def make_sphere(name="Nisse", create_uvs=1, radius=3):
"""
Example function that will make a sphere name Nisse
:return:
"""
pm.polySphere(name=name, createUVs=create_uvs, radius=radius)
return "I made a sphere"
def make_sphere(name="Nisse"):
"""
Example function that will make a sphere name Nisse
:return:
"""
pm.polySphere(name=name)
return "I made a sphere"
def test():
facs = utils.FACS()
print facs.getAttrs(attrNum=False,
attrGrp=False,
attrName=True,
splitAttrName=False,
splitPart=False,
auNum=False,
auName=False)
pm.polySphere()
def create_sphere_display_control_base(self, control, radius):
new_sphere_transform, new_sphere_creator = pm.polySphere()
self.display_spheres.append([new_sphere_transform, new_sphere_creator])
pfx = pm.createNode('pfxToon')
transform_pfx = pm.ls('pfxToon1')[0]
new_sphere_transform.setParent(self.rig_system.kinematics)
self.name_conv.rename_name_in_format(transform_pfx, name='display')
self.name_conv.rename_name_in_format(pfx, name='displaypfx')
self.name_conv.rename_name_in_format(new_sphere_transform,
name='displaySphere')
self.name_conv.rename_name_in_format(new_sphere_creator,
name='displaySphereCreation')
new_sphere_transform.outMesh >> pfx.inputSurface[0].surface
new_sphere_transform.worldMatrix >> pfx.inputSurface[0].inputWorldMatrix
pfx.displayPercent.set(100)
pfx.screenspaceWidth.set(True)
pfx.distanceScaling.set(1)
pfx.minPixelWidth.set(1)
pfx.maxPixelWidth.set(10)
pfx.profileColor.set(0.5, 0.0, 0.0)
len(pm.getAttr(pfx.inputSurface, mi=True))
pfx.overrideEnabled.set(True)
pfx.overrideDisplayType.set(2)
pm.addAttr(control, ln='radius', at='float', k=True, hnv=True, min=0)
pm.addAttr(control, ln='influenceDisplay', at='bool', k=True)
control.radius >> new_sphere_creator.radius
control.radius.set(radius)
control.influenceDisplay.set(True)
control.influenceDisplay >> transform_pfx.visibility
pm.parentConstraint(control, new_sphere_transform)
def sphere_generator(source_sphrs, source_verts, gen_bones, settings):
spheres = []
for i in range(len(source_sphrs)):
sphere = source_sphrs[i]
core_vert = source_verts[sphere.vertex]
coords = [core_vert.x, core_vert.y, core_vert.z]
poly_transform, poly_sphere = pm.polySphere(
name="Sphere" + str(i),
r=sphere.size * WORLD_SCALE,
sx=settings.sphere_resolution,
sy=settings.sphere_resolution)
poly_transform.translate.set(coords)
poly_transform.rotate.set([90, 0, 0])
poly_shape = poly_transform.getShape()
if settings.use_palette:
sg = "paletteSG" + str(sphere.colour)
pm.sets(sg, edit=True, forceElement=poly_transform)
pm.polySoftEdge(a=180)
if settings.use_rigging:
pm.skinCluster(gen_bones[core_vert.bone], poly_shape, tsb=True)
spheres.append(poly_shape)
return spheres
def addSkinnedShape(self):
testNode = self.createNode()
testShapes = testNode.getShapes()
otherNode = pm.polySphere()[0]
otherShapes = otherNode.getShapes()
oldShape = otherNode.getShape()
oldShape.addAttr('SomeSpecialTestMarkerAttr', attributeType = controls.Attribute.Type.BOOL)
newObject = self.testingClass(testNode)
newObject.addSkinnedShape([oldShape.faces])
other = find('Other node\'s shapes changed').using(otherNode.getShapes())
verify(other).collection.isEqualTo(otherShapes)
difference = list(set(testShapes) ^ set(testNode.getShapes()))
actual = find('Incorrect shape count after addition').using(difference)
verify(actual).collection.size(1)
newShape = difference[0]
actual = find('Old shape was not duplicated').using(newShape)
verify(actual).isNotEqualTo(oldShape)
actual = find('New shape was not a duplicate').using(newShape.hasAttr('SomeSpecialTestMarkerAttr'))
verify(actual).isTrue()
def setUp(self):
self.temp = tempfile.mkdtemp(prefix='referencesTest')
print "created temp dir: %s" % self.temp
# Refs:
# sphere.ma
# (no refs)
# cube.ma
# :sphere => sphere.ma
# cone.ma
# :cubeInCone => cube.ma
# :cubeInCone:sphere => sphere.ma
# master.ma
# :sphere1 => sphere.ma
# :sphere2 => sphere.ma
# :cube1 => cube.ma
# :cube1:sphere => sphere.ma
# :cone1 => cone.ma
# :cone1:cubeInCone => cube.ma
# :cone1:cubeInCone:sphere => sphere.ma
# create sphere file
print "sphere file"
# cmds.file(new=1, f=1)
pm.newFile(f=1)
sphere = pm.polySphere()
# We will use this to test failed ref edits...
pm.addAttr(sphere, ln='zombieAttr')
self.sphereFile = pm.saveAs(os.path.join(self.temp, 'sphere.ma'), f=1)
# create cube file
print "cube file"
pm.newFile(f=1)
pm.polyCube()
pm.createReference(self.sphereFile, namespace='sphere')
pm.PyNode('sphere:pSphere1').attr('translateX').set(2)
self.cubeFile = pm.saveAs(os.path.join(self.temp, 'cube.ma'), f=1)
# create cone file
print "cone file"
pm.newFile(f=1)
pm.polyCone()
pm.createReference(self.cubeFile, namespace='cubeInCone')
pm.PyNode('cubeInCone:pCube1').attr('translateZ').set(2)
pm.PyNode('cubeInCone:sphere:pSphere1').attr('translateZ').set(2)
self.coneFile = pm.saveAs(os.path.join(self.temp, 'cone.ma'), f=1)
print "master file"
pm.newFile(f=1)
self.sphereRef1 = pm.createReference(self.sphereFile,
namespace='sphere1')
pm.PyNode('sphere1:pSphere1').attr('translateY').set(2)
self.sphereRef2 = pm.createReference(self.sphereFile,
namespace='sphere2')
pm.PyNode('sphere2:pSphere1').attr('translateY').set(4)
self.cubeRef1 = pm.createReference(self.cubeFile, namespace='cube1')
pm.PyNode('cube1:sphere:pSphere1').attr('translateY').set(6)
pm.PyNode('cube1:pCube1').attr('translateY').set(6)
self.coneRef1 = pm.createReference(self.coneFile, namespace='cone1')
self.masterFile = pm.saveAs(os.path.join(self.temp, 'master.ma'), f=1)
def create_background_sphere(name):
'''Create a sphere aligned to aiSkyDomeLight shape'''
xform, _ = pmc.polySphere(radius=995)
shape = xform.getShape()
xform.rename('HDR_Reflector')
# align sphere to aiSkyDomeLight
xform.rotateY.set(71.5)
uv_count = pmc.polyEvaluate(shape, uv=True)
pmc.polyFlipUV(
'{}.map[0:{}]'.format(str(shape), uv_count),
flipType=0,
local=True
)
pmc.delete(xform, ch=True)
pmc.makeIdentity(xform, apply=True)
# set defaults
shape.doubleSided.set(False)
shape.castsShadows.set(False)
shape.receiveShadows.set(False)
shape.opposite.set(True)
shape.aiSelfShadows.set(0)
shape.aiOpaque.set(0)
shape.aiVisibleInDiffuse.set(0)
shape.aiVisibleInGlossy.set(0)
return xform, shape
def __init__(self, array):
if isinstance(array, pm.datatypes.BoundingBox):
self.boundingbox = array
else:
_spheres = [pm.polySphere(r=0.01)[0] for x in xrange(6)]
for sphere, points, axe in zip(_spheres, array, 'xyzxyz'):
sphere.setAttr('t{}'.format(axe), points)
pm.select(_spheres, r=1)
_lattrice = pm.lattice(pm.selected(),
divisions=(2, 2, 2),
ldv=(2, 2, 2),
objectCentered=True)
self.boundingbox = (_lattrice[-1]).getBoundingBox()
pm.delete(_lattrice)
pm.delete(_spheres)
self.getAllPos()
self.all_locs = []
self.axisDic = {
'all': 'all',
'x': 0,
'y': 1,
'z': 2,
}
def makeLantern(): #clear workspace cmds.select(all=True) cmds.delete() #get values from sliders ridges = cmds.intSliderGrp(ridgesSlider, q=True, value=True) deform = cmds.intSliderGrp(deformSlider, q=True, value=True) bend = cmds.intSliderGrp(bendSlider, q=True, value=True) bendNum = bend/100.0+1.0 flatten = float(cmds.intSliderGrp(flattenSlider, q=True, value=True)) lantern = pm.polySphere(n='lantern', sx=10, r=1, sy=ridges) rings = pm.polySelect( lantern, er=1) pm.select(lantern, cl=True) toggle = True for i in rings: if toggle: pm.polySelect( lantern, el=i) pm.scale(pm.selected(), [bendNum,bendNum,bendNum], xz=True) toggle = not toggle pm.select(lantern) pm.displaySmoothness(divisionsU=3, divisionsV=3, pointsWire=16, pointsShaded=4, polygonObject=3) wave = pm.nonLinear(type='wave', amplitude=0.03) pm.setAttr(wave[0]+'.wavelength', deform/100+0.1) pm.rotate(wave, 0, 0, '45deg') pm.select(all=True) pm.scale(lantern, [1,1-(flatten/100),1], xyz=True) pm.delete(ch=True)
def addEyeMesh(self, name, parent, position=None):
"""Add a loc object to the guide.
