def regularLink(rot_X, move_X, SIZE, THICK, nsTmp):
Idx1 = 5
Idx2 = 8
#creates a torus
cmds.polyTorus(sa=8, sh=8, sr=THICK, n="Link1_")
cmds.rotate(90, 0, 0)
#select a range of faces
for i in range(9):
facet = nsTmp + ":Link1_.f[" + str(Idx1) + ":" + str(Idx2) + "]"
if i == 0:
cmds.select(nsTmp + ":Link1_" + ".f[0]")
else:
cmds.select(facet, add=True)
Idx1 = Idx1 + 8
if i == 7:
Idx2 = Idx2 + 7
else:
Idx2 = Idx2 + 8
#extrudes the faces and moves them to the left, thus making the elongated shape
cmds.polyExtrudeFacet(kft=True, ws=True, t=[2, 0, 0])
cmds.delete(ch=True)
cmds.makeIdentity(apply=True, t=1, r=1, s=1, n=2)
cmds.select(nsTmp + ":Link1_")
cmds.xform(cp=True)
cmds.scale(SIZE, SIZE, SIZE)
cmds.move(move_X, 0, 0)
cmds.rotate(rot_X, 0, 0)
cmds.polySmooth()
def make_shape(type, name, divisions):
"""
Creates shape based on argument passed
Args:
type: {cube, cone, cylinder, plane, torus, sphere}
name: name of the object
divisions: number of subdivisions we want to apply in x,y and z axis.
Same value will be taken in all axis.
Return:
None
"""
if type == 'cube':
mc.polyCube(n=name, sx=divisions, sy=divisions, sz=divisions)
elif type == 'cone':
mc.polyCone(n=name, sx=divisions, sy=divisions, sz=divisions)
elif type == 'cylinder':
mc.polyCylinder(n=name, sx=divisions, sy=divisions, sz=divisions)
elif type == 'plane':
mc.polyPlane(n=name, sx=divisions, sy=divisions)
elif type == 'torus':
mc.polyTorus(n=name, sx=divisions, sy=divisions)
elif type == 'sphere':
mc.polySphere(n=name, sx=divisions, sy=divisions)
else:
mc.polySphere()
def createItem(self,*args):
self.item = mc.optionMenu(self.objectSelectionMenu, query = True, value = True)
if self.item == "Sphere":
self.xSubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value1= True)
self.ySubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value2= True)
self.radiusInput = mc.intSliderGrp(self.radiusFloat, query = True, value = True)
mc.polySphere(n = "mySphere",sx = self.xSubInput, sy = self.ySubInput, r = self.radiusInput)
elif self.item == "Cube":
self.xSubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value1= True)
self.ySubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value2= True)
self.widthInput = mc.intSliderGrp(self.widthFloat, query = True, value = True)
self.depthInput = mc.intSliderGrp(self.depthFloat, query = True, value = True)
self.heightInput = mc.intSliderGrp(self.heightFloat, query = True, value = True)
mc.polyCube(n = "myCube", sx = self.xSubInput, sy = self.ySubInput, w = self.widthInput, d = self.depthInput, h = self.heightInput)
elif self.item == "Cylinder":
self.xSubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value1= True)
self.ySubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value2= True)
self.radiusInput = mc.intSliderGrp(self.radiusFloat, query = True, value = True)
mc.polyCylinder(n = "myCylinder",sx = self.xSubInput, sy = self.ySubInput, r = self.radiusInput)
elif self.item == "Cone":
self.xSubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value1= True)
self.ySubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value2= True)
self.radiusInput = mc.intSliderGrp(self.radiusFloat, query = True, value = True)
mc.polyCone(n = "myCone",sx = self.xSubInput, sy = self.ySubInput, r = self.radiusInput)
elif self.item == "Torus":
self.xSubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value1= True)
self.ySubInput = mc.intFieldGrp(self.objectSubFloat, query = True, value2= True)
self.radiusInput = mc.intSliderGrp(self.radiusFloat, query = True, value = True)
mc.polyTorus(n = "myTorus",sx = self.xSubInput, sy = self.ySubInput, r = self.radiusInput)
def createCrossAxel():
length = createMainAxel("CrossAvelWidth")
cmds.select(cu[0])
cmds.scale(1, 1, 1.5)
sideCylin1 = cmds.polyCylinder(r=0.4, h=length, sz=12, sx=12, sy=12)
cmds.rotate(90, 0, 0)
cmds.delete(ch=True)
cu[0] = cmds.polyBoolOp(sideCylin1[0], cu[0], op=2, n="block", ch=False)
Tor = cmds.polyTorus(sx=2, sy=2, r=0.377, sr=0.037)
cmds.rotate(90, 0, 0)
cmds.delete(ch=True)
cu[0] = cmds.polyBoolOp(Tor[0], cu[0], op=1, n="block", ch=False)
Tor2 = cmds.polyTorus(sx=2, sy=2, r=0.377, sr=0.037)
cmds.rotate(90, 0, 0)
cmds.move(length / 3.2, moveZ=True)
cmds.delete(ch=True)
cu[0] = cmds.polyBoolOp(Tor2[0], cu[0], op=1, n="block", ch=False)
Tor3 = cmds.polyTorus(sx=2, sy=2, r=0.377, sr=0.037)
cmds.rotate(90, 0, 0)
cmds.move(-1 * (length / 3.2), moveZ=True)
cmds.delete(ch=True)
cu[0] = cmds.polyBoolOp(Tor3[0], cu[0], op=1, n="block", ch=False)
cmds.select(cu[0])
cmds.rotate(0, 0, 45)
distance1 = 0.33
distance2 = 0.35
createSideEdgesAxel(length, distance1, distance2)
def squareLink(rot_X, rot_Y, move_X, SIZE, THICK, nsTmp):
cmds.polyTorus(sa=4, sr=THICK, n="Link1")
cmds.rotate(rot_Y, rotateY=True)
cmds.makeIdentity(apply=True, t=1, r=1, s=1, n=2)
cmds.rotate(rot_X, rotateX=True)
cmds.move(move_X, 0, 0)
cmds.scale(SIZE, SIZE, SIZE)
def HI(self):
if self.checkSphere.isChecked():
cmds.polySphere()
if self.checkTorus.isChecked():
cmds.polyTorus()
if self.checkCube.isChecked():
cmds.polyCube()
pass
def HI(self):
if self.checkSphere.isChecked():
cmds.polySphere()
if self.checkTorus.isChecked():
cmds.polyTorus()
if self.checkCube.isChecked():
cmds.polyCube()
pass
def MyGeo(geo):
if geo == "cube":
cmds.polyCube(w=10, h=3, d=3, sx=10, sy=2, sz=2, ch=1)
elif geo == "sphere":
cmds.polySphere(r=1, sx=20, sy=20, ch=1)
elif geo == "torus":
cmds.polyTorus(r=1, sr=0.5, tw=0, sx=20, sy=20, ch=1)
def RandomTorus():
cmds.polyTorus(sx=4, sy=4, r=random.randrange(1,50), sr=random.randrange(1,50))
cmds.select()
Transforms()
cmds.makeIdentity(apply=True, t=1, r=1, s=1, n=0)
created.append(cmds.ls(selection=True))
cmds.duplicate()
cmds.scale(-1,1,1)
created.append(cmds.ls())
def eightLink(rot_X, move_X, SIZE, THICK, nsTmp):
Idx1 = 5
Idx2 = 8
cmds.polyTorus(sa=8, sh=8, sr=THICK, n="Link1_")
cmds.rotate('90deg', 0, 0)
#select a range of faces
for i in range(9):
facet = nsTmp + ":Link1_.f[" + str(Idx1) + ":" + str(Idx2) + "]"
if i == 0:
cmds.select(nsTmp + ":Link1_" + ".f[0]")
else:
cmds.select(facet, add=True)
Idx1 = Idx1 + 8
if i == 7:
Idx2 = Idx2 + 7
else:
Idx2 = Idx2 + 8
cmds.polyExtrudeFacet(kft=True, ws=True, t=[1, 0, 0])
cmds.polyExtrudeFacet(kft=True, ws=True, t=[1, 0, 0])
#select the vertexes and move them to make the 8 shape
num = 44
for i in range(7):
if i == 0:
cmds.select(nsTmp + ':Link1_.vtx[' + str(40) + ':' + str(41) + ']')
else:
cmds.select(nsTmp + ':Link1_.vtx[' + str(num) + ']', add=True)
num += 2
cmds.move(0, -0.8, 0, r=True)
num = 45
for i in range(7):
if i == 0:
cmds.select(nsTmp + ':Link1_.vtx[' + str(42) + ':' + str(43) + ']')
else:
cmds.select(nsTmp + ':Link1_.vtx[' + str(num) + ']', add=True)
num += 2
cmds.move(0, 0.8, 0, r=True)
cmds.delete(ch=True)
