def _makeMolecule(self):
#H2O
O = cmds.polySphere(r=1, n='O', ax = [0,0,0]);
H1 = cmds.polySphere(r=0.8, n='H1', ax=[0,0,0]);
H2 = cmds.polySphere(r=0.8, n='H2', ax=[0,0,0]);
cmds.move(0.0,0.0,1,H1, r=True)
cmds.move(0.0,0.0,-1,H2, r=True)
cmds.xform(H1, piv=[0,0,0], ws=True)
cmds.xform(H2, piv=[0,0,0], ws=True)
cmds.rotate(0,'60',0, H1);
#group O, H1, H2 as a water molecule
H2O = cmds.group( empty=True, name='H2O' )
cmds.parent(H1,H2,O,H2O)
#paint on colors for the water molecule
#create red lambert
cmds.sets( renderable=True, noSurfaceShader=True, empty=True, name='O_WhiteSG' )
cmds.shadingNode( 'lambert', asShader=True, name='O_White' )
cmds.setAttr( 'O_White.color', 1, 1, 1, type='double3')
cmds.connectAttr('O_White.outColor', 'O_WhiteSG.surfaceShader')
#create red lambert
cmds.sets( renderable=True, noSurfaceShader=True, empty=True, name='H_RedSG' )
cmds.shadingNode( 'lambert', asShader=True, name='H_Red' )
cmds.setAttr( 'H_Red.color', 1, 0, 0, type='double3')
cmds.connectAttr('H_Red.outColor', 'H_RedSG.surfaceShader')
#assign the material
cmds.sets('H1', edit=True, forceElement='H_RedSG')
cmds.sets('H2', edit=True, forceElement='H_RedSG')
cmds.sets('O', edit=True, forceElement='O_WhiteSG')
return H2O
def _handleCreateBall(self):
cmds.polySphere(name='ball', r=2, sx=20, sy=20, ax=[0, 1, 0])
cmds.polyColorPerVertex(rgb=(1, 1, 1), cdo=True)
cmds.select('ball.f[380:399]', 'ball.f[320:339]', 'ball.f[280:299]', 'ball.f[240:259]', 'ball.f[200:219]', 'ball.f[160:179]', 'ball.f[120:139]', 'ball.f[80:99]', 'ball.f[40:59]', 'ball.f[0:19]')
cmds.polyColorPerVertex(rgb=(1, 0, 0), cdo=True)
cmds.select('ball')
cmds.nonLinear( type='squash')
def createBubble(tx, tz, name):
"""
:param tx: translate x value
:param tz: translate z value
:param name: string name of bubble
:return: nothing
"""
cmds.polySphere(sx=15, sy=15, r=.1, n=name)
cmds.move(tx,0,tz, name, absolute=True)
def _handleBubblesButton(self):
"""
This callback creates a polygonal sphere in the Maya scene.
it then translates it.
"""
decRange = np.arange(-1,1,.1)
decRange2 = np.arange(0,1,.1)
r = 2
a = 2.0*r
y = (0, 1, 0) # y up
#polyPlane -w 1 -h 1 -sx 10 -sy 10 -ax 0 1 0 -cuv 2 -ch 1;
p = cmd.polyPlane(
w=100, h=100, sx=10, sy=10, ax=y, cuv=3, ch=1,n='HotPlate')[0]
cmd.select(p)
cmd.move(0,2,0,r=True)
cmd.setKeyframe()
c = cmds.polySphere(
r=r, sx=10, sy=10, ax=y, cuv=2, ch=1, n='Bubble')[0]
cmds.select(c)
cmd.setKeyframe()
'''
cmd.setKeyframe()
for i in range(1,300,5):
x = rand.choice(decRange)
y = 5*rand.choice(decRange2)
z = rand.choice(decRange)
cmd.currentTime(i)
cmd.move(x, y, z, r=True)
cmd.setKeyframe()
'''
randBubbleCount = rand.choice(range(10,300)) #this should be set in the interface
for i in range(0,100,1):
randX = rand.choice(range(-50,50,1))
randZ = rand.choice(range(-50,50,1))
r = 2
a = 2.0*r
yUp = (0, 1, 0) # y up
b = cmds.polySphere(
r=r, sx=10, sy=10, ax=yUp, cuv=2, ch=1, n='Bubble')[0]
cmds.select(b)
startTime = rand.choice(range(1, 600, 1))
cmd.currentTime(1)
cmd.move(randX, 0, randZ, a=True)
cmd.setKeyframe()
for j in range(startTime, 600, 2):
x = rand.choice(decRange)
y = 5*rand.choice(decRange2)
z = rand.choice(decRange)
cmd.currentTime(j)
cmd.move(x, y, z, r=True)
cmd.setKeyframe()
response = nimble.createRemoteResponse(globals())
response.put('name', c)
def _createGeometry(self, side):
mc.select(cl=True)
self.r_hand_palm = mc.polyCube(sx=4,
sy=4,
sz=4,
w=10,
h=10,
d=3,
n='R_palm')[0]
mc.move(0, 5, -1.5)
self.r_hand_heal = mc.polyCube(w=10, h=2, d=2, n='R_heal')[0]
mc.move(0, 1, 1, r=True)
if side == Side.right:
mc.select(self.r_hand_heal + '.e[7]')
elif side == Side.left:
mc.select(self.r_hand_heal + '.e[6]')
mc.move(0, 2, 0, r=True)
self.r_hand = mc.polyUnite(self.r_hand_heal,
self.r_hand_palm,
n='r_hand')[0]
self.r_hand_n_1 = mc.polySphere(r=1.2, n="r_hand_n_1")[0]
mc.move(-3.75, 9.25, -.5)
self.r_hand_n_2 = mc.polySphere(r=1.2, n="r_hand_n_2")[0]
mc.move(-1.25, 9.25, -.5)
self.r_hand_n_3 = mc.polySphere(r=1.2, n="r_hand_n_3")[0]
mc.move(1.25, 9.25, -.5)
self.r_hand_n_4 = mc.polySphere(r=1.2, n="r_hand_n_4")[0]
mc.move(3.75, 9.25, -.5)
self.r_hand_n_t = mc.polySphere(r=1.2, n="r_hand_n_t")[0]
if side == Side.right:
mc.move(4.5, 2, 1.5)
elif side == Side.left:
mc.move(-4.5, 2, 1.5)
#self.hand = mc.polyCBoolOp(self.r_hand, self.r_hand_n_1, self.r_hand_n_2, self.r_hand_n_3, self.r_hand_n_4, self.r_hand_n_t,
# op=2, n='r_hand')
### we did this becuase maya is stupid, and 2014 does not have polyCBoolOp()
self.hand = mc.polyBoolOp(self.r_hand,