This mehod can initialize the object or draw it.
Loc object is a simple null to define a position or a tranformation in
the guide.
Args:
name (str): Local name of the element.
parent (dagNode): The parent of the element.
position (vector): The default position of the element.
Returns:
dagNode: The locator object.
"""
if name not in self.tra.keys():
self.tra[name] = transform.getTransformFromPos(position)
eyeMesh = pm.polySphere(name=self.getName(name),
subdivisionsX=30,
subdivisionsY=45,
radius=0.5)[0]
eyeMesh.setTransformation(self.tra[name])
pm.parent(eyeMesh, parent)
eyeMesh.setTranslation
return eyeMesh
def make_circler_nodes(self):
spherexform = pmc.polySphere()[0]
spherexform.translate.set([44, 55, 66])
circler = self.createNode('circler')
pmc.PyNode('time1').outTime.connect(circler.input)
circler.outSine.connect(spherexform.translateX)
circler.outCosine.connect(spherexform.translateY)
return spherexform, circler
def make_circler_nodes(self):
spherexform = pmc.polySphere()[0]
spherexform.translate.set([44, 55, 66])
circler = self.createNode('circler')
pmc.PyNode('time1').outTime.connect(circler.input)
circler.outSine.connect(spherexform.translateX)
circler.outCosine.connect(spherexform.translateY)
return spherexform, circler
def setUp(self):
self.temp = tempfile.mkdtemp(prefix='referencesTest')
print "created temp dir: %s" % self.temp
# Refs:
# sphere.ma
# (no refs)
# cube.ma
# :sphere => sphere.ma
# cone.ma
# :cubeInCone => cube.ma
# :cubeInCone:sphere => sphere.ma
# master.ma
# :sphere1 => sphere.ma
# :sphere2 => sphere.ma
# :cube1 => cube.ma
# :cube1:sphere => sphere.ma
# :cone1 => cone.ma
# :cone1:cubeInCone => cube.ma
# :cone1:cubeInCone:sphere => sphere.ma
# create sphere file
print "sphere file"
# cmds.file(new=1, f=1)
pm.newFile(f=1)
sphere = pm.polySphere()
# We will use this to test failed ref edits...
pm.addAttr(sphere, ln='zombieAttr')
self.sphereFile = pm.saveAs( os.path.join( self.temp, 'sphere.ma' ), f=1 )
# create cube file
print "cube file"
pm.newFile(f=1)
pm.polyCube()
pm.createReference( self.sphereFile, namespace='sphere' )
pm.PyNode('sphere:pSphere1').attr('translateX').set(2)
self.cubeFile = pm.saveAs( os.path.join( self.temp, 'cube.ma' ), f=1 )
# create cone file
print "cone file"
pm.newFile(f=1)
pm.polyCone()
pm.createReference( self.cubeFile, namespace='cubeInCone' )
pm.PyNode('cubeInCone:pCube1').attr('translateZ').set(2)
pm.PyNode('cubeInCone:sphere:pSphere1').attr('translateZ').set(2)
self.coneFile = pm.saveAs( os.path.join( self.temp, 'cone.ma' ), f=1 )
print "master file"
pm.newFile(f=1)
self.sphereRef1 = pm.createReference( self.sphereFile, namespace='sphere1' )
pm.PyNode('sphere1:pSphere1').attr('translateY').set(2)
self.sphereRef2 = pm.createReference( self.sphereFile, namespace='sphere2' )
pm.PyNode('sphere2:pSphere1').attr('translateY').set(4)
self.cubeRef1 = pm.createReference( self.cubeFile, namespace='cube1' )
pm.PyNode('cube1:sphere:pSphere1').attr('translateY').set(6)
pm.PyNode('cube1:pCube1').attr('translateY').set(6)
self.coneRef1 = pm.createReference( self.coneFile, namespace='cone1' )
self.masterFile = pm.saveAs(os.path.join(self.temp, 'master.ma'), f=1)
def sphereHull(self):
sel = pm.ls(sl=True, fl=True)
bb, cnt, transform = self._get_bounds(sel)
hull = pm.polySphere(radius=max(bb.width(), bb.height(), bb.depth()) / 2, sx=8, sy=8,
n='UCX_{0}_01'.format(transform))
hull[0].setTranslation(cnt)
sg = pm.PyNode('initialShadingGroup')
sg.remove(hull[0].getShape())
hull[0].setParent(transform)
def randPrims(numPrims, maxSize, minX, maxX, minY, maxY, minZ, maxZ, minSize=0.1): prims = [] for m in range(numPrims): # roll a random whole number between 0 to 4: p = random.randrange(0,5) if p == 0: # roll a random number between 0 and max sizes for all parameters radiusSphere = random.uniform(minSize, maxSize) x = random.uniform(minX, maxX) y = random.uniform(minY, maxY) z = random.uniform(minZ, maxZ) # store the object in a variable temporarily so it's easier to append it to the list n = pm.polySphere(r=radiusSphere)[0] pm.move(n, x, y, z) prims.append(n) # create elif statements in case we roll 1, 2, 3 or 4 elif p == 1: volCube = random.uniform(minSize, maxSize) x = random.uniform(minX, maxX) y = random.uniform(minY, maxY) z = random.uniform(minZ, maxZ) n = pm.polyCube(w=volCube, h=volCube, d=volCube)[0] pm.move(n, x, y, z) prims.append(n) elif p == 2: radiusCyl = random.uniform(minSize, maxSize) heightCyl = random.uniform(minSize, maxSize) x = random.uniform(minX, maxX) y = random.uniform(minY, maxY) z = random.uniform(minZ, maxZ) n = pm.polyCylinder(h=heightCyl, r=radiusCyl)[0] pm.move(n, x, y, z) prims.append(n) elif p == 3: radiusCone = random.uniform(minSize, maxSize) heightCone = random.uniform(minSize, maxSize) x = random.uniform(minX, maxX) y = random.uniform(minY, maxY) z = random.uniform(minZ, maxZ) n = pm.polyCone(h=heightCone, r=radiusCone)[0] pm.move(n, x, y, z) prims.append(n) elif p == 4: widthPlane = random.uniform(minSize, maxSize) heightPlane = random.uniform(minSize, maxSize) x = random.uniform(minX, maxX) y = random.uniform(minY, maxY) z = random.uniform(minZ, maxZ) n = pm.polyPlane(h=heightPlane, w=widthPlane)[0] pm.move(n, x, y, z) prims.append(n) return prims
def sphereHull(self):
sel = pm.ls(sl=True, fl=True)