cmds.makeIdentity(apply=True, t=1, r=1, s=1, n=2)
cmds.select(nsTmp + ":Link1_")
cmds.xform(cp=True)
cmds.scale(SIZE, SIZE, SIZE)
cmds.move(move_X, 0, 0)
cmds.rotate(rot_X, 0, 0)
cmds.polySmooth()
def RandomTorus():
cmds.polyTorus(sx=4,
sy=4,
r=random.randrange(1, 50),
sr=random.randrange(1, 50))
cmds.select()
Transforms()
cmds.makeIdentity(apply=True, t=1, r=1, s=1, n=0)
created.append(cmds.ls(selection=True))
cmds.duplicate()
cmds.scale(-1, 1, 1)
created.append(cmds.ls())
def createTargetPrim(*args):
#delete existing target primitive
#deleteTargetPrim()
createTargetPrim.targetprim = 0
if UI.targetPrim == 'Cube':
createTargetPrim.targetprim = mc.polyCube(sx=1, sy=1, sz=1)
mc.hyperShade(assign=Materials.shader)
#mc.polyColorPerVertex( rgb=(UI.targetR, UI.targetG, UI.targetB), cdo = True )
#if UI.randomOrientation != False:
#mc.select(targetprim)
mc.rotate(UI.targetOrientation[0],
UI.targetOrientation[1],
UI.targetOrientation[2],
a=True)
if UI.targetMiddle != True:
mc.move(random.randint(-10, 10), random.randint(-10, 10), 35)
else:
mc.move(0, 0, 35)
if UI.targetPrim == 'Sphere':
mc.polySphere(sx=24, sy=24, r=1)
mc.hyperShade(assign=Materials.shader)
#mc.polyColorPerVertex( rgb=(UI.targetR, UI.targetG, UI.targetB), cdo = True )
if UI.targetMiddle != True:
mc.move(random.randint(-10, 10), random.randint(-10, 10), 35)
if UI.targetPrim == 'Cylinder':
mc.polyCylinder(sx=24, sy=2, sz=2)
mc.hyperShade(assign=Materials.shader)
#mc.polyColorPerVertex( rgb=(UI.targetR, UI.targetG, UI.targetB), cdo = True )
if UI.targetMiddle != True:
mc.move(random.randint(-10, 10), random.randint(-10, 10), 35)
if UI.targetPrim == 'Torus':
mc.polyTorus(n='target', sx=24, sy=16, r=2, sr=1)
mc.hyperShade(assign=Materials.shader)
#mc.polyColorPerVertex( rgb=(UI.targetR, UI.targetG, UI.targetB), cdo = True )
if UI.targetMiddle != True:
mc.move(random.randint(-10, 10), random.randint(-10, 10), 35)
if UI.targetPrim == 'Cone':
mc.polyCone(sx=1, sy=1, sz=1)
mc.hyperShade(assign=Materials.shader)
#mc.polyColorPerVertex( rgb=(UI.targetR, UI.targetG, UI.targetB), cdo = True )
if UI.targetMiddle != True:
mc.move(random.randint(-10, 10), random.randint(-10, 10), 35)
def __init__(self, index, planet_radius, number_of_rings):
# The index is used when determining the scale and rotation of the ring.
self.__index = index
# To shrink each successive ring, a decrement value is calculated.
self.__scale_decrement_value = .5 / number_of_rings
# Names the ring.
name = "Ring"
# If this is the first ring created, create a polyTorus.
if (index == 0):
# Since this is the first ring, the outer radius is stored and used when calculating how far away the moons and starfields should be.
radius = self.__radius = float(planet_radius + number_of_rings)
# The torus that makes the ring is created then smoothed.
instance_nodes = polyTorus(name=name,
radius=radius,
sectionRadius=(radius / 100))
polySmooth(divisions=2)
# Since this is the first ring, its transform node is also stored as a class member.
self.__transform_node = instance_nodes[0]
# Otherwise, instance the initial ring.
else:
# Creates an instance of the initial ring and stores the nodes.
nodes = instance(name)
# The transform node of the ring is stored as an instance member.
self.__transform_node = nodes[0]
def createTargetPrim(*args):
#delete existing target primitive
#deleteTargetPrim()
createTargetPrim.targetprim = 0
if UI.targetPrim == 'Cube':
createTargetPrim.targetprim = mc.polyCube(sx=1, sy=1, sz=1)
assignMatAndPlaceInScene(createTargetPrim.targetprim[0])
if UI.targetPrim == 'Sphere':
createTargetPrim.targetprim = mc.polySphere(sx=24, sy=24, r=1)
assignMatAndPlaceInScene(createTargetPrim.targetprim[0])
if UI.targetPrim == 'Cylinder':
createTargetPrim.targetprim = mc.polyCylinder(sx=24, sy=2, sz=2)
assignMatAndPlaceInScene(createTargetPrim.targetprim[0])
if UI.targetPrim == 'Torus':
createTargetPrim.targetprim = mc.polyTorus(n='target',
sx=24,
sy=16,
r=2,
sr=1)
assignMatAndPlaceInScene(createTargetPrim.targetprim[0])
if UI.targetPrim == 'Cone':
createTargetPrim.targetprim = mc.polyCone(sx=1, sy=1, sz=1)
assignMatAndPlaceInScene(createTargetPrim.targetprim[0])
def MakeWheel(radius=3.6): # Function returns group name for a wheel
myListOfRotValues = range(0, 360, 20)
wheel = []
x = 0
for curCyl in myListOfRotValues:
curSpoke = mc.polyCylinder(r=0.1, h=radius)
wheel.append(curSpoke[0])
mc.move(0, radius / 2, 0)
mc.move(0, 0, 0, curSpoke[0] + ".scalePivot",
curSpoke[0] + ".rotatePivot")
mc.rotate(20 * x, 0, 0)
x += 1
wheelCenter = mc.polyCylinder(ax=(1, 0, 0))
wheel.append(wheelCenter[0])
mc.scale(0.22, 0.6, 0.6)
wheelEdge = mc.polyTorus(r=radius, sr=0.3, sx=40, sy=5, ax=(1, 0, 0))
mc.scale(0.537, 1, 1)
wheel.append(wheelEdge[0])
finalWheel = mc.group(wheel)
if trainSpeed > 0:
circumference = 2 * 3.14 * radius
wheelRotationTime = (circumference / trainSpeed)
mc.expression(s="rotateX = time * (360 / " + str(wheelRotationTime) +
");",
o=finalWheel)
return finalWheel
def __init__(self, ringNumber, radius, linkRadius):
#diffirent naming for the first ring
if ringNumber == 0:
(self.transform, self.shape) = cmds.polyTorus(r=radius,
sr=linkRadius,
name="Chain_root")
self.ringName = self.transform
#Naming for all other rings.
else:
(self.transform,
self.shape) = cmds.polyTorus(r=radius,
sr=linkRadius,
name="ring_" + str(ringNumber))
self.ringName = self.transform
self.ringNumber = ringNumber
def get_geometry(geo_type='sphere', sx=8, sy=8, sz=0):
the_primitive = 'Fancy_geo_primitive'
output_edges = []
if geo_type == 'sphere':
cmds.polySphere(name=the_primitive, sx=sx, sy=sy)
cmds.rotate(10, 0, 20, the_primitive)
elif geo_type == 'cube':
cmds.polyCube(name=the_primitive, sx=sx, sy=sy, sz=sz)
cmds.rotate(30, 0, 10, the_primitive)
elif geo_type == 'cylinder':
cmds.polyCylinder(name=the_primitive, sx=sx, sy=sy, sz=sz)
cmds.rotate(10, 0, 20, the_primitive)
elif geo_type == 'cone':
cmds.polyCone(name=the_primitive, sx=sx, sy=sy, sz=sz)
cmds.move(0, -0.2, 0, the_primitive)
cmds.rotate(170, 0, 10, the_primitive)
elif geo_type == 'torus':
cmds.polyTorus(name=the_primitive, sx=sx, sy=sy)
cmds.rotate(30, 0, 40, the_primitive)
elif geo_type == 'plane':
cmds.polyPlane(name=the_primitive, sx=sx, sy=sy)
cmds.rotate(30, 0, 45, the_primitive)
edge_count = cmds.polyEvaluate(the_primitive)['edge']
for i in range(edge_count):
all_edges = cmds.polyListComponentConversion('{0}.e[{1}]'.format(
the_primitive, i),
tv=True)
edge_start_end = cmds.ls(all_edges, flatten=True)
output_edges.append([
cmds.pointPosition(edge_start_end[0]),
cmds.pointPosition(edge_start_end[1])
])
cmds.delete(the_primitive)
return output_edges
def rootZ( inBitName ):
bit = cmds.polyTorus( axis=[0,0,1],
radius=6,
sectionRadius=0.2,
twist=0,
subdivisionsX=8,
subdivisionsY=3,
name=inBitName )
