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remove obsolete deep_mimic files (use the one in deep_mimic/env)

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add plane_implicit.urdf
This commit is contained in:
erwincoumans
2019-02-10 21:04:28 -08:00
parent 9bddca873c
commit be20ed6aa2
5 changed files with 31 additions and 1066 deletions
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31
examples/pybullet/gym/pybullet_data/plane_implicit.urdf Normal file
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<?xml version="1.0" ?>
<robot name="plane">
<link name="planeLink">
<contact>
<lateral_friction value="0.9"/>
</contact>
<inertial>
<origin rpy="0 0 0" xyz="0 0 0"/>
<mass value=".0"/>
<inertia ixx="0" ixy="0" ixz="0" iyy="0" iyz="0" izz="0"/>
</inertial>
<visual>
<origin rpy="0 0 0" xyz="0 0 0"/>
<geometry>
<mesh filename="plane100.obj" scale="1 1 1"/>
</geometry>
<material name="white">
<color rgba="1 1 1 1"/>
</material>
</visual>
<collision>
<origin rpy="0 0 0" xyz="0 0 0"/>
<!--<origin rpy="0 0 0" xyz="0 0 -5"/>-->
<geometry>
<plane normal="0 0 1"/>
<!--<box size="100 100 10"/>-->
</geometry>
</collision>
</link>
</robot>

683
examples/pybullet/gym/pybullet_envs/deep_mimic/humanoid.py
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import os, inspect
import math
currentdir = os.path.dirname(os.path.abspath(inspect.getfile(inspect.currentframe())))
parentdir = os.path.dirname(os.path.dirname(currentdir))
os.sys.path.insert(0,parentdir)
from pybullet_utils.bullet_client import BulletClient
import pybullet_data
jointTypes = ["JOINT_REVOLUTE","JOINT_PRISMATIC",
"JOINT_SPHERICAL","JOINT_PLANAR","JOINT_FIXED"]
class HumanoidPose(object):
def __init__(self):
pass
def Reset(self):
self._basePos = [0,0,0]
self._baseLinVel = [0,0,0]
self._baseOrn = [0,0,0,1]
self._baseAngVel = [0,0,0]
self._chestRot = [0,0,0,1]
self._chestVel = [0,0,0]
self._neckRot = [0,0,0,1]
self._neckVel = [0,0,0]
self._rightHipRot = [0,0,0,1]
self._rightHipVel = [0,0,0]
self._rightKneeRot = [0]
self._rightKneeVel = [0]
self._rightAnkleRot = [0,0,0,1]
self._rightAnkleVel = [0,0,0]
self._rightShoulderRot = [0,0,0,1]
self._rightShoulderVel = [0,0,0]
self._rightElbowRot = [0]
self._rightElbowVel = [0]
self._leftHipRot = [0,0,0,1]
self._leftHipVel = [0,0,0]
self._leftKneeRot = [0]
self._leftKneeVel = [0]
self._leftAnkleRot = [0,0,0,1]
self._leftAnkleVel = [0,0,0]
self._leftShoulderRot = [0,0,0,1]
self._leftShoulderVel = [0,0,0]
self._leftElbowRot = [0]
self._leftElbowVel = [0]
def ComputeLinVel(self,posStart, posEnd, deltaTime):
vel = [(posEnd[0]-posStart[0])/deltaTime,(posEnd[1]-posStart[1])/deltaTime,(posEnd[2]-posStart[2])/deltaTime]
return vel
def ComputeAngVel(self,ornStart, ornEnd, deltaTime, bullet_client):
dorn = bullet_client.getDifferenceQuaternion(ornStart,ornEnd)
axis,angle = bullet_client.getAxisAngleFromQuaternion(dorn)
angVel = [(axis[0]*angle)/deltaTime,(axis[1]*angle)/deltaTime,(axis[2]*angle)/deltaTime]
return angVel
def NormalizeQuaternion(self, orn):
length2 = orn[0]*orn[0]+orn[1]*orn[1]+orn[2]*orn[2]+orn[3]*orn[3]
if (length2>0):
length = math.sqrt(length2)
#print("Normalize? length=",length)
def PostProcessMotionData(self, frameData):
baseOrn1Start = [frameData[5],frameData[6], frameData[7],frameData[4]]
self.NormalizeQuaternion(baseOrn1Start)
chestRotStart = [frameData[9],frameData[10],frameData[11],frameData[8]]
neckRotStart = [frameData[13],frameData[14],frameData[15],frameData[12]]
rightHipRotStart = [frameData[17],frameData[18],frameData[19],frameData[16]]
rightAnkleRotStart = [frameData[22],frameData[23],frameData[24],frameData[21]]
rightShoulderRotStart = [frameData[26],frameData[27],frameData[28],frameData[25]]
leftHipRotStart = [frameData[31],frameData[32],frameData[33],frameData[30]]
leftAnkleRotStart = [frameData[36],frameData[37],frameData[38],frameData[35]]
leftShoulderRotStart = [frameData[40],frameData[41],frameData[42],frameData[39]]
def Slerp(self, frameFraction, frameData, frameDataNext,bullet_client ):
keyFrameDuration = frameData[0]
basePos1Start = [frameData[1],frameData[2],frameData[3]]
basePos1End = [frameDataNext[1],frameDataNext[2],frameDataNext[3]]
self._basePos = [basePos1Start[0]+frameFraction*(basePos1End[0]-basePos1Start[0]),
basePos1Start[1]+frameFraction*(basePos1End[1]-basePos1Start[1]),
basePos1Start[2]+frameFraction*(basePos1End[2]-basePos1Start[2])]
self._baseLinVel = self.ComputeLinVel(basePos1Start,basePos1End, keyFrameDuration)
baseOrn1Start = [frameData[5],frameData[6], frameData[7],frameData[4]]