self.r_hand_n_1,
op=2,
n='r_hand')[0]
self.hand = mc.polyBoolOp(self.hand, self.r_hand_n_2, op=2,
n='r_hand')[0]
self.hand = mc.polyBoolOp(self.hand, self.r_hand_n_3, op=2,
n='r_hand')[0]
self.hand = mc.polyBoolOp(self.hand, self.r_hand_n_4, op=2,
n='r_hand')[0]
self.hand = mc.polyBoolOp(self.hand, self.r_hand_n_t, op=2,
n='r_hand')[0]
def _createCalfArmor(self, name, side):
p1 = mc.polySphere(r=10)[0]
mc.scale(.35, 1.5, .75)
mc.move(5, 0, 0)
p2 = mc.polySphere(r=10)[0]
mc.scale(.35, 1.5, .75)
mc.move(-5, 0, 0)
p3 = mc.polyCylinder(r=10, sx=40)[0]
mc.rotate(0, 0, '90deg')
mc.scale(1.5, 5, .75)
#claf1 = mc.polyUnite(p1,p2,p3)
#print calf1
#calf1 = mc.polyBoolOp(p1, p3, op=1, n='calf')[0]
#calf2 = mc.polyBoolOp(calf1, p2, op=1, n='calf')[0]
p4 = mc.polyCube(w=10, h=10, d=10)[0]
mc.move(0, 10, -5)
p5 = mc.polyCube(w=10, h=10, d=10)[0]
mc.move(0, 10, -5)
p6 = mc.polyCube(w=10, h=10, d=10)[0]
mc.move(0, 10, -5)
c1 = mc.polyBoolOp(p1, p4, op=2)[0]
c2 = mc.polyBoolOp(p2, p5, op=2)[0]
c3 = mc.polyBoolOp(p3, p6, op=2)[0]
claf1 = mc.polyUnite(c1, c2, c3)
mc.sets(e=True, forceElement=self.color1)
mc.move(0, 45, -10)
self.tibia = mc.polyUnite(self.tibia, claf1)
t1 = mc.polyCube(sx=3, sy=3, sz=3, w=10, h=10, d=10, n='thigh')[0]
t1r = mc.polyBevel(ws=1, oaf=1, o=.5, sa=30)[0]
mc.scale(1, 5, 1)
mc.move(0, 75, -12, r=True)
t3 = mc.polyCube(sx=3, sy=3, sz=3, w=10, h=15, d=10,
n='thight_armor')[0]
mc.sets(e=True, forceElement=self.color1)
t3r = mc.polyBevel(ws=1, oaf=1, o=.5, sa=30)[0]
mc.scale(1.75, 3, 1.4)
mc.move(0, 90, -9, r=True)
self.femur = mc.polyUnite(self.femur, t1, t3)
pass
def create_bubble():
cmds.playbackOptions(minTime='0', maxTime='71') # set playback range
size = 0.2
bubble = cmds.polySphere(name='bubble', radius=0.2) # create a sphere
#for f in range(72): # for the first 84 frames (starting from 0 and ending with 83)
for time in [1, 15, 30, 45, 60, 72]: # for each frame calculate sub-steps
#mc.setKeyframe( bubble, attribute='translateX', value=px, t=f ) # set keyframes
cmds.setKeyframe(bubble,
attribute='translateY',
value=size + 0.1 * time,
t=time)
cmds.setKeyframe(bubble,
attribute='scaleX',
value=size + 0.02 * time,
t=time)
cmds.setKeyframe(bubble,
attribute='scaleY',
value=size + 0.02 * time,
t=time)
cmds.setKeyframe(bubble,
attribute='scaleZ',
value=size + 0.02 * time,
t=time)
def _handleBubbleButton(self):
"""
This callback creates a polygonal sphere in the Maya scene.
it then translates it.
"""
decRange = np.arange(-1,1,.1)
decRange2 = np.arange(0,1,.1)
r = 2
a = 2.0*r
y = (0, 1, 0) # y up
c = cmds.polySphere(
r=r, sx=10, sy=10, ax=y, cuv=2, ch=1, n='Bubble')[0]
cmds.select(c)
cmd.setKeyframe()
cmd.setKeyframe()
for i in range(1,300,5):
x = rand.choice(decRange)
y = 5*rand.choice(decRange2)
z = rand.choice(decRange)
cmd.currentTime(i)
cmd.move(x,y,z,r=True)
cmd.setKeyframe()
response = nimble.createRemoteResponse(globals())
response.put('name', c)
def _createGeometry(self, name, side):
#build toe
self.side = side
self.name = name
self.toe = mc.polyCube(sx=2,
sy=2,
sz=2,
w=5,
h=2,
d=3,
n=name + '_toe')[0]
self.ball = mc.polyCylinder(h=5, n=name + '_ball')[0]
mc.move(0, 0, -2, r=True)
mc.rotate(0, 0, '90deg')
self.toe = mc.polyUnite(self.toe, self.ball, n=name + '_toe')[0]
mc.move(0, 0, -2, self.toe + ".scalePivot", self.toe + ".rotatePivot")
#build arch
self.arch = mc.polyCube(w=5, d=10, n=name + '_arch')[0]
mc.move(0, 0, -7, r=True)
#mc.select(f[8]-f[11])
mc.select(self.arch + '.f[2]')
mc.move(0, 3, 0, r=True)
self.ankle = mc.polySphere(r=2.5)[0]
mc.move(0, 3, -12, r=True)
self.arch = mc.polyUnite(self.arch, self.ankle, n=name + '_arch')[0]
mc.move(0, 3, -12, self.arch + ".scalePivot",
self.arch + ".rotatePivot")
#self.heal = mc.polyCube(sx=2, sy=2, sz=2,w=5, h=3, n=name+'_heal')
pass
def _createGeometry(self, name, side):
#create tibia
self.tibia = mc.polyCube(sx=1,
sy=1,
sz=1,
w=2,
h=50,
d=2,
n=name + '_tibia')[0]
mc.move(0, 28, -12)
self.knee = mc.polyCylinder(h=5, r=2, n=name + '_knee')[0]
mc.move(0, 54, -12, r=True)
mc.rotate(0, 0, '90deg')
self.tibia = mc.polyUnite(self.tibia, self.knee, n=name + '_tibia')[0]
mc.move(0, 54, -12, self.tibia + ".scalePivot",
self.tibia + ".rotatePivot")
#create feamer
self.femur = mc.polyCube(sx=1,
sy=1,
sz=1,
w=3,
h=50,
d=3,
n=name + '_feamer')[0]
mc.move(0, 80, -12)
self.hip = mc.polySphere(r=5, n=name + '_hip')
mc.move(0, 107, -12)
self.femur = mc.polyUnite(self.femur, self.hip, n=name + '_femur')[0]