# Return the name of the newly created bit.
return bit[0]
def create_geometry(geo_type, sx, sy, sz=0):
if geo_type == 'sphere':
cmds.polySphere(sx=sx, sy=sy)
elif geo_type == 'cube':
cmds.polyCube(sx=sx, sy=sy, sz=sz)
elif geo_type == 'cylinder':
cmds.polyCylinder(sx=sx, sy=sy, sz=sz)
elif geo_type == 'cone':
cmds.polyCone(sx=sx, sy=sy, sz=sz)
elif geo_type == 'torus':
cmds.polyTorus(sx=sx, sy=sy)
elif geo_type == 'plane':
cmds.polyPlane(sx=sx, sy=sy)
def main(): print "We're Running a script INSIDE MAYA!" print(math.sin(6)) x = cmds.polySphere(radius=2.5) print x print cmds.polySphere(x[0], query=True, radius=True) cmds.polyCube() cmds.polyTorus() cmds.polySphere(radius=6.0) x = cmds.polySphere(radius=8.0) print x x = cmds.polySphere(radius=30.0) print x x = cmds.polySphere(radius=70.0) print x x = cmds.polySphere(radius=100.0) print x x = cmds.polySphere(radius=50.0) print x
def rootX( inBitName ):
# Bit is a list. [name, meshType]
bit = cmds.polyTorus( axis=[1,0,0],
radius=6,
sectionRadius=0.2,
twist=0,
subdivisionsX=8,
subdivisionsY=3,
name=inBitName )
# Return the name of the newly created bit.
return bit[0]
def __init__(self, ringNumber, radius, linkRadius):
#diffirent naming for the first ring
if ringNumber == 0:
(self.transform, self.shape) = cmds.polyTorus(r=radius,
sr=linkRadius,
name="Chain_root")
self.ringName = self.transform
# change pivot to allow easier whole chain scaling
# cmds.setAttr(self.transform,ax)
#Naming for all other rings. Also parents the rings to the first ring.
else:
(self.transform,
self.shape) = cmds.polyTorus(r=radius,
sr=linkRadius,
name="ring_" + str(ringNumber))
self.ringName = self.transform
self.ringNumber = ringNumber
def createTire():
global cu
cu = cmds.polyTorus(sx=2, sy=2, r=0.5, sr=0.25)
cmds.scale(1, 1.712, 1)
cmds.delete(ch=True)
middle = cmds.polyCylinder(r=0.45, h=2, sz=4, sy=12)
cu[0] = cmds.polyBoolOp(cu[0], middle[0], op=2, n="block", ch=False)
extrudeForTire()
cmds.delete(ch=True)
pip1 = cmds.polyPipe(r=0.4906, h=1.5094, t=0.0755)
cu[0] = cmds.polyUnite(cu[0], pip1[0], n="block", ch=False)
pip2 = cmds.polyPipe(r=0.4150, h=1.1321, t=0.0)
cu[0] = cmds.polyUnite(cu[0], pip2[0], n="block", ch=False)
def connector():
rgb = cmds.colorSliderGrp('miscColour', query=True, rgbValue=True)
cX = 1.6
cY = 0.6
cZ = 0.6
cMiddle = cmds.polyCylinder( h = 1.6/2, r = 0.5/2, sz = 1 )
cmds.rotate( 90, rotateZ = True )
cmds.move( (1.6/2)/2, moveX = True )
cInsideRidge = cmds.polyCylinder( h = 0.1, r = cY/2, sz = 1 )
cmds.rotate( 90, rotateZ = True )
cmds.move( 0.1/2, moveX = True )
cOutsideRidge = cmds.polyTorus( sr = 0.05, r = (cY/2.6))
cmds.rotate( 90, rotateZ = True )
cmds.move( (cX/2) - (0.08/2), moveX = True )
connector = cmds.polyCBoolOp( cMiddle, cInsideRidge, op = 1 )
connector = cmds.polyCBoolOp( connector, cOutsideRidge, op = 1 )
cCut = createRoundedBlock( cY * 0.6, cY * 0.2, 5, 2 )
cmds.move( cY + 0.1, moveX = True )
connector = cmds.polyCBoolOp( connector, cCut, op = 2 )
cMCut = cmds.polyCylinder( h = 1.6, r = 0.45/2, sz = 1 )
cmds.rotate( 90, rotateZ = True )
cmds.move( (1.6/2)/2, moveX = True )
connector = cmds.polyCBoolOp( connector, cMCut, op = 2 )
connectorL = cmds.duplicate( connector )
cmds.scale( -1, scaleX = True )
cmds.move( -(1.6/2), moveX = True )
connector = cmds.polyUnite( connector, connectorL)
myShader = cmds.shadingNode( 'phong', asShader=True )
cmds.setAttr( myShader+".color", rgb[0], rgb[1], rgb[2], type='double3')
cmds.setAttr( myShader+".reflectivity", 0 )
cmds.select( connector )
cmds.hyperShade( assign = myShader )
cmds.delete( ch = True )
def createParticleSystem_goal():
# Create a constant sized particle object following a deformed torus shape (using goal)
cmds.file(new=True, force=True)
# Create a torus, we will use it as goal
xrez = 14
yrez = 8
goalTorus = cmds.polyTorus( r=1, sr=0.5, tw=0, sx=xrez, sy=yrez, ax=(0, 1, 0), cuv=1, ch=0)[0]
# nParticle creation depends on an optoinVar value, make sure we use the default one
cmds.optionVar( sv=("NParticleStyle","Points") )
# Emit a lot of particle, the actual number will be limited to the max particle attribute in the particleShape
emitter = cmds.emitter(dx=1, dy=0, dz=0, sp=0.1, pos=(0, 5, 0),rate=2500)[0]
particleSystem, particleSystemShape = cmds.nParticle(n="nParticle_test_goal")
cmds.setAttr('%s.lfm' % particleSystemShape, 0) # live forever
cmds.setAttr('%s.particleRenderType' % particleSystemShape, 7) # Blobby, to see radius
cmds.setAttr('%s.maxCount' % particleSystemShape, xrez*yrez) # max count is the number of vertices on the torus
cmds.connectDynamic( particleSystemShape, em=emitter)
# Create Goal
cmds.goal(particleSystem, w=1, utr=0, g=goalTorus);
# Create Initial state to we start with the correct amount of particle
# NOTE: When using this script in command line, the first frame is not correctly evaluated and the particleShape is empty
# This doesn't happens in interactive maya
for i in range(1, 10):
cmds.currentTime(i)
cmds.saveInitialState(particleSystemShape)
cmds.currentTime(1)
bend, bendHandle = cmds.nonLinear( goalTorus, type="bend", lowBound=-1, highBound=1, curvature=0)
cmds.setAttr( "%s.rotateZ" % bendHandle, 90)
cmds.setKeyframe( "%s.curvature" % bend, v=0, t=1, inTangentType="flat", outTangentType="flat")
cmds.setKeyframe( "%s.curvature" % bend, v=-130, t=12, inTangentType="flat", outTangentType="flat")
cmds.setKeyframe( "%s.curvature" % bend, v=130, t=24, inTangentType="flat", outTangentType="flat")
# Make the bend animation loop
cmds.setInfinity( bend, poi="oscillate", attribute="curvature")
return particleSystem, particleSystemShape
def createParticleSystem_goal():
# Create a constant sized particle object following a deformed torus shape (using goal)
cmds.file(new=True, force=True)
# Create a torus, we will use it as goal
xrez = 14
yrez = 8
goalTorus = cmds.polyTorus(r=1, sr=0.5, tw=0, sx=xrez, sy=yrez, ax=(0, 1, 0), cuv=1, ch=0)[0]
# nParticle creation depends on an optoinVar value, make sure we use the default one
cmds.optionVar(sv=("NParticleStyle", "Points"))
# Emit a lot of particle, the actual number will be limited to the max particle attribute in the particleShape
emitter = cmds.emitter(dx=1, dy=0, dz=0, sp=0.1, pos=(0, 5, 0), rate=2500)[0]
particleSystem, particleSystemShape = cmds.nParticle(n="nParticle_test_goal")
cmds.setAttr('%s.lfm' % particleSystemShape, 0) # live forever
cmds.setAttr('%s.particleRenderType' % particleSystemShape, 7) # Blobby, to see radius
cmds.setAttr('%s.maxCount' % particleSystemShape, xrez * yrez) # max count is the number of vertices on the torus
