bullet3/examples/pybullet/gym/pybullet_envs/deep_mimic/env/testLaikago.py

import pybullet as p1
from pybullet_utils import bullet_client
import pybullet_data
from pybullet_utils import pd_controller_stable

import time
import motion_capture_data
import quadrupedPoseInterpolator

useConstraints = False
  
p =  bullet_client.BulletClient(connection_mode=p1.GUI)
p.setAdditionalSearchPath(pybullet_data.getDataPath())

plane = p.loadURDF("plane.urdf")
p.setGravity(0,0,-10)
timeStep=1./500
p.setTimeStep(timeStep)
#p.setDefaultContactERP(0)
#urdfFlags = p.URDF_USE_SELF_COLLISION+p.URDF_USE_SELF_COLLISION_EXCLUDE_ALL_PARENTS 
urdfFlags = p.URDF_USE_SELF_COLLISION


startPos=[0.007058990464444105, 0.03149299192130908, 0.4918981912395484]
startOrn=[0.005934649695708604, 0.7065453990917289, 0.7076373820553712, -0.0027774940359030264]
quadruped = p.loadURDF("laikago/laikago.urdf",startPos,startOrn, flags = urdfFlags,useFixedBase=False)
p.resetBasePositionAndOrientation(quadruped,startPos,startOrn)
if not useConstraints:
  for j in range(p.getNumJoints(quadruped)):
    p.setJointMotorControl2(quadruped,j,p.POSITION_CONTROL,force=0)
  
#This cube is added as a soft constraint to keep the laikago from falling 
#since we didn't train it yet, it doesn't balance
cube = p.loadURDF("cube_no_rotation.urdf",[0,0,-0.5],[0,0.5,0.5,0])
p.setCollisionFilterGroupMask(cube,-1,0,0)
for j in range(p.getNumJoints(cube)):
  p.setJointMotorControl2(cube,j,p.POSITION_CONTROL,force=0)
  p.setCollisionFilterGroupMask(cube,j,0,0)
  p.changeVisualShape(cube,j,rgbaColor=[1,0,0,0])
cid = p.createConstraint(cube,p.getNumJoints(cube)-1,quadruped,-1,p.JOINT_FIXED,[0,0,0],[0,1,0],[0,0,0])
p.changeConstraint(cid, maxForce=10)


jointIds=[]
paramIds=[]
jointOffsets=[]
jointDirections=[-1,1,1,1,1,1,-1,1,1,1,1,1]
jointAngles=[0,0,0,0,0,0,0,0,0,0,0,0]

for i in range (4):
  jointOffsets.append(0)
  jointOffsets.append(-0.7)
  jointOffsets.append(0.7)

maxForceId = p.addUserDebugParameter("maxForce",0,100,20)

for j in range (p.getNumJoints(quadruped)):
        p.changeDynamics(quadruped,j,linearDamping=0, angularDamping=0)
        info = p.getJointInfo(quadruped,j)
        #print(info)
        jointName = info[1]
        jointType = info[2]
        if (jointType==p.JOINT_PRISMATIC or jointType==p.JOINT_REVOLUTE):
                jointIds.append(j)

    
startQ=[0.08389, 0.8482, -1.547832, -0.068933, 0.625726, -1.272086, 0.074398, 0.61135, -1.255892, -0.068262, 0.836745, -1.534517]
for j in range(p.getNumJoints(quadruped)):
  p.resetJointState(quadruped,jointIds[j],jointDirections[j]*startQ[j]+jointOffsets[j])


qpi = quadrupedPoseInterpolator.QuadrupedPoseInterpolator()

#enable collision between lower legs

for j in range (p.getNumJoints(quadruped)):
		print(p.getJointInfo(quadruped,j))

#2,5,8 and 11 are the lower legs
lower_legs = [2,5,8,11]
for l0 in lower_legs:
	for l1 in lower_legs:
		if (l1>l0):
			enableCollision = 1
			print("collision for pair",l0,l1, p.getJointInfo(quadruped,l0)[12],p.getJointInfo(quadruped,l1)[12], "enabled=",enableCollision)
			p.setCollisionFilterPair(quadruped, quadruped, 2,5,enableCollision)

jointIds=[]
paramIds=[]
jointOffsets=[]
jointDirections=[-1,1,1,1,1,1,-1,1,1,1,1,1]
jointAngles=[0,0,0,0,0,0,0,0,0,0,0,0]

for i in range (4):
	jointOffsets.append(0)
	jointOffsets.append(-0.7)
	jointOffsets.append(0.7)

maxForceId = p.addUserDebugParameter("maxForce",0,100,20)

for j in range (p.getNumJoints(quadruped)):
        p.changeDynamics(quadruped,j,linearDamping=0, angularDamping=0)
        info = p.getJointInfo(quadruped,j)
        #print(info)
        jointName = info[1]
        jointType = info[2]
        if (jointType==p.JOINT_PRISMATIC or jointType==p.JOINT_REVOLUTE):
                jointIds.append(j)

		
p.getCameraImage(480,320)
p.setRealTimeSimulation(0)

joints=[]


mocapData = motion_capture_data.MotionCaptureData()

motionPath = pybullet_data.getDataPath()+"/data/motions/laikago_walk.json"

mocapData.Load(motionPath)
print("mocapData.NumFrames=",mocapData.NumFrames())
print("mocapData.KeyFrameDuraction=",mocapData.KeyFrameDuraction())
print("mocapData.getCycleTime=",mocapData.getCycleTime())
print("mocapData.computeCycleOffset=",mocapData.computeCycleOffset())

stablePD = pd_controller_stable.PDControllerStable(p)

cycleTime = mocapData.getCycleTime()
t=0

while t<10.*cycleTime:
  #get interpolated joint
  keyFrameDuration = mocapData.KeyFrameDuraction()
  cycleTime = mocapData.getCycleTime()
  cycleCount = mocapData.calcCycleCount(t, cycleTime)
  