bb, cnt, transform = self._get_bounds(sel)
hull = pm.polySphere(radius=max(bb.width(), bb.height(), bb.depth()) /
2,
sx=8,
sy=8,
n='UCX_{0}_01'.format(transform))
hull[0].setTranslation(cnt)
sg = pm.PyNode('initialShadingGroup')
sg.remove(hull[0].getShape())
hull[0].setParent(transform)
def createParentCubeSphere():
# | による親子付け
#トランスフォームノードとシェイプノードのリストが返ってくるため、[0]で一つ目の要素のみ受け取っています
myCube = pm.polyCube()[0]
#同じく
mySphere = pm.polySphere()[0]
#親子付け
myCube | mySphere
#階層化されているか確認
print '階層化の確認', mySphere.name(long=True)
def rig(self, component_node, control, bake_controls=False, default_space=None, use_global_queue=False, **kwargs):
# Create the dynamic pendulum to be used as the Aim space for the overdriver
self.network = self.create_meta_network(component_node)
#self.zero_character(self.network['character'], use_global_queue)
aim_up_group_name = "{0}pre_dynamics_{1}_grp".format(self.namespace, self.prefix)
pre_dynamic_group = pm.group(empty=True, name=aim_up_group_name)
pre_dynamic_group.setParent(self.network['addon'].group)
pm.parentConstraint(self.character_world, pre_dynamic_group, mo=False)
cur_namespace = pm.namespaceInfo(cur=True)
pm.namespace(set=":")
time_range = (pm.playbackOptions(q=True, min=True), pm.playbackOptions(q=True, max=True))
object_space = pm.polySphere(r=8, sx=20, sy=20, ax=[0,1,0], cuv=2, ch=1, n="pendulum")[0]
object_space.setParent(pre_dynamic_group)
ws_pos = pm.xform(control, q=True, ws=True, t=True)
pm.xform(object_space, ws=True, t=ws_pos)
rigid_body = pm.rigidBody(object_space, b=0, dp=5)
rigid_body_nail = pm.PyNode(pm.constrain(rigid_body, nail=True))
rigid_body_nail.setParent(pre_dynamic_group)
rigid_point_constraint = pm.pointConstraint(control, rigid_body_nail, mo=False)
pm.select(None)
gravity_field = pm.gravity(m=980)
gravity_field.setParent(pre_dynamic_group)
pm.connectDynamic(object_space, f=gravity_field)
self.reset_pendulum(object_space)
if not super(Pendulum, self).rig(component_node, control, [object_space], bake_controls=bake_controls, default_space=default_space, use_global_queue=use_global_queue, **kwargs):
return False
driver_control = self.network['controls'].get_first_connection()
driver_control.addAttr("damping", type='double', hidden=False, keyable=True)
driver_control.damping.set(rigid_body.damping.get())
driver_control.damping >> rigid_body.damping
driver_control.addAttr("bounciness", type='double', hidden=False, keyable=True)
driver_control.bounciness.set(rigid_body.bounciness.get())
driver_control.bounciness >> rigid_body.bounciness
driver_control.addAttr("gravity", type='double', hidden=False, keyable=True)
driver_control.gravity.set(gravity_field.magnitude.get())
driver_control.gravity >> gravity_field.magnitude
self.reset_pendulum(object_space)
def create_lightchecker(name):
'''
Creates a poly mesh to use as lightchecker.
Args:
name(String): Name of the object
Returns:
lightchecker
'''
lightchecker = pm.polySphere(name='{0}:{1}_geo'.format(NAMESPACE, name),
radius=7,
subdivisionsX=60,
subdivisionsY=40,
constructionHistory=False)[0]
return lightchecker
def ctrlRadiusFromJoint(self, jnt, useSphere=True):
childJnt = jnt.getChildren()
if len(childJnt) > 0:
radius = util.get_distance(jnt, childJnt[0])
if useSphere:
sphere = pm.polySphere(r=radius, sx=20, sy=20, ch=False)[0]
radius = util.getPlanarRadiusBBOXFromTransform(sphere, radiusFactor=3)['3D']
pm.delete(sphere)
else:
return 1
return radius
def shaderTest(shader, attribute, objA=None, minV=0.0, maxV=1.0, step=0.1):
""" Setup Balls to Render """
if objA == None:
objA = pm.polySphere()[0]
copies = maxV / step
objList = duplicateArray(objA=objA, noCopies=copies, direction="+x")
attrV = minV
for i, _obj in enumerate(objList, 1):
print i, _obj, attribute, attrV
shd, grp = createShader(shader, "%s_SHD" % str(_obj))
assignShaderToObject(_obj, grp)
if isinstance(shd.getAttr(attribute), float):
shd.setAttr(attribute, attrV)
elif isinstance(shd.getAttr(attribute), tuple): # Color Support
shd.setAttr(attribute, [attrV, attrV, attrV])
attrV += step
def AddSphere(self,*args): #create sphere #---------------------------------- collisionSphereTrans = pm.polySphere(sx = 8,sy = 8, n = 'collisionSphere0', r = 2, ch = 0)[0] collisionSphereShape = collisionSphereTrans.getShape() collisionSphereTrans.translate.set(0,1,0) pm.select(cl = True) #connect sphere as collision object #---------------------------------- clothSolver = self.GlobalVars["clothSolver"] clothSolver.collisionConstraint[self.NumOfCol].collisionConstraintActive.set(1) clothSolver.collisionConstraint[self.NumOfCol].collisionConstraintType.set(0) collisionSphereShape.outMesh >> clothSolver.collisionConstraint[self.NumOfCol].collisionConstraintGeo collisionSphereShape.parentMatrix >> clothSolver.collisionConstraint[self.NumOfCol].collisionConstraintGeoMatrix self.NumOfCol = self.NumOfCol + 1 pm.select(cl = True)
def setUp(self):
new_obs = []
collumn = 5
row = 6
for i in range(collumn):
new_ob = pm.polySphere()[0]
if new_obs:
new_ob.setParent(new_obs[-1])
new_obs.append(new_ob)
new_obs = [new_obs[0]]
for i in range(row):
dup_ob = pm.duplicate(
new_obs[-1],
name = new_obs[-1].name()+'_i',
rc=True)
new_obs.append(dup_ob)
self.selected = pm.selected()
def createVertSphere():
'''
create a poly sphere that will be used to determine
what verts should be influenced.