cmds.connectDynamic(particleSystemShape, em=emitter)
# Create Goal
cmds.goal(particleSystem, w=1, utr=0, g=goalTorus);
# Create Initial state to we start with the correct amount of particle
# NOTE: When using this script in command line, the first frame is not correctly evaluated and the particleShape is empty
# This doesn't happens in interactive maya
for i in range(1, 10):
cmds.currentTime(i)
cmds.saveInitialState(particleSystemShape)
cmds.currentTime(1)
bend, bendHandle = cmds.nonLinear(goalTorus, type="bend", lowBound=-1, highBound=1, curvature=0)
cmds.setAttr("%s.rotateZ" % bendHandle, 90)
cmds.setKeyframe("%s.curvature" % bend, v=0, t=1, inTangentType="flat", outTangentType="flat")
cmds.setKeyframe("%s.curvature" % bend, v=-130, t=12, inTangentType="flat", outTangentType="flat")
cmds.setKeyframe("%s.curvature" % bend, v=130, t=24, inTangentType="flat", outTangentType="flat")
# Make the bend animation loop
cmds.setInfinity(bend, poi="oscillate", attribute="curvature")
return particleSystem, particleSystemShape
def worldIgnoreSlope():
#new file
cmds.file(force=True, new=True)
#move the camera
cmds.setAttr('persp.translateX', 133.600)
cmds.setAttr('persp.translateY', 97.700)
cmds.setAttr('persp.translateZ', 133.600)
#create a poly cube
ptorus = cmds.polyTorus(r=80, sr=6, sh=15, sx=100)
pcube = cmds.polyCube(w=0.1, h=2, d=0.1)
#create a new MASH network
mashNetwork = mapi.Network()
mashNetwork.createNetwork("CurlNoiseNetwork")
shape = cmds.listRelatives(ptorus[0], s=True)[0]
mashNetwork.meshDistribute(shape, 1)
cmds.setAttr(mashNetwork.distribute + '.floodMesh', 1)
cmds.setAttr(mashNetwork.distribute + '.pointCount', 20)
#add a World node
node = mashNetwork.addNode("MASH_World")
#set some attributes on the world node using the .name of the node instance
cmds.setAttr(node.name + ".clusterMode", 7)
cmds.setAttr(node.name + ".sparsity", 0.5)
cmds.setKeyframe(node.name, attribute='ecosystemAge', t=['0sec'], v=0.0)
cmds.setKeyframe(node.name, attribute='ecosystemAge', t=['5sec'], v=120.0)
cmds.setAttr(node.name + ".ignoreSlope", 1)
node.addGroundPlane(ptorus[0])
jsonString = '[{"Slope": 0.6, "colorBar": [255, 255, 255], "Id Min": 0, "Name": "Default Genotype", "Seed Count": 4, "Resiliance": 0.2, "Age": 100, "Soil Quality": 0.5, "Id": 0, "Temperature": 0.5, "Rate": 0.12, "Id Max": 0, "Id Color": [0.0, 0.0, 0.0], "Moisture": 0.5, "Variance": 0.2, "Seed Age": 10, "Size": 1.0}]' #
cmds.setAttr(node.name + '.genotypeJSON', jsonString, type='string')
cmds.hide(ptorus[0])
cmds.flushIdleQueue()
#playblast
cmds.playbackOptions(animationEndTime='5sec')
cmds.playblast(format="qt", viewer=True, p=100)
def floatingLanterns():
h = cmds.floatSliderGrp(height, q=True, value=True) # radius of lantern
r = cmds.floatSliderGrp(radius, q=True, value=True) # height of lantern
x = cmds.floatSliderGrp(xCenter, q=True, value=True) # center of field
y = cmds.floatSliderGrp(yBottom, q=True, value=True) # bottom of field
z = cmds.floatSliderGrp(zCenter, q=True, value=True) # center of field
a = cmds.floatSliderGrp(yApex, q=True,
value=True) # highest floating height
n = cmds.intSliderGrp(rowcol, q=True,
value=True) # number of rows/columns of lanterns
m = cmds.floatSliderGrp(
dist, q=True,
value=True) # initial distance between vertices of cylinders
f = cmds.intSliderGrp(frames, q=True,
value=True) # number of frames in animation
bc = cmds.colorSliderGrp(baseColor, q=True,
rgb=True) # base color of lanterns
random.seed(12345)
cmds.select(all=True)
cmds.delete()
paper = cmds.polyCylinder(r=r,
h=h,
sx=50,
sy=1,
sz=1,
ax=(0, 1, 0),
rcp=0,
cuv=3,
ch=1,
n='myPaper')
cmds.select(cl=True)
for i in range(50, 100):
cmds.select(paper[0] + '.f[' + str(i) + ']', tgl=True)
cmds.delete() # deletes bottom faces of cylinder for opening of lantern
cmds.select(paper[0])
cmds.move(0, h / 2, 0) # moves lantern paper so that it sit on mirror
wick = cmds.polyCube(w=0.5 * r, h=0.01 * r, d=0.5 * r, n='myWick')
cmds.rotate(0, 45, 0)
wickShader = cmds.shadingNode('lambert', asShader=True, n='myWickShader')
SG1 = cmds.sets(renderable=True, noSurfaceShader=True, empty=True)
cmds.connectAttr((wickShader + '.outColor'), (SG1 + '.surfaceShader'), f=1)
cmds.setAttr('myWickShader.color', 0.2, 0.2, 0.2)
cmds.setAttr('myWickShader.ambientColor', 0.2, 0.2, 0.2)
cmds.sets(wick[0], e=1, forceElement=SG1)
rim = cmds.polyTorus(r=r, sr=0.02 * r, sx=50)
len = r - 0.25 * r * math.sqrt(
2) # length of strings = dist between rim and wick
stringGroup = cmds.group(empty=True, name='myStringGroup')
for i in range(0, 4):
mv = len / 2 + 0.25 * r * math.sqrt(2)
string = cmds.polyCylinder(r=0.01 * r, h=len, n='myString#')
cmds.select(string[0])
xRotate = [90, 90, 0, 0]
zRotate = [0, 0, 90, 90]
xMove = [0, 0, mv, -mv]
zMove = [mv, -mv, 0, 0]
cmds.rotate(xRotate[i], 0, zRotate[i], string)
cmds.move(xMove[i], 0, zMove[i], string)
cmds.parent(string, stringGroup)
strings = cmds.polyUnite(
rim, stringGroup,
n='myStrings') # unites rim and strings into one poly object
stringShader = cmds.shadingNode('lambert',
asShader=True,
n='myStringShader')
SG2 = cmds.sets(renderable=True, noSurfaceShader=True, empty=True)
cmds.connectAttr((stringShader + '.outColor'), (SG2 + '.surfaceShader'),
f=1)
cmds.setAttr('myStringShader.color', 1, 1, 1)
cmds.setAttr('myStringShader.ambientColor', 1, 1, 1)
cmds.sets(strings[0], e=1, forceElement=SG2)
fire = cmds.polyUnite(
wick, strings,
n='myFire') # unites wick and strings (rim + strings) into one object
cmds.move(0, 0.01, 0, fire) # moves fire items to sit on top of mirror
lanternGroup = cmds.group(paper, fire, n='myLanternGroup')
lanternInstanceGroup = cmds.group(empty=True,
name='myLanternInstanceGroup')
for i in range(0, n * n):
instanceLanternGroup = cmds.group(empty=True,
n='myLanternGroupInstance#')
instancePaper = cmds.duplicate(paper[0], n='paperInstance#')
# randomize color of lanterns
r = random.uniform(bc[0] - 0.1, bc[0])
g = random.uniform(bc[1] - 0.1, bc[1] + 0.1)
b = random.uniform(bc[2] - 0.2, bc[2] + 0.2)
paperShader = cmds.shadingNode('lambert',
asShader=True,
n='myPaperShader#')
SG3 = cmds.sets(renderable=True, noSurfaceShader=True, empty=True)
cmds.connectAttr((paperShader + '.outColor'), (SG3 + '.surfaceShader'),
f=1)
cmds.setAttr('myPaperShader' + str(i + 1) + '.color', r, g, b)
cmds.setAttr('myPaperShader' + str(i + 1) + '.ambientColor', r, g, b)
cmds.sets(instancePaper[0], e=1, forceElement=SG3)
cmds.parent(instancePaper, instanceLanternGroup)
instanceFire = cmds.duplicate(fire, n='fireInstance#')
cmds.parent(instanceFire, instanceLanternGroup)