  #print("cycleTime=",cycleTime)
  #print("cycleCount=",cycleCount)
  
  #print("cycles=",cycles)
  frameTime = t - cycleCount*cycleTime
  #print("frameTime=",frameTime)
  if (frameTime<0):
    frameTime += cycleTime

  frame = int(frameTime/keyFrameDuration)
  frameNext = frame+1
  if (frameNext >=  mocapData.NumFrames()):
    frameNext = frame
  frameFraction = (frameTime - frame*keyFrameDuration)/(keyFrameDuration)
  #print("frame=",frame)
  #print("frameFraction=",frameFraction)
  frameData = mocapData._motion_data['Frames'][frame]
  frameDataNext = mocapData._motion_data['Frames'][frameNext]
    
  jointsStr,qdot=qpi.Slerp(frameFraction, frameData, frameDataNext, p)
  
  maxForce = p.readUserDebugParameter(maxForceId)
  print("jointIds=",jointIds)

  if useConstraints:
    for j in range (12):
      #skip the base positional dofs
      targetPos = float(jointsStr[j+7])
      p.setJointMotorControl2(quadruped,jointIds[j],p.POSITION_CONTROL,jointDirections[j]*targetPos+jointOffsets[j], force=maxForce)
    
  else:
    desiredPositions=[]
    for j in range (7):
      targetPosUnmodified = float(jointsStr[j])
      desiredPositions.append(targetPosUnmodified)
    for j in range (12):
      targetPosUnmodified = float(jointsStr[j+7])
      targetPos=jointDirections[j]*targetPosUnmodified+jointOffsets[j]
      desiredPositions.append(targetPos)
    numBaseDofs=6
    totalDofs=12+numBaseDofs
    desiredVelocities=None
    if desiredVelocities==None:
      desiredVelocities = [0]*totalDofs 
    taus = stablePD.computePD(bodyUniqueId=quadruped, 
      jointIndices = jointIds,
      desiredPositions = desiredPositions,
      desiredVelocities = desiredVelocities,
      kps = [4000]*totalDofs,
      kds = [40]*totalDofs,
      maxForces = [500]*totalDofs, 
      timeStep=timeStep)
    
    dofIndex=6
    scaling = 1
    for index in range (len(jointIds)):
      jointIndex = jointIds[index]
      force=[scaling*taus[dofIndex]]
      print("force[", jointIndex,"]=",force)
      p.setJointMotorControlMultiDof(quadruped, jointIndex, controlMode=p.TORQUE_CONTROL, force=force)
      dofIndex+=1
   

  p.stepSimulation()
  t+=timeStep
  time.sleep(timeStep)

useOrgData=False
if useOrgData:
  with open("data1.txt","r") as filestream:
  	for line in filestream:
  		maxForce = p.readUserDebugParameter(maxForceId)
  		currentline = line.split(",")
  		frame = currentline[0]
  		t = currentline[1]
  		joints=currentline[2:14]
  		for j in range (12):
  			targetPos = float(joints[j])
  			p.setJointMotorControl2(quadruped,jointIds[j],p.POSITION_CONTROL,jointDirections[j]*targetPos+jointOffsets[j], force=maxForce)
  		p.stepSimulation()
  		for lower_leg in lower_legs:
  			#print("points for ", quadruped, " link: ", lower_leg)
  			pts = p.getContactPoints(quadruped,-1, lower_leg)
  			#print("num points=",len(pts))
  			#for pt in pts:
  			#	print(pt[9])
  		time.sleep(1./500.)


for j in range (p.getNumJoints(quadruped)):
        p.changeDynamics(quadruped,j,linearDamping=0, angularDamping=0)
        info = p.getJointInfo(quadruped,j)
        js = p.getJointState(quadruped,j)
        #print(info)
        jointName = info[1]
        jointType = info[2]
        if (jointType==p.JOINT_PRISMATIC or jointType==p.JOINT_REVOLUTE):
                paramIds.append(p.addUserDebugParameter(jointName.decode("utf-8"),-4,4,(js[0]-jointOffsets[j])/jointDirections[j]))


p.setRealTimeSimulation(1)

while (1):
	
	for i in range(len(paramIds)):
		c = paramIds[i]
		targetPos = p.readUserDebugParameter(c)
		maxForce = p.readUserDebugParameter(maxForceId)
		p.setJointMotorControl2(quadruped,jointIds[i],p.POSITION_CONTROL,jointDirections[i]*targetPos+jointOffsets[i], force=maxForce)