'''
sel = pm.selected()
for s in sel:
print pm.objectType(s)
if pm.objectType(s) == 'joint':
userPos = pm.xform(s, q = True, t = True, ws = True)
elif pm.objectType(s) == 'mesh':
userPos = pm.pointPosition(s, w = True)
vSphere = pm.polySphere(n = '{0}_vtxSphere'.format(s), ch = False)
pm.move(userPos[0],userPos[1],userPos[2], vSphere)
return vSphere
def duplicateTransformHierarchyRec(origNode, parentToNode, geoProxy=False):
origChildren = origNode.getChildren(type='transform')
if len(origChildren) == 0: return 'Finished'
for origChild in origChildren:
origShape = origChild.getShape()
if origShape is not None: # shape
if geoProxy is not False:
print 'duplicating mesh'
proxySphere = pm.polySphere(name='temp', sx=4, sy=6)[0]
pm.matchTransform(proxySphere, origChild)
pm.parent(proxySphere, parentToNode)
proxySphere.rename(origChild)
else:
dup = origChild.duplicate(n='temp', po=1)[0]
pm.parent(dup, parentToNode)
dup.rename(origChild)
duplicateTransformHierarchyRec(origChild, dup, geoProxy)
def setUp(self):
self.temp = os.path.join(tempfile.gettempdir(), "referencesTest")
if not os.path.isdir(self.temp):
os.makedirs(self.temp)
print "created temp dir: %s" % self.temp
# Refs:
# sphere.ma
# (no refs)
# master.ma
# :sphere1 => sphere.ma
# :sphere2 => sphere.ma
# create sphere file
print "sphere file"
# cmds.file(new=1, f=1)
pm.newFile(f=1)
sphere = pm.polySphere()[0]
pm.addAttr(sphere, ln="zombieAttr1")
pm.addAttr(sphere, ln="zombieAttr2")
cmds.setAttr("%s.v" % sphere, lock=1)
cmds.setAttr("%s.zombieAttr1" % sphere, lock=1)
self.sphereFile = pm.saveAs(os.path.join(self.temp, "sphere.ma"), f=1)
print "master file"
pm.newFile(f=1)
self.sphereRef1 = pm.createReference(self.sphereFile, namespace="sphere1")
self.sphereRef2 = pm.createReference(self.sphereFile, namespace="sphere2")
self.sphere1 = pm.PyNode("sphere1:pSphere1")
self.sphere2 = pm.PyNode("sphere2:pSphere1")
self.sphere1.attr("translateY").set(2)
self.sphere2.attr("translateY").set(4)
self.cube = pm.polyCube()[0]
pm.addAttr(self.cube, ln="zombieAttr1")
pm.addAttr(self.cube, ln="zombieAttr2")
cmds.setAttr("%s.v" % self.cube, lock=1)
cmds.setAttr("%s.zombieAttr1" % self.cube, lock=1)
self.masterFile = pm.saveAs(os.path.join(self.temp, "master.ma"), f=1)
def setUp(self):
print "getting temp dir"
self.temp = os.path.join(tempfile.gettempdir(), 'referencesTest')
if not os.path.isdir(self.temp):
os.makedirs(self.temp)
# create sphere file
print "sphere file"
# cmds.file(new=1, f=1)
pm.newFile(f=1)
sphere = pm.polySphere()
# We will use this to test failed ref edits...
pm.addAttr(sphere, ln='zombieAttr')
self.sphereFile = pm.saveAs( os.path.join( self.temp, 'sphere.ma' ), f=1 )
# create cube file
print "cube file"
pm.newFile(f=1)
pm.polyCube()
pm.createReference( self.sphereFile, namespace='sphere' )
pm.PyNode('sphere:pSphere1').attr('translateX').set(2)
self.cubeFile = pm.saveAs( os.path.join( self.temp, 'cube.ma' ), f=1 )
# create cone file
print "cone file"
pm.newFile(f=1)
pm.polyCone()
pm.createReference( self.cubeFile, namespace='cubeInCone' )
pm.PyNode('cubeInCone:pCube1').attr('translateZ').set(2)
pm.PyNode('cubeInCone:sphere:pSphere1').attr('translateZ').set(2)
self.coneFile = pm.saveAs( os.path.join( self.temp, 'cone.ma' ), f=1 )
print "master file"
pm.newFile(f=1)
self.sphereRef1 = pm.createReference( self.sphereFile, namespace='sphere1' )
pm.PyNode('sphere1:pSphere1').attr('translateY').set(2)
self.sphereRef2 = pm.createReference( self.sphereFile, namespace='sphere2' )
pm.PyNode('sphere2:pSphere1').attr('translateY').set(4)
self.cubeRef1 = pm.createReference( self.cubeFile, namespace='cube1' )
pm.PyNode('cube1:sphere:pSphere1').attr('translateY').set(6)
pm.PyNode('cube1:pCube1').attr('translateY').set(6)
self.coneRef1 = pm.createReference( self.coneFile, namespace='cone1' )
def setUp(self):
print "getting temp dir"
self.temp = os.path.join(tempfile.gettempdir(), 'referencesTest')
if not os.path.isdir(self.temp):
os.makedirs(self.temp)
# create sphere file
print "sphere file"
# cmds.file(new=1, f=1)
pm.newFile(f=1)
sphere = pm.polySphere()
# We will use this to test failed ref edits...
pm.addAttr(sphere, ln='zombieAttr')
self.sphereFile = pm.saveAs( os.path.join( self.temp, 'sphere.ma' ), f=1 )
# create cube file
print "cube file"
pm.newFile(f=1)
pm.polyCube()
pm.createReference( self.sphereFile, namespace='sphere' )
pm.PyNode('sphere:pSphere1').attr('translateX').set(2)
self.cubeFile = pm.saveAs( os.path.join( self.temp, 'cube.ma' ), f=1 )
# create cone file
print "cone file"
pm.newFile(f=1)
pm.polyCone()
pm.createReference( self.cubeFile, namespace='cubeInCone' )
pm.PyNode('cubeInCone:pCube1').attr('translateZ').set(2)
pm.PyNode('cubeInCone:sphere:pSphere1').attr('translateZ').set(2)
self.coneFile = pm.saveAs( os.path.join( self.temp, 'cone.ma' ), f=1 )
print "master file"
pm.newFile(f=1)
self.sphereRef1 = pm.createReference( self.sphereFile, namespace='sphere1' )
pm.PyNode('sphere1:pSphere1').attr('translateY').set(2)
self.sphereRef2 = pm.createReference( self.sphereFile, namespace='sphere2' )
pm.PyNode('sphere2:pSphere1').attr('translateY').set(4)
self.cubeRef1 = pm.createReference( self.cubeFile, namespace='cube1' )
pm.PyNode('cube1:sphere:pSphere1').attr('translateY').set(6)
pm.PyNode('cube1:pCube1').attr('translateY').set(6)
self.coneRef1 = pm.createReference( self.coneFile, namespace='cone1' )
def flexiplane_mid_ctrl(self, name=None):
"""
Create Mid Control
:param name:
:return:
"""
if not name:
name = '_mid_ctrl'
mid_ctrl = pm.polySphere(n=name,
r=0.3,
sx=8,
sy=8,
ax=(0.0, 1.0, 0.0),
ch=False)[0]
# cc_shp = cc.getShape()
# cc_shp.overrideEnabled.set(1)
# cc_shp.overrideColor.set(color)
self.create_surfaceshader(mid_ctrl, color=(1.0, 1.0, 0.0))
return mid_ctrl
def create_shapes(*args):
print('This will create shapes')
num = slider1.getValue()
print('Number of shapes to be created:', num)
i = 0
while i < num:
value = float(i) / num
angle = random.randint(0, 359)
radius = random.uniform(0.5, 2)
height = random.uniform(0.5, 1)
x, y, z = pm.pointOnCurve('curve1', pr=value, turnOnPercentage=True)
x1 = random.uniform(x - 3, x + 3)
y1 = random.uniform(y - 3, y + 3)
z1 = random.uniform(z - 3, z + 3)
shape = options.getValueArray4()
j = random.randint(0, 3)
if shape[j] == True:
if j == 0:
figure = pm.polyTorus(r=radius, sr=0.25)
pm.move(x1, y1, z1, figure)
i += 1
elif j == 1:
figure = pm.polyCone(sx=1, sy=1.5, sz=0.5, r=radius, h=height)
pm.move(x1, y1, z1, figure)
i += 1
elif j == 2:
figure = pm.polySphere(r=radius)
pm.move(x1, y1, z1, figure)
i += 1
elif j == 3:
figure = pm.polyCylinder(r=radius, h=height)
pm.move(x1, y1, z1, figure)
i += 1