instanceLantern = cmds.polyUnite(instanceLanternGroup,
n='myLanternInstance#')
cmds.parent(instanceLantern, instanceLanternGroup)
cmds.parent(instanceLanternGroup, lanternInstanceGroup)
cmds.rotate(0, random.uniform(0, 360), 0, instanceLantern)
scalingFactorXZ = random.uniform(1, 1.5)
scalingFactorY = random.uniform(1, 1.5)
cmds.scale(scalingFactorXZ, scalingFactorY, scalingFactorXZ,
instanceLantern)
cmds.setAttr('myLanternInstance' + str(i + 1) + '.castsShadows', 0)
cmds.setAttr('myLanternInstance' + str(i + 1) + '.receiveShadows', 0)
# variables for placement of lanterns in rows/colums on mirror
nf = float(n)
mf = float(m)
s = (nf - 1) / 2 * mf # starting point of random placement
xMove = float(x - s + mf * (int(i / nf))) # determines lantern row
zMove = float(z - s + mf * (i % nf)) # determines lantern column
yMove = y + 0.02
# sets lantern's floating path
ran = random.uniform(-a / 10, a / 10)
path = cmds.curve(p=[(xMove, yMove, zMove),
(xMove, yMove + a / 5, zMove),
(xMove + ran, yMove + 2 * a / 5, zMove + ran),
(xMove, yMove + 3 * a / 5, zMove),
(xMove - ran, yMove + 4 * a / 5, zMove - ran),
(xMove, yMove + a, zMove)],
n='myPath#')
cmds.parent(path, instanceLanternGroup)
cmds.select(instanceLantern, path)
cmds.pathAnimation(fm=True,
f=True,
fa='y',
ua='x',
wut='objectrotation',
wu=(0, 1, 0),
iu=False,
inverseFront=False,
b=False,
stu=random.uniform(0, f / 2),
etu=random.uniform(f, 2 * f))
cmds.setAttr('myPath' + str(i + 1) + '.visibility', 0)
lantern = cmds.polyUnite(lanternGroup, n='myLantern')
cmds.hide(lantern[0]) # hides initial lantern
cmds.xform(instanceLanternGroup, centerPivots=True)
mirror = cmds.polyPlane(ax=(0, 1, 0), n='myMirror')
cmds.scale(
n * m + m / 2, n * m + m / 2, mirror, xz=True
) # mirror side length = (# of lantern rows/columns)*(dist b/t lanterns)+half*(dist b/t lanterns)
mirrorShader = cmds.shadingNode('blinn',
asShader=True,
name='myMirrorShader')
cmds.setAttr('myMirrorShader.reflectivity', 1)
cmds.setAttr('myMirrorShader.refractions', 1)
cmds.setAttr('myMirrorShader.refractiveIndex', 5)
SG4 = cmds.sets(renderable=True, noSurfaceShader=True, empty=True)
cmds.connectAttr((mirrorShader + '.outColor'), (SG4 + '.surfaceShader'),
f=1)
cmds.sets(mirror[0], e=1, forceElement=SG4)
cmds.setAttr('myMirror.castsShadows', 0)
cmds.setAttr('myMirror.receiveShadows', 0)
cmds.select(cl=True)
def _polyTorus(self):
cmds.polyTorus()
def PolyToruses(\
x = random.uniform(-10,10),\
x_r = 1,\
y = random.uniform(0,20),\
y_r = 1,\
z = random.uniform(-10,10),\
z_r = 1,\
xRot = random.uniform( 0, 360 ),\
xRot_r = 10,\
yRot = random.uniform( 0, 360 ),\
yRot_r = 10,\
zRot = random.uniform( 0, 360 ),\
zRot_r = 10,\
r = random.uniform(0,2),\
r_r = .1,\
g = random.uniform(0,2),\
g_r = .1,\
b = random.randint(0,2),\
b_r = .1,\
scaleF = random.uniform( 0.3, 1.5 ),\
scaleF_r = .1,\
):
def change(start,min,max,rate):
if random.randint(0,5) == 0:
rate = (-1 * rate)
start += rate
if start < min or start > max:
rate = (-1 * rate)
start += rate
return start,rate
for i in range( 0, 50 ):
#create cube
cmds.polyTorus( sx=1, sy=1, r=1, sr=1, n='torus{}'.format(i))
#vary location
x = change(x,-10,10,x_r)[0]
x_r = change(x,-10,10,x_r)[1]
y = change(y,0,20,y_r)[0]
y_r = change(y,0,20,y_r)[1]
z = change(z,-10,10,z_r)[0]
z_r = change(z,-10,10,z_r)[1]
#vary rotation
xRot = change(xRot,1,360,xRot_r)[0]
xRot_r = change(xRot,1,360,xRot_r)[1]
yRot = change(yRot,1,360,yRot_r)[0]
yRot_r = change(yRot,1,360,yRot_r)[1]
zRot = change(zRot,1,360,zRot_r)[0]
zRot_r = change(zRot,1,360,zRot_r)[1]
#vary color
r = change(r,0,2,r_r)[0]
r_r = change(r,0,2,r_r)[1]
g = change(g,0,2,g_r)[0]
g_r = change(g,0,2,g_r)[1]
b = change(b,0,2,b_r)[0]
b_r = change(b,0,2,b_r)[1]
#vary scale
scaleF = change(scaleF,0.3,1.5,scaleF_r)[0]
scaleF_r = change(scaleF,0.3,1.5,scaleF_r)[1]
#apply variabels
cmds.rotate( xRot, yRot, zRot, 'torus{}'.format(i))
cmds.scale(scaleF, scaleF, scaleF, 'torus{}'.format(i))
cmds.move( x, y, z, 'torus{}'.format(i))
cmds.sets( name='TorusMaterial{}'.format(i), renderable=True, empty=True )
cmds.shadingNode( 'phong', name='TorusShader{}'.format(i), asShader=True )
cmds.setAttr( 'TorusShader{}'.format(i)+'.color', r, g, b, type='double3' )
cmds.surfaceShaderList( 'TorusShader{}'.format(i), add='TorusMaterial{}'.format(i))
cmds.sets( 'torus{}'.format(i), forceElement='TorusMaterial{}'.format(i))
def MakeCar():
trainCarTop = []
carBody = mc.polyCube()
trainCarTop.append(carBody[0])
mc.scale(1.6, 12, 10)
for x in range(0, 22):
mc.polyExtrudeFacet(carBody[0] + ".f[4]", thickness=1.6)
x = 0
for x in range(0, 12):
if x == 0:
faceNum = 0
else:
faceNum = 8 * x + 5
faceString = ".f[" + str(faceNum) + "]"
mc.polyExtrudeFacet(carBody[0] + faceString, thickness=0.5)
x += 1
x = 0
for x in range(0, 12):
if x == 0:
faceNum = 2
else:
faceNum = 8 * x + 3
faceString = ".f[" + str(faceNum) + "]"
mc.polyExtrudeFacet(carBody[0] + faceString, thickness=0.5)
x += 1
mc.select(carBody[0])
mc.move(-80, 11, 0)
bottomRail = mc.polyCube()
trainCarTop.append(bottomRail[0])
mc.move(-62.27, 3.691, 0)
mc.scale(40.221, 1.036, 3.53)
connectorBack = mc.polyTorus(r=1.212, sr=0.25)
trainCarTop.append(connectorBack[0])
mc.move(-82.834, 3.71, 0)
connectorFront = mc.polyTorus(r=1.212, sr=0.25)
trainCarTop.append(connectorFront[0])
mc.move(-41.979, 3.71, 0)
mc.rotate(90, 0, 0)
theFrikinMain = mc.group(trainCarTop)
# Wheels on the cars
carWheels = []
whe01 = MakeWheel(radius=2.5)
mc.move(-49.672, 3.78, 3.14)
mc.rotate(0, 90, 0)
carWheels.append(whe01)
whe02 = mc.duplicate(rr=True, ic=True)
carWheels.extend(whe02)
mc.move(-55.4, 3.78, 3.14)
whe03 = mc.duplicate(rr=True, ic=True)
carWheels.extend(whe03)
mc.move(-70.123, 3.78, 3.14)
whe04 = mc.duplicate(rr=True, ic=True)
carWheels.extend(whe04)
mc.move(-75.727, 3.78, 3.14)
wheelsRight = mc.group(carWheels)
wheelsLeft = mc.duplicate(rr=True, ic=True)
mc.move(0, 0, -6.245)
# Group all geometry in car
theCar = []
theCar.append(theFrikinMain)
theCar.append(wheelsRight)
theCar.extend(wheelsLeft)
groupedCar = mc.group(theCar, n="Car1")
mc.move(0,
-8.978713,
0,
groupedCar + '.scalePivot',
groupedCar + '.rotatePivot',
r=True)
return groupedCar
def circleLink(rot_X, move_X, SIZE, THICK, nsTmp):
cmds.polyTorus(sr=THICK, n="Link1")
cmds.move(move_X, 0, 0)
cmds.rotate(rot_X, 0, 0)
cmds.scale(SIZE, SIZE, SIZE)
import maya.cmds as mc
plane = mc.polyPlane(n="BasicPlane", w=25, h=25)
torus = mc.polyTorus(n="Torus")
mc.move(0, 5, 0, torus)
mc.scale(5, 5, 5, torus)
mc.createNode('transform', n='RPRPhysicalLightTop')
phLightTop = mc.createNode('RPRPhysicalLight',
n='RPRPhysicalLightShapeTop',