baseOrn1Next = [frameDataNext[5],frameDataNext[6], frameDataNext[7],frameDataNext[4]]
self._baseOrn = bullet_client.getQuaternionSlerp(baseOrn1Start,baseOrn1Next,frameFraction)
self._baseAngVel = self.ComputeAngVel(baseOrn1Start,baseOrn1Next, keyFrameDuration, bullet_client)
##pre-rotate to make z-up
#y2zPos=[0,0,0.0]
#y2zOrn = p.getQuaternionFromEuler([1.57,0,0])
#basePos,baseOrn = p.multiplyTransforms(y2zPos, y2zOrn,basePos1,baseOrn1)
chestRotStart = [frameData[9],frameData[10],frameData[11],frameData[8]]
chestRotEnd = [frameDataNext[9],frameDataNext[10],frameDataNext[11],frameDataNext[8]]
self._chestRot = bullet_client.getQuaternionSlerp(chestRotStart,chestRotEnd,frameFraction)
self._chestVel = self.ComputeAngVel(chestRotStart,chestRotEnd,keyFrameDuration,bullet_client)
neckRotStart = [frameData[13],frameData[14],frameData[15],frameData[12]]
neckRotEnd= [frameDataNext[13],frameDataNext[14],frameDataNext[15],frameDataNext[12]]
self._neckRot = bullet_client.getQuaternionSlerp(neckRotStart,neckRotEnd,frameFraction)
self._neckVel = self.ComputeAngVel(neckRotStart,neckRotEnd,keyFrameDuration,bullet_client)
rightHipRotStart = [frameData[17],frameData[18],frameData[19],frameData[16]]
rightHipRotEnd = [frameDataNext[17],frameDataNext[18],frameDataNext[19],frameDataNext[16]]
self._rightHipRot = bullet_client.getQuaternionSlerp(rightHipRotStart,rightHipRotEnd,frameFraction)
self._rightHipVel = self.ComputeAngVel(rightHipRotStart,rightHipRotEnd,keyFrameDuration,bullet_client)
rightKneeRotStart = [frameData[20]]
rightKneeRotEnd = [frameDataNext[20]]
self._rightKneeRot = [rightKneeRotStart[0]+frameFraction*(rightKneeRotEnd[0]-rightKneeRotStart[0])]
self._rightKneeVel = [(rightKneeRotEnd[0]-rightKneeRotStart[0])/keyFrameDuration]
rightAnkleRotStart = [frameData[22],frameData[23],frameData[24],frameData[21]]
rightAnkleRotEnd = [frameDataNext[22],frameDataNext[23],frameDataNext[24],frameDataNext[21]]
self._rightAnkleRot = bullet_client.getQuaternionSlerp(rightAnkleRotStart,rightAnkleRotEnd,frameFraction)
self._rightAnkleVel = self.ComputeAngVel(rightAnkleRotStart,rightAnkleRotEnd,keyFrameDuration,bullet_client)
rightShoulderRotStart = [frameData[26],frameData[27],frameData[28],frameData[25]]
rightShoulderRotEnd = [frameDataNext[26],frameDataNext[27],frameDataNext[28],frameDataNext[25]]
self._rightShoulderRot = bullet_client.getQuaternionSlerp(rightShoulderRotStart,rightShoulderRotEnd,frameFraction)
self._rightShoulderVel = self.ComputeAngVel(rightShoulderRotStart,rightShoulderRotEnd, keyFrameDuration,bullet_client)
rightElbowRotStart = [frameData[29]]
rightElbowRotEnd = [frameDataNext[29]]
self._rightElbowRot = [rightElbowRotStart[0]+frameFraction*(rightElbowRotEnd[0]-rightElbowRotStart[0])]
self._rightElbowVel = [(rightElbowRotEnd[0]-rightElbowRotStart[0])/keyFrameDuration]
leftHipRotStart = [frameData[31],frameData[32],frameData[33],frameData[30]]
leftHipRotEnd = [frameDataNext[31],frameDataNext[32],frameDataNext[33],frameDataNext[30]]
self._leftHipRot = bullet_client.getQuaternionSlerp(leftHipRotStart,leftHipRotEnd,frameFraction)
self._leftHipVel = self.ComputeAngVel(leftHipRotStart, leftHipRotEnd,keyFrameDuration,bullet_client)
leftKneeRotStart = [frameData[34]]
leftKneeRotEnd = [frameDataNext[34]]
self._leftKneeRot = [leftKneeRotStart[0] +frameFraction*(leftKneeRotEnd[0]-leftKneeRotStart[0]) ]
self._leftKneeVel = [(leftKneeRotEnd[0]-leftKneeRotStart[0])/keyFrameDuration]
leftAnkleRotStart = [frameData[36],frameData[37],frameData[38],frameData[35]]
leftAnkleRotEnd = [frameDataNext[36],frameDataNext[37],frameDataNext[38],frameDataNext[35]]
self._leftAnkleRot = bullet_client.getQuaternionSlerp(leftAnkleRotStart,leftAnkleRotEnd,frameFraction)
self._leftAnkleVel = self.ComputeAngVel(leftAnkleRotStart,leftAnkleRotEnd,keyFrameDuration,bullet_client)
leftShoulderRotStart = [frameData[40],frameData[41],frameData[42],frameData[39]]
leftShoulderRotEnd = [frameDataNext[40],frameDataNext[41],frameDataNext[42],frameDataNext[39]]
self._leftShoulderRot = bullet_client.getQuaternionSlerp(leftShoulderRotStart,leftShoulderRotEnd,frameFraction)
self._leftShoulderVel = self.ComputeAngVel(leftShoulderRotStart,leftShoulderRotEnd,keyFrameDuration,bullet_client)
leftElbowRotStart = [frameData[43]]
leftElbowRotEnd = [frameDataNext[43]]
self._leftElbowRot = [leftElbowRotStart[0]+frameFraction*(leftElbowRotEnd[0]-leftElbowRotStart[0])]
self._leftElbowVel = [(leftElbowRotEnd[0]-leftElbowRotStart[0])/keyFrameDuration]
class Humanoid(object):
def __init__(self, pybullet_client, motion_data, baseShift):
"""Constructs a humanoid and reset it to the initial states.