mc.move(0, 107, -12, self.femur + ".scalePivot",
self.femur + ".rotatePivot")
pass
def _handlePlasticBlue(self):
if materials.blueCPlasticSG == None:
materials.blueClearPlastic()
Sphere = mc.polySphere(r=5, n='bluePlasticSphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.blueCPlasticSG)
def _handleChromeTex(self):
if materials.npchromeSG == None:
materials.npchrome()
Sphere = mc.polySphere(r=5, n='texChromephere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.npchromeSG)
def _handleSilver(self):
if materials.silverSG == None:
materials.silver()
Sphere = mc.polySphere(r=5, n='sliverSphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.silverSG)
def _handleShinyGold(self):
if materials.shinyGoldSG == None:
materials.shinyGold()
Sphere = mc.polySphere(r=5, n='shinyGoldSphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.shinyGoldSG)
def doMulti(time):
for i in range(0, time / 2):
#makes time/2 bubbles and sets up a bunch of random stats for them
initTime = randint(0, time - 30)
initX = randint(-10, 10)
initZ = randint(-10, 10)
xRand = randint(-5, 5)
zRand = randint(-5, 5)
#keyframes all the bubbles based on time that user sets in Qt slider
r = .1
c = cmds.polySphere(r=r)
cmds.setAttr(c[0] + ".visibility", 0)
cmds.setKeyframe(time=initTime + 60)
cmds.scale(11, 10, 11)
cmds.move(initX, 20, initZ)
cmds.setKeyframe(time=initTime + 50)
cmds.setAttr(c[0] + ".visibility", 1)
cmds.rotate(100, 0, 0)
cmds.scale(10, 9, 9.5)
cmds.setKeyframe(time=initTime + 40)
cmds.move(initX + xRand, 10, initZ + zRand)
cmds.rotate(60, 0, 0)
cmds.setKeyframe(time=initTime + 30)
cmds.move(initX, 6, initZ)
cmds.rotate(0, 0, 0)
cmds.setKeyframe(time=initTime + 20)
cmds.move(initX, 3, initZ)
cmds.scale(3, 3, 3)
cmds.setKeyframe(time=initTime + 10)
cmds.move(initX, 0, initZ)
cmds.scale(1, .8, 1)
cmds.setKeyframe(time=initTime)
def _handleBlueFM(self):
if materials.blueFMSG == None:
materials.blueFineMetallic()
Sphere = mc.polySphere(r=5, n='blueFMSphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.blueFMSG)
def _handleBlueAA(self):
if materials.blueAASG == None:
materials.blueAnodizedAluminum()
Sphere = mc.polySphere(r=5, n='blueAASphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.blueAASG)
def doSingle():
#keyframes a bubble, does NOT use slider
r = .1
c = cmds.polySphere(r=r)
cmds.setAttr(c[0] + ".visibility", 0)
cmds.setKeyframe(time=60)
cmds.scale(11, 10, 11)
cmds.move(0, 20, 0)
cmds.setKeyframe(time=50)
cmds.setAttr(c[0] + ".visibility", 1)
cmds.rotate(100, 0, 0)
cmds.scale(10, 9, 9.5)
cmds.setKeyframe(time=40)
cmds.move(4, 10, 0)
cmds.rotate(60, 0, 0)
cmds.setKeyframe(time=30)
cmds.move(0, 6, 0)
cmds.rotate(0, 0, 0)
cmds.setKeyframe(time=20)
cmds.move(0, 3, 0)
cmds.scale(3, 3, 3)
cmds.setKeyframe(time=10)
cmds.move(0, 0, 0)
cmds.scale(1, .8, 1)
cmds.setKeyframe(time=1)
def _handleRedAA(self):
if materials.redAASG == None:
materials.redAnodizedAluminum()
print materials.redAASG
Sphere = mc.polySphere(r=5, n='redAASphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=materials.redAASG)
def _CreateSphereButton(self):
"""
This callback creates a polygonal cylinder in the Maya scene.
"""
sphere = cmds.polySphere(r=50.0, name='sphere1')
cmds.select(sphere)
response = nimble.createRemoteResponse(globals())
response.put('name', sphere)
def _CreateSphereButton(self):
"""
This callback creates a polygonal cylinder in the Maya scene.
"""
sphere = cmds.polySphere(r=50.0, name='sphere1')
cmds.select(sphere)
response = nimble.createRemoteResponse(globals())
response.put('name', sphere)
def _handlePlasticCustom(self):
r = self.redSpin.value()
g = self.greenSpin.value()
b = self.blueSpin.value()
custPlast = materials.clearPlasticRGB('cust', r, g, b)
Sphere = mc.polySphere(r=5, n='custAASphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=custPlast.PlasticSG)
def _handleCustomFM(self):
r = self.redSpin.value()
g = self.greenSpin.value()
b = self.blueSpin.value()
custFM = materials.fineMetallic('cust', r, g, b)
Sphere = mc.polySphere(r=5, n='custFMSphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=custFM.FMSG)
def _CreateSphereButton(self):
"""
This callback creates a polygonal cylinder in the Maya scene.
"""
sphere = cmds.polySphere(r=20, name="sphere1")
cmds.duplicate('sphere1')
response = nimble.createRemoteResponse(globals())
response.put('name', sphere)
global created
created = 'sphere'
def _CreateSphereButton(self):
"""
This callback creates a polygonal cylinder in the Maya scene.