p='RPRPhysicalLightTop')
mc.move(0, 24, 0, phLightTop)
mc.rotate(-90, 0, 0, phLightTop)
mc.scale(5, 5, 1, phLightTop)
mc.setAttr('RPRPhysicalLightShapeTop.lightType', 3)
mc.setAttr('RPRPhysicalLightShapeTop.lightIntensity', 1.5)
mc.createNode('transform', n='RPRPhysicalLightBottom')
phLightBottom = mc.createNode('RPRPhysicalLight',
n='RPRPhysicalLightShapeBottom',
p='RPRPhysicalLightBottom')
mc.move(0, 2, 0, phLightBottom)
mc.rotate(90, 0, 0, phLightBottom)
mc.scale(5, 5, 1, phLightBottom)
def makeTube():
"""
makes a simple tube mesh
"""
mesh = cmds.polyTorus(r=2, sr=0.2, sx=50, sy=4, tw=45)
cmds.setAttr(mesh[0]+'.sy', 5)
def run_script(num_shield_pieces=50):
RED = [1, 0, 0] #red blood cells
BLUE = [0, 0, 1] #blue for the core, aka Sonic
DARK_RED = [.545, 0, 0]
#create the lighting for the scene
main_light = cmds.directionalLight(name="main_light", intensity=5)
cmds.move(-5.711, 14.564, 11.097, "main_light")
cmds.rotate('-67.367deg', '-24.33deg', '54.557deg', "main_light")
#create the shape of the core and the shield
shield_shape = cmds.polyTorus(sr=0.2, name="myRing#") #shape of shield
shield_center = cmds.polyPlatonicSolid(radius=2.55, st=1, name="core")
applyMaterial(shield_center[0], DARK_RED, 'lambert')
cmds.move(0, 9, 0, "core") #move the core higher
#add decorative cylinder to core
core_piece_1 = cmds.polyCylinder(name="tube_1")
applyMaterial(core_piece_1[0], BLUE, 'lambert')
cmds.move(0.195, 11.014, -1.221, "tube_1")
cmds.rotate('-30.351deg', 0, 0, "tube_1")
cmds.scale(0.505, 0.619, 0.505, "tube_1")
#add another decorative cylinder to core
core_piece_2 = cmds.polyCylinder(name="tube_2")
applyMaterial(core_piece_2[0], RED, 'lambert')
cmds.move(-0.917, 11.185, -0.216, "tube_2")
cmds.rotate('-3.436deg', '14.201deg', '24.834deg', "tube_2")
cmds.scale(0.505, 0.619, 0.505, "tube_2")
#generate random shield fragments
shield_pieces, shield_pieces_group = generate_shield(
shield_shape, num_shield_pieces)
#coloring the shield pieces
for piece_obj in shield_pieces:
applyMaterial(piece_obj[0], RED, 'phong')
#aim fragments at core
aim_at_first(shield_center, shield_pieces)
#create and link expansion attribute
locator_group = expand_from_first(shield_center, shield_pieces)
#must group locators so they can be rotated with the fragments
cmds.parent(locator_group, shield_pieces_group)
startTime = cmds.playbackOptions(query=True, minTime=True)
endTime = cmds.playbackOptions(query=True, maxTime=True)
#second param is rotation param
key_rotation(shield_pieces_group, 'rotateY', startTime, endTime)
#create heartbeat animation pattern
cmds.cutKey(shield_center,
time=(startTime, endTime),
attribute='expansion')
heartbeat(shield_center, 0)
heartbeat(shield_center, 2)
heartbeat(shield_center, 4)
heartbeat(shield_center, 6)
heartbeat(shield_center, 8)
heartbeat(shield_center, 10)
cmds.selectKey(shield_center,
time=(startTime, endTime),
attribute='expansion',
keyframe=True)
cmds.keyTangent(inTangentType='linear', outTangentType='linear')
def _polyTorus(self):
cmds.polyTorus()
def testAnimPolyDeleteReload(self):
# create a poly cube and animate
shapeName = 'pCube'
MayaCmds.polyCube( name=shapeName )
MayaCmds.move(5, 0, 0, r=True)
MayaCmds.setKeyframe( shapeName+'.vtx[2:5]', time=[1, 24] )
MayaCmds.currentTime( 12 )
MayaCmds.select( shapeName+'.vtx[2:5]',replace=True )
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe( shapeName+'.vtx[2:5]', time=[12] )
# create a poly sphere and animate
shapeName = 'pSphere'
MayaCmds.polySphere( name=shapeName )
MayaCmds.move(-5, 0, 0, r=True)
MayaCmds.setKeyframe( shapeName+'.vtx[200:379]',
shapeName+'.vtx[381]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select( shapeName+'.vtx[200:379]',
shapeName+'.vtx[381]',replace=True)
MayaCmds.scale(0.5, 0.5, 0.5, relative=True)
MayaCmds.setKeyframe( shapeName+'.vtx[200:379]',
shapeName+'.vtx[381]', time=[12])
MayaCmds.currentTime(1)
# create a poly torus and animate
shapeName = 'pTorus'
MayaCmds.polyTorus(name=shapeName)
MayaCmds.setKeyframe(shapeName+'.vtx[200:219]',time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName+'.vtx[200:219]',replace=True)
MayaCmds.scale(2, 1, 2, relative=True)
MayaCmds.setKeyframe(shapeName+'.vtx[200:219]', time=[12])
# create a poly cone and animate
shapeName = 'pCone'
MayaCmds.polyCone(name=shapeName)
MayaCmds.move(0, 0, -5, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[20]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName+'.vtx[20]',replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[20]', time=[12])
# write it out to Abc file and load back in
self.__files.append(util.expandFileName('testPolyReload.abc'))
MayaCmds.AbcExport(j='-fr 1 24 -root pCube -root pSphere -root pTorus -root pCone -file %s' %
self.__files[-1])
# load back the Abc file, delete the sphere and save to a maya file
MayaCmds.AbcImport( self.__files[-1], mode='open')
MayaCmds.delete('pSphere')
self.__files.append(util.expandFileName('test.mb'))
MayaCmds.file(rename=self.__files[-1])
MayaCmds.file(save=True)
# import the saved maya file to compare with the original scene
MayaCmds.file(self.__files[-1], open=True)
MayaCmds.select('pCube', 'pTorus', 'pCone', replace=True)
MayaCmds.group(name='ReloadGrp')
MayaCmds.AbcImport(self.__files[-2], mode='import')
shapeList = MayaCmds.ls(type='mesh')
self.failUnlessEqual(len(shapeList), 7)
meshes = [('|pCube|pCubeShape', '|ReloadGrp|pCube|pCubeShape'),
('|pTorus|pTorusShape', '|ReloadGrp|pTorus|pTorusShape'),
('|pCone|pConeShape', '|ReloadGrp|pCone|pConeShape')]
for m in meshes:
for t in range(1, 25):
MayaCmds.currentTime(t, update=True)
if not util.compareMesh(m[0], m[1]):
self.fail('%s and %s are not the same at frame %d' %
(m[0], m[1], t))
cube = mc.polyCube (w=1, h=1, d=1, sx=1, sy=1, sz=1, ax=(0, 1, 0), cuv=4, ch=1) mc.scale(2, 2.6, 3, cube, r=True) mc.move(-6, 0, 0, cube, r=True) mc.rotate(14, 4, 3.5, cube, os=True) cylinder = mc.polyCylinder(r=1, h=2, sx=20, sy=1, sz=1, ax=(0, 1, 0), rcp=0, cuv=3, ch=1) mc.scale(2, 1, 2, cylinder, r=True) mc.move(0, 0, -6, r=True) mc.rotate(3, 5, 6, cylinder, r=True, os=True) cone = mc.polyCone(r=1, h=2, sx=20, sy=1, sz=0, ax=(0, 1, 0), rcp=0, cuv=3, ch=1) mc.scale(2, 3, 2, cone, r=True) mc.move(6, 0, 6, cone, r=True) mc.rotate(12, 11, 5, cone, r=True, os=True) torus = mc.polyTorus(r=1, sr=0.5, tx=0, sx=20, sy=0, ax=(0, 1, 0), cuv=3, ch=1) mc.scale(2, 2, 2, torus, r=True) mc.move(-6, 0, 6, torus, r=True) mc.rotate(1, 23, 5, torus, r=True, os=True) prism = mc.polyPrism(w=1, ns=3, sh=1, sc=0, ax=(0, 1, 0), cuv=3, ch=1) mc.scale(2, 2, 2, prism, r=True) mc.move(0, 0, 6, prism, r=True) mc.rotate(1, 4, 30, prism, r=True, os=True) pyramid = mc.polyPyramid(w=1, ns=4, sh=0, sc=0, ax=(0, 1, 0), cuv=3, ch=1) mc.scale(4, 5, 4, pyramid, r=True) mc.move(6, 0, -6, pyramid, r=True) pipe = mc.polyPipe(r=1, h=3, t=0.5, sa=20, sh=1, sc=0, ax=(0, 1, 0), cuv=3, rcp=0, ch=1) mc.scale(2, 2, 2, pipe, r=True)