Args:
pybullet_client: The instance of BulletClient to manage different
simulations.
"""
self._baseShift = baseShift
self._pybullet_client = pybullet_client
self.kin_client = BulletClient(pybullet_client.DIRECT)# use SHARED_MEMORY for visual debugging, start a GUI physics server first
self.kin_client.resetSimulation()
self.kin_client.setAdditionalSearchPath(pybullet_data.getDataPath())
self.kin_client.configureDebugVisualizer(self.kin_client.COV_ENABLE_Y_AXIS_UP,1)
self.kin_client.setGravity(0,-9.8,0)
self._motion_data = motion_data
print("LOADING humanoid!")
self._humanoid = self._pybullet_client.loadURDF(
"humanoid/humanoid.urdf", [0,0.9,0],globalScaling=0.25, useFixedBase=False)
self._kinematicHumanoid = self.kin_client.loadURDF(
"humanoid/humanoid.urdf", [0,0.9,0],globalScaling=0.25, useFixedBase=False)
#print("human #joints=", self._pybullet_client.getNumJoints(self._humanoid))
pose = HumanoidPose()
for i in range (self._motion_data.NumFrames()-1):
frameData = self._motion_data._motion_data['Frames'][i]
pose.PostProcessMotionData(frameData)
self._pybullet_client.resetBasePositionAndOrientation(self._humanoid,self._baseShift,[0,0,0,1])
self._pybullet_client.changeDynamics(self._humanoid, -1, linearDamping=0, angularDamping=0)
for j in range (self._pybullet_client.getNumJoints(self._humanoid)):
ji = self._pybullet_client.getJointInfo(self._humanoid,j)
self._pybullet_client.changeDynamics(self._humanoid, j, linearDamping=0, angularDamping=0)
self._pybullet_client.changeVisualShape(self._humanoid, j , rgbaColor=[1,1,1,1])
#print("joint[",j,"].type=",jointTypes[ji[2]])
#print("joint[",j,"].name=",ji[1])
self._initial_state = self._pybullet_client.saveState()
self._allowed_body_parts=[11,14]
self.Reset()
def Reset(self):
self._pybullet_client.restoreState(self._initial_state)
self.SetSimTime(0)
pose = self.InitializePoseFromMotionData()
self.ApplyPose(pose, True, True, self._humanoid, self._pybullet_client)
def CalcCycleCount(self, simTime, cycleTime):
phases = simTime / cycleTime;
count = math.floor(phases)
loop = True
#count = (loop) ? count : cMathUtil::Clamp(count, 0, 1);
return count
def SetSimTime(self, t):
self._simTime = t
#print("SetTimeTime time =",t)
keyFrameDuration = self._motion_data.KeyFrameDuraction()
cycleTime = keyFrameDuration*(self._motion_data.NumFrames()-1)
#print("self._motion_data.NumFrames()=",self._motion_data.NumFrames())
#print("cycleTime=",cycleTime)
cycles = self.CalcCycleCount(t, cycleTime)
#print("cycles=",cycles)
frameTime = t - cycles*cycleTime
if (frameTime<0):
frameTime += cycleTime
#print("keyFrameDuration=",keyFrameDuration)
#print("frameTime=",frameTime)
self._frame = int(frameTime/keyFrameDuration)
#print("self._frame=",self._frame)
self._frameNext = self._frame+1
if (self._frameNext >= self._motion_data.NumFrames()):
self._frameNext = self._frame
self._frameFraction = (frameTime - self._frame*keyFrameDuration)/(keyFrameDuration)
#print("self._frameFraction=",self._frameFraction)
def Terminates(self):
#check if any non-allowed body part hits the ground
terminates=False
pts = self._pybullet_client.getContactPoints()
for p in pts:
part = -1
if (p[1]==self._humanoid):
part=p[3]
if (p[2]==self._humanoid):
part=p[4]
if (part >=0 and part not in self._allowed_body_parts):
terminates=True
return terminates
def BuildHeadingTrans(self, rootOrn):
#align root transform 'forward' with world-space x axis
eul = self._pybullet_client.getEulerFromQuaternion(rootOrn)
refDir = [1,0,0]
rotVec = self._pybullet_client.rotateVector(rootOrn, refDir)
heading = math.atan2(-rotVec[2], rotVec[0])
heading2=eul[1]
#print("heading=",heading)
headingOrn = self._pybullet_client.getQuaternionFromAxisAngle([0,1,0],-heading)
return headingOrn
def GetPhase(self):
keyFrameDuration = self._motion_data.KeyFrameDuraction()
cycleTime = keyFrameDuration*(self._motion_data.NumFrames()-1)
phase = self._simTime / cycleTime
phase = math.fmod(phase,1.0)
if (phase<0):
phase += 1
return phase
def BuildOriginTrans(self):
rootPos,rootOrn = self._pybullet_client.getBasePositionAndOrientation(self._humanoid)
#print("rootPos=",rootPos, " rootOrn=",rootOrn)
invRootPos=[-rootPos[0], 0, -rootPos[2]]
#invOrigTransPos, invOrigTransOrn = self._pybullet_client.invertTransform(rootPos,rootOrn)
headingOrn = self.BuildHeadingTrans(rootOrn)
#print("headingOrn=",headingOrn)
headingMat = self._pybullet_client.getMatrixFromQuaternion(headingOrn)
#print("headingMat=",headingMat)
#dummy, rootOrnWithoutHeading = self._pybullet_client.multiplyTransforms([0,0,0],headingOrn, [0,0,0], rootOrn)
#dummy, invOrigTransOrn = self._pybullet_client.multiplyTransforms([0,0,0],rootOrnWithoutHeading, invOrigTransPos, invOrigTransOrn)