pm.select(figure)
pm.rotate(angle, 0, 0, r=True)
pm.select(clear=True)
def createPointParent(ob, name="PointParent#", shapeReplace=False, r=1):
'''Create a Parent of selected'''
obOldParent = ob.getParent()
obNewParent = pm.polySphere(name=name,
subdivisionsAxis=6,
subdivisionsHeight=4,
radius=r / 3)
for a in [('castsShadows', 0), ('receiveShadows', 0), ('smoothShading', 0),
('primaryVisibility', 0), ('visibleInReflections', 0),
('visibleInRefractions', 0), ('overrideEnabled', 1),
('overrideShading', 0), ('overrideTexturing', 0),
('overrideRGBColors', 1), ('overrideColorRGB', (1, 0, 0))]:
obNewParent[0].getShape().attr(a[0]).set(a[1])
if not shapeReplace:
pm.xform(obNewParent[0], ws=1, t=pm.xform(ob, q=1, ws=1, t=1))
pm.xform(obNewParent[0], ws=1, ro=pm.xform(ob, q=1, ws=1, ro=1))
#pm.color(obNewParent[0],rgb=(1,0,0))
#obNewParent.setAttr("translate",obPos)
if obOldParent:
pm.parent(obNewParent[0], obOldParent)
pm.parent(ob, obNewParent[0])
else:
pm.parent(obNewParent[0].listsRelatives(shapes=1)[0], ob, r=1, s=1)
pm.delete(obNewParent)
# 基本的な使い方 ## ライブラリ読み込み ~~~ import maya.cmds as cmds ~~~ ## 球体を作成 ~~~ import pymel.core as pm # 球体を作成 pm.polySphere(r=10,n='testsphere') ~~~
pm.select(cl = True) clothSolver.positionConstraint[3].positionConstraintVertexIndex.set(10) positionConstraintLocatorIndex10Shape.worldPosition >> clothSolver.positionConstraint[3].positionConstraintCoordinate pm.select(cl = True) clothSolver.positionConstraint[4].positionConstraintVertexIndex.set(60) positionConstraintLocatorIndex60Shape.worldPosition >> clothSolver.positionConstraint[4].positionConstraintCoordinate pm.select(cl = True) #set clothSolver active attr #---------------------------------- clothSolver.positionConstraint[0].positionConstraintActive.set(1) clothSolver.positionConstraint[1].positionConstraintActive.set(1) #create sphere #---------------------------------- collisionSphereTrans = pm.polySphere(sx = 8,sy = 8, n = 'collisionSphere0', r = 2, ch = 0)[0] collisionSphereShape = collisionSphereTrans.getShape() collisionSphereTrans.translate.set(0,1,0) pm.select(cl = True) #connect sphere as collision object #---------------------------------- clothSolver.collisionConstraint[0].collisionConstraintActive.set(1) clothSolver.collisionConstraint[0].collisionConstraintType.set(0) collisionSphereShape.outMesh >> clothSolver.collisionConstraint[0].collisionConstraintGeo collisionSphereShape.parentMatrix >> clothSolver.collisionConstraint[0].collisionConstraintGeoMatrix pm.select(cl = True) #create cube #---------------------------------- collisionCubeTrans = pm.polyCube(sx = 1,sy = 1, sz = 1, d = 4, w = 4, h = 4, n = 'collisionCube1', ch = 0)[0]
def build_rbf(self):
try:
pm.loadPlugin('jsRadial.mll')
except:
pm.error('ERROR: jsRadial.mll not loaded.')
pm.undoInfo(openChunk=True)
rbf = pm.createNode('jsRadPose')
# Notify if RBF is made with no connections
if len(self.pose) == 0 and len(self.targets) == 0:
print "RBF node made with no connections"
# Only create one sigma blinn material
if self.sigma_chk.isChecked():
self.sigma_shader = pm.shadingNode("lambert",
asShader=True,
name="sigmaLmbt")
pm.setAttr(self.sigma_shader.color.colorR, 0.0)
pm.setAttr(self.sigma_shader.color.colorG, 0.5)
pm.setAttr(self.sigma_shader.color.colorB, 1.0)
pm.setAttr(self.sigma_shader.transparency, (0.95, 0.95, 0.95))
self.sigma_sg = pm.sets(renderable=1,
noSurfaceShader=1,
empty=1,
n="sigmaLmbt_SG")
pm.connectAttr(self.sigma_shader.outColor,
self.sigma_sg.surfaceShader)
self.falloff_group = pm.group(empty=1, n="GRP_rbf_falloff")
# Connect pose attrs
if len(self.pose) == 1:
# Connect pose matrix
if self.matrix_chk.isChecked() == True:
if self.world_rad.isChecked() == True:
pm.connectAttr(self.pose[0][0].worldMatrix[0],
rbf.poseMatrix)
else:
pm.connectAttr(self.pose[0][0].parentMatrix[0],
rbf.poseMatrix)
# Connect pose color
if self.rgb_chk.isChecked() == True or self.alpha_chk.isChecked(
) == True:
shape = pm.listRelatives(self.pose[0], shapes=1)[0]
shader_grp = pm.listConnections(shape, type='shadingEngine')
shader = pm.listConnections(shader_grp[0], d=0, s=1)[0]
if self.rgb_chk.isChecked():
try:
pm.connectAttr(shader.color, rbf.poseColor)
except:
try:
pm.connectAttr(shader.outColor, rbf.poseColor)
except:
pass
if self.alpha_chk.isChecked():
try:
pm.connectAttr(shader.transparency,
rbf.poseTransparency)
except:
try:
pm.connectAttr(shader.outTransparency,
rbf.poseTransparency)
except:
pass
# Build pose rotate locators
locX = pm.spaceLocator(n=self.pose[0][0] + '_rotLocX')
locY = pm.spaceLocator(n=self.pose[0][0] + '_rotLocY')
locZ = pm.spaceLocator(n=self.pose[0][0] + '_rotLocZ')
pm.parent(locX, locY, locZ, self.pose[0])
pm.setAttr(locX.translate, (0, 0, 0))
pm.setAttr(locY.translate, (0, 0, 0))
pm.setAttr(locZ.translate, (0, 0, 0))
mult = pm.createNode('multiplyDivide',
n='MULTinv_' + self.pose[0][0])
pm.setAttr(mult.operation, 2)
pm.setAttr(mult.input1X, 1)
pm.setAttr(mult.input1Y, 1)
pm.setAttr(mult.input1Z, 1)
pm.connectAttr(self.pose[0][0].scale, mult.input2)
pm.connectAttr(mult.output, locX.scale)
pm.connectAttr(mult.output, locY.scale)
pm.connectAttr(mult.output, locZ.scale)
mult_neg = pm.createNode('multiplyDivide',
n='MULTneg_' + self.pose[0][0])
pm.setAttr(mult_neg.operation, 1)
pm.setAttr(mult_neg.input1X, -1)
pm.setAttr(mult_neg.input1Y, -1)
pm.setAttr(mult_neg.input1Z, -1)
pm.connectAttr(rbf.rotateLocatorOffset, locX.tx)
pm.connectAttr(rbf.rotateLocatorOffset, locY.ty)
pm.connectAttr(rbf.rotateLocatorOffset, locZ.tz)
pm.connectAttr(rbf.rotateLocatorOffset, mult_neg.input2X)
pm.connectAttr(rbf.rotateLocatorOffset, mult_neg.input2Y)
pm.connectAttr(rbf.rotateLocatorOffset, mult_neg.input2Z)
pm.connectAttr(mult_neg.outputX, locX.scalePivotX)
pm.connectAttr(mult_neg.outputY, locY.scalePivotY)
pm.connectAttr(mult_neg.outputZ, locZ.scalePivotZ)
pm.connectAttr(locX.worldMatrix[0], rbf.poseRotateLocX)
pm.connectAttr(locY.worldMatrix[0], rbf.poseRotateLocY)
pm.connectAttr(locZ.worldMatrix[0], rbf.poseRotateLocZ)
pm.connectAttr(rbf.rotateLocatorsVisible, locX.visibility)
pm.connectAttr(rbf.rotateLocatorsVisible, locY.visibility)
pm.connectAttr(rbf.rotateLocatorsVisible, locZ.visibility)
pm.setAttr(locX.overrideEnabled, 1)
pm.setAttr(locY.overrideEnabled, 1)
pm.setAttr(locZ.overrideEnabled, 1)
pm.setAttr(locX.overrideColor, 12)
pm.setAttr(locY.overrideColor, 23)
pm.setAttr(locZ.overrideColor, 29)
# Check target list for pose and duplicates
if len(self.pose) == 1:
single_set = set(self.targets)
self.targets = list(single_set)
if self.pose[0][0] in self.targets:
print "Pose " + self.pose[0][
0] + " was removed from target list but kept as input pose."