"""
sphere = cmds.polySphere(r=20, name="sphere1")
cmds.duplicate('sphere1')
response = nimble.createRemoteResponse(globals())
response.put('name', sphere)
global created
created = 'sphere'
def bouncingBubble(amp, sampFreq, scaleFactor):
startRadius = 1.0 #2.865
spf = sampFreq / 24 # approximate samples per frame
sphere = cmds.polySphere(
n='bubble',
r=startRadius)[0] # bakes in radius, scale of 1.0 makes radius 2.865
shader = str(
cmds.listConnections(cmds.listHistory(sphere, f=1), type='lambert')[0])
print('Created ' + sphere + ' with shader ' + shader)
# cmds.xform('column', t = [0,.5,0], sp=[0,-.5,0]) # move scale pivot to bottom of shape
frameWin = BoxOnSphere.SPHERE_STEP
print('Calculating average amplitude for every ' + str(frameWin) +
'-frame (' + str(frameWin / 24.) + ' second) ' + 'window')
avgs = averageAmplitude(amp, spf * frameWin)
curProg = 1
tenPercent = len(avgs) / 10
# scaleFactor = 10.0
print('Keyframing size translations')
for i in range(1, len(avgs)):
h = normalize(
avgs, i
) * scaleFactor # take away or add + 1 to allow or disallow the sphere to decay infinitely small
cmds.setKeyframe(sphere, v=h, at='scaleX', t=(i - 1) * frameWin)
cmds.setKeyframe(sphere, v=h, at='scaleY', t=(i - 1) * frameWin)
cmds.setKeyframe(sphere, v=h, at='scaleZ', t=(i - 1) * frameWin)
if i % tenPercent == 0:
if not (curProg == 0 or curProg == 10):
sys.stdout.write(str(curProg) + '0%...')
curProg += 1
print('100%')
frameWin = 10
print('Calculating average amplitude for every ' + str(frameWin) +
'-frame (' + str(frameWin / 24.) + ' second) ' + 'window')
avgs = averageAmplitude(amp, spf * frameWin)
curProg = 1
tenPercent = len(avgs) / 10
print('Keyframing color translations')
for i in range(1, len(avgs)):
norm = normalize(avgs, i)
rgb = colorsys.hsv_to_rgb(norm, 1, min(
norm + .2, 1)) # hue and value both vary with amplitude
# listConnections returns a list with unicode strings
cmds.setAttr(shader + '.color', rgb[0], rgb[1], rgb[2], type='double3')
cmds.setKeyframe(shader + '.color', at='color', t=i * frameWin)
if i % tenPercent == 0:
if not (curProg == 0 or curProg == 10):
sys.stdout.write(str(curProg) + '0%...')
curProg += 1
print('100%')
return sphere
def _handleCustomAA(self):
name = self.customName.text()
r = self.redSpin.value()
g = self.greenSpin.value()
b = self.blueSpin.value()
custAA = materials.anodizedAluminum(name + '_cust', r, g, b)
Sphere = mc.polySphere(r=5, n=name + '_custAASphere')[0]
mc.select(cl=True)
mc.select(Sphere)
mc.sets(e=True, forceElement=custAA.AASG)
listOfMaterialShader.append(custAA.AASG)
def _createGeometry(self, name, side):
#create tibia
self.tibia = mc.polyCube(sx=1,
sy=1,
sz=1,
w=2,
h=50,
d=2,
n=name + '_tibia')[0]
mc.move(0, 28, -12)
self.knee = mc.polyCylinder(h=5, r=2, n=name + '_knee')[0]
mc.move(0, 54, -12, r=True)
mc.rotate(0, 0, '90deg')
self.tibia = mc.polyUnite(self.tibia, self.knee, n=name + '_tibia')[0]
self.llegArmor = mc.polyCube(w=8, h=30, d=8)[0]
mc.move(0, 22, -12)
mc.select(self.llegArmor + '.f[3]')
mc.scale(1.5, 1, 1.5)
mc.select(self.llegArmor + '.e[0]')
mc.polySubdivideEdge(dv=2)
mc.select(self.llegArmor + '.e[12]')
mc.move(0, 2, 0, r=True)
self.tibia = mc.polyUnite(self.tibia,
self.llegArmor,
n=name + '_tibia')[0]
mc.move(0, 54, -12, self.tibia + ".scalePivot",
self.tibia + ".rotatePivot")
#create feamer
self.femur = mc.polyCube(sx=1,
sy=1,
sz=1,
w=3,
h=50,
d=3,
n=name + '_feamer')[0]
mc.move(0, 80, -12)
self.hip = mc.polySphere(r=5, n=name + '_hip')
mc.move(0, 107, -12)
self.femur = mc.polyUnite(self.femur, self.hip, n=name + '_femur')[0]
mc.move(0, 107, -12, self.femur + ".scalePivot",
self.femur + ".rotatePivot")
self._createCalfArmor(name, side)
pass
def _handleSphereButton(self):
"""
This callback creates a polygonal sphere in the Maya scene.
it then translates it.