invOrigTransPos, invOrigTransOrn = self._pybullet_client.multiplyTransforms( [0,0,0],headingOrn, invRootPos,[0,0,0,1])
#print("invOrigTransPos=",invOrigTransPos)
#print("invOrigTransOrn=",invOrigTransOrn)
invOrigTransMat = self._pybullet_client.getMatrixFromQuaternion(invOrigTransOrn)
#print("invOrigTransMat =",invOrigTransMat )
return invOrigTransPos, invOrigTransOrn
def InitializePoseFromMotionData(self):
frameData = self._motion_data._motion_data['Frames'][self._frame]
frameDataNext = self._motion_data._motion_data['Frames'][self._frameNext]
pose = HumanoidPose()
pose.Slerp(self._frameFraction, frameData, frameDataNext, self._pybullet_client)
return pose
def ApplyAction(self, action):
#turn action into pose
pose = HumanoidPose()
pose.Reset()
index=0
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._chestRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
#print("pose._chestRot=",pose._chestRot)
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._neckRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._rightHipRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
index+=1
pose._rightKneeRot = [angle]
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._rightAnkleRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._rightShoulderRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
index+=1
pose._rightElbowRot = [angle]
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._leftHipRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
index+=1
pose._leftKneeRot = [angle]
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._leftAnkleRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
axis = [action[index+1],action[index+2],action[index+3]]
index+=4
pose._leftShoulderRot = self._pybullet_client.getQuaternionFromAxisAngle(axis,angle)
angle = action[index]
index+=1
pose._leftElbowRot = [angle]
#print("index=",index)
initializeBase = False
initializeVelocities = False
self.ApplyPose(pose, initializeBase, initializeVelocities, self._humanoid, self._pybullet_client)
def ApplyPose(self, pose, initializeBase, initializeVelocities, humanoid,bc):
#todo: get tunable parametes from a json file or from URDF (kd, maxForce)
if (initializeBase):
bc.changeVisualShape(humanoid, 2 , rgbaColor=[1,0,0,1])
basePos=[pose._basePos[0]+self._baseShift[0],pose._basePos[1]+self._baseShift[1],pose._basePos[2]+self._baseShift[2]]
bc.resetBasePositionAndOrientation(humanoid,
basePos, pose._baseOrn)
if initializeVelocities:
bc.resetBaseVelocity(humanoid, pose._baseLinVel, pose._baseAngVel)
#print("resetBaseVelocity=",pose._baseLinVel)
else:
bc.changeVisualShape(humanoid, 2 , rgbaColor=[1,1,1,1])
kp=0.03
chest=1
neck=2
rightShoulder=3
rightElbow=4
leftShoulder=6
leftElbow = 7
rightHip = 9
rightKnee=10
rightAnkle=11
leftHip = 12
leftKnee=13
leftAnkle=14
controlMode = bc.POSITION_CONTROL
if (initializeBase):
if initializeVelocities:
bc.resetJointStateMultiDof(humanoid,chest,pose._chestRot, pose._chestVel)
bc.resetJointStateMultiDof(humanoid,neck,pose._neckRot, pose._neckVel)
bc.resetJointStateMultiDof(humanoid,rightHip,pose._rightHipRot, pose._rightHipVel)
bc.resetJointStateMultiDof(humanoid,rightKnee,pose._rightKneeRot, pose._rightKneeVel)
bc.resetJointStateMultiDof(humanoid,rightAnkle,pose._rightAnkleRot, pose._rightAnkleVel)
bc.resetJointStateMultiDof(humanoid,rightShoulder,pose._rightShoulderRot, pose._rightShoulderVel)
bc.resetJointStateMultiDof(humanoid,rightElbow, pose._rightElbowRot, pose._rightElbowVel)
bc.resetJointStateMultiDof(humanoid,leftHip, pose._leftHipRot, pose._leftHipVel)
bc.resetJointStateMultiDof(humanoid,leftKnee, pose._leftKneeRot, pose._leftKneeVel)
bc.resetJointStateMultiDof(humanoid,leftAnkle, pose._leftAnkleRot, pose._leftAnkleVel)
bc.resetJointStateMultiDof(humanoid,leftShoulder, pose._leftShoulderRot, pose._leftShoulderVel)
bc.resetJointStateMultiDof(humanoid,leftElbow, pose._leftElbowRot, pose._leftElbowVel)
else:
bc.resetJointStateMultiDof(humanoid,chest,pose._chestRot)
bc.resetJointStateMultiDof(humanoid,neck,pose._neckRot)
bc.resetJointStateMultiDof(humanoid,rightHip,pose._rightHipRot)
bc.resetJointStateMultiDof(humanoid,rightKnee,pose._rightKneeRot)
bc.resetJointStateMultiDof(humanoid,rightAnkle,pose._rightAnkleRot)
bc.resetJointStateMultiDof(humanoid,rightShoulder,pose._rightShoulderRot)
bc.resetJointStateMultiDof(humanoid,rightElbow, pose._rightElbowRot)
bc.resetJointStateMultiDof(humanoid,leftHip, pose._leftHipRot)
bc.resetJointStateMultiDof(humanoid,leftKnee, pose._leftKneeRot)
bc.resetJointStateMultiDof(humanoid,leftAnkle, pose._leftAnkleRot)
bc.resetJointStateMultiDof(humanoid,leftShoulder, pose._leftShoulderRot)
bc.resetJointStateMultiDof(humanoid,leftElbow, pose._leftElbowRot)
bc.setJointMotorControlMultiDof(humanoid,chest,controlMode, targetPosition=pose._chestRot,positionGain=kp, force=[200])