def torus(**kwargs):
try:
return cmds.polyTorus(**kwargs)[1]
except:
raise
def polyTorus(*args, **kwargs):
res = cmds.polyTorus(*args, **kwargs)
if not kwargs.get('query', kwargs.get('q', False)):
res = _factories.maybeConvert(res, _general.PyNode)
return res
def testAnimPolyDeleteReload(self):
# create a poly cube and animate
shapeName = 'pCube'
MayaCmds.polyCube(name=shapeName)
MayaCmds.move(5, 0, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[2:5]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[2:5]', replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[2:5]', time=[12])
# create a poly sphere and animate
shapeName = 'pSphere'
MayaCmds.polySphere(name=shapeName)
MayaCmds.move(-5, 0, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:379]',
shapeName + '.vtx[381]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[200:379]',
shapeName + '.vtx[381]', replace=True)
MayaCmds.scale(0.5, 0.5, 0.5, relative=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:379]',
shapeName + '.vtx[381]', time=[12])
MayaCmds.currentTime(1)
# create a poly torus and animate
shapeName = 'pTorus'
MayaCmds.polyTorus(name=shapeName)
MayaCmds.setKeyframe(shapeName + '.vtx[200:219]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[200:219]', replace=True)
MayaCmds.scale(2, 1, 2, relative=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:219]', time=[12])
# create a poly cone and animate
shapeName = 'pCone'
MayaCmds.polyCone(name=shapeName)
MayaCmds.move(0, 0, -5, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[20]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[20]', replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[20]', time=[12])
# write it out to Abc file and load back in
self.__files.append(util.expandFileName('testPolyReload.abc'))
MayaCmds.AbcExport(j='-fr 1 24 -root pCube -root pSphere -root pTorus -root pCone -file %s' %
self.__files[-1])
# load back the Abc file, delete the sphere and save to a maya file
MayaCmds.AbcImport(self.__files[-1], mode='open')
MayaCmds.delete('pSphere')
self.__files.append(util.expandFileName('test.mb'))
MayaCmds.file(rename=self.__files[-1])
MayaCmds.file(save=True)
# import the saved maya file to compare with the original scene
MayaCmds.file(self.__files[-1], open=True)
MayaCmds.select('pCube', 'pTorus', 'pCone', replace=True)
MayaCmds.group(name='ReloadGrp')
MayaCmds.AbcImport(self.__files[-2], mode='import')
shapeList = MayaCmds.ls(type='mesh')
self.failUnlessEqual(len(shapeList), 7)
meshes = [('|pCube|pCubeShape', '|ReloadGrp|pCube|pCubeShape'),
('|pTorus|pTorusShape', '|ReloadGrp|pTorus|pTorusShape'),
('|pCone|pConeShape', '|ReloadGrp|pCone|pConeShape')]
for m in meshes:
for t in range(1, 25):
MayaCmds.currentTime(t, update=True)
if not util.compareMesh(m[0], m[1]):
self.fail('%s and %s are not the same at frame %d' %
(m[0], m[1], t))
import maya.cmds as cmds #create generic polycube (automatically selects it) cmds.polyCube(sx=10, sy=10, sz=10, w=20, h=20, d=20, n="generic_cube") #create generic polytorus (automatically selects it) cmds.polyTorus(sx=8, sy=16, r=10, sr=1, n="generic_torus") #delete selected object cmds.delete()
def testAnimSubDDeleteReload(self):
# create a subD cube and animate
shapeName = 'cube'
MayaCmds.polyCube(name=shapeName)
MayaCmds.select('cubeShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.move(5, 0, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[2:5]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[2:5]', replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[2:5]', time=[12])
# create a subD sphere and animate
shapeName = 'sphere'
MayaCmds.polySphere(name=shapeName)
MayaCmds.select('sphereShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.move(-5, 0, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:379]', shapeName + '.vtx[381]',
time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[200:379]', shapeName + '.vtx[381]',
replace=True)
MayaCmds.scale(0.5, 0.5, 0.5, relative=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:379]', shapeName + '.vtx[381]',
time=[12])
MayaCmds.currentTime(1)
# create a subD torus and animate
shapeName = 'torus'
MayaCmds.polyTorus(name=shapeName)
MayaCmds.select('torusShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:219]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[200:219]', replace=True)
MayaCmds.scale(2, 1, 2, relative=True)
MayaCmds.setKeyframe(shapeName + '.vtx[200:219]', time=[12])
# create a subD cone and animate
shapeName = 'cone'
MayaCmds.polyCone(name=shapeName)
MayaCmds.select('coneShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.move(0, 0, -5, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[20]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName + '.vtx[20]', replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName + '.vtx[20]', time=[12])
self.__files.append(util.expandFileName('testSubDReload.abc'))
# write it out to Abc file and load back in
MayaCmds.AbcExport(j='-fr 1 24 -root cube -root sphere -root torus -root cone -file ' +
self.__files[-1])
# load back the Abc file, delete the sphere and save to a maya file
MayaCmds.AbcImport(self.__files[-1], mode='open')
MayaCmds.delete('sphere')
self.__files.append(util.expandFileName('test.mb'))
MayaCmds.file(rename=self.__files[-1])
MayaCmds.file(save=True)
# import the saved maya file to compare with the original scene
MayaCmds.file(self.__files[-1], open=True)
MayaCmds.select('cube', 'torus', 'cone', replace=True)
MayaCmds.group(name='ReloadGrp')
MayaCmds.AbcImport(self.__files[-2], mode='import')
shapeList = MayaCmds.ls(type='mesh')
self.failUnlessEqual(len(shapeList), 7)
# test the equality of cubes
meshes = [('|cube|cubeShape', '|ReloadGrp|cube|cubeShape'),
('|torus|torusShape', '|ReloadGrp|torus|torusShape'),
('|cone|coneShape', '|ReloadGrp|cone|coneShape')]
for m in meshes:
for t in range(1, 25):
MayaCmds.currentTime(t, update=True)
if not util.compareMesh(m[0], m[1]):
self.fail('%s and %s are not the same at frame %d' %
(m[0], m[1], t))
def rim():
#get values from UI
rimStyle = cmds.radioButtonGrp( 'rimStyle', query = True, select = True)
rgb = cmds.colorSliderGrp('wheelColour', query=True, rgbValue=True)
#set up variables
radius = 1.6