self.targets.remove(self.pose[0][0])
# Connect target attrs
for i in range(0, len(self.targets)):
# Connect target matrix
if self.matrix_chk.isChecked() == True:
if self.world_rad.isChecked() == True:
pm.connectAttr(self.targets[i].worldMatrix[0],
rbf.target[i].targetMatrix)
else:
pm.connectAttr(self.targets[i].parentMatrix[0],
rbf.target[i].targetMatrix)
# Connect target rbga
if self.rgb_chk.isChecked() == True or self.alpha_chk.isChecked(
) == True:
shape = pm.listRelatives(self.targets[i], shapes=1)[0]
shader_grp = pm.listConnections(shape, type='shadingEngine')
shader = pm.listConnections(shader_grp[0], d=0, s=1)[0]
if self.rgb_chk.isChecked() == True:
try:
pm.connectAttr(shader.color, rbf.target[i].targetColor)
except:
try:
pm.connectAttr(shader.outColor,
rbf.target[i].targetColor)
except:
pass
if self.alpha_chk.isChecked() == True:
try:
pm.connectAttr(shader.transparency,
rbf.target[i].targetTransparency)
except:
try:
pm.connectAttr(shader.outTransparency,
rbf.target[i].targetTransparency)
except:
pass
# Build target rotate locators
locX = pm.spaceLocator(n=self.targets[i] + '_rotLocX')
locY = pm.spaceLocator(n=self.targets[i] + '_rotLocY')
locZ = pm.spaceLocator(n=self.targets[i] + '_rotLocZ')
pm.parent(locX, locY, locZ, self.targets[i])
pm.setAttr(locX.translate, (0, 0, 0))
pm.setAttr(locY.translate, (0, 0, 0))
pm.setAttr(locZ.translate, (0, 0, 0))
mult = pm.createNode('multiplyDivide',
n='MULTinv_' + self.targets[i])
pm.setAttr(mult.operation, 2)
pm.setAttr(mult.input1X, 1)
pm.setAttr(mult.input1Y, 1)
pm.setAttr(mult.input1Z, 1)
pm.connectAttr(self.targets[i].scale, mult.input2)
pm.connectAttr(mult.output, locX.scale)
pm.connectAttr(mult.output, locY.scale)
pm.connectAttr(mult.output, locZ.scale)
mult_neg = pm.createNode('multiplyDivide',
n='MULTneg_' + self.targets[i])
pm.setAttr(mult_neg.operation, 1)
pm.setAttr(mult_neg.input1X, -1)
pm.setAttr(mult_neg.input1Y, -1)
pm.setAttr(mult_neg.input1Z, -1)
pm.connectAttr(rbf.rotateLocatorOffset, locX.tx)
pm.connectAttr(rbf.rotateLocatorOffset, locY.ty)
pm.connectAttr(rbf.rotateLocatorOffset, locZ.tz)
pm.connectAttr(rbf.rotateLocatorOffset, mult_neg.input2X)
pm.connectAttr(rbf.rotateLocatorOffset, mult_neg.input2Y)
pm.connectAttr(rbf.rotateLocatorOffset, mult_neg.input2Z)
pm.connectAttr(mult_neg.outputX, locX.scalePivotX)
pm.connectAttr(mult_neg.outputY, locY.scalePivotY)
pm.connectAttr(mult_neg.outputZ, locZ.scalePivotZ)
pm.connectAttr(locX.worldMatrix[0], rbf.target[i].rotateLocX)
pm.connectAttr(locY.worldMatrix[0], rbf.target[i].rotateLocY)
pm.connectAttr(locZ.worldMatrix[0], rbf.target[i].rotateLocZ)
pm.connectAttr(rbf.rotateLocatorsVisible, locX.visibility)
pm.connectAttr(rbf.rotateLocatorsVisible, locY.visibility)
pm.connectAttr(rbf.rotateLocatorsVisible, locZ.visibility)
pm.setAttr(locX.overrideEnabled, 1)
pm.setAttr(locY.overrideEnabled, 1)
pm.setAttr(locZ.overrideEnabled, 1)
pm.setAttr(locX.overrideColor, 12)
pm.setAttr(locY.overrideColor, 23)
pm.setAttr(locZ.overrideColor, 29)
# Build target alias attrs on RBF node
if self.alias_chk.isChecked():
alias = self.targets[i]
if '|' in alias:
alias = alias.replace('|', '_')
pm.aliasAttr(alias, rbf.target[i])
outAlias = alias + 'Out'
sigmaAlias = alias + 'Falloff'
pm.aliasAttr(outAlias, rbf.outputInterpolate[i])
pm.aliasAttr(sigmaAlias, rbf.outputSigma[i])
pm.getAttr(rbf.outputInterpolate[i])
pm.getAttr(rbf.outputSigma[i])
# Build falloff spheres
if self.sigma_chk.isChecked():
bb = pm.xform(self.targets[i], q=1, bb=1)
scale = bb[3] - bb[0]
### hard coding sphere radius from trial and error
sphere = pm.polySphere(r=5.0,
sx=20,
sy=20,
ax=(0, 1, 0),
ch=0,
n=str(self.targets[i]) + '_falloff')
sphereShp = pm.listRelatives(sphere, s=1)
pcon = pm.parentConstraint(self.targets[i], sphere, mo=0)
pm.sets(self.sigma_sg, e=1, forceElement=sphereShp)
mult = pm.createNode('multiplyDivide',
n='MULT_' + self.targets[i] + '_falloff')
pm.setAttr(mult.input1X, 0.5)
pm.setAttr(mult.operation, 2)
pm.connectAttr(rbf.outputSigma[i], mult.input2X)
pm.connectAttr(mult.outputX, sphere[0].scaleX)
pm.connectAttr(mult.outputX, sphere[0].scaleY)
pm.connectAttr(mult.outputX, sphere[0].scaleZ)
pm.parent(sphere, self.falloff_group)
pm.undoInfo(closeChunk=True)
self.close()
def renderBuddy(ren, arg=1):
####: REN
# 1 : mentalRay
# 2 : V-ray
####: ARGS
# 1 : create
# 2 : delete
if arg is 1:
# cleanup check
if pm.objExists('LGT_REF_OBJ') | pm.objExists('diff_18SG') | pm.objExists('diff_18'):
pm.delete('diff_80', 'diff_18', 'refl_100', 'refl_75', 'diff_18SG', 'diff_80SG', 'refl_01SG', 'refl_02SG', 'LGT_REF_OBJ')
# create four spheres & a plane
tmp1 = pm.polySphere(r = 1, n = "fBall_D1", ch = 0)
diff01 = tmp1[0]
tmp1 = pm.polySphere(r = 1, n = "fBall_D2", ch = 0)
diff02 = tmp1[0]
tmp1 = pm.polySphere(r = 1, n = "fBall_R1", ch = 0)
refl01 = tmp1[0]
tmp1 = pm.polySphere(r = 1, n = "fBall_R2", ch = 0)
refl02 = tmp1[0]
tmp1 = pm.polyPlane (n = "fGround", ch = 1)
grid01 = tmp1[0]
objs = [diff01, diff02, refl01, refl02, grid01]
#shds = [shd_diff_80, shd_diff_18, shd_refl_01, shd_refl_02]
#shgs = [shg_diff_80, shg_diff_18, shg_refl_01, shg_refl_02]
# group them
grp = pm.group(diff01, diff02, refl01, refl02, grid01, n = "LGT_REF_OBJ")
grp.translateY.set(10)
# move them around
offset = 4.5
for o in objs:
o.translateX.set(offset)
offset = offset -3
grid01.scaleX.set(50)
grid01.scaleZ.set(50)
grid01.translateX.set(0)
grid01.translateY.set(-10)
# create shaders
# 80% diffuse goes to mesh diff01
shg_diff_80 = pm.sets(n = "diff_80SG", renderable = 1, empty = 1)
shd_diff_80 = pm.shadingNode('lambert', asShader = 1, n = "diff_80")