bc.setJointMotorControlMultiDof(humanoid,neck,controlMode,targetPosition=pose._neckRot,positionGain=kp, force=[50])
bc.setJointMotorControlMultiDof(humanoid,rightHip,controlMode,targetPosition=pose._rightHipRot,positionGain=kp, force=[200])
bc.setJointMotorControlMultiDof(humanoid,rightKnee,controlMode,targetPosition=pose._rightKneeRot,positionGain=kp, force=[150])
bc.setJointMotorControlMultiDof(humanoid,rightAnkle,controlMode,targetPosition=pose._rightAnkleRot,positionGain=kp, force=[90])
bc.setJointMotorControlMultiDof(humanoid,rightShoulder,controlMode,targetPosition=pose._rightShoulderRot,positionGain=kp, force=[100])
bc.setJointMotorControlMultiDof(humanoid,rightElbow, controlMode,targetPosition=pose._rightElbowRot,positionGain=kp, force=[60])
bc.setJointMotorControlMultiDof(humanoid,leftHip, controlMode,targetPosition=pose._leftHipRot,positionGain=kp, force=[200])
bc.setJointMotorControlMultiDof(humanoid,leftKnee, controlMode,targetPosition=pose._leftKneeRot,positionGain=kp, force=[150])
bc.setJointMotorControlMultiDof(humanoid,leftAnkle, controlMode,targetPosition=pose._leftAnkleRot,positionGain=kp, force=[90])
bc.setJointMotorControlMultiDof(humanoid,leftShoulder, controlMode,targetPosition=pose._leftShoulderRot,positionGain=kp, force=[100])
bc.setJointMotorControlMultiDof(humanoid,leftElbow, controlMode,targetPosition=pose._leftElbowRot,positionGain=kp, force=[60])
#debug space
#if (False):
# for j in range (bc.getNumJoints(self._humanoid)):
# js = bc.getJointState(self._humanoid, j)
# bc.resetJointState(self._humanoidDebug, j,js[0])
# jsm = bc.getJointStateMultiDof(self._humanoid, j)
# if (len(jsm[0])>0):
# bc.resetJointStateMultiDof(self._humanoidDebug,j,jsm[0])
def GetState(self):
stateVector = []
phase = self.GetPhase()
#print("phase=",phase)
stateVector.append(phase)
rootTransPos, rootTransOrn=self.BuildOriginTrans()
basePos,baseOrn = self._pybullet_client.getBasePositionAndOrientation(self._humanoid)
rootPosRel, dummy = self._pybullet_client.multiplyTransforms(rootTransPos, rootTransOrn, basePos,[0,0,0,1])
#print("!!!rootPosRel =",rootPosRel )
#print("rootTransPos=",rootTransPos)
#print("basePos=",basePos)
localPos,localOrn = self._pybullet_client.multiplyTransforms( rootTransPos, rootTransOrn , basePos,baseOrn )
localPos=[localPos[0]-rootPosRel[0],localPos[1]-rootPosRel[1],localPos[2]-rootPosRel[2]]
#print("localPos=",localPos)
stateVector.append(rootPosRel[1])
self.pb2dmJoints=[0,1,2,9,10,11,3,4,5,12,13,14,6,7,8]
for pbJoint in range (self._pybullet_client.getNumJoints(self._humanoid)):
j = self.pb2dmJoints[pbJoint]
#print("joint order:",j)
ls = self._pybullet_client.getLinkState(self._humanoid, j, computeForwardKinematics=True)
linkPos = ls[0]
linkOrn = ls[1]
linkPosLocal, linkOrnLocal = self._pybullet_client.multiplyTransforms(rootTransPos, rootTransOrn, linkPos,linkOrn)
if (linkOrnLocal[3]<0):
linkOrnLocal=[-linkOrnLocal[0],-linkOrnLocal[1],-linkOrnLocal[2],-linkOrnLocal[3]]
linkPosLocal=[linkPosLocal[0]-rootPosRel[0],linkPosLocal[1]-rootPosRel[1],linkPosLocal[2]-rootPosRel[2]]
for l in linkPosLocal:
stateVector.append(l)
#re-order the quaternion, DeepMimic uses w,x,y,z
stateVector.append(linkOrnLocal[3])
stateVector.append(linkOrnLocal[0])
stateVector.append(linkOrnLocal[1])
stateVector.append(linkOrnLocal[2])
for pbJoint in range (self._pybullet_client.getNumJoints(self._humanoid)):
j = self.pb2dmJoints[pbJoint]
ls = self._pybullet_client.getLinkState(self._humanoid, j, computeLinkVelocity=True)
linkLinVel = ls[6]
linkAngVel = ls[7]
for l in linkLinVel:
stateVector.append(l)
for l in linkAngVel:
stateVector.append(l)
#print("stateVector len=",len(stateVector))
#for st in range (len(stateVector)):
# print("state[",st,"]=",stateVector[st])
return stateVector
def GetReward(self):
#from DeepMimic double cSceneImitate::CalcRewardImitate
pose_w = 0.5
vel_w = 0.05
end_eff_w = 0 #0.15
root_w = 0 #0.2
com_w = 0.1
total_w = pose_w + vel_w + end_eff_w + root_w + com_w
pose_w /= total_w
vel_w /= total_w
end_eff_w /= total_w
root_w /= total_w
com_w /= total_w
pose_scale = 2
vel_scale = 0.1
end_eff_scale = 40
root_scale = 5
com_scale = 10
err_scale = 1
reward = 0
pose_err = 0
vel_err = 0
end_eff_err = 0
root_err = 0
com_err = 0
heading_err = 0
#create a mimic reward, comparing the dynamics humanoid with a kinematic one
pose = self.InitializePoseFromMotionData()
#print("self._kinematicHumanoid=",self._kinematicHumanoid)
#print("kinematicHumanoid #joints=",self.kin_client.getNumJoints(self._kinematicHumanoid))
self.ApplyPose(pose, True, True, self._kinematicHumanoid, self.kin_client)
#const Eigen::VectorXd& pose0 = sim_char.GetPose();
#const Eigen::VectorXd& vel0 = sim_char.GetVel();