widthHalf = 2.1 / 2
if( rimStyle == 1 ):
mediumCircle = cmds.polyCylinder( h = widthHalf * 0.4, r = radius * 0.67 )
cmds.rotate( 90, rotateZ = True )
crossV = cmds.polyCube( w = widthHalf, h = 0.4, d = 0.2 )
crossH = cmds.polyCube( w = widthHalf, h = 0.2, d = 0.4 )
cross = cmds.polyCBoolOp( crossV, crossH, op = 1 )
cmds.move( widthHalf / 2, moveX = True )
mediumCircle = cmds.polyCBoolOp( mediumCircle, cross, op = 2 )
innerCircle = cmds.polyPipe( h = widthHalf * 0.3, r = radius * 0.33, t = 0.14 )
cmds.rotate( 90, rotateZ = True )
cmds.move( ((widthHalf * 0.4) / 2) + ((widthHalf * 0.3) / 2), moveX = True )
outerCircle = cmds.polyPipe( h = widthHalf, r = radius, t = 0.2 )
cmds.rotate( 90, rotateZ = True )
cmds.move( (((widthHalf * 0.4) / 2) + ((widthHalf * 0.5) / 2)) + 0.1, moveX = True )
outerCircleCut = cmds.polyPipe( h = widthHalf * 0.33, r = radius, t = 0.1 )
cmds.rotate( 90, rotateZ = True )
cmds.move( (((widthHalf * 0.4) / 2) + ((widthHalf * 0.5) / 2)) + 0.1, moveX = True )
outerCircle = cmds.polyCBoolOp( outerCircle, outerCircleCut, op = 2 )
slope = cmds.polyCone()
cmds.rotate( 90, rotateZ = True )
cmds.move( 0.810, moveX = True )
cmds.scale( 5.455, 1, 5.455 )
slopeCutL = cmds.polyCylinder( h = widthHalf, r = radius )
cmds.rotate( 90, rotateZ = True )
cmds.move( -( widthHalf / 2), moveX = True )
slopeCutR = cmds.polyCylinder( h = 4, r = radius * 10 )
cmds.rotate( 90, rotateZ = True )
cmds.move( 2.326, moveX = True )
slope = cmds.polyCBoolOp( slope, slopeCutL, op = 2 )[0]
slope = cmds.polyCBoolOp( slope, slopeCutR, op = 2 )[0]
cmds.delete( slope+".f[21]")
rimL = cmds.polyUnite( mediumCircle, innerCircle, outerCircle, slope )
cmds.move( (widthHalf*0.4)/2, moveX = True )
rimR = cmds.duplicate( rimL )
cmds.scale( -1, scaleX = True )
cmds.move( -((widthHalf*0.4)/2), moveX = True )
rim = cmds.polyUnite( rimR, rimL )
elif( rimStyle == 2 ):
radius = 1.5
circleList = []
mainCircle = cmds.polyCylinder( h = 0.4, r = radius - 0.2 )
innerCircle = cmds.polyCylinder( h = 0.5, r = radius * 0.2 )
hCross = cmds.polyCube( w = radius * 0.24, h = 3, d = radius * 0.1 )
vCross = cmds.polyCube( w = radius * 0.1, h = 3, d = radius * 0.24 )
cross = cmds.polyCBoolOp( hCross, vCross, op = 1 )[0]
rim = cmds.polyCBoolOp( mainCircle, innerCircle, op = 1 )
rim = cmds.polyCBoolOp( rim, cross, op = 2 )
lRidge = cmds.polyTorus( sr = 0.1, r = (radius * 0.9))
cmds.move( 0.4/2, moveY = True )
rRidge = cmds.polyTorus( sr = 0.1, r = (radius * 0.9))
cmds.move( -(0.4/2), moveY = True )
rim = cmds.polyCBoolOp( rim, lRidge, op = 1 )[0]
rim = cmds.polyCBoolOp( rim, rRidge, op = 1 )[0]
cutCircle = cmds.polyCylinder( h = 3, r = radius * 0.17 )[0]
cmds.move( 0, 0, 0.8)
cmds.move( 0, 0, 0, cutCircle+".scalePivot", cutCircle+".rotatePivot", absolute=True)
circleList.append( cutCircle )
for i in range( 0, 5):
cutCircle = cmds.duplicate( cutCircle )
cmds.rotate( 0, 60, 0, cutCircle, r = True )
circleList.append( cutCircle )
cutCircles = cmds.polyUnite( *circleList)
rim = cmds.polyCBoolOp( rim, cutCircles, op = 2 )
cmds.rotate( 90, rotateX = True )
myShader = cmds.shadingNode( 'phong', asShader=True )
cmds.setAttr( myShader+".color", rgb[0], rgb[1], rgb[2], type='double3')
cmds.setAttr( myShader+".reflectivity", 0 )
cmds.select( rim )
cmds.hyperShade( assign = myShader )
cmds.delete( ch = True )
def testAnimSubDDeleteReload(self):
# create a subD cube and animate
shapeName = 'cube'
MayaCmds.polyCube( name=shapeName )
MayaCmds.select('cubeShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.move(5, 0, 0, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[2:5]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName+'.vtx[2:5]',replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[2:5]', time=[12])
# create a subD sphere and animate
shapeName = 'sphere'
MayaCmds.polySphere(name=shapeName)
MayaCmds.select('sphereShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.move(-5, 0, 0, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[200:379]', shapeName+'.vtx[381]',
time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName+'.vtx[200:379]', shapeName+'.vtx[381]',
replace=True)
MayaCmds.scale(0.5, 0.5, 0.5, relative=True)
MayaCmds.setKeyframe(shapeName+'.vtx[200:379]', shapeName+'.vtx[381]',
time=[12])
MayaCmds.currentTime(1)
# create a subD torus and animate
shapeName = 'torus'
MayaCmds.polyTorus(name=shapeName)
MayaCmds.select('torusShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.setKeyframe(shapeName+'.vtx[200:219]',time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName+'.vtx[200:219]',replace=True)
MayaCmds.scale(2, 1, 2, relative=True)
MayaCmds.setKeyframe(shapeName+'.vtx[200:219]', time=[12])
# create a subD cone and animate
shapeName = 'cone'
MayaCmds.polyCone( name=shapeName )
MayaCmds.select('coneShape')
MayaCmds.addAttr(longName='SubDivisionMesh', attributeType='bool',
defaultValue=True)
MayaCmds.move(0, 0, -5, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[20]', time=[1, 24])
MayaCmds.currentTime(12)
MayaCmds.select(shapeName+'.vtx[20]',replace=True)
MayaCmds.move(0, 4, 0, r=True)
MayaCmds.setKeyframe(shapeName+'.vtx[20]', time=[12])
self.__files.append(util.expandFileName('testSubDReload.abc'))
# write it out to Abc file and load back in
MayaCmds.AbcExport(j='-fr 1 24 -root cube -root sphere -root torus -root cone -file ' +
self.__files[-1])
# load back the Abc file, delete the sphere and save to a maya file
MayaCmds.AbcImport( self.__files[-1], mode='open' )
MayaCmds.delete('sphere')
self.__files.append(util.expandFileName('test.mb'))
MayaCmds.file(rename=self.__files[-1])
MayaCmds.file(save=True)
# import the saved maya file to compare with the original scene
MayaCmds.file(self.__files[-1], open=True)
MayaCmds.select('cube', 'torus', 'cone', replace=True)
MayaCmds.group(name='ReloadGrp')
MayaCmds.AbcImport(self.__files[-2], mode='import')
shapeList = MayaCmds.ls(type='mesh')
self.failUnlessEqual(len(shapeList), 7)
# test the equality of cubes
meshes = [('|cube|cubeShape', '|ReloadGrp|cube|cubeShape'),
('|torus|torusShape', '|ReloadGrp|torus|torusShape'),
('|cone|coneShape', '|ReloadGrp|cone|coneShape')]
for m in meshes:
for t in range(1, 25):
MayaCmds.currentTime(t, update=True)
if not util.compareMesh(m[0], m[1]):
self.fail('%s and %s are not the same at frame %d' %
(m[0], m[1], t))
def kmTorus(self):
mc.polyTorus(r=6, sr=3, tw=0, sx=8, sy=8, ax=[0, 1, 0], cuv=1, ch=1)
def octLink(rot_X, move_X, SIZE, THICK, nsTmp):
cmds.polyTorus(sa=8, sh=8, sr=THICK, n="Link1")
cmds.move(move_X, 0, 0)
cmds.rotate(rot_X, 0, 0)
cmds.scale(SIZE, SIZE, SIZE)