"""
r = 2
a = 2.0*r
y = (0, 1, 0) # y up
c = cmds.polySphere(
r=r, sx=10, sy=10, ax=y, cuv=2, ch=1, n='Bubble')[0]
cmds.select(c)
cmd.move(0, 5, 0, r = True)
response = nimble.createRemoteResponse(globals())
response.put('name', c)
def _createGeometry(self, segmentLength, offset):
mc.select(cl=True)
#section 1 cunstruction
self.r_hand_p_n_1 = mc.polySphere(r=.6,n="r_hand_p_n_1")
mc.move(offset,2,.25)
self.r_hand_p_b_1 = mc.polyCylinder(r=.25,h=.5,n="r_hand_p_b_1")
mc.move(offset,2.6,.25)
self.r_hand_p_p_1 = mc.polyCube(sx=2, sy=2, sz=2, h=segmentLength)
mc.move(offset,3.25+self.segOffset,.25)
self.r_hand_p_n_2_a = mc.polyCylinder(ax=[1,0,0], sx=2, sy=2, sz=2, h=.3, r=.5,n='r_hand_p_n_2_a')
mc.move(offset+.35,4.25+(2*self.segOffset),.25) #1.875 + .35
self.r_hand_p_n_2_b = mc.polyCylinder(ax=[1,0,0], sx=2, sy=2, sz=2, h=.3, r=.5,n='r_hand_p_n_2_b')
mc.move(offset-.35,4.25+(2*self.segOffset),.25) #1.875 -.35
#section 1 unite
self.r_hand_p_s_1 = mc.polyUnite(self.r_hand_p_n_1, self.r_hand_p_b_1, self.r_hand_p_p_1,
self.r_hand_p_n_2_a, self.r_hand_p_n_2_b, n='r_hand_p_s_1')[0]
mc.move(offset,2,.25, self.r_hand_p_s_1+".scalePivot", self.r_hand_p_s_1+".rotatePivot")
#section 2 construction
self.r_hand_p_n_2_c = mc.polyCylinder(ax=[1,0,0], sx=2, sy=2, sz=2, h=.3, r=.5,n='r_hand_p_n_2_c')
mc.move(offset,4.25+(2*self.segOffset),.25)
self.r_hand_p_p_2 = mc.polyCube(sx=2, sy=2, sz=2, h=segmentLength)
mc.move(offset,5.25+(3*self.segOffset),.25)
self.r_hand_p_n_3_a = mc.polyCylinder(ax=[1,0,0], sx=2, sy=2, sz=2, h=.3, r=.5,n='r_hand_p_n_3_a')
mc.move(offset+.35,6.25+(4*self.segOffset),.25) #1.875 + .35
self.r_hand_p_n_3_b = mc.polyCylinder(ax=[1,0,0], sx=2, sy=2, sz=2, h=.3, r=.5,n='r_hand_p_n_3_b')
mc.move(offset-.35,6.25+(4*self.segOffset),.25) #1.875 -.35
#section 2 unite
self.r_hand_p_s_2 = mc.polyUnite(self.r_hand_p_n_2_c, self.r_hand_p_p_2, self.r_hand_p_n_3_a,
self.r_hand_p_n_3_b, n='r_hand_p_s_2')[0]
mc.move(offset,4.25+(2*self.segOffset),.25, self.r_hand_p_s_2+".scalePivot", self.r_hand_p_s_2+".rotatePivot")
#section 3 construction
self.r_hand_p_n_3_c = mc.polyCylinder(ax=[1,0,0], sx=2, sy=2, sz=2, h=.3, r=.5,n='r_hand_p_n_3_c')
mc.move(offset,6.25+(4*self.segOffset),.25)
self.r_hand_p_p_3 = mc.polyCube(sx=2, sy=2, sz=2, h=segmentLength)
mc.move(offset,7.25+(5*self.segOffset),.25)
#section 3 unite
self.r_hand_p_s_3 = mc.polyUnite(self.r_hand_p_n_3_c, self.r_hand_p_p_3, n='r_hand_p_s_3')[0]
mc.move(offset,6.25+(4*self.segOffset),.25, self.r_hand_p_s_3+".scalePivot", self.r_hand_p_s_3+".rotatePivot")
def _createGeometry(self, name, side):
#create radius
self.radius = mc.polyCube(sx=1, sy=1, sz=1, w=2,h=40, d=2, n=name+'_radius')[0]
mc.move(0,20,0)
self.elbow = mc.polyCylinder(h=5,r=2,n=name+'_elbow')[0]
mc.move(0,41,0,r=True)
mc.rotate(0,0,'90deg')
self.radius = mc.polyUnite(self.radius,self.elbow, n=name+'_radius')[0]
mc.move(0,41,0, self.radius+".scalePivot", self.radius+".rotatePivot")
#create humerus
self.humerus = mc.polyCube(sx=1, sy=1, sz=1, w=3,h=40, d=3, n=name+'_humerus')[0]
mc.move(0,62,0)
self.shoulder = mc.polySphere(r=5,n=name+'_shoulder')
mc.move(0,84,0)
self.humerus = mc.polyUnite(self.humerus,self.shoulder, n=name+'_humerus')[0]
mc.move(0,84,0, self.humerus+".scalePivot", self.humerus+".rotatePivot")
pass
def drawBubble(radius, xpoint, ypoint, zpoint, name, time):
"""
Arguments: radius is the size of the overall shape
Return: None
"""
y = (0, 1, 0)
d = cmds.polyCylinder(r=10,
h=20,
sx=40,
sy=10,
sz=1,
ax=(0, 0, 0),
rcp=0,
cuv=2,
ch=1,
n='CylinderContainer')[0]
cmds.move(0, 10, 0)
cmds.select(d)
response = nimble.createRemoteResponse(globals())
response.put('name', d)
c = cmds.polySphere(r=radius, ax=y, cuv=2, ch=1, n=name)[0]
xpoint = 0
for i in range(1, time + 1, 3): # figure out best time step
cmds.setKeyframe(name, t=i)
cmds.move(xpoint, ypoint, zpoint, relative=False)
cmds.select(name)
response = nimble.createRemoteResponse(globals())
response.put('name', name)
xpoint = xpoint + .1 # need to do some physics for theses
print(ypoint, i)
if ypoint >= 19.5:
ypoint = 20
print("pop")
break
else:
ypoint = (.55 + float(ypoint))
zpoint = zpoint + .001
#cmds.setKeyframe( name , at="translateY", t=time, v=xpoint + 3)
return None
from __future__ import print_function, absolute_import, unicode_literals, division
import nimble
import random
from nimble import cmds
from nimble import MayaCommandException
count = 0
while count < 100:
result = cmds.polySphere()
name = result[0]
bcmds = nimble.createCommandsBatch()
index = 0
while index < 100:
bcmds.move(
2.0*(random.random() - 0.5),
2.0*(random.random() - 0.5),
2.0*(random.random() - 0.5),
name, relative=True)
bcmds.rotate(
random.random() - 0.5,
random.random() - 0.5,
random.random() - 0.5,
name, relative=True)
bcmds.scale(
1.0 + 0.01*(random.random() - 0.5),
1.0 + 0.01*(random.random() - 0.5),
1.0 + 0.01*(random.random() - 0.5),
def setUpMolecule():
#Adjust time slider
cmds.playbackOptions( minTime='1', maxTime='300', mps=1)
# Create the oxygen part of the larger bond (cylinder)
cmds.polyCylinder(n='oxyCylinder', r=1, h=2, sx=20, sy=1, sz=1, ax=(1, 0, 0), rcp=0, cuv=3, ch=1)
#Set scale for oxyCylinder
cmds.setAttr("oxyCylinder.translateX", 6)
cmds.setAttr("oxyCylinder.scaleZ", 2)
cmds.setAttr("oxyCylinder.scaleX", 2)
cmds.setAttr("oxyCylinder.scaleY", 2)
#-------Set up shader and shade cylinder----------