#const Eigen::VectorXd& pose1 = kin_char.GetPose();
#const Eigen::VectorXd& vel1 = kin_char.GetVel();
#tMatrix origin_trans = sim_char.BuildOriginTrans();
#tMatrix kin_origin_trans = kin_char.BuildOriginTrans();
#
#tVector com0_world = sim_char.CalcCOM();
#tVector com_vel0_world = sim_char.CalcCOMVel();
#tVector com1_world;
#tVector com_vel1_world;
#cRBDUtil::CalcCoM(joint_mat, body_defs, pose1, vel1, com1_world, com_vel1_world);
#
root_id = 0
#tVector root_pos0 = cKinTree::GetRootPos(joint_mat, pose0);
#tVector root_pos1 = cKinTree::GetRootPos(joint_mat, pose1);
#tQuaternion root_rot0 = cKinTree::GetRootRot(joint_mat, pose0);
#tQuaternion root_rot1 = cKinTree::GetRootRot(joint_mat, pose1);
#tVector root_vel0 = cKinTree::GetRootVel(joint_mat, vel0);
#tVector root_vel1 = cKinTree::GetRootVel(joint_mat, vel1);
#tVector root_ang_vel0 = cKinTree::GetRootAngVel(joint_mat, vel0);
#tVector root_ang_vel1 = cKinTree::GetRootAngVel(joint_mat, vel1);
mJointWeights = [0.20833,0.10416, 0.0625, 0.10416,
0.0625, 0.041666666666666671, 0.0625, 0.0416,
0.00, 0.10416, 0.0625, 0.0416, 0.0625, 0.0416, 0.0000]
num_end_effs = 0
num_joints = 15
root_rot_w = mJointWeights[root_id]
#pose_err += root_rot_w * cKinTree::CalcRootRotErr(joint_mat, pose0, pose1)
#vel_err += root_rot_w * cKinTree::CalcRootAngVelErr(joint_mat, vel0, vel1)
for j in range (num_joints):
curr_pose_err = 0
curr_vel_err = 0
w = mJointWeights[j];
simJointInfo = self._pybullet_client.getJointStateMultiDof(self._humanoid, j)
#print("simJointInfo.pos=",simJointInfo[0])
#print("simJointInfo.vel=",simJointInfo[1])
kinJointInfo = self.kin_client.getJointStateMultiDof(self._kinematicHumanoid,j)
#print("kinJointInfo.pos=",kinJointInfo[0])
#print("kinJointInfo.vel=",kinJointInfo[1])
if (len(simJointInfo[0])==1):
angle = simJointInfo[0][0]-kinJointInfo[0][0]
curr_pose_err = angle*angle
velDiff = simJointInfo[1][0]-kinJointInfo[1][0]
curr_vel_err = velDiff*velDiff
if (len(simJointInfo[0])==4):
#print("quaternion diff")
diffQuat = self._pybullet_client.getDifferenceQuaternion(simJointInfo[0],kinJointInfo[0])
axis,angle = self._pybullet_client.getAxisAngleFromQuaternion(diffQuat)
curr_pose_err = angle*angle
diffVel = [simJointInfo[1][0]-kinJointInfo[1][0],simJointInfo[1][1]-kinJointInfo[1][1],simJointInfo[1][2]-kinJointInfo[1][2]]
curr_vel_err = diffVel[0]*diffVel[0]+diffVel[1]*diffVel[1]+diffVel[2]*diffVel[2]
pose_err += w * curr_pose_err
vel_err += w * curr_vel_err
# bool is_end_eff = sim_char.IsEndEffector(j)
# if (is_end_eff)
# {
# tVector pos0 = sim_char.CalcJointPos(j)
# tVector pos1 = cKinTree::CalcJointWorldPos(joint_mat, pose1, j)
# double ground_h0 = mGround->SampleHeight(pos0)
# double ground_h1 = kin_char.GetOriginPos()[1]
#
# tVector pos_rel0 = pos0 - root_pos0
# tVector pos_rel1 = pos1 - root_pos1
# pos_rel0[1] = pos0[1] - ground_h0
# pos_rel1[1] = pos1[1] - ground_h1
#
# pos_rel0 = origin_trans * pos_rel0
# pos_rel1 = kin_origin_trans * pos_rel1
#
# curr_end_err = (pos_rel1 - pos_rel0).squaredNorm()
# end_eff_err += curr_end_err;
# ++num_end_effs;
# }
#}
#if (num_end_effs > 0):
# end_eff_err /= num_end_effs
#
#double root_ground_h0 = mGround->SampleHeight(sim_char.GetRootPos())
#double root_ground_h1 = kin_char.GetOriginPos()[1]
#root_pos0[1] -= root_ground_h0
#root_pos1[1] -= root_ground_h1
#root_pos_err = (root_pos0 - root_pos1).squaredNorm()
#
#root_rot_err = cMathUtil::QuatDiffTheta(root_rot0, root_rot1)
#root_rot_err *= root_rot_err
#root_vel_err = (root_vel1 - root_vel0).squaredNorm()
#root_ang_vel_err = (root_ang_vel1 - root_ang_vel0).squaredNorm()
#root_err = root_pos_err
# + 0.1 * root_rot_err
# + 0.01 * root_vel_err
# + 0.001 * root_ang_vel_err
#com_err = 0.1 * (com_vel1_world - com_vel0_world).squaredNorm()
#print("pose_err=",pose_err)
#print("vel_err=",vel_err)
pose_reward = math.exp(-err_scale * pose_scale * pose_err)
vel_reward = math.exp(-err_scale * vel_scale * vel_err)
end_eff_reward = math.exp(-err_scale * end_eff_scale * end_eff_err)
root_reward = math.exp(-err_scale * root_scale * root_err)
com_reward = math.exp(-err_scale * com_scale * com_err)
reward = pose_w * pose_reward + vel_w * vel_reward + end_eff_w * end_eff_reward + root_w * root_reward + com_w * com_reward
#print("reward = %f (pose_reward=%f, vel_reward=%f, end_eff_reward=%f, root_reward=%f, com_reward=%f)\n", reward,
# pose_reward,vel_reward,end_eff_reward, root_reward, com_reward);
return reward
def GetBasePosition(self):
pos,orn = self._pybullet_client.getBasePositionAndOrientation(self._humanoid)
return pos

277
examples/pybullet/gym/pybullet_envs/deep_mimic/humanoid_deepmimic_gym_env.py
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@@ -1,277 +0,0 @@
"""This file implements the gym environment of humanoid deepmimic using PyBullet.