shd_diff_80.diffuse.set(0.8)
shd_diff_80.color.set(1, 1, 1)
pm.surfaceShaderList(shd_diff_80, add = shg_diff_80)
pm.sets(shg_diff_80, e = 1, forceElement = diff01)
# 18% diffuse goes to mesh diff02
shg_diff_18 = pm.sets(n = "diff_18SG", renderable = 1, empty = 1)
shd_diff_18 = pm.shadingNode('lambert', asShader = 1, n = "diff_18")
shd_diff_18.diffuse.set(0.18)
shd_diff_18.color.set(1, 1, 1)
pm.surfaceShaderList(shd_diff_18, add = shg_diff_18)
pm.sets(shg_diff_18, e = 1, forceElement = diff02)
### REFLECTION SPHERES DEPEND ON DIFFERENT SHADERS FOR MENTALRAY / VRAY ###
if ren is 1:
# (MENTALRAY) 100% glossy mia goes to mesh refl01
shg_refl_01 = pm.sets(n = "refl_01SG", renderable = 1, empty = 1)
shd_refl_01 = pm.shadingNode('mia_material_x_passes', asShader = 1, n = "refl_100")
shd_refl_01.diffuse_weight.set(0)
shd_refl_01.reflectivity.set(1)
pm.disconnectAttr('lambert1.outColor', shg_refl_01.surfaceShader)
pm.connectAttr(shd_refl_01.message, shg_refl_01.miMaterialShader)
pm.sets(shg_refl_01, e = 1, forceElement = refl01)
# (MENTALRAY) 75% glossy mia goes to mesh refl02
shg_refl_02 = pm.sets(n = "refl_02SG", renderable = 1, empty = 1)
shd_refl_02 = pm.shadingNode('mia_material_x_passes', asShader = 1, n = "refl_75")
shd_refl_02.diffuse_weight.set(0)
shd_refl_02.reflectivity.set(1)
shd_refl_02.refl_gloss.set(0.75)
pm.disconnectAttr('lambert1.outColor', shg_refl_02.surfaceShader)
pm.connectAttr(shd_refl_02.message, shg_refl_02.miMaterialShader)
pm.sets(shg_refl_02, e = 1, forceElement = refl02)
if ren is 2:
# (VRAY) 100% glossy vraymtl goes to mesh refl01
shg_refl_01 = pm.sets(n = "refl_01SG", renderable = 1, empty = 1)
shd_refl_01 = pm.shadingNode('VRayMtl', asShader = 1, n = "refl_100")
shd_refl_01.diffuseColorAmount.set(0)
shd_refl_01.reflectionColor.set(1,1,1)
pm.surfaceShaderList(shd_refl_01, add = shg_refl_01)
pm.sets(shg_refl_01, e = 1, forceElement = refl01)
# (VRAY) 75% glossy vraymtl goes to mesh refl02
shg_refl_02 = pm.sets(n = "refl_02SG", renderable = 1, empty = 1)
shd_refl_02 = pm.shadingNode('VRayMtl', asShader = 1, n = "refl_75")
shd_refl_02.diffuseColorAmount.set(0)
shd_refl_02.reflectionColor.set(1,1,1)
pm.surfaceShaderList(shd_refl_02, add = shg_refl_02)
pm.sets(shg_refl_02, e = 1, forceElement = refl02)
if arg is 2:
pm.delete('diff_80', 'diff_18', 'refl_100', 'refl_75', 'diff_18SG', 'diff_80SG', 'refl_01SG', 'refl_02SG', 'LGT_REF_OBJ')
import pymel.core as pm s = pm.polySphere()[0] # second in list is the history node, if construction history is on c = pm.polyCube()[0] print c, s c.setTranslation( [0,2,0] ) s.setTranslation( [1,-2,0] ) g = pm.group( s, c, n='newGroup' ) print "The children of %s are %s" % (g, g.getChildren()) #print g.getChildren()[0].getShape() print "difference =", c.translate.get() - s.translate.get() # basic vector operation s2 = s.duplicate()[0] # move the new sphere relatively along the z axis s2.setTranslation([0,0,-2], relative=1) # cycle through and move some verts. # we're moving each verts a relative amount based on its vertex number num = s2.numVertices() for i, vert in enumerate(s2.verts): pm.move( vert, [ i / float(num), 0, 0 ], r=1) # save the current scene scene currScene = pm.saveAs( 'pymel_test_main.ma') # the parent property gives the parent directory of the current scene.
import pymel.core as pm import forms.util.mesh as meshUtil reload ( meshUtil ) sphere = pm.polySphere( subdivisionsAxis = 8, subdivisionsX = 8, subdivisionsY = 8, subdivisionsHeight = 8, radius = 10 ) mesh1 = pm.duplicate( sphere[ 0 ] ) mesh2 = pm.duplicate( sphere[ 0 ] ) mesh1[ 0 ].setAttr( 'translateZ', -20 ) mesh2[ 0 ].setAttr( 'translateZ', 20 ) meshUtil.polyWire( mesh1, depth = 0.9, extrudeMode = 0 ) meshUtil.polyWire( mesh2, depth = 0.9, extrudeMode = 1 ) print mesh1 print mesh2 # Result: [nt.Transform(u'pSphere2')] # Result: [nt.Transform(u'pSphere3')] mesh1 = pm.duplicate( sphere[ 0 ] ) mesh2 = pm.duplicate( sphere[ 0 ] ) mesh3 = pm.duplicate( sphere[ 0 ] ) mesh1[ 0 ].setTranslation( [ -20, 0, -10 ] ) mesh2[ 0 ].setTranslation( [ -20, 0, 10 ] ) mesh3[ 0 ].setTranslation( [ -20, 0, 0 ] ) meshUtil.combineClean( pm.group( mesh1, mesh2, mesh3 ), 'combineCleanResult' )
def setup(self):
for i in range(0, self.total_verts):
self.vertices.append([0, 0, 0, ''])
self.vertices_last.append([0, 0, 0, ''])
self.v_forces.append([0, 0, 0])
self.vertices.append([0, 0, 0])
# Calculate initial vertices
counter = 0
for i in range(0, self.sim_u):
for j in range(0, self.sim_v):
self.vertices[counter] = [
((float(i) / (float(self.sim_u) - 1.0)) * 2.0 - 1.0) *
self.VERTEX_SIZE_HALF, self.VERTEX_SIZE + 1,
((float(j) / (float(self.sim_v) - 1.0)) *
self.VERTEX_SIZE), ''
]
self.vertices_last[counter] = self.vertices[counter]
counter = counter + 1
# Fill in triangle indices
for i in range(0, self.num_y):
for j in range(0, self.num_x):
i_0 = i * (self.num_x + 1) + j
i_1 = i_0 + 1
i_2 = i_0 + (self.num_x + 1)
i_3 = i_2 + 1
if (j + i) % 2:
self.v_indices.append(i_0)
self.v_indices.append(i_2)
self.v_indices.append(i_1)
self.v_indices.append(i_1)
self.v_indices.append(i_2)
self.v_indices.append(i_3)
else:
self.v_indices.append(i_0)
self.v_indices.append(i_2)
self.v_indices.append(i_3)
self.v_indices.append(i_0)
self.v_indices.append(i_3)
self.v_indices.append(i_1)
# Add structural springs
# Horizontal
for i in range(0, self.sim_v):
for j in range(0, self.sim_u - 1):
self.add_spring((i * self.sim_u) + j, (i * self.sim_u) + j + 1,
self.KS_STRUCTURAL, self.KD_STRUCTURAL,
self.STRUCTURAL_SPRING_TYPE)
# Vertical
for i in range(0, self.sim_u):
for j in range(0, self.sim_v - 1):
self.add_spring((j * self.sim_u) + i,
