndarray:
	"""
	Compute the object position in the camera NDC space.
	Refer to OpenGL.
	:param pos: object position in the world frame.
	"""
	assert len(pos) in (3, 4)
	if len(pos) == 3:
	# homogeneous coordinates: (x, y, z) -> (x, y, z, w)
	pos_obj = np.ones((4, 1))
	pos_obj[: 3, 0] = pos
	else:
	pos_obj = np.array(pos).reshape((4, 1))

	view_matrix = np.array(self.view_matrix).reshape(4, 4).T
	proj_matrix = np.array(self.proj_matrix).reshape(4, 4).T
	# pos in the camera frame
	pos_cam = np.dot(proj_matrix, np.dot(view_matrix, pos_obj))
	pos_cam /= pos_cam[3, 0]
	return np.array([pos_cam[0][0], - pos_cam[1][0]]) # be consistent with get_centroid

	@property
	def homo_delta(self):
	return self._homo_delta

	@homo_delta.setter
	def homo_delta(self, val: np.ndarray):
	self._homo_delta = val

	@property
	def wz(self):
	return self._wz