"""
import math
import time
import os, inspect
currentdir = os.path.dirname(os.path.abspath(inspect.getfile(inspect.currentframe())))
parentdir = os.path.dirname(os.path.dirname(currentdir))
os.sys.path.insert(0,parentdir)
import gym
from gym import spaces
from gym.utils import seeding
import random
import numpy as np
import pybullet
import pybullet_data
from pybullet_envs.deep_mimic.humanoid import Humanoid
from pkg_resources import parse_version
from pybullet_utils import bullet_client
from pybullet_envs.deep_mimic.motion_capture_data import MotionCaptureData
RENDER_HEIGHT = 360
RENDER_WIDTH = 480
class HumanoidDeepMimicGymEnv(gym.Env):
"""The gym environment for the humanoid deep mimic.
"""
metadata = {
"render.modes": ["human", "rgb_array"],
"video.frames_per_second": 100
}
def __init__(self,
urdf_root=pybullet_data.getDataPath(),
render=False):
"""Initialize the gym environment.
Args:
urdf_root: The path to the urdf data folder.
render: Whether to render the simulation.
Raises:
ValueError: If the urdf_version is not supported.
"""
# Set up logging.
self._urdf_root = urdf_root
self._observation = []
self._env_step_counter = 0
self._is_render = render
self._cam_dist = 1.0
self._cam_yaw = 0
self._cam_pitch = -30
self._ground_id = None
self._pybullet_client = None
self._humanoid = None
self._control_time_step = 8.*(1./240.)#0.033333
self.seed()
observation_high = (self._get_observation_upper_bound())
observation_low = (self._get_observation_lower_bound())
action_dim = 36
self._action_bound = 3.14 #todo: check this
action_high = np.array([self._action_bound] * action_dim)
self.action_space = spaces.Box(-action_high, action_high, dtype=np.float32)
self.observation_space = spaces.Box(observation_low, observation_high, dtype=np.float32)
def close(self):
self._humanoid = None
self._pybullet_client.disconnect()
def reset(self):
if (self._pybullet_client==None):
if self._is_render:
self._pybullet_client = bullet_client.BulletClient(
connection_mode=pybullet.GUI)
else:
self._pybullet_client = bullet_client.BulletClient()
self._pybullet_client.setAdditionalSearchPath(pybullet_data.getDataPath())
self._pybullet_client.configureDebugVisualizer(self._pybullet_client.COV_ENABLE_Y_AXIS_UP,1)
self._motion=MotionCaptureData()
motionPath = pybullet_data.getDataPath()+"/motions/humanoid3d_walk.txt"#humanoid3d_spinkick.txt"#/motions/humanoid3d_backflip.txt"
self._motion.Load(motionPath)
self._pybullet_client.configureDebugVisualizer(
self._pybullet_client.COV_ENABLE_RENDERING, 0)
self._pybullet_client.resetSimulation()
self._pybullet_client.setGravity(0,-9.8,0)
y2zOrn = self._pybullet_client.getQuaternionFromEuler([-1.57,0,0])
self._ground_id = self._pybullet_client.loadURDF(
"%s/plane.urdf" % self._urdf_root, [0,0,0], y2zOrn)
#self._pybullet_client.changeVisualShape(self._ground_id,-1,rgbaColor=[1,1,1,0.8])
#self._pybullet_client.configureDebugVisualizer(self._pybullet_client.COV_ENABLE_PLANAR_REFLECTION,self._ground_id)
shift=[0,0,0]
self._humanoid = Humanoid(self._pybullet_client,self._motion,shift)
self._humanoid.Reset()
simTime = random.randint(0,self._motion.NumFrames()-2)
self._humanoid.SetSimTime(simTime)
pose = self._humanoid.InitializePoseFromMotionData()
self._humanoid.ApplyPose(pose, True, True, self._humanoid._humanoid,self._pybullet_client)
self._env_step_counter = 0
self._objectives = []
self._pybullet_client.resetDebugVisualizerCamera(
self._cam_dist, self._cam_yaw, self._cam_pitch, [0, 0, 0])
self._pybullet_client.configureDebugVisualizer(
self._pybullet_client.COV_ENABLE_RENDERING, 1)
return self._get_observation()
def seed(self, seed=None):
self.np_random, seed = seeding.np_random(seed)
return [seed]
def step(self, action):
"""Step forward the simulation, given the action.
Args:
action: A list of desired motor angles for eight motors.
Returns:
observations: The angles, velocities and torques of all motors.
reward: The reward for the current state-action pair.
done: Whether the episode has ended.
info: A dictionary that stores diagnostic information.
Raises:
ValueError: The action dimension is not the same as the number of motors.
ValueError: The magnitude of actions is out of bounds.
"""
self._last_base_position = self._humanoid.GetBasePosition()
if self._is_render:
# Sleep, otherwise the computation takes less time than real time,
# which will make the visualization like a fast-forward video.
#time_spent = time.time() - self._last_frame_time
#self._last_frame_time = time.time()
#time_to_sleep = self._control_time_step - time_spent
#if time_to_sleep > 0:
# time.sleep(time_to_sleep)
base_pos = self._humanoid.GetBasePosition()