redShader = cmds.shadingNode('blinn', asShader=True, n='redBlinn')
cmds.setAttr("redBlinn.color", 0.772, 0, 0, type="double3")
cmds.select('oxyCylinder')
cmds.hyperShade(assign=redShader)
#--------------White Cylinder-------------
# Create the oxygen part of the larger bond (cylinder)
cmds.polyCylinder(n='hydroCylinder', r=1, h=2, sx=20, sy=1, sz=1, ax=(1, 0, 0), rcp=0, cuv=3, ch=1)
#Set scale for oxyCylinder
cmds.setAttr("hydroCylinder.translateX", 10)
cmds.setAttr("hydroCylinder.scaleZ", 2)
cmds.setAttr("hydroCylinder.scaleX", 2)
cmds.setAttr("hydroCylinder.scaleY", 2)
#-------Set up shader and shade cylinder----------
whiteShader = cmds.shadingNode('blinn', asShader=True, n='whiteBlinn')
cmds.setAttr("whiteBlinn.color", 1, 1, 1, type="double3")
#Select the cylinder to color
cmds.select('hydroCylinder')
# Assign shader
cmds.hyperShade(assign=whiteShader)
#----------------------------------------------------------
#-----------Group two cylinders together as "cylinder"-----
#----------------------------------------------------------
cmds.group(em=True, n='cylinder')
cmds.parent('oxyCylinder', 'cylinder')
cmds.parent('hydroCylinder', 'cylinder')
#------------Oxygen-------------
# Create the Oxygen sphere
cmds.polySphere(n='oxygen', r=1, sx=20, sy=20, ax=(0, 1, 0), cuv=2, ch=1)
#Set scale for oxygen
cmds.setAttr("oxygen.scaleZ", 5)
cmds.setAttr("oxygen.scaleX", 5)
cmds.setAttr("oxygen.scaleY", 5)
#-------Assign shader--------
cmds.select('oxygen')
cmds.hyperShade(assign=redShader)
#------------Hydrogen-------------
# Create the Hydrogen sphere
cmds.polySphere(n='hydrogen', r=1, sx=20, sy=20, ax=(0, 1, 0), cuv=2, ch=1)
#Set scale for oxygen
cmds.setAttr("hydrogen.translateX", 14)
cmds.setAttr("hydrogen.scaleZ", 4)
cmds.setAttr("hydrogen.scaleX", 4)
cmds.setAttr("hydrogen.scaleY", 4)
#-------Assign shader--------
cmds.select('hydrogen')
cmds.hyperShade(assign=whiteShader)
#----------------------------------------------------------
#-----------Group 'cylinder' and hydrogen together as "hydroAssembly"-----
#----------------------------------------------------------
cmds.group(em=True, n='hydroAssembly1')
cmds.parent('cylinder', 'hydroAssembly1')
cmds.parent('hydrogen', 'hydroAssembly1')
#----------------------------------------------------------
#-----------Group into realign group
#----------------------------------------------------------
cmds.group(em=True, n='realignGroup1')
cmds.parent('hydroAssembly1', 'realignGroup1')
#-------------------------------------------------------------
#------------Duplicate the assembly--------------------------
#-------------------------------------------------------------
cmds.duplicate('realignGroup1', n='realignGroup2')
cmds.setAttr('realignGroup2.rotateZ', 180)
cmds.rename('realignGroup2|hydroAssembly1','hydroAssembly2')
#----------------------------------------------------------
#-----------Make entire thing a group "molecule"-----
#----------------------------------------------------------
cmds.group(em=True, n='molecule')
cmds.parent('oxygen', 'molecule')
cmds.parent('realignGroup1', 'molecule')
cmds.parent('realignGroup2', 'molecule')
#-------Move entire molecule up-------
cmds.setAttr("molecule.translateY", 10)
def buildScene(self):
"""Doc..."""
groupItems = []
hinds = []
fores = []
for c in self._data.getChannelsByKind(ChannelsEnum.POSITION):
isHind = c.target in [TargetsEnum.LEFT_HIND, TargetsEnum.RIGHT_HIND]
radius = 20 if isHind else 15
res = cmds.polySphere(radius=radius, name=c.target)
groupItems.append(res[0])
if isHind:
hinds.append(res[0])
else:
fores.append(res[0])
if c.target == TargetsEnum.LEFT_HIND:
self._leftHind = res[0]
elif c.target == TargetsEnum.RIGHT_HIND:
self._rightHind = res[0]
elif c.target == TargetsEnum.RIGHT_FORE:
self._rightFore = res[0]
elif c.target == TargetsEnum.LEFT_FORE:
self._leftFore = res[0]
for k in c.keys:
frames = [
['translateX', k.value.x, k.inTangentMaya[0], k.outTangentMaya[0]],
['translateY', k.value.y, k.inTangentMaya[1], k.outTangentMaya[1]],
['translateZ', k.value.z, k.inTangentMaya[2], k.outTangentMaya[2]]
]
for f in frames:
cmds.setKeyframe(
res[0],
attribute=f[0],
time=k.time,
value=f[1],
inTangentType=f[2],
outTangentType=f[3]
)
if k.event == 'land':
printResult = cmds.polyCylinder(
name=c.target + '_print1',
radius=radius,
height=(1.0 if isHind else 5.0)
)
cmds.move(k.value.x, k.value.y, k.value.z, printResult[0])
groupItems.append(printResult[0])
cfg = self._data.configs
name = 'cyc' + str(int(cfg.get(GaitConfigEnum.CYCLES))) + \
'_ph' + str(int(cfg.get(GaitConfigEnum.PHASE))) + \
'_gad' + str(int(cfg.get(SkeletonConfigEnum.FORE_OFFSET).z)) + \
'_step' + str(int(cfg.get(SkeletonConfigEnum.STRIDE_LENGTH)))
cube = cmds.polyCube(name='pelvic_reference', width=20, height=20, depth=20)
self._hips = cube[0]
groupItems.append(cube[0])
cmds.move(0, 100, 0, cube[0])
backLength = self._data.configs.get(SkeletonConfigEnum.FORE_OFFSET).z - \
self._data.configs.get(SkeletonConfigEnum.HIND_OFFSET).z
cube2 = cmds.polyCube(name='pectoral_comparator', width=15, height=15, depth=15)
cmds.move(0, 115, backLength, cube2[0])
cmds.parent(cube2[0], cube[0], absolute=True)
cmds.expression(
string="%s.translateZ = 0.5*abs(%s.translateZ - %s.translateZ) + min(%s.translateZ, %s.translateZ)" %
(cube[0], hinds[0], hinds[1], hinds[0], hinds[1])
)
cube = cmds.polyCube(name='pectoral_reference', width=15, height=15, depth=15)
self._pecs = cube[0]
groupItems.append(cube[0])
cmds.move(0, 100, 0, cube[0])
cmds.expression(
string="%s.translateZ = 0.5*abs(%s.translateZ - %s.translateZ) + min(%s.translateZ, %s.translateZ)" %
(cube[0], fores[0], fores[1], fores[0], fores[1])
)
self._group = cmds.group(*groupItems, world=True, name=name)
cfg = self._data.configs
info = 'Gait Phase: ' + \
str(cfg.get(GaitConfigEnum.PHASE)) + \
'\nGleno-Acetabular Distance (GAD): ' + \
str(cfg.get(SkeletonConfigEnum.FORE_OFFSET).z) + \
'\nStep Length: ' + \
str(cfg.get(SkeletonConfigEnum.STRIDE_LENGTH)) + \
'\nHind Duty Factor: ' + \
str(cfg.get(GaitConfigEnum.DUTY_FACTOR_HIND)) + \
'\nFore Duty Factor: ' + \
str(cfg.get(GaitConfigEnum.DUTY_FACTOR_FORE)) + \
'\nCycles: ' + \
str(cfg.get(GaitConfigEnum.CYCLES))
cmds.select(self._group)
if not cmds.attributeQuery('notes', node=self._group, exists=True):
cmds.addAttr(longName='notes', dataType='string')
cmds.setAttr(self._group + '.notes', info, type='string')
self.createShaders()
self.createRenderEnvironment()
minTime = min(0, int(cmds.playbackOptions(query=True, minTime=True)))
deltaTime = cfg.get(GeneralConfigEnum.STOP_TIME) - cfg.get(GeneralConfigEnum.START_TIME)
maxTime = max(
int(float(cfg.get(GaitConfigEnum.CYCLES))*float(deltaTime)),
int(cmds.playbackOptions(query=True, maxTime=True))
)
cmds.playbackOptions(
minTime=minTime, animationStartTime=minTime, maxTime= maxTime, animationEndTime=maxTime
)
cmds.currentTime(0, update=True)
cmds.select(self._group)
def _handleExampleButton(self):
"""
This callback creates a polygonal cylinder in the Maya scene.
"""
random.seed(1234)
#check
sphereList = cmds.ls('hydrogen1','hydrogen2', 'oxygen','H2O')
if len(sphereList)>0:
cmds.delete(sphereList)
#create 2 hydrogen and oxygen
h1 = cmds.polySphere(r=12.0, name='hydrogen1')
h2 = cmds.polySphere(r=12.0, name='hydrogen2')
oxygen = cmds.polySphere(r=15.0, name='oxygen')
#move
cmds.move(-15,0,0,h1)
cmds.move(15,0,0,h2)
cmds.xform(h1, piv=[0,0,0],ws=True)
cmds.xform(h2, piv=[0,0,0],ws=True)
cmds.rotate(0,'75',0,h1)
#group hydrogen and oxygen together
H2O = cmds.group(empty=True, name='H2O#')
cmds.parent('hydrogen1','hydrogen2','oxygen','H2O1')
#add color
def createMaterial( name, color, type ):
cmds.sets( renderable=True, noSurfaceShader=True, empty=True, name=name + 'SG' )
cmds.shadingNode( type, asShader=True, name=name )
cmds.setAttr( name+'.color', color[0], color[1], color[2], type='double3')
cmds.connectAttr(name+'.outColor', name+'SG.surfaceShader')
def assignMaterial (name, object):
cmds.sets(object, edit=True, forceElement=name+'SG')
def assignNewMaterial( name, color, type, object):
createMaterial (name, color, type)
assignMaterial (name, object)
#H is white and O is red
assignNewMaterial('Red', (1,0,0), 'lambert', 'oxygen');
assignNewMaterial('White',(1,1,1),'lambert', 'hydrogen1');
assignMaterial('White', 'hydrogen2');
#key frame
def keyFullRotation( pObjectName, pStartTime, pEndTime, pTargetAttribute,pValueStart, pvalueEnd ):
keyt = (pStartTime[0], pStartTime[0])
cmds.cutKey( pObjectName, time=(keyt, keyt), attribute=pTargetAttribute )
cmds.setKeyframe( pObjectName, time=pStartTime, attribute=pTargetAttribute, value=pValueStart )
cmds.setKeyframe( pObjectName, time=pEndTime, attribute=pTargetAttribute, value=pvalueEnd )
#cmds.selectKey( pObjectName, time=(pStartTime, [pEndTime]), attribute=pTargetAttribute, keyframe=True )
#duplicate H2O
for i in range(1,52):
cmds.duplicate(H2O)
#get random coord
x = random.uniform(-200,200)
y = random.uniform(0,300)
z = random.uniform(-200,200)
cmds.move(x,y,z, H2O)
xRot = random.uniform(0,360)
yRot = random.uniform(0,360)
zRot = random.uniform(0,360)
cmds.rotate(xRot,yRot,zRot,H2O)
startTime = cmds.playbackOptions(minTime=1 )
endTime = cmds.playbackOptions( maxTime=30 )
h2o = "H2O"+str(i)
for y in range(3):
coordsX = cmds.getAttr( h2o+'.translateX' )
coordsY = cmds.getAttr( h2o+'.translateY' )
coordsZ = cmds.getAttr( h2o+'.translateZ' )
ranStartX = int(random.uniform(0,15))
ranStartY = int(random.uniform(0,15))
ranStartZ = int(random.uniform(0,15))
ranEndX = int(random.uniform(15,30))
ranEndY = int(random.uniform(15,30))
ranEndZ = int(random.uniform(15,30))
x = random.uniform(coordsX-50,coordsX+50)
y = random.uniform(coordsY,coordsY+50)
z = random.uniform(coordsZ-50,coordsZ+50)
#print x,y,z
keyFullRotation( h2o, ranStartZ, 15, 'translateZ',coordsZ,z)
keyFullRotation( h2o, ranStartX, 15, 'translateX', coordsX,x)
keyFullRotation( h2o, ranStartY, 15, 'translateY', coordsY,y)
keyFullRotation( h2o, 15, ranEndZ, 'translateZ',z,coordsZ)
keyFullRotation( h2o, 15, ranEndX, 'translateX', x,coordsX)
keyFullRotation( h2o, 15, ranEndY, 'translateY', y,coordsY)
RcoordsX = cmds.getAttr( h2o+'.rotateX' )
RcoordsY = cmds.getAttr( h2o+'.rotateY' )
RcoordsZ = cmds.getAttr( h2o+'.rotateZ' )
xRot = random.uniform(0,360)
yRot = random.uniform(0,360)
zRot = random.uniform(0,360)
keyFullRotation( h2o, ranStartZ, 15, 'rotateZ',RcoordsZ,zRot)
keyFullRotation( h2o, ranStartX, 15, 'rotateX', RcoordsX,xRot)
keyFullRotation( h2o, ranStartY, 15, 'rotateY', RcoordsY,zRot)
keyFullRotation( h2o, 15, ranEndZ, 'rotateZ',zRot,RcoordsZ)
keyFullRotation( h2o, 15, ranEndX, 'rotateX', xRot,RcoordsX)
keyFullRotation( h2o, 15, ranEndY, 'rotateY', zRot,RcoordsY)
print 'done'
cmds.delete('H2O52')
def _handleExampleButton(self):
"""
This callback creates a polygonal cylinder in the Maya scene.
"""
random.seed(1234)
#check
sphereList = cmds.ls('hydrogen1', 'hydrogen2', 'oxygen', 'H2O')
if len(sphereList) > 0:
cmds.delete(sphereList)
#create 2 hydrogen and oxygen
h1 = cmds.polySphere(r=12.0, name='hydrogen1')
h2 = cmds.polySphere(r=12.0, name='hydrogen2')
oxygen = cmds.polySphere(r=15.0, name='oxygen')
#move
cmds.move(-15, 0, 0, h1)
cmds.move(15, 0, 0, h2)
cmds.xform(h1, piv=[0, 0, 0], ws=True)
cmds.xform(h2, piv=[0, 0, 0], ws=True)
cmds.rotate(0, '75', 0, h1)
#group hydrogen and oxygen together
H2O = cmds.group(empty=True, name='H2O#')
cmds.parent('hydrogen1', 'hydrogen2', 'oxygen', 'H2O1')
#add color
def createMaterial(name, color, type):
cmds.sets(renderable=True,
noSurfaceShader=True,
empty=True,
name=name + 'SG')
cmds.shadingNode(type, asShader=True, name=name)
cmds.setAttr(name + '.color',
color[0],
color[1],
color[2],
type='double3')
cmds.connectAttr(name + '.outColor', name + 'SG.surfaceShader')
def assignMaterial(name, object):
cmds.sets(object, edit=True, forceElement=name + 'SG')
def assignNewMaterial(name, color, type, object):
createMaterial(name, color, type)
assignMaterial(name, object)
#H is white and O is red
assignNewMaterial('Red', (1, 0, 0), 'lambert', 'oxygen')
assignNewMaterial('White', (1, 1, 1), 'lambert', 'hydrogen1')
assignMaterial('White', 'hydrogen2')
#key frame
def keyFullRotation(pObjectName, pStartTime, pEndTime,
pTargetAttribute, pValueStart, pvalueEnd):
keyt = (pStartTime[0], pStartTime[0])
cmds.cutKey(pObjectName,
time=(keyt, keyt),
attribute=pTargetAttribute)
cmds.setKeyframe(pObjectName,
time=pStartTime,
attribute=pTargetAttribute,
value=pValueStart)
cmds.setKeyframe(pObjectName,
time=pEndTime,
attribute=pTargetAttribute,
value=pvalueEnd)
#cmds.selectKey( pObjectName, time=(pStartTime, [pEndTime]), attribute=pTargetAttribute, keyframe=True )
#duplicate H2O
for i in range(1, 52):
cmds.duplicate(H2O)
#get random coord
x = random.uniform(-200, 200)
y = random.uniform(0, 300)
z = random.uniform(-200, 200)
cmds.move(x, y, z, H2O)
xRot = random.uniform(0, 360)
yRot = random.uniform(0, 360)
zRot = random.uniform(0, 360)
cmds.rotate(xRot, yRot, zRot, H2O)
startTime = cmds.playbackOptions(minTime=1)
endTime = cmds.playbackOptions(maxTime=30)
h2o = "H2O" + str(i)
for y in range(3):
coordsX = cmds.getAttr(h2o + '.translateX')
coordsY = cmds.getAttr(h2o + '.translateY')
coordsZ = cmds.getAttr(h2o + '.translateZ')
ranStartX = int(random.uniform(0, 15))
ranStartY = int(random.uniform(0, 15))
ranStartZ = int(random.uniform(0, 15))
ranEndX = int(random.uniform(15, 30))
ranEndY = int(random.uniform(15, 30))
ranEndZ = int(random.uniform(15, 30))
x = random.uniform(coordsX - 50, coordsX + 50)
y = random.uniform(coordsY, coordsY + 50)
z = random.uniform(coordsZ - 50, coordsZ + 50)
#print x,y,z
keyFullRotation(h2o, ranStartZ, 15, 'translateZ', coordsZ, z)
keyFullRotation(h2o, ranStartX, 15, 'translateX', coordsX, x)
keyFullRotation(h2o, ranStartY, 15, 'translateY', coordsY, y)
keyFullRotation(h2o, 15, ranEndZ, 'translateZ', z, coordsZ)
keyFullRotation(h2o, 15, ranEndX, 'translateX', x, coordsX)
keyFullRotation(h2o, 15, ranEndY, 'translateY', y, coordsY)
RcoordsX = cmds.getAttr(h2o + '.rotateX')
RcoordsY = cmds.getAttr(h2o + '.rotateY')
RcoordsZ = cmds.getAttr(h2o + '.rotateZ')
xRot = random.uniform(0, 360)
yRot = random.uniform(0, 360)
zRot = random.uniform(0, 360)
keyFullRotation(h2o, ranStartZ, 15, 'rotateZ', RcoordsZ, zRot)
keyFullRotation(h2o, ranStartX, 15, 'rotateX', RcoordsX, xRot)
keyFullRotation(h2o, ranStartY, 15, 'rotateY', RcoordsY, zRot)
keyFullRotation(h2o, 15, ranEndZ, 'rotateZ', zRot, RcoordsZ)
keyFullRotation(h2o, 15, ranEndX, 'rotateX', xRot, RcoordsX)
keyFullRotation(h2o, 15, ranEndY, 'rotateY', zRot, RcoordsY)
print 'done'
cmds.delete('H2O52')
def _handleRestoreButton(self):
ball = cmds.ls('ball')[0]
if(ball != None):
cmds.delete(ball)
cmds.polySphere(r=0.658, n='ball', ax = [0,0,0])
cmds.move(29.108,2,-0.2, 'ball')