((j + 1) * self.sim_u) + i, self.KS_STRUCTURAL,
self.KD_STRUCTURAL,
self.STRUCTURAL_SPRING_TYPE)
# Add shear springs
for i in range(0, self.sim_v - 1):
for j in range(0, self.sim_u - 1):
self.add_spring((i * self.sim_u) + j,
((i + 1) * self.sim_u) + j + 1, self.KS_SHEAR,
self.KD_SHEAR, self.SHEAR_SPRING_TYPE)
self.add_spring(((i + 1) * self.sim_u) + j,
(i * self.sim_u) + j + 1, self.KS_SHEAR,
self.KD_SHEAR, self.SHEAR_SPRING_TYPE)
# Add bend strings
for i in range(0, self.sim_v):
for j in range(0, self.sim_u - 2):
self.add_spring((i * self.sim_u) + j, (i * self.sim_u) + j + 2,
self.KS_BEND, self.KD_BEND,
self.BEND_SPRING_TYPE)
self.add_spring((i * self.sim_u) + (self.sim_u - 3),
(i * self.sim_u) + (self.sim_u - 1), self.KS_BEND,
self.KD_BEND, self.BEND_SPRING_TYPE)
for i in range(0, self.sim_u):
for j in range(0, self.sim_v - 2):
self.add_spring((j * self.sim_u) + i,
((j + 2) * self.sim_u) + i, self.KS_BEND,
self.KD_BEND, self.BEND_SPRING_TYPE)
self.add_spring(((self.sim_v - 3) * self.sim_u) + i,
((self.sim_v - 1) * self.sim_u) + i, self.KS_BEND,
self.KD_BEND, self.BEND_SPRING_TYPE)
# Add spheres at initial vertex positions, put reference name in last field
for i in range(0, len(self.v_indices), 3):
p_1 = self.vertices[self.v_indices[i]]
p_2 = self.vertices[self.v_indices[i + 1]]
p_3 = self.vertices[self.v_indices[i + 2]]
sphere = pm.polySphere(sx=4, sy=4, r=0.1)
pm.move(p_1[0], p_1[1], p_1[2], sphere[0], ws=True)
self.vertices[self.v_indices[i]][3] = sphere[0]
sphere = pm.polySphere(sx=4, sy=4, r=0.1)
pm.move(p_2[0], p_2[1], p_2[2], sphere[0], ws=True)
self.vertices[self.v_indices[i + 1]][3] = sphere[0]
sphere = pm.polySphere(sx=4, sy=4, r=0.1)
pm.move(p_3[0], p_3[1], p_3[2], sphere[0], ws=True)
self.vertices[self.v_indices[i + 2]][3] = sphere[0]
# -*- coding: Shift_Jis -*- import pymel.core as pm import os # 新規シーンファイルをつくる pm.newFile() # ポリゴンの球をつくる pm.polySphere() # シーンファイルを保存するファイルパスを指定する pm.renameFile(os.getcwd() + '\\hello.ma') # シーンファイルを保存する pm.saveFile()
def setUp(self):
cmds.file(new=1, f=1)
self.sphere = pm.polySphere()[0]
self.cube = pm.polyCube()[0]
self.cone = pm.polyCone()[0]
print e
pmc.polyColorPerVertex(selection, rgb=colour, cdo=True)
paint.last = selection
paint.last = None
def erase(mesh):
""" Clear / Prepare colour on mesh """
pmc.polyColorPerVertex(mesh.vtx, rgb=BASE_COLOUR)
mesh.displayColors.set(0)
if __name__ == '__main__':
# Testing
import time, threading, random
from maya.utils import executeInMainThreadWithResult as ex
pmc.system.newFile(force=True)
xform, shape = pmc.polySphere() # Create a cylinder and joints
vert_num = xform.numVertices() - 1
erase(xform)
def flip():
def random_colour():
try:
col = [random.random() for a in range(3)]
rng = sorted([int(random.random() * vert_num) for a in range(2)])
sel = xform.vtx[slice(*rng)]
paint(sel, col)
return True
except pmc.MayaNodeError:
pass
while True:
if not ex(random_colour): break
time.sleep(1)
def __AddTestNodes(self):
cube = pCore.polyCube()[0]
sphere = pCore.polySphere()[0]
null = pCore.spaceLocator()
metaNode = eMetaData.MetaData()
self.TestNodes.extend([cube, sphere, null, metaNode.MetaNode])
# Create and set custom vertex colors on a polygon object
# We create a poly sphere, then add two new colorsets,
# (1) with the "shared" vertex normal
# (2) with the face normal set on all face-vertices
import pymel.core as pm # PyMel commands
object = pm.polySphere(name='myPolySphere')
poly = pm.PyNode(object[0]).getShape()
try:
pm.nodetypes.Mesh(poly)
print ">> mesh:", poly.name()
except TypeError:
print "Not a mesh"
allColorSets = poly.getColorSetNames()
print ">> color sets, before:", allColorSets
# (1) set color from shared normal at each polygon vertex
colorSet = 'mySharedNormal'
print ">> create color set:", colorSet
# create new empty custom color set
if not colorSet in allColorSets:
poly.createColorSet(colorSetName=colorSet)
pmc.select(sel, r=True)
def add(s, m): s.nodes[0].add(m)
def discard(s, m):
for sel in s.nodes:
if m in sel: sel.remove(m)
def __len__(s): return sum(len(a) for a in s.nodes)
def __iter__(s):
for node in s.nodes:
for mesh in node:
yield mesh
def __contains__(s, m): return m in set(b for a in s.nodes for b in a)
def __repr__(s): return "Collection :: [%s]" % ",".join(repr(a) for a in s)
if __name__ == '__main__':
# Testing
import random
def rand_pos(): return [random.random() * 10 - 5 for a in range(3)]
pmc.system.newFile(force=True)
objs = [pmc.polySphere()[0] for a in range(5)]
for o in objs: pmc.xform(o, t=rand_pos())
name = "OutOfControlRig"
set1 = pmc.sets(objs[:2], n="some:thing:%s" % name)
container = Meshes("OutOfControlRig")
print "contains".center(20, "-")
print container
print "added".center(20, "-")
for o in objs: container.add(o)
print container
#load new scene without saving
pm.mel.eval('file -f -new;')
#if plugin is loaded unload and reload it, else reload
if(pm.pluginInfo( 'rbRoll.py', query=True, loaded=True )):
pm.unloadPlugin( 'rbRoll.py' )
pm.loadPlugin( 'rbRoll.py' )
else: pm.loadPlugin( 'rbRoll.py' )
except:
print('Error Reloading Plugin')
try:
#Create Sphere
sphereTrans = pm.polySphere(ch = False, r = 1)[0]
pm.select(cl = True)
sphereShape = sphereTrans.getShape()
pm.select(cl = True)
#Create root_j and root_j_grp
root_j = pm.joint(a = True, p = (0.0,0.0,0.0), n = 'root_j')
pm.select(cl = True)
root_j_grp = pm.group(root_j, n = 'root_j_grp')
pm.select(cl = True)
#create root_j_manip
root_j_manip = pm.circle(r = 1.3, nr = (0.0,1.0,0.0), n = 'root_j_manip', ch = False)[0]
pm.select(cl = True)
root_j_manip_grp = pm.group(root_j_manip, n = 'root_j_manip_grp')
pm.select(cl = True)