# Keep the previous orientation of the camera set by the user.
[yaw, pitch,
dist] = self._pybullet_client.getDebugVisualizerCamera()[8:11]
self._pybullet_client.resetDebugVisualizerCamera(dist, yaw, pitch,
base_pos)
self._humanoid.ApplyAction(action)
for s in range (8):
#print("step:",s)
self._pybullet_client.stepSimulation()
self._initial_frame = self._initial_frame + self._control_time_step
self._humanoid.setSimTime(self._initial_frame)
reward = self._reward()
done = self._termination()
self._env_step_counter += 1
return np.array(self._get_observation()), reward, done, {}
def render(self, mode="rgb_array", close=False):
if mode == "human":
self._is_render = True
if mode != "rgb_array":
return np.array([])
base_pos = self._humanoid.GetBasePosition()
view_matrix = self._pybullet_client.computeViewMatrixFromYawPitchRoll(
cameraTargetPosition=base_pos,
distance=self._cam_dist,
yaw=self._cam_yaw,
pitch=self._cam_pitch,
roll=0,
upAxisIndex=1)
proj_matrix = self._pybullet_client.computeProjectionMatrixFOV(
fov=60,
aspect=float(RENDER_WIDTH) / RENDER_HEIGHT,
nearVal=0.1,
farVal=100.0)
(_, _, px, _, _) = self._pybullet_client.getCameraImage(
width=RENDER_WIDTH,
height=RENDER_HEIGHT,
renderer=self._pybullet_client.ER_BULLET_HARDWARE_OPENGL,
viewMatrix=view_matrix,
projectionMatrix=proj_matrix)
rgb_array = np.array(px)
rgb_array = rgb_array[:, :, :3]
return rgb_array
def _termination(self):
if (self._humanoid):
term = self._humanoid.Terminates()
return term
return False
def _reward(self):
reward = 0
if (self._humanoid):
reward = self._humanoid.GetReward()
return reward
def get_objectives(self):
return self._objectives
@property
def objective_weights(self):
"""Accessor for the weights for all the objectives.
Returns:
List of floating points that corresponds to weights for the objectives in
the order that objectives are stored.
"""
return self._objective_weights
def _get_observation(self):
"""Get observation of this environment.
"""
observation = []
if (self._humanoid):
observation = self._humanoid.GetState()
else:
observation = [0]*197
self._observation = observation
return self._observation
def _get_observation_upper_bound(self):
"""Get the upper bound of the observation.
Returns:
The upper bound of an observation. See GetObservation() for the details
of each element of an observation.
"""
upper_bound = np.zeros(self._get_observation_dimension())
upper_bound[0] = 10 #height
upper_bound[1:107] = math.pi # Joint angle.
upper_bound[107:197] = 10 #joint velocity, check it
return upper_bound
def _get_observation_lower_bound(self):
"""Get the lower bound of the observation."""
return -self._get_observation_upper_bound()
def _get_observation_dimension(self):
"""Get the length of the observation list.
Returns:
The length of the observation list.
"""
return len(self._get_observation())
def configure(self, args):
pass
if parse_version(gym.__version__) < parse_version('0.9.6'):
_render = render
_reset = reset
_seed = seed
_step = step
_close = close
@property
def pybullet_client(self):
return self._pybullet_client
@property
def ground_id(self):
return self._ground_id
@ground_id.setter
def ground_id(self, new_ground_id):
self._ground_id = new_ground_id
@property
def env_step_counter(self):
return self._env_step_counter

87
examples/pybullet/gym/pybullet_envs/deep_mimic/humanoid_test.py
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@@ -1,87 +0,0 @@
import os, inspect
currentdir = os.path.dirname(os.path.abspath(inspect.getfile(inspect.currentframe())))
parentdir = os.path.dirname(os.path.dirname(currentdir))
os.sys.path.insert(0,parentdir)
from pybullet_envs.deep_mimic.humanoid import Humanoid
from pybullet_utils.bullet_client import BulletClient
from pybullet_envs.deep_mimic.motion_capture_data import MotionCaptureData
import pybullet_data
import pybullet
import time
import random
bc = BulletClient(connection_mode=pybullet.GUI)
bc.setAdditionalSearchPath(pybullet_data.getDataPath())
bc.configureDebugVisualizer(bc.COV_ENABLE_Y_AXIS_UP,1)
bc.setGravity(0,-9.8,0)
motion=MotionCaptureData()
motionPath = pybullet_data.getDataPath()+"/motions/humanoid3d_walk.txt"#humanoid3d_spinkick.txt"#/motions/humanoid3d_backflip.txt"
motion.Load(motionPath)
#print("numFrames = ", motion.NumFrames())
simTimeId= bc.addUserDebugParameter("simTime",0,motion.NumFrames()-1.1,0)
y2zOrn = bc.getQuaternionFromEuler([-1.57,0,0])
bc.loadURDF("plane.urdf",[0,-0.04,0], y2zOrn)
humanoid = Humanoid(bc, motion,[0,0,0])#4000,0,5000])
simTime = 0
keyFrameDuration = motion.KeyFrameDuraction()
#print("keyFrameDuration=",keyFrameDuration)
#for i in range (50):
# bc.stepSimulation()
stage = 0
def Reset(humanoid):
global simTime
humanoid.Reset()
simTime = 0 #random.randint(0,motion.NumFrames()-2)
humanoid.SetSimTime(simTime)
pose = humanoid.InitializePoseFromMotionData()
humanoid.ApplyPose(pose, True, True, humanoid._humanoid,bc)
Reset(humanoid)
#bc.stepSimulation()
while (1):
#simTime = bc.readUserDebugParameter(frameTimeId)
#print("keyFrameDuration=",keyFrameDuration)
dt = (1./240.)
#print("------------------------------------------")
#print("dt=",dt)
#print("simTime=",simTime)
#print("humanoid.SetSimTime(simTime)")
humanoid.SetSimTime(simTime)
#pose = humanoid.InitializePoseFromMotionData()
#humanoid.ApplyPose(pose, True)#False)#False, False)
if (humanoid.Terminates()):
Reset(humanoid)
state = humanoid.GetState()
print("len(state)=",len(state))
print("state=", state)
action = [0]*36
humanoid.ApplyAction(action)
for s in range (8):
#print("step:",s)
bc.stepSimulation()
simTime += dt
time.sleep(1./240.)
reward = humanoid.GetReward()
print("reward=",reward)

19
examples/pybullet/gym/pybullet_envs/deep_mimic/motion_capture_data.py
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@@ -1,19 +0,0 @@
import json
class MotionCaptureData(object):
def __init__(self):
self.Reset()
def Reset(self):
self._motion_data = []
def Load(self, path):
with open(path, 'r') as f:
self._motion_data = json.load(f)
def NumFrames(self):
return len(self._motion_data['Frames'])
def KeyFrameDuraction(self):
return self._motion_data['Frames'][0][